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HcalTB04Analysis Class Reference

#include <SimG4CMS/HcalTestBeam/interface/HcalTB04Analysis.h>

Inheritance diagram for HcalTB04Analysis:
SimProducer Observer< const BeginOfRun * > Observer< const BeginOfEvent * > Observer< const EndOfEvent * > Observer< const G4Step * > SimWatcher

Public Member Functions

 HcalTB04Analysis (const edm::ParameterSet &p)
 
virtual void produce (edm::Event &, const edm::EventSetup &)
 
virtual ~HcalTB04Analysis ()
 
- Public Member Functions inherited from SimProducer
void registerProducts (edm::ProducerBase &iProd)
 
 SimProducer ()
 
- Public Member Functions inherited from SimWatcher
 SimWatcher ()
 
virtual ~SimWatcher ()
 
- Public Member Functions inherited from Observer< const BeginOfRun * >
 Observer ()
 
void slotForUpdate (const BeginOfRun *iT)
 
virtual ~Observer ()
 
- Public Member Functions inherited from Observer< const BeginOfEvent * >
 Observer ()
 
void slotForUpdate (const BeginOfEvent *iT)
 
virtual ~Observer ()
 
- Public Member Functions inherited from Observer< const EndOfEvent * >
 Observer ()
 
void slotForUpdate (const EndOfEvent *iT)
 
virtual ~Observer ()
 
- Public Member Functions inherited from Observer< const G4Step * >
 Observer ()
 
void slotForUpdate (const G4Step *iT)
 
virtual ~Observer ()
 

Private Member Functions

void clear ()
 
void fillBuffer (const EndOfEvent *evt)
 
void fillEvent (PHcalTB04Info &)
 
void finalAnalysis ()
 
 HcalTB04Analysis (const HcalTB04Analysis &)
 
void init ()
 
const HcalTB04Analysisoperator= (const HcalTB04Analysis &)
 
void qieAnalysis (CLHEP::HepRandomEngine *)
 
double scale (int det, int layer)
 
double timeOfFlight (int det, int layer, double eta)
 
int unitID (uint32_t id)
 
void update (const BeginOfRun *run)
 This routine will be called when the appropriate signal arrives. More...
 
void update (const BeginOfEvent *evt)
 This routine will be called when the appropriate signal arrives. More...
 
void update (const G4Step *step)
 This routine will be called when the appropriate signal arrives. More...
 
void update (const EndOfEvent *evt)
 This routine will be called when the appropriate signal arrives. More...
 
void xtalAnalysis (CLHEP::HepRandomEngine *)
 

Private Attributes

G4RotationMatrix * beamline_RM
 
double beamOffset
 
int count
 
std::vector< CaloHitecalHitCache
 
double ecalNoise
 
double eecalq
 
double eecals
 
double ehcalq
 
double ehcals
 
std::vector< double > enois
 
std::vector< double > eqeta
 
std::vector< double > eqie
 
std::vector< double > eqlay
 
std::vector< double > eqphi
 
std::vector< double > eseta
 
std::vector< double > esime
 
std::vector< double > esimh
 
std::vector< double > eslay
 
std::vector< double > esphi
 
double etaInit
 
double etotq
 
double etots
 
int evNum
 
std::vector< CaloHithcalHitCache
 
std::vector< CaloHithcalHitLayer
 
bool hcalOnly
 
HcalTB04Histohisto
 
int iceta
 
int icphi
 
std::vector< uint32_t > idEcal
 
std::vector< int > idHcal
 
std::vector< uint32_t > idTower
 
std::vector< int > idXtal
 
int mode
 
HcalQiemyQie
 
std::vector< std::string > names
 
int nCrystal
 
int nPrimary
 
int nTower
 
int particleType
 
double phiInit
 
double pInit
 
bool pvFound
 
G4ThreeVector pvMomentum
 
G4ThreeVector pvPosition
 
int pvType
 
G4ThreeVector pvUVW
 
double scaleHB0
 
double scaleHB16
 
double scaleHE0
 
double scaleHO
 
std::vector< double > secEkin
 
std::vector< G4ThreeVector > secMomentum
 
std::vector< int > secPartID
 
std::vector< int > secTrackID
 
std::vector< int > shortLivedSecondaries
 
int type
 

Additional Inherited Members

- Protected Member Functions inherited from SimProducer
template<class T >
void produces ()
 
template<class T >
void produces (const std::string &instanceName)
 

Detailed Description

Description: Analysis of 2004 Hcal Test beam simulation

Usage: A Simwatcher class and can be activated from Oscarproducer module

Definition at line 51 of file HcalTB04Analysis.h.

Constructor & Destructor Documentation

HcalTB04Analysis::HcalTB04Analysis ( const edm::ParameterSet p)

Definition at line 57 of file HcalTB04Analysis.cc.

References beamline_RM, beamOffset, ecalNoise, create_public_lumi_plots::exp, edm::ParameterSet::getParameter(), hcalOnly, histo, iceta, icphi, init(), mode, myQie, names, scaleHB0, scaleHB16, scaleHE0, and scaleHO.

57  : myQie(0),
58  histo(0) {
59 
60  edm::ParameterSet m_Anal = p.getParameter<edm::ParameterSet>("HcalTB04Analysis");
61  hcalOnly = m_Anal.getParameter<bool>("HcalOnly");
62  mode = m_Anal.getParameter<int>("Mode");
63  type = m_Anal.getParameter<int>("Type");
64  ecalNoise = m_Anal.getParameter<double>("EcalNoise");
65  scaleHB0 = m_Anal.getParameter<double>("ScaleHB0");
66  scaleHB16 = m_Anal.getParameter<double>("ScaleHB16");
67  scaleHO = m_Anal.getParameter<double>("ScaleHO");
68  scaleHE0 = m_Anal.getParameter<double>("ScaleHE0");
69  names = m_Anal.getParameter<std::vector<std::string> >("Names");
70  beamOffset =-m_Anal.getParameter<double>("BeamPosition")*cm;
71  double fMinEta = m_Anal.getParameter<double>("MinEta");
72  double fMaxEta = m_Anal.getParameter<double>("MaxEta");
73  double fMinPhi = m_Anal.getParameter<double>("MinPhi");
74  double fMaxPhi = m_Anal.getParameter<double>("MaxPhi");
75  double beamEta = (fMaxEta+fMinEta)/2.;
76  double beamPhi = (fMaxPhi+fMinPhi)/2.;
77  double beamThet= 2*atan(exp(-beamEta));
78  if (beamPhi < 0) beamPhi += twopi;
79  iceta = (int)(beamEta/0.087) + 1;
80  icphi = (int)(fabs(beamPhi)/0.087) + 5;
81  if (icphi > 72) icphi -= 73;
82 
83  produces<PHcalTB04Info>();
84 
85  beamline_RM = new G4RotationMatrix;
86  beamline_RM->rotateZ(-beamPhi);
87  beamline_RM->rotateY(-beamThet);
88 
89  edm::LogInfo("HcalTBSim") << "HcalTB04:: Initialised as observer of BeginOf"
90  << "Job/BeginOfRun/BeginOfEvent/G4Step/EndOfEvent"
91  << " with Parameter values:\n \thcalOnly = "
92  << hcalOnly << "\tecalNoise = " << ecalNoise
93  << "\n\tMode = " << mode << " (0: HB2 Standard; "
94  << "1:HB2 Segmented)" << "\tType = " << type
95  << " (0: HB; 1 HE; 2 HB+HE)\n\tbeamOffset = "
96  << beamOffset << "\ticeta = " << iceta
97  << "\ticphi = " << icphi << "\n\tbeamline_RM = "
98  << *beamline_RM;
99 
100  init();
101 
102  myQie = new HcalQie(p);
103  histo = new HcalTB04Histo(m_Anal);
104 }
type
Definition: HCALResponse.h:21
T getParameter(std::string const &) const
G4RotationMatrix * beamline_RM
HcalTB04Histo * histo
std::vector< std::string > names
HcalTB04Analysis::~HcalTB04Analysis ( )
virtual

Definition at line 106 of file HcalTB04Analysis.cc.

References count, histo, and myQie.

106  {
107 
108  edm::LogInfo("HcalTBSim") << "\n --------> Total number of selected entries"
109  << " : " << count << "\nPointers:: QIE " << myQie
110  << " Histo " << histo;
111  if (myQie) {
112  delete myQie;
113  myQie = 0;
114  }
115  if (histo) {
116  delete histo;
117  histo = 0;
118  }
119 }
HcalTB04Histo * histo
HcalTB04Analysis::HcalTB04Analysis ( const HcalTB04Analysis )
private

Member Function Documentation

void HcalTB04Analysis::clear ( void  )
private

Definition at line 944 of file HcalTB04Analysis.cc.

References ecalHitCache, enois, eqie, esime, esimh, etaInit, hcalHitCache, hcalHitLayer, i, nCrystal, nPrimary, nTower, particleType, phiInit, pInit, pvFound, pvMomentum, pvPosition, pvType, pvUVW, secEkin, secMomentum, secPartID, secTrackID, and shortLivedSecondaries.

Referenced by init(), and update().

944  {
945  pvFound = false;
946  pvType =-2;
947  pvPosition = G4ThreeVector();
948  pvMomentum = G4ThreeVector();
949  pvUVW = G4ThreeVector();
950  secTrackID.clear();
951  secPartID.clear();
952  secMomentum.clear();
953  secEkin.clear();
954  shortLivedSecondaries.clear();
955 
956  ecalHitCache.erase(ecalHitCache.begin(), ecalHitCache.end());
957  hcalHitCache.erase(hcalHitCache.begin(), hcalHitCache.end());
958  hcalHitLayer.erase(hcalHitLayer.begin(), hcalHitLayer.end());
959  nPrimary = particleType = 0;
960  pInit = etaInit = phiInit = 0;
961 
962  esimh.clear();
963  eqie.clear();
964  esimh.reserve(nTower);
965  eqie.reserve(nTower);
966  for (int i=0; i<nTower; i++) {
967  esimh.push_back(0.);
968  eqie.push_back(0.);
969  }
970  esime.clear();
971  enois.clear();
972  esime.reserve(nCrystal);
973  enois.reserve(nCrystal);
974  for (int i=0; i<nCrystal; i++) {
975  esime.push_back(0.);
976  enois.push_back(0.);
977  }
978 }
int i
Definition: DBlmapReader.cc:9
std::vector< double > secEkin
std::vector< CaloHit > hcalHitLayer
std::vector< double > eqie
std::vector< int > shortLivedSecondaries
std::vector< int > secTrackID
std::vector< int > secPartID
G4ThreeVector pvUVW
std::vector< double > esime
std::vector< CaloHit > hcalHitCache
std::vector< CaloHit > ecalHitCache
std::vector< double > enois
std::vector< G4ThreeVector > secMomentum
G4ThreeVector pvMomentum
G4ThreeVector pvPosition
std::vector< double > esimh
void HcalTB04Analysis::fillBuffer ( const EndOfEvent evt)
private

Definition at line 399 of file HcalTB04Analysis.cc.

References TauDecayModes::dec, alignCSCRings::e, ecalHitCache, eta, etaInit, evNum, CaloG4Hit::getEnergyDeposit(), CaloG4Hit::getEntry(), CaloG4Hit::getTimeSlice(), CaloG4Hit::getTrackID(), HcalTBNumberingScheme::getUnitID(), CaloG4Hit::getUnitID(), GeV, watchdog::group, hcalHitCache, hcalHitLayer, i, j, relval_steps::k2, dqm-mbProfile::log, LogDebug, bookConverter::max, min(), mode, names, nPrimary, AlCaHLTBitMon_ParallelJobs::p, particleType, phi, phiInit, pInit, funct::pow(), scale(), mathSSE::sqrt(), AlCaHLTBitMon_QueryRunRegistry::string, funct::tan(), theta(), timeOfFlight(), unitID(), HcalTestNumbering::unpackHcalIndex(), and z.

Referenced by update().

399  {
400 
401  std::vector<CaloHit> hhits, hhitl;
402  int idHC, j;
403  CaloG4HitCollection* theHC;
404  std::map<int,float,std::less<int> > primaries;
405  double etot1=0, etot2=0;
406 
407  // Look for the Hit Collection of HCal
408  G4HCofThisEvent* allHC = (*evt)()->GetHCofThisEvent();
409  std::string sdName = names[0];
410  idHC = G4SDManager::GetSDMpointer()->GetCollectionID(sdName);
411  theHC = (CaloG4HitCollection*) allHC->GetHC(idHC);
412  LogDebug("HcalTBSim") << "HcalTB04Analysis:: Hit Collection for " << sdName
413  << " of ID " << idHC << " is obtained at " << theHC;
414 
415  if (idHC >= 0 && theHC > 0) {
416  hhits.reserve(theHC->entries());
417  hhitl.reserve(theHC->entries());
418  for (j = 0; j < theHC->entries(); j++) {
419  CaloG4Hit* aHit = (*theHC)[j];
420  double e = aHit->getEnergyDeposit()/GeV;
421  double time = aHit->getTimeSlice();
422  math::XYZPoint pos = aHit->getEntry();
423  unsigned int id = aHit->getUnitID();
424  double theta = pos.theta();
425  double eta = -log(tan(theta * 0.5));
426  double phi = pos.phi();
427  int det, z, group, ieta, iphi, layer;
428  HcalTestNumbering::unpackHcalIndex(id,det,z,group,ieta,iphi,layer);
429  double jitter = time-timeOfFlight(det,layer,eta);
430  if (jitter<0) jitter = 0;
431  if (e < 0 || e > 1.) e = 0;
432  double escl = e * scale(det,layer);
433  unsigned int idx= HcalTBNumberingScheme::getUnitID(id,mode);
434  CaloHit hit(det,layer,escl,eta,phi,jitter,idx);
435  hhits.push_back(hit);
436  CaloHit hitl(det,layer,escl,eta,phi,jitter,id);
437  hhitl.push_back(hitl);
438  primaries[aHit->getTrackID()]+= e;
439  etot1 += escl;
440 #ifdef ddebug
441  LogDebug("HcalTBSim") << "HcalTB04Analysis:: Hcal Hit i/p " << j
442  << " ID 0x" << std::hex << id << " 0x" << idx
443  << std::dec << " time " << std::setw(6) << time
444  << " " << std::setw(6) << jitter << " theta "
445  << std::setw(8) << theta << " eta " << std::setw(8)
446  << eta << " phi " << std::setw(8) << phi << " e "
447  << std::setw(8) << e << " " << std::setw(8) <<escl;
448 #endif
449  }
450  }
451 
452  // Add hits in the same channel within same time slice
453  std::vector<CaloHit>::iterator itr;
454  int nHit = hhits.size();
455  std::vector<CaloHit*> hits(nHit);
456  for (j = 0, itr = hhits.begin(); itr != hhits.end(); j++, itr++) {
457  hits[j] = &hhits[j];
458  }
459  sort(hits.begin(),hits.end(),CaloHitIdMore());
460  std::vector<CaloHit*>::iterator k1, k2;
461  int nhit = 0;
462  for (k1 = hits.begin(); k1 != hits.end(); k1++) {
463  int det = (**k1).det();
464  int layer = (**k1).layer();
465  double ehit = (**k1).e();
466  double eta = (**k1).eta();
467  double phi = (**k1).phi();
468  double jitter = (**k1).t();
469  uint32_t unitID = (**k1).id();
470  int jump = 0;
471  for (k2 = k1+1; k2 != hits.end() && fabs(jitter-(**k2).t())<1 &&
472  unitID==(**k2).id(); k2++) {
473  ehit += (**k2).e();
474  jump++;
475  }
476  nhit++;
477  CaloHit hit(det, layer, ehit, eta, phi, jitter, unitID);
478  hcalHitCache.push_back(hit);
479  etot2 += ehit;
480  k1 += jump;
481 #ifdef ddebug
482  LogDebug("HcalTBSim") << "HcalTB04Analysis:: Hcal Hit store " << nhit
483  << " ID 0x" << std::hex << unitID << std::dec
484  << " time " << std::setw(6) << jitter << " eta "
485  << std::setw(8) << eta << " phi " << std::setw(8)
486  << phi << " e " << std::setw(8) << ehit;
487 #endif
488  }
489  LogDebug("HcalTBSim") << "HcalTB04Analysis:: Stores " << nhit << " HCal hits"
490  << " from " << nHit << " input hits E(Hcal) " << etot1
491  << " " << etot2;
492 
493  //Repeat for Hit in each layer (hhits and hhitl sizes are the same)
494  for (j = 0, itr = hhitl.begin(); itr != hhitl.end(); j++, itr++) {
495  hits[j] = &hhitl[j];
496  }
497  sort(hits.begin(),hits.end(),CaloHitIdMore());
498  int nhitl = 0;
499  double etotl = 0;
500  for (k1 = hits.begin(); k1 != hits.end(); k1++) {
501  int det = (**k1).det();
502  int layer = (**k1).layer();
503  double ehit = (**k1).e();
504  double eta = (**k1).eta();
505  double phi = (**k1).phi();
506  double jitter = (**k1).t();
507  uint32_t unitID = (**k1).id();
508  int jump = 0;
509  for (k2 = k1+1; k2 != hits.end() && fabs(jitter-(**k2).t())<1 &&
510  unitID==(**k2).id(); k2++) {
511  ehit += (**k2).e();
512  jump++;
513  }
514  nhitl++;
515  CaloHit hit(det, layer, ehit, eta, phi, jitter, unitID);
516  hcalHitLayer.push_back(hit);
517  etotl += ehit;
518  k1 += jump;
519 #ifdef ddebug
520  LogDebug("HcalTBSim") << "HcalTB04Analysis:: Hcal Hit store " << nhitl
521  << " ID 0x" << std::hex << unitID << std::dec
522  << " time " << std::setw(6) << jitter << " eta "
523  << std::setw(8) << eta << " phi " << std::setw(8)
524  << phi << " e " << std::setw(8) << ehit;
525 #endif
526  }
527  LogDebug("HcalTBSim") << "HcalTB04Analysis:: Stores " << nhitl << " HCal "
528  << "hits from " << nHit << " input hits E(Hcal) "
529  << etot1 << " " << etotl;
530 
531  // Look for the Hit Collection of ECal
532  std::vector<CaloHit> ehits;
533  sdName= names[1];
534  idHC = G4SDManager::GetSDMpointer()->GetCollectionID(sdName);
535  theHC = (CaloG4HitCollection*) allHC->GetHC(idHC);
536  etot1 = etot2 = 0;
537  LogDebug("HcalTBSim") << "HcalTB04Analysis:: Hit Collection for " << sdName
538  << " of ID " << idHC << " is obtained at " << theHC;
539  if (idHC >= 0 && theHC > 0) {
540  ehits.reserve(theHC->entries());
541  for (j = 0; j < theHC->entries(); j++) {
542  CaloG4Hit* aHit = (*theHC)[j];
543  double e = aHit->getEnergyDeposit()/GeV;
544  double time = aHit->getTimeSlice();
545  math::XYZPoint pos = aHit->getEntry();
546  unsigned int id = aHit->getUnitID();
547  double theta = pos.theta();
548  double eta = -log(tan(theta * 0.5));
549  double phi = pos.phi();
550  if (e < 0 || e > 100000.) e = 0;
551  int det, z, group, ieta, iphi, layer;
552  HcalTestNumbering::unpackHcalIndex(id,det,z,group,ieta,iphi,layer);
553  CaloHit hit(det,0,e,eta,phi,time,id);
554  ehits.push_back(hit);
555  primaries[aHit->getTrackID()]+= e;
556  etot1 += e;
557 #ifdef ddebug
558  LogDebug("HcalTBSim") << "HcalTB04Analysis:: Ecal Hit i/p " << j
559  << " ID 0x" << std::hex << id << std::dec
560  << " time " << std::setw(6) << time << " theta "
561  << std::setw(8) << theta << " eta " <<std::setw(8)
562  << eta << " phi " << std::setw(8) << phi << " e "
563  << std::setw(8) << e;
564 #endif
565  }
566  }
567 
568  // Add hits in the same channel within same time slice
569  nHit = ehits.size();
570  std::vector<CaloHit*> hite(nHit);
571  for (j = 0, itr = ehits.begin(); itr != ehits.end(); j++, itr++) {
572  hite[j] = &ehits[j];
573  }
574  sort(hite.begin(),hite.end(),CaloHitIdMore());
575  nhit = 0;
576  for (k1 = hite.begin(); k1 != hite.end(); k1++) {
577  int det = (**k1).det();
578  int layer = (**k1).layer();
579  double ehit = (**k1).e();
580  double eta = (**k1).eta();
581  double phi = (**k1).phi();
582  double jitter = (**k1).t();
583  uint32_t unitID = (**k1).id();
584  int jump = 0;
585  for (k2 = k1+1; k2 != hite.end() && fabs(jitter-(**k2).t())<1 &&
586  unitID==(**k2).id(); k2++) {
587  ehit += (**k2).e();
588  jump++;
589  }
590  nhit++;
591  CaloHit hit(det, layer, ehit, eta, phi, jitter, unitID);
592  ecalHitCache.push_back(hit);
593  etot2 += ehit;
594  k1 += jump;
595 #ifdef ddebug
596  LogDebug("HcalTBSim") << "HcalTB04Analysis:: Ecal Hit store " << nhit
597  << " ID 0x" << std::hex << unitID << std::dec
598  << " time " << std::setw(6) << jitter << " eta "
599  << std::setw(8) << eta << " phi " << std::setw(8)
600  << phi << " e " << std::setw(8) << ehit;
601 #endif
602  }
603  LogDebug("HcalTBSim") << "HcalTB04Analysis:: Stores " << nhit << " ECal hits"
604  << " from " << nHit << " input hits E(Ecal) " << etot1
605  << " " << etot2;
606 
607  // Find Primary info:
608  nPrimary = (int)(primaries.size());
609  int trackID = 0;
610  G4PrimaryParticle* thePrim=0;
611  int nvertex = (*evt)()->GetNumberOfPrimaryVertex();
612  LogDebug("HcalTBSim") << "HcalTB04Analysis:: Event has " << nvertex
613  << " verteices";
614  if (nvertex<=0)
615  edm::LogInfo("HcalTBSim") << "HcalTB04Analysis::EndOfEvent ERROR: no "
616  << "vertex found for event " << evNum;
617 
618  for (int i = 0 ; i<nvertex; i++) {
619  G4PrimaryVertex* avertex = (*evt)()->GetPrimaryVertex(i);
620  if (avertex == 0) {
621  edm::LogInfo("HcalTBSim") << "HcalTB04Analysis::EndOfEvent ERR: pointer "
622  << "to vertex = 0 for event " << evNum;
623  } else {
624  LogDebug("HcalTBSim") << "HcalTB04Analysis::Vertex number :" << i << " "
625  << avertex->GetPosition();
626  int npart = avertex->GetNumberOfParticle();
627  if (npart == 0)
628  edm::LogWarning("HcalTBSim") << "HcalTB04Analysis::End Of Event ERR: "
629  << "no primary!";
630  if (thePrim==0) thePrim=avertex->GetPrimary(trackID);
631  }
632  }
633 
634  if (thePrim != 0) {
635  double px = thePrim->GetPx();
636  double py = thePrim->GetPy();
637  double pz = thePrim->GetPz();
638  double p = std::sqrt(pow(px,2.)+pow(py,2.)+pow(pz,2.));
639  pInit = p/GeV;
640  if (p==0)
641  edm::LogWarning("HcalTBSim") << "HcalTB04Analysis:: EndOfEvent ERR: "
642  << "primary has p=0 ";
643  else {
644  double costheta = pz/p;
645  double theta = acos(std::min(std::max(costheta,-1.),1.));
646  etaInit = -log(tan(theta/2));
647  if (px != 0 || py != 0) phiInit = atan2(py,px);
648  }
649  particleType = thePrim->GetPDGcode();
650  } else
651  edm::LogWarning("HcalTBSim") << "HcalTB04Analysis::EndOfEvent ERR: could "
652  << "not find primary";
653 
654 }
#define LogDebug(id)
int i
Definition: DBlmapReader.cc:9
const double GeV
Definition: MathUtil.h:16
std::vector< CaloHit > hcalHitLayer
Geom::Theta< T > theta() const
T sqrt(T t)
Definition: SSEVec.h:18
Tan< T >::type tan(const T &t)
Definition: Tan.h:22
int j
Definition: DBlmapReader.cc:9
static void unpackHcalIndex(const uint32_t &idx, int &det, int &z, int &depth, int &eta, int &phi, int &lay)
T min(T a, T b)
Definition: MathUtil.h:58
double scale(int det, int layer)
double timeOfFlight(int det, int layer, double eta)
tuple group
Definition: watchdog.py:82
std::vector< CaloHit > hcalHitCache
int getTrackID() const
Definition: CaloG4Hit.h:68
static uint32_t getUnitID(const uint32_t id, const int mode)
XYZPointD XYZPoint
point in space with cartesian internal representation
Definition: Point3D.h:12
std::vector< CaloHit > ecalHitCache
int unitID(uint32_t id)
G4THitsCollection< CaloG4Hit > CaloG4HitCollection
double getTimeSlice() const
Definition: CaloG4Hit.h:70
math::XYZPoint getEntry() const
Definition: CaloG4Hit.h:50
uint32_t getUnitID() const
Definition: CaloG4Hit.h:69
std::vector< std::string > names
Power< A, B >::type pow(const A &a, const B &b)
Definition: Power.h:40
double getEnergyDeposit() const
Definition: CaloG4Hit.h:81
void HcalTB04Analysis::fillEvent ( PHcalTB04Info product)
private

Definition at line 870 of file HcalTB04Analysis.cc.

References TauDecayModes::dec, ecalHitCache, eecalq, eecals, ehcalq, ehcals, enois, eqeta, eqie, eqlay, eqphi, eseta, esime, esimh, eslay, esphi, etaInit, etotq, etots, evNum, watchdog::group, hcalHitCache, i, hit::id, idHcal, idXtal, LogDebug, nPrimary, particleType, phiInit, pInit, pvMomentum, pvPosition, pvType, pvUVW, PHcalTB04Info::saveHit(), secEkin, secMomentum, secPartID, secTrackID, PHcalTB04Info::setEdep(), PHcalTB04Info::setEdepHcal(), PHcalTB04Info::setIDs(), PHcalTB04Info::setLongProf(), PHcalTB04Info::setPrimary(), PHcalTB04Info::setTrnsProf(), PHcalTB04Info::setVtxPrim(), PHcalTB04Info::setVtxSec(), HcalTestNumbering::unpackHcalIndex(), x, y, and z.

Referenced by produce().

870  {
871 
872  //Setup the ID's
873  product.setIDs(idHcal, idXtal);
874 
875  //Beam Information
877 
878  //Energy deposits in the crystals and towers
879  product.setEdepHcal(esimh, eqie);
880  product.setEdepHcal(esime, enois);
881 
882  // Total Energy
883  product.setEdep(etots, eecals, ehcals, etotq, eecalq, ehcalq);
884 
885  // Lateral Profile
886  product.setTrnsProf(eseta,eqeta,esphi,eqphi);
887 
888  // Longitudianl profile
889  product.setLongProf(eslay, eqlay);
890 
891  //Save Hits
892  int i, nhit=0;
893  std::vector<CaloHit>::iterator itr;
894  for (i=0, itr=ecalHitCache.begin(); itr!=ecalHitCache.end(); i++,itr++) {
895  uint32_t id = itr->id();
896  int det, z, group, ieta, iphi, lay;
897  HcalTestNumbering::unpackHcalIndex(id,det,z,group,ieta,iphi,lay);
898  product.saveHit(det, lay, ieta, iphi, itr->e(), itr->t());
899  nhit++;
900 #ifdef debug
901  LogDebug("HcalTBSim") << "HcalTB04Analysis:: Save Hit " << std::setw(3)
902  << i+1 << " ID 0x" << std::hex << group << std::dec
903  << " " << std::setw(2) << det << " " << std::setw(2)
904  << lay << " " << std::setw(1) << z << " "
905  << std::setw(3) << ieta << " " << std::setw(3) <<iphi
906  << " T " << std::setw(6) << itr->t() << " E "
907  << std::setw(6) << itr->e();
908 #endif
909  }
910  LogDebug("HcalTBSim") << "HcalTB04Analysis:: Saves " << nhit
911  << " hits from Crystals";
912  int hit = nhit;
913  nhit = 0;
914 
915  for (i=hit, itr=hcalHitCache.begin(); itr!=hcalHitCache.end(); i++,itr++) {
916  uint32_t id = itr->id();
917  int det, z, group, ieta, iphi, lay;
918  HcalTestNumbering::unpackHcalIndex(id,det,z,group,ieta,iphi,lay);
919  product.saveHit(det, lay, ieta, iphi, itr->e(), itr->t());
920  nhit++;
921 #ifdef debug
922  LogDebug("HcalTBSim") << "HcalTB04Analysis:: Save Hit " << std::setw(3)
923  << i+1 << " ID 0x" << std::hex << group << std::dec
924  << " " << std::setw(2) << det << " " << std::setw(2)
925  << lay << " " << std::setw(1) << z << " "
926  << std::setw(3) << ieta << " " << std::setw(3) <<iphi
927  << " T " << std::setw(6) << itr->t() << " E "
928  << std::setw(6) << itr->e();
929 #endif
930  }
931  LogDebug("HcalTBSim") << "HcalTB04Analysis:: Saves " << nhit
932  << " hits from HCal";
933 
934  //Vertex associated quantities
935  product.setVtxPrim(evNum, pvType, pvPosition.x(), pvPosition.y(),
936  pvPosition.z(), pvUVW.x(), pvUVW.y(), pvUVW.z(),
937  pvMomentum.x(), pvMomentum.y(), pvMomentum.z());
938  for (unsigned int i = 0; i < secTrackID.size(); i++) {
939  product.setVtxSec(secTrackID[i], secPartID[i], secMomentum[i].x(),
940  secMomentum[i].y(), secMomentum[i].z(), secEkin[i]);
941  }
942 }
#define LogDebug(id)
int i
Definition: DBlmapReader.cc:9
std::vector< double > secEkin
void setLongProf(const std::vector< double > &es, const std::vector< double > &eq)
std::vector< int > idHcal
std::vector< double > eqeta
std::vector< double > eqie
std::vector< int > secTrackID
std::vector< double > eqphi
void setPrimary(int primary, int id, double energy, double eta, double phi)
void setEdep(double simtot, double sime, double simh, double digtot, double dige, double digh)
void setTrnsProf(const std::vector< double > &es1, const std::vector< double > &eq1, const std::vector< double > &es2, const std::vector< double > &eq2)
void saveHit(int det, int lay, int eta, int phi, double e, double t)
std::vector< int > secPartID
std::vector< double > eseta
void setIDs(const std::vector< int > &, const std::vector< int > &)
void setVtxSec(int id, int pdg, double px, double py, double pz, double ek)
G4ThreeVector pvUVW
void setEdepHcal(const std::vector< double > &esim, const std::vector< double > &edig)
static void unpackHcalIndex(const uint32_t &idx, int &det, int &z, int &depth, int &eta, int &phi, int &lay)
std::vector< double > esime
std::vector< double > esphi
unsigned int id
tuple group
Definition: watchdog.py:82
std::vector< CaloHit > hcalHitCache
std::vector< int > idXtal
std::vector< CaloHit > ecalHitCache
std::vector< double > enois
void setVtxPrim(int evNum, int type, double x, double y, double z, double u, double v, double w, double px, double py, double pz)
std::vector< G4ThreeVector > secMomentum
G4ThreeVector pvMomentum
std::vector< double > eslay
std::vector< double > eqlay
G4ThreeVector pvPosition
std::vector< double > esimh
void HcalTB04Analysis::finalAnalysis ( )
private

Definition at line 768 of file HcalTB04Analysis.cc.

References reco::e1, reco::e2, eecalq, eecals, ehcalq, ehcals, enois, eqeta, eqie, eqlay, eqphi, eseta, esime, esimh, eslay, esphi, etaInit, etotq, etots, HcalTB04Histo::fillEdep(), HcalTB04Histo::fillLongProf(), HcalTB04Histo::fillPrimary(), HcalTB04Histo::fillTrnsProf(), watchdog::group, histo, i, iceta, icphi, idTower, LogDebug, nCrystal, nTower, phiInit, pInit, HcalTestNumbering::unpackHcalIndex(), and z.

Referenced by update().

768  {
769 
770  //Beam Information
772 
773  // Total Energy
774  eecals = ehcals = eecalq = ehcalq = 0.;
775  for (int i=0; i<nTower; i++) {
776  ehcals += esimh[i];
777  ehcalq += eqie[i];
778  }
779  for (int i=0; i<nCrystal; i++) {
780  eecals += esime[i];
781  eecalq += enois[i];
782  }
783  etots = eecals + ehcals;
784  etotq = eecalq + ehcalq;
785  LogDebug("HcalTBSim") << "HcalTB04Analysis:: Energy deposit at Sim Level "
786  << "(Total) " << etots << " (ECal) " << eecals
787  << " (HCal) " << ehcals << "\nHcalTB04Analysis:: "
788  << "Energy deposit at Qie Level (Total) " << etotq
789  << " (ECal) " << eecalq << " (HCal) " << ehcalq;
790  histo->fillEdep(etots, eecals, ehcals, etotq, eecalq, ehcalq);
791 
792  // Lateral Profile
793  for (int i=0; i<5; i++) {
794  eseta[i] = 0.;
795  eqeta[i] = 0.;
796  }
797  for (int i=0; i<3; i++) {
798  esphi[i] = 0.;
799  eqphi[i] = 0.;
800  }
801  double e1=0, e2=0;
802  unsigned int id;
803  for (int i=0; i<nTower; i++) {
804  int det, z, group, ieta, iphi, layer;
805  id = idTower[i];
806  HcalTestNumbering::unpackHcalIndex(id,det,z,group,ieta,iphi,layer);
807  iphi -= (icphi - 1);
808  if (icphi > 4) {
809  if (ieta == 0) ieta = 2;
810  else ieta =-1;
811  } else {
812  ieta = ieta - iceta + 2;
813  }
814  if (iphi >= 0 && iphi < 3 && ieta >= 0 && ieta < 5) {
815  eseta[ieta] += esimh[i];
816  esphi[iphi] += esimh[i];
817  e1 += esimh[i];
818  eqeta[ieta] += eqie[i];
819  eqphi[iphi] += eqie[i];
820  e2 += eqie[i];
821  }
822  }
823  for (int i=0; i<3; i++) {
824  if (e1>0) esphi[i] /= e1;
825  if (e2>0) eqphi[i] /= e2;
826  }
827  for (int i=0; i<5; i++) {
828  if (e1>0) eseta[i] /= e1;
829  if (e2>0) eqeta[i] /= e2;
830  }
831  LogDebug("HcalTBSim") << "HcalTB04Analysis:: Energy fraction along Eta and"
832  << " Phi (Sim/Qie)";
833  for (int i=0; i<5; i++)
834  LogDebug("HcalTBSim") << "HcalTB04Analysis:: [" << i << "] Eta Sim = "
835  << eseta[i] << " Qie = " << eqeta[i] << " Phi Sim = "
836  << esphi[i] << " Qie = " << eqphi[i];
838 
839  // Longitudianl profile
840  for (int i=0; i<20; i++) {
841  eslay[i] = 0.;
842  eqlay[i] = 0.;
843  }
844  e1=0; e2=0;
845  for (int i=0; i<nTower; i++) {
846  int det, z, group, ieta, iphi, layer;
847  id = idTower[i];
848  HcalTestNumbering::unpackHcalIndex(id,det,z,group,ieta,iphi,layer);
849  iphi -= (icphi - 1);
850  layer -= 1;
851  if (iphi >= 0 && iphi < 3 && layer >= 0 && layer < 20) {
852  eslay[layer] += esimh[i];
853  e1 += esimh[i];
854  eqlay[layer] += eqie[i];
855  e2 += eqie[i];
856  }
857  }
858  for (int i=0; i<20; i++) {
859  if (e1>0) eslay[i] /= e1;
860  if (e2>0) eqlay[i] /= e2;
861  }
862  LogDebug("HcalTBSim") << "HcalTB04Analysis:: Energy fraction along Layer";
863  for (int i=0; i<20; i++)
864  LogDebug("HcalTBSim") << "HcalTB04Analysis:: [" << i << "] Sim = "
865  << eslay[i] << " Qie = " << eqlay[i];
866  histo->fillLongProf(eslay, eqlay);
867 }
#define LogDebug(id)
int i
Definition: DBlmapReader.cc:9
void fillPrimary(double energy, double eta, double phi)
std::vector< double > eqeta
std::vector< double > eqie
void fillTrnsProf(const std::vector< double > &es1, const std::vector< double > &eq1, const std::vector< double > &es2, const std::vector< double > &eq2)
std::vector< double > eqphi
std::vector< double > eseta
static void unpackHcalIndex(const uint32_t &idx, int &det, int &z, int &depth, int &eta, int &phi, int &lay)
std::vector< double > esime
std::vector< double > esphi
Float e1
Definition: deltaR.h:20
tuple group
Definition: watchdog.py:82
std::vector< double > enois
Float e2
Definition: deltaR.h:21
HcalTB04Histo * histo
std::vector< uint32_t > idTower
std::vector< double > eslay
std::vector< double > eqlay
void fillEdep(double etots, double eecals, double ehcals, double etotq, double eecalq, double ehcalq)
std::vector< double > esimh
void fillLongProf(const std::vector< double > &es, const std::vector< double > &eq)
void HcalTB04Analysis::init ( void  )
private

Definition at line 132 of file HcalTB04Analysis.cc.

References clear(), count, TauDecayModes::dec, eqeta, eqlay, eqphi, eseta, eslay, esphi, evNum, HcalTBNumberingScheme::getUnitIDs(), hcalOnly, i, idEcal, idHcal, idTower, idXtal, LogDebug, mode, nCrystal, nTower, HcalTestNumbering::packHcalIndex(), and unitID().

Referenced by HcalTB04Analysis().

132  {
133 
135  nTower = idTower.size();
136  edm::LogInfo("HcalTBSim") << "HcalTB04Analysis:: Save information from "
137  << nTower << " HCal towers";
138  idHcal.reserve(nTower);
139  for (int i=0; i<nTower; i++) {
140  int id = unitID(idTower[i]);
141  idHcal.push_back(id);
142  LogDebug("HcalTBSim") << "\tTower[" << i << "] Original " << std::hex
143  << idTower[i] << " Stored " << idHcal[i] << std::dec;
144  }
145 
146  if (!hcalOnly) {
147  int det = 10;
148  uint32_t id1;
149  nCrystal = 0;
150  for (int lay=1; lay<8; lay++) {
151  for (int icr=1; icr<8; icr++) {
152  id1 = HcalTestNumbering::packHcalIndex(det,0,1,icr,lay,1);
153  int id = unitID(id1);
154  idEcal.push_back(id1);
155  idXtal.push_back(id);
156  nCrystal++;
157  }
158  }
159  edm::LogInfo("HcalTBSim") << "HcalTB04Analysis:: Save information from "
160  << nCrystal << " ECal Crystals";
161  for (int i=0; i<nCrystal; i++) {
162  LogDebug("HcalTBSim") << "\tCrystal[" << i << "] Original " << std::hex
163  << idEcal[i] << " Stored " << idXtal[i] <<std::dec;
164  }
165  }
166  // Profile vectors
167  eseta.reserve(5);
168  eqeta.reserve(5);
169  esphi.reserve(3);
170  eqphi.reserve(3);
171  eslay.reserve(20);
172  eqlay.reserve(20);
173  for (int i=0; i<5; i++) {
174  eseta.push_back(0.);
175  eqeta.push_back(0.);
176  }
177  for (int i=0; i<3; i++) {
178  esphi.push_back(0.);
179  eqphi.push_back(0.);
180  }
181  for (int i=0; i<20; i++) {
182  eslay.push_back(0.);
183  eqlay.push_back(0.);
184  }
185 
186  // counter
187  count = 0;
188  evNum = 0;
189  clear();
190 }
#define LogDebug(id)
type
Definition: HCALResponse.h:21
int i
Definition: DBlmapReader.cc:9
std::vector< int > idHcal
std::vector< double > eqeta
std::vector< double > eqphi
static uint32_t packHcalIndex(int det, int z, int depth, int eta, int phi, int lay)
std::vector< uint32_t > idEcal
std::vector< double > eseta
static std::vector< uint32_t > getUnitIDs(const int type, const int mode)
std::vector< double > esphi
std::vector< int > idXtal
int unitID(uint32_t id)
std::vector< uint32_t > idTower
std::vector< double > eslay
std::vector< double > eqlay
const HcalTB04Analysis& HcalTB04Analysis::operator= ( const HcalTB04Analysis )
private
void HcalTB04Analysis::produce ( edm::Event e,
const edm::EventSetup  
)
virtual

Implements SimProducer.

Definition at line 125 of file HcalTB04Analysis.cc.

References fillEvent(), eostools::move(), and edm::Event::put().

125  {
126 
127  std::unique_ptr<PHcalTB04Info> product(new PHcalTB04Info);
128  fillEvent(*product);
129  e.put(std::move(product));
130 }
OrphanHandle< PROD > put(std::unique_ptr< PROD > product)
Put a new product.
Definition: Event.h:122
def move
Definition: eostools.py:510
void fillEvent(PHcalTB04Info &)
void HcalTB04Analysis::qieAnalysis ( CLHEP::HepRandomEngine *  engine)
private

Definition at line 656 of file HcalTB04Analysis.cc.

References TauDecayModes::dec, CaloHit::e(), Vispa.Plugins.EdmBrowser.EdmDataAccessor::eq(), eqie, esimh, HcalQie::getCode(), HcalQie::getEnergy(), hcalHitCache, CaloHit::id(), idTower, relval_steps::k2, LogDebug, myQie, and nTower.

Referenced by update().

656  {
657 
658  int hittot = hcalHitCache.size();
659  if (hittot<=0) hittot = 1;
660  std::vector<CaloHit> hits(hittot);
661  std::vector<int> todo(nTower,0);
662 
663  LogDebug("HcalTBSim") << "HcalTB04Analysis::qieAnalysis: Size "
664  << hits.size() << " " << todo.size() << " "
665  << idTower.size() << " " << esimh.size() << " "
666  << eqie.size();
667  // Loop over all HCal hits
668  for (unsigned int k1 = 0; k1 < hcalHitCache.size(); k1++) {
669  CaloHit hit = hcalHitCache[k1];
670  uint32_t id = hit.id();
671  int nhit = 0;
672  double esim = hit.e();
673  hits[nhit] = hit;
674  for (unsigned int k2 = k1+1; k2 < hcalHitCache.size(); k2++) {
675  hit = hcalHitCache[k2];
676  if (hit.id() == id) {
677  nhit++;
678  hits[nhit] = hit;
679  esim += hit.e();
680  }
681  }
682  k1 += nhit;
683  nhit++;
684  std::vector<int> cd = myQie->getCode(nhit, hits, engine);
685  double eq = myQie->getEnergy(cd);
686  LogDebug("HcalTBSim") << "HcalTB04Analysis:: ID 0x" << std::hex << id
687  << std::dec << " registers " << esim << " energy "
688  << "from " << nhit << " hits starting with hit # "
689  << k1 << " energy with noise " << eq;
690  for (int k2 = 0; k2 < nTower; k2++) {
691  if (id == idTower[k2]) {
692  todo[k2] = 1;
693  esimh[k2] = esim;
694  eqie[k2] = eq;
695  }
696  }
697  }
698 
699  // Towers with no hit
700  for (int k2 = 0; k2 < nTower; k2++) {
701  if (todo[k2] == 0) {
702  std::vector<int> cd = myQie->getCode(0, hits, engine);
703  double eq = myQie->getEnergy(cd);
704  esimh[k2] = 0;
705  eqie[k2] = eq;
706 #ifdef ddebug
707  LogDebug("HcalTBSim") << "HcalTB04Analysis:: ID 0x" << std::hex
708  << idTower[k2] << std::dec << " registers "
709  << esimh[k2] << " energy from hits and energy "
710  << "after QIE analysis " << eqie[k2];
711 #endif
712  }
713  }
714 }
#define LogDebug(id)
std::vector< double > eqie
uint32_t id() const
Definition: CaloHit.h:28
double getEnergy(const std::vector< int > &)
Definition: HcalQie.cc:390
std::vector< CaloHit > hcalHitCache
double e() const
Definition: CaloHit.h:24
std::vector< int > getCode(int, const std::vector< CaloHit > &, CLHEP::HepRandomEngine *)
Definition: HcalQie.cc:296
std::vector< uint32_t > idTower
std::vector< double > esimh
double HcalTB04Analysis::scale ( int  det,
int  layer 
)
private

Definition at line 992 of file HcalTB04Analysis.cc.

References HcalBarrel, scaleHB0, scaleHB16, scaleHE0, scaleHO, and tmp.

Referenced by fillBuffer().

992  {
993 
994  double tmp = 1.;
995  if (det == static_cast<int>(HcalBarrel)) {
996  if (layer == 1) tmp = scaleHB0;
997  else if (layer == 17) tmp = scaleHB16;
998  else if (layer > 17) tmp = scaleHO;
999  } else {
1000  if (layer <= 2) tmp = scaleHE0;
1001  }
1002  return tmp;
1003 }
std::vector< std::vector< double > > tmp
Definition: MVATrainer.cc:100
double HcalTB04Analysis::timeOfFlight ( int  det,
int  layer,
double  eta 
)
private

Definition at line 1005 of file HcalTB04Analysis.cc.

References beamOffset, funct::cos(), create_public_lumi_plots::exp, HcalBarrel, LogDebug, funct::sin(), theta(), and tmp.

Referenced by fillBuffer().

1005  {
1006 
1007  double theta = 2.0*atan(exp(-eta));
1008  double dist = beamOffset;
1009  if (det == static_cast<int>(HcalBarrel)) {
1010  const double rLay[19] = {
1011  1836.0, 1902.0, 1962.0, 2022.0, 2082.0, 2142.0, 2202.0, 2262.0, 2322.0,
1012  2382.0, 2448.0, 2514.0, 2580.0, 2646.0, 2712.0, 2776.0, 2862.5, 3847.0,
1013  4052.0};
1014  if (layer>0 && layer<=19) dist += rLay[layer-1]*mm/sin(theta);
1015  } else {
1016  const double zLay[19] = {
1017  4034.0, 4032.0, 4123.0, 4210.0, 4297.0, 4384.0, 4471.0, 4558.0, 4645.0,
1018  4732.0, 4819.0, 4906.0, 4993.0, 5080.0, 5167.0, 5254.0, 5341.0, 5428.0,
1019  5515.0};
1020  if (layer>0 && layer<=19) dist += zLay[layer-1]*mm/cos(theta);
1021  }
1022 
1023  double tmp = dist/c_light/ns;
1024 #ifdef ddebug
1025  LogDebug("HcalTBSim") << "HcalTB04Analysis::timeOfFlight " << tmp
1026  << " for det/lay " << det << " " << layer
1027  << " eta/theta " << eta << " " << theta/deg
1028  << " dist " << dist;
1029 #endif
1030  return tmp;
1031 }
#define LogDebug(id)
Sin< T >::type sin(const T &t)
Definition: Sin.h:22
Geom::Theta< T > theta() const
Cos< T >::type cos(const T &t)
Definition: Cos.h:22
std::vector< std::vector< double > > tmp
Definition: MVATrainer.cc:100
int HcalTB04Analysis::unitID ( uint32_t  id)
private

Definition at line 980 of file HcalTB04Analysis.cc.

References watchdog::group, HcalTestNumbering::unpackHcalIndex(), and z.

Referenced by fillBuffer(), and init().

980  {
981 
982  int det, z, group, ieta, iphi, lay;
983  HcalTestNumbering::unpackHcalIndex(id,det,z,group,ieta,iphi,lay);
984  group = (det&15)<<20;
985  group += ((lay-1)&31)<<15;
986  group += (z&1)<<14;
987  group += (ieta&127)<<7;
988  group += (iphi&127);
989  return group;
990 }
static void unpackHcalIndex(const uint32_t &idx, int &det, int &z, int &depth, int &eta, int &phi, int &lay)
tuple group
Definition: watchdog.py:82
void HcalTB04Analysis::update ( const BeginOfRun )
privatevirtual

This routine will be called when the appropriate signal arrives.

Implements Observer< const BeginOfRun * >.

Definition at line 192 of file HcalTB04Analysis.cc.

References hcalOnly, names, sd, ECalSD::setNumberingScheme(), HCalSD::setNumberingScheme(), and AlCaHLTBitMon_QueryRunRegistry::string.

Referenced by progressbar.ProgressBar::__next__(), MatrixUtil.Matrix::__setitem__(), MatrixUtil.Steps::__setitem__(), Vispa.Gui.VispaWidget.VispaWidget::autosize(), Vispa.Views.LineDecayView.LineDecayContainer::createObject(), Vispa.Views.LineDecayView.LineDecayContainer::deselectAllObjects(), Vispa.Gui.VispaWidgetOwner.VispaWidgetOwner::deselectAllWidgets(), Vispa.Gui.VispaWidget.VispaWidget::enableAutosizing(), progressbar.ProgressBar::finish(), Vispa.Gui.MenuWidget.MenuWidget::leaveEvent(), Vispa.Gui.VispaWidgetOwner.VispaWidgetOwner::mouseMoveEvent(), Vispa.Gui.MenuWidget.MenuWidget::mouseMoveEvent(), Vispa.Views.LineDecayView.LineDecayContainer::mouseMoveEvent(), Vispa.Gui.VispaWidgetOwner.VispaWidgetOwner::mouseReleaseEvent(), Vispa.Views.LineDecayView.LineDecayContainer::objectMoved(), MatrixUtil.Steps::overwrite(), Vispa.Views.LineDecayView.LineDecayContainer::removeObject(), Vispa.Gui.ConnectableWidget.ConnectableWidget::removePorts(), Vispa.Gui.FindDialog.FindDialog::reset(), Vispa.Gui.PortConnection.PointToPointConnection::select(), Vispa.Gui.VispaWidget.VispaWidget::select(), Vispa.Views.LineDecayView.LineDecayContainer::select(), Vispa.Gui.VispaWidget.VispaWidget::setText(), Vispa.Gui.VispaWidget.VispaWidget::setTitle(), Vispa.Gui.ZoomableWidget.ZoomableWidget::setZoom(), Vispa.Views.LineDecayView.LineDecayContainer::setZoom(), and Vispa.Gui.PortConnection.PointToPointConnection::updateConnection().

192  {
193 
194  int irun = (*run)()->GetRunID();
195  edm::LogInfo("HcalTBSim") <<" =====> Begin of Run = " << irun;
196 
197  G4SDManager* sd = G4SDManager::GetSDMpointerIfExist();
198  if (sd != 0) {
199  std::string sdname = names[0];
200  G4VSensitiveDetector* aSD = sd->FindSensitiveDetector(sdname);
201  if (aSD==0) {
202  edm::LogWarning("HcalTBSim") << "HcalTB04Analysis::beginOfRun: No SD"
203  << " with name " << sdname << " in this "
204  << "Setup";
205  } else {
206  HCalSD* theCaloSD = dynamic_cast<HCalSD*>(aSD);
207  edm::LogInfo("HcalTBSim") << "HcalTB04Analysis::beginOfRun: Finds SD "
208  << "with name " << theCaloSD->GetName()
209  << " in this Setup";
211  theCaloSD->setNumberingScheme(org);
212  edm::LogInfo("HcalTBSim") << "HcalTB04Analysis::beginOfRun: set a "
213  << "new numbering scheme";
214  }
215  if (!hcalOnly) {
216  sdname = names[1];
217  aSD = sd->FindSensitiveDetector(sdname);
218  if (aSD==0) {
219  edm::LogWarning("HcalTBSim") << "HcalTB04Analysis::beginOfRun: No SD"
220  << " with name " << sdname << " in this "
221  << "Setup";
222  } else {
223  ECalSD* theCaloSD = dynamic_cast<ECalSD*>(aSD);
224  edm::LogInfo("HcalTBSim") << "HcalTB04Analysis::beginOfRun: Finds SD "
225  << "with name " << theCaloSD->GetName()
226  << " in this Setup";
228  theCaloSD->setNumberingScheme(org);
229  edm::LogInfo("HcalTBSim") << "HcalTB04Analysis::beginOfRun: set a "
230  << "new numbering scheme";
231  }
232  }
233  } else {
234  edm::LogWarning("HcalTBSim") << "HcalTB04Analysis::beginOfRun: Could "
235  << "not get SD Manager!";
236  }
237 
238 }
void setNumberingScheme(HcalNumberingScheme *)
Definition: HCalSD.cc:571
Definition: HCalSD.h:35
Definition: ECalSD.h:26
double sd
void setNumberingScheme(EcalNumberingScheme *)
Definition: ECalSD.cc:315
std::vector< std::string > names
void HcalTB04Analysis::update ( const BeginOfEvent )
privatevirtual

This routine will be called when the appropriate signal arrives.

Implements Observer< const BeginOfEvent * >.

Definition at line 240 of file HcalTB04Analysis.cc.

References clear(), and evNum.

Referenced by progressbar.ProgressBar::__next__(), MatrixUtil.Matrix::__setitem__(), MatrixUtil.Steps::__setitem__(), Vispa.Gui.VispaWidget.VispaWidget::autosize(), Vispa.Views.LineDecayView.LineDecayContainer::createObject(), Vispa.Views.LineDecayView.LineDecayContainer::deselectAllObjects(), Vispa.Gui.VispaWidgetOwner.VispaWidgetOwner::deselectAllWidgets(), Vispa.Gui.VispaWidget.VispaWidget::enableAutosizing(), progressbar.ProgressBar::finish(), Vispa.Gui.MenuWidget.MenuWidget::leaveEvent(), Vispa.Gui.VispaWidgetOwner.VispaWidgetOwner::mouseMoveEvent(), Vispa.Gui.MenuWidget.MenuWidget::mouseMoveEvent(), Vispa.Views.LineDecayView.LineDecayContainer::mouseMoveEvent(), Vispa.Gui.VispaWidgetOwner.VispaWidgetOwner::mouseReleaseEvent(), Vispa.Views.LineDecayView.LineDecayContainer::objectMoved(), MatrixUtil.Steps::overwrite(), Vispa.Views.LineDecayView.LineDecayContainer::removeObject(), Vispa.Gui.ConnectableWidget.ConnectableWidget::removePorts(), Vispa.Gui.FindDialog.FindDialog::reset(), Vispa.Gui.PortConnection.PointToPointConnection::select(), Vispa.Gui.VispaWidget.VispaWidget::select(), Vispa.Views.LineDecayView.LineDecayContainer::select(), Vispa.Gui.VispaWidget.VispaWidget::setText(), Vispa.Gui.VispaWidget.VispaWidget::setTitle(), Vispa.Gui.ZoomableWidget.ZoomableWidget::setZoom(), Vispa.Views.LineDecayView.LineDecayContainer::setZoom(), and Vispa.Gui.PortConnection.PointToPointConnection::updateConnection().

240  {
241 
242  evNum = (*evt) ()->GetEventID ();
243  clear();
244  edm::LogInfo("HcalTBSim") << "HcalTB04Analysis: =====> Begin of event = "
245  << evNum;
246 }
void HcalTB04Analysis::update ( const G4Step *  )
privatevirtual

This routine will be called when the appropriate signal arrives.

Implements Observer< const G4Step * >.

Definition at line 248 of file HcalTB04Analysis.cc.

References LogDebug, NULL, sysUtil::pid, position, pvFound, pvMomentum, pvPosition, pvType, pvUVW, secEkin, secMomentum, secPartID, secTrackID, and shortLivedSecondaries.

Referenced by progressbar.ProgressBar::__next__(), MatrixUtil.Matrix::__setitem__(), MatrixUtil.Steps::__setitem__(), Vispa.Gui.VispaWidget.VispaWidget::autosize(), Vispa.Views.LineDecayView.LineDecayContainer::createObject(), Vispa.Views.LineDecayView.LineDecayContainer::deselectAllObjects(), Vispa.Gui.VispaWidgetOwner.VispaWidgetOwner::deselectAllWidgets(), Vispa.Gui.VispaWidget.VispaWidget::enableAutosizing(), progressbar.ProgressBar::finish(), Vispa.Gui.MenuWidget.MenuWidget::leaveEvent(), Vispa.Gui.VispaWidgetOwner.VispaWidgetOwner::mouseMoveEvent(), Vispa.Gui.MenuWidget.MenuWidget::mouseMoveEvent(), Vispa.Views.LineDecayView.LineDecayContainer::mouseMoveEvent(), Vispa.Gui.VispaWidgetOwner.VispaWidgetOwner::mouseReleaseEvent(), Vispa.Views.LineDecayView.LineDecayContainer::objectMoved(), MatrixUtil.Steps::overwrite(), Vispa.Views.LineDecayView.LineDecayContainer::removeObject(), Vispa.Gui.ConnectableWidget.ConnectableWidget::removePorts(), Vispa.Gui.FindDialog.FindDialog::reset(), Vispa.Gui.PortConnection.PointToPointConnection::select(), Vispa.Gui.VispaWidget.VispaWidget::select(), Vispa.Views.LineDecayView.LineDecayContainer::select(), Vispa.Gui.VispaWidget.VispaWidget::setText(), Vispa.Gui.VispaWidget.VispaWidget::setTitle(), Vispa.Gui.ZoomableWidget.ZoomableWidget::setZoom(), Vispa.Views.LineDecayView.LineDecayContainer::setZoom(), and Vispa.Gui.PortConnection.PointToPointConnection::updateConnection().

248  {
249 
250  if (aStep != NULL) {
251  //Get Step properties
252  G4ThreeVector thePreStepPoint = aStep->GetPreStepPoint()->GetPosition();
253  G4ThreeVector thePostStepPoint;
254 
255  // Get Tracks properties
256  G4Track* aTrack = aStep->GetTrack();
257  int trackID = aTrack->GetTrackID();
258  int parentID = aTrack->GetParentID();
259  G4ThreeVector position = aTrack->GetPosition();
260  G4ThreeVector momentum = aTrack->GetMomentum();
261  G4String partType = aTrack->GetDefinition()->GetParticleType();
262  G4String partSubType = aTrack->GetDefinition()->GetParticleSubType();
263  int partPDGEncoding = aTrack->GetDefinition()->GetPDGEncoding();
264 #ifdef ddebug
265  bool isPDGStable = aTrack->GetDefinition()->GetPDGStable();
266 #endif
267  double pDGlifetime = aTrack->GetDefinition()->GetPDGLifeTime();
268  double gammaFactor = aStep->GetPreStepPoint()->GetGamma();
269 
270  if (!pvFound) { //search for v1
271  double stepDeltaEnergy = aStep->GetDeltaEnergy ();
272  double kinEnergy = aTrack->GetKineticEnergy ();
273 
274  // look for DeltaE > 10% kinEnergy of particle, or particle death - Ek=0
275  if (trackID == 1 && parentID == 0 &&
276  ((kinEnergy == 0.) || (fabs (stepDeltaEnergy / kinEnergy) > 0.1))) {
277  pvType = -1;
278  if (kinEnergy == 0.) {
279  pvType = 0;
280  } else {
281  if (fabs (stepDeltaEnergy / kinEnergy) > 0.1) pvType = 1;
282  }
283  pvFound = true;
285  pvMomentum = momentum;
286  // Rotated coord.system:
287  pvUVW = (*beamline_RM)*(pvPosition);
288 
289  //Volume name requires some checks:
290  G4String thePostPVname = "NoName";
291  G4StepPoint * thePostPoint = aStep->GetPostStepPoint ();
292  if (thePostPoint) {
293  thePostStepPoint = thePostPoint->GetPosition();
294  G4VPhysicalVolume * thePostPV = thePostPoint->GetPhysicalVolume ();
295  if (thePostPV) thePostPVname = thePostPV->GetName ();
296  }
297 #ifdef ddebug
298  LogDebug("HcalTBSim") << "HcalTB04Analysis:: V1 found at: "
299  << thePostStepPoint << " G4VPhysicalVolume: "
300  << thePostPVname;
301 #endif
302  LogDebug("HcalTBSim") << "HcalTB04Analysis::fill_v1Pos: Primary Track "
303  << "momentum: " << pvMomentum << " psoition "
304  << pvPosition << " u/v/w " << pvUVW;
305  }
306  } else {
307  // watch for secondaries originating @v1, including the surviving primary
308  if ((trackID != 1 && parentID == 1 &&
309  (aTrack->GetCurrentStepNumber () == 1) &&
310  (thePreStepPoint == pvPosition)) ||
311  (trackID == 1 && thePreStepPoint == pvPosition)) {
312 #ifdef ddebug
313  LogDebug("HcalTBSim") << "HcalTB04Analysis::A secondary... PDG:"
314  << partPDGEncoding << " TrackID:" << trackID
315  << " ParentID:" << parentID << " stable: "
316  << isPDGStable << " Tau: " << pDGlifetime
317  << " cTauGamma="
318  << c_light*pDGlifetime*gammaFactor*1000.
319  << "um" << " GammaFactor: " << gammaFactor;
320 #endif
321  secTrackID.push_back(trackID);
322  secPartID.push_back(partPDGEncoding);
323  secMomentum.push_back(momentum);
324  secEkin.push_back(aTrack->GetKineticEnergy());
325 
326  // Check for short-lived secondaries: cTauGamma<100um
327  double ctaugamma_um = c_light * pDGlifetime * gammaFactor * 1000.;
328  if ((ctaugamma_um>0.) && (ctaugamma_um<100.)) {//short-lived secondary
329  shortLivedSecondaries.push_back(trackID);
330  } else {//normal secondary - enter into the V1-calorimetric tree
331  // histos->fill_v1cSec (aTrack);
332  }
333  }
334  // Also watch for tertiary particles coming from
335  // short-lived secondaries from V1
336  if (aTrack->GetCurrentStepNumber() == 1) {
337  if (shortLivedSecondaries.size() > 0) {
338  int pid = parentID;
339  std::vector<int>::iterator pos1= shortLivedSecondaries.begin();
340  std::vector<int>::iterator pos2 = shortLivedSecondaries.end();
341  std::vector<int>::iterator pos;
342  for (pos = pos1; pos != pos2; pos++) {
343  if (*pos == pid) {//ParentID is on the list of short-lived
344  // secondary
345 #ifdef ddebug
346  LogDebug("HcalTBSim") << "HcalTB04Analysis:: A tertiary... PDG:"
347  << partPDGEncoding << " TrackID:" <<trackID
348  << " ParentID:" << parentID << " stable: "
349  << isPDGStable << " Tau: " << pDGlifetime
350  << " cTauGamma="
351  << c_light*pDGlifetime*gammaFactor*1000.
352  << "um GammaFactor: " << gammaFactor;
353 #endif
354  }
355  }
356  }
357  }
358  }
359  }
360 }
#define LogDebug(id)
std::vector< double > secEkin
std::vector< int > shortLivedSecondaries
std::vector< int > secTrackID
#define NULL
Definition: scimark2.h:8
std::vector< int > secPartID
G4ThreeVector pvUVW
tuple pid
Definition: sysUtil.py:22
std::vector< G4ThreeVector > secMomentum
static int position[264][3]
Definition: ReadPGInfo.cc:509
G4ThreeVector pvMomentum
G4ThreeVector pvPosition
void HcalTB04Analysis::update ( const EndOfEvent )
privatevirtual

This routine will be called when the appropriate signal arrives.

Implements Observer< const EndOfEvent * >.

Definition at line 362 of file HcalTB04Analysis.cc.

References count, ecalHitCache, fillBuffer(), finalAnalysis(), hcalHitCache, hcalOnly, LogDebug, qieAnalysis(), and xtalAnalysis().

Referenced by progressbar.ProgressBar::__next__(), MatrixUtil.Matrix::__setitem__(), MatrixUtil.Steps::__setitem__(), Vispa.Gui.VispaWidget.VispaWidget::autosize(), Vispa.Views.LineDecayView.LineDecayContainer::createObject(), Vispa.Views.LineDecayView.LineDecayContainer::deselectAllObjects(), Vispa.Gui.VispaWidgetOwner.VispaWidgetOwner::deselectAllWidgets(), Vispa.Gui.VispaWidget.VispaWidget::enableAutosizing(), progressbar.ProgressBar::finish(), Vispa.Gui.MenuWidget.MenuWidget::leaveEvent(), Vispa.Gui.VispaWidgetOwner.VispaWidgetOwner::mouseMoveEvent(), Vispa.Gui.MenuWidget.MenuWidget::mouseMoveEvent(), Vispa.Views.LineDecayView.LineDecayContainer::mouseMoveEvent(), Vispa.Gui.VispaWidgetOwner.VispaWidgetOwner::mouseReleaseEvent(), Vispa.Views.LineDecayView.LineDecayContainer::objectMoved(), MatrixUtil.Steps::overwrite(), Vispa.Views.LineDecayView.LineDecayContainer::removeObject(), Vispa.Gui.ConnectableWidget.ConnectableWidget::removePorts(), Vispa.Gui.FindDialog.FindDialog::reset(), Vispa.Gui.PortConnection.PointToPointConnection::select(), Vispa.Gui.VispaWidget.VispaWidget::select(), Vispa.Views.LineDecayView.LineDecayContainer::select(), Vispa.Gui.VispaWidget.VispaWidget::setText(), Vispa.Gui.VispaWidget.VispaWidget::setTitle(), Vispa.Gui.ZoomableWidget.ZoomableWidget::setZoom(), Vispa.Views.LineDecayView.LineDecayContainer::setZoom(), and Vispa.Gui.PortConnection.PointToPointConnection::updateConnection().

362  {
363 
364  count++;
365 
366  //fill the buffer
367  LogDebug("HcalTBSim") << "HcalTB04Analysis::Fill event "
368  << (*evt)()->GetEventID();
369  fillBuffer (evt);
370 
371  //QIE analysis
372  LogDebug("HcalTBSim") << "HcalTB04Analysis::Do QIE analysis with "
373  << hcalHitCache.size() << " hits";
374  CLHEP::HepRandomEngine* engine = G4Random::getTheEngine();
375  qieAnalysis(engine);
376 
377  //Energy in Crystal Matrix
378  if (!hcalOnly) {
379  LogDebug("HcalTBSim") << "HcalTB04Analysis::Do Xtal analysis with "
380  << ecalHitCache.size() << " hits";
381  xtalAnalysis(engine);
382  }
383 
384  //Final Analysis
385  LogDebug("HcalTBSim") << "HcalTB04Analysis::Final analysis";
386  finalAnalysis();
387 
388  int iEvt = (*evt)()->GetEventID();
389  if (iEvt < 10)
390  edm::LogInfo("HcalTBSim") << "HcalTB04Analysis:: Event " << iEvt;
391  else if ((iEvt < 100) && (iEvt%10 == 0))
392  edm::LogInfo("HcalTBSim") << "HcalTB04Analysis:: Event " << iEvt;
393  else if ((iEvt < 1000) && (iEvt%100 == 0))
394  edm::LogInfo("HcalTBSim") << "HcalTB04Analysis:: Event " << iEvt;
395  else if ((iEvt < 10000) && (iEvt%1000 == 0))
396  edm::LogInfo("HcalTBSim") << "HcalTB04Analysis:: Event " << iEvt;
397 }
#define LogDebug(id)
void fillBuffer(const EndOfEvent *evt)
std::vector< CaloHit > hcalHitCache
void xtalAnalysis(CLHEP::HepRandomEngine *)
std::vector< CaloHit > ecalHitCache
void qieAnalysis(CLHEP::HepRandomEngine *)
void HcalTB04Analysis::xtalAnalysis ( CLHEP::HepRandomEngine *  engine)
private

Definition at line 716 of file HcalTB04Analysis.cc.

References TauDecayModes::dec, ecalHitCache, ecalNoise, enois, Vispa.Plugins.EdmBrowser.EdmDataAccessor::eq(), esime, idEcal, relval_steps::k2, LogDebug, and nCrystal.

Referenced by update().

716  {
717 
718  CLHEP::RandGaussQ randGauss(*engine);
719 
720  // Crystal Data
721  std::vector<int> iok(nCrystal,0);
722  LogDebug("HcalTBSim") << "HcalTB04Analysis::xtalAnalysis: Size " <<iok.size()
723  << " " << idEcal.size() << " " << esime.size() << " "
724  << enois.size();
725  for (unsigned int k1 = 0; k1 < ecalHitCache.size(); k1++) {
726  uint32_t id = ecalHitCache[k1].id();
727  int nhit = 0;
728  double esim = ecalHitCache[k1].e();
729  for (unsigned int k2 = k1+1; k2 < ecalHitCache.size(); k2++) {
730  if (ecalHitCache[k2].id() == id) {
731  nhit++;
732  esim += ecalHitCache[k2].e();
733  }
734  }
735  k1 += nhit;
736  nhit++;
737  double eq = esim + randGauss.fire(0., ecalNoise);
738 #ifdef ddebug
739  LogDebug("HcalTBSim") << "HcalTB04Analysis:: ID 0x" << std::hex << id
740  << std::dec << " registers " << esim << " energy "
741  << "from " << nhit << " hits starting with hit # "
742  << k1 << " energy with noise " << eq;
743 #endif
744  for (int k2 = 0; k2 < nCrystal; k2++) {
745  if (id == idEcal[k2]) {
746  iok[k2] = 1;
747  esime[k2] = esim;
748  enois[k2] = eq;
749  }
750  }
751  }
752 
753  // Crystals with no hit
754  for (int k2 = 0; k2 < nCrystal; k2++) {
755  if (iok[k2] == 0) {
756  esime[k2] = 0;
757  enois[k2] = randGauss.fire(0., ecalNoise);
758 #ifdef ddebug
759  LogDebug("HcalTBSim") << "HcalTB04Analysis:: ID 0x" << std::hex
760  << idEcal[k2] << std::dec << " registers "
761  << esime[k2] << " energy from hits and energy from"
762  << " noise " << enois[k2];
763 #endif
764  }
765  }
766 }
#define LogDebug(id)
std::vector< uint32_t > idEcal
std::vector< double > esime
std::vector< CaloHit > ecalHitCache
std::vector< double > enois

Member Data Documentation

G4RotationMatrix* HcalTB04Analysis::beamline_RM
private

Definition at line 101 of file HcalTB04Analysis.h.

Referenced by HcalTB04Analysis().

double HcalTB04Analysis::beamOffset
private

Definition at line 97 of file HcalTB04Analysis.h.

Referenced by HcalTB04Analysis(), and timeOfFlight().

int HcalTB04Analysis::count
private

Definition at line 104 of file HcalTB04Analysis.h.

Referenced by init(), update(), and ~HcalTB04Analysis().

std::vector<CaloHit> HcalTB04Analysis::ecalHitCache
private

Definition at line 112 of file HcalTB04Analysis.h.

Referenced by clear(), fillBuffer(), fillEvent(), update(), and xtalAnalysis().

double HcalTB04Analysis::ecalNoise
private

Definition at line 97 of file HcalTB04Analysis.h.

Referenced by HcalTB04Analysis(), and xtalAnalysis().

double HcalTB04Analysis::eecalq
private

Definition at line 116 of file HcalTB04Analysis.h.

Referenced by fillEvent(), and finalAnalysis().

double HcalTB04Analysis::eecals
private

Definition at line 116 of file HcalTB04Analysis.h.

Referenced by fillEvent(), and finalAnalysis().

double HcalTB04Analysis::ehcalq
private

Definition at line 116 of file HcalTB04Analysis.h.

Referenced by fillEvent(), and finalAnalysis().

double HcalTB04Analysis::ehcals
private

Definition at line 116 of file HcalTB04Analysis.h.

Referenced by fillEvent(), and finalAnalysis().

std::vector<double> HcalTB04Analysis::enois
private

Definition at line 114 of file HcalTB04Analysis.h.

Referenced by clear(), fillEvent(), finalAnalysis(), and xtalAnalysis().

std::vector<double> HcalTB04Analysis::eqeta
private

Definition at line 115 of file HcalTB04Analysis.h.

Referenced by fillEvent(), finalAnalysis(), and init().

std::vector<double> HcalTB04Analysis::eqie
private

Definition at line 114 of file HcalTB04Analysis.h.

Referenced by clear(), fillEvent(), finalAnalysis(), and qieAnalysis().

std::vector<double> HcalTB04Analysis::eqlay
private

Definition at line 115 of file HcalTB04Analysis.h.

Referenced by fillEvent(), finalAnalysis(), and init().

std::vector<double> HcalTB04Analysis::eqphi
private

Definition at line 115 of file HcalTB04Analysis.h.

Referenced by fillEvent(), finalAnalysis(), and init().

std::vector<double> HcalTB04Analysis::eseta
private

Definition at line 115 of file HcalTB04Analysis.h.

Referenced by fillEvent(), finalAnalysis(), and init().

std::vector<double> HcalTB04Analysis::esime
private

Definition at line 114 of file HcalTB04Analysis.h.

Referenced by clear(), fillEvent(), finalAnalysis(), and xtalAnalysis().

std::vector<double> HcalTB04Analysis::esimh
private

Definition at line 114 of file HcalTB04Analysis.h.

Referenced by clear(), fillEvent(), finalAnalysis(), and qieAnalysis().

std::vector<double> HcalTB04Analysis::eslay
private

Definition at line 115 of file HcalTB04Analysis.h.

Referenced by fillEvent(), finalAnalysis(), and init().

std::vector<double> HcalTB04Analysis::esphi
private

Definition at line 115 of file HcalTB04Analysis.h.

Referenced by fillEvent(), finalAnalysis(), and init().

double HcalTB04Analysis::etaInit
private

Definition at line 111 of file HcalTB04Analysis.h.

Referenced by clear(), fillBuffer(), fillEvent(), and finalAnalysis().

double HcalTB04Analysis::etotq
private

Definition at line 116 of file HcalTB04Analysis.h.

Referenced by fillEvent(), and finalAnalysis().

double HcalTB04Analysis::etots
private

Definition at line 116 of file HcalTB04Analysis.h.

Referenced by fillEvent(), and finalAnalysis().

int HcalTB04Analysis::evNum
private

Definition at line 119 of file HcalTB04Analysis.h.

Referenced by fillBuffer(), fillEvent(), init(), and update().

std::vector<CaloHit> HcalTB04Analysis::hcalHitCache
private

Definition at line 113 of file HcalTB04Analysis.h.

Referenced by clear(), fillBuffer(), fillEvent(), qieAnalysis(), and update().

std::vector<CaloHit> HcalTB04Analysis::hcalHitLayer
private

Definition at line 113 of file HcalTB04Analysis.h.

Referenced by clear(), and fillBuffer().

bool HcalTB04Analysis::hcalOnly
private

Definition at line 95 of file HcalTB04Analysis.h.

Referenced by HcalTB04Analysis(), init(), and update().

HcalTB04Histo* HcalTB04Analysis::histo
private

Definition at line 92 of file HcalTB04Analysis.h.

Referenced by finalAnalysis(), HcalTB04Analysis(), and ~HcalTB04Analysis().

int HcalTB04Analysis::iceta
private

Definition at line 98 of file HcalTB04Analysis.h.

Referenced by finalAnalysis(), and HcalTB04Analysis().

int HcalTB04Analysis::icphi
private

Definition at line 98 of file HcalTB04Analysis.h.

Referenced by finalAnalysis(), and HcalTB04Analysis().

std::vector<uint32_t> HcalTB04Analysis::idEcal
private

Definition at line 107 of file HcalTB04Analysis.h.

Referenced by init(), and xtalAnalysis().

std::vector<int> HcalTB04Analysis::idHcal
private

Definition at line 106 of file HcalTB04Analysis.h.

Referenced by fillEvent(), and init().

std::vector<uint32_t> HcalTB04Analysis::idTower
private

Definition at line 107 of file HcalTB04Analysis.h.

Referenced by finalAnalysis(), init(), and qieAnalysis().

std::vector<int> HcalTB04Analysis::idXtal
private

Definition at line 106 of file HcalTB04Analysis.h.

Referenced by fillEvent(), and init().

int HcalTB04Analysis::mode
private

Definition at line 96 of file HcalTB04Analysis.h.

Referenced by fillBuffer(), HcalTB04Analysis(), and init().

HcalQie* HcalTB04Analysis::myQie
private

Definition at line 91 of file HcalTB04Analysis.h.

Referenced by HcalTB04Analysis(), qieAnalysis(), and ~HcalTB04Analysis().

std::vector<std::string> HcalTB04Analysis::names
private

Definition at line 100 of file HcalTB04Analysis.h.

Referenced by fillBuffer(), HcalTB04Analysis(), and update().

int HcalTB04Analysis::nCrystal
private

Definition at line 105 of file HcalTB04Analysis.h.

Referenced by clear(), finalAnalysis(), init(), and xtalAnalysis().

int HcalTB04Analysis::nPrimary
private

Definition at line 110 of file HcalTB04Analysis.h.

Referenced by clear(), fillBuffer(), and fillEvent().

int HcalTB04Analysis::nTower
private

Definition at line 105 of file HcalTB04Analysis.h.

Referenced by clear(), finalAnalysis(), init(), and qieAnalysis().

int HcalTB04Analysis::particleType
private

Definition at line 110 of file HcalTB04Analysis.h.

Referenced by clear(), fillBuffer(), and fillEvent().

double HcalTB04Analysis::phiInit
private

Definition at line 111 of file HcalTB04Analysis.h.

Referenced by clear(), fillBuffer(), fillEvent(), and finalAnalysis().

double HcalTB04Analysis::pInit
private

Definition at line 111 of file HcalTB04Analysis.h.

Referenced by clear(), fillBuffer(), fillEvent(), and finalAnalysis().

bool HcalTB04Analysis::pvFound
private

Definition at line 118 of file HcalTB04Analysis.h.

Referenced by clear(), and update().

G4ThreeVector HcalTB04Analysis::pvMomentum
private

Definition at line 120 of file HcalTB04Analysis.h.

Referenced by clear(), fillEvent(), and update().

G4ThreeVector HcalTB04Analysis::pvPosition
private

Definition at line 120 of file HcalTB04Analysis.h.

Referenced by clear(), fillEvent(), and update().

int HcalTB04Analysis::pvType
private

Definition at line 119 of file HcalTB04Analysis.h.

Referenced by clear(), fillEvent(), and update().

G4ThreeVector HcalTB04Analysis::pvUVW
private

Definition at line 120 of file HcalTB04Analysis.h.

Referenced by clear(), fillEvent(), and update().

double HcalTB04Analysis::scaleHB0
private

Definition at line 99 of file HcalTB04Analysis.h.

Referenced by HcalTB04Analysis(), and scale().

double HcalTB04Analysis::scaleHB16
private

Definition at line 99 of file HcalTB04Analysis.h.

Referenced by HcalTB04Analysis(), and scale().

double HcalTB04Analysis::scaleHE0
private

Definition at line 99 of file HcalTB04Analysis.h.

Referenced by HcalTB04Analysis(), and scale().

double HcalTB04Analysis::scaleHO
private

Definition at line 99 of file HcalTB04Analysis.h.

Referenced by HcalTB04Analysis(), and scale().

std::vector<double> HcalTB04Analysis::secEkin
private

Definition at line 123 of file HcalTB04Analysis.h.

Referenced by clear(), fillEvent(), and update().

std::vector<G4ThreeVector> HcalTB04Analysis::secMomentum
private

Definition at line 122 of file HcalTB04Analysis.h.

Referenced by clear(), fillEvent(), and update().

std::vector<int> HcalTB04Analysis::secPartID
private

Definition at line 121 of file HcalTB04Analysis.h.

Referenced by clear(), fillEvent(), and update().

std::vector<int> HcalTB04Analysis::secTrackID
private

Definition at line 121 of file HcalTB04Analysis.h.

Referenced by clear(), fillEvent(), and update().

std::vector<int> HcalTB04Analysis::shortLivedSecondaries
private

Definition at line 124 of file HcalTB04Analysis.h.

Referenced by clear(), and update().

int HcalTB04Analysis::type
private