#include <HCalSD.h>
Public Member Functions | |
virtual double | getEnergyDeposit (G4Step *) |
HCalSD (G4String, const DDCompactView &, SensitiveDetectorCatalog &, edm::ParameterSet const &, const SimTrackManager *) | |
virtual bool | ProcessHits (G4Step *, G4TouchableHistory *) |
virtual uint32_t | setDetUnitId (G4Step *step) |
void | setNumberingScheme (HcalNumberingScheme *) |
virtual | ~HCalSD () |
Protected Member Functions | |
virtual bool | filterHit (CaloG4Hit *, double) |
virtual void | initRun () |
Private Member Functions | |
std::vector< double > | getDDDArray (const std::string &, const DDsvalues_type &) |
void | getFromLibrary (G4Step *step, double weight) |
void | getFromParam (G4Step *step, double weight) |
void | getHitFibreBundle (G4Step *step, bool type) |
void | getHitPMT (G4Step *step) |
std::vector< G4String > | getNames (DDFilteredView &) |
void | hitForFibre (G4Step *step, double weight) |
bool | isItConicalBundle (G4LogicalVolume *) |
bool | isItFibre (G4LogicalVolume *) |
bool | isItFibre (G4String) |
bool | isItHF (G4Step *) |
bool | isItHF (G4String) |
bool | isItinFidVolume (G4ThreeVector &) |
bool | isItPMT (G4LogicalVolume *) |
bool | isItScintillator (G4Material *) |
bool | isItStraightBundle (G4LogicalVolume *) |
double | layerWeight (int, G4ThreeVector, int, int) |
void | plotHF (G4ThreeVector &pos, bool emType) |
void | plotProfile (G4Step *step, G4ThreeVector pos, double edep, double time, int id) |
void | readWeightFromFile (std::string) |
uint32_t | setDetUnitId (int, G4ThreeVector, int, int) |
int | setTrackID (G4Step *step) |
Private Attributes | |
bool | applyFidCut |
double | betaThr |
double | birk1 |
double | birk2 |
double | birk3 |
double | deliveredLumi |
TH1F * | dist_ [9] |
double | eminHitHB |
double | eminHitHE |
double | eminHitHF |
double | eminHitHO |
std::vector< G4LogicalVolume * > | fibre1LV |
std::vector< G4LogicalVolume * > | fibre2LV |
std::vector< G4LogicalVolume * > | fibreLV |
std::vector< G4String > | fibreNames |
std::vector< double > | gpar |
std::vector< int > | hfLevels |
std::vector< G4LogicalVolume * > | hfLV |
std::vector< G4String > | hfNames |
HFShower * | hfshower |
TH1F * | hit_ [9] |
TH1F * | hzvem |
TH1F * | hzvhad |
std::vector< double > | layer0wt |
std::map< uint32_t, double > | layerWeights |
HEDarkening * | m_HEDarkening |
HFDarkening * | m_HFDarkening |
std::vector< G4Material * > | materials |
std::vector< G4String > | matNames |
G4int | mumPDG |
G4int | mupPDG |
HcalNumberingFromDDD * | numberingFromDDD |
HcalNumberingScheme * | numberingScheme |
std::vector< G4LogicalVolume * > | pmtLV |
HFShowerFibreBundle * | showerBundle |
HFShowerLibrary * | showerLibrary |
HFShowerParam * | showerParam |
HFShowerPMT * | showerPMT |
TH1F * | time_ [9] |
bool | useBirk |
bool | useFibreBundle |
bool | useHF |
bool | useLayerWt |
bool | useParam |
bool | usePMTHit |
bool | useShowerLibrary |
HCalSD::HCalSD | ( | G4String | name, |
const DDCompactView & | cpv, | ||
SensitiveDetectorCatalog & | clg, | ||
edm::ParameterSet const & | p, | ||
const SimTrackManager * | manager | ||
) |
Definition at line 35 of file HCalSD.cc.
References DDFilteredView::addFilter(), applyFidCut, betaThr, birk1, birk2, birk3, deliveredLumi, dist_, eminHitHB, eminHitHE, eminHitHF, eminHitHO, DDSpecificsFilter::equals, fibre1LV, fibre2LV, fibreLV, fibreNames, mergeVDriftHistosByStation::file, DDFilteredView::firstChild(), g, getDDDArray(), SensitiveDetector::getNames(), edm::ParameterSet::getParameter(), edm::ParameterSet::getUntrackedParameter(), gpar, hfLevels, hfLV, hfNames, hfshower, hit_, hzvem, hzvhad, i, edm::Service< T >::isAvailable(), isItFibre(), isItHF(), CaloSD::kmaxIon, CaloSD::kmaxNeutron, CaloSD::kmaxProton, reco_calib_source_client_cfg::labels, layer0wt, testEve_cfg::level, funct::log(), LogDebug, DDFilteredView::logicalPart(), m_HEDarkening, m_HFDarkening, TFileDirectory::make(), DDLogicalPart::material(), materials, matNames, DDFilteredView::mergedSpecifics(), mumPDG, mupPDG, SensitiveDetector::name, DDName::name(), DDBase< N, C >::name(), DDFilteredView::next(), numberingFromDDD, pmtLV, readWeightFromFile(), DDSpecificsFilter::setCriteria(), setNumberingScheme(), showerBundle, showerLibrary, showerParam, showerPMT, AlCaHLTBitMon_QueryRunRegistry::string, CaloSD::suppressHeavy, groupFilesInBlocks::temp, time_, indexGen::title, useBirk, useFibreBundle, useHF, useLayerWt, useParam, usePMTHit, useShowerLibrary, and relativeConstraints::value.
: CaloSD(name, cpv, clg, p, manager, p.getParameter<edm::ParameterSet>("HCalSD").getParameter<int>("TimeSliceUnit"), p.getParameter<edm::ParameterSet>("HCalSD").getParameter<bool>("IgnoreTrackID")), numberingFromDDD(0), numberingScheme(0), showerLibrary(0), hfshower(0), showerParam(0), showerPMT(0), showerBundle(0), m_HEDarkening(0), m_HFDarkening(0) { //static SimpleConfigurable<bool> on1(false, "HCalSD:UseBirkLaw"); //static SimpleConfigurable<double> bk1(0.013, "HCalSD:BirkC1"); //static SimpleConfigurable<double> bk2(0.0568,"HCalSD:BirkC2"); //static SimpleConfigurable<double> bk3(1.75, "HCalSD:BirkC3"); // Values from NIM 80 (1970) 239-244: as implemented in Geant3 //static SimpleConfigurable<bool> on2(true,"HCalSD:UseShowerLibrary"); edm::ParameterSet m_HC = p.getParameter<edm::ParameterSet>("HCalSD"); useBirk = m_HC.getParameter<bool>("UseBirkLaw"); birk1 = m_HC.getParameter<double>("BirkC1")*(g/(MeV*cm2)); birk2 = m_HC.getParameter<double>("BirkC2"); birk3 = m_HC.getParameter<double>("BirkC3"); useShowerLibrary = m_HC.getParameter<bool>("UseShowerLibrary"); useParam = m_HC.getParameter<bool>("UseParametrize"); bool testNumber = m_HC.getParameter<bool>("TestNumberingScheme"); usePMTHit = m_HC.getParameter<bool>("UsePMTHits"); betaThr = m_HC.getParameter<double>("BetaThreshold"); eminHitHB = m_HC.getParameter<double>("EminHitHB")*MeV; eminHitHE = m_HC.getParameter<double>("EminHitHE")*MeV; eminHitHO = m_HC.getParameter<double>("EminHitHO")*MeV; eminHitHF = m_HC.getParameter<double>("EminHitHF")*MeV; useFibreBundle = m_HC.getParameter<bool>("UseFibreBundleHits"); deliveredLumi = m_HC.getParameter<double>("DelivLuminosity"); bool ageingFlagHE= m_HC.getParameter<bool>("HEDarkening"); bool ageingFlagHF= m_HC.getParameter<bool>("HFDarkening"); useHF = m_HC.getUntrackedParameter<bool>("UseHF",true); bool forTBH2 = m_HC.getUntrackedParameter<bool>("ForTBH2",false); useLayerWt = m_HC.getUntrackedParameter<bool>("UseLayerWt",false); std::string file = m_HC.getUntrackedParameter<std::string>("WtFile","None"); edm::ParameterSet m_HF = p.getParameter<edm::ParameterSet>("HFShower"); applyFidCut = m_HF.getParameter<bool>("ApplyFiducialCut"); #ifdef DebugLog LogDebug("HcalSim") << "***************************************************" << "\n" << "* *" << "\n" << "* Constructing a HCalSD with name " << name << "\n" << "* *" << "\n" << "***************************************************"; #endif edm::LogInfo("HcalSim") << "HCalSD:: Use of HF code is set to " << useHF << "\nUse of shower parametrization set to " << useParam << "\nUse of shower library is set to " << useShowerLibrary << "\nUse PMT Hit is set to " << usePMTHit << " with beta Threshold "<< betaThr << "\nUSe of FibreBundle Hit set to "<<useFibreBundle << "\n Use of Birks law is set to " << useBirk << " with three constants kB = " << birk1 << ", C1 = " << birk2 << ", C2 = " << birk3; edm::LogInfo("HcalSim") << "HCalSD:: Suppression Flag " << suppressHeavy << " protons below " << kmaxProton << " MeV," << " neutrons below " << kmaxNeutron << " MeV and" << " ions below " << kmaxIon << " MeV\n" << " Threshold for storing hits in HB: " << eminHitHB << " HE: " << eminHitHE << " HO: " << eminHitHO << " HF: " << eminHitHF << "\n" << "Delivered luminosity for Darkening " << deliveredLumi << " Flag (HE) " << ageingFlagHE << " Flag (HF) " << ageingFlagHF << "\n" << "Application of Fiducial Cut " << applyFidCut; numberingFromDDD = new HcalNumberingFromDDD(name, cpv); HcalNumberingScheme* scheme; if (testNumber || forTBH2) scheme = dynamic_cast<HcalNumberingScheme*>(new HcalTestNumberingScheme(forTBH2)); else scheme = new HcalNumberingScheme(); setNumberingScheme(scheme); const G4LogicalVolumeStore * lvs = G4LogicalVolumeStore::GetInstance(); std::vector<G4LogicalVolume *>::const_iterator lvcite; G4LogicalVolume* lv; std::string attribute, value; if (useHF) { if (useParam) { showerParam = new HFShowerParam(name, cpv, p); } else { if (useShowerLibrary) showerLibrary = new HFShowerLibrary(name, cpv, p); hfshower = new HFShower(name, cpv, p, 0); } // HF volume names attribute = "Volume"; value = "HF"; DDSpecificsFilter filter0; DDValue ddv0(attribute, value, 0); filter0.setCriteria(ddv0, DDSpecificsFilter::equals); DDFilteredView fv0(cpv); fv0.addFilter(filter0); hfNames = getNames(fv0); fv0.firstChild(); DDsvalues_type sv0(fv0.mergedSpecifics()); std::vector<double> temp = getDDDArray("Levels",sv0); edm::LogInfo("HcalSim") << "HCalSD: Names to be tested for " << attribute << " = " << value << " has " << hfNames.size() << " elements"; for (unsigned int i=0; i < hfNames.size(); ++i) { G4String namv = hfNames[i]; lv = 0; for(lvcite=lvs->begin(); lvcite!=lvs->end(); lvcite++) if((*lvcite)->GetName()==namv) { lv = (*lvcite); break; } hfLV.push_back(lv); int level = static_cast<int>(temp[i]); hfLevels.push_back(level); edm::LogInfo("HcalSim") << "HCalSD: HF[" << i << "] = " << hfNames[i] << " LV " << hfLV[i] << " at level " << hfLevels[i]; } // HF Fibre volume names value = "HFFibre"; DDSpecificsFilter filter1; DDValue ddv1(attribute,value,0); filter1.setCriteria(ddv1, DDSpecificsFilter::equals); DDFilteredView fv1(cpv); fv1.addFilter(filter1); fibreNames = getNames(fv1); edm::LogInfo("HcalSim") << "HCalSD: Names to be tested for " << attribute << " = " << value << ":"; for (unsigned int i=0; i<fibreNames.size(); ++i) { G4String namv = fibreNames[i]; lv = 0; for (lvcite = lvs->begin(); lvcite != lvs->end(); ++lvcite) { if ((*lvcite)->GetName() == namv) { lv = (*lvcite); break; } } fibreLV.push_back(lv); edm::LogInfo("HcalSim") << "HCalSD: (" << i << ") " << fibreNames[i] << " LV " << fibreLV[i]; } // HF PMT volume names value = "HFPMT"; DDSpecificsFilter filter3; DDValue ddv3(attribute,value,0); filter3.setCriteria(ddv3,DDSpecificsFilter::equals); DDFilteredView fv3(cpv); fv3.addFilter(filter3); std::vector<G4String> pmtNames = getNames(fv3); edm::LogInfo("HcalSim") << "HCalSD: Names to be tested for " << attribute << " = " << value << " have " << pmtNames.size() << " entries"; for (unsigned int i=0; i<pmtNames.size(); ++i) { G4String namv = pmtNames[i]; lv = 0; for (lvcite = lvs->begin(); lvcite != lvs->end(); ++lvcite) if ((*lvcite)->GetName() == namv) { lv = (*lvcite); break; } pmtLV.push_back(lv); edm::LogInfo("HcalSim") << "HCalSD: (" << i << ") " << pmtNames[i] << " LV " << pmtLV[i]; } if (pmtNames.size() > 0) showerPMT = new HFShowerPMT (name, cpv, p); // HF Fibre bundles value = "HFFibreBundleStraight"; DDSpecificsFilter filter4; DDValue ddv4(attribute,value,0); filter4.setCriteria(ddv4,DDSpecificsFilter::equals); DDFilteredView fv4(cpv); fv4.addFilter(filter4); std::vector<G4String> fibreNames = getNames(fv4); edm::LogInfo("HcalSim") << "HCalSD: Names to be tested for " << attribute << " = " << value << " have " << fibreNames.size() << " entries"; for (unsigned int i=0; i<fibreNames.size(); ++i) { G4String namv = fibreNames[i]; lv = 0; for (lvcite = lvs->begin(); lvcite != lvs->end(); lvcite++) if ((*lvcite)->GetName() == namv) { lv = (*lvcite); break; } fibre1LV.push_back(lv); edm::LogInfo("HcalSim") << "HCalSD: (" << i << ") " << fibreNames[i] << " LV " << fibre1LV[i]; } // Geometry parameters for HF value = "HFFibreBundleConical"; DDSpecificsFilter filter5; DDValue ddv5(attribute,value,0); filter5.setCriteria(ddv5,DDSpecificsFilter::equals); DDFilteredView fv5(cpv); fv5.addFilter(filter5); fibreNames = getNames(fv5); edm::LogInfo("HcalSim") << "HCalSD: Names to be tested for " << attribute << " = " << value << " have " << fibreNames.size() << " entries"; for (unsigned int i=0; i<fibreNames.size(); ++i) { G4String namv = fibreNames[i]; lv = 0; for (lvcite = lvs->begin(); lvcite != lvs->end(); ++lvcite) if ((*lvcite)->GetName() == namv) { lv = (*lvcite); break; } fibre2LV.push_back(lv); edm::LogInfo("HcalSim") << "HCalSD: (" << i << ") " << fibreNames[i] << " LV " << fibre2LV[i]; } if (fibre1LV.size() > 0 || fibre2LV.size() > 0) showerBundle = new HFShowerFibreBundle (name, cpv, p); attribute = "ReadOutName"; value = name; DDSpecificsFilter filter6; DDValue ddv6(attribute,value,0); filter6.setCriteria(ddv6,DDSpecificsFilter::equals); DDFilteredView fv6(cpv); fv6.addFilter(filter6); if (fv6.firstChild()) { DDsvalues_type sv(fv6.mergedSpecifics()); //Special Geometry parameters gpar = getDDDArray("gparHF",sv); edm::LogInfo("HFShower") << "HFShowerParam: " << gpar.size() << " gpar (cm)"; for (unsigned int ig=0; ig<gpar.size(); ig++) edm::LogInfo("HFShower") << "HFShowerParam: gpar[" << ig << "] = " << gpar[ig]/cm << " cm"; } else { edm::LogWarning("HFShower") << "HFShowerParam: cannot get filtered " << " view for " << attribute << " matching " << name; } } //Material list for HB/HE/HO sensitive detectors attribute = "ReadOutName"; DDSpecificsFilter filter2; DDValue ddv2(attribute,name,0); filter2.setCriteria(ddv2,DDSpecificsFilter::equals); DDFilteredView fv2(cpv); fv2.addFilter(filter2); bool dodet = fv2.firstChild(); DDsvalues_type sv(fv2.mergedSpecifics()); //Layer0 Weight layer0wt = getDDDArray("Layer0Wt",sv); edm::LogInfo("HcalSim") << "HCalSD: " << layer0wt.size() << " Layer0Wt"; for (unsigned int it=0; it<layer0wt.size(); ++it) edm::LogInfo("HcalSim") << "HCalSD: [" << it << "] " << layer0wt[it]; const G4MaterialTable * matTab = G4Material::GetMaterialTable(); std::vector<G4Material*>::const_iterator matite; while (dodet) { const DDLogicalPart & log = fv2.logicalPart(); G4String namx = log.name().name(); if (!isItHF(namx) && !isItFibre(namx)) { bool notIn = true; for (unsigned int i=0; i<matNames.size(); ++i) { if (!strcmp(matNames[i].c_str(),log.material().name().name().c_str())){ notIn = false; break; } } if (notIn) { namx = log.material().name().name(); matNames.push_back(namx); G4Material* mat; for (matite = matTab->begin(); matite != matTab->end(); ++matite) { if ((*matite)->GetName() == namx) { mat = (*matite); break; } } materials.push_back(mat); } } dodet = fv2.next(); } edm::LogInfo("HcalSim") << "HCalSD: Material names for " << attribute << " = " << name << ":"; for (unsigned int i=0; i<matNames.size(); ++i) edm::LogInfo("HcalSim") << "HCalSD: (" << i << ") " << matNames[i] << " pointer " << materials[i]; mumPDG = mupPDG = 0; if (useLayerWt) readWeightFromFile(file); for (int i=0; i<9; ++i) hit_[i] = time_[i]= dist_[i] = 0; hzvem = hzvhad = 0; if (ageingFlagHE) m_HEDarkening = new HEDarkening(); if (ageingFlagHF) m_HFDarkening = new HFDarkening(); #ifdef plotDebug edm::Service<TFileService> tfile; if ( tfile.isAvailable() ) { static std::string labels[9] = {"HB", "HE", "HO", "HF Absorber", "HF PMT", "HF Absorber Long", "HF Absorber Short", "HF PMT Long", "HF PMT Short"}; TFileDirectory hcDir = tfile->mkdir("ProfileFromHCalSD"); char name[20], title[60]; for (int i=0; i<9; ++i) { sprintf (title, "Hit energy in %s", labels[i].c_str()); sprintf (name, "HCalSDHit%d", i); hit_[i] = hcDir.make<TH1F>(name, title, 2000, 0., 2000.); sprintf (title, "Energy (MeV)"); hit_[i]->GetXaxis()->SetTitle(title); hit_[i]->GetYaxis()->SetTitle("Hits"); sprintf (title, "Time of the hit in %s", labels[i].c_str()); sprintf (name, "HCalSDTime%d", i); time_[i] = hcDir.make<TH1F>(name, title, 2000, 0., 2000.); sprintf (title, "Time (ns)"); time_[i]->GetXaxis()->SetTitle(title); time_[i]->GetYaxis()->SetTitle("Hits"); sprintf (title, "Longitudinal profile in %s", labels[i].c_str()); sprintf (name, "HCalSDDist%d", i); dist_[i] = hcDir.make<TH1F>(name, title, 2000, 0., 2000.); sprintf (title, "Distance (mm)"); dist_[i]->GetXaxis()->SetTitle(title); dist_[i]->GetYaxis()->SetTitle("Hits"); } if (useHF && (!useParam)) { hzvem = hcDir.make<TH1F>("hzvem", "Longitudinal Profile (EM Part)",330,0.0,1650.0); hzvem->GetXaxis()->SetTitle("Longitudinal Profile (EM Part)"); hzvhad = hcDir.make<TH1F>("hzvhad","Longitudinal Profile (Had Part)",330,0.0,1650.0); hzvhad->GetXaxis()->SetTitle("Longitudinal Profile (Hadronic Part)"); } } #endif }
HCalSD::~HCalSD | ( | ) | [virtual] |
Definition at line 379 of file HCalSD.cc.
References hfshower, m_HEDarkening, m_HFDarkening, numberingFromDDD, numberingScheme, showerBundle, showerLibrary, showerParam, and showerPMT.
{ if (numberingFromDDD) delete numberingFromDDD; if (numberingScheme) delete numberingScheme; if (showerLibrary) delete showerLibrary; if (hfshower) delete hfshower; if (showerParam) delete showerParam; if (showerPMT) delete showerPMT; if (showerBundle) delete showerBundle; if (m_HEDarkening) delete m_HEDarkening; if (m_HFDarkening) delete m_HFDarkening; }
bool HCalSD::filterHit | ( | CaloG4Hit * | aHit, |
double | time | ||
) | [protected, virtual] |
Reimplemented from CaloSD.
Definition at line 617 of file HCalSD.cc.
References eminHitHB, eminHitHE, eminHitHF, eminHitHO, CaloG4Hit::getEnergyDeposit(), CaloG4Hit::getUnitID(), HcalBarrel, HcalEndcap, HcalForward, HcalOuter, dtDQMClient_cfg::threshold, and CaloSD::tmaxHit.
{ double threshold=0; DetId theId(aHit->getUnitID()); switch (theId.subdetId()) { case HcalBarrel: threshold = eminHitHB; break; case HcalEndcap: threshold = eminHitHE; break; case HcalOuter: threshold = eminHitHO; break; case HcalForward: threshold = eminHitHF; break; default: break; } return ((time <= tmaxHit) && (aHit->getEnergyDeposit() > threshold)); }
std::vector< double > HCalSD::getDDDArray | ( | const std::string & | str, |
const DDsvalues_type & | sv | ||
) | [private] |
Definition at line 647 of file HCalSD.cc.
References DDfetch(), DDValue::doubles(), Exception, LogDebug, and relativeConstraints::value.
Referenced by HCalSD().
{ #ifdef DebugLog LogDebug("HcalSim") << "HCalSD:getDDDArray called for " << str; #endif DDValue value(str); if (DDfetch(&sv,value)) { #ifdef DebugLog LogDebug("HcalSim") << value; #endif const std::vector<double> & fvec = value.doubles(); int nval = fvec.size(); if (nval < 1) { edm::LogError("HcalSim") << "HCalSD : # of " << str << " bins " << nval << " < 2 ==> illegal"; throw cms::Exception("Unknown", "HCalSD") << "nval < 2 for array " << str << "\n"; } return fvec; } else { edm::LogError("HcalSim") << "HCalSD : cannot get array " << str; throw cms::Exception("Unknown", "HCalSD") << "cannot get array " << str << "\n"; } }
double HCalSD::getEnergyDeposit | ( | G4Step * | aStep | ) | [virtual] |
Reimplemented from CaloSD.
Definition at line 496 of file HCalSD.cc.
References birk1, birk2, birk3, HEDarkening::degradation(), deliveredLumi, HEDarkening::dose(), CaloSD::getAttenuation(), CaloSD::getResponseWt(), HEDarkening::int_lumi(), isItScintillator(), TrackInformation::isPrimary(), ke, CaloSD::kmaxIon, CaloSD::kmaxNeutron, CaloSD::kmaxProton, layer0wt, layerWeight(), LogDebug, m_HEDarkening, alignCSCRings::r, CaloSD::suppressHeavy, CaloSD::theTrack, useBirk, useLayerWt, and CommonMethods::weight().
{ double destep = aStep->GetTotalEnergyDeposit(); double weight = 1; G4Track* theTrack = aStep->GetTrack(); const G4VTouchable* touch = aStep->GetPreStepPoint()->GetTouchable(); int depth = (touch->GetReplicaNumber(0))%10; int det = ((touch->GetReplicaNumber(1))/1000)-3; if (depth==0 && (det==0 || det==1)) weight = layer0wt[det]; if (useLayerWt) { int lay = (touch->GetReplicaNumber(0)/10)%100 + 1; G4ThreeVector hitPoint = aStep->GetPreStepPoint()->GetPosition(); weight = layerWeight(det+3, hitPoint, depth, lay); } if (m_HEDarkening !=0 && det == 1) { int lay = (touch->GetReplicaNumber(0)/10)%100 + 1; G4ThreeVector hitPoint = aStep->GetPreStepPoint()->GetPosition(); float r = (hitPoint.perp())/CLHEP::cm; #ifdef DebugLog LogDebug("HcalSim") << "HCalSD:HE_Darkening >>> position: "<< hitPoint << " lay: " << lay << " R: " << r << " cm "; #endif float normalized_lumi = m_HEDarkening->int_lumi(deliveredLumi); float dose_acquired = m_HEDarkening->dose(lay-2,r);//NB:diff. layer count weight *= m_HEDarkening->degradation(normalized_lumi * dose_acquired); #ifdef DebugLog LogDebug("HcalSim") << "HCalSD: >>> norm_Lumi: " << normalized_lumi << " dose: " << dose_acquired << " coefficient = " << weight; #endif } if (suppressHeavy) { TrackInformation * trkInfo = (TrackInformation *)(theTrack->GetUserInformation()); if (trkInfo) { int pdg = theTrack->GetDefinition()->GetPDGEncoding(); if (!(trkInfo->isPrimary())) { // Only secondary particles double ke = theTrack->GetKineticEnergy()/MeV; if ( pdg/1000000000 == 1 && (pdg/10000)%100 > 0 && (pdg/10)%100 > 0 && ke <kmaxIon ) weight = 0; if ((pdg == 2212) && (ke < kmaxProton)) weight = 0; if ((pdg == 2112) && (ke < kmaxNeutron)) weight = 0; #ifdef DebugLog if (weight == 0) edm::LogInfo("HcalSim") << "HCalSD:Ignore Track " << theTrack->GetTrackID() << " Type " << theTrack->GetDefinition()->GetParticleName() << " Kinetic Energy " << ke << " MeV"; #endif } } } #ifdef DebugLog double weight0 = weight; #endif if (useBirk) { G4Material* mat = aStep->GetPreStepPoint()->GetMaterial(); if (isItScintillator(mat)) weight *= getAttenuation(aStep, birk1, birk2, birk3); } double wt1 = getResponseWt(theTrack); double wt2 = theTrack->GetWeight(); /* if(wt2 != 1.0) { std::cout << "HCalSD: Detector " << det+3 << " Depth " << depth << " weight= " << weight << " wt1= " << wt1 << " wt2= " << wt2 << std::endl; std::cout << theTrack->GetDefinition()->GetParticleName() << " " << theTrack->GetKineticEnergy() << " Id=" << theTrack->GetTrackID() << " IdP=" << theTrack->GetParentID(); const G4VProcess* pr = theTrack->GetCreatorProcess(); if(pr) std::cout << " from " << pr->GetProcessName(); std::cout << std::endl; } */ #ifdef DebugLog edm::LogInfo("HcalSim") << "HCalSD: Detector " << det+3 << " Depth " << depth << " weight " << weight0 << " " << weight << " " << wt1 << " " << wt2; #endif double edep = weight*wt1*destep; if(wt2 > 0.0) { edep *= wt2; } return edep; }
void HCalSD::getFromLibrary | ( | G4Step * | step, |
double | weight | ||
) | [private] |
Definition at line 763 of file HCalSD.cc.
References CaloSD::checkHit(), CaloSD::createNewHit(), CaloSD::currentHit, CaloSD::currentID, CaloSD::edepositEM, CaloSD::edepositHAD, CaloSD::emPDG, CaloSD::epPDG, CaloSD::gammaPDG, HFShowerLibrary::getHits(), GetVolume(), i, isItinFidVolume(), convertSQLiteXML::ok, plotHF(), plotProfile(), CaloSD::posGlobal, CaloSD::preStepPoint, CaloSD::previousID, CaloSD::resetForNewPrimary(), setDetUnitId(), CaloHitID::setID(), setTrackID(), showerLibrary, CaloSD::theTrack, cond::rpcobgas::time, and CaloSD::updateHit().
Referenced by ProcessHits().
{ preStepPoint = aStep->GetPreStepPoint(); theTrack = aStep->GetTrack(); int det = 5; bool ok; std::vector<HFShowerLibrary::Hit> hits = showerLibrary->getHits(aStep, ok, weight, false); double etrack = preStepPoint->GetKineticEnergy(); int primaryID = setTrackID(aStep); // Reset entry point for new primary posGlobal = preStepPoint->GetPosition(); resetForNewPrimary(posGlobal, etrack); G4int particleCode = theTrack->GetDefinition()->GetPDGEncoding(); if (particleCode==emPDG || particleCode==epPDG || particleCode==gammaPDG) { edepositEM = 1.*GeV; edepositHAD = 0.; } else { edepositEM = 0.; edepositHAD = 1.*GeV; } #ifdef DebugLog edm::LogInfo("HcalSim") << "HCalSD::getFromLibrary " <<hits.size() << " hits for " << GetName() << " of " << primaryID << " with " << theTrack->GetDefinition()->GetParticleName() << " of " << preStepPoint->GetKineticEnergy()/GeV << " GeV"; #endif for (unsigned int i=0; i<hits.size(); ++i) { G4ThreeVector hitPoint = hits[i].position; if (isItinFidVolume (hitPoint)) { int depth = hits[i].depth; double time = hits[i].time; unsigned int unitID = setDetUnitId(det, hitPoint, depth); currentID.setID(unitID, time, primaryID, 0); #ifdef plotDebug plotProfile(aStep, hitPoint, 1.0*GeV, time, depth); bool emType = false; if (particleCode==emPDG || particleCode==epPDG || particleCode==gammaPDG) emType = true; plotHF(hitPoint,emType); #endif // check if it is in the same unit and timeslice as the previous one if (currentID == previousID) { updateHit(currentHit); } else { if (!checkHit()) currentHit = createNewHit(); } } } //Now kill the current track if (ok) { theTrack->SetTrackStatus(fStopAndKill); G4TrackVector tv = *(aStep->GetSecondary()); for (unsigned int kk=0; kk<tv.size(); ++kk) if (tv[kk]->GetVolume() == preStepPoint->GetPhysicalVolume()) tv[kk]->SetTrackStatus(fStopAndKill); } }
void HCalSD::getFromParam | ( | G4Step * | step, |
double | weight | ||
) | [private] |
Definition at line 878 of file HCalSD.cc.
References CaloSD::checkHit(), CaloSD::createNewHit(), CaloSD::currentHit, CaloSD::currentID, CaloSD::edepositEM, CaloSD::edepositHAD, HFShowerParam::getHits(), i, plotProfile(), CaloSD::posGlobal, CaloSD::preStepPoint, CaloSD::previousID, setDetUnitId(), CaloHitID::setID(), setTrackID(), showerParam, cond::rpcobgas::time, and CaloSD::updateHit().
Referenced by ProcessHits().
{ std::vector<HFShowerParam::Hit> hits = showerParam->getHits(aStep, weight); int nHit = static_cast<int>(hits.size()); if (nHit > 0) { preStepPoint = aStep->GetPreStepPoint(); int primaryID = setTrackID(aStep); int det = 5; #ifdef DebugLog edm::LogInfo("HcalSim") << "HCalSD::getFromParam " << nHit << " hits for " << GetName() << " of " << primaryID << " with " << aStep->GetTrack()->GetDefinition()->GetParticleName() << " of " << preStepPoint->GetKineticEnergy()/GeV << " GeV in detector type " << det; #endif for (int i = 0; i<nHit; ++i) { G4ThreeVector hitPoint = hits[i].position; int depth = hits[i].depth; double time = hits[i].time; unsigned int unitID = setDetUnitId(det, hitPoint, depth); currentID.setID(unitID, time, primaryID, 0); edepositEM = hits[i].edep*GeV; edepositHAD = 0.; #ifdef plotDebug plotProfile(aStep, hitPoint, edepositEM, time, depth); #endif // check if it is in the same unit and timeslice as the previous one if (currentID == previousID) { updateHit(currentHit); } else { posGlobal = preStepPoint->GetPosition(); if (!checkHit()) currentHit = createNewHit(); } } } }
void HCalSD::getHitFibreBundle | ( | G4Step * | step, |
bool | type | ||
) | [private] |
Definition at line 984 of file HCalSD.cc.
References beta, CaloSD::checkHit(), CaloSD::createNewHit(), CaloSD::currentHit, CaloSD::currentID, CaloSD::edepositEM, CaloSD::edepositHAD, CaloSD::energyCut, HFShowerFibreBundle::getHits(), HFShowerFibreBundle::getRadius(), HcalNumberingScheme::getUnitID(), HcalForward, LogDebug, numberingFromDDD, numberingScheme, phi, plotProfile(), CaloSD::posGlobal, CaloSD::preStepPoint, CaloSD::previousID, CaloSD::resetForNewPrimary(), findQualityFiles::rr, CaloHitID::setID(), showerBundle, CaloSD::theTrack, cond::rpcobgas::time, tmp, HcalNumberingFromDDD::unitID(), and CaloSD::updateHit().
Referenced by ProcessHits().
{ preStepPoint = aStep->GetPreStepPoint(); theTrack = aStep->GetTrack(); double edep = showerBundle->getHits(aStep, type); if (edep >= 0) { double etrack = preStepPoint->GetKineticEnergy(); int primaryID = 0; if (etrack >= energyCut) { primaryID = theTrack->GetTrackID(); } else { primaryID = theTrack->GetParentID(); if (primaryID == 0) primaryID = theTrack->GetTrackID(); } // Reset entry point for new primary posGlobal = preStepPoint->GetPosition(); resetForNewPrimary(posGlobal, etrack); // int det = static_cast<int>(HcalForward); G4ThreeVector hitPoint = preStepPoint->GetPosition(); double rr = (hitPoint.x()*hitPoint.x() + hitPoint.y()*hitPoint.y()); double phi = (rr == 0. ? 0. :atan2(hitPoint.y(),hitPoint.x())); double etaR = showerBundle->getRadius(); int depth = 1; if (etaR < 0) { depth = 2; etaR =-etaR; } if (hitPoint.z() < 0) etaR =-etaR; #ifdef DebugLog LogDebug("HcalSim") << "HCalSD::Hit for Detector " << det << " etaR " << etaR << " phi " << phi/deg << " depth " <<depth; #endif double time = (aStep->GetPostStepPoint()->GetGlobalTime()); uint32_t unitID = 0; if (numberingFromDDD) { HcalNumberingFromDDD::HcalID tmp = numberingFromDDD->unitID(det,etaR,phi,depth,1); if (numberingScheme) unitID = numberingScheme->getUnitID(tmp); } if (type) currentID.setID(unitID, time, primaryID, 3); else currentID.setID(unitID, time, primaryID, 2); edepositHAD = aStep->GetTotalEnergyDeposit(); edepositEM =-edepositHAD + (edep*GeV); #ifdef plotDebug plotProfile(aStep, hitPoint, edep*GeV, time, depth); #endif #ifdef DebugLog double beta = preStepPoint->GetBeta(); LogDebug("HcalSim") << "HCalSD::getHitFibreBundle 1 hit for " << GetName() << " of " << primaryID << " with " << theTrack->GetDefinition()->GetParticleName() << " of " << preStepPoint->GetKineticEnergy()/GeV << " GeV with velocity " << beta << " UnitID " << std::hex << unitID << std::dec; #endif // check if it is in the same unit and timeslice as the previous one if (currentID == previousID) updateHit(currentHit); else if (!checkHit()) currentHit = createNewHit(); } // non-zero energy deposit }
void HCalSD::getHitPMT | ( | G4Step * | step | ) | [private] |
Definition at line 917 of file HCalSD.cc.
References beta, CaloSD::checkHit(), CaloSD::createNewHit(), CaloSD::currentHit, CaloSD::currentID, CaloSD::edepositEM, CaloSD::edepositHAD, CaloSD::energyCut, HFShowerPMT::getHits(), HFShowerPMT::getRadius(), HcalNumberingScheme::getUnitID(), HcalForward, LogDebug, numberingFromDDD, numberingScheme, phi, plotProfile(), CaloSD::posGlobal, CaloSD::preStepPoint, CaloSD::previousID, CaloSD::resetForNewPrimary(), findQualityFiles::rr, CaloHitID::setID(), showerPMT, CaloSD::theTrack, cond::rpcobgas::time, tmp, HcalNumberingFromDDD::unitID(), and CaloSD::updateHit().
Referenced by ProcessHits().
{ preStepPoint = aStep->GetPreStepPoint(); theTrack = aStep->GetTrack(); double edep = showerPMT->getHits(aStep); if (edep >= 0) { double etrack = preStepPoint->GetKineticEnergy(); int primaryID = 0; if (etrack >= energyCut) { primaryID = theTrack->GetTrackID(); } else { primaryID = theTrack->GetParentID(); if (primaryID == 0) primaryID = theTrack->GetTrackID(); } // Reset entry point for new primary posGlobal = preStepPoint->GetPosition(); resetForNewPrimary(posGlobal, etrack); // int det = static_cast<int>(HcalForward); G4ThreeVector hitPoint = preStepPoint->GetPosition(); double rr = (hitPoint.x()*hitPoint.x() + hitPoint.y()*hitPoint.y()); double phi = (rr == 0. ? 0. :atan2(hitPoint.y(),hitPoint.x())); double etaR = showerPMT->getRadius(); int depth = 1; if (etaR < 0) { depth = 2; etaR =-etaR; } if (hitPoint.z() < 0) etaR =-etaR; #ifdef DebugLog edm::LogInfo("HcalSim") << "HCalSD::Hit for Detector " << det << " etaR " << etaR << " phi " << phi/deg << " depth " <<depth; #endif double time = (aStep->GetPostStepPoint()->GetGlobalTime()); uint32_t unitID = 0; if (numberingFromDDD) { HcalNumberingFromDDD::HcalID tmp = numberingFromDDD->unitID(det,etaR,phi, depth,1); if (numberingScheme) unitID = numberingScheme->getUnitID(tmp); } currentID.setID(unitID, time, primaryID, 1); edepositHAD = aStep->GetTotalEnergyDeposit(); edepositEM =-edepositHAD + (edep*GeV); #ifdef plotDebug plotProfile(aStep, hitPoint, edep*GeV, time, depth); #endif #ifdef DebugLog double beta = preStepPoint->GetBeta(); LogDebug("HcalSim") << "HCalSD::getHitPMT 1 hit for " << GetName() << " of " << primaryID << " with " << theTrack->GetDefinition()->GetParticleName() << " of " << preStepPoint->GetKineticEnergy()/GeV << " GeV with velocity " << beta << " UnitID " << std::hex << unitID << std::dec; #endif // check if it is in the same unit and timeslice as the previous one if (currentID == previousID) { updateHit(currentHit); } else { if (!checkHit()) currentHit = createNewHit(); } } }
std::vector< G4String > HCalSD::getNames | ( | DDFilteredView & | fv | ) | [private] |
Definition at line 672 of file HCalSD.cc.
References DDFilteredView::firstChild(), i, funct::log(), DDFilteredView::logicalPart(), DDName::name(), DDBase< N, C >::name(), DDFilteredView::next(), convertSQLiteXML::ok, and tmp.
{ std::vector<G4String> tmp; bool dodet = fv.firstChild(); while (dodet) { const DDLogicalPart & log = fv.logicalPart(); bool ok = true; for (unsigned int i=0; i<tmp.size(); ++i) { if (!strcmp(tmp[i].c_str(), log.name().name().c_str())) { ok = false; break; } } if (ok) tmp.push_back(log.name().name()); dodet = fv.next(); } return tmp; }
void HCalSD::hitForFibre | ( | G4Step * | step, |
double | weight | ||
) | [private] |
Definition at line 826 of file HCalSD.cc.
References CaloSD::checkHit(), CaloSD::createNewHit(), CaloSD::currentHit, CaloSD::currentID, CaloSD::edepositEM, CaloSD::edepositHAD, CaloSD::emPDG, CaloSD::epPDG, CaloSD::gammaPDG, HFShower::getHits(), hfshower, i, isItinFidVolume(), plotHF(), plotProfile(), CaloSD::posGlobal, CaloSD::preStepPoint, CaloSD::previousID, setDetUnitId(), CaloHitID::setID(), setTrackID(), CaloSD::theTrack, cond::rpcobgas::time, and CaloSD::updateHit().
Referenced by ProcessHits().
{ // if not ParamShower preStepPoint = aStep->GetPreStepPoint(); theTrack = aStep->GetTrack(); int primaryID = setTrackID(aStep); int det = 5; std::vector<HFShower::Hit> hits = hfshower->getHits(aStep, weight); G4int particleCode = theTrack->GetDefinition()->GetPDGEncoding(); if (particleCode==emPDG || particleCode==epPDG || particleCode==gammaPDG) { edepositEM = 1.*GeV; edepositHAD = 0.; } else { edepositEM = 0.; edepositHAD = 1.*GeV; } #ifdef DebugLog edm::LogInfo("HcalSim") << "HCalSD::hitForFibre " << hits.size() << " hits for " << GetName() << " of " << primaryID << " with " << theTrack->GetDefinition()->GetParticleName() << " of " << preStepPoint->GetKineticEnergy()/GeV << " GeV in detector type " << det; #endif if (hits.size() > 0) { for (unsigned int i=0; i<hits.size(); ++i) { G4ThreeVector hitPoint = hits[i].position; if (isItinFidVolume (hitPoint)) { int depth = hits[i].depth; double time = hits[i].time; unsigned int unitID = setDetUnitId(det, hitPoint, depth); currentID.setID(unitID, time, primaryID, 0); #ifdef plotDebug plotProfile(aStep, hitPoint, edepositEM, time, depth); bool emType = false; if (particleCode==emPDG || particleCode==epPDG || particleCode==gammaPDG) emType = true; plotHF(hitPoint,emType); #endif // check if it is in the same unit and timeslice as the previous one if (currentID == previousID) { updateHit(currentHit); } else { posGlobal = preStepPoint->GetPosition(); if (!checkHit()) currentHit = createNewHit(); } } } } }
void HCalSD::initRun | ( | ) | [protected, virtual] |
Reimplemented from CaloSD.
Definition at line 603 of file HCalSD.cc.
References hfshower, HFShowerLibrary::initRun(), HFShower::initRun(), HFShowerParam::initRun(), LogDebug, mumPDG, mupPDG, showerLibrary, and showerParam.
{ G4ParticleTable * theParticleTable = G4ParticleTable::GetParticleTable(); G4String particleName; mumPDG = theParticleTable->FindParticle(particleName="mu-")->GetPDGEncoding(); mupPDG = theParticleTable->FindParticle(particleName="mu+")->GetPDGEncoding(); #ifdef DebugLog LogDebug("HcalSim") << "HCalSD: Particle code for mu- = " << mumPDG << " for mu+ = " << mupPDG; #endif if (showerLibrary) showerLibrary->initRun(theParticleTable); if (showerParam) showerParam->initRun(theParticleTable); if (hfshower) hfshower->initRun(theParticleTable); }
bool HCalSD::isItConicalBundle | ( | G4LogicalVolume * | lv | ) | [private] |
bool HCalSD::isItFibre | ( | G4LogicalVolume * | lv | ) | [private] |
bool HCalSD::isItFibre | ( | G4String | name | ) | [private] |
Definition at line 716 of file HCalSD.cc.
References fibreNames.
{ std::vector<G4String>::const_iterator it = fibreNames.begin(); for (; it != fibreNames.end(); ++it) if (name == *it) return true; return false; }
bool HCalSD::isItHF | ( | G4Step * | aStep | ) | [private] |
Definition at line 692 of file HCalSD.cc.
References hfLevels, hfLV, and hfNames.
Referenced by HCalSD(), and ProcessHits().
{ const G4VTouchable* touch = aStep->GetPreStepPoint()->GetTouchable(); int levels = (touch->GetHistoryDepth()) + 1; for (unsigned int it=0; it < hfNames.size(); ++it) { if (levels >= hfLevels[it]) { G4LogicalVolume* lv = touch->GetVolume(levels-hfLevels[it])->GetLogicalVolume(); if (lv == hfLV[it]) return true; } } return false; }
bool HCalSD::isItHF | ( | G4String | name | ) | [private] |
bool HCalSD::isItinFidVolume | ( | G4ThreeVector & | hitPoint | ) | [private] |
Definition at line 746 of file HCalSD.cc.
References applyFidCut, and HFFibreFiducial::PMTNumber().
Referenced by getFromLibrary(), and hitForFibre().
{ bool flag = true; if (applyFidCut) { int npmt = HFFibreFiducial:: PMTNumber(hitPoint); #ifdef DebugLog edm::LogInfo("HcalSim") << "HCalSD::isItinFidVolume:#PMT= " << npmt << " for hit point " << hitPoint; #endif if (npmt <= 0) flag = false; } #ifdef DebugLog edm::LogInfo("HcalSim") << "HCalSD::isItinFidVolume: point " << hitPoint << " return flag " << flag; #endif return flag; }
bool HCalSD::isItPMT | ( | G4LogicalVolume * | lv | ) | [private] |
bool HCalSD::isItScintillator | ( | G4Material * | mat | ) | [private] |
bool HCalSD::isItStraightBundle | ( | G4LogicalVolume * | lv | ) | [private] |
double HCalSD::layerWeight | ( | int | det, |
G4ThreeVector | pos, | ||
int | depth, | ||
int | lay | ||
) | [private] |
Definition at line 1093 of file HCalSD.cc.
References HcalNumberingFromDDD::HcalID::etaR, HcalNumberingFromDDD::HcalID::lay, layerWeights, numberingFromDDD, HcalTestNumbering::packHcalIndex(), HcalNumberingFromDDD::HcalID::phis, HcalNumberingFromDDD::HcalID::subdet, tmp, HcalNumberingFromDDD::unitID(), and HcalNumberingFromDDD::HcalID::zside.
Referenced by getEnergyDeposit().
{ double wt = 1.; if (numberingFromDDD) { //get the ID's as eta, phi, depth, ... indices HcalNumberingFromDDD::HcalID tmp = numberingFromDDD->unitID(det, pos, depth, lay); uint32_t id = HcalTestNumbering::packHcalIndex(tmp.subdet, tmp.zside, 1, tmp.etaR, tmp.phis,tmp.lay); std::map<uint32_t,double>::const_iterator ite = layerWeights.find(id); if (ite != layerWeights.end()) wt = ite->second; #ifdef DebugLog edm::LogInfo("HcalSim") << "HCalSD::layerWeight: ID " << std::hex << id << std::dec << " (" << tmp.subdet << "/" << tmp.zside << "/1/" << tmp.etaR << "/" << tmp.phis << "/" << tmp.lay << ") Weight " <<wt; #endif } return wt; }
void HCalSD::plotHF | ( | G4ThreeVector & | pos, |
bool | emType | ||
) | [private] |
void HCalSD::plotProfile | ( | G4Step * | step, |
G4ThreeVector | pos, | ||
double | edep, | ||
double | time, | ||
int | id | ||
) | [private] |
Definition at line 1114 of file HCalSD.cc.
References abs, dist_, newFWLiteAna::found, hit_, UserOptions_cff::idx, LogDebug, n, SensitiveDetector::name, cond::rpcobgas::time, and time_.
Referenced by getFromLibrary(), getFromParam(), getHitFibreBundle(), getHitPMT(), hitForFibre(), and ProcessHits().
{ const G4VTouchable* touch = aStep->GetPreStepPoint()->GetTouchable(); static G4String modName[8] = {"HEModule", "HVQF" , "HBModule", "MBAT", "MBBT" , "MBBTC", "MBBT_R1P", "MBBT_R1M"}; G4ThreeVector local; bool found=false; double depth=-2000; int idx = 4; for (int n=0; n<touch->GetHistoryDepth(); ++n) { G4String name = touch->GetVolume(n)->GetName(); #ifdef DebugLog LogDebug("HcalSim") << "plotProfile Depth " << n << " Name " << name; #endif for (unsigned int ii=0; ii<8; ++ii) { if (name == modName[ii]) { found = true; int dn = touch->GetHistoryDepth() - n; local = touch->GetHistory()->GetTransform(dn).TransformPoint(global); if (ii == 0) {depth = local.z() - 4006.5; idx = 1;} else if (ii == 1) {depth = local.z() + 825.0; idx = 3;} else if (ii == 2) {depth = local.x() - 1775.; idx = 0;} else {depth = local.y() + 15.; idx = 2;} break; } } if (found) break; } if (!found) depth = std::abs(global.z()) - 11500; #ifdef DebugLog LogDebug("HcalSim") << "plotProfile Found " << found << " Global " << global << " Local " << local << " depth " << depth << " ID " << id << " EDEP " << edep << " Time " << time; #endif if (hit_[idx] != 0) hit_[idx]->Fill(edep); if (time_[idx] != 0) time_[idx]->Fill(time,edep); if (dist_[idx] != 0) dist_[idx]->Fill(depth,edep); int jd = 2*idx + id - 7; if (jd >= 0 && jd < 4) { jd += 5; if (hit_[jd] != 0) hit_[jd]->Fill(edep); if (time_[jd] != 0) time_[jd]->Fill(time,edep); if (dist_[jd] != 0) dist_[jd]->Fill(depth,edep); } }
bool HCalSD::ProcessHits | ( | G4Step * | aStep, |
G4TouchableHistory * | |||
) | [virtual] |
Reimplemented from CaloSD.
Definition at line 392 of file HCalSD.cc.
References abs, CaloSD::createNewHit(), CaloSD::currentHit, HFDarkening::degradation(), deliveredLumi, HFDarkening::dose(), CaloSD::edepositEM, CaloSD::edepositHAD, getFromLibrary(), getFromParam(), getHitFibreBundle(), getHitPMT(), CaloSD::getNumberOfHits(), CaloSD::getStepInfo(), CaloSD::hitExists(), hitForFibre(), i, HFDarkening::int_lumi(), isItConicalBundle(), isItFibre(), isItHF(), isItPMT(), isItStraightBundle(), LogDebug, m_HFDarkening, mumPDG, mupPDG, SensitiveDetector::NaNTrap(), NULL, plotProfile(), alignCSCRings::r, showerBundle, showerPMT, useFibreBundle, useParam, usePMTHit, useShowerLibrary, CommonMethods::weight(), and z.
{ NaNTrap( aStep ) ; if (aStep == NULL) { return true; } else { G4LogicalVolume* lv = aStep->GetPreStepPoint()->GetPhysicalVolume()->GetLogicalVolume(); G4String nameVolume = lv->GetName(); if (isItHF(aStep)) { G4int parCode = aStep->GetTrack()->GetDefinition()->GetPDGEncoding(); double weight(1.0); if (m_HFDarkening != 0) { G4ThreeVector hitPoint = aStep->GetPreStepPoint()->GetPosition(); double r = hitPoint.perp()/CLHEP::cm; double z = std::abs(hitPoint.z())/CLHEP::cm; float dose_acquired = 0.; if (z>=1100 && z <= 1300) { int hfZLayer = (int)((z - 1100)/20); if (hfZLayer > 9) hfZLayer = 9; float normalized_lumi = m_HFDarkening->int_lumi(deliveredLumi); for (int i = hfZLayer; i <= 9; ++i) { dose_acquired = m_HFDarkening->dose(i,r); weight *= m_HFDarkening->degradation(normalized_lumi*dose_acquired); } } #ifdef DebugLog LogDebug("HcalSim") << "HCalSD: HFLumiDarkening at r = " << r << ", z = " << z << " Dose " << dose_acquired << " weight " << weight; #endif } if (useParam) { #ifdef DebugLog LogDebug("HcalSim") << "HCalSD: " << getNumberOfHits() << " hits from parametrization in " << nameVolume << " for Track " << aStep->GetTrack()->GetTrackID() <<" (" << aStep->GetTrack()->GetDefinition()->GetParticleName() <<")"; #endif getFromParam(aStep, weight); #ifdef DebugLog LogDebug("HcalSim") << "HCalSD: " << getNumberOfHits() << " hits afterParamS*"; #endif } else { bool notaMuon = true; if (parCode == mupPDG || parCode == mumPDG ) notaMuon = false; if (useShowerLibrary && notaMuon) { #ifdef DebugLog LogDebug("HcalSim") << "HCalSD: Starts shower library from " << nameVolume << " for Track " << aStep->GetTrack()->GetTrackID() << " (" << aStep->GetTrack()->GetDefinition()->GetParticleName() << ")"; #endif getFromLibrary(aStep, weight); } else if (isItFibre(lv)) { #ifdef DebugLog LogDebug("HcalSim") << "HCalSD: Hit at Fibre in " << nameVolume << " for Track " << aStep->GetTrack()->GetTrackID() <<" (" << aStep->GetTrack()->GetDefinition()->GetParticleName() << ")"; #endif hitForFibre(aStep, weight); } } } else if (isItPMT(lv)) { #ifdef DebugLog LogDebug("HcalSim") << "HCalSD: Hit from PMT parametrization from " << nameVolume << " for Track " << aStep->GetTrack()->GetTrackID() << " (" << aStep->GetTrack()->GetDefinition()->GetParticleName() << ")"; #endif if (usePMTHit && showerPMT) getHitPMT(aStep); } else if (isItStraightBundle(lv) || isItConicalBundle(lv)) { #ifdef DebugLog LogDebug("HcalSim") << "HCalSD: Hit from FibreBundle from " << nameVolume << " for Track " << aStep->GetTrack()->GetTrackID() << " (" << aStep->GetTrack()->GetDefinition()->GetParticleName() << ")"; #endif if (useFibreBundle && showerBundle) getHitFibreBundle(aStep, isItConicalBundle(lv)); } else { #ifdef DebugLog LogDebug("HcalSim") << "HCalSD: Hit from standard path from " << nameVolume << " for Track " << aStep->GetTrack()->GetTrackID() << " (" << aStep->GetTrack()->GetDefinition()->GetParticleName() << ")"; #endif if (getStepInfo(aStep)) { #ifdef plotDebug if (edepositEM+edepositHAD > 0) plotProfile(aStep, aStep->GetPreStepPoint()->GetPosition(), edepositEM+edepositHAD,aStep->GetPostStepPoint()->GetGlobalTime(),0); #endif if (hitExists() == false && edepositEM+edepositHAD>0.) currentHit = createNewHit(); } } return true; } }
void HCalSD::readWeightFromFile | ( | std::string | fName | ) | [private] |
Definition at line 1067 of file HCalSD.cc.
References recoMuon::in, EdgesToViz::infile, layerWeights, HcalTestNumbering::packHcalIndex(), phi, and useLayerWt.
Referenced by HCalSD().
{ std::ifstream infile; int entry=0; infile.open(fName.c_str(), std::ios::in); if (infile) { int det, zside, etaR, phi, lay; double wt; while (infile >> det >> zside >> etaR >> phi >> lay >> wt) { uint32_t id = HcalTestNumbering::packHcalIndex(det,zside,1,etaR,phi,lay); layerWeights.insert(std::pair<uint32_t,double>(id,wt)); ++entry; #ifdef DebugLog edm::LogInfo("HcalSim") << "HCalSD::readWeightFromFile:Entry " << entry << " ID " << std::hex << id << std::dec << " (" << det << "/" << zside << "/1/" << etaR << "/" << phi << "/" << lay << ") Weight " << wt; #endif } infile.close(); } edm::LogInfo("HcalSim") << "HCalSD::readWeightFromFile: reads " << entry << " weights from " << fName; if (entry <= 0) useLayerWt = false; }
uint32_t HCalSD::setDetUnitId | ( | G4Step * | step | ) | [virtual] |
Implements CaloSD.
Definition at line 582 of file HCalSD.cc.
References CaloSD::preStepPoint.
Referenced by getFromLibrary(), getFromParam(), and hitForFibre().
{ G4StepPoint* preStepPoint = aStep->GetPreStepPoint(); const G4VTouchable* touch = preStepPoint->GetTouchable(); G4ThreeVector hitPoint = preStepPoint->GetPosition(); int depth = (touch->GetReplicaNumber(0))%10 + 1; int lay = (touch->GetReplicaNumber(0)/10)%100 + 1; int det = (touch->GetReplicaNumber(1))/1000; return setDetUnitId (det, hitPoint, depth, lay); }
uint32_t HCalSD::setDetUnitId | ( | int | det, |
G4ThreeVector | pos, | ||
int | depth, | ||
int | lay = 1 |
||
) | [private] |
Definition at line 636 of file HCalSD.cc.
References HcalNumberingScheme::getUnitID(), numberingFromDDD, numberingScheme, tmp, and HcalNumberingFromDDD::unitID().
{ uint32_t id = 0; if (numberingFromDDD) { //get the ID's as eta, phi, depth, ... indices HcalNumberingFromDDD::HcalID tmp = numberingFromDDD->unitID(det, pos, depth, lay); //get the ID if (numberingScheme) id = numberingScheme->getUnitID(tmp); } return id; }
void HCalSD::setNumberingScheme | ( | HcalNumberingScheme * | scheme | ) |
Definition at line 595 of file HCalSD.cc.
References numberingScheme.
Referenced by HCalSD(), HcalTB04Analysis::update(), HcalTestAnalysis::update(), and SimG4HcalValidation::update().
{ if (scheme != 0) { edm::LogInfo("HcalSim") << "HCalSD: updates numbering scheme for " << GetName(); if (numberingScheme) delete numberingScheme; numberingScheme = scheme; } }
int HCalSD::setTrackID | ( | G4Step * | step | ) | [private] |
Definition at line 1047 of file HCalSD.cc.
References TrackInformation::getIDonCaloSurface(), CaloSD::preStepPoint, CaloSD::previousID, CaloSD::resetForNewPrimary(), CaloSD::theTrack, and CaloHitID::trackID().
Referenced by getFromLibrary(), getFromParam(), and hitForFibre().
{ theTrack = aStep->GetTrack(); double etrack = preStepPoint->GetKineticEnergy(); TrackInformation * trkInfo = (TrackInformation *)(theTrack->GetUserInformation()); int primaryID = trkInfo->getIDonCaloSurface(); if (primaryID == 0) { #ifdef DebugLog edm::LogInfo("HcalSim") << "HCalSD: Problem with primaryID **** set by " << "force to TkID **** " <<theTrack->GetTrackID(); #endif primaryID = theTrack->GetTrackID(); } if (primaryID != previousID.trackID()) resetForNewPrimary(preStepPoint->GetPosition(), etrack); return primaryID; }
bool HCalSD::applyFidCut [private] |
Definition at line 88 of file HCalSD.h.
Referenced by HCalSD(), and isItinFidVolume().
double HCalSD::betaThr [private] |
double HCalSD::birk1 [private] |
Definition at line 87 of file HCalSD.h.
Referenced by getEnergyDeposit(), and HCalSD().
double HCalSD::birk2 [private] |
Definition at line 87 of file HCalSD.h.
Referenced by getEnergyDeposit(), and HCalSD().
double HCalSD::birk3 [private] |
Definition at line 87 of file HCalSD.h.
Referenced by getEnergyDeposit(), and HCalSD().
double HCalSD::deliveredLumi [private] |
Definition at line 90 of file HCalSD.h.
Referenced by getEnergyDeposit(), HCalSD(), and ProcessHits().
TH1F * HCalSD::dist_[9] [private] |
Definition at line 98 of file HCalSD.h.
Referenced by HCalSD(), and plotProfile().
double HCalSD::eminHitHB [private] |
Definition at line 89 of file HCalSD.h.
Referenced by filterHit(), and HCalSD().
double HCalSD::eminHitHE [private] |
Definition at line 89 of file HCalSD.h.
Referenced by filterHit(), and HCalSD().
double HCalSD::eminHitHF [private] |
Definition at line 89 of file HCalSD.h.
Referenced by filterHit(), and HCalSD().
double HCalSD::eminHitHO [private] |
Definition at line 89 of file HCalSD.h.
Referenced by filterHit(), and HCalSD().
std::vector<G4LogicalVolume*> HCalSD::fibre1LV [private] |
Definition at line 96 of file HCalSD.h.
Referenced by HCalSD(), and isItStraightBundle().
std::vector<G4LogicalVolume*> HCalSD::fibre2LV [private] |
Definition at line 96 of file HCalSD.h.
Referenced by HCalSD(), and isItConicalBundle().
std::vector<G4LogicalVolume*> HCalSD::fibreLV [private] |
Definition at line 96 of file HCalSD.h.
Referenced by HCalSD(), and isItFibre().
std::vector<G4String> HCalSD::fibreNames [private] |
Definition at line 94 of file HCalSD.h.
Referenced by HCalSD(), and isItFibre().
std::vector<double> HCalSD::gpar [private] |
std::vector<int> HCalSD::hfLevels [private] |
std::vector<G4LogicalVolume*> HCalSD::hfLV [private] |
std::vector<G4String> HCalSD::hfNames [private] |
HFShower* HCalSD::hfshower [private] |
TH1F* HCalSD::hit_[9] [private] |
Definition at line 98 of file HCalSD.h.
Referenced by HCalSD(), and plotProfile().
TH1F * HCalSD::hzvem [private] |
TH1F * HCalSD::hzvhad [private] |
std::vector<double> HCalSD::layer0wt [private] |
Definition at line 92 of file HCalSD.h.
Referenced by getEnergyDeposit(), and HCalSD().
std::map<uint32_t,double> HCalSD::layerWeights [private] |
Definition at line 97 of file HCalSD.h.
Referenced by layerWeight(), and readWeightFromFile().
HEDarkening* HCalSD::m_HEDarkening [private] |
Definition at line 84 of file HCalSD.h.
Referenced by getEnergyDeposit(), HCalSD(), and ~HCalSD().
HFDarkening* HCalSD::m_HFDarkening [private] |
Definition at line 85 of file HCalSD.h.
Referenced by HCalSD(), ProcessHits(), and ~HCalSD().
std::vector<G4Material*> HCalSD::materials [private] |
Definition at line 95 of file HCalSD.h.
Referenced by HCalSD(), and isItScintillator().
std::vector<G4String> HCalSD::matNames [private] |
G4int HCalSD::mumPDG [private] |
Definition at line 91 of file HCalSD.h.
Referenced by HCalSD(), initRun(), and ProcessHits().
G4int HCalSD::mupPDG [private] |
Definition at line 91 of file HCalSD.h.
Referenced by HCalSD(), initRun(), and ProcessHits().
HcalNumberingFromDDD* HCalSD::numberingFromDDD [private] |
Definition at line 77 of file HCalSD.h.
Referenced by getHitFibreBundle(), getHitPMT(), HCalSD(), layerWeight(), setDetUnitId(), and ~HCalSD().
HcalNumberingScheme* HCalSD::numberingScheme [private] |
Definition at line 78 of file HCalSD.h.
Referenced by getHitFibreBundle(), getHitPMT(), setDetUnitId(), setNumberingScheme(), and ~HCalSD().
std::vector<G4LogicalVolume*> HCalSD::pmtLV [private] |
HFShowerFibreBundle* HCalSD::showerBundle [private] |
Definition at line 83 of file HCalSD.h.
Referenced by getHitFibreBundle(), HCalSD(), ProcessHits(), and ~HCalSD().
HFShowerLibrary* HCalSD::showerLibrary [private] |
HFShowerParam* HCalSD::showerParam [private] |
HFShowerPMT* HCalSD::showerPMT [private] |
Definition at line 82 of file HCalSD.h.
Referenced by getHitPMT(), HCalSD(), ProcessHits(), and ~HCalSD().
TH1F * HCalSD::time_[9] [private] |
Definition at line 98 of file HCalSD.h.
Referenced by HCalSD(), and plotProfile().
bool HCalSD::useBirk [private] |
Definition at line 86 of file HCalSD.h.
Referenced by getEnergyDeposit(), and HCalSD().
bool HCalSD::useFibreBundle [private] |
Definition at line 86 of file HCalSD.h.
Referenced by HCalSD(), and ProcessHits().
bool HCalSD::useHF [private] |
bool HCalSD::useLayerWt [private] |
Definition at line 86 of file HCalSD.h.
Referenced by getEnergyDeposit(), HCalSD(), and readWeightFromFile().
bool HCalSD::useParam [private] |
Definition at line 88 of file HCalSD.h.
Referenced by HCalSD(), and ProcessHits().
bool HCalSD::usePMTHit [private] |
Definition at line 86 of file HCalSD.h.
Referenced by HCalSD(), and ProcessHits().
bool HCalSD::useShowerLibrary [private] |
Definition at line 88 of file HCalSD.h.
Referenced by HCalSD(), and ProcessHits().