/* ======================================================================== *\ ! ! * ! * This file is part of MARS, the MAGIC Analysis and Reconstruction ! * Software. It is distributed to you in the hope that it can be a useful ! * and timesaving tool in analysing Data of imaging Cerenkov telescopes. ! * It is distributed WITHOUT ANY WARRANTY. ! * ! * Permission to use, copy, modify and distribute this software and its ! * documentation for any purpose is hereby granted without fee, ! * provided that the above copyright notice appear in all copies and ! * that both that copyright notice and this permission notice appear ! * in supporting documentation. It is provided "as is" without express ! * or implied warranty. ! * ! ! ! Author(s): Abelardo Moralejo, 02/2005 ! ! Copyright: MAGIC Software Development, 2000-2005 ! ! \* ======================================================================== */ ///////////////////////////////////////////////////////////////////////////// // // MMcEvtBasic // // This class contains the most basic MonteCarlo information // with which an event has been generated // // Note: The azimuth fTelescopePhi angle in this and other MC classes // follow the convention in the Corsika program (see Corsika manual and // TDAS 02-11). There, phi is the azimuth of the momentum vector of // particles, and is measured from the north direction, anticlockwise // (i.e, west is phi=90 degrees). When it refers to the telescope // orientation, it is the azimuth of a vector along the telescope axis, // going from the camera to the mirror. So, fTelescopeTheta=90, // fTelescopePhi = 0 means the telescope is pointing horizontally towards // South. // // // Version 1: // New container to keep the very basic informations on the // original MC events produced by Corsika // // Version 2: // - added typedef for ParticleId_t from MMcEvt // - replaced MMcEvt::ParticleId_t by ParticleId_t // // Version 3: // - moved fPhi from MMcEvt // - moved fTheta from MmcEvt // ///////////////////////////////////////////////////////////////////////////// #include "MMcEvtBasic.h" #include "MString.h" #include "MLog.h" #include "MLogManip.h" ClassImp(MMcEvtBasic); using namespace std; // -------------------------------------------------------------------------- // // Default constructor. Calls Clear() // MMcEvtBasic::MMcEvtBasic() { fName = "MMcEvtBasic"; fTitle = "Basic event info from Monte Carlo"; Clear(); } // -------------------------------------------------------------------------- // // Constructor. Use this to set all data members // // THIS FUNCTION IS FOR THE SIMULATION OLNY. // DON'T USE THIS MEMBERFUNCTION IN THE ANALYSIS. // MMcEvtBasic::MMcEvtBasic(ParticleId_t usPId, Float_t fEner, Float_t fImpa, Float_t fTPhii, Float_t fTThet) : fPartId(usPId), fEnergy(fEner), fImpact(fImpa), fTelescopePhi(fTPhii), fTelescopeTheta(fTThet), fTheta(0), fPhi(0) { fName = "MMcEvtBasic"; fTitle = "Basic event info from Monte Carlo"; } // -------------------------------------------------------------------------- // // Copy operator. Copy all data members // void MMcEvtBasic::operator=(const MMcEvtBasic &evt) { fPartId = evt.fPartId; fEnergy = evt.fEnergy; fImpact = evt.fImpact; fTelescopePhi = evt.fTelescopePhi; fTelescopeTheta = evt.fTelescopeTheta; fPhi = evt.fPhi; fTheta = evt.fTheta; } // -------------------------------------------------------------------------- // // Reset all values. // void MMcEvtBasic::Clear(Option_t *opt) { fPartId = kUNDEFINED; fEnergy = -1; fImpact = -1; fTelescopePhi = 0; fTelescopeTheta = 0; fTheta = 0; fPhi = 0; } // -------------------------------------------------------------------------- // // Fill all data members // void MMcEvtBasic::Fill(ParticleId_t usPId, Float_t fEner, Float_t fImpa, Float_t fTPhii, Float_t fTThet) { fPartId = usPId; fEnergy = fEner; fImpact = fImpa; fTelescopePhi = fTPhii; fTelescopeTheta = fTThet; } TString MMcEvtBasic::GetParticleName(Int_t id) { switch (id) { case kUNDEFINED: return "Undefined"; case kGAMMA: return "Gamma"; case kPOSITRON: return "Positron"; case kELECTRON: return "Electron"; case kANTIMUON: return "Anti-Muon"; case kMUON: return "Muon"; case kPI0: return "Pi-0"; case kNEUTRON: return "Neutron"; case kPROTON: return "Proton"; case kHELIUM: return "Helium"; case kOXYGEN: return "Oxygen"; case kIRON: return "Iron"; case kArtificial: return "Artificial"; case kNightSky: return "NightSky"; } return MString::Format("Id:%d", id); } TString MMcEvtBasic::GetParticleSymbol(Int_t id) { switch (id) { case kUNDEFINED:return "N/A"; case kGAMMA: return "\\gamma"; case kPOSITRON: return "e^{+}"; case kELECTRON: return "e^{-}"; case kANTIMUON: return "\\mu^{+}"; case kMUON: return "\\mu^{-}"; case kPI0: return "\\pi^{0}"; case kNEUTRON: return "n"; case kPROTON: return "p"; case kHELIUM: return "He"; case kOXYGEN: return "O"; case kIRON: return "Fe"; case kNightSky: return "\\gamma_{NSB}"; } return MString::Format("Id:%d", id); } TString MMcEvtBasic::GetEnergyStr(Float_t e) { if (e>=1000) return MString::Format("%.1fTeV", e/1000); if (e>=10) return MString::Format("%dGeV", (Int_t)(e+.5)); if (e>=1) return MString::Format("%.1fGeV", e); return MString::Format("%dMeV", (Int_t)(e*1000+.5)); } // -------------------------------------------------------------------------- // // Print the contents of the container. // // if you specify an option only the requested data members are printed: // allowed options are: id, energy, impact // void MMcEvtBasic::Print(Option_t *opt) const { // // print out the data member on screen // TString str(opt); if (str.IsNull()) { *fLog << all << endl; *fLog << "Monte Carlo output:" << endl; *fLog << " Particle Id: " << GetParticleName() << endl; *fLog << " Energy: " << fEnergy << "GeV" << endl; *fLog << " Impactparam.: " << fImpact/100 << "m" << endl; *fLog << endl; return; } if (str.Contains("id", TString::kIgnoreCase)) *fLog << "Particle: " << GetParticleName() << endl; if (str.Contains("energy", TString::kIgnoreCase)) *fLog << "Energy: " << fEnergy << "GeV" << endl; if (str.Contains("impact", TString::kIgnoreCase)) *fLog << "Impact: " << fImpact << "cm" << endl; }