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//////////////////////////////////////////////////////////
// This class has been automatically generated on
// Fri Apr 27 12:47:47 2007 by ROOT version 5.12/00
// from TTree sim/simulated showers
// found on file: protons_150gev.root
//////////////////////////////////////////////////////////
#ifndef sim_h
#define sim_h
#include <TROOT.h>
#include <TChain.h>
#include <TFile.h>
const Int_t kMaxshower = 1;
const Int_t kMaxparticle_ = 100000;
const Int_t kMaxlong = 10000;
const Int_t kMaxcerenkov = 1;
class sim {
public:
TTree *fChain; //!pointer to the analyzed TTree or TChain
Int_t fCurrent; //!current Tree number in a TChain
// Declaration of leave types
//crsIO::TShower *shower.;
UInt_t shower_TObject_fUniqueID;
UInt_t shower_TObject_fBits;
Int_t shower_EventID;
Float_t shower_Energy;
Float_t shower_StartingAltitude;
Int_t shower_FirstTarget;
Float_t shower_FirstHeight;
Float_t shower_Theta;
Float_t shower_Phi;
Int_t shower_RandomSeed[10];
Int_t shower_RandomOffset[10];
Float_t shower_nPhotons;
Float_t shower_nElectrons;
Float_t shower_nHadrons;
Float_t shower_nMuons;
Int_t shower_nParticlesWritten;
Int_t shower_nPhotonsWritten;
Int_t shower_nElectronsWritten;
Int_t shower_nHadronsWritten;
Int_t shower_nMuonsWritten;
Float_t shower_GH_Nmax;
Float_t shower_GH_t0;
Float_t shower_GH_tmax;
Float_t shower_GH_a;
Float_t shower_GH_b;
Float_t shower_GH_c;
Float_t shower_GH_Chi2;
Int_t shower_nPreshower;
Int_t shower_CPUtime;
Int_t particle__;
UInt_t particle__fUniqueID[kMaxparticle_]; //[particle._]
UInt_t particle__fBits[kMaxparticle_]; //[particle._]
Int_t particle__ParticleID[kMaxparticle_]; //[particle._]
Int_t particle__ObservationLevel[kMaxparticle_]; //[particle._]
Int_t particle__HadronicGeneration[kMaxparticle_]; //[particle._]
Double_t particle__Px[kMaxparticle_]; //[particle._]
Double_t particle__Py[kMaxparticle_]; //[particle._]
Double_t particle__Pz[kMaxparticle_]; //[particle._]
Double_t particle__x[kMaxparticle_]; //[particle._]
Double_t particle__y[kMaxparticle_]; //[particle._]
Double_t particle__Time[kMaxparticle_]; //[particle._]
Double_t particle__Weight[kMaxparticle_]; //[particle._]
Int_t long_;
UInt_t long_fUniqueID[kMaxlong]; //[long_]
UInt_t long_fBits[kMaxlong]; //[long_]
Float_t long_Depth[kMaxlong]; //[long_]
ULong64_t long_nGammas[kMaxlong]; //[long_]
ULong64_t long_nElectrons[kMaxlong]; //[long_]
ULong64_t long_nPositrons[kMaxlong]; //[long_]
ULong64_t long_nMuons[kMaxlong]; //[long_]
ULong64_t long_nAntiMuons[kMaxlong]; //[long_]
ULong64_t long_nHadrons[kMaxlong]; //[long_]
ULong64_t long_nCharged[kMaxlong]; //[long_]
ULong64_t long_nNuclei[kMaxlong]; //[long_]
ULong64_t long_nCerenkov[kMaxlong]; //[long_]
Int_t cerenkov_;
UInt_t cerenkov_fUniqueID[kMaxcerenkov]; //[cerenkov_]
UInt_t cerenkov_fBits[kMaxcerenkov]; //[cerenkov_]
Float_t cerenkov_nPhotons[kMaxcerenkov]; //[cerenkov_]
Float_t cerenkov_x[kMaxcerenkov]; //[cerenkov_]
Float_t cerenkov_y[kMaxcerenkov]; //[cerenkov_]
Float_t cerenkov_u[kMaxcerenkov]; //[cerenkov_]
Float_t cerenkov_v[kMaxcerenkov]; //[cerenkov_]
Float_t cerenkov_Time[kMaxcerenkov]; //[cerenkov_]
Float_t cerenkov_ProductionHeight[kMaxcerenkov]; //[cerenkov_]
Float_t cerenkov_Weight[kMaxcerenkov]; //[cerenkov_]
// List of branches
TBranch *b_shower_TObject_fUniqueID; //!
TBranch *b_shower_TObject_fBits; //!
TBranch *b_shower_EventID; //!
TBranch *b_shower_Energy; //!
TBranch *b_shower_StartingAltitude; //!
TBranch *b_shower_FirstTarget; //!
TBranch *b_shower_FirstHeight; //!
TBranch *b_shower_Theta; //!
TBranch *b_shower_Phi; //!
TBranch *b_shower_RandomSeed; //!
TBranch *b_shower_RandomOffset; //!
TBranch *b_shower_nPhotons; //!
TBranch *b_shower_nElectrons; //!
TBranch *b_shower_nHadrons; //!
TBranch *b_shower_nMuons; //!
TBranch *b_shower_nParticlesWritten; //!
TBranch *b_shower_nPhotonsWritten; //!
TBranch *b_shower_nElectronsWritten; //!
TBranch *b_shower_nHadronsWritten; //!
TBranch *b_shower_nMuonsWritten; //!
TBranch *b_shower_GH_Nmax; //!
TBranch *b_shower_GH_t0; //!
TBranch *b_shower_GH_tmax; //!
TBranch *b_shower_GH_a; //!
TBranch *b_shower_GH_b; //!
TBranch *b_shower_GH_c; //!
TBranch *b_shower_GH_Chi2; //!
TBranch *b_shower_nPreshower; //!
TBranch *b_shower_CPUtime; //!
TBranch *b_particle__; //!
TBranch *b_particle__fUniqueID; //!
TBranch *b_particle__fBits; //!
TBranch *b_particle__ParticleID; //!
TBranch *b_particle__ObservationLevel; //!
TBranch *b_particle__HadronicGeneration; //!
TBranch *b_particle__Px; //!
TBranch *b_particle__Py; //!
TBranch *b_particle__Pz; //!
TBranch *b_particle__x; //!
TBranch *b_particle__y; //!
TBranch *b_particle__Time; //!
TBranch *b_particle__Weight; //!
TBranch *b_long_; //!
TBranch *b_long_fUniqueID; //!
TBranch *b_long_fBits; //!
TBranch *b_long_Depth; //!
TBranch *b_long_nGammas; //!
TBranch *b_long_nElectrons; //!
TBranch *b_long_nPositrons; //!
TBranch *b_long_nMuons; //!
TBranch *b_long_nAntiMuons; //!
TBranch *b_long_nHadrons; //!
TBranch *b_long_nCharged; //!
TBranch *b_long_nNuclei; //!
TBranch *b_long_nCerenkov; //!
TBranch *b_cerenkov_; //!
TBranch *b_cerenkov_fUniqueID; //!
TBranch *b_cerenkov_fBits; //!
TBranch *b_cerenkov_nPhotons; //!
TBranch *b_cerenkov_x; //!
TBranch *b_cerenkov_y; //!
TBranch *b_cerenkov_u; //!
TBranch *b_cerenkov_v; //!
TBranch *b_cerenkov_Time; //!
TBranch *b_cerenkov_ProductionHeight; //!
TBranch *b_cerenkov_Weight; //!
sim(TTree *tree = nullptr);
virtual ~sim();
virtual Int_t Cut(Long64_t entry);
virtual Int_t GetEntry(Long64_t entry);
virtual Long64_t LoadTree(Long64_t entry);
virtual void Init(TTree *tree);
//virtual void Loop();
virtual Bool_t Notify();
virtual void Show(Long64_t entry = -1);
};
#endif
#ifdef sim_cxx
inline sim::sim(TTree *tree) {
// if parameter tree is not specified (or zero), connect the file
// used to generate this class and read the Tree.
if (tree == nullptr) {
std::cout << "sim::sim: tree = 0" << std::endl;
TFile *f = (TFile *)gROOT->GetListOfFiles()->FindObject("protons_150gev.root");
if (!f) {
f = new TFile("protons_150gev.root");
}
tree = (TTree *)gDirectory->Get("sim");
}
//else std::cout << "sim::sim: tree != 0 => Alright!" << std::endl;
Init(tree);
}
inline sim::~sim() {
if (!fChain)
return;
delete fChain->GetCurrentFile();
}
inline Int_t sim::GetEntry(Long64_t entry) {
// Read contents of entry.
if (!fChain)
return 0;
return fChain->GetEntry(entry);
}
inline Long64_t sim::LoadTree(Long64_t entry) {
// Set the environment to read one entry
std::cout << "sim::LoadTree: " << std::endl;
if (fChain)
std::cout << " fChain<>0" << std::endl;
else
std::cout << " fChain=0" << std::endl;
if (!fChain)
return -5;
Long64_t centry = fChain->LoadTree(entry);
if (centry < 0)
return centry;
if (fChain->IsA() != TChain::Class())
return centry;
TChain *chain = (TChain *)fChain;
if (chain->GetTreeNumber() != fCurrent) {
fCurrent = chain->GetTreeNumber();
Notify();
}
return centry;
}
inline void sim::Init(TTree *tree) {
// The Init() function is called when the selector needs to initialize
// a new tree or chain. Typically here the branch addresses and branch
// pointers of the tree will be set.
// It is normaly not necessary to make changes to the generated
// code, but the routine can be extended by the user if needed.
// Init() will be called many times when running on PROOF
// (once per file to be processed).
// Set branch addresses and branch pointers
if (!tree)
return;
fChain = tree;
fCurrent = -1;
fChain->SetMakeClass(1);
fChain->SetBranchAddress("shower.TObject.fUniqueID", &shower_TObject_fUniqueID, &b_shower_TObject_fUniqueID);
fChain->SetBranchAddress("shower.TObject.fBits", &shower_TObject_fBits, &b_shower_TObject_fBits);
fChain->SetBranchAddress("shower.EventID", &shower_EventID, &b_shower_EventID);
fChain->SetBranchAddress("shower.Energy", &shower_Energy, &b_shower_Energy);
fChain->SetBranchAddress("shower.StartingAltitude", &shower_StartingAltitude, &b_shower_StartingAltitude);
fChain->SetBranchAddress("shower.FirstTarget", &shower_FirstTarget, &b_shower_FirstTarget);
fChain->SetBranchAddress("shower.FirstHeight", &shower_FirstHeight, &b_shower_FirstHeight);
fChain->SetBranchAddress("shower.Theta", &shower_Theta, &b_shower_Theta);
fChain->SetBranchAddress("shower.Phi", &shower_Phi, &b_shower_Phi);
fChain->SetBranchAddress("shower.RandomSeed[10]", shower_RandomSeed, &b_shower_RandomSeed);
fChain->SetBranchAddress("shower.RandomOffset[10]", shower_RandomOffset, &b_shower_RandomOffset);
fChain->SetBranchAddress("shower.nPhotons", &shower_nPhotons, &b_shower_nPhotons);
fChain->SetBranchAddress("shower.nElectrons", &shower_nElectrons, &b_shower_nElectrons);
fChain->SetBranchAddress("shower.nHadrons", &shower_nHadrons, &b_shower_nHadrons);
fChain->SetBranchAddress("shower.nMuons", &shower_nMuons, &b_shower_nMuons);
fChain->SetBranchAddress("shower.nParticlesWritten", &shower_nParticlesWritten, &b_shower_nParticlesWritten);
fChain->SetBranchAddress("shower.nPhotonsWritten", &shower_nPhotonsWritten, &b_shower_nPhotonsWritten);
fChain->SetBranchAddress("shower.nElectronsWritten", &shower_nElectronsWritten, &b_shower_nElectronsWritten);
fChain->SetBranchAddress("shower.nHadronsWritten", &shower_nHadronsWritten, &b_shower_nHadronsWritten);
fChain->SetBranchAddress("shower.nMuonsWritten", &shower_nMuonsWritten, &b_shower_nMuonsWritten);
fChain->SetBranchAddress("shower.GH_Nmax", &shower_GH_Nmax, &b_shower_GH_Nmax);
fChain->SetBranchAddress("shower.GH_t0", &shower_GH_t0, &b_shower_GH_t0);
fChain->SetBranchAddress("shower.GH_tmax", &shower_GH_tmax, &b_shower_GH_tmax);
fChain->SetBranchAddress("shower.GH_a", &shower_GH_a, &b_shower_GH_a);
fChain->SetBranchAddress("shower.GH_b", &shower_GH_b, &b_shower_GH_b);
fChain->SetBranchAddress("shower.GH_c", &shower_GH_c, &b_shower_GH_c);
fChain->SetBranchAddress("shower.GH_Chi2", &shower_GH_Chi2, &b_shower_GH_Chi2);
fChain->SetBranchAddress("shower.nPreshower", &shower_nPreshower, &b_shower_nPreshower);
fChain->SetBranchAddress("shower.CPUtime", &shower_CPUtime, &b_shower_CPUtime);
fChain->SetBranchAddress("particle.", &particle__, &b_particle__);
fChain->SetBranchAddress("particle..fUniqueID", particle__fUniqueID, &b_particle__fUniqueID);
fChain->SetBranchAddress("particle..fBits", particle__fBits, &b_particle__fBits);
fChain->SetBranchAddress("particle..ParticleID", particle__ParticleID, &b_particle__ParticleID);
fChain->SetBranchAddress("particle..ObservationLevel", particle__ObservationLevel, &b_particle__ObservationLevel);
fChain->SetBranchAddress(
"particle..HadronicGeneration", particle__HadronicGeneration, &b_particle__HadronicGeneration);
fChain->SetBranchAddress("particle..Px", particle__Px, &b_particle__Px);
fChain->SetBranchAddress("particle..Py", particle__Py, &b_particle__Py);
fChain->SetBranchAddress("particle..Pz", particle__Pz, &b_particle__Pz);
fChain->SetBranchAddress("particle..x", particle__x, &b_particle__x);
fChain->SetBranchAddress("particle..y", particle__y, &b_particle__y);
fChain->SetBranchAddress("particle..Time", particle__Time, &b_particle__Time);
fChain->SetBranchAddress("particle..Weight", particle__Weight, &b_particle__Weight);
fChain->SetBranchAddress("long", &long_, &b_long_);
fChain->SetBranchAddress("long.fUniqueID", long_fUniqueID, &b_long_fUniqueID);
fChain->SetBranchAddress("long.fBits", long_fBits, &b_long_fBits);
fChain->SetBranchAddress("long.Depth", long_Depth, &b_long_Depth);
fChain->SetBranchAddress("long.nGammas", long_nGammas, &b_long_nGammas);
fChain->SetBranchAddress("long.nElectrons", long_nElectrons, &b_long_nElectrons);
fChain->SetBranchAddress("long.nPositrons", long_nPositrons, &b_long_nPositrons);
fChain->SetBranchAddress("long.nMuons", long_nMuons, &b_long_nMuons);
fChain->SetBranchAddress("long.nAntiMuons", long_nAntiMuons, &b_long_nAntiMuons);
fChain->SetBranchAddress("long.nHadrons", long_nHadrons, &b_long_nHadrons);
fChain->SetBranchAddress("long.nCharged", long_nCharged, &b_long_nCharged);
fChain->SetBranchAddress("long.nNuclei", long_nNuclei, &b_long_nNuclei);
fChain->SetBranchAddress("long.nCerenkov", long_nCerenkov, &b_long_nCerenkov);
fChain->SetBranchAddress("cerenkov", &cerenkov_, &b_cerenkov_);
fChain->SetBranchAddress("cerenkov.fUniqueID", &cerenkov_fUniqueID, &b_cerenkov_fUniqueID);
fChain->SetBranchAddress("cerenkov.fBits", &cerenkov_fBits, &b_cerenkov_fBits);
fChain->SetBranchAddress("cerenkov.nPhotons", &cerenkov_nPhotons, &b_cerenkov_nPhotons);
fChain->SetBranchAddress("cerenkov.x", &cerenkov_x, &b_cerenkov_x);
fChain->SetBranchAddress("cerenkov.y", &cerenkov_y, &b_cerenkov_y);
fChain->SetBranchAddress("cerenkov.u", &cerenkov_u, &b_cerenkov_u);
fChain->SetBranchAddress("cerenkov.v", &cerenkov_v, &b_cerenkov_v);
fChain->SetBranchAddress("cerenkov.Time", &cerenkov_Time, &b_cerenkov_Time);
fChain->SetBranchAddress("cerenkov.ProductionHeight", &cerenkov_ProductionHeight, &b_cerenkov_ProductionHeight);
fChain->SetBranchAddress("cerenkov.Weight", &cerenkov_Weight, &b_cerenkov_Weight);
Notify();
}
inline Bool_t sim::Notify() {
// The Notify() function is called when a new file is opened. This
// can be either for a new TTree in a TChain or when when a new TTree
// is started when using PROOF. It is normaly not necessary to make changes
// to the generated code, but the routine can be extended by the
// user if needed. The return value is currently not used.
return kTRUE;
}
inline void sim::Show(Long64_t entry) {
// Print contents of entry.
// If entry is not specified, print current entry
if (!fChain)
return;
fChain->Show(entry);
}
inline Int_t sim::Cut(Long64_t entry) {
// This function may be called from Loop.
// returns 1 if entry is accepted.
// returns -1 otherwise.
return 1;
}
#endif // #ifdef sim_cxx
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