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	diff --git a/src/InputHandler/GENIEInputHandler.cxx b/src/InputHandler/GENIEInputHandler.cxx
	index b03b8f7..3fc8663 100644
	--- a/src/InputHandler/GENIEInputHandler.cxx
	+++ b/src/InputHandler/GENIEInputHandler.cxx
	@@ -1,390 +1,394 @@
	#include "GENIEInputHandler.h"
	#ifdef __GENIE_ENABLED__

	GENIEGeneratorInfo::~GENIEGeneratorInfo() {
	DeallocateParticleStack();
	}

	void GENIEGeneratorInfo::AddBranchesToTree(TTree* tn) {
	tn->Branch("GenieParticlePDGs", &fGenieParticlePDGs, "GenieParticlePDGs/I");
	}

	void GENIEGeneratorInfo::SetBranchesFromTree(TTree* tn) {
	tn->SetBranchAddress("GenieParticlePDGs", &fGenieParticlePDGs);
	}

	void GENIEGeneratorInfo::AllocateParticleStack(int stacksize) {
	fGenieParticlePDGs = new int[stacksize];
	}

	void GENIEGeneratorInfo::DeallocateParticleStack() {
	delete fGenieParticlePDGs;
	}

	void GENIEGeneratorInfo::FillGeneratorInfo(NtpMCEventRecord* ntpl) {
	Reset();

	// Check for GENIE Event
	if (!ntpl) return;
	if (!ntpl->event) return;

	// Cast Event Record
	GHepRecord* ghep = static_cast<GHepRecord*>(ntpl->event);
	if (!ghep) return;

	// Fill Particle Stack
	GHepParticle* p = 0;
	TObjArrayIter iter(ghep);

	// Loop over all particles
	int i = 0;
	while ((p = (dynamic_cast<genie::GHepParticle*>((iter).Next())))) {
	if (!p) continue;

	// Get PDG
	fGenieParticlePDGs[i] = p->Pdg();
	i++;
	}
	}

	void GENIEGeneratorInfo::Reset() {
	for (int i = 0; i < kMaxParticles; i++) {
	fGenieParticlePDGs[i] = 0;
	}
	}


	GENIEInputHandler::GENIEInputHandler(std::string const& handle, std::string const& rawinputs) {
	LOG(SAM) << "Creating GENIEInputHandler : " << handle << std::endl;

	// Run a joint input handling
	fName = handle;

	// Setup the TChain
	fGENIETree = new TChain("gtree");
	fSaveExtra = FitPar::Config().GetParB("SaveExtraGenie");
	fCacheSize = FitPar::Config().GetParI("CacheSize");
	fMaxEvents = FitPar::Config().GetParI("MAXEVENTS");

	// Loop over all inputs and grab flux, eventhist, and nevents
	std::vector<std::string> inputs = InputUtils::ParseInputFileList(rawinputs);
	for (size_t inp_it = 0; inp_it < inputs.size(); ++inp_it) {

	// Open File for histogram access
	TFile* inp_file = new TFile(InputUtils::ExpandInputDirectories(inputs[inp_it]).c_str(), "READ");
	if (!inp_file or inp_file->IsZombie()) {
	THROW( "GENIE File IsZombie() at : '" << inputs[inp_it] << "'" << std::endl
	<< "Check that your file paths are correct and the file exists!" << std::endl
	<< "$ ls -lh " << inputs[inp_it] );
	}

	// Get Flux/Event hist
	TH1D* fluxhist = (TH1D*)inp_file->Get("nuisance_flux");
	TH1D* eventhist = (TH1D*)inp_file->Get("nuisance_events");
	if (!fluxhist or !eventhist) {
	ERROR(FTL, "Input File Contents: " << inputs[inp_it] );
	inp_file->ls();
	THROW( "GENIE FILE doesn't contain flux/xsec info." << std::endl
	<< "Try running the app PrepareGENIE first on :" << inputs[inp_it] << std::endl
	<< "$ PrepareGENIE -h" );
	}

	// Get N Events
	TTree* genietree = (TTree*)inp_file->Get("gtree");
	if (!genietree) {
	ERROR(FTL, "gtree not located in GENIE file: " << inputs[inp_it]);
	THROW("Check your inputs, they may need to be completely regenerated!");
	throw;
	}
	int nevents = genietree->GetEntries();
	if (nevents <= 0){
	THROW("Trying to a TTree with " << nevents << " to TChain from : " << inputs[inp_it]);
	}


	// Register input to form flux/event rate hists
	RegisterJointInput(inputs[inp_it], nevents, fluxhist, eventhist);

	// Add To TChain
	fGENIETree->AddFile( inputs[inp_it].c_str() );
	}

	// Registor all our file inputs
	SetupJointInputs();

	// Assign to tree
	fEventType = kGENIE;
	fGenieNtpl = NULL;
	fGENIETree->SetBranchAddress("gmcrec", &fGenieNtpl);
	+
	+ // Libraries should be seen but not heard...
	+ StopTalking();
	fGENIETree->GetEntry(0);
	+ StartTalking();

	// Create Fit Event
	fNUISANCEEvent = new FitEvent();
	fNUISANCEEvent->SetGenieEvent(fGenieNtpl);

	if (fSaveExtra) {
	fGenieInfo = new GENIEGeneratorInfo();
	fNUISANCEEvent->AddGeneratorInfo(fGenieInfo);
	}

	fNUISANCEEvent->HardReset();

	};

	GENIEInputHandler::~GENIEInputHandler() {
	//if (fGenieGHep) delete fGenieGHep;
	//if (fGenieNtpl) delete fGenieNtpl;
	//if (fGENIETree) delete fGENIETree;
	//if (fGenieInfo) delete fGenieInfo;
	}

	void GENIEInputHandler::CreateCache() {
	if (fCacheSize > 0) {
	// fGENIETree->SetCacheEntryRange(0, fNEvents);
	fGENIETree->AddBranchToCache("*", 1);
	fGENIETree->SetCacheSize(fCacheSize);
	}
	}

	void GENIEInputHandler::RemoveCache() {
	// fGENIETree->SetCacheEntryRange(0, fNEvents);
	fGENIETree->AddBranchToCache("*", 0);
	fGENIETree->SetCacheSize(0);
	}

	FitEvent* GENIEInputHandler::GetNuisanceEvent(const UInt_t entry, const bool lightweight) {
	if (entry >= (UInt_t)fNEvents) return NULL;

	// Read Entry from TTree to fill NEUT Vect in BaseFitEvt;
	fGENIETree->GetEntry(entry);

	// Run NUISANCE Vector Filler
	if (!lightweight) {
	CalcNUISANCEKinematics();
	}

	// Setup Input scaling for joint inputs
	fNUISANCEEvent->InputWeight = GetInputWeight(entry);

	return fNUISANCEEvent;
	}


	int GENIEInputHandler::GetGENIEParticleStatus(genie::GHepParticle* p, int mode) {
	/*
	kIStUndefined = -1,
	kIStInitialState = 0, / generator-level initial state /
	kIStStableFinalState = 1, / generator-level final state:
	particles to be tracked by detector-level MC /
	kIStIntermediateState = 2,
	kIStDecayedState = 3,
	kIStCorrelatedNucleon = 10,
	kIStNucleonTarget = 11,
	kIStDISPreFragmHadronicState = 12,
	kIStPreDecayResonantState = 13,
	kIStHadronInTheNucleus = 14, / hadrons inside the nucleus: marked
	for hadron transport modules to act on /
	kIStFinalStateNuclearRemnant = 15, / low energy nuclear fragments
	entering the record collectively as a 'hadronic blob' pseudo-particle /
	kIStNucleonClusterTarget = 16, // for composite nucleons before
	phase space decay
	*/

	int state = kUndefinedState;
	switch (p->Status()) {
	case genie::kIStNucleonTarget:
	case genie::kIStInitialState:
	case genie::kIStCorrelatedNucleon:
	case genie::kIStNucleonClusterTarget:
	state = kInitialState;
	break;

	case genie::kIStStableFinalState:
	state = kFinalState;
	break;

	case genie::kIStHadronInTheNucleus:
	if (abs(mode) == 2)
	state = kInitialState;
	else
	state = kFSIState;
	break;

	case genie::kIStPreDecayResonantState:
	case genie::kIStDISPreFragmHadronicState:
	case genie::kIStIntermediateState:
	state = kFSIState;
	break;

	case genie::kIStFinalStateNuclearRemnant:
	case genie::kIStUndefined:
	case genie::kIStDecayedState:
	default:
	break;
	}

	// Flag to remove nuclear part in genie
	if (p->Pdg() > 1000000) {
	if (state == kInitialState)
	state = kNuclearInitial;
	else if (state == kFinalState)
	state = kNuclearRemnant;
	}

	return state;
	}
	#endif

	#ifdef __GENIE_ENABLED__
	int GENIEInputHandler::ConvertGENIEReactionCode(GHepRecord* gheprec) {

	// Electron Scattering
	if (gheprec->Summary()->ProcInfo().IsEM()) {
	if (gheprec->Summary()->InitState().ProbePdg() == 11) {
	if (gheprec->Summary()->ProcInfo().IsQuasiElastic()) return 1;
	else if (gheprec->Summary()->ProcInfo().IsMEC()) return 2;
	else if (gheprec->Summary()->ProcInfo().IsResonant()) return 13;
	else if (gheprec->Summary()->ProcInfo().IsDeepInelastic()) return 26;
	else {
	ERROR(WRN, "Unknown GENIE Electron Scattering Mode!" << std::endl
	<< "ScatteringTypeId = " << gheprec->Summary()->ProcInfo().ScatteringTypeId() << " "
	<< "InteractionTypeId = " << gheprec->Summary()->ProcInfo().InteractionTypeId() << std::endl
	<< genie::ScatteringType::AsString(gheprec->Summary()->ProcInfo().ScatteringTypeId()) << " "
	<< genie::InteractionType::AsString(gheprec->Summary()->ProcInfo().InteractionTypeId()) << " "
	<< gheprec->Summary()->ProcInfo().IsMEC());
	return 0;
	}
	}

	// Weak CC
	} else if (gheprec->Summary()->ProcInfo().IsWeakCC()) {

	// CC MEC
	if (gheprec->Summary()->ProcInfo().IsMEC()) {
	if (pdg::IsNeutrino(gheprec->Summary()->InitState().ProbePdg())) return 2;
	else if (pdg::IsAntiNeutrino(gheprec->Summary()->InitState().ProbePdg())) return -2;

	// CC OTHER
	} else {
	return utils::ghep::NeutReactionCode(gheprec);
	}

	// Weak NC
	} else if (gheprec->Summary()->ProcInfo().IsWeakNC()) {
	// NC MEC
	if (gheprec->Summary()->ProcInfo().IsMEC()) {
	if (pdg::IsNeutrino(gheprec->Summary()->InitState().ProbePdg())) return 32;
	else if (pdg::IsAntiNeutrino(gheprec->Summary()->InitState().ProbePdg())) return -32;

	// NC OTHER
	} else {
	return utils::ghep::NeutReactionCode(gheprec);
	}
	}

	return 0;
	}

	void GENIEInputHandler::CalcNUISANCEKinematics() {

	// Reset all variables
	fNUISANCEEvent->ResetEvent();

	// Check for GENIE Event
	if (!fGenieNtpl) return;
	if (!fGenieNtpl->event) return;

	// Cast Event Record
	fGenieGHep = static_cast<GHepRecord*>(fGenieNtpl->event);
	if (!fGenieGHep) return;

	// Convert GENIE Reaction Code
	fNUISANCEEvent->fMode = ConvertGENIEReactionCode(fGenieGHep);

	// Set Event Info
	fNUISANCEEvent->Mode = fNUISANCEEvent->fMode;
	fNUISANCEEvent->fEventNo = 0.0;
	fNUISANCEEvent->fTotCrs = fGenieGHep->XSec();
	fNUISANCEEvent->fTargetA = 0.0;
	fNUISANCEEvent->fTargetZ = 0.0;
	fNUISANCEEvent->fTargetH = 0;
	fNUISANCEEvent->fBound = 0.0;
	fNUISANCEEvent->InputWeight = 1.0; //(1E+38 / genie::units::cm2) * fGenieGHep->XSec();

	// Get N Particle Stack
	unsigned int npart = fGenieGHep->GetEntries();
	unsigned int kmax = fNUISANCEEvent->kMaxParticles;
	if (npart > kmax) {
	ERR(WRN) << "GENIE has too many particles, expanding stack." << std::endl;
	fNUISANCEEvent->ExpandParticleStack(npart);
	}

	// Fill Particle Stack
	GHepParticle* p = 0;
	TObjArrayIter iter(fGenieGHep);
	fNUISANCEEvent->fNParticles = 0;

	// Loop over all particles
	while ((p = (dynamic_cast<genie::GHepParticle*>((iter).Next())))) {
	if (!p) continue;

	// Get Status
	int state = GetGENIEParticleStatus(p, fNUISANCEEvent->fMode);

	// Remove Undefined
	if (kRemoveUndefParticles &&
	state == kUndefinedState) continue;

	// Remove FSI
	if (kRemoveFSIParticles &&
	state == kFSIState) continue;

	if (kRemoveNuclearParticles &&
	(state == kNuclearInitial \|\| state == kNuclearRemnant)) continue;

	// Fill Vectors
	int curpart = fNUISANCEEvent->fNParticles;
	fNUISANCEEvent->fParticleState[curpart] = state;

	// Mom
	fNUISANCEEvent->fParticleMom[curpart][0] = p->Px() * 1.E3;
	fNUISANCEEvent->fParticleMom[curpart][1] = p->Py() * 1.E3;
	fNUISANCEEvent->fParticleMom[curpart][2] = p->Pz() * 1.E3;
	fNUISANCEEvent->fParticleMom[curpart][3] = p->E() * 1.E3;

	// PDG
	fNUISANCEEvent->fParticlePDG[curpart] = p->Pdg();

	// Add to N particle count
	fNUISANCEEvent->fNParticles++;

	// Extra Check incase GENIE fails.
	if ((UInt_t)fNUISANCEEvent->fNParticles == kmax) {
	ERR(WRN) << "Number of GENIE Particles exceeds maximum!" << std::endl;
	ERR(WRN) << "Extend kMax, or run without including FSI particles!" << std::endl;
	break;
	}
	}

	// Fill Extra Stack
	if (fSaveExtra) fGenieInfo->FillGeneratorInfo(fGenieNtpl);

	// Run Initial, FSI, Final, Other ordering.
	fNUISANCEEvent-> OrderStack();

	FitParticle* ISNeutralLepton =
	fNUISANCEEvent->GetHMISParticle(PhysConst::pdg_neutrinos);
	if (ISNeutralLepton) {
	fNUISANCEEvent->probe_E = ISNeutralLepton->E();
	fNUISANCEEvent->probe_pdg = ISNeutralLepton->PDG();
	}

	return;
	}

	void GENIEInputHandler::Print() {
	}

	#endif

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