Part2A.C

/* Made by Francesco Vassalli for analysis of PbGl detector for sPHENIX EMCal calibration effort
	 June - October 2018
	 This script takes beam data files in DSTReader format and plots the PbGl energy.  
	 It outputs formatted textfiles with the esstial variables for calculating
	 linearity and resolution 
	 Run in batch mode 
	 needs the frootutils library Francesco.Vassalli@colorado.edu
github:FrancescoVassalli
*/

/* General information:
	 there was two sets of data taking one taken a month earlier both at Fermilab
	 the second test has runNumber>1000*/

#include "NicePlots.C" //code from/in support if frootutils
#include <Scalar.h> //code from/in support if frootutils

#include "TClonesArray.h"
#include "TObject.h"
#include "TH1D.h"
#include "TChain.h"
#include "TF1.h"

#include <TH2.h>
#include <TStyle.h>
#include <TCanvas.h>
#include <TROOT.h>
#include <TChain.h>
#include <TFile.h>

#include <sstream>
#include <queue>
#include <iostream>

/*this include can be direct pathed to your copy of NiceHists which is a condensed 
	version of frootutils that has everything for this project
#include "/Users/Chase/Documents/HeavyIonsResearch/FranTools/Bin/NiceHists.C" 
*/
//from the ATLASStyle package 

using namespace std;

namespace {
	int plotcount=0; //for TNamed naming 
}

void myText(Double_t x,Double_t y,Color_t color, const char *text, Double_t tsize) {
	TLatex l; //l.SetTextAlign(12); 
	l.SetTextSize(tsize); 
	l.SetNDC();
	l.SetTextColor(color);
	l.DrawLatex(x,y,text);
}

	template<class T>
void oleSwitcheroo(T* xp, T* yp)
{
	T temp = *xp;
	*xp = *yp;
	*yp = temp;
}

int runToVoltage(int run);
int runToEnergy(int run);

//classes from NiceHist for plotting 
class PlotWithLine
{
	public:
		virtual void Draw(){
			main->Draw();
		}
		~PlotWithLine(){ // there might be some mem leakage here 
		}
		virtual TH1* get_main(){
			return main;
		}

	protected:
		TH1 *main;

};

class CutPlot :public PlotWithLine{
	public:
		CutPlot(TH1 *main, TLine* cut) : cut(cut){
			this->main  = main;
		}
		~CutPlot(){
			delete cut;
			cut=NULL;
		}
		void Draw(){
			main->Draw();
			cut->Draw("same");
		}
	private:
		TLine *cut;
};

class GausPlot :public PlotWithLine
{
	public:
		GausPlot(TH1* main, TF1* gaus,double lowBound,double upBound) : gaus(gaus),lowBound(lowBound), upBound(upBound){
			this->main  = main;
			fitgaus = new TF1("fitgaus","gaus",lowBound,upBound);
			fitgaus->SetLineColor(kBlue);
			fitgaus->FixParameter(0,gaus->GetParameter(0));
			fitgaus->FixParameter(1,gaus->GetParameter(1));
			fitgaus->FixParameter(2,gaus->GetParameter(2));
		}
		~GausPlot(){
			delete gaus;
			gaus=NULL;
			delete fitgaus;
			fitgaus=NULL;
		}
		void Draw(){
			main->Draw();
			gaus->Draw("same");
			fitgaus->Draw("same");
		}
		TF1* get_gaus(){
			return gaus;
		}
		TF1* get_fitGaus(){
			return fitgaus;
		}
		double getUpBound(){
			return upBound;
		}
		double getMean(){
			return gaus->GetParameter(1);
		}
		double getSigma(){
			return gaus->GetParameter(2);
		}

	private:
		TF1 *gaus;
		TF1 *fitgaus;
		double lowBound;
		double upBound;
};

//this is used by the main to select which files to read 
class RunSelecTOR
{
	public:
		RunSelecTOR(bool newData, bool checkVoltage, int voltage){
			this->voltage=voltage;
			this->newData=newData;
			this->checkVoltage=checkVoltage;
		}
		~RunSelecTOR(){}

		int* operator()(int *runNumber, int* SIZE){
			int *r = new int[*SIZE];
			int j=0;
			if (newData)
			{
				for (int i = 0; i < *SIZE; ++i)
				{
					if ((!checkVoltage||runToVoltage(runNumber[i])==voltage)&&runNumber[i]>1000)
					{
						r[j] = runNumber[i];
						j++;
					}
				}
			}
			else{
				for (int i = 0; i < *SIZE; ++i)
				{
					if ((!checkVoltage||runToVoltage(runNumber[i])==voltage)&&runNumber[i]<1000)
					{
						r[j] = runNumber[i];
						j++;
					}
				}
			}
			*SIZE = j;
			return r;
		}
		std::string getName(){
			if (newData)
			{
				return "PbGl"+std::to_string(voltage)+"new.txt";
			}
			else{
				return "PbGl"+std::to_string(voltage)+".txt";
			}
		}

	private:
		int voltage;
		bool newData;
		bool checkVoltage;
		int runToEnergy(int run){
			int r;
			int s = (int) run;
			switch (s){
				case 558:
					r=6;
					break;
				case 551:
					r= 4;
					break;
				case 563:
					r= 2;
					break;
				case 573:
					r= 12;
					break;
				case 567:
					r= 8;
					break;
				case 776:
					r=2;
					break;
				case 777:
					r=2;
					break;
				case 809:
					r=6;
					break;
				case 810:
					r=4;
					break;
				case 816:
					r=2;
					break;
				case 829:
					r=6;
					break;
				case 830:
					r=2;
					break;
				case 849:
					r=2;
					break;
				case 859:
					r=5;
					break;
				case 900:
					r=1;
					break;
				case 631:
					r=8;
					break;
				case 632:
					r=12;
					break;
				case 544:
					r= 8;
					break;
				case 652:
					r= 16;
					break;
				case 653:
					r= 16;
					break;
				case 654:
					r= 24;
					break;
				case 687:
					r= 28;
					break;
				case 572:
					r= 12;
					break;
				case 574:
					r= 12;
					break;
				case 577:
					r= 2;
					break;
				case 578:
					r= 2;
					break;
				case 579:
					r= 2;
					break;	
				case 580:
					r=2;
					break;
				case 1876:
					r=8; break;
				case 1879:
					r=8; break;
				case 1882:
					r=8; break;
				case 1883:
					r=8; break;
				case 1888:
					r=8; break;
				case 1890:
					r=6; break;
				case 2128:
					r=16; break;
				case 2125:
					r=12; break;
				case 2126:
					r=12; break;
				case 2127:
					r=16; break;
				case 1889:
					r=6; break;
				case 1901:
					r=4; break;
				case 1902:
					r=4; break;
				case 1904:
					r=2; break;
				case 1906:
					r=2; break;
				case 1924:
					r=12; break;
				case 1925:
					r=12; break;
				case 1943:
					r=24; break;
				case 1945:
					r=28; break;
				case 2073:
					r=3; break;
				case 2074:
					r=4; break;
				case 2094:
					r=6; break;
				case 2095:
					r=6; break;
				case 2097:
					r=8; break;
				case 2098:
					r=8; break;
				case 2149:
					r=20; break;
				case 2150:
					r=24; break;
				case 2167:
					r=28; break;
				case 773:
					r=10;
					break;
				case 772:
					r=10;
					break;
				case 1926:
					r=16; 
					break;
				case 2045:
					r=2; 
					break;
				default:
					r=-1;
					cout<<"Error in runToEnergy line:"<<__LINE__<<std::endl;
					break;
			}
			return r;
		}

		int runToVoltage(int run){
			int r;
			int s = (int) run;

			switch (s){
				case 2045:
					r=1200; 
					break;
				case 1926:
					r=1100; 
					break;
				case 2167:
					r=1000; 
					break;
				case 1945:
					r=1000; 
					break;
				case 2150:
					r=1000;
					break;
				case 1943:
					r=1000;
					break;
				case 2149:
					r=1000;
					break;
				case 1924:
					r=1200;
					break;
				case 1925:
					r=1100;
					break;
				case 2125:
					r=1200;
					break;
				case 2126:
					r=1100;
					break;
				case 632:
					r=1100;
					break;
				case 773:
					r=-1;
					break;
				case 772:
					r=-1;
					break;
				case 1901:
					r=1200;
					break;
				case 2074:
					r=1200;
					break;
				case 2094:
					r=1200;
					break;
				case 2095:
					r=1100;
					break;
				case 1889:
					r=1100;
					break;
				case 2127:
					r=1100;
					break;
				case 2128: // probably saturated 
					r=1200;
					break;
				case 2098:
					r=1200;
					break;
				case 1883:
					r=1200;
					break;
				case 1882:
					r=1200;
					break;
				case 1879:
					r=1200;
					break;
				case 1906:
					r=1200;
					break;
				case 900: //undersaturated 
					r=1200;
					break;
				case 1904:
					r=1100;
					break;
				case 2073:
					r=1200;
					break;
				case 1876: //this is a guess 
					r=1100;
					break;
				case 2097:
					r=1100;
					break;
				case 1888:
					r=1100;
					break;
				case 1890:
					r=1200;
					break;
				case 1902:
					r=1100;
					break;
				case 558:
					r=1200;
					break;
				case 551:
					r= 1200;
					break;
				case 563:
					r= 1200;
					break;
				case 573: //saturated
					r= 00;
					break;
				case 567:
					r= 1200;
					break;
				case 776:
					r=1200;
					break;
				case 777:
					r=1200;
					break;
				case 809:
					r=1200;
					break;
				case 810:
					r=1200;
					break;
				case 816: // double check this 
					r=1200;
					break;
				case 829:
					r=1200;
					break;
				case 830:
					r=1200;
					break;
				case 849:
					r=1200;
					break;
				case 859:
					r=1200;
					break;
				case 631: // not in list 
					r=1100; 
					break;
				case 544:
					r= 1100;
					break;
				case 652:
					r= 1100;
					break;
				case 653:
					r= 1000;
					break;
				case 654:
					r= 1000;
					break;
				case 687: // saturated 1100V run  28GeV
					r= 1000;
					break;
				case 572:
					r= 0;
					break;
				case 574:
					r= 1100;
					break;
				case 577:
					r= 1100;
					break;
				case 578:
					r= 1100;
					break;
				case 579:
					r= 1100;
					break;	
				case 580:
					r=1100;
					break;
				default:
					r=0;
					cout<<"warning voltage not found for run:"<<run<<std::endl;
					break;
			}
			return r;
		}
};

/*
This is main workhorse of the file.  All the data is read in from the DSTReader
files and processed in this class.  The main then interfaces with this class to
get the data out.  There should be one instance of this class per file processed
*/
#ifndef OfficalBeamData_h
#define OfficalBeamData_h 
class OfficalBeamData
{
	public:
		OfficalBeamData(){}
		//this constructor makes the TH1Ds and tracks the voltage and energy
		OfficalBeamData(int number, int voltage, float beamEnergy,bool makeSidePlots)
		 : makeSidePlots(makeSidePlots), beamVoltage(voltage), beamEnergy(beamEnergy){
			runNumber = number;
			cout<<"Processing run:"<<runNumber<<endl;
			name = to_string(number);
			const int kNHODO=setHighMultiplicity(); //decides if this event is highMultiplicity
			//set up the constants of the histogram 
			const float kMAX = 10000;
			float bintemp;
			if (beamEnergy>=8&&beamEnergy<=16&&beamVoltage==1100)
			{
				bintemp=450;
			}
			else{
				bintemp=300;
			}
			const float kMainBins = bintemp;
			mainBinWidth = kMAX/kMainBins;
			//this is main plot that will have the final data
			pbglPlot = new TH1D(name.c_str(),"",kMainBins,0,kMAX); 
			pbglPlot->Sumw2();
			//we also record the data with each step of the cutting process
			pbglUnFit = new TH1D(string(name+" no fit").c_str(),"",200,0,10000); 
			pbglNoCut= new TH1D(string(name+"NoCUT").c_str(),"",200,0,10000);
			pbglCCut = new TH1D(string(name+"CCUT").c_str(),"",200,0,10000);
			pbglCVCut = new TH1D(string(name+"CVCUT").c_str(),"",200,0,10000);
			/*the data with different tightness of hodoscope cut are recorded
			the number indicates a nxn hodoscope cut*/
			hodo2=new TH1D (string( name+"hodo2").c_str(),"",70,0,8000);
			hodo4=new TH1D (string( name+"hodo4").c_str(),"",70,0,8000);
			hodo8=new TH1D (string( name+"hodo8").c_str(),"",70,0,8000);
			pbglPlot->Sumw2();
			pbglUnFit->Sumw2();
			pbglCCut->Sumw2();
			pbglCVCut->Sumw2();
			pbglNoCut->Sumw2();
			//declare plots for energy, all veto counters, and hodoscopes counters
			if (makeSidePlots)
			{
				cerenkov = new TH1D(string(name+"ceren").c_str(),"",200,0,10000); 
				p_veto1 = new TH1D(string(name+"veto1").c_str(),"",20,0,2);
				p_veto2 = new TH1D(string(name+"veto2").c_str(),"",20,0,2);
				p_veto3 = new TH1D(string(name+"veto3").c_str(),"",20,0,2);
				p_veto4 = new TH1D(string(name+"veto4").c_str(),"",20,0,2);
				p_hodov1 = new TH1D(string(name+"hodov1").c_str(),"",20,0,2);
				p_hodov2 = new TH1D(string(name+"hodov2").c_str(),"",20,0,2);
				p_hodov3 = new TH1D(string(name+"hodov3").c_str(),"",20,0,2);
				p_hodov4 = new TH1D(string(name+"hodov4").c_str(),"",20,0,2);
				p_hodov5 = new TH1D(string(name+"hodov5").c_str(),"",20,0,2);
				p_hodov6 = new TH1D(string(name+"hodov6").c_str(),"",20,0,2);
				p_hodov7 = new TH1D(string(name+"hodov7").c_str(),"",20,0,2);
				p_hodov8 = new TH1D(string(name+"hodov8").c_str(),"",20,0,2);
				p_hodoh1 = new TH1D(string(name+"hodoh1").c_str(),"",20,0,2);
				p_hodoh2 = new TH1D(string(name+"hodoh2").c_str(),"",20,0,2);
				p_hodoh3 = new TH1D(string(name+"hodoh3").c_str(),"",20,0,2);
				p_hodoh4 = new TH1D(string(name+"hodoh4").c_str(),"",20,0,2);
				p_hodoh5 = new TH1D(string(name+"hodoh5").c_str(),"",20,0,2);
				p_hodoh6 = new TH1D(string(name+"hodoh6").c_str(),"",20,0,2);
				p_hodoh7 = new TH1D(string(name+"hodoh7").c_str(),"",20,0,2);
				p_hodoh8 = new TH1D(string(name+"hodoh8").c_str(),"",20,0,2);

				const int kHODOOFFSET= TMath::Abs(setHodoOffset(kNHODO));
				hodo2d = new TH2D(string(name+"hodo2d").c_str(),"",kNHODO,kHODOOFFSET-.5,kNHODO+kHODOOFFSET-.5,kNHODO ,kHODOOFFSET	-.5,kNHODO+kHODOOFFSET-.5);

			}
		
			//some booleans are recorded for which processes have already been run
			for (int i = 0; i < NUMPLOTS; ++i)
			{
				plotsexits[i]=false;
			}
			//cleaner visual output 
			gStyle->SetOptStat(0);
		}
		//Noting important here
		~OfficalBeamData(){
		 /* I am almost certain I made memory leaks writing this 
		 because ROOT tries to some automatic memory handling that I don't understand
		 but there are no segfaults and there is nothing severe*/
			if(mainGaus!=NULL){
				delete mainGaus;
			}
			if(cut_cerenkov!=NULL) delete cut_cerenkov;
			if(cut_hodov1!=NULL) delete cut_hodov1;
			if(cut_hodov2!=NULL) delete cut_hodov2;
			if(cut_hodov3!=NULL) delete cut_hodov3;
			if(cut_hodov4!=NULL) delete cut_hodov4;
			if(cut_hodov5!=NULL) delete cut_hodov5;
			if(cut_hodov6!=NULL) delete cut_hodov6;
			if(cut_hodov7!=NULL) delete cut_hodov7;
			if(cut_hodov8!=NULL) delete cut_hodov8;
			if(cut_hodoh1!=NULL) delete cut_hodoh1;
			if(cut_hodoh2!=NULL) delete cut_hodoh2;
			if(cut_hodoh3!=NULL) delete cut_hodoh3;
			if(cut_hodoh4!=NULL) delete cut_hodoh4;
			if(cut_hodoh5!=NULL) delete cut_hodoh5;
			if(cut_hodoh6!=NULL) delete cut_hodoh6;
			if(cut_hodoh7!=NULL) delete cut_hodoh7;
			if(cut_hodoh8!=NULL) delete cut_hodoh8;
			if(cut_veto1!=NULL) delete cut_veto1;
			if(cut_veto2!=NULL) delete cut_veto2;
			if(cut_veto3!=NULL) delete cut_veto3;
			if(cut_veto4!=NULL) delete cut_veto4;
			/*if(pbglPlot!=NULL) delete pbglPlot; // these seg fault but also probably mem leak
				if(cerenkov!=NULL) delete cerenkov;
				if(p_hodov1!=NULL) delete p_hodov1;
				if(p_hodov2!=NULL) delete p_hodov2;
				if(p_hodov3!=NULL) delete p_hodov3;
				if(p_hodov4!=NULL) delete p_hodov4;
				if(p_hodov5!=NULL) delete p_hodov5;
				if(p_hodov6!=NULL) delete p_hodov6;
				if(p_hodov7!=NULL) delete p_hodov7;
				if(p_hodov8!=NULL) delete p_hodov8;
				if(p_hodoh1!=NULL) delete p_hodoh1;
				if(p_hodoh2!=NULL) delete p_hodoh2;
				if(p_hodoh3!=NULL) delete p_hodoh3;
				if(p_hodoh4!=NULL) delete p_hodoh4;
				if(p_hodoh5!=NULL) delete p_hodoh5;
				if(p_hodoh6!=NULL) delete p_hodoh6;
				if(p_hodoh7!=NULL) delete p_hodoh7;
				if(p_hodoh8!=NULL) delete p_hodoh8;
				if(p_veto1!=NULL) delete p_veto1;
				if(p_veto2!=NULL) delete p_veto2;
				if(p_veto3!=NULL) delete p_veto3;
				if(p_veto4!=NULL) delete p_veto4;*/
			/*if(hodo2!=NULL) delete hodo2; //maybe root objects delete their members   
				if(hodo4!=NULL) delete hodo4;
				if(hodo8!=NULL) delete hodo8;*/
		}
		/* this is how the DSTReader interfaces with the class all of the data goes 
		in through this function it then puts it into the appropriate historgram
		based on cuts
		returns true if the data was added to the main plot 
		*/
		bool add(double cerenkov, double* veto, double* hhodo, double* vhodo, double pbgl){
			bool r = false;
			//fill all the cut plots with their data 
			if (makeSidePlots)
			{
				this->cerenkov->Fill(cerenkov);
				p_hodoh1->Fill(hhodo[0]);
				p_hodoh2->Fill(hhodo[1]);
				p_hodoh3->Fill(hhodo[2]);
				p_hodoh4->Fill(hhodo[3]);
				p_hodoh5->Fill(hhodo[4]);
				p_hodoh6->Fill(hhodo[5]);
				p_hodoh7->Fill(hhodo[6]);
				p_hodoh8->Fill(hhodo[7]);
				p_hodov1->Fill(vhodo[0]);
				p_hodov2->Fill(vhodo[1]);
				p_hodov3->Fill(vhodo[2]);
				p_hodov4->Fill(vhodo[3]);
				p_hodov5->Fill(vhodo[4]);
				p_hodov6->Fill(vhodo[5]);
				p_hodov7->Fill(vhodo[6]);
				p_hodov8->Fill(vhodo[7]);
				p_veto1->Fill(veto[0]);
				p_veto2->Fill(veto[1]);
				p_veto3->Fill(veto[2]);
				p_veto4->Fill(veto[3]);
				fillhodo2D(hhodo,vhodo);
			}
			
			//here the main plot is filled 
			int pbglCUT;
			/*the low energy points get closer to the minimum ionizing potential peak 
			so I can not cut as much of it out*/
			if (beamEnergy>8)
			{
				pbglCUT=500;
			}
			else{
				pbglCUT=100;
			}
			if (pbgl>pbglCUT)
			{
				pbglNoCut->Fill(pbgl);
				if(passCerenkov((float)cerenkov)){
					pbglCCut->Fill(pbgl);
					if(noVeto(veto)){
						pbglCVCut->Fill(pbgl);
						if (passHodoH(hhodo)&&passHodoV(vhodo)){
							hodo8->Fill(pbgl);
							/*depending on the multiplicity of the event different 
							hodoscope cuts can be set up I use 4x4 for everything 
							in the final plots but other cuts can provide insight*/
							switch(multiplicityType){
								case 0:
									pbglPlot->Fill(pbgl);
									pbglUnFit->Fill(pbgl);
									r=true;
									if (passHodoH4x4(hhodo)&&passHodoV4x4(vhodo))
									{	
										hodo4->Fill(pbgl);
										if (passHodoH2x2(hhodo)&&passHodoV2x2(vhodo))
										{
											hodo2->Fill(pbgl);
										}
									}
									break;
								case 1:
									if (passHodoH4x4(hhodo)&&passHodoV4x4(vhodo))
									{	
										pbglPlot->Fill(pbgl);
										pbglUnFit->Fill(pbgl);
										hodo4->Fill(pbgl);
										r=true;
										if (passHodoH2x2(hhodo)&&passHodoV2x2(vhodo))
										{
											hodo2->Fill(pbgl);
										}
									}
									break;
								case 2:
									if (passHodoH4x4(hhodo)&&passHodoV4x4(vhodo))
									{	
										hodo4->Fill(pbgl);
										if (passHodoH2x2(hhodo)&&passHodoV2x2(vhodo))
										{
											hodo2->Fill(pbgl);
											pbglUnFit->Fill(pbgl);
											pbglPlot->Fill(pbgl);
											r=true;
										}
									}
									break;
								case 3:
									if (passHodoH4x4(hhodo)&&passHodoV4x4(vhodo))
									{	
										hodo4->Fill(pbgl);
										if (passHodoH2x2(hhodo)&&passHodoV2x2(vhodo))
										{
											hodo2->Fill(pbgl);
										}
										else{
											pbglUnFit->Fill(pbgl);
											pbglPlot->Fill(pbgl);
											r=true;
										}
									}
									break;
								default:
									cout<<"Error multiplicityType"<<endl;
									exit(2);
									break;
							}
						}
					}
				}
			}
			return r;
		}
		/*this function can be used to make all the cuts at once but I wouldn't 
		recomend that unless you just want rough fast data*/
		inline bool passCuts(double cerenkov, double* veto, double* vhodo, double* hhodo){
			return passCerenkov((float)cerenkov) && noVeto(veto),passHodoV(vhodo),passHodoH(hhodo);
		}
		//then there are the functions for each cut 
		inline bool noVeto(double* veto){
			if(runNumber<1000){
				return veto[0]<VETOcut && veto[1]<VETOcut && veto[2]<VETOcut && veto[3]<VETOcut;
			}
			else{ // the secod data set has runnumber >1000 and the 4th veto was moved slightly
				return veto[0]<VETOcut && veto[1]<VETOcut && veto[2]<VETOcut && veto[3]<.25;

			}
		}
		//the Cerenkov cut has no signal for >=20GeV events 
		inline bool passCerenkov(float cerenkov){
			if(beamEnergy>=20){
				return true;
			} 
			return cerenkov>CERENKOVcut;
		}
		//the hardcoded values were visually tuned from analyzing the hodoscope signal
		inline bool passHodoV(double* hodo){
			if (beamEnergy>2)
			{
				return hodo[0]>HODOVcut[0] ^ hodo[1]>HODOVcut[1] ^ hodo[2]>HODOVcut[2] ^ hodo[3]>HODOVcut[3] ^ hodo[4]>HODOVcut[4] ^ hodo[5]>HODOVcut[5] ^ hodo[6]>HODOVcut[6] ^ hodo[7]>HODOVcut[7];
			}
			else{
				return hodo[0]>HODOVcut[0]+.05 ^ hodo[1]>HODOVcut[1]+.05 ^ hodo[2]>HODOVcut[2]+.05 ^ hodo[3]>HODOVcut[3]+.05 ^ hodo[4]>HODOVcut[4]+.05 ^ hodo[5]>HODOVcut[5]+.05 ^ hodo[6]>HODOVcut[6]+.05 ^ hodo[7]>HODOVcut[7]+.05;
			}
		}
		inline bool passHodoH(double* hodo){ 
			if (beamEnergy>2)
			{
				return hodo[0]>HODOHcut[0] ^ hodo[1]>HODOHcut[1] ^ hodo[2]>HODOHcut[2] ^ hodo[3]>HODOHcut[3] ^ hodo[4]>HODOHcut[4] ^ hodo[5]>HODOHcut[5] ^ hodo[6]>HODOHcut[6] ^ hodo[7]>HODOHcut[7];
			}
			else{
				return hodo[0]>HODOHcut[0]+.05 ^ hodo[1]>HODOHcut[1]+.05 ^ hodo[2]>HODOHcut[2]+.05 ^ hodo[3]>HODOHcut[3]+.05 ^ hodo[4]>HODOHcut[4]+.05 ^ hodo[5]>HODOHcut[5]+.05 ^ hodo[6]>HODOHcut[6]+.05 ^ hodo[7]>HODOHcut[7]+.05;
			}	
		}
		//might need to tighen the hodo cut in 4x4 for 2GeV runs
		inline bool passHodoV4x4(double* hodo){ //exclusive or 
			return hodo[2]>HODOVcut[2] ^ hodo[3]>HODOVcut[3] ^ hodo[4]>HODOVcut[4] ^ hodo[5]>HODOVcut[5];
		}
		inline bool passHodoH4x4(double* hodo){ //exclusive or 
			return hodo[2]>HODOHcut[2] ^ hodo[3]>HODOHcut[3] ^ hodo[4]>HODOHcut[4] ^ hodo[5]>HODOHcut[5];
		}
		inline bool passHodoV2x2(double* hodo){ //exclusive or 
			return hodo[3]>HODOVcut[3] ^ hodo[4]>HODOVcut[4];
		}
		inline bool passHodoH2x2(double* hodo){ //exclusive or 
			return hodo[3]>HODOHcut[3] ^ hodo[4]>HODOHcut[4];
		}
		inline void fillhodo2D(double* hhodo, double* vhodo){
			//the plot only plots the hodoscopes I am using 
			const int kSCOPES = multiplicityToHodo(multiplicityType);
			//the cuts are slightly different for the second set 
				std::queue<int> trigged_scope_v;
				std::queue<int> trigged_scope_h;
				switch(kSCOPES){
					//default fill values 
					
					case 8:
						for (int i = 0; i < kSCOPES; ++i)
						{
							if (hhodo[i]>HODOHcut[i])
							{
								trigged_scope_h.push(i);
							}
							if (vhodo[i]>HODOVcut[i])
							{
								trigged_scope_v.push(i);
							}
						}
						while(!trigged_scope_v.empty()&&!trigged_scope_h.empty()){
							hodo2d->Fill(trigged_scope_h.front(),trigged_scope_v.front());
							trigged_scope_v.pop();
							trigged_scope_h.pop();
						}
						break;
					case 4:
						{
							const int kHODOOFFSET=2;
							for (int i = kHODOOFFSET; i < kSCOPES+kHODOOFFSET; ++i)
							{
								if (hhodo[i]>HODOHcut[i])
								{
									trigged_scope_h.push(i);
								}
								if (vhodo[i]>HODOVcut[i])
								{
									trigged_scope_v.push(i);
								}
							}
							while(!trigged_scope_v.empty()&&!trigged_scope_h.empty()){
								hodo2d->Fill(trigged_scope_h.front(),trigged_scope_v.front());
								trigged_scope_v.pop();
								trigged_scope_h.pop();
							}
						}
						break;

					case 2:
						{
							const int kHODOOFFSET=4;
							for (int i = kHODOOFFSET; i < kSCOPES+kHODOOFFSET; ++i)
							{
									if (hhodo[i]>HODOHcut[i])
								{
									trigged_scope_h.push(i);
								}
								if (vhodo[i]>HODOVcut[i])
								{
									trigged_scope_v.push(i);
								}
							}
							while(!trigged_scope_v.empty()&&!trigged_scope_h.empty()){
								hodo2d->Fill(trigged_scope_h.front(),trigged_scope_v.front());
								trigged_scope_v.pop();
								trigged_scope_h.pop();
							}
						}
						break;
					default:
						cout<<"Warning bad multiplicity conversion"<<endl;
						break;
				}
	
		}
		//returns the fit to the signal after the cuts 
		TF1* makeGaus(){
			made=true;
			int maxbin = pbglPlot->GetMaximumBin();
			double gausLowBound = pbglPlot->GetBinLowEdge(maxbin);
			double temp = gausLowBound*.3; //sometimes this number needs to be ajusted to make the guas fit well
			double gausUpbound = gausLowBound +temp;
			if(gausUpbound >10000){gausUpbound=10000;} //so that fit doesn't exceed range of histogram
			gausLowBound -= temp; 
			Scalar mygaus[2];
			TF1* gaus; 
			// instead of cherenkov cut I model and subtract the nuclear hadronic background
			if (beamEnergy>=20)
			{
				gaus= noCerenkovFit();
				mygaus[0] = Scalar(gaus->GetParameter(1),gaus->GetParError(1)); //mean
				mygaus[1] = Scalar(gaus->GetParameter(2),gaus->GetParError(2)); //sigma
				mainGaus = new GausPlot(pbglPlot,gaus,4000,10000);
			}
			else{
				gaus= new TF1("gaus","gaus",gausLowBound,gausUpbound);
				const float gausRange = 1.5; //how many rigma the gaussian is fit over
				pbglPlot->Fit(gaus,"QN","",gausLowBound,gausUpbound);       //“R” Use the range specified in the function range
				mygaus[0] = Scalar(gaus->GetParameter(1),gaus->GetParError(1)); //mean
				mygaus[1] = Scalar(gaus->GetParameter(2),gaus->GetParError(2)); //sigma
				recursiveGaus(pbglPlot, gaus, mygaus, gausRange,97);
				gausLowBound=mygaus[0]-(mygaus[1]*gausRange);
				gausUpbound=mygaus[0]+mygaus[1]*gausRange;
				mainGaus = new GausPlot(pbglPlot,gaus,gausLowBound,gausUpbound);
			}
			//I wrap the hist and fit into these PlotWithLine classes 
			pbglPlot->GetXaxis()->SetRangeUser(mygaus[0]-(mygaus[1]*5.0),mygaus[0]+mygaus[1]*5.0);
			gaus->SetLineStyle(1);
			gaus->SetLineWidth(2);
			gaus->SetLineColor(kRed);
			mean = mygaus[0];
			sigma = mygaus[1];
			return gaus;
		}	

		//print a fit to the pbgl and display the parameters indexed in the list
		void printFit(TF1* fit,string filename,std::pair<float,float>* range=NULL,int nTitles=0,int* parameterNums=NULL,string* names=NULL){
			TCanvas* tc = new TCanvas();
			TH1* plot = (TH1*)pbglPlot->Clone("plot");
			TLegend* tl = new TLegend(.75,.75,.95,.95);
			string plottitle= "PbGl Signal Run:"+name+" "+to_string(beamEnergy)+"GeV "+to_string(beamVoltage)+"V;ADC signal;N";
			plot->SetTitle(plottitle.c_str());
			plot->Draw();
			if(range){
				fit->Clone()->Draw("same");
				cout<<"drew mains"<<endl;
				fit->SetRange(range->first,range->second);
				fit->SetLineColor(kBlue);
			}
			fit->Draw("same");
			if (nTitles>0)
			{
				string title="";
				for (int i = nTitles-1; i >=0 ; i--)
				{
					title = names[i]+":"+Form("%0.3f#pm%0.3f",fit->GetParameter(i),fit->GetParError(i))+'\n';
					tl->AddEntry(fit,title.c_str(),"l");
				}
				cout<<"drawing legend"<<endl;
				tl->Draw();
			}
			cout<<"draw range"<<endl;
			tc->SaveAs(filename.c_str());
			if (plot)
			{
				delete plot;
			}
			delete tc;
		}
		string* titleSigmaMean(){
			string *titles = new string[2];
			titles[0]="#sigma";
			titles[1]="#mu";
			return titles;
		}
		TF1* noCerenkovFit(){
			//fit double gaus 
			TH1F *h_work = (TH1F*)pbglPlot->Clone("pbglPlotworking");
			//make single gausses for the guesses
			TF1* backgroundGaus = new TF1("background","gaus",500,10000);	
			TF1* backgroundExpo = new TF1("background2","expo",500,10000);
			TF1* signalGaus = new TF1("rgaus","gaus",4000,10000);
			signalGaus->SetLineColor(kBlue);
			//kinda weird run 
			if(beamEnergy==28){
				signalGaus->SetParLimits(1,6000,7000);
			}
			else{
				signalGaus->SetParLimits(1,4000,9000);
			}

			//for printing
			//int paramNums[]={1,2};

			//make the initial gaussian background fit 
			backgroundGaus->SetParLimits(1,500,10000);
			h_work->Fit(backgroundGaus,"NL","",500,4000);
			//string outname="background1G-"+to_string(runNumber)+".pdf";
			//printFit(backgroundGaus,outname);

			//use it to define the range 
			//std::pair<float,float> expoRange;
			//expoRange.second=4500;
			//expoRange.first=backgroundGaus->GetParameter(1);

			//try and exponential fit
			//h_work->Fit(backgroundExpo,"NL","",expoRange.first,expoRange.second);
			//outname="background1E-"+to_string(runNumber)+".pdf";
			//printFit(backgroundExpo,outname,&expoRange);

			//try fitting the signal with each of the background models 
			h_work->Add(backgroundGaus,-1);
			signalGaus->SetParameter(1,h_work->GetBinLowEdge(h_work->GetMaximumBin()));
			h_work->Fit(signalGaus,"RN");	
			//outname="background2G-"+to_string(runNumber)+".pdf";
			//printFit(signalGaus,outname,NULL,2,paramNums,titleSigmaMean());

			/*h_work->Add(backgroundGaus,1);
			h_work->Add(backgroundExpo,-1);
			h_work->Fit(signalGaus,"RN");	
			outname="background2E-"+to_string(runNumber)+".pdf";*/
			//printFit(signalGaus,outname,NULL,2,paramNums,titleSigmaMean());

			//use the guesses to fit a double gaus 
			/*TF1* doubleGaus = new TF1("doubleGaus","[0]*TMath::Exp(-(x-[1])*(x-[1])/(2*[2]*[2]))+[3]*TMath::Exp(-(x-[4])*(x-[4])	/(2*[5]*[5]))",500,10000);
			doubleGaus->SetParLimits(1,500,10000);
			doubleGaus->SetParLimits(4,signalGaus->GetParameter(1)-2*signalGaus->GetParameter(2),signalGaus->GetParameter(1)+2*signalGaus->GetParameter(2));
			doubleGaus->SetParLimits(3,0,500000);
			doubleGaus->SetParLimits(5,0,6000);
			doubleGaus->SetParameter(1,backgroundGaus->GetParameter(1)); //guess the background peak 
			doubleGaus->SetParameter(2,backgroundGaus->GetParameter(2)); //guess the background width
			doubleGaus->SetParameter(0,backgroundGaus->GetParameter(0)); //guess the background area 
			doubleGaus->SetParameter(3,signalGaus->GetParameter(0)); //guess the signal area 
			doubleGaus->SetParameter(4,signalGaus->GetParameter(1)); //guess the signal peak
			doubleGaus->SetParameter(5,signalGaus->GetParameter(2)); //guess the signal width
			if (runNumber==1945) //for some reason this one won't converge but the signal fit looks good.
			{
				doubleGaus->FixParameter(3,signalGaus->GetParameter(0));
				doubleGaus->FixParameter(4,signalGaus->GetParameter(1));
				doubleGaus->FixParameter(5,signalGaus->GetParameter(2));
				doubleGaus->SetParError(3,signalGaus->GetParError(0));
				doubleGaus->SetParError(4,signalGaus->GetParError(1));
				doubleGaus->SetParError(5,signalGaus->GetParError(2));
			}
			pbglPlot->Fit(doubleGaus,"RMNL");

			outname="background3-"+to_string(runNumber)+".pdf";
			printFit(doubleGaus,outname);*/

			//return the signal
			delete backgroundGaus;
			delete backgroundExpo;
			delete h_work;
			return signalGaus;
		}
		/*this class is insteaded to be run in batch mode 
		many of the following functions are plotting functions which save a plot 
		rather than displaying it*/
		//draws the cut pbgl signal 
		void plot(){ //note there may be a bug where it does not draw properly but it will save properly
			TCanvas *tc = new TCanvas("tc","tc",800,600);
			plotsexits[0]=true;
			pbglPlot->Draw();
			if (!made)makeGaus();
			mainGaus->Draw();
			TLegend* tl = new TLegend(.75,.75,.9,.9);
			tl->AddEntry(mainGaus->get_gaus(),Form("#mu:%0.0f #sigma:%0.0f",mainGaus->getMean(),mainGaus->getSigma()),"l");
			tl->AddEntry(mainGaus->get_fitGaus(),"Fit Range","l");
			tl->Draw();
			string out = name+".pdf";
			tc->Print(out.c_str());
			tc->Close();
			delete tl;
			delete tc;
		}
		//saves the histogram of the main plot
		void SaveMainHist(){
			string outname = name+"-"+to_string(multiplicityType)+"pbglfinal.root";
			pbglPlot->SaveAs(outname.c_str());
		}
		TH1D* getPlot(){
			return pbglPlot;
		}
		GausPlot* getMainPlot(){
			if (!plotsexits[0])
			{
				plotsexits[0]=true;
				TF1 *gaus = makeGaus();
				pbglPlot->SetMarkerSize(.03);
			}
			return mainGaus;
		}
		void plotCerenkov(){
			TCanvas *tc = new TCanvas("tc","tc",800,600);
			plotsexits[1]=true;
			gPad->SetLogy();
			cerenkov->GetXaxis()->SetRangeUser(1,100000);
			cerenkov->Draw();
			cerenkov->SetTitle("Cherenkov Signal;ADC signal;N");
			TLegend *tl = new TLegend(.85,.85,.95,.95);
			TLine *cut = new TLine(CERENKOVcut,0,CERENKOVcut+1,DBL_MAX);
			cut->SetLineWidth(2); cut->SetLineColor(kBlue) ;
			cut->SetLineStyle(9);
			cut->Draw("same");
			tl->AddEntry(cut,"Cut","l");
			tl->Draw();
			if (!cut_cerenkov)
			{
				cut_cerenkov = new CutPlot(cerenkov,cut);
			}
			string out = name+"ceren.pdf";
			tc->Print(out.c_str());
			tc->Close();
			delete tl;
			delete tc;
		}
		void print2DHodo(){
			string title  = "hodo2D"+to_string(runNumber)+".pdf";
			TCanvas *tc = new TCanvas();
			hodo2d->SetTitle(";Horizontal Hodoscope Counts;Vertical Hodoscope Counts");
			hodo2d->Draw("colz");
			tc->SaveAs(title.c_str());
			delete tc;
		}
		void save2DHodo(){
			string title  = "hodo2D"+to_string(runNumber)+"-"+to_string(multiplicityType)+".root";
			hodo2d->SaveAs(title.c_str());
		}
		//prints what the data would look like for each hodo cut 
		void compareHodo(int number){
			TCanvas *tc = new TCanvas();
			gPad->SetLogy();
			makeDifferent(hodo4,1);
			makeDifferent(hodo2,2);
			hodo8->Draw();
			hodo4->Draw("same");
			hodo2->Draw("same");
			/*TLegend *dairy = new TLegend(.6,.6,.9,.9);
				dairy->AddEntry(hodo8,"8x8","l");
				dairy->AddEntry(hodo4,"4x4","l");
				dairy->AddEntry(hodo2,"2x2","l");
				dairy->Draw();*/
			string title  = "hodocompare"+to_string(number)+".pdf";
			tc->Print(title.c_str());
			delete tc;
		}
		CutPlot* getCerenkovPlot(){
			if (!plotsexits[1])
			{
				plotsexits[1]=true;
				TLine *cut =  new TLine(CERENKOVcut,0,CERENKOVcut+1,DBL_MAX);
				cut->SetLineWidth(2); cut->SetLineColor(kBlue) ; cut->SetLineColor(kBlue) ;
				cut->SetLineStyle(9);
				cut_cerenkov = new CutPlot(cerenkov,cut);
			}
			return cut_cerenkov;
		}
		//there are 4 veto counters you can specifiy which one you want 
		void plotVeto(int i){
			switch (i){
				case 1:
					plotVeto1();
					plotsexits[2]=true;
					break;
				case 2: 
					plotVeto2();
					plotsexits[3]=true;
					break;
				case 3: 
					plotVeto3();
					plotsexits[4]=true;
					break;
				case 4: 
					plotVeto4();
					plotsexits[5]=true;
					break;
				default:
					cout<<"invalid plot number: "<<i<<endl;	
			}
		}
		CutPlot* getVetoPlot(int i){
			switch (i){
				case 1:
					if (!plotsexits[2])
					{
						plotsexits[2]=true;
						TLine *cut = new TLine(VETOcut,0,VETOcut+1,DBL_MAX);
						cut->SetLineWidth(2); cut->SetLineColor(kBlue) ; cut->SetLineColor(kBlue) ;
						cut->SetLineStyle(9);
						cut_veto1 = new CutPlot(p_veto1,cut);
					}
					return cut_veto1;
					break;
				case 2: 
					if (!plotsexits[3])
					{
						plotsexits[3]=true;
						TLine *cut =  new TLine(VETOcut,0,VETOcut+1,DBL_MAX);
						cut->SetLineWidth(2); cut->SetLineColor(kBlue) ; cut->SetLineColor(kBlue) ;
						cut->SetLineStyle(9);
						cut_veto2 = new CutPlot(p_veto2,cut);
					}
					return cut_veto2;
					break;
				case 3: 
					if (!plotsexits[4])
					{
						plotsexits[4]=true;
						TLine *cut = new TLine(VETOcut,0,VETOcut+1,DBL_MAX);
						cut->SetLineWidth(2); cut->SetLineColor(kBlue) ; cut->SetLineColor(kBlue) ;
						cut->SetLineStyle(9);
						cut_veto3 = new CutPlot(p_veto3,cut);
					}
					return cut_veto3;
					break;
				case 4: 
					if (!plotsexits[5])
					{
						plotsexits[5]=true;
						TLine *cut;
						if (runNumber<1000)
						{
							cut=new TLine(VETOcut,0,VETOcut+1,DBL_MAX);
						}
						else{
							cut=new TLine(.25,0,VETOcut+1,DBL_MAX);
						}
						cut->SetLineWidth(2); cut->SetLineColor(kBlue) ; cut->SetLineColor(kBlue) ;
						cut->SetLineStyle(9);
						cut_veto4 = new CutPlot(p_veto4,cut);
					}
					return cut_veto4;
					break;
				default:
					cout<<"invalid plot number: "<<i<<endl;	
					return NULL;
			}
		}
		void plotVeto(){ 
			plotVeto1();
			plotVeto2();
			plotVeto3();
			plotVeto4();
			plotsexits[2]=true;
			plotsexits[3]=true;
			plotsexits[4]=true;
			plotsexits[5]=true;
		}
		//there are 8 horizontal hodoscopes you can specify which one you want
		CutPlot* getHodoH(int i){
			switch (i){
				case 1:
					if (!plotsexits[6])
					{
						plotsexits[6]=true;
						TLine *cut = new TLine(HODOHcut[0],0,HODOHcut[0]+1,DBL_MAX);
						cut->SetLineWidth(2); cut->SetLineColor(kBlue) ; cut->SetLineColor(kBlue) ;
						cut->SetLineStyle(9);
						cut_hodoh1 = new CutPlot(p_hodoh1,cut);
					}
					return cut_hodoh1;
					break;
				case 2: 
					if (!plotsexits[7])
					{
						plotsexits[7]=true;
						TLine *cut = new TLine(HODOHcut[1],0,HODOHcut[1]+1,DBL_MAX);
						cut->SetLineWidth(2); cut->SetLineColor(kBlue) ; cut->SetLineColor(kBlue) ;
						cut->SetLineStyle(9);
						cut_hodoh2 = new CutPlot(p_hodoh2,cut);
					}
					return cut_hodoh2;
					break;
				case 3: 
					if (!plotsexits[8])
					{
						plotsexits[8]=true;
						TLine *cut = new TLine(HODOHcut[2],0,HODOHcut[2]+1,DBL_MAX);
						cut->SetLineWidth(2); cut->SetLineColor(kBlue) ; cut->SetLineColor(kBlue) ;
						cut->SetLineStyle(9);
						cut_hodoh3 = new CutPlot(p_hodoh3,cut);
					}
					return cut_hodoh3;
					break;
				case 4: 
					if (!plotsexits[9])
					{
						plotsexits[9]=true;
						TLine *cut = new TLine(HODOHcut[3],0,HODOHcut[3]+1,DBL_MAX);
						cut->SetLineWidth(2); cut->SetLineColor(kBlue) ; cut->SetLineColor(kBlue) ;
						cut->SetLineStyle(9);
						cut_hodoh4 = new CutPlot(p_hodoh4,cut);
					}
					return cut_hodoh4;
					break;
				case 5:
					if (!plotsexits[10])
					{
						plotsexits[10]=true;
						TLine *cut = new TLine(HODOHcut[4],0,HODOHcut[4]+1,DBL_MAX);
						cut->SetLineWidth(2); cut->SetLineColor(kBlue) ; cut->SetLineColor(kBlue) ;
						cut->SetLineStyle(9);
						cut_hodoh5 = new CutPlot(p_hodoh5,cut);
					}
					return cut_hodoh5;
					break;
				case 6: 
					if (!plotsexits[11])
					{
						plotsexits[11]=true;
						TLine *cut = new TLine(HODOHcut[5],0,HODOHcut[5]+1,DBL_MAX);
						cut->SetLineWidth(2); cut->SetLineColor(kBlue) ; cut->SetLineColor(kBlue) ;
						cut->SetLineStyle(9);
						cut_hodoh6 = new CutPlot(p_hodoh6,cut);
					}
					return cut_hodoh6;
					break;
				case 7: 
					if (!plotsexits[12])
					{
						plotsexits[12]=true;
						TLine *cut = new TLine(HODOHcut[6],0,HODOHcut[6]+1,DBL_MAX);
						cut->SetLineWidth(2); cut->SetLineColor(kBlue) ; cut->SetLineColor(kBlue) ;
						cut->SetLineStyle(9);
						cut_hodoh7 = new CutPlot(p_hodoh7,cut);
					}
					return cut_hodoh7;
					break;
				case 8: 
					if (!plotsexits[13])
					{
						plotsexits[13]=true;
						TLine *cut = new TLine(HODOHcut[7],0,HODOHcut[7]+1,DBL_MAX);
						cut->SetLineWidth(2); cut->SetLineColor(kBlue) ; cut->SetLineColor(kBlue) ;
						cut->SetLineStyle(9);
						cut_hodoh8 = new CutPlot(p_hodoh8,cut);
					}
					return cut_hodoh8;
					break;
				default:
					cout<<"invalid plot number: "<<i<<endl;
					return NULL;
			}
		}
		void plotHodoH(int i){
			switch (i){
				case 1:
					plotsexits[6]=true;
					plotHodoh1();
					break;
				case 2: 
					plotHodoh2();
					plotsexits[7]=true;
					break;
				case 3: 
					plotHodoh3();
					plotsexits[8]=true;
					break;
				case 4: 
					plotHodoh4();
					plotsexits[9]=true;
					break;
				case 5:
					plotHodoh5();
					plotsexits[10]=true;
					break;
				case 6: 
					plotHodoh6();
					plotsexits[11]=true;
					break;
				case 7: 
					plotHodoh7();
					plotsexits[12]=true;
					break;
				case 8: 
					plotHodoh8();
					plotsexits[13]=true;
					break;
				default:
					cout<<"invalid plot number: "<<i<<endl;
			}
		}
		void plotHodoH(){ 
			plotHodoh1();
			plotHodoh2();
			plotHodoh3();
			plotHodoh4();
			plotHodoh5();
			plotHodoh6();
			plotHodoh7();
			plotHodoh8();
			plotsexits[12]=true;
			plotsexits[13]=true;
			plotsexits[6]=true;
			plotsexits[7]=true;
			plotsexits[8]=true;
			plotsexits[9]=true;
			plotsexits[10]=true;
			plotsexits[11]=true;
		}
		CutPlot* getHodoV(int i){
			switch (i){
				case 1:
					if (!plotsexits[14])
					{
						plotsexits[14]=true;
						TLine *cut = new TLine(HODOVcut[0],0,HODOVcut[0]+1,DBL_MAX);
						cut->SetLineWidth(2); cut->SetLineColor(kBlue) ; cut->SetLineColor(kBlue) ;
						cut->SetLineStyle(9);
						cut_hodov1 = new CutPlot(p_hodov1,cut);
					}
					return cut_hodov1;
					break;
				case 2: 
					if (!plotsexits[15])
					{
						plotsexits[15]=true;
						TLine *cut = new TLine(HODOVcut[1],0,HODOVcut[1]+1,DBL_MAX);
						cut->SetLineWidth(2); cut->SetLineColor(kBlue) ; cut->SetLineColor(kBlue) ;
						cut->SetLineStyle(9);
						cut_hodov2 = new CutPlot(p_hodov2,cut);
					}
					return cut_hodov2;
					break;
				case 3: 
					if (!plotsexits[16])
					{
						plotsexits[16]=true;
						TLine *cut = new TLine(HODOVcut[2],0,HODOVcut[2]+1,DBL_MAX);
						cut->SetLineWidth(2); cut->SetLineColor(kBlue) ;
						cut->SetLineStyle(9);
						cut_hodov3 = new CutPlot(p_hodov3,cut);
					}
					return cut_hodov3;
					break;
				case 4: 
					if (!plotsexits[17])
					{
						plotsexits[17]=true;
						TLine *cut = new TLine(HODOVcut[3],0,HODOVcut[3]+1,DBL_MAX);
						cut->SetLineWidth(2); cut->SetLineColor(kBlue) ;
						cut->SetLineStyle(9);
						cut_hodov4 = new CutPlot(p_hodov4,cut);
					}
					return cut_hodov4;
					break;
				case 5:
					if (!plotsexits[18])
					{
						plotsexits[18]=true;
						TLine *cut = new TLine(HODOVcut[4],0,HODOVcut[4]+1,DBL_MAX);
						cut->SetLineWidth(2); cut->SetLineColor(kBlue) ;
						cut->SetLineStyle(9);
						cut_hodov5 = new CutPlot(p_hodov5,cut);
					}
					return cut_hodov5;
					break;
				case 6: 
					if (!plotsexits[19])
					{
						plotsexits[19]=true;
						TLine *cut = new TLine(HODOVcut[5],0,HODOVcut[5]+1,DBL_MAX);
						cut->SetLineWidth(2); cut->SetLineColor(kBlue) ;
						cut->SetLineStyle(9);
						cut_hodov6 = new CutPlot(p_hodov6,cut);
					}
					return cut_hodov6;
					break;
				case 7: 
					if (!plotsexits[20])
					{
						plotsexits[20]=true;
						TLine *cut = new TLine(HODOVcut[6],0,HODOVcut[6]+1,DBL_MAX);
						cut->SetLineWidth(2); cut->SetLineColor(kBlue) ;
						cut->SetLineStyle(9);
						cut_hodov7 = new CutPlot(p_hodov7,cut);
					}
					return cut_hodov7;
					break;
				case 8: 
					if (!plotsexits[21])
					{
						plotsexits[21]=true;
						TLine *cut = new TLine(HODOVcut[7],0,HODOVcut[7]+1,DBL_MAX);
						cut->SetLineWidth(2); cut->SetLineColor(kBlue) ;
						cut->SetLineStyle(9);
						cut_hodov8 = new CutPlot(p_hodov8,cut);
					}
					return cut_hodov8;
					break;
				default:
					cout<<"invalid plot number: "<<i<<endl;
					return NULL;
			}
		}

		void plotHodoV(int i){
			switch (i){
				case 1:
					plotHodov1();
					plotsexits[14]=true;
					break;
				case 2: 
					plotHodov2();
					plotsexits[15]=true;
					break;
				case 3: 
					plotHodov3();
					plotsexits[16]=true;
					break;
				case 4: 
					plotHodov4();
					plotsexits[17]=true;
					break;
				case 5:
					plotHodov5();
					plotsexits[18]=true;
					break;
				case 6: 
					plotHodov6();
					plotsexits[19]=true;
					break;
				case 7: 
					plotHodov7();
					plotsexits[20]=true;
					break;
				case 8: 
					plotHodov8();
					plotsexits[21]=true;
					break;
				default:
					cout<<"invalid plot number: "<<i<<endl;
			}
		}
		void plotHodoV(){ //overloaded to plot all 8 horizontal hodo plots
			plotHodov1();
			plotHodov2();
			plotHodov3();
			plotHodov4();
			plotHodov5();
			plotHodov6();
			plotHodov7();
			plotHodov8();
			plotsexits[14]=true;
			plotsexits[15]=true;
			plotsexits[16]=true;
			plotsexits[17]=true;
			plotsexits[18]=true;
			plotsexits[19]=true;
			plotsexits[20]=true;
			plotsexits[21]=true;
		}

		double getResolution(){
			if(!made) makeGaus();
			return (sigma/mean).value;
		}
		double getMean(){
			if(!made) makeGaus();
			return mean.value;
		}
		double getResolutionUncertainty(){
			if(!made) makeGaus();
			return (sigma/mean).uncertainty;
		}
		double getMeanUncertainty(){
			if(!made) makeGaus();
			return TMath::Sqrt(mean.uncertainty*mean.uncertainty+mainBinWidth*mainBinWidth);
		}
		double getSigmaUncertainty(){
			if(!made) makeGaus();
			return sigma.uncertainty;
		}
		double getSigma(){
			if(!made) makeGaus();
			return sigma.value;
		}
		int getEnergy(){
			return beamEnergy;
		}
		void makeAllPlots(){
			getMainPlot();
			getCerenkovPlot();
			getVetoPlot(1);
			getVetoPlot(2);
			getVetoPlot(3);
			getVetoPlot(4);
			getHodoV(1);
			getHodoV(2);
			getHodoV(3);
			getHodoV(4);
			getHodoV(5);
			getHodoV(6);
			getHodoV(7);
			getHodoV(8);
			getHodoH(1);
			getHodoH(2);
			getHodoH(3);
			getHodoH(4);
			getHodoH(5);
			getHodoH(6);
			getHodoH(7);
			getHodoH(8);
		}
		//shows the ratio of the data to the fit 
		void fitPlot(string name){
			TCanvas *tc = new TCanvas();
			TH1 *p_fit = mainGaus->get_main();
			p_fit->Divide(mainGaus->get_gaus());
			p_fit->Draw();
			name+=".pdf";
			tc->Print(name.c_str());
		}
		void printCutPlot(){
			TCanvas *tc = new TCanvas(getNextPlotName(&plotcount).c_str(),"",800,600);
			pbglCCut->SetMarkerSize(.03);
			pbglCVCut->SetMarkerSize(.03);
			pbglUnFit->SetMarkerSize(.03);
			pbglNoCut->SetMarkerSize(.03);
			pbglCCut->SetLineColor(kRed);
			makeDifferent(pbglCVCut,2);
			makeDifferent(pbglNoCut,3);
			gPad->SetLogy();
			TLegend *cutLegend = new TLegend(.7,.6,.9,.9);
			cutLegend->SetBorderSize(0);
			cutLegend->SetFillColorAlpha(kWhite,0);
			pbglNoCut->Draw();
			pbglCCut->Draw("same");
			pbglCVCut->Draw("same");
			pbglUnFit->Draw("same");
			cutLegend->AddEntry(pbglNoCut,"No Cuts","l");
			cutLegend->AddEntry(pbglCCut,"Cherenkov Cut","l");
			cutLegend->AddEntry(pbglCVCut,"Cherenkov+Veto","l");
			cutLegend->AddEntry(pbglUnFit,"All Cuts","l");
			cutLegend->Draw();
			axisTitles(pbglNoCut,"ADC","N");
			string outname = name+"cuts.pdf";
			tc->Print(outname.c_str());
			delete cutLegend;
			delete tc;
		}
		/*make a 24 panel slide with the signal for each counter and the calorimeter
		show the cutting process and record the important values*/
		void makeBigPlot(string name){
			makeAllPlots();
			TCanvas *tc = new TCanvas(getNextPlotName(&plotcount).c_str(),"",800,600);
			tc->Divide(5,5,0.01,0.01);
			tc->cd(23); 
			mainGaus->Draw();
			myText(.6,.8,kBlack,"PbGl E",.16);
			tc->cd(24); 
			/*pbglCCut->GetXaxis()->SetRangeUser(0,mainGaus->getUpBound()*1.25);
				pbglCVCut->GetXaxis()->SetRangeUser(0,mainGaus->getUpBound()*1.25);
				pbglUnFit->GetXaxis()->SetRangeUser(0,mainGaus->getUpBound()*1.25);
				pbglNoCut->GetXaxis()->SetRangeUser(0,mainGaus->getUpBound()*1.25);*/
			pbglCCut->SetMarkerSize(.03);
			pbglCVCut->SetMarkerSize(.03);
			pbglUnFit->SetMarkerSize(.03);
			pbglNoCut->SetMarkerSize(.03);
			makeDifferent(pbglCCut,1); //colors the lines 
			makeDifferent(pbglCVCut,2);
			makeDifferent(pbglNoCut,3);
			gPad->SetLogy();
			TLegend *cutLegend = new TLegend(.2,.2,.8,.8);
			cutLegend->SetBorderSize(0);
			cutLegend->SetFillColorAlpha(kWhite,0);
			pbglNoCut->Draw();
			pbglCCut->Draw("same");
			pbglCVCut->Draw("same");
			pbglUnFit->Draw("same");
			cutLegend->AddEntry(pbglNoCut,"No Cuts","l");
			cutLegend->AddEntry(pbglCCut,"Cherenkov Cut","l");
			cutLegend->AddEntry(pbglCVCut,"Cherenkov+Veto","l");
			cutLegend->AddEntry(pbglUnFit,"All Cuts","l");
			myText(.2,.8,kBlack,"PbGl Cuts",.16);
			tc->cd(25);
			cutLegend->Draw();
			tc->cd(2); gPad->SetLogy();
			cut_cerenkov->Draw();
			myText(.4,.8,kBlack,"Cherenkov Signal",.18);
			tc->cd(3); gPad->SetLogy();
			cut_veto1->Draw();
			myText(.4,.8,kBlack,"Veto1",.18);
			tc->cd(4); gPad->SetLogy();
			cut_veto2->Draw();
			myText(.4,.8,kBlack,"Veto2",.18);
			tc->cd(5); gPad->SetLogy();
			cut_veto3->Draw();
			myText(.4,.8,kBlack,"Veto3",.18);
			tc->cd(6); gPad->SetLogy();
			cut_veto4->Draw();
			myText(.4,.8,kBlack,"Veto4",.18);
			tc->cd(7); gPad->SetLogy();
			cut_hodov1->Draw();
			myText(.4,.8,kBlack,"H-Hodo1",.18);
			tc->cd(8); gPad->SetLogy();
			cut_hodov2->Draw();
			myText(.4,.8,kBlack,"H-Hodo2",.18);
			tc->cd(9); gPad->SetLogy();
			cut_hodov3->Draw();
			myText(.4,.8,kBlack,"H-Hodo3",.18);
			tc->cd(10); gPad->SetLogy();
			cut_hodov4->Draw();
			myText(.4,.8,kBlack,"H-Hodo4",.18);
			tc->cd(11); gPad->SetLogy();
			cut_hodov5->Draw();
			myText(.4,.8,kBlack,"H-Hodo5",.18);
			tc->cd(12); gPad->SetLogy();
			cut_hodov6->Draw();
			myText(.4,.8,kBlack,"H-Hodo6",.18);
			tc->cd(13); gPad->SetLogy();
			cut_hodov7->Draw();
			myText(.4,.8,kBlack,"H-Hodo7",.18);
			tc->cd(14); gPad->SetLogy();
			cut_hodov8->Draw();
			myText(.4,.8,kBlack,"H-Hodo8",.18);
			tc->cd(15); gPad->SetLogy();
			cut_hodoh1->Draw();
			myText(.4,.8,kBlack,"V-Hodo1",.18);
			tc->cd(16); gPad->SetLogy();
			cut_hodoh2->Draw();
			myText(.4,.8,kBlack,"V-Hodo2",.18);
			tc->cd(17); gPad->SetLogy();
			cut_hodoh3->Draw();
			myText(.4,.8,kBlack,"V-Hodo3",.18);
			tc->cd(18); gPad->SetLogy();
			cut_hodoh4->Draw();
			myText(.4,.8,kBlack,"V-Hodo4",.18);
			tc->cd(19); gPad->SetLogy();
			cut_hodoh5->Draw();
			myText(.4,.8,kBlack,"V-Hodo5",.18);
			tc->cd(20); gPad->SetLogy();
			cut_hodoh6->Draw();
			myText(.4,.8,kBlack,"V-Hodo6",.18);
			tc->cd(21); gPad->SetLogy();
			cut_hodoh7->Draw();
			myText(.4,.8,kBlack,"V-Hodo7",.18);
			tc->cd(22); gPad->SetLogy();
			cut_hodoh8->Draw();
			myText(.4,.8,kBlack,"V-Hodo8",.18);
			tc->cd(1);
			myText(.12,.8,kBlack,name.c_str(),.13);
			myText(.12,.6,kBlack,Form("Mean:%0.2f#pm %0.2f",mean.value,mean.uncertainty),.13);
			myText(.12,.4,kBlack,Form("#sigma:%0.2f#pm %0.2f",sigma.value,sigma.uncertainty),.13);
			myText(.12,.2,kBlack,Form("Resolution:%0.3f#pm%0.3f",(sigma/mean).value,(sigma/mean).uncertainty),.11);
			for (int i = 0; i < 25; ++i)
			{
				tc->cd(i+1);
				gPad->SetTopMargin(.01);
				gPad->SetBottomMargin(.06);
				gPad->SetRightMargin(.001);
				gPad->SetLeftMargin(.07);
			}
			name+=".pdf";
			tc->SaveAs(name.c_str());
			tc->Close();
			delete tc;
		}
	private:
		/* these are the cut values which were visually analyzed from the respective
		counter signals*/
		const double CERENKOVcut = 1400; 
		const float VETOcut = .35; 
		const float HODOHcut[8] = {.45,.55,.45,.5,.5,.55,.45,.45}; 
		const float HODOVcut[8] = {.65,.66,.70,.65,.65,.55,.60,.60};
		const int VETOSIZE = 4;
		const int HODOSIZE = 8;

		//run level information 
		int beamVoltage;
		int beamEnergy;
		int multiplicityType;
		string name; // a descriptive class name used for printing 
		int runNumber=0;
		float mainBinWidth;

		bool makeSidePlots;

		//pointers for all the plots 
		TH1D *pbglPlot=NULL; // the main data plot that gets fit 
		TH1D *cerenkov=NULL; // the signal from the cherenkov counter 
		TH1D *p_hodov1=NULL; // signal from hodo 
		TH1D *p_hodov2=NULL;
		TH1D *p_hodov3=NULL;
		TH1D *p_hodov4=NULL;
		TH1D *p_hodov5=NULL;
		TH1D *p_hodov6=NULL;
		TH1D *p_hodov7=NULL;
		TH1D *p_hodov8=NULL;
		TH1D *p_hodoh1=NULL;
		TH1D *p_hodoh2=NULL;
		TH1D *p_hodoh3=NULL;
		TH1D *p_hodoh4=NULL;
		TH1D *p_hodoh5=NULL;
		TH1D *p_hodoh6=NULL;
		TH1D *p_hodoh7=NULL;
		TH1D *p_hodoh8=NULL;
		TH1D *p_veto1=NULL; // signal from veto
		TH1D *p_veto2=NULL;
		TH1D *p_veto3=NULL;
		TH1D *p_veto4=NULL;

		TH1D *pbglCCut=NULL; //pbgl energy after cherenkov cut 
		TH1D *pbglCVCut=NULL;//pbgl energy after cherenkov and veto cut 
		TH1D *pbglNoCut=NULL; //pbgl energy without cuts 
		TH1D *pbglUnFit=NULL; //the main plot but does not get fit to a guassian 
		TH1D *hodo2=NULL; // the final plot with nxn hodo cuts 
		TH1D *hodo4=NULL;
		TH1D *hodo8=NULL;

		TH2D *hodo2d=NULL;

		GausPlot *mainGaus=NULL; //combined class of the main plot and its gaussian 
		CutPlot *cut_cerenkov=NULL; // combined class of the cherenkov signal and the line showing the cut 
		CutPlot *cut_hodov1=NULL; // combined class of the hodo signal  and the line showing the cut
		CutPlot *cut_hodov2=NULL;
		CutPlot *cut_hodov3=NULL;
		CutPlot *cut_hodov4=NULL;
		CutPlot *cut_hodov5=NULL;
		CutPlot *cut_hodov6=NULL;
		CutPlot *cut_hodov7=NULL;
		CutPlot *cut_hodov8=NULL;
		CutPlot *cut_hodoh1=NULL;
		CutPlot *cut_hodoh2=NULL;
		CutPlot *cut_hodoh3=NULL;
		CutPlot *cut_hodoh4=NULL;
		CutPlot *cut_hodoh5=NULL;
		CutPlot *cut_hodoh6=NULL;
		CutPlot *cut_hodoh7=NULL;
		CutPlot *cut_hodoh8=NULL;
		CutPlot *cut_veto1=NULL; // combined class of the veto signal  and the line showing the cut
		CutPlot *cut_veto2=NULL;
		CutPlot *cut_veto3=NULL;
		CutPlot *cut_veto4=NULL;

		//internal booleans for tracking what values have been initialized 
		bool made=false; 
		bool hasEnergy=false;
		static const int NUMPLOTS=22;
		bool plotsexits[NUMPLOTS]; // to track if the plots have been made first the main then the cerenkov then the veto then the vhodo then the hhodo

		//the important results of the class 
		Scalar mean;
		Scalar sigma;

		/*this sets the tightness of the hodoscope cut for each beam energy
		0=8x8, 1=4x4, 2=2x2, 3=4x4-2x2 (to check leakage)*/
		inline int setHighMultiplicity(){
			if(beamEnergy>2){
				multiplicityType=1;
			}
			else{
				multiplicityType=1;	
			}
			return multiplicityToHodo(multiplicityType);
		}
		inline int setHodoOffset(int nHodo){
			switch(nHodo){
				case 8:
					return 0;
					break;
				case 4:
					return 2;
					break;
				case 2:
					return 4;
					break;
				case 3:
					return -2;
						break;
				default:
					cout<<"warning: invalid hodo offset"<<endl;
					return 0;
					break;
			}
		}
		inline int multiplicityToHodo(int multiplicityType){
			switch(multiplicityType){
				case 0:
					return 8;
					break;
				case 1:
					return 4;
					break;
				case 2:
					return 2;
					break;
				case 3:
					return 4;
					break;
				default:
					cout<<"Warning bad multiplicity conversion"<<endl;
					return 0;
					break;
			}
		}

		void recursiveGaus(TH1* h, TF1* gaus, Scalar* data, float sigmadistance,int lazyMan=0){
			h->Fit(gaus,"QN","",data[0]-data[1]*sigmadistance,data[0]+data[1]*sigmadistance);
			if(data[0]!=gaus->GetParameter(1)){
				if(lazyMan == 100){return;}
				data[0] = Scalar(gaus->GetParameter(1),gaus->GetParError(1));
				data[1] = Scalar(gaus->GetParameter(2),gaus->GetParError(2));
				lazyMan++;
				recursiveGaus(h,gaus,data,sigmadistance,lazyMan);
			}
			else{
				data[0] = Scalar(gaus->GetParameter(1),gaus->GetParError(1));
				data[1] = Scalar(gaus->GetParameter(2),gaus->GetParError(2));
				return;
			}
		}

		//more plotting functions
		void plotVeto1(){
			TCanvas *v1 = new TCanvas("v1","tc",800,600);
			gPad->SetLogy();
			p_veto1->Draw();
			TLine *cut = new TLine(VETOcut,0,VETOcut+1,DBL_MAX);
			cut->Draw("same");
			cut->SetLineWidth(2); cut->SetLineColor(kBlue) ;
			cut->SetLineStyle(9);
			string plottitle= "Run:"+name+" veto1 Signal; ADC signal;N";
			p_veto1->SetTitle(plottitle.c_str());
			cut_veto1 = new CutPlot(p_veto1,cut);
			string out = name+"veto1.pdf";
			v1->Print(out.c_str());
			v1->Close();
			delete v1;
		}
		void plotHodoh1(){
			TCanvas *hh1 = new TCanvas("hh1","tc",800,600);
			gPad->SetLogy();
			p_hodoh1->Draw();
			TLine *cut = new TLine(HODOHcut[0],0,HODOHcut[0]+1,DBL_MAX);
			cut->Draw("same");
			cut->SetLineWidth(2); cut->SetLineColor(kBlue) ;
			cut->SetLineStyle(9);
			string plottitle= "Run:"+name+" hodoh1 Signal; ADC signal;N";
			p_hodoh1->SetTitle(plottitle.c_str());
			cut_hodoh1 = new CutPlot(p_hodoh1 ,cut);
			string out = name+"hodoh1.pdf";
			hh1->Print(out.c_str());
			hh1->Close();
			delete hh1;
		}
		void plotVeto2(){
			TCanvas *v2 = new TCanvas("v2","tc",800,600);
			gPad->SetLogy();
			p_veto1->Draw();
			TLine *cut = new TLine(VETOcut,0,VETOcut+1,DBL_MAX);
			cut->Draw("same");
			cut->SetLineWidth(2); cut->SetLineColor(kBlue) ;
			cut->SetLineStyle(9);
			axisTitles(p_veto2,"calibrated veto2 energy","count");
			cut_veto2 = new CutPlot(p_veto2,cut);
			string out = name+"veto2.pdf";
			v2->Print(out.c_str());
			v2->Close();
			delete v2;
		}
		void plotHodoh2(){
			TCanvas *hh2 = new TCanvas("hh2","tc",800,600);
			gPad->SetLogy();
			p_hodoh2->Draw();
			TLine *cut = new TLine(HODOHcut[1],0,HODOHcut[1]+1,DBL_MAX);
			cut->Draw("same");
			cut->SetLineWidth(2); cut->SetLineColor(kBlue) ;
			cut->SetLineStyle(9);
			axisTitles(p_hodoh2,"calibrated hodoscope h2 energy","count");
			cut_hodoh2 = new CutPlot(p_hodoh2,cut);
			string out = name+"hodoh2.pdf";
			hh2->Print(out.c_str());
			hh2->Close();delete hh2;
		}
		void plotVeto3(){
			TCanvas *v3 = new TCanvas("v3","tc",800,600);
			gPad->SetLogy();
			p_veto3->Draw();
			TLine *cut = new TLine(VETOcut,0,VETOcut+1,DBL_MAX);
			cut->Draw("same");
			cut->SetLineWidth(2); cut->SetLineColor(kBlue) ;
			cut->SetLineStyle(9);
			axisTitles(p_veto3,"calibrated veto3 energy","count");
			cut_veto3 = new CutPlot(p_veto3,cut);
			string out = name+"veto3.pdf";
			v3->Print(out.c_str());
			v3->Close();delete v3;
		}
		void plotHodoh3(){
			TCanvas *hh3 = new TCanvas("hh3","tc",800,600);
			gPad->SetLogy();
			p_hodoh3->Draw();
			TLine *cut = new TLine(HODOHcut[2],0,HODOHcut[2]+1,DBL_MAX);
			cut->Draw("same");
			cut->SetLineWidth(2); cut->SetLineColor(kBlue) ;
			cut->SetLineStyle(9);
			axisTitles(p_hodoh3,"calibrated hodoscope h3 energy","count");
			cut_hodoh3 = new CutPlot(p_hodoh3,cut);
			string out = name+"hodoh3.pdf";
			hh3->Print(out.c_str());
			hh3->Close();delete hh3;
		}

		void plotVeto4(){
			TCanvas *v4 = new TCanvas("v4","tc",800,600);
			gPad->SetLogy();
			p_veto4->Draw();
			TLine *cut = new TLine(VETOcut,0,VETOcut+1,DBL_MAX);
			cut->Draw("same");
			cut->SetLineWidth(2); cut->SetLineColor(kBlue) ;
			cut->SetLineStyle(9);
			axisTitles(p_veto4,"calibrated veto4 energy","count");
			cut_veto3 = new CutPlot(p_veto3,cut);
			string out = name+"veto4.pdf";
			v4->Print(out.c_str());
			v4->Close();delete v4;
		}
		void plotHodoh4(){
			TCanvas *hh4 = new TCanvas("hh4","tc",800,600);
			gPad->SetLogy();
			p_hodoh4->Draw();
			TLine *cut = new TLine(HODOHcut[3],0,HODOHcut[3]+1,DBL_MAX);
			cut->Draw("same");
			cut->SetLineWidth(2); cut->SetLineColor(kBlue) ;
			cut->SetLineStyle(9);
			axisTitles(p_hodoh4,"calibrated hodoscope h4 energy","count");
			cut_hodoh4 = new CutPlot(p_hodoh4,cut);
			string out = name+"hodoh4.pdf";
			hh4->Print(out.c_str());
			hh4->Close();delete hh4;
		}
		void plotHodoh5(){
			TCanvas *hh5 = new TCanvas("hh5","tc",800,600);
			gPad->SetLogy();
			p_hodoh5->Draw();
			TLine *cut = new TLine(HODOHcut[4],0,HODOHcut[4]+1,DBL_MAX);
			cut->Draw("same");
			cut->SetLineWidth(2); cut->SetLineColor(kBlue) ;
			cut->SetLineStyle(9);
			axisTitles(p_hodoh5,"calibrated hodoscope h5 energy","count");
			cut_hodoh5 = new CutPlot(p_hodoh5,cut);
			string out = name+"hodoh5.pdf";
			hh5->Print(out.c_str());
			hh5->Close();delete hh5;
		}
		void plotHodoh6(){
			TCanvas *hh6 = new TCanvas("hh6","tc",800,600);
			gPad->SetLogy();
			p_hodoh6->Draw();
			TLine *cut = new TLine(HODOHcut[5],0,HODOHcut[5]+1,DBL_MAX);
			cut->Draw("same");
			cut->SetLineWidth(2); cut->SetLineColor(kBlue) ;
			cut->SetLineStyle(9);
			axisTitles(p_hodoh6,"calibrated hodoscope h6 energy","count");
			cut_hodoh6 = new CutPlot(p_hodoh6,cut);
			string out = name+"hodoh6.pdf";
			hh6->Print(out.c_str());
			hh6->Close();delete hh6;
		}
		void plotHodoh7(){
			TCanvas *hh7 = new TCanvas("hh7","tc",800,600);
			gPad->SetLogy();
			p_hodoh7->Draw();
			TLine *cut = new TLine(HODOHcut[6],0,HODOHcut[6]+1,DBL_MAX);
			cut->Draw("same");
			cut->SetLineWidth(2); cut->SetLineColor(kBlue) ;
			cut->SetLineStyle(9);
			axisTitles(p_hodoh7,"calibrated hodoscope h7 energy","count");
			cut_hodoh7 = new CutPlot(p_hodoh7,cut);
			string out = name+"hodoh7.pdf";
			hh7->Print(out.c_str());
			hh7->Close();delete hh7;
		}
		void plotHodoh8(){
			TCanvas *hh8 = new TCanvas("hh8","tc",800,600);
			gPad->SetLogy();
			p_hodoh8->Draw();
			TLine *cut = new TLine(HODOHcut[7],0,HODOHcut[7]+1,DBL_MAX);
			cut->Draw("same");
			cut->SetLineWidth(2); cut->SetLineColor(kBlue) ;
			cut->SetLineStyle(9);
			axisTitles(p_hodoh8,"calibrated hodoscope h8 energy","count");
			cut_hodoh8 = new CutPlot(p_hodoh8,cut);
			string out = name+"hodoh8.pdf";
			hh8->Print(out.c_str());
			hh8->Close();delete hh8;
		}
		void plotHodov1(){
			TCanvas *hv1 = new TCanvas("hv1","tc",800,600);
			gPad->SetLogy();
			p_hodov1->Draw();
			TLine *cut = new TLine(HODOVcut[0],0,HODOVcut[0]+1,DBL_MAX);
			cut->Draw("same");
			cut->SetLineWidth(2); cut->SetLineColor(kBlue) ;
			cut->SetLineStyle(9);
			axisTitles(p_hodov1,"calibrated hodoscope v1 energy","count");
			cut_hodov1 = new CutPlot(p_hodov1,cut);
			string out = name+"hodov1.pdf";
			hv1->Print(out.c_str());
			hv1->Close();delete hv1;
		}
		void plotHodov2(){
			TCanvas *hv2 = new TCanvas("hv2","tc",800,600);
			gPad->SetLogy();
			p_hodov2->Draw();
			TLine *cut = new TLine(HODOVcut[1],0,HODOVcut[1]+1,DBL_MAX);
			cut->Draw("same");
			cut->SetLineWidth(2); cut->SetLineColor(kBlue) ;
			cut->SetLineStyle(9);
			axisTitles(p_hodov2,"calibrated hodoscope v2 energy","count");
			cut_hodov2 = new CutPlot(p_hodov2,cut);
			string out = name+"hodov2.pdf";
			hv2->Print(out.c_str());
			hv2->Close();delete hv2;
		}
		void plotHodov3(){
			TCanvas *hv3 = new TCanvas("hv3","tc",800,600);
			gPad->SetLogy();
			p_hodov3->Draw();
			TLine *cut = new TLine(HODOVcut[2],0,HODOVcut[2]+1,DBL_MAX);
			cut->Draw("same");
			cut->SetLineWidth(2); cut->SetLineColor(kBlue) ;
			cut->SetLineStyle(9);
			axisTitles(p_hodov3,"calibrated hodoscope v3 energy","count");
			cut_hodov3 = new CutPlot(p_hodov3,cut);
			string out = name+"hodov3.pdf";
			hv3->Print(out.c_str());
			hv3->Close();delete hv3;
		}
		void plotHodov4(){
			TCanvas *hv4 = new TCanvas("hv4","tc",800,600);
			gPad->SetLogy();
			p_hodov4->Draw();
			TLine *cut = new TLine(HODOVcut[3],0,HODOVcut[3]+1,DBL_MAX);
			cut->Draw("same");
			cut->SetLineWidth(2); cut->SetLineColor(kBlue) ;
			cut->SetLineStyle(9);
			axisTitles(p_hodov4,"calibrated hodoscope v4 energy","count");
			cut_hodov4 = new CutPlot(p_hodov4,cut);
			string out = name+"hodov4.pdf";
			hv4->Print(out.c_str());
			hv4->Close();delete hv4;
		}
		void plotHodov5(){
			TCanvas *hv5 = new TCanvas("hv5","tc",800,600);
			gPad->SetLogy();
			p_hodov5->Draw();
			TLine *cut = new TLine(HODOVcut[4],0,HODOVcut[4]+1,DBL_MAX);
			cut->Draw("same");
			cut->SetLineWidth(2); cut->SetLineColor(kBlue) ;
			cut->SetLineStyle(9);
			axisTitles(p_hodov5,"calibrated hodoscope v5 energy","count");
			cut_hodov5 = new CutPlot(p_hodov5,cut);
			string out = name+"hodov5.pdf";
			hv5->Print(out.c_str());
			hv5->Close();delete hv5;
		}
		void plotHodov6(){
			TCanvas *hv6 = new TCanvas("hv6","tc",800,600);
			gPad->SetLogy();
			p_hodov6->Draw();
			TLine *cut = new TLine(HODOVcut[5],0,HODOVcut[5]+1,DBL_MAX);
			cut->Draw("same");
			cut->SetLineWidth(2); cut->SetLineColor(kBlue) ;
			cut->SetLineStyle(9);
			axisTitles(p_hodov6,"calibrated hodoscope v6 energy","count");
			cut_hodov6 = new CutPlot(p_hodov6,cut);
			string out = name+"hodov6.pdf";
			hv6->Print(out.c_str());
			hv6->Close();delete hv6;
		}
		void plotHodov7(){
			TCanvas *hv7 = new TCanvas("hv7","tc",800,600);
			gPad->SetLogy();
			p_hodov7->Draw();
			TLine *cut = new TLine(HODOVcut[6],0,HODOVcut[6]+1,DBL_MAX);
			cut->Draw("same");
			cut->SetLineWidth(2); cut->SetLineColor(kBlue) ;
			cut->SetLineStyle(9);
			axisTitles(p_hodov7,"calibrated hodoscope v7 energy","count");
			cut_hodov7 = new CutPlot(p_hodov7,cut);
			string out = name+"hodov7.pdf";
			hv7->Print(out.c_str());
			hv7->Close();delete hv7;
		}
		void plotHodov8(){
			TCanvas *hv8 = new TCanvas("hv8","tc",800,600);
			gPad->SetLogy();
			p_hodov8->Draw();
			TLine *cut = new TLine(HODOVcut[7],0,HODOVcut[7]+1,DBL_MAX);
			cut->Draw("same");
			cut->SetLineWidth(2); cut->SetLineColor(kBlue) ;
			cut->SetLineStyle(9);
			axisTitles(p_hodov8,"calibrated hodoscope v8 energy","count");
			cut_hodov8 = new CutPlot(p_hodov8,cut);
			string out = name+"hodov8.pdf";
			hv8->Print(out.c_str());
			hv8->Close();delete hv8;
		}
};
#endif

class DSTReader551 {

	//////////////////////////////////////////////////////////
	// This class has been automatically generated on
	// Tue Jun 26 12:53:58 2018 by ROOT version 6.10/02
	// from TTree T/Prototype4DSTReader
	// found on file: beam_00000551-0000_DSTReader.root
	//////////////////////////////////////////////////////////


	public :
		TTree          *fChain;   //!pointer to the analyzed TTree or TChain
		Int_t           fCurrent; //!current Tree number in a TChain

		// Fixed size dimensions of array or collections stored in the TTree if any.
		static constexpr Int_t kMaxTOWER_RAW_LG_HCALIN = 16;
		static constexpr Int_t kMaxTOWER_RAW_LG_HCALOUT = 16;
		static constexpr Int_t kMaxTOWER_RAW_HG_HCALOUT = 16;
		static constexpr Int_t kMaxTOWER_CALIB_LG_HCALIN = 16;
		static constexpr Int_t kMaxTOWER_CALIB_LG_HCALOUT = 16;
		static constexpr Int_t kMaxTOWER_CALIB_HG_HCALOUT = 16;
		static constexpr Int_t kMaxTOWER_RAW_CEMC = 64;
		static constexpr Int_t kMaxTOWER_CALIB_CEMC = 64;
		static constexpr Int_t kMaxTOWER_RAW_HODO_VERTICAL = 8;
		static constexpr Int_t kMaxTOWER_RAW_HODO_HORIZONTAL = 8;
		static constexpr Int_t kMaxTOWER_CALIB_HODO_VERTICAL = 8;
		static constexpr Int_t kMaxTOWER_CALIB_HODO_HORIZONTAL = 8;
		static constexpr Int_t kMaxTOWER_RAW_C1 = 1;
		static constexpr Int_t kMaxTOWER_CALIB_C1 = 1;
		static constexpr Int_t kMaxTOWER_RAW_C2 = 3;
		static constexpr Int_t kMaxTOWER_CALIB_C2 = 3;
		static constexpr Int_t kMaxTOWER_RAW_PbGL = 1;
		static constexpr Int_t kMaxTOWER_CALIB_PbGL = 1;
		static constexpr Int_t kMaxTOWER_RAW_TRIGGER_VETO = 4;
		static constexpr Int_t kMaxTOWER_CALIB_TRIGGER_VETO = 4;
		static constexpr Int_t kMaxTOWER_RAW_TILE_MAPPER = 16;
		static constexpr Int_t kMaxTOWER_CALIB_TILE_MAPPER = 16;
		static constexpr Int_t kMaxTOWER_RAW_SC3 = 1;
		static constexpr Int_t kMaxTOWER_CALIB_SC3 = 1;
		static constexpr Int_t kMaxTOWER_RAW_FINGER_COUNTER = 1;
		static constexpr Int_t kMaxTOWER_CALIB_FINGER_COUNTER = 1;

		// Declaration of leaf types
		Double_t        beam_MTNRG_GeV;
		Double_t        beam_2CH_mm;
		Double_t        beam_2CV_mm;
		Double_t        EMCAL_A0_HighGain;
		Double_t        EMCAL_GR0_BiasOffset_Tower21;
		Double_t        EMCAL_T0_Tower21;
		Double_t        EMCAL_Is_HighEta;
		Int_t           n_TOWER_RAW_LG_HCALIN;
		Int_t           TOWER_RAW_LG_HCALIN_;
		UInt_t          TOWER_RAW_LG_HCALIN_fUniqueID[kMaxTOWER_RAW_LG_HCALIN];   //[TOWER_RAW_LG_HCALIN_]
		UInt_t          TOWER_RAW_LG_HCALIN_fBits[kMaxTOWER_RAW_LG_HCALIN];   //[TOWER_RAW_LG_HCALIN_]
		UInt_t          TOWER_RAW_LG_HCALIN_towerid[kMaxTOWER_RAW_LG_HCALIN];   //[TOWER_RAW_LG_HCALIN_]
		Double_t        TOWER_RAW_LG_HCALIN_energy[kMaxTOWER_RAW_LG_HCALIN];   //[TOWER_RAW_LG_HCALIN_]
		Float_t         TOWER_RAW_LG_HCALIN_time[kMaxTOWER_RAW_LG_HCALIN];   //[TOWER_RAW_LG_HCALIN_]
		Float_t         TOWER_RAW_LG_HCALIN_signal_samples[kMaxTOWER_RAW_LG_HCALIN][31];   //[TOWER_RAW_LG_HCALIN_]
		Int_t           TOWER_RAW_LG_HCALIN_HBD_channel[kMaxTOWER_RAW_LG_HCALIN];   //[TOWER_RAW_LG_HCALIN_]
		Int_t           n_TOWER_RAW_LG_HCALOUT;
		Int_t           TOWER_RAW_LG_HCALOUT_;
		UInt_t          TOWER_RAW_LG_HCALOUT_fUniqueID[kMaxTOWER_RAW_LG_HCALOUT];   //[TOWER_RAW_LG_HCALOUT_]
		UInt_t          TOWER_RAW_LG_HCALOUT_fBits[kMaxTOWER_RAW_LG_HCALOUT];   //[TOWER_RAW_LG_HCALOUT_]
		UInt_t          TOWER_RAW_LG_HCALOUT_towerid[kMaxTOWER_RAW_LG_HCALOUT];   //[TOWER_RAW_LG_HCALOUT_]
		Double_t        TOWER_RAW_LG_HCALOUT_energy[kMaxTOWER_RAW_LG_HCALOUT];   //[TOWER_RAW_LG_HCALOUT_]
		Float_t         TOWER_RAW_LG_HCALOUT_time[kMaxTOWER_RAW_LG_HCALOUT];   //[TOWER_RAW_LG_HCALOUT_]
		Float_t         TOWER_RAW_LG_HCALOUT_signal_samples[kMaxTOWER_RAW_LG_HCALOUT][31];   //[TOWER_RAW_LG_HCALOUT_]
		Int_t           TOWER_RAW_LG_HCALOUT_HBD_channel[kMaxTOWER_RAW_LG_HCALOUT];   //[TOWER_RAW_LG_HCALOUT_]
		Int_t           n_TOWER_RAW_HG_HCALOUT;
		Int_t           TOWER_RAW_HG_HCALOUT_;
		UInt_t          TOWER_RAW_HG_HCALOUT_fUniqueID[kMaxTOWER_RAW_HG_HCALOUT];   //[TOWER_RAW_HG_HCALOUT_]
		UInt_t          TOWER_RAW_HG_HCALOUT_fBits[kMaxTOWER_RAW_HG_HCALOUT];   //[TOWER_RAW_HG_HCALOUT_]
		UInt_t          TOWER_RAW_HG_HCALOUT_towerid[kMaxTOWER_RAW_HG_HCALOUT];   //[TOWER_RAW_HG_HCALOUT_]
		Double_t        TOWER_RAW_HG_HCALOUT_energy[kMaxTOWER_RAW_HG_HCALOUT];   //[TOWER_RAW_HG_HCALOUT_]
		Float_t         TOWER_RAW_HG_HCALOUT_time[kMaxTOWER_RAW_HG_HCALOUT];   //[TOWER_RAW_HG_HCALOUT_]
		Float_t         TOWER_RAW_HG_HCALOUT_signal_samples[kMaxTOWER_RAW_HG_HCALOUT][31];   //[TOWER_RAW_HG_HCALOUT_]
		Int_t           TOWER_RAW_HG_HCALOUT_HBD_channel[kMaxTOWER_RAW_HG_HCALOUT];   //[TOWER_RAW_HG_HCALOUT_]
		Int_t           n_TOWER_CALIB_LG_HCALIN;
		Int_t           TOWER_CALIB_LG_HCALIN_;
		UInt_t          TOWER_CALIB_LG_HCALIN_fUniqueID[kMaxTOWER_CALIB_LG_HCALIN];   //[TOWER_CALIB_LG_HCALIN_]
		UInt_t          TOWER_CALIB_LG_HCALIN_fBits[kMaxTOWER_CALIB_LG_HCALIN];   //[TOWER_CALIB_LG_HCALIN_]
		UInt_t          TOWER_CALIB_LG_HCALIN_towerid[kMaxTOWER_CALIB_LG_HCALIN];   //[TOWER_CALIB_LG_HCALIN_]
		Double_t        TOWER_CALIB_LG_HCALIN_energy[kMaxTOWER_CALIB_LG_HCALIN];   //[TOWER_CALIB_LG_HCALIN_]
		Float_t         TOWER_CALIB_LG_HCALIN_time[kMaxTOWER_CALIB_LG_HCALIN];   //[TOWER_CALIB_LG_HCALIN_]
		Float_t         TOWER_CALIB_LG_HCALIN_signal_samples[kMaxTOWER_CALIB_LG_HCALIN][31];   //[TOWER_CALIB_LG_HCALIN_]
		Int_t           TOWER_CALIB_LG_HCALIN_HBD_channel[kMaxTOWER_CALIB_LG_HCALIN];   //[TOWER_CALIB_LG_HCALIN_]
		Int_t           n_TOWER_CALIB_LG_HCALOUT;
		Int_t           TOWER_CALIB_LG_HCALOUT_;
		UInt_t          TOWER_CALIB_LG_HCALOUT_fUniqueID[kMaxTOWER_CALIB_LG_HCALOUT];   //[TOWER_CALIB_LG_HCALOUT_]
		UInt_t          TOWER_CALIB_LG_HCALOUT_fBits[kMaxTOWER_CALIB_LG_HCALOUT];   //[TOWER_CALIB_LG_HCALOUT_]
		UInt_t          TOWER_CALIB_LG_HCALOUT_towerid[kMaxTOWER_CALIB_LG_HCALOUT];   //[TOWER_CALIB_LG_HCALOUT_]
		Double_t        TOWER_CALIB_LG_HCALOUT_energy[kMaxTOWER_CALIB_LG_HCALOUT];   //[TOWER_CALIB_LG_HCALOUT_]
		Float_t         TOWER_CALIB_LG_HCALOUT_time[kMaxTOWER_CALIB_LG_HCALOUT];   //[TOWER_CALIB_LG_HCALOUT_]
		Float_t         TOWER_CALIB_LG_HCALOUT_signal_samples[kMaxTOWER_CALIB_LG_HCALOUT][31];   //[TOWER_CALIB_LG_HCALOUT_]
		Int_t           TOWER_CALIB_LG_HCALOUT_HBD_channel[kMaxTOWER_CALIB_LG_HCALOUT];   //[TOWER_CALIB_LG_HCALOUT_]
		Int_t           n_TOWER_CALIB_HG_HCALOUT;
		Int_t           TOWER_CALIB_HG_HCALOUT_;
		UInt_t          TOWER_CALIB_HG_HCALOUT_fUniqueID[kMaxTOWER_CALIB_HG_HCALOUT];   //[TOWER_CALIB_HG_HCALOUT_]
		UInt_t          TOWER_CALIB_HG_HCALOUT_fBits[kMaxTOWER_CALIB_HG_HCALOUT];   //[TOWER_CALIB_HG_HCALOUT_]
		UInt_t          TOWER_CALIB_HG_HCALOUT_towerid[kMaxTOWER_CALIB_HG_HCALOUT];   //[TOWER_CALIB_HG_HCALOUT_]
		Double_t        TOWER_CALIB_HG_HCALOUT_energy[kMaxTOWER_CALIB_HG_HCALOUT];   //[TOWER_CALIB_HG_HCALOUT_]
		Float_t         TOWER_CALIB_HG_HCALOUT_time[kMaxTOWER_CALIB_HG_HCALOUT];   //[TOWER_CALIB_HG_HCALOUT_]
		Float_t         TOWER_CALIB_HG_HCALOUT_signal_samples[kMaxTOWER_CALIB_HG_HCALOUT][31];   //[TOWER_CALIB_HG_HCALOUT_]
		Int_t           TOWER_CALIB_HG_HCALOUT_HBD_channel[kMaxTOWER_CALIB_HG_HCALOUT];   //[TOWER_CALIB_HG_HCALOUT_]
		Int_t           n_TOWER_RAW_CEMC;
		Int_t           TOWER_RAW_CEMC_;
		UInt_t          TOWER_RAW_CEMC_fUniqueID[kMaxTOWER_RAW_CEMC];   //[TOWER_RAW_CEMC_]
		UInt_t          TOWER_RAW_CEMC_fBits[kMaxTOWER_RAW_CEMC];   //[TOWER_RAW_CEMC_]
		UInt_t          TOWER_RAW_CEMC_towerid[kMaxTOWER_RAW_CEMC];   //[TOWER_RAW_CEMC_]
		Double_t        TOWER_RAW_CEMC_energy[kMaxTOWER_RAW_CEMC];   //[TOWER_RAW_CEMC_]
		Float_t         TOWER_RAW_CEMC_time[kMaxTOWER_RAW_CEMC];   //[TOWER_RAW_CEMC_]
		Float_t         TOWER_RAW_CEMC_signal_samples[kMaxTOWER_RAW_CEMC][31];   //[TOWER_RAW_CEMC_]
		Int_t           TOWER_RAW_CEMC_HBD_channel[kMaxTOWER_RAW_CEMC];   //[TOWER_RAW_CEMC_]
		Int_t           n_TOWER_CALIB_CEMC;
		Int_t           TOWER_CALIB_CEMC_;
		UInt_t          TOWER_CALIB_CEMC_fUniqueID[kMaxTOWER_CALIB_CEMC];   //[TOWER_CALIB_CEMC_]
		UInt_t          TOWER_CALIB_CEMC_fBits[kMaxTOWER_CALIB_CEMC];   //[TOWER_CALIB_CEMC_]
		UInt_t          TOWER_CALIB_CEMC_towerid[kMaxTOWER_CALIB_CEMC];   //[TOWER_CALIB_CEMC_]
		Double_t        TOWER_CALIB_CEMC_energy[kMaxTOWER_CALIB_CEMC];   //[TOWER_CALIB_CEMC_]
		Float_t         TOWER_CALIB_CEMC_time[kMaxTOWER_CALIB_CEMC];   //[TOWER_CALIB_CEMC_]
		Float_t         TOWER_CALIB_CEMC_signal_samples[kMaxTOWER_CALIB_CEMC][31];   //[TOWER_CALIB_CEMC_]
		Int_t           TOWER_CALIB_CEMC_HBD_channel[kMaxTOWER_CALIB_CEMC];   //[TOWER_CALIB_CEMC_]
		Int_t           n_TOWER_RAW_HODO_VERTICAL;
		Int_t           TOWER_RAW_HODO_VERTICAL_;
		UInt_t          TOWER_RAW_HODO_VERTICAL_fUniqueID[kMaxTOWER_RAW_HODO_VERTICAL];   //[TOWER_RAW_HODO_VERTICAL_]
		UInt_t          TOWER_RAW_HODO_VERTICAL_fBits[kMaxTOWER_RAW_HODO_VERTICAL];   //[TOWER_RAW_HODO_VERTICAL_]
		UInt_t          TOWER_RAW_HODO_VERTICAL_towerid[kMaxTOWER_RAW_HODO_VERTICAL];   //[TOWER_RAW_HODO_VERTICAL_]
		Double_t        TOWER_RAW_HODO_VERTICAL_energy[kMaxTOWER_RAW_HODO_VERTICAL];   //[TOWER_RAW_HODO_VERTICAL_]
		Float_t         TOWER_RAW_HODO_VERTICAL_time[kMaxTOWER_RAW_HODO_VERTICAL];   //[TOWER_RAW_HODO_VERTICAL_]
		Float_t         TOWER_RAW_HODO_VERTICAL_signal_samples[kMaxTOWER_RAW_HODO_VERTICAL][31];   //[TOWER_RAW_HODO_VERTICAL_]
		Int_t           TOWER_RAW_HODO_VERTICAL_HBD_channel[kMaxTOWER_RAW_HODO_VERTICAL];   //[TOWER_RAW_HODO_VERTICAL_]
		Int_t           n_TOWER_RAW_HODO_HORIZONTAL;
		Int_t           TOWER_RAW_HODO_HORIZONTAL_;
		UInt_t          TOWER_RAW_HODO_HORIZONTAL_fUniqueID[kMaxTOWER_RAW_HODO_HORIZONTAL];   //[TOWER_RAW_HODO_HORIZONTAL_]
		UInt_t          TOWER_RAW_HODO_HORIZONTAL_fBits[kMaxTOWER_RAW_HODO_HORIZONTAL];   //[TOWER_RAW_HODO_HORIZONTAL_]
		UInt_t          TOWER_RAW_HODO_HORIZONTAL_towerid[kMaxTOWER_RAW_HODO_HORIZONTAL];   //[TOWER_RAW_HODO_HORIZONTAL_]
		Double_t        TOWER_RAW_HODO_HORIZONTAL_energy[kMaxTOWER_RAW_HODO_HORIZONTAL];   //[TOWER_RAW_HODO_HORIZONTAL_]
		Float_t         TOWER_RAW_HODO_HORIZONTAL_time[kMaxTOWER_RAW_HODO_HORIZONTAL];   //[TOWER_RAW_HODO_HORIZONTAL_]
		Float_t         TOWER_RAW_HODO_HORIZONTAL_signal_samples[kMaxTOWER_RAW_HODO_HORIZONTAL][31];   //[TOWER_RAW_HODO_HORIZONTAL_]
		Int_t           TOWER_RAW_HODO_HORIZONTAL_HBD_channel[kMaxTOWER_RAW_HODO_HORIZONTAL];   //[TOWER_RAW_HODO_HORIZONTAL_]
		Int_t           n_TOWER_CALIB_HODO_VERTICAL;
		Int_t           TOWER_CALIB_HODO_VERTICAL_;
		UInt_t          TOWER_CALIB_HODO_VERTICAL_fUniqueID[kMaxTOWER_CALIB_HODO_VERTICAL];   //[TOWER_CALIB_HODO_VERTICAL_]
		UInt_t          TOWER_CALIB_HODO_VERTICAL_fBits[kMaxTOWER_CALIB_HODO_VERTICAL];   //[TOWER_CALIB_HODO_VERTICAL_]
		UInt_t          TOWER_CALIB_HODO_VERTICAL_towerid[kMaxTOWER_CALIB_HODO_VERTICAL];   //[TOWER_CALIB_HODO_VERTICAL_]
		Double_t        TOWER_CALIB_HODO_VERTICAL_energy[kMaxTOWER_CALIB_HODO_VERTICAL];   //[TOWER_CALIB_HODO_VERTICAL_]
		Float_t         TOWER_CALIB_HODO_VERTICAL_time[kMaxTOWER_CALIB_HODO_VERTICAL];   //[TOWER_CALIB_HODO_VERTICAL_]
		Float_t         TOWER_CALIB_HODO_VERTICAL_signal_samples[kMaxTOWER_CALIB_HODO_VERTICAL][31];   //[TOWER_CALIB_HODO_VERTICAL_]
		Int_t           TOWER_CALIB_HODO_VERTICAL_HBD_channel[kMaxTOWER_CALIB_HODO_VERTICAL];   //[TOWER_CALIB_HODO_VERTICAL_]
		Int_t           n_TOWER_CALIB_HODO_HORIZONTAL;
		Int_t           TOWER_CALIB_HODO_HORIZONTAL_;
		UInt_t          TOWER_CALIB_HODO_HORIZONTAL_fUniqueID[kMaxTOWER_CALIB_HODO_HORIZONTAL];   //[TOWER_CALIB_HODO_HORIZONTAL_]
		UInt_t          TOWER_CALIB_HODO_HORIZONTAL_fBits[kMaxTOWER_CALIB_HODO_HORIZONTAL];   //[TOWER_CALIB_HODO_HORIZONTAL_]
		UInt_t          TOWER_CALIB_HODO_HORIZONTAL_towerid[kMaxTOWER_CALIB_HODO_HORIZONTAL];   //[TOWER_CALIB_HODO_HORIZONTAL_]
		Double_t        TOWER_CALIB_HODO_HORIZONTAL_energy[kMaxTOWER_CALIB_HODO_HORIZONTAL];   //[TOWER_CALIB_HODO_HORIZONTAL_]
		Float_t         TOWER_CALIB_HODO_HORIZONTAL_time[kMaxTOWER_CALIB_HODO_HORIZONTAL];   //[TOWER_CALIB_HODO_HORIZONTAL_]
		Float_t         TOWER_CALIB_HODO_HORIZONTAL_signal_samples[kMaxTOWER_CALIB_HODO_HORIZONTAL][31];   //[TOWER_CALIB_HODO_HORIZONTAL_]
		Int_t           TOWER_CALIB_HODO_HORIZONTAL_HBD_channel[kMaxTOWER_CALIB_HODO_HORIZONTAL];   //[TOWER_CALIB_HODO_HORIZONTAL_]
		Int_t           n_TOWER_RAW_C1;
		Int_t           TOWER_RAW_C1_;
		UInt_t          TOWER_RAW_C1_fUniqueID[kMaxTOWER_RAW_C1];   //[TOWER_RAW_C1_]
		UInt_t          TOWER_RAW_C1_fBits[kMaxTOWER_RAW_C1];   //[TOWER_RAW_C1_]
		UInt_t          TOWER_RAW_C1_towerid[kMaxTOWER_RAW_C1];   //[TOWER_RAW_C1_]
		Double_t        TOWER_RAW_C1_energy[kMaxTOWER_RAW_C1];   //[TOWER_RAW_C1_]
		Float_t         TOWER_RAW_C1_time[kMaxTOWER_RAW_C1];   //[TOWER_RAW_C1_]
		Float_t         TOWER_RAW_C1_signal_samples[kMaxTOWER_RAW_C1][31];   //[TOWER_RAW_C1_]
		Int_t           TOWER_RAW_C1_HBD_channel[kMaxTOWER_RAW_C1];   //[TOWER_RAW_C1_]
		Int_t           n_TOWER_CALIB_C1;
		Int_t           TOWER_CALIB_C1_;
		UInt_t          TOWER_CALIB_C1_fUniqueID[kMaxTOWER_CALIB_C1];   //[TOWER_CALIB_C1_]
		UInt_t          TOWER_CALIB_C1_fBits[kMaxTOWER_CALIB_C1];   //[TOWER_CALIB_C1_]
		UInt_t          TOWER_CALIB_C1_towerid[kMaxTOWER_CALIB_C1];   //[TOWER_CALIB_C1_]
		Double_t        TOWER_CALIB_C1_energy[kMaxTOWER_CALIB_C1];   //[TOWER_CALIB_C1_]
		Float_t         TOWER_CALIB_C1_time[kMaxTOWER_CALIB_C1];   //[TOWER_CALIB_C1_]
		Float_t         TOWER_CALIB_C1_signal_samples[kMaxTOWER_CALIB_C1][31];   //[TOWER_CALIB_C1_]
		Int_t           TOWER_CALIB_C1_HBD_channel[kMaxTOWER_CALIB_C1];   //[TOWER_CALIB_C1_]
		Int_t           n_TOWER_RAW_C2;
		Int_t           TOWER_RAW_C2_;
		UInt_t          TOWER_RAW_C2_fUniqueID[kMaxTOWER_RAW_C2];   //[TOWER_RAW_C2_]
		UInt_t          TOWER_RAW_C2_fBits[kMaxTOWER_RAW_C2];   //[TOWER_RAW_C2_]
		UInt_t          TOWER_RAW_C2_towerid[kMaxTOWER_RAW_C2];   //[TOWER_RAW_C2_]
		Double_t        TOWER_RAW_C2_energy[kMaxTOWER_RAW_C2];   //[TOWER_RAW_C2_]
		Float_t         TOWER_RAW_C2_time[kMaxTOWER_RAW_C2];   //[TOWER_RAW_C2_]
		Float_t         TOWER_RAW_C2_signal_samples[kMaxTOWER_RAW_C2][31];   //[TOWER_RAW_C2_]
		Int_t           TOWER_RAW_C2_HBD_channel[kMaxTOWER_RAW_C2];   //[TOWER_RAW_C2_]
		Int_t           n_TOWER_CALIB_C2;
		Int_t           TOWER_CALIB_C2_;
		UInt_t          TOWER_CALIB_C2_fUniqueID[kMaxTOWER_CALIB_C2];   //[TOWER_CALIB_C2_]
		UInt_t          TOWER_CALIB_C2_fBits[kMaxTOWER_CALIB_C2];   //[TOWER_CALIB_C2_]
		UInt_t          TOWER_CALIB_C2_towerid[kMaxTOWER_CALIB_C2];   //[TOWER_CALIB_C2_]
		Double_t        TOWER_CALIB_C2_energy[kMaxTOWER_CALIB_C2];   //[TOWER_CALIB_C2_]
		Float_t         TOWER_CALIB_C2_time[kMaxTOWER_CALIB_C2];   //[TOWER_CALIB_C2_]
		Float_t         TOWER_CALIB_C2_signal_samples[kMaxTOWER_CALIB_C2][31];   //[TOWER_CALIB_C2_]
		Int_t           TOWER_CALIB_C2_HBD_channel[kMaxTOWER_CALIB_C2];   //[TOWER_CALIB_C2_]
		Int_t           n_TOWER_RAW_PbGL;
		Int_t           TOWER_RAW_PbGL_;
		UInt_t          TOWER_RAW_PbGL_fUniqueID[kMaxTOWER_RAW_PbGL];   //[TOWER_RAW_PbGL_]
		UInt_t          TOWER_RAW_PbGL_fBits[kMaxTOWER_RAW_PbGL];   //[TOWER_RAW_PbGL_]
		UInt_t          TOWER_RAW_PbGL_towerid[kMaxTOWER_RAW_PbGL];   //[TOWER_RAW_PbGL_]
		Double_t        TOWER_RAW_PbGL_energy[kMaxTOWER_RAW_PbGL];   //[TOWER_RAW_PbGL_]
		Float_t         TOWER_RAW_PbGL_time[kMaxTOWER_RAW_PbGL];   //[TOWER_RAW_PbGL_]
		Float_t         TOWER_RAW_PbGL_signal_samples[kMaxTOWER_RAW_PbGL][31];   //[TOWER_RAW_PbGL_]
		Int_t           TOWER_RAW_PbGL_HBD_channel[kMaxTOWER_RAW_PbGL];   //[TOWER_RAW_PbGL_]
		Int_t           n_TOWER_CALIB_PbGL;
		Int_t           TOWER_CALIB_PbGL_;
		UInt_t          TOWER_CALIB_PbGL_fUniqueID[kMaxTOWER_CALIB_PbGL];   //[TOWER_CALIB_PbGL_]
		UInt_t          TOWER_CALIB_PbGL_fBits[kMaxTOWER_CALIB_PbGL];   //[TOWER_CALIB_PbGL_]
		UInt_t          TOWER_CALIB_PbGL_towerid[kMaxTOWER_CALIB_PbGL];   //[TOWER_CALIB_PbGL_]
		Double_t        TOWER_CALIB_PbGL_energy[kMaxTOWER_CALIB_PbGL];   //[TOWER_CALIB_PbGL_]
		Float_t         TOWER_CALIB_PbGL_time[kMaxTOWER_CALIB_PbGL];   //[TOWER_CALIB_PbGL_]
		Float_t         TOWER_CALIB_PbGL_signal_samples[kMaxTOWER_CALIB_PbGL][31];   //[TOWER_CALIB_PbGL_]
		Int_t           TOWER_CALIB_PbGL_HBD_channel[kMaxTOWER_CALIB_PbGL];   //[TOWER_CALIB_PbGL_]
		Int_t           n_TOWER_RAW_TRIGGER_VETO;
		Int_t           TOWER_RAW_TRIGGER_VETO_;
		UInt_t          TOWER_RAW_TRIGGER_VETO_fUniqueID[kMaxTOWER_RAW_TRIGGER_VETO];   //[TOWER_RAW_TRIGGER_VETO_]
		UInt_t          TOWER_RAW_TRIGGER_VETO_fBits[kMaxTOWER_RAW_TRIGGER_VETO];   //[TOWER_RAW_TRIGGER_VETO_]
		UInt_t          TOWER_RAW_TRIGGER_VETO_towerid[kMaxTOWER_RAW_TRIGGER_VETO];   //[TOWER_RAW_TRIGGER_VETO_]
		Double_t        TOWER_RAW_TRIGGER_VETO_energy[kMaxTOWER_RAW_TRIGGER_VETO];   //[TOWER_RAW_TRIGGER_VETO_]
		Float_t         TOWER_RAW_TRIGGER_VETO_time[kMaxTOWER_RAW_TRIGGER_VETO];   //[TOWER_RAW_TRIGGER_VETO_]
		Float_t         TOWER_RAW_TRIGGER_VETO_signal_samples[kMaxTOWER_RAW_TRIGGER_VETO][31];   //[TOWER_RAW_TRIGGER_VETO_]
		Int_t           TOWER_RAW_TRIGGER_VETO_HBD_channel[kMaxTOWER_RAW_TRIGGER_VETO];   //[TOWER_RAW_TRIGGER_VETO_]
		Int_t           n_TOWER_CALIB_TRIGGER_VETO;
		Int_t           TOWER_CALIB_TRIGGER_VETO_;
		UInt_t          TOWER_CALIB_TRIGGER_VETO_fUniqueID[kMaxTOWER_CALIB_TRIGGER_VETO];   //[TOWER_CALIB_TRIGGER_VETO_]
		UInt_t          TOWER_CALIB_TRIGGER_VETO_fBits[kMaxTOWER_CALIB_TRIGGER_VETO];   //[TOWER_CALIB_TRIGGER_VETO_]
		UInt_t          TOWER_CALIB_TRIGGER_VETO_towerid[kMaxTOWER_CALIB_TRIGGER_VETO];   //[TOWER_CALIB_TRIGGER_VETO_]
		Double_t        TOWER_CALIB_TRIGGER_VETO_energy[kMaxTOWER_CALIB_TRIGGER_VETO];   //[TOWER_CALIB_TRIGGER_VETO_]
		Float_t         TOWER_CALIB_TRIGGER_VETO_time[kMaxTOWER_CALIB_TRIGGER_VETO];   //[TOWER_CALIB_TRIGGER_VETO_]
		Float_t         TOWER_CALIB_TRIGGER_VETO_signal_samples[kMaxTOWER_CALIB_TRIGGER_VETO][31];   //[TOWER_CALIB_TRIGGER_VETO_]
		Int_t           TOWER_CALIB_TRIGGER_VETO_HBD_channel[kMaxTOWER_CALIB_TRIGGER_VETO];   //[TOWER_CALIB_TRIGGER_VETO_]
		Int_t           n_TOWER_RAW_TILE_MAPPER;
		Int_t           TOWER_RAW_TILE_MAPPER_;
		UInt_t          TOWER_RAW_TILE_MAPPER_fUniqueID[kMaxTOWER_RAW_TILE_MAPPER];   //[TOWER_RAW_TILE_MAPPER_]
		UInt_t          TOWER_RAW_TILE_MAPPER_fBits[kMaxTOWER_RAW_TILE_MAPPER];   //[TOWER_RAW_TILE_MAPPER_]
		UInt_t          TOWER_RAW_TILE_MAPPER_towerid[kMaxTOWER_RAW_TILE_MAPPER];   //[TOWER_RAW_TILE_MAPPER_]
		Double_t        TOWER_RAW_TILE_MAPPER_energy[kMaxTOWER_RAW_TILE_MAPPER];   //[TOWER_RAW_TILE_MAPPER_]
		Float_t         TOWER_RAW_TILE_MAPPER_time[kMaxTOWER_RAW_TILE_MAPPER];   //[TOWER_RAW_TILE_MAPPER_]
		Float_t         TOWER_RAW_TILE_MAPPER_signal_samples[kMaxTOWER_RAW_TILE_MAPPER][31];   //[TOWER_RAW_TILE_MAPPER_]
		Int_t           TOWER_RAW_TILE_MAPPER_HBD_channel[kMaxTOWER_RAW_TILE_MAPPER];   //[TOWER_RAW_TILE_MAPPER_]
		Int_t           n_TOWER_CALIB_TILE_MAPPER;
		Int_t           TOWER_CALIB_TILE_MAPPER_;
		UInt_t          TOWER_CALIB_TILE_MAPPER_fUniqueID[kMaxTOWER_CALIB_TILE_MAPPER];   //[TOWER_CALIB_TILE_MAPPER_]
		UInt_t          TOWER_CALIB_TILE_MAPPER_fBits[kMaxTOWER_CALIB_TILE_MAPPER];   //[TOWER_CALIB_TILE_MAPPER_]
		UInt_t          TOWER_CALIB_TILE_MAPPER_towerid[kMaxTOWER_CALIB_TILE_MAPPER];   //[TOWER_CALIB_TILE_MAPPER_]
		Double_t        TOWER_CALIB_TILE_MAPPER_energy[kMaxTOWER_CALIB_TILE_MAPPER];   //[TOWER_CALIB_TILE_MAPPER_]
		Float_t         TOWER_CALIB_TILE_MAPPER_time[kMaxTOWER_CALIB_TILE_MAPPER];   //[TOWER_CALIB_TILE_MAPPER_]
		Float_t         TOWER_CALIB_TILE_MAPPER_signal_samples[kMaxTOWER_CALIB_TILE_MAPPER][31];   //[TOWER_CALIB_TILE_MAPPER_]
		Int_t           TOWER_CALIB_TILE_MAPPER_HBD_channel[kMaxTOWER_CALIB_TILE_MAPPER];   //[TOWER_CALIB_TILE_MAPPER_]
		Int_t           n_TOWER_RAW_SC3;
		Int_t           TOWER_RAW_SC3_;
		UInt_t          TOWER_RAW_SC3_fUniqueID[kMaxTOWER_RAW_SC3];   //[TOWER_RAW_SC3_]
		UInt_t          TOWER_RAW_SC3_fBits[kMaxTOWER_RAW_SC3];   //[TOWER_RAW_SC3_]
		UInt_t          TOWER_RAW_SC3_towerid[kMaxTOWER_RAW_SC3];   //[TOWER_RAW_SC3_]
		Double_t        TOWER_RAW_SC3_energy[kMaxTOWER_RAW_SC3];   //[TOWER_RAW_SC3_]
		Float_t         TOWER_RAW_SC3_time[kMaxTOWER_RAW_SC3];   //[TOWER_RAW_SC3_]
		Float_t         TOWER_RAW_SC3_signal_samples[kMaxTOWER_RAW_SC3][31];   //[TOWER_RAW_SC3_]
		Int_t           TOWER_RAW_SC3_HBD_channel[kMaxTOWER_RAW_SC3];   //[TOWER_RAW_SC3_]
		Int_t           n_TOWER_CALIB_SC3;
		Int_t           TOWER_CALIB_SC3_;
		UInt_t          TOWER_CALIB_SC3_fUniqueID[kMaxTOWER_CALIB_SC3];   //[TOWER_CALIB_SC3_]
		UInt_t          TOWER_CALIB_SC3_fBits[kMaxTOWER_CALIB_SC3];   //[TOWER_CALIB_SC3_]
		UInt_t          TOWER_CALIB_SC3_towerid[kMaxTOWER_CALIB_SC3];   //[TOWER_CALIB_SC3_]
		Double_t        TOWER_CALIB_SC3_energy[kMaxTOWER_CALIB_SC3];   //[TOWER_CALIB_SC3_]
		Float_t         TOWER_CALIB_SC3_time[kMaxTOWER_CALIB_SC3];   //[TOWER_CALIB_SC3_]
		Float_t         TOWER_CALIB_SC3_signal_samples[kMaxTOWER_CALIB_SC3][31];   //[TOWER_CALIB_SC3_]
		Int_t           TOWER_CALIB_SC3_HBD_channel[kMaxTOWER_CALIB_SC3];   //[TOWER_CALIB_SC3_]
		Int_t           n_TOWER_RAW_FINGER_COUNTER;
		Int_t           TOWER_RAW_FINGER_COUNTER_;
		UInt_t          TOWER_RAW_FINGER_COUNTER_fUniqueID[kMaxTOWER_RAW_FINGER_COUNTER];   //[TOWER_RAW_FINGER_COUNTER_]
		UInt_t          TOWER_RAW_FINGER_COUNTER_fBits[kMaxTOWER_RAW_FINGER_COUNTER];   //[TOWER_RAW_FINGER_COUNTER_]
		UInt_t          TOWER_RAW_FINGER_COUNTER_towerid[kMaxTOWER_RAW_FINGER_COUNTER];   //[TOWER_RAW_FINGER_COUNTER_]
		Double_t        TOWER_RAW_FINGER_COUNTER_energy[kMaxTOWER_RAW_FINGER_COUNTER];   //[TOWER_RAW_FINGER_COUNTER_]
		Float_t         TOWER_RAW_FINGER_COUNTER_time[kMaxTOWER_RAW_FINGER_COUNTER];   //[TOWER_RAW_FINGER_COUNTER_]
		Float_t         TOWER_RAW_FINGER_COUNTER_signal_samples[kMaxTOWER_RAW_FINGER_COUNTER][31];   //[TOWER_RAW_FINGER_COUNTER_]
		Int_t           TOWER_RAW_FINGER_COUNTER_HBD_channel[kMaxTOWER_RAW_FINGER_COUNTER];   //[TOWER_RAW_FINGER_COUNTER_]
		Int_t           n_TOWER_CALIB_FINGER_COUNTER;
		Int_t           TOWER_CALIB_FINGER_COUNTER_;
		UInt_t          TOWER_CALIB_FINGER_COUNTER_fUniqueID[kMaxTOWER_CALIB_FINGER_COUNTER];   //[TOWER_CALIB_FINGER_COUNTER_]
		UInt_t          TOWER_CALIB_FINGER_COUNTER_fBits[kMaxTOWER_CALIB_FINGER_COUNTER];   //[TOWER_CALIB_FINGER_COUNTER_]
		UInt_t          TOWER_CALIB_FINGER_COUNTER_towerid[kMaxTOWER_CALIB_FINGER_COUNTER];   //[TOWER_CALIB_FINGER_COUNTER_]
		Double_t        TOWER_CALIB_FINGER_COUNTER_energy[kMaxTOWER_CALIB_FINGER_COUNTER];   //[TOWER_CALIB_FINGER_COUNTER_]
		Float_t         TOWER_CALIB_FINGER_COUNTER_time[kMaxTOWER_CALIB_FINGER_COUNTER];   //[TOWER_CALIB_FINGER_COUNTER_]
		Float_t         TOWER_CALIB_FINGER_COUNTER_signal_samples[kMaxTOWER_CALIB_FINGER_COUNTER][31];   //[TOWER_CALIB_FINGER_COUNTER_]
		Int_t           TOWER_CALIB_FINGER_COUNTER_HBD_channel[kMaxTOWER_CALIB_FINGER_COUNTER];   //[TOWER_CALIB_FINGER_COUNTER_]

		// List of branches
		TBranch        *b_beam_MTNRG_GeV;   //!
		TBranch        *b_beam_2CH_mm;   //!
		TBranch        *b_beam_2CV_mm;   //!
		TBranch        *b_EMCAL_A0_HighGain;   //!
		TBranch        *b_EMCAL_GR0_BiasOffset_Tower21;   //!
		TBranch        *b_EMCAL_T0_Tower21;   //!
		TBranch        *b_EMCAL_Is_HighEta;   //!
		TBranch        *b_n_TOWER_RAW_LG_HCALIN;   //!
		TBranch        *b_TOWER_RAW_LG_HCALIN_;   //!
		TBranch        *b_TOWER_RAW_LG_HCALIN_fUniqueID;   //!
		TBranch        *b_TOWER_RAW_LG_HCALIN_fBits;   //!
		TBranch        *b_TOWER_RAW_LG_HCALIN_towerid;   //!
		TBranch        *b_TOWER_RAW_LG_HCALIN_energy;   //!
		TBranch        *b_TOWER_RAW_LG_HCALIN_time;   //!
		TBranch        *b_TOWER_RAW_LG_HCALIN_signal_samples;   //!
		TBranch        *b_TOWER_RAW_LG_HCALIN_HBD_channel;   //!
		TBranch        *b_n_TOWER_RAW_LG_HCALOUT;   //!
		TBranch        *b_TOWER_RAW_LG_HCALOUT_;   //!
		TBranch        *b_TOWER_RAW_LG_HCALOUT_fUniqueID;   //!
		TBranch        *b_TOWER_RAW_LG_HCALOUT_fBits;   //!
		TBranch        *b_TOWER_RAW_LG_HCALOUT_towerid;   //!
		TBranch        *b_TOWER_RAW_LG_HCALOUT_energy;   //!
		TBranch        *b_TOWER_RAW_LG_HCALOUT_time;   //!
		TBranch        *b_TOWER_RAW_LG_HCALOUT_signal_samples;   //!
		TBranch        *b_TOWER_RAW_LG_HCALOUT_HBD_channel;   //!
		TBranch        *b_n_TOWER_RAW_HG_HCALOUT;   //!
		TBranch        *b_TOWER_RAW_HG_HCALOUT_;   //!
		TBranch        *b_TOWER_RAW_HG_HCALOUT_fUniqueID;   //!
		TBranch        *b_TOWER_RAW_HG_HCALOUT_fBits;   //!
		TBranch        *b_TOWER_RAW_HG_HCALOUT_towerid;   //!
		TBranch        *b_TOWER_RAW_HG_HCALOUT_energy;   //!
		TBranch        *b_TOWER_RAW_HG_HCALOUT_time;   //!
		TBranch        *b_TOWER_RAW_HG_HCALOUT_signal_samples;   //!
		TBranch        *b_TOWER_RAW_HG_HCALOUT_HBD_channel;   //!
		TBranch        *b_n_TOWER_CALIB_LG_HCALIN;   //!
		TBranch        *b_TOWER_CALIB_LG_HCALIN_;   //!
		TBranch        *b_TOWER_CALIB_LG_HCALIN_fUniqueID;   //!
		TBranch        *b_TOWER_CALIB_LG_HCALIN_fBits;   //!
		TBranch        *b_TOWER_CALIB_LG_HCALIN_towerid;   //!
		TBranch        *b_TOWER_CALIB_LG_HCALIN_energy;   //!
		TBranch        *b_TOWER_CALIB_LG_HCALIN_time;   //!
		TBranch        *b_TOWER_CALIB_LG_HCALIN_signal_samples;   //!
		TBranch        *b_TOWER_CALIB_LG_HCALIN_HBD_channel;   //!
		TBranch        *b_n_TOWER_CALIB_LG_HCALOUT;   //!
		TBranch        *b_TOWER_CALIB_LG_HCALOUT_;   //!
		TBranch        *b_TOWER_CALIB_LG_HCALOUT_fUniqueID;   //!
		TBranch        *b_TOWER_CALIB_LG_HCALOUT_fBits;   //!
		TBranch        *b_TOWER_CALIB_LG_HCALOUT_towerid;   //!
		TBranch        *b_TOWER_CALIB_LG_HCALOUT_energy;   //!
		TBranch        *b_TOWER_CALIB_LG_HCALOUT_time;   //!
		TBranch        *b_TOWER_CALIB_LG_HCALOUT_signal_samples;   //!
		TBranch        *b_TOWER_CALIB_LG_HCALOUT_HBD_channel;   //!
		TBranch        *b_n_TOWER_CALIB_HG_HCALOUT;   //!
		TBranch        *b_TOWER_CALIB_HG_HCALOUT_;   //!
		TBranch        *b_TOWER_CALIB_HG_HCALOUT_fUniqueID;   //!
		TBranch        *b_TOWER_CALIB_HG_HCALOUT_fBits;   //!
		TBranch        *b_TOWER_CALIB_HG_HCALOUT_towerid;   //!
		TBranch        *b_TOWER_CALIB_HG_HCALOUT_energy;   //!
		TBranch        *b_TOWER_CALIB_HG_HCALOUT_time;   //!
		TBranch        *b_TOWER_CALIB_HG_HCALOUT_signal_samples;   //!
		TBranch        *b_TOWER_CALIB_HG_HCALOUT_HBD_channel;   //!
		TBranch        *b_n_TOWER_RAW_CEMC;   //!
		TBranch        *b_TOWER_RAW_CEMC_;   //!
		TBranch        *b_TOWER_RAW_CEMC_fUniqueID;   //!
		TBranch        *b_TOWER_RAW_CEMC_fBits;   //!
		TBranch        *b_TOWER_RAW_CEMC_towerid;   //!
		TBranch        *b_TOWER_RAW_CEMC_energy;   //!
		TBranch        *b_TOWER_RAW_CEMC_time;   //!
		TBranch        *b_TOWER_RAW_CEMC_signal_samples;   //!
		TBranch        *b_TOWER_RAW_CEMC_HBD_channel;   //!
		TBranch        *b_n_TOWER_CALIB_CEMC;   //!
		TBranch        *b_TOWER_CALIB_CEMC_;   //!
		TBranch        *b_TOWER_CALIB_CEMC_fUniqueID;   //!
		TBranch        *b_TOWER_CALIB_CEMC_fBits;   //!
		TBranch        *b_TOWER_CALIB_CEMC_towerid;   //!
		TBranch        *b_TOWER_CALIB_CEMC_energy;   //!
		TBranch        *b_TOWER_CALIB_CEMC_time;   //!
		TBranch        *b_TOWER_CALIB_CEMC_signal_samples;   //!
		TBranch        *b_TOWER_CALIB_CEMC_HBD_channel;   //!
		TBranch        *b_n_TOWER_RAW_HODO_VERTICAL;   //!
		TBranch        *b_TOWER_RAW_HODO_VERTICAL_;   //!
		TBranch        *b_TOWER_RAW_HODO_VERTICAL_fUniqueID;   //!
		TBranch        *b_TOWER_RAW_HODO_VERTICAL_fBits;   //!
		TBranch        *b_TOWER_RAW_HODO_VERTICAL_towerid;   //!
		TBranch        *b_TOWER_RAW_HODO_VERTICAL_energy;   //!
		TBranch        *b_TOWER_RAW_HODO_VERTICAL_time;   //!
		TBranch        *b_TOWER_RAW_HODO_VERTICAL_signal_samples;   //!
		TBranch        *b_TOWER_RAW_HODO_VERTICAL_HBD_channel;   //!
		TBranch        *b_n_TOWER_RAW_HODO_HORIZONTAL;   //!
		TBranch        *b_TOWER_RAW_HODO_HORIZONTAL_;   //!
		TBranch        *b_TOWER_RAW_HODO_HORIZONTAL_fUniqueID;   //!
		TBranch        *b_TOWER_RAW_HODO_HORIZONTAL_fBits;   //!
		TBranch        *b_TOWER_RAW_HODO_HORIZONTAL_towerid;   //!
		TBranch        *b_TOWER_RAW_HODO_HORIZONTAL_energy;   //!
		TBranch        *b_TOWER_RAW_HODO_HORIZONTAL_time;   //!
		TBranch        *b_TOWER_RAW_HODO_HORIZONTAL_signal_samples;   //!
		TBranch        *b_TOWER_RAW_HODO_HORIZONTAL_HBD_channel;   //!
		TBranch        *b_n_TOWER_CALIB_HODO_VERTICAL;   //!
		TBranch        *b_TOWER_CALIB_HODO_VERTICAL_;   //!
		TBranch        *b_TOWER_CALIB_HODO_VERTICAL_fUniqueID;   //!
		TBranch        *b_TOWER_CALIB_HODO_VERTICAL_fBits;   //!
		TBranch        *b_TOWER_CALIB_HODO_VERTICAL_towerid;   //!
		TBranch        *b_TOWER_CALIB_HODO_VERTICAL_energy;   //!
		TBranch        *b_TOWER_CALIB_HODO_VERTICAL_time;   //!
		TBranch        *b_TOWER_CALIB_HODO_VERTICAL_signal_samples;   //!
		TBranch        *b_TOWER_CALIB_HODO_VERTICAL_HBD_channel;   //!
		TBranch        *b_n_TOWER_CALIB_HODO_HORIZONTAL;   //!
		TBranch        *b_TOWER_CALIB_HODO_HORIZONTAL_;   //!
		TBranch        *b_TOWER_CALIB_HODO_HORIZONTAL_fUniqueID;   //!
		TBranch        *b_TOWER_CALIB_HODO_HORIZONTAL_fBits;   //!
		TBranch        *b_TOWER_CALIB_HODO_HORIZONTAL_towerid;   //!
		TBranch        *b_TOWER_CALIB_HODO_HORIZONTAL_energy;   //!
		TBranch        *b_TOWER_CALIB_HODO_HORIZONTAL_time;   //!
		TBranch        *b_TOWER_CALIB_HODO_HORIZONTAL_signal_samples;   //!
		TBranch        *b_TOWER_CALIB_HODO_HORIZONTAL_HBD_channel;   //!
		TBranch        *b_n_TOWER_RAW_C1;   //!
		TBranch        *b_TOWER_RAW_C1_;   //!
		TBranch        *b_TOWER_RAW_C1_fUniqueID;   //!
		TBranch        *b_TOWER_RAW_C1_fBits;   //!
		TBranch        *b_TOWER_RAW_C1_towerid;   //!
		TBranch        *b_TOWER_RAW_C1_energy;   //!
		TBranch        *b_TOWER_RAW_C1_time;   //!
		TBranch        *b_TOWER_RAW_C1_signal_samples;   //!
		TBranch        *b_TOWER_RAW_C1_HBD_channel;   //!
		TBranch        *b_n_TOWER_CALIB_C1;   //!
		TBranch        *b_TOWER_CALIB_C1_;   //!
		TBranch        *b_TOWER_CALIB_C1_fUniqueID;   //!
		TBranch        *b_TOWER_CALIB_C1_fBits;   //!
		TBranch        *b_TOWER_CALIB_C1_towerid;   //!
		TBranch        *b_TOWER_CALIB_C1_energy;   //!
		TBranch        *b_TOWER_CALIB_C1_time;   //!
		TBranch        *b_TOWER_CALIB_C1_signal_samples;   //!
		TBranch        *b_TOWER_CALIB_C1_HBD_channel;   //!
		TBranch        *b_n_TOWER_RAW_C2;   //!
		TBranch        *b_TOWER_RAW_C2_;   //!
		TBranch        *b_TOWER_RAW_C2_fUniqueID;   //!
		TBranch        *b_TOWER_RAW_C2_fBits;   //!
		TBranch        *b_TOWER_RAW_C2_towerid;   //!
		TBranch        *b_TOWER_RAW_C2_energy;   //!
		TBranch        *b_TOWER_RAW_C2_time;   //!
		TBranch        *b_TOWER_RAW_C2_signal_samples;   //!
		TBranch        *b_TOWER_RAW_C2_HBD_channel;   //!
		TBranch        *b_n_TOWER_CALIB_C2;   //!
		TBranch        *b_TOWER_CALIB_C2_;   //!
		TBranch        *b_TOWER_CALIB_C2_fUniqueID;   //!
		TBranch        *b_TOWER_CALIB_C2_fBits;   //!
		TBranch        *b_TOWER_CALIB_C2_towerid;   //!
		TBranch        *b_TOWER_CALIB_C2_energy;   //!
		TBranch        *b_TOWER_CALIB_C2_time;   //!
		TBranch        *b_TOWER_CALIB_C2_signal_samples;   //!
		TBranch        *b_TOWER_CALIB_C2_HBD_channel;   //!
		TBranch        *b_n_TOWER_RAW_PbGL;   //!
		TBranch        *b_TOWER_RAW_PbGL_;   //!
		TBranch        *b_TOWER_RAW_PbGL_fUniqueID;   //!
		TBranch        *b_TOWER_RAW_PbGL_fBits;   //!
		TBranch        *b_TOWER_RAW_PbGL_towerid;   //!
		TBranch        *b_TOWER_RAW_PbGL_energy;   //!
		TBranch        *b_TOWER_RAW_PbGL_time;   //!
		TBranch        *b_TOWER_RAW_PbGL_signal_samples;   //!
		TBranch        *b_TOWER_RAW_PbGL_HBD_channel;   //!
		TBranch        *b_n_TOWER_CALIB_PbGL;   //!
		TBranch        *b_TOWER_CALIB_PbGL_;   //!
		TBranch        *b_TOWER_CALIB_PbGL_fUniqueID;   //!
		TBranch        *b_TOWER_CALIB_PbGL_fBits;   //!
		TBranch        *b_TOWER_CALIB_PbGL_towerid;   //!
		TBranch        *b_TOWER_CALIB_PbGL_energy;   //!
		TBranch        *b_TOWER_CALIB_PbGL_time;   //!
		TBranch        *b_TOWER_CALIB_PbGL_signal_samples;   //!
		TBranch        *b_TOWER_CALIB_PbGL_HBD_channel;   //!
		TBranch        *b_n_TOWER_RAW_TRIGGER_VETO;   //!
		TBranch        *b_TOWER_RAW_TRIGGER_VETO_;   //!
		TBranch        *b_TOWER_RAW_TRIGGER_VETO_fUniqueID;   //!
		TBranch        *b_TOWER_RAW_TRIGGER_VETO_fBits;   //!
		TBranch        *b_TOWER_RAW_TRIGGER_VETO_towerid;   //!
		TBranch        *b_TOWER_RAW_TRIGGER_VETO_energy;   //!
		TBranch        *b_TOWER_RAW_TRIGGER_VETO_time;   //!
		TBranch        *b_TOWER_RAW_TRIGGER_VETO_signal_samples;   //!
		TBranch        *b_TOWER_RAW_TRIGGER_VETO_HBD_channel;   //!
		TBranch        *b_n_TOWER_CALIB_TRIGGER_VETO;   //!
		TBranch        *b_TOWER_CALIB_TRIGGER_VETO_;   //!
		TBranch        *b_TOWER_CALIB_TRIGGER_VETO_fUniqueID;   //!
		TBranch        *b_TOWER_CALIB_TRIGGER_VETO_fBits;   //!
		TBranch        *b_TOWER_CALIB_TRIGGER_VETO_towerid;   //!
		TBranch        *b_TOWER_CALIB_TRIGGER_VETO_energy;   //!
		TBranch        *b_TOWER_CALIB_TRIGGER_VETO_time;   //!
		TBranch        *b_TOWER_CALIB_TRIGGER_VETO_signal_samples;   //!
		TBranch        *b_TOWER_CALIB_TRIGGER_VETO_HBD_channel;   //!
		TBranch        *b_n_TOWER_RAW_TILE_MAPPER;   //!
		TBranch        *b_TOWER_RAW_TILE_MAPPER_;   //!
		TBranch        *b_TOWER_RAW_TILE_MAPPER_fUniqueID;   //!
		TBranch        *b_TOWER_RAW_TILE_MAPPER_fBits;   //!
		TBranch        *b_TOWER_RAW_TILE_MAPPER_towerid;   //!
		TBranch        *b_TOWER_RAW_TILE_MAPPER_energy;   //!
		TBranch        *b_TOWER_RAW_TILE_MAPPER_time;   //!
		TBranch        *b_TOWER_RAW_TILE_MAPPER_signal_samples;   //!
		TBranch        *b_TOWER_RAW_TILE_MAPPER_HBD_channel;   //!
		TBranch        *b_n_TOWER_CALIB_TILE_MAPPER;   //!
		TBranch        *b_TOWER_CALIB_TILE_MAPPER_;   //!
		TBranch        *b_TOWER_CALIB_TILE_MAPPER_fUniqueID;   //!
		TBranch        *b_TOWER_CALIB_TILE_MAPPER_fBits;   //!
		TBranch        *b_TOWER_CALIB_TILE_MAPPER_towerid;   //!
		TBranch        *b_TOWER_CALIB_TILE_MAPPER_energy;   //!
		TBranch        *b_TOWER_CALIB_TILE_MAPPER_time;   //!
		TBranch        *b_TOWER_CALIB_TILE_MAPPER_signal_samples;   //!
		TBranch        *b_TOWER_CALIB_TILE_MAPPER_HBD_channel;   //!
		TBranch        *b_n_TOWER_RAW_SC3;   //!
		TBranch        *b_TOWER_RAW_SC3_;   //!
		TBranch        *b_TOWER_RAW_SC3_fUniqueID;   //!
		TBranch        *b_TOWER_RAW_SC3_fBits;   //!
		TBranch        *b_TOWER_RAW_SC3_towerid;   //!
		TBranch        *b_TOWER_RAW_SC3_energy;   //!
		TBranch        *b_TOWER_RAW_SC3_time;   //!
		TBranch        *b_TOWER_RAW_SC3_signal_samples;   //!
		TBranch        *b_TOWER_RAW_SC3_HBD_channel;   //!
		TBranch        *b_n_TOWER_CALIB_SC3;   //!
		TBranch        *b_TOWER_CALIB_SC3_;   //!
		TBranch        *b_TOWER_CALIB_SC3_fUniqueID;   //!
		TBranch        *b_TOWER_CALIB_SC3_fBits;   //!
		TBranch        *b_TOWER_CALIB_SC3_towerid;   //!
		TBranch        *b_TOWER_CALIB_SC3_energy;   //!
		TBranch        *b_TOWER_CALIB_SC3_time;   //!
		TBranch        *b_TOWER_CALIB_SC3_signal_samples;   //!
		TBranch        *b_TOWER_CALIB_SC3_HBD_channel;   //!
		TBranch        *b_n_TOWER_RAW_FINGER_COUNTER;   //!
		TBranch        *b_TOWER_RAW_FINGER_COUNTER_;   //!
		TBranch        *b_TOWER_RAW_FINGER_COUNTER_fUniqueID;   //!
		TBranch        *b_TOWER_RAW_FINGER_COUNTER_fBits;   //!
		TBranch        *b_TOWER_RAW_FINGER_COUNTER_towerid;   //!
		TBranch        *b_TOWER_RAW_FINGER_COUNTER_energy;   //!
		TBranch        *b_TOWER_RAW_FINGER_COUNTER_time;   //!
		TBranch        *b_TOWER_RAW_FINGER_COUNTER_signal_samples;   //!
		TBranch        *b_TOWER_RAW_FINGER_COUNTER_HBD_channel;   //!
		TBranch        *b_n_TOWER_CALIB_FINGER_COUNTER;   //!
		TBranch        *b_TOWER_CALIB_FINGER_COUNTER_;   //!
		TBranch        *b_TOWER_CALIB_FINGER_COUNTER_fUniqueID;   //!
		TBranch        *b_TOWER_CALIB_FINGER_COUNTER_fBits;   //!
		TBranch        *b_TOWER_CALIB_FINGER_COUNTER_towerid;   //!
		TBranch        *b_TOWER_CALIB_FINGER_COUNTER_energy;   //!
		TBranch        *b_TOWER_CALIB_FINGER_COUNTER_time;   //!
		TBranch        *b_TOWER_CALIB_FINGER_COUNTER_signal_samples;   //!
		TBranch        *b_TOWER_CALIB_FINGER_COUNTER_HBD_channel;   //!

		DSTReader551(TTree *tree=0,string name="beam_00000551-0000_DSTReader.root");
		virtual ~DSTReader551();
		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 OfficalBeamData*     Loop(int runnumber,bool makeSidePlots);
		virtual Bool_t   Notify();
		virtual void     Show(Long64_t entry = -1);
};

DSTReader551::DSTReader551(TTree *tree,string file) : fChain(0) 
{
	// if parameter tree is not specified (or zero), connect the file
	// used to generate this class and read the Tree.
	if (tree == 0) {
		TFile *f = (TFile*)gROOT->GetListOfFiles()->FindObject(file.c_str());
		if (!f || !f->IsOpen()) {
			f = new TFile(file.c_str());
		}
		f->GetObject("T",tree);

	}
	Init(tree);
}

DSTReader551::~DSTReader551()
{
	if (!fChain) return;
	delete fChain->GetCurrentFile();
}

Int_t DSTReader551::GetEntry(Long64_t entry)
{
	// Read contents of entry.
	if (!fChain) return 0;
	return fChain->GetEntry(entry);
}
Long64_t DSTReader551::LoadTree(Long64_t entry)
{
	// Set the environment to read one entry
	if (!fChain) return -5;
	Long64_t centry = fChain->LoadTree(entry);
	if (centry < 0) return centry;
	if (fChain->GetTreeNumber() != fCurrent) {
		fCurrent = fChain->GetTreeNumber();
		Notify();
	}
	return centry;
}

void DSTReader551::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 normally 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("beam_MTNRG_GeV", &beam_MTNRG_GeV, &b_beam_MTNRG_GeV);
	fChain->SetBranchAddress("beam_2CH_mm", &beam_2CH_mm, &b_beam_2CH_mm);
	fChain->SetBranchAddress("beam_2CV_mm", &beam_2CV_mm, &b_beam_2CV_mm);
	fChain->SetBranchAddress("EMCAL_A0_HighGain", &EMCAL_A0_HighGain, &b_EMCAL_A0_HighGain);
	fChain->SetBranchAddress("EMCAL_GR0_BiasOffset_Tower21", &EMCAL_GR0_BiasOffset_Tower21, &b_EMCAL_GR0_BiasOffset_Tower21);
	fChain->SetBranchAddress("EMCAL_T0_Tower21", &EMCAL_T0_Tower21, &b_EMCAL_T0_Tower21);
	fChain->SetBranchAddress("EMCAL_Is_HighEta", &EMCAL_Is_HighEta, &b_EMCAL_Is_HighEta);
	fChain->SetBranchAddress("n_TOWER_RAW_LG_HCALIN", &n_TOWER_RAW_LG_HCALIN, &b_n_TOWER_RAW_LG_HCALIN);
	fChain->SetBranchAddress("TOWER_RAW_LG_HCALIN", &TOWER_RAW_LG_HCALIN_, &b_TOWER_RAW_LG_HCALIN_);
	fChain->SetBranchAddress("TOWER_RAW_LG_HCALIN.fUniqueID", TOWER_RAW_LG_HCALIN_fUniqueID, &b_TOWER_RAW_LG_HCALIN_fUniqueID);
	fChain->SetBranchAddress("TOWER_RAW_LG_HCALIN.fBits", TOWER_RAW_LG_HCALIN_fBits, &b_TOWER_RAW_LG_HCALIN_fBits);
	fChain->SetBranchAddress("TOWER_RAW_LG_HCALIN.towerid", TOWER_RAW_LG_HCALIN_towerid, &b_TOWER_RAW_LG_HCALIN_towerid);
	fChain->SetBranchAddress("TOWER_RAW_LG_HCALIN.energy", TOWER_RAW_LG_HCALIN_energy, &b_TOWER_RAW_LG_HCALIN_energy);
	fChain->SetBranchAddress("TOWER_RAW_LG_HCALIN.time", TOWER_RAW_LG_HCALIN_time, &b_TOWER_RAW_LG_HCALIN_time);
	fChain->SetBranchAddress("TOWER_RAW_LG_HCALIN.signal_samples[31]", TOWER_RAW_LG_HCALIN_signal_samples, &b_TOWER_RAW_LG_HCALIN_signal_samples);
	fChain->SetBranchAddress("TOWER_RAW_LG_HCALIN.HBD_channel", TOWER_RAW_LG_HCALIN_HBD_channel, &b_TOWER_RAW_LG_HCALIN_HBD_channel);
	fChain->SetBranchAddress("n_TOWER_RAW_LG_HCALOUT", &n_TOWER_RAW_LG_HCALOUT, &b_n_TOWER_RAW_LG_HCALOUT);
	fChain->SetBranchAddress("TOWER_RAW_LG_HCALOUT", &TOWER_RAW_LG_HCALOUT_, &b_TOWER_RAW_LG_HCALOUT_);
	fChain->SetBranchAddress("TOWER_RAW_LG_HCALOUT.fUniqueID", TOWER_RAW_LG_HCALOUT_fUniqueID, &b_TOWER_RAW_LG_HCALOUT_fUniqueID);
	fChain->SetBranchAddress("TOWER_RAW_LG_HCALOUT.fBits", TOWER_RAW_LG_HCALOUT_fBits, &b_TOWER_RAW_LG_HCALOUT_fBits);
	fChain->SetBranchAddress("TOWER_RAW_LG_HCALOUT.towerid", TOWER_RAW_LG_HCALOUT_towerid, &b_TOWER_RAW_LG_HCALOUT_towerid);
	fChain->SetBranchAddress("TOWER_RAW_LG_HCALOUT.energy", TOWER_RAW_LG_HCALOUT_energy, &b_TOWER_RAW_LG_HCALOUT_energy);
	fChain->SetBranchAddress("TOWER_RAW_LG_HCALOUT.time", TOWER_RAW_LG_HCALOUT_time, &b_TOWER_RAW_LG_HCALOUT_time);
	fChain->SetBranchAddress("TOWER_RAW_LG_HCALOUT.signal_samples[31]", TOWER_RAW_LG_HCALOUT_signal_samples, &b_TOWER_RAW_LG_HCALOUT_signal_samples);
	fChain->SetBranchAddress("TOWER_RAW_LG_HCALOUT.HBD_channel", TOWER_RAW_LG_HCALOUT_HBD_channel, &b_TOWER_RAW_LG_HCALOUT_HBD_channel);
	fChain->SetBranchAddress("n_TOWER_RAW_HG_HCALOUT", &n_TOWER_RAW_HG_HCALOUT, &b_n_TOWER_RAW_HG_HCALOUT);
	fChain->SetBranchAddress("TOWER_RAW_HG_HCALOUT", &TOWER_RAW_HG_HCALOUT_, &b_TOWER_RAW_HG_HCALOUT_);
	fChain->SetBranchAddress("TOWER_RAW_HG_HCALOUT.fUniqueID", TOWER_RAW_HG_HCALOUT_fUniqueID, &b_TOWER_RAW_HG_HCALOUT_fUniqueID);
	fChain->SetBranchAddress("TOWER_RAW_HG_HCALOUT.fBits", TOWER_RAW_HG_HCALOUT_fBits, &b_TOWER_RAW_HG_HCALOUT_fBits);
	fChain->SetBranchAddress("TOWER_RAW_HG_HCALOUT.towerid", TOWER_RAW_HG_HCALOUT_towerid, &b_TOWER_RAW_HG_HCALOUT_towerid);
	fChain->SetBranchAddress("TOWER_RAW_HG_HCALOUT.energy", TOWER_RAW_HG_HCALOUT_energy, &b_TOWER_RAW_HG_HCALOUT_energy);
	fChain->SetBranchAddress("TOWER_RAW_HG_HCALOUT.time", TOWER_RAW_HG_HCALOUT_time, &b_TOWER_RAW_HG_HCALOUT_time);
	fChain->SetBranchAddress("TOWER_RAW_HG_HCALOUT.signal_samples[31]", TOWER_RAW_HG_HCALOUT_signal_samples, &b_TOWER_RAW_HG_HCALOUT_signal_samples);
	fChain->SetBranchAddress("TOWER_RAW_HG_HCALOUT.HBD_channel", TOWER_RAW_HG_HCALOUT_HBD_channel, &b_TOWER_RAW_HG_HCALOUT_HBD_channel);
	fChain->SetBranchAddress("n_TOWER_CALIB_LG_HCALIN", &n_TOWER_CALIB_LG_HCALIN, &b_n_TOWER_CALIB_LG_HCALIN);
	fChain->SetBranchAddress("TOWER_CALIB_LG_HCALIN", &TOWER_CALIB_LG_HCALIN_, &b_TOWER_CALIB_LG_HCALIN_);
	fChain->SetBranchAddress("TOWER_CALIB_LG_HCALIN.fUniqueID", TOWER_CALIB_LG_HCALIN_fUniqueID, &b_TOWER_CALIB_LG_HCALIN_fUniqueID);
	fChain->SetBranchAddress("TOWER_CALIB_LG_HCALIN.fBits", TOWER_CALIB_LG_HCALIN_fBits, &b_TOWER_CALIB_LG_HCALIN_fBits);
	fChain->SetBranchAddress("TOWER_CALIB_LG_HCALIN.towerid", TOWER_CALIB_LG_HCALIN_towerid, &b_TOWER_CALIB_LG_HCALIN_towerid);
	fChain->SetBranchAddress("TOWER_CALIB_LG_HCALIN.energy", TOWER_CALIB_LG_HCALIN_energy, &b_TOWER_CALIB_LG_HCALIN_energy);
	fChain->SetBranchAddress("TOWER_CALIB_LG_HCALIN.time", TOWER_CALIB_LG_HCALIN_time, &b_TOWER_CALIB_LG_HCALIN_time);
	fChain->SetBranchAddress("TOWER_CALIB_LG_HCALIN.signal_samples[31]", TOWER_CALIB_LG_HCALIN_signal_samples, &b_TOWER_CALIB_LG_HCALIN_signal_samples);
	fChain->SetBranchAddress("TOWER_CALIB_LG_HCALIN.HBD_channel", TOWER_CALIB_LG_HCALIN_HBD_channel, &b_TOWER_CALIB_LG_HCALIN_HBD_channel);
	fChain->SetBranchAddress("n_TOWER_CALIB_LG_HCALOUT", &n_TOWER_CALIB_LG_HCALOUT, &b_n_TOWER_CALIB_LG_HCALOUT);
	fChain->SetBranchAddress("TOWER_CALIB_LG_HCALOUT", &TOWER_CALIB_LG_HCALOUT_, &b_TOWER_CALIB_LG_HCALOUT_);
	fChain->SetBranchAddress("TOWER_CALIB_LG_HCALOUT.fUniqueID", TOWER_CALIB_LG_HCALOUT_fUniqueID, &b_TOWER_CALIB_LG_HCALOUT_fUniqueID);
	fChain->SetBranchAddress("TOWER_CALIB_LG_HCALOUT.fBits", TOWER_CALIB_LG_HCALOUT_fBits, &b_TOWER_CALIB_LG_HCALOUT_fBits);
	fChain->SetBranchAddress("TOWER_CALIB_LG_HCALOUT.towerid", TOWER_CALIB_LG_HCALOUT_towerid, &b_TOWER_CALIB_LG_HCALOUT_towerid);
	fChain->SetBranchAddress("TOWER_CALIB_LG_HCALOUT.energy", TOWER_CALIB_LG_HCALOUT_energy, &b_TOWER_CALIB_LG_HCALOUT_energy);
	fChain->SetBranchAddress("TOWER_CALIB_LG_HCALOUT.time", TOWER_CALIB_LG_HCALOUT_time, &b_TOWER_CALIB_LG_HCALOUT_time);
	fChain->SetBranchAddress("TOWER_CALIB_LG_HCALOUT.signal_samples[31]", TOWER_CALIB_LG_HCALOUT_signal_samples, &b_TOWER_CALIB_LG_HCALOUT_signal_samples);
	fChain->SetBranchAddress("TOWER_CALIB_LG_HCALOUT.HBD_channel", TOWER_CALIB_LG_HCALOUT_HBD_channel, &b_TOWER_CALIB_LG_HCALOUT_HBD_channel);
	fChain->SetBranchAddress("n_TOWER_CALIB_HG_HCALOUT", &n_TOWER_CALIB_HG_HCALOUT, &b_n_TOWER_CALIB_HG_HCALOUT);
	fChain->SetBranchAddress("TOWER_CALIB_HG_HCALOUT", &TOWER_CALIB_HG_HCALOUT_, &b_TOWER_CALIB_HG_HCALOUT_);
	fChain->SetBranchAddress("TOWER_CALIB_HG_HCALOUT.fUniqueID", TOWER_CALIB_HG_HCALOUT_fUniqueID, &b_TOWER_CALIB_HG_HCALOUT_fUniqueID);
	fChain->SetBranchAddress("TOWER_CALIB_HG_HCALOUT.fBits", TOWER_CALIB_HG_HCALOUT_fBits, &b_TOWER_CALIB_HG_HCALOUT_fBits);
	fChain->SetBranchAddress("TOWER_CALIB_HG_HCALOUT.towerid", TOWER_CALIB_HG_HCALOUT_towerid, &b_TOWER_CALIB_HG_HCALOUT_towerid);
	fChain->SetBranchAddress("TOWER_CALIB_HG_HCALOUT.energy", TOWER_CALIB_HG_HCALOUT_energy, &b_TOWER_CALIB_HG_HCALOUT_energy);
	fChain->SetBranchAddress("TOWER_CALIB_HG_HCALOUT.time", TOWER_CALIB_HG_HCALOUT_time, &b_TOWER_CALIB_HG_HCALOUT_time);
	fChain->SetBranchAddress("TOWER_CALIB_HG_HCALOUT.signal_samples[31]", TOWER_CALIB_HG_HCALOUT_signal_samples, &b_TOWER_CALIB_HG_HCALOUT_signal_samples);
	fChain->SetBranchAddress("TOWER_CALIB_HG_HCALOUT.HBD_channel", TOWER_CALIB_HG_HCALOUT_HBD_channel, &b_TOWER_CALIB_HG_HCALOUT_HBD_channel);
	fChain->SetBranchAddress("n_TOWER_RAW_CEMC", &n_TOWER_RAW_CEMC, &b_n_TOWER_RAW_CEMC);
	fChain->SetBranchAddress("TOWER_RAW_CEMC", &TOWER_RAW_CEMC_, &b_TOWER_RAW_CEMC_);
	fChain->SetBranchAddress("TOWER_RAW_CEMC.fUniqueID", TOWER_RAW_CEMC_fUniqueID, &b_TOWER_RAW_CEMC_fUniqueID);
	fChain->SetBranchAddress("TOWER_RAW_CEMC.fBits", TOWER_RAW_CEMC_fBits, &b_TOWER_RAW_CEMC_fBits);
	fChain->SetBranchAddress("TOWER_RAW_CEMC.towerid", TOWER_RAW_CEMC_towerid, &b_TOWER_RAW_CEMC_towerid);
	fChain->SetBranchAddress("TOWER_RAW_CEMC.energy", TOWER_RAW_CEMC_energy, &b_TOWER_RAW_CEMC_energy);
	fChain->SetBranchAddress("TOWER_RAW_CEMC.time", TOWER_RAW_CEMC_time, &b_TOWER_RAW_CEMC_time);
	fChain->SetBranchAddress("TOWER_RAW_CEMC.signal_samples[31]", TOWER_RAW_CEMC_signal_samples, &b_TOWER_RAW_CEMC_signal_samples);
	fChain->SetBranchAddress("TOWER_RAW_CEMC.HBD_channel", TOWER_RAW_CEMC_HBD_channel, &b_TOWER_RAW_CEMC_HBD_channel);
	fChain->SetBranchAddress("n_TOWER_CALIB_CEMC", &n_TOWER_CALIB_CEMC, &b_n_TOWER_CALIB_CEMC);
	fChain->SetBranchAddress("TOWER_CALIB_CEMC", &TOWER_CALIB_CEMC_, &b_TOWER_CALIB_CEMC_);
	fChain->SetBranchAddress("TOWER_CALIB_CEMC.fUniqueID", TOWER_CALIB_CEMC_fUniqueID, &b_TOWER_CALIB_CEMC_fUniqueID);
	fChain->SetBranchAddress("TOWER_CALIB_CEMC.fBits", TOWER_CALIB_CEMC_fBits, &b_TOWER_CALIB_CEMC_fBits);
	fChain->SetBranchAddress("TOWER_CALIB_CEMC.towerid", TOWER_CALIB_CEMC_towerid, &b_TOWER_CALIB_CEMC_towerid);
	fChain->SetBranchAddress("TOWER_CALIB_CEMC.energy", TOWER_CALIB_CEMC_energy, &b_TOWER_CALIB_CEMC_energy);
	fChain->SetBranchAddress("TOWER_CALIB_CEMC.time", TOWER_CALIB_CEMC_time, &b_TOWER_CALIB_CEMC_time);
	fChain->SetBranchAddress("TOWER_CALIB_CEMC.signal_samples[31]", TOWER_CALIB_CEMC_signal_samples, &b_TOWER_CALIB_CEMC_signal_samples);
	fChain->SetBranchAddress("TOWER_CALIB_CEMC.HBD_channel", TOWER_CALIB_CEMC_HBD_channel, &b_TOWER_CALIB_CEMC_HBD_channel);
	fChain->SetBranchAddress("n_TOWER_RAW_HODO_VERTICAL", &n_TOWER_RAW_HODO_VERTICAL, &b_n_TOWER_RAW_HODO_VERTICAL);
	fChain->SetBranchAddress("TOWER_RAW_HODO_VERTICAL", &TOWER_RAW_HODO_VERTICAL_, &b_TOWER_RAW_HODO_VERTICAL_);
	fChain->SetBranchAddress("TOWER_RAW_HODO_VERTICAL.fUniqueID", TOWER_RAW_HODO_VERTICAL_fUniqueID, &b_TOWER_RAW_HODO_VERTICAL_fUniqueID);
	fChain->SetBranchAddress("TOWER_RAW_HODO_VERTICAL.fBits", TOWER_RAW_HODO_VERTICAL_fBits, &b_TOWER_RAW_HODO_VERTICAL_fBits);
	fChain->SetBranchAddress("TOWER_RAW_HODO_VERTICAL.towerid", TOWER_RAW_HODO_VERTICAL_towerid, &b_TOWER_RAW_HODO_VERTICAL_towerid);
	fChain->SetBranchAddress("TOWER_RAW_HODO_VERTICAL.energy", TOWER_RAW_HODO_VERTICAL_energy, &b_TOWER_RAW_HODO_VERTICAL_energy);
	fChain->SetBranchAddress("TOWER_RAW_HODO_VERTICAL.time", TOWER_RAW_HODO_VERTICAL_time, &b_TOWER_RAW_HODO_VERTICAL_time);
	fChain->SetBranchAddress("TOWER_RAW_HODO_VERTICAL.signal_samples[31]", TOWER_RAW_HODO_VERTICAL_signal_samples, &b_TOWER_RAW_HODO_VERTICAL_signal_samples);
	fChain->SetBranchAddress("TOWER_RAW_HODO_VERTICAL.HBD_channel", TOWER_RAW_HODO_VERTICAL_HBD_channel, &b_TOWER_RAW_HODO_VERTICAL_HBD_channel);
	fChain->SetBranchAddress("n_TOWER_RAW_HODO_HORIZONTAL", &n_TOWER_RAW_HODO_HORIZONTAL, &b_n_TOWER_RAW_HODO_HORIZONTAL);
	fChain->SetBranchAddress("TOWER_RAW_HODO_HORIZONTAL", &TOWER_RAW_HODO_HORIZONTAL_, &b_TOWER_RAW_HODO_HORIZONTAL_);
	fChain->SetBranchAddress("TOWER_RAW_HODO_HORIZONTAL.fUniqueID", TOWER_RAW_HODO_HORIZONTAL_fUniqueID, &b_TOWER_RAW_HODO_HORIZONTAL_fUniqueID);
	fChain->SetBranchAddress("TOWER_RAW_HODO_HORIZONTAL.fBits", TOWER_RAW_HODO_HORIZONTAL_fBits, &b_TOWER_RAW_HODO_HORIZONTAL_fBits);
	fChain->SetBranchAddress("TOWER_RAW_HODO_HORIZONTAL.towerid", TOWER_RAW_HODO_HORIZONTAL_towerid, &b_TOWER_RAW_HODO_HORIZONTAL_towerid);
	fChain->SetBranchAddress("TOWER_RAW_HODO_HORIZONTAL.energy", TOWER_RAW_HODO_HORIZONTAL_energy, &b_TOWER_RAW_HODO_HORIZONTAL_energy);
	fChain->SetBranchAddress("TOWER_RAW_HODO_HORIZONTAL.time", TOWER_RAW_HODO_HORIZONTAL_time, &b_TOWER_RAW_HODO_HORIZONTAL_time);
	fChain->SetBranchAddress("TOWER_RAW_HODO_HORIZONTAL.signal_samples[31]", TOWER_RAW_HODO_HORIZONTAL_signal_samples, &b_TOWER_RAW_HODO_HORIZONTAL_signal_samples);
	fChain->SetBranchAddress("TOWER_RAW_HODO_HORIZONTAL.HBD_channel", TOWER_RAW_HODO_HORIZONTAL_HBD_channel, &b_TOWER_RAW_HODO_HORIZONTAL_HBD_channel);
	fChain->SetBranchAddress("n_TOWER_CALIB_HODO_VERTICAL", &n_TOWER_CALIB_HODO_VERTICAL, &b_n_TOWER_CALIB_HODO_VERTICAL);
	fChain->SetBranchAddress("TOWER_CALIB_HODO_VERTICAL", &TOWER_CALIB_HODO_VERTICAL_, &b_TOWER_CALIB_HODO_VERTICAL_);
	fChain->SetBranchAddress("TOWER_CALIB_HODO_VERTICAL.fUniqueID", TOWER_CALIB_HODO_VERTICAL_fUniqueID, &b_TOWER_CALIB_HODO_VERTICAL_fUniqueID);
	fChain->SetBranchAddress("TOWER_CALIB_HODO_VERTICAL.fBits", TOWER_CALIB_HODO_VERTICAL_fBits, &b_TOWER_CALIB_HODO_VERTICAL_fBits);
	fChain->SetBranchAddress("TOWER_CALIB_HODO_VERTICAL.towerid", TOWER_CALIB_HODO_VERTICAL_towerid, &b_TOWER_CALIB_HODO_VERTICAL_towerid);
	fChain->SetBranchAddress("TOWER_CALIB_HODO_VERTICAL.energy", TOWER_CALIB_HODO_VERTICAL_energy, &b_TOWER_CALIB_HODO_VERTICAL_energy);
	fChain->SetBranchAddress("TOWER_CALIB_HODO_VERTICAL.time", TOWER_CALIB_HODO_VERTICAL_time, &b_TOWER_CALIB_HODO_VERTICAL_time);
	fChain->SetBranchAddress("TOWER_CALIB_HODO_VERTICAL.signal_samples[31]", TOWER_CALIB_HODO_VERTICAL_signal_samples, &b_TOWER_CALIB_HODO_VERTICAL_signal_samples);
	fChain->SetBranchAddress("TOWER_CALIB_HODO_VERTICAL.HBD_channel", TOWER_CALIB_HODO_VERTICAL_HBD_channel, &b_TOWER_CALIB_HODO_VERTICAL_HBD_channel);
	fChain->SetBranchAddress("n_TOWER_CALIB_HODO_HORIZONTAL", &n_TOWER_CALIB_HODO_HORIZONTAL, &b_n_TOWER_CALIB_HODO_HORIZONTAL);
	fChain->SetBranchAddress("TOWER_CALIB_HODO_HORIZONTAL", &TOWER_CALIB_HODO_HORIZONTAL_, &b_TOWER_CALIB_HODO_HORIZONTAL_);
	fChain->SetBranchAddress("TOWER_CALIB_HODO_HORIZONTAL.fUniqueID", TOWER_CALIB_HODO_HORIZONTAL_fUniqueID, &b_TOWER_CALIB_HODO_HORIZONTAL_fUniqueID);
	fChain->SetBranchAddress("TOWER_CALIB_HODO_HORIZONTAL.fBits", TOWER_CALIB_HODO_HORIZONTAL_fBits, &b_TOWER_CALIB_HODO_HORIZONTAL_fBits);
	fChain->SetBranchAddress("TOWER_CALIB_HODO_HORIZONTAL.towerid", TOWER_CALIB_HODO_HORIZONTAL_towerid, &b_TOWER_CALIB_HODO_HORIZONTAL_towerid);
	fChain->SetBranchAddress("TOWER_CALIB_HODO_HORIZONTAL.energy", TOWER_CALIB_HODO_HORIZONTAL_energy, &b_TOWER_CALIB_HODO_HORIZONTAL_energy);
	fChain->SetBranchAddress("TOWER_CALIB_HODO_HORIZONTAL.time", TOWER_CALIB_HODO_HORIZONTAL_time, &b_TOWER_CALIB_HODO_HORIZONTAL_time);
	fChain->SetBranchAddress("TOWER_CALIB_HODO_HORIZONTAL.signal_samples[31]", TOWER_CALIB_HODO_HORIZONTAL_signal_samples, &b_TOWER_CALIB_HODO_HORIZONTAL_signal_samples);
	fChain->SetBranchAddress("TOWER_CALIB_HODO_HORIZONTAL.HBD_channel", TOWER_CALIB_HODO_HORIZONTAL_HBD_channel, &b_TOWER_CALIB_HODO_HORIZONTAL_HBD_channel);
	fChain->SetBranchAddress("n_TOWER_RAW_C1", &n_TOWER_RAW_C1, &b_n_TOWER_RAW_C1);
	fChain->SetBranchAddress("TOWER_RAW_C1", &TOWER_RAW_C1_, &b_TOWER_RAW_C1_);
	fChain->SetBranchAddress("TOWER_RAW_C1.fUniqueID", TOWER_RAW_C1_fUniqueID, &b_TOWER_RAW_C1_fUniqueID);
	fChain->SetBranchAddress("TOWER_RAW_C1.fBits", TOWER_RAW_C1_fBits, &b_TOWER_RAW_C1_fBits);
	fChain->SetBranchAddress("TOWER_RAW_C1.towerid", TOWER_RAW_C1_towerid, &b_TOWER_RAW_C1_towerid);
	fChain->SetBranchAddress("TOWER_RAW_C1.energy", TOWER_RAW_C1_energy, &b_TOWER_RAW_C1_energy);
	fChain->SetBranchAddress("TOWER_RAW_C1.time", TOWER_RAW_C1_time, &b_TOWER_RAW_C1_time);
	fChain->SetBranchAddress("TOWER_RAW_C1.signal_samples[31]", TOWER_RAW_C1_signal_samples, &b_TOWER_RAW_C1_signal_samples);
	fChain->SetBranchAddress("TOWER_RAW_C1.HBD_channel", TOWER_RAW_C1_HBD_channel, &b_TOWER_RAW_C1_HBD_channel);
	fChain->SetBranchAddress("n_TOWER_CALIB_C1", &n_TOWER_CALIB_C1, &b_n_TOWER_CALIB_C1);
	fChain->SetBranchAddress("TOWER_CALIB_C1", &TOWER_CALIB_C1_, &b_TOWER_CALIB_C1_);
	fChain->SetBranchAddress("TOWER_CALIB_C1.fUniqueID", TOWER_CALIB_C1_fUniqueID, &b_TOWER_CALIB_C1_fUniqueID);
	fChain->SetBranchAddress("TOWER_CALIB_C1.fBits", TOWER_CALIB_C1_fBits, &b_TOWER_CALIB_C1_fBits);
	fChain->SetBranchAddress("TOWER_CALIB_C1.towerid", TOWER_CALIB_C1_towerid, &b_TOWER_CALIB_C1_towerid);
	fChain->SetBranchAddress("TOWER_CALIB_C1.energy", TOWER_CALIB_C1_energy, &b_TOWER_CALIB_C1_energy);
	fChain->SetBranchAddress("TOWER_CALIB_C1.time", TOWER_CALIB_C1_time, &b_TOWER_CALIB_C1_time);
	fChain->SetBranchAddress("TOWER_CALIB_C1.signal_samples[31]", TOWER_CALIB_C1_signal_samples, &b_TOWER_CALIB_C1_signal_samples);
	fChain->SetBranchAddress("TOWER_CALIB_C1.HBD_channel", TOWER_CALIB_C1_HBD_channel, &b_TOWER_CALIB_C1_HBD_channel);
	fChain->SetBranchAddress("n_TOWER_RAW_C2", &n_TOWER_RAW_C2, &b_n_TOWER_RAW_C2);
	fChain->SetBranchAddress("TOWER_RAW_C2", &TOWER_RAW_C2_, &b_TOWER_RAW_C2_);
	fChain->SetBranchAddress("TOWER_RAW_C2.fUniqueID", TOWER_RAW_C2_fUniqueID, &b_TOWER_RAW_C2_fUniqueID);
	fChain->SetBranchAddress("TOWER_RAW_C2.fBits", TOWER_RAW_C2_fBits, &b_TOWER_RAW_C2_fBits);
	fChain->SetBranchAddress("TOWER_RAW_C2.towerid", TOWER_RAW_C2_towerid, &b_TOWER_RAW_C2_towerid);
	fChain->SetBranchAddress("TOWER_RAW_C2.energy", TOWER_RAW_C2_energy, &b_TOWER_RAW_C2_energy);
	fChain->SetBranchAddress("TOWER_RAW_C2.time", TOWER_RAW_C2_time, &b_TOWER_RAW_C2_time);
	fChain->SetBranchAddress("TOWER_RAW_C2.signal_samples[31]", TOWER_RAW_C2_signal_samples, &b_TOWER_RAW_C2_signal_samples);
	fChain->SetBranchAddress("TOWER_RAW_C2.HBD_channel", TOWER_RAW_C2_HBD_channel, &b_TOWER_RAW_C2_HBD_channel);
	fChain->SetBranchAddress("n_TOWER_CALIB_C2", &n_TOWER_CALIB_C2, &b_n_TOWER_CALIB_C2);
	fChain->SetBranchAddress("TOWER_CALIB_C2", &TOWER_CALIB_C2_, &b_TOWER_CALIB_C2_);
	fChain->SetBranchAddress("TOWER_CALIB_C2.fUniqueID", TOWER_CALIB_C2_fUniqueID, &b_TOWER_CALIB_C2_fUniqueID);
	fChain->SetBranchAddress("TOWER_CALIB_C2.fBits", TOWER_CALIB_C2_fBits, &b_TOWER_CALIB_C2_fBits);
	fChain->SetBranchAddress("TOWER_CALIB_C2.towerid", TOWER_CALIB_C2_towerid, &b_TOWER_CALIB_C2_towerid);
	fChain->SetBranchAddress("TOWER_CALIB_C2.energy", TOWER_CALIB_C2_energy, &b_TOWER_CALIB_C2_energy);
	fChain->SetBranchAddress("TOWER_CALIB_C2.time", TOWER_CALIB_C2_time, &b_TOWER_CALIB_C2_time);
	fChain->SetBranchAddress("TOWER_CALIB_C2.signal_samples[31]", TOWER_CALIB_C2_signal_samples, &b_TOWER_CALIB_C2_signal_samples);
	fChain->SetBranchAddress("TOWER_CALIB_C2.HBD_channel", TOWER_CALIB_C2_HBD_channel, &b_TOWER_CALIB_C2_HBD_channel);
	fChain->SetBranchAddress("n_TOWER_RAW_PbGL", &n_TOWER_RAW_PbGL, &b_n_TOWER_RAW_PbGL);
	fChain->SetBranchAddress("TOWER_RAW_PbGL", &TOWER_RAW_PbGL_, &b_TOWER_RAW_PbGL_);
	fChain->SetBranchAddress("TOWER_RAW_PbGL.fUniqueID", TOWER_RAW_PbGL_fUniqueID, &b_TOWER_RAW_PbGL_fUniqueID);
	fChain->SetBranchAddress("TOWER_RAW_PbGL.fBits", TOWER_RAW_PbGL_fBits, &b_TOWER_RAW_PbGL_fBits);
	fChain->SetBranchAddress("TOWER_RAW_PbGL.towerid", TOWER_RAW_PbGL_towerid, &b_TOWER_RAW_PbGL_towerid);
	fChain->SetBranchAddress("TOWER_RAW_PbGL.energy", TOWER_RAW_PbGL_energy, &b_TOWER_RAW_PbGL_energy);
	fChain->SetBranchAddress("TOWER_RAW_PbGL.time", TOWER_RAW_PbGL_time, &b_TOWER_RAW_PbGL_time);
	fChain->SetBranchAddress("TOWER_RAW_PbGL.signal_samples[31]", TOWER_RAW_PbGL_signal_samples, &b_TOWER_RAW_PbGL_signal_samples);
	fChain->SetBranchAddress("TOWER_RAW_PbGL.HBD_channel", TOWER_RAW_PbGL_HBD_channel, &b_TOWER_RAW_PbGL_HBD_channel);
	fChain->SetBranchAddress("n_TOWER_CALIB_PbGL", &n_TOWER_CALIB_PbGL, &b_n_TOWER_CALIB_PbGL);
	fChain->SetBranchAddress("TOWER_CALIB_PbGL", &TOWER_CALIB_PbGL_, &b_TOWER_CALIB_PbGL_);
	fChain->SetBranchAddress("TOWER_CALIB_PbGL.fUniqueID", TOWER_CALIB_PbGL_fUniqueID, &b_TOWER_CALIB_PbGL_fUniqueID);
	fChain->SetBranchAddress("TOWER_CALIB_PbGL.fBits", TOWER_CALIB_PbGL_fBits, &b_TOWER_CALIB_PbGL_fBits);
	fChain->SetBranchAddress("TOWER_CALIB_PbGL.towerid", TOWER_CALIB_PbGL_towerid, &b_TOWER_CALIB_PbGL_towerid);
	fChain->SetBranchAddress("TOWER_CALIB_PbGL.energy", TOWER_CALIB_PbGL_energy, &b_TOWER_CALIB_PbGL_energy);
	fChain->SetBranchAddress("TOWER_CALIB_PbGL.time", TOWER_CALIB_PbGL_time, &b_TOWER_CALIB_PbGL_time);
	fChain->SetBranchAddress("TOWER_CALIB_PbGL.signal_samples[31]", TOWER_CALIB_PbGL_signal_samples, &b_TOWER_CALIB_PbGL_signal_samples);
	fChain->SetBranchAddress("TOWER_CALIB_PbGL.HBD_channel", TOWER_CALIB_PbGL_HBD_channel, &b_TOWER_CALIB_PbGL_HBD_channel);
	fChain->SetBranchAddress("n_TOWER_RAW_TRIGGER_VETO", &n_TOWER_RAW_TRIGGER_VETO, &b_n_TOWER_RAW_TRIGGER_VETO);
	fChain->SetBranchAddress("TOWER_RAW_TRIGGER_VETO", &TOWER_RAW_TRIGGER_VETO_, &b_TOWER_RAW_TRIGGER_VETO_);
	fChain->SetBranchAddress("TOWER_RAW_TRIGGER_VETO.fUniqueID", TOWER_RAW_TRIGGER_VETO_fUniqueID, &b_TOWER_RAW_TRIGGER_VETO_fUniqueID);
	fChain->SetBranchAddress("TOWER_RAW_TRIGGER_VETO.fBits", TOWER_RAW_TRIGGER_VETO_fBits, &b_TOWER_RAW_TRIGGER_VETO_fBits);
	fChain->SetBranchAddress("TOWER_RAW_TRIGGER_VETO.towerid", TOWER_RAW_TRIGGER_VETO_towerid, &b_TOWER_RAW_TRIGGER_VETO_towerid);
	fChain->SetBranchAddress("TOWER_RAW_TRIGGER_VETO.energy", TOWER_RAW_TRIGGER_VETO_energy, &b_TOWER_RAW_TRIGGER_VETO_energy);
	fChain->SetBranchAddress("TOWER_RAW_TRIGGER_VETO.time", TOWER_RAW_TRIGGER_VETO_time, &b_TOWER_RAW_TRIGGER_VETO_time);
	fChain->SetBranchAddress("TOWER_RAW_TRIGGER_VETO.signal_samples[31]", TOWER_RAW_TRIGGER_VETO_signal_samples, &b_TOWER_RAW_TRIGGER_VETO_signal_samples);
	fChain->SetBranchAddress("TOWER_RAW_TRIGGER_VETO.HBD_channel", TOWER_RAW_TRIGGER_VETO_HBD_channel, &b_TOWER_RAW_TRIGGER_VETO_HBD_channel);
	fChain->SetBranchAddress("n_TOWER_CALIB_TRIGGER_VETO", &n_TOWER_CALIB_TRIGGER_VETO, &b_n_TOWER_CALIB_TRIGGER_VETO);
	fChain->SetBranchAddress("TOWER_CALIB_TRIGGER_VETO", &TOWER_CALIB_TRIGGER_VETO_, &b_TOWER_CALIB_TRIGGER_VETO_);
	fChain->SetBranchAddress("TOWER_CALIB_TRIGGER_VETO.fUniqueID", TOWER_CALIB_TRIGGER_VETO_fUniqueID, &b_TOWER_CALIB_TRIGGER_VETO_fUniqueID);
	fChain->SetBranchAddress("TOWER_CALIB_TRIGGER_VETO.fBits", TOWER_CALIB_TRIGGER_VETO_fBits, &b_TOWER_CALIB_TRIGGER_VETO_fBits);
	fChain->SetBranchAddress("TOWER_CALIB_TRIGGER_VETO.towerid", TOWER_CALIB_TRIGGER_VETO_towerid, &b_TOWER_CALIB_TRIGGER_VETO_towerid);
	fChain->SetBranchAddress("TOWER_CALIB_TRIGGER_VETO.energy", TOWER_CALIB_TRIGGER_VETO_energy, &b_TOWER_CALIB_TRIGGER_VETO_energy);
	fChain->SetBranchAddress("TOWER_CALIB_TRIGGER_VETO.time", TOWER_CALIB_TRIGGER_VETO_time, &b_TOWER_CALIB_TRIGGER_VETO_time);
	fChain->SetBranchAddress("TOWER_CALIB_TRIGGER_VETO.signal_samples[31]", TOWER_CALIB_TRIGGER_VETO_signal_samples, &b_TOWER_CALIB_TRIGGER_VETO_signal_samples);
	fChain->SetBranchAddress("TOWER_CALIB_TRIGGER_VETO.HBD_channel", TOWER_CALIB_TRIGGER_VETO_HBD_channel, &b_TOWER_CALIB_TRIGGER_VETO_HBD_channel);
	fChain->SetBranchAddress("n_TOWER_RAW_TILE_MAPPER", &n_TOWER_RAW_TILE_MAPPER, &b_n_TOWER_RAW_TILE_MAPPER);
	fChain->SetBranchAddress("TOWER_RAW_TILE_MAPPER", &TOWER_RAW_TILE_MAPPER_, &b_TOWER_RAW_TILE_MAPPER_);
	fChain->SetBranchAddress("TOWER_RAW_TILE_MAPPER.fUniqueID", TOWER_RAW_TILE_MAPPER_fUniqueID, &b_TOWER_RAW_TILE_MAPPER_fUniqueID);
	fChain->SetBranchAddress("TOWER_RAW_TILE_MAPPER.fBits", TOWER_RAW_TILE_MAPPER_fBits, &b_TOWER_RAW_TILE_MAPPER_fBits);
	fChain->SetBranchAddress("TOWER_RAW_TILE_MAPPER.towerid", TOWER_RAW_TILE_MAPPER_towerid, &b_TOWER_RAW_TILE_MAPPER_towerid);
	fChain->SetBranchAddress("TOWER_RAW_TILE_MAPPER.energy", TOWER_RAW_TILE_MAPPER_energy, &b_TOWER_RAW_TILE_MAPPER_energy);
	fChain->SetBranchAddress("TOWER_RAW_TILE_MAPPER.time", TOWER_RAW_TILE_MAPPER_time, &b_TOWER_RAW_TILE_MAPPER_time);
	fChain->SetBranchAddress("TOWER_RAW_TILE_MAPPER.signal_samples[31]", TOWER_RAW_TILE_MAPPER_signal_samples, &b_TOWER_RAW_TILE_MAPPER_signal_samples);
	fChain->SetBranchAddress("TOWER_RAW_TILE_MAPPER.HBD_channel", TOWER_RAW_TILE_MAPPER_HBD_channel, &b_TOWER_RAW_TILE_MAPPER_HBD_channel);
	fChain->SetBranchAddress("n_TOWER_CALIB_TILE_MAPPER", &n_TOWER_CALIB_TILE_MAPPER, &b_n_TOWER_CALIB_TILE_MAPPER);
	fChain->SetBranchAddress("TOWER_CALIB_TILE_MAPPER", &TOWER_CALIB_TILE_MAPPER_, &b_TOWER_CALIB_TILE_MAPPER_);
	fChain->SetBranchAddress("TOWER_CALIB_TILE_MAPPER.fUniqueID", TOWER_CALIB_TILE_MAPPER_fUniqueID, &b_TOWER_CALIB_TILE_MAPPER_fUniqueID);
	fChain->SetBranchAddress("TOWER_CALIB_TILE_MAPPER.fBits", TOWER_CALIB_TILE_MAPPER_fBits, &b_TOWER_CALIB_TILE_MAPPER_fBits);
	fChain->SetBranchAddress("TOWER_CALIB_TILE_MAPPER.towerid", TOWER_CALIB_TILE_MAPPER_towerid, &b_TOWER_CALIB_TILE_MAPPER_towerid);
	fChain->SetBranchAddress("TOWER_CALIB_TILE_MAPPER.energy", TOWER_CALIB_TILE_MAPPER_energy, &b_TOWER_CALIB_TILE_MAPPER_energy);
	fChain->SetBranchAddress("TOWER_CALIB_TILE_MAPPER.time", TOWER_CALIB_TILE_MAPPER_time, &b_TOWER_CALIB_TILE_MAPPER_time);
	fChain->SetBranchAddress("TOWER_CALIB_TILE_MAPPER.signal_samples[31]", TOWER_CALIB_TILE_MAPPER_signal_samples, &b_TOWER_CALIB_TILE_MAPPER_signal_samples);
	fChain->SetBranchAddress("TOWER_CALIB_TILE_MAPPER.HBD_channel", TOWER_CALIB_TILE_MAPPER_HBD_channel, &b_TOWER_CALIB_TILE_MAPPER_HBD_channel);
	fChain->SetBranchAddress("n_TOWER_RAW_SC3", &n_TOWER_RAW_SC3, &b_n_TOWER_RAW_SC3);
	fChain->SetBranchAddress("TOWER_RAW_SC3", &TOWER_RAW_SC3_, &b_TOWER_RAW_SC3_);
	fChain->SetBranchAddress("TOWER_RAW_SC3.fUniqueID", TOWER_RAW_SC3_fUniqueID, &b_TOWER_RAW_SC3_fUniqueID);
	fChain->SetBranchAddress("TOWER_RAW_SC3.fBits", TOWER_RAW_SC3_fBits, &b_TOWER_RAW_SC3_fBits);
	fChain->SetBranchAddress("TOWER_RAW_SC3.towerid", TOWER_RAW_SC3_towerid, &b_TOWER_RAW_SC3_towerid);
	fChain->SetBranchAddress("TOWER_RAW_SC3.energy", TOWER_RAW_SC3_energy, &b_TOWER_RAW_SC3_energy);
	fChain->SetBranchAddress("TOWER_RAW_SC3.time", TOWER_RAW_SC3_time, &b_TOWER_RAW_SC3_time);
	fChain->SetBranchAddress("TOWER_RAW_SC3.signal_samples[31]", TOWER_RAW_SC3_signal_samples, &b_TOWER_RAW_SC3_signal_samples);
	fChain->SetBranchAddress("TOWER_RAW_SC3.HBD_channel", TOWER_RAW_SC3_HBD_channel, &b_TOWER_RAW_SC3_HBD_channel);
	fChain->SetBranchAddress("n_TOWER_CALIB_SC3", &n_TOWER_CALIB_SC3, &b_n_TOWER_CALIB_SC3);
	fChain->SetBranchAddress("TOWER_CALIB_SC3", &TOWER_CALIB_SC3_, &b_TOWER_CALIB_SC3_);
	fChain->SetBranchAddress("TOWER_CALIB_SC3.fUniqueID", TOWER_CALIB_SC3_fUniqueID, &b_TOWER_CALIB_SC3_fUniqueID);
	fChain->SetBranchAddress("TOWER_CALIB_SC3.fBits", TOWER_CALIB_SC3_fBits, &b_TOWER_CALIB_SC3_fBits);
	fChain->SetBranchAddress("TOWER_CALIB_SC3.towerid", TOWER_CALIB_SC3_towerid, &b_TOWER_CALIB_SC3_towerid);
	fChain->SetBranchAddress("TOWER_CALIB_SC3.energy", TOWER_CALIB_SC3_energy, &b_TOWER_CALIB_SC3_energy);
	fChain->SetBranchAddress("TOWER_CALIB_SC3.time", TOWER_CALIB_SC3_time, &b_TOWER_CALIB_SC3_time);
	fChain->SetBranchAddress("TOWER_CALIB_SC3.signal_samples[31]", TOWER_CALIB_SC3_signal_samples, &b_TOWER_CALIB_SC3_signal_samples);
	fChain->SetBranchAddress("TOWER_CALIB_SC3.HBD_channel", TOWER_CALIB_SC3_HBD_channel, &b_TOWER_CALIB_SC3_HBD_channel);
	fChain->SetBranchAddress("n_TOWER_RAW_FINGER_COUNTER", &n_TOWER_RAW_FINGER_COUNTER, &b_n_TOWER_RAW_FINGER_COUNTER);
	fChain->SetBranchAddress("TOWER_RAW_FINGER_COUNTER", &TOWER_RAW_FINGER_COUNTER_, &b_TOWER_RAW_FINGER_COUNTER_);
	fChain->SetBranchAddress("TOWER_RAW_FINGER_COUNTER.fUniqueID", TOWER_RAW_FINGER_COUNTER_fUniqueID, &b_TOWER_RAW_FINGER_COUNTER_fUniqueID);
	fChain->SetBranchAddress("TOWER_RAW_FINGER_COUNTER.fBits", TOWER_RAW_FINGER_COUNTER_fBits, &b_TOWER_RAW_FINGER_COUNTER_fBits);
	fChain->SetBranchAddress("TOWER_RAW_FINGER_COUNTER.towerid", TOWER_RAW_FINGER_COUNTER_towerid, &b_TOWER_RAW_FINGER_COUNTER_towerid);
	fChain->SetBranchAddress("TOWER_RAW_FINGER_COUNTER.energy", TOWER_RAW_FINGER_COUNTER_energy, &b_TOWER_RAW_FINGER_COUNTER_energy);
	fChain->SetBranchAddress("TOWER_RAW_FINGER_COUNTER.time", TOWER_RAW_FINGER_COUNTER_time, &b_TOWER_RAW_FINGER_COUNTER_time);
	fChain->SetBranchAddress("TOWER_RAW_FINGER_COUNTER.signal_samples[31]", TOWER_RAW_FINGER_COUNTER_signal_samples, &b_TOWER_RAW_FINGER_COUNTER_signal_samples);
	fChain->SetBranchAddress("TOWER_RAW_FINGER_COUNTER.HBD_channel", TOWER_RAW_FINGER_COUNTER_HBD_channel, &b_TOWER_RAW_FINGER_COUNTER_HBD_channel);
	fChain->SetBranchAddress("n_TOWER_CALIB_FINGER_COUNTER", &n_TOWER_CALIB_FINGER_COUNTER, &b_n_TOWER_CALIB_FINGER_COUNTER);
	fChain->SetBranchAddress("TOWER_CALIB_FINGER_COUNTER", &TOWER_CALIB_FINGER_COUNTER_, &b_TOWER_CALIB_FINGER_COUNTER_);
	fChain->SetBranchAddress("TOWER_CALIB_FINGER_COUNTER.fUniqueID", TOWER_CALIB_FINGER_COUNTER_fUniqueID, &b_TOWER_CALIB_FINGER_COUNTER_fUniqueID);
	fChain->SetBranchAddress("TOWER_CALIB_FINGER_COUNTER.fBits", TOWER_CALIB_FINGER_COUNTER_fBits, &b_TOWER_CALIB_FINGER_COUNTER_fBits);
	fChain->SetBranchAddress("TOWER_CALIB_FINGER_COUNTER.towerid", TOWER_CALIB_FINGER_COUNTER_towerid, &b_TOWER_CALIB_FINGER_COUNTER_towerid);
	fChain->SetBranchAddress("TOWER_CALIB_FINGER_COUNTER.energy", TOWER_CALIB_FINGER_COUNTER_energy, &b_TOWER_CALIB_FINGER_COUNTER_energy);
	fChain->SetBranchAddress("TOWER_CALIB_FINGER_COUNTER.time", TOWER_CALIB_FINGER_COUNTER_time, &b_TOWER_CALIB_FINGER_COUNTER_time);
	fChain->SetBranchAddress("TOWER_CALIB_FINGER_COUNTER.signal_samples[31]", TOWER_CALIB_FINGER_COUNTER_signal_samples, &b_TOWER_CALIB_FINGER_COUNTER_signal_samples);
	fChain->SetBranchAddress("TOWER_CALIB_FINGER_COUNTER.HBD_channel", TOWER_CALIB_FINGER_COUNTER_HBD_channel, &b_TOWER_CALIB_FINGER_COUNTER_HBD_channel);
	Notify();
}

Bool_t DSTReader551::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 normally 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;
}

void DSTReader551::Show(Long64_t entry)
{
	// Print contents of entry.
	// If entry is not specified, print current entry
	if (!fChain) return;
	fChain->Show(entry);
}
Int_t DSTReader551::Cut(Long64_t entry)
{
	// This function may be called from Loop.
	// returns  1 if entry is accepted.
	// returns -1 otherwise.
	return 1;
}

//this function has been changed from the auto generated one to interface with OffcialBeamData
OfficalBeamData* DSTReader551::Loop(int number, bool makeSidePlots=true)
{
	if (fChain == 0) return NULL;
	fChain->GetEntry(1);
	//the files have the beam energy in them except for this one 
	if(number == 567){beam_MTNRG_GeV = 8;}
	OfficalBeamData *tally = new OfficalBeamData(number,runToVoltage(number),TMath::Abs(beam_MTNRG_GeV),makeSidePlots);
	Long64_t nentries = fChain->GetEntriesFast();

	Long64_t nbytes = 0, nb = 0;
	for (Long64_t jentry=1; jentry<nentries; jentry++) {
		Long64_t ientry = LoadTree(jentry);
		if (ientry < 0) break;
		nb = fChain->GetEntry(jentry);   nbytes += nb;
		tally->add(TOWER_CALIB_C2_energy[1],TOWER_CALIB_TRIGGER_VETO_energy,TOWER_CALIB_HODO_HORIZONTAL_energy,TOWER_CALIB_HODO_VERTICAL_energy,TOWER_CALIB_PbGL_energy[0]);

		if(jentry%10000==0) cout<<jentry<<" events entered"<<'\n';
	}
	return tally;
}

int* runToEnergy(int* runs, int SIZE){
	int *energies = new int[SIZE];
	for (int i = 0; i < SIZE; ++i)
	{
		energies[i] = runToEnergy(runs[i]);
	}
	return energies;
}
int* runToVoltage(int* runs, int SIZE){
	int *voltages = new int[SIZE];
	for (int i = 0; i < SIZE; ++i)
	{
		voltages[i] = runToVoltage(runs[i]);
	}
	return &voltages[0];
}

//this is used to organize the output text files in increasing beam energy 
void superArraySorter5000(float* energies, float* mean, float* meanError, float* sigma, float* sigmaError,int* runNumber,int SIZE)
{
	int i, j;

	for (i = 0; i < SIZE-1; i++) 
	{  
		for (j = 0; j < SIZE-i-1; j++) 
		{
			if (energies[j] > energies[j+1])
			{
				oleSwitcheroo(&energies[j],&energies[j+1]);
				oleSwitcheroo(&mean[j],&mean[j+1]);
				oleSwitcheroo(&meanError[j],&meanError[j+1]);
				oleSwitcheroo(&sigma[j],&sigma[j+1]);
				oleSwitcheroo(&sigmaError[j],&sigmaError[j+1]);
				oleSwitcheroo(&runNumber[j],&runNumber[j+1]);
			}
		}
	}
}

/*this is the main program which selects which files to read and then calls 
OfficialBeamData and formats a text file to output*/
void Part2A(){
	//The first few lines set up what files you want 
	int voltageSelection=1000; //choose what voltage to run 
	bool newData=true;  //do you want the new dataset or the old one 
	//uses your choices to initialize a FCTOR to select the files 
	RunSelecTOR selecTOR(newData,true,voltageSelection); //newData, checkvoltage,voltage
	string fileLocation = "/Users/naglelab/Documents/FranData/FTB/"; 
	//the actualy filename is expected to have the format BEGINNING-NUMBER-END
	string filename = "beam_0000";
	string filenameleadingzero = "beam_00000";
	string extension = "-0000_DSTReader.root";
	filename = fileLocation+filename;
	filenameleadingzero=fileLocation+filenameleadingzero;
	//input the total numbe of data files you have not just the ones you wabt 
	const int totalNUMSIZE=47;
	//set of all the files
	int totalnumber[] = {2045,1879,1882,1883,1888,1889,1890,1901,1902,1906,1925,1926,1943,1945,2073,2074,2094,2095,2097,2098,2126,2127,2149,2150,2167,631,632,558,551,563,544,652,653,654,687,772,773,776,777,809,810,829,830,849,859,574,567 }; //all,beam,files
	//////////////////////////////////////////////////////////
	//saturated : 573 572 2125 2128 1924 //don't change this list its for Francesco
	//undersaturated: 578 579 580 1904   //if you are not fran this is not for you
	////////////////////////////////////////////////////
	int NUMSIZE= totalNUMSIZE; // sorry bad programming had to make a u-sub 
	int* number = selecTOR(&totalnumber[0],&NUMSIZE); // gets the number of files to process 
	//get the ROOT made class to process the tree from the beam you want
	DSTReader551 *reader; 
	TFile *file;
	stringstream ss;
	float mean[NUMSIZE];
	float meanU[NUMSIZE];
	float sigma[NUMSIZE];
	float sigmaU[NUMSIZE];
	float energy[NUMSIZE];
	for (int i = 0; i < NUMSIZE; ++i)//loop over beam files
	{
		if(number[i]>1000){
			fileLocation = filename+to_string(number[i])+extension;
		}
		else{
			fileLocation = filenameleadingzero+to_string(number[i])+extension;
		}
		file = new TFile(fileLocation.c_str());
		TTree *orange= (TTree*) file->Get("T");
		reader = new DSTReader551(orange,fileLocation);  
		OfficalBeamData* data = reader->Loop(number[i],true); // call the loop method for the reader you have, this fills data structures
		//decide what data you want from the OfficalBeamData
		//data->plotVeto(1);
		//data->SaveMainHist();
		//cout<<"Res:"<<data->getResolution()<<'\n';
		//use these to make the text file
		mean[i] =data->getMean();
		meanU[i]=data->getMeanUncertainty();
		sigma[i]=data->getSigma();
		sigmaU[i]=data->getSigmaUncertainty();
		energy[i]=data->getEnergy();
		string bigname = to_string(number[i])+": "+to_string(runToEnergy(number[i]))+"GeV "+to_string(runToVoltage(number[i]))+"V";
		data->makeBigPlot(bigname);
		//data->printCutPlot();
		data->SaveMainHist();
		//data->fitPlot("fit3");
		//data->compareHodo(number[i]);
		//cout<<"Energy:"<<energy[i]<<'\n';
		data->plot();
		cout<<fileLocation<<'\n';
		file->Close();
		delete file;
		delete data;
		delete reader;
	}
	//organize the output file
	superArraySorter5000(energy,mean,meanU,sigma,sigmaU,number,NUMSIZE); //sort all arrays so that it goes in ascending energy order
	//output the file 
	ofstream outFile;
	outFile.open(selecTOR.getName().c_str());

	if(outFile.is_open()) //read info out to txt file if it opens
	{
		cout<<"File Opened!"<<endl;

		outFile << "RunNumber";
		for(int i = 0; i < NUMSIZE; i++) //enter all run numbers into txt file
		{
			outFile << ","<< number[i];
		}
		outFile << "\n";
		outFile << "Mean";
		for(int i = 0; i < NUMSIZE; i++) //enter all mean values into txt file
		{
			outFile << ","<< mean[i];
		}
		outFile << "\n";
		outFile << "MeanUncertainty";
		for(int i = 0; i < NUMSIZE; i++) //enter all mean values into txt file
		{
			outFile << ","<< meanU[i];
		}
		outFile << "\n";
		outFile << "Sigma";
		for(int i = 0; i < NUMSIZE; i++) //enter all signma values into txt file
		{
			outFile << ","<< sigma[i];
		}
		outFile << "\n";
		outFile << "SigmaUncertainty";
		for(int i = 0; i < NUMSIZE; i++) //enter all signma values into txt file
		{
			outFile << ","<< sigmaU[i];
		}
		outFile << "\n";
		outFile << "Energy";
		for(int i = 0; i < NUMSIZE; i++) //enter all signma values into txt file
		{
			outFile << ","<< energy[i];
		}
		outFile << "\n";

		outFile.close();
	}
	else {cout<<"RED ALERT! RED ALERT! FAILED TO WRITE TO A TEXT FILE! I REPEAT! RED ALERT!"<<endl;}

	cout<<"End"<<std::endl;
}
//everything past here is just run level information about the files 
int runToEnergy(int run){
	int r;
	int s = (int) run;
	switch (s){
		case 558:
			r=6;
			break;
		case 551:
			r= 4;
			break;
		case 563:
			r= 2;
			break;
		case 573:
			r= 12;
			break;
		case 567:
			r= 8;
			break;
		case 776:
			r=2;
			break;
		case 777:
			r=2;
			break;
		case 809:
			r=6;
			break;
		case 810:
			r=4;
			break;
		case 816:
			r=2;
			break;
		case 829:
			r=6;
			break;
		case 830:
			r=2;
			break;
		case 849:
			r=2;
			break;
		case 859:
			r=5;
			break;
		case 900:
			r=1;
			break;
		case 631:
			r=8;
			break;
		case 632:
			r=12;
			break;
		case 544:
			r= 8;
			break;
		case 652:
			r= 16;
			break;
		case 653:
			r= 16;
			break;
		case 654:
			r= 24;
			break;
		case 687:
			r= 28;
			break;
		case 572:
			r= 12;
			break;
		case 574:
			r= 12;
			break;
		case 577:
			r= 2;
			break;
		case 578:
			r= 2;
			break;
		case 579:
			r= 2;
			break;	
		case 580:
			r=2;
			break;
		case 1876:
			r=8; break;
		case 1879:
			r=8; break;
		case 1882:
			r=8; break;
		case 1883:
			r=8; break;
		case 1888:
			r=8; break;
		case 1890:
			r=6; break;
		case 2128:
			r=16; break;
		case 2125:
			r=12; break;
		case 2126:
			r=12; break;
		case 2127:
			r=16; break;
		case 1889:
			r=6; break;
		case 1901:
			r=4; break;
		case 1902:
			r=4; break;
		case 1904:
			r=2; break;
		case 1906:
			r=2; break;
		case 1924:
			r=12; break;
		case 1925:
			r=12; break;
		case 1943:
			r=24; break;
		case 1945:
			r=28; break;
		case 2073:
			r=3; break;
		case 2074:
			r=4; break;
		case 2094:
			r=6; break;
		case 2095:
			r=6; break;
		case 2097:
			r=8; break;
		case 2098:
			r=8; break;
		case 2149:
			r=20; break;
		case 2150:
			r=24; break;
		case 2167:
			r=28; break;
		case 773:
			r=10;
			break;
		case 772:
			r=10;
			break;
		case 1926:
			r=16; 
			break;
		case 2045:
			r=2; 
			break;
		default:
			r=-1;
			cout<<"Error in runToEnergy line:"<<__LINE__<<std::endl;
			break;
	}
	return r;
}

int runToVoltage(int run){
	int r;
	int s = (int) run;

	switch (s){
		case 1876:
			r=1100;//guess
			break;
		case 2045:
			r=1200; 
			break;
		case 1926:
			r=1100; 
			break;
		case 2167:
			r=1000; 
			break;
		case 1945:
			r=1000; 
			break;
		case 2150:
			r=1000;
			break;
		case 1943:
			r=1000;
			break;
		case 2149:
			r=1000;
			break;
		case 1924:
			r=1200;
			break;
		case 1925:
			r=1100;
			break;
		case 2125:
			r=1200;
			break;
		case 2126:
			r=1100;
			break;
		case 632:
			r=1100;
			break;
		case 773:
			r=-1;
			break;
		case 772:
			r=-1;
			break;
		case 1901:
			r=1200;
			break;
		case 2074:
			r=1200;
			break;
		case 2094:
			r=1200;
			break;
		case 2095:
			r=1100;
			break;
		case 1889:
			r=1100;
			break;
		case 2127:
			r=1100;
			break;
		case 2128: // probably saturated 
			r=1200;
			break;
		case 2098:
			r=1200;
			break;
		case 1883:
			r=1200;
			break;
		case 1882:
			r=1200;
			break;
		case 1879:
			r=1200;
			break;
		case 1906:
			r=1200;
			break;
		case 900: //may need to test this at 1100V 
			r=1200;
			break;
		case 1904:
			r=1100;
			break;
		case 2073:
			r=1200;
			break;
		case 2097:
			r=1100;
			break;
		case 1888:
			r=1100;
			break;
		case 1890:
			r=1200;
			break;
		case 1902:
			r=1100;
			break;
		case 558:
			r=1200;
			break;
		case 551:
			r= 1200;
			break;
		case 563:
			r= 1200;
			break;
		case 573: //saturated
			r= 00;
			break;
		case 567:
			r= 1200;
			break;
		case 776:
			r=1200;
			break;
		case 777:
			r=1200;
			break;
		case 809:
			r=1200;
			break;
		case 810:
			r=1200;
			break;
		case 816:  
			r=1200;
			break;
		case 829:
			r=1200;
			break;
		case 830:
			r=1200;
			break;
		case 849:
			r=1200;
			break;
		case 859:
			r=1200;
			break;
		case 631: // not in list 
			r=1100; 
			break;
		case 544:
			r= 1100;
			break;
		case 652:
			r= 1100;
			break;
		case 653:
			r= 1000;
			break;
		case 654:
			r= 1000;
			break;
		case 687: // saturated 1100V run  28GeV
			r= 1000;
			break;
		case 572:
			r= 0;
			break;
		case 574:
			r= 1100;
			break;
		case 577:
			r= 1100;
			break;
		case 578:
			r= 1100;
			break;
		case 579:
			r= 1100;
			break;	
		case 580:
			r=1100;
			break;
		default:
			r=0;
			cout<<"warning voltage not found for run:"<<run<<std::endl;
			break;
	}
	return r;
}