SOLARIS_Analysis/working/Monitors.C

#define Monitors_cxx

#include <TH2.h>
#include <TH1.h>
#include <TF1.h>
#include <TStyle.h>
#include <TCutG.h>
#include <TGraph.h>
#include <TMath.h>
#include <TMultiGraph.h>
#include <TString.h>
#include <TLatex.h>
#include <TSystem.h>
#include <TMacro.h>
#include <TLine.h>
#include <TStopwatch.h>
#include <TCanvas.h>
#include <TBox.h>
#include <TDatime.h>
#include <TMD5.h>
#include <TObjArray.h>
#include <fstream>
#include <vector>
#include "../Cleopatra/Isotope.h"
#include "Mapping.h"

using namespace std;

//############################################ User setting
ULong64_t maxNumberEvent = 1000000000;

//---histogram setting
int rawEnergyRange[2] = {   100,    4000};       /// share with e, xf, xn
int    energyRange[2] = {     0,      10};       /// in the E-Z plot
int     rdtDERange[2] = {     0,      80}; 
int      rdtERange[2] = {     0,      80};
int   thetaCMRange[2] = {0, 80};

double     exRange[3] = {  100,    -2,     10};  /// bin [keV], low[MeV], high[MeV]

int  coinTimeRange[2] = { -200, 200};
int  timeRangeUser[2] = {0, 99999999}; /// min, use when cannot find time, this set the min and max

bool isUseArrayTrace = false;
bool isUseRDTTrace = false;

//---Gate
bool isTimeGateOn     = true;
int timeGate[2]       = {-20, 12};             /// min, max, 1 ch = 10 ns
double eCalCut[2]     = {0.5, 50};             /// lower & higher limit for eCal
int dEgate[2]         = {  500,  1500};
int Eresgate[2]       = { 1000,  4000};
double thetaCMGate    = 10;                    /// deg
double xGate          = 0.9;                  ///cut out the edge
vector<int> skipDetID = {11, 16, 23} ;//{2,  11, 17}

TString rdtCutFile1 = "";
TString rdtCutFile2 = "";
TString ezCutFile   = "";//"ezCut.root";

//############################################ end of user setting
/******************************************************************
*   variable and histogram naming rules                           *
*   name are case sensitive, so as any C/C++ code                 *
*                                                                 *
*   ID is dettector ID                                            *
*                                                                 *
*   raw data from gen_tree are e, xf, xn, ring.                   *
*   the x from raw data is x                                      *
*                                                                 *
*   xf + xn = xs, s for sum                                       *
*                                                                 *
*   calibrated data are  eCal, xfCal, xnCal, ringCal.             *
*   the x from cal data is xCal                                   *
*                                                                 *
*   xfCal + xnCal = xsCal                                         *
*                                                                 *
*   since the z is always from xCal, so it calls z.               *
*                                                                 *
*   Excitation energy calls Ex                                    *
*                                                                 *
*                                                                 *
*   TH2D is always using "V" to seperate 2 variables, like eVx    *
*                                                                 *
*  histogram with TCutG, add suffix "GC" for Graphical-Cut.       *
*                                                                 *
*******************************************************************/
//======== raw data
TH1F** he;
TH1F** hxf;
TH1F** hxn;

TH2F** hxfVxn;
TH2F** heVxs;

TH1F* hMultiHit; 
TH2F** heVx; // e vs (xf-xn)/e

TH2F* heVID;
TH2F* hxfVID;
TH2F* hxnVID;

//====== cal data
TH1F** heCal;
TH2F** hxfCalVxnCal; 
TH2F** heVxsCal; // raw e vs xf
TH2F** heCalVxCal; // eCal vs xCal
TH2F** heCalVxCalG; // eCal vs xCal

TH2F* heCalID; // e vs detID
TH2F* heCalVz;
TH2F* heCalVzGC;
TH2F** hecalVzRow;

//====== Ex data
TH1F* hEx;
TH1F** hExi;
TH2F** hExVxCal;

TH2F* hExThetaCM;

TH1F* hExCut1;
TH1F* hExCut2;

//======= Recoil
TH2F* hrdtID;
TH1F** hrdt; // single recoil
TH1F** hrdtg; 

TH2F** hrdt2D;
TH2F** hrdt2Dg;
TH2F** hrdt2Dsum;

TH1F* hrdtRate1;
TH1F* hrdtRate2;

//======= multi-Hit
TH2I *hmult;
TH1I *hmultEZ;
TH2I *hArrayRDTMatrix;
TH2I *hArrayRDTMatrixG;

//======= ARRAY-RDT time diff
TH1I *htdiff;
TH1I *htdiffg;

/***************************
 ***************************/
double zRange[2] = {-1000, 0}; // zMin, zMax

double Ex, thetaCM;
int padID = 0;
TLatex text;

int numCol, numRow;
ULong64_t NumEntries = 0;
ULong64_t ProcessedEntries = 0;
Float_t Frac = 0.1; ///Progress bar
TStopwatch StpWatch;

//======= Canvas
TCanvas *cCanvas;
TString canvasTitle;
int lastRunID;
bool contFlag;
double runTime=0;

//======= Recoil Cut
TCutG* cutG; //!  //general temeprary pointer to cut

TObjArray * cutList1;
TObjArray * cutList2;

//======= Other Cuts
TCutG* EZCut;
Bool_t isEZCutFileOpen;

#include "Monitors.h"

//^###########################################################
//^ * Begin
//^###########################################################
void Monitors::Begin(TTree *tree){

  TString option = GetOption();

  NumEntries = tree->GetEntries();
  
  canvasTitle = GetCanvasTitle();
  lastRunID = -1;
  contFlag = false;
  
  printf("###########################################################\n");
  printf("##########           SOLARIS Monitors.C           #########\n");
  printf("###########################################################\n");
  
  //===================================================== loading parameter
  printf("################## loading parameter files\n"); 
  
  AnalysisLib::LoadDetGeoAndReactionConfigFile();
  AnalysisLib::LoadXNCorr();
  AnalysisLib::LoadXFXN2ECorr();
  AnalysisLib::LoadXScaleCorr();
  AnalysisLib::LoadECorr();
  AnalysisLib::LoadRDTCorr();
  AnalysisLib::LoadReactionParas(true);

  if( (int) AnalysisLib::xnCorr.size()    < mapping::NARRAY ) { isXNCorrOK = false;     printf("!!!!!!!! size of xnCorr < NARRAY .\n"); }
  if( (int) AnalysisLib::xfxneCorr.size() < mapping::NARRAY ) { isXFXNCorrOK = false;   printf("!!!!!!!! size of xfxneCorr < NARRAY .\n"); }
  if( (int) AnalysisLib::eCorr.size()     < mapping::NARRAY ) { isXScaleCorrOK = false; printf("!!!!!!!! size of eCorr < NARRAY .\n"); }
  if( (int) AnalysisLib::xScale.size()    < mapping::NARRAY ) { isECorrOK = false;      printf("!!!!!!!! size of xScale < NARRAY .\n"); }
  if( (int) AnalysisLib::rdtCorr.size()   < mapping::NRDT   ) { isRDTCorrOK = false;    printf("!!!!!!!! size of rdtCorr < NRDT .\n"); }

  numRow = AnalysisLib::detGeo.nDet;
  numCol = mapping::NARRAY/numRow;

  //================  Get Recoil cuts;
  cutG = new TCutG();

  cutList1 = AnalysisLib::LoadListOfTCut(rdtCutFile1, "cutList");
  cutList2 = AnalysisLib::LoadListOfTCut(rdtCutFile2, "cutList");
  
  //================  Get EZ cuts;
  EZCut = AnalysisLib::LoadSingleTCut(ezCutFile);
  
  
  //========================= Generate all of the histograms needed for drawing later on
  printf("======================================== Histograms declaration\n");

  gROOT->cd();

  he     = new TH1F * [mapping::NARRAY];
  hxf    = new TH1F * [mapping::NARRAY];
  hxn    = new TH1F * [mapping::NARRAY];
  hxfVxn = new TH2F * [mapping::NARRAY];
  heVxs  = new TH2F * [mapping::NARRAY];
  heVx   = new TH2F * [mapping::NARRAY];

  heCal        = new TH1F * [mapping::NARRAY];
  hxfCalVxnCal = new TH2F * [mapping::NARRAY];
  heVxsCal     = new TH2F * [mapping::NARRAY];
  heCalVxCal   = new TH2F * [mapping::NARRAY];
  heCalVxCalG  = new TH2F * [mapping::NARRAY];

  for (Int_t i = 0; i < mapping::NARRAY; i++) {//array loop
    
    he[i]      = new TH1F(Form("he%d", i),     Form("Raw e (ch=%d); e (channel); count", i),                   2000, rawEnergyRange[0], rawEnergyRange[1]);
    hxf[i]     = new TH1F(Form("hxf%d", i),    Form("Raw xf (ch=%d); xf (channel); count", i),                  200, rawEnergyRange[0], rawEnergyRange[1]);
    hxn[i]     = new TH1F(Form("hxn%d", i),    Form("Raw xn (ch=%d); xn (channel); count", i),                  200, rawEnergyRange[0], rawEnergyRange[1]);
    hxfVxn[i]  = new TH2F(Form("hxfVxn%d",i),  Form("Raw xf vs. xn (ch=%d);xf (channel);xn (channel)",i),       500,                 0, rawEnergyRange[1], 500,                 0, rawEnergyRange[1]);
    heVxs[i]   = new TH2F(Form("heVxs%d", i),  Form("Raw e vs xf+xn (ch=%d); xf+xn (channel); e (channel)", i), 500, rawEnergyRange[0], rawEnergyRange[1], 500, rawEnergyRange[0], rawEnergyRange[1]);
    heVx[i]    = new TH2F(Form("heVx%d",i),         Form("Raw PSD E vs. X (ch=%d);X (channel);E (channel)",i),  500,              -0.1,               1.1, 500, rawEnergyRange[0], rawEnergyRange[1]);
    
    heCal[i]        = new TH1F(Form("heCal%d", i),       Form("Corrected e (ch=%d); e (MeV); count", i),                                          2000,   energyRange[0], energyRange[1]);
    hxfCalVxnCal[i] = new TH2F(Form("hxfCalVxnCal%d",i), Form("Corrected XF vs. XN (ch=%d);XF (channel);XN (channel)",i),                         500,                 0, rawEnergyRange[1], 500,                 0, rawEnergyRange[1]);      
    heVxsCal[i]     = new TH2F(Form("heVxsCal%d", i),    Form("Raw e vs Corrected xf+xn (ch=%d); corrected xf+xn (channel); Raw e (channel)", i), 500, rawEnergyRange[0], rawEnergyRange[1], 500, rawEnergyRange[0], rawEnergyRange[1]);           
    heCalVxCal[i]   = new TH2F(Form("heCalVxCal%d",i),   Form("Cal PSD E vs. X (ch=%d);X (cm);E (MeV)",i),                                        500,              -2.5,  AnalysisLib::detGeo.detLength + 2.5, 500,    energyRange[0],    energyRange[1]);
    heCalVxCalG[i]  = new TH2F(Form("heCalVxCalG%d",i),  Form("Cal PSD E vs. X (ch=%d);X (cm);E (MeV)",i),                                        500,              -2.5,  AnalysisLib::detGeo.detLength + 2.5, 500,    energyRange[0],    energyRange[1]);
  }

  heVID    = new TH2F("heVID",    "Raw e vs channel", mapping::NARRAY, 0, mapping::NARRAY, 500, rawEnergyRange[0], rawEnergyRange[1]);
  hxfVID   = new TH2F("hxfVID",   "Raw xf vs channel", mapping::NARRAY, 0, mapping::NARRAY, 500, rawEnergyRange[0], rawEnergyRange[1]);
  hxnVID   = new TH2F("hxnVID",   "Raw xn vs channel", mapping::NARRAY, 0, mapping::NARRAY, 500, rawEnergyRange[0], rawEnergyRange[1]);
  
  heCalID = new TH2F("heCalID", "Corrected E vs detID; detID; E / 10 keV", mapping::NARRAY, 0, mapping::NARRAY, 2000, energyRange[0], energyRange[1]);
  
  hMultiHit = new TH1F("hMultiHit", "Multi-Hit of Energy", 10, 0, 1);

  //====================== E-Z plot
  heCalVz   = new TH2F("heCalVz",  "E vs. Z;Z (mm);E (MeV)"      , 400, zRange[0], zRange[1], 400, energyRange[0], energyRange[1]);
  heCalVzGC = new TH2F("heCalVzGC","E vs. Z gated;Z (mm);E (MeV)", 400, zRange[0], zRange[1], 400, 0, energyRange[1]);
  
  hecalVzRow = new TH2F * [numRow];
  for( int i = 0; i < numRow; i++){
    hecalVzRow[i] = new TH2F(Form("heCalVzRow%d", i), Form("E vs. Z (ch=%d-%d); Z (cm); E (MeV)", numCol*i, numCol*(i+1)-1), 500, zRange[0], zRange[1], 500, energyRange[0], energyRange[1]);
  }

  //===================== energy spectrum
  hEx    = new TH1F("hEx",Form("excitation spectrum w/ goodFlag; Ex [MeV] ; Count / %4.0f keV", exRange[0]), (int) (exRange[2]-exRange[1])/exRange[0]*1000, exRange[1], exRange[2]);
  
  hExCut1  = new TH1F("hExCut1",Form("excitation spectrum w/ goodFlag; Ex [MeV] ; Count / %4.0f keV", exRange[0]), (int) (exRange[2]-exRange[1])/exRange[0]*1000, exRange[1], exRange[2]);
  hExCut2  = new TH1F("hExCut2",Form("excitation spectrum w/ goodFlag; Ex [MeV] ; Count / %4.0f keV", exRange[0]), (int) (exRange[2]-exRange[1])/exRange[0]*1000, exRange[1], exRange[2]);
  hExCut1->SetLineColor(2);
  hExCut2->SetLineColor(4);
  
  hExi     = new TH1F * [mapping::NARRAY];
  hExVxCal = new TH2F * [mapping::NARRAY];
  for(int i = 0 ; i < mapping::NARRAY; i++){
    hExi[i]     = new TH1F(Form("hExi%02d", i),  Form("Ex (det=%i) w/goodFlag; Ex [MeV]; Count / %4.0f keV",i, exRange[0]), (int) (exRange[2]-exRange[1])/exRange[0]*1000, exRange[1], exRange[2]);
    hExVxCal[i] = new TH2F(Form("hExVxCal%d",i), Form("Ex vs X (ch=%d); X (cm); Ex (MeV)", i),    500,   -0.1,  1.1, (int) (exRange[2]-exRange[1])/exRange[0]*1000, exRange[1], exRange[2]);
  }
  
  hExThetaCM = new TH2F("hExThetaCM", "Ex vs ThetaCM; ThetaCM [deg]; Ex [MeV]", 200, thetaCMRange[0], thetaCMRange[1],  (int) (exRange[2]-exRange[1])/exRange[0]*1000, exRange[1], exRange[2]);
  
  //===================== Recoils
  hrdtID = new TH2F("hrdtID", "RDT vs ID; ID; energy [ch]", 8, 0, 8, 500, TMath::Min(rdtERange[0], rdtDERange[0]), TMath::Max(rdtERange[1], rdtDERange[1])); 

  hrdt  = new TH1F * [mapping::NRDT];
  hrdtg = new TH1F * [mapping::NRDT];

  hrdt2D    = new TH2F * [mapping::NRDT/2];
  hrdt2Dg   = new TH2F * [mapping::NRDT/2];
  hrdt2Dsum = new TH2F * [mapping::NRDT/2];

  for (Int_t i = 0; i < mapping::NRDT ; i++) {
    if( i % 2 == 0 ) hrdt[i]  = new TH1F(Form("hrdt%d",i), Form("Raw Recoil E(ch=%d); E (channel)",i),         500,  rdtERange[0],  rdtERange[1]);
    if( i % 2 == 0 ) hrdtg[i] = new TH1F(Form("hrdt%dg",i),Form("Raw Recoil E(ch=%d) gated; E (channel)",i),   500,  rdtERange[0],  rdtERange[1]);
    if( i % 2 == 1 ) hrdt[i]  = new TH1F(Form("hrdt%d",i), Form("Raw Recoil DE(ch=%d); DE (channel)",i),       500, rdtDERange[0], rdtDERange[1]);
    if( i % 2 == 1 ) hrdtg[i] = new TH1F(Form("hrdt%dg",i),Form("Raw Recoil DE(ch=%d) gated; DE (channel)",i), 500, rdtDERange[0], rdtDERange[1]);
    
    ///dE vs E      
    if( i % 2 == 0 ) {
      int tempID = i / 2;
      hrdt2D[tempID]    = new TH2F(Form("hrdt2D%d",tempID),    Form("Raw Recoil DE vs Eres (dE=%d, E=%d); Eres (channel); DE (channel)", i+1, i),       500, rdtERange[0], rdtERange[1],500,rdtDERange[0],rdtDERange[1]);
      hrdt2Dg[tempID]   = new TH2F(Form("hrdt2Dg%d",tempID),   Form("Gated Raw Recoil DE vs Eres (dE=%d, E=%d); Eres (channel); DE (channel)",i+1, i),  500, rdtERange[0], rdtERange[1],500,rdtDERange[0], rdtDERange[1]);
      hrdt2Dsum[tempID] = new TH2F(Form("hrdt2Dsum%d",tempID), Form("Raw Recoil DE vs Eres+DE (dE=%d, E=%d); Eres+DE (channel); DE (channel)", i+1, i), 500, rdtERange[0], rdtERange[1]+rdtDERange[1], 500, rdtDERange[0], rdtDERange[1]);
    }
  }
  
  hrdtRate1 = new TH1F("hrdtRate1", "recoil rate 1 / min; min; count / 1 min", timeRange[1] - timeRange[0], timeRange[0], timeRange[1]);
  hrdtRate2 = new TH1F("hrdtRate2", "recoil rate 2 / min; min; count / 1 min", timeRange[1] - timeRange[0], timeRange[0], timeRange[1]);
  hrdtRate1->SetLineColor(2);
  hrdtRate2->SetLineColor(4);

  //===================== multiplicity
  hmultEZ           = new TH1I("hmultEZ",          "Filled EZ with coinTime and recoil",                       10,  0,  10);
  hmult             = new TH2I("hmult",            "Array Multiplicity vs Recoil Multiplicity; Array ; Recoil",10,  0,  10, 10,  0, 10);
  hArrayRDTMatrix   = new TH2I("hArrayRDTMatrix",  "Array ID vs Recoil ID; Array ID; Recoil ID",               30,  0,  30,  8,  0,  8);
  hArrayRDTMatrixG  = new TH2I("hArrayRDTMatrixG", "Array ID vs Recoil ID / g; Array ID; Recoil ID",           30,  0,  30,  8,  0,  8);

  //===================== coincident time 
  htdiff  = new TH1I("htdiff" ,"Coincident time (recoil-dE - array); time [ch = 10ns]; count", coinTimeRange[1] - coinTimeRange[0], coinTimeRange[0], coinTimeRange[1]);   
  htdiffg = new TH1I("htdiffg","Coincident time (recoil-dE - array) w/ recoil gated; time [ch = 10ns]; count", coinTimeRange[1] - coinTimeRange[0], coinTimeRange[0], coinTimeRange[1]);
  

  printf("======================================== End of histograms Declaration\n");
  StpWatch.Start();

}

//^###########################################################
//^ * Process
//^###########################################################
Bool_t Monitors::Process(Long64_t entry){

  if( entry == 0 ) printf("========== %s \n", __func__);

  if( ProcessedEntries > maxNumberEvent ) return kTRUE;
  ProcessedEntries++;
  
  //@*********** Progress Bar ******************************************/ 
  if (ProcessedEntries>NumEntries*Frac-1) {
    TString msg; msg.Form("%llu", NumEntries/1000);
    int len = msg.Sizeof();
    printf(" %3.0f%% (%*llu/%llu k) processed in %6.1f sec | expect %6.1f sec\n",
              Frac*100, len, ProcessedEntries/1000,NumEntries/1000,StpWatch.RealTime(), StpWatch.RealTime()/Frac);
    StpWatch.Start(kFALSE);
    Frac+=0.1;
  }

  //@********** Get Branch *********************************************/
  b_Energy->GetEntry(entry);
  b_XF->GetEntry(entry);
  b_XN->GetEntry(entry);
  b_EnergyTimestamp->GetEntry(entry);

  if( isRDTExist ){
    b_RDT->GetEntry(entry);
    b_RDTTimestamp->GetEntry(entry);
  }
   
  // if( isArrayTraceExist ) {
  //   ///b_Trace_Energy->GetEntry(entry);
  //   b_Trace_Energy_RiseTime->GetEntry(entry);
  //   b_Trace_Energy_Time->GetEntry(entry);
  // }
   
  // if( isRDTTraceExist ){
  //   ///b_Trace_RDT->GetEntry(entry); 
  //   b_Trace_RDT_Time->GetEntry(entry);
  //   b_Trace_RDT_RiseTime->GetEntry(entry);
  // }
  
  //@*********** initization ******************************************/
  for( int i = 0 ; i < mapping::NARRAY; i++){
      z[i] = TMath::QuietNaN();
      x[i] = TMath::QuietNaN();
      xCal[i] = TMath::QuietNaN();
      eCal[i] = TMath::QuietNaN();
  }
    
  //@*********** Apply Recoil correction here *************************/
  if( isRDTCorrOK ){
    for( int i = 0 ; i < mapping::NRDT; i++){
      rdt[i] = rdt[i]*AnalysisLib::rdtCorr[i][0] + AnalysisLib::rdtCorr[i][1];
    }
  }

  //@*********** Array ************************************************/ 
  //Do calculations and fill histograms
  Int_t recoilMulti = 0;
  Int_t arrayMulti = 0;
  Int_t multiEZ = 0;
  bool rdtgate1 = false;
  bool rdtgate2 = false;
  bool coinFlag = false;
  bool ezGate = false;
  bool isGoodEventFlag = false;

  for (Int_t detID = 0; detID < mapping::NARRAY; detID++) {
      
    //@================== Filling raw data
    he[detID]->Fill(e[detID]);
    hxf[detID]->Fill(xf[detID]);
    hxn[detID]->Fill(xn[detID]);
    hxfVxn[detID]->Fill(xf[detID],xn[detID]);
    heVxs[detID]->Fill(xf[detID]+xn[detID], e[detID]);
    
    heVID->Fill(detID, e[detID]);
    hxfVID->Fill(detID, xf[detID]);
    hxnVID->Fill(detID, xn[detID]);

    //if( !TMath::IsNaN(e[detID]) ) printf("%llu | %d | %f %f %f \n", entry, detID, e[detID], xf[detID], xn[detID]);
      
    //@==================== Basic gate
    if( TMath::IsNaN(e[detID]) ) continue ; 
    ///if( ring[detID] < -100 || ring[detID] > 100 ) continue; 
    ///if( ring[detID] > 300 ) continue; 
    if( TMath::IsNaN(xn[detID]) &&  TMath::IsNaN(xf[detID]) ) continue ; 
      
    //@==================== Skip detector 
    bool skipFlag = false;
    for( unsigned int kk = 0; kk < skipDetID.size() ; kk++){
        if( detID == skipDetID[kk] ) {
          skipFlag = true;
          break;
        }
    }
    if (skipFlag ) continue;

    //@==================== Basic gate
    if( TMath::IsNaN(e[detID]) ) continue ; 
    ///if( ring[detID] < -100 || ring[detID] > 100 ) continue; 
    ///if( ring[detID] > 300 ) continue; 
    if( TMath::IsNaN(xn[detID]) &&  TMath::IsNaN(xf[detID]) ) continue ; 

    //@==================== Calibrations go here
    if( isXNCorrOK && isXFXNCorrOK ) xnCal[detID] = xn[detID] * AnalysisLib::xnCorr[detID] * AnalysisLib::xfxneCorr[detID][1] + AnalysisLib::xfxneCorr[detID][0];
    if( isXNCorrOK && isXFXNCorrOK ) xfCal[detID] = xf[detID] * AnalysisLib::xfxneCorr[detID][1] + AnalysisLib::xfxneCorr[detID][0];
    if( isECorrOK )                  eCal[detID] = e[detID] / AnalysisLib::eCorr[detID][0] + AnalysisLib::eCorr[detID][1];

    if( eCal[detID] < eCalCut[0] ) continue;
    if( eCal[detID] > eCalCut[1] ) continue;
      
    //@===================== fill Calibrated  data
    heCal[detID]->Fill(eCal[detID]);
    heCalID->Fill(detID, eCal[detID]);
    hxfCalVxnCal[detID]->Fill(xfCal[detID], xnCal[detID]);
    heVxsCal[detID]->Fill(xnCal[detID] + xfCal[detID], e[detID]);
      
    //@===================== calculate X
    if( (xf[detID] > 0 || !TMath::IsNaN(xf[detID])) && ( xn[detID]>0 || !TMath::IsNaN(xn[detID])) ) {
      ///x[detID] = 0.5*((xf[detID]-xn[detID]) / (xf[detID]+xn[detID]))+0.5;
      x[detID] = 0.5*((xf[detID]-xn[detID]) / e[detID])+0.5;
    }
    
    /// range of x is (0, 1)
    if  ( !TMath::IsNaN(xf[detID]) && !TMath::IsNaN(xn[detID]) ) xCal[detID] = 0.5 + 0.5 * (xfCal[detID] - xnCal[detID] ) / e[detID];
    if  ( !TMath::IsNaN(xf[detID]) &&  TMath::IsNaN(xn[detID]) ) xCal[detID] = xfCal[detID]/ e[detID];
    if  (  TMath::IsNaN(xf[detID]) && !TMath::IsNaN(xn[detID]) ) xCal[detID] = 1.0 - xnCal[detID]/ e[detID];
    
    //@======= Scale xcal from (0,1)      
    if( isXScaleCorrOK ) xCal[detID] = (xCal[detID]-0.5)/AnalysisLib::xScale[detID] + 0.5; /// if include this scale, need to also inclused in Cali_littleTree
    
    if( abs(xCal[detID] - 0.5) > xGate/2. ) continue; 
    
    //@==================== calculate Z
    if( AnalysisLib::detGeo.firstPos > 0 ) {
      z[detID] = AnalysisLib::detGeo.detLength*(1.0-xCal[detID]) + AnalysisLib::detGeo.detPos[detID%numCol];
    }else{
      z[detID] = AnalysisLib::detGeo.detLength*(xCal[detID]-1.0) + AnalysisLib::detGeo.detPos[detID%numCol];
    }

    //@===================== multiplicity
    arrayMulti++; /// multi-hit when both e, xf, xn are not NaN

    //@=================== Array fill
    heVx[detID]->Fill(x[detID],e[detID]);
    
    heCalVxCal[detID]->Fill(xCal[detID]*AnalysisLib::detGeo.detLength,eCal[detID]);
    heCalVz->Fill(z[detID],eCal[detID]);

    //@=================== Recoil Gate
    if( isRDTExist && (cutList1 || cutList2)){
      for(int i = 0 ; i < cutList1->GetEntries() ; i++ ){
        cutG = (TCutG *)cutList1->At(i) ;
        if(cutG->IsInside(rdt[2*i],rdt[2*i+1])) {
        // if(cutG->IsInside(rdt[2*i] + rdt[2*i+1],rdt[2*i+1])) {
          rdtgate1= true;
          break; /// only one is enough
        }
      }
      
      for(int i = 0 ; i < cutList2->GetEntries() ; i++ ){
        cutG = (TCutG *)cutList2->At(i) ;
        if(cutG->IsInside(rdt[2*i],rdt[2*i+1])) {
        //if(cutG->IsInside(rdt[2*i]+ rdt[2*i+1],rdt[2*i+1])) {
          rdtgate2= true;
          break; /// only one is enough
        }
      }
      
    }else{
      rdtgate1 = true;
      rdtgate2 = true;
    }
      
    //================ coincident with Recoil when z is calculated.
    if( !TMath::IsNaN(z[detID]) ) { 
      for( int j = 0; j < mapping::NRDT ; j++){
        if( TMath::IsNaN(rdt[j]) ) continue; 
  
        int tdiff = rdt_t[j] - e_t[detID];
  
        if( j%2 == 1) {
          htdiff->Fill(tdiff);
          if((rdtgate1 || rdtgate2) && (eCalCut[1] > eCal[detID] && eCal[detID]>eCalCut[0])) {
            htdiffg->Fill(tdiff);
          }
        }

        hArrayRDTMatrix->Fill(detID, j); 
  
        if( isTimeGateOn && timeGate[0] < tdiff && tdiff < timeGate[1] ) {
          if(j % 2 == 0 ) hrdt2Dg[j/2]->Fill(rdt[j],rdt[j+1]); /// x=E, y=dE
          ///if(j % 2 == 0 ) hrdt2Dg[j/2]->Fill(rdt[j+1],rdt[j]); /// x=dE, y=E
          hArrayRDTMatrixG->Fill(detID, j); 
          ///if( rdtgate1) hArrayRDTMatrixG->Fill(detID, j); 
          
          hrdtg[j]->Fill(rdt[j]);
          coinFlag = true;
          
        }
      }
    }
      
    if( !isTimeGateOn ) coinFlag = true;
    
    //================ E-Z gate
    if( isEZCutFileOpen ) { 
      if( EZCut->IsInside(z[detID], eCal[detID])  ) ezGate = true;
    }else{
      ezGate = true;
    }
    
    if( coinFlag && (rdtgate1 || rdtgate2) && ezGate){ 
      heCalVzGC->Fill( z[detID] , eCal[detID] );
    
      heCalVxCalG[detID]->Fill(xCal[detID]*AnalysisLib::detGeo.detLength,eCal[detID]);
  
      multiEZ ++;
      isGoodEventFlag = true;
    }
      
  }//end of array loop
    
  if( !isEZCutFileOpen ) ezGate = true;
    
  //@*********** RECOILS ***********************************************/    
  for( int i = 0; i < mapping::NRDT ; i++){
    hrdtID->Fill(i, rdt[i]);
    hrdt[i]->Fill(rdt[i]);
  
    if( i % 2 == 0  ){        
      
    recoilMulti++; // when both dE and E are hit
        hrdt2D[i/2]->Fill(rdt[i],rdt[i+1]); //E-dE
    }
  }
   
  //@******************* Multi-hit *************************************/
  hmultEZ->Fill(multiEZ);
  hmult->Fill(recoilMulti,arrayMulti);
  hMultiHit->Fill(arrayMulti);

  //@*********** Good event Gate ***************************************/ 
  if( !isGoodEventFlag ) return kTRUE;
   
  //@*********** Ex and thetaCM ****************************************/ 
  for(Int_t detID = 0; detID < mapping::NARRAY ; detID++){
     	
    if( TMath::IsNaN(e[detID]) ) continue ; 
    if( TMath::IsNaN(z[detID]) ) continue ;
    if( eCal[detID] <  eCalCut[0] ) continue ;
    if( eCal[detID] >  eCalCut[1] ) continue ;

    if( AnalysisLib::hasReactionPara ){

      std::vector<double> ExThetaCM = AnalysisLib::CalExTheta(eCal[detID], x[detID]);

      Ex = ExThetaCM[0];
      thetaCM = ExThetaCM[1];

      //  ///======== Ex calculation by Ryan 
      //  double y = eCal[detID] + mass; // to give the KE + mass of proton;
      //  double Z = alpha * gamm * betRel * z[detID];
      //  double H = TMath::Sqrt(TMath::Power(gamm * betRel,2) * (y*y - mass * mass) ) ;
 
      //  if( TMath::Abs(Z) < H ) {
      //    ///using Newton's method to solve 0 ==	H * sin(phi) - G * tan(phi) - Z = f(phi) 
      //    double tolerrence = 0.001;
      //    double phi = 0;  ///initial phi = 0 -> ensure the solution has f'(phi) > 0
      //    double nPhi = 0; /// new phi

      //    int iter = 0;
      //    do{
      //      phi = nPhi;
      //      nPhi = phi - (H * TMath::Sin(phi) - G * TMath::Tan(phi) - Z) / (H * TMath::Cos(phi) - G /TMath::Power( TMath::Cos(phi), 2));					 
      //      iter ++;
      //      if( iter > 10 || TMath::Abs(nPhi) > TMath::PiOver2()) break;
      //    }while( TMath::Abs(phi - nPhi ) > tolerrence);
      //    phi = nPhi;

      //    /// check f'(phi) > 0
      //    double Df = H * TMath::Cos(phi) - G / TMath::Power( TMath::Cos(phi),2);
      //    if( Df > 0 && TMath::Abs(phi) < TMath::PiOver2()  ){
      //      double K = H * TMath::Sin(phi);
      //      double x = TMath::ACos( mass / ( y * gamm - K));
      //      double momt = mass * TMath::Tan(x); /// momentum of particel b or B in CM frame
      //      double EB = TMath::Sqrt(mass*mass + Et*Et - 2*Et*TMath::Sqrt(momt*momt + mass * mass));
      //      Ex = EB - massB;

      //      double hahaha1 = gamm* TMath::Sqrt(mass * mass + momt * momt) - y;
      //      double hahaha2 = gamm* betRel * momt;
      //      thetaCM = TMath::ACos(hahaha1/hahaha2) * TMath::RadToDeg();

      //    }else{
      //      Ex = TMath::QuietNaN();
      //      thetaCM = TMath::QuietNaN();
      //    }
      //  }else{
      //    Ex = TMath::QuietNaN();
      //    thetaCM = TMath::QuietNaN();
      //  }
    }else{
      Ex = TMath::QuietNaN();
      thetaCM = TMath::QuietNaN();
    }
     
    if( thetaCM > thetaCMGate ) {

      hEx->Fill(Ex);

      hExThetaCM->Fill(thetaCM, Ex);
      
      if( rdtgate1 ) {
        hExCut1->Fill(Ex);
        hExThetaCM->Fill(thetaCM, Ex);
      }
      if( rdtgate2 ) {
        hExCut2->Fill(Ex);
        hExThetaCM->Fill(thetaCM, Ex);
      }
      
      hExi[detID]->Fill(Ex);
      hExVxCal[detID]->Fill(xCal[detID], Ex);
        
    }
  }
  
  return kTRUE;
}

//^###########################################################
//^ * Terminate
//^###########################################################
void Monitors::Terminate(){
  printf("============================== finishing.\n");

  gROOT->cd();
  
  int strLen = canvasTitle.Sizeof();
  canvasTitle.Remove(strLen-3);
  
  TString runTimeStr = "";
  if( runTime > 0. ) {
    runTimeStr = Form("%.0f min", runTime);
    canvasTitle += " | " + runTimeStr;
  }

  //############################################ User is free to edit this section
  //--- Canvas Size
  int canvasXY[2] = {1200 , 800} ;// x, y
  int canvasDiv[2] = {3,2};
  cCanvas  = new TCanvas("cCanvas",canvasTitle + " | " + rdtCutFile1,canvasXY[0],canvasXY[1]);
  cCanvas->Modified(); cCanvas->Update();
  cCanvas->cd(); cCanvas->Divide(canvasDiv[0],canvasDiv[1]);

  gStyle->SetOptStat("neiou");
    
  text.SetNDC();
  text.SetTextFont(82);
  text.SetTextSize(0.04);
  text.SetTextColor(2);

  double yMax = 0;

  Isotope hRecoil(AnalysisLib::reactionConfig.recoilHeavyA, AnalysisLib::reactionConfig.recoilHeavyZ);
  double Sn = hRecoil.CalSp(0,1);
  double Sp = hRecoil.CalSp(1,0);
  double Sa = hRecoil.CalSp2(4,2);
  
  //TODO, Module each plot
  ///----------------------------------- Canvas - 1
  PlotEZ(1); /// raw EZ
    
  ///----------------------------------- Canvas - 2
  PlotEZ(0); ///gated EZ

  ///----------------------------------- Canvas - 3
  PlotTDiff(1, 1); ///with Gated Tdiff, isLog
  
  ///----------------------------------- Canvas - 4
  padID++; cCanvas->cd(padID); 
  
  //hEx->Draw();
  hExCut1->Draw("");
  hExCut2->Draw("same");
  DrawLine(hEx, Sn);
  DrawLine(hEx, Sa);
  
  if(isTimeGateOn)text.DrawLatex(0.15, 0.8, Form("%d < coinTime < %d", timeGate[0], timeGate[1])); 
  if( xGate < 1 ) text.DrawLatex(0.15, 0.75, Form("with |x-0.5|<%.4f", xGate/2.));
  if( cutList1 ) text.DrawLatex(0.15, 0.7, "with recoil gated"); 

  ///----------------------------------- Canvas - 5
  padID++; cCanvas->cd(padID); 
  
  //Draw2DHist(hExThetaCM);
  //heVIDG->Draw();
  //text.DrawLatex(0.15, 0.75, Form("#theta_{cm} > %.1f deg", thetaCMGate));

  Draw2DHist(hrdt2D[0]);
//      Draw2DHist(hrdt2Dsum[0]);

  if( cutList1 && cutList1->GetEntries() > 0 ) {cutG = (TCutG *)cutList1->At(0) ; cutG->Draw("same");}
  if( cutList2 && cutList2->GetEntries() > 0 ) {cutG = (TCutG *)cutList2->At(0) ; cutG->Draw("same");}


  //helum4D->Draw();
  //text.DrawLatex(0.25, 0.3, Form("gated from 800 to 1200 ch\n"));
  
  ///----------------------------------- Canvas - 6
  PlotRDT(0,0);
  
// padID++; cCanvas->cd(padID); 
//  Draw2DHist(hrdtExGated);
  
  //padID++; cCanvas->cd(padID); 
  //Draw2DHist(htacEx);
  
  ///------------------------------------- Canvas - 7
  //PlotRDT(0, 0);
  
  ///----------------------------------- Canvas - 8
  //PlotRDT(1, 0);

  ///yMax = hic2->GetMaximum()*1.2;
  ///hic2->GetYaxis()->SetRangeUser(0, yMax);
  ///hic2->Draw();
  ///TBox * box14N = new TBox (-10, 0, -2, yMax);
  ///box14N->SetFillColorAlpha(2, 0.1);
  ///box14N->Draw();
  ///
  ///TBox * box14C = new TBox (8, 0, 16, yMax);
  ///box14C->SetFillColorAlpha(4, 0.1);
  ///box14C->Draw();
  ///
  ///text.SetTextColor(2); text.DrawLatex(0.38, 0.50, "14N");
  ///text.SetTextColor(4); text.DrawLatex(0.6, 0.45, "14C");
  ///text.SetTextColor(2);
  ///----------------------------------- Canvas - 9
  //padID++; cCanvas->cd(padID);  
  
  //Draw2DHist(hic01);

  ///----------------------------------- Canvas - 10
  //PlotRDT(3,0);
  
  //TH1F * helumDBIC = new TH1F("helumDBIC", "elum(d)/BIC; time [min]; count/min", timeRange[1]-timeRange[0], timeRange[0], timeRange[1]);
  //helumDBIC = (TH1F*) helum4D->Clone();
  //helumDBIC->SetTitle("elum(d)/BIC; time [min]; count/min");
  //helumDBIC->SetName("helumDBIC");
  //helumDBIC->SetLineColor(2);
  
  //helumDBIC->Divide(hBIC);
  
  //yMax = helumDBIC->GetMaximum();
  //if( yMax < hBIC->GetMaximum() ) yMax = hBIC->GetMaximum();
  
  //helumDBIC->SetMaximum(yMax * 1.2);
  //hBIC->SetMaximum(yMax * 1.2);
  
  //hBIC->Draw();
  //helumDBIC->Draw("same");
  
  //text.DrawLatex(0.15, 0.5, Form("Elum(D) / BIC \n"));
  
  ///----------------------------------- Canvas - 11
  //PlotRDT(2,0);
  
  ///----------------------------------- Canvas - 12
  //padID++; cCanvas->cd(padID);
  //htac->Draw();

  
  /*
  ///----------------------------------- Canvas - 13
  padID++; cCanvas->cd(padID);
  
  ///hicT14N->Draw("");
  ///hicT14C->Draw("same");
  ///
  ///text.SetTextColor(2); text.DrawLatex(0.15, 0.60, "14N");
  ///text.SetTextColor(4); text.DrawLatex(0.15, 0.25, "14C");
  ///text.SetTextColor(2);
  
  ///----------------------------------- Canvas - 14
  padID++; cCanvas->cd(padID);
  
  ///hrdtRate1->Draw("");
  ///hrdtRate2->Draw("same");
  
  ///----------------------------------- Canvas - 15
  padID++; cCanvas->cd(padID);  
    
  ///----------------------------------- Canvas - 16
  padID++; cCanvas->cd(padID); 
  


  ///----------------------------------- Canvas - 17
  padID++; cCanvas->cd(padID);    
  

  ///----------------------------------- Canvas - 18
  padID++; cCanvas->cd(padID);


  ///----------------------------------- Canvas - 19
  padID++; cCanvas->cd(padID);
  

  
  ///----------------------------------- Canvas - 20
  padID++; cCanvas->cd(padID);
  
  htac->Draw();
  */
  
  /************************************/
  gStyle->GetAttDate()->SetTextSize(0.02);
  gStyle->SetOptDate(1);
  gStyle->SetDateX(0);
  gStyle->SetDateY(0);
  
  /************************************/
  StpWatch.Start(kFALSE);
  
  gROOT->ProcessLine(".L ../Armory/Monitor_Util.C");
  printf("=============== loaded Monitor_Utils.C\n");
  gROOT->ProcessLine(".L ../Armory/AutoFit.C");
  printf("=============== loaded Armory/AutoFit.C\n");
  gROOT->ProcessLine(".L ../Armory/RDTCutCreator.C");
  printf("=============== loaded Armory/RDTCutCreator.C\n");
  gROOT->ProcessLine(".L ../Armory/Check_rdtGate.C");
  printf("=============== loaded Armory/Check_rdtGate.C\n");
  gROOT->ProcessLine(".L ../Armory/readTrace.C");
  printf("=============== loaded Armory/readTrace.C\n");
  //gROOT->ProcessLine(".L ../Armory/readRawTrace.C");
  //printf("=============== loaded Armory/readRawTrace.C\n");
  gROOT->ProcessLine("listDraws()");
  
  /************************* Save histograms to root file*/
  
  gROOT->cd();
  

  /************************************/
  //gROOT->ProcessLine("recoils()");

}