XIAEventBuilder/Analyzer.C

#define Analyzer_cxx

#include "Analyzer.h"
#include <TH2.h>
#include <TStyle.h>
#include <TH1.h>
#include <TCanvas.h>
#include <TMath.h>
#include <vector>
#include <stdio.h>

//############################################ User setting

int rawEnergyRange[2] = {0,  6000}; // in ch
int energyRange[3] = {1, 50, 2000}; // keV {resol, min, max}

double BGO_threshold = 0; // in ch

TString e_corr = "correction_e.dat";

bool save_ev2 = true;

//############################################ end of user setting


//############################################ histogram declaration

TH2F * heVID;
TH1F * he[NCRYSTAL];

TH2F * hgg[NCRYSTAL][NCRYSTAL];

TH2F * hcoin;

TH2F * hcrystalBGO;

TH1F * hTDiff;

///----- after calibration and BGO veto
TH2F * heCalVID;
TH1F * heCal[NCRYSTAL]; 
TH2F * hcoinBGO;

TH2F * hcrystalBGO_G;

//############################################ BEGIN
void Analyzer::Begin(TTree * tree){

   TString option = GetOption();

   totnumEntry = tree->GetEntries();

   printf( "=========================================================================== \n");
   printf( "==========================  Analysis.C/h   ================================ \n");
   printf( "======  total Entry : %lld \n", totnumEntry);
   printf( "=========================================================================== \n");

   printf("======================== Histograms declaration\n");
   
   heVID    = new TH2F("heVID",                                              "e vs ID; det ID; e [ch]", NCRYSTAL, 0, NCRYSTAL, rawEnergyRange[1] - rawEnergyRange[0], rawEnergyRange[0], rawEnergyRange[1]);
   heCalVID = new TH2F("heCalVID", Form("eCal vs ID (BGO veto > %.1f); det ID; Energy [keV]", BGO_threshold), NCRYSTAL, 0, NCRYSTAL, (energyRange[2] - energyRange[1])/energyRange[0], energyRange[1], energyRange[2]);
   
   hTDiff = new TH1F("hTDiff", "data time different within an event; tick [10 ns]", 110, 0, 110);
   
   heVID->SetNdivisions(-409, "X");
   heCalVID->SetNdivisions(-409, "X");
   
   for( int i = 0; i < NCRYSTAL; i ++){
      he[i]    = new TH1F(   Form("he%02d", i),                                  Form("e -%02d", i), rawEnergyRange[1] - rawEnergyRange[0], rawEnergyRange[0], rawEnergyRange[1]);
      heCal[i] = new TH1F(Form("heCal%02d", i), Form("eCal -%02d (BGO veto > %.1f); Energy [keV];  count / %d keV", i, BGO_threshold, energyRange[0]), (energyRange[2] - energyRange[1])/energyRange[0], energyRange[1], energyRange[2]);
   }
   
   for( int i = 0; i < NCRYSTAL; i++){
      for( int j = i+1; j < NCRYSTAL; j++){
         //hgg[i][j] = new TH2F(Form("hgg%02d%02d", i, j), Form("e%02d vs e%02d; e%02d; e%02d", i, j, i, j), 
         //        (rawEnergyRange[1] - rawEnergyRange[0])/2, rawEnergyRange[0], rawEnergyRange[1], 
         //        (rawEnergyRange[1] - rawEnergyRange[0])/2, rawEnergyRange[0], rawEnergyRange[1]);
      }
   }
   
   hcoin = new TH2F("hcoin", "detector coin.; det ID; det ID", NCRYSTAL, 0, NCRYSTAL, NCRYSTAL, 0 , NCRYSTAL); 
   
   hcoinBGO = new TH2F("hcoinBGO", Form("detector coin. (BGO veto > %.1f); det ID; det ID", BGO_threshold), NCRYSTAL, 0, NCRYSTAL, NCRYSTAL, 0 , NCRYSTAL); 
   hcrystalBGO = new TH2F("hcrystalBGO", Form("crystal vs BGO ; det ID; BGO ID"), NCRYSTAL, 0, NCRYSTAL, NBGO, 0 , NBGO); 
   hcrystalBGO_G = new TH2F("hcrystalBGO_G", Form("crystal vs BGO (BGO veto); det ID; BGO ID"), NCRYSTAL, 0, NCRYSTAL, NBGO, 0 , NBGO); 
   
   printf("======================== Load parameters.\n");
   
   eCorr = LoadCorrectionParameters(e_corr); 
   
   saveEV2 = save_ev2;

}

//############################################ PROCESS
Bool_t Analyzer::Process(Long64_t entry){

   ProcessedEntries++;
   
   /*********** Progress Bar ******************************************/ 
   if (ProcessedEntries>totnumEntry*Frac-1) {
      TString msg; msg.Form("%llu", totnumEntry/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,totnumEntry/1000,StpWatch.RealTime(), StpWatch.RealTime()/Frac);
      StpWatch.Start(kFALSE);
      Frac+=0.1;
   }

   b_energy->GetEntry(entry);
   b_time->GetEntry(entry);
   b_multi->GetEntry(entry);
   b_multiCry->GetEntry(entry);
   b_detID->GetEntry(entry);
   
   if( multi == 0 ) return kTRUE;
   
   for( int i = 0; i < NCRYSTAL; i++) eCal[i] = TMath::QuietNaN();

   ///printf("---------------------------- %d \n", multi);
   ///=========== Looping data for the event
   for( int i = 0; i < multi ; i ++){
      
      int id = detID[i];
      
      ///printf("%d %f %llu\n", id, e[i], e_t[i]);

      //======== Fill raw data
      if( 0 <= id &&  id < NCRYSTAL ){  /// gamma data
         heVID->Fill( id, e[i]);
         he[id]->Fill(e[i]);
         
         for ( int j = i + 1; j < multi; j++){
            if( 100 <= detID[j] && detID[j] < 200 ) hcrystalBGO->Fill(id, detID[j]-100); /// crystal - BGO coincident 
            
            if( detID[j] < 100 ) hcoin->Fill(id, detID[j]); /// crystal-crystal coincident 
            
         }
      }
      
      if ( 100 < id && id < 200 ){ /// BGO data
         
      }
      
      if ( i > 0 ) hTDiff->Fill( e_t[i] - e_t[0]);
      
     
      //======== BGO veto
      bool dropflag = false;
      if( id < NCRYSTAL && multi > 1) {
         for( int j =  i + 1; j < multi; j++){
            if( detID[j] >= 100 && (detID[j]-100)*4 <= id && id < (detID[j]-100 +1)*4) {
               dropflag = true;
               break;
            }
         }
      }
      if( dropflag ) return kTRUE;
      
   
      if( 0<= id && id < NCRYSTAL ) {
         if( e_corr == "" ){
            eCal[id] = e[i];
         }else{
            ///========= apply correction
            int order = (int) eCorr[id].size();
            eCal[id] = 0;
            for( int k = 0; k < order ; k++){
               eCal[id] += eCorr[id][k] * TMath::Power(e[i], k);
            }
         }
         
         heCalVID->Fill( id,  eCal[id]);
         heCal[id]->Fill(eCal[id]);
      
         for ( int j = i + 1; j < multi; j++){
            if( 100 <= detID[j] && detID[j] < 200 ) hcrystalBGO_G->Fill(id, detID[j]-100); /// crystal - BGO coincident 
         }   
      
      }
      
   }
   
   
   if ( saveEV2) Save2ev2();
   
   
   return kTRUE;
}
//############################################ TERMINATE
void Analyzer::Terminate(){
   
   if(saveEV2) fclose(outEV2);

   printf("============================== finishing.\n");
   gROOT->cd();

   int canvasXY[2] = {1200 , 1200} ;// x, y
   int canvasDiv[2] = {2,2};
   TCanvas *cCanvas  = new TCanvas("cCanvas", "" ,canvasXY[0],canvasXY[1]);
   cCanvas->Modified(); cCanvas->Update();
   cCanvas->cd(); cCanvas->Divide(canvasDiv[0],canvasDiv[1]);

   gStyle->SetOptStat("neiou");

   cCanvas->cd(1);
   cCanvas->cd(1)->SetLogz(1);
   heVID->Draw("colz");

   cCanvas->cd(2);
   cCanvas->cd(2)->SetLogz(1);
   heCalVID->Draw("colz");
   
   cCanvas->cd(3);
   cCanvas->cd(3)->SetLogz(1);
   hcrystalBGO->Draw("colz");
   
   cCanvas->cd(4);
   cCanvas->cd(4)->SetLogz(1);
   hcrystalBGO_G->Draw("colz");
   //he[0]->SetLineColor(2);
   //he[0]->Draw();
   //heCal[0]->Draw("same");
   //hcoinBGO->Draw("colz");

   printf("=============== loaded AutoFit.C, try showFitMethos()\n");
   gROOT->ProcessLine(".L armory/AutoFit.C");   
   printf("=============== Analyzer Utility\n");
   gROOT->ProcessLine(".L armory/Analyzer_Utili.c");
   gROOT->ProcessLine("listDraws()");
   

   

}