ANASEN_analysis/MakeVertex.C

#define MakeVertex_cxx

Int_t colors[40] = {
    kBlack, kRed, kGreen, kBlue, kYellow, kMagenta, kCyan, kOrange,
    kSpring, kTeal, kAzure, kViolet, kPink, kGray, kWhite,
    kRed + 2, kGreen + 2, kBlue + 2, kYellow + 2, kMagenta + 2, kCyan + 2, kOrange + 2,
    kSpring + 2, kTeal + 2, kAzure + 2, kViolet + 2, kPink + 2,
    kRed - 7, kGreen - 7, kBlue - 7, kYellow - 7, kMagenta - 7, kCyan - 7, kOrange - 7,
    kSpring - 7, kTeal - 7, kAzure - 7, kViolet - 7, kPink - 7, kGray + 2};

#include "MakeVertex.h"
#include "Armory/ClassPW.h"
#include "Armory/HistPlotter.h"
#include "Armory/SX3Geom.h"

#include <TH2.h>
#include <TStyle.h>
#include <TCanvas.h>
#include <TMath.h>
#include <TBranch.h>
#include <TVector3.h>
#include <TGraph2D.h>
#include <TView.h>
#include <TPolyLine3D.h>
#include <TPolyMarker3D.h>
#include <TH3D.h>

#include <fstream>
#include <iostream>
#include <sstream>
#include <vector>
#include <array>
#include <map>
#include <utility>
#include <algorithm>

bool realtime = true;
const double source_vertex = 53;
const double qqq_z = 100.0;
const double anode_gain = 1.5146e-5; // channels --> MeV

TApplication *app = NULL;
TH1F *hha = NULL, *hhc = NULL;
TH3D *frame = NULL;
TCanvas *can1 = NULL, *can2 = NULL;

TPolyLine3D *pla[24] = {NULL};
TPolyLine3D *plc[24] = {NULL};
TPolyLine3D *qqqw[16][4] = {NULL};
TGraph2D *qqqg = NULL, *crossoverg = NULL, *guessg = NULL;

double z_to_crossover_rho(double z)
{
  return 9.20645e-5 * z * z + 34.1973;
}

double z_to_crossover_rho_cathode(double z)
{
  return 9.20645e-5 * z * z + 34.1973;
}

// Global instances
PW pwinstance;
TVector3 hitPos;
double qqqenergy, qqqtimestamp;
class Event
{
public:
  Event(TVector3 p, double e1, double e2, double t1, double t2) : pos(p), Energy1(e1), Energy2(e2), Time1(t1), Time2(t2) {}
  Event(TVector3 p, double e1, double e2, double t1, double t2, int c1, int c2) : pos(p), Energy1(e1), Energy2(e2), Time1(t1), Time2(t2), ch1(c1), ch2(c2) {}
  Event(TVector3 p, double e1, double e2, double t1, double t2, int a, int c, int c1, int c2) : pos(p), Energy1(e1), Energy2(e2), Time1(t1), Time2(t2), Anodech(a), Cathodech(c), ch1(c1), ch2(c2) {}

  TVector3 pos;
  int ch1 = -1;        // int(ch1/16) gives qqq id, ch1%16 gives ring#
  int ch2 = -1;        // int(ch2/16) gives qqq id, ch2%16 gives wedge#
  double Energy1 = -1; // Front for QQQ, Anode for PC
  double Energy2 = -1; // Back for QQQ, Cathode for PC
  double Time1 = -1;
  double Time2 = -1;
  int Anodech = -1;
  int Cathodech = -1;
  int multi1 = -1, multi2 = -1;
};

// Calibration globals
const int MAX_QQQ = 4;
const int MAX_RING = 16;
const int MAX_WEDGE = 16;
double qqqGain[MAX_QQQ][MAX_RING][MAX_WEDGE] = {{{0}}};
bool qqqGainValid[MAX_QQQ][MAX_RING][MAX_WEDGE] = {{{false}}};
double qqqCalib[MAX_QQQ][MAX_RING][MAX_WEDGE] = {{{0}}};
bool qqqCalibValid[MAX_QQQ][MAX_RING][MAX_WEDGE] = {{{false}}};
// TCutg *cutQQQ;

double sx3BackGain[24][4][4] = {{{1.}}};
double sx3FrontGain[24][4] = {{1.}};
double sx3FrontOffset[24][4] = {{0.}};
double sx3RightGain[24][4] = {{1.}};

// PC Arrays
double pcSlope[48];
double pcIntercept[48];

HistPlotter *plotter;

bool HitNonZero;
bool sx3ecut;
bool qqqEcut;

void MakeVertex::Begin(TTree * /*tree*/)
{
  TString option = GetOption();
  plotter = new HistPlotter("Analyzer_SX3.root", "TFILE");
  pwinstance.ConstructGeo();
  // if (gROOT->IsBatch())
  realtime = false;

  // ---------------------------------------------------------
  // 1. CRITICAL FIX: Initialize PC Arrays to Default (Raw)
  // ---------------------------------------------------------
  for (int i = 0; i < 48; i++)
  {
    pcSlope[i] = 1.0;     // Default slope = 1 (preserves Raw energy)
    pcIntercept[i] = 0.0; // Default intercept = 0
  }

  // Load PC Calibrations
  std::ifstream inputFile("slope_intercept_results.dat");
  if (inputFile.is_open())
  {
    std::string line;
    int index;
    double slope, intercept;
    while (std::getline(inputFile, line))
    {
      std::stringstream ss(line);
      ss >> index >> slope >> intercept;
      if (index >= 0 && index <= 47)
      {
        pcSlope[index] = slope;
        pcIntercept[index] = intercept;
      }
    }
    inputFile.close();
  }
  else
  {
    std::cerr << "Error opening slope_intercept.dat" << std::endl;
  }

  // Load QQQ Cuts from file
  //   {
  //     std::string filename = "QQQ_PCCut.root";
  //     TFile *cutFile = TFile::Open(filename.c_str(), "READ");
  //     if (cutFile && !cutFile->IsZombie())
  //     {
  //       cutQQQ = (TCutg *)cutFile->Get("cutQQQPC");
  //       if (cutQQQ)
  //       {
  //         std::cout << "Loaded QQQ PC cut from " << filename << std::endl;
  //       }
  //       else
  //       {
  //         std::cerr << "Error: cutQQQPC not found in " << filename << std::endl;
  //       }
  //       cutFile->Close();
  //   }
  // }

  // ... (Load QQQ Gains and Calibs - same as before) ...
  {
    std::string filename = "qqq_GainMatch.dat";
    std::ifstream infile(filename);
    if (infile.is_open())
    {
      int det, ring, wedge;
      double gainw, gainr;
      while (infile >> det >> wedge >> ring >> gainw >> gainr)
      {
        qqqGain[det][wedge][ring] = gainw;
        qqqGainValid[det][wedge][ring] = (gainw > 0);
        // std::cout << "QQQ Gain Loaded: Det " << det << " Ring " << ring << " Wedge " << wedge << " GainW " << gainw << " GainR " << gainr << std::endl;
      }
      infile.close();
    }
  }
  {
    std::string filename = "qqq_Calib.dat";
    std::ifstream infile(filename);
    if (infile.is_open())
    {
      int det, ring, wedge;
      double slope;
      while (infile >> det >> wedge >> ring >> slope)
      {
        qqqCalib[det][wedge][ring] = slope;
        qqqCalibValid[det][wedge][ring] = (slope > 0);
        // std::cout << "QQQ Calib Loaded: Det " << det << " Ring " << ring << " Wedge " << wedge << " Slope " << slope << std::endl;
      }
      infile.close();
    }
  }

  {
    std::ifstream infile("sx3cal/backgains.dat");
    std::string temp;
    int backpos, frontpos, clkpos;
    std::cout << "foo" << std::endl;
    if (infile.is_open())
      while (infile >> clkpos >> temp >> frontpos >> temp >> backpos >> sx3BackGain[clkpos][frontpos][backpos])
        std::cout << sx3BackGain[clkpos][frontpos][backpos] << std::endl;
    infile.close();

    infile.open("sx3cal/frontgains.dat");
    if (infile.is_open())
      while (infile >> clkpos >> temp >> temp >> frontpos >> sx3FrontOffset[clkpos][frontpos] >> sx3FrontGain[clkpos][frontpos])
        std::cout << sx3FrontOffset[clkpos][frontpos] << " " << sx3FrontGain[clkpos][frontpos] << std::endl;
    infile.close();

    infile.open("sx3cal/rightgains.dat");
    if (infile.is_open())
      while (infile >> clkpos >> frontpos >> temp >> sx3RightGain[clkpos][frontpos])
      {
        sx3RightGain[clkpos][frontpos] = TMath::Abs(sx3RightGain[clkpos][frontpos]);
      }
    infile.close();
  }
  if (realtime)
  {
    can1 = new TCanvas("wireindex", "c1", 0, 0, 640, 480);
    can2 = new TCanvas("3d", "c2", 650, 0, 640, 480);
    can1->cd();
    // can2->SetFillColor(30);
    frame = new TH3D("frame", "frame", 1000, -100, 100, 1000, -100, 100, 1000, -200, 200);
    hha = new TH1F("hha", "Anode Ecal vs wire#", 48, -12, 36);
    hhc = new TH1F("hhc", "Cathode Ecal vs wire#", 48, -12, 36);
    hha->SetLineColor(kRed);
    hha->GetYaxis()->SetRangeUser(0, 16384);
    hha->GetXaxis()->SetTitle("press any key, interrupt/refresh or double click to continue..");
    hha->Draw();
    hhc->Draw("SAME");
    can1->Modified();
    can1->Update();
    can1->BuildLegend();

    can2->cd();
    frame->Draw();
    for (int i = 0; i < 24; i++)
    {
      plc[i] = new TPolyLine3D(2);
      pla[i] = new TPolyLine3D(2);
      pla[i]->SetPoint(0, pwinstance.An[i].first.X(), pwinstance.An[i].first.Y(), pwinstance.An[i].first.Z());
      pla[i]->SetPoint(1, pwinstance.An[i].second.X(), pwinstance.An[i].second.Y(), pwinstance.An[i].second.Z());
      plc[i]->SetPoint(0, pwinstance.Ca[i].first.X(), pwinstance.Ca[i].first.Y(), pwinstance.Ca[i].first.Z());
      plc[i]->SetPoint(1, pwinstance.Ca[i].second.X(), pwinstance.Ca[i].second.Y(), pwinstance.Ca[i].second.Z());
      plc[i]->SetLineStyle(kDotted);
      pla[i]->SetLineStyle(kDotted);
      pla[i]->SetLineWidth(1.);
      plc[i]->SetLineWidth(1.);
      plc[i]->Draw("same");
      pla[i]->Draw("same");
      plc[i]->SetLineColor(colors[i]);
      pla[i]->SetLineColor(colors[i]);
    }
    crossoverg = new TGraph2D(1);
    crossoverg->SetName("crossoverg");
    crossoverg->SetMarkerStyle(20);
    crossoverg->SetMarkerColor(kBlue + 3);
    qqqg = new TGraph2D(1);
    qqqg->SetName("qqqg");
    qqqg->SetMarkerColor(kRed);
    qqqg->SetMarkerStyle(42);

    crossoverg->SetPoint(0, 0, 0, 0);
    qqqg->SetPoint(0, 0, 0, qqq_z);
    crossoverg->Draw("P same");
    qqqg->Draw("P same");

    can2->Modified();
    can2->Update();
  }

  std::cout << "aaa" << std::endl;
}

Bool_t MakeVertex::Process(Long64_t entry)
{
  hitPos.Clear();
  qqqenergy = -1;
  qqqtimestamp = -1;
  HitNonZero = false;
  bool qqq1000cut = false;
  b_sx3Multi->GetEntry(entry);
  b_sx3ID->GetEntry(entry);
  b_sx3Ch->GetEntry(entry);
  b_sx3E->GetEntry(entry);
  b_sx3T->GetEntry(entry);
  b_qqqMulti->GetEntry(entry);
  b_qqqID->GetEntry(entry);
  b_qqqCh->GetEntry(entry);
  b_qqqE->GetEntry(entry);
  b_qqqT->GetEntry(entry);
  b_pcMulti->GetEntry(entry);
  b_pcID->GetEntry(entry);
  b_pcCh->GetEntry(entry);
  b_pcE->GetEntry(entry);
  b_pcT->GetEntry(entry);

  sx3.CalIndex();
  qqq.CalIndex();
  pc.CalIndex();

  std::vector<Event> sx3Events;
  if (sx3.multi > 1)
  {
    std::array<sx3det, 24> Fsx3;
    // std::cout << "-----" << std::endl;
    for (int i = 0; i < sx3.multi; i++)
    {
      int id = sx3.id[i];
      // if(id>=12) continue;
      if (sx3.ch[i] >= 8)
      {
        int sx3ch = sx3.ch[i] - 8;
        sx3ch = (sx3ch + 3) % 4;
        if (sx3ch == 0 || sx3ch == 3)
          continue;
        float value = sx3.e[i];
        int gch = sx3.id[i] * 4 + (sx3.ch[i] - 8);
        Fsx3.at(id).fillevent("BACK", sx3ch, value);
        Fsx3.at(id).ts = static_cast<double>(sx3.t[i]);
        plotter->Fill2D("sx3backs_raw", 100, 0, 100, 800, 0, 4096, gch, sx3.e[i]);
      }
      else
      {
        int sx3ch = sx3.ch[i] / 2;
        double value = sx3.e[i];
        if (sx3.ch[i] % 2 == 0)
        {
          Fsx3.at(id).fillevent("FRONT_L", sx3ch, value * sx3RightGain[id][sx3ch]);
        }
        else
        {
          Fsx3.at(id).fillevent("FRONT_R", sx3ch, value);
        }
      }
    }
    for (int id = 0; id < 24; id++)
    {
      // std::cout << id << " " << Fsx3.at(id).valid_front_chans.size() << " " << Fsx3.at(id).valid_back_chans.size() << std::endl;;
      try
      {
        Fsx3.at(id).validate();
      }
      catch (std::exception exc)
      {
        std::cout << "oops! anyway" << std::endl;
        continue;
      }
      auto det = Fsx3.at(id);
      bool no_charge_sharing_strict = det.valid_front_chans.size() == 1 && det.valid_back_chans.size() == 1;
      if (det.valid)
      {
        // std::cout << det.frontEL << " " << det.frontEL*sx3RightGain[id][det.stripF] << std::endl;
        plotter->Fill2D("be_vs_x_sx3_id_" + std::to_string(id) + "_f" + std::to_string(det.stripF) + "_b" + std::to_string(det.stripB), 200, -1, 1, 800, 0, 8192,
                        det.frontX, det.backE, "evsx");
        // std::cout << sx3BackGain[id][det.stripF][det.stripB] << " " << sx3FrontGain[id][det.stripF] << std::endl;
        plotter->Fill2D("matched_be_vs_x_sx3_id_" + std::to_string(id) + "_f" + std::to_string(det.stripF), 200, -30, 30, 800, 0, 8192,
                        det.frontX * sx3FrontGain[id][det.stripF] + sx3FrontOffset[id][det.stripF], det.backE * sx3BackGain[id][det.stripF][det.stripB], "evsx_matched");
        // plotter->Fill2D("fe_vs_x_sx3_id_"+std::to_string(id)+"_f"+std::to_string(det.stripF)+"_"+std::to_string(det.stripB),200,-1,1,800,0,4096,det.frontX,det.backE,"evsx");
        plotter->Fill2D("l_vs_r_sx3_id_" + std::to_string(id) + "_f" + std::to_string(det.stripF), 800, 0, 4096, 800, 0, 4096, det.frontEL, det.frontER, "l_vs_r");
      }
      if (det.valid && (id == 9 || id == 7 || id == 1 || id == 3) && det.stripF != DEFAULT_NULL && det.stripB != DEFAULT_NULL)
      {
        double z = det.frontX * sx3FrontGain[id][det.stripF] + sx3FrontOffset[id][det.stripF];
        double backE = det.backE * sx3BackGain[id][det.stripF][det.stripB];
        double beta_n = 15.0 + TMath::ATan2((2 * det.stripF - 3) * 40.30, 8.0 * 88.0 * TMath::Cos(15.0 * M_PI / 180.0)) * 180. / M_PI; // how much to add per strip to the starting position
        double phi_n = ((-id + 0.5) * 30 + beta_n) * M_PI / 180.;                                                                      // starting-position phi + strip contribution
        Event sx3ev(TVector3(88.0 * TMath::Cos(phi_n), 88.0 * TMath::Sin(phi_n), z), backE, -1, det.ts, -1, det.stripB + 4 * id, det.stripF + 4 * id);
        sx3Events.push_back(sx3ev);
      }
    }
  }
  // return kTRUE;
  // QQQ Processing

  int qqqCount = 0;
  int qqqAdjCh = 0;
  // REMOVE WHEN RERUNNING USING THE NEW CALIBRATION FILE
  // for (int i = 0; i < qqq.multi; i++)
  // {
  //   //if ((qqq.id[i] == 3 || qqq.id[i] == 1) && qqq.ch[i] < 16)
  //   if (qqq.id[i] == 1 && qqq.ch[i] < 16) //for run 12, 26Al
  //   {
  //     qqq.ch[i] = 16 - qqq.ch[i];
  //   }
  // }
  // for (int i = 0; i < qqq.multi; i++)
  // {
  //   if (qqq.id[i] == 0 && qqq.ch[i] >= 16)
  //   {
  //     qqq.ch[i] = 31 - qqq.ch[i] + 16;
  //   }
  // }

  std::vector<Event> QQQ_Events, PC_Events;
  std::vector<Event> QQQ_Events_Raw, PC_Events_Raw;
  std::vector<Event> QQQ_Events2; // clustering done

  std::unordered_map<int, std::tuple<int, int, double, double>> qvecr[4], qvecw[4];
  if (qqq.multi > 1)
  {
    // if(qqq.multi>=3) std::cout << "-----" << std::endl;
    for (int i = 0; i < qqq.multi; i++)
    {
      if (qqq.ch[i] / 16)
      {
        if (qvecr[qqq.id[i]].find(qqq.ch[i]) != qvecr[qqq.id[i]].end())
          std::cout << "mayday!" << std::endl;
        qvecr[qqq.id[i]][qqq.ch[i]] = std::tuple(qqq.id[i], qqq.ch[i], qqq.e[i], qqq.t[i]);
      }
      else
      {
        if (qvecw[qqq.id[i]].find(qqq.ch[i]) != qvecw[qqq.id[i]].end())
          std::cout << "mayday!" << std::endl;
        qvecw[qqq.id[i]][qqq.ch[i]] = std::tuple(qqq.id[i], qqq.ch[i], qqq.e[i], qqq.t[i]);
      }
    }
  }

  bool PCQQQTimeCut = false;
  bool PCAQQQTimeCut = false;
  bool PCCQQQTimeCut = false;
  for (int i = 0; i < qqq.multi; i++)
  {
    plotter->Fill2D("QQQ_Index_Vs_Energy", 16 * 8, 0, 16 * 8, 2000, 0, 16000, qqq.index[i], qqq.e[i], "hRawQQQ");

    for (int j = 0; j < qqq.multi; j++)
    {
      if (j == i)
        continue;
      plotter->Fill2D("QQQ_Coincidence_Matrix", 16 * 8, 0, 16 * 8, 16 * 8, 0, 16 * 8, qqq.index[i], qqq.index[j], "hRawQQQ");
    }

    for (int k = 0; k < pc.multi; k++)
    {
      if (pc.index[k] < 24 && pc.e[k] > 50)
      {
        plotter->Fill2D("QQQ_Vs_Anode_Energy", 400, 0, 4000, 1000, 0, 16000, qqq.e[i], pc.e[k], "hRawQQQ");
        plotter->Fill2D("QQQ_Vs_PC_Index", 16 * 8, 0, 16 * 8, 24, 0, 24, qqq.index[i], pc.index[k], "hRawQQQ");
      }
      else if (pc.index[k] >= 24 && pc.e[k] > 50)
      {
        plotter->Fill2D("QQQ_Vs_Cathode_Energy", 400, 0, 4000, 1000, 0, 16000, qqq.e[i], pc.e[k], "hRawQQQ");
      }
    }

    for (int j = i + 1; j < qqq.multi; j++)
    {
      if (qqq.id[i] == qqq.id[j])
      {
        qqqCount++;

        int chWedge = -1;
        int chRing = -1;
        double eWedge = 0.0;
        double eWedgeMeV = 0.0;
        double eRing = 0.0;
        double eRingMeV = 0.0;
        double tRing = 0.0;
        double tWedge = 0.0;

        if (qqq.ch[i] < 16 && qqq.ch[j] >= 16 && qqqGainValid[qqq.id[i]][qqq.ch[i]][qqq.ch[j] - 16])
        {
          chWedge = qqq.ch[i];
          eWedge = qqq.e[i] * qqqGain[qqq.id[i]][qqq.ch[i]][qqq.ch[j] - 16];
          chRing = qqq.ch[j] - 16;
          eRing = qqq.e[j];
          tRing = static_cast<double>(qqq.t[j]);
          tWedge = static_cast<double>(qqq.t[i]);
        }
        else if (qqq.ch[j] < 16 && qqq.ch[i] >= 16 && qqqGainValid[qqq.id[j]][qqq.ch[j]][qqq.ch[i] - 16])
        {
          chWedge = qqq.ch[j];
          eWedge = qqq.e[j] * qqqGain[qqq.id[j]][qqq.ch[j]][qqq.ch[i] - 16];
          chRing = qqq.ch[i] - 16;
          eRing = qqq.e[i];
          tRing = static_cast<double>(qqq.t[i]);
          tWedge = static_cast<double>(qqq.t[j]);
        }
        else
          continue;

        plotter->Fill1D("Wedgetime_Vs_Ringtime", 100, -1000, 1000, tWedge - tRing, "hTiming");
        plotter->Fill2D("RingE_vs_Index", 16 * 4, 0, 16 * 4, 1000, 0, 16000, chRing + qqq.id[i] * 16, eRing, "hRawQQQ");
        plotter->Fill2D("WedgeE_vs_Index", 16 * 4, 0, 16 * 4, 1000, 0, 16000, chWedge + qqq.id[i] * 16, eWedge, "hRawQQQ");

        if (qqqCalibValid[qqq.id[i]][chWedge][chRing])
        {
          eWedgeMeV = eWedge * qqqCalib[qqq.id[i]][chWedge][chRing] / 1000;
          eRingMeV = eRing * qqqCalib[qqq.id[i]][chWedge][chRing] / 1000;

          if (eRingMeV / eWedgeMeV > 3.0 || eRingMeV / eWedgeMeV < 1.0 / 3.0)
            continue;
          // if(eRingMeV<4.0 || eWedgeMeV<4.0) continue;

          // double theta = -TMath::Pi() / 2 + 2 * TMath::Pi() / 16 / 4. * (qqq.id[i] * 16 + chWedge + 0.5); old method
          double theta = 2 * TMath::Pi() * (-qqq.id[i] * 16 + (15 - chWedge) + 0.5) / (16 * 4);
          double rho = 50. + (50. / 16.) * (chRing + 0.5); //"?"
                                                           // z used to be 75+30+23=128
          // we found a 12mm shift towards the vertex later --> 116
          Event qqqevent(TVector3(rho * TMath::Cos(theta), rho * TMath::Sin(theta), qqq_z), eRingMeV, eWedgeMeV, tRing, tWedge, chRing + qqq.id[i] * 16, chWedge + qqq.id[i] * 16);
          Event qqqeventr(TVector3(rho * TMath::Cos(theta), rho * TMath::Sin(theta), qqq_z), eRing, eWedge, tRing, tWedge, chRing + qqq.id[i] * 16, chWedge + qqq.id[i] * 16);
          if (qqq.id[i] >= 1)
          {
            QQQ_Events.push_back(qqqevent);
            QQQ_Events_Raw.push_back(qqqeventr);
          }

          plotter->Fill2D("QQQCartesianPlot", 200, -100, 100, 200, -100, 100, rho * TMath::Cos(theta), rho * TMath::Sin(theta), "hCalQQQ");
          plotter->Fill2D("QQQCartesianPlot" + std::to_string(qqq.id[i]), 200, -100, 100, 200, -100, 100, rho * TMath::Cos(theta), rho * TMath::Sin(theta), "hCalQQQ");
          plotter->Fill2D("PC_XY_Projection_QQQ" + std::to_string(qqq.id[i]), 400, -100, 100, 400, -100, 100, rho * TMath::Cos(theta), rho * TMath::Sin(theta), "hPCQQQ");
        }
        else
          continue;

        plotter->Fill2D("WedgeE_Vs_RingECal", 1000, 0, 10, 1000, 0, 10, eWedgeMeV, eRingMeV, "hCalQQQ");
        plotter->Fill2D("WedgeE_Vs_RingECal_selected", 1000, 0, 10, 1000, 0, 10, eWedgeMeV, eRingMeV, "hCalQQQ");

        for (int k = 0; k < pc.multi; k++)
        {
          plotter->Fill2D("RingCh_vs_Anode_Index", 16 * 4, 0, 16 * 4, 24, 0, 24, chRing + qqq.id[i] * 16, pc.index[k], "hRawQQQ");
          plotter->Fill2D("WedgeCh_vs_Anode_Index", 16 * 4, 0, 16 * 4, 24, 0, 24, chWedge + qqq.id[i] * 16, pc.index[k], "hRawQQQ");
          plotter->Fill2D("WedgeCh_vs_Anode_Index" + std::to_string(qqq.id[i]), 16 * 4, 0, 16 * 4, 24, 0, 24, chWedge + qqq.id[i] * 16, pc.index[k]);
          plotter->Fill2D("RingCh_vs_Cathode_Index", 16 * 4, 0, 16 * 4, 24, 24, 48, chRing + qqq.id[i] * 16, pc.index[k], "hRawQQQ");
          plotter->Fill2D("WedgeCh_vs_Cathode_Index", 16 * 4, 0, 16 * 4, 24, 24, 48, chWedge + qqq.id[i] * 16, pc.index[k], "hRawQQQ");

          if (pc.index[k] < 24 && pc.e[k] > 50)
          {
            plotter->Fill2D("Timing_Difference_QQQ_PC", 500, -2000, 2000, 16, 0, 16, tRing - static_cast<double>(pc.t[k]), chRing, "hTiming");
            plotter->Fill2D("DelT_Vs_QQQRingECal", 500, -2000, 2000, 1000, 0, 10, tRing - static_cast<double>(pc.t[k]), eRingMeV, "hTiming");
            plotter->Fill2D("CalibratedQQQEvsPCE_R", 1000, 0, 10, 2000, 0, 30000, eRingMeV, pc.e[k], "hPCQQQ");
            plotter->Fill2D("CalibratedQQQEvsPCE_W", 1000, 0, 10, 2000, 0, 30000, eWedgeMeV, pc.e[k], "hPCQQQ");
            if (tRing - static_cast<double>(pc.t[k]) < -150) // proton tests, 27Al
            // if (tRing - static_cast<double>(pc.t[k]) < -150 && tRing - static_cast<double>(pc.t[k]) > -450) // 27Al
            // if (tRing - static_cast<double>(pc.t[k]) < -70 && tRing - static_cast<double>(pc.t[k]) > -150) // 17F
            {
              PCAQQQTimeCut = true;
            }
          }

          if (pc.index[k] >= 24 && pc.e[k] > 10)
          {
            if (tRing - static_cast<double>(pc.t[k]) < -200)
              PCCQQQTimeCut = true;
            plotter->Fill2D("Timing_Difference_QQQ_PC_Cathode", 500, -2000, 2000, 16, 0, 16, tRing - static_cast<double>(pc.t[k]), chRing, "hTiming");
          }
        } // end of pc k loop

        if (!HitNonZero)
        {
          // double theta = -TMath::Pi() / 2 + 2 * TMath::Pi() / 16 / 4. * (qqq.id[i] * 16 + chWedge + 0.5); old method
          double theta = 2 * TMath::Pi() * (-qqq.id[i] * 16 + (15 - chWedge) + 0.5) / (16 * 4);
          double rho = 50. + (50. / 16.) * (chRing + 0.5); //"?"

          double x = rho * TMath::Cos(theta);
          double y = rho * TMath::Sin(theta);
          hitPos.SetXYZ(x, y, (qqq_z));
          if (realtime)
            qqqg->SetPoint(0, hitPos.X(), hitPos.Y(), hitPos.Z());
          qqqenergy = eRingMeV;
          qqqtimestamp = tRing;
          HitNonZero = true;
        }
      } // if j==i
    } // j loop end
  } // i loop end

  PCQQQTimeCut = PCAQQQTimeCut && PCCQQQTimeCut;

  plotter->Fill1D("QQQ_Multiplicity", 10, 0, 10, qqqCount, "hRawQQQ");

  typedef std::unordered_map<int, std::tuple<int, double, double>> WireEvent; // this stores nearest neighbour wire events, or a 'cluster'
  WireEvent aWireEvents, cWireEvents;                                         // naming for book keeping
  aWireEvents.clear();
  aWireEvents.reserve(24);
  if (realtime)
  {
    hha->Reset();
    hhc->Reset();
  }

  // PC Gain Matching and Filling
  double anodeT = -99999;
  double cathodeT = 99999;
  int anodeIndex = -1;
  int cathodeIndex = -1;
  for (int i = 0; i < pc.multi; i++)
  {
    if (pc.e[i] > 20)
    {
      plotter->Fill2D("PC_Index_Vs_Energy", 48, 0, 48, 2000, 0, 30000, pc.index[i], static_cast<double>(pc.e[i]), "hRawPC");
    }
    else
    {
      continue;
    }

    if (pc.index[i] < 48)
    {
      pc.e[i] = pcSlope[pc.index[i]] * pc.e[i] + pcIntercept[pc.index[i]];
      plotter->Fill2D("PC_Index_VS_GainMatched_Energy", 48, 0, 48, 2000, 0, 30000, pc.index[i], pc.e[i], "hGMPC");
    }

    if (pc.index[i] < 24)
    {
      anodeT = static_cast<double>(pc.t[i]);
      anodeIndex = pc.index[i];
      aWireEvents[pc.index[i]] = std::tuple(pc.index[i], pc.e[i], static_cast<double>(pc.t[i]));
      if (realtime)
        hha->SetBinContent(hha->FindFixBin(anodeIndex), pc.e[i]);
    }
    else
    {
      cathodeT = static_cast<double>(pc.t[i]);
      cathodeIndex = pc.index[i] - 24;
      cWireEvents[pc.index[i] - 24] = std::tuple(pc.index[i] - 24, pc.e[i], static_cast<double>(pc.t[i]));
      if (realtime)
        hhc->SetBinContent(hhc->FindFixBin(cathodeIndex), pc.e[i]);
    }

    if (anodeT != -99999 && cathodeT != 99999)
    {
      for (int j = 0; j < qqq.multi; j++)
      {
        plotter->Fill1D("PC_Time_qqq", 200, -2000, 2000, anodeT - cathodeT, "hTiming");
        plotter->Fill2D("PC_Time_Vs_QQQ_ch", 200, -2000, 2000, 16 * 8, 0, 16 * 8, anodeT - cathodeT, qqq.ch[j], "hTiming");
        plotter->Fill2D("PC_Time_vs_AIndex", 200, -2000, 2000, 24, 0, 24, anodeT - cathodeT, anodeIndex, "hTiming");
        plotter->Fill2D("PC_Time_vs_CIndex", 200, -2000, 2000, 24, 0, 24, anodeT - cathodeT, cathodeIndex, "hTiming");
        // plotter->Fill1D("PC_Time_A" + std::to_string(anodeIndex) + "_C" + std::to_string(cathodeIndex), 200, -1000, 1000, anodeT - cathodeT, "TimingPC");
      }

      for (int j = 0; j < sx3.multi; j++)
      {
        plotter->Fill1D("PC_Time_sx3", 200, -2000, 2000, anodeT - cathodeT, "hTiming");
      }

      plotter->Fill1D("PC_Time", 200, -2000, 2000, anodeT - cathodeT, "hTiming");
    }

    for (int j = i + 1; j < pc.multi; j++)
    {
      plotter->Fill2D("PC_Coincidence_Matrix", 48, 0, 48, 48, 0, 48, pc.index[i], pc.index[j], "hRawPC");
      plotter->Fill2D("PC_Coincidence_Matrix_anodeMinusCathode_lt_-200_" + std::to_string(anodeT - cathodeT < -200), 48, 0, 48, 48, 0, 48, pc.index[i], pc.index[j], "hRawPC");
      plotter->Fill2D("Anode_V_Anode", 24, 0, 24, 24, 0, 24, pc.index[i], pc.index[j], "hGMPC");
    }
  }

  anodeHits.clear();
  cathodeHits.clear();
  corrcatMax.clear();

  int aID = 0;
  int cID = 0;
  double aE = 0;
  double cE = 0;
  double aESum = 0;
  double cESum = 0;
  double aEMax = 0;
  double cEMax = 0;
  int aIDMax = 0;
  int cIDMax = 0;

  for (int i = 0; i < pc.multi; i++)
  {
    // if (pc.e[i] > 100)
    {
      if (pc.index[i] < 24)
      {
        anodeHits.push_back(std::pair<int, double>(pc.index[i], pc.e[i]));
      }
      else if (pc.index[i] >= 24)
      {
        cathodeHits.push_back(std::pair<int, double>(pc.index[i] - 24, pc.e[i]));
      }
    }
  }

  // std::sort(anodeHits.begin(), anodeHits.end(), [](std::pair<int, double> a, std::pair<int, double> b)
  //           { return a.first < b.first; });
  // std::sort(cathodeHits.begin(), cathodeHits.end(), [](std::pair<int, double> a, std::pair<int, double> b)
  //           { return a.first < b.first; });

  // clusters = collection of (collection of wires) where each wire is (index, energy, timestamp)
  std::vector<std::vector<std::tuple<int, double, double>>> aClusters = pwinstance.Make_Clusters(aWireEvents);
  std::vector<std::vector<std::tuple<int, double, double>>> cClusters = pwinstance.Make_Clusters(cWireEvents);

  std::vector<std::pair<double, double>> sumE_AC;
  for (auto aCluster : aClusters)
  {
    for (auto cCluster : cClusters)
    {
      // if (aCluster.size() <= 1 && cCluster.size() <= 1)
      //   continue;
      if (aCluster.size() <= 1 && cCluster.size() == 0)
        continue;
      auto [crossover, alpha, apSumE, cpSumE, apMaxE, cpMaxE, apTSMaxE, cpTSMaxE] = pwinstance.FindCrossoverProperties(aCluster, cCluster);
      if (alpha != 9999999 && apSumE != -1)
      {
        // Event PCEvent(crossover,apMaxE,cpMaxE,apTSMaxE,cpTSMaxE);
        // Event PCEvent(crossover,apSumE,cpSumE,apTSMaxE,cpTSMaxE);
        Event PCEvent(crossover, apSumE, cpMaxE, apTSMaxE, cpTSMaxE); // run12 shows cathode-max and anode-sum provide best dE signals.
        // std::cout << apSumE << " " << crossover.Perp() << " " << apMaxE << " " << apTSMaxE << std::endl;
        // PCEvent.multi1=aCluster.size();
        // PCEvent.multi2=cCluster.size();
        PC_Events.push_back(PCEvent);
        sumE_AC.push_back(std::pair(apSumE, cpSumE));
      }
    }
  }
  if (QQQ_Events.size() && PC_Events.size())
    plotter->Fill2D("PCEv_vs_QQQEv", 20, 0, 20, 20, 0, 20, QQQ_Events.size(), PC_Events.size());

  plotter->Fill2D("ac_vs_cc", 20, 0, 20, 20, 0, 20, aClusters.size(), cClusters.size(), "wiremult");
  for (auto cluster : aClusters)
  {
    plotter->Fill1D("aClusters" + std::to_string(aClusters.size()), 20, -5, 15, cluster.size(), "wiremult");
  }
  for (auto cluster : cClusters)
  {
    plotter->Fill1D("cClusters" + std::to_string(cClusters.size()), 20, -5, 15, cluster.size(), "wiremult");
  }

  if (cClusters.size() && aClusters.size())
  {
    plotter->Fill2D("ac_vs_cc_ign0", 20, 0, 20, 20, 0, 20, aClusters.size(), cClusters.size(), "wiremult");
  }

  for (auto pcevent : PC_Events)
  {
    if (aClusters.size() == 1 && cClusters.size() == 1)
    {
      // plotter->Fill1D("pcz_a"+std::to_string(aClusters.at(0).size())+"_c"+std::to_string(cClusters.at(0).size()),800,-200,200,pcevent.pos.Z(),"wiremult");
      std::string detid = "_+_";
      if (sx3Events.size())
        detid = "+sx3";
      if (QQQ_Events.size())
        detid = "+qqq";
      plotter->Fill1D("pcz_a" + std::to_string(aClusters.at(0).size()) + "_c" + std::to_string(cClusters.at(0).size()) + detid, 800, -200, 200, pcevent.pos.Z(), "wiremult");
    }
    for (auto sx3event : sx3Events)
    {
      plotter->Fill1D("dt_pcA_sx3B" + std::to_string(sx3event.ch2), 640, -2000, 2000, sx3event.Time1 - pcevent.Time1);
      plotter->Fill1D("dt_pcC_sx3B" + std::to_string(sx3event.ch2), 640, -2000, 2000, sx3event.Time1 - pcevent.Time2);
      plotter->Fill2D("dE_E_Anodesx3B", 400, 0, 10, 800, 0, 40000, sx3event.Energy1 * 0.001, pcevent.Energy1);

      plotter->Fill2D("dE_E_Cathodesx3B", 400, 0, 10, 800, 0, 10000, sx3event.Energy1 * 0.001, pcevent.Energy2);
      double sx3z = sx3event.pos.Z() + (75.0 / 2.0) - 3.0; // w.r.t target origin at 90 for run12
      double sx3rho = 88.0;                                // approximate barrel radius
      double sx3theta = TMath::ATan2(sx3rho, sx3z - source_vertex);
      double pczguess = 37.0 / TMath::Tan(sx3theta) + source_vertex;
      plotter->Fill2D("pcz_vs_sx3pczguess", 300, -178, 178, 150, 0, 200, pczguess, pcevent.pos.Z());
      plotter->Fill2D("pcz_vs_sx3pczguess" + std::to_string(sx3event.ch2), 300, -178, 178, 150, 0, 200, pczguess, pcevent.pos.Z());
      plotter->Fill2D("pcz_vs_sx3z", 300, 0, 178, 300, -200, 200, sx3z, pcevent.pos.Z());
    }
  }

  for (auto aCluster : aClusters)
  {
    for (auto cCluster : cClusters)
    {
      // if (aCluster.size() <= 1 && cCluster.size() <= 1)
      //   continue;
      if (aCluster.size() == 1 && cCluster.size() == 1)
      {
        // plotter->Fill2D("AnodeE_vs_CathodeE_TC" + std::to_string(PCQQQTimeCut) + "_a" + std::to_string(std::get<0>(aCluster.back())) + "c" + std::to_string(std::get<0>(cCluster.back())), 800, 0, 20000, 800, 0, 7000, std::get<1>(aCluster.back()), std::get<1>(cCluster.back()), "AvC");
        plotter->Fill2D("AnodeE_vs_CathodeE_TC" + std::to_string(PCQQQTimeCut), 800, 0, 20000, 800, 0, 7000, std::get<1>(aCluster.back()), std::get<1>(cCluster.back()), "AvC");
      }
      else if (aCluster.size() == 1 && cCluster.size() == 2)
      {
        plotter->Fill2D("CCh1_vsCCh2", 24, 0, 24, 24, 0, 24, std::get<0>(cCluster.back()), std::get<0>(cCluster.front()), "AvC");
        if (std::get<1>(cCluster.back()) + std::get<1>(cCluster.front()) < 3400)
        {
          plotter->Fill2D("CCh1_vsCCh2_gated", 24, 0, 24, 24, 0, 24, std::get<0>(cCluster.back()), std::get<0>(cCluster.front()), "AvC");

          if (std::get<1>(cCluster.back()) > std::get<1>(cCluster.front()))
          {
            plotter->Fill2D("C1vsC2_gated", 400, 0, 8000, 400, 0, 8000, std::get<1>(cCluster.back()), std::get<1>(cCluster.front()), "AvC");
          }
          else if (std::get<1>(cCluster.back()) < std::get<1>(cCluster.front()))
          {
            plotter->Fill2D("C1vsC2_gated", 400, 0, 8000, 400, 0, 8000, std::get<1>(cCluster.front()), std::get<1>(cCluster.back()), "AvC");
          }
        }
        plotter->Fill2D("AnodeE_vs_CathodeESum_TC" + std::to_string(PCQQQTimeCut), 800, 0, 20000, 800, 0, 14000, std::get<1>(aCluster.back()), std::get<1>(cCluster.back()) + std::get<1>(cCluster.front()), "AvC");
        // if (std::get<1>(cCluster.back()) > std::get<1>(cCluster.front()))

        plotter->Fill2D("C1vsC2", 400, 0, 8000, 400, 0, 8000, std::get<1>(cCluster.front()), std::get<1>(cCluster.back()), "AvC");
        plotter->Fill2D("C1vsC2_normA", 1000, 0, 1, 1000, 0, 1, std::get<1>(cCluster.front()) / std::get<1>(aCluster.back()), std::get<1>(cCluster.back()) / std::get<1>(aCluster.back()), "AvC");
        plotter->Fill2D("C1vsC2_normCsum", 1000, 0, 1, 1000, 0, 1, std::get<1>(cCluster.front()) /( std::get<1>(cCluster.back()) + std::get<1>(cCluster.front())), std::get<1>(cCluster.back())/( std::get<1>(cCluster.back()) + std::get<1>(cCluster.front())), "AvC");
        plotter->Fill2D("C1vsC2_normA_TC" + std::to_string(PCQQQTimeCut), 1000, 0, 1, 1000, 0, 1, std::get<1>(cCluster.front()) / std::get<1>(aCluster.back()), std::get<1>(cCluster.back()) / std::get<1>(aCluster.back()), "AvC");
        plotter->Fill2D("C1vsC2_TC" + std::to_string(PCQQQTimeCut), 400, 0, 8000, 400, 0, 8000, std::get<1>(cCluster.front()), std::get<1>(cCluster.back()), "AvC");

        for (auto qqqevent : QQQ_Events)
        {
          plotter->Fill2D("qqqER_2Cathode_dESum", 800, 0, 10, 800, 0, 14000, qqqevent.Energy1, std::get<1>(cCluster.back()) + std::get<1>(cCluster.front()), "AvC");
          plotter->Fill2D("qqqER_AnodeE", 800, 0, 10, 800, 0, 14000, qqqevent.Energy1, std::get<1>(aCluster.back()), "AvC");
        }
      }
      else if (aCluster.size() == 2 && cCluster.size() == 1)
      {
        plotter->Fill2D("ACh1_vsACh2", 24, 0, 24, 24, 0, 24, std::get<0>(aCluster.back()), std::get<0>(aCluster.front()), "AvC");
        if (std::get<1>(aCluster.back()) + std::get<1>(aCluster.front()) < 6800)
        {
          plotter->Fill2D("ACh1_vsACh2_gated", 24, 0, 24, 24, 0, 24, std::get<0>(aCluster.back()), std::get<0>(aCluster.front()), "AvC");
          // if (std::get<1>(aCluster.back()) > std::get<1>(aCluster.front()))
          {
            plotter->Fill2D("A1vsA2_gated", 400, 0, 20000, 400, 0, 20000, std::get<1>(aCluster.back()), std::get<1>(aCluster.front()), "AvC");
          }
        }
        plotter->Fill2D("AnodeESum_vs_CathodeE_TC" + std::to_string(PCQQQTimeCut) + "_a" + std::to_string(std::get<0>(aCluster.back())) + "c" + std::to_string(std::get<0>(cCluster.back())), 800, 0, 30000, 800, 0, 7000, std::get<1>(aCluster.back()) + std::get<1>(aCluster.front()), std::get<1>(cCluster.back()), "AvC");
        plotter->Fill2D("AnodeESum_vs_CathodeE_TC" + std::to_string(PCQQQTimeCut), 800, 0, 30000, 800, 0, 7000, std::get<1>(aCluster.back()) + std::get<1>(aCluster.front()), std::get<1>(cCluster.back()), "AvC");
        // if (std::get<1>(aCluster.back()) > std::get<1>(aCluster.front()))
        {
          plotter->Fill2D("A1vsA2", 400, 0, 20000, 400, 0, 20000, std::get<1>(aCluster.back()), std::get<1>(aCluster.front()), "AvC");
          plotter->Fill2D("A1vsA2_TC" + std::to_string(PCQQQTimeCut), 400, 0, 20000, 400, 0, 20000, std::get<1>(aCluster.back()), std::get<1>(aCluster.front()), "AvC");
        }
        for (auto qqqevent : QQQ_Events)
        {
          plotter->Fill2D("qqqER_2Anode_dESum", 800, 0, 10, 800, 0, 14000, qqqevent.Energy1, std::get<1>(cCluster.back()) + std::get<1>(cCluster.front()), "AvC");
        }
      }
    }
  }

  for (auto pcevent : PC_Events)
  {
    int aSize = pcevent.ch1;
    int cSize = pcevent.ch2;

    if (cSize == 1)
    {
      if (aSize == 1)
        plotter->Fill1D("pcz_a1c1Cluster", 600, -300, 300, pcevent.pos.Z(), "hPCzQQQ");
      else if (aSize == 2)
        plotter->Fill1D("pcz_a2c1Cluster", 600, -300, 300, pcevent.pos.Z(), "hPCzQQQ");
      else if (aSize >= 3)
        plotter->Fill1D("pcz_aNc1Cluster", 600, -300, 300, pcevent.pos.Z(), "hPCzQQQ");
    }
    else if (cSize == 2)
    {
      if (aSize == 1)
        plotter->Fill1D("pcz_a1c2Cluster", 600, -300, 300, pcevent.pos.Z(), "hPCzQQQ");
      else if (aSize == 2)
        plotter->Fill1D("pcz_a2c2Cluster", 600, -300, 300, pcevent.pos.Z(), "hPCzQQQ");
      else if (aSize >= 3)
        plotter->Fill1D("pcz_aNc2Cluster", 600, -300, 300, pcevent.pos.Z(), "hPCzQQQ");
    }
    else if (cSize >= 3)
    {
      if (aSize == 1)
        plotter->Fill1D("pcz_a1cNCluster", 600, -300, 300, pcevent.pos.Z(), "hPCzQQQ");
      else if (aSize == 2)
        plotter->Fill1D("pcz_a2cNCluster", 600, -300, 300, pcevent.pos.Z(), "hPCzQQQ");
      else if (aSize >= 3)
        plotter->Fill1D("pcz_aNcNCluster", 600, -300, 300, pcevent.pos.Z(), "hPCzQQQ");
    }

    for (auto qqqevent : QQQ_Events)
    {
      plotter->Fill1D("dt_pcA_qqqR", 640, -2000, 2000, qqqevent.Time1 - pcevent.Time1);
      plotter->Fill1D("dt_pcC_qqqW", 640, -2000, 2000, qqqevent.Time2 - pcevent.Time2);
      plotter->Fill2D("dE_E_AnodeQQQR", 400, 0, 10, 800, 0, 40000, qqqevent.Energy1, pcevent.Energy1);
      plotter->Fill2D("dE_E_CathodeQQQR", 400, 0, 10, 800, 0, 10000, qqqevent.Energy2, pcevent.Energy2);
      double sinTheta = TMath::Sin((qqqevent.pos - TVector3(0, 0, source_vertex)).Theta());
      if ((qqqevent.pos - TVector3(0, 0, source_vertex)).Theta() * 180 / M_PI > 52)
      {
        plotter->Fill2D("dE2_E_AnodeQQQR_outer", 400, 0, 10, 800, 0, 40000, qqqevent.Energy1, pcevent.Energy1 * sinTheta);
        plotter->Fill2D("dE2_E_CathodeQQQR_outer", 400, 0, 10, 800, 0, 10000, qqqevent.Energy2, pcevent.Energy2 * sinTheta);
        plotter->Fill2D("dE_E_AnodeQQQR_outer", 400, 0, 10, 800, 0, 40000, qqqevent.Energy1, pcevent.Energy1);
        plotter->Fill2D("dE_E_CathodeQQQR_outer", 400, 0, 10, 800, 0, 10000, qqqevent.Energy2, pcevent.Energy2);
      }
      else
      {
        plotter->Fill2D("dE2_E_AnodeQQQR_inner", 400, 0, 10, 800, 0, 40000, qqqevent.Energy1, pcevent.Energy1 * sinTheta);
        plotter->Fill2D("dE2_E_CathodeQQQR_inner", 400, 0, 10, 800, 0, 10000, qqqevent.Energy2, pcevent.Energy2 * sinTheta);
        plotter->Fill2D("dE_E_AnodeQQQR_inner", 400, 0, 10, 800, 0, 40000, qqqevent.Energy1, pcevent.Energy1);
        plotter->Fill2D("dE_E_CathodeQQQR_inner", 400, 0, 10, 800, 0, 10000, qqqevent.Energy2, pcevent.Energy2);
      }

      bool timecut = (qqqevent.Time1 - pcevent.Time1 < -150);
      if (timecut)
      { // && qqqevent.pos.Phi() <= pcevent.pos.Phi()+TMath::Pi()/4. && qqqevent.pos.Phi() >= pcevent.pos.Phi()-TMath::Pi()/4. ) {
        plotter->Fill2D("dE_theta_AnodeQQQR", 75, 0, 90, 400, 0, 20000, (qqqevent.pos - TVector3(0, 0, source_vertex)).Theta() * 180 / M_PI, pcevent.Energy1);
        plotter->Fill2D("dE2_theta_AnodeQQQR", 75, 0, 90, 400, 0, 20000, (qqqevent.pos - TVector3(0, 0, source_vertex)).Theta() * 180 / M_PI, pcevent.Energy1 * sinTheta);

        plotter->Fill2D("E_theta_AnodeQQQR", 75, 0, 90, 300, 0, 15, (qqqevent.pos - TVector3(0, 0, source_vertex)).Theta() * 180 / M_PI, qqqevent.Energy1);
        plotter->Fill2D("E2_theta_AnodeQQQR", 75, 0, 90, 300, 0, 15, (qqqevent.pos - TVector3(0, 0, source_vertex)).Theta() * 180 / M_PI, qqqevent.Energy1);
        plotter->Fill2D("Etot2_theta_AnodeQQQR", 75, 0, 90, 300, 0, 15, (qqqevent.pos - TVector3(0, 0, source_vertex)).Theta() * 180 / M_PI, qqqevent.Energy1 + pcevent.Energy1 * anode_gain * sinTheta);

        plotter->Fill2D("dE_theta_CathodeQQQR", 75, 0, 90, 800, 0, 10000, (qqqevent.pos - TVector3(0, 0, source_vertex)).Theta() * 180 / M_PI, pcevent.Energy2);
        plotter->Fill2D("dE2_theta_CathodeQQQR", 75, 0, 90, 800, 0, 10000, (qqqevent.pos - TVector3(0, 0, source_vertex)).Theta() * 180 / M_PI, pcevent.Energy2 * sinTheta);

        plotter->Fill2D("dE_phi_AnodeQQQR", 100, -180, 180, 800, 0, 40000, (qqqevent.pos - TVector3(0, 0, source_vertex)).Phi() * 180 / M_PI, pcevent.Energy1);

        plotter->Fill2D("dE_phi_CathodeQQQR", 100, -180, 180, 800, 0, 10000, (qqqevent.pos - TVector3(0, 0, source_vertex)).Phi() * 180 / M_PI, pcevent.Energy2);
        plotter->Fill1D("PCZ", 800, -200, 200, pcevent.pos.Z(), "phicut");
        plotter->Fill1D("PCZ_phicut_a" + std::to_string(aClusters.at(0).size()) + "_c" + std::to_string(cClusters.at(0).size()), 800, -200, 200, pcevent.pos.Z(), "wiremult");

        double pcz_guess_37 = 37. / TMath::Tan((qqqevent.pos - TVector3(0, 0, source_vertex)).Theta()) + source_vertex;
        plotter->Fill2D("pczguess_vs_pc_37", 180, 0, 200, 150, 0, 200, pcz_guess_37, pcevent.pos.Z(), "phicut");

        double pcz_guess_42 = 42. / TMath::Tan((qqqevent.pos - TVector3(0, 0, source_vertex)).Theta()) + source_vertex;
        plotter->Fill2D("pczguess_vs_pc_42", 180, 0, 200, 150, 0, 200, pcz_guess_42, pcevent.pos.Z(), "phicut");

        double pcz_guess_int = z_to_crossover_rho(pcevent.pos.Z()) / TMath::Tan((qqqevent.pos - TVector3(0, 0, source_vertex)).Theta()) + source_vertex;
        // plotter->Fill2D("pczguess_vs_pc_int",180,0,200,150,0,200,pcz_guess_int,pcevent.pos.Z(),"phicut");
        plotter->Fill2D("pczguess_vs_pc_int", 180, 0, 200, 600, -400, 400, pcz_guess_int, pcevent.pos.Z(), "phicut");

        double qqqrho = qqqevent.pos.Perp();
        double qqqz = (qqqevent.pos - TVector3(0, 0, source_vertex)).Z();
        double tan_theta = qqqrho / qqqz;
        double pcz_guess_int2 = z_to_crossover_rho(pcevent.pos.Z()) / tan_theta + source_vertex;
        plotter->Fill2D("pczguess_vs_pc_int2", 180, 0, 200, 150, 0, 200, pcz_guess_int, pcevent.pos.Z(), "phicut");
        plotter->Fill2D("pczguess_vs_pc_int2_a" + std::to_string(pcevent.multi1) + "_c" + std::to_string(pcevent.multi2), 180, 0, 200, 150, 0, 200, pcz_guess_int, pcevent.pos.Z(), "phicut");

        double pcz_guess = pcz_guess_int;
        plotter->Fill2D("pctheta_vs_qqqtheta", 320, 0, 160, 320, 0, 160, (qqqevent.pos - TVector3(0, 0, source_vertex)).Theta() * 180 / M_PI, (pcevent.pos - TVector3(0, 0, source_vertex)).Theta() * 180 / M_PI, "phicut");

        plotter->Fill2D("pczguess_vs_pc_phi=" + std::to_string(qqqevent.pos.Phi() * 180. / M_PI), 300, 0, 200, 150, 0, 200, pcz_guess, pcevent.pos.Z(), "phicut");

        // plotter->Fill1D("PCZ",800,-200,200,pcevent.pos.Z(),"phicut");
      }

      if (qqqevent.pos.Phi() <= pcevent.pos.Phi() + TMath::Pi() / 4. && qqqevent.pos.Phi() >= pcevent.pos.Phi() - TMath::Pi() / 4.)
      {
        plotter->Fill1D("PCZ", 800, -200, 200, pcevent.pos.Z(), "phicut");
        double pcz_guess_37 = 37. / TMath::Tan((qqqevent.pos - TVector3(0, 0, source_vertex)).Theta()) + source_vertex;
        plotter->Fill2D("pczguess_vs_pc_37", 180, 0, 200, 150, 0, 200, pcz_guess_37, pcevent.pos.Z(), "phicut");

        double pcz_guess_42 = 42. / TMath::Tan((qqqevent.pos - TVector3(0, 0, source_vertex)).Theta()) + source_vertex;
        plotter->Fill2D("pczguess_vs_pc_42", 180, 0, 200, 150, 0, 200, pcz_guess_42, pcevent.pos.Z(), "phicut");

        double pcz_guess_int = z_to_crossover_rho(pcevent.pos.Z()) / TMath::Tan((qqqevent.pos - TVector3(0, 0, source_vertex)).Theta()) + source_vertex;
        // plotter->Fill2D("pczguess_vs_pc_int",180,0,200,150,0,200,pcz_guess_int,pcevent.pos.Z(),"phicut");
        plotter->Fill2D("pczguess_vs_pc_int", 180, 0, 200, 600, -400, 400, pcz_guess_int, pcevent.pos.Z(), "phicut");

        double qqqrho = qqqevent.pos.Perp();
        double qqqz = (qqqevent.pos - TVector3(0, 0, source_vertex)).Z();
        double tan_theta = qqqrho / qqqz;
        double pcz_guess_int2 = z_to_crossover_rho(pcevent.pos.Z()) / tan_theta + source_vertex;
        plotter->Fill2D("pczguess_vs_pc_int2", 180, 0, 200, 150, 0, 200, pcz_guess_int, pcevent.pos.Z(), "phicut");
        plotter->Fill2D("pczguess_vs_pc_int2_a" + std::to_string(pcevent.multi1) + "_c" + std::to_string(pcevent.multi2), 180, 0, 200, 150, 0, 200, pcz_guess_int, pcevent.pos.Z(), "phicut");

        double pcz_guess = pcz_guess_int;
        plotter->Fill2D("pctheta_vs_qqqtheta", 320, 0, 160, 320, 0, 160, (qqqevent.pos - TVector3(0, 0, source_vertex)).Theta() * 180 / M_PI, (pcevent.pos - TVector3(0, 0, source_vertex)).Theta() * 180 / M_PI, "phicut");

        plotter->Fill2D("pczguess_vs_pc_phi=" + std::to_string(qqqevent.pos.Phi() * 180. / M_PI), 300, 0, 200, 150, 0, 200, pcz_guess, pcevent.pos.Z(), "phicut");
      }

      if (cSize == 1)
      {
        if (aSize == 1)
          plotter->Fill1D("pcz_a1c1Cluster_QQQ", 600, -300, 300, pcevent.pos.Z(), "hPCzQQQ");
        else if (aSize == 2)
          plotter->Fill1D("pcz_a2c1Cluster_QQQ", 600, -300, 300, pcevent.pos.Z(), "hPCzQQQ");
        else if (aSize >= 3)
          plotter->Fill1D("pcz_aNc1Cluster_QQQ", 600, -300, 300, pcevent.pos.Z(), "hPCzQQQ");
      }
      else if (cSize == 2)
      {
        if (aSize == 1)
          plotter->Fill1D("pcz_a1c2Cluster_QQQ", 600, -300, 300, pcevent.pos.Z(), "hPCzQQQ");
        else if (aSize == 2)
          plotter->Fill1D("pcz_a2c2Cluster_QQQ", 600, -300, 300, pcevent.pos.Z(), "hPCzQQQ");
        else if (aSize >= 3)
          plotter->Fill1D("pcz_aNc2Cluster_QQQ", 600, -300, 300, pcevent.pos.Z(), "hPCzQQQ");
      }
      else if (cSize >= 3)
      {
        if (aSize == 1)
          plotter->Fill1D("pcz_a1cNCluster_QQQ", 600, -300, 300, pcevent.pos.Z(), "hPCzQQQ");
        else if (aSize == 2)
          plotter->Fill1D("pcz_a2cNCluster_QQQ", 600, -300, 300, pcevent.pos.Z(), "hPCzQQQ");
        else if (aSize >= 3)
          plotter->Fill1D("pcz_aNcNCluster_QQQ", 600, -300, 300, pcevent.pos.Z(), "hPCzQQQ");
      }
    }
  }
  // HALFTIME! Can stop here in future versions
  // return kTRUE;

  if (anodeHits.size() >= 1 && cathodeHits.size() >= 1)
  {
    // 2. CRITICAL FIX: Define reference vector 'a'
    // In Analyzer.cxx, 'a' was left over from the loop. We use the first anode wire as reference here.
    // (Assuming pwinstance.An is populated and wires are generally parallel).
    TVector3 refAnode = pwinstance.An[0].first - pwinstance.An[0].second;

    {
      for (const auto &anode : anodeHits)
      {
        aID = anode.first;
        aE = anode.second;
        aESum += aE;
        if (aE > aEMax)
        {
          aEMax = aE;
          aIDMax = aID;
        }
      }

      for (const auto &cathode : cathodeHits)
      {
        cID = cathode.first;
        cE = cathode.second;
        plotter->Fill2D("AnodeMax_Vs_Cathode_Coincidence_Matrix", 24, 0, 24, 24, 0, 24, aIDMax, cID, "hRawPC");
        plotter->Fill2D("Anode_Vs_Cathode_Coincidence_Matrix", 24, 0, 24, 24, 0, 24, aID, cID, "hRawPC");
        plotter->Fill2D("Anode_vs_CathodeE", 2000, 0, 30000, 2000, 0, 30000, aE, cE, "hGMPC");
        plotter->Fill2D("CathodeMult_V_CathodeE", 6, 0, 6, 2000, 0, 30000, cathodeHits.size(), cE, "hGMPC");
        for (int j = -4; j < 3; j++)
        {
          if ((aIDMax + 24 + j) % 24 == 23 - cID)
          {
            corrcatMax.push_back(std::pair<int, double>(cID, cE));
            cESum += cE;
            if (cE > cEMax)
            {
              cEMax = cE;
              cIDMax = cID;
            }
          }
        }
      }
    }
  }

  TVector3 anodeIntersection, vector_closest_to_z;
  anodeIntersection.Clear();
  vector_closest_to_z.Clear();
  if (corrcatMax.size() > 0)
  {
    double x = 0, y = 0, z = 0;
    for (const auto &corr : corrcatMax)
    {
      if (pwinstance.Crossover[aIDMax][corr.first][0].z > 9000000)
        continue;
      if (cESum > 0)
      {
        x += (corr.second) / cESum * pwinstance.Crossover[aIDMax][corr.first][0].x;
        y += (corr.second) / cESum * pwinstance.Crossover[aIDMax][corr.first][0].y;
        z += (corr.second) / cESum * pwinstance.Crossover[aIDMax][corr.first][0].z;
      }
    }
    if (x == 0 && y == 0 && z == 0)
      ;
    // to ignore events with no valid crossover points
    else
      anodeIntersection = TVector3(x, y, z);
    // << "Anode Intersection: " << anodeIntersection.X() << ", " << anodeIntersection.Y() << ", " << anodeIntersection.Z() << std::endl;
  }
  bool PCQQQPhiCut = false;
  // flip the algorithm for cathode 1 multi anode events
  if ((hitPos.Phi() > (anodeIntersection.Phi() - TMath::PiOver4())) && (hitPos.Phi() < (anodeIntersection.Phi() + TMath::PiOver4())))
  {
    PCQQQPhiCut = true;
  }

  if (anodeIndex != -1 && cathodeIndex != -1 && hitPos.Perp() != 0 && anodeIntersection.Perp() != 0 && realtime)
  {
    can1->Modified();
    can1->Update();
    for (auto cath : corrcatMax)
    {
      plc[cath.first]->SetLineWidth(3);
      // plc[cath.first]->SetLineStyle(kLine);
    }
    for (auto anodeW : anodeHits)
    {
      pla[anodeW.first]->SetLineWidth(3);
      // pla[anodeW.first]->SetLineStyle(kLine);
    }
    // can2->Modified();
    can2->Update();
    while (can1->WaitPrimitive())
      ;
    // pla[anodeIndex]->SetLineWidth(1);
    // pla[anodeIndex]->SetLineStyle(kDotted);
    for (auto anodeW : anodeHits)
    {
      pla[anodeW.first]->SetLineWidth(1);
      pla[anodeW.first]->SetLineStyle(kDotted);
    }
    for (auto cath : corrcatMax)
    {
      plc[cathodeIndex]->SetLineStyle(kDotted);
      plc[cath.first]->SetLineWidth(1);
    }
  }

  if (anodeIntersection.Z() != 0 && anodeIntersection.Perp() > 0 && HitNonZero)
  {
    plotter->Fill1D("PC_Z_Projection", 600, -300, 300, anodeIntersection.Z(), "hPCzQQQ");
    plotter->Fill2D("Z_Proj_VsDelTime", 600, -300, 300, 200, -2000, 2000, anodeIntersection.Z(), anodeT - cathodeT, "hPCzQQQ");
    plotter->Fill2D("IntPhi_vs_QQQphi", 100, -200, 200, 80, -200, 200, anodeIntersection.Phi() * 180. / TMath::Pi(), hitPos.Phi() * 180. / TMath::Pi(), "hPCQQQ");
    // plotter->Fill2D("Inttheta_vs_QQQtheta", 90, 0, 180, 20, 0, 45, anodeIntersection.Theta() * 180. / TMath::Pi(), hitPos.Theta() * 180. / TMath::Pi(), "hPCQQQ");
    // plotter->Fill2D("Inttheta_vs_QQQtheta_TC" + std::to_string(PCQQQTimeCut)+ "_PC"+std::to_string(PCQQQPhiCut), 90, 0, 180, 20, 0, 45, anodeIntersection.Theta() * 180. / TMath::Pi(), hitPos.Theta() * 180. / TMath::Pi(), "hPCQQQ");
    plotter->Fill2D("IntPhi_vs_QQQphi_TC" + std::to_string(PCQQQTimeCut) + "PhiC" + std::to_string(PCQQQPhiCut), 100, -200, 200, 80, -200, 200, anodeIntersection.Phi() * 180. / TMath::Pi(), hitPos.Phi() * 180. / TMath::Pi(), "hPCQQQ");
  }
  if (anodeIntersection.Z() != 0 && cathodeHits.size() >= 2)
    plotter->Fill1D("PC_Z_Projection_TC" + std::to_string(PCQQQTimeCut) + "PhiC" + std::to_string(PCQQQPhiCut), 600, -300, 300, anodeIntersection.Z(), "hPCzQQQ");

  if (anodeIntersection.Z() != 0 && cathodeHits.size() == 1)
  {
    plotter->Fill1D("PC_Z_proj_1C", 600, -300, 300, anodeIntersection.Z(), "hPCzQQQ");
    plotter->Fill2D("IntersectionPhi_vs_AnodeZ_1C", 400, -200, 200, 600, -300, 300, anodeIntersection.Phi() * 180. / TMath::Pi(), anodeIntersection.Z(), "hPCzQQQ");
  }

  if (anodeIntersection.Z() != 0 && cathodeHits.size() == 2)
  {
    plotter->Fill1D("PC_Z_proj_2C", 600, -300, 300, anodeIntersection.Z(), "hPCzQQQ");
    plotter->Fill2D("IntersectionPhi_vs_AnodeZ_2C", 400, -200, 200, 600, -300, 300, anodeIntersection.Phi() * 180. / TMath::Pi(), anodeIntersection.Z(), "hGMPC");
  }
  if (anodeIntersection.Z() != 0 && cathodeHits.size() > 2)
  {
    plotter->Fill1D("PC_Z_proj_nC", 600, -300, 300, anodeIntersection.Z(), "hPCzQQQ");
    plotter->Fill2D("IntersectionPhi_vs_AnodeZ_nC", 400, -200, 200, 600, -300, 300, anodeIntersection.Phi() * 180. / TMath::Pi(), anodeIntersection.Z(), "hGMPC");
  }
  if (anodeHits.size() > 0 && cathodeHits.size() > 0)
    plotter->Fill2D("AHits_vs_CHits", 12, 0, 11, 6, 0, 5, anodeHits.size(), cathodeHits.size(), "hRawPC");

  // make another plot with nearest neighbour constraint
  bool hasNeighbourAnodes = false;
  bool hasNeighbourCathodes = false;

  // 1. Check Anodes for neighbours (including wrap-around 0-23)
  for (size_t i = 0; i < anodeHits.size(); i++)
  {
    for (size_t j = i + 1; j < anodeHits.size(); j++)
    {
      int diff = std::abs(anodeHits[i].first - anodeHits[j].first);
      if (diff == 1 || diff == 23)
      { // 23 handles the cylindrical wrap
        hasNeighbourAnodes = true;
        break;
      }
    }
    if (hasNeighbourAnodes)
      break;
  }

  // 2. Check Cathodes for neighbours (including wrap-around 0-23)
  for (size_t i = 0; i < cathodeHits.size(); i++)
  {
    for (size_t j = i + 1; j < cathodeHits.size(); j++)
    {
      int diff = std::abs(cathodeHits[i].first - cathodeHits[j].first);
      if (diff == 1 || diff == 23)
      {
        hasNeighbourCathodes = true;
        break;
      }
    }
    if (hasNeighbourCathodes)
      break;
  }

  // ---------------------------------------------------------
  // FILL PLOTS
  // ---------------------------------------------------------
  if (anodeHits.size() > 0 && cathodeHits.size() > 0)
  {
    plotter->Fill2D("AHits_vs_CHits_NA" + std::to_string(hasNeighbourAnodes), 12, 0, 11, 6, 0, 5, anodeHits.size(), cathodeHits.size(), "hRawPC");
    plotter->Fill2D("AHits_vs_CHits_NC" + std::to_string(hasNeighbourCathodes), 12, 0, 11, 6, 0, 5, anodeHits.size(), cathodeHits.size(), "hRawPC");

    // Constraint Plot: Only fill if BOTH planes have adjacent hits
    // This effectively removes events with only isolated single-wire hits (noise)
    if (hasNeighbourAnodes && hasNeighbourCathodes)
    {
      plotter->Fill2D("AHits_vs_CHits_NN", 12, 0, 11, 6, 0, 5, anodeHits.size(), cathodeHits.size(), "hRawPC");
    }
  }

  if (HitNonZero && anodeIntersection.Z() != 0)
  {
    pwinstance.CalTrack2(hitPos, anodeIntersection);
    plotter->Fill1D("VertexRecon", 600, -1300, 1300, pwinstance.GetZ0());
    plotter->Fill1D("VertexRecon_TC" + std::to_string(PCQQQTimeCut) + "_PhiC" + std::to_string(PCQQQPhiCut), 600, -1300, 1300, pwinstance.GetZ0());

    if (cathodeHits.size() == 2)
      plotter->Fill1D("VertexRecon_2c_TC" + std::to_string(PCQQQTimeCut) + "_PhiC" + std::to_string(PCQQQPhiCut), 600, -1300, 1300, pwinstance.GetZ0());

    TVector3 x2(anodeIntersection), x1(hitPos);

    TVector3 v = x2 - x1;
    double t_minimum = -1.0 * (x1.X() * v.X() + x1.Y() * v.Y()) / (v.X() * v.X() + v.Y() * v.Y());
    vector_closest_to_z = x1 + t_minimum * v;

    plotter->Fill1D("VertexRecon_Z_TC" + std::to_string(PCQQQTimeCut) + "_PhiC" + std::to_string(PCQQQPhiCut), 600, -1300, 1300, vector_closest_to_z.Z(), "customVertex");
    if (vector_closest_to_z.Perp() < 20)
    {
      plotter->Fill1D("VertexRecon_RadialCut_Z_TC" + std::to_string(PCQQQTimeCut) + "_PhiC" + std::to_string(PCQQQPhiCut), 600, -1300, 1300, vector_closest_to_z.Z(), "customVertex");
    }

    plotter->Fill2D("VertexRecon_XY_TC" + std::to_string(PCQQQTimeCut) + "_PhiC" + std::to_string(PCQQQPhiCut), 100, -100, 100, 100, -100, 100, vector_closest_to_z.X(), vector_closest_to_z.Y(), "customVertex");
    if (cathodeHits.size() == 2)
    {
      plotter->Fill1D("VertexRecon2C_Z_TC" + std::to_string(PCQQQTimeCut) + "_PhiC" + std::to_string(PCQQQPhiCut), 600, -1300, 1300, vector_closest_to_z.Z(), "customVertex");
      if (vector_closest_to_z.Perp() < 20)
      {
        plotter->Fill1D("VertexRecon2C_RadialCut_Z_TC" + std::to_string(PCQQQTimeCut) + "_PhiC" + std::to_string(PCQQQPhiCut), 600, -1300, 1300, vector_closest_to_z.Z(), "customVertex");
      }
      plotter->Fill2D("VertexRecon2C_XY_TC" + std::to_string(PCQQQTimeCut) + "_PhiC" + std::to_string(PCQQQPhiCut), 100, -100, 100, 100, -100, 100, vector_closest_to_z.X(), vector_closest_to_z.Y(), "customVertex");
      plotter->Fill2D("VertexRecon2C_RhoZ_TC" + std::to_string(PCQQQTimeCut) + "_PhiC" + std::to_string(PCQQQPhiCut), 100, -100, 100, 600, -1300, 1300, vector_closest_to_z.Perp(), vector_closest_to_z.Z(), "customVertex");
      plotter->Fill2D("VertexRecon2C_Z_vs_QQQE_TC" + std::to_string(PCQQQTimeCut) + "_PhiC" + std::to_string(PCQQQPhiCut), 600, -1300, 1300, 800, 0, 20000, vector_closest_to_z.Z(), qqqenergy, "customVertex");
    }
  }

  for (int i = 0; i < qqq.multi; i++)
  {
    if (anodeIntersection.Perp() > 0)
    { // suppress x,y=0,0 events
      if (PCQQQTimeCut)
      {
        plotter->Fill2D("PC_XY_Projection_QQQ_TimeCut" + std::to_string(qqq.id[i]), 400, -100, 100, 400, -100, 100, anodeIntersection.X(), anodeIntersection.Y(), "hPCQQQ");
      }
      plotter->Fill2D("PC_XY_Projection_QQQ" + std::to_string(qqq.id[i]), 400, -100, 100, 400, -100, 100, anodeIntersection.X(), anodeIntersection.Y(), "hPCQQQ");
    }
    for (int j = i + 1; j < qqq.multi; j++)
    {
      if (qqq.id[i] == qqq.id[j])
      {
        int chWedge = -1;
        int chRing = -1;
        double eWedge = 0.0;
        double eWedgeMeV = 0.0;
        double eRing = 0.0;
        double eRingMeV = 0.0;
        double tRing = 0.0;
        int qqqID = -1;
        if (qqq.ch[i] < 16 && qqq.ch[j] >= 16 && qqqGainValid[qqq.id[i]][qqq.ch[i]][qqq.ch[j] - 16])
        {
          chWedge = qqq.ch[i];
          eWedge = qqq.e[i] * qqqGain[qqq.id[i]][qqq.ch[i]][qqq.ch[j] - 16];
          chRing = qqq.ch[j] - 16;
          eRing = qqq.e[j];
          tRing = static_cast<double>(qqq.t[j]);
          qqqID = qqq.id[i];
        }
        else if (qqq.ch[j] < 16 && qqq.ch[i] >= 16 && qqqGainValid[qqq.id[j]][qqq.ch[j]][qqq.ch[i] - 16])
        {
          chWedge = qqq.ch[j];
          eWedge = qqq.e[j] * qqqGain[qqq.id[j]][qqq.ch[j]][qqq.ch[i] - 16];
          chRing = qqq.ch[i] - 16;
          tRing = static_cast<double>(qqq.t[i]);
          eRing = qqq.e[i];
          qqqID = qqq.id[i];
        }
        else
          continue;

        if (qqqCalibValid[qqq.id[i]][chRing][chWedge])
        {
          eWedgeMeV = eWedge * qqqCalib[qqq.id[i]][chRing][chWedge] / 1000;
          eRingMeV = eRing * qqqCalib[qqq.id[i]][chRing][chWedge] / 1000;
        }
        else
          continue;

        // if (anodeIntersection.Z() != 0)
        {
          plotter->Fill2D("PC_Z_vs_QQQRing", 600, -300, 300, 16, 0, 16, anodeIntersection.Z(), chRing, "hPCzQQQ");
          plotter->Fill2D("PC_Z_vs_QQQRho", 600, -300, 300, 40, 40, 110, anodeIntersection.Z(), hitPos.Perp(), "hPCzQQQ");
        }

        if (anodeIntersection.Z() != 0 && cathodeHits.size() == 2)
        {
          plotter->Fill2D("PC_Z_vs_QQQRing_2C", 600, -300, 300, 16, 0, 16, anodeIntersection.Z(), chRing, "hPCzQQQ");
          plotter->Fill2D("PC_Z_vs_QQQRing_2C" + std::to_string(qqq.id[i]), 600, -300, 300, 16, 0, 16, anodeIntersection.Z(), chRing, "hPCzQQQ");
          plotter->Fill2D("PC_Z_vs_QQQWedge_2C", 600, -300, 300, 16, 0, 16, anodeIntersection.Z(), chWedge, "hPCzQQQ");
        }
        plotter->Fill2D("VertexRecon_QQQRingTC" + std::to_string(PCQQQTimeCut) + "PhiC" + std::to_string(PCQQQPhiCut), 600, -1300, 1300, 16, 0, 16, vector_closest_to_z.Z(), chRing, "hPCQQQ");
        double phi = TMath::ATan2(anodeIntersection.Y(), anodeIntersection.X()) * 180. / TMath::Pi();
        plotter->Fill2D("PolarAngle_Vs_QQQWedge" + std::to_string(qqqID), 360, -360, 360, 16, 0, 16, phi, chWedge, "hPCQQQ");
        // plotter->Fill2D("EdE_PC_vs_QQQ_timegate_ls1000"+std::to_string())

        plotter->Fill2D("PC_Z_vs_QQQRing_Det" + std::to_string(qqqID), 600, -300, 300, 16, 0, 16, anodeIntersection.Z(), chRing, "hPCQQQ");
        // double theta = -TMath::Pi() / 2 + 2 * TMath::Pi() / 16 / 4. * (qqq.id[i] * 16 + chWedge + 0.5);
        // double rho = 50. + 40. / 16. * (chRing + 0.5);

        for (int k = 0; k < pc.multi; k++)
        {
          if (pc.index[k] >= 24)
            continue;

          //          double sinTheta = TMath::Sin((hitPos-vector_closest_to_z).Theta());
          double sinTheta = TMath::Sin((anodeIntersection - TVector3(0, 0, 90.0)).Theta());
          //           double sinTheta = TMath::Sin((anodeIntersection-vector_closest_to_z).Theta());
          //          double sinTheta = TMath::Sin((hitPos-TVector3(0,0,30.0)).Theta());
          //          double sinTheta = TMath::Sin(hitPos.Theta());

          if (cathodeHits.size() == 2 && PCQQQPhiCut)
          {
            plotter->Fill2D("CalibratedQQQE_RvsCPCE_TC" + std::to_string(PCQQQTimeCut), 400, 0, 10, 400, 0, 30000, eRingMeV, pc.e[k] * sinTheta, "hPCQQQ");
            plotter->Fill2D("CalibratedQQQE_WvsCPCE_TC" + std::to_string(PCQQQTimeCut), 400, 0, 10, 400, 0, 30000, eWedgeMeV, pc.e[k] * sinTheta, "hPCQQQ");
            plotter->Fill2D("CalibratedQQQE_RvsPCE_TC" + std::to_string(PCQQQTimeCut), 400, 0, 10, 400, 0, 30000, eRingMeV, pc.e[k], "hPCQQQ");
            plotter->Fill2D("CalibratedQQQE_WvsPCE_TC" + std::to_string(PCQQQTimeCut), 400, 0, 10, 400, 0, 30000, eWedgeMeV, pc.e[k], "hPCQQQ");
            plotter->Fill2D("PCQQQ_dTimevsdPhi", 200, -2000, 2000, 80, -200, 200, tRing - static_cast<double>(pc.t[k]), (hitPos.Phi() - anodeIntersection.Phi()) * 180. / TMath::Pi(), "hTiming");
          }
        }
      } /// qqq i==j case end
    } // j loop end
  } // qqq i loop end

  TVector3 guessVertex(0, 0, source_vertex); // for run12, subtract anodeIntersection.Z() by ~74.0 seems to work
  // rho=40.0 mm is halfway between the cathodes(rho=42) and anodes(rho=37)
  double pcz_guess = z_to_crossover_rho(anodeIntersection.Z()) / TMath::Tan((hitPos - guessVertex).Theta()) + guessVertex.Z(); // this is ideally kept to be all QQQ+userinput for calibration of pcz
  if (PCQQQTimeCut && PCQQQPhiCut && hitPos.Perp() > 0 && anodeIntersection.Perp() > 0 && cathodeHits.size() >= 2)
  {
    plotter->Fill2D("pczguess_vs_qqqE", 100, 0, 200, 800, 0, 20, pcz_guess, qqqenergy, "pczguess");
    double pczoffset = 0.0;
    // plotter->Fill2D("pczguess_vs_pcz_rad="+std::to_string(hitPos.Perp()),100,0,200,150,0,200,pcz_guess,anodeIntersection.Z(),"pczguess"); //entirely qqq-derived position vs entirely PC derived position
    plotter->Fill2D("pczguess_vs_pcz_phi=" + std::to_string(hitPos.Phi() * 180. / M_PI), 100, 0, 200, 150, 0, 200, pcz_guess, anodeIntersection.Z(), "pczguess"); // entirely qqq-derived position vs entirely PC derived position
    plotter->Fill2D("pczguess_vs_pcz", 100, 0, 200, 150, 0, 200, pcz_guess, anodeIntersection.Z() + pczoffset);
    plotter->Fill2D("pcz_vs_pcPhi_rad=" + std::to_string(hitPos.Perp()), 360, 0, 360, 150, 0, 200, anodeIntersection.Phi() * 180. / M_PI, anodeIntersection.Z() + pczoffset, "pczguess");
  }
  for (int i = 0; i < sx3.multi; i++)
  {
    // plotting sx3 strip hits vs anode phi
    if (sx3.ch[i] < 8 && anodeIntersection.Perp() > 0)
      plotter->Fill2D("PCPhi_vs_SX3Strip", 100, -200, 200, 8 * 24, 0, 8 * 24, anodeIntersection.Phi() * 180. / TMath::Pi(), sx3.id[i] * 8 + sx3.ch[i]);
  }

  if (anodeIntersection.Perp() != 0)
  {
    plotter->Fill2D("AnodeMaxE_Vs_Cathode_Sum_Energy", 2000, 0, 20000, 2000, 0, 10000, aEMax, cESum, "hGMPC");
    plotter->Fill2D("AnodeSumE_Vs_Cathode_Max_Energy", 800, 0, 20000, 800, 0, 10000, aESum, cEMax, "hGMPC");
    plotter->Fill2D("AnodeMaxE_Vs_Cathode_Max_Energy", 800, 0, 20000, 800, 0, 10000, aEMax, cEMax, "hGMPC");
    // double sinTheta = TMath::Sin((anodeIntersection - TVector3(0,0,source_vertex)).Theta());///TMath::Sin((TVector3(51.5,0,128.) - TVector3(0,0,85)).Theta());
    // plotter->Fill2D("AnodeMaxE_Vs_Cathode_Max_Energy_path_corrected", 800, 0, 20000, 800, 0, 10000, aEMax*sinTheta, cEMax*sinTheta, "hGMPC");
    plotter->Fill2D("AnodeSumE_Vs_Cathode_Sum_Energy", 800, 0, 20000, 800, 0, 10000, aESum, cESum, "hGMPC");
    plotter->Fill2D("AnodeSumE_Vs_Cathode_Max_Energy_TC" + std::to_string(PCQQQTimeCut) + "_PC" + std::to_string(PCQQQPhiCut), 800, 0, 20000, 800, 0, 10000, aESum, cEMax, "hGMPC");
    // plotter->Fill2D("AnodeSumE_Vs_Cathode_Max_Energy_path_corrected"+std::to_string(PCQQQTimeCut)+"_PC"+std::to_string(PCQQQPhiCut), 800, 0, 20000, 800, 0, 10000, aESum*sinTheta, cEMax*sinTheta, "hGMPC");
    // plotter->Fill2D("AnodeSumE_Vs_Cathode_Max_Energy_path_corrected", 800, 0, 20000, 800, 0, 10000, aESum*sinTheta, cEMax*sinTheta, "hGMPC");

    if (PCQQQTimeCut && PCQQQPhiCut)
    {
      plotter->Fill2D("AnodeSumE_Vs_Cathode_Max_Energy_TC" + std::to_string(PCQQQTimeCut) + "_PC" + std::to_string(PCQQQPhiCut) + "_cMax" + std::to_string(cIDMax), 800, 0, 20000, 800, 0, 10000, aESum, cEMax, "hGMPC");
    }
    // plotter->Fill2D("AnodeSumE_Vs_CathodeSum_Energy_path_corrected", 800, 0, 20000, 800, 0, 10000, aESum*sinTheta, cESum*sinTheta, "hGMPC");
    // plotter->Fill2D("AnodeSumE_Vs_CathodeSum_Energy_path_corrected_TC"+std::to_string(PCQQQTimeCut)+"_PC"+std::to_string(PCQQQPhiCut), 800, 0, 20000, 800, 0, 10000, aESum*sinTheta, cESum*sinTheta, "hGMPC");        */
  }

  if (anodeHits.size() < 1)
  {
    plotter->Fill1D("NoAnodeHits_CathodeHits", 6, 0, 5, cathodeHits.size(), "hGMPC");
  }

  return kTRUE;
}

void MakeVertex::Terminate()
{
  plotter->FlushToDisk();
}