G4NuclWatcher.cc

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// $Id$
//
// 20100202  M. Kelsey -- Move most code here from .hh file, clean up
// 20100405  M. Kelsey -- Pass const-ref std::vector<>
// 20101010  M. Kelsey -- Migrate to integer A and Z
// 20101019  M. Kelsey -- CoVerity report: "!true" should be "!here"

#include "G4NuclWatcher.hh"
#include "globals.hh"

#include <algorithm>
#include <vector>
#include <cmath>

G4NuclWatcher::G4NuclWatcher(G4int z, 
                             const std::vector<G4double>& expa, 
                             const std::vector<G4double>& expcs, 
                             const std::vector<G4double>& experr, 
                             G4bool check, 
                             G4bool nucl)
  : nuclz(z), izotop_chsq(0.), average_ratio(0.), aver_rat_err(0.),
    aver_lhood(0.), aver_matched(0.), exper_as(expa), exper_cs(expcs),
    exper_err(experr), checkable(check), nucleable(nucl) {}

void G4NuclWatcher::watch(G4int a, G4int z) {
  const G4double small = 0.001;
  
  if (std::abs(z-nuclz) >= small) return;

  G4bool here = false;          // Increment specified nucleus count
  G4int  simulatedAsSize = simulated_as.size();
  for (G4int i = 0; i<simulatedAsSize && !here; i++) {
    if (std::abs(simulated_as[i] - a) < small) {
      simulated_cs[i] += 1.0;
      here = true;              // Terminates loop
    }
  }

  if (!here) {                  // Nothing found, so add new entry
    simulated_as.push_back(a); 
    simulated_cs.push_back(1.0); 
  }
}

void G4NuclWatcher::setInuclCs(G4double csec, G4int nev) { 
  G4int  simulatedAsSize = simulated_as.size();
  for(G4int i = 0; i < simulatedAsSize ; i++) {
    double err = std::sqrt(simulated_cs[i]) / simulated_cs[i];
    
    simulated_prob.push_back(simulated_cs[i] / nev);
    simulated_cs[i] *= csec / nev;
    simulated_errors.push_back(simulated_cs[i] * err);    
  }
}

std::pair<G4double, G4double> G4NuclWatcher::getExpCs() const {
  G4double cs = 0.0;
  G4double err = 0.0;
  
  G4int experAsSize = exper_as.size();
  for(G4int iz = 0; iz < experAsSize; iz++) {
    cs += exper_cs[iz];
    err += exper_err[iz];
  }
  
  return std::pair<G4double, G4double>(cs, err);
}

std::pair<G4double, G4double> G4NuclWatcher::getInuclCs() const {
  G4double cs = 0.0;
  G4double err = 0.0;
  G4int  simulatedAsSize = simulated_as.size();
  for(G4int iz = 0; iz < simulatedAsSize; iz++) {
    cs += simulated_cs[iz];
    err += simulated_errors[iz];
  }
  
  return std::pair<G4double, G4double>(cs, err);
}

void G4NuclWatcher::print() {
  const G4double small = 0.001;
  
  G4cout << "\n ++++++++++++++++++++++++++++++++++++++++++++++++++++++++ "
         << "\n **** izotop Z **** " << nuclz << G4endl;
  
  izotop_chsq = 0.0;
  average_ratio = 0.0;
  aver_rat_err = 0.0;
  G4double exp_cs = 0.0;
  G4double exp_cs_err = 0.0;
  G4double inucl_cs = 0.0;
  G4double inucl_cs_err = 0.0;
  std::vector<G4bool> not_used(simulated_cs.size(), true);
  G4int nmatched = exper_as.size();
  G4int nused = simulated_cs.size();
  G4double lhood = 0.0;
  G4int experAsSize = exper_as.size();

  for (G4int iz = 0; iz < experAsSize; iz++) {
    G4double a = exper_as[iz];
    
    exp_cs += exper_cs[iz];
    exp_cs_err += exper_err[iz];
    
    G4bool found = false;
    G4int  simulatedAsSize = simulated_as.size();
    for (G4int i = 0; i<simulatedAsSize && !found; i++) {
      if (std::fabs(simulated_as[i] - a) < small) {
        G4double rat = simulated_cs[i] / exper_cs[iz];
        
        lhood += std::log10(rat) * std::log10(rat);
        
        G4double rat_err
          = std::sqrt(simulated_errors[i]*simulated_errors[i] +
                      exper_err[iz]*exper_err[iz] * rat*rat) / exper_cs[iz];
        average_ratio += rat;
        aver_rat_err += rat_err; 
        
        G4cout << " A " << a << " exp.cs " << exper_cs[iz] << " err " 
               << exper_err[iz] << G4endl << " sim. cs " << simulated_cs[i]
               << " err " << simulated_errors[i] << G4endl
               << " ratio " << rat << " err " << rat_err << G4endl
               << " simulated production rate " << simulated_prob[i] << G4endl;
        
        not_used[i] = false;
        izotop_chsq += (rat - 1.0) * (rat - 1.0) / rat_err / rat_err; 
        found = true;
        nused--;
      }
    }

    if (found) nmatched--;
    else
      G4cout << " not found exper.: A " << a << " exp.cs " << exper_cs[iz] 
             << " err " << exper_err[iz] << G4endl;
  }
  
  G4cout << " not found in simulations " << nmatched << G4endl
         << " not found in exper: " << nused << G4endl;

  G4int  simulatedAsSize = simulated_as.size();
  for(G4int i = 0; i < simulatedAsSize; i++) {
    inucl_cs += simulated_cs[i];
    inucl_cs_err += simulated_errors[i];
    
    if(not_used[i]) 
      G4cout << " extra simul.: A " << simulated_as[i] << " sim. cs "
             << simulated_cs[i] << " err " << simulated_errors[i] << G4endl;

    G4cout << " simulated production rate " << simulated_prob[i] << G4endl;
  }

  G4int matched = exper_as.size() - nmatched;
  
  if (matched > 0) {
    aver_lhood = lhood;
    aver_matched = matched;    
    lhood = std::pow(10.0, std::sqrt(lhood/matched));
    
    G4cout << " matched " << matched << " CHSQ " << std::sqrt(izotop_chsq) / matched
           << G4endl
           << " raw chsq " << izotop_chsq << G4endl
           << " average ratio " << average_ratio / matched 
           << " err " << aver_rat_err / matched << G4endl 
           << " lhood " << lhood << G4endl;
  }
  else {
    izotop_chsq = 0.0;
    aver_lhood = 0.0;    
  } 
  
  G4cout << " exper. cs " << exp_cs << " err " << exp_cs_err << G4endl
         << " inucl. cs " << inucl_cs << " err " << inucl_cs_err << G4endl
         <<  " ++++++++++++++++++++++++++++++++++++++++++++++++++++++++ "
         << G4endl;
}

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