Implemented starting configuration.

[phys/u1casc.git] / u1casc-flux / obs_plaq.hpp

#ifndef OBS_PLAQ_HPP
#define OBS_PLAQ_HPP

#include "latlib/o815/o815.h"

#include "latlib/writeout.h"

#include "latlib/obstat.hpp"

#include <iostream>

using namespace std;

class obs_plaq : public o815::obs {

public:
  struct obsmem {
    double A;
    double B;
  };
  obs_plaq(o815 *_O815);
  
private:
  void _start();
  void _meas(bool loadedobs, const int& nthmeas);
  void _finish();
 
  obsmem* OM;

  static void prePlaqSus(vector< vector <double> > *allVals, vector <double> *preCalculated, void *para);
  static double plaqSus(vector <double> *preCalculated, vector<double> *excludedMeas, int nmeas, void *para);

  sim *Sim;
  obstat<double,double> oPlaq;

  double A(const double& beta);
  double B(const double& beta);
};

obs_plaq::obs_plaq(o815 *_O815) : o815::obs("plaq", 
                                            _O815->paraQ->getParaNames() + "plaq:plaq_err:plaqsus:plaqsus_err", 
                                            _O815, sizeof(obsmem) ) {
  OM = (obsmem*)obsMem;
  Sim = (sim*)O815->Sim;
}

void obs_plaq::_start() {
  //*out << "OBS_test: start" << endl;
};

void obs_plaq::_meas(bool loadedobs, const int& nthmeas) {
  if (!loadedobs) {
    OM->A = A((*paraQ)["beta"]);
    OM->B = B((*paraQ)["beta"]);
  }

  double tmpMeas[2] = {OM->A, OM->B};
  oPlaq.addMeas(tmpMeas, 2);
};

void obs_plaq::_finish() {
  *out << O815->paraQ->getParaVals();

  int compid_plaq, compid_plaqsus;

  compid_plaq = oPlaq.computeEasy();
  compid_plaqsus = oPlaq.computeJack(obs_plaq::prePlaqSus, obs_plaq::plaqSus, &(Sim->lsize4));

  *out << "\t" << oPlaq.getMean(compid_plaq) << "\t" << oPlaq.getErr(compid_plaq);
  *out << "\t" << oPlaq.getMean(compid_plaqsus) << "\t" << oPlaq.getErr(compid_plaqsus);

  *out << endl;

  oPlaq.reset();
};

void obs_plaq::prePlaqSus(vector< vector <double> > *allVals, vector <double> *preCalculated, void *para) {
  preCalculated->push_back(0);
  preCalculated->push_back(0);

  for(vector< vector<double> >::iterator valIt = allVals->begin(); valIt != allVals->end(); ++valIt) {
    (*preCalculated)[0] += (*valIt)[1] + pow((*valIt)[0], 2)*(*(int*)para*6);
    (*preCalculated)[1] += (*valIt)[0];
  }
}

double obs_plaq::plaqSus(vector <double> *preCalculated, vector<double> *excludedMeas, int nmeas, void *para) {
  return ( (*preCalculated)[0] - pow((*excludedMeas)[0], 2) * *(int*)para * 6 - (*excludedMeas)[1] ) / (nmeas-1)
    - pow( ( (*preCalculated)[1] - (*excludedMeas)[0] ) / (nmeas-1), 2 )
    * *(int*)para * 6;
}

double obs_plaq::A(const double& beta)
{
  double A = 0;

  for( int x=0; x<Sim->lsize4; x++ )
    for( int sigma=0; sigma<3; sigma++ )
      for( int tau=sigma+1; tau<4; tau++ ) {
        A += Sim->I( Sim->p[ x*6 + Sim->iPlaq(sigma,tau) ] + 1 ) / Sim->I( Sim->p[ x*6 + Sim->iPlaq(sigma,tau) ] );
        A += Sim->p[ x*6 + Sim->iPlaq(sigma,tau) ] / beta;
      }
  
  return A/(6*Sim->lsize4);
}

double obs_plaq::B(const double& beta)
{
  double B=0;

  for( int x=0; x<Sim->lsize4; x++ )
    for( int sigma=0; sigma<3; sigma++ )
      for( int tau=sigma+1; tau<4; tau++ ) {
        B += Sim->I( Sim->p[ x*6 + Sim->iPlaq(sigma,tau) ] + 2 ) / Sim->I( Sim->p[ x*6 + Sim->iPlaq(sigma,tau) ] );
        B += ( (Sim->p[ x*6 + Sim->iPlaq(sigma,tau) ] + 1) * Sim->I(Sim->p[ x*6 + Sim->iPlaq(sigma,tau) ] + 1) ) / 
          ( beta *  Sim->I(Sim->p[ x*6 + Sim->iPlaq(sigma,tau) ]) );
        B -= pow(Sim->I( Sim->p[ x*6 + Sim->iPlaq(sigma,tau) ] + 1 ) / Sim->I( Sim->p[ x*6 + Sim->iPlaq(sigma,tau) ] ), 2);
        B -= ( Sim->p[ x*6 + Sim->iPlaq(sigma,tau) ] * Sim->I(Sim->p[ x*6 + Sim->iPlaq(sigma,tau) ] + 1) ) / 
          ( beta *  Sim->I(Sim->p[ x*6 + Sim->iPlaq(sigma,tau) ]) );
        B -= Sim->p[ x*6 + Sim->iPlaq(sigma,tau)] / pow(beta,2);
      }
  
  return B/(6*Sim->lsize4);
}

#endif