G4AdjointCSMatrix.cc

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//
// $Id$
//
 
#include <iomanip>
#include <fstream>
 
#include "G4AdjointCSMatrix.hh"
#include "G4SystemOfUnits.hh"
#include "G4AdjointInterpolator.hh"
 
///////////////////////////////////////////////////////
//
G4AdjointCSMatrix::G4AdjointCSMatrix(G4bool aBool){
    theLogPrimEnergyVector.clear();
    theLogCrossSectionVector.clear();
    theLogSecondEnergyMatrix.clear();
    theLogProbMatrix.clear();
    theLogProbMatrixIndex.clear();
    log0Vector.clear();
    nb_of_PrimEnergy=0;
    is_scat_proj_to_proj_case  =aBool;
    dlog =0;
}
///////////////////////////////////////////////////////
//
G4AdjointCSMatrix::~G4AdjointCSMatrix(){
    theLogPrimEnergyVector.clear();
    theLogCrossSectionVector.clear();
    theLogSecondEnergyMatrix.clear();
    theLogProbMatrix.clear();
}
///////////////////////////////////////////////////////
//
void G4AdjointCSMatrix::Clear()
{
    theLogPrimEnergyVector.clear();
    theLogCrossSectionVector.clear();
    theLogSecondEnergyMatrix.clear();
    theLogProbMatrix.clear();
    theLogProbMatrixIndex.clear();
    log0Vector.clear();
    nb_of_PrimEnergy=0;
}
///////////////////////////////////////////////////////
//
 void G4AdjointCSMatrix::AddData(G4double aLogPrimEnergy,G4double aLogCS, std::vector< double>* aLogSecondEnergyVector,
                                       std::vector< double>* aLogProbVector,size_t n_pro_decade){
    
    G4AdjointInterpolator* theInterpolator=G4AdjointInterpolator::GetInstance();
    
    //At this time we consider that the energy is increasing monotically
    theLogPrimEnergyVector.push_back(aLogPrimEnergy);
    theLogCrossSectionVector.push_back(aLogCS);
    theLogSecondEnergyMatrix.push_back(aLogSecondEnergyVector);
    theLogProbMatrix.push_back(aLogProbVector);
    
    std::vector< size_t>* aLogProbVectorIndex = 0;
    dlog =0;
    
    if (n_pro_decade > 0 && aLogProbVector->size()>0) {
        aLogProbVectorIndex = new std::vector< size_t>();
        dlog=std::log(10.)/n_pro_decade;
        G4double log_val = int(std::min((*aLogProbVector)[0],aLogProbVector->back())/dlog)*dlog;
        log0Vector.push_back(log_val);
        
        while(log_val<0.) {
            aLogProbVectorIndex->push_back(theInterpolator->FindPosition(log_val,(*aLogProbVector)));
            log_val+=dlog;
        } 
    }
    else {
        log0Vector.push_back(0.);
    }
    theLogProbMatrixIndex.push_back(aLogProbVectorIndex);
    
    
    nb_of_PrimEnergy++;
    
    
}
///////////////////////////////////////////////////////
//
G4bool G4AdjointCSMatrix::GetData(unsigned int i, G4double& aLogPrimEnergy,G4double& aLogCS,G4double& log0, std::vector< double>*& aLogSecondEnergyVector,
                                       std::vector< double>*& aLogProbVector, std::vector< size_t>*& aLogProbVectorIndex)
{   if (i>= nb_of_PrimEnergy) return false;
    //G4cout<<"Test Get Data "<<G4endl;
    aLogPrimEnergy = theLogPrimEnergyVector[i];
    aLogCS = theLogCrossSectionVector[i];
    aLogSecondEnergyVector = theLogSecondEnergyMatrix[i];
    aLogProbVector = theLogProbMatrix[i];
    aLogProbVectorIndex = theLogProbMatrixIndex[i];
    log0=log0Vector[i];
    return true;
    
}
///////////////////////////////////////////////////////
//
void G4AdjointCSMatrix::Write(G4String file_name)
{   std::fstream FileOutput(file_name, std::ios::out);            
    FileOutput<<std::setiosflags(std::ios::scientific);
    FileOutput<<std::setprecision(6);
    FileOutput<<theLogPrimEnergyVector.size()<<G4endl;
    for (size_t i=0;i<theLogPrimEnergyVector.size();i++){
        FileOutput<<std::exp(theLogPrimEnergyVector[i])/MeV<<'\t'<<std::exp(theLogCrossSectionVector[i])<<G4endl;
        size_t j1=0;
        FileOutput<<theLogSecondEnergyMatrix[i]->size()<<G4endl;
        for (size_t j=0;j<theLogSecondEnergyMatrix[i]->size();j++){
            FileOutput<<std::exp((*theLogSecondEnergyMatrix[i])[j]);
            j1++;
            if (j1<10) FileOutput<<'\t';
            else  {
                FileOutput<<G4endl;
                j1=0;
            }   
        }
        if (j1>0) FileOutput<<G4endl;
        j1=0;
        FileOutput<<theLogProbMatrix[i]->size()<<G4endl;
        for (size_t j=0;j<theLogProbMatrix[i]->size();j++){
            FileOutput<<std::exp((*theLogProbMatrix[i])[j]);
            j1++;
            if (j1<10) FileOutput<<'\t';
            else  {
                FileOutput<<G4endl;
                j1=0;
            }   
        }
        if (j1>0) FileOutput<<G4endl;
        
        
    }
    
}
///////////////////////////////////////////////////////
//
void G4AdjointCSMatrix::Read(G4String file_name)
{   std::fstream FileOutput(file_name, std::ios::in);
    size_t n1,n2;
    
    
    theLogPrimEnergyVector.clear();
    theLogCrossSectionVector.clear();
    theLogSecondEnergyMatrix.clear();
    theLogProbMatrix.clear();
    FileOutput>>n1;
    for (size_t i=0; i<n1;i++){
        G4double E,CS;
        FileOutput>>E>>CS;
        theLogPrimEnergyVector.push_back(E);
        theLogCrossSectionVector.push_back(CS);
        FileOutput>>n2;
        theLogSecondEnergyMatrix.push_back(new std::vector<G4double>());
        theLogProbMatrix.push_back(new std::vector<G4double>());
        
        for (size_t j=0; j<n2;j++){
            G4double E1;
            FileOutput>>E1;
            theLogSecondEnergyMatrix[i]->push_back(E1);
        }
        FileOutput>>n2;
        for (size_t j=0; j<n2;j++){
            G4double prob;
            FileOutput>>prob;
            theLogProbMatrix[i]->push_back(prob);
        }
        
        
        
    }
    
                  
    
    
}