source: trunk/examples/advanced/hadrontherapy/src/HadrontherapyMatrix.cc @ 1272

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// $Id: HadrontherapyMatrix.cc;
// See more at: http://g4advancedexamples.lngs.infn.it/Examples/hadrontherapy//

#include "HadrontherapyMatrix.hh"
#include "HadrontherapyAnalysisManager.hh"
#include "globals.hh"
#include <fstream>

HadrontherapyMatrix* HadrontherapyMatrix::instance = NULL;
// Static method that only return a pointer to the matrix object
HadrontherapyMatrix* HadrontherapyMatrix::getInstance() 
{
  return instance;
}
// This STATIC method delete (!) the old matrix and rewrite a new object returning a pointer to it
HadrontherapyMatrix* HadrontherapyMatrix::getInstance(G4int voxelX, G4int voxelY, G4int voxelZ)  
{
    if (instance) delete instance;
    instance = new HadrontherapyMatrix(voxelX, voxelY, voxelZ);
    instance -> Initialize();   
    return instance;
}

HadrontherapyMatrix::HadrontherapyMatrix(G4int voxelX, G4int voxelY, G4int voxelZ):
    matrix(0)
{  
// Number of the voxels of the phantom
// For Y = Z = 1 the phantom is divided in slices (and not in voxels)
// orthogonal to the beam axis
  numberVoxelX = voxelX;
  numberVoxelY = voxelY;
  numberVoxelZ = voxelZ; 
  // Create the dose matrix
  matrix = new G4double[numberVoxelX*numberVoxelY*numberVoxelZ];
  if (matrix) G4cout << "Matrix: Memory space to store physical dose into " <<  
                        numberVoxelX*numberVoxelY*numberVoxelZ <<
                        " voxels has been allocated " << G4endl;
  else G4Exception("Can't allocate memory to store physical dose!");
}

HadrontherapyMatrix::~HadrontherapyMatrix()
{
    delete[] matrix;
}

void HadrontherapyMatrix::flush()
{
        if(matrix)
        for(int i=0; i<numberVoxelX*numberVoxelY*numberVoxelZ; i++)
        {
          matrix[i] = 0;
        }
}
void HadrontherapyMatrix::Initialize()
{ 
// Initialise the elements of the matrix to zero
  for(G4int i = 0; i < numberVoxelX; i++)
    {
      for(G4int j = 0; j < numberVoxelY; j++)
           {
              for(G4int k = 0; k < numberVoxelZ; k++)

              matrix[Index(i,j,k)] = 0.;
           } 
    }
}

void HadrontherapyMatrix::Fill(G4int i, G4int j, G4int k, 
                               G4double energyDeposit)
{
  if (matrix)
    matrix[Index(i,j,k)] += energyDeposit;
  
  // Store the energy deposit in the matrix element corresponding 
  // to the phantom voxel  i, j, k
}

void HadrontherapyMatrix::TotalEnergyDeposit()
{
  // Store the information of the matrix in a ntuple and in 
  // a 1D Histogram

  G4int k;
  G4int j;
  G4int i;
  
  if (matrix)
    {  
      std::ofstream ofs;        
      ofs.open("DoseDistribution.out"); 
      
      for(G4int l = 0; l < numberVoxelZ; l++) 
        {
          k = l;
          
          for(G4int m = 0; m < numberVoxelY; m++) 
            { 
              j = m * numberVoxelZ + k; 
                
                for(G4int n = 0; n <  numberVoxelX; n++)
                  {
                    i =  n* numberVoxelZ * numberVoxelY + j;
                    if(matrix[i] != 0)
                      { 
                        ofs << n << '\t' << m << '\t' <<
                          k << '\t' << matrix[i] << G4endl;
                        
#ifdef ANALYSIS_USE
                        HadrontherapyAnalysisManager* analysis = 
                        HadrontherapyAnalysisManager::getInstance();
                        analysis -> FillEnergyDeposit(n, m, k, matrix[i]);
                        analysis -> BraggPeak(n, matrix[i]);
#endif
                      }
}       
              }
          }
    }
}