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/data/refman/pasoursint/CMSSW_5_3_10_patch2/src/SimTracker/TrackerMaterialAnalysis/plugins/MaterialAccountingGroup.h

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00001 #ifndef MaterialAccountingGroup_h
00002 #define MaterialAccountingGroup_h
00003 
00004 #include <string>
00005 #include <stdexcept>
00006 #include <utility>
00007 
00008 #include "Geometry/CommonDetUnit/interface/GeomDetEnumerators.h"
00009 
00010 #include "SimDataFormats/ValidationFormats/interface/MaterialAccountingStep.h"
00011 #include "SimDataFormats/ValidationFormats/interface/MaterialAccountingDetector.h"
00012 
00013 class TH1;
00014 class TH1F;
00015 class TProfile;
00016 class TFile;
00017 
00018 class MaterialAccountingGroup {
00019 private:
00020 
00021   // quick implementation of a bounding cilinder
00022   class BoundingBox {
00023   public:
00024 
00025     BoundingBox(double min_r, double max_r, double min_z, double max_z) :
00026       r_min(min_r),
00027       r_max(max_r),
00028       z_min(min_z),
00029       z_max(max_z)
00030     { }
00031 
00032     BoundingBox() :
00033       r_min(0.),
00034       r_max(0.),
00035       z_min(0.),
00036       z_max(0.)
00037     { }
00038 
00039     void grow(double r, double z) {
00040       if (r < r_min) r_min = r;
00041       if (r > r_max) r_max = r;
00042       if (z < z_min) z_min = z;
00043       if (z > z_max) z_max = z;
00044     }
00045 
00046     void grow(double skin) {
00047       r_min -= skin;    // yes, we allow r_min to go negative
00048       r_max += skin;
00049       z_min -= skin;
00050       z_max += skin;
00051     }
00052 
00053     bool inside(double r, double z) const {
00054       return (r >= r_min and r <= r_max and z >= z_min and z <= z_max);
00055     }
00056 
00057     std::pair<double, double> range_r() const {
00058       return std::make_pair(r_min, r_max);
00059     }
00060 
00061     std::pair<double, double> range_z() const {
00062       return std::make_pair(z_min, z_max);
00063     }
00064 
00065   private:
00066     double r_min;
00067     double r_max;
00068     double z_min;
00069     double z_max;
00070   };
00071   
00072 public:
00074   MaterialAccountingGroup( const std::string & name, const DDCompactView & geometry );
00075     
00077   ~MaterialAccountingGroup( void );
00078 
00079 private:
00081   MaterialAccountingGroup(const MaterialAccountingGroup & layer);
00082 
00084   MaterialAccountingGroup& operator=( const MaterialAccountingGroup & layer);
00085 
00086 public:
00088   bool addDetector( const MaterialAccountingDetector& detector );
00089  
00091   void endOfTrack( void );
00092   
00094   bool inside( const MaterialAccountingDetector& detector ) const;
00095 
00097   MaterialAccountingStep average(void) const 
00098   {
00099     return m_tracks ? m_accounting / m_tracks : MaterialAccountingStep();
00100   }
00101 
00103   double averageLength(void) const 
00104   {
00105     return m_tracks ? m_accounting.length() / m_tracks : 0.;
00106   }
00107   
00109   double averageRadiationLengths(void) const 
00110   {
00111     return m_tracks ? m_accounting.radiationLengths() / m_tracks : 0.;
00112   }
00113   
00115   double averageEnergyLoss(void) const 
00116   {
00117     return m_tracks ? m_accounting.energyLoss() / m_tracks : 0.;
00118   }
00119  
00121   double sigmaLength(void) const 
00122   {
00123     return m_tracks ? std::sqrt(m_errors.length() / m_tracks - averageLength()*averageLength()) : 0.;
00124   }
00125   
00127   double sigmaRadiationLengths(void) const 
00128   {
00129     return m_tracks ? std::sqrt(m_errors.radiationLengths() / m_tracks - averageRadiationLengths()*averageRadiationLengths()) : 0.;
00130   }
00131   
00133   double sigmaEnergyLoss(void) const 
00134   {
00135     return m_tracks ? std::sqrt(m_errors.energyLoss() / m_tracks - averageEnergyLoss()*averageEnergyLoss()) : 0.;
00136   }
00137  
00139   unsigned int tracks(void) const 
00140   {
00141     return m_tracks;
00142   }
00143  
00145   const std::string & name(void) const
00146   {
00147     return m_name;
00148   }
00149 
00151   std::string info(void) const;
00152 
00154   void savePlots(void);
00155  
00156 private:
00157   void savePlot(TH1F * plot, const std::string & name);
00158   void savePlot(TProfile * plot, float average, const std::string & name);
00159  
00160   std::string                   m_name;
00161   std::vector<GlobalPoint>      m_elements;
00162   BoundingBox                   m_boundingbox;
00163   MaterialAccountingStep        m_accounting;
00164   MaterialAccountingStep        m_errors;
00165   unsigned int                  m_tracks;
00166   bool                          m_counted;
00167   MaterialAccountingStep        m_buffer;
00168   
00169   // plots of material effects distribution
00170   TH1F * m_dedx_spectrum;
00171   TH1F * m_radlen_spectrum;
00172   // plots of material effects vs. η / Z / R
00173   TProfile * m_dedx_vs_eta;
00174   TProfile * m_dedx_vs_z;
00175   TProfile * m_dedx_vs_r;
00176   TProfile * m_radlen_vs_eta;
00177   TProfile * m_radlen_vs_z;
00178   TProfile * m_radlen_vs_r;
00179 
00180   // file to store plots into
00181   mutable TFile * m_file;
00182 
00183   // 100um should be small enough that no elements from different layers/groups are so close
00184   static double s_tolerance;
00185 };
00186 
00187 #endif // MaterialAccountingGroup_h