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// $Id: $
// GEANT4 tag $Name: not supported by cvs2svn $
//
// -------------------------------------------------------------------
//
// GEANT4 Class header file
//
//
// File name:    G4VCrossSectionDataSet
//
// Author  F.W. Jones, TRIUMF, 20-JAN-97
//
// Modifications:
// 23.01.2009 V.Ivanchenko move constructor and destructor to source
// 05.07.2010 V.Ivanchenko added name, min and max energy limit and
//            corresponding access methods
// 12.08.2011 G.Folger, V.Ivanchenko, T.Koi, D.Wright redesign the class
// 
//
// Class Description
// This is a base class for hadronic cross section data sets.  Users may 
// derive specialized cross section classes and register them with the
// appropriate process, or use provided data sets.
//
// Each cross section should have unique name
// Minimal and maximal energy for the cross section will be used in run
// time before IsApplicable method is called
// 
// Both the name and the energy interval will be used for documentation 
//
// Class Description - End

#ifndef G4VCrossSectionDataSet_h
#define G4VCrossSectionDataSet_h 1

#include "globals.hh"
#include "G4ParticleDefinition.hh"
#include "G4Element.hh"
#include "G4HadTmpUtil.hh"
#include <iostream>

class G4DynamicParticle;
class G4Isotope;
class G4Material;

class G4VCrossSectionDataSet
{
public: //with description

  G4VCrossSectionDataSet(const G4String& nam = "");

  virtual ~G4VCrossSectionDataSet();

  //============== Is Applicable methods ===============================
  // The following three methods have default implementations returning
  // "false".  Derived classes should implement only needed methods.
 
  // Element-wise cross section
  virtual
  G4bool IsElementApplicable(const G4DynamicParticle*, G4int Z, 
			     const G4Material* mat = 0);

  // Derived classes should implement this method if they provide isotope-wise 
  // cross sections.  Default arguments G4Element and G4Material are needed to 
  // access low-energy neutron cross sections, but are not required for others.
  virtual
  G4bool IsIsoApplicable(const G4DynamicParticle*, G4int Z, G4int A,    
			 const G4Element* elm = 0,
			 const G4Material* mat = 0);

  //============== GetCrossSection methods ===============================

  // This is a generic method to access cross section per element
  // This method should not be overwritten in a derived class
  inline G4double GetCrossSection(const G4DynamicParticle*, const G4Element*,
				  const G4Material* mat = 0);

  // This is a generic method to compute cross section per element
  // If the DataSet is not applicable the method returns zero
  // This method should not be overwritten in a derived class
  G4double ComputeCrossSection(const G4DynamicParticle*, 
			       const G4Element*,
			       const G4Material* mat = 0);

  // The following two methods have default implementations which throw
  // G4HadronicException.  Derived classes should implement only needed
  // methods, which are assumed to be called at run time.

  // Implement this method for element-wise cross section 
  virtual
  G4double GetElementCrossSection(const G4DynamicParticle*, G4int Z,
				  const G4Material* mat = 0);

  // Derived classes should implement this method if they provide isotope-wise
  // cross sections.  Default arguments G4Element and G4Material are needed to
  // access low-energy neutron cross sections, but are not required for others. 
  virtual
  G4double GetIsoCrossSection(const G4DynamicParticle*, G4int Z, G4int A,  
			      const G4Isotope* iso = 0,
			      const G4Element* elm = 0,
			      const G4Material* mat = 0);

  //=====================================================================

  // Implement this method if needed
  virtual
  void BuildPhysicsTable(const G4ParticleDefinition&);

  // Implement this method if needed
  // Default implementation will provide a dump of the cross section 
  // in logarithmic scale in the interval of applicability 
  virtual
  void DumpPhysicsTable(const G4ParticleDefinition&);

  virtual void CrossSectionDescription(std::ostream&) const;

public: // Without Description

  inline void SetVerboseLevel(G4int value);

  inline G4double GetMinKinEnergy() const;

  inline void SetMinKinEnergy(G4double value);

  inline G4double GetMaxKinEnergy() const;

  inline void SetMaxKinEnergy(G4double value);

  inline const G4String& GetName() const;

protected:

  inline void SetName(const G4String&);

  G4int verboseLevel;

private:

  G4VCrossSectionDataSet & operator=(const G4VCrossSectionDataSet &right);
  G4VCrossSectionDataSet(const G4VCrossSectionDataSet&);

  G4double minKinEnergy;
  G4double maxKinEnergy;

  G4String name;
};

inline G4double 
G4VCrossSectionDataSet::GetCrossSection(const G4DynamicParticle* dp, 
					const G4Element* elm,
					const G4Material* mat)
{
  return ComputeCrossSection(dp, elm, mat);
}

inline void G4VCrossSectionDataSet::SetVerboseLevel(G4int value)
{
  verboseLevel = value;
}

inline void G4VCrossSectionDataSet::SetMinKinEnergy(G4double value)
{
  minKinEnergy = value;
}

inline G4double G4VCrossSectionDataSet::GetMinKinEnergy() const
{
  return minKinEnergy;
}

inline void G4VCrossSectionDataSet::SetMaxKinEnergy(G4double value)
{
  maxKinEnergy = value;
}

inline G4double G4VCrossSectionDataSet::GetMaxKinEnergy() const
{
  return maxKinEnergy;
}

inline const G4String& G4VCrossSectionDataSet::GetName() const
{
  return name;
}

inline void G4VCrossSectionDataSet::SetName(const G4String& s)
{
  name = s;
}

#endif