G4ITStepProcessor.hh

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// Author: Mathieu Karamitros
 
// The code is developed in the framework of the ESA AO7146
//
// We would be very happy hearing from you, send us your feedback! :)
//
// In order for Geant4-DNA to be maintained and still open-source,
// article citations are crucial. 
// If you use Geant4-DNA chemistry and you publish papers about your software, 
// in addition to the general paper on Geant4-DNA:
//
// Int. J. Model. Simul. Sci. Comput. 1 (2010) 157–178
//
// we would be very happy if you could please also cite the following
// reference papers on chemistry:
//
// J. Comput. Phys. 274 (2014) 841-882
// Prog. Nucl. Sci. Tec. 2 (2011) 503-508 
 
#ifndef G4ITSTEPPROCESSOR_H
#define G4ITSTEPPROCESSOR_H
 
#include "G4ios.hh"                   // Include from 'system'
#include "globals.hh"                 // Include from 'global'
#include "Randomize.hh"               // Include from 'global'
 
#include "G4LogicalVolume.hh"         // Include from 'geometry'
#include "G4VPhysicalVolume.hh"       // Include from 'geometry'
#include "G4ProcessManager.hh"        // Include from 'piim'
 
#include "G4Track.hh"                 // Include from 'track'
#include "G4TrackVector.hh"           // Include from 'track'
#include "G4TrackStatus.hh"           // Include from 'track'
#include "G4StepStatus.hh"            // Include from 'track'
//#include "G4UserSteppingAction.hh"    // Include from 'tracking'
//#include "G4UserTrackingAction.hh"    // Include from 'tracking'
#include "G4Step.hh"                  // Include from 'track'
#include "G4StepPoint.hh"             // Include from 'track'
#include "G4TouchableHandle.hh"             // Include from 'geometry'
#include "G4TouchableHistoryHandle.hh"      // Include from 'geometry'
 
#include "G4ITStepProcessorState_Lock.hh"
#include "G4ITLeadingTracks.hh"
 
class G4ITNavigator;
class G4ParticleDefinition;
class G4ITTrackingManager;
class G4IT;
class G4TrackingInformation;
class G4ITTransportation;
class G4VITProcess;
class G4VITSteppingVerbose;
class G4ITTrackHolder;
typedef class std::vector<int, std::allocator<int> > G4SelectedAtRestDoItVector;
typedef class std::vector<int, std::allocator<int> > G4SelectedAlongStepDoItVector;
typedef class std::vector<int, std::allocator<int> > G4SelectedPostStepDoItVector;
 
//________________________________________________
//
// Members related to ParticleDefinition and not
// proper to a track
//________________________________________________
struct ProcessGeneralInfo
{
  G4ProcessVector* fpAtRestDoItVector;
  G4ProcessVector* fpAlongStepDoItVector;
  G4ProcessVector* fpPostStepDoItVector;
 
  G4ProcessVector* fpAtRestGetPhysIntVector;
  G4ProcessVector* fpAlongStepGetPhysIntVector;
  G4ProcessVector* fpPostStepGetPhysIntVector;
  //
  // Note: DoItVector has inverse order against GetPhysIntVector
  //       and SelectedPostStepDoItVector.
  //
  // * Max number of processes
  size_t MAXofAtRestLoops;
  size_t MAXofAlongStepLoops;
  size_t MAXofPostStepLoops;
  // Maximum number of processes for each type of process
  // These depend on the G4ParticleDefinition, so on the track
 
  // * Transportation process
  G4ITTransportation* fpTransportation;
};
 
//________________________________________________
//
//          Members proper to a track
//________________________________________________
class G4ITStepProcessorState : public G4ITStepProcessorState_Lock
{
public:
  G4ITStepProcessorState();
  virtual ~G4ITStepProcessorState();
 
  G4ITStepProcessorState(const G4ITStepProcessorState&);
  G4ITStepProcessorState& operator=(const G4ITStepProcessorState&);
 
  // * Max Number of Process
  G4SelectedAtRestDoItVector fSelectedAtRestDoItVector;
  G4SelectedPostStepDoItVector fSelectedPostStepDoItVector;
 
  G4double fPhysicalStep;
  G4double fPreviousStepSize;
  G4double fSafety;
 
  G4StepStatus fStepStatus;
 
  // * Safety
  G4double fProposedSafety;
  // This keeps the minimum safety value proposed by AlongStepGPILs.
  G4ThreeVector fEndpointSafOrigin;
  G4double fEndpointSafety;
  // To get the true safety value at the PostStepPoint, you have
  // to subtract the distance to 'endpointSafOrigin' from this value.
 
  G4TouchableHandle fTouchableHandle;
};
 
class G4ITStepProcessor
{
friend class G4Scheduler;
public:
  G4ITStepProcessor();
  virtual ~G4ITStepProcessor();
 
  inline void SetPreviousStepTime(G4double);
 
  inline G4Track* GetTrack()
  {
    return fpTrack;
  }
  inline G4Step* GetStep()
  {
    return fpStep;
  }
  inline const G4Step* GetStep() const
  {
    return fpStep;
  }
  inline void SetStep(G4Step* val)
  {
    fpStep = val;
  }
 
  inline G4TrackVector* GetSecondaries() const
  {
    return fpSecondary;
  }
  inline void SetTrackingManager(G4ITTrackingManager* trackMan)
  {
    fpTrackingManager = trackMan;
  }
  inline G4ITTrackingManager* GetTrackingManager()
  {
    return fpTrackingManager;
  }
 
  //___________________________________
 
  virtual void Initialize();
  void ForceReInitialization();
 
  void ResetLeadingTracks();
  void PrepareLeadingTracks();
 
  //___________________________________
  G4double ComputeInteractionLength(double previousTimeStep);
  void DefinePhysicalStepLength(G4Track*);
  G4double GetILTimeStep()
  {
    return fILTimeStep;
  }
 
  //___________________________________
  // DoIt
  void DoIt(double timeStep);
  void ExtractDoItData();
  void Stepping(G4Track*, const double&);
  void FindTransportationStep();
  //___________________________________
 
  inline double GetInteractionTime();
  inline const G4Track* GetTrack() const;
  inline void CleanProcessor();
 
  size_t GetAtRestDoItProcTriggered() const
  {
    return fAtRestDoItProcTriggered;
  }
 
  G4GPILSelection GetGPILSelection() const
  {
    return fGPILSelection;
  }
 
  G4int GetN2ndariesAlongStepDoIt() const
  {
    return fN2ndariesAlongStepDoIt;
  }
 
  G4int GetN2ndariesAtRestDoIt() const
  {
    return fN2ndariesAtRestDoIt;
  }
 
  G4int GetN2ndariesPostStepDoIt() const
  {
    return fN2ndariesPostStepDoIt;
  }
 
  const G4VITProcess* GetCurrentProcess() const
  {
    return fpCurrentProcess;
  }
 
  G4double GetPhysIntLength() const
  {
    return fPhysIntLength;
  }
 
  size_t GetPostStepAtTimeDoItProcTriggered() const
  {
    return fPostStepAtTimeDoItProcTriggered;
  }
 
  size_t GetPostStepDoItProcTriggered() const
  {
    return fPostStepDoItProcTriggered;
  }
 
  const ProcessGeneralInfo* GetCurrentProcessInfo() const
  {
    return fpProcessInfo;
  }
 
  const G4ITStepProcessorState* GetProcessorState() const
  {
    return fpState;
  }
 
  const G4VParticleChange* GetParticleChange() const
  {
    return fpParticleChange;
  }
 
  const G4VPhysicalVolume* GetCurrentVolume() const
  {
    return fpCurrentVolume;
  }
 
  G4ForceCondition GetCondition() const
  {
    return fCondition;
  }
 
protected:
 
  void ExtractILData();
 
  void SetupGeneralProcessInfo(G4ParticleDefinition*, G4ProcessManager*);
  void ClearProcessInfo();
  void SetTrack(G4Track*);
 
  void GetProcessInfo();
 
  void SetupMembers();
  void ResetSecondaries();
  void InitDefineStep();
 
  void SetInitialStep();
 
  void GetAtRestIL();
  void DoDefinePhysicalStepLength();
  void DoStepping();
  void PushSecondaries();
 
  // void CalculateStep();
  // void DoCalculateStep();
 
  // void CloneProcesses();
  void ActiveOnlyITProcess();
  void ActiveOnlyITProcess(G4ProcessManager*);
 
  void DealWithSecondaries(G4int&);
  void InvokeAtRestDoItProcs();
  void InvokeAlongStepDoItProcs();
  void InvokePostStepDoItProcs();
  void InvokePSDIP(size_t); //
  void InvokeTransportationProc();
  void SetNavigator(G4ITNavigator *value);
  G4double CalculateSafety();
 
  // Return the estimated safety value at the PostStepPoint
  void ApplyProductionCut(G4Track*);
 
  G4ITStepProcessor(const G4ITStepProcessor& other);
  G4ITStepProcessor& operator=(const G4ITStepProcessor& other);
 
private:
  //________________________________________________
  //
  //              General members
  //________________________________________________
 
  G4bool fInitialized;
 
  G4ITTrackingManager* fpTrackingManager;
 
  G4double kCarTolerance;
  // Cached geometrical tolerance on surface
 
  G4ITNavigator* fpNavigator;
  G4int fStoreTrajectory;
  G4VITSteppingVerbose* fpVerbose;
 
  G4ITTrackHolder* fpTrackContainer;
  G4ITLeadingTracks fLeadingTracks;
 
  //________________________________________________
  //
  // Members used as temporaries (= not proper to a track)
  //________________________________________________
 
  G4double fTimeStep; // not proper to a track
  G4double fILTimeStep; // proper to a track ensemble
 
  G4double fPreviousTimeStep;
  G4TrackVector* fpSecondary; // get from fpStep at every configuration setup
  G4VParticleChange* fpParticleChange;
 
  G4VITProcess* fpCurrentProcess;
  // The pointer to the process of which DoIt or
  // GetPhysicalInteractionLength has been just executed
 
  // * Secondaries
  G4int fN2ndariesAtRestDoIt;
  G4int fN2ndariesAlongStepDoIt;
  G4int fN2ndariesPostStepDoIt;
  // These are the numbers of secondaries generated by the process
  // just executed.
 
  // * Process selection
  size_t fAtRestDoItProcTriggered;
  size_t fPostStepDoItProcTriggered;
  size_t fPostStepAtTimeDoItProcTriggered;
  // Record the selected process
 
  G4ForceCondition fCondition;
  G4GPILSelection fGPILSelection;
  // Above three variables are for the method
  // DefinePhysicalStepLength(). To pass these information to
  // the method Verbose, they are kept at here. Need a more
  // elegant mechanism.
 
  G4double fPhysIntLength;
  // The minimum physical interaction length over all possible processes
 
  // * Sensitive detector
  //    G4SteppingControl StepControlFlag;
  //    G4VSensitiveDetector*   fpSensitive;
 
  G4VPhysicalVolume* fpCurrentVolume;
  // Get from fpStep or touchable, keep as member for user interface
 
  //________________________________________________
  //
  // Members related to ParticleDefinition and not
  // proper to a track
  //________________________________________________
 
  std::map<const G4ParticleDefinition*, ProcessGeneralInfo*> fProcessGeneralInfoMap;
  ProcessGeneralInfo* fpProcessInfo;
  G4ITTransportation* fpTransportation;
 
  //________________________________________________
  //
  // Members used for setting up the processor
  //________________________________________________
 
  G4Track* fpTrack; // Set track
  G4IT* fpITrack; // Set track
  G4TrackingInformation* fpTrackingInfo; // Set track
 
  G4ITStepProcessorState* fpState; // SetupMembers or InitDefineStep
  G4Step* fpStep; // Set track or InitDefineStep
 
  G4StepPoint* fpPreStepPoint; // SetupMembers
  G4StepPoint* fpPostStepPoint; // SetupMembers
};
 
//______________________________________________________________________________
 
inline void G4ITStepProcessor::SetPreviousStepTime(G4double previousTimeStep)
{
  fPreviousTimeStep = previousTimeStep;
}
 
//______________________________________________________________________________
 
inline const G4Track* G4ITStepProcessor::GetTrack() const
{
  return fpTrack;
}
 
//______________________________________________________________________________
 
inline G4double G4ITStepProcessor::CalculateSafety()
{
  return std::max(fpState->fEndpointSafety - (fpState->fEndpointSafOrigin
                      - fpPostStepPoint->GetPosition()).mag(),
                  kCarTolerance);
}
 
//______________________________________________________________________________
 
inline void G4ITStepProcessor::SetNavigator(G4ITNavigator *value)
{
  fpNavigator = value;
}
 
//______________________________________________________________________________
 
inline void G4ITStepProcessor::CleanProcessor()
{
  fTimeStep = DBL_MAX;
  fPhysIntLength = DBL_MAX;
 
  fpState = 0;
  fpTrack = 0;
  fpTrackingInfo = 0;
  fpITrack = 0;
  fpStep = 0;
  fpPreStepPoint = 0;
  fpPostStepPoint = 0;
 
  fpParticleChange = 0;
 
  fpCurrentVolume = 0;
  //    fpSensitive = 0;
 
  fpSecondary = 0;
 
  fpTransportation = 0;
 
  fpCurrentProcess= 0;
  fpProcessInfo = 0;
 
  fAtRestDoItProcTriggered = INT_MAX;
  fPostStepDoItProcTriggered = INT_MAX;
  fPostStepAtTimeDoItProcTriggered = INT_MAX;
  fGPILSelection = NotCandidateForSelection;
  fCondition = NotForced;
}
 
//______________________________________________________________________________
 
inline double G4ITStepProcessor::GetInteractionTime()
{
  return fTimeStep;
}
 
#endif // G4ITSTEPPROCESSOR_H