G4tgbPlaceParamCircle Class Reference

#include <G4tgbPlaceParamCircle.hh>

Inheritance diagram for G4tgbPlaceParamCircle:

Public Member Functions
	G4tgbPlaceParamCircle (G4tgrPlaceParameterisation *)
	~G4tgbPlaceParamCircle ()
void	ComputeTransformation (const G4int copyNo, G4VPhysicalVolume *physVol) const
Public Member Functions inherited from G4tgbPlaceParameterisation
	G4tgbPlaceParameterisation (G4tgrPlaceParameterisation *tgrParam)
virtual	~G4tgbPlaceParameterisation ()
virtual void	ComputeTransformation (const G4int, G4VPhysicalVolume *) const
void	CheckNExtraData (G4tgrPlaceParameterisation *tgrParam, G4int nWcheck, WLSIZEtype st, const G4String &methodName)
G4int	GetNCopies () const
EAxis	GetAxis () const
Public Member Functions inherited from G4VPVParameterisation
	G4VPVParameterisation ()=default
virtual	~G4VPVParameterisation ()=default
virtual void	ComputeTransformation (const G4int, G4VPhysicalVolume *) const =0
virtual G4VSolid *	ComputeSolid (const G4int, G4VPhysicalVolume *)
virtual G4Material *	ComputeMaterial (const G4int repNo, G4VPhysicalVolume *currentVol, const G4VTouchable *parentTouch=nullptr)
virtual G4bool	IsNested () const
virtual G4VVolumeMaterialScanner *	GetMaterialScanner ()
virtual void	ComputeDimensions (G4Box &, const G4int, const G4VPhysicalVolume *) const
virtual void	ComputeDimensions (G4Tubs &, const G4int, const G4VPhysicalVolume *) const
virtual void	ComputeDimensions (G4Trd &, const G4int, const G4VPhysicalVolume *) const
virtual void	ComputeDimensions (G4Trap &, const G4int, const G4VPhysicalVolume *) const
virtual void	ComputeDimensions (G4Cons &, const G4int, const G4VPhysicalVolume *) const
virtual void	ComputeDimensions (G4Sphere &, const G4int, const G4VPhysicalVolume *) const
virtual void	ComputeDimensions (G4Orb &, const G4int, const G4VPhysicalVolume *) const
virtual void	ComputeDimensions (G4Ellipsoid &, const G4int, const G4VPhysicalVolume *) const
virtual void	ComputeDimensions (G4Torus &, const G4int, const G4VPhysicalVolume *) const
virtual void	ComputeDimensions (G4Para &, const G4int, const G4VPhysicalVolume *) const
virtual void	ComputeDimensions (G4Polycone &, const G4int, const G4VPhysicalVolume *) const
virtual void	ComputeDimensions (G4Polyhedra &, const G4int, const G4VPhysicalVolume *) const
virtual void	ComputeDimensions (G4Hype &, const G4int, const G4VPhysicalVolume *) const

Additional Inherited Members
Protected Attributes inherited from G4tgbPlaceParameterisation
G4int	theNCopies = 0
EAxis	theAxis = kUndefined
G4ThreeVector	theTranslation
G4RotationMatrix *	theRotationMatrix = nullptr

Detailed Description

Definition at line 46 of file G4tgbPlaceParamCircle.hh.

Constructor & Destructor Documentation

G4tgbPlaceParamCircle()

G4tgbPlaceParamCircle::G4tgbPlaceParamCircle

(

G4tgrPlaceParameterisation *

tgrParam

)

Definition at line 45 of file G4tgbPlaceParamCircle.cc.

  : G4tgbPlaceParameterisation(tgrParam)
{
  //---- Get translation and rotation
  if(tgrParam->GetParamType() == "CIRCLE")
  {
    CheckNExtraData(tgrParam, 7, WLSIZE_EQ, "G4tgbPlaceParamCircle:");
    theCircleAxis =
      G4ThreeVector(tgrParam->GetExtraData()[4], tgrParam->GetExtraData()[5],
                    tgrParam->GetExtraData()[6]);
 
    G4ThreeVector zaxis(0., 0., -1.);
    if(zaxis.cross(theCircleAxis).mag() > 1.E-6)
    {
      theDirInPlane = zaxis.cross(theCircleAxis);
    }
    else
    {
      theDirInPlane = theCircleAxis.cross(G4ThreeVector(0., -1., 0.));
    }
    theAxis = kZAxis;
  }
  else
  {
    CheckNExtraData(tgrParam, 4, WLSIZE_EQ, "G4tgbPlaceParamCircle:");
    if(tgrParam->GetParamType() == "CIRCLE_XY")
    {
      theCircleAxis = G4ThreeVector(0., 0., 1.);
      theDirInPlane = G4ThreeVector(1., 0., 0.);
      theAxis       = kZAxis;
    }
    else if(tgrParam->GetParamType() == "CIRCLE_XZ")
    {
      theCircleAxis = G4ThreeVector(0., 1., 0.);
      theDirInPlane = G4ThreeVector(1., 0., 0.);
      theAxis       = kYAxis;
    }
    else if(tgrParam->GetParamType() == "CIRCLE_YZ")
    {
      theCircleAxis = G4ThreeVector(1., 0., 0.);
      theDirInPlane = G4ThreeVector(0., 1., 0.);
      theAxis       = kXAxis;
    }
  }
 
  if(theCircleAxis.mag() == 0.)
  {
    G4Exception("G4tgbPlaceParamCircle::G4tgbPlaceParamCircle()",
                "InvalidSetup", FatalException, "Circle axis is zero !");
  }
  theCircleAxis /= theCircleAxis.mag();
 
  theAxis = kZAxis;
 
  theNCopies = G4int(tgrParam->GetExtraData()[0]);
  theStep    = tgrParam->GetExtraData()[1];
  theOffset  = tgrParam->GetExtraData()[2];
  theRadius  = tgrParam->GetExtraData()[3];
 
#ifdef G4VERBOSE
  if(G4tgrMessenger::GetVerboseLevel() >= 2)
  {
    G4cout << " G4tgbPlaceParamCircle::G4tgbPlaceParamCircle():" << G4endl
           << " param type " << tgrParam->GetParamType() << G4endl
           << "   no copies - " << theNCopies << G4endl << "   step - "
           << theStep << G4endl << "   offset - " << theOffset << G4endl
           << "   radius - " << theRadius << G4endl << "   circle axis - "
           << theCircleAxis << G4endl << "   dir in plane - " << theDirInPlane
           << G4endl;
  }
#endif
}

~G4tgbPlaceParamCircle()

G4tgbPlaceParamCircle::~G4tgbPlaceParamCircle

(

)

Definition at line 40 of file G4tgbPlaceParamCircle.cc.

{
}

Member Function Documentation

ComputeTransformation()

void G4tgbPlaceParamCircle::ComputeTransformation ( const G4int  copyNo, G4VPhysicalVolume *  physVol  ) const

virtual

Reimplemented from G4tgbPlaceParameterisation.

Definition at line 120 of file G4tgbPlaceParamCircle.cc.

{
  G4double posi        = theOffset + copyNo * theStep;
  G4ThreeVector origin = theDirInPlane * theRadius;
  origin.rotate(posi, theCircleAxis);
 
  //----- Calculate rotation matrix (so that all volumes point to the centre)
  G4RotationMatrix rm;
  rm.rotate(-posi, theCircleAxis);
 
  //----- Set translation and rotation
  physVol->SetTranslation(origin);
  G4RotationMatrix* pvRm = physVol->GetRotation();
  if(pvRm == nullptr)
  {
    pvRm = new G4RotationMatrix;
  }
  *pvRm = *theRotationMatrix * rm;
  physVol->SetRotation(pvRm);
  physVol->SetCopyNo(copyNo);
 
#ifdef G4VERBOSE
  if(G4tgrMessenger::GetVerboseLevel() >= 3)
  {
    G4cout << " G4tgbPlaceParamCircle::ComputeTransformation():"
           << physVol->GetName() << G4endl << "   no copies - " << theNCopies
           << G4endl << "   centre - " << origin << G4endl
           << "   rotation-matrix - " << *pvRm << G4endl;
  }
#endif
}

---

The documentation for this class was generated from the following files:

• G4tgbPlaceParamCircle.hh
• G4tgbPlaceParamCircle.cc