Manuals/CHOMBO-SVN/ResistivityOp_8H_source.html

 #ifdef CH_LANG_CC
 /*
  *      _______              __
  *     / ___/ /  ___  __ _  / /  ___
  *    / /__/ _ \/ _ \/  V \/ _ \/ _ \
  *    \___/_//_/\___/_/_/_/_.__/\___/
  *    Please refer to Copyright.txt, in Chombo's root directory.
  */
 #endif

 // dtg 2007

 #ifndef _RESISTIVITYOP_H_
 #define _RESISTIVITYOP_H_

 #include "AMRMultiGrid.H"
 #include "REAL.H"
 #include "Box.H"
 #include "LevelDataOps.H"
 #include "BCFunc.H"
 #include "FArrayBox.H"
 #include "FluxBox.H"
 #include "CFIVS.H"
 #include "TensorCFInterp.H"
 #include "CoarseAverage.H"
 #include "AMRTGA.H"
 #include "NamespaceHeader.H"

 ///
 /**
    operator L is defined as
    L(B) = alpha B + beta*(divF)
    where
    F = eta((grad B - grad B^T) + I  (div B))
    alpha and beta are constants.  eta is a function of space.
    beta and eta are incorporated into the flux F when getFlux is called.
    This is always 3 variables.  SpaceDim refers to only the derivatives
    that are meaningful in this bizzare application.
 */
 class ResistivityOp : public LevelTGAHelmOp<LevelData<FArrayBox>, FluxBox>
 {
 public:

   virtual void setAlphaAndBeta(const Real& a_alpha,
                                const Real& a_beta)
   {
     m_alpha = a_alpha;
     m_beta = a_beta;
     setLambda();
   }

   virtual void diagonalScale(LevelData<FArrayBox>& a_rhs, bool a_kappaWeighted)
   {
     diagonalScale(a_rhs);
   }

   virtual void diagonalScale(LevelData<FArrayBox>& a_rhs)
   {
     //does not apply here
   }

   virtual void divideByIdentityCoef(LevelData<FArrayBox>& a_rhs)
   {
     //does not apply here
   }

   ///
   /**
    */
   virtual ~ResistivityOp()
   {
   }

   //use at thy peril
   virtual void getFlux(FluxBox&             a_flux,
                const LevelData<FArrayBox>&  a_data,
                const Box&       a_grid,
                const DataIndex& a_dit,
                Real             a_scale);

   ///
   /**
    */
   ResistivityOp(const DisjointBoxLayout&                    a_grids,
                 const DisjointBoxLayout&                    a_gridsFine,
                 const DisjointBoxLayout&                    a_gridsCoar,
                 const RefCountedPtr<LevelData<FluxBox> >&   a_eta,
                 Real                                        a_alpha,
                 Real                                        a_beta,
                 int                                         a_refToFine,
                 int                                         a_refToCoar,
                 const ProblemDomain&                        a_domain,
                 const Real&                                 a_dxLevel,
                 const Real&                                 a_dxCoar,
                 BCFunc                                      a_bc);

   virtual void residual(  LevelData<FArrayBox>& a_lhs,
                           const LevelData<FArrayBox>& a_phi,
                           const LevelData<FArrayBox>& a_rhs,
                           bool a_homogeneous = false);

   virtual void preCond(   LevelData<FArrayBox>& a_correction,
                           const LevelData<FArrayBox>& a_residual);

   virtual void applyOp(   LevelData<FArrayBox>& a_lhs,
                           const LevelData<FArrayBox>& a_phi,
                           bool a_homogeneous = false);

   virtual void applyOpNoBoundary( LevelData<FArrayBox>& a_lhs,
                                   const LevelData<FArrayBox>& a_phi);

   virtual void create(    LevelData<FArrayBox>& a_lhs,
                           const LevelData<FArrayBox>& a_rhs);
   virtual void createCoarsened(    LevelData<FArrayBox>& a_lhs,
                                    const LevelData<FArrayBox>& a_rhs,
                                    const int& a_refRat);

   void reflux(const LevelData<FArrayBox>& a_phiFine,
               const LevelData<FArrayBox>& a_phi,
               LevelData<FArrayBox>& residual,
               AMRLevelOp<LevelData<FArrayBox> >* a_finerOp);

   void getFlux(FArrayBox&       a_flux,
                const FArrayBox& a_data,
                const FArrayBox& a_gradData,
                const FArrayBox& a_etaFace,
                const Box&       a_facebox,
                int              a_dir,
                int ref = 1);

   /// utility function which computes operator after all bc's have been set
   void computeOperatorNoBCs(LevelData<FArrayBox>& a_lhs,
                             const LevelData<FArrayBox>& a_phi);

   virtual void assign(    LevelData<FArrayBox>& a_lhs,
                           const LevelData<FArrayBox>& a_rhs) ;
   virtual Real dotProduct(const LevelData<FArrayBox>& a_1,
                           const LevelData<FArrayBox>& a_2) ;
   virtual void incr( LevelData<FArrayBox>& a_lhs,
                      const LevelData<FArrayBox>& a_x,
                      Real a_scale) ;
   virtual void axby( LevelData<FArrayBox>& a_lhs,
                      const LevelData<FArrayBox>& a_x,
                      const LevelData<FArrayBox>& a_y,
                      Real a, Real b) ;

   virtual void scale(LevelData<FArrayBox>& a_lhs, const Real& a_scale) ;

   virtual Real norm(const LevelData<FArrayBox>& a_x, int a_ord);

   virtual void setToZero( LevelData<FArrayBox>& a_x);
   /*@}*/

   /**
      \name MGLevelOp functions */
   /*@{*/

   virtual void relax(LevelData<FArrayBox>& a_e,
                      const LevelData<FArrayBox>& a_residual,
                      int iterations);

   virtual void createCoarser(LevelData<FArrayBox>& a_coarse,
                              const LevelData<FArrayBox>& a_fine,
                              bool ghosted);
   /**
      calculate restricted residual
      a_resCoarse[2h] = I[h->2h] (rhsFine[h] - L[h](phiFine[h])
   */
   virtual void restrictResidual(LevelData<FArrayBox>& a_resCoarse,
                                 LevelData<FArrayBox>& a_phiFine,
                                 const LevelData<FArrayBox>& a_rhsFine);

   /**
      correct the fine solution based on coarse correction
      a_phiThisLevel += I[2h->h](a_correctCoarse)
   */
   virtual void prolongIncrement(LevelData<FArrayBox>& a_phiThisLevel,
                                 const LevelData<FArrayBox>& a_correctCoarse);

   /*@}*/

   /**
      \name AMRLevelOp functions */
   /*@{*/

   /** returns 1 when there are no coarser AMRLevelOp objects */
   virtual int refToCoarser()
   {
     return m_refToCoar;
   }

   /** a_residual = a_rhs - L(a_phi, a_phiFine, a_phiCoarse) */
   virtual void AMRResidual(LevelData<FArrayBox>& a_residual,
                            const LevelData<FArrayBox>& a_phiFine,
                            const LevelData<FArrayBox>& a_phi,
                            const LevelData<FArrayBox>& a_phiCoarse,
                            const LevelData<FArrayBox>& a_rhs,
                            bool a_homogeneousPhysBC,
                            AMRLevelOp<LevelData<FArrayBox> >* a_finerOp);

   /** residual assuming no more coarser AMR levels */

   virtual void AMRResidualNC(LevelData<FArrayBox>& a_residual,
                              const LevelData<FArrayBox>& a_phiFine,
                              const LevelData<FArrayBox>& a_phi,
                              const LevelData<FArrayBox>& a_rhs,
                              bool a_homogeneousPhysBC,
                              AMRLevelOp<LevelData<FArrayBox> >* a_finerOp);

   /** a_residual = a_rhs - L(a_phi, a_phiCoarse)  */
   virtual void AMRResidualNF(LevelData<FArrayBox>& a_residual,
                              const LevelData<FArrayBox>& a_phi,
                              const LevelData<FArrayBox>& a_phiCoarse,
                              const LevelData<FArrayBox>& a_rhs,
                              bool a_homogeneousPhysBC);

   /** a_resCoarse = I[h-2h]( a_residual - L(a_correction, a_coarseCorrection))
       it is assumed that a_resCoarse has already been filled in with the coarse
       version of AMRResidualNF and that this operation is free to overwrite
       in the overlap regions.
   */

   virtual void AMRRestrict(LevelData<FArrayBox>& a_resCoarse,
                            const LevelData<FArrayBox>& a_residual,
                            const LevelData<FArrayBox>& a_correction,
                            const LevelData<FArrayBox>& a_coarseCorrection,
                            bool a_skip_res = false );

   /** a_correction += I[h->h](a_coarseCorrection) */
   virtual void AMRProlong(LevelData<FArrayBox>& a_correction,
                           const LevelData<FArrayBox>& a_coarseCorrection);

   /** a_residual = a_residual - L(a_correction, a_coarseCorrection) */
   virtual void AMRUpdateResidual(LevelData<FArrayBox>& a_residual,
                                  const LevelData<FArrayBox>& a_correction,
                                  const LevelData<FArrayBox>& a_coarseCorrection);

   ///
   /**
      compute norm over all cells on coarse not covered by finer
   */
   virtual Real AMRNorm(const LevelData<FArrayBox>& a_coarseResid,
                        const LevelData<FArrayBox>& a_fineResid,
                        const int&                  a_refRat,
                        const int&                  a_ord);

   void homogeneousCFInterp(LevelData<FArrayBox>& a_phif);
  ///
   /**
      does homogeneous coarse/fine interpolation for phi
   */
   void
   homogeneousCFInterpPhi(LevelData<FArrayBox>& a_phif,
                          const DataIndex& a_datInd,
                          int a_idir,
                          Side::LoHiSide a_hiorlo);

   ///
   /** does homogeneous coarse/fine interpolation for tangential gradient
       (needs phi ghost cells to be filled in first, so should call
       homogeneousCFInterpPhi first)
   */
   void homogeneousCFInterpTanGrad(LevelData<FArrayBox>& a_tanGrad,
                                   const LevelData<FArrayBox>& a_phi,
                                   const DataIndex& a_datInd,
                                   int a_idir,
                                   Side::LoHiSide a_hiorlo);

   void interpOnIVSHomo(LevelData<FArrayBox>& a_phif,
                        const DataIndex& a_datInd,
                        const int a_idir,
                        const Side::LoHiSide a_hiorlo,
                        const IntVectSet& a_interpIVS);
   ///
   /**
      Apply the AMR operator, including coarse-fine matching
   */
   void AMROperator(      LevelData<FArrayBox>& a_LofPhi,
                    const LevelData<FArrayBox>& a_phiFine,
                    const LevelData<FArrayBox>& a_phi,
                    const LevelData<FArrayBox>& a_phiCoarse,
                    bool a_homogeneousDomBC,
                    AMRLevelOp<LevelData<FArrayBox> >*  a_finerOp);

   void AMROperatorNF(      LevelData<FArrayBox>& a_LofPhi,
                      const LevelData<FArrayBox>& a_phi,
                      const LevelData<FArrayBox>& a_phiCoarse,
                      bool a_homogeneousBC);

   virtual void AMROperatorNC(      LevelData<FArrayBox>& a_LofPhi,
                              const LevelData<FArrayBox>& a_phiFine,
                              const LevelData<FArrayBox>& a_phi,
                              bool a_homogeneousBC,
                              AMRLevelOp<LevelData<FArrayBox> >* a_finerOp);

   void cellGrad(FArrayBox&             a_gradPhi,
                 const  FArrayBox&      a_phi,
                 const Box&             a_grid);

   void cfinterp(const LevelData<FArrayBox>& a_phiFine,
                 const LevelData<FArrayBox>& a_phiCoarse);

   virtual void fillGrad(const LevelData<FArrayBox>& a_phiFine);

   void loHiCenterFace(Box&                 a_loBox,
                       int&                 a_hasLo,
                       Box&                 a_hiBox,
                       int&                 a_hasHi,
                       Box&                 a_centerBox,
                       const ProblemDomain& a_eblg,
                       const Box&           a_inBox,
                       const int&           a_dir);

   void getFaceDivAndGrad(FArrayBox&             a_faceDiv,
                          FArrayBox&             a_faceGrad,
                          const FArrayBox&       a_data,
                          const FArrayBox&       a_gradData,
                          const ProblemDomain&   a_domain,
                          const Box&             a_faceBox,
                          const int&             a_faceDir,
                          const Real             a_dx);

   ///take cell centered divergence of the inputs.
   /**
       not part of the operator evaluation.  this is to
       test whether the divergence of b converges at h^2
       as b does if b is analytically divergence-free.
    */
   void divergenceCC(LevelData<FArrayBox>&       a_div,
                     const LevelData<FArrayBox>& a_phi,
                     const LevelData<FArrayBox>* a_phiC);
 protected:
   void setLambda();
   RefCountedPtr<LevelData<FluxBox> >         m_eta;
   DisjointBoxLayout                          m_grids;
   Real                                       m_alpha;
   Real                                       m_beta;
   int                                        m_refToCoar;
   int                                        m_refToFine;
   BCFunc                                     m_bc;

   //b is a scalar in 2d, vector in 3d
   static const int        s_nComp; //==3
   static const int        s_nGradComp; //==3*SpaceDim
   Real                    m_dx;
   Real                    m_dxCrse;
   ProblemDomain           m_domain;
   //relaxation coef
   LevelData<FArrayBox>    m_lambda;
   LevelData<FArrayBox>    m_grad;
   LevelDataOps<FArrayBox> m_levelOps;
   Copier                  m_exchangeCopier;
   TensorCFInterp          m_interpWithCoarser;

   LayoutData<CFIVS> m_loCFIVS[SpaceDim];
   LayoutData<CFIVS> m_hiCFIVS[SpaceDim];
   // will need these to do tangential gradient computations
   LayoutData<TensorFineStencilSet> m_hiTanStencilSets[SpaceDim];
   LayoutData<TensorFineStencilSet> m_loTanStencilSets[SpaceDim];
   Vector<IntVect> m_colors;
 private:
   ///weak construction is bad
   ResistivityOp()
   {
     MayDay::Error("invalid operator");
   }
   //copy constructor and operator= disallowed for all the usual reasons
   ResistivityOp(const ResistivityOp& a_opin)
   {
     MayDay::Error("invalid operator");
   }
   void operator=(const ResistivityOp& a_opin)
   {
     MayDay::Error("invalid operator");
   }
 };

 ///
 /**
    Factory to create ResistivityOps
  */
 class ResistivityOpFactory: public AMRLevelOpFactory<LevelData< FArrayBox> >
 {
 public:
   virtual ~ResistivityOpFactory()
   {
   }

   ResistivityOpFactory(const Vector<DisjointBoxLayout>&                     a_grids,
                        const Vector<RefCountedPtr<LevelData<FluxBox> > >&   a_eta,
                        Real                                                 a_alpha,
                        Real                                                 a_beta,
                        const Vector<int>&                                   a_refRatios,
                        const ProblemDomain&                                 a_domainCoar,
                        const Real&                                          a_dxCoar,
                        BCFunc                                               a_bc);

   ///
   virtual MGLevelOp< LevelData<FArrayBox> >*
   MGnewOp(const ProblemDomain& a_FineindexSpace,
           int depth,
           bool homoOnly = true);

   ///
   virtual AMRLevelOp< LevelData<FArrayBox> >*
   AMRnewOp(const ProblemDomain& a_indexSpace);

   ///
   virtual int refToFiner(const ProblemDomain&) const;

 private:
   Vector<RefCountedPtr<LevelData<FluxBox> > >    m_eta;
   LevelData<FArrayBox>                           m_phic;
   Vector<ProblemDomain>                          m_domains;
   Vector<DisjointBoxLayout>                      m_boxes;
   Vector<Real>                                   m_dx;
   // refinement to next coarser level
   Vector<int>                                    m_refRatios;
   BCFunc  m_bc;
   Real m_alpha, m_beta;

   ///weak construction is bad
   ResistivityOpFactory()
   {
     MayDay::Error("invalid operator");
   }
   //copy constructor and operator= disallowed for all the usual reasons
   ResistivityOpFactory(const ResistivityOpFactory& a_opin)
   {
     MayDay::Error("invalid operator");
   }

   void operator=(const ResistivityOpFactory& a_opin)
   {
     MayDay::Error("invalid operator");
   }
 };

 #include "NamespaceFooter.H"
 #endif
ResistivityOpFactory::m_dx
Vector< Real > m_dx
Definition: ResistivityOp.H:416

ResistivityOpFactory
Definition: ResistivityOp.H:382

ResistivityOp::applyOp
virtual void applyOp(LevelData< FArrayBox > &a_lhs, const LevelData< FArrayBox > &a_phi, bool a_homogeneous=false)

RefCountedPtr
A reference-counting handle class.
Definition: RefCountedPtr.H:173

CFIVS.H

IntVectSet
An irregular domain on an integer lattice.
Definition: IntVectSet.H:44

LevelDataOps< FArrayBox >

ResistivityOp::m_alpha
Real m_alpha
Definition: ResistivityOp.H:336

ProblemDomain
A class to facilitate interaction with physical boundary conditions.
Definition: ProblemDomain.H:141

ResistivityOpFactory::m_beta
Real m_beta
Definition: ResistivityOp.H:420

ResistivityOp::m_loCFIVS
LayoutData< CFIVS > m_loCFIVS[SpaceDim]
Definition: ResistivityOp.H:355

ResistivityOp::s_nGradComp
static const int s_nGradComp
Definition: ResistivityOp.H:344

ResistivityOp::s_nComp
static const int s_nComp
Definition: ResistivityOp.H:343

ResistivityOp::loHiCenterFace
void loHiCenterFace(Box &a_loBox, int &a_hasLo, Box &a_hiBox, int &a_hasHi, Box &a_centerBox, const ProblemDomain &a_eblg, const Box &a_inBox, const int &a_dir)

ResistivityOp::assign
virtual void assign(LevelData< FArrayBox > &a_lhs, const LevelData< FArrayBox > &a_rhs)

Vector< IntVect >

LayoutData< CFIVS >

ResistivityOp::m_levelOps
LevelDataOps< FArrayBox > m_levelOps
Definition: ResistivityOp.H:351

ResistivityOp::computeOperatorNoBCs
void computeOperatorNoBCs(LevelData< FArrayBox > &a_lhs, const LevelData< FArrayBox > &a_phi)
utility function which computes operator after all bc&#39;s have been set

Copier
A strange but true thing to make copying from one boxlayoutdata to another fast.
Definition: Copier.H:152

ResistivityOp::divideByIdentityCoef
virtual void divideByIdentityCoef(LevelData< FArrayBox > &a_rhs)
Definition: ResistivityOp.H:62

ResistivityOp::m_grad
LevelData< FArrayBox > m_grad
Definition: ResistivityOp.H:350

FArrayBox.H

ResistivityOpFactory::m_boxes
Vector< DisjointBoxLayout > m_boxes
Definition: ResistivityOp.H:415

ResistivityOp::diagonalScale
virtual void diagonalScale(LevelData< FArrayBox > &a_rhs, bool a_kappaWeighted)
Definition: ResistivityOp.H:52

ResistivityOp::preCond
virtual void preCond(LevelData< FArrayBox > &a_correction, const LevelData< FArrayBox > &a_residual)

ResistivityOp::interpOnIVSHomo
void interpOnIVSHomo(LevelData< FArrayBox > &a_phif, const DataIndex &a_datInd, const int a_idir, const Side::LoHiSide a_hiorlo, const IntVectSet &a_interpIVS)

TensorCFInterp
Quadratic coarse-fine interpolation utility for tensors.
Definition: TensorCFInterp.H:36

ResistivityOp::m_hiTanStencilSets
LayoutData< TensorFineStencilSet > m_hiTanStencilSets[SpaceDim]
Definition: ResistivityOp.H:358

ResistivityOp::AMROperator
void AMROperator(LevelData< FArrayBox > &a_LofPhi, const LevelData< FArrayBox > &a_phiFine, const LevelData< FArrayBox > &a_phi, const LevelData< FArrayBox > &a_phiCoarse, bool a_homogeneousDomBC, AMRLevelOp< LevelData< FArrayBox > > *a_finerOp)

ResistivityOp::restrictResidual
virtual void restrictResidual(LevelData< FArrayBox > &a_resCoarse, LevelData< FArrayBox > &a_phiFine, const LevelData< FArrayBox > &a_rhsFine)

ResistivityOp::createCoarsened
virtual void createCoarsened(LevelData< FArrayBox > &a_lhs, const LevelData< FArrayBox > &a_rhs, const int &a_refRat)

ResistivityOp::AMRResidualNF
virtual void AMRResidualNF(LevelData< FArrayBox > &a_residual, const LevelData< FArrayBox > &a_phi, const LevelData< FArrayBox > &a_phiCoarse, const LevelData< FArrayBox > &a_rhs, bool a_homogeneousPhysBC)

ResistivityOp::m_colors
Vector< IntVect > m_colors
Definition: ResistivityOp.H:360

ResistivityOp::reflux
void reflux(const LevelData< FArrayBox > &a_phiFine, const LevelData< FArrayBox > &a_phi, LevelData< FArrayBox > &residual, AMRLevelOp< LevelData< FArrayBox > > *a_finerOp)

ResistivityOpFactory::m_domains
Vector< ProblemDomain > m_domains
Definition: ResistivityOp.H:414

BCFunc
void(* BCFunc)(FArrayBox &a_state, const Box &a_valid, const ProblemDomain &a_domain, Real a_dx, bool a_homogeneous)
Definition: BCFunc.H:30

AMRTGA.H

ResistivityOp
Definition: ResistivityOp.H:40

ResistivityOp::cfinterp
void cfinterp(const LevelData< FArrayBox > &a_phiFine, const LevelData< FArrayBox > &a_phiCoarse)

SpaceDim
const int SpaceDim
Definition: SPACE.H:38

LevelDataOps.H

AMRLevelOp
Definition: AMRMultiGrid.H:39

ResistivityOp::scale
virtual void scale(LevelData< FArrayBox > &a_lhs, const Real &a_scale)

ResistivityOp::m_dxCrse
Real m_dxCrse
Definition: ResistivityOp.H:346

ResistivityOpFactory::m_eta
Vector< RefCountedPtr< LevelData< FluxBox > > > m_eta
Definition: ResistivityOp.H:412

ResistivityOp::~ResistivityOp
virtual ~ResistivityOp()
Definition: ResistivityOp.H:70

ResistivityOp::AMROperatorNF
void AMROperatorNF(LevelData< FArrayBox > &a_LofPhi, const LevelData< FArrayBox > &a_phi, const LevelData< FArrayBox > &a_phiCoarse, bool a_homogeneousBC)

FluxBox
A FArrayBox-like container for face-centered fluxes.
Definition: FluxBox.H:22

ResistivityOpFactory::ResistivityOpFactory
ResistivityOpFactory()
weak construction is bad
Definition: ResistivityOp.H:423

ResistivityOpFactory::m_phic
LevelData< FArrayBox > m_phic
Definition: ResistivityOp.H:413

ResistivityOp::refToCoarser
virtual int refToCoarser()
Definition: ResistivityOp.H:187

BCFunc.H

ResistivityOp::norm
virtual Real norm(const LevelData< FArrayBox > &a_x, int a_ord)

ResistivityOp::setAlphaAndBeta
virtual void setAlphaAndBeta(const Real &a_alpha, const Real &a_beta)
Definition: ResistivityOp.H:44

ResistivityOp::applyOpNoBoundary
virtual void applyOpNoBoundary(LevelData< FArrayBox > &a_lhs, const LevelData< FArrayBox > &a_phi)

LevelData< FArrayBox >

ResistivityOp::prolongIncrement
virtual void prolongIncrement(LevelData< FArrayBox > &a_phiThisLevel, const LevelData< FArrayBox > &a_correctCoarse)

ResistivityOp::create
virtual void create(LevelData< FArrayBox > &a_lhs, const LevelData< FArrayBox > &a_rhs)

ResistivityOp::homogeneousCFInterpPhi
void homogeneousCFInterpPhi(LevelData< FArrayBox > &a_phif, const DataIndex &a_datInd, int a_idir, Side::LoHiSide a_hiorlo)

ResistivityOp::AMRProlong
virtual void AMRProlong(LevelData< FArrayBox > &a_correction, const LevelData< FArrayBox > &a_coarseCorrection)

ResistivityOp::m_refToFine
int m_refToFine
Definition: ResistivityOp.H:339

Real
double Real
Definition: REAL.H:33

MGLevelOp
Definition: MultiGrid.H:30

ResistivityOp::setToZero
virtual void setToZero(LevelData< FArrayBox > &a_x)

ResistivityOp::m_domain
ProblemDomain m_domain
Definition: ResistivityOp.H:347

ResistivityOp::AMRUpdateResidual
virtual void AMRUpdateResidual(LevelData< FArrayBox > &a_residual, const LevelData< FArrayBox > &a_correction, const LevelData< FArrayBox > &a_coarseCorrection)

ResistivityOp::fillGrad
virtual void fillGrad(const LevelData< FArrayBox > &a_phiFine)
These functions are part of the LevelTGA interface......

ResistivityOp::getFlux
virtual void getFlux(FluxBox &a_flux, const LevelData< FArrayBox > &a_data, const Box &a_grid, const DataIndex &a_dit, Real a_scale)

ResistivityOp::dotProduct
virtual Real dotProduct(const LevelData< FArrayBox > &a_1, const LevelData< FArrayBox > &a_2)

DisjointBoxLayout
A BoxLayout that has a concept of disjointedness.
Definition: DisjointBoxLayout.H:30

ResistivityOp::getFaceDivAndGrad
void getFaceDivAndGrad(FArrayBox &a_faceDiv, FArrayBox &a_faceGrad, const FArrayBox &a_data, const FArrayBox &a_gradData, const ProblemDomain &a_domain, const Box &a_faceBox, const int &a_faceDir, const Real a_dx)

ResistivityOp::cellGrad
void cellGrad(FArrayBox &a_gradPhi, const FArrayBox &a_phi, const Box &a_grid)

Side::LoHiSide
LoHiSide
Definition: LoHiSide.H:27

ResistivityOp::divergenceCC
void divergenceCC(LevelData< FArrayBox > &a_div, const LevelData< FArrayBox > &a_phi, const LevelData< FArrayBox > *a_phiC)
take cell centered divergence of the inputs.

AMRMultiGrid.H

ResistivityOp::m_beta
Real m_beta
Definition: ResistivityOp.H:337

ResistivityOpFactory::ResistivityOpFactory
ResistivityOpFactory(const ResistivityOpFactory &a_opin)
Definition: ResistivityOp.H:428

TensorCFInterp.H

ResistivityOp::createCoarser
virtual void createCoarser(LevelData< FArrayBox > &a_coarse, const LevelData< FArrayBox > &a_fine, bool ghosted)

MayDay::Error
static void Error(const char *const a_msg=m_nullString, int m_exitCode=CH_DEFAULT_ERROR_CODE)
Print out message to cerr and exit with the specified exit code.

ResistivityOp::m_interpWithCoarser
TensorCFInterp m_interpWithCoarser
Definition: ResistivityOp.H:353

ResistivityOp::incr
virtual void incr(LevelData< FArrayBox > &a_lhs, const LevelData< FArrayBox > &a_x, Real a_scale)

ResistivityOp::m_exchangeCopier
Copier m_exchangeCopier
Definition: ResistivityOp.H:352

ResistivityOp::setLambda
void setLambda()

ResistivityOp::AMRRestrict
virtual void AMRRestrict(LevelData< FArrayBox > &a_resCoarse, const LevelData< FArrayBox > &a_residual, const LevelData< FArrayBox > &a_correction, const LevelData< FArrayBox > &a_coarseCorrection, bool a_skip_res=false)

ResistivityOp::m_eta
RefCountedPtr< LevelData< FluxBox > > m_eta
Definition: ResistivityOp.H:334

Box
A Rectangular Domain on an Integer Lattice.
Definition: Box.H:469

ResistivityOp::homogeneousCFInterp
void homogeneousCFInterp(LevelData< FArrayBox > &a_phif)

ResistivityOp::residual
virtual void residual(LevelData< FArrayBox > &a_lhs, const LevelData< FArrayBox > &a_phi, const LevelData< FArrayBox > &a_rhs, bool a_homogeneous=false)

ResistivityOp::ResistivityOp
ResistivityOp(const ResistivityOp &a_opin)
Definition: ResistivityOp.H:368

DataIndex
Definition: DataIndex.H:114

ResistivityOp::AMRResidualNC
virtual void AMRResidualNC(LevelData< FArrayBox > &a_residual, const LevelData< FArrayBox > &a_phiFine, const LevelData< FArrayBox > &a_phi, const LevelData< FArrayBox > &a_rhs, bool a_homogeneousPhysBC, AMRLevelOp< LevelData< FArrayBox > > *a_finerOp)

ResistivityOp::m_dx
Real m_dx
Definition: ResistivityOp.H:345

ResistivityOp::AMROperatorNC
virtual void AMROperatorNC(LevelData< FArrayBox > &a_LofPhi, const LevelData< FArrayBox > &a_phiFine, const LevelData< FArrayBox > &a_phi, bool a_homogeneousBC, AMRLevelOp< LevelData< FArrayBox > > *a_finerOp)

FArrayBox
Definition: FArrayBox.H:45

LevelTGAHelmOp
Definition: AMRTGA.H:159

FluxBox.H

Box.H

ResistivityOp::m_refToCoar
int m_refToCoar
Definition: ResistivityOp.H:338

REAL.H

ResistivityOp::AMRResidual
virtual void AMRResidual(LevelData< FArrayBox > &a_residual, const LevelData< FArrayBox > &a_phiFine, const LevelData< FArrayBox > &a_phi, const LevelData< FArrayBox > &a_phiCoarse, const LevelData< FArrayBox > &a_rhs, bool a_homogeneousPhysBC, AMRLevelOp< LevelData< FArrayBox > > *a_finerOp)

CoarseAverage.H

ResistivityOp::m_bc
BCFunc m_bc
Definition: ResistivityOp.H:340

ResistivityOp::homogeneousCFInterpTanGrad
void homogeneousCFInterpTanGrad(LevelData< FArrayBox > &a_tanGrad, const LevelData< FArrayBox > &a_phi, const DataIndex &a_datInd, int a_idir, Side::LoHiSide a_hiorlo)

ResistivityOp::AMRNorm
virtual Real AMRNorm(const LevelData< FArrayBox > &a_coarseResid, const LevelData< FArrayBox > &a_fineResid, const int &a_refRat, const int &a_ord)

AMRLevelOpFactory
Definition: AMRMultiGrid.H:233

ResistivityOp::operator=
void operator=(const ResistivityOp &a_opin)
Definition: ResistivityOp.H:372

ResistivityOpFactory::m_bc
BCFunc m_bc
Definition: ResistivityOp.H:419

ResistivityOp::m_loTanStencilSets
LayoutData< TensorFineStencilSet > m_loTanStencilSets[SpaceDim]
Definition: ResistivityOp.H:359

ResistivityOp::m_lambda
LevelData< FArrayBox > m_lambda
Definition: ResistivityOp.H:349

ResistivityOpFactory::~ResistivityOpFactory
virtual ~ResistivityOpFactory()
Definition: ResistivityOp.H:385

ResistivityOp::m_hiCFIVS
LayoutData< CFIVS > m_hiCFIVS[SpaceDim]
Definition: ResistivityOp.H:356

ResistivityOpFactory::operator=
void operator=(const ResistivityOpFactory &a_opin)
Definition: ResistivityOp.H:433

ResistivityOp::m_grids
DisjointBoxLayout m_grids
Definition: ResistivityOp.H:335

ResistivityOp::diagonalScale
virtual void diagonalScale(LevelData< FArrayBox > &a_rhs)
Definition: ResistivityOp.H:57

ResistivityOp::relax
virtual void relax(LevelData< FArrayBox > &a_e, const LevelData< FArrayBox > &a_residual, int iterations)

ResistivityOp::ResistivityOp
ResistivityOp()
weak construction is bad
Definition: ResistivityOp.H:363

ResistivityOpFactory::m_refRatios
Vector< int > m_refRatios
Definition: ResistivityOp.H:418

ResistivityOp::axby
virtual void axby(LevelData< FArrayBox > &a_lhs, const LevelData< FArrayBox > &a_x, const LevelData< FArrayBox > &a_y, Real a, Real b)