ResistivityOp Class Reference

#include <ResistivityOp.H>

Inheritance diagram for ResistivityOp:

[legend]

List of all members.

---

Detailed Description

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.

AMRLevelOp functions
RefCountedPtr< LevelData < FluxBox > >	m_eta
DisjointBoxLayout	m_grids
Real	m_alpha
Real	m_beta
int	m_refToCoar
int	m_refToFine
BCFunc	m_bc
Real	m_dx
Real	m_dxCrse
ProblemDomain	m_domain
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]
LayoutData< TensorFineStencilSet >	m_hiTanStencilSets [SpaceDim]
LayoutData< TensorFineStencilSet >	m_loTanStencilSets [SpaceDim]
Vector< IntVect >	m_colors
static const int	s_nComp
static const int	s_nGradComp
virtual int	refToCoarser ()
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)
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)
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)
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)
virtual void	AMRProlong (LevelData< FArrayBox > &a_correction, const LevelData< FArrayBox > &a_coarseCorrection)
virtual void	AMRUpdateResidual (LevelData< FArrayBox > &a_residual, const LevelData< FArrayBox > &a_correction, const LevelData< FArrayBox > &a_coarseCorrection)
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)
void	homogeneousCFInterpPhi (LevelData< FArrayBox > &a_phif, const DataIndex &a_datInd, int a_idir, Side::LoHiSide a_hiorlo)
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)
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)
	These functions are part of the LevelTGA interface......
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)
void	divergenceCC (LevelData< FArrayBox > &a_div, const LevelData< FArrayBox > &a_phi, const LevelData< FArrayBox > *a_phiC)
	take cell centered divergence of the inputs.
void	setLambda ()
	ResistivityOp ()
	weak construction is bad
	ResistivityOp (const ResistivityOp &a_opin)
void	operator= (const ResistivityOp &a_opin)
Public Member Functions
virtual void	setAlphaAndBeta (const Real &a_alpha, const Real &a_beta)
virtual void	diagonalScale (LevelData< FArrayBox > &a_rhs, bool a_kappaWeighted)
virtual void	diagonalScale (LevelData< FArrayBox > &a_rhs)
virtual void	divideByIdentityCoef (LevelData< FArrayBox > &a_rhs)
virtual	~ResistivityOp ()
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)
void	computeOperatorNoBCs (LevelData< FArrayBox > &a_lhs, const LevelData< FArrayBox > &a_phi)
	utility function which computes operator after all bc's have been set
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)
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)
virtual void	restrictResidual (LevelData< FArrayBox > &a_resCoarse, LevelData< FArrayBox > &a_phiFine, const LevelData< FArrayBox > &a_rhsFine)
virtual void	prolongIncrement (LevelData< FArrayBox > &a_phiThisLevel, const LevelData< FArrayBox > &a_correctCoarse)

---

Constructor & Destructor Documentation

virtual ResistivityOp::~ResistivityOp

(

)

[inline, virtual]

ResistivityOp::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
	)

ResistivityOp::ResistivityOp

(

)

[inline, private]

weak construction is bad

References MayDay::Error().

ResistivityOp::ResistivityOp

(

const ResistivityOp &

a_opin

)

[inline, private]

References MayDay::Error().

---

Member Function Documentation

virtual void ResistivityOp::setAlphaAndBeta	(	const Real &	a_alpha,
		const Real &	a_beta
	)			[inline, virtual]

Sets the scaling constants in the Helmholtz equation.

Parameters:

	a_alpha	The scaling constant that multiplies the identity term.
	a_beta	The scaling constant that multiplies the derivative term.

Implements TGAHelmOp< LevelData< FArrayBox > >.

References m_alpha, m_beta, and setLambda().

virtual void ResistivityOp::diagonalScale	(	LevelData< FArrayBox > &	a_rhs,
		bool	a_kappaWeighted
	)			[inline, virtual]

Scales the right hand side of the Helmholtz equation by the identity term in the operator. If you are solving rho(x) dphi/dt = L(phi), this means multiply by rho (or kappa * rho in embedded boundary calculations.

Parameters:

	a_rhs	The right hand side of the equation to be scaled.
	a_kappaWeighted	If set to true, a_rhs will be scaled by the volume fraction in addition to the identity term.

Reimplemented from TGAHelmOp< LevelData< FArrayBox > >.

virtual void ResistivityOp::diagonalScale

(

LevelData< FArrayBox > &

a_rhs

)

[inline, virtual]

Scales the right hand side of the Helmholtz equation by the identity term in the operator. This version assumes volume fraction weighting.

Parameters:

a_rhs

The right hand side of the equation to be scaled.

Reimplemented from TGAHelmOp< LevelData< FArrayBox > >.

virtual void ResistivityOp::divideByIdentityCoef

(

LevelData< FArrayBox > &

a_rhs

)

[inline, virtual]

Divides the right hand side of the Helmholtz equation by the identity coefficient rho(x) in the equation rho(x) dphi/dt = L(phi).

Parameters:

a_rhs

The right hand side of the equation to be scaled.

Implements TGAHelmOp< LevelData< FArrayBox > >.

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

Implements LevelTGAHelmOp< LevelData< FArrayBox >, FluxBox >.

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

Say you are solving L(phi) = rhs. Make a_lhs = L(a_phi) - a_rhs. If a_homogeneous is true, evaluate the operator using homogeneous boundary conditions.

Implements LinearOp< LevelData< FArrayBox > >.

virtual void ResistivityOp::preCond	(	LevelData< FArrayBox > &	a_cor,
		const LevelData< FArrayBox > &	a_residual
	)			[virtual]

Given the current state of the residual the correction, apply your preconditioner to a_cor.

Implements LinearOp< LevelData< FArrayBox > >.

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

In the context of solving L(phi) = rhs, set a_lhs = L(a_phi). If a_homogeneous is true, evaluate the operator using homogeneous boundary conditions.

Implements LinearOp< LevelData< FArrayBox > >.

virtual void ResistivityOp::applyOpNoBoundary	(	LevelData< FArrayBox > &	a_ans,
		const LevelData< FArrayBox > &	a_phi
	)			[virtual]

Apply the differential operator without any boundary or coarse-fine boundary conditions and no finer level

Parameters:

	a_ans	The result of the application of the operator to a_phi.
	a_phi	The data to which the operator is applied.

Implements TGAHelmOp< LevelData< FArrayBox > >.

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

Creat data holder a_lhs that mirrors a_rhs. You do not need to copy the data of a_rhs, just make a holder the same size.

Implements LinearOp< LevelData< FArrayBox > >.

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

Implements AMRLevelOp< LevelData< FArrayBox > >.

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

void ResistivityOp::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
	)

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

utility function which computes operator after all bc's have been set

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

Set a_lhs equal to a_rhs.

Implements LinearOp< LevelData< FArrayBox > >.

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

Compute and return the dot product of a_1 and a_2. In most contexts, this means return the sum over all data points of a_1*a_2.

Implements LinearOp< LevelData< FArrayBox > >.

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

Increment by scaled amount (a_lhs += a_scale*a_x).

Implements LinearOp< LevelData< FArrayBox > >.

virtual void ResistivityOp::axby	(	LevelData< FArrayBox > &	a_lhs,
		const LevelData< FArrayBox > &	a_x,
		const LevelData< FArrayBox > &	a_y,
		Real	a_a,
		Real	a_b
	)			[virtual]

Set input to a scaled sum (a_lhs = a_a*a_x + a_b*a_y).

Implements LinearOp< LevelData< FArrayBox > >.

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

Multiply the input by a given scale (a_lhs *= a_scale).

Implements LinearOp< LevelData< FArrayBox > >.

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

Return the norm of a_rhs. a_ord == 0 max norm, a_ord == 1 sum(abs(a_rhs)), else, L(a_ord) norm.

Implements LinearOp< LevelData< FArrayBox > >.

virtual void ResistivityOp::setToZero

(

LevelData< FArrayBox > &

a_lhs

)

[virtual]

Set a_lhs to zero.

Implements LinearOp< LevelData< FArrayBox > >.

virtual void ResistivityOp::relax	(	LevelData< FArrayBox > &	a_correction,
		const LevelData< FArrayBox > &	a_residual,
		int	a_iterations
	)			[virtual]

Use your relaxation operator to remove the high frequency wave numbers from the correction so that it may be averaged to a coarser refinement. A point relaxtion scheme, for example takes the form a_correction -= lambda*(L(a_correction) - a_residual).

Implements MGLevelOp< LevelData< FArrayBox > >.

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

Create a coarsened (by two) version of the input data. This does not include averaging the data. So if a_fine is over a Box of (0, 0, 0) (63, 63, 63), a_fine should be over a Box (0, 0, 0) (31, 31, 31).

Implements MGLevelOp< LevelData< FArrayBox > >.

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

calculate restricted residual a_resCoarse[2h] = I[h->2h] (rhsFine[h] - L[h](phiFine[h])

Implements MGLevelOp< LevelData< FArrayBox > >.

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

correct the fine solution based on coarse correction a_phiThisLevel += I[2h->h](a_correctCoarse)

Implements MGLevelOp< LevelData< FArrayBox > >.

virtual int ResistivityOp::refToCoarser

(

)

[inline, virtual]

returns 1 when there are no coarser AMRLevelOp objects

Implements AMRLevelOp< LevelData< FArrayBox > >.

References m_refToCoar.

virtual void ResistivityOp::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
	)			[virtual]

a_residual = a_rhs - L(a_phi, a_phiFine, a_phiCoarse)

Implements AMRLevelOp< LevelData< FArrayBox > >.

virtual void ResistivityOp::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
	)			[virtual]

residual assuming no more coarser AMR levels

Implements AMRLevelOp< LevelData< FArrayBox > >.

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

a_residual = a_rhs - L(a_phi, a_phiCoarse)

Implements AMRLevelOp< LevelData< FArrayBox > >.

virtual void ResistivityOp::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
	)			[virtual]

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.

Implements AMRLevelOp< LevelData< FArrayBox > >.

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

a_correction += I[h->h](a_coarseCorrection)

Implements AMRLevelOp< LevelData< FArrayBox > >.

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

a_residual = a_residual - L(a_correction, a_coarseCorrection)

Implements AMRLevelOp< LevelData< FArrayBox > >.

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

compute norm over all cells on coarse not covered by finer

Reimplemented from AMRLevelOp< LevelData< FArrayBox > >.

void ResistivityOp::homogeneousCFInterp

(

LevelData< FArrayBox > &

a_phif

)

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

does homogeneous coarse/fine interpolation for phi

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

void ResistivityOp::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
	)			[virtual]

Apply the AMR operator, including coarse-fine matching

Implements AMRLevelOp< LevelData< FArrayBox > >.

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

Apply the AMR operator, including coarse-fine matching. assume no finer AMR level

Implements AMRLevelOp< LevelData< FArrayBox > >.

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

Apply the AMR operator, including coarse-fine matching assume no coarser AMR level

Implements AMRLevelOp< LevelData< FArrayBox > >.

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

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

virtual void ResistivityOp::fillGrad

(

const LevelData< FArrayBox > &

a_phi

)

[virtual]

These functions are part of the LevelTGA interface......

Implements LevelTGAHelmOp< LevelData< FArrayBox >, FluxBox >.

void ResistivityOp::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 ResistivityOp::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
	)

void ResistivityOp::divergenceCC	(	LevelData< FArrayBox > &	a_div,
		const LevelData< FArrayBox > &	a_phi,
		const LevelData< FArrayBox > *	a_phiC
	)

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 ResistivityOp::setLambda

(

)

[protected]

Referenced by setAlphaAndBeta().

void ResistivityOp::operator=

(

const ResistivityOp &

a_opin

)

[inline, private]

References MayDay::Error().

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Member Data Documentation

RefCountedPtr<LevelData<FluxBox> > ResistivityOp::m_eta [protected]

DisjointBoxLayout ResistivityOp::m_grids [protected]

Real ResistivityOp::m_alpha [protected]

Referenced by setAlphaAndBeta().

Real ResistivityOp::m_beta [protected]

Referenced by setAlphaAndBeta().

int ResistivityOp::m_refToCoar [protected]

Referenced by refToCoarser().

int ResistivityOp::m_refToFine [protected]

BCFunc ResistivityOp::m_bc [protected]

const int ResistivityOp::s_nComp [static, protected]

const int ResistivityOp::s_nGradComp [static, protected]

Real ResistivityOp::m_dx [protected]

Real ResistivityOp::m_dxCrse [protected]

ProblemDomain ResistivityOp::m_domain [protected]

LevelData<FArrayBox> ResistivityOp::m_lambda [protected]

LevelData<FArrayBox> ResistivityOp::m_grad [protected]

LevelDataOps<FArrayBox> ResistivityOp::m_levelOps [protected]

Copier ResistivityOp::m_exchangeCopier [protected]

TensorCFInterp ResistivityOp::m_interpWithCoarser [protected]

LayoutData<CFIVS> ResistivityOp::m_loCFIVS[SpaceDim] [protected]

LayoutData<CFIVS> ResistivityOp::m_hiCFIVS[SpaceDim] [protected]

LayoutData<TensorFineStencilSet> ResistivityOp::m_hiTanStencilSets[SpaceDim] [protected]

LayoutData<TensorFineStencilSet> ResistivityOp::m_loTanStencilSets[SpaceDim] [protected]

Vector<IntVect> ResistivityOp::m_colors [protected]

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

• ResistivityOp.H