MFEM v4.7.0
Finite element discretization library
Loading...
Searching...
No Matches
mfem::GridFunctionPumi Class Reference

Class for PUMI grid functions. More...

#include <pumi.hpp>

Inheritance diagram for mfem::GridFunctionPumi:
[legend]
Collaboration diagram for mfem::GridFunctionPumi:
[legend]

Public Member Functions

 GridFunctionPumi (Mesh *m, apf::Mesh2 *PumiM, apf::Numbering *v_num_loc, const int mesh_order)
 Construct a GridFunction from a PUMI mesh.
 
virtual ~GridFunctionPumi ()
 Destroy the grid function.
 
- Public Member Functions inherited from mfem::GridFunction
 GridFunction ()
 
 GridFunction (const GridFunction &orig)
 Copy constructor. The internal true-dof vector t_vec is not copied.
 
 GridFunction (FiniteElementSpace *f)
 Construct a GridFunction associated with the FiniteElementSpace *f.
 
 GridFunction (FiniteElementSpace *f, real_t *data)
 Construct a GridFunction using previously allocated array data.
 
 GridFunction (FiniteElementSpace *f, Vector &base, int base_offset=0)
 Construct a GridFunction using previously allocated Vector base starting at the given offset, base_offset.
 
 GridFunction (Mesh *m, std::istream &input)
 Construct a GridFunction on the given Mesh, using the data from input.
 
 GridFunction (Mesh *m, GridFunction *gf_array[], int num_pieces)
 
GridFunctionoperator= (const GridFunction &rhs)
 Copy assignment. Only the data of the base class Vector is copied.
 
void MakeOwner (FiniteElementCollection *fec_)
 Make the GridFunction the owner of fec and fes.
 
FiniteElementCollectionOwnFEC ()
 
int VectorDim () const
 
int CurlDim () const
 
const VectorGetTrueVector () const
 Read only access to the (optional) internal true-dof Vector.
 
VectorGetTrueVector ()
 Read and write access to the (optional) internal true-dof Vector.
 
void GetTrueDofs (Vector &tv) const
 Extract the true-dofs from the GridFunction.
 
void SetTrueVector ()
 Shortcut for calling GetTrueDofs() with GetTrueVector() as argument.
 
virtual void SetFromTrueDofs (const Vector &tv)
 Set the GridFunction from the given true-dof vector.
 
void SetFromTrueVector ()
 Shortcut for calling SetFromTrueDofs() with GetTrueVector() as argument.
 
void GetNodalValues (int i, Array< real_t > &nval, int vdim=1) const
 Returns the values in the vertices of i'th element for dimension vdim.
 
void GetLaplacians (int i, const IntegrationRule &ir, Vector &laps, int vdim=1) const
 
void GetLaplacians (int i, const IntegrationRule &ir, Vector &laps, DenseMatrix &tr, int vdim=1) const
 
void GetHessians (int i, const IntegrationRule &ir, DenseMatrix &hess, int vdim=1) const
 
void GetHessians (int i, const IntegrationRule &ir, DenseMatrix &hess, DenseMatrix &tr, int vdim=1) const
 
void GetValuesFrom (const GridFunction &orig_func)
 
void GetBdrValuesFrom (const GridFunction &orig_func)
 
void GetVectorFieldValues (int i, const IntegrationRule &ir, DenseMatrix &vals, DenseMatrix &tr, int comp=0) const
 
void ReorderByNodes ()
 For a vector grid function, makes sure that the ordering is byNODES.
 
void GetNodalValues (Vector &nval, int vdim=1) const
 Return the values as a vector on mesh vertices for dimension vdim.
 
void GetVectorFieldNodalValues (Vector &val, int comp) const
 
void ProjectVectorFieldOn (GridFunction &vec_field, int comp=0)
 
void GetDerivative (int comp, int der_comp, GridFunction &der)
 Compute a certain derivative of a function's component. Derivatives of the function are computed at the DOF locations of der, and averaged over overlapping DOFs. Thus this function projects the derivative to the FiniteElementSpace of der.
 
real_t GetDivergence (ElementTransformation &tr) const
 
void GetCurl (ElementTransformation &tr, Vector &curl) const
 
void GetGradient (ElementTransformation &tr, Vector &grad) const
 Gradient of a scalar function at a quadrature point.
 
void GetGradients (ElementTransformation &tr, const IntegrationRule &ir, DenseMatrix &grad) const
 Extension of GetGradient(...) for a collection of IntegrationPoints.
 
void GetGradients (const int elem, const IntegrationRule &ir, DenseMatrix &grad) const
 Extension of GetGradient(...) for a collection of IntegrationPoints.
 
void GetVectorGradient (ElementTransformation &tr, DenseMatrix &grad) const
 Compute the vector gradient with respect to the physical element variable.
 
void GetVectorGradientHat (ElementTransformation &T, DenseMatrix &gh) const
 Compute the vector gradient with respect to the reference element variable.
 
void GetElementAverages (GridFunction &avgs) const
 
virtual void GetElementDofValues (int el, Vector &dof_vals) const
 
void ImposeBounds (int i, const Vector &weights, const Vector &lo_, const Vector &hi_)
 
void ImposeBounds (int i, const Vector &weights, real_t min_=0.0, real_t max_=infinity())
 
void RestrictConforming ()
 
void ProjectGridFunction (const GridFunction &src)
 Project the src GridFunction to this GridFunction, both of which must be on the same mesh.
 
virtual void ProjectCoefficient (Coefficient &coeff)
 Project coeff Coefficient to this GridFunction. The projection computation depends on the choice of the FiniteElementSpace fes. Note that this is usually interpolation at the degrees of freedom in each element (not L2 projection).
 
void ProjectCoefficient (Coefficient &coeff, Array< int > &dofs, int vd=0)
 Project coeff Coefficient to this GridFunction, using one element for each degree of freedom in dofs and nodal interpolation on that element.
 
void ProjectCoefficient (VectorCoefficient &vcoeff)
 Project vcoeff VectorCoefficient to this GridFunction. The projection computation depends on the choice of the FiniteElementSpace fes. Note that this is usually interpolation at the degrees of freedom in each element (not L2 projection).
 
void ProjectCoefficient (VectorCoefficient &vcoeff, Array< int > &dofs)
 Project vcoeff VectorCoefficient to this GridFunction, using one element for each degree of freedom in dofs and nodal interpolation on that element.
 
void ProjectCoefficient (VectorCoefficient &vcoeff, int attribute)
 Project vcoeff VectorCoefficient to this GridFunction, only projecting onto elements with the given attribute.
 
void ProjectCoefficient (Coefficient *coeff[])
 Analogous to the version with argument vcoeff VectorCoefficient but using an array of scalar coefficients for each component.
 
virtual void ProjectDiscCoefficient (VectorCoefficient &coeff)
 Project a discontinuous vector coefficient as a grid function on a continuous finite element space. The values in shared dofs are determined from the element with maximal attribute.
 
virtual void ProjectDiscCoefficient (Coefficient &coeff, AvgType type)
 Projects a discontinuous coefficient so that the values in shared vdofs are computed by taking an average of the possible values.
 
virtual void ProjectDiscCoefficient (VectorCoefficient &coeff, AvgType type)
 Projects a discontinuous vector coefficient so that the values in shared vdofs are computed by taking an average of the possible values.
 
virtual void CountElementsPerVDof (Array< int > &elem_per_vdof) const
 For each vdof, counts how many elements contain the vdof, as containment is determined by FiniteElementSpace::GetElementVDofs().
 
void ProjectBdrCoefficient (Coefficient &coeff, const Array< int > &attr)
 Project a Coefficient on the GridFunction, modifying only DOFs on the boundary associated with the boundary attributes marked in the attr array.
 
virtual void ProjectBdrCoefficient (VectorCoefficient &vcoeff, const Array< int > &attr)
 Project a VectorCoefficient on the GridFunction, modifying only DOFs on the boundary associated with the boundary attributes marked in the attr array.
 
virtual void ProjectBdrCoefficient (Coefficient *coeff[], const Array< int > &attr)
 Project a set of Coefficients on the components of the GridFunction, modifying only DOFs on the boundary associated with the boundary attributed marked in the attr array.
 
void ProjectBdrCoefficientNormal (VectorCoefficient &vcoeff, const Array< int > &bdr_attr)
 
virtual void ProjectBdrCoefficientTangent (VectorCoefficient &vcoeff, const Array< int > &bdr_attr)
 Project the tangential components of the given VectorCoefficient on the boundary. Only boundary attributes that are marked in bdr_attr are projected. Assumes ND-type VectorFE GridFunction.
 
virtual real_t ComputeL2Error (Coefficient *exsol[], const IntegrationRule *irs[]=NULL, const Array< int > *elems=NULL) const
 
virtual real_t ComputeElementGradError (int ielem, VectorCoefficient *exgrad, const IntegrationRule *irs[]=NULL) const
 Returns ||grad u_ex - grad u_h||_L2 in element ielem for H1 or L2 elements.
 
virtual real_t ComputeL2Error (Coefficient &exsol, const IntegrationRule *irs[]=NULL, const Array< int > *elems=NULL) const
 Returns ||u_ex - u_h||_L2 for H1 or L2 elements.
 
virtual real_t ComputeL2Error (VectorCoefficient &exsol, const IntegrationRule *irs[]=NULL, const Array< int > *elems=NULL) const
 
virtual real_t ComputeGradError (VectorCoefficient *exgrad, const IntegrationRule *irs[]=NULL) const
 Returns ||grad u_ex - grad u_h||_L2 for H1 or L2 elements.
 
virtual real_t ComputeCurlError (VectorCoefficient *excurl, const IntegrationRule *irs[]=NULL) const
 Returns ||curl u_ex - curl u_h||_L2 for ND elements.
 
virtual real_t ComputeDivError (Coefficient *exdiv, const IntegrationRule *irs[]=NULL) const
 Returns ||div u_ex - div u_h||_L2 for RT elements.
 
virtual real_t ComputeDGFaceJumpError (Coefficient *exsol, Coefficient *ell_coeff, class JumpScaling jump_scaling, const IntegrationRule *irs[]=NULL) const
 
MFEM_DEPRECATED real_t ComputeDGFaceJumpError (Coefficient *exsol, Coefficient *ell_coeff, real_t Nu, const IntegrationRule *irs[]=NULL) const
 Returns the Face Jumps error for L2 elements, with 1/h scaling.
 
virtual real_t ComputeH1Error (Coefficient *exsol, VectorCoefficient *exgrad, Coefficient *ell_coef, real_t Nu, int norm_type) const
 
virtual real_t ComputeH1Error (Coefficient *exsol, VectorCoefficient *exgrad, const IntegrationRule *irs[]=NULL) const
 
virtual real_t ComputeHDivError (VectorCoefficient *exsol, Coefficient *exdiv, const IntegrationRule *irs[]=NULL) const
 Returns the error measured in H(div)-norm for RT elements.
 
virtual real_t ComputeHCurlError (VectorCoefficient *exsol, VectorCoefficient *excurl, const IntegrationRule *irs[]=NULL) const
 Returns the error measured in H(curl)-norm for ND elements.
 
virtual real_t ComputeMaxError (Coefficient &exsol, const IntegrationRule *irs[]=NULL) const
 
virtual real_t ComputeMaxError (Coefficient *exsol[], const IntegrationRule *irs[]=NULL) const
 
virtual real_t ComputeMaxError (VectorCoefficient &exsol, const IntegrationRule *irs[]=NULL) const
 
virtual real_t ComputeL1Error (Coefficient *exsol[], const IntegrationRule *irs[]=NULL) const
 
virtual real_t ComputeL1Error (Coefficient &exsol, const IntegrationRule *irs[]=NULL) const
 
virtual real_t ComputeW11Error (Coefficient *exsol, VectorCoefficient *exgrad, int norm_type, const Array< int > *elems=NULL, const IntegrationRule *irs[]=NULL) const
 
virtual real_t ComputeL1Error (VectorCoefficient &exsol, const IntegrationRule *irs[]=NULL) const
 
virtual real_t ComputeLpError (const real_t p, Coefficient &exsol, Coefficient *weight=NULL, const IntegrationRule *irs[]=NULL, const Array< int > *elems=NULL) const
 
virtual void ComputeElementLpErrors (const real_t p, Coefficient &exsol, Vector &error, Coefficient *weight=NULL, const IntegrationRule *irs[]=NULL) const
 
virtual void ComputeElementL1Errors (Coefficient &exsol, Vector &error, const IntegrationRule *irs[]=NULL) const
 
virtual void ComputeElementL2Errors (Coefficient &exsol, Vector &error, const IntegrationRule *irs[]=NULL) const
 
virtual void ComputeElementMaxErrors (Coefficient &exsol, Vector &error, const IntegrationRule *irs[]=NULL) const
 
virtual real_t ComputeLpError (const real_t p, VectorCoefficient &exsol, Coefficient *weight=NULL, VectorCoefficient *v_weight=NULL, const IntegrationRule *irs[]=NULL) const
 
virtual void ComputeElementLpErrors (const real_t p, VectorCoefficient &exsol, Vector &error, Coefficient *weight=NULL, VectorCoefficient *v_weight=NULL, const IntegrationRule *irs[]=NULL) const
 
virtual void ComputeElementL1Errors (VectorCoefficient &exsol, Vector &error, const IntegrationRule *irs[]=NULL) const
 
virtual void ComputeElementL2Errors (VectorCoefficient &exsol, Vector &error, const IntegrationRule *irs[]=NULL) const
 
virtual void ComputeElementMaxErrors (VectorCoefficient &exsol, Vector &error, const IntegrationRule *irs[]=NULL) const
 
virtual void ComputeFlux (BilinearFormIntegrator &blfi, GridFunction &flux, bool wcoef=true, int subdomain=-1)
 
GridFunctionoperator= (real_t value)
 Redefine '=' for GridFunction = constant.
 
GridFunctionoperator= (const Vector &v)
 Copy the data from v.
 
virtual void Update ()
 Transform by the Space UpdateMatrix (e.g., on Mesh change).
 
long GetSequence () const
 
FiniteElementSpaceFESpace ()
 
const FiniteElementSpaceFESpace () const
 
virtual void SetSpace (FiniteElementSpace *f)
 Associate a new FiniteElementSpace with the GridFunction.
 
virtual void MakeRef (FiniteElementSpace *f, real_t *v)
 Make the GridFunction reference external data on a new FiniteElementSpace.
 
virtual void MakeRef (FiniteElementSpace *f, Vector &v, int v_offset)
 Make the GridFunction reference external data on a new FiniteElementSpace.
 
void MakeTRef (FiniteElementSpace *f, real_t *tv)
 Associate a new FiniteElementSpace and new true-dof data with the GridFunction.
 
void MakeTRef (FiniteElementSpace *f, Vector &tv, int tv_offset)
 Associate a new FiniteElementSpace and new true-dof data with the GridFunction.
 
virtual void Save (std::ostream &out) const
 Save the GridFunction to an output stream.
 
virtual void Save (const char *fname, int precision=16) const
 
virtual void Save (adios2stream &out, const std::string &variable_name, const adios2stream::data_type type=adios2stream::data_type::point_data) const
 Save the GridFunction to a binary output stream using adios2 bp format.
 
void SaveVTK (std::ostream &out, const std::string &field_name, int ref)
 Write the GridFunction in VTK format. Note that Mesh::PrintVTK must be called first. The parameter ref > 0 must match the one used in Mesh::PrintVTK.
 
void SaveSTL (std::ostream &out, int TimesToRefine=1)
 Write the GridFunction in STL format. Note that the mesh dimension must be 2 and that quad elements will be broken into two triangles.
 
virtual ~GridFunction ()
 Destroys grid function.
 
void MakeRef (Vector &base, int offset, int size)
 Reset the Vector to be a reference to a sub-vector of base.
 
void MakeRef (Vector &base, int offset)
 Reset the Vector to be a reference to a sub-vector of base without changing its current size.
 
virtual real_t GetValue (int i, const IntegrationPoint &ip, int vdim=1) const
 
virtual void GetVectorValue (int i, const IntegrationPoint &ip, Vector &val) const
 
void GetValues (int i, const IntegrationRule &ir, Vector &vals, int vdim=1) const
 
void GetValues (int i, const IntegrationRule &ir, Vector &vals, DenseMatrix &tr, int vdim=1) const
 
void GetVectorValues (int i, const IntegrationRule &ir, DenseMatrix &vals, DenseMatrix &tr) const
 
virtual real_t GetValue (ElementTransformation &T, const IntegrationPoint &ip, int comp=0, Vector *tr=NULL) const
 
virtual void GetVectorValue (ElementTransformation &T, const IntegrationPoint &ip, Vector &val, Vector *tr=NULL) const
 
void GetValues (ElementTransformation &T, const IntegrationRule &ir, Vector &vals, int comp=0, DenseMatrix *tr=NULL) const
 
void GetVectorValues (ElementTransformation &T, const IntegrationRule &ir, DenseMatrix &vals, DenseMatrix *tr=NULL) const
 
int GetFaceValues (int i, int side, const IntegrationRule &ir, Vector &vals, DenseMatrix &tr, int vdim=1) const
 
int GetFaceVectorValues (int i, int side, const IntegrationRule &ir, DenseMatrix &vals, DenseMatrix &tr) const
 
- Public Member Functions inherited from mfem::Vector
 Vector ()
 
 Vector (const Vector &)
 Copy constructor. Allocates a new data array and copies the data.
 
 Vector (Vector &&v)
 Move constructor. "Steals" data from its argument.
 
 Vector (int s)
 Creates vector of size s.
 
 Vector (real_t *data_, int size_)
 Creates a vector referencing an array of doubles, owned by someone else.
 
 Vector (Vector &base, int base_offset, int size_)
 Create a Vector referencing a sub-vector of the Vector base starting at the given offset, base_offset, and size size_.
 
 Vector (int size_, MemoryType mt)
 Create a Vector of size size_ using MemoryType mt.
 
 Vector (int size_, MemoryType h_mt, MemoryType d_mt)
 Create a Vector of size size_ using host MemoryType h_mt and device MemoryType d_mt.
 
template<int N, typename T = real_t>
 Vector (const T(&values)[N])
 Create a vector using a braced initializer list.
 
virtual void UseDevice (bool use_dev) const
 Enable execution of Vector operations using the mfem::Device.
 
virtual bool UseDevice () const
 Return the device flag of the Memory object used by the Vector.
 
void Load (std::istream **in, int np, int *dim)
 Reads a vector from multiple files.
 
void Load (std::istream &in, int Size)
 Load a vector from an input stream.
 
void Load (std::istream &in)
 Load a vector from an input stream, reading the size from the stream.
 
void SetSize (int s)
 Resize the vector to size s.
 
void SetSize (int s, MemoryType mt)
 Resize the vector to size s using MemoryType mt.
 
void SetSize (int s, const Vector &v)
 Resize the vector to size s using the MemoryType of v.
 
void SetData (real_t *d)
 
void SetDataAndSize (real_t *d, int s)
 Set the Vector data and size.
 
void NewDataAndSize (real_t *d, int s)
 Set the Vector data and size, deleting the old data, if owned.
 
void NewMemoryAndSize (const Memory< real_t > &mem, int s, bool own_mem)
 Reset the Vector to use the given external Memory mem and size s.
 
void MakeRef (Vector &base, int offset, int size)
 Reset the Vector to be a reference to a sub-vector of base.
 
void MakeRef (Vector &base, int offset)
 Reset the Vector to be a reference to a sub-vector of base without changing its current size.
 
void MakeDataOwner () const
 Set the Vector data (host pointer) ownership flag.
 
void Destroy ()
 Destroy a vector.
 
void DeleteDevice (bool copy_to_host=true)
 Delete the device pointer, if owned. If copy_to_host is true and the data is valid only on device, move it to host before deleting. Invalidates the device memory.
 
int Size () const
 Returns the size of the vector.
 
int Capacity () const
 Return the size of the currently allocated data array.
 
real_tGetData () const
 Return a pointer to the beginning of the Vector data.
 
MFEM_DEPRECATED operator real_t * ()
 Conversion to double *. Deprecated.
 
MFEM_DEPRECATED operator const real_t * () const
 Conversion to const double *. Deprecated.
 
real_tbegin ()
 STL-like begin.
 
real_tend ()
 STL-like end.
 
const real_tbegin () const
 STL-like begin (const version).
 
const real_tend () const
 STL-like end (const version).
 
Memory< real_t > & GetMemory ()
 Return a reference to the Memory object used by the Vector.
 
const Memory< real_t > & GetMemory () const
 Return a reference to the Memory object used by the Vector, const version.
 
void SyncMemory (const Vector &v) const
 Update the memory location of the vector to match v.
 
void SyncAliasMemory (const Vector &v) const
 Update the alias memory location of the vector to match v.
 
bool OwnsData () const
 Read the Vector data (host pointer) ownership flag.
 
void StealData (real_t **p)
 Changes the ownership of the data; after the call the Vector is empty.
 
real_tStealData ()
 Changes the ownership of the data; after the call the Vector is empty.
 
real_tElem (int i)
 Access Vector entries. Index i = 0 .. size-1.
 
const real_tElem (int i) const
 Read only access to Vector entries. Index i = 0 .. size-1.
 
real_toperator() (int i)
 Access Vector entries using () for 0-based indexing.
 
const real_toperator() (int i) const
 Read only access to Vector entries using () for 0-based indexing.
 
real_toperator[] (int i)
 Access Vector entries using [] for 0-based indexing.
 
const real_toperator[] (int i) const
 Read only access to Vector entries using [] for 0-based indexing.
 
real_t operator* (const real_t *) const
 Dot product with a double * array.
 
real_t operator* (const Vector &v) const
 Return the inner-product.
 
Vectoroperator= (const real_t *v)
 Copy Size() entries from v.
 
Vectoroperator= (const Vector &v)
 Copy assignment.
 
Vectoroperator= (Vector &&v)
 Move assignment.
 
Vectoroperator= (real_t value)
 Redefine '=' for vector = constant.
 
Vectoroperator*= (real_t c)
 
Vectoroperator*= (const Vector &v)
 Component-wise scaling: (*this)(i) *= v(i)
 
Vectoroperator/= (real_t c)
 
Vectoroperator/= (const Vector &v)
 Component-wise division: (*this)(i) /= v(i)
 
Vectoroperator-= (real_t c)
 
Vectoroperator-= (const Vector &v)
 
Vectoroperator+= (real_t c)
 
Vectoroperator+= (const Vector &v)
 
VectorAdd (const real_t a, const Vector &Va)
 (*this) += a * Va
 
VectorSet (const real_t a, const Vector &x)
 (*this) = a * x
 
void SetVector (const Vector &v, int offset)
 
void AddSubVector (const Vector &v, int offset)
 
void Neg ()
 (*this) = -(*this)
 
void Reciprocal ()
 (*this)(i) = 1.0 / (*this)(i)
 
void Swap (Vector &other)
 Swap the contents of two Vectors.
 
void cross3D (const Vector &vin, Vector &vout) const
 
void median (const Vector &lo, const Vector &hi)
 v = median(v,lo,hi) entrywise. Implementation assumes lo <= hi.
 
void GetSubVector (const Array< int > &dofs, Vector &elemvect) const
 Extract entries listed in dofs to the output Vector elemvect.
 
void GetSubVector (const Array< int > &dofs, real_t *elem_data) const
 Extract entries listed in dofs to the output array elem_data.
 
void SetSubVector (const Array< int > &dofs, const real_t value)
 Set the entries listed in dofs to the given value.
 
void SetSubVector (const Array< int > &dofs, const Vector &elemvect)
 Set the entries listed in dofs to the values given in the elemvect Vector. Negative dof values cause the -dof-1 position in this Vector to receive the -val from elemvect.
 
void SetSubVector (const Array< int > &dofs, real_t *elem_data)
 Set the entries listed in dofs to the values given the , elem_data array. Negative dof values cause the -dof-1 position in this Vector to receive the -val from elem_data.
 
void AddElementVector (const Array< int > &dofs, const Vector &elemvect)
 Add elements of the elemvect Vector to the entries listed in dofs. Negative dof values cause the -dof-1 position in this Vector to add the -val from elemvect.
 
void AddElementVector (const Array< int > &dofs, real_t *elem_data)
 Add elements of the elem_data array to the entries listed in dofs. Negative dof values cause the -dof-1 position in this Vector to add the -val from elem_data.
 
void AddElementVector (const Array< int > &dofs, const real_t a, const Vector &elemvect)
 Add times the elements of the elemvect Vector to the entries listed in dofs. Negative dof values cause the -dof-1 position in this Vector to add the -a*val from elemvect.
 
void SetSubVectorComplement (const Array< int > &dofs, const real_t val)
 Set all vector entries NOT in the dofs Array to the given val.
 
void Print (std::ostream &out=mfem::out, int width=8) const
 Prints vector to stream out.
 
void Print (adios2stream &out, const std::string &variable_name) const
 
void Print_HYPRE (std::ostream &out) const
 Prints vector to stream out in HYPRE_Vector format.
 
void PrintHash (std::ostream &out) const
 Print the Vector size and hash of its data.
 
void Randomize (int seed=0)
 Set random values in the vector.
 
real_t Norml2 () const
 Returns the l2 norm of the vector.
 
real_t Normlinf () const
 Returns the l_infinity norm of the vector.
 
real_t Norml1 () const
 Returns the l_1 norm of the vector.
 
real_t Normlp (real_t p) const
 Returns the l_p norm of the vector.
 
real_t Max () const
 Returns the maximal element of the vector.
 
real_t Min () const
 Returns the minimal element of the vector.
 
real_t Sum () const
 Return the sum of the vector entries.
 
real_t DistanceSquaredTo (const real_t *p) const
 Compute the square of the Euclidean distance to another vector.
 
real_t DistanceSquaredTo (const Vector &p) const
 Compute the square of the Euclidean distance to another vector.
 
real_t DistanceTo (const real_t *p) const
 Compute the Euclidean distance to another vector.
 
real_t DistanceTo (const Vector &p) const
 Compute the Euclidean distance to another vector.
 
int CheckFinite () const
 Count the number of entries in the Vector for which isfinite is false, i.e. the entry is a NaN or +/-Inf.
 
virtual ~Vector ()
 Destroys vector.
 
virtual const real_tRead (bool on_dev=true) const
 Shortcut for mfem::Read(vec.GetMemory(), vec.Size(), on_dev).
 
virtual const real_tHostRead () const
 Shortcut for mfem::Read(vec.GetMemory(), vec.Size(), false).
 
virtual real_tWrite (bool on_dev=true)
 Shortcut for mfem::Write(vec.GetMemory(), vec.Size(), on_dev).
 
virtual real_tHostWrite ()
 Shortcut for mfem::Write(vec.GetMemory(), vec.Size(), false).
 
virtual real_tReadWrite (bool on_dev=true)
 Shortcut for mfem::ReadWrite(vec.GetMemory(), vec.Size(), on_dev).
 
virtual real_tHostReadWrite ()
 Shortcut for mfem::ReadWrite(vec.GetMemory(), vec.Size(), false).
 

Additional Inherited Members

- Public Types inherited from mfem::GridFunction
enum  AvgType { ARITHMETIC , HARMONIC }
 
- Protected Member Functions inherited from mfem::GridFunction
void SaveSTLTri (std::ostream &out, real_t p1[], real_t p2[], real_t p3[])
 
void ProjectDeltaCoefficient (DeltaCoefficient &delta_coeff, real_t &integral)
 
void SumFluxAndCount (BilinearFormIntegrator &blfi, GridFunction &flux, Array< int > &counts, bool wcoef, int subdomain)
 
void ProjectDiscCoefficient (VectorCoefficient &coeff, Array< int > &dof_attr)
 
void LegacyNCReorder ()
 Loading helper.
 
void Destroy ()
 
void AccumulateAndCountZones (Coefficient &coeff, AvgType type, Array< int > &zones_per_vdof)
 Accumulates (depending on type) the values of coeff at all shared vdofs and counts in how many zones each vdof appears.
 
void AccumulateAndCountZones (VectorCoefficient &vcoeff, AvgType type, Array< int > &zones_per_vdof)
 Accumulates (depending on type) the values of vcoeff at all shared vdofs and counts in how many zones each vdof appears.
 
void AccumulateAndCountDerivativeValues (int comp, int der_comp, GridFunction &der, Array< int > &zones_per_dof)
 Used for the serial and parallel implementations of the GetDerivative() method; see its documentation.
 
void AccumulateAndCountBdrValues (Coefficient *coeff[], VectorCoefficient *vcoeff, const Array< int > &attr, Array< int > &values_counter)
 
void AccumulateAndCountBdrTangentValues (VectorCoefficient &vcoeff, const Array< int > &bdr_attr, Array< int > &values_counter)
 
void ComputeMeans (AvgType type, Array< int > &zones_per_vdof)
 
- Protected Attributes inherited from mfem::GridFunction
FiniteElementSpacefes
 FE space on which the grid function lives. Owned if fec is not NULL.
 
FiniteElementCollectionfec
 Used when the grid function is read from a file. It can also be set explicitly, see MakeOwner().
 
long fes_sequence
 
Vector t_vec
 
- Protected Attributes inherited from mfem::Vector
Memory< real_tdata
 
int size
 

Detailed Description

Class for PUMI grid functions.

Definition at line 151 of file pumi.hpp.

Constructor & Destructor Documentation

◆ GridFunctionPumi()

mfem::GridFunctionPumi::GridFunctionPumi ( Mesh * m,
apf::Mesh2 * PumiM,
apf::Numbering * v_num_loc,
const int mesh_order )

Construct a GridFunction from a PUMI mesh.

Definition at line 887 of file pumi.cpp.

◆ ~GridFunctionPumi()

virtual mfem::GridFunctionPumi::~GridFunctionPumi ( )
inlinevirtual

Destroy the grid function.

Definition at line 159 of file pumi.hpp.


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