/usr/include/ufc.h is in python-ffc 1.6.0-2.
This file is owned by root:root, with mode 0o644.
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// This code is released into the public domain.
//
// The FEniCS Project (http://www.fenicsproject.org/) 2006-2015.
#ifndef __UFC_H
#define __UFC_H
#define UFC_VERSION_MAJOR 1
#define UFC_VERSION_MINOR 6
#define UFC_VERSION_MAINTENANCE 0
#define UFC_VERSION_RELEASE 1
#include <vector>
#include <cstddef>
#include <stdexcept>
#include <ufc_geometry.h>
#define CONCAT(a,b,c) #a "." #b "." #c
#define EVALUATOR(a,b,c) CONCAT(a,b,c)
#if UFC_VERSION_RELEASE
const char UFC_VERSION[] = EVALUATOR(UFC_VERSION_MAJOR, UFC_VERSION_MINOR, UFC_VERSION_MAINTENANCE);
#else
const char UFC_VERSION[] = EVALUATOR(UFC_VERSION_MAJOR, UFC_VERSION_MINOR, UFC_VERSION_MAINTENANCE) "dev";
#endif
#undef CONCAT
#undef EVALUATOR
namespace ufc
{
/// Valid cell shapes
enum shape {interval, triangle, quadrilateral, tetrahedron, hexahedron};
/// This class defines the data structure for a cell in a mesh.
class cell
{
public:
/// Constructor
cell(): cell_shape(interval),
topological_dimension(0), geometric_dimension(0),
index(0), local_facet(-1), mesh_identifier(-1) {}
/// Destructor
virtual ~cell() {}
/// Shape of the cell
shape cell_shape;
/// Topological dimension of the mesh
std::size_t topological_dimension;
/// Geometric dimension of the mesh
std::size_t geometric_dimension;
/// Array of global indices for the mesh entities of the cell
std::vector<std::vector<std::size_t> > entity_indices;
/// Cell index (short-cut for entity_indices[topological_dimension][0])
std::size_t index;
/// Local facet index
int local_facet;
/// Cell orientation
int orientation;
/// Unique mesh identifier
int mesh_identifier;
};
/// This class defines the interface for a general tensor-valued function.
class function
{
public:
/// Destructor
virtual ~function() {}
/// Evaluate function at given point in cell
virtual void evaluate(double* values,
const double* coordinates,
const cell& c) const = 0;
};
/// This class defines the interface for a finite element.
class finite_element
{
public:
/// Destructor
virtual ~finite_element() {}
/// Return a string identifying the finite element
virtual const char* signature() const = 0;
/// Return the cell shape
virtual shape cell_shape() const = 0;
/// Return the topological dimension of the cell shape
virtual std::size_t topological_dimension() const = 0;
/// Return the geometric dimension of the cell shape
virtual std::size_t geometric_dimension() const = 0;
/// Return the dimension of the finite element function space
virtual std::size_t space_dimension() const = 0;
/// Return the rank of the value space
virtual std::size_t value_rank() const = 0;
/// Return the dimension of the value space for axis i
virtual std::size_t value_dimension(std::size_t i) const = 0;
/// Evaluate basis function i at given point x in cell
virtual void evaluate_basis(std::size_t i,
double* values,
const double* x,
const double* vertex_coordinates,
int cell_orientation) const = 0;
/// Evaluate all basis functions at given point x in cell
virtual void evaluate_basis_all(double* values,
const double* x,
const double* vertex_coordinates,
int cell_orientation) const = 0;
/// Evaluate order n derivatives of basis function i at given point x in cell
virtual void evaluate_basis_derivatives(std::size_t i,
std::size_t n,
double* values,
const double* x,
const double* vertex_coordinates,
int cell_orientation) const = 0;
/// Evaluate order n derivatives of all basis functions at given point x in cell
virtual void evaluate_basis_derivatives_all(std::size_t n,
double* values,
const double* x,
const double* vertex_coordinates,
int cell_orientation) const = 0;
// FIXME: cell argument only included here so we can pass it to the eval function...
/// Evaluate linear functional for dof i on the function f
virtual double evaluate_dof(std::size_t i,
const function& f,
const double* vertex_coordinates,
int cell_orientation,
const cell& c) const = 0;
/// Evaluate linear functionals for all dofs on the function f
virtual void evaluate_dofs(double* values,
const function& f,
const double* vertex_coordinates,
int cell_orientation,
const cell& c) const = 0;
/// Interpolate vertex values from dof values
virtual void interpolate_vertex_values(double* vertex_values,
const double* dof_values,
const double* vertex_coordinates,
int cell_orientation,
const cell& c) const = 0;
/// Map coordinate xhat from reference cell to coordinate x in cell
virtual void map_from_reference_cell(double* x,
const double* xhat,
const cell& c) const = 0;
/// Map from coordinate x in cell to coordinate xhat in reference cell
virtual void map_to_reference_cell(double* xhat,
const double* x,
const cell& c) const = 0;
/// Return the number of sub elements (for a mixed element)
virtual std::size_t num_sub_elements() const = 0;
/// Create a new finite element for sub element i (for a mixed element)
virtual finite_element* create_sub_element(std::size_t i) const = 0;
/// Create a new class instance
virtual finite_element* create() const = 0;
};
/// This class defines the interface for a local-to-global mapping of
/// degrees of freedom (dofs).
class dofmap
{
public:
/// Destructor
virtual ~dofmap() {}
/// Return a string identifying the dofmap
virtual const char* signature() const = 0;
/// Return true iff mesh entities of topological dimension d are
/// needed
virtual bool needs_mesh_entities(std::size_t d) const = 0;
/// Return the topological dimension of the associated cell shape
virtual std::size_t topological_dimension() const = 0;
/// Return the geometric dimension of the associated cell shape
virtual std::size_t geometric_dimension() const = 0;
/// Return the dimension of the global finite element function space
virtual std::size_t global_dimension(const std::vector<std::size_t>&
num_global_mesh_entities) const = 0;
/// Return the dimension of the local finite element function space
/// for a cell
virtual std::size_t num_element_dofs() const = 0;
/// Return the number of dofs on each cell facet
virtual std::size_t num_facet_dofs() const = 0;
/// Return the number of dofs associated with each cell entity of
/// dimension d
virtual std::size_t num_entity_dofs(std::size_t d) const = 0;
/// Tabulate the local-to-global mapping of dofs on a cell
virtual void tabulate_dofs(std::size_t* dofs,
const std::vector<std::size_t>& num_global_entities,
const cell& c) const = 0;
/// Tabulate the local-to-local mapping from facet dofs to cell dofs
virtual void tabulate_facet_dofs(std::size_t* dofs,
std::size_t facet) const = 0;
/// Tabulate the local-to-local mapping of dofs on entity (d, i)
virtual void tabulate_entity_dofs(std::size_t* dofs,
std::size_t d, std::size_t i) const = 0;
/// Tabulate the coordinates of all dofs on a cell
virtual void tabulate_coordinates(double* dof_coordinates,
const double* vertex_coordinates) const = 0;
/// Return the number of sub dofmaps (for a mixed element)
virtual std::size_t num_sub_dofmaps() const = 0;
/// Create a new dofmap for sub dofmap i (for a mixed element)
virtual dofmap* create_sub_dofmap(std::size_t i) const = 0;
/// Create a new class instance
virtual dofmap* create() const = 0;
};
/// This class defines the shared interface for classes implementing
/// the tabulation of a tensor corresponding to the local contribution
/// to a form from an integral.
class integral
{
public:
/// Destructor
virtual ~integral() {}
/// Tabulate which form coefficients are used by this integral
virtual const std::vector<bool> & enabled_coefficients() const = 0;
};
/// This class defines the interface for the tabulation of the cell
/// tensor corresponding to the local contribution to a form from
/// the integral over a cell.
class cell_integral: public integral
{
public:
/// Destructor
virtual ~cell_integral() {}
/// Tabulate the tensor for the contribution from a local cell
virtual void tabulate_tensor(double* A,
const double * const * w,
const double* vertex_coordinates,
int cell_orientation) const = 0;
};
/// This class defines the interface for the tabulation of the
/// exterior facet tensor corresponding to the local contribution to
/// a form from the integral over an exterior facet.
class exterior_facet_integral: public integral
{
public:
/// Destructor
virtual ~exterior_facet_integral() {}
/// Tabulate the tensor for the contribution from a local exterior facet
virtual void tabulate_tensor(double* A,
const double * const * w,
const double* vertex_coordinates,
std::size_t facet,
int cell_orientation) const = 0;
};
/// This class defines the interface for the tabulation of the
/// interior facet tensor corresponding to the local contribution to
/// a form from the integral over an interior facet.
class interior_facet_integral: public integral
{
public:
/// Destructor
virtual ~interior_facet_integral() {}
/// Tabulate the tensor for the contribution from a local interior facet
virtual void tabulate_tensor(double* A,
const double * const * w,
const double* vertex_coordinates_0,
const double* vertex_coordinates_1,
std::size_t facet_0,
std::size_t facet_1,
int cell_orientation_0,
int cell_orientation_1) const = 0;
};
/// This class defines the interface for the tabulation of
/// an expression evaluated at exactly one point.
class vertex_integral: public integral
{
public:
/// Constructor
vertex_integral() {}
/// Destructor
virtual ~vertex_integral() {}
/// Tabulate the tensor for the contribution from the local vertex
virtual void tabulate_tensor(double* A,
const double * const * w,
const double* vertex_coordinates,
std::size_t vertex,
int cell_orientation) const = 0;
};
/// This class defines the interface for the tabulation of the
/// tensor corresponding to the local contribution to a form from
/// the integral over a custom domain defined in terms of a set of
/// quadrature points and weights.
class custom_integral: public integral
{
public:
/// Constructor
custom_integral() {}
/// Destructor
virtual ~custom_integral() {};
/// Return the number of cells involved in evaluation of the integral
virtual std::size_t num_cells() const = 0;
/// Tabulate the tensor for the contribution from a custom domain
virtual void tabulate_tensor(double* A,
const double * const * w,
const double* vertex_coordinates,
std::size_t num_quadrature_points,
const double* quadrature_points,
const double* quadrature_weights,
const double* facet_normals,
int cell_orientation) const = 0;
};
/// This class defines the interface for the assembly of the global
/// tensor corresponding to a form with r + n arguments, that is, a
/// mapping
///
/// a : V1 x V2 x ... Vr x W1 x W2 x ... x Wn -> R
///
/// with arguments v1, v2, ..., vr, w1, w2, ..., wn. The rank r
/// global tensor A is defined by
///
/// A = a(V1, V2, ..., Vr, w1, w2, ..., wn),
///
/// where each argument Vj represents the application to the
/// sequence of basis functions of Vj and w1, w2, ..., wn are given
/// fixed functions (coefficients).
class form
{
public:
/// Destructor
virtual ~form() {}
/// Return a string identifying the form
virtual const char* signature() const = 0;
/// Return the rank of the global tensor (r)
virtual std::size_t rank() const = 0;
/// Return the number of coefficients (n)
virtual std::size_t num_coefficients() const = 0;
/// Return original coefficient position for each coefficient (0 <= i < n)
virtual std::size_t original_coefficient_position(std::size_t i) const = 0;
/// Create a new finite element for argument function 0 <= i < r+n
virtual finite_element* create_finite_element(std::size_t i) const = 0;
/// Create a new dofmap for argument function 0 <= i < r+n
virtual dofmap* create_dofmap(std::size_t i) const = 0;
/// Return the upper bound on subdomain ids for cell integrals
virtual std::size_t max_cell_subdomain_id() const = 0;
/// Return the upper bound on subdomain ids for exterior facet integrals
virtual std::size_t max_exterior_facet_subdomain_id() const = 0;
/// Return the upper bound on subdomain ids for interior facet integrals
virtual std::size_t max_interior_facet_subdomain_id() const = 0;
/// Return the upper bound on subdomain ids for vertex integrals
virtual std::size_t max_vertex_subdomain_id() const = 0;
/// Return the upper bound on subdomain ids for custom integrals
virtual std::size_t max_custom_subdomain_id() const = 0;
/// Return whether form has any cell integrals
virtual bool has_cell_integrals() const = 0;
/// Return whether form has any exterior facet integrals
virtual bool has_exterior_facet_integrals() const = 0;
/// Return whether form has any interior facet integrals
virtual bool has_interior_facet_integrals() const = 0;
/// Return whether form has any vertex integrals
virtual bool has_vertex_integrals() const = 0;
/// Return whether form has any custom integrals
virtual bool has_custom_integrals() const = 0;
/// Create a new cell integral on sub domain subdomain_id
virtual cell_integral* create_cell_integral(std::size_t subdomain_id) const = 0;
/// Create a new exterior facet integral on sub domain subdomain_id
virtual exterior_facet_integral*
create_exterior_facet_integral(std::size_t subdomain_id) const = 0;
/// Create a new interior facet integral on sub domain subdomain_id
virtual interior_facet_integral*
create_interior_facet_integral(std::size_t subdomain_id) const = 0;
/// Create a new vertex integral on sub domain subdomain_id
virtual vertex_integral* create_vertex_integral(std::size_t subdomain_id) const = 0;
/// Create a new custom integral on sub domain subdomain_id
virtual custom_integral* create_custom_integral(std::size_t subdomain_id) const = 0;
/// Create a new cell integral on everywhere else
virtual cell_integral* create_default_cell_integral() const = 0;
/// Create a new exterior facet integral on everywhere else
virtual exterior_facet_integral*
create_default_exterior_facet_integral() const = 0;
/// Create a new interior facet integral on everywhere else
virtual interior_facet_integral*
create_default_interior_facet_integral() const = 0;
/// Create a new vertex integral on everywhere else
virtual vertex_integral* create_default_vertex_integral() const = 0;
/// Create a new custom integral on everywhere else
virtual custom_integral* create_default_custom_integral() const = 0;
};
}
#endif
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