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rAKA akantu
element_class.hh
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/**
* Copyright (©) 2010-2023 EPFL (Ecole Polytechnique Fédérale de Lausanne)
* Laboratory (LSMS - Laboratoire de Simulation en Mécanique des Solides)
*
* This file is part of Akantu
*
* Akantu is free software: you can redistribute it and/or modify it under the
* terms of the GNU Lesser General Public License as published by the Free
* Software Foundation, either version 3 of the License, or (at your option) any
* later version.
*
* Akantu is distributed in the hope that it will be useful, but WITHOUT ANY
* WARRANTY; without even the implied warranty of MERCHANTABILITY or FITNESS FOR
* A PARTICULAR PURPOSE. See the GNU Lesser General Public License for more
* details.
*
* You should have received a copy of the GNU Lesser General Public License
* along with Akantu. If not, see <http://www.gnu.org/licenses/>.
*/
/* -------------------------------------------------------------------------- */
#include "aka_common.hh"
#include "aka_types.hh"
/* -------------------------------------------------------------------------- */
#ifndef AKANTU_ELEMENT_CLASS_HH_
#define AKANTU_ELEMENT_CLASS_HH_
namespace
akantu
{
/* -------------------------------------------------------------------------- */
/// default element class structure
template
<
ElementType
element_type
>
struct
ElementClassProperty
{
static
constexpr
GeometricalType
geometrical_type
{
_gt_not_defined
};
static
constexpr
InterpolationType
interpolation_type
{
_itp_not_defined
};
static
constexpr
ElementKind
element_kind
{
_ek_regular
};
static
constexpr
Int
spatial_dimension
{
0
};
static
constexpr
GaussIntegrationType
gauss_itegration_type
{
_git_not_defined
};
static
constexpr
Int
polynomial_degree
{
0
};
};
#if !defined(DOXYGEN)
/// Macro to generate the element class structures for different element types
#define AKANTU_DEFINE_ELEMENT_CLASS_PROPERTY(elem_type, geom_type, \
interp_type, elem_kind, sp, \
gauss_int_type, min_int_order) \
template <> struct ElementClassProperty<elem_type> { \
static constexpr GeometricalType geometrical_type{geom_type}; \
static constexpr InterpolationType interpolation_type{interp_type}; \
static constexpr ElementKind element_kind{elem_kind}; \
static constexpr Int spatial_dimension{sp}; \
static constexpr GaussIntegrationType gauss_integration_type{ \
gauss_int_type}; \
static constexpr Int polynomial_degree{min_int_order}; \
}
#else
#define AKANTU_DEFINE_ELEMENT_CLASS_PROPERTY(elem_type, geom_type, \
interp_type, elem_kind, sp, \
gauss_int_type, min_int_order)
#endif
/* -------------------------------------------------------------------------- */
/* Geometry */
/* -------------------------------------------------------------------------- */
/// Default GeometricalShape structure
template
<
GeometricalType
geometrical_type
>
struct
GeometricalShape
{
static
constexpr
GeometricalShapeType
shape
{
_gst_point
};
};
/// Templated GeometricalShape with function contains
template
<
GeometricalShapeType
shape
>
struct
GeometricalShapeContains
{
/// Check if the point (vector in 2 and 3D) at natural coordinate coord
template
<
class
D
>
static
inline
bool
contains
(
const
Eigen
::
MatrixBase
<
D
>
&
coord
);
};
#if !defined(DOXYGEN)
/// Macro to generate the GeometricalShape structures for different geometrical
/// types
#define AKANTU_DEFINE_SHAPE(geom_type, geom_shape) \
template <> struct GeometricalShape<geom_type> { \
static constexpr GeometricalShapeType shape{geom_shape}; \
}
AKANTU_DEFINE_SHAPE
(
_gt_hexahedron_20
,
_gst_square
);
AKANTU_DEFINE_SHAPE
(
_gt_hexahedron_8
,
_gst_square
);
AKANTU_DEFINE_SHAPE
(
_gt_pentahedron_15
,
_gst_prism
);
AKANTU_DEFINE_SHAPE
(
_gt_pentahedron_6
,
_gst_prism
);
AKANTU_DEFINE_SHAPE
(
_gt_point
,
_gst_point
);
AKANTU_DEFINE_SHAPE
(
_gt_quadrangle_4
,
_gst_square
);
AKANTU_DEFINE_SHAPE
(
_gt_quadrangle_8
,
_gst_square
);
AKANTU_DEFINE_SHAPE
(
_gt_segment_2
,
_gst_square
);
AKANTU_DEFINE_SHAPE
(
_gt_segment_3
,
_gst_square
);
AKANTU_DEFINE_SHAPE
(
_gt_tetrahedron_10
,
_gst_triangle
);
AKANTU_DEFINE_SHAPE
(
_gt_tetrahedron_4
,
_gst_triangle
);
AKANTU_DEFINE_SHAPE
(
_gt_triangle_3
,
_gst_triangle
);
AKANTU_DEFINE_SHAPE
(
_gt_triangle_6
,
_gst_triangle
);
#endif
/* -------------------------------------------------------------------------- */
template
<
GeometricalType
geometrical_type
>
struct
GeometricalElementProperty
{};
template
<
ElementType
element_type
>
struct
ElementClassExtraGeometryProperties
{};
/* -------------------------------------------------------------------------- */
/// Templated GeometricalElement with function getInradius
template
<
GeometricalType
geometrical_type
,
GeometricalShapeType
shape
=
GeometricalShape
<
geometrical_type
>::
shape
>
class
GeometricalElement
{
using
geometrical_property
=
GeometricalElementProperty
<
geometrical_type
>
;
public
:
/// compute the in-radius: \todo should be renamed for characteristic length
template
<
class
D
>
static
inline
Real
getInradius
(
const
Eigen
::
MatrixBase
<
D
>
&
/*X*/
)
{
return
0.
;
}
/// compute the normal to the element
template
<
class
D1
,
class
D2
>
static
inline
void
getNormal
(
const
Eigen
::
MatrixBase
<
D1
>
&
/*X*/
,
Eigen
::
MatrixBase
<
D2
>
&
n
)
{
n
.
zero
();
}
/// true if the natural coordinates are in the element
template
<
class
D
>
static
inline
bool
contains
(
const
Eigen
::
MatrixBase
<
D
>
&
coord
);
public
:
static
constexpr
auto
getSpatialDimension
()
{
return
geometrical_property
::
spatial_dimension
;
}
static
constexpr
auto
getNbNodesPerElement
()
{
return
geometrical_property
::
nb_nodes_per_element
;
}
static
inline
constexpr
auto
getNbFacetTypes
()
{
return
geometrical_property
::
nb_facet_types
;
};
static
inline
constexpr
Int
getNbFacetsPerElement
(
Idx
t
);
static
inline
constexpr
Int
getNbFacetsPerElement
();
static
inline
constexpr
decltype
(
auto
)
getFacetLocalConnectivityPerElement
(
Idx
t
=
0
);
template
<
Idx
t
,
std
::
size_t
size
=
std
::
tuple_size
<
decltype
(
geometrical_property
::
nb_facets
)
>::
value
,
std
::
enable_if_t
<
(
t
<
size
)
>
*
=
nullptr
>
static
inline
constexpr
decltype
(
auto
)
getFacetLocalConnectivityPerElement
();
template
<
Idx
t
,
std
::
size_t
size
=
std
::
tuple_size
<
decltype
(
geometrical_property
::
nb_facets
)
>::
value
,
std
::
enable_if_t
<
not
(
t
<
size
)
>
*
=
nullptr
>
static
inline
constexpr
decltype
(
auto
)
getFacetLocalConnectivityPerElement
();
};
/* -------------------------------------------------------------------------- */
/* Interpolation */
/* -------------------------------------------------------------------------- */
/// default InterpolationProperty structure
template
<
InterpolationType
interpolation_type
>
struct
InterpolationProperty
{};
#if !defined(DOXYGEN)
/// Macro to generate the InterpolationProperty structures for different
/// interpolation types
#define AKANTU_DEFINE_INTERPOLATION_TYPE_PROPERTY(itp_type, itp_kind, \
nb_nodes, ndim) \
template <> struct InterpolationProperty<itp_type> { \
static constexpr InterpolationKind kind{itp_kind}; \
static constexpr Int nb_nodes_per_element{nb_nodes}; \
static constexpr Int natural_space_dimension{ndim}; \
}
#else
#define AKANTU_DEFINE_INTERPOLATION_TYPE_PROPERTY(itp_type, itp_kind, \
nb_nodes, ndim)
#endif
/* -------------------------------------------------------------------------- */
/// Generic (templated by the enum InterpolationType which specifies the order
/// and the dimension of the interpolation) class handling the elemental
/// interpolation
template
<
InterpolationType
interpolation_type
,
InterpolationKind
kind
=
InterpolationProperty
<
interpolation_type
>::
kind
>
class
InterpolationElement
{
public
:
using
interpolation_property
=
InterpolationProperty
<
interpolation_type
>
;
/// compute the shape values for a given set of points in natural coordinates
template
<
class
D1
,
class
D2
,
aka
::
enable_if_t
<
aka
::
are_matrices
<
D1
,
D2
>::
value
>
*
=
nullptr
>
static
inline
void
computeShapes
(
const
Eigen
::
MatrixBase
<
D1
>
&
Xs
,
const
Eigen
::
MatrixBase
<
D2
>
&
N_
);
/// compute the shape values for a given point in natural coordinates
template
<
class
D1
,
class
D2
,
aka
::
enable_if_t
<
aka
::
are_vectors
<
D1
,
D2
>::
value
>
*
=
nullptr
>
static
inline
void
computeShapes
(
const
Eigen
::
MatrixBase
<
D1
>
&
/*Xs*/
,
Eigen
::
MatrixBase
<
D2
>
&
/*N_*/
)
{
AKANTU_TO_IMPLEMENT
();
}
/**
* compute @f$ B_{ij} = \frac{\partial N_j}{\partial S_i} @f$ the variation of
* shape functions along with variation of natural coordinates on a given set
* of points in natural coordinates
*/
template
<
class
D
>
static
inline
void
computeDNDS
(
const
Eigen
::
MatrixBase
<
D
>
&
Xs
,
Tensor3Base
<
Real
>
&
dnds
);
/**
* compute @f$ B_{ij} = \frac{\partial N_j}{\partial S_i} @f$ the variation of
* shape functions along with
* variation of natural coordinates on a given point in natural
* coordinates
*/
template
<
class
D1
,
class
D2
>
static
inline
void
computeDNDS
(
const
Eigen
::
MatrixBase
<
D1
>
&
/*Xs*/
,
Eigen
::
MatrixBase
<
D2
>
&
/*dNdS*/
)
{
AKANTU_TO_IMPLEMENT
();
}
/**
* compute @f$ @f$
**/
static
inline
void
computeD2NDS2
(
const
Matrix
<
Real
>
&
natural_coord
,
Tensor3
<
Real
>
&
d2nds2
);
/**
* compute @f$ B_{ij} = \frac{\partial N_j}{\partial S_i} @f$ the
* second variation of
* shape functions along with
* variation of natural coordinates on a given point in natural
* coordinates
*/
template
<
class
vector_type
,
class
matrix_type
>
static
inline
void
computeD2NDS2
(
const
vector_type
&
/*unused*/
,
matrix_type
&
/*unused*/
)
{
AKANTU_TO_IMPLEMENT
();
}
/// compute jacobian (or integration variable change factor) for a given point
/// in the case of spatial_dimension != natural_space_dimension
template
<
class
D
>
static
inline
Real
computeSpecialJacobian
(
const
Eigen
::
MatrixBase
<
D
>
&
)
{
AKANTU_TO_IMPLEMENT
();
}
/// interpolate a field given (arbitrary) natural coordinates
template
<
class
Derived1
,
class
Derived2
>
static
inline
decltype
(
auto
)
interpolateOnNaturalCoordinates
(
const
Eigen
::
MatrixBase
<
Derived1
>
&
natural_coords
,
const
Eigen
::
MatrixBase
<
Derived2
>
&
nodal_values
)
{
using
interpolation
=
InterpolationProperty
<
interpolation_type
>
;
Eigen
::
Matrix
<
Real
,
interpolation
::
nb_nodes_per_element
,
1
>
shapes
;
computeShapes
(
natural_coords
,
shapes
);
Matrix
<
Real
,
Eigen
::
Dynamic
,
1
>
res
;
res
.
noalias
()
=
interpolate
(
nodal_values
,
shapes
);
return
res
;
}
/// interpolate a field given the shape functions on the interpolation point
template
<
class
Derived1
,
class
Derived2
>
static
inline
auto
interpolate
(
const
Eigen
::
MatrixBase
<
Derived1
>
&
nodal_values
,
const
Eigen
::
MatrixBase
<
Derived2
>
&
shapes
);
/// interpolate a field given the shape functions on the interpolations points
template
<
class
Derived1
,
class
Derived2
,
class
Derived3
>
static
inline
void
interpolate
(
const
Eigen
::
MatrixBase
<
Derived1
>
&
nodal_values
,
const
Eigen
::
MatrixBase
<
Derived2
>
&
Ns
,
const
Eigen
::
MatrixBase
<
Derived3
>
&
interpolated
);
/// compute the gradient of a given field on the given natural coordinates
template
<
class
D1
,
class
D2
,
class
D3
>
static
inline
void
gradientOnNaturalCoordinates
(
const
Eigen
::
MatrixBase
<
D1
>
&
natural_coords
,
const
Eigen
::
MatrixBase
<
D2
>
&
f
,
const
Eigen
::
MatrixBase
<
D3
>
&
dfds
);
public
:
static
constexpr
auto
getShapeSize
()
{
return
InterpolationProperty
<
interpolation_type
>::
nb_nodes_per_element
;
}
static
constexpr
auto
getShapeDerivativesSize
()
{
return
(
InterpolationProperty
<
interpolation_type
>::
nb_nodes_per_element
*
InterpolationProperty
<
interpolation_type
>::
natural_space_dimension
);
}
static
constexpr
auto
getNaturalSpaceDimension
()
{
return
InterpolationProperty
<
interpolation_type
>::
natural_space_dimension
;
}
static
constexpr
auto
getNbNodesPerInterpolationElement
()
{
return
InterpolationProperty
<
interpolation_type
>::
nb_nodes_per_element
;
}
};
/* -------------------------------------------------------------------------- */
/* Integration */
/* -------------------------------------------------------------------------- */
template
<
GaussIntegrationType
git_class
,
Int
nb_points
>
struct
GaussIntegrationTypeData
{
/// quadrature points in natural coordinates
static
Real
quad_positions
[];
/// weights for the Gauss integration
static
Real
quad_weights
[];
};
template
<
ElementType
type
,
Int
n
=
ElementClassProperty
<
type
>::
polynomial_degree
>
class
GaussIntegrationElement
{
static
constexpr
InterpolationType
itp_type
=
ElementClassProperty
<
type
>::
interpolation_type
;
using
interpolation_property
=
InterpolationProperty
<
itp_type
>
;
public
:
static
constexpr
Int
getNbQuadraturePoints
();
static
constexpr
auto
getQuadraturePoints
();
static
constexpr
auto
getWeights
();
};
/* -------------------------------------------------------------------------- */
/* ElementClass */
/* -------------------------------------------------------------------------- */
template
<
ElementType
element_type
,
ElementKind
element_kind
=
ElementClassProperty
<
element_type
>::
element_kind
>
class
ElementClass
:
public
GeometricalElement
<
ElementClassProperty
<
element_type
>::
geometrical_type
>
,
public
InterpolationElement
<
ElementClassProperty
<
element_type
>::
interpolation_type
>
{
protected
:
using
geometrical_element
=
GeometricalElement
<
ElementClassProperty
<
element_type
>::
geometrical_type
>
;
using
interpolation_element
=
InterpolationElement
<
ElementClassProperty
<
element_type
>::
interpolation_type
>
;
using
element_property
=
ElementClassProperty
<
element_type
>
;
using
interpolation_property
=
typename
interpolation_element
::
interpolation_property
;
public
:
/**
* compute @f$ J = \frac{\partial x_j}{\partial s_i} @f$ the variation of real
* coordinates along with variation of natural coordinates on a given point in
* natural coordinates
*/
template
<
class
D1
,
class
D2
>
static
inline
decltype
(
auto
)
computeJMat
(
const
Eigen
::
MatrixBase
<
D1
>
&
dnds
,
const
Eigen
::
MatrixBase
<
D2
>
&
node_coords
);
/**
* compute the Jacobian matrix by computing the variation of real coordinates
* along with variation of natural coordinates on a given set of points in
* natural coordinates
*/
template
<
class
D
>
static
inline
void
computeJMat
(
const
Tensor3Base
<
Real
>
&
dnds
,
const
Eigen
::
MatrixBase
<
D
>
&
node_coords
,
Tensor3Base
<
Real
>
&
J
);
/// compute the jacobians of a serie of natural coordinates
template
<
class
D1
,
class
D2
,
class
D3
>
static
inline
void
computeJacobian
(
const
Eigen
::
MatrixBase
<
D1
>
&
natural_coords
,
const
Eigen
::
MatrixBase
<
D2
>
&
node_coords
,
Eigen
::
MatrixBase
<
D3
>
&
jacobians
);
/// compute jacobian (or integration variable change factor) for a set of
/// points
template
<
class
D
>
static
inline
void
computeJacobian
(
const
Tensor3Base
<
Real
>
&
J
,
Eigen
::
MatrixBase
<
D
>
&
jacobians
);
/// compute jacobian (or integration variable change factor) for a given point
template
<
class
D
>
static
inline
Real
computeJacobian
(
const
Eigen
::
MatrixBase
<
D
>
&
J
);
/// compute shape derivatives (input is dxds) for a set of points
static
inline
void
computeShapeDerivatives
(
const
Tensor3Base
<
Real
>
&
J
,
const
Tensor3Base
<
Real
>
&
dnds
,
Tensor3Base
<
Real
>
&
shape_deriv
);
/// compute shape derivatives (input is dxds) for a given point
template
<
class
D1
,
class
D2
,
class
D3
>
static
inline
void
computeShapeDerivatives
(
const
Eigen
::
MatrixBase
<
D1
>
&
J
,
const
Eigen
::
MatrixBase
<
D2
>
&
dnds
,
Eigen
::
MatrixBase
<
D3
>
&
shape_deriv
);
/// compute the normal of a surface defined by the function f
template
<
class
D1
,
class
D2
,
class
D3
>
static
inline
void
computeNormalsOnNaturalCoordinates
(
const
Eigen
::
MatrixBase
<
D1
>
&
coord
,
const
Eigen
::
MatrixBase
<
D2
>
&
f
,
Eigen
::
MatrixBase
<
D3
>
&
normals
);
/// get natural coordinates from real coordinates
template
<
class
D1
,
class
D2
,
class
D3
,
aka
::
enable_if_vectors_t
<
D1
,
D3
>
*
=
nullptr
>
static
inline
void
inverseMap
(
const
Eigen
::
MatrixBase
<
D1
>
&
real_coords
,
const
Eigen
::
MatrixBase
<
D2
>
&
node_coords
,
const
Eigen
::
MatrixBase
<
D3
>
&
natural_coords
,
Int
max_iterations
=
100
,
Real
tolerance
=
1e-10
);
/// get natural coordinates from real coordinates
template
<
class
D1
,
class
D2
,
class
D3
,
aka
::
enable_if_matrices_t
<
D1
,
D3
>
*
=
nullptr
>
static
inline
void
inverseMap
(
const
Eigen
::
MatrixBase
<
D1
>
&
real_coords
,
const
Eigen
::
MatrixBase
<
D2
>
&
node_coords
,
const
Eigen
::
MatrixBase
<
D3
>
&
natural_coords_
,
Int
max_iterations
=
100
,
Real
tolerance
=
1e-10
);
public
:
static
constexpr
auto
getKind
()
{
return
element_kind
;
}
static
constexpr
auto
getSpatialDimension
()
{
return
ElementClassProperty
<
element_type
>::
spatial_dimension
;
}
using
element_class_extra_geom_property
=
ElementClassExtraGeometryProperties
<
element_type
>
;
static
constexpr
decltype
(
auto
)
getP1ElementType
()
{
return
element_class_extra_geom_property
::
p1_type
;
}
static
constexpr
decltype
(
auto
)
getFacetType
(
UInt
t
=
0
)
{
return
element_class_extra_geom_property
::
facet_type
[
t
];
}
static
constexpr
decltype
(
auto
)
getFacetTypes
();
};
/* -------------------------------------------------------------------------- */
}
// namespace akantu
/* -------------------------------------------------------------------------- */
#include "interpolation_element_tmpl.hh"
/* -------------------------------------------------------------------------- */
#include "geometrical_element_property.hh"
/* -------------------------------------------------------------------------- */
#include "element_class_tmpl.hh"
/* -------------------------------------------------------------------------- */
#include "element_class_hexahedron_8_inline_impl.hh"
#include "element_class_pentahedron_6_inline_impl.hh"
/* keep order */
#include "element_class_hexahedron_20_inline_impl.hh"
#include "element_class_pentahedron_15_inline_impl.hh"
#include "element_class_point_1_inline_impl.hh"
#include "element_class_quadrangle_4_inline_impl.hh"
#include "element_class_quadrangle_8_inline_impl.hh"
#include "element_class_segment_2_inline_impl.hh"
#include "element_class_segment_3_inline_impl.hh"
#include "element_class_tetrahedron_10_inline_impl.hh"
#include "element_class_tetrahedron_4_inline_impl.hh"
#include "element_class_triangle_3_inline_impl.hh"
#include "element_class_triangle_6_inline_impl.hh"
/* -------------------------------------------------------------------------- */
#if defined(AKANTU_STRUCTURAL_MECHANICS)
#include "element_class_structural.hh"
#endif
#if defined(AKANTU_COHESIVE_ELEMENT)
#include "cohesive_element.hh"
#endif
#if defined(AKANTU_IGFEM)
#include "element_class_igfem.hh"
#endif
#endif
/* AKANTU_ELEMENT_CLASS_HH_ */
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