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rAKA akantu
boundary_condition_tmpl.hh
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/**
* @file boundary_condition_tmpl.hh
*
* @author Dana Christen <dana.christen@gmail.com>
* @author Nicolas Richart <nicolas.richart@epfl.ch>
*
* @date creation: Fri May 03 2013
* @date last modification: Mon Jun 23 2014
*
* @brief XXX
*
* @section LICENSE
*
* Copyright (©) 2014 EPFL (Ecole Polytechnique Fédérale de Lausanne)
* Laboratory (LSMS - Laboratoire de Simulation en Mécanique des Solides)
*
* 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 "element_group.hh"
/* -------------------------------------------------------------------------- */
__BEGIN_AKANTU__
/* -------------------------------------------------------------------------- */
template
<
typename
ModelType
>
void
BoundaryCondition
<
ModelType
>::
initBC
(
ModelType
&
model
,
Array
<
Real
>
&
primal
,
Array
<
Real
>
&
dual
)
{
this
->
model
=
&
model
;
this
->
primal
=
&
primal
;
this
->
dual
=
&
dual
;
if
(
this
->
model
->
getSpatialDimension
()
>
1
)
this
->
model
->
initFEEngineBoundary
();
}
/* -------------------------------------------------------------------------- */
template
<
typename
ModelType
>
void
BoundaryCondition
<
ModelType
>::
initBC
(
ModelType
&
model
,
Array
<
Real
>
&
primal
,
Array
<
Real
>
&
primal_increment
,
Array
<
Real
>
&
dual
)
{
this
->
initBC
(
model
,
primal
,
dual
);
this
->
primal_increment
=
&
primal_increment
;
}
/* -------------------------------------------------------------------------- */
/* Partial specialization for DIRICHLET functors */
template
<
typename
ModelType
>
template
<
typename
FunctorType
>
struct
BoundaryCondition
<
ModelType
>::
TemplateFunctionWrapper
<
FunctorType
,
BC
::
Functor
::
_dirichlet
>
{
static
inline
void
applyBC
(
const
FunctorType
&
func
,
const
ElementGroup
&
group
,
BoundaryCondition
<
ModelType
>
&
bc_instance
)
{
ModelType
&
model
=
bc_instance
.
getModel
();
Array
<
Real
>
&
primal
=
bc_instance
.
getPrimal
();
const
Array
<
Real
>
&
coords
=
model
.
getMesh
().
getNodes
();
Array
<
bool
>
&
boundary_flags
=
model
.
getBlockedDOFs
();
UInt
dim
=
model
.
getMesh
().
getSpatialDimension
();
Array
<
Real
>::
vector_iterator
primal_iter
=
primal
.
begin
(
primal
.
getNbComponent
());
Array
<
Real
>::
const_vector_iterator
coords_iter
=
coords
.
begin
(
dim
);
Array
<
bool
>::
vector_iterator
flags_iter
=
boundary_flags
.
begin
(
boundary_flags
.
getNbComponent
());
for
(
ElementGroup
::
const_node_iterator
nodes_it
(
group
.
node_begin
());
nodes_it
!=
group
.
node_end
();
++
nodes_it
)
{
UInt
n
=
*
nodes_it
;
func
(
n
,
flags_iter
[
n
],
primal_iter
[
n
],
coords_iter
[
n
]);
}
}
};
/* -------------------------------------------------------------------------- */
/* Partial specialization for NEUMANN functors */
template
<
typename
ModelType
>
template
<
typename
FunctorType
>
struct
BoundaryCondition
<
ModelType
>::
TemplateFunctionWrapper
<
FunctorType
,
BC
::
Functor
::
_neumann
>
{
static
inline
void
applyBC
(
const
FunctorType
&
func
,
const
ElementGroup
&
group
,
BoundaryCondition
<
ModelType
>
&
bc_instance
)
{
UInt
dim
=
bc_instance
.
getModel
().
getSpatialDimension
();
switch
(
dim
)
{
case
1
:
{
AKANTU_DEBUG_TO_IMPLEMENT
();
break
;
}
case
2
:
case
3
:
{
applyBC
(
func
,
group
,
bc_instance
,
_not_ghost
);
applyBC
(
func
,
group
,
bc_instance
,
_ghost
);
break
;
}
}
}
static
inline
void
applyBC
(
const
FunctorType
&
func
,
const
ElementGroup
&
group
,
BoundaryCondition
<
ModelType
>
&
bc_instance
,
GhostType
ghost_type
)
{
ModelType
&
model
=
bc_instance
.
getModel
();
Array
<
Real
>
&
dual
=
bc_instance
.
getDual
();
const
Mesh
&
mesh
=
model
.
getMesh
();
const
Array
<
Real
>
&
nodes_coords
=
mesh
.
getNodes
();
const
FEEngine
&
fem_boundary
=
model
.
getFEEngineBoundary
();
UInt
dim
=
model
.
getSpatialDimension
();
UInt
nb_degree_of_freedom
=
dual
.
getNbComponent
();
QuadraturePoint
quad_point
;
quad_point
.
ghost_type
=
ghost_type
;
ElementGroup
::
type_iterator
type_it
=
group
.
firstType
(
dim
-
1
,
ghost_type
);
ElementGroup
::
type_iterator
type_end
=
group
.
lastType
(
dim
-
1
,
ghost_type
);
// Loop over the boundary element types
for
(;
type_it
!=
type_end
;
++
type_it
)
{
const
Array
<
UInt
>
&
element_ids
=
group
.
getElements
(
*
type_it
,
ghost_type
);
Array
<
UInt
>::
const_scalar_iterator
elem_iter
=
element_ids
.
begin
();
Array
<
UInt
>::
const_scalar_iterator
elem_iter_end
=
element_ids
.
end
();
UInt
nb_quad_points
=
fem_boundary
.
getNbQuadraturePoints
(
*
type_it
,
ghost_type
);
UInt
nb_elements
=
element_ids
.
getSize
();
UInt
nb_nodes_per_element
=
mesh
.
getNbNodesPerElement
(
*
type_it
);
Array
<
Real
>
*
dual_before_integ
=
new
Array
<
Real
>
(
nb_elements
*
nb_quad_points
,
nb_degree_of_freedom
,
0.
);
Array
<
Real
>
*
quad_coords
=
new
Array
<
Real
>
(
nb_elements
*
nb_quad_points
,
dim
);
const
Array
<
Real
>
&
normals_on_quad
=
fem_boundary
.
getNormalsOnQuadPoints
(
*
type_it
,
ghost_type
);
fem_boundary
.
interpolateOnQuadraturePoints
(
nodes_coords
,
*
quad_coords
,
dim
,
*
type_it
,
ghost_type
,
element_ids
);
Array
<
Real
>::
const_vector_iterator
normals_begin
=
normals_on_quad
.
begin
(
dim
);
Array
<
Real
>::
const_vector_iterator
normals_iter
;
Array
<
Real
>::
const_vector_iterator
quad_coords_iter
=
quad_coords
->
begin
(
dim
);
Array
<
Real
>::
vector_iterator
dual_iter
=
dual_before_integ
->
begin
(
nb_degree_of_freedom
);
quad_point
.
type
=
*
type_it
;
for
(;
elem_iter
!=
elem_iter_end
;
++
elem_iter
)
{
UInt
el
=
*
elem_iter
;
quad_point
.
element
=
el
;
normals_iter
=
normals_begin
+
el
*
nb_quad_points
;
for
(
UInt
q
(
0
);
q
<
nb_quad_points
;
++
q
)
{
quad_point
.
num_point
=
q
;
func
(
quad_point
,
*
dual_iter
,
*
quad_coords_iter
,
*
normals_iter
);
++
dual_iter
;
++
quad_coords_iter
;
++
normals_iter
;
}
}
delete
quad_coords
;
/* -------------------------------------------------------------------- */
// Initialization of iterators
Array
<
Real
>::
matrix_iterator
dual_iter_mat
=
dual_before_integ
->
begin
(
nb_degree_of_freedom
,
1
);
elem_iter
=
element_ids
.
begin
();
Array
<
Real
>::
const_matrix_iterator
shapes_iter_begin
=
fem_boundary
.
getShapes
(
*
type_it
,
ghost_type
).
begin
(
1
,
nb_nodes_per_element
);
Array
<
Real
>
*
dual_by_shapes
=
new
Array
<
Real
>
(
nb_elements
*
nb_quad_points
,
nb_degree_of_freedom
*
nb_nodes_per_element
);
Array
<
Real
>::
matrix_iterator
dual_by_shapes_iter
=
dual_by_shapes
->
begin
(
nb_degree_of_freedom
,
nb_nodes_per_element
);
Array
<
Real
>::
const_matrix_iterator
shapes_iter
;
/* -------------------------------------------------------------------- */
// Loop computing dual x shapes
for
(;
elem_iter
!=
elem_iter_end
;
++
elem_iter
)
{
shapes_iter
=
shapes_iter_begin
+
*
elem_iter
*
nb_quad_points
;
for
(
UInt
q
(
0
);
q
<
nb_quad_points
;
++
q
,
++
dual_iter_mat
,
++
dual_by_shapes_iter
,
++
shapes_iter
)
{
dual_by_shapes_iter
->
mul
<
false
,
false
>
(
*
dual_iter_mat
,
*
shapes_iter
);
}
}
delete
dual_before_integ
;
Array
<
Real
>
*
dual_by_shapes_integ
=
new
Array
<
Real
>
(
nb_elements
,
nb_degree_of_freedom
*
nb_nodes_per_element
);
fem_boundary
.
integrate
(
*
dual_by_shapes
,
*
dual_by_shapes_integ
,
nb_degree_of_freedom
*
nb_nodes_per_element
,
*
type_it
,
ghost_type
,
element_ids
);
delete
dual_by_shapes
;
// assemble the result into force vector
fem_boundary
.
assembleArray
(
*
dual_by_shapes_integ
,
dual
,
model
.
getDOFSynchronizer
().
getLocalDOFEquationNumbers
(),
nb_degree_of_freedom
,
*
type_it
,
ghost_type
,
element_ids
);
delete
dual_by_shapes_integ
;
}
}
};
/* -------------------------------------------------------------------------- */
template
<
typename
ModelType
>
template
<
typename
FunctorType
>
inline
void
BoundaryCondition
<
ModelType
>::
applyBC
(
const
FunctorType
&
func
)
{
GroupManager
::
const_element_group_iterator
bit
=
model
->
getMesh
().
getGroupManager
().
element_group_begin
();
GroupManager
::
const_element_group_iterator
bend
=
model
->
getMesh
().
getGroupManager
().
element_group_end
();
for
(;
bit
!=
bend
;
++
bit
)
applyBC
(
func
,
*
bit
);
}
/* -------------------------------------------------------------------------- */
template
<
typename
ModelType
>
template
<
typename
FunctorType
>
inline
void
BoundaryCondition
<
ModelType
>::
applyBC
(
const
FunctorType
&
func
,
const
std
::
string
&
group_name
)
{
try
{
const
ElementGroup
&
element_group
=
model
->
getMesh
().
getElementGroup
(
group_name
);
applyBC
(
func
,
element_group
);
}
catch
(
akantu
::
debug
::
Exception
e
)
{
AKANTU_EXCEPTION
(
"Error applying a boundary condition onto
\"
"
<<
group_name
<<
"
\"
! ["
<<
e
.
what
()
<<
"]"
);
}
}
/* -------------------------------------------------------------------------- */
template
<
typename
ModelType
>
template
<
typename
FunctorType
>
inline
void
BoundaryCondition
<
ModelType
>::
applyBC
(
const
FunctorType
&
func
,
const
ElementGroup
&
element_group
)
{
#if !defined(AKANTU_NDEBUG)
if
(
element_group
.
getDimension
()
!=
model
->
getSpatialDimension
()
-
1
)
AKANTU_DEBUG_WARNING
(
"The group "
<<
element_group
.
getName
()
<<
" does not contain only boundaries elements"
);
#endif
TemplateFunctionWrapper
<
FunctorType
>::
applyBC
(
func
,
element_group
,
*
this
);
}
__END_AKANTU__
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