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rAKA akantu
py_mesh.cc
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/**
* Copyright (©) 2019-2023 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_config.hh"
/* -------------------------------------------------------------------------- */
#include "py_aka_array.hh"
/* -------------------------------------------------------------------------- */
#include <element_type_map.hh>
#include <fe_engine.hh>
#include <mesh.hh>
#include <mesh_accessor.hh>
#include <mesh_utils.hh>
/* -------------------------------------------------------------------------- */
#include <pybind11/pybind11.h>
#include <pybind11/stl.h>
/* -------------------------------------------------------------------------- */
namespace
py
=
pybind11
;
/* -------------------------------------------------------------------------- */
namespace
akantu
{
namespace
{
/* ------------------------------------------------------------------------ */
template
<
typename
T
>
auto
register_element_type_map_array
(
py
::
module
&
mod
,
const
std
::
string
&
name
)
{
return
py
::
class_
<
ElementTypeMapArray
<
T
>
,
std
::
shared_ptr
<
ElementTypeMapArray
<
T
>>>
(
mod
,
(
"ElementTypeMapArray"
+
name
).
c_str
())
.
def
(
py
::
init
<
const
ID
&
,
const
ID
&>
(),
py
::
arg
(
"id"
)
=
"by_element_type_array"
,
py
::
arg
(
"parent_id"
)
=
"no_parent"
)
.
def
(
"__call__"
,
[](
ElementTypeMapArray
<
T
>
&
self
,
ElementType
type
,
GhostType
ghost_type
)
->
decltype
(
auto
)
{
return
self
(
type
,
ghost_type
);
},
py
::
arg
(
"type"
),
py
::
arg
(
"ghost_type"
)
=
_not_ghost
,
py
::
return_value_policy
::
reference
,
py
::
keep_alive
<
0
,
1
>
())
.
def
(
"elementTypes"
,
[](
ElementTypeMapArray
<
T
>
&
self
,
Int
_dim
,
GhostType
_ghost_type
,
ElementKind
_kind
)
->
std
::
vector
<
ElementType
>
{
auto
types
=
self
.
elementTypes
(
_dim
,
_ghost_type
,
_kind
);
std
::
vector
<
ElementType
>
_types
;
for
(
auto
&&
t
:
types
)
{
_types
.
push_back
(
t
);
}
return
_types
;
},
py
::
arg
(
"dim"
)
=
_all_dimensions
,
py
::
arg
(
"ghost_type"
)
=
_not_ghost
,
py
::
arg
(
"kind"
)
=
_ek_regular
)
.
def
(
"initialize"
,
[](
ElementTypeMapArray
<
T
>
&
self
,
const
Mesh
&
mesh
,
GhostType
ghost_type
,
Int
nb_component
,
Int
spatial_dimension
,
ElementKind
element_kind
,
bool
with_nb_element
,
bool
with_nb_nodes_per_element
,
T
default_value
,
bool
do_not_default
)
{
self
.
initialize
(
mesh
,
_ghost_type
=
ghost_type
,
_nb_component
=
nb_component
,
_spatial_dimension
=
(
spatial_dimension
==
-
2
?
mesh
.
getSpatialDimension
()
:
spatial_dimension
),
_element_kind
=
element_kind
,
_with_nb_element
=
with_nb_element
,
_with_nb_nodes_per_element
=
with_nb_nodes_per_element
,
_default_value
=
default_value
,
_do_not_default
=
do_not_default
);
},
py
::
arg
(
"mesh"
),
py
::
kw_only
(),
py
::
arg
(
"ghost_type"
)
=
_casper
,
py
::
arg
(
"nb_component"
)
=
1
,
py
::
arg
(
"spatial_dimension"
)
=
-
2
,
py
::
arg
(
"element_kind"
)
=
_ek_not_defined
,
py
::
arg
(
"with_nb_element"
)
=
false
,
py
::
arg
(
"with_nb_nodes_per_element"
)
=
false
,
py
::
arg
(
"default_value"
)
=
T
{},
py
::
arg
(
"do_not_default"
)
=
false
)
.
def
(
"initialize"
,
[](
ElementTypeMapArray
<
T
>
&
self
,
const
FEEngine
&
fe_engine
,
GhostType
ghost_type
,
Int
nb_component
,
Int
spatial_dimension
,
ElementKind
element_kind
,
bool
with_nb_element
,
bool
with_nb_nodes_per_element
,
T
default_value
,
bool
do_not_default
)
{
self
.
initialize
(
fe_engine
,
_ghost_type
=
ghost_type
,
_nb_component
=
nb_component
,
_spatial_dimension
=
(
spatial_dimension
==
-
2
?
fe_engine
.
getMesh
().
getSpatialDimension
()
:
spatial_dimension
),
_element_kind
=
element_kind
,
_with_nb_element
=
with_nb_element
,
_with_nb_nodes_per_element
=
with_nb_nodes_per_element
,
_default_value
=
default_value
,
_do_not_default
=
do_not_default
);
},
py
::
arg
(
"mesh"
),
py
::
kw_only
(),
py
::
arg
(
"ghost_type"
)
=
_casper
,
py
::
arg
(
"nb_component"
)
=
1
,
py
::
arg
(
"spatial_dimension"
)
=
-
2
,
py
::
arg
(
"element_kind"
)
=
_ek_not_defined
,
py
::
arg
(
"with_nb_element"
)
=
false
,
py
::
arg
(
"with_nb_nodes_per_element"
)
=
false
,
py
::
arg
(
"default_value"
)
=
T
{},
py
::
arg
(
"do_not_default"
)
=
false
)
.
def
(
"initialize"
,
[](
ElementTypeMapArray
<
T
>
&
self
,
const
FEEngine
&
fe_engine
,
GhostType
ghost_type
,
Int
nb_component
,
Int
spatial_dimension
,
ElementKind
element_kind
,
bool
with_nb_element
,
bool
with_nb_nodes_per_element
,
T
default_value
,
bool
do_not_default
)
{
self
.
initialize
(
fe_engine
,
_ghost_type
=
ghost_type
,
_nb_component
=
nb_component
,
_spatial_dimension
=
(
spatial_dimension
==
-
2
?
fe_engine
.
getMesh
().
getSpatialDimension
()
:
spatial_dimension
),
_element_kind
=
element_kind
,
_with_nb_element
=
with_nb_element
,
_with_nb_nodes_per_element
=
with_nb_nodes_per_element
,
_default_value
=
default_value
,
_do_not_default
=
do_not_default
);
},
py
::
arg
(
"fe_engine"
),
py
::
arg
(
"ghost_type"
)
=
_casper
,
py
::
arg
(
"nb_component"
)
=
1
,
py
::
arg
(
"spatial_dimension"
)
=
-
2
,
py
::
arg
(
"element_kind"
)
=
_ek_not_defined
,
py
::
arg
(
"with_nb_element"
)
=
false
,
py
::
arg
(
"with_nb_nodes_per_element"
)
=
false
,
py
::
arg
(
"default_value"
)
=
T
{},
py
::
arg
(
"do_not_default"
)
=
false
)
.
def
(
"getID"
,
&
ElementTypeMapArray
<
T
>::
getID
);
}
}
// namespace
/* -------------------------------------------------------------------------- */
void
register_mesh
(
py
::
module
&
mod
)
{
py
::
class_
<
Mesh
::
PeriodicSlaves
>
(
mod
,
"PeriodicSlaves"
)
.
def
(
"__iter__"
,
[](
Mesh
::
PeriodicSlaves
&
_this
)
{
return
py
::
make_iterator
(
_this
.
begin
(),
_this
.
end
());
},
py
::
keep_alive
<
0
,
1
>
());
py
::
class_
<
MeshData
>
(
mod
,
"MeshData"
)
.
def
(
"getElementalDataUInt"
,
[](
MeshData
&
_this
,
const
ID
&
name
)
->
decltype
(
auto
)
{
return
_this
.
getElementalData
<
UInt
>
(
name
);
},
py
::
return_value_policy
::
reference
)
.
def
(
"getElementalDataReal"
,
[](
MeshData
&
_this
,
const
ID
&
name
)
->
decltype
(
auto
)
{
return
_this
.
getElementalData
<
Real
>
(
name
);
},
py
::
return_value_policy
::
reference
);
py
::
class_
<
Mesh
,
GroupManager
,
Dumpable
,
MeshData
>
(
mod
,
"Mesh"
,
py
::
multiple_inheritance
())
.
def
(
py
::
init
<
Int
,
const
ID
&>
(),
py
::
arg
(
"spatial_dimension"
),
py
::
arg
(
"id"
)
=
"mesh"
)
.
def
(
"read"
,
&
Mesh
::
read
,
py
::
arg
(
"filename"
),
py
::
arg
(
"mesh_io_type"
)
=
_miot_auto
,
"read the mesh from a file"
)
.
def
(
"getNodes"
,
[](
Mesh
&
self
)
->
decltype
(
auto
)
{
return
self
.
getNodes
();
},
py
::
return_value_policy
::
reference
)
.
def
(
"getNbNodes"
,
&
Mesh
::
getNbNodes
)
.
def
(
"getConnectivity"
,
[](
Mesh
&
self
,
ElementType
type
)
->
decltype
(
auto
)
{
return
self
.
getConnectivity
(
type
);
},
py
::
return_value_policy
::
reference
)
.
def
(
"getConnectivities"
,
[](
Mesh
&
self
)
->
decltype
(
auto
)
{
return
self
.
getConnectivities
();
},
py
::
return_value_policy
::
reference
)
.
def
(
"addConnectivityType"
,
[](
Mesh
&
self
,
ElementType
type
,
GhostType
ghost_type
)
->
void
{
self
.
addConnectivityType
(
type
,
ghost_type
);
},
py
::
arg
(
"type"
),
py
::
arg
(
"ghost_type"
)
=
_not_ghost
)
.
def
(
"distribute"
,
[](
Mesh
&
self
)
{
self
.
distribute
();
})
.
def
(
"isDistributed"
,
[](
const
Mesh
&
self
)
{
return
self
.
isDistributed
();
})
.
def
(
"fillNodesToElements"
,
&
Mesh
::
fillNodesToElements
,
py
::
arg
(
"dimension"
)
=
_all_dimensions
)
.
def
(
"getAssociatedElements"
,
[](
Mesh
&
self
,
const
Idx
&
node
,
py
::
list
list
)
{
Array
<
Element
>
elements
;
self
.
getAssociatedElements
(
node
,
elements
);
for
(
auto
&&
element
:
elements
)
{
list
.
append
(
element
);
}
})
.
def
(
"makePeriodic"
,
[](
Mesh
&
self
,
const
SpatialDirection
&
direction
)
{
self
.
makePeriodic
(
direction
);
})
.
def
(
"getNbElement"
,
[](
Mesh
&
self
,
const
Int
spatial_dimension
,
GhostType
ghost_type
,
ElementKind
kind
)
{
return
self
.
getNbElement
(
spatial_dimension
,
ghost_type
,
kind
);
},
py
::
kw_only
(),
py
::
arg
(
"spatial_dimension"
)
=
_all_dimensions
,
py
::
arg
(
"ghost_type"
)
=
_not_ghost
,
py
::
arg
(
"kind"
)
=
_ek_not_defined
)
.
def
(
"getNbElement"
,
[](
Mesh
&
self
,
ElementType
type
,
GhostType
ghost_type
)
{
return
self
.
getNbElement
(
type
,
ghost_type
);
},
py
::
kw_only
(),
py
::
arg
(
"type"
),
py
::
arg
(
"ghost_type"
)
=
_not_ghost
)
.
def_static
(
"getSpatialDimension"
,
[](
ElementType
&
type
)
{
return
Mesh
::
getSpatialDimension
(
type
);
})
.
def
(
"getDataReal"
,
[](
Mesh
&
_this
,
const
ID
&
name
,
ElementType
type
,
GhostType
ghost_type
)
->
decltype
(
auto
)
{
return
_this
.
getData
<
Real
>
(
name
,
type
,
ghost_type
);
},
py
::
arg
(
"name"
),
py
::
arg
(
"type"
),
py
::
arg
(
"ghost_type"
)
=
_not_ghost
,
py
::
return_value_policy
::
reference
)
.
def
(
"hasDataReal"
,
[](
Mesh
&
_this
,
const
ID
&
name
,
ElementType
type
,
GhostType
ghost_type
)
->
bool
{
return
_this
.
hasData
<
Real
>
(
name
,
type
,
ghost_type
);
},
py
::
arg
(
"name"
),
py
::
arg
(
"type"
),
py
::
arg
(
"ghost_type"
)
=
_not_ghost
)
.
def
(
"isPeriodic"
,
[](
const
Mesh
&
_this
)
{
return
_this
.
isPeriodic
();
})
.
def
(
"getPeriodicMaster"
,
&
Mesh
::
getPeriodicMaster
)
.
def
(
"getPeriodicSlaves"
,
&
Mesh
::
getPeriodicSlaves
)
.
def
(
"isPeriodicSlave"
,
&
Mesh
::
isPeriodicSlave
)
.
def
(
"isPeriodicMaster"
,
&
Mesh
::
isPeriodicMaster
)
.
def
(
"getMeshFacets"
,
[](
const
Mesh
&
self
)
->
const
Mesh
&
{
return
self
.
getMeshFacets
();
},
py
::
return_value_policy
::
reference
)
.
def
(
"getUpperBounds"
,
&
Mesh
::
getUpperBounds
)
.
def
(
"getLowerBounds"
,
&
Mesh
::
getLowerBounds
)
.
def
(
"initMeshFacets"
,
&
Mesh
::
initMeshFacets
,
py
::
arg
(
"id"
)
=
"mesh_facets"
,
py
::
return_value_policy
::
reference
);
/* ------------------------------------------------------------------------ */
py
::
class_
<
MeshUtils
>
(
mod
,
"MeshUtils"
)
.
def_static
(
"buildFacets"
,
&
MeshUtils
::
buildFacets
);
py
::
class_
<
MeshAccessor
>
(
mod
,
"MeshAccessor"
)
.
def
(
py
::
init
<
Mesh
&>
(),
py
::
arg
(
"mesh"
))
.
def
(
"resizeConnectivity"
,
[](
MeshAccessor
&
self
,
Int
new_size
,
ElementType
type
,
GhostType
gt
)
->
void
{
self
.
resizeConnectivity
(
new_size
,
type
,
gt
);
},
py
::
arg
(
"new_size"
),
py
::
arg
(
"type"
),
py
::
arg
(
"ghost_type"
)
=
_not_ghost
)
.
def
(
"resizeNodes"
,
[](
MeshAccessor
&
self
,
Int
new_size
)
->
void
{
self
.
resizeNodes
(
new_size
);
},
py
::
arg
(
"new_size"
))
.
def
(
"makeReady"
,
&
MeshAccessor
::
makeReady
);
register_element_type_map_array
<
Real
>
(
mod
,
"Real"
);
register_element_type_map_array
<
UInt
>
(
mod
,
"UInt"
);
register_element_type_map_array
<
Int
>
(
mod
,
"Int"
);
register_element_type_map_array
<
bool
>
(
mod
,
"bool"
);
}
}
// namespace akantu
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