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py_dof_manager.cc
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rAKA akantu
py_dof_manager.cc
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/**
* Copyright (©) 2021-2023 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 "py_dof_manager.hh"
#include "py_aka_array.hh"
#include "py_akantu_pybind11_compatibility.hh"
/* -------------------------------------------------------------------------- */
#include <dof_manager.hh>
#include <non_linear_solver.hh>
#include <solver_callback.hh>
#include <time_step_solver.hh>
/* -------------------------------------------------------------------------- */
#include <pybind11/operators.h>
#include <pybind11/pybind11.h>
#include <pybind11/stl.h>
/* -------------------------------------------------------------------------- */
namespace
py
=
pybind11
;
/* -------------------------------------------------------------------------- */
namespace
akantu
{
namespace
{
class
PySolverCallback
:
public
SolverCallback
{
public
:
using
SolverCallback
::
SolverCallback
;
/// get the type of matrix needed
MatrixType
getMatrixType
(
const
ID
&
matrix_id
)
const
override
{
// NOLINTNEXTLINE
PYBIND11_OVERRIDE_PURE
(
MatrixType
,
SolverCallback
,
getMatrixType
,
matrix_id
);
}
/// callback to assemble a Matrix
void
assembleMatrix
(
const
ID
&
matrix_id
)
override
{
// NOLINTNEXTLINE
PYBIND11_OVERRIDE_PURE
(
void
,
SolverCallback
,
assembleMatrix
,
matrix_id
);
}
/// callback to assemble a lumped Matrix
void
assembleLumpedMatrix
(
const
ID
&
matrix_id
)
override
{
// NOLINTNEXTLINE
PYBIND11_OVERRIDE_PURE
(
void
,
SolverCallback
,
assembleLumpedMatrix
,
matrix_id
);
}
/// callback to assemble the residual (rhs)
void
assembleResidual
()
override
{
// NOLINTNEXTLINE
PYBIND11_OVERRIDE_PURE
(
void
,
SolverCallback
,
assembleResidual
,
);
}
/// callback for the predictor (in case of dynamic simulation)
void
predictor
()
override
{
// NOLINTNEXTLINE
PYBIND11_OVERRIDE
(
void
,
SolverCallback
,
predictor
,
);
}
/// callback for the corrector (in case of dynamic simulation)
void
corrector
()
override
{
// NOLINTNEXTLINE
PYBIND11_OVERRIDE
(
void
,
SolverCallback
,
corrector
,
);
}
void
beforeSolveStep
()
override
{
// NOLINTNEXTLINE
PYBIND11_OVERRIDE
(
void
,
SolverCallback
,
beforeSolveStep
,
);
}
void
afterSolveStep
(
bool
converged
)
override
{
// NOLINTNEXTLINE
PYBIND11_OVERRIDE
(
void
,
SolverCallback
,
afterSolveStep
,
converged
);
}
};
class
PyInterceptSolverCallback
:
public
InterceptSolverCallback
{
public
:
using
InterceptSolverCallback
::
InterceptSolverCallback
;
MatrixType
getMatrixType
(
const
ID
&
matrix_id
)
const
override
{
// NOLINTNEXTLINE
PYBIND11_OVERRIDE
(
MatrixType
,
InterceptSolverCallback
,
getMatrixType
,
matrix_id
);
}
void
assembleMatrix
(
const
ID
&
matrix_id
)
override
{
// NOLINTNEXTLINE
PYBIND11_OVERRIDE
(
void
,
InterceptSolverCallback
,
assembleMatrix
,
matrix_id
);
}
/// callback to assemble a lumped Matrix
void
assembleLumpedMatrix
(
const
ID
&
matrix_id
)
override
{
// NOLINTNEXTLINE
PYBIND11_OVERRIDE
(
void
,
InterceptSolverCallback
,
assembleLumpedMatrix
,
matrix_id
);
}
void
assembleResidual
()
override
{
// NOLINTNEXTLINE
PYBIND11_OVERRIDE
(
void
,
InterceptSolverCallback
,
assembleResidual
,
);
}
void
predictor
()
override
{
// NOLINTNEXTLINE
PYBIND11_OVERRIDE
(
void
,
InterceptSolverCallback
,
predictor
,
);
}
void
corrector
()
override
{
// NOLINTNEXTLINE
PYBIND11_OVERRIDE
(
void
,
InterceptSolverCallback
,
corrector
,
);
}
void
beforeSolveStep
()
override
{
// NOLINTNEXTLINE
PYBIND11_OVERRIDE
(
void
,
InterceptSolverCallback
,
beforeSolveStep
,
);
}
void
afterSolveStep
(
bool
converged
)
override
{
// NOLINTNEXTLINE
PYBIND11_OVERRIDE
(
void
,
InterceptSolverCallback
,
afterSolveStep
,
converged
);
}
};
}
// namespace
/* -------------------------------------------------------------------------- */
void
register_dof_manager
(
py
::
module
&
mod
)
{
py
::
class_
<
DOFManager
,
std
::
shared_ptr
<
DOFManager
>>
(
mod
,
"DOFManager"
)
.
def
(
"getMatrix"
,
&
DOFManager
::
getMatrix
,
py
::
return_value_policy
::
reference
)
.
def
(
"getNewMatrix"
,
[](
DOFManager
&
self
,
const
std
::
string
&
name
,
const
std
::
string
&
matrix_to_copy_id
)
->
decltype
(
auto
)
{
return
self
.
getNewMatrix
(
name
,
matrix_to_copy_id
);
},
py
::
return_value_policy
::
reference
)
.
def
(
"getResidual"
,
[](
DOFManager
&
self
)
->
decltype
(
auto
)
{
return
self
.
getResidual
();
},
py
::
return_value_policy
::
reference
)
.
def
(
"getArrayPerDOFs"
,
&
DOFManager
::
getArrayPerDOFs
)
.
def
(
"hasMatrix"
,
[](
DOFManager
&
self
,
const
ID
&
name
)
->
bool
{
return
self
.
hasMatrix
(
name
);
},
py
::
arg
(
"name"
))
.
def
(
"assembleToResidual"
,
&
DOFManager
::
assembleToResidual
,
py
::
arg
(
"dof_id"
),
py
::
arg
(
"array_to_assemble"
),
py
::
arg
(
"scale_factor"
)
=
1.
)
.
def
(
"assembleToLumpedMatrix"
,
&
DOFManager
::
assembleToLumpedMatrix
,
py
::
arg
(
"dof_id"
),
py
::
arg
(
"array_to_assemble"
),
py
::
arg
(
"lumped_mtx"
),
py
::
arg
(
"scale_factor"
)
=
1.
)
.
def
(
"assemblePreassembledMatrix"
,
&
DOFManager
::
assemblePreassembledMatrix
,
py
::
arg
(
"matrix_id"
),
py
::
arg
(
"terms"
))
.
def
(
"zeroResidual"
,
&
DOFManager
::
zeroResidual
);
py
::
class_
<
NonLinearSolver
,
Parsable
>
(
mod
,
"NonLinearSolver"
)
.
def
(
"set"
,
[](
NonLinearSolver
&
self
,
const
std
::
string
&
id
,
const
Real
&
val
)
{
if
(
id
==
"max_iterations"
)
{
self
.
set
(
id
,
int
(
val
));
}
else
{
self
.
set
(
id
,
val
);
}
})
.
def
(
"set"
,
[](
NonLinearSolver
&
self
,
const
std
::
string
&
id
,
const
SolveConvergenceCriteria
&
val
)
{
self
.
set
(
id
,
val
);
});
py
::
class_
<
TimeStepSolver
>
(
mod
,
"TimeStepSolver"
)
.
def
(
"getIntegrationScheme"
,
&
TimeStepSolver
::
getIntegrationScheme
);
py
::
class_
<
SolverCallback
,
PySolverCallback
>
(
mod
,
"SolverCallback"
)
.
def
(
py
::
init_alias
<
DOFManager
&>
())
.
def
(
"getMatrixType"
,
&
SolverCallback
::
getMatrixType
)
.
def
(
"assembleMatrix"
,
&
SolverCallback
::
assembleMatrix
)
.
def
(
"assembleLumpedMatrix"
,
&
SolverCallback
::
assembleLumpedMatrix
)
.
def
(
"assembleResidual"
,
[](
SolverCallback
&
self
)
{
self
.
assembleResidual
();
})
.
def
(
"predictor"
,
&
SolverCallback
::
predictor
)
.
def
(
"corrector"
,
&
SolverCallback
::
corrector
)
.
def
(
"beforeSolveStep"
,
&
SolverCallback
::
beforeSolveStep
)
.
def
(
"afterSolveStep"
,
&
SolverCallback
::
afterSolveStep
)
.
def_property_readonly
(
"dof_manager"
,
&
SolverCallback
::
getSCDOFManager
,
py
::
return_value_policy
::
reference
);
py
::
class_
<
InterceptSolverCallback
,
SolverCallback
,
PyInterceptSolverCallback
>
(
mod
,
"InterceptSolverCallback"
)
.
def
(
py
::
init_alias
<
SolverCallback
&>
());
}
}
// namespace akantu
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