Page Menu
Home
c4science
Search
Configure Global Search
Log In
Files
F65941201
bind_py_solvers.cc
No One
Temporary
Actions
Download File
Edit File
Delete File
View Transforms
Subscribe
Mute Notifications
Award Token
Subscribers
None
File Metadata
Details
File Info
Storage
Attached
Created
Fri, Jun 7, 05:50
Size
5 KB
Mime Type
text/x-c++
Expires
Sun, Jun 9, 05:50 (2 d)
Engine
blob
Format
Raw Data
Handle
18148883
Attached To
rMUSPECTRE µSpectre
bind_py_solvers.cc
View Options
/**
* file bind_py_solver.cc
*
* @author Till Junge <till.junge@epfl.ch>
*
* @date 09 Jan 2018
*
* @brief python bindings for the muSpectre solvers
*
* @section LICENSE
*
* Copyright © 2018 Till Junge
*
* µSpectre is free software; you can redistribute it and/or
* modify it under the terms of the GNU General Public License as
* published by the Free Software Foundation, either version 3, or (at
* your option) any later version.
*
* µSpectre 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
* General Public License for more details.
*
* You should have received a copy of the GNU General Public License
* along with GNU Emacs; see the file COPYING. If not, write to the
* Free Software Foundation, Inc., 59 Temple Place - Suite 330,
* Boston, MA 02111-1307, USA.
*/
#include "common/common.hh"
#include "solver/solvers.hh"
#include "solver/solver_cg.hh"
#include "solver/solver_cg_eigen.hh"
#include <pybind11/pybind11.h>
#include <pybind11/stl.h>
#include <pybind11/eigen.h>
using
namespace
muSpectre
;
namespace
py
=
pybind11
;
using
namespace
pybind11
::
literals
;
/**
* Solvers instanciated for systems with equal spatial and material dimension
*/
template
<
Dim_t
sdim
,
class
Solver
>
void
add_iterative_solver_helper
(
py
::
module
&
mod
,
std
::
string
name_start
)
{
using
sys
=
SystemBase
<
sdim
>
;
std
::
stringstream
name
{};
name
<<
name_start
<<
'_'
<<
sdim
<<
'd'
;
py
::
class_
<
Solver
,
typename
Solver
::
Parent
>
(
mod
,
name
.
str
().
c_str
())
.
def
(
py
::
init
<
sys
&
,
Real
,
Uint
,
bool
>
(),
"cell"
_a
,
"tol"
_a
,
"maxiter"
_a
,
"verbose"
_a
=
false
)
.
def
(
"name"
,
&
Solver
::
name
);
mod
.
def
(
name_start
.
c_str
(),
[](
sys
&
cell
,
Real
tol
,
Uint
maxiter
,
bool
verbose
)
{
return
std
::
make_unique
<
Solver
>
(
cell
,
tol
,
maxiter
,
verbose
);
},
"cell"
_a
,
"tol"
_a
,
"maxiter"
_a
,
"verbose"
_a
=
false
);
}
template
<
Dim_t
sdim
>
void
add_iterative_solver_dispatcher
(
py
::
module
&
mod
)
{
std
::
stringstream
name
{};
name
<<
"SolverBase_"
<<
sdim
<<
'd'
;
py
::
class_
<
SolverBase
<
sdim
>>
(
mod
,
name
.
str
().
c_str
());
add_iterative_solver_helper
<
sdim
,
SolverCG
<
sdim
>>
(
mod
,
"SolverCG"
);
add_iterative_solver_helper
<
sdim
,
SolverCGEigen
<
sdim
>>
(
mod
,
"SolverCGEigen"
);
add_iterative_solver_helper
<
sdim
,
SolverGMRESEigen
<
sdim
>>
(
mod
,
"SolverGMRESEigen"
);
add_iterative_solver_helper
<
sdim
,
SolverBiCGSTABEigen
<
sdim
>>
(
mod
,
"SolverBiCGSTABEigen"
);
add_iterative_solver_helper
<
sdim
,
SolverDGMRESEigen
<
sdim
>>
(
mod
,
"SolverDGMRESEigen"
);
add_iterative_solver_helper
<
sdim
,
SolverMINRESEigen
<
sdim
>>
(
mod
,
"SolverMINRESEigen"
);
}
void
add_iterative_solver
(
py
::
module
&
mod
)
{
add_iterative_solver_dispatcher
<
twoD
>
(
mod
);
add_iterative_solver_dispatcher
<
threeD
>
(
mod
);
}
template
<
Dim_t
sdim
>
void
add_newton_cg_helper
(
py
::
module
&
mod
)
{
const
char
name
[]{
"newton_cg"
};
constexpr
Dim_t
mdim
{
sdim
};
using
sys
=
SystemBase
<
sdim
,
mdim
>
;
using
solver
=
SolverBase
<
sdim
,
mdim
>
;
using
grad
=
Grad_t
<
sdim
>
;
using
grad_vec
=
GradIncrements
<
sdim
>
;
mod
.
def
(
name
,
[](
sys
&
s
,
const
grad
&
g
,
solver
&
so
,
Real
nt
,
Dim_t
verb
)
->
OptimizeResult
{
return
newton_cg
(
s
,
g
,
so
,
nt
,
verb
);
},
"system"
_a
,
"ΔF₀"
_a
,
"solver"
_a
,
"newton_tol"
_a
,
"verbose"
_a
=
0
);
mod
.
def
(
name
,
[](
sys
&
s
,
const
grad_vec
&
g
,
solver
&
so
,
Real
nt
,
Dim_t
verb
)
->
std
::
vector
<
OptimizeResult
>
{
return
newton_cg
(
s
,
g
,
so
,
nt
,
verb
);
},
"system"
_a
,
"ΔF₀"
_a
,
"solver"
_a
,
"newton_tol"
_a
,
"verbose"
_a
=
0
);
}
template
<
Dim_t
sdim
>
void
add_de_geus_helper
(
py
::
module
&
mod
)
{
const
char
name
[]{
"de_geus"
};
constexpr
Dim_t
mdim
{
sdim
};
using
sys
=
SystemBase
<
sdim
,
mdim
>
;
using
solver
=
SolverBase
<
sdim
,
mdim
>
;
using
grad
=
Grad_t
<
sdim
>
;
using
grad_vec
=
GradIncrements
<
sdim
>
;
mod
.
def
(
name
,
[](
sys
&
s
,
const
grad
&
g
,
solver
&
so
,
Real
nt
,
Dim_t
verb
)
->
OptimizeResult
{
return
de_geus
(
s
,
g
,
so
,
nt
,
verb
);
},
"system"
_a
,
"ΔF₀"
_a
,
"solver"
_a
,
"newton_tol"
_a
,
"verbose"
_a
=
0
);
mod
.
def
(
name
,
[](
sys
&
s
,
const
grad_vec
&
g
,
solver
&
so
,
Real
nt
,
Dim_t
verb
)
->
std
::
vector
<
OptimizeResult
>
{
return
de_geus
(
s
,
g
,
so
,
nt
,
verb
);
},
"system"
_a
,
"ΔF₀"
_a
,
"solver"
_a
,
"newton_tol"
_a
,
"verbose"
_a
=
0
);
}
template
<
Dim_t
dim
>
void
add_solver_helper
(
py
::
module
&
mod
)
{
add_newton_cg_helper
<
dim
>
(
mod
);
add_de_geus_helper
<
dim
>
(
mod
);
}
void
add_solvers
(
py
::
module
&
mod
)
{
auto
solvers
{
mod
.
def_submodule
(
"solvers"
)};
solvers
.
doc
()
=
"bindings for solvers"
;
py
::
class_
<
OptimizeResult
>
(
mod
,
"OptimizeResult"
)
.
def_readwrite
(
"grad"
,
&
OptimizeResult
::
grad
)
.
def_readwrite
(
"stress"
,
&
OptimizeResult
::
stress
)
.
def_readwrite
(
"success"
,
&
OptimizeResult
::
success
)
.
def_readwrite
(
"status"
,
&
OptimizeResult
::
status
)
.
def_readwrite
(
"message"
,
&
OptimizeResult
::
message
)
.
def_readwrite
(
"nb_it"
,
&
OptimizeResult
::
nb_it
)
.
def_readwrite
(
"nb_fev"
,
&
OptimizeResult
::
nb_fev
);
add_iterative_solver
(
solvers
);
add_solver_helper
<
twoD
>
(
solvers
);
add_solver_helper
<
threeD
>
(
solvers
);
}
Event Timeline
Log In to Comment