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rAKA akantu
dof_manager_default.cc
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/**
* @file dof_manager_default.cc
*
* @author Nicolas Richart <nicolas.richart@epfl.ch>
*
* @date creation: Tue Aug 18 2015
* @date last modification: Thu Feb 08 2018
*
* @brief Implementation of the default DOFManager
*
*
* Copyright (©) 2015-2018 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 "dof_manager_default.hh"
#include "communicator.hh"
#include "dof_synchronizer.hh"
#include "element_group.hh"
#include "non_linear_solver_default.hh"
#include "periodic_node_synchronizer.hh"
#include "solver_vector_default.hh"
#include "solver_vector_distributed.hh"
#include "sparse_matrix_aij.hh"
#include "time_step_solver_default.hh"
/* -------------------------------------------------------------------------- */
#include <algorithm>
#include <memory>
#include <numeric>
#include <unordered_map>
/* -------------------------------------------------------------------------- */
namespace
akantu
{
/* -------------------------------------------------------------------------- */
DOFManagerDefault
::
DOFManagerDefault
(
const
ID
&
id
)
:
DOFManager
(
id
),
synchronizer
(
nullptr
)
{
residual
=
std
::
make_unique
<
SolverVectorDefault
>
(
*
this
,
std
::
string
(
id
+
":residual"
));
solution
=
std
::
make_unique
<
SolverVectorDefault
>
(
*
this
,
std
::
string
(
id
+
":solution"
));
data_cache
=
std
::
make_unique
<
SolverVectorDefault
>
(
*
this
,
std
::
string
(
id
+
":data_cache"
));
}
/* -------------------------------------------------------------------------- */
DOFManagerDefault
::
DOFManagerDefault
(
Mesh
&
mesh
,
const
ID
&
id
)
:
DOFManager
(
mesh
,
id
),
synchronizer
(
nullptr
)
{
if
(
this
->
mesh
->
isDistributed
())
{
this
->
synchronizer
=
std
::
make_unique
<
DOFSynchronizer
>
(
*
this
,
this
->
id
+
":dof_synchronizer"
);
residual
=
std
::
make_unique
<
SolverVectorDistributed
>
(
*
this
,
std
::
string
(
id
+
":residual"
));
solution
=
std
::
make_unique
<
SolverVectorDistributed
>
(
*
this
,
std
::
string
(
id
+
":solution"
));
data_cache
=
std
::
make_unique
<
SolverVectorDistributed
>
(
*
this
,
std
::
string
(
id
+
":data_cache"
));
}
else
{
residual
=
std
::
make_unique
<
SolverVectorDefault
>
(
*
this
,
std
::
string
(
id
+
":residual"
));
solution
=
std
::
make_unique
<
SolverVectorDefault
>
(
*
this
,
std
::
string
(
id
+
":solution"
));
data_cache
=
std
::
make_unique
<
SolverVectorDefault
>
(
*
this
,
std
::
string
(
id
+
":data_cache"
));
}
}
/* -------------------------------------------------------------------------- */
DOFManagerDefault
::~
DOFManagerDefault
()
=
default
;
/* -------------------------------------------------------------------------- */
void
DOFManagerDefault
::
makeConsistentForPeriodicity
(
const
ID
&
dof_id
,
SolverVector
&
array
)
{
auto
&
dof_data
=
this
->
getDOFDataTyped
<
DOFDataDefault
>
(
dof_id
);
if
(
dof_data
.
support_type
!=
_dst_nodal
)
{
return
;
}
if
(
not
mesh
->
isPeriodic
())
{
return
;
}
this
->
mesh
->
getPeriodicNodeSynchronizer
()
.
reduceSynchronizeWithPBCSlaves
<
AddOperation
>
(
aka
::
as_type
<
SolverVectorDefault
>
(
array
).
getVector
());
}
/* -------------------------------------------------------------------------- */
template
<
typename
T
>
void
DOFManagerDefault
::
assembleToGlobalArray
(
const
ID
&
dof_id
,
const
Array
<
T
>
&
array_to_assemble
,
Array
<
T
>
&
global_array
,
T
scale_factor
)
{
AKANTU_DEBUG_IN
();
auto
&
dof_data
=
this
->
getDOFDataTyped
<
DOFDataDefault
>
(
dof_id
);
AKANTU_DEBUG_ASSERT
(
dof_data
.
local_equation_number
.
size
()
==
array_to_assemble
.
size
()
*
array_to_assemble
.
getNbComponent
(),
"The array to assemble does not have a correct size."
<<
" ("
<<
array_to_assemble
.
getID
()
<<
")"
);
if
(
dof_data
.
support_type
==
_dst_nodal
and
mesh
->
isPeriodic
())
{
for
(
auto
&&
data
:
zip
(
dof_data
.
local_equation_number
,
dof_data
.
associated_nodes
,
make_view
(
array_to_assemble
)))
{
auto
&&
equ_num
=
std
::
get
<
0
>
(
data
);
// auto && node = std::get<1>(data);
auto
&&
arr
=
std
::
get
<
2
>
(
data
);
// Guillaume to Nico:
// This filter of periodic slave should not be.
// Indeed you want to get the contribution even
// from periodic slaves and cumulate to the right
// equation number.
global_array
(
equ_num
)
+=
scale_factor
*
(
arr
);
// scale_factor * (arr) * (not this->mesh->isPeriodicSlave(node));
}
}
else
{
for
(
auto
&&
data
:
zip
(
dof_data
.
local_equation_number
,
make_view
(
array_to_assemble
)))
{
auto
&&
equ_num
=
std
::
get
<
0
>
(
data
);
auto
&&
arr
=
std
::
get
<
1
>
(
data
);
global_array
(
equ_num
)
+=
scale_factor
*
(
arr
);
}
}
AKANTU_DEBUG_OUT
();
}
/* -------------------------------------------------------------------------- */
void
DOFManagerDefault
::
assembleToGlobalArray
(
const
ID
&
dof_id
,
const
Array
<
Real
>
&
array_to_assemble
,
SolverVector
&
global_array_v
,
Real
scale_factor
)
{
assembleToGlobalArray
(
dof_id
,
array_to_assemble
,
aka
::
as_type
<
SolverVectorDefault
>
(
global_array_v
).
getVector
(),
scale_factor
);
}
/* -------------------------------------------------------------------------- */
DOFManagerDefault
::
DOFDataDefault
::
DOFDataDefault
(
const
ID
&
dof_id
)
:
DOFData
(
dof_id
)
{}
/* -------------------------------------------------------------------------- */
auto
DOFManagerDefault
::
getNewDOFData
(
const
ID
&
dof_id
)
->
std
::
unique_ptr
<
DOFData
>
{
return
std
::
make_unique
<
DOFDataDefault
>
(
dof_id
);
}
/* -------------------------------------------------------------------------- */
std
::
tuple
<
UInt
,
UInt
,
UInt
>
DOFManagerDefault
::
registerDOFsInternal
(
const
ID
&
dof_id
,
Array
<
Real
>
&
dofs_array
)
{
auto
ret
=
DOFManager
::
registerDOFsInternal
(
dof_id
,
dofs_array
);
// update the synchronizer if needed
if
(
this
->
synchronizer
)
{
this
->
synchronizer
->
registerDOFs
(
dof_id
);
}
return
ret
;
}
/* -------------------------------------------------------------------------- */
SparseMatrix
&
DOFManagerDefault
::
getNewMatrix
(
const
ID
&
id
,
const
MatrixType
&
matrix_type
)
{
return
this
->
registerSparseMatrix
<
SparseMatrixAIJ
>
(
*
this
,
id
,
matrix_type
);
}
/* -------------------------------------------------------------------------- */
SparseMatrix
&
DOFManagerDefault
::
getNewMatrix
(
const
ID
&
id
,
const
ID
&
matrix_to_copy_id
)
{
return
this
->
registerSparseMatrix
<
SparseMatrixAIJ
>
(
id
,
matrix_to_copy_id
);
}
/* -------------------------------------------------------------------------- */
SolverVector
&
DOFManagerDefault
::
getNewLumpedMatrix
(
const
ID
&
id
)
{
return
this
->
registerLumpedMatrix
<
SolverVectorDefault
>
(
*
this
,
id
);
}
/* -------------------------------------------------------------------------- */
SparseMatrixAIJ
&
DOFManagerDefault
::
getMatrix
(
const
ID
&
id
)
{
auto
&
matrix
=
DOFManager
::
getMatrix
(
id
);
return
aka
::
as_type
<
SparseMatrixAIJ
>
(
matrix
);
}
/* -------------------------------------------------------------------------- */
NonLinearSolver
&
DOFManagerDefault
::
getNewNonLinearSolver
(
const
ID
&
id
,
const
NonLinearSolverType
&
type
)
{
switch
(
type
)
{
#if defined(AKANTU_USE_MUMPS)
case
NonLinearSolverType
::
_newton_raphson:
/* FALLTHRU */
/* [[fallthrough]]; un-comment when compiler will get it */
case
NonLinearSolverType
::
_newton_raphson_modified:
{
return
this
->
registerNonLinearSolver
<
NonLinearSolverNewtonRaphson
>
(
*
this
,
id
,
type
);
}
case
NonLinearSolverType
::
_linear:
{
return
this
->
registerNonLinearSolver
<
NonLinearSolverLinear
>
(
*
this
,
id
,
type
);
}
#endif
case
NonLinearSolverType
::
_lumped:
{
return
this
->
registerNonLinearSolver
<
NonLinearSolverLumped
>
(
*
this
,
id
,
type
);
}
default
:
AKANTU_EXCEPTION
(
"The asked type of non linear solver is not supported by "
"this dof manager"
);
}
}
/* -------------------------------------------------------------------------- */
TimeStepSolver
&
DOFManagerDefault
::
getNewTimeStepSolver
(
const
ID
&
id
,
const
TimeStepSolverType
&
type
,
NonLinearSolver
&
non_linear_solver
,
SolverCallback
&
solver_callback
)
{
return
this
->
registerTimeStepSolver
<
TimeStepSolverDefault
>
(
*
this
,
id
,
type
,
non_linear_solver
,
solver_callback
);
}
/* -------------------------------------------------------------------------- */
template
<
typename
T
>
void
DOFManagerDefault
::
getArrayPerDOFs
(
const
ID
&
dof_id
,
const
Array
<
T
>
&
global_array
,
Array
<
T
>
&
local_array
)
const
{
AKANTU_DEBUG_IN
();
const
Array
<
Int
>
&
equation_number
=
this
->
getLocalEquationsNumbers
(
dof_id
);
UInt
nb_degree_of_freedoms
=
equation_number
.
size
();
local_array
.
resize
(
nb_degree_of_freedoms
/
local_array
.
getNbComponent
());
auto
loc_it
=
local_array
.
begin_reinterpret
(
nb_degree_of_freedoms
);
auto
equ_it
=
equation_number
.
begin
();
for
(
UInt
d
=
0
;
d
<
nb_degree_of_freedoms
;
++
d
,
++
loc_it
,
++
equ_it
)
{
(
*
loc_it
)
=
global_array
(
*
equ_it
);
}
AKANTU_DEBUG_OUT
();
}
/* -------------------------------------------------------------------------- */
void
DOFManagerDefault
::
getArrayPerDOFs
(
const
ID
&
dof_id
,
const
SolverVector
&
global_array
,
Array
<
Real
>
&
local_array
)
{
getArrayPerDOFs
(
dof_id
,
aka
::
as_type
<
SolverVectorDefault
>
(
global_array
).
getVector
(),
local_array
);
}
/* -------------------------------------------------------------------------- */
void
DOFManagerDefault
::
assembleLumpedMatMulVectToResidual
(
const
ID
&
dof_id
,
const
ID
&
A_id
,
const
Array
<
Real
>
&
x
,
Real
scale_factor
)
{
const
Array
<
Real
>
&
A
=
this
->
getLumpedMatrix
(
A_id
);
auto
&
cache
=
aka
::
as_type
<
SolverVectorArray
>
(
*
this
->
data_cache
);
cache
.
zero
();
this
->
assembleToGlobalArray
(
dof_id
,
x
,
cache
.
getVector
(),
scale_factor
);
for
(
auto
&&
data
:
zip
(
make_view
(
A
),
make_view
(
cache
.
getVector
()),
make_view
(
this
->
getResidualArray
())))
{
const
auto
&
A
=
std
::
get
<
0
>
(
data
);
const
auto
&
x
=
std
::
get
<
1
>
(
data
);
auto
&
r
=
std
::
get
<
2
>
(
data
);
r
+=
A
*
x
;
}
}
/* -------------------------------------------------------------------------- */
void
DOFManagerDefault
::
assembleElementalMatricesToMatrix
(
const
ID
&
matrix_id
,
const
ID
&
dof_id
,
const
Array
<
Real
>
&
elementary_mat
,
ElementType
type
,
GhostType
ghost_type
,
const
MatrixType
&
elemental_matrix_type
,
const
Array
<
UInt
>
&
filter_elements
)
{
this
->
addToProfile
(
matrix_id
,
dof_id
,
type
,
ghost_type
);
auto
&
A
=
getMatrix
(
matrix_id
);
DOFManager
::
assembleElementalMatricesToMatrix_
(
A
,
dof_id
,
elementary_mat
,
type
,
ghost_type
,
elemental_matrix_type
,
filter_elements
);
}
/* -------------------------------------------------------------------------- */
void
DOFManagerDefault
::
assemblePreassembledMatrix
(
const
ID
&
dof_id_m
,
const
ID
&
dof_id_n
,
const
ID
&
matrix_id
,
const
TermsToAssemble
&
terms
)
{
auto
&
A
=
getMatrix
(
matrix_id
);
DOFManager
::
assemblePreassembledMatrix_
(
A
,
dof_id_m
,
dof_id_n
,
terms
);
}
/* -------------------------------------------------------------------------- */
void
DOFManagerDefault
::
assembleMatMulVectToArray
(
const
ID
&
dof_id
,
const
ID
&
A_id
,
const
Array
<
Real
>
&
x
,
Array
<
Real
>
&
array
,
Real
scale_factor
)
{
if
(
mesh
->
isDistributed
())
{
DOFManager
::
assembleMatMulVectToArray_
<
SolverVectorDistributed
>
(
dof_id
,
A_id
,
x
,
array
,
scale_factor
);
}
else
{
DOFManager
::
assembleMatMulVectToArray_
<
SolverVectorDefault
>
(
dof_id
,
A_id
,
x
,
array
,
scale_factor
);
}
}
/* -------------------------------------------------------------------------- */
void
DOFManagerDefault
::
addToProfile
(
const
ID
&
matrix_id
,
const
ID
&
dof_id
,
ElementType
type
,
GhostType
ghost_type
)
{
AKANTU_DEBUG_IN
();
const
auto
&
dof_data
=
this
->
getDOFData
(
dof_id
);
if
(
dof_data
.
support_type
!=
_dst_nodal
)
{
return
;
}
auto
mat_dof
=
std
::
make_pair
(
matrix_id
,
dof_id
);
auto
type_pair
=
std
::
make_pair
(
type
,
ghost_type
);
auto
prof_it
=
this
->
matrix_profiled_dofs
.
find
(
mat_dof
);
if
(
prof_it
!=
this
->
matrix_profiled_dofs
.
end
()
&&
std
::
find
(
prof_it
->
second
.
begin
(),
prof_it
->
second
.
end
(),
type_pair
)
!=
prof_it
->
second
.
end
())
{
return
;
}
auto
nb_degree_of_freedom_per_node
=
dof_data
.
dof
->
getNbComponent
();
const
auto
&
equation_number
=
this
->
getLocalEquationsNumbers
(
dof_id
);
auto
&
A
=
this
->
getMatrix
(
matrix_id
);
A
.
resize
(
system_size
);
auto
size
=
A
.
size
();
auto
nb_nodes_per_element
=
Mesh
::
getNbNodesPerElement
(
type
);
const
auto
&
connectivity
=
this
->
mesh
->
getConnectivity
(
type
,
ghost_type
);
auto
cbegin
=
connectivity
.
begin
(
nb_nodes_per_element
);
auto
cit
=
cbegin
;
auto
nb_elements
=
connectivity
.
size
();
UInt
*
ge_it
=
nullptr
;
if
(
dof_data
.
group_support
!=
"__mesh__"
)
{
const
auto
&
group_elements
=
this
->
mesh
->
getElementGroup
(
dof_data
.
group_support
)
.
getElements
(
type
,
ghost_type
);
ge_it
=
group_elements
.
storage
();
nb_elements
=
group_elements
.
size
();
}
UInt
size_mat
=
nb_nodes_per_element
*
nb_degree_of_freedom_per_node
;
Vector
<
Int
>
element_eq_nb
(
size_mat
);
for
(
UInt
e
=
0
;
e
<
nb_elements
;
++
e
)
{
if
(
ge_it
!=
nullptr
)
{
cit
=
cbegin
+
*
ge_it
;
}
this
->
extractElementEquationNumber
(
equation_number
,
*
cit
,
nb_degree_of_freedom_per_node
,
element_eq_nb
);
std
::
transform
(
element_eq_nb
.
storage
(),
element_eq_nb
.
storage
()
+
element_eq_nb
.
size
(),
element_eq_nb
.
storage
(),
[
&
](
auto
&
local
)
{
return
this
->
localToGlobalEquationNumber
(
local
);
});
if
(
ge_it
!=
nullptr
)
{
++
ge_it
;
}
else
{
++
cit
;
}
for
(
UInt
i
=
0
;
i
<
size_mat
;
++
i
)
{
UInt
c_irn
=
element_eq_nb
(
i
);
if
(
c_irn
<
size
)
{
for
(
UInt
j
=
0
;
j
<
size_mat
;
++
j
)
{
UInt
c_jcn
=
element_eq_nb
(
j
);
if
(
c_jcn
<
size
)
{
A
.
add
(
c_irn
,
c_jcn
);
}
}
}
}
}
this
->
matrix_profiled_dofs
[
mat_dof
].
push_back
(
type_pair
);
AKANTU_DEBUG_OUT
();
}
/* -------------------------------------------------------------------------- */
Array
<
Real
>
&
DOFManagerDefault
::
getSolutionArray
()
{
return
dynamic_cast
<
SolverVectorDefault
*>
(
this
->
solution
.
get
())
->
getVector
();
}
/* -------------------------------------------------------------------------- */
const
Array
<
Real
>
&
DOFManagerDefault
::
getResidualArray
()
const
{
return
dynamic_cast
<
SolverVectorDefault
*>
(
this
->
residual
.
get
())
->
getVector
();
}
/* -------------------------------------------------------------------------- */
Array
<
Real
>
&
DOFManagerDefault
::
getResidualArray
()
{
return
dynamic_cast
<
SolverVectorDefault
*>
(
this
->
residual
.
get
())
->
getVector
();
}
/* -------------------------------------------------------------------------- */
void
DOFManagerDefault
::
onNodesAdded
(
const
Array
<
UInt
>
&
nodes_list
,
const
NewNodesEvent
&
event
)
{
DOFManager
::
onNodesAdded
(
nodes_list
,
event
);
if
(
this
->
synchronizer
)
{
this
->
synchronizer
->
onNodesAdded
(
nodes_list
);
}
}
/* -------------------------------------------------------------------------- */
void
DOFManagerDefault
::
resizeGlobalArrays
()
{
DOFManager
::
resizeGlobalArrays
();
this
->
global_blocked_dofs
.
resize
(
this
->
local_system_size
,
1
);
this
->
previous_global_blocked_dofs
.
resize
(
this
->
local_system_size
,
1
);
matrix_profiled_dofs
.
clear
();
}
/* -------------------------------------------------------------------------- */
void
DOFManagerDefault
::
updateGlobalBlockedDofs
()
{
DOFManager
::
updateGlobalBlockedDofs
();
if
(
this
->
global_blocked_dofs_release
==
this
->
previous_global_blocked_dofs_release
)
{
return
;
}
global_blocked_dofs_uint
.
resize
(
local_system_size
);
global_blocked_dofs_uint
.
set
(
false
);
for
(
const
auto
&
dof
:
global_blocked_dofs
)
{
global_blocked_dofs_uint
[
dof
]
=
true
;
}
}
/* -------------------------------------------------------------------------- */
Array
<
bool
>
&
DOFManagerDefault
::
getBlockedDOFs
()
{
return
global_blocked_dofs_uint
;
}
/* -------------------------------------------------------------------------- */
const
Array
<
bool
>
&
DOFManagerDefault
::
getBlockedDOFs
()
const
{
return
global_blocked_dofs_uint
;
}
/* -------------------------------------------------------------------------- */
static
bool
dof_manager_is_registered
[[
gnu
::
unused
]]
=
DOFManagerFactory
::
getInstance
().
registerAllocator
(
"default"
,
[](
Mesh
&
mesh
,
const
ID
&
id
)
->
std
::
unique_ptr
<
DOFManager
>
{
return
std
::
make_unique
<
DOFManagerDefault
>
(
mesh
,
id
);
});
static
bool
dof_manager_is_registered_mumps
[[
gnu
::
unused
]]
=
DOFManagerFactory
::
getInstance
().
registerAllocator
(
"mumps"
,
[](
Mesh
&
mesh
,
const
ID
&
id
)
->
std
::
unique_ptr
<
DOFManager
>
{
return
std
::
make_unique
<
DOFManagerDefault
>
(
mesh
,
id
);
});
}
// namespace akantu
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