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test_model_solver_dynamic_petsc.cc
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rAKA akantu
test_model_solver_dynamic_petsc.cc
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/**
* @file test_model_solver_dynamic.cc
*
* @author Nicolas Richart <nicolas.richart@epfl.ch>
*
* @date creation: Wed Apr 13 2016
* @date last modification: Tue Feb 20 2018
*
* @brief Test default dof manager
*
* @section LICENSE
*
* Copyright (©) 2016-2018 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 "communicator.hh"
#include "element_group.hh"
#include "mesh.hh"
#include "mesh_accessor.hh"
#include "non_linear_solver.hh"
/* -------------------------------------------------------------------------- */
#include "boundary_condition_functor.hh"
#include "mpi_communicator_data.hh"
/* -------------------------------------------------------------------------- */
#include "dumpable_inline_impl.hh"
#include "dumper_element_partition.hh"
#include "dumper_iohelper_paraview.hh"
/* -------------------------------------------------------------------------- */
#include <fstream>
/* -------------------------------------------------------------------------- */
#include <petscmat.h>
#include <petscsnes.h>
#include <petscvec.h>
/* -------------------------------------------------------------------------- */
#ifndef EXPLICIT
#define EXPLICIT true
#endif
template
<
typename
func
>
void
CHECK_ERR_CXX
(
func
&&
func_
,
PetscErrorCode
ierr
)
{
if
(
PetscUnlikely
(
ierr
!=
0
))
{
const
char
*
desc
;
PetscErrorMessage
(
ierr
,
&
desc
,
nullptr
);
AKANTU_EXCEPTION
(
"Error in PETSc call to
\'
"
<<
func_
<<
"
\'
: "
<<
desc
);
}
}
using
namespace
akantu
;
static
void
genMesh
(
Mesh
&
mesh
,
UInt
nb_nodes
);
class
MyModel
{
public
:
MyModel
(
Real
F
,
Mesh
&
mesh
,
bool
lumped
)
:
nb_dofs
(
mesh
.
getNbNodes
()),
nb_elements
(
mesh
.
getNbElement
(
_segment_2
)),
lumped
(
lumped
),
E
(
1.
),
A
(
1.
),
rho
(
1.
),
mesh
(
mesh
),
displacement
(
nb_dofs
,
1
,
"disp"
),
velocity
(
nb_dofs
,
1
,
"velo"
),
acceleration
(
nb_dofs
,
1
,
"accel"
),
blocked
(
nb_dofs
,
1
,
"blocked"
),
forces
(
nb_dofs
,
1
,
"force_ext"
),
internal_forces
(
nb_dofs
,
1
,
"force_int"
),
stresses
(
nb_elements
,
1
,
"stress"
),
strains
(
nb_elements
,
1
,
"strain"
),
initial_lengths
(
nb_elements
,
1
,
"L0"
)
{
auto
n_global
=
mesh
.
getNbGlobalNodes
();
int
n_local
=
0
;
std
::
vector
<
PetscInt
>
nodes_global_ids
(
nb_dofs
);
for
(
auto
&&
data
:
enumerate
(
nodes_global_ids
))
{
auto
n
=
std
::
get
<
0
>
(
data
);
n_local
+=
mesh
.
isLocalOrMasterNode
(
n
);
std
::
get
<
1
>
(
data
)
=
mesh
.
getNodeGlobalId
(
n
);
}
mpi_comm
=
dynamic_cast
<
MPICommunicatorData
&>
(
mesh
.
getCommunicator
().
getCommunicatorData
())
.
getMPICommunicator
();
MeshAccessor
mesh_accessor
(
mesh
);
ierr
=
ISLocalToGlobalMappingCreate
(
mpi_comm
,
1
,
mesh
.
getNbNodes
(),
nodes_global_ids
.
data
(),
PETSC_COPY_VALUES
,
&
petsc_local_to_global
);
CHECK_ERR_CXX
(
"ISLocalToGlobalMappingCreate"
,
ierr
);
auto
setName
=
[](
auto
&&
Obj
,
auto
&&
name
)
{
PetscObjectSetName
(
reinterpret_cast
<
PetscObject
>
(
Obj
),
name
);
};
ierr
=
VecCreate
(
mpi_comm
,
&
rhs
);
ierr
=
VecSetSizes
(
rhs
,
n_local
,
n_global
);
ierr
=
VecSetFromOptions
(
rhs
);
ierr
=
VecSetLocalToGlobalMapping
(
rhs
,
petsc_local_to_global
);
setName
(
rhs
,
"rhs"
);
ierr
=
VecDuplicate
(
rhs
,
&
x
);
ierr
=
VecDuplicate
(
rhs
,
&
x_save
);
ierr
=
VecDuplicate
(
rhs
,
&
dx
);
ierr
=
VecDuplicate
(
rhs
,
&
f_int
);
ierr
=
VecDuplicate
(
rhs
,
&
f_dirichlet
);
setName
(
x
,
"x"
);
setName
(
x_save
,
"x save"
);
setName
(
dx
,
"dx"
);
setName
(
f_int
,
"f_int"
);
setName
(
f_dirichlet
,
"f_dirichlet"
);
ierr
=
MatCreate
(
mpi_comm
,
&
M
);
ierr
=
MatSetSizes
(
M
,
n_local
,
n_local
,
n_global
,
n_global
);
ierr
=
MatSetFromOptions
(
M
);
ierr
=
MatSetOption
(
M
,
MAT_SYMMETRIC
,
PETSC_TRUE
);
ierr
=
MatSetOption
(
M
,
MAT_ROW_ORIENTED
,
PETSC_TRUE
);
ierr
=
MatSetUp
(
M
);
ierr
=
MatSetLocalToGlobalMapping
(
M
,
petsc_local_to_global
,
petsc_local_to_global
);
setName
(
M
,
"M"
);
assembleMass
();
ierr
=
MatDuplicate
(
M
,
MAT_DO_NOT_COPY_VALUES
,
&
K
);
setName
(
K
,
"K"
);
ierr
=
MatDuplicate
(
M
,
MAT_DO_NOT_COPY_VALUES
,
&
J
);
setName
(
J
,
"J"
);
ierr
=
SNESCreate
(
mpi_comm
,
&
snes
);
ierr
=
SNESSetFromOptions
(
snes
);
ierr
=
SNESSetFunction
(
snes
,
rhs
,
MyModel
::
FormFunction
,
this
);
ierr
=
SNESSetJacobian
(
snes
,
J
,
J
,
MyModel
::
FormJacobian
,
this
);
PetscViewerPushFormat
(
PETSC_VIEWER_STDOUT_WORLD
,
PETSC_VIEWER_ASCII_INDEX
);
displacement
.
set
(
0.
);
velocity
.
set
(
0.
);
acceleration
.
set
(
0.
);
forces
.
set
(
0.
);
blocked
.
set
(
false
);
blocked
(
0
,
0
)
=
true
;
blocked
(
nb_dofs
-
1
,
0
)
=
true
;
displacement
(
0
,
0
)
=
0
;
displacement
(
nb_dofs
-
1
,
0
)
=
1
;
for
(
auto
&&
data
:
zip
(
make_view
(
this
->
mesh
.
getConnectivity
(
_segment_2
),
2
),
make_view
(
this
->
initial_lengths
)))
{
const
auto
&
conn
=
std
::
get
<
0
>
(
data
);
auto
&
L
=
std
::
get
<
1
>
(
data
);
auto
p1
=
this
->
mesh
.
getNodes
()(
conn
(
0
),
_x
);
auto
p2
=
this
->
mesh
.
getNodes
()(
conn
(
1
),
_x
);
L
=
std
::
abs
(
p2
-
p1
);
}
}
// static PetscErrorCode SNESMonitor(SNES snes,PetscInt its,PetscReal
// fnorm,void *ctx) {
// auto & _this = *reinterpret_cast<MyModel *>(ctx);
// //SNESMonitorDefault(snes, its, fnorm, PETSC_VIEWER_STDOUT_WORLD);
// }
static
PetscErrorCode
FormFunction
(
SNES
/*snes*/
,
Vec
/*dx*/
,
Vec
/*f*/
,
void
*
ctx
)
{
auto
&
_this
=
*
reinterpret_cast
<
MyModel
*>
(
ctx
);
_this
.
assembleResidual
();
return
0
;
}
static
PetscErrorCode
FormJacobian
(
SNES
/*snes*/
,
Vec
/*dx*/
,
Mat
/*J*/
,
Mat
/*P*/
,
void
*
ctx
)
{
auto
&
_this
=
*
reinterpret_cast
<
MyModel
*>
(
ctx
);
_this
.
assembleJacobian
();
return
0
;
}
~
MyModel
()
{
ierr
=
MatDestroy
(
&
M
);
ierr
=
MatDestroy
(
&
K
);
ierr
=
MatDestroy
(
&
J
);
ierr
=
VecDestroy
(
&
rhs
);
ierr
=
VecDestroy
(
&
x
);
ierr
=
VecDestroy
(
&
dx
);
ierr
=
VecDestroy
(
&
x_save
);
ierr
=
VecDestroy
(
&
f_int
);
PetscFinalize
();
}
void
solveStep
()
{
std
::
cout
<<
"solveStep"
<<
std
::
endl
;
copy
(
x_save
,
displacement
);
ierr
=
SNESSolve
(
snes
,
NULL
,
dx
);
CHECK_ERR_CXX
(
"SNESSolve"
,
ierr
);
setSolutionToDisplacement
();
assembleResidual
();
}
void
applyBC
()
{
std
::
vector
<
PetscInt
>
rows
;
for
(
auto
&&
data
:
enumerate
(
blocked
))
{
if
(
std
::
get
<
1
>
(
data
))
{
rows
.
push_back
(
std
::
get
<
0
>
(
data
));
}
}
copy
(
x
,
displacement
);
ierr
=
MatZeroRowsColumnsLocal
(
J
,
rows
.
size
(),
rows
.
data
(),
1.
,
x
,
f_dirichlet
);
VecView
(
f_dirichlet
,
PETSC_VIEWER_STDOUT_WORLD
);
CHECK_ERR_CXX
(
"MatZeroRowsColumnsLocal"
,
ierr
);
}
void
setSolutionToDisplacement
()
{
std
::
cout
<<
"setSolutionToDisplacement"
<<
std
::
endl
;
ierr
=
VecWAXPY
(
x
,
1
,
x_save
,
dx
);
copy
(
displacement
,
x
);
}
void
assembleJacobian
()
{
std
::
cout
<<
"assembleJacobian"
<<
std
::
endl
;
setSolutionToDisplacement
();
assembleStiffness
();
ierr
=
MatZeroEntries
(
J
);
CHECK_ERR_CXX
(
"MatZeroEntries"
,
ierr
);
ierr
=
MatAXPY
(
J
,
1.
,
K
,
SAME_NONZERO_PATTERN
);
CHECK_ERR_CXX
(
"MatAXPY"
,
ierr
);
MatView
(
J
,
PETSC_VIEWER_STDOUT_WORLD
);
applyBC
();
MatView
(
J
,
PETSC_VIEWER_STDOUT_WORLD
);
}
void
assembleMass
()
{
std
::
cout
<<
"assembleMass"
<<
std
::
endl
;
ierr
=
MatZeroEntries
(
M
);
CHECK_ERR_CXX
(
"MatZeroEntries"
,
ierr
);
Array
<
Real
>
m_all_el
(
this
->
nb_elements
,
4
);
Matrix
<
Real
>
m
(
2
,
2
);
m
(
0
,
0
)
=
m
(
1
,
1
)
=
2
;
m
(
0
,
1
)
=
m
(
1
,
0
)
=
1
;
// under integrated
// m(0, 0) = m(1, 1) = 3./2.;
// m(0, 1) = m(1, 0) = 3./2.;
// lumping the mass matrix
// m(0, 0) += m(0, 1);
// m(1, 1) += m(1, 0);
// m(0, 1) = m(1, 0) = 0;
for
(
auto
&&
data
:
zip
(
make_view
(
this
->
mesh
.
getConnectivity
(
_segment_2
),
2
),
make_view
(
m_all_el
,
2
,
2
)))
{
const
auto
&
conn
=
std
::
get
<
0
>
(
data
);
auto
&
m_el
=
std
::
get
<
1
>
(
data
);
UInt
n1
=
conn
(
0
);
UInt
n2
=
conn
(
1
);
Real
p1
=
this
->
mesh
.
getNodes
()(
n1
,
_x
);
Real
p2
=
this
->
mesh
.
getNodes
()(
n2
,
_x
);
Real
L
=
std
::
abs
(
p2
-
p1
);
m_el
=
m
;
m_el
*=
rho
*
A
*
L
/
6.
;
Vector
<
Int
>
conn_int
(
conn
.
size
());
for
(
auto
&&
data
:
zip
(
conn_int
,
conn
))
{
std
::
get
<
0
>
(
data
)
=
std
::
get
<
1
>
(
data
);
}
ierr
=
MatSetValuesLocal
(
M
,
conn_int
.
size
(),
conn_int
.
storage
(),
conn_int
.
size
(),
conn_int
.
storage
(),
m
.
storage
(),
ADD_VALUES
);
}
ierr
=
MatAssemblyBegin
(
M
,
MAT_FINAL_ASSEMBLY
);
ierr
=
MatAssemblyEnd
(
M
,
MAT_FINAL_ASSEMBLY
);
ierr
=
MatSetOption
(
M
,
MAT_NEW_NONZERO_LOCATIONS
,
PETSC_FALSE
);
PetscViewer
viewer
;
ierr
=
PetscViewerASCIIOpen
(
mpi_comm
,
"M.mtx"
,
&
viewer
);
PetscViewerPushFormat
(
viewer
,
PETSC_VIEWER_ASCII_MATRIXMARKET
);
ierr
=
MatView
(
M
,
viewer
);
PetscViewerPopFormat
(
viewer
);
ierr
=
PetscViewerDestroy
(
&
viewer
);
// this->getDOFManager().assembleElementalMatricesToMatrix(
// "M", "disp", m_all_el, _segment_2);
is_mass_assembled
=
true
;
}
// MatrixType getMatrixType(const ID &) { return _symmetric; }
// void assembleMatrix(const ID & matrix_id) {
// if (matrix_id == "K") {
// if (not is_stiffness_assembled)
// this->assembleStiffness();
// } else if (matrix_id == "M") {
// if (not is_mass_assembled)
// this->assembleMass();
// } else if (matrix_id == "C") {
// // pass, no damping matrix
// } else {
// AKANTU_EXCEPTION("This solver does not know what to do with a matrix "
// << matrix_id);
// }
// }
void
assembleLumpedMatrix
(
const
ID
&
matrix_id
)
{
std
::
cout
<<
"assembleLumpedMatrix"
<<
std
::
endl
;
AKANTU_EXCEPTION
(
"This solver does not know what to do with a matrix "
<<
matrix_id
);
}
void
assembleStiffness
()
{
std
::
cout
<<
"assembleStiffness"
<<
std
::
endl
;
// SparseMatrix & K = this->getDOFManager().getMatrix("K");
// K.clear();
ierr
=
MatZeroEntries
(
K
);
CHECK_ERR_CXX
(
"MatZeroEntries"
,
ierr
);
Matrix
<
Real
>
k
(
2
,
2
);
k
(
0
,
0
)
=
k
(
1
,
1
)
=
1
;
k
(
0
,
1
)
=
k
(
1
,
0
)
=
-
1
;
Array
<
Real
>
k_all_el
(
this
->
nb_elements
,
4
);
auto
k_it
=
k_all_el
.
begin
(
2
,
2
);
auto
cit
=
this
->
mesh
.
getConnectivity
(
_segment_2
).
begin
(
2
);
auto
cend
=
this
->
mesh
.
getConnectivity
(
_segment_2
).
end
(
2
);
for
(;
cit
!=
cend
;
++
cit
,
++
k_it
)
{
const
auto
&
conn
=
*
cit
;
UInt
n1
=
conn
(
0
);
UInt
n2
=
conn
(
1
);
Real
p1
=
this
->
mesh
.
getNodes
()(
n1
,
_x
);
Real
p2
=
this
->
mesh
.
getNodes
()(
n2
,
_x
);
Real
L
=
std
::
abs
(
p2
-
p1
);
auto
&
k_el
=
*
k_it
;
k_el
=
k
;
k_el
*=
E
*
A
/
L
;
Vector
<
Int
>
conn_int
(
conn
.
size
());
for
(
auto
&&
data
:
zip
(
conn_int
,
conn
))
{
std
::
get
<
0
>
(
data
)
=
std
::
get
<
1
>
(
data
);
}
ierr
=
MatSetValuesLocal
(
K
,
conn_int
.
size
(),
conn_int
.
storage
(),
conn_int
.
size
(),
conn_int
.
storage
(),
k_el
.
storage
(),
ADD_VALUES
);
}
ierr
=
MatAssemblyBegin
(
K
,
MAT_FINAL_ASSEMBLY
);
CHECK_ERR_CXX
(
"MatAssemblyBegin"
,
ierr
);
ierr
=
MatAssemblyEnd
(
K
,
MAT_FINAL_ASSEMBLY
);
CHECK_ERR_CXX
(
"MatAssemblyEnd"
,
ierr
);
ierr
=
MatSetOption
(
K
,
MAT_NEW_NONZERO_LOCATIONS
,
PETSC_FALSE
);
CHECK_ERR_CXX
(
"MatSetOption"
,
ierr
);
PetscViewer
viewer
;
ierr
=
PetscViewerASCIIOpen
(
mpi_comm
,
"K.mtx"
,
&
viewer
);
CHECK_ERR_CXX
(
"PetscViewerASCIIOpen"
,
ierr
);
PetscViewerPushFormat
(
viewer
,
PETSC_VIEWER_ASCII_MATRIXMARKET
);
ierr
=
MatView
(
K
,
viewer
);
CHECK_ERR_CXX
(
"MatView"
,
ierr
);
PetscViewerPopFormat
(
viewer
);
ierr
=
PetscViewerDestroy
(
&
viewer
);
CHECK_ERR_CXX
(
"PetscViewerDestroy"
,
ierr
);
// this->getDOFManager().assembleElementalMatricesToMatrix(
// "K", "disp", k_all_el, _segment_2);
is_stiffness_assembled
=
true
;
}
void
copy
(
Array
<
Real
>
&
y
,
Vec
x
)
{
std
::
cout
<<
"copy <-"
<<
std
::
endl
;
const
PetscScalar
*
x_local
;
ierr
=
VecGetArrayRead
(
x
,
&
x_local
);
for
(
auto
&&
data
:
zip
(
y
,
range
(
x_local
+
0
,
x_local
+
y
.
size
())))
{
std
::
get
<
0
>
(
data
)
=
std
::
get
<
1
>
(
data
);
}
ierr
=
VecRestoreArrayRead
(
x
,
&
x_local
);
// VecView(x, PETSC_VIEWER_STDOUT_WORLD);
// std::cout << y.getID() << " " << Vector<Real>(y.storage(), y.size())
// << std::endl;
}
void
print
(
const
Array
<
Real
>
&
x
)
const
{
std
::
cout
<<
x
.
getID
()
<<
" "
<<
Vector
<
Real
>
(
x
.
storage
(),
x
.
size
())
<<
std
::
endl
;
}
void
copy
(
Vec
x
,
const
Array
<
Real
>
&
y
)
{
std
::
cout
<<
"copy ->"
<<
std
::
endl
;
PetscScalar
*
x_local
;
ierr
=
VecGetArray
(
x
,
&
x_local
);
for
(
auto
&&
data
:
zip
(
y
,
range
(
x_local
+
0
,
x_local
+
y
.
size
())))
{
std
::
get
<
1
>
(
data
)
=
std
::
get
<
0
>
(
data
);
}
ierr
=
VecRestoreArray
(
x
,
&
x_local
);
// std::cout << y.getID() << " " << Vector<Real>(y.storage(), y.size())
// << std::endl;
// VecView(x, PETSC_VIEWER_STDOUT_WORLD);
}
void
assembleResidual
()
{
std
::
cout
<<
"assembleResidual"
<<
std
::
endl
;
// this->getDOFManager().assembleToResidual("disp", forces);
setSolutionToDisplacement
();
copy
(
rhs
,
forces
);
// VecAXPY(rhs, -1., f_dirichlet);
print
(
displacement
);
this
->
assembleResidual
(
_not_ghost
);
// this->synchronize(SynchronizationTag::_user_1);
// this->getDOFManager().assembleToResidual("disp", internal_forces, -1.);
VecAXPY
(
rhs
,
1.
,
f_int
);
for
(
auto
&&
data
:
enumerate
(
blocked
))
{
if
(
std
::
get
<
1
>
(
data
))
{
VecSetValueLocal
(
rhs
,
std
::
get
<
0
>
(
data
),
0.
,
INSERT_VALUES
);
}
}
VecAssemblyBegin
(
rhs
);
VecAssemblyEnd
(
rhs
);
VecView
(
rhs
,
PETSC_VIEWER_STDOUT_WORLD
);
}
void
assembleResidual
(
const
GhostType
&
ghost_type
)
{
std
::
cout
<<
"assembleResidual"
<<
std
::
endl
;
VecZeroEntries
(
f_int
);
auto
cit
=
this
->
mesh
.
getConnectivity
(
_segment_2
,
ghost_type
).
begin
(
2
);
auto
cend
=
this
->
mesh
.
getConnectivity
(
_segment_2
,
ghost_type
).
end
(
2
);
auto
strain_it
=
this
->
strains
.
begin
();
auto
stress_it
=
this
->
stresses
.
begin
();
auto
L_it
=
this
->
initial_lengths
.
begin
();
for
(;
cit
!=
cend
;
++
cit
,
++
strain_it
,
++
stress_it
,
++
L_it
)
{
const
auto
&
conn
=
*
cit
;
UInt
n1
=
conn
(
0
);
UInt
n2
=
conn
(
1
);
Real
u1
=
this
->
displacement
(
n1
,
_x
);
Real
u2
=
this
->
displacement
(
n2
,
_x
);
*
strain_it
=
(
u2
-
u1
)
/
*
L_it
;
*
stress_it
=
E
*
*
strain_it
;
Real
f_n
=
A
*
*
stress_it
;
std
::
cout
<<
n1
<<
"["
<<
u1
<<
"]"
<<
" <-> "
<<
n2
<<
"["
<<
u2
<<
"]"
<<
" : "
<<
f_n
<<
std
::
endl
;
ierr
=
VecSetValueLocal
(
f_int
,
n1
,
-
f_n
,
ADD_VALUES
);
ierr
=
VecSetValueLocal
(
f_int
,
n2
,
f_n
,
ADD_VALUES
);
}
ierr
=
VecAssemblyBegin
(
f_int
);
ierr
=
VecAssemblyEnd
(
f_int
);
// this->getDOFManager().assembleElementalArrayLocalArray(
// forces_internal_el, internal_forces, _segment_2, ghost_type);
}
Real
getPotentialEnergy
()
{
std
::
cout
<<
"getPotentialEnergy"
<<
std
::
endl
;
copy
(
x
,
displacement
);
Vec
Ax
;
ierr
=
VecDuplicate
(
x
,
&
Ax
);
ierr
=
MatMult
(
K
,
x
,
Ax
);
PetscScalar
res
;
ierr
=
VecDot
(
x
,
Ax
,
&
res
);
return
res
/
2.
;
}
Real
getKineticEnergy
()
{
std
::
cout
<<
"getKineticEnergy"
<<
std
::
endl
;
return
0
;
}
// Real getExternalWorkIncrement() {
// Real res = 0;
// auto it = velocity.begin();
// auto end = velocity.end();
// auto if_it = internal_forces.begin();
// auto ef_it = forces.begin();
// auto b_it = blocked.begin();
// for (UInt node = 0; it != end; ++it, ++if_it, ++ef_it, ++b_it, ++node) {
// if (mesh.isLocalOrMasterNode(node))
// res += (*b_it ? -*if_it : *ef_it) * *it;
// }
// mesh.getCommunicator().allReduce(res, SynchronizerOperation::_sum);
// return res * this->getTimeStep();
// }
// void predictor() {}
// void corrector() {}
// /* ------------------------------------------------------------------------
// */ UInt getNbData(const Array<Element> & elements,
// const SynchronizationTag &) const {
// return elements.size() * sizeof(Real);
// }
// void packData(CommunicationBuffer & buffer, const Array<Element> &
// elements,
// const SynchronizationTag & tag) const {
// if (tag == SynchronizationTag::_user_1) {
// for (const auto & el : elements) {
// buffer << this->stresses(el.element);
// }
// }
// }
// void unpackData(CommunicationBuffer & buffer, const Array<Element> &
// elements,
// const SynchronizationTag & tag) {
// if (tag == SynchronizationTag::_user_1) {
// auto cit = this->mesh.getConnectivity(_segment_2, _ghost).begin(2);
// for (const auto & el : elements) {
// Real stress;
// buffer >> stress;
// Real f = A * stress;
// Vector<UInt> conn = cit[el.element];
// this->internal_forces(conn(0), _x) += -f;
// this->internal_forces(conn(1), _x) += f;
// }
// }
// }
Real
getExternalWorkIncrement
()
{
std
::
cout
<<
"getExternalWorkIncrement"
<<
std
::
endl
;
return
0.
;
}
template
<
class
Functor
>
void
applyBC
(
Functor
&&
func
,
const
ID
&
group_id
)
{
auto
&
group
=
mesh
.
getElementGroup
(
group_id
).
getNodeGroup
().
getNodes
();
auto
blocked_dofs
=
make_view
(
blocked
,
1
).
begin
();
auto
disps
=
make_view
(
displacement
,
1
).
begin
();
auto
poss
=
make_view
(
mesh
.
getNodes
(),
1
).
begin
();
for
(
auto
&&
node
:
group
)
{
auto
disp
=
Vector
<
Real
>
(
disps
[
node
]);
auto
pos
=
Vector
<
Real
>
(
poss
[
node
]);
auto
flags
=
Vector
<
bool
>
(
blocked_dofs
[
node
]);
func
(
node
,
flags
,
disp
,
pos
);
}
}
const
Mesh
&
getMesh
()
const
{
return
mesh
;
}
UInt
getSpatialDimension
()
const
{
return
1
;
}
auto
&
getBlockedDOFs
()
{
return
blocked
;
}
void
setTimeStep
(
Real
dt
)
{
std
::
cout
<<
"setTimeStep"
<<
std
::
endl
;
this
->
dt
=
dt
;
}
private
:
PetscErrorCode
ierr
{
0
};
MPI_Comm
mpi_comm
;
ISLocalToGlobalMapping
petsc_local_to_global
;
UInt
nb_dofs
;
UInt
nb_elements
;
bool
lumped
;
bool
is_stiffness_assembled
{
false
};
bool
is_mass_assembled
{
false
};
bool
is_lumped_mass_assembled
{
false
};
Mat
K
{
nullptr
},
J
{
nullptr
},
M
{
nullptr
};
Vec
rhs
{
nullptr
},
x
{
nullptr
},
x_save
{
nullptr
},
dx
{
nullptr
},
f_int
{
nullptr
},
f_dirichlet
{
nullptr
};
SNES
snes
;
Real
dt
{
0
};
Array
<
Real
>
save_displacement
;
public
:
Real
E
,
A
,
rho
;
Mesh
&
mesh
;
Array
<
Real
>
displacement
;
Array
<
Real
>
velocity
;
Array
<
Real
>
acceleration
;
Array
<
bool
>
blocked
;
Array
<
Real
>
forces
;
Array
<
Real
>
internal_forces
;
Array
<
Real
>
stresses
;
Array
<
Real
>
strains
;
Array
<
Real
>
initial_lengths
;
};
/* -------------------------------------------------------------------------- */
class
Sinusoidal
:
public
BC
::
Dirichlet
::
DirichletFunctor
{
public
:
Sinusoidal
(
MyModel
&
model
,
Real
amplitude
,
Real
pulse_width
,
Real
t
)
:
model
(
model
),
A
(
amplitude
),
k
(
2
*
M_PI
/
pulse_width
),
t
(
t
),
v
{
std
::
sqrt
(
model
.
E
/
model
.
rho
)}
{}
void
operator
()(
UInt
n
,
Vector
<
bool
>
&
/*flags*/
,
Vector
<
Real
>
&
disp
,
const
Vector
<
Real
>
&
coord
)
const
{
auto
x
=
coord
(
_x
);
model
.
velocity
(
n
,
_x
)
=
k
*
v
*
A
*
sin
(
k
*
(
x
-
v
*
t
));
disp
(
_x
)
=
A
*
cos
(
k
*
(
x
-
v
*
t
));
}
private
:
MyModel
&
model
;
Real
A
{
1.
};
Real
k
{
2
*
M_PI
};
Real
t
{
1.
};
Real
v
{
1.
};
};
/* -------------------------------------------------------------------------- */
int
main
(
int
argc
,
char
*
argv
[])
{
initialize
(
argc
,
argv
);
PetscInitialize
(
&
argc
,
&
argv
,
nullptr
,
nullptr
);
UInt
prank
=
Communicator
::
getStaticCommunicator
().
whoAmI
();
UInt
global_nb_nodes
=
3
;
UInt
max_steps
=
400
;
Real
time_step
=
0.001
;
Mesh
mesh
(
1
);
Real
F
=
-
9.81
;
bool
_explicit
=
EXPLICIT
;
const
Real
pulse_width
=
0.2
;
const
Real
A
=
0.01
;
if
(
prank
==
0
)
genMesh
(
mesh
,
global_nb_nodes
);
mesh
.
distribute
();
// mesh.makePeriodic(_x);
MyModel
model
(
F
,
mesh
,
_explicit
);
// model.forces.clear();
// model.blocked.clear();
// model.applyBC(Sinusoidal(model, A, pulse_width, 0.), "all");
// model.applyBC(BC::Dirichlet::FlagOnly(_x), "border");
// if (!_explicit) {
// model.getNewSolver("dynamic", TimeStepSolverType::_dynamic,
// NonLinearSolverType::_newton_raphson);
// model.setIntegrationScheme("dynamic", "disp",
// IntegrationSchemeType::_trapezoidal_rule_2,
// IntegrationScheme::_displacement);
// } else {
// model.getNewSolver("dynamic", TimeStepSolverType::_dynamic_lumped,
// NonLinearSolverType::_lumped);
// model.setIntegrationScheme("dynamic", "disp",
// IntegrationSchemeType::_central_difference,
// IntegrationScheme::_acceleration);
// }
model
.
setTimeStep
(
time_step
);
if
(
prank
==
0
)
{
std
::
cout
<<
std
::
scientific
;
std
::
cout
<<
std
::
setw
(
14
)
<<
"time"
<<
","
<<
std
::
setw
(
14
)
<<
"wext"
<<
","
<<
std
::
setw
(
14
)
<<
"epot"
<<
","
<<
std
::
setw
(
14
)
<<
"ekin"
<<
","
<<
std
::
setw
(
14
)
<<
"total"
<<
","
<<
std
::
setw
(
14
)
<<
"max_disp"
<<
","
<<
std
::
setw
(
14
)
<<
"min_disp"
<<
std
::
endl
;
}
Real
wext
=
0.
;
// model.getDOFManager().clearResidual();
// model.assembleResidual();
Real
epot
=
0
;
// model.getPotentialEnergy();
Real
ekin
=
0
;
// model.getKineticEnergy();
Real
einit
=
ekin
+
epot
;
Real
etot
=
ekin
+
epot
-
wext
-
einit
;
Real
max_disp
=
0.
,
min_disp
=
0.
;
for
(
auto
&&
disp
:
model
.
displacement
)
{
max_disp
=
std
::
max
(
max_disp
,
disp
);
min_disp
=
std
::
min
(
min_disp
,
disp
);
}
if
(
prank
==
0
)
{
std
::
cout
<<
std
::
setw
(
14
)
<<
0.
<<
","
<<
std
::
setw
(
14
)
<<
wext
<<
","
<<
std
::
setw
(
14
)
<<
epot
<<
","
<<
std
::
setw
(
14
)
<<
ekin
<<
","
<<
std
::
setw
(
14
)
<<
etot
<<
","
<<
std
::
setw
(
14
)
<<
max_disp
<<
","
<<
std
::
setw
(
14
)
<<
min_disp
<<
std
::
endl
;
}
// #if EXPLICIT == false
// NonLinearSolver & solver =
// model.getDOFManager().getNonLinearSolver("dynamic");
// solver.set("max_iterations", 20);
// #endif
auto
*
dumper
=
new
DumperParaview
(
"dynamic"
,
"./paraview"
);
mesh
.
registerExternalDumper
(
*
dumper
,
"dynamic"
,
true
);
mesh
.
addDumpMesh
(
mesh
);
mesh
.
addDumpFieldExternalToDumper
(
"dynamic"
,
"displacement"
,
model
.
displacement
);
mesh
.
addDumpFieldExternalToDumper
(
"dynamic"
,
"velocity"
,
model
.
velocity
);
mesh
.
addDumpFieldExternalToDumper
(
"dynamic"
,
"forces"
,
model
.
forces
);
mesh
.
addDumpFieldExternalToDumper
(
"dynamic"
,
"acceleration"
,
model
.
acceleration
);
mesh
.
dump
();
max_steps
=
1
;
for
(
UInt
i
=
1
;
i
<
max_steps
+
1
;
++
i
)
{
// model.applyBC(Sinusoidal(model, A, pulse_width, time_step * (i - 1)),
// "border");
model
.
solveStep
();
mesh
.
dump
();
epot
=
model
.
getPotentialEnergy
();
ekin
=
model
.
getKineticEnergy
();
wext
+=
model
.
getExternalWorkIncrement
();
etot
=
ekin
+
epot
-
wext
-
einit
;
Real
max_disp
=
0.
,
min_disp
=
0.
;
for
(
auto
&&
disp
:
model
.
displacement
)
{
max_disp
=
std
::
max
(
max_disp
,
disp
);
min_disp
=
std
::
min
(
min_disp
,
disp
);
}
if
(
prank
==
0
)
{
std
::
cout
<<
std
::
setw
(
14
)
<<
time_step
*
i
<<
","
<<
std
::
setw
(
14
)
<<
wext
<<
","
<<
std
::
setw
(
14
)
<<
epot
<<
","
<<
std
::
setw
(
14
)
<<
ekin
<<
","
<<
std
::
setw
(
14
)
<<
etot
<<
","
<<
std
::
setw
(
14
)
<<
max_disp
<<
","
<<
std
::
setw
(
14
)
<<
min_disp
<<
std
::
endl
;
}
}
// output.close();
// finalize();
// PetscFinalize();
return
EXIT_SUCCESS
;
}
/* -------------------------------------------------------------------------- */
void
genMesh
(
Mesh
&
mesh
,
UInt
nb_nodes
)
{
MeshAccessor
mesh_accessor
(
mesh
);
Array
<
Real
>
&
nodes
=
mesh_accessor
.
getNodes
();
Array
<
UInt
>
&
conn
=
mesh_accessor
.
getConnectivity
(
_segment_2
);
nodes
.
resize
(
nb_nodes
);
auto
&
all
=
mesh
.
createNodeGroup
(
"all_nodes"
);
for
(
UInt
n
=
0
;
n
<
nb_nodes
;
++
n
)
{
nodes
(
n
,
_x
)
=
n
*
(
1.
/
(
nb_nodes
-
1
));
all
.
add
(
n
);
}
mesh
.
createElementGroupFromNodeGroup
(
"all"
,
"all_nodes"
);
conn
.
resize
(
nb_nodes
-
1
);
for
(
UInt
n
=
0
;
n
<
nb_nodes
-
1
;
++
n
)
{
conn
(
n
,
0
)
=
n
;
conn
(
n
,
1
)
=
n
+
1
;
}
Array
<
UInt
>
&
conn_points
=
mesh_accessor
.
getConnectivity
(
_point_1
);
conn_points
.
resize
(
2
);
conn_points
(
0
,
0
)
=
0
;
conn_points
(
1
,
0
)
=
nb_nodes
-
1
;
auto
&
border
=
mesh
.
createElementGroup
(
"border"
,
0
);
border
.
add
({
_point_1
,
0
,
_not_ghost
},
true
);
border
.
add
({
_point_1
,
1
,
_not_ghost
},
true
);
mesh_accessor
.
makeReady
();
}
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