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rLIBMULTISCALE LibMultiScale
domain_akantu.cc
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/**
* @file domain_akantu.cc
*
* @author Guillaume Anciaux <guillaume.anciaux@epfl.ch>
* @author Till Junge <till.junge@epfl.ch>
* @author Srinivasa Babu Ramisetti <srinivasa.ramisetti@epfl.ch>
* @author Nicolas Richart <nicolas.richart@epfl.ch>
*
* @date Mon Jul 21 10:32:33 2014
*
* @brief This is the model wrapping Akantu
*
* @section LICENSE
*
* Copyright (©) 2010-2011 EPFL (Ecole Polytechnique Fédérale de Lausanne)
* Laboratory (LSMS - Laboratoire de Simulation en Mécanique des Solides)
*
* LibMultiScale 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.
*
* LibMultiScale 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 LibMultiScale. If not, see <http://www.gnu.org/licenses/>.
*
*/
#define TIMER
/* -------------------------------------------------------------------------- */
#include "lm_common.hh"
#include "domain_akantu.hh"
#include "lib_geometry.hh"
#include "math_tools.hh"
#include "units.hh"
/* -------------------------------------------------------------------------- */
#include <solid_mechanics_model.hh>
#include <material.hh>
#include <material_elastic.hh>
/* -------------------------------------------------------------------------- */
#include <iomanip>
#include <sstream>
/* -------------------------------------------------------------------------- */
__BEGIN_LIBMULTISCALE__
template
<
UInt
Dim
>
DomainAkantu
<
Dim
>::~
DomainAkantu
(){
delete
(
model
);
model
=
NULL
;
delete
(
position0
);
position0
=
NULL
;
delete
(
velocity
);
velocity
=
NULL
;
delete
(
displacement
);
displacement
=
NULL
;
delete
(
acceleration
);
acceleration
=
NULL
;
delete
(
applied_force
);
applied_force
=
NULL
;
delete
(
residual
);
residual
=
NULL
;
delete
(
mass
);
mass
=
NULL
;
delete
(
mesh
);
mesh
=
NULL
;
}
/* -------------------------------------------------------------------------- */
template
<
UInt
Dim
>
DomainAkantu
<
Dim
>::
DomainAkantu
(
DomainID
ID
,
CommGroup
GID
)
:
DomainContinuum
<
ContainerElemsAkantu
<
Dim
>
,
ContainerNodesAkantu
<
Dim
>
,
Dim
>
(
ID
,
GID
),
mesh
(
NULL
),
model
(
NULL
),
position0
(
NULL
),
velocity
(
NULL
),
displacement
(
NULL
),
acceleration
(
NULL
),
applied_force
(
NULL
),
residual
(
NULL
),
mass
(
NULL
),
surface_tag
(
""
),
boundary_start
(
0
),
boundary_is_traction
(
false
),
boundary_has_been_applied
(
false
)
{
for
(
UInt
i
=
0
;
i
<
3
;
++
i
)
{
pbc
[
i
]
=
0
;
scale
[
i
]
=
0.
;
shift
[
i
]
=
0.
;
for
(
UInt
j
=
0
;
j
<
Dim
;
++
j
)
{
this
->
boundary_stress
[
Dim
*
i
+
j
]
=
std
::
numeric_limits
<
Real
>::
max
();
}
}
}
/* -------------------------------------------------------------------------- */
template
<
UInt
Dim
>
void
DomainAkantu
<
Dim
>::
scaleMesh
(){
for
(
UInt
i
=
0
;
i
<
Dim
;
++
i
)
{
if
(
!
scale
[
i
])
continue
;
Real
*
nodes
=
mesh
->
getNodes
().
storage
();
UInt
nb_nodes
=
mesh
->
getNbNodes
();
for
(
UInt
n
=
0
;
n
<
nb_nodes
;
++
n
)
{
nodes
[
n
*
Dim
+
i
]
*=
scale
[
i
];
}
}
}
/* -------------------------------------------------------------------------- */
template
<
UInt
Dim
>
void
DomainAkantu
<
Dim
>::
shiftMesh
(){
for
(
UInt
i
=
0
;
i
<
Dim
;
++
i
)
{
if
(
!
shift
[
i
])
continue
;
Real
*
nodes
=
mesh
->
getNodes
().
storage
();
UInt
nb_nodes
=
mesh
->
getNbNodes
();
for
(
UInt
n
=
0
;
n
<
nb_nodes
;
++
n
)
{
nodes
[
n
*
Dim
+
i
]
+=
shift
[
i
];
}
}
}
/* -------------------------------------------------------------------------- */
template
<
UInt
Dim
>
void
DomainAkantu
<
Dim
>::
initMesh
(){
mesh
=
new
akantu
::
Mesh
(
Dim
,
this
->
getID
(),
0
);
UInt
prank
=
Communicator
::
getCommunicator
().
groupRank
(
lm_my_proc_id
,
this
->
getGroupID
());
if
(
prank
==
0
)
{
if
(
mesh_filename
!=
""
){
mesh
->
read
(
mesh_filename
);
#ifndef LM_OPTIMIZED
akantu
::
Mesh
::
type_iterator
it
=
mesh
->
firstType
(
Dim
);
akantu
::
Mesh
::
type_iterator
end
=
mesh
->
lastType
(
Dim
);
UInt
ntypes
=
0
;
for
(;
it
!=
end
;
++
it
,
++
ntypes
)
{}
LM_ASSERT
(
ntypes
<=
1
,
"At current time Akantu plugin cannot support to load"
<<
" more than one element type for volume elements"
);
#endif
//LM_OPTIMIZED
scaleMesh
();
shiftMesh
();
// UInt nb_fragments = mesh->createClusters(Dim);
// DUMP("the number of fragments is " << nb_fragments,DBG_MESSAGE);
}
else
{
LM_ASSERT
(
Dim
==
1
,
"automatic mesh generation only possible in 1D"
<<
"a mesh file should have been provided using the"
<<
" MESH_FILENAME keyword"
);
const
akantu
::
ElementType
type
=
akantu
::
_segment_2
;
mesh
->
addConnectivityType
(
type
);
Ball
*
b
=
dynamic_cast
<
Ball
*>
(
GeometryManager
::
getManager
().
getGeometry
(
this
->
geometries
[
0
]));
if
(
b
==
NULL
)
LM_FATAL
(
"geometry given is not a valid ball"
);
//number of element on each side of the zero
UInt
nx
=
(
UInt
)(
nearbyint
((
b
->
rMax
()
-
b
->
rMin
())
/
elem_size
));
Real
center
=
b
->
getCenter
(
0
);
Real
rmin
=
b
->
rMin
();
Real
rmax
=
b
->
rMax
();
Real
range
=
rmax
-
rmin
;
Real
e_size
=
range
/
nx
;
DUMP
(
"element size "
<<
e_size
,
DBG_MESSAGE
);
UInt
nb_nodes
;
nb_nodes
=
2
*
nx
+
1
;
if
(
rmin
>
0
)
++
nb_nodes
;
UInt
nb_elems
;
nb_elems
=
2
*
nx
;
akantu
::
Array
<
Real
>
&
nodes
=
const_cast
<
akantu
::
Array
<
Real
>
&>
(
mesh
->
getNodes
());
nodes
.
resize
(
nb_nodes
);
// create nodes from -1 to 0
for
(
UInt
i
=
0
;
i
<
nx
+
1
;
++
i
){
nodes
(
i
)
=
static_cast
<
Real
>
(
i
)
/
static_cast
<
Real
>
(
nx
)
-
1.0
;
nodes
(
i
)
=
nodes
(
i
)
*
range
-
rmin
+
center
;
DUMP
(
"creating node at position "
<<
nodes
(
i
),
DBG_DETAIL
)
}
// create nodes from 0 to 1
if
(
rmin
==
0
){
for
(
UInt
i
=
0
;
i
<
nx
+
1
;
++
i
){
nodes
(
i
+
nx
)
=
static_cast
<
Real
>
(
i
)
/
static_cast
<
Real
>
(
nx
);
nodes
(
i
+
nx
)
=
nodes
(
i
+
nx
)
*
range
+
rmin
+
center
;
DUMP
(
"creating node at position "
<<
nodes
(
i
+
nx
),
DBG_DETAIL
)
}
}
else
for
(
UInt
i
=
0
;
i
<
nx
+
1
;
++
i
){
nodes
(
i
+
nx
+
1
)
=
static_cast
<
Real
>
(
i
)
/
static_cast
<
Real
>
(
nx
);
nodes
(
i
+
nx
+
1
)
=
nodes
(
i
+
nx
+
1
)
*
range
+
rmin
+
center
;
DUMP
(
"creating node at position "
<<
nodes
(
i
+
nx
+
1
),
DBG_DETAIL
)
}
akantu
::
Array
<
UInt
>
&
connectivity
=
const_cast
<
akantu
::
Array
<
UInt
>
&>
(
mesh
->
getConnectivity
(
type
));
connectivity
.
resize
(
nb_elems
);
for
(
UInt
i
=
0
;
i
<
nx
;
++
i
){
connectivity
(
i
,
0
)
=
i
;
connectivity
(
i
,
1
)
=
i
+
1
;
}
if
(
rmin
==
0
)
for
(
UInt
i
=
0
;
i
<
nx
;
++
i
){
connectivity
(
i
+
nx
,
0
)
=
i
+
nx
;
connectivity
(
i
+
nx
,
1
)
=
i
+
nx
+
1
;
}
else
for
(
UInt
i
=
0
;
i
<
nx
;
++
i
){
connectivity
(
i
+
nx
,
0
)
=
i
+
nx
+
1
;
connectivity
(
i
+
nx
,
1
)
=
i
+
nx
+
2
;
}
}
}
}
/* -------------------------------------------------------------------------- */
template
<
UInt
Dim
>
void
DomainAkantu
<
Dim
>::
initMaterial
(){
if
(
this
->
material_filename
==
""
){
LM_ASSERT
(
Dim
==
1
,
"automatic material property definition only possible in 1D"
<<
"a material file should have been provided using the"
<<
" MATERIAL_FILENAME keyword"
);
DUMP
(
"Automatic parameter generation for LJ and lattice provided parameters"
,
DBG_WARNING
);
akantu
::
Material
&
mat
=
model
->
registerNewEmptyMaterial
<
akantu
::
MaterialElastic
<
1u
>
>
(
"elastic1DMaterial"
);
UInt
ordre
=
static_cast
<
UInt
>
(
rcut
/
r0
);
Real
coeff
=
MathTools
::
ipow
(
sigma
/
r0
,
6
);
Real
E
=
24.0
*
epsilon
*
coeff
/
r0
*
(
-
7.0
*
MathTools
::
zeta
(
6
,
ordre
)
+
26.0
*
coeff
*
MathTools
::
zeta
(
12
,
ordre
));
mat
.
setParam
(
"E"
,
E
);
mat
.
setParam
(
"nu"
,
0.0
);
mat
.
setParam
(
"rho"
,
Real
(
atomic_mass
/
r0
));
DUMP
(
"mass density "
<<
(
Real
)(
atomic_mass
/
r0
),
DBG_MESSAGE
);
DUMP
(
"r0 "
<<
r0
,
DBG_MESSAGE
);
DUMP
(
"atomic_mass "
<<
atomic_mass
,
DBG_MESSAGE
);
}
this
->
model
->
initMaterials
();
}
/* -------------------------------------------------------------------------- */
template
<
UInt
Dim
>
void
DomainAkantu
<
Dim
>::
init
(){
if
(
!
Communicator
::
getCommunicator
().
amIinGroup
(
this
->
getGroupID
()))
return
;
akantu
::
debug
::
setDebugLevel
(
akantu
::
dbl0
);
// akantu::debug::setDebugLevel(akantu::dblTrace);
initMesh
();
UInt
prank
=
Communicator
::
getCommunicator
().
groupRank
(
lm_my_proc_id
,
this
->
getGroupID
());
UInt
psize
=
Communicator
::
getCommunicator
().
getNBprocsOnGroup
(
this
->
getGroupID
());
akantu
::
MeshPartition
*
partition
=
NULL
;
if
(
prank
==
0
)
{
partition
=
new
akantu
::
MeshPartitionScotch
(
*
mesh
,
Dim
);
partition
->
partitionate
(
psize
);
}
this
->
model
=
new
akantu
::
SolidMechanicsModel
(
*
mesh
,
Dim
,
this
->
getID
());
this
->
model
->
initParallel
(
partition
);
delete
partition
;
this
->
model
->
getMesh
().
computeBoundingBox
();
this
->
model
->
setF_M2A
(
code_unit_system
.
ft_m2v
);
bool
pbc_activated
=
false
;
for
(
UInt
i
=
0
;
i
<
Dim
;
++
i
)
{
pbc_activated
|=
pbc
[
i
];
}
if
(
pbc_activated
)
{
this
->
model
->
setPBC
(
pbc
[
0
],
pbc
[
1
],
pbc
[
2
]);
std
::
map
<
UInt
,
UInt
>
&
akantu_pairs
=
this
->
model
->
getPBCPairs
();
std
::
map
<
UInt
,
UInt
>::
iterator
it
=
akantu_pairs
.
begin
();
std
::
map
<
UInt
,
UInt
>::
iterator
end
=
akantu_pairs
.
end
();
while
(
it
!=
end
)
{
this
->
pbc_pairs
.
push_back
((
*
it
));
++
it
;
}
}
}
/* -------------------------------------------------------------------------- */
template
<
UInt
Dim
>
void
DomainAkantu
<
Dim
>::
performStep1
(){
if
(
this
->
prestressed_periodicity_flag
&&
!
this
->
slave_displacements_computed
)
{
this
->
buildSlaveDisplacements
();
this
->
slave_displacements_computed
=
true
;
}
if
((
this
->
haveToApplyNeumann
())
&&
!
this
->
boundary_has_been_applied
&&
(
current_step
>=
this
->
boundary_start
))
{
this
->
enableNeumanBndyConditions
();
}
}
/* -------------------------------------------------------------------------- */
template
<
UInt
Dim
>
void
DomainAkantu
<
Dim
>::
performStep3
(){
}
/* -------------------------------------------------------------------------- */
template
<
UInt
Dim
>
UInt
DomainAkantu
<
Dim
>::
getCurrentStep
(){
LM_TOIMPLEMENT
;
}
/* -------------------------------------------------------------------------- */
template
<
UInt
Dim
>
void
DomainAkantu
<
Dim
>::
buildSlaveDisplacements
()
{
typedef
std
::
vector
<
std
::
pair
<
UInt
,
UInt
>
>::
iterator
pair_it
;
pair_it
pbc_pair
=
this
->
pbc_pairs
.
begin
();
pair_it
end
=
this
->
pbc_pairs
.
end
();
// upper bounds are masters, lower bounds slaves
for
(;
pbc_pair
!=
end
;
++
pbc_pair
)
{
for
(
UInt
direction
=
0
;
direction
<
Dim
;
++
direction
)
{
this
->
slave_displacements
.
push_back
((
*
this
->
displacement
)[
Dim
*
pbc_pair
->
first
+
direction
]
-
(
*
this
->
displacement
)[
Dim
*
pbc_pair
->
second
+
direction
]);
}
}
}
/* -------------------------------------------------------------------------- */
template
<
UInt
Dim
>
void
DomainAkantu
<
Dim
>::
checkBoundaryInputSanity
()
{
try
{
this
->
mesh
->
template
createGroupsFromMeshData
<
std
::
string
>
(
"physical_names"
);
}
catch
(...)
{
this
->
mesh
->
template
createGroupsFromMeshData
<
UInt
>
(
"tag_0"
);
}
bool
is_stress
;
Real
realmax
=
std
::
numeric_limits
<
Real
>::
max
();
this
->
boundary_is_traction
=
((
this
->
boundary_stress
[
0
]
!=
realmax
)
&&
(
this
->
boundary_stress
[
Dim
]
==
realmax
));
is_stress
=
(
this
->
boundary_stress
[
Dim
]
!=
realmax
);
if
(
this
->
boundary_is_traction
&&
is_stress
)
{
LM_FATAL
(
"you cannot specify both a traction (TRACTION_BNDY_VECTOR) and "
<<
"a stress (TRACTION_BNDY_TENSOR) for traction "
<<
"boundary conditions"
);
}
else
if
(
!
this
->
boundary_is_traction
&&
!
is_stress
)
{
LM_FATAL
(
"you specified a TRACTION_BNDY_TAG, but neither a stress "
<<
"(TRACTION_BNDY_TENSOR) nor a traction "
<<
"(TRACTION_BNDY_VECTOR)"
);
}
}
/* -------------------------------------------------------------------------- */
template
<
UInt
Dim
>
void
DomainAkantu
<
Dim
>::
enableNeumanBndyConditions
()
{
try
{
if
(
boundary_is_traction
)
{
akantu
::
Vector
<
Real
>
surface_traction
(
Dim
);
for
(
UInt
i
=
0
;
i
<
Dim
;
++
i
)
{
surface_traction
(
i
)
=
this
->
boundary_stress
[
i
];
}
model
->
applyBC
(
akantu
::
BC
::
Neumann
::
FromSameDim
(
surface_traction
),
surface_tag
);
}
else
{
akantu
::
Matrix
<
Real
>
surface_stress
(
Dim
,
Dim
);
for
(
UInt
i
=
0
;
i
<
Dim
;
++
i
)
{
for
(
UInt
j
=
0
;
j
<
Dim
;
++
j
)
{
surface_stress
(
i
,
j
)
=
this
->
boundary_stress
[
Dim
*
i
+
j
];
}
}
model
->
applyBC
(
akantu
::
BC
::
Neumann
::
FromHigherDim
(
surface_stress
),
surface_tag
);
}
}
catch
(
akantu
::
debug
::
Exception
&
)
{}
this
->
boundary_has_been_applied
=
true
;
}
/* -------------------------------------------------------------------------- */
template
<
UInt
Dim
>
void
DomainAkantu
<
Dim
>::
setTimeStep
(
Real
ts
){
model
->
setTimeStep
(
ts
);
this
->
timeStep
=
ts
;
}
/* -------------------------------------------------------------------------- */
template
<
UInt
Dim
>
void
DomainAkantu
<
Dim
>::
setCurrentStep
(
UInt
step
){
current_step
=
step
;
}
/* -------------------------------------------------------------------------- */
template
<
UInt
Dim
>
Real
DomainAkantu
<
Dim
>::
getEpot
(){
LM_TOIMPLEMENT
;
}
/* -------------------------------------------------------------------------- */
template
<
UInt
Dim
>
void
DomainAkantu
<
Dim
>::
getSubDomainDimensions
(
Real
*
xmin
,
Real
*
xmax
){
akantu
::
Vector
<
Real
>
_xmin
;
akantu
::
Vector
<
Real
>
_xmax
;
_xmin
=
mesh
->
getLocalLowerBounds
();
_xmax
=
mesh
->
getLocalUpperBounds
();
for
(
UInt
k
=
0
;
k
<
Dim
;
++
k
)
{
xmin
[
k
]
=
_xmin
[
k
];
xmax
[
k
]
=
_xmax
[
k
];
}
}
/* -------------------------------------------------------------------------- */
template
<
UInt
Dim
>
void
DomainAkantu
<
Dim
>::
getDomainDimensions
(
Real
*
xmin
,
Real
*
xmax
){
akantu
::
Vector
<
Real
>
_xmin
;
akantu
::
Vector
<
Real
>
_xmax
;
_xmin
=
mesh
->
getLowerBounds
();
_xmax
=
mesh
->
getUpperBounds
();
for
(
UInt
k
=
0
;
k
<
Dim
;
++
k
)
{
xmin
[
k
]
=
_xmin
[
k
];
xmax
[
k
]
=
_xmax
[
k
];
}
}
/* -------------------------------------------------------------------------- */
/* LMDESC AKANTU_BASE
This domain implements the plugin with Akantu Finite Element library.
*/
/* LMHERITANCE domain_continuum */
template
<
UInt
Dim
>
void
DomainAkantu
<
Dim
>::
declareParams
(){
DomainContinuum
<
ContainerElemsAkantu
<
Dim
>
,
ContainerNodesAkantu
<
Dim
>
,
Dim
>::
declareParams
();
/* LMKEYWORD MESH_FILENAME
Specify the mesh file to be loaded using the MeshIO utility of Akantu
*/
this
->
parseKeyword
(
"MESH_FILENAME"
,
mesh_filename
,
""
);
/* LMKEYWORD MATERIAL_FILENAME
Specify the material file to be loaded for the Akantu SolidMechanicsModel object
*/
this
->
parseKeyword
(
"MATERIAL_FILENAME"
,
material_filename
,
""
);
/* LMKEYWORD PBC
Specify the directions in which Periodic Boundary Conditions should be activated
*/
this
->
parseVectorKeyword
(
"PBC"
,
Dim
,
pbc
,
VEC_DEFAULTS
(
0u
,
0u
,
0u
));
/* LMKEYWORD SCALE
Specify factors for each directions to be used in rescaling the mesh nodal positions
*/
this
->
parseVectorKeyword
(
"SCALE"
,
Dim
,
scale
,
VEC_DEFAULTS
(
1.
,
1.
,
1.
));
/* LMKEYWORD SHIFT
Specify factors for each directions to be used in shifting the mesh nodal positions
*/
this
->
parseVectorKeyword
(
"SHIFT"
,
Dim
,
shift
,
VEC_DEFAULTS
(
0.
,
0.
,
0.
));
/* LMKEYWORD R0
In the case of 1D mesh allows to use a linearized LJ material definition //
fitting monoatomic chain:\\
This provides the interatomic distance.
*/
this
->
parseKeyword
(
"R0"
,
r0
,
0.
);
/* LMKEYWORD RCUT
In the case of 1D mesh allows to use a linearized LJ material definition
fitting monoatomic chain:\\
This provides the cutoff radius for the potential evaluation.
*/
this
->
parseKeyword
(
"RCUT"
,
rcut
,
0.
);
/* LMKEYWORD EPSILON
In the case of 1D mesh allows to use a linearized LJ material definition
fitting monoatomic chain:\\
This provides the $\epsilon$ parameter in the LJ potential definition.
*/
this
->
parseKeyword
(
"EPSILON"
,
epsilon
,
0.
);
/* LMKEYWORD SIGMA
In the case of 1D mesh allows to use a linearized LJ material definition
fitting monoatomic chain:\\
This provides the $\sigma$ parameter in the LJ potential definition.
*/
this
->
parseKeyword
(
"SIGMA"
,
sigma
,
0.
);
/* LMKEYWORD MASS
In the case of 1D mesh allows to use a linearized LJ material definition
fitting monoatomic chain:\ \
This provides the atomic mass.
*/
this
->
parseKeyword
(
"MASS"
,
atomic_mass
,
0.
);
/* LMKEYWORD ELEM_SIZE
In the case of 1D mesh generates automatically a homogeneous
1D first order mesh.
*/
this
->
parseKeyword
(
"ELEM_SIZE"
,
elem_size
,
0.
);
/* LMKEYWORD TRACTION_BNDY_TENSOR
Specify a full stress tensor to be applied to a boundary */
this
->
parseVectorKeyword
(
"TRACTION_BNDY_TENSOR"
,
Dim
*
Dim
,
this
->
boundary_stress
,
VEC_DEFAULTS
(
0.
,
0.
,
0.
,
0.
,
0.
,
0.
,
0.
,
0.
,
0.
));
// /* L2MKEYWORD TRACTION_BNDY_VECTOR
// Specify a traction vector to be applied to a boundary */
// this->parseVectorKeyword("TRACTION_BNDY_VECTOR", Dim, this->boundary_stress,
// {0.,0.,0.});
/* LMKEYWORD TRACTION_BNDY_TAG
Specify the tag of the boundary on which the traction should be applied.
This refers to "tag\_1" in the msh format */
this
->
parseKeyword
(
"TRACTION_BNDY_TAG"
,
this
->
surface_tag
,
""
);
/* LMKEYWORD TRACTION_BNDY_START
Specify the time step at which to start applying the traction boundary
conditions */
this
->
parseKeyword
(
"TRACTION_BNDY_START"
,
this
->
boundary_start
,
0u
);
}
/* -------------------------------------------------------------------------- */
template
class
DomainAkantu
<
3
>
;
template
class
DomainAkantu
<
2
>
;
template
class
DomainAkantu
<
1
>
;
__END_LIBMULTISCALE__
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