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rAKA akantu
phase_field_model.cc
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/**
* @file phase_field_model.cc
*
* @author Mohit Pundir <mohit.pundir@epfl.ch>
*
* @date creation: Wed Aug 01 2018
* @date last modification: Wed Aug 01 2018
*
* @brief Implementation of PhaseFieldModel class
*
* @section LICENSE
*
* Copyright (©) 2010-2018 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 "phase_field_model.hh"
#include "dumpable_inline_impl.hh"
#include "element_synchronizer.hh"
#include "fe_engine_template.hh"
#include "group_manager_inline_impl.cc"
#include "integrator_gauss.hh"
#include "mesh.hh"
#include "parser.hh"
#include "shape_lagrange.hh"
#ifdef AKANTU_USE_IOHELPER
#include "dumper_element_partition.hh"
#include "dumper_elemental_field.hh"
#include "dumper_internal_material_field.hh"
#include "dumper_iohelper_paraview.hh"
#endif
/* -------------------------------------------------------------------------- */
namespace
akantu
{
// material functor can be created
/* -------------------------------------------------------------------------- */
PhaseFieldModel
::
PhaseFieldModel
(
Mesh
&
mesh
,
UInt
dim
,
const
ID
&
id
,
const
MemoryID
&
memory_id
)
:
Model
(
mesh
,
ModelType
::
_phase_field_model
,
dim
,
id
,
memory_id
),
damage_gradient
(
"damage_gradient"
,
id
),
damage_on_qpoints
(
"damage_on_qpoints"
,
id
),
strain_history_on_qpoints
(
"strain_history_on_qpoints"
,
id
),
displacement_on_qpoints
(
"displacement_on_qpoints"
,
id
){
AKANTU_DEBUG_IN
();
this
->
initDOFManager
();
this
->
registerDataAccessor
(
*
this
);
if
(
this
->
mesh
.
isDistributed
())
{
auto
&
synchronizer
=
this
->
mesh
.
getElementSynchronizer
();
this
->
registerSynchronizer
(
synchronizer
,
_gst_pfm_damage
);
this
->
registerSynchronizer
(
synchronizer
,
_gst_pfm_gradient_damage
);
}
registerFEEngineObject
<
FEEngineType
>
(
id
+
":fem"
,
mesh
,
spatial_dimension
);
#ifdef AKANTU_USE_IOHELPER
this
->
mesh
.
registerDumper
<
DumperParaview
>
(
"phase_field"
,
id
,
true
);
this
->
mesh
.
addDumpMesh
(
mesh
,
spatial_dimension
,
_not_ghost
,
_ek_regular
);
#endif
// AKANTU_USE_IOHELPER
this
->
registerParam
(
"l0"
,
l_0
,
0.
,
_pat_parsmod
,
"length scale"
);
this
->
registerParam
(
"gc"
,
g_c
,
_pat_parsmod
,
"critical local fracture energy density"
);
this
->
registerParam
(
"lambda"
,
lame_lambda
,
_pat_parsmod
,
"lame parameter lambda"
);
this
->
registerParam
(
"mu"
,
lame_mu
,
_pat_parsmod
,
"lame paramter mu"
);
AKANTU_DEBUG_OUT
();
}
/* -------------------------------------------------------------------------- */
void
PhaseFieldModel
::
initModel
()
{
auto
&
fem
=
this
->
getFEEngine
();
fem
.
initShapeFunctions
(
_not_ghost
);
fem
.
initShapeFunctions
(
_ghost
);
damage_on_qpoints
.
initialize
(
fem
,
_nb_component
=
1
);
damage_gradient
.
initialize
(
fem
,
_nb_component
=
spatial_dimension
);
displacement_on_qpoints
.
initialize
(
fem
,
_nb_component
=
spatial_dimension
);
strain_history_on_qpoints
.
initialize
(
fem
,
_nb_component
=
1
);
}
/* -------------------------------------------------------------------------- */
PhaseFieldModel
::~
PhaseFieldModel
()
=
default
;
/* -------------------------------------------------------------------------- */
void
PhaseFieldModel
::
assembleMatrix
(
const
ID
&
matrix_id
)
{
if
(
matrix_id
==
"K"
)
{
this
->
assembleDamageMatrix
();
}
else
if
(
matrix_id
==
"M"
and
need_to_reassemble_capacity
)
{
this
->
assembleDamageGradMatrix
();
}
}
/* -------------------------------------------------------------------------- */
void
PhaseFieldModel
::
initSolver
(
TimeStepSolverType
time_step_solver_type
,
NonLinearSolverType
)
{
DOFManager
&
dof_manager
=
this
->
getDOFManager
();
this
->
allocNodalField
(
this
->
damage
,
"damage"
);
this
->
allocNodalField
(
this
->
external_force
,
"external_force"
);
this
->
allocNodalField
(
this
->
internal_force
,
"internal_force"
);
this
->
allocNodalField
(
this
->
blocked_dofs
,
"blocked_dofs"
);
if
(
!
dof_manager
.
hasDOFs
(
"damage"
))
{
dof_manager
.
registerDOFs
(
"damage"
,
*
this
->
damage
,
_dst_nodal
);
dof_manager
.
registerBlockedDOFs
(
"damage"
,
*
this
->
blocked_dofs
);
}
/*if (time_step_solver_type == _tsst_dynamic ||
time_step_solver_type == _tsst_dynamic_lumped) {
this->allocNodalField(this->damage_rate, "damage_rate");
if (!dof_manager.hasDOFsDerivatives("damage", 1)) {
dof_manager.registerDOFsDerivative("damage", 1,
*this->damage_rate);
}
}*/
}
/* -------------------------------------------------------------------------- */
void
PhaseFieldModel
::
assembleDamageMatrix
()
{
AKANTU_DEBUG_IN
();
AKANTU_DEBUG_INFO
(
"Assemble the new damage matrix"
);
this
->
computeStrainHistoryOnQuadPoints
(
_not_ghost
);
if
(
!
this
->
getDOFManager
().
hasMatrix
(
"K"
))
{
this
->
getDOFManager
().
getNewMatrix
(
"K"
,
getMatrixType
(
"K"
));
}
this
->
getDOFManager
().
clearMatrix
(
"K"
);
switch
(
mesh
.
getSpatialDimension
())
{
case
1
:
this
->
assembleDamageMatrix
<
1
>
(
_not_ghost
);
break
;
case
2
:
this
->
assembleDamageMatrix
<
2
>
(
_not_ghost
);
break
;
case
3
:
this
->
assembleDamageMatrix
<
3
>
(
_not_ghost
);
break
;
}
AKANTU_DEBUG_OUT
();
}
/* -------------------------------------------------------------------------- */
void
PhaseFieldModel
::
assembleDamageGradMatrix
()
{
AKANTU_DEBUG_IN
();
AKANTU_DEBUG_INFO
(
"Assemble the new damage gradient matrix"
);
if
(
!
this
->
getDOFManager
().
hasMatrix
(
"K"
))
{
this
->
getDOFManager
().
getNewMatrix
(
"K"
,
getMatrixType
(
"K"
));
}
this
->
getDOFManager
().
clearMatrix
(
"K"
);
switch
(
mesh
.
getSpatialDimension
())
{
case
1
:
this
->
assembleDamageGradMatrix
<
1
>
(
_not_ghost
);
break
;
case
2
:
this
->
assembleDamageGradMatrix
<
2
>
(
_not_ghost
);
break
;
case
3
:
this
->
assembleDamageGradMatrix
<
3
>
(
_not_ghost
);
break
;
}
AKANTU_DEBUG_OUT
();
}
/* -------------------------------------------------------------------------- */
std
::
tuple
<
ID
,
TimeStepSolverType
>
PhaseFieldModel
::
getDefaultSolverID
(
const
AnalysisMethod
&
method
)
{
switch
(
method
)
{
case
_explicit_lumped_mass:
{
return
std
::
make_tuple
(
"explicit_lumped"
,
_tsst_dynamic_lumped
);
}
case
_static:
{
return
std
::
make_tuple
(
"static"
,
_tsst_static
);
}
case
_implicit_dynamic:
{
return
std
::
make_tuple
(
"implicit"
,
_tsst_dynamic
);
}
default
:
return
std
::
make_tuple
(
"unknown"
,
_tsst_not_defined
);
}
}
/* -------------------------------------------------------------------------- */
ModelSolverOptions
PhaseFieldModel
::
getDefaultSolverOptions
(
const
TimeStepSolverType
&
type
)
const
{
ModelSolverOptions
options
;
switch
(
type
)
{
case
_tsst_dynamic_lumped:
{
options
.
non_linear_solver_type
=
_nls_lumped
;
options
.
integration_scheme_type
[
"damage"
]
=
_ist_forward_euler
;
options
.
solution_type
[
"damage"
]
=
IntegrationScheme
::
_temperature_rate
;
break
;
}
case
_tsst_static:
{
options
.
non_linear_solver_type
=
_nls_newton_raphson
;
options
.
integration_scheme_type
[
"damage"
]
=
_ist_pseudo_time
;
options
.
solution_type
[
"damage"
]
=
IntegrationScheme
::
_not_defined
;
break
;
}
case
_tsst_dynamic:
{
if
(
this
->
method
==
_explicit_consistent_mass
)
{
options
.
non_linear_solver_type
=
_nls_newton_raphson
;
options
.
integration_scheme_type
[
"damage"
]
=
_ist_forward_euler
;
options
.
solution_type
[
"damage"
]
=
IntegrationScheme
::
_temperature_rate
;
}
else
{
options
.
non_linear_solver_type
=
_nls_newton_raphson
;
options
.
integration_scheme_type
[
"damage"
]
=
_ist_backward_euler
;
options
.
solution_type
[
"damage"
]
=
IntegrationScheme
::
_damage
;
}
break
;
}
default
:
AKANTU_EXCEPTION
(
type
<<
" is not a valid time step solver type"
);
}
return
options
;
}
/* -------------------------------------------------------------------------- */
template
<
UInt
dim
>
void
PhaseFieldModel
::
assembleDamageMatrix
(
const
GhostType
&
ghost_type
)
{
AKANTU_DEBUG_IN
();
auto
&
fem
=
this
->
getFEEngine
();
for
(
auto
&&
type
:
mesh
.
elementTypes
(
spatial_dimension
,
ghost_type
))
{
auto
nb_element
=
mesh
.
getNbElement
(
type
,
ghost_type
);
auto
nb_nodes_per_element
=
Mesh
::
getNbNodesPerElement
(
type
);
auto
nb_quadrature_points
=
fem
.
getNbIntegrationPoints
(
type
,
ghost_type
);
auto
nt_d_n
=
std
::
make_unique
<
Array
<
Real
>>
(
nb_element
*
nb_quadrature_points
,
nb_nodes_per_element
*
nb_nodes_per_element
,
"N^t*D*N"
);
// conductivity_on_qpoints = gc*l0 = scalar
fem
.
computeNtDN
(
conductivity_on_qpoints
(
type
,
ghost_type
),
*
nt_d_n
,
type
,
ghost_type
);
/// compute @f$ K_d = \int_e \mathbf{N}^t * \mathbf{D} *
/// \mathbf{N}@f$
auto
K_d
=
std
::
make_unique
<
Array
<
Real
>>
(
nb_element
,
nb_nodes_per_element
*
nb_nodes_per_element
,
"K_d"
);
fem
.
integrate
(
*
nt_d_n
,
*
K_d
,
nb_nodes_per_element
*
nb_nodes_per_element
,
type
,
ghost_type
);
this
->
getDOFManager
().
assembleElementalMatricesToMatrix
(
"K"
,
"phasefield"
,
*
K_d
,
type
,
ghost_type
,
_symmetric
);
}
AKANTU_DEBUG_OUT
();
}
/* -------------------------------------------------------------------------- */
template
<
UInt
dim
>
void
PhaseFieldModel
::
assembleDamageGradMatrix
(
const
GhostType
&
ghost_type
)
{
AKANTU_DEBUG_IN
();
auto
&
fem
=
this
->
getFEEngine
();
for
(
auto
&&
type
:
mesh
.
elementTypes
(
spatial_dimension
,
ghost_type
))
{
auto
nb_element
=
mesh
.
getNbElement
(
type
,
ghost_type
);
auto
nb_nodes_per_element
=
Mesh
::
getNbNodesPerElement
(
type
);
auto
nb_quadrature_points
=
fem
.
getNbIntegrationPoints
(
type
,
ghost_type
);
auto
bt_d_b
=
std
::
make_unique
<
Array
<
Real
>>
(
nb_element
*
nb_quadrature_points
,
nb_nodes_per_element
*
nb_nodes_per_element
,
"B^t*D*B"
);
// conductivity_on_qpoints = gc*l0 = scalar
fem
.
computeBtDB
(
conductivity_on_qpoints
(
type
,
ghost_type
),
*
bt_d_b
,
type
,
ghost_type
);
/// compute @f$ K_{\grad d} = \int_e \mathbf{B}^t * \mathbf{W} *
/// \mathbf{B}@f$
auto
K_b
=
std
::
make_unique
<
Array
<
Real
>>
(
nb_element
,
nb_nodes_per_element
*
nb_nodes_per_element
,
"K_b"
);
fem
.
integrate
(
*
bt_d_b
,
*
K_b
,
nb_nodes_per_element
*
nb_nodes_per_element
,
type
,
ghost_type
);
this
->
getDOFManager
().
assembleElementalMatricesToMatrix
(
"K"
,
"phasefield"
,
*
K_b
,
type
,
ghost_type
,
_symmetric
);
}
AKANTU_DEBUG_OUT
();
}
/* -------------------------------------------------------------------------- */
void
PhaseFieldModel
::
computeStrainHistoryOnQuadPoints
(
const
GhostType
&
ghost_type
)
{
for
(
auto
&
type
:
mesh
.
elementType
(
spatial_dimension
,
ghost_type
))
{
auto
&
displacement_interpolated
=
displacement_on_qpoints
(
type
,
ghost_type
);
// compute the strain on quadrature points
this
->
getFEEngine
().
interpolateOnIntegrationPoints
(
*
displacement
,
displacement_interpolated
,
,
type
,
ghost_type
);
auto
&
strain_history
=
strain_history_on_qpoints
(
type
,
ghost_type
);
for
(
auto
&&
tuple
:
zip
(
make_view
(
strain_history
,
spatial_dimension
,
spatial_dimension
),
displacement_interpolated
))
{
// compute strain on quad from displacement_interpolated
// commpute matrix sigma_plus and sigma_minus using
// lame_lambda and lame_mu
// compute phi_plus
// updated strain_history
}
}
}
/* -------------------------------------------------------------------------- */
void
PhaseFieldModel
::
assembleResidual
()
{
AKANTU_DEBUG_IN
();
this
->
assembleInternalForces
();
this
->
getDOFManager
().
assembleToResidual
(
"damage"
,
*
this
->
external_force
,
1
);
this
->
getDOFManager
().
assembleToResidual
(
"damage"
,
*
this
->
internal_force
,
1
);
AKANTU_DEBUG_OUT
();
}
/* -------------------------------------------------------------------------- */
void
PhaseFieldModel
::
assembleInternalForces
()
{
AKANTU_DEBUG_IN
();
this
->
internal_force
->
clear
();
this
->
synchronize
(
_gst_pfm_damage
);
auto
&
fem
=
this
->
getFFEngine
();
for
(
auto
ghost_type:
ghost_types
)
{
for
(
auto
type:
mesh
.
elementTypes
(
spatial_dimension
,
ghost_type
))
{
UInt
nb_nodes_per_element
=
Mesh
::
getNbNodesPerElement
(
type
);
auto
&
strain_history_on_qpoints_vect
=
strain_history_on_qpoints
(
type
,
ghost_type
);
UInt
nb_quad_points
=
strain_history_on_qpoints_vect
.
size
();
Array
<
Real
>
nt_strain_history
(
nb_quad_points
,
nb_nodes_per_element
);
fem
.
computeNtb
(
strain_history_on_qpoints_vect
,
nt_strain_history
,
type
,
ghost_type
);
UInt
nb_elements
=
mesh
.
getNbElement
(
type
,
ghost_type
);
Array
<
Real
>
int_nt_srain_history
(
nb_elements
,
nb_nodes_per_element
);
fem
.
integrate
(
nt_strain_history
,
int_nt_srain_history
,
nb_nodes_per_element
,
type
,
ghost_type
);
this
->
getDOFManager
().
assembleElementalArrayLocalArray
(
int_nt_srain_history
,
*
this
->
internal_force
,
type
,
ghost_type
,
-
1
);
}
}
AKANTU_DEBUG_OUT
();
}
/* -------------------------------------------------------------------------- */
void
PhaseFieldModel
::
readMaterials
()
{
auto
sect
=
this
->
getParserSection
();
if
(
not
std
::
get
<
1
>
(
sect
))
{
const
auto
&
section
=
std
::
get
<
0
>
(
sect
);
this
->
parseSection
(
section
);
}
gc_on_qpoints
.
set
(
g_c
);
}
/* -------------------------------------------------------------------------- */
void
PhaseFieldModel
::
initFullImpl
(
const
ModelOptions
&
options
)
{
Model
::
initFullImpl
(
options
);
readMaterials
();
}
/* -------------------------------------------------------------------------- */
UInt
PhaseFieldModel
::
getNbData
(
const
Array
<
Element
>
&
elements
,
const
Synchronizationtag
&
tag
)
const
{
AKANTU_DEBUG_IN
();
UInt
size
=
0
;
UInt
nb_nodes_per_element
=
0
;
for
(
const
Element
&
el
:
elements
)
{
nb_nodes_per_element
+=
Mesh
::
getNbNodesPerElement
(
el
.
type
);
}
switch
(
tag
)
{
case
_gst_material_id:
{
size
+=
elements
.
size
()
*
sizeof
(
UInt
);
break
;
}
case
_gst_pfm_damage:
{
size
+=
nb_nodes_per_element
*
sizeof
(
Real
);
// damage
break
;
}
case
_gst_pfm_gradient_damage:
{
size
+=
getNbIntegrationPoints
(
elements
)
*
spatial_dimension
*
sizeof
(
Real
);
size
+=
nb_nodes_per_element
*
sizeof
(
Real
);
break
;
}
default
:
{
AKANTU_ERROR
(
"Unknown ghost synchronization tag : "
<<
tag
);
}
}
AKANTU_DEBUG_OUT
();
return
size
;
}
/* -------------------------------------------------------------------------- */
void
PhaseFieldModel
::
packData
(
CommunicationBuffer
&
buffer
,
const
Array
<
Element
>
&
elements
,
const
SynchronizationTag
&
tag
)
const
{
switch
(
tag
)
{
case
_gst_pfm_damage:
{
packNodalDataHelper
(
*
damage
,
buffer
,
elements
,
mesh
);
break
;
}
case
_gst_htm_gradient_damage:
{
packElementalDataHelper
(
damage_gradient
,
buffer
,
elements
,
true
,
getFEEngine
());
packNodalDataHelper
(
*
damage
,
buffer
,
elements
,
mesh
);
break
;
}
default
:
{
AKANTU_ERROR
(
"Unknown ghost synchronization tag : "
<<
tag
);
}
}
}
/* -------------------------------------------------------------------------- */
void
PhaseFieldModel
::
unpackData
(
CommunicationBuffer
&
buffer
,
const
Array
<
Element
>
&
elements
,
const
SynchronizationTag
&
tag
)
{
switch
(
tag
)
{
case
_gst_pfm_damage:
{
unpackNodalDataHelper
(
*
damage
,
buffer
,
elements
,
mesh
);
break
;
}
case
_gst_pfm_gradient_damage:
{
unpackElementalDataHelper
(
damage_gradient
,
buffer
,
elements
,
true
,
getFEEngine
());
unpackNodalDataHelper
(
*
damage
,
buffer
,
elements
,
mesh
);
break
;
}
default
:
{
AKANTU_ERROR
(
"Unknown ghost synchronization tag : "
<<
tag
);
}
}
}
/* -------------------------------------------------------------------------- */
void
PhaseFieldModel
::
getNbData
(
const
Array
<
UInt
>
&
indexes
,
const
SynchronizationTag
&
tag
)
const
{
AKANTU_DEBUG_IN
();
UInt
size
=
0
;
UInt
nb_nodes
=
indexes
.
size
();
switch
(
tag
)
{
case
_gst_pfm_damage:
{
size
+=
nb_nodes
*
sizeof
(
Real
);
break
;
}
default
:
{
AKANTU_ERROR
(
"Unknown ghost synchronization tag : "
<<
tag
);
}
}
AKANTU_DEBUG_OUT
();
return
size
;
}
/* -------------------------------------------------------------------------- */
void
PhaseFieldModel
::
packData
(
CommunicationBuffer
&
buffer
,
const
Array
<
UInt
>
&
indexes
,
const
SynchronizationTag
&
tag
)
const
{
AKANTU_DEBUG_IN
();
for
(
auto
index
:
indexes
)
{
switch
(
tag
)
{
case
_gst_pfm_damage:
{
buffer
<<
(
*
damage
)(
index
);
break
;
}
default
:
{
AKANTU_ERROR
(
"Unknown ghost synchronization tag : "
<<
tag
);
}
}
}
AKANTU_DEBUG_OUT
();
}
/* -------------------------------------------------------------------------- */
void
PhaseFieldModel
::
unpackData
(
CommunicationBuffer
&
buffer
,
const
Array
<
UInt
>
&
indexes
,
const
Synchronization
&
tag
)
{
AKANTU_DEBUG_IN
();
for
(
auto
index
:
indexes
)
{
switch
(
tag
)
{
case
_gst_pfm_damage:
{
buffer
>>
(
*
damage
)(
index
);
break
;
}
default
:
{
AKANTU_ERROR
(
"Unknown ghost synchronization tag : "
<<
tag
);
}
}
}
AKANTU_DEBUG_OUT
();
}
/* -------------------------------------------------------------------------- */
/* -------------------------------------------------------------------------- */
#ifdef AKANTU_USE_IOHELPER
dumper
::
Field
*
PhaseFieldModel
::
createNodalFieldBool
(
const
std
::
string
&
field_name
,
const
std
::
string
&
group_name
,
__attribute__
((
unused
))
bool
padding_flag
)
{
std
::
map
<
std
::
string
,
Array
<
bool
>
*>
uint_nodal_fields
;
uint_nodal_fields
[
"blocked_dofs"
]
=
blocked_dofs
;
dumper
::
Field
*
field
=
nullptr
;
field
=
mesh
.
createNodalFieldBool
(
uint_nodal_fields
[
field_name
],
group_name
);
return
field
;
}
/* -------------------------------------------------------------------------- */
dumper
::
Field
*
PhaseFieldModel
::
createNodalFieldReal
(
const
std
::
string
&
field_name
,
const
std
::
string
&
group_name
,
__attribute__
((
unused
))
bool
padding_flag
)
{
if
(
field_name
==
"capacity_lumped"
)
{
AKANTU_EXCEPTION
(
"Capacity lumped is a nodal field now stored in the DOF manager."
"Therefore it cannot be used by a dumper anymore"
);
}
std
::
map
<
std
::
string
,
Array
<
Real
>
*>
real_nodal_fields
;
real_nodal_fields
[
"damage"
]
=
damage
;
dumper
::
Field
*
field
=
mesh
.
createNodalField
(
real_nodal_fields
[
field_name
],
group_name
);
return
field
;
}
/* -------------------------------------------------------------------------- */
dumper
::
Field
*
PhaseFieldModel
::
createElementalField
(
const
std
::
string
&
field_name
,
const
std
::
string
&
group_name
,
__attribute__
((
unused
))
bool
padding_flag
,
__attribute__
((
unused
))
const
UInt
&
spatial_dimension
,
const
ElementKind
&
element_kind
)
{
dumper
::
Field
*
field
=
nullptr
;
if
(
field_name
==
"partitions"
)
field
=
mesh
.
createElementalField
<
UInt
,
dumper
::
ElementpartitionField
>
(
mesh
.
getConnectivities
(),
group_name
,
this
->
spatial_dimension
,
element_kind
);
else
if
(
field_name
==
"damage_gradient"
)
{
ElementTypeMap
<
UInt
>
nb_data_per_elem
=
this
->
mesh
.
getNbDataPerElem
(
damage_gradient
,
element_kind
);
field
=
mesh
.
createElementalField
<
Real
,
dumper
::
InternalMaterialField
>
(
damage_gradient
,
group_name
,
this
->
spatial_dimension
,
element_kind
,
nb_data_per_elem
);
}
else
if
(
field_name
==
"conductivity"
)
{
ElementTypeMap
<
UInt
>
nb_data_per_elem
=
this
->
mesh
.
getNbDataPerElem
(
conductivity_on_qpoints
,
element_kind
);
field
=
mesh
.
createElementalField
<
Real
,
dumper
::
InternalMaterialField
>
(
conductivity_on_qpoints
,
group_name
,
this
->
spatial_dimension
,
element_kind
,
nb_data_per_elem
);
}
return
field
;
}
/* -------------------------------------------------------------------------- */
#else
/* -------------------------------------------------------------------------- */
dumper
::
Field
*
HeatTransferModel
::
createElementalField
(
__attribute__
((
unused
))
const
std
::
string
&
field_name
,
__attribute__
((
unused
))
const
std
::
string
&
group_name
,
__attribute__
((
unused
))
bool
padding_flag
,
__attribute__
((
unused
))
const
ElementKind
&
element_kind
)
{
return
nullptr
;
}
/* -------------------------------------------------------------------------- */
dumper
::
Field
*
HeatTransferModel
::
createNodalFieldBool
(
__attribute__
((
unused
))
const
std
::
string
&
field_name
,
__attribute__
((
unused
))
const
std
::
string
&
group_name
,
__attribute__
((
unused
))
bool
padding_flag
)
{
return
nullptr
;
}
/* -------------------------------------------------------------------------- */
dumper
::
Field
*
HeatTransferModel
::
createNodalFieldReal
(
__attribute__
((
unused
))
const
std
::
string
&
field_name
,
__attribute__
((
unused
))
const
std
::
string
&
group_name
,
__attribute__
((
unused
))
bool
padding_flag
)
{
return
nullptr
;
}
#endif
/* -------------------------------------------------------------------------- */
void
PhaseFieldModel
::
dump
(
conts
std
::
string
&
dumper_name
)
{
mesh
.
dump
(
dumper_name
);
}
/* -------------------------------------------------------------------------- */
void
PhaseFieldModel
::
dump
(
const
std
::
string
&
dumper_name
,
UInt
step
)
{
mesh
.
dump
(
dumper_name
,
step
);
}
/* -------------------------------------------------------------------------- */
void
PhaseFieldModel
::
dump
(
const
std
::
string
&
dumper_name
,
Real
time
,
UInt
step
)
{
mesh
.
dump
(
dumper_name
,
time
,
step
);
}
/* -------------------------------------------------------------------------- */
void
PhaseFieldModel
::
dump
()
{
mesh
.
dump
();
}
/* -------------------------------------------------------------------------- */
void
PhaseFieldModel
::
dump
(
UInt
step
)
{
mesh
.
dump
(
step
);
}
/* -------------------------------------------------------------------------- */
void
PhaseFieldModel
::
dump
(
Real
time
,
UInt
step
)
{
mesh
.
dump
(
time
,
step
);
}
/* -------------------------------------------------------------------------- */
}
// akantu
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