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fenics_engine_base.py
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R6746 RationalROMPy
fenics_engine_base.py
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# Copyright (C) 2018 by the RROMPy authors
#
# This file is part of RROMPy.
#
# RROMPy 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.
#
# RROMPy 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 RROMPy. If not, see <http://www.gnu.org/licenses/>.
#
from
os
import
path
,
mkdir
import
fenics
as
fen
import
numpy
as
np
from
matplotlib
import
pyplot
as
plt
from
.hfengine_base
import
HFEngineBase
from
rrompy.utilities.base.types
import
Np1D
,
strLst
,
FenFunc
,
Tuple
,
List
from
rrompy.utilities.base
import
(
purgeList
,
getNewFilename
,
verbosityManager
as
vbMng
)
from
rrompy.solver.fenics
import
L2NormMatrix
,
fenplot
,
interp_project
from
.boundary_conditions
import
BoundaryConditions
from
rrompy.utilities.exception_manager
import
RROMPyException
__all__
=
[
'FenicsEngineBase'
]
class
FenicsEngineBase
(
HFEngineBase
):
"""Generic solver for parametric fenics problems."""
def
__init__
(
self
,
degree_threshold
:
int
=
np
.
inf
,
verbosity
:
int
=
10
,
timestamp
:
bool
=
True
):
super
()
.
__init__
(
verbosity
=
verbosity
,
timestamp
=
timestamp
)
self
.
BCManager
=
BoundaryConditions
(
"Dirichlet"
)
self
.
V
=
fen
.
FunctionSpace
(
fen
.
UnitSquareMesh
(
10
,
10
),
"P"
,
1
)
self
.
degree_threshold
=
degree_threshold
@property
def
V
(
self
):
"""Value of V."""
return
self
.
_V
@V.setter
def
V
(
self
,
V
):
if
not
type
(
V
)
.
__name__
==
'FunctionSpace'
:
raise
RROMPyException
(
"V type not recognized."
)
self
.
dsToBeSet
=
True
self
.
_V
=
V
self
.
u
=
fen
.
TrialFunction
(
V
)
self
.
v
=
fen
.
TestFunction
(
V
)
@property
def
spacedim
(
self
):
if
hasattr
(
self
,
"_V"
):
return
self
.
V
.
dim
()
return
super
()
.
spacedim
def
autoSetDS
(
self
):
"""Set FEniCS boundary measure based on boundary function handles."""
if
self
.
dsToBeSet
:
vbMng
(
self
,
"INIT"
,
"Initializing boundary measures."
,
20
)
mesh
=
self
.
V
.
mesh
()
NB
=
self
.
NeumannBoundary
RB
=
self
.
RobinBoundary
boundary_markers
=
fen
.
MeshFunction
(
"size_t"
,
mesh
,
mesh
.
topology
()
.
dim
()
-
1
)
NB
.
mark
(
boundary_markers
,
0
)
RB
.
mark
(
boundary_markers
,
1
)
self
.
ds
=
fen
.
Measure
(
"ds"
,
domain
=
mesh
,
subdomain_data
=
boundary_markers
)
self
.
dsToBeSet
=
False
vbMng
(
self
,
"DEL"
,
"Done assembling boundary measures."
,
20
)
def
buildEnergyNormForm
(
self
):
"""
Build sparse matrix (in CSR format) representative of scalar product.
"""
vbMng
(
self
,
"INIT"
,
"Assembling energy matrix."
,
20
)
self
.
energyNormMatrix
=
L2NormMatrix
(
self
.
V
)
vbMng
(
self
,
"DEL"
,
"Done assembling energy matrix."
,
20
)
def
buildEnergyNormDualForm
(
self
):
"""
Build sparse matrix (in CSR format) representative of dual scalar
product.
"""
if
not
hasattr
(
self
,
"energyNormMatrix"
):
self
.
buildEnergyNormForm
()
self
.
energyNormDualMatrix
=
self
.
energyNormMatrix
def
buildEnergyNormPartialDualForm
(
self
):
"""
Build sparse matrix (in CSR format) representative of dual scalar
product without duality.
"""
if
not
hasattr
(
self
,
"energyNormMatrix"
):
self
.
buildEnergyNormForm
()
self
.
energyNormPartialDualMatrix
=
self
.
energyNormMatrix
def
liftDirichletData
(
self
)
->
Np1D
:
"""Lift Dirichlet datum."""
if
not
hasattr
(
self
,
"_liftedDirichletDatum"
):
liftRe
=
interp_project
(
self
.
DirichletDatum
[
0
],
self
.
V
)
liftIm
=
interp_project
(
self
.
DirichletDatum
[
1
],
self
.
V
)
self
.
_liftedDirichletDatum
=
(
np
.
array
(
liftRe
.
vector
())
+
1.j
*
np
.
array
(
liftIm
.
vector
()))
return
self
.
_liftedDirichletDatum
def
reduceQuadratureDegree
(
self
,
fun
:
FenFunc
,
name
:
str
):
"""Check whether to reduce compiler parameters to degree threshold."""
if
not
np
.
isinf
(
self
.
degree_threshold
):
from
ufl.algorithms.estimate_degrees
import
(
estimate_total_polynomial_degree
as
ETPD
)
try
:
deg
=
ETPD
(
fun
)
except
:
return
False
if
deg
>
self
.
degree_threshold
:
vbMng
(
self
,
"MAIN"
,
(
"Reducing quadrature degree from {} to {} for "
"{}."
)
.
format
(
deg
,
self
.
degree_threshold
,
name
),
15
)
return
True
return
False
def
iterReduceQuadratureDegree
(
self
,
funsNames
:
List
[
Tuple
[
FenFunc
,
str
]]):
"""
Iterate reduceQuadratureDegree over list and define reduce compiler
parameters.
"""
if
funsNames
is
not
None
:
for
fun
,
name
in
funsNames
:
if
self
.
reduceQuadratureDegree
(
fun
,
name
):
return
{
"quadrature_degree"
:
self
.
degree_threshold
}
return
{}
def
plot
(
self
,
u
:
Np1D
,
warping
:
List
[
callable
]
=
None
,
is_state
:
bool
=
False
,
name
:
str
=
"u"
,
save
:
str
=
None
,
what
:
strLst
=
'all'
,
saveFormat
:
str
=
"eps"
,
saveDPI
:
int
=
100
,
show
:
bool
=
True
,
fenplotArgs
:
dict
=
{},
**
figspecs
)
->
str
:
"""
Do some nice plots of the complex-valued function with given dofs.
Args:
u: numpy complex array with function dofs.
warping(optional): Domain warping functions.
is_state(optional): whether given u is value before multiplication
by c. Defaults to False.
name(optional): Name to be shown as title of the plots. Defaults to
'u'.
save(optional): Where to save plot(s). Defaults to None, i.e. no
saving.
what(optional): Which plots to do. If list, can contain 'ABS',
'PHASE', 'REAL', 'IMAG'. If str, same plus wildcard 'ALL'.
Defaults to 'ALL'.
saveFormat(optional): Format for saved plot(s). Defaults to "eps".
saveDPI(optional): DPI for saved plot(s). Defaults to 100.
show(optional): Whether to show figure. Defaults to True.
fenplotArgs(optional): Optional arguments for fenplot.
figspecs(optional key args): Optional arguments for matplotlib
figure creation.
Returns:
Output filename.
"""
if
not
is_state
and
not
self
.
isCEye
:
return
super
()
.
plot
(
u
,
warping
,
name
,
save
,
what
,
saveFormat
,
saveDPI
,
show
,
fenplotArgs
,
**
figspecs
)
if
isinstance
(
what
,
(
str
,)):
if
what
.
upper
()
==
'ALL'
:
what
=
[
'ABS'
,
'PHASE'
,
'REAL'
,
'IMAG'
]
else
:
what
=
[
what
]
what
=
purgeList
(
what
,
[
'ABS'
,
'PHASE'
,
'REAL'
,
'IMAG'
],
listname
=
self
.
name
()
+
".what"
,
baselevel
=
1
)
if
len
(
what
)
==
0
:
return
if
'figsize'
not
in
figspecs
.
keys
():
figspecs
[
'figsize'
]
=
(
13.
*
len
(
what
)
/
4
,
3
)
subplotcode
=
100
+
len
(
what
)
*
10
plt
.
figure
(
**
figspecs
)
plt
.
jet
()
if
'ABS'
in
what
:
uAb
=
fen
.
Function
(
self
.
V
)
uAb
.
vector
()
.
set_local
(
np
.
abs
(
u
))
subplotcode
=
subplotcode
+
1
plt
.
subplot
(
subplotcode
)
p
=
fenplot
(
uAb
,
warping
=
warping
,
title
=
"|{0}|"
.
format
(
name
),
**
fenplotArgs
)
if
self
.
V
.
mesh
()
.
geometric_dimension
()
>
1
:
plt
.
colorbar
(
p
)
if
'PHASE'
in
what
:
uPh
=
fen
.
Function
(
self
.
V
)
uPh
.
vector
()
.
set_local
(
np
.
angle
(
u
))
subplotcode
=
subplotcode
+
1
plt
.
subplot
(
subplotcode
)
p
=
fenplot
(
uPh
,
warping
=
warping
,
title
=
"phase({0})"
.
format
(
name
),
**
fenplotArgs
)
if
self
.
V
.
mesh
()
.
geometric_dimension
()
>
1
:
plt
.
colorbar
(
p
)
if
'REAL'
in
what
:
uRe
=
fen
.
Function
(
self
.
V
)
uRe
.
vector
()
.
set_local
(
np
.
real
(
u
))
subplotcode
=
subplotcode
+
1
plt
.
subplot
(
subplotcode
)
p
=
fenplot
(
uRe
,
warping
=
warping
,
title
=
"Re({0})"
.
format
(
name
),
**
fenplotArgs
)
if
self
.
V
.
mesh
()
.
geometric_dimension
()
>
1
:
plt
.
colorbar
(
p
)
if
'IMAG'
in
what
:
uIm
=
fen
.
Function
(
self
.
V
)
uIm
.
vector
()
.
set_local
(
np
.
imag
(
u
))
subplotcode
=
subplotcode
+
1
plt
.
subplot
(
subplotcode
)
p
=
fenplot
(
uIm
,
warping
=
warping
,
title
=
"Im({0})"
.
format
(
name
),
**
fenplotArgs
)
if
self
.
V
.
mesh
()
.
geometric_dimension
()
>
1
:
plt
.
colorbar
(
p
)
if
save
is
not
None
:
save
=
save
.
strip
()
fileOut
=
getNewFilename
(
"{}_fig_"
.
format
(
save
),
saveFormat
)
plt
.
savefig
(
fileOut
,
format
=
saveFormat
,
dpi
=
saveDPI
)
else
:
fileOut
=
None
if
show
:
plt
.
show
()
plt
.
close
()
return
fileOut
def
plotmesh
(
self
,
warping
:
List
[
callable
]
=
None
,
name
:
str
=
"Mesh"
,
save
:
str
=
None
,
saveFormat
:
str
=
"eps"
,
saveDPI
:
int
=
100
,
show
:
bool
=
True
,
fenplotArgs
:
dict
=
{},
**
figspecs
)
->
str
:
"""
Do a nice plot of the mesh.
Args:
u: numpy complex array with function dofs.
warping(optional): Domain warping functions.
name(optional): Name to be shown as title of the plots. Defaults to
'u'.
save(optional): Where to save plot(s). Defaults to None, i.e. no
saving.
saveFormat(optional): Format for saved plot(s). Defaults to "eps".
saveDPI(optional): DPI for saved plot(s). Defaults to 100.
show(optional): Whether to show figure. Defaults to True.
fenplotArgs(optional): Optional arguments for fenplot.
figspecs(optional key args): Optional arguments for matplotlib
figure creation.
Returns:
Output filename.
"""
plt
.
figure
(
**
figspecs
)
fenplot
(
self
.
V
.
mesh
(),
warping
=
warping
,
**
fenplotArgs
)
if
save
is
not
None
:
save
=
save
.
strip
()
fileOut
=
getNewFilename
(
"{}_msh_"
.
format
(
save
),
saveFormat
)
plt
.
savefig
(
fileOut
,
format
=
saveFormat
,
dpi
=
saveDPI
)
else
:
fileOut
=
None
if
show
:
plt
.
show
()
plt
.
close
()
return
fileOut
def
outParaview
(
self
,
u
:
Np1D
,
warping
:
List
[
callable
]
=
None
,
is_state
:
bool
=
False
,
name
:
str
=
"u"
,
filename
:
str
=
"out"
,
time
:
float
=
0.
,
what
:
strLst
=
'all'
,
forceNewFile
:
bool
=
True
,
folder
:
bool
=
False
,
filePW
=
None
)
->
str
:
"""
Output complex-valued function with given dofs to ParaView file.
Args:
u: numpy complex array with function dofs.
warping(optional): Domain warping functions.
is_state(optional): whether given u is value before multiplication
by c. Defaults to False.
name(optional): Base name to be used for data output.
filename(optional): Name of output file.
time(optional): Timestamp.
what(optional): Which plots to do. If list, can contain 'MESH',
'ABS', 'PHASE', 'REAL', 'IMAG'. If str, same plus wildcard
'ALL'. Defaults to 'ALL'.
forceNewFile(optional): Whether to create new output file.
folder(optional): Whether to create an additional folder layer.
filePW(optional): Fenics File entity (for time series).
Returns:
Output filename.
"""
if
not
is_state
and
not
self
.
isCEye
:
raise
RROMPyException
((
"Cannot output to Paraview non-state "
"object."
))
if
isinstance
(
what
,
(
str
,)):
if
what
.
upper
()
==
'ALL'
:
what
=
[
'MESH'
,
'ABS'
,
'PHASE'
,
'REAL'
,
'IMAG'
]
else
:
what
=
[
what
]
what
=
purgeList
(
what
,
[
'MESH'
,
'ABS'
,
'PHASE'
,
'REAL'
,
'IMAG'
],
listname
=
self
.
name
()
+
".what"
,
baselevel
=
1
)
if
len
(
what
)
==
0
:
return
if
filePW
is
None
:
if
folder
:
if
not
path
.
exists
(
filename
+
"/"
):
mkdir
(
filename
)
idxpath
=
filename
.
rfind
(
"/"
)
filename
+=
"/"
+
filename
[
idxpath
+
1
:]
if
forceNewFile
:
filePW
=
fen
.
File
(
getNewFilename
(
filename
,
"pvd"
))
else
:
filePW
=
fen
.
File
(
"{}.pvd"
.
format
(
filename
))
if
warping
is
not
None
:
fen
.
ALE
.
move
(
self
.
V
.
mesh
(),
interp_project
(
warping
[
0
],
self
.
V
.
mesh
()))
if
what
==
[
'MESH'
]:
filePW
<<
(
self
.
V
.
mesh
(),
time
)
if
'ABS'
in
what
:
uAb
=
fen
.
Function
(
self
.
V
,
name
=
"{}_ABS"
.
format
(
name
))
uAb
.
vector
()
.
set_local
(
np
.
abs
(
u
))
filePW
<<
(
uAb
,
time
)
if
'PHASE'
in
what
:
uPh
=
fen
.
Function
(
self
.
V
,
name
=
"{}_PHASE"
.
format
(
name
))
uPh
.
vector
()
.
set_local
(
np
.
angle
(
u
))
filePW
<<
(
uPh
,
time
)
if
'REAL'
in
what
:
uRe
=
fen
.
Function
(
self
.
V
,
name
=
"{}_REAL"
.
format
(
name
))
uRe
.
vector
()
.
set_local
(
np
.
real
(
u
))
filePW
<<
(
uRe
,
time
)
if
'IMAG'
in
what
:
uIm
=
fen
.
Function
(
self
.
V
,
name
=
"{}_IMAG"
.
format
(
name
))
uIm
.
vector
()
.
set_local
(
np
.
imag
(
u
))
filePW
<<
(
uIm
,
time
)
if
warping
is
not
None
:
fen
.
ALE
.
move
(
self
.
V
.
mesh
(),
interp_project
(
warping
[
1
],
self
.
V
.
mesh
()))
return
filePW
def
outParaviewTimeDomain
(
self
,
u
:
Np1D
,
omega
:
float
,
warping
:
List
[
callable
]
=
None
,
is_state
:
bool
=
False
,
timeFinal
:
float
=
None
,
periodResolution
:
int
=
20
,
name
:
str
=
"u"
,
filename
:
str
=
"out"
,
forceNewFile
:
bool
=
True
,
folder
:
bool
=
False
)
->
str
:
"""
Output complex-valued function with given dofs to ParaView file,
converted to time domain.
Args:
u: numpy complex array with function dofs.
omega: frequency.
warping(optional): Domain warping functions.
is_state(optional): whether given u is value before multiplication
by c. Defaults to False.
timeFinal(optional): final time of simulation.
periodResolution(optional): number of time steps per period.
name(optional): Base name to be used for data output.
filename(optional): Name of output file.
forceNewFile(optional): Whether to create new output file.
folder(optional): Whether to create an additional folder layer.
Returns:
Output filename.
"""
if
not
is_state
and
not
self
.
isCEye
:
raise
RROMPyException
((
"Cannot output to Paraview non-state "
"object."
))
if
folder
:
if
not
path
.
exists
(
filename
+
"/"
):
mkdir
(
filename
)
idxpath
=
filename
.
rfind
(
"/"
)
filename
+=
"/"
+
filename
[
idxpath
+
1
:]
if
forceNewFile
:
filePW
=
fen
.
File
(
getNewFilename
(
filename
,
"pvd"
))
else
:
filePW
=
fen
.
File
(
"{}.pvd"
.
format
(
filename
))
omega
=
np
.
abs
(
omega
)
t
=
0.
dt
=
2.
*
np
.
pi
/
omega
/
periodResolution
if
timeFinal
is
None
:
timeFinal
=
2.
*
np
.
pi
/
omega
-
dt
if
warping
is
not
None
:
fen
.
ALE
.
move
(
self
.
V
.
mesh
(),
interp_project
(
warping
[
0
],
self
.
V
.
mesh
()))
for
j
in
range
(
int
(
np
.
ceil
(
timeFinal
/
dt
))
+
1
):
ut
=
fen
.
Function
(
self
.
V
,
name
=
name
)
ut
.
vector
()
.
set_local
(
np
.
real
(
u
)
*
np
.
cos
(
omega
*
t
)
+
np
.
imag
(
u
)
*
np
.
sin
(
omega
*
t
))
filePW
<<
(
ut
,
t
)
t
+=
dt
if
warping
is
not
None
:
fen
.
ALE
.
move
(
self
.
V
.
mesh
(),
interp_project
(
warping
[
1
],
self
.
V
.
mesh
()))
return
filePW
Event Timeline
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