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boundary.py
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boundary.py
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"""
Provides classes of boundary conditons and other related tools.
Supports mixed boundary condition given by (in)equalities.
"""
# pylama:ignore=E731
import re
from dolfin import FacetFunction, SubDomain
from paramchecker import evaluate
import numpy as np
from cPickle import dumps
bcApplyChoices = ['global', 'conditions'] # no sides yet
class GenericBoundary(object):
""" Generic boundary conditon class. """
value = 0
def __init__(self):
""" Set all default condition values. """
self.param = "None"
self.applyTo = 'global'
self.conditions = 'True'
self.parValue = None
self.check = "lambda x, y, z=0: True"
self.on = True
def __repr__(self):
"""Return string representation suitable for object reconstruction."""
s = self.name
if self.param != "None":
s += ' with parameter '+self.param
s += '; '+self.applyTo
if self.applyTo != "global":
s += ': '+self.conditions
return s
def update(self, applyTo='global', conditions='True', param="None"):
"""
Parse boundary condition parameters.
applyTo sets the type of the boundary specification:
sides: list of boundary sides/triangles to which BC should apply
conditions: logical conditions for (x,y,z)
OR is placed between elements if a list is provided
global: apply to the whole boundary
param is used if a value is associated with a boundary condition.
self.on =
True: forces BC to apply only on the mesh boundary
False: interior points can be a part of BC
"""
self.on = True
applyTo = applyTo.lower()
self.applyTo = applyTo
if applyTo == 'sides':
self.initializeSides(conditions)
elif applyTo == 'conditions':
self.initializeConditions(conditions)
else: # global
self.applyTo = "global"
try:
self.parValue = evaluate(param)[0]
self.param = param
except:
pass
@staticmethod
def preprocessConditions(conditions):
""" Turn a list of conditions into a function. """
conditions = re.sub(r'&+', ' and ', conditions)
conditions = re.sub(r'\|+', ' or ', conditions)
conditions = re.sub(r'==+', '=', conditions)
conditions = re.sub(r'(?<![<>])=', '==', conditions)
conditions = "lambda x, y, z=0: any([ " + conditions + " ])"
return conditions
def initializeConditions(self, conditions):
""" Try to parse logical conditions given by the user. """
try:
new = self.preprocessConditions(conditions)
evaluate(new) # check if valid
self.conditions = conditions
self.check = new
except:
try:
new = self.preprocessConditions(self.conditions)
evaluate(new)
self.check = new
except:
self.conditions = "True"
self.check = "lambda x, y, z=0: True"
def getTest(self):
""" Return a function which can check if a point belongs to bc. """
if self.applyTo == 'global':
return lambda x, on: on
fun = evaluate(self.check)[0]
if self.on:
return lambda x, on: fun(*x) and on
else:
return lambda x, on: fun(*x)
def initializeSides(self, sides):
"""
Generate point in interval/triangle tests for all boundary cells.
Make self.check functions based on boundary cells from sides.
Not implemented yet.
"""
self.conditions = "All"
self.check = "lambda x, y, z=0: True"
class NeumannBoundary(GenericBoundary):
"""
Neumann.
Neumann boundary condition.
Since this is the natural BC, it essentialy removes other conditions.
"""
value = 0
def update(self, applyTo='global', conditions='True', param="None"):
"""Neumann does not use parameters."""
super(NeumannBoundary, self).update(applyTo, conditions, "None")
class DirichletBoundary(GenericBoundary):
"""
Dirichlet.
Dirichlet boundary condition.
Can also be applied in the interior of the domain.
"""
value = 1
def update(self, applyTo='global', conditions='True', param="None"):
"""Dirichlet conditon can be applied to the interior points."""
if applyTo == 'inside':
super(DirichletBoundary, self).update('conditions',
conditions, "None")
self.on = False
self.applyTo = 'inside'
else:
super(DirichletBoundary, self).update(applyTo, conditions, "None")
class RobinBoundary(GenericBoundary):
"""
Robin.
Robin boundary condition.
The default value of the Robin parameter is 1.
"""
value = 2
def __init__(self):
"""Consecutive Robin objects must be distinguishable."""
super(RobinBoundary, self).__init__()
self.value = RobinBoundary.value
RobinBoundary.value += 1
self.update(param="1")
class SteklovBoundary(GenericBoundary):
r"""
Steklov.
Steklov boundary condition.
The default value of the Steklov parameter is 1.
If any part of the boundary has a Steklov condition applied, \
the denominator of the Rayleigh quotient is evaluated over Steklov \
boundary instead of inside the domain.
"""
value = -1
def __init__(self):
"""Consecutive Steklov objects must be distinguishable."""
super(SteklovBoundary, self).__init__()
self.value = SteklovBoundary.value
SteklovBoundary.value -= 1
self.update(param="1")
#
# tools
#
def build_bc_dict():
"""
Return dictionary of all boundary conditions.
Keys: BC names
Values: BC classes
"""
from inspect import getdoc
import re
bc_dict = {}
for subcls in GenericBoundary.__subclasses__():
lines = re.sub(r'\\\n', '', getdoc(subcls)).split("\n")
subcls.name = lines[0][:-1]
subcls.help = "\n".join(lines[2:])
try:
dumps(subcls())
bc_dict[subcls.name] = subcls
except:
print subcls.name + ' not picklable'
return bc_dict
class OnBoundary(SubDomain):
""" Boundary as subdomain. """
def inside(self, _, on):
""" True for any boundary point. """
return on
def marked_boundary(mesh):
""" Return array of vertex values with 1 on boundary, 0 otherwise. """
fun = FacetFunction("int", mesh, 0)
on = OnBoundary()
on.mark(fun, 1)
return fun.array()
def mark_conditions(mesh, lst):
""" Mark all boundary conditions from the list. """
fun = FacetFunction("int", mesh, 0)
for bc in lst:
sub = OnBoundary()
# overwrite inside function with the one from bc
sub.inside = bc.getTest()
sub.mark(fun, bc.value)
return fun.array()
def get_bc_parts(mesh, lst):
"""
Build a size_t function with boundary condition parts.
Returns all Robin and Steklov conditions that need to be applied,
the shift needed to get a nonnegative function,
and the function itself.
"""
if len(lst) > 0:
shift = max(0, -min(e.value for e in lst))
else:
return [], [], 0, FacetFunction("size_t", mesh, 0)
# values must be shifted by smallest Steklov value since size_t is unsigned
fun = FacetFunction("size_t", mesh, shift)
for bc in lst:
sub = OnBoundary()
# overwrite inside function with the one from bc
sub.inside = bc.getTest()
sub.mark(fun, bc.value + shift)
# some conditions may cancel eachother
exist = set(np.unique(fun.array()))
lst = [e for e in lst if e.value+shift in exist]
# separate Robin and Steklov, Dirichlet and Neumann are irrelevant
Robin = [e for e in lst if e.value > 1 and e.parValue != 0]
Steklov = [e for e in lst if e.value < 0 and e.parValue != 0]
return Robin, Steklov, shift, fun