def test_equation_2d_4():
V = VectorFunctionSpace('V', domain)
v = element_of(V, name='v')
u = element_of(V, name='u')
x, y = domain.coordinates
B1 = Boundary(r'\Gamma_1', domain)
int_0 = lambda expr: integral(domain, expr)
int_1 = lambda expr: integral(B1, expr)
# ... bilinear/linear forms
a1 = BilinearForm((v, u), int_0(inner(grad(v), grad(u))))
f = Tuple(x * y, sin(pi * x) * sin(pi * y))
l1 = LinearForm(v, int_0(dot(f, v)))
# ...
# ...
bc = EssentialBC(u, 0, B1)
eq = Equation(a1, l1, tests=v, trials=u, bc=bc)
# ...
# ...
bc = EssentialBC(u[0], 0, B1)
eq = Equation(a1, l1, tests=v, trials=u, bc=bc)
# ...
# ...
nn = NormalVector('nn')
bc = EssentialBC(dot(u, nn), 0, B1)
eq = Equation(a1, l1, tests=v, trials=u, bc=bc)
def test_equation_2d_3():
V = ScalarFunctionSpace('V', domain)
v = element_of(V, name='v')
u = element_of(V, name='u')
x, y = domain.coordinates
B1 = Boundary(r'\Gamma_1', domain)
int_0 = lambda expr: integral(domain, expr)
int_1 = lambda expr: integral(B1, expr)
# ... bilinear/linear forms
a1 = BilinearForm((v, u), int_0(dot(grad(v), grad(u))))
a2 = BilinearForm((v, u), int_0(v * u))
l1 = LinearForm(v, int_0(x * y * v))
l2 = LinearForm(v, int_0(cos(x + y) * v))
# ...
# ...
bc = EssentialBC(u, 0, B1)
eq = Equation(a1, l1, tests=v, trials=u, bc=bc)
# ...
# ...
nn = NormalVector('nn')
bc = EssentialBC(dot(grad(u), nn), 0, B1)
eq = Equation(a1, l1, tests=v, trials=u, bc=bc)
def test_terminal_expr_bilinear_2d_2():
domain = Domain('Omega', dim=2)
B1 = Boundary(r'\Gamma_1', domain)
x, y = domain.coordinates
kappa = Constant('kappa', is_real=True)
mu = Constant('mu', is_real=True)
nn = NormalVector('nn')
V = VectorFunctionSpace('V', domain)
u, u1, u2 = [element_of(V, name=i) for i in ['u', 'u1', 'u2']]
v, v1, v2 = [element_of(V, name=i) for i in ['v', 'v1', 'v2']]
# ...
int_0 = lambda expr: integral(domain, expr)
int_1 = lambda expr: integral(B1, expr)
a = BilinearForm((u, v), int_0(dot(u, v)))
print(TerminalExpr(a))
print('')
# ...
a = BilinearForm((u, v), int_0(inner(grad(u), grad(v))))
print(TerminalExpr(a))
print('')
# ...
# ...
a = BilinearForm((u, v), int_0(dot(u, v) + inner(grad(u), grad(v))))
print(TerminalExpr(a))
print('')
def eval(cls, *_args):
"""."""
if not _args:
return
if not len(_args) == 1:
raise ValueError('Expecting one argument')
expr = _args[0]
if isinstance(expr, Add):
args = [cls.eval(a) for a in expr.args]
return Add(*args)
elif isinstance(expr, Mul):
coeffs = [a for a in expr.args if isinstance(a, _coeffs_registery)]
vectors = [a for a in expr.args if not(a in coeffs)]
a = S.One
if coeffs:
a = Mul(*coeffs)
b = S.One
if vectors:
try:
if len(vectors) == 1:
f = vectors[0]
b = cls(f)
elif len(vectors) == 2:
f,g = vectors
b = f*cls(g) + g*cls(f)
else:
left = vectors[0]
right = Mul(*vectors[1:])
f_left = cls(left, evaluate=True)
f_right = cls(right, evaluate=True)
b = left * f_right + f_left * right
except:
b = cls(Mul(*vectors), evaluate=False)
return Mul(a, b)
elif isinstance(expr, NormalDerivative):
n = NormalVector('n')
u = expr._args[0]
return Dot(Grad(cls(u)), cls(n))
elif isinstance(expr, NormalVector):
return PlusNormalVector('n')
return cls(expr, evaluate=False)
def _print_NormalDerivative(self, expr):
nn = self._print(NormalVector('n'))
arg = expr.args[0]
if isinstance(arg, (ScalarFunction, VectorFunction)):
arg = r'\nabla ' + self._print(arg)
else:
arg = r'\nabla \left( ' + self._print(arg) + r' \right)'
return arg + r' \cdot ' + nn
def test_essential_bc_1():
domain = Domain('Omega', dim=2)
V = ScalarFunctionSpace('V', domain)
W = VectorFunctionSpace('W', domain)
v = element_of(V, name='v')
w = element_of(W, name='w')
B1 = Boundary(r'\Gamma_1', domain)
nn = NormalVector('nn')
# ... scalar case
bc = EssentialBC(v, 0, B1)
assert (bc.variable == v)
assert (bc.order == 0)
assert (bc.normal_component == False)
assert (bc.index_component == None)
# ...
# ... scalar case
bc = EssentialBC(dot(grad(v), nn), 0, B1)
assert (bc.variable == v)
assert (bc.order == 1)
assert (bc.normal_component == False)
assert (bc.index_component == None)
# ...
# ... vector case
bc = EssentialBC(w, 0, B1)
assert (bc.variable == w)
assert (bc.order == 0)
assert (bc.normal_component == False)
assert (bc.index_component == [0, 1])
# ...
# ... vector case
bc = EssentialBC(dot(w, nn), 0, B1)
assert (bc.variable == w)
assert (bc.order == 0)
assert (bc.normal_component == True)
assert (bc.index_component == None)
# ...
# ... vector case
bc = EssentialBC(w[0], 0, B1)
assert (bc.variable == w)
assert (bc.order == 0)
assert (bc.normal_component == False)
assert (bc.index_component == [0])
def test_terminal_expr_linear_2d_5(boundary=[r'\Gamma_1', r'\Gamma_3']):
# ... abstract model
domain = Square()
V = ScalarFunctionSpace('V', domain)
B_neumann = [domain.get_boundary(i) for i in boundary]
if len(B_neumann) == 1:
B_neumann = B_neumann[0]
else:
B_neumann = Union(*B_neumann)
x, y = domain.coordinates
nn = NormalVector('nn')
F = element_of(V, name='F')
v = element_of(V, name='v')
u = element_of(V, name='u')
int_0 = lambda expr: integral(domain, expr)
int_1 = lambda expr: integral(B_neumann, expr)
expr = dot(grad(v), grad(u))
a = BilinearForm((v, u), int_0(expr))
solution = cos(0.5 * pi * x) * cos(0.5 * pi * y)
f = (1. / 2.) * pi**2 * solution
expr = f * v
l0 = LinearForm(v, int_0(expr))
expr = v * dot(grad(solution), nn)
l_B_neumann = LinearForm(v, int_1(expr))
expr = l0(v) + l_B_neumann(v)
l = LinearForm(v, expr)
print(TerminalExpr(l))
print('')
def test_terminal_expr_linear_2d_3():
domain = Square()
B = domain.boundary
x, y = domain.coordinates
kappa = Constant('kappa', is_real=True)
mu = Constant('mu', is_real=True)
nn = NormalVector('nn')
V = ScalarFunctionSpace('V', domain)
u, u1, u2 = [element_of(V, name=i) for i in ['u', 'u1', 'u2']]
v, v1, v2 = [element_of(V, name=i) for i in ['v', 'v1', 'v2']]
# ...
int_0 = lambda expr: integral(domain, expr)
int_1 = lambda expr: integral(B, expr)
l = LinearForm(v, int_1(dot(grad(v), nn)))
print(TerminalExpr(l))
print('')
def eval(cls, *_args, **kwargs):
"""."""
if not _args:
return
if not len(_args) == 1:
raise ValueError('Expecting one argument')
expr = _args[0]
n_rows = kwargs.pop('n_rows', None)
n_cols = kwargs.pop('n_cols', None)
dim = kwargs.pop('dim', None)
if isinstance(expr, Add):
args = [cls.eval(a, dim=dim) for a in expr.args]
o = args[0]
for arg in args[1:]:
o = o + arg
return o
elif isinstance(expr, Mul):
args = [cls.eval(a, dim=dim) for a in expr.args]
o = args[0]
for arg in args[1:]:
o = o * arg
return o
elif isinstance(expr, (ScalarTestFunction, VectorTestFunction)):
return expr
elif isinstance(expr, BasicForm):
# ...
dim = expr.ldim
domain = expr.domain
if isinstance(domain, Union):
domain = list(domain._args)
elif not is_sequence(domain):
domain = [domain]
# ...
# ...
d_expr = {}
for d in domain:
d_expr[d] = S.Zero
# ...
if isinstance(expr.expr, Add):
for a in expr.expr.args:
newexpr = cls.eval(a, dim=dim)
newexpr = expand(newexpr)
# ...
try:
domain = _get_domain(a)
if isinstance(domain, Union):
domain = list(domain._args)
elif not is_sequence(domain):
domain = [domain]
except:
pass
# ...
# ...
for d in domain:
d_expr[d] += newexpr
# ...
else:
newexpr = cls.eval(expr.expr, dim=dim)
newexpr = expand(newexpr)
# ...
if isinstance(expr, Functional):
domain = expr.domain
else:
domain = _get_domain(expr.expr)
if isinstance(domain, Union):
domain = list(domain._args)
elif not is_sequence(domain):
domain = [domain]
# ...
# ...
for d in domain:
d_expr[d] += newexpr
# ...
# ...
# ...
d_new = {}
for domain, newexpr in d_expr.items():
if newexpr != 0:
M, test_indices, trial_indices = _init_matrix(expr)
M = _to_matrix_form(newexpr, M, test_indices,
trial_indices)
# TODO ARA make sure thre is no problem with psydac
# we should always take the interior of a domain
if not isinstance(domain,
(Boundary, Interface, InteriorDomain)):
domain = domain.interior
d_new[domain] = M
# ...
# ...
ls = []
d_all = {}
# ...
# print(d_new)
# print([type(i) for i in d_new.keys()])
# ... treating interfaces
keys = [k for k in d_new.keys() if isinstance(k, Interface)]
for interface in keys:
# ...
trials = None
tests = None
if expr.is_bilinear:
trials = list(expr.variables[0])
tests = list(expr.variables[1])
elif expr.is_linear:
tests = list(expr.variables)
# ...
# ...
newexpr = d_new[interface]
ls_int, d = _split_expr_over_interface(newexpr,
interface,
tests=tests,
trials=trials)
# ...
# ...
ls += ls_int
# ...
# ...
for k, v in d.items():
if k in d_all.keys():
d_all[k] += v
else:
d_all[k] = v
# ...
# ...
# ... treating subdomains
keys = [k for k in d_new.keys() if isinstance(k, Union)]
for domain in keys:
# ...
trials = None
tests = None
if expr.is_bilinear:
trials = list(expr.variables[0])
tests = list(expr.variables[1])
elif expr.is_linear:
tests = list(expr.variables)
else:
raise NotImplementedError(
'Only Bilinear and Linear forms are available')
# ...
# ...
newexpr = d_new[domain]
d = _split_expr_over_subdomains(newexpr,
domain.as_tuple(),
tests=tests,
trials=trials)
# ...
# ...
for k, v in d.items():
if k in d_all.keys():
d_all[k] += v
else:
d_all[k] = v
# ...
# ...
# ...
d = {}
for k, v in d_new.items():
if not isinstance(k, (Interface, Union)):
d[k] = d_new[k]
for k, v in d_all.items():
if k in d.keys():
d[k] += v
else:
d[k] = v
d_new = d
# ...
# ...
for domain, newexpr in d_new.items():
if isinstance(domain, Boundary):
ls += [BoundaryExpression(domain, newexpr)]
elif isinstance(domain, Interface):
ls += [InterfaceExpression(domain, newexpr)]
elif isinstance(domain, BasicDomain):
ls += [DomainExpression(domain, newexpr)]
else:
raise TypeError('not implemented for {}'.format(
type(domain)))
# ...
return ls
elif isinstance(expr,
(DomainIntegral, BoundaryIntegral, InterfaceIntegral)):
if dim is None:
domain = expr.domain
dim = domain.dim
return cls.eval(expr._args[0], dim=dim)
elif isinstance(expr, NormalVector):
lines = [[expr[i] for i in range(dim)]]
return Matrix(lines)
elif isinstance(expr, TangentVector):
lines = [[expr[i] for i in range(dim)]]
return Matrix(lines)
elif isinstance(expr, BasicExpr):
return cls.eval(expr.expr, dim=dim)
elif isinstance(expr, _generic_ops):
# if i = Dot(...) then type(i) is Grad
op = type(expr)
new = eval('{0}_{1}d'.format(op, dim))
args = [cls.eval(i, dim=dim) for i in expr.args]
return new(*args)
elif isinstance(expr, Trace):
# TODO treate different spaces
if expr.order == 0:
return cls.eval(expr.expr, dim=dim)
elif expr.order == 1:
# TODO give a name to normal vector
normal_vector_name = 'n'
n = NormalVector(normal_vector_name)
M = cls.eval(expr.expr, dim=dim)
if dim == 1:
return M
else:
if isinstance(M, (Add, Mul)):
ls = M.atoms(Tuple)
for i in ls:
M = M.subs(i, Matrix(i))
M = simplify(M)
e = 0
for i in range(0, dim):
e += M[i] * n[i]
return e
else:
raise ValueError(
'> Only traces of order 0 and 1 are available')
elif isinstance(expr, Matrix):
n, m = expr.shape
lines = []
for i in range(0, n):
line = []
for j in range(0, m):
line.append(cls.eval(expr[i, j], dim=dim))
lines.append(line)
return Matrix(lines)
return expr
def test_terminal_expr_bilinear_2d_3():
domain = Square()
V = ScalarFunctionSpace('V', domain)
B = domain.boundary
v = element_of(V, name='v')
u = element_of(V, name='u')
kappa = Constant('kappa', is_real=True)
mu = Constant('mu', is_real=True)
nn = NormalVector('nn')
int_0 = lambda expr: integral(domain, expr)
int_1 = lambda expr: integral(B, expr)
# nitsche
a0 = BilinearForm((u, v), int_0(dot(grad(v), grad(u))))
a_B = BilinearForm((u,v), int_1(-u*dot(grad(v), nn) \
-v*dot(grad(u), nn) \
+kappa*u*v))
a = BilinearForm((u, v), a0(u, v) + a_B(u, v))
print(TerminalExpr(a))
print('')
a = BilinearForm(
(u, v),
int_0(u * v + dot(grad(u), grad(v))) + int_1(v * dot(grad(u), nn)))
print(TerminalExpr(a))
print('')
# ...
# ...
a = BilinearForm((u, v), int_0(u * v))
print(TerminalExpr(a))
print('')
# ...
# ...
a1 = BilinearForm((u, v), int_0(u * v))
a = BilinearForm((u, v), a1(u, v))
print(TerminalExpr(a))
print('')
# ...
# ...
a1 = BilinearForm((u, v), int_0(u * v))
a2 = BilinearForm((u, v), int_0(dot(grad(u), grad(v))))
a = BilinearForm((u, v), a1(u, v) + a2(u, v))
print(TerminalExpr(a))
print('')
# ...
# ...
a1 = BilinearForm((u, v), int_0(u * v))
a2 = BilinearForm((u, v), int_0(dot(grad(u), grad(v))))
a = BilinearForm((u, v), a1(u, v) + kappa * a2(u, v))
print(TerminalExpr(a))
print('')
# ...
# ...
a1 = BilinearForm((u, v), int_0(u * v))
a2 = BilinearForm((u, v), int_0(dot(grad(u), grad(v))))
a3 = BilinearForm((u, v), int_1(v * dot(grad(u), nn)))
a = BilinearForm((u, v), a1(u, v) + kappa * a2(u, v) + mu * a3(u, v))
print(TerminalExpr(a))
print('')
def test_linearity_linear_form_2d_1():
from sympde.expr.errors import UnconsistentLinearExpressionError
domain = Domain('Omega', dim=2)
B1 = Boundary(r'\Gamma_1', domain)
x, y = domain.coordinates
kappa = Constant('kappa', is_real=True)
mu = Constant('mu', is_real=True)
nn = NormalVector('nn')
V = ScalarFunctionSpace('V', domain)
W = VectorFunctionSpace('W', domain)
v, v1, v2 = elements_of(V, names='v, v1, v2')
w = element_of(W, name='w')
# ...
int_0 = lambda expr: integral(domain, expr)
int_1 = lambda expr: integral(B1, expr)
# The following integral expressions are linear, hence it must be possible
# to create LinearForm objects from them
_ = LinearForm(v, int_0(x * y * v))
_ = LinearForm(v, int_0(x * y * v + v))
g = Matrix((x**2, y**2))
_ = LinearForm(v, int_0(v * dot(g, nn)))
g = Matrix((x**2, y**2))
_ = LinearForm(v, int_1(v * dot(g, nn)) + int_0(x * y * v))
l1 = LinearForm(v1, int_0(x * y * v1))
_ = LinearForm(v, l1(v))
g = Matrix((x, y))
l1 = LinearForm(v1, int_0(x * y * v1))
l2 = LinearForm(v2, int_0(dot(grad(v2), g)))
_ = LinearForm(v, l1(v) + l2(v))
l1 = LinearForm(v1, int_0(x * y * v1))
l2 = LinearForm(v1, int_0(v1))
_ = LinearForm(v, l1(v) + kappa * l2(v))
g = Matrix((x**2, y**2))
l1 = LinearForm(v1, int_0(x * y * v1))
l2 = LinearForm(v1, int_0(v1))
l3 = LinearForm(v, int_1(v * dot(g, nn)))
_ = LinearForm(v, l1(v) + kappa * l2(v) + mu * l3(v))
l1 = LinearForm(w, int_0(5 * w * x))
l2 = LinearForm(w, int_1(w * y))
_ = LinearForm(w, l1(w) + kappa * l2(w))
l0 = LinearForm(v, int_0(x * y * v))
l1 = LinearForm(w, int_0(w[0] * y))
l2 = LinearForm(w, int_1(w[1] * x))
l3 = LinearForm(w, kappa * l1(w) + mu * l2(w))
_ = LinearForm((v, w), l0(v) + l3(w))
# The following integral expressions are not linear, hence LinearForm must
# raise an exception
with pytest.raises(UnconsistentLinearExpressionError):
_ = LinearForm(v, int_0(x * y * v + 1))
with pytest.raises(UnconsistentLinearExpressionError):
_ = LinearForm(v, int_0(x * v**2))
with pytest.raises(UnconsistentLinearExpressionError):
_ = LinearForm(v, int_0(x * y * v) + int_1(v * exp(v)))
with pytest.raises(UnconsistentLinearExpressionError):
_ = LinearForm(w, int_0(w * w))
with pytest.raises(UnconsistentLinearExpressionError):
_ = LinearForm(w, int_0(w[0] * w[1]))
with pytest.raises(UnconsistentLinearExpressionError):
_ = LinearForm((v, w), int_0(x * w[0]) + int_1(v * w[1]))
def test_terminal_expr_bilinear_2d_1():
domain = Domain('Omega', dim=2)
B1 = Boundary(r'\Gamma_1', domain)
x, y = domain.coordinates
kappa = Constant('kappa', is_real=True)
mu = Constant('mu', is_real=True)
eps = Constant('eps', real=True)
nn = NormalVector('nn')
V = ScalarFunctionSpace('V', domain)
u, u1, u2 = [element_of(V, name=i) for i in ['u', 'u1', 'u2']]
v, v1, v2 = [element_of(V, name=i) for i in ['v', 'v1', 'v2']]
# ...
int_0 = lambda expr: integral(domain, expr)
int_1 = lambda expr: integral(B1, expr)
a = BilinearForm((u, v), int_0(u * v))
print(a)
print(TerminalExpr(a))
print('')
# ...
# ...
a = BilinearForm((u, v), int_0(dot(grad(u), grad(v))))
print(a)
print(TerminalExpr(a))
print('')
# ...
# ...
a = BilinearForm((u, v), int_0(u * v + dot(grad(u), grad(v))))
print(a)
print(TerminalExpr(a))
print('')
# ...
# ...
a = BilinearForm(
(u, v),
int_0(u * v + dot(grad(u), grad(v))) + int_1(v * dot(grad(u), nn)))
print(a)
print(TerminalExpr(a))
print('')
# ...
# ...
a = BilinearForm(((u1, u2), (v1, v2)), int_0(u1 * v1 + u2 * v2))
print(a)
print(TerminalExpr(a))
print('')
# ...
# ...
a1 = BilinearForm((u1, v1), int_0(u1 * v1))
a = BilinearForm((u, v), a1(u, v))
print(a)
print(TerminalExpr(a))
print('')
# ...
# ...
a1 = BilinearForm((u1, v1), int_0(u1 * v1))
a2 = BilinearForm((u2, v2), int_0(dot(grad(u2), grad(v2))))
a = BilinearForm((u, v), a1(u, v) + a2(u, v))
print(a)
print(TerminalExpr(a))
print('')
# ...
# ...
a1 = BilinearForm((u1, v1), int_0(u1 * v1))
a2 = BilinearForm((u2, v2), int_0(dot(grad(u2), grad(v2))))
a = BilinearForm((u, v), a1(u, v) + kappa * a2(u, v))
print(a)
print(TerminalExpr(a))
print('')
# ...
# ...
a1 = BilinearForm((u1, v1), int_0(u1 * v1))
a2 = BilinearForm((u2, v2), int_0(dot(grad(u2), grad(v2))))
a3 = BilinearForm((u, v), int_1(v * dot(grad(u), nn)))
a = BilinearForm((u, v), a1(u, v) + kappa * a2(u, v) + mu * a3(u, v))
print(a)
print(TerminalExpr(a))
print('')
# ...
# ... Poisson with Nitsch method
a0 = BilinearForm((u, v), int_0(dot(grad(u), grad(v))))
a_B1 = BilinearForm((u, v),
int_1(-kappa * u * dot(grad(v), nn) -
v * dot(grad(u), nn) + u * v / eps))
a = BilinearForm((u, v), a0(u, v) + a_B1(u, v))
print(a)
print(TerminalExpr(a))
print('')
def test_terminal_expr_linear_2d_1():
domain = Domain('Omega', dim=2)
B1 = Boundary(r'\Gamma_1', domain)
x, y = domain.coordinates
kappa = Constant('kappa', is_real=True)
mu = Constant('mu', is_real=True)
nn = NormalVector('nn')
V = ScalarFunctionSpace('V', domain)
u, u1, u2 = [element_of(V, name=i) for i in ['u', 'u1', 'u2']]
v, v1, v2 = [element_of(V, name=i) for i in ['v', 'v1', 'v2']]
# ...
int_0 = lambda expr: integral(domain, expr)
int_1 = lambda expr: integral(B1, expr)
l = LinearForm(v, int_0(x * y * v))
print(TerminalExpr(l))
print('')
# ...
# ...
l = LinearForm(v, int_0(x * y * v + v))
print(TerminalExpr(l))
print('')
# ...
# ...
g = Matrix((x**2, y**2))
l = LinearForm(v, int_1(v * dot(g, nn)))
print(TerminalExpr(l))
print('')
# ...
# ...
g = Matrix((x**2, y**2))
l = LinearForm(v, int_1(v * dot(g, nn)) + int_0(x * y * v))
print(TerminalExpr(l))
print('')
# ...
# ...
l1 = LinearForm(v1, int_0(x * y * v1))
l = LinearForm(v, l1(v))
print(TerminalExpr(l))
print('')
# ...
# ...
g = Matrix((x, y))
l1 = LinearForm(v1, int_0(x * y * v1))
l2 = LinearForm(v2, int_0(dot(grad(v2), g)))
l = LinearForm(v, l1(v) + l2(v))
print(TerminalExpr(l))
print('')
# ...
# ...
l1 = LinearForm(v1, int_0(x * y * v1))
l2 = LinearForm(v1, int_0(v1))
l = LinearForm(v, l1(v) + kappa * l2(v))
print(TerminalExpr(l))
print('')
# ...
# ...
g = Matrix((x**2, y**2))
l1 = LinearForm(v1, int_0(x * y * v1))
l2 = LinearForm(v1, int_0(v1))
l3 = LinearForm(v, int_1(v * dot(g, nn)))
l = LinearForm(v, l1(v) + kappa * l2(v) + mu * l3(v))
print(TerminalExpr(l))
print('')
def test_bilinear_form_2d_1():
domain = Domain('Omega', dim=2)
B1 = Boundary(r'\Gamma_1', domain)
x, y = domain.coordinates
kappa = Constant('kappa', is_real=True)
mu = Constant('mu', is_real=True)
nn = NormalVector('nn')
V = ScalarFunctionSpace('V', domain)
u, u1, u2 = [element_of(V, name=i) for i in ['u', 'u1', 'u2']]
v, v1, v2 = [element_of(V, name=i) for i in ['v', 'v1', 'v2']]
# ...
int_0 = lambda expr: integral(domain, expr)
int_1 = lambda expr: integral(B1, expr)
a = BilinearForm((u, v), int_0(u * v))
assert (a.domain == domain.interior)
assert (a(u1, v1) == int_0(u1 * v1))
# ...
# ...
a = BilinearForm((u, v), int_0(u * v + dot(grad(u), grad(v))))
assert (a.domain == domain.interior)
assert (a(u1, v1) == int_0(u1 * v1) + int_0(dot(grad(u1), grad(v1))))
# ...
# ...
a = BilinearForm((u, v), int_1(v * dot(grad(u), nn)))
assert (a.domain == B1)
assert (a(u1, v1) == int_1(v1 * trace_1(grad(u1), B1)))
# ...
# ...
a = BilinearForm((u, v), int_0(u * v) + int_1(v * dot(grad(u), nn)))
# TODO a.domain are not ordered
assert (len(a.domain.args) == 2)
for i in a.domain.args:
assert (i in [domain.interior, B1])
assert (a(u1, v1) == int_0(u1 * v1) + int_1(v1 * trace_1(grad(u1), B1)))
# ...
# ...
a1 = BilinearForm((u1, v1), int_0(u1 * v1))
a = BilinearForm((u, v), a1(u, v))
assert (a.domain == domain.interior)
assert (a(u2, v2) == int_0(u2 * v2))
# ...
# ...
a1 = BilinearForm((u1, v1), int_0(u1 * v1))
a2 = BilinearForm((u2, v2), int_0(dot(grad(u2), grad(v2))))
a = BilinearForm((u, v), a1(u, v) + kappa * a2(u, v))
assert (a.domain == domain.interior)
assert (a(u, v) == int_0(u * v) + int_0(kappa * dot(grad(u), grad(v))))
def test_linearity_bilinear_form_2d_1():
from sympde.expr.errors import UnconsistentLinearExpressionError
domain = Domain('Omega', dim=2)
B1 = Boundary(r'\Gamma_1', domain)
x, y = domain.coordinates
kappa = Constant('kappa', is_real=True)
mu = Constant('mu', is_real=True)
eps = Constant('eps', real=True)
nn = NormalVector('nn')
V = ScalarFunctionSpace('V', domain)
u, u1, u2 = elements_of(V, names='u, u1, u2')
v, v1, v2 = elements_of(V, names='v, v1, v2')
# ...
int_0 = lambda expr: integral(domain, expr)
int_1 = lambda expr: integral(B1, expr)
# The following integral expressions are bilinear, hence it must be possible
# to create BilinearForm objects from them
_ = BilinearForm((u, v), int_0(u * v))
_ = BilinearForm((u, v), int_0(dot(grad(u), grad(v))))
_ = BilinearForm((u, v), int_0(u * v + dot(grad(u), grad(v))))
_ = BilinearForm(
(u, v),
int_0(u * v + dot(grad(u), grad(v))) + int_1(v * dot(grad(u), nn)))
_ = BilinearForm(((u1, u2), (v1, v2)), int_0(u1 * v1 + u2 * v2))
a1 = BilinearForm((u1, v1), int_0(u1 * v1))
_ = BilinearForm((u, v), a1(u, v))
a1 = BilinearForm((u1, v1), int_0(u1 * v1))
a2 = BilinearForm((u2, v2), int_0(dot(grad(u2), grad(v2))))
_ = BilinearForm((u, v), a1(u, v) + a2(u, v))
a1 = BilinearForm((u1, v1), int_0(u1 * v1))
a2 = BilinearForm((u2, v2), int_0(dot(grad(u2), grad(v2))))
_ = BilinearForm((u, v), a1(u, v) + kappa * a2(u, v))
a1 = BilinearForm((u1, v1), int_0(u1 * v1))
a2 = BilinearForm((u2, v2), int_0(dot(grad(u2), grad(v2))))
a3 = BilinearForm((u, v), int_1(v * dot(grad(u), nn)))
_ = BilinearForm((u, v), a1(u, v) + kappa * a2(u, v) + mu * a3(u, v))
# ... Poisson with Nitsch method
a0 = BilinearForm((u, v), int_0(dot(grad(u), grad(v))))
a_B1 = BilinearForm((u, v),
int_1(-kappa * u * dot(grad(v), nn) -
v * dot(grad(u), nn) + u * v / eps))
_ = BilinearForm((u, v), a0(u, v) + a_B1(u, v))
# ...
# The following integral expressions are not bilinear, hence BilinearForm must
# raise an exception
with pytest.raises(UnconsistentLinearExpressionError):
_ = BilinearForm((u, v), int_0(x * y * dot(grad(u), grad(v)) + 1))
with pytest.raises(UnconsistentLinearExpressionError):
_ = BilinearForm((u, v), int_0(x * dot(grad(u), grad(v**2))))
with pytest.raises(UnconsistentLinearExpressionError):
_ = BilinearForm((u, v), int_0(u * v) + int_1(v * exp(u)))
def test_equation_2d_1():
V = ScalarFunctionSpace('V', domain)
U = ScalarFunctionSpace('U', domain)
v = element_of(V, name='v')
u = element_of(U, name='u')
x, y = domain.coordinates
alpha = Constant('alpha')
kappa = Constant('kappa', real=True)
eps = Constant('eps', real=True)
nn = NormalVector('nn')
B1 = Boundary(r'\Gamma_1', domain)
B2 = Boundary(r'\Gamma_2', domain)
B3 = Boundary(r'\Gamma_3', domain)
int_0 = lambda expr: integral(domain, expr)
int_1 = lambda expr: integral(B1, expr)
int_2 = lambda expr: integral(B2, expr)
# ... bilinear/linear forms
expr = dot(grad(v), grad(u))
a1 = BilinearForm((v, u), int_0(expr))
expr = v * u
a2 = BilinearForm((v, u), int_0(expr))
expr = v * u
a_B1 = BilinearForm((v, u), int_1(expr))
expr = x * y * v
l1 = LinearForm(v, int_0(expr))
expr = cos(x + y) * v
l2 = LinearForm(v, int_0(expr))
expr = x * y * v
l_B2 = LinearForm(v, int_2(expr))
# ...
# # ...
# with pytest.raises(UnconsistentLhsError):
# equation = Equation(a1, l1(v))
#
# with pytest.raises(UnconsistentLhsError):
# equation = Equation(l1(v), l1(v))
#
# with pytest.raises(UnconsistentLhsError):
# equation = Equation(a1(v,u) + alpha*a2(v,u), l1(v))
# # ...
#
# # ...
# with pytest.raises(UnconsistentRhsError):
# equation = Equation(a1(v,u), l1)
#
# with pytest.raises(UnconsistentRhsError):
# equation = Equation(a1(v,u), a1(v,u))
#
# with pytest.raises(UnconsistentRhsError):
# equation = Equation(a1(v,u), l1(v) + l2(v))
# # ...
# ...
equation = Equation(a1, l1, tests=v, trials=u)
# ...
# ...
a = BilinearForm((v, u), a1(v, u) + alpha * a2(v, u))
equation = Equation(a, l1, tests=v, trials=u)
# ...
# ...
a = BilinearForm((v, u), a1(v, u) + a_B1(v, u))
equation = Equation(a, l1, tests=v, trials=u)
# ...
# ...
a = BilinearForm((v, u), a1(v, u) + a_B1(v, u))
l = LinearForm(v, l1(v) + l2(v))
equation = Equation(a, l, tests=v, trials=u)
# ...
# ...
a = BilinearForm((v, u), a1(v, u) + a_B1(v, u))
l = LinearForm(v, l1(v) + alpha * l_B2(v))
equation = Equation(a, l, tests=v, trials=u)
# ...
# ... using bc
equation = Equation(a1, l1, tests=v, trials=u, bc=EssentialBC(u, 0, B1))
# ...
# ... Poisson with Nitsch method
g = cos(pi * x) * cos(pi * y)
a0 = BilinearForm((u, v), int_0(dot(grad(u), grad(v))))
a_B1 = BilinearForm((u, v), -int_1(kappa * u * dot(grad(v), nn) -
v * dot(grad(u), nn) + u * v / eps))
a = BilinearForm((u, v), a0(u, v) + a_B1(u, v))
l = LinearForm(v, int_0(g * v / eps) - int_1(kappa * v * g))
equation = Equation(a, l, tests=v, trials=u)
def test_linear_form_2d_1():
domain = Domain('Omega', dim=2)
B1 = Boundary(r'\Gamma_1', domain)
x, y = domain.coordinates
kappa = Constant('kappa', is_real=True)
mu = Constant('mu', is_real=True)
nn = NormalVector('nn')
V = ScalarFunctionSpace('V', domain)
W = VectorFunctionSpace('W', domain)
u, u1, u2 = [element_of(V, name=i) for i in ['u', 'u1', 'u2']]
v, v1, v2 = [element_of(V, name=i) for i in ['v', 'v1', 'v2']]
# ...
int_0 = lambda expr: integral(domain, expr)
int_1 = lambda expr: integral(B1, expr)
l = LinearForm(v, int_0(x * y * v))
assert (l.domain == domain.interior)
assert (l(v1) == int_0(x * y * v1))
# ...
# ...
g = Tuple(x**2, y**2)
l = LinearForm(v, int_1(v * dot(g, nn)))
print(l)
assert (l.domain == B1)
assert (l(v1) == int_1(v1 * trace_1(g, B1)))
# ...
# ...
g = Tuple(x**2, y**2)
l = LinearForm(v, int_1(v * dot(g, nn)) + int_0(x * y * v))
assert (len(l.domain.args) == 2)
for i in l.domain.args:
assert (i in [domain.interior, B1])
assert (l(v1) == int_1(v1 * trace_1(g, B1)) + int_0(x * y * v1))
# ...
# ...
l1 = LinearForm(v1, int_0(x * y * v1))
l = LinearForm(v, l1(v))
assert (l.domain == domain.interior)
assert (l(u1) == int_0(x * y * u1))
# ...
# ...
g = Tuple(x, y)
l1 = LinearForm(u1, int_0(x * y * u1))
l2 = LinearForm(u2, int_0(dot(grad(u2), g)))
l = LinearForm(v, l1(v) + l2(v))
assert (l.domain == domain.interior)
assert (l(v1) == int_0(x * y * v1) + int_0(dot(grad(v1), g)))
# ...
# ...
pn, wn = [element_of(V, name=i) for i in ['pn', 'wn']]
tau = element_of(V, name='tau')
sigma = element_of(V, name='sigma')
Re = Constant('Re', real=True)
dt = Constant('dt', real=True)
alpha = Constant('alpha', real=True)
l1 = LinearForm(
tau, int_0(bracket(pn, wn) * tau - 1. / Re * dot(grad(tau), grad(wn))))
l = LinearForm((tau, sigma), dt * l1(tau))
assert (l.domain == domain.interior)
assert (l(u1,
u2).expand() == int_0(-1.0 * dt * dot(grad(u1), grad(wn)) / Re) +
int_0(dt * u1 * bracket(pn, wn)))
