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__copyright__ = "Copyright (C) 2015 Andreas Kloeckner"
__license__ = """
Permission is hereby granted, free of charge, to any person obtaining a copy
of this software and associated documentation files (the "Software"), to deal
in the Software without restriction, including without limitation the rights
to use, copy, modify, merge, publish, distribute, sublicense, and/or sell
copies of the Software, and to permit persons to whom the Software is
furnished to do so, subject to the following conditions:
The above copyright notice and this permission notice shall be included in
all copies or substantial portions of the Software.
THE SOFTWARE IS PROVIDED "AS IS", WITHOUT WARRANTY OF ANY KIND, EXPRESS OR
IMPLIED, INCLUDING BUT NOT LIMITED TO THE WARRANTIES OF MERCHANTABILITY,
FITNESS FOR A PARTICULAR PURPOSE AND NONINFRINGEMENT. IN NO EVENT SHALL THE
AUTHORS OR COPYRIGHT HOLDERS BE LIABLE FOR ANY CLAIM, DAMAGES OR OTHER
LIABILITY, WHETHER IN AN ACTION OF CONTRACT, TORT OR OTHERWISE, ARISING FROM,
OUT OF OR IN CONNECTION WITH THE SOFTWARE OR THE USE OR OTHER DEALINGS IN
THE SOFTWARE.
"""
import numpy as np
import numpy.linalg as la
from meshmode import _acf # noqa: F401
from meshmode.dof_array import flatten, thaw
Andreas Klöckner
committed
import meshmode.mesh.generation as mgen
from pytools.obj_array import flat_obj_array, make_obj_array
from grudge import sym, bind, DiscretizationCollection
import grudge.dof_desc as dof_desc
from meshmode.array_context import ( # noqa
pytest_generate_tests_for_pyopencl_array_context
as pytest_generate_tests)
Andreas Klöckner
committed
@pytest.mark.parametrize("dim", [2, 3])
def test_inverse_metric(actx_factory, dim):
actx = actx_factory()
mesh = mgen.generate_regular_rect_mesh(a=(-0.5,)*dim, b=(0.5,)*dim,
Andreas Klöckner
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n=(6,)*dim, order=4)
def m(x):
result = np.empty_like(x)
result[0] = (
1.5*x[0] + np.cos(x[0])
+ 0.1*np.sin(10*x[1]))
result[1] = (
0.05*np.cos(10*x[0])
+ 1.3*x[1] + np.sin(x[1]))
if len(x) == 3:
result[2] = x[2]
return result
from meshmode.mesh.processing import map_mesh
mesh = map_mesh(mesh, m)
discr = DiscretizationCollection(actx, mesh, order=4)
sym_op = (
sym.forward_metric_derivative_mat(mesh.dim)
.dot(
sym.inverse_metric_derivative_mat(mesh.dim)
)
.reshape(-1))
op = bind(discr, sym_op)
mat = op(actx).reshape(mesh.dim, mesh.dim)
for i in range(mesh.dim):
for j in range(mesh.dim):
tgt = 1 if i == j else 0
err = actx.np.linalg.norm(mat[i, j] - tgt, ord=np.inf)
logger.info("error[%d, %d]: %.5e", i, j, err)
assert err < 1.0e-12, (i, j, err)
# }}}
# {{{ mass operator trig integration
@pytest.mark.parametrize("ambient_dim", [1, 2, 3])
@pytest.mark.parametrize("quad_tag", [dof_desc.QTAG_NONE, "OVSMP"])
def test_mass_mat_trig(actx_factory, ambient_dim, quad_tag):
"""Check the integral of some trig functions on an interval using the mass
actx = actx_factory()
nelements = 17
order = 4
a = -4.0 * np.pi
b = +9.0 * np.pi
true_integral = 13*np.pi/2 * (b - a)**(ambient_dim - 1)
from meshmode.discretization.poly_element import QuadratureSimplexGroupFactory
dd_quad = dof_desc.DOFDesc(dof_desc.DTAG_VOLUME_ALL, quad_tag)
if quad_tag is dof_desc.QTAG_NONE:
quad_tag_to_group_factory = {}
else:
quad_tag_to_group_factory = {
quad_tag: QuadratureSimplexGroupFactory(order=2*order)
}
mesh = mgen.generate_regular_rect_mesh(
a=(a,)*ambient_dim, b=(b,)*ambient_dim,
n=(nelements,)*ambient_dim, order=1)
discr = DiscretizationCollection(actx, mesh, order=order,
quad_tag_to_group_factory=quad_tag_to_group_factory)
def _get_variables_on(dd):
sym_f = sym.var("f", dd=dd)
sym_x = sym.nodes(ambient_dim, dd=dd)
sym_ones = sym.Ones(dd)
return sym_f, sym_x, sym_ones
sym_f, sym_x, sym_ones = _get_variables_on(dof_desc.DD_VOLUME)
f_volm = actx.to_numpy(flatten(bind(discr, sym.cos(sym_x[0])**2)(actx)))
ones_volm = actx.to_numpy(flatten(bind(discr, sym_ones)(actx)))
sym_f, sym_x, sym_ones = _get_variables_on(dd_quad)
f_quad = bind(discr, sym.cos(sym_x[0])**2)(actx)
ones_quad = bind(discr, sym_ones)(actx)
mass_op = bind(discr, sym.MassOperator(dd_quad, dof_desc.DD_VOLUME)(sym_f))
num_integral_1 = np.dot(ones_volm, actx.to_numpy(flatten(mass_op(f=f_quad))))
err_1 = abs(num_integral_1 - true_integral)
assert err_1 < 1e-9, err_1
num_integral_2 = np.dot(f_volm, actx.to_numpy(flatten(mass_op(f=ones_quad))))
err_2 = abs(num_integral_2 - true_integral)
assert err_2 < 1.0e-9, err_2
if quad_tag is dof_desc.QTAG_NONE:
# NOTE: `integral` always makes a square mass matrix and
# `QuadratureSimplexGroupFactory` does not have a `mass_matrix` method.
num_integral_3 = bind(discr,
sym.integral(sym_f, dd=dd_quad))(f=f_quad)
err_3 = abs(num_integral_3 - true_integral)
assert err_3 < 5.0e-10, err_3
# }}}
# {{{ mass operator surface area
def _ellipse_surface_area(radius, aspect_ratio):
# https://docs.scipy.org/doc/scipy/reference/generated/scipy.special.ellipe.html
eccentricity = 1.0 - (1/aspect_ratio)**2
if abs(aspect_ratio - 2.0) < 1.0e-14:
# NOTE: hardcoded value so we don't need scipy for the test
ellip_e = 1.2110560275684594
else:
from scipy.special import ellipe # pylint: disable=no-name-in-module
ellip_e = ellipe(eccentricity)
return 4.0 * radius * ellip_e
def _spheroid_surface_area(radius, aspect_ratio):
# https://en.wikipedia.org/wiki/Ellipsoid#Surface_area
a = 1.0
c = aspect_ratio
if a < c:
e = np.sqrt(1.0 - (a/c)**2)
return 2.0 * np.pi * radius**2 * (1.0 + (c/a) / e * np.arcsin(e))
else:
e = np.sqrt(1.0 - (c/a)**2)
return 2.0 * np.pi * radius**2 * (1 + (c/a)**2 / e * np.arctanh(e))
@pytest.mark.parametrize("name", [
"2-1-ellipse", "spheroid", "box2d", "box3d"
])
def test_mass_surface_area(actx_factory, name):
actx = actx_factory()
# {{{ cases
if name == "2-1-ellipse":
from mesh_data import EllipseMeshBuilder
builder = EllipseMeshBuilder(radius=3.1, aspect_ratio=2.0)
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