def subdomains(self, n=None):
d = self.gz / 2
blocks = [
SubdomainSpec3D((0, 0, 0), (self.gx, self.gy, d)),
SubdomainSpec3D((0, 0, d), (self.gx, self.gy, d))
]
return blocks
def subdomains(self, n=None):
w = self.gx / 2
blocks = [
SubdomainSpec3D((0, 0, 0), (w, self.gy, self.gz)),
SubdomainSpec3D((w, 0, 0), (w, self.gy, self.gz))
]
return blocks
def subdomains(self):
if not self.config.geometry_for_decomposition:
return super(WeightedSubdomainsGeometry3D, self).subdomains()
geo = util.load_array(self.config.geometry_for_decomposition)
assert self.gz == geo.shape[0]
assert self.gy == geo.shape[1]
assert self.gx == geo.shape[2]
axes = set([0, 1, 2])
conn_axis = 'xyz'.index(self.config.conn_axis)
axes.remove(conn_axis)
profile = np.sum(np.logical_not(geo), axis=tuple(axes))
profile = np.cumsum(profile)
start = [0, 0, 0]
size = [self.gx, self.gy, self.gz]
nodes_per_subdomain = profile[-1] // self.config.subdomains
ret = []
for i, cum_nodes in enumerate(profile):
if cum_nodes - profile[start[conn_axis]] >= nodes_per_subdomain:
size[conn_axis] = i - start[conn_axis] + 1
ret.append(SubdomainSpec3D(start, size))
start[conn_axis] = i + 1
if start[conn_axis] < len(profile) - 1:
size[conn_axis] = len(profile) - start[conn_axis]
ret.append(SubdomainSpec3D(start, size))
return ret
def subdomains(self):
s = self.config.subdomains
if self.config.conn_axis == 'x':
sx = self.gx / s
rx = self.gx % s
return [
SubdomainSpec3D(
(i * sx, 0, 0),
(sx if i < s - 1 else rx + sx, self.gy, self.gz))
for i in range(0, s)
]
elif self.config.conn_axis == 'y':
sy = self.gy / s
ry = self.gy % s
return [
SubdomainSpec3D(
(0, i * sy, 0),
(self.gx, sy if i < s - 1 else ry + sy, self.gz))
for i in range(0, s)
]
else:
sz = self.gz / s
rz = self.gz % s
return [
SubdomainSpec3D(
(0, 0, i * sz),
(self.gx, self.gy, sz if i < s - 1 else rz + sz))
for i in range(0, s)
]
def subdomains(self, n=None):
h = self.gy / 2
blocks = [
SubdomainSpec3D((0, 0, 0), (self.gx, h, self.gz)),
SubdomainSpec3D((0, h, 0), (self.gx, h, self.gz))
]
return blocks
def subdomains(self, n=None):
return [
SubdomainSpec3D((0, 0, 0), (32, 32, 32)),
SubdomainSpec3D((0, 0, 32), (32, 32, 32)),
SubdomainSpec3D((0, 32, 0), (32, 32, 32)),
SubdomainSpec3D((0, 32, 32), (32, 32, 32))
]
def test_subdomain_connection_edge_non_x(self):
base = SubdomainSpec3D((10, 10, 10), (10, 10, 10),
envelope_size=1,
id_=0)
b1 = SubdomainSpec3D((10, 5, 5), (10, 5, 5), envelope_size=1, id_=1)
self.assertTrue(base.connect(b1, grid=D3Q19))
cpair = base.get_connection(SubdomainSpec3D.Y_LOW, b1.id)
self.assertEqual(cpair.src.src_slice, [slice(1, 11), slice(0, 1)])
self.assertEqual(cpair.src.src_macro_slice,
[slice(1, 11), slice(1, 2)])
self.assertEqual(cpair.src.dst_macro_slice,
[slice(1, 11), slice(0, 1)])
self.assertEqual(cpair.src.dst_low, [0, 4])
self.assertEqual(cpair.src.dst_slice, [])
self.assertEqual(cpair.src.dst_full_buf_slice, [])
expected_map = {vi3(0, -1, -1): [(x, 0) for x in range(0, 10)]}
_verify_partial_map(self, cpair.src, expected_map)
b2 = SubdomainSpec3D((10, 20, 5), (10, 5, 5), envelope_size=1, id_=2)
self.assertTrue(base.connect(b2, grid=D3Q19))
cpair = base.get_connection(SubdomainSpec3D.Y_HIGH, b2.id)
self.assertEqual(cpair.src.src_slice, [slice(1, 11), slice(0, 1)])
self.assertEqual(cpair.src.src_macro_slice,
[slice(1, 11), slice(1, 2)])
self.assertEqual(cpair.src.dst_macro_slice,
[slice(1, 11), slice(0, 1)])
self.assertEqual(cpair.src.dst_low, [0, 4])
self.assertEqual(cpair.src.dst_slice, [])
self.assertEqual(cpair.src.dst_full_buf_slice, [])
expected_map = {vi3(0, 1, -1): [(x, 0) for x in range(0, 10)]}
_verify_partial_map(self, cpair.src, expected_map)
b3 = SubdomainSpec3D((10, 5, 20), (10, 5, 5), envelope_size=1, id_=3)
self.assertTrue(base.connect(b3, grid=D3Q19))
cpair = base.get_connection(SubdomainSpec3D.Y_LOW, b3.id)
self.assertEqual(cpair.src.src_slice, [slice(1, 11), slice(11, 12)])
self.assertEqual(cpair.src.src_macro_slice,
[slice(1, 11), slice(10, 11)])
self.assertEqual(cpair.src.dst_macro_slice,
[slice(1, 11), slice(11, 12)])
self.assertEqual(cpair.src.dst_low, [0, 0])
self.assertEqual(cpair.src.dst_slice, [])
self.assertEqual(cpair.src.dst_full_buf_slice, [])
expected_map = {vi3(0, -1, 1): [(x, 0) for x in range(0, 10)]}
_verify_partial_map(self, cpair.src, expected_map)
b4 = SubdomainSpec3D((10, 20, 20), (10, 5, 5), envelope_size=1, id_=4)
self.assertTrue(base.connect(b4, grid=D3Q19))
cpair = base.get_connection(SubdomainSpec3D.Y_HIGH, b4.id)
self.assertEqual(cpair.src.src_slice, [slice(1, 11), slice(11, 12)])
self.assertEqual(cpair.src.src_macro_slice,
[slice(1, 11), slice(10, 11)])
self.assertEqual(cpair.src.dst_macro_slice,
[slice(1, 11), slice(11, 12)])
self.assertEqual(cpair.src.dst_low, [0, 0])
self.assertEqual(cpair.src.dst_slice, [])
self.assertEqual(cpair.src.dst_full_buf_slice, [])
expected_map = {vi3(0, 1, 1): [(x, 0) for x in range(0, 10)]}
_verify_partial_map(self, cpair.src, expected_map)
def test_periodic_yz_2subdomains(self):
self.sim.config.periodic_y = True
self.sim.config.periodic_z = True
spec0 = SubdomainSpec3D((0, 0, 0),
self.lattice_size,
envelope_size=1,
id_=0)
spec1 = SubdomainSpec3D((0, 0, self.lattice_size[2]),
self.lattice_size,
envelope_size=1,
id_=1)
nx, ny, nz = self.lattice_size
spec0, spec1 = LBGeometryProcessor(
[spec0, spec1], 3, (nx, ny, 2 * nz)).transform(self.sim.config)
spec0.runner = SubdomainRunner(self.sim,
spec0,
output=None,
backend=self.backend,
quit_event=None)
spec0.runner._init_shape()
spec1.runner = SubdomainRunner(self.sim,
spec1,
output=None,
backend=self.backend,
quit_event=None)
spec1.runner._init_shape()
class _LinkTaggingSubdomain3D(Subdomain3D):
def boundary_conditions(self, hx, hy, hz):
self.set_node((hx == 0) | (hx == self.gx - 1), NTHalfBBWall)
sub0 = _LinkTaggingSubdomain3D(list(reversed(self.lattice_size)),
spec0, D3Q19)
sub0.allocate()
sub0.reset()
sub1 = _LinkTaggingSubdomain3D(list(reversed(self.lattice_size)),
spec1, D3Q19)
sub1.allocate()
sub1.reset()
hx, hy, hz = sub1._get_mgrid()
hx_tags = reduce(
operator.or_,
((1 << i) for i, vec in enumerate(D3Q19.basis[1:]) if vec[0] >= 0))
np.testing.assert_equal(hx_tags, sub0._orientation[hx == 0])
np.testing.assert_equal(hx_tags, sub1._orientation[hx == 0])
hx_tags = reduce(
operator.or_,
((1 << i) for i, vec in enumerate(D3Q19.basis[1:]) if vec[0] <= 0))
np.testing.assert_equal(hx_tags, sub0._orientation[hx == nx - 1])
np.testing.assert_equal(hx_tags, sub1._orientation[hx == nx - 1])
def test_orientation_channel_2subdomains(self):
self.sim.config.periodic_z = True
self.sim.config.periodic_y = True
spec0 = SubdomainSpec3D((0, 0, 0),
self.lattice_size,
envelope_size=1,
id_=0)
spec0.enable_local_periodicity(1)
spec1 = SubdomainSpec3D((0, 0, self.lattice_size[2]),
self.lattice_size,
envelope_size=1,
id_=1)
spec1.enable_local_periodicity(1)
self.assertTrue(spec0.connect(spec1, grid=D3Q19))
spec0.runner = SubdomainRunner(self.sim,
spec0,
output=None,
backend=self.backend,
quit_event=None)
spec0.runner._init_shape()
spec1.runner = SubdomainRunner(self.sim,
spec1,
output=None,
backend=self.backend,
quit_event=None)
spec1.runner._init_shape()
sub0 = self._ChannelSubdomain3D(list(reversed(self.lattice_size)),
spec0, D3Q19)
sub0.allocate()
sub0.reset()
sub1 = self._ChannelSubdomain3D(list(reversed(self.lattice_size)),
spec1, D3Q19)
sub1.allocate()
sub1.reset()
nx, ny, nz = self.lattice_size
hx, hy, hz = sub0._get_mgrid()
np.testing.assert_equal(sub0._orientation[(hx == 0)],
D3Q19.vec_to_dir([1, 0, 0]))
np.testing.assert_equal(sub0._orientation[(hx == nx - 1)],
D3Q19.vec_to_dir([-1, 0, 0]))
np.testing.assert_equal(sub1._orientation[(hx == 0)],
D3Q19.vec_to_dir([1, 0, 0]))
np.testing.assert_equal(sub1._orientation[(hx == nx - 1)],
D3Q19.vec_to_dir([-1, 0, 0]))
def subdomains(self, n=None):
subdomains = []
bps = int(self.config.ldc_subdomains**(1.0 / 3))
if bps**3 != self.config.ldc_subdomains:
print('Only configurations with '
'a third power of an integer number of subdomains are '
'supported. Falling back to {0} x {0} subdomains.'.format(
bps))
xq = self.gx / bps
xd = self.gx % bps
yq = self.gy / bps
yd = self.gy % bps
zq = self.gz / bps
zd = self.gz % bps
for i in range(0, bps):
xsize = xq
if i == bps - 1:
xsize += xd
for j in range(0, bps):
ysize = yq
if j == bps - 1:
ysize += yd
for k in range(0, bps):
zsize = zq
if k == bps - 1:
zsize += zd
subdomains.append(
SubdomainSpec3D((i * xq, j * yq, k * zq),
(xsize, ysize, zsize)))
return subdomains
def test_periodic_xz(self):
self.sim.config.periodic_x = True
self.sim.config.periodic_z = True
spec = SubdomainSpec3D((0, 0, 0), self.lattice_size, envelope_size=1, id_=0)
spec.enable_local_periodicity(0)
spec.enable_local_periodicity(2)
spec.runner = SubdomainRunner(self.sim, spec, output=None,
backend=self.backend, quit_event=None)
spec.runner._init_shape()
class _LinkTaggingSubdomain3D(Subdomain3D):
def boundary_conditions(self, hx, hy, hz):
self.set_node((hy == 0) | (hy == self.gy - 1), NTHalfBBWall)
sub = _LinkTaggingSubdomain3D(list(reversed(self.lattice_size)), spec, D3Q19)
sub.allocate()
sub.reset()
nx, ny, nz = self.lattice_size
hx, hy, hz = sub._get_mgrid()
hy_tags = reduce(operator.or_, ((1 << i) for i, vec in
enumerate(D3Q19.basis[1:]) if vec[1] >= 0))
np.testing.assert_equal(hy_tags, sub._orientation[hy == 0])
hy_tags = reduce(operator.or_, ((1 << i) for i, vec in
enumerate(D3Q19.basis[1:]) if vec[1] <= 0))
np.testing.assert_equal(hy_tags, sub._orientation[hy == ny - 1])
def test_orientation_channel_pbc(self):
self.sim.config.periodic_z = True
self.sim.config.periodic_y = True
spec = SubdomainSpec3D((0, 0, 0),
self.lattice_size,
envelope_size=1,
id_=0)
spec.enable_local_periodicity(1)
spec.enable_local_periodicity(2)
spec.runner = SubdomainRunner(self.sim,
spec,
output=None,
backend=self.backend,
quit_event=None)
spec.runner._init_shape()
sub = ChannelSubdomain3D(list(reversed(self.lattice_size)), spec,
D3Q19)
sub.allocate()
sub.reset()
nx, ny, nz = self.lattice_size
hx, hy, hz = sub._get_mgrid()
np.testing.assert_equal(sub._orientation[(hx == 0)],
D3Q19.vec_to_dir([1, 0, 0]))
np.testing.assert_equal(sub._orientation[(hx == nx - 1)],
D3Q19.vec_to_dir([-1, 0, 0]))
def test_array_setting(self):
envelope = 1
spec = SubdomainSpec3D((0, 0, 0),
self.lattice_size,
envelope_size=envelope,
id_=0)
spec.runner = SubdomainRunner(self.sim,
spec,
output=None,
backend=self.backend,
quit_event=None)
spec.runner._init_shape()
sub = SubdomainTest3D(list(reversed(self.lattice_size)), spec, D3Q19)
sub.reset()
center_y = 32 / 2
center_z = 16 / 2
for y in range(0, 16):
np.testing.assert_array_almost_equal(
np.float64(
[0.01 * (y - center_y)**2, 0.03 * (y - center_z)**2, 0.0]),
np.float64(
sub._encoder.get_param(
(y + envelope, y + envelope, y + envelope), 3)))
np.testing.assert_equal(sub._type_map[1:6, 1:4, 12:-1], _NTUnused.id)
def testBoundaryNodes(self):
spec = SubdomainSpec3D((0, 0, 0), (5, 8, 3), envelope_size=1, id_=0)
spec.runner = SubdomainRunner(self.sim, spec, output=None,
backend=self.backend, quit_event=None)
spec.runner._init_shape()
class _LinkTaggingSubdomain3D(Subdomain3D):
def boundary_conditions(self, hx, hy, hz):
wall_map = np.array([
[[0, 0, 0, 0, 1],
[0, 0, 0, 0, 1],
[0, 0, 0, 1, 1],
[0, 0, 0, 1, 1], # There was a bug once that caused the
# middle node here to be marked
# PropagationOnly.
[0, 0, 1, 1, 1],
[0, 1, 1, 1, 1],
[1, 1, 1, 1, 1],
[1, 1, 1, 1, 1]],
[[0, 0, 0, 1, 1],
[0, 0, 0, 1, 1],
[0, 0, 1, 1, 1],
[0, 1, 1, 1, 1],
[0, 1, 1, 1, 1],
[1, 1, 1, 1, 1],
[1, 1, 1, 1, 1],
[1, 1, 1, 1, 1]],
[[0, 0, 1, 1, 1],
[0, 1, 1, 1, 1],
[0, 1, 1, 1, 1],
[1, 1, 1, 1, 1],
[1, 1, 1, 1, 1],
[1, 1, 1, 1, 1],
[1, 1, 1, 1, 1],
[1, 1, 1, 1, 1]]], dtype=np.bool)
wall_map = np.pad(wall_map, (1, 1), mode='constant',
constant_values=0)
self.set_node(wall_map, NTFullBBWall)
self.set_node(np.logical_not(wall_map) & (hz == 0),
NTEquilibriumDensity(1.0))
sub = _LinkTaggingSubdomain3D((3, 8, 5), spec, D3Q19)
sub.allocate()
sub.reset(encode=False)
expected = np.array([
[ 3, 3, 3, 3, 5],
[ 3, 3, 3, 3, 5],
[ 3, 3, 3, 5, 5],
[ 3, 3, 3, 5, 19],
[ 3, 3, 5, 5, 19],
[ 3, 5, 5, 19, 19],
[ 5, 5, 19, 19, 20],
[19, 19, 19, 20, 20]])
expected[expected == 3] = NTEquilibriumDensity.id
expected[expected == 5] = NTFullBBWall.id
expected[expected == 19] = _NTPropagationOnly.id
expected[expected == 20] = _NTUnused.id
np.testing.assert_equal(expected, sub._type_map[0,:,:])
def subdomains(self):
"""Returns a 1-element list containing a single 3D block
covering the whole domain."""
return [
SubdomainSpec3D(
(0, 0, 0),
(self.config.lat_nx, self.config.lat_ny, self.config.lat_nz))
]
def test_strides_and_size_3d(self):
block = SubdomainSpec3D(self.location_3d, self.size_3d)
block.set_actual_size(0)
runner = self.get_subdomain_runner(block)
runner._init_shape()
# Last dimension is rounded up to a multiple of block_size
real_size = [7, 5, 8]
self.assertEqual(runner._physical_size, real_size)
nodes = runner.num_phys_nodes
self.assertEqual(nodes, reduce(operator.mul, real_size))
def test_subdomain_connection_z(self):
base = SubdomainSpec3D((10, 10, 10), (10, 12, 10),
envelope_size=1,
id_=0)
face_hi = SubdomainSpec3D.Z_HIGH
# exact match
b1 = SubdomainSpec3D((10, 10, 20), (10, 12, 5), envelope_size=1, id_=1)
self.assertTrue(base.connect(b1, grid=D3Q19))
cpair = base.get_connection(face_hi, b1.id)
self.assertEqual(cpair.src.src_slice, [slice(1, 11), slice(1, 13)])
self.assertEqual(cpair.src.src_macro_slice,
[slice(1, 11), slice(1, 13)])
self.assertEqual(cpair.src.dst_macro_slice,
[slice(1, 11), slice(1, 13)])
self.assertEqual(cpair.src.dst_low, [0, 0])
self.assertEqual(cpair.src.dst_slice, [slice(1, 9), slice(1, 11)])
self.assertEqual(cpair.src.dst_full_buf_slice,
[slice(1, 9), slice(1, 11)])
# Order of axes in the connection buffer is: x, y
# Edges
l = [(x, 0) for x in range(1, 9)]
r = [(x, 11) for x in range(1, 9)]
t = [(9, y) for y in range(1, 11)]
b = [(0, y) for y in range(1, 11)]
# Corners
tl = [(9, 0)]
tr = [(9, 11)]
bl = [(0, 0)]
br = [(0, 11)]
expected_map = {
vi3(0, 0, 1): l + r + t + b + tl + tr + br + bl,
vi3(1, 0, 1): l + r + t + tl + tr,
vi3(-1, 0, 1): l + r + b + bl + br,
vi3(0, 1, 1): r + t + b + tr + br,
vi3(0, -1, 1): l + t + b + tl + bl,
}
_verify_partial_map(self, cpair.src, expected_map)
def subdomains(self):
c = self.config
# Recirculation buffer.
buf = SubdomainSpec3D((0, 0, 0), (c.lat_nx, c.lat_ny, self.buf_nz(c)))
# Enable PBC along the Z axis.
buf.enable_local_periodicity(2)
ret = [buf]
# Actual simulation domain.
n = self.config.subdomains
z = self.buf_nz(c)
dz = self.main_nz(c) / n
rz = self.main_nz(c) % n
for i in range(0, n):
ret.append(
SubdomainSpec3D(
(0, 0, z),
(c.lat_nx, c.lat_ny, dz if i < n - 1 else dz + rz)))
z += dz
return ret
def test_duct(self):
self.sim.config.periodic_z = True
spec = SubdomainSpec3D((0, 0, 0),
self.lattice_size,
envelope_size=1,
id_=0)
spec.enable_local_periodicity(2)
spec.runner = SubdomainRunner(self.sim,
spec,
output=None,
backend=self.backend,
quit_event=None)
spec.runner._init_shape()
class _DuctSubdomain(Subdomain3D):
def boundary_conditions(self, hx, hy, hz):
self.set_node((hy == 0) | (hy == self.gy - 1) | (hx == 0) |
(hx == self.gx - 1), NTHalfBBWall)
sub = _DuctSubdomain(list(reversed(self.lattice_size)), spec, D3Q19)
sub.allocate()
sub.reset()
nx, ny, nz = self.lattice_size
hx, hy, hz = sub._get_mgrid()
# Link tags should be the same in every Z-slice.
for z in range(nz):
np.testing.assert_equal(sub._orientation[hz == z],
sub._orientation[hz == 0])
def _get_tags(cond):
return reduce(
operator.or_,
((1 << i)
for i, vec in enumerate(D3Q19.basis[1:]) if cond(vec)))
expected = np.zeros_like(sub._orientation[0, :, :])
# Edges.
expected[1:-1, 0] = _get_tags(lambda v: v[0] >= 0)
expected[1:-1, -1] = _get_tags(lambda v: v[0] <= 0)
expected[0, 1:-1] = _get_tags(lambda v: v[1] >= 0)
expected[-1, 1:-1] = _get_tags(lambda v: v[1] <= 0)
# Corners.
expected[0, 0] = _get_tags(lambda v: v[0] >= 0 and v[1] >= 0)
expected[0, -1] = _get_tags(lambda v: v[0] <= 0 and v[1] >= 0)
expected[-1, 0] = _get_tags(lambda v: v[0] >= 0 and v[1] <= 0)
expected[-1, -1] = _get_tags(lambda v: v[0] <= 0 and v[1] <= 0)
np.testing.assert_equal(expected, sub._orientation[0, :, :])
def test_subdomain_connection_x(self):
base = SubdomainSpec3D((10, 10, 10), (10, 12, 10),
envelope_size=1,
id_=0)
face_hi = SubdomainSpec3D.X_HIGH
# exact match
b1 = SubdomainSpec3D((20, 10, 10), (5, 12, 10), envelope_size=1, id_=1)
self.assertTrue(base.connect(b1, grid=D3Q19))
cpair = base.get_connection(face_hi, b1.id)
self.assertEqual(
set(cpair.src.dists),
set([
vi3(1, 0, 0),
vi3(1, 1, 0),
vi3(1, -1, 0),
vi3(1, 0, 1),
vi3(1, 0, -1)
]))
self.assertEqual(cpair.src.src_slice, [slice(1, 13), slice(1, 11)])
self.assertEqual(cpair.src.src_macro_slice,
[slice(1, 13), slice(1, 11)])
self.assertEqual(cpair.src.dst_macro_slice,
[slice(1, 13), slice(1, 11)])
self.assertEqual(cpair.src.dst_low, [0, 0])
self.assertEqual(cpair.src.dst_slice, [slice(1, 11), slice(1, 9)])
self.assertEqual(cpair.src.dst_full_buf_slice,
[slice(1, 11), slice(1, 9)])
# Order of axes in the connection buffer is y, z
# Edges
l = [(y, 0) for y in range(1, 11)]
r = [(y, 9) for y in range(1, 11)]
t = [(11, z) for z in range(1, 9)]
b = [(0, z) for z in range(1, 9)]
# Corners
tl = [(11, 0)]
tr = [(11, 9)]
bl = [(0, 0)]
br = [(0, 9)]
expected_map = {
vi3(1, 0, 0): l + r + t + b + tl + tr + br + bl,
vi3(1, 1, 0): l + r + t + tl + tr,
vi3(1, -1, 0): l + r + b + bl + br,
vi3(1, 0, 1): r + t + b + tr + br,
vi3(1, 0, -1): l + t + b + tl + bl,
}
_verify_partial_map(self, cpair.src, expected_map)
base = SubdomainSpec3D((10, 10, 10), (10, 10, 10),
envelope_size=1,
id_=0)
# full overlap (2nd subdomain is smaller)
b2 = SubdomainSpec3D((20, 12, 14), (5, 6, 4), envelope_size=1, id_=2)
self.assertTrue(base.connect(b2, grid=D3Q19))
cpair = base.get_connection(face_hi, b2.id)
self.assertEqual(cpair.src.src_slice, [slice(3, 9), slice(5, 9)])
self.assertEqual(cpair.src.src_macro_slice,
[slice(2, 10), slice(4, 10)])
self.assertEqual(cpair.src.dst_macro_slice, [slice(3, 9), slice(5, 9)])
self.assertEqual(cpair.src.dst_low, [0, 0])
self.assertEqual(cpair.src.dst_slice, [slice(0, 6), slice(0, 4)])
self.assertEqual(cpair.src.dst_full_buf_slice,
[slice(0, 6), slice(0, 4)])
# full overlap (2nd subdomain is larger)
b3 = SubdomainSpec3D((20, 8, 9), (5, 14, 15), envelope_size=1, id_=3)
self.assertTrue(base.connect(b3, grid=D3Q19))
cpair = base.get_connection(face_hi, b3.id)
self.assertEqual(cpair.src.src_slice, [slice(0, 12), slice(0, 12)])
self.assertEqual(cpair.src.src_macro_slice,
[slice(1, 11), slice(1, 11)])
self.assertEqual(cpair.src.dst_macro_slice,
[slice(0, 12), slice(0, 12)])
self.assertEqual(cpair.src.dst_low, [1, 0])
self.assertEqual(cpair.src.dst_slice, [slice(3, 11), slice(2, 10)])
self.assertEqual(cpair.src.dst_full_buf_slice,
[slice(2, 10), slice(2, 10)])
# Edges
l = [(y, 1) for y in range(2, 10)]
r = [(y, 10) for y in range(2, 10)]
t = [(10, z) for z in range(2, 10)]
b = [(1, z) for z in range(2, 10)]
le = [(y, 0) for y in range(1, 11)]
re = [(y, 11) for y in range(1, 11)]
te = [(11, z) for z in range(1, 11)]
be = [(0, z) for z in range(1, 11)]
# Corners
tl = [(10, 1)]
tr = [(10, 10)]
bl = [(1, 1)]
br = [(1, 10)]
expected_map = {
vi3(1, 0, 0): l + r + t + b + tl + tr + br + bl,
vi3(1, 1, 0): l + r + t + tl + tr + te,
vi3(1, -1, 0): l + r + b + bl + br + be,
vi3(1, 0, 1): r + t + b + tr + br + re,
vi3(1, 0, -1): l + t + b + tl + bl + le,
}
_verify_partial_map(self, cpair.src, expected_map)
# top-left corner match (no connection in D3Q19 topology)
bf1 = SubdomainSpec3D((20, 20, 5), (5, 5, 5), envelope_size=1)
self.assertFalse(base.connect(bf1, grid=D3Q19))
# too far along X axis
bf2 = SubdomainSpec3D((21, 10, 10), (5, 10, 10), envelope_size=1)
self.assertFalse(base.connect(bf2, grid=D3Q19))
# too far along Y axis
bf3 = SubdomainSpec3D((20, 21, 10), (5, 10, 10), envelope_size=1)
self.assertFalse(base.connect(bf3, grid=D3Q19))
def test_orientation_box(self):
spec = SubdomainSpec3D((0, 0, 0), self.lattice_size, envelope_size=1, id_=0)
spec.runner = SubdomainRunner(self.sim, spec, output=None,
backend=self.backend, quit_event=None)
spec.runner._init_shape()
class _OrientationSubdomain3D(Subdomain3D):
def boundary_conditions(self, hx, hy, hz):
self.set_node((hx == 0) | (hy == 0) | (hz == 0) | (hz == self.gz - 1) |
(hx == self.gx - 1) | (hy == self.gy - 1),
NTEquilibriumDensity(1.0))
sub = _OrientationSubdomain3D(list(reversed(self.lattice_size)), spec, D3Q19)
sub.allocate()
sub.reset()
nx, ny, nz = self.lattice_size
hx, hy, hz = sub._get_mgrid()
xx = np.logical_not((hx == 0) | (hx == nx - 1))
yy = np.logical_not((hy == 0) | (hy == ny - 1))
zz = np.logical_not((hz == 0) | (hz == nz - 1))
np.testing.assert_equal(sub._orientation[(hx == 0) & yy & zz],
D3Q19.vec_to_dir([1, 0, 0]))
np.testing.assert_equal(sub._orientation[(hy == 0) & xx & zz],
D3Q19.vec_to_dir([0, 1, 0]))
np.testing.assert_equal(sub._orientation[(hz == 0) & yy & xx],
D3Q19.vec_to_dir([0, 0, 1]))
np.testing.assert_equal(sub._orientation[(hx == nx - 1) & yy & zz],
D3Q19.vec_to_dir([-1, 0, 0]))
np.testing.assert_equal(sub._orientation[(hy == ny - 1) & xx & zz],
D3Q19.vec_to_dir([0, -1, 0]))
np.testing.assert_equal(sub._orientation[(hz == nz - 1) & yy & xx],
D3Q19.vec_to_dir([0, 0, -1]))
# No orientation vector for edge nodes.
np.testing.assert_equal(sub._orientation[(hx == 0) & (hy == 0)], 0)
np.testing.assert_equal(sub._orientation[(hx == 0) & (hz == 0)], 0)
np.testing.assert_equal(sub._orientation[(hz == 0) & (hy == 0)], 0)
np.testing.assert_equal(sub._orientation[(hx == 0) & (hy == ny - 1)], 0)
np.testing.assert_equal(sub._orientation[(hx == 0) & (hz == nz - 1)], 0)
np.testing.assert_equal(sub._orientation[(hz == 0) & (hy == ny - 1)], 0)
np.testing.assert_equal(sub._orientation[(hx == nx - 1) & (hy == 0)], 0)
np.testing.assert_equal(sub._orientation[(hx == nx - 1) & (hz == 0)], 0)
np.testing.assert_equal(sub._orientation[(hz == nz - 1) & (hy == 0)], 0)
np.testing.assert_equal(sub._orientation[(hx == nx - 1) & (hy == ny - 1)], 0)
np.testing.assert_equal(sub._orientation[(hx == nx - 1) & (hz == nz - 1)], 0)
np.testing.assert_equal(sub._orientation[(hz == nz - 1) & (hy == ny - 1)], 0)
# No orientation vector for corner nodes.
np.testing.assert_equal(sub._orientation[0, 0, 0], 0)
np.testing.assert_equal(sub._orientation[0, 0, nx - 1], 0)
np.testing.assert_equal(sub._orientation[0, ny - 1, 0], 0)
np.testing.assert_equal(sub._orientation[0, ny - 1, nx - 1], 0)
np.testing.assert_equal(sub._orientation[nz - 1, 0, 0], 0)
np.testing.assert_equal(sub._orientation[nz - 1, 0, nx - 1], 0)
np.testing.assert_equal(sub._orientation[nz - 1, ny - 1, 0], 0)
np.testing.assert_equal(sub._orientation[nz - 1, ny - 1, nx - 1], 0)
def test_orientation(self):
spec = SubdomainSpec3D((0, 0, 0),
self.lattice_size,
envelope_size=1,
id_=0)
spec.runner = SubdomainRunner(self.sim,
spec,
output=None,
backend=self.backend,
quit_event=None)
spec.runner._init_shape()
sub = TestSubdomain3D(list(reversed(self.lattice_size)), spec, D3Q19)
sub.reset()
sub._encoder.detect_orientation(sub._orientation_base)
nx, ny, nz = self.lattice_size
hx, hy, hz = sub._get_mgrid()
xx = np.logical_not((hx == 0) | (hx == nx - 1))
yy = np.logical_not((hy == 0) | (hy == ny - 1))
zz = np.logical_not((hz == 0) | (hz == nz - 1))
np.testing.assert_equal(sub._orientation[(hx == 0) & yy & zz],
D3Q19.vec_to_dir([1, 0, 0]))
np.testing.assert_equal(sub._orientation[(hy == 0) & xx & zz],
D3Q19.vec_to_dir([0, 1, 0]))
np.testing.assert_equal(sub._orientation[(hz == 0) & yy & xx],
D3Q19.vec_to_dir([0, 0, 1]))
np.testing.assert_equal(sub._orientation[(hx == nx - 1) & yy & zz],
D3Q19.vec_to_dir([-1, 0, 0]))
np.testing.assert_equal(sub._orientation[(hy == ny - 1) & xx & zz],
D3Q19.vec_to_dir([0, -1, 0]))
np.testing.assert_equal(sub._orientation[(hz == nz - 1) & yy & xx],
D3Q19.vec_to_dir([0, 0, -1]))
# No orientation vector for edge nodes.
np.testing.assert_equal(sub._orientation[(hx == 0) & (hy == 0)], 0)
np.testing.assert_equal(sub._orientation[(hx == 0) & (hz == 0)], 0)
np.testing.assert_equal(sub._orientation[(hz == 0) & (hy == 0)], 0)
np.testing.assert_equal(sub._orientation[(hx == 0) & (hy == ny - 1)],
0)
np.testing.assert_equal(sub._orientation[(hx == 0) & (hz == nz - 1)],
0)
np.testing.assert_equal(sub._orientation[(hz == 0) & (hy == ny - 1)],
0)
np.testing.assert_equal(sub._orientation[(hx == nx - 1) & (hy == 0)],
0)
np.testing.assert_equal(sub._orientation[(hx == nx - 1) & (hz == 0)],
0)
np.testing.assert_equal(sub._orientation[(hz == nz - 1) & (hy == 0)],
0)
np.testing.assert_equal(
sub._orientation[(hx == nx - 1) & (hy == ny - 1)], 0)
np.testing.assert_equal(
sub._orientation[(hx == nx - 1) & (hz == nz - 1)], 0)
np.testing.assert_equal(
sub._orientation[(hz == nz - 1) & (hy == ny - 1)], 0)
# No orientation vector for corner nodes.
np.testing.assert_equal(sub._orientation[0, 0, 0], 0)
np.testing.assert_equal(sub._orientation[0, 0, nx - 1], 0)
np.testing.assert_equal(sub._orientation[0, ny - 1, 0], 0)
np.testing.assert_equal(sub._orientation[0, ny - 1, nx - 1], 0)
np.testing.assert_equal(sub._orientation[nz - 1, 0, 0], 0)
np.testing.assert_equal(sub._orientation[nz - 1, 0, nx - 1], 0)
np.testing.assert_equal(sub._orientation[nz - 1, ny - 1, 0], 0)
np.testing.assert_equal(sub._orientation[nz - 1, ny - 1, nx - 1], 0)
def subdomains(self, n=None):
return [
SubdomainSpec3D((0, 0, 0), (50, 30, 13)),
SubdomainSpec3D((5, 30, 0), (50, 10, 13))
]
def _corner_helper(self, face):
base = SubdomainSpec3D((10, 10, 10), (10, 10, 10),
envelope_size=1,
id_=0)
if face == SubdomainSpec3D.X_LOW:
x_low = 5
x_dir = -1
else:
x_low = 20
x_dir = 1
b1 = SubdomainSpec3D((x_low, 5, 5), (5, 5, 5), envelope_size=1, id_=1)
self.assertTrue(base.connect(b1, grid=D3Q15))
cpair = base.get_connection(face, b1.id)
self.assertEqual(cpair.src.src_slice, [slice(0, 1), slice(0, 1)])
self.assertEqual(cpair.src.src_macro_slice, [slice(1, 2), slice(1, 2)])
self.assertEqual(cpair.src.dst_macro_slice, [slice(0, 1), slice(0, 1)])
self.assertEqual(cpair.src.dst_low, [4, 4])
self.assertEqual(cpair.src.dst_slice, [])
self.assertEqual(cpair.src.dst_full_buf_slice, [])
expected_map = {vi15(x_dir, -1, -1): [(0, 0)]}
_verify_partial_map(self, cpair.src, expected_map)
b2 = SubdomainSpec3D((x_low, 20, 5), (5, 5, 5), envelope_size=1, id_=2)
self.assertTrue(base.connect(b2, grid=D3Q15))
cpair = base.get_connection(face, b2.id)
self.assertEqual(cpair.src.src_slice, [slice(11, 12), slice(0, 1)])
self.assertEqual(cpair.src.src_macro_slice,
[slice(10, 11), slice(1, 2)])
self.assertEqual(cpair.src.dst_macro_slice,
[slice(11, 12), slice(0, 1)])
self.assertEqual(cpair.src.dst_low, [0, 4])
self.assertEqual(cpair.src.dst_slice, [])
self.assertEqual(cpair.src.dst_full_buf_slice, [])
expected_map = {vi15(x_dir, 1, -1): [(0, 0)]}
_verify_partial_map(self, cpair.src, expected_map)
b3 = SubdomainSpec3D((x_low, 20, 20), (5, 5, 5),
envelope_size=1,
id_=3)
self.assertTrue(base.connect(b3, grid=D3Q15))
cpair = base.get_connection(face, b3.id)
self.assertEqual(cpair.src.src_slice, [slice(11, 12), slice(11, 12)])
self.assertEqual(cpair.src.src_macro_slice,
[slice(10, 11), slice(10, 11)])
self.assertEqual(cpair.src.dst_macro_slice,
[slice(11, 12), slice(11, 12)])
self.assertEqual(cpair.src.dst_low, [0, 0])
self.assertEqual(cpair.src.dst_slice, [])
self.assertEqual(cpair.src.dst_full_buf_slice, [])
expected_map = {vi15(x_dir, 1, 1): [(0, 0)]}
_verify_partial_map(self, cpair.src, expected_map)
b4 = SubdomainSpec3D((x_low, 5, 20), (5, 5, 5), envelope_size=1, id_=4)
self.assertTrue(base.connect(b4, grid=D3Q15))
cpair = base.get_connection(face, b4.id)
self.assertEqual(cpair.src.src_slice, [slice(0, 1), slice(11, 12)])
self.assertEqual(cpair.src.src_macro_slice,
[slice(1, 2), slice(10, 11)])
self.assertEqual(cpair.src.dst_macro_slice,
[slice(0, 1), slice(11, 12)])
self.assertEqual(cpair.src.dst_low, [4, 0])
self.assertEqual(cpair.src.dst_slice, [])
self.assertEqual(cpair.src.dst_full_buf_slice, [])
expected_map = {vi15(x_dir, -1, 1): [(0, 0)]}
_verify_partial_map(self, cpair.src, expected_map)
def subdomains(self, n=None):
return [
SubdomainSpec3D((0, 0, 0), (20, 15, 30)),
SubdomainSpec3D((20, 2, 7), (10, 15, 30))
]
def _x_edge_helper(self, face):
"""Tests connections along the edges of one of the faces orthogonal
to the X axis."""
base = SubdomainSpec3D((10, 10, 10), (10, 10, 10),
envelope_size=1,
id_=0)
if face == SubdomainSpec3D.X_LOW:
x_low = 5
x_dir = -1
else:
x_low = 20
x_dir = 1
# bottom edge match
b1 = SubdomainSpec3D((x_low, 5, 10), (5, 5, 10),
envelope_size=1,
id_=1)
self.assertTrue(base.connect(b1, grid=D3Q19))
cpair = base.get_connection(face, b1.id)
self.assertEqual(cpair.src.src_slice, [slice(0, 1), slice(1, 11)])
self.assertEqual(cpair.src.src_macro_slice,
[slice(1, 2), slice(1, 11)])
self.assertEqual(cpair.src.dst_macro_slice,
[slice(0, 1), slice(1, 11)])
self.assertEqual(cpair.src.dst_low, [4, 0])
self.assertEqual(cpair.src.dst_slice, [])
self.assertEqual(cpair.src.dst_full_buf_slice, [])
expected_map = {vi3(x_dir, -1, 0): [(0, z) for z in range(0, 10)]}
_verify_partial_map(self, cpair.src, expected_map)
# top edge match
b2 = SubdomainSpec3D((x_low, 20, 10), (5, 5, 10),
envelope_size=1,
id_=2)
self.assertTrue(base.connect(b2, grid=D3Q19))
cpair = base.get_connection(face, b2.id)
self.assertEqual(cpair.src.src_slice, [slice(11, 12), slice(1, 11)])
self.assertEqual(cpair.src.src_macro_slice,
[slice(10, 11), slice(1, 11)])
self.assertEqual(cpair.src.dst_macro_slice,
[slice(11, 12), slice(1, 11)])
self.assertEqual(cpair.src.dst_low, [0, 0])
self.assertEqual(cpair.src.dst_slice, [])
self.assertEqual(cpair.src.dst_full_buf_slice, [])
expected_map = {vi3(x_dir, 1, 0): [(0, z) for z in range(0, 10)]}
_verify_partial_map(self, cpair.src, expected_map)
# right edge match
b3 = SubdomainSpec3D((x_low, 10, 20), (5, 10, 5),
envelope_size=1,
id_=3)
self.assertTrue(base.connect(b3, grid=D3Q19))
cpair = base.get_connection(face, b3.id)
self.assertEqual(cpair.src.src_slice, [slice(1, 11), slice(11, 12)])
self.assertEqual(cpair.src.src_macro_slice,
[slice(1, 11), slice(10, 11)])
self.assertEqual(cpair.src.dst_macro_slice,
[slice(1, 11), slice(11, 12)])
self.assertEqual(cpair.src.dst_low, [0, 0])
self.assertEqual(cpair.src.dst_slice, [])
self.assertEqual(cpair.src.dst_full_buf_slice, [])
expected_map = {vi3(x_dir, 0, 1): [(y, 0) for y in range(0, 10)]}
_verify_partial_map(self, cpair.src, expected_map)
# left edge match
b4 = SubdomainSpec3D((x_low, 10, 5), (5, 10, 5),
envelope_size=1,
id_=4)
self.assertTrue(base.connect(b4, grid=D3Q19))
cpair = base.get_connection(face, b4.id)
self.assertEqual(cpair.src.src_slice, [slice(1, 11), slice(0, 1)])
self.assertEqual(cpair.src.src_macro_slice,
[slice(1, 11), slice(1, 2)])
self.assertEqual(cpair.src.dst_macro_slice,
[slice(1, 11), slice(0, 1)])
self.assertEqual(cpair.src.dst_low, [0, 4])
self.assertEqual(cpair.src.dst_slice, [])
self.assertEqual(cpair.src.dst_full_buf_slice, [])
expected_map = {vi3(x_dir, 0, -1): [(y, 0) for y in range(0, 10)]}
_verify_partial_map(self, cpair.src, expected_map)
def subdomains(self, n=None):
blocks = []
blocks.append(SubdomainSpec3D((0, 0, 0), (64, 66, 64)))
blocks.append(SubdomainSpec3D((0, 0, 64), (64, 66, 64)))
return blocks
def subdomains(self, n=None):
return [SubdomainSpec3D((0, 0, 0), (64, 62, 66))]
