d = CGL.newDataClass(a, CGK.NondimensionalParameter_s)
a = CGL.newDiscreteData(z, '{DiscreteData}')
d = CGL.newDataClass(a, CGK.NondimensionalParameter_s)
i = CGL.newBaseIterativeData(b, '{BaseIterativeData}')
d = CGL.newDataClass(i, CGK.NondimensionalParameter_s)
i = CGL.newZoneIterativeData(z, '{ZoneIterativeData}')
d = CGL.newDataClass(i, CGK.NondimensionalParameter_s)
m = CGL.newRigidGridMotion(z,
'{RigidGridMotion}',
vector=NPY.array([[0.0, 0.0], [0.0, 0.0],
[0.0, 0.0]]))
d = CGL.newDataClass(m, CGK.NondimensionalParameter_s)
m = CGL.newArbitraryGridMotion(z, '{ArbitraryGridMotion}')
d = CGL.newDataClass(m, CGK.NondimensionalParameter_s)
x = CGL.newZoneGridConnectivity(z)
x = CGL.newGridConnectivity(x, '{GridConnectivity}', z[0])
CGL.newPointRange(x,
value=NPY.array([[1, 1], [1, 1], [1, 1]],
dtype=NPY.int32,
order='Fortran'))
p = CGL.newGridConnectivityProperty(x)
m = CGL.newPeriodic(p)
d = CGL.newDataClass(m, CGK.NondimensionalParameter_s)
w = CGL.newConvergenceHistory(b)
d = CGL.newDataClass(w, CGK.NondimensionalParameter_s)
i = CGL.newIntegralData(b, '{IntegralData}')
d = CGL.newDataClass(i, CGK.NondimensionalParameter_s)
i = CGL.newUserDefinedData(b, '{UserDefinedData}')
d = CGL.newDataClass(i, CGK.NondimensionalParameter_s)
i = CGL.newGravity(b)
d = CGL.newDataClass(i, CGK.NondimensionalParameter_s)
NPY.ones((cellsize * 4), dtype='int32'),
NPY.array([[1, cellsize]], 'i', order='F'))
tris = CGL.newElements(
z2, 'TRIS', CGK.TRI_3_s, NPY.ones((ntris * 3), dtype='int32'),
NPY.array([[cellsize + 1, cellsize + ntris]], 'i', order='F'))
z3 = CGU.copyNode(z1, 'Zone3')
b[2].append(z3)
z4 = CGU.copyNode(z2, 'Zone4')
b[2].append(z4)
z = [z1, z2, z3, z4]
return (T, b, z)
(T, b, z) = makeCorrectTree()
zgc = CGL.newZoneGridConnectivity(z[0])
gc = CGL.newGridConnectivity(zgc, 'join1_3', 'Zone3', ctype=CGK.Abutting1to1_s)
CGL.newPointRange(gc, value=NPY.array([[1, 1], [1, 7], [1, 9]], order='F'))
CGL.newPointRange(gc,
name=CGK.PointRangeDonor_s,
value=NPY.array([[1, 1], [1, 7], [1, 9]], order='F'))
gc = CGL.newGridConnectivity(zgc, 'join1_2', 'Zone2', ctype=CGK.Abutting1to1_s)
CGL.newPointRange(gc, value=NPY.array([[1, 5], [1, 1], [1, 9]], order='F'))
CGL.newIndexArray(gc,
CGK.PointListDonor_s,
value=NPY.array([range(cellsize + 1, cellsize + ntris + 1)],
order='F'))
CGL.newGridLocation(gc, value=CGK.FaceCenter_s)
TESTS.append((tag, T, diag))
# -------------------------------------------------------------------------
tag = 'gridconnectivity bad datatype'
NPY.array([[1, cellsize]], 'i', order='F'))
tris = CGL.newElements(
z, 'TRIS', CGK.TRI_3_s, NPY.ones((ntris * 3), dtype='int32'),
NPY.array([[cellsize + 1, cellsize + ntris]], 'i', order='F'))
tris[1][1] = ntris
zbc = CGL.newZoneBC(z)
n = CGL.newBoundary(zbc,
'BC', [range(cellsize + 1, cellsize + ntris + 1)],
btype=CGK.Null_s,
family=None,
pttype=CGK.PointList_s)
g = CGL.newGridLocation(n, value=CGK.FaceCenter_s)
z2 = CGU.copyNode(z, 'Zone2')
b[2].append(z2)
zgc = CGL.newZoneGridConnectivity(z)
gc = CGL.newGridConnectivity(zgc, 'join1_2', 'Zone2', ctype=CGK.Abutting1to1_s)
CGL.newIndexArray(gc,
CGK.PointList_s,
value=NPY.array([range(cellsize + 2, cellsize + ntris)],
order='F'))
CGL.newIndexArray(gc,
CGK.PointListDonor_s,
value=NPY.array([range(cellsize + 2, cellsize + ntris)],
order='F'))
CGL.newGridLocation(gc, value=CGK.FaceCenter_s)
zgc = CGL.newZoneGridConnectivity(z2)
gc = CGL.newGridConnectivity(zgc, 'join2_1', 'Zone', ctype=CGK.Abutting1to1_s)
CGL.newIndexArray(gc,
CGK.PointList_s,
value=NPY.array([range(cellsize + 2, cellsize + ntris)],
order='F'))