# --------------------------------------------------------------------------- # pyCGNS - Python package for CFD General Notation System - # See license.txt file in the root directory of this Python module source # --------------------------------------------------------------------------- # from __future__ import unicode_literals import CGNS.PAT.cgnslib as C import CGNS.PAT.cgnserrors as E import CGNS.PAT.cgnskeywords as K import numpy as N # data = C.newDimensionalUnits(None) status = '4.3' comment = 'Full SIDS with all optionals' pattern = [data, status, comment] #
# ---------------------------------------------------------------------------
# pyCGNS - Python package for CFD General Notation System -
# See license.txt file in the root directory of this Python module source
# ---------------------------------------------------------------------------
#
from __future__ import unicode_literals
import CGNS.PAT.cgnslib as C
import CGNS.PAT.cgnskeywords as K
import CGNS.PAT.cgnserrors as E
import numpy as N
#
#
data = C.newArbitraryGridMotion(None, '{ArbitraryGridMotion}')
C.newRind(data, N.array([0, 0, 0, 0, 1, 1]))
C.newGridLocation(data)
C.newDataArray(data, K.GridVelocityX_s)
C.newDataArray(data, K.GridVelocityY_s)
C.newDataArray(data, K.GridVelocityZ_s)
C.newDataClass(data)
C.newDimensionalUnits(data)
C.newUserDefinedData(data, '{UserDefinedData}')
C.newDescriptor(data, '{Descriptor}')
#
status = '11.3'
comment = 'Full SIDS with all optionals'
pattern = [data, status, comment]
#
m = CGL.newEMConductivityModel(f)
d = CGL.newDataClass(m, CGK.NondimensionalParameter_s)
m = CGL.newEMMagneticFieldModel(f)
d = CGL.newDataClass(m, CGK.NondimensionalParameter_s)
m = CGL.newEMElectricFieldModel(f)
d = CGL.newDataClass(m, CGK.NondimensionalParameter_s)
TESTS.append((tag, T, diag))
# -------------------------------------------------------------------------
tag = 'all levels dataclass/dimensionalunits'
diag = True
T = CGL.newCGNSTree()
b = CGL.newBase(T, '{Base}', 3, 3)
d = CGL.newFamily(b, '{Family}')
d = CGL.newDataClass(b, CGK.NormalizedByDimensional_s)
u = CGL.newDimensionalUnits(b)
z = CGL.newZone(b, '{Zone}',
NPY.array([[5, 4, 0], [7, 6, 0], [9, 8, 0]], order='F'))
d = CGL.newDataClass(z, CGK.NormalizedByDimensional_s)
u = CGL.newDimensionalUnits(z)
g = CGL.newGridCoordinates(z, CGK.GridCoordinates_s)
w = CGL.newDataArray(g, CGK.CoordinateX_s,
NPY.ones((5, 7, 9), dtype='float64', order='F'))
w = CGL.newDataArray(g, CGK.CoordinateY_s,
NPY.ones((5, 7, 9), dtype='float64', order='F'))
w = CGL.newDataArray(g, CGK.CoordinateZ_s,
NPY.ones((5, 7, 9), dtype='float64', order='F'))
d = CGL.newDataClass(g, CGK.NormalizedByDimensional_s)
u = CGL.newDimensionalUnits(g)
f = CGL.newFlowSolution(z)
d = CGL.newDataClass(f, CGK.NormalizedByDimensional_s)
