simulation/ghostcells.py# ----------------------------------------------------------------------------
# CLASSES: nightly
#
# Test Case: ghostcells.py
#
# Tests: libsim - connecting to simulation and retrieving data from it.
# mesh - 2D structured mesh.
# scalars defined on material sub regions.
#
# Programmer: Brad Whitlock
# Date: Wed Dec 18 12:04:01 PST 2013
#
#
# NOTES: #3, #17 do not look correct.
#
# Modifications:
#
# ----------------------------------------------------------------------------
# Create our simulation object.
sim = TestSimulation("ghostcells", "ghostcells.sim2")
# Test that we can start and connect to the simulation.
started, connected = TestSimStartAndConnect("ghostcells00", sim)
# Perform our tests.
if connected:
# Make sure the metadata is right.
TestSimMetaData("ghostcells01", sim.metadata())
meshes = ("rect_blank", "curv_blank", "ucd_blank",
"multi_domain_index", "multi_domain", "multi_types")
scalars= ("rect_var", "curv_var", "ucd_var",
"multi_var", "multi_var_index", "multi_types_var")
i = 2
TestSection("Ghosting with meshes")
for m in meshes:
AddPlot("Subset", m)
s = SubsetAttributes(1)
if "multi" in m:
s.opacity = 0.4
SetPlotOptions(s)
DrawPlots()
ResetView()
Test("ghostcells%02d" % i)
s.colorType = s.ColorBySingleColor
s.singleColor = (0,0,255,255)
SetPlotOptions(s)
AddOperator("InverseGhostZone")
s.opacity = 1.
SetPlotOptions(s)
DrawPlots()
Test("ghostcells%02d" % (i+1))
DeleteAllPlots()
i = i + 2
TestSection("Ghosting with scalars")
for s in scalars:
AddPlot("Pseudocolor", s)
pc = PseudocolorAttributes(1)
if "multi" in s:
pc.opacityType = pc.Constant
pc.opacity = 0.4
SetPlotOptions(pc)
DrawPlots()
ResetView()
Test("ghostcells%02d" % i)
AddOperator("InverseGhostZone")
pc.opacity = 1.0
SetPlotOptions(pc)
DrawPlots()
Test("ghostcells%02d" % (i+1))
DeleteAllPlots()
i = i + 2
# Close down the simulation.
if started:
sim.endsim()
Exit()