def setUp(self):
"""Initial setting up of test fixture, automatically called by
TestCase before any other test method is invoked"""
e = NullEngine()
# Uncomment to see visualization for debugging etc.
# e = Engine()
e.start()
s = e.new_scene()
poly_data = BuiltinSurface()
e.add_source(poly_data)
outline = Outline()
e.add_module(outline)
surface = Surface()
e.add_module(surface)
poly_data.data_source.shaft_radius = 0.05
poly_data.data_source.shaft_resolution = 7
poly_data.data_source.tip_radius = 0.1
self.e = e
self.scene = e.current_scene
return
def get_null_engine(self):
"""Return a suitable null engine and make that the current
engine.
"""
# First check if the current engine is running and if it is in
# the registered engines.
ce = self.current_engine
if ce is not None:
if not ce.running or ce not in registry.engines.values():
self.current_engine = None
if self.current_engine is not None:
engines = list((self.current_engine,))
else:
engines = list()
engines.extend(registry.engines.values())
engine = None
for e in engines:
if e.__class__.__name__ == 'NullEngine':
engine = e
break
else:
engine = NullEngine(name='Null Mlab Engine')
engine.start()
self.current_engine = engine
return engine
def setUp(self):
e = NullEngine()
# Uncomment to see visualization for debugging etc.
# e = Engine()
e.start()
s = e.new_scene()
image_data = BuiltinImage()
e.add_source(image_data)
outline = Outline()
e.add_module(outline)
surface = Surface()
e.add_module(surface)
image_data.data_source.radius = array([80.0, 80.0, 80.0])
image_data.data_source.center = array([150.0, 150.0, 0.0])
image_data.data_source.whole_extent = array([10, 245, 10, 245, 0, 0])
if is_old_pipeline():
image_data.data_source.update_whole_extent()
else:
image_data.data_source.set_update_extent_to_whole_extent()
self.e = e
self.scene = e.current_scene
return
def setUp(self):
e = NullEngine()
e.start()
registry.register_engine(e)
engine_manager.current_engine = e
self.e = e
self.s = e.new_scene()
self.s.scene = DummyScene()
def setUp(self):
# Create dataset with multiple scalars.
arr1 = zeros(27, 'f')
for n in range(27):
arr1[n] = (1+float(n))/10.0
arr2 = (arr1 + 1).astype('d')
arr3 = arr1 + 2.0*(0.5 - random.random(27))
arr3 = arr3.astype('f')
p = tvtk.ImageData(dimensions=[3,3,3],spacing=[1,1,1],
scalar_type='int')
p.point_data.scalars = arr1
p.point_data.scalars.name = 'first'
j2 = p.point_data.add_array(arr2)
p.point_data.get_array(j2).name='second'
j3 = p.point_data.add_array(arr3)
p.point_data.get_array(j3).name='third'
p.update()
self.img = p
self.first = arr1
self.second = arr2
self.third = arr3
# Setup the mayavi pipeline.
e = NullEngine()
e.start()
e.new_scene()
self.e = e
src = VTKDataSource(data=p)
e.add_source(src)
self.src = src
ipw = ImagePlaneWidget()
e.add_module(ipw)
self.ipw = ipw
def new_engine(self):
""" Creates a new engine, envisage or not depending on the
options.
"""
check_backend()
if options.backend == "envisage":
from mayavi.plugins.app import Mayavi
m = Mayavi(start_gui_event_loop=False)
m.main()
process_ui_events()
window = m.application.workbench.active_window
engine = window.get_service(Engine)
elif options.backend == "test":
engine = NullEngine(name="Null Mlab Engine")
engine.start()
else:
if options.offscreen:
engine = OffScreenEngine(name="Mlab offscreen Engine")
engine.start()
else:
engine = Engine(name="Mlab Engine")
engine.start()
self.current_engine = engine
return engine
def setUp(self):
"""Initial setting up of test fixture, automatically called by TestCase
before any other test method is invoked"""
e = NullEngine()
# Uncomment to see visualization for debugging etc.
#from mayavi.core.engine import Engine
#e = Engine()
e.start()
e.new_scene()
self.e = e
def setUp(self):
"""Initial setting up of test fixture, automatically called by TestCase
before any other test method is invoked"""
e = NullEngine()
#Uncomment to see visualization for debugging etc.
#e = Engine()
e.start()
e.new_scene()
self.e=e
self.scene = e.current_scene
return
def setUp(self):
e = NullEngine()
# Uncomment to see visualization for debugging etc.
#e = Engine()
e.start()
self.e = e
s = e.new_scene()
self.scene = e.current_scene
self.setup_reader()
self.setup_viz()
return
def create_fn():
e = NullEngine()
e.start()
e.new_scene()
e.new_scene()
e.new_scene()
return e
def setUp(self):
self.root = tempfile.mkdtemp()
abc1 = os.path.join(self.root, "abc_1.vti")
abc2 = os.path.join(self.root, "abc_2.vti")
def1 = os.path.join(self.root, "def_1.vti")
def2 = os.path.join(self.root, "def_2.vti")
xyz1 = os.path.join(self.root, "xyz_1.vti")
cube = get_example_data("cube.vti")
self.abc1, self.abc2 = abc1, abc2
self.def1, self.def2 = def1, def2
self.xyz1 = xyz1
self.cube = cube
for i in (abc1, abc2, def1, def2, xyz1):
shutil.copy(cube, i)
e = NullEngine()
# Uncomment to see visualization for debugging etc.
# e = Engine()
e.start()
e.new_scene()
self.engine = e
def new_engine(self):
""" Creates a new engine, envisage or not depending on the
options.
"""
check_backend()
if options.backend == 'envisage':
from mayavi.plugins.app import Mayavi
m = Mayavi(start_gui_event_loop=False)
m.main()
process_ui_events()
window = m.application.workbench.active_window
engine = window.get_service(Engine)
elif options.backend == 'test':
engine = NullEngine(name='Null Mlab Engine')
engine.start()
else:
if options.offscreen:
engine = OffScreenEngine(name='Mlab offscreen Engine')
engine.start()
else:
engine = Engine(name='Mlab Engine')
engine.start()
self.current_engine = engine
return engine
def setUp(self):
"""Initial setting up of test fixture, automatically called by TestCase
before any other test method is invoked"""
e = NullEngine()
#Uncomment to see visualization for debugging etc.
#e = Engine()
e.start()
e.new_scene()
self.e = e
self.scene = e.current_scene
return
def setUp(self):
"""Initial setting up of test fixture, automatically called by TestCase
before any other test method is invoked"""
e = NullEngine()
# Uncomment to see visualization for debugging etc.
#from mayavi.core.engine import Engine
#e = Engine()
e.start()
e.new_scene()
self.e = e
def setUp(self):
"""Initial setting up of test fixture, automatically called by TestCase before any other test method is invoked"""
e = NullEngine()
# Uncomment to see visualization for debugging etc.
#e = Engine()
e.start()
s=e.new_scene()
self.e=e
self.s=s
############################################################
# Create a new scene and set up the visualization.
d = ArraySource()
sc = self.make_data()
d.scalar_data = sc
e.add_source(d)
self.t = Text3D()
e.add_module(self.t)
self.scene = e.current_scene
return
def setUp(self):
e = NullEngine()
e.start()
e.new_scene()
scene = e.scenes[-1]
s = ParametricSurface()
e.add_source(s)
o = Outline()
s.add_child(o)
o1 = Outline()
s.add_child(o1)
self.scene = scene
self.e = e
self.s = s
self.o = o
self.o1 = o1
return
def setUp(self):
"""Initial setting up of test fixture, automatically called by TestCase before any other test method is invoked"""
e = NullEngine()
# Uncomment to see visualization for debugging etc.
#e = Engine()
e.start()
s=e.new_scene()
self.e=e
self.s=s
############################################################
# Create a new scene and set up the visualization.
d = ArraySource()
sc = self.make_data()
d.scalar_data = sc
e.add_source(d)
self.t = Text3D()
e.add_module(self.t)
self.scene = e.current_scene
return
def setUp(self):
self.root = tempfile.mkdtemp()
abc1 = os.path.join(self.root, 'abc_1.vti')
abc2 = os.path.join(self.root, 'abc_2.vti')
def1 = os.path.join(self.root, 'def_1.vti')
def2 = os.path.join(self.root, 'def_2.vti')
xyz1 = os.path.join(self.root, 'xyz_1.vti')
cube = get_example_data('cube.vti')
self.abc1, self.abc2 = abc1, abc2
self.def1, self.def2 = def1, def2
self.xyz1 = xyz1
self.cube = cube
for i in (abc1, abc2, def1, def2, xyz1):
shutil.copy(cube, i)
e = NullEngine()
# Uncomment to see visualization for debugging etc.
#e = Engine()
e.start()
e.new_scene()
self.engine = e
def setUp(self):
"""Initial setting up of test fixture, automatically called by
TestCase before any other test method is invoked"""
e = NullEngine()
# Uncomment to see visualization for debugging etc.
#e = Engine()
e.start()
s=e.new_scene()
self.e=e
self.s=s
############################################################
# Create a new scene and set up the visualization.
#Make the grid
grid = self.make_grid4scatter()
e.add_source(grid)
eg = ExtractGrid()
e.add_filter(eg)
nb_ticks = 6
eg.x_ratio = eg.y_ratio = eg.z_ratio = 100/(nb_ticks-1)/2
gpx = GridPlane()
e.add_module(gpx)
gpx.grid_plane.axis = 'x'
gpy = GridPlane()
e.add_module(gpy)
gpy.grid_plane.axis = 'y'
gpz = GridPlane()
e.add_module(gpz)
gpz.grid_plane.axis = 'z'
#Add the scatter
d = VTKDataSource()
d.data = self.make_scatter()
e.add_source(d)
if is_old_pipeline():
a = Axes()
e.add_module(a)
a.axes.number_of_labels = nb_ticks
self.eg = eg
self.gpx = gpx
self.gpy = gpy
self.gpz = gpz
self.scene = e.current_scene
return
def test_script_recording(self):
"Does script recording work correctly."
# Create a mayavi pipeline and record it.
tape = self.tape
e = NullEngine()
e.start()
# Start recording.
tape.recording = True
tape.register(e, known=True, script_id='engine')
e.new_scene()
#print tape.script
self.assertEqual(tape.lines[-1],
"dummy_viewer = engine.new_scene()")
src = ParametricSurface()
e.add_source(src)
expect = 'from mayavi.sources.parametric_surface '\
'import ParametricSurface'
self.assertEqual(tape.lines[-3], expect)
self.assertEqual(tape.lines[-2],
"parametric_surface = ParametricSurface()")
self.assertEqual(tape.lines[-1],
"engine.add_source(parametric_surface)")
src.function = 'dini'
self.assertEqual(tape.lines[-1],
"parametric_surface.function = 'dini'")
o = Outline()
e.add_module(o)
expect = 'from mayavi.modules.outline import Outline'
self.assertEqual(tape.lines[-3], expect)
self.assertEqual(tape.lines[-2], "outline = Outline()")
self.assertEqual(tape.lines[-1],
"engine.add_module(outline)")
o.actor.property.color = (1,0,0)
self.assertEqual(tape.lines[-1],
"outline.actor.property.color = (1.0, 0.0, 0.0)")
s = Surface()
e.add_module(s)
expect = 'from mayavi.modules.surface import Surface'
self.assertEqual(tape.lines[-3], expect)
self.assertEqual(tape.lines[-2], "surface = Surface()")
self.assertEqual(tape.lines[-1],
"engine.add_module(surface)")
s.actor.property.representation = 'wireframe'
self.assertEqual(tape.lines[-1],
"surface.actor.property.representation = 'wireframe'")
o.actor.property.representation = 'wireframe'
self.assertEqual(tape.lines[-1],
"outline.actor.property.representation = 'wireframe'")
s.actor.property.opacity = 0.5
self.assertEqual(tape.lines[-1],
"surface.actor.property.opacity = 0.5")
s.actor.mapper.scalar_visibility = False
self.assertEqual(tape.lines[-1],
"surface.actor.mapper.scalar_visibility = False")
#print tape.script
# Stop recording and test.
tape.unregister(e)
tape.record('#end') # Placeholder
o.actor.property.opacity = 0.5
self.assertEqual(tape.lines[-1], '#end')
s.actor.property.color = (1,0,0)
self.assertEqual(tape.lines[-1], '#end')
s.enable_contours = True
self.assertEqual(tape.lines[-1], '#end')
src.function = 'klein'
self.assertEqual(tape.lines[-1], '#end')
def setUp(self):
"""Initial setting up of test fixture, automatically called by
TestCase before any other test method is invoked"""
e = NullEngine()
# Uncomment to see visualization for debugging etc.
#e = Engine()
e.start()
s = e.new_scene()
self.e = e
self.s = s
############################################################
# Create a new scene and set up the visualization.
#Make the grid
grid = self.make_grid4scatter()
e.add_source(grid)
eg = ExtractGrid()
e.add_filter(eg)
nb_ticks = 6
eg.x_ratio = eg.y_ratio = eg.z_ratio = 100 / (nb_ticks - 1) / 2
gpx = GridPlane()
e.add_module(gpx)
gpx.grid_plane.axis = 'x'
gpy = GridPlane()
e.add_module(gpy)
gpy.grid_plane.axis = 'y'
gpz = GridPlane()
e.add_module(gpz)
gpz.grid_plane.axis = 'z'
#Add the scatter
d = VTKDataSource()
d.data = self.make_scatter()
e.add_source(d)
if is_old_pipeline():
a = Axes()
e.add_module(a)
a.axes.number_of_labels = nb_ticks
self.eg = eg
self.gpx = gpx
self.gpy = gpy
self.gpz = gpz
self.scene = e.current_scene
return
def setUp(self):
e = NullEngine()
# Uncomment to see visualization for debugging etc.
# e = Engine()
e.start()
s = e.new_scene()
self.e = e
self.s = s
############################################################
# Create a new scene and set up the visualization.
d = ArraySource()
sc, vec = self.make_data()
d.origin = (-5, -5, -5)
d.scalar_data = sc
d.vector_data = vec
e.add_source(d)
# Create an outline for the data.
o = Outline()
e.add_module(o)
# Glyphs for the scalars
g = Glyph()
e.add_module(g)
g.glyph.glyph_source.glyph_position = 'center'
g.glyph.glyph.vector_mode = 'use_normal'
g.glyph.glyph.scale_factor = 0.5
g.glyph.mask_points.on_ratio = 20
g.actor.property.line_width = 1.0
v = VectorCutPlane()
glyph = v.glyph
gs = glyph.glyph_source
gs.glyph_position = 'tail'
gs.glyph_source = gs.glyph_list[1]
e.add_module(v)
v.implicit_plane.trait_set(normal=(0, 1, 0), origin=(0, 3, 0))
v = VectorCutPlane()
glyph = v.glyph
gs = glyph.glyph_source
gs.glyph_source = gs.glyph_list[2]
gs.glyph_position = 'head'
e.add_module(v)
v.implicit_plane.trait_set(normal=(0, 1, 0), origin=(0, -2, 0))
self.g = g
self.v = v
self.scene = e.current_scene
return
def setUp(self):
"""Initial setting up of test fixture, automatically called by TestCase before any other test method is invoked"""
e = NullEngine()
# Uncomment to see visualization for debugging etc.
#e = Engine()
e.start()
e.new_scene()
self.e = e
sgrid = datasets.generateStructuredGrid()
src = VTKDataSource(data=sgrid)
e.add_source(src)
# Create an outline for the data.
o = Outline()
e.add_module(o)
# Create one ContourGridPlane normal to the 'x' axis.
cgp1 = ContourGridPlane()
e.add_module(cgp1)
# Set the position to the middle of the data.
cgp1.grid_plane.position = 15
# Another with filled contours normal to 'y' axis.
cgp2 = ContourGridPlane()
cgp2.contour.filled_contours = True
# Set the axis and position to the middle of the data.
cgp2.grid_plane.axis = 'y'
cgp2.grid_plane.position = 15
e.add_module(cgp2)
# An isosurface module.
iso = IsoSurface(compute_normals=True)
e.add_module(iso)
iso.contour.contours = [5]
# An interactive scalar cut plane.
cp = ScalarCutPlane()
e.add_module(cp)
ip = cp.implicit_plane
ip.normal = 0, 0, 1
ip.origin = 0.5, 0.5, 1.0
# Since this is running offscreen this seems necessary.
ip.widget.origin = 0.5, 0.5, 1.0
ip.widget.enabled = False
self.scene = e.current_scene
self.cgp2 = cgp2
self.iso = iso
self.cp = cp
return
def setUp(self):
"""Initial setting up of test fixture, automatically called by TestCase before any other test method is invoked"""
e = NullEngine()
# Uncomment to see visualization for debugging etc.
#e = Engine()
e.start()
s=e.new_scene()
self.e=e
self.s=s
############################################################
# Create a new scene and set up the visualization.
d = ArraySource()
sc, vec = self.make_data()
d.origin = (-5, -5, -5)
d.scalar_data = sc
d.vector_data = vec
e.add_source(d)
# Create an outline for the data.
o = Outline()
e.add_module(o)
# View the data.
st = Streamline()
e.add_module(st)
widget = st.seed.widget
widget.set(radius=1.0, center=(-4.0, -4.0, -4.0),
theta_resolution=4, phi_resolution=4)
st = Streamline(streamline_type='ribbon')
seed = st.seed
seed.widget = seed.widget_list[1]
e.add_module(st)
seed.widget.set(point1=(-5.0, -4.5, -4.0), point2=(-5.0, -4.5, 4.0))
st.ribbon_filter.width = 0.25
st = Streamline(streamline_type='tube')
seed = st.seed
seed.widget = seed.widget_list[2]
e.add_module(st)
seed.widget.set(center=(-5.0, 1.5, -2.5))
st.tube_filter.radius = 0.15
st = Streamline(streamline_type='tube')
seed = st.seed
seed.widget = seed.widget_list[3]
e.add_module(st)
seed.widget.position=(-5.0, 3.75, 3.75)
st.tube_filter.radius = 0.2
self.st = st
self.scene = e.current_scene
return
def setUp(self):
e = NullEngine()
# Uncomment to see visualization for debugging etc.
#e = Engine()
e.start()
e.new_scene()
self.e=e
# Read a VTK XML data file.
r = VTKXMLFileReader()
r.initialize(get_example_data('cube.vti'))
e.add_source(r)
# Create an outline for the data.
o = Outline()
e.add_module(o)
# Create one ContourGridPlane normal to the 'x' axis.
cgp1 = ContourGridPlane()
e.add_module(cgp1)
# Set the position to the middle of the data.
cgp1.grid_plane.position = 1
# Another with filled contours normal to 'y' axis.
cgp2 = ContourGridPlane()
cgp2.contour.filled_contours = True
# Set the axis and position to the middle of the data.
cgp2.grid_plane.axis = 'y'
cgp2.grid_plane.position = 1
e.add_module(cgp2)
# An interactive scalar cut plane.
cp = ScalarCutPlane()
e.add_module(cp)
ip = cp.implicit_plane
ip.normal = 0,0,1
ip.origin = 0.5, 0.5, 1.0
# Since this is running offscreen this seems necessary.
ip.widget.origin = 0.5, 0.5, 1.0
ip.widget.enabled = False
self.scene = e.current_scene
self.cgp2=cgp2
self.cp=cp
return
def setUp(self):
"""Initial setting up of test fixture, automatically called by TestCase before any other test method is invoked"""
e = NullEngine()
# Uncomment to see visualization for debugging etc.
#e = Engine()
e.start()
s=e.new_scene()
self.e=e
self.s=s
############################################################
# Create a new scene and set up the visualization.
d = ArraySource()
sc, vec = self.make_data()
d.origin = (-5, -5, -5)
d.scalar_data = sc
d.vector_data = vec
e.add_source(d)
# Create an outline for the data.
o = Outline()
e.add_module(o)
# Glyphs for the scalars
g = Glyph()
e.add_module(g)
g.glyph.glyph_source.glyph_position = 'center'
g.glyph.glyph.vector_mode = 'use_normal'
g.glyph.glyph.scale_factor = 0.5
g.glyph.mask_points.on_ratio = 20
g.actor.property.line_width = 1.0
v = VectorCutPlane()
glyph = v.glyph
gs = glyph.glyph_source
gs.glyph_position = 'tail'
gs.glyph_source = gs.glyph_list[1]
e.add_module(v)
v.implicit_plane.set(normal=(0, 1, 0), origin=(0, 3, 0))
v = VectorCutPlane()
glyph = v.glyph
gs = glyph.glyph_source
gs.glyph_source = gs.glyph_list[2]
gs.glyph_position = 'head'
e.add_module(v)
v.implicit_plane.set(normal=(0, 1, 0), origin=(0, -2, 0))
self.g=g
self.v=v
self.scene = e.current_scene
return
def setUp(self):
"""Initial setting up of test fixture, automatically called by TestCase before any other test method is invoked"""
e = NullEngine()
# Uncomment to see visualization for debugging etc.
#e = Engine()
e.start()
e.new_scene()
self.e=e
# Read a VTK (old style) data file.
r = VTKXMLFileReader()
r.initialize(get_example_data('pyramid_ug.vtu'))
e.add_source(r)
# Create the filters.
idp = ImageDataProbe()
idp.rescale_scalars = True
e.add_filter(idp)
cgp = ContourGridPlane(enable_contours=False)
e.add_module(cgp)
cgp.grid_plane.axis = 'z'
cgp.grid_plane.position = 1
self.scene = e.current_scene
return
def setUp(self):
"""Initial setting up of test fixture, automatically called by TestCase before any other test method is invoked"""
e = NullEngine()
# Uncomment to see visualization for debugging etc.
#e = Engine()
e.start()
e.new_scene()
self.e = e
r = VTKXMLFileReader()
r.initialize(get_example_data('pyramid_ug.vtu'))
e.add_source(r)
r.point_scalars_name = 'temperature'
o = Outline()
e.add_module(o)
c = Contour()
e.add_filter(c)
n = PolyDataNormals()
e.add_filter(n)
aa = SetActiveAttribute()
e.add_filter(aa)
aa.point_scalars_name = 'pressure'
s = Surface()
e.add_module(s)
self.scene = e.current_scene
return
def setUp(self):
"""Initial setting up of test fixture, automatically called by TestCase before any other test method is invoked"""
e = NullEngine()
# Uncomment to see visualization for debugging etc.
#e = Engine()
e.start()
e.new_scene()
self.e=e
# Read the multi-block plot3d file.
r = PLOT3DReader()
r.reader.set(has_byte_count=True, multi_grid=True,
byte_order='little_endian')
r.initialize(get_example_data('tiny.xyz'),
get_example_data('tiny.q'),
configure=False)
e.add_source(r)
# Add the filter.
f = SelectOutput()
e.add_filter(f)
# Create an outline for the data.
o = Outline()
e.add_module(o)
o.render()
self.o=o
self.r=r
self.e=e
self.scene = e.current_scene
return
def test_script_recording(self):
"Does script recording work correctly."
# Create a mayavi pipeline and record it.
tape = self.tape
e = NullEngine()
e.start()
# Start recording.
tape.recording = True
tape.register(e, known=True, script_id='engine')
e.new_scene()
self.assertEqual(tape.lines[-1], "dummy_viewer = engine.new_scene()")
src = ParametricSurface()
e.add_source(src)
expect = 'from mayavi.sources.parametric_surface '\
'import ParametricSurface'
self.assertEqual(tape.lines[-3], expect)
self.assertEqual(tape.lines[-2],
"parametric_surface = ParametricSurface()")
self.assertEqual(tape.lines[-1],
"engine.add_source(parametric_surface)")
src.function = 'dini'
self.assertEqual(tape.lines[-1],
"parametric_surface.function = 'dini'")
o = Outline()
e.add_module(o)
expect = 'from mayavi.modules.outline import Outline'
self.assertEqual(tape.lines[-3], expect)
self.assertEqual(tape.lines[-2], "outline = Outline()")
self.assertEqual(tape.lines[-1], "engine.add_module(outline)")
o.actor.property.color = (1, 0, 0)
self.assertEqual(tape.lines[-1],
"outline.actor.property.color = (1.0, 0.0, 0.0)")
s = Surface()
e.add_module(s)
expect = 'from mayavi.modules.surface import Surface'
self.assertEqual(tape.lines[-3], expect)
self.assertEqual(tape.lines[-2], "surface = Surface()")
self.assertEqual(tape.lines[-1], "engine.add_module(surface)")
s.actor.property.representation = 'wireframe'
self.assertEqual(
tape.lines[-1],
"surface.actor.property.representation = 'wireframe'")
o.actor.property.representation = 'wireframe'
self.assertEqual(
tape.lines[-1],
"outline.actor.property.representation = 'wireframe'")
s.actor.property.opacity = 0.5
self.assertEqual(tape.lines[-1],
"surface.actor.property.opacity = 0.5")
s.actor.mapper.scalar_visibility = False
self.assertEqual(tape.lines[-1],
"surface.actor.mapper.scalar_visibility = False")
# Stop recording and test.
tape.unregister(e)
tape.record('#end') # Placeholder
o.actor.property.opacity = 0.5
self.assertEqual(tape.lines[-1], '#end')
s.actor.property.color = (1, 0, 0)
self.assertEqual(tape.lines[-1], '#end')
s.enable_contours = True
self.assertEqual(tape.lines[-1], '#end')
src.function = 'klein'
self.assertEqual(tape.lines[-1], '#end')
def setUp(self):
e = NullEngine()
# Uncomment to see visualization for debugging etc.
#e = Engine()
e.start()
e.new_scene()
self.e=e
# Read a VTK XML data file.
r = VTKXMLFileReader()
r.initialize(get_example_data('cube.vti'))
e.add_source(r)
# Create an outline for the data.
o = Outline()
e.add_module(o)
# Create one ContourGridPlane normal to the 'x' axis.
cgp1 = ContourGridPlane()
e.add_module(cgp1)
# Set the position to the middle of the data.
cgp1.grid_plane.position = 1
# Another with filled contours normal to 'y' axis.
cgp2 = ContourGridPlane()
cgp2.contour.filled_contours = True
# Set the axis and position to the middle of the data.
cgp2.grid_plane.axis = 'y'
cgp2.grid_plane.position = 1
e.add_module(cgp2)
# An interactive scalar cut plane.
cp = ScalarCutPlane()
e.add_module(cp)
ip = cp.implicit_plane
ip.normal = 0,0,1
ip.origin = 0.5, 0.5, 1.0
# Since this is running offscreen this seems necessary.
ip.widget.origin = 0.5, 0.5, 1.0
ip.widget.enabled = False
self.scene = e.current_scene
self.cgp2=cgp2
self.cp=cp
return
def setUp(self):
"""Initial setting up of test fixture, automatically called by TestCase before any other test method is invoked"""
e = NullEngine()
# Uncomment to see visualization for debugging etc.
#e = Engine()
e.start()
e.new_scene()
self.e=e
# Read a VTK (old style) data file.
r = VTKXMLFileReader()
r.initialize(get_example_data('pyramid_ug.vtu'))
e.add_source(r)
# Create the filters.
idp = ImageDataProbe()
idp.rescale_scalars = True
e.add_filter(idp)
cgp = ContourGridPlane(enable_contours=False)
e.add_module(cgp)
cgp.grid_plane.axis = 'z'
cgp.grid_plane.position = 1
self.scene = e.current_scene
return
def setUp(self):
"""Initial setting up of test fixture, automatically called by TestCase before any other test method is invoked"""
e = NullEngine()
# Uncomment to see visualization for debugging etc.
#e = Engine()
e.start()
s=e.new_scene()
self.e=e
self.s=s
############################################################
# Create a new scene and set up the visualization.
d = ArraySource()
sc = self.make_data()
d.scalar_data = sc
e.add_source(d)
# Create an outline for the data.
o = Outline()
e.add_module(o)
# ImagePlaneWidgets for the scalars
ipw = ImagePlaneWidget()
e.add_module(ipw)
ipw_y = ImagePlaneWidget()
e.add_module(ipw_y)
ipw_y.ipw.plane_orientation = 'y_axes'
ipw_z = ImagePlaneWidget()
e.add_module(ipw_z)
ipw_z.ipw.plane_orientation = 'z_axes'
self.scene = e.current_scene
return
def setUp(self):
"""Initial setting up of test fixture, automatically called by TestCase before any other test method is invoked"""
e = NullEngine()
# Uncomment to see visualization for debugging etc.
#e = Engine()
e.start()
s = e.new_scene()
self.e = e
self.s = s
############################################################
# Create a new scene and set up the visualization.
d = ArraySource()
sc, vec = self.make_data()
d.origin = (-5, -5, -5)
d.scalar_data = sc
d.vector_data = vec
e.add_source(d)
# Create an outline for the data.
o = Outline()
e.add_module(o)
# View the data.
st = Streamline()
e.add_module(st)
widget = st.seed.widget
widget.set(radius=1.0,
center=(-4.0, -4.0, -4.0),
theta_resolution=4,
phi_resolution=4)
st = Streamline(streamline_type='ribbon')
seed = st.seed
seed.widget = seed.widget_list[1]
e.add_module(st)
seed.widget.set(point1=(-5.0, -4.5, -4.0), point2=(-5.0, -4.5, 4.0))
st.ribbon_filter.width = 0.25
st = Streamline(streamline_type='tube')
seed = st.seed
seed.widget = seed.widget_list[2]
e.add_module(st)
seed.widget.set(center=(-5.0, 1.5, -2.5))
st.tube_filter.radius = 0.15
st = Streamline(streamline_type='tube')
seed = st.seed
seed.widget = seed.widget_list[3]
e.add_module(st)
seed.widget.position = (-5.0, 3.75, 3.75)
st.tube_filter.radius = 0.2
self.st = st
self.scene = e.current_scene
return
def setUp(self):
mlab.options.backend = 'test'
e = NullEngine()
e.start()
mlab.set_engine(e)
self.e = e
def setUp(self):
"""Initial setting up of test fixture, automatically called by TestCase before any other test method is invoked"""
e = NullEngine()
# Uncomment to see visualization for debugging etc.
#e = Engine()
e.start()
e.new_scene()
self.e = e
# Read a VTK (old style) data file.
r = VTKXMLFileReader()
r.initialize(get_example_data('pyramid_ug.vtu'))
e.add_source(r)
# Create the filters.
# CellDerivatives
cd = tvtk.CellDerivatives()
ud = UserDefined(filter=cd)
e.add_filter(ud)
ctp = CellToPointData()
ctp.filter.pass_cell_data = False
e.add_filter(ctp)
evn = ExtractVectorNorm()
e.add_filter(evn)
evc = ExtractVectorComponents(component='y-component')
o = Optional(filter=evc)
e.add_filter(o)
e.add_module(ScalarCutPlane())
self.scene = e.current_scene
s = self.scene
return
def setUp(self):
"""Initial setting up of test fixture, automatically called by TestCase before any other test method is invoked"""
e = NullEngine()
# Uncomment to see visualization for debugging etc.
#e = Engine()
e.start()
e.new_scene()
self.e=e
sgrid=datasets.generateStructuredGrid()
src = VTKDataSource(data = sgrid)
e.add_source(src)
# Create an outline for the data.
o = Outline()
e.add_module(o)
# Create one ContourGridPlane normal to the 'x' axis.
cgp1 = ContourGridPlane()
e.add_module(cgp1)
# Set the position to the middle of the data.
cgp1.grid_plane.position = 15
# Another with filled contours normal to 'y' axis.
cgp2 = ContourGridPlane()
cgp2.contour.filled_contours = True
# Set the axis and position to the middle of the data.
cgp2.grid_plane.axis = 'y'
cgp2.grid_plane.position = 15
e.add_module(cgp2)
# An isosurface module.
iso = IsoSurface(compute_normals=True)
e.add_module(iso)
iso.contour.contours = [5]
# An interactive scalar cut plane.
cp = ScalarCutPlane()
e.add_module(cp)
ip = cp.implicit_plane
ip.normal = 0,0,1
ip.origin = 0.5, 0.5, 1.0
# Since this is running offscreen this seems necessary.
ip.widget.origin = 0.5, 0.5, 1.0
ip.widget.enabled = False
self.scene = e.current_scene
self.cgp2=cgp2
self.iso=iso
self.cp=cp
return
def setUp(self):
"""Initial setting up of test fixture, automatically called by TestCase before any other test method is invoked"""
e = NullEngine()
# Uncomment to see visualization for debugging etc.
#e = Engine()
e.start()
e.new_scene()
self.e=e
r = VTKXMLFileReader()
r.initialize(get_example_data('pyramid_ug.vtu'))
e.add_source(r)
r.point_scalars_name = 'temperature'
o = Outline()
e.add_module(o)
c = Contour()
e.add_filter(c)
n = PolyDataNormals()
e.add_filter(n)
aa = SetActiveAttribute()
e.add_filter(aa)
aa.point_scalars_name = 'pressure'
s = Surface()
e.add_module(s)
self.scene = e.current_scene
return
def setUp(self):
"""Initial setting up of test fixture, automatically called by TestCase before any other test method is invoked"""
e = NullEngine()
# Uncomment to see visualization for debugging etc.
# e = Engine()
e.start()
e.new_scene()
self.e = e
# Read a VTK (old style) data file.
r = VTKXMLFileReader()
r.initialize(get_example_data("pyramid_ug.vtu"))
e.add_source(r)
# Create the filters.
# CellDerivatives
cd = tvtk.CellDerivatives()
ud = UserDefined(filter=cd)
e.add_filter(ud)
ctp = CellToPointData()
ctp.filter.pass_cell_data = False
e.add_filter(ctp)
evn = ExtractVectorNorm()
e.add_filter(evn)
evc = ExtractVectorComponents(component="y-component")
o = Optional(filter=evc)
e.add_filter(o)
e.add_module(ScalarCutPlane())
self.scene = e.current_scene
s = self.scene
return
def setUp(self):
e = NullEngine()
# Uncomment to see visualization for debugging etc.
#e = Engine()
e.start()
s=e.new_scene()
image_data = BuiltinImage()
e.add_source(image_data)
outline = Outline()
e.add_module(outline)
surface = Surface()
e.add_module(surface)
image_data.data_source.radius = array([ 80., 80., 80.])
image_data.data_source.center = array([ 150., 150., 0.])
image_data.data_source.whole_extent = array([ 10, 245, 10, 245, 0, 0])
if is_old_pipeline():
image_data.data_source.update_whole_extent()
else:
image_data.data_source.set_update_extent_to_whole_extent()
self.e=e
self.scene = e.current_scene
return
def setUp(self):
"""Initial setting up of test fixture, automatically called by
TestCase before any other test method is invoked"""
e = NullEngine()
# Uncomment to see visualization for debugging etc.
#e = Engine()
e.start()
s = e.new_scene()
poly_data = BuiltinSurface()
e.add_source(poly_data)
outline = Outline()
e.add_module(outline)
surface = Surface()
e.add_module(surface)
poly_data.data_source.shaft_radius = 0.05
poly_data.data_source.shaft_resolution = 7
poly_data.data_source.tip_radius = 0.1
self.e = e
self.scene = e.current_scene
return
def setUp(self):
"""Initial setting up of test fixture, automatically called by TestCase before any other test method is invoked"""
e = NullEngine()
# Uncomment to see visualization for debugging etc.
#e = Engine()
e.start()
e.new_scene()
self.e = e
sgrid = datasets.generateStructuredGrid()
src = VTKDataSource(data=sgrid)
e.add_source(src)
# Create an outline for the data.
o = Outline()
e.add_module(o)
# Create three simple grid plane modules.
# First normal to 'x' axis.
gp1 = GridPlane()
e.add_module(gp1)
# Second normal to 'y' axis.
gp2 = GridPlane()
# We'll test how robust things are by setting attributes
gp2.grid_plane.axis = 'y'
gp2.grid_plane.position = 16
e.add_module(gp2)
# Third normal to 'z' axis.
gp3 = GridPlane()
e.add_module(gp3)
gp3.grid_plane.axis = 'z'
gp3.grid_plane.position = 6
for gp in (gp1, gp2, gp3):
gp.actor.property.trait_set(ambient=1.0)
self.scene = e.current_scene
return
def setUp(self):
"""Initial setting up of test fixture, automatically called by TestCase before any other test method is invoked"""
e = NullEngine()
# Uncomment to see visualization for debugging etc.
#e = Engine()
e.start()
s=e.new_scene()
self.e=e
self.s=s
############################################################
# Create a new scene and set up the visualization.
d = ArraySource()
sc = self.make_data()
d.scalar_data = sc
e.add_source(d)
# Create an outline for the data.
o = Outline()
e.add_module(o)
# ImagePlaneWidgets for the scalars
ipw = ImagePlaneWidget()
e.add_module(ipw)
ipw_y = ImagePlaneWidget()
e.add_module(ipw_y)
ipw_y.ipw.plane_orientation = 'y_axes'
ipw_z = ImagePlaneWidget()
e.add_module(ipw_z)
ipw_z.ipw.plane_orientation = 'z_axes'
self.scene = e.current_scene
return
def setUp(self):
"""Initial setting up of test fixture, automatically called by TestCase before any other test method is invoked"""
e = NullEngine()
# Uncomment to see visualization for debugging etc.
#e = Engine()
e.start()
e.new_scene()
self.e = e
# Read the multi-block plot3d file.
r = PLOT3DReader()
r.reader.trait_set(has_byte_count=True,
multi_grid=True,
byte_order='little_endian')
r.initialize(get_example_data('tiny.xyz'),
get_example_data('tiny.q'),
configure=False)
e.add_source(r)
# Add the filter.
f = SelectOutput()
e.add_filter(f)
# Create an outline for the data.
o = Outline()
e.add_module(o)
o.render()
self.o = o
self.r = r
self.e = e
self.scene = e.current_scene
return
def setUp(self):
"""Initial setting up of test fixture, automatically called by TestCase before any other test method is invoked"""
e = NullEngine()
# Uncomment to see visualization for debugging etc.
#e = Engine()
e.start()
e.new_scene()
self.e=e
sgrid = datasets.generateStructuredGrid()
src = VTKDataSource(data = sgrid)
e.add_source(src)
# Create an outline for the data.
o = Outline()
e.add_module(o)
# Create three simple grid plane modules.
# First normal to 'x' axis.
gp1 = GridPlane()
e.add_module(gp1)
# Second normal to 'y' axis.
gp2 = GridPlane()
# We'll test how robust things are by setting attributes
gp2.grid_plane.axis = 'y'
gp2.grid_plane.position = 16
e.add_module(gp2)
# Third normal to 'z' axis.
gp3 = GridPlane()
e.add_module(gp3)
gp3.grid_plane.axis = 'z'
gp3.grid_plane.position = 6
for gp in (gp1, gp2, gp3):
gp.actor.property.set(ambient=1.0)
self.scene = e.current_scene
return
def create_fn():
e = NullEngine()
e.start()
scene = e.new_scene()
return scene
def setUp(self):
"""Initial setting up of test fixture, automatically called by TestCase before any other test method is invoked"""
e = NullEngine()
# Uncomment to see visualization for debugging etc.
#e = Engine()
e.start()
e.new_scene()
self.e=e
sgrid=datasets.generateStructuredGrid()
src = VTKDataSource(data = sgrid)
e.add_source(src)
c = Contour()
# `name` is used for the notebook tabs.
n = PolyDataNormals(name='Normals')
o = Optional(filter=n, label_text='Compute normals')
coll = Collection(filters=[c, o], name='IsoSurface')
e.add_filter(coll)
s = Surface()
e.add_module(s)
self.coll = coll
self.scene = e.current_scene
return
