def vtk_actors(self):
if (self.actors is None):
self.actors = []
points = _getfem_to_tvtk_points(self.sl.pts())
(triangles, cv2tr) = self.sl.splxs(2)
triangles = numpy.array(triangles.transpose(), 'I')
data = tvtk.PolyData(points=points, polys=triangles)
if self.scalar_data is not None:
data.point_data.scalars = numpy.array(self.scalar_data)
if self.vector_data is not None:
data.point_data.vectors = numpy.array(self.vector_data)
if self.glyph_name is not None:
mask = tvtk.MaskPoints()
mask.maximum_number_of_points = self.glyph_nb_pts
mask.random_mode = True
mask.input = data
if self.glyph_name == 'default':
if self.vector_data is not None:
self.glyph_name = 'arrow'
else:
self.glyph_name = 'ball'
glyph = tvtk.Glyph3D()
glyph.scale_mode = 'scale_by_vector'
glyph.color_mode = 'color_by_scalar'
#glyph.scale_mode = 'data_scaling_off'
glyph.vector_mode = 'use_vector' # or 'use_normal'
glyph.input = mask.output
if self.glyph_name == 'arrow':
glyph.source = tvtk.ArrowSource().output
elif self.glyph_name == 'ball':
glyph.source = tvtk.SphereSource().output
elif self.glyph_name == 'cone':
glyph.source = tvtk.ConeSource().output
elif self.glyph_name == 'cylinder':
glyph.source = tvtk.CylinderSource().output
elif self.glyph_name == 'cube':
glyph.source = tvtk.CubeSource().output
else:
raise Exception("Unknown glyph name..")
#glyph.scaling = 1
#glyph.scale_factor = self.glyph_scale_factor
data = glyph.output
if self.show_faces:
## if self.deform is not None:
## data.point_data.vectors = array(numarray.transpose(self.deform))
## warper = tvtk.WarpVector(input=data)
## data = warper.output
## lut = tvtk.LookupTable()
## lut.hue_range = 0.667,0
## c=gf_colormap('tripod')
## lut.number_of_table_values=c.shape[0]
## for i in range(0,c.shape[0]):
## lut.set_table_value(i,c[i,0],c[i,1],c[i,2],1)
self.mapper = tvtk.PolyDataMapper(input=data)
self.mapper.scalar_range = self.scalar_data_range
self.mapper.scalar_visibility = True
# Create mesh actor for display
self.actors += [tvtk.Actor(mapper=self.mapper)]
if self.show_edges:
(Pe, E1, E2) = self.sl.edges()
if Pe.size:
E = numpy.array(
numpy.concatenate((E1.transpose(), E2.transpose()),
axis=0), 'I')
edges = tvtk.PolyData(points=_getfem_to_tvtk_points(Pe),
polys=E)
mapper_edges = tvtk.PolyDataMapper(input=edges)
actor_edges = tvtk.Actor(mapper=mapper_edges)
actor_edges.property.representation = 'wireframe'
#actor_edges.property.configure_traits()
actor_edges.property.color = self.edges_color
actor_edges.property.line_width = self.edges_width
actor_edges.property.ambient = 0.5
self.actors += [actor_edges]
if self.sl.nbsplxs(1):
# plot tubes
(seg, cv2seg) = self.sl.splxs(1)
seg = numpy.array(seg.transpose(), 'I')
data = tvtk.Axes(origin=(0, 0, 0),
scale_factor=0.5,
symmetric=1)
data = tvtk.PolyData(points=points, lines=seg)
tube = tvtk.TubeFilter(radius=0.4,
number_of_sides=10,
vary_radius='vary_radius_off',
input=data)
mapper = tvtk.PolyDataMapper(input=tube.output)
actor_tubes = tvtk.Actor(mapper=mapper)
#actor_tubes.property.representation = 'wireframe'
actor_tubes.property.color = self.tube_color
#actor_tubes.property.line_width = 8
#actor_tubes.property.ambient = 0.5
self.actors += [actor_tubes]
if self.use_scalar_bar:
self.scalar_bar = tvtk.ScalarBarActor(
title=self.scalar_data_name,
orientation='horizontal',
width=0.8,
height=0.07)
self.scalar_bar.position_coordinate.coordinate_system = 'normalized_viewport'
self.scalar_bar.position_coordinate.value = 0.1, 0.01, 0.0
self.actors += [self.scalar_bar]
if (self.lookup_table is not None):
self.set_colormap(self.lookup_table)
return self.actors
# -*- coding: utf-8 -*-
from .example_cut_plane import read_data
import numpy as np
from tvtk.api import tvtk
from scpy2.tvtk.tvtkhelp import ivtk_scene, event_loop, make_outline
plot3d = read_data()
grid = plot3d.output.get_block(0)
mask = tvtk.MaskPoints(random_mode=True, on_ratio=50)
mask.set_input_data(grid)
arrow_source = tvtk.ArrowSource()
arrows = tvtk.Glyph3D(input_connection=mask.output_port,
scale_factor=2 /
np.max(grid.point_data.scalars.to_array()))
arrows.set_source_connection(arrow_source.output_port)
arrows_mapper = tvtk.PolyDataMapper(scalar_range=grid.point_data.scalars.range,
input_connection=arrows.output_port)
arrows_actor = tvtk.Actor(mapper=arrows_mapper)
center = grid.center
sphere = tvtk.SphereSource(center=(2, center[1], center[2]),
radius=2,
phi_resolution=6,
theta_resolution=6)
sphere_mapper = tvtk.PolyDataMapper(input_connection=sphere.output_port)
sphere_actor = tvtk.Actor(mapper=sphere_mapper)
sphere_actor.property.set(representation="wireframe", color=(0, 0, 0))
from tvtk.api import tvtk
from tvtkfunc import ivtk_scene, event_loop
plot3d = tvtk.MultiBlockPLOT3DReader(xyz_file_name="combxyz.bin",
q_file_name="combq.bin",
scalar_function_number=100,
vector_function_number=200)
plot3d.update()
grid = plot3d.output.get_block(0)
#用MaskPoints来pooling
mask = tvtk.MaskPoints(random_mode=True, on_ratio=10) #随机选点,10选一
mask.set_input_data(grid)
glyph_source = tvtk.ArrowSource()
#用Glyph3D在MaskPoints的点上放上ArrowSource(箭头)
glyph = tvtk.Glyph3D(input_connection=mask.output_port, scale_factor=1)
glyph.set_source_connection(glyph_source.output_port)
m = tvtk.PolyDataMapper(scalar_range=grid.point_data.scalars.range,
input_connection=glyph.output_port)
a = tvtk.Actor(mapper=m)
win = ivtk_scene(a)
win.scene.isometric_view()
event_loop()
