def PlaneSphereActors():
ps = vtk.vtkPlaneSource()
ps.SetXResolution(10)
ps.SetYResolution(10)
ss = vtk.vtkSphereSource()
ss.SetRadius (0.3)
group = vtk.vtkMultiBlockDataGroupFilter()
group.AddInputConnection(ps.GetOutputPort())
group.AddInputConnection(ss.GetOutputPort())
ag = vtk.vtkRandomAttributeGenerator()
ag.SetInputConnection(group.GetOutputPort())
ag.GenerateCellScalarsOn()
ag.AttributesConstantPerBlockOn()
n = vtk.vtkPolyDataNormals()
n.SetInputConnection(ag.GetOutputPort())
n.Update ();
actors = []
it = n.GetOutputDataObject(0).NewIterator()
it.InitTraversal()
while not it.IsDoneWithTraversal():
pm = vtk.vtkPolyDataMapper()
pm.SetInputData(it.GetCurrentDataObject())
a = vtk.vtkActor()
a.SetMapper(pm)
actors.append (a)
it.GoToNextItem()
return actors
def __init__( self ): PerkEvaluatorMetric.__init__( self ) self.outputPolyData = vtk.vtkAppendPolyData() self.planeSource = vtk.vtkPlaneSource() self.planePolyData = self.planeSource.GetOutput()
def __init__(self, module_manager):
SimpleVTKClassModuleBase.__init__(
self, module_manager,
vtk.vtkPlaneSource(), 'Processing.',
(), ('vtkPolyData',),
replaceDoc=True,
inputFunctions=None, outputFunctions=None)
def __init__(self, name, sliceDirections, defaultPlaneOrientation=2):
self.sliceDirections = sliceDirections
self._defaultPlaneOrientation = 2
# orthoPipeline is a list of dictionaries. each dictionary is:
# {'planeSource' : vtkPlaneSource, 'planeActor' : vtkActor,
# 'textureMapToPlane' : vtkTextureMapToPlane,
# '
self._orthoPipeline = []
# this is the frame that we will use to display our slice pipeline
self._orthoViewFrame = None
#
self._renderer = None
# list of vtkImagePlaneWidgets (first is "primary", rest are overlays)
self._ipws = []
# then some state variables
self._enabled = True
self._interactionEnabled = True
# list of objects that want to be contoured by this slice
self._contourObjectsDict = {}
self.overlayMode = 'greenOpacityRange'
self.fusionAlpha = 0.4
# we'll use this to store the polydata of our primary slice
self._primaryCopyPlaneSource = vtk.vtkPlaneSource()
self._primaryCopyPlaneSource.SetXResolution(64)
self._primaryCopyPlaneSource.SetYResolution(64)
self.primaryPolyData = self._primaryCopyPlaneSource.GetOutput()
def __init__(self, parent = None):
super(VTKFrame, self).__init__(parent)
self.vtkWidget = QVTKRenderWindowInteractor(self)
vl = QtGui.QVBoxLayout(self)
vl.addWidget(self.vtkWidget)
vl.setContentsMargins(0, 0, 0, 0)
self.ren = vtk.vtkRenderer()
self.ren.SetBackground(0.1, 0.2, 0.4)
self.vtkWidget.GetRenderWindow().AddRenderer(self.ren)
self.iren = self.vtkWidget.GetRenderWindow().GetInteractor()
# Provide some geometry
resolution = 8
aPlane = vtk.vtkPlaneSource()
aPlane.SetXResolution(resolution)
aPlane.SetYResolution(resolution)
# Create cell data
cellData = vtk.vtkFloatArray()
for i in range(resolution * resolution):
cellData.InsertNextValue(i+1)
# Create a lookup table to map cell data to colors
lut = vtk.vtkLookupTable()
tableSize = max(resolution*resolution+1, 10)
lut.SetNumberOfTableValues(tableSize)
lut.Build()
# Fill in a few known colors, the rest will be generated if needed
lut.SetTableValue(0 , 0 , 0 , 0, 1)# Black
lut.SetTableValue(1, 0.8900, 0.8100, 0.3400, 1)# Banana
lut.SetTableValue(2, 1.0000, 0.3882, 0.2784, 1)# Tomato
lut.SetTableValue(3, 0.9608, 0.8706, 0.7020, 1)# Wheat
lut.SetTableValue(4, 0.9020, 0.9020, 0.9804, 1)# Lavender
lut.SetTableValue(5, 1.0000, 0.4900, 0.2500, 1)# Flesh
lut.SetTableValue(6, 0.5300, 0.1500, 0.3400, 1)# Raspberry
lut.SetTableValue(7, 0.9804, 0.5020, 0.4471, 1)# Salmon
lut.SetTableValue(8, 0.7400, 0.9900, 0.7900, 1)# Mint
lut.SetTableValue(9, 0.2000, 0.6300, 0.7900, 1)# Peacock
aPlane.Update() #Force an update so we can set cell data
aPlane.GetOutput().GetCellData().SetScalars(cellData)
# Create a mapper
mapper = vtk.vtkPolyDataMapper()
mapper.SetInputConnection(aPlane.GetOutputPort())
mapper.SetScalarRange(0, tableSize - 1)
mapper.SetLookupTable(lut)
# Create an actor
actor = vtk.vtkActor()
actor.SetMapper(mapper)
self.ren.AddActor(actor)
self.ren.ResetCamera()
self._initialized = False
def initSeedPoint(self):
print "initializing SeedPoint"
self.vtkSeeds = vtk.vtkPlaneSource()
self.vtkSeeds.SetXResolution(4)
self.vtkSeeds.SetYResolution(4)
self.vtkSeeds.SetOrigin(0.0, 0.0, 0.0)
self.vtkSeeds.SetPoint1(-10.0, -10.0, -10.0)
self.vtkSeeds.SetPoint2(10.0, 10.0, 10.0)
def coplanar(self):
numSelected = EventHandler().get_num_selected()
if numSelected !=3:
error_msg("You must first select exactly 3 markers",
)
return
# SetNormal is missing from the 4.2 python API so this is
# a long winded way of setting the pw to intersect 3
# selected markers
m1, m2, m3 = EventHandler().get_selected()
p1 = m1.get_center()
p2 = m2.get_center()
p3 = m3.get_center()
pw = pwo.get_pw()
planeO = vtk.vtkPlaneSource()
planeO.SetOrigin(pw.GetOrigin())
planeO.SetPoint1(pw.GetPoint1())
planeO.SetPoint2(pw.GetPoint2())
planeO.Update()
planeN = vtk.vtkPlaneSource()
planeN.SetOrigin(p1)
planeN.SetPoint1(p2)
planeN.SetPoint2(p3)
planeN.Update()
normal = planeN.GetNormal()
planeO.SetNormal(normal)
planeO.SetCenter(
(p1[0] + p2[0] + p3[0])/3,
(p1[1] + p2[1] + p3[1])/3,
(p1[2] + p2[2] + p3[2])/3,
)
planeO.Update()
pwxyz = pwo.get_pwxyz()
pw.SetOrigin(planeO.GetOrigin())
pw.SetPoint1(planeO.GetPoint1())
pw.SetPoint2(planeO.GetPoint2())
pw.UpdatePlacement()
pwo.update_plane()
pwo.Render()
pwxyz.Render()
def __init__(self, center=(0,0,0), color=(0,0,1) ):
self.src = vtk.vtkPlaneSource()
#self.src.SetCenter(center)
self.mapper = vtk.vtkPolyDataMapper()
self.mapper.SetInput(self.src.GetOutput())
self.SetMapper(self.mapper)
self.SetColor(color)
self.SetOrigin(center)
def __init__(self):
# ODE initialization
self.world = ode.World()
self.world.setGravity(GRAVITY)
self.world.setERP(ERP)
self.world.setCFM(CFM)
self.space = ode.Space()
self.floor = ode.GeomPlane(self.space, (0.0,1.0,0.0), 0.0)
self.jointGroup = ode.JointGroup()
self.time = 0.0
# VTK initialization
self.renderer = vtk.vtkRenderer()
self.renderer.SetBackground(102.0/255.0,204/255.0,1.0)
self.window = vtk.vtkRenderWindow()
self.window.SetSize(WINDOW_WIDTH,WINDOW_HEIGHT)
self.window.AddRenderer(self.renderer)
self.interactor = vtk.vtkRenderWindowInteractor()
self.interactor.SetRenderWindow(self.window)
self.axes = vtk.vtkAxesActor()
self.axes.SetAxisLabels(0)
transform = vtk.vtkTransform()
transform.Scale(0.1,0.1,0.1)
self.axes.SetUserTransform(transform)
self.renderer.AddActor(self.axes)
# Create ground plane visualization
self.floorVisual = vtk.vtkPlaneSource()
self.floorVisual.SetNormal((0.0,1.0,0.0))
self.floorVisual.SetResolution(10,10)
self.floorReader = vtk.vtkJPEGReader()
self.floorReader.SetFileName(FLOOR_IMAGE)
self.floorTexture = vtk.vtkTexture()
transform = vtk.vtkTransform()
transform.Scale(50.0,50.0,50.0)
self.floorTexture.SetTransform(transform)
self.floorTexture.SetInput(self.floorReader.GetOutput())
self.floorMap = vtk.vtkTextureMapToPlane()
self.floorMap.SetInput(self.floorVisual.GetOutput())
self.floorMapper = vtk.vtkPolyDataMapper()
self.floorMapper.SetInput(self.floorMap.GetOutput())
self.floorActor = vtk.vtkActor()
transform = vtk.vtkTransform()
transform.Scale(100.0,100.0,100.0)
self.floorActor.SetUserTransform(transform)
self.floorActor.SetMapper(self.floorMapper)
self.floorActor.SetTexture(self.floorTexture)
self.renderer.AddActor(self.floorActor)
# VTK camera setup
self.camera = vtk.vtkCamera()
self.renderer.SetActiveCamera(self.camera)
self.cameraFocus = [0.0, 0.0, 0.0]
self.cameraPos = [4.0, 2.5, 1.5]
self.cameraOffset = [0.0,1.0,3.0]
self.cameraRoll = 0.0
# Keep track of the simulated bodies and robots
self.bodies = []
self.robots = []
self.controllers = []
def _MakeXYActors(self, reduce=1):
# get a texture-mapped actor
extent = self._ImageReslice.GetOutputExtent()
origin = self._ImageReslice.GetOutputOrigin()
spacing = self._ImageReslice.GetOutputSpacing()
bounds = [origin[0] + spacing[0] * (extent[0] - 0.5),
origin[0] + spacing[0] * (extent[1] + 0.5),
origin[1] + spacing[1] * (extent[2] - 0.5),
origin[1] + spacing[1] * (extent[3] + 0.5),
origin[2] + spacing[2] * (extent[4] - 0.5),
origin[2] + spacing[2] * (extent[5] + 0.5)]
for sliceNumber in range(extent[4], old_div((extent[5] + 1), reduce)):
# the z position of the slice
z = origin[2] + reduce * sliceNumber * spacing[2]
plane = vtk.vtkPlaneSource()
plane.SetXResolution(1)
plane.SetYResolution(1)
plane.SetOrigin(bounds[0], bounds[2], z)
plane.SetPoint1(bounds[1], bounds[2], z)
plane.SetPoint2(bounds[0], bounds[3], z)
imageClip = vtk.vtkExtractVOI()
imageClip.SetInput(self._ImageToStructuredPoints.GetOutput())
imageClip.SetVOI(extent[0], extent[1],
extent[2], extent[3],
reduce * sliceNumber, reduce * sliceNumber)
imageClip.ReleaseDataFlagOn()
texture = vtk.vtkTexture()
texture.SetQualityTo32Bit()
texture.SetInput(imageClip.GetOutput())
texture.RepeatOff()
texture.InterpolateOn()
texture.MapColorScalarsThroughLookupTableOff()
for i in range(3):
mapper = vtk.vtkPolyDataMapper()
mapper.SetInput(plane.GetOutput())
mapper.SetClippingPlanes(self._ClippingPlanes[i])
actor = vtk.vtkActor()
actor.SetMapper(mapper)
actor.SetTexture(texture)
actor.PickableOff()
actor.SetProperty(self._PropertyXY)
self._PlanesXY.append(plane)
self._ImageClipsXY.append(imageClip)
self._ActorsXY.append(actor)
numberOfPlanes = (extent[5] - extent[4] + 1) / reduce * 3
return self._ActorsXY[-numberOfPlanes:]
def SetInput(self, imagedata):
axes = PLANE_DATA[self.orientation][0] # "x", "y" or "z"
colour = PLANE_DATA[self.orientation][1]
#if self.orientation == SAGITAL:
# spacing = min(imagedata.GetSpacing())
# permute = vtk.vtkImagePermute()
# permute.SetInput(imagedata)
# permute.GetOutput().ReleaseDataFlagOn()
# permute.SetOutputSpacing(spacing, spacing, spacing)
# imagedata = permute.GetOutput()
# Picker for enabling plane motion.
# Allows selection of a cell by shooting a ray into graphics window
picker = vtk.vtkCellPicker()
picker.SetTolerance(0.005)
picker.PickFromListOn()
# 3D widget for reslicing image data.
# This 3D widget defines a plane that can be interactively placed in an image volume.
widget = vtk.vtkImagePlaneWidget()
widget.SetInput(imagedata)
widget.SetSliceIndex(self.index)
widget.SetPicker(picker)
widget.SetKeyPressActivationValue(axes)
widget.SetInteractor(self.iren)
widget.TextureVisibilityOff()
widget.DisplayTextOff()
widget.RestrictPlaneToVolumeOff()
exec("widget.SetPlaneOrientationTo"+axes.upper()+"Axes()")
widget.AddObserver("InteractionEvent",self.Update)
self.widget = widget
prop = widget.GetPlaneProperty()
prop.SetColor(colour)
# Syncronize coloured outline with texture appropriately
source = vtk.vtkPlaneSource()
source.SetOrigin(widget.GetOrigin())
source.SetPoint1(widget.GetPoint1())
source.SetPoint2(widget.GetPoint2())
source.SetNormal(widget.GetNormal())
self.source = source
mapper = vtk.vtkPolyDataMapper()
mapper.SetInput(source.GetOutput())
actor = vtk.vtkActor()
actor.SetMapper(mapper)
actor.SetTexture(widget.GetTexture())
actor.VisibilityOff()
self.actor = actor
self.render.AddActor(actor)
def _create_geometry(self):
self._plane_source = vtk.vtkPlaneSource()
self._plane_source.SetNormal((0.0,0.0,1.0))
self._plane_source.SetXResolution(1)
self._plane_source.SetYResolution(1)
m = vtk.vtkPolyDataMapper()
m.SetInputConnection(self._plane_source.GetOutputPort())
a = vtk.vtkActor()
a.SetMapper(m)
a.GetProperty().SetOpacity(0.3)
a.GetProperty().SetColor(0.0, 0.0, 0.7)
self.props = [a]
def MakePlane():
'''
Make a plane as the source.
:return: vtkPolyData with normal and scalar data.
'''
source = vtk.vtkPlaneSource()
source.SetOrigin(-10.0, -10.0, 0.0)
source.SetPoint2(-10.0, 10.0, 0.0)
source.SetPoint1(10.0, -10.0, 0.0)
source.SetXResolution(20)
source.SetYResolution(20)
source.Update()
return MakeElevations(source.GetOutput())
def createPlaneActor(plane):
center = plane.center()
normal = plane.normal()
source = vtk.vtkPlaneSource()
source.SetCenter(center[0], center[1], center[2])
source.SetNormal(normal[0], normal[1], normal[2])
mapper = vtk.vtkPolyDataMapper()
mapper.SetInputConnection(source.GetOutputPort())
obj = vtk.vtkActor()
obj.SetMapper(mapper)
return obj
def __init__(self, origin, p1, p2, width, height):
logging.debug("In Slice::__init__()")
self._p1 = p1
self._p2 = p2
self._width = width
self._origin = origin
self._height = height
self._plane = vtk.vtkPlaneSource()
self._plane.SetOrigin(self._origin)
self._plane.SetPoint1(self._p1)
self._plane.SetPoint2(self._p2)
self._plane.Update()
self.normalizePlaneSize()
self.createBoundsPlanes()
self._resliceTransform = None
def Plane(self):
p = vtkPlaneSource()
# Default is:
# Centre = 0,0,0
# Normal = 0,0,1
# Origin = -0.5, -0.5, 0
# So set the radius first while it's simple
p.SetOrigin(-self.Radius, -self.Radius, 0.)
p.SetPoint1(+self.Radius, -self.Radius, 0.)
p.SetPoint2(-self.Radius, +self.Radius, 0.)
# Shift to the right place
p.SetCenter(self.Centre.x, self.Centre.y, self.Centre.z)
# Orient correctly
p.SetNormal(self.Normal.x, self.Normal.y, self.Normal.z)
return p
def init_fiducial_actor(self, fiducial_obj):
"""Initialize a plane VTK actor to display the fiducials."""
plane_source = vtk.vtkPlaneSource()
plane_source.SetCenter(0.0, 0.0, 0.0)
plane_source.SetNormal(0.0, 0.0, 1.0)
plane_source.Update()
plane = plane_source.GetOutput()
mapper = vtk.vtkPolyDataMapper()
mapper.SetInputData(plane)
actor = vtk.vtkActor()
actor.SetMapper(mapper)
actor.GetProperty().SetColor(1.0, 0.0, 0.0)
actor.SetScale(fiducial_obj.apriltag_properties.dimensions.x,
fiducial_obj.apriltag_properties.dimensions.y, 1.0)
return actor
def planesCallback(self, obj, event):
fp = self.ren_list[1].GetActiveCamera().GetFocalPoint()
p = self.ren_list[1].GetActiveCamera().GetPosition()
dist = np.sqrt((p[0] - fp[0]) ** 2 + (p[1] - fp[1]) ** 2 + (p[2] - fp[2]) ** 2)
self.ren_list[1].GetActiveCamera().SetPosition(fp[0], fp[1], fp[2] + dist)
self.ren_list[1].GetActiveCamera().SetViewUp(0.0, 1.0, 0.0)
fp = self.ren_list[2].GetActiveCamera().GetFocalPoint()
p = self.ren_list[2].GetActiveCamera().GetPosition()
dist = np.sqrt((p[0] - fp[0]) ** 2 + (p[1] - fp[1]) ** 2 + (p[2] - fp[2]) ** 2)
self.ren_list[2].GetActiveCamera().SetPosition(fp[0] + dist, fp[1], fp[2])
self.ren_list[2].GetActiveCamera().SetViewUp(0.0, -1.0, 0.0)
self.ren_list[2].GetActiveCamera().Roll(90)
fp = self.ren_list[3].GetActiveCamera().GetFocalPoint()
p = self.ren_list[3].GetActiveCamera().GetPosition()
dist = np.sqrt((p[0] - fp[0]) ** 2 + (p[1] - fp[1]) ** 2 + (p[2] - fp[2]) ** 2)
self.ren_list[3].GetActiveCamera().SetPosition(fp[0], fp[1] - dist, fp[2])
self.ren_list[3].GetActiveCamera().SetViewUp(-1.0, 0.0, 0.0)
self.ren_list[3].GetActiveCamera().Roll(90)
new_center = obj.GetCenter()
new_normal = obj.GetNormal()
index = obj.index
new_source = vtk.vtkPlaneSource()
new_source.SetCenter(new_center)
new_source.SetNormal(new_normal)
new_source.Update()
self.geo_data.foliation_modify(index, X=new_center[0], Y=new_center[1], Z=new_center[2],
G_x=new_normal[0], G_y=new_normal[1], G_z=new_normal[2])
render = obj.n_render
if render != 0:
self.f_rend_1[obj.n_plane].SetInputData(new_source.GetOutput())
self.f_rend_1[obj.n_plane].SetNormal(new_normal)
if render != 1:
self.f_rend_2[obj.n_plane].SetInputData(new_source.GetOutput())
self.f_rend_2[obj.n_plane].SetNormal(new_normal)
if render != 2:
self.f_rend_3[obj.n_plane].SetInputData(new_source.GetOutput())
self.f_rend_3[obj.n_plane].SetNormal(new_normal)
if render != 3:
self.f_rend_4[obj.n_plane].SetInputData(new_source.GetOutput())
self.f_rend_4[obj.n_plane].SetNormal(new_normal)
def Plane(center=(0, 0, 0),
direction=(0, 0, 1),
i_size=1,
j_size=1,
i_resolution=10,
j_resolution=10):
"""
Create a plane
Parameters
----------
center : list or np.ndarray
Location of the centroid in [x, y, z]
direction : list or np.ndarray
Direction cylinder points to in [x, y, z]
i_size : float
Size of the plane in the i direction.
j_size : float
Size of the plane in the i direction.
i_resolution : int
Number of points on the plane in the i direction.
j_resolution : int
Number of points on the plane in the j direction.
Returns
-------
plane : pyvista.PolyData
Plane mesh
"""
planeSource = vtk.vtkPlaneSource()
planeSource.SetXResolution(i_resolution)
planeSource.SetYResolution(j_resolution)
planeSource.Update()
surf = pyvista.PolyData(planeSource.GetOutput())
surf.points[:, 0] *= i_size
surf.points[:, 1] *= j_size
surf.rotate_y(-90)
translate(surf, center, direction)
return surf
def floor():
plane = vtk.vtkPlaneSource()
reader = vtk.vtkJPEGReader()
reader.SetFileName(
pkg_resources.resource_filename(
__name__, '/'.join(('media', 'imgs', 'floor.jpg'))))
texture = vtk.vtkTexture()
texture.SetInputConnection(reader.GetOutputPort())
map_to_plane = vtk.vtkTextureMapToPlane()
map_to_plane.SetInputConnection(plane.GetOutputPort())
mapper = vtk.vtkPolyDataMapper()
mapper.SetInputConnection(map_to_plane.GetOutputPort())
actor = vtk.vtkActor()
actor.SetMapper(mapper)
actor.SetTexture(texture)
return actor
def makeBorderPD(ipw):
# setup source
ps = vtk.vtkPlaneSource()
ps.SetOrigin(ipw.GetOrigin())
ps.SetPoint1(ipw.GetPoint1())
ps.SetPoint2(ipw.GetPoint2())
fe = vtk.vtkFeatureEdges()
fe.SetInput(ps.GetOutput())
tubef = vtk.vtkTubeFilter()
tubef.SetNumberOfSides(12)
tubef.SetRadius(0.5)
tubef.SetInput(fe.GetOutput())
return tubef.GetOutput()
def CreateImageLabelModel(self, width, height):
# Create Image Label Transform if not in scene already
try:
self.imageLabelTransform = slicer.util.getNode(
"ImageLabelTransform")
except:
self.imageLabelTransform = slicer.util.loadTransform(
os.path.join(self.resourcePath,
'Resources/ImageLabelTransform.h5'))
self.imageLabelTransform.SetAndObserveTransformNodeID(
self.sceneTransform.GetID())
# Create Backup so we can move red border back to there
self.imageLabelMatrix = vtk.vtkMatrix4x4()
self.imageLabelTransform.GetMatrixTransformToParent(
self.imageLabelMatrix)
self.imageLabelTransformBackup = self.imageLabelTransform
# Create Instruction Model Node if not in scene already
try:
self.imageLabelModelNode = slicer.util.getNode("ImageLabelModel")
except:
self.imageLabelPlane = vtk.vtkPlaneSource()
self.imageLabelPlane.SetPoint1(0, height, 0)
self.imageLabelPlane.SetPoint2(width, 0, 0)
self.imageLabelPlane.SetOrigin(0, 0, 0)
self.imageLabelPlane.Update()
self.pngImageReader = vtk.vtkPNGReader()
self.pngImageReader.SetFileName(
os.path.join(self.resourcePath,
'Resources/RedBorderTrans.png'))
self.pngImageReader.Update()
self.imageLabelModelNode = slicer.mrmlScene.AddNewNodeByClass(
'vtkMRMLModelNode')
self.imageLabelModelNode.SetName("ImageLabelModel")
self.imageLabelModelNode.CreateDefaultDisplayNodes()
self.imageLabelModelNode.SetAndObservePolyData(
self.imageLabelPlane.GetOutput())
self.imageLabelModelNode.SetAndObserveTransformNodeID(
self.imageLabelTransform.GetID())
self.imageLabelModelDisplay = self.imageLabelModelNode.GetDisplayNode(
)
self.imageLabelModelDisplay.SetTextureImageDataConnection(
self.pngImageReader.GetOutputPort())
self.imageLabelModelDisplay.VisibilityOn()
self.imageLabelModelDisplay.SetFrontfaceCulling(False)
self.imageLabelModelDisplay.SetBackfaceCulling(False)
def __add_plane_to_ren(center, normal, length, ren):
import vtk
center = np.array(center)
source = vtk.vtkPlaneSource()
source.SetOrigin(0, 0, 0)
source.SetPoint1(length, 0, 0)
source.SetPoint2(0, length, 0)
source.SetCenter(*center)
source.SetNormal(*normal)
source.Update()
mapper = vtk.vtkPolyDataMapper()
mapper.SetInputConnection(source.GetOutputPort())
ac = vtk.vtkActor()
ac.SetMapper(mapper)
ren.AddActor(ac)
return ac
def make_vtk_plane():
''' Create a plane in vtk and return the actor for the plane.'''
# create source
source = vtk.vtkPlaneSource()
source.SetPoint1(-10, 10, 0)
source.SetPoint2(10, -10, 0)
source.SetOrigin(-10, -10, 0)
# mapper
mapper = vtk.vtkPolyDataMapper()
mapper.SetInputConnection(source.GetOutputPort())
# actor
actor = vtk.vtkActor()
actor.SetMapper(mapper)
return actor
def makeBorderPD(ipw):
# setup source
ps = vtk.vtkPlaneSource()
ps.SetOrigin(ipw.GetOrigin())
ps.SetPoint1(ipw.GetPoint1())
ps.SetPoint2(ipw.GetPoint2())
fe = vtk.vtkFeatureEdges()
fe.SetInput(ps.GetOutput())
tubef = vtk.vtkTubeFilter()
tubef.SetNumberOfSides(12)
tubef.SetRadius(0.5)
tubef.SetInput(fe.GetOutput())
return tubef.GetOutput()
def grid(pos=[0, 0, 0],
normal=[0, 0, 1],
sx=1,
sy=1,
c='g',
bc='darkgreen',
lw=1,
alpha=1,
legend=None,
resx=10,
resy=10):
'''Return a grid plane.
.. hint:: Example: `brownian2D.py <https://github.com/marcomusy/vtkplotter/blob/master/examples/advanced/brownian2D.py>`_
.. image:: https://user-images.githubusercontent.com/32848391/50738948-73ce8300-11d9-11e9-8ef6-fc4f64c4a9ce.gif
'''
ps = vtk.vtkPlaneSource()
ps.SetResolution(resx, resy)
ps.Update()
poly0 = ps.GetOutput()
t0 = vtk.vtkTransform()
t0.Scale(sx, sy, 1)
tf0 = vtk.vtkTransformPolyDataFilter()
tf0.SetInputData(poly0)
tf0.SetTransform(t0)
tf0.Update()
poly = tf0.GetOutput()
axis = np.array(normal) / np.linalg.norm(normal)
theta = np.arccos(axis[2])
phi = np.arctan2(axis[1], axis[0])
t = vtk.vtkTransform()
t.PostMultiply()
t.RotateY(theta * 57.3)
t.RotateZ(phi * 57.3)
tf = vtk.vtkTransformPolyDataFilter()
tf.SetInputData(poly)
tf.SetTransform(t)
tf.Update()
pd = tf.GetOutput()
actor = Actor(pd, c=c, bc=bc, alpha=alpha, legend=legend)
actor.GetProperty().SetRepresentationToWireframe()
actor.GetProperty().SetLineWidth(lw)
actor.SetPosition(pos)
actor.PickableOff()
return actor
def Grid(
pos=(0, 0, 0),
normal=(0, 0, 1),
sx=1,
sy=1,
c="g",
bc="darkgreen",
lw=1,
alpha=1,
resx=10,
resy=10,
):
"""Return a grid plane.
.. hint:: |brownian2D| |brownian2D.py|_
"""
ps = vtk.vtkPlaneSource()
ps.SetResolution(resx, resy)
ps.Update()
poly0 = ps.GetOutput()
t0 = vtk.vtkTransform()
t0.Scale(sx, sy, 1)
tf0 = vtk.vtkTransformPolyDataFilter()
tf0.SetInputData(poly0)
tf0.SetTransform(t0)
tf0.Update()
poly = tf0.GetOutput()
axis = np.array(normal) / np.linalg.norm(normal)
theta = np.arccos(axis[2])
phi = np.arctan2(axis[1], axis[0])
t = vtk.vtkTransform()
t.PostMultiply()
t.RotateY(np.rad2deg(theta))
t.RotateZ(np.rad2deg(phi))
tf = vtk.vtkTransformPolyDataFilter()
tf.SetInputData(poly)
tf.SetTransform(t)
tf.Update()
pd = tf.GetOutput()
actor = Actor(pd, c=c, bc=bc, alpha=alpha)
actor.GetProperty().SetRepresentationToWireframe()
actor.GetProperty().SetLineWidth(lw)
actor.SetPosition(pos)
settings.collectable_actors.append(actor)
return actor
def __init__(self, parent=None):
super(VTKFrame, self).__init__(parent)
self.vtkWidget = QVTKRenderWindowInteractor(self)
vl = QtGui.QVBoxLayout(self)
vl.addWidget(self.vtkWidget)
vl.setContentsMargins(0, 0, 0, 0)
self.ren = vtk.vtkRenderer()
self.ren.SetBackground(0.1, 0.2, 0.4)
self.vtkWidget.GetRenderWindow().AddRenderer(self.ren)
self.iren = self.vtkWidget.GetRenderWindow().GetInteractor()
# Provide some geometry
resolution = 8
aPlane = vtk.vtkPlaneSource()
aPlane.SetXResolution(resolution)
aPlane.SetYResolution(resolution)
aPlane.Update()
# Create cell data
cellData = vtk.vtkUnsignedCharArray()
cellData.SetNumberOfComponents(3)
cellData.SetNumberOfTuples(aPlane.GetOutput().GetNumberOfCells())
for i in range(aPlane.GetOutput().GetNumberOfCells()):
rgb = random.randint(64, 255), random.randint(64,
255), random.randint(
64, 255)
cellData.InsertTuple(i, rgb)
aPlane.GetOutput().GetCellData().SetScalars(cellData)
# Create a mapper
mapper = vtk.vtkPolyDataMapper()
mapper.SetInputConnection(aPlane.GetOutputPort())
# Create an actor
actor = vtk.vtkActor()
actor.SetMapper(mapper)
self.ren.AddActor(actor)
self.ren.ResetCamera()
self._initialized = False
def make_color_plane(x, y, colors):
plane = vtk.vtkPlaneSource()
plane.SetXResolution(x)
plane.SetYResolution(y)
plane.Update()
colorData = colors_to_scalars(colors)
plane.GetOutput().GetCellData().SetScalars(colorData)
mapper = vtk.vtkPolyDataMapper()
mapper.SetInputConnection(plane.GetOutputPort())
mapper.SetScalarModeToUseCellData()
mapper.Update()
actor = vtk.vtkActor()
actor.SetMapper(mapper)
return actor
def make_color_plane(x, y, colors):
plane = vtk.vtkPlaneSource()
plane.SetXResolution(x)
plane.SetYResolution(y)
plane.Update()
colorData = colors_to_scalars(colors)
plane.GetOutput().GetCellData().SetScalars(colorData)
mapper = vtk.vtkPolyDataMapper()
mapper.SetInputConnection(plane.GetOutputPort())
mapper.SetScalarModeToUseCellData()
mapper.Update()
actor = vtk.vtkActor()
actor.SetMapper(mapper)
return actor
def addPlane(self,
name,
point1,
point2,
point3,
color=np.array([255.0, 255.0, 255.0]),
opacity=1.0):
self.removeActorByName(name)
# Create a plane
planeSource = vtk.vtkPlaneSource()
# planeSource.SetOrigin(center_point[0], center_point[1], center_point[2])
# #planeSource.SetNormal(normal_vector[0], normal_vector[1], normal_vector[2])
# #print(dir(planeSource))
# planeSource.SetPoint1(top_left_point[0], top_left_point[1], top_left_point[2])
# planeSource.SetPoint2(bot_right_point[0], bot_right_point[1], bot_right_point[2])
# planeSource.SetXResolution(10)
# planeSource.SetYResolution(340)
planeSource.SetOrigin(point1[0], point1[1], point1[2])
planeSource.SetPoint1(point2[0], point2[1], point2[2])
planeSource.SetPoint2(point3[0], point3[1], point3[2])
planeSource.SetXResolution(10)
planeSource.SetYResolution(340)
planeSource.Update()
plane = planeSource.GetOutput()
# Create a mapper and actor
polygonMapper = vtk.vtkPolyDataMapper()
if vtk.VTK_MAJOR_VERSION <= 5:
polygonMapper.SetInputConnection(polygon.GetProducerPort())
else:
polygonMapper.SetInputData(plane)
polygonMapper.Update()
polygonActor = vtk.vtkActor()
polygonActor.SetMapper(polygonMapper)
polygonActor.GetProperty().SetColor([color[0], color[1], color[2]])
polygonActor.GetProperty().SetOpacity(opacity)
#actor.GetProperty().SetColor(colors->GetColor3d("Cyan").GetData());
self.ren.AddActor(polygonActor)
self.actor_list[name] = polygonActor
def call_back_plane_move_changes(self, indices):
df_changes = self.model._orientations.df.loc[np.atleast_1d(indices).astype(int)][['X', 'Y', 'Z',
'G_x', 'G_y', 'G_z', 'id']]
for index, new_values_df in df_changes.iterrows():
new_center = new_values_df[['X', 'Y', 'Z']].values
new_normal = new_values_df[['G_x', 'G_y', 'G_z']].values
new_source = vtk.vtkPlaneSource()
new_source.SetCenter(new_center)
new_source.SetNormal(new_normal)
new_source.Update()
plane1 = self.orientations_widgets[index]
# plane1.SetInputData(new_source.GetOutput())
plane1.SetNormal(new_normal)
plane1.SetCenter(new_center[0], new_center[1], new_center[2])
_color_lot = self._get_color_lot(is_faults=True, is_basement=False, index='id')
plane1.GetPlaneProperty().SetColor(mcolors.hex2color(_color_lot[int(new_values_df['id'])]))
plane1.GetHandleProperty().SetColor(mcolors.hex2color(_color_lot[int(new_values_df['id'])]))
def makeZCutter(self, bounds, scaleFactor, value):
""" create z cutter plane """
npos = self._calculateZCutterPos(value)
self.zplane = vtk.vtkPlane()
self.zplane.SetOrigin(0, 0, npos)
self.zplane.SetNormal(0, 0, 1)
self.ZCutter = vtk.vtkCutter()
self.ZCutter.SetInputConnection(self.warp.GetOutputPort())
self.ZCutter.SetCutFunction(self.zplane)
self.ZCutter.GenerateCutScalarsOff()
self.ZCutterMapper = vtk.vtkPolyDataMapper()
self.ZCutterMapper.SetInputConnection(self.ZCutter.GetOutputPort())
# visual plane to move
plane = vtk.vtkPlaneSource()
plane.SetResolution(50, 50)
plane.SetCenter(0, 0, 0)
plane.SetNormal(0, 0, 1)
tran = vtk.vtkTransform()
tran.Translate((bounds[1] - bounds[0]) / 2. - (0 - bounds[0]), (bounds[3] - bounds[2]) / 2. - (0 - bounds[2]),
npos)
tran.Scale((bounds[1] - bounds[0]), (bounds[3] - bounds[2]), 1)
tran.PostMultiply()
self.ZCutterTransform = tran
tranf = vtk.vtkTransformPolyDataFilter()
tranf.SetInputConnection(plane.GetOutputPort())
tranf.SetTransform(tran)
mapper = vtk.vtkPolyDataMapper()
mapper.SetInputConnection(tranf.GetOutputPort())
actor = vtk.vtkActor()
actor.SetMapper(mapper)
actor.GetProperty().SetColor(0.9, 0.9, 0.9)
actor.GetProperty().SetOpacity(self.opacitySlice)
return actor
def plane(pos=[0, 0, 0],
normal=[0, 0, 1],
sx=1,
sy=None,
c='g',
bc='darkgreen',
alpha=1,
legend=None,
texture=None):
'''
Draw a plane of size sx and sy oriented perpendicular to vector normal
and so that it passes through point pos.
'''
if sy is None: sy = sx
ps = vtk.vtkPlaneSource()
ps.SetResolution(1, 1)
tri = vtk.vtkTriangleFilter()
tri.SetInputConnection(ps.GetOutputPort())
tri.Update()
poly = tri.GetOutput()
axis = np.array(normal) / np.linalg.norm(normal)
theta = np.arccos(axis[2])
phi = np.arctan2(axis[1], axis[0])
t = vtk.vtkTransform()
t.PostMultiply()
t.Scale(sx, sy, 1)
t.RotateY(theta * 57.3)
t.RotateZ(phi * 57.3)
tf = vtk.vtkTransformPolyDataFilter()
vu.setInput(tf, poly)
tf.SetTransform(t)
tf.Update()
pd = tf.GetOutput()
actor = vu.makeActor(pd,
c=c,
bc=bc,
alpha=alpha,
legend=legend,
texture=texture)
actor.SetPosition(pos)
actor.PickableOff()
return actor
def make_texture_overly_object(self):
input_image = self.session.overlay_image_fname
reader = vtk.vtkJPEGReader()
reader.SetFileName(input_image)
texture = vtk.vtkTexture()
texture.SetInput(reader.GetOutput())
texture.SetInputConnection(reader.GetOutputPort())
texture.InterpolateOn()
plane = vtk.vtkPlaneSource()
plane.SetOrigin((0, 0, 0))
plane.SetPoint1(self.bounds.lat_max_distance)
plane.SetPoint2(self.bounds.long_max_distance)
planeMapper = vtk.vtkPolyDataMapper()
planeMapper.SetInputConnection(plane.GetOutputPort())
self.overlayActor = vtk.vtkActor()
self.overlayActor.SetMapper(planeMapper)
self.overlayActor.SetTexture(texture)
self.actors.append(self.overlayActor)
def add_plane(self, center, normal):
"""Add a plane to the viewer
Parameters
----------
center : array_like
The origin of the plane
normal : array_like
The normal of the plane
"""
plane = vtk.vtkPlaneSource()
plane.SetCenter(center)
plane.SetNormal(normal)
mapper = vtk.vtkPolyDataMapper()
if vtk.VTK_MAJOR_VERSION <= 5:
mapper.SetInput(plane.GetOutput())
else:
mapper.SetInputData(plane.GetOutput())
def __create_planes(self):
plane_list = []
scaling = self.settings.scaling
for x in self.settings.plane_surface_list:
actor = vtk.vtkActor()
plane = vtk.vtkPlaneSource()
plane.SetOrigin(x["origin"] * scaling)
plane.SetPoint1(x["axis1"] * scaling)
plane.SetPoint2(x["axis2"] * scaling)
mapper = vtk.vtkPolyDataMapper()
mapper.SetInput(plane.GetOutput())
actor.SetMapper(mapper)
prop = actor.GetProperty()
prop.SetColor(x["color"])
prop.SetOpacity(x["opacity"])
plane_list.append(actor)
return plane_list
def make_texture_overly_object(self):
input_image = self.session.overlay_image_fname
reader = vtk.vtkJPEGReader()
reader.SetFileName(input_image)
texture = vtk.vtkTexture()
texture.SetInput(reader.GetOutput())
texture.SetInputConnection(reader.GetOutputPort())
texture.InterpolateOn()
plane = vtk.vtkPlaneSource()
plane.SetOrigin((0, 0, 0))
plane.SetPoint1(self.bounds.lat_max_distance)
plane.SetPoint2(self.bounds.long_max_distance)
planeMapper = vtk.vtkPolyDataMapper()
planeMapper.SetInputConnection(plane.GetOutputPort())
self.overlayActor = vtk.vtkActor()
self.overlayActor.SetMapper(planeMapper)
self.overlayActor.SetTexture(texture)
self.actors.append(self.overlayActor)
def _create_planes(self):
plane_list = []
scaling = self.settings.scaling
for x in self.settings.plane_surface_list:
actor = vtk.vtkActor()
plane = vtk.vtkPlaneSource()
plane.SetOrigin(numpy.array(x['origin']) * scaling)
plane.SetPoint1(numpy.array(x['axis1']) * scaling)
plane.SetPoint2(numpy.array(x['axis2']) * scaling)
mapper = vtk.vtkPolyDataMapper()
mapper.SetInput(plane.GetOutput())
actor.SetMapper(mapper)
prop = actor.GetProperty()
prop.SetColor(x['color'])
prop.SetOpacity(x['opacity'])
plane_list.append(actor)
return plane_list
def _create_planes(self):
plane_list = []
scaling = self.settings.scaling
for x in self.settings.plane_surface_list:
actor = vtk.vtkActor()
plane = vtk.vtkPlaneSource()
plane.SetOrigin(numpy.array(x['origin']) * scaling)
plane.SetPoint1(numpy.array(x['axis1']) * scaling)
plane.SetPoint2(numpy.array(x['axis2']) * scaling)
mapper = vtk.vtkPolyDataMapper()
mapper.SetInput(plane.GetOutput())
actor.SetMapper(mapper)
prop = actor.GetProperty()
prop.SetColor(x['color'])
prop.SetOpacity(x['opacity'])
plane_list.append(actor)
return plane_list
def create_textured_plane(**kwargs):
"""
create a plane with correct size and texture it with a map
"""
image_reader = vtk.vtkPNGReader()
image_reader.SetFileName(kwargs['map'])
plane = vtk.vtkPlaneSource()
size = kwargs['size']
z_level = 0.0
plane.SetOrigin(-0.5 * size[0], -0.5 * size[1], z_level)
plane.SetPoint1(+0.5 * size[0], -0.5 * size[1], z_level)
plane.SetPoint2(-0.5 * size[0], +0.5 * size[1], z_level)
texture = vtk.vtkTexture()
texture.SetInputConnection(image_reader.GetOutputPort())
texture_plane = vtk.vtkTextureMapToPlane()
texture_plane.SetInputConnection(plane.GetOutputPort())
return texture_plane, texture
def create_textured_plane(**kwargs):
"""
create a plane with correct size and texture it with a map
"""
image_reader = vtk.vtkPNGReader()
image_reader.SetFileName(kwargs['map'])
plane = vtk.vtkPlaneSource()
size = kwargs['size']
z_level = 0.0
plane.SetOrigin(-0.5*size[0], -0.5*size[1], z_level)
plane.SetPoint1(+0.5*size[0], -0.5*size[1], z_level)
plane.SetPoint2(-0.5*size[0], +0.5*size[1], z_level)
texture = vtk.vtkTexture()
texture.SetInputConnection(image_reader.GetOutputPort())
texture_plane = vtk.vtkTextureMapToPlane()
texture_plane.SetInputConnection(plane.GetOutputPort())
return texture_plane, texture
def CreatePlaneModel(self, width, height):
# Create Instruction Transform Node if not in scene already
try:
self.instructionTransform = slicer.util.getNode(
"InstructionTransform")
except:
self.instructionTransform = slicer.util.loadTransform(
os.path.join(self.resourcePath,
'Resources/InstructionTransform.h5'))
self.instructionTransform.SetAndObserveTransformNodeID(
self.sceneTransform.GetID())
# Create Instruction Model Node if not in scene already
try:
self.instructionModelNode = slicer.util.getNode("InstructionModel")
except:
self.imagePlane = vtk.vtkPlaneSource()
self.imagePlane.SetPoint1(0, height, 0)
self.imagePlane.SetPoint2(width, 0, 0)
self.imagePlane.SetOrigin(0, 0, 0)
self.imagePlane.Update()
self.pngReader = vtk.vtkPNGReader()
#self.pngReader.SetFileName(os.path.join(self.resourcePath, 'Resources/Instructions2.png'))
self.pngReader.SetFileName(
os.path.join(self.resourcePath, 'Resources/ThreeViews3.png'))
self.pngReader.Update()
self.instructionModelNode = slicer.mrmlScene.AddNewNodeByClass(
'vtkMRMLModelNode')
self.instructionModelNode.SetName("InstructionModel")
self.instructionModelNode.CreateDefaultDisplayNodes()
self.instructionModelNode.SetAndObservePolyData(
self.imagePlane.GetOutput())
self.instructionModelNode.SetAndObserveTransformNodeID(
self.instructionTransform.GetID())
self.instructionModelDisplay = self.instructionModelNode.GetDisplayNode(
)
self.instructionModelDisplay.SetTextureImageDataConnection(
self.pngReader.GetOutputPort())
self.instructionModelDisplay.VisibilityOn()
self.instructionModelDisplay.SetFrontfaceCulling(False)
self.instructionModelDisplay.SetBackfaceCulling(False)
def grid(pos=[0, 0, 0],
normal=[0, 0, 1],
sx=1,
sy=1,
c='g',
bc='darkgreen',
lw=1,
alpha=1,
legend=None,
resx=10,
resy=10):
'''Return a grid plane'''
ps = vtk.vtkPlaneSource()
ps.SetResolution(resx, resy)
ps.Update()
poly0 = ps.GetOutput()
t0 = vtk.vtkTransform()
t0.Scale(sx, sy, 1)
tf0 = vtk.vtkTransformPolyDataFilter()
vu.setInput(tf0, poly0)
tf0.SetTransform(t0)
tf0.Update()
poly = tf0.GetOutput()
axis = np.array(normal) / np.linalg.norm(normal)
theta = np.arccos(axis[2])
phi = np.arctan2(axis[1], axis[0])
t = vtk.vtkTransform()
t.PostMultiply()
t.RotateY(theta * 57.3)
t.RotateZ(phi * 57.3)
tf = vtk.vtkTransformPolyDataFilter()
vu.setInput(tf, poly)
tf.SetTransform(t)
tf.Update()
pd = tf.GetOutput()
actor = vu.makeActor(pd, c=c, bc=bc, alpha=alpha, legend=legend)
actor.GetProperty().SetRepresentationToWireframe()
actor.GetProperty().SetLineWidth(lw)
actor.SetPosition(pos)
actor.PickableOff()
return actor
def create_ground_frame(size=300):
planeSource = vtk.vtkPlaneSource()
planeSource.SetXResolution(10)
planeSource.SetYResolution(10)
planeSource.SetCenter(0.0, 0.0, 0.0)
planeSource.SetNormal(0.0, 0.0, 1.0)
planeSource.Update()
scaled_plane = scale_object(planeSource, size)
# Create a mapper and actor
mapper = vtk.vtkPolyDataMapper()
mapper.SetInputData(scaled_plane.GetOutput())
actor = vtk.vtkActor()
actor.SetMapper(mapper)
actor.GetProperty().EdgeVisibilityOn()
actor.GetProperty().LightingOff()
actor.GetProperty().SetOpacity(0.3)
actor.GetProperty().SetColor([255, 0, 0])
return actor
def DrawPlan(renderer,color,center,normal,scaleFactor,oldActor=None):
# Create a plane
planeSource = vtk.vtkPlaneSource()
planeSource.SetCenter(0,0,0)
planeSource.SetNormal(normal)
planeSource.Update()
# Scale plane
scaleTransform=vtk.vtkTransform()
scaleTransform.Scale((scaleFactor))
scaleFilter = vtk.vtkTransformPolyDataFilter()
scaleFilter.SetInputConnection(planeSource.GetOutputPort())
scaleFilter.SetTransform(scaleTransform)
scaleFilter.Update()
# Translate plane
translation = vtk.vtkTransform()
translation.Translate(center)
transformFilter = vtk.vtkTransformPolyDataFilter()
transformFilter.SetInputConnection(scaleFilter.GetOutputPort())
transformFilter.SetTransform(translation)
transformFilter.Update()
plane = transformFilter.GetOutput()
# Create a mapper and actor
mapper = vtk.vtkPolyDataMapper()
mapper.SetInputData(plane)
actor = vtk.vtkActor()
actor.SetMapper(mapper)
#actor.GetProperty().SetRepresentationToWireframe() #plan unfilled
actor.GetProperty().SetColor(color)
actor.GetProperty().SetOpacity(0.5)
if oldActor != None :
renderer.RemoveActor(oldActor)
renderer.AddActor(actor)
return actor
def __init__(self, renderer, parent, screenDistance, width, height, isActiveCamera = False):
'''
Initialize the CameraScreen model.
If you are going to stream data to it, set isActiveCamera to true in the constructor parameters and pass jpeg data to the update method.
'''
# Call the parent constructor
super(CameraScreen,self).__init__(renderer, parent)
# Create a plane for the camera
# Ref: http://www.vtk.org/doc/nightly/html/classvtkPlaneSource.html
planeSource = vtk.vtkPlaneSource()
# Defaults work for this, so just push it out a bit
#planeSource.Push(screenDistance)
# Transform scale it to the right size
trans = vtk.vtkTransform()
trans.Scale(width, height, 1)
trans.Translate(0, 0, screenDistance)
trans.RotateY(180) # Effectively flipping the UV (texture) mapping so that the video isn't left/right flipped
transF = vtk.vtkTransformPolyDataFilter()
transF.SetInputConnection(planeSource.GetOutputPort())
transF.SetTransform(trans)
# Create a test picture and assign it to the screen for now...
# Ref: http://vtk.org/gitweb?p=VTK.git;a=blob;f=Examples/Rendering/Python/TPlane.py
if not isActiveCamera:
self.__textReader = vtk.vtkPNGReader()
self.__textReader.SetFileName("../scene/media/semisortedcameralogo.png")
else:
self.__textReader = vtk.vtkJPEGReader()
self.cameraVtkTexture = vtk.vtkTexture()
self.cameraVtkTexture.SetInputConnection(self.__textReader.GetOutputPort())
self.cameraVtkTexture.InterpolateOn()
# Finally assign the mapper and the actor
planeMapper = vtk.vtkPolyDataMapper()
planeMapper.SetInputConnection(transF.GetOutputPort())
self.vtkActor.SetMapper(planeMapper)
self.vtkActor.SetTexture(self.cameraVtkTexture)
def TextureMappedPlane(self, obj, event):
# use dummy image data here
e = vtk.vtkImageEllipsoidSource()
scene = slicer.mrmlScene
# Create model node
model = slicer.vtkMRMLModelNode()
model.SetScene(scene)
model.SetName(scene.GenerateUniqueName("2DImageModel"))
planeSource = vtk.vtkPlaneSource()
model.SetAndObservePolyData(planeSource.GetOutput())
# Create display node
modelDisplay = slicer.vtkMRMLModelDisplayNode()
modelDisplay.SetColor(1, 1, 0) # yellow
# modelDisplay.SetBackfaceCulling(0)
modelDisplay.SetScene(scene)
scene.AddNode(modelDisplay)
model.SetAndObserveDisplayNodeID(modelDisplay.GetID())
modelDisplay.SetSliceIntersectionVisibility(True)
modelDisplay.SetVisibility(True)
# Add to scene
modelDisplay.SetTextureImageDataConnection(e.GetOutputPort())
# modelDisplay.SetInputPolyDataConnection(model.GetPolyDataConnection())
scene.AddNode(model)
transform = slicer.vtkMRMLLinearTransformNode()
scene.AddNode(transform)
model.SetAndObserveTransformNodeID(transform.GetID())
vTransform = vtk.vtkTransform()
vTransform.Scale(50, 50, 50)
vTransform.RotateX(30)
# transform.SetAndObserveMatrixTransformToParent(vTransform.GetMatrix())
transform.SetMatrixTransformToParent(vTransform.GetMatrix())
def _createOrthoPipelineForNewIPW(self, ipw):
"""This will create and append all the necessary constructs for a
single new layer (ipw) to the self._orthoPipeline.
Make sure you only call this method if the orthoView exists!
After having done this, you still need to call _syncOrthoView() or
_resetOrthoView() if you've added a new primary.
"""
_ps = vtk.vtkPlaneSource()
_pa = vtk.vtkActor()
_tm2p = vtk.vtkTextureMapToPlane()
self._orthoPipeline.append({
'planeSource': _ps,
'planeActor': _pa,
'textureMapToPlane': _tm2p
})
_tm2p.AutomaticPlaneGenerationOff()
_tm2p.SetInput(_ps.GetOutput())
mapper = vtk.vtkPolyDataMapper()
mapper.SetInput(_tm2p.GetOutput())
_pa.SetMapper(mapper)
otherTexture = ipw.GetTexture()
# we don't just use the texture, else VTK goes mad re-uploading
# the same texture unnecessarily... let's just make use of the
# same input, we get much more effective use of the
# host->GPU bus
texture = vtk.vtkTexture()
texture.SetInterpolate(otherTexture.GetInterpolate())
texture.SetQuality(otherTexture.GetQuality())
texture.MapColorScalarsThroughLookupTableOff()
texture.RepeatOff()
texture.SetInput(otherTexture.GetInput())
_pa.SetTexture(texture)
self._renderer.AddActor(_pa)
def Create(self):
self.plane_widget = plane_widget = vtk.vtkImagePlaneWidget()
plane_widget.SetInputData(self.img)
plane_widget.SetPlaneOrientationToXAxes()
#plane_widget.SetResliceInterpolateToLinear()
plane_widget.TextureVisibilityOff()
#Set left mouse button to move and rotate plane
plane_widget.SetLeftButtonAction(1)
#SetColor margin to green
margin_property = plane_widget.GetMarginProperty()
margin_property.SetColor(0, 0.8, 0)
#Disable cross
cursor_property = plane_widget.GetCursorProperty()
cursor_property.SetOpacity(0)
self.plane_source = plane_source = vtk.vtkPlaneSource()
plane_source.SetOrigin(plane_widget.GetOrigin())
plane_source.SetPoint1(plane_widget.GetPoint1())
plane_source.SetPoint2(plane_widget.GetPoint2())
plane_source.SetNormal(plane_widget.GetNormal())
plane_mapper = self.plane_mapper = vtk.vtkPolyDataMapper()
plane_mapper.SetInputData(plane_source.GetOutput())
self.plane_actor = plane_actor = vtk.vtkActor()
plane_actor.SetMapper(plane_mapper)
plane_actor.GetProperty().BackfaceCullingOn()
plane_actor.GetProperty().SetOpacity(0)
plane_widget.AddObserver("InteractionEvent", self.Update)
Publisher.sendMessage('AppendActor', actor=self.plane_actor)
Publisher.sendMessage('Set Widget Interactor',
widget=self.plane_widget)
plane_actor.SetVisibility(1)
plane_widget.On()
self.plane = plane = vtk.vtkPlane()
plane.SetNormal(self.plane_source.GetNormal())
plane.SetOrigin(self.plane_source.GetOrigin())
self.volume_mapper.AddClippingPlane(plane)
#Storage First Position
self.origin = plane_widget.GetOrigin()
self.p1 = plane_widget.GetPoint1()
self.p2 = plane_widget.GetPoint2()
self.normal = plane_widget.GetNormal()
def _createOrthoPipelineForNewIPW(self, ipw):
"""This will create and append all the necessary constructs for a
single new layer (ipw) to the self._orthoPipeline.
Make sure you only call this method if the orthoView exists!
After having done this, you still need to call _syncOrthoView() or
_resetOrthoView() if you've added a new primary.
"""
_ps = vtk.vtkPlaneSource()
_pa = vtk.vtkActor()
_tm2p = vtk.vtkTextureMapToPlane()
self._orthoPipeline.append(
{'planeSource' : _ps,
'planeActor' : _pa,
'textureMapToPlane': _tm2p})
_tm2p.AutomaticPlaneGenerationOff()
_tm2p.SetInput(_ps.GetOutput())
mapper = vtk.vtkPolyDataMapper()
mapper.SetInput(_tm2p.GetOutput())
_pa.SetMapper(mapper)
otherTexture = ipw.GetTexture()
# we don't just use the texture, else VTK goes mad re-uploading
# the same texture unnecessarily... let's just make use of the
# same input, we get much more effective use of the
# host->GPU bus
texture = vtk.vtkTexture()
texture.SetInterpolate(otherTexture.GetInterpolate())
texture.SetQuality(otherTexture.GetQuality())
texture.MapColorScalarsThroughLookupTableOff()
texture.RepeatOff()
texture.SetInput(otherTexture.GetInput())
_pa.SetTexture(texture)
self._renderer.AddActor(_pa)
def Plane(pos=(0, 0, 0),
normal=(0, 0, 1),
sx=1,
sy=None,
c="g",
bc="darkgreen",
alpha=1,
texture=None):
"""
Draw a plane of size `sx` and `sy` oriented perpendicular to vector `normal`
and so that it passes through point `pos`.
|Plane|
"""
if sy is None:
sy = sx
ps = vtk.vtkPlaneSource()
ps.SetResolution(1, 1)
tri = vtk.vtkTriangleFilter()
tri.SetInputConnection(ps.GetOutputPort())
tri.Update()
poly = tri.GetOutput()
axis = np.array(normal) / np.linalg.norm(normal)
theta = np.arccos(axis[2])
phi = np.arctan2(axis[1], axis[0])
t = vtk.vtkTransform()
t.PostMultiply()
t.Scale(sx, sy, 1)
t.RotateY(np.rad2deg(theta))
t.RotateZ(np.rad2deg(phi))
tf = vtk.vtkTransformPolyDataFilter()
tf.SetInputData(poly)
tf.SetTransform(t)
tf.Update()
pd = tf.GetOutput()
actor = Actor(pd, c=c, bc=bc, alpha=alpha, texture=texture)
actor.SetPosition(pos)
settings.collectable_actors.append(actor)
return actor
def create_plane(self, props, texture):
"""Create flat plane"""
# Pull and scale dimensions
SIZE = np.asarray(props["Size"])
POS = np.asarray(props["Translate"])
# Create texture reader
reader = vtk.vtkJPEGReader()
reader.SetFileName(texture)
# Create texture object
texture = vtk.vtkTexture()
texture.SetInputConnection(reader.GetOutputPort())
texture.InterpolateOn()
# Create plane model
plane = vtk.vtkPlaneSource()
plane.SetResolution(1, 1)
plane.SetPoint1(0, SIZE[1], 0)
plane.SetPoint2(SIZE[0], 0, 0)
# Translate to centre
transP = vtk.vtkTransform()
transP.Translate(POS[0], POS[1], POS[2])
tpd = vtk.vtkTransformPolyDataFilter()
tpd.SetInputConnection(plane.GetOutputPort())
tpd.SetTransform(transP)
mapper = vtk.vtkPolyDataMapper()
mapper.SetInputConnection(tpd.GetOutputPort())
actor = vtk.vtkActor()
actor.SetMapper(mapper)
actor.SetTexture(texture)
actor.GetProperty().SetAmbient(1.0)
actor.GetProperty().SetSpecular(.5)
actor.GetProperty().SetSpecularPower(5.0)
actor.GetProperty().SetDiffuse(0.2)
return actor
def Create(self):
self.plane_widget = plane_widget = vtk.vtkImagePlaneWidget()
plane_widget.SetInputData(self.img)
plane_widget.SetPlaneOrientationToXAxes()
#plane_widget.SetResliceInterpolateToLinear()
plane_widget.TextureVisibilityOff()
#Set left mouse button to move and rotate plane
plane_widget.SetLeftButtonAction(1)
#SetColor margin to green
margin_property = plane_widget.GetMarginProperty()
margin_property.SetColor(0,0.8,0)
#Disable cross
cursor_property = plane_widget.GetCursorProperty()
cursor_property.SetOpacity(0)
self.plane_source = plane_source = vtk.vtkPlaneSource()
plane_source.SetOrigin(plane_widget.GetOrigin())
plane_source.SetPoint1(plane_widget.GetPoint1())
plane_source.SetPoint2(plane_widget.GetPoint2())
plane_source.SetNormal(plane_widget.GetNormal())
plane_mapper = self.plane_mapper = vtk.vtkPolyDataMapper()
plane_mapper.SetInputData(plane_source.GetOutput())
self.plane_actor = plane_actor = vtk.vtkActor()
plane_actor.SetMapper(plane_mapper)
plane_actor.GetProperty().BackfaceCullingOn()
plane_actor.GetProperty().SetOpacity(0)
plane_widget.AddObserver("InteractionEvent", self.Update)
Publisher.sendMessage('AppendActor', self.plane_actor)
Publisher.sendMessage('Set Widget Interactor', self.plane_widget)
plane_actor.SetVisibility(1)
plane_widget.On()
self.plane = plane = vtk.vtkPlane()
plane.SetNormal(self.plane_source.GetNormal())
plane.SetOrigin(self.plane_source.GetOrigin())
self.volume_mapper.AddClippingPlane(plane)
#Storage First Position
self.origin = plane_widget.GetOrigin()
self.p1 = plane_widget.GetPoint1()
self.p2 = plane_widget.GetPoint2()
self.normal = plane_widget.GetNormal()
def CreateGround(self, size=4000):
# create plane source
plane = vtk.vtkPlaneSource()
plane.SetXResolution(100)
plane.SetYResolution(100)
plane.SetCenter(0.3, 0.3, 0)
plane.SetNormal(0, 0, 1)
# mapper
mapper = vtk.vtkPolyDataMapper()
mapper.SetInputConnection(plane.GetOutputPort())
# actor
actor = vtk.vtkActor()
actor.SetMapper(mapper)
actor.GetProperty().SetRepresentationToWireframe()
actor.GetProperty().SetColor(211 / 255, 211 / 255, 211 / 255)
transform = vtk.vtkTransform()
transform.Scale(size, size, 1)
actor.SetUserTransform(transform)
return actor
def main():
colors = vtk.vtkNamedColors()
# Set the background color.
colors.SetColor('BkgColor', [26, 51, 77, 255])
# Create a plane
planeSource = vtk.vtkPlaneSource()
planeSource.SetCenter(1.0, 0.0, 0.0)
planeSource.SetNormal(1.0, 0.0, 1.0)
planeSource.Update()
plane = planeSource.GetOutput()
# Create a mapper and actor
mapper = vtk.vtkPolyDataMapper()
mapper.SetInputData(plane)
actor = vtk.vtkActor()
actor.SetMapper(mapper)
actor.GetProperty().SetColor(colors.GetColor3d('Banana'))
# Create a renderer, render window and interactor
renderer = vtk.vtkRenderer()
renderWindow = vtk.vtkRenderWindow()
renderWindow.SetWindowName('Plane')
renderWindow.AddRenderer(renderer)
renderWindowInteractor = vtk.vtkRenderWindowInteractor()
renderWindowInteractor.SetRenderWindow(renderWindow)
# Add the actors to the scene
renderer.AddActor(actor)
renderer.SetBackground(colors.GetColor3d('BkgColor'))
# Render and interact
renderWindow.Render()
renderWindowInteractor.Start()
def main(vector_file, magnitude_file):
num_critical_points = 6
CriticalPoints = vtk.vtkPoints()
CriticalPoints.InsertNextPoint(35, 14, 20)
CriticalPoints.InsertNextPoint(55, 15, 20)
CriticalPoints.InsertNextPoint(65, 45, 19)
CriticalPoints.InsertNextPoint(45, 44.8, 20)
CriticalPoints.InsertNextPoint(20, 29.7, 19.8)
CriticalPoints.InsertNextPoint(10, 32.2, 16.1)
ColorRange = vtk.vtkLookupTable()
ColorRange.SetTableRange(0, 1)
ColorRange.SetHueRange(0, 1)
ColorRange.SetSaturationRange(1, 1)
ColorRange.SetAlphaRange(0.3, 0.5)
ColorRange.Build()
reader = vtk.vtkStructuredPointsReader()
reader.SetFileName(vector_file)
reader.Update()
mags = reader.GetOutput()
range1 = mags.GetScalarRange()
v0 = range1[0]
v1 = range1[1]
reader_magnitude = vtk.vtkStructuredPointsReader()
reader_magnitude.SetFileName(magnitude_file)
reader_magnitude.Update()
# All entities initialized equal to number of critical points
sphere1, stream1, scalarSurface1, tube1, dataMapper1, dataActor1, criticalMarker1, criticalMapper1, criticalActor1, probe1, mask1, glyph1, glyphMapper1, glyphActor1, plane1 = (
[],
[],
[],
[],
[],
[],
[],
[],
[],
[],
[],
[],
[],
[],
[],
)
for i in range(0, num_critical_points):
sphere1.append(vtk.vtkSphereSource())
stream1.append(vtk.vtkStreamLine())
scalarSurface1.append(vtk.vtkRuledSurfaceFilter())
tube1.append(vtk.vtkTubeFilter())
dataMapper1.append(vtk.vtkPolyDataMapper())
dataActor1.append(vtk.vtkActor())
criticalMarker1.append(vtk.vtkSphereSource())
criticalMapper1.append(vtk.vtkPolyDataMapper())
criticalActor1.append(vtk.vtkActor())
probe1.append(vtk.vtkProbeFilter())
mask1.append(vtk.vtkMaskPoints())
glyph1.append(vtk.vtkGlyph3D())
glyphMapper1.append(vtk.vtkPolyDataMapper())
glyphActor1.append(vtk.vtkActor())
plane1.append(vtk.vtkPlaneSource())
integ = vtk.vtkRungeKutta4()
cone = vtk.vtkConeSource()
cone.SetResolution(8)
cone.SetHeight(1.0)
cone.SetRadius(0.2)
transform = vtk.vtkTransform()
transform.Translate(0, 0, 0)
transformFilter = vtk.vtkTransformPolyDataFilter()
transformFilter.SetInput(cone.GetOutput())
transformFilter.SetTransform(transform)
outline = vtk.vtkOutlineFilter()
outline.SetInput(reader.GetOutput())
outlineMapper = vtk.vtkPolyDataMapper()
outlineMapper.SetInput(outline.GetOutput())
outlineActor = vtk.vtkActor()
outlineActor.SetMapper(outlineMapper)
outlineActor.GetProperty().SetColor(1, 1, 1)
bar = vtk.vtkScalarBarActor()
bar.SetLookupTable(ColorRange)
renderer = vtk.vtkRenderer()
for i in range(0, num_critical_points):
sphere1[i].SetRadius(2)
sphere1[i].SetCenter(
CriticalPoints.GetPoint(i)[0], CriticalPoints.GetPoint(i)[1], CriticalPoints.GetPoint(i)[2]
)
sphere1[i].SetThetaResolution(1)
stream1[i].SetInput(reader.GetOutput())
stream1[i].SetSource(sphere1[i].GetOutput())
stream1[i].SetIntegrator(integ)
stream1[i].SetMaximumPropagationTime(500)
stream1[i].SetIntegrationStepLength(0.1)
stream1[i].SetIntegrationDirectionToIntegrateBothDirections()
stream1[i].SetStepLength(0.1)
scalarSurface1[i].SetInput(stream1[i].GetOutput())
scalarSurface1[i].SetOffset(0)
scalarSurface1[i].SetOnRatio(2)
scalarSurface1[i].PassLinesOn()
scalarSurface1[i].SetRuledModeToPointWalk()
scalarSurface1[i].SetDistanceFactor(50)
tube1[i].SetInput(scalarSurface1[i].GetOutput())
tube1[i].SetRadius(0.1)
tube1[i].SetNumberOfSides(6)
dataMapper1[i].SetInput(tube1[i].GetOutput())
dataMapper1[i].SetScalarRange(v0, v1)
dataMapper1[i].SetLookupTable(ColorRange)
dataActor1[i].SetMapper(dataMapper1[i])
# renderer.AddActor(dataActor1[i])
criticalMarker1[i].SetRadius(1.0)
criticalMarker1[i].SetCenter(
CriticalPoints.GetPoint(i)[0], CriticalPoints.GetPoint(i)[1], CriticalPoints.GetPoint(i)[2]
)
criticalMarker1[i].SetThetaResolution(10)
criticalMapper1[i].SetInput(criticalMarker1[i].GetOutput())
criticalActor1[i].SetMapper(criticalMapper1[i])
criticalActor1[i].GetProperty().SetColor(1, 1, 0)
criticalActor1[i].GetProperty().SetOpacity(0.5)
# renderer.AddActor(criticalActor1[i])
probe1[i].SetInput(stream1[i].GetOutput())
probe1[i].SetSource(reader.GetOutput())
mask1[i].SetInput(probe1[i].GetOutput())
mask1[i].SetOnRatio(60)
mask1[i].RandomModeOn()
glyph1[i].SetInput(mask1[i].GetOutput())
glyph1[i].SetSource(transformFilter.GetOutput())
glyph1[i].SetScaleModeToScaleByVector()
glyph1[i].SetScaleFactor(2)
glyph1[i].SetVectorModeToUseVector()
glyph1[i].SetColorModeToColorByVector()
glyphMapper1[i].SetInput(glyph1[i].GetOutput())
glyphMapper1[i].SetLookupTable(ColorRange)
glyphActor1[i].SetMapper(glyphMapper1[i])
# renderer.AddActor(glyphActor1[i])
# removeActors1(renderer, dataActor, criticalActor, glyphActor, dataActor1, criticalActor1, glyphActor1)
mags = reader.GetOutput()
bounds = mags.GetBounds()
x0 = bounds[0]
x1 = bounds[1]
y0 = bounds[2]
y1 = bounds[3]
z0 = bounds[4]
z1 = bounds[5]
range1 = mags.GetScalarRange()
v0 = range1[0]
v1 = range1[1]
plane1[0].SetOrigin(x0, y0, z0)
plane1[0].SetPoint1(x0, y1, z0)
plane1[0].SetPoint2(x0, y0, z1)
plane1[1].SetOrigin(x0, y0, z0)
plane1[1].SetPoint1(x0, y1, z0)
plane1[1].SetPoint2(x1, y0, z0)
plane1[2].SetOrigin(x0, y0, z0)
plane1[2].SetPoint1(x0, y0, z1)
plane1[2].SetPoint2(x1, y0, z0)
plane1[3].SetOrigin(x1, y1, z1)
plane1[3].SetPoint1(x1, y1, z0)
plane1[3].SetPoint2(x1, y0, z1)
plane1[4].SetOrigin(x1, y1, z1)
plane1[4].SetPoint1(x0, y1, z1)
plane1[4].SetPoint2(x1, y1, z0)
plane1[5].SetOrigin(x1, y1, z1)
plane1[5].SetPoint1(x0, y1, z1)
plane1[5].SetPoint2(x1, y1, z0)
for i in range(0, num_critical_points):
plane1[i].SetResolution(5, 5)
stream1[i].SetSource(plane1[i].GetOutput())
renderer.AddActor(dataActor1[i])
renderer.AddActor(glyphActor1[i])
glyph1[i].SetScaleFactor(4)
renderer.AddActor(bar)
renderer.AddActor(outlineActor)
for i in range(0, num_critical_points):
renderer.AddActor(criticalActor1[i])
renderer_window = vtk.vtkRenderWindow()
renderer_window.AddRenderer(renderer)
renderer_window.SetSize(512, 512)
interactor = vtk.vtkRenderWindowInteractor()
interactor.SetRenderWindow(renderer_window)
style = vtk.vtkInteractorStyleTrackballCamera()
interactor.SetInteractorStyle(style)
renderer.AddActor(bar)
renderer.AddActor(outlineActor)
renderer_window.Render()
interactor.Start()
def init_planes(self):
self.vtkPlanes = vtk.vtkPlaneSource()
plane_mapper = vtk.vtkPolyDataMapper()
plane_mapper.SetInput(self.vtkPlanes.GetOutput())
self.plane_vtkActor = vtk.vtkActor()
self.plane_vtkActor.SetMapper(plane_mapper)
import vtk # create a rendering window and renderer ren = vtk.vtkRenderer() renWin = vtk.vtkRenderWindow() renWin.AddRenderer(ren) # create a renderwindowinteractor iren = vtk.vtkRenderWindowInteractor() iren.SetRenderWindow(renWin) # create source source = vtk.vtkPlaneSource() source.SetCenter(1,0,0) source.SetNormal(1,2,3) # mapper mapper = vtk.vtkPolyDataMapper() mapper.SetInput(source.GetOutput()) # actor actor = vtk.vtkActor() actor.SetMapper(mapper) # assign actor to the renderer ren.AddActor(actor) # enable user interface interactor iren.Initialize() renWin.Render() iren.Start()
