def createNewModelNode(self, polyData, nodeName):
modelNode = slicer.mrmlScene.AddNode(slicer.vtkMRMLModelNode())
modelNode.SetName(nodeName)
modelNode.CreateDefaultDisplayNodes()
modelNode.SetAndObservePolyData(polyData)
return modelNode
def lineModel(self, scene, point1, point2, name, color):
""" Create a line to reflect the puncture path"""
#Line mode source
line = vtk.vtkLineSource()
line.SetPoint1(point1) #(point1[0][0], point1[0][1], point1[0][2])
line.SetPoint2(point2) #(point2[0][0], point2[0][1], point2[0][2])
# Create model node
lineModel = slicer.vtkMRMLModelNode()
lineModel.SetScene(scene)
lineModel.SetName(name)
lineModel.SetAndObservePolyData(line.GetOutput())
# Create display node
lineModelDisplay = slicer.vtkMRMLModelDisplayNode()
lineModelDisplay.SetColor(color)
lineModelDisplay.SetScene(scene)
scene.AddNode(lineModelDisplay)
lineModel.SetAndObserveDisplayNodeID(lineModelDisplay.GetID())
lineModelDisplay.SetInputPolyDataConnection(line.GetOutputPort())
scene.AddNode(lineModel)
return line
def onApply(self):
# Allow users revert to this state by clicking Undo
self.scriptedEffect.saveStateForUndo()
inputVolume = self.scriptedEffect.parameterSetNode(
).GetMasterVolumeNode()
outputVolume = self.outputVolumeSelector.currentNode()
maskOutsideSurface = self.maskOutsideSurfaceCheckBox.checked
fillValue = self.fillValueEdit.value
segmentID = self.scriptedEffect.parameterSetNode(
).GetSelectedSegmentID()
segmentationNode = self.scriptedEffect.parameterSetNode(
).GetSegmentationNode()
maskingModel = slicer.vtkMRMLModelNode()
outputPolyData = vtk.vtkPolyData()
slicer.vtkSlicerSegmentationsModuleLogic.GetSegmentClosedSurfaceRepresentation(
segmentationNode, segmentID, outputPolyData)
maskingModel.SetAndObservePolyData(outputPolyData)
self.maskVolumeWithSegment(inputVolume, maskingModel,
maskOutsideSurface, fillValue, outputVolume)
qt.QApplication.restoreOverrideCursor()
#De-select effect
self.scriptedEffect.selectEffect("")
def merge_models(self, modelA, modelB, modelC):
scene = slicer.mrmlScene
# Create model node
mergedModel = slicer.vtkMRMLModelNode()
mergedModel.SetScene(scene)
mergedModel.SetName(modelName)
dnode = slicer.vtkMRMLModelDisplayNode()
snode = slicer.vtkMRMLModelStorageNode()
mergedModel.SetAndObserveDisplayNodeID(dnode.GetID())
mergedModel.SetAndObserveStorageNodeID(snode.GetID())
scene.AddNode(dnode)
scene.AddNode(snode)
scene.AddNode(mergedModel)
# Get transformed poly data from input models
modelA_polydata = self.getTransformedPolyDataFromModel(self.modelA)
modelB_polydata = self.getTransformedPolyDataFromModel(self.modelB)
modelC_polydata = self.getTransformedPolyDataFromModel(self.modelC)
# Append poly data
appendFilter = vtk.vtkAppendPolyData()
appendFilter.AddInputData(modelA_polydata)
appendFilter.AddInputData(modelB_polydata)
appendFilter.AddInputData(modelC_polydata)
appendFilter.Update();
# Output
mergedModel.SetAndObservePolyData(appendFilter.GetOutput());
mergedModel.SetAndObserveDisplayNodeID(dnode.GetID());
return mergedModel
def copyAndHardenModel(self,originalModel):
# copy model
outputModel = slicer.vtkMRMLModelNode()
fullPolyData = originalModel.GetPolyData()
outputModel.SetAndObservePolyData(fullPolyData)
md2 = slicer.vtkMRMLModelDisplayNode()
slicer.mrmlScene.AddNode(outputModel)
slicer.mrmlScene.AddNode(md2)
outputModel.SetAndObserveDisplayNodeID(md2.GetID())
md2.SetVisibility(0)
# apply transforms tree to copied model
parent_transform = originalModel.GetParentTransformNode()
try:
t = slicer.util.getNode('DefinedTransform')
identityTransform = vtk.vtkMatrix4x4()
t.SetMatrixTransformToParent(identityTransform)
except:
t=slicer.vtkMRMLLinearTransformNode()
t.SetName('DefinedTransform')
slicer.mrmlScene.AddNode(t)
t.SetAndObserveTransformNodeID(parent_transform.GetID())
t.HardenTransform()
outputModel.SetAndObserveTransformNodeID(t.GetID())
outputModel.HardenTransform()
return outputModel,t
def createSampleModelVolume(self, name, color, volumeNode=None):
if volumeNode:
self.assertTrue( volumeNode.IsA('vtkMRMLScalarVolumeNode') )
bounds = [0.0, 0.0, 0.0, 0.0, 0.0, 0.0]
volumeNode.GetRASBounds(bounds)
x = (bounds[0] + bounds[1])/2
y = (bounds[2] + bounds[3])/2
z = (bounds[4] + bounds[5])/2
radius = min(bounds[1]-bounds[0],bounds[3]-bounds[2],bounds[5]-bounds[4]) / 3.0
else:
radius = 50
x = y = z = 0
# Taken from: http://www.na-mic.org/Bug/view.php?id=1536
sphere = vtk.vtkSphereSource()
sphere.SetCenter(x, y, z)
sphere.SetRadius(radius)
modelNode = slicer.vtkMRMLModelNode()
modelNode.SetName(name)
modelNode = slicer.mrmlScene.AddNode(modelNode)
if vtk.VTK_MAJOR_VERSION <= 5:
modelNode.SetAndObservePolyData(sphere.GetOutput())
else:
modelNode.SetPolyDataConnection(sphere.GetOutputPort())
modelNode.SetHideFromEditors(0)
displayNode = slicer.vtkMRMLModelDisplayNode()
slicer.mrmlScene.AddNode(displayNode)
displayNode.SliceIntersectionVisibilityOn()
displayNode.VisibilityOn()
displayNode.SetColor(color[0], color[1], color[2])
modelNode.SetAndObserveDisplayNodeID(displayNode.GetID())
return modelNode
def arrowModel(self, scene, point1, point2, name, color):
""" Create a line to reflect the puncture path"""
#Line mode source
arrow = vtk.vtkLineSource()
#arrow.SetShaftRadius(0.01)
#arrow.SetTipLength(.9)
arrow.SetPoint1(point1) #(point1[0][0], point1[0][1], point1[0][2])
arrow.SetPoint2(point2) #(point2[0][0], point2[0][1], point2[0][2])
tubes = vtk.vtkTubeFilter()
tubes.SetInputConnection(arrow.GetOutputPort())
tubes.SetRadius(0.8)
tubes.SetNumberOfSides(6)
# Create model node
arrowModel = slicer.vtkMRMLModelNode()
arrowModel.SetScene(scene)
arrowModel.SetName(name)
arrowModel.SetAndObservePolyData(tubes.GetOutput())
# Create display node
arrowModelDisplay = slicer.vtkMRMLModelDisplayNode()
arrowModelDisplay.SetColor(color)
arrowModelDisplay.SetScene(scene)
scene.AddNode(arrowModelDisplay)
arrowModel.SetAndObserveDisplayNodeID(arrowModelDisplay.GetID())
arrowModelDisplay.SetInputPolyDataConnection(tubes.GetOutputPort())
scene.AddNode(arrowModel)
return arrow
def onApplyButtonClicked(self):
"""
Real algorithm should be in class VascularWallLogic.
"""
logging.info("applyButton is clicked.")
# Create models for sphere
self.sphere = vtk.vtkSphereSource()
# Model node
model = slicer.vtkMRMLModelNode()
model.SetAndObservePolyData(self.sphere.GetOutput())
# Display node
self.modelDisplay = slicer.vtkMRMLModelDisplayNode()
self.modelDisplay.SetSliceIntersectionVisibility(True)
self.modelDisplay.SetVisibility(self.showCheckBox.isChecked())
self.modelDisplay.SetOpacity(0.5)
self.modelDisplay.SetRepresentation(1)
slicer.mrmlScene.AddNode(self.modelDisplay)
model.SetAndObserveDisplayNodeID(self.modelDisplay.GetID())
# Add to scene
self.modelDisplay.SetInputPolyDataConnection(
model.GetPolyDataConnection())
slicer.mrmlScene.AddNode(model)
# Callback
self.UpdateSphere(0, 0)
self.rulerSelector.currentNode().AddObserver(
'ModifiedEvent', self.UpdateSphere)
def createNeedleModel(self, toolname):
modelNode = slicer.vtkMRMLModelNode()
# create needle model module logic
createModelLogic = slicer.modules.createmodels.logic()
#modelDisplayNode = slicer.vtkMRMLModelDisplayNode()
#modelDisplayNode.SetName(modelNode.GetName())
# create a RFA probe needle
if 'RFAProbe' in toolname:
modelNode = createModelLogic.CreateNeedle(150, True, 0, 1)
modelNode.SetName(toolname)
modelDisplayNode = modelNode.GetDisplayNode()
modelDisplayNode.SetColor([0, 0, 1]) # Blue
# slicer.mrmlScene.AddNode(modelDisplayNode)
# modelNode.SetAndObserveDisplayNodeID(modelDisplayNode.GetID())
elif 'Introducer' in toolname:
modelNode = createModelLogic.CreateNeedle(100, True, 0, 1)
modelNode.SetName(toolname)
modelDisplayNode = modelNode.GetDisplayNode()
modelDisplayNode.SetColor([1, 0, 0]) # Red
# slicer.mrmlScene.AddNode(modelDisplayNode)
# modelNode.SetAndObserveDisplayNodeID(modelDisplayNode.GetID())
else:
modelNode = createModelLogic.CreateNeedle(100, True, 1, 1)
modelNode.SetName(toolname)
modelDisplayNode = modelNode.GetDisplayNode()
modelDisplayNode.SetColor([0, 1, 0])
return modelNode
def createSampleModelNode(self, name, color, volumeNode=None):
if volumeNode:
self.assertTrue(volumeNode.IsA('vtkMRMLScalarVolumeNode'))
bounds = [0.0, 0.0, 0.0, 0.0, 0.0, 0.0]
volumeNode.GetRASBounds(bounds)
x = (bounds[0] + bounds[1]) / 2
y = (bounds[2] + bounds[3]) / 2
z = (bounds[4] + bounds[5]) / 2
radius = min(bounds[1] - bounds[0], bounds[3] - bounds[2],
bounds[5] - bounds[4]) / 3.0
else:
radius = 50
x = y = z = 0
# Taken from: https://mantisarchive.slicer.org/view.php?id=1536
sphere = vtk.vtkSphereSource()
sphere.SetCenter(x, y, z)
sphere.SetRadius(radius)
modelNode = slicer.vtkMRMLModelNode()
modelNode.SetName(name)
modelNode = slicer.mrmlScene.AddNode(modelNode)
modelNode.SetPolyDataConnection(sphere.GetOutputPort())
modelNode.SetHideFromEditors(0)
displayNode = slicer.vtkMRMLModelDisplayNode()
slicer.mrmlScene.AddNode(displayNode)
displayNode.Visibility2DOn()
displayNode.VisibilityOn()
displayNode.SetColor(color[0], color[1], color[2])
modelNode.SetAndObserveDisplayNodeID(displayNode.GetID())
return modelNode
def onCircularROIBtn(self):
self.markups = slicer.util.getNode("F")
self.sphere = vtk.vtkSphereSource()
self.UpdateSphere(0, 0)
scene = slicer.mrmlScene
# Create model node
model = slicer.vtkMRMLModelNode()
model.SetAndObservePolyData(self.sphere.GetOutput())
# self.modelDisplay.SetColor(1, 1, 0) # yellows
# self.modelDisplay.SetBackfaceCulling(0)
# Create display node
self.modelDisplay = slicer.vtkMRMLModelDisplayNode()
self.modelDisplay.SetSliceIntersectionVisibility(True)
self.modelDisplay.SetVisibility(True)
scene.AddNode(self.modelDisplay)
model.SetAndObserveDisplayNodeID(self.modelDisplay.GetID())
# Add to scene
self.modelDisplay.SetInputPolyDataConnection(model.GetPolyDataConnection())
scene.AddNode(model)
self.markups.AddObserver("ModifiedEvent", self.UpdateSphere, 2)
def onEdit(self):
# Create empty model node
if self.segmentModel is None:
self.segmentModel = slicer.vtkMRMLModelNode()
slicer.mrmlScene.AddNode(self.segmentModel)
segmentID = self.scriptedEffect.parameterSetNode(
).GetSelectedSegmentID()
segmentationNode = self.scriptedEffect.parameterSetNode(
).GetSegmentationNode()
segment = segmentationNode.GetSegmentation().GetSegment(segmentID)
fPosStr = vtk.mutable("")
segment.GetTag("DrawTubeEffectMarkupPositions", fPosStr)
# convert from space-separated list o fnumbers to 1D array
import numpy
fPos = numpy.fromstring(str(fPosStr), sep=' ')
# convert from 1D array (N*3) to 2D array (N,3)
fPosNum = int(len(fPos) / 3)
fPos = fPos.reshape((fPosNum, 3))
for i in xrange(fPosNum):
self.segmentMarkupNode.AddFiducialFromArray(fPos[i])
self.editButton.setEnabled(False)
self.updateModelFromSegmentMarkupNode()
def tree2Model(self, tree, model=None):
# convert the tree structure a vtkMRMLModelNode
if model is None:
model = slicer.vtkMRMLModelNode()
model.SetName('Tree')
mesh = self.tree2Mesh(tree)
model.SetAndObserveMesh(mesh)
return model
def planeModel(self, scene, normal, origin, name, color):
""" Create a plane model node which can be viewed in the 3D View """
#A plane source
plane = vtk.vtkPlane()
plane.SetOrigin(origin)
plane.SetNormal(normal)
planeSample = vtk.vtkSampleFunction()
planeSample.SetImplicitFunction(plane)
planeSample.SetModelBounds(-100, 100, -100, 100, -100, 100)
planeSample.SetSampleDimensions(100, 100, 100)
planeSample.ComputeNormalsOff()
planeContour = vtk.vtkContourFilter()
# planeContour.SetInput(planeSample.GetOutput())
planeContour.SetInputData(planeSample.GetOutput())
# Create plane model node
planeNode = slicer.vtkMRMLModelNode()
planeNode.SetScene(scene)
planeNode.SetName(name)
planeNode.SetAndObservePolyData(planeContour.GetOutput())
# Create plane display model node
planeModelDisplay = slicer.vtkMRMLModelDisplayNode()
planeModelDisplay.SetColor(color)
planeModelDisplay.SetBackfaceCulling(0)
planeModelDisplay.SetScene(scene)
scene.AddNode(planeModelDisplay)
planeNode.SetAndObserveDisplayNodeID(planeModelDisplay.GetID())
#Add to scene
# planeModelDisplay.SetInputPolyData(planeContour.GetOutput())
planeModelDisplay.SetInputPolyDataConnection(
planeContour.GetOutputPort())
scene.AddNode(planeNode)
return plane
def placeFiducials(self):
self.clippingModelNode = slicer.vtkMRMLModelNode()
self.clippingModelNode.SetName('clipModelNode')
slicer.mrmlScene.AddNode(self.clippingModelNode)
self.createAndConfigureClippingModelDisplayNode()
self.createMarkupsFiducialNode()
self.inputMarkupNode.AddObserver(vtk.vtkCommand.ModifiedEvent, self.updateModel)
volumeClipPointsDisplayNode = self.setupDisplayNode()
self.inputMarkupNode.SetAndObserveDisplayNodeID(volumeClipPointsDisplayNode.GetID())
def test_Segmentation(self):
""" Test the GetRASBounds & GetBounds method on a segmentation.
"""
#self.delayDisplay("Starting test_Segmentation")
cubeSource = vtk.vtkCubeSource()
cubeSource.SetXLength(500)
cubeSource.SetYLength(200)
cubeSource.SetZLength(300)
cubeSource.SetCenter(10, -85, 0.7)
rotation = vtk.vtkTransform()
rotation.RotateX(15.0)
rotation.RotateZ(78)
applyTransform = vtk.vtkTransformPolyDataFilter()
applyTransform.SetTransform(rotation)
applyTransform.SetInputConnection(cubeSource.GetOutputPort())
applyTransform.Update()
modelNode = slicer.mrmlScene.AddNode(slicer.vtkMRMLModelNode())
modelNode.SetPolyDataConnection(applyTransform.GetOutputPort())
segmentationNode = slicer.mrmlScene.AddNewNodeByClass(
"vtkMRMLSegmentationNode")
segmentationLogic = slicer.modules.segmentations.logic()
segmentationLogic.ImportModelToSegmentationNode(
modelNode, segmentationNode)
# Testing
bounds = list(range(6))
segmentationNode.GetRASBounds(bounds)
untransformedBounds = [
-65.41641522206768, 237.23434621664228, -303.75878430165756,
289.7072339384945, -217.463212035832, 213.6873140360733
]
self.assertListAlmostEquals(bounds, untransformedBounds)
segmentationNode.GetBounds(bounds)
self.assertListAlmostEquals(bounds, untransformedBounds)
transform = vtk.vtkTransform()
transform.Translate([-5.0, +42.0, -0.1])
transform.RotateWXYZ(41, 0.7, 0.6, 75)
transform.Scale(2, 3, 10)
transformNode = slicer.mrmlScene.AddNode(slicer.vtkMRMLTransformNode())
transformNode.ApplyTransform(transform)
segmentationNode.SetAndObserveTransformNodeID(transformNode.GetID())
transformedBounds = [
-690.2701685073093, 966.991271911892, -740.4842166018336,
1018.2608117218165, -2183.4229718546612, 2144.1077463008546
]
segmentationNode.GetRASBounds(bounds)
self.assertListAlmostEquals(bounds, transformedBounds)
segmentationNode.GetBounds(bounds)
self.assertListAlmostEquals(bounds, untransformedBounds)
def test_Segmentation(self):
""" Test the GetRASBounds & GetBounds method on a segmentation.
"""
#self.delayDisplay("Starting test_Segmentation")
cubeSource = vtk.vtkCubeSource()
cubeSource.SetXLength(500)
cubeSource.SetYLength(200)
cubeSource.SetZLength(300)
cubeSource.SetCenter(10, -85, 0.7)
rotation = vtk.vtkTransform()
rotation.RotateX(15.0)
rotation.RotateZ(78)
applyTransform = vtk.vtkTransformPolyDataFilter()
applyTransform.SetTransform(rotation)
applyTransform.SetInputConnection(cubeSource.GetOutputPort())
applyTransform.Update()
modelNode = slicer.mrmlScene.AddNode(slicer.vtkMRMLModelNode())
modelNode.SetPolyDataConnection(applyTransform.GetOutputPort())
segmentationNode = slicer.mrmlScene.AddNewNodeByClass(
"vtkMRMLSegmentationNode")
segmentationLogic = slicer.modules.segmentations.logic()
segmentationLogic.ImportModelToSegmentationNode(
modelNode, segmentationNode)
# Testing
bounds = range(6)
segmentationNode.GetRASBounds(bounds)
untransformedBounds = [
-65.4164152220677, 237.23434621664234, -305.4495706784099,
289.7072339384947, -217.46321203583187, 213.68731403607347
]
self.assertListAlmostEquals(bounds, untransformedBounds)
segmentationNode.GetBounds(bounds)
self.assertListAlmostEquals(bounds, untransformedBounds)
transform = vtk.vtkTransform()
transform.Translate([-5.0, +42.0, -0.1])
transform.RotateWXYZ(41, 0.7, 0.6, 75)
transform.Scale(2, 3, 10)
transformNode = slicer.mrmlScene.AddNode(slicer.vtkMRMLTransformNode())
transformNode.ApplyTransform(transform)
segmentationNode.SetAndObserveTransformNodeID(transformNode.GetID())
transformedBounds = [
-690.2701685073098, 970.3186946284741, -744.3124542486084,
1018.260811721817, -2183.4639807718822, 2144.107746300856
]
segmentationNode.GetRASBounds(bounds)
self.assertListAlmostEquals(bounds, transformedBounds)
segmentationNode.GetBounds(bounds)
self.assertListAlmostEquals(bounds, untransformedBounds)
def showColorMap(self):
# Get PolyData from Segment 1
self.segment1.CreateClosedSurfaceRepresentation()
ss1 = self.segment1.GetSegmentation()
str1 = ss1.GetNthSegmentID(0)
pl1 = vtk.vtkPolyData()
pl1 = self.segment1.GetClosedSurfaceRepresentation(str1)
# Get PolyData from Segment 2
self.segment2.CreateClosedSurfaceRepresentation()
ss2 = self.segment2.GetSegmentation()
str2 = ss2.GetNthSegmentID(0)
pl2 = vtk.vtkPolyData()
pl2 = self.segment2.GetClosedSurfaceRepresentation(str2)
# Compute distance
distanceFilter = vtk.vtkDistancePolyDataFilter()
distanceFilter.SetInputData(0, pl1)
distanceFilter.SetInputData(1, pl2)
distanceFilter.SignedDistanceOff()
distanceFilter.Update()
# Center 3D view
#slicer.app.layoutManager().tableWidget(0).setVisible(False)
layoutManager = slicer.app.layoutManager()
threeDWidget = layoutManager.threeDWidget(0)
threeDView = threeDWidget.threeDView()
threeDView.resetFocalPoint()
# Output model
model = slicer.vtkMRMLModelNode()
slicer.mrmlScene.AddNode(model)
model.SetName('DistanceModelNode')
model.SetAndObservePolyData(distanceFilter.GetOutput())
self.distanceColorMap_display = slicer.vtkMRMLModelDisplayNode()
slicer.mrmlScene.AddNode(self.distanceColorMap_display)
model.SetAndObserveDisplayNodeID(self.distanceColorMap_display.GetID())
self.distanceColorMap_display.SetActiveScalarName('Distance')
self.distanceColorMap_display.SetAndObserveColorNodeID(
'vtkMRMLColorTableNodeFileDivergingBlueRed.txt')
self.distanceColorMap_display.SetScalarVisibility(True)
self.distanceColorMap_display.SetScalarRangeFlag(
0) # Set scalar range mode to Manual
self.distanceColorMap_display.SetScalarRange(0.0, 10.0)
[rmin, rmax] = self.distanceColorMap_display.GetScalarRange()
print(rmin)
print(rmax)
# Scalar bar
self.updateScalarBarRange(0.0, 10.0)
self.updateScalarBarVisibility(True)
# Deactivate visibility of segments (deberia actualizarse el checkbox del GUI pero no lo consigo)
self.updateSegment1Visibility(False)
self.updateSegment2Visibility(False)
def onApplyButton(self):
print("Transducer parameters >> /n")
print("ROC:" + str(self.ROC.value))
print("Width:" + str(self.width.value))
print("ROC:" + str(self.freq.value))
skull, skull_actor = hlp.read_skull_vtk(
"/Users/home/Desktop/Simulation/Simulation/SMA_matlab_skull_transform0.vtk",
0.5, [0.8, 0.8, 0.8])
model = slicer.vtkMRMLModelNode()
model.SetAndObservePolyData(skull)
## set model node properties
modelDisplay = slicer.vtkMRMLModelDisplayNode()
modelDisplay.SetColor(0.8, 0.8, 0.8)
modelDisplay.BackfaceCullingOff()
modelDisplay.SetOpacity(0.5)
modelDisplay.SetPointSize(3)
## mode node display
modelDisplay.SetSliceIntersectionVisibility(True)
modelDisplay.SetVisibility(True)
slicer.mrmlScene.AddNode(modelDisplay)
model.SetAndObserveDisplayNodeID(modelDisplay.GetID())
modelDisplay.SetInputPolyDataConnection(model.GetPolyDataConnection())
## model node set name
slicer.mrmlScene.AddNode(model).SetName("Skull")
## read vtk object convert to vtkimage
result_image = hlp.vtk_grid2image(
"/Users/home/Desktop/Simulation/Simulation/SMA_full_0.vtk")
result_volume = slicer.vtkMRMLScalarVolumeNode()
result_volume.SetAndObserveImageData(result_image)
## image to 2D scene
defaultVolumeDisplayNode = slicer.mrmlScene.CreateNodeByClass(
"vtkMRMLScalarVolumeDisplayNode")
defaultVolumeDisplayNode.AutoWindowLevelOn()
defaultVolumeDisplayNode.SetVisibility(True)
defaultVolumeDisplayNode.AddWindowLevelPresetFromString(
"ColdToHotRainbow")
slicer.mrmlScene.AddDefaultNode(defaultVolumeDisplayNode)
result_volume.SetAndObserveDisplayNodeID(
defaultVolumeDisplayNode.GetID())
defaultVolumeDisplayNode.SetInputImageDataConnection(
result_volume.GetImageDataConnection())
## volume node set name
slicer.mrmlScene.AddNode(result_volume).SetName("simulation_result")
## volume rendering
hlp.showVolumeRendering(result_volume)
slicer.mrmlScene.AddObserver(slicer.vtkMRMLScene.NodeAddedEvent,
hlp.onNodeAdded)
def defineSphere(self):
sphereSource = vtk.vtkSphereSource()
sphereSource.SetRadius(100.0)
model = slicer.vtkMRMLModelNode()
model.SetAndObservePolyData(sphereSource.GetOutput())
modelDisplay = slicer.vtkMRMLModelDisplayNode()
slicer.mrmlScene.AddNode(modelDisplay)
model.SetAndObserveDisplayNodeID(modelDisplay.GetID())
modelDisplay.SetInputPolyDataConnection(sphereSource.GetOutputPort())
return model
def tube2Model(self, tube, model=None):
# convert a single tubular structure to a vtkMRMLModelNode
if model is None:
model = slicer.vtkMRMLModelNode()
name = 'Segment ' + str(
tube['ID']) + (' - ' + tube['Name'] if 'Name' in tube else '')
model.SetName(name)
mesh = self.tube2CylinderMesh(tube)
model.SetAndObserveMesh(mesh)
return model
def createTrajectoryModel(self):
createModelLogic = slicer.modules.createmodels.logic()
trajectoryModelNode = slicer.vtkMRMLModelNode()
trajectoryModelNode = createModelLogic.CreateCylinder(100, 0.05)
probeModelDisplayNode = trajectoryModelNode.GetDisplayNode()
probeModelDisplayNode.SetColor([1, 0, 0])
probeModelDisplayNode.SetOpacity(0.5)
probeModelDisplayNode.SetSliceIntersectionVisibility(1)
slicer.mrmlScene.AddNode(trajectoryModelNode)
self.trajectoryModelNode = trajectoryModelNode
return trajectoryModelNode
def onFiducialPlacementToggleChanged(self):
if self.fiducialPlacementToggle.placeButton().isChecked():
# Create empty model node
if self.segmentModel is None:
self.segmentModel = slicer.vtkMRMLModelNode()
slicer.mrmlScene.AddNode(self.segmentModel)
# Create empty markup fiducial node
if self.segmentMarkupNode is None:
self.createNewMarkupNode()
self.fiducialPlacementToggle.setCurrentNode(
self.segmentMarkupNode)
def getSourceTargetFromDrawing(self):
# get smplae distance
sampleDistance = float(
self.parameterNode.GetParameter("DrawSampleDistance"))
# create curve from drawing and resample
sourceCurve = slicer.mrmlScene.AddNewNodeByClass(
'vtkMRMLMarkupsCurveNode')
sourceCurve.GetDisplayNode().SetSelectedColor(1, 1, 0)
sourceCurve.SetControlPointPositionsWorld(self.rasPoints)
sourceCurve.ResampleCurveWorld(sampleDistance)
self.auxNodes.append(sourceCurve)
# get resampled points
resampledPoints = vtk.vtkPoints()
sourceCurve.GetControlPointPositionsWorld(resampledPoints)
if resampledPoints.GetNumberOfPoints() <= 1:
return (None, ) * 3
# get closest model sliced
slicedModel, originalModel = self.sliceClosestModel(
resampledPoints.GetPoint(0))
if not slicedModel:
return (None, ) * 3
self.auxNodes.append(slicedModel)
# resample sourceCurve in sliced model with same amount of points
targetCurve = slicer.mrmlScene.AddNewNodeByClass(
'vtkMRMLMarkupsCurveNode')
targetCurve.GetDisplayNode().SetVisibility(0)
targetCurve.SetControlPointPositionsWorld(resampledPoints)
targetCurve.SetCurveTypeToShortestDistanceOnSurface(slicedModel)
targetCurve.ResampleCurveSurface(
sampleDistance,
slicer.vtkMRMLModelNode().SafeDownCast(slicedModel), 0.0025)
targetCurve.ResampleCurveWorld(targetCurve.GetCurveLengthWorld() / max(
(sourceCurve.GetNumberOfControlPoints() - 1), 1))
self.auxNodes.append(targetCurve)
# curve to fiducial
sourceFiducial = self.curveToFiducial(sourceCurve)
targetFiducial = self.curveToFiducial(targetCurve)
# set name
shNode = slicer.mrmlScene.GetSubjectHierarchyNode()
modelParentName = shNode.GetItemName(
shNode.GetItemParent(shNode.GetItemByDataNode(originalModel)))
targetFiducial.SetName(modelParentName + '_' + originalModel.GetName())
return sourceFiducial, targetFiducial, sourceCurve
def test_Model(self):
""" Test the GetRASBounds & GetBounds method on a model.
"""
#self.delayDisplay("Starting test_Model")
# Setup
cubeSource = vtk.vtkCubeSource()
cubeSource.SetXLength(500)
cubeSource.SetYLength(200)
cubeSource.SetZLength(300)
cubeSource.SetCenter(10, -85, 0.7)
rotation = vtk.vtkTransform()
rotation.RotateX(15.0)
rotation.RotateZ(78)
applyTransform = vtk.vtkTransformPolyDataFilter()
applyTransform.SetTransform(rotation)
applyTransform.SetInputConnection(cubeSource.GetOutputPort())
applyTransform.Update()
modelNode = slicer.mrmlScene.AddNode(slicer.vtkMRMLModelNode())
modelNode.SetPolyDataConnection(applyTransform.GetOutputPort())
# Testing
bounds = range(6)
modelNode.GetRASBounds(bounds)
untransformedBounds = [
-64.5710220336914, 235.01434326171875, -302.91339111328125,
287.3067932128906, -214.92703247070312, 212.1946258544922
]
self.assertListAlmostEquals(bounds, untransformedBounds)
modelNode.GetBounds(bounds)
self.assertListAlmostEquals(bounds, untransformedBounds)
transform = vtk.vtkTransform()
transform.Translate([-5.0, +42.0, -0.1])
transform.RotateWXYZ(41, 0.7, 0.6, 75)
transform.Scale(2, 3, 10)
transformNode = slicer.mrmlScene.AddNode(slicer.vtkMRMLTransformNode())
transformNode.ApplyTransform(transform)
modelNode.SetAndObserveTransformNodeID(transformNode.GetID())
transformedBounds = [
-684.0789214975257, 961.8640451930095, -737.3987882515103,
1009.8075011032414, -2158.028473491281, 2129.118193451847
]
modelNode.GetRASBounds(bounds)
self.assertListAlmostEquals(bounds, transformedBounds)
modelNode.GetBounds(bounds)
self.assertListAlmostEquals(bounds, untransformedBounds)
def measurementsTable2Model(self, tableNode, model=None):
# convert a measurements table to a mesh a vtkMRMLModelNode
if model is None:
model = slicer.vtkMRMLModelNode()
model.SetName('Measurements')
if self.getType(tableNode) == 'tree':
mesh = self.treeTable2Mesh(tableNode)
elif self.getType(tableNode) == 'areaMeasurements':
mesh = self.areaMeasurementsTable2Mesh(tableNode)
else:
mesh = self.volumeMeasurementsTable2Mesh(tableNode)
model.SetAndObserveMesh(mesh)
return model
def OnSmoothLabelMapButtonClicked(self):
# Get working polydata
WorkingNodeName = self.WorkingLabelMapStorage.currentNode().GetName()
if self.SegmentationNode.GetClosedSurfaceRepresentation(
WorkingNodeName) == None:
self.SegmentationNode.CreateClosedSurfaceRepresentation()
WorkingPolyData = self.SegmentationNode.GetClosedSurfaceRepresentation(
WorkingNodeName)
# Smooth working polydata
logic = UsSurfaceToLandmarksLogic()
SmoothedPolyData = logic.SmoothPolyData(
WorkingPolyData, self.SmoothingConvergenceSlider.value,
self.SmoothingIterationsSlider.value)
# Convert polydata to labelmap via segmentation and vtkmodel
SmoothedModelNode = slicer.vtkMRMLModelNode()
SmoothedModelNode.SetName(WorkingNodeName)
SmoothedModelNode.SetAndObservePolyData(SmoothedPolyData)
#SmoothedModelNode
ConvSeg = slicer.vtkMRMLSegmentationNode()
ConvSeg.SetScene(slicer.mrmlScene)
SegLogic = slicer.modules.segmentations.logic()
SegLogic.ImportModelToSegmentationNode(SmoothedModelNode, ConvSeg)
ConvSeg.CreateBinaryLabelmapRepresentation()
ConvSeg.SetMasterRepresentationToBinaryLabelmap()
# Clear mrmlScene of old labelmap node before exporting the new one
#OldLabelMapNode = self.WorkingLabelMapStorage.currentNode()
#OldLabelMapNode = slicer.util.getNode(WorkingNodeName)
#if OldLabelMapNode != None:
# slicer.mrmlScene.RemoveNode(OldLabelMapNode)
# Export segmentation label map representation to mrml node for storage in interface
SmoothedLabelMapNode = slicer.vtkMRMLLabelMapVolumeNode()
SmoothedLabelMapNode.SetName(WorkingNodeName + self.SmoothTag)
LabelMapName = vtk.vtkStringArray()
LabelMapName.InsertNextValue(WorkingNodeName)
slicer.mrmlScene.AddNode(SmoothedLabelMapNode)
SegLogic.ExportSegmentsToLabelmapNode(ConvSeg, LabelMapName,
SmoothedLabelMapNode)
#SmoothedLabelMapNode.SetOrigin(self.InputVolumeSelector.currentNode().GetOrigin())
# Update working polydata in UI
# Add new smoothed label map node to mrmlScene
self.WorkingLabelMapStorage.setCurrentNode(SmoothedLabelMapNode)
self.UpdateSegmentationNode()
return True
def test_Segmentation(self):
""" Test the GetRASBounds & GetBounds method on a segmentation.
"""
#self.delayDisplay("Starting test_Segmentation")
cubeSource = vtk.vtkCubeSource()
cubeSource.SetXLength(500)
cubeSource.SetYLength(200)
cubeSource.SetZLength(300)
cubeSource.SetCenter(10, -85, 0.7)
rotation = vtk.vtkTransform()
rotation.RotateX(15.0)
rotation.RotateZ(78)
applyTransform = vtk.vtkTransformPolyDataFilter()
applyTransform.SetTransform(rotation)
applyTransform.SetInputConnection(cubeSource.GetOutputPort())
applyTransform.Update()
modelNode = slicer.mrmlScene.AddNode(slicer.vtkMRMLModelNode())
modelNode.SetPolyDataConnection(applyTransform.GetOutputPort())
segmentationNode = slicer.mrmlScene.AddNode(slicer.vtkMRMLSegmentationNode())
segmentationLogic = slicer.modules.segmentations.logic()
segmentationLogic.ImportModelToSegmentationNode(modelNode, segmentationNode)
# Testing
bounds = range(6)
segmentationNode.GetRASBounds(bounds)
untransformedBounds = [-65.4164152220677, 237.23434621664234, -305.4495706784099, 289.7072339384947, -217.46321203583187, 213.68731403607347]
self.assertListAlmostEquals(bounds, untransformedBounds)
segmentationNode.GetBounds(bounds)
self.assertListAlmostEquals(bounds, untransformedBounds)
transform = vtk.vtkTransform()
transform.Translate([-5.0, +42.0, -0.1])
transform.RotateWXYZ(41, 0.7, 0.6, 75)
transform.Scale(2, 3, 10)
transformNode = slicer.mrmlScene.AddNode(slicer.vtkMRMLTransformNode())
transformNode.ApplyTransform(transform)
segmentationNode.SetAndObserveTransformNodeID(transformNode.GetID())
transformedBounds = [-690.2701685073098, 970.3186946284741, -744.3124542486084, 1018.260811721817, -2183.4639807718822, 2144.107746300856]
segmentationNode.GetRASBounds(bounds)
self.assertListAlmostEquals(bounds, transformedBounds)
segmentationNode.GetBounds(bounds)
self.assertListAlmostEquals(bounds, untransformedBounds)
def test_Segmentation(self):
""" Test the GetRASBounds & GetBounds method on a segmentation.
"""
#self.delayDisplay("Starting test_Segmentation")
cubeSource = vtk.vtkCubeSource()
cubeSource.SetXLength(500)
cubeSource.SetYLength(200)
cubeSource.SetZLength(300)
cubeSource.SetCenter(10, -85, 0.7)
rotation = vtk.vtkTransform()
rotation.RotateX(15.0)
rotation.RotateZ(78)
applyTransform = vtk.vtkTransformPolyDataFilter()
applyTransform.SetTransform(rotation)
applyTransform.SetInputConnection(cubeSource.GetOutputPort())
applyTransform.Update()
modelNode = slicer.mrmlScene.AddNode(slicer.vtkMRMLModelNode())
modelNode.SetPolyDataConnection(applyTransform.GetOutputPort())
segmentationNode = slicer.mrmlScene.AddNode(slicer.vtkMRMLSegmentationNode())
segmentationLogic = slicer.modules.segmentations.logic()
segmentationLogic.ImportModelToSegmentationNode(modelNode, segmentationNode)
# Testing
bounds = range(6)
segmentationNode.GetRASBounds(bounds)
untransformedBounds = [-65.0710220336914, 235.9289779663086, -304.413391113281, 288.586608886719, -216.427032470703, 213.572967529297]
self.assertListAlmostEquals(bounds, untransformedBounds)
segmentationNode.GetBounds(bounds)
self.assertListAlmostEquals(bounds, untransformedBounds)
transform = vtk.vtkTransform()
transform.Translate([-5.0, +42.0, -0.1])
transform.RotateWXYZ(41, 0.7, 0.6, 75)
transform.Scale(2, 3, 10)
transformNode = slicer.mrmlScene.AddNode(slicer.vtkMRMLTransformNode())
transformNode.ApplyTransform(transform)
segmentationNode.SetAndObserveTransformNodeID(transformNode.GetID())
transformedBounds = [-687.4653523284665, 966.3004987004498, -741.50842882335, 1013.9676912857693, -2173.06971199151, 2142.935099515583]
segmentationNode.GetRASBounds(bounds)
self.assertListAlmostEquals(bounds, transformedBounds)
segmentationNode.GetBounds(bounds)
self.assertListAlmostEquals(bounds, untransformedBounds)
def test_Segmentation(self):
""" Test the GetRASBounds & GetBounds method on a segmentation.
"""
#self.delayDisplay("Starting test_Segmentation")
cubeSource = vtk.vtkCubeSource()
cubeSource.SetXLength(500)
cubeSource.SetYLength(200)
cubeSource.SetZLength(300)
cubeSource.SetCenter(10, -85, 0.7)
rotation = vtk.vtkTransform()
rotation.RotateX(15.0)
rotation.RotateZ(78)
applyTransform = vtk.vtkTransformPolyDataFilter()
applyTransform.SetTransform(rotation)
applyTransform.SetInputConnection(cubeSource.GetOutputPort())
applyTransform.Update()
modelNode = slicer.mrmlScene.AddNode(slicer.vtkMRMLModelNode())
modelNode.SetPolyDataConnection(applyTransform.GetOutputPort())
segmentationNode = slicer.mrmlScene.AddNode(slicer.vtkMRMLSegmentationNode())
segmentationLogic = slicer.modules.segmentations.logic()
segmentationLogic.ImportModelToSegmentationNode(modelNode, segmentationNode)
# Testing
bounds = range(6)
segmentationNode.GetRASBounds(bounds)
untransformedBounds = [-65.0710220336914, 235.9289779663086, -304.413391113281, 288.586608886719, -216.427032470703, 213.572967529297]
self.assertListAlmostEquals(bounds, untransformedBounds)
segmentationNode.GetBounds(bounds)
self.assertListAlmostEquals(bounds, untransformedBounds)
transform = vtk.vtkTransform()
transform.Translate([-5.0, +42.0, -0.1])
transform.RotateWXYZ(41, 0.7, 0.6, 75)
transform.Scale(2, 3, 10)
transformNode = slicer.mrmlScene.AddNode(slicer.vtkMRMLTransformNode())
transformNode.ApplyTransform(transform)
segmentationNode.SetAndObserveTransformNodeID(transformNode.GetID())
transformedBounds = [-200.70776329131795, 479.54290966330126, -723.6172978253361, 996.0765602877555, -2171.2883672792996, 2141.1537548033725]
segmentationNode.GetRASBounds(bounds)
self.assertListAlmostEquals(bounds, transformedBounds)
segmentationNode.GetBounds(bounds)
self.assertListAlmostEquals(bounds, untransformedBounds)
def drawCone(self, coneSource, coneDimensions, center):
coneModelNode = slicer.vtkMRMLModelNode()
slicer.mrmlScene.AddNode(coneModelNode)
coneModelNode.SetName('ConeModel')
coneModelNodeToUpdate = coneModelNode
coneSource.Update()
coneModelNodeToUpdate.SetAndObservePolyData(coneSource.GetOutput())
if coneModelNodeToUpdate.GetDisplayNode() is None:
displayNode = slicer.vtkMRMLModelDisplayNode()
slicer.mrmlScene.AddNode(displayNode)
displayNode.SetName('ConeModelDisplay')
coneModelNodeToUpdate.SetAndObserveDisplayNodeID(displayNode.GetID())
return coneModelNode
def __init__(self):
self.sendDataOK = False
self.OSC_active = False
self.line = slicer.util.getNode('Line')
if not self.line:
self.line = slicer.vtkMRMLModelNode()
self.line.SetName('Line')
linePolyData = vtk.vtkPolyData()
self.line.SetAndObservePolyData(linePolyData)
modelDisplay = slicer.vtkMRMLModelDisplayNode()
modelDisplay.SetSliceIntersectionVisibility(True)
modelDisplay.SetColor(0,1,0)
slicer.mrmlScene.AddNode(modelDisplay)
self.line.SetAndObserveDisplayNodeID(modelDisplay.GetID())
slicer.mrmlScene.AddNode(self.line)
def createAndConfigureSegmentModelDisplayNode(self):
self.segmentModelNode = slicer.vtkMRMLModelNode()
prefix = "{}-".format(self.seriesNumber) if self.seriesNumber else ""
self.segmentModelNode.SetName('%sSurfaceCut-MODEL' % prefix)
slicer.mrmlScene.AddNode(self.segmentModelNode)
self.segmentModelDisplayNode = slicer.vtkMRMLModelDisplayNode()
self.segmentModelDisplayNode.SetSliceIntersectionThickness(3)
# self.refreshViewNodeIDs
self.segmentModelDisplayNode.SetColor(self.labelValueToRGB(self.outputLabelValue) if self.outputLabelValue
else [0.200, 0.800, 0.000])
self.segmentModelDisplayNode.BackfaceCullingOff()
self.segmentModelDisplayNode.SliceIntersectionVisibilityOn()
self.segmentModelDisplayNode.SetOpacity(0.3)
slicer.mrmlScene.AddNode(self.segmentModelDisplayNode)
self.segmentModelNode.SetAndObserveDisplayNodeID(self.segmentModelDisplayNode.GetID())
def drawPlane(self, m, V_norm):
scene = slicer.mrmlScene
#create a plane to cut,here it cuts in the XZ direction (xz normal=(1,0,0);XY =(0,0,1),YZ =(0,1,0)
planex=vtk.vtkPlane()
planex.SetOrigin(m[0],m[1],m[2])
planex.SetNormal(V_norm[0],V_norm[1],V_norm[2])
renderer = slicer.app.layoutManager().threeDWidget(0).threeDView().renderWindow().GetRenderers().GetFirstRenderer()
viewSize = renderer.ComputeVisiblePropBounds()
#viewSize = (-50.0, 50.0, -50.0, 50.0, -50.0, 50.0)
planexSample = vtk.vtkSampleFunction()
planexSample.SetImplicitFunction(planex)
planexSample.SetModelBounds(viewSize)
#planexSample.SetSampleDimensions(200,200,200)
planexSample.ComputeNormalsOff()
plane1 = vtk.vtkContourFilter()
plane1.SetInputConnection(planexSample.GetOutputPort())
# Create model Plane A node
planeA = slicer.vtkMRMLModelNode()
planeA.SetScene(scene)
planeA.SetName("X-Y Plane")
planeA.SetAndObservePolyData(plane1.GetOutput())
# Create display model Plane A node
planeAModelDisplay = slicer.vtkMRMLModelDisplayNode()
planeAModelDisplay.SetColor(0.145,0.77,0.596)
planeAModelDisplay.BackfaceCullingOff()
planeAModelDisplay.SetScene(scene)
scene.AddNode(planeAModelDisplay)
planeA.SetAndObserveDisplayNodeID(planeAModelDisplay.GetID())
#Add to scene
planeAModelDisplay.SetInputPolyDataConnection(plane1.GetOutputPort())
scene.AddNode(planeA)
# adjust center of 3d view to plane
layoutManager = slicer.app.layoutManager()
threeDWidget = layoutManager.threeDWidget(0)
threeDView = threeDWidget.threeDView()
threeDView.resetFocalPoint()
def test_Model(self):
""" Test the GetRASBounds & GetBounds method on a model.
"""
#self.delayDisplay("Starting test_Model")
# Setup
cubeSource = vtk.vtkCubeSource()
cubeSource.SetXLength(500)
cubeSource.SetYLength(200)
cubeSource.SetZLength(300)
cubeSource.SetCenter(10, -85, 0.7)
rotation = vtk.vtkTransform()
rotation.RotateX(15.0)
rotation.RotateZ(78)
applyTransform = vtk.vtkTransformPolyDataFilter()
applyTransform.SetTransform(rotation)
applyTransform.SetInputConnection(cubeSource.GetOutputPort())
applyTransform.Update()
modelNode = slicer.mrmlScene.AddNode(slicer.vtkMRMLModelNode())
modelNode.SetPolyDataConnection(applyTransform.GetOutputPort())
# Testing
bounds = range(6)
modelNode.GetRASBounds(bounds)
untransformedBounds = [-64.5710220336914, 235.01434326171875, -302.91339111328125, 287.3067932128906, -214.92703247070312, 212.1946258544922]
self.assertListAlmostEquals(bounds, untransformedBounds)
modelNode.GetBounds(bounds)
self.assertListAlmostEquals(bounds, untransformedBounds)
transform = vtk.vtkTransform()
transform.Translate([-5.0, +42.0, -0.1])
transform.RotateWXYZ(41, 0.7, 0.6, 75)
transform.Scale(2, 3, 10)
transformNode = slicer.mrmlScene.AddNode(slicer.vtkMRMLTransformNode())
transformNode.ApplyTransform(transform)
modelNode.SetAndObserveTransformNodeID(transformNode.GetID())
transformedBounds = [-684.0789214975257, 961.8640451930095, -737.3987882515103, 1009.8075011032414, -2158.028473491281, 2129.118193451847]
modelNode.GetRASBounds(bounds)
self.assertListAlmostEquals(bounds, transformedBounds)
modelNode.GetBounds(bounds)
self.assertListAlmostEquals(bounds, untransformedBounds)
def createIntermediateHardenModel(self, model):
hardenModel = slicer.mrmlScene.GetNodesByName("SurfaceRegistration_" + model.GetName() + "_hardenCopy_" + str(
slicer.app.applicationPid())).GetItemAsObject(0)
if hardenModel is None:
hardenModel = slicer.vtkMRMLModelNode()
hardenPolyData = vtk.vtkPolyData()
hardenPolyData.DeepCopy(model.GetPolyData())
hardenModel.SetAndObservePolyData(hardenPolyData)
hardenModel.SetName(
"SurfaceRegistration_" + model.GetName() + "_hardenCopy_" + str(slicer.app.applicationPid()))
if model.GetParentTransformNode():
hardenModel.SetAndObserveTransformNodeID(model.GetParentTransformNode().GetID())
hardenModel.HideFromEditorsOn()
slicer.mrmlScene.AddNode(hardenModel)
logic = slicer.vtkSlicerTransformLogic()
logic.hardenTransform(hardenModel)
return hardenModel
def drawSphere(self, centerOfSphere, radiusOfSphere):
s = vtk.vtkSphereSource()
s.SetRadius(radiusOfSphere)
s.SetCenter(centerOfSphere[0], centerOfSphere[1], centerOfSphere[2])
s.SetPhiResolution(36)
s.SetThetaResolution(36)
s.Update()
m = slicer.vtkMRMLModelNode()
slicer.mrmlScene.AddNode(m)
m.CreateDefaultDisplayNodes()
#m = self.setup.outputSelector
m.GetDisplayNode().SetSliceIntersectionVisibility(True)
m.GetDisplayNode().SetColor(1, 0, 0)
m.SetAndObservePolyData(s.GetOutput())
def run(self):
"""
Run the actual algorithm
"""
#generating Nodes for displaying a new model
modelNode = slicer.vtkMRMLModelNode()
dispNode = slicer.vtkMRMLModelDisplayNode()
transform = slicer.vtkMRMLLinearTransformNode()
#Display node characteristics
dispNode.SetVisibility(True)
dispNode.SetSliceIntersectionVisibility(True)
dispNode.SetOpacity(1)
dispNode.SetColor(1, 1, 0)
dispNode.SetScene(slicer.mrmlScene)
#generate sphere data
sphere = vtk.vtkSphereSource()
sphere.SetCenter(10,10,10)
sphere.SetRadius(40)
sphere.Update()
#adding necessary nodes to the Scene
slicer.mrmlScene.AddNode(dispNode)
slicer.mrmlScene.AddNode(transform)
slicer.mrmlScene.AddNode(modelNode)
#model node name and associations!
modelNode.SetName("SphereModelNode")
modelNode.SetScene(slicer.mrmlScene)
modelNode.SetAndObserveTransformNodeID(transform.GetID())
modelNode.SetAndObserveDisplayNodeID(dispNode.GetID())
apd = vtk.vtkAppendPolyData()
apd.AddInputData(sphere.GetOutput())
apd.Update()
#adding model node poly data! Here there are sphere's data!!!
modelNode.SetAndObservePolyData(apd.GetOutput())
#update the scene
slicer.mrmlScene.Modified()
return True
def createIntermediateHardenModel(self, model):
hardenModel = slicer.mrmlScene.GetNodesByName(
"SurfaceRegistration_" + model.GetName() + "_hardenCopy_" +
str(slicer.app.applicationPid())).GetItemAsObject(0)
if hardenModel is None:
hardenModel = slicer.vtkMRMLModelNode()
hardenPolyData = vtk.vtkPolyData()
hardenPolyData.DeepCopy(model.GetPolyData())
hardenModel.SetAndObservePolyData(hardenPolyData)
hardenModel.SetName("SurfaceRegistration_" + model.GetName() +
"_hardenCopy_" + str(slicer.app.applicationPid()))
if model.GetParentTransformNode():
hardenModel.SetAndObserveTransformNodeID(
model.GetParentTransformNode().GetID())
hardenModel.HideFromEditorsOn()
slicer.mrmlScene.AddNode(hardenModel)
logic = slicer.vtkSlicerTransformLogic()
logic.hardenTransform(hardenModel)
return hardenModel
def plotLineZaxis(self):
# Create a vtkPoints object and store the points in it
self.pos = [0.0, 0.0, 0.0, 0.0]
self.targetFiducial.GetNthFiducialWorldCoordinates(0, self.pos)
targetP = [self.pos[i] for i in (0,1,2)]
self.surfPoint = [0.0, 0.0, 0.0, 0.0]
self.surfaceFiducial.GetNthFiducialWorldCoordinates(0, self.surfPoint)
surfaceP = [self.surfPoint[i] for i in (0,1,2)]
self.zVector = np.subtract(targetP,surfaceP)
points = vtk.vtkPoints()
points.InsertNextPoint(targetP)
points.InsertNextPoint(surfaceP)
# Create line
line = vtk.vtkLine()
line.GetPointIds().SetId(0,0)
line.GetPointIds().SetId(1,1)
lineCellArray = vtk.vtkCellArray()
lineCellArray.InsertNextCell(line)
self.lineNode = slicer.vtkMRMLModelNode()
self.lineNode.SetName('LineZ')
linePolyData = vtk.vtkPolyData()
self.lineNode.SetAndObservePolyData(linePolyData)
modelDisplay = slicer.vtkMRMLModelDisplayNode()
modelDisplay.SetSliceIntersectionVisibility(True)
modelDisplay.SetColor(1,1,1)
slicer.mrmlScene.AddNode(modelDisplay)
self.lineNode.SetAndObserveDisplayNodeID(modelDisplay.GetID())
slicer.mrmlScene.AddNode(self.lineNode)
self.lineNode.GetPolyData().SetPoints(points)
self.lineNode.GetPolyData().SetLines(lineCellArray)
#self.lineNode.SetAndObserveTransformNodeID(self.boxToReference.GetID())
self.drawPlane(surfaceP, self.zVector)
self.definePlaneAxis(surfaceP, self.zVector)
def OnDecimateLabelMapButtonClicked(self):
# Get working polydata
WorkingNodeName = self.WorkingLabelMapStorage.currentNode().GetName()
if self.SegmentationNode.GetClosedSurfaceRepresentation(
WorkingNodeName) == None:
self.SegmentationNode.CreateClosedSurfaceRepresentation()
WorkingPolyData = self.SegmentationNode.GetClosedSurfaceRepresentation(
WorkingNodeName)
# Decimate working polydata
logic = UsSurfaceToLandmarksLogic()
DecimatedPolyData = logic.DecimatePolyData(WorkingPolyData)
# Convert polydata to labelmap via segmentation and vtkmodel
DecimatedModelNode = slicer.vtkMRMLModelNode()
DecimatedModelNode.SetName(WorkingNodeName)
DecimatedModelNode.SetAndObservePolyData(DecimatedPolyData)
ConvSeg = slicer.vtkMRMLSegmentationNode()
ConvSeg.SetScene(slicer.mrmlScene)
SegLogic = slicer.modules.segmentations.logic()
SegLogic.ImportModelToSegmentationNode(DecimatedModelNode, ConvSeg)
ConvSeg.CreateBinaryLabelmapRepresentation()
ConvSeg.SetMasterRepresentationToBinaryLabelmap()
LabelMapName = vtk.vtkStringArray()
LabelMapName.InsertNextValue(WorkingNodeName)
DecimatedLabelMapNode = slicer.vtkMRMLLabelMapVolumeNode()
DecimatedLabelMapNode.SetName(WorkingNodeName)
slicer.mrmlScene.AddNode(DecimatedLabelMapNode)
SegLogic.ExportSegmentsToLabelmapNode(ConvSeg, LabelMapName,
DecimatedLabelMapNode)
#SmoothedOrientedImageData = ConvSeg.GetBinaryLabelmapRepresentation(WorkingNodeName)
#DecimatedLabelMapNode.SetAndObserveImageData(SmoothedOrientedImageData)
# Update working polydata in UI
self.WorkingLabelMapStorage.setCurrentNode(DecimatedLabelMapNode)
self.UpdateSegmentationNode()
return True
def onShowPathButton(self):
print 'Reconstructing retractor trajectory ...'
fidNode = slicer.util.getNode('MarkupsFiducial_*')
if fidNode == None:
slicer.util.CreateNodeByClass('vtkMRMLMarkupsFiducialNode')
fidNode = slicer.util.getNode('MarkupsFiducial_*')
outputModel = slicer.mrmlScene.AddNode(slicer.vtkMRMLModelNode())
outputModel.SetName('Path Trajectory')
outputModel.CreateDefaultDisplayNodes()
outputModel.GetDisplayNode().SetSliceIntersectionVisibility(True)
outputModel.GetDisplayNode().SetColor(1, 1, 0)
markupsToModel = slicer.mrmlScene.AddNode(
slicer.vtkMRMLMarkupsToModelNode())
markupsToModel.SetAutoUpdateOutput(True)
markupsToModel.SetAndObserveModelNodeID(outputModel.GetID())
markupsToModel.SetAndObserveMarkupsNodeID(fidNode.GetID())
markupsToModel.SetModelType(slicer.vtkMRMLMarkupsToModelNode.Curve)
markupsToModel.SetCurveType(
slicer.vtkMRMLMarkupsToModelNode.CardinalSpline)
print 'Reconstruction complete'
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 test_LabelMapToModel1(self):
""" Ideally you should have several levels of tests. At the lowest level
tests should exercise the functionality of the logic with different inputs
(both valid and invalid). At higher levels your tests should emulate the
way the user would interact with your code and confirm that it still works
the way you intended.
One of the most important features of the tests is that it should alert other
developers when their changes will have an impact on the behavior of your
module. For example, if a developer removes a feature that you depend on,
your test should break so they know that the feature is needed.
"""
self.delayDisplay("Starting the test")
#
# first, get some data
#
import urllib
downloads = (
('http://slicer.kitware.com/midas3/download?items=153172',
'BrainTumor_GBM_HG0003.mrb', slicer.util.loadScene),
)
for url, name, loader in downloads:
filePath = slicer.app.temporaryPath + '/' + name
if not os.path.exists(filePath) or os.stat(filePath).st_size == 0:
logging.info(
'Requesting download %s from %s...\n' % (name, url))
urllib.urlretrieve(url, filePath)
if loader:
logging.info('Loading %s...' % (name,))
loader(filePath)
self.delayDisplay('Finished with download and loading')
labelMapNode = slicer.util.getNode(pattern="Tissue Segmentation Volume")
logic = LabelMapToModelLogic()
self.assertTrue(logic.hasImageData(labelMapNode))
modelNode = slicer.vtkMRMLModelNode()
logic.run(labelMapNode, modelNode)
self.delayDisplay('Test passed!')
def fiberToModel(self,fiber):
"""Convert a vtkMRMLFiberBundleNode into a dummy vtkMRMLModelNode
so it can use the same converter.
Note: need to use attributes to send color since we cannot
add a display node to the dummy node since it is not in a scene.
If fiberMode is tube, create tubes from fiber tracts, else use lines from tracts
"""
if self.targetFiberCount and int(self.targetFiberCount) < fiber.GetPolyData().GetNumberOfCells():
fiberPolyData = self.copyFirstNLines(fiber.GetPolyData(), int(self.targetFiberCount))
else:
fiberPolyData = fiber.GetPolyData()
model = slicer.vtkMRMLModelNode()
model.SetName("ModelFrom_"+fiber.GetID())
displayNode = None
if self.fiberMode == "tubes":
tuber = vtk.vtkTubeFilter()
tuber.SetInputDataObject(fiberPolyData)
tuber.Update()
polyData = tuber.GetOutput()
model.SetAndObservePolyData(polyData)
normalsArray = polyData.GetPointData().GetArray('TubeNormals')
if not normalsArray:
return None
normalsArray.SetName('Normals')
displayNode = fiber.GetTubeDisplayNode()
elif self.fiberMode == "lines":
model.SetAndObservePolyData(fiberPolyData)
displayNode = fiber.GetLineDisplayNode()
if displayNode:
color = json.dumps(list(displayNode.GetColor()))
model.SetAttribute("color", color)
model.SetAttribute("visibility", str(displayNode.GetVisibility()))
return(model)
notes = """
def __init__(self):
self.toolTipToTool = slicer.util.getNode('toolTipToTool')
if not self.toolTipToTool:
self.toolTipToTool=slicer.vtkMRMLLinearTransformNode()
self.toolTipToTool.SetName("toolTipToTool")
m = vtk.vtkMatrix4x4()
m.SetElement( 0, 0, 1 ) # Row 1
m.SetElement( 0, 1, 0 )
m.SetElement( 0, 2, 0 )
m.SetElement( 0, 3, 0 )
m.SetElement( 1, 0, 0 ) # Row 2
m.SetElement( 1, 1, 1 )
m.SetElement( 1, 2, 0 )
m.SetElement( 1, 3, 0 )
m.SetElement( 2, 0, 0 ) # Row 3
m.SetElement( 2, 1, 0 )
m.SetElement( 2, 2, 1 )
m.SetElement( 2, 3, 0 )
self.toolTipToTool.SetMatrixTransformToParent(m)
slicer.mrmlScene.AddNode(self.toolTipToTool)
self.toolToReference = slicer.util.getNode('toolToReference')
if not self.toolToReference:
self.toolToReference=slicer.vtkMRMLLinearTransformNode()
self.toolToReference.SetName("toolToReference")
matrixRef = vtk.vtkMatrix4x4()
matrixRef.SetElement( 0, 0, 1 ) # Row 1
matrixRef.SetElement( 0, 1, 0 )
matrixRef.SetElement( 0, 2, 0 )
matrixRef.SetElement( 0, 3, 0 )
matrixRef.SetElement( 1, 0, 0 ) # Row 2
matrixRef.SetElement( 1, 1, 1 )
matrixRef.SetElement( 1, 2, 0 )
matrixRef.SetElement( 1, 3, 0 )
matrixRef.SetElement( 2, 0, 0 ) # Row 3
matrixRef.SetElement( 2, 1, 0 )
matrixRef.SetElement( 2, 2, 1 )
matrixRef.SetElement( 2, 3, 0 )
self.toolToReference.SetMatrixTransformToParent(matrixRef)
slicer.mrmlScene.AddNode(self.toolToReference)
self.tipFiducial = slicer.util.getNode('Tip')
if not self.tipFiducial:
self.tipFiducial = slicer.vtkMRMLMarkupsFiducialNode()
self.tipFiducial.SetName('Tip')
self.tipFiducial.AddFiducial(0, 0, 0)
self.tipFiducial.SetNthFiducialLabel(0, '')
slicer.mrmlScene.AddNode(self.tipFiducial)
self.tipFiducial.SetDisplayVisibility(True)
self.tipFiducial.GetDisplayNode().SetGlyphType(1) # Vertex2D
self.tipFiducial.GetDisplayNode().SetTextScale(1.3)
self.tipFiducial.GetDisplayNode().SetSelectedColor(1,1,1)
self.targetFiducial = slicer.util.getNode('Target')
if not self.targetFiducial:
self.targetFiducial = slicer.vtkMRMLMarkupsFiducialNode()
self.targetFiducial.SetName('Target')
self.targetFiducial.AddFiducial(0, 0, 0)
self.targetFiducial.SetNthFiducialLabel(0, '')
slicer.mrmlScene.AddNode(self.targetFiducial)
self.targetFiducial.SetDisplayVisibility(True)
self.targetFiducial.GetDisplayNode().SetGlyphType(1) # Vertex2D
self.targetFiducial.GetDisplayNode().SetTextScale(1.3)
self.targetFiducial.GetDisplayNode().SetSelectedColor(1,1,1)
self.line = slicer.util.getNode('Line')
if not self.line:
self.line = slicer.vtkMRMLModelNode()
self.line.SetName('Line')
linePolyData = vtk.vtkPolyData()
self.line.SetAndObservePolyData(linePolyData)
modelDisplay = slicer.vtkMRMLModelDisplayNode()
modelDisplay.SetSliceIntersectionVisibility(True)
modelDisplay.SetColor(0,1,0)
slicer.mrmlScene.AddNode(modelDisplay)
self.line.SetAndObserveDisplayNodeID(modelDisplay.GetID())
slicer.mrmlScene.AddNode(self.line)
# VTK objects
self.transformPolyDataFilter = vtk.vtkTransformPolyDataFilter()
self.cellLocator = vtk.vtkCellLocator()
# 3D View
threeDWidget = slicer.app.layoutManager().threeDWidget(0)
self.threeDView = threeDWidget.threeDView()
self.callbackObserverTag = -1
self.observerTag=None
# Output Distance Label
self.outputDistanceLabel=None
import Viewpoint # Viewpoint Module must have been added to Slicer
self.viewpointLogic = Viewpoint.ViewpointLogic()
# Camera transformations
self.needleCameraToNeedle = slicer.util.getNode('needleCameraToNeedle')
if not self.needleCameraToNeedle:
self.needleCameraToNeedle=slicer.vtkMRMLLinearTransformNode()
self.needleCameraToNeedle.SetName("needleCameraToNeedle")
matrixNeedleCamera = vtk.vtkMatrix4x4()
matrixNeedleCamera.SetElement( 0, 0, -0.05 ) # Row 1
matrixNeedleCamera.SetElement( 0, 1, 0.09 )
matrixNeedleCamera.SetElement( 0, 2, -0.99 )
matrixNeedleCamera.SetElement( 0, 3, 60.72 )
matrixNeedleCamera.SetElement( 1, 0, -0.01 ) # Row 2
matrixNeedleCamera.SetElement( 1, 1, 1 )
matrixNeedleCamera.SetElement( 1, 2, 0.09 )
matrixNeedleCamera.SetElement( 1, 3, 12.17 )
matrixNeedleCamera.SetElement( 2, 0, 1 ) # Row 3
matrixNeedleCamera.SetElement( 2, 1, 0.01 )
matrixNeedleCamera.SetElement( 2, 2, -0.05 )
matrixNeedleCamera.SetElement( 2, 3, -7.26 )
self.needleCameraToNeedle.SetMatrixTransformToParent(matrixNeedleCamera)
slicer.mrmlScene.AddNode(self.needleCameraToNeedle)
self.pointerCameraToPointer = slicer.util.getNode('pointerCameraToPointer')
if not self.pointerCameraToPointer:
self.pointerCameraToPointer=slicer.vtkMRMLLinearTransformNode()
self.pointerCameraToPointer.SetName("pointerCameraToPointer")
matrixPointerCamera = vtk.vtkMatrix4x4()
matrixPointerCamera.SetElement( 0, 0, -0.05 ) # Row 1
matrixPointerCamera.SetElement( 0, 1, 0.09 )
matrixPointerCamera.SetElement( 0, 2, -0.99 )
matrixPointerCamera.SetElement( 0, 3, 121.72 )
matrixPointerCamera.SetElement( 1, 0, -0.01 ) # Row 2
matrixPointerCamera.SetElement( 1, 1, 1 )
matrixPointerCamera.SetElement( 1, 2, 0.09 )
matrixPointerCamera.SetElement( 1, 3, 17.17 )
matrixPointerCamera.SetElement( 2, 0, 1 ) # Row 3
matrixPointerCamera.SetElement( 2, 1, 0.01 )
matrixPointerCamera.SetElement( 2, 2, -0.05 )
matrixPointerCamera.SetElement( 2, 3, -7.26 )
self.pointerCameraToPointer.SetMatrixTransformToParent(matrixPointerCamera)
slicer.mrmlScene.AddNode(self.pointerCameraToPointer)
def __init__(self):
self.toolTipToTool = slicer.util.getNode('toolTipToTool')
self.pointerTipToReference = None
self.targetCreatedTransformed = False
self.firstFiducial = True
if not self.toolTipToTool:
self.toolTipToTool=slicer.vtkMRMLLinearTransformNode()
self.toolTipToTool.SetName("toolTipToTool")
m = vtk.vtkMatrix4x4()
m.SetElement( 0, 0, 1 ) # Row 1
m.SetElement( 0, 1, 0 )
m.SetElement( 0, 2, 0 )
m.SetElement( 0, 3, 0 )
m.SetElement( 1, 0, 0 ) # Row 2
m.SetElement( 1, 1, 1 )
m.SetElement( 1, 2, 0 )
m.SetElement( 1, 3, 0 )
m.SetElement( 2, 0, 0 ) # Row 3
m.SetElement( 2, 1, 0 )
m.SetElement( 2, 2, 1 )
m.SetElement( 2, 3, 0 )
self.toolTipToTool.SetMatrixTransformToParent(m)
slicer.mrmlScene.AddNode(self.toolTipToTool)
self.line = slicer.util.getNode('Line')
if not self.line:
self.line = slicer.vtkMRMLModelNode()
self.line.SetName('Line')
linePolyData = vtk.vtkPolyData()
self.line.SetAndObservePolyData(linePolyData)
modelDisplay = slicer.vtkMRMLModelDisplayNode()
modelDisplay.SetSliceIntersectionVisibility(True)
modelDisplay.SetColor(0,1,0)
slicer.mrmlScene.AddNode(modelDisplay)
self.line.SetAndObserveDisplayNodeID(modelDisplay.GetID())
slicer.mrmlScene.AddNode(self.line)
# VTK objects
self.transformPolyDataFilter = vtk.vtkTransformPolyDataFilter()
self.cellLocator = vtk.vtkCellLocator()
# 3D View
threeDWidget = slicer.app.layoutManager().threeDWidget(0)
self.threeDView = threeDWidget.threeDView()
self.callbackObserverTag = -1
self.observerTag=None
# Output Distance Label
self.outputDistanceLabel=None
import Viewpoint # Viewpoint Module must have been added to Slicer
self.viewpointLogic = Viewpoint.ViewpointLogic()
# Camera transformations
self.needleCameraToNeedle = slicer.util.getNode('needleCameraToNeedle')
if not self.needleCameraToNeedle:
self.needleCameraToNeedle=slicer.vtkMRMLLinearTransformNode()
self.needleCameraToNeedle.SetName("needleCameraToNeedle")
matrixNeedleCamera = vtk.vtkMatrix4x4()
matrixNeedleCamera.SetElement( 0, 0, -0.05 ) # Row 1
matrixNeedleCamera.SetElement( 0, 1, 0.09 )
matrixNeedleCamera.SetElement( 0, 2, -0.99 )
matrixNeedleCamera.SetElement( 0, 3, 60.72 )
matrixNeedleCamera.SetElement( 1, 0, -0.01 ) # Row 2
matrixNeedleCamera.SetElement( 1, 1, 1 )
matrixNeedleCamera.SetElement( 1, 2, 0.09 )
matrixNeedleCamera.SetElement( 1, 3, 12.17 )
matrixNeedleCamera.SetElement( 2, 0, 1 ) # Row 3
matrixNeedleCamera.SetElement( 2, 1, 0.01 )
matrixNeedleCamera.SetElement( 2, 2, -0.05 )
matrixNeedleCamera.SetElement( 2, 3, -7.26 )
self.needleCameraToNeedle.SetMatrixTransformToParent(matrixNeedleCamera)
slicer.mrmlScene.AddNode(self.needleCameraToNeedle)
self.pointerCameraToPointer = slicer.util.getNode('pointerCameraToPointer')
if not self.pointerCameraToPointer:
self.pointerCameraToPointer=slicer.vtkMRMLLinearTransformNode()
self.pointerCameraToPointer.SetName("pointerCameraToPointer")
matrixPointerCamera = vtk.vtkMatrix4x4()
matrixPointerCamera.SetElement( 0, 0, -0.05 ) # Row 1
matrixPointerCamera.SetElement( 0, 1, 0.09 )
matrixPointerCamera.SetElement( 0, 2, -0.99 )
matrixPointerCamera.SetElement( 0, 3, 121.72 )
matrixPointerCamera.SetElement( 1, 0, -0.01 ) # Row 2
matrixPointerCamera.SetElement( 1, 1, 1 )
matrixPointerCamera.SetElement( 1, 2, 0.09 )
matrixPointerCamera.SetElement( 1, 3, 17.17 )
matrixPointerCamera.SetElement( 2, 0, 1 ) # Row 3
matrixPointerCamera.SetElement( 2, 1, 0.01 )
matrixPointerCamera.SetElement( 2, 2, -0.05 )
matrixPointerCamera.SetElement( 2, 3, -7.26 )
self.pointerCameraToPointer.SetMatrixTransformToParent(matrixPointerCamera)
slicer.mrmlScene.AddNode(self.pointerCameraToPointer)
# Tranformations to fix models orientation
self.needleModelToNeedleTip = slicer.util.getNode('needleModelToNeedleTip')
if not self.needleModelToNeedleTip:
self.needleModelToNeedleTip=slicer.vtkMRMLLinearTransformNode()
self.needleModelToNeedleTip.SetName("needleModelToNeedleTip")
matrixNeedleModel = vtk.vtkMatrix4x4()
matrixNeedleModel.SetElement( 0, 0, -1 ) # Row 1
matrixNeedleModel.SetElement( 0, 1, 0 )
matrixNeedleModel.SetElement( 0, 2, 0 )
matrixNeedleModel.SetElement( 0, 3, 0 )
matrixNeedleModel.SetElement( 1, 0, 0 ) # Row 2
matrixNeedleModel.SetElement( 1, 1, 1 )
matrixNeedleModel.SetElement( 1, 2, 0 )
matrixNeedleModel.SetElement( 1, 3, 0 )
matrixNeedleModel.SetElement( 2, 0, 0 ) # Row 3
matrixNeedleModel.SetElement( 2, 1, 0 )
matrixNeedleModel.SetElement( 2, 2, -1 )
matrixNeedleModel.SetElement( 2, 3, 0 )
self.needleModelToNeedleTip.SetMatrixTransformToParent(matrixNeedleModel)
slicer.mrmlScene.AddNode(self.needleModelToNeedleTip)
self.pointerModelToPointerTip = slicer.util.getNode('pointerModelToPointerTip')
if not self.pointerModelToPointerTip:
self.pointerModelToPointerTip=slicer.vtkMRMLLinearTransformNode()
self.pointerModelToPointerTip.SetName("pointerModelToPointerTip")
matrixPointerModel = vtk.vtkMatrix4x4()
matrixPointerModel.SetElement( 0, 0, 0 ) # Row 1
matrixPointerModel.SetElement( 0, 1, 0 )
matrixPointerModel.SetElement( 0, 2, 1 )
matrixPointerModel.SetElement( 0, 3, 0 )
matrixPointerModel.SetElement( 1, 0, 0 ) # Row 2
matrixPointerModel.SetElement( 1, 1, 1 )
matrixPointerModel.SetElement( 1, 2, 0 )
matrixPointerModel.SetElement( 1, 3, 0 )
matrixPointerModel.SetElement( 2, 0, -1 ) # Row 3
matrixPointerModel.SetElement( 2, 1, 0 )
matrixPointerModel.SetElement( 2, 2, 0 )
matrixPointerModel.SetElement( 2, 3, 0 )
self.pointerModelToPointerTip.SetMatrixTransformToParent(matrixPointerModel)
slicer.mrmlScene.AddNode(self.pointerModelToPointerTip)
self.fRBLToSLPR = slicer.util.getNode('FRBLToSLPR')
if not self.fRBLToSLPR:
self.fRBLToSLPR = slicer.vtkMRMLLinearTransformNode()
self.fRBLToSLPR.SetName('FRBLToSLPR')
slicer.mrmlScene.AddNode(self.fRBLToSLPR)
# Create fiducials to orientate model
self.fiducialsFRBL = slicer.util.getNode('FiducialsFRBL')
if not self.fiducialsFRBL:
self.fiducialsFRBL = slicer.vtkMRMLMarkupsFiducialNode()
self.fiducialsFRBL.SetName('FiducialsFRBL')
slicer.mrmlScene.AddNode(self.fiducialsFRBL)
self.fiducialsFRBL.SetDisplayVisibility(False)
self.fiducialsSLPR = slicer.util.getNode('FiducialsSLPR')
if not self.fiducialsSLPR:
self.fiducialsSLPR = slicer.vtkMRMLMarkupsFiducialNode()
self.fiducialsSLPR.SetName('FiducialsSLPR')
self.fiducialsSLPR.AddFiducial(0, 100, 0)
self.fiducialsSLPR.SetNthFiducialLabel(0, 'S')
self.fiducialsSLPR.AddFiducial(-100, 0, 0)
self.fiducialsSLPR.SetNthFiducialLabel(1, 'L')
self.fiducialsSLPR.AddFiducial(0, -100, 0)
self.fiducialsSLPR.SetNthFiducialLabel(2, 'P')
self.fiducialsSLPR.AddFiducial(100, 0, 0)
self.fiducialsSLPR.SetNthFiducialLabel(3, 'R')
slicer.mrmlScene.AddNode(self.fiducialsSLPR)
self.fiducialsSLPR.SetDisplayVisibility(False)
def test_3D_interaction2Models(self):
""" Test that the interaction widget works with multiple models.
"""
#self.delayDisplay("Starting test_3D_interaction2Models")
#
# Setup:
# 1. Create 2 cubes:
# - 1 centered
# - Another moved.
# 2. Get the widget
#
# Centered cube
centeredCubeSource = vtk.vtkCubeSource()
centeredCubeSize = [500, 200, 300]
centeredCubeSource.SetXLength(centeredCubeSize[0])
centeredCubeSource.SetYLength(centeredCubeSize[1])
centeredCubeSource.SetZLength(centeredCubeSize[2])
centeredCubeSource.SetCenter(0.0, 0.0, 0.0)
centeredCubeSource.Update()
centeredCubeNode = slicer.mrmlScene.AddNode(slicer.vtkMRMLModelNode())
centeredCubeNode.SetPolyDataConnection(centeredCubeSource.GetOutputPort())
# Moved cube
movedCubeSource = vtk.vtkCubeSource()
movedCubeSource.SetXLength(800)
movedCubeSource.SetYLength(233)
movedCubeSource.SetZLength(761)
movedCubeSource.SetCenter(100.0, -80.0, -700.023)
rotation = vtk.vtkTransform()
rotation.RotateY(45.0)
applyTransform = vtk.vtkTransformPolyDataFilter()
applyTransform.SetTransform(rotation)
applyTransform.SetInputConnection(movedCubeSource.GetOutputPort())
applyTransform.Update()
movedCubeNode = slicer.mrmlScene.AddNode(slicer.vtkMRMLModelNode())
movedCubeNode.SetPolyDataConnection(applyTransform.GetOutputPort())
# Get the widget
logic = SlicerTransformInteractionTest1Logic()
tNode, tdNode = logic.addTransform()
slicer.app.layoutManager().layout = slicer.vtkMRMLLayoutNode.SlicerLayoutOneUp3DView
manager = logic.getModel3DDisplayableManager()
self.assertIsNotNone(manager)
widget = manager.GetWidget(tdNode)
tdNode.SetEditorVisibility(True)
self.assertTrue(widget.GetEnabled())
representation = widget.GetRepresentation()
transform = vtk.vtkTransform()
#
# No transform, make sure the widget is correctly placed around:
# 1. No cubes
# 2. The centered cube
# 3. The centered cube AND the other cube
# 4. The other cube only
# 5. No cubes
#
# Check default widget tranform values
expectedDefaultTransform = [
[100.0, 0.0, 0.0, 0.0],
[0.0, 100.0, 0.0, 0.0],
[0.0, 0.0, 100.0, 0.0],
[0.0, 0.0, 0.0, 1.0],
]
representation.GetTransform(transform)
self.assertTransform(transform, expectedDefaultTransform)
# Transform the centered cube
centeredCubeNode.SetAndObserveTransformNodeID(tNode.GetID())
tdNode.UpdateEditorBounds()
centeredCubeTransform = copy.deepcopy(expectedDefaultTransform)
for i in range(3):
centeredCubeTransform[i][i] = 2*centeredCubeSize[i]
representation.GetTransform(transform)
self.assertTransform(transform, centeredCubeTransform)
# Transform both cubes
movedCubeNode.SetAndObserveTransformNodeID(tNode.GetID())
tdNode.UpdateEditorBounds()
bothCubeTransform = [
[2452.35424805, 0.0, 0.0, -363.088562012],
[0.0, 593.0, 0.0, -48.25],
[0.0, 0.0, 2535.19702148, -483.799255371],
[0.0, 0.0, 0.0, 1.0],
]
representation.GetTransform(transform)
self.assertTransform(transform, bothCubeTransform)
# Transform only moved cube
centeredCubeNode.SetAndObserveTransformNodeID(None)
tdNode.UpdateEditorBounds()
movedCubeTransform = [
[2207.58724976, 0.0, 0.0, -424.280311584],
[0.0, 466.0, 0.0, -80.0],
[0.0, 0.0, 2207.58731651, -565.701681614],
[0.0, 0.0, 0.0, 1.0],
]
representation.GetTransform(transform)
self.assertTransform(transform, movedCubeTransform)
# Default again
movedCubeNode.SetAndObserveTransformNodeID(None)
tdNode.UpdateEditorBounds()
representation.GetTransform(transform)
self.assertTransform(transform, expectedDefaultTransform)
def createCone(self):
#f = slicer.util.getNode('Target')
self.pos = [0,0,0]
self.pos1 = [0,0,0]
self.targetFiducial.GetNthFiducialPosition(0,self.pos)
self.targetFiducial.GetNthFiducialPosition(1,self.pos1)
# Create a vtkPoints object and store the points in it
points = vtk.vtkPoints()
points.InsertNextPoint(self.pos)
points.InsertNextPoint(self.pos1)
# Create line
line = vtk.vtkLine()
line.GetPointIds().SetId(0,0)
line.GetPointIds().SetId(1,1)
lineCellArray = vtk.vtkCellArray()
lineCellArray.InsertNextCell(line)
self.lineNode = slicer.vtkMRMLModelNode()
self.lineNode.SetName('Line')
linePolyData = vtk.vtkPolyData()
self.lineNode.SetAndObservePolyData(linePolyData)
modelDisplay = slicer.vtkMRMLModelDisplayNode()
modelDisplay.SetSliceIntersectionVisibility(True)
modelDisplay.SetColor(0,0,1)
slicer.mrmlScene.AddNode(modelDisplay)
self.lineNode.SetAndObserveDisplayNodeID(modelDisplay.GetID())
slicer.mrmlScene.AddNode(self.lineNode)
self.lineNode.GetPolyData().SetPoints(points)
self.lineNode.GetPolyData().SetLines(lineCellArray)
self.cone = vtk.vtkConeSource()
self.cone = vtk.vtkConeSource()
self.cone.SetResolution(50)
self.cone.SetRadius(20)
vector = np.subtract(self.pos,self.pos1)
self.cone.SetDirection([vector[0],vector[1],vector[2]])
dist = np.linalg.norm(vector)
self.cone.SetHeight(dist)
self.coneModel = slicer.vtkMRMLModelNode()
self.coneModel.SetName('Cone')
self.coneModel.SetPolyDataConnection(self.cone.GetOutputPort())
slicer.mrmlScene.AddNode(self.coneModel)
modelDisplay1 = slicer.vtkMRMLModelDisplayNode()
modelDisplay1.SetSliceIntersectionVisibility(True)
modelDisplay1.SetColor(0,1,1)
modelDisplay1.SetOpacity(0.30)
slicer.mrmlScene.AddNode(modelDisplay1)
self.coneModel.SetAndObserveDisplayNodeID(modelDisplay1.GetID())
slicer.mrmlScene.AddNode(self.coneModel)
x3 = [(self.pos1[0]-self.pos[0])/2 + self.pos[0], (self.pos1[1]-self.pos[1])/2 +self.pos[1], (self.pos1[2]-self.pos[2])/2 +self.pos[2]]
self.cone.SetCenter(x3)
def TestSection_3_ImportExportSegment(self):
# Import/export, both one label and all labels
logging.info('Test section 3: Import/export segment')
# Export single segment to model node
bodyModelNode = slicer.vtkMRMLModelNode()
bodyModelNode.SetName('BodyModel')
slicer.mrmlScene.AddNode(bodyModelNode)
bodySegment = self.inputSegmentationNode.GetSegmentation().GetSegment('Body_Contour')
result = vtkSlicerSegmentationsModuleLogic.ExportSegmentToRepresentationNode(bodySegment, bodyModelNode)
self.assertTrue(result)
self.assertIsNotNone(bodyModelNode.GetPolyData())
self.assertEqual(bodyModelNode.GetPolyData().GetNumberOfPoints(), 302)
#TODO: On Linux and Windows it is 588, on Mac it is 580. Need to investigate
# self.assertEqual(bodyModelNode.GetPolyData().GetNumberOfCells(), 588)
self.assertTrue(bodyModelNode.GetPolyData().GetNumberOfCells() == 588 or bodyModelNode.GetPolyData().GetNumberOfCells() == 580)
# Export single segment to volume node
bodyLabelmapNode = slicer.vtkMRMLLabelMapVolumeNode()
bodyLabelmapNode.SetName('BodyLabelmap')
slicer.mrmlScene.AddNode(bodyLabelmapNode)
result = vtkSlicerSegmentationsModuleLogic.ExportSegmentToRepresentationNode(bodySegment, bodyLabelmapNode)
self.assertTrue(result)
bodyImageData = bodyLabelmapNode.GetImageData()
self.assertIsNotNone(bodyImageData)
imageStat = vtk.vtkImageAccumulate()
imageStat.SetInputData(bodyImageData)
imageStat.Update()
self.assertEqual(imageStat.GetVoxelCount(), 648)
self.assertEqual(imageStat.GetMin()[0], 0)
self.assertEqual(imageStat.GetMax()[0], 1)
# Export multiple segments to volume node
allSegmentsLabelmapNode = slicer.vtkMRMLLabelMapVolumeNode()
allSegmentsLabelmapNode.SetName('AllSegmentsLabelmap')
slicer.mrmlScene.AddNode(allSegmentsLabelmapNode)
result = vtkSlicerSegmentationsModuleLogic.ExportAllSegmentsToLabelmapNode(self.inputSegmentationNode, allSegmentsLabelmapNode)
self.assertTrue(result)
allSegmentsImageData = allSegmentsLabelmapNode.GetImageData()
self.assertIsNotNone(allSegmentsImageData)
imageStat = vtk.vtkImageAccumulate()
imageStat.SetInputData(allSegmentsImageData)
imageStat.SetComponentExtent(0,5,0,0,0,0)
imageStat.SetComponentOrigin(0,0,0)
imageStat.SetComponentSpacing(1,1,1)
imageStat.Update()
self.assertEqual(imageStat.GetVoxelCount(), 54872000)
imageStatResult = imageStat.GetOutput()
self.assertEqual(imageStatResult.GetScalarComponentAsDouble(0,0,0,0), 46678738)
self.assertEqual(imageStatResult.GetScalarComponentAsDouble(1,0,0,0), 0)
self.assertEqual(imageStatResult.GetScalarComponentAsDouble(2,0,0,0), 7618805)
self.assertEqual(imageStatResult.GetScalarComponentAsDouble(3,0,0,0), 128968)
self.assertEqual(imageStatResult.GetScalarComponentAsDouble(4,0,0,0), 0) # Built from color table and color four is removed in previous test section
self.assertEqual(imageStatResult.GetScalarComponentAsDouble(5,0,0,0), 445489)
# Import model to segment
modelImportSegmentationNode = vtkMRMLSegmentationNode()
modelImportSegmentationNode.SetName('ModelImport')
modelImportSegmentationNode.GetSegmentation().SetMasterRepresentationName(self.closedSurfaceReprName)
slicer.mrmlScene.AddNode(modelImportSegmentationNode)
modelSegment = vtkSlicerSegmentationsModuleLogic.CreateSegmentFromModelNode(bodyModelNode)
modelSegment.UnRegister(None) # Need to release ownership
self.assertIsNotNone(modelSegment)
self.assertIsNotNone(modelSegment.GetRepresentation(self.closedSurfaceReprName))
# Import multi-label labelmap to segmentation
multiLabelImportSegmentationNode = vtkMRMLSegmentationNode()
multiLabelImportSegmentationNode.SetName('MultiLabelImport')
multiLabelImportSegmentationNode.GetSegmentation().SetMasterRepresentationName(self.binaryLabelmapReprName)
slicer.mrmlScene.AddNode(multiLabelImportSegmentationNode)
result = vtkSlicerSegmentationsModuleLogic.ImportLabelmapToSegmentationNode(allSegmentsLabelmapNode, multiLabelImportSegmentationNode)
self.assertTrue(result)
self.assertEqual(multiLabelImportSegmentationNode.GetSegmentation().GetNumberOfSegments(), 3)
# Import labelmap into single segment
singleLabelImportSegmentationNode = vtkMRMLSegmentationNode()
singleLabelImportSegmentationNode.SetName('SingleLabelImport')
singleLabelImportSegmentationNode.GetSegmentation().SetMasterRepresentationName(self.binaryLabelmapReprName)
slicer.mrmlScene.AddNode(singleLabelImportSegmentationNode)
# Should not import multi-label labelmap to segment
nullSegment = vtkSlicerSegmentationsModuleLogic.CreateSegmentFromLabelmapVolumeNode(allSegmentsLabelmapNode)
self.assertIsNone(nullSegment)
logging.info('(This error message tests an impossible scenario, it is supposed to appear)')
# Make labelmap single-label and import again
threshold = vtk.vtkImageThreshold()
threshold.ThresholdByUpper(0.5)
threshold.SetInValue(1)
threshold.SetOutValue(0)
threshold.SetOutputScalarType(vtk.VTK_UNSIGNED_CHAR)
if vtk.VTK_MAJOR_VERSION <= 5:
threshold.SetInput(allSegmentsLabelmapNode.GetImageData())
else:
threshold.SetInputData(allSegmentsLabelmapNode.GetImageData())
threshold.SetOutput(allSegmentsLabelmapNode.GetImageData())
threshold.Update()
labelSegment = vtkSlicerSegmentationsModuleLogic.CreateSegmentFromLabelmapVolumeNode(allSegmentsLabelmapNode)
labelSegment.UnRegister(None) # Need to release ownership
self.assertIsNotNone(labelSegment)
self.assertIsNotNone(labelSegment.GetRepresentation(self.binaryLabelmapReprName))
# Import/export with transforms
logging.info('Test section 4/2: Import/export with transforms')
# Create transform node that will be used to transform the tested nodes
bodyModelTransformNode = slicer.vtkMRMLLinearTransformNode()
slicer.mrmlScene.AddNode(bodyModelTransformNode)
bodyModelTransform = vtk.vtkTransform()
bodyModelTransform.Translate(1000.0, 0.0, 0.0)
bodyModelTransformNode.ApplyTransformMatrix(bodyModelTransform.GetMatrix())
# Set transform as parent to input segmentation node
self.inputSegmentationNode.SetAndObserveTransformNodeID(bodyModelTransformNode.GetID())
# Export single segment to model node from transformed segmentation
bodyModelNodeTransformed = slicer.vtkMRMLModelNode()
bodyModelNodeTransformed.SetName('BodyModelTransformed')
slicer.mrmlScene.AddNode(bodyModelNodeTransformed)
bodySegment = self.inputSegmentationNode.GetSegmentation().GetSegment('Body_Contour')
result = vtkSlicerSegmentationsModuleLogic.ExportSegmentToRepresentationNode(bodySegment, bodyModelNodeTransformed)
self.assertTrue(result)
self.assertIsNotNone(bodyModelNodeTransformed.GetParentTransformNode())
# Export single segment to volume node from transformed segmentation
bodyLabelmapNodeTransformed = slicer.vtkMRMLLabelMapVolumeNode()
bodyLabelmapNodeTransformed.SetName('BodyLabelmapTransformed')
slicer.mrmlScene.AddNode(bodyLabelmapNodeTransformed)
result = vtkSlicerSegmentationsModuleLogic.ExportSegmentToRepresentationNode(bodySegment, bodyLabelmapNodeTransformed)
self.assertTrue(result)
self.assertIsNotNone(bodyLabelmapNodeTransformed.GetParentTransformNode())
# Create transform node that will be used to transform the tested nodes
modelTransformedImportSegmentationTransformNode = slicer.vtkMRMLLinearTransformNode()
slicer.mrmlScene.AddNode(modelTransformedImportSegmentationTransformNode)
modelTransformedImportSegmentationTransform = vtk.vtkTransform()
modelTransformedImportSegmentationTransform.Translate(-500.0, 0.0, 0.0)
modelTransformedImportSegmentationTransformNode.ApplyTransformMatrix(modelTransformedImportSegmentationTransform.GetMatrix())
# Import transformed model to segment in transformed segmentation
modelTransformedImportSegmentationNode = vtkMRMLSegmentationNode()
modelTransformedImportSegmentationNode.SetName('ModelImportTransformed')
modelTransformedImportSegmentationNode.GetSegmentation().SetMasterRepresentationName(self.closedSurfaceReprName)
slicer.mrmlScene.AddNode(modelTransformedImportSegmentationNode)
modelTransformedImportSegmentationNode.SetAndObserveTransformNodeID(modelTransformedImportSegmentationTransformNode.GetID())
modelSegmentTranformed = vtkSlicerSegmentationsModuleLogic.CreateSegmentFromModelNode(bodyModelNodeTransformed, modelTransformedImportSegmentationNode)
modelSegmentTranformed.UnRegister(None) # Need to release ownership
self.assertIsNotNone(modelSegmentTranformed)
modelSegmentTransformedPolyData = modelSegmentTranformed.GetRepresentation(self.closedSurfaceReprName)
self.assertIsNotNone(modelSegmentTransformedPolyData)
self.assertEqual(int(modelSegmentTransformedPolyData.GetBounds()[0]), 1332)
self.assertEqual(int(modelSegmentTransformedPolyData.GetBounds()[1]), 1675)
# Clean up temporary nodes
slicer.mrmlScene.RemoveNode(bodyModelNode)
slicer.mrmlScene.RemoveNode(bodyLabelmapNode)
slicer.mrmlScene.RemoveNode(allSegmentsLabelmapNode)
slicer.mrmlScene.RemoveNode(modelImportSegmentationNode)
slicer.mrmlScene.RemoveNode(multiLabelImportSegmentationNode)
slicer.mrmlScene.RemoveNode(singleLabelImportSegmentationNode)
slicer.mrmlScene.RemoveNode(bodyModelTransformNode)
slicer.mrmlScene.RemoveNode(bodyModelNodeTransformed)
slicer.mrmlScene.RemoveNode(bodyLabelmapNodeTransformed)
slicer.mrmlScene.RemoveNode(modelTransformedImportSegmentationNode)
def __init__(self, path, fiducialListNode):
fids = fiducialListNode
scene = slicer.mrmlScene
points = vtk.vtkPoints()
polyData = vtk.vtkPolyData()
polyData.SetPoints(points)
lines = vtk.vtkCellArray()
polyData.SetLines(lines)
linesIDArray = lines.GetData()
linesIDArray.Reset()
linesIDArray.InsertNextTuple1(0)
polygons = vtk.vtkCellArray()
polyData.SetPolys( polygons )
idArray = polygons.GetData()
idArray.Reset()
idArray.InsertNextTuple1(0)
for point in path:
pointIndex = points.InsertNextPoint(*point)
linesIDArray.InsertNextTuple1(pointIndex)
linesIDArray.SetTuple1( 0, linesIDArray.GetNumberOfTuples() - 1 )
lines.SetNumberOfCells(1)
# Create model node
model = slicer.vtkMRMLModelNode()
model.SetScene(scene)
model.SetName(scene.GenerateUniqueName("Path-%s" % fids.GetName()))
model.SetAndObservePolyData(polyData)
# Create display node
modelDisplay = slicer.vtkMRMLModelDisplayNode()
modelDisplay.SetColor(1,1,0) # yellow
modelDisplay.SetScene(scene)
scene.AddNode(modelDisplay)
model.SetAndObserveDisplayNodeID(modelDisplay.GetID())
# Add to scene
if vtk.VTK_MAJOR_VERSION <= 5:
# shall not be needed.
modelDisplay.SetInputPolyData(model.GetPolyData())
scene.AddNode(model)
# Camera cursor
sphere = vtk.vtkSphereSource()
sphere.Update()
# Create model node
cursor = slicer.vtkMRMLModelNode()
cursor.SetScene(scene)
cursor.SetName(scene.GenerateUniqueName("Cursor-%s" % fids.GetName()))
if vtk.VTK_MAJOR_VERSION <= 5:
cursor.SetAndObservePolyData(sphere.GetOutput())
else:
cursor.SetPolyDataConnection(sphere.GetOutputPort())
# Create display node
cursorModelDisplay = slicer.vtkMRMLModelDisplayNode()
cursorModelDisplay.SetColor(1,0,0) # red
cursorModelDisplay.SetScene(scene)
scene.AddNode(cursorModelDisplay)
cursor.SetAndObserveDisplayNodeID(cursorModelDisplay.GetID())
# Add to scene
if vtk.VTK_MAJOR_VERSION <= 5:
# Shall not be needed.
cursorModelDisplay.SetInputPolyData(sphere.GetOutput())
scene.AddNode(cursor)
# Create transform node
transform = slicer.vtkMRMLLinearTransformNode()
transform.SetName(scene.GenerateUniqueName("Transform-%s" % fids.GetName()))
scene.AddNode(transform)
cursor.SetAndObserveTransformNodeID(transform.GetID())
self.transform = transform
def transform(self,cmd):
if not hasattr(self,'p'):
self.p = numpy.zeros(3)
self.dpdt = numpy.zeros(3)
self.d2pdt2 = numpy.zeros(3)
self.o = numpy.zeros(3)
self.dodt = numpy.zeros(3)
self.d2odt2 = numpy.zeros(3)
p = urlparse.urlparse(cmd)
q = urlparse.parse_qs(p.query)
print (q)
dt = float(q['interval'][0])
self.d2pdt2 = 1000 * numpy.array([float(q['x'][0]), float(q['y'][0]), float(q['z'][0])])
if not hasattr(self,'g0'):
self.g0 = self.d2pdt2
self.d2pdt2 = self.d2pdt2 - self.g0
self.dpdt = self.dpdt + dt * self.d2pdt2
self.p = self.p + dt * self.dpdt
# TODO: integrate rotations
if not hasattr(self, "idevice"):
""" set up the mrml parts or use existing """
nodes = slicer.mrmlScene.GetNodesByName('idevice')
if nodes.GetNumberOfItems() > 0:
self.idevice = nodes.GetItemAsObject(0)
nodes = slicer.mrmlScene.GetNodesByName('tracker')
self.tracker = nodes.GetItemAsObject(0)
else:
# idevice cursor
self.cube = vtk.vtkCubeSource()
self.cube.SetXLength(30)
self.cube.SetYLength(70)
self.cube.SetZLength(5)
self.cube.Update()
# display node
self.modelDisplay = slicer.vtkMRMLModelDisplayNode()
self.modelDisplay.SetColor(1,1,0) # yellow
slicer.mrmlScene.AddNode(self.modelDisplay)
self.modelDisplay.SetPolyData(self.cube.GetOutput())
# Create model node
self.idevice = slicer.vtkMRMLModelNode()
self.idevice.SetScene(slicer.mrmlScene)
self.idevice.SetName("idevice")
self.idevice.SetAndObservePolyData(self.cube.GetOutput())
self.idevice.SetAndObserveDisplayNodeID(self.modelDisplay.GetID())
slicer.mrmlScene.AddNode(self.idevice)
# tracker
self.tracker = slicer.vtkMRMLLinearTransformNode()
self.tracker.SetName('tracker')
slicer.mrmlScene.AddNode(self.tracker)
self.idevice.SetAndObserveTransformNodeID(self.tracker.GetID())
m = self.tracker.GetMatrixTransformToParent()
m.Identity()
up = numpy.zeros(3)
up[2] = 1
d = self.d2pdt2
dd = d / numpy.sqrt(numpy.dot(d,d))
xx = numpy.cross(dd,up)
yy = numpy.cross(dd,xx)
for row in xrange(3):
m.SetElement(row,0, dd[row])
m.SetElement(row,1, xx[row])
m.SetElement(row,2, yy[row])
#m.SetElement(row,3, self.p[row])
return ( "got it" )
def __init__(self, path, fiducialListNode):
fids = fiducialListNode
scene = slicer.mrmlScene
points = vtk.vtkPoints()
polyData = vtk.vtkPolyData()
polyData.SetPoints(points)
lines = vtk.vtkCellArray()
polyData.SetLines(lines)
linesIDArray = lines.GetData()
linesIDArray.Reset()
linesIDArray.InsertNextTuple1(0)
polygons = vtk.vtkCellArray()
polyData.SetPolys( polygons )
idArray = polygons.GetData()
idArray.Reset()
idArray.InsertNextTuple1(0)
for point in path:
pointIndex = points.InsertNextPoint(*point)
linesIDArray.InsertNextTuple1(pointIndex)
linesIDArray.SetTuple1( 0, linesIDArray.GetNumberOfTuples() - 1 )
lines.SetNumberOfCells(1)
import vtk.util.numpy_support as VN
pointsArray = VN.vtk_to_numpy(points.GetData())
self.planePosition, self.planeNormal = self.planeFit(pointsArray.T)
# Create model node
model = slicer.vtkMRMLModelNode()
model.SetScene(scene)
model.SetName(scene.GenerateUniqueName("Path-%s" % fids.GetName()))
model.SetAndObservePolyData(polyData)
# Create display node
modelDisplay = slicer.vtkMRMLModelDisplayNode()
modelDisplay.SetColor(1,1,0) # yellow
modelDisplay.SetScene(scene)
scene.AddNode(modelDisplay)
model.SetAndObserveDisplayNodeID(modelDisplay.GetID())
# Add to scene
scene.AddNode(model)
# Camera cursor
sphere = vtk.vtkSphereSource()
sphere.Update()
# Create model node
cursor = slicer.vtkMRMLModelNode()
cursor.SetScene(scene)
cursor.SetName(scene.GenerateUniqueName("Cursor-%s" % fids.GetName()))
cursor.SetPolyDataConnection(sphere.GetOutputPort())
# Create display node
cursorModelDisplay = slicer.vtkMRMLModelDisplayNode()
cursorModelDisplay.SetColor(1,0,0) # red
cursorModelDisplay.SetScene(scene)
scene.AddNode(cursorModelDisplay)
cursor.SetAndObserveDisplayNodeID(cursorModelDisplay.GetID())
# Add to scene
scene.AddNode(cursor)
# Create transform node
transform = slicer.vtkMRMLLinearTransformNode()
transform.SetName(scene.GenerateUniqueName("Transform-%s" % fids.GetName()))
scene.AddNode(transform)
cursor.SetAndObserveTransformNodeID(transform.GetID())
self.transform = transform
def TestSection_ImportExportSegment(self):
# Import/export, both one label and all labels
logging.info('Test section: Import/export segment')
# Export single segment to model node
bodyModelNode = slicer.vtkMRMLModelNode()
bodyModelNode.SetName('BodyModel')
slicer.mrmlScene.AddNode(bodyModelNode)
bodySegment = self.inputSegmentationNode.GetSegmentation().GetSegment(self.bodySegmentName)
result = slicer.vtkSlicerSegmentationsModuleLogic.ExportSegmentToRepresentationNode(bodySegment, bodyModelNode)
self.assertTrue(result)
self.assertIsNotNone(bodyModelNode.GetPolyData())
#TODO: Number of points increased to 1677 due to end-capping, need to investigate!
#self.assertEqual(bodyModelNode.GetPolyData().GetNumberOfPoints(), 302)
#TODO: On Linux and Windows it is 588, on Mac it is 580. Need to investigate
# self.assertEqual(bodyModelNode.GetPolyData().GetNumberOfCells(), 588)
#self.assertTrue(bodyModelNode.GetPolyData().GetNumberOfCells() == 588 or bodyModelNode.GetPolyData().GetNumberOfCells() == 580)
# Export single segment to volume node
bodyLabelmapNode = slicer.vtkMRMLLabelMapVolumeNode()
bodyLabelmapNode.SetName('BodyLabelmap')
slicer.mrmlScene.AddNode(bodyLabelmapNode)
result = slicer.vtkSlicerSegmentationsModuleLogic.ExportSegmentToRepresentationNode(bodySegment, bodyLabelmapNode)
self.assertTrue(result)
bodyImageData = bodyLabelmapNode.GetImageData()
self.assertIsNotNone(bodyImageData)
imageStat = vtk.vtkImageAccumulate()
imageStat.SetInputData(bodyImageData)
imageStat.Update()
self.assertEqual(imageStat.GetVoxelCount(), 792)
self.assertEqual(imageStat.GetMin()[0], 0)
self.assertEqual(imageStat.GetMax()[0], 1)
# Export multiple segments to volume node
allSegmentsLabelmapNode = slicer.vtkMRMLLabelMapVolumeNode()
allSegmentsLabelmapNode.SetName('AllSegmentsLabelmap')
slicer.mrmlScene.AddNode(allSegmentsLabelmapNode)
result = slicer.vtkSlicerSegmentationsModuleLogic.ExportAllSegmentsToLabelmapNode(self.inputSegmentationNode, allSegmentsLabelmapNode)
self.assertTrue(result)
allSegmentsImageData = allSegmentsLabelmapNode.GetImageData()
self.assertIsNotNone(allSegmentsImageData)
imageStat = vtk.vtkImageAccumulate()
imageStat.SetInputData(allSegmentsImageData)
imageStat.SetComponentExtent(0,5,0,0,0,0)
imageStat.SetComponentOrigin(0,0,0)
imageStat.SetComponentSpacing(1,1,1)
imageStat.Update()
imageStatResult = imageStat.GetOutput()
for i in range(4):
logging.info("Volume {0}: {1}".format(i, imageStatResult.GetScalarComponentAsDouble(i,0,0,0)))
self.assertEqual(imageStat.GetVoxelCount(), 127109360)
self.assertEqual(imageStatResult.GetScalarComponentAsDouble(0,0,0,0), 78967249)
self.assertEqual(imageStatResult.GetScalarComponentAsDouble(1,0,0,0), 39705288)
self.assertEqual(imageStatResult.GetScalarComponentAsDouble(2,0,0,0), 890883)
self.assertEqual(imageStatResult.GetScalarComponentAsDouble(3,0,0,0), 7545940)
# Import model to segment
modelImportSegmentationNode = slicer.mrmlScene.AddNewNodeByClass('vtkMRMLSegmentationNode', 'ModelImport')
modelImportSegmentationNode.GetSegmentation().SetMasterRepresentationName(self.closedSurfaceReprName)
modelSegment = slicer.vtkSlicerSegmentationsModuleLogic.CreateSegmentFromModelNode(bodyModelNode)
modelSegment.UnRegister(None) # Need to release ownership
self.assertIsNotNone(modelSegment)
self.assertIsNotNone(modelSegment.GetRepresentation(self.closedSurfaceReprName))
# Import multi-label labelmap to segmentation
multiLabelImportSegmentationNode = slicer.mrmlScene.AddNewNodeByClass('vtkMRMLSegmentationNode', 'MultiLabelImport')
multiLabelImportSegmentationNode.GetSegmentation().SetMasterRepresentationName(self.binaryLabelmapReprName)
result = slicer.vtkSlicerSegmentationsModuleLogic.ImportLabelmapToSegmentationNode(allSegmentsLabelmapNode, multiLabelImportSegmentationNode)
self.assertTrue(result)
self.assertEqual(multiLabelImportSegmentationNode.GetSegmentation().GetNumberOfSegments(), 3)
# Import labelmap into single segment
singleLabelImportSegmentationNode = slicer.mrmlScene.AddNewNodeByClass('vtkMRMLSegmentationNode', 'SingleLabelImport')
singleLabelImportSegmentationNode.GetSegmentation().SetMasterRepresentationName(self.binaryLabelmapReprName)
# Should not import multi-label labelmap to segment
nullSegment = slicer.vtkSlicerSegmentationsModuleLogic.CreateSegmentFromLabelmapVolumeNode(allSegmentsLabelmapNode)
self.assertIsNone(nullSegment)
logging.info('(This error message is a result of testing an impossible scenario, it is supposed to appear)')
# Make labelmap single-label and import again
threshold = vtk.vtkImageThreshold()
threshold.SetInValue(0)
threshold.SetOutValue(1)
threshold.ReplaceInOn()
threshold.ThresholdByLower(0)
threshold.SetOutputScalarType(vtk.VTK_UNSIGNED_CHAR)
if vtk.VTK_MAJOR_VERSION <= 5:
threshold.SetInput(allSegmentsLabelmapNode.GetImageData())
else:
threshold.SetInputData(allSegmentsLabelmapNode.GetImageData())
threshold.Update()
allSegmentsLabelmapNode.GetImageData().ShallowCopy(threshold.GetOutput())
labelSegment = slicer.vtkSlicerSegmentationsModuleLogic.CreateSegmentFromLabelmapVolumeNode(allSegmentsLabelmapNode)
labelSegment.UnRegister(None) # Need to release ownership
self.assertIsNotNone(labelSegment)
self.assertIsNotNone(labelSegment.GetRepresentation(self.binaryLabelmapReprName))
# Import/export with transforms
logging.info('Test subsection: Import/export with transforms')
# Create transform node that will be used to transform the tested nodes
bodyModelTransformNode = slicer.vtkMRMLLinearTransformNode()
slicer.mrmlScene.AddNode(bodyModelTransformNode)
bodyModelTransform = vtk.vtkTransform()
bodyModelTransform.Translate(1000.0, 0.0, 0.0)
bodyModelTransformNode.ApplyTransformMatrix(bodyModelTransform.GetMatrix())
# Set transform as parent to input segmentation node
self.inputSegmentationNode.SetAndObserveTransformNodeID(bodyModelTransformNode.GetID())
# Export single segment to model node from transformed segmentation
bodyModelNodeTransformed = slicer.vtkMRMLModelNode()
bodyModelNodeTransformed.SetName('BodyModelTransformed')
slicer.mrmlScene.AddNode(bodyModelNodeTransformed)
bodySegment = self.inputSegmentationNode.GetSegmentation().GetSegment(self.bodySegmentName)
result = slicer.vtkSlicerSegmentationsModuleLogic.ExportSegmentToRepresentationNode(bodySegment, bodyModelNodeTransformed)
self.assertTrue(result)
self.assertIsNotNone(bodyModelNodeTransformed.GetParentTransformNode())
# Export single segment to volume node from transformed segmentation
bodyLabelmapNodeTransformed = slicer.vtkMRMLLabelMapVolumeNode()
bodyLabelmapNodeTransformed.SetName('BodyLabelmapTransformed')
slicer.mrmlScene.AddNode(bodyLabelmapNodeTransformed)
result = slicer.vtkSlicerSegmentationsModuleLogic.ExportSegmentToRepresentationNode(bodySegment, bodyLabelmapNodeTransformed)
self.assertTrue(result)
self.assertIsNotNone(bodyLabelmapNodeTransformed.GetParentTransformNode())
# Create transform node that will be used to transform the tested nodes
modelTransformedImportSegmentationTransformNode = slicer.vtkMRMLLinearTransformNode()
slicer.mrmlScene.AddNode(modelTransformedImportSegmentationTransformNode)
modelTransformedImportSegmentationTransform = vtk.vtkTransform()
modelTransformedImportSegmentationTransform.Translate(-500.0, 0.0, 0.0)
modelTransformedImportSegmentationTransformNode.ApplyTransformMatrix(modelTransformedImportSegmentationTransform.GetMatrix())
# Import transformed model to segment in transformed segmentation
modelTransformedImportSegmentationNode = slicer.mrmlScene.AddNewNodeByClass('vtkMRMLSegmentationNode', 'ModelImportTransformed')
modelTransformedImportSegmentationNode.GetSegmentation().SetMasterRepresentationName(self.closedSurfaceReprName)
modelTransformedImportSegmentationNode.SetAndObserveTransformNodeID(modelTransformedImportSegmentationTransformNode.GetID())
modelSegmentTranformed = slicer.vtkSlicerSegmentationsModuleLogic.CreateSegmentFromModelNode(bodyModelNodeTransformed, modelTransformedImportSegmentationNode)
modelSegmentTranformed.UnRegister(None) # Need to release ownership
self.assertIsNotNone(modelSegmentTranformed)
modelSegmentTransformedPolyData = modelSegmentTranformed.GetRepresentation(self.closedSurfaceReprName)
self.assertIsNotNone(modelSegmentTransformedPolyData)
self.assertEqual(int(modelSegmentTransformedPolyData.GetBounds()[0]), 1332)
self.assertEqual(int(modelSegmentTransformedPolyData.GetBounds()[1]), 1675)
# Clean up temporary nodes
slicer.mrmlScene.RemoveNode(bodyModelNode)
slicer.mrmlScene.RemoveNode(bodyLabelmapNode)
slicer.mrmlScene.RemoveNode(allSegmentsLabelmapNode)
slicer.mrmlScene.RemoveNode(modelImportSegmentationNode)
slicer.mrmlScene.RemoveNode(multiLabelImportSegmentationNode)
slicer.mrmlScene.RemoveNode(singleLabelImportSegmentationNode)
slicer.mrmlScene.RemoveNode(bodyModelTransformNode)
slicer.mrmlScene.RemoveNode(bodyModelNodeTransformed)
slicer.mrmlScene.RemoveNode(bodyLabelmapNodeTransformed)
slicer.mrmlScene.RemoveNode(modelTransformedImportSegmentationNode)
