def DisplayGraph(graph): ''' Display the graph. ''' theme = vtk.vtkViewTheme() theme.SetBackgroundColor(0, 0, .1) theme.SetBackgroundColor2(0, 0, .5) # Layout the graph # Pick a strategy you like. # strategy = vtk.vtkCircularLayoutStrategy() strategy = vtk.vtkSimple2DLayoutStrategy() # strategy = vtk.vtkRandomLayoutStrategy() layout = vtk.vtkGraphLayout() layout.SetLayoutStrategy(strategy) layout.SetInputData(graph) view = vtk.vtkGraphLayoutView() view.AddRepresentationFromInputConnection(layout.GetOutputPort()) # Tell the view to use the vertex layout we provide. view.SetLayoutStrategyToPassThrough() view.SetEdgeLabelVisibility(True) view.SetVertexLabelArrayName("Labels") view.SetVertexLabelVisibility(True) view.ApplyViewTheme(theme) # Manually create an actor containing the glyphed arrows. # Get the edge geometry edgeGeom = vtk.vtkGraphToPolyData() edgeGeom.SetInputConnection(layout.GetOutputPort()) edgeGeom.EdgeGlyphOutputOn() # Set the position (0: edge start, 1: edge end) where # the edge arrows should go. # edgeGeom.SetEdgeGlyphPosition(0.8) edgeGeom.SetEdgeGlyphPosition(0.85) # Make a simple edge arrow for glyphing. # arrowSource = vtk.vtkGlyphSource2D() # arrowSource.SetGlyphTypeToEdgeArrow() # arrowSource.SetScale(0.075) # Or use a cone. coneSource = vtk.vtkConeSource() coneSource.SetRadius(0.025) coneSource.SetHeight(0.1) coneSource.SetResolution(12) # Use Glyph3D to repeat the glyph on all edges. arrowGlyph = vtk.vtkGlyph3D() arrowGlyph.SetInputConnection(0, edgeGeom.GetOutputPort(1)) # arrowGlyph.SetInputConnection(1, arrowSource.GetOutputPort()) arrowGlyph.SetInputConnection(1, coneSource.GetOutputPort()) # Add the edge arrow actor to the view. arrowMapper = vtk.vtkPolyDataMapper() arrowMapper.SetInputConnection(arrowGlyph.GetOutputPort()) arrowActor = vtk.vtkActor() arrowActor.SetMapper(arrowMapper) view.GetRenderer().AddActor(arrowActor) view.ResetCamera() view.Render() view.SetInteractionModeTo3D() view.GetInteractor().Initialize() view.GetInteractor().Start()
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() g = vtk.vtkMutableDirectedGraph() v1 = g.AddVertex() v2 = g.AddVertex() v3 = g.AddVertex() ### g.AddEdge(v1, v2) g.AddGraphEdge(v1, v2) g.AddGraphEdge(v2, v3) g.AddGraphEdge(v3, v1) # Do layout manually before handing graph to the view. # This allows us to know the positions of edge arrows. graphLayoutView = vtk.vtkGraphLayoutView() layout = vtk.vtkGraphLayout() strategy = vtk.vtkSimple2DLayoutStrategy() layout.SetInput(g) layout.SetLayoutStrategy(strategy) # Tell the view to use the vertex layout we provide graphLayoutView.SetLayoutStrategyToPassThrough() # The arrows will be positioned on a straight line between two # vertices so tell the view not to draw arcs for parallel edges graphLayoutView.SetEdgeLayoutStrategyToPassThrough() # Add the graph to the view. This will render vertices and edges, # but not edge arrows. graphLayoutView.AddRepresentationFromInputConnection(layout.GetOutputPort()) # Manually create an actor containing the glyphed arrows. graphToPoly = vtk.vtkGraphToPolyData() graphToPoly.SetInputConnection(layout.GetOutputPort()) graphToPoly.EdgeGlyphOutputOn() # Set the position (0: edge start, 1:edge end) where # the edge arrows should go. graphToPoly.SetEdgeGlyphPosition(0.98) # Make a simple edge arrow for glyphing. arrowSource = vtk.vtkGlyphSource2D() arrowSource.SetGlyphTypeToEdgeArrow() arrowSource.SetScale(0.1) arrowSource.Update() # Use Glyph3D to repeat the glyph on all edges. arrowGlyph = vtk.vtkGlyph3D() arrowGlyph.SetInputConnection(0, graphToPoly.GetOutputPort(1)) arrowGlyph.SetInputConnection(1, arrowSource.GetOutputPort()) # Create a mapper mapper = vtk.vtkPolyDataMapper() mapper.SetInputConnection(arrowGlyph.GetOutputPort()) # Create an actor actor = vtk.vtkActor() actor.SetMapper(mapper) self.ren.AddActor(actor) self.ren.ResetCamera() self._initialized = False
def loadGraph(): # ---------- # Load and construct whole graph and multi-resolution data from Matlab structure dataDir = '/Users/emonson/Programming/Matlab/EMonson/Fodava/DocumentAnalysis/Analysis/' filename = dataDir + 'X20_042709b.mat' # filename = '/Users/emonson/Programming/Python/VTK/X20_040609b.mat' X = scipy.io.loadmat(filename) # Get graph structure G out of matlab variables G = X['G'] # ---------- # Set multi-resolution level bounds in GUI sliders levelMax = G.Tree.shape[0]-1 ui_window.hSlider_level.setMinimum(1) ui_window.hSlider_level.setMaximum(levelMax) ui_window.spinBox_level.setMinimum(1) ui_window.spinBox_level.setMaximum(levelMax) # Start setting up basis function for display as subgraph ExtBasis = GTree[level,0]['ExtBasis'][0][0][0] basisMax = ExtBasis.shape[1]-1 # zero-based indices # Set particular level basis function bounds in GUI sliders ui_window.hSlider_basisIndex.setMinimum(0) ui_window.hSlider_basisIndex.setMaximum(basisMax) ui_window.spinBox_basisIndex.setMinimum(0) ui_window.spinBox_basisIndex.setMaximum(basisMax) # Build table which will become graph table = vtk.vtkTable() col0 = vtk.vtkIntArray() col0.SetName('index1') col1 = vtk.vtkIntArray() col1.SetName('index2') val = vtk.vtkDoubleArray() val.SetName('weight') Tmat = G.T # Tmat = G.W for ii in range(Tmat.nzmax): col0.InsertNextValue(Tmat.rowcol(ii)[0]) col1.InsertNextValue(Tmat.rowcol(ii)[1]) val.InsertNextValue(abs(Tmat.getdata(ii))) table.AddColumn(col0) table.AddColumn(col1) table.AddColumn(val) # Vertex links need to be done with index2 first or indexing won't be right... # TODO: Make this foolproof so that graph always ends up with correct ordering of indices... tgraph = vtk.vtkTableToGraph() tgraph.SetInput(table) tgraph.AddLinkVertex('index2', 'stuff', False) tgraph.AddLinkVertex('index1', 'stuff', False) tgraph.AddLinkEdge('index2', 'index1') rawGraph = tgraph.GetOutput() rawGraph.Update() # print graph # Load and assign whole graph pre-layout coordinates ptsFile = os.path.splitext(filename)[0] + '_pts.vtp' if os.path.exists(ptsFile): polyreader = vtk.vtkXMLPolyDataReader() polyreader.SetFileName(ptsFile) polyreader.Update() pts = polyreader.GetOutput().GetPoints() rawGraph.SetPoints(pts) # print pts strategy = vtk.vtkPassThroughLayoutStrategy() layout = vtk.vtkGraphLayout() layout.SetInput(rawGraph) layout.SetLayoutStrategy(strategy) edgeLayout = vtk.vtkEdgeLayout() edgeStrategy = vtk.vtkArcParallelEdgeStrategy() edgeStrategy.SetNumberOfSubdivisions(50) edgeLayout.SetInputConnection(layout.GetOutputPort()) edgeLayout.SetLayoutStrategy(edgeStrategy) graph = edgeLayout.GetOutput() graph.Update() # -------- # Add ExtBasis to graph data & Select particular basis function # print 'ExtBasis shape: ' + str(ExtBasis[:,basisNum].data.shape) + ' (level,basis) (' + str(level) + ',' + str(basisNum) + ')' # Indexing of ExtBasis is backwards from graph, so need to reverse with [::-1] # and array not "contiguous" if don't do .copy() Esub = ExtBasis[:,basisNum].data[::-1].copy() EsubSq = Esub**2 # Esub = N.random.random(ExtBasis[:,basisNum].data.shape[0]) # SubIdxs = (Esub > 0.001).nonzero() # SubIdxs = (Esub**2 > 0.8).nonzero() # Set ExtBasis vertex data from numpy array basisFunc = VN.numpy_to_vtk(Esub) basisFunc.SetName('ExtBasis') basisFuncSq = VN.numpy_to_vtk(EsubSq) basisFuncSq.SetName('ExtBasisSq') vertexData = graph.GetVertexData() vertexData.AddArray(basisFunc) vertexData.AddArray(basisFuncSq) selection = vtk.vtkSelectionSource() selection.SetContentType(7) # vtkSelection::THRESHOLDS # selection.SetContentType(2) # vtkSelection::PEDIGREE_IDS selection.SetFieldType(3) # vtkSelection::VERTEX selection.SetArrayName("ExtBasisSq") selection.AddThreshold(basisCutoff, 10) # TODO: There was something wrong with the indexing in the PEDIGREE_IDS selection... # for ii in SubIdxs[0]: # selection.AddID(0,ii) minmax = "(%3.2e, %3.2e)" % (EsubSq.min(), EsubSq.max()) ui_window.label_basisCutoff_minmax.setText(minmax) selection.Update() # ---------- # Back to pipeline degree = vtk.vtkVertexDegree() degree.SetInput(graph) subgraph = vtk.vtkExtractSelectedGraph() subgraph.SetRemoveIsolatedVertices(False) subgraph.SetInputConnection(degree.GetOutputPort()) subgraph.SetSelectionConnection(selection.GetOutputPort()) # +++++++++++++ graphToPoly = vtk.vtkGraphToPolyData() graphToPoly.SetInputConnection(subgraph.GetOutputPort()) edgeMapper = vtk.vtkPolyDataMapper() edgeMapper.SetInputConnection(graphToPoly.GetOutputPort()) edgeMapper.SetScalarModeToUseCellData() edgeMapper.SetScalarVisibility(False) edgeMapper.SetImmediateModeRendering(True) edgeActor = vtk.vtkActor() edgeActor.SetMapper(edgeMapper) edgeActor.SetPosition(0, 0, -0.003); lut = vtk.vtkLookupTable() lutNum = 256 lut.SetNumberOfTableValues(lutNum) ctf = vtk.vtkColorTransferFunction() ctf.SetColorSpaceToDiverging() ctf.AddRGBPoint(0.0, 0, 0, 1.0) ctf.AddRGBPoint(1.0, 1.0, 0, 0) for ii,ss in enumerate([float(xx)/float(lutNum) for xx in range(lutNum)]): cc = ctf.GetColor(ss) lut.SetTableValue(ii,cc[0],cc[1],cc[2],1.0) vertGlyph = vtk.vtkVertexGlyphFilter() vertGlyph.SetInputConnection(subgraph.GetOutputPort()) vertMapper = vtk.vtkPolyDataMapper() vertMapper.SetInputConnection(vertGlyph.GetOutputPort()) vertMapper.SetImmediateModeRendering(True) vertMapper.SetScalarModeToUsePointFieldData() vertMapper.SetLookupTable(lut) vertMapper.SelectColorArray('ExtBasis') vertMapper.Update() vertRange = vertMapper.GetInput().GetPointData().GetArray(vertMapper.GetArrayName()).GetRange() vertMapper.SetScalarRange(-1.0*vertRange[1], vertRange[1]) vertActor = vtk.vtkActor() vertActor.SetMapper(vertMapper) outlineMapper = vtk.vtkPolyDataMapper() outlineMapper.SetScalarVisibility(False) outlineMapper.SetImmediateModeRendering(True) outlineMapper.SetInputConnection(vertGlyph.GetOutputPort()) outlineActor = vtk.vtkActor() outlineActor.PickableOff() outlineActor.SetPosition(0, 0, -0.001) outlineActor.GetProperty().SetRepresentationToWireframe() outlineActor.SetMapper(outlineMapper) # Create an Actor Collection for applying visibility to group basisActorCollection = vtk.vtkActorCollection() basisActorCollection.AddItem(vertActor) # basisActorCollection.AddItem(edgeActor) basisActorCollection.AddItem(outlineActor) # Apply a theme to the views theme = vtk.vtkViewTheme.CreateMellowTheme() theme.SetLineWidth(3) theme.SetPointSize(5) theme.SetSelectedCellColor(1,1,1) theme.SetSelectedPointColor(1,1,1) theme.SetOutlineColor(0.8, 0.8, 0.8) # theme.SetPointColor(0.9, 0.7, 0.3) theme.SetCellColor(0.9, 0.7, 0.3) # theme.SetPointOpacity(0.5) # theme.SetPointHueRange(0.0, 0.15) # theme.SetPointSaturationRange(0.6, 0.8) # theme.SetPointValueRange(0.4,0.8) # theme.SetPointAlphaRange(0.2,0.8) # theme.SetPointAlphaRange(1.0,1.0) # Apply theme # vertActor.GetProperty().SetColor(theme.GetPointColor()) # vertActor.GetProperty().SetOpacity(theme.GetPointOpacity()) vertActor.GetProperty().SetPointSize(theme.GetPointSize()) outlineActor.GetProperty().SetPointSize(vertActor.GetProperty().GetPointSize()+2) outlineActor.GetProperty().SetColor(theme.GetOutlineColor()) outlineActor.GetProperty().SetOpacity(theme.GetPointOpacity()) edgeActor.GetProperty().SetColor(theme.GetCellColor()) edgeActor.GetProperty().SetOpacity(theme.GetCellOpacity()) edgeActor.GetProperty().SetLineWidth(theme.GetLineWidth()) # ---------- # Background graph skeleton graphMapper = vtk.vtkGraphMapper() graphMapper.SetInputConnection(0, degree.GetOutputPort(0)) # Apply a theme to the background graph gtheme = vtk.vtkViewTheme() gtheme.SetLineWidth(1) gtheme.SetPointSize(0) gtheme.SetCellColor(0.8, 0.8, 0.8) gtheme.SetCellOpacity(0.2) gtheme.SetOutlineColor(0.8, 0.8, 0.8) gtheme.SetPointColor(0.8, 0.8, 0.8) gtheme.SetPointOpacity(0.0) graphMapper.ApplyViewTheme(gtheme) graphActor = vtk.vtkActor() graphActor.SetMapper(graphMapper) graphActor.SetPosition(0,0,-0.005) # ---------- # Background vertices graphPoly = vtk.vtkGraphToPolyData() graphPoly.SetInputConnection(0, tgraph.GetOutputPort(0)) vertGlyph = vtk.vtkGlyph3D() vertGlyph.SetInputConnection(0, graphPoly.GetOutputPort()) glyphSource = vtk.vtkGlyphSource2D() glyphSource.SetGlyphTypeToVertex() # glyphSource.SetGlyphTypeToCircle() # glyphSource.SetScale(0.025) vertGlyph.SetInputConnection(1, glyphSource.GetOutputPort()) vertexMapper = vtk.vtkPolyDataMapper() vertexMapper.SetInputConnection(vertGlyph.GetOutputPort()) vertexActor = vtk.vtkActor() vertexActor.SetMapper(vertexMapper) vertexActor.GetProperty().SetPointSize(4) vertexActor.GetProperty().SetOpacity(0.5) vertexActor.GetProperty().SetColor(0.6, 0.6, 0.6) vertexActor.SetPosition(0, 0, -0.004) # ---------- # Vertex index labels labelMapper = vtk.vtkDynamic2DLabelMapper() labelMapper.SetInputConnection(0, graphPoly.GetOutputPort(0)) labelMapper.SetLabelModeToLabelFieldData() labelMapper.SetFieldDataName("label") labelMapper.SetLabelFormat("%s") labelMapper.GetLabelTextProperty().SetColor(0.0, 0.0, 0.0) labelActor = vtk.vtkActor2D() labelActor.SetMapper(labelMapper) # ---------- # MultiScale Graph msGraph = buildSubGraph(level) msMapper = vtk.vtkGraphMapper() msMapper.SetInput(msGraph) msMapper.SetColorEdges(True) msMapper.SetEdgeColorArrayName('weight') # Apply a theme to the background graph mtheme = vtk.vtkViewTheme() mtheme.SetLineWidth(3) mtheme.SetPointSize(11) # mtheme.SetCellColor(0.5, 0.5, 0.7) # mtheme.SetCellOpacity(0.5) mtheme.SetOutlineColor(0.8, 0.8, 0.8) mtheme.SetPointColor(0.3, 0.3, 0.6) mtheme.SetPointOpacity(1.0) mtheme.SetCellHueRange(0.67, 0.67) mtheme.SetCellSaturationRange(0.6, 0.1) mtheme.SetCellValueRange(0.5,1.0) mtheme.SetCellAlphaRange(0.2,0.8) msMapper.ApplyViewTheme(mtheme) msActor = vtk.vtkActor() msActor.SetMapper(msMapper) msActor.SetPosition(0,0,-0.002) # ---------- # Set up window and add actors view.SetLayoutStrategyToPassThrough() # view.ApplyViewTheme(theme) # view.SetupRenderWindow(win) view.GetRenderer().SetBackground(theme.GetBackgroundColor()) view.GetRenderer().SetBackground2(theme.GetBackgroundColor2()) view.GetRenderer().SetGradientBackground(True) view.GetRenderer().AddActor(vertActor) view.GetRenderer().AddActor(outlineActor) view.GetRenderer().AddActor(edgeActor) view.GetRenderer().AddActor(graphActor) view.GetRenderer().AddActor(vertexActor) view.GetRenderer().AddActor(labelActor) view.GetRenderer().AddActor(msActor) # ---------- # General interactor isty = vtk.vtkInteractorStyleRubberBand2D() # RubberBand2D assumes/needs parallel projection ON view.GetRenderer().GetActiveCamera().ParallelProjectionOn() iren = view.GetRenderWindow().GetInteractor() iren.SetInteractorStyle(isty) # Interactor style must be set before scalar bar can be shown # view.SetVertexScalarBarVisibility(True) sbActor = vtk.vtkScalarBarActor() sbActor.SetLookupTable(vertMapper.GetLookupTable()) sbActor.SetTitle(vertMapper.GetArrayName()) sbActor.SetNumberOfLabels(3) vertexScalarBar = vtk.vtkScalarBarWidget() vertexScalarBar.SetScalarBarActor(sbActor) vertexScalarBar.SetInteractor(iren) vertexScalarBar.SetDefaultRenderer(view.GetRenderer()) vertexScalarBar.SetCurrentRenderer(view.GetRenderer()) vertexScalarBar.SetEnabled(True) scalarBarRep = vertexScalarBar.GetRepresentation() scalarBarRep.SetOrientation(1) # 0 = Horizontal, 1 = Vertical scalarBarRep.GetPositionCoordinate().SetValue(0.05,0.05) scalarBarRep.GetPosition2Coordinate().SetValue(0.15,0.25) # Adding it this way gets it to show up, but it's not interactive view.GetRenderer().AddActor(sbActor) view.ResetCamera() view.Render() # ---------- # Add Actors to QListWidget to allow check and uncheck for visibility listItem0 = QtGui.QListWidgetItem() listItem0.setText('Index Labels') listItem0.setFlags(QtCore.Qt.ItemIsUserCheckable | QtCore.Qt.ItemIsEnabled | QtCore.Qt.ItemIsSelectable) labelActor.SetVisibility(0) listItem0.setCheckState(QtCore.Qt.Unchecked) # Put actor it in as data in the list widget item listItem0.setData(QtCore.Qt.UserRole, QtCore.QVariant(labelActor)) ui_window.listWidget.insertItem(0,listItem0) # Test retrieval of actor from list widget item # tmpItem = ui_window.listWidget.item(0) # tmpQtActor = tmpItem.data(QtCore.Qt.UserRole) # tmpActor = tmpQtActor.toPyObject() # tmpActor.SetVisibility(0) # Shorter way to add item to list widget listItem1 = QtGui.QListWidgetItem('Vertices (background)', ui_window.listWidget) listItem1.setData(QtCore.Qt.UserRole, QtCore.QVariant(vertexActor)) listItem1.setFlags(QtCore.Qt.ItemIsUserCheckable | QtCore.Qt.ItemIsEnabled | QtCore.Qt.ItemIsSelectable) listItem1.setCheckState(QtCore.Qt.Checked) listItem2 = QtGui.QListWidgetItem('Graph (background)', ui_window.listWidget) listItem2.setData(QtCore.Qt.UserRole, QtCore.QVariant(graphActor)) listItem2.setFlags(QtCore.Qt.ItemIsUserCheckable | QtCore.Qt.ItemIsEnabled | QtCore.Qt.ItemIsSelectable) listItem2.setCheckState(QtCore.Qt.Checked) listItem3 = QtGui.QListWidgetItem() listItem3.setText('Basis Function Vertices') listItem3.setData(QtCore.Qt.UserRole, QtCore.QVariant(basisActorCollection)) listItem3.setFlags(QtCore.Qt.ItemIsUserCheckable | QtCore.Qt.ItemIsEnabled | QtCore.Qt.ItemIsSelectable) listItem3.setCheckState(QtCore.Qt.Checked) ui_window.listWidget.insertItem(1,listItem3) listItem6 = QtGui.QListWidgetItem() listItem6.setText('Basis Function Edges') listItem6.setData(QtCore.Qt.UserRole, QtCore.QVariant(edgeActor)) listItem6.setFlags(QtCore.Qt.ItemIsUserCheckable | QtCore.Qt.ItemIsEnabled | QtCore.Qt.ItemIsSelectable) listItem6.setCheckState(QtCore.Qt.Checked) ui_window.listWidget.insertItem(2,listItem6) listItem4 = QtGui.QListWidgetItem() listItem4.setText('MultiScale Graph') listItem4.setData(QtCore.Qt.UserRole, QtCore.QVariant(msActor)) listItem4.setFlags(QtCore.Qt.ItemIsUserCheckable | QtCore.Qt.ItemIsEnabled | QtCore.Qt.ItemIsSelectable) listItem4.setCheckState(QtCore.Qt.Checked) ui_window.listWidget.insertItem(3,listItem4) listItem5 = QtGui.QListWidgetItem() listItem5.setText('Basis Function Scale Bar') listItem5.setData(QtCore.Qt.UserRole, QtCore.QVariant(sbActor)) listItem5.setFlags(QtCore.Qt.ItemIsUserCheckable | QtCore.Qt.ItemIsEnabled | QtCore.Qt.ItemIsSelectable) listItem5.setCheckState(QtCore.Qt.Checked) ui_window.listWidget.insertItem(3,listItem5) iren.Initialize() iren.Start()
# theme.SetPointColor(0.9, 0.7, 0.3) # theme.SetCellColor(0.9, 0.7, 0.3) # orig theme.SetCellHueRange(0.11111, 0.11111) theme.SetCellSaturationRange(0.66667, 0.66667) theme.SetCellValueRange(0.8, 0.8) theme.SetCellAlphaRange(0.075, 0.8) ui_window.hSlider_ExtBasisAlpha.setValue(30) # corresponds to min alpha 0.075 # theme.SetPointOpacity(0.5) # theme.SetPointHueRange(0.0, 0.15) # theme.SetPointSaturationRange(0.6, 0.8) # theme.SetPointValueRange(0.4,0.8) # theme.SetPointAlphaRange(0.2,0.8) # theme.SetPointAlphaRange(1.0,1.0) # +++++++++++++ graphToPoly = vtk.vtkGraphToPolyData() graphToPoly.SetInputConnection(subgraph.GetOutputPort()) edgeMapper = vtk.vtkPolyDataMapper() edgeMapper.SetInputConnection(graphToPoly.GetOutputPort()) edgeMapper.SetScalarVisibility(True) edgeMapper.SetScalarModeToUseCellFieldData() edgeMapper.SelectColorArray('weight') edgeMapper.SetLookupTable(theme.GetCellLookupTable()) edgeMapper.SetImmediateModeRendering(True) edgeActor = vtk.vtkActor() edgeActor.SetMapper(edgeMapper) # edgeActor.GetProperty().SetColor(theme.GetCellColor()) # edgeActor.GetProperty().SetOpacity(theme.GetCellOpacity()) edgeActor.GetProperty().SetLineWidth(theme.GetLineWidth()) edgeActor.SetPosition(0, 0, -0.003); edgeActor.SetVisibility(0)
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() g = vtk.vtkMutableDirectedGraph() v1 = g.AddVertex() v2 = g.AddVertex() v3 = g.AddVertex() ### g.AddEdge(v1, v2) g.AddGraphEdge(v1, v2) g.AddGraphEdge(v2, v3) g.AddGraphEdge(v3, v1) # Do layout manually before handing graph to the view. # This allows us to know the positions of edge arrows. graphLayoutView = vtk.vtkGraphLayoutView() layout = vtk.vtkGraphLayout() strategy = vtk.vtkSimple2DLayoutStrategy() layout.SetInput(g) layout.SetLayoutStrategy(strategy) # Tell the view to use the vertex layout we provide graphLayoutView.SetLayoutStrategyToPassThrough() # The arrows will be positioned on a straight line between two # vertices so tell the view not to draw arcs for parallel edges graphLayoutView.SetEdgeLayoutStrategyToPassThrough() # Add the graph to the view. This will render vertices and edges, # but not edge arrows. graphLayoutView.AddRepresentationFromInputConnection( layout.GetOutputPort()) # Manually create an actor containing the glyphed arrows. graphToPoly = vtk.vtkGraphToPolyData() graphToPoly.SetInputConnection(layout.GetOutputPort()) graphToPoly.EdgeGlyphOutputOn() # Set the position (0: edge start, 1:edge end) where # the edge arrows should go. graphToPoly.SetEdgeGlyphPosition(0.98) # Make a simple edge arrow for glyphing. arrowSource = vtk.vtkGlyphSource2D() arrowSource.SetGlyphTypeToEdgeArrow() arrowSource.SetScale(0.1) arrowSource.Update() # Use Glyph3D to repeat the glyph on all edges. arrowGlyph = vtk.vtkGlyph3D() arrowGlyph.SetInputConnection(0, graphToPoly.GetOutputPort(1)) arrowGlyph.SetInputConnection(1, arrowSource.GetOutputPort()) # Create a mapper mapper = vtk.vtkPolyDataMapper() mapper.SetInputConnection(arrowGlyph.GetOutputPort()) # Create an actor actor = vtk.vtkActor() actor.SetMapper(mapper) self.ren.AddActor(actor) self.ren.ResetCamera() self._initialized = False