static void Main()
{
string VTK_DATA_ROOT = "C:/Program Files/VTKData";
// Create a vtkBYUReader and read in a data set.
vtkBYUReader fohe = new vtkBYUReader();
fohe.SetGeometryFileName(VTK_DATA_ROOT + "/Data/teapot.g");
// Create a vtkPolyDataNormals filter to calculate the normals of the
// data set.
vtkPolyDataNormals normals = new vtkPolyDataNormals();
normals.SetInputConnection(fohe.GetOutputPort());
// Set up the associated mapper and actor.
vtkPolyDataMapper foheMapper = new vtkPolyDataMapper();
foheMapper.SetInputConnection(normals.GetOutputPort());
vtkLODActor foheActor = new vtkLODActor();
foheActor.SetMapper(foheMapper);
// Create a vtkOutlineFilter to draw the bounding box of the data set.
// Also create the associated mapper and actor.
vtkOutlineFilter outline = new vtkOutlineFilter();
outline.SetInputConnection(normals.GetOutputPort());
vtkPolyDataMapper mapOutline = new vtkPolyDataMapper();
mapOutline.SetInputConnection(outline.GetOutputPort());
vtkActor outlineActor = new vtkActor();
outlineActor.SetMapper(mapOutline);
outlineActor.GetProperty().SetColor(0, 0, 0);
// Create a vtkCamera, and set the camera parameters.
vtkCamera camera = new vtkCamera();
camera.SetClippingRange(1.60187, 20.0842);
camera.SetFocalPoint(0.21406, 1.5, 0);
camera.SetPosition(8.3761, 4.94858, 4.12505);
camera.SetViewUp(0.180325, 0.549245, -0.815974);
// Create a vtkLight, and set the light parameters.
vtkLight light = new vtkLight();
light.SetFocalPoint(0.21406, 1.5, 0);
light.SetPosition(8.3761, 4.94858, 4.12505);
// Create the Renderers. Assign them the appropriate viewport
// coordinates, active camera, and light.
vtkRenderer ren = new vtkRenderer();
ren.SetViewport(0, 0, 0.5, 1.0);
ren.SetActiveCamera(camera);
ren.AddLight(light);
vtkRenderer ren2 = new vtkRenderer();
ren2.SetViewport(0.5, 0, 1.0, 1.0);
ren2.SetActiveCamera(camera);
ren2.AddLight(light);
// Create the RenderWindow and RenderWindowInteractor.
vtkRenderWindow renWin = new vtkRenderWindow();
renWin.AddRenderer(ren);
renWin.AddRenderer(ren2);
renWin.SetWindowName("VTK - Cube Axes");
renWin.SetSize(600, 300);
vtkRenderWindowInteractor iren = new vtkRenderWindowInteractor();
iren.SetRenderWindow(renWin);
// Add the actors to the renderer, and set the background.
ren.AddViewProp(foheActor);
ren.AddViewProp(outlineActor);
ren2.AddViewProp(foheActor);
ren2.AddViewProp(outlineActor);
ren.SetBackground(0.1, 0.2, 0.4);
ren2.SetBackground(0.1, 0.2, 0.4);
// Create a text property for both cube axes
vtkTextProperty tprop = new vtkTextProperty();
tprop.SetColor(1, 1, 1);
tprop.ShadowOn();
// Create a vtkCubeAxesActor2D. Use the outer edges of the bounding box to
// draw the axes. Add the actor to the renderer.
vtkCubeAxesActor2D axes = new vtkCubeAxesActor2D();
axes.SetInput(normals.GetOutput());
axes.SetCamera(ren.GetActiveCamera());
axes.SetLabelFormat("%6.4g");
axes.SetFlyModeToOuterEdges();
axes.SetFontFactor(0.8);
axes.SetAxisTitleTextProperty(tprop);
axes.SetAxisLabelTextProperty(tprop);
ren.AddViewProp(axes);
// Create a vtkCubeAxesActor2D. Use the closest vertex to the camera to
// determine where to draw the axes. Add the actor to the renderer.
vtkCubeAxesActor2D axes2 = new vtkCubeAxesActor2D();
axes2.SetViewProp(foheActor);
axes2.SetCamera(ren2.GetActiveCamera());
axes2.SetLabelFormat("%6.4g");
axes2.SetFlyModeToClosestTriad();
axes2.SetFontFactor(0.8);
axes2.ScalingOff();
axes2.SetAxisTitleTextProperty(tprop);
axes2.SetAxisLabelTextProperty(tprop);
ren2.AddViewProp(axes2);
renWin.AddObserver((uint) EventIds.AbortCheckEvent, CheckAbort);
iren.Initialize();
renWin.Render();
iren.Start();
vtkWin32OpenGLRenderWindow win32win =
vtkWin32OpenGLRenderWindow.SafeDownCast(renWin);
if (null != win32win) win32win.Clean();
}
private void IsoContours()
{
vtkImageData data = vtkImageData.New();
CreateData(ref data);
// Create an isosurface
_ContourFilter = vtkContourFilter.New();
#if VTK_MAJOR_VERSION_5
_ContourFilter.SetInput(data);
#else
contourFilter.SetInputData(data);
#endif
_ContourFilter.GenerateValues(1, 10, 10); // (numContours, rangeStart, rangeEnd)
// Map the contours to graphical primitives
vtkPolyDataMapper contourMapper = vtkPolyDataMapper.New();
#if VTK_MAJOR_VERSION_5
contourMapper.SetInputConnection(_ContourFilter.GetOutputPort());
#else
contourMapper.SetInputData(contourFilter);
#endif
// Create an actor for the contours
vtkActor contourActor = vtkActor.New();
contourActor.SetMapper(contourMapper);
// Create the outline
vtkOutlineFilter outlineFilter = vtkOutlineFilter.New();
vtkPolyDataMapper outlineMapper = vtkPolyDataMapper.New();
#if VTK_MAJOR_VERSION_5
outlineFilter.SetInput(data);
outlineMapper.SetInputConnection(outlineFilter.GetOutputPort());
#else
outlineFilter.SetInputData(data);
outlineMapper.SetInputData(outlineFilter);
#endif
vtkActor outlineActor = vtkActor.New();
outlineActor.SetMapper(outlineMapper);
// get a reference to the renderwindow of our renderWindowControl1
_RenderWindow = renderWindowControl1.RenderWindow;
// renderer
vtkRenderer renderer = _RenderWindow.GetRenderers().GetFirstRenderer();
// set background color
renderer.SetBackground(.2, .3, .4);
// add our actor to the renderer
renderer.AddActor(contourActor);
renderer.AddActor(outlineActor);
}
//绘制外边框
private vtkActor BuildOutlineActor(vtkImageData ImageData)
{
//创建Outline
vtkOutlineFilter OutlineFilter = vtkOutlineFilter.New();
OutlineFilter.SetInput(ImageData);
vtkPolyDataMapper OutlineMapper = vtkPolyDataMapper.New();
OutlineMapper.SetInputConnection(OutlineFilter.GetOutputPort());
vtkActor outlineActor = vtkActor.New();
outlineActor.SetMapper(OutlineMapper);
outlineActor.GetProperty().SetColor(0.5, 0.5, 0.5);
return(outlineActor);
}
///<summary> A Set Method for Static Variables </summary>
public static void SetoutTpd3(vtkOutlineFilter toSet)
{
outTpd3 = toSet;
}
private void DrawVisQuad()
{
//# This example demonstrates the use of the contour filter, and the use of
//# the vtkSampleFunction to generate a volume of data samples from an
//# implicit function.
//# VTK supports implicit functions of the form f(x,y,z)=constant. These
//# functions can represent things spheres, cones, etc. Here we use a
//# general form for a quadric to create an elliptical data field.
vtkQuadric quadricFunction = vtkQuadric.New();
quadricFunction.SetCoefficients(0.5, 1, 0.2, 0, 0.1, 0, 0, 0.2, 0, 0);
//# vtkSampleFunction samples an implicit function over the x-y-z range
//# specified (here it defaults to -1,1 in the x,y,z directions).
vtkSampleFunction sample = vtkSampleFunction.New();
sample.SetSampleDimensions(30, 30, 30);
sample.SetImplicitFunction(quadricFunction);
//# Create five surfaces F(x,y,z) = constant between range specified. The
//# GenerateValues() method creates n isocontour values between the range
//# specified.
vtkContourFilter contourFilter = vtkContourFilter.New();
contourFilter.SetInputConnection(sample.GetOutputPort());
contourFilter.GenerateValues(10, 0.0, 1.2);
vtkPolyDataMapper contMapper = vtkPolyDataMapper.New();
contMapper.SetInputConnection(contourFilter.GetOutputPort());
contMapper.SetScalarRange(0.0, 1.2);
vtkActor conActor = vtkActor.New();
conActor.SetMapper(contMapper);
//We'll put a simple outline around the data
vtkOutlineFilter outline = vtkOutlineFilter.New();
outline.SetInputConnection(sample.GetOutputPort());
vtkPolyDataMapper outlineMapper = vtkPolyDataMapper.New();
outlineMapper.SetInputConnection(outline.GetOutputPort());
vtkActor outlineActor = vtkActor.New();
outlineActor.SetMapper(outlineMapper);
outlineActor.GetProperty().SetColor(0, 0, 0);
//The usual rendering stuff
vtkRenderer ren = vtkRenderer.New();
vtkRenderWindow renWin = myRenderWindowControl.RenderWindow;
//vtkRenderWindow renWin = vtkRenderWindow.New();
renWin.AddRenderer(ren);
//vtkRenderWindowInteractor iren = vtkRenderWindowInteractor.New();
//iren.SetRenderWindow(renWin);
ren.SetBackground(1, 1, 1);
ren.AddActor(conActor);
ren.AddActor(outlineActor);
//iren.Initialize();
//renWin.Render();
//iren.Start();
}
/// <summary>
/// The main entry method called by the CSharp driver
/// </summary>
/// <param name="argv"></param>
public static void AVprobeComb(String [] argv)
{
//Prefix Content is: ""
// create planes[]
// Create the RenderWindow, Renderer and both Actors[]
//[]
ren1 = vtkRenderer.New();
renWin = vtkRenderWindow.New();
renWin.SetMultiSamples(0);
renWin.AddRenderer((vtkRenderer)ren1);
iren = new vtkRenderWindowInteractor();
iren.SetRenderWindow((vtkRenderWindow)renWin);
// create pipeline[]
//[]
pl3d = new vtkMultiBlockPLOT3DReader();
pl3d.SetXYZFileName((string)"" + (VTK_DATA_ROOT.ToString()) + "/Data/combxyz.bin");
pl3d.SetQFileName((string)"" + (VTK_DATA_ROOT.ToString()) + "/Data/combq.bin");
pl3d.SetScalarFunctionNumber((int)100);
pl3d.SetVectorFunctionNumber((int)202);
pl3d.Update();
plane = new vtkPlaneSource();
plane.SetResolution((int)50, (int)50);
transP1 = new vtkTransform();
transP1.Translate((double)3.7, (double)0.0, (double)28.37);
transP1.Scale((double)5, (double)5, (double)5);
transP1.RotateY((double)90);
tpd1 = new vtkTransformPolyDataFilter();
tpd1.SetInputConnection((vtkAlgorithmOutput)plane.GetOutputPort());
tpd1.SetTransform((vtkAbstractTransform)transP1);
outTpd1 = new vtkOutlineFilter();
outTpd1.SetInputConnection((vtkAlgorithmOutput)tpd1.GetOutputPort());
mapTpd1 = vtkPolyDataMapper.New();
mapTpd1.SetInputConnection((vtkAlgorithmOutput)outTpd1.GetOutputPort());
tpd1Actor = new vtkActor();
tpd1Actor.SetMapper((vtkMapper)mapTpd1);
tpd1Actor.GetProperty().SetColor((double)0, (double)0, (double)0);
transP2 = new vtkTransform();
transP2.Translate((double)9.2, (double)0.0, (double)31.20);
transP2.Scale((double)5, (double)5, (double)5);
transP2.RotateY((double)90);
tpd2 = new vtkTransformPolyDataFilter();
tpd2.SetInputConnection((vtkAlgorithmOutput)plane.GetOutputPort());
tpd2.SetTransform((vtkAbstractTransform)transP2);
outTpd2 = new vtkOutlineFilter();
outTpd2.SetInputConnection((vtkAlgorithmOutput)tpd2.GetOutputPort());
mapTpd2 = vtkPolyDataMapper.New();
mapTpd2.SetInputConnection((vtkAlgorithmOutput)outTpd2.GetOutputPort());
tpd2Actor = new vtkActor();
tpd2Actor.SetMapper((vtkMapper)mapTpd2);
tpd2Actor.GetProperty().SetColor((double)0, (double)0, (double)0);
transP3 = new vtkTransform();
transP3.Translate((double)13.27, (double)0.0, (double)33.30);
transP3.Scale((double)5, (double)5, (double)5);
transP3.RotateY((double)90);
tpd3 = new vtkTransformPolyDataFilter();
tpd3.SetInputConnection((vtkAlgorithmOutput)plane.GetOutputPort());
tpd3.SetTransform((vtkAbstractTransform)transP3);
outTpd3 = new vtkOutlineFilter();
outTpd3.SetInputConnection((vtkAlgorithmOutput)tpd3.GetOutputPort());
mapTpd3 = vtkPolyDataMapper.New();
mapTpd3.SetInputConnection((vtkAlgorithmOutput)outTpd3.GetOutputPort());
tpd3Actor = new vtkActor();
tpd3Actor.SetMapper((vtkMapper)mapTpd3);
tpd3Actor.GetProperty().SetColor((double)0, (double)0, (double)0);
appendF = new vtkAppendPolyData();
appendF.AddInputConnection(tpd1.GetOutputPort());
appendF.AddInputConnection(tpd2.GetOutputPort());
appendF.AddInputConnection(tpd3.GetOutputPort());
probe = new vtkProbeFilter();
probe.SetInputConnection((vtkAlgorithmOutput)appendF.GetOutputPort());
probe.SetSourceData((vtkDataSet)pl3d.GetOutput().GetBlock(0));
contour = new vtkContourFilter();
contour.SetInputConnection((vtkAlgorithmOutput)probe.GetOutputPort());
contour.GenerateValues((int)50, (double)((vtkDataSet)pl3d.GetOutput().GetBlock(0)).GetScalarRange()[0],
(double)((vtkDataSet)pl3d.GetOutput().GetBlock(0)).GetScalarRange()[1]);
contourMapper = vtkPolyDataMapper.New();
contourMapper.SetInputConnection((vtkAlgorithmOutput)contour.GetOutputPort());
contourMapper.SetScalarRange((double)((vtkDataSet)pl3d.GetOutput().GetBlock(0)).GetScalarRange()[0],
(double)((vtkDataSet)pl3d.GetOutput().GetBlock(0)).GetScalarRange()[1]);
planeActor = new vtkActor();
planeActor.SetMapper((vtkMapper)contourMapper);
outline = new vtkStructuredGridOutlineFilter();
outline.SetInputData((vtkDataSet)pl3d.GetOutput().GetBlock(0));
outlineMapper = vtkPolyDataMapper.New();
outlineMapper.SetInputConnection((vtkAlgorithmOutput)outline.GetOutputPort());
outlineActor = new vtkActor();
outlineActor.SetMapper((vtkMapper)outlineMapper);
outlineActor.GetProperty().SetColor((double)0, (double)0, (double)0);
ren1.AddActor((vtkProp)outlineActor);
ren1.AddActor((vtkProp)planeActor);
ren1.AddActor((vtkProp)tpd1Actor);
ren1.AddActor((vtkProp)tpd2Actor);
ren1.AddActor((vtkProp)tpd3Actor);
ren1.SetBackground((double)1, (double)1, (double)1);
renWin.SetSize((int)400, (int)400);
cam1 = ren1.GetActiveCamera();
cam1.SetClippingRange((double)3.95297, (double)50);
cam1.SetFocalPoint((double)8.88908, (double)0.595038, (double)29.3342);
cam1.SetPosition((double)-12.3332, (double)31.7479, (double)41.2387);
cam1.SetViewUp((double)0.060772, (double)-0.319905, (double)0.945498);
iren.Initialize();
// prevent the tk window from showing up then start the event loop[]
//deleteAllVTKObjects();
}
///<summary> A Set Method for Static Variables </summary>
public static void Setoutline(vtkOutlineFilter toSet)
{
outline = toSet;
}
/// <summary>
/// The main entry method called by the CSharp driver
/// </summary>
/// <param name="argv"></param>
public static void AVcursor3D(String [] argv)
{
//Prefix Content is: ""
// This little example shows how a cursor can be created in []
// image viewers, and renderers. The standard TkImageViewerWidget and[]
// TkRenderWidget bindings are used. There is a new binding:[]
// middle button in the image viewer sets the position of the cursor. []
// First we include the VTK Tcl packages which will make available []
// all of the vtk commands to Tcl[]
// Global values[]
CURSOR_X = 20;
CURSOR_Y = 20;
CURSOR_Z = 20;
IMAGE_MAG_X = 4;
IMAGE_MAG_Y = 4;
IMAGE_MAG_Z = 1;
// Pipeline stuff[]
reader = new vtkSLCReader();
reader.SetFileName((string)"" + (VTK_DATA_ROOT.ToString()) + "/Data/neghip.slc");
// Cursor stuff[]
magnify = new vtkImageMagnify();
magnify.SetInputConnection((vtkAlgorithmOutput)reader.GetOutputPort());
magnify.SetMagnificationFactors((int)IMAGE_MAG_X, (int)IMAGE_MAG_Y, (int)IMAGE_MAG_Z);
image_cursor = new vtkImageCursor3D();
image_cursor.SetInputConnection((vtkAlgorithmOutput)magnify.GetOutputPort());
image_cursor.SetCursorPosition((double)CURSOR_X * IMAGE_MAG_X, (double)CURSOR_Y * IMAGE_MAG_Y, (double)CURSOR_Z * IMAGE_MAG_Z);
image_cursor.SetCursorValue((double)255);
image_cursor.SetCursorRadius((int)50 * IMAGE_MAG_X);
axes = new vtkAxes();
axes.SymmetricOn();
axes.SetOrigin((double)CURSOR_X, (double)CURSOR_Y, (double)CURSOR_Z);
axes.SetScaleFactor((double)50.0);
axes_mapper = vtkPolyDataMapper.New();
axes_mapper.SetInputConnection((vtkAlgorithmOutput)axes.GetOutputPort());
axesActor = new vtkActor();
axesActor.SetMapper((vtkMapper)axes_mapper);
axesActor.GetProperty().SetAmbient((double)0.5);
// Image viewer stuff[]
viewer = new vtkImageViewer();
viewer.SetInputConnection((vtkAlgorithmOutput)image_cursor.GetOutputPort());
viewer.SetZSlice((int)CURSOR_Z * IMAGE_MAG_Z);
viewer.SetColorWindow((double)256);
viewer.SetColorLevel((double)128);
//method moved
//method moved
//method moved
// Create transfer functions for opacity and color[]
opacity_transfer_function = new vtkPiecewiseFunction();
opacity_transfer_function.AddPoint((double)20, (double)0.0);
opacity_transfer_function.AddPoint((double)255, (double)0.2);
color_transfer_function = new vtkColorTransferFunction();
color_transfer_function.AddRGBPoint((double)0, (double)0, (double)0, (double)0);
color_transfer_function.AddRGBPoint((double)64, (double)1, (double)0, (double)0);
color_transfer_function.AddRGBPoint((double)128, (double)0, (double)0, (double)1);
color_transfer_function.AddRGBPoint((double)192, (double)0, (double)1, (double)0);
color_transfer_function.AddRGBPoint((double)255, (double)0, (double).2, (double)0);
// Create properties, mappers, volume actors, and ray cast function[]
volume_property = new vtkVolumeProperty();
volume_property.SetColor((vtkColorTransferFunction)color_transfer_function);
volume_property.SetScalarOpacity((vtkPiecewiseFunction)opacity_transfer_function);
composite_function = new vtkVolumeRayCastCompositeFunction();
volume_mapper = new vtkVolumeRayCastMapper();
volume_mapper.SetInputConnection((vtkAlgorithmOutput)reader.GetOutputPort());
volume_mapper.SetVolumeRayCastFunction((vtkVolumeRayCastFunction)composite_function);
volume = new vtkVolume();
volume.SetMapper((vtkAbstractVolumeMapper)volume_mapper);
volume.SetProperty((vtkVolumeProperty)volume_property);
// Create outline[]
outline = new vtkOutlineFilter();
outline.SetInputConnection((vtkAlgorithmOutput)reader.GetOutputPort());
outline_mapper = vtkPolyDataMapper.New();
outline_mapper.SetInputConnection((vtkAlgorithmOutput)outline.GetOutputPort());
outlineActor = new vtkActor();
outlineActor.SetMapper((vtkMapper)outline_mapper);
outlineActor.GetProperty().SetColor((double)1, (double)1, (double)1);
// Create the renderer[]
ren1 = vtkRenderer.New();
ren1.AddActor((vtkProp)axesActor);
ren1.AddVolume((vtkProp)volume);
ren1.SetBackground((double)0.1, (double)0.2, (double)0.4);
renWin2 = vtkRenderWindow.New();
renWin2.AddRenderer((vtkRenderer)ren1);
renWin2.SetSize((int)256, (int)256);
// Create the GUI: two renderer widgets and a quit button[]
//tk window skipped..
// Set the window manager (wm command) so that it registers a[]
// command to handle the WM_DELETE_WINDOW protocal request. This[]
// request is triggered when the widget is closed using the standard[]
// window manager icons or buttons. In this case the exit callback[]
// will be called and it will free up any objects we created then exit[]
// the application.[]
// Help label, frame and quit button[]
//tk window skipped..
//tk window skipped..
//tk window skipped..
//deleteAllVTKObjects();
}
/// <summary>
/// The main entry method called by the CSharp driver
/// </summary>
/// <param name="argv"></param>
public static void AVHyperScalarBar(String [] argv)
{
//Prefix Content is: ""
// Test the scalar bar actor using a logarithmic lookup table[]
//[]
VTK_INTEGRATE_BOTH_DIRECTIONS = 2;
//[]
// generate tensors[]
ptLoad = new vtkPointLoad();
ptLoad.SetLoadValue((double)100.0);
ptLoad.SetSampleDimensions((int)20, (int)20, (int)20);
ptLoad.ComputeEffectiveStressOn();
ptLoad.SetModelBounds((double)-10, (double)10, (double)-10, (double)10, (double)-10, (double)10);
// Generate hyperstreamlines[]
s1 = new vtkHyperStreamline();
s1.SetInputConnection((vtkAlgorithmOutput)ptLoad.GetOutputPort());
s1.SetStartPosition((double)9, (double)9, (double)-9);
s1.IntegrateMinorEigenvector();
s1.SetMaximumPropagationDistance((double)18.0);
s1.SetIntegrationStepLength((double)0.1);
s1.SetStepLength((double)0.01);
s1.SetRadius((double)0.25);
s1.SetNumberOfSides((int)18);
s1.SetIntegrationDirection((int)VTK_INTEGRATE_BOTH_DIRECTIONS);
s1.Update();
// Map hyperstreamlines[]
lut = new vtkLogLookupTable();
lut.SetHueRange((double).6667, (double)0.0);
scalarBar = new vtkScalarBarActor();
scalarBar.SetLookupTable((vtkScalarsToColors)lut);
scalarBar.SetTitle((string)"Stress");
scalarBar.GetPositionCoordinate().SetCoordinateSystemToNormalizedViewport();
scalarBar.GetPositionCoordinate().SetValue((double)0.1, (double)0.05);
scalarBar.SetOrientationToVertical();
scalarBar.SetWidth((double)0.1);
scalarBar.SetHeight((double)0.9);
scalarBar.SetPosition((double)0.01, (double)0.1);
scalarBar.SetLabelFormat((string)"%-#6.3f");
scalarBar.GetLabelTextProperty().SetColor((double)1, (double)0, (double)0);
scalarBar.GetTitleTextProperty().SetColor((double)1, (double)0, (double)0);
s1Mapper = vtkPolyDataMapper.New();
s1Mapper.SetInputConnection((vtkAlgorithmOutput)s1.GetOutputPort());
s1Mapper.SetLookupTable((vtkScalarsToColors)lut);
ptLoad.Update();
//force update for scalar range[]
s1Mapper.SetScalarRange((double)((vtkDataSet)ptLoad.GetOutput()).GetScalarRange()[0], (double)((vtkDataSet)ptLoad.GetOutput()).GetScalarRange()[1]);
s1Actor = new vtkActor();
s1Actor.SetMapper((vtkMapper)s1Mapper);
s2 = new vtkHyperStreamline();
s2.SetInputConnection((vtkAlgorithmOutput)ptLoad.GetOutputPort());
s2.SetStartPosition((double)-9, (double)-9, (double)-9);
s2.IntegrateMinorEigenvector();
s2.SetMaximumPropagationDistance((double)18.0);
s2.SetIntegrationStepLength((double)0.1);
s2.SetStepLength((double)0.01);
s2.SetRadius((double)0.25);
s2.SetNumberOfSides((int)18);
s2.SetIntegrationDirection((int)VTK_INTEGRATE_BOTH_DIRECTIONS);
s2.Update();
s2Mapper = vtkPolyDataMapper.New();
s2Mapper.SetInputConnection((vtkAlgorithmOutput)s2.GetOutputPort());
s2Mapper.SetLookupTable((vtkScalarsToColors)lut);
s2Mapper.SetScalarRange((double)((vtkDataSet)ptLoad.GetOutput()).GetScalarRange()[0], (double)((vtkDataSet)ptLoad.GetOutput()).GetScalarRange()[1]);
s2Actor = new vtkActor();
s2Actor.SetMapper((vtkMapper)s2Mapper);
s3 = new vtkHyperStreamline();
s3.SetInputConnection((vtkAlgorithmOutput)ptLoad.GetOutputPort());
s3.SetStartPosition((double)9, (double)-9, (double)-9);
s3.IntegrateMinorEigenvector();
s3.SetMaximumPropagationDistance((double)18.0);
s3.SetIntegrationStepLength((double)0.1);
s3.SetStepLength((double)0.01);
s3.SetRadius((double)0.25);
s3.SetNumberOfSides((int)18);
s3.SetIntegrationDirection((int)VTK_INTEGRATE_BOTH_DIRECTIONS);
s3.Update();
s3Mapper = vtkPolyDataMapper.New();
s3Mapper.SetInputConnection((vtkAlgorithmOutput)s3.GetOutputPort());
s3Mapper.SetLookupTable((vtkScalarsToColors)lut);
s3Mapper.SetScalarRange((double)((vtkDataSet)ptLoad.GetOutput()).GetScalarRange()[0], (double)((vtkDataSet)ptLoad.GetOutput()).GetScalarRange()[1]);
s3Actor = new vtkActor();
s3Actor.SetMapper((vtkMapper)s3Mapper);
s4 = new vtkHyperStreamline();
s4.SetInputConnection((vtkAlgorithmOutput)ptLoad.GetOutputPort());
s4.SetStartPosition((double)-9, (double)9, (double)-9);
s4.IntegrateMinorEigenvector();
s4.SetMaximumPropagationDistance((double)18.0);
s4.SetIntegrationStepLength((double)0.1);
s4.SetStepLength((double)0.01);
s4.SetRadius((double)0.25);
s4.SetNumberOfSides((int)18);
s4.SetIntegrationDirection((int)VTK_INTEGRATE_BOTH_DIRECTIONS);
s4.Update();
s4Mapper = vtkPolyDataMapper.New();
s4Mapper.SetInputConnection((vtkAlgorithmOutput)s4.GetOutputPort());
s4Mapper.SetLookupTable((vtkScalarsToColors)lut);
s4Mapper.SetScalarRange((double)((vtkDataSet)ptLoad.GetOutput()).GetScalarRange()[0], (double)((vtkDataSet)ptLoad.GetOutput()).GetScalarRange()[1]);
s4Actor = new vtkActor();
s4Actor.SetMapper((vtkMapper)s4Mapper);
// plane for context[]
//[]
g = new vtkImageDataGeometryFilter();
g.SetInputConnection((vtkAlgorithmOutput)ptLoad.GetOutputPort());
g.SetExtent((int)0, (int)100, (int)0, (int)100, (int)0, (int)0);
g.Update();
//for scalar range[]
gm = vtkPolyDataMapper.New();
gm.SetInputConnection((vtkAlgorithmOutput)g.GetOutputPort());
gm.SetScalarRange((double)((vtkImageDataGeometryFilter)g).GetOutput().GetScalarRange()[0], (double)((vtkImageDataGeometryFilter)g).GetOutput().GetScalarRange()[1]);
ga = new vtkActor();
ga.SetMapper((vtkMapper)gm);
// Create outline around data[]
//[]
outline = new vtkOutlineFilter();
outline.SetInputConnection((vtkAlgorithmOutput)ptLoad.GetOutputPort());
outlineMapper = vtkPolyDataMapper.New();
outlineMapper.SetInputConnection((vtkAlgorithmOutput)outline.GetOutputPort());
outlineActor = new vtkActor();
outlineActor.SetMapper((vtkMapper)outlineMapper);
outlineActor.GetProperty().SetColor((double)0, (double)0, (double)0);
// Create cone indicating application of load[]
//[]
coneSrc = new vtkConeSource();
coneSrc.SetRadius((double).5);
coneSrc.SetHeight((double)2);
coneMap = vtkPolyDataMapper.New();
coneMap.SetInputConnection((vtkAlgorithmOutput)coneSrc.GetOutputPort());
coneActor = new vtkActor();
coneActor.SetMapper((vtkMapper)coneMap);
coneActor.SetPosition((double)0, (double)0, (double)11);
coneActor.RotateY((double)90);
coneActor.GetProperty().SetColor((double)1, (double)0, (double)0);
// Create the rendering infrastructure[]
//[]
ren1 = vtkRenderer.New();
renWin = vtkRenderWindow.New();
renWin.AddRenderer((vtkRenderer)ren1);
iren = new vtkRenderWindowInteractor();
iren.SetRenderWindow((vtkRenderWindow)renWin);
camera = new vtkCamera();
camera.SetFocalPoint((double)0.113766, (double)-1.13665, (double)-1.01919);
camera.SetPosition((double)-29.4886, (double)-63.1488, (double)26.5807);
camera.SetViewAngle((double)24.4617);
camera.SetViewUp((double)0.17138, (double)0.331163, (double)0.927879);
camera.SetClippingRange((double)1, (double)100);
ren1.AddActor2D((vtkProp)scalarBar);
ren1.AddActor((vtkProp)s1Actor);
ren1.AddActor((vtkProp)s2Actor);
ren1.AddActor((vtkProp)s3Actor);
ren1.AddActor((vtkProp)s4Actor);
ren1.AddActor((vtkProp)outlineActor);
ren1.AddActor((vtkProp)coneActor);
ren1.AddActor((vtkProp)ga);
ren1.SetBackground((double)1.0, (double)1.0, (double)1.0);
ren1.SetActiveCamera((vtkCamera)camera);
renWin.SetSize((int)300, (int)300);
renWin.Render();
// prevent the tk window from showing up then start the event loop[]
//deleteAllVTKObjects();
}
/// <summary>
/// The main entry method called by the CSharp driver
/// </summary>
/// <param name="argv"></param>
public static void AVExtractTensors(String [] argv)
{
//Prefix Content is: ""
// create tensor ellipsoids[]
// Create the RenderWindow, Renderer and interactive renderer[]
//[]
ren1 = vtkRenderer.New();
renWin = vtkRenderWindow.New();
renWin.AddRenderer((vtkRenderer)ren1);
iren = new vtkRenderWindowInteractor();
iren.SetRenderWindow((vtkRenderWindow)renWin);
ptLoad = new vtkPointLoad();
ptLoad.SetLoadValue((double)100.0);
ptLoad.SetSampleDimensions((int)30,(int)30,(int)30);
ptLoad.ComputeEffectiveStressOn();
ptLoad.SetModelBounds((double)-10,(double)10,(double)-10,(double)10,(double)-10,(double)10);
extractTensor = new vtkExtractTensorComponents();
extractTensor.SetInputConnection((vtkAlgorithmOutput)ptLoad.GetOutputPort());
extractTensor.ScalarIsEffectiveStress();
extractTensor.ScalarIsComponent();
extractTensor.ExtractScalarsOn();
extractTensor.ExtractVectorsOn();
extractTensor.ExtractNormalsOff();
extractTensor.ExtractTCoordsOn();
contour = new vtkContourFilter();
contour.SetInputConnection((vtkAlgorithmOutput)extractTensor.GetOutputPort());
contour.SetValue((int)0,(double)0);
probe = new vtkProbeFilter();
probe.SetInputConnection((vtkAlgorithmOutput)contour.GetOutputPort());
probe.SetSource((vtkDataObject)ptLoad.GetOutput());
su = new vtkLoopSubdivisionFilter();
su.SetInputConnection((vtkAlgorithmOutput)probe.GetOutputPort());
su.SetNumberOfSubdivisions((int)1);
s1Mapper = vtkPolyDataMapper.New();
s1Mapper.SetInputConnection((vtkAlgorithmOutput)probe.GetOutputPort());
// s1Mapper SetInputConnection [su GetOutputPort][]
s1Actor = new vtkActor();
s1Actor.SetMapper((vtkMapper)s1Mapper);
//[]
// plane for context[]
//[]
g = new vtkImageDataGeometryFilter();
g.SetInputConnection((vtkAlgorithmOutput)ptLoad.GetOutputPort());
g.SetExtent((int)0,(int)100,(int)0,(int)100,(int)0,(int)0);
g.Update();
//for scalar range[]
gm = vtkPolyDataMapper.New();
gm.SetInputConnection((vtkAlgorithmOutput)g.GetOutputPort());
gm.SetScalarRange((double)((vtkDataSet)g.GetOutput()).GetScalarRange()[0],(double)((vtkDataSet)g.GetOutput()).GetScalarRange()[1]);
ga = new vtkActor();
ga.SetMapper((vtkMapper)gm);
s1Mapper.SetScalarRange((double)((vtkDataSet)g.GetOutput()).GetScalarRange()[0],(double)((vtkDataSet)g.GetOutput()).GetScalarRange()[1]);
//[]
// Create outline around data[]
//[]
outline = new vtkOutlineFilter();
outline.SetInputConnection((vtkAlgorithmOutput)ptLoad.GetOutputPort());
outlineMapper = vtkPolyDataMapper.New();
outlineMapper.SetInputConnection((vtkAlgorithmOutput)outline.GetOutputPort());
outlineActor = new vtkActor();
outlineActor.SetMapper((vtkMapper)outlineMapper);
outlineActor.GetProperty().SetColor((double)0,(double)0,(double)0);
//[]
// Create cone indicating application of load[]
//[]
coneSrc = new vtkConeSource();
coneSrc.SetRadius((double).5);
coneSrc.SetHeight((double)2);
coneMap = vtkPolyDataMapper.New();
coneMap.SetInputConnection((vtkAlgorithmOutput)coneSrc.GetOutputPort());
coneActor = new vtkActor();
coneActor.SetMapper((vtkMapper)coneMap);
coneActor.SetPosition((double)0,(double)0,(double)11);
coneActor.RotateY((double)90);
coneActor.GetProperty().SetColor((double)1,(double)0,(double)0);
camera = new vtkCamera();
camera.SetFocalPoint((double)0.113766,(double)-1.13665,(double)-1.01919);
camera.SetPosition((double)-29.4886,(double)-63.1488,(double)26.5807);
camera.SetViewAngle((double)24.4617);
camera.SetViewUp((double)0.17138,(double)0.331163,(double)0.927879);
camera.SetClippingRange((double)1,(double)100);
ren1.AddActor((vtkProp)s1Actor);
ren1.AddActor((vtkProp)outlineActor);
ren1.AddActor((vtkProp)coneActor);
ren1.AddActor((vtkProp)ga);
ren1.SetBackground((double)1.0,(double)1.0,(double)1.0);
ren1.SetActiveCamera((vtkCamera)camera);
renWin.SetSize((int)300,(int)300);
renWin.Render();
// prevent the tk window from showing up then start the event loop[]
//deleteAllVTKObjects();
}
private void SampleFunction()
{
vtkSphere sphere = vtkSphere.New();
// Sample the function
vtkSampleFunction sample = vtkSampleFunction.New();
sample.SetSampleDimensions(50, 50, 50);
sample.SetImplicitFunction(sphere);
double value = 2.0;
double xmin = -value, xmax = value, ymin = -value, ymax = value, zmin = -value, zmax = value;
sample.SetModelBounds(xmin, xmax, ymin, ymax, zmin, zmax);
// Create the 0 isosurface
vtkContourFilter contours = vtkContourFilter.New();
#if VTK_MAJOR_VERSION_5
contours.SetInputConnection(sample.GetOutputPort());
#else
contours.SetInputData(sample);
#endif
contours.GenerateValues(1, 1, 1);
// Map the contours to graphical primitives
vtkPolyDataMapper contourMapper = vtkPolyDataMapper.New();
#if VTK_MAJOR_VERSION_5
contourMapper.SetInputConnection(contours.GetOutputPort());
#else
contourMapper.SetInputData(contours);
#endif
contourMapper.SetScalarRange(0.0, 1.2);
// Create an actor for the contours
vtkActor contourActor = vtkActor.New();
contourActor.SetMapper(contourMapper);
// -- create a box around the function to indicate the sampling volume --
// Create outline
vtkOutlineFilter outline = vtkOutlineFilter.New();
#if VTK_MAJOR_VERSION_5
outline.SetInputConnection(sample.GetOutputPort());
#else
outline.SetInputData(sample);
#endif
// Map it to graphics primitives
vtkPolyDataMapper outlineMapper = vtkPolyDataMapper.New();
#if VTK_MAJOR_VERSION_5
outlineMapper.SetInputConnection(outline.GetOutputPort());
#else
outlineMapper.SetInputData(outline);
#endif
// Create an actor for it
vtkActor outlineActor = vtkActor.New();
outlineActor.SetMapper(outlineMapper);
outlineActor.GetProperty().SetColor(0, 0, 0);
// get a reference to the renderwindow of our renderWindowControl1
vtkRenderWindow renderWindow = renderWindowControl1.RenderWindow;
// renderer
vtkRenderer renderer = renderWindow.GetRenderers().GetFirstRenderer();
// set background color
renderer.SetBackground(1.0, 1.0, 1.0);
// add our actor to the renderer
renderer.AddActor(contourActor);
renderer.AddActor(outlineActor);
}
/// <summary>
/// The main entry method called by the CSharp driver
/// </summary>
/// <param name="argv"></param>
public static void AVfieldToRGrid(String [] argv)
{
//Prefix Content is: ""
//# Generate a rectilinear grid from a field.[]
//#[]
// get the interactor ui[]
// Create a reader and write out the field[]
reader = new vtkDataSetReader();
reader.SetFileName((string)"" + (VTK_DATA_ROOT.ToString()) + "/Data/RectGrid2.vtk");
ds2do = new vtkDataSetToDataObjectFilter();
ds2do.SetInputConnection((vtkAlgorithmOutput)reader.GetOutputPort());
try
{
channel = new StreamWriter("RGridField.vtk");
tryCatchError = "NOERROR";
}
catch(Exception)
{tryCatchError = "ERROR";}
if(tryCatchError.Equals("NOERROR"))
{
channel.Close();
writer = new vtkDataObjectWriter();
writer.SetInputConnection((vtkAlgorithmOutput)ds2do.GetOutputPort());
writer.SetFileName((string)"RGridField.vtk");
writer.Write();
// Read the field[]
//[]
dor = new vtkDataObjectReader();
dor.SetFileName((string)"RGridField.vtk");
do2ds = new vtkDataObjectToDataSetFilter();
do2ds.SetInputConnection((vtkAlgorithmOutput)dor.GetOutputPort());
do2ds.SetDataSetTypeToRectilinearGrid();
do2ds.SetDimensionsComponent((string)"Dimensions",(int)0);
do2ds.SetPointComponent((int)0,(string)"XCoordinates",(int)0);
do2ds.SetPointComponent((int)1,(string)"YCoordinates",(int)0);
do2ds.SetPointComponent((int)2,(string)"ZCoordinates",(int)0);
fd2ad = new vtkFieldDataToAttributeDataFilter();
fd2ad.SetInput((vtkDataObject)do2ds.GetRectilinearGridOutput());
fd2ad.SetInputFieldToDataObjectField();
fd2ad.SetOutputAttributeDataToPointData();
fd2ad.SetVectorComponent((int)0,(string)"vectors",(int)0);
fd2ad.SetVectorComponent((int)1,(string)"vectors",(int)1);
fd2ad.SetVectorComponent((int)2,(string)"vectors",(int)2);
fd2ad.SetScalarComponent((int)0,(string)"scalars",(int)0);
fd2ad.Update();
// create pipeline[]
//[]
plane = new vtkRectilinearGridGeometryFilter();
plane.SetInput((vtkDataObject)fd2ad.GetRectilinearGridOutput());
plane.SetExtent((int)0,(int)100,(int)0,(int)100,(int)15,(int)15);
warper = new vtkWarpVector();
warper.SetInputConnection((vtkAlgorithmOutput)plane.GetOutputPort());
warper.SetScaleFactor((double)0.05);
planeMapper = new vtkDataSetMapper();
planeMapper.SetInputConnection((vtkAlgorithmOutput)warper.GetOutputPort());
planeMapper.SetScalarRange((double)0.197813,(double)0.710419);
planeActor = new vtkActor();
planeActor.SetMapper((vtkMapper)planeMapper);
cutPlane = new vtkPlane();
cutPlane.SetOrigin(fd2ad.GetOutput().GetCenter()[0],fd2ad.GetOutput().GetCenter()[1],fd2ad.GetOutput().GetCenter()[2]);
cutPlane.SetNormal((double)1,(double)0,(double)0);
planeCut = new vtkCutter();
planeCut.SetInput((vtkDataObject)fd2ad.GetRectilinearGridOutput());
planeCut.SetCutFunction((vtkImplicitFunction)cutPlane);
cutMapper = new vtkDataSetMapper();
cutMapper.SetInputConnection((vtkAlgorithmOutput)planeCut.GetOutputPort());
cutMapper.SetScalarRange(
(double)((vtkDataSet)fd2ad.GetOutput()).GetPointData().GetScalars().GetRange()[0],
(double)((vtkDataSet)fd2ad.GetOutput()).GetPointData().GetScalars().GetRange()[1]);
cutActor = new vtkActor();
cutActor.SetMapper((vtkMapper)cutMapper);
iso = new vtkContourFilter();
iso.SetInput((vtkDataObject)fd2ad.GetRectilinearGridOutput());
iso.SetValue((int)0,(double)0.7);
normals = new vtkPolyDataNormals();
normals.SetInputConnection((vtkAlgorithmOutput)iso.GetOutputPort());
normals.SetFeatureAngle((double)45);
isoMapper = vtkPolyDataMapper.New();
isoMapper.SetInputConnection((vtkAlgorithmOutput)normals.GetOutputPort());
isoMapper.ScalarVisibilityOff();
isoActor = new vtkActor();
isoActor.SetMapper((vtkMapper)isoMapper);
isoActor.GetProperty().SetColor((double) 1.0000, 0.8941, 0.7686 );
isoActor.GetProperty().SetRepresentationToWireframe();
streamer = new vtkStreamLine();
streamer.SetInputConnection((vtkAlgorithmOutput)fd2ad.GetOutputPort());
streamer.SetStartPosition((double)-1.2,(double)-0.1,(double)1.3);
streamer.SetMaximumPropagationTime((double)500);
streamer.SetStepLength((double)0.05);
streamer.SetIntegrationStepLength((double)0.05);
streamer.SetIntegrationDirectionToIntegrateBothDirections();
streamTube = new vtkTubeFilter();
streamTube.SetInputConnection((vtkAlgorithmOutput)streamer.GetOutputPort());
streamTube.SetRadius((double)0.025);
streamTube.SetNumberOfSides((int)6);
streamTube.SetVaryRadiusToVaryRadiusByVector();
mapStreamTube = vtkPolyDataMapper.New();
mapStreamTube.SetInputConnection((vtkAlgorithmOutput)streamTube.GetOutputPort());
mapStreamTube.SetScalarRange(
(double)((vtkDataSet)fd2ad.GetOutput()).GetPointData().GetScalars().GetRange()[0],
(double)((vtkDataSet)fd2ad.GetOutput()).GetPointData().GetScalars().GetRange()[1]);
streamTubeActor = new vtkActor();
streamTubeActor.SetMapper((vtkMapper)mapStreamTube);
streamTubeActor.GetProperty().BackfaceCullingOn();
outline = new vtkOutlineFilter();
outline.SetInput((vtkDataObject)fd2ad.GetRectilinearGridOutput());
outlineMapper = vtkPolyDataMapper.New();
outlineMapper.SetInputConnection((vtkAlgorithmOutput)outline.GetOutputPort());
outlineActor = new vtkActor();
outlineActor.SetMapper((vtkMapper)outlineMapper);
outlineActor.GetProperty().SetColor((double) 0.0000, 0.0000, 0.0000 );
// Graphics stuff[]
// Create the RenderWindow, Renderer and both Actors[]
//[]
ren1 = vtkRenderer.New();
renWin = vtkRenderWindow.New();
renWin.AddRenderer((vtkRenderer)ren1);
iren = new vtkRenderWindowInteractor();
iren.SetRenderWindow((vtkRenderWindow)renWin);
// Add the actors to the renderer, set the background and size[]
//[]
ren1.AddActor((vtkProp)outlineActor);
ren1.AddActor((vtkProp)planeActor);
ren1.AddActor((vtkProp)cutActor);
ren1.AddActor((vtkProp)isoActor);
ren1.AddActor((vtkProp)streamTubeActor);
ren1.SetBackground((double)1,(double)1,(double)1);
renWin.SetSize((int)300,(int)300);
ren1.GetActiveCamera().SetPosition((double)0.0390893,(double)0.184813,(double)-3.94026);
ren1.GetActiveCamera().SetFocalPoint((double)-0.00578326,(double)0,(double)0.701967);
ren1.GetActiveCamera().SetViewAngle((double)30);
ren1.GetActiveCamera().SetViewUp((double)0.00850257,(double)0.999169,(double)0.0398605);
ren1.GetActiveCamera().SetClippingRange((double)3.08127,(double)6.62716);
iren.Initialize();
// render the image[]
//[]
File.Delete("RGridField.vtk");
}
// prevent the tk window from showing up then start the event loop[]
//deleteAllVTKObjects();
}
/// <summary>
/// The main entry method called by the CSharp driver
/// </summary>
/// <param name="argv"></param>
public static void AVfieldToRGrid(String [] argv)
{
//Prefix Content is: ""
//# Generate a rectilinear grid from a field.[]
//#[]
// get the interactor ui[]
// Create a reader and write out the field[]
reader = new vtkDataSetReader();
reader.SetFileName((string)"" + (VTK_DATA_ROOT.ToString()) + "/Data/RectGrid2.vtk");
ds2do = new vtkDataSetToDataObjectFilter();
ds2do.SetInputConnection((vtkAlgorithmOutput)reader.GetOutputPort());
try
{
channel = new StreamWriter("RGridField.vtk");
tryCatchError = "NOERROR";
}
catch (Exception)
{ tryCatchError = "ERROR"; }
if (tryCatchError.Equals("NOERROR"))
{
channel.Close();
writer = new vtkDataObjectWriter();
writer.SetInputConnection((vtkAlgorithmOutput)ds2do.GetOutputPort());
writer.SetFileName((string)"RGridField.vtk");
writer.Write();
// Read the field[]
//[]
dor = new vtkDataObjectReader();
dor.SetFileName((string)"RGridField.vtk");
do2ds = new vtkDataObjectToDataSetFilter();
do2ds.SetInputConnection((vtkAlgorithmOutput)dor.GetOutputPort());
do2ds.SetDataSetTypeToRectilinearGrid();
do2ds.SetDimensionsComponent((string)"Dimensions", (int)0);
do2ds.SetPointComponent((int)0, (string)"XCoordinates", (int)0);
do2ds.SetPointComponent((int)1, (string)"YCoordinates", (int)0);
do2ds.SetPointComponent((int)2, (string)"ZCoordinates", (int)0);
do2ds.Update();
fd2ad = new vtkFieldDataToAttributeDataFilter();
fd2ad.SetInputData((vtkDataObject)do2ds.GetRectilinearGridOutput());
fd2ad.SetInputFieldToDataObjectField();
fd2ad.SetOutputAttributeDataToPointData();
fd2ad.SetVectorComponent((int)0, (string)"vectors", (int)0);
fd2ad.SetVectorComponent((int)1, (string)"vectors", (int)1);
fd2ad.SetVectorComponent((int)2, (string)"vectors", (int)2);
fd2ad.SetScalarComponent((int)0, (string)"scalars", (int)0);
fd2ad.Update();
// create pipeline[]
//[]
plane = new vtkRectilinearGridGeometryFilter();
plane.SetInputData((vtkDataObject)fd2ad.GetRectilinearGridOutput());
plane.SetExtent((int)0, (int)100, (int)0, (int)100, (int)15, (int)15);
warper = new vtkWarpVector();
warper.SetInputConnection((vtkAlgorithmOutput)plane.GetOutputPort());
warper.SetScaleFactor((double)0.05);
planeMapper = new vtkDataSetMapper();
planeMapper.SetInputConnection((vtkAlgorithmOutput)warper.GetOutputPort());
planeMapper.SetScalarRange((double)0.197813, (double)0.710419);
planeActor = new vtkActor();
planeActor.SetMapper((vtkMapper)planeMapper);
cutPlane = new vtkPlane();
cutPlane.SetOrigin(fd2ad.GetOutput().GetCenter()[0], fd2ad.GetOutput().GetCenter()[1], fd2ad.GetOutput().GetCenter()[2]);
cutPlane.SetNormal((double)1, (double)0, (double)0);
planeCut = new vtkCutter();
planeCut.SetInputData((vtkDataObject)fd2ad.GetRectilinearGridOutput());
planeCut.SetCutFunction((vtkImplicitFunction)cutPlane);
cutMapper = new vtkDataSetMapper();
cutMapper.SetInputConnection((vtkAlgorithmOutput)planeCut.GetOutputPort());
cutMapper.SetScalarRange(
(double)((vtkDataSet)fd2ad.GetOutput()).GetPointData().GetScalars().GetRange()[0],
(double)((vtkDataSet)fd2ad.GetOutput()).GetPointData().GetScalars().GetRange()[1]);
cutActor = new vtkActor();
cutActor.SetMapper((vtkMapper)cutMapper);
iso = new vtkContourFilter();
iso.SetInputData((vtkDataObject)fd2ad.GetRectilinearGridOutput());
iso.SetValue((int)0, (double)0.7);
normals = new vtkPolyDataNormals();
normals.SetInputConnection((vtkAlgorithmOutput)iso.GetOutputPort());
normals.SetFeatureAngle((double)45);
isoMapper = vtkPolyDataMapper.New();
isoMapper.SetInputConnection((vtkAlgorithmOutput)normals.GetOutputPort());
isoMapper.ScalarVisibilityOff();
isoActor = new vtkActor();
isoActor.SetMapper((vtkMapper)isoMapper);
isoActor.GetProperty().SetColor((double)1.0000, 0.8941, 0.7686);
isoActor.GetProperty().SetRepresentationToWireframe();
streamer = new vtkStreamLine();
streamer.SetInputConnection((vtkAlgorithmOutput)fd2ad.GetOutputPort());
streamer.SetStartPosition((double)-1.2, (double)-0.1, (double)1.3);
streamer.SetMaximumPropagationTime((double)500);
streamer.SetStepLength((double)0.05);
streamer.SetIntegrationStepLength((double)0.05);
streamer.SetIntegrationDirectionToIntegrateBothDirections();
streamTube = new vtkTubeFilter();
streamTube.SetInputConnection((vtkAlgorithmOutput)streamer.GetOutputPort());
streamTube.SetRadius((double)0.025);
streamTube.SetNumberOfSides((int)6);
streamTube.SetVaryRadiusToVaryRadiusByVector();
mapStreamTube = vtkPolyDataMapper.New();
mapStreamTube.SetInputConnection((vtkAlgorithmOutput)streamTube.GetOutputPort());
mapStreamTube.SetScalarRange(
(double)((vtkDataSet)fd2ad.GetOutput()).GetPointData().GetScalars().GetRange()[0],
(double)((vtkDataSet)fd2ad.GetOutput()).GetPointData().GetScalars().GetRange()[1]);
streamTubeActor = new vtkActor();
streamTubeActor.SetMapper((vtkMapper)mapStreamTube);
streamTubeActor.GetProperty().BackfaceCullingOn();
outline = new vtkOutlineFilter();
outline.SetInputData((vtkDataObject)fd2ad.GetRectilinearGridOutput());
outlineMapper = vtkPolyDataMapper.New();
outlineMapper.SetInputConnection((vtkAlgorithmOutput)outline.GetOutputPort());
outlineActor = new vtkActor();
outlineActor.SetMapper((vtkMapper)outlineMapper);
outlineActor.GetProperty().SetColor((double)0.0000, 0.0000, 0.0000);
// Graphics stuff[]
// Create the RenderWindow, Renderer and both Actors[]
//[]
ren1 = vtkRenderer.New();
renWin = vtkRenderWindow.New();
renWin.SetMultiSamples(0);
renWin.AddRenderer((vtkRenderer)ren1);
iren = new vtkRenderWindowInteractor();
iren.SetRenderWindow((vtkRenderWindow)renWin);
// Add the actors to the renderer, set the background and size[]
//[]
ren1.AddActor((vtkProp)outlineActor);
ren1.AddActor((vtkProp)planeActor);
ren1.AddActor((vtkProp)cutActor);
ren1.AddActor((vtkProp)isoActor);
ren1.AddActor((vtkProp)streamTubeActor);
ren1.SetBackground((double)1, (double)1, (double)1);
renWin.SetSize((int)300, (int)300);
ren1.GetActiveCamera().SetPosition((double)0.0390893, (double)0.184813, (double)-3.94026);
ren1.GetActiveCamera().SetFocalPoint((double)-0.00578326, (double)0, (double)0.701967);
ren1.GetActiveCamera().SetViewAngle((double)30);
ren1.GetActiveCamera().SetViewUp((double)0.00850257, (double)0.999169, (double)0.0398605);
ren1.GetActiveCamera().SetClippingRange((double)3.08127, (double)6.62716);
iren.Initialize();
// render the image[]
//[]
File.Delete("RGridField.vtk");
}
// prevent the tk window from showing up then start the event loop[]
//deleteAllVTKObjects();
}
/// <summary>
/// The main entry method called by the CSharp driver
/// </summary>
/// <param name="argv"></param>
public static void AVHyper(String [] argv)
{
//Prefix Content is: ""
// Create the RenderWindow, Renderer and interactive renderer[]
//[]
ren1 = vtkRenderer.New();
renWin = vtkRenderWindow.New();
renWin.AddRenderer((vtkRenderer)ren1);
iren = new vtkRenderWindowInteractor();
iren.SetRenderWindow((vtkRenderWindow)renWin);
VTK_INTEGRATE_BOTH_DIRECTIONS = 2;
//[]
// generate tensors[]
ptLoad = new vtkPointLoad();
ptLoad.SetLoadValue((double)100.0);
ptLoad.SetSampleDimensions((int)20, (int)20, (int)20);
ptLoad.ComputeEffectiveStressOn();
ptLoad.SetModelBounds((double)-10, (double)10, (double)-10, (double)10, (double)-10, (double)10);
//[]
// If the current directory is writable, then test the witers[]
//[]
try
{
channel = new StreamWriter("test.tmp");
tryCatchError = "NOERROR";
}
catch (Exception)
{ tryCatchError = "ERROR"; }
if (tryCatchError.Equals("NOERROR"))
{
channel.Close();
File.Delete("test.tmp");
wSP = new vtkDataSetWriter();
wSP.SetInputConnection((vtkAlgorithmOutput)ptLoad.GetOutputPort());
wSP.SetFileName((string)"wSP.vtk");
wSP.SetTensorsName((string)"pointload");
wSP.SetScalarsName((string)"effective_stress");
wSP.Write();
rSP = new vtkDataSetReader();
rSP.SetFileName((string)"wSP.vtk");
rSP.SetTensorsName((string)"pointload");
rSP.SetScalarsName((string)"effective_stress");
rSP.Update();
input = rSP.GetOutput();
File.Delete("wSP.vtk");
}
else
{
input = ptLoad.GetOutput();
}
// Generate hyperstreamlines[]
s1 = new vtkHyperStreamline();
s1.SetInputData((vtkDataObject)input);
s1.SetStartPosition((double)9, (double)9, (double)-9);
s1.IntegrateMinorEigenvector();
s1.SetMaximumPropagationDistance((double)18.0);
s1.SetIntegrationStepLength((double)0.1);
s1.SetStepLength((double)0.01);
s1.SetRadius((double)0.25);
s1.SetNumberOfSides((int)18);
s1.SetIntegrationDirection((int)VTK_INTEGRATE_BOTH_DIRECTIONS);
s1.Update();
// Map hyperstreamlines[]
lut = new vtkLogLookupTable();
lut.SetHueRange((double).6667, (double)0.0);
s1Mapper = vtkPolyDataMapper.New();
s1Mapper.SetInputConnection((vtkAlgorithmOutput)s1.GetOutputPort());
s1Mapper.SetLookupTable((vtkScalarsToColors)lut);
ptLoad.Update();
//force update for scalar range[]
s1Mapper.SetScalarRange((double)((vtkDataSet)ptLoad.GetOutput()).GetScalarRange()[0], (double)((vtkDataSet)ptLoad.GetOutput()).GetScalarRange()[1]);
s1Actor = new vtkActor();
s1Actor.SetMapper((vtkMapper)s1Mapper);
s2 = new vtkHyperStreamline();
s2.SetInputData((vtkDataObject)input);
s2.SetStartPosition((double)-9, (double)-9, (double)-9);
s2.IntegrateMinorEigenvector();
s2.SetMaximumPropagationDistance((double)18.0);
s2.SetIntegrationStepLength((double)0.1);
s2.SetStepLength((double)0.01);
s2.SetRadius((double)0.25);
s2.SetNumberOfSides((int)18);
s2.SetIntegrationDirection((int)VTK_INTEGRATE_BOTH_DIRECTIONS);
s2.Update();
s2Mapper = vtkPolyDataMapper.New();
s2Mapper.SetInputConnection((vtkAlgorithmOutput)s2.GetOutputPort());
s2Mapper.SetLookupTable((vtkScalarsToColors)lut);
s2Mapper.SetScalarRange((double)((vtkDataSet)input).GetScalarRange()[0], (double)((vtkDataSet)input).GetScalarRange()[1]);
s2Actor = new vtkActor();
s2Actor.SetMapper((vtkMapper)s2Mapper);
s3 = new vtkHyperStreamline();
s3.SetInputData((vtkDataObject)input);
s3.SetStartPosition((double)9, (double)-9, (double)-9);
s3.IntegrateMinorEigenvector();
s3.SetMaximumPropagationDistance((double)18.0);
s3.SetIntegrationStepLength((double)0.1);
s3.SetStepLength((double)0.01);
s3.SetRadius((double)0.25);
s3.SetNumberOfSides((int)18);
s3.SetIntegrationDirection((int)VTK_INTEGRATE_BOTH_DIRECTIONS);
s3.Update();
s3Mapper = vtkPolyDataMapper.New();
s3Mapper.SetInputConnection((vtkAlgorithmOutput)s3.GetOutputPort());
s3Mapper.SetLookupTable((vtkScalarsToColors)lut);
s3Mapper.SetScalarRange((double)((vtkDataSet)input).GetScalarRange()[0],
(double)((vtkDataSet)input).GetScalarRange()[1]);
s3Actor = new vtkActor();
s3Actor.SetMapper((vtkMapper)s3Mapper);
s4 = new vtkHyperStreamline();
s4.SetInputData((vtkDataObject)input);
s4.SetStartPosition((double)-9, (double)9, (double)-9);
s4.IntegrateMinorEigenvector();
s4.SetMaximumPropagationDistance((double)18.0);
s4.SetIntegrationStepLength((double)0.1);
s4.SetStepLength((double)0.01);
s4.SetRadius((double)0.25);
s4.SetNumberOfSides((int)18);
s4.SetIntegrationDirection((int)VTK_INTEGRATE_BOTH_DIRECTIONS);
s4.Update();
s4Mapper = vtkPolyDataMapper.New();
s4Mapper.SetInputConnection((vtkAlgorithmOutput)s4.GetOutputPort());
s4Mapper.SetLookupTable((vtkScalarsToColors)lut);
s4Mapper.SetScalarRange((double)((vtkDataSet)input).GetScalarRange()[0], (double)((vtkDataSet)input).GetScalarRange()[1]);
s4Actor = new vtkActor();
s4Actor.SetMapper((vtkMapper)s4Mapper);
// plane for context[]
//[]
g = new vtkImageDataGeometryFilter();
g.SetInputData((vtkDataObject)input);
g.SetExtent((int)0, (int)100, (int)0, (int)100, (int)0, (int)0);
g.Update();
//for scalar range[]
gm = vtkPolyDataMapper.New();
gm.SetInputConnection((vtkAlgorithmOutput)g.GetOutputPort());
gm.SetScalarRange((double)((vtkDataSet)g.GetOutput()).GetScalarRange()[0], (double)((vtkDataSet)g.GetOutput()).GetScalarRange()[1]);
ga = new vtkActor();
ga.SetMapper((vtkMapper)gm);
// Create outline around data[]
//[]
outline = new vtkOutlineFilter();
outline.SetInputData((vtkDataObject)input);
outlineMapper = vtkPolyDataMapper.New();
outlineMapper.SetInputConnection((vtkAlgorithmOutput)outline.GetOutputPort());
outlineActor = new vtkActor();
outlineActor.SetMapper((vtkMapper)outlineMapper);
outlineActor.GetProperty().SetColor((double)0, (double)0, (double)0);
// Create cone indicating application of load[]
//[]
coneSrc = new vtkConeSource();
coneSrc.SetRadius((double).5);
coneSrc.SetHeight((double)2);
coneMap = vtkPolyDataMapper.New();
coneMap.SetInputConnection((vtkAlgorithmOutput)coneSrc.GetOutputPort());
coneActor = new vtkActor();
coneActor.SetMapper((vtkMapper)coneMap);
coneActor.SetPosition((double)0, (double)0, (double)11);
coneActor.RotateY((double)90);
coneActor.GetProperty().SetColor((double)1, (double)0, (double)0);
camera = new vtkCamera();
camera.SetFocalPoint((double)0.113766, (double)-1.13665, (double)-1.01919);
camera.SetPosition((double)-29.4886, (double)-63.1488, (double)26.5807);
camera.SetViewAngle((double)24.4617);
camera.SetViewUp((double)0.17138, (double)0.331163, (double)0.927879);
camera.SetClippingRange((double)1, (double)100);
ren1.AddActor((vtkProp)s1Actor);
ren1.AddActor((vtkProp)s2Actor);
ren1.AddActor((vtkProp)s3Actor);
ren1.AddActor((vtkProp)s4Actor);
ren1.AddActor((vtkProp)outlineActor);
ren1.AddActor((vtkProp)coneActor);
ren1.AddActor((vtkProp)ga);
ren1.SetBackground((double)1.0, (double)1.0, (double)1.0);
ren1.SetActiveCamera((vtkCamera)camera);
renWin.SetSize((int)300, (int)300);
renWin.Render();
// prevent the tk window from showing up then start the event loop[]
//deleteAllVTKObjects();
}
/// <summary>
/// The main entry method called by the CSharp driver
/// </summary>
/// <param name="argv"></param>
public static void AVprobeComb(String [] argv)
{
//Prefix Content is: ""
// create planes[]
// Create the RenderWindow, Renderer and both Actors[]
//[]
ren1 = vtkRenderer.New();
renWin = vtkRenderWindow.New();
renWin.AddRenderer((vtkRenderer)ren1);
iren = new vtkRenderWindowInteractor();
iren.SetRenderWindow((vtkRenderWindow)renWin);
// create pipeline[]
//[]
pl3d = new vtkPLOT3DReader();
pl3d.SetXYZFileName((string)"" + (VTK_DATA_ROOT.ToString()) + "/Data/combxyz.bin");
pl3d.SetQFileName((string)"" + (VTK_DATA_ROOT.ToString()) + "/Data/combq.bin");
pl3d.SetScalarFunctionNumber((int)100);
pl3d.SetVectorFunctionNumber((int)202);
pl3d.Update();
plane = new vtkPlaneSource();
plane.SetResolution((int)50,(int)50);
transP1 = new vtkTransform();
transP1.Translate((double)3.7,(double)0.0,(double)28.37);
transP1.Scale((double)5,(double)5,(double)5);
transP1.RotateY((double)90);
tpd1 = new vtkTransformPolyDataFilter();
tpd1.SetInputConnection((vtkAlgorithmOutput)plane.GetOutputPort());
tpd1.SetTransform((vtkAbstractTransform)transP1);
outTpd1 = new vtkOutlineFilter();
outTpd1.SetInputConnection((vtkAlgorithmOutput)tpd1.GetOutputPort());
mapTpd1 = vtkPolyDataMapper.New();
mapTpd1.SetInputConnection((vtkAlgorithmOutput)outTpd1.GetOutputPort());
tpd1Actor = new vtkActor();
tpd1Actor.SetMapper((vtkMapper)mapTpd1);
tpd1Actor.GetProperty().SetColor((double)0,(double)0,(double)0);
transP2 = new vtkTransform();
transP2.Translate((double)9.2,(double)0.0,(double)31.20);
transP2.Scale((double)5,(double)5,(double)5);
transP2.RotateY((double)90);
tpd2 = new vtkTransformPolyDataFilter();
tpd2.SetInputConnection((vtkAlgorithmOutput)plane.GetOutputPort());
tpd2.SetTransform((vtkAbstractTransform)transP2);
outTpd2 = new vtkOutlineFilter();
outTpd2.SetInputConnection((vtkAlgorithmOutput)tpd2.GetOutputPort());
mapTpd2 = vtkPolyDataMapper.New();
mapTpd2.SetInputConnection((vtkAlgorithmOutput)outTpd2.GetOutputPort());
tpd2Actor = new vtkActor();
tpd2Actor.SetMapper((vtkMapper)mapTpd2);
tpd2Actor.GetProperty().SetColor((double)0,(double)0,(double)0);
transP3 = new vtkTransform();
transP3.Translate((double)13.27,(double)0.0,(double)33.30);
transP3.Scale((double)5,(double)5,(double)5);
transP3.RotateY((double)90);
tpd3 = new vtkTransformPolyDataFilter();
tpd3.SetInputConnection((vtkAlgorithmOutput)plane.GetOutputPort());
tpd3.SetTransform((vtkAbstractTransform)transP3);
outTpd3 = new vtkOutlineFilter();
outTpd3.SetInputConnection((vtkAlgorithmOutput)tpd3.GetOutputPort());
mapTpd3 = vtkPolyDataMapper.New();
mapTpd3.SetInputConnection((vtkAlgorithmOutput)outTpd3.GetOutputPort());
tpd3Actor = new vtkActor();
tpd3Actor.SetMapper((vtkMapper)mapTpd3);
tpd3Actor.GetProperty().SetColor((double)0,(double)0,(double)0);
appendF = new vtkAppendPolyData();
appendF.AddInput((vtkPolyData)tpd1.GetOutput());
appendF.AddInput((vtkPolyData)tpd2.GetOutput());
appendF.AddInput((vtkPolyData)tpd3.GetOutput());
probe = new vtkProbeFilter();
probe.SetInputConnection((vtkAlgorithmOutput)appendF.GetOutputPort());
probe.SetSource((vtkDataObject)pl3d.GetOutput());
contour = new vtkContourFilter();
contour.SetInputConnection((vtkAlgorithmOutput)probe.GetOutputPort());
contour.GenerateValues((int)50,(double)((vtkDataSet)pl3d.GetOutput()).GetScalarRange()[0],
(double)((vtkDataSet)pl3d.GetOutput()).GetScalarRange()[1]);
contourMapper = vtkPolyDataMapper.New();
contourMapper.SetInputConnection((vtkAlgorithmOutput)contour.GetOutputPort());
contourMapper.SetScalarRange((double)((vtkDataSet)pl3d.GetOutput()).GetScalarRange()[0],
(double)((vtkDataSet)pl3d.GetOutput()).GetScalarRange()[1]);
planeActor = new vtkActor();
planeActor.SetMapper((vtkMapper)contourMapper);
outline = new vtkStructuredGridOutlineFilter();
outline.SetInputConnection((vtkAlgorithmOutput)pl3d.GetOutputPort());
outlineMapper = vtkPolyDataMapper.New();
outlineMapper.SetInputConnection((vtkAlgorithmOutput)outline.GetOutputPort());
outlineActor = new vtkActor();
outlineActor.SetMapper((vtkMapper)outlineMapper);
outlineActor.GetProperty().SetColor((double)0,(double)0,(double)0);
ren1.AddActor((vtkProp)outlineActor);
ren1.AddActor((vtkProp)planeActor);
ren1.AddActor((vtkProp)tpd1Actor);
ren1.AddActor((vtkProp)tpd2Actor);
ren1.AddActor((vtkProp)tpd3Actor);
ren1.SetBackground((double)1,(double)1,(double)1);
renWin.SetSize((int)400,(int)400);
cam1 = ren1.GetActiveCamera();
cam1.SetClippingRange((double)3.95297,(double)50);
cam1.SetFocalPoint((double)8.88908,(double)0.595038,(double)29.3342);
cam1.SetPosition((double)-12.3332,(double)31.7479,(double)41.2387);
cam1.SetViewUp((double)0.060772,(double)-0.319905,(double)0.945498);
iren.Initialize();
// prevent the tk window from showing up then start the event loop[]
//deleteAllVTKObjects();
}
///<summary> A Set Method for Static Variables </summary>
public static void SetoutTpd3(vtkOutlineFilter toSet)
{
outTpd3 = toSet;
}
private void MarchingSquares()
{
// Path to vtk data must be set as an environment variable
// VTK_DATA_ROOT = "C:\VTK\vtkdata-5.8.0"
vtkTesting test = vtkTesting.New();
string root = test.GetDataRoot();
vtkVolume16Reader v16 = vtkVolume16Reader.New();
v16.SetDataDimensions(64, 64);
v16.GetOutput().SetOrigin(0.0, 0.0, 0.0);
v16.SetDataByteOrderToLittleEndian();
v16.SetFilePrefix(System.IO.Path.Combine(root, @"Data\headsq\quarter"));
v16.SetImageRange(1, 93);
v16.SetDataSpacing(3.2, 3.2, 1.5);
v16.Update();
vtkMergePoints myLocator = vtkMergePoints.New();
vtkMarchingSquares isoXY = vtkMarchingSquares.New();
#if VTK_MAJOR_VERSION_5
isoXY.SetInputConnection(v16.GetOutputPort());
#else
isoXY.SetInputData(v16);
#endif
isoXY.GenerateValues(2, 600, 1200);
isoXY.SetImageRange(0, 32, 32, 63, 45, 45);
isoXY.SetLocator(myLocator);
vtkPolyDataMapper isoXYMapper = vtkPolyDataMapper.New();
#if VTK_MAJOR_VERSION_5
isoXYMapper.SetInputConnection(isoXY.GetOutputPort());
#else
isoXYMapper.SetInputData(isoXY);
#endif
isoXYMapper.SetScalarRange(600, 1200);
vtkActor isoXYActor = vtkActor.New();
isoXYActor.SetMapper(isoXYMapper);
vtkMarchingSquares isoYZ = vtkMarchingSquares.New();
#if VTK_MAJOR_VERSION_5
isoYZ.SetInputConnection(v16.GetOutputPort());
#else
isoYZ.SetInputData(v16);
#endif
isoYZ.GenerateValues(2, 600, 1200);
isoYZ.SetImageRange(32, 32, 32, 63, 46, 92);
vtkPolyDataMapper isoYZMapper = vtkPolyDataMapper.New();
#if VTK_MAJOR_VERSION_5
isoYZMapper.SetInputConnection(isoYZ.GetOutputPort());
#else
isoYZMapper.SetInputData(isoYZ);
#endif
isoYZMapper.SetScalarRange(600, 1200);
vtkActor isoYZActor = vtkActor.New();
isoYZActor.SetMapper(isoYZMapper);
vtkMarchingSquares isoXZ = vtkMarchingSquares.New();
#if VTK_MAJOR_VERSION_5
isoXZ.SetInputConnection(v16.GetOutputPort());
#else
isoXZ.SetInputData(v16);
#endif
isoXZ.GenerateValues(2, 600, 1200);
isoXZ.SetImageRange(0, 32, 32, 32, 0, 46);
vtkPolyDataMapper isoXZMapper = vtkPolyDataMapper.New();
#if VTK_MAJOR_VERSION_5
isoXZMapper.SetInputConnection(isoXZ.GetOutputPort());
#else
isoXZMapper.SetInputData(isoXZ);
#endif
isoXZMapper.SetScalarRange(600, 1200);
vtkActor isoXZActor = vtkActor.New();
isoXZActor.SetMapper(isoXZMapper);
vtkOutlineFilter outline = vtkOutlineFilter.New();
#if VTK_MAJOR_VERSION_5
outline.SetInputConnection(v16.GetOutputPort());
#else
outline.SetInputData(v16);
#endif
vtkPolyDataMapper outlineMapper = vtkPolyDataMapper.New();
#if VTK_MAJOR_VERSION_5
outlineMapper.SetInputConnection(outline.GetOutputPort());
#else
outlineMapper.SetInputData(outline);
#endif
vtkActor outlineActor = vtkActor.New();
outlineActor.SetMapper(outlineMapper);
outlineActor.VisibilityOff();
// get a reference to the renderwindow of our renderWindowControl1
vtkRenderWindow renderWindow = renderWindowControl1.RenderWindow;
// renderer
vtkRenderer renderer = renderWindow.GetRenderers().GetFirstRenderer();
// set background color
renderer.SetBackground(1.0, 1.0, 1.0);
//Add the actors to the renderer, set the background and size
renderer.AddActor(outlineActor);
renderer.AddActor(isoXYActor);
renderer.AddActor(isoYZActor);
renderer.AddActor(isoXZActor);
renderer.GetActiveCamera().SetPosition(324.368, 284.266, -19.3293);
renderer.GetActiveCamera().SetFocalPoint(73.5683, 120.903, 70.7309);
renderer.GetActiveCamera().SetViewAngle(30);
renderer.GetActiveCamera().SetViewUp(-0.304692, -0.0563843, -0.950781);
}
///<summary> A Set Method for Static Variables </summary>
public static void Setbounds(vtkOutlineFilter toSet)
{
bounds = toSet;
}
/// <summary>
/// The main entry method called by the CSharp driver
/// </summary>
/// <param name="argv"></param>
public static void AVTenEllip(String [] argv)
{
//Prefix Content is: ""
// create tensor ellipsoids[]
// Create the RenderWindow, Renderer and interactive renderer[]
//[]
ren1 = vtkRenderer.New();
renWin = vtkRenderWindow.New();
renWin.SetMultiSamples(0);
renWin.AddRenderer((vtkRenderer)ren1);
iren = new vtkRenderWindowInteractor();
iren.SetRenderWindow((vtkRenderWindow)renWin);
//[]
// Create tensor ellipsoids[]
//[]
// generate tensors[]
ptLoad = new vtkPointLoad();
ptLoad.SetLoadValue((double)100.0);
ptLoad.SetSampleDimensions((int)6, (int)6, (int)6);
ptLoad.ComputeEffectiveStressOn();
ptLoad.SetModelBounds((double)-10, (double)10, (double)-10, (double)10, (double)-10, (double)10);
// extract plane of data[]
plane = new vtkImageDataGeometryFilter();
plane.SetInputConnection((vtkAlgorithmOutput)ptLoad.GetOutputPort());
plane.SetExtent((int)2, (int)2, (int)0, (int)99, (int)0, (int)99);
// Generate ellipsoids[]
sphere = new vtkSphereSource();
sphere.SetThetaResolution((int)8);
sphere.SetPhiResolution((int)8);
ellipsoids = new vtkTensorGlyph();
ellipsoids.SetInputConnection((vtkAlgorithmOutput)ptLoad.GetOutputPort());
ellipsoids.SetSourceConnection((vtkAlgorithmOutput)sphere.GetOutputPort());
ellipsoids.SetScaleFactor((double)10);
ellipsoids.ClampScalingOn();
ellipNormals = new vtkPolyDataNormals();
ellipNormals.SetInputConnection((vtkAlgorithmOutput)ellipsoids.GetOutputPort());
// Map contour[]
lut = new vtkLogLookupTable();
lut.SetHueRange((double).6667, (double)0.0);
ellipMapper = vtkPolyDataMapper.New();
ellipMapper.SetInputConnection((vtkAlgorithmOutput)ellipNormals.GetOutputPort());
ellipMapper.SetLookupTable((vtkScalarsToColors)lut);
plane.Update();
//force update for scalar range[]
ellipMapper.SetScalarRange((double)((vtkDataSet)plane.GetOutput()).GetScalarRange()[0], (double)((vtkDataSet)plane.GetOutput()).GetScalarRange()[1]);
ellipActor = new vtkActor();
ellipActor.SetMapper((vtkMapper)ellipMapper);
//[]
// Create outline around data[]
//[]
outline = new vtkOutlineFilter();
outline.SetInputConnection((vtkAlgorithmOutput)ptLoad.GetOutputPort());
outlineMapper = vtkPolyDataMapper.New();
outlineMapper.SetInputConnection((vtkAlgorithmOutput)outline.GetOutputPort());
outlineActor = new vtkActor();
outlineActor.SetMapper((vtkMapper)outlineMapper);
outlineActor.GetProperty().SetColor((double)0, (double)0, (double)0);
//[]
// Create cone indicating application of load[]
//[]
coneSrc = new vtkConeSource();
coneSrc.SetRadius((double).5);
coneSrc.SetHeight((double)2);
coneMap = vtkPolyDataMapper.New();
coneMap.SetInputConnection((vtkAlgorithmOutput)coneSrc.GetOutputPort());
coneActor = new vtkActor();
coneActor.SetMapper((vtkMapper)coneMap);
coneActor.SetPosition((double)0, (double)0, (double)11);
coneActor.RotateY((double)90);
coneActor.GetProperty().SetColor((double)1, (double)0, (double)0);
camera = new vtkCamera();
camera.SetFocalPoint((double)0.113766, (double)-1.13665, (double)-1.01919);
camera.SetPosition((double)-29.4886, (double)-63.1488, (double)26.5807);
camera.SetViewAngle((double)24.4617);
camera.SetViewUp((double)0.17138, (double)0.331163, (double)0.927879);
camera.SetClippingRange((double)1, (double)100);
ren1.AddActor((vtkProp)ellipActor);
ren1.AddActor((vtkProp)outlineActor);
ren1.AddActor((vtkProp)coneActor);
ren1.SetBackground((double)1.0, (double)1.0, (double)1.0);
ren1.SetActiveCamera((vtkCamera)camera);
renWin.SetSize((int)400, (int)400);
renWin.Render();
// prevent the tk window from showing up then start the event loop[]
//deleteAllVTKObjects();
}
/// <summary>
/// The main entry method called by the CSharp driver
/// </summary>
/// <param name="argv"></param>
public static void AVgaussian(String [] argv)
{
//Prefix Content is: ""
ren1 = vtkRenderer.New();
renWin = vtkRenderWindow.New();
renWin.AddRenderer((vtkRenderer)ren1);
renWin.SetSize((int)300,(int)300);
iren = new vtkRenderWindowInteractor();
iren.SetRenderWindow((vtkRenderWindow)renWin);
camera = new vtkCamera();
camera.ParallelProjectionOn();
camera.SetViewUp((double)0,(double)1,(double)0);
camera.SetFocalPoint((double)12,(double)10.5,(double)15);
camera.SetPosition((double)-70,(double)15,(double)34);
camera.ComputeViewPlaneNormal();
ren1.SetActiveCamera((vtkCamera)camera);
// Create the reader for the data[]
//vtkStructuredPointsReader reader[]
reader = new vtkGaussianCubeReader();
reader.SetFileName((string)"" + (VTK_DATA_ROOT.ToString()) + "/Data/m4_TotalDensity.cube");
reader.SetHBScale((double)1.1);
reader.SetBScale((double)10);
reader.Update();
range = reader.GetGridOutput().GetPointData().GetScalars().GetRange();
min = (double)(lindex(range,0));
max = (double)(lindex(range,1));
readerSS = new vtkImageShiftScale();
readerSS.SetInput((vtkDataObject)reader.GetGridOutput());
readerSS.SetShift((double)min*-1);
readerSS.SetScale((double)255/(max-min));
readerSS.SetOutputScalarTypeToUnsignedChar();
bounds = new vtkOutlineFilter();
bounds.SetInput((vtkDataObject)reader.GetGridOutput());
boundsMapper = vtkPolyDataMapper.New();
boundsMapper.SetInputConnection((vtkAlgorithmOutput)bounds.GetOutputPort());
boundsActor = new vtkActor();
boundsActor.SetMapper((vtkMapper)boundsMapper);
boundsActor.GetProperty().SetColor((double)0,(double)0,(double)0);
contour = new vtkContourFilter();
contour.SetInput((vtkDataObject)reader.GetGridOutput());
contour.GenerateValues((int)5,(double)0,(double).05);
contourMapper = vtkPolyDataMapper.New();
contourMapper.SetInputConnection((vtkAlgorithmOutput)contour.GetOutputPort());
contourMapper.SetScalarRange((double)0,(double).1);
((vtkLookupTable)contourMapper.GetLookupTable()).SetHueRange(0.32,0);
contourActor = new vtkActor();
contourActor.SetMapper((vtkMapper)contourMapper);
contourActor.GetProperty().SetOpacity((double).5);
// Create transfer mapping scalar value to opacity[]
opacityTransferFunction = new vtkPiecewiseFunction();
opacityTransferFunction.AddPoint((double)0,(double)0.01);
opacityTransferFunction.AddPoint((double)255,(double)0.35);
opacityTransferFunction.ClampingOn();
// Create transfer mapping scalar value to color[]
colorTransferFunction = new vtkColorTransferFunction();
colorTransferFunction.AddHSVPoint((double)0.0,(double)0.66,(double)1.0,(double)1.0);
colorTransferFunction.AddHSVPoint((double)50.0,(double)0.33,(double)1.0,(double)1.0);
colorTransferFunction.AddHSVPoint((double)100.0,(double)0.00,(double)1.0,(double)1.0);
// The property describes how the data will look[]
volumeProperty = new vtkVolumeProperty();
volumeProperty.SetColor((vtkColorTransferFunction)colorTransferFunction);
volumeProperty.SetScalarOpacity((vtkPiecewiseFunction)opacityTransferFunction);
volumeProperty.SetInterpolationTypeToLinear();
// The mapper / ray cast function know how to render the data[]
compositeFunction = new vtkVolumeRayCastCompositeFunction();
volumeMapper = new vtkVolumeRayCastMapper();
//vtkVolumeTextureMapper2D volumeMapper[]
volumeMapper.SetVolumeRayCastFunction((vtkVolumeRayCastFunction)compositeFunction);
volumeMapper.SetInputConnection((vtkAlgorithmOutput)readerSS.GetOutputPort());
// The volume holds the mapper and the property and[]
// can be used to position/orient the volume[]
volume = new vtkVolume();
volume.SetMapper((vtkAbstractVolumeMapper)volumeMapper);
volume.SetProperty((vtkVolumeProperty)volumeProperty);
ren1.AddVolume((vtkProp)volume);
//ren1 AddActor contourActor[]
ren1.AddActor((vtkProp)boundsActor);
//#####################################################################[]
Sphere = new vtkSphereSource();
Sphere.SetCenter((double)0,(double)0,(double)0);
Sphere.SetRadius((double)1);
Sphere.SetThetaResolution((int)16);
Sphere.SetStartTheta((double)0);
Sphere.SetEndTheta((double)360);
Sphere.SetPhiResolution((int)16);
Sphere.SetStartPhi((double)0);
Sphere.SetEndPhi((double)180);
Glyph = new vtkGlyph3D();
Glyph.SetInputConnection((vtkAlgorithmOutput)reader.GetOutputPort());
Glyph.SetOrient((int)1);
Glyph.SetColorMode((int)1);
//Glyph ScalingOn[]
Glyph.SetScaleMode((int)2);
Glyph.SetScaleFactor((double).6);
Glyph.SetSource((vtkPolyData)Sphere.GetOutput());
AtomsMapper = vtkPolyDataMapper.New();
AtomsMapper.SetInputConnection((vtkAlgorithmOutput)Glyph.GetOutputPort());
AtomsMapper.SetImmediateModeRendering((int)1);
AtomsMapper.UseLookupTableScalarRangeOff();
AtomsMapper.SetScalarVisibility((int)1);
AtomsMapper.SetScalarModeToDefault();
Atoms = new vtkActor();
Atoms.SetMapper((vtkMapper)AtomsMapper);
Atoms.GetProperty().SetRepresentationToSurface();
Atoms.GetProperty().SetInterpolationToGouraud();
Atoms.GetProperty().SetAmbient((double)0.15);
Atoms.GetProperty().SetDiffuse((double)0.85);
Atoms.GetProperty().SetSpecular((double)0.1);
Atoms.GetProperty().SetSpecularPower((double)100);
Atoms.GetProperty().SetSpecularColor((double)1,(double)1,(double)1);
Atoms.GetProperty().SetColor((double)1,(double)1,(double)1);
Tube = new vtkTubeFilter();
Tube.SetInputConnection((vtkAlgorithmOutput)reader.GetOutputPort());
Tube.SetNumberOfSides((int)16);
Tube.SetCapping((int)0);
Tube.SetRadius((double)0.2);
Tube.SetVaryRadius((int)0);
Tube.SetRadiusFactor((double)10);
BondsMapper = vtkPolyDataMapper.New();
BondsMapper.SetInputConnection((vtkAlgorithmOutput)Tube.GetOutputPort());
BondsMapper.SetImmediateModeRendering((int)1);
BondsMapper.UseLookupTableScalarRangeOff();
BondsMapper.SetScalarVisibility((int)1);
BondsMapper.SetScalarModeToDefault();
Bonds = new vtkActor();
Bonds.SetMapper((vtkMapper)BondsMapper);
Bonds.GetProperty().SetRepresentationToSurface();
Bonds.GetProperty().SetInterpolationToGouraud();
Bonds.GetProperty().SetAmbient((double)0.15);
Bonds.GetProperty().SetDiffuse((double)0.85);
Bonds.GetProperty().SetSpecular((double)0.1);
Bonds.GetProperty().SetSpecularPower((double)100);
Bonds.GetProperty().SetSpecularColor((double)1,(double)1,(double)1);
Bonds.GetProperty().SetColor((double)1,(double)1,(double)1);
ren1.AddActor((vtkProp)Bonds);
ren1.AddActor((vtkProp)Atoms);
//###################################################[]
ren1.SetBackground((double)1,(double)1,(double)1);
ren1.ResetCamera();
renWin.Render();
//method moved
renWin.AbortCheckEvt += new Kitware.VTK.vtkObject.vtkObjectEventHandler(TkCheckAbort_Command.Execute);
iren.Initialize();
//deleteAllVTKObjects();
}
/// <summary>
/// The main entry method called by the CSharp driver
/// </summary>
/// <param name="argv"></param>
public static void AVextractRectGrid(String [] argv)
{
//Prefix Content is: ""
// create pipeline - rectilinear grid[]
//[]
rgridReader = new vtkRectilinearGridReader();
rgridReader.SetFileName((string)"" + (VTK_DATA_ROOT.ToString()) + "/Data/RectGrid2.vtk");
outline = new vtkOutlineFilter();
outline.SetInputConnection((vtkAlgorithmOutput)rgridReader.GetOutputPort());
mapper = vtkPolyDataMapper.New();
mapper.SetInputConnection((vtkAlgorithmOutput)outline.GetOutputPort());
actor = new vtkActor();
actor.SetMapper((vtkMapper)mapper);
rgridReader.Update();
extract1 = new vtkExtractRectilinearGrid();
extract1.SetInputConnection((vtkAlgorithmOutput)rgridReader.GetOutputPort());
//extract1 SetVOI 0 46 0 32 0 10[]
extract1.SetVOI((int)23, (int)40, (int)16, (int)30, (int)9, (int)9);
extract1.SetSampleRate((int)2, (int)2, (int)1);
extract1.IncludeBoundaryOn();
extract1.Update();
surf1 = new vtkDataSetSurfaceFilter();
surf1.SetInputConnection((vtkAlgorithmOutput)extract1.GetOutputPort());
tris = new vtkTriangleFilter();
tris.SetInputConnection((vtkAlgorithmOutput)surf1.GetOutputPort());
mapper1 = vtkPolyDataMapper.New();
mapper1.SetInputConnection((vtkAlgorithmOutput)tris.GetOutputPort());
mapper1.SetScalarRange((double)((vtkDataSet)extract1.GetOutput()).GetScalarRange()[0], (double)((vtkDataSet)extract1.GetOutput()).GetScalarRange()[1]);
actor1 = new vtkActor();
actor1.SetMapper((vtkMapper)mapper1);
// write out a rect grid[]
// write to the temp directory if possible, otherwise use .[]
dir = ".";
dir = TclToCsScriptTestDriver.GetTempDirectory();
// make sure the directory is writeable first[]
try
{
channel = new StreamWriter("" + (dir.ToString()) + "/test.tmp");
tryCatchError = "NOERROR";
}
catch (Exception)
{ tryCatchError = "ERROR"; }
if (tryCatchError.Equals("NOERROR"))
{
channel.Close();
File.Delete("" + (dir.ToString()) + "/test.tmp");
rectWriter = new vtkRectilinearGridWriter();
rectWriter.SetInputConnection((vtkAlgorithmOutput)extract1.GetOutputPort());
rectWriter.SetFileName((string)"" + (dir.ToString()) + "/rect.tmp");
rectWriter.Write();
// delete the file[]
File.Delete("" + (dir.ToString()) + "/rect.tmp");
}
// Create the RenderWindow, Renderer and both Actors[]
//[]
ren1 = vtkRenderer.New();
renWin = vtkRenderWindow.New();
renWin.AddRenderer((vtkRenderer)ren1);
iren = new vtkRenderWindowInteractor();
iren.SetRenderWindow((vtkRenderWindow)renWin);
//ren1 AddActor actor[]
ren1.AddActor((vtkProp)actor1);
renWin.SetSize((int)340, (int)400);
iren.Initialize();
// render the image[]
//[]
// prevent the tk window from showing up then start the event loop[]
//deleteAllVTKObjects();
}
/// <summary>
/// An example that does not use a Windows Form
/// </summary>
/// <param name="argv"></param>
public static void Main(String[] argv)
{
// This example demonstrates the use of vtkCubeAxesActor2D to indicate the
// position in space that the camera is currently viewing.
// The vtkCubeAxesActor2D draws axes on the bounding box of the data set and
// labels the axes with x-y-z coordinates.
//
// First we include the VTK Tcl packages which will make available
// all of the vtk commands to Tcl
//
// Create a vtkBYUReader and read in a data set.
//
fohe = vtkBYUReader.New();
fohe.SetGeometryFileName("../../../teapot.g");
// Create a vtkPolyDataNormals filter to calculate the normals of the data set.
normals = vtkPolyDataNormals.New();
normals.SetInputConnection(fohe.GetOutputPort());
// Set up the associated mapper and actor.
foheMapper = vtkPolyDataMapper.New();
foheMapper.SetInputConnection(normals.GetOutputPort());
foheActor = vtkLODActor.New();
foheActor.SetMapper(foheMapper);
// Create a vtkOutlineFilter to draw the bounding box of the data set. Also
// create the associated mapper and actor.
outline = vtkOutlineFilter.New();
outline.SetInputConnection(normals.GetOutputPort());
mapOutline = vtkPolyDataMapper.New();
mapOutline.SetInputConnection(outline.GetOutputPort());
outlineActor = vtkActor.New();
outlineActor.SetMapper(mapOutline);
outlineActor.GetProperty().SetColor(0, 0, 0);
// Create a vtkCamera, and set the camera parameters.
camera = vtkCamera.New();
camera.SetClippingRange(1.60187, 20.0842);
camera.SetFocalPoint(0.21406, 1.5, 0);
camera.SetPosition(8.3761, 4.94858, 4.12505);
camera.SetViewUp(0.180325, 0.549245, -0.815974);
// Create a vtkLight, and set the light parameters.
light = vtkLight.New();
light.SetFocalPoint(0.21406, 1.5, 0);
light.SetPosition(8.3761, 4.94858, 4.12505);
// Create the Renderers. Assign them the appropriate viewport coordinates,
// active camera, and light.
ren1 = vtkRenderer.New();
ren1.SetViewport(0, 0, 0.5, 1.0);
ren1.SetActiveCamera(camera);
ren1.AddLight(light);
ren2 = vtkRenderer.New();
ren2.SetViewport(0.5, 0, 1.0, 1.0);
ren2.SetActiveCamera(camera);
ren2.AddLight(light);
// Create the RenderWindow and RenderWindowInteractor.
renWin = vtkRenderWindow.New();
renWin.AddRenderer(ren1);
renWin.AddRenderer(ren2);
renWin.SetWindowName("VTK - Cube Axes");
renWin.SetSize(600, 300);
iren = vtkRenderWindowInteractor.New();
iren.SetRenderWindow(renWin);
// Add the actors to the renderer, and set the background.
ren1.AddViewProp(foheActor);
ren1.AddViewProp(outlineActor);
ren2.AddViewProp(foheActor);
ren2.AddViewProp(outlineActor);
ren1.SetBackground(0.1, 0.2, 0.4);
ren2.SetBackground(0.1, 0.2, 0.4);
// Create a text property for both cube axes
tprop = vtkTextProperty.New();
tprop.SetColor(1, 1, 1);
tprop.ShadowOn();
// Create a vtkCubeAxesActor2D. Use the outer edges of the bounding box to
// draw the axes. Add the actor to the renderer.
axes = vtkCubeAxesActor2D.New();
axes.SetInput(normals.GetOutput());
axes.SetCamera(ren1.GetActiveCamera());
axes.SetLabelFormat("%6.4g");
axes.SetFlyModeToOuterEdges();
axes.SetFontFactor(0.8);
axes.SetAxisTitleTextProperty(tprop);
axes.SetAxisLabelTextProperty(tprop);
ren1.AddViewProp(axes);
// Create a vtkCubeAxesActor2D. Use the closest vertex to the camera to
// determine where to draw the axes. Add the actor to the renderer.
axes2 = vtkCubeAxesActor2D.New();
axes2.SetViewProp(foheActor);
axes2.SetCamera(ren2.GetActiveCamera());
axes2.SetLabelFormat("%6.4g");
axes2.SetFlyModeToClosestTriad();
axes2.SetFontFactor(0.8);
axes2.ScalingOff();
axes2.SetAxisTitleTextProperty(tprop);
axes2.SetAxisLabelTextProperty(tprop);
ren2.AddViewProp(axes2);
// Render
renWin.Render();
// Set the user method (bound to key 'u')
iren.Initialize();
iren.Start();
// Set up a check for aborting rendering.
renWin.AbortCheckEvt += new vtkObject.vtkObjectEventHandler(TkCheckAbort);
//Clean Up
deleteAllVTKObjects();
}
/// <summary>
/// The main entry method called by the CSharp driver
/// </summary>
/// <param name="argv"></param>
public static void AVgaussian(String [] argv)
{
//Prefix Content is: ""
ren1 = vtkRenderer.New();
renWin = vtkRenderWindow.New();
renWin.SetMultiSamples(0);
renWin.AddRenderer((vtkRenderer)ren1);
renWin.SetSize((int)300, (int)300);
iren = new vtkRenderWindowInteractor();
iren.SetRenderWindow((vtkRenderWindow)renWin);
camera = new vtkCamera();
camera.ParallelProjectionOn();
camera.SetViewUp((double)0, (double)1, (double)0);
camera.SetFocalPoint((double)12, (double)10.5, (double)15);
camera.SetPosition((double)-70, (double)15, (double)34);
camera.ComputeViewPlaneNormal();
ren1.SetActiveCamera((vtkCamera)camera);
// Create the reader for the data[]
//vtkStructuredPointsReader reader[]
reader = new vtkGaussianCubeReader();
reader.SetFileName((string)"" + (VTK_DATA_ROOT.ToString()) + "/Data/m4_TotalDensity.cube");
reader.SetHBScale((double)1.1);
reader.SetBScale((double)10);
reader.Update();
range = reader.GetGridOutput().GetPointData().GetScalars().GetRange();
min = (double)(lindex(range, 0));
max = (double)(lindex(range, 1));
readerSS = new vtkImageShiftScale();
readerSS.SetInputData((vtkDataObject)reader.GetGridOutput());
readerSS.SetShift((double)min * -1);
readerSS.SetScale((double)255 / (max - min));
readerSS.SetOutputScalarTypeToUnsignedChar();
bounds = new vtkOutlineFilter();
bounds.SetInputData((vtkDataObject)reader.GetGridOutput());
boundsMapper = vtkPolyDataMapper.New();
boundsMapper.SetInputConnection((vtkAlgorithmOutput)bounds.GetOutputPort());
boundsActor = new vtkActor();
boundsActor.SetMapper((vtkMapper)boundsMapper);
boundsActor.GetProperty().SetColor((double)0, (double)0, (double)0);
contour = new vtkContourFilter();
contour.SetInputData((vtkDataObject)reader.GetGridOutput());
contour.GenerateValues((int)5, (double)0, (double).05);
contourMapper = vtkPolyDataMapper.New();
contourMapper.SetInputConnection((vtkAlgorithmOutput)contour.GetOutputPort());
contourMapper.SetScalarRange((double)0, (double).1);
((vtkLookupTable)contourMapper.GetLookupTable()).SetHueRange(0.32, 0);
contourActor = new vtkActor();
contourActor.SetMapper((vtkMapper)contourMapper);
contourActor.GetProperty().SetOpacity((double).5);
// Create transfer mapping scalar value to opacity[]
opacityTransferFunction = new vtkPiecewiseFunction();
opacityTransferFunction.AddPoint((double)0, (double)0.01);
opacityTransferFunction.AddPoint((double)255, (double)0.35);
opacityTransferFunction.ClampingOn();
// Create transfer mapping scalar value to color[]
colorTransferFunction = new vtkColorTransferFunction();
colorTransferFunction.AddHSVPoint((double)0.0, (double)0.66, (double)1.0, (double)1.0);
colorTransferFunction.AddHSVPoint((double)50.0, (double)0.33, (double)1.0, (double)1.0);
colorTransferFunction.AddHSVPoint((double)100.0, (double)0.00, (double)1.0, (double)1.0);
// The property describes how the data will look[]
volumeProperty = new vtkVolumeProperty();
volumeProperty.SetColor((vtkColorTransferFunction)colorTransferFunction);
volumeProperty.SetScalarOpacity((vtkPiecewiseFunction)opacityTransferFunction);
volumeProperty.SetInterpolationTypeToLinear();
// The mapper / ray cast function know how to render the data[]
compositeFunction = new vtkVolumeRayCastCompositeFunction();
volumeMapper = new vtkVolumeRayCastMapper();
//vtkVolumeTextureMapper2D volumeMapper[]
volumeMapper.SetVolumeRayCastFunction((vtkVolumeRayCastFunction)compositeFunction);
volumeMapper.SetInputConnection((vtkAlgorithmOutput)readerSS.GetOutputPort());
// The volume holds the mapper and the property and[]
// can be used to position/orient the volume[]
volume = new vtkVolume();
volume.SetMapper((vtkAbstractVolumeMapper)volumeMapper);
volume.SetProperty((vtkVolumeProperty)volumeProperty);
ren1.AddVolume((vtkProp)volume);
//ren1 AddActor contourActor[]
ren1.AddActor((vtkProp)boundsActor);
//#####################################################################[]
Sphere = new vtkSphereSource();
Sphere.SetCenter((double)0, (double)0, (double)0);
Sphere.SetRadius((double)1);
Sphere.SetThetaResolution((int)16);
Sphere.SetStartTheta((double)0);
Sphere.SetEndTheta((double)360);
Sphere.SetPhiResolution((int)16);
Sphere.SetStartPhi((double)0);
Sphere.SetEndPhi((double)180);
Glyph = new vtkGlyph3D();
Glyph.SetInputConnection((vtkAlgorithmOutput)reader.GetOutputPort());
Glyph.SetOrient((int)1);
Glyph.SetColorMode((int)1);
//Glyph ScalingOn[]
Glyph.SetScaleMode((int)2);
Glyph.SetScaleFactor((double).6);
Glyph.SetSourceConnection(Sphere.GetOutputPort());
AtomsMapper = vtkPolyDataMapper.New();
AtomsMapper.SetInputConnection((vtkAlgorithmOutput)Glyph.GetOutputPort());
AtomsMapper.SetImmediateModeRendering((int)1);
AtomsMapper.UseLookupTableScalarRangeOff();
AtomsMapper.SetScalarVisibility((int)1);
AtomsMapper.SetScalarModeToDefault();
Atoms = new vtkActor();
Atoms.SetMapper((vtkMapper)AtomsMapper);
Atoms.GetProperty().SetRepresentationToSurface();
Atoms.GetProperty().SetInterpolationToGouraud();
Atoms.GetProperty().SetAmbient((double)0.15);
Atoms.GetProperty().SetDiffuse((double)0.85);
Atoms.GetProperty().SetSpecular((double)0.1);
Atoms.GetProperty().SetSpecularPower((double)100);
Atoms.GetProperty().SetSpecularColor((double)1, (double)1, (double)1);
Atoms.GetProperty().SetColor((double)1, (double)1, (double)1);
Tube = new vtkTubeFilter();
Tube.SetInputConnection((vtkAlgorithmOutput)reader.GetOutputPort());
Tube.SetNumberOfSides((int)16);
Tube.SetCapping((int)0);
Tube.SetRadius((double)0.2);
Tube.SetVaryRadius((int)0);
Tube.SetRadiusFactor((double)10);
BondsMapper = vtkPolyDataMapper.New();
BondsMapper.SetInputConnection((vtkAlgorithmOutput)Tube.GetOutputPort());
BondsMapper.SetImmediateModeRendering((int)1);
BondsMapper.UseLookupTableScalarRangeOff();
BondsMapper.SetScalarVisibility((int)1);
BondsMapper.SetScalarModeToDefault();
Bonds = new vtkActor();
Bonds.SetMapper((vtkMapper)BondsMapper);
Bonds.GetProperty().SetRepresentationToSurface();
Bonds.GetProperty().SetInterpolationToGouraud();
Bonds.GetProperty().SetAmbient((double)0.15);
Bonds.GetProperty().SetDiffuse((double)0.85);
Bonds.GetProperty().SetSpecular((double)0.1);
Bonds.GetProperty().SetSpecularPower((double)100);
Bonds.GetProperty().SetSpecularColor((double)1, (double)1, (double)1);
Bonds.GetProperty().SetColor((double)1, (double)1, (double)1);
ren1.AddActor((vtkProp)Bonds);
ren1.AddActor((vtkProp)Atoms);
//###################################################[]
ren1.SetBackground((double)1, (double)1, (double)1);
ren1.ResetCamera();
renWin.Render();
//method moved
renWin.AbortCheckEvt += new Kitware.VTK.vtkObject.vtkObjectEventHandler(TkCheckAbort_Command.Execute);
iren.Initialize();
//deleteAllVTKObjects();
}
///<summary> A Set Method for Static Variables </summary>
public static void Setbounds(vtkOutlineFilter toSet)
{
bounds = toSet;
}
/// <summary>
/// The main entry method called by the CSharp driver
/// </summary>
/// <param name="argv"></param>
public static void AVExtractTensors(String [] argv)
{
//Prefix Content is: ""
// create tensor ellipsoids[]
// Create the RenderWindow, Renderer and interactive renderer[]
//[]
ren1 = vtkRenderer.New();
renWin = vtkRenderWindow.New();
renWin.AddRenderer((vtkRenderer)ren1);
iren = new vtkRenderWindowInteractor();
iren.SetRenderWindow((vtkRenderWindow)renWin);
ptLoad = new vtkPointLoad();
ptLoad.SetLoadValue((double)100.0);
ptLoad.SetSampleDimensions((int)30, (int)30, (int)30);
ptLoad.ComputeEffectiveStressOn();
ptLoad.SetModelBounds((double)-10, (double)10, (double)-10, (double)10, (double)-10, (double)10);
extractTensor = new vtkExtractTensorComponents();
extractTensor.SetInputConnection((vtkAlgorithmOutput)ptLoad.GetOutputPort());
extractTensor.ScalarIsEffectiveStress();
extractTensor.ScalarIsComponent();
extractTensor.ExtractScalarsOn();
extractTensor.ExtractVectorsOn();
extractTensor.ExtractNormalsOff();
extractTensor.ExtractTCoordsOn();
contour = new vtkContourFilter();
contour.SetInputConnection((vtkAlgorithmOutput)extractTensor.GetOutputPort());
contour.SetValue((int)0, (double)0);
probe = new vtkProbeFilter();
probe.SetInputConnection((vtkAlgorithmOutput)contour.GetOutputPort());
probe.SetSourceConnection(ptLoad.GetOutputPort());
su = new vtkLoopSubdivisionFilter();
su.SetInputConnection((vtkAlgorithmOutput)probe.GetOutputPort());
su.SetNumberOfSubdivisions((int)1);
s1Mapper = vtkPolyDataMapper.New();
s1Mapper.SetInputConnection((vtkAlgorithmOutput)probe.GetOutputPort());
// s1Mapper SetInputConnection [su GetOutputPort][]
s1Actor = new vtkActor();
s1Actor.SetMapper((vtkMapper)s1Mapper);
//[]
// plane for context[]
//[]
g = new vtkImageDataGeometryFilter();
g.SetInputConnection((vtkAlgorithmOutput)ptLoad.GetOutputPort());
g.SetExtent((int)0, (int)100, (int)0, (int)100, (int)0, (int)0);
g.Update();
//for scalar range[]
gm = vtkPolyDataMapper.New();
gm.SetInputConnection((vtkAlgorithmOutput)g.GetOutputPort());
gm.SetScalarRange((double)((vtkDataSet)g.GetOutput()).GetScalarRange()[0], (double)((vtkDataSet)g.GetOutput()).GetScalarRange()[1]);
ga = new vtkActor();
ga.SetMapper((vtkMapper)gm);
s1Mapper.SetScalarRange((double)((vtkDataSet)g.GetOutput()).GetScalarRange()[0], (double)((vtkDataSet)g.GetOutput()).GetScalarRange()[1]);
//[]
// Create outline around data[]
//[]
outline = new vtkOutlineFilter();
outline.SetInputConnection((vtkAlgorithmOutput)ptLoad.GetOutputPort());
outlineMapper = vtkPolyDataMapper.New();
outlineMapper.SetInputConnection((vtkAlgorithmOutput)outline.GetOutputPort());
outlineActor = new vtkActor();
outlineActor.SetMapper((vtkMapper)outlineMapper);
outlineActor.GetProperty().SetColor((double)0, (double)0, (double)0);
//[]
// Create cone indicating application of load[]
//[]
coneSrc = new vtkConeSource();
coneSrc.SetRadius((double).5);
coneSrc.SetHeight((double)2);
coneMap = vtkPolyDataMapper.New();
coneMap.SetInputConnection((vtkAlgorithmOutput)coneSrc.GetOutputPort());
coneActor = new vtkActor();
coneActor.SetMapper((vtkMapper)coneMap);
coneActor.SetPosition((double)0, (double)0, (double)11);
coneActor.RotateY((double)90);
coneActor.GetProperty().SetColor((double)1, (double)0, (double)0);
camera = new vtkCamera();
camera.SetFocalPoint((double)0.113766, (double)-1.13665, (double)-1.01919);
camera.SetPosition((double)-29.4886, (double)-63.1488, (double)26.5807);
camera.SetViewAngle((double)24.4617);
camera.SetViewUp((double)0.17138, (double)0.331163, (double)0.927879);
camera.SetClippingRange((double)1, (double)100);
ren1.AddActor((vtkProp)s1Actor);
ren1.AddActor((vtkProp)outlineActor);
ren1.AddActor((vtkProp)coneActor);
ren1.AddActor((vtkProp)ga);
ren1.SetBackground((double)1.0, (double)1.0, (double)1.0);
ren1.SetActiveCamera((vtkCamera)camera);
renWin.SetSize((int)300, (int)300);
renWin.Render();
// prevent the tk window from showing up then start the event loop[]
//deleteAllVTKObjects();
}
/// <summary>
/// The main entry method called by the CSharp driver
/// </summary>
/// <param name="argv"></param>
public static void AVcursor3D(String [] argv)
{
//Prefix Content is: ""
// This little example shows how a cursor can be created in []
// image viewers, and renderers. The standard TkImageViewerWidget and[]
// TkRenderWidget bindings are used. There is a new binding:[]
// middle button in the image viewer sets the position of the cursor. []
// First we include the VTK Tcl packages which will make available []
// all of the vtk commands to Tcl[]
// Global values[]
CURSOR_X = 20;
CURSOR_Y = 20;
CURSOR_Z = 20;
IMAGE_MAG_X = 4;
IMAGE_MAG_Y = 4;
IMAGE_MAG_Z = 1;
// Pipeline stuff[]
reader = new vtkSLCReader();
reader.SetFileName((string)"" + (VTK_DATA_ROOT.ToString()) + "/Data/neghip.slc");
// Cursor stuff[]
magnify = new vtkImageMagnify();
magnify.SetInputConnection((vtkAlgorithmOutput)reader.GetOutputPort());
magnify.SetMagnificationFactors((int)IMAGE_MAG_X,(int)IMAGE_MAG_Y,(int)IMAGE_MAG_Z);
image_cursor = new vtkImageCursor3D();
image_cursor.SetInputConnection((vtkAlgorithmOutput)magnify.GetOutputPort());
image_cursor.SetCursorPosition((double)CURSOR_X*IMAGE_MAG_X,(double)CURSOR_Y*IMAGE_MAG_Y,(double)CURSOR_Z*IMAGE_MAG_Z);
image_cursor.SetCursorValue((double)255);
image_cursor.SetCursorRadius((int)50*IMAGE_MAG_X);
axes = new vtkAxes();
axes.SymmetricOn();
axes.SetOrigin((double)CURSOR_X,(double)CURSOR_Y,(double)CURSOR_Z);
axes.SetScaleFactor((double)50.0);
axes_mapper = vtkPolyDataMapper.New();
axes_mapper.SetInputConnection((vtkAlgorithmOutput)axes.GetOutputPort());
axesActor = new vtkActor();
axesActor.SetMapper((vtkMapper)axes_mapper);
axesActor.GetProperty().SetAmbient((double)0.5);
// Image viewer stuff[]
viewer = new vtkImageViewer();
viewer.SetInputConnection((vtkAlgorithmOutput)image_cursor.GetOutputPort());
viewer.SetZSlice((int)CURSOR_Z*IMAGE_MAG_Z);
viewer.SetColorWindow((double)256);
viewer.SetColorLevel((double)128);
//method moved
//method moved
//method moved
// Create transfer functions for opacity and color[]
opacity_transfer_function = new vtkPiecewiseFunction();
opacity_transfer_function.AddPoint((double)20,(double)0.0);
opacity_transfer_function.AddPoint((double)255,(double)0.2);
color_transfer_function = new vtkColorTransferFunction();
color_transfer_function.AddRGBPoint((double)0,(double)0,(double)0,(double)0);
color_transfer_function.AddRGBPoint((double)64,(double)1,(double)0,(double)0);
color_transfer_function.AddRGBPoint((double)128,(double)0,(double)0,(double)1);
color_transfer_function.AddRGBPoint((double)192,(double)0,(double)1,(double)0);
color_transfer_function.AddRGBPoint((double)255,(double)0,(double).2,(double)0);
// Create properties, mappers, volume actors, and ray cast function[]
volume_property = new vtkVolumeProperty();
volume_property.SetColor((vtkColorTransferFunction)color_transfer_function);
volume_property.SetScalarOpacity((vtkPiecewiseFunction)opacity_transfer_function);
composite_function = new vtkVolumeRayCastCompositeFunction();
volume_mapper = new vtkVolumeRayCastMapper();
volume_mapper.SetInputConnection((vtkAlgorithmOutput)reader.GetOutputPort());
volume_mapper.SetVolumeRayCastFunction((vtkVolumeRayCastFunction)composite_function);
volume = new vtkVolume();
volume.SetMapper((vtkAbstractVolumeMapper)volume_mapper);
volume.SetProperty((vtkVolumeProperty)volume_property);
// Create outline[]
outline = new vtkOutlineFilter();
outline.SetInputConnection((vtkAlgorithmOutput)reader.GetOutputPort());
outline_mapper = vtkPolyDataMapper.New();
outline_mapper.SetInputConnection((vtkAlgorithmOutput)outline.GetOutputPort());
outlineActor = new vtkActor();
outlineActor.SetMapper((vtkMapper)outline_mapper);
outlineActor.GetProperty().SetColor((double)1,(double)1,(double)1);
// Create the renderer[]
ren1 = vtkRenderer.New();
ren1.AddActor((vtkProp)axesActor);
ren1.AddVolume((vtkProp)volume);
ren1.SetBackground((double)0.1,(double)0.2,(double)0.4);
renWin2 = vtkRenderWindow.New();
renWin2.AddRenderer((vtkRenderer)ren1);
renWin2.SetSize((int)256,(int)256);
// Create the GUI: two renderer widgets and a quit button[]
//tk window skipped..
// Set the window manager (wm command) so that it registers a[]
// command to handle the WM_DELETE_WINDOW protocal request. This[]
// request is triggered when the widget is closed using the standard[]
// window manager icons or buttons. In this case the exit callback[]
// will be called and it will free up any objects we created then exit[]
// the application.[]
// Help label, frame and quit button[]
//tk window skipped..
//tk window skipped..
//tk window skipped..
//deleteAllVTKObjects();
}
/// <summary>
/// The main entry method called by the CSharp driver
/// </summary>
/// <param name="argv"></param>
public static void AVHyper(String [] argv)
{
//Prefix Content is: ""
// Create the RenderWindow, Renderer and interactive renderer[]
//[]
ren1 = vtkRenderer.New();
renWin = vtkRenderWindow.New();
renWin.AddRenderer((vtkRenderer)ren1);
iren = new vtkRenderWindowInteractor();
iren.SetRenderWindow((vtkRenderWindow)renWin);
VTK_INTEGRATE_BOTH_DIRECTIONS = 2;
//[]
// generate tensors[]
ptLoad = new vtkPointLoad();
ptLoad.SetLoadValue((double)100.0);
ptLoad.SetSampleDimensions((int)20,(int)20,(int)20);
ptLoad.ComputeEffectiveStressOn();
ptLoad.SetModelBounds((double)-10,(double)10,(double)-10,(double)10,(double)-10,(double)10);
//[]
// If the current directory is writable, then test the witers[]
//[]
try
{
channel = new StreamWriter("test.tmp");
tryCatchError = "NOERROR";
}
catch(Exception)
{tryCatchError = "ERROR";}
if(tryCatchError.Equals("NOERROR"))
{
channel.Close();
File.Delete("test.tmp");
wSP = new vtkDataSetWriter();
wSP.SetInputConnection((vtkAlgorithmOutput)ptLoad.GetOutputPort());
wSP.SetFileName((string)"wSP.vtk");
wSP.SetTensorsName((string)"pointload");
wSP.SetScalarsName((string)"effective_stress");
wSP.Write();
rSP = new vtkDataSetReader();
rSP.SetFileName((string)"wSP.vtk");
rSP.SetTensorsName((string)"pointload");
rSP.SetScalarsName((string)"effective_stress");
rSP.Update();
input = rSP.GetOutput();
File.Delete("wSP.vtk");
}
else
{
input = ptLoad.GetOutput();
}
// Generate hyperstreamlines[]
s1 = new vtkHyperStreamline();
s1.SetInputData((vtkDataObject)input);
s1.SetStartPosition((double)9,(double)9,(double)-9);
s1.IntegrateMinorEigenvector();
s1.SetMaximumPropagationDistance((double)18.0);
s1.SetIntegrationStepLength((double)0.1);
s1.SetStepLength((double)0.01);
s1.SetRadius((double)0.25);
s1.SetNumberOfSides((int)18);
s1.SetIntegrationDirection((int)VTK_INTEGRATE_BOTH_DIRECTIONS);
s1.Update();
// Map hyperstreamlines[]
lut = new vtkLogLookupTable();
lut.SetHueRange((double).6667,(double)0.0);
s1Mapper = vtkPolyDataMapper.New();
s1Mapper.SetInputConnection((vtkAlgorithmOutput)s1.GetOutputPort());
s1Mapper.SetLookupTable((vtkScalarsToColors)lut);
ptLoad.Update();
//force update for scalar range[]
s1Mapper.SetScalarRange((double)((vtkDataSet)ptLoad.GetOutput()).GetScalarRange()[0],(double)((vtkDataSet)ptLoad.GetOutput()).GetScalarRange()[1]);
s1Actor = new vtkActor();
s1Actor.SetMapper((vtkMapper)s1Mapper);
s2 = new vtkHyperStreamline();
s2.SetInputData((vtkDataObject)input);
s2.SetStartPosition((double)-9,(double)-9,(double)-9);
s2.IntegrateMinorEigenvector();
s2.SetMaximumPropagationDistance((double)18.0);
s2.SetIntegrationStepLength((double)0.1);
s2.SetStepLength((double)0.01);
s2.SetRadius((double)0.25);
s2.SetNumberOfSides((int)18);
s2.SetIntegrationDirection((int)VTK_INTEGRATE_BOTH_DIRECTIONS);
s2.Update();
s2Mapper = vtkPolyDataMapper.New();
s2Mapper.SetInputConnection((vtkAlgorithmOutput)s2.GetOutputPort());
s2Mapper.SetLookupTable((vtkScalarsToColors)lut);
s2Mapper.SetScalarRange((double)((vtkDataSet)input).GetScalarRange()[0],(double)((vtkDataSet)input).GetScalarRange()[1]);
s2Actor = new vtkActor();
s2Actor.SetMapper((vtkMapper)s2Mapper);
s3 = new vtkHyperStreamline();
s3.SetInputData((vtkDataObject)input);
s3.SetStartPosition((double)9,(double)-9,(double)-9);
s3.IntegrateMinorEigenvector();
s3.SetMaximumPropagationDistance((double)18.0);
s3.SetIntegrationStepLength((double)0.1);
s3.SetStepLength((double)0.01);
s3.SetRadius((double)0.25);
s3.SetNumberOfSides((int)18);
s3.SetIntegrationDirection((int)VTK_INTEGRATE_BOTH_DIRECTIONS);
s3.Update();
s3Mapper = vtkPolyDataMapper.New();
s3Mapper.SetInputConnection((vtkAlgorithmOutput)s3.GetOutputPort());
s3Mapper.SetLookupTable((vtkScalarsToColors)lut);
s3Mapper.SetScalarRange((double)((vtkDataSet)input).GetScalarRange()[0],
(double)((vtkDataSet)input).GetScalarRange()[1]);
s3Actor = new vtkActor();
s3Actor.SetMapper((vtkMapper)s3Mapper);
s4 = new vtkHyperStreamline();
s4.SetInputData((vtkDataObject)input);
s4.SetStartPosition((double)-9,(double)9,(double)-9);
s4.IntegrateMinorEigenvector();
s4.SetMaximumPropagationDistance((double)18.0);
s4.SetIntegrationStepLength((double)0.1);
s4.SetStepLength((double)0.01);
s4.SetRadius((double)0.25);
s4.SetNumberOfSides((int)18);
s4.SetIntegrationDirection((int)VTK_INTEGRATE_BOTH_DIRECTIONS);
s4.Update();
s4Mapper = vtkPolyDataMapper.New();
s4Mapper.SetInputConnection((vtkAlgorithmOutput)s4.GetOutputPort());
s4Mapper.SetLookupTable((vtkScalarsToColors)lut);
s4Mapper.SetScalarRange((double)((vtkDataSet)input).GetScalarRange()[0],(double)((vtkDataSet)input).GetScalarRange()[1]);
s4Actor = new vtkActor();
s4Actor.SetMapper((vtkMapper)s4Mapper);
// plane for context[]
//[]
g = new vtkImageDataGeometryFilter();
g.SetInputData((vtkDataObject)input);
g.SetExtent((int)0,(int)100,(int)0,(int)100,(int)0,(int)0);
g.Update();
//for scalar range[]
gm = vtkPolyDataMapper.New();
gm.SetInputConnection((vtkAlgorithmOutput)g.GetOutputPort());
gm.SetScalarRange((double)((vtkDataSet)g.GetOutput()).GetScalarRange()[0],(double)((vtkDataSet)g.GetOutput()).GetScalarRange()[1]);
ga = new vtkActor();
ga.SetMapper((vtkMapper)gm);
// Create outline around data[]
//[]
outline = new vtkOutlineFilter();
outline.SetInputData((vtkDataObject)input);
outlineMapper = vtkPolyDataMapper.New();
outlineMapper.SetInputConnection((vtkAlgorithmOutput)outline.GetOutputPort());
outlineActor = new vtkActor();
outlineActor.SetMapper((vtkMapper)outlineMapper);
outlineActor.GetProperty().SetColor((double)0,(double)0,(double)0);
// Create cone indicating application of load[]
//[]
coneSrc = new vtkConeSource();
coneSrc.SetRadius((double).5);
coneSrc.SetHeight((double)2);
coneMap = vtkPolyDataMapper.New();
coneMap.SetInputConnection((vtkAlgorithmOutput)coneSrc.GetOutputPort());
coneActor = new vtkActor();
coneActor.SetMapper((vtkMapper)coneMap);
coneActor.SetPosition((double)0,(double)0,(double)11);
coneActor.RotateY((double)90);
coneActor.GetProperty().SetColor((double)1,(double)0,(double)0);
camera = new vtkCamera();
camera.SetFocalPoint((double)0.113766,(double)-1.13665,(double)-1.01919);
camera.SetPosition((double)-29.4886,(double)-63.1488,(double)26.5807);
camera.SetViewAngle((double)24.4617);
camera.SetViewUp((double)0.17138,(double)0.331163,(double)0.927879);
camera.SetClippingRange((double)1,(double)100);
ren1.AddActor((vtkProp)s1Actor);
ren1.AddActor((vtkProp)s2Actor);
ren1.AddActor((vtkProp)s3Actor);
ren1.AddActor((vtkProp)s4Actor);
ren1.AddActor((vtkProp)outlineActor);
ren1.AddActor((vtkProp)coneActor);
ren1.AddActor((vtkProp)ga);
ren1.SetBackground((double)1.0,(double)1.0,(double)1.0);
ren1.SetActiveCamera((vtkCamera)camera);
renWin.SetSize((int)300,(int)300);
renWin.Render();
// prevent the tk window from showing up then start the event loop[]
//deleteAllVTKObjects();
}
/// <summary>
/// The main entry method called by the CSharp driver
/// </summary>
/// <param name="argv"></param>
public static void AVEnSightRectGridASCII(String [] argv)
{
//Prefix Content is: ""
VTK_VARY_RADIUS_BY_VECTOR = 2;
// create pipeline[]
//[]
reader = new vtkGenericEnSightReader();
// Make sure all algorithms use the composite data pipeline[]
cdp = new vtkCompositeDataPipeline();
vtkGenericEnSightReader.SetDefaultExecutivePrototype((vtkExecutive)cdp);
reader.SetCaseFileName((string)"" + (VTK_DATA_ROOT.ToString()) + "/Data/EnSight/RectGrid_ascii.case");
reader.Update();
toRectilinearGrid = new vtkCastToConcrete();
// toRectilinearGrid SetInputConnection [reader GetOutputPort] []
toRectilinearGrid.SetInput((vtkDataObject)reader.GetOutput().GetBlock((uint)0));
plane = new vtkRectilinearGridGeometryFilter();
plane.SetInput((vtkDataObject)toRectilinearGrid.GetRectilinearGridOutput());
plane.SetExtent((int)0,(int)100,(int)0,(int)100,(int)15,(int)15);
tri = new vtkTriangleFilter();
tri.SetInputConnection((vtkAlgorithmOutput)plane.GetOutputPort());
warper = new vtkWarpVector();
warper.SetInputConnection((vtkAlgorithmOutput)tri.GetOutputPort());
warper.SetScaleFactor((double)0.05);
planeMapper = new vtkDataSetMapper();
planeMapper.SetInputConnection((vtkAlgorithmOutput)warper.GetOutputPort());
planeMapper.SetScalarRange((double)0.197813,(double)0.710419);
planeActor = new vtkActor();
planeActor.SetMapper((vtkMapper)planeMapper);
cutPlane = new vtkPlane();
// eval cutPlane SetOrigin [[reader GetOutput] GetCenter][]
cutPlane.SetOrigin((double)((vtkDataSet)reader.GetOutput().GetBlock((uint)0)).GetCenter()[0], (double)((vtkDataSet)reader.GetOutput().GetBlock((uint)0)).GetCenter()[1], (double)((vtkDataSet)reader.GetOutput().GetBlock((uint)0)).GetCenter()[2]);
cutPlane.SetNormal((double)1,(double)0,(double)0);
planeCut = new vtkCutter();
planeCut.SetInput((vtkDataObject)toRectilinearGrid.GetRectilinearGridOutput());
planeCut.SetCutFunction((vtkImplicitFunction)cutPlane);
cutMapper = new vtkDataSetMapper();
cutMapper.SetInputConnection((vtkAlgorithmOutput)planeCut.GetOutputPort());
cutMapper.SetScalarRange((double)((vtkDataSet)((vtkMultiBlockDataSet)reader.GetOutput()).GetBlock((uint)0)).GetPointData().GetScalars().GetRange()[0], (double)((vtkDataSet)((vtkMultiBlockDataSet)reader.GetOutput()).GetBlock((uint)0)).GetPointData().GetScalars().GetRange()[1]);
cutActor = new vtkActor();
cutActor.SetMapper((vtkMapper)cutMapper);
iso = new vtkContourFilter();
iso.SetInput((vtkDataObject)toRectilinearGrid.GetRectilinearGridOutput());
iso.SetValue((int)0,(double)0.7);
normals = new vtkPolyDataNormals();
normals.SetInputConnection((vtkAlgorithmOutput)iso.GetOutputPort());
normals.SetFeatureAngle((double)45);
isoMapper = vtkPolyDataMapper.New();
isoMapper.SetInputConnection((vtkAlgorithmOutput)normals.GetOutputPort());
isoMapper.ScalarVisibilityOff();
isoActor = new vtkActor();
isoActor.SetMapper((vtkMapper)isoMapper);
isoActor.GetProperty().SetColor((double) 1.0000, 0.8941, 0.7686 );
isoActor.GetProperty().SetRepresentationToWireframe();
streamer = new vtkStreamLine();
// streamer SetInputConnection [reader GetOutputPort][]
streamer.SetInput((vtkDataObject)reader.GetOutput().GetBlock((uint)0));
streamer.SetStartPosition((double)-1.2,(double)-0.1,(double)1.3);
streamer.SetMaximumPropagationTime((double)500);
streamer.SetStepLength((double)0.05);
streamer.SetIntegrationStepLength((double)0.05);
streamer.SetIntegrationDirectionToIntegrateBothDirections();
streamTube = new vtkTubeFilter();
streamTube.SetInputConnection((vtkAlgorithmOutput)streamer.GetOutputPort());
streamTube.SetRadius((double)0.025);
streamTube.SetNumberOfSides((int)6);
streamTube.SetVaryRadius((int)VTK_VARY_RADIUS_BY_VECTOR);
mapStreamTube = vtkPolyDataMapper.New();
mapStreamTube.SetInputConnection((vtkAlgorithmOutput)streamTube.GetOutputPort());
mapStreamTube.SetScalarRange((double)((vtkDataSet)reader.GetOutput().GetBlock((uint)0)).GetPointData().GetScalars().GetRange()[0], (double)((vtkDataSet)reader.GetOutput().GetBlock((uint)0)).GetPointData().GetScalars().GetRange()[1]);
// [[[[reader GetOutput] GetPointData] GetScalars] GetRange][]
streamTubeActor = new vtkActor();
streamTubeActor.SetMapper((vtkMapper)mapStreamTube);
streamTubeActor.GetProperty().BackfaceCullingOn();
outline = new vtkOutlineFilter();
outline.SetInput((vtkDataObject)toRectilinearGrid.GetRectilinearGridOutput());
outlineMapper = vtkPolyDataMapper.New();
outlineMapper.SetInputConnection((vtkAlgorithmOutput)outline.GetOutputPort());
outlineActor = new vtkActor();
outlineActor.SetMapper((vtkMapper)outlineMapper);
outlineActor.GetProperty().SetColor((double) 0.0000, 0.0000, 0.0000 );
// Graphics stuff[]
// Create the RenderWindow, Renderer and both Actors[]
//[]
ren1 = vtkRenderer.New();
renWin = vtkRenderWindow.New();
renWin.AddRenderer((vtkRenderer)ren1);
iren = new vtkRenderWindowInteractor();
iren.SetRenderWindow((vtkRenderWindow)renWin);
// Add the actors to the renderer, set the background and size[]
//[]
ren1.AddActor((vtkProp)outlineActor);
ren1.AddActor((vtkProp)planeActor);
ren1.AddActor((vtkProp)cutActor);
ren1.AddActor((vtkProp)isoActor);
ren1.AddActor((vtkProp)streamTubeActor);
ren1.SetBackground((double)1,(double)1,(double)1);
renWin.SetSize((int)400,(int)400);
cam1 = ren1.GetActiveCamera();
cam1.SetClippingRange((double)3.76213,(double)10.712);
cam1.SetFocalPoint((double)-0.0842503,(double)-0.136905,(double)0.610234);
cam1.SetPosition((double)2.53813,(double)2.2678,(double)-5.22172);
cam1.SetViewUp((double)-0.241047,(double)0.930635,(double)0.275343);
iren.Initialize();
// render the image[]
//[]
// prevent the tk window from showing up then start the event loop[]
vtkGenericEnSightReader.SetDefaultExecutivePrototype(null);
//deleteAllVTKObjects();
}
/// <summary>
/// The main entry method called by the CSharp driver
/// </summary>
/// <param name="argv"></param>
public static void AVrectGrid(String [] argv)
{
//Prefix Content is: ""
VTK_VARY_RADIUS_BY_VECTOR = 2;
// create pipeline[]
//[]
reader = new vtkDataSetReader();
reader.SetFileName((string)"" + (VTK_DATA_ROOT.ToString()) + "/Data/RectGrid2.vtk");
reader.Update();
toRectilinearGrid = new vtkCastToConcrete();
toRectilinearGrid.SetInputConnection((vtkAlgorithmOutput)reader.GetOutputPort());
toRectilinearGrid.Update();
plane = new vtkRectilinearGridGeometryFilter();
plane.SetInputData((vtkDataObject)toRectilinearGrid.GetRectilinearGridOutput());
plane.SetExtent((int)0, (int)100, (int)0, (int)100, (int)15, (int)15);
warper = new vtkWarpVector();
warper.SetInputConnection((vtkAlgorithmOutput)plane.GetOutputPort());
warper.SetScaleFactor((double)0.05);
planeMapper = new vtkDataSetMapper();
planeMapper.SetInputConnection((vtkAlgorithmOutput)warper.GetOutputPort());
planeMapper.SetScalarRange((double)0.197813, (double)0.710419);
planeActor = new vtkActor();
planeActor.SetMapper((vtkMapper)planeMapper);
cutPlane = new vtkPlane();
cutPlane.SetOrigin(reader.GetOutput().GetCenter()[0], reader.GetOutput().GetCenter()[1], reader.GetOutput().GetCenter()[2]);
cutPlane.SetNormal((double)1, (double)0, (double)0);
planeCut = new vtkCutter();
planeCut.SetInputData((vtkDataObject)toRectilinearGrid.GetRectilinearGridOutput());
planeCut.SetCutFunction((vtkImplicitFunction)cutPlane);
cutMapper = new vtkDataSetMapper();
cutMapper.SetInputConnection((vtkAlgorithmOutput)planeCut.GetOutputPort());
cutMapper.SetScalarRange((double)((vtkDataSet)reader.GetOutput()).GetPointData().GetScalars().GetRange()[0], (double)((vtkDataSet)reader.GetOutput()).GetPointData().GetScalars().GetRange()[1]);
cutActor = new vtkActor();
cutActor.SetMapper((vtkMapper)cutMapper);
iso = new vtkContourFilter();
iso.SetInputData((vtkDataObject)toRectilinearGrid.GetRectilinearGridOutput());
iso.SetValue((int)0, (double)0.7);
normals = new vtkPolyDataNormals();
normals.SetInputConnection((vtkAlgorithmOutput)iso.GetOutputPort());
normals.SetFeatureAngle((double)45);
isoMapper = vtkPolyDataMapper.New();
isoMapper.SetInputConnection((vtkAlgorithmOutput)normals.GetOutputPort());
isoMapper.ScalarVisibilityOff();
isoActor = new vtkActor();
isoActor.SetMapper((vtkMapper)isoMapper);
isoActor.GetProperty().SetColor((double)1.0000, 0.8941, 0.7686);
isoActor.GetProperty().SetRepresentationToWireframe();
streamer = new vtkStreamLine();
streamer.SetInputConnection((vtkAlgorithmOutput)reader.GetOutputPort());
streamer.SetStartPosition((double)-1.2, (double)-0.1, (double)1.3);
streamer.SetMaximumPropagationTime((double)500);
streamer.SetStepLength((double)0.05);
streamer.SetIntegrationStepLength((double)0.05);
streamer.SetIntegrationDirectionToIntegrateBothDirections();
streamTube = new vtkTubeFilter();
streamTube.SetInputConnection((vtkAlgorithmOutput)streamer.GetOutputPort());
streamTube.SetRadius((double)0.025);
streamTube.SetNumberOfSides((int)6);
streamTube.SetVaryRadius((int)VTK_VARY_RADIUS_BY_VECTOR);
mapStreamTube = vtkPolyDataMapper.New();
mapStreamTube.SetInputConnection((vtkAlgorithmOutput)streamTube.GetOutputPort());
mapStreamTube.SetScalarRange((double)((vtkDataSet)reader.GetOutput()).GetPointData().GetScalars().GetRange()[0], (double)((vtkDataSet)reader.GetOutput()).GetPointData().GetScalars().GetRange()[1]);
streamTubeActor = new vtkActor();
streamTubeActor.SetMapper((vtkMapper)mapStreamTube);
streamTubeActor.GetProperty().BackfaceCullingOn();
outline = new vtkOutlineFilter();
outline.SetInputData((vtkDataObject)toRectilinearGrid.GetRectilinearGridOutput());
outlineMapper = vtkPolyDataMapper.New();
outlineMapper.SetInputConnection((vtkAlgorithmOutput)outline.GetOutputPort());
outlineActor = new vtkActor();
outlineActor.SetMapper((vtkMapper)outlineMapper);
outlineActor.GetProperty().SetColor((double)0.0000, 0.0000, 0.0000);
// Graphics stuff[]
// Create the RenderWindow, Renderer and both Actors[]
//[]
ren1 = vtkRenderer.New();
renWin = vtkRenderWindow.New();
renWin.SetMultiSamples(0);
renWin.AddRenderer((vtkRenderer)ren1);
iren = new vtkRenderWindowInteractor();
iren.SetRenderWindow((vtkRenderWindow)renWin);
// Add the actors to the renderer, set the background and size[]
//[]
ren1.AddActor((vtkProp)outlineActor);
ren1.AddActor((vtkProp)planeActor);
ren1.AddActor((vtkProp)cutActor);
ren1.AddActor((vtkProp)isoActor);
ren1.AddActor((vtkProp)streamTubeActor);
ren1.SetBackground((double)1, (double)1, (double)1);
renWin.SetSize((int)400, (int)400);
cam1 = ren1.GetActiveCamera();
cam1.SetClippingRange((double)3.76213, (double)10.712);
cam1.SetFocalPoint((double)-0.0842503, (double)-0.136905, (double)0.610234);
cam1.SetPosition((double)2.53813, (double)2.2678, (double)-5.22172);
cam1.SetViewUp((double)-0.241047, (double)0.930635, (double)0.275343);
iren.Initialize();
// render the image[]
//[]
// prevent the tk window from showing up then start the event loop[]
//deleteAllVTKObjects();
}
/// <summary>
/// The main entry method called by the CSharp driver
/// </summary>
/// <param name="argv"></param>
public static void AVTenEllip(String [] argv)
{
//Prefix Content is: ""
// create tensor ellipsoids[]
// Create the RenderWindow, Renderer and interactive renderer[]
//[]
ren1 = vtkRenderer.New();
renWin = vtkRenderWindow.New();
renWin.SetMultiSamples(0);
renWin.AddRenderer((vtkRenderer)ren1);
iren = new vtkRenderWindowInteractor();
iren.SetRenderWindow((vtkRenderWindow)renWin);
//[]
// Create tensor ellipsoids[]
//[]
// generate tensors[]
ptLoad = new vtkPointLoad();
ptLoad.SetLoadValue((double)100.0);
ptLoad.SetSampleDimensions((int)6,(int)6,(int)6);
ptLoad.ComputeEffectiveStressOn();
ptLoad.SetModelBounds((double)-10,(double)10,(double)-10,(double)10,(double)-10,(double)10);
// extract plane of data[]
plane = new vtkImageDataGeometryFilter();
plane.SetInputConnection((vtkAlgorithmOutput)ptLoad.GetOutputPort());
plane.SetExtent((int)2,(int)2,(int)0,(int)99,(int)0,(int)99);
// Generate ellipsoids[]
sphere = new vtkSphereSource();
sphere.SetThetaResolution((int)8);
sphere.SetPhiResolution((int)8);
ellipsoids = new vtkTensorGlyph();
ellipsoids.SetInputConnection((vtkAlgorithmOutput)ptLoad.GetOutputPort());
ellipsoids.SetSourceConnection((vtkAlgorithmOutput)sphere.GetOutputPort());
ellipsoids.SetScaleFactor((double)10);
ellipsoids.ClampScalingOn();
ellipNormals = new vtkPolyDataNormals();
ellipNormals.SetInputConnection((vtkAlgorithmOutput)ellipsoids.GetOutputPort());
// Map contour[]
lut = new vtkLogLookupTable();
lut.SetHueRange((double).6667,(double)0.0);
ellipMapper = vtkPolyDataMapper.New();
ellipMapper.SetInputConnection((vtkAlgorithmOutput)ellipNormals.GetOutputPort());
ellipMapper.SetLookupTable((vtkScalarsToColors)lut);
plane.Update();
//force update for scalar range[]
ellipMapper.SetScalarRange((double)((vtkDataSet)plane.GetOutput()).GetScalarRange()[0],(double)((vtkDataSet)plane.GetOutput()).GetScalarRange()[1]);
ellipActor = new vtkActor();
ellipActor.SetMapper((vtkMapper)ellipMapper);
//[]
// Create outline around data[]
//[]
outline = new vtkOutlineFilter();
outline.SetInputConnection((vtkAlgorithmOutput)ptLoad.GetOutputPort());
outlineMapper = vtkPolyDataMapper.New();
outlineMapper.SetInputConnection((vtkAlgorithmOutput)outline.GetOutputPort());
outlineActor = new vtkActor();
outlineActor.SetMapper((vtkMapper)outlineMapper);
outlineActor.GetProperty().SetColor((double)0,(double)0,(double)0);
//[]
// Create cone indicating application of load[]
//[]
coneSrc = new vtkConeSource();
coneSrc.SetRadius((double).5);
coneSrc.SetHeight((double)2);
coneMap = vtkPolyDataMapper.New();
coneMap.SetInputConnection((vtkAlgorithmOutput)coneSrc.GetOutputPort());
coneActor = new vtkActor();
coneActor.SetMapper((vtkMapper)coneMap);
coneActor.SetPosition((double)0,(double)0,(double)11);
coneActor.RotateY((double)90);
coneActor.GetProperty().SetColor((double)1,(double)0,(double)0);
camera = new vtkCamera();
camera.SetFocalPoint((double)0.113766,(double)-1.13665,(double)-1.01919);
camera.SetPosition((double)-29.4886,(double)-63.1488,(double)26.5807);
camera.SetViewAngle((double)24.4617);
camera.SetViewUp((double)0.17138,(double)0.331163,(double)0.927879);
camera.SetClippingRange((double)1,(double)100);
ren1.AddActor((vtkProp)ellipActor);
ren1.AddActor((vtkProp)outlineActor);
ren1.AddActor((vtkProp)coneActor);
ren1.SetBackground((double)1.0,(double)1.0,(double)1.0);
ren1.SetActiveCamera((vtkCamera)camera);
renWin.SetSize((int)400,(int)400);
renWin.Render();
// prevent the tk window from showing up then start the event loop[]
//deleteAllVTKObjects();
}
/// <summary>
/// The main entry method called by the CSharp driver
/// </summary>
/// <param name="argv"></param>
public static void AVextractRectGrid(String [] argv)
{
//Prefix Content is: ""
// create pipeline - rectilinear grid[]
//[]
rgridReader = new vtkRectilinearGridReader();
rgridReader.SetFileName((string)"" + (VTK_DATA_ROOT.ToString()) + "/Data/RectGrid2.vtk");
outline = new vtkOutlineFilter();
outline.SetInputConnection((vtkAlgorithmOutput)rgridReader.GetOutputPort());
mapper = vtkPolyDataMapper.New();
mapper.SetInputConnection((vtkAlgorithmOutput)outline.GetOutputPort());
actor = new vtkActor();
actor.SetMapper((vtkMapper)mapper);
rgridReader.Update();
extract1 = new vtkExtractRectilinearGrid();
extract1.SetInputConnection((vtkAlgorithmOutput)rgridReader.GetOutputPort());
//extract1 SetVOI 0 46 0 32 0 10[]
extract1.SetVOI((int)23,(int)40,(int)16,(int)30,(int)9,(int)9);
extract1.SetSampleRate((int)2,(int)2,(int)1);
extract1.IncludeBoundaryOn();
extract1.Update();
surf1 = new vtkDataSetSurfaceFilter();
surf1.SetInputConnection((vtkAlgorithmOutput)extract1.GetOutputPort());
tris = new vtkTriangleFilter();
tris.SetInputConnection((vtkAlgorithmOutput)surf1.GetOutputPort());
mapper1 = vtkPolyDataMapper.New();
mapper1.SetInputConnection((vtkAlgorithmOutput)tris.GetOutputPort());
mapper1.SetScalarRange((double)((vtkDataSet)extract1.GetOutput()).GetScalarRange()[0], (double)((vtkDataSet)extract1.GetOutput()).GetScalarRange()[1]);
actor1 = new vtkActor();
actor1.SetMapper((vtkMapper)mapper1);
// write out a rect grid[]
// write to the temp directory if possible, otherwise use .[]
dir = ".";
dir = TclToCsScriptTestDriver.GetTempDirectory();
// make sure the directory is writeable first[]
try
{
channel = new StreamWriter("" + (dir.ToString()) + "/test.tmp");
tryCatchError = "NOERROR";
}
catch(Exception)
{tryCatchError = "ERROR";}
if(tryCatchError.Equals("NOERROR"))
{
channel.Close();
File.Delete("" + (dir.ToString()) + "/test.tmp");
rectWriter = new vtkRectilinearGridWriter();
rectWriter.SetInputConnection((vtkAlgorithmOutput)extract1.GetOutputPort());
rectWriter.SetFileName((string)"" + (dir.ToString()) + "/rect.tmp");
rectWriter.Write();
// delete the file[]
File.Delete("" + (dir.ToString()) + "/rect.tmp");
}
// Create the RenderWindow, Renderer and both Actors[]
//[]
ren1 = vtkRenderer.New();
renWin = vtkRenderWindow.New();
renWin.AddRenderer((vtkRenderer)ren1);
iren = new vtkRenderWindowInteractor();
iren.SetRenderWindow((vtkRenderWindow)renWin);
//ren1 AddActor actor[]
ren1.AddActor((vtkProp)actor1);
renWin.SetSize((int)340,(int)400);
iren.Initialize();
// render the image[]
//[]
// prevent the tk window from showing up then start the event loop[]
//deleteAllVTKObjects();
}
///<summary> A Set Method for Static Variables </summary>
public static void Setoutline(vtkOutlineFilter toSet)
{
outline = toSet;
}
/// <summary>
/// The main entry method called by the CSharp driver
/// </summary>
/// <param name="argv"></param>
public static void AVHyperScalarBar(String [] argv)
{
//Prefix Content is: ""
// Test the scalar bar actor using a logarithmic lookup table[]
//[]
VTK_INTEGRATE_BOTH_DIRECTIONS = 2;
//[]
// generate tensors[]
ptLoad = new vtkPointLoad();
ptLoad.SetLoadValue((double)100.0);
ptLoad.SetSampleDimensions((int)20,(int)20,(int)20);
ptLoad.ComputeEffectiveStressOn();
ptLoad.SetModelBounds((double)-10,(double)10,(double)-10,(double)10,(double)-10,(double)10);
// Generate hyperstreamlines[]
s1 = new vtkHyperStreamline();
s1.SetInputConnection((vtkAlgorithmOutput)ptLoad.GetOutputPort());
s1.SetStartPosition((double)9,(double)9,(double)-9);
s1.IntegrateMinorEigenvector();
s1.SetMaximumPropagationDistance((double)18.0);
s1.SetIntegrationStepLength((double)0.1);
s1.SetStepLength((double)0.01);
s1.SetRadius((double)0.25);
s1.SetNumberOfSides((int)18);
s1.SetIntegrationDirection((int)VTK_INTEGRATE_BOTH_DIRECTIONS);
s1.Update();
// Map hyperstreamlines[]
lut = new vtkLogLookupTable();
lut.SetHueRange((double).6667,(double)0.0);
scalarBar = new vtkScalarBarActor();
scalarBar.SetLookupTable((vtkScalarsToColors)lut);
scalarBar.SetTitle((string)"Stress");
scalarBar.GetPositionCoordinate().SetCoordinateSystemToNormalizedViewport();
scalarBar.GetPositionCoordinate().SetValue((double)0.1,(double)0.05);
scalarBar.SetOrientationToVertical();
scalarBar.SetWidth((double)0.1);
scalarBar.SetHeight((double)0.9);
scalarBar.SetPosition((double)0.01,(double)0.1);
scalarBar.SetLabelFormat((string)"%-#6.3f");
scalarBar.GetLabelTextProperty().SetColor((double)1,(double)0,(double)0);
scalarBar.GetTitleTextProperty().SetColor((double)1,(double)0,(double)0);
s1Mapper = vtkPolyDataMapper.New();
s1Mapper.SetInputConnection((vtkAlgorithmOutput)s1.GetOutputPort());
s1Mapper.SetLookupTable((vtkScalarsToColors)lut);
ptLoad.Update();
//force update for scalar range[]
s1Mapper.SetScalarRange((double)((vtkDataSet)ptLoad.GetOutput()).GetScalarRange()[0],(double)((vtkDataSet)ptLoad.GetOutput()).GetScalarRange()[1]);
s1Actor = new vtkActor();
s1Actor.SetMapper((vtkMapper)s1Mapper);
s2 = new vtkHyperStreamline();
s2.SetInputConnection((vtkAlgorithmOutput)ptLoad.GetOutputPort());
s2.SetStartPosition((double)-9,(double)-9,(double)-9);
s2.IntegrateMinorEigenvector();
s2.SetMaximumPropagationDistance((double)18.0);
s2.SetIntegrationStepLength((double)0.1);
s2.SetStepLength((double)0.01);
s2.SetRadius((double)0.25);
s2.SetNumberOfSides((int)18);
s2.SetIntegrationDirection((int)VTK_INTEGRATE_BOTH_DIRECTIONS);
s2.Update();
s2Mapper = vtkPolyDataMapper.New();
s2Mapper.SetInputConnection((vtkAlgorithmOutput)s2.GetOutputPort());
s2Mapper.SetLookupTable((vtkScalarsToColors)lut);
s2Mapper.SetScalarRange((double)((vtkDataSet)ptLoad.GetOutput()).GetScalarRange()[0],(double)((vtkDataSet)ptLoad.GetOutput()).GetScalarRange()[1]);
s2Actor = new vtkActor();
s2Actor.SetMapper((vtkMapper)s2Mapper);
s3 = new vtkHyperStreamline();
s3.SetInputConnection((vtkAlgorithmOutput)ptLoad.GetOutputPort());
s3.SetStartPosition((double)9,(double)-9,(double)-9);
s3.IntegrateMinorEigenvector();
s3.SetMaximumPropagationDistance((double)18.0);
s3.SetIntegrationStepLength((double)0.1);
s3.SetStepLength((double)0.01);
s3.SetRadius((double)0.25);
s3.SetNumberOfSides((int)18);
s3.SetIntegrationDirection((int)VTK_INTEGRATE_BOTH_DIRECTIONS);
s3.Update();
s3Mapper = vtkPolyDataMapper.New();
s3Mapper.SetInputConnection((vtkAlgorithmOutput)s3.GetOutputPort());
s3Mapper.SetLookupTable((vtkScalarsToColors)lut);
s3Mapper.SetScalarRange((double)((vtkDataSet)ptLoad.GetOutput()).GetScalarRange()[0],(double)((vtkDataSet)ptLoad.GetOutput()).GetScalarRange()[1]);
s3Actor = new vtkActor();
s3Actor.SetMapper((vtkMapper)s3Mapper);
s4 = new vtkHyperStreamline();
s4.SetInputConnection((vtkAlgorithmOutput)ptLoad.GetOutputPort());
s4.SetStartPosition((double)-9,(double)9,(double)-9);
s4.IntegrateMinorEigenvector();
s4.SetMaximumPropagationDistance((double)18.0);
s4.SetIntegrationStepLength((double)0.1);
s4.SetStepLength((double)0.01);
s4.SetRadius((double)0.25);
s4.SetNumberOfSides((int)18);
s4.SetIntegrationDirection((int)VTK_INTEGRATE_BOTH_DIRECTIONS);
s4.Update();
s4Mapper = vtkPolyDataMapper.New();
s4Mapper.SetInputConnection((vtkAlgorithmOutput)s4.GetOutputPort());
s4Mapper.SetLookupTable((vtkScalarsToColors)lut);
s4Mapper.SetScalarRange((double)((vtkDataSet)ptLoad.GetOutput()).GetScalarRange()[0],(double)((vtkDataSet)ptLoad.GetOutput()).GetScalarRange()[1]);
s4Actor = new vtkActor();
s4Actor.SetMapper((vtkMapper)s4Mapper);
// plane for context[]
//[]
g = new vtkImageDataGeometryFilter();
g.SetInputConnection((vtkAlgorithmOutput)ptLoad.GetOutputPort());
g.SetExtent((int)0,(int)100,(int)0,(int)100,(int)0,(int)0);
g.Update();
//for scalar range[]
gm = vtkPolyDataMapper.New();
gm.SetInputConnection((vtkAlgorithmOutput)g.GetOutputPort());
gm.SetScalarRange((double)((vtkImageDataGeometryFilter)g).GetOutput().GetScalarRange()[0], (double)((vtkImageDataGeometryFilter)g).GetOutput().GetScalarRange()[1]);
ga = new vtkActor();
ga.SetMapper((vtkMapper)gm);
// Create outline around data[]
//[]
outline = new vtkOutlineFilter();
outline.SetInputConnection((vtkAlgorithmOutput)ptLoad.GetOutputPort());
outlineMapper = vtkPolyDataMapper.New();
outlineMapper.SetInputConnection((vtkAlgorithmOutput)outline.GetOutputPort());
outlineActor = new vtkActor();
outlineActor.SetMapper((vtkMapper)outlineMapper);
outlineActor.GetProperty().SetColor((double)0,(double)0,(double)0);
// Create cone indicating application of load[]
//[]
coneSrc = new vtkConeSource();
coneSrc.SetRadius((double).5);
coneSrc.SetHeight((double)2);
coneMap = vtkPolyDataMapper.New();
coneMap.SetInputConnection((vtkAlgorithmOutput)coneSrc.GetOutputPort());
coneActor = new vtkActor();
coneActor.SetMapper((vtkMapper)coneMap);
coneActor.SetPosition((double)0,(double)0,(double)11);
coneActor.RotateY((double)90);
coneActor.GetProperty().SetColor((double)1,(double)0,(double)0);
// Create the rendering infrastructure[]
//[]
ren1 = vtkRenderer.New();
renWin = vtkRenderWindow.New();
renWin.AddRenderer((vtkRenderer)ren1);
iren = new vtkRenderWindowInteractor();
iren.SetRenderWindow((vtkRenderWindow)renWin);
camera = new vtkCamera();
camera.SetFocalPoint((double)0.113766,(double)-1.13665,(double)-1.01919);
camera.SetPosition((double)-29.4886,(double)-63.1488,(double)26.5807);
camera.SetViewAngle((double)24.4617);
camera.SetViewUp((double)0.17138,(double)0.331163,(double)0.927879);
camera.SetClippingRange((double)1,(double)100);
ren1.AddActor2D((vtkProp)scalarBar);
ren1.AddActor((vtkProp)s1Actor);
ren1.AddActor((vtkProp)s2Actor);
ren1.AddActor((vtkProp)s3Actor);
ren1.AddActor((vtkProp)s4Actor);
ren1.AddActor((vtkProp)outlineActor);
ren1.AddActor((vtkProp)coneActor);
ren1.AddActor((vtkProp)ga);
ren1.SetBackground((double)1.0,(double)1.0,(double)1.0);
ren1.SetActiveCamera((vtkCamera)camera);
renWin.SetSize((int)300,(int)300);
renWin.Render();
// prevent the tk window from showing up then start the event loop[]
//deleteAllVTKObjects();
}
