PointDataSubdivision

#include <vtkActor.h>
#include <vtkActor2D.h>
#include <vtkArrowSource.h>
#include <vtkAxesActor.h>
#include <vtkButterflySubdivisionFilter.h>
#include <vtkCamera.h>
#include <vtkCaptionActor2D.h>
#include <vtkCleanPolyData.h>
#include <vtkColorSeries.h>
#include <vtkColorTransferFunction.h>
#include <vtkConeSource.h>
#include <vtkDataSetMapper.h>
#include <vtkElevationFilter.h>
#include <vtkGlyph3D.h>
#include <vtkLinearSubdivisionFilter.h>
#include <vtkMaskPoints.h>
#include <vtkNamedColors.h>
#include <vtkNew.h>
#include <vtkOrientationMarkerWidget.h>
#include <vtkPNGWriter.h>
#include <vtkParametricBoy.h>
#include <vtkParametricEllipsoid.h>
#include <vtkParametricFunctionSource.h>
#include <vtkParametricMobius.h>
#include <vtkParametricRandomHills.h>
#include <vtkParametricTorus.h>
#include <vtkPointData.h>
#include <vtkPolyDataMapper.h>
#include <vtkPolyDataNormals.h>
#include <vtkProperty.h>
#include <vtkProperty2D.h>
#include <vtkRenderLargeImage.h>
#include <vtkRenderWindow.h>
#include <vtkRenderWindowInteractor.h>
#include <vtkRenderer.h>
#include <vtkSmartPointer.h>
#include <vtkSphereSource.h>
#include <vtkSuperquadricSource.h>
#include <vtkTextActor.h>
#include <vtkTextMapper.h>
#include <vtkTextProperty.h>
#include <vtkTriangleFilter.h>

#include <algorithm>
#include <iostream>
#include <map>
#include <string>

namespace {
/**
 * If you add more sources, you may need to provide one or all of these filters:
 *  - A Triangle filter
 *  - A Normal filter
 *  - An elevation filter.
 *  - A CleanPolyData filter.
 *  - For parametric sources, we may need to apply one of both of JoinUOff() or
 * JoinVOff().
 *
 * Use the representative sources provided here as templates.
 */

void ParametricTorusSource(vtkPolyData* src);

void EllipsoidSource(vtkPolyData* src);

void BoySource(vtkPolyData* src);

void MobiusSource(vtkPolyData* src);

void ParametricRandomHills(vtkPolyData* src);

void SphereSource(vtkPolyData* src);

/**
 * Make a torus as the source using vtkSuperquadricSource.
 */
void SuperquadricSource(vtkPolyData* src);

void ConeSource(vtkPolyData* src);

/**
 * Make a lookup table using a predefined color series.
 *
 * @param scalarRange The range of the scalars to be coloured.
 *
 * @return A lookup table.
 */
vtkSmartPointer<vtkColorTransferFunction> MakeLUT(double const* scalarRange);

/**
 * Create the actor for glyphing the normals.
 *
 * @param source the surface.
 * @param glyphPoints The number of points used by the mask filter.
 * @param scalarRange The range in terms of scalar minimum and maximum.
 * @param scaleFactor The scaling factor for the glyph.
 * @param lut The lookup table to use.
 *
 * @return The glyph actor.
 */

vtkSmartPointer<vtkActor> GlyphActor(vtkPolyData* source, int glyphPoints,
                                     double* scalarRange, double scaleFactor,
                                     vtkColorTransferFunction* lut);

/**
 * Create the actor for a surface.
 *
 * @param surface The surface.
 * @param scalarRange The range in terms of scalar minimum and maximum.
 * @param lut The lookup table to use.
 *
 * @return The actor for the surface.
 */
vtkSmartPointer<vtkActor> MakeSurfaceActor(vtkPolyData* surface,
                                           double const* scalarRange,
                                           vtkColorTransferFunction* lut);

/**
 * Create a label.
 *
 * @param textLabel The label.
 * @param renWinSize The size of the render window. Used to set the font size.
 *
 * @return The actor for the text label.
 */
vtkSmartPointer<vtkActor2D> MakeLabel(const char* textLabel, int renWinSize);

/**
 * Make an axis actor.
 *
 * @return The axis actor.
 */
vtkSmartPointer<vtkAxesActor> MakeAxesActor();

/**
 * Create an orientation marker for a given renderer.
 *
 * @param renderer The renderer.
 * @param iren The interactor.
 *
 * @return: The orientation marker.
 */
vtkSmartPointer<vtkOrientationMarkerWidget>
MakeOrientationMarker(vtkRenderer* renderer, vtkRenderWindowInteractor* iren);

/**
 * Save the image as a PNG.
 *
 * @param ren the renderer.
 * @param fn the file name.
 * @param magnification the magnification, usually 1.
 */
void WritePNG(vtkRenderer* ren, char* fn, int magnification = 1);

} // namespace

/**
 * Demonstrates point data subdivision with the glyphing of normals on the
 * surface.
 *
 * This program takes a surface and displays three surfaces.
 *
 * The first surface is the original surface and the second and third surfaces
 * have had linear and butterfly interpolation applied respectively.
 *
 * The user can control the object to use, normal generation, type of shading
 * and number of points to use for the normals.
 */
int main(int argc, char* argv[])
{
  if (argc < 1)
  {
    std::cerr << "Missing parameters." << std::endl;
    std::cerr << "Usage: " << argv[0]
              << "sourcetouse: (parametric_torus; parametric_ellipsoid; boy; "
                 "sphere; mobius; cone; random_hills; superquadric)"
              << "[displayNormals]" << "[gouraudInterpolation]"
              << "[glyphPoints]" << std::endl;
    return EXIT_FAILURE;
  }

  std::map<std::string, int> availableSurfaces{{"parametric_torus", 0},
                                               {"parametric_ellipsoid", 1},
                                               {"boy", 2},
                                               {"sphere", 3},
                                               {"mobius", 4},
                                               {"cone", 5},
                                               {"random_hills", 6},
                                               {"superquadric", 7}};

  std::string desiredSurface{"parametric_torus"};
  if (argc < 2)
  {
    std::cout << "Using parametric_torus as the surface." << std::endl;
  }
  else
  {
    desiredSurface = argv[1];
    std::transform(desiredSurface.begin(), desiredSurface.end(),
                   desiredSurface.begin(),
                   [](char c) { return std::tolower(c); });
    if (availableSurfaces.find(desiredSurface) == availableSurfaces.end())
    {
      std::cout << "The requested surface: " << argv[1]
                << " not found, reverting to using parametric_torus."
                << std::endl;
      desiredSurface = "parametric_torus";
    }
  }

  vtkNew<vtkPolyData> polyData;
  switch (availableSurfaces[desiredSurface])
  {
  case 0:
    ParametricTorusSource(polyData);
    break;
  case 1:
    EllipsoidSource(polyData);
    break;
  case 2:
    BoySource(polyData.GetPointer());
    break;
  case 3:
    SphereSource(polyData);
    break;
  case 4:
    MobiusSource(polyData);
    break;
  case 5:
    ConeSource(polyData);
    break;
  case 6:
    ParametricRandomHills(polyData);
    break;
  case 7:
    SuperquadricSource(polyData);
    break;
  default:
    ParametricTorusSource(polyData);
  }

  bool displayNormals = true;
  if (argc > 2)
  {
    displayNormals = (atoi(argv[2]) != 0);
  }

  bool gouraudInterpolation = true;
  if (argc > 3)
  {
    gouraudInterpolation = (atoi(argv[3]) != 0);
  }

  int glyphPoints = 50;
  if (argc > 4)
  {
    glyphPoints = atoi(argv[4]);
  }

  // The size of the render window.
  int renWinXSize = 1200;
  int renWinYSize = renWinXSize / 3;
  int minRenWinDim = std::min(renWinXSize, renWinYSize);

  // [xMin, xMax, yMin, yMax, zMin, zMax]
  const double* bounds = polyData->GetBounds();
  // Use this to scale the normal glyph.
  std::vector<double> dims;
  dims.push_back(std::abs(bounds[1] - bounds[0]));
  dims.push_back(std::abs(bounds[3] - bounds[2]));
  dims.push_back(std::abs(bounds[5] - bounds[4]));
  double scaleFactor = *std::min_element(dims.begin(), dims.end()) * 0.2;

  polyData->GetPointData()->GetScalars()->SetName("Elevation");
  double* scalarRange = polyData->GetScalarRange();

  vtkNew<vtkButterflySubdivisionFilter> butterfly;
  butterfly->SetInputData(polyData);
  butterfly->SetNumberOfSubdivisions(3);
  butterfly->Update();

  vtkNew<vtkLinearSubdivisionFilter> linear;
  linear->SetInputData(polyData);
  linear->SetNumberOfSubdivisions(3);
  linear->Update();

  vtkSmartPointer<vtkColorTransferFunction> lut = MakeLUT(scalarRange);

  std::vector<vtkSmartPointer<vtkActor>> actors;
  actors.push_back(MakeSurfaceActor(butterfly->GetOutput(), scalarRange, lut));
  actors.push_back(MakeSurfaceActor(linear->GetOutput(), scalarRange, lut));
  actors.push_back(MakeSurfaceActor(polyData, scalarRange, lut));

  // Let's visualise the normals.
  std::vector<vtkSmartPointer<vtkActor>> glyphActors;
  if (displayNormals)
  {
    glyphActors.push_back(GlyphActor(butterfly->GetOutput(), glyphPoints,
                                     scalarRange, scaleFactor, lut));
    glyphActors.push_back(GlyphActor(linear->GetOutput(), glyphPoints,
                                     scalarRange, scaleFactor, lut));
    glyphActors.push_back(
        GlyphActor(polyData, glyphPoints, scalarRange, scaleFactor, lut));
  }

  std::vector<vtkSmartPointer<vtkActor2D>> labelActors;
  labelActors.push_back(MakeLabel("Butterfly Subdivision", minRenWinDim));
  labelActors.push_back(MakeLabel("Linear Subdivision", minRenWinDim));
  labelActors.push_back(MakeLabel("Original", minRenWinDim));

  std::vector<vtkSmartPointer<vtkRenderer>> ren;
  ren.push_back(vtkSmartPointer<vtkRenderer>::New());
  ren.push_back(vtkSmartPointer<vtkRenderer>::New());
  ren.push_back(vtkSmartPointer<vtkRenderer>::New());
  ren[2]->SetViewport(0, 0, 1.0 / 3.0, 1);         // Original
  ren[1]->SetViewport(1.0 / 3.0, 0, 2.0 / 3.0, 1); // Linear
  ren[0]->SetViewport(2.0 / 3.0, 0, 1, 1);         // Butterfly

  vtkNew<vtkRenderWindow> renWin;
  vtkNew<vtkRenderWindowInteractor> iren;
  iren->SetRenderWindow(renWin);

  vtkNew<vtkNamedColors> nc;

  // Orientation markers.
  std::vector<vtkSmartPointer<vtkOrientationMarkerWidget>> om;

  // Shared camera.
  vtkNew<vtkCamera> camera;

  // Make the imaging pipelines.
  for (unsigned int i = 0; i < ren.size(); ++i)
  {
    renWin->AddRenderer(ren[i]);

    ren[i]->AddActor(actors[i]);
    ren[i]->AddActor(labelActors[i]);
    ren[i]->SetBackground(nc->GetColor3d("SlateGray").GetData());
    ren[i]->SetActiveCamera(camera);
    if (displayNormals)
    {
      ren[i]->AddActor(glyphActors[i]);
    }

    om.push_back(MakeOrientationMarker(ren[i], iren));
  }
  renWin->SetSize(renWinXSize, renWinYSize);

  iren->Initialize();

  if (gouraudInterpolation)
  {
    for (unsigned int i = 0; i < actors.size(); ++i)
    {
      actors[i]->GetProperty()->SetInterpolationToGouraud();
    }
  }
  else
  {
    for (unsigned int i = 0; i < actors.size(); ++i)
    {
      actors[i]->GetProperty()->SetInterpolationToFlat();
    }
  }

  renWin->Render();
  ren[0]->ResetCamera();
  renWin->Render();
  renWin->SetWindowName("PointDataSubdivision");
  renWin->Render();

  iren->Start();

  return EXIT_SUCCESS;
}

namespace {

void ParametricTorusSource(vtkPolyData* src)
{
  vtkNew<vtkParametricTorus> torus;
  torus->JoinUOff();
  torus->JoinVOff();

  vtkNew<vtkParametricFunctionSource> torusSource;
  torusSource->SetParametricFunction(torus);
  torusSource->SetScalarModeToZ();
  torusSource->Update();

  src->ShallowCopy(torusSource->GetOutput());
}

void EllipsoidSource(vtkPolyData* src)
{
  vtkNew<vtkParametricEllipsoid> ellipsoid;
  ellipsoid->SetXRadius(0.5);
  ellipsoid->SetYRadius(1.0);
  ellipsoid->SetZRadius(2.0);
  ellipsoid->JoinUOff();
  // ellipsoid->JoinVOff();

  vtkNew<vtkParametricFunctionSource> ellipsoidSource;
  ellipsoidSource->SetParametricFunction(ellipsoid);
  ellipsoidSource->SetScalarModeToZ();
  ellipsoidSource->Update();

  src->ShallowCopy(ellipsoidSource->GetOutput());
}

void BoySource(vtkPolyData* src)
{
  vtkNew<vtkParametricBoy> boy;
  boy->JoinUOff();
  // boy->JoinVOff();

  vtkNew<vtkParametricFunctionSource> boySource;
  boySource->SetParametricFunction(boy);
  boySource->SetScalarModeToZ();
  boySource->Update();
  src->ShallowCopy(boySource->GetOutput());
}

void MobiusSource(vtkPolyData* src)
{
  vtkNew<vtkParametricMobius> mobius;
  mobius->SetRadius(2);
  mobius->SetMinimumV(-0.5);
  mobius->SetMaximumV(0.5);
  mobius->JoinUOff();

  vtkNew<vtkParametricFunctionSource> mobiusSource;
  mobiusSource->SetParametricFunction(mobius);
  mobiusSource->SetScalarModeToX();
  mobiusSource->Update();

  src->ShallowCopy(mobiusSource->GetOutput());
}

void ParametricRandomHills(vtkPolyData* src)
{
  vtkNew<vtkParametricRandomHills> randomHills;
  // randomHills->AllowRandomGenerationOff();
  randomHills->SetRandomSeed(1);
  randomHills->SetNumberOfHills(30);

  vtkNew<vtkParametricFunctionSource> randomHillsSource;
  randomHillsSource->SetParametricFunction(randomHills);
  randomHillsSource->SetScalarModeToZ();
  randomHillsSource->SetUResolution(10);
  randomHillsSource->SetVResolution(10);
  randomHillsSource->Update();

  src->ShallowCopy(randomHillsSource->GetOutput());
}

void SphereSource(vtkPolyData* src)
{
  vtkNew<vtkSphereSource> sphere;
  sphere->SetPhiResolution(11);
  sphere->SetThetaResolution(11);
  sphere->Update();
  double* sphereBounds = sphere->GetOutput()->GetBounds();

  vtkNew<vtkElevationFilter> elev;
  elev->SetInputConnection(sphere->GetOutputPort());
  elev->SetLowPoint(0, sphereBounds[2], 0);
  elev->SetHighPoint(0, sphereBounds[3], 0);
  elev->Update();

  src->ShallowCopy(elev->GetPolyDataOutput());
}

void SuperquadricSource(vtkPolyData* src)
{
  vtkNew<vtkSuperquadricSource> source;
  source->SetCenter(0.0, 0.0, 0.0);
  source->SetScale(1.0, 1.0, 1.0);
  source->SetPhiResolution(64);
  source->SetThetaResolution(64);
  source->SetThetaRoundness(1);
  source->SetThickness(0.5);
  source->SetSize(10);
  source->SetToroidal(1);

  // The quadric is made of strips, so pass it through a triangle filter as
  // the curvature filter only operates on polys.
  vtkNew<vtkTriangleFilter> tri;
  tri->SetInputConnection(source->GetOutputPort());

  // The quadric has nasty discontinuities from the way the edges are
  // generated so let's pass it though a CleanPolyDataFilter and merge any
  // points which are coincident, or very close.
  vtkNew<vtkCleanPolyData> cleaner;
  cleaner->SetInputConnection(tri->GetOutputPort());
  cleaner->SetTolerance(0.005);
  cleaner->Update();
  double* cleanerBounds = cleaner->GetOutput()->GetBounds();

  vtkNew<vtkElevationFilter> elev;
  elev->SetInputConnection(cleaner->GetOutputPort());
  elev->SetLowPoint(0, cleanerBounds[2], 0);
  elev->SetHighPoint(0, cleanerBounds[3], 0);
  elev->Update();

  src->ShallowCopy(elev->GetPolyDataOutput());
}

void ConeSource(vtkPolyData* src)
{
  vtkNew<vtkConeSource> cone;
  cone->SetResolution(6);
  cone->CappingOn();
  cone->Update();
  double* coneBounds = cone->GetOutput()->GetBounds();

  vtkNew<vtkPolyDataNormals> coneNormals;
  coneNormals->SetInputConnection(cone->GetOutputPort());

  vtkNew<vtkElevationFilter> elev;
  elev->SetInputConnection(coneNormals->GetOutputPort());
  elev->SetLowPoint(coneBounds[0], 0, 0);
  elev->SetHighPoint(coneBounds[1], 0, 0);

  // vtkButterflySubdivisionFilter and vtkLinearSubdivisionFilter operate on
  // triangles.
  vtkNew<vtkTriangleFilter> tf;
  tf->SetInputConnection(elev->GetOutputPort());
  tf->Update();

  src->ShallowCopy(tf->GetOutput());
}

vtkSmartPointer<vtkColorTransferFunction> MakeLUT(double const* scalarRange)
{
  vtkNew<vtkColorSeries> colorSeries;
  // Select a color scheme.
  // for (unsigned int i = 0; i < 62; ++i)
  //{
  //  colorSeries->SetColorScheme(i);
  //  std::cout << "Colour scheme: " << colorSeries->GetColorScheme() << ": " <<
  //  colorSeries->GetColorSchemeName();
  //}

  // Colour scheme 61: Brewer Qualitative Set3
  colorSeries->SetColorScheme(61);
  // We use this colour series to create the transfer function.
  vtkNew<vtkColorTransferFunction> lut;
  lut->SetColorSpaceToHSV();
  int numColors = colorSeries->GetNumberOfColors();
  for (int i = 0; i < numColors; ++i)
  {
    vtkColor3ub color = colorSeries->GetColor(i);
    std::vector<double> c;
    for (unsigned int j = 0; j < 3; ++j)
    {
      c.push_back(color[j] / 255.0);
    }
    double t = scalarRange[0] +
        (scalarRange[1] - scalarRange[0]) / (numColors - 1) * i;
    lut->AddRGBPoint(t, c[0], c[1], c[2]);
  }
  return lut;
}

vtkSmartPointer<vtkActor> GlyphActor(vtkPolyData* source, int glyphPoints,
                                     double* scalarRange, double scaleFactor,
                                     vtkColorTransferFunction* lut)
{
  vtkNew<vtkArrowSource> arrowSource;
  // Subsample the dataset.
  vtkNew<vtkMaskPoints> maskPts;
  maskPts->SetInputData(source);
  maskPts->SetOnRatio(source->GetNumberOfPoints() / glyphPoints);
  maskPts->SetRandomMode(1);

  vtkNew<vtkGlyph3D> arrowGlyph;
  arrowGlyph->SetScaleFactor(scaleFactor);
  arrowGlyph->SetVectorModeToUseNormal();
  arrowGlyph->SetColorModeToColorByScalar();
  arrowGlyph->SetScaleModeToScaleByVector();
  arrowGlyph->OrientOn();
  arrowGlyph->SetSourceConnection(arrowSource->GetOutputPort());
  arrowGlyph->SetInputConnection(maskPts->GetOutputPort());
  arrowGlyph->Update();

  vtkNew<vtkDataSetMapper> arrowGlyphMapper;
  // Colour by scalars.
  arrowGlyphMapper->SetScalarRange(scalarRange);
  arrowGlyphMapper->SetColorModeToMapScalars();
  arrowGlyphMapper->ScalarVisibilityOn();
  arrowGlyphMapper->SetLookupTable(lut);
  arrowGlyphMapper->SetInputConnection(arrowGlyph->GetOutputPort());

  vtkNew<vtkActor> glyphActor;
  glyphActor->SetMapper(arrowGlyphMapper);
  return glyphActor;
}

vtkSmartPointer<vtkActor> MakeSurfaceActor(vtkPolyData* surface,
                                           double const* scalarRange,
                                           vtkColorTransferFunction* lut)
{
  vtkNew<vtkPolyDataMapper> mapper;
  mapper->SetInputData(surface);
  mapper->SetLookupTable(lut);
  mapper->SetScalarRange(scalarRange);
  mapper->SetColorModeToMapScalars();
  mapper->ScalarVisibilityOn();
  vtkNew<vtkActor> actor;
  actor->SetMapper(mapper);
  return actor;
}

vtkSmartPointer<vtkActor2D> MakeLabel(const char* textLabel, int renWinSize)
{
  vtkNew<vtkNamedColors> colors;

  // Create one text property for all
  vtkNew<vtkTextProperty> textProperty;
  textProperty->SetJustificationToCentered();
  textProperty->SetFontSize(int(renWinSize / 20));

  vtkNew<vtkTextMapper> mapper;
  mapper->SetInput(textLabel);
  mapper->SetTextProperty(textProperty);

  vtkNew<vtkActor2D> actor;
  actor->SetMapper(mapper);
  actor->SetPosition(renWinSize / 2.0, renWinSize / 20);
  actor->GetProperty()->SetColor(colors->GetColor3d("Gold").GetData());
  return actor;
}

vtkSmartPointer<vtkAxesActor> MakeAxesActor()
{
  vtkNew<vtkAxesActor> axes;
  axes->SetShaftTypeToCylinder();
  axes->SetXAxisLabelText("X");
  axes->SetYAxisLabelText("Y");
  axes->SetZAxisLabelText("Z");
  axes->SetTotalLength(1.0, 1.0, 1.0);
  axes->SetCylinderRadius(1.0 * axes->GetCylinderRadius());
  axes->SetConeRadius(1.75 * axes->GetConeRadius());
  axes->SetSphereRadius(1.0 * axes->GetSphereRadius());
  axes->GetXAxisCaptionActor2D()->GetTextActor()->GetScaledTextProperty();
  axes->GetXAxisCaptionActor2D()->GetTextActor()->SetTextScaleModeToNone();
  axes->GetYAxisCaptionActor2D()->GetTextActor()->GetScaledTextProperty();
  axes->GetYAxisCaptionActor2D()->GetTextActor()->SetTextScaleModeToNone();
  axes->GetZAxisCaptionActor2D()->GetTextActor()->GetScaledTextProperty();
  axes->GetZAxisCaptionActor2D()->GetTextActor()->SetTextScaleModeToNone();
  return axes;
}

vtkSmartPointer<vtkOrientationMarkerWidget>
MakeOrientationMarker(vtkRenderer* renderer, vtkRenderWindowInteractor* iren)
{
  vtkNew<vtkOrientationMarkerWidget> om;
  auto axesActor = MakeAxesActor();
  om->SetOrientationMarker(axesActor);
  // Position lower left in the viewport.
  om->SetViewport(0, 0, 0.2, 0.2);
  om->SetInteractor(iren);
  om->SetDefaultRenderer(renderer);
  om->EnabledOn();
  om->InteractiveOn();
  return om;
}

void WritePNG(vtkRenderer* ren, char* fn, int magnification)
{
  vtkNew<vtkRenderLargeImage> renLgeIm;
  vtkNew<vtkPNGWriter> imgWriter;
  renLgeIm->SetInput(ren);
  renLgeIm->SetMagnification(magnification);
  imgWriter->SetInputConnection(renLgeIm->GetOutputPort());
  imgWriter->SetFileName(fn);
  imgWriter->Write();
}

} // namespace

cmake_minimum_required(VERSION 3.12 FATAL_ERROR)

project(PointDataSubdivision)

find_package(VTK COMPONENTS 
  CommonColor
  CommonComputationalGeometry
  CommonCore
  CommonDataModel
  FiltersCore
  FiltersHybrid
  FiltersModeling
  FiltersSources
  IOImage
  InteractionStyle
  InteractionWidgets
  RenderingAnnotation
  RenderingContextOpenGL2
  RenderingCore
  RenderingFreeType
  RenderingGL2PSOpenGL2
  RenderingOpenGL2
)

if (NOT VTK_FOUND)
  message(FATAL_ERROR "PointDataSubdivision: Unable to find the VTK build folder.")
endif()

# Prevent a "command line is too long" failure in Windows.
set(CMAKE_NINJA_FORCE_RESPONSE_FILE "ON" CACHE BOOL "Force Ninja to use response files.")
add_executable(PointDataSubdivision MACOSX_BUNDLE PointDataSubdivision.cxx )
  target_link_libraries(PointDataSubdivision PRIVATE ${VTK_LIBRARIES}
)
# vtk_module_autoinit is needed
vtk_module_autoinit(
  TARGETS PointDataSubdivision
  MODULES ${VTK_LIBRARIES}
)

cd PointDataSubdivision/build

cmake ..

cmake -DVTK_DIR:PATH=/home/me/vtk_build ..

make

./PointDataSubdivision