ParaView-5.0.1: Added the source-tree to ThirdParty-dev and patched as described in the README file

Resolves bug-report http://bugs.openfoam.org/view.php?id=2098

ParaView-5.0.1/VTK/Examples/Tutorial/Step1/Java/Cone.java

@@ -0,0 +1,91 @@
+//
+// This example creates a polygonal model of a cone, and then renders it to
+// the screen. It will rotate the cone 360 degrees and then exit. The basic
+// setup of source -> mapper -> actor -> renderer -> renderwindow is
+// typical of most VTK programs.
+//
+
+// We import the vtk wrapped classes first.
+import vtk.*;
+
+// Then we define our class.
+public class Cone {
+
+  // In the static contructor we load in the native code.
+  // The libraries must be in your path to work.
+  static {
+    System.loadLibrary("vtkCommonJava");
+    System.loadLibrary("vtkFilteringJava");
+    System.loadLibrary("vtkIOJava");
+    System.loadLibrary("vtkImagingJava");
+    System.loadLibrary("vtkGraphicsJava");
+    System.loadLibrary("vtkRenderingJava");
+  }
+
+  // now the main program
+  public static void main (String []args) {
+    //
+    // Next we create an instance of vtkConeSource and set some of its
+    // properties. The instance of vtkConeSource "cone" is part of a
+    // visualization pipeline (it is a source process object); it produces data
+    // (output type is vtkPolyData) which other filters may process.
+    //
+    vtkConeSource cone = new vtkConeSource();
+    cone.SetHeight( 3.0 );
+    cone.SetRadius( 1.0 );
+    cone.SetResolution( 10 );
+
+    //
+    // In this example we terminate the pipeline with a mapper process object.
+    // (Intermediate filters such as vtkShrinkPolyData could be inserted in
+    // between the source and the mapper.)  We create an instance of
+    // vtkPolyDataMapper to map the polygonal data into graphics primitives. We
+    // connect the output of the cone souece to the input of this mapper.
+    //
+    vtkPolyDataMapper coneMapper = new vtkPolyDataMapper();
+    coneMapper.SetInputConnection( cone.GetOutputPort() );
+
+    //
+    // Create an actor to represent the cone. The actor orchestrates rendering
+    // of the mapper's graphics primitives. An actor also refers to properties
+    // via a vtkProperty instance, and includes an internal transformation
+    // matrix. We set this actor's mapper to be coneMapper which we created
+    // above.
+    //
+    vtkActor coneActor = new vtkActor();
+    coneActor.SetMapper( coneMapper );
+
+    //
+    // Create the Renderer and assign actors to it. A renderer is like a
+    // viewport. It is part or all of a window on the screen and it is
+    // responsible for drawing the actors it has.  We also set the background
+    // color here
+    //
+    vtkRenderer ren1 = new vtkRenderer();
+    ren1.AddActor( coneActor );
+    ren1.SetBackground( 0.1, 0.2, 0.4 );
+
+    //
+    // Finally we create the render window which will show up on the screen
+    // We put our renderer into the render window using AddRenderer. We also
+    // set the size to be 300 pixels by 300
+    //
+    vtkRenderWindow renWin = new vtkRenderWindow();
+    renWin.AddRenderer( ren1 );
+    renWin.SetSize( 300, 300 );
+
+    //
+    // now we loop over 360 degreeees and render the cone each time
+    //
+    int i;
+    for (i = 0; i < 360; ++i)
+      {
+      // render the image
+      renWin.Render();
+      // rotate the active camera by one degree
+      ren1.GetActiveCamera().Azimuth( 1 );
+      }
+
+    }
+}
+