/*========================================================================= Program: Visualization Toolkit Module: $RCSfile: Cone3.cxx,v $ Copyright (c) Ken Martin, Will Schroeder, Bill Lorensen All rights reserved. See Copyright.txt or http://www.kitware.com/Copyright.htm for details. This software is distributed WITHOUT ANY WARRANTY; without even the implied warranty of MERCHANTABILITY or FITNESS FOR A PARTICULAR PURPOSE. See the above copyright notice for more information. =========================================================================*/ // // This example demonstrates how to use multiple renderers within a // render window. It is a variation of the Cone.cxx example. Please // refer to that example for additional documentation. // // First include the required header files for the VTK classes we are using. #include "vtkConeSource.h" #include "vtkPolyDataMapper.h" #include "vtkRenderWindow.h" #include "vtkCamera.h" #include "vtkActor.h" #include "vtkRenderer.h" int main() { // // 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 = vtkConeSource::New(); 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 = vtkPolyDataMapper::New(); 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 = vtkActor::New(); coneActor->SetMapper( coneMapper ); // // Create two renderers and assign actors to them. A renderer renders into // a viewport within the vtkRenderWindow. 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. In this example we are adding the same // actor to two different renderers; it is okay to add different actors to // different renderers as well. // vtkRenderer *ren1= vtkRenderer::New(); ren1->AddActor( coneActor ); ren1->SetBackground( 0.1, 0.2, 0.4 ); ren1->SetViewport(0.0, 0.0, 0.5, 1.0); vtkRenderer *ren2= vtkRenderer::New(); ren2->AddActor( coneActor ); ren2->SetBackground( 0.2, 0.3, 0.5 ); ren2->SetViewport(0.5, 0.0, 1.0, 1.0); // // 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 = vtkRenderWindow::New(); renWin->AddRenderer( ren1 ); renWin->AddRenderer( ren2 ); renWin->SetSize( 600, 300 ); // // Make one view 90 degrees from other. // ren1->ResetCamera(); ren1->GetActiveCamera()->Azimuth(90); // // 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 ); ren2->GetActiveCamera()->Azimuth( 1 ); } // // Free up any objects we created. All instances in VTK are deleted by // using the Delete() method. // cone->Delete(); coneMapper->Delete(); coneActor->Delete(); ren1->Delete(); ren2->Delete(); renWin->Delete(); return 0; }