cylinder.cxx

VTK入门样例(种类齐全)

/*=========================================================================

  Program:   Visualization Toolkit
  Module:    $RCSfile: Cone4.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 the creation of multiple actors and the
// manipulation of their properties and transformations. It is a
// derivative of Cone.tcl, see that example for more information.
//

// 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"
#include "vtkProperty.h"
#include "vtkRenderWindowInteractor.h"
#include "windows.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 first cone. The actor's properties are
  // modified to give it different surface properties. By default, an actor
  // is create with a property so the GetProperty() method can be used.
  //
  vtkActor *coneActor = vtkActor::New();
  coneActor->SetMapper( coneMapper );
  coneActor->GetProperty()->SetColor(0.2, 0.63, 0.79);
  coneActor->GetProperty()->SetDiffuse(0.7);
  coneActor->GetProperty()->SetSpecular(0.4);
  coneActor->GetProperty()->SetSpecularPower(20);

  //
  // Create a property and directly manipulate it. Assign it to the
  // second actor.
  //
  vtkProperty *property = vtkProperty::New();
  property->SetColor(1.0, 0.3882, 0.2784);
  property->SetDiffuse(0.7);
  property->SetSpecular(0.4);
  property->SetSpecularPower(20);

  //
  // Create a second actor and a property. The property is directly
  // manipulated and then assigned to the actor. In this way, a single
  // property can be shared among many actors. Note also that we use the
  // same mapper as the first actor did. This way we avoid duplicating
  // geometry, which may save lots of memory if the geoemtry is large.
  vtkActor *coneActor2 = vtkActor::New();
  coneActor2->SetMapper(coneMapper);
  coneActor2->GetProperty()->SetColor(0.2, 0.63, 0.79);
  coneActor2->SetProperty(property);
  coneActor2->SetPosition(0, 2, 0);

  //
  // 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= vtkRenderer::New();
  ren1->AddActor( coneActor );
  ren1->AddActor( coneActor2 );
  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 = vtkRenderWindow::New();
  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 );//竖直为轴旋转
	Sleep(10);
    }
*/
  /*
  for (i = 0; i < 360; ++i)
    {
    // render the image
    renWin->Render();
    // rotate the active camera by one degree
    ren1->GetActiveCamera()->Roll ( 1 );//视点平面法线为轴旋转
	Sleep(10);
    }
*/

	/*
  for (i = 0; i < 360; ++i)
    {
    // render the image
    renWin->Render();
    // rotate the active camera by one degree
    ren1->GetActiveCamera()->Pitch ( 1 );//竖直移动
	Sleep(10);
    }
	*/


  /*
  for (i = 0; i < 360; ++i)
    {
    // render the image
    renWin->Render();
    // rotate the active camera by one degree
    ren1->GetActiveCamera()->Yaw  ( 1 );//水平移动
	Sleep(10);
    }
	*/
	/*	
  for (i = 0; i < 360; ++i)
    {
    // render the image
    renWin->Render();
    // rotate the active camera by one degree
    ren1->GetActiveCamera()->Elevation  ( -1 );//水平为轴旋转
	Sleep(10);
    }
*/	
/*	
  for (i = 0; i < 50; ++i)
    {
    // render the image
    renWin->Render();
    // rotate the active camera by one degree
	ren1->ResetCamera();
    ren1->GetActiveCamera()->Dolly((125-i)/100.0 );//水平为轴旋转
	Sleep(10);
    }
*/
/**/	
  for (i = 0; i < 190; ++i)
    {
    // render the image
    renWin->Render();
    // rotate the active camera by one degree
	ren1->ResetCamera();
    ren1->GetActiveCamera()->Zoom((200-i)/100.0 );//水平为轴旋转
	Sleep(10);
    }


  vtkRenderWindowInteractor *iren = vtkRenderWindowInteractor::New();
  iren->SetRenderWindow(renWin);
  iren->Initialize();
  iren->Start();
  //
  // Free up any objects we created. All instances in VTK are deleted by
  // using the Delete() method.
  //
  cone->Delete();
  coneMapper->Delete();
  coneActor->Delete();
  property->Delete();
  coneActor2->Delete();
  ren1->Delete();
  renWin->Delete();

  return 0;
}