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Win10系统VS2019+Cmake+vtk_8.2.0环境配置

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1 vtk

 

1.1 简要介绍


VTK(visualization toolkit)是一个开源的BSD许可证免费软件系统,主要用于三维计算机图形学、图像处理和科学计算可视化。VTK是在三角函数库OpenGL的基础上采用面向对象的设计方法发展起来的,它将我们在可视化开发过程中会经常遇到的细节屏蔽起来,并将一些常用的算法封装起来。

1.2 依赖库


vtk一般不需要再配置其他库。

1.2.1 MPI


非必选,如果想要编译vtkIOMPIImage或vtkIOMPIParallel模块,需要依赖MPI库,用于加速。
MPI库下载地址:
https://www.microsoft.com/en-us/download/details.aspx?id=57467

注:对于编译vtk,下载msmpisdk.msi即可,即MPI库的SDK,安装后生成include和Lib两个文件夹。

1.3 源码包下载


vtk源码地址:
github:https://github.com/Kitware/VTK.git

2 Cmake构建项目

 

2.1 路径


源代码路径:D:/ThirdParty/vtk/VTK_8.2.0
构建项目路径:D:/ThirdParty/vtk/VTK_8.2.0_build

2.2 构建选项


 

 

 

 如果想要编译vtkIOMPIImagevtkIOMPIParallel这两个模块,还需要如下设置:

 

 

 

 

注:这样的配置仅能保证Configure能过,Generate代码时会有一堆报警,但也能成功生成项目,但这在编译vtkParallelMPI,vtkIOMPIImage和vtkIOParallelNetCDF这3个项目时,仍会报MPI中无法解析的外部符号错误,我是针对这3个项目,在附加依赖项中,手动添加了MPI库Lib/x64文件夹下的几个库文件名,我对cmake不熟,没有找到更好的办法,大家要是有更好的方法,欢迎留言赐教。
另外,针对这3个项目,在附加库目录中,手动添加了MPI库Include/x64文件夹的路径。

2.3 构建项目

 

 

 

步骤如下:

  1. 指定源码路径;
  2. 指定构建项目路径;
  3. 点击Configure;
  4. 按照2.2节表中的值进行设置;
  5. 再次点击Configure;
  6. 点击Generate,构建项目路径中将生成解决方案文件VTK.sln。
  7. 点击Configure或Generate后,如果顺利,会出现Configuring done
点击Configure或Generate后,如果顺利,会出现Configuring done或Generating done。

3 打开解决方案并编译

 

3.1 编译解决方案

点击Open Project(或者在2.3节步骤2中指定的构建项目路径中,找到生成的解决方案文件VTK.sln,通过Visual Studio打开),打开通过Cmake构建的项目;
选中ALL_BUILD项目,分别在DebugRelease模式下,重新生成解决方案。

 

3.2 安装vtk

 

选中INSTALL项目,右击,重新生成,此时,将会在指定路径下(2.2节表中CMAKE_INSTALL_PREFIX选项的值)主要生成3个文件夹includelibbin

4 实际项目环境配置

注:以下通过属性表的方式进行环境配置。

4.1 附加包含目录

 

 

 

 $(vtk)\vtk-8.2\include

$(vtk)(在系统环境变量中添加并设置)就是2.2节表中CMAKE_INSTALL_PREFIX选项的值。

4.2 附加库目录

 

 

 

 $(vtk)\lib

4.3 附加依赖项

 

 

 

 将库目录$(vtk)\lib中文件后缀名为.lib的文件依次添加至附加依赖项中,并依次配置debug版本(文件名中有d)和release版本。

注意,添加附加依赖项时,不要漏掉文件后缀名.lib!

4.4 动态库

将动态库目录添加至系统环境变量Path,步骤如下:

  1. 计算机右击,点击“属性”;
  2. 点击“高级系统设置”;
  3. 点击“环境变量”;
  4. 双击Path
  5. 添加%vtk%\bin,该目录下是包含了动态库文件。

 

 

 

 

本文使用的都是相对路径,因此需事先设置好环境变量vtk,值为CMAKE_INSTALL_PREFIX对应的目录,也可以使用绝对路径。

 

 

 

注:上述步骤是按照加载vtk动态库的方式进行配置的;
当然也可以按照静态库的方式配置,可省略步骤4.4。

 

 

4.5 测试代码

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

  Program:   Visualization Toolkit
  Module:    Cone.cxx

  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 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.
//

// First include the required header files for the VTK classes we are using.
#include <vtkAutoInit.h>
VTK_MODULE_INIT(vtkRenderingOpenGL2);
VTK_MODULE_INIT(vtkInteractionStyle);
VTK_MODULE_INIT(vtkRenderingFreeType);
//#define vtkRenderingCore_AUTOINIT 2(vtkInteractionStyle,vtkRenderingOpenGL2)
#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 source 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 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->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 degrees 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);
    }

    //
    // 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();
    renWin->Delete();
    std::system("pause");
    return 0;
}

如果编译时报错,提示error LNK2019:无法解析的外部符号 __imp_SymGetLineFromAddr64,解决方案如下:
“项目”–>“属性”–>“链接器”–>“输入”–>“附加依赖项”,添加dgbhelp.lib。

如果运行时报错,提示Error: no override found for 'vtkPolyDataMapper',解决方案如下:

  1. 在附加依赖项中添加opengl32.lib
  2. 程序开头添加如下代码:
#include <vtkAutoInit.h>
VTK_MODULE_INIT(vtkRenderingOpenGL2);    // 也有可能是VTK_MODULE_INIT(vtkRenderingOpenGL);
VTK_MODULE_INIT(vtkInteractionStyle);
VTK_MODULE_INIT(vtkRenderingFreeType);

或者程序开头直接添加一句代码:
#define vtkRenderingCore_AUTOINIT 2(vtkInteractionStyle,vtkRenderingOpenGL2)

这句代码来源于编译代码生成目录D:\ThirdParty\vtk\VTK_8.2.0_build\CMakeFiles下的vtkRenderingCore_AUTOINIT_vtkInteractionStyle_vtkRenderingOpenGL2.h文件内。

 

标签:8.2,Cmake,lib,VS2019,VTK,添加,cone,include,vtk
来源: https://www.cnblogs.com/lishanyang/p/16424812.html