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181 lines
7.7 KiB
C++
181 lines
7.7 KiB
C++
/*
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#
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# File : mcf_levelsets3d.cpp
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# ( C++ source file )
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#
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# Description : Implementation of the Mean Curvature Flow on Surfaces
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# using the framework of Level Sets 3D.
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# This file is a part of the CImg Library project.
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# ( http://cimg.eu )
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#
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# Copyright : David Tschumperlé
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# ( http://tschumperle.users.greyc.fr/ )
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#
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# License : CeCILL v2.0
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# ( http://www.cecill.info/licences/Licence_CeCILL_V2-en.html )
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#
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# This software is governed by the CeCILL license under French law and
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# abiding by the rules of distribution of free software. You can use,
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# modify and/ or redistribute the software under the terms of the CeCILL
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# license as circulated by CEA, CNRS and INRIA at the following URL
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# "http://www.cecill.info".
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#
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# As a counterpart to the access to the source code and rights to copy,
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# modify and redistribute granted by the license, users are provided only
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# with a limited warranty and the software's author, the holder of the
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# economic rights, and the successive licensors have only limited
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# liability.
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#
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# In this respect, the user's attention is drawn to the risks associated
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# with loading, using, modifying and/or developing or reproducing the
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# software by the user in light of its specific status of free software,
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# that may mean that it is complicated to manipulate, and that also
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# therefore means that it is reserved for developers and experienced
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# professionals having in-depth computer knowledge. Users are therefore
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# encouraged to load and test the software's suitability as regards their
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# requirements in conditions enabling the security of their systems and/or
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# data to be ensured and, more generally, to use and operate it in the
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# same conditions as regards security.
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#
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# The fact that you are presently reading this means that you have had
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# knowledge of the CeCILL license and that you accept its terms.
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#
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*/
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#include "CImg.h"
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using namespace cimg_library;
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#undef min
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#undef max
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// Apply the Mean curvature flow PDE
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//-----------------------------------
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template<typename T> CImg<T>& mcf_PDE(CImg<T>& img, const unsigned int nb_iterations,
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const float dt=0.25f, const float narrow=4.0f) {
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CImg<float> velocity(img.width(),img.height(),img.depth(),img.spectrum());
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CImg_3x3x3(I,float);
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for (unsigned int iteration = 0; iteration<nb_iterations; ++iteration) {
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float *ptrd = velocity.data(), veloc_max = 0;
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cimg_for3x3x3(img,x,y,z,0,I,float) if (cimg::abs(Iccc)<narrow) {
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const float
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ix = (Incc - Ipcc)/2,
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iy = (Icnc - Icpc)/2,
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iz = (Iccn - Iccp)/2,
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norm = (float)std::sqrt(1e-5f + ix*ix + iy*iy + iz*iz),
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ixx = Incc + Ipcc - 2*Iccc,
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ixy = (Ippc + Innc - Inpc - Ipnc)/4,
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ixz = (Ipcp + Incn - Incp - Ipcn)/4,
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iyy = Icnc + Icpc - 2*Iccc,
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iyz = (Icpp + Icnn - Icnp - Icpn)/4,
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izz = Iccn + Iccp - 2*Iccc,
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a = ix/norm,
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b = iy/norm,
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c = iz/norm,
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inn = a*a*ixx + b*b*iyy + c*c*izz + 2*a*b*ixy + 2*a*c*ixz + 2*b*c*iyz,
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veloc = ixx + iyy + izz - inn;
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*(ptrd++) = veloc;
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if (veloc>veloc_max) veloc_max = veloc; else if (-veloc>veloc_max) veloc_max = -veloc;
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} else *(ptrd++) = 0;
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if (veloc_max>0) img+=(velocity*=dt/veloc_max);
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}
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return img;
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}
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/*----------------------
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Main procedure
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--------------------*/
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int main(int argc,char **argv) {
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cimg_usage("Mean curvature flow of a surface, using 3D level sets");
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const char *file_i = cimg_option("-i",(char*)0,"Input image");
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const float dt = cimg_option("-dt",0.05f,"PDE Time step");
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const float narrow = cimg_option("-band",5.0f,"Size of the narrow band");
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const bool both = cimg_option("-both",false,"Show both evolving and initial surface");
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// Define the signed distance map of the initial surface.
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CImg<> img;
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if (file_i) {
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const float sigma = cimg_option("-sigma",1.2f,"Segmentation regularity");
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const float alpha = cimg_option("-alpha",5.0f,"Region growing tolerance");
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img.load(file_i).channel(0);
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CImg<int> s;
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CImgDisplay disp(img,"Please select a starting point");
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while (!s || s[0]<0) s = img.get_select(0,disp);
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CImg<> region;
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float tmp[] = { 0 };
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img.draw_fill(s[0],s[1],s[2],tmp,1,region,alpha);
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((img = region.normalize(-1,1))*=-1).blur(sigma);
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}
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else { // Create synthetic implicit function
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img.assign(60,60,60);
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const float exte[] = { 1 }, inte[] = { -1 };
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img.fill(*exte).draw_rectangle(15,15,15,45,45,45,inte).draw_rectangle(25,25,0,35,35,img.depth() - 1,exte).
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draw_rectangle(0,25,25,img.width() - 1,35,35,exte).draw_rectangle(25,0,25,35,img.height() - 1,35,exte).noise(0.7);
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}
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img.distance_eikonal(10,0,0.1f);
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// Compute corresponding surface triangularization by the marching cube algorithm (isovalue 0).
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CImg<> points0;
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CImgList<unsigned int> faces0;
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if (both) points0 = img.get_isosurface3d(faces0,0);
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const CImgList<unsigned char> colors0(faces0.size(),CImg<unsigned char>::vector(100,200,255));
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const CImgList<> opacities0(faces0.size(),1,1,1,1,0.2f);
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// Perform MCF evolution.
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CImgDisplay disp(256,256,0,1), disp3d(512,512,0,0);
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float alpha = 0, beta = 0;
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for (unsigned int iteration = 0; !disp.is_closed() && !disp3d.is_closed() &&
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!disp.is_keyESC() && !disp3d.is_keyESC() && !disp.is_keyQ() && !disp3d.is_keyQ(); ++iteration) {
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disp.set_title("3D implicit Function (iter. %u)",iteration);
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disp3d.set_title("Mean curvature flow 3D - Isosurface (iter. %u)",iteration);
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// Apply PDE on the distance function.
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mcf_PDE(img,1,dt,narrow); // Do one iteration of mean curvature flow
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// Every 10 steps, do one iteration of distance function re-initialization.
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if (!(iteration%10)) img.distance_eikonal(1,narrow,0.5f);
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// Compute surface triangularization by the marching cube algorithm (isovalue 0)
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CImgList<unsigned int> faces;
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CImg<> points = img.get_isosurface3d(faces,0);
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CImgList<unsigned char> colors(faces.size(),CImg<unsigned char>::vector(200,128,100));
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CImgList<> opacities(faces.size(),CImg<>::vector(1.0f));
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const float fact = 3*std::max(disp3d.width(),disp3d.height())/(4.0f*std::max(img.width(),img.height()));
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// Append initial object if necessary.
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if (both) {
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points.append_object3d(faces,points0,faces0);
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colors.insert(colors0);
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opacities.insert(opacities0);
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}
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// Center and rescale the objects
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cimg_forX(points,l) {
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points(l,0)=(points(l,0) - img.width()/2)*fact;
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points(l,1)=(points(l,1) - img.height()/2)*fact;
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points(l,2)=(points(l,2) - img.depth()/2)*fact;
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}
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// Display 3D object on the display window.
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CImg<unsigned char> visu(disp3d.width(),disp3d.height(),1,3,0);
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const CImg<> rot = CImg<>::rotation_matrix(1,0,0,(beta+=0.5f))*CImg<>::rotation_matrix(0,1,1,(alpha+=3));
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if (points.size()) {
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visu.draw_object3d(visu.width()/2.0f,visu.height()/2.0f,0.0f,
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rot*points,faces,colors,opacities,3,
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false,500.0,0.0f,0.0f,-8000.0f).display(disp3d);
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} else visu.fill(0).display(disp3d);
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img.display(disp.wait(20));
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if ((disp3d.button() || disp3d.key()) && points.size() && !disp3d.is_keyESC() && !disp3d.is_keyQ()) {
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const unsigned char white[3] = { 255, 255, 255 };
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visu.fill(0).draw_text(10,10,"Time stopped, press any key to start again",white).
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display_object3d(disp3d,points,faces,colors,opacities,true,4,3,false,500,0,0,-5000,0.4f,0.3f);
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disp3d.set_key();
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}
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if (disp.is_resized()) disp.resize(false);
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if (disp3d.is_resized()) disp3d.resize(false);
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disp.wait(50);
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}
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return 0;
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}
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