319 lines
15 KiB
C++
319 lines
15 KiB
C++
/****************************************************************************
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* VCGLib o o *
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* Visual and Computer Graphics Library o o *
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* _ O _ *
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* Copyright(C) 2004-2016 \/)\/ *
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* Visual Computing Lab /\/| *
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* ISTI - Italian National Research Council | *
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* \ *
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* All rights reserved. *
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* *
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* This program is free software; you can redistribute it and/or modify *
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* it under the terms of the GNU General Public License as published by *
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* the Free Software Foundation; either version 2 of the License, or *
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* (at your option) any later version. *
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* *
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* This program is distributed in the hope that it will be useful, *
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* but WITHOUT ANY WARRANTY; without even the implied warranty of *
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* MERCHANTABILITY or FITNESS FOR A PARTICULAR PURPOSE. See the *
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* GNU General Public License (http://www.gnu.org/licenses/gpl.txt) *
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* for more details. *
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* *
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****************************************************************************/
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// standard libraries
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#include <time.h>
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#include <vcg/math/histogram.h>
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#include <vcg/complex/complex.h>
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#include <wrap/io_trimesh/import.h>
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#include <wrap/io_trimesh/export.h>
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#include <vcg/simplex/face/component_ep.h>
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#include <vcg/complex/algorithms/update/component_ep.h>
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#include <vcg/complex/algorithms/update/bounding.h>
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#include "sampling.h"
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using namespace std;
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// project definitions.
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// error messages
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#define MSG_ERR_MESH_LOAD "error loading the input meshes.\n"
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#define MSG_ERR_INVALID_OPTION "unable to parse option '%s'\n"
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#define MSG_ERR_FILE_OPEN "unable to open the output file.'n"
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#define MSG_ERR_UNKNOWN_FORMAT "unknown file format '%s'.\n"
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// global constants
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#define NO_SAMPLES_PER_FACE 10
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#define N_SAMPLES_EDGE_TO_FACE_RATIO 0.1
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#define BBOX_FACTOR 0.1
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#define INFLATE_PERCENTAGE 0.02
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#define MIN_SIZE 125 /* 125 = 5^3 */
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#define N_HIST_BINS 256
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#define PRINT_EVERY_N_ELEMENTS 1000
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class CFace;
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class CVertex;
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struct UsedTypes:public vcg::UsedTypes< vcg::Use<CFace>::AsFaceType, vcg::Use<CVertex>::AsVertexType>{};
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class CVertex : public vcg::Vertex<UsedTypes,vcg::vertex::Coord3d,vcg::vertex::Qualityf,vcg::vertex::Normal3d,vcg::vertex::Color4b,vcg::vertex::BitFlags> {};
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class CFace : public vcg::Face< UsedTypes,vcg::face::VertexRef, vcg::face::Normal3d, vcg::face::EdgePlane,vcg::face::Color4b,vcg::face::Mark,vcg::face::BitFlags> {};
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class CMesh : public vcg::tri::TriMesh< std::vector<CVertex>, std::vector<CFace> > {};
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// -----------------------------------------------------------------------------------------------
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using namespace vcg;
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////////////////// Command line Flags and parameters
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bool NumberOfSamples = false;
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bool SamplesPerAreaUnit = false;
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bool CleaningFlag=false;
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// -----------------------------------------------------------------------------------------------
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void Usage()
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{
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printf("\nUsage: "\
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"metro file1 file2 [opt]\n"\
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"Where opt can be:\n"\
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" -v disable vertex sampling\n"\
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" -e disable edge sampling\n"\
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" -f disable face sampling\n"\
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" -u ignore unreferred vertices\n"\
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" -sx set the face sampling mode\n"\
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" where x can be:\n"\
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" -s0 montecarlo sampling\n"\
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" -s1 subdivision sampling\n"\
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" -s2 similar triangles sampling (Default)\n"\
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" -n# set the required number of samples (overrides -A)\n"\
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" -a# set the required number of samples per area unit (overrides -N)\n"\
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" -c save a mesh with error as per-vertex colour and quality\n"\
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" -C # # Set the min/max values used for color mapping\n"\
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" -L Remove duplicated and unreferenced vertices before processing\n"\
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" -h write files with histograms of error distribution\n"\
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" -G Use a static Uniform Grid as Search Structure (default)\n"\
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" -O Use an octree as a Search Structure\n"\
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" -A Use an AxisAligned Bounding Box Tree as Search Structure\n"\
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" -H Use an Hashed Uniform Grid as Search Structure\n"\
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"\n"
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"Default options are to sample vertexes, edge and faces by taking \n"
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"a number of samples that is approx. 10x the face number.\n"
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);
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exit(-1);
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}
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// simple aux function that compute the name for the file containing the stored computations
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std::string SaveFileName(const std::string &filename)
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{
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int pos=filename.find_last_of('.',filename.length());
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std::string fileout=filename.substr(0,pos)+"_metro.ply";
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return fileout;
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}
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// Open Mesh
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void OpenMesh(const char *filename, CMesh &m)
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{
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int err = tri::io::Importer<CMesh>::Open(m,filename);
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if(err) {
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printf("Error in reading %s: '%s'\n",filename,tri::io::Importer<CMesh>::ErrorMsg(err));
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if(tri::io::Importer<CMesh>::ErrorCritical(err)) exit(-1);
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}
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printf("read mesh `%s'\n", filename);
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if(CleaningFlag){
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int dup = tri::Clean<CMesh>::RemoveDuplicateVertex(m);
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int unref = tri::Clean<CMesh>::RemoveUnreferencedVertex(m);
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printf("Removed %i duplicate and %i unreferenced vertices from mesh %s\n",dup,unref,filename);
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}
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}
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int main(int argc, char**argv)
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{
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CMesh S1, S2;
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float ColorMin=0, ColorMax=0;
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double dist1_max, dist2_max;
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unsigned long n_samples_target, elapsed_time;
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double n_samples_per_area_unit;
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int flags;
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// print program info
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printf("-------------------------------\n"
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" Metro V.4.07 \n"
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" http://vcg.isti.cnr.it\n"
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" release date: " __DATE__ "\n"
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"-------------------------------\n\n");
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if(argc <= 2) Usage();
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// default parameters
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flags = SamplingFlags::VERTEX_SAMPLING |
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SamplingFlags::EDGE_SAMPLING |
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SamplingFlags::FACE_SAMPLING |
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SamplingFlags::SIMILAR_SAMPLING;
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// parse command line.
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for(int i=3; i < argc;)
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{
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if(argv[i][0]=='-')
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switch(argv[i][1])
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{
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case 'h' : flags |= SamplingFlags::HIST; break;
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case 'v' : flags &= ~SamplingFlags::VERTEX_SAMPLING; break;
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case 'e' : flags &= ~SamplingFlags::EDGE_SAMPLING; break;
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case 'f' : flags &= ~SamplingFlags::FACE_SAMPLING; break;
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case 'u' : flags |= SamplingFlags::INCLUDE_UNREFERENCED_VERTICES; break;
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case 's' :
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switch(argv[i][2])
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{
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case '0': flags = (flags | SamplingFlags::MONTECARLO_SAMPLING ) & (~ SamplingFlags::NO_SAMPLING );break;
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case '1': flags = (flags | SamplingFlags::SUBDIVISION_SAMPLING ) & (~ SamplingFlags::NO_SAMPLING );break;
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case '2': flags = (flags | SamplingFlags::SIMILAR_SAMPLING ) & (~ SamplingFlags::NO_SAMPLING );break;
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default : printf(MSG_ERR_INVALID_OPTION, argv[i]);
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exit(0);
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}
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break;
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case 'n': NumberOfSamples = true; n_samples_target = (unsigned long) atoi(&(argv[i][2])); break;
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case 'a': SamplesPerAreaUnit = true; n_samples_per_area_unit = (unsigned long) atoi(&(argv[i][2])); break;
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case 'c': flags |= SamplingFlags::SAVE_ERROR; break;
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case 'L': CleaningFlag=true; break;
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case 'C': ColorMin=float(atof(argv[i+1])); ColorMax=float(atof(argv[i+2])); i+=2; break;
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case 'A': flags |= SamplingFlags::USE_AABB_TREE; printf("Using AABB Tree as search structure\n"); break;
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case 'G': flags |= SamplingFlags::USE_STATIC_GRID; printf("Using static uniform grid as search structure\n"); break;
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case 'H': flags |= SamplingFlags::USE_HASH_GRID; printf("Using hashed uniform grid as search structure\n"); break;
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case 'O': flags |= SamplingFlags::USE_OCTREE; printf("Using octree as search structure\n"); break;
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default : printf(MSG_ERR_INVALID_OPTION, argv[i]);
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exit(0);
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}
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i++;
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}
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if(!(flags & SamplingFlags::USE_HASH_GRID) && !(flags & SamplingFlags::USE_AABB_TREE) && !(flags & SamplingFlags::USE_OCTREE))
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flags |= SamplingFlags::USE_STATIC_GRID;
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// load input meshes.
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OpenMesh(argv[1],S1);
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OpenMesh(argv[2],S2);
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string S1NewName=SaveFileName(argv[1]);
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string S2NewName=SaveFileName(argv[2]);
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if(!NumberOfSamples && !SamplesPerAreaUnit)
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{
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NumberOfSamples = true;
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n_samples_target = 10 * max(S1.fn,S2.fn);// take 10 samples per face
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}
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// compute face information
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tri::UpdateComponentEP<CMesh>::Set(S1);
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tri::UpdateComponentEP<CMesh>::Set(S2);
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// set bounding boxes for S1 and S2
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tri::UpdateBounding<CMesh>::Box(S1);
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tri::UpdateBounding<CMesh>::Box(S2);
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// set Bounding Box.
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Box3<CMesh::ScalarType> bbox, tmp_bbox_M1=S1.bbox, tmp_bbox_M2=S2.bbox;
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bbox.Add(S1.bbox);
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bbox.Add(S2.bbox);
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bbox.Offset(bbox.Diag()*0.02);
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S1.bbox = bbox;
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S2.bbox = bbox;
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// initialize time info.
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int t0=clock();
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Sampling<CMesh> ForwardSampling(S1,S2);
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Sampling<CMesh> BackwardSampling(S2,S1);
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// print mesh info.
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printf("Mesh info:\n");
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printf(" M1: '%s'\n\tvertices %7i\n\tfaces %7i\n\tarea %12.4f\n", argv[1], S1.vn, S1.fn, ForwardSampling.GetArea());
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printf("\tbbox (%7.4f %7.4f %7.4f)-(%7.4f %7.4f %7.4f)\n", tmp_bbox_M1.min[0], tmp_bbox_M1.min[1], tmp_bbox_M1.min[2], tmp_bbox_M1.max[0], tmp_bbox_M1.max[1], tmp_bbox_M1.max[2]);
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printf("\tbbox diagonal %f\n", (float)tmp_bbox_M1.Diag());
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printf(" M2: '%s'\n\tvertices %7i\n\tfaces %7i\n\tarea %12.4f\n", argv[2], S2.vn, S2.fn, BackwardSampling.GetArea());
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printf("\tbbox (%7.4f %7.4f %7.4f)-(%7.4f %7.4f %7.4f)\n", tmp_bbox_M2.min[0], tmp_bbox_M2.min[1], tmp_bbox_M2.min[2], tmp_bbox_M2.max[0], tmp_bbox_M2.max[1], tmp_bbox_M2.max[2]);
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printf("\tbbox diagonal %f\n", (float)tmp_bbox_M2.Diag());
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// Forward distance.
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printf("\nForward distance (M1 -> M2):\n");
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ForwardSampling.SetFlags(flags);
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if(NumberOfSamples)
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{
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ForwardSampling.SetSamplesTarget(n_samples_target);
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n_samples_per_area_unit = ForwardSampling.GetNSamplesPerAreaUnit();
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}
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else
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{
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ForwardSampling.SetSamplesPerAreaUnit(n_samples_per_area_unit);
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n_samples_target = ForwardSampling.GetNSamplesTarget();
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}
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printf("target # samples : %lu\ntarget # samples/area : %f\n", n_samples_target, n_samples_per_area_unit);
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ForwardSampling.Hausdorff();
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dist1_max = ForwardSampling.GetDistMax();
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printf("\ndistances:\n max : %f (%f wrt bounding box diagonal)\n", (float)dist1_max, (float)dist1_max/bbox.Diag());
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printf(" mean : %f\n", ForwardSampling.GetDistMean());
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printf(" RMS : %f\n", ForwardSampling.GetDistRMS());
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printf("# vertex samples %9lu\n", ForwardSampling.GetNVertexSamples());
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printf("# edge samples %9lu\n", ForwardSampling.GetNEdgeSamples());
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printf("# area samples %9lu\n", ForwardSampling.GetNAreaSamples());
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printf("# total samples %9lu\n", ForwardSampling.GetNSamples());
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printf("# samples per area unit: %f\n\n", ForwardSampling.GetNSamplesPerAreaUnit());
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// Backward distance.
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printf("\nBackward distance (M2 -> M1):\n");
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BackwardSampling.SetFlags(flags);
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if(NumberOfSamples)
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{
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BackwardSampling.SetSamplesTarget(n_samples_target);
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n_samples_per_area_unit = BackwardSampling.GetNSamplesPerAreaUnit();
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}
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else
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{
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BackwardSampling.SetSamplesPerAreaUnit(n_samples_per_area_unit);
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n_samples_target = BackwardSampling.GetNSamplesTarget();
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}
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printf("target # samples : %lu\ntarget # samples/area : %f\n", n_samples_target, n_samples_per_area_unit);
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BackwardSampling.Hausdorff();
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dist2_max = BackwardSampling.GetDistMax();
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printf("\ndistances:\n max : %f (%f wrt bounding box diagonal)\n", (float)dist2_max, (float)dist2_max/bbox.Diag());
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printf(" mean : %f\n", BackwardSampling.GetDistMean());
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printf(" RMS : %f\n", BackwardSampling.GetDistRMS());
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printf("# vertex samples %9lu\n", BackwardSampling.GetNVertexSamples());
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printf("# edge samples %9lu\n", BackwardSampling.GetNEdgeSamples());
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printf("# area samples %9lu\n", BackwardSampling.GetNAreaSamples());
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printf("# total samples %9lu\n", BackwardSampling.GetNSamples());
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printf("# samples per area unit: %f\n\n", BackwardSampling.GetNSamplesPerAreaUnit());
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// compute time info.
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elapsed_time = clock() - t0;
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int n_total_sample=ForwardSampling.GetNSamples()+BackwardSampling.GetNSamples();
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double mesh_dist_max = max(dist1_max , dist2_max);
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printf("\nHausdorff distance: %f (%f wrt bounding box diagonal)\n",(float)mesh_dist_max,(float)mesh_dist_max/bbox.Diag());
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printf(" Computation time : %d ms\n",(int)(1000.0*elapsed_time/CLOCKS_PER_SEC));
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printf(" # samples/second : %f\n\n", (float)n_total_sample/((float)elapsed_time/CLOCKS_PER_SEC));
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// save error files.
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if(flags & SamplingFlags::SAVE_ERROR)
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{
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int saveMask = vcg::tri::io::Mask::IOM_VERTCOLOR | vcg::tri::io::Mask::IOM_VERTQUALITY /* | vcg::ply::PLYMask::PM_VERTQUALITY*/ ;
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//p.mask|=vcg::ply::PLYMask::PM_VERTCOLOR|vcg::ply::PLYMask::PM_VERTQUALITY;
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if(ColorMax!=0 || ColorMin != 0){
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vcg::tri::UpdateColor<CMesh>::PerVertexQualityRamp(S1,ColorMin,ColorMax);
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vcg::tri::UpdateColor<CMesh>::PerVertexQualityRamp(S2,ColorMin,ColorMax);
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}
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tri::io::ExporterPLY<CMesh>::Save( S1,S1NewName.c_str(),saveMask);
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tri::io::ExporterPLY<CMesh>::Save( S2,S2NewName.c_str(),saveMask);
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}
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// save error files.
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if(flags & SamplingFlags::HIST)
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{
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ForwardSampling.GetHist().FileWrite("forward_result.csv");
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BackwardSampling.GetHist().FileWrite("backward_result.csv");
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}
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return 0;
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}
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// -----------------------------------------------------------------------------------------------
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