4.7/Surface_mesh_parameterization/Surface_mesh_parameterization_2polyhedron_ex_parameterization_8cpp-example.html

// ----------------------------------------------------------------------------

// USAGE EXAMPLES

// ----------------------------------------------------------------------------


//----------------------------------------------------------

// Discrete Conformal Map parameterization

// circle border

// OpenNL solver

// output is a eps map

// input file is mesh.off

//----------------------------------------------------------

// polyhedron_ex_parameterization -t conformal -b circle mesh.off mesh.eps


//----------------------------------------------------------

// Least Squares Conformal Maps parameterization

// two pinned vertices (automatically picked)

// OpenNL solver

// output is a .obj

// input file is mesh.off

//----------------------------------------------------------

// polyhedron_ex_parameterization -t lscm -b 2pts mesh.off mesh.obj


#include <CGAL/Timer.h>

#include <CGAL/parameterize.h>

#include <CGAL/Parameterization_mesh_patch_3.h>

#include <CGAL/Circular_border_parameterizer_3.h>

#include <CGAL/Square_border_parameterizer_3.h>

#include <CGAL/Two_vertices_parameterizer_3.h>

#include <CGAL/Barycentric_mapping_parameterizer_3.h>

#include <CGAL/Discrete_conformal_map_parameterizer_3.h>

#include <CGAL/Discrete_authalic_parameterizer_3.h>

#include <CGAL/Mean_value_coordinates_parameterizer_3.h>

#include <CGAL/LSCM_parameterizer_3.h>

#include <CGAL/Parameterization_mesh_feature_extractor.h>


#include <CGAL/OpenNL/linear_solver.h>


#include "Polyhedron_ex.h"

#include "Mesh_cutter.h"

#include "Parameterization_polyhedron_adaptor_ex.h"


#include <iostream>

#include <string.h>

#include <ctype.h>

#include <fstream>

#include <cassert>


#ifdef CGAL_USE_BOOST_PROGRAM_OPTIONS

    #include <boost/program_options.hpp>

    namespace po = boost::program_options;

#endif


// ----------------------------------------------------------------------------

// Private types

// ----------------------------------------------------------------------------


typedef Polyhedron_ex                                       Polyhedron;


// Mesh adaptors

typedef Parameterization_polyhedron_adaptor_ex              Parameterization_polyhedron_adaptor;

typedef CGAL::Parameterization_mesh_patch_3<Parameterization_polyhedron_adaptor>

                                                            Mesh_patch_polyhedron;


// Type describing a border or seam as a vertex list

typedef std::list<Parameterization_polyhedron_adaptor::Vertex_handle>

                                                            Seam;


// ----------------------------------------------------------------------------

// Private functions

// ----------------------------------------------------------------------------


// Cut the mesh to make it homeomorphic to a disk

// or extract a region homeomorphic to a disc.

// Return the border of this region (empty on error)

//

// CAUTION:

// This method is provided "as is". It is very buggy and simply part of this example.

// Developers using this package should implement a more robust cut algorithm!

static Seam cut_mesh(Parameterization_polyhedron_adaptor& mesh_adaptor)

{

    // Helper class to compute genus or extract borders

    typedef CGAL::Parameterization_mesh_feature_extractor<Parameterization_polyhedron_adaptor_ex>

                                            Mesh_feature_extractor;

    typedef Mesh_cutter::Backbone           Backbone;


    Seam seam;              // returned list


    // Get refererence to Polyhedron_3 mesh

    Polyhedron& mesh = mesh_adaptor.get_adapted_mesh();


    // Extract mesh borders and compute genus

    Mesh_feature_extractor feature_extractor(mesh_adaptor);

    int nb_borders = feature_extractor.get_nb_borders();

    int genus = feature_extractor.get_genus();


    // If mesh is a topological disk

    if (genus == 0 && nb_borders > 0)

    {

        // Pick the longest border

        seam = feature_extractor.get_longest_border();

    }

    else // if mesh is *not* a topological disk, create a virtual cut

    {

        Backbone seamingBackbone;           // result of cutting

        Backbone::iterator he;


        // Compute a cutting path that makes the mesh a "virtual" topological disk

        mesh.compute_facet_centers();

        Mesh_cutter cutter(mesh);

        if (genus == 0)

        {

            // no border, we need to cut the mesh

            assert (nb_borders == 0);

            cutter.cut(seamingBackbone);    // simple cut

        }

        else // genus > 0 -> cut the mesh

        {

            cutter.cut_genus(seamingBackbone);

        }


        // The Mesh_cutter class is quite buggy

        // => we check that seamingBackbone is valid

        //

        // 1) Check that seamingBackbone is not empty

        if (seamingBackbone.begin() == seamingBackbone.end())

            return seam;                    // return empty list

        //

        // 2) Check that seamingBackbone is a loop and

        //    count occurences of seam halfedges

        mesh.tag_halfedges(0);              // Reset counters

        for (he = seamingBackbone.begin(); he != seamingBackbone.end(); he++)

        {

            // Get next halfedge iterator (looping)

            Backbone::iterator next_he = he;

            next_he++;

            if (next_he == seamingBackbone.end())

                next_he = seamingBackbone.begin();


            // Check that seamingBackbone is a loop: check that

            // end of current HE == start of next one

            if ((*he)->vertex() != (*next_he)->opposite()->vertex())

                return seam;                // return empty list


            // Increment counter (in "tag" field) of seam halfedges

            (*he)->tag( (*he)->tag()+1 );

        }

        //

        // 3) check that the seamingBackbone is a two-way list

        for (he = seamingBackbone.begin(); he != seamingBackbone.end(); he++)

        {

            // Counter of halfedge and opposite halfedge must be 1

            if ((*he)->tag() != 1 || (*he)->opposite()->tag() != 1)

                return seam;                // return empty list

        }


        // Convert list of halfedges to a list of vertices

        for (he = seamingBackbone.begin(); he != seamingBackbone.end(); he++)

            seam.push_back((*he)->vertex());

    }


    return seam;

}


// Call appropriate parameterization method based on command line parameters

template<

    class ParameterizationMesh_3,   // 3D surface

    class GeneralSparseLinearAlgebraTraits_d,

                                    // Traits class to solve a general sparse linear system

    class SymmetricSparseLinearAlgebraTraits_d

                                    // Traits class to solve a symmetric sparse linear system

>

typename CGAL::Parameterizer_traits_3<ParameterizationMesh_3>::Error_code

parameterize(ParameterizationMesh_3& mesh,  // Mesh parameterization adaptor

             const std::string& type,              // type of parameterization (see usage)

             const std::string& border)            // type of border parameterization (see usage)

{

    typename CGAL::Parameterizer_traits_3<ParameterizationMesh_3>::Error_code err;


    if ( (type == std::string("floater"))  && (border == std::string("circle")) )

    {

        err = CGAL::parameterize(

            mesh,

            CGAL::Mean_value_coordinates_parameterizer_3<

                ParameterizationMesh_3,

                CGAL::Circular_border_arc_length_parameterizer_3<ParameterizationMesh_3>,

                GeneralSparseLinearAlgebraTraits_d

            >());

    }

    else if ( (type == std::string("floater")) && (border == std::string("square")) )

    {

        err = CGAL::parameterize(

            mesh,

            CGAL::Mean_value_coordinates_parameterizer_3<

                ParameterizationMesh_3,

                CGAL::Square_border_arc_length_parameterizer_3<ParameterizationMesh_3>,

                GeneralSparseLinearAlgebraTraits_d

            >());

    }

    else if ( (type == std::string("barycentric")) && (border == std::string("circle")) )

    {

        err = CGAL::parameterize(

            mesh,

            CGAL::Barycentric_mapping_parameterizer_3<

                ParameterizationMesh_3,

                CGAL::Circular_border_uniform_parameterizer_3<ParameterizationMesh_3>,

                GeneralSparseLinearAlgebraTraits_d

            >());

    }

    else if ( (type == std::string("barycentric")) && (border == std::string("square")) )

    {

        err = CGAL::parameterize(

            mesh,

            CGAL::Barycentric_mapping_parameterizer_3<

                ParameterizationMesh_3,

                CGAL::Square_border_uniform_parameterizer_3<ParameterizationMesh_3>,

                GeneralSparseLinearAlgebraTraits_d

            >());

    }

    else if ( (type == std::string("conformal")) && (border == std::string("circle")) )

    {

        err = CGAL::parameterize(

            mesh,

            CGAL::Discrete_conformal_map_parameterizer_3<

                ParameterizationMesh_3,

                CGAL::Circular_border_arc_length_parameterizer_3<ParameterizationMesh_3>,

                GeneralSparseLinearAlgebraTraits_d

            >());

    }

    else if ( (type == std::string("conformal")) && (border == std::string("square")) )

    {

        err = CGAL::parameterize(

            mesh,

            CGAL::Discrete_conformal_map_parameterizer_3<

                ParameterizationMesh_3,

                CGAL::Square_border_arc_length_parameterizer_3<ParameterizationMesh_3>,

                GeneralSparseLinearAlgebraTraits_d

            >());

    }

    else if ( (type == std::string("authalic")) && (border == std::string("circle")) )

    {

        err = CGAL::parameterize(

            mesh,

            CGAL::Discrete_authalic_parameterizer_3<

                ParameterizationMesh_3,

                CGAL::Circular_border_arc_length_parameterizer_3<ParameterizationMesh_3>,

                GeneralSparseLinearAlgebraTraits_d

            >());

    }

    else if ( (type == std::string("authalic")) && (border == std::string("square")) )

    {

        err = CGAL::parameterize(

            mesh,

            CGAL::Discrete_authalic_parameterizer_3<

                ParameterizationMesh_3,

                CGAL::Square_border_arc_length_parameterizer_3<ParameterizationMesh_3>,

                GeneralSparseLinearAlgebraTraits_d

            >());

    }

    else if ( (type == std::string("lscm")) && (border == std::string("2pts")) )

    {

        err = CGAL::parameterize(

            mesh,

            CGAL::LSCM_parameterizer_3<

                ParameterizationMesh_3,

                CGAL::Two_vertices_parameterizer_3<ParameterizationMesh_3>,

                SymmetricSparseLinearAlgebraTraits_d

            >());

    }

    else

    {

        std::cerr << "Error: invalid parameters combination " << type << " + " << border << std::endl;

        err = CGAL::Parameterizer_traits_3<ParameterizationMesh_3>::ERROR_WRONG_PARAMETER;

    }


    return err;

}


// ----------------------------------------------------------------------------

// main()

// ----------------------------------------------------------------------------


#ifdef CGAL_USE_BOOST_PROGRAM_OPTIONS

int main(int argc, char * argv[])

#else

int main()

#endif

{

    CGAL::Timer total_timer;

    total_timer.start();


    std::cerr << "PARAMETERIZATION" << std::endl;


    //***************************************

    // Read options on the command line

    //***************************************


    std::string type;               // default: Floater param

    std::string border;             // default: circular border param.

    std::string solver;             // default: OpenNL solver

    std::string input;              // required

    std::string output;             // default: out.eps

    try

    {

#ifdef CGAL_USE_BOOST_PROGRAM_OPTIONS

        po::options_description desc("Allowed options");

        desc.add_options()

            ("help,h", "prints this help message")

            ("type,t", po::value<std::string>(&type)->default_value("floater"),

            "parameterization method: floater, conformal, barycentric, authalic or lscm")

            ("border,b", po::value<std::string>(&border)->default_value("circle"),

            "border shape: circle, square or 2pts (lscm only)")

            ("solver,s", po::value<std::string>(&solver)->default_value("opennl"),

            "solver: opennl")

            ("input,i", po::value<std::string>(&input)->default_value(""),

            "input mesh (OFF)")

            ("output,o", po::value<std::string>(&output)->default_value("out.eps"),

            "output file (EPS or OBJ)")

            ;


        po::positional_options_description p;

        p.add("input", 1);

        p.add("output", 1);


        po::variables_map vm;

        po::store(po::command_line_parser(argc, argv).options(desc).positional(p).run(), vm);

        po::notify(vm);


        if (vm.count("help")) {

            std::cout << desc << "\n";

            return 1;

        }

#else

        std::cerr << "Command-line options require Boost.ProgramOptions" << std::endl;

        std::cerr << "Use hard-coded options" << std::endl;

        border = "square";

        type = "floater";

        solver = "opennl";

        input = "data/rotor.off";

        output = "rotor_floater_square_opennl_parameterized.obj";

#endif

    }

    catch(std::exception& e) {

      std::cerr << "error: " << e.what() << "\n";

      return 1;

    }

    catch(...) {

      std::cerr << "Exception of unknown type!\n";

      throw;

    }


    //***************************************

    // Read the mesh

    //***************************************


    CGAL::Timer task_timer;

    task_timer.start();


    // Read the mesh

    std::ifstream stream(input.c_str());

    Polyhedron mesh;

    stream >> mesh;

    if(!stream || !mesh.is_valid() || mesh.empty())

    {

        std::cerr << "Error: cannot read OFF file " << input << std::endl;

        return EXIT_FAILURE;

    }


    std::cerr << "Read file " << input << ": "

              << task_timer.time() << " seconds "

              << "(" << mesh.size_of_facets() << " facets, "

              << mesh.size_of_vertices() << " vertices)" << std::endl;

    task_timer.reset();


    //***************************************

    // Create mesh adaptor

    //***************************************


    // The Surface_mesh_parameterization package needs an adaptor to handle Polyhedron_ex meshes

    Parameterization_polyhedron_adaptor mesh_adaptor(mesh);


    // The parameterization methods support only meshes that

    // are topological disks => we need to compute a cutting path

    // that makes the mesh a "virtual" topological disk

    //

    // 1) Cut the mesh

    Seam seam = cut_mesh(mesh_adaptor);

    if (seam.empty())

    {

        std::cerr << "Input mesh not supported: the example cutting algorithm is too simple to cut this shape" << std::endl;

        return EXIT_FAILURE;

    }

    //

    // 2) Create adaptor that virtually "cuts" a patch in a Polyhedron_ex mesh

    Mesh_patch_polyhedron   mesh_patch(mesh_adaptor, seam.begin(), seam.end());

    if (!mesh_patch.is_valid())

    {

        std::cerr << "Input mesh not supported: non manifold shape or invalid cutting" << std::endl;

        return EXIT_FAILURE;

    }


    std::cerr << "Mesh cutting: " << task_timer.time() << " seconds." << std::endl;

    task_timer.reset();


    //***************************************

    // switch parameterization

    //***************************************


    std::cerr << "Parameterization..." << std::endl;


    // Defines the error codes

    typedef CGAL::Parameterizer_traits_3<Mesh_patch_polyhedron> Parameterizer;

    Parameterizer::Error_code err;


    if (solver == std::string("opennl"))

    {

        err = parameterize<Mesh_patch_polyhedron,

                           OpenNL::DefaultLinearSolverTraits<double>,

                           OpenNL::SymmetricLinearSolverTraits<double>

                          >(mesh_patch, type, border);

    }

    else

    {

        std::cerr << "Error: invalid solver parameter " << solver << std::endl;

        err = Parameterizer::ERROR_WRONG_PARAMETER;

    }


    // Report errors

    switch(err) {

    case Parameterizer::OK: // Success

        break;

    case Parameterizer::ERROR_EMPTY_MESH: // Input mesh not supported

    case Parameterizer::ERROR_NON_TRIANGULAR_MESH:

    case Parameterizer::ERROR_NO_TOPOLOGICAL_DISC:

    case Parameterizer::ERROR_BORDER_TOO_SHORT:

        std::cerr << "Input mesh not supported: " << Parameterizer::get_error_message(err) << std::endl;

        return EXIT_FAILURE;

        break;

    default: // Error

        std::cerr << "Error: " << Parameterizer::get_error_message(err) << std::endl;

        return EXIT_FAILURE;

        break;

    };


    std::cerr << "Parameterization: " << task_timer.time() << " seconds." << std::endl;

    task_timer.reset();


    //***************************************

    // Output

    //***************************************


    // get output file's extension

    std::string extension = output.substr(output.find_last_of('.'));


    // Save mesh

    if (extension == ".eps" || extension == ".EPS")

    {

        // write Postscript file

        if ( ! mesh.write_file_eps(output.c_str()) )

        {

            std::cerr << "Error: cannot write file " << output << std::endl;

            return EXIT_FAILURE;

        }

    }

    else if (extension == ".obj" || extension == ".OBJ")

    {

        // write Wavefront obj file

        if ( ! mesh.write_file_obj(output.c_str()) )

        {

            std::cerr << "Error: cannot write file " << output << std::endl;

            return EXIT_FAILURE;

        }

    }

    else

    {

        std::cerr << "Error: output format not supported" << output << std::endl;

        err = Parameterizer::ERROR_WRONG_PARAMETER;

        return EXIT_FAILURE;

    }


    std::cerr << "Write file " << output << ": "

              << task_timer.time() << " seconds " << std::endl;


    return EXIT_SUCCESS;

}