dust3d/thirdparty/cgal/CGAL-5.1/include/CGAL/Skin_surface_base_3.h

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// Copyright (c) 2005 Rijksuniversiteit Groningen (Netherlands)
// All rights reserved.
//
// This file is part of CGAL (www.cgal.org).
//
2020-10-13 12:44:25 +00:00
// $URL: https://github.com/CGAL/cgal/blob/v5.1/Skin_surface_3/include/CGAL/Skin_surface_base_3.h $
// $Id: Skin_surface_base_3.h 254d60f 2019-10-19T15:23:19+02:00 Sébastien Loriot
// SPDX-License-Identifier: GPL-3.0-or-later OR LicenseRef-Commercial
//
//
// Author(s) : Nico Kruithof <Nico@cs.rug.nl>
#ifndef CGAL_SKIN_SURFACE_BASE_3_H
#define CGAL_SKIN_SURFACE_BASE_3_H
#include <CGAL/license/Skin_surface_3.h>
#include <CGAL/Exact_predicates_exact_constructions_kernel.h>
#include <CGAL/Exact_predicates_inexact_constructions_kernel.h>
#include <CGAL/Simple_cartesian.h>
#include <CGAL/Regular_triangulation_3.h>
#include <boost/random/linear_congruential.hpp>
#include <boost/random/uniform_smallint.hpp>
#include <boost/random/variate_generator.hpp>
#include <boost/shared_ptr.hpp>
// Used for the triangulated mixed complex / Voronoi diagram
#include <CGAL/Triangulation_vertex_base_with_info_3.h>
#include <CGAL/Triangulation_cell_base_with_info_3.h>
#include <CGAL/Skin_surface_quadratic_surface_3.h>
// Skin surface mesher
#include <CGAL/Marching_tetrahedra_traits_skin_surface_3.h>
#include <CGAL/Skin_surface_marching_tetrahedra_observer_3.h>
// Skin surface subdivider
#include <CGAL/Skin_surface_refinement_policy_3.h>
#include <CGAL/subdivide_skin_surface_mesh_3.h>
#include <CGAL/internal/Has_nested_type_Bare_point.h>
#include <boost/mpl/if.hpp>
#include <boost/mpl/identity.hpp>
namespace CGAL {
template <class MixedComplexTraits_3>
class Skin_surface_base_3
{
typedef MixedComplexTraits_3 Gt;
typedef Skin_surface_base_3<Gt> Self;
public:
typedef MixedComplexTraits_3 Geometric_traits;
typedef typename Gt::Weighted_point_3 Weighted_point;
typedef typename boost::mpl::eval_if_c<
internal::Has_nested_type_Bare_point<Gt>::value,
typename internal::Bare_point_type<Gt>,
boost::mpl::identity<typename Gt::Point_3>
>::type Bare_point;
typedef typename Gt::FT FT;
// For normal
typedef typename Gt::Vector_3 Vector;
typedef Regular_triangulation_3<Gt> Regular;
private:
typedef Exact_predicates_inexact_constructions_kernel Filtered_kernel;
public:
typedef Skin_surface_quadratic_surface_3<Filtered_kernel> Quadratic_surface;
typedef typename Regular::Vertex_handle Vertex_handle;
typedef typename Regular::Edge Edge;
typedef typename Regular::Facet Facet;
typedef typename Regular::Facet_circulator Facet_circulator;
typedef typename Regular::Cell_handle Cell_handle;
typedef Triangulation_simplex_3<Regular> Simplex;
// pair of a del- and vor-simplex
typedef std::pair<Simplex,Simplex> Anchor_point;
private:
typedef typename Regular::Finite_vertices_iterator Finite_vertices_iterator;
typedef typename Regular::Finite_edges_iterator Finite_edges_iterator;
typedef typename Regular::Finite_facets_iterator Finite_facets_iterator;
typedef typename Regular::Finite_cells_iterator Finite_cells_iterator;
public:
typedef Anchor_point Vertex_info;
typedef std::pair<Simplex, boost::shared_ptr<Quadratic_surface> > Cell_info;
private:
// Triangulated_mixed_complex:
typedef CGAL::Exact_predicates_exact_constructions_kernel FK;
typedef Triangulation_vertex_base_with_info_3<Vertex_info, FK> Vb;
typedef Triangulation_cell_base_with_info_3<Cell_info, FK> Cb;
typedef Triangulation_data_structure_3<Vb,Cb> Tds;
public:
typedef Triangulation_3<FK, Tds> TMC;
typedef typename TMC::Geom_traits TMC_Geom_traits;
typedef typename TMC::Finite_vertices_iterator TMC_Vertex_iterator;
typedef typename TMC::Finite_cells_iterator TMC_Cell_iterator;
typedef typename TMC::Vertex_handle TMC_Vertex_handle;
typedef typename TMC::Cell_handle TMC_Cell_handle;
typedef typename TMC::Point TMC_Point;
// Constructor
template < class WP_iterator >
Skin_surface_base_3(WP_iterator begin, WP_iterator end, FT shrink,
bool grow_balls = true,
Gt gt_ = Gt(), bool _verbose = false);
template <class Polyhedron_3>
void mesh_surface_3(Polyhedron_3 &p) const;
template <class Polyhedron_3>
void subdivide_mesh_3(Polyhedron_3 &p) const;
// Access functions:
TMC &triangulated_mixed_complex();
const FT shrink_factor() const { return shrink; }
Geometric_traits &geometric_traits() const { return gt; }
// TMC &triangulated_mixed_complex() { return _tmc; }
Regular &regular() { return _regular; }
// Predicates and constructions
Sign sign(TMC_Vertex_handle vit) const;
Sign sign(const Bare_point &p,
const TMC_Cell_handle start = TMC_Cell_handle()) const;
Sign sign(const Bare_point &p,
const Cell_info &info) const;
// Uses inexact computations to compute the sign
Sign sign_inexact(const Bare_point &p,
const Cell_info &info) const;
void intersect(TMC_Cell_handle ch, int i, int j, Bare_point &p) const;
void intersect(Bare_point &p1, Bare_point &p2,
TMC_Cell_handle &s1, TMC_Cell_handle &s2,
Bare_point &p) const;
void intersect_with_transversal_segment(
Bare_point &p,
const TMC_Cell_handle &start = TMC_Cell_handle()) const;
template <class Gt2>
static
typename Skin_surface_base_3<Gt2>::Bare_point
get_weighted_circumcenter(const Simplex &s, Gt2 &traits);
Vector normal(const Bare_point &p, TMC_Cell_handle start = TMC_Cell_handle()) const;
template <class Gt2>
static
typename Skin_surface_base_3<Gt2>::Bare_point
get_anchor_point(const Anchor_point &anchor, Gt2 &traits);
private:
void construct_bounding_box();
template< class Traits >
Skin_surface_quadratic_surface_3<Traits>
construct_surface(const Simplex &sim,
const Traits &traits = typename Geometric_traits::Kernel()) const;
Sign compare(Cell_info &info, const Bare_point &p1, const Bare_point &p2) const;
Sign compare(Cell_info &info1, const Bare_point &p1,
Cell_info &info2, const Bare_point &p2) const;
TMC_Cell_handle locate_in_tmc(const Bare_point &p,
TMC_Cell_handle start = TMC_Cell_handle()) const;
private:
FT shrink;
Geometric_traits gt;
Regular _regular;
// Triangulated mixed complex or Voronoi diagram:
TMC _tmc;
bool verbose;
};
template <class MixedComplexTraits_3>
template < class WP_iterator >
Skin_surface_base_3<MixedComplexTraits_3>::
Skin_surface_base_3(WP_iterator begin, WP_iterator end, FT shrink_,
bool grow_balls,
Gt gt_, bool verbose_)
: shrink(shrink_), gt(gt_), verbose(verbose_)
{
gt.set_shrink(shrink);
CGAL_assertion(begin != end);
if (grow_balls) {
for (; begin != end; begin++) {
regular().insert(gt.construct_weighted_point_3_object()(gt.construct_point_3_object()(*begin), begin->weight()/shrink_factor()));
}
} else {
regular().insert(begin, end);
}
construct_bounding_box();
if (verbose) {
std::cerr << "Triangulation ready" << std::endl;
std::cerr << "Vertices: " << regular().number_of_vertices() << std::endl;
std::cerr << "Cells: " << regular().number_of_cells() << std::endl;
}
}
template <class MixedComplexTraits_3>
template <class Polyhedron_3>
void
Skin_surface_base_3<MixedComplexTraits_3>::
mesh_surface_3(Polyhedron_3 &p) const
{
typedef Polyhedron_3 Polyhedron;
typedef Marching_tetrahedra_traits_skin_surface_3<
Self,
TMC_Vertex_iterator,
TMC_Cell_iterator,
typename Polyhedron::HalfedgeDS> Traits;
typedef Skin_surface_marching_tetrahedra_observer_3<
TMC_Vertex_iterator,
TMC_Cell_iterator,
Polyhedron> Observer;
// Extract the coarse mesh using marching_tetrahedra
Traits marching_traits(*this);
Observer marching_observer;
marching_tetrahedra_3(_tmc.finite_vertices_begin(),
_tmc.finite_vertices_end(),
_tmc.finite_cells_begin(),
_tmc.finite_cells_end(),
p,
marching_traits,
marching_observer);
}
template <class MixedComplexTraits_3>
template <class Polyhedron_3>
void
Skin_surface_base_3<MixedComplexTraits_3>::
subdivide_mesh_3(Polyhedron_3 &p) const
{
typedef Skin_surface_refinement_policy_3<Self, Polyhedron_3> Policy;
typedef Skin_surface_sqrt3<Self, Polyhedron_3, Policy> Subdivider;
Policy policy(*this);
Subdivider subdivider(*this, p, policy);
subdivider.subdivide();
}
template <class MixedComplexTraits_3>
typename Skin_surface_base_3<MixedComplexTraits_3>::TMC &
Skin_surface_base_3<MixedComplexTraits_3>::
triangulated_mixed_complex() {
return _tmc;
}
template <class MixedComplexTraits_3>
typename Skin_surface_base_3<MixedComplexTraits_3>::Vector
Skin_surface_base_3<MixedComplexTraits_3>::
normal(const Bare_point &p, TMC_Cell_handle start) const
{
if (start == TMC_Cell_handle()) {
start = locate_in_tmc(p,start);
}
return start->info().second->gradient(p);
}
template <class MixedComplexTraits_3>
Sign
Skin_surface_base_3<MixedComplexTraits_3>::
sign(TMC_Vertex_handle vit) const
{
CGAL_assertion(!_tmc.is_infinite(vit));
TMC_Cell_handle ch = vit->cell();
if (_tmc.is_infinite(ch)) {
std::vector<TMC_Cell_handle> nbs;
_tmc.incident_cells(vit, std::back_inserter(nbs));
for (typename std::vector<TMC_Cell_handle>::iterator it = nbs.begin();
_tmc.is_infinite(ch) && (it != nbs.end());
it++) {
ch = *it;
}
}
CGAL_assertion(!_tmc.is_infinite(ch));
// don't use sign, since the point is constructed:
CGAL_BRANCH_PROFILER(std::string(" NGHK: failures/calls to : ") + std::string(CGAL_PRETTY_FUNCTION), tmp);
{
// Protection is outside the try block as VC8 has the CGAL_CFG_FPU_ROUNDING_MODE_UNWINDING_VC_BUG
Protect_FPU_rounding<true> P;
try
{
Sign result = vit->cell()->info().second->sign(vit->point());
if (is_certain(result))
return result;
}
catch (Uncertain_conversion_exception&) {}
}
CGAL_BRANCH_PROFILER_BRANCH(tmp);
Protect_FPU_rounding<false> P(CGAL_FE_TONEAREST);
typedef Exact_predicates_exact_constructions_kernel EK;
typedef Skin_surface_traits_3<EK> Exact_skin_surface_traits;
typedef Skin_surface_base_3<Exact_skin_surface_traits> Exact_skin_surface_base;
typedef typename Exact_skin_surface_base::Bare_point Exact_bare_point;
Exact_skin_surface_traits exact_traits(shrink_factor());
Exact_bare_point p_exact = get_anchor_point(vit->info(), exact_traits);
return construct_surface(vit->cell()->info().first, EK()).sign(p_exact);
}
template <class MixedComplexTraits_3>
Sign
Skin_surface_base_3<MixedComplexTraits_3>::
sign(const Bare_point &p, const TMC_Cell_handle start) const
{
if (start == TMC_Cell_handle()) {
return sign(p, locate_in_tmc(p,start)->info());
} else {
return sign(p, start->info());
}
}
template <class MixedComplexTraits_3>
Sign
Skin_surface_base_3<MixedComplexTraits_3>::
sign(const Bare_point &p, const Cell_info &info) const
{
CGAL_BRANCH_PROFILER(std::string(" NGHK: failures/calls to : ") + std::string(CGAL_PRETTY_FUNCTION), tmp);
{
Protect_FPU_rounding<true> P;
try
{
Sign result = sign_inexact(p,info);
if (is_certain(result))
return result;
}
catch (Uncertain_conversion_exception&) {}
}
CGAL_BRANCH_PROFILER_BRANCH(tmp);
Protect_FPU_rounding<false> P(CGAL_FE_TONEAREST);
return construct_surface(info.first,
Exact_predicates_exact_constructions_kernel()).sign(p);
}
template <class MixedComplexTraits_3>
Sign
Skin_surface_base_3<MixedComplexTraits_3>::
sign_inexact(const Bare_point &p, const Cell_info &info) const {
return info.second->sign(p);
}
template <class MixedComplexTraits_3>
void
Skin_surface_base_3<MixedComplexTraits_3>::
intersect(TMC_Cell_handle ch, int i, int j, Bare_point &p) const
{
Cartesian_converter<FK, Gt> converter;
Bare_point p1 = gt.construct_point_3_object()(converter(ch->vertex(i)->point()));
Bare_point p2 = gt.construct_point_3_object()(converter(ch->vertex(j)->point()));
return intersect(p1, p2, ch, ch, p);
}
template <class MixedComplexTraits_3>
void
Skin_surface_base_3<MixedComplexTraits_3>::
intersect(Bare_point &p1, Bare_point &p2,
TMC_Cell_handle &s1, TMC_Cell_handle &s2,
Bare_point &p) const
{
FT sq_dist = squared_distance(p1,p2);
// Use value to make the computation robust (endpoints near the surface)
if (compare(s1->info(), p1, s2->info(), p2) == LARGER) {
std::swap(p1, p2);
}
TMC_Cell_handle sp = s1;
while ((s1 != s2) && (sq_dist > 1e-8)) {
p = midpoint(p1, p2);
sp = locate_in_tmc(p, sp);
if (sign_inexact(p, sp->info()) == NEGATIVE) { p1 = p; s1 = sp; }
else { p2 = p; s2 = sp; }
sq_dist *= .25;
}
while (sq_dist > 1e-8) {
p = midpoint(p1, p2);
if (sign_inexact(p, s1->info()) == NEGATIVE) { p1 = p; }
else { p2 = p; }
sq_dist *= .25;
}
p = midpoint(p1, p2);
}
template <class MixedComplexTraits_3>
void
Skin_surface_base_3<MixedComplexTraits_3>::
intersect_with_transversal_segment(
Bare_point &p,
const TMC_Cell_handle &start) const
{
typedef typename Geometric_traits::Kernel::Plane_3 Plane;
typedef typename Geometric_traits::Kernel::Line_3 Line;
TMC_Cell_handle tet = start;
if (tet == TMC_Cell_handle()) {
tet = locate_in_tmc(p, tet);
}
// get transversal segment:
Bare_point p1, p2;
// Compute signs on vertices and sort them:
int nIn = 0;
int sortedV[4];
for (int i=0; i<4; i++) {
if (sign(tet->vertex(i))==POSITIVE) {
sortedV[nIn] = i; nIn++;
} else {
sortedV[3-i+nIn] = i;
}
}
Cartesian_converter<FK, typename Bare_point::R> converter;
Object obj;
Bare_point tet_pts[4];
for (int i=0; i<4; i++) {
tet_pts[i] = converter(tet->vertex(i)->point());
}
if (nIn==1) {
p1 = tet_pts[sortedV[0]];
obj = CGAL::intersection(Plane(tet_pts[sortedV[1]],
tet_pts[sortedV[2]],
tet_pts[sortedV[3]]),
Line(p1, p));
if ( !assign(p2, obj) ) {
CGAL_error_msg("intersection: no intersection.");
}
} else if (nIn==2) {
obj = CGAL::intersection(Plane(tet_pts[sortedV[2]],
tet_pts[sortedV[3]],
p),
Line(tet_pts[sortedV[0]],
tet_pts[sortedV[1]]));
if ( !assign(p1, obj) ) {
CGAL_error_msg("intersection: no intersection.");
}
obj = CGAL::intersection(Plane(tet_pts[sortedV[0]],
tet_pts[sortedV[1]],
p),
Line(tet_pts[sortedV[2]],
tet_pts[sortedV[3]]));
if ( !assign(p2, obj) ) {
CGAL_error_msg("intersection: no intersection.");
}
} else if (nIn==3) {
p2 = tet_pts[sortedV[3]];
obj = CGAL::intersection(Plane(tet_pts[sortedV[0]],
tet_pts[sortedV[1]],
tet_pts[sortedV[2]]),
Line(p2, p));
if ( !assign(p1, obj) ) {
CGAL_error_msg("intersection: no intersection.");
}
} else {
CGAL_error();
}
// Find the intersection:
intersect(p1, p2, tet, tet, p);
}
template <class MixedComplexTraits_3>
void
Skin_surface_base_3<MixedComplexTraits_3>::
construct_bounding_box()
{
typedef typename Regular::Finite_vertices_iterator Finite_vertices_iterator;
Finite_vertices_iterator vit = regular().finite_vertices_begin();
if (vit != regular().finite_vertices_end()) {
Bbox_3 bbox = vit->point().bbox();
FT max_weight=0;
for (;vit != regular().finite_vertices_end(); ++vit) {
bbox = bbox + vit->point().bbox();
if (max_weight < vit->point().weight()) {
max_weight = vit->point().weight();
}
}
// add a bounding octahedron:
FT dx = bbox.xmax() - bbox.xmin();
FT dy = bbox.ymax() - bbox.ymin();
FT dz = bbox.zmax() - bbox.zmin();
Bare_point mid(bbox.xmin() + dx/2,
bbox.ymin() + dy/2,
bbox.zmin() + dz/2);
FT dr =
(dx+dy+dz+sqrt(CGAL::to_double(max_weight))+.001) / gt.get_shrink();
Weighted_point wp;
wp = Weighted_point(Bare_point(mid.x()+dr,
mid.y(),
mid.z()),-1);
regular().insert(wp);
wp = Weighted_point(Bare_point(mid.x()-dr,
mid.y(),
mid.z()),-1);
regular().insert(wp);
wp = Weighted_point(Bare_point(mid.x(),
mid.y()+dr,
mid.z()),-1);
regular().insert(wp);
wp = Weighted_point(Bare_point(mid.x(),
mid.y()-dr,
mid.z()),-1);
regular().insert(wp);
wp = Weighted_point(Bare_point(mid.x(),
mid.y(),
mid.z()+dr),-1);
regular().insert(wp);
wp = Weighted_point(Bare_point(mid.x(),
mid.y(),
mid.z()-dr),-1);
regular().insert(wp);
}
}
template <class MixedComplexTraits_3>
template <class Gt2>
typename Skin_surface_base_3<Gt2>::Bare_point
Skin_surface_base_3<MixedComplexTraits_3>::
get_anchor_point(const Anchor_point &anchor, Gt2 &traits)
{
typename Skin_surface_base_3<Gt2>::Bare_point p_del, p_vor;
p_del = get_weighted_circumcenter(anchor.first, traits);
p_vor = get_weighted_circumcenter(anchor.second, traits);
return traits.construct_anchor_point_3_object()(p_del,p_vor);
}
template <class MixedComplexTraits_3>
template< class Traits >
Skin_surface_quadratic_surface_3<Traits>
Skin_surface_base_3<MixedComplexTraits_3>::
construct_surface(const Simplex &sim, const Traits &) const
{
typedef Skin_surface_quadratic_surface_3<Traits> Quadratic_surface;
typedef Cartesian_converter<typename Bare_point::R, Traits> Converter;
typedef typename Traits::Weighted_point_3 Weighted_point;
Converter conv;
switch (sim.dimension()) {
case 0: {
Vertex_handle vh = sim;
return Quadratic_surface(conv(vh->point()), shrink_factor());
}
case 1: {
Edge e = sim;
Weighted_point p0 = conv(e.first->vertex(e.second)->point());
Weighted_point p1 = conv(e.first->vertex(e.third)->point());
return Quadratic_surface(p0, p1, shrink_factor());
}
case 2: {
Facet f = sim;
Weighted_point p0 = conv(f.first->vertex((f.second+1)&3)->point());
Weighted_point p1 = conv(f.first->vertex((f.second+2)&3)->point());
Weighted_point p2 = conv(f.first->vertex((f.second+3)&3)->point());
return Quadratic_surface(p0,p1,p2, shrink_factor());
}
case 3: {
Cell_handle ch = sim;
Weighted_point p0 = conv(ch->vertex(0)->point());
Weighted_point p1 = conv(ch->vertex(1)->point());
Weighted_point p2 = conv(ch->vertex(2)->point());
Weighted_point p3 = conv(ch->vertex(3)->point());
return Quadratic_surface(p0,p1,p2,p3, shrink_factor());
}
}
CGAL_error();
return Quadratic_surface();
}
template <class MixedComplexTraits_3>
Sign
Skin_surface_base_3<MixedComplexTraits_3>::
compare(Cell_info &info, const Bare_point &p1, const Bare_point &p2) const {
return compare(info, p1, info, p2);
}
template <class MixedComplexTraits_3>
Sign
Skin_surface_base_3<MixedComplexTraits_3>::
compare(Cell_info &info1, const Bare_point &p1,
Cell_info &info2, const Bare_point &p2) const
{
CGAL_BRANCH_PROFILER(std::string(" NGHK: failures/calls to : ") + std::string(CGAL_PRETTY_FUNCTION), tmp);
{
Protect_FPU_rounding<true> P;
try
{
Sign result = CGAL_NTS sign(info1.second->value(p1) -
info2.second->value(p2));
if (is_certain(result))
return result;
}
catch (Uncertain_conversion_exception&) {}
}
CGAL_BRANCH_PROFILER_BRANCH(tmp);
Protect_FPU_rounding<false> P(CGAL_FE_TONEAREST);
return CGAL_NTS sign(
construct_surface(info1.first,
Exact_predicates_exact_constructions_kernel()).value(p1) -
construct_surface(info2.first,
Exact_predicates_exact_constructions_kernel()).value(p2));
}
template <class MixedComplexTraits_3>
typename Skin_surface_base_3<MixedComplexTraits_3>::TMC_Cell_handle
Skin_surface_base_3<MixedComplexTraits_3>::
locate_in_tmc(const Bare_point &p0, TMC_Cell_handle start) const
{
Cartesian_converter<typename Bare_point::R, TMC_Geom_traits> converter_fk;
TMC_Point p_inexact = converter_fk(p0);
// Make sure we continue from here with a finite cell.
if ( start == TMC_Cell_handle() )
start = _tmc.infinite_cell();
int ind_inf;
if (start->has_vertex(_tmc.infinite_vertex(), ind_inf) )
start = start->neighbor(ind_inf);
CGAL_triangulation_precondition(start != TMC_Cell_handle());
CGAL_triangulation_precondition(!start->has_vertex(_tmc.infinite_vertex()));
// We implement the remembering visibility/stochastic walk.
// Remembers the previous cell to avoid useless orientation tests.
TMC_Cell_handle previous = TMC_Cell_handle();
TMC_Cell_handle c = start;
// Now treat the cell c.
try_next_cell:
const TMC_Point* pts[4] = { &(c->vertex(0)->point()),
&(c->vertex(1)->point()),
&(c->vertex(2)->point()),
&(c->vertex(3)->point()) };
// For the remembering stochastic walk,
// we need to start trying with a random index :
boost::rand48 rng;
boost::uniform_smallint<> four(0, 3);
boost::variate_generator<boost::rand48&, boost::uniform_smallint<> > die4(rng, four);
int i = die4();
// For the remembering visibility walk (Delaunay only), we don't :
// int i = 0;
Orientation o;
for (int j=0; j != 4; ++j, i = (i+1)&3) {
TMC_Cell_handle next = c->neighbor(i);
if (previous == next) {
continue;
}
// We temporarily put p at i's place in pts.
const TMC_Point* backup = pts[i];
pts[i] = &p_inexact;
{
Protect_FPU_rounding<true> P;
try {
o = TMC_Geom_traits().orientation_3_object()(*pts[0], *pts[1],
*pts[2], *pts[3]);
} catch (Uncertain_conversion_exception&) {
Protect_FPU_rounding<false> P(CGAL_FE_TONEAREST);
typedef Exact_predicates_exact_constructions_kernel EK;
Cartesian_converter<typename Bare_point::R, EK> converter_ek;
Skin_surface_traits_3<EK> exact_traits(shrink_factor());
typename EK::Point_3 e_pts[4];
// We know that the 4 vertices of c are positively oriented.
// So, in order to test if p is seen outside from one of c's facets,
// we just replace the corresponding point by p in the orientation
// test. We do this using the array below.
for (int k=0; k<4; k++) {
if (k != i) {
e_pts[k] = get_anchor_point(c->vertex(k)->info(), exact_traits);
} else {
e_pts[k] = converter_ek(p0);
}
}
o = orientation(e_pts[0], e_pts[1], e_pts[2], e_pts[3]);
}
}
if ( o != NEGATIVE ) {
pts[i] = backup;
continue;
}
if ( next->has_vertex(_tmc.infinite_vertex()) ) {
std::cout << "We are outside the convex hull." << std::endl;
return next;
}
previous = c;
c = next;
goto try_next_cell;
}
CGAL_assertion(c->vertex(0) != _tmc.infinite_vertex());
CGAL_assertion(c->vertex(1) != _tmc.infinite_vertex());
CGAL_assertion(c->vertex(2) != _tmc.infinite_vertex());
CGAL_assertion(c->vertex(3) != _tmc.infinite_vertex());
return c;
}
template <class MixedComplexTraits_3>
template <class Gt2>
typename Skin_surface_base_3<Gt2>::Bare_point
Skin_surface_base_3<MixedComplexTraits_3>::
get_weighted_circumcenter(const Simplex &s, Gt2 &traits)
{
typedef typename Skin_surface_base_3<Gt2>::Bare_point Gt2_Bare_point;
Vertex_handle vh;
Edge e;
Facet f;
Cell_handle ch;
Cartesian_converter<typename Bare_point::R,
typename Gt2_Bare_point::R> converter;
Gt2_Bare_point result;
switch(s.dimension()) {
case 0:
{
vh = s;
result = traits.construct_point_3_object()(converter(vh->point()));
break;
}
case 1:
{
e = s;
result = traits.construct_weighted_circumcenter_3_object()
(converter(e.first->vertex(e.second)->point()),
converter(e.first->vertex(e.third)->point()));
break;
}
case 2:
{
2020-10-13 12:44:25 +00:00
f = Facet(s);
result = traits.construct_weighted_circumcenter_3_object()
(converter(f.first->vertex((f.second+1)&3)->point()),
converter(f.first->vertex((f.second+2)&3)->point()),
converter(f.first->vertex((f.second+3)&3)->point()));
break;
}
case 3:
{
ch = s;
result = traits.construct_weighted_circumcenter_3_object()
(converter(ch->vertex(0)->point()),
converter(ch->vertex(1)->point()),
converter(ch->vertex(2)->point()),
converter(ch->vertex(3)->point()));
break;
}
default:
{
CGAL_error();
}
}
return result;
}
} //namespace CGAL
#endif // CGAL_SKIN_SURFACE_BASE_3_H