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[/] [openrisc/] [trunk/] [gnu-dev/] [or1k-gcc/] [gcc/] [testsuite/] [g++.dg/] [torture/] [pr46383.C] - Rev 693
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// { dg-do compile }
namespace std {
template<class,class>struct pair{};
template<typename _Tp> struct _Vector_base {
struct _Vector_impl
{
_Tp* _M_start;
_Tp* _M_finish;
_Tp* _M_end_of_storage;
};
_Vector_impl _M_impl;
};
template<typename _Tp >
struct vector : _Vector_base<_Tp>
{
vector(const vector& __x);
};
}
namespace boost {
struct G{};
template <class T, class U >
struct modable2
: G
{ };
}
namespace CGAL {
struct Rep { };
struct Handle
{
Handle() ;
Handle(const Handle& x) ;
Rep* PTR;
};
template <typename ET_> class Lazy_exact_nt
: Handle
, boost::modable2< Lazy_exact_nt<ET_>, int >
, boost::modable2< Lazy_exact_nt<ET_>, double >
{ };
struct CC_iterator { };
struct Triangulation_data_structure_3 {
typedef CC_iterator Vertex_handle;
typedef CC_iterator Cell_handle;
typedef std::pair<Cell_handle, int> Facet;
};
template < class GT, class Tds_ > struct Triangulation_3 {
typedef Tds_ Tds;
typedef typename GT::Point_3 Point;
typedef typename Tds::Facet Facet;
typedef typename Tds::Vertex_handle Vertex_handle;
enum Locate_type { VERTEX=0, EDGE, FACET, CELL, OUTSIDE_CONVEX_HULL, OUTSIDE_AFFINE_HULL };
Tds _tds;
bool is_infinite(const Facet & f) const ;
};
template < class Gt, class Tds_ > struct Delaunay_triangulation_3 : public Triangulation_3<Gt, Tds_> { };
namespace Surface_mesher { enum Verbose_flag { VERBOSE, NOT_VERBOSE }; }
enum Mesher_level_conflict_status { NO_CONFLICT = 0, CONFLICT_BUT_ELEMENT_CAN_BE_RECONSIDERED, CONFLICT_AND_ELEMENT_SHOULD_BE_DROPPED };
struct Null_mesher_level {
template <typename P, typename Z> Mesher_level_conflict_status test_point_conflict_from_superior(P, Z) ;
};
template < class Tr, class Derived, class Element, class Previous, class Triangulation_traits > struct Mesher_level {
typedef Tr Triangulation;
typedef typename Triangulation::Point Point;
typedef typename Triangulation::Vertex_handle Vertex_handle;
typedef typename Triangulation_traits::Zone Zone;
typedef Previous Previous_level;
Derived& derived() { return static_cast<Derived&>(*this); }
Previous& previous_level;
Mesher_level(Previous_level& previous)
: previous_level(previous)
{ }
Vertex_handle insert(Point p, Zone& z) ;
Zone conflicts_zone(const Point& p, Element e) ;
Element get_next_element() ;
template <class Mesh_visitor> void before_insertion(Element& e, const Point& p, Zone& zone, Mesh_visitor visitor) {
visitor.before_insertion(e, p, zone);
}
template <class Mesh_visitor> void after_insertion(Vertex_handle vh, Mesh_visitor visitor) {
derived().after_insertion_impl(vh);
}
template <class Mesh_visitor> void after_no_insertion(const Element& e, const Point& p, Zone& zone, Mesh_visitor visitor) {
visitor.after_no_insertion(e, p, zone);
}
template <class Mesh_visitor> void refine(Mesh_visitor visitor)
{
Element e = get_next_element();
const Mesher_level_conflict_status result = try_to_refine_element(e, visitor);
}
template <class Mesh_visitor> Mesher_level_conflict_status try_to_refine_element(Element e, Mesh_visitor visitor)
{
Point p ;
Zone zone = conflicts_zone(p, e);
const Mesher_level_conflict_status result = test_point_conflict(p, zone);
before_insertion(e, p, zone, visitor);
Vertex_handle v = insert(p, zone);
after_insertion(v, visitor);
after_no_insertion(e, p, zone, visitor);
}
Mesher_level_conflict_status test_point_conflict(const Point& p, Zone& zone)
{
return previous_level.test_point_conflict_from_superior(p, zone);
}
};
struct Null_mesh_visitor {
template <typename E, typename P, typename Z> void before_insertion(E, P, Z) const {}
template <typename E, typename P, typename Z> void after_no_insertion(E, P, Z) const {}
};
template <class Tr> struct Triangulation_ref_impl {
Triangulation_ref_impl(Tr& t);
};
template <typename Tr> struct Triangulation_mesher_level_traits_3
: public Triangulation_ref_impl<Tr>
{
typedef typename Tr::Facet Facet;
Triangulation_mesher_level_traits_3(Tr& t)
: Triangulation_ref_impl<Tr>(t)
{ }
struct Zone {
typedef std::vector<int*> Cells;
typedef std::vector<Facet> Facets;
typedef typename Tr::Locate_type Locate_type;
Locate_type locate_type;
Cells cells;
Facets boundary_facets;
Facets internal_facets;
};
};
namespace Surface_mesher {
namespace details {
template <typename Base> struct Triangulation_generator {
typedef typename Base::Complex_2_in_triangulation_3 C2T3;
typedef typename C2T3::Triangulation Triangulation;
typedef Triangulation Type;
typedef Type type;
};
template <typename Base> struct Facet_generator {
typedef typename Triangulation_generator<Base>::type Tr;
typedef typename Tr::Facet Type;
typedef Type type;
};
template <typename Base, typename Self, typename Element, typename PreviousLevel = Null_mesher_level> struct Mesher_level_generator {
typedef typename Base::Complex_2_in_triangulation_3 C2T3;
typedef typename C2T3::Triangulation Triangulation;
typedef Triangulation_mesher_level_traits_3<Triangulation> Tr_m_l_traits_3;
typedef Mesher_level <Triangulation, Self, Element, PreviousLevel, Tr_m_l_traits_3> Type;
};
}
template < class C2T3, class Surface_, class SurfaceMeshTraits, class Criteria_ > struct Surface_mesher_base
: public Triangulation_mesher_level_traits_3<typename C2T3::Triangulation>
{
typedef C2T3 Complex_2_in_triangulation_3;
typedef Surface_ Surface;
typedef SurfaceMeshTraits Surface_mesh_traits;
typedef Criteria_ Criteria;
typedef typename C2T3::Triangulation Tr;
typedef typename Tr::Vertex_handle Vertex_handle;
typedef typename Tr::Facet Facet;
Surface_mesher_base (C2T3& co, const Surface& s, const Surface_mesh_traits& mesh_traits, const Criteria& c)
: Triangulation_mesher_level_traits_3<Tr>(co.triangulation()), c2t3(co), tr(co.triangulation()), surf(s), meshtraits(mesh_traits), criteria(c)
{ }
C2T3& c2t3;
Tr& tr;
const Surface& surf;
const Surface_mesh_traits& meshtraits;
const Criteria& criteria;
void after_insertion_impl(const Vertex_handle& v) {
after_insertion_handle_opposite_facet (Facet ());
after_insertion_handle_incident_facet (Facet ());
}
void after_insertion_handle_incident_facet (const Facet& f) {
tr.is_infinite(f) ;
new_facet<false>(f);
}
template <bool remove_from_complex_if_not_in_restricted_Delaunay> void new_facet (const Facet& f) ;
void after_insertion_handle_opposite_facet (const Facet& f) {
after_insertion_handle_incident_facet (f);
}
};
template < typename Base, typename Element = typename details::Facet_generator<Base>::type, typename PreviousLevel = Null_mesher_level, Verbose_flag verbose = NOT_VERBOSE > struct Surface_mesher
: public Base , public details::Mesher_level_generator< Base, Surface_mesher<Base, Element, PreviousLevel, verbose>, Element, PreviousLevel >::Type
{
typedef typename Base::Complex_2_in_triangulation_3 C2T3;
typedef typename Base::Surface Surface;
typedef typename Base::Criteria Criteria;
typedef typename Base::Surface_mesh_traits Surface_mesh_traits;
typedef typename details::Mesher_level_generator< Base, Surface_mesher<Base, Element, PreviousLevel, verbose>, Element, PreviousLevel >::Type Mesher_lvl;
using Mesher_lvl::refine;
Null_mesher_level null_mesher_level;
Null_mesh_visitor null_visitor;
bool initialized;
Surface_mesher(C2T3& c2t3, const Surface& surface, const Surface_mesh_traits& mesh_traits, const Criteria& criteria)
: Base(c2t3, surface, mesh_traits, criteria), Mesher_lvl(null_mesher_level), initialized(false)
{ }
void refine_mesh () {
refine(null_visitor);
}
};
}
template <typename Surface> struct Surface_mesh_traits_generator_3 {
typedef typename Surface::Surface_mesher_traits_3 Type;
typedef Type type;
};
template < class Tr, typename Edge_info_ = void > struct Complex_2_in_triangulation_3 {
typedef Tr Triangulation;
Triangulation& triangulation();
};
template <class Tr> struct Surface_mesh_complex_2_in_triangulation_3
: public Complex_2_in_triangulation_3<Tr>
{ };
struct Non_manifold_tag {};
template < typename C2T3, typename SurfaceMeshTraits_3, typename Criteria, typename Tag > struct Make_surface_mesh_helper {
typedef Surface_mesher::Surface_mesher_base< C2T3, typename SurfaceMeshTraits_3::Surface_3, SurfaceMeshTraits_3, Criteria> Mesher_base;
};
template <typename C2T3, typename SurfaceMeshTraits_3, typename Criteria, typename Tag, Surface_mesher::Verbose_flag verbosity = Surface_mesher::NOT_VERBOSE > struct Surface_mesher_generator {
typedef typename Make_surface_mesh_helper< C2T3, SurfaceMeshTraits_3, Criteria, Tag>::Mesher_base Mesher_base;
typedef Surface_mesher::Surface_mesher< Mesher_base, typename Surface_mesher::details::Facet_generator<Mesher_base>::type, Null_mesher_level, verbosity> Mesher;
typedef Mesher type;
};
template <typename C2T3, typename SurfaceMeshTraits_3, typename Criteria> void make_surface_mesh(C2T3& c2t3, const typename SurfaceMeshTraits_3::Surface_3& surface, const SurfaceMeshTraits_3& surface_mesh_traits, const Criteria& criteria) {
typedef typename Surface_mesher_generator< C2T3, SurfaceMeshTraits_3, Criteria, Non_manifold_tag, Surface_mesher::NOT_VERBOSE >::type Mesher;
Mesher mesher(c2t3, surface, surface_mesh_traits, criteria);
mesher.refine_mesh();
}
template <class Kernel> struct Surface_mesh_triangulation_generator_3 {
typedef CGAL::Triangulation_data_structure_3 Tds;
typedef CGAL::Delaunay_triangulation_3<Kernel, Tds> Type;
};
namespace Surface_mesher {
namespace { struct Return_min { }; }
template < class GT, class Surface, class Unused = Return_min > struct Implicit_surface_oracle_3 {
typedef Surface Surface_3;
};
}
template< typename GT> struct Implicit_surface_3 {
typedef GT Geom_traits;
typedef Implicit_surface_3<Geom_traits > Self;
typedef Surface_mesher::Implicit_surface_oracle_3< Geom_traits, Self> Surface_mesher_traits_3;
};
}
struct K {
struct Point_3 {
CGAL::Lazy_exact_nt<double> a[3];
};
};
typedef CGAL::Surface_mesh_triangulation_generator_3<K>::Type Tr;
typedef CGAL::Surface_mesh_complex_2_in_triangulation_3<Tr> C2T3;
typedef CGAL::Implicit_surface_3<K > Surface;
typedef CGAL::Surface_mesh_traits_generator_3<Surface>::type Traits;
void f() {
C2T3 c2t3 ;
CGAL::make_surface_mesh(c2t3, Surface(), Traits(), 3);
}