// ====================================================================== // // Copyright (c) 2000 The CGAL Consortium // // This software and related documentation is part of an INTERNAL release // of the Computational Geometry Algorithms Library (CGAL). It is not // intended for general use. // // ---------------------------------------------------------------------- // // release : // release_date : // // file : include/CGAL/Cartesian/Iso_cuboid_3.h // revision : $Revision$ // revision_date : $Date$ // author(s) : Hervé Brönnimann // coordinator : INRIA Sophia-Antipolis (Mariette.Yvinec@sophia.inria.fr) // // ====================================================================== #ifndef CGAL_CARTESIAN_ISO_CUBOID_3_H #define CGAL_CARTESIAN_ISO_CUBOID_3_H #include #include CGAL_BEGIN_NAMESPACE template < class R_ > class Iso_cuboidC3 : public R_::template Handle >::type { CGAL_VC7_BUG_PROTECTED typedef typename R_::FT FT; typedef typename R_::Iso_cuboid_3 Iso_cuboid_3; typedef typename R_::Point_3 Point_3; typedef typename R_::Aff_transformation_3 Aff_transformation_3; typedef Twotuple rep; typedef typename R_::template Handle::type base; public: typedef R_ R; Iso_cuboidC3() {} Iso_cuboidC3(const Point_3 &p, const Point_3 &q) { FT minx, maxx, miny, maxy, minz, maxz; if (p.x() < q.x()) { minx = p.x(); maxx = q.x(); } else { minx = q.x(); maxx = p.x(); } if (p.y() < q.y()) { miny = p.y(); maxy = q.y(); } else { miny = q.y(); maxy = p.y(); } if (p.z() < q.z()) { minz = p.z(); maxz = q.z(); } else { minz = q.z(); maxz = p.z(); } initialize_with(rep(Point_3(minx, miny, minz), Point_3(maxx, maxy, maxz))); } Iso_cuboidC3(const Point_3 &left, const Point_3 &right, const Point_3 &bottom, const Point_3 &top, const Point_3 &far_, const Point_3 &close) : base(rep(Point_3(left.x(), bottom.y(), far_.z()), Point_3(right.x(), top.y(), close.z()))) { CGAL_kernel_precondition(!less_x(right, left)); CGAL_kernel_precondition(!less_y(top, bottom)); CGAL_kernel_precondition(!less_z(close, far_)); } Iso_cuboidC3(const FT& min_x, const FT& min_y, const FT& min_z, const FT& max_x, const FT& max_y, const FT& max_z) : base(rep(Point_3(min_x, min_y, min_z), Point_3(max_x, max_y, max_z))) { CGAL_kernel_precondition(min_x <= max_x); CGAL_kernel_precondition(min_y <= max_y); CGAL_kernel_precondition(min_z <= max_z); } Iso_cuboidC3(const FT& min_hx, const FT& min_hy, const FT& min_hz, const FT& max_hx, const FT& max_hy, const FT& max_hz, const FT& hw) { if (hw == FT(1)) initialize_with(rep(Point_3(min_hx, min_hy, min_hz), Point_3(max_hx, max_hy, max_hz))); else initialize_with( rep( Point_3(min_hx/hw, min_hy/hw, min_hz/hw), Point_3(max_hx/hw, max_hy/hw, max_hz/hw))); } bool operator==(const Iso_cuboidC3& s) const; bool operator!=(const Iso_cuboidC3& s) const; const Point_3 & min() const { return Ptr()->e0; } const Point_3 & max() const { return Ptr()->e1; } Point_3 vertex(int i) const; Point_3 operator[](int i) const; Iso_cuboid_3 transform(const Aff_transformation_3 &t) const { return Iso_cuboidC3(t.transform(min()), t.transform(max())); } Bounded_side bounded_side(const Point_3& p) const; bool has_on(const Point_3& p) const; bool has_on_boundary(const Point_3& p) const; bool has_on_bounded_side(const Point_3& p) const; bool has_on_unbounded_side(const Point_3& p) const; bool is_degenerate() const; Bbox_3 bbox() const; const FT & xmin() const; const FT & ymin() const; const FT & zmin() const; const FT & xmax() const; const FT & ymax() const; const FT & zmax() const; const FT & min_coord(int i) const; const FT & max_coord(int i) const; FT volume() const; }; template < class R > CGAL_KERNEL_INLINE bool Iso_cuboidC3::operator==(const Iso_cuboidC3& r) const { // FIXME : predicate if (identical(r)) return true; return min() == r.min() && max() == r.max(); } template < class R > inline bool Iso_cuboidC3::operator!=(const Iso_cuboidC3& r) const { return !(*this == r); } template < class R > inline const typename Iso_cuboidC3::FT & Iso_cuboidC3::xmin() const { return min().x(); } template < class R > inline const typename Iso_cuboidC3::FT & Iso_cuboidC3::ymin() const { return min().y(); } template < class R > inline const typename Iso_cuboidC3::FT & Iso_cuboidC3::zmin() const { return min().z(); } template < class R > inline const typename Iso_cuboidC3::FT & Iso_cuboidC3::xmax() const { return max().x(); } template < class R > inline const typename Iso_cuboidC3::FT & Iso_cuboidC3::ymax() const { return max().y(); } template < class R > inline const typename Iso_cuboidC3::FT & Iso_cuboidC3::zmax() const { return max().z(); } template < class R > inline const typename Iso_cuboidC3::FT & Iso_cuboidC3::min_coord(int i) const { CGAL_kernel_precondition( i == 0 || i == 1 || i == 2 ); if (i == 0) return xmin(); else if (i == 1) return ymin(); else return zmin(); } template < class R > inline const typename Iso_cuboidC3::FT & Iso_cuboidC3::max_coord(int i) const { CGAL_kernel_precondition( i == 0 || i == 1 || i == 2 ); if (i == 0) return xmax(); else if (i == 1) return ymax(); else return zmax(); } template < class R > CGAL_KERNEL_LARGE_INLINE typename Iso_cuboidC3::Point_3 Iso_cuboidC3::vertex(int i) const { switch (i%8) { case 0: return min(); case 1: return Point_3(max().hx(), min().hy(), min().hz()); case 2: return Point_3(max().hx(), max().hy(), min().hz()); case 3: return Point_3(min().hx(), max().hy(), min().hz()); case 4: return Point_3(min().hx(), max().hy(), max().hz()); case 5: return Point_3(min().hx(), min().hy(), max().hz()); case 6: return Point_3(max().hx(), min().hy(), max().hz()); default: // case 7: return max(); } } template < class R > inline typename Iso_cuboidC3::Point_3 Iso_cuboidC3::operator[](int i) const { return vertex(i); } template < class R > inline typename Iso_cuboidC3::FT Iso_cuboidC3::volume() const { return (xmax()-xmin()) * (ymax()-ymin()) * (zmax()-zmin()); } template < class R > CGAL_KERNEL_MEDIUM_INLINE Bounded_side Iso_cuboidC3:: bounded_side(const typename Iso_cuboidC3::Point_3& p) const { if (strict_dominance(p, min()) && strict_dominance(max(), p) ) return ON_BOUNDED_SIDE; if (dominance(p, min()) && dominance(max(), p)) return ON_BOUNDARY; return ON_UNBOUNDED_SIDE; } template < class R > inline bool Iso_cuboidC3:: has_on_boundary(const typename Iso_cuboidC3::Point_3& p) const { return bounded_side(p) == ON_BOUNDARY; } template < class R > inline bool Iso_cuboidC3:: has_on(const typename Iso_cuboidC3::Point_3& p) const { return bounded_side(p) == ON_BOUNDARY; } template < class R > inline bool Iso_cuboidC3:: has_on_bounded_side(const typename Iso_cuboidC3::Point_3& p) const { return bounded_side(p) == ON_BOUNDED_SIDE; } template < class R > CGAL_KERNEL_INLINE bool Iso_cuboidC3:: has_on_unbounded_side(const typename Iso_cuboidC3::Point_3& p) const { return bounded_side(p) == ON_UNBOUNDED_SIDE; } template < class R > CGAL_KERNEL_INLINE bool Iso_cuboidC3::is_degenerate() const { // FIXME : predicate return min().hx() == max().hx() || min().hy() == max().hy() || min().hz() == max().hz(); } template < class R > inline Bbox_3 Iso_cuboidC3::bbox() const { return min().bbox() + max().bbox(); } #ifndef CGAL_NO_OSTREAM_INSERT_ISO_CUBOIDC3 template < class R > std::ostream & operator<<(std::ostream& os, const Iso_cuboidC3& r) { switch(os.iword(IO::mode)) { case IO::ASCII : return os << r.min() << ' ' << r.max(); case IO::BINARY : return os << r.min() << r.max(); default: return os << "Iso_cuboidC3(" << r.min() << ", " << r.max() << ")"; } } #endif // CGAL_NO_OSTREAM_INSERT_ISO_CUBOIDC3 #ifndef CGAL_NO_ISTREAM_EXTRACT_ISO_CUBOIDC3 template < class R > std::istream & operator>>(std::istream& is, Iso_cuboidC3& r) { typename R::Point_3 p, q; is >> p >> q; if (is) r = Iso_cuboidC3(p, q); return is; } #endif // CGAL_NO_ISTREAM_EXTRACT_ISO_CUBOIDC3 CGAL_END_NAMESPACE #endif // CGAL_CARTESIAN_ISO_CUBOID_3_H