/usr/include/CGAL/function_objects.h is in libcgal-dev 4.11-2build1.
This file is owned by root:root, with mode 0o644.
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// Utrecht University (The Netherlands),
// ETH Zurich (Switzerland),
// INRIA Sophia-Antipolis (France),
// Max-Planck-Institute Saarbruecken (Germany),
// and Tel-Aviv University (Israel). All rights reserved.
//
// This file is part of CGAL (www.cgal.org); you can redistribute it and/or
// modify it under the terms of the GNU Lesser General Public License as
// published by the Free Software Foundation; either version 3 of the License,
// or (at your option) any later version.
//
// Licensees holding a valid commercial license may use this file in
// accordance with the commercial license agreement provided with the software.
//
// This file is provided AS IS with NO WARRANTY OF ANY KIND, INCLUDING THE
// WARRANTY OF DESIGN, MERCHANTABILITY AND FITNESS FOR A PARTICULAR PURPOSE.
//
// $URL$
// $Id$
//
//
// Author(s) : Michael Hoffmann <hoffmann@inf.ethz.ch>
// Lutz Kettner <kettner@mpi-sb.mpg.de>
// Sylvain Pion
#ifndef CGAL_FUNCTION_OBJECTS_H
#define CGAL_FUNCTION_OBJECTS_H 1
#include <functional>
#include <CGAL/enum.h>
namespace CGAL {
template < class Value>
struct Identity {
typedef Value argument_type;
typedef Value result_type;
Value& operator()( Value& x) const { return x; }
const Value& operator()( const Value& x) const { return x; }
};
template < class Value>
struct Dereference {
typedef Value* argument_type;
typedef Value result_type;
Value& operator()( Value* x) const { return *x;}
const Value& operator()( const Value* x) const { return *x;}
};
template < class Value>
struct Get_address {
typedef Value argument_type;
typedef Value* result_type;
Value* operator()( Value& x) const { return &x;}
const Value* operator()( const Value& x) const { return &x;}
};
template < class Arg, class Result>
struct Cast_function_object {
typedef Arg argument_type;
typedef Result result_type;
Result& operator()( Arg& x) const { return (Result&)(x); }
const Result& operator()( const Arg& x) const {
return (const Result&)(x);
}
};
template < class Node>
struct Project_vertex {
typedef Node argument_type;
typedef typename Node::Vertex Vertex;
typedef Vertex result_type;
Vertex& operator()( Node& x) const { return x.vertex(); }
const Vertex& operator()( const Node& x) const { return x.vertex(); }
};
template < class Node>
struct Project_facet {
typedef Node argument_type;
typedef typename Node::Facet Facet;
typedef Facet result_type;
Facet& operator()( Node& x) const { return x.facet(); }
const Facet& operator()( const Node& x) const { return x.facet(); }
};
template < class Node>
struct Project_point {
typedef Node argument_type;
typedef typename Node::Point Point;
typedef Point result_type;
Point& operator()( Node& x) const { return x.point(); }
const Point& operator()( const Node& x) const { return x.point(); }
};
template < class Node>
struct Project_normal {
typedef Node argument_type;
typedef typename Node::Normal Normal;
typedef Normal result_type;
Normal& operator()( Node& x) const { return x.normal(); }
const Normal& operator()( const Node& x) const { return x.normal(); }
};
template < class Node>
struct Project_plane {
typedef Node argument_type;
typedef typename Node::Plane Plane;
typedef Plane result_type;
Plane& operator()( Node& x) const { return x.plane(); }
const Plane& operator()( const Node& x) const { return x.plane(); }
};
// The following four adaptors are used to create the circulators
// for polyhedral surfaces.
template < class Node>
struct Project_next {
typedef Node* argument_type;
typedef Node* result_type;
Node* operator()( Node* x) const { return x->next(); }
const Node* operator()( const Node* x) const { return x->next(); }
};
template < class Node>
struct Project_prev {
typedef Node* argument_type;
typedef Node* result_type;
Node* operator()( Node* x) const { return x->prev(); }
const Node* operator()( const Node* x) const { return x->prev(); }
};
template < class Node>
struct Project_next_opposite {
typedef Node* argument_type;
typedef Node* result_type;
Node* operator()( Node* x) const {
return x->next()->opposite();
}
const Node* operator()( const Node* x) const {
return x->next()->opposite();
}
};
template < class Node>
struct Project_opposite_prev {
typedef Node* argument_type;
typedef Node* result_type;
Node* operator()( Node* x) const {
return x->opposite()->prev();
}
const Node* operator()( const Node* x) const {
return x->opposite()->prev();
}
};
template < class Arg, class Result >
class Creator_1 {
public:
typedef Arg argument_type;
typedef Arg argument1_type;
typedef Result result_type;
Result operator()(Arg a) const { return Result(a);}
};
template < class Arg1, class Arg2, class Result >
class Creator_2 {
public:
typedef Arg1 argument1_type;
typedef Arg2 argument2_type;
typedef Result result_type;
Result operator()(Arg1 a1, Arg2 a2) const { return Result(a1,a2);}
};
template < class Arg1, class Arg2, class Arg3, class Result >
class Creator_3 {
public:
typedef Arg1 argument1_type;
typedef Arg2 argument2_type;
typedef Arg3 argument3_type;
typedef Result result_type;
Result operator()(Arg1 a1, Arg2 a2, Arg3 a3) const {
return Result(a1,a2,a3);
}
};
template < class Arg1, class Arg2, class Arg3, class Arg4, class Result >
class Creator_4 {
public:
typedef Arg1 argument1_type;
typedef Arg2 argument2_type;
typedef Arg3 argument3_type;
typedef Arg4 argument4_type;
typedef Result result_type;
Result operator()(Arg1 a1, Arg2 a2, Arg3 a3, Arg4 a4) const {
return Result(a1,a2,a3,a4);
}
};
template < class Arg1, class Arg2, class Arg3, class Arg4, class Arg5,
class Result >
class Creator_5 {
public:
typedef Arg1 argument1_type;
typedef Arg2 argument2_type;
typedef Arg3 argument3_type;
typedef Arg4 argument4_type;
typedef Arg5 argument5_type;
typedef Result result_type;
Result operator()(Arg1 a1, Arg2 a2, Arg3 a3, Arg4 a4, Arg5 a5) const {
return Result(a1,a2,a3,a4,a5);
}
};
template < class Arg, class Result >
class Creator_uniform_2 {
public:
typedef Arg argument_type;
typedef Arg argument1_type;
typedef Arg argument2_type;
typedef Result result_type;
Result operator()(Arg a1, Arg a2) const { return Result(a1,a2);}
};
template < class Arg, class Result >
class Creator_uniform_3 {
public:
typedef Arg argument_type;
typedef Arg argument1_type;
typedef Arg argument2_type;
typedef Arg argument3_type;
typedef Result result_type;
Result operator()(Arg a1, Arg a2, Arg a3) const {
return Result(a1,a2,a3);
}
};
template < class Arg, class Result >
class Creator_uniform_4 {
public:
typedef Arg argument_type;
typedef Arg argument1_type;
typedef Arg argument2_type;
typedef Arg argument3_type;
typedef Arg argument4_type;
typedef Result result_type;
Result operator()(Arg a1, Arg a2, Arg a3, Arg a4) const {
return Result(a1,a2,a3,a4);
}
};
template < class Arg, class Result >
class Creator_uniform_5 {
public:
typedef Arg argument_type;
typedef Arg argument1_type;
typedef Arg argument2_type;
typedef Arg argument3_type;
typedef Arg argument4_type;
typedef Arg argument5_type;
typedef Result result_type;
Result operator()(Arg a1, Arg a2, Arg a3, Arg a4, Arg a5) const {
return Result(a1,a2,a3,a4,a5);
}
};
template < class Arg, class Result >
class Creator_uniform_6 {
public:
typedef Arg argument_type;
typedef Arg argument1_type;
typedef Arg argument2_type;
typedef Arg argument3_type;
typedef Arg argument4_type;
typedef Arg argument5_type;
typedef Arg argument6_type;
typedef Result result_type;
Result operator()(Arg a1, Arg a2, Arg a3, Arg a4, Arg a5, Arg a6
) const {
return Result(a1,a2,a3,a4,a5,a6);
}
};
template < class Arg, class Result >
class Creator_uniform_7 {
public:
typedef Arg argument_type;
typedef Arg argument1_type;
typedef Arg argument2_type;
typedef Arg argument3_type;
typedef Arg argument4_type;
typedef Arg argument5_type;
typedef Arg argument6_type;
typedef Arg argument7_type;
typedef Result result_type;
Result operator()(Arg a1, Arg a2, Arg a3, Arg a4, Arg a5, Arg a6,
Arg a7) const {
return Result(a1,a2,a3,a4,a5,a6,a7);
}
};
template < class Arg, class Result >
class Creator_uniform_8 {
public:
typedef Arg argument_type;
typedef Arg argument1_type;
typedef Arg argument2_type;
typedef Arg argument3_type;
typedef Arg argument4_type;
typedef Arg argument5_type;
typedef Arg argument6_type;
typedef Arg argument7_type;
typedef Arg argument8_type;
typedef Result result_type;
Result operator()(Arg a1, Arg a2, Arg a3, Arg a4, Arg a5, Arg a6,
Arg a7, Arg a8) const {
return Result(a1,a2,a3,a4,a5,a6,a7,a8);
}
};
template < class Arg, class Result >
class Creator_uniform_9 {
public:
typedef Arg argument_type;
typedef Arg argument1_type;
typedef Arg argument2_type;
typedef Arg argument3_type;
typedef Arg argument4_type;
typedef Arg argument5_type;
typedef Arg argument6_type;
typedef Arg argument7_type;
typedef Arg argument8_type;
typedef Arg argument9_type;
typedef Result result_type;
Result operator()(Arg a1, Arg a2, Arg a3, Arg a4, Arg a5, Arg a6,
Arg a7, Arg a8, Arg a9) const {
return Result(a1,a2,a3,a4,a5,a6,a7,a8,a9);
}
};
template < class Arg, class Result >
class Creator_uniform_d {
int d;
private:
Creator_uniform_d(){}
public:
typedef Arg argument1_type;
typedef Result result_type;
Creator_uniform_d(int dim)
: d(dim)
{}
Result operator()(Arg a1, Arg a2) const { return Result(d, a1,a2);}
};
template < class Op1, class Op2 >
class Unary_compose_1
: public std::unary_function< typename Op2::argument_type,
typename Op1::result_type >
{
protected:
Op1 op1;
Op2 op2;
public:
typedef typename Op2::argument_type argument_type;
typedef typename Op1::result_type result_type;
Unary_compose_1(const Op1& x, const Op2& y) : op1(x), op2(y) {}
result_type
operator()(const argument_type& x) const
{ return op1(op2(x)); }
};
template < class Op1, class Op2 >
inline Unary_compose_1< Op1, Op2 >
compose1_1(const Op1& op1, const Op2& op2)
{ return Unary_compose_1< Op1, Op2 >(op1, op2); }
template < class Op1, class Op2, class Op3 >
class Binary_compose_1
: public std::unary_function< typename Op2::argument_type,
typename Op1::result_type >
{
protected:
Op1 op1;
Op2 op2;
Op3 op3;
public:
typedef typename Op2::argument_type argument_type;
typedef typename Op1::result_type result_type;
Binary_compose_1(const Op1& x, const Op2& y, const Op3& z)
: op1(x), op2(y), op3(z) {}
result_type
operator()(const argument_type& x) const
{ return op1(op2(x), op3(x)); }
};
template < class Op1, class Op2, class Op3 >
inline Binary_compose_1< Op1, Op2, Op3 >
compose2_1(const Op1& op1, const Op2& op2, const Op3& op3)
{ return Binary_compose_1< Op1, Op2, Op3 >(op1, op2, op3); }
template < class Op1, class Op2 >
class Unary_compose_2
: public std::binary_function< typename Op2::first_argument_type,
typename Op2::second_argument_type,
typename Op1::result_type >
{
protected:
Op1 op1;
Op2 op2;
public:
typedef typename Op2::first_argument_type first_argument_type;
typedef typename Op2::second_argument_type second_argument_type;
typedef typename Op1::result_type result_type;
Unary_compose_2(const Op1& x, const Op2& y) : op1(x), op2(y) {}
result_type
operator()(const first_argument_type& x,
const second_argument_type& y) const
{ return op1(op2(x, y)); }
};
template < class Op1, class Op2 >
inline Unary_compose_2< Op1, Op2 >
compose1_2(const Op1& op1, const Op2& op2)
{ return Unary_compose_2< Op1, Op2 >(op1, op2); }
template < class Op1, class Op2, class Op3 >
class Binary_compose_2
: public std::binary_function< typename Op2::argument_type,
typename Op3::argument_type,
typename Op1::result_type >
{
protected:
Op1 op1;
Op2 op2;
Op3 op3;
public:
typedef typename Op2::argument_type first_argument_type;
typedef typename Op3::argument_type second_argument_type;
typedef typename Op1::result_type result_type;
Binary_compose_2(const Op1& x, const Op2& y, const Op3& z)
: op1(x), op2(y), op3(z) {}
result_type
operator()(const first_argument_type& x,
const second_argument_type& y) const
{ return op1(op2(x), op3(y)); }
};
template < class Op1, class Op2, class Op3 >
inline Binary_compose_2< Op1, Op2, Op3 >
compose2_2(const Op1& op1, const Op2& op2, const Op3& op3)
{ return Binary_compose_2< Op1, Op2, Op3 >(op1, op2, op3); }
template < class Op >
class Compare_to_less
: public Op
{
public:
typedef Op Type;
typedef bool result_type;
Compare_to_less(const Op& op) : Op(op) {}
template < typename A1 >
bool
operator()(const A1 &a1) const
{ return Op::operator()(a1) == SMALLER; }
template < typename A1, typename A2 >
bool
operator()(const A1 &a1, const A2 &a2) const
{ return Op::operator()(a1, a2) == SMALLER; }
template < typename A1, typename A2, typename A3 >
bool
operator()(const A1 &a1, const A2 &a2, const A3 &a3) const
{ return Op::operator()(a1, a2, a3) == SMALLER; }
template < typename A1, typename A2, typename A3, typename A4 >
bool
operator()(const A1 &a1, const A2 &a2, const A3 &a3, const A4 &a4) const
{ return Op::operator()(a1, a2, a3, a4) == SMALLER; }
// More can be added.
};
template < class Op >
inline Compare_to_less<Op>
compare_to_less(const Op& op)
{ return Compare_to_less<Op>(op); }
/*!\brief
* Functor class to determine lexicographical order of pairs
*/
template < class T1, class T2,
class Less1 = std::less<T1>, class Less2 = std::less<T2> >
struct Pair_lexicographical_less_than {
typedef bool result_type;
typedef std::pair<T1,T2> first_argument_type;
typedef std::pair<T1,T2> second_argument_type;
/*!\brief
* returns \c true iff \c x is lexicograhically smaller than \c y
* using \c Less1 and \c Less2 functors.
*/
bool operator () (const std::pair<T1,T2>& x, const std::pair<T1,T2>& y) const {
Less1 lt1;
Less2 lt2;
if (lt1(x.first, y.first)) {
return true;
} else if (lt1(y.first, x.first)) {
return false;
} else /* neither is less than the other */ {
return lt2(x.second, y.second);
}
}
};
} //namespace CGAL
#endif // CGAL_FUNCTION_OBJECTS_H
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