dust3d/thirdparty/cgal/CGAL-4.13/include/CGAL/NewKernel_d/Lazy_cartesian.h

// Copyright (c) 2014
// INRIA Saclay-Ile de France (France)
//
// 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.
//
// $URL$
// $Id$
// SPDX-License-Identifier: LGPL-3.0+
//
// Author(s)     : Marc Glisse

#ifndef CGAL_KERNEL_D_LAZY_CARTESIAN_H
#define CGAL_KERNEL_D_LAZY_CARTESIAN_H

#include <CGAL/basic.h>
#include <CGAL/algorithm.h>
#include <CGAL/Lazy.h>
#include <CGAL/Default.h>
#include <CGAL/NewKernel_d/Filtered_predicate2.h>
#include <CGAL/iterator_from_indices.h>
#include <CGAL/NewKernel_d/Define_kernel_types.h>

namespace CGAL {

template<class K,class T>
struct Nth_iterator_element : private Store_kernel<K> {
  Nth_iterator_element(){}
  Nth_iterator_element(K const&k):Store_kernel<K>(k){}
  typedef typename Get_type<K, typename iterator_tag_traits<T>::value_tag>::type result_type;
  template<class U> result_type operator()(CGAL_FORWARDABLE(U) u, int i) const {
    typename Get_functor<K, Construct_ttag<T> >::type ci(this->kernel());
    return *cpp0x::next(ci(CGAL_FORWARD(U,u),Begin_tag()),i);
  }
};
      //typedef typename Functor<typename iterator_tag_traits<T>::nth_element>::type nth_elem;
template<class K, class T, bool = iterator_tag_traits<T>::has_nth_element>
struct Select_nth_element_functor {
  typedef Nth_iterator_element<K, T> type;
};
template<class K, class T>
struct Select_nth_element_functor <K, T, true> :
  Get_functor<K, typename iterator_tag_traits<T>::nth_element> {};

namespace internal {
  template<class A,class B,class C,bool/*is_NT=false*/>
    struct Lazy_construction_maybe_nt {
      typedef Lazy_construction<A,B,C> type;
    };
  template<class A,class B,class C>
    struct Lazy_construction_maybe_nt<A,B,C,true> {
      typedef Lazy_construction_nt<A,B,C> type;
    };
}

template <class EK_, class AK_, class E2A_, class Kernel_>
struct Lazy_cartesian_types
{
    typedef typename typeset_intersection<
      typename AK_::Object_list,
      typename EK_::Object_list
	>::type Object_list;

    typedef typename typeset_intersection<
      typename AK_::Iterator_list,
      typename EK_::Iterator_list
	>::type Iterator_list;

    template <class T,class=typename Get_type_category<Kernel_,T>::type> struct Type {};
    template <class T> struct Type<T,Object_tag> {
	    typedef Lazy<
		    typename Get_type<AK_,T>::type,
		    typename Get_type<EK_,T>::type,
		    typename Get_type<EK_, FT_tag>::type,
		    E2A_> type;
    };
    template <class T> struct Type<T,Number_tag> {
      typedef CGAL::Lazy_exact_nt<typename Get_type<EK_,T>::type>  type;
    };

    template <class T> struct Iterator {
      typedef typename iterator_tag_traits<T>::value_tag Vt;
      typedef typename Type<Vt>::type V;
      typedef typename Select_nth_element_functor<AK_,T>::type AF;
      typedef typename Select_nth_element_functor<EK_,T>::type EF;

      typedef typename internal::Lazy_construction_maybe_nt<
	Kernel_, AF, EF, is_NT_tag<Vt>::value
	>::type nth_elem;

      typedef Iterator_from_indices<
	const typename Type<typename iterator_tag_traits<T>::container>::type,
	const V, V, nth_elem
      > type;
    };
};

template <class EK_, class AK_, class E2A_/*, class Kernel_=Default*/>
struct Lazy_cartesian : Dimension_base<typename EK_::Default_ambient_dimension>,
  Lazy_cartesian_types<EK_,AK_,E2A_,Lazy_cartesian<EK_,AK_,E2A_> >
{
    //CGAL_CONSTEXPR Lazy_cartesian(){}
    //CGAL_CONSTEXPR Lazy_cartesian(int d):Base_(d){}

    //TODO: Do we want to store an AK and an EK? Or just references?
    //FIXME: references would be better I guess.
    //TODO: In any case, make sure that we don't end up storing this kernel for
    //nothing (it is not empty but references empty kernels or something)
    AK_ ak; EK_ ek;
    AK_ const& approximate_kernel()const{return ak;}
    EK_ const& exact_kernel()const{return ek;}

    typedef Lazy_cartesian Self;
    typedef Lazy_cartesian_types<EK_,AK_,E2A_,Self> Base;
    //typedef typename Default::Get<Kernel_,Self>::type Kernel;
    typedef Self  Kernel;
    typedef AK_   Approximate_kernel;
    typedef EK_   Exact_kernel;
    typedef E2A_  E2A;
    typedef Approx_converter<Kernel, Approximate_kernel>   C2A;
    typedef Exact_converter<Kernel, Exact_kernel>    C2E;

    typedef typename Exact_kernel::Rep_tag Rep_tag;
    typedef typename Exact_kernel::Kernel_tag Kernel_tag;
    typedef typename Exact_kernel::Default_ambient_dimension Default_ambient_dimension;
    typedef typename Exact_kernel::Max_ambient_dimension Max_ambient_dimension;
    //typedef typename Exact_kernel::Flat_orientation Flat_orientation;
    // Check that Approximate_kernel agrees with all that...

    template<class T,class D=void,class=typename Get_functor_category<Lazy_cartesian,T,D>::type> struct Functor {
	    typedef Null_functor type;
    };
	    //FIXME: what do we do with D here?
    template<class T,class D> struct Functor<T,D,Predicate_tag> {
	    typedef typename Get_functor<Approximate_kernel, T>::type FA;
	    typedef typename Get_functor<Exact_kernel, T>::type FE;
	    typedef Filtered_predicate2<FE,FA,C2E,C2A> type;
    };
    template<class T,class D> struct Functor<T,D,Compute_tag> {
	    typedef typename Get_functor<Approximate_kernel, T>::type FA;
	    typedef typename Get_functor<Exact_kernel, T>::type FE;
	    typedef Lazy_construction_nt<Kernel,FA,FE> type;
    };
    template<class T,class D> struct Functor<T,D,Construct_tag> {
	    typedef typename Get_functor<Approximate_kernel, T>::type FA;
	    typedef typename Get_functor<Exact_kernel, T>::type FE;
	    typedef Lazy_construction<Kernel,FA,FE> type;
    };

    //typedef typename Iterator<Point_cartesian_const_iterator_tag>::type Point_cartesian_const_iterator;
    //typedef typename Iterator<Vector_cartesian_const_iterator_tag>::type Vector_cartesian_const_iterator;

    template<class U>
    struct Construct_iter : private Store_kernel<Kernel> {
	    Construct_iter(){}
	    Construct_iter(Kernel const&k):Store_kernel<Kernel>(k){}
	    //FIXME: pass the kernel to the functor in the iterator
	    typedef U result_type;
	    template<class T>
	    result_type operator()(T const& t,Begin_tag)const{
		    return result_type(t,0,this->kernel());
	    }
	    template<class T>
	    result_type operator()(T const& t,End_tag)const{
		    return result_type(t,Self().dimension(),this->kernel());
	    }
    };
    template<class T,class D> struct Functor<T,D,Construct_iterator_tag> {
	    typedef Construct_iter<typename Base::template Iterator<typename map_result_tag<T>::type>::type> type;
    };


    //TODO: what about other functors of the Misc category?
    // for Point_dimension, we should apply it to the approximate point
    // for printing, we should??? just not do printing this way?
};


} //namespace CGAL

#endif // CGAL_KERNEL_D_LAZY_CARTESIAN_H
Integrate Instant-Meshes 1. Drop windows 32bit support Add windows 64bit support. 2. Remove Script(quickjs) support The current integrated quickjs is a very old version which doesn’t support windows 64bit system. In the future, (TODO)WebAssembly should be integrate as plugin system. 3. Integrate Instant-Meshes Instant-Meshes take less than 1 second on all three platforms. 4. Remove QuadriFlow Current implementation of QuadriFlow is too slow (take about 5 seconds on the example model) to do realtime remeshing. 2020-01-04 10:29:10 +00:00			`// Copyright (c) 2014`
			`// INRIA Saclay-Ile de France (France)`
			`//`
			`// 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.`
			`//`
			`// $URL$`
			`// $Id$`
			`// SPDX-License-Identifier: LGPL-3.0+`
			`//`
			`// Author(s) : Marc Glisse`

			`#ifndef CGAL_KERNEL_D_LAZY_CARTESIAN_H`
			`#define CGAL_KERNEL_D_LAZY_CARTESIAN_H`

			`#include <CGAL/basic.h>`
			`#include <CGAL/algorithm.h>`
			`#include <CGAL/Lazy.h>`
			`#include <CGAL/Default.h>`
			`#include <CGAL/NewKernel_d/Filtered_predicate2.h>`
			`#include <CGAL/iterator_from_indices.h>`
			`#include <CGAL/NewKernel_d/Define_kernel_types.h>`

			`namespace CGAL {`

			`template<class K,class T>`
			`struct Nth_iterator_element : private Store_kernel<K> {`
			`Nth_iterator_element(){}`
			`Nth_iterator_element(K const&k):Store_kernel<K>(k){}`
			`typedef typename Get_type<K, typename iterator_tag_traits<T>::value_tag>::type result_type;`
			`template<class U> result_type operator()(CGAL_FORWARDABLE(U) u, int i) const {`
			`typename Get_functor<K, Construct_ttag<T> >::type ci(this->kernel());`
			`return *cpp0x::next(ci(CGAL_FORWARD(U,u),Begin_tag()),i);`
			`}`
			`};`
			`//typedef typename Functor<typename iterator_tag_traits<T>::nth_element>::type nth_elem;`
			`template<class K, class T, bool = iterator_tag_traits<T>::has_nth_element>`
			`struct Select_nth_element_functor {`
			`typedef Nth_iterator_element<K, T> type;`
			`};`
			`template<class K, class T>`
			`struct Select_nth_element_functor <K, T, true> :`
			`Get_functor<K, typename iterator_tag_traits<T>::nth_element> {};`

			`namespace internal {`
			`template<class A,class B,class C,bool/is_NT=false/>`
			`struct Lazy_construction_maybe_nt {`
			`typedef Lazy_construction<A,B,C> type;`
			`};`
			`template<class A,class B,class C>`
			`struct Lazy_construction_maybe_nt<A,B,C,true> {`
			`typedef Lazy_construction_nt<A,B,C> type;`
			`};`
			`}`

			`template <class EK_, class AK_, class E2A_, class Kernel_>`
			`struct Lazy_cartesian_types`
			`{`
			`typedef typename typeset_intersection<`
			`typename AK_::Object_list,`
			`typename EK_::Object_list`
			`>::type Object_list;`

			`typedef typename typeset_intersection<`
			`typename AK_::Iterator_list,`
			`typename EK_::Iterator_list`
			`>::type Iterator_list;`

			`template <class T,class=typename Get_type_category<Kernel_,T>::type> struct Type {};`
			`template <class T> struct Type<T,Object_tag> {`
			`typedef Lazy<`
			`typename Get_type<AK_,T>::type,`
			`typename Get_type<EK_,T>::type,`
			`typename Get_type<EK_, FT_tag>::type,`
			`E2A_> type;`
			`};`
			`template <class T> struct Type<T,Number_tag> {`
			`typedef CGAL::Lazy_exact_nt<typename Get_type<EK_,T>::type> type;`
			`};`

			`template <class T> struct Iterator {`
			`typedef typename iterator_tag_traits<T>::value_tag Vt;`
			`typedef typename Type<Vt>::type V;`
			`typedef typename Select_nth_element_functor<AK_,T>::type AF;`
			`typedef typename Select_nth_element_functor<EK_,T>::type EF;`

			`typedef typename internal::Lazy_construction_maybe_nt<`
			`Kernel_, AF, EF, is_NT_tag<Vt>::value`
			`>::type nth_elem;`

			`typedef Iterator_from_indices<`
			`const typename Type<typename iterator_tag_traits<T>::container>::type,`
			`const V, V, nth_elem`
			`> type;`
			`};`
			`};`

			`template <class EK_, class AK_, class E2A_/, class Kernel_=Default/>`
			`struct Lazy_cartesian : Dimension_base<typename EK_::Default_ambient_dimension>,`
			`Lazy_cartesian_types<EK_,AK_,E2A_,Lazy_cartesian<EK_,AK_,E2A_> >`
			`{`
			`//CGAL_CONSTEXPR Lazy_cartesian(){}`
			`//CGAL_CONSTEXPR Lazy_cartesian(int d):Base_(d){}`

			`//TODO: Do we want to store an AK and an EK? Or just references?`
			`//FIXME: references would be better I guess.`
			`//TODO: In any case, make sure that we don't end up storing this kernel for`
			`//nothing (it is not empty but references empty kernels or something)`
			`AK_ ak; EK_ ek;`
			`AK_ const& approximate_kernel()const{return ak;}`
			`EK_ const& exact_kernel()const{return ek;}`

			`typedef Lazy_cartesian Self;`
			`typedef Lazy_cartesian_types<EK_,AK_,E2A_,Self> Base;`
			`//typedef typename Default::Get<Kernel_,Self>::type Kernel;`
			`typedef Self Kernel;`
			`typedef AK_ Approximate_kernel;`
			`typedef EK_ Exact_kernel;`
			`typedef E2A_ E2A;`
			`typedef Approx_converter<Kernel, Approximate_kernel> C2A;`
			`typedef Exact_converter<Kernel, Exact_kernel> C2E;`

			`typedef typename Exact_kernel::Rep_tag Rep_tag;`
			`typedef typename Exact_kernel::Kernel_tag Kernel_tag;`
			`typedef typename Exact_kernel::Default_ambient_dimension Default_ambient_dimension;`
			`typedef typename Exact_kernel::Max_ambient_dimension Max_ambient_dimension;`
			`//typedef typename Exact_kernel::Flat_orientation Flat_orientation;`
			`// Check that Approximate_kernel agrees with all that...`

			`template<class T,class D=void,class=typename Get_functor_category<Lazy_cartesian,T,D>::type> struct Functor {`
			`typedef Null_functor type;`
			`};`
			`//FIXME: what do we do with D here?`
			`template<class T,class D> struct Functor<T,D,Predicate_tag> {`
			`typedef typename Get_functor<Approximate_kernel, T>::type FA;`
			`typedef typename Get_functor<Exact_kernel, T>::type FE;`
			`typedef Filtered_predicate2<FE,FA,C2E,C2A> type;`
			`};`
			`template<class T,class D> struct Functor<T,D,Compute_tag> {`
			`typedef typename Get_functor<Approximate_kernel, T>::type FA;`
			`typedef typename Get_functor<Exact_kernel, T>::type FE;`
			`typedef Lazy_construction_nt<Kernel,FA,FE> type;`
			`};`
			`template<class T,class D> struct Functor<T,D,Construct_tag> {`
			`typedef typename Get_functor<Approximate_kernel, T>::type FA;`
			`typedef typename Get_functor<Exact_kernel, T>::type FE;`
			`typedef Lazy_construction<Kernel,FA,FE> type;`
			`};`

			`//typedef typename Iterator<Point_cartesian_const_iterator_tag>::type Point_cartesian_const_iterator;`
			`//typedef typename Iterator<Vector_cartesian_const_iterator_tag>::type Vector_cartesian_const_iterator;`

			`template<class U>`
			`struct Construct_iter : private Store_kernel<Kernel> {`
			`Construct_iter(){}`
			`Construct_iter(Kernel const&k):Store_kernel<Kernel>(k){}`
			`//FIXME: pass the kernel to the functor in the iterator`
			`typedef U result_type;`
			`template<class T>`
			`result_type operator()(T const& t,Begin_tag)const{`
			`return result_type(t,0,this->kernel());`
			`}`
			`template<class T>`
			`result_type operator()(T const& t,End_tag)const{`
			`return result_type(t,Self().dimension(),this->kernel());`
			`}`
			`};`
			`template<class T,class D> struct Functor<T,D,Construct_iterator_tag> {`
			`typedef Construct_iter<typename Base::template Iterator<typename map_result_tag<T>::type>::type> type;`
			`};`


			`//TODO: what about other functors of the Misc category?`
			`// for Point_dimension, we should apply it to the approximate point`
			`// for printing, we should??? just not do printing this way?`
			`};`


			`} //namespace CGAL`

			`#endif // CGAL_KERNEL_D_LAZY_CARTESIAN_H`