boost_1_45_0/boost/multi_index/detail/rnd_index_loader.hpp - nest-learning-thermostat/5.0/boost - Git at Google

 /* Copyright 2003-2008 Joaquin M Lopez Munoz.
  * Distributed under the Boost Software License, Version 1.0.
  * (See accompanying file LICENSE_1_0.txt or copy at
  * http://www.boost.org/LICENSE_1_0.txt)
  *
  * See http://www.boost.org/libs/multi_index for library home page.
  */

 #ifndef BOOST_MULTI_INDEX_DETAIL_RND_INDEX_LOADER_HPP
 #define BOOST_MULTI_INDEX_DETAIL_RND_INDEX_LOADER_HPP

 #if defined(_MSC_VER)&&(_MSC_VER>=1200)
 #pragma once
 #endif

 #include <boost/config.hpp> /* keep it first to prevent nasty warns in MSVC */
 #include <algorithm>
 #include <boost/detail/allocator_utilities.hpp>
 #include <boost/multi_index/detail/auto_space.hpp>
 #include <boost/multi_index/detail/prevent_eti.hpp>
 #include <boost/multi_index/detail/rnd_index_ptr_array.hpp>
 #include <boost/noncopyable.hpp>
 #include <cstddef>

 namespace boost{

 namespace multi_index{

 namespace detail{

 /* This class implements a serialization rearranger for random access
  * indices. In order to achieve O(n) performance, the following strategy
  * is followed: the nodes of the index are handled as if in a bidirectional
  * list, where the next pointers are stored in the original
  * random_access_index_ptr_array and the prev pointers are stored in
  * an auxiliary array. Rearranging of nodes in such a bidirectional list
  * is constant time. Once all the arrangements are performed (on destruction
  * time) the list is traversed in reverse order and
  * pointers are swapped and set accordingly so that they recover its
  * original semantics ( *(node->up())==node ) while retaining the
  * new order.
  */

 template<typename Allocator>
 class random_access_index_loader_base:private noncopyable
 {
 protected:
   typedef typename prevent_eti<
     Allocator,
     random_access_index_node_impl<
       typename boost::detail::allocator::rebind_to<
         Allocator,
         char
       >::type
     >
   >::type                                           node_impl_type;
   typedef typename node_impl_type::pointer          node_impl_pointer;
   typedef random_access_index_ptr_array<Allocator>  ptr_array;

   random_access_index_loader_base(const Allocator& al_,ptr_array& ptrs_):
     al(al_),
     ptrs(ptrs_),
     header(*ptrs.end()),
     prev_spc(al,0),
     preprocessed(false)
   {}

   ~random_access_index_loader_base()
   {
     if(preprocessed)
     {
       node_impl_pointer n=header;
       next(n)=n;

       for(std::size_t i=ptrs.size();i--;){
         n=prev(n);
         std::size_t d=position(n);
         if(d!=i){
           node_impl_pointer m=prev(next_at(i));
           std::swap(m->up(),n->up());
           next_at(d)=next_at(i);
           std::swap(prev_at(d),prev_at(i));
         }
         next(n)=n;
       }
     }
   }

   void rearrange(node_impl_pointer position,node_impl_pointer x)
   {
     preprocess(); /* only incur this penalty if rearrange() is ever called */
     if(position==node_impl_pointer(0))position=header;
     next(prev(x))=next(x);
     prev(next(x))=prev(x);
     prev(x)=position;
     next(x)=next(position);
     next(prev(x))=prev(next(x))=x;
   }

 private:
   void preprocess()
   {
     if(!preprocessed){
       /* get space for the auxiliary prev array */
       auto_space<node_impl_pointer,Allocator> tmp(al,ptrs.size()+1);
       prev_spc.swap(tmp);

       /* prev_spc elements point to the prev nodes */
       std::rotate_copy(
         &*ptrs.begin(),&*ptrs.end(),&*ptrs.end()+1,&*prev_spc.data());

       /* ptrs elements point to the next nodes */
       std::rotate(&*ptrs.begin(),&*ptrs.begin()+1,&*ptrs.end()+1);

       preprocessed=true;
     }
   }

   std::size_t position(node_impl_pointer x)const
   {
     return (std::size_t)(x->up()-ptrs.begin());
   }

   node_impl_pointer& next_at(std::size_t n)const
   {
     return *ptrs.at(n);
   }

   node_impl_pointer& prev_at(std::size_t n)const
   {
     return *(prev_spc.data()+n);
   }

   node_impl_pointer& next(node_impl_pointer x)const
   {
     return *(x->up());
   }

   node_impl_pointer& prev(node_impl_pointer x)const
   {
     return prev_at(position(x));
   }

   Allocator                               al;
   ptr_array&                              ptrs;
   node_impl_pointer                       header;
   auto_space<node_impl_pointer,Allocator> prev_spc;
   bool                                    preprocessed;
 };

 template<typename Node,typename Allocator>
 class random_access_index_loader:
   private random_access_index_loader_base<Allocator>
 {
   typedef random_access_index_loader_base<Allocator> super;
   typedef typename super::node_impl_pointer          node_impl_pointer;
   typedef typename super::ptr_array                  ptr_array;

 public:
   random_access_index_loader(const Allocator& al_,ptr_array& ptrs_):
     super(al_,ptrs_)
   {}

   void rearrange(Node* position,Node *x)
   {
     super::rearrange(position?position->impl():node_impl_pointer(0),x->impl());
   }
 };

 } /* namespace multi_index::detail */

 } /* namespace multi_index */

 } /* namespace boost */

 #endif
	/* Copyright 2003-2008 Joaquin M Lopez Munoz.
	* Distributed under the Boost Software License, Version 1.0.
	* (See accompanying file LICENSE_1_0.txt or copy at
	* http://www.boost.org/LICENSE_1_0.txt)
	*
	* See http://www.boost.org/libs/multi_index for library home page.
	*/

	#ifndef BOOST_MULTI_INDEX_DETAIL_RND_INDEX_LOADER_HPP
	#define BOOST_MULTI_INDEX_DETAIL_RND_INDEX_LOADER_HPP

	#if defined(_MSC_VER)&&(_MSC_VER>=1200)
	#pragma once
	#endif

	#include <boost/config.hpp> /* keep it first to prevent nasty warns in MSVC */
	#include <algorithm>
	#include <boost/detail/allocator_utilities.hpp>
	#include <boost/multi_index/detail/auto_space.hpp>
	#include <boost/multi_index/detail/prevent_eti.hpp>
	#include <boost/multi_index/detail/rnd_index_ptr_array.hpp>
	#include <boost/noncopyable.hpp>
	#include <cstddef>

	namespace boost{

	namespace multi_index{

	namespace detail{

	/* This class implements a serialization rearranger for random access
	* indices. In order to achieve O(n) performance, the following strategy
	* is followed: the nodes of the index are handled as if in a bidirectional
	* list, where the next pointers are stored in the original
	* random_access_index_ptr_array and the prev pointers are stored in
	* an auxiliary array. Rearranging of nodes in such a bidirectional list
	* is constant time. Once all the arrangements are performed (on destruction
	* time) the list is traversed in reverse order and
	* pointers are swapped and set accordingly so that they recover its
	* original semantics ( *(node->up())==node ) while retaining the
	* new order.
	*/

	template<typename Allocator>
	class random_access_index_loader_base:private noncopyable
	{
	protected:
	typedef typename prevent_eti<
	Allocator,
	random_access_index_node_impl<
	typename boost::detail::allocator::rebind_to<
	Allocator,
	char
	>::type
	>
	>::type node_impl_type;
	typedef typename node_impl_type::pointer node_impl_pointer;
	typedef random_access_index_ptr_array<Allocator> ptr_array;

	random_access_index_loader_base(const Allocator& al_,ptr_array& ptrs_):
	al(al_),
	ptrs(ptrs_),
	header(*ptrs.end()),
	prev_spc(al,0),
	preprocessed(false)
	{}

	~random_access_index_loader_base()
	{
	if(preprocessed)
	{
	node_impl_pointer n=header;
	next(n)=n;

	for(std::size_t i=ptrs.size();i--;){
	n=prev(n);
	std::size_t d=position(n);
	if(d!=i){
	node_impl_pointer m=prev(next_at(i));
	std::swap(m->up(),n->up());
	next_at(d)=next_at(i);
	std::swap(prev_at(d),prev_at(i));
	}
	next(n)=n;
	}
	}
	}

	void rearrange(node_impl_pointer position,node_impl_pointer x)
	{
	preprocess(); /* only incur this penalty if rearrange() is ever called */
	if(position==node_impl_pointer(0))position=header;
	next(prev(x))=next(x);
	prev(next(x))=prev(x);
	prev(x)=position;
	next(x)=next(position);
	next(prev(x))=prev(next(x))=x;
	}

	private:
	void preprocess()
	{
	if(!preprocessed){
	/* get space for the auxiliary prev array */
	auto_space<node_impl_pointer,Allocator> tmp(al,ptrs.size()+1);
	prev_spc.swap(tmp);

	/* prev_spc elements point to the prev nodes */
	std::rotate_copy(
	&ptrs.begin(),&ptrs.end(),&ptrs.end()+1,&prev_spc.data());

	/* ptrs elements point to the next nodes */
	std::rotate(&ptrs.begin(),&ptrs.begin()+1,&*ptrs.end()+1);

	preprocessed=true;
	}
	}

	std::size_t position(node_impl_pointer x)const
	{
	return (std::size_t)(x->up()-ptrs.begin());
	}

	node_impl_pointer& next_at(std::size_t n)const
	{
	return *ptrs.at(n);
	}

	node_impl_pointer& prev_at(std::size_t n)const
	{
	return *(prev_spc.data()+n);
	}

	node_impl_pointer& next(node_impl_pointer x)const
	{
	return *(x->up());
	}

	node_impl_pointer& prev(node_impl_pointer x)const
	{
	return prev_at(position(x));
	}

	Allocator al;
	ptr_array& ptrs;
	node_impl_pointer header;
	auto_space<node_impl_pointer,Allocator> prev_spc;
	bool preprocessed;
	};

	template<typename Node,typename Allocator>
	class random_access_index_loader:
	private random_access_index_loader_base<Allocator>
	{
	typedef random_access_index_loader_base<Allocator> super;
	typedef typename super::node_impl_pointer node_impl_pointer;
	typedef typename super::ptr_array ptr_array;

	public:
	random_access_index_loader(const Allocator& al_,ptr_array& ptrs_):
	super(al_,ptrs_)
	{}

	void rearrange(Node* position,Node *x)
	{
	super::rearrange(position?position->impl():node_impl_pointer(0),x->impl());
	}
	};

	} /* namespace multi_index::detail */

	} /* namespace multi_index */

	} /* namespace boost */

	#endif