utils/trie/trie.h - ndnSIM - Gitiles

 /* -*-  Mode: C++; c-file-style: "gnu"; indent-tabs-mode:nil; -*- */
 /*
  * Copyright (c) 2011 University of California, Los Angeles
  *
  * This program is free software; you can redistribute it and/or modify
  * it under the terms of the GNU General Public License version 2 as
  * published by the Free Software Foundation;
  *
  * This program is distributed in the hope that it will be useful,
  * but WITHOUT ANY WARRANTY; without even the implied warranty of
  * MERCHANTABILITY or FITNESS FOR A PARTICULAR PURPOSE.  See the
  * GNU General Public License for more details.
  *
  * You should have received a copy of the GNU General Public License
  * along with this program; if not, write to the Free Software
  * Foundation, Inc., 59 Temple Place, Suite 330, Boston, MA  02111-1307  USA
  *
  * Author: Alexander Afanasyev <alexander.afanasyev@ucla.edu>
  */

 #ifndef TRIE_H_
 #define TRIE_H_

 #include "ns3/ptr.h"

 #include <boost/intrusive/unordered_set.hpp>
 #include <boost/intrusive/list.hpp>
 #include <boost/intrusive/set.hpp>
 #include <boost/functional/hash.hpp>
 #include <boost/interprocess/smart_ptr/unique_ptr.hpp>
 #include <boost/tuple/tuple.hpp>
 #include <boost/foreach.hpp>
 #include <boost/mpl/if.hpp>

 namespace ns3 {
 namespace ndn {
 namespace ndnSIM {

 /////////////////////////////////////////////////////
 // Allow customization for payload
 //
 template<typename Payload, typename BasePayload = Payload>
 struct pointer_payload_traits
 {
   typedef Payload         payload_type; // general type of the payload
   typedef Payload*        storage_type; // how the payload is actually stored
   typedef Payload*        insert_type;  // what parameter is inserted

   typedef Payload*        return_type;  // what is returned on access
   typedef const Payload*  const_return_type; // what is returned on const access

   typedef BasePayload*       base_type;       // base type of the entry (when implementation details need to be hidden)
   typedef const BasePayload* const_base_type; // const base type of the entry (when implementation details need to be hidden)

   static Payload* empty_payload;
 };

 template<typename Payload, typename BasePayload>
 Payload*
 pointer_payload_traits<Payload, BasePayload>::empty_payload = 0;

 template<typename Payload, typename BasePayload = Payload>
 struct smart_pointer_payload_traits
 {
   typedef Payload                 payload_type;
   typedef ns3::Ptr<Payload>       storage_type;
   typedef ns3::Ptr<Payload>       insert_type;

   typedef ns3::Ptr<Payload>       return_type;
   typedef ns3::Ptr<const Payload> const_return_type;

   typedef ns3::Ptr<BasePayload> base_type;
   typedef ns3::Ptr<const BasePayload> const_base_type;

   static ns3::Ptr<Payload> empty_payload;
 };

 template<typename Payload, typename BasePayload>
 ns3::Ptr<Payload>
 smart_pointer_payload_traits<Payload, BasePayload>::empty_payload = 0;

 template<typename Payload, typename BasePayload = Payload>
 struct non_pointer_traits
 {
   typedef Payload         payload_type;
   typedef Payload         storage_type;
   typedef const Payload & insert_type; // nothing to insert

   typedef Payload&        return_type;
   typedef const Payload & const_return_type;

   typedef BasePayload&       base_type;
   typedef const BasePayload& const_base_type;

   static Payload empty_payload;
 };

 template<typename Payload, typename BasePayload>
 Payload
 non_pointer_traits<Payload, BasePayload>::empty_payload = Payload ();


 ////////////////////////////////////////////////////
 // forward declarations
 //
 template<typename FullKey,
          typename PayloadTraits,
          typename PolicyHook >
 class trie;

 template<typename FullKey, typename PayloadTraits, typename PolicyHook>
 inline std::ostream&
 operator << (std::ostream &os,
              const trie<FullKey, PayloadTraits, PolicyHook> &trie_node);

 template<typename FullKey, typename PayloadTraits, typename PolicyHook>
 bool
 operator== (const trie<FullKey, PayloadTraits, PolicyHook> &a,
             const trie<FullKey, PayloadTraits, PolicyHook> &b);

 template<typename FullKey, typename PayloadTraits, typename PolicyHook >
 std::size_t
 hash_value (const trie<FullKey, PayloadTraits, PolicyHook> &trie_node);

 ///////////////////////////////////////////////////
 // actual definition
 //
 template<class T, class NonConstT>
 class trie_iterator;

 template<class T>
 class trie_point_iterator;

 template<typename FullKey,
 	 typename PayloadTraits,
          typename PolicyHook >
 class trie
 {
 public:
   typedef typename FullKey::partial_type Key;

   typedef trie*       iterator;
   typedef const trie* const_iterator;

   typedef trie_iterator<trie, trie> recursive_iterator;
   typedef trie_iterator<const trie, trie> const_recursive_iterator;

   typedef trie_point_iterator<trie> point_iterator;
   typedef trie_point_iterator<const trie> const_point_iterator;

   typedef PayloadTraits payload_traits;

   inline
   trie (const Key &key, size_t bucketSize = 10, size_t bucketIncrement = 10)
     : key_ (key)
     , initialBucketSize_ (bucketSize)
     , bucketIncrement_ (bucketIncrement)
     , bucketSize_ (initialBucketSize_)
     , buckets_ (new bucket_type [bucketSize_]) //cannot use normal pointer, because lifetime of buckets should be larger than lifetime of the container
     , children_ (bucket_traits (buckets_.get (), bucketSize_))
     , payload_ (PayloadTraits::empty_payload)
     , parent_ (0)
   {
   }

   inline
   ~trie ()
   {
     payload_ = PayloadTraits::empty_payload; // necessary for smart pointers...
     children_.clear_and_dispose (trie_delete_disposer ());
   }

   void
   clear ()
   {
     children_.clear_and_dispose (trie_delete_disposer ());
   }

   template<class Predicate>
   void
   clear_if (Predicate cond)
   {
     recursive_iterator trieNode (this);
     recursive_iterator end (0);

     while (trieNode != end)
       {
         if (cond (*trieNode))
           {
             trieNode = recursive_iterator (trieNode->erase ());
           }
         trieNode ++;
       }
   }

   // actual entry
   friend bool
   operator== <> (const trie<FullKey, PayloadTraits, PolicyHook> &a,
                  const trie<FullKey, PayloadTraits, PolicyHook> &b);

   friend std::size_t
   hash_value <> (const trie<FullKey, PayloadTraits, PolicyHook> &trie_node);

   inline std::pair<iterator, bool>
   insert (const FullKey &key,
           typename PayloadTraits::insert_type payload)
   {
     trie *trieNode = this;

     BOOST_FOREACH (const Key &subkey, key)
       {
         typename unordered_set::iterator item = trieNode->children_.find (subkey);
         if (item == trieNode->children_.end ())
           {
             trie *newNode = new trie (subkey, initialBucketSize_, bucketIncrement_);
             // std::cout << "new " << newNode << "\n";
             newNode->parent_ = trieNode;

             if (trieNode->children_.size () >= trieNode->bucketSize_)
               {
                 trieNode->bucketSize_ += trieNode->bucketIncrement_;
                 trieNode->bucketIncrement_ *= 2; // increase bucketIncrement exponentially

                 buckets_array newBuckets (new bucket_type [trieNode->bucketSize_]);
                 trieNode->children_.rehash (bucket_traits (newBuckets.get (), trieNode->bucketSize_));
                 trieNode->buckets_.swap (newBuckets);
               }

             std::pair< typename unordered_set::iterator, bool > ret =
               trieNode->children_.insert (*newNode);

             trieNode = &(*ret.first);
           }
         else
           trieNode = &(*item);
       }

     if (trieNode->payload_ == PayloadTraits::empty_payload)
       {
         trieNode->payload_ = payload;
         return std::make_pair (trieNode, true);
       }
     else
       return std::make_pair (trieNode, false);
   }

   /**
    * @brief Removes payload (if it exists) and if there are no children, prunes parents trie
    */
   inline iterator
   erase ()
   {
     payload_ = PayloadTraits::empty_payload;
     return prune ();
   }

   /**
    * @brief Do exactly as erase, but without erasing the payload
    */
   inline iterator
   prune ()
   {
     if (payload_ == PayloadTraits::empty_payload &&
         children_.size () == 0)
       {
         if (parent_ == 0) return this;

         trie *parent = parent_;
         parent->children_.erase_and_dispose (*this, trie_delete_disposer ()); // delete this; basically, committing a suicide

         return parent->prune ();
       }
     return this;
   }

   /**
    * @brief Perform prune of the node, but without attempting to parent of the node
    */
   inline void
   prune_node ()
   {
     if (payload_ == PayloadTraits::empty_payload &&
         children_.size () == 0)
       {
         if (parent_ == 0) return;

         trie *parent = parent_;
         parent->children_.erase_and_dispose (*this, trie_delete_disposer ()); // delete this; basically, committing a suicide
       }
   }

   // inline boost::tuple<const iterator, bool, const iterator>
   // find (const FullKey &key) const
   // {
   //   return const_cast<trie*> (this)->find (key);
   // }

   /**
    * @brief Perform the longest prefix match
    * @param key the key for which to perform the longest prefix match
    *
    * @return ->second is true if prefix in ->first is longer than key
    */
   inline boost::tuple<iterator, bool, iterator>
   find (const FullKey &key)
   {
     trie *trieNode = this;
     iterator foundNode = (payload_ != PayloadTraits::empty_payload) ? this : 0;
     bool reachLast = true;

     BOOST_FOREACH (const Key &subkey, key)
       {
         typename unordered_set::iterator item = trieNode->children_.find (subkey);
         if (item == trieNode->children_.end ())
           {
             reachLast = false;
             break;
           }
         else
           {
             trieNode = &(*item);

             if (trieNode->payload_ != PayloadTraits::empty_payload)
               foundNode = trieNode;
           }
       }

     return boost::make_tuple (foundNode, reachLast, trieNode);
   }

   /**
    * @brief Perform the longest prefix match satisfying preficate
    * @param key the key for which to perform the longest prefix match
    *
    * @return ->second is true if prefix in ->first is longer than key
    */
   template<class Predicate>
   inline boost::tuple<iterator, bool, iterator>
   find_if (const FullKey &key, Predicate pred)
   {
     trie *trieNode = this;
     iterator foundNode = (payload_ != PayloadTraits::empty_payload) ? this : 0;
     bool reachLast = true;

     BOOST_FOREACH (const Key &subkey, key)
       {
         typename unordered_set::iterator item = trieNode->children_.find (subkey);
         if (item == trieNode->children_.end ())
           {
             reachLast = false;
             break;
           }
         else
           {
             trieNode = &(*item);

             if (trieNode->payload_ != PayloadTraits::empty_payload &&
                 pred (trieNode->payload_))
               {
                 foundNode = trieNode;
               }
           }
       }

     return boost::make_tuple (foundNode, reachLast, trieNode);
   }

   /**
    * @brief Find next payload of the sub-trie
    * @returns end() or a valid iterator pointing to the trie leaf (order is not defined, enumeration )
    */
   inline iterator
   find ()
   {
     if (payload_ != PayloadTraits::empty_payload)
       return this;

     typedef trie<FullKey, PayloadTraits, PolicyHook> trie;
     for (typename trie::unordered_set::iterator subnode = children_.begin ();
          subnode != children_.end ();
          subnode++ )
       // BOOST_FOREACH (trie &subnode, children_)
       {
         iterator value = subnode->find ();
         if (value != 0)
           return value;
       }

     return 0;
   }

   /**
    * @brief Find next payload of the sub-trie satisfying the predicate
    * @param pred predicate
    * @returns end() or a valid iterator pointing to the trie leaf (order is not defined, enumeration )
    */
   template<class Predicate>
   inline const iterator
   find_if (Predicate pred)
   {
     if (payload_ != PayloadTraits::empty_payload && pred (payload_))
       return this;

     typedef trie<FullKey, PayloadTraits, PolicyHook> trie;
     for (typename trie::unordered_set::iterator subnode = children_.begin ();
          subnode != children_.end ();
          subnode++ )
       // BOOST_FOREACH (const trie &subnode, children_)
       {
         iterator value = subnode->find_if (pred);
         if (value != 0)
           return value;
       }

     return 0;
   }

   iterator end ()
   {
     return 0;
   }

   const_iterator end () const
   {
     return 0;
   }

   typename PayloadTraits::const_return_type
   payload () const
   {
     return payload_;
   }

   typename PayloadTraits::return_type
   payload ()
   {
     return payload_;
   }

   void
   set_payload (typename PayloadTraits::insert_type payload)
   {
     payload_ = payload;
   }

   Key key () const
   {
     return key_;
   }

   inline void
   PrintStat (std::ostream &os) const;

 private:
   //The disposer object function
   struct trie_delete_disposer
   {
     void operator() (trie *delete_this)
     {
       delete delete_this;
     }
   };

   template<class D>
   struct array_disposer
   {
     void operator() (D *array)
     {
       delete [] array;
     }
   };

   friend
   std::ostream&
   operator<< < > (std::ostream &os, const trie &trie_node);

 public:
   PolicyHook policy_hook_;

 private:
   boost::intrusive::unordered_set_member_hook<> unordered_set_member_hook_;

   // necessary typedefs
   typedef trie self_type;
   typedef boost::intrusive::member_hook< trie,
                                          boost::intrusive::unordered_set_member_hook< >,
                                          &trie::unordered_set_member_hook_ > member_hook;

   typedef boost::intrusive::unordered_set< trie, member_hook > unordered_set;
   typedef typename unordered_set::bucket_type   bucket_type;
   typedef typename unordered_set::bucket_traits bucket_traits;

   template<class T, class NonConstT>
   friend class trie_iterator;

   template<class T>
   friend class trie_point_iterator;

   ////////////////////////////////////////////////
   // Actual data
   ////////////////////////////////////////////////

   Key key_; ///< name component

   size_t initialBucketSize_;
   size_t bucketIncrement_;

   size_t bucketSize_;
   typedef boost::interprocess::unique_ptr< bucket_type, array_disposer<bucket_type> > buckets_array;
   buckets_array buckets_;
   unordered_set children_;

   typename PayloadTraits::storage_type payload_;
   trie *parent_; // to make cleaning effective
 };


 template<typename FullKey, typename PayloadTraits, typename PolicyHook>
 inline std::ostream&
 operator << (std::ostream &os, const trie<FullKey, PayloadTraits, PolicyHook> &trie_node)
 {
   os << "# " << trie_node.key_ << ((trie_node.payload_ != PayloadTraits::empty_payload)?"*":"") << std::endl;
   typedef trie<FullKey, PayloadTraits, PolicyHook> trie;

   for (typename trie::unordered_set::const_iterator subnode = trie_node.children_.begin ();
        subnode != trie_node.children_.end ();
        subnode++ )
   // BOOST_FOREACH (const trie &subnode, trie_node.children_)
     {
       os << "\"" << &trie_node << "\"" << " [label=\"" << trie_node.key_ << ((trie_node.payload_ != PayloadTraits::empty_payload)?"*":"") << "\"]\n";
       os << "\"" << &(*subnode) << "\"" << " [label=\"" << subnode->key_ << ((subnode->payload_ != PayloadTraits::empty_payload)?"*":"") << "\"]""\n";

       os << "\"" << &trie_node << "\"" << " -> " << "\"" << &(*subnode) << "\"" << "\n";
       os << *subnode;
     }

   return os;
 }

 template<typename FullKey, typename PayloadTraits, typename PolicyHook>
 inline void
 trie<FullKey, PayloadTraits, PolicyHook>
 ::PrintStat (std::ostream &os) const
 {
   os << "# " << key_ << ((payload_ != PayloadTraits::empty_payload)?"*":"") << ": " << children_.size() << " children" << std::endl;
   for (size_t bucket = 0, maxbucket = children_.bucket_count ();
        bucket < maxbucket;
        bucket++)
     {
       os << " " << children_.bucket_size (bucket);
     }
   os << "\n";

   typedef trie<FullKey, PayloadTraits, PolicyHook> trie;
   for (typename trie::unordered_set::const_iterator subnode = children_.begin ();
        subnode != children_.end ();
        subnode++ )
   // BOOST_FOREACH (const trie &subnode, children_)
     {
       subnode->PrintStat (os);
     }
 }


 template<typename FullKey, typename PayloadTraits, typename PolicyHook>
 inline bool
 operator == (const trie<FullKey, PayloadTraits, PolicyHook> &a,
              const trie<FullKey, PayloadTraits, PolicyHook> &b)
 {
   return a.key_ == b.key_;
 }

 template<typename FullKey, typename PayloadTraits, typename PolicyHook>
 inline std::size_t
 hash_value (const trie<FullKey, PayloadTraits, PolicyHook> &trie_node)
 {
   return boost::hash_value (trie_node.key_);
 }


 template<class Trie, class NonConstTrie> // hack for boost < 1.47
 class trie_iterator
 {
 public:
   trie_iterator () : trie_ (0) {}
   trie_iterator (typename Trie::iterator item) : trie_ (item) {}
   trie_iterator (Trie &item) : trie_ (&item) {}

   Trie & operator* () { return *trie_; }
   const Trie & operator* () const { return *trie_; }
   Trie * operator-> () { return trie_; }
   const Trie * operator-> () const { return trie_; }
   bool operator== (trie_iterator<const Trie, NonConstTrie> &other) const { return (trie_ == other.trie_); }
   bool operator== (trie_iterator<Trie, NonConstTrie> &other) { return (trie_ == other.trie_); }
   bool operator!= (trie_iterator<const Trie, NonConstTrie> &other) const { return !(*this == other); }
   bool operator!= (trie_iterator<Trie, NonConstTrie> &other) { return !(*this == other); }

   trie_iterator<Trie,NonConstTrie> &
   operator++ (int)
   {
     if (trie_->children_.size () > 0)
       trie_ = &(*trie_->children_.begin ());
     else
       trie_ = goUp ();
     return *this;
   }

   trie_iterator<Trie,NonConstTrie> &
   operator++ ()
   {
     (*this)++;
     return *this;
   }

 private:
   typedef typename boost::mpl::if_< boost::is_same<Trie, NonConstTrie>,
                                     typename Trie::unordered_set::iterator,
                                     typename Trie::unordered_set::const_iterator>::type set_iterator;

   Trie* goUp ()
   {
     if (trie_->parent_ != 0)
       {
         // typename Trie::unordered_set::iterator item =
         set_iterator item = const_cast<NonConstTrie*>(trie_)->parent_->children_.iterator_to (const_cast<NonConstTrie&> (*trie_));
         item++;
         if (item != trie_->parent_->children_.end ())
           {
             return &(*item);
           }
         else
           {
             trie_ = trie_->parent_;
             return goUp ();
           }
       }
     else
       return 0;
   }
 private:
   Trie *trie_;
 };


 template<class Trie>
 class trie_point_iterator
 {
 private:
   typedef typename boost::mpl::if_< boost::is_same<Trie, const Trie>,
                                     typename Trie::unordered_set::const_iterator,
                                     typename Trie::unordered_set::iterator>::type set_iterator;

 public:
   trie_point_iterator () : trie_ (0) {}
   trie_point_iterator (typename Trie::iterator item) : trie_ (item) {}
   trie_point_iterator (Trie &item)
   {
     if (item.children_.size () != 0)
       trie_ = &*item.children_.begin ();
     else
       trie_ = 0;
   }

   Trie & operator* () { return *trie_; }
   const Trie & operator* () const { return *trie_; }
   Trie * operator-> () { return trie_; }
   const Trie * operator-> () const { return trie_; }
   bool operator== (trie_point_iterator<const Trie> &other) const { return (trie_ == other.trie_); }
   bool operator== (trie_point_iterator<Trie> &other) { return (trie_ == other.trie_); }
   bool operator!= (trie_point_iterator<const Trie> &other) const { return !(*this == other); }
   bool operator!= (trie_point_iterator<Trie> &other) { return !(*this == other); }

   trie_point_iterator<Trie> &
   operator++ (int)
   {
     if (trie_->parent_ != 0)
       {
         set_iterator item = trie_->parent_->children_.iterator_to (*trie_);
         item ++;
         if (item == trie_->parent_->children_.end ())
           trie_ = 0;
         else
           trie_ = &*item;
       }
     else
       {
         trie_ = 0;
       }
     return *this;
   }

   trie_point_iterator<Trie> &
   operator++ ()
   {
     (*this)++;
     return *this;
   }

 private:
   Trie *trie_;
 };


 } // ndnSIM
 } // ndn
 } // ns3

 #endif // TRIE_H_
	/* -- Mode: C++; c-file-style: "gnu"; indent-tabs-mode:nil; -- */
	/*
	* Copyright (c) 2011 University of California, Los Angeles
	*
	* This program is free software; you can redistribute it and/or modify
	* it under the terms of the GNU General Public License version 2 as
	* published by the Free Software Foundation;
	*
	* This program is distributed in the hope that it will be useful,
	* but WITHOUT ANY WARRANTY; without even the implied warranty of
	* MERCHANTABILITY or FITNESS FOR A PARTICULAR PURPOSE. See the
	* GNU General Public License for more details.
	*
	* You should have received a copy of the GNU General Public License
	* along with this program; if not, write to the Free Software
	* Foundation, Inc., 59 Temple Place, Suite 330, Boston, MA 02111-1307 USA
	*
	* Author: Alexander Afanasyev <alexander.afanasyev@ucla.edu>
	*/

	#ifndef TRIE_H_
	#define TRIE_H_

	#include "ns3/ptr.h"

	#include <boost/intrusive/unordered_set.hpp>
	#include <boost/intrusive/list.hpp>
	#include <boost/intrusive/set.hpp>
	#include <boost/functional/hash.hpp>
	#include <boost/interprocess/smart_ptr/unique_ptr.hpp>
	#include <boost/tuple/tuple.hpp>
	#include <boost/foreach.hpp>
	#include <boost/mpl/if.hpp>

	namespace ns3 {
	namespace ndn {
	namespace ndnSIM {

	/////////////////////////////////////////////////////
	// Allow customization for payload
	//
	template<typename Payload, typename BasePayload = Payload>
	struct pointer_payload_traits
	{
	typedef Payload payload_type; // general type of the payload
	typedef Payload* storage_type; // how the payload is actually stored
	typedef Payload* insert_type; // what parameter is inserted

	typedef Payload* return_type; // what is returned on access
	typedef const Payload* const_return_type; // what is returned on const access

	typedef BasePayload* base_type; // base type of the entry (when implementation details need to be hidden)
	typedef const BasePayload* const_base_type; // const base type of the entry (when implementation details need to be hidden)

	static Payload* empty_payload;
	};

	template<typename Payload, typename BasePayload>
	Payload*
	pointer_payload_traits<Payload, BasePayload>::empty_payload = 0;

	template<typename Payload, typename BasePayload = Payload>
	struct smart_pointer_payload_traits
	{
	typedef Payload payload_type;
	typedef ns3::Ptr<Payload> storage_type;
	typedef ns3::Ptr<Payload> insert_type;

	typedef ns3::Ptr<Payload> return_type;
	typedef ns3::Ptr<const Payload> const_return_type;

	typedef ns3::Ptr<BasePayload> base_type;
	typedef ns3::Ptr<const BasePayload> const_base_type;

	static ns3::Ptr<Payload> empty_payload;
	};

	template<typename Payload, typename BasePayload>
	ns3::Ptr<Payload>
	smart_pointer_payload_traits<Payload, BasePayload>::empty_payload = 0;

	template<typename Payload, typename BasePayload = Payload>
	struct non_pointer_traits
	{
	typedef Payload payload_type;
	typedef Payload storage_type;
	typedef const Payload & insert_type; // nothing to insert

	typedef Payload& return_type;
	typedef const Payload & const_return_type;

	typedef BasePayload& base_type;
	typedef const BasePayload& const_base_type;

	static Payload empty_payload;
	};

	template<typename Payload, typename BasePayload>
	Payload
	non_pointer_traits<Payload, BasePayload>::empty_payload = Payload ();


	////////////////////////////////////////////////////
	// forward declarations
	//
	template<typename FullKey,
	typename PayloadTraits,
	typename PolicyHook >
	class trie;

	template<typename FullKey, typename PayloadTraits, typename PolicyHook>
	inline std::ostream&
	operator << (std::ostream &os,
	const trie<FullKey, PayloadTraits, PolicyHook> &trie_node);

	template<typename FullKey, typename PayloadTraits, typename PolicyHook>
	bool
	operator== (const trie<FullKey, PayloadTraits, PolicyHook> &a,
	const trie<FullKey, PayloadTraits, PolicyHook> &b);

	template<typename FullKey, typename PayloadTraits, typename PolicyHook >
	std::size_t
	hash_value (const trie<FullKey, PayloadTraits, PolicyHook> &trie_node);

	///////////////////////////////////////////////////
	// actual definition
	//
	template<class T, class NonConstT>
	class trie_iterator;

	template<class T>
	class trie_point_iterator;

	template<typename FullKey,
	typename PayloadTraits,
	typename PolicyHook >
	class trie
	{
	public:
	typedef typename FullKey::partial_type Key;

	typedef trie* iterator;
	typedef const trie* const_iterator;

	typedef trie_iterator<trie, trie> recursive_iterator;
	typedef trie_iterator<const trie, trie> const_recursive_iterator;

	typedef trie_point_iterator<trie> point_iterator;
	typedef trie_point_iterator<const trie> const_point_iterator;

	typedef PayloadTraits payload_traits;

	inline
	trie (const Key &key, size_t bucketSize = 10, size_t bucketIncrement = 10)
	: key_ (key)
	, initialBucketSize_ (bucketSize)
	, bucketIncrement_ (bucketIncrement)
	, bucketSize_ (initialBucketSize_)
	, buckets_ (new bucket_type [bucketSize_]) //cannot use normal pointer, because lifetime of buckets should be larger than lifetime of the container
	, children_ (bucket_traits (buckets_.get (), bucketSize_))
	, payload_ (PayloadTraits::empty_payload)
	, parent_ (0)
	{
	}

	inline
	~trie ()
	{
	payload_ = PayloadTraits::empty_payload; // necessary for smart pointers...
	children_.clear_and_dispose (trie_delete_disposer ());
	}

	void
	clear ()
	{
	children_.clear_and_dispose (trie_delete_disposer ());
	}

	template<class Predicate>
	void
	clear_if (Predicate cond)
	{
	recursive_iterator trieNode (this);
	recursive_iterator end (0);

	while (trieNode != end)
	{
	if (cond (*trieNode))
	{
	trieNode = recursive_iterator (trieNode->erase ());
	}
	trieNode ++;
	}
	}

	// actual entry
	friend bool
	operator== <> (const trie<FullKey, PayloadTraits, PolicyHook> &a,
	const trie<FullKey, PayloadTraits, PolicyHook> &b);

	friend std::size_t
	hash_value <> (const trie<FullKey, PayloadTraits, PolicyHook> &trie_node);

	inline std::pair<iterator, bool>
	insert (const FullKey &key,
	typename PayloadTraits::insert_type payload)
	{
	trie *trieNode = this;

	BOOST_FOREACH (const Key &subkey, key)
	{
	typename unordered_set::iterator item = trieNode->children_.find (subkey);
	if (item == trieNode->children_.end ())
	{
	trie *newNode = new trie (subkey, initialBucketSize_, bucketIncrement_);
	// std::cout << "new " << newNode << "\n";
	newNode->parent_ = trieNode;

	if (trieNode->children_.size () >= trieNode->bucketSize_)
	{
	trieNode->bucketSize_ += trieNode->bucketIncrement_;
	trieNode->bucketIncrement_ *= 2; // increase bucketIncrement exponentially

	buckets_array newBuckets (new bucket_type [trieNode->bucketSize_]);
	trieNode->children_.rehash (bucket_traits (newBuckets.get (), trieNode->bucketSize_));
	trieNode->buckets_.swap (newBuckets);
	}

	std::pair< typename unordered_set::iterator, bool > ret =
	trieNode->children_.insert (*newNode);

	trieNode = &(*ret.first);
	}
	else
	trieNode = &(*item);
	}

	if (trieNode->payload_ == PayloadTraits::empty_payload)
	{
	trieNode->payload_ = payload;
	return std::make_pair (trieNode, true);
	}
	else
	return std::make_pair (trieNode, false);
	}

	/**
	* @brief Removes payload (if it exists) and if there are no children, prunes parents trie
	*/
	inline iterator
	erase ()
	{
	payload_ = PayloadTraits::empty_payload;
	return prune ();
	}

	/**
	* @brief Do exactly as erase, but without erasing the payload
	*/
	inline iterator
	prune ()
	{
	if (payload_ == PayloadTraits::empty_payload &&
	children_.size () == 0)
	{
	if (parent_ == 0) return this;

	trie *parent = parent_;
	parent->children_.erase_and_dispose (*this, trie_delete_disposer ()); // delete this; basically, committing a suicide

	return parent->prune ();
	}
	return this;
	}

	/**
	* @brief Perform prune of the node, but without attempting to parent of the node
	*/
	inline void
	prune_node ()
	{
	if (payload_ == PayloadTraits::empty_payload &&
	children_.size () == 0)
	{
	if (parent_ == 0) return;

	trie *parent = parent_;
	parent->children_.erase_and_dispose (*this, trie_delete_disposer ()); // delete this; basically, committing a suicide
	}
	}

	// inline boost::tuple<const iterator, bool, const iterator>
	// find (const FullKey &key) const
	// {
	// return const_cast<trie*> (this)->find (key);
	// }

	/**
	* @brief Perform the longest prefix match
	* @param key the key for which to perform the longest prefix match
	*
	* @return ->second is true if prefix in ->first is longer than key
	*/
	inline boost::tuple<iterator, bool, iterator>
	find (const FullKey &key)
	{
	trie *trieNode = this;
	iterator foundNode = (payload_ != PayloadTraits::empty_payload) ? this : 0;
	bool reachLast = true;

	BOOST_FOREACH (const Key &subkey, key)
	{
	typename unordered_set::iterator item = trieNode->children_.find (subkey);
	if (item == trieNode->children_.end ())
	{
	reachLast = false;
	break;
	}
	else
	{
	trieNode = &(*item);

	if (trieNode->payload_ != PayloadTraits::empty_payload)
	foundNode = trieNode;
	}
	}

	return boost::make_tuple (foundNode, reachLast, trieNode);
	}

	/**
	* @brief Perform the longest prefix match satisfying preficate
	* @param key the key for which to perform the longest prefix match
	*
	* @return ->second is true if prefix in ->first is longer than key
	*/
	template<class Predicate>
	inline boost::tuple<iterator, bool, iterator>
	find_if (const FullKey &key, Predicate pred)
	{
	trie *trieNode = this;
	iterator foundNode = (payload_ != PayloadTraits::empty_payload) ? this : 0;
	bool reachLast = true;

	BOOST_FOREACH (const Key &subkey, key)
	{
	typename unordered_set::iterator item = trieNode->children_.find (subkey);
	if (item == trieNode->children_.end ())
	{
	reachLast = false;
	break;
	}
	else
	{
	trieNode = &(*item);

	if (trieNode->payload_ != PayloadTraits::empty_payload &&
	pred (trieNode->payload_))
	{
	foundNode = trieNode;
	}
	}
	}

	return boost::make_tuple (foundNode, reachLast, trieNode);
	}

	/**
	* @brief Find next payload of the sub-trie
	* @returns end() or a valid iterator pointing to the trie leaf (order is not defined, enumeration )
	*/
	inline iterator
	find ()
	{
	if (payload_ != PayloadTraits::empty_payload)
	return this;

	typedef trie<FullKey, PayloadTraits, PolicyHook> trie;
	for (typename trie::unordered_set::iterator subnode = children_.begin ();
	subnode != children_.end ();
	subnode++ )
	// BOOST_FOREACH (trie &subnode, children_)
	{
	iterator value = subnode->find ();
	if (value != 0)
	return value;
	}

	return 0;
	}

	/**
	* @brief Find next payload of the sub-trie satisfying the predicate
	* @param pred predicate
	* @returns end() or a valid iterator pointing to the trie leaf (order is not defined, enumeration )
	*/
	template<class Predicate>
	inline const iterator
	find_if (Predicate pred)
	{
	if (payload_ != PayloadTraits::empty_payload && pred (payload_))
	return this;

	typedef trie<FullKey, PayloadTraits, PolicyHook> trie;
	for (typename trie::unordered_set::iterator subnode = children_.begin ();
	subnode != children_.end ();
	subnode++ )
	// BOOST_FOREACH (const trie &subnode, children_)
	{
	iterator value = subnode->find_if (pred);
	if (value != 0)
	return value;
	}

	return 0;
	}

	iterator end ()
	{
	return 0;
	}

	const_iterator end () const
	{
	return 0;
	}

	typename PayloadTraits::const_return_type
	payload () const
	{
	return payload_;
	}

	typename PayloadTraits::return_type
	payload ()
	{
	return payload_;
	}

	void
	set_payload (typename PayloadTraits::insert_type payload)
	{
	payload_ = payload;
	}

	Key key () const
	{
	return key_;
	}

	inline void
	PrintStat (std::ostream &os) const;

	private:
	//The disposer object function
	struct trie_delete_disposer
	{
	void operator() (trie *delete_this)
	{
	delete delete_this;
	}
	};

	template<class D>
	struct array_disposer
	{
	void operator() (D *array)
	{
	delete [] array;
	}
	};

	friend
	std::ostream&
	operator<< < > (std::ostream &os, const trie &trie_node);

	public:
	PolicyHook policy_hook_;

	private:
	boost::intrusive::unordered_set_member_hook<> unordered_set_member_hook_;

	// necessary typedefs
	typedef trie self_type;
	typedef boost::intrusive::member_hook< trie,
	boost::intrusive::unordered_set_member_hook< >,
	&trie::unordered_set_member_hook_ > member_hook;

	typedef boost::intrusive::unordered_set< trie, member_hook > unordered_set;
	typedef typename unordered_set::bucket_type bucket_type;
	typedef typename unordered_set::bucket_traits bucket_traits;

	template<class T, class NonConstT>
	friend class trie_iterator;

	template<class T>
	friend class trie_point_iterator;

	////////////////////////////////////////////////
	// Actual data
	////////////////////////////////////////////////

	Key key_; ///< name component

	size_t initialBucketSize_;
	size_t bucketIncrement_;

	size_t bucketSize_;
	typedef boost::interprocess::unique_ptr< bucket_type, array_disposer<bucket_type> > buckets_array;
	buckets_array buckets_;
	unordered_set children_;

	typename PayloadTraits::storage_type payload_;
	trie *parent_; // to make cleaning effective
	};




	template<typename FullKey, typename PayloadTraits, typename PolicyHook>
	inline std::ostream&
	operator << (std::ostream &os, const trie<FullKey, PayloadTraits, PolicyHook> &trie_node)
	{
	os << "# " << trie_node.key_ << ((trie_node.payload_ != PayloadTraits::empty_payload)?"*":"") << std::endl;
	typedef trie<FullKey, PayloadTraits, PolicyHook> trie;

	for (typename trie::unordered_set::const_iterator subnode = trie_node.children_.begin ();
	subnode != trie_node.children_.end ();
	subnode++ )
	// BOOST_FOREACH (const trie &subnode, trie_node.children_)
	{
	os << "\"" << &trie_node << "\"" << " [label=\"" << trie_node.key_ << ((trie_node.payload_ != PayloadTraits::empty_payload)?"*":"") << "\"]\n";
	os << "\"" << &(subnode) << "\"" << " [label=\"" << subnode->key_ << ((subnode->payload_ != PayloadTraits::empty_payload)?"":"") << "\"]""\n";

	os << "\"" << &trie_node << "\"" << " -> " << "\"" << &(*subnode) << "\"" << "\n";
	os << *subnode;
	}

	return os;
	}

	template<typename FullKey, typename PayloadTraits, typename PolicyHook>
	inline void
	trie<FullKey, PayloadTraits, PolicyHook>
	::PrintStat (std::ostream &os) const
	{
	os << "# " << key_ << ((payload_ != PayloadTraits::empty_payload)?"*":"") << ": " << children_.size() << " children" << std::endl;
	for (size_t bucket = 0, maxbucket = children_.bucket_count ();
	bucket < maxbucket;
	bucket++)
	{
	os << " " << children_.bucket_size (bucket);
	}
	os << "\n";

	typedef trie<FullKey, PayloadTraits, PolicyHook> trie;
	for (typename trie::unordered_set::const_iterator subnode = children_.begin ();
	subnode != children_.end ();
	subnode++ )
	// BOOST_FOREACH (const trie &subnode, children_)
	{
	subnode->PrintStat (os);
	}
	}


	template<typename FullKey, typename PayloadTraits, typename PolicyHook>
	inline bool
	operator == (const trie<FullKey, PayloadTraits, PolicyHook> &a,
	const trie<FullKey, PayloadTraits, PolicyHook> &b)
	{
	return a.key_ == b.key_;
	}

	template<typename FullKey, typename PayloadTraits, typename PolicyHook>
	inline std::size_t
	hash_value (const trie<FullKey, PayloadTraits, PolicyHook> &trie_node)
	{
	return boost::hash_value (trie_node.key_);
	}



	template<class Trie, class NonConstTrie> // hack for boost < 1.47
	class trie_iterator
	{
	public:
	trie_iterator () : trie_ (0) {}
	trie_iterator (typename Trie::iterator item) : trie_ (item) {}
	trie_iterator (Trie &item) : trie_ (&item) {}

	Trie & operator* () { return *trie_; }
	const Trie & operator* () const { return *trie_; }
	Trie * operator-> () { return trie_; }
	const Trie * operator-> () const { return trie_; }
	bool operator== (trie_iterator<const Trie, NonConstTrie> &other) const { return (trie_ == other.trie_); }
	bool operator== (trie_iterator<Trie, NonConstTrie> &other) { return (trie_ == other.trie_); }
	bool operator!= (trie_iterator<const Trie, NonConstTrie> &other) const { return !(*this == other); }
	bool operator!= (trie_iterator<Trie, NonConstTrie> &other) { return !(*this == other); }

	trie_iterator<Trie,NonConstTrie> &
	operator++ (int)
	{
	if (trie_->children_.size () > 0)
	trie_ = &(*trie_->children_.begin ());
	else
	trie_ = goUp ();
	return *this;
	}

	trie_iterator<Trie,NonConstTrie> &
	operator++ ()
	{
	(*this)++;
	return *this;
	}

	private:
	typedef typename boost::mpl::if_< boost::is_same<Trie, NonConstTrie>,
	typename Trie::unordered_set::iterator,
	typename Trie::unordered_set::const_iterator>::type set_iterator;

	Trie* goUp ()
	{
	if (trie_->parent_ != 0)
	{
	// typename Trie::unordered_set::iterator item =
	set_iterator item = const_cast<NonConstTrie>(trie_)->parent_->children_.iterator_to (const_cast<NonConstTrie&> (trie_));
	item++;
	if (item != trie_->parent_->children_.end ())
	{
	return &(*item);
	}
	else
	{
	trie_ = trie_->parent_;
	return goUp ();
	}
	}
	else
	return 0;
	}
	private:
	Trie *trie_;
	};


	template<class Trie>
	class trie_point_iterator
	{
	private:
	typedef typename boost::mpl::if_< boost::is_same<Trie, const Trie>,
	typename Trie::unordered_set::const_iterator,
	typename Trie::unordered_set::iterator>::type set_iterator;

	public:
	trie_point_iterator () : trie_ (0) {}
	trie_point_iterator (typename Trie::iterator item) : trie_ (item) {}
	trie_point_iterator (Trie &item)
	{
	if (item.children_.size () != 0)
	trie_ = &*item.children_.begin ();
	else
	trie_ = 0;
	}

	Trie & operator* () { return *trie_; }
	const Trie & operator* () const { return *trie_; }
	Trie * operator-> () { return trie_; }
	const Trie * operator-> () const { return trie_; }
	bool operator== (trie_point_iterator<const Trie> &other) const { return (trie_ == other.trie_); }
	bool operator== (trie_point_iterator<Trie> &other) { return (trie_ == other.trie_); }
	bool operator!= (trie_point_iterator<const Trie> &other) const { return !(*this == other); }
	bool operator!= (trie_point_iterator<Trie> &other) { return !(*this == other); }

	trie_point_iterator<Trie> &
	operator++ (int)
	{
	if (trie_->parent_ != 0)
	{
	set_iterator item = trie_->parent_->children_.iterator_to (*trie_);
	item ++;
	if (item == trie_->parent_->children_.end ())
	trie_ = 0;
	else
	trie_ = &*item;
	}
	else
	{
	trie_ = 0;
	}
	return *this;
	}

	trie_point_iterator<Trie> &
	operator++ ()
	{
	(*this)++;
	return *this;
	}

	private:
	Trie *trie_;
	};


	} // ndnSIM
	} // ndn
	} // ns3

	#endif // TRIE_H_