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gerrit.named-data.net / ndnSIM / 460f57c4cfef060f9bf20f5226880242e7b50add / . / utils / trie / trie.hpp
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/* -*- Mode:C++; c-file-style:"gnu"; indent-tabs-mode:nil; -*- */
/**
* Copyright (c) 2011-2015 Regents of the University of California.
*
* This file is part of ndnSIM. See AUTHORS for complete list of ndnSIM authors and
* contributors.
*
* ndnSIM is free software: you can redistribute it and/or modify it under the terms
* of the GNU General Public License as published by the Free Software Foundation,
* either version 3 of the License, or (at your option) any later version.
*
* ndnSIM 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
* ndnSIM, e.g., in COPYING.md file. If not, see <http://www.gnu.org/licenses/>.
**/
#ifndef TRIE_H_
#define TRIE_H_
/// @cond include_hidden
#include "ns3/ndnSIM/model/ndn-common.hpp"
#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 <tuple>
#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::value_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 = 1, size_t bucketIncrement = 1)
: 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 std::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 std::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 std::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 std::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 std::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;
}
/**
* @brief Find next payload of the sub-trie satisfying the predicate
* @param pred predicate
*
* This version check predicate only for the next level children
*
* @returns end() or a valid iterator pointing to the trie leaf (order is not defined, enumeration
*)
*/
template<class Predicate>
inline const iterator
find_if_next_level(Predicate pred)
{
typedef trie<FullKey, PayloadTraits, PolicyHook> trie;
for (typename trie::unordered_set::iterator subnode = children_.begin();
subnode != children_.end(); subnode++) {
if (pred(subnode->key())) {
return subnode->find();
}
}
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
/// @endcond
#endif // TRIE_H_