daemon/table/name-tree-hashtable.cpp - NFD - Gitiles

 /* -*- Mode:C++; c-file-style:"gnu"; indent-tabs-mode:nil; -*- */
 /**
  * Copyright (c) 2014-2016,  Regents of the University of California,
  *                           Arizona Board of Regents,
  *                           Colorado State University,
  *                           University Pierre & Marie Curie, Sorbonne University,
  *                           Washington University in St. Louis,
  *                           Beijing Institute of Technology,
  *                           The University of Memphis.
  *
  * This file is part of NFD (Named Data Networking Forwarding Daemon).
  * See AUTHORS.md for complete list of NFD authors and contributors.
  *
  * NFD 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.
  *
  * NFD 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
  * NFD, e.g., in COPYING.md file.  If not, see <http://www.gnu.org/licenses/>.
  */

 #include "name-tree-hashtable.hpp"
 #include "core/logger.hpp"
 #include "core/city-hash.hpp"

 namespace nfd {
 namespace name_tree {

 NFD_LOG_INIT("NameTreeHashtable");

 class Hash32
 {
 public:
   static HashValue
   compute(const void* buffer, size_t length)
   {
     return static_cast<HashValue>(CityHash32(reinterpret_cast<const char*>(buffer), length));
   }
 };

 class Hash64
 {
 public:
   static HashValue
   compute(const void* buffer, size_t length)
   {
     return static_cast<HashValue>(CityHash64(reinterpret_cast<const char*>(buffer), length));
   }
 };

 /** \brief a type with compute static method to compute hash value from a raw buffer
  */
 typedef std::conditional<(sizeof(HashValue) > 4), Hash64, Hash32>::type HashFunc;

 HashValue
 computeHash(const Name& name, ssize_t prefixLen)
 {
   name.wireEncode(); // ensure wire buffer exists

   HashValue h = 0;
   for (size_t i = 0, last = prefixLen < 0 ? name.size() : prefixLen; i < last; ++i) {
     const name::Component& comp = name[i];
     h ^= HashFunc::compute(comp.wire(), comp.size());
   }
   return h;
 }

 HashSequence
 computeHashes(const Name& name)
 {
   name.wireEncode(); // ensure wire buffer exists

   HashSequence seq;
   seq.reserve(name.size() + 1);

   HashValue h = 0;
   seq.push_back(h);

   for (const name::Component& comp : name) {
     h ^= HashFunc::compute(comp.wire(), comp.size());
     seq.push_back(h);
   }
   return seq;
 }

 Node::Node(HashValue h, const Name& name)
   : hash(h)
   , prev(nullptr)
   , next(nullptr)
   , entry(name, this)
 {
 }

 Node::~Node()
 {
   BOOST_ASSERT(prev == nullptr);
   BOOST_ASSERT(next == nullptr);
 }

 Node*
 getNode(const Entry& entry)
 {
   return entry.m_node;
 }

 HashtableOptions::HashtableOptions(size_t size)
   : initialSize(size)
   , minSize(size)
 {
 }

 Hashtable::Hashtable(const Options& options)
   : m_options(options)
   , m_size(0)
 {
   BOOST_ASSERT(m_options.minSize > 0);
   BOOST_ASSERT(m_options.initialSize >= m_options.minSize);
   BOOST_ASSERT(m_options.expandLoadFactor > 0.0);
   BOOST_ASSERT(m_options.expandLoadFactor <= 1.0);
   BOOST_ASSERT(m_options.expandFactor > 1.0);
   BOOST_ASSERT(m_options.shrinkLoadFactor >= 0.0);
   BOOST_ASSERT(m_options.shrinkLoadFactor < 1.0);
   BOOST_ASSERT(m_options.shrinkFactor > 0.0);
   BOOST_ASSERT(m_options.shrinkFactor < 1.0);

   m_buckets.resize(options.initialSize);
   this->computeThresholds();
 }

 Hashtable::~Hashtable()
 {
   for (size_t i = 0; i < m_buckets.size(); ++i) {
     foreachNode(m_buckets[i], [] (Node* node) {
       node->prev = node->next = nullptr;
       delete node;
     });
   }
 }

 void
 Hashtable::attach(size_t bucket, Node* node)
 {
   node->prev = nullptr;
   node->next = m_buckets[bucket];

   if (node->next != nullptr) {
     BOOST_ASSERT(node->next->prev == nullptr);
     node->next->prev = node;
   }

   m_buckets[bucket] = node;
 }

 void
 Hashtable::detach(size_t bucket, Node* node)
 {
   if (node->prev != nullptr) {
     BOOST_ASSERT(node->prev->next == node);
     node->prev->next = node->next;
   }
   else {
     BOOST_ASSERT(m_buckets[bucket] == node);
     m_buckets[bucket] = node->next;
   }

   if (node->next != nullptr) {
     BOOST_ASSERT(node->next->prev == node);
     node->next->prev = node->prev;
   }

   node->prev = node->next = nullptr;
 }

 std::pair<const Node*, bool>
 Hashtable::findOrInsert(const Name& name, size_t prefixLen, HashValue h, bool allowInsert)
 {
   size_t bucket = this->computeBucketIndex(h);

   for (const Node* node = m_buckets[bucket]; node != nullptr; node = node->next) {
     if (node->hash == h && name.compare(0, prefixLen, node->entry.getName()) == 0) {
       NFD_LOG_TRACE("found " << name.getPrefix(prefixLen) << " hash=" << h << " bucket=" << bucket);
       return {node, false};
     }
   }

   if (!allowInsert) {
     NFD_LOG_TRACE("not-found " << name.getPrefix(prefixLen) << " hash=" << h << " bucket=" << bucket);
     return {nullptr, false};
   }

   Node* node = new Node(h, name.getPrefix(prefixLen));
   this->attach(bucket, node);
   NFD_LOG_TRACE("insert " << node->entry.getName() << " hash=" << h << " bucket=" << bucket);
   ++m_size;

   if (m_size > m_expandThreshold) {
     this->resize(static_cast<size_t>(m_options.expandFactor * this->getNBuckets()));
   }

   return {node, true};
 }

 const Node*
 Hashtable::find(const Name& name, size_t prefixLen) const
 {
   HashValue h = computeHash(name, prefixLen);
   return const_cast<Hashtable*>(this)->findOrInsert(name, prefixLen, h, false).first;
 }

 const Node*
 Hashtable::find(const Name& name, size_t prefixLen, const HashSequence& hashes) const
 {
   BOOST_ASSERT(hashes.at(prefixLen) == computeHash(name, prefixLen));
   return const_cast<Hashtable*>(this)->findOrInsert(name, prefixLen, hashes[prefixLen], false).first;
 }

 std::pair<const Node*, bool>
 Hashtable::insert(const Name& name, size_t prefixLen, const HashSequence& hashes)
 {
   BOOST_ASSERT(hashes.at(prefixLen) == computeHash(name, prefixLen));
   return this->findOrInsert(name, prefixLen, hashes[prefixLen], true);
 }

 void
 Hashtable::erase(Node* node)
 {
   BOOST_ASSERT(node != nullptr);
   BOOST_ASSERT(node->entry.getParent() == nullptr);

   size_t bucket = this->computeBucketIndex(node->hash);
   NFD_LOG_TRACE("erase " << node->entry.getName() << " hash=" << node->hash << " bucket=" << bucket);

   this->detach(bucket, node);
   delete node;
   --m_size;

   if (m_size < m_shrinkThreshold) {
     size_t newNBuckets = std::max(m_options.minSize,
       static_cast<size_t>(m_options.shrinkFactor * this->getNBuckets()));
     this->resize(newNBuckets);
   }
 }

 void
 Hashtable::computeThresholds()
 {
   m_expandThreshold = static_cast<size_t>(m_options.expandLoadFactor * this->getNBuckets());
   m_shrinkThreshold = static_cast<size_t>(m_options.shrinkLoadFactor * this->getNBuckets());
   NFD_LOG_TRACE("thresholds expand=" << m_expandThreshold << " shrink=" << m_shrinkThreshold);
 }

 void
 Hashtable::resize(size_t newNBuckets)
 {
   if (this->getNBuckets() == newNBuckets) {
     return;
   }
   NFD_LOG_DEBUG("resize from=" << this->getNBuckets() << " to=" << newNBuckets);

   std::vector<Node*> oldBuckets;
   oldBuckets.swap(m_buckets);
   m_buckets.resize(newNBuckets);

   for (Node* head : oldBuckets) {
     foreachNode(head, [this] (Node* node) {
       size_t bucket = this->computeBucketIndex(node->hash);
       this->attach(bucket, node);
     });
   }

   this->computeThresholds();
 }

 } // namespace name_tree
 } // namespace nfd
	/* -- Mode:C++; c-file-style:"gnu"; indent-tabs-mode:nil; -- */
	/**
	* Copyright (c) 2014-2016, Regents of the University of California,
	* Arizona Board of Regents,
	* Colorado State University,
	* University Pierre & Marie Curie, Sorbonne University,
	* Washington University in St. Louis,
	* Beijing Institute of Technology,
	* The University of Memphis.
	*
	* This file is part of NFD (Named Data Networking Forwarding Daemon).
	* See AUTHORS.md for complete list of NFD authors and contributors.
	*
	* NFD 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.
	*
	* NFD 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
	* NFD, e.g., in COPYING.md file. If not, see <http://www.gnu.org/licenses/>.
	*/

	#include "name-tree-hashtable.hpp"
	#include "core/logger.hpp"
	#include "core/city-hash.hpp"

	namespace nfd {
	namespace name_tree {

	NFD_LOG_INIT("NameTreeHashtable");

	class Hash32
	{
	public:
	static HashValue
	compute(const void* buffer, size_t length)
	{
	return static_cast<HashValue>(CityHash32(reinterpret_cast<const char*>(buffer), length));
	}
	};

	class Hash64
	{
	public:
	static HashValue
	compute(const void* buffer, size_t length)
	{
	return static_cast<HashValue>(CityHash64(reinterpret_cast<const char*>(buffer), length));
	}
	};

	/** \brief a type with compute static method to compute hash value from a raw buffer
	*/
	typedef std::conditional<(sizeof(HashValue) > 4), Hash64, Hash32>::type HashFunc;

	HashValue
	computeHash(const Name& name, ssize_t prefixLen)
	{
	name.wireEncode(); // ensure wire buffer exists

	HashValue h = 0;
	for (size_t i = 0, last = prefixLen < 0 ? name.size() : prefixLen; i < last; ++i) {
	const name::Component& comp = name[i];
	h ^= HashFunc::compute(comp.wire(), comp.size());
	}
	return h;
	}

	HashSequence
	computeHashes(const Name& name)
	{
	name.wireEncode(); // ensure wire buffer exists

	HashSequence seq;
	seq.reserve(name.size() + 1);

	HashValue h = 0;
	seq.push_back(h);

	for (const name::Component& comp : name) {
	h ^= HashFunc::compute(comp.wire(), comp.size());
	seq.push_back(h);
	}
	return seq;
	}

	Node::Node(HashValue h, const Name& name)
	: hash(h)
	, prev(nullptr)
	, next(nullptr)
	, entry(name, this)
	{
	}

	Node::~Node()
	{
	BOOST_ASSERT(prev == nullptr);
	BOOST_ASSERT(next == nullptr);
	}

	Node*
	getNode(const Entry& entry)
	{
	return entry.m_node;
	}

	HashtableOptions::HashtableOptions(size_t size)
	: initialSize(size)
	, minSize(size)
	{
	}

	Hashtable::Hashtable(const Options& options)
	: m_options(options)
	, m_size(0)
	{
	BOOST_ASSERT(m_options.minSize > 0);
	BOOST_ASSERT(m_options.initialSize >= m_options.minSize);
	BOOST_ASSERT(m_options.expandLoadFactor > 0.0);
	BOOST_ASSERT(m_options.expandLoadFactor <= 1.0);
	BOOST_ASSERT(m_options.expandFactor > 1.0);
	BOOST_ASSERT(m_options.shrinkLoadFactor >= 0.0);
	BOOST_ASSERT(m_options.shrinkLoadFactor < 1.0);
	BOOST_ASSERT(m_options.shrinkFactor > 0.0);
	BOOST_ASSERT(m_options.shrinkFactor < 1.0);

	m_buckets.resize(options.initialSize);
	this->computeThresholds();
	}

	Hashtable::~Hashtable()
	{
	for (size_t i = 0; i < m_buckets.size(); ++i) {
	foreachNode(m_buckets[i], [] (Node* node) {
	node->prev = node->next = nullptr;
	delete node;
	});
	}
	}

	void
	Hashtable::attach(size_t bucket, Node* node)
	{
	node->prev = nullptr;
	node->next = m_buckets[bucket];

	if (node->next != nullptr) {
	BOOST_ASSERT(node->next->prev == nullptr);
	node->next->prev = node;
	}

	m_buckets[bucket] = node;
	}

	void
	Hashtable::detach(size_t bucket, Node* node)
	{
	if (node->prev != nullptr) {
	BOOST_ASSERT(node->prev->next == node);
	node->prev->next = node->next;
	}
	else {
	BOOST_ASSERT(m_buckets[bucket] == node);
	m_buckets[bucket] = node->next;
	}

	if (node->next != nullptr) {
	BOOST_ASSERT(node->next->prev == node);
	node->next->prev = node->prev;
	}

	node->prev = node->next = nullptr;
	}

	std::pair<const Node*, bool>
	Hashtable::findOrInsert(const Name& name, size_t prefixLen, HashValue h, bool allowInsert)
	{
	size_t bucket = this->computeBucketIndex(h);

	for (const Node* node = m_buckets[bucket]; node != nullptr; node = node->next) {
	if (node->hash == h && name.compare(0, prefixLen, node->entry.getName()) == 0) {
	NFD_LOG_TRACE("found " << name.getPrefix(prefixLen) << " hash=" << h << " bucket=" << bucket);
	return {node, false};
	}
	}

	if (!allowInsert) {
	NFD_LOG_TRACE("not-found " << name.getPrefix(prefixLen) << " hash=" << h << " bucket=" << bucket);
	return {nullptr, false};
	}

	Node* node = new Node(h, name.getPrefix(prefixLen));
	this->attach(bucket, node);
	NFD_LOG_TRACE("insert " << node->entry.getName() << " hash=" << h << " bucket=" << bucket);
	++m_size;

	if (m_size > m_expandThreshold) {
	this->resize(static_cast<size_t>(m_options.expandFactor * this->getNBuckets()));
	}

	return {node, true};
	}

	const Node*
	Hashtable::find(const Name& name, size_t prefixLen) const
	{
	HashValue h = computeHash(name, prefixLen);
	return const_cast<Hashtable*>(this)->findOrInsert(name, prefixLen, h, false).first;
	}

	const Node*
	Hashtable::find(const Name& name, size_t prefixLen, const HashSequence& hashes) const
	{
	BOOST_ASSERT(hashes.at(prefixLen) == computeHash(name, prefixLen));
	return const_cast<Hashtable*>(this)->findOrInsert(name, prefixLen, hashes[prefixLen], false).first;
	}

	std::pair<const Node*, bool>
	Hashtable::insert(const Name& name, size_t prefixLen, const HashSequence& hashes)
	{
	BOOST_ASSERT(hashes.at(prefixLen) == computeHash(name, prefixLen));
	return this->findOrInsert(name, prefixLen, hashes[prefixLen], true);
	}

	void
	Hashtable::erase(Node* node)
	{
	BOOST_ASSERT(node != nullptr);
	BOOST_ASSERT(node->entry.getParent() == nullptr);

	size_t bucket = this->computeBucketIndex(node->hash);
	NFD_LOG_TRACE("erase " << node->entry.getName() << " hash=" << node->hash << " bucket=" << bucket);

	this->detach(bucket, node);
	delete node;
	--m_size;

	if (m_size < m_shrinkThreshold) {
	size_t newNBuckets = std::max(m_options.minSize,
	static_cast<size_t>(m_options.shrinkFactor * this->getNBuckets()));
	this->resize(newNBuckets);
	}
	}

	void
	Hashtable::computeThresholds()
	{
	m_expandThreshold = static_cast<size_t>(m_options.expandLoadFactor * this->getNBuckets());
	m_shrinkThreshold = static_cast<size_t>(m_options.shrinkLoadFactor * this->getNBuckets());
	NFD_LOG_TRACE("thresholds expand=" << m_expandThreshold << " shrink=" << m_shrinkThreshold);
	}

	void
	Hashtable::resize(size_t newNBuckets)
	{
	if (this->getNBuckets() == newNBuckets) {
	return;
	}
	NFD_LOG_DEBUG("resize from=" << this->getNBuckets() << " to=" << newNBuckets);

	std::vector<Node*> oldBuckets;
	oldBuckets.swap(m_buckets);
	m_buckets.resize(newNBuckets);

	for (Node* head : oldBuckets) {
	foreachNode(head, [this] (Node* node) {
	size_t bucket = this->computeBucketIndex(node->hash);
	this->attach(bucket, node);
	});
	}

	this->computeThresholds();
	}

	} // namespace name_tree
	} // namespace nfd