daemon/table/cs.cpp - ndnSIM - Gitiles

 /* -*- Mode:C++; c-file-style:"gnu"; indent-tabs-mode:nil; -*- */
 /**
  * Copyright (C) 2014 Named Data Networking Project
  * See COPYING for copyright and distribution information.
  *
  * Author: Ilya Moiseenko <iliamo@ucla.edu>
  */

 #include "cs.hpp"
 #include "core/logger.hpp"

 #include <ndn-cpp-dev/util/crypto.hpp>

 #define SKIPLIST_MAX_LAYERS 32
 #define SKIPLIST_PROBABILITY 50         // 50% ( p = 1/2 )

 NFD_LOG_INIT("ContentStore");

 namespace nfd {

 Cs::Cs(int nMaxPackets)
   : m_nMaxPackets(nMaxPackets)
 {
   srand (time::toUnixTimestamp(time::system_clock::now()).count());
   SkipListLayer* zeroLayer = new SkipListLayer();
   m_skipList.push_back(zeroLayer);
 }

 Cs::~Cs()
 {
   /// \todo Fix memory leak
 }

 size_t
 Cs::size() const
 {
   return (*m_skipList.begin())->size(); // size of the first layer in a skip list
 }

 void
 Cs::setLimit(size_t nMaxPackets)
 {
   m_nMaxPackets = nMaxPackets;

   while (isFull())
     {
       evictItem();
     }
 }

 size_t
 Cs::getLimit() const
 {
   return m_nMaxPackets;
 }

 //Reference: "Skip Lists: A Probabilistic Alternative to Balanced Trees" by W.Pugh
 std::pair< shared_ptr<cs::Entry>, bool>
 Cs::insertToSkipList(const Data& data, bool isUnsolicited)
 {
   NFD_LOG_INFO("insertToSkipList() " << data.getName());
   NFD_LOG_DEBUG("SkipList size " << size());

   shared_ptr<cs::Entry> entry = make_shared<cs::Entry>(data, isUnsolicited);

   bool insertInFront = false;
   bool isIterated = false;
   SkipList::reverse_iterator topLayer = m_skipList.rbegin();
   SkipListLayer::iterator updateTable[SKIPLIST_MAX_LAYERS];
   SkipListLayer::iterator head = (*topLayer)->begin();

   if ( !(*topLayer)->empty() )
     {
       //start from the upper layer towards bottom
       int layer = m_skipList.size() - 1;
       for (SkipList::reverse_iterator rit = topLayer; rit != m_skipList.rend(); ++rit)
         {
           //if we didn't do any iterations on the higher layers, start from the begin() again
           if ( !isIterated )
             head = (*rit)->begin();

           updateTable[layer] = head;

           if (head != (*rit)->end())
             {
               // it can happen when begin() contains the element in front of which we need to insert
               if ( !isIterated && ((*head)->getName() >= entry->getName()) )
                 {
                   --updateTable[layer];
                   insertInFront = true;
                 }
               else
                 {
                   SkipListLayer::iterator it = head;

                   while ((*it)->getName() < entry->getName())
                     {
                       head = it;
                       updateTable[layer] = it;
                       isIterated = true;

                       ++it;
                       if (it == (*rit)->end())
                         break;
                     }
                 }
             }

           if (layer > 0)
             head = (*head)->getIterators().find(layer - 1)->second; // move HEAD to the lower layer

           layer--;
         }
     }
   else
     {
       updateTable[0] = (*topLayer)->begin(); //initialization
     }

   head = updateTable[0];
   ++head; // look at the next slot to check if it contains a duplicate

   bool isCsEmpty = (size() == 0);
   bool isInBoundaries = (head != (*m_skipList.begin())->end());
   bool isNameIdentical = false;
   if (!isCsEmpty && isInBoundaries)
     {
       isNameIdentical = (*head)->getName() == entry->getName();
     }

   //check if this is a duplicate packet
   if (isNameIdentical)
     {
       NFD_LOG_DEBUG("Duplicate name (with digest)");

       (*head)->setData(data, entry->getDigest()); //updates stale time

       return std::make_pair(*head, false);
     }

   NFD_LOG_DEBUG("Not a duplicate");

   size_t randomLayer = pickRandomLayer();

   while ( m_skipList.size() < randomLayer + 1)
     {
       SkipListLayer* newLayer = new SkipListLayer();
       m_skipList.push_back(newLayer);

       updateTable[(m_skipList.size() - 1)] = newLayer->begin();
     }

   size_t layer = 0;
   for (SkipList::iterator i = m_skipList.begin();
        i != m_skipList.end() && layer <= randomLayer; ++i)
     {
       if (updateTable[layer] == (*i)->end() && !insertInFront)
         {
           (*i)->push_back(entry);
           SkipListLayer::iterator last = (*i)->end();
           --last;
           entry->setIterator(layer, last);

           NFD_LOG_DEBUG("pushback " << &(*last));
         }
       else if (updateTable[layer] == (*i)->end() && insertInFront)
         {
           (*i)->push_front(entry);
           entry->setIterator(layer, (*i)->begin());

           NFD_LOG_DEBUG("pushfront ");
         }
       else
         {
           NFD_LOG_DEBUG("insertafter");
           ++updateTable[layer]; // insert after
           SkipListLayer::iterator position = (*i)->insert(updateTable[layer], entry);
           entry->setIterator(layer, position); // save iterator where item was inserted
         }
       layer++;
     }

   printSkipList();

   return std::make_pair(entry, true);
 }

 bool
 Cs::insert(const Data& data, bool isUnsolicited)
 {
   NFD_LOG_INFO("insert() " << data.getName());

   if (isFull())
     {
       evictItem();
     }

   //pointer and insertion status
   std::pair< shared_ptr<cs::Entry>, bool> entry = insertToSkipList(data, isUnsolicited);

   //new entry
   if (entry.first && (entry.second == true))
     {
       m_contentByArrival.push(entry.first);
       m_contentByStaleness.push(entry.first);

       if (entry.first->isUnsolicited())
         m_unsolicitedContent.push(entry.first);

       return true;
     }

   return false;
 }

 size_t
 Cs::pickRandomLayer() const
 {
   int layer = -1;
   int randomValue;

   do
     {
       layer++;
       randomValue = rand() % 100 + 1;
     }
   while ( (randomValue < SKIPLIST_PROBABILITY) && (layer < SKIPLIST_MAX_LAYERS) );

   return static_cast<size_t>(layer);
 }

 bool
 Cs::isFull() const
 {
   if (size() >= m_nMaxPackets) //size of the first layer vs. max size
     return true;

   return false;
 }

 bool
 Cs::eraseFromSkipList(shared_ptr<cs::Entry> entry)
 {
   NFD_LOG_INFO("eraseFromSkipList() "  << entry->getName());
   NFD_LOG_DEBUG("SkipList size " << size());

   bool isErased = false;

   int layer = m_skipList.size() - 1;
   for (SkipList::reverse_iterator rit = m_skipList.rbegin(); rit != m_skipList.rend(); ++rit)
     {
       const std::map<int, std::list< shared_ptr<cs::Entry> >::iterator>& iterators = entry->getIterators();
       std::map<int, std::list< shared_ptr<cs::Entry> >::iterator>::const_iterator it = iterators.find(layer);
       if (it != iterators.end())
         {
           (*rit)->erase(it->second);
           entry->removeIterator(layer);
           isErased = true;
         }

       layer--;
     }

   printSkipList();

   //remove layers that do not contain any elements (starting from the second layer)
   for (SkipList::iterator it = (++m_skipList.begin()); it != m_skipList.end();)
     {
       if ((*it)->empty())
         {
           it = m_skipList.erase(it);
         }
       else
         ++it;
     }

   return isErased;
 }

 bool
 Cs::evictItem()
 {
   NFD_LOG_INFO("evictItem()");

   //because there is a possibility that this item is in a queue, but no longer in skiplist
   while ( !m_unsolicitedContent.empty() )
     {
       NFD_LOG_DEBUG("Evict from unsolicited queue");

       shared_ptr<cs::Entry> entry = m_unsolicitedContent.front();
       m_unsolicitedContent.pop();
       bool isErased = eraseFromSkipList(entry);

       if (isErased)
         return true;
     }

   //because there is a possibility that this item is in a queue, but no longer in skiplist
   int nIterations = size() * 0.01;  // 1% of the Content Store
   while ( !m_contentByStaleness.empty() )
     {
       NFD_LOG_DEBUG("Evict from staleness queue");

       shared_ptr<cs::Entry> entry = m_contentByStaleness.top();

       //because stale time could be updated by the duplicate packet
       if (entry->getStaleTime() < time::steady_clock::now())
         {
           m_contentByStaleness.pop();
           bool isErased = eraseFromSkipList(entry);

           if (isErased)
             return true;
         }
       else if ( (entry->getStaleTime() > time::steady_clock::now()) && entry->wasRefreshedByDuplicate() )
         {
           m_contentByStaleness.pop();
           m_contentByStaleness.push(entry); // place in a right order

           nIterations--;
           // if 1% of the CS are non-expired refreshed CS entries (allocated sequentially),
           // then stop to prevent too many iterations
           if ( nIterations <= 0 )
             break;
         }
       else //no further item will be expired, stop
         {
           break;
         }
     }

   //because there is a possibility that this item is in a queue, but no longer in skiplist
   while ( !m_contentByArrival.empty() )
     {
       NFD_LOG_DEBUG("Evict from arrival queue");

       shared_ptr<cs::Entry> entry = m_contentByArrival.front();
       m_contentByArrival.pop();
       bool isErased = eraseFromSkipList(entry);

       if (isErased)
         return true;
     }

   return false;
 }

 const Data*
 Cs::find(const Interest& interest) const
 {
   NFD_LOG_INFO("find() " << interest.getName());

   bool isIterated = false;
   SkipList::const_reverse_iterator topLayer = m_skipList.rbegin();
   SkipListLayer::iterator head = (*topLayer)->begin();

   if ( !(*topLayer)->empty() )
     {
       //start from the upper layer towards bottom
       int layer = m_skipList.size() - 1;
       for (SkipList::const_reverse_iterator rit = topLayer; rit != m_skipList.rend(); ++rit)
         {
           //if we didn't do any iterations on the higher layers, start from the begin() again
           if (!isIterated)
             head = (*rit)->begin();

           if (head != (*rit)->end())
             {
               // it happens when begin() contains the element we want to find
               if ( !isIterated && (interest.getName().isPrefixOf((*head)->getName())) )
                 {
                   if (layer > 0)
                     {
                       layer--;
                       continue; // try lower layer
                     }
                   else
                     {
                       isIterated = true;
                     }
                 }
               else
                 {
                   SkipListLayer::iterator it = head;

                   while ( (*it)->getName() < interest.getName() )
                     {
                       NFD_LOG_DEBUG((*it)->getName() << " < " << interest.getName());
                       head = it;
                       isIterated = true;

                       ++it;
                       if (it == (*rit)->end())
                         break;
                     }
                 }
             }

           if (layer > 0)
             {
               head = (*head)->getIterators().find(layer - 1)->second; // move HEAD to the lower layer
             }
           else //if we reached the first layer
             {
               if ( isIterated )
                 return selectChild(interest, head);
             }

           layer--;
         }
     }

   return 0;
 }

 // because skip list is a probabilistic data structure and the way it is traversed,
 // there is no guarantee that startingPoint is an element preceding the leftmost child
 const Data*
 Cs::selectChild(const Interest& interest, SkipListLayer::iterator startingPoint) const
 {
   BOOST_ASSERT( startingPoint != (*m_skipList.begin())->end() );

   if (startingPoint != (*m_skipList.begin())->begin())
     {
       BOOST_ASSERT( (*startingPoint)->getName() < interest.getName() );
     }

   NFD_LOG_INFO("selectChild() " << interest.getChildSelector() << " " << (*startingPoint)->getName());

   bool hasLeftmostSelector = (interest.getChildSelector() <= 0);
   bool hasRightmostSelector = !hasLeftmostSelector;

   if (hasLeftmostSelector)
     {
       bool doesInterestContainDigest = recognizeInterestWithDigest(interest, *startingPoint);
       bool isInPrefix = false;

       if (doesInterestContainDigest)
         {
           isInPrefix = interest.getName().getPrefix(-1).isPrefixOf((*startingPoint)->getName());
         }
       else
         {
           isInPrefix = interest.getName().isPrefixOf((*startingPoint)->getName());
         }

       if (isInPrefix)
         {
           if (doesComplyWithSelectors(interest, *startingPoint))
             {
               return &(*startingPoint)->getData();
             }
         }
     }

   //iterate to the right
   SkipListLayer::iterator rightmost = startingPoint;
   if (startingPoint != (*m_skipList.begin())->end())
     {
       SkipListLayer::iterator rightmostCandidate = startingPoint;
       Name currentChildPrefix("");

       while (true)
         {
           ++rightmostCandidate;

           bool isInBoundaries = (rightmostCandidate != (*m_skipList.begin())->end());
           bool isInPrefix = false;
           bool doesInterestContainDigest = false;
           if (isInBoundaries)
             {
               doesInterestContainDigest = recognizeInterestWithDigest(interest, *rightmostCandidate);

               if (doesInterestContainDigest)
                 {
                   isInPrefix = interest.getName().getPrefix(-1).isPrefixOf((*rightmostCandidate)->getName());
                 }
               else
                 {
                   isInPrefix = interest.getName().isPrefixOf((*rightmostCandidate)->getName());
                 }
             }

           if (isInPrefix)
             {
               if (doesComplyWithSelectors(interest, *rightmostCandidate))
                 {
                   if (hasLeftmostSelector)
                     {
                       return &(*rightmostCandidate)->getData();
                     }

                   if (hasRightmostSelector)
                     {
                       if (doesInterestContainDigest)
                         {
                           // get prefix which is one component longer than Interest name (without digest)
                           const Name& childPrefix = (*rightmostCandidate)->getName().getPrefix(interest.getName().size());
                           NFD_LOG_DEBUG("Child prefix" << childPrefix);

                           if ( currentChildPrefix.empty() || (childPrefix != currentChildPrefix) )
                             {
                               currentChildPrefix = childPrefix;
                               rightmost = rightmostCandidate;
                             }
                         }
                       else
                         {
                           // get prefix which is one component longer than Interest name
                           const Name& childPrefix = (*rightmostCandidate)->getName().getPrefix(interest.getName().size() + 1);
                           NFD_LOG_DEBUG("Child prefix" << childPrefix);

                           if ( currentChildPrefix.empty() || (childPrefix != currentChildPrefix) )
                             {
                               currentChildPrefix = childPrefix;
                               rightmost = rightmostCandidate;
                             }
                         }
                     }
                 }
             }
           else
             break;
         }
     }

   if (rightmost != startingPoint)
     {
       return &(*rightmost)->getData();
     }

   if (hasRightmostSelector) // if rightmost was not found, try starting point
     {
       bool doesInterestContainDigest = recognizeInterestWithDigest(interest, *startingPoint);
       bool isInPrefix = false;

       if (doesInterestContainDigest)
         {
           isInPrefix = interest.getName().getPrefix(-1).isPrefixOf((*startingPoint)->getName());
         }
       else
         {
           isInPrefix = interest.getName().isPrefixOf((*startingPoint)->getName());
         }

       if (isInPrefix)
         {
           if (doesComplyWithSelectors(interest, *startingPoint))
             {
               return &(*startingPoint)->getData();
             }
         }
     }

   return 0;
 }

 bool
 Cs::doesComplyWithSelectors(const Interest& interest, shared_ptr<cs::Entry> entry) const
 {
   NFD_LOG_INFO("doesComplyWithSelectors()");

   /// \todo The following detection is not correct
   ///       1. If data name ends with 32-octet component doesn't mean that this component is digest
   ///       2. Only min/max selectors (both 0) can be specified, all other selectors do not make sense
   ///          for interests with digest (though not sure if we need to enforce this)
   bool doesInterestContainDigest = recognizeInterestWithDigest(interest, entry);
   if ( doesInterestContainDigest )
     {
       const ndn::name::Component& last = interest.getName().get(-1);
       const ndn::ConstBufferPtr& digest = entry->getDigest();

       BOOST_ASSERT(digest->size() == last.value_size());
       BOOST_ASSERT(digest->size() == ndn::crypto::SHA256_DIGEST_SIZE);

       if (std::memcmp(digest->buf(), last.value(), ndn::crypto::SHA256_DIGEST_SIZE) != 0)
         {
           NFD_LOG_DEBUG("violates implicit digest");
           return false;
         }
     }

   if ( !doesInterestContainDigest )
     {
       if (interest.getMinSuffixComponents() >= 0)
         {
           size_t minDataNameLength = interest.getName().size() + interest.getMinSuffixComponents();

           bool isSatisfied = (minDataNameLength <= entry->getName().size());
           if ( !isSatisfied )
             {
               NFD_LOG_DEBUG("violates minComponents");
               return false;
             }
         }

       if (interest.getMaxSuffixComponents() >= 0)
         {
           size_t maxDataNameLength = interest.getName().size() + interest.getMaxSuffixComponents();

           bool isSatisfied = (maxDataNameLength >= entry->getName().size());
           if ( !isSatisfied )
             {
               NFD_LOG_DEBUG("violates maxComponents");
               return false;
             }
         }
     }

   if (interest.getMustBeFresh() && entry->getStaleTime() < time::steady_clock::now())
     {
       NFD_LOG_DEBUG("violates mustBeFresh");
       return false;
     }

   if ( doesInterestContainDigest )
     {
       const ndn::name::Component& lastComponent = entry->getName().get(-1);

       if ( !lastComponent.empty() )
         {
           if (interest.getExclude().isExcluded(lastComponent))
             {
               NFD_LOG_DEBUG("violates exclusion");
               return false;
             }
         }
     }
   else
     {
       if (entry->getName().size() >= interest.getName().size() + 1)
         {
           const ndn::name::Component& nextComponent = entry->getName().get(interest.getName().size());

           if ( !nextComponent.empty() )
             {
               if (interest.getExclude().isExcluded(nextComponent))
                 {
                   NFD_LOG_DEBUG("violates exclusion");
                   return false;
                 }
             }
         }
     }


   NFD_LOG_DEBUG("complies!");
   return true;
 }

 bool
 Cs::recognizeInterestWithDigest(const Interest& interest, shared_ptr<cs::Entry> entry) const
 {
   // only when min selector is not specified or specified with value of 0
   // and Interest's name length is exactly the length of the name of CS entry
   if (interest.getMinSuffixComponents() <= 0 &&
       interest.getName().size() == (entry->getName().size()))
     {
       const ndn::name::Component& last = interest.getName().get(-1);
       if (last.value_size() == ndn::crypto::SHA256_DIGEST_SIZE)
         {
           NFD_LOG_DEBUG("digest recognized");
           return true;
         }
     }

   return false;
 }

 void
 Cs::erase(const Name& exactName)
 {
   NFD_LOG_INFO("insert() " << exactName);
   NFD_LOG_DEBUG("SkipList size " << size());

   bool isIterated = false;
   SkipListLayer::iterator updateTable[SKIPLIST_MAX_LAYERS];
   SkipList::reverse_iterator topLayer = m_skipList.rbegin();
   SkipListLayer::iterator head = (*topLayer)->begin();

   if ( !(*topLayer)->empty() )
     {
       //start from the upper layer towards bottom
       int layer = m_skipList.size() - 1;
       for (SkipList::reverse_iterator rit = topLayer; rit != m_skipList.rend(); ++rit)
         {
           //if we didn't do any iterations on the higher layers, start from the begin() again
           if ( !isIterated )
             head = (*rit)->begin();

           updateTable[layer] = head;

           if (head != (*rit)->end())
             {
               // it can happen when begin() contains the element we want to remove
               if ( !isIterated && ((*head)->getName() == exactName) )
                 {
                   eraseFromSkipList(*head);
                   return;
                 }
               else
                 {
                   SkipListLayer::iterator it = head;

                   while ((*it)->getName() < exactName)
                     {
                       head = it;
                       updateTable[layer] = it;
                       isIterated = true;

                       ++it;
                       if ( it == (*rit)->end() )
                         break;
                     }
                 }
             }

           if (layer > 0)
             head = (*head)->getIterators().find(layer - 1)->second; // move HEAD to the lower layer

           layer--;
         }
     }
   else
     {
       return;
     }

   head = updateTable[0];
   ++head; // look at the next slot to check if it contains the item we want to remove

   bool isCsEmpty = (size() == 0);
   bool isInBoundaries = (head != (*m_skipList.begin())->end());
   bool isNameIdentical = false;
   if (!isCsEmpty && isInBoundaries)
     {
       NFD_LOG_DEBUG("Identical? " << (*head)->getName());
       isNameIdentical = (*head)->getName() == exactName;
     }

   if (isNameIdentical)
     {
       NFD_LOG_DEBUG("Found target " << (*head)->getName());
       eraseFromSkipList(*head);
     }

   printSkipList();
 }

 void
 Cs::printSkipList() const
 {
   NFD_LOG_INFO("print()");
   //start from the upper layer towards bottom
   int layer = m_skipList.size() - 1;
   for (SkipList::const_reverse_iterator rit = m_skipList.rbegin(); rit != m_skipList.rend(); ++rit)
     {
       for (SkipListLayer::iterator it = (*rit)->begin(); it != (*rit)->end(); ++it)
         {
           NFD_LOG_DEBUG("Layer " << layer << " " << (*it)->getName());
         }
       layer--;
     }
 }

 } //namespace nfd
	/* -- Mode:C++; c-file-style:"gnu"; indent-tabs-mode:nil; -- */
	/**
	* Copyright (C) 2014 Named Data Networking Project
	* See COPYING for copyright and distribution information.
	*
	* Author: Ilya Moiseenko <iliamo@ucla.edu>
	*/

	#include "cs.hpp"
	#include "core/logger.hpp"

	#include <ndn-cpp-dev/util/crypto.hpp>

	#define SKIPLIST_MAX_LAYERS 32
	#define SKIPLIST_PROBABILITY 50 // 50% ( p = 1/2 )

	NFD_LOG_INIT("ContentStore");

	namespace nfd {

	Cs::Cs(int nMaxPackets)
	: m_nMaxPackets(nMaxPackets)
	{
	srand (time::toUnixTimestamp(time::system_clock::now()).count());
	SkipListLayer* zeroLayer = new SkipListLayer();
	m_skipList.push_back(zeroLayer);
	}

	Cs::~Cs()
	{
	/// \todo Fix memory leak
	}

	size_t
	Cs::size() const
	{
	return (*m_skipList.begin())->size(); // size of the first layer in a skip list
	}

	void
	Cs::setLimit(size_t nMaxPackets)
	{
	m_nMaxPackets = nMaxPackets;

	while (isFull())
	{
	evictItem();
	}
	}

	size_t
	Cs::getLimit() const
	{
	return m_nMaxPackets;
	}

	//Reference: "Skip Lists: A Probabilistic Alternative to Balanced Trees" by W.Pugh
	std::pair< shared_ptr<cs::Entry>, bool>
	Cs::insertToSkipList(const Data& data, bool isUnsolicited)
	{
	NFD_LOG_INFO("insertToSkipList() " << data.getName());
	NFD_LOG_DEBUG("SkipList size " << size());

	shared_ptr<cs::Entry> entry = make_shared<cs::Entry>(data, isUnsolicited);

	bool insertInFront = false;
	bool isIterated = false;
	SkipList::reverse_iterator topLayer = m_skipList.rbegin();
	SkipListLayer::iterator updateTable[SKIPLIST_MAX_LAYERS];
	SkipListLayer::iterator head = (*topLayer)->begin();

	if ( !(*topLayer)->empty() )
	{
	//start from the upper layer towards bottom
	int layer = m_skipList.size() - 1;
	for (SkipList::reverse_iterator rit = topLayer; rit != m_skipList.rend(); ++rit)
	{
	//if we didn't do any iterations on the higher layers, start from the begin() again
	if ( !isIterated )
	head = (*rit)->begin();

	updateTable[layer] = head;

	if (head != (*rit)->end())
	{
	// it can happen when begin() contains the element in front of which we need to insert
	if ( !isIterated && ((*head)->getName() >= entry->getName()) )
	{
	--updateTable[layer];
	insertInFront = true;
	}
	else
	{
	SkipListLayer::iterator it = head;

	while ((*it)->getName() < entry->getName())
	{
	head = it;
	updateTable[layer] = it;
	isIterated = true;

	++it;
	if (it == (*rit)->end())
	break;
	}
	}
	}

	if (layer > 0)
	head = (*head)->getIterators().find(layer - 1)->second; // move HEAD to the lower layer

	layer--;
	}
	}
	else
	{
	updateTable[0] = (*topLayer)->begin(); //initialization
	}

	head = updateTable[0];
	++head; // look at the next slot to check if it contains a duplicate

	bool isCsEmpty = (size() == 0);
	bool isInBoundaries = (head != (*m_skipList.begin())->end());
	bool isNameIdentical = false;
	if (!isCsEmpty && isInBoundaries)
	{
	isNameIdentical = (*head)->getName() == entry->getName();
	}

	//check if this is a duplicate packet
	if (isNameIdentical)
	{
	NFD_LOG_DEBUG("Duplicate name (with digest)");

	(*head)->setData(data, entry->getDigest()); //updates stale time

	return std::make_pair(*head, false);
	}

	NFD_LOG_DEBUG("Not a duplicate");

	size_t randomLayer = pickRandomLayer();

	while ( m_skipList.size() < randomLayer + 1)
	{
	SkipListLayer* newLayer = new SkipListLayer();
	m_skipList.push_back(newLayer);

	updateTable[(m_skipList.size() - 1)] = newLayer->begin();
	}

	size_t layer = 0;
	for (SkipList::iterator i = m_skipList.begin();
	i != m_skipList.end() && layer <= randomLayer; ++i)
	{
	if (updateTable[layer] == (*i)->end() && !insertInFront)
	{
	(*i)->push_back(entry);
	SkipListLayer::iterator last = (*i)->end();
	--last;
	entry->setIterator(layer, last);

	NFD_LOG_DEBUG("pushback " << &(*last));
	}
	else if (updateTable[layer] == (*i)->end() && insertInFront)
	{
	(*i)->push_front(entry);
	entry->setIterator(layer, (*i)->begin());

	NFD_LOG_DEBUG("pushfront ");
	}
	else
	{
	NFD_LOG_DEBUG("insertafter");
	++updateTable[layer]; // insert after
	SkipListLayer::iterator position = (*i)->insert(updateTable[layer], entry);
	entry->setIterator(layer, position); // save iterator where item was inserted
	}
	layer++;
	}

	printSkipList();

	return std::make_pair(entry, true);
	}

	bool
	Cs::insert(const Data& data, bool isUnsolicited)
	{
	NFD_LOG_INFO("insert() " << data.getName());

	if (isFull())
	{
	evictItem();
	}

	//pointer and insertion status
	std::pair< shared_ptr<cs::Entry>, bool> entry = insertToSkipList(data, isUnsolicited);

	//new entry
	if (entry.first && (entry.second == true))
	{
	m_contentByArrival.push(entry.first);
	m_contentByStaleness.push(entry.first);

	if (entry.first->isUnsolicited())
	m_unsolicitedContent.push(entry.first);

	return true;
	}

	return false;
	}

	size_t
	Cs::pickRandomLayer() const
	{
	int layer = -1;
	int randomValue;

	do
	{
	layer++;
	randomValue = rand() % 100 + 1;
	}
	while ( (randomValue < SKIPLIST_PROBABILITY) && (layer < SKIPLIST_MAX_LAYERS) );

	return static_cast<size_t>(layer);
	}

	bool
	Cs::isFull() const
	{
	if (size() >= m_nMaxPackets) //size of the first layer vs. max size
	return true;

	return false;
	}

	bool
	Cs::eraseFromSkipList(shared_ptr<cs::Entry> entry)
	{
	NFD_LOG_INFO("eraseFromSkipList() " << entry->getName());
	NFD_LOG_DEBUG("SkipList size " << size());

	bool isErased = false;

	int layer = m_skipList.size() - 1;
	for (SkipList::reverse_iterator rit = m_skipList.rbegin(); rit != m_skipList.rend(); ++rit)
	{
	const std::map<int, std::list< shared_ptr<cs::Entry> >::iterator>& iterators = entry->getIterators();
	std::map<int, std::list< shared_ptr<cs::Entry> >::iterator>::const_iterator it = iterators.find(layer);
	if (it != iterators.end())
	{
	(*rit)->erase(it->second);
	entry->removeIterator(layer);
	isErased = true;
	}

	layer--;
	}

	printSkipList();

	//remove layers that do not contain any elements (starting from the second layer)
	for (SkipList::iterator it = (++m_skipList.begin()); it != m_skipList.end();)
	{
	if ((*it)->empty())
	{
	it = m_skipList.erase(it);
	}
	else
	++it;
	}

	return isErased;
	}

	bool
	Cs::evictItem()
	{
	NFD_LOG_INFO("evictItem()");

	//because there is a possibility that this item is in a queue, but no longer in skiplist
	while ( !m_unsolicitedContent.empty() )
	{
	NFD_LOG_DEBUG("Evict from unsolicited queue");

	shared_ptr<cs::Entry> entry = m_unsolicitedContent.front();
	m_unsolicitedContent.pop();
	bool isErased = eraseFromSkipList(entry);

	if (isErased)
	return true;
	}

	//because there is a possibility that this item is in a queue, but no longer in skiplist
	int nIterations = size() * 0.01; // 1% of the Content Store
	while ( !m_contentByStaleness.empty() )
	{
	NFD_LOG_DEBUG("Evict from staleness queue");

	shared_ptr<cs::Entry> entry = m_contentByStaleness.top();

	//because stale time could be updated by the duplicate packet
	if (entry->getStaleTime() < time::steady_clock::now())
	{
	m_contentByStaleness.pop();
	bool isErased = eraseFromSkipList(entry);

	if (isErased)
	return true;
	}
	else if ( (entry->getStaleTime() > time::steady_clock::now()) && entry->wasRefreshedByDuplicate() )
	{
	m_contentByStaleness.pop();
	m_contentByStaleness.push(entry); // place in a right order

	nIterations--;
	// if 1% of the CS are non-expired refreshed CS entries (allocated sequentially),
	// then stop to prevent too many iterations
	if ( nIterations <= 0 )
	break;
	}
	else //no further item will be expired, stop
	{
	break;
	}
	}

	//because there is a possibility that this item is in a queue, but no longer in skiplist
	while ( !m_contentByArrival.empty() )
	{
	NFD_LOG_DEBUG("Evict from arrival queue");

	shared_ptr<cs::Entry> entry = m_contentByArrival.front();
	m_contentByArrival.pop();
	bool isErased = eraseFromSkipList(entry);

	if (isErased)
	return true;
	}

	return false;
	}

	const Data*
	Cs::find(const Interest& interest) const
	{
	NFD_LOG_INFO("find() " << interest.getName());

	bool isIterated = false;
	SkipList::const_reverse_iterator topLayer = m_skipList.rbegin();
	SkipListLayer::iterator head = (*topLayer)->begin();

	if ( !(*topLayer)->empty() )
	{
	//start from the upper layer towards bottom
	int layer = m_skipList.size() - 1;
	for (SkipList::const_reverse_iterator rit = topLayer; rit != m_skipList.rend(); ++rit)
	{
	//if we didn't do any iterations on the higher layers, start from the begin() again
	if (!isIterated)
	head = (*rit)->begin();

	if (head != (*rit)->end())
	{
	// it happens when begin() contains the element we want to find
	if ( !isIterated && (interest.getName().isPrefixOf((*head)->getName())) )
	{
	if (layer > 0)
	{
	layer--;
	continue; // try lower layer
	}
	else
	{
	isIterated = true;
	}
	}
	else
	{
	SkipListLayer::iterator it = head;

	while ( (*it)->getName() < interest.getName() )
	{
	NFD_LOG_DEBUG((*it)->getName() << " < " << interest.getName());
	head = it;
	isIterated = true;

	++it;
	if (it == (*rit)->end())
	break;
	}
	}
	}

	if (layer > 0)
	{
	head = (*head)->getIterators().find(layer - 1)->second; // move HEAD to the lower layer
	}
	else //if we reached the first layer
	{
	if ( isIterated )
	return selectChild(interest, head);
	}

	layer--;
	}
	}

	return 0;
	}

	// because skip list is a probabilistic data structure and the way it is traversed,
	// there is no guarantee that startingPoint is an element preceding the leftmost child
	const Data*
	Cs::selectChild(const Interest& interest, SkipListLayer::iterator startingPoint) const
	{
	BOOST_ASSERT( startingPoint != (*m_skipList.begin())->end() );

	if (startingPoint != (*m_skipList.begin())->begin())
	{
	BOOST_ASSERT( (*startingPoint)->getName() < interest.getName() );
	}

	NFD_LOG_INFO("selectChild() " << interest.getChildSelector() << " " << (*startingPoint)->getName());

	bool hasLeftmostSelector = (interest.getChildSelector() <= 0);
	bool hasRightmostSelector = !hasLeftmostSelector;

	if (hasLeftmostSelector)
	{
	bool doesInterestContainDigest = recognizeInterestWithDigest(interest, *startingPoint);
	bool isInPrefix = false;

	if (doesInterestContainDigest)
	{
	isInPrefix = interest.getName().getPrefix(-1).isPrefixOf((*startingPoint)->getName());
	}
	else
	{
	isInPrefix = interest.getName().isPrefixOf((*startingPoint)->getName());
	}

	if (isInPrefix)
	{
	if (doesComplyWithSelectors(interest, *startingPoint))
	{
	return &(*startingPoint)->getData();
	}
	}
	}

	//iterate to the right
	SkipListLayer::iterator rightmost = startingPoint;
	if (startingPoint != (*m_skipList.begin())->end())
	{
	SkipListLayer::iterator rightmostCandidate = startingPoint;
	Name currentChildPrefix("");

	while (true)
	{
	++rightmostCandidate;

	bool isInBoundaries = (rightmostCandidate != (*m_skipList.begin())->end());
	bool isInPrefix = false;
	bool doesInterestContainDigest = false;
	if (isInBoundaries)
	{
	doesInterestContainDigest = recognizeInterestWithDigest(interest, *rightmostCandidate);

	if (doesInterestContainDigest)
	{
	isInPrefix = interest.getName().getPrefix(-1).isPrefixOf((*rightmostCandidate)->getName());
	}
	else
	{
	isInPrefix = interest.getName().isPrefixOf((*rightmostCandidate)->getName());
	}
	}

	if (isInPrefix)
	{
	if (doesComplyWithSelectors(interest, *rightmostCandidate))
	{
	if (hasLeftmostSelector)
	{
	return &(*rightmostCandidate)->getData();
	}

	if (hasRightmostSelector)
	{
	if (doesInterestContainDigest)
	{
	// get prefix which is one component longer than Interest name (without digest)
	const Name& childPrefix = (*rightmostCandidate)->getName().getPrefix(interest.getName().size());
	NFD_LOG_DEBUG("Child prefix" << childPrefix);

	if ( currentChildPrefix.empty() \|\| (childPrefix != currentChildPrefix) )
	{
	currentChildPrefix = childPrefix;
	rightmost = rightmostCandidate;
	}
	}
	else
	{
	// get prefix which is one component longer than Interest name
	const Name& childPrefix = (*rightmostCandidate)->getName().getPrefix(interest.getName().size() + 1);
	NFD_LOG_DEBUG("Child prefix" << childPrefix);

	if ( currentChildPrefix.empty() \|\| (childPrefix != currentChildPrefix) )
	{
	currentChildPrefix = childPrefix;
	rightmost = rightmostCandidate;
	}
	}
	}
	}
	}
	else
	break;
	}
	}

	if (rightmost != startingPoint)
	{
	return &(*rightmost)->getData();
	}

	if (hasRightmostSelector) // if rightmost was not found, try starting point
	{
	bool doesInterestContainDigest = recognizeInterestWithDigest(interest, *startingPoint);
	bool isInPrefix = false;

	if (doesInterestContainDigest)
	{
	isInPrefix = interest.getName().getPrefix(-1).isPrefixOf((*startingPoint)->getName());
	}
	else
	{
	isInPrefix = interest.getName().isPrefixOf((*startingPoint)->getName());
	}

	if (isInPrefix)
	{
	if (doesComplyWithSelectors(interest, *startingPoint))
	{
	return &(*startingPoint)->getData();
	}
	}
	}

	return 0;
	}

	bool
	Cs::doesComplyWithSelectors(const Interest& interest, shared_ptr<cs::Entry> entry) const
	{
	NFD_LOG_INFO("doesComplyWithSelectors()");

	/// \todo The following detection is not correct
	/// 1. If data name ends with 32-octet component doesn't mean that this component is digest
	/// 2. Only min/max selectors (both 0) can be specified, all other selectors do not make sense
	/// for interests with digest (though not sure if we need to enforce this)
	bool doesInterestContainDigest = recognizeInterestWithDigest(interest, entry);
	if ( doesInterestContainDigest )
	{
	const ndn::name::Component& last = interest.getName().get(-1);
	const ndn::ConstBufferPtr& digest = entry->getDigest();

	BOOST_ASSERT(digest->size() == last.value_size());
	BOOST_ASSERT(digest->size() == ndn::crypto::SHA256_DIGEST_SIZE);

	if (std::memcmp(digest->buf(), last.value(), ndn::crypto::SHA256_DIGEST_SIZE) != 0)
	{
	NFD_LOG_DEBUG("violates implicit digest");
	return false;
	}
	}

	if ( !doesInterestContainDigest )
	{
	if (interest.getMinSuffixComponents() >= 0)
	{
	size_t minDataNameLength = interest.getName().size() + interest.getMinSuffixComponents();

	bool isSatisfied = (minDataNameLength <= entry->getName().size());
	if ( !isSatisfied )
	{
	NFD_LOG_DEBUG("violates minComponents");
	return false;
	}
	}

	if (interest.getMaxSuffixComponents() >= 0)
	{
	size_t maxDataNameLength = interest.getName().size() + interest.getMaxSuffixComponents();

	bool isSatisfied = (maxDataNameLength >= entry->getName().size());
	if ( !isSatisfied )
	{
	NFD_LOG_DEBUG("violates maxComponents");
	return false;
	}
	}
	}

	if (interest.getMustBeFresh() && entry->getStaleTime() < time::steady_clock::now())
	{
	NFD_LOG_DEBUG("violates mustBeFresh");
	return false;
	}

	if ( doesInterestContainDigest )
	{
	const ndn::name::Component& lastComponent = entry->getName().get(-1);

	if ( !lastComponent.empty() )
	{
	if (interest.getExclude().isExcluded(lastComponent))
	{
	NFD_LOG_DEBUG("violates exclusion");
	return false;
	}
	}
	}
	else
	{
	if (entry->getName().size() >= interest.getName().size() + 1)
	{
	const ndn::name::Component& nextComponent = entry->getName().get(interest.getName().size());

	if ( !nextComponent.empty() )
	{
	if (interest.getExclude().isExcluded(nextComponent))
	{
	NFD_LOG_DEBUG("violates exclusion");
	return false;
	}
	}
	}
	}


	NFD_LOG_DEBUG("complies!");
	return true;
	}

	bool
	Cs::recognizeInterestWithDigest(const Interest& interest, shared_ptr<cs::Entry> entry) const
	{
	// only when min selector is not specified or specified with value of 0
	// and Interest's name length is exactly the length of the name of CS entry
	if (interest.getMinSuffixComponents() <= 0 &&
	interest.getName().size() == (entry->getName().size()))
	{
	const ndn::name::Component& last = interest.getName().get(-1);
	if (last.value_size() == ndn::crypto::SHA256_DIGEST_SIZE)
	{
	NFD_LOG_DEBUG("digest recognized");
	return true;
	}
	}

	return false;
	}

	void
	Cs::erase(const Name& exactName)
	{
	NFD_LOG_INFO("insert() " << exactName);
	NFD_LOG_DEBUG("SkipList size " << size());

	bool isIterated = false;
	SkipListLayer::iterator updateTable[SKIPLIST_MAX_LAYERS];
	SkipList::reverse_iterator topLayer = m_skipList.rbegin();
	SkipListLayer::iterator head = (*topLayer)->begin();

	if ( !(*topLayer)->empty() )
	{
	//start from the upper layer towards bottom
	int layer = m_skipList.size() - 1;
	for (SkipList::reverse_iterator rit = topLayer; rit != m_skipList.rend(); ++rit)
	{
	//if we didn't do any iterations on the higher layers, start from the begin() again
	if ( !isIterated )
	head = (*rit)->begin();

	updateTable[layer] = head;

	if (head != (*rit)->end())
	{
	// it can happen when begin() contains the element we want to remove
	if ( !isIterated && ((*head)->getName() == exactName) )
	{
	eraseFromSkipList(*head);
	return;
	}
	else
	{
	SkipListLayer::iterator it = head;

	while ((*it)->getName() < exactName)
	{
	head = it;
	updateTable[layer] = it;
	isIterated = true;

	++it;
	if ( it == (*rit)->end() )
	break;
	}
	}
	}

	if (layer > 0)
	head = (*head)->getIterators().find(layer - 1)->second; // move HEAD to the lower layer

	layer--;
	}
	}
	else
	{
	return;
	}

	head = updateTable[0];
	++head; // look at the next slot to check if it contains the item we want to remove

	bool isCsEmpty = (size() == 0);
	bool isInBoundaries = (head != (*m_skipList.begin())->end());
	bool isNameIdentical = false;
	if (!isCsEmpty && isInBoundaries)
	{
	NFD_LOG_DEBUG("Identical? " << (*head)->getName());
	isNameIdentical = (*head)->getName() == exactName;
	}

	if (isNameIdentical)
	{
	NFD_LOG_DEBUG("Found target " << (*head)->getName());
	eraseFromSkipList(*head);
	}

	printSkipList();
	}

	void
	Cs::printSkipList() const
	{
	NFD_LOG_INFO("print()");
	//start from the upper layer towards bottom
	int layer = m_skipList.size() - 1;
	for (SkipList::const_reverse_iterator rit = m_skipList.rbegin(); rit != m_skipList.rend(); ++rit)
	{
	for (SkipListLayer::iterator it = (rit)->begin(); it != (rit)->end(); ++it)
	{
	NFD_LOG_DEBUG("Layer " << layer << " " << (*it)->getName());
	}
	layer--;
	}
	}

	} //namespace nfd