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/* -*- Mode:C++; c-file-style:"gnu"; indent-tabs-mode:nil; -*- */
/**
* Copyright (c) 2014-2015, 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 "cs.hpp"
#include "core/logger.hpp"
#include "core/algorithm.hpp"
#include <numeric>
NFD_LOG_INIT("ContentStore");
namespace nfd {
namespace cs {
// http://en.cppreference.com/w/cpp/concept/ForwardIterator
BOOST_CONCEPT_ASSERT((boost::ForwardIterator<Cs::const_iterator>));
// boost::ForwardIterator follows SGI standard http://www.sgi.com/tech/stl/ForwardIterator.html,
// which doesn't require DefaultConstructible
#ifdef HAVE_IS_DEFAULT_CONSTRUCTIBLE
static_assert(std::is_default_constructible<Cs::const_iterator>::value,
"Cs::const_iterator must be default-constructible");
#else
BOOST_CONCEPT_ASSERT((boost::DefaultConstructible<Cs::const_iterator>));
#endif // HAVE_IS_DEFAULT_CONSTRUCTIBLE
Cs::Cs(size_t nMaxPackets)
: m_limit(nMaxPackets)
{
BOOST_ASSERT(nMaxPackets > 0);
}
void
Cs::setLimit(size_t nMaxPackets)
{
BOOST_ASSERT(nMaxPackets > 0);
m_limit = nMaxPackets;
this->evict();
}
bool
Cs::insert(const Data& data, bool isUnsolicited)
{
NFD_LOG_DEBUG("insert " << data.getName());
// recognize CachingPolicy
using ndn::nfd::LocalControlHeader;
const LocalControlHeader& lch = data.getLocalControlHeader();
if (lch.hasCachingPolicy()) {
LocalControlHeader::CachingPolicy policy = lch.getCachingPolicy();
if (policy == LocalControlHeader::CachingPolicy::NO_CACHE) {
return false;
}
}
bool isNewEntry = false; TableIt it;
// use .insert because gcc46 does not support .emplace
std::tie(it, isNewEntry) = m_table.insert(EntryImpl(data.shared_from_this(), isUnsolicited));
EntryImpl& entry = const_cast<EntryImpl&>(*it);
if (!isNewEntry) { // existing entry
this->detachQueue(it);
// XXX This doesn't forbid unsolicited Data from refreshing a solicited entry.
if (entry.isUnsolicited() && !isUnsolicited) {
entry.unsetUnsolicited();
}
}
entry.updateStaleTime();
this->attachQueue(it);
// check there are same amount of entries in the table and in queues
BOOST_ASSERT(m_table.size() == std::accumulate(m_queues, m_queues + QUEUE_MAX, 0U,
[] (size_t sum, const Queue queue) { return sum + queue.size(); }));
this->evict(); // XXX The new entry could be evicted, but it shouldn't matter.
return true;
}
const Data*
Cs::find(const Interest& interest) const
{
const Name& prefix = interest.getName();
bool isRightmost = interest.getChildSelector() == 1;
NFD_LOG_DEBUG("find " << prefix << (isRightmost ? " R" : " L"));
TableIt first = m_table.lower_bound(prefix);
TableIt last = m_table.end();
if (prefix.size() > 0) {
last = m_table.lower_bound(prefix.getSuccessor());
}
TableIt match = last;
if (isRightmost) {
match = this->findRightmost(interest, first, last);
}
else {
match = this->findLeftmost(interest, first, last);
}
if (match == last) {
NFD_LOG_DEBUG(" no-match");
return nullptr;
}
NFD_LOG_DEBUG(" matching " << match->getName());
return &match->getData();
}
TableIt
Cs::findLeftmost(const Interest& interest, TableIt first, TableIt last) const
{
return std::find_if(first, last, bind(&cs::EntryImpl::canSatisfy, _1, interest));
}
TableIt
Cs::findRightmost(const Interest& interest, TableIt first, TableIt last) const
{
// Each loop visits a sub-namespace under a prefix one component longer than Interest Name.
// If there is a match in that sub-namespace, the leftmost match is returned;
// otherwise, loop continues.
size_t interestNameLength = interest.getName().size();
for (TableIt right = last; right != first;) {
TableIt prev = std::prev(right);
// special case: [first,prev] have exact Names
if (prev->getName().size() == interestNameLength) {
NFD_LOG_TRACE(" find-among-exact " << prev->getName());
TableIt matchExact = this->findRightmostAmongExact(interest, first, right);
return matchExact == right ? last : matchExact;
}
Name prefix = prev->getName().getPrefix(interestNameLength + 1);
TableIt left = m_table.lower_bound(prefix);
// normal case: [left,right) are under one-component-longer prefix
NFD_LOG_TRACE(" find-under-prefix " << prefix);
TableIt match = this->findLeftmost(interest, left, right);
if (match != right) {
return match;
}
right = left;
}
return last;
}
TableIt
Cs::findRightmostAmongExact(const Interest& interest, TableIt first, TableIt last) const
{
return find_last_if(first, last, bind(&EntryImpl::canSatisfy, _1, interest));
}
void
Cs::attachQueue(TableIt it)
{
EntryImpl& entry = const_cast<EntryImpl&>(*it);
if (entry.queueType != QUEUE_NONE) {
this->detachQueue(it);
}
if (entry.isUnsolicited()) {
entry.queueType = QUEUE_UNSOLICITED;
}
else if (entry.isStale()) {
entry.queueType = QUEUE_STALE;
}
else {
entry.queueType = QUEUE_FIFO;
if (entry.canStale()) {
entry.moveStaleEvent = scheduler::schedule(entry.getData().getFreshnessPeriod(),
bind(&Cs::moveToStaleQueue, this, it));
}
}
Queue& queue = m_queues[entry.queueType];
entry.queueIt = queue.insert(queue.end(), it);
}
void
Cs::detachQueue(TableIt it)
{
EntryImpl& entry = const_cast<EntryImpl&>(*it);
BOOST_ASSERT(entry.queueType != QUEUE_NONE);
if (entry.queueType == QUEUE_FIFO) {
scheduler::cancel(entry.moveStaleEvent);
}
m_queues[entry.queueType].erase(entry.queueIt);
entry.queueType = QUEUE_NONE;
}
void
Cs::moveToStaleQueue(TableIt it)
{
EntryImpl& entry = const_cast<EntryImpl&>(*it);
BOOST_ASSERT(entry.queueType == QUEUE_FIFO);
m_queues[QUEUE_FIFO].erase(entry.queueIt);
entry.queueType = QUEUE_STALE;
Queue& queue = m_queues[QUEUE_STALE];
entry.queueIt = queue.insert(queue.end(), it);
}
std::tuple<TableIt, std::string>
Cs::evictPick()
{
if (!m_queues[QUEUE_UNSOLICITED].empty()) {
return std::make_tuple(m_queues[QUEUE_UNSOLICITED].front(), "unsolicited");
}
if (!m_queues[QUEUE_STALE].empty()) {
return std::make_tuple(m_queues[QUEUE_STALE].front(), "stale");
}
if (!m_queues[QUEUE_FIFO].empty()) {
return std::make_tuple(m_queues[QUEUE_FIFO].front(), "fifo");
}
BOOST_ASSERT(false);
return std::make_tuple(m_table.end(), "error");
}
void
Cs::evict()
{
while (this->size() > m_limit) {
TableIt it; std::string reason;
std::tie(it, reason) = this->evictPick();
NFD_LOG_DEBUG("evict " << it->getName() << " " << reason);
this->detachQueue(it);
m_table.erase(it);
}
}
void
Cs::dump()
{
NFD_LOG_DEBUG("dump table");
for (const EntryImpl& entry : m_table) {
NFD_LOG_TRACE(entry.getFullName());
}
}
} // namespace cs
} // namespace nfd