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/* -*- Mode:C++; c-file-style:"gnu"; indent-tabs-mode:nil; -*- */
/*
* Copyright (c) 2014-2020, 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 "access-strategy.hpp"
#include "algorithm.hpp"
#include "common/global.hpp"
#include "common/logger.hpp"
namespace nfd {
namespace fw {
NFD_LOG_INIT(AccessStrategy);
NFD_REGISTER_STRATEGY(AccessStrategy);
AccessStrategy::AccessStrategy(Forwarder& forwarder, const Name& name)
: Strategy(forwarder)
, m_rttEstimatorOpts(make_shared<RttEstimator::Options>()) // use the default options
, m_removeFaceConn(beforeRemoveFace.connect([this] (const Face& face) { m_fit.erase(face.getId()); }))
{
ParsedInstanceName parsed = parseInstanceName(name);
if (!parsed.parameters.empty()) {
NDN_THROW(std::invalid_argument("AccessStrategy does not accept parameters"));
}
if (parsed.version && *parsed.version != getStrategyName()[-1].toVersion()) {
NDN_THROW(std::invalid_argument("AccessStrategy does not support version " + to_string(*parsed.version)));
}
this->setInstanceName(makeInstanceName(name, getStrategyName()));
}
const Name&
AccessStrategy::getStrategyName()
{
static Name strategyName("/localhost/nfd/strategy/access/%FD%01");
return strategyName;
}
void
AccessStrategy::afterReceiveInterest(const FaceEndpoint& ingress, const Interest& interest,
const shared_ptr<pit::Entry>& pitEntry)
{
auto suppressResult = m_retxSuppression.decidePerPitEntry(*pitEntry);
switch (suppressResult) {
case RetxSuppressionResult::NEW:
return afterReceiveNewInterest(ingress, interest, pitEntry);
case RetxSuppressionResult::FORWARD:
return afterReceiveRetxInterest(ingress, interest, pitEntry);
case RetxSuppressionResult::SUPPRESS:
NFD_LOG_DEBUG(interest << " interestFrom " << ingress << " retx-suppress");
return;
}
}
void
AccessStrategy::afterReceiveNewInterest(const FaceEndpoint& ingress, const Interest& interest,
const shared_ptr<pit::Entry>& pitEntry)
{
const auto& fibEntry = this->lookupFib(*pitEntry);
Name miName;
MtInfo* mi = nullptr;
std::tie(miName, mi) = this->findPrefixMeasurements(*pitEntry);
// has measurements for Interest Name?
if (mi != nullptr) {
NFD_LOG_DEBUG(interest << " interestFrom " << ingress << " new-interest mi=" << miName);
// send to last working nexthop
bool isSentToLastNexthop = this->sendToLastNexthop(ingress, interest, pitEntry, *mi, fibEntry);
if (isSentToLastNexthop) {
return;
}
}
else {
NFD_LOG_DEBUG(interest << " interestFrom " << ingress << " new-interest no-mi");
}
// no measurements, or last working nexthop unavailable
// multicast to all nexthops except incoming face
size_t nMulticastSent = this->multicast(ingress.face, interest, pitEntry, fibEntry);
if (nMulticastSent == 0) {
this->rejectPendingInterest(pitEntry);
}
}
void
AccessStrategy::afterReceiveRetxInterest(const FaceEndpoint& ingress, const Interest& interest,
const shared_ptr<pit::Entry>& pitEntry)
{
const auto& fibEntry = this->lookupFib(*pitEntry);
NFD_LOG_DEBUG(interest << " interestFrom " << ingress << " retx-forward");
this->multicast(ingress.face, interest, pitEntry, fibEntry);
}
bool
AccessStrategy::sendToLastNexthop(const FaceEndpoint& ingress, const Interest& interest,
const shared_ptr<pit::Entry>& pitEntry, MtInfo& mi,
const fib::Entry& fibEntry)
{
if (mi.lastNexthop == face::INVALID_FACEID) {
NFD_LOG_DEBUG(pitEntry->getInterest() << " no-last-nexthop");
return false;
}
if (mi.lastNexthop == ingress.face.getId()) {
NFD_LOG_DEBUG(pitEntry->getInterest() << " last-nexthop-is-downstream");
return false;
}
Face* outFace = this->getFace(mi.lastNexthop);
if (outFace == nullptr || !fibEntry.hasNextHop(*outFace)) {
NFD_LOG_DEBUG(pitEntry->getInterest() << " last-nexthop-gone");
return false;
}
if (wouldViolateScope(ingress.face, interest, *outFace)) {
NFD_LOG_DEBUG(pitEntry->getInterest() << " last-nexthop-violates-scope");
return false;
}
auto rto = mi.rtt.getEstimatedRto();
NFD_LOG_DEBUG(pitEntry->getInterest() << " interestTo " << mi.lastNexthop
<< " last-nexthop rto=" << time::duration_cast<time::microseconds>(rto).count());
this->sendInterest(pitEntry, *outFace, interest);
// schedule RTO timeout
PitInfo* pi = pitEntry->insertStrategyInfo<PitInfo>().first;
pi->rtoTimer = getScheduler().schedule(rto,
[this, pitWeak = weak_ptr<pit::Entry>(pitEntry), face = ingress.face.getId(), nh = mi.lastNexthop] {
afterRtoTimeout(pitWeak, face, nh);
});
return true;
}
void
AccessStrategy::afterRtoTimeout(const weak_ptr<pit::Entry>& pitWeak,
FaceId inFaceId, FaceId firstOutFaceId)
{
shared_ptr<pit::Entry> pitEntry = pitWeak.lock();
// if PIT entry is gone, RTO timer should have been cancelled
BOOST_ASSERT(pitEntry != nullptr);
Face* inFace = this->getFace(inFaceId);
if (inFace == nullptr) {
NFD_LOG_DEBUG(pitEntry->getInterest() << " timeoutFrom " << firstOutFaceId
<< " inFace-gone " << inFaceId);
return;
}
auto inRecord = pitEntry->getInRecord(*inFace);
// in-record is erased only if Interest is satisfied, and RTO timer should have been cancelled
// note: if this strategy is extended to send Nacks, that would also erase the in-record,
// and the RTO timer should be cancelled in that case as well
BOOST_ASSERT(inRecord != pitEntry->in_end());
const Interest& interest = inRecord->getInterest();
const fib::Entry& fibEntry = this->lookupFib(*pitEntry);
NFD_LOG_DEBUG(pitEntry->getInterest() << " timeoutFrom " << firstOutFaceId
<< " multicast-except " << firstOutFaceId);
this->multicast(*inFace, interest, pitEntry, fibEntry, firstOutFaceId);
}
size_t
AccessStrategy::multicast(const Face& inFace, const Interest& interest,
const shared_ptr<pit::Entry>& pitEntry, const fib::Entry& fibEntry,
FaceId exceptFace)
{
size_t nSent = 0;
for (const auto& nexthop : fibEntry.getNextHops()) {
Face& outFace = nexthop.getFace();
if (&outFace == &inFace || outFace.getId() == exceptFace ||
wouldViolateScope(inFace, interest, outFace)) {
continue;
}
NFD_LOG_DEBUG(pitEntry->getInterest() << " interestTo " << outFace.getId() << " multicast");
this->sendInterest(pitEntry, outFace, interest);
++nSent;
}
return nSent;
}
void
AccessStrategy::beforeSatisfyInterest(const shared_ptr<pit::Entry>& pitEntry,
const FaceEndpoint& ingress, const Data& data)
{
PitInfo* pi = pitEntry->getStrategyInfo<PitInfo>();
if (pi != nullptr) {
pi->rtoTimer.cancel();
}
if (!pitEntry->hasInRecords()) { // already satisfied by another upstream
NFD_LOG_DEBUG(pitEntry->getInterest() << " dataFrom " << ingress << " not-fastest");
return;
}
auto outRecord = pitEntry->getOutRecord(ingress.face);
if (outRecord == pitEntry->out_end()) { // no out-record
NFD_LOG_DEBUG(pitEntry->getInterest() << " dataFrom " << ingress << " no-out-record");
return;
}
auto rtt = time::steady_clock::now() - outRecord->getLastRenewed();
NFD_LOG_DEBUG(pitEntry->getInterest() << " dataFrom " << ingress
<< " rtt=" << time::duration_cast<time::microseconds>(rtt).count());
this->updateMeasurements(ingress.face, data, rtt);
}
void
AccessStrategy::updateMeasurements(const Face& inFace, const Data& data, time::nanoseconds rtt)
{
auto ret = m_fit.emplace(std::piecewise_construct,
std::forward_as_tuple(inFace.getId()),
std::forward_as_tuple(m_rttEstimatorOpts));
FaceInfo& fi = ret.first->second;
fi.rtt.addMeasurement(rtt);
MtInfo* mi = this->addPrefixMeasurements(data);
if (mi->lastNexthop != inFace.getId()) {
mi->lastNexthop = inFace.getId();
mi->rtt = fi.rtt;
}
else {
mi->rtt.addMeasurement(rtt);
}
}
std::tuple<Name, AccessStrategy::MtInfo*>
AccessStrategy::findPrefixMeasurements(const pit::Entry& pitEntry)
{
measurements::Entry* me = this->getMeasurements().findLongestPrefixMatch(pitEntry);
if (me == nullptr) {
return std::make_tuple(Name(), nullptr);
}
MtInfo* mi = me->getStrategyInfo<MtInfo>();
BOOST_ASSERT(mi != nullptr);
// XXX after runtime strategy change, it's possible that me exists but mi doesn't exist;
// this case needs another longest prefix match until mi is found
return std::make_tuple(me->getName(), mi);
}
AccessStrategy::MtInfo*
AccessStrategy::addPrefixMeasurements(const Data& data)
{
measurements::Entry* me = nullptr;
if (!data.getName().empty()) {
me = this->getMeasurements().get(data.getName().getPrefix(-1));
}
if (me == nullptr) { // parent of Data Name is not in this strategy, or Data Name is empty
me = this->getMeasurements().get(data.getName());
// Data Name must be in this strategy
BOOST_ASSERT(me != nullptr);
}
this->getMeasurements().extendLifetime(*me, 8_s);
return me->insertStrategyInfo<MtInfo>(m_rttEstimatorOpts).first;
}
} // namespace fw
} // namespace nfd