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/* -*- Mode:C++; c-file-style:"gnu"; indent-tabs-mode:nil; -*- */
/*
* Copyright (c) 2014-2023, 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 "generic-link-service.hpp"
#include <ndn-cxx/lp/fields.hpp>
#include <ndn-cxx/lp/pit-token.hpp>
#include <ndn-cxx/lp/tags.hpp>
#include <cmath>
namespace nfd::face {
NFD_LOG_INIT(GenericLinkService);
constexpr size_t CONGESTION_MARK_SIZE = tlv::sizeOfVarNumber(lp::tlv::CongestionMark) + // type
tlv::sizeOfVarNumber(sizeof(uint64_t)) + // length
tlv::sizeOfNonNegativeInteger(UINT64_MAX); // value
GenericLinkService::GenericLinkService(const GenericLinkService::Options& options)
: m_options(options)
, m_fragmenter(m_options.fragmenterOptions, this)
, m_reassembler(m_options.reassemblerOptions, this)
, m_reliability(m_options.reliabilityOptions, this)
, m_lastSeqNo(-2)
, m_nextMarkTime(time::steady_clock::time_point::max())
, m_nMarkedSinceInMarkingState(0)
{
m_reassembler.beforeTimeout.connect([this] (auto&&...) { ++nReassemblyTimeouts; });
m_reliability.onDroppedInterest.connect([this] (const auto& i) { notifyDroppedInterest(i); });
nReassembling.observe(&m_reassembler);
}
void
GenericLinkService::setOptions(const GenericLinkService::Options& options)
{
m_options = options;
m_fragmenter.setOptions(m_options.fragmenterOptions);
m_reassembler.setOptions(m_options.reassemblerOptions);
m_reliability.setOptions(m_options.reliabilityOptions);
}
ssize_t
GenericLinkService::getEffectiveMtu() const
{
// Since MTU_UNLIMITED is negative, it will implicitly override any finite override MTU
return std::min(m_options.overrideMtu, getTransport()->getMtu());
}
bool
GenericLinkService::canOverrideMtuTo(ssize_t mtu) const
{
// Not allowed to override unlimited transport MTU
if (getTransport()->getMtu() == MTU_UNLIMITED) {
return false;
}
// Override MTU must be at least MIN_MTU (also implicitly forbids MTU_UNLIMITED and MTU_INVALID)
return mtu >= MIN_MTU;
}
void
GenericLinkService::requestIdlePacket()
{
// No need to request Acks to attach to this packet from LpReliability, as they are already
// attached in sendLpPacket
NFD_LOG_FACE_TRACE("IDLE packet requested");
this->sendLpPacket({});
}
void
GenericLinkService::sendLpPacket(lp::Packet&& pkt)
{
const ssize_t mtu = getEffectiveMtu();
if (m_options.reliabilityOptions.isEnabled) {
m_reliability.piggyback(pkt, mtu);
}
if (m_options.allowCongestionMarking) {
checkCongestionLevel(pkt);
}
auto block = pkt.wireEncode();
if (mtu != MTU_UNLIMITED && block.size() > static_cast<size_t>(mtu)) {
++nOutOverMtu;
NFD_LOG_FACE_WARN("attempted to send packet over MTU limit");
return;
}
this->sendPacket(block);
}
void
GenericLinkService::doSendInterest(const Interest& interest)
{
lp::Packet lpPacket(interest.wireEncode());
encodeLpFields(interest, lpPacket);
this->sendNetPacket(std::move(lpPacket), true);
}
void
GenericLinkService::doSendData(const Data& data)
{
lp::Packet lpPacket(data.wireEncode());
encodeLpFields(data, lpPacket);
this->sendNetPacket(std::move(lpPacket), false);
}
void
GenericLinkService::doSendNack(const lp::Nack& nack)
{
lp::Packet lpPacket(nack.getInterest().wireEncode());
lpPacket.add<lp::NackField>(nack.getHeader());
encodeLpFields(nack, lpPacket);
this->sendNetPacket(std::move(lpPacket), false);
}
void
GenericLinkService::assignSequences(std::vector<lp::Packet>& pkts)
{
std::for_each(pkts.begin(), pkts.end(), [this] (lp::Packet& pkt) {
pkt.set<lp::SequenceField>(++m_lastSeqNo);
});
}
void
GenericLinkService::encodeLpFields(const ndn::PacketBase& netPkt, lp::Packet& lpPacket)
{
if (m_options.allowLocalFields) {
auto incomingFaceIdTag = netPkt.getTag<lp::IncomingFaceIdTag>();
if (incomingFaceIdTag != nullptr) {
lpPacket.add<lp::IncomingFaceIdField>(*incomingFaceIdTag);
}
}
auto congestionMarkTag = netPkt.getTag<lp::CongestionMarkTag>();
if (congestionMarkTag != nullptr) {
lpPacket.add<lp::CongestionMarkField>(*congestionMarkTag);
}
if (m_options.allowSelfLearning) {
auto nonDiscoveryTag = netPkt.getTag<lp::NonDiscoveryTag>();
if (nonDiscoveryTag != nullptr) {
lpPacket.add<lp::NonDiscoveryField>(*nonDiscoveryTag);
}
auto prefixAnnouncementTag = netPkt.getTag<lp::PrefixAnnouncementTag>();
if (prefixAnnouncementTag != nullptr) {
lpPacket.add<lp::PrefixAnnouncementField>(*prefixAnnouncementTag);
}
}
auto pitToken = netPkt.getTag<lp::PitToken>();
if (pitToken != nullptr) {
lpPacket.add<lp::PitTokenField>(*pitToken);
}
}
void
GenericLinkService::sendNetPacket(lp::Packet&& pkt, bool isInterest)
{
std::vector<lp::Packet> frags;
ssize_t mtu = getEffectiveMtu();
// Make space for feature fields in fragments
if (m_options.reliabilityOptions.isEnabled && mtu != MTU_UNLIMITED) {
mtu -= LpReliability::RESERVED_HEADER_SPACE;
}
if (m_options.allowCongestionMarking && mtu != MTU_UNLIMITED) {
mtu -= CONGESTION_MARK_SIZE;
}
// An MTU of 0 is allowed but will cause all packets to be dropped before transmission
BOOST_ASSERT(mtu == MTU_UNLIMITED || mtu >= 0);
if (m_options.allowFragmentation && mtu != MTU_UNLIMITED) {
bool isOk = false;
std::tie(isOk, frags) = m_fragmenter.fragmentPacket(pkt, mtu);
if (!isOk) {
// fragmentation failed (warning is logged by LpFragmenter)
++nFragmentationErrors;
return;
}
}
else {
if (m_options.reliabilityOptions.isEnabled) {
frags.push_back(pkt);
}
else {
frags.push_back(std::move(pkt));
}
}
if (frags.size() == 1) {
// even if indexed fragmentation is enabled, the fragmenter should not
// fragment the packet if it can fit in MTU
BOOST_ASSERT(!frags.front().has<lp::FragIndexField>());
BOOST_ASSERT(!frags.front().has<lp::FragCountField>());
}
// Only assign sequences to fragments if reliability enabled or if packet contains >1 fragment
if (m_options.reliabilityOptions.isEnabled || frags.size() > 1) {
// Assign sequences to all fragments
this->assignSequences(frags);
}
if (m_options.reliabilityOptions.isEnabled && frags.front().has<lp::FragmentField>()) {
m_reliability.handleOutgoing(frags, std::move(pkt), isInterest);
}
for (lp::Packet& frag : frags) {
this->sendLpPacket(std::move(frag));
}
}
void
GenericLinkService::checkCongestionLevel(lp::Packet& pkt)
{
ssize_t sendQueueLength = getTransport()->getSendQueueLength();
// The transport must support retrieving the current send queue length
if (sendQueueLength < 0) {
return;
}
if (sendQueueLength > 0) {
NFD_LOG_FACE_TRACE("txqlen=" << sendQueueLength << " threshold=" <<
m_options.defaultCongestionThreshold << " capacity=" <<
getTransport()->getSendQueueCapacity());
}
// sendQueue is above target
if (static_cast<size_t>(sendQueueLength) > m_options.defaultCongestionThreshold) {
const auto now = time::steady_clock::now();
if (m_nextMarkTime == time::steady_clock::time_point::max()) {
m_nextMarkTime = now + m_options.baseCongestionMarkingInterval;
}
// Mark packet if sendQueue stays above target for one interval
else if (now >= m_nextMarkTime) {
pkt.set<lp::CongestionMarkField>(1);
++nCongestionMarked;
NFD_LOG_FACE_DEBUG("LpPacket was marked as congested");
++m_nMarkedSinceInMarkingState;
// Decrease the marking interval by the inverse of the square root of the number of packets
// marked in this incident of congestion
time::nanoseconds interval(static_cast<time::nanoseconds::rep>(
m_options.baseCongestionMarkingInterval.count() /
std::sqrt(m_nMarkedSinceInMarkingState + 1)));
m_nextMarkTime += interval;
}
}
else if (m_nextMarkTime != time::steady_clock::time_point::max()) {
// Congestion incident has ended, so reset
NFD_LOG_FACE_DEBUG("Send queue length dropped below congestion threshold");
m_nextMarkTime = time::steady_clock::time_point::max();
m_nMarkedSinceInMarkingState = 0;
}
}
void
GenericLinkService::doReceivePacket(const Block& packet, const EndpointId& endpoint)
{
try {
lp::Packet pkt(packet);
if (m_options.reliabilityOptions.isEnabled) {
if (!m_reliability.processIncomingPacket(pkt)) {
NFD_LOG_FACE_TRACE("received duplicate fragment: DROP");
++nDuplicateSequence;
return;
}
}
if (!pkt.has<lp::FragmentField>()) {
NFD_LOG_FACE_TRACE("received IDLE packet: DROP");
return;
}
if ((pkt.has<lp::FragIndexField>() || pkt.has<lp::FragCountField>()) &&
!m_options.allowReassembly) {
NFD_LOG_FACE_WARN("received fragment, but reassembly disabled: DROP");
return;
}
auto [isReassembled, netPkt, firstPkt] = m_reassembler.receiveFragment(endpoint, pkt);
if (isReassembled) {
this->decodeNetPacket(netPkt, firstPkt, endpoint);
}
}
catch (const tlv::Error& e) {
++nInLpInvalid;
NFD_LOG_FACE_WARN("packet parse error (" << e.what() << "): DROP");
}
}
void
GenericLinkService::decodeNetPacket(const Block& netPkt, const lp::Packet& firstPkt,
const EndpointId& endpointId)
{
try {
switch (netPkt.type()) {
case tlv::Interest:
if (firstPkt.has<lp::NackField>()) {
this->decodeNack(netPkt, firstPkt, endpointId);
}
else {
this->decodeInterest(netPkt, firstPkt, endpointId);
}
break;
case tlv::Data:
this->decodeData(netPkt, firstPkt, endpointId);
break;
default:
++nInNetInvalid;
NFD_LOG_FACE_WARN("unrecognized network-layer packet TLV-TYPE " << netPkt.type() << ": DROP");
return;
}
}
catch (const tlv::Error& e) {
++nInNetInvalid;
NFD_LOG_FACE_WARN("packet parse error (" << e.what() << "): DROP");
}
}
void
GenericLinkService::decodeInterest(const Block& netPkt, const lp::Packet& firstPkt,
const EndpointId& endpointId)
{
BOOST_ASSERT(netPkt.type() == tlv::Interest);
BOOST_ASSERT(!firstPkt.has<lp::NackField>());
// forwarding expects Interest to be created with make_shared
auto interest = make_shared<Interest>(netPkt);
if (firstPkt.has<lp::NextHopFaceIdField>()) {
if (m_options.allowLocalFields) {
interest->setTag(make_shared<lp::NextHopFaceIdTag>(firstPkt.get<lp::NextHopFaceIdField>()));
}
else {
NFD_LOG_FACE_WARN("received NextHopFaceId, but local fields disabled: DROP");
return;
}
}
if (firstPkt.has<lp::CachePolicyField>()) {
++nInNetInvalid;
NFD_LOG_FACE_WARN("received CachePolicy with Interest: DROP");
return;
}
if (firstPkt.has<lp::IncomingFaceIdField>()) {
NFD_LOG_FACE_WARN("received IncomingFaceId: IGNORE");
}
if (firstPkt.has<lp::CongestionMarkField>()) {
interest->setTag(make_shared<lp::CongestionMarkTag>(firstPkt.get<lp::CongestionMarkField>()));
}
if (firstPkt.has<lp::NonDiscoveryField>()) {
if (m_options.allowSelfLearning) {
interest->setTag(make_shared<lp::NonDiscoveryTag>(firstPkt.get<lp::NonDiscoveryField>()));
}
else {
NFD_LOG_FACE_WARN("received NonDiscovery, but self-learning disabled: IGNORE");
}
}
if (firstPkt.has<lp::PrefixAnnouncementField>()) {
++nInNetInvalid;
NFD_LOG_FACE_WARN("received PrefixAnnouncement with Interest: DROP");
return;
}
if (firstPkt.has<lp::PitTokenField>()) {
interest->setTag(make_shared<lp::PitToken>(firstPkt.get<lp::PitTokenField>()));
}
this->receiveInterest(*interest, endpointId);
}
void
GenericLinkService::decodeData(const Block& netPkt, const lp::Packet& firstPkt,
const EndpointId& endpointId)
{
BOOST_ASSERT(netPkt.type() == tlv::Data);
// forwarding expects Data to be created with make_shared
auto data = make_shared<Data>(netPkt);
if (firstPkt.has<lp::NackField>()) {
++nInNetInvalid;
NFD_LOG_FACE_WARN("received Nack with Data: DROP");
return;
}
if (firstPkt.has<lp::NextHopFaceIdField>()) {
++nInNetInvalid;
NFD_LOG_FACE_WARN("received NextHopFaceId with Data: DROP");
return;
}
if (firstPkt.has<lp::CachePolicyField>()) {
// CachePolicy is unprivileged and does not require allowLocalFields option.
// In case of an invalid CachePolicyType, get<lp::CachePolicyField> will throw,
// so it's unnecessary to check here.
data->setTag(make_shared<lp::CachePolicyTag>(firstPkt.get<lp::CachePolicyField>()));
}
if (firstPkt.has<lp::IncomingFaceIdField>()) {
NFD_LOG_FACE_WARN("received IncomingFaceId: IGNORE");
}
if (firstPkt.has<lp::CongestionMarkField>()) {
data->setTag(make_shared<lp::CongestionMarkTag>(firstPkt.get<lp::CongestionMarkField>()));
}
if (firstPkt.has<lp::NonDiscoveryField>()) {
++nInNetInvalid;
NFD_LOG_FACE_WARN("received NonDiscovery with Data: DROP");
return;
}
if (firstPkt.has<lp::PrefixAnnouncementField>()) {
if (m_options.allowSelfLearning) {
data->setTag(make_shared<lp::PrefixAnnouncementTag>(firstPkt.get<lp::PrefixAnnouncementField>()));
}
else {
NFD_LOG_FACE_WARN("received PrefixAnnouncement, but self-learning disabled: IGNORE");
}
}
this->receiveData(*data, endpointId);
}
void
GenericLinkService::decodeNack(const Block& netPkt, const lp::Packet& firstPkt,
const EndpointId& endpointId)
{
BOOST_ASSERT(netPkt.type() == tlv::Interest);
BOOST_ASSERT(firstPkt.has<lp::NackField>());
lp::Nack nack((Interest(netPkt)));
nack.setHeader(firstPkt.get<lp::NackField>());
if (firstPkt.has<lp::NextHopFaceIdField>()) {
++nInNetInvalid;
NFD_LOG_FACE_WARN("received NextHopFaceId with Nack: DROP");
return;
}
if (firstPkt.has<lp::CachePolicyField>()) {
++nInNetInvalid;
NFD_LOG_FACE_WARN("received CachePolicy with Nack: DROP");
return;
}
if (firstPkt.has<lp::IncomingFaceIdField>()) {
NFD_LOG_FACE_WARN("received IncomingFaceId: IGNORE");
}
if (firstPkt.has<lp::CongestionMarkField>()) {
nack.setTag(make_shared<lp::CongestionMarkTag>(firstPkt.get<lp::CongestionMarkField>()));
}
if (firstPkt.has<lp::NonDiscoveryField>()) {
++nInNetInvalid;
NFD_LOG_FACE_WARN("received NonDiscovery with Nack: DROP");
return;
}
if (firstPkt.has<lp::PrefixAnnouncementField>()) {
++nInNetInvalid;
NFD_LOG_FACE_WARN("received PrefixAnnouncement with Nack: DROP");
return;
}
this->receiveNack(nack, endpointId);
}
} // namespace nfd::face