void
DatagramTransport<T, U>::receiveDatagram(const uint8_t* buffer, size_t nBytesReceived,
const boost::system::error_code& error)
{
if (error)
return processErrorCode(error);
NFD_LOG_FACE_TRACE("Received: " << nBytesReceived << " bytes from " << m_sender);
bool isOk = false;
Block element;
std::tie(isOk, element) = Block::fromBuffer(buffer, nBytesReceived);
if (!isOk) {
NFD_LOG_FACE_WARN("Failed to parse incoming packet from " << m_sender);
// This packet won't extend the face lifetime
return;
}
if (element.size() != nBytesReceived) {
NFD_LOG_FACE_WARN("Received datagram size and decoded element size don't match");
// This packet won't extend the face lifetime
return;
}
m_hasRecentlyReceived = true;
Transport::Packet tp(std::move(element));
tp.remoteEndpoint = makeEndpointId(m_sender);
this->receive(std::move(tp));
}
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:
++this->nInNetInvalid;
NFD_LOG_FACE_WARN("unrecognized network-layer packet TLV-TYPE " << netPkt.type() << ": DROP");
return;
}
}
catch (const tlv::Error& e) {
++this->nInNetInvalid;
NFD_LOG_FACE_WARN("packet parse error (" << e.what() << "): DROP");
}
}
void
GenericLinkService::doReceivePacket(const Block& packet, const EndpointId& endpoint)
{
try {
lp::Packet pkt(packet);
if (m_options.reliabilityOptions.isEnabled) {
m_reliability.processIncomingPacket(pkt);
}
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;
}
bool isReassembled = false;
Block netPkt;
lp::Packet firstPkt;
std::tie(isReassembled, netPkt, firstPkt) = m_reassembler.receiveFragment(endpoint, pkt);
if (isReassembled) {
this->decodeNetPacket(netPkt, firstPkt, endpoint);
}
}
catch (const tlv::Error& e) {
++this->nInLpInvalid;
NFD_LOG_FACE_WARN("packet parse error (" << e.what() << "): DROP");
}
}
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>()) {
++this->nInNetInvalid;
NFD_LOG_FACE_WARN("received Nack with Data: DROP");
return;
}
if (firstPkt.has<lp::NextHopFaceIdField>()) {
++this->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>()) {
++this->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::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>()) {
++this->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>()) {
++this->nInNetInvalid;
NFD_LOG_FACE_WARN("received PrefixAnnouncement with Interest: DROP");
return;
}
this->receiveInterest(*interest, endpointId);
}
UdpFace::UdpFace(const FaceUri& remoteUri, const FaceUri& localUri,
protocol::socket socket, ndn::nfd::FacePersistency persistency,
const time::seconds& idleTimeout)
: DatagramFace(remoteUri, localUri, std::move(socket))
, m_idleTimeout(idleTimeout)
, m_lastIdleCheck(time::steady_clock::now())
{
this->setPersistency(persistency);
#ifdef __linux__
//
// By default, Linux does path MTU discovery on IPv4 sockets,
// and sets the DF (Don't Fragment) flag on datagrams smaller
// than the interface MTU. However this does not work for us,
// because we cannot properly respond to ICMP "packet too big"
// messages by fragmenting the packet at the application level,
// since we want to rely on IP for fragmentation and reassembly.
//
// Therefore, we disable PMTU discovery, which prevents the kernel
// from setting the DF flag on outgoing datagrams, and thus allows
// routers along the path to perform fragmentation as needed.
//
const int value = IP_PMTUDISC_DONT;
if (::setsockopt(m_socket.native_handle(), IPPROTO_IP,
IP_MTU_DISCOVER, &value, sizeof(value)) < 0) {
NFD_LOG_FACE_WARN("Failed to disable path MTU discovery: " << std::strerror(errno));
}
#endif
if (this->getPersistency() == ndn::nfd::FACE_PERSISTENCY_ON_DEMAND && m_idleTimeout > time::seconds::zero()) {
m_closeIfIdleEvent = scheduler::schedule(m_idleTimeout, bind(&UdpFace::closeIfIdle, this));
}
}
void
WebSocketTransport::handlePongTimeout()
{
NFD_LOG_FACE_WARN(__func__);
this->setState(TransportState::FAILED);
doClose();
}
ssize_t
DatagramTransport<T, U>::getSendQueueLength()
{
ssize_t queueLength = getTxQueueLength(m_socket.native_handle());
if (queueLength == QUEUE_ERROR) {
NFD_LOG_FACE_WARN("Failed to obtain send queue length from socket: " << std::strerror(errno));
}
return queueLength;
}
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>()) {
++this->nInNetInvalid;
NFD_LOG_FACE_WARN("received NextHopFaceId with Nack: DROP");
return;
}
if (firstPkt.has<lp::CachePolicyField>()) {
++this->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>()) {
++this->nInNetInvalid;
NFD_LOG_FACE_WARN("received NonDiscovery with Nack: DROP");
return;
}
if (firstPkt.has<lp::PrefixAnnouncementField>()) {
++this->nInNetInvalid;
NFD_LOG_FACE_WARN("received PrefixAnnouncement with Nack: DROP");
return;
}
this->receiveNack(nack, endpointId);
}
void
WebSocketTransport::receiveMessage(const std::string& msg)
{
NFD_LOG_FACE_TRACE("Received: " << msg.size() << " bytes");
bool isOk = false;
Block element;
std::tie(isOk, element) = Block::fromBuffer(reinterpret_cast<const uint8_t*>(msg.c_str()), msg.size());
if (!isOk) {
NFD_LOG_FACE_WARN("Failed to parse message payload");
return;
}
this->receive(Transport::Packet(std::move(element)));
}
void
WebSocketTransport::processErrorCode(const websocketpp::lib::error_code& error)
{
NFD_LOG_FACE_TRACE(__func__);
if (getState() == TransportState::CLOSING ||
getState() == TransportState::FAILED ||
getState() == TransportState::CLOSED)
// transport is shutting down, ignore any errors
return;
NFD_LOG_FACE_WARN("Send or ping operation failed: " << error.message());
this->setState(TransportState::FAILED);
doClose();
}
DatagramTransport<T, U>::DatagramTransport(typename DatagramTransport::protocol::socket&& socket)
: m_socket(std::move(socket))
, m_hasRecentlyReceived(false)
{
boost::asio::socket_base::send_buffer_size sendBufferSizeOption;
boost::system::error_code error;
m_socket.get_option(sendBufferSizeOption, error);
if (error) {
NFD_LOG_FACE_WARN("Failed to obtain send queue capacity from socket: " << error.message());
this->setSendQueueCapacity(QUEUE_ERROR);
}
else {
this->setSendQueueCapacity(sendBufferSizeOption.value());
}
m_socket.async_receive_from(boost::asio::buffer(m_receiveBuffer), m_sender,
[this] (auto&&... args) {
this->handleReceive(std::forward<decltype(args)>(args)...);
});
}
void
GenericLinkService::sendLpPacket(lp::Packet&& pkt, const EndpointId& endpointId)
{
const ssize_t mtu = this->getTransport()->getMtu();
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)) {
++this->nOutOverMtu;
NFD_LOG_FACE_WARN("attempted to send packet over MTU limit");
return;
}
this->sendPacket(block, endpointId);
}
UnicastUdpTransport::UnicastUdpTransport(protocol::socket&& socket,
ndn::nfd::FacePersistency persistency,
time::nanoseconds idleTimeout)
: DatagramTransport(std::move(socket))
, m_idleTimeout(idleTimeout)
{
this->setLocalUri(FaceUri(m_socket.local_endpoint()));
this->setRemoteUri(FaceUri(m_socket.remote_endpoint()));
this->setScope(ndn::nfd::FACE_SCOPE_NON_LOCAL);
this->setPersistency(persistency);
this->setLinkType(ndn::nfd::LINK_TYPE_POINT_TO_POINT);
this->setMtu(udp::computeMtu(m_socket.local_endpoint()));
NFD_LOG_FACE_INFO("Creating transport");
#ifdef __linux__
//
// By default, Linux does path MTU discovery on IPv4 sockets,
// and sets the DF (Don't Fragment) flag on datagrams smaller
// than the interface MTU. However this does not work for us,
// because we cannot properly respond to ICMP "packet too big"
// messages by fragmenting the packet at the application level,
// since we want to rely on IP for fragmentation and reassembly.
//
// Therefore, we disable PMTU discovery, which prevents the kernel
// from setting the DF flag on outgoing datagrams, and thus allows
// routers along the path to perform fragmentation as needed.
//
const int value = IP_PMTUDISC_DONT;
if (::setsockopt(m_socket.native_handle(), IPPROTO_IP,
IP_MTU_DISCOVER, &value, sizeof(value)) < 0) {
NFD_LOG_FACE_WARN("Failed to disable path MTU discovery: " << std::strerror(errno));
}
#endif
if (getPersistency() == ndn::nfd::FACE_PERSISTENCY_ON_DEMAND &&
m_idleTimeout > time::nanoseconds::zero()) {
scheduleClosureWhenIdle();
}
}
std::tuple<bool, Block, lp::Packet>
LpReassembler::receiveFragment(Transport::EndpointId remoteEndpoint, const lp::Packet& packet)
{
BOOST_ASSERT(packet.has<lp::FragmentField>());
static auto FALSE_RETURN = std::make_tuple(false, Block(), lp::Packet());
// read and check FragIndex and FragCount
uint64_t fragIndex = 0;
uint64_t fragCount = 1;
if (packet.has<lp::FragIndexField>()) {
fragIndex = packet.get<lp::FragIndexField>();
}
if (packet.has<lp::FragCountField>()) {
fragCount = packet.get<lp::FragCountField>();
}
if (fragIndex >= fragCount) {
NFD_LOG_FACE_WARN("reassembly error, FragIndex>=FragCount: DROP");
return FALSE_RETURN;
}
if (fragCount > m_options.nMaxFragments) {
NFD_LOG_FACE_WARN("reassembly error, FragCount over limit: DROP");
return FALSE_RETURN;
}
// check for fast path
if (fragIndex == 0 && fragCount == 1) {
ndn::Buffer::const_iterator fragBegin, fragEnd;
std::tie(fragBegin, fragEnd) = packet.get<lp::FragmentField>();
Block netPkt(&*fragBegin, std::distance(fragBegin, fragEnd));
return std::make_tuple(true, netPkt, packet);
}
// check Sequence and compute message identifier
if (!packet.has<lp::SequenceField>()) {
NFD_LOG_FACE_WARN("reassembly error, Sequence missing: DROP");
return FALSE_RETURN;
}
lp::Sequence messageIdentifier = packet.get<lp::SequenceField>() - fragIndex;
Key key = std::make_tuple(remoteEndpoint, messageIdentifier);
// add to PartialPacket
PartialPacket& pp = m_partialPackets[key];
if (pp.fragCount == 0) { // new PartialPacket
pp.fragCount = fragCount;
pp.nReceivedFragments = 0;
pp.fragments.resize(fragCount);
}
else {
if (fragCount != pp.fragCount) {
NFD_LOG_FACE_WARN("reassembly error, FragCount changed: DROP");
return FALSE_RETURN;
}
}
if (pp.fragments[fragIndex].has<lp::SequenceField>()) {
NFD_LOG_FACE_TRACE("fragment already received: DROP");
return FALSE_RETURN;
}
pp.fragments[fragIndex] = packet;
++pp.nReceivedFragments;
// check complete condition
if (pp.nReceivedFragments == pp.fragCount) {
Block reassembled = doReassembly(key);
lp::Packet firstFrag(std::move(pp.fragments[0]));
m_partialPackets.erase(key);
return std::make_tuple(true, reassembled, firstFrag);
}
// set drop timer
pp.dropTimer = scheduler::schedule(m_options.reassemblyTimeout, [=] { timeoutPartialPacket(key); });
return FALSE_RETURN;
}
