blob: a7ff33a7dcc8d246d5f6e7796e97583ea8997850 [file] [log] [blame]
/* -*- 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 "topology-tester.hpp"
#include "common/global.hpp"
#include "face/generic-link-service.hpp"
#include <ndn-cxx/encoding/encoding-buffer-fwd.hpp>
namespace nfd::tests {
using face::GenericLinkService;
using face::InternalClientTransport;
using face::InternalForwarderTransport;
TopologyLink::NodeTransport::NodeTransport(shared_ptr<Face> f, ReceiveProxy::Callback cb)
: face(std::move(f))
, transport(dynamic_cast<InternalForwarderTransport*>(face->getTransport()))
, proxy(std::move(cb))
{
BOOST_ASSERT(transport != nullptr);
}
TopologyLink::TopologyLink(time::nanoseconds delay)
{
this->setDelay(delay);
}
void
TopologyLink::block(TopologyNode i, TopologyNode j)
{
m_transports.at(i).blockedDestinations.insert(j);
}
void
TopologyLink::unblock(TopologyNode i, TopologyNode j)
{
m_transports.at(i).blockedDestinations.erase(j);
}
void
TopologyLink::setDelay(time::nanoseconds delay)
{
BOOST_ASSERT(delay > time::nanoseconds::zero()); // zero delay does not work on macOS
m_delay = delay;
}
void
TopologyLink::addFace(TopologyNode i, shared_ptr<Face> face)
{
auto receiveCb = [this, i] (const Block& packet) { transmit(i, packet); };
auto ret = m_transports.try_emplace(i, std::move(face), std::move(receiveCb));
BOOST_ASSERT(ret.second);
auto& node = ret.first->second;
node.transport->setPeer(&node.proxy);
}
void
TopologyLink::transmit(TopologyNode i, const Block& packet)
{
if (!m_isUp) {
return;
}
const auto& blockedDestinations = m_transports.at(i).blockedDestinations;
for (const auto& [node, transport] : m_transports) {
if (node == i || blockedDestinations.count(node) > 0) {
continue;
}
getScheduler().schedule(m_delay, [packet, recipient = transport.transport] {
recipient->receivePacket(packet);
});
}
}
TopologySingleLink::TopologySingleLink(shared_ptr<Face> forwarderFace)
: m_face(std::move(forwarderFace))
, m_forwarderTransport(static_cast<InternalForwarderTransport*>(m_face->getTransport()))
{
}
TopologyAppLink::TopologyAppLink(shared_ptr<Face> forwarderFace)
: TopologySingleLink(std::move(forwarderFace))
, m_clientTransport(make_shared<InternalClientTransport>())
, m_client(make_shared<ndn::Face>(m_clientTransport, getGlobalIoService()))
{
this->recover();
}
void
TopologyAppLink::fail()
{
m_clientTransport->connectToForwarder(nullptr);
}
void
TopologyAppLink::recover()
{
m_clientTransport->connectToForwarder(m_forwarderTransport);
}
class TopologyBareLink::Observer final : public face::InternalTransportBase
{
public:
explicit
Observer(std::vector<Block>& receivedPackets)
: m_receivedPackets(receivedPackets)
{
}
void
receivePacket(const Block& packet) final
{
m_receivedPackets.push_back(packet);
}
private:
std::vector<Block>& m_receivedPackets;
};
TopologyBareLink::TopologyBareLink(shared_ptr<Face> forwarderFace)
: TopologySingleLink(std::move(forwarderFace))
, m_observer(make_unique<Observer>(sentPackets))
{
m_forwarderTransport->setPeer(m_observer.get());
}
void
TopologyBareLink::receivePacket(const Block& packet)
{
m_forwarderTransport->receivePacket(packet);
}
class TopologyPcapLinkService : public GenericLinkService
, public TopologyPcap
{
private:
///\todo #3941 call GenericLinkServiceCounters constructor in TopologyPcapLinkService constructor
void
doSendInterest(const Interest& interest) override
{
this->sentInterests.push_back(interest);
this->sentInterests.back().setTag(std::make_shared<TopologyPcapTimestamp>(time::steady_clock::now()));
this->GenericLinkService::doSendInterest(interest);
}
void
doSendData(const Data& data) override
{
this->sentData.push_back(data);
this->sentData.back().setTag(std::make_shared<TopologyPcapTimestamp>(time::steady_clock::now()));
this->GenericLinkService::doSendData(data);
}
void
doSendNack(const lp::Nack& nack) override
{
this->sentNacks.push_back(nack);
this->sentNacks.back().setTag(std::make_shared<TopologyPcapTimestamp>(time::steady_clock::now()));
this->GenericLinkService::doSendNack(nack);
}
};
TopologyNode
TopologyTester::addForwarder(const std::string& label)
{
size_t i = m_forwarders.size();
m_forwarders.push_back(make_unique<TopologyForwarder>(label));
return i;
}
shared_ptr<Face>
TopologyTester::makeFace(TopologyNode i, const FaceUri& localUri, const FaceUri& remoteUri,
ndn::nfd::FaceScope scope, ndn::nfd::LinkType linkType)
{
unique_ptr<GenericLinkService> service = m_wantPcap ? make_unique<TopologyPcapLinkService>() :
make_unique<GenericLinkService>();
auto transport = make_unique<InternalForwarderTransport>(localUri, remoteUri, scope, linkType);
auto face = make_shared<Face>(std::move(service), std::move(transport));
m_forwarders.at(i)->faceTable.add(face);
return face;
}
shared_ptr<TopologyLink>
TopologyTester::addLink(const std::string& label, time::nanoseconds delay,
std::initializer_list<TopologyNode> forwarders,
ndn::nfd::LinkType linkType)
{
auto link = std::make_shared<TopologyLink>(delay);
FaceUri remoteUri("topology://link/" + label);
if (linkType == ndn::nfd::LINK_TYPE_NONE) {
linkType = forwarders.size() > 2 ? ndn::nfd::LINK_TYPE_MULTI_ACCESS :
ndn::nfd::LINK_TYPE_POINT_TO_POINT;
}
BOOST_ASSERT(forwarders.size() <= 2 || linkType != ndn::nfd::LINK_TYPE_POINT_TO_POINT);
for (TopologyNode i : forwarders) {
FaceUri localUri("topology://" + m_forwarders.at(i)->label + "/" + label);
auto face = makeFace(i, localUri, remoteUri, ndn::nfd::FACE_SCOPE_NON_LOCAL, linkType);
link->addFace(i, std::move(face));
}
m_links.push_back(link); // keep a shared_ptr so callers don't have to
return link;
}
shared_ptr<TopologyAppLink>
TopologyTester::addAppFace(const std::string& label, TopologyNode i)
{
FaceUri localUri("topology://" + m_forwarders.at(i)->label + "/local/" + label);
FaceUri remoteUri("topology://" + m_forwarders.at(i)->label + "/app/" + label);
auto face = makeFace(i, localUri, remoteUri, ndn::nfd::FACE_SCOPE_LOCAL, ndn::nfd::LINK_TYPE_POINT_TO_POINT);
auto al = make_shared<TopologyAppLink>(std::move(face));
m_appLinks.push_back(al); // keep a shared_ptr so callers don't have to
return al;
}
shared_ptr<TopologyAppLink>
TopologyTester::addAppFace(const std::string& label, TopologyNode i, const Name& prefix, uint64_t cost)
{
shared_ptr<TopologyAppLink> al = this->addAppFace(label, i);
this->registerPrefix(i, al->getForwarderFace(), prefix, cost);
return al;
}
shared_ptr<TopologyBareLink>
TopologyTester::addBareLink(const std::string& label, TopologyNode i, ndn::nfd::FaceScope scope,
ndn::nfd::LinkType linkType)
{
FaceUri localUri("topology://" + m_forwarders.at(i)->label + "/local/" + label);
FaceUri remoteUri("topology://" + m_forwarders.at(i)->label + "/bare/" + label);
auto face = makeFace(i, localUri, remoteUri, scope, linkType);
auto bl = make_shared<TopologyBareLink>(std::move(face));
m_bareLinks.push_back(bl); // keep a shared_ptr so callers don't have to
return bl;
}
TopologyPcap&
TopologyTester::getPcap(const Face& face)
{
return dynamic_cast<TopologyPcapLinkService&>(*face.getLinkService());
}
void
TopologyTester::registerPrefix(TopologyNode i, const Face& face, const Name& prefix, uint64_t cost)
{
Forwarder& forwarder = this->getForwarder(i);
Fib& fib = forwarder.getFib();
fib::Entry* entry = fib.insert(prefix).first;
fib.addOrUpdateNextHop(*entry, const_cast<Face&>(face), cost);
}
void
TopologyTester::addEchoProducer(ndn::Face& face, const Name& prefix, time::nanoseconds replyDelay)
{
BOOST_ASSERT(replyDelay >= 0_ns);
face.setInterestFilter(prefix, [=, &face] (const auto&, const auto& interest) {
auto data = makeData(interest.getName());
if (replyDelay == 0_ns) {
// reply immediately
face.put(*data);
}
else {
// delay the reply
getScheduler().schedule(replyDelay, [&face, data = std::move(data)] {
face.put(*data);
});
}
});
}
void
TopologyTester::addIntervalConsumer(ndn::Face& face, const Name& prefix,
time::nanoseconds interval, size_t n, int seq)
{
Name name(prefix);
if (seq >= 0) {
name.appendSequenceNumber(seq);
++seq;
}
else {
name.appendTimestamp();
}
auto interest = makeInterest(name);
face.expressInterest(*interest, nullptr, nullptr, nullptr);
if (n > 1) {
getScheduler().schedule(interval, [=, &face] {
addIntervalConsumer(face, prefix, interval, n - 1, seq);
});
}
}
} // namespace nfd::tests