#include
#include
#include
#include
#include
#include
#include
#include
static constexpr auto LINK_LAYER_TICK_INTERVAL = 100ms;
namespace llarp
{
static constexpr size_t MaxSessionsPerKey = 16;
ILinkLayer::ILinkLayer(
std::shared_ptr keyManager,
GetRCFunc getrc,
LinkMessageHandler handler,
SignBufferFunc signbuf,
SessionEstablishedHandler establishedSession,
SessionRenegotiateHandler reneg,
TimeoutHandler timeout,
SessionClosedHandler closed,
PumpDoneHandler pumpDone,
WorkerFunc_t work)
: HandleMessage(std::move(handler))
, HandleTimeout(std::move(timeout))
, Sign(std::move(signbuf))
, GetOurRC(std::move(getrc))
, SessionEstablished(std::move(establishedSession))
, SessionClosed(std::move(closed))
, SessionRenegotiate(std::move(reneg))
, PumpDone(std::move(pumpDone))
, QueueWork(std::move(work))
, m_RouterEncSecret(keyManager->encryptionKey)
, m_SecretKey(keyManager->transportKey)
{
}
ILinkLayer::~ILinkLayer() = default;
bool
ILinkLayer::HasSessionTo(const RouterID& id)
{
Lock_t l(m_AuthedLinksMutex);
return m_AuthedLinks.find(id) != m_AuthedLinks.end();
}
void
ILinkLayer::ForEachSession(std::function visit, bool randomize) const
{
std::vector> sessions;
{
Lock_t l(m_AuthedLinksMutex);
if (m_AuthedLinks.size() == 0)
return;
const size_t sz = randint() % m_AuthedLinks.size();
auto itr = m_AuthedLinks.begin();
auto begin = itr;
if (randomize)
{
std::advance(itr, sz);
begin = itr;
}
while (itr != m_AuthedLinks.end())
{
sessions.emplace_back(itr->second);
++itr;
}
if (randomize)
{
itr = m_AuthedLinks.begin();
while (itr != begin)
{
sessions.emplace_back(itr->second);
++itr;
}
}
}
for (const auto& session : sessions)
visit(session.get());
}
bool
ILinkLayer::VisitSessionByPubkey(const RouterID& pk, std::function visit)
{
std::shared_ptr session;
{
Lock_t l(m_AuthedLinksMutex);
auto itr = m_AuthedLinks.find(pk);
if (itr == m_AuthedLinks.end())
return false;
session = itr->second;
}
return visit(session.get());
}
void
ILinkLayer::ForEachSession(std::function visit)
{
std::vector> sessions;
{
Lock_t l(m_AuthedLinksMutex);
auto itr = m_AuthedLinks.begin();
while (itr != m_AuthedLinks.end())
{
sessions.emplace_back(itr->second);
++itr;
}
}
for (const auto& s : sessions)
visit(s.get());
}
bool
ILinkLayer::Configure(llarp_ev_loop_ptr loop, const std::string& ifname, int af, uint16_t port)
{
m_Loop = loop;
m_udp.user = this;
m_udp.recvfrom = [](llarp_udp_io* udp, const llarp::SockAddr& from, ManagedBuffer pktbuf) {
ILinkSession::Packet_t pkt;
auto& buf = pktbuf.underlying;
pkt.resize(buf.sz);
std::copy_n(buf.base, buf.sz, pkt.data());
static_cast(udp->user)->RecvFrom(from, std::move(pkt));
};
m_udp.tick = &ILinkLayer::udp_tick;
if (ifname == "*")
{
if (!AllInterfaces(af, m_ourAddr))
return false;
}
else
{
if (const auto maybe = GetIFAddr(ifname, af))
{
m_ourAddr = *maybe;
}
else
{
try
{
m_ourAddr = IpAddress(ifname);
}
catch (const std::exception& e)
{
LogError(stringify("Could not use ifname ", ifname, " to configure ILinkLayer"));
}
throw;
}
}
m_ourAddr.setPort(port);
return llarp_ev_add_udp(m_Loop.get(), &m_udp, m_ourAddr.createSockAddr()) != -1;
}
void
ILinkLayer::Pump()
{
std::unordered_set closedSessions;
std::vector> closedPending;
auto _now = Now();
{
Lock_t l(m_AuthedLinksMutex);
auto itr = m_AuthedLinks.begin();
while (itr != m_AuthedLinks.end())
{
if (not itr->second->TimedOut(_now))
{
itr->second->Pump();
++itr;
}
else
{
llarp::LogInfo("session to ", RouterID(itr->second->GetPubKey()), " timed out");
itr->second->Close();
closedSessions.emplace(itr->first);
itr = m_AuthedLinks.erase(itr);
}
}
}
{
Lock_t l(m_PendingMutex);
auto itr = m_Pending.begin();
while (itr != m_Pending.end())
{
if (not itr->second->TimedOut(_now))
{
itr->second->Pump();
++itr;
}
else
{
LogInfo("pending session at ", itr->first, " timed out");
// defer call so we can acquire mutexes later
closedPending.emplace_back(std::move(itr->second));
itr = m_Pending.erase(itr);
}
}
}
{
Lock_t l(m_AuthedLinksMutex);
for (const auto& r : closedSessions)
{
if (m_AuthedLinks.count(r) == 0)
{
SessionClosed(r);
}
}
}
for (const auto& pending : closedPending)
{
if (pending->IsInbound())
continue;
HandleTimeout(pending.get());
}
}
bool
ILinkLayer::MapAddr(const RouterID& pk, ILinkSession* s)
{
Lock_t l_authed(m_AuthedLinksMutex);
Lock_t l_pending(m_PendingMutex);
IpAddress addr = s->GetRemoteEndpoint();
auto itr = m_Pending.find(addr);
if (itr != m_Pending.end())
{
if (m_AuthedLinks.count(pk) > MaxSessionsPerKey)
{
LogWarn("too many session for ", pk);
s->Close();
return false;
}
m_AuthedLinks.emplace(pk, itr->second);
itr = m_Pending.erase(itr);
return true;
}
return false;
}
bool
ILinkLayer::PickAddress(const RouterContact& rc, llarp::AddressInfo& picked) const
{
std::string OurDialect = Name();
for (const auto& addr : rc.addrs)
{
if (addr.dialect == OurDialect)
{
picked = addr;
return true;
}
}
return false;
}
util::StatusObject
ILinkLayer::ExtractStatus() const
{
std::vector pending, established;
{
Lock_t l(m_PendingMutex);
std::transform(
m_Pending.cbegin(),
m_Pending.cend(),
std::back_inserter(pending),
[](const auto& item) -> util::StatusObject { return item.second->ExtractStatus(); });
}
{
Lock_t l(m_AuthedLinksMutex);
std::transform(
m_AuthedLinks.cbegin(),
m_AuthedLinks.cend(),
std::back_inserter(established),
[](const auto& item) -> util::StatusObject { return item.second->ExtractStatus(); });
}
return {{"name", Name()},
{"rank", uint64_t(Rank())},
{"addr", m_ourAddr.toString()},
{"sessions", util::StatusObject{{"pending", pending}, {"established", established}}}};
}
bool
ILinkLayer::TryEstablishTo(RouterContact rc)
{
{
Lock_t l(m_AuthedLinksMutex);
if (m_AuthedLinks.count(rc.pubkey) >= MaxSessionsPerKey)
{
LogDebug("Too many links to ", RouterID{rc.pubkey}, ", not establishing another one");
return false;
}
}
llarp::AddressInfo to;
if (!PickAddress(rc, to))
return false;
const IpAddress address = to.toIpAddress();
{
Lock_t l(m_PendingMutex);
if (m_Pending.count(address) >= MaxSessionsPerKey)
{
LogDebug(
"Too many pending connections to ",
address,
" while establishing to ",
RouterID{rc.pubkey},
", not establishing another");
return false;
}
}
std::shared_ptr s = NewOutboundSession(rc, to);
if (PutSession(s))
{
s->Start();
return true;
}
return false;
}
bool
ILinkLayer::Start(std::shared_ptr l)
{
m_Logic = l;
ScheduleTick(LINK_LAYER_TICK_INTERVAL);
return true;
}
void
ILinkLayer::Tick(llarp_time_t now)
{
{
Lock_t l(m_AuthedLinksMutex);
auto itr = m_AuthedLinks.begin();
while (itr != m_AuthedLinks.end())
{
itr->second->Tick(now);
++itr;
}
}
{
Lock_t l(m_PendingMutex);
auto itr = m_Pending.begin();
while (itr != m_Pending.end())
{
itr->second->Tick(now);
++itr;
}
}
{
// decay recently closed list
auto itr = m_RecentlyClosed.begin();
while (itr != m_RecentlyClosed.end())
{
if (itr->second >= now)
itr = m_RecentlyClosed.erase(itr);
else
++itr;
}
}
}
void
ILinkLayer::Stop()
{
if (m_Logic && tick_id)
m_Logic->remove_call(tick_id);
{
Lock_t l(m_AuthedLinksMutex);
auto itr = m_AuthedLinks.begin();
while (itr != m_AuthedLinks.end())
{
itr->second->Close();
++itr;
}
}
{
Lock_t l(m_PendingMutex);
auto itr = m_Pending.begin();
while (itr != m_Pending.end())
{
itr->second->Close();
++itr;
}
}
}
void
ILinkLayer::CloseSessionTo(const RouterID& remote)
{
static constexpr auto CloseGraceWindow = 500ms;
const auto now = Now();
Lock_t l(m_AuthedLinksMutex);
RouterID r = remote;
llarp::LogInfo("Closing all to ", r);
auto range = m_AuthedLinks.equal_range(r);
auto itr = range.first;
while (itr != range.second)
{
itr->second->Close();
m_RecentlyClosed.emplace(itr->second->GetRemoteEndpoint(), now + CloseGraceWindow);
itr = m_AuthedLinks.erase(itr);
}
}
void
ILinkLayer::KeepAliveSessionTo(const RouterID& remote)
{
Lock_t l(m_AuthedLinksMutex);
auto range = m_AuthedLinks.equal_range(remote);
auto itr = range.first;
while (itr != range.second)
{
if (itr->second->ShouldPing())
{
LogDebug("keepalive to ", remote);
itr->second->SendKeepAlive();
}
++itr;
}
}
bool
ILinkLayer::SendTo(
const RouterID& remote, const llarp_buffer_t& buf, ILinkSession::CompletionHandler completed)
{
std::shared_ptr s;
{
Lock_t l(m_AuthedLinksMutex);
auto range = m_AuthedLinks.equal_range(remote);
auto itr = range.first;
// pick lowest backlog session
size_t min = std::numeric_limits::max();
while (itr != range.second)
{
const auto backlog = itr->second->SendQueueBacklog();
if (backlog < min)
{
s = itr->second;
min = backlog;
}
++itr;
}
}
ILinkSession::Message_t pkt(buf.sz);
std::copy_n(buf.base, buf.sz, pkt.begin());
return s && s->SendMessageBuffer(std::move(pkt), completed);
}
bool
ILinkLayer::GetOurAddressInfo(llarp::AddressInfo& addr) const
{
addr.fromIpAddress(m_ourAddr);
addr.dialect = Name();
addr.pubkey = TransportPubKey();
addr.rank = Rank();
return true;
}
const byte_t*
ILinkLayer::TransportPubKey() const
{
return llarp::seckey_topublic(TransportSecretKey());
}
const SecretKey&
ILinkLayer::TransportSecretKey() const
{
return m_SecretKey;
}
bool
ILinkLayer::PutSession(const std::shared_ptr& s)
{
static constexpr size_t MaxSessionsPerEndpoint = 5;
Lock_t lock(m_PendingMutex);
IpAddress address = s->GetRemoteEndpoint();
if (m_Pending.count(address) >= MaxSessionsPerEndpoint)
return false;
m_Pending.emplace(address, s);
return true;
}
void
ILinkLayer::OnTick()
{
auto now = Now();
Tick(now);
ScheduleTick(LINK_LAYER_TICK_INTERVAL);
}
void
ILinkLayer::ScheduleTick(llarp_time_t interval)
{
tick_id = m_Logic->call_later(interval, std::bind(&ILinkLayer::OnTick, this));
}
void
ILinkLayer::udp_tick(llarp_udp_io* udp)
{
ILinkLayer* link = static_cast(udp->user);
link->Pump();
}
} // namespace llarp