lokinet/llarp/path/path.cpp
dr7ana 11e54f6552 More message refactoring
- routing messages and surrounding code
- shim code in place for iteration and optimization after deciding what to do with buffer, string handling, and subsequent function calls
2023-08-31 09:28:16 -07:00

929 lines
25 KiB
C++

#include "path.hpp"
#include <llarp/exit/exit_messages.hpp>
#include <llarp/link/i_link_manager.hpp>
#include <llarp/messages/discard.hpp>
#include <llarp/messages/relay_commit.hpp>
#include <llarp/messages/relay_status.hpp>
#include "pathbuilder.hpp"
#include "transit_hop.hpp"
#include <llarp/nodedb.hpp>
#include <llarp/profiling.hpp>
#include <llarp/router/abstractrouter.hpp>
#include <llarp/routing/path_dht_message.hpp>
#include <llarp/routing/path_latency_message.hpp>
#include <llarp/routing/transfer_traffic_message.hpp>
#include <llarp/util/buffer.hpp>
#include <llarp/tooling/path_event.hpp>
#include <oxenc/endian.h>
#include <deque>
#include <queue>
namespace llarp::path
{
Path::Path(
const std::vector<RouterContact>& h,
std::weak_ptr<PathSet> pathset,
PathRole startingRoles,
std::string shortName)
: m_PathSet{std::move(pathset)}, _role{startingRoles}, m_shortName{std::move(shortName)}
{
hops.resize(h.size());
size_t hsz = h.size();
for (size_t idx = 0; idx < hsz; ++idx)
{
hops[idx].rc = h[idx];
do
{
hops[idx].txID.Randomize();
} while (hops[idx].txID.IsZero());
do
{
hops[idx].rxID.Randomize();
} while (hops[idx].rxID.IsZero());
}
for (size_t idx = 0; idx < hsz - 1; ++idx)
{
hops[idx].txID = hops[idx + 1].rxID;
}
// initialize parts of the introduction
intro.router = hops[hsz - 1].rc.pubkey;
intro.path_id = hops[hsz - 1].txID;
if (auto parent = m_PathSet.lock())
EnterState(ePathBuilding, parent->Now());
}
void
Path::SetBuildResultHook(BuildResultHookFunc func)
{
m_BuiltHook = func;
}
bool
Path::HandleUpstream(const llarp_buffer_t& X, const TunnelNonce& Y, AbstractRouter* r)
{
if (not m_UpstreamReplayFilter.Insert(Y))
return false;
return IHopHandler::HandleUpstream(X, Y, r);
}
bool
Path::HandleDownstream(const llarp_buffer_t& X, const TunnelNonce& Y, AbstractRouter* r)
{
if (not m_DownstreamReplayFilter.Insert(Y))
return false;
return IHopHandler::HandleDownstream(X, Y, r);
}
RouterID
Path::Endpoint() const
{
return hops[hops.size() - 1].rc.pubkey;
}
PubKey
Path::EndpointPubKey() const
{
return hops[hops.size() - 1].rc.pubkey;
}
PathID_t
Path::TXID() const
{
return hops[0].txID;
}
PathID_t
Path::RXID() const
{
return hops[0].rxID;
}
bool
Path::IsReady() const
{
if (Expired(llarp::time_now_ms()))
return false;
return intro.latency > 0s && _status == ePathEstablished;
}
bool
Path::IsEndpoint(const RouterID& r, const PathID_t& id) const
{
return hops[hops.size() - 1].rc.pubkey == r && hops[hops.size() - 1].txID == id;
}
RouterID
Path::Upstream() const
{
return hops[0].rc.pubkey;
}
const std::string&
Path::ShortName() const
{
return m_shortName;
}
std::string
Path::HopsString() const
{
std::string hops_str;
hops_str.reserve(hops.size() * 62); // 52 for the pkey, 6 for .snode, 4 for the ' -> ' joiner
for (const auto& hop : hops)
{
if (!hops.empty())
hops_str += " -> ";
hops_str += RouterID(hop.rc.pubkey).ToString();
}
return hops_str;
}
bool
Path::HandleLRSM(uint64_t status, std::array<EncryptedFrame, 8>& frames, AbstractRouter* r)
{
uint64_t currentStatus = status;
size_t index = 0;
std::optional<RouterID> failedAt;
while (index < hops.size())
{
if (!frames[index].DoDecrypt(hops[index].shared))
{
currentStatus = LR_StatusRecord::FAIL_DECRYPT_ERROR;
failedAt = hops[index].rc.pubkey;
break;
}
llarp::LogDebug("decrypted LRSM frame from ", hops[index].rc.pubkey);
llarp_buffer_t* buf = frames[index].Buffer();
buf->cur = buf->base + EncryptedFrameOverheadSize;
LR_StatusRecord record;
// successful decrypt
if (!record.BDecode(buf))
{
llarp::LogWarn("malformed frame inside LRCM from ", hops[index].rc.pubkey);
currentStatus = LR_StatusRecord::FAIL_MALFORMED_RECORD;
failedAt = hops[index].rc.pubkey;
break;
}
llarp::LogDebug("Decoded LR Status Record from ", hops[index].rc.pubkey);
currentStatus = record.status;
if ((record.status & LR_StatusRecord::SUCCESS) != LR_StatusRecord::SUCCESS)
{
if (record.status & LR_StatusRecord::FAIL_CONGESTION and index == 0)
{
// first hop building too fast
failedAt = hops[index].rc.pubkey;
break;
}
// failed at next hop
if (index + 1 < hops.size())
{
failedAt = hops[index + 1].rc.pubkey;
}
break;
}
++index;
}
if ((currentStatus & LR_StatusRecord::SUCCESS) == LR_StatusRecord::SUCCESS)
{
llarp::LogDebug("LR_Status message processed, path build successful");
r->loop()->call([r, self = shared_from_this()] { self->HandlePathConfirmMessage(r); });
}
else
{
if (failedAt)
{
r->NotifyRouterEvent<tooling::PathBuildRejectedEvent>(Endpoint(), RXID(), *failedAt);
LogWarn(
Name(),
" build failed at ",
*failedAt,
" status=",
LRStatusCodeToString(currentStatus),
" hops=",
HopsString());
r->routerProfiling().MarkHopFail(*failedAt);
}
else
r->routerProfiling().MarkPathFail(this);
llarp::LogDebug("LR_Status message processed, path build failed");
if (currentStatus & LR_StatusRecord::FAIL_TIMEOUT)
{
llarp::LogDebug("Path build failed due to timeout");
}
else if (currentStatus & LR_StatusRecord::FAIL_CONGESTION)
{
llarp::LogDebug("Path build failed due to congestion");
}
else if (currentStatus & LR_StatusRecord::FAIL_DEST_UNKNOWN)
{
llarp::LogDebug(
"Path build failed due to one or more nodes giving destination "
"unknown");
}
else if (currentStatus & LR_StatusRecord::FAIL_DEST_INVALID)
{
llarp::LogDebug(
"Path build failed due to one or more nodes considered an "
"invalid destination");
if (failedAt)
{
r->loop()->call([nodedb = r->nodedb(), router = *failedAt]() {
LogInfo("router ", router, " is deregistered so we remove it");
nodedb->Remove(router);
});
}
}
else if (currentStatus & LR_StatusRecord::FAIL_CANNOT_CONNECT)
{
llarp::LogDebug(
"Path build failed due to a node being unable to connect to the "
"next hop");
}
else if (currentStatus & LR_StatusRecord::FAIL_MALFORMED_RECORD)
{
llarp::LogDebug(
"Path build failed due to a malformed record in the build status "
"message");
}
else if (currentStatus & LR_StatusRecord::FAIL_DECRYPT_ERROR)
{
llarp::LogDebug(
"Path build failed due to a decrypt error in the build status "
"message");
}
else
{
llarp::LogDebug("Path build failed for an unspecified reason");
}
RouterID edge{};
if (failedAt)
edge = *failedAt;
r->loop()->call([r, self = shared_from_this(), edge]() {
self->EnterState(ePathFailed, r->Now());
if (auto parent = self->m_PathSet.lock())
{
parent->HandlePathBuildFailedAt(self, edge);
}
});
}
// TODO: meaningful return value?
return true;
} // namespace path
void
Path::EnterState(PathStatus st, llarp_time_t now)
{
if (st == ePathFailed)
{
_status = st;
return;
}
if (st == ePathExpired && _status == ePathBuilding)
{
_status = st;
if (auto parent = m_PathSet.lock())
{
parent->HandlePathBuildTimeout(shared_from_this());
}
}
else if (st == ePathBuilding)
{
LogInfo("path ", Name(), " is building");
buildStarted = now;
}
else if (st == ePathEstablished && _status == ePathBuilding)
{
LogInfo("path ", Name(), " is built, took ", ToString(now - buildStarted));
}
else if (st == ePathTimeout && _status == ePathEstablished)
{
LogInfo("path ", Name(), " died");
_status = st;
if (auto parent = m_PathSet.lock())
{
parent->HandlePathDied(shared_from_this());
}
}
else if (st == ePathEstablished && _status == ePathTimeout)
{
LogInfo("path ", Name(), " reanimated");
}
else if (st == ePathIgnore)
{
LogInfo("path ", Name(), " ignored");
}
_status = st;
}
util::StatusObject
PathHopConfig::ExtractStatus() const
{
const auto ip = net::In6ToHUInt(rc.addrs[0].ip);
util::StatusObject obj{
{"ip", ip.ToString()},
{"lifetime", to_json(lifetime)},
{"router", rc.pubkey.ToHex()},
{"txid", txID.ToHex()},
{"rxid", rxID.ToHex()}};
return obj;
}
util::StatusObject
Path::ExtractStatus() const
{
auto now = llarp::time_now_ms();
util::StatusObject obj{
{"intro", intro.ExtractStatus()},
{"lastRecvMsg", to_json(m_LastRecvMessage)},
{"lastLatencyTest", to_json(m_LastLatencyTestTime)},
{"buildStarted", to_json(buildStarted)},
{"expired", Expired(now)},
{"expiresSoon", ExpiresSoon(now)},
{"expiresAt", to_json(ExpireTime())},
{"ready", IsReady()},
{"txRateCurrent", m_LastTXRate},
{"rxRateCurrent", m_LastRXRate},
{"replayTX", m_UpstreamReplayFilter.Size()},
{"replayRX", m_DownstreamReplayFilter.Size()},
{"hasExit", SupportsAnyRoles(ePathRoleExit)}};
std::vector<util::StatusObject> hopsObj;
std::transform(
hops.begin(),
hops.end(),
std::back_inserter(hopsObj),
[](const auto& hop) -> util::StatusObject { return hop.ExtractStatus(); });
obj["hops"] = hopsObj;
switch (_status)
{
case ePathBuilding:
obj["status"] = "building";
break;
case ePathEstablished:
obj["status"] = "established";
break;
case ePathTimeout:
obj["status"] = "timeout";
break;
case ePathExpired:
obj["status"] = "expired";
break;
case ePathFailed:
obj["status"] = "failed";
break;
case ePathIgnore:
obj["status"] = "ignored";
break;
default:
obj["status"] = "unknown";
break;
}
return obj;
}
void
Path::Rebuild()
{
if (auto parent = m_PathSet.lock())
{
std::vector<RouterContact> newHops;
for (const auto& hop : hops)
newHops.emplace_back(hop.rc);
LogInfo(Name(), " rebuilding on ", ShortName());
parent->Build(newHops);
}
}
bool
Path::SendLatencyMessage(AbstractRouter* r)
{
const auto now = r->Now();
// send path latency test
routing::PathLatencyMessage latency{};
latency.sent_time = randint();
latency.sequence_number = NextSeqNo();
m_LastLatencyTestID = latency.sent_time;
m_LastLatencyTestTime = now;
LogDebug(Name(), " send latency test id=", latency.sent_time);
if (not SendRoutingMessage(latency, r))
return false;
FlushUpstream(r);
return true;
}
void
Path::Tick(llarp_time_t now, AbstractRouter* r)
{
if (Expired(now))
return;
m_LastRXRate = m_RXRate;
m_LastTXRate = m_TXRate;
m_RXRate = 0;
m_TXRate = 0;
if (_status == ePathBuilding)
{
if (buildStarted == 0s)
return;
if (now >= buildStarted)
{
const auto dlt = now - buildStarted;
if (dlt >= path::build_timeout)
{
LogWarn(Name(), " waited for ", ToString(dlt), " and no path was built");
r->routerProfiling().MarkPathFail(this);
EnterState(ePathExpired, now);
return;
}
}
}
// check to see if this path is dead
if (_status == ePathEstablished)
{
auto dlt = now - m_LastLatencyTestTime;
if (dlt > path::latency_interval && m_LastLatencyTestID == 0)
{
SendLatencyMessage(r);
// latency test FEC
r->loop()->call_later(2s, [self = shared_from_this(), r]() {
if (self->m_LastLatencyTestID)
self->SendLatencyMessage(r);
});
return;
}
dlt = now - m_LastRecvMessage;
if (dlt >= path::alive_timeout)
{
LogWarn(Name(), " waited for ", ToString(dlt), " and path looks dead");
r->routerProfiling().MarkPathFail(this);
EnterState(ePathTimeout, now);
}
}
if (_status == ePathIgnore and now - m_LastRecvMessage >= path::alive_timeout)
{
// clean up this path as we dont use it anymore
EnterState(ePathExpired, now);
}
}
void
Path::HandleAllUpstream(std::vector<RelayUpstreamMessage> msgs, AbstractRouter* r)
{
for (const auto& msg : msgs)
{
if (r->SendToOrQueue(Upstream(), msg))
{
m_TXRate += msg.enc.size();
}
else
{
LogDebug("failed to send upstream to ", Upstream());
}
}
r->TriggerPump();
}
void
Path::UpstreamWork(TrafficQueue_t msgs, AbstractRouter* r)
{
std::vector<RelayUpstreamMessage> sendmsgs(msgs.size());
size_t idx = 0;
for (auto& ev : msgs)
{
const llarp_buffer_t buf(ev.first);
TunnelNonce n = ev.second;
for (const auto& hop : hops)
{
CryptoManager::instance()->xchacha20(buf, hop.shared, n);
n ^= hop.nonceXOR;
}
auto& msg = sendmsgs[idx];
msg.enc = buf;
msg.nonce = ev.second;
msg.pathid = TXID();
++idx;
}
r->loop()->call([self = shared_from_this(), data = std::move(sendmsgs), r]() mutable {
self->HandleAllUpstream(std::move(data), r);
});
}
void
Path::FlushUpstream(AbstractRouter* r)
{
if (not m_UpstreamQueue.empty())
{
r->QueueWork([self = shared_from_this(),
data = std::exchange(m_UpstreamQueue, {}),
r]() mutable { self->UpstreamWork(std::move(data), r); });
}
}
void
Path::FlushDownstream(AbstractRouter* r)
{
if (not m_DownstreamQueue.empty())
{
r->QueueWork([self = shared_from_this(),
data = std::exchange(m_DownstreamQueue, {}),
r]() mutable { self->DownstreamWork(std::move(data), r); });
}
}
/// how long we wait for a path to become active again after it times out
constexpr auto PathReanimationTimeout = 45s;
bool
Path::Expired(llarp_time_t now) const
{
if (_status == ePathFailed)
return true;
if (_status == ePathBuilding)
return false;
if (_status == ePathTimeout)
{
return now >= m_LastRecvMessage + PathReanimationTimeout;
}
if (_status == ePathEstablished or _status == ePathIgnore)
{
return now >= ExpireTime();
}
return true;
}
std::string
Path::Name() const
{
return fmt::format("TX={} RX={}", TXID(), RXID());
}
void
Path::DownstreamWork(TrafficQueue_t msgs, AbstractRouter* r)
{
std::vector<RelayDownstreamMessage> sendMsgs(msgs.size());
size_t idx = 0;
for (auto& ev : msgs)
{
const llarp_buffer_t buf(ev.first);
sendMsgs[idx].nonce = ev.second;
for (const auto& hop : hops)
{
sendMsgs[idx].nonce ^= hop.nonceXOR;
CryptoManager::instance()->xchacha20(buf, hop.shared, sendMsgs[idx].nonce);
}
sendMsgs[idx].enc = buf;
++idx;
}
r->loop()->call([self = shared_from_this(), msgs = std::move(sendMsgs), r]() mutable {
self->HandleAllDownstream(std::move(msgs), r);
});
}
void
Path::HandleAllDownstream(std::vector<RelayDownstreamMessage> msgs, AbstractRouter* r)
{
for (const auto& msg : msgs)
{
const llarp_buffer_t buf{msg.enc};
m_RXRate += buf.sz;
if (HandleRoutingMessage(buf, r))
{
r->TriggerPump();
m_LastRecvMessage = r->Now();
}
}
}
bool
Path::HandleRoutingMessage(const llarp_buffer_t& buf, AbstractRouter* r)
{
if (!r->ParseRoutingMessageBuffer(buf, this, RXID()))
{
LogWarn("Failed to parse inbound routing message");
return false;
}
return true;
}
bool
Path::HandleUpdateExitVerifyMessage(
const routing::UpdateExitVerifyMessage& msg, AbstractRouter* r)
{
(void)r;
if (m_UpdateExitTX && msg.tx_id == m_UpdateExitTX)
{
if (m_ExitUpdated)
return m_ExitUpdated(shared_from_this());
}
if (m_CloseExitTX && msg.tx_id == m_CloseExitTX)
{
if (m_ExitClosed)
return m_ExitClosed(shared_from_this());
}
return false;
}
/** Note: this is one of two places where AbstractRoutingMessage::bt_encode() is called, the
other of which is llarp/path/transit_hop.cpp in TransitHop::SendRoutingMessage(). For now,
we will default to the override of ::bt_encode() that returns an std::string. The role that
llarp_buffer_t plays here is likely superfluous, and can be replaced with either a leaner
llarp_buffer, or just handled using strings.
One important consideration is the frequency at which routing messages are sent, making
superfluous copies important to optimize out here. We have to instantiate at least one
std::string whether we pass a bt_dict_producer as a reference or create one within the
::bt_encode() call.
If we decide to stay with std::strings, the function Path::HandleUpstream (along with the
functions it calls and so on) will need to be modified to take an std::string that we can
std::move around.
*/
bool
Path::SendRoutingMessage(const routing::AbstractRoutingMessage& msg, AbstractRouter* r)
{
std::array<byte_t, MAX_LINK_MSG_SIZE / 2> tmp;
llarp_buffer_t buf(tmp);
// should help prevent bad paths with uninitialized members
// FIXME: Why would we get uninitialized IMessages?
if (msg.version != llarp::constants::proto_version)
return false;
auto bte = msg.bt_encode();
buf.write(bte.begin(), bte.end());
// make nonce
TunnelNonce N;
N.Randomize();
buf.sz = buf.cur - buf.base;
// pad smaller messages
if (buf.sz < pad_size)
{
// randomize padding
CryptoManager::instance()->randbytes(buf.cur, pad_size - buf.sz);
buf.sz = pad_size;
}
buf.cur = buf.base;
LogDebug(
"send routing message ",
msg.sequence_number,
" with ",
buf.sz,
" bytes to endpoint ",
Endpoint());
return HandleUpstream(buf, N, r);
}
bool
Path::HandlePathTransferMessage(
const routing::PathTransferMessage& /*msg*/, AbstractRouter* /*r*/)
{
LogWarn("unwarranted path transfer message on tx=", TXID(), " rx=", RXID());
return false;
}
bool
Path::HandleDataDiscardMessage(const routing::DataDiscardMessage& msg, AbstractRouter* r)
{
MarkActive(r->Now());
if (m_DropHandler)
return m_DropHandler(shared_from_this(), msg.path_id, msg.sequence_number);
return true;
}
bool
Path::HandlePathConfirmMessage(AbstractRouter* r)
{
LogDebug("Path Build Confirm, path: ", ShortName());
const auto now = llarp::time_now_ms();
if (_status == ePathBuilding)
{
// finish initializing introduction
intro.expiry = buildStarted + hops[0].lifetime;
r->routerProfiling().MarkPathSuccess(this);
// persist session with upstream router until the path is done
r->PersistSessionUntil(Upstream(), intro.expiry);
MarkActive(now);
return SendLatencyMessage(r);
}
LogWarn("got unwarranted path confirm message on tx=", RXID(), " rx=", RXID());
return false;
}
bool
Path::HandlePathConfirmMessage(const routing::PathConfirmMessage& /*msg*/, AbstractRouter* r)
{
return HandlePathConfirmMessage(r);
}
bool
Path::HandleHiddenServiceFrame(const service::ProtocolFrameMessage& frame)
{
if (auto parent = m_PathSet.lock())
{
MarkActive(parent->Now());
return m_DataHandler && m_DataHandler(shared_from_this(), frame);
}
return false;
}
template <typename Samples_t>
static llarp_time_t
computeLatency(const Samples_t& samps)
{
llarp_time_t mean = 0s;
if (samps.empty())
return mean;
for (const auto& samp : samps)
mean += samp;
return mean / samps.size();
}
constexpr auto MaxLatencySamples = 8;
bool
Path::HandlePathLatencyMessage(const routing::PathLatencyMessage&, AbstractRouter* r)
{
const auto now = r->Now();
MarkActive(now);
if (m_LastLatencyTestID)
{
m_LatencySamples.emplace_back(now - m_LastLatencyTestTime);
while (m_LatencySamples.size() > MaxLatencySamples)
m_LatencySamples.pop_front();
intro.latency = computeLatency(m_LatencySamples);
m_LastLatencyTestID = 0;
EnterState(ePathEstablished, now);
if (m_BuiltHook)
m_BuiltHook(shared_from_this());
m_BuiltHook = nullptr;
}
return true;
}
/// this is the Client's side of handling a DHT message. it's handled
/// in-place.
bool
Path::HandleDHTMessage(const dht::AbstractDHTMessage& msg, AbstractRouter* r)
{
MarkActive(r->Now());
routing::PathDHTMessage reply;
if (!msg.handle_message(r->dht(), reply.dht_msgs))
return false;
if (reply.dht_msgs.size())
return SendRoutingMessage(reply, r);
return true;
}
bool
Path::HandleCloseExitMessage(const routing::CloseExitMessage& msg, AbstractRouter* /*r*/)
{
/// allows exits to close from their end
if (SupportsAnyRoles(ePathRoleExit | ePathRoleSVC))
{
if (msg.Verify(EndpointPubKey()))
{
LogInfo(Name(), " had its exit closed");
_role &= ~ePathRoleExit;
return true;
}
LogError(Name(), " CXM from exit with bad signature");
}
else
LogError(Name(), " unwarranted CXM");
return false;
}
bool
Path::SendExitRequest(const routing::ObtainExitMessage& msg, AbstractRouter* r)
{
LogInfo(Name(), " sending exit request to ", Endpoint());
m_ExitObtainTX = msg.tx_id;
return SendRoutingMessage(msg, r);
}
bool
Path::SendExitClose(const routing::CloseExitMessage& msg, AbstractRouter* r)
{
LogInfo(Name(), " closing exit to ", Endpoint());
// mark as not exit anymore
_role &= ~ePathRoleExit;
return SendRoutingMessage(msg, r);
}
bool
Path::HandleObtainExitMessage(const routing::ObtainExitMessage& msg, AbstractRouter* r)
{
(void)msg;
(void)r;
LogError(Name(), " got unwarranted OXM");
return false;
}
bool
Path::HandleUpdateExitMessage(const routing::UpdateExitMessage& msg, AbstractRouter* r)
{
(void)msg;
(void)r;
LogError(Name(), " got unwarranted UXM");
return false;
}
bool
Path::HandleRejectExitMessage(const routing::RejectExitMessage& msg, AbstractRouter* r)
{
if (m_ExitObtainTX && msg.tx_id == m_ExitObtainTX)
{
if (!msg.Verify(EndpointPubKey()))
{
LogError(Name(), "RXM invalid signature");
return false;
}
LogInfo(Name(), " ", Endpoint(), " Rejected exit");
MarkActive(r->Now());
return InformExitResult(llarp_time_t(msg.backoff_time));
}
LogError(Name(), " got unwarranted RXM");
return false;
}
bool
Path::HandleGrantExitMessage(const routing::GrantExitMessage& msg, AbstractRouter* r)
{
if (m_ExitObtainTX && msg.tx_id == m_ExitObtainTX)
{
if (!msg.Verify(EndpointPubKey()))
{
LogError(Name(), " GXM signature failed");
return false;
}
// we now can send exit traffic
_role |= ePathRoleExit;
LogInfo(Name(), " ", Endpoint(), " Granted exit");
MarkActive(r->Now());
return InformExitResult(0s);
}
LogError(Name(), " got unwarranted GXM");
return false;
}
bool
Path::InformExitResult(llarp_time_t B)
{
auto self = shared_from_this();
bool result = true;
for (const auto& hook : m_ObtainedExitHooks)
result = hook(self, B) and result;
m_ObtainedExitHooks.clear();
return result;
}
bool
Path::HandleTransferTrafficMessage(const routing::TransferTrafficMessage& msg, AbstractRouter* r)
{
// check if we can handle exit data
if (!SupportsAnyRoles(ePathRoleExit | ePathRoleSVC))
return false;
// handle traffic if we have a handler
if (!m_ExitTrafficHandler)
return false;
bool sent = msg.enc_buf.size() > 0;
auto self = shared_from_this();
for (const auto& pkt : msg.enc_buf)
{
if (pkt.size() <= 8)
continue;
auto counter = oxenc::load_big_to_host<uint64_t>(pkt.data());
if (m_ExitTrafficHandler(
self, llarp_buffer_t(pkt.data() + 8, pkt.size() - 8), counter, msg.protocol))
{
MarkActive(r->Now());
EnterState(ePathEstablished, r->Now());
}
}
return sent;
}
} // namespace llarp::path