lokinet/llarp/path.cpp
Jeff Becker 08b60a9ae7 update code to match protocol spec
backwards incompat change
2018-07-29 08:20:32 +10:00

496 lines
12 KiB
C++

#include <deque>
#include <llarp/encrypted_frame.hpp>
#include <llarp/path.hpp>
#include <llarp/pathbuilder.hpp>
#include "buffer.hpp"
#include "router.hpp"
namespace llarp
{
namespace path
{
PathContext::PathContext(llarp_router* router)
: m_Router(router), m_AllowTransit(false)
{
}
PathContext::~PathContext()
{
}
void
PathContext::AllowTransit()
{
m_AllowTransit = true;
}
bool
PathContext::AllowingTransit() const
{
return m_AllowTransit;
}
llarp_threadpool*
PathContext::Worker()
{
return m_Router->tp;
}
llarp_crypto*
PathContext::Crypto()
{
return &m_Router->crypto;
}
llarp_logic*
PathContext::Logic()
{
return m_Router->logic;
}
byte_t*
PathContext::EncryptionSecretKey()
{
return m_Router->encryption;
}
bool
PathContext::HopIsUs(const PubKey& k) const
{
return memcmp(k, m_Router->pubkey(), PUBKEYSIZE) == 0;
}
bool
PathContext::ForwardLRCM(const RouterID& nextHop,
std::deque< EncryptedFrame >& frames)
{
llarp::LogDebug("fowarding LRCM to ", nextHop);
LR_CommitMessage* msg = new LR_CommitMessage;
while(frames.size())
{
msg->frames.push_back(frames.front());
frames.pop_front();
}
return m_Router->SendToOrQueue(nextHop, msg);
}
template < typename Map_t, typename Key_t, typename CheckValue_t,
typename GetFunc_t >
IHopHandler*
MapGet(Map_t& map, const Key_t& k, CheckValue_t check, GetFunc_t get)
{
std::unique_lock< std::mutex > lock(map.first);
auto range = map.second.equal_range(k);
for(auto i = range.first; i != range.second; ++i)
{
if(check(i->second))
return get(i->second);
}
return nullptr;
}
template < typename Map_t, typename Key_t, typename CheckValue_t >
bool
MapHas(Map_t& map, const Key_t& k, CheckValue_t check)
{
std::unique_lock< std::mutex > lock(map.first);
auto range = map.second.equal_range(k);
for(auto i = range.first; i != range.second; ++i)
{
if(check(i->second))
return true;
}
return false;
}
template < typename Map_t, typename Key_t, typename Value_t >
void
MapPut(Map_t& map, const Key_t& k, const Value_t& v)
{
std::unique_lock< std::mutex > lock(map.first);
map.second.insert(std::make_pair(k, v));
}
template < typename Map_t, typename Visit_t >
void
MapIter(Map_t& map, Visit_t v)
{
std::unique_lock< std::mutex > lock(map.first);
for(const auto& item : map.second)
v(item);
}
template < typename Map_t, typename Key_t, typename Check_t >
void
MapDel(Map_t& map, const Key_t& k, Check_t check)
{
std::unique_lock< std::mutex > lock(map.first);
auto range = map.second.equal_range(k);
for(auto i = range.first; i != range.second;)
{
if(check(i->second))
i = map.second.erase(i);
else
++i;
}
}
void
PathContext::AddOwnPath(PathSet* set, Path* path)
{
set->AddPath(path);
MapPut(m_OurPaths, path->TXID(), set);
MapPut(m_OurPaths, path->RXID(), set);
}
bool
PathContext::HasTransitHop(const TransitHopInfo& info)
{
return MapHas(m_TransitPaths, info.txID, [info](TransitHop* hop) -> bool {
return info == hop->info;
});
}
IHopHandler*
PathContext::GetByUpstream(const RouterID& remote, const PathID_t& id)
{
auto own = MapGet(m_OurPaths, id,
[](const PathSet* s) -> bool {
// TODO: is this right?
return true;
},
[remote, id](PathSet* p) -> IHopHandler* {
return p->GetByUpstream(remote, id);
});
if(own)
return own;
return MapGet(m_TransitPaths, id,
[remote](const TransitHop* hop) -> bool {
return hop->info.upstream == remote;
},
[](TransitHop* h) -> IHopHandler* { return h; });
}
IHopHandler*
PathContext::GetByDownstream(const RouterID& remote, const PathID_t& id)
{
return MapGet(m_TransitPaths, id,
[remote](const TransitHop* hop) -> bool {
return hop->info.downstream == remote;
},
[](TransitHop* h) -> IHopHandler* { return h; });
}
PathSet*
PathContext::GetLocalPathSet(const PathID_t& id)
{
auto& map = m_OurPaths;
std::unique_lock< std::mutex > lock(map.first);
auto itr = map.second.find(id);
if(itr != map.second.end())
{
return itr->second;
}
return nullptr;
}
const byte_t*
PathContext::OurRouterID() const
{
return m_Router->pubkey();
}
llarp_router*
PathContext::Router()
{
return m_Router;
}
void
PathContext::PutTransitHop(TransitHop* hop)
{
MapPut(m_TransitPaths, hop->info.txID, hop);
MapPut(m_TransitPaths, hop->info.rxID, hop);
}
void
PathContext::ExpirePaths()
{
std::unique_lock< std::mutex > lock(m_TransitPaths.first);
auto now = llarp_time_now_ms();
auto& map = m_TransitPaths.second;
auto itr = map.begin();
std::set< TransitHop* > removePaths;
while(itr != map.end())
{
if(itr->second->Expired(now))
{
TransitHop* path = itr->second;
llarp::LogDebug("transit path expired ", path->info);
removePaths.insert(path);
}
++itr;
}
for(auto& p : removePaths)
{
map.erase(p->info.txID);
map.erase(p->info.rxID);
delete p;
}
for(auto& builder : m_PathBuilders)
{
builder->ExpirePaths(now);
}
}
void
PathContext::BuildPaths()
{
for(auto& builder : m_PathBuilders)
{
if(builder->ShouldBuildMore())
{
builder->BuildOne();
}
}
}
void
PathContext::TickPaths()
{
auto now = llarp_time_now_ms();
for(auto& builder : m_PathBuilders)
builder->Tick(now, m_Router);
}
void
PathContext::AddPathBuilder(llarp_pathbuilder_context* ctx)
{
m_PathBuilders.push_back(ctx);
}
PathHopConfig::PathHopConfig()
{
llarp_rc_clear(&router);
}
PathHopConfig::~PathHopConfig()
{
llarp_rc_free(&router);
}
Path::Path(llarp_path_hops* h) : hops(h->numHops)
{
for(size_t idx = 0; idx < h->numHops; ++idx)
{
llarp_rc_copy(&hops[idx].router, &h->hops[idx].router);
hops[idx].txID.Randomize();
hops[idx].rxID.Randomize();
}
for(size_t idx = 0; idx < h->numHops - 1; ++idx)
{
hops[idx].txID = hops[idx + 1].rxID;
}
// initialize parts of the introduction
intro.router = hops[h->numHops - 1].router.pubkey;
// TODO: or is it rxid ?
intro.pathID = hops[h->numHops - 1].txID;
}
void
Path::SetBuildResultHook(BuildResultHookFunc func)
{
m_BuiltHook = func;
}
RouterID
Path::Endpoint() const
{
return hops[hops.size() - 1].router.pubkey;
}
const PathID_t&
Path::TXID() const
{
return hops[0].txID;
}
const PathID_t&
Path::RXID() const
{
return hops[0].rxID;
}
bool
Path::IsReady() const
{
return intro.latency > 0 && status == ePathEstablished;
}
RouterID
Path::Upstream() const
{
return hops[0].router.pubkey;
}
void
Path::Tick(llarp_time_t now, llarp_router* r)
{
if(Expired(now))
return;
if(now < m_LastLatencyTestTime)
return;
auto dlt = now - m_LastLatencyTestTime;
if(dlt > 5000 && m_LastLatencyTestID == 0)
{
llarp::routing::PathLatencyMessage latency;
latency.T = llarp_randint();
m_LastLatencyTestID = latency.T;
m_LastLatencyTestTime = now;
SendRoutingMessage(&latency, r);
}
}
bool
Path::HandleUpstream(llarp_buffer_t buf, const TunnelNonce& Y,
llarp_router* r)
{
TunnelNonce n = Y;
for(const auto& hop : hops)
{
r->crypto.xchacha20(buf, hop.shared, n);
n ^= hop.nonceXOR;
}
RelayUpstreamMessage* msg = new RelayUpstreamMessage;
msg->X = buf;
msg->Y = Y;
msg->pathid = TXID();
return r->SendToOrQueue(Upstream(), msg);
}
bool
Path::Expired(llarp_time_t now) const
{
if(status == ePathEstablished)
return now - buildStarted > hops[0].lifetime;
else if(status == ePathBuilding)
return now - buildStarted > PATH_BUILD_TIMEOUT;
else
return true;
}
bool
Path::HandleDownstream(llarp_buffer_t buf, const TunnelNonce& Y,
llarp_router* r)
{
TunnelNonce n = Y;
for(const auto& hop : hops)
{
n ^= hop.nonceXOR;
r->crypto.xchacha20(buf, hop.shared, n);
}
return HandleRoutingMessage(buf, r);
}
bool
Path::HandleRoutingMessage(llarp_buffer_t buf, llarp_router* r)
{
if(!m_InboundMessageParser.ParseMessageBuffer(buf, this, RXID(), r))
{
llarp::LogWarn("Failed to parse inbound routing message");
return false;
}
return true;
}
bool
Path::SendRoutingMessage(llarp::routing::IMessage* msg, llarp_router* r)
{
msg->S = m_SequenceNum++;
byte_t tmp[MAX_LINK_MSG_SIZE / 2];
auto buf = llarp::StackBuffer< decltype(tmp) >(tmp);
if(!msg->BEncode(&buf))
return false;
// make nonce
TunnelNonce N;
N.Randomize();
buf.sz = buf.cur - buf.base;
// pad smaller messages
if(buf.sz < MESSAGE_PAD_SIZE)
{
// randomize padding
r->crypto.randbytes(buf.cur, MESSAGE_PAD_SIZE - buf.sz);
buf.sz = MESSAGE_PAD_SIZE;
}
buf.cur = buf.base;
return HandleUpstream(buf, N, r);
}
bool
Path::HandlePathTransferMessage(
const llarp::routing::PathTransferMessage* msg, llarp_router* r)
{
llarp::LogWarn("unwarrented path transfer message on tx=", TXID(),
" rx=", RXID());
return false;
}
bool
Path::HandlePathConfirmMessage(
const llarp::routing::PathConfirmMessage* msg, llarp_router* r)
{
if(status == ePathBuilding)
{
// finish initializing introduction
intro.expiresAt = buildStarted + hops[0].lifetime;
// confirm that we build the path
status = ePathEstablished;
llarp::LogInfo("path is confirmed tx=", TXID(), " rx=", RXID());
if(m_BuiltHook)
m_BuiltHook(this);
m_BuiltHook = nullptr;
llarp::routing::PathLatencyMessage latency;
latency.T = llarp_randint();
m_LastLatencyTestID = latency.T;
m_LastLatencyTestTime = llarp_time_now_ms();
return SendRoutingMessage(&latency, r);
}
llarp::LogWarn("got unwarrented path confirm message on tx=", RXID(),
" rx=", RXID());
return false;
}
bool
Path::HandlePathLatencyMessage(
const llarp::routing::PathLatencyMessage* msg, llarp_router* r)
{
if(msg->L == m_LastLatencyTestID && status == ePathEstablished)
{
intro.latency = llarp_time_now_ms() - m_LastLatencyTestTime;
llarp::LogInfo("path latency is ", intro.latency, " ms for tx=", TXID(),
" rx=", RXID());
m_LastLatencyTestID = 0;
return true;
}
else
{
llarp::LogWarn("unwarrented path latency message via ", Upstream());
return false;
}
}
bool
Path::HandleDHTMessage(const llarp::dht::IMessage* msg, llarp_router* r)
{
std::vector< llarp::dht::IMessage* > discard;
auto result = msg->HandleMessage(r->dht, discard);
for(auto& msg : discard)
delete msg;
return result;
}
} // namespace path
} // namespace llarp