lokinet/llarp/service/protocol.cpp
2019-12-03 11:20:45 -07:00

470 lines
14 KiB
C++

#include <service/protocol.hpp>
#include <path/path.hpp>
#include <routing/handler.hpp>
#include <util/buffer.hpp>
#include <util/mem.hpp>
#include <util/meta/memfn.hpp>
#include <util/thread/logic.hpp>
#include <utility>
namespace llarp
{
namespace service
{
ProtocolMessage::ProtocolMessage()
{
tag.Zero();
}
ProtocolMessage::ProtocolMessage(const ConvoTag& t) : tag(t)
{
}
ProtocolMessage::~ProtocolMessage() = default;
void
ProtocolMessage::PutBuffer(const llarp_buffer_t& buf)
{
payload.resize(buf.sz);
memcpy(payload.data(), buf.base, buf.sz);
}
void
ProtocolMessage::ProcessAsync(path::Path_ptr path, PathID_t from,
std::shared_ptr< ProtocolMessage > self)
{
if(!self->handler->HandleDataMessage(path, from, self))
LogWarn("failed to handle data message from ", path->Name());
}
bool
ProtocolMessage::DecodeKey(const llarp_buffer_t& k, llarp_buffer_t* buf)
{
bool read = false;
if(!BEncodeMaybeReadDictInt("a", proto, read, k, buf))
return false;
if(k == "d")
{
llarp_buffer_t strbuf;
if(!bencode_read_string(buf, &strbuf))
return false;
PutBuffer(strbuf);
return true;
}
if(!BEncodeMaybeReadDictEntry("i", introReply, read, k, buf))
return false;
if(!BEncodeMaybeReadDictInt("n", seqno, read, k, buf))
return false;
if(!BEncodeMaybeReadDictEntry("s", sender, read, k, buf))
return false;
if(!BEncodeMaybeReadDictEntry("t", tag, read, k, buf))
return false;
if(!BEncodeMaybeReadDictInt("v", version, read, k, buf))
return false;
return read;
}
bool
ProtocolMessage::BEncode(llarp_buffer_t* buf) const
{
if(!bencode_start_dict(buf))
return false;
if(!BEncodeWriteDictInt("a", proto, buf))
return false;
if(!bencode_write_bytestring(buf, "d", 1))
return false;
if(!bencode_write_bytestring(buf, payload.data(), payload.size()))
return false;
if(!BEncodeWriteDictEntry("i", introReply, buf))
return false;
if(!BEncodeWriteDictInt("n", seqno, buf))
return false;
if(!BEncodeWriteDictEntry("s", sender, buf))
return false;
if(!tag.IsZero())
{
if(!BEncodeWriteDictEntry("t", tag, buf))
return false;
}
if(!BEncodeWriteDictInt("v", version, buf))
return false;
return bencode_end(buf);
}
ProtocolFrame::~ProtocolFrame() = default;
bool
ProtocolFrame::BEncode(llarp_buffer_t* buf) const
{
if(!bencode_start_dict(buf))
return false;
if(!BEncodeWriteDictMsgType(buf, "A", "H"))
return false;
if(!C.IsZero())
{
if(!BEncodeWriteDictEntry("C", C, buf))
return false;
}
if(D.size() > 0)
{
if(!BEncodeWriteDictEntry("D", D, buf))
return false;
}
if(!BEncodeWriteDictEntry("F", F, buf))
return false;
if(!N.IsZero())
{
if(!BEncodeWriteDictEntry("N", N, buf))
return false;
}
if(R)
{
if(!BEncodeWriteDictInt("R", R, buf))
return false;
}
if(!T.IsZero())
{
if(!BEncodeWriteDictEntry("T", T, buf))
return false;
}
if(!BEncodeWriteDictInt("V", version, buf))
return false;
if(!BEncodeWriteDictEntry("Z", Z, buf))
return false;
return bencode_end(buf);
}
bool
ProtocolFrame::DecodeKey(const llarp_buffer_t& key, llarp_buffer_t* val)
{
bool read = false;
if(key == "A")
{
llarp_buffer_t strbuf;
if(!bencode_read_string(val, &strbuf))
return false;
if(strbuf.sz != 1)
return false;
return *strbuf.cur == 'H';
}
if(!BEncodeMaybeReadDictEntry("D", D, read, key, val))
return false;
if(!BEncodeMaybeReadDictEntry("F", F, read, key, val))
return false;
if(!BEncodeMaybeReadDictEntry("C", C, read, key, val))
return false;
if(!BEncodeMaybeReadDictEntry("N", N, read, key, val))
return false;
if(!BEncodeMaybeReadDictInt("S", S, read, key, val))
return false;
if(!BEncodeMaybeReadDictInt("R", R, read, key, val))
return false;
if(!BEncodeMaybeReadDictEntry("T", T, read, key, val))
return false;
if(!BEncodeMaybeVerifyVersion("V", version, LLARP_PROTO_VERSION, read, key,
val))
return false;
if(!BEncodeMaybeReadDictEntry("Z", Z, read, key, val))
return false;
return read;
}
bool
ProtocolFrame::DecryptPayloadInto(const SharedSecret& sharedkey,
ProtocolMessage& msg) const
{
Encrypted_t tmp = D;
auto buf = tmp.Buffer();
CryptoManager::instance()->xchacha20(*buf, sharedkey, N);
return bencode_decode_dict(msg, buf);
}
bool
ProtocolFrame::Sign(const Identity& localIdent)
{
Z.Zero();
std::array< byte_t, MAX_PROTOCOL_MESSAGE_SIZE > tmp;
llarp_buffer_t buf(tmp);
// encode
if(!BEncode(&buf))
{
LogError("message too big to encode");
return false;
}
// rewind
buf.sz = buf.cur - buf.base;
buf.cur = buf.base;
// sign
return localIdent.Sign(Z, buf);
}
bool
ProtocolFrame::EncryptAndSign(const ProtocolMessage& msg,
const SharedSecret& sessionKey,
const Identity& localIdent)
{
std::array< byte_t, MAX_PROTOCOL_MESSAGE_SIZE > tmp;
llarp_buffer_t buf(tmp);
// encode message
if(!msg.BEncode(&buf))
{
LogError("message too big to encode");
return false;
}
// rewind
buf.sz = buf.cur - buf.base;
buf.cur = buf.base;
// encrypt
CryptoManager::instance()->xchacha20(buf, sessionKey, N);
// put encrypted buffer
D = buf;
// zero out signature
Z.Zero();
llarp_buffer_t buf2(tmp);
// encode frame
if(!BEncode(&buf2))
{
LogError("frame too big to encode");
DumpBuffer(buf2);
return false;
}
// rewind
buf2.sz = buf2.cur - buf2.base;
buf2.cur = buf2.base;
// sign
if(!localIdent.Sign(Z, buf2))
{
LogError("failed to sign? wtf?!");
return false;
}
return true;
}
struct AsyncFrameDecrypt
{
path::Path_ptr path;
std::shared_ptr< Logic > logic;
std::shared_ptr< ProtocolMessage > msg;
const Identity& m_LocalIdentity;
IDataHandler* handler;
const ProtocolFrame frame;
const Introduction fromIntro;
AsyncFrameDecrypt(std::shared_ptr< Logic > l, const Identity& localIdent,
IDataHandler* h, std::shared_ptr< ProtocolMessage > m,
const ProtocolFrame& f, const Introduction& recvIntro)
: logic(std::move(l))
, msg(std::move(m))
, m_LocalIdentity(localIdent)
, handler(h)
, frame(f)
, fromIntro(recvIntro)
{
}
static void
Work(void* user)
{
auto* self = static_cast< AsyncFrameDecrypt* >(user);
auto crypto = CryptoManager::instance();
SharedSecret K;
SharedSecret sharedKey;
// copy
ProtocolFrame frame(self->frame);
if(!crypto->pqe_decrypt(self->frame.C, K,
pq_keypair_to_secret(self->m_LocalIdentity.pq)))
{
LogError("pqke failed C=", self->frame.C);
self->msg.reset();
delete self;
return;
}
// decrypt
auto buf = frame.D.Buffer();
crypto->xchacha20(*buf, K, self->frame.N);
if(!bencode_decode_dict(*self->msg, buf))
{
LogError("failed to decode inner protocol message");
DumpBuffer(*buf);
self->msg.reset();
delete self;
return;
}
// verify signature of outer message after we parsed the inner message
if(!self->frame.Verify(self->msg->sender))
{
LogError("intro frame has invalid signature Z=", self->frame.Z,
" from ", self->msg->sender.Addr());
Dump< MAX_PROTOCOL_MESSAGE_SIZE >(self->frame);
Dump< MAX_PROTOCOL_MESSAGE_SIZE >(*self->msg);
self->msg.reset();
delete self;
return;
}
if(self->handler->HasConvoTag(self->msg->tag))
{
LogError("dropping duplicate convo tag T=", self->msg->tag);
// TODO: send convotag reset
self->msg.reset();
delete self;
return;
}
// PKE (A, B, N)
SharedSecret sharedSecret;
path_dh_func dh_server =
util::memFn(&Crypto::dh_server, CryptoManager::instance());
if(!self->m_LocalIdentity.KeyExchange(dh_server, sharedSecret,
self->msg->sender, self->frame.N))
{
LogError("x25519 key exchange failed");
Dump< MAX_PROTOCOL_MESSAGE_SIZE >(self->frame);
self->msg.reset();
delete self;
return;
}
std::array< byte_t, 64 > tmp;
// K
std::copy(K.begin(), K.end(), tmp.begin());
// S = HS( K + PKE( A, B, N))
std::copy(sharedSecret.begin(), sharedSecret.end(), tmp.begin() + 32);
crypto->shorthash(sharedKey, llarp_buffer_t(tmp));
self->handler->PutIntroFor(self->msg->tag, self->msg->introReply);
self->handler->PutReplyIntroFor(self->msg->tag, self->fromIntro);
self->handler->PutSenderFor(self->msg->tag, self->msg->sender, true);
self->handler->PutCachedSessionKeyFor(self->msg->tag, sharedKey);
self->msg->handler = self->handler;
std::shared_ptr< ProtocolMessage > msg = std::move(self->msg);
path::Path_ptr path = std::move(self->path);
const PathID_t from = self->frame.F;
LogicCall(self->logic,
[=]() { ProtocolMessage::ProcessAsync(path, from, msg); });
delete self;
}
};
ProtocolFrame&
ProtocolFrame::operator=(const ProtocolFrame& other)
{
C = other.C;
D = other.D;
F = other.F;
N = other.N;
Z = other.Z;
T = other.T;
R = other.R;
S = other.S;
version = other.version;
return *this;
}
struct AsyncDecrypt
{
ServiceInfo si;
SharedSecret shared;
ProtocolFrame frame;
};
bool
ProtocolFrame::AsyncDecryptAndVerify(
std::shared_ptr< Logic > logic, path::Path_ptr recvPath,
const std::shared_ptr< llarp::thread::ThreadPool >& worker,
const Identity& localIdent, IDataHandler* handler) const
{
auto msg = std::make_shared< ProtocolMessage >();
msg->handler = handler;
if(T.IsZero())
{
LogInfo("Got protocol frame with new convo");
// we need to dh
auto dh = new AsyncFrameDecrypt(logic, localIdent, handler, msg, *this,
recvPath->intro);
dh->path = recvPath;
return worker->addJob(std::bind(&AsyncFrameDecrypt::Work, dh));
}
auto v = new AsyncDecrypt();
if(!handler->GetCachedSessionKeyFor(T, v->shared))
{
LogError("No cached session for T=", T);
delete v;
return false;
}
if(!handler->GetSenderFor(T, v->si))
{
LogError("No sender for T=", T);
delete v;
return false;
}
v->frame = *this;
return worker->addJob(
[v, msg = std::move(msg), recvPath = std::move(recvPath)]() {
if(not v->frame.Verify(v->si))
{
LogError("Signature failure from ", v->si.Addr());
delete v;
return;
}
if(not v->frame.DecryptPayloadInto(v->shared, *msg))
{
LogError("failed to decrypt message");
delete v;
return;
}
RecvDataEvent ev;
ev.fromPath = std::move(recvPath);
ev.pathid = v->frame.F;
ev.msg = std::move(msg);
msg->handler->QueueRecvData(std::move(ev));
delete v;
});
}
bool
ProtocolFrame::operator==(const ProtocolFrame& other) const
{
return C == other.C && D == other.D && N == other.N && Z == other.Z
&& T == other.T && S == other.S && version == other.version;
}
bool
ProtocolFrame::Verify(const ServiceInfo& svc) const
{
ProtocolFrame copy(*this);
// save signature
// zero out signature for verify
copy.Z.Zero();
// serialize
std::array< byte_t, MAX_PROTOCOL_MESSAGE_SIZE > tmp;
llarp_buffer_t buf(tmp);
if(!copy.BEncode(&buf))
{
LogError("bencode fail");
return false;
}
// rewind buffer
buf.sz = buf.cur - buf.base;
buf.cur = buf.base;
// verify
return svc.Verify(buf, Z);
}
bool
ProtocolFrame::HandleMessage(routing::IMessageHandler* h,
ABSL_ATTRIBUTE_UNUSED AbstractRouter* r) const
{
return h->HandleHiddenServiceFrame(*this);
}
} // namespace service
} // namespace llarp