#include #include #include #include #include #include #include #include #include #include #include #include namespace llarp { NetID & NetID::DefaultValue() { static NetID defaultID( reinterpret_cast< const byte_t * >(Version::LLARP_NET_ID)); return defaultID; } bool RouterContact::IgnoreBogons = false; #ifdef TESTNET // 1 minute for testnet llarp_time_t RouterContact::Lifetime = 60 * 1000; #else /// 1 day for real network llarp_time_t RouterContact::Lifetime = 24 * 60 * 60 * 1000; #endif /// update RCs every 5 minutes llarp_time_t RouterContact::UpdateInterval = 5 * 60 * 1000; /// an RC inserted long enough ago (30 min) is considered stale and is removed llarp_time_t RouterContact::StaleInsertionAge = 30 * 60 * 1000; NetID::NetID(const byte_t *val) : AlignedBuffer< 8 >() { size_t len = strnlen(reinterpret_cast< const char * >(val), size()); std::copy(val, val + len, begin()); } NetID::NetID() : NetID(DefaultValue().data()) { } bool NetID::operator==(const NetID &other) const { return ToString() == other.ToString(); } std::string NetID::ToString() const { auto term = std::find(begin(), end(), '\0'); return std::string(begin(), term); } bool NetID::BDecode(llarp_buffer_t *buf) { Zero(); llarp_buffer_t strbuf; if(!bencode_read_string(buf, &strbuf)) return false; if(strbuf.sz > size()) return false; std::copy(strbuf.base, strbuf.base + strbuf.sz, begin()); return true; } bool NetID::BEncode(llarp_buffer_t *buf) const { auto term = std::find(begin(), end(), '\0'); return bencode_write_bytestring(buf, data(), std::distance(begin(), term)); } bool RouterContact::BEncode(llarp_buffer_t *buf) const { /* write dict begin */ if(!bencode_start_dict(buf)) return false; /* write ai if they exist */ if(!bencode_write_bytestring(buf, "a", 1)) return false; if(!BEncodeWriteList(addrs.begin(), addrs.end(), buf)) return false; /* write netid */ if(!bencode_write_bytestring(buf, "i", 1)) return false; if(!netID.BEncode(buf)) return false; /* write signing pubkey */ if(!bencode_write_bytestring(buf, "k", 1)) return false; if(!pubkey.BEncode(buf)) return false; std::string nick = Nick(); if(nick.size()) { /* write nickname */ if(!bencode_write_bytestring(buf, "n", 1)) return false; if(!bencode_write_bytestring(buf, nick.c_str(), nick.size())) return false; } /* write encryption pubkey */ if(!bencode_write_bytestring(buf, "p", 1)) return false; if(!enckey.BEncode(buf)) return false; /* write last updated */ if(!bencode_write_bytestring(buf, "u", 1)) return false; if(!bencode_write_uint64(buf, last_updated)) return false; /* write version */ if(!bencode_write_version_entry(buf)) return false; /* write xi if they exist */ if(!bencode_write_bytestring(buf, "x", 1)) return false; if(!BEncodeWriteList(exits.begin(), exits.end(), buf)) return false; /* write signature */ if(!bencode_write_bytestring(buf, "z", 1)) return false; if(!signature.BEncode(buf)) return false; return bencode_end(buf); } void RouterContact::Clear() { addrs.clear(); exits.clear(); signature.Zero(); nickname.Zero(); enckey.Zero(); pubkey.Zero(); last_updated = 0; } util::StatusObject RouterContact::ExtractStatus() const { util::StatusObject obj{{"lastUpdated", last_updated}, {"exit", IsExit()}, {"publicRouter", IsPublicRouter()}, {"identity", pubkey.ToHex()}}; if(HasNick()) obj.Put("nickname", Nick()); return obj; } bool RouterContact::DecodeKey(const llarp_buffer_t &key, llarp_buffer_t *buf) { bool read = false; if(!BEncodeMaybeReadDictList("a", addrs, read, key, buf)) return false; if(!BEncodeMaybeReadDictEntry("i", netID, read, key, buf)) return false; if(!BEncodeMaybeReadDictEntry("k", pubkey, read, key, buf)) return false; if(key == "n") { llarp_buffer_t strbuf; if(!bencode_read_string(buf, &strbuf)) return false; if(strbuf.sz > nickname.size()) return false; nickname.Zero(); std::copy(strbuf.base, strbuf.base + strbuf.sz, nickname.begin()); return true; } if(!BEncodeMaybeReadDictEntry("p", enckey, read, key, buf)) return false; if(!BEncodeMaybeReadDictInt("u", last_updated, read, key, buf)) return false; if(!BEncodeMaybeReadDictInt("v", version, read, key, buf)) return false; if(!BEncodeMaybeReadDictList("x", exits, read, key, buf)) return false; if(!BEncodeMaybeReadDictEntry("z", signature, read, key, buf)) return false; return read; } bool RouterContact::IsPublicRouter() const { return addrs.size() > 0; } bool RouterContact::HasNick() const { return nickname[0] != 0; } void RouterContact::SetNick(string_view nick) { nickname.Zero(); std::copy(nick.begin(), nick.begin() + std::min(nick.size(), nickname.size()), nickname.begin()); } bool RouterContact::IsExpired(llarp_time_t now) const { return Age(now) >= Lifetime; } llarp_time_t RouterContact::TimeUntilExpires(llarp_time_t now) const { const auto expiresAt = last_updated + Lifetime; return now < expiresAt ? expiresAt - now : 0; } llarp_time_t RouterContact::Age(llarp_time_t now) const { return now > last_updated ? now - last_updated : 0; } bool RouterContact::ExpiresSoon(llarp_time_t now, llarp_time_t dlt) const { return TimeUntilExpires(now) <= dlt; } std::string RouterContact::Nick() const { auto term = std::find(nickname.begin(), nickname.end(), '\0'); return std::string(nickname.begin(), term); } bool RouterContact::Sign(const SecretKey &secretkey) { pubkey = llarp::seckey_topublic(secretkey); std::array< byte_t, MAX_RC_SIZE > tmp; llarp_buffer_t buf(tmp); signature.Zero(); last_updated = time_now_ms(); if(!BEncode(&buf)) return false; buf.sz = buf.cur - buf.base; buf.cur = buf.base; return CryptoManager::instance()->sign(signature, secretkey, buf); } bool RouterContact::Verify(llarp_time_t now, bool allowExpired) const { if(netID != NetID::DefaultValue()) { llarp::LogError("netid missmatch: '", netID, "' != '", NetID::DefaultValue(), "'"); return false; } if(IsExpired(now)) { if(!allowExpired) { llarp::LogError("RC is expired"); return false; } llarp::LogWarn("RC is expired"); } for(const auto &a : addrs) { if(IsBogon(a.ip) && !IgnoreBogons) { llarp::LogError("invalid address info: ", a); return false; } } for(const auto &exit : exits) { if(IsBogonRange(exit.address, exit.netmask)) { llarp::LogError("bogon exit: ", exit); return false; } } if(!VerifySignature()) { llarp::LogError("invalid signature"); return false; } return true; } bool RouterContact::VerifySignature() const { RouterContact copy; copy = *this; copy.signature.Zero(); std::array< byte_t, MAX_RC_SIZE > tmp; llarp_buffer_t buf(tmp); if(!copy.BEncode(&buf)) { llarp::LogError("bencode failed"); return false; } buf.sz = buf.cur - buf.base; buf.cur = buf.base; return CryptoManager::instance()->verify(pubkey, buf, signature); } bool RouterContact::Write(const char *fname) const { std::array< byte_t, MAX_RC_SIZE > tmp; llarp_buffer_t buf(tmp); if(!BEncode(&buf)) return false; buf.sz = buf.cur - buf.base; buf.cur = buf.base; const fs::path fpath = std::string(fname); /* */ auto optional_f = llarp::util::OpenFileStream< std::ofstream >(fpath, std::ios::binary); if(!optional_f) return false; auto &f = optional_f.value(); if(!f.is_open()) return false; f.write((char *)buf.base, buf.sz); return true; } bool RouterContact::Read(const char *fname) { std::array< byte_t, MAX_RC_SIZE > tmp; llarp_buffer_t buf(tmp); std::ifstream f; f.open(fname, std::ios::binary); if(!f.is_open()) { llarp::LogError("Failed to open ", fname); return false; } f.seekg(0, std::ios::end); auto l = f.tellg(); if(l > static_cast< std::streamoff >(sizeof tmp)) return false; f.seekg(0, std::ios::beg); f.read((char *)tmp.data(), l); return BDecode(&buf); } std::ostream & RouterContact::print(std::ostream &stream, int level, int spaces) const { Printer printer(stream, level, spaces); printer.printAttribute("k", pubkey); printer.printAttribute("updated", last_updated); printer.printAttribute("netid", netID); printer.printAttribute("v", version); printer.printAttribute("ai", addrs); printer.printAttribute("xi", exits); printer.printAttribute("e", enckey); printer.printAttribute("z", signature); return stream; } } // namespace llarp