/* * Copyright (c) 2013-2020, The PurpleI2P Project * * This file is part of Purple i2pd project and licensed under BSD3 * * See full license text in LICENSE file at top of project tree */ #include #include #include #include "I2PEndian.h" #include "Log.h" #include "Timestamp.h" #include "LeaseSet.h" #include "ClientContext.h" #include "Transports.h" #include "Signature.h" #include "I2CP.h" namespace i2p { namespace client { I2CPDestination::I2CPDestination (boost::asio::io_service& service, std::shared_ptr owner, std::shared_ptr identity, bool isPublic, const std::map& params): LeaseSetDestination (service, isPublic, ¶ms), m_Owner (owner), m_Identity (identity), m_EncryptionKeyType (m_Identity->GetCryptoKeyType ()) { } void I2CPDestination::SetEncryptionPrivateKey (const uint8_t * key) { m_Decryptor = i2p::data::PrivateKeys::CreateDecryptor (m_Identity->GetCryptoKeyType (), key); } void I2CPDestination::SetECIESx25519EncryptionPrivateKey (const uint8_t * key) { if (!m_ECIESx25519Decryptor || memcmp (m_ECIESx25519PrivateKey, key, 32)) // new key? { m_ECIESx25519Decryptor = std::make_shared(key, true); // calculate public memcpy (m_ECIESx25519PrivateKey, key, 32); } } bool I2CPDestination::Decrypt (const uint8_t * encrypted, uint8_t * data, BN_CTX * ctx, i2p::data::CryptoKeyType preferredCrypto) const { if (preferredCrypto == i2p::data::CRYPTO_KEY_TYPE_ECIES_X25519_AEAD && m_ECIESx25519Decryptor) return m_ECIESx25519Decryptor->Decrypt (encrypted, data, ctx, true); if (m_Decryptor) return m_Decryptor->Decrypt (encrypted, data, ctx, true); else LogPrint (eLogError, "I2CP: decryptor is not set"); return false; } const uint8_t * I2CPDestination::GetEncryptionPublicKey (i2p::data::CryptoKeyType keyType) const { if (keyType == i2p::data::CRYPTO_KEY_TYPE_ECIES_X25519_AEAD && m_ECIESx25519Decryptor) return m_ECIESx25519Decryptor->GetPubicKey (); return nullptr; } bool I2CPDestination::SupportsEncryptionType (i2p::data::CryptoKeyType keyType) const { return keyType == i2p::data::CRYPTO_KEY_TYPE_ECIES_X25519_AEAD ? (bool)m_ECIESx25519Decryptor : m_EncryptionKeyType == keyType; } void I2CPDestination::HandleDataMessage (const uint8_t * buf, size_t len) { uint32_t length = bufbe32toh (buf); if (length > len - 4) length = len - 4; m_Owner->SendMessagePayloadMessage (buf + 4, length); } void I2CPDestination::CreateNewLeaseSet (std::vector > tunnels) { uint8_t priv[256] = {0}; i2p::data::LocalLeaseSet ls (m_Identity, priv, tunnels); // we don't care about encryption key, we need leases only m_LeaseSetExpirationTime = ls.GetExpirationTime (); uint8_t * leases = ls.GetLeases (); leases[-1] = tunnels.size (); htobe16buf (leases - 3, m_Owner->GetSessionID ()); size_t l = 2/*sessionID*/ + 1/*num leases*/ + i2p::data::LEASE_SIZE*tunnels.size (); m_Owner->SendI2CPMessage (I2CP_REQUEST_VARIABLE_LEASESET_MESSAGE, leases - 3, l); } void I2CPDestination::LeaseSetCreated (const uint8_t * buf, size_t len) { auto ls = std::make_shared (m_Identity, buf, len); ls->SetExpirationTime (m_LeaseSetExpirationTime); SetLeaseSet (ls); } void I2CPDestination::LeaseSet2Created (uint8_t storeType, const uint8_t * buf, size_t len) { auto ls = (storeType == i2p::data::NETDB_STORE_TYPE_ENCRYPTED_LEASESET2) ? std::make_shared (m_Identity, buf, len): std::make_shared (storeType, m_Identity, buf, len); ls->SetExpirationTime (m_LeaseSetExpirationTime); SetLeaseSet (ls); } void I2CPDestination::SendMsgTo (const uint8_t * payload, size_t len, const i2p::data::IdentHash& ident, uint32_t nonce) { auto msg = NewI2NPMessage (); uint8_t * buf = msg->GetPayload (); htobe32buf (buf, len); memcpy (buf + 4, payload, len); msg->len += len + 4; msg->FillI2NPMessageHeader (eI2NPData); auto s = GetSharedFromThis (); auto remote = FindLeaseSet (ident); if (remote) { GetService ().post ( [s, msg, remote, nonce]() { bool sent = s->SendMsg (msg, remote); s->m_Owner->SendMessageStatusMessage (nonce, sent ? eI2CPMessageStatusGuaranteedSuccess : eI2CPMessageStatusGuaranteedFailure); }); } else { RequestDestination (ident, [s, msg, nonce](std::shared_ptr ls) { if (ls) { bool sent = s->SendMsg (msg, ls); s->m_Owner->SendMessageStatusMessage (nonce, sent ? eI2CPMessageStatusGuaranteedSuccess : eI2CPMessageStatusGuaranteedFailure); } else s->m_Owner->SendMessageStatusMessage (nonce, eI2CPMessageStatusNoLeaseSet); }); } } bool I2CPDestination::SendMsg (std::shared_ptr msg, std::shared_ptr remote) { auto remoteSession = GetRoutingSession (remote, true); if (!remoteSession) { LogPrint (eLogError, "I2CP: Failed to create remote session"); return false; } auto path = remoteSession->GetSharedRoutingPath (); std::shared_ptr outboundTunnel; std::shared_ptr remoteLease; if (path) { if (!remoteSession->CleanupUnconfirmedTags ()) // no stuck tags { outboundTunnel = path->outboundTunnel; remoteLease = path->remoteLease; } else remoteSession->SetSharedRoutingPath (nullptr); } else { outboundTunnel = GetTunnelPool ()->GetNextOutboundTunnel (); auto leases = remote->GetNonExpiredLeases (); if (!leases.empty ()) remoteLease = leases[rand () % leases.size ()]; if (remoteLease && outboundTunnel) remoteSession->SetSharedRoutingPath (std::make_shared ( i2p::garlic::GarlicRoutingPath{outboundTunnel, remoteLease, 10000, 0, 0})); // 10 secs RTT else remoteSession->SetSharedRoutingPath (nullptr); } if (remoteLease && outboundTunnel) { std::vector msgs; auto garlic = remoteSession->WrapSingleMessage (msg); msgs.push_back (i2p::tunnel::TunnelMessageBlock { i2p::tunnel::eDeliveryTypeTunnel, remoteLease->tunnelGateway, remoteLease->tunnelID, garlic }); outboundTunnel->SendTunnelDataMsg (msgs); return true; } else { if (outboundTunnel) LogPrint (eLogWarning, "I2CP: Failed to send message. All leases expired"); else LogPrint (eLogWarning, "I2CP: Failed to send message. No outbound tunnels"); return false; } } RunnableI2CPDestination::RunnableI2CPDestination (std::shared_ptr owner, std::shared_ptr identity, bool isPublic, const std::map& params): RunnableService ("I2CP"), I2CPDestination (GetIOService (), owner, identity, isPublic, params) { } RunnableI2CPDestination::~RunnableI2CPDestination () { if (IsRunning ()) Stop (); } void RunnableI2CPDestination::Start () { if (!IsRunning ()) { I2CPDestination::Start (); StartIOService (); } } void RunnableI2CPDestination::Stop () { if (IsRunning ()) { I2CPDestination::Stop (); StopIOService (); } } I2CPSession::I2CPSession (I2CPServer& owner, std::shared_ptr socket): m_Owner (owner), m_Socket (socket), m_SessionID (0xFFFF), m_MessageID (0), m_IsSendAccepted (true), m_IsSending (false) { } I2CPSession::~I2CPSession () { if (m_SendQueue) { for (auto& it: *m_SendQueue) delete[] boost::asio::buffer_cast(it); } } void I2CPSession::Start () { ReadProtocolByte (); } void I2CPSession::Stop () { Terminate (); } void I2CPSession::ReadProtocolByte () { if (m_Socket) { auto s = shared_from_this (); m_Socket->async_read_some (boost::asio::buffer (m_Header, 1), [s](const boost::system::error_code& ecode, std::size_t bytes_transferred) { if (!ecode && bytes_transferred > 0 && s->m_Header[0] == I2CP_PROTOCOL_BYTE) s->ReceiveHeader (); else s->Terminate (); }); } } void I2CPSession::ReceiveHeader () { if (!m_Socket) { LogPrint (eLogError, "I2CP: Can't receive header"); return; } boost::asio::async_read (*m_Socket, boost::asio::buffer (m_Header, I2CP_HEADER_SIZE), boost::asio::transfer_all (), std::bind (&I2CPSession::HandleReceivedHeader, shared_from_this (), std::placeholders::_1, std::placeholders::_2)); } void I2CPSession::HandleReceivedHeader (const boost::system::error_code& ecode, std::size_t bytes_transferred) { if (ecode) Terminate (); else { m_PayloadLen = bufbe32toh (m_Header + I2CP_HEADER_LENGTH_OFFSET); if (m_PayloadLen > 0) { if (m_PayloadLen <= I2CP_MAX_MESSAGE_LENGTH) ReceivePayload (); else { LogPrint (eLogError, "I2CP: Unexpected payload length ", m_PayloadLen); Terminate (); } } else // no following payload { HandleMessage (); ReceiveHeader (); // next message } } } void I2CPSession::ReceivePayload () { if (!m_Socket) { LogPrint (eLogError, "I2CP: Can't receive payload"); return; } boost::asio::async_read (*m_Socket, boost::asio::buffer (m_Payload, m_PayloadLen), boost::asio::transfer_all (), std::bind (&I2CPSession::HandleReceivedPayload, shared_from_this (), std::placeholders::_1, std::placeholders::_2)); } void I2CPSession::HandleReceivedPayload (const boost::system::error_code& ecode, std::size_t bytes_transferred) { if (ecode) Terminate (); else { HandleMessage (); m_PayloadLen = 0; ReceiveHeader (); // next message } } void I2CPSession::HandleMessage () { auto handler = m_Owner.GetMessagesHandlers ()[m_Header[I2CP_HEADER_TYPE_OFFSET]]; if (handler) (this->*handler)(m_Payload, m_PayloadLen); else LogPrint (eLogError, "I2CP: Unknown I2CP message ", (int)m_Header[I2CP_HEADER_TYPE_OFFSET]); } void I2CPSession::Terminate () { if (m_Destination) { m_Destination->Stop (); m_Destination = nullptr; } if (m_Socket) { m_Socket->close (); m_Socket = nullptr; } m_Owner.RemoveSession (GetSessionID ()); LogPrint (eLogDebug, "I2CP: session ", m_SessionID, " terminated"); } void I2CPSession::SendI2CPMessage (uint8_t type, const uint8_t * payload, size_t len) { auto l = len + I2CP_HEADER_SIZE; if (l > I2CP_MAX_MESSAGE_LENGTH) { LogPrint (eLogError, "I2CP: Message to send is too long ", l); return; } uint8_t * buf = m_IsSending ? new uint8_t[l] : m_SendBuffer; htobe32buf (buf + I2CP_HEADER_LENGTH_OFFSET, len); buf[I2CP_HEADER_TYPE_OFFSET] = type; memcpy (buf + I2CP_HEADER_SIZE, payload, len); SendBuffer (buf, l); } void I2CPSession::HandleI2CPMessageSent (const boost::system::error_code& ecode, std::size_t bytes_transferred) { if (ecode) { if (ecode != boost::asio::error::operation_aborted) Terminate (); } else if (m_SendQueue) { auto socket = m_Socket; if (socket) { auto queue = m_SendQueue; m_SendQueue = nullptr; boost::asio::async_write (*socket, *queue, boost::asio::transfer_all (), std::bind(&I2CPSession::HandleI2CPMessageSentQueue, shared_from_this (), std::placeholders::_1, std::placeholders::_2, queue)); } } else m_IsSending = false; } void I2CPSession::HandleI2CPMessageSentQueue (const boost::system::error_code& ecode, std::size_t bytes_transferred, SendQueue queue) { for (auto& it: *queue) delete[] boost::asio::buffer_cast(it);; HandleI2CPMessageSent (ecode, bytes_transferred); } void I2CPSession::SendBuffer (uint8_t * buf, size_t len) { auto socket = m_Socket; if (socket) { if (m_IsSending) { auto sendQueue = m_SendQueue; if (!sendQueue) { sendQueue = std::make_shared (); m_SendQueue = sendQueue; } else if (sendQueue->size () > I2CP_MAX_SEND_QUEUE_SIZE) { LogPrint (eLogError, "I2CP: Queue size exceeds ", I2CP_MAX_SEND_QUEUE_SIZE); return; } sendQueue->push_back ({buf, len}); } else { m_IsSending = true; boost::asio::async_write (*socket, boost::asio::buffer (buf, len), boost::asio::transfer_all (), std::bind(&I2CPSession::HandleI2CPMessageSent, shared_from_this (), std::placeholders::_1, std::placeholders::_2)); } } else LogPrint (eLogError, "I2CP: Can't write to the socket"); } std::string I2CPSession::ExtractString (const uint8_t * buf, size_t len) { uint8_t l = buf[0]; if (l > len) l = len; return std::string ((const char *)(buf + 1), l); } size_t I2CPSession::PutString (uint8_t * buf, size_t len, const std::string& str) { auto l = str.length (); if (l + 1 >= len) l = len - 1; if (l > 255) l = 255; // 1 byte max buf[0] = l; memcpy (buf + 1, str.c_str (), l); return l + 1; } void I2CPSession::ExtractMapping (const uint8_t * buf, size_t len, std::map& mapping) // TODO: move to Base.cpp { size_t offset = 0; while (offset < len) { std::string param = ExtractString (buf + offset, len - offset); offset += param.length () + 1; if (buf[offset] != '=') { LogPrint (eLogWarning, "I2CP: Unexpected character ", buf[offset], " instead '=' after ", param); break; } offset++; std::string value = ExtractString (buf + offset, len - offset); offset += value.length () + 1; if (buf[offset] != ';') { LogPrint (eLogWarning, "I2CP: Unexpected character ", buf[offset], " instead ';' after ", value); break; } offset++; mapping.insert (std::make_pair (param, value)); } } void I2CPSession::GetDateMessageHandler (const uint8_t * buf, size_t len) { // get version auto version = ExtractString (buf, len); auto l = version.length () + 1 + 8; uint8_t * payload = new uint8_t[l]; // set date auto ts = i2p::util::GetMillisecondsSinceEpoch (); htobe64buf (payload, ts); // echo vesrion back PutString (payload + 8, l - 8, version); SendI2CPMessage (I2CP_SET_DATE_MESSAGE, payload, l); delete[] payload; } void I2CPSession::CreateSessionMessageHandler (const uint8_t * buf, size_t len) { RAND_bytes ((uint8_t *)&m_SessionID, 2); m_Owner.InsertSession (shared_from_this ()); auto identity = std::make_shared(); size_t offset = identity->FromBuffer (buf, len); if (!offset) { LogPrint (eLogError, "I2CP: create session malformed identity"); SendSessionStatusMessage (3); // invalid return; } uint16_t optionsSize = bufbe16toh (buf + offset); offset += 2; if (optionsSize > len - offset) { LogPrint (eLogError, "I2CP: options size ", optionsSize, "exceeds message size"); SendSessionStatusMessage (3); // invalid return; } std::map params; ExtractMapping (buf + offset, optionsSize, params); offset += optionsSize; // options if (params[I2CP_PARAM_MESSAGE_RELIABILITY] == "none") m_IsSendAccepted = false; offset += 8; // date if (identity->Verify (buf, offset, buf + offset)) // signature { bool isPublic = true; if (params[I2CP_PARAM_DONT_PUBLISH_LEASESET] == "true") isPublic = false; if (!m_Destination) { m_Destination = m_Owner.IsSingleThread () ? std::make_shared(m_Owner.GetService (), shared_from_this (), identity, isPublic, params): std::make_shared(shared_from_this (), identity, isPublic, params); SendSessionStatusMessage (1); // created LogPrint (eLogDebug, "I2CP: session ", m_SessionID, " created"); m_Destination->Start (); } else { LogPrint (eLogError, "I2CP: session already exists"); SendSessionStatusMessage (4); // refused } } else { LogPrint (eLogError, "I2CP: create session signature verification failed"); SendSessionStatusMessage (3); // invalid } } void I2CPSession::DestroySessionMessageHandler (const uint8_t * buf, size_t len) { SendSessionStatusMessage (0); // destroy LogPrint (eLogDebug, "I2CP: session ", m_SessionID, " destroyed"); if (m_Destination) { m_Destination->Stop (); m_Destination = 0; } } void I2CPSession::ReconfigureSessionMessageHandler (const uint8_t * buf, size_t len) { uint8_t status = 3; // rejected if(len > sizeof(uint16_t)) { uint16_t sessionID = bufbe16toh(buf); if(sessionID == m_SessionID) { buf += sizeof(uint16_t); const uint8_t * body = buf; i2p::data::IdentityEx ident; if(ident.FromBuffer(buf, len - sizeof(uint16_t))) { if (ident == *m_Destination->GetIdentity()) { size_t identsz = ident.GetFullLen(); buf += identsz; uint16_t optssize = bufbe16toh(buf); if (optssize <= len - sizeof(uint16_t) - sizeof(uint64_t) - identsz - ident.GetSignatureLen() - sizeof(uint16_t)) { buf += sizeof(uint16_t); std::map opts; ExtractMapping(buf, optssize, opts); buf += optssize; //uint64_t date = bufbe64toh(buf); buf += sizeof(uint64_t); const uint8_t * sig = buf; if(ident.Verify(body, len - sizeof(uint16_t) - ident.GetSignatureLen(), sig)) { if(m_Destination->Reconfigure(opts)) { LogPrint(eLogInfo, "I2CP: reconfigured destination"); status = 2; // updated } else LogPrint(eLogWarning, "I2CP: failed to reconfigure destination"); } else LogPrint(eLogError, "I2CP: invalid reconfigure message signature"); } else LogPrint(eLogError, "I2CP: mapping size mismatch"); } else LogPrint(eLogError, "I2CP: destination mismatch"); } else LogPrint(eLogError, "I2CP: malfromed destination"); } else LogPrint(eLogError, "I2CP: session mismatch"); } else LogPrint(eLogError, "I2CP: short message"); SendSessionStatusMessage (status); } void I2CPSession::SendSessionStatusMessage (uint8_t status) { uint8_t buf[3]; htobe16buf (buf, m_SessionID); buf[2] = status; SendI2CPMessage (I2CP_SESSION_STATUS_MESSAGE, buf, 3); } void I2CPSession::SendMessageStatusMessage (uint32_t nonce, I2CPMessageStatus status) { if (!nonce) return; // don't send status with zero nonce uint8_t buf[15]; htobe16buf (buf, m_SessionID); htobe32buf (buf + 2, m_MessageID++); buf[6] = (uint8_t)status; memset (buf + 7, 0, 4); // size htobe32buf (buf + 11, nonce); SendI2CPMessage (I2CP_MESSAGE_STATUS_MESSAGE, buf, 15); } void I2CPSession::CreateLeaseSetMessageHandler (const uint8_t * buf, size_t len) { uint16_t sessionID = bufbe16toh (buf); if (sessionID == m_SessionID) { size_t offset = 2; if (m_Destination) { offset += i2p::crypto::DSA_PRIVATE_KEY_LENGTH; // skip signing private key // we always assume this field as 20 bytes (DSA) regardless actual size // instead of //offset += m_Destination->GetIdentity ()->GetSigningPrivateKeyLen (); m_Destination->SetEncryptionPrivateKey (buf + offset); offset += 256; m_Destination->LeaseSetCreated (buf + offset, len - offset); } } else LogPrint (eLogError, "I2CP: unexpected sessionID ", sessionID); } void I2CPSession::CreateLeaseSet2MessageHandler (const uint8_t * buf, size_t len) { uint16_t sessionID = bufbe16toh (buf); if (sessionID == m_SessionID) { size_t offset = 2; if (m_Destination) { uint8_t storeType = buf[offset]; offset++; // store type i2p::data::LeaseSet2 ls (storeType, buf + offset, len - offset); // outer layer only for encrypted if (!ls.IsValid ()) { LogPrint (eLogError, "I2CP: invalid LeaseSet2 of type ", storeType); return; } offset += ls.GetBufferLen (); // private keys int numPrivateKeys = buf[offset]; offset++; for (int i = 0; i < numPrivateKeys; i++) { if (offset + 4 > len) return; uint16_t keyType = bufbe16toh (buf + offset); offset += 2; // encryption type uint16_t keyLen = bufbe16toh (buf + offset); offset += 2; // private key length if (offset + keyLen > len) return; if (keyType == i2p::data::CRYPTO_KEY_TYPE_ECIES_X25519_AEAD) m_Destination->SetECIESx25519EncryptionPrivateKey (buf + offset); else { m_Destination->SetEncryptionType (keyType); m_Destination->SetEncryptionPrivateKey (buf + offset); } offset += keyLen; } m_Destination->LeaseSet2Created (storeType, ls.GetBuffer (), ls.GetBufferLen ()); } } else LogPrint (eLogError, "I2CP: unexpected sessionID ", sessionID); } void I2CPSession::SendMessageMessageHandler (const uint8_t * buf, size_t len) { uint16_t sessionID = bufbe16toh (buf); if (sessionID == m_SessionID) { size_t offset = 2; if (m_Destination) { i2p::data::IdentityEx identity; size_t identsize = identity.FromBuffer (buf + offset, len - offset); if (identsize) { offset += identsize; uint32_t payloadLen = bufbe32toh (buf + offset); if (payloadLen + offset <= len) { offset += 4; uint32_t nonce = bufbe32toh (buf + offset + payloadLen); if (m_IsSendAccepted) SendMessageStatusMessage (nonce, eI2CPMessageStatusAccepted); // accepted m_Destination->SendMsgTo (buf + offset, payloadLen, identity.GetIdentHash (), nonce); } else LogPrint(eLogError, "I2CP: cannot send message, too big"); } else LogPrint(eLogError, "I2CP: invalid identity"); } } else LogPrint (eLogError, "I2CP: unexpected sessionID ", sessionID); } void I2CPSession::SendMessageExpiresMessageHandler (const uint8_t * buf, size_t len) { SendMessageMessageHandler (buf, len - 8); // ignore flags(2) and expiration(6) } void I2CPSession::HostLookupMessageHandler (const uint8_t * buf, size_t len) { uint16_t sessionID = bufbe16toh (buf); if (sessionID == m_SessionID || sessionID == 0xFFFF) // -1 means without session { uint32_t requestID = bufbe32toh (buf + 2); //uint32_t timeout = bufbe32toh (buf + 6); i2p::data::IdentHash ident; switch (buf[10]) { case 0: // hash ident = i2p::data::IdentHash (buf + 11); break; case 1: // address { auto name = ExtractString (buf + 11, len - 11); auto addr = i2p::client::context.GetAddressBook ().GetAddress (name); if (!addr || !addr->IsIdentHash ()) { // TODO: handle blinded addresses LogPrint (eLogError, "I2CP: address ", name, " not found"); SendHostReplyMessage (requestID, nullptr); return; } else ident = addr->identHash; break; } default: LogPrint (eLogError, "I2CP: request type ", (int)buf[10], " is not supported"); SendHostReplyMessage (requestID, nullptr); return; } std::shared_ptr destination = m_Destination; if(!destination) destination = i2p::client::context.GetSharedLocalDestination (); if (destination) { auto ls = destination->FindLeaseSet (ident); if (ls) SendHostReplyMessage (requestID, ls->GetIdentity ()); else { auto s = shared_from_this (); destination->RequestDestination (ident, [s, requestID](std::shared_ptr leaseSet) { s->SendHostReplyMessage (requestID, leaseSet ? leaseSet->GetIdentity () : nullptr); }); } } else SendHostReplyMessage (requestID, nullptr); } else LogPrint (eLogError, "I2CP: unexpected sessionID ", sessionID); } void I2CPSession::SendHostReplyMessage (uint32_t requestID, std::shared_ptr identity) { if (identity) { size_t l = identity->GetFullLen () + 7; uint8_t * buf = new uint8_t[l]; htobe16buf (buf, m_SessionID); htobe32buf (buf + 2, requestID); buf[6] = 0; // result code identity->ToBuffer (buf + 7, l - 7); SendI2CPMessage (I2CP_HOST_REPLY_MESSAGE, buf, l); delete[] buf; } else { uint8_t buf[7]; htobe16buf (buf, m_SessionID); htobe32buf (buf + 2, requestID); buf[6] = 1; // result code SendI2CPMessage (I2CP_HOST_REPLY_MESSAGE, buf, 7); } } void I2CPSession::DestLookupMessageHandler (const uint8_t * buf, size_t len) { if (m_Destination) { auto ls = m_Destination->FindLeaseSet (buf); if (ls) { auto l = ls->GetIdentity ()->GetFullLen (); uint8_t * identBuf = new uint8_t[l]; ls->GetIdentity ()->ToBuffer (identBuf, l); SendI2CPMessage (I2CP_DEST_REPLY_MESSAGE, identBuf, l); delete[] identBuf; } else { auto s = shared_from_this (); i2p::data::IdentHash ident (buf); m_Destination->RequestDestination (ident, [s, ident](std::shared_ptr leaseSet) { if (leaseSet) // found { auto l = leaseSet->GetIdentity ()->GetFullLen (); uint8_t * identBuf = new uint8_t[l]; leaseSet->GetIdentity ()->ToBuffer (identBuf, l); s->SendI2CPMessage (I2CP_DEST_REPLY_MESSAGE, identBuf, l); delete[] identBuf; } else s->SendI2CPMessage (I2CP_DEST_REPLY_MESSAGE, ident, 32); // not found }); } } else SendI2CPMessage (I2CP_DEST_REPLY_MESSAGE, buf, 32); } void I2CPSession::GetBandwidthLimitsMessageHandler (const uint8_t * buf, size_t len) { uint8_t limits[64]; memset (limits, 0, 64); htobe32buf (limits, i2p::transport::transports.GetInBandwidth ()); // inbound htobe32buf (limits + 4, i2p::transport::transports.GetOutBandwidth ()); // outbound SendI2CPMessage (I2CP_BANDWIDTH_LIMITS_MESSAGE, limits, 64); } void I2CPSession::SendMessagePayloadMessage (const uint8_t * payload, size_t len) { // we don't use SendI2CPMessage to eliminate additional copy auto l = len + 10 + I2CP_HEADER_SIZE; if (l > I2CP_MAX_MESSAGE_LENGTH) { LogPrint (eLogError, "I2CP: Message to send is too long ", l); return; } uint8_t * buf = m_IsSending ? new uint8_t[l] : m_SendBuffer; htobe32buf (buf + I2CP_HEADER_LENGTH_OFFSET, len + 10); buf[I2CP_HEADER_TYPE_OFFSET] = I2CP_MESSAGE_PAYLOAD_MESSAGE; htobe16buf (buf + I2CP_HEADER_SIZE, m_SessionID); htobe32buf (buf + I2CP_HEADER_SIZE + 2, m_MessageID++); htobe32buf (buf + I2CP_HEADER_SIZE + 6, len); memcpy (buf + I2CP_HEADER_SIZE + 10, payload, len); SendBuffer (buf, l); } I2CPServer::I2CPServer (const std::string& interface, int port, bool isSingleThread): RunnableService ("I2CP"), m_IsSingleThread (isSingleThread), m_Acceptor (GetIOService (), #ifdef ANDROID I2CPSession::proto::endpoint(std::string (1, '\0') + interface)) // leading 0 for abstract address #else I2CPSession::proto::endpoint(boost::asio::ip::address::from_string(interface), port)) #endif { memset (m_MessagesHandlers, 0, sizeof (m_MessagesHandlers)); m_MessagesHandlers[I2CP_GET_DATE_MESSAGE] = &I2CPSession::GetDateMessageHandler; m_MessagesHandlers[I2CP_CREATE_SESSION_MESSAGE] = &I2CPSession::CreateSessionMessageHandler; m_MessagesHandlers[I2CP_DESTROY_SESSION_MESSAGE] = &I2CPSession::DestroySessionMessageHandler; m_MessagesHandlers[I2CP_RECONFIGURE_SESSION_MESSAGE] = &I2CPSession::ReconfigureSessionMessageHandler; m_MessagesHandlers[I2CP_CREATE_LEASESET_MESSAGE] = &I2CPSession::CreateLeaseSetMessageHandler; m_MessagesHandlers[I2CP_CREATE_LEASESET2_MESSAGE] = &I2CPSession::CreateLeaseSet2MessageHandler; m_MessagesHandlers[I2CP_SEND_MESSAGE_MESSAGE] = &I2CPSession::SendMessageMessageHandler; m_MessagesHandlers[I2CP_SEND_MESSAGE_EXPIRES_MESSAGE] = &I2CPSession::SendMessageExpiresMessageHandler; m_MessagesHandlers[I2CP_HOST_LOOKUP_MESSAGE] = &I2CPSession::HostLookupMessageHandler; m_MessagesHandlers[I2CP_DEST_LOOKUP_MESSAGE] = &I2CPSession::DestLookupMessageHandler; m_MessagesHandlers[I2CP_GET_BANDWIDTH_LIMITS_MESSAGE] = &I2CPSession::GetBandwidthLimitsMessageHandler; } I2CPServer::~I2CPServer () { if (IsRunning ()) Stop (); } void I2CPServer::Start () { Accept (); StartIOService (); } void I2CPServer::Stop () { m_Acceptor.cancel (); { auto sessions = m_Sessions; for (auto& it: sessions) it.second->Stop (); } m_Sessions.clear (); StopIOService (); } void I2CPServer::Accept () { auto newSocket = std::make_shared (GetIOService ()); m_Acceptor.async_accept (*newSocket, std::bind (&I2CPServer::HandleAccept, this, std::placeholders::_1, newSocket)); } void I2CPServer::HandleAccept(const boost::system::error_code& ecode, std::shared_ptr socket) { if (!ecode && socket) { boost::system::error_code ec; auto ep = socket->remote_endpoint (ec); if (!ec) { LogPrint (eLogDebug, "I2CP: new connection from ", ep); auto session = std::make_shared(*this, socket); session->Start (); } else LogPrint (eLogError, "I2CP: incoming connection error ", ec.message ()); } else LogPrint (eLogError, "I2CP: accept error: ", ecode.message ()); if (ecode != boost::asio::error::operation_aborted) Accept (); } bool I2CPServer::InsertSession (std::shared_ptr session) { if (!session) return false; if (!m_Sessions.insert({session->GetSessionID (), session}).second) { LogPrint (eLogError, "I2CP: duplicate session id ", session->GetSessionID ()); return false; } return true; } void I2CPServer::RemoveSession (uint16_t sessionID) { m_Sessions.erase (sessionID); } } }