/// <returns>null if registration failed with timeout or some error code</returns> public async Task <ConnectionToNeighbor> RegisterAsync(LocalDrpPeer localDrpPeer, IPEndPoint epEndpoint, uint minimalDistanceToNeighbor, byte numberofHops, double[] directionVectorNullable, bool allowConnectionsToRequesterRegistrationId) // engine thread { var regSW = Stopwatch.StartNew(); WriteToLog_reg_requesterSide_higherLevelDetail($"connecting via EntryPeer {epEndpoint}", null, null); localDrpPeer.CurrentRegistrationOperationsCount++; try { #region PoW1 RegisterPow1ResponsePacket pow1ResponsePacket = null; if (!Configuration.SandboxModeOnly_DisablePoW) { WriteToLog_reg_requesterSide_detail($"generating PoW1 request", null, null); var pow1SW = Stopwatch.StartNew(); await PowThreadQueue.EnqueueAsync("pow1 6318"); WriteToLog_reg_requesterSide_detail($"generating PoW1 request @pow thread", null, null); var registerPow1RequestPacket = GenerateRegisterPow1RequestPacket(localDrpPeer.PublicIpApiProviderResponse.GetAddressBytes(), Timestamp32S); await EngineThreadQueue.EnqueueAsync("pow1 234709"); WriteToLog_reg_requesterSide_detail($"generated PoW1 request @engine thread", null, null); // send register pow1 request if (pow1SW.Elapsed.TotalMilliseconds > 3000) { WriteToLog_reg_requesterSide_lightPain($"PoW1 took {(int)pow1SW.Elapsed.TotalMilliseconds}ms", null, null); } WriteToLog_reg_requesterSide_detail($"PoW1 took {(int)pow1SW.Elapsed.TotalMilliseconds}ms. sending PoW1 request", null, null); var rpPow1ResponsePacketData = await SendUdpRequestAsync_Retransmit( new PendingLowLevelUdpRequest("rpPow1 469", epEndpoint, RegisterPow1ResponsePacket.GetScanner(registerPow1RequestPacket.Pow1RequestId), DateTimeNowUtc, Configuration.UdpLowLevelRequests_ExpirationTimeoutS, registerPow1RequestPacket.Encode(), Configuration.UdpLowLevelRequests_InitialRetransmissionTimeoutS, Configuration.UdpLowLevelRequests_RetransmissionTimeoutIncrement )); // wait for response, retransmit if (rpPow1ResponsePacketData == null) { throw new DrpTimeoutException($"pow1 request to EP '{epEndpoint}' (timeout={Configuration.UdpLowLevelRequests_ExpirationTimeoutS}s)"); } ; pow1ResponsePacket = new RegisterPow1ResponsePacket(rpPow1ResponsePacketData); WriteToLog_reg_requesterSide_detail($"got PoW1 response with status={pow1ResponsePacket.StatusCode}", null, null); if (pow1ResponsePacket.StatusCode != RegisterPow1ResponseStatusCode.succeeded_Pow2Challenge) { throw new Pow1RejectedException(pow1ResponsePacket.StatusCode); } } #endregion var newConnectionToNeighbor = new ConnectionToNeighbor(this, localDrpPeer, ConnectedDrpPeerInitiatedBy.localPeer, null); PongPacket pong; var req = new RegisterRequestPacket { RequesterRegistrationId = localDrpPeer.Configuration.LocalPeerRegistrationId, ReqTimestamp64 = Timestamp64, MinimalDistanceToNeighbor = minimalDistanceToNeighbor, RequesterNatBehaviour = LocalNatBehaviour, AllowConnectionsToRequesterRegistrationId = allowConnectionsToRequesterRegistrationId, NumberOfHopsRemaining = numberofHops, RequesterEcdhePublicKey = new EcdhPublicKey(newConnectionToNeighbor.LocalEcdhe25519PublicKey), ReqP2pSeq16 = GetNewNpaSeq16_AtoEP(), EpEndpoint = epEndpoint, DirectionVectorNullableD = directionVectorNullable }; var logger = new Logger(this, localDrpPeer, req, VisionChannelModuleName_reg_requesterSide); try { #region register REQ PoW2 RecentUniquePublicEcdhKeys.AssertIsUnique(req.RequesterEcdhePublicKey.Ecdh25519PublicKey, $"req.RequesterEcdhePublicKey {req}"); // this is used in non-standard way when routing registration requests to same (local) reg. ID, too var pow2SW = Stopwatch.StartNew(); if (!Configuration.SandboxModeOnly_DisablePoW) { await PowThreadQueue.EnqueueAsync("pow2 23465"); if (logger.WriteToLog_detail_enabled) { logger.WriteToLog_detail($"calculating PoW2 @pow thread"); } GenerateRegisterReqPow2(req, pow1ResponsePacket.ProofOfWork2Request); await EngineThreadQueue.EnqueueAsync("pow2 2496"); if (logger.WriteToLog_detail_enabled) { logger.WriteToLog_detail($"calculated PoW2 @engine thread"); } } else { req.ProofOfWork2 = new byte[64]; } pow2SW.Stop(); if (pow2SW.Elapsed.TotalMilliseconds > 3000) { logger.WriteToLog_lightPain($"PoW2 took {(int)pow2SW.Elapsed.TotalMilliseconds}ms"); } req.RequesterSignature = RegistrationSignature.Sign(_cryptoLibrary, w => req.GetSharedSignedFields(w, false), localDrpPeer.Configuration.LocalPeerRegistrationPrivateKey ); var reqToAck1Stopwatch = Stopwatch.StartNew(); if (logger.WriteToLog_detail_enabled) { logger.WriteToLog_detail($"PoW2 took {(int)pow2SW.Elapsed.TotalMilliseconds}ms. sending REQ, waiting for NPACK. ReqP2pSeq16={req.ReqP2pSeq16}"); } #endregion // var reqSW = Stopwatch.StartNew(); #region wait for ACK1 var sentRequest = new SentRequest(this, logger, epEndpoint, null, req.Encode_OptionallySignNeighborHMAC(null), req.ReqP2pSeq16, RegisterAck1Packet.GetScanner(logger, req)); var ack1UdpData = await sentRequest.SendRequestAsync("reg req ack1 367097"); var ack1 = RegisterAck1Packet.DecodeAndOptionallyVerify(logger, ack1UdpData, req, newConnectionToNeighbor); if (logger.WriteToLog_detail_enabled) { logger.WriteToLog_detail($"verified ACK1. RequesterEndpoint={ack1.RequesterEndpoint}"); } #endregion // check if it matches to previously known local public IP if (ack1.RequesterEndpoint.Address.Equals(localDrpPeer.PublicIpApiProviderResponse) == false) { // MITM attack / EP sent local (requester) endpoint IP some bad IP address throw new PossibleAttackException(); } RecentUniquePublicEcdhKeys.AssertIsUnique(ack1.ResponderEcdhePublicKey.Ecdh25519PublicKey, $"ack1.ResponderEcdhePublicKey from {epEndpoint}"); newConnectionToNeighbor.LocalEndpoint = ack1.RequesterEndpoint; newConnectionToNeighbor.RemoteRegistrationId = ack1.ResponderRegistrationId; reqToAck1Stopwatch.Stop(); var reqToAck1TimeMs = reqToAck1Stopwatch.Elapsed.TotalMilliseconds; if (logger.WriteToLog_detail_enabled) { logger.WriteToLog_detail($"measured REQ-ACK1_RTT={(int)reqToAck1TimeMs}ms"); } #region send ACK2, encode local IP var ack2 = new RegisterAck2Packet { ReqTimestamp64 = req.ReqTimestamp64, RequesterRegistrationId = localDrpPeer.Configuration.LocalPeerRegistrationId, ReqP2pSeq16 = GetNewNpaSeq16_AtoEP() }; ack2.ToRequesterTxParametersEncrypted = newConnectionToNeighbor.Encrypt_ack2_ToRequesterTxParametersEncrypted_AtRequester(logger, req, ack1, ack2); newConnectionToNeighbor.InitializeP2pStream(req, ack1, ack2); ack2.RequesterSignature = RegistrationSignature.Sign(_cryptoLibrary, w => { req.GetSharedSignedFields(w, true); ack1.GetSharedSignedFields(w, true, true); ack2.GetSharedSignedFields(w, false, true); }, localDrpPeer.Configuration.LocalPeerRegistrationPrivateKey ); if (logger.WriteToLog_detail_enabled) { logger.WriteToLog_detail($"sending ACK2 (in response to ACK1), waiting for NPACK"); } RespondToRequestAndRetransmissions(ack1UdpData, ack2.Encode_OptionallySignNeighborHMAC(null), epEndpoint); await OptionallySendUdpRequestAsync_Retransmit_WaitForNeighborPeerAck("ack2 46873", null, epEndpoint, ack2.ReqP2pSeq16); #endregion var neighborWaitTimeMs = reqToAck1TimeMs * 0.5 - 250; if (neighborWaitTimeMs < 0) { neighborWaitTimeMs = 0; } if (neighborWaitTimeMs > 20) { if (logger.WriteToLog_detail_enabled) { logger.WriteToLog_detail($"awaiting {(int)neighborWaitTimeMs}ms before PING..."); } await EngineThreadQueue.WaitAsync(TimeSpan.FromMilliseconds(neighborWaitTimeMs), "before PING 34589"); // wait until the ACK2 reaches neighbor N via peers if (logger.WriteToLog_detail_enabled) { logger.WriteToLog_detail($"... awaiting is complete"); } } localDrpPeer.AddToConnectedNeighbors(newConnectionToNeighbor, req); #region send ping request directly to neighbor N, retransmit var pingRequest = newConnectionToNeighbor.CreatePing(true, false, localDrpPeer.ConnectedNeighborsBusySectorIds, localDrpPeer.AnotherNeighborToSameSectorExists(newConnectionToNeighbor)); newConnectionToNeighbor.InitialPendingPingRequest = new PendingLowLevelUdpRequest("pingRequest 3850", newConnectionToNeighbor.RemoteEndpoint, PongPacket.GetScanner(newConnectionToNeighbor.LocalNeighborToken32, pingRequest.PingRequestId32), DateTimeNowUtc, Configuration.InitialPingRequests_ExpirationTimeoutS, pingRequest.Encode(), Configuration.InitialPingRequests_InitialRetransmissionTimeoutS, Configuration.InitialPingRequests_RetransmissionTimeoutIncrement ); if (logger.WriteToLog_detail_enabled) { logger.WriteToLog_detail($"sending PING neighborToken32={pingRequest.NeighborToken32}, waiting for PONG"); } var pongPacketData = await SendUdpRequestAsync_Retransmit(newConnectionToNeighbor.InitialPendingPingRequest); if (pongPacketData == null) { throw new DrpTimeoutException($"initial reg. requester PING to {newConnectionToNeighbor} (timeout={Configuration.InitialPingRequests_ExpirationTimeoutS}s)"); } if (newConnectionToNeighbor.IsDisposed) { throw new ObjectDisposedException($"initial reg. requester PING to {newConnectionToNeighbor} (special case: connection is disposed)", (Exception)null); // ping timeout already destroyed the connection, so PONG response here is too late } pong = PongPacket.DecodeAndVerify(_cryptoLibrary, pongPacketData, pingRequest, newConnectionToNeighbor, true); if (logger.WriteToLog_detail_enabled) { logger.WriteToLog_detail($"verified PONG"); } newConnectionToNeighbor.OnReceivedVerifiedPong(pong, newConnectionToNeighbor.InitialPendingPingRequest.ResponseReceivedAtUtc.Value, newConnectionToNeighbor.InitialPendingPingRequest.ResponseReceivedAtUtc.Value - newConnectionToNeighbor.InitialPendingPingRequest.InitialTxTimeUTC.Value); #endregion } catch { // todo update QoS newConnectionToNeighbor.Dispose(); // remove from token32 table throw; } #region send registration confirmation packet to EP->X->N try { var cfm = new RegisterConfirmationPacket { ReqTimestamp64 = req.ReqTimestamp64, RequesterRegistrationId = localDrpPeer.Configuration.LocalPeerRegistrationId, ResponderRegistrationConfirmationSignature = pong.ResponderRegistrationConfirmationSignature, ReqP2pSeq16 = GetNewNpaSeq16_AtoEP() }; cfm.RequesterRegistrationConfirmationSignature = RegistrationSignature.Sign(_cryptoLibrary, w => newConnectionToNeighbor.GetRequesterRegistrationConfirmationSignatureFields(w, cfm.ResponderRegistrationConfirmationSignature), localDrpPeer.Configuration.LocalPeerRegistrationPrivateKey); if (logger.WriteToLog_detail_enabled) { logger.WriteToLog_detail($"sending CFM, waiting for NPACK"); } await OptionallySendUdpRequestAsync_Retransmit_WaitForNeighborPeerAck("cfm 32107", cfm.Encode_OptionallySignNeighborHMAC(null), epEndpoint, cfm.ReqP2pSeq16); if (logger.WriteToLog_detail_enabled) { logger.WriteToLog_detail($"received NPACK to CFM"); } } catch (DrpTimeoutException exc) { // we ingnore exceptions here, just wite warning to log. the connection is alive already, as direct ping channel to neighbor is set up logger.WriteToLog_needsAttention($"... registration confirmation request failed: {exc}"); } catch (Exception exc) { // we ingnore exceptions here, just wite warning to log. the connection is alive already, as direct ping channel to neighbor is set up logger.WriteToLog_mediumPain($"... registration confirmation request failed: {exc}"); } #endregion regSW.Stop(); if (regSW.Elapsed.TotalMilliseconds > 5000) { logger.WriteToLog_lightPain($"registration is completed in {(int)regSW.Elapsed.TotalMilliseconds}ms"); } else { logger.WriteToLog_higherLevelDetail($"registration is completed in {(int)regSW.Elapsed.TotalMilliseconds}ms"); }; return(newConnectionToNeighbor); } finally { localDrpPeer.CurrentRegistrationOperationsCount--; } }
/// <summary> /// main register responder proc for both A-EP and P2P modes /// in P2P mode Timestamp32S, NeighborToken32 and NeighborHMAC are verified at this time /// </summary> /// <param name="receivedFromInP2pMode"> /// is null in A-EP mode /// </param> internal async Task AcceptRegisterRequestAsync(LocalDrpPeer acceptAt, RoutedRequest routedRequest) // engine thread { var logger = routedRequest.Logger; logger.ModuleName = VisionChannelModuleName_reg_responderSide; var req = routedRequest.RegisterReq; if (req.RequesterRegistrationId.Equals(acceptAt.Configuration.LocalPeerRegistrationId)) { throw new InvalidOperationException(); } // check signature of requester (A) if (!req.RequesterSignature.Verify(_cryptoLibrary, w => req.GetSharedSignedFields(w, false), req.RequesterRegistrationId ) ) { throw new BadSignatureException("invalid REGISTER REQ RequesterSignature 2396"); } if (routedRequest.ReceivedFromNeighborNullable == null) { // A-EP mode if (req.EpEndpoint.Address.Equals(acceptAt.PublicIpApiProviderResponse) == false) { throw new PossibleAttackException(); } } if (PendingRegisterRequestExists(req.RequesterRegistrationId)) { // received duplicate REGISTER REQ packet logger.WriteToLog_needsAttention($"ignoring duplicate registration request {req.RequesterRegistrationId} from {routedRequest.ReceivedFromEndpoint}"); return; } if (!RecentUniqueAcceptedRegistrationRequests.Filter(req.GetUniqueRequestIdFields)) { logger.WriteToLog_needsAttention($"ignoring registration request {req.RequesterRegistrationId} ts={req.ReqTimestamp64} from {routedRequest.ReceivedFromEndpoint} with non-unique request ID fields"); return; } logger.WriteToLog_higherLevelDetail($"accepting registration from {routedRequest.ReceivedFromEndpoint}: ReqP2pSeq16={req.ReqP2pSeq16}, NumberOfHopsRemaining={req.NumberOfHopsRemaining}, epEndpoint={req.EpEndpoint}, sourcePeer={routedRequest.ReceivedFromNeighborNullable}, ts={req.ReqTimestamp64}"); if (!RecentUniquePublicEcdhKeys.Filter(req.RequesterEcdhePublicKey.Ecdh25519PublicKey)) { logger.WriteToLog_needsAttention($"ignoring registration request {req.RequesterRegistrationId} from {routedRequest.ReceivedFromEndpoint} with non-unique RequesterEcdhePublicKey"); return; } _pendingRegisterRequests.Add(req.RequesterRegistrationId); try { if (logger.WriteToLog_detail_enabled) { logger.WriteToLog_detail($"sending NPACK to REQ to {routedRequest.ReceivedFromEndpoint} (delay={routedRequest.ReqReceivedSw_ms}ms)"); } routedRequest.SendNeighborPeerAck_accepted_IfNotAlreadyReplied(); var newConnectionToNeighbor = new ConnectionToNeighbor(this, acceptAt, ConnectedDrpPeerInitiatedBy.remotePeer, req.RequesterRegistrationId) { LocalEndpoint = routedRequest.ReceivedFromNeighborNullable?.LocalEndpoint ?? req.EpEndpoint, }; byte[] ack1UdpData; try { var ack1 = new RegisterAck1Packet { RequesterRegistrationId = req.RequesterRegistrationId, ReqTimestamp64 = req.ReqTimestamp64, ResponderEcdhePublicKey = new EcdhPublicKey(newConnectionToNeighbor.LocalEcdhe25519PublicKey), ResponderRegistrationId = acceptAt.Configuration.LocalPeerRegistrationId, ReqP2pSeq16 = GetNewNpaSeq16_AtoEP(), }; RecentUniquePublicEcdhKeys.AssertIsUnique(ack1.ResponderEcdhePublicKey.Ecdh25519PublicKey, $"ack1.ResponderEcdhePublicKey"); ack1.ToResponderTxParametersEncrypted = newConnectionToNeighbor.Encrypt_ack1_ToResponderTxParametersEncrypted_AtResponder_DeriveSharedDhSecret(logger, req, ack1, routedRequest.ReceivedFromNeighborNullable); ack1.ResponderSignature = RegistrationSignature.Sign(_cryptoLibrary, (w2) => { req.GetSharedSignedFields(w2, true); ack1.GetSharedSignedFields(w2, false, true); }, acceptAt.Configuration.LocalPeerRegistrationPrivateKey); if (routedRequest.ReceivedFromNeighborNullable == null) { ack1.RequesterEndpoint = routedRequest.ReceivedFromEndpoint; } ack1UdpData = ack1.Encode_OpionallySignNeighborHMAC(routedRequest.ReceivedFromNeighborNullable); var ack2Scanner = RegisterAck2Packet.GetScanner(logger, routedRequest.ReceivedFromNeighborNullable, req); var requesterVisibleDescription = routedRequest.ReceivedFromNeighborNullable?.ToString() ?? routedRequest.ReceivedFromEndpoint.ToString(); byte[] ack2UdpData; if (routedRequest.ReceivedFromNeighborNullable == null) { // wait for ACK2, retransmitting ACK1 if (logger.WriteToLog_detail_enabled) { logger.WriteToLog_detail($"sending ACK1, waiting for ACK2"); } ack2UdpData = await OptionallySendUdpRequestAsync_Retransmit_WaitForResponse("ack2 33469", requesterVisibleDescription, ack1UdpData, routedRequest.ReceivedFromEndpoint, ack2Scanner); } else { // retransmit ACK1 until NPACK (via P2P); at same time wait for ACK if (logger.WriteToLog_detail_enabled) { logger.WriteToLog_detail($"sending ACK1, awaiting for NPACK"); } _ = OptionallySendUdpRequestAsync_Retransmit_WaitForNeighborPeerAck("ack1 423087", ack1UdpData, routedRequest.ReceivedFromEndpoint, ack1.ReqP2pSeq16, routedRequest.ReceivedFromNeighborNullable, ack1.GetSignedFieldsForNeighborHMAC); // not waiting for NPACK, wait for ACK if (logger.WriteToLog_detail_enabled) { logger.WriteToLog_detail($"waiting for ACK2"); } ack2UdpData = await OptionallySendUdpRequestAsync_Retransmit_WaitForResponse("ack2 46051", requesterVisibleDescription, null, routedRequest.ReceivedFromEndpoint, ack2Scanner); } if (logger.WriteToLog_detail_enabled) { logger.WriteToLog_detail($"received ACK2"); } var ack2 = RegisterAck2Packet.Decode_OptionallyVerify_InitializeP2pStreamAtResponder(logger, ack2UdpData, req, ack1, newConnectionToNeighbor); if (logger.WriteToLog_detail_enabled) { logger.WriteToLog_detail($"verified ACK2"); } acceptAt.AddToConnectedNeighbors(newConnectionToNeighbor, req); // added to list here in order to respond to ping requests from A SendNeighborPeerAckResponseToRegisterAck2(ack2, routedRequest.ReceivedFromEndpoint, routedRequest.ReceivedFromNeighborNullable); // send NPACK to ACK _ = WaitForRegistrationConfirmationRequestAsync(requesterVisibleDescription, logger, routedRequest.ReceivedFromEndpoint, req, newConnectionToNeighbor, routedRequest.ReceivedFromNeighborNullable); #region send ping, verify pong var ping = newConnectionToNeighbor.CreatePing(true, false, acceptAt.ConnectedNeighborsBusySectorIds, acceptAt.AnotherNeighborToSameSectorExists(newConnectionToNeighbor)); var pendingPingRequest = new PendingLowLevelUdpRequest("pendingPingRequest 693", newConnectionToNeighbor.RemoteEndpoint, PongPacket.GetScanner(newConnectionToNeighbor.LocalNeighborToken32, ping.PingRequestId32), DateTimeNowUtc, Configuration.InitialPingRequests_ExpirationTimeoutS, ping.Encode(), Configuration.InitialPingRequests_InitialRetransmissionTimeoutS, Configuration.InitialPingRequests_RetransmissionTimeoutIncrement ); if (logger.WriteToLog_detail_enabled) { logger.WriteToLog_detail($"sent PING"); } var pongPacketData = await SendUdpRequestAsync_Retransmit(pendingPingRequest); // wait for pong from A if (pongPacketData == null) { throw new DrpTimeoutException($"reg. responder initial PING request to {newConnectionToNeighbor} (timeout={Configuration.InitialPingRequests_ExpirationTimeoutS}s)"); } var pong = PongPacket.DecodeAndVerify(_cryptoLibrary, pongPacketData, ping, newConnectionToNeighbor, true); if (logger.WriteToLog_detail_enabled) { logger.WriteToLog_detail($"verified PONG"); } newConnectionToNeighbor.OnReceivedVerifiedPong(pong, pendingPingRequest.ResponseReceivedAtUtc.Value, pendingPingRequest.ResponseReceivedAtUtc.Value - pendingPingRequest.InitialTxTimeUTC.Value); #endregion } catch (Exception exc) { newConnectionToNeighbor.Dispose(); throw exc; } } catch (DrpTimeoutException exc) { logger.WriteToLog_needsAttention($"could not accept REGISTER request: {exc}"); } catch (Exception exc) { logger.WriteToLog_mediumPain($"could not accept REGISTER request: {exc}"); } finally { _pendingRegisterRequests.Remove(req.RequesterRegistrationId); } }
void RouteRegistrationRequest_LocalDrpPeerIteration(LocalDrpPeer localDrpPeer, RoutedRequest routedRequest, ref double?maxP2pConnectionValue, ref ConnectionToNeighbor proxyToDestinationPeer, ref LocalDrpPeer acceptAt) { var req = routedRequest.RegisterReq; var connectedNeighborsForRouting = localDrpPeer.GetConnectedNeighborsForRouting(routedRequest).ToList(); var logger = routedRequest.Logger; var distancesToNeighbors = new List <RegistrationIdDistance>(); var requestedDirectionMulResults = new List <double>(); int connectedNeighborsCountThatMatchReqFilters = 0; foreach (var neighbor in connectedNeighborsForRouting) { if (req.MinimalDistanceToNeighbor != 0) { var distanceToNeighbor = req.RequesterRegistrationId.GetDistanceTo(_cryptoLibrary, neighbor.RemoteRegistrationId, NumberOfDimensions); distancesToNeighbors.Add(distanceToNeighbor); if (logger.WriteToLog_detail_enabled) { logger.WriteToLog_detail($"distanceToNeighbor={distanceToNeighbor} from REGISTER REQ {req.RequesterRegistrationId} to {neighbor} (req.min={req.MinimalDistanceToNeighbor})"); } if (distanceToNeighbor.IsLessThan(req.MinimalDistanceToNeighbor)) { // skip: this is too close than requested if (logger.WriteToLog_detail_enabled) { logger.WriteToLog_detail($"skipping connection to {neighbor}: distance={distanceToNeighbor} is less than requested={req.MinimalDistanceToNeighbor}"); } continue; } } if (req.DirectionVectorNullable != null) { var requestedDirectionVector = req.DirectionVectorNullableD; var vectorFromThisToNeighbor = RegistrationId.GetDifferenceVector(req.RequesterRegistrationId, neighbor.RemoteRegistrationId, CryptoLibrary, Configuration.SandboxModeOnly_NumberOfDimensions); double mulResult = 0; for (int i = 0; i < requestedDirectionVector.Length; i++) { mulResult += requestedDirectionVector[i] * requestedDirectionVector[i]; } requestedDirectionMulResults.Add(mulResult); if (mulResult < 0) { if (logger.WriteToLog_detail_enabled) { logger.WriteToLog_detail($"skipping connection to {neighbor}: direction from requester to neighbor does not match requested vector"); } continue; } } if (neighbor.RemoteRegistrationId.Equals(localDrpPeer.Configuration.LocalPeerRegistrationId)) { if (logger.WriteToLog_detail_enabled) { logger.WriteToLog_detail($"skipping connection to {neighbor}: same registration ID as local peer"); } continue; } connectedNeighborsCountThatMatchReqFilters++; var p2pConnectionValue_withNeighbor = P2pConnectionValueCalculator.GetMutualP2pConnectionValue(CryptoLibrary, req.RequesterRegistrationId, req.RequesterNeighborsBusySectorIds, neighbor.RemoteRegistrationId, neighbor.RemoteNeighborsBusySectorIds ?? 0, NumberOfDimensions, false, false, false, req.AllowConnectionsToRequesterRegistrationId); if (logger.WriteToLog_deepDetail_enabled) { logger.WriteToLog_deepDetail($"p2pConnectionValue_withNeighbor={p2pConnectionValue_withNeighbor} from REGISTER REQ {req.RequesterRegistrationId} to {neighbor}"); } if (maxP2pConnectionValue == null || maxP2pConnectionValue < p2pConnectionValue_withNeighbor) { maxP2pConnectionValue = p2pConnectionValue_withNeighbor; proxyToDestinationPeer = neighbor; acceptAt = null; } } if (connectedNeighborsCountThatMatchReqFilters == 0 && connectedNeighborsForRouting.Count != 0) { if (req.MinimalDistanceToNeighbor != 0) { // special case: we are inside the "minDistance" hypersphere: move away from the requester, proxy to most distant neighbor if (logger.WriteToLog_detail_enabled) { logger.WriteToLog_detail($"special case: move away from the requester, proxy to most distant neighbor"); } RegistrationIdDistance maxDistance = null; for (int i = 0; i < connectedNeighborsForRouting.Count; i++) { var neighbor = connectedNeighborsForRouting[i]; var distanceToNeighbor = distancesToNeighbors[i]; if (logger.WriteToLog_detail_enabled) { logger.WriteToLog_detail($"distanceToConnectedPeer={distanceToNeighbor} from REGISTER REQ {req.RequesterRegistrationId} to {neighbor} (req.min={req.MinimalDistanceToNeighbor})"); } if (maxDistance == null || distanceToNeighbor.IsGreaterThan(maxDistance)) { maxDistance = distanceToNeighbor; proxyToDestinationPeer = neighbor; acceptAt = null; } } } if (req.DirectionVectorNullable != null) { if (logger.WriteToLog_detail_enabled) { logger.WriteToLog_detail($"special case: move towards the specified direction"); } double?maxMulResult = null; for (int i = 0; i < connectedNeighborsForRouting.Count; i++) { var neighbor = connectedNeighborsForRouting[i]; var mulResult = requestedDirectionMulResults[i]; if (logger.WriteToLog_detail_enabled) { logger.WriteToLog_detail($"mulResult={mulResult} for {neighbor}"); } if (maxMulResult == null || mulResult > maxMulResult) { maxMulResult = mulResult; proxyToDestinationPeer = neighbor; acceptAt = null; } } } } if (RecentUniquePublicEcdhKeys.DataIsUnique(req.RequesterEcdhePublicKey.Ecdh25519PublicKey) == false) { if (logger.WriteToLog_detail_enabled) { logger.WriteToLog_detail($"not accepting request at local peer: it has ECDHE key that is recently locally generated"); } } else if (localDrpPeer.ConnectedNeighbors.Any(x => x.RemoteRegistrationId.Equals(req.RequesterRegistrationId)) == true) { if (logger.WriteToLog_detail_enabled) { logger.WriteToLog_detail($"not accepting request at local peer: already connected to {req.RequesterRegistrationId}"); } } else if (localDrpPeer.ConnectedNeighbors.Count > localDrpPeer.Configuration.AbsoluteMaxNumberOfNeighbors) { if (logger.WriteToLog_detail_enabled) { logger.WriteToLog_detail($"not accepting request at local peer: already too many neighbors ({localDrpPeer.ConnectedNeighbors.Count})"); } } else { var p2pConnectionValue_withLocalPeer = P2pConnectionValueCalculator.GetMutualP2pConnectionValue(CryptoLibrary, req.RequesterRegistrationId, req.RequesterNeighborsBusySectorIds, localDrpPeer.Configuration.LocalPeerRegistrationId, localDrpPeer.ConnectedNeighborsBusySectorIds, NumberOfDimensions, false, false, false, req.AllowConnectionsToRequesterRegistrationId); if (logger.WriteToLog_detail_enabled) { logger.WriteToLog_detail($"p2pConnectionValue_withLocalPeer={p2pConnectionValue_withLocalPeer} from REGISTER REQ {req.RequesterRegistrationId} to {localDrpPeer.Configuration.LocalPeerRegistrationId}"); } if (maxP2pConnectionValue == null || p2pConnectionValue_withLocalPeer > maxP2pConnectionValue) { maxP2pConnectionValue = p2pConnectionValue_withLocalPeer; proxyToDestinationPeer = null; acceptAt = localDrpPeer; } } if (logger.WriteToLog_detail_enabled) { logger.WriteToLog_detail($"<< RouteRegistrationRequest_LocalDrpPeerIteration() proxyTo={proxyToDestinationPeer}, acceptAt={acceptAt}"); } }