====== SSU2 ====== .. meta:: :author: orignal, zlatinb, zzz :created: 2021-09-12 :thread: http://zzz.i2p/topics/2612 :lastupdated: 2021-10-14 :status: Open :target: 0.9.55 .. contents:: Overview ======== This proposal describes an authenticated key agreement protocol to improve the resistance of [SSU]_ to various forms of automated identification and attacks. The proposal is organized as follows: the security goals are presented, followed by a discussion of the basic protocol. Next, a complete specification of all protocol messages is given. Finally, router addresses and version identification are discussed. An appendix discussing a generic attack on common padding schemes is also included, as well as an appendix containing a number of candidates for the authenticated cipher. As with other I2P transports, SSU2 is defined solely for point-to-point (router-to-router) transport of I2NP messages. It is not a general-purpose data pipe. Motivation ========== SSU is the only remaining protocol layer that requires ElGamal, which is very slow. The flow control for SSU is complex and does not work well. Portions of SSU are vulnerable to address spoofing attacks. The handshake does not use Noise. Design Goals ============ - Reduce CPU usage by eliminating ElGamal. Use X25519 for the DH. - Maintain the Peer Test and Relay functions, and increase security for them. - Make implementation easier by allowing for standard flow control algorithms. - Increase speed and reduce latency. Median setup time is currently about 135 ms for NTCP2 and 187 ms for SSU, even though NTCP2 has an additional round trip; replacing ElGamal in SSU2 should reduce it, but other changes may also help. - (maybe) Prevent traffic amplification attacks from spoofed source addresses via "address validation"? Is this necessary, or are there other ways that would not require an additional round trip? Does this conflict with the requirement to prevent traffic identification? See below. - Make packet identification easier, to reduce reliance on fallbacks and heuristics that make the code overly complex. - (maybe) Support SSU 1 and 2 on a single port, auto-detect, and published as a single "transport" (i.e. [RouterAddress]_) in the [NetDB]_. - Publish support for version 1 only, 2 only, or 1+2 in the NetDB in a separate field, and default to version 1 only (don't bind version support to a particular router version) - Ensure that all implementations (Java/i2pd/Go) can add version 2 support (or not) on their own schedules - Add random padding to all SSU messages including handshake and data messages. Provide options mechanism for both sides to request min and max padding and/or padding distribution. Specifics of the padding distribution are implementation-dependent and may or may not be specified in the protocol itself. - Obfuscate the contents of messages that aren't encrypted (Session Created and Confirmed), sufficiently so that DPI boxes and AV signatures can't easily classify them. Also ensure that the messages going to a single peer or set of peers do not have a similar pattern of bits. - Fix loss of bits in DH due to Java format [Ticket1112]_, possibly (probably?) by switching to X25519. - Switch to a real key derivation function (KDF) rather than using the DH result as-is - Add "probing resistance" (as Tor calls it); this includes replay resistance. - Maintain 2-way authenticated key exchange (2W-AKE). 1W-AKE is not sufficient for our application. - Continue to use the variable-type, variable-length signatures (from the published [RouterIdentity]_ signing key) as a part of authentication. Rely on a static public key published in the RouterInfo as another part of authentication. - Add options/version in handshake for future extensibility. - Add resistance to malicious MitM TCP segmentation if possible. - Don't add significantly to CPU required for connection setup; if possible, reduce it significantly. - Add message authentication (MAC) using ChaCha/Poly1305. - Use a 3-message, one-round-trip handshake, as in [SSU]_. - Minimize protocol overhead before padding. While padding will be added, overhead before padding is still overhead. Low-bandwidth nodes must be able to use SSU2. - All padding must be covered by the MAC, unlike the end-of-packet padding in SSU. - Maintain timestamps for replay and skew detection. - Avoid any year 2038 issues in timestamps, must work until at least 2106. - Maintain a max I2NP message size of approximately 32K, as in SSU. Increase to 64 KB? TBD - Include representatives of Java, C++, and Go router developers in the design. Non-Goals --------- - Bullet-proof DPI resistance... that would be pluggable transports, [Prop109]_. - A TLS-based (or HTTPS-lookalike) transport... that would be [Prop104]_. - It's OK to change the symmetric stream cryptography. - Timing-based DPI resistance (inter-message timing/delays can be implementation-dependent; intra-message delays can be introduced at any point, including before sending the random padding, for example). Artificial delays (what obfs4 calls IAT or inter-arrival time) are independent of the protocol itself. - Deniability of participating in a session (there's signatures in there). Non-goals that may be partially reconsidered or discussed: - The degree of protection against Deep Packet Inspection (DPI) - Post-Quantum (PQ) security - Deniability Security Goals ============== We consider three parties: - Alice, who wishes to establish a new session. - Bob, with whom Alice wishes to establish a session. - Mallory, the "man in the middle" between Alice and Bob. At most two participants can engage in active attacks. Alice and Bob are both in possession of a static key pair, which is contained in their [RouterIdentity]_. The proposed protocol attempts to allow Alice and Bob to agree on a shared secret key (K) under the following requirements: 1) Private key security: neither Bob nor Mallory learns anything about Alice's static private key. Symmetrically, Alice does not learn anything about Bob's static private key. 2) The session key K is only known by Alice and Bob. 3) Perfect forward secrecy: the agreed upon session key remains secret in the future, even when the static private keys of Alice and/or Bob are revealed after the key has been agreed upon. 4) Two-way authentication: Alice is certain that she has established a session with Bob, and vice versa. 5) Protection against online DPI: Ensure that it is not trivial to detect that Alice and Bob are engaged in the protocol using only straightforward deep packet inspection (DPI) techniques. See below. 6) Limited deniability: neither Alice nor Bob can deny participation in the protocol, but if either leaks the shared key the other party can deny the authenticity of the contents of the transmitted data. The present proposal attempts to provide all five requirements based on the Station-To-Station (STS) protocol [STS]_. Note that this protocol is also the basis for the [SSU]_ protocol. Additional DPI Discussion ------------------------- We assume two DPI components: 1) Online DPI ````````````` Online DPI inspecting all flows in real-time. Connections may be blocked or otherwise tampered with. Connection data or metadata may be identified and stored for offline analysis. The online DPI does not have access to the I2P network database. The online DPI has only limited real-time computational capability, including length calculation, field inspection, and simple calculations such as XOR. The online DPI does have the capability of fast real-time cryptographic functions such as AES, AEAD, and hashing, but these would be too expensive to apply to most or all flows. Any application of these cryptographic operations would apply only to flows on IP/Port combinations previously identified by offline analysis. The online DPI does not have the capability of high-overhead cryptographic functions such as DH or elligator2. The online DPI is not designed specifically to detect I2P, although it may have limited classification rules for that purpose. It is a goal to prevent protocol identification by an online DPI. The notion of online or "straightforward" DPI is here taken to include the following adversary capabilities: 1) The ability to inspect all data sent or received by the target. 2) The ability to perform operations on the observed data, such as applying block ciphers or hash functions. 3) The ability to store and compare with previously sent messages. 4) The ability to modify, delay or fragment packets. However, the online DPI is assumed to have the following restrictions: 5) The inability to map IP addresses to router hashes. While this is trivial with real-time access to the network database, it would require a DPI system specifically designed to target I2P. 6) The inability to use timing information to detect the protocol. 7) Generally speaking, the online DPI toolbox does not contain any built-in tools that are specifically designed for I2P detection. This includes creating "honeypots", which would for example include nonrandom padding in their messages. Note that this does not exclude machine learning systems or highly configurable DPI tools as long as they meet the other requirements. To counter payload analysis, it is ensured that all messages are indistinguishable from random. This also requires their length to be random, which is more complicated than just adding random padding. In fact, in Appendix A, the authors argue that a naive (i.e. uniform) padding scheme does not resolve the problem. Appendix A therefore proposes to include either random delays or to develop an alternate padding scheme that can provide reasonable protection for the proposed attack. To protect against the sixth entry above, implementations should include random delays in the protocol. Such techniques are not covered by this proposal, but they could also resolve the padding length issues. In summary, the proposal provides good protection against payload analysis (when the considerations in Appendix A are taken into account), but only limited protection against flow analysis. 2) Offline DPI `````````````` Offline DPI inspecting data stored by the online DPI for later analysis. The offline DPI may be designed specifically to detect I2P. The offline DPI does have real-time access to the I2P network database. The offline DPI does have access to this and other I2P specifications. The offline DPI has unlimited computational capability, including all cryptographic functions defined in this specification. The offline DPI does not have the ability to block existing connections. The offline DPI does have the capability to do near-realtime (within minutes of setup) sending to host/port of parties, for example TCP RST. The offline DPI does have the capability to do near-realtime (within minutes of setup) replay of previous messages (modified or not) for "probing" or other reasons. It is not a goal to prevent protocol identification by an offline DPI. All decoding of obfuscated data in the first two messages, which is implemented by I2P routers, may also be implemented by the offline DPI. It is a goal to reject attempted connections using replay of previous messages. Future work ``````````` TBD Address Validation --------------------------- Following is copied from QUIC [RFC-9000]_. Address validation ensures that an endpoint cannot be used for a traffic amplification attack. In such an attack, a packet is sent to a server with spoofed source address information that identifies a victim. If a server generates more or larger packets in response to that packet, the attacker can use the server to send more data toward the victim than it would be able to send on its own. The primary defense against amplification attacks is verifying that a peer is able to receive packets at the transport address that it claims. Therefore, after receiving packets from an address that is not yet validated, an endpoint MUST limit the amount of data it sends to the unvalidated address to three times the amount of data received from that address. This limit on the size of responses is known as the anti-amplification limit. Address validation is performed both during connection establishment (see Section 8.1) and during connection migration (see Section 8.2). Address Validation during Connection Establishment ``````````````````````````````````````````````````````` Connection establishment implicitly provides address validation for both endpoints. In particular, receipt of a packet protected with Handshake keys confirms that the peer successfully processed an Initial packet. Once an endpoint has successfully processed a Handshake packet from the peer, it can consider the peer address to have been validated. Additionally, an endpoint MAY consider the peer address validated if the peer uses a connection ID chosen by the endpoint and the connection ID contains at least 64 bits of entropy. For the client, the value of the Destination Connection ID field in its first Initial packet allows it to validate the server address as a part of successfully processing any packet. Initial packets from the server are protected with keys that are derived from this value (see Section 5.2 of [QUIC-TLS]). Alternatively, the value is echoed by the server in Version Negotiation packets (Section 6) or included in the Integrity Tag in Retry packets (Section 5.8 of [QUIC-TLS]). Prior to validating the client address, servers MUST NOT send more than three times as many bytes as the number of bytes they have received. This limits the magnitude of any amplification attack that can be mounted using spoofed source addresses. For the purposes of avoiding amplification prior to address validation, servers MUST count all of the payload bytes received in datagrams that are uniquely attributed to a single connection. This includes datagrams that contain packets that are successfully processed and datagrams that contain packets that are all discarded. Clients MUST ensure that UDP datagrams containing Initial packets have UDP payloads of at least 1200 bytes, adding PADDING frames as necessary. A client that sends padded datagrams allows the server to send more data prior to completing address validation. Loss of an Initial or Handshake packet from the server can cause a deadlock if the client does not send additional Initial or Handshake packets. A deadlock could occur when the server reaches its anti- amplification limit and the client has received acknowledgments for all the data it has sent. In this case, when the client has no reason to send additional packets, the server will be unable to send more data because it has not validated the client's address. To prevent this deadlock, clients MUST send a packet on a Probe Timeout (PTO); see Section 6.2 of [QUIC-RECOVERY]. Specifically, the client MUST send an Initial packet in a UDP datagram that contains at least 1200 bytes if it does not have Handshake keys, and otherwise send a Handshake packet. A server might wish to validate the client address before starting the cryptographic handshake. QUIC uses a token in the Initial packet to provide address validation prior to completing the handshake. This token is delivered to the client during connection establishment with a Retry packet (see Section 8.1.2) or in a previous connection using the NEW_TOKEN frame (see Section 8.1.3). In addition to sending limits imposed prior to address validation, servers are also constrained in what they can send by the limits set by the congestion controller. Clients are only constrained by the congestion controller. Token Construction ``````````````````````````````````````````````````````` A token sent in a NEW_TOKEN frame or a Retry packet MUST be constructed in a way that allows the server to identify how it was provided to a client. These tokens are carried in the same field but require different handling from servers. Address Validation Using Retry Packets ``````````````````````````````````````````````````````` Upon receiving the client's Initial packet, the server can request address validation by sending a Retry packet (Section 17.2.5) containing a token. This token MUST be repeated by the client in all Initial packets it sends for that connection after it receives the Retry packet. In response to processing an Initial packet containing a token that was provided in a Retry packet, a server cannot send another Retry packet; it can only refuse the connection or permit it to proceed. As long as it is not possible for an attacker to generate a valid token for its own address (see Section 8.1.4) and the client is able to return that token, it proves to the server that it received the token. A server can also use a Retry packet to defer the state and processing costs of connection establishment. Requiring the server to provide a different connection ID, along with the original_destination_connection_id transport parameter defined in Section 18.2, forces the server to demonstrate that it, or an entity it cooperates with, received the original Initial packet from the client. Providing a different connection ID also grants a server some control over how subsequent packets are routed. This can be used to direct connections to a different server instance. If a server receives a client Initial that contains an invalid Retry token but is otherwise valid, it knows the client will not accept another Retry token. The server can discard such a packet and allow the client to time out to detect handshake failure, but that could impose a significant latency penalty on the client. Instead, the server SHOULD immediately close (Section 10.2) the connection with an INVALID_TOKEN error. Note that a server has not established any state for the connection at this point and so does not enter the closing period. A flow showing the use of a Retry packet is shown in Figure 9. .. raw:: html {% highlight %} Client Server Initial[0]: CRYPTO[CH] -> <- Retry+Token Initial+Token[1]: CRYPTO[CH] -> Initial[0]: CRYPTO[SH] ACK[1] Handshake[0]: CRYPTO[EE, CERT, CV, FIN] <- 1-RTT[0]: STREAM[1, "..."] Figure 9: Example Handshake with Retry {% endhighlight %} Address Validation for Future Connections ``````````````````````````````````````````````````````` A server MAY provide clients with an address validation token during one connection that can be used on a subsequent connection. Address validation is especially important with 0-RTT because a server potentially sends a significant amount of data to a client in response to 0-RTT data. The server uses the NEW_TOKEN frame (Section 19.7) to provide the client with an address validation token that can be used to validate future connections. In a future connection, the client includes this token in Initial packets to provide address validation. The client MUST include the token in all Initial packets it sends, unless a Retry replaces the token with a newer one. The client MUST NOT use the token provided in a Retry for future connections. Servers MAY discard any Initial packet that does not carry the expected token. Unlike the token that is created for a Retry packet, which is used immediately, the token sent in the NEW_TOKEN frame can be used after some period of time has passed. Thus, a token SHOULD have an expiration time, which could be either an explicit expiration time or an issued timestamp that can be used to dynamically calculate the expiration time. A server can store the expiration time or include it in an encrypted form in the token. A token issued with NEW_TOKEN MUST NOT include information that would allow values to be linked by an observer to the connection on which it was issued. For example, it cannot include the previous connection ID or addressing information, unless the values are encrypted. A server MUST ensure that every NEW_TOKEN frame it sends is unique across all clients, with the exception of those sent to repair losses of previously sent NEW_TOKEN frames. Information that allows the server to distinguish between tokens from Retry and NEW_TOKEN MAY be accessible to entities other than the server. It is unlikely that the client port number is the same on two different connections; validating the port is therefore unlikely to be successful. A token received in a NEW_TOKEN frame is applicable to any server that the connection is considered authoritative for (e.g., server names included in the certificate). When connecting to a server for which the client retains an applicable and unused token, it SHOULD include that token in the Token field of its Initial packet. Including a token might allow the server to validate the client address without an additional round trip. A client MUST NOT include a token that is not applicable to the server that it is connecting to, unless the client has the knowledge that the server that issued the token and the server the client is connecting to are jointly managing the tokens. A client MAY use a token from any previous connection to that server. A token allows a server to correlate activity between the connection where the token was issued and any connection where it is used. Clients that want to break continuity of identity with a server can discard tokens provided using the NEW_TOKEN frame. In comparison, a token obtained in a Retry packet MUST be used immediately during the connection attempt and cannot be used in subsequent connection attempts. A client SHOULD NOT reuse a token from a NEW_TOKEN frame for different connection attempts. Reusing a token allows connections to be linked by entities on the network path; see Section 9.5. Clients might receive multiple tokens on a single connection. Aside from preventing linkability, any token can be used in any connection attempt. Servers can send additional tokens to either enable address validation for multiple connection attempts or replace older tokens that might become invalid. For a client, this ambiguity means that sending the most recent unused token is most likely to be effective. Though saving and using older tokens have no negative consequences, clients can regard older tokens as being less likely to be useful to the server for address validation. When a server receives an Initial packet with an address validation token, it MUST attempt to validate the token, unless it has already completed address validation. If the token is invalid, then the server SHOULD proceed as if the client did not have a validated address, including potentially sending a Retry packet. Tokens provided with NEW_TOKEN frames and Retry packets can be distinguished by servers (see Section 8.1.1), and the latter can be validated more strictly. If the validation succeeds, the server SHOULD then allow the handshake to proceed. Note: The rationale for treating the client as unvalidated rather than discarding the packet is that the client might have received the token in a previous connection using the NEW_TOKEN frame, and if the server has lost state, it might be unable to validate the token at all, leading to connection failure if the packet is discarded. In a stateless design, a server can use encrypted and authenticated tokens to pass information to clients that the server can later recover and use to validate a client address. Tokens are not integrated into the cryptographic handshake, and so they are not authenticated. For instance, a client might be able to reuse a token. To avoid attacks that exploit this property, a server can limit its use of tokens to only the information needed to validate client addresses. Clients MAY use tokens obtained on one connection for any connection attempt using the same version. When selecting a token to use, clients do not need to consider other properties of the connection that is being attempted, including the choice of possible application protocols, session tickets, or other connection properties. Address Validation Token Integrity ``````````````````````````````````````````````````````` An address validation token MUST be difficult to guess. Including a random value with at least 128 bits of entropy in the token would be sufficient, but this depends on the server remembering the value it sends to clients. A token-based scheme allows the server to offload any state associated with validation to the client. For this design to work, the token MUST be covered by integrity protection against modification or falsification by clients. Without integrity protection, malicious clients could generate or guess values for tokens that would be accepted by the server. Only the server requires access to the integrity protection key for tokens. There is no need for a single well-defined format for the token because the server that generates the token also consumes it. Tokens sent in Retry packets SHOULD include information that allows the server to verify that the source IP address and port in client packets remain constant. Tokens sent in NEW_TOKEN frames MUST include information that allows the server to verify that the client IP address has not changed from when the token was issued. Servers can use tokens from NEW_TOKEN frames in deciding not to send a Retry packet, even if the client address has changed. If the client IP address has changed, the server MUST adhere to the anti-amplification limit; see Section 8. Note that in the presence of NAT, this requirement might be insufficient to protect other hosts that share the NAT from amplification attacks. Attackers could replay tokens to use servers as amplifiers in DDoS attacks. To protect against such attacks, servers MUST ensure that replay of tokens is prevented or limited. Servers SHOULD ensure that tokens sent in Retry packets are only accepted for a short time, as they are returned immediately by clients. Tokens that are provided in NEW_TOKEN frames (Section 19.7) need to be valid for longer but SHOULD NOT be accepted multiple times. Servers are encouraged to allow tokens to be used only once, if possible; tokens MAY include additional information about clients to further narrow applicability or reuse. Path Validation ``````````````````````````````````````````````````````` Path validation is used by both peers during connection migration (see Section 9) to verify reachability after a change of address. In path validation, endpoints test reachability between a specific local address and a specific peer address, where an address is the 2-tuple of IP address and port. Path validation tests that packets sent on a path to a peer are received by that peer. Path validation is used to ensure that packets received from a migrating peer do not carry a spoofed source address. Path validation does not validate that a peer can send in the return direction. Acknowledgments cannot be used for return path validation because they contain insufficient entropy and might be spoofed. Endpoints independently determine reachability on each direction of a path, and therefore return reachability can only be established by the peer. Path validation can be used at any time by either endpoint. For instance, an endpoint might check that a peer is still in possession of its address after a period of quiescence. Path validation is not designed as a NAT traversal mechanism. Though the mechanism described here might be effective for the creation of NAT bindings that support NAT traversal, the expectation is that one endpoint is able to receive packets without first having sent a packet on that path. Effective NAT traversal needs additional synchronization mechanisms that are not provided here. An endpoint MAY include other frames with the PATH_CHALLENGE and PATH_RESPONSE frames used for path validation. In particular, an endpoint can include PADDING frames with a PATH_CHALLENGE frame for Path Maximum Transmission Unit Discovery (PMTUD); see Section 14.2.1. An endpoint can also include its own PATH_CHALLENGE frame when sending a PATH_RESPONSE frame. An endpoint uses a new connection ID for probes sent from a new local address; see Section 9.5. When probing a new path, an endpoint can ensure that its peer has an unused connection ID available for responses. Sending NEW_CONNECTION_ID and PATH_CHALLENGE frames in the same packet, if the peer's active_connection_id_limit permits, ensures that an unused connection ID will be available to the peer when sending a response. An endpoint can choose to simultaneously probe multiple paths. The number of simultaneous paths used for probes is limited by the number of extra connection IDs its peer has previously supplied, since each new local address used for a probe requires a previously unused connection ID. Initiating Path Validation ``````````````````````````````````````````````````````` To initiate path validation, an endpoint sends a PATH_CHALLENGE frame containing an unpredictable payload on the path to be validated. An endpoint MAY send multiple PATH_CHALLENGE frames to guard against packet loss. However, an endpoint SHOULD NOT send multiple PATH_CHALLENGE frames in a single packet. An endpoint SHOULD NOT probe a new path with packets containing a PATH_CHALLENGE frame more frequently than it would send an Initial packet. This ensures that connection migration is no more load on a new path than establishing a new connection. The endpoint MUST use unpredictable data in every PATH_CHALLENGE frame so that it can associate the peer's response with the corresponding PATH_CHALLENGE. An endpoint MUST expand datagrams that contain a PATH_CHALLENGE frame to at least the smallest allowed maximum datagram size of 1200 bytes, unless the anti-amplification limit for the path does not permit sending a datagram of this size. Sending UDP datagrams of this size ensures that the network path from the endpoint to the peer can be used for QUIC; see Section 14. When an endpoint is unable to expand the datagram size to 1200 bytes due to the anti-amplification limit, the path MTU will not be validated. To ensure that the path MTU is large enough, the endpoint MUST perform a second path validation by sending a PATH_CHALLENGE frame in a datagram of at least 1200 bytes. This additional validation can be performed after a PATH_RESPONSE is successfully received or when enough bytes have been received on the path that sending the larger datagram will not result in exceeding the anti- amplification limit. Unlike other cases where datagrams are expanded, endpoints MUST NOT discard datagrams that appear to be too small when they contain PATH_CHALLENGE or PATH_RESPONSE. Path Validation Responses ``````````````````````````````````````````````````````` On receiving a PATH_CHALLENGE frame, an endpoint MUST respond by echoing the data contained in the PATH_CHALLENGE frame in a PATH_RESPONSE frame. An endpoint MUST NOT delay transmission of a packet containing a PATH_RESPONSE frame unless constrained by congestion control. A PATH_RESPONSE frame MUST be sent on the network path where the PATH_CHALLENGE frame was received. This ensures that path validation by a peer only succeeds if the path is functional in both directions. This requirement MUST NOT be enforced by the endpoint that initiates path validation, as that would enable an attack on migration; see Section 9.3.3. An endpoint MUST expand datagrams that contain a PATH_RESPONSE frame to at least the smallest allowed maximum datagram size of 1200 bytes. This verifies that the path is able to carry datagrams of this size in both directions. However, an endpoint MUST NOT expand the datagram containing the PATH_RESPONSE if the resulting data exceeds the anti-amplification limit. This is expected to only occur if the received PATH_CHALLENGE was not sent in an expanded datagram. An endpoint MUST NOT send more than one PATH_RESPONSE frame in response to one PATH_CHALLENGE frame; see Section 13.3. The peer is expected to send more PATH_CHALLENGE frames as necessary to evoke additional PATH_RESPONSE frames. Successful Path Validation ``````````````````````````````````````````````````````` Path validation succeeds when a PATH_RESPONSE frame is received that contains the data that was sent in a previous PATH_CHALLENGE frame. A PATH_RESPONSE frame received on any network path validates the path on which the PATH_CHALLENGE was sent. If an endpoint sends a PATH_CHALLENGE frame in a datagram that is not expanded to at least 1200 bytes and if the response to it validates the peer address, the path is validated but not the path MTU. As a result, the endpoint can now send more than three times the amount of data that has been received. However, the endpoint MUST initiate another path validation with an expanded datagram to verify that the path supports the required MTU. Receipt of an acknowledgment for a packet containing a PATH_CHALLENGE frame is not adequate validation, since the acknowledgment can be spoofed by a malicious peer. Failed Path Validation ``````````````````````````````````````````````````````` Path validation only fails when the endpoint attempting to validate the path abandons its attempt to validate the path. Endpoints SHOULD abandon path validation based on a timer. When setting this timer, implementations are cautioned that the new path could have a longer round-trip time than the original. A value of three times the larger of the current PTO or the PTO for the new path (using kInitialRtt, as defined in [QUIC-RECOVERY]) is RECOMMENDED. This timeout allows for multiple PTOs to expire prior to failing path validation, so that loss of a single PATH_CHALLENGE or PATH_RESPONSE frame does not cause path validation failure. Note that the endpoint might receive packets containing other frames on the new path, but a PATH_RESPONSE frame with appropriate data is required for path validation to succeed. When an endpoint abandons path validation, it determines that the path is unusable. This does not necessarily imply a failure of the connection -- endpoints can continue sending packets over other paths as appropriate. If no paths are available, an endpoint can wait for a new path to become available or close the connection. An endpoint that has no valid network path to its peer MAY signal this using the NO_VIABLE_PATH connection error, noting that this is only possible if the network path exists but does not support the required MTU (Section 14). A path validation might be abandoned for other reasons besides failure. Primarily, this happens if a connection migration to a new path is initiated while a path validation on the old path is in progress. Connection Migration ---------------------------- Following is copied from QUIC [RFC-9000]_. The use of a connection ID allows connections to survive changes to endpoint addresses (IP address and port), such as those caused by an endpoint migrating to a new network. This section describes the process by which an endpoint migrates to a new address. The design of QUIC relies on endpoints retaining a stable address for the duration of the handshake. An endpoint MUST NOT initiate connection migration before the handshake is confirmed, as defined in Section 4.1.2 of [QUIC-TLS]. If the peer sent the disable_active_migration transport parameter, an endpoint also MUST NOT send packets (including probing packets; see Section 9.1) from a different local address to the address the peer used during the handshake, unless the endpoint has acted on a preferred_address transport parameter from the peer. If the peer violates this requirement, the endpoint MUST either drop the incoming packets on that path without generating a Stateless Reset or proceed with path validation and allow the peer to migrate. Generating a Stateless Reset or closing the connection would allow third parties in the network to cause connections to close by spoofing or otherwise manipulating observed traffic. Not all changes of peer address are intentional, or active, migrations. The peer could experience NAT rebinding: a change of address due to a middlebox, usually a NAT, allocating a new outgoing port or even a new outgoing IP address for a flow. An endpoint MUST perform path validation (Section 8.2) if it detects any change to a peer's address, unless it has previously validated that address. When an endpoint has no validated path on which to send packets, it MAY discard connection state. An endpoint capable of connection migration MAY wait for a new path to become available before discarding connection state. This document limits migration of connections to new client addresses, except as described in Section 9.6. Clients are responsible for initiating all migrations. Servers do not send non- probing packets (see Section 9.1) toward a client address until they see a non-probing packet from that address. If a client receives packets from an unknown server address, the client MUST discard these packets. Probing a New Path ````````````````````````` An endpoint MAY probe for peer reachability from a new local address using path validation (Section 8.2) prior to migrating the connection to the new local address. Failure of path validation simply means that the new path is not usable for this connection. Failure to validate a path does not cause the connection to end unless there are no valid alternative paths available. PATH_CHALLENGE, PATH_RESPONSE, NEW_CONNECTION_ID, and PADDING frames are "probing frames", and all other frames are "non-probing frames". A packet containing only probing frames is a "probing packet", and a packet containing any other frame is a "non-probing packet". Initiating Connection Migration ````````````````````````````````````` An endpoint can migrate a connection to a new local address by sending packets containing non-probing frames from that address. Each endpoint validates its peer's address during connection establishment. Therefore, a migrating endpoint can send to its peer knowing that the peer is willing to receive at the peer's current address. Thus, an endpoint can migrate to a new local address without first validating the peer's address. To establish reachability on the new path, an endpoint initiates path validation (Section 8.2) on the new path. An endpoint MAY defer path validation until after a peer sends the next non-probing frame to its new address. When migrating, the new path might not support the endpoint's current sending rate. Therefore, the endpoint resets its congestion controller and RTT estimate, as described in Section 9.4. The new path might not have the same ECN capability. Therefore, the endpoint validates ECN capability as described in Section 13.4. Responding to Connection Migration ``````````````````````````````````````````` Receiving a packet from a new peer address containing a non-probing frame indicates that the peer has migrated to that address. If the recipient permits the migration, it MUST send subsequent packets to the new peer address and MUST initiate path validation (Section 8.2) to verify the peer's ownership of the address if validation is not already underway. If the recipient has no unused connection IDs from the peer, it will not be able to send anything on the new path until the peer provides one; see Section 9.5. An endpoint only changes the address to which it sends packets in response to the highest-numbered non-probing packet. This ensures that an endpoint does not send packets to an old peer address in the case that it receives reordered packets. An endpoint MAY send data to an unvalidated peer address, but it MUST protect against potential attacks as described in Sections 9.3.1 and 9.3.2. An endpoint MAY skip validation of a peer address if that address has been seen recently. In particular, if an endpoint returns to a previously validated path after detecting some form of spurious migration, skipping address validation and restoring loss detection and congestion state can reduce the performance impact of the attack. After changing the address to which it sends non-probing packets, an endpoint can abandon any path validation for other addresses. Receiving a packet from a new peer address could be the result of a NAT rebinding at the peer. After verifying a new client address, the server SHOULD send new address validation tokens (Section 8) to the client. Peer Address Spoofing ````````````````````````` It is possible that a peer is spoofing its source address to cause an endpoint to send excessive amounts of data to an unwilling host. If the endpoint sends significantly more data than the spoofing peer, connection migration might be used to amplify the volume of data that an attacker can generate toward a victim. As described in Section 9.3, an endpoint is required to validate a peer's new address to confirm the peer's possession of the new address. Until a peer's address is deemed valid, an endpoint limits the amount of data it sends to that address; see Section 8. In the absence of this limit, an endpoint risks being used for a denial-of- service attack against an unsuspecting victim. If an endpoint skips validation of a peer address as described above, it does not need to limit its sending rate. On-Path Address Spoofing ````````````````````````` An on-path attacker could cause a spurious connection migration by copying and forwarding a packet with a spoofed address such that it arrives before the original packet. The packet with the spoofed address will be seen to come from a migrating connection, and the original packet will be seen as a duplicate and dropped. After a spurious migration, validation of the source address will fail because the entity at the source address does not have the necessary cryptographic keys to read or respond to the PATH_CHALLENGE frame that is sent to it even if it wanted to. To protect the connection from failing due to such a spurious migration, an endpoint MUST revert to using the last validated peer address when validation of a new peer address fails. Additionally, receipt of packets with higher packet numbers from the legitimate peer address will trigger another connection migration. This will cause the validation of the address of the spurious migration to be abandoned, thus containing migrations initiated by the attacker injecting a single packet. If an endpoint has no state about the last validated peer address, it MUST close the connection silently by discarding all connection state. This results in new packets on the connection being handled generically. For instance, an endpoint MAY send a Stateless Reset in response to any further incoming packets. Off-Path Packet Forwarding ``````````````````````````````````` An off-path attacker that can observe packets might forward copies of genuine packets to endpoints. If the copied packet arrives before the genuine packet, this will appear as a NAT rebinding. Any genuine packet will be discarded as a duplicate. If the attacker is able to continue forwarding packets, it might be able to cause migration to a path via the attacker. This places the attacker on-path, giving it the ability to observe or drop all subsequent packets. This style of attack relies on the attacker using a path that has approximately the same characteristics as the direct path between endpoints. The attack is more reliable if relatively few packets are sent or if packet loss coincides with the attempted attack. A non-probing packet received on the original path that increases the maximum received packet number will cause the endpoint to move back to that path. Eliciting packets on this path increases the likelihood that the attack is unsuccessful. Therefore, mitigation of this attack relies on triggering the exchange of packets. In response to an apparent migration, endpoints MUST validate the previously active path using a PATH_CHALLENGE frame. This induces the sending of new packets on that path. If the path is no longer viable, the validation attempt will time out and fail; if the path is viable but no longer desired, the validation will succeed but only results in probing packets being sent on the path. An endpoint that receives a PATH_CHALLENGE on an active path SHOULD send a non-probing packet in response. If the non-probing packet arrives before any copy made by an attacker, this results in the connection being migrated back to the original path. Any subsequent migration to another path restarts this entire process. This defense is imperfect, but this is not considered a serious problem. If the path via the attack is reliably faster than the original path despite multiple attempts to use that original path, it is not possible to distinguish between an attack and an improvement in routing. An endpoint could also use heuristics to improve detection of this style of attack. For instance, NAT rebinding is improbable if packets were recently received on the old path; similarly, rebinding is rare on IPv6 paths. Endpoints can also look for duplicated packets. Conversely, a change in connection ID is more likely to indicate an intentional migration rather than an attack. Loss Detection and Congestion Control ````````````````````````````````````````` The capacity available on the new path might not be the same as the old path. Packets sent on the old path MUST NOT contribute to congestion control or RTT estimation for the new path. On confirming a peer's ownership of its new address, an endpoint MUST immediately reset the congestion controller and round-trip time estimator for the new path to initial values (see Appendices A.3 and B.3 of [QUIC-RECOVERY]) unless the only change in the peer's address is its port number. Because port-only changes are commonly the result of NAT rebinding or other middlebox activity, the endpoint MAY instead retain its congestion control state and round-trip estimate in those cases instead of reverting to initial values. In cases where congestion control state retained from an old path is used on a new path with substantially different characteristics, a sender could transmit too aggressively until the congestion controller and the RTT estimator have adapted. Generally, implementations are advised to be cautious when using previous values on a new path. There could be apparent reordering at the receiver when an endpoint sends data and probes from/to multiple addresses during the migration period, since the two resulting paths could have different round-trip times. A receiver of packets on multiple paths will still send ACK frames covering all received packets. While multiple paths might be used during connection migration, a single congestion control context and a single loss recovery context (as described in [QUIC-RECOVERY]) could be adequate. For instance, an endpoint might delay switching to a new congestion control context until it is confirmed that an old path is no longer needed (such as the case described in Section 9.3.3). A sender can make exceptions for probe packets so that their loss detection is independent and does not unduly cause the congestion controller to reduce its sending rate. An endpoint might set a separate timer when a PATH_CHALLENGE is sent, which is canceled if the corresponding PATH_RESPONSE is received. If the timer fires before the PATH_RESPONSE is received, the endpoint might send a new PATH_CHALLENGE and restart the timer for a longer period of time. This timer SHOULD be set as described in Section 6.2.1 of [QUIC-RECOVERY] and MUST NOT be more aggressive. Privacy Implications of Connection Migration ````````````````````````````````````````````````` Using a stable connection ID on multiple network paths would allow a passive observer to correlate activity between those paths. An endpoint that moves between networks might not wish to have their activity correlated by any entity other than their peer, so different connection IDs are used when sending from different local addresses, as discussed in Section 5.1. For this to be effective, endpoints need to ensure that connection IDs they provide cannot be linked by any other entity. At any time, endpoints MAY change the Destination Connection ID they transmit with to a value that has not been used on another path. An endpoint MUST NOT reuse a connection ID when sending from more than one local address -- for example, when initiating connection migration as described in Section 9.2 or when probing a new network path as described in Section 9.1. Similarly, an endpoint MUST NOT reuse a connection ID when sending to more than one destination address. Due to network changes outside the control of its peer, an endpoint might receive packets from a new source address with the same Destination Connection ID field value, in which case it MAY continue to use the current connection ID with the new remote address while still sending from the same local address. These requirements regarding connection ID reuse apply only to the sending of packets, as unintentional changes in path without a change in connection ID are possible. For example, after a period of network inactivity, NAT rebinding might cause packets to be sent on a new path when the client resumes sending. An endpoint responds to such an event as described in Section 9.3. Using different connection IDs for packets sent in both directions on each new network path eliminates the use of the connection ID for linking packets from the same connection across different network paths. Header protection ensures that packet numbers cannot be used to correlate activity. This does not prevent other properties of packets, such as timing and size, from being used to correlate activity. An endpoint SHOULD NOT initiate migration with a peer that has requested a zero-length connection ID, because traffic over the new path might be trivially linkable to traffic over the old one. If the server is able to associate packets with a zero-length connection ID to the right connection, it means that the server is using other information to demultiplex packets. For example, a server might provide a unique address to every client -- for instance, using HTTP alternative services [ALTSVC]. Information that might allow correct routing of packets across multiple network paths will also allow activity on those paths to be linked by entities other than the peer. A client might wish to reduce linkability by switching to a new connection ID, source UDP port, or IP address (see [RFC8981]) when sending traffic after a period of inactivity. Changing the address from which it sends packets at the same time might cause the server to detect a connection migration. This ensures that the mechanisms that support migration are exercised even for clients that do not experience NAT rebindings or genuine migrations. Changing address can cause a peer to reset its congestion control state (see Section 9.4), so addresses SHOULD only be changed infrequently. An endpoint that exhausts available connection IDs cannot probe new paths or initiate migration, nor can it respond to probes or attempts by its peer to migrate. To ensure that migration is possible and packets sent on different paths cannot be correlated, endpoints SHOULD provide new connection IDs before peers migrate; see Section 5.1.1. If a peer might have exhausted available connection IDs, a migrating endpoint could include a NEW_CONNECTION_ID frame in all packets sent on a new network path. Server's Preferred Address ````````````````````````````` QUIC allows servers to accept connections on one IP address and attempt to transfer these connections to a more preferred address shortly after the handshake. This is particularly useful when clients initially connect to an address shared by multiple servers but would prefer to use a unicast address to ensure connection stability. This section describes the protocol for migrating a connection to a preferred server address. Migrating a connection to a new server address mid-connection is not supported by the version of QUIC specified in this document. If a client receives packets from a new server address when the client has not initiated a migration to that address, the client SHOULD discard these packets. Communicating a Preferred Address `````````````````````````````````````` A server conveys a preferred address by including the preferred_address transport parameter in the TLS handshake. Servers MAY communicate a preferred address of each address family (IPv4 and IPv6) to allow clients to pick the one most suited to their network attachment. Once the handshake is confirmed, the client SHOULD select one of the two addresses provided by the server and initiate path validation (see Section 8.2). A client constructs packets using any previously unused active connection ID, taken from either the preferred_address transport parameter or a NEW_CONNECTION_ID frame. As soon as path validation succeeds, the client SHOULD begin sending all future packets to the new server address using the new connection ID and discontinue use of the old server address. If path validation fails, the client MUST continue sending all future packets to the server's original IP address. Migration to a Preferred Address ```````````````````````````````````` A client that migrates to a preferred address MUST validate the address it chooses before migrating; see Section 21.5.3. A server might receive a packet addressed to its preferred IP address at any time after it accepts a connection. If this packet contains a PATH_CHALLENGE frame, the server sends a packet containing a PATH_RESPONSE frame as per Section 8.2. The server MUST send non- probing packets from its original address until it receives a non- probing packet from the client at its preferred address and until the server has validated the new path. The server MUST probe on the path toward the client from its preferred address. This helps to guard against spurious migration initiated by an attacker. Once the server has completed its path validation and has received a non-probing packet with a new largest packet number on its preferred address, the server begins sending non-probing packets to the client exclusively from its preferred IP address. The server SHOULD drop newer packets for this connection that are received on the old IP address. The server MAY continue to process delayed packets that are received on the old IP address. The addresses that a server provides in the preferred_address transport parameter are only valid for the connection in which they are provided. A client MUST NOT use these for other connections, including connections that are resumed from the current connection. Interaction of Client Migration and Preferred Address `````````````````````````````````````````````````````````` A client might need to perform a connection migration before it has migrated to the server's preferred address. In this case, the client SHOULD perform path validation to both the original and preferred server address from the client's new address concurrently. If path validation of the server's preferred address succeeds, the client MUST abandon validation of the original address and migrate to using the server's preferred address. If path validation of the server's preferred address fails but validation of the server's original address succeeds, the client MAY migrate to its new address and continue sending to the server's original address. If packets received at the server's preferred address have a different source address than observed from the client during the handshake, the server MUST protect against potential attacks as described in Sections 9.3.1 and 9.3.2. In addition to intentional simultaneous migration, this might also occur because the client's access network used a different NAT binding for the server's preferred address. Servers SHOULD initiate path validation to the client's new address upon receiving a probe packet from a different address; see Section 8. A client that migrates to a new address SHOULD use a preferred address from the same address family for the server. The connection ID provided in the preferred_address transport parameter is not specific to the addresses that are provided. This connection ID is provided to ensure that the client has a connection ID available for migration, but the client MAY use this connection ID on any path. Use of IPv6 Flow Label and Migration `````````````````````````````````````````` Endpoints that send data using IPv6 SHOULD apply an IPv6 flow label in compliance with [RFC6437], unless the local API does not allow setting IPv6 flow labels. The flow label generation MUST be designed to minimize the chances of linkability with a previously used flow label, as a stable flow label would enable correlating activity on multiple paths; see Section 9.5. [RFC6437] suggests deriving values using a pseudorandom function to generate flow labels. Including the Destination Connection ID field in addition to source and destination addresses when generating flow labels ensures that changes are synchronized with changes in other observable identifiers. A cryptographic hash function that combines these inputs with a local secret is one way this might be implemented. Security Considerations --------------------------- Following is copied from QUIC [RFC-9000]_. The goal of QUIC is to provide a secure transport connection. Section 21.1 provides an overview of those properties; subsequent sections discuss constraints and caveats regarding these properties, including descriptions of known attacks and countermeasures. Overview of Security Properties `````````````````````````````````````````````` A complete security analysis of QUIC is outside the scope of this document. This section provides an informal description of the desired security properties as an aid to implementers and to help guide protocol analysis. QUIC assumes the threat model described in [SEC-CONS] and provides protections against many of the attacks that arise from that model. For this purpose, attacks are divided into passive and active attacks. Passive attackers have the ability to read packets from the network, while active attackers also have the ability to write packets into the network. However, a passive attack could involve an attacker with the ability to cause a routing change or other modification in the path taken by packets that comprise a connection. Attackers are additionally categorized as either on-path attackers or off-path attackers. An on-path attacker can read, modify, or remove any packet it observes such that the packet no longer reaches its destination, while an off-path attacker observes the packets but cannot prevent the original packet from reaching its intended destination. Both types of attackers can also transmit arbitrary packets. This definition differs from that of Section 3.5 of [SEC-CONS] in that an off-path attacker is able to observe packets. Properties of the handshake, protected packets, and connection migration are considered separately. Handshake `````````````````````````````````````````````` The QUIC handshake incorporates the TLS 1.3 handshake and inherits the cryptographic properties described in Appendix E.1 of [TLS13]. Many of the security properties of QUIC depend on the TLS handshake providing these properties. Any attack on the TLS handshake could affect QUIC. Any attack on the TLS handshake that compromises the secrecy or uniqueness of session keys, or the authentication of the participating peers, affects other security guarantees provided by QUIC that depend on those keys. For instance, migration (Section 9) depends on the efficacy of confidentiality protections, both for the negotiation of keys using the TLS handshake and for QUIC packet protection, to avoid linkability across network paths. An attack on the integrity of the TLS handshake might allow an attacker to affect the selection of application protocol or QUIC version. In addition to the properties provided by TLS, the QUIC handshake provides some defense against DoS attacks on the handshake. Anti-Amplification `````````````````````````````````````````````` Address validation (Section 8) is used to verify that an entity that claims a given address is able to receive packets at that address. Address validation limits amplification attack targets to addresses for which an attacker can observe packets. Prior to address validation, endpoints are limited in what they are able to send. Endpoints cannot send data toward an unvalidated address in excess of three times the data received from that address. Note: The anti-amplification limit only applies when an endpoint responds to packets received from an unvalidated address. The anti-amplification limit does not apply to clients when establishing a new connection or when initiating connection migration. Server-Side DoS `````````````````````````````````````````````` Computing the server's first flight for a full handshake is potentially expensive, requiring both a signature and a key exchange computation. In order to prevent computational DoS attacks, the Retry packet provides a cheap token exchange mechanism that allows servers to validate a client's IP address prior to doing any expensive computations at the cost of a single round trip. After a successful handshake, servers can issue new tokens to a client, which will allow new connection establishment without incurring this cost. On-Path Handshake Termination `````````````````````````````````````````````` An on-path or off-path attacker can force a handshake to fail by replacing or racing Initial packets. Once valid Initial packets have been exchanged, subsequent Handshake packets are protected with the Handshake keys, and an on-path attacker cannot force handshake failure other than by dropping packets to cause endpoints to abandon the attempt. An on-path attacker can also replace the addresses of packets on either side and therefore cause the client or server to have an incorrect view of the remote addresses. Such an attack is indistinguishable from the functions performed by a NAT. Parameter Negotiation `````````````````````````````````````````````` The entire handshake is cryptographically protected, with the Initial packets being encrypted with per-version keys and the Handshake and later packets being encrypted with keys derived from the TLS key exchange. Further, parameter negotiation is folded into the TLS transcript and thus provides the same integrity guarantees as ordinary TLS negotiation. An attacker can observe the client's transport parameters (as long as it knows the version-specific salt) but cannot observe the server's transport parameters and cannot influence parameter negotiation. Connection IDs are unencrypted but integrity protected in all packets. This version of QUIC does not incorporate a version negotiation mechanism; implementations of incompatible versions will simply fail to establish a connection. Protected Packets `````````````````````````````````````````````` Packet protection (Section 12.1) applies authenticated encryption to all packets except Version Negotiation packets, though Initial and Retry packets have limited protection due to the use of version- specific keying material; see [QUIC-TLS] for more details. This section considers passive and active attacks against protected packets. Both on-path and off-path attackers can mount a passive attack in which they save observed packets for an offline attack against packet protection at a future time; this is true for any observer of any packet on any network. An attacker that injects packets without being able to observe valid packets for a connection is unlikely to be successful, since packet protection ensures that valid packets are only generated by endpoints that possess the key material established during the handshake; see Sections 7 and 21.1.1. Similarly, any active attacker that observes packets and attempts to insert new data or modify existing data in those packets should not be able to generate packets deemed valid by the receiving endpoint, other than Initial packets. A spoofing attack, in which an active attacker rewrites unprotected parts of a packet that it forwards or injects, such as the source or destination address, is only effective if the attacker can forward packets to the original endpoint. Packet protection ensures that the packet payloads can only be processed by the endpoints that completed the handshake, and invalid packets are ignored by those endpoints. An attacker can also modify the boundaries between packets and UDP datagrams, causing multiple packets to be coalesced into a single datagram or splitting coalesced packets into multiple datagrams. Aside from datagrams containing Initial packets, which require padding, modification of how packets are arranged in datagrams has no functional effect on a connection, although it might change some performance characteristics. Connection Migration `````````````````````````````````````````````` Connection migration (Section 9) provides endpoints with the ability to transition between IP addresses and ports on multiple paths, using one path at a time for transmission and receipt of non-probing frames. Path validation (Section 8.2) establishes that a peer is both willing and able to receive packets sent on a particular path. This helps reduce the effects of address spoofing by limiting the number of packets sent to a spoofed address. This section describes the intended security properties of connection migration under various types of DoS attacks. On-Path Active Attacks `````````````````````````````````````````````` An attacker that can cause a packet it observes to no longer reach its intended destination is considered an on-path attacker. When an attacker is present between a client and server, endpoints are required to send packets through the attacker to establish connectivity on a given path. An on-path attacker can: * Inspect packets * Modify IP and UDP packet headers * Inject new packets * Delay packets * Reorder packets * Drop packets * Split and merge datagrams along packet boundaries An on-path attacker cannot: * Modify an authenticated portion of a packet and cause the recipient to accept that packet An on-path attacker has the opportunity to modify the packets that it observes; however, any modifications to an authenticated portion of a packet will cause it to be dropped by the receiving endpoint as invalid, as packet payloads are both authenticated and encrypted. QUIC aims to constrain the capabilities of an on-path attacker as follows: 1. An on-path attacker can prevent the use of a path for a connection, causing the connection to fail if it cannot use a different path that does not contain the attacker. This can be achieved by dropping all packets, modifying them so that they fail to decrypt, or other methods. 2. An on-path attacker can prevent migration to a new path for which the attacker is also on-path by causing path validation to fail on the new path. 3. An on-path attacker cannot prevent a client from migrating to a path for which the attacker is not on-path. 4. An on-path attacker can reduce the throughput of a connection by delaying packets or dropping them. 5. An on-path attacker cannot cause an endpoint to accept a packet for which it has modified an authenticated portion of that packet. Off-Path Active Attacks `````````````````````````````````````````````` An off-path attacker is not directly on the path between a client and server but could be able to obtain copies of some or all packets sent between the client and the server. It is also able to send copies of those packets to either endpoint. An off-path attacker can: * Inspect packets * Inject new packets * Reorder injected packets An off-path attacker cannot: * Modify packets sent by endpoints * Delay packets * Drop packets * Reorder original packets An off-path attacker can create modified copies of packets that it has observed and inject those copies into the network, potentially with spoofed source and destination addresses. For the purposes of this discussion, it is assumed that an off-path attacker has the ability to inject a modified copy of a packet into the network that will reach the destination endpoint prior to the arrival of the original packet observed by the attacker. In other words, an attacker has the ability to consistently "win" a race with the legitimate packets between the endpoints, potentially causing the original packet to be ignored by the recipient. It is also assumed that an attacker has the resources necessary to affect NAT state. In particular, an attacker can cause an endpoint to lose its NAT binding and then obtain the same port for use with its own traffic. QUIC aims to constrain the capabilities of an off-path attacker as follows: 1. An off-path attacker can race packets and attempt to become a "limited" on-path attacker. 2. An off-path attacker can cause path validation to succeed for forwarded packets with the source address listed as the off-path attacker as long as it can provide improved connectivity between the client and the server. 3. An off-path attacker cannot cause a connection to close once the handshake has completed. 4. An off-path attacker cannot cause migration to a new path to fail if it cannot observe the new path. 5. An off-path attacker can become a limited on-path attacker during migration to a new path for which it is also an off-path attacker. 6. An off-path attacker can become a limited on-path attacker by affecting shared NAT state such that it sends packets to the server from the same IP address and port that the client originally used. Limited On-Path Active Attacks `````````````````````````````````````````````` A limited on-path attacker is an off-path attacker that has offered improved routing of packets by duplicating and forwarding original packets between the server and the client, causing those packets to arrive before the original copies such that the original packets are dropped by the destination endpoint. A limited on-path attacker differs from an on-path attacker in that it is not on the original path between endpoints, and therefore the original packets sent by an endpoint are still reaching their destination. This means that a future failure to route copied packets to the destination faster than their original path will not prevent the original packets from reaching the destination. A limited on-path attacker can: * Inspect packets * Inject new packets * Modify unencrypted packet headers * Reorder packets A limited on-path attacker cannot: * Delay packets so that they arrive later than packets sent on the original path * Drop packets * Modify the authenticated and encrypted portion of a packet and cause the recipient to accept that packet A limited on-path attacker can only delay packets up to the point that the original packets arrive before the duplicate packets, meaning that it cannot offer routing with worse latency than the original path. If a limited on-path attacker drops packets, the original copy will still arrive at the destination endpoint. QUIC aims to constrain the capabilities of a limited off-path attacker as follows: 1. A limited on-path attacker cannot cause a connection to close once the handshake has completed. 2. A limited on-path attacker cannot cause an idle connection to close if the client is first to resume activity. 3. A limited on-path attacker can cause an idle connection to be deemed lost if the server is the first to resume activity. Note that these guarantees are the same guarantees provided for any NAT, for the same reasons. Handshake Denial of Service `````````````````````````````````````````````` As an encrypted and authenticated transport, QUIC provides a range of protections against denial of service. Once the cryptographic handshake is complete, QUIC endpoints discard most packets that are not authenticated, greatly limiting the ability of an attacker to interfere with existing connections. Once a connection is established, QUIC endpoints might accept some unauthenticated ICMP packets (see Section 14.2.1), but the use of these packets is extremely limited. The only other type of packet that an endpoint might accept is a stateless reset (Section 10.3), which relies on the token being kept secret until it is used. During the creation of a connection, QUIC only provides protection against attacks from off the network path. All QUIC packets contain proof that the recipient saw a preceding packet from its peer. Addresses cannot change during the handshake, so endpoints can discard packets that are received on a different network path. The Source and Destination Connection ID fields are the primary means of protection against an off-path attack during the handshake; see Section 8.1. These are required to match those set by a peer. Except for Initial and Stateless Resets, an endpoint only accepts packets that include a Destination Connection ID field that matches a value the endpoint previously chose. This is the only protection offered for Version Negotiation packets. The Destination Connection ID field in an Initial packet is selected by a client to be unpredictable, which serves an additional purpose. The packets that carry the cryptographic handshake are protected with a key that is derived from this connection ID and a salt specific to the QUIC version. This allows endpoints to use the same process for authenticating packets that they receive as they use after the cryptographic handshake completes. Packets that cannot be authenticated are discarded. Protecting packets in this fashion provides a strong assurance that the sender of the packet saw the Initial packet and understood it. These protections are not intended to be effective against an attacker that is able to receive QUIC packets prior to the connection being established. Such an attacker can potentially send packets that will be accepted by QUIC endpoints. This version of QUIC attempts to detect this sort of attack, but it expects that endpoints will fail to establish a connection rather than recovering. For the most part, the cryptographic handshake protocol [QUIC-TLS] is responsible for detecting tampering during the handshake. Endpoints are permitted to use other methods to detect and attempt to recover from interference with the handshake. Invalid packets can be identified and discarded using other methods, but no specific method is mandated in this document. Amplification Attack `````````````````````````````````````````````` An attacker might be able to receive an address validation token (Section 8) from a server and then release the IP address it used to acquire that token. At a later time, the attacker can initiate a 0-RTT connection with a server by spoofing this same address, which might now address a different (victim) endpoint. The attacker can thus potentially cause the server to send an initial congestion window's worth of data towards the victim. Servers SHOULD provide mitigations for this attack by limiting the usage and lifetime of address validation tokens; see Section 8.1.3. Optimistic ACK Attack `````````````````````````````````````````````` An endpoint that acknowledges packets it has not received might cause a congestion controller to permit sending at rates beyond what the network supports. An endpoint MAY skip packet numbers when sending packets to detect this behavior. An endpoint can then immediately close the connection with a connection error of type PROTOCOL_VIOLATION; see Section 10.2. Request Forgery Attacks `````````````````````````````````````````````` A request forgery attack occurs where an endpoint causes its peer to issue a request towards a victim, with the request controlled by the endpoint. Request forgery attacks aim to provide an attacker with access to capabilities of its peer that might otherwise be unavailable to the attacker. For a networking protocol, a request forgery attack is often used to exploit any implicit authorization conferred on the peer by the victim due to the peer's location in the network. For request forgery to be effective, an attacker needs to be able to influence what packets the peer sends and where these packets are sent. If an attacker can target a vulnerable service with a controlled payload, that service might perform actions that are attributed to the attacker's peer but are decided by the attacker. For example, cross-site request forgery [CSRF] exploits on the Web cause a client to issue requests that include authorization cookies [COOKIE], allowing one site access to information and actions that are intended to be restricted to a different site. As QUIC runs over UDP, the primary attack modality of concern is one where an attacker can select the address to which its peer sends UDP datagrams and can control some of the unprotected content of those packets. As much of the data sent by QUIC endpoints is protected, this includes control over ciphertext. An attack is successful if an attacker can cause a peer to send a UDP datagram to a host that will perform some action based on content in the datagram. This section discusses ways in which QUIC might be used for request forgery attacks. This section also describes limited countermeasures that can be implemented by QUIC endpoints. These mitigations can be employed unilaterally by a QUIC implementation or deployment, without potential targets for request forgery attacks taking action. However, these countermeasures could be insufficient if UDP-based services do not properly authorize requests. Because the migration attack described in Section 21.5.4 is quite powerful and does not have adequate countermeasures, QUIC server implementations should assume that attackers can cause them to generate arbitrary UDP payloads to arbitrary destinations. QUIC servers SHOULD NOT be deployed in networks that do not deploy ingress filtering [BCP38] and also have inadequately secured UDP endpoints. Although it is not generally possible to ensure that clients are not co-located with vulnerable endpoints, this version of QUIC does not allow servers to migrate, thus preventing spoofed migration attacks on clients. Any future extension that allows server migration MUST also define countermeasures for forgery attacks. Control Options for Endpoints `````````````````````````````````````````````` QUIC offers some opportunities for an attacker to influence or control where its peer sends UDP datagrams: * initial connection establishment (Section 7), where a server is able to choose where a client sends datagrams -- for example, by populating DNS records; * preferred addresses (Section 9.6), where a server is able to choose where a client sends datagrams; * spoofed connection migrations (Section 9.3.1), where a client is able to use source address spoofing to select where a server sends subsequent datagrams; and * spoofed packets that cause a server to send a Version Negotiation packet (Section 21.5.5). In all cases, the attacker can cause its peer to send datagrams to a victim that might not understand QUIC. That is, these packets are sent by the peer prior to address validation; see Section 8. Outside of the encrypted portion of packets, QUIC offers an endpoint several options for controlling the content of UDP datagrams that its peer sends. The Destination Connection ID field offers direct control over bytes that appear early in packets sent by the peer; see Section 5.1. The Token field in Initial packets offers a server control over other bytes of Initial packets; see Section 17.2.2. There are no measures in this version of QUIC to prevent indirect control over the encrypted portions of packets. It is necessary to assume that endpoints are able to control the contents of frames that a peer sends, especially those frames that convey application data, such as STREAM frames. Though this depends to some degree on details of the application protocol, some control is possible in many protocol usage contexts. As the attacker has access to packet protection keys, they are likely to be capable of predicting how a peer will encrypt future packets. Successful control over datagram content then only requires that the attacker be able to predict the packet number and placement of frames in packets with some amount of reliability. This section assumes that limiting control over datagram content is not feasible. The focus of the mitigations in subsequent sections is on limiting the ways in which datagrams that are sent prior to address validation can be used for request forgery. Request Forgery with Client Initial Packets `````````````````````````````````````````````` An attacker acting as a server can choose the IP address and port on which it advertises its availability, so Initial packets from clients are assumed to be available for use in this sort of attack. The address validation implicit in the handshake ensures that -- for a new connection -- a client will not send other types of packets to a destination that does not understand QUIC or is not willing to accept a QUIC connection. Initial packet protection (Section 5.2 of [QUIC-TLS]) makes it difficult for servers to control the content of Initial packets sent by clients. A client choosing an unpredictable Destination Connection ID ensures that servers are unable to control any of the encrypted portion of Initial packets from clients. However, the Token field is open to server control and does allow a server to use clients to mount request forgery attacks. The use of tokens provided with the NEW_TOKEN frame (Section 8.1.3) offers the only option for request forgery during connection establishment. Clients, however, are not obligated to use the NEW_TOKEN frame. Request forgery attacks that rely on the Token field can be avoided if clients send an empty Token field when the server address has changed from when the NEW_TOKEN frame was received. Clients could avoid using NEW_TOKEN if the server address changes. However, not including a Token field could adversely affect performance. Servers could rely on NEW_TOKEN to enable the sending of data in excess of the three-times limit on sending data; see Section 8.1. In particular, this affects cases where clients use 0-RTT to request data from servers. Sending a Retry packet (Section 17.2.5) offers a server the option to change the Token field. After sending a Retry, the server can also control the Destination Connection ID field of subsequent Initial packets from the client. This also might allow indirect control over the encrypted content of Initial packets. However, the exchange of a Retry packet validates the server's address, thereby preventing the use of subsequent Initial packets for request forgery. Request Forgery with Preferred Addresses `````````````````````````````````````````````` Servers can specify a preferred address, which clients then migrate to after confirming the handshake; see Section 9.6. The Destination Connection ID field of packets that the client sends to a preferred address can be used for request forgery. A client MUST NOT send non-probing frames to a preferred address prior to validating that address; see Section 8. This greatly reduces the options that a server has to control the encrypted portion of datagrams. This document does not offer any additional countermeasures that are specific to the use of preferred addresses and can be implemented by endpoints. The generic measures described in Section 21.5.6 could be used as further mitigation. Request Forgery with Spoofed Migration `````````````````````````````````````````` Clients are able to present a spoofed source address as part of an apparent connection migration to cause a server to send datagrams to that address. The Destination Connection ID field in any packets that a server subsequently sends to this spoofed address can be used for request forgery. A client might also be able to influence the ciphertext. A server that only sends probing packets (Section 9.1) to an address prior to address validation provides an attacker with only limited control over the encrypted portion of datagrams. However, particularly for NAT rebinding, this can adversely affect performance. If the server sends frames carrying application data, an attacker might be able to control most of the content of datagrams. This document does not offer specific countermeasures that can be implemented by endpoints, aside from the generic measures described in Section 21.5.6. However, countermeasures for address spoofing at the network level -- in particular, ingress filtering [BCP38] -- are especially effective against attacks that use spoofing and originate from an external network. Request Forgery with Version Negotiation ````````````````````````````````````````````````````` Clients that are able to present a spoofed source address on a packet can cause a server to send a Version Negotiation packet (Section 17.2.1) to that address. The absence of size restrictions on the connection ID fields for packets of an unknown version increases the amount of data that the client controls from the resulting datagram. The first byte of this packet is not under client control and the next four bytes are zero, but the client is able to control up to 512 bytes starting from the fifth byte. No specific countermeasures are provided for this attack, though generic protections (Section 21.5.6) could apply. In this case, ingress filtering [BCP38] is also effective. Generic Request Forgery Countermeasures ````````````````````````````````````````````````````` The most effective defense against request forgery attacks is to modify vulnerable services to use strong authentication. However, this is not always something that is within the control of a QUIC deployment. This section outlines some other steps that QUIC endpoints could take unilaterally. These additional steps are all discretionary because, depending on circumstances, they could interfere with or prevent legitimate uses. Services offered over loopback interfaces often lack proper authentication. Endpoints MAY prevent connection attempts or migration to a loopback address. Endpoints SHOULD NOT allow connections or migration to a loopback address if the same service was previously available at a different interface or if the address was provided by a service at a non-loopback address. Endpoints that depend on these capabilities could offer an option to disable these protections. Similarly, endpoints could regard a change in address to a link-local address [RFC4291] or an address in a private-use range [RFC1918] from a global, unique-local [RFC4193], or non-private address as a potential attempt at request forgery. Endpoints could refuse to use these addresses entirely, but that carries a significant risk of interfering with legitimate uses. Endpoints SHOULD NOT refuse to use an address unless they have specific knowledge about the network indicating that sending datagrams to unvalidated addresses in a given range is not safe. Endpoints MAY choose to reduce the risk of request forgery by not including values from NEW_TOKEN frames in Initial packets or by only sending probing frames in packets prior to completing address validation. Note that this does not prevent an attacker from using the Destination Connection ID field for an attack. Endpoints are not expected to have specific information about the location of servers that could be vulnerable targets of a request forgery attack. However, it might be possible over time to identify specific UDP ports that are common targets of attacks or particular patterns in datagrams that are used for attacks. Endpoints MAY choose to avoid sending datagrams to these ports or not send datagrams that match these patterns prior to validating the destination address. Endpoints MAY retire connection IDs containing patterns known to be problematic without using them. Note: Modifying endpoints to apply these protections is more efficient than deploying network-based protections, as endpoints do not need to perform any additional processing when sending to an address that has been validated. Slowloris Attacks ````````````````````````````````````````````````````` The attacks commonly known as Slowloris [SLOWLORIS] try to keep many connections to the target endpoint open and hold them open as long as possible. These attacks can be executed against a QUIC endpoint by generating the minimum amount of activity necessary to avoid being closed for inactivity. This might involve sending small amounts of data, gradually opening flow control windows in order to control the sender rate, or manufacturing ACK frames that simulate a high loss rate. QUIC deployments SHOULD provide mitigations for the Slowloris attacks, such as increasing the maximum number of clients the server will allow, limiting the number of connections a single IP address is allowed to make, imposing restrictions on the minimum transfer speed a connection is allowed to have, and restricting the length of time an endpoint is allowed to stay connected. Stream Fragmentation and Reassembly Attacks ````````````````````````````````````````````````````` An adversarial sender might intentionally not send portions of the stream data, causing the receiver to commit resources for the unsent data. This could cause a disproportionate receive buffer memory commitment and/or the creation of a large and inefficient data structure at the receiver. An adversarial receiver might intentionally not acknowledge packets containing stream data in an attempt to force the sender to store the unacknowledged stream data for retransmission. The attack on receivers is mitigated if flow control windows correspond to available memory. However, some receivers will overcommit memory and advertise flow control offsets in the aggregate that exceed actual available memory. The overcommitment strategy can lead to better performance when endpoints are well behaved, but renders endpoints vulnerable to the stream fragmentation attack. QUIC deployments SHOULD provide mitigations for stream fragmentation attacks. Mitigations could consist of avoiding overcommitting memory, limiting the size of tracking data structures, delaying reassembly of STREAM frames, implementing heuristics based on the age and duration of reassembly holes, or some combination of these. Stream Commitment Attack ````````````````````````````````````````````````````` An adversarial endpoint can open a large number of streams, exhausting state on an endpoint. The adversarial endpoint could repeat the process on a large number of connections, in a manner similar to SYN flooding attacks in TCP. Normally, clients will open streams sequentially, as explained in Section 2.1. However, when several streams are initiated at short intervals, loss or reordering can cause STREAM frames that open streams to be received out of sequence. On receiving a higher- numbered stream ID, a receiver is required to open all intervening streams of the same type; see Section 3.2. Thus, on a new connection, opening stream 4000000 opens 1 million and 1 client- initiated bidirectional streams. The number of active streams is limited by the initial_max_streams_bidi and initial_max_streams_uni transport parameters as updated by any received MAX_STREAMS frames, as explained in Section 4.6. If chosen judiciously, these limits mitigate the effect of the stream commitment attack. However, setting the limit too low could affect performance when applications expect to open a large number of streams. Peer Denial of Service ````````````````````````````````````````````````````` QUIC and TLS both contain frames or messages that have legitimate uses in some contexts, but these frames or messages can be abused to cause a peer to expend processing resources without having any observable impact on the state of the connection. Messages can also be used to change and revert state in small or inconsequential ways, such as by sending small increments to flow control limits. If processing costs are disproportionately large in comparison to bandwidth consumption or effect on state, then this could allow a malicious peer to exhaust processing capacity. While there are legitimate uses for all messages, implementations SHOULD track cost of processing relative to progress and treat excessive quantities of any non-productive packets as indicative of an attack. Endpoints MAY respond to this condition with a connection error or by dropping packets. Explicit Congestion Notification Attacks ````````````````````````````````````````````````````` An on-path attacker could manipulate the value of ECN fields in the IP header to influence the sender's rate. [RFC3168] discusses manipulations and their effects in more detail. A limited on-path attacker can duplicate and send packets with modified ECN fields to affect the sender's rate. If duplicate packets are discarded by a receiver, an attacker will need to race the duplicate packet against the original to be successful in this attack. Therefore, QUIC endpoints ignore the ECN field in an IP packet unless at least one QUIC packet in that IP packet is successfully processed; see Section 13.4. Stateless Reset Oracle ````````````````````````````````````````````````````` Stateless resets create a possible denial-of-service attack analogous to a TCP reset injection. This attack is possible if an attacker is able to cause a stateless reset token to be generated for a connection with a selected connection ID. An attacker that can cause this token to be generated can reset an active connection with the same connection ID. If a packet can be routed to different instances that share a static key -- for example, by changing an IP address or port -- then an attacker can cause the server to send a stateless reset. To defend against this style of denial of service, endpoints that share a static key for stateless resets (see Section 10.3.2) MUST be arranged so that packets with a given connection ID always arrive at an instance that has connection state, unless that connection is no longer active. More generally, servers MUST NOT generate a stateless reset if a connection with the corresponding connection ID could be active on any endpoint using the same static key. In the case of a cluster that uses dynamic load balancing, it is possible that a change in load-balancer configuration could occur while an active instance retains connection state. Even if an instance retains connection state, the change in routing and resulting stateless reset will result in the connection being terminated. If there is no chance of the packet being routed to the correct instance, it is better to send a stateless reset than wait for the connection to time out. However, this is acceptable only if the routing cannot be influenced by an attacker. Version Downgrade ````````````````````````````````````````````````````` This document defines QUIC Version Negotiation packets (Section 6), which can be used to negotiate the QUIC version used between two endpoints. However, this document does not specify how this negotiation will be performed between this version and subsequent future versions. In particular, Version Negotiation packets do not contain any mechanism to prevent version downgrade attacks. Future versions of QUIC that use Version Negotiation packets MUST define a mechanism that is robust against version downgrade attacks. Targeted Attacks by Routing ````````````````````````````````````````````````````` Deployments should limit the ability of an attacker to target a new connection to a particular server instance. Ideally, routing decisions are made independently of client-selected values, including addresses. Once an instance is selected, a connection ID can be selected so that later packets are routed to the same instance. Traffic Analysis ````````````````````````````````````````````````````` The length of QUIC packets can reveal information about the length of the content of those packets. The PADDING frame is provided so that endpoints have some ability to obscure the length of packet content; see Section 19.1. Defeating traffic analysis is challenging and the subject of active research. Length is not the only way that information might leak. Endpoints might also reveal sensitive information through other side channels, such as the timing of packets. Design Overview ==================== Summary -------- We rely on several existing protocols, both within I2P and outside standards, for inspiration, guidance, and code reuse: * Threat models: From NTCP2 [NTCP2]_, with significant additional threats relevant to UDP transport as analyzed by QUIC [RFC9000]_ [RFC9001]_. * Cryptographic choices: From [NTCP2]_. * Handshake: Noise XK from [NTCP2]_ and [NOISE]_. Significant simplifications to NTCP2 are possible due to the encapsulation (inherent message boundaries) provided by UDP. * Handshake ephemeral key obfuscation: Adapted from [NTCP2]_ * Packet headers: Adapted from WireGuard [WireGuard]_ and QUIC [RFC9000]_ [RFC9001]_. * Packet header obfuscation: Adapted from [NTCP2]_ * Packet header protection: Adapted from QUIC [RFC9001]_ and [NAN]_ * Headers used as AEAD associated data as in [ECIES]_. * Packet numbering: Adapted from WireGuard [WireGuard]_ and QUIC [RFC9000]_ [RFC9001]_. * Messages: Adapted from [SSU]_ * Block format: From [NTCP2]_ and [ECIES]_. * Padding and options: From [NTCP2]_ and [ECIES]_. * Flow control, acks, nacks: TBD Noise Protocol Framework ------------------------- This proposal provides the requirements based on the Noise Protocol Framework [NOISE]_ (Revision 33, 2017-10-04). Noise has similar properties to the Station-To-Station protocol [STS]_, which is the basis for the [SSU]_ protocol. In Noise parlance, Alice is the initiator, and Bob is the responder. SSU2 is based on the Noise protocol Noise_XK_25519_ChaChaPoly_SHA256. (The actual identifier for the initial key derivation function is "Noise_XKaesobfse+hs2+hs3_25519_ChaChaPoly_SHA256" to indicate I2P extensions - see KDF 1 section below) This Noise protocol uses the following primitives: - Handshake Pattern: XK Alice transmits her key to Bob (X) Alice knows Bob's static key already (K) - DH Function: X25519 X25519 DH with a key length of 32 bytes as specified in [RFC-7748]_. - Cipher Function: ChaChaPoly AEAD_CHACHA20_POLY1305 as specified in [RFC-7539]_ section 2.8. 12 byte nonce, with the first 4 bytes set to zero. - Hash Function: SHA256 Standard 32-byte hash, already used extensively in I2P. Additions to the Framework ------------------------------- This proposal defines the following enhancements to Noise_XK_25519_ChaChaPoly_SHA256. These generally follow the guidelines in [NOISE]_ section 13. 1) Cleartext ephemeral keys are obfuscated with AES encryption using a known key and IV. This is quicker than elligator2. New Cryptographic Primitives for I2P --------------------------------------- None? Investigate other hash functions to replace SHA256. Processing overhead estimate ----------------------------------- TBD Messages ======== Each UDP datagram contains exactly one message. The length of the datagram (after the IP header) is the length of the message. Padding, if any, is contained in a padding block inside the message. All SSU2 messages are less than or equal to TBD bytes in length. The message format is based on Noise messages, with modifications for framing and indistinguishability. Implementations using standard Noise libraries may need to pre-process received messages to/from the Noise message format. All encrypted fields are AEAD ciphertexts. The following messages are defined: ==== ================ ===== Type Message Notes ==== ================ ===== 0 SessionRequest 1 SessionCreated 2 SessionConfirmed 3 RelayRequest TBD may be a block 4 RelayResponse TBD may be a block 5 RelayIntro TBD may be a block 6 Data 7 PeerTest TBD may be a block 8 SessionDestroyed TBD may be a block 9 Retry n/a HolePunch ==== ================ ===== The standard establishment sequence is as follows: .. raw:: html {% highlight %} Alice Bob SessionRequest -------------------> <------------------- SessionCreated SessionConfirmed -----------------> {% endhighlight %} When address verification is used, the establishment sequence is as follows: .. raw:: html {% highlight %} Alice Bob SessionRequest -------------------> <--------------------------- Retry SessionRequest -------------------> <------------------- SessionCreated SessionConfirmed -----------------> {% endhighlight %} Using Noise terminology, the establishment and data sequence is as follows: (Payload Security Properties) .. raw:: html {% highlight lang='text' %} XK(s, rs): Authentication Confidentiality <- s ... -> e, es 0 2 <- e, ee 2 1 -> s, se 2 5 <- 2 5 {% endhighlight %} Once a session has been established, Alice and Bob can exchange Data messages. All message types (SessionRequest, SessionCreated, SessionConfirmed, Data and TimeSync) are specified in this section. Some notations:: - RH_A = Router Hash for Alice (32 bytes) - RH_B = Router Hash for Bob (32 bytes) Packet Header --------------- All packets start with an obfuscated header. There are two header types, long and short. Long Header ````````````` The long header is 32 bytes. It is used before a session is created, for SessionRequest, SessionCreated, and Retry. Before header obfuscation and protection: .. raw:: html {% highlight lang='dataspec' %} +----+----+----+----+----+----+----+----+ | Destination Connection ID | +----+----+----+----+----+----+----+----+ | id | ver|type|flag| Packet Number | +----+----+----+----+----+----+----+----+ | Source Connection ID | +----+----+----+----+----+----+----+----+ | Retry Token | +----+----+----+----+----+----+----+----+ Destination Connection ID :: 8 bytes, unsigned big endian integer id :: 1 byte, the network ID (currently 2, except for test networks) ver :: The protocol version, equal to 2 type :: The message type, 0-10 flag :: 1 byte, unused, set to 0 for future compatibility Packet Number :: 4 bytes, unsigned big endian integer Source Connection ID :: 8 bytes, unsigned big endian integer Retry Token :: 8 bytes, unsigned big endian integer {% endhighlight %} Short Header ````````````` The short header is 13 bytes. It is used after a session is created, for Data messages. or (maybe?) for unauthenticated messages. Before header obfuscation and protection: .. raw:: html {% highlight lang='dataspec' %} +----+----+----+----+----+----+----+----+ | Destination Connection ID | +----+----+----+----+----+----+----+----+ |type| Packet Number | +----+----+----+----+----+ Destination Connection ID :: 8 bytes, unsigned big endian integer type :: The message type, 0-10 Packet Number :: 4 bytes, unsigned big endian integer {% endhighlight %} Header Binding ```````````````` The header (before obfuscation and protection) is always the associated data for the AEAD function, to cryptographically bind the header to the data. Header Obfuscation ``````````````````` Both the long and short headers are always obfuscated with AES-CBC using (generally) the destination router hash and IV. For SessionCreated, where the destination router hash and IV are not yet known, the source router hash and IV are used. Header Protection ``````````````````` In addition to obfuscation, bytes 8-15 of the long header and bytes 8-12 of the short header are encrypted by XORing with a known key, as in QUIC [RFC9001]_ and [NAN]_. For SessionCreated, where the destination router hash and IV are not yet known, the source router hash and IV are used. Authenticated Encryption ------------------------ There are three separate authenticated encryption instances (CipherStates). One during the handshake phase, and two (transmit and receive) for the data phase. Each has its own key from a KDF. Encrypted/authenticated data will be represented as .. raw:: html {% highlight lang='dataspec' %} +----+----+----+----+----+----+----+----+ | | + + | Encrypted and authenticated data | ~ . . . ~ | | +----+----+----+----+----+----+----+----+ {% endhighlight %} ChaCha20/Poly1305 ````````````````` Encrypted and authenticated data format. Inputs to the encryption/decryption functions: .. raw:: html {% highlight lang='dataspec' %} k :: 32 byte cipher key, as generated from KDF nonce :: Counter-based nonce, 12 bytes. Starts at 0 and incremented for each message. First four bytes are always zero. Last eight bytes are the counter, little-endian encoded. Maximum value is 2**64 - 2. Connection must be dropped and restarted after it reaches that value. The value 2**64 - 1 must never be sent. ad :: In handshake phase: Associated data, 32 bytes. The SHA256 hash of all preceding data. In data phase: Zero bytes data :: Plaintext data, 0 or more bytes {% endhighlight %} Output of the encryption function, input to the decryption function: .. raw:: html {% highlight lang='dataspec' %} +----+----+----+----+----+----+----+----+ | | + + | ChaCha20 encrypted data | ~ . . . ~ | | +----+----+----+----+----+----+----+----+ | Poly1305 Message Authentication Code | + (MAC) + | 16 bytes | +----+----+----+----+----+----+----+----+ encrypted data :: Same size as plaintext data, 0 - 65519 bytes MAC :: Poly1305 message authentication code, 16 bytes {% endhighlight %} For ChaCha20, what is described here corresponds to [RFC-7539]_, which is also used similarly in TLS [RFC-7905]_. Notes ````` - Since ChaCha20 is a stream cipher, plaintexts need not be padded. Additional keystream bytes are discarded. - The key for the cipher (256 bits) is agreed upon by means of the SHA256 KDF. The details of the KDF for each message are in separate sections below. AEAD Error Handling ``````````````````` - In all messages, the AEAD message size is known in advance. On an AEAD authentication failure, recipient must halt further message processing and close the connection without responding. This should be an abnormal close (TCP RST). - For probing resistance, in Session Request, after an AEAD failure, Bob should set a random timeout (range TBD) and then read a random number of bytes (range TBD) before closing the socket. Bob should maintain a blacklist of IPs with repeated failures. Key Derivation Function (KDF) (for Session Request) ------------------------------------------------------- The KDF generates a handshake phase cipher key k from the DH result, using HMAC-SHA256(key, data) as defined in [RFC-2104]_. These are the InitializeSymmetric(), MixHash(), and MixKey() functions, exactly as defined in the Noise spec. .. raw:: html {% highlight lang='text' %} This is the "e" message pattern: // Define protocol_name. Set protocol_name = "Noise_XKaesobfse+hs2+hs3_25519_ChaChaPoly_SHA256" (48 bytes, US-ASCII encoded, no NULL termination). // Define Hash h = 32 bytes h = SHA256(protocol_name); Define ck = 32 byte chaining key. Copy the h data to ck. Set ck = h Define rs = Bob's 32-byte static key as published in the RouterInfo // MixHash(null prologue) h = SHA256(h); // up until here, can all be precalculated by Alice for all outgoing connections // Alice must validate that Bob's static key is a valid point on the curve here. // Bob static key // MixHash(rs) // || below means append h = SHA256(h || rs); // up until here, can all be precalculated by Bob for all incoming connections This is the "e" message pattern: Alice generates her ephemeral DH key pair e. // Alice ephemeral key X // MixHash(e.pubkey) // || below means append h = SHA256(h || e.pubkey); // h is used as the associated data for the AEAD in Session Request // Retain the Hash h for the Session Created KDF End of "e" message pattern. This is the "es" message pattern: // DH(e, rs) == DH(s, re) Define input_key_material = 32 byte DH result of Alice's ephemeral key and Bob's static key Set input_key_material = X25519 DH result // MixKey(DH()) Define temp_key = 32 bytes Define HMAC-SHA256(key, data) as in [RFC-2104]_ // Generate a temp key from the chaining key and DH result // ck is the chaining key, defined above temp_key = HMAC-SHA256(ck, input_key_material) // overwrite the DH result in memory, no longer needed input_key_material = (all zeros) // Output 1 // Set a new chaining key from the temp key // byte() below means a single byte ck = HMAC-SHA256(temp_key, byte(0x01)). // Output 2 // Generate the cipher key k Define k = 32 bytes // || below means append // byte() below means a single byte k = HMAC-SHA256(temp_key, ck || byte(0x02)). // overwrite the temp_key in memory, no longer needed temp_key = (all zeros) // retain the chaining key ck for Session Created KDF End of "es" message pattern. {% endhighlight %} 1) SessionRequest ------------------ Alice sends to Bob. Long header. Noise content: Alice's ephemeral key X Noise payload: datetime and padding blocks (Payload Security Properties) .. raw:: html {% highlight lang='text' %} XK(s, rs): Authentication Confidentiality -> e, es 0 2 Authentication: None (0). This payload may have been sent by any party, including an active attacker. Confidentiality: 2. Encryption to a known recipient, forward secrecy for sender compromise only, vulnerable to replay. This payload is encrypted based only on DHs involving the recipient's static key pair. If the recipient's static private key is compromised, even at a later date, this payload can be decrypted. This message can also be replayed, since there's no ephemeral contribution from the recipient. "e": Alice generates a new ephemeral key pair and stores it in the e variable, writes the ephemeral public key as cleartext into the message buffer, and hashes the public key along with the old h to derive a new h. "es": A DH is performed between the Alice's ephemeral key pair and the Bob's static key pair. The result is hashed along with the old ck to derive a new ck and k, and n is set to zero. {% endhighlight %} The X value is encrypted to ensure payload indistinguishably and uniqueness, which are necessary DPI countermeasures. We use AES encryption to achieve this, rather than more complex and slower alternatives such as elligator2. Asymmetric encryption to Bob's router public key would be far too slow. AES encryption uses Bob's router hash as the key and Bob's IV as published in the network database. AES encryption is for DPI resistance only. Any party knowing Bob's router hash, and IV, which are published in the network database, may decrypt the X value in this message. Raw contents: .. raw:: html {% highlight lang='dataspec' %} +----+----+----+----+----+----+----+----+ | | + obfuscated with RH_B + | AES-CBC-256 encrypted | + bytes 8-15 header protected + | Long Header | + (32 bytes) + | | +----+----+----+----+----+----+----+----+ | | + obfuscated with RH_B + | AES-CBC-256 encrypted X | + (32 bytes) + | | + + | | +----+----+----+----+----+----+----+----+ | | + + | ChaCha20 encrypted data | + (length varies) + | k defined in KDF for Session Request | + n = 0 + | see KDF for associated data | +----+----+----+----+----+----+----+----+ | | + Poly1305 MAC (16 bytes) + | | +----+----+----+----+----+----+----+----+ X :: 32 bytes, AES-256-CBC encrypted X25519 ephemeral key, little endian key: RH_B iv: As published in Bobs network database entry {% endhighlight %} Unencrypted data (Poly1305 authentication tag not shown): .. raw:: html {% highlight lang='dataspec' %} +----+----+----+----+----+----+----+----+ | Destination Connection ID | +----+----+----+----+----+----+----+----+ | id | ver|type|flag| Packet Number | +----+----+----+----+----+----+----+----+ | Source Connection ID | +----+----+----+----+----+----+----+----+ | Retry Token | +----+----+----+----+----+----+----+----+ | | + + | X | + (32 bytes) + | | + + | | +----+----+----+----+----+----+----+----+ | Noise payload (block data) | + (length varies) + | | +----+----+----+----+----+----+----+----+ Destination Connection ID :: Randomly generated by Alice id :: 1 byte, the network ID (currently 2, except for test networks) ver :: 2 type :: 0 flag :: 1 byte, unused, set to 0 for future compatibility Packet Number :: 0 unless retransmitted or resent after Retry Source Connection ID :: Randomly generated by Alice Retry Token :: 0 if not previously received from Bob X :: 32 bytes, X25519 ephemeral key, little endian options :: options block, 16 bytes, see below {% endhighlight %} Options block: Note: All fields are big-endian. .. raw:: html {% highlight lang='dataspec' %} +----+----+----+----+----+----+----+----+ | id | ver| padLen | m3p2len | Rsvd(0) | +----+----+----+----+----+----+----+----+ | tsA | Reserved (0) | +----+----+----+----+----+----+----+----+ id :: 1 byte, the network ID (currently 2, except for test networks) As of 0.9.42. See proposal 147. ver :: 1 byte, protocol version (currently 2) padLen :: 2 bytes, length of the padding, 0 or more Min/max guidelines TBD. Random size from 0 to 31 bytes minimum? (Distribution to be determined, see Appendix A.) m3p2Len :: 2 bytes, length of the the second AEAD frame in SessionConfirmed See notes below Rsvd :: 2 bytes, set to 0 for compatibility with future options tsA :: 4 bytes, Unix timestamp, unsigned seconds. Wraps around in 2106 Reserved :: 4 bytes, set to 0 for compatibility with future options {% endhighlight %} Notes ````` - When the published address is "NTCP", Bob supports both NTCP and SSU2 on the same port. For compatibility, when initiating a connection to an address published as "NTCP", Alice must limit the maximum size of this message, including padding, to 287 bytes or less. This facilitates automatic protocol identification by Bob. When published as "SSU2", there is no size restriction. See the Published Addresses and Version Detection sections below. - The unique X value in the initial AES block ensure that the ciphertext is different for every session. - Bob must reject connections where the timestamp value is too far off from the current time. Call the maximum delta time "D". Bob must maintain a local cache of previously-used handshake values and reject duplicates, to prevent replay attacks. Values in the cache must have a lifetime of at least 2*D. The cache values are implementation-dependent, however the 32-byte X value (or its encrypted equivalent) may be used. - Diffie-Hellman ephemeral keys may never be reused, to prevent cryptographic attacks, and reuse will be rejected as a replay attack. - The "KE" and "auth" options must be compatible, i.e. the shared secret K must be of the appropriate size. If more "auth" options are added, this could implicitly change the meaning of the "KE" flag to use a different KDF or a different truncation size. - Bob must validate that Alice's ephemeral key is a valid point on the curve here. - Padding should be limited to a reasonable amount. Bob may reject connections with excessive padding. Bob will specify his padding options in Session Created. Min/max guidelines TBD. Random size from 0 to 31 bytes minimum? (Distribution to be determined, see Appendix A.) - On any error, including AEAD, DH, timestamp, apparent replay, or key validation failure, Bob must halt further message processing and close the connection without responding. This should be an abnormal close (TCP RST). For probing resistance, after an AEAD failure, Bob should set a random timeout (range TBD) and then read a random number of bytes (range TBD), before closing the socket. - DoS Mitigation: DH is a relatively expensive operation. As with the previous NTCP protocol, routers should take all necessary measures to prevent CPU or connection exhaustion. Place limits on maximum active connections and maximum connection setups in progress. Enforce read timeouts (both per-read and total for "slowloris"). Limit repeated or simultaneous connections from the same source. Maintain blacklists for sources that repeatedly fail. Do not respond to AEAD failure. - To facilitate rapid version detection and handshaking, implementations must ensure that Alice buffers and then flushes the entire contents of the first message at once, including the padding. This increases the likelihood that the data will be contained in a single TCP packet (unless segmented by the OS or middleboxes), and received all at once by Bob. Additionally, implementations must ensure that Bob buffers and then flushes the entire contents of the second message at once, including the padding. and that Bob buffers and then flushes the entire contents of the third message at once. This is also for efficiency and to ensure the effectiveness of the random padding. - "ver" field: The overall Noise protocol, extensions, and SSU2 protocol including payload specifications, indicating SSU2. This field may be used to indicate support for future changes. - Bob must fail the connection if any incoming data remains after validating Session Request and reading in the padding. There should be no extra data from Alice, as Bob has not responded with Session Created yet. - The network ID field is used to quickly identify cross-network connections. If this field is nonzero, and does not match Bob's network ID, Bob should disconnect and block future connections. Key Derivation Function (KDF) (for Session Created and Session Confirmed part 1) ---------------------------------------------------------------------------------- .. raw:: html {% highlight lang='text' %} // take h saved from Session Request KDF // MixHash(ciphertext) h = SHA256(h || 32 byte encrypted payload from Session Request) // MixHash(padding) // Only if padding length is nonzero h = SHA256(h || random padding from Session Request) This is the "e" message pattern: Bob generates his ephemeral DH key pair e. // h is from KDF for Session Request // Bob ephemeral key Y // MixHash(e.pubkey) // || below means append h = SHA256(h || e.pubkey); // h is used as the associated data for the AEAD in Session Created // Retain the Hash h for the Session Confirmed KDF End of "e" message pattern. This is the "ee" message pattern: // DH(e, re) Define input_key_material = 32 byte DH result of Alice's ephemeral key and Bob's ephemeral key Set input_key_material = X25519 DH result // overwrite Alice's ephemeral key in memory, no longer needed // Alice: e(public and private) = (all zeros) // Bob: re = (all zeros) // MixKey(DH()) Define temp_key = 32 bytes Define HMAC-SHA256(key, data) as in [RFC-2104]_ // Generate a temp key from the chaining key and DH result // ck is the chaining key, from the KDF for Session Request temp_key = HMAC-SHA256(ck, input_key_material) // overwrite the DH result in memory, no longer needed input_key_material = (all zeros) // Output 1 // Set a new chaining key from the temp key // byte() below means a single byte ck = HMAC-SHA256(temp_key, byte(0x01)). // Output 2 // Generate the cipher key k Define k = 32 bytes // || below means append // byte() below means a single byte k = HMAC-SHA256(temp_key, ck || byte(0x02)). // overwrite the temp_key in memory, no longer needed temp_key = (all zeros) // retain the chaining key ck for Session Confirmed KDF End of "ee" message pattern. {% endhighlight %} 2) SessionCreated ------------------ Bob sends to Alice. Noise content: Bob's ephemeral key Y Noise payload: datetime, options, and padding blocks (Payload Security Properties) .. raw:: html {% highlight lang='text' %} XK(s, rs): Authentication Confidentiality <- e, ee 2 1 Authentication: 2. Sender authentication resistant to key-compromise impersonation (KCI). The sender authentication is based on an ephemeral-static DH ("es" or "se") between the sender's static key pair and the recipient's ephemeral key pair. Assuming the corresponding private keys are secure, this authentication cannot be forged. Confidentiality: 1. Encryption to an ephemeral recipient. This payload has forward secrecy, since encryption involves an ephemeral-ephemeral DH ("ee"). However, the sender has not authenticated the recipient, so this payload might be sent to any party, including an active attacker. "e": Bob generates a new ephemeral key pair and stores it in the e variable, writes the ephemeral public key as cleartext into the message buffer, and hashes the public key along with the old h to derive a new h. "ee": A DH is performed between the Bob's ephemeral key pair and the Alice's ephemeral key pair. The result is hashed along with the old ck to derive a new ck and k, and n is set to zero. {% endhighlight %} The Y value is encrypted to ensure payload indistinguishably and uniqueness, which are necessary DPI countermeasures. We use AES encryption to achieve this, rather than more complex and slower alternatives such as elligator2. Asymmetric encryption to Alice's router public key would be far too slow. AES encryption uses Bob's router hash as the key and the AES state from Session Request (which was initialized with Bob's IV as published in the network database). AES encryption is for DPI resistance only. Any party knowing Bob's router hash and IV, which are published in the network database, and captured the first 32 bytes of Session Request, may decrypt the Y value in this message. Raw contents: .. raw:: html {% highlight lang='dataspec' %} +----+----+----+----+----+----+----+----+ | | + obfuscated with RH_B + | AES-CBC-256 encrypted | + bytes 8-15 header protected + | Long Header | + (32 bytes) + | | +----+----+----+----+----+----+----+----+ | | + obfuscated with RH_B + | AES-CBC-256 encrypted Y | + (32 bytes) + | | + + | | +----+----+----+----+----+----+----+----+ | ChaCha20 data | + Encrypted and authenticated data + | length varies | + k defined in KDF for Session Created + | n = 0; see KDF for associated data | + + | | +----+----+----+----+----+----+----+----+ | | + Poly1305 MAC (16 bytes) + | | +----+----+----+----+----+----+----+----+ Y :: 32 bytes, AES-256-CBC encrypted X25519 ephemeral key, little endian key: RH_B iv: Using AES state from Session Request {% endhighlight %} Unencrypted data (Poly1305 auth tag not shown): .. raw:: html {% highlight lang='dataspec' %} +----+----+----+----+----+----+----+----+ | Destination Connection ID | +----+----+----+----+----+----+----+----+ | id | ver|type|flag| Packet Number | +----+----+----+----+----+----+----+----+ | Source Connection ID | +----+----+----+----+----+----+----+----+ | Retry Token | +----+----+----+----+----+----+----+----+ | | + + | Y | + (32 bytes) + | | + + | | +----+----+----+----+----+----+----+----+ | Noise payload (block data) | + (length varies) + | | +----+----+----+----+----+----+----+----+ Destination Connection ID :: As sent by Alice id :: 1 byte, the network ID (currently 2, except for test networks) ver :: 2 type :: 0 flag :: 1 byte, unused, set to 0 for future compatibility Packet Number :: 0 unless retransmitted or resent after Retry Source Connection ID :: Randomly generated by Alice Retry Token :: 0 if not previously received from Bob Y :: 32 bytes, X25519 ephemeral key, little endian {% endhighlight %} Notes ````` - Alice must validate that Bob's ephemeral key is a valid point on the curve here. - Padding should be limited to a reasonable amount. Alice may reject connections with excessive padding. Alice will specify her padding options in Session Confirmed. Min/max guidelines TBD. Random size from 0 to 31 bytes minimum? (Distribution to be determined, see Appendix A.) - On any error, including AEAD, DH, timestamp, apparent replay, or key validation failure, Alice must halt further message processing and close the connection without responding. - Alice must fail the connection if any incoming data remains after validating Session Created and reading in the padding. There should be no extra data from Bob, as Alice has not responded with Session Confirmed yet. - Alice must reject connections where the timestamp value is too far off from the current time. Call the maximum delta time "D". Alice must maintain a local cache of previously-used handshake values and reject duplicates, to prevent replay attacks. Values in the cache must have a lifetime of at least 2*D. The cache values are implementation-dependent, however the 32-byte Y value (or its encrypted equivalent) may be used. Issues `````` - Include min/max padding options here? Encryption for for Session Confirmed part 1, using Session Created KDF) --------------------------------------------------------------------------- .. raw:: html {% highlight lang='text' %} // take h saved from Session Created KDF // MixHash(ciphertext) h = SHA256(h || 24 byte encrypted payload from Session Created) // MixHash(padding) // Only if padding length is nonzero h = SHA256(h || random padding from Session Created) // h is used as the associated data for the AEAD in Session Confirmed part 1, below This is the "s" message pattern: Define s = Alice's static public key, 32 bytes // EncryptAndHash(s.publickey) // EncryptWithAd(h, s.publickey) // AEAD_ChaCha20_Poly1305(key, nonce, associatedData, data) // k is from Session Request // n is 1 ciphertext = AEAD_ChaCha20_Poly1305(k, n++, h, s.publickey) // MixHash(ciphertext) // || below means append h = SHA256(h || ciphertext); // h is used as the associated data for the AEAD in Session Confirmed part 2 End of "s" message pattern. {% endhighlight %} Key Derivation Function (KDF) (for Session Confirmed part 2) -------------------------------------------------------------- .. raw:: html {% highlight lang='text' %} This is the "se" message pattern: // DH(s, re) == DH(e, rs) Define input_key_material = 32 byte DH result of Alice's static key and Bob's ephemeral key Set input_key_material = X25519 DH result // overwrite Bob's ephemeral key in memory, no longer needed // Alice: re = (all zeros) // Bob: e(public and private) = (all zeros) // MixKey(DH()) Define temp_key = 32 bytes Define HMAC-SHA256(key, data) as in [RFC-2104]_ // Generate a temp key from the chaining key and DH result // ck is the chaining key, from the KDF for Session Request temp_key = HMAC-SHA256(ck, input_key_material) // overwrite the DH result in memory, no longer needed input_key_material = (all zeros) // Output 1 // Set a new chaining key from the temp key // byte() below means a single byte ck = HMAC-SHA256(temp_key, byte(0x01)). // Output 2 // Generate the cipher key k Define k = 32 bytes // || below means append // byte() below means a single byte k = HMAC-SHA256(temp_key, ck || byte(0x02)). // h from Session Confirmed part 1 is used as the associated data for the AEAD in Session Confirmed part 2 // EncryptAndHash(payload) // EncryptWithAd(h, payload) // AEAD_ChaCha20_Poly1305(key, nonce, associatedData, data) // n is 0 ciphertext = AEAD_ChaCha20_Poly1305(k, n++, h, payload) // MixHash(ciphertext) // || below means append h = SHA256(h || ciphertext); // retain the chaining key ck for the data phase KDF // retain the hash h for the data phase Additional Symmetric Key (SipHash) KDF End of "se" message pattern. // overwrite the temp_key in memory, no longer needed temp_key = (all zeros) {% endhighlight %} 3) SessionConfirmed -------------------- Alice sends to Bob. Noise content: Alice's static key Noise payload: Alice's RouterInfo, options, data, and padding blocks (Payload Security Properties) .. raw:: html {% highlight lang='text' %} XK(s, rs): Authentication Confidentiality -> s, se 2 5 Authentication: 2. Sender authentication resistant to key-compromise impersonation (KCI). The sender authentication is based on an ephemeral-static DH ("es" or "se") between the sender's static key pair and the recipient's ephemeral key pair. Assuming the corresponding private keys are secure, this authentication cannot be forged. Confidentiality: 5. Encryption to a known recipient, strong forward secrecy. This payload is encrypted based on an ephemeral-ephemeral DH as well as an ephemeral-static DH with the recipient's static key pair. Assuming the ephemeral private keys are secure, and the recipient is not being actively impersonated by an attacker that has stolen its static private key, this payload cannot be decrypted. "s": Alice writes her static public key from the s variable into the message buffer, encrypting it, and hashes the output along with the old h to derive a new h. "se": A DH is performed between the Alice's static key pair and the Bob's ephemeral key pair. The result is hashed along with the old ck to derive a new ck and k, and n is set to zero. {% endhighlight %} This contains two ChaChaPoly frames. The first is Alice's encrypted static public key. The second is the Noise payload: Alice's encrypted RouterInfo, optional options, and optional padding. They use different keys, because the MixKey() function is called in between. Raw contents: .. raw:: html {% highlight lang='dataspec' %} +----+----+----+----+----+----+----+----+ | | + ChaChaPoly frame (48 bytes) + | Encrypted and authenticated | + Alice static key S + | (32 bytes) | + + | k defined in KDF for Session Created | + n = 1 + | see KDF for associated data | + + | | +----+----+----+----+----+----+----+----+ | | + Length varies (remainder of packet) + | | + ChaChaPoly frame + | Encrypted and authenticated | + + | Alice RouterInfo | + using block format 2 + | Alice Options (optional) | + using block format 1 + | Arbitrary padding | + using block format 254 + | | + + | k defined in KDF for | + Session Confirmed part 2 + | n = 0 | + see KDF for associated data + ~ . . . ~ | | +----+----+----+----+----+----+----+----+ S :: 32 bytes, ChaChaPoly encrypted Alice's X25519 static key, little endian inside 48 byte ChaChaPoly frame {% endhighlight %} Unencrypted data (Poly1305 auth tags not shown): .. raw:: html {% highlight lang='dataspec' %} +----+----+----+----+----+----+----+----+ | | + + | S | + Alice static key + | (32 bytes) | + + | | + + +----+----+----+----+----+----+----+----+ | | + + | | + + | Alice RouterInfo block | ~ . . . ~ | | +----+----+----+----+----+----+----+----+ | | + Optional Options block + | | ~ . . . ~ | | +----+----+----+----+----+----+----+----+ | | + Optional I2NP blocks + | | ~ . . . ~ | | +----+----+----+----+----+----+----+----+ | | + Optional Padding block + | | ~ . . . ~ | | +----+----+----+----+----+----+----+----+ S :: 32 bytes, Alice's X25519 static key, little endian {% endhighlight %} Notes ````` - Bob must perform the usual Router Info validation. Ensure the signature type is supported, verify the signature, verify the timestamp is within bounds, and any other checks necessary. - Bob must verify that Alice's static key received in the first frame matches the static key in the Router Info. Bob must first search the Router Info for a NTCP or SSU2 Router Address with a matching version (v) option. See Published Router Info and Unpublished Router Info sections below. - If Bob has an older version of Alice's RouterInfo in his netdb, verify that the static key in the router info is the same in both, if present, and if the older version is less than XXX old (see key rotate time below) - Bob must validate that Alice's static key is a valid point on the curve here. - Options should be included, to specify padding parameters. - On any error, including AEAD, RI, DH, timestamp, or key validation failure, Bob must halt further message processing and close the connection without responding. - Message 3 part 2 frame content: This format of this frame is the same as the format of data phase frames, except that the length of the frame is sent by Alice in Session Request. See below for the data phase frame format. The frame must contain 1 to 4 blocks in the following order: 1) Alice's Router Info block (required) 2) Options block (optional) 3) I2NP blocks (optional) 4) Padding block (optional) This frame must never contain any other block type. - Message 3 part 2 padding may not be required if Alice includes one or more I2NP blocks in the Session Confirmed. As Alice will generally, but not always, have an I2NP message to send to Bob (that's why she connected to him), this is the recommended implementation, for efficiency and to ensure the effectiveness of the random padding. - Total length of both Message 3 AEAD frames (parts 1 and 2) is 65535 bytes; part 1 is 48 bytes so part 2 max frame length is 65487; part 2 max plaintext length excluding MAC is 65471. Key Derivation Function (KDF) (for data phase) ---------------------------------------------- The data phase uses a zero-length associated data input. The KDF generates two cipher keys k_ab and k_ba from the chaining key ck, using HMAC-SHA256(key, data) as defined in [RFC-2104]_. This is the Split() function, exactly as defined in the Noise spec. .. raw:: html {% highlight lang='text' %} ck = from handshake phase // k_ab, k_ba = HKDF(ck, zerolen) // ask_master = HKDF(ck, zerolen, info="ask") // zerolen is a zero-length byte array temp_key = HMAC-SHA256(ck, zerolen) // overwrite the chaining key in memory, no longer needed ck = (all zeros) // Output 1 // cipher key, for Alice transmits to Bob (Noise doesn't make clear which is which, but Java code does) k_ab = HMAC-SHA256(temp_key, byte(0x01)). // Output 2 // cipher key, for Bob transmits to Alice (Noise doesn't make clear which is which, but Java code does) k_ba = HMAC-SHA256(temp_key, k_ab || byte(0x02)). {% endhighlight %} 3-5) Relay Messages -------------------- TBD, only required if these must be sent outside of an existing session. 6) Data Message ---------------- Noise payload: All block types are allowed Starting with the 2nd part of Session Confirmed, all messages are inside an authenticated and encrypted ChaChaPoly payload. with a prepended two-byte obfuscated length. All padding is inside the frame. Inside the payload is a standard format with zero or more "blocks". Each block has a one-byte type and a two-byte length. Types include date/time, I2NP message, options, termination, and padding. Note: Bob may, but is not required, to send his RouterInfo to Alice as his first message to Alice in the data phase. (Payload Security Properties) .. raw:: html {% highlight lang='text' %} XK(s, rs): Authentication Confidentiality <- 2 5 -> 2 5 Authentication: 2. Sender authentication resistant to key-compromise impersonation (KCI). The sender authentication is based on an ephemeral-static DH ("es" or "se") between the sender's static key pair and the recipient's ephemeral key pair. Assuming the corresponding private keys are secure, this authentication cannot be forged. Confidentiality: 5. Encryption to a known recipient, strong forward secrecy. This payload is encrypted based on an ephemeral-ephemeral DH as well as an ephemeral-static DH with the recipient's static key pair. Assuming the ephemeral private keys are secure, and the recipient is not being actively impersonated by an attacker that has stolen its static private key, this payload cannot be decrypted. {% endhighlight %} Notes ````` - For efficiency and to minimize identification of the length field, implementations must ensure that the sender buffers and then flushes the entire contents of data messages at once, including the length field and the AEAD payload. This increases the likelihood that the data will be contained in a single TCP packet (unless segmented by the OS or middleboxes), and received all at once the other party. This is also for efficiency and to ensure the effectiveness of the random padding. - The router may choose to terminate the session on AEAD error, or may continue to attempt communications. If continuing, the router should terminate after repeated errors. .. raw:: html {% highlight lang='dataspec' %} +----+----+----+----+----+----+----+----+ |Short Header obfuscated with dest hash | +encrypted, bytes 8-12 +----+----+----+ | header protected | | +----+----+----+----+----+ + | ChaCha20 data | + Encrypted and authenticated data + | length varies | +k defined in KDF for Session Confirmed + | n = from heder | + + | | +----+----+----+----+----+----+----+----+ | | + Poly1305 MAC (16 bytes) + | | +----+----+----+----+----+----+----+----+ {% endhighlight %} Unencrypted data (Poly1305 auth tag not shown): .. raw:: html {% highlight lang='dataspec' %} +----+----+----+----+----+----+----+----+ | Destination Connection ID | +----+----+----+----+----+----+----+----+ |type| Packet Number | | +----+----+----+----+----+ + | Noise payload (block data) | + (length varies) + | | +----+----+----+----+----+----+----+----+ Destination Connection ID :: As specified in session setup type :: 6 Packet Number :: 4 byte big endian integer {% endhighlight %} Notes ````` 7) Peer Test Message ------------------------ TBD, only required if these must be sent outside of an existing session. 8) Session Destroyed Message ------------------------------- TBD, only required if these must be sent outside of an existing session. 9) Retry Message ------------------------------- TODO encrypted? to what key? Noise payload: Only padding block Raw contents: .. raw:: html {% highlight lang='dataspec' %} +----+----+----+----+----+----+----+----+ | | + obfuscated with RH_B + | AES-CBC-256 encrypted | + bytes 8-15 header protected + | Long Header | + (32 bytes) + | | +----+----+----+----+----+----+----+----+ | | + + | ChaCha20 encrypted data | + (length varies) + | k defined in KDF for Session Request | + n = 0 + | see KDF for associated data | +----+----+----+----+----+----+----+----+ | | + Poly1305 MAC (16 bytes) + | | +----+----+----+----+----+----+----+----+ {% endhighlight %} Unencrypted data (Poly1305 authentication tag not shown): .. raw:: html {% highlight lang='dataspec' %} +----+----+----+----+----+----+----+----+ | Destination Connection ID | +----+----+----+----+----+----+----+----+ | id | ver|type|flag| Packet Number | +----+----+----+----+----+----+----+----+ | Source Connection ID | +----+----+----+----+----+----+----+----+ | Retry Token | +----+----+----+----+----+----+----+----+ | Noise payload (block data) | + (length varies) + | | +----+----+----+----+----+----+----+----+ Destination Connection ID :: Randomly generated by Alice id :: 1 byte, the network ID (currently 2, except for test networks) ver :: 2 type :: 0 flag :: 1 byte, unused, set to 0 for future compatibility Packet Number :: 0 unless retransmitted or resent after Retry Source Connection ID :: Randomly generated by Alice Retry Token :: 8 byte unsigned integer options :: options block, 16 bytes, see below {% endhighlight %} Hole Punch Message ------------------------------- An empty datagram. No content. Same as SSU 1. Noise Payload =============== All noise sections contain zero or more "blocks". This uses the same block format as defined in the [NTCP2]_ and [ECIES]_ specifications. Individual block types are defined differently. There are concerns that encouraging implementers to share code may lead to parsing issues. Implementers should carefully consider the benefits and risks of sharing code, and ensure that the ordering and valid block rules are different for the two contexts. Payload Format ---------------- There are zero or more blocks in the encrypted payload. Each block contains a one-byte identifier, a two-byte length, and zero or more bytes of data. For extensibility, receivers must ignore blocks with unknown identifiers, and treat them as padding. Encrypted data is 65535 bytes max, including a 16-byte authentication header, so the max unencrypted data is 65519 bytes. (Poly1305 auth tag not shown): .. raw:: html {% highlight lang='dataspec' %} +----+----+----+----+----+----+----+----+ |blk | size | data | +----+----+----+ + | | ~ . . . ~ | | +----+----+----+----+----+----+----+----+ |blk | size | data | +----+----+----+ + | | ~ . . . ~ | | +----+----+----+----+----+----+----+----+ ~ . . . ~ blk :: 1 byte, see below size :: 2 bytes, big endian, size of data to follow, 0 - TBD data :: the data Maximum ChaChaPoly payload is TBD bytes. Poly1305 tag is 16 bytes Maximum total block size is TBD bytes Maximum single block size is TBD bytes Block type is 1 byte Block length is 2 bytes Maximum single block data size is TBD bytes. {% endhighlight %} Block types: ==================================== ============= ============ Payload Block Type Type Number Block Length ==================================== ============= ============ DateTime 0 7 Options (TBD) 1 21+ Router Info 2 varies I2NP Message 3 varies Termination (TBD) 4 9 typ. Relay Request 5 TBD Relay Response 6 TBD Relay Intro 7 TBD Peer Test 8 TBD Next Nonce 9 TBD ACK 10 varies ACK 11 varies reserved for experimental features 255 Padding 254 varies reserved for future extension 255 ==================================== ============= ============ Block Ordering Rules ---------------------- In the Session Confirmed part 2, order must be: RouterInfo, followed by Options if present, followed by Padding if present. No other blocks are allowed. In the data phase, order is unspecified, except for the following requirements: Padding, if present, must be the last block. Termination, if present, must be the last block except for Padding. There may be multiple I2NP blocks in a single payload. Multiple Padding blocks are not allowed in a single payload. Other block types probably won't have multiple blocks in a single payload, but it is not prohibited. Block Specifications ---------------------- DateTime ```````` For time synchronization: .. raw:: html {% highlight lang='dataspec' %} +----+----+----+----+----+----+----+ | 0 | 4 | timestamp | +----+----+----+----+----+----+----+ blk :: 0 size :: 2 bytes, big endian, value = 4 timestamp :: Unix timestamp, unsigned seconds. Wraps around in 2106 {% endhighlight %} Options ``````` Pass updated options. Options include: Min and max padding. Options block will be variable length. .. raw:: html {% highlight lang='dataspec' %} +----+----+----+----+----+----+----+----+ | 1 | size |tmin|tmax|rmin|rmax|tdmy| +----+----+----+----+----+----+----+----+ |tdmy| rdmy | tdelay | rdelay | | ~----+----+----+----+----+----+----+ ~ | more_options | ~ . . . ~ | | +----+----+----+----+----+----+----+----+ blk :: 1 size :: 2 bytes, big endian, size of options to follow, 12 bytes minimum tmin, tmax, rmin, rmax :: requested padding limits tmin and rmin are for desired resistance to traffic analysis. tmax and rmax are for bandwidth limits. tmin and tmax are the transmit limits for the router sending this options block. rmin and rmax are the receive limits for the router sending this options block. Each is a 4.4 fixed-point float representing 0 to 15.9375 (or think of it as an unsigned 8-bit integer divided by 16.0). This is the ratio of padding to data. Examples: Value of 0x00 means no padding Value of 0x01 means add 6 percent padding Value of 0x10 means add 100 percent padding Value of 0x80 means add 800 percent (8x) padding Alice and Bob will negotiate the minimum and maximum in each direction. These are guidelines, there is no enforcement. Sender should honor receiver's maximum. Sender may or may not honor receiver's minimum, within bandwidth constraints. tdmy: Max dummy traffic willing to send, 2 bytes big endian, bytes/sec average rdmy: Requested dummy traffic, 2 bytes big endian, bytes/sec average tdelay: Max intra-message delay willing to insert, 2 bytes big endian, msec average rdelay: Requested intra-message delay, 2 bytes big endian, msec average Padding distribution specified as additional parameters? Random delay specified as additional parameters? more_options :: Format TBD {% endhighlight %} Options Issues `````````````` - Options negotiation is TBD. RouterInfo `````````` Pass Alice's RouterInfo to Bob. Used in Session Confirmed part 2. Pass Alice's RouterInfo to Bob, or Bob's to Alice. Used optionally in the data phase. .. raw:: html {% highlight lang='dataspec' %} +----+----+----+----+----+----+----+----+ | 2 | size |flg | RouterInfo | +----+----+----+----+ + | (Alice RI in handshake msg 3 part 2) | ~ (Alice, Bob, or third-party ~ | RI in data phase) | ~ . . . ~ | | +----+----+----+----+----+----+----+----+ blk :: 2 size :: 2 bytes, big endian, size of flag + router info to follow flg :: 1 byte flags bit order: 76543210 bit 0: 0 for local store, 1 for flood request bits 7-1: Unused, set to 0 for future compatibility routerinfo :: Alice's or Bob's RouterInfo {% endhighlight %} Notes ````` - When used in the data phase, receiver (Alice or Bob) shall validate that it's the same Router Hash as originally sent (for Alice) or sent to (for Bob). Then, treat it as a local I2NP DatabaseStore Message. Validate signature, validate more recent timestamp, and store in the local netdb. If the flag bit 0 is 1, and the receiving party is floodfill, treat it as a DatabaseStore Message with a nonzero reply token, and flood it to the nearest floodfills. - The Router Info is NOT compressed with gzip (unlike in a DatabaseStore Message, where it is) - Flooding must not be requested unless there are published RouterAddresses in the RouterInfo. The receiving router must not flood the RouterInfo unless there are published RouterAddresses in it. - Implementers must ensure that when reading a block, malformed or malicious data will not cause reads to overrun into the next block. - This protocol does not provide an acknowledgement that the RouterInfo was received, stored, or flooded (either in the handshake or data phase). If acknowledgement is desired, and the receiver is floodfill, the sender should instead send a standard I2NP DatabaseStoreMessage with a reply token. Issues `````` - Could also be used in data phase, instead of a I2NP DatabaseStoreMessage. For example, Bob could use it to start off the data phase. - Is it allowed for this to contain the RI for routers other than the originator, as a general replacement for DatabaseStoreMessages, e.g. for flooding by floodfills? I2NP Message ```````````` An single I2NP message with a modified header. I2NP messages may not be fragmented across blocks or across ChaChaPoly payloads. This uses the first 9 bytes from the standard NTCP I2NP header, and removes the last 7 bytes of the header, as follows: truncate the expiration from 8 to 4 bytes, remove the 2 byte length (use the block size - 9), and remove the one-byte SHA256 checksum. .. raw:: html {% highlight lang='dataspec' %} +----+----+----+----+----+----+----+----+ | 3 | size |type| msg id | +----+----+----+----+----+----+----+----+ | short exp | message | +----+----+----+----+ + | | ~ . . . ~ | | +----+----+----+----+----+----+----+----+ blk :: 3 size :: 2 bytes, big endian, size of type + msg id + exp + message to follow I2NP message body size is (size - 9). type :: 1 byte, I2NP msg type, see I2NP spec msg id :: 4 bytes, big endian, I2NP message ID short exp :: 4 bytes, big endian, I2NP message expiration, Unix timestamp, unsigned seconds. Wraps around in 2106 message :: I2NP message body {% endhighlight %} Notes ````` - Implementers must ensure that when reading a block, malformed or malicious data will not cause reads to overrun into the next block. Termination ``````````` Drop the connection. This must be the last non-padding block in the payload. .. raw:: html {% highlight lang='dataspec' %} +----+----+----+----+----+----+----+----+ | 4 | size | valid data packets | +----+----+----+----+----+----+----+----+ received | rsn| addl data | +----+----+----+----+ + ~ . . . ~ +----+----+----+----+----+----+----+----+ blk :: 4 size :: 2 bytes, big endian, value = 9 or more valid data packets received :: The number of valid packets received (current receive nonce value) 0 if error occurs in handshake phase 8 bytes, big endian rsn :: reason, 1 byte: 0: normal close or unspecified 1: termination received 2: idle timeout 3: router shutdown 4: data phase AEAD failure 5: incompatible options 6: incompatible signature type 7: clock skew 8: padding violation 9: AEAD framing error 10: payload format error 11: Session Request error 12: Session Created error 13: Session Confirmed error 14: Timeout 15: RI signature verification fail 16: s parameter missing, invalid, or mismatched in RouterInfo 17: banned addl data :: optional, 0 or more bytes, for future expansion, debugging, or reason text. Format unspecified and may vary based on reason code. {% endhighlight %} Notes ````` Not all reasons may actually be used, implementation dependent. Handshake failures will generally result in a close with TCP RST instead. See notes in handshake message sections above. Additional reasons listed are for consistency, logging, debugging, or if policy changes. RelayRequest `````````````` .. raw:: html {% highlight lang='dataspec' %} +----+----+----+----+----+----+----+----+ | 5 | size | TBD | +----+----+----+ + | | ~ . . . ~ | | +----+----+----+----+----+----+----+----+ blk :: 5 size :: 2 bytes, big endian, size of data to follow {% endhighlight %} RelayResponse `````````````` .. raw:: html {% highlight lang='dataspec' %} +----+----+----+----+----+----+----+----+ | 6 | size | TBD | +----+----+----+ + | | ~ . . . ~ | | +----+----+----+----+----+----+----+----+ blk :: 6 size :: 2 bytes, big endian, size of data to follow {% endhighlight %} RelayIntro `````````````` .. raw:: html {% highlight lang='dataspec' %} +----+----+----+----+----+----+----+----+ | 7 | size | TBD | +----+----+----+ + | | ~ . . . ~ | | +----+----+----+----+----+----+----+----+ blk :: 7 size :: 2 bytes, big endian, size of data to follow {% endhighlight %} PeerTest `````````````` .. raw:: html {% highlight lang='dataspec' %} +----+----+----+----+----+----+----+----+ | 8 | size | TBD | +----+----+----+ + | | ~ . . . ~ | | +----+----+----+----+----+----+----+----+ blk :: 8 size :: 2 bytes, big endian, size of data to follow {% endhighlight %} NextNonce `````````````` .. raw:: html {% highlight lang='dataspec' %} +----+----+----+----+----+----+----+----+ | 9 | size | TBD | +----+----+----+ + | | ~ . . . ~ | | +----+----+----+----+----+----+----+----+ blk :: 9 size :: 2 bytes, big endian, size of data to follow {% endhighlight %} Ack `````````````` .. raw:: html {% highlight lang='dataspec' %} +----+----+----+----+----+----+----+----+ | 10 | size | TBD | +----+----+----+ + | | ~ . . . ~ | | +----+----+----+----+----+----+----+----+ blk :: 10 size :: 2 bytes, big endian, size of data to follow {% endhighlight %} Nack `````````````` .. raw:: html {% highlight lang='dataspec' %} +----+----+----+----+----+----+----+----+ | 11 | size | TBD | +----+----+----+ + | | ~ . . . ~ | | +----+----+----+----+----+----+----+----+ blk :: 11 size :: 2 bytes, big endian, size of data to follow {% endhighlight %} Padding ``````` This is for padding inside AEAD payloads. Padding for all messages are inside AEAD payloads. Padding should roughly adhere to the negotiated parameters. Bob sent his requested tx/rx min/max parameters in Session Created. Alice sent her requested tx/rx min/max parameters in Session Confirmed. Updated options may be sent during the data phase. See options block information above. If present, this must be the last block in the payload. .. raw:: html {% highlight lang='dataspec' %} +----+----+----+----+----+----+----+----+ |254 | size | padding | +----+----+----+ + | | ~ . . . ~ | | +----+----+----+----+----+----+----+----+ blk :: 254 size :: 2 bytes, big endian, size of padding to follow padding :: random data {% endhighlight %} Notes ````` - Padding strategies TBD. - Minimum padding TBD. - Padding-only blocks are allowed. - Padding defaults TBD. - See options block for padding parameter negotiation - See options block for min/max padding parameters - Noise limits messages to 64KB. If more padding is necessary, send multiple messages. - Router response on violation of negotiated padding is implementation-dependent. Other block types ````````````````` Implementations should ignore unknown block types for forward compatibility, except in Session Confirmed part 2, where unknown blocks are not allowed. Future work ``````````` - The padding length is either to be decided on a per-message basis and estimates of the length distribution, or random delays should be added. These countermeasures are to be included to resist DPI, as message sizes would otherwise reveal that I2P traffic is being carried by the transport protocol. The exact padding scheme is an area of future work, Appendix A provides more information on the topic. Session Termination ===================== Message or block? TBD Upon any normal or abnormal termination, routers should zero-out any in-memory ephemeral data, including handshake ephemeral keys, symmetric crypto keys, and related information. Congestion Control ==================== Sequence numbers, acks, backoff, retransmission Published Router Info ===================== Published Addresses ------------------- The published RouterAddress (part of the RouterInfo) will have a protocol identifier of either "SSU" or "SSU2". The RouterAddress must contain "host" and "port" options, as in the current SSU protocol. The RouterAddress must contain three options to indicate SSU2 support: - s=(Base64 key) The current Noise static public key (s) for this RouterAddress. Base 64 encoded using the standard I2P Base 64 alphabet. 32 bytes in binary, 44 bytes as Base 64 encoded, little-endian X25519 public key. - i=(Base64 IV) The current IV for encrypting the X value in Session Request for this RouterAddress. Base 64 encoded using the standard I2P Base 64 alphabet. 16 bytes in binary, 24 bytes as Base 64 encoded, big-endian. - v=2 The current version (2). When published as "SSU", additional support for version 1 is implied. Support for future versions will be with comma-separated values, e.g. v=2,3 Implementation should verify compatibility, including multiple versions if a comma is present. Comma-separated versions must be in numerical order. Alice must verify that all three options are present and valid before connecting using the SSU2 protocol. When published as "SSU" with "s", "i", and "v" options, the router must accept incoming connections on that host and port for both SSU and SSU2 protocols, and automatically detect the protocol version. When published as "SSU2" with "s", "i", and "v" options, the router accepts incoming connections on that host and port for the SSU2 protocol only. If a router supports both SSU1 and SSU2 connections but does not implement automatic version detection for incoming connections, it must advertise both "SSU" and "SSU2" addresses, and include the SSU2 options in the "SSU2" address only. The router should set a lower cost value (higher priority) in the "SSU2" address than the "SSU" address, so SSU2 is preferred. If multiple SSU2 RouterAddresses (either as "SSU" or "SSU2") are published in the same RouterInfo (for additional IP addresses or ports), all addresses specifying the same port must contain the identical SSU2 options and values. In particular, all must contain the same static key and iv. Unpublished SSU2 Address ------------------------- If Alice does not publish her SSU2 address (as "SSU" or "SSU2") for incoming connections, she must publish a "SSU2" router address containing only her static key and SSU2 version, so that Bob may validate the key after receiving Alice's RouterInfo in Session Confirmed part 2. - s=(Base64 key) As defined above for published addresses. - v=2 As defined above for published addresses. This router address will not contain "i", "host" or "port" options, as these are not required for outbound SSU2 connections. The published cost for this address does not strictly matter, as it is inbound only; however, it may be helpful to other routers if the cost is set higher (lower priority) than other addresses. The suggested value is 14. Alice may also simply add the "s" and "v" options to an existing published "SSU" address. Public Key and IV Rotation -------------------------- Due to caching of RouterInfos, routers must not rotate the static public key or IV while the router is up, whether in a published address or not. Routers must persistently store this key and IV for reuse after an immediate restart, so incoming connections will continue to work, and restart times are not exposed. Routers must persistently store, or otherwise determine, last-shutdown time, so that the previous downtime may be calculated at startup. Subject to concerns about exposing restart times, routers may rotate this key or IV at startup if the router was previously down for some time (a couple hours at least). If the router has any published SSU2 RouterAddresses (as SSU or SSU2), the minimum downtime before rotation should be much longer, for example one month, unless the local IP address has changed or the router "rekeys". If the router has any published SSU RouterAddresses, but not SSU2 (as SSU or SSU2) the minimum downtime before rotation should be longer, for example one day, unless the local IP address has changed or the router "rekeys". This applies even if the published SSU address has introducers. If the router does not have any published RouterAddresses (SSU, SSU2, or SSU), the minimum downtime before rotation may be as short as two hours, even if the IP address changes, unless the router "rekeys". If the router "rekeys" to a different Router Hash, it should generate a new noise key and IV as well. Implementations must be aware that changing the static public key or IV will prohibit incoming SSU2 connections from routers that have cached an older RouterInfo. RouterInfo publishing, tunnel peer selection (including both OBGW and IB closest hop), zero-hop tunnel selection, transport selection, and other implementation strategies must take this into account. IV rotation is subject to identical rules as key rotation, except that IVs are not present except in published RouterAddresses, so there is no IV for hidden or firewalled routers. If anything changes (version, key, options?) it is recommended that the IV change as well. Note: The minimum downtime before rekeying may be modified to ensure network health, and to prevent reseeding by a router down for a moderate amount of time. Identity Hiding ``````````````` Deniability is not a goal. See overview above. Each pattern is assigned properties describing the confidentiality supplied to the initiator's static public key, and to the responder's static public key. The underlying assumptions are that ephemeral private keys are secure, and that parties abort the handshake if they receive a static public key from the other party which they don't trust. This section only considers identity leakage through static public key fields in handshakes. Of course, the identities of Noise participants might be exposed through other means, including payload fields, traffic analysis, or metadata such as IP addresses. Alice: (8) Encrypted with forward secrecy to an authenticated party. Bob: (3) Not transmitted, but a passive attacker can check candidates for the responder's private key and determine whether the candidate is correct. Bob publishes his static public key in the netdb. Alice may not, but must include it in the RI sent to Bob. Inbound Packet Handling ========================== In SSU 1, inbound packet classification is difficult, because there is no header to indicate session number. Routers must first match the source IP and port to an existing peer state, and if not found, attempt multiple decryptions with different keys to find the appropriate peer state or start a new one. In the event that the source IP or port for an existing session changes, possibly due to NAT behavior the router may use expensive heuristics to attempt to match the packet to an existing session and recover the contents. SSU 2 is designed to minimize the inbound packet classification effort while maintaining DPI resistance and other on-path threats. The session number is included in the header for all message types, and obfuscated using AES with a known key and IV. Additionally, the message type is also included in the header (encrypted with header protection to a known key and then obfuscated with AES) and may be used for additional classification. In no case should a trial DH operation be necessary to classify a packet. For almost all messages from all peers, the AES key and IV are the destination router's router hash and IV as published in the netdb. The only exceptions are the first messages sent from Bob to Alice (Session Created or Retry) where Alice's router hash is not yet known to Bob. In these cases, Bob's router hash and IV are used. Therefore, the recommended processing steps are: 1) Remove the AES obfuscation to recover the session ID. If known, use that session for further processing. 2) Remove the header protection to recover the version, net ID, message type, and packet number fields. If all are sensible, and the message type is 0 (Session Request), create a new session and use that session for further processing. 3) Look up a pending outbound session by the source IP/port of the packet; if found, remove the session ID obfuscation using Bob's router hash and IV, verify the session ID matches, and use that pending session for further processing. Issues -------- If Relay and Peer Test messages are allowed outside of a session, they may also require additional processing steps to classify them. Version Detection -------------------- It may not be possible to efficiently detect if incoming packets are version 1 or 2 on the same inbound port. The steps above may make sense to do before SSU 1 processing, to avoid attempting trial DH operations using both protocol versions. TBD if required. Variants, Fallbacks, and General Issues ======================================= TBD References ========== .. [ECIES] {{ site_url('docs/spec/ecies', True) }} .. [NetDB] {{ site_url('docs/how/network-database', True) }} .. [NOISE] https://noiseprotocol.org/noise.html .. [Nonces] https://eprint.iacr.org/2019/624.pdf .. [NTCP] {{ site_url('docs/transport/ntcp', True) }} .. [NTCP2] {{ site_url('docs/spec/ntcp2', True) }} .. [Prop104] {{ proposal_url('104') }} .. [Prop109] {{ proposal_url('109') }} .. [RFC-2104] https://tools.ietf.org/html/rfc2104 .. [RFC-3526] https://tools.ietf.org/html/rfc3526 .. [RFC-6151] https://tools.ietf.org/html/rfc6151 .. [RFC-7539] https://tools.ietf.org/html/rfc7539 .. [RFC-7748] https://tools.ietf.org/html/rfc7748 .. [RFC-7905] https://tools.ietf.org/html/rfc7905 .. [RFC-9000] https://datatracker.ietf.org/doc/html/rfc9000 .. [RFC-9001] https://datatracker.ietf.org/doc/html/rfc9001 .. [RouterAddress] {{ ctags_url('RouterAddress') }} .. [RouterIdentity] {{ ctags_url('RouterIdentity') }} .. [SigningPublicKey] {{ ctags_url('SigningPublicKey') }} .. [SipHash] https://www.131002.net/siphash/ .. [SSU] {{ site_url('docs/transport/ssu', True) }} .. [STS] Diffie, W.; van Oorschot P. C.; Wiener M. J., Authentication and Authenticated Key Exchanges .. [Ticket1112] https://{{ i2pconv('trac.i2p2.i2p') }}/ticket/1112 .. [Ticket1849] https://{{ i2pconv('trac.i2p2.i2p') }}/ticket/1849 .. [WireGuard] https://www.wireguard.com/protocol/