Internet-Draft | DTLS Return Routability Check | September 2024 |
Tschofenig, et al. | Expires 28 March 2025 | [Page] |
This document specifies a return routability check for use in context of the Connection ID (CID) construct for the Datagram Transport Layer Security (DTLS) protocol versions 1.2 and 1.3.¶
This note is to be removed before publishing as an RFC.¶
Discussion of this document takes place on the Transport Layer Security Working Group mailing list ([email protected]), which is archived at https://mailarchive.ietf.org/arch/browse/tls/.¶
Source for this draft and an issue tracker can be found at https://github.com/tlswg/dtls-rrc.¶
This Internet-Draft is submitted in full conformance with the provisions of BCP 78 and BCP 79.¶
Internet-Drafts are working documents of the Internet Engineering Task Force (IETF). Note that other groups may also distribute working documents as Internet-Drafts. The list of current Internet-Drafts is at https://datatracker.ietf.org/drafts/current/.¶
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This Internet-Draft will expire on 28 March 2025.¶
Copyright (c) 2024 IETF Trust and the persons identified as the document authors. All rights reserved.¶
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A CID is an identifier carried in the record layer header of a DTLS datagram that gives the receiver additional information for selecting the appropriate security context. The CID mechanism has been specified in [RFC9146] for DTLS 1.2 and in [RFC9147] for DTLS 1.3.¶
Section 6 of [RFC9146] describes how the use of CID increases the attack surface of DTLS 1.2 and 1.3 by providing both on-path and off-path attackers an opportunity for (D)DoS. It then goes on describing the steps a DTLS principal must take when a record with a CID is received that has a source address (and/or port) different from the one currently associated with the DTLS connection. However, the actual mechanism for ensuring that the new peer address is willing to receive and process DTLS records is left open. To address the gap, this document defines a return routability check (RRC) sub-protocol for DTLS 1.2 and 1.3.¶
The return routability check is performed by the receiving endpoint before the CID-address binding is updated in that endpoint's session state. This is done in order to give the receiving endpoint confidence that the sending peer is in fact reachable at the source address (and port) indicated in the received datagram.¶
Section 7.1 of this document explains the fundamental mechanism that aims to reduce the DDoS attack surface. Additionally, in Section 7.2, a more advanced address validation mechanism is discussed. This mechanism is designed to counteract off-path attackers trying to place themselves on-path by racing packets that trigger address rebinding at the receiver. To gain a detailed understanding of the attacker model, please refer to Section 6.¶
Apart from of its use in the context of CID-address binding updates, the path validation capability offered by RRC can be used at any time by either endpoint. For instance, an endpoint might use RRC to check that a peer is still reachable at its last known address after a period of quiescence.¶
The key words "MUST", "MUST NOT", "REQUIRED", "SHALL", "SHALL NOT", "SHOULD", "SHOULD NOT", "RECOMMENDED", "NOT RECOMMENDED", "MAY", and "OPTIONAL" in this document are to be interpreted as described in BCP 14 [RFC2119] [RFC8174] when, and only when, they appear in all capitals, as shown here.¶
This document assumes familiarity with the CID format and protocol defined for DTLS 1.2 [RFC9146] and for DTLS 1.3 [RFC9147]. The presentation language used in this document is described in Section 4 of [RFC8446].¶
This document reuses the definition of "anti-amplification limit" from [RFC9000] to mean three times the amount of data received from an unvalidated address. This includes all DTLS records originating from that source address, excluding discarded ones.¶
The terms "peer" and "endpoint" are defined in Section 1.1 of [RFC8446].¶
The use of RRC is negotiated via the rrc
extension.
The rrc
extension is only defined for DTLS 1.2 and DTLS 1.3.
On connecting, a client wishing to use RRC includes the rrc
extension in its ClientHello.
If the server is capable of meeting this requirement, it responds with a
rrc
extension in its ServerHello. The extension_type
value for this
extension is TBD1 and the extension_data
field of this extension is empty.
The client and server MUST NOT use RRC unless both sides have successfully
exchanged rrc
extensions.¶
This document defines the return_routability_check
content type
(Figure 1) to carry Return Routability Check messages.¶
The RRC sub-protocol consists of three message types: path_challenge
, path_response
and path_drop
that are used for path validation and selection as described in
Section 7.¶
Each message carries a Cookie, an 8-byte field containing arbitrary data.¶
The return_routability_check
message MUST be authenticated and encrypted
using the currently active security context.¶
Future extensions to the Return Routability Check sub-protocol may
define new message types. Implementations MUST be able to parse and ignore
messages with an unknown msg_type
.
(Naturally, implementation MUST be able to parse and understand the three RRC message types defined in this document.)¶
RRC offers an in-protocol mechanism to perform peer address validation that complements the "peer address update" procedure described in Section 6 of [RFC9146]. Specifically, when both CID [RFC9146] and RRC have been successfully negotiated for the session, if a record with CID is received that has the source address and/or source port number of the enclosing UDP datagram different from what is currently associated with that CID value, the receiver SHOULD perform a return routability check as described in Section 7, unless an application layer specific address validation mechanism can be triggered instead (e.g., CoAP Echo [RFC9175]).¶
We define two classes of attackers, off-path and on-path, with increasing capabilities (see Figure 2) partly following terminology introduced in QUIC [RFC9000]:¶
An off-path attacker is not on the original path between the DTLS peers, but is able to observe packets on the original path and has faster routing compared to the DTLS peers, which allows it to make copies of the observed packets, race its copies to either peer and consistently win the race.¶
An on-path attacker is on the original path between the DTLS peers and is therefore capable, compared to the off-path attacker, to also drop and delay records at will.¶
Note that, in general, attackers cannot craft DTLS records in a way that would successfully pass verification, due to the cryptographic protections applied by the DTLS record layer.¶
RRC is designed to defend against the following attacks:¶
On-path and off-path attackers that try to create an amplification attack by spoofing the source address of the victim (Section 6.1).¶
Off-path attackers that try to put themselves on-path (Section 6.2), provided that the enhanced path validation algorithm is used (Section 7.2).¶
Both on-path and off-path attackers can send a packet (either by modifying it on the fly, or by copying, injecting, and racing it, respectively) with the source address modified to that of a victim host. If the traffic generated by the server in response is larger compared to the received packet (e.g., a CoAP server returning an MTU's worth of data from a 20-bytes GET request [I-D.irtf-t2trg-amplification-attacks]) the attacker can use the server as a traffic amplifier toward the victim.¶
When receiving a packet with a known CID and a spoofed source address, an
RRC-capable endpoint will not send a (potentially large) response but instead a
small path_challenge
message to the victim host. Since the host is not able
to decrypt it and generate a valid path_response
, the address validation
fails, which in turn keeps the original address binding unaltered.¶
Note that in case of an off-path attacker, the original packet still reaches the intended destination; therefore, an implementation could use a different strategy to mitigate the attack.¶
An off-path attacker that can observe packets might forward copies of genuine packets to endpoints over a different path. If the copied packet arrives before the genuine packet, this will appear as a path change, like in a genuine NAT rebinding occurrence. 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 the same or better characteristics (e.g., due to a more favourable service level agreements) 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 data packet received on the original path that increases the maximum received packet number will cause the endpoint to move back to that path. Therefore, eliciting packets on this path increases the likelihood that the attack is unsuccessful. Note however that, unlike QUIC, DTLS has no "non-probing" packets so this would require application specific mechanisms.¶
Figure 3 illustrates the case where a receiver receives a
packet with a new source IP address and/or new port number. In order
to determine whether this path change was not triggered
by an off-path attacker, the receiver will send a RRC message of type
path_challenge
(1) on the old path.¶
Three cases need to be considered:¶
Case 1: The old path is dead (e.g., due to a NAT rebinding), which leads to a timeout of (1).¶
As shown in Figure 4, a path_challenge
(2) needs to be sent on
the new path. If the sender replies with a path_response
on the new path
(3), the switch to the new path is considered legitimate.¶
Case 2: The old path is alive but not preferred.¶
This case is shown in Figure 5 whereby the sender
replies with a path_drop
message (2) on the old path. This triggers
the receiver to send a path_challenge
(3) on the new path. The sender
will reply with a path_response
(4) on the new path, thus providing
confirmation for the path migration.¶
Case 3: The old path is alive and preferred.¶
This is most likely the result of an off-path attacker trying to place itself
on path. The receiver sends a path_challenge
on the old path and the sender
replies with a path_response
(2) on the old path. The interaction is shown in
Figure 6. This results in the connection not being migrated
to the new path, thus thwarting the attack.¶
Note that this defense is imperfect, but this is not considered a serious problem. If the path via the attacker is reliably faster than the old path despite multiple attempts to use that old 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. Note that changes in connection IDs are supported in DTLS 1.3 but not in DTLS 1.2.¶
The receiver that observes the peer's address or port update MUST stop sending any buffered application data, or limit the data sent to the unvalidated address to the anti-amplification limit.¶
It then initiates the return routability check that proceeds as described either in Section 7.2 or Section 7.1, depending on whether the off-path attacker scenario described in Section 6.2 is to be taken into account or not.¶
(The decision on what strategy to choose depends mainly on the threat model, but may also be influenced by other considerations. Examples of impacting factors include: the need to minimise implementation complexity, privacy concerns, and the need to reduce the time it takes to switch path. The choice may be offered as a configuration option to the user.)¶
After the path validation procedure is completed, any pending send operation is resumed to the bound peer address.¶
Section 7.3 and Section 7.4 list the requirements for the initiator and responder roles, broken down per protocol phase.¶
The receiver (i.e., the initiator) creates a return_routability_check
message of
type path_challenge
and places the unpredictable cookie into the message.¶
The message is sent to the observed new address and a timer T (see Section 7.5) is started.¶
The peer (i.e., the responder) cryptographically verifies the received
return_routability_check
message of
type path_challenge
and responds by echoing the cookie value in a
return_routability_check
message of type path_response
.¶
When the initiator receives the return_routability_check
message of type path_response
and verifies that it contains the sent cookie, it updates the peer
address binding.¶
If T expires the peer address binding is not updated.¶
The receiver (i.e., the initiator) creates a return_routability_check
message of
type path_challenge
and places the unpredictable cookie into the message.¶
The message is sent to the previously valid address, which corresponds to the old path. Additionally, a timer T, see Section 7.5, is started.¶
If the path is still functional, the peer (i.e., the responder) cryptographically verifies the received
return_routability_check
message of
type path_challenge
.
The action to be taken depends on whether the path through which
the message was received is the preferred one or not anymore:¶
If the path through which the message was received is preferred,
a return_routability_check
message of type path_response
MUST be returned.¶
If the path through which the message was received is not preferred,
a return_routability_check
message of type path_drop
MUST be returned.
In either case, the peer echoes the cookie value in the response.¶
The initiator receives and verifies that the return_routability_check
message contains the previously sent cookie. The actions taken by the
initiator differ based on the received message:¶
When a return_routability_check
message of type path_response
was received,
the initiator MUST continue using the previously valid address, i.e., no switch
to the new path takes place and the peer address binding is not updated.¶
When a return_routability_check
message of type path_drop
was received,
the initiator MUST perform a return routability check on the observed new
address, as described in Section 7.1.¶
If T expires the peer address binding is not updated. In this case, the initiator MUST perform a return routability check on the observed new address, as described in Section 7.1.¶
The initiator MAY send multiple return_routability_check
messages of type
path_challenge
to cater for packet loss on the probed path.¶
Each path_challenge
SHOULD go into different transport packets. (Note that
the DTLS implementation may not have control over the packetization done by
the transport layer.)¶
The transmission of subsequent path_challenge
messages SHOULD be paced to
decrease the chance of loss.¶
Each path_challenge
message MUST contain random data.¶
The initiator MAY use padding using the record padding mechanism available in DTLS 1.3 (and in DTLS 1.2, when CID is enabled on the sending direction) up to the anti-amplification limit to probe if the path MTU (PMTU) for the new path is still acceptable.¶
The responder MUST NOT delay sending an elicited path_response
or
path_drop
messages.¶
The responder MUST send exactly one path_response
or path_drop
message
for each received path_challenge
.¶
The responder MUST send the path_response
or the path_drop
on the path
where the corresponding path_challenge
has been received, so that validation
succeeds only if the path is functional in both directions. The initiator
MUST NOT enforce this behaviour.¶
The initiator MUST silently discard any invalid path_response
or
path_drop
it receives.¶
Note that RRC does not cater for PMTU discovery on the reverse path. If the responder wants to do PMTU discovery using RRC, it should initiate a new path validation procedure.¶
When setting T, implementations are cautioned that the new path could have a longer round-trip time (RTT) than the original.¶
In settings where there is external information about the RTT of the active path, implementations SHOULD use T = 3xRTT.¶
If an implementation has no way to obtain information regarding the RTT of the active path, T SHOULD be set to 1s.¶
Profiles for specific deployment environments -- for example, constrained networks [I-D.ietf-uta-tls13-iot-profile] -- MAY specify a different, more suitable value.¶
In the example DTLS 1.3 handshake shown in Figure 7, a client and a server successfully negotiate support for both CID and the RRC extension.¶
Once a connection has been established, the client and the server exchange application payloads protected by DTLS with a unilaterally used CID. In our case, the client is requested to use CID 100 for records sent to the server.¶
At some point in the communication interaction, the IP address used by the client changes and, thanks to the CID usage, the security context to interpret the record is successfully located by the server. However, the server wants to test the reachability of the client at its new IP address.¶
Figure 8 shows the server initiating a "basic" RRC exchange (see Section 7.1) that establishes reachability of the client at the new IP address.¶
Note that the return routability checks do not protect against flooding of third-parties if the attacker is on-path, as the attacker can redirect the return routability checks to the real peer (even if those datagrams are cryptographically authenticated). On-path adversaries can, in general, pose a harm to connectivity.¶
When using DTLS 1.3, peers SHOULD avoid using the same CID on multiple network paths, in particular when initiating connection migration or when probing a new network path, as described in Section 7, as an adversary can otherwise correlate the communication interaction across those different paths. DTLS 1.3 provides mechanisms to ensure that a new CID can always be used. In general, an endpoint should proactively send a RequestConnectionId message to ask for new CIDs as soon as the pool of spare CIDs is depleted (or goes below a threshold). Also, in case a peer might have exhausted available CIDs, a migrating endpoint could include NewConnectionId in packets sent on the new path to make sure that the subsequent path validation can use fresh CIDs.¶
Note that DTLS 1.2 does not offer the ability to request new CIDs during the session lifetime since CIDs have the same life-span of the connection. Therefore, deployments that use DTLS in multihoming environments SHOULD refuse to use CIDs with DTLS 1.2 and switch to DTLS 1.3 if the correlation privacy threat is a concern.¶
RFC Editor: please replace RFCthis with this RFC number and remove this note.¶
IANA is requested to allocate an entry to the TLS ContentType
registry, for the return_routability_check(TBD2)
message defined in
this document. IANA is requested to set the DTLS_OK
column to Y
and
to add the following note prior to the table:¶
NOTE: The return_routability_check content type is only applicable to DTLS 1.2 and 1.3.¶
IANA is requested to allocate the extension code point (TBD1) for the rrc
extension to the TLS ExtensionType Values
registry as described in
Table 1.¶
Value | Extension Name | TLS 1.3 | DTLS-Only | Recommended | Reference |
---|---|---|---|---|---|
TBD1 | rrc | CH, SH | Y | N | RFCthis |
IANA is requested to create a new sub-registry for RRC Message Types in the TLS Parameters registry [IANA.tls-parameters], with the policy "Standards Action" [RFC8126].¶
Each entry in the registry must include:¶
A number in the range from 0 to 255 (decimal)¶
a brief description of the message¶
RRC is only available in DTLS, therefore this column will be set to Y
for
all the entries in this registry¶
a reference document¶
The initial state of this sub-registry is as follows:¶
Value | Description | DTLS-Only | Reference |
---|---|---|---|
0 | path_challenge | Y | RFCthis |
1 | path_response | Y | RFCthis |
2 | path_drop | Y | RFCthis |
3-253 | Unassigned | ||
254-255 | Reserved for Private Use | Y | RFCthis |
Issues against this document are tracked at https://github.com/tlswg/dtls-rrc/issues¶
We would like to thank Hanno Becker, Hanno Böck, Manuel Pégourié-Gonnard, Marco Tiloca, Martin Thomson, Mohit Sahni, Rich Salz, Yaron Sheffer and Sean Turner for their input to this document.¶
RFC EDITOR: PLEASE REMOVE THIS SECTION¶
draft-ietf-tls-dtls-rrc-10:¶
WGLC comments from Marco Tiloca¶
Change registration policy for new RRC messages to STD action (from expert review)¶
draft-ietf-tls-dtls-rrc-09:¶
Refresh document while queueing for WGLC¶
draft-ietf-tls-dtls-rrc-08¶
Refresh document while queueing for WGLC¶
draft-ietf-tls-dtls-rrc-07¶
Fix ambiguous wording around timer settings¶
Clarify that the detailed protocol flow describes "basic" RRC¶
draft-ietf-tls-dtls-rrc-06¶
Add Achim as co-author¶
Added IANA registry for RRC message types (#14)¶
Small fix in the path validation algorithm (#15)¶
Renamed path_delete
to path_drop
(#16)¶
Added an "attacker model" section (#17, #31, #44, #45, #48)¶
Add criteria for choosing between basic and enhanced path validation (#18)¶
Reorganise Section 4 a bit (#19)¶
Small fix in Path Response/Drop Requirements section (#20)¶
Add privacy considerations wrt CID reuse (#30)¶
draft-ietf-tls-dtls-rrc-05¶
Added text about off-path packet forwarding¶
draft-ietf-tls-dtls-rrc-04¶
Re-submitted draft to fix references¶
draft-ietf-tls-dtls-rrc-03¶
Added details for challenge-response exchange¶
draft-ietf-tls-dtls-rrc-02¶
Undo the TLS flags extension for negotiating RRC, use a new extension type¶
draft-ietf-tls-dtls-rrc-01¶
Use the TLS flags extension for negotiating RRC¶
Enhanced IANA consideration section¶
Expanded example section¶
Revamp message layout:¶
draft-ietf-tls-dtls-rrc-00¶
Draft name changed after WG adoption¶
draft-tschofenig-tls-dtls-rrc-01¶
Removed text that overlapped with draft-ietf-tls-dtls-connection-id¶
draft-tschofenig-tls-dtls-rrc-00¶
Initial version¶