Internet Engineering Task Force Francis Dupont INTERNET DRAFT ENST Bretagne Expires in October 2003 April 2003 Address Management for IKE version 2 Status of this Memo This document is an Internet Draft and is in full conformance with all provisions of Section 10 of RFC 2026. This document is an Internet-Draft. Internet-Drafts are working documents of the Internet Engineering Task Force (IETF), its areas, and its working groups. Note that other groups may also distribute working documents as Internet-Drafts. Internet-Drafts are draft documents valid for a maximum of six months and may be updated, replaced, or obsoleted by other documents at any time. It is inappropriate to use Internet- Drafts as reference material or to cite them other than as "work in progress." The list of current Internet Drafts can be accessed at http://www.ietf.org/ietf/1id-abstracts.txt The list of Internet-Draft Shadow Directories can be accessed at http://www.ietf.org/shadow.html. Distribution of this memo is unlimited. Abstract The current IKEv2 proposal [1] lacks an address management feature. As it includes a NAT traversal capability, this document extends it to a complete address management with support for multi-homing and mobility. 1. Introduction In this document, the addresses used to transport IKE messages are named the "peer addresses" (term introduced by [2]). These peer addresses should no more be directly or indirectly included in identities ([3] and [4]) as it is commonly done for IKEv1. draft-dupont-ikev2-addrmgmt-02.txt [Page 1] INTERNET-DRAFT Address Management for IKEv2 Apr 2003 The current IKEv2 draft [1] often makes the assumption that an address identifies a node when nodes behind a NAT can share the same address and a node can use many different addresses. This must be fixed. This document describes the goals of an address management for IKEv2, including the requirements for multi-homing and mobility support, and finishes by a concrete proposal. In this document, open questions are introduced by the word NOTE. 2. Goals The goals of the address management proposed in the document can be divided in some general goals and in requirements for the three mechanisms which can change the peer addresses. 2.1 General goals 2.1.1 Simplicity, Performance and Security The address management should be as simple as possible, i.e., it should introduce minimal changes to the current IKEv2 draft [1] and each changes should be justified. The performance is an important criterion. For instance, rekeying can update the peer addresses of an IKE SA or of an IPsec SA pair, but rekeying is too expensive and a specific solution is needed. As a security protocol, IKEv2 should get a high security level. Unfortunately we already showed that the NAT traversal feature comes with a security issue (the transient pseudo-NAT attack [5]). Such problems introduced by the peer address flexibility must be described in this document and at least be mitigated by options in configurations. For instance, the NAT traversal feature should never be enabled when one knows that there can not be a NAT as in today IPv6. 2.1.4 Extensions of the IKEv2 draft The first things to fix in the current IKEv2 draft [1] are for the NAT traversal mechanisms but we exclude them from the scope of this document. We assume that the NAT detection is performed in the first exchange. draft-dupont-ikev2-addrmgmt-02.txt [Page 2] INTERNET-DRAFT Address Management for IKEv2 Apr 2003 The second missing thing in the current IKEv2 draft [1] is about some misusage of the peer addresses: - At the reception of a message, the lookup of the corresponding IKE SA MUST be done using only the SPIs, never using the peer addresses. - An INITIAL-CONTACT notification deletes old IKE SAs associated to the peer Identity, not to the peer address. Current wording is a bit misleading. - The revised identity proposal [3] should be integrated in the IKEv2 specifications. According to IAB recommendations [4], addresses should not be used as or associated to identities. Note that the last point stresses the issue of the lack of protection of peer addresses. The last thing to fix in the current IKEv2 draft [1] is the support of the proxy case: the setup of transport mode IPsec SAs on the behalf of another party. 2.2 Multi-homing requirements In this document, the support of multi-homing is the support of nodes with several global addresses. Some of the addresses can be "better" than others, or "better" for some destinations. Some can, from time to time, be unavailable. The main requirement for the support of multi-homing is the management of a set of peer addresses for each peer. The set can be partially ordered or some subset can be loosely associated with some destinations (i.e., some subset of the other peer address set). For the communication between multi-addressed hosts, the support of the proxy case can be useful because it provides an easy way to setup transport mode IPsec SAs with different addresses from one IKE SA. In such cases the other party is in fact the same host, this dramatically simplifies the authorization issue. draft-dupont-ikev2-addrmgmt-02.txt [Page 3] INTERNET-DRAFT Address Management for IKEv2 Apr 2003 2.3 Mobility requirements In the context of Mobile IPv6 ([7] and for the special case of Home Agents [8]), the interaction of Mobility and IPsec was analyzed in another document [9]. This document assumes an IPv6 context as Mobile IPv6 is the most powerful mobility proposal available today. An IPv6 mobile node is another type of multi-addressed node with: - a care-of address in a prefix of the visited link. The care-of address is used to route packets. - the home address in a prefix of the home link. The home address is used to identify the mobile node. The care-of address is transient and usually the mobile node can not provide a proof that it is the node using it. So it must be trusted and a return routability check (i.e., an enforced answer from this address) should be used if it is not. With a common correspondent, the mobility is transparent and there is no reason to use another address than the home address. With the home agent, there are three main cases (c.f. [8]): - The mobility signaling which is mandatory protected and raises a specific issue in its initial phase: the IKE SA must be setup using the care-of address as the peer address but this IKE SA is used to build an IPsec SA pair with the home address as traffic selector. This IPsec SA will protect the home registration which will make the home address available. This can be considered as a special proxy case. - Other genuine communications between the home agent and the mobile node can be covered by the proxy case support too. Note this is the only case at the exception of signaling where mobility behaves in a different way than a mobile IPsec VPN (so we proposed to relax the corresponding rule in a future version of [7] and [8]). - The traffic relayed by the home agent through a tunnel with the mobile node can be partially or fully protected by IPsec SA pair(s). Encapsulation should be performed only once, including for degenerated (but not for free) encapsulation like the home address option or the mobility routing header. draft-dupont-ikev2-addrmgmt-02.txt [Page 4] INTERNET-DRAFT Address Management for IKEv2 Apr 2003 In all cases of interaction with the home agent, the mobile node peer address should be a care-of address. When the mobile node moves, another care-of address is used and some SAs, including the IKE SA, must be updated to use the new address. Usually the previous peer address is no more usable. In order to avoid a trivial denial of services, a strong sequencing of updates is required with a way to cancel possible pending updates when fast multiple handoff happen. The IPsec pair which protects the mobility signaling uses the home address as its traffic selector for the mobile node. It must not be updated at each handoff. The update mechanism must provide a fine grain (i.e., per SA) update. 3. Proposal The proposal for an address management in IKEv2 is spawn from the NAT traversal mechanisms, mainly with a new peer address update notification. But there are some points that have to be kept as they are in the current IKEv2 draft [1]. 3.1 Kept points from draft 06 A peer address change has to be supported but not at any time: the peer addresses MUST NOT change during an exchange, i.e., they are allowed to change only between two exchanges. This address stability requirement applies in fact only to the Initial exchange as it is the only exchange with more than two messages specified today. The peer addresses are used to transport messages. The reply to a request MUST be sent to the source of the request from the destination request, i.e., addresses and ports are reversed between the request and its reply. There is no exception to this rule. For tunnel mode IPsec SAs, the endpoint addresses are the peer addresses. We don't propose an alternate way to specify them. The same requirement applies to transport mode IPsec SAs at the exception of the proxy case. draft-dupont-ikev2-addrmgmt-02.txt [Page 5] INTERNET-DRAFT Address Management for IKEv2 Apr 2003 3.2 Small points In the proxy case, the initiator is acting as a client negotiator on the behalf of another party. The address of this other party is sent in the initiator traffic selector and will become the address of this end of the transport mode IPsec SA pair. A proper authorization in the local policy of the responder is REQUIRED. Note that the IPsec SAs built in such cases are not managed in the proposal of these document, and that the proxy case is limited to the transport mode. The INITIAL-CONTACT notification uses only identities. All the references to peer addresses must be removed from or fixed in the current wording. In retransmission of requests or responses, copies of messages do not include peer addresses. So a peer MAY retransmit a message from or to a different address. 3.3 Peer address notifications The peer address notifications are copied from the current NAT-DETECTION-SOURCE-IP and NAT-DETECTION-DESTINATION-IP notifications. They includes the peer source or destination address and the source or destination port and MUST be in an encrypted payload. All messages after the first exchange MUST include at least one peer address notification for each peer, i.e., at least one for the source and at least one for the destination. They provide a cryptographically proof of no alteration en-route of the peer addresses and, when multiple peer address notifications for the same peer are included, they encode its whole peer address set. To allow the reduction of the peer address set to one address, an address MAY be repeated. If multiple peer address notifications for the same peer are included in a message, the first one MUST be the used peer address. In order to associate some possible peer source addresses to possible peer destination addresses, the source and destination peer addresses notifications MAY be mixed (i.e., not in the common order source(s) first, destination(s) after). For instance S1, S2, D1, S3, D2, D3 is a hint: S1 or S2 should be used in conjunction with D1, S3 with D2 or D3. draft-dupont-ikev2-addrmgmt-02.txt [Page 6] INTERNET-DRAFT Address Management for IKEv2 Apr 2003 In case of a mismatch of a peer address with the corresponding peer address notifications, there is a dangling update or an attack. If the possibly compromised message is a new request, its content MUST be ignored and a warning notification sent, but the message counter MUST be incremented in order to accept next requests. If it is a retransmitted request, the cached reply MUST be sent. If it is a reply, the corresponding request MUST be retransmitted. If the peer has moved between two retransmissions of a request, it can interleave an explicit address update of at least the IKE SA. 3.4 Explicit address update payload The explicit mechanism MUST be used when NAT traversal is disabled and only it this case. A new payload has to be defined. We propose to copy it from the delete payload, see Annex C. The new peer address update payload has strong sequencing requirements. IKEv2 messages have a protected sequence number so the only sequencing issues are the window of processing and pending exchanges. Any messages with a peer address update payload MUST be processed in order. When the receiver of an update request has to check the validity of the new peer address, it MAY use a return routability check sending an informational request at the new address and waiting for an answer. As informational exchanges are protected no more is needed. Example of a return routability check: I --- address update request --> R I <-- informational RR request - R I --- informational RR reply --> R now the responder knows the initiator should be where it claimed to be. I <--- address update reply ---- R As for the delete [ayload, the peer address update payload specifies the SPIs of the IPsec and IKE SAs it applies to. But a simple way to specify all SAs (i.e., the IKE SA and all the non-proxy IPsec SAs it negotiated) is needed. draft-dupont-ikev2-addrmgmt-02.txt [Page 7] INTERNET-DRAFT Address Management for IKEv2 Apr 2003 4. Security Considerations Great care was used to avoid to introduce security threats. The NAT traversal feature comes with a security flaw (the transient pseudo-NAT attack [5]) which can not be easily avoid. IMHO the NAT traversal feature should be enabled only when the presence of NATs is likely/possible. When the NAT traversal feature is disabled, the other peer address can not be changed en-route by an attacker but the proofs the peer is really at its address are: - the trust in the peer - the proof that the peer can receive messages sent to its address The second (a.k.a. the return routability check) works only with at least three messages, i.e., for the initial exchange (with the address stability requirement) and for the explicit optional checks. IMHO these checks SHOULD be required by default. 5. Acknowledgments The need for an address management for IKEv2 was explained at the ipsec session of the Yokohama IETF meeting. It seems most people agree but do not propose concrete solutions. The rare people in the Mobility world with IPsec interests, or in the IPsec world with Mobility interest, should receive all thanks because without them we (me and all the future co-authors) have given up for a long time. Tero Kivinen helped to improve the NAT traversal part of this proposal. 6. Changes from previous versions The explicit peer address update mechanism is a new payload (and it followed the update of the deletion payload). The NAT traversal part was dropped and the "merge" style given up. Secret peer addresses are supported. The implicit mechanism comes back but is restricted to NAT traversal. Annexes are added for a more accurate proposal. draft-dupont-ikev2-addrmgmt-02.txt [Page 8] INTERNET-DRAFT Address Management for IKEv2 Apr 2003 7. Normative References None? 8. Informative References [1] C. Kaufman, ed., "Proposal for the IKEv2 Protocol", draft-ietf-ipsec-ikev2-06.txt, March 2003. [2] B. Korver, E. Rescorla, "The Internet IP Security PKI Profile of ISAKMP and PKIX", draft-ietf-ipsec-pki-profile-02.txt, February 2003. [3] P. Hoffman, "Adding revised identities to IKEv2", http://www.vpnc.org/ietf-ipsec/, Message-Id: , November 2002. [4] M. Kaat, "Overview of 1999 IAB Network Layer Workshop", RFC 2956, October 2000. [5] F. Dupont, J.-J. Bernard, "Transient pseudo-NAT attacks or how NATs are even more evil than you believed", draft-dupont-transient-pseudonat-01.txt, December 2002. [6] Jayant Shukla, "RE: peer address protection and NAT Traversal", http://www.vpnc.org/ietf-ipsec/, Message-ID: <000201c2bb27$e7021ff0$5803a8c0@trlhpc1>, January 2003. [7] D. Johnson, C. Perkins, J. Arkko, "Mobility Support in IPv6", draft-ietf-mobileip-ipv6-21.txt, February 2003. [8] J. Arkko, V. Devarapalli, F. Dupont, "Using IPsec to Protect Mobile IPv6 Signaling between Mobile Nodes and Home Agents", draft-ietf-mobileip-mipv6-ha-ipsec-04.txt, March 2003. [9] F. Dupont, W. Haddad, "How to make IPsec more mobile IPv6 friendly", draft-dupont-ipsec-mipv6-03.txt, March 2003. [10] D. McDonald, C. Metz, B. Phan, "PF_KEY Key Management API, Version 2", RFC 2367, July 1998. draft-dupont-ikev2-addrmgmt-02.txt [Page 9] INTERNET-DRAFT Address Management for IKEv2 Apr 2003 9. Author's Address Francis Dupont ENST Bretagne Campus de Rennes 2, rue de la Chataigneraie BP 78 35512 Cesson-Sevigne Cedex FRANCE Fax: +33 2 99 12 70 30 EMail: Francis.Dupont@enst-bretagne.fr Annex A. Proxy Case Usage Scenario. +-+-+-+-+-+-+ ! ! !Negotiator ! !Endpoint !<.....\ IKE ! ! \............................\ +-+-+-+-+-+-+ ! V +-+-+-+-+-+ +-+-+-+-+-+ ! ! ! ! !Protected! IPsec Transport !Protected! !Endpoint !<-------------------------------->!Endpoint ! ! ! ! ! +-+-+-+-+-+ +-+-+-+-+-+ In this scenario, both protected endpoints of the IP connection implement IPsec both the first one does not support IKE. The negotiator endpoint needs only to implement IKE. Address management is not supported for the IPsec SAs between the two protected endpoints because the negotiator endpoint has no control over the address of the protected endpoint it establishes on the behalf of. For instance, NAT traversal is not supported. draft-dupont-ikev2-addrmgmt-02.txt [Page 10] INTERNET-DRAFT Address Management for IKEv2 Apr 2003 Annex B. Peer Address Notification Format. The following diagram illustrates the content of the Peer Address Notification: 1 2 3 0 1 2 3 4 5 6 7 8 9 0 1 2 3 4 5 6 7 8 9 0 1 2 3 4 5 6 7 8 9 0 1 +-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+ ! Next Payload !C! RESERVED ! Payload Length ! +-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+ ! Protocol-ID ! SPI Size ! Notify Message Type ! +-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+ ! Address Family ! Port ! +-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+ ~ Address ~ +-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+ The notification header is for IKE SA (Protocol-ID 0, SPI Size 0 and no SPI. The Address Family is from IANA Address Family Numbers (IPv4 is 1 and IPv6 2). The proposed names are PEER-ADDRESS-SOURCE and PEER-ADDRESS-DESTINATION, with 248XX. Annex C. Peer Address Update Payload Format. The next figure 17 shows the format of the Peer Address Update Payload. It is possible to send multiple SPIs in a Peer Address Update payload, however, each SPI MUST be for the same protocol. Mixing of Protocol Identifiers MUST NOT be performed in a the Peer Address Update payload. It is permitted, however, to include multiple Peer Address Update payloads in a single INFORMATIONAL Exchange where each Peer Address Update payload lists SPIs for a different protocol. Update of the IKE_SA is indicated by a Protocol_Id of 0 (IKE) but no SPIs. Update of a CHILD_SA, such as ESP or AH, will contain the Protocol_Id of that protocol (1 for ESP, 2 for AH) and the SPI is the SPI the sending endpoint would expect in inbound ESP or AH packets. draft-dupont-ikev2-addrmgmt-02.txt [Page 11] INTERNET-DRAFT Address Management for IKEv2 Apr 2003 The following diagram illustrates the content of the Peer Address Update Notification: 1 2 3 0 1 2 3 4 5 6 7 8 9 0 1 2 3 4 5 6 7 8 9 0 1 2 3 4 5 6 7 8 9 0 1 +-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+ ! Next Payload !C! RESERVED ! Payload Length ! +-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+ !A| Protocol-ID ! SPI Size ! # of SPIs ! +-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+ ! ! ~ Security Parameter Index(es) (SPI) ~ ! ! +-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+ o All (1 bit) - MUST be set to one when all SAs (the IKE SA and all non-proxy outgoing IPsec SAs negotiated by it) are updated. In this case the update is for the IKE-SA (Protocol-ID 0, SPI size 0, no SPI and number of SPIs 0). MUST be set to zero when an individual SA is updated. o Protocol_Id (7 bits) - Must be zero for an IKE_SA, 1 for ESP, or 2 for AH. o SPI Size (1 octet) - Length in octets of the SPI as defined by the Protocol-Id. Zero for IKE (SPI is in message header) or four for AH and ESP. o # of SPIs (2 octets) - The number of SPIs contained in the Peer Address Update Notification. The size of each SPI is defined by the SPI Size field. o Security Parameter Index(es) (variable length) - Identifies the specific security association(s) to delete. The lengths of these fields are determined by the SPI Size and # of SPIs fields. ESP and AH SAs always exist in pairs, with one SA in each direction. When an SA is updated for a peer address, both members of the pair MUST be updated. When SAs are nested, as when data (and IP headers if in tunnel mode) are encapsulated first with IPcomp, then with ESP, and finally with AH between the same pair of endpoints, all of the SAs MUST be updated together. Each endpoint MUST update the SAs it receives on and allow the other endpoint to update the other SA in each pair. draft-dupont-ikev2-addrmgmt-02.txt [Page 12] INTERNET-DRAFT Address Management for IKEv2 Apr 2003 To update a peer address of an SA, an Informational Exchange with one or more peer address update payloads is sent listing the SPIs (as they would be placed in the headers of inbound packets) of the SAs to be updated. The recipient MUST update the designated SAs. Normally, the reply in the Informational Exchange will contain peer address update payloads for the paired SAs going in the other direction. Note there is no special case for update collision. The proposed name is the Update (U) payload. Annex D. PF_KEY version 2 SADB_X_ADDUPD This annex describes an extension to PF_KEYv2 [10] which provides a way to ask a peer address update of an IPsec SA and all its siblings (i.e., an update with the All flag set to one). The format of the message is: and is sent the registered socket listeners by or via the kernel. No answer is needed because if it fails it will be done again. New values are needed for SADB_X_ADDUPD and for SADB_X_EXT_NEW_ADDRESS_SRC and SADB_X_EXT_NEW_ADDRESS_DST which should have the same layout than SADB_EXT_ADDRESS_*, i.e., sadb_address structure. NOTE: IKE itself needs a PF_KEYv2 extension for individual updating of an IPsec SA. draft-dupont-ikev2-addrmgmt-02.txt [Page 13]