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diff --git a/doc/standards/draft-hoffman-ikev2bis-00.txt b/doc/standards/draft-hoffman-ikev2bis-00.txt new file mode 100644 index 000000000..9d1b9d74d --- /dev/null +++ b/doc/standards/draft-hoffman-ikev2bis-00.txt @@ -0,0 +1,6776 @@ + + + +Network Working Group C. Kaufman +Internet-Draft Microsoft +Expires: August 27, 2006 P. Hoffman + VPN Consortium + P. Eronen + Nokia + February 23, 2006 + + + Internet Key Exchange Protocol: IKEv2 + draft-hoffman-ikev2bis-00.txt + +Status of this Memo + + By submitting this Internet-Draft, each author represents that any + applicable patent or other IPR claims of which he or she is aware + have been or will be disclosed, and any of which he or she becomes + aware will be disclosed, in accordance with Section 6 of BCP 79. + + 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. + + This Internet-Draft will expire on August 27, 2006. + +Copyright Notice + + Copyright (C) The Internet Society (2006). + +Abstract + + This document describes version 2 of the Internet Key Exchange (IKE) + protocol. It is a restatement of RFC 4306, and includes all of the + clarifications from the "IKEv2 Clarifications" document. + + + + + +Kaufman, et al. Expires August 27, 2006 [Page 1] + +Internet-Draft IKEv2bis February 2006 + + +Table of Contents + + 1. Introduction . . . . . . . . . . . . . . . . . . . . . . . . 5 + 1.1. Usage Scenarios . . . . . . . . . . . . . . . . . . . . . 6 + 1.1.1. Security Gateway to Security Gateway Tunnel . . . . . 7 + 1.1.2. Endpoint-to-Endpoint Transport . . . . . . . . . . . 7 + 1.1.3. Endpoint to Security Gateway Tunnel . . . . . . . . . 8 + 1.1.4. Other Scenarios . . . . . . . . . . . . . . . . . . . 9 + 1.2. The Initial Exchanges . . . . . . . . . . . . . . . . . . 9 + 1.3. The CREATE_CHILD_SA Exchange . . . . . . . . . . . . . . 12 + 1.3.1. Creating New CHILD_SAs with the CREATE_CHILD_SA + Exchange . . . . . . . . . . . . . . . . . . . . . . 13 + 1.3.2. Rekeying IKE_SAs with the CREATE_CHILD_SA Exchange . 14 + 1.3.3. Rekeying CHILD_SAs with the CREATE_CHILD_SA + Exchange . . . . . . . . . . . . . . . . . . . . . . 14 + 1.4. The INFORMATIONAL Exchange . . . . . . . . . . . . . . . 15 + 1.5. Informational Messages outside of an IKE_SA . . . . . . . 16 + 1.6. Requirements Terminology . . . . . . . . . . . . . . . . 17 + 1.7. Differences Between RFC 4306 and This Document . . . . . 17 + 2. IKE Protocol Details and Variations . . . . . . . . . . . . . 18 + 2.1. Use of Retransmission Timers . . . . . . . . . . . . . . 19 + 2.2. Use of Sequence Numbers for Message ID . . . . . . . . . 19 + 2.3. Window Size for Overlapping Requests . . . . . . . . . . 20 + 2.4. State Synchronization and Connection Timeouts . . . . . . 21 + 2.5. Version Numbers and Forward Compatibility . . . . . . . . 23 + 2.6. Cookies . . . . . . . . . . . . . . . . . . . . . . . . . 25 + 2.6.1. Interaction of COOKIE and INVALID_KE_PAYLOAD . . . . 27 + 2.7. Cryptographic Algorithm Negotiation . . . . . . . . . . . 28 + 2.8. Rekeying . . . . . . . . . . . . . . . . . . . . . . . . 29 + 2.8.1. Simultaneous CHILD_SA rekeying . . . . . . . . . . . 31 + 2.8.2. Rekeying the IKE_SA Versus Reauthentication . . . . . 33 + 2.9. Traffic Selector Negotiation . . . . . . . . . . . . . . 34 + 2.9.1. Traffic Selectors Violating Own Policy . . . . . . . 37 + 2.10. Nonces . . . . . . . . . . . . . . . . . . . . . . . . . 38 + 2.11. Address and Port Agility . . . . . . . . . . . . . . . . 38 + 2.12. Reuse of Diffie-Hellman Exponentials . . . . . . . . . . 38 + 2.13. Generating Keying Material . . . . . . . . . . . . . . . 39 + 2.14. Generating Keying Material for the IKE_SA . . . . . . . . 40 + 2.15. Authentication of the IKE_SA . . . . . . . . . . . . . . 41 + 2.16. Extensible Authentication Protocol Methods . . . . . . . 43 + 2.17. Generating Keying Material for CHILD_SAs . . . . . . . . 45 + 2.18. Rekeying IKE_SAs Using a CREATE_CHILD_SA Exchange . . . . 46 + 2.19. Requesting an Internal Address on a Remote Network . . . 47 + 2.20. Requesting the Peer's Version . . . . . . . . . . . . . . 48 + 2.21. Error Handling . . . . . . . . . . . . . . . . . . . . . 49 + 2.22. IPComp . . . . . . . . . . . . . . . . . . . . . . . . . 50 + 2.23. NAT Traversal . . . . . . . . . . . . . . . . . . . . . . 50 + 2.24. Explicit Congestion Notification (ECN) . . . . . . . . . 53 + + + +Kaufman, et al. Expires August 27, 2006 [Page 2] + +Internet-Draft IKEv2bis February 2006 + + + 3. Header and Payload Formats . . . . . . . . . . . . . . . . . 53 + 3.1. The IKE Header . . . . . . . . . . . . . . . . . . . . . 53 + 3.2. Generic Payload Header . . . . . . . . . . . . . . . . . 56 + 3.3. Security Association Payload . . . . . . . . . . . . . . 58 + 3.3.1. Proposal Substructure . . . . . . . . . . . . . . . . 60 + 3.3.2. Transform Substructure . . . . . . . . . . . . . . . 62 + 3.3.3. Valid Transform Types by Protocol . . . . . . . . . . 64 + 3.3.4. Mandatory Transform IDs . . . . . . . . . . . . . . . 65 + 3.3.5. Transform Attributes . . . . . . . . . . . . . . . . 66 + 3.3.6. Attribute Negotiation . . . . . . . . . . . . . . . . 67 + 3.4. Key Exchange Payload . . . . . . . . . . . . . . . . . . 68 + 3.5. Identification Payloads . . . . . . . . . . . . . . . . . 69 + 3.6. Certificate Payload . . . . . . . . . . . . . . . . . . . 71 + 3.7. Certificate Request Payload . . . . . . . . . . . . . . . 74 + 3.8. Authentication Payload . . . . . . . . . . . . . . . . . 76 + 3.9. Nonce Payload . . . . . . . . . . . . . . . . . . . . . . 77 + 3.10. Notify Payload . . . . . . . . . . . . . . . . . . . . . 77 + 3.10.1. Notify Message Types . . . . . . . . . . . . . . . . 78 + 3.11. Delete Payload . . . . . . . . . . . . . . . . . . . . . 84 + 3.12. Vendor ID Payload . . . . . . . . . . . . . . . . . . . . 85 + 3.13. Traffic Selector Payload . . . . . . . . . . . . . . . . 86 + 3.13.1. Traffic Selector . . . . . . . . . . . . . . . . . . 88 + 3.14. Encrypted Payload . . . . . . . . . . . . . . . . . . . . 90 + 3.15. Configuration Payload . . . . . . . . . . . . . . . . . . 92 + 3.15.1. Configuration Attributes . . . . . . . . . . . . . . 94 + 3.15.2. Meaning of INTERNAL_IP4_SUBNET/INTERNAL_IP6_SUBNET . 97 + 3.15.3. Configuration payloads for IPv6 . . . . . . . . . . . 99 + 3.15.4. Address Assignment Failures . . . . . . . . . . . . . 100 + 3.16. Extensible Authentication Protocol (EAP) Payload . . . . 100 + 4. Conformance Requirements . . . . . . . . . . . . . . . . . . 102 + 5. Security Considerations . . . . . . . . . . . . . . . . . . . 104 + 5.1. Traffic selector authorization . . . . . . . . . . . . . 107 + 6. IANA Considerations . . . . . . . . . . . . . . . . . . . . . 108 + 7. Acknowledgements . . . . . . . . . . . . . . . . . . . . . . 108 + 8. References . . . . . . . . . . . . . . . . . . . . . . . . . 109 + 8.1. Normative References . . . . . . . . . . . . . . . . . . 109 + 8.2. Informative References . . . . . . . . . . . . . . . . . 110 + Appendix A. Summary of changes from IKEv1 . . . . . . . . . . . 114 + Appendix B. Diffie-Hellman Groups . . . . . . . . . . . . . . . 115 + B.1. Group 1 - 768 Bit MODP . . . . . . . . . . . . . . . . . 115 + B.2. Group 2 - 1024 Bit MODP . . . . . . . . . . . . . . . . . 115 + Appendix C. Exchanges and Payloads . . . . . . . . . . . . . . . 116 + C.1. IKE_SA_INIT Exchange . . . . . . . . . . . . . . . . . . 116 + C.2. IKE_AUTH Exchange without EAP . . . . . . . . . . . . . . 117 + C.3. IKE_AUTH Exchange with EAP . . . . . . . . . . . . . . . 118 + C.4. CREATE_CHILD_SA Exchange for Creating or Rekeying + CHILD_SAs . . . . . . . . . . . . . . . . . . . . . . . . 119 + C.5. CREATE_CHILD_SA Exchange for Rekeying the IKE_SA . . . . 119 + + + +Kaufman, et al. Expires August 27, 2006 [Page 3] + +Internet-Draft IKEv2bis February 2006 + + + C.6. INFORMATIONAL Exchange . . . . . . . . . . . . . . . . . 119 + Appendix D. Changes Between Internet Draft Versions . . . . . . 119 + D.1. Changes from IKEv2 to draft -00 . . . . . . . . . . . . . 119 + Authors' Addresses . . . . . . . . . . . . . . . . . . . . . . . 120 + Intellectual Property and Copyright Statements . . . . . . . . . 120 + + + + + + + + + + + + + + + + + + + + + + + + + + + + + + + + + + + + + + + + + + + + + + +Kaufman, et al. Expires August 27, 2006 [Page 4] + +Internet-Draft IKEv2bis February 2006 + + +1. Introduction + + {{ An introduction to the differences between RFC 4306 [IKEV2] and + this document is given at the end of Section 1. It is put there + (instead of here) to preserve the section numbering of the original + IKEv2 document. }} + + IP Security (IPsec) provides confidentiality, data integrity, access + control, and data source authentication to IP datagrams. These + services are provided by maintaining shared state between the source + and the sink of an IP datagram. This state defines, among other + things, the specific services provided to the datagram, which + cryptographic algorithms will be used to provide the services, and + the keys used as input to the cryptographic algorithms. + + Establishing this shared state in a manual fashion does not scale + well. Therefore, a protocol to establish this state dynamically is + needed. This memo describes such a protocol -- the Internet Key + Exchange (IKE). Version 1 of IKE was defined in RFCs 2407 [DOI], + 2408 [ISAKMP], and 2409 [IKEV1]. IKEv2 was defined in [IKEV2]. This + single document is intended to replace all three of those RFCs. + + Definitions of the primitive terms in this document (such as Security + Association or SA) can be found in [IPSECARCH]. {{ Clarif-7.2 }} It + should be noted that parts of IKEv2 rely on some of the processing + rules in [IPSECARCH], as described in various sections of this + document. + + IKE performs mutual authentication between two parties and + establishes an IKE security association (SA) that includes shared + secret information that can be used to efficiently establish SAs for + Encapsulating Security Payload (ESP) [ESP] and/or Authentication + Header (AH) [AH] and a set of cryptographic algorithms to be used by + the SAs to protect the traffic that they carry. In this document, + the term "suite" or "cryptographic suite" refers to a complete set of + algorithms used to protect an SA. An initiator proposes one or more + suites by listing supported algorithms that can be combined into + suites in a mix-and-match fashion. IKE can also negotiate use of IP + Compression (IPComp) [IPCOMP] in connection with an ESP and/or AH SA. + We call the IKE SA an "IKE_SA". The SAs for ESP and/or AH that get + set up through that IKE_SA we call "CHILD_SAs". + + All IKE communications consist of pairs of messages: a request and a + response. The pair is called an "exchange". We call the first + messages establishing an IKE_SA IKE_SA_INIT and IKE_AUTH exchanges + and subsequent IKE exchanges CREATE_CHILD_SA or INFORMATIONAL + exchanges. In the common case, there is a single IKE_SA_INIT + exchange and a single IKE_AUTH exchange (a total of four messages) to + + + +Kaufman, et al. Expires August 27, 2006 [Page 5] + +Internet-Draft IKEv2bis February 2006 + + + establish the IKE_SA and the first CHILD_SA. In exceptional cases, + there may be more than one of each of these exchanges. In all cases, + all IKE_SA_INIT exchanges MUST complete before any other exchange + type, then all IKE_AUTH exchanges MUST complete, and following that + any number of CREATE_CHILD_SA and INFORMATIONAL exchanges may occur + in any order. In some scenarios, only a single CHILD_SA is needed + between the IPsec endpoints, and therefore there would be no + additional exchanges. Subsequent exchanges MAY be used to establish + additional CHILD_SAs between the same authenticated pair of endpoints + and to perform housekeeping functions. + + IKE message flow always consists of a request followed by a response. + It is the responsibility of the requester to ensure reliability. If + the response is not received within a timeout interval, the requester + needs to retransmit the request (or abandon the connection). + + The first request/response of an IKE session (IKE_SA_INIT) negotiates + security parameters for the IKE_SA, sends nonces, and sends Diffie- + Hellman values. + + The second request/response (IKE_AUTH) transmits identities, proves + knowledge of the secrets corresponding to the two identities, and + sets up an SA for the first (and often only) AH and/or ESP CHILD_SA. + + The types of subsequent exchanges are CREATE_CHILD_SA (which creates + a CHILD_SA) and INFORMATIONAL (which deletes an SA, reports error + conditions, or does other housekeeping). Every request requires a + response. An INFORMATIONAL request with no payloads (other than the + empty Encrypted payload required by the syntax) is commonly used as a + check for liveness. These subsequent exchanges cannot be used until + the initial exchanges have completed. + + In the description that follows, we assume that no errors occur. + Modifications to the flow should errors occur are described in + Section 2.21. + +1.1. Usage Scenarios + + IKE is expected to be used to negotiate ESP and/or AH SAs in a number + of different scenarios, each with its own special requirements. + + + + + + + + + + + +Kaufman, et al. Expires August 27, 2006 [Page 6] + +Internet-Draft IKEv2bis February 2006 + + +1.1.1. Security Gateway to Security Gateway Tunnel + + +-+-+-+-+-+ +-+-+-+-+-+ + ! ! IPsec ! ! + Protected !Tunnel ! tunnel !Tunnel ! Protected + Subnet <-->!Endpoint !<---------->!Endpoint !<--> Subnet + ! ! ! ! + +-+-+-+-+-+ +-+-+-+-+-+ + + Figure 1: Security Gateway to Security Gateway Tunnel + + In this scenario, neither endpoint of the IP connection implements + IPsec, but network nodes between them protect traffic for part of the + way. Protection is transparent to the endpoints, and depends on + ordinary routing to send packets through the tunnel endpoints for + processing. Each endpoint would announce the set of addresses + "behind" it, and packets would be sent in tunnel mode where the inner + IP header would contain the IP addresses of the actual endpoints. + +1.1.2. Endpoint-to-Endpoint Transport + + +-+-+-+-+-+ +-+-+-+-+-+ + ! ! IPsec transport ! ! + !Protected! or tunnel mode SA !Protected! + !Endpoint !<---------------------------------------->!Endpoint ! + ! ! ! ! + +-+-+-+-+-+ +-+-+-+-+-+ + + Figure 2: Endpoint to Endpoint + + In this scenario, both endpoints of the IP connection implement + IPsec, as required of hosts in [IPSECARCH]. Transport mode will + commonly be used with no inner IP header. If there is an inner IP + header, the inner addresses will be the same as the outer addresses. + A single pair of addresses will be negotiated for packets to be + protected by this SA. These endpoints MAY implement application + layer access controls based on the IPsec authenticated identities of + the participants. This scenario enables the end-to-end security that + has been a guiding principle for the Internet since [ARCHPRINC], + [TRANSPARENCY], and a method of limiting the inherent problems with + complexity in networks noted by [ARCHGUIDEPHIL]. Although this + scenario may not be fully applicable to the IPv4 Internet, it has + been deployed successfully in specific scenarios within intranets + using IKEv1. It should be more broadly enabled during the transition + to IPv6 and with the adoption of IKEv2. + + It is possible in this scenario that one or both of the protected + endpoints will be behind a network address translation (NAT) node, in + + + +Kaufman, et al. Expires August 27, 2006 [Page 7] + +Internet-Draft IKEv2bis February 2006 + + + which case the tunneled packets will have to be UDP encapsulated so + that port numbers in the UDP headers can be used to identify + individual endpoints "behind" the NAT (see Section 2.23). + +1.1.3. Endpoint to Security Gateway Tunnel + + +-+-+-+-+-+ +-+-+-+-+-+ + ! ! IPsec ! ! Protected + !Protected! tunnel !Tunnel ! Subnet + !Endpoint !<------------------------>!Endpoint !<--- and/or + ! ! ! ! Internet + +-+-+-+-+-+ +-+-+-+-+-+ + + Figure 3: Endpoint to Security Gateway Tunnel + + In this scenario, a protected endpoint (typically a portable roaming + computer) connects back to its corporate network through an IPsec- + protected tunnel. It might use this tunnel only to access + information on the corporate network, or it might tunnel all of its + traffic back through the corporate network in order to take advantage + of protection provided by a corporate firewall against Internet-based + attacks. In either case, the protected endpoint will want an IP + address associated with the security gateway so that packets returned + to it will go to the security gateway and be tunneled back. This IP + address may be static or may be dynamically allocated by the security + gateway. {{ Clarif-6.1 }} In support of the latter case, IKEv2 + includes a mechanism (namely, configuration payloads) for the + initiator to request an IP address owned by the security gateway for + use for the duration of its SA. + + In this scenario, packets will use tunnel mode. On each packet from + the protected endpoint, the outer IP header will contain the source + IP address associated with its current location (i.e., the address + that will get traffic routed to the endpoint directly), while the + inner IP header will contain the source IP address assigned by the + security gateway (i.e., the address that will get traffic routed to + the security gateway for forwarding to the endpoint). The outer + destination address will always be that of the security gateway, + while the inner destination address will be the ultimate destination + for the packet. + + In this scenario, it is possible that the protected endpoint will be + behind a NAT. In that case, the IP address as seen by the security + gateway will not be the same as the IP address sent by the protected + endpoint, and packets will have to be UDP encapsulated in order to be + routed properly. + + + + + +Kaufman, et al. Expires August 27, 2006 [Page 8] + +Internet-Draft IKEv2bis February 2006 + + +1.1.4. Other Scenarios + + Other scenarios are possible, as are nested combinations of the + above. One notable example combines aspects of 1.1.1 and 1.1.3. A + subnet may make all external accesses through a remote security + gateway using an IPsec tunnel, where the addresses on the subnet are + routed to the security gateway by the rest of the Internet. An + example would be someone's home network being virtually on the + Internet with static IP addresses even though connectivity is + provided by an ISP that assigns a single dynamically assigned IP + address to the user's security gateway (where the static IP addresses + and an IPsec relay are provided by a third party located elsewhere). + +1.2. The Initial Exchanges + + Communication using IKE always begins with IKE_SA_INIT and IKE_AUTH + exchanges (known in IKEv1 as Phase 1). These initial exchanges + normally consist of four messages, though in some scenarios that + number can grow. All communications using IKE consist of request/ + response pairs. We'll describe the base exchange first, followed by + variations. The first pair of messages (IKE_SA_INIT) negotiate + cryptographic algorithms, exchange nonces, and do a Diffie-Hellman + exchange [DH]. + + The second pair of messages (IKE_AUTH) authenticate the previous + messages, exchange identities and certificates, and establish the + first CHILD_SA. Parts of these messages are encrypted and integrity + protected with keys established through the IKE_SA_INIT exchange, so + the identities are hidden from eavesdroppers and all fields in all + the messages are authenticated. + + In the following descriptions, the payloads contained in the message + are indicated by names as listed below. + + + + + + + + + + + + + + + + + + +Kaufman, et al. Expires August 27, 2006 [Page 9] + +Internet-Draft IKEv2bis February 2006 + + + Notation Payload + ----------------------------------------- + AUTH Authentication + CERT Certificate + CERTREQ Certificate Request + CP Configuration + D Delete + E Encrypted + EAP Extensible Authentication + HDR IKE Header + IDi Identification - Initiator + IDr Identification - Responder + KE Key Exchange + Ni, Nr Nonce + N Notify + SA Security Association + TSi Traffic Selector - Initiator + TSr Traffic Selector - Responder + V Vendor ID + + The details of the contents of each payload are described in section + 3. Payloads that may optionally appear will be shown in brackets, + such as [CERTREQ], indicate that optionally a certificate request + payload can be included. + + {{ Clarif-7.10 }} Many payloads contain fields marked as "RESERVED". + Some payloads in IKEv2 (and historically in IKEv1) are not aligned to + 4-byte boundaries. + + The initial exchanges are as follows: + + Initiator Responder + ------------------------------------------------------------------- + HDR, SAi1, KEi, Ni --> + + HDR contains the Security Parameter Indexes (SPIs), version numbers, + and flags of various sorts. The SAi1 payload states the + cryptographic algorithms the initiator supports for the IKE_SA. The + KE payload sends the initiator's Diffie-Hellman value. Ni is the + initiator's nonce. + + <-- HDR, SAr1, KEr, Nr, [CERTREQ] + + The responder chooses a cryptographic suite from the initiator's + offered choices and expresses that choice in the SAr1 payload, + completes the Diffie-Hellman exchange with the KEr payload, and sends + its nonce in the Nr payload. + + + + +Kaufman, et al. Expires August 27, 2006 [Page 10] + +Internet-Draft IKEv2bis February 2006 + + + At this point in the negotiation, each party can generate SKEYSEED, + from which all keys are derived for that IKE_SA. All but the headers + of all the messages that follow are encrypted and integrity + protected. The keys used for the encryption and integrity protection + are derived from SKEYSEED and are known as SK_e (encryption) and SK_a + (authentication, a.k.a. integrity protection). A separate SK_e and + SK_a is computed for each direction. In addition to the keys SK_e + and SK_a derived from the DH value for protection of the IKE_SA, + another quantity SK_d is derived and used for derivation of further + keying material for CHILD_SAs. The notation SK { ... } indicates + that these payloads are encrypted and integrity protected using that + direction's SK_e and SK_a. + + HDR, SK {IDi, [CERT,] [CERTREQ,] + [IDr,] AUTH, SAi2, + TSi, TSr} --> + + The initiator asserts its identity with the IDi payload, proves + knowledge of the secret corresponding to IDi and integrity protects + the contents of the first message using the AUTH payload (see + Section 2.15). It might also send its certificate(s) in CERT + payload(s) and a list of its trust anchors in CERTREQ payload(s). If + any CERT payloads are included, the first certificate provided MUST + contain the public key used to verify the AUTH field. The optional + payload IDr enables the initiator to specify which of the responder's + identities it wants to talk to. This is useful when the machine on + which the responder is running is hosting multiple identities at the + same IP address. The initiator begins negotiation of a CHILD_SA + using the SAi2 payload. The final fields (starting with SAi2) are + described in the description of the CREATE_CHILD_SA exchange. + + <-- HDR, SK {IDr, [CERT,] AUTH, + SAr2, TSi, TSr} + + The responder asserts its identity with the IDr payload, optionally + sends one or more certificates (again with the certificate containing + the public key used to verify AUTH listed first), authenticates its + identity and protects the integrity of the second message with the + AUTH payload, and completes negotiation of a CHILD_SA with the + additional fields described below in the CREATE_CHILD_SA exchange. + + The recipients of messages 3 and 4 MUST verify that all signatures + and MACs are computed correctly and that the names in the ID payloads + correspond to the keys used to generate the AUTH payload. + + {{ Clarif-4.2}} If creating the CHILD_SA during the IKE_AUTH exchange + fails for some reason, the IKE_SA is still created as usual. The + list of responses in the IKE_AUTH exchange that do not prevent an + + + +Kaufman, et al. Expires August 27, 2006 [Page 11] + +Internet-Draft IKEv2bis February 2006 + + + IKE_SA from being set up include at least the following: + NO_PROPOSAL_CHOSEN, TS_UNACCEPTABLE, SINGLE_PAIR_REQUIRED, + INTERNAL_ADDRESS_FAILURE, and FAILED_CP_REQUIRED. + + {{ Clarif-4.3 }} Note that IKE_AUTH messages do not contain KEi/KEr + or Ni/Nr payloads. Thus, the SA payload in IKE_AUTH exchange cannot + contain Transform Type 4 (Diffie-Hellman Group) with any value other + than NONE. Implementations SHOULD NOT send such a transform because + it cannot be interpreted consistently, and implementations SHOULD + ignore any such tranforms they receive. + +1.3. The CREATE_CHILD_SA Exchange + + {{ This is a heavy rewrite of most of this section. The major + organization changes are described in Clarif-4.1 and Clarif-5.1. }} + + The CREATE_CHILD_SA exchange is used to create new CHILD_SAs and to + rekey both IKE_SAs and CHILD_SAs. This exchange consists of a single + request/response pair, and some of its function was referred to as a + phase 2 exchange in IKEv1. It MAY be initiated by either end of the + IKE_SA after the initial exchanges are completed. + + All messages following the initial exchange are cryptographically + protected using the cryptographic algorithms and keys negotiated in + the first two messages of the IKE exchange. These subsequent + messages use the syntax of the Encrypted Payload described in + Section 3.14. All subsequent messages include an Encrypted Payload, + even if they are referred to in the text as "empty". For both + messages in the CREATE_CHILD_SA, the message following the header is + encrypted and the message including the header is integrity protected + using the cryptographic algorithms negotiated for the IKE_SA. + + The CREATE_CHILD_SA is also used for rekeying IKE_SAs and CHILD_SAs. + An SA is rekeyed by creating a new SA and then deleting the old one. + This section describes the first part of rekeying, the creation of + new SAs; Section 2.8 covers the mechanics of rekeying, including + moving traffic from old to new SAs and the deletion of the old SAs. + The two sections must be read together to understand the entire + process of rekeying. + + Either endpoint may initiate a CREATE_CHILD_SA exchange, so in this + section the term initiator refers to the endpoint initiating this + exchange. An implementation MAY refuse all CREATE_CHILD_SA requests + within an IKE_SA. + + The CREATE_CHILD_SA request MAY optionally contain a KE payload for + an additional Diffie-Hellman exchange to enable stronger guarantees + of forward secrecy for the CHILD_SA. The keying material for the + + + +Kaufman, et al. Expires August 27, 2006 [Page 12] + +Internet-Draft IKEv2bis February 2006 + + + CHILD_SA is a function of SK_d established during the establishment + of the IKE_SA, the nonces exchanged during the CREATE_CHILD_SA + exchange, and the Diffie-Hellman value (if KE payloads are included + in the CREATE_CHILD_SA exchange). + + If a CREATE_CHILD_SA exchange includes a KEi payload, at least one of + the SA offers MUST include the Diffie-Hellman group of the KEi. The + Diffie-Hellman group of the KEi MUST be an element of the group the + initiator expects the responder to accept (additional Diffie-Hellman + groups can be proposed). If the responder rejects the Diffie-Hellman + group of the KEi payload, the responder MUST reject the request and + indicate its preferred Diffie-Hellman group in the INVALID_KE_PAYLOAD + Notification payload. In the case of such a rejection, the + CREATE_CHILD_SA exchange fails, and the initiator will probably retry + the exchange with a Diffie-Hellman proposal and KEi in the group that + the responder gave in the INVALID_KE_PAYLOAD. + +1.3.1. Creating New CHILD_SAs with the CREATE_CHILD_SA Exchange + + A CHILD_SA may be created by sending a CREATE_CHILD_SA request. The + CREATE_CHILD_SA request for creating a new CHILD_SA is: + + Initiator Responder + ------------------------------------------------------------------- + HDR, SK {SA, Ni, [KEi], + TSi, TSr} --> + + The initiator sends SA offer(s) in the SA payload, a nonce in the Ni + payload, optionally a Diffie-Hellman value in the KEi payload, and + the proposed traffic selectors for the proposed CHILD_SA in the TSi + and TSr payloads. + + The CREATE_CHILD_SA response for creating a new CHILD_SA is: + + <-- HDR, SK {SA, Nr, [KEr], + TSi, TSr} + + The responder replies (using the same Message ID to respond) with the + accepted offer in an SA payload, and a Diffie-Hellman value in the + KEr payload if KEi was included in the request and the selected + cryptographic suite includes that group. + + The traffic selectors for traffic to be sent on that SA are specified + in the TS payloads in the response, which may be a subset of what the + initiator of the CHILD_SA proposed. + + + + + + +Kaufman, et al. Expires August 27, 2006 [Page 13] + +Internet-Draft IKEv2bis February 2006 + + +1.3.2. Rekeying IKE_SAs with the CREATE_CHILD_SA Exchange + + The CREATE_CHILD_SA request for rekeying an IKE_SA is: + + Initiator Responder + ------------------------------------------------------------------- + HDR, SK {SA, Ni, KEi} --> + + The initiator sends SA offer(s) in the SA payload, a nonce in the Ni + payload, and a Diffie-Hellman value in the KEi payload. New + initiator and responder SPIs are supplied in the SPI fields. + + The CREATE_CHILD_SA response for rekeying an IKE_SA is: + + <-- HDR, SK {SA, Nr, KEr} + + The responder replies (using the same Message ID to respond) with the + accepted offer in an SA payload, and a Diffie-Hellman value in the + KEr payload if the selected cryptographic suite includes that group. + + The new IKE_SA has its message counters set to 0, regardless of what + they were in the earlier IKE_SA. The window size starts at 1 for any + new IKE_SA. + + KEi and KEr are required for rekeying an IKE_SA. + +1.3.3. Rekeying CHILD_SAs with the CREATE_CHILD_SA Exchange + + The CREATE_CHILD_SA request for rekeying a CHILD_SA is: + + Initiator Responder + ------------------------------------------------------------------- + HDR, SK {N, SA, Ni, [KEi], + TSi, TSr} --> + + The initiator sends SA offer(s) in the SA payload, a nonce in the Ni + payload, optionally a Diffie-Hellman value in the KEi payload, and + the proposed traffic selectors for the proposed CHILD_SA in the TSi + and TSr payloads. When rekeying an existing CHILD_SA, the leading N + payload of type REKEY_SA MUST be included and MUST give the SPI (as + they would be expected in the headers of inbound packets) of the SAs + being rekeyed. + + The CREATE_CHILD_SA response for rekeying a CHILD_SA is: + + <-- HDR, SK {SA, Nr, [KEr], + Si, TSr} + + + + +Kaufman, et al. Expires August 27, 2006 [Page 14] + +Internet-Draft IKEv2bis February 2006 + + + The responder replies (using the same Message ID to respond) with the + accepted offer in an SA payload, and a Diffie-Hellman value in the + KEr payload if KEi was included in the request and the selected + cryptographic suite includes that group. + + The traffic selectors for traffic to be sent on that SA are specified + in the TS payloads in the response, which may be a subset of what the + initiator of the CHILD_SA proposed. + +1.4. The INFORMATIONAL Exchange + + At various points during the operation of an IKE_SA, peers may desire + to convey control messages to each other regarding errors or + notifications of certain events. To accomplish this, IKE defines an + INFORMATIONAL exchange. INFORMATIONAL exchanges MUST ONLY occur + after the initial exchanges and are cryptographically protected with + the negotiated keys. + + Control messages that pertain to an IKE_SA MUST be sent under that + IKE_SA. Control messages that pertain to CHILD_SAs MUST be sent + under the protection of the IKE_SA which generated them (or its + successor if the IKE_SA was replaced for the purpose of rekeying). + + Messages in an INFORMATIONAL exchange contain zero or more + Notification, Delete, and Configuration payloads. The Recipient of + an INFORMATIONAL exchange request MUST send some response (else the + Sender will assume the message was lost in the network and will + retransmit it). That response MAY be a message with no payloads. + The request message in an INFORMATIONAL exchange MAY also contain no + payloads. This is the expected way an endpoint can ask the other + endpoint to verify that it is alive. + + {{ Clarif-5.6 }} ESP and AH SAs always exist in pairs, with one SA in + each direction. When an SA is closed, both members of the pair MUST + be closed (that is, deleted). 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 deleted together. Each endpoint + MUST close its incoming SAs and allow the other endpoint to close the + other SA in each pair. To delete an SA, an INFORMATIONAL exchange + with one or more delete payloads is sent listing the SPIs (as they + would be expected in the headers of inbound packets) of the SAs to be + deleted. The recipient MUST close the designated SAs. {{ Clarif-5.7 + }} Note that one never sends delete payloads for the two sides of an + SA in a single message. If there are many SAs to delete at the same + time (such as for nested SAs), one includes delete payloads for in + inbound half of each SA pair in your Informational exchange. + + + + +Kaufman, et al. Expires August 27, 2006 [Page 15] + +Internet-Draft IKEv2bis February 2006 + + + Normally, the reply in the INFORMATIONAL exchange will contain delete + payloads for the paired SAs going in the other direction. There is + one exception. If by chance both ends of a set of SAs independently + decide to close them, each may send a delete payload and the two + requests may cross in the network. If a node receives a delete + request for SAs for which it has already issued a delete request, it + MUST delete the outgoing SAs while processing the request and the + incoming SAs while processing the response. In that case, the + responses MUST NOT include delete payloads for the deleted SAs, since + that would result in duplicate deletion and could in theory delete + the wrong SA. + + {{ Demoted the SHOULD }} Half-closed connections are anomalous, and a + node with auditing capability should probably audit their existence + if they persist. Note that this specification nowhere specifies time + periods, so it is up to individual endpoints to decide how long to + wait. A node MAY refuse to accept incoming data on half-closed + connections but MUST NOT unilaterally close them and reuse the SPIs. + If connection state becomes sufficiently messed up, a node MAY close + the IKE_SA; doing so will implicitly close all SAs negotiated under + it. It can then rebuild the SAs it needs on a clean base under a new + IKE_SA. {{ Clarif-5.8 }} The response to a request that deletes the + IKE_SA is an empty Informational response. + + The INFORMATIONAL exchange is defined as: + + Initiator Responder + ------------------------------------------------------------------- + HDR, SK {[N,] [D,] + [CP,] ...} --> + <-- HDR, SK {[N,] [D,] + [CP], ...} + + The processing of an INFORMATIONAL exchange is determined by its + component payloads. + +1.5. Informational Messages outside of an IKE_SA + + If an encrypted IKE packet arrives on port 500 or 4500 with an + unrecognized SPI, it could be because the receiving node has recently + crashed and lost state or because of some other system malfunction or + attack. If the receiving node has an active IKE_SA to the IP address + from whence the packet came, it MAY send a notification of the + wayward packet over that IKE_SA in an INFORMATIONAL exchange. If it + does not have such an IKE_SA, it MAY send an Informational message + without cryptographic protection to the source IP address. Such a + message is not part of an informational exchange, and the receiving + node MUST NOT respond to it. Doing so could cause a message loop. + + + +Kaufman, et al. Expires August 27, 2006 [Page 16] + +Internet-Draft IKEv2bis February 2006 + + + {{ Clarif-7.7 }} There are two cases when such a one-way notification + is sent: INVALID_IKE_SPI and INVALID_SPI. These notifications are + sent outside of an IKE_SA. Note that such notifications are + explicitly not Informational exchanges; these are one-way messages + that must not be responded to. In case of INVALID_IKE_SPI, the + message sent is a response message, and thus it is sent to the IP + address and port from whence it came with the same IKE SPIs and the + Message ID copied. In case of INVALID_SPI, however, there are no IKE + SPI values that would be meaningful to the recipient of such a + notification. Using zero values or random values are both + acceptable. + +1.6. Requirements Terminology + + Keywords "MUST", "MUST NOT", "REQUIRED", "SHOULD", "SHOULD NOT" and + "MAY" that appear in this document are to be interpreted as described + in [MUSTSHOULD]. + + The term "Expert Review" is to be interpreted as defined in + [IANACONS]. + +1.7. Differences Between RFC 4306 and This Document + + {{ Added this entire section, including this recursive remark. }} + + This document contains clarifications and amplifications to IKEv2 + [IKEV2]. The clarifications are mostly based on [Clarif]. The + changes listed in that document were discussed in the IPsec Working + Group and, after the Working Group was disbanded, on the IPsec + mailing list. That document contains detailed explanations of areas + that were unclear in IKEv2, and is thus useful to implementers of + IKEv2. + + The protocol described in this document retains the same major + version number (2) and minor version number (0) as was used in RFC + 4306. + + In the body of this document, notes that are enclosed in double curly + braces {{ such as this }} point out changes from IKEv2. Changes that + come from [Clarif] are marked with the section from that document, + such as "{{ Clarif-2.10 }}". + + This document also make the figures and references a bit more regular + than in [IKEV2]. + + IKEv2 developers have noted that the SHOULD-level requirements are + often unclear in that they don't say when it is OK to not obey the + requirements. They also have noted that there are MUST-level + + + +Kaufman, et al. Expires August 27, 2006 [Page 17] + +Internet-Draft IKEv2bis February 2006 + + + requirements that are not related to interoperability. This document + has more explanation of some of these requirements. All non- + capitalized uses of the words SHOULD and MUST now mean their normal + English sense, not the interoperability sense of [MUSTSHOULD]. + + IKEv2 (and IKEv1) developers have noted that there is a great deal of + material in the tables of codes in Section 3.10. This leads to + implementers not having all the needed information in the main body + of the docment. A later version of this document may move much of + the material from those tables into the associated parts of the main + body of the document. + + A later version of this document will probably have all the {{ }} + comments removed from the body of the document and instead appear in + an appendix. + + +2. IKE Protocol Details and Variations + + IKE normally listens and sends on UDP port 500, though IKE messages + may also be received on UDP port 4500 with a slightly different + format (see Section 2.23). Since UDP is a datagram (unreliable) + protocol, IKE includes in its definition recovery from transmission + errors, including packet loss, packet replay, and packet forgery. + IKE is designed to function so long as (1) at least one of a series + of retransmitted packets reaches its destination before timing out; + and (2) the channel is not so full of forged and replayed packets so + as to exhaust the network or CPU capacities of either endpoint. Even + in the absence of those minimum performance requirements, IKE is + designed to fail cleanly (as though the network were broken). + + Although IKEv2 messages are intended to be short, they contain + structures with no hard upper bound on size (in particular, X.509 + certificates), and IKEv2 itself does not have a mechanism for + fragmenting large messages. IP defines a mechanism for fragmentation + of oversize UDP messages, but implementations vary in the maximum + message size supported. Furthermore, use of IP fragmentation opens + an implementation to denial of service attacks [DOSUDPPROT]. + Finally, some NAT and/or firewall implementations may block IP + fragments. + + All IKEv2 implementations MUST be able to send, receive, and process + IKE messages that are up to 1280 bytes long, and they SHOULD be able + to send, receive, and process messages that are up to 3000 bytes + long. {{ Demoted the SHOULD }} IKEv2 implementations need to be aware + of the maximum UDP message size supported and MAY shorten messages by + leaving out some certificates or cryptographic suite proposals if + that will keep messages below the maximum. Use of the "Hash and URL" + + + +Kaufman, et al. Expires August 27, 2006 [Page 18] + +Internet-Draft IKEv2bis February 2006 + + + formats rather than including certificates in exchanges where + possible can avoid most problems. {{ Demoted the SHOULD }} + Implementations and configuration need to keep in mind, however, that + if the URL lookups are possible only after the IPsec SA is + established, recursion issues could prevent this technique from + working. + + {{ Clarif-7.5 }} All packets sent on port 4500 MUST begin with the + prefix of four zeros; otherwise, the receiver won't know how to + handle them. + +2.1. Use of Retransmission Timers + + All messages in IKE exist in pairs: a request and a response. The + setup of an IKE_SA normally consists of two request/response pairs. + Once the IKE_SA is set up, either end of the security association may + initiate requests at any time, and there can be many requests and + responses "in flight" at any given moment. But each message is + labeled as either a request or a response, and for each request/ + response pair one end of the security association is the initiator + and the other is the responder. + + For every pair of IKE messages, the initiator is responsible for + retransmission in the event of a timeout. The responder MUST never + retransmit a response unless it receives a retransmission of the + request. In that event, the responder MUST ignore the retransmitted + request except insofar as it triggers a retransmission of the + response. The initiator MUST remember each request until it receives + the corresponding response. The responder MUST remember each + response until it receives a request whose sequence number is larger + than the sequence number in the response plus its window size (see + Section 2.3). + + IKE is a reliable protocol, in the sense that the initiator MUST + retransmit a request until either it receives a corresponding reply + OR it deems the IKE security association to have failed and it + discards all state associated with the IKE_SA and any CHILD_SAs + negotiated using that IKE_SA. + +2.2. Use of Sequence Numbers for Message ID + + Every IKE message contains a Message ID as part of its fixed header. + This Message ID is used to match up requests and responses, and to + identify retransmissions of messages. + + The Message ID is a 32-bit quantity, which is zero for the first IKE + request in each direction. {{ Clarif-3.10 }} When the IKE_AUTH + exchange does not use EAP, the IKE_SA initial setup messages will + + + +Kaufman, et al. Expires August 27, 2006 [Page 19] + +Internet-Draft IKEv2bis February 2006 + + + always be numbered 0 and 1. When EAP is used, each pair of messages + have their message numbers incremented; the first pair of AUTH + messages will have an ID of 1, the second will be 2, and so on. + + Each endpoint in the IKE Security Association maintains two "current" + Message IDs: the next one to be used for a request it initiates and + the next one it expects to see in a request from the other end. + These counters increment as requests are generated and received. + Responses always contain the same message ID as the corresponding + request. That means that after the initial exchange, each integer n + may appear as the message ID in four distinct messages: the nth + request from the original IKE initiator, the corresponding response, + the nth request from the original IKE responder, and the + corresponding response. If the two ends make very different numbers + of requests, the Message IDs in the two directions can be very + different. There is no ambiguity in the messages, however, because + the (I)nitiator and (R)esponse bits in the message header specify + which of the four messages a particular one is. + + {{ Clarif-2.2 }} The Message ID for IKE_SA_INIT messages is always + zero, including for retries of the message due to responses such as + COOKIE and INVALID_KE_PAYLOAD. + + Note that Message IDs are cryptographically protected and provide + protection against message replays. In the unlikely event that + Message IDs grow too large to fit in 32 bits, the IKE_SA MUST be + closed. Rekeying an IKE_SA resets the sequence numbers. + + {{ Clarif-2.3 }} When a responder receives an IKE_SA_INIT request, it + has to determine whether the packet is a retransmission belonging to + an existing "half-open" IKE_SA (in which case the responder + retransmits the same response), or a new request (in which case the + responder creates a new IKE_SA and sends a fresh response), or it is + a retransmission of a now-opened IKE_SA (in whcih case the responder + ignores it). It is not sufficient to use the initiator's SPI and/or + IP address to differentiate between the two cases because two + different peers behind a single NAT could choose the same initiator + SPI. Instead, a robust responder will do the IKE_SA lookup using the + whole packet, its hash, or the Ni payload. + +2.3. Window Size for Overlapping Requests + + In order to maximize IKE throughput, an IKE endpoint MAY issue + multiple requests before getting a response to any of them if the + other endpoint has indicated its ability to handle such requests. + For simplicity, an IKE implementation MAY choose to process requests + strictly in order and/or wait for a response to one request before + issuing another. Certain rules must be followed to ensure + + + +Kaufman, et al. Expires August 27, 2006 [Page 20] + +Internet-Draft IKEv2bis February 2006 + + + interoperability between implementations using different strategies. + + After an IKE_SA is set up, either end can initiate one or more + requests. These requests may pass one another over the network. An + IKE endpoint MUST be prepared to accept and process a request while + it has a request outstanding in order to avoid a deadlock in this + situation. {{ Downgraded the SHOULD }} An IKE endpoint may also + accept and process multiple requests while it has a request + outstanding. + + An IKE endpoint MUST wait for a response to each of its messages + before sending a subsequent message unless it has received a + SET_WINDOW_SIZE Notify message from its peer informing it that the + peer is prepared to maintain state for multiple outstanding messages + in order to allow greater throughput. + + An IKE endpoint MUST NOT exceed the peer's stated window size for + transmitted IKE requests. In other words, if the responder stated + its window size is N, then when the initiator needs to make a request + X, it MUST wait until it has received responses to all requests up + through request X-N. An IKE endpoint MUST keep a copy of (or be able + to regenerate exactly) each request it has sent until it receives the + corresponding response. An IKE endpoint MUST keep a copy of (or be + able to regenerate exactly) the number of previous responses equal to + its declared window size in case its response was lost and the + initiator requests its retransmission by retransmitting the request. + + An IKE endpoint supporting a window size greater than one ought to be + capable of processing incoming requests out of order to maximize + performance in the event of network failures or packet reordering. + + {{ Clarif-7.3 }} The window size is normally a (possibly + configurable) property of a particular implementation, and is not + related to congestion control (unlike the window size in TCP, for + example). In particular, it is not defined what the responder should + do when it receives a SET_WINDOW_SIZE notification containing a + smaller value than is currently in effect. Thus, there is currently + no way to reduce the window size of an existing IKE_SA; you can only + increase it. When rekeying an IKE_SA, the new IKE_SA starts with + window size 1 until it is explicitly increased by sending a new + SET_WINDOW_SIZE notification. + +2.4. State Synchronization and Connection Timeouts + + An IKE endpoint is allowed to forget all of its state associated with + an IKE_SA and the collection of corresponding CHILD_SAs at any time. + This is the anticipated behavior in the event of an endpoint crash + and restart. It is important when an endpoint either fails or + + + +Kaufman, et al. Expires August 27, 2006 [Page 21] + +Internet-Draft IKEv2bis February 2006 + + + reinitializes its state that the other endpoint detect those + conditions and not continue to waste network bandwidth by sending + packets over discarded SAs and having them fall into a black hole. + + Since IKE is designed to operate in spite of Denial of Service (DoS) + attacks from the network, an endpoint MUST NOT conclude that the + other endpoint has failed based on any routing information (e.g., + ICMP messages) or IKE messages that arrive without cryptographic + protection (e.g., Notify messages complaining about unknown SPIs). + An endpoint MUST conclude that the other endpoint has failed only + when repeated attempts to contact it have gone unanswered for a + timeout period or when a cryptographically protected INITIAL_CONTACT + notification is received on a different IKE_SA to the same + authenticated identity. {{ Demoted the SHOULD }} An endpoint should + suspect that the other endpoint has failed based on routing + information and initiate a request to see whether the other endpoint + is alive. To check whether the other side is alive, IKE specifies an + empty INFORMATIONAL message that (like all IKE requests) requires an + acknowledgement (note that within the context of an IKE_SA, an + "empty" message consists of an IKE header followed by an Encrypted + payload that contains no payloads). If a cryptographically protected + message has been received from the other side recently, unprotected + notifications MAY be ignored. Implementations MUST limit the rate at + which they take actions based on unprotected messages. + + Numbers of retries and lengths of timeouts are not covered in this + specification because they do not affect interoperability. It is + suggested that messages be retransmitted at least a dozen times over + a period of at least several minutes before giving up on an SA, but + different environments may require different rules. To be a good + network citizen, retranmission times MUST increase exponentially to + avoid flooding the network and making an existing congestion + situation worse. If there has only been outgoing traffic on all of + the SAs associated with an IKE_SA, it is essential to confirm + liveness of the other endpoint to avoid black holes. If no + cryptographically protected messages have been received on an IKE_SA + or any of its CHILD_SAs recently, the system needs to perform a + liveness check in order to prevent sending messages to a dead peer. + Receipt of a fresh cryptographically protected message on an IKE_SA + or any of its CHILD_SAs ensures liveness of the IKE_SA and all of its + CHILD_SAs. Note that this places requirements on the failure modes + of an IKE endpoint. An implementation MUST NOT continue sending on + any SA if some failure prevents it from receiving on all of the + associated SAs. If CHILD_SAs can fail independently from one another + without the associated IKE_SA being able to send a delete message, + then they MUST be negotiated by separate IKE_SAs. + + There is a Denial of Service attack on the initiator of an IKE_SA + + + +Kaufman, et al. Expires August 27, 2006 [Page 22] + +Internet-Draft IKEv2bis February 2006 + + + that can be avoided if the initiator takes the proper care. Since + the first two messages of an SA setup are not cryptographically + protected, an attacker could respond to the initiator's message + before the genuine responder and poison the connection setup attempt. + To prevent this, the initiator MAY be willing to accept multiple + responses to its first message, treat each as potentially legitimate, + respond to it, and then discard all the invalid half-open connections + when it receives a valid cryptographically protected response to any + one of its requests. Once a cryptographically valid response is + received, all subsequent responses should be ignored whether or not + they are cryptographically valid. + + Note that with these rules, there is no reason to negotiate and agree + upon an SA lifetime. If IKE presumes the partner is dead, based on + repeated lack of acknowledgement to an IKE message, then the IKE SA + and all CHILD_SAs set up through that IKE_SA are deleted. + + An IKE endpoint may at any time delete inactive CHILD_SAs to recover + resources used to hold their state. If an IKE endpoint chooses to + delete CHILD_SAs, it MUST send Delete payloads to the other end + notifying it of the deletion. It MAY similarly time out the IKE_SA. + {{ Clarified the SHOULD }} Closing the IKE_SA implicitly closes all + associated CHILD_SAs. In this case, an IKE endpoint SHOULD send a + Delete payload indicating that it has closed the IKE_SA unless the + other endpoint is no longer responding. + +2.5. Version Numbers and Forward Compatibility + + This document describes version 2.0 of IKE, meaning the major version + number is 2 and the minor version number is 0. {{ Restated the + relationship to RFC 4306 }} This document is a clarification of + [IKEV2]. It is likely that some implementations will want to support + version 1.0 and version 2.0, and in the future, other versions. + + The major version number should be incremented only if the packet + formats or required actions have changed so dramatically that an + older version node would not be able to interoperate with a newer + version node if it simply ignored the fields it did not understand + and took the actions specified in the older specification. The minor + version number indicates new capabilities, and MUST be ignored by a + node with a smaller minor version number, but used for informational + purposes by the node with the larger minor version number. For + example, it might indicate the ability to process a newly defined + notification message. The node with the larger minor version number + would simply note that its correspondent would not be able to + understand that message and therefore would not send it. + + If an endpoint receives a message with a higher major version number, + + + +Kaufman, et al. Expires August 27, 2006 [Page 23] + +Internet-Draft IKEv2bis February 2006 + + + it MUST drop the message and SHOULD send an unauthenticated + notification message containing the highest version number it + supports. If an endpoint supports major version n, and major version + m, it MUST support all versions between n and m. If it receives a + message with a major version that it supports, it MUST respond with + that version number. In order to prevent two nodes from being + tricked into corresponding with a lower major version number than the + maximum that they both support, IKE has a flag that indicates that + the node is capable of speaking a higher major version number. + + Thus, the major version number in the IKE header indicates the + version number of the message, not the highest version number that + the transmitter supports. If the initiator is capable of speaking + versions n, n+1, and n+2, and the responder is capable of speaking + versions n and n+1, then they will negotiate speaking n+1, where the + initiator will set the flag indicating its ability to speak a higher + version. If they mistakenly (perhaps through an active attacker + sending error messages) negotiate to version n, then both will notice + that the other side can support a higher version number, and they + MUST break the connection and reconnect using version n+1. + + Note that IKEv1 does not follow these rules, because there is no way + in v1 of noting that you are capable of speaking a higher version + number. So an active attacker can trick two v2-capable nodes into + speaking v1. {{ Demoted the SHOULD }} When a v2-capable node + negotiates down to v1, it should note that fact in its logs. + + Also for forward compatibility, all fields marked RESERVED MUST be + set to zero by an implementation running version 2.0 or later, and + their content MUST be ignored by an implementation running version + 2.0 or later ("Be conservative in what you send and liberal in what + you receive"). In this way, future versions of the protocol can use + those fields in a way that is guaranteed to be ignored by + implementations that do not understand them. Similarly, payload + types that are not defined are reserved for future use; + implementations of a version where they are undefined MUST skip over + those payloads and ignore their contents. + + IKEv2 adds a "critical" flag to each payload header for further + flexibility for forward compatibility. If the critical flag is set + and the payload type is unrecognized, the message MUST be rejected + and the response to the IKE request containing that payload MUST + include a Notify payload UNSUPPORTED_CRITICAL_PAYLOAD, indicating an + unsupported critical payload was included. If the critical flag is + not set and the payload type is unsupported, that payload MUST be + ignored. + + {{ Demoted the SHOULD in the second clause }}Although new payload + + + +Kaufman, et al. Expires August 27, 2006 [Page 24] + +Internet-Draft IKEv2bis February 2006 + + + types may be added in the future and may appear interleaved with the + fields defined in this specification, implementations MUST send the + payloads defined in this specification in the order shown in the + figures in Section 2; implementations are explicitly allowed to + reject as invalid a message with those payloads in any other order. + +2.6. Cookies + + The term "cookies" originates with Karn and Simpson [PHOTURIS] in + Photuris, an early proposal for key management with IPsec, and it has + persisted. The Internet Security Association and Key Management + Protocol (ISAKMP) [ISAKMP] fixed message header includes two eight- + octet fields titled "cookies", and that syntax is used by both IKEv1 + and IKEv2 though in IKEv2 they are referred to as the IKE SPI and + there is a new separate field in a Notify payload holding the cookie. + The initial two eight-octet fields in the header are used as a + connection identifier at the beginning of IKE packets. {{ Demoted the + SHOULD }} Each endpoint chooses one of the two SPIs and needs to + choose them so as to be unique identifiers of an IKE_SA. An SPI + value of zero is special and indicates that the remote SPI value is + not yet known by the sender. + + Unlike ESP and AH where only the recipient's SPI appears in the + header of a message, in IKE the sender's SPI is also sent in every + message. Since the SPI chosen by the original initiator of the + IKE_SA is always sent first, an endpoint with multiple IKE_SAs open + that wants to find the appropriate IKE_SA using the SPI it assigned + must look at the I(nitiator) Flag bit in the header to determine + whether it assigned the first or the second eight octets. + + In the first message of an initial IKE exchange, the initiator will + not know the responder's SPI value and will therefore set that field + to zero. + + An expected attack against IKE is state and CPU exhaustion, where the + target is flooded with session initiation requests from forged IP + addresses. This attack can be made less effective if an + implementation of a responder uses minimal CPU and commits no state + to an SA until it knows the initiator can receive packets at the + address from which it claims to be sending them. To accomplish this, + a responder SHOULD -- when it detects a large number of half-open + IKE_SAs -- reject initial IKE messages unless they contain a Notify + payload of type COOKIE. {{ Clarified the SHOULD }} If the responder + wants to set up an SA, it SHOULD instead send an unprotected IKE + message as a response and include COOKIE Notify payload with the + cookie data to be returned. Initiators who receive such responses + MUST retry the IKE_SA_INIT with a Notify payload of type COOKIE + containing the responder supplied cookie data as the first payload + + + +Kaufman, et al. Expires August 27, 2006 [Page 25] + +Internet-Draft IKEv2bis February 2006 + + + and all other payloads unchanged. The initial exchange will then be + as follows: + + Initiator Responder + ------------------------------------------------------------------- + HDR(A,0), SAi1, KEi, Ni --> + <-- HDR(A,0), N(COOKIE) + HDR(A,0), N(COOKIE), SAi1, + KEi, Ni --> + <-- HDR(A,B), SAr1, KEr, + Nr, [CERTREQ] + HDR(A,B), SK {IDi, [CERT,] + [CERTREQ,] [IDr,] AUTH, + SAi2, TSi, TSr} --> + <-- HDR(A,B), SK {IDr, [CERT,] + AUTH, SAr2, TSi, TSr} + + The first two messages do not affect any initiator or responder state + except for communicating the cookie. In particular, the message + sequence numbers in the first four messages will all be zero and the + message sequence numbers in the last two messages will be one. 'A' + is the SPI assigned by the initiator, while 'B' is the SPI assigned + by the responder. + + {{ Clarif-2.1 }} Because the responder's SPI identifies security- + related state held by the responder, and in this case no state is + created, the responder sends a zero value for the responder's SPI. + + {{ Demoted the SHOULD }} An IKE implementation should implement its + responder cookie generation in such a way as to not require any saved + state to recognize its valid cookie when the second IKE_SA_INIT + message arrives. The exact algorithms and syntax they use to + generate cookies do not affect interoperability and hence are not + specified here. The following is an example of how an endpoint could + use cookies to implement limited DOS protection. + + A good way to do this is to set the responder cookie to be: + + Cookie = <VersionIDofSecret> | Hash(Ni | IPi | SPIi | <secret>) + + where <secret> is a randomly generated secret known only to the + responder and periodically changed and | indicates concatenation. + <VersionIDofSecret> should be changed whenever <secret> is + regenerated. The cookie can be recomputed when the IKE_SA_INIT + arrives the second time and compared to the cookie in the received + message. If it matches, the responder knows that the cookie was + generated since the last change to <secret> and that IPi must be the + same as the source address it saw the first time. Incorporating SPIi + + + +Kaufman, et al. Expires August 27, 2006 [Page 26] + +Internet-Draft IKEv2bis February 2006 + + + into the calculation ensures that if multiple IKE_SAs are being set + up in parallel they will all get different cookies (assuming the + initiator chooses unique SPIi's). Incorporating Ni into the hash + ensures that an attacker who sees only message 2 can't successfully + forge a message 3. + + If a new value for <secret> is chosen while there are connections in + the process of being initialized, an IKE_SA_INIT might be returned + with other than the current <VersionIDofSecret>. The responder in + that case MAY reject the message by sending another response with a + new cookie or it MAY keep the old value of <secret> around for a + short time and accept cookies computed from either one. {{ Demoted + the SHOULD NOT }} The responder should not accept cookies + indefinitely after <secret> is changed, since that would defeat part + of the denial of service protection. {{ Demoted the SHOULD }} The + responder should change the value of <secret> frequently, especially + if under attack. + + {{ Clarif-2.1 }} In addition to cookies, there are several cases + where the IKE_SA_INIT exchange does not result in the creation of an + IKE_SA (such as INVALID_KE_PAYLOAD or NO_PROPOSAL_CHOSEN). In such a + case, sending a zero value for the Responder's SPI is correct. If + the responder sends a non-zero responder SPI, the initiator should + not reject the response for only that reason. + + {{ Clarif-2.5 }} When one party receives an IKE_SA_INIT request + containing a cookie whose contents do not match the value expected, + that party MUST ignore the cookie and process the message as if no + cookie had been included; usually this means sending a response + containing a new cookie. + +2.6.1. Interaction of COOKIE and INVALID_KE_PAYLOAD + + {{ This section added by Clarif-2.4 }} + + There are two common reasons why the initiator may have to retry the + IKE_SA_INIT exchange: the responder requests a cookie or wants a + different Diffie-Hellman group than was included in the KEi payload. + If the initiator receives a cookie from the responder, the initiator + needs to decide whether or not to include the cookie in only the next + retry of the IKE_SA_INIT request, or in all subsequent retries as + well. + + If the initiator includes the cookie only in the next retry, one + additional roundtrip may be needed in some cases. An additional + roundtrip is needed also if the initiator includes the cookie in all + retries, but the responder does not support this. For instance, if + the responder includes the SAi1 and KEi payloads in cookie + + + +Kaufman, et al. Expires August 27, 2006 [Page 27] + +Internet-Draft IKEv2bis February 2006 + + + calculation, it will reject the request by sending a new cookie. + + If both peers support including the cookie in all retries, a slightly + shorter exchange can happen. Implementations SHOULD support this + shorter exchange, but MUST NOT fail if other implementations do not + support this shorter exchange. + +2.7. Cryptographic Algorithm Negotiation + + The payload type known as "SA" indicates a proposal for a set of + choices of IPsec protocols (IKE, ESP, and/or AH) for the SA as well + as cryptographic algorithms associated with each protocol. + + An SA payload consists of one or more proposals. Each proposal + includes one or more protocols (usually one). Each protocol contains + one or more transforms -- each specifying a cryptographic algorithm. + Each transform contains zero or more attributes (attributes are + needed only if the transform identifier does not completely specify + the cryptographic algorithm). + + This hierarchical structure was designed to efficiently encode + proposals for cryptographic suites when the number of supported + suites is large because multiple values are acceptable for multiple + transforms. The responder MUST choose a single suite, which MAY be + any subset of the SA proposal following the rules below: + + Each proposal contains one or more protocols. If a proposal is + accepted, the SA response MUST contain the same protocols in the same + order as the proposal. The responder MUST accept a single proposal + or reject them all and return an error. (Example: if a single + proposal contains ESP and AH and that proposal is accepted, both ESP + and AH MUST be accepted. If ESP and AH are included in separate + proposals, the responder MUST accept only one of them). + + Each IPsec protocol proposal contains one or more transforms. Each + transform contains a transform type. The accepted cryptographic + suite MUST contain exactly one transform of each type included in the + proposal. For example: if an ESP proposal includes transforms + ENCR_3DES, ENCR_AES w/keysize 128, ENCR_AES w/keysize 256, + AUTH_HMAC_MD5, and AUTH_HMAC_SHA, the accepted suite MUST contain one + of the ENCR_ transforms and one of the AUTH_ transforms. Thus, six + combinations are acceptable. + + Since the initiator sends its Diffie-Hellman value in the + IKE_SA_INIT, it must guess the Diffie-Hellman group that the + responder will select from its list of supported groups. If the + initiator guesses wrong, the responder will respond with a Notify + payload of type INVALID_KE_PAYLOAD indicating the selected group. In + + + +Kaufman, et al. Expires August 27, 2006 [Page 28] + +Internet-Draft IKEv2bis February 2006 + + + this case, the initiator MUST retry the IKE_SA_INIT with the + corrected Diffie-Hellman group. The initiator MUST again propose its + full set of acceptable cryptographic suites because the rejection + message was unauthenticated and otherwise an active attacker could + trick the endpoints into negotiating a weaker suite than a stronger + one that they both prefer. + +2.8. Rekeying + + {{ Demoted the SHOULD }} IKE, ESP, and AH security associations use + secret keys that should be used only for a limited amount of time and + to protect a limited amount of data. This limits the lifetime of the + entire security association. When the lifetime of a security + association expires, the security association MUST NOT be used. If + there is demand, new security associations MAY be established. + Reestablishment of security associations to take the place of ones + that expire is referred to as "rekeying". + + To allow for minimal IPsec implementations, the ability to rekey SAs + without restarting the entire IKE_SA is optional. An implementation + MAY refuse all CREATE_CHILD_SA requests within an IKE_SA. If an SA + has expired or is about to expire and rekeying attempts using the + mechanisms described here fail, an implementation MUST close the + IKE_SA and any associated CHILD_SAs and then MAY start new ones. {{ + Demoted the SHOULD }} Implementations may wish to support in-place + rekeying of SAs, since doing so offers better performance and is + likely to reduce the number of packets lost during the transition. + + To rekey a CHILD_SA within an existing IKE_SA, create a new, + equivalent SA (see Section 2.17 below), and when the new one is + established, delete the old one. To rekey an IKE_SA, establish a new + equivalent IKE_SA (see Section 2.18 below) with the peer to whom the + old IKE_SA is shared using a CREATE_CHILD_SA within the existing + IKE_SA. An IKE_SA so created inherits all of the original IKE_SA's + CHILD_SAs. Use the new IKE_SA for all control messages needed to + maintain the CHILD_SAs created by the old IKE_SA, and delete the old + IKE_SA. The Delete payload to delete itself MUST be the last request + sent over an IKE_SA. + + {{ Demoted the SHOULD }} SAs should be rekeyed proactively, i.e., the + new SA should be established before the old one expires and becomes + unusable. Enough time should elapse between the time the new SA is + established and the old one becomes unusable so that traffic can be + switched over to the new SA. + + A difference between IKEv1 and IKEv2 is that in IKEv1 SA lifetimes + were negotiated. In IKEv2, each end of the SA is responsible for + enforcing its own lifetime policy on the SA and rekeying the SA when + + + +Kaufman, et al. Expires August 27, 2006 [Page 29] + +Internet-Draft IKEv2bis February 2006 + + + necessary. If the two ends have different lifetime policies, the end + with the shorter lifetime will end up always being the one to request + the rekeying. If an SA bundle has been inactive for a long time and + if an endpoint would not initiate the SA in the absence of traffic, + the endpoint MAY choose to close the SA instead of rekeying it when + its lifetime expires. {{ Demoted the SHOULD }} It should do so if + there has been no traffic since the last time the SA was rekeyed. + + Note that IKEv2 deliberately allows parallel SAs with the same + traffic selectors between common endpoints. One of the purposes of + this is to support traffic quality of service (QoS) differences among + the SAs (see [DIFFSERVFIELD], [DIFFSERVARCH], and section 4.1 of + [DIFFTUNNEL]). Hence unlike IKEv1, the combination of the endpoints + and the traffic selectors may not uniquely identify an SA between + those endpoints, so the IKEv1 rekeying heuristic of deleting SAs on + the basis of duplicate traffic selectors SHOULD NOT be used. + + {{ Demoted the SHOULD }} The node that initiated the surviving + rekeyed SA should delete the replaced SA after the new one is + established. + + There are timing windows -- particularly in the presence of lost + packets -- where endpoints may not agree on the state of an SA. The + responder to a CREATE_CHILD_SA MUST be prepared to accept messages on + an SA before sending its response to the creation request, so there + is no ambiguity for the initiator. The initiator MAY begin sending + on an SA as soon as it processes the response. The initiator, + however, cannot receive on a newly created SA until it receives and + processes the response to its CREATE_CHILD_SA request. How, then, is + the responder to know when it is OK to send on the newly created SA? + + From a technical correctness and interoperability perspective, the + responder MAY begin sending on an SA as soon as it sends its response + to the CREATE_CHILD_SA request. In some situations, however, this + could result in packets unnecessarily being dropped, so an + implementation MAY want to defer such sending. + + The responder can be assured that the initiator is prepared to + receive messages on an SA if either (1) it has received a + cryptographically valid message on the new SA, or (2) the new SA + rekeys an existing SA and it receives an IKE request to close the + replaced SA. When rekeying an SA, the responder continues to send + traffic on the old SA until one of those events occurs. When + establishing a new SA, the responder MAY defer sending messages on a + new SA until either it receives one or a timeout has occurred. {{ + Demoted the SHOULD }} If an initiator receives a message on an SA for + which it has not received a response to its CREATE_CHILD_SA request, + it interprets that as a likely packet loss and retransmits the + + + +Kaufman, et al. Expires August 27, 2006 [Page 30] + +Internet-Draft IKEv2bis February 2006 + + + CREATE_CHILD_SA request. An initiator MAY send a dummy message on a + newly created SA if it has no messages queued in order to assure the + responder that the initiator is ready to receive messages. + + {{ Clarif-5.9 }} Throughout this document, "initiator" refers to the + party who initiated the exchange being described, and "original + initiator" refers to the party who initiated the whole IKE_SA. The + "original initiator" always refers to the party who initiated the + exchange which resulted in the current IKE_SA. In other words, if + the the "original responder" starts rekeying the IKE_SA, that party + becomes the "original initiator" of the new IKE_SA. + +2.8.1. Simultaneous CHILD_SA rekeying + + {{ The first two paragraphs were moved, and the rest was added, based + on Clarif-5.11 }} + + If the two ends have the same lifetime policies, it is possible that + both will initiate a rekeying at the same time (which will result in + redundant SAs). To reduce the probability of this happening, the + timing of rekeying requests SHOULD be jittered (delayed by a random + amount of time after the need for rekeying is noticed). + + This form of rekeying may temporarily result in multiple similar SAs + between the same pairs of nodes. When there are two SAs eligible to + receive packets, a node MUST accept incoming packets through either + SA. If redundant SAs are created though such a collision, the SA + created with the lowest of the four nonces used in the two exchanges + SHOULD be closed by the endpoint that created it. {{ Clarif-5.10 }} + "Lowest" means an octet-by-octet, lexicographical comparison (instead + of, for instance, comparing the nonces as large integers). In other + words, start by comparing the first octet; if they're equal, move to + the next octet, and so on. If you reach the end of one nonce, that + nonce is the lower one. + + The following is an explanation on the impact this has on + implementations. Assume that hosts A and B have an existing IPsec SA + pair with SPIs (SPIa1,SPIb1), and both start rekeying it at the same + time: + + Host A Host B + ------------------------------------------------------------------- + send req1: N(REKEY_SA,SPIa1), + SA(..,SPIa2,..),Ni1,.. --> + <-- send req2: N(REKEY_SA,SPIb1), + SA(..,SPIb2,..),Ni2 + recv req2 <-- + + + + +Kaufman, et al. Expires August 27, 2006 [Page 31] + +Internet-Draft IKEv2bis February 2006 + + + At this point, A knows there is a simultaneous rekeying going on. + However, it cannot yet know which of the exchanges will have the + lowest nonce, so it will just note the situation and respond as + usual. + + send resp2: SA(..,SPIa3,..), + Nr1,.. --> + --> recv req1 + + Now B also knows that simultaneous rekeying is going on. It responds + as usual. + + <-- send resp1: SA(..,SPIb3,..), + Nr2,.. + recv resp1 <-- + --> recv resp2 + + At this point, there are three CHILD_SA pairs between A and B (the + old one and two new ones). A and B can now compare the nonces. + Suppose that the lowest nonce was Nr1 in message resp2; in this case, + B (the sender of req2) deletes the redundant new SA, and A (the node + that initiated the surviving rekeyed SA), deletes the old one. + + send req3: D(SPIa1) --> + <-- send req4: D(SPIb2) + --> recv req3 + <-- send resp4: D(SPIb1) + recv req4 <-- + send resp4: D(SPIa3) --> + + The rekeying is now finished. + + However, there is a second possible sequence of events that can + happen if some packets are lost in the network, resulting in + retransmissions. The rekeying begins as usual, but A's first packet + (req1) is lost. + + + + + + + + + + + + + + + +Kaufman, et al. Expires August 27, 2006 [Page 32] + +Internet-Draft IKEv2bis February 2006 + + + Host A Host B + ------------------------------------------------------------------- + send req1: N(REKEY_SA,SPIa1), + SA(..,SPIa2,..), + Ni1,.. --> (lost) + <-- send req2: N(REKEY_SA,SPIb1), + SA(..,SPIb2,..),Ni2 + recv req2 <-- + send resp2: SA(..,SPIa3,..), + Nr1,.. --> + --> recv resp2 + <-- send req3: D(SPIb1) + recv req3 <-- + send resp3: D(SPIa1) --> + --> recv resp3 + + From B's point of view, the rekeying is now completed, and since it + has not yet received A's req1, it does not even know that there was + simultaneous rekeying. However, A will continue retransmitting the + message, and eventually it will reach B. + + resend req1 --> + --> recv req1 + + To B, it looks like A is trying to rekey an SA that no longer exists; + thus, B responds to the request with something non-fatal such as + NO_PROPOSAL_CHOSEN. + + <-- send resp1: N(NO_PROPOSAL_CHOSEN) + recv resp1 <-- + + When A receives this error, it already knows there was simultaneous + rekeying, so it can ignore the error message. + +2.8.2. Rekeying the IKE_SA Versus Reauthentication + + {{ Added this section from Clarif-5.2 }} + + Rekeying the IKE_SA and reauthentication are different concepts in + IKEv2. Rekeying the IKE_SA establishes new keys for the IKE_SA and + resets the Message ID counters, but it does not authenticate the + parties again (no AUTH or EAP payloads are involved). + + Although rekeying the IKE_SA may be important in some environments, + reauthentication (the verification that the parties still have access + to the long-term credentials) is often more important. + + IKEv2 does not have any special support for reauthentication. + + + +Kaufman, et al. Expires August 27, 2006 [Page 33] + +Internet-Draft IKEv2bis February 2006 + + + Reauthentication is done by creating a new IKE_SA from scratch (using + IKE_SA_INIT/IKE_AUTH exchanges, without any REKEY_SA notify + payloads), creating new CHILD_SAs within the new IKE_SA (without + REKEY_SA notify payloads), and finally deleting the old IKE_SA (which + deletes the old CHILD_SAs as well). + + This means that reauthentication also establishes new keys for the + IKE_SA and CHILD_SAs. Therefore, while rekeying can be performed + more often than reauthentication, the situation where "authentication + lifetime" is shorter than "key lifetime" does not make sense. + + While creation of a new IKE_SA can be initiated by either party + (initiator or responder in the original IKE_SA), the use of EAP + authentication and/or configuration payloads means in practice that + reauthentication has to be initiated by the same party as the + original IKE_SA. IKEv2 does not currently allow the responder to + request reauthentication in this case; however, there is ongoing work + to add this functionality [REAUTH]. + +2.9. Traffic Selector Negotiation + + {{ Clarif-7.2 }} When an RFC4301-compliant IPsec subsystem receives + an IP packet and matches a "protect" selector in its Security Policy + Database (SPD), the subsystem protects that packet with IPsec. When + no SA exists yet, it is the task of IKE to create it. Maintenance of + a system's SPD is outside the scope of IKE (see [PFKEY] for an + example protocol), though some implementations might update their SPD + in connection with the running of IKE (for an example scenario, see + Section 1.1.3). + + Traffic Selector (TS) payloads allow endpoints to communicate some of + the information from their SPD to their peers. TS payloads specify + the selection criteria for packets that will be forwarded over the + newly set up SA. This can serve as a consistency check in some + scenarios to assure that the SPDs are consistent. In others, it + guides the dynamic update of the SPD. + + Two TS payloads appear in each of the messages in the exchange that + creates a CHILD_SA pair. Each TS payload contains one or more + Traffic Selectors. Each Traffic Selector consists of an address + range (IPv4 or IPv6), a port range, and an IP protocol ID. In + support of the scenario described in Section 1.1.3, an initiator may + request that the responder assign an IP address and tell the + initiator what it is. {{ Clarif-6.1 }} That request is done using + configuration payloads, not traffic selectors. An address in a TSi + payload in a response does not mean that the responder has assigned + that address to the initiator: it only means that if packets matching + these traffic selectors are sent by the initiator, IPsec processing + + + +Kaufman, et al. Expires August 27, 2006 [Page 34] + +Internet-Draft IKEv2bis February 2006 + + + can be performed as agreed for this SA. + + IKEv2 allows the responder to choose a subset of the traffic proposed + by the initiator. This could happen when the configurations of the + two endpoints are being updated but only one end has received the new + information. Since the two endpoints may be configured by different + people, the incompatibility may persist for an extended period even + in the absence of errors. It also allows for intentionally different + configurations, as when one end is configured to tunnel all addresses + and depends on the other end to have the up-to-date list. + + The first of the two TS payloads is known as TSi (Traffic Selector- + initiator). The second is known as TSr (Traffic Selector-responder). + TSi specifies the source address of traffic forwarded from (or the + destination address of traffic forwarded to) the initiator of the + CHILD_SA pair. TSr specifies the destination address of the traffic + forwarded to (or the source address of the traffic forwarded from) + the responder of the CHILD_SA pair. For example, if the original + initiator request the creation of a CHILD_SA pair, and wishes to + tunnel all traffic from subnet 192.0.1.* on the initiator's side to + subnet 192.0.2.* on the responder's side, the initiator would include + a single traffic selector in each TS payload. TSi would specify the + address range (192.0.1.0 - 192.0.1.255) and TSr would specify the + address range (192.0.2.0 - 192.0.2.255). Assuming that proposal was + acceptable to the responder, it would send identical TS payloads + back. (Note: The IP address range 192.0.2.* has been reserved for + use in examples in RFCs and similar documents. This document needed + two such ranges, and so also used 192.0.1.*. This should not be + confused with any actual address.) + + The responder is allowed to narrow the choices by selecting a subset + of the traffic, for instance by eliminating or narrowing the range of + one or more members of the set of traffic selectors, provided the set + does not become the NULL set. + + It is possible for the responder's policy to contain multiple smaller + ranges, all encompassed by the initiator's traffic selector, and with + the responder's policy being that each of those ranges should be sent + over a different SA. Continuing the example above, the responder + might have a policy of being willing to tunnel those addresses to and + from the initiator, but might require that each address pair be on a + separately negotiated CHILD_SA. If the initiator generated its + request in response to an incoming packet from 192.0.1.43 to + 192.0.2.123, there would be no way for the responder to determine + which pair of addresses should be included in this tunnel, and it + would have to make a guess or reject the request with a status of + SINGLE_PAIR_REQUIRED. + + + + +Kaufman, et al. Expires August 27, 2006 [Page 35] + +Internet-Draft IKEv2bis February 2006 + + + {{ Clarif-4.11 }} Few implementations will have policies that require + separate SAs for each address pair. Because of this, if only some + part (or parts) of the TSi/TSr proposed by the initiator is (are) + acceptable to the responder, responders SHOULD narrow TSi/TSr to an + acceptable subset rather than use SINGLE_PAIR_REQUIRED. + + To enable the responder to choose the appropriate range in this case, + if the initiator has requested the SA due to a data packet, the + initiator SHOULD include as the first traffic selector in each of TSi + and TSr a very specific traffic selector including the addresses in + the packet triggering the request. In the example, the initiator + would include in TSi two traffic selectors: the first containing the + address range (192.0.1.43 - 192.0.1.43) and the source port and IP + protocol from the packet and the second containing (192.0.1.0 - + 192.0.1.255) with all ports and IP protocols. The initiator would + similarly include two traffic selectors in TSr. + + If the responder's policy does not allow it to accept the entire set + of traffic selectors in the initiator's request, but does allow him + to accept the first selector of TSi and TSr, then the responder MUST + narrow the traffic selectors to a subset that includes the + initiator's first choices. In this example, the responder might + respond with TSi being (192.0.1.43 - 192.0.1.43) with all ports and + IP protocols. + + If the initiator creates the CHILD_SA pair not in response to an + arriving packet, but rather, say, upon startup, then there may be no + specific addresses the initiator prefers for the initial tunnel over + any other. In that case, the first values in TSi and TSr MAY be + ranges rather than specific values, and the responder chooses a + subset of the initiator's TSi and TSr that are acceptable. If more + than one subset is acceptable but their union is not, the responder + MUST accept some subset and MAY include a Notify payload of type + ADDITIONAL_TS_POSSIBLE to indicate that the initiator might want to + try again. This case will occur only when the initiator and + responder are configured differently from one another. If the + initiator and responder agree on the granularity of tunnels, the + initiator will never request a tunnel wider than the responder will + accept. {{ Demoted the SHOULD }} Such misconfigurations should be + recorded in error logs. + + {{ Clarif-4.10 }} A concise summary of the narrowing process is: + + o If the responder's policy does not allow any part of the traffic + covered by TSi/TSr, it responds with TS_UNACCEPTABLE. + + o If the responder's policy allows the entire set of traffic covered + by TSi/TSr, no narrowing is necessary, and the responder can + + + +Kaufman, et al. Expires August 27, 2006 [Page 36] + +Internet-Draft IKEv2bis February 2006 + + + return the same TSi/TSr values. + + o Otherwise, narrowing is needed. If the responder's policy allows + all traffic covered by TSi[1]/TSr[1] (the first traffic selectors + in TSi/TSr) but not entire TSi/TSr, the responder narrows to an + acceptable subset of TSi/TSr that includes TSi[1]/TSr[1]. + + o If the responder's policy does not allow all traffic covered by + TSi[1]/TSr[1], but does allow some parts of TSi/TSr, it narrows to + an acceptable subset of TSi/TSr. + + In the last two cases, there may be several subsets that are + acceptable (but their union is not); in this case, the responder + arbitrarily chooses one of them, and includes ADDITIONAL_TS_POSSIBLE + notification in the response. + +2.9.1. Traffic Selectors Violating Own Policy + + {{ Clarif-4.12 }} + + When creating a new SA, the initiator needs to avoid proposing + traffic selectors that violate its own policy. If this rule is not + followed, valid traffic may be dropped. + + This is best illustrated by an example. Suppose that host A has a + policy whose effect is that traffic to 192.0.1.66 is sent via host B + encrypted using AES, and traffic to all other hosts in 192.0.1.0/24 + is also sent via B, but must use 3DES. Suppose also that host B + accepts any combination of AES and 3DES. + + If host A now proposes an SA that uses 3DES, and includes TSr + containing (192.0.1.0-192.0.1.0.255), this will be accepted by host + B. Now, host B can also use this SA to send traffic from 192.0.1.66, + but those packets will be dropped by A since it requires the use of + AES for those traffic. Even if host A creates a new SA only for + 192.0.1.66 that uses AES, host B may freely continue to use the first + SA for the traffic. In this situation, when proposing the SA, host A + should have followed its own policy, and included a TSr containing + ((192.0.1.0-192.0.1.65),(192.0.1.67-192.0.1.255)) instead. + + In general, if (1) the initiator makes a proposal "for traffic X + (TSi/TSr), do SA", and (2) for some subset X' of X, the initiator + does not actually accept traffic X' with SA, and (3) the initiator + would be willing to accept traffic X' with some SA' (!=SA), valid + traffic can be unnecessarily dropped since the responder can apply + either SA or SA' to traffic X'. + + + + + +Kaufman, et al. Expires August 27, 2006 [Page 37] + +Internet-Draft IKEv2bis February 2006 + + +2.10. Nonces + + The IKE_SA_INIT messages each contain a nonce. These nonces are used + as inputs to cryptographic functions. The CREATE_CHILD_SA request + and the CREATE_CHILD_SA response also contain nonces. These nonces + are used to add freshness to the key derivation technique used to + obtain keys for CHILD_SA, and to ensure creation of strong pseudo- + random bits from the Diffie-Hellman key. Nonces used in IKEv2 MUST + be randomly chosen, MUST be at least 128 bits in size, and MUST be at + least half the key size of the negotiated prf. ("prf" refers to + "pseudo-random function", one of the cryptographic algorithms + negotiated in the IKE exchange.) {{ Clarif-7.4 }} However, the + initiator chooses the nonce before the outcome of the negotiation is + known. Because of that, the nonce has to be long enough for all the + PRFs being proposed. If the same random number source is used for + both keys and nonces, care must be taken to ensure that the latter + use does not compromise the former. + +2.11. Address and Port Agility + + IKE runs over UDP ports 500 and 4500, and implicitly sets up ESP and + AH associations for the same IP addresses it runs over. The IP + addresses and ports in the outer header are, however, not themselves + cryptographically protected, and IKE is designed to work even through + Network Address Translation (NAT) boxes. An implementation MUST + accept incoming requests even if the source port is not 500 or 4500, + and MUST respond to the address and port from which the request was + received. It MUST specify the address and port at which the request + was received as the source address and port in the response. IKE + functions identically over IPv4 or IPv6. + +2.12. Reuse of Diffie-Hellman Exponentials + + IKE generates keying material using an ephemeral Diffie-Hellman + exchange in order to gain the property of "perfect forward secrecy". + This means that once a connection is closed and its corresponding + keys are forgotten, even someone who has recorded all of the data + from the connection and gets access to all of the long-term keys of + the two endpoints cannot reconstruct the keys used to protect the + conversation without doing a brute force search of the session key + space. + + Achieving perfect forward secrecy requires that when a connection is + closed, each endpoint MUST forget not only the keys used by the + connection but also any information that could be used to recompute + those keys. In particular, it MUST forget the secrets used in the + Diffie-Hellman calculation and any state that may persist in the + state of a pseudo-random number generator that could be used to + + + +Kaufman, et al. Expires August 27, 2006 [Page 38] + +Internet-Draft IKEv2bis February 2006 + + + recompute the Diffie-Hellman secrets. + + Since the computing of Diffie-Hellman exponentials is computationally + expensive, an endpoint may find it advantageous to reuse those + exponentials for multiple connection setups. There are several + reasonable strategies for doing this. An endpoint could choose a new + exponential only periodically though this could result in less-than- + perfect forward secrecy if some connection lasts for less than the + lifetime of the exponential. Or it could keep track of which + exponential was used for each connection and delete the information + associated with the exponential only when some corresponding + connection was closed. This would allow the exponential to be reused + without losing perfect forward secrecy at the cost of maintaining + more state. + + Decisions as to whether and when to reuse Diffie-Hellman exponentials + is a private decision in the sense that it will not affect + interoperability. An implementation that reuses exponentials MAY + choose to remember the exponential used by the other endpoint on past + exchanges and if one is reused to avoid the second half of the + calculation. + +2.13. Generating Keying Material + + In the context of the IKE_SA, four cryptographic algorithms are + negotiated: an encryption algorithm, an integrity protection + algorithm, a Diffie-Hellman group, and a pseudo-random function + (prf). The pseudo-random function is used for the construction of + keying material for all of the cryptographic algorithms used in both + the IKE_SA and the CHILD_SAs. + + We assume that each encryption algorithm and integrity protection + algorithm uses a fixed-size key and that any randomly chosen value of + that fixed size can serve as an appropriate key. For algorithms that + accept a variable length key, a fixed key size MUST be specified as + part of the cryptographic transform negotiated. For algorithms for + which not all values are valid keys (such as DES or 3DES with key + parity), the algorithm by which keys are derived from arbitrary + values MUST be specified by the cryptographic transform. For + integrity protection functions based on Hashed Message Authentication + Code (HMAC), the fixed key size is the size of the output of the + underlying hash function. When the prf function takes a variable + length key, variable length data, and produces a fixed-length output + (e.g., when using HMAC), the formulas in this document apply. When + the key for the prf function has fixed length, the data provided as a + key is truncated or padded with zeros as necessary unless exceptional + processing is explained following the formula. + + + + +Kaufman, et al. Expires August 27, 2006 [Page 39] + +Internet-Draft IKEv2bis February 2006 + + + Keying material will always be derived as the output of the + negotiated prf algorithm. Since the amount of keying material needed + may be greater than the size of the output of the prf algorithm, we + will use the prf iteratively. We will use the terminology prf+ to + describe the function that outputs a pseudo-random stream based on + the inputs to a prf as follows: (where | indicates concatenation) + + prf+ (K,S) = T1 | T2 | T3 | T4 | ... + + where: + T1 = prf (K, S | 0x01) + T2 = prf (K, T1 | S | 0x02) + T3 = prf (K, T2 | S | 0x03) + T4 = prf (K, T3 | S | 0x04) + + continuing as needed to compute all required keys. The keys are + taken from the output string without regard to boundaries (e.g., if + the required keys are a 256-bit Advanced Encryption Standard (AES) + key and a 160-bit HMAC key, and the prf function generates 160 bits, + the AES key will come from T1 and the beginning of T2, while the HMAC + key will come from the rest of T2 and the beginning of T3). + + The constant concatenated to the end of each string feeding the prf + is a single octet. prf+ in this document is not defined beyond 255 + times the size of the prf output. + +2.14. Generating Keying Material for the IKE_SA + + The shared keys are computed as follows. A quantity called SKEYSEED + is calculated from the nonces exchanged during the IKE_SA_INIT + exchange and the Diffie-Hellman shared secret established during that + exchange. SKEYSEED is used to calculate seven other secrets: SK_d + used for deriving new keys for the CHILD_SAs established with this + IKE_SA; SK_ai and SK_ar used as a key to the integrity protection + algorithm for authenticating the component messages of subsequent + exchanges; SK_ei and SK_er used for encrypting (and of course + decrypting) all subsequent exchanges; and SK_pi and SK_pr, which are + used when generating an AUTH payload. + + SKEYSEED and its derivatives are computed as follows: + + SKEYSEED = prf(Ni | Nr, g^ir) + + {SK_d | SK_ai | SK_ar | SK_ei | SK_er | SK_pi | SK_pr } + = prf+ (SKEYSEED, Ni | Nr | SPIi | SPIr ) + + (indicating that the quantities SK_d, SK_ai, SK_ar, SK_ei, SK_er, + SK_pi, and SK_pr are taken in order from the generated bits of the + + + +Kaufman, et al. Expires August 27, 2006 [Page 40] + +Internet-Draft IKEv2bis February 2006 + + + prf+). g^ir is the shared secret from the ephemeral Diffie-Hellman + exchange. g^ir is represented as a string of octets in big endian + order padded with zeros if necessary to make it the length of the + modulus. Ni and Nr are the nonces, stripped of any headers. If the + negotiated prf takes a fixed-length key and the lengths of Ni and Nr + do not add up to that length, half the bits must come from Ni and + half from Nr, taking the first bits of each. + + The two directions of traffic flow use different keys. The keys used + to protect messages from the original initiator are SK_ai and SK_ei. + The keys used to protect messages in the other direction are SK_ar + and SK_er. Each algorithm takes a fixed number of bits of keying + material, which is specified as part of the algorithm. For integrity + algorithms based on a keyed hash, the key size is always equal to the + length of the output of the underlying hash function. + +2.15. Authentication of the IKE_SA + + When not using extensible authentication (see Section 2.16), the + peers are authenticated by having each sign (or MAC using a shared + secret as the key) a block of data. For the responder, the octets to + be signed start with the first octet of the first SPI in the header + of the second message and end with the last octet of the last payload + in the second message. Appended to this (for purposes of computing + the signature) are the initiator's nonce Ni (just the value, not the + payload containing it), and the value prf(SK_pr,IDr') where IDr' is + the responder's ID payload excluding the fixed header. Note that + neither the nonce Ni nor the value prf(SK_pr,IDr') are transmitted. + Similarly, the initiator signs the first message, starting with the + first octet of the first SPI in the header and ending with the last + octet of the last payload. Appended to this (for purposes of + computing the signature) are the responder's nonce Nr, and the value + prf(SK_pi,IDi'). In the above calculation, IDi' and IDr' are the + entire ID payloads excluding the fixed header. It is critical to the + security of the exchange that each side sign the other side's nonce. + + {{ Clarif-3.1 }} + + The initiator's signed octets can be described as: + + InitiatorSignedOctets = RealMessage1 | NonceRData | MACedIDForI + GenIKEHDR = [ four octets 0 if using port 4500 ] | RealIKEHDR + RealIKEHDR = SPIi | SPIr | . . . | Length + RealMessage1 = RealIKEHDR | RestOfMessage1 + NonceRPayload = PayloadHeader | NonceRData + InitiatorIDPayload = PayloadHeader | RestOfIDPayload + RestOfInitIDPayload = IDType | RESERVED | InitIDData + MACedIDForI = prf(SK_pi, RestOfInitIDPayload) + + + +Kaufman, et al. Expires August 27, 2006 [Page 41] + +Internet-Draft IKEv2bis February 2006 + + + The responder's signed octets can be described as: + + ResponderSignedOctets = RealMessage2 | NonceIData | MACedIDForR + GenIKEHDR = [ four octets 0 if using port 4500 ] | RealIKEHDR + RealIKEHDR = SPIi | SPIr | . . . | Length + RealMessage2 = RealIKEHDR | RestOfMessage2 + NonceIPayload = PayloadHeader | NonceIData + ResponderIDPayload = PayloadHeader | RestOfIDPayload + RestOfRespIDPayload = IDType | RESERVED | InitIDData + MACedIDForR = prf(SK_pr, RestOfRespIDPayload) + + Note that all of the payloads are included under the signature, + including any payload types not defined in this document. If the + first message of the exchange is sent twice (the second time with a + responder cookie and/or a different Diffie-Hellman group), it is the + second version of the message that is signed. + + Optionally, messages 3 and 4 MAY include a certificate, or + certificate chain providing evidence that the key used to compute a + digital signature belongs to the name in the ID payload. The + signature or MAC will be computed using algorithms dictated by the + type of key used by the signer, and specified by the Auth Method + field in the Authentication payload. There is no requirement that + the initiator and responder sign with the same cryptographic + algorithms. The choice of cryptographic algorithms depends on the + type of key each has. In particular, the initiator may be using a + shared key while the responder may have a public signature key and + certificate. It will commonly be the case (but it is not required) + that if a shared secret is used for authentication that the same key + is used in both directions. Note that it is a common but typically + insecure practice to have a shared key derived solely from a user- + chosen password without incorporating another source of randomness. + + This is typically insecure because user-chosen passwords are unlikely + to have sufficient unpredictability to resist dictionary attacks and + these attacks are not prevented in this authentication method. + (Applications using password-based authentication for bootstrapping + and IKE_SA should use the authentication method in Section 2.16, + which is designed to prevent off-line dictionary attacks.) {{ Demoted + the SHOULD }} The pre-shared key needs to contain as much + unpredictability as the strongest key being negotiated. In the case + of a pre-shared key, the AUTH value is computed as: + + AUTH = prf(prf(Shared Secret,"Key Pad for IKEv2"), <msg octets>) + + where the string "Key Pad for IKEv2" is 17 ASCII characters without + null termination. The shared secret can be variable length. The pad + string is added so that if the shared secret is derived from a + + + +Kaufman, et al. Expires August 27, 2006 [Page 42] + +Internet-Draft IKEv2bis February 2006 + + + password, the IKE implementation need not store the password in + cleartext, but rather can store the value prf(Shared Secret,"Key Pad + for IKEv2"), which could not be used as a password equivalent for + protocols other than IKEv2. As noted above, deriving the shared + secret from a password is not secure. This construction is used + because it is anticipated that people will do it anyway. The + management interface by which the Shared Secret is provided MUST + accept ASCII strings of at least 64 octets and MUST NOT add a null + terminator before using them as shared secrets. It MUST also accept + a hex encoding of the Shared Secret. The management interface MAY + accept other encodings if the algorithm for translating the encoding + to a binary string is specified. + + {{ Clarif-3.7 }} If the negotiated prf takes a fixed-size key, the + shared secret MUST be of that fixed size. This requirement means + that it is difficult to use these PRFs with shared key authentication + because it limits the shared secrets that can be used. Thus, PRFs + that require a fixed-size key SHOULD NOT be used with shared key + authentication. For example, PRF_AES128_CBC [PRFAES128CBC] + originally used fixed key sizes; that RFC has been updated to handle + variable key sizes in [PRFAES128CBC-bis]. Note that Section 2.13 + also contains text that is related to PRFs with fixed key size. + However, the text in that section applies only to the prf+ + construction. + +2.16. Extensible Authentication Protocol Methods + + In addition to authentication using public key signatures and shared + secrets, IKE supports authentication using methods defined in RFC + 3748 [EAP]. Typically, these methods are asymmetric (designed for a + user authenticating to a server), and they may not be mutual. {{ In + the next sentence, changed "public key signature based" to "strong" + }} For this reason, these protocols are typically used to + authenticate the initiator to the responder and MUST be used in + conjunction with a strong authentication of the responder to the + initiator. These methods are often associated with mechanisms + referred to as "Legacy Authentication" mechanisms. + + While this memo references [EAP] with the intent that new methods can + be added in the future without updating this specification, some + simpler variations are documented here and in Section 3.16. [EAP] + defines an authentication protocol requiring a variable number of + messages. Extensible Authentication is implemented in IKE as + additional IKE_AUTH exchanges that MUST be completed in order to + initialize the IKE_SA. + + An initiator indicates a desire to use extensible authentication by + leaving out the AUTH payload from message 3. By including an IDi + + + +Kaufman, et al. Expires August 27, 2006 [Page 43] + +Internet-Draft IKEv2bis February 2006 + + + payload but not an AUTH payload, the initiator has declared an + identity but has not proven it. If the responder is willing to use + an extensible authentication method, it will place an Extensible + Authentication Protocol (EAP) payload in message 4 and defer sending + SAr2, TSi, and TSr until initiator authentication is complete in a + subsequent IKE_AUTH exchange. In the case of a minimal extensible + authentication, the initial SA establishment will appear as follows: + + Initiator Responder + ------------------------------------------------------------------- + HDR, SAi1, KEi, Ni --> + <-- HDR, SAr1, KEr, Nr, [CERTREQ] + HDR, SK {IDi, [CERTREQ,] + [IDr,] SAi2, + TSi, TSr} --> + <-- HDR, SK {IDr, [CERT,] AUTH, + EAP } + HDR, SK {EAP} --> + <-- HDR, SK {EAP (success)} + HDR, SK {AUTH} --> + <-- HDR, SK {AUTH, SAr2, TSi, TSr } + + {{ Clarif-3.10 }} As described in Section 2.2, when EAP is used, each + pair of IKE_SA initial setup messages will have their message numbers + incremented; the first pair of AUTH messages will have an ID of 1, + the second will be 2, and so on. + + For EAP methods that create a shared key as a side effect of + authentication, that shared key MUST be used by both the initiator + and responder to generate AUTH payloads in messages 7 and 8 using the + syntax for shared secrets specified in Section 2.15. The shared key + from EAP is the field from the EAP specification named MSK. The + shared key generated during an IKE exchange MUST NOT be used for any + other purpose. + + EAP methods that do not establish a shared key SHOULD NOT be used, as + they are subject to a number of man-in-the-middle attacks [EAPMITM] + if these EAP methods are used in other protocols that do not use a + server-authenticated tunnel. Please see the Security Considerations + section for more details. If EAP methods that do not generate a + shared key are used, the AUTH payloads in messages 7 and 8 MUST be + generated using SK_pi and SK_pr, respectively. + + {{ Demoted the SHOULD }} The initiator of an IKE_SA using EAP needs + to be capable of extending the initial protocol exchange to at least + ten IKE_AUTH exchanges in the event the responder sends notification + messages and/or retries the authentication prompt. Once the protocol + exchange defined by the chosen EAP authentication method has + + + +Kaufman, et al. Expires August 27, 2006 [Page 44] + +Internet-Draft IKEv2bis February 2006 + + + successfully terminated, the responder MUST send an EAP payload + containing the Success message. Similarly, if the authentication + method has failed, the responder MUST send an EAP payload containing + the Failure message. The responder MAY at any time terminate the IKE + exchange by sending an EAP payload containing the Failure message. + + Following such an extended exchange, the EAP AUTH payloads MUST be + included in the two messages following the one containing the EAP + Success message. + + {{ Clarif-3.5 }} When the initiator authentication uses EAP, it is + possible that the contents of the IDi payload is used only for AAA + routing purposes and selecting which EAP method to use. This value + may be different from the identity authenticated by the EAP method. + It is important that policy lookups and access control decisions use + the actual authenticated identity. Often the EAP server is + implemented in a separate AAA server that communicates with the IKEv2 + responder. In this case, the authenticated identity has to be sent + from the AAA server to the IKEv2 responder. + + {{ Clarif-3.8 }} The information in Section 2.17 about PRFs with + fixed-size keys also applies to EAP authentication. For instance, a + PRF that requires a 128-bit key cannot be used with EAP because + specifies that the MSK is at least 512 bits long. + +2.17. Generating Keying Material for CHILD_SAs + + A single CHILD_SA is created by the IKE_AUTH exchange, and additional + CHILD_SAs can optionally be created in CREATE_CHILD_SA exchanges. + Keying material for them is generated as follows: + + KEYMAT = prf+(SK_d, Ni | Nr) + + Where Ni and Nr are the nonces from the IKE_SA_INIT exchange if this + request is the first CHILD_SA created or the fresh Ni and Nr from the + CREATE_CHILD_SA exchange if this is a subsequent creation. + + For CREATE_CHILD_SA exchanges including an optional Diffie-Hellman + exchange, the keying material is defined as: + + KEYMAT = prf+(SK_d, g^ir (new) | Ni | Nr ) + + where g^ir (new) is the shared secret from the ephemeral Diffie- + Hellman exchange of this CREATE_CHILD_SA exchange (represented as an + octet string in big endian order padded with zeros in the high-order + bits if necessary to make it the length of the modulus). + + A single CHILD_SA negotiation may result in multiple security + + + +Kaufman, et al. Expires August 27, 2006 [Page 45] + +Internet-Draft IKEv2bis February 2006 + + + associations. ESP and AH SAs exist in pairs (one in each direction), + and four SAs could be created in a single CHILD_SA negotiation if a + combination of ESP and AH is being negotiated. + + Keying material MUST be taken from the expanded KEYMAT in the + following order: + + o All keys for SAs carrying data from the initiator to the responder + are taken before SAs going in the reverse direction. + + o If multiple IPsec protocols are negotiated, keying material is + taken in the order in which the protocol headers will appear in + the encapsulated packet. + + o If a single protocol has both encryption and authentication keys, + the encryption key is taken from the first octets of KEYMAT and + the authentication key is taken from the next octets. + + Each cryptographic algorithm takes a fixed number of bits of keying + material specified as part of the algorithm. + +2.18. Rekeying IKE_SAs Using a CREATE_CHILD_SA Exchange + + The CREATE_CHILD_SA exchange can be used to rekey an existing IKE_SA + (see Section 2.8). {{ Clarif-5.3 }} New initiator and responder SPIs + are supplied in the SPI fields in the Proposal structures inside the + Security Association (SA) payloads (not the SPI fields in the IKE + header). The TS payloads are omitted when rekeying an IKE_SA. + SKEYSEED for the new IKE_SA is computed using SK_d from the existing + IKE_SA as follows: + + SKEYSEED = prf(SK_d (old), [g^ir (new)] | Ni | Nr) + + where g^ir (new) is the shared secret from the ephemeral Diffie- + Hellman exchange of this CREATE_CHILD_SA exchange (represented as an + octet string in big endian order padded with zeros if necessary to + make it the length of the modulus) and Ni and Nr are the two nonces + stripped of any headers. + + {{ Clarif-5.5 }} The old and new IKE_SA may have selected a different + PRF. Because the rekeying exchange belongs to the old IKE_SA, it is + the old IKE_SA's PRF that is used. Note that this may not work if + the new IKE_SA's PRF has a fixed key size because the output of the + PRF may not be of the correct size. + + The new IKE_SA MUST reset its message counters to 0. + + SK_d, SK_ai, SK_ar, SK_ei, and SK_er are computed from SKEYSEED as + + + +Kaufman, et al. Expires August 27, 2006 [Page 46] + +Internet-Draft IKEv2bis February 2006 + + + specified in Section 2.14. + +2.19. Requesting an Internal Address on a Remote Network + + Most commonly occurring in the endpoint-to-security-gateway scenario, + an endpoint may need an IP address in the network protected by the + security gateway and may need to have that address dynamically + assigned. A request for such a temporary address can be included in + any request to create a CHILD_SA (including the implicit request in + message 3) by including a CP payload. + + This function provides address allocation to an IPsec Remote Access + Client (IRAC) trying to tunnel into a network protected by an IPsec + Remote Access Server (IRAS). Since the IKE_AUTH exchange creates an + IKE_SA and a CHILD_SA, the IRAC MUST request the IRAS-controlled + address (and optionally other information concerning the protected + network) in the IKE_AUTH exchange. The IRAS may procure an address + for the IRAC from any number of sources such as a DHCP/BOOTP server + or its own address pool. + + Initiator Responder + ------------------------------------------------------------------- + HDR, SK {IDi, [CERT,] + [CERTREQ,] [IDr,] AUTH, + CP(CFG_REQUEST), SAi2, + TSi, TSr} --> + <-- HDR, SK {IDr, [CERT,] AUTH, + CP(CFG_REPLY), SAr2, + TSi, TSr} + + In all cases, the CP payload MUST be inserted before the SA payload. + In variations of the protocol where there are multiple IKE_AUTH + exchanges, the CP payloads MUST be inserted in the messages + containing the SA payloads. + + CP(CFG_REQUEST) MUST contain at least an INTERNAL_ADDRESS attribute + (either IPv4 or IPv6) but MAY contain any number of additional + attributes the initiator wants returned in the response. + + For example, message from initiator to responder: + + CP(CFG_REQUEST)= + INTERNAL_ADDRESS() + TSi = (0, 0-65535,0.0.0.0-255.255.255.255) + TSr = (0, 0-65535,0.0.0.0-255.255.255.255) + + NOTE: Traffic Selectors contain (protocol, port range, address + range). + + + +Kaufman, et al. Expires August 27, 2006 [Page 47] + +Internet-Draft IKEv2bis February 2006 + + + Message from responder to initiator: + + CP(CFG_REPLY)= + INTERNAL_ADDRESS(192.0.2.202) + INTERNAL_NETMASK(255.255.255.0) + INTERNAL_SUBNET(192.0.2.0/255.255.255.0) + TSi = (0, 0-65535,192.0.2.202-192.0.2.202) + TSr = (0, 0-65535,192.0.2.0-192.0.2.255) + + All returned values will be implementation dependent. As can be seen + in the above example, the IRAS MAY also send other attributes that + were not included in CP(CFG_REQUEST) and MAY ignore the non- + mandatory attributes that it does not support. + + The responder MUST NOT send a CFG_REPLY without having first received + a CP(CFG_REQUEST) from the initiator, because we do not want the IRAS + to perform an unnecessary configuration lookup if the IRAC cannot + process the REPLY. In the case where the IRAS's configuration + requires that CP be used for a given identity IDi, but IRAC has + failed to send a CP(CFG_REQUEST), IRAS MUST fail the request, and + terminate the IKE exchange with a FAILED_CP_REQUIRED error. + +2.20. Requesting the Peer's Version + + An IKE peer wishing to inquire about the other peer's IKE software + version information MAY use the method below. This is an example of + a configuration request within an INFORMATIONAL exchange, after the + IKE_SA and first CHILD_SA have been created. + + An IKE implementation MAY decline to give out version information + prior to authentication or even after authentication to prevent + trolling in case some implementation is known to have some security + weakness. In that case, it MUST either return an empty string or no + CP payload if CP is not supported. + + Initiator Responder + ------------------------------------------------------------------- + HDR, SK{CP(CFG_REQUEST)} --> + <-- HDR, SK{CP(CFG_REPLY)} + + CP(CFG_REQUEST)= + APPLICATION_VERSION("") + + CP(CFG_REPLY) APPLICATION_VERSION("foobar v1.3beta, (c) Foo Bar + Inc.") + + + + + + +Kaufman, et al. Expires August 27, 2006 [Page 48] + +Internet-Draft IKEv2bis February 2006 + + +2.21. Error Handling + + There are many kinds of errors that can occur during IKE processing. + If a request is received that is badly formatted or unacceptable for + reasons of policy (e.g., no matching cryptographic algorithms), the + response MUST contain a Notify payload indicating the error. If an + error occurs outside the context of an IKE request (e.g., the node is + getting ESP messages on a nonexistent SPI), the node SHOULD initiate + an INFORMATIONAL exchange with a Notify payload describing the + problem. + + Errors that occur before a cryptographically protected IKE_SA is + established must be handled very carefully. There is a trade-off + between wanting to be helpful in diagnosing a problem and responding + to it and wanting to avoid being a dupe in a denial of service attack + based on forged messages. + + If a node receives a message on UDP port 500 or 4500 outside the + context of an IKE_SA known to it (and not a request to start one), it + may be the result of a recent crash of the node. If the message is + marked as a response, the node MAY audit the suspicious event but + MUST NOT respond. If the message is marked as a request, the node + MAY audit the suspicious event and MAY send a response. If a + response is sent, the response MUST be sent to the IP address and + port from whence it came with the same IKE SPIs and the Message ID + copied. The response MUST NOT be cryptographically protected and + MUST contain a Notify payload indicating INVALID_IKE_SPI. + + A node receiving such an unprotected Notify payload MUST NOT respond + and MUST NOT change the state of any existing SAs. The message might + be a forgery or might be a response the genuine correspondent was + tricked into sending. {{ Demoted two SHOULDs }} A node should treat + such a message (and also a network message like ICMP destination + unreachable) as a hint that there might be problems with SAs to that + IP address and should initiate a liveness test for any such IKE_SA. + An implementation SHOULD limit the frequency of such tests to avoid + being tricked into participating in a denial of service attack. + + A node receiving a suspicious message from an IP address with which + it has an IKE_SA MAY send an IKE Notify payload in an IKE + INFORMATIONAL exchange over that SA. {{ Demoted the SHOULD }} The + recipient MUST NOT change the state of any SAs as a result, but may + wish to audit the event to aid in diagnosing malfunctions. A node + MUST limit the rate at which it will send messages in response to + unprotected messages. + + + + + + +Kaufman, et al. Expires August 27, 2006 [Page 49] + +Internet-Draft IKEv2bis February 2006 + + +2.22. IPComp + + Use of IP compression [IPCOMP] can be negotiated as part of the setup + of a CHILD_SA. While IP compression involves an extra header in each + packet and a compression parameter index (CPI), the virtual + "compression association" has no life outside the ESP or AH SA that + contains it. Compression associations disappear when the + corresponding ESP or AH SA goes away. It is not explicitly mentioned + in any DELETE payload. + + Negotiation of IP compression is separate from the negotiation of + cryptographic parameters associated with a CHILD_SA. A node + requesting a CHILD_SA MAY advertise its support for one or more + compression algorithms through one or more Notify payloads of type + IPCOMP_SUPPORTED. The response MAY indicate acceptance of a single + compression algorithm with a Notify payload of type IPCOMP_SUPPORTED. + These payloads MUST NOT occur in messages that do not contain SA + payloads. + + Although there has been discussion of allowing multiple compression + algorithms to be accepted and to have different compression + algorithms available for the two directions of a CHILD_SA, + implementations of this specification MUST NOT accept an IPComp + algorithm that was not proposed, MUST NOT accept more than one, and + MUST NOT compress using an algorithm other than one proposed and + accepted in the setup of the CHILD_SA. + + A side effect of separating the negotiation of IPComp from + cryptographic parameters is that it is not possible to propose + multiple cryptographic suites and propose IP compression with some of + them but not others. + +2.23. NAT Traversal + + Network Address Translation (NAT) gateways are a controversial + subject. This section briefly describes what they are and how they + are likely to act on IKE traffic. Many people believe that NATs are + evil and that we should not design our protocols so as to make them + work better. IKEv2 does specify some unintuitive processing rules in + order that NATs are more likely to work. + + NATs exist primarily because of the shortage of IPv4 addresses, + though there are other rationales. IP nodes that are "behind" a NAT + have IP addresses that are not globally unique, but rather are + assigned from some space that is unique within the network behind the + NAT but that are likely to be reused by nodes behind other NATs. + Generally, nodes behind NATs can communicate with other nodes behind + the same NAT and with nodes with globally unique addresses, but not + + + +Kaufman, et al. Expires August 27, 2006 [Page 50] + +Internet-Draft IKEv2bis February 2006 + + + with nodes behind other NATs. There are exceptions to that rule. + When those nodes make connections to nodes on the real Internet, the + NAT gateway "translates" the IP source address to an address that + will be routed back to the gateway. Messages to the gateway from the + Internet have their destination addresses "translated" to the + internal address that will route the packet to the correct endnode. + + NATs are designed to be "transparent" to endnodes. Neither software + on the node behind the NAT nor the node on the Internet requires + modification to communicate through the NAT. Achieving this + transparency is more difficult with some protocols than with others. + Protocols that include IP addresses of the endpoints within the + payloads of the packet will fail unless the NAT gateway understands + the protocol and modifies the internal references as well as those in + the headers. Such knowledge is inherently unreliable, is a network + layer violation, and often results in subtle problems. + + Opening an IPsec connection through a NAT introduces special + problems. If the connection runs in transport mode, changing the IP + addresses on packets will cause the checksums to fail and the NAT + cannot correct the checksums because they are cryptographically + protected. Even in tunnel mode, there are routing problems because + transparently translating the addresses of AH and ESP packets + requires special logic in the NAT and that logic is heuristic and + unreliable in nature. For that reason, IKEv2 can negotiate UDP + encapsulation of IKE and ESP packets. This encoding is slightly less + efficient but is easier for NATs to process. In addition, firewalls + may be configured to pass IPsec traffic over UDP but not ESP/AH or + vice versa. + + It is a common practice of NATs to translate TCP and UDP port numbers + as well as addresses and use the port numbers of inbound packets to + decide which internal node should get a given packet. For this + reason, even though IKE packets MUST be sent from and to UDP port + 500, they MUST be accepted coming from any port and responses MUST be + sent to the port from whence they came. This is because the ports + may be modified as the packets pass through NATs. Similarly, IP + addresses of the IKE endpoints are generally not included in the IKE + payloads because the payloads are cryptographically protected and + could not be transparently modified by NATs. + + Port 4500 is reserved for UDP-encapsulated ESP and IKE. When working + through a NAT, it is generally better to pass IKE packets over port + 4500 because some older NATs handle IKE traffic on port 500 cleverly + in an attempt to transparently establish IPsec connections between + endpoints that don't handle NAT traversal themselves. Such NATs may + interfere with the straightforward NAT traversal envisioned by this + document. {{ Clarif-7.6 }} An IPsec endpoint that discovers a NAT + + + +Kaufman, et al. Expires August 27, 2006 [Page 51] + +Internet-Draft IKEv2bis February 2006 + + + between it and its correspondent MUST send all subsequent traffic + from port 4500, which NATs should not treat specially (as they might + with port 500). + + The specific requirements for supporting NAT traversal [NATREQ] are + listed below. Support for NAT traversal is optional. In this + section only, requirements listed as MUST apply only to + implementations supporting NAT traversal. + + o IKE MUST listen on port 4500 as well as port 500. IKE MUST + respond to the IP address and port from which packets arrived. + + o Both IKE initiator and responder MUST include in their IKE_SA_INIT + packets Notify payloads of type NAT_DETECTION_SOURCE_IP and + NAT_DETECTION_DESTINATION_IP. Those payloads can be used to + detect if there is NAT between the hosts, and which end is behind + the NAT. The location of the payloads in the IKE_SA_INIT packets + are just after the Ni and Nr payloads (before the optional CERTREQ + payload). + + o If none of the NAT_DETECTION_SOURCE_IP payload(s) received matches + the hash of the source IP and port found from the IP header of the + packet containing the payload, it means that the other end is + behind NAT (i.e., someone along the route changed the source + address of the original packet to match the address of the NAT + box). In this case, this end should allow dynamic update of the + other ends IP address, as described later. + + o If the NAT_DETECTION_DESTINATION_IP payload received does not + match the hash of the destination IP and port found from the IP + header of the packet containing the payload, it means that this + end is behind a NAT. In this case, this end SHOULD start sending + keepalive packets as explained in [UDPENCAPS]. + + o The IKE initiator MUST check these payloads if present and if they + do not match the addresses in the outer packet MUST tunnel all + future IKE and ESP packets associated with this IKE_SA over UDP + port 4500. + + o To tunnel IKE packets over UDP port 4500, the IKE header has four + octets of zero prepended and the result immediately follows the + UDP header. To tunnel ESP packets over UDP port 4500, the ESP + header immediately follows the UDP header. Since the first four + bytes of the ESP header contain the SPI, and the SPI cannot + validly be zero, it is always possible to distinguish ESP and IKE + messages. + + + + + +Kaufman, et al. Expires August 27, 2006 [Page 52] + +Internet-Draft IKEv2bis February 2006 + + + o The original source and destination IP address required for the + transport mode TCP and UDP packet checksum fixup (see [UDPENCAPS]) + are obtained from the Traffic Selectors associated with the + exchange. In the case of NAT traversal, the Traffic Selectors + MUST contain exactly one IP address, which is then used as the + original IP address. + + o There are cases where a NAT box decides to remove mappings that + are still alive (for example, the keepalive interval is too long, + or the NAT box is rebooted). To recover in these cases, hosts + that are not behind a NAT SHOULD send all packets (including + retransmission packets) to the IP address and port from the last + valid authenticated packet from the other end (i.e., dynamically + update the address). A host behind a NAT SHOULD NOT do this + because it opens a DoS attack possibility. Any authenticated IKE + packet or any authenticated UDP-encapsulated ESP packet can be + used to detect that the IP address or the port has changed. + + Note that similar but probably not identical actions will likely be + needed to make IKE work with Mobile IP, but such processing is not + addressed by this document. + +2.24. Explicit Congestion Notification (ECN) + + When IPsec tunnels behave as originally specified in [IPSECARCH-OLD], + ECN usage is not appropriate for the outer IP headers because tunnel + decapsulation processing discards ECN congestion indications to the + detriment of the network. ECN support for IPsec tunnels for IKEv1- + based IPsec requires multiple operating modes and negotiation (see + [ECN]). IKEv2 simplifies this situation by requiring that ECN be + usable in the outer IP headers of all tunnel-mode IPsec SAs created + by IKEv2. Specifically, tunnel encapsulators and decapsulators for + all tunnel-mode SAs created by IKEv2 MUST support the ECN full- + functionality option for tunnels specified in [ECN] and MUST + implement the tunnel encapsulation and decapsulation processing + specified in [IPSECARCH] to prevent discarding of ECN congestion + indications. + + +3. Header and Payload Formats + +3.1. The IKE Header + + IKE messages use UDP ports 500 and/or 4500, with one IKE message per + UDP datagram. Information from the beginning of the packet through + the UDP header is largely ignored except that the IP addresses and + UDP ports from the headers are reversed and used for return packets. + When sent on UDP port 500, IKE messages begin immediately following + + + +Kaufman, et al. Expires August 27, 2006 [Page 53] + +Internet-Draft IKEv2bis February 2006 + + + the UDP header. When sent on UDP port 4500, IKE messages have + prepended four octets of zero. These four octets of zero are not + part of the IKE message and are not included in any of the length + fields or checksums defined by IKE. Each IKE message begins with the + IKE header, denoted HDR in this memo. Following the header are one + or more IKE payloads each identified by a "Next Payload" field in the + preceding payload. Payloads are processed in the order in which they + appear in an IKE message by invoking the appropriate processing + routine according to the "Next Payload" field in the IKE header and + subsequently according to the "Next Payload" field in the IKE payload + itself until a "Next Payload" field of zero indicates that no + payloads follow. If a payload of type "Encrypted" is found, that + payload is decrypted and its contents parsed as additional payloads. + An Encrypted payload MUST be the last payload in a packet and an + Encrypted payload MUST NOT contain another Encrypted payload. + + The Recipient SPI in the header identifies an instance of an IKE + security association. It is therefore possible for a single instance + of IKE to multiplex distinct sessions with multiple peers. + + All multi-octet fields representing integers are laid out in big + endian order (aka most significant byte first, or network byte + order). + + The format of the IKE header is shown in Figure 4. + + 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 + +-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+ + ! IKE_SA Initiator's SPI ! + ! ! + +-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+ + ! IKE_SA Responder's SPI ! + ! ! + +-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+ + ! Next Payload ! MjVer ! MnVer ! Exchange Type ! Flags ! + +-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+ + ! Message ID ! + +-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+ + ! Length ! + +-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+ + + Figure 4: IKE Header Format + + o Initiator's SPI (8 octets) - A value chosen by the initiator to + identify a unique IKE security association. This value MUST NOT + be zero. + + + + +Kaufman, et al. Expires August 27, 2006 [Page 54] + +Internet-Draft IKEv2bis February 2006 + + + o Responder's SPI (8 octets) - A value chosen by the responder to + identify a unique IKE security association. This value MUST be + zero in the first message of an IKE Initial Exchange (including + repeats of that message including a cookie). {{ The phrase "and + MUST NOT be zero in any other message" was removed; Clarif-2.1 }} + + o Next Payload (1 octet) - Indicates the type of payload that + immediately follows the header. The format and value of each + payload are defined below. + + o Major Version (4 bits) - Indicates the major version of the IKE + protocol in use. Implementations based on this version of IKE + MUST set the Major Version to 2. Implementations based on + previous versions of IKE and ISAKMP MUST set the Major Version to + 1. Implementations based on this version of IKE MUST reject or + ignore messages containing a version number greater than 2. + + o Minor Version (4 bits) - Indicates the minor version of the IKE + protocol in use. Implementations based on this version of IKE + MUST set the Minor Version to 0. They MUST ignore the minor + version number of received messages. + + o Exchange Type (1 octet) - Indicates the type of exchange being + used. This constrains the payloads sent in each message and + orderings of messages in an exchange. + + Exchange Type Value + ---------------------------------- + RESERVED 0-33 + IKE_SA_INIT 34 + IKE_AUTH 35 + CREATE_CHILD_SA 36 + INFORMATIONAL 37 + RESERVED TO IANA 38-239 + Reserved for private use 240-255 + + o Flags (1 octet) - Indicates specific options that are set for the + message. Presence of options are indicated by the appropriate bit + in the flags field being set. The bits are defined LSB first, so + bit 0 would be the least significant bit of the Flags octet. In + the description below, a bit being 'set' means its value is '1', + while 'cleared' means its value is '0'. + + * X(reserved) (bits 0-2) - These bits MUST be cleared when + sending and MUST be ignored on receipt. + + * I(nitiator) (bit 3 of Flags) - This bit MUST be set in messages + sent by the original initiator of the IKE_SA and MUST be + + + +Kaufman, et al. Expires August 27, 2006 [Page 55] + +Internet-Draft IKEv2bis February 2006 + + + cleared in messages sent by the original responder. It is used + by the recipient to determine which eight octets of the SPI + were generated by the recipient. + + * V(ersion) (bit 4 of Flags) - This bit indicates that the + transmitter is capable of speaking a higher major version + number of the protocol than the one indicated in the major + version number field. Implementations of IKEv2 must clear this + bit when sending and MUST ignore it in incoming messages. + + * R(esponse) (bit 5 of Flags) - This bit indicates that this + message is a response to a message containing the same message + ID. This bit MUST be cleared in all request messages and MUST + be set in all responses. An IKE endpoint MUST NOT generate a + response to a message that is marked as being a response. + + * X(reserved) (bits 6-7 of Flags) - These bits MUST be cleared + when sending and MUST be ignored on receipt. + + o Message ID (4 octets) - Message identifier used to control + retransmission of lost packets and matching of requests and + responses. It is essential to the security of the protocol + because it is used to prevent message replay attacks. See + Section 2.1 and Section 2.2. + + o Length (4 octets) - Length of total message (header + payloads) in + octets. + +3.2. Generic Payload Header + + Each IKE payload defined in Section 3.3 through Section 3.16 begins + with a generic payload header, shown in Figure 5. Figures for each + payload below will include the generic payload header, but for + brevity the description of each field will be omitted. + + 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 ! + +-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+ + + Figure 5: Generic Payload Header + + The Generic Payload Header fields are defined as follows: + + o Next Payload (1 octet) - Identifier for the payload type of the + next payload in the message. If the current payload is the last + in the message, then this field will be 0. This field provides a + + + +Kaufman, et al. Expires August 27, 2006 [Page 56] + +Internet-Draft IKEv2bis February 2006 + + + "chaining" capability whereby additional payloads can be added to + a message by appending it to the end of the message and setting + the "Next Payload" field of the preceding payload to indicate the + new payload's type. An Encrypted payload, which must always be + the last payload of a message, is an exception. It contains data + structures in the format of additional payloads. In the header of + an Encrypted payload, the Next Payload field is set to the payload + type of the first contained payload (instead of 0). The payload + type values are: + + Next Payload Type Notation Value + -------------------------------------------------- + No Next Payload 0 + RESERVED 1-32 + Security Association SA 33 + Key Exchange KE 34 + Identification - Initiator IDi 35 + Identification - Responder IDr 36 + Certificate CERT 37 + Certificate Request CERTREQ 38 + Authentication AUTH 39 + Nonce Ni, Nr 40 + Notify N 41 + Delete D 42 + Vendor ID V 43 + Traffic Selector - Initiator TSi 44 + Traffic Selector - Responder TSr 45 + Encrypted E 46 + Configuration CP 47 + Extensible Authentication EAP 48 + RESERVED TO IANA 49-127 + PRIVATE USE 128-255 + + (Payload type values 1-32 should not be assigned in the + future so that there is no overlap with the code assignments + for IKEv1.) + + o Critical (1 bit) - MUST be set to zero if the sender wants the + recipient to skip this payload if it does not understand the + payload type code in the Next Payload field of the previous + payload. MUST be set to one if the sender wants the recipient to + reject this entire message if it does not understand the payload + type. MUST be ignored by the recipient if the recipient + understands the payload type code. MUST be set to zero for + payload types defined in this document. Note that the critical + bit applies to the current payload rather than the "next" payload + whose type code appears in the first octet. The reasoning behind + not setting the critical bit for payloads defined in this document + + + +Kaufman, et al. Expires August 27, 2006 [Page 57] + +Internet-Draft IKEv2bis February 2006 + + + is that all implementations MUST understand all payload types + defined in this document and therefore must ignore the Critical + bit's value. Skipped payloads are expected to have valid Next + Payload and Payload Length fields. + + o RESERVED (7 bits) - MUST be sent as zero; MUST be ignored on + receipt. + + o Payload Length (2 octets) - Length in octets of the current + payload, including the generic payload header. + +3.3. Security Association Payload + + The Security Association Payload, denoted SA in this memo, is used to + negotiate attributes of a security association. Assembly of Security + Association Payloads requires great peace of mind. An SA payload MAY + contain multiple proposals. If there is more than one, they MUST be + ordered from most preferred to least preferred. Each proposal may + contain multiple IPsec protocols (where a protocol is IKE, ESP, or + AH), each protocol MAY contain multiple transforms, and each + transform MAY contain multiple attributes. When parsing an SA, an + implementation MUST check that the total Payload Length is consistent + with the payload's internal lengths and counts. Proposals, + Transforms, and Attributes each have their own variable length + encodings. They are nested such that the Payload Length of an SA + includes the combined contents of the SA, Proposal, Transform, and + Attribute information. The length of a Proposal includes the lengths + of all Transforms and Attributes it contains. The length of a + Transform includes the lengths of all Attributes it contains. + + The syntax of Security Associations, Proposals, Transforms, and + Attributes is based on ISAKMP; however the semantics are somewhat + different. The reason for the complexity and the hierarchy is to + allow for multiple possible combinations of algorithms to be encoded + in a single SA. Sometimes there is a choice of multiple algorithms, + whereas other times there is a combination of algorithms. For + example, an initiator might want to propose using (AH w/MD5 and ESP + w/3DES) OR (ESP w/MD5 and 3DES). + + One of the reasons the semantics of the SA payload has changed from + ISAKMP and IKEv1 is to make the encodings more compact in common + cases. + + The Proposal structure contains within it a Proposal # and an IPsec + protocol ID. Each structure MUST have the same Proposal # as the + previous one or be one (1) greater. The first Proposal MUST have a + Proposal # of one (1). If two successive structures have the same + Proposal number, it means that the proposal consists of the first + + + +Kaufman, et al. Expires August 27, 2006 [Page 58] + +Internet-Draft IKEv2bis February 2006 + + + structure AND the second. So a proposal of AH AND ESP would have two + proposal structures, one for AH and one for ESP and both would have + Proposal #1. A proposal of AH OR ESP would have two proposal + structures, one for AH with Proposal #1 and one for ESP with Proposal + #2. + + Each Proposal/Protocol structure is followed by one or more transform + structures. The number of different transforms is generally + determined by the Protocol. AH generally has a single transform: an + integrity check algorithm. ESP generally has two: an encryption + algorithm and an integrity check algorithm. IKE generally has four + transforms: a Diffie-Hellman group, an integrity check algorithm, a + prf algorithm, and an encryption algorithm. If an algorithm that + combines encryption and integrity protection is proposed, it MUST be + proposed as an encryption algorithm and an integrity protection + algorithm MUST NOT be proposed. For each Protocol, the set of + permissible transforms is assigned transform ID numbers, which appear + in the header of each transform. + + If there are multiple transforms with the same Transform Type, the + proposal is an OR of those transforms. If there are multiple + Transforms with different Transform Types, the proposal is an AND of + the different groups. For example, to propose ESP with (3DES or + IDEA) and (HMAC_MD5 or HMAC_SHA), the ESP proposal would contain two + Transform Type 1 candidates (one for 3DES and one for IDEA) and two + Transform Type 2 candidates (one for HMAC_MD5 and one for HMAC_SHA). + This effectively proposes four combinations of algorithms. If the + initiator wanted to propose only a subset of those, for example (3DES + and HMAC_MD5) or (IDEA and HMAC_SHA), there is no way to encode that + as multiple transforms within a single Proposal. Instead, the + initiator would have to construct two different Proposals, each with + two transforms. + + A given transform MAY have one or more Attributes. Attributes are + necessary when the transform can be used in more than one way, as + when an encryption algorithm has a variable key size. The transform + would specify the algorithm and the attribute would specify the key + size. Most transforms do not have attributes. A transform MUST NOT + have multiple attributes of the same type. To propose alternate + values for an attribute (for example, multiple key sizes for the AES + encryption algorithm), and implementation MUST include multiple + Transforms with the same Transform Type each with a single Attribute. + + Note that the semantics of Transforms and Attributes are quite + different from those in IKEv1. In IKEv1, a single Transform carried + multiple algorithms for a protocol with one carried in the Transform + and the others carried in the Attributes. + + + + +Kaufman, et al. Expires August 27, 2006 [Page 59] + +Internet-Draft IKEv2bis February 2006 + + + 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 ! + +-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+ + ! ! + ~ <Proposals> ~ + ! ! + +-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+ + + Figure 6: Security Association Payload + + o Proposals (variable) - One or more proposal substructures. + + The payload type for the Security Association Payload is thirty three + (33). + +3.3.1. Proposal Substructure + + 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 + +-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+ + ! 0 (last) or 2 ! RESERVED ! Proposal Length ! + +-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+ + ! Proposal # ! Protocol ID ! SPI Size !# of Transforms! + +-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+ + ~ SPI (variable) ~ + +-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+ + ! ! + ~ <Transforms> ~ + ! ! + +-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+ + + Figure 7: Proposal Substructure + + o 0 (last) or 2 (more) (1 octet) - Specifies whether this is the + last Proposal Substructure in the SA. This syntax is inherited + from ISAKMP, but is unnecessary because the last Proposal could be + identified from the length of the SA. The value (2) corresponds + to a Payload Type of Proposal in IKEv1, and the first four octets + of the Proposal structure are designed to look somewhat like the + header of a Payload. + + o RESERVED (1 octet) - MUST be sent as zero; MUST be ignored on + receipt. + + o Proposal Length (2 octets) - Length of this proposal, including + all transforms and attributes that follow. + + + +Kaufman, et al. Expires August 27, 2006 [Page 60] + +Internet-Draft IKEv2bis February 2006 + + + o Proposal # (1 octet) - When a proposal is made, the first proposal + in an SA payload MUST be #1, and subsequent proposals MUST either + be the same as the previous proposal (indicating an AND of the two + proposals) or one more than the previous proposal (indicating an + OR of the two proposals). When a proposal is accepted, all of the + proposal numbers in the SA payload MUST be the same and MUST match + the number on the proposal sent that was accepted. + + o Protocol ID (1 octet) - Specifies the IPsec protocol identifier + for the current negotiation. The defined values are: + + Protocol Protocol ID + ----------------------------------- + RESERVED 0 + IKE 1 + AH 2 + ESP 3 + RESERVED TO IANA 4-200 + PRIVATE USE 201-255 + + o SPI Size (1 octet) - For an initial IKE_SA negotiation, this field + MUST be zero; the SPI is obtained from the outer header. During + subsequent negotiations, it is equal to the size, in octets, of + the SPI of the corresponding protocol (8 for IKE, 4 for ESP and + AH). + + o # of Transforms (1 octet) - Specifies the number of transforms in + this proposal. + + o SPI (variable) - The sending entity's SPI. Even if the SPI Size + is not a multiple of 4 octets, there is no padding applied to the + payload. When the SPI Size field is zero, this field is not + present in the Security Association payload. + + o Transforms (variable) - One or more transform substructures. + + + + + + + + + + + + + + + + +Kaufman, et al. Expires August 27, 2006 [Page 61] + +Internet-Draft IKEv2bis February 2006 + + +3.3.2. Transform Substructure + + 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 + +-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+ + ! 0 (last) or 3 ! RESERVED ! Transform Length ! + +-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+ + !Transform Type ! RESERVED ! Transform ID ! + +-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+ + ! ! + ~ Transform Attributes ~ + ! ! + +-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+ + + Figure 8: Transform Substructure + + o 0 (last) or 3 (more) (1 octet) - Specifies whether this is the + last Transform Substructure in the Proposal. This syntax is + inherited from ISAKMP, but is unnecessary because the last + Proposal could be identified from the length of the SA. The value + (3) corresponds to a Payload Type of Transform in IKEv1, and the + first four octets of the Transform structure are designed to look + somewhat like the header of a Payload. + + o RESERVED - MUST be sent as zero; MUST be ignored on receipt. + + o Transform Length - The length (in octets) of the Transform + Substructure including Header and Attributes. + + o Transform Type (1 octet) - The type of transform being specified + in this transform. Different protocols support different + transform types. For some protocols, some of the transforms may + be optional. If a transform is optional and the initiator wishes + to propose that the transform be omitted, no transform of the + given type is included in the proposal. If the initiator wishes + to make use of the transform optional to the responder, it + includes a transform substructure with transform ID = 0 as one of + the options. + + o Transform ID (2 octets) - The specific instance of the transform + type being proposed. + + The tranform type values are: + + + + + + + + +Kaufman, et al. Expires August 27, 2006 [Page 62] + +Internet-Draft IKEv2bis February 2006 + + + Description Trans. Used In + Type + ------------------------------------------------------------------ + RESERVED 0 + Encryption Algorithm (ENCR) 1 IKE and ESP + Pseudo-random Function (PRF) 2 IKE + Integrity Algorithm (INTEG) 3 IKE, AH, optional in ESP + Diffie-Hellman Group (D-H) 4 IKE, optional in AH & ESP + Extended Sequence Numbers (ESN) 5 AH and ESP + RESERVED TO IANA 6-240 + PRIVATE USE 241-255 + + For Transform Type 1 (Encryption Algorithm), defined Transform IDs + are: + + Name Number Defined In + --------------------------------------------------- + RESERVED 0 + ENCR_DES_IV64 1 (RFC1827) + ENCR_DES 2 (RFC2405), [DES] + ENCR_3DES 3 (RFC2451) + ENCR_RC5 4 (RFC2451) + ENCR_IDEA 5 (RFC2451), [IDEA] + ENCR_CAST 6 (RFC2451) + ENCR_BLOWFISH 7 (RFC2451) + ENCR_3IDEA 8 (RFC2451) + ENCR_DES_IV32 9 + RESERVED 10 + ENCR_NULL 11 (RFC2410) + ENCR_AES_CBC 12 (RFC3602) + ENCR_AES_CTR 13 (RFC3664) + RESERVED TO IANA 14-1023 + PRIVATE USE 1024-65535 + + For Transform Type 2 (Pseudo-random Function), defined Transform IDs + are: + + Name Number Defined In + ------------------------------------------------------ + RESERVED 0 + PRF_HMAC_MD5 1 (RFC2104), [MD5] + PRF_HMAC_SHA1 2 (RFC2104), [SHA] + PRF_HMAC_TIGER 3 (RFC2104) + PRF_AES128_XCBC 4 (RFC3664) + RESERVED TO IANA 5-1023 + PRIVATE USE 1024-65535 + + For Transform Type 3 (Integrity Algorithm), defined Transform IDs + + + +Kaufman, et al. Expires August 27, 2006 [Page 63] + +Internet-Draft IKEv2bis February 2006 + + + are: + + Name Number Defined In + ---------------------------------------- + NONE 0 + AUTH_HMAC_MD5_96 1 (RFC2403) + AUTH_HMAC_SHA1_96 2 (RFC2404) + AUTH_DES_MAC 3 + AUTH_KPDK_MD5 4 (RFC1826) + AUTH_AES_XCBC_96 5 (RFC3566) + RESERVED TO IANA 6-1023 + PRIVATE USE 1024-65535 + + For Transform Type 4 (Diffie-Hellman Group), defined Transform IDs + are: + + Name Number + -------------------------------------- + NONE 0 + Defined in Appendix B 1 - 2 + RESERVED 3 - 4 + Defined in [ADDGROUP] 5 + RESERVED TO IANA 6 - 13 + Defined in [ADDGROUP] 14 - 18 + RESERVED TO IANA 19 - 1023 + PRIVATE USE 1024-65535 + + For Transform Type 5 (Extended Sequence Numbers), defined Transform + IDs are: + + Name Number + -------------------------------------------- + No Extended Sequence Numbers 0 + Extended Sequence Numbers 1 + RESERVED 2 - 65535 + +3.3.3. Valid Transform Types by Protocol + + The number and type of transforms that accompany an SA payload are + dependent on the protocol in the SA itself. An SA payload proposing + the establishment of an SA has the following mandatory and optional + transform types. A compliant implementation MUST understand all + mandatory and optional types for each protocol it supports (though it + need not accept proposals with unacceptable suites). A proposal MAY + omit the optional types if the only value for them it will accept is + NONE. + + + + + +Kaufman, et al. Expires August 27, 2006 [Page 64] + +Internet-Draft IKEv2bis February 2006 + + + Protocol Mandatory Types Optional Types + --------------------------------------------------- + IKE ENCR, PRF, INTEG, D-H + ESP ENCR, ESN INTEG, D-H + AH INTEG, ESN D-H + +3.3.4. Mandatory Transform IDs + + The specification of suites that MUST and SHOULD be supported for + interoperability has been removed from this document because they are + likely to change more rapidly than this document evolves. + + An important lesson learned from IKEv1 is that no system should only + implement the mandatory algorithms and expect them to be the best + choice for all customers. For example, at the time that this + document was written, many IKEv1 implementers were starting to + migrate to AES in Cipher Block Chaining (CBC) mode for Virtual + Private Network (VPN) applications. Many IPsec systems based on + IKEv2 will implement AES, additional Diffie-Hellman groups, and + additional hash algorithms, and some IPsec customers already require + these algorithms in addition to the ones listed above. + + It is likely that IANA will add additional transforms in the future, + and some users may want to use private suites, especially for IKE + where implementations should be capable of supporting different + parameters, up to certain size limits. In support of this goal, all + implementations of IKEv2 SHOULD include a management facility that + allows specification (by a user or system administrator) of Diffie- + Hellman (DH) parameters (the generator, modulus, and exponent lengths + and values) for new DH groups. Implementations SHOULD provide a + management interface through which these parameters and the + associated transform IDs may be entered (by a user or system + administrator), to enable negotiating such groups. + + All implementations of IKEv2 MUST include a management facility that + enables a user or system administrator to specify the suites that are + acceptable for use with IKE. Upon receipt of a payload with a set of + transform IDs, the implementation MUST compare the transmitted + transform IDs against those locally configured via the management + controls, to verify that the proposed suite is acceptable based on + local policy. The implementation MUST reject SA proposals that are + not authorized by these IKE suite controls. Note that cryptographic + suites that MUST be implemented need not be configured as acceptable + to local policy. + + + + + + + +Kaufman, et al. Expires August 27, 2006 [Page 65] + +Internet-Draft IKEv2bis February 2006 + + +3.3.5. Transform Attributes + + Each transform in a Security Association payload may include + attributes that modify or complete the specification of the + transform. These attributes are type/value pairs and are defined + below. For example, if an encryption algorithm has a variable-length + key, the key length to be used may be specified as an attribute. + Attributes can have a value with a fixed two octet length or a + variable-length value. For the latter, the attribute is encoded as + type/length/value. + + 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 + +-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+ + !A! Attribute Type ! AF=0 Attribute Length ! + !F! ! AF=1 Attribute Value ! + +-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+ + ! AF=0 Attribute Value ! + ! AF=1 Not Transmitted ! + +-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+ + + Figure 9: Data Attributes + + o Attribute Type (2 octets) - Unique identifier for each type of + attribute (see below). The most significant bit of this field is + the Attribute Format bit (AF). It indicates whether the data + attributes follow the Type/Length/Value (TLV) format or a + shortened Type/Value (TV) format. If the AF bit is zero (0), then + the Data Attributes are of the Type/Length/Value (TLV) form. If + the AF bit is a one (1), then the Data Attributes are of the Type/ + Value form. + + o Attribute Length (2 octets) - Length in octets of the Attribute + Value. When the AF bit is a one (1), the Attribute Value is only + 2 octets and the Attribute Length field is not present. + + o Attribute Value (variable length) - Value of the Attribute + associated with the Attribute Type. If the AF bit is a zero (0), + this field has a variable length defined by the Attribute Length + field. If the AF bit is a one (1), the Attribute Value has a + length of 2 octets. + + o Key Length - When using an Encryption Algorithm that has a + variable-length key, this attribute specifies the key length in + bits (MUST use network byte order). This attribute MUST NOT be + used when the specified Encryption Algorithm uses a fixed-length + key. + + + + +Kaufman, et al. Expires August 27, 2006 [Page 66] + +Internet-Draft IKEv2bis February 2006 + + + Note that only a single attribute type (Key Length) is defined, and + it is fixed length. The variable-length encoding specification is + included only for future extensions. {{ Clarif-7.11 removed the + sentence that listed, incorrectly, the algorithms defined in the + document that accept attributes. }} + + Attributes described as basic MUST NOT be encoded using the variable- + length encoding. Variable-length attributes MUST NOT be encoded as + basic even if their value can fit into two octets. NOTE: This is a + change from IKEv1, where increased flexibility may have simplified + the composer of messages but certainly complicated the parser. + + Attribute Type Value Attribute Format + ------------------------------------------------------------ + RESERVED 0-13 + Key Length (in bits) 14 TV + RESERVED 15-17 + RESERVED TO IANA 18-16383 + PRIVATE USE 16384-32767 + Values 0-13 and 15-17 were used in a similar context in + IKEv1, and should not be assigned except to matching values. + +3.3.6. Attribute Negotiation + + During security association negotiation initiators present offers to + responders. Responders MUST select a single complete set of + parameters from the offers (or reject all offers if none are + acceptable). If there are multiple proposals, the responder MUST + choose a single proposal number and return all of the Proposal + substructures with that Proposal number. If there are multiple + Transforms with the same type, the responder MUST choose a single + one. Any attributes of a selected transform MUST be returned + unmodified. The initiator of an exchange MUST check that the + accepted offer is consistent with one of its proposals, and if not + that response MUST be rejected. + + Negotiating Diffie-Hellman groups presents some special challenges. + SA offers include proposed attributes and a Diffie-Hellman public + number (KE) in the same message. If in the initial exchange the + initiator offers to use one of several Diffie-Hellman groups, it + SHOULD pick the one the responder is most likely to accept and + include a KE corresponding to that group. If the guess turns out to + be wrong, the responder will indicate the correct group in the + response and the initiator SHOULD pick an element of that group for + its KE value when retrying the first message. It SHOULD, however, + continue to propose its full supported set of groups in order to + prevent a man-in-the-middle downgrade attack. + + + + +Kaufman, et al. Expires August 27, 2006 [Page 67] + +Internet-Draft IKEv2bis February 2006 + + + Implementation Note: + + Certain negotiable attributes can have ranges or could have multiple + acceptable values. These include the key length of a variable key + length symmetric cipher. To further interoperability and to support + upgrading endpoints independently, implementers of this protocol + SHOULD accept values that they deem to supply greater security. For + instance, if a peer is configured to accept a variable-length cipher + with a key length of X bits and is offered that cipher with a larger + key length, the implementation SHOULD accept the offer if it supports + use of the longer key. + + Support of this capability allows an implementation to express a + concept of "at least" a certain level of security-- "a key length of + _at least_ X bits for cipher Y". + +3.4. Key Exchange Payload + + The Key Exchange Payload, denoted KE in this memo, is used to + exchange Diffie-Hellman public numbers as part of a Diffie-Hellman + key exchange. The Key Exchange Payload consists of the IKE generic + payload header followed by the Diffie-Hellman public value itself. + + 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 ! + +-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+ + ! DH Group # ! RESERVED ! + +-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+ + ! ! + ~ Key Exchange Data ~ + ! ! + +-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+ + + Figure 10: Key Exchange Payload Format + + A key exchange payload is constructed by copying one's Diffie-Hellman + public value into the "Key Exchange Data" portion of the payload. + The length of the Diffie-Hellman public value MUST be equal to the + length of the prime modulus over which the exponentiation was + performed, prepending zero bits to the value if necessary. + + The DH Group # identifies the Diffie-Hellman group in which the Key + Exchange Data was computed (see Section 3.3.2). If the selected + proposal uses a different Diffie-Hellman group, the message MUST be + rejected with a Notify payload of type INVALID_KE_PAYLOAD. + + + + +Kaufman, et al. Expires August 27, 2006 [Page 68] + +Internet-Draft IKEv2bis February 2006 + + + The payload type for the Key Exchange payload is thirty four (34). + +3.5. Identification Payloads + + The Identification Payloads, denoted IDi and IDr in this memo, allow + peers to assert an identity to one another. This identity may be + used for policy lookup, but does not necessarily have to match + anything in the CERT payload; both fields may be used by an + implementation to perform access control decisions. {{ Clarif-7.1 }} + When using the ID_IPV4_ADDR/ID_IPV6_ADDR identity types in IDi/IDr + payloads, IKEv2 does not require this address to match the address in + the IP header of IKEv2 packets, or anything in the TSi/TSr payloads. + The contents of IDi/IDr is used purely to fetch the policy and + authentication data related to the other party. + + NOTE: In IKEv1, two ID payloads were used in each direction to hold + Traffic Selector (TS) information for data passing over the SA. In + IKEv2, this information is carried in TS payloads (see Section 3.13). + + The Identification Payload consists of the IKE generic payload header + followed by identification fields as follows: + + 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 ! + +-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+ + ! ID Type ! RESERVED | + +-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+ + ! ! + ~ Identification Data ~ + ! ! + +-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+ + + Figure 11: Identification Payload Format + + o ID Type (1 octet) - Specifies the type of Identification being + used. + + o RESERVED - MUST be sent as zero; MUST be ignored on receipt. + + o Identification Data (variable length) - Value, as indicated by the + Identification Type. The length of the Identification Data is + computed from the size in the ID payload header. + + The payload types for the Identification Payload are thirty five (35) + for IDi and thirty six (36) for IDr. + + + + +Kaufman, et al. Expires August 27, 2006 [Page 69] + +Internet-Draft IKEv2bis February 2006 + + + The following table lists the assigned values for the Identification + Type field: + + ID Type Value + ------------------------------------------------------------------- + RESERVED 0 + + ID_IPV4_ADDR 1 + A single four (4) octet IPv4 address. + + ID_FQDN 2 + A fully-qualified domain name string. An example of a ID_FQDN + is, "example.com". The string MUST not contain any terminators + (e.g., NULL, CR, etc.). + + ID_RFC822_ADDR 3 + A fully-qualified RFC822 email address string, An example of a + ID_RFC822_ADDR is, "jsmith@example.com". The string MUST not + contain any terminators. + + RESERVED TO IANA 4 + + ID_IPV6_ADDR 5 + A single sixteen (16) octet IPv6 address. + + RESERVED TO IANA 6 - 8 + + ID_DER_ASN1_DN 9 + The binary Distinguished Encoding Rules (DER) encoding of an + ASN.1 X.500 Distinguished Name [X.501]. + + ID_DER_ASN1_GN 10 + The binary DER encoding of an ASN.1 X.500 GeneralName [X.509]. + + ID_KEY_ID 11 + An opaque octet stream which may be used to pass vendor- + specific information necessary to do certain proprietary + types of identification. + + RESERVED TO IANA 12-200 + + PRIVATE USE 201-255 + + Two implementations will interoperate only if each can generate a + type of ID acceptable to the other. To assure maximum + interoperability, implementations MUST be configurable to send at + least one of ID_IPV4_ADDR, ID_FQDN, ID_RFC822_ADDR, or ID_KEY_ID, and + MUST be configurable to accept all of these types. Implementations + + + +Kaufman, et al. Expires August 27, 2006 [Page 70] + +Internet-Draft IKEv2bis February 2006 + + + SHOULD be capable of generating and accepting all of these types. + IPv6-capable implementations MUST additionally be configurable to + accept ID_IPV6_ADDR. IPv6-only implementations MAY be configurable + to send only ID_IPV6_ADDR. + + {{ Clarif-3.4 }} EAP [EAP] does not mandate the use of any particular + type of identifier, but often EAP is used with Network Access + Identifiers (NAIs) defined in [NAI]. Although NAIs look a bit like + email addresses (e.g., "joe@example.com"), the syntax is not exactly + the same as the syntax of email address in [MAILFORMAT]. For those + NAIs that include the realm component, the ID_RFC822_ADDR + identification type SHOULD be used. Responder implementations should + not attempt to verify that the contents actually conform to the exact + syntax given in [MAILFORMAT], but instead should accept any + reasonable-looking NAI. For NAIs that do not include the realm + component,the ID_KEY_ID identification type SHOULD be used. + +3.6. Certificate Payload + + The Certificate Payload, denoted CERT in this memo, provides a means + to transport certificates or other authentication-related information + via IKE. Certificate payloads SHOULD be included in an exchange if + certificates are available to the sender unless the peer has + indicated an ability to retrieve this information from elsewhere + using an HTTP_CERT_LOOKUP_SUPPORTED Notify payload. Note that the + term "Certificate Payload" is somewhat misleading, because not all + authentication mechanisms use certificates and data other than + certificates may be passed in this payload. + + The Certificate Payload is defined as follows: + + 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 ! + +-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+ + ! Cert Encoding ! ! + +-+-+-+-+-+-+-+-+ ! + ~ Certificate Data ~ + ! ! + +-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+ + + Figure 12: Certificate Payload Format + + o Certificate Encoding (1 octet) - This field indicates the type of + certificate or certificate-related information contained in the + Certificate Data field. + + + + +Kaufman, et al. Expires August 27, 2006 [Page 71] + +Internet-Draft IKEv2bis February 2006 + + + Certificate Encoding Value + ------------------------------------------------- + RESERVED 0 + PKCS #7 wrapped X.509 certificate 1 + PGP Certificate 2 + DNS Signed Key 3 + X.509 Certificate - Signature 4 + Kerberos Token 6 + Certificate Revocation List (CRL) 7 + Authority Revocation List (ARL) 8 + SPKI Certificate 9 + X.509 Certificate - Attribute 10 + Raw RSA Key 11 + Hash and URL of X.509 certificate 12 + Hash and URL of X.509 bundle 13 + RESERVED to IANA 14 - 200 + PRIVATE USE 201 - 255 + + o Certificate Data (variable length) - Actual encoding of + certificate data. The type of certificate is indicated by the + Certificate Encoding field. + + The payload type for the Certificate Payload is thirty seven (37). + + Specific syntax is for some of the certificate type codes above is + not defined in this document. The types whose syntax is defined in + this document are: + + o X.509 Certificate - Signature (4) contains a DER encoded X.509 + certificate whose public key is used to validate the sender's AUTH + payload. + + o Certificate Revocation List (7) contains a DER encoded X.509 + certificate revocation list. + + o {{ Added "DER-encoded RSAPublicKey structure" from Clarif-3.6 }} + Raw RSA Key (11) contains a PKCS #1 encoded RSA key, that is, a + DER-encoded RSAPublicKey structure (see [RSA] and [PKCS1]). + + o Hash and URL encodings (12-13) allow IKE messages to remain short + by replacing long data structures with a 20 octet SHA-1 hash (see + [SHA]) of the replaced value followed by a variable-length URL + that resolves to the DER encoded data structure itself. This + improves efficiency when the endpoints have certificate data + cached and makes IKE less subject to denial of service attacks + that become easier to mount when IKE messages are large enough to + require IP fragmentation [DOSUDPPROT]. + + + + +Kaufman, et al. Expires August 27, 2006 [Page 72] + +Internet-Draft IKEv2bis February 2006 + + + Use the following ASN.1 definition for an X.509 bundle: + + CertBundle + { iso(1) identified-organization(3) dod(6) internet(1) + security(5) mechanisms(5) pkix(7) id-mod(0) + id-mod-cert-bundle(34) } + + DEFINITIONS EXPLICIT TAGS ::= + BEGIN + + IMPORTS + Certificate, CertificateList + FROM PKIX1Explicit88 + { iso(1) identified-organization(3) dod(6) + internet(1) security(5) mechanisms(5) pkix(7) + id-mod(0) id-pkix1-explicit(18) } ; + + CertificateOrCRL ::= CHOICE { + cert [0] Certificate, + crl [1] CertificateList } + + CertificateBundle ::= SEQUENCE OF CertificateOrCRL + + END + + Implementations MUST be capable of being configured to send and + accept up to four X.509 certificates in support of authentication, + and also MUST be capable of being configured to send and accept the + first two Hash and URL formats (with HTTP URLs). Implementations + SHOULD be capable of being configured to send and accept Raw RSA + keys. If multiple certificates are sent, the first certificate MUST + contain the public key used to sign the AUTH payload. The other + certificates may be sent in any order. + + {{ Clarif-3.6 }} Because the contents and use of some of the + certificate types are not defined, they SHOULD NOT be used. In + specific, implementations SHOULD NOT use the following types unless + they are later defined in a standards-track document: + + PKCS #7 wrapped X.509 certificate 1 + PGP Certificate 2 + DNS Signed Key 3 + Kerberos Token 6 + SPKI Certificate 9 + + + + + + + +Kaufman, et al. Expires August 27, 2006 [Page 73] + +Internet-Draft IKEv2bis February 2006 + + +3.7. Certificate Request Payload + + The Certificate Request Payload, denoted CERTREQ in this memo, + provides a means to request preferred certificates via IKE and can + appear in the IKE_INIT_SA response and/or the IKE_AUTH request. + Certificate Request payloads MAY be included in an exchange when the + sender needs to get the certificate of the receiver. If multiple CAs + are trusted and the cert encoding does not allow a list, then + multiple Certificate Request payloads SHOULD be transmitted. + + The Certificate Request Payload is defined as follows: + + 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 ! + +-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+ + ! Cert Encoding ! ! + +-+-+-+-+-+-+-+-+ ! + ~ Certification Authority ~ + ! ! + +-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+ + + Figure 13: Certificate Request Payload Format + + o Certificate Encoding (1 octet) - Contains an encoding of the type + or format of certificate requested. Values are listed in + Section 3.6. + + o Certification Authority (variable length) - Contains an encoding + of an acceptable certification authority for the type of + certificate requested. + + The payload type for the Certificate Request Payload is thirty eight + (38). + + The Certificate Encoding field has the same values as those defined + in Section 3.6. The Certification Authority field contains an + indicator of trusted authorities for this certificate type. The + Certification Authority value is a concatenated list of SHA-1 hashes + of the public keys of trusted Certification Authorities (CAs). Each + is encoded as the SHA-1 hash of the Subject Public Key Info element + (see section 4.1.2.7 of [PKIX]) from each Trust Anchor certificate. + The twenty-octet hashes are concatenated and included with no other + formatting. + + {{ Clarif-3.6 }} The contents of the "Certification Authority" field + are defined only for X.509 certificates, which are types 4, 10, 12, + + + +Kaufman, et al. Expires August 27, 2006 [Page 74] + +Internet-Draft IKEv2bis February 2006 + + + and 13. Other values SHOULD NOT be used until standards-track + specifications that specify their use are published. + + Note that the term "Certificate Request" is somewhat misleading, in + that values other than certificates are defined in a "Certificate" + payload and requests for those values can be present in a Certificate + Request Payload. The syntax of the Certificate Request payload in + such cases is not defined in this document. + + The Certificate Request Payload is processed by inspecting the "Cert + Encoding" field to determine whether the processor has any + certificates of this type. If so, the "Certification Authority" + field is inspected to determine if the processor has any certificates + that can be validated up to one of the specified certification + authorities. This can be a chain of certificates. + + If an end-entity certificate exists that satisfies the criteria + specified in the CERTREQ, a certificate or certificate chain SHOULD + be sent back to the certificate requestor if the recipient of the + CERTREQ: + + o is configured to use certificate authentication, + + o is allowed to send a CERT payload, + + o has matching CA trust policy governing the current negotiation, + and + + o has at least one time-wise and usage appropriate end-entity + certificate chaining to a CA provided in the CERTREQ. + + Certificate revocation checking must be considered during the + chaining process used to select a certificate. Note that even if two + peers are configured to use two different CAs, cross-certification + relationships should be supported by appropriate selection logic. + + The intent is not to prevent communication through the strict + adherence of selection of a certificate based on CERTREQ, when an + alternate certificate could be selected by the sender that would + still enable the recipient to successfully validate and trust it + through trust conveyed by cross-certification, CRLs, or other out-of- + band configured means. Thus, the processing of a CERTREQ should be + seen as a suggestion for a certificate to select, not a mandated one. + If no certificates exist, then the CERTREQ is ignored. This is not + an error condition of the protocol. There may be cases where there + is a preferred CA sent in the CERTREQ, but an alternate might be + acceptable (perhaps after prompting a human operator). + + + + +Kaufman, et al. Expires August 27, 2006 [Page 75] + +Internet-Draft IKEv2bis February 2006 + + +3.8. Authentication Payload + + The Authentication Payload, denoted AUTH in this memo, contains data + used for authentication purposes. The syntax of the Authentication + data varies according to the Auth Method as specified below. + + The Authentication Payload is defined as follows: + + 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 ! + +-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+ + ! Auth Method ! RESERVED ! + +-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+ + ! ! + ~ Authentication Data ~ + ! ! + +-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+ + + Figure 14: Authentication Payload Format + + o Auth Method (1 octet) - Specifies the method of authentication + used. Values defined are: + + * RSA Digital Signature (1) - Computed as specified in + Section 2.15 using an RSA private key over a PKCS#1 padded hash + (see [RSA] and [PKCS1]). {{ Clarif-3.2 }} To promote + interoperability, implementations that support this type SHOULD + support signatures that use SHA-1 as the hash function and + SHOULD use SHA-1 as the default hash function when generating + signatures. {{ Clarif-3.3 }} A newer version of PKCS#1 (v2.1) + defines two different encoding methods (ways of "padding the + hash") for signatures. However, IKEv2 and this document point + specifically to the PKCS#1 v2.0 which has only one encoding + method for signatures (EMSA-PKCS1- v1_5). + + * Shared Key Message Integrity Code (2) - Computed as specified + in Section 2.15 using the shared key associated with the + identity in the ID payload and the negotiated prf function + + * DSS Digital Signature (3) - Computed as specified in + Section 2.15 using a DSS private key (see [DSS]) over a SHA-1 + hash. + + * The values 0 and 4-200 are reserved to IANA. The values 201- + 255 are available for private use. + + + + +Kaufman, et al. Expires August 27, 2006 [Page 76] + +Internet-Draft IKEv2bis February 2006 + + + o Authentication Data (variable length) - see Section 2.15. + + The payload type for the Authentication Payload is thirty nine (39). + +3.9. Nonce Payload + + The Nonce Payload, denoted Ni and Nr in this memo for the initiator's + and responder's nonce respectively, contains random data used to + guarantee liveness during an exchange and protect against replay + attacks. + + The Nonce Payload is defined as follows: + + 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 ! + +-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+ + ! ! + ~ Nonce Data ~ + ! ! + +-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+ + + Figure 15: Nonce Payload Format + + o Nonce Data (variable length) - Contains the random data generated + by the transmitting entity. + + The payload type for the Nonce Payload is forty (40). + + The size of a Nonce MUST be between 16 and 256 octets inclusive. + Nonce values MUST NOT be reused. + +3.10. Notify Payload + + The Notify Payload, denoted N in this document, is used to transmit + informational data, such as error conditions and state transitions, + to an IKE peer. A Notify Payload may appear in a response message + (usually specifying why a request was rejected), in an INFORMATIONAL + Exchange (to report an error not in an IKE request), or in any other + message to indicate sender capabilities or to modify the meaning of + the request. + + The Notify Payload is defined as follows: + + + + + + + +Kaufman, et al. Expires August 27, 2006 [Page 77] + +Internet-Draft IKEv2bis February 2006 + + + 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 ! + +-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+ + ! ! + ~ Security Parameter Index (SPI) ~ + ! ! + +-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+ + ! ! + ~ Notification Data ~ + ! ! + +-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+ + + Figure 16: Notify Payload Format + + o Protocol ID (1 octet) - If this notification concerns an existing + SA, this field indicates the type of that SA. For IKE_SA + notifications, this field MUST be one (1). For notifications + concerning IPsec SAs this field MUST contain either (2) to + indicate AH or (3) to indicate ESP. {{ Clarif-7.8 }} For + notifications that do not relate to an existing SA, this field + MUST be sent as zero and MUST be ignored on receipt; this is + currently only true for the INVALID_SELECTORS and REKEY_SA + notifications. All other values for this field are reserved to + IANA for future assignment. + + o SPI Size (1 octet) - Length in octets of the SPI as defined by the + IPsec protocol ID or zero if no SPI is applicable. For a + notification concerning the IKE_SA, the SPI Size MUST be zero. + + o Notify Message Type (2 octets) - Specifies the type of + notification message. + + o SPI (variable length) - Security Parameter Index. + + o Notification Data (variable length) - Informational or error data + transmitted in addition to the Notify Message Type. Values for + this field are type specific (see below). + + The payload type for the Notify Payload is forty one (41). + +3.10.1. Notify Message Types + + Notification information can be error messages specifying why an SA + could not be established. It can also be status data that a process + + + +Kaufman, et al. Expires August 27, 2006 [Page 78] + +Internet-Draft IKEv2bis February 2006 + + + managing an SA database wishes to communicate with a peer process. + The table below lists the Notification messages and their + corresponding values. The number of different error statuses was + greatly reduced from IKEv1 both for simplification and to avoid + giving configuration information to probers. + + Types in the range 0 - 16383 are intended for reporting errors. An + implementation receiving a Notify payload with one of these types + that it does not recognize in a response MUST assume that the + corresponding request has failed entirely. {{ Demoted the SHOULD }} + Unrecognized error types in a request and status types in a request + or response MUST be ignored, and they should be logged. + + Notify payloads with status types MAY be added to any message and + MUST be ignored if not recognized. They are intended to indicate + capabilities, and as part of SA negotiation are used to negotiate + non-cryptographic parameters. + + NOTIFY messages: error types Value + ------------------------------------------------------------------- + + RESERVED 0 + + UNSUPPORTED_CRITICAL_PAYLOAD 1 + Sent if the payload has the "critical" bit set and the payload + type is not recognized. Notification Data contains the one-octet + payload type. + + INVALID_IKE_SPI 4 + Indicates an IKE message was received with an unrecognized + destination SPI. This usually indicates that the recipient has + rebooted and forgotten the existence of an IKE_SA. + + INVALID_MAJOR_VERSION 5 + Indicates the recipient cannot handle the version of IKE + specified in the header. The closest version number that the + recipient can support will be in the reply header. + + INVALID_SYNTAX 7 + Indicates the IKE message that was received was invalid because + some type, length, or value was out of range or because the + request was rejected for policy reasons. To avoid a denial of + service attack using forged messages, this status may only be + returned for and in an encrypted packet if the message ID and + cryptographic checksum were valid. To avoid leaking information + to someone probing a node, this status MUST be sent in response + to any error not covered by one of the other status types. + {{ Demoted the SHOULD }} To aid debugging, more detailed error + + + +Kaufman, et al. Expires August 27, 2006 [Page 79] + +Internet-Draft IKEv2bis February 2006 + + + information should be written to a console or log. + + INVALID_MESSAGE_ID 9 + Sent when an IKE message ID outside the supported window is + received. This Notify MUST NOT be sent in a response; the invalid + request MUST NOT be acknowledged. Instead, inform the other side + by initiating an INFORMATIONAL exchange with Notification data + containing the four octet invalid message ID. Sending this + notification is optional, and notifications of this type MUST be + rate limited. + + INVALID_SPI 11 + MAY be sent in an IKE INFORMATIONAL exchange when a node receives + an ESP or AH packet with an invalid SPI. The Notification Data + contains the SPI of the invalid packet. This usually indicates a + node has rebooted and forgotten an SA. If this Informational + Message is sent outside the context of an IKE_SA, it should only + be used by the recipient as a "hint" that something might be + wrong (because it could easily be forged). + + NO_PROPOSAL_CHOSEN 14 + None of the proposed crypto suites was acceptable. + + INVALID_KE_PAYLOAD 17 + The D-H Group # field in the KE payload is not the group # + selected by the responder for this exchange. There are two octets + of data associated with this notification: the accepted D-H Group + # in big endian order. + + AUTHENTICATION_FAILED 24 + Sent in the response to an IKE_AUTH message when for some reason + the authentication failed. There is no associated data. + + SINGLE_PAIR_REQUIRED 34 + This error indicates that a CREATE_CHILD_SA request is + unacceptable because its sender is only willing to accept traffic + selectors specifying a single pair of addresses. The requestor is + expected to respond by requesting an SA for only the specific + traffic it is trying to forward. + + NO_ADDITIONAL_SAS 35 + This error indicates that a CREATE_CHILD_SA request is + unacceptable because the responder is unwilling to accept any + more CHILD_SAs on this IKE_SA. Some minimal implementations may + only accept a single CHILD_SA setup in the context of an initial + IKE exchange and reject any subsequent attempts to add more. + + INTERNAL_ADDRESS_FAILURE 36 + + + +Kaufman, et al. Expires August 27, 2006 [Page 80] + +Internet-Draft IKEv2bis February 2006 + + + Indicates an error assigning an internal address (i.e., + INTERNAL_IP4_ADDRESS or INTERNAL_IP6_ADDRESS) during the + processing of a Configuration Payload by a responder. If this + error is generated within an IKE_AUTH exchange, no CHILD_SA will + be created. + + FAILED_CP_REQUIRED 37 + Sent by responder in the case where CP(CFG_REQUEST) was expected + but not received, and so is a conflict with locally configured + policy. There is no associated data. + + TS_UNACCEPTABLE 38 + Indicates that none of the addresses/protocols/ports in the + supplied traffic selectors is acceptable. + + INVALID_SELECTORS 39 + MAY be sent in an IKE INFORMATIONAL exchange when a node receives + an ESP or AH packet whose selectors do not match those of the SA + on which it was delivered (and that caused the packet to be + dropped). The Notification Data contains the start of the + offending packet (as in ICMP messages) and the SPI field of the + notification is set to match the SPI of the IPsec SA. + + RESERVED TO IANA 40-8191 + + PRIVATE USE 8192-16383 + + + NOTIFY messages: status types Value + ------------------------------------------------------------------- + + INITIAL_CONTACT 16384 + This notification asserts that this IKE_SA is the only IKE_SA + currently active between the authenticated identities. It MAY be + sent when an IKE_SA is established after a crash, and the + recipient MAY use this information to delete any other IKE_SAs it + has to the same authenticated identity without waiting for a + timeout. This notification MUST NOT be sent by an entity that may + be replicated (e.g., a roaming user's credentials where the user + is allowed to connect to the corporate firewall from two remote + systems at the same time). {{ Clarif-7.9 }} The INITIAL_CONTACT + notification, if sent, SHOULD be in the first IKE_AUTH request, + not as a separate exchange afterwards; however, receiving + parties need to deal with it in other requests. + + SET_WINDOW_SIZE 16385 + This notification asserts that the sending endpoint is capable of + keeping state for multiple outstanding exchanges, permitting the + + + +Kaufman, et al. Expires August 27, 2006 [Page 81] + +Internet-Draft IKEv2bis February 2006 + + + recipient to send multiple requests before getting a response to + the first. The data associated with a SET_WINDOW_SIZE + notification MUST be 4 octets long and contain the big endian + representation of the number of messages the sender promises to + keep. Window size is always one until the initial exchanges + complete. + + ADDITIONAL_TS_POSSIBLE 16386 + This notification asserts that the sending endpoint narrowed the + proposed traffic selectors but that other traffic selectors would + also have been acceptable, though only in a separate SA (see + section 2.9). There is no data associated with this Notify type. + It may be sent only as an additional payload in a message + including accepted TSs. + + IPCOMP_SUPPORTED 16387 + This notification may be included only in a message containing an + SA payload negotiating a CHILD_SA and indicates a willingness by + its sender to use IPComp on this SA. The data associated with + this notification includes a two-octet IPComp CPI followed by a + one-octet transform ID optionally followed by attributes whose + length and format are defined by that transform ID. A message + proposing an SA may contain multiple IPCOMP_SUPPORTED + notifications to indicate multiple supported algorithms. A + message accepting an SA may contain at most one. + + The transform IDs currently defined are: + + Name Number Defined In + ------------------------------------- + RESERVED 0 + IPCOMP_OUI 1 + IPCOMP_DEFLATE 2 RFC 2394 + IPCOMP_LZS 3 RFC 2395 + IPCOMP_LZJH 4 RFC 3051 + RESERVED TO IANA 5-240 + PRIVATE USE 241-255 + + NAT_DETECTION_SOURCE_IP 16388 + This notification is used by its recipient to determine whether + the source is behind a NAT box. The data associated with this + notification is a SHA-1 digest of the SPIs (in the order they + appear in the header), IP address, and port on which this packet + was sent. There MAY be multiple Notify payloads of this type in a + message if the sender does not know which of several network + attachments will be used to send the packet. The recipient of + this notification MAY compare the supplied value to a SHA-1 hash + of the SPIs, source IP address, and port, and if they don't match + + + +Kaufman, et al. Expires August 27, 2006 [Page 82] + +Internet-Draft IKEv2bis February 2006 + + + it SHOULD enable NAT traversal (see section 2.23). Alternately, + it MAY reject the connection attempt if NAT traversal is not + supported. + + NAT_DETECTION_DESTINATION_IP 16389 + This notification is used by its recipient to determine whether + it is behind a NAT box. The data associated with this + notification is a SHA-1 digest of the SPIs (in the order they + appear in the header), IP address, and port to which this packet + was sent. The recipient of this notification MAY compare the + supplied value to a hash of the SPIs, destination IP address, and + port, and if they don't match it SHOULD invoke NAT traversal (see + section 2.23). If they don't match, it means that this end is + behind a NAT and this end SHOULD start sending keepalive packets + as defined in [UDPENCAPS]. Alternately, it MAY reject the + connection attempt if NAT traversal is not supported. + + COOKIE 16390 + This notification MAY be included in an IKE_SA_INIT response. It + indicates that the request should be retried with a copy of this + notification as the first payload. This notification MUST be + included in an IKE_SA_INIT request retry if a COOKIE notification + was included in the initial response. The data associated with + this notification MUST be between 1 and 64 octets in length + (inclusive). + + USE_TRANSPORT_MODE 16391 + This notification MAY be included in a request message that also + includes an SA payload requesting a CHILD_SA. It requests that + the CHILD_SA use transport mode rather than tunnel mode for the + SA created. If the request is accepted, the response MUST also + include a notification of type USE_TRANSPORT_MODE. If the + responder declines the request, the CHILD_SA will be established + in tunnel mode. If this is unacceptable to the initiator, the + initiator MUST delete the SA. Note: Except when using this option + to negotiate transport mode, all CHILD_SAs will use tunnel mode. + + Note: The ECN decapsulation modifications specified in + [IPSECARCH] MUST be performed for every tunnel mode SA created + by IKEv2. + + HTTP_CERT_LOOKUP_SUPPORTED 16392 + This notification MAY be included in any message that can include + a CERTREQ payload and indicates that the sender is capable of + looking up certificates based on an HTTP-based URL (and hence + presumably would prefer to receive certificate specifications in + that format). + + + + +Kaufman, et al. Expires August 27, 2006 [Page 83] + +Internet-Draft IKEv2bis February 2006 + + + REKEY_SA 16393 + This notification MUST be included in a CREATE_CHILD_SA exchange + if the purpose of the exchange is to replace an existing ESP or + AH SA. The SPI field identifies the SA being rekeyed. + {{ Clarif-5.4 }} The SPI placed in the REKEY_SA + notification is the SPI the exchange initiator would expect in + inbound ESP or AH packets. There is no data. + + ESP_TFC_PADDING_NOT_SUPPORTED 16394 + This notification asserts that the sending endpoint will NOT + accept packets that contain Flow Confidentiality (TFC) padding. + {{ Clarif-4.5 }} The scope of this message is a single + CHILD_SA, and thus this notification is included in messages + containing an SA payload negotiating a CHILD_SA. If neither + endpoint accepts TFC padding, this notification SHOULD be + included in both the request proposing an SA and the response + accepting it. If this notification is included in only one of + the messages, TFC padding can still be sent in the other + direction. + + NON_FIRST_FRAGMENTS_ALSO 16395 + Used for fragmentation control. See [IPSECARCH] for explanation. + {{ Clarif-4.6 }} Sending non-first fragments is + enabled only if NON_FIRST_FRAGMENTS_ALSO notification is + included in both the request proposing an SA and the response + accepting it. If the peer rejects this proposal, the peer only + omits NON_FIRST_FRAGMENTS_ALSO notification from the response, + but does not reject the whole CHILD_SA creation. + + RESERVED TO IANA 16396-40959 + + PRIVATE USE 40960-65535 + +3.11. Delete Payload + + The Delete Payload, denoted D in this memo, contains a protocol + specific security association identifier that the sender has removed + from its security association database and is, therefore, no longer + valid. Figure 17 shows the format of the Delete Payload. It is + possible to send multiple SPIs in a Delete payload; however, each SPI + MUST be for the same protocol. Mixing of protocol identifiers MUST + NOT be performed in the Delete payload. It is permitted, however, to + include multiple Delete payloads in a single INFORMATIONAL exchange + where each Delete payload lists SPIs for a different protocol. + + Deletion of the IKE_SA is indicated by a protocol ID of 1 (IKE) but + no SPIs. Deletion of a CHILD_SA, such as ESP or AH, will contain the + IPsec protocol ID of that protocol (2 for AH, 3 for ESP), and the SPI + + + +Kaufman, et al. Expires August 27, 2006 [Page 84] + +Internet-Draft IKEv2bis February 2006 + + + is the SPI the sending endpoint would expect in inbound ESP or AH + packets. + + The Delete Payload is defined as follows: + + 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 ! # of SPIs ! + +-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+ + ! ! + ~ Security Parameter Index(es) (SPI) ~ + ! ! + +-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+ + + Figure 17: Delete Payload Format + + o Protocol ID (1 octet) - Must be 1 for an IKE_SA, 2 for AH, or 3 + for ESP. + + o SPI Size (1 octet) - Length in octets of the SPI as defined by the + protocol ID. It MUST be 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 Delete + payload. 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 length of this + field is determined by the SPI Size and # of SPIs fields. + + The payload type for the Delete Payload is forty two (42). + +3.12. Vendor ID Payload + + The Vendor ID Payload, denoted V in this memo, contains a vendor + defined constant. The constant is used by vendors to identify and + recognize remote instances of their implementations. This mechanism + allows a vendor to experiment with new features while maintaining + backward compatibility. + + A Vendor ID payload MAY announce that the sender is capable to + accepting certain extensions to the protocol, or it MAY simply + identify the implementation as an aid in debugging. A Vendor ID + payload MUST NOT change the interpretation of any information defined + in this specification (i.e., the critical bit MUST be set to 0). + + + +Kaufman, et al. Expires August 27, 2006 [Page 85] + +Internet-Draft IKEv2bis February 2006 + + + Multiple Vendor ID payloads MAY be sent. An implementation is NOT + REQUIRED to send any Vendor ID payload at all. + + A Vendor ID payload may be sent as part of any message. Reception of + a familiar Vendor ID payload allows an implementation to make use of + Private USE numbers described throughout this memo-- private + payloads, private exchanges, private notifications, etc. Unfamiliar + Vendor IDs MUST be ignored. + + Writers of Internet-Drafts who wish to extend this protocol MUST + define a Vendor ID payload to announce the ability to implement the + extension in the Internet-Draft. It is expected that Internet-Drafts + that gain acceptance and are standardized will be given "magic + numbers" out of the Future Use range by IANA, and the requirement to + use a Vendor ID will go away. + + The Vendor ID Payload fields are defined as follows: + + 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 ! + +-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+ + ! ! + ~ Vendor ID (VID) ~ + ! ! + +-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+ + + Figure 18: Vendor ID Payload Format + + o Vendor ID (variable length) - It is the responsibility of the + person choosing the Vendor ID to assure its uniqueness in spite of + the absence of any central registry for IDs. Good practice is to + include a company name, a person name, or some such. If you want + to show off, you might include the latitude and longitude and time + where you were when you chose the ID and some random input. A + message digest of a long unique string is preferable to the long + unique string itself. + + The payload type for the Vendor ID Payload is forty three (43). + +3.13. Traffic Selector Payload + + The Traffic Selector Payload, denoted TS in this memo, allows peers + to identify packet flows for processing by IPsec security services. + The Traffic Selector Payload consists of the IKE generic payload + header followed by individual traffic selectors as follows: + + + + +Kaufman, et al. Expires August 27, 2006 [Page 86] + +Internet-Draft IKEv2bis February 2006 + + + 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 ! + +-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+ + ! Number of TSs ! RESERVED ! + +-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+ + ! ! + ~ <Traffic Selectors> ~ + ! ! + +-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+ + + Figure 19: Traffic Selectors Payload Format + + o Number of TSs (1 octet) - Number of traffic selectors being + provided. + + o RESERVED - This field MUST be sent as zero and MUST be ignored on + receipt. + + o Traffic Selectors (variable length) - One or more individual + traffic selectors. + + The length of the Traffic Selector payload includes the TS header and + all the traffic selectors. + + The payload type for the Traffic Selector payload is forty four (44) + for addresses at the initiator's end of the SA and forty five (45) + for addresses at the responder's end. + + {{ Clarif-4.7 }} There is no requirement that TSi and TSr contain the + same number of individual traffic selectors. Thus, they are + interpreted as follows: a packet matches a given TSi/TSr if it + matches at least one of the individual selectors in TSi, and at least + one of the individual selectors in TSr. + + For instance, the following traffic selectors: + + TSi = ((17, 100, 192.0.1.66-192.0.1.66), + (17, 200, 192.0.1.66-192.0.1.66)) + TSr = ((17, 300, 0.0.0.0-255.255.255.255), + (17, 400, 0.0.0.0-255.255.255.255)) + + would match UDP packets from 192.0.1.66 to anywhere, with any of the + four combinations of source/destination ports (100,300), (100,400), + (200,300), and (200, 400). + + Thus, some types of policies may require several CHILD_SA pairs. For + + + +Kaufman, et al. Expires August 27, 2006 [Page 87] + +Internet-Draft IKEv2bis February 2006 + + + instance, a policy matching only source/destination ports (100,300) + and (200,400), but not the other two combinations, cannot be + negotiated as a single CHILD_SA pair. + +3.13.1. Traffic Selector + + 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 + +-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+ + ! TS Type !IP Protocol ID*| Selector Length | + +-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+ + | Start Port* | End Port* | + +-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+ + ! ! + ~ Starting Address* ~ + ! ! + +-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+ + ! ! + ~ Ending Address* ~ + ! ! + +-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+ + + Figure 20: Traffic Selector + + *Note: All fields other than TS Type and Selector Length depend on + the TS Type. The fields shown are for TS Types 7 and 8, the only two + values currently defined. + + o TS Type (one octet) - Specifies the type of traffic selector. + + o IP protocol ID (1 octet) - Value specifying an associated IP + protocol ID (e.g., UDP/TCP/ICMP). A value of zero means that the + protocol ID is not relevant to this traffic selector-- the SA can + carry all protocols. + + o Selector Length - Specifies the length of this Traffic Selector + Substructure including the header. + + o Start Port (2 octets) - Value specifying the smallest port number + allowed by this Traffic Selector. For protocols for which port is + undefined, or if all ports are allowed, this field MUST be zero. + For the ICMP protocol, the two one-octet fields Type and Code are + treated as a single 16-bit integer (with Type in the most + significant eight bits and Code in the least significant eight + bits) port number for the purposes of filtering based on this + field. + + + + + +Kaufman, et al. Expires August 27, 2006 [Page 88] + +Internet-Draft IKEv2bis February 2006 + + + o End Port (2 octets) - Value specifying the largest port number + allowed by this Traffic Selector. For protocols for which port is + undefined, or if all ports are allowed, this field MUST be 65535. + For the ICMP protocol, the two one-octet fields Type and Code are + treated as a single 16-bit integer (with Type in the most + significant eight bits and Code in the least significant eight + bits) port number for the purposed of filtering based on this + field. + + o Starting Address - The smallest address included in this Traffic + Selector (length determined by TS type). + + o Ending Address - The largest address included in this Traffic + Selector (length determined by TS type). + + Systems that are complying with [IPSECARCH] that wish to indicate + "ANY" ports MUST set the start port to 0 and the end port to 65535; + note that according to [IPSECARCH], "ANY" includes "OPAQUE". Systems + working with [IPSECARCH] that wish to indicate "OPAQUE" ports, but + not "ANY" ports, MUST set the start port to 65535 and the end port to + 0. + + {{ Added from Clarif-4.8 }} The traffic selector types 7 and 8 can + also refer to ICMP type and code fields. Note, however, that ICMP + packets do not have separate source and destination port fields. The + method for specifying the traffic selectors for ICMP is shown by + example in Section 4.4.1.3 of [IPSECARCH]. + + {{ Added from Clarif-4.9 }} Traffic selectors can use IP Protocol ID + 135 to match the IPv6 mobility header [MIPV6]. This document does + not specify how to represent the "MH Type" field in traffic + selectors, although it is likely that a different document will + specify this in the future. Note that [IPSECARCH] says that the IPv6 + mobility header (MH) message type is placed in the most significant + eight bits of the 16-bit local port selector. The direction + semantics of TSi/TSr port fields are the same as for ICMP. + + The following table lists the assigned values for the Traffic + Selector Type field and the corresponding Address Selector Data. + + + + + + + + + + + + +Kaufman, et al. Expires August 27, 2006 [Page 89] + +Internet-Draft IKEv2bis February 2006 + + + TS Type Value + ------------------------------------------------------------------- + RESERVED 0-6 + + TS_IPV4_ADDR_RANGE 7 + + A range of IPv4 addresses, represented by two four-octet + values. The first value is the beginning IPv4 address + (inclusive) and the second value is the ending IPv4 address + (inclusive). All addresses falling between the two specified + addresses are considered to be within the list. + + TS_IPV6_ADDR_RANGE 8 + + A range of IPv6 addresses, represented by two sixteen-octet + values. The first value is the beginning IPv6 address + (inclusive) and the second value is the ending IPv6 address + (inclusive). All addresses falling between the two specified + addresses are considered to be within the list. + + RESERVED TO IANA 9-240 + PRIVATE USE 241-255 + +3.14. Encrypted Payload + + The Encrypted Payload, denoted SK{...} or E in this memo, contains + other payloads in encrypted form. The Encrypted Payload, if present + in a message, MUST be the last payload in the message. Often, it is + the only payload in the message. + + The algorithms for encryption and integrity protection are negotiated + during IKE_SA setup, and the keys are computed as specified in + Section 2.14 and Section 2.18. + + The encryption and integrity protection algorithms are modeled after + the ESP algorithms described in RFCs 2104 [HMAC], 4303 [ESP], and + 2451 [ESPCBC]. This document completely specifies the cryptographic + processing of IKE data, but those documents should be consulted for + design rationale. We require a block cipher with a fixed block size + and an integrity check algorithm that computes a fixed-length + checksum over a variable size message. + + The payload type for an Encrypted payload is forty six (46). The + Encrypted Payload consists of the IKE generic payload header followed + by individual fields as follows: + + + + + + +Kaufman, et al. Expires August 27, 2006 [Page 90] + +Internet-Draft IKEv2bis February 2006 + + + 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 ! + +-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+ + ! Initialization Vector ! + ! (length is block size for encryption algorithm) ! + +-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+ + ~ Encrypted IKE Payloads ~ + + +-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+ + ! ! Padding (0-255 octets) ! + +-+-+-+-+-+-+-+-+ +-+-+-+-+-+-+-+-+ + ! ! Pad Length ! + +-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+ + ~ Integrity Checksum Data ~ + +-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+ + + Figure 21: Encrypted Payload Format + + o Next Payload - The payload type of the first embedded payload. + Note that this is an exception in the standard header format, + since the Encrypted payload is the last payload in the message and + therefore the Next Payload field would normally be zero. But + because the content of this payload is embedded payloads and there + was no natural place to put the type of the first one, that type + is placed here. + + o Payload Length - Includes the lengths of the header, IV, Encrypted + IKE Payloads, Padding, Pad Length, and Integrity Checksum Data. + + o Initialization Vector - A randomly chosen value whose length is + equal to the block length of the underlying encryption algorithm. + Recipients MUST accept any value. Senders SHOULD either pick this + value pseudo-randomly and independently for each message or use + the final ciphertext block of the previous message sent. Senders + MUST NOT use the same value for each message, use a sequence of + values with low hamming distance (e.g., a sequence number), or use + ciphertext from a received message. + + o IKE Payloads are as specified earlier in this section. This field + is encrypted with the negotiated cipher. + + o Padding MAY contain any value chosen by the sender, and MUST have + a length that makes the combination of the Payloads, the Padding, + and the Pad Length to be a multiple of the encryption block size. + This field is encrypted with the negotiated cipher. + + + + + +Kaufman, et al. Expires August 27, 2006 [Page 91] + +Internet-Draft IKEv2bis February 2006 + + + o Pad Length is the length of the Padding field. The sender SHOULD + set the Pad Length to the minimum value that makes the combination + of the Payloads, the Padding, and the Pad Length a multiple of the + block size, but the recipient MUST accept any length that results + in proper alignment. This field is encrypted with the negotiated + cipher. + + o Integrity Checksum Data is the cryptographic checksum of the + entire message starting with the Fixed IKE Header through the Pad + Length. The checksum MUST be computed over the encrypted message. + Its length is determined by the integrity algorithm negotiated. + +3.15. Configuration Payload + + The Configuration payload, denoted CP in this document, is used to + exchange configuration information between IKE peers. The exchange + is for an IRAC to request an internal IP address from an IRAS and to + exchange other information of the sort that one would acquire with + Dynamic Host Configuration Protocol (DHCP) if the IRAC were directly + connected to a LAN. + + Configuration payloads are of type CFG_REQUEST/CFG_REPLY or CFG_SET/ + CFG_ACK (see CFG Type in the payload description below). CFG_REQUEST + and CFG_SET payloads may optionally be added to any IKE request. The + IKE response MUST include either a corresponding CFG_REPLY or CFG_ACK + or a Notify payload with an error type indicating why the request + could not be honored. An exception is that a minimal implementation + MAY ignore all CFG_REQUEST and CFG_SET payloads, so a response + message without a corresponding CFG_REPLY or CFG_ACK MUST be accepted + as an indication that the request was not supported. + + "CFG_REQUEST/CFG_REPLY" allows an IKE endpoint to request information + from its peer. If an attribute in the CFG_REQUEST Configuration + Payload is not zero-length, it is taken as a suggestion for that + attribute. The CFG_REPLY Configuration Payload MAY return that + value, or a new one. It MAY also add new attributes and not include + some requested ones. Requestors MUST ignore returned attributes that + they do not recognize. + + Some attributes MAY be multi-valued, in which case multiple attribute + values of the same type are sent and/or returned. Generally, all + values of an attribute are returned when the attribute is requested. + For some attributes (in this version of the specification only + internal addresses), multiple requests indicates a request that + multiple values be assigned. For these attributes, the number of + values returned SHOULD NOT exceed the number requested. + + If the data type requested in a CFG_REQUEST is not recognized or not + + + +Kaufman, et al. Expires August 27, 2006 [Page 92] + +Internet-Draft IKEv2bis February 2006 + + + supported, the responder MUST NOT return an error type but rather + MUST either send a CFG_REPLY that MAY be empty or a reply not + containing a CFG_REPLY payload at all. Error returns are reserved + for cases where the request is recognized but cannot be performed as + requested or the request is badly formatted. + + "CFG_SET/CFG_ACK" allows an IKE endpoint to push configuration data + to its peer. In this case, the CFG_SET Configuration Payload + contains attributes the initiator wants its peer to alter. The + responder MUST return a Configuration Payload if it accepted any of + the configuration data and it MUST contain the attributes that the + responder accepted with zero-length data. Those attributes that it + did not accept MUST NOT be in the CFG_ACK Configuration Payload. If + no attributes were accepted, the responder MUST return either an + empty CFG_ACK payload or a response message without a CFG_ACK + payload. There are currently no defined uses for the CFG_SET/CFG_ACK + exchange, though they may be used in connection with extensions based + on Vendor IDs. An minimal implementation of this specification MAY + ignore CFG_SET payloads. + + {{ Demoted the SHOULD }} Extensions via the CP payload should not be + used for general purpose management. Its main intent is to provide a + bootstrap mechanism to exchange information within IPsec from IRAS to + IRAC. While it MAY be useful to use such a method to exchange + information between some Security Gateways (SGW) or small networks, + existing management protocols such as DHCP [DHCP], RADIUS [RADIUS], + SNMP, or LDAP [LDAP] should be preferred for enterprise management as + well as subsequent information exchanges. + + The Configuration Payload is defined as follows: + + 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 ! + +-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+ + ! CFG Type ! RESERVED ! + +-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+ + ! ! + ~ Configuration Attributes ~ + ! ! + +-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+ + + Figure 22: Configuration Payload Format + + The payload type for the Configuration Payload is forty seven (47). + + + + + +Kaufman, et al. Expires August 27, 2006 [Page 93] + +Internet-Draft IKEv2bis February 2006 + + + o CFG Type (1 octet) - The type of exchange represented by the + Configuration Attributes. + + CFG Type Value + -------------------------- + RESERVED 0 + CFG_REQUEST 1 + CFG_REPLY 2 + CFG_SET 3 + CFG_ACK 4 + RESERVED TO IANA 5-127 + PRIVATE USE 128-255 + + o RESERVED (3 octets) - MUST be sent as zero; MUST be ignored on + receipt. + + o Configuration Attributes (variable length) - These are type length + values specific to the Configuration Payload and are defined + below. There may be zero or more Configuration Attributes in this + payload. + +3.15.1. Configuration Attributes + + 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 + +-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+ + !R| Attribute Type ! Length | + +-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+ + | | + ~ Value ~ + | | + +-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+ + + Figure 23: Configuration Attribute Format + + o Reserved (1 bit) - This bit MUST be set to zero and MUST be + ignored on receipt. + + o Attribute Type (15 bits) - A unique identifier for each of the + Configuration Attribute Types. + + o Length (2 octets) - Length in octets of Value. + + o Value (0 or more octets) - The variable-length value of this + Configuration Attribute. The following attribute types have been + defined: + + + + + +Kaufman, et al. Expires August 27, 2006 [Page 94] + +Internet-Draft IKEv2bis February 2006 + + + Multi- + Attribute Type Value Valued Length + ------------------------------------------------------- + RESERVED 0 + INTERNAL_IP4_ADDRESS 1 YES* 0 or 4 octets + INTERNAL_IP4_NETMASK 2 NO 0 or 4 octets + INTERNAL_IP4_DNS 3 YES 0 or 4 octets + INTERNAL_IP4_NBNS 4 YES 0 or 4 octets + INTERNAL_ADDRESS_EXPIRY 5 NO 0 or 4 octets + INTERNAL_IP4_DHCP 6 YES 0 or 4 octets + APPLICATION_VERSION 7 NO 0 or more + INTERNAL_IP6_ADDRESS 8 YES* 0 or 17 octets + RESERVED 9 + INTERNAL_IP6_DNS 10 YES 0 or 16 octets + INTERNAL_IP6_NBNS 11 YES 0 or 16 octets + INTERNAL_IP6_DHCP 12 YES 0 or 16 octets + INTERNAL_IP4_SUBNET 13 YES 0 or 8 octets + SUPPORTED_ATTRIBUTES 14 NO Multiple of 2 + INTERNAL_IP6_SUBNET 15 YES 17 octets + RESERVED TO IANA 16-16383 + PRIVATE USE 16384-32767 + + * These attributes may be multi-valued on return only if + multiple values were requested. + + o INTERNAL_IP4_ADDRESS, INTERNAL_IP6_ADDRESS - An address on the + internal network, sometimes called a red node address or private + address and MAY be a private address on the Internet. {{ + Clarif-6.2}} In a request message, the address specified is a + requested address (or a zero-length address if no specific address + is requested). If a specific address is requested, it likely + indicates that a previous connection existed with this address and + the requestor would like to reuse that address. With IPv6, a + requestor MAY supply the low-order address bytes it wants to use. + Multiple internal addresses MAY be requested by requesting + multiple internal address attributes. The responder MAY only send + up to the number of addresses requested. The INTERNAL_IP6_ADDRESS + is made up of two fields: the first is a 16-octet IPv6 address, + and the second is a one-octet prefix-length as defined in + [ADDRIPV6]. + + The requested address is valid until the expiry time defined with + the INTERNAL_ADDRESS_EXPIRY attribute or there are no IKE_SAs + between the peers. + + o INTERNAL_IP4_NETMASK - The internal network's netmask. Only one + netmask is allowed in the request and reply messages (e.g., + 255.255.255.0), and it MUST be used only with an + + + +Kaufman, et al. Expires August 27, 2006 [Page 95] + +Internet-Draft IKEv2bis February 2006 + + + INTERNAL_IP4_ADDRESS attribute. {{ Clarif-6.4 }} + INTERNAL_IP4_NETMASK in a CFG_REPLY means roughly the same thing + as INTERNAL_IP4_SUBNET containing the same information ("send + traffic to these addresses through me"), but also implies a link + boundary. For instance, the client could use its own address and + the netmask to calculate the broadcast address of the link. An + empty INTERNAL_IP4_NETMASK attribute can be included in a + CFG_REQUEST to request this information (although the gateway can + send the information even when not requested). Non-empty values + for this attribute in a CFG_REQUEST do not make sense and thus + MUST NOT be included. + + o INTERNAL_IP4_DNS, INTERNAL_IP6_DNS - Specifies an address of a DNS + server within the network. Multiple DNS servers MAY be requested. + The responder MAY respond with zero or more DNS server attributes. + + o INTERNAL_IP4_NBNS, INTERNAL_IP6_NBNS - Specifies an address of a + NetBios Name Server (WINS) within the network. Multiple NBNS + servers MAY be requested. The responder MAY respond with zero or + more NBNS server attributes. {{ Clarif-6.6 }} NetBIOS is not + defined for IPv6; therefore, INTERNAL_IP6_NBNS SHOULD NOT be used. + + o INTERNAL_ADDRESS_EXPIRY - Specifies the number of seconds that the + host can use the internal IP address. The host MUST renew the IP + address before this expiry time. Only one of these attributes MAY + be present in the reply. {{ Clarif-6.7 }} Expiry times and + explicit renewals are primarily useful in environments like DHCP, + where the server cannot reliably know when the client has gone + away. However, in IKEv2, this is known, and the gateway can + simply free the address when the IKE_SA is deleted. Further, + supporting renewals is not mandatory. Thus + INTERNAL_ADDRESS_EXPIRY attribute MUST NOT be used. + + o INTERNAL_IP4_DHCP, INTERNAL_IP6_DHCP - Instructs the host to send + any internal DHCP requests to the address contained within the + attribute. Multiple DHCP servers MAY be requested. The responder + MAY respond with zero or more DHCP server attributes. + + o APPLICATION_VERSION - The version or application information of + the IPsec host. This is a string of printable ASCII characters + that is NOT null terminated. + + o INTERNAL_IP4_SUBNET - The protected sub-networks that this edge- + device protects. This attribute is made up of two fields: the + first being an IP address and the second being a netmask. + Multiple sub-networks MAY be requested. The responder MAY respond + with zero or more sub-network attributes. + + + + +Kaufman, et al. Expires August 27, 2006 [Page 96] + +Internet-Draft IKEv2bis February 2006 + + + o SUPPORTED_ATTRIBUTES - When used within a Request, this attribute + MUST be zero-length and specifies a query to the responder to + reply back with all of the attributes that it supports. The + response contains an attribute that contains a set of attribute + identifiers each in 2 octets. The length divided by 2 (octets) + would state the number of supported attributes contained in the + response. + + o INTERNAL_IP6_SUBNET - The protected sub-networks that this edge- + device protects. This attribute is made up of two fields: the + first is a 16-octet IPv6 address, and the second is a one-octet + prefix-length as defined in [ADDRIPV6]. Multiple sub-networks MAY + be requested. The responder MAY respond with zero or more sub- + network attributes. + + Note that no recommendations are made in this document as to how an + implementation actually figures out what information to send in a + reply. That is, we do not recommend any specific method of an IRAS + determining which DNS server should be returned to a requesting IRAC. + +3.15.2. Meaning of INTERNAL_IP4_SUBNET/INTERNAL_IP6_SUBNET + + {{ Section added based on Clarif-6.3 }} + + INTERNAL_IP4/6_SUBNET attributes can indicate additional subnets, + ones that need one or more separate SAs, that can be reached through + the gateway that announces the attributes. INTERNAL_IP4/6_SUBNET + attributes may also express the gateway's policy about what traffic + should be sent through the gateway; the client can choose whether + other traffic (covered by TSr, but not in INTERNAL_IP4/6_SUBNET) is + sent through the gateway or directly to the destination. Thus, + traffic to the addresses listed in the INTERNAL_IP4/6_SUBNET + attributes should be sent through the gateway that announces the + attributes. If there are no existing IPsec SAs whose traffic + selectors cover the address in question, new SAs need to be created. + + For instance, if there are two subnets, 192.0.1.0/26 and + 192.0.2.0/24, and the client's request contains the following: + + CP(CFG_REQUEST) = + INTERNAL_IP4_ADDRESS() + TSi = (0, 0-65535, 0.0.0.0-255.255.255.255) + TSr = (0, 0-65535, 0.0.0.0-255.255.255.255) + + then a valid response could be the following (in which TSr and + INTERNAL_IP4_SUBNET contain the same information): + + + + + +Kaufman, et al. Expires August 27, 2006 [Page 97] + +Internet-Draft IKEv2bis February 2006 + + + CP(CFG_REPLY) = + INTERNAL_IP4_ADDRESS(192.0.1.234) + INTERNAL_IP4_SUBNET(192.0.1.0/255.255.255.192) + INTERNAL_IP4_SUBNET(192.0.2.0/255.255.255.0) + TSi = (0, 0-65535, 192.0.1.234-192.0.1.234) + TSr = ((0, 0-65535, 192.0.1.0-192.0.1.63), + (0, 0-65535, 192.0.2.0-192.0.2.255)) + + In these cases, the INTERNAL_IP4_SUBNET does not really carry any + useful information. + + A different possible reply would have been this: + + CP(CFG_REPLY) = + INTERNAL_IP4_ADDRESS(192.0.1.234) + INTERNAL_IP4_SUBNET(192.0.1.0/255.255.255.192) + INTERNAL_IP4_SUBNET(192.0.2.0/255.255.255.0) + TSi = (0, 0-65535, 192.0.1.234-192.0.1.234) + TSr = (0, 0-65535, 0.0.0.0-255.255.255.255) + + That reply would mean that the client can send all its traffic + through the gateway, but the gateway does not mind if the client + sends traffic not included by INTERNAL_IP4_SUBNET directly to the + destination (without going through the gateway). + + A different situation arises if the gateway has a policy that + requires the traffic for the two subnets to be carried in separate + SAs. Then a response like this would indicate to the client that if + it wants access to the second subnet, it needs to create a separate + SA: + + CP(CFG_REPLY) = + INTERNAL_IP4_ADDRESS(192.0.1.234) + INTERNAL_IP4_SUBNET(192.0.1.0/255.255.255.192) + INTERNAL_IP4_SUBNET(192.0.2.0/255.255.255.0) + TSi = (0, 0-65535, 192.0.1.234-192.0.1.234) + TSr = (0, 0-65535, 192.0.1.0-192.0.1.63) + + INTERNAL_IP4_SUBNET can also be useful if the client's TSr included + only part of the address space. For instance, if the client requests + the following: + + CP(CFG_REQUEST) = + INTERNAL_IP4_ADDRESS() + TSi = (0, 0-65535, 0.0.0.0-255.255.255.255) + TSr = (0, 0-65535, 192.0.2.155-192.0.2.155) + + then the gateway's reply might be: + + + +Kaufman, et al. Expires August 27, 2006 [Page 98] + +Internet-Draft IKEv2bis February 2006 + + + CP(CFG_REPLY) = + INTERNAL_IP4_ADDRESS(192.0.1.234) + INTERNAL_IP4_SUBNET(192.0.1.0/255.255.255.192) + INTERNAL_IP4_SUBNET(192.0.2.0/255.255.255.0) + TSi = (0, 0-65535, 192.0.1.234-192.0.1.234) + TSr = (0, 0-65535, 192.0.2.155-192.0.2.155) + + Because the meaning of INTERNAL_IP4_SUBNET/INTERNAL_IP6_SUBNET is in + CFG_REQUESTs is unclear, they cannot be used reliably in + CFG_REQUESTs. + +3.15.3. Configuration payloads for IPv6 + + {{ Added this section from Clarif-6.5 }} + + The configuration payloads for IPv6 are based on the corresponding + IPv4 payloads, and do not fully follow the "normal IPv6 way of doing + things". In particular, IPv6 stateless autoconfiguration or router + advertisement messages are not used; neither is neighbor discovery. + + A client can be assigned an IPv6 address using the + INTERNAL_IP6_ADDRESS configuration payload. A minimal exchange might + look like this: + + CP(CFG_REQUEST) = + INTERNAL_IP6_ADDRESS() + INTERNAL_IP6_DNS() + TSi = (0, 0-65535, :: - FFFF:FFFF:FFFF:FFFF:FFFF:FFFF:FFFF:FFFF) + TSr = (0, 0-65535, :: - FFFF:FFFF:FFFF:FFFF:FFFF:FFFF:FFFF:FFFF) + + CP(CFG_REPLY) = + INTERNAL_IP6_ADDRESS(2001:DB8:0:1:2:3:4:5/64) + INTERNAL_IP6_DNS(2001:DB8:99:88:77:66:55:44) + TSi = (0, 0-65535, 2001:DB8:0:1:2:3:4:5 - 2001:DB8:0:1:2:3:4:5) + TSr = (0, 0-65535, :: - FFFF:FFFF:FFFF:FFFF:FFFF:FFFF:FFFF:FFFF) + + The client MAY send a non-empty INTERNAL_IP6_ADDRESS attribute in the + CFG_REQUEST to request a specific address or interface identifier. + The gateway first checks if the specified address is acceptable, and + if it is, returns that one. If the address was not acceptable, the + gateway attempts to use the interface identifier with some other + prefix; if even that fails, the gateway selects another interface + identifier. + + The INTERNAL_IP6_ADDRESS attribute also contains a prefix length + field. When used in a CFG_REPLY, this corresponds to the + INTERNAL_IP4_NETMASK attribute in the IPv4 case. + + + + +Kaufman, et al. Expires August 27, 2006 [Page 99] + +Internet-Draft IKEv2bis February 2006 + + + Although this approach to configuring IPv6 addresses is reasonably + simple, it has some limitations. IPsec tunnels configured using + IKEv2 are not fully-featured "interfaces" in the IPv6 addressing + architecture sense [IPV6ADDR]. In particular, they do not + necessarily have link-local addresses, and this may complicate the + use of protocols that assume them, such as [MLDV2]. + +3.15.4. Address Assignment Failures + + {{ Added this section from Clarif-6.8 }} + + If the responder encounters an error while attempting to assign an IP + address to the initiator, it responds with an + INTERNAL_ADDRESS_FAILURE notification. However, there are some more + complex error cases. + + If the responder does not support configuration payloads at all, it + can simply ignore all configuration payloads. This type of + implementation never sends INTERNAL_ADDRESS_FAILURE notifications. + If the initiator requires the assignment of an IP address, it will + treat a response without CFG_REPLY as an error. + + The initiator may request a particular type of address (IPv4 or IPv6) + that the responder does not support, even though the responder + supports configuration payloads. In this case, the responder simply + ignores the type of address it does not support and processes the + rest of the request as usual. + + If the initiator requests multiple addresses of a type that the + responder supports, and some (but not all) of the requests fail, the + responder replies with the successful addresses only. The responder + sends INTERNAL_ADDRESS_FAILURE only if no addresses can be assigned. + +3.16. Extensible Authentication Protocol (EAP) Payload + + The Extensible Authentication Protocol Payload, denoted EAP in this + memo, allows IKE_SAs to be authenticated using the protocol defined + in RFC 3748 [EAP] and subsequent extensions to that protocol. The + full set of acceptable values for the payload is defined elsewhere, + but a short summary of RFC 3748 is included here to make this + document stand alone in the common cases. + + + + + + + + + + +Kaufman, et al. Expires August 27, 2006 [Page 100] + +Internet-Draft IKEv2bis February 2006 + + + 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 ! + +-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+ + ! ! + ~ EAP Message ~ + ! ! + +-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+ + + Figure 24: EAP Payload Format + + The payload type for an EAP Payload is forty eight (48). + + 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 + +-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+ + ! Code ! Identifier ! Length ! + +-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+ + ! Type ! Type_Data... + +-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+- + + Figure 25: EAP Message Format + + o Code (1 octet) indicates whether this message is a Request (1), + Response (2), Success (3), or Failure (4). + + o Identifier (1 octet) is used in PPP to distinguish replayed + messages from repeated ones. Since in IKE, EAP runs over a + reliable protocol, it serves no function here. In a response + message, this octet MUST be set to match the identifier in the + corresponding request. In other messages, this field MAY be set + to any value. + + o Length (2 octets) is the length of the EAP message and MUST be + four less than the Payload Length of the encapsulating payload. + + o Type (1 octet) is present only if the Code field is Request (1) or + Response (2). For other codes, the EAP message length MUST be + four octets and the Type and Type_Data fields MUST NOT be present. + In a Request (1) message, Type indicates the data being requested. + In a Response (2) message, Type MUST either be Nak or match the + type of the data requested. The following types are defined in + RFC 3748: + + + + + + + +Kaufman, et al. Expires August 27, 2006 [Page 101] + +Internet-Draft IKEv2bis February 2006 + + + 1 Identity + 2 Notification + 3 Nak (Response Only) + 4 MD5-Challenge + 5 One-Time Password (OTP) + 6 Generic Token Card + + o Type_Data (Variable Length) varies with the Type of Request and + the associated Response. For the documentation of the EAP + methods, see [EAP]. + + {{ Demoted the SHOULD NOT and SHOULD }} Note that since IKE passes an + indication of initiator identity in message 3 of the protocol, the + responder should not send EAP Identity requests. The initiator may, + however, respond to such requests if it receives them. + + +4. Conformance Requirements + + In order to assure that all implementations of IKEv2 can + interoperate, there are "MUST support" requirements in addition to + those listed elsewhere. Of course, IKEv2 is a security protocol, and + one of its major functions is to allow only authorized parties to + successfully complete establishment of SAs. So a particular + implementation may be configured with any of a number of restrictions + concerning algorithms and trusted authorities that will prevent + universal interoperability. + + IKEv2 is designed to permit minimal implementations that can + interoperate with all compliant implementations. There are a series + of optional features that can easily be ignored by a particular + implementation if it does not support that feature. Those features + include: + + o Ability to negotiate SAs through a NAT and tunnel the resulting + ESP SA over UDP. + + o Ability to request (and respond to a request for) a temporary IP + address on the remote end of a tunnel. + + o Ability to support various types of legacy authentication. + + o Ability to support window sizes greater than one. + + o Ability to establish multiple ESP and/or AH SAs within a single + IKE_SA. + + + + + +Kaufman, et al. Expires August 27, 2006 [Page 102] + +Internet-Draft IKEv2bis February 2006 + + + o Ability to rekey SAs. + + To assure interoperability, all implementations MUST be capable of + parsing all payload types (if only to skip over them) and to ignore + payload types that it does not support unless the critical bit is set + in the payload header. If the critical bit is set in an unsupported + payload header, all implementations MUST reject the messages + containing those payloads. + + Every implementation MUST be capable of doing four-message + IKE_SA_INIT and IKE_AUTH exchanges establishing two SAs (one for IKE, + one for ESP and/or AH). Implementations MAY be initiate-only or + respond-only if appropriate for their platform. Every implementation + MUST be capable of responding to an INFORMATIONAL exchange, but a + minimal implementation MAY respond to any INFORMATIONAL message with + an empty INFORMATIONAL reply (note that within the context of an + IKE_SA, an "empty" message consists of an IKE header followed by an + Encrypted payload with no payloads contained in it). A minimal + implementation MAY support the CREATE_CHILD_SA exchange only in so + far as to recognize requests and reject them with a Notify payload of + type NO_ADDITIONAL_SAS. A minimal implementation need not be able to + initiate CREATE_CHILD_SA or INFORMATIONAL exchanges. When an SA + expires (based on locally configured values of either lifetime or + octets passed), and implementation MAY either try to renew it with a + CREATE_CHILD_SA exchange or it MAY delete (close) the old SA and + create a new one. If the responder rejects the CREATE_CHILD_SA + request with a NO_ADDITIONAL_SAS notification, the implementation + MUST be capable of instead deleting the old SA and creating a new + one. + + Implementations are not required to support requesting temporary IP + addresses or responding to such requests. If an implementation does + support issuing such requests, it MUST include a CP payload in + message 3 containing at least a field of type INTERNAL_IP4_ADDRESS or + INTERNAL_IP6_ADDRESS. All other fields are optional. If an + implementation supports responding to such requests, it MUST parse + the CP payload of type CFG_REQUEST in message 3 and recognize a field + of type INTERNAL_IP4_ADDRESS or INTERNAL_IP6_ADDRESS. If it supports + leasing an address of the appropriate type, it MUST return a CP + payload of type CFG_REPLY containing an address of the requested + type. {{ Demoted the SHOULD }} The responder may include any other + related attributes. + + A minimal IPv4 responder implementation will ignore the contents of + the CP payload except to determine that it includes an + INTERNAL_IP4_ADDRESS attribute and will respond with the address and + other related attributes regardless of whether the initiator + requested them. + + + +Kaufman, et al. Expires August 27, 2006 [Page 103] + +Internet-Draft IKEv2bis February 2006 + + + A minimal IPv4 initiator will generate a CP payload containing only + an INTERNAL_IP4_ADDRESS attribute and will parse the response + ignoring attributes it does not know how to use. {{ Clarif-6.7 + removes the sentence about processing INTERNAL_ADDRESS_EXPIRY. }} + Minimal initiators need not be able to request lease renewals and + minimal responders need not respond to them. + + For an implementation to be called conforming to this specification, + it MUST be possible to configure it to accept the following: + + o PKIX Certificates containing and signed by RSA keys of size 1024 + or 2048 bits, where the ID passed is any of ID_KEY_ID, ID_FQDN, + ID_RFC822_ADDR, or ID_DER_ASN1_DN. + + o Shared key authentication where the ID passes is any of ID_KEY_ID, + ID_FQDN, or ID_RFC822_ADDR. + + o Authentication where the responder is authenticated using PKIX + Certificates and the initiator is authenticated using shared key + authentication. + + +5. Security Considerations + + While this protocol is designed to minimize disclosure of + configuration information to unauthenticated peers, some such + disclosure is unavoidable. One peer or the other must identify + itself first and prove its identity first. To avoid probing, the + initiator of an exchange is required to identify itself first, and + usually is required to authenticate itself first. The initiator can, + however, learn that the responder supports IKE and what cryptographic + protocols it supports. The responder (or someone impersonating the + responder) can probe the initiator not only for its identity, but + using CERTREQ payloads may be able to determine what certificates the + initiator is willing to use. + + Use of EAP authentication changes the probing possibilities somewhat. + When EAP authentication is used, the responder proves its identity + before the initiator does, so an initiator that knew the name of a + valid initiator could probe the responder for both its name and + certificates. + + Repeated rekeying using CREATE_CHILD_SA without additional Diffie- + Hellman exchanges leaves all SAs vulnerable to cryptanalysis of a + single key or overrun of either endpoint. Implementers should take + note of this fact and set a limit on CREATE_CHILD_SA exchanges + between exponentiations. This memo does not prescribe such a limit. + + + + +Kaufman, et al. Expires August 27, 2006 [Page 104] + +Internet-Draft IKEv2bis February 2006 + + + The strength of a key derived from a Diffie-Hellman exchange using + any of the groups defined here depends on the inherent strength of + the group, the size of the exponent used, and the entropy provided by + the random number generator used. Due to these inputs, it is + difficult to determine the strength of a key for any of the defined + groups. Diffie-Hellman group number two, when used with a strong + random number generator and an exponent no less than 200 bits, is + common for use with 3DES. Group five provides greater security than + group two. Group one is for historic purposes only and does not + provide sufficient strength except for use with DES, which is also + for historic use only. Implementations should make note of these + estimates when establishing policy and negotiating security + parameters. + + Note that these limitations are on the Diffie-Hellman groups + themselves. There is nothing in IKE that prohibits using stronger + groups nor is there anything that will dilute the strength obtained + from stronger groups (limited by the strength of the other algorithms + negotiated including the prf function). In fact, the extensible + framework of IKE encourages the definition of more groups; use of + elliptical curve groups may greatly increase strength using much + smaller numbers. + + It is assumed that all Diffie-Hellman exponents are erased from + memory after use. In particular, these exponents MUST NOT be derived + from long-lived secrets like the seed to a pseudo-random generator + that is not erased after use. + + The strength of all keys is limited by the size of the output of the + negotiated prf function. For this reason, a prf function whose + output is less than 128 bits (e.g., 3DES-CBC) MUST NOT be used with + this protocol. + + The security of this protocol is critically dependent on the + randomness of the randomly chosen parameters. These should be + generated by a strong random or properly seeded pseudo-random source + (see [RANDOMNESS]). Implementers should take care to ensure that use + of random numbers for both keys and nonces is engineered in a fashion + that does not undermine the security of the keys. + + For information on the rationale of many of the cryptographic design + choices in this protocol, see [SIGMA] and [SKEME]. Though the + security of negotiated CHILD_SAs does not depend on the strength of + the encryption and integrity protection negotiated in the IKE_SA, + implementations MUST NOT negotiate NONE as the IKE integrity + protection algorithm or ENCR_NULL as the IKE encryption algorithm. + + When using pre-shared keys, a critical consideration is how to assure + + + +Kaufman, et al. Expires August 27, 2006 [Page 105] + +Internet-Draft IKEv2bis February 2006 + + + the randomness of these secrets. The strongest practice is to ensure + that any pre-shared key contain as much randomness as the strongest + key being negotiated. Deriving a shared secret from a password, + name, or other low-entropy source is not secure. These sources are + subject to dictionary and social engineering attacks, among others. + + The NAT_DETECTION_*_IP notifications contain a hash of the addresses + and ports in an attempt to hide internal IP addresses behind a NAT. + Since the IPv4 address space is only 32 bits, and it is usually very + sparse, it would be possible for an attacker to find out the internal + address used behind the NAT box by trying all possible IP addresses + and trying to find the matching hash. The port numbers are normally + fixed to 500, and the SPIs can be extracted from the packet. This + reduces the number of hash calculations to 2^32. With an educated + guess of the use of private address space, the number of hash + calculations is much smaller. Designers should therefore not assume + that use of IKE will not leak internal address information. + + When using an EAP authentication method that does not generate a + shared key for protecting a subsequent AUTH payload, certain man-in- + the-middle and server impersonation attacks are possible [EAPMITM]. + These vulnerabilities occur when EAP is also used in protocols that + are not protected with a secure tunnel. Since EAP is a general- + purpose authentication protocol, which is often used to provide + single-signon facilities, a deployed IPsec solution that relies on an + EAP authentication method that does not generate a shared key (also + known as a non-key-generating EAP method) can become compromised due + to the deployment of an entirely unrelated application that also + happens to use the same non-key-generating EAP method, but in an + unprotected fashion. Note that this vulnerability is not limited to + just EAP, but can occur in other scenarios where an authentication + infrastructure is reused. For example, if the EAP mechanism used by + IKEv2 utilizes a token authenticator, a man-in-the-middle attacker + could impersonate the web server, intercept the token authentication + exchange, and use it to initiate an IKEv2 connection. For this + reason, use of non-key-generating EAP methods SHOULD be avoided where + possible. Where they are used, it is extremely important that all + usages of these EAP methods SHOULD utilize a protected tunnel, where + the initiator validates the responder's certificate before initiating + the EAP exchange. {{ Demoted the SHOULD }} Implementers should + describe the vulnerabilities of using non-key-generating EAP methods + in the documentation of their implementations so that the + administrators deploying IPsec solutions are aware of these dangers. + + An implementation using EAP MUST also use a public-key-based + authentication of the server to the client before the EAP exchange + begins, even if the EAP method offers mutual authentication. This + avoids having additional IKEv2 protocol variations and protects the + + + +Kaufman, et al. Expires August 27, 2006 [Page 106] + +Internet-Draft IKEv2bis February 2006 + + + EAP data from active attackers. + + If the messages of IKEv2 are long enough that IP-level fragmentation + is necessary, it is possible that attackers could prevent the + exchange from completing by exhausting the reassembly buffers. The + chances of this can be minimized by using the Hash and URL encodings + instead of sending certificates (see Section 3.6). Additional + mitigations are discussed in [DOSUDPPROT]. + +5.1. Traffic selector authorization + + {{ Added this section from Clarif-4.13 }} + + IKEv2 relies on information in the Peer Authorization Database (PAD) + when determining what kind of IPsec SAs a peer is allowed to create. + This process is described in [IPSECARCH] Section 4.4.3. When a peer + requests the creation of an IPsec SA with some traffic selectors, the + PAD must contain "Child SA Authorization Data" linking the identity + authenticated by IKEv2 and the addresses permitted for traffic + selectors. + + For example, the PAD might be configured so that authenticated + identity "sgw23.example.com" is allowed to create IPsec SAs for + 192.0.2.0/24, meaning this security gateway is a valid + "representative" for these addresses. Host-to-host IPsec requires + similar entries, linking, for example, "fooserver4.example.com" with + 192.0.1.66/32, meaning this identity a valid "owner" or + "representative" of the address in question. + + As noted in [IPSECARCH], "It is necessary to impose these constraints + on creation of child SAs to prevent an authenticated peer from + spoofing IDs associated with other, legitimate peers." In the + example given above, a correct configuration of the PAD prevents + sgw23 from creating IPsec SAs with address 192.0.1.66, and prevents + fooserver4 from creating IPsec SAs with addresses from 192.0.2.0/24. + + It is important to note that simply sending IKEv2 packets using some + particular address does not imply a permission to create IPsec SAs + with that address in the traffic selectors. For example, even if + sgw23 would be able to spoof its IP address as 192.0.1.66, it could + not create IPsec SAs matching fooserver4's traffic. + + The IKEv2 specification does not specify how exactly IP address + assignment using configuration payloads interacts with the PAD. Our + interpretation is that when a security gateway assigns an address + using configuration payloads, it also creates a temporary PAD entry + linking the authenticated peer identity and the newly allocated inner + address. + + + +Kaufman, et al. Expires August 27, 2006 [Page 107] + +Internet-Draft IKEv2bis February 2006 + + + It has been recognized that configuring the PAD correctly may be + difficult in some environments. For instance, if IPsec is used + between a pair of hosts whose addresses are allocated dynamically + using DHCP, it is extremely difficult to ensure that the PAD + specifies the correct "owner" for each IP address. This would + require a mechanism to securely convey address assignments from the + DHCP server, and link them to identities authenticated using IKEv2. + + Due to this limitation, some vendors have been known to configure + their PADs to allow an authenticated peer to create IPsec SAs with + traffic selectors containing the same address that was used for the + IKEv2 packets. In environments where IP spoofing is possible (i.e., + almost everywhere) this essentially allows any peer to create IPsec + SAs with any traffic selectors. This is not an appropriate or secure + configuration in most circumstances. See [H2HIPSEC] for an extensive + discussion about this issue, and the limitations of host-to-host + IPsec in general. + + +6. IANA Considerations + + {{ This section was changed to not re-define any new IANA registries. + }} + + [IKEV2] defined many field types and values. IANA has already + registered those types and values, so the are not listed here again. + No new types or values are registered in this document. + + +7. Acknowledgements + + The acknowledgements from the IKEv2 document were: + + This document is a collaborative effort of the entire IPsec WG. If + there were no limit to the number of authors that could appear on an + RFC, the following, in alphabetical order, would have been listed: + Bill Aiello, Stephane Beaulieu, Steve Bellovin, Sara Bitan, Matt + Blaze, Ran Canetti, Darren Dukes, Dan Harkins, Paul Hoffman, John + Ioannidis, Charlie Kaufman, Steve Kent, Angelos Keromytis, Tero + Kivinen, Hugo Krawczyk, Andrew Krywaniuk, Radia Perlman, Omer + Reingold, and Michael Richardson. Many other people contributed to + the design. It is an evolution of IKEv1, ISAKMP, and the IPsec DOI, + each of which has its own list of authors. Hugh Daniel suggested the + feature of having the initiator, in message 3, specify a name for the + responder, and gave the feature the cute name "You Tarzan, Me Jane". + David Faucher and Valery Smyzlov helped refine the design of the + traffic selector negotiation. + + + + +Kaufman, et al. Expires August 27, 2006 [Page 108] + +Internet-Draft IKEv2bis February 2006 + + + This paragraph lists references that appear only in figures. The + section is only here to keep the 'xml2rfc' program happy, and will be + removed when the document is published. Feel free to ignore it. + [DES] [IDEA] [MD5] [X.501] [X.509] + + +8. References + +8.1. Normative References + + [ADDGROUP] + Kivinen, T. and M. Kojo, "More Modular Exponential (MODP) + Diffie-Hellman groups for Internet Key Exchange (IKE)", + RFC 3526, May 2003. + + [ADDRIPV6] + Hinden, R. and S. Deering, "Internet Protocol Version 6 + (IPv6) Addressing Architecture", RFC 3513, April 2003. + + [Clarif] "IKEv2 Clarifications and Implementation Guidelines", + draft-eronen-ipsec-ikev2-clarifications (work in + progress). + + [EAP] Aboba, B., Blunk, L., Vollbrecht, J., Carlson, J., and H. + Levkowetz, "Extensible Authentication Protocol (EAP)", + RFC 3748, June 2004. + + [ECN] Ramakrishnan, K., Floyd, S., and D. Black, "The Addition + of Explicit Congestion Notification (ECN) to IP", + RFC 3168, September 2001. + + [ESPCBC] Pereira, R. and R. Adams, "The ESP CBC-Mode Cipher + Algorithms", RFC 2451, November 1998. + + [IANACONS] + Narten, T. and H. Alvestrand, "Guidelines for Writing an + IANA Considerations Section in RFCs", BCP 26, RFC 2434. + + [IKEV2] Kaufman, C., "Internet Key Exchange (IKEv2) Protocol", + RFC 4306, December 2005. + + [IPSECARCH] + Kent, S. and K. Seo, "Security Architecture for the + Internet Protocol", RFC 4301, December 2005. + + [MUSTSHOULD] + Bradner, S., "Key Words for use in RFCs to indicate + Requirement Levels", BCP 14, RFC 2119, March 1997. + + + +Kaufman, et al. Expires August 27, 2006 [Page 109] + +Internet-Draft IKEv2bis February 2006 + + + [PKIX] Housley, R., Polk, W., Ford, W., and D. Solo, "Internet + X.509 Public Key Infrastructure Certificate and + Certificate Revocation List (CRL) Profile", RFC 3280, + April 2002. + + [UDPENCAPS] + Huttunen, A., Swander, B., Volpe, V., DiBurro, L., and M. + Stenberg, "UDP Encapsulation of IPsec ESP Packets", + RFC 3948, January 2005. + +8.2. Informative References + + [AH] Kent, S., "IP Authentication Header", RFC 4302, + December 2005. + + [ARCHGUIDEPHIL] + Bush, R. and D. Meyer, "Some Internet Architectural + Guidelines and Philosophy", RFC 3439, December 2002. + + [ARCHPRINC] + Carpenter, B., "Architectural Principles of the Internet", + RFC 1958, June 1996. + + [DES] American National Standards Institute, "American National + Standard for Information Systems-Data Link Encryption", + ANSI X3.106, 1983. + + [DH] Diffie, W. and M. Hellman, "New Directions in + Cryptography", IEEE Transactions on Information Theory, + V.IT-22 n. 6, June 1977. + + [DHCP] Droms, R., "Dynamic Host Configuration Protocol", + RFC 2131, March 1997. + + [DIFFSERVARCH] + Blake, S., Black, D., Carlson, M., Davies, E., Wang, Z., + and W. Weiss, "An Architecture for Differentiated + Services", RFC 2475. + + [DIFFSERVFIELD] + Nichols, K., Blake, S., Baker, F., and D. Black, + "Definition of the Differentiated Services Field (DS + Field) in the IPv4 and IPv6 Headers", RFC 2474, + December 1998. + + [DIFFTUNNEL] + Black, D., "Differentiated Services and Tunnels", + RFC 2983, October 2000. + + + +Kaufman, et al. Expires August 27, 2006 [Page 110] + +Internet-Draft IKEv2bis February 2006 + + + [DOI] Piper, D., "The Internet IP Security Domain of + Interpretation for ISAKMP", RFC 2407, November 1998. + + [DOSUDPPROT] + C. Kaufman, R. Perlman, and B. Sommerfeld, "DoS protection + for UDP-based protocols", ACM Conference on Computer and + Communications Security , October 2003. + + [DSS] National Institute of Standards and Technology, U.S. + Department of Commerce, "Digital Signature Standard", + FIPS 186, May 1994. + + [EAPMITM] N. Asokan, V. Nierni, and K. Nyberg, "Man-in-the-Middle in + Tunneled Authentication Protocols", November 2002, + <http://eprint.iacr.org/2002/163>. + + [ESP] Kent, S., "IP Encapsulating Security Payload (ESP)", + RFC 4303, December 2005. + + [EXCHANGEANALYSIS] + R. Perlman and C. Kaufman, "Analysis of the IPsec key + exchange Standard", WET-ICE Security Conference, MIT , + 2001, + <http://sec.femto.org/wetice-2001/papers/radia-paper.pdf>. + + [H2HIPSEC] + Aura, T., Roe, M., and A. Mohammed, "Experiences with + Host-to-Host IPsec", 13th International Workshop on + Security Protocols, Cambridge, UK, April 2005. + + [HMAC] Krawczyk, H., Bellare, M., and R. Canetti, "HMAC: Keyed- + Hashing for Message Authentication", RFC 2104, + February 1997. + + [IDEA] X. Lai, "On the Design and Security of Block Ciphers", ETH + Series in Information Processing, v. 1, Konstanz: Hartung- + Gorre Verlag, 1992. + + [IKEV1] Harkins, D. and D. Carrel, "The Internet Key Exchange + (IKE)", RFC 2409, November 1998. + + [IPCOMP] Shacham, A., Monsour, B., Pereira, R., and M. Thomas, "IP + Payload Compression Protocol (IPComp)", RFC 3173, + September 2001. + + [IPSECARCH-OLD] + Kent, S. and R. Atkinson, "Security Architecture for the + Internet Protocol", RFC 2401, November 1998. + + + +Kaufman, et al. Expires August 27, 2006 [Page 111] + +Internet-Draft IKEv2bis February 2006 + + + [IPV6ADDR] + Hinden, R. and S. Deering, "Internet Protocol Version 6 + (IPv6) Addressing Architecture", RFC 3513, April 2003. + + [ISAKMP] Maughan, D., Schneider, M., and M. Schertler, "Internet + Security Association and Key Management Protocol + (ISAKMP)", RFC 2408, November 1998. + + [LDAP] Wahl, M., Howes, T., and S. Kille, "Lightweight Directory + Access Protocol (v3)", RFC 2251, December 1997. + + [MAILFORMAT] + Resnick, P., "Internet Message Format", RFC 2822, + April 2001. + + [MD5] Rivest, R., "The MD5 Message-Digest Algorithm", RFC 1321, + April 1992. + + [MIPV6] Johnson, D., Perkins, C., and J. Arkko, "Mobility Support + in IPv6", RFC 3775, June 2004. + + [MLDV2] Vida, R. and L. Costa, "Multicast Listener Discovery + Version 2 (MLDv2) for IPv6", RFC 3810, June 2004. + + [NAI] Aboba, B. and M. Beadles, "The Network Access Identifier", + RFC 2486, January 1999. + + [NATREQ] Aboba, B. and W. Dixon, "IPsec-Network Address Translation + (NAT) Compatibility Requirements", RFC 3715, March 2004. + + [OAKLEY] Orman, H., "The OAKLEY Key Determination Protocol", + RFC 2412, November 1998. + + [PFKEY] McDonald, D., Metz, C., and B. Phan, "PF_KEY Key + Management API, Version 2", RFC 2367, July 1998. + + [PHOTURIS] + Karn, P. and W. Simpson, "Photuris: Session-Key Management + Protocol", RFC 2522, March 1999. + + [PKCS1] B. Kaliski and J. Staddon, "PKCS #1: RSA Cryptography + Specifications Version 2", September 1998. + + [PRFAES128CBC] + Hoffman, P., "The AES-XCBC-PRF-128 Algorithm for the + Internet Key Exchange Protocol (IKE)", RFC 3664, + January 2004. + + + + +Kaufman, et al. Expires August 27, 2006 [Page 112] + +Internet-Draft IKEv2bis February 2006 + + + [PRFAES128CBC-bis] + Hoffman, P., "The AES-XCBC-PRF-128 Algorithm for the + Internet Key Exchange Protocol (IKE)", + draft-hoffman-rfc3664bis (work in progress), October 2005. + + [RADIUS] Rigney, C., Rubens, A., Simpson, W., and S. Willens, + "Remote Authentication Dial In User Service (RADIUS)", + RFC 2138, April 1997. + + [RANDOMNESS] + Eastlake, D., Schiller, J., and S. Crocker, "Randomness + Requirements for Security", BCP 106, RFC 4086, June 2005. + + [REAUTH] Nir, Y., ""Repeated Authentication in IKEv2", + draft-nir-ikev2-auth-lt (work in progress), May 2005. + + [RSA] R. Rivest, A. Shamir, and L. Adleman, "A Method for + Obtaining Digital Signatures and Public-Key + Cryptosystems", February 1978. + + [SHA] National Institute of Standards and Technology, U.S. + Department of Commerce, "Secure Hash Standard", + FIPS 180-1, May 1994. + + [SIGMA] H. Krawczyk, "SIGMA: the `SIGn-and-MAc' Approach to + Authenticated Diffie-Hellman and its Use in the IKE + Protocols", Advances in Cryptography - CRYPTO 2003 + Proceedings LNCS 2729, 2003, <http:// + www.informatik.uni-trier.de/~ley/db/conf/crypto/ + crypto2003.html>. + + [SKEME] H. Krawczyk, "SKEME: A Versatile Secure Key Exchange + Mechanism for Internet", IEEE Proceedings of the 1996 + Symposium on Network and Distributed Systems Security , + 1996. + + [TRANSPARENCY] + Carpenter, B., "Internet Transparency", RFC 2775, + February 2000. + + [X.501] ITU-T, "Recommendation X.501: Information Technology - + Open Systems Interconnection - The Directory: Models", + 1993. + + [X.509] ITU-T, "Recommendation X.509 (1997 E): Information + Technology - Open Systems Interconnection - The Directory: + Authentication Framework", 1997. + + + + +Kaufman, et al. Expires August 27, 2006 [Page 113] + +Internet-Draft IKEv2bis February 2006 + + +Appendix A. Summary of changes from IKEv1 + + The goals of this revision to IKE are: + + 1. To define the entire IKE protocol in a single document, + replacing RFCs 2407, 2408, and 2409 and incorporating subsequent + changes to support NAT Traversal, Extensible Authentication, and + Remote Address acquisition; + + 2. To simplify IKE by replacing the eight different initial + exchanges with a single four-message exchange (with changes in + authentication mechanisms affecting only a single AUTH payload + rather than restructuring the entire exchange) see + [EXCHANGEANALYSIS]; + + 3. To remove the Domain of Interpretation (DOI), Situation (SIT), + and Labeled Domain Identifier fields, and the Commit and + Authentication only bits; + + 4. To decrease IKE's latency in the common case by making the + initial exchange be 2 round trips (4 messages), and allowing the + ability to piggyback setup of a CHILD_SA on that exchange; + + 5. To replace the cryptographic syntax for protecting the IKE + messages themselves with one based closely on ESP to simplify + implementation and security analysis; + + 6. To reduce the number of possible error states by making the + protocol reliable (all messages are acknowledged) and sequenced. + This allows shortening CREATE_CHILD_SA exchanges from 3 messages + to 2; + + 7. To increase robustness by allowing the responder to not do + significant processing until it receives a message proving that + the initiator can receive messages at its claimed IP address, + and not commit any state to an exchange until the initiator can + be cryptographically authenticated; + + 8. To fix cryptographic weaknesses such as the problem with + symmetries in hashes used for authentication documented by Tero + Kivinen; + + 9. To specify Traffic Selectors in their own payloads type rather + than overloading ID payloads, and making more flexible the + Traffic Selectors that may be specified; + + 10. To specify required behavior under certain error conditions or + when data that is not understood is received in order to make it + + + +Kaufman, et al. Expires August 27, 2006 [Page 114] + +Internet-Draft IKEv2bis February 2006 + + + easier to make future revisions in a way that does not break + backwards compatibility; + + 11. To simplify and clarify how shared state is maintained in the + presence of network failures and Denial of Service attacks; and + + 12. To maintain existing syntax and magic numbers to the extent + possible to make it likely that implementations of IKEv1 can be + enhanced to support IKEv2 with minimum effort. + + +Appendix B. Diffie-Hellman Groups + + There are two Diffie-Hellman groups defined here for use in IKE. + These groups were generated by Richard Schroeppel at the University + of Arizona. Properties of these primes are described in [OAKLEY]. + + The strength supplied by group one may not be sufficient for the + mandatory-to-implement encryption algorithm and is here for historic + reasons. + + Additional Diffie-Hellman groups have been defined in [ADDGROUP]. + +B.1. Group 1 - 768 Bit MODP + + This group is assigned id 1 (one). + + The prime is: 2^768 - 2 ^704 - 1 + 2^64 * { [2^638 pi] + 149686 } + Its hexadecimal value is: + + FFFFFFFF FFFFFFFF C90FDAA2 2168C234 C4C6628B 80DC1CD1 + 29024E08 8A67CC74 020BBEA6 3B139B22 514A0879 8E3404DD + EF9519B3 CD3A431B 302B0A6D F25F1437 4FE1356D 6D51C245 + E485B576 625E7EC6 F44C42E9 A63A3620 FFFFFFFF FFFFFFFF + + The generator is 2. + +B.2. Group 2 - 1024 Bit MODP + + This group is assigned id 2 (two). + + + + + + + + + + + +Kaufman, et al. Expires August 27, 2006 [Page 115] + +Internet-Draft IKEv2bis February 2006 + + + The prime is 2^1024 - 2^960 - 1 + 2^64 * { [2^894 pi] + 129093 }. + Its hexadecimal value is: + + FFFFFFFF FFFFFFFF C90FDAA2 2168C234 C4C6628B 80DC1CD1 + 29024E08 8A67CC74 020BBEA6 3B139B22 514A0879 8E3404DD + EF9519B3 CD3A431B 302B0A6D F25F1437 4FE1356D 6D51C245 + E485B576 625E7EC6 F44C42E9 A637ED6B 0BFF5CB6 F406B7ED + EE386BFB 5A899FA5 AE9F2411 7C4B1FE6 49286651 ECE65381 + FFFFFFFF FFFFFFFF + + The generator is 2. + + +Appendix C. Exchanges and Payloads + + {{ Clarif-AppA }} + + This appendix contains a short summary of the IKEv2 exchanges, and + what payloads can appear in which message. This appendix is purely + informative; if it disagrees with the body of this document, the + other text is considered correct. + + Vendor-ID (V) payloads may be included in any place in any message. + This sequence here shows what are the most logical places for them. + +C.1. IKE_SA_INIT Exchange + + request --> [N(COOKIE)], + SA, KE, Ni, + [N(NAT_DETECTION_SOURCE_IP)+, + N(NAT_DETECTION_DESTINATION_IP)], + [V+] + + normal response <-- SA, KE, Nr, + (no cookie) [N(NAT_DETECTION_SOURCE_IP), + N(NAT_DETECTION_DESTINATION_IP)], + [[N(HTTP_CERT_LOOKUP_SUPPORTED)], CERTREQ+], + [V+] + + + + + + + + + + + + + +Kaufman, et al. Expires August 27, 2006 [Page 116] + +Internet-Draft IKEv2bis February 2006 + + +C.2. IKE_AUTH Exchange without EAP + + request --> IDi, [CERT+], + [N(INITIAL_CONTACT)], + [[N(HTTP_CERT_LOOKUP_SUPPORTED)], CERTREQ+], + [IDr], + AUTH, + [CP(CFG_REQUEST)], + [N(IPCOMP_SUPPORTED)+], + [N(USE_TRANSPORT_MODE)], + [N(ESP_TFC_PADDING_NOT_SUPPORTED)], + [N(NON_FIRST_FRAGMENTS_ALSO)], + SA, TSi, TSr, + [V+] + + response <-- IDr, [CERT+], + AUTH, + [CP(CFG_REPLY)], + [N(IPCOMP_SUPPORTED)], + [N(USE_TRANSPORT_MODE)], + [N(ESP_TFC_PADDING_NOT_SUPPORTED)], + [N(NON_FIRST_FRAGMENTS_ALSO)], + SA, TSi, TSr, + [N(ADDITIONAL_TS_POSSIBLE)], + [V+] + + + + + + + + + + + + + + + + + + + + + + + + + + +Kaufman, et al. Expires August 27, 2006 [Page 117] + +Internet-Draft IKEv2bis February 2006 + + +C.3. IKE_AUTH Exchange with EAP + + first request --> IDi, + [N(INITIAL_CONTACT)], + [[N(HTTP_CERT_LOOKUP_SUPPORTED)], CERTREQ+], + [IDr], + [CP(CFG_REQUEST)], + [N(IPCOMP_SUPPORTED)+], + [N(USE_TRANSPORT_MODE)], + [N(ESP_TFC_PADDING_NOT_SUPPORTED)], + [N(NON_FIRST_FRAGMENTS_ALSO)], + SA, TSi, TSr, + [V+] + + first response <-- IDr, [CERT+], AUTH, + EAP, + [V+] + + / --> EAP + repeat 1..N times | + \ <-- EAP + + last request --> AUTH + + last response <-- AUTH, + [CP(CFG_REPLY)], + [N(IPCOMP_SUPPORTED)], + [N(USE_TRANSPORT_MODE)], + [N(ESP_TFC_PADDING_NOT_SUPPORTED)], + [N(NON_FIRST_FRAGMENTS_ALSO)], + SA, TSi, TSr, + [N(ADDITIONAL_TS_POSSIBLE)], + [V+] + + + + + + + + + + + + + + + + + + +Kaufman, et al. Expires August 27, 2006 [Page 118] + +Internet-Draft IKEv2bis February 2006 + + +C.4. CREATE_CHILD_SA Exchange for Creating or Rekeying CHILD_SAs + + request --> [N(REKEY_SA)], + [N(IPCOMP_SUPPORTED)+], + [N(USE_TRANSPORT_MODE)], + [N(ESP_TFC_PADDING_NOT_SUPPORTED)], + [N(NON_FIRST_FRAGMENTS_ALSO)], + SA, Ni, [KEi], TSi, TSr + + response <-- [N(IPCOMP_SUPPORTED)], + [N(USE_TRANSPORT_MODE)], + [N(ESP_TFC_PADDING_NOT_SUPPORTED)], + [N(NON_FIRST_FRAGMENTS_ALSO)], + SA, Nr, [KEr], TSi, TSr, + [N(ADDITIONAL_TS_POSSIBLE)] + +C.5. CREATE_CHILD_SA Exchange for Rekeying the IKE_SA + + request --> SA, Ni, [KEi] + + response <-- SA, Nr, [KEr] + +C.6. INFORMATIONAL Exchange + + request --> [N+], + [D+], + [CP(CFG_REQUEST)] + + response <-- [N+], + [D+], + [CP(CFG_REPLY)] + + +Appendix D. Changes Between Internet Draft Versions + + This section will be removed before publication as an RFC. + +D.1. Changes from IKEv2 to draft -00 + + There were a zillion additions from the Clarifications document. + These are noted with "{{ Clarif-nn }}". The numbers used in the text + of this version are based on + draft-eronen-ipsec-ikev2-clarifications-08.txt, which has different + numbers than earlier versions of that draft. + + Cleaned up many of the figures. Made the table headings consistent. + Made some tables easier to read by removing blank spaces. Removed + the "reserved to IANA" and "private use" text wording and moved it + + + +Kaufman, et al. Expires August 27, 2006 [Page 119] + +Internet-Draft IKEv2bis February 2006 + + + into the tables. + + Changed many SHOULD requirements to better match RFC 2119. These are + also marked with comments such as "{{ Demoted the SHOULD }}". + + In Section 2.16, changed the MUST requirement of authenticating the + responder from "public key signature based" to "strong" because that + is what most current IKEv2 implementations do, and it better matches + the actual security requirement. + + +Authors' Addresses + + Charlie Kaufman + Microsoft + 1 Microsoft Way + Redmond, WA 98052 + US + + Phone: 1-425-707-3335 + Email: charliek@microsoft.com + + + Paul Hoffman + VPN Consortium + 127 Segre Place + Santa Cruz, CA 95060 + US + + Phone: 1-831-426-9827 + Email: paul.hoffman@vpnc.org + + + Pasi Eronen + Nokia Research Center + P.O. Box 407 + FIN-00045 Nokia Group + Finland + + Email: pasi.eronen@nokia.com + + +Full Copyright Statement + + Copyright (C) The Internet Society (2006). + + This document is subject to the rights, licenses and restrictions + contained in BCP 78, and except as set forth therein, the authors + + + +Kaufman, et al. Expires August 27, 2006 [Page 120] + +Internet-Draft IKEv2bis February 2006 + + + retain all their rights. + + This document and the information contained herein are provided on an + "AS IS" basis and THE CONTRIBUTOR, THE ORGANIZATION HE/SHE REPRESENTS + OR IS SPONSORED BY (IF ANY), THE INTERNET SOCIETY AND THE INTERNET + ENGINEERING TASK FORCE DISCLAIM ALL WARRANTIES, EXPRESS OR IMPLIED, + INCLUDING BUT NOT LIMITED TO ANY WARRANTY THAT THE USE OF THE + INFORMATION HEREIN WILL NOT INFRINGE ANY RIGHTS OR ANY IMPLIED + WARRANTIES OF MERCHANTABILITY OR FITNESS FOR A PARTICULAR PURPOSE. + + +Intellectual Property + + The IETF takes no position regarding the validity or scope of any + Intellectual Property Rights or other rights that might be claimed to + pertain to the implementation or use of the technology described in + this document or the extent to which any license under such rights + might or might not be available; nor does it represent that it has + made any independent effort to identify any such rights. 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