PPPEXT Working Group Bernard Aboba INTERNET-DRAFT Microsoft Category: Experimental 15 August 2001 EAP GSS Authentication Protocol Status of this Memo This document is an Internet-Draft and is in full conformance with all provisions of Section 10 of RFC2026. This document is an Internet-Draft. Internet-Drafts are working documents of the Internet Engineering Task Force (IETF), its areas, and its working groups. Note that other groups may also distribute working documents as Internet-Drafts. Internet-Drafts are draft documents valid for a maximum of six months and may be updated, replaced, or obsoleted by other documents at any time. It is inappropriate to use Internet- Drafts as reference material or to cite them other than as "work in progress." The list of current Internet-Drafts can be accessed at http://www.ietf.org/ietf/1id-abstracts.txt The list of Internet-Draft Shadow Directories can be accessed at http://www.ietf.org/shadow.html. Copyright Notice Copyright (C) The Internet Society (2001). All Rights Reserved. Abstract The Extensible Authentication Protocol (EAP) provides a standard mechanism for support of multiple authentication methods, including public key, smart cards, Kerberos, One Time Passwords, and others. EAP typically runs directly over the link layer without requiring IP and therefore includes its own support for in-order delivery and re- transmission. While EAP was originally developed for use with PPP, it is also now in use with IEEE 802. The encapsulation of EAP on IEEE 802 links is described within IEEE 802.1X. This document describes the EAP GSS protocol, which supports fragmentation and reassembly, and enables the use of GSS-API mechanisms within EAP. As a result, any GSS-API mechanism providing initial authentication can be used with EAP GSS, including IAKERB. Supporting Aboba Experimental [Page 1] INTERNET-DRAFT EAP GSS Authentication Protocol 15 August 2001 GSS-API authentication methods within EAP is desirable because this enables developers creating GSS-API authentication methods to leverage their development efforts. Since the EAP Type field is a finite (one octet) resource, EAP GSS allows GSS-API methods to automatically be supported within EAP without having to consume an EAP Type for each GSS- API method. Table of Contents 1. Introduction .......................................... 3 1.1 Requirements language ........................... 3 1.2 Terminology ..................................... 3 2. Protocol overview ...................... .............. 4 2.1 EAP server as GSS-API initiator ................. 4 2.2 Peer as GSS-API initiator ....................... 5 3. Detailed description of EAP GSS protocol .............. 8 3.1 EAP GSS packet format ........................... 8 3.2 EAP GSS Request packet .......................... 9 3.3 EAP GSS Response packet ......................... 10 3.4 Fragmentation ....... ........................... 11 3.5 Retry behavior .................................. 14 3.6 Identity verification ........................... 14 3.7 Use of addresses ................................ 15 4. References ............................................ 15 5. Security considerations ............................... 18 5.1 Dictionary attacks .............................. 18 5.2 Certificate revocation ......................... 19 5.3 Mutual authentication ........................... 19 5.4 Credential reuse ................................ 20 5.5 Key management ........................... ...... 21 5.6 ECP negotiation ................................. 21 6. IANA Considerations ................................... 22 Appendix A - Example IAKERB topologies ....................... 23 A.1 RADIUS+KDC backend .............................. 24 A.2 Kerberos KDC backend ............................ 26 Acknowledgments .............................................. 28 Author's Addresses ........................................... 28 Intellectual Property Statement .............................. 28 Full Copyright Statement ..................................... 29 Aboba Experimental [Page 2] INTERNET-DRAFT EAP GSS Authentication Protocol 15 August 2001 1. Introduction The Extensible Authentication Protocol (EAP) [5] provides a standard mechanism for support of multiple authentication methods, including public key [12], smart cards, Kerberos, One Time Passwords [5], and others. EAP typically runs directly over the link layer without requiring IP and therefore includes its own support for in-order delivery and re-transmission. While EAP was originally developed for use with PPP [1], it is also now in use with IEEE 802 [21]. The encapsulation of EAP on IEEE 802 links is described within IEEE 802.1X [27]. This document describes the EAP GSS protocol, which supports fragmentation and reassembly, and enables the use of GSS-API mechanisms within EAP. As a result, any GSS-API mechanism providing initial authentication can be used with EAP GSS, including IAKERB [18]. Supporting GSS-API authentication methods within EAP is desirable because this enables developers creating GSS-API authentication methods to leverage their development efforts. Since the EAP Type field is a finite (one octet) resource, EAP GSS allows GSS-API methods to automatically be supported within EAP without having to consume an EAP Type for each GSS-API method. 1.1. Requirements language In this document, the key words "MAY", "MUST, "MUST NOT", "optional", "recommended", "SHOULD", and "SHOULD NOT", are to be interpreted as described in [11]. 1.2. Terminology This document frequently uses the following terms: NAS The end of the link requiring the authentication. In IEEE 802.1X, this end is known as the Authenticator. Peer The other end of the point-to-point link (PPP), point-to-point LAN segment (IEEE 802.1X) or 802.11 wireless link, which being authenticated by the NAS. In IEEE 802.1X, this end is known as the Supplicant. Authentication Server An Authentication Server is an entity that provides an Authentication Service to an NAS. This service verifies from the credentials provided by the peer, the claim of identity made by the peer. Aboba Experimental [Page 3] INTERNET-DRAFT EAP GSS Authentication Protocol 15 August 2001 2. Protocol overview As described in [5], the EAP GSS conversation will typically begin with the NAS and the peer negotiating EAP. The NAS will then typically send an EAP-Request/Identity packet to the peer, and the peer will respond with an EAP-Response/Identity packet to the NAS, containing the peer's user-Id. Once having received the peer's Identity, the EAP server responds with an EAP-Request packet of EAP-Type=EAP GSS. From this point forward, the EAP GSS conversation may proceed in one of two way. In the first mode, the EAP server acts as the GSS-API initiator, and the peer acts as the GSS-API target. In the second mode, which adds an extra round-trip, the peer acts as the GSS-API initiator, and the EAP server acts as the GSS-API target. We discuss each mode in turn. 2.1. EAP server as GSS-API initiator As described in RFC 2284 [5], the EAP server typically authenticates the peer using a prearranged method or set of methods. As a result, the EAP server may have predetermined the use of EAP GSS as well as the GSS-API method to be used. If that GSS-API method can be initiated by the EAP Server, then the EAP server MAY act as a GSS-API initiator with the peer acting as a GSS-API target. In this case, the EAP Server will indicate the pre-determined GSS-API method, possibly via SPNEGO, but SHOULD NOT allow negotiation of a substitute GSS-API method. To initiate the conversation, the EAP-Server sends an EAP-Request packet with EAP-Type=EAP GSS. The data field of the packet will encapsulate a GSS-API token, created as a result of a call to GSS_Init_sec_context (). In this case mutual authentication MUST be requested (otherwise the peer would not be authenticated to the NAS!) so that the the mutual_req_flag is set and the call to GSS_Init_sec-context() returns GSS_S_CONTINUE_NEEDED status. When it receives the EAP-Request, the peer will de-capsulate the received GSS-API token within the EAP GSS frame, and will pass it as the input_token parameter to GSS_Accept_sec_context(). If GSS_Accept_sec_context indicates GSS_S_COMPLETE status, then the NAS has been authenticated by the peer, and the NAS's indicated identity is provided in the src_name result, along with an output_token to be encapsulated within an EAP-Response packet with EAP-Type=EAP GSS, and passed back to the EAP-Server. The EAP server will then de-capsulate the GSS-API token within the EAP- Response message and pass it as the input_token parameter to GSS_Init_sec_context(). If the call returns GSS_S_COMPLETE status, then Aboba Experimental [Page 4] INTERNET-DRAFT EAP GSS Authentication Protocol 15 August 2001 the peer has been authenticated to the EAP-Server, then the EAP-Server responds with an EAP-Success message. If GSS_S_CONTINUE_NEEDED status is returned, then the EAP Server encapsulates the returned output_token with an EAP-Request packet of EAP-Type=EAP GSS, and pass this back to the peer. The conversation (which can be completed in a minimum of 2.5 round trips), appears as follows: Peer NAS ------ ------------- EAP/Identity <-------Request EAP/Identity Response --------> GSS_Init_sec_context(mutual_req_flag) returns GSS_S_CONTINUE_NEEDED, output_token <--------EAP Request EAP Type=EAP GSS output_token GSS_Accept_sec_context(input_token) returns GSS_S_COMPLETE, output_token EAP Response --------> EAP Type=EAP GSS output_token GSS_Init_sec_context(input_token) returns GSS_S_COMPLETE <--------EAP Success 2.2. Peer as GSS-API initiator If the EAP server is prepared to allow negotiation of the GSS-API method via SPNEGO [19], or if the EAP server knows the GSS-API method to be used, but cannot initiate it (e.g. IAKERB, or Kerberos V), then the peer MUST act as a GSS-API initiator, with the EAP server acting as the GSS- API target. In this case, the EAP server MUST respond with an EAP GSS/Start packet, which is an EAP-Request packet with EAP-Type=EAP GSS, the Start (S) bit Aboba Experimental [Page 5] INTERNET-DRAFT EAP GSS Authentication Protocol 15 August 2001 set, and no data. The peer then calls GSS_Init_sec_context(), typically with mutual authentication requested so that the mutual_req_flag is set and the call returns GSS_S_CONTINUE_NEEDED status. The output_token is then encapsulated within an EAP-Response packet with EAP-Type=EAP GSS and sent to the NAS. If method negotiation is to be used, then an initial negotiation token for the Simple and Protected GSS-API Negotiation Mechanism (SPNEGO) [19] is transferred. This contains an ordered list of mechanisms, a set of options that should be supported by the selected mechanism and the initial security token for the mechanism preferred by the peer. The inclusion of the initial security token for the preferred method saves a round-trip, assuming that the NAS agrees to the preferred mechanism. The EAP server then de-capsulates the GSS-API token contained within the EAP-Response of EAP-Type=EAP GSS and uses this as the input_token parameter to a call to GSS_Accept_sec_context(). The output_token parameter will then contain a token, containing the result of the negotiation and in the case of accept, the agreed security mechanism and the response to the initial security token as described in [19]. This token is then encapsulated within an EAP-Request packet of EAP-Type=GSS- API, which is sent to the peer. This occurs whether the call completed with GSS_S_CONTINUE_NEEDED status or GSS_S_COMPLETE status. The peer then de-capsulates the GSS-API token contained within the EAP- Request packet with EAP-Type=EAP GSS, and passes the input_token parameter to GSS_Init_sec_context(). The output_token is encapsulated within an EAP-Response packet with EAP-Type=EAP GSS and sent to the EAP server. This occurs whether the call completed with GSS_S_CONTINUE_NEEDED status or GSS_S_COMPLETE status. If the previous call to GSS_Accept_sec_context() returned GSS_S_COMPLETE status, then the EAP-Server returns an EAP-Success message to the client. Otherwise, it de-capsulates the GSS-API token contained within the EAP-Request packet, and the conversation continues. Aboba Experimental [Page 6] INTERNET-DRAFT EAP GSS Authentication Protocol 15 August 2001 The conversation (which can be completed in a minimum of 3.5 round trips), appears as follows: Authenticating Peer NAS ------------------- ------------- EAP-Request/ <- Identity EAP-Response/ Identity (MyID) -> EAP-Request/ EAP-Type=EAP GSS <- (GSS Start, S bit set) GSS_Init_sec_context(mutual_req_flag) returns GSS_S_CONTINUE_NEEDED, output_token (SPNEGO) EAP-Response/ EAP-Type=EAP GSS output_token -> GSS_Accept_sec_context(input_token) returns GSS_S_COMPLETE, output_token (SPNEGO) EAP-Request/ EAP-Type=EAP GSS <- output_token GSS_Init_sec_context(input_token) returns GSS_S_COMPLETE, output_token EAP-Response/ EAP-Type=EAP GSS output_token -> <- EAP-Success Aboba Experimental [Page 7] INTERNET-DRAFT EAP GSS Authentication Protocol 15 August 2001 3. Detailed description of the EAP GSS protocol 3.1. EAP GSS Packet Format A summary of the EAP GSS Request/Response packet format is shown below. The fields are transmitted from left to right. 0 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 | Data... +-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+ Code 1 - Request 2 - Response Identifier The identifier field is one octet and aids in matching responses with requests. Length The Length field is two octets and indicates the length of the EAP packet including the Code, Identifier, Length, Type, and Data fields. Octets outside the range of the Length field should be treated as Data Link Layer padding and should be ignored on reception. Type TBD - EAP GSS Data The format of the Data field is determined by the Code field. Aboba Experimental [Page 8] INTERNET-DRAFT EAP GSS Authentication Protocol 15 August 2001 3.2. EAP GSS Request Packet A summary of the EAP GSS Request packet format is shown below. The fields are transmitted from left to right. 0 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 | Flags | GSS Message Length +-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+ | GSS Message Length | GSS Data... +-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+ Code 1 Identifier The Identifier field is one octet and aids in matching responses with requests. The Identifier field MUST be changed on each Request packet. Length The Length field is two octets and indicates the length of the EAP packet including the Code, Identifier, Length, Type, and GSS Response fields. Type TBD - EAP GSS Aboba Experimental [Page 9] INTERNET-DRAFT EAP GSS Authentication Protocol 15 August 2001 Flags 0 1 2 3 4 5 6 7 8 +-+-+-+-+-+-+-+-+ |L M S R R R R R| +-+-+-+-+-+-+-+-+ L = Length included M = More fragments S = EAP GSS start R = Reserved The L bit (length included) is set to indicate the presence of the four octet GSS Message Length field, and MUST be set for the first fragment of a fragmented GSS message or set of messages. The M bit (more fragments) is set on all but the last fragment. The S bit (EAP GSS start) is set in an EAP GSS Start message. This differentiates the EAP GSS Start message from a fragment acknowledgment. GSS Message Length The GSS Message Length field is four octets, and is present only if the L bit is set. This field provides the total length of the GSS message or set of messages that is being fragmented. GSS data The GSS data consists of the encapsulated GSS packet. 3.3. EAP GSS Response Packet A summary of the EAP GSS Response packet format is shown below. The fields are transmitted from left to right. 0 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 | Flags | GSS Message Length +-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+ | GSS Message Length | GSS Data... +-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+ Code 2 Aboba Experimental [Page 10] INTERNET-DRAFT EAP GSS Authentication Protocol 15 August 2001 Identifier The Identifier field is one octet and MUST match the Identifier field from the corresponding request. Length The Length field is two octets and indicates the length of the EAP packet including the Code, Identifier, Length, Type, and GSS data fields. Type TBD - EAP GSS Flags 0 1 2 3 4 5 6 7 8 +-+-+-+-+-+-+-+-+ |L M S R R R R R| +-+-+-+-+-+-+-+-+ L = Length included M = More fragments S = EAP GSS start R = Reserved The L bit (length included) is set to indicate the presence of the four octet GSS Message Length field, and MUST be set for the first fragment of a fragmented GSS message or set of messages. The M bit (more fragments) is set on all but the last fragment. The S bit (EAP GSS start) is set in an EAP GSS Start message. This differentiates the EAP GSS Start message from a fragment acknowledgment. GSS Message Length The GSS Message Length field is four octets, and is present only if the L bit is set. This field provides the total length of the GSS message or set of messages that is being fragmented. GSS data The GSS data consists of the encapsulated GSS packet. 3.4. Fragmentation It is possible that EAP GSS messages may exceed the link MTU size, the maximum RADIUS packet size of 4096 octets, or even the PPP Multilink Aboba Experimental [Page 11] INTERNET-DRAFT EAP GSS Authentication Protocol 15 August 2001 Maximum Received Reconstructed Unit (MRRU). As described in [2], within PPP the multi-link MRRU is negotiated via the Multilink MRRU LCP option, which includes an MRRU length field of two octets, and thus can support MRRUs as large as 64 KB. In order to protect against reassembly lockup and denial of service attacks, it may be desirable for an implementation to set a maximum size for a GSS-API token. Since a typical certificate chain is rarely longer than a few thousand octets, and no other field is likely to be anywhere near as long, a reasonable choice of maximum acceptable message length might be 64 KB. If this value is chosen, then for PPP links, fragmentation can be handled via the multi-link PPP fragmentation mechanisms described in [2]. While this is desirable, there may be cases in which multi-link or the MRRU LCP option cannot be negotiated. Also, since EAP methods must also be usable within IEEE 802.1X [27], an EAP GSS implementation MUST provide its own support for fragmentation and reassembly. Since EAP is a simple ACK-NAK protocol, fragmentation support can be added in a simple manner. In EAP, fragments that are lost or damaged in transit will be retransmitted, and since sequencing information is provided by the Identifier field in EAP, there is no need for a fragment offset field as is provided in IP. EAP GSS fragmentation support is provided through addition of a flags octet within the EAP-Response and EAP-Request packets, as well as a GSS Message Length field of four octets. Flags include the Length included (L), More fragments (M), and EAP GSS Start (S) bits. The L flag is set to indicate the presence of the four octet GSS Message Length field, and MUST be set for the first fragment of a fragmented GSS message or set of messages. The M flag is set on all but the last fragment. The S flag is set only within the EAP GSS start message sent from the EAP server to the peer. The GSS Message Length field is four octets, and provides the total length of the GSS-API token or set of messages that is being fragmented; this simplifies buffer allocation. When an EAP GSS peer receives an EAP-Request packet with the M bit set, it MUST respond with an EAP-Response with EAP-Type=EAP GSS and no data. This serves as a fragment ACK. The EAP server MUST wait until it receives the EAP-Response before sending another fragment. In order to prevent errors in processing of fragments, the EAP server MUST increment the Identifier field for each fragment contained within an EAP-Request, and the peer MUST include this Identifier value in the fragment ACK contained within the EAP-Response. Retransmitted fragments will contain the same Identifier value. Aboba Experimental [Page 12] INTERNET-DRAFT EAP GSS Authentication Protocol 15 August 2001 Similarly, when the EAP server receives an EAP-Response with the M bit set, it MUST respond with an EAP-Request with EAP-Type=EAP GSS and no data. This serves as a fragment ACK. The EAP peer MUST wait until it receives the EAP-Request before sending another fragment. In order to prevent errors in the processing of fragments, the EAP server MUST use increment the Identifier value for each fragment ACK contained within an EAP-Request, and the peer MUST include this Identifier value in the subsequent fragment contained within an EAP-Response. In the case where the EAP GSS authentication is successful, and fragmentation is required, the conversation will appear as follows: Authenticating Peer NAS ------------------- ------------- EAP-Request/ <- Identity EAP-Response/ Identity (MyID) -> EAP-Request/ EAP-Type=EAP GSS <-(GSS Start, S bit set) GSS_Init_sec_context(mutual_req_flag) returns GSS_S_CONTINUE_NEEDED, output_token (SPNEGO) EAP-Response/ EAP-Type=EAP GSS output_token -> GSS_Accept_sec_context(input_token) returns GSS_S_COMPLETE, output_token (SPNEGO) EAP-Request/ EAP-Type=EAP GSS output_token <- (Fragment 1: L, M bits set) EAP-Response/ EAP-Type=EAP GSS -> EAP-Request/ EAP-Type=EAP GSS <- (Fragment 2: M bit set) EAP-Response/ EAP-Type=EAP GSS -> EAP-Request/ EAP-Type=EAP GSS Aboba Experimental [Page 13] INTERNET-DRAFT EAP GSS Authentication Protocol 15 August 2001 <- (Fragment 3) GSS_Init_sec_context(input_token) returns GSS_S_COMPLETE, output_token EAP-Response/ EAP-Type=EAP GSS output_token (Fragment 1: L, M bits set)-> EAP-Request/ <- EAP-Type=EAP GSS EAP-Response/ EAP-Type=EAP GSS (Fragment 2)-> <- EAP-Success 3.5. Retry behavior As with other EAP protocols, the EAP server is responsible for retry behavior. This means that if the EAP server does not receive a reply from the peer, it MUST resend the EAP-Request for which it has not yet received an EAP-Response. However, the peer MUST NOT resend EAP-Response packets without first being prompted by the EAP server. For example, if the initial EAP GSS start packet sent by the EAP server were to be lost, then the peer would not receive this packet, and would not respond to it. As a result, the EAP GSS start packet would be resent by the EAP server. Once the peer received the EAP GSS start packet, it would send an EAP-Response encapsulating the client_hello message. If the EAP-Response were to be lost, then the EAP server would resend the initial EAP GSS start, and the peer would resend the EAP-Response. As a result, it is possible that a peer will receive duplicate EAP- Request messages, and may send duplicate EAP-Responses. Both the peer and the EAP-Server should be engineered to handle this possibility. 3.6. Identity verification As part of the GSS-API conversation, it is possible that the server may present a certificate to the peer, or that the peer may present a certificate to the EAP server. If the peer has made a claim of identity in the EAP-Response/Identity (MyID) packet, the EAP server SHOULD verify that the claimed identity corresponds to the certificate presented by the peer. Typically this will be accomplished either by placing the userId within the peer certificate, or by providing a mapping between the peer certificate and the userId using a directory Aboba Experimental [Page 14] INTERNET-DRAFT EAP GSS Authentication Protocol 15 August 2001 service. Similarly, the peer MUST verify the validity of the EAP server certificate, and SHOULD also examine the EAP server name presented in the certificate, in order to determine whether the EAP server can be trusted. Please note that in the case where the EAP authentication is remoted that the EAP server will not reside on the same machine as the NAS, and therefore the name in the EAP server's certificate cannot be expected to match that of the intended destination. In this case, a more appropriate test might be whether the EAP server's certificate is signed by a CA controlling the intended destination and whether the EAP server exists within a target sub-domain. 3.7. Use of addresses When using EAP GSS, the EAP client may not be able to include an address in an EAP-Response message, since prior to obtaining access the EAP client may not have an IP address. This limits effective use of EAP GSS to GSS-API methods that do not require the peer to have an IP address prior to authentication. The IAKERB GSS-API method can explicitly handle this situation, as described in [18]. However, where the Kerberos V protocol, described in [16], is negotiated as a GSS-API method as described in [20], the addresses field of the AS_REQ and TGS_REQ SHOULD be blank and the caddr field of the ticket SHOULD also be left blank. 4. References [1] Simpson, W., Editor, "The Point-to-Point Protocol (PPP)." STD 51, RFC 1661, July 1994. [2] Sklower, K., Lloyd, B., McGregor, G., Carr, D., and T. Coradetti, "The PPP Multilink Protocol (MP)." RFC 1990, August 1996. [3] Simpson, W., Editor, "PPP LCP Extensions." RFC 1570, January 1994. [4] Rivest, R., Dusse, S., "The MD5 Message-Digest Algorithm", RFC 1321, April 1992. [5] Blunk, L., Vollbrecht, J., "PPP Extensible Authentication Protocol (EAP)", RFC 2284, March 1998. [6] Meyer, G., "The PPP Encryption Protocol (ECP)." RFC 1968, June 1996 [7] U.S. DoC/NIST, "Data encryption standard (DES)", FIPS 46-3, October 25, 1999. Aboba Experimental [Page 15] INTERNET-DRAFT EAP GSS Authentication Protocol 15 August 2001 [8] National Bureau of Standards, "DES Modes of Operation", FIPS PUB 81 (December 1980). [9] Sklower, K., Meyer, G., "The PPP DES Encryption Protocol, Version 2 (DESE-bis)", RFC 2419, September 1998. [10] Hummert, K., "The PPP Triple-DES Encryption Protocol (3DESE)", RFC 2420, September 1998. [11] Bradner, S., "Key words for use in RFCs to Indicate Requirement Levels", BCP 14, RFC 2119, March 1997. [12] Aboba, B., Simon, S.,"PPP EAP TLS Authentication Protocol", RFC 2716, October 1999. [13] D. Rand. "The PPP Compression Control Protocol." RFC 1962, Novell, June 1996. [14] Myers, J., "Simple Authentication and Security Layer (SASL)", RFC 2222, October 1997. [15] Linn, J., "Generic Security Service Application Program Interface, Version 2", RFC 2743, January 2000. [16] Kohl, J., Neuman, C., "The Kerberos Network Authentication Service (V5)", RFC 1510, September 1993. [17] Neuman, B. C., Ts'o, T., "Kerberos: An Authentication Service for Computer Networks", IEEE Communications, 32(9):33-38, September 1994. [18] Swift, M., Trostle, J., Aboba, B., Zorn, G., "Initial Authentication and Pass Through Authentication Using Kerberos V5 and the GSS-API (IAKERB)", Internet draft (work in progress), draft-ietf-cat-iakerb-08.txt, August 2001. [19] Baize, E., Pinkas., D., "The Simple and Protected GSS-API Negotiation Mechanism", RFC 2478, December 1998. [20] Linn, J., "The Kerberos Version 5 GSS-API Mechanism", RFC 1964, June 1996. [21] IEEE Standards for Local and Metropolitan Area Networks: Overview and Architecture, ANSI/IEEE Std 802, 1990. [22] ISO/IEC 10038 Information technology - Telecommunications and information exchange between systems - Local area networks - Media Access Control (MAC) Bridges, (also ANSI/IEEE Std 802.1D- 1993), Aboba Experimental [Page 16] INTERNET-DRAFT EAP GSS Authentication Protocol 15 August 2001 1993. [23] ISO/IEC Final CD 15802-3 Information technology - Tele- communications and information exchange between systems - Local and metropolitan area networks - Common specifications - Part 3:Media Access Control (MAC) bridges, (current draft available as IEEE P802.1D/D15). [24] IEEE Standards for Local and Metropolitan Area Networks: Draft Standard for Virtual Bridged Local Area Networks, P802.1Q/D8, January 1998. [25] ISO/IEC 8802-3 Information technology - Telecommunications and information exchange between systems - Local and metropolitan area networks - Common specifications - Part 3: Carrier Sense Multiple Access with Collision Detection (CSMA/CD) Access Method and Physical Layer Specifications, (also ANSI/IEEE Std 802.3- 1996), 1996. [26] IEEE Standards for Local and Metropolitan Area Networks: Demand Priority Access Method, Physical Layer and Repeater Specification For 100 Mb/s Operation, IEEE Std 802.12-1995. [27] IEEE Standards for Local and Metropolitan Area Networks: Port based Network Access Control, IEEE Std 802.1X-2001, June 2001. [28] Information technology - Telecommunications and information exchange between systems - Local and metropolitan area networks - Specific Requirements Part 11: Wireless LAN Medium Access Control (MAC) and Physical Layer (PHY) Specifications, IEEE Std. 802.11-1997, 1997. [29] Rigney, C., Rubens, A., Simpson, W., Willens, S., "Remote Authentication Dial In User Service (RADIUS)", RFC 2865, June 2000. [30] Rigney, C., "RADIUS Accounting", RFC 2866, June 2000. [31] Zorn, G., Mitton, D., Aboba, B., "RADIUS Accounting Modifications for Tunnel Protocol Support", RFC 2867, June 2000. [32] Zorn, G., Leifer, D., Rubens, A., Shriver, J., Holdrege, M., Goyret, I., "RADIUS Attributes for Tunnel Protocol Support", RFC 2868, June 2000. [33] Rigney, C., Willats, W., Calhoun, P., "RADIUS Extensions", RFC 2869, June 2000. Aboba Experimental [Page 17] INTERNET-DRAFT EAP GSS Authentication Protocol 15 August 2001 [34] Wu, T., "A Real-World Analysis of Kerberos Password Security", Stanford University Computer Science Department, http://theory.stanford.edu/~tjw/krbpass.html [35] Bellovin, S.M., Merritt, M., "Limitations of the kerberos authentication system", Proceedings of the 1991 Winter USENIX Conference, pp. 253-267, 1991. [36] Dole, B., Lodin, S., and Spafford, E., "Misplaced trust: Kerberos 4 session keys", Proceedings of the Internet Society Network and Distributed System Security Symposium, pp. 60-70, March 1997. [37] Wu, T., "The SRP Authentication and Key Exchange System", RFC 2945, September 2000. [38] Bellovin, S.M., Merritt, M., "Encrypted key exchange: Password- based protocols secure against dictionary attacks", Proceedings of the 1992 IEEE Computer Society Conference on Research in Security and Privacy, pp. 72-84, 1992. [39] Jablon, D., "Strong password-only authenticated key exchange", Computer Communication Review, 26(5):5-26, October 1996. [40] Jaspan, B., "Dual-workfactor encrypted key exchange: Efficiently preventing password chaining and dictionary attacks", Proceedings of the Sixth Annual USENIX Security Conference, pp. 43-50, July 1996. [41] Tung, B. Neuman, C., Hur, M., Medvinsky, A., Medvinsky, S., Wray, J., Trostle, J., "Public Key Cryptography for Initial Authentication in Kerberos", draft-ietf-cat-kerberos-pk- init-13.txt, August 2001. 5. Security Considerations 5.1. Dictionary attacks As noted in [34]-[36], both Kerberos IV and V are vulnerable to attack. These attacks are particularly potent when carried out in a location where a large number of authentication exchanges can be collected within a short period of time, such as with wireless LANs deployed in "hot spots". As noted in [34], offline dictionary attacks are easily carried out against the AS_REP, since the key encrypting the enclosed Kerberos ticket is a function of the password. Such attacks are amenable to parallelization, and it is therefore possible to crack a large number of passwords in short time with only modest resources. As noted in [34], Aboba Experimental [Page 18] INTERNET-DRAFT EAP GSS Authentication Protocol 15 August 2001 the imposition of a password policy is likely only to decrease the yield, but given access to sufficient exchanges, large scale password compromise remains likely. For this reason, when used on wireless networks, EAP GSS SHOULD be to negotiate methods thought to be invulnerable to offline dictionary attacks against the on-the-wire protocol. This includes public key authentication techniques or password-based techniques described in [37]-[40]. Kerberos V SHOULD NOT be used without extensions providing protection against offline dictionary attacks. As noted in [34], it has been proposed that Kerberos V dictionary attack vulnerabilities be addressed via a pre-authentication exchange. The vulnerability can also be addressed by use of PKINIT [41]. 5.2. Certificate revocation Since the EAP server is on the Internet during the EAP conversation, the server is capable of following a certificate chain or verifying whether the peer's certificate has been revoked. In contrast, the peer may or may not have Internet connectivity, and thus while it can validate the EAP server's certificate based on a pre-configured set of CAs, it may not be able to follow a certificate chain or verify whether the EAP server's certificate has been revoked. In the case where the peer is initiating a voluntary Layer 2 tunnel using PPTP or L2TP, the peer will typically already have a PPP interface and Internet connectivity established at the time of tunnel initiation. As a result, during the EAP conversation it is capable of checking for certificate revocation. However, in the case where the peer is initiating a connection, it will not have Internet connectivity and is therefore not capable of checking for certificate revocation until after the peer has access to the Internet. In this case, the peer SHOULD check for certificate revocation after connecting to the Internet. 5.3. Mutual authentication It is recommended that a GSS-API method supporting mutual authentication be selected during the SPNEGO negotiation. This addresses vulnerabilities associated with rogue EAP servers, as well as avoiding vulnerabilities associated with parallel one-way authentications. Aboba Experimental [Page 19] INTERNET-DRAFT EAP GSS Authentication Protocol 15 August 2001 5.4. Credential reuse A peer with valid credentials may reuse those credentials in a subsequent authentication. Credential reuse improves efficiency in a number of scenarios. Where the peer attempts to re-authenticate to an EAP server within a short period of time, the re-authentication time may be shortened. Also, where the peer roams to another NAS willing to accept credentials from a previous NAS, fast-handoff may be achieved. Credential reuse may also prove useful during multi-link authentication. For example, a peer initially using the IAKERB GSS-API method to obtain a TGT and a ticket to the NAS may subsequently reuse that ticket in an AP_REQ/AP_REP exchange that may occur either in-band (e.g. via use of the Kerberos V GSS-API method) or out-of-band (e.g. via an 802.1X EAPOL- Key message). Typically in-band efficiency savings are modest (one round-trip saved using the Kerberos V GSS-API method versus IAKERB), while savings from out-of-band credential reuse can be more substantial. The decision of whether to attempt to reuse credentials is left up to the peer, which needs to determine whether credential use is likely to succeed. The decision may be based on out-of-band information (such as probe/response messages exchanged via 802.11 [28]), or the time elapsed since the previous authentication attempt. If the peer attempts to reuse credentials that are not valid, then the NAS will respond with an error and the peer can re-authenticate using the more complete sequence. For example, after an initial IAKERB authentication, the peer will have obtained a TGT from the KDC via the AS_REP, and a ticket to the NAS within the TGS_REP. The peer may subsequently attempt to negotiate the Kerberos V GSS-API method, so as to reuse the previously obtained credentials. Should a KRB_ERROR be returned by the NAS, then the peer can negotiate IAKERB on its next attempt instead. Note that credential reuse for the purpose of "fast handoff" has significant limitations. For example, in order to reuse a Kerberos ticket on a different NAS, it is necessary for NASes within the same geographic area to share a key with the KDC. If this is not the case, then peers moving from one NAS to another will not be able to reuse credentials. Allowing multiple NASes to share a key with the KDC makes it more likely that an attacker sniffing the wire will be able to obtain the NAS key, particularly if the key is derived from a password. Details are provided within reference [34]. Similarly, if the EAP servers are set up in a rotary or made available via a round-robin technique, then the credentials also may not be reusable, unless the EAP authentication is remoted to a central authentication server. Aboba Experimental [Page 20] INTERNET-DRAFT EAP GSS Authentication Protocol 15 August 2001 Furthermore, since existing Kerberos implementations do not include AAA authorizations within the authorization data field of the Kerberos ticket [16], even if the credentials can be reused, it may be necessary for the NAS to obtain the authorization information from the AAA server before the correct session state can be re-established on the new NAS. If AAA authorizations are not obtained prior to granting access, then the new NAS could potentially provide the wrong service to the peer. For example, where Filter-Id [29] or tunnel attributes [32] were unavailable, a peer might be given unrestricted network access where this was not intended. As a result of these considerations, credential reuse for the purpose of "fast handoff" does not appear to be practical at this time. 5.5. Key management As a result of the EAP GSS conversation, the EAP endpoints will mutually authenticate and derive a session key for subsequent use in PPP or 802.11 WEP [28] encryption. Since the peer and EAP client reside on the same machine, it is necessary for the EAP client module to pass the session key to the layer 2 encryption module. The situation may be more complex on the NAS, which may or may not reside on the same machine as the EAP server. In the case where the EAP server and NAS reside on different machines, there are several implications for security. Firstly, the mutual authentication defined in EAP GSS will occur between the peer and the EAP server, not between the peer and the NAS. This means that as a result of the EAP GSS conversation, it is not possible for the peer to validate the identity of the device that it is speaking to. The second issue is that the session key negotiated between the peer and EAP server will need to be transmitted to the NAS. Both issues can be addressed via addition of a followon exchange. For example, where the IAKERB GSS-API method is used for initial authentication, the Kerberos V GSS-API method can be used to mutually authenticate the peer and NAS and transfer the session key from the peer to the NAS. 5.6. ECP negotiation ECP, described in [6], supports unprotected cipher-suite negotiations within PPP and is thus vulnerable to attack. Since SPNEGO [19] supports protected cipher-suite negotiation in the case where the negotiated method provides authentication and integrity protection, use of SPNEGO is preferable to ECP. Peers completing the GSS-API SPNEGO negotiation will typically implicitly select a cipher-suite, which includes key strength, encryption and hashing methods. As a result, a subsequent Encryption Control Protocol (ECP) conversation [6], if it occurs, has a predetermined result. Aboba Experimental [Page 21] INTERNET-DRAFT EAP GSS Authentication Protocol 15 August 2001 However, since the ECP-supported ciphersuites may not correspond to the ciphersuites implicitly negotiated as part of SPNEGO, it may not be possible for the ECP conversation to verify the ciphersuites implicitly selected via SPNEGO. For example, the ECP methods defined in [9]-[10] only support DES and 3DES transforms for confidentiality, and do not support authentication or integrity protection. Thus, there is no correspondence between existing ECP methods and the ciphersuites available within GSS-API methods such as Kerberos [16]-[17]. 6. IANA Considerations This document requires assignment of a EAP Type for EAP GSS. It does not create any new number spaces for IANA administration. Aboba Experimental [Page 22] INTERNET-DRAFT EAP GSS Authentication Protocol 15 August 2001 Appendix A - Example IAKERB topologies Where EAP GSS is used along with the GSS-API IAKERB [18] or Kerberos V [20] mechanisms, two major topologies are possible: RADIUS+KDC backend Here a RADIUS backend is used, along with a Kerberos KDC backend. The NAS functions as an EAP-pass-through device, encapsulating EAP messages received from the peer within RADIUS as described in [33], and passing them on to the RADIUS server. In turn, the RADIUS server acts as an IAKERB proxy, de-capsulating EAP GSS/IAKERB packets, and passing them on to the Kerberos KDC. In turn, the RADIUS server will encapsulated packets from the Kerberos KDC in EAP GSS/IAKERB and send this to the NAS. EAP-Message attributes received from the RADIUS server are de-capsulated by the NAS and sent to the peer. In this topology, the NAS need not have knowledge of specific EAP or GSS-API methods, while the RADIUS server does require this knowledge. KDC backend In this topology, only a Kerberos KDC is used as a backend, and the NAS functions as an IAKERB proxy, de-capsulating EAP GSS/IAKERB messages and passing them on to the KDC. Messages from the KDC are encapsulated within EAP GSS/IAKERB by the NAS and sent to the peer. In this case, the NAS needs to understand the EAP GSS, GSS-API IAKERB, as well as GSS-API Kerberos V mechanisms. In addition, where the peer already has a valid TGT and ticket to the NAS, it may choose to use the Kerberos V mechanism within EAP. Note that in the case of 802.11, the Kerberos AP_REQ/AP_REP messages may be carried in messages outside the conventional EAP exchange [27] so that use of the Kerberos V mechanism within EAP is not necessary. In the examples below, each topology is discussed. While nominally the EAP conversation occurs between the NAS and the peer, the NAS MAY act as a pass-through device, with the EAP packets received from the peer being encapsulated for transmission to a RADIUS server. In the discussion that follows, we will use the term "EAP server" to denote the ultimate endpoint conversing with the peer. Aboba Experimental [Page 23] INTERNET-DRAFT EAP GSS Authentication Protocol 15 August 2001 A.1 RADIUS+KDC backend In this topology, the NAS will act as an EAP pass-through, and the RADIUS server acts as an IAKERB proxy. A successful EAP GSS/IAKERB authentication will appear as follows: Peer NAS RADIUS KDC ------ ------------- --------- ------ EAP/Identity <-Request EAP/Identity Response -> EAP/Identity Response -> Access-Challenge EAP GSS Request <- (Start) <-EAP GSS Request(Empty) EAP GSS Response [1] (SPNEGO) -> EAP GSS Response (SPNEGO) -> Access-Challenge EAP GSS Request <-(SPNEGO) EAP GSS Request <-(SPNEGO) EAP GSS IAKERB Response [2] (AS_REQ) -> EAP GSS IAKERB Response (AS_REQ) -> AS_REQ -> <- AS_REP Access-Challenge EAP GSS IAKERB Request Aboba Experimental [Page 24] INTERNET-DRAFT EAP GSS Authentication Protocol 15 August 2001 <-(AS_REP) EAP GSS IAKERB Request <-(AS_REP) EAP GSS IAKERB Response [3] (TGS_REQ) -> EAP GSS IAKERB Response (TGS_REQ) -> TGS_REQ -> <- TGS_REP Access-Challenge EAP GSS IAKERB Request <-(TGS_REP) EAP GSS IAKERB Request <-(TGS_REP) EAP GSS IAKERB Response (Empty) -> EAP GSS IAKERB Response (Empty) -> Access-Accept [4] <- EAP-Success <- EAP-Success AP_REQ -> <- AP_REP [5] Notes: 1. IAKERB may be requested by the EAP GSS client without the need for negotiation, or SPNEGO may be used. 2. The AS_REQ requests a TGT from the KDC. It may or may not include PADATA. As a result, the AS_REQ may not authenticate the peer to the KDC, but the AS_REP authenticates the KDC to the peer. Aboba Experimental [Page 25] INTERNET-DRAFT EAP GSS Authentication Protocol 15 August 2001 3. The TGS_REQ requests a ticket to the NAS service. The ticket is encrypted with the NAS's key so that it can only be validated by the NAS. 4. On receiving a TGS_REP from the KDC rather than a KRB_ERROR, the RADIUS server can conclude that the peer has successfully authenticated, and thus that it is appropriate to reply to the NAS with an Access-Accept encapsulating an EAP-Success. 5. The IAKERB exchange ends before the AP_REQ/AP_REP exchange occurs. As a result, the AP_REQ/AP_REP exchange either will not occur (preventing mutual authentication between peer and NAS or transport of the session key from peer to NAS), will occur out-of-band (e.g. after access is granted), or will occur in a subsequent EAP GSS conversation (e.g. using the GSS-API Kerberos V method). A.2 Kerberos KDC backend In this topology, there is no RADIUS server, and the NAS functions as an IAKERB proxy, de-capsulating EAP GSS/IAKERB frames and passing them on to the KDC. In turn, packets from the KDC are are encapsulated in EAP GSS/IAKERB frames and sent to the peer by the NAS. Where IAKERB is used, the NAS functions as an IAKERB proxy, de-capsulating EAP GSS/IAKERB messages and passing them on to the KDC. In addition, where the peer already has a valid TGT and ticket to the NAS, it may choose to use the Kerberos V mechanism within EAP. Note that in the case of 802.11, the Kerberos AP_REQ/AP_REP messages are carried in messages outside the conventional EAP exchange [27] so that use of the Kerberos V mechanism within EAP is not necessary. In the Kerberos-only topology, messages from the KDC are encapsulated within EAP GSS/IAKERB and sent to the peer. In this case, the NAS needs to understand the EAP GSS, GSS-API IAKERB, as well as GSS-API Kerberos V mechanisms. Aboba Experimental [Page 26] INTERNET-DRAFT EAP GSS Authentication Protocol 15 August 2001 A successful EAP GSS/IAKERB authentication occurring in a topology with a NAS acting as an IAKERB proxy to a Kerberos KDC will appear as follows: Peer NAS KDC ------ ------------- --------- EAP/Identity <-Request EAP/Identity Response -> <-EAP GSS Start EAP GSS IAKERB Response [1] (AS_REQ) -> AS_REQ -> <- AS_REP [2] EAP GSS IAKERB Request <-AS_REP) EAP GSS IAKERB Response [3] (TGS_REQ) -> TGS_REQ -> <- TGS_REP [4] EAP GSS IAKERB Request <-(TGS_REP) EAP GSS IAKERB Response (Empty) -> <- EAP-Success AP_REQ [5]-> <- AP_REP [6] Notes: 1. If PADATA is not used in the AS_REQ, then the peer does not authenticate to the KDC. Aboba Experimental [Page 27] INTERNET-DRAFT EAP GSS Authentication Protocol 15 August 2001 2. The KDC authenticates to the peer in the AS_REP. 3. The peer authenticates to the KDC via the TGS_REQ. 4. The KDC authenticates to the peer via the TGS_REP. The TGS_REP also provides the peer with a ticket and session-key for use with the NAS. 5. Up until this point, the peer has not mutually authenticated with the NAS, or exchanged a key with it. As a result, the peer and NAS need to conclude an AP_REQ/AP_REP exchange. This can occur in-band or out-of-band. In the AP-REQ, the peer authenticates to the NAS and provides it with a session key. 6. The NAS authenticates to the peer using the AP_REP. Acknowledgments Thanks to Paul Leach of Microsoft, Glen Zorn of Cisco Systems, and Jesse Walker of Intel for useful discussions of this problem space. Authors' Addresses Bernard Aboba Microsoft Corporation One Microsoft Way Redmond, WA 98052 Phone: +1 (425) 936-6605 EMail: bernarda@microsoft.com Intellectual Property Statement The IETF takes no position regarding the validity or scope of any intellectual property 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; neither does it represent that it has made any effort to identify any such rights. Information on the IETF's procedures with respect to rights in standards-track and standards- related documentation can be found in BCP-11. 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