Network Working Group Andrew J. Valencia Request for Comments: DRAFT Category: Internet Draft Title: draft-ietf-l2tpext-l2tphc-02.txt Date: June 2000 L2TP Header Compression ('L2TPHC') Status of this Memo This document is an Internet-Draft and is in full conformance with all provisions of Section 10 of RFC2026. 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. Abstract The Layer 2 Tunneling Protocol (``L2TP'') [RFC2661] defines a mechanism for tunneling PPP sessions over arbitrary media. There exists a class of specific media applications for which protocol overhead may be optimized, and where such reduction results in improved operation. This document describes the solution space addressed, its underlying motivations, and the protocol modifications required. The enhancement to the L2TP protocol is called L2TP Header Compression, or ``L2TPHC''. 1. Introduction L2TP [RFC2661] defines a general purpose mechanism for tunneling PPP over various media. In most cases, the header overhead of the L2TP tunnel is negligible. However, when L2TP operates over bandwidth constrained networks such as dialup links or some classes of WAN backhauls, any savings of bytes transmitted results in a substantial efficiency gain. This effect is further amplified when streams of small IP packets dominate the traffic (thus increasing the header- to-payload ratio), as is common with multimedia and other types of real-time data traffic. Valencia expires December 2000 [Page 1] INTERNET DRAFT June 2000 2. Simplifying Assumptions If several simplifying assumptions may be met, it is possible to reduce the size of the L2TP encapsulation: - The tunnel will not operate through a NAT interface - The tunnel uses a single IP address for the life of the tunnel - The tunnel's host uses only one public IP network interface - There will be only one tunnel between the LAC and the LNS - There might be only one session within a tunnel - Alignment is not required - Packet length is preserved by the IP header Each of these simplifying assumptions directly relates to an L2TP protocol header field's function. Because NAT functionality is not needed, the UDP header is not required. Because the endpoints will not change their source IP addresses (due to either changing IP addresses, moving among IP egress points, or switching to a distinct backup IP interface), the identity of the peer may be determined by its source IP address, rather than the Tunnel ID. If there is only one session within the tunnel, it is trivial to determine the Session ID. Because each byte is a measurable component of overhead, it is better to send fields on unaligned boundaries rather than ever pad. Because IP will preserve the packet length end-to-end, there is no need to communicate this in the header itself. In addition, several operational considerations permit further simplification: - There is no need to optimize control packet overhead - Version compatibility may be determined by control packets The first two bytes of an L2TP payload header determined the presence of further, optional, fields. It also contains a Version field, used to detect compatible version operation. Realistically, these may all be determined in advance of payload exchange. Thus, by choosing very reasonable simplifying assumptions, it is possible to minimize the L2TP fields in the header of a payload packet. The resulting protocol is a one octet mandatory header, possibly followed by one or two additional octets, followed by a PPP frame, all encapsulated within a raw IP protocol header. These packets are exchanged in parallel with the regular UDP-based L2TP tunnel which provides all management and related functions. 3. Tunnel Establishment 3.1 Negotiation L2TPHC is negotiated by an optional AVP ``L2TPHC-Assigned- Session-ID'' which is placed in the ICRQ/ICRP and OCRQ/OCRP session establishment messages. The effect of this AVP will never occur until L2TP reaches a state where the session within the Valencia expires December 2000 [Page 2] INTERNET DRAFT June 2000 tunnel is fully established (i.e., success indicated in the ICCN/OCCN). Additionally, each side intending to use L2TPHC MUST NOT do so unless it both sends and receives this AVP. Thus, unless both sides support L2TPHC, the optional AVP (in the ICRQ or OCRQ message) will be ignored by one side, and not sent (in the corresponding ICRP or OCRP) to the other side, and L2TP will operate in its regular mode. As L2TPHC does not provide a Tunnel ID, there can be only a single tunnel using L2TPHC between any two IP peers (with multiple sessions within, if needed). Since all control messages are passed over the parallel L2TP tunnel corresponding to the L2TPHC one, tunnel shutdown of the L2TP session is always achieved by explicitly closing the L2TP session; the associated L2TPHC session is implicitly terminated. 3.2 AVP Format 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 +-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+ |M|H| rsvd | (6, 7, or 8) | 9 | +-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+ | 1 | Session ID1 | Session ID2 | +-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+ The L2TPHC-Assigned-Session-ID AVP MUST always be sent with the M, H, and "rsvd" bits all set to 0. The Attribute is the 16-bit value 1, encoded in network byte order. The Vendor ID is 9, reflecting Cisco Systems, the initial developer of this extension--a new Attribute value under Vendor ID 0 MUST be assigned if this document advances on the standards track. The Value field is set based on how session ID's will be used for this L2TPHC client. If the Length field of the AVP is 6, the Value field is not present, and the session ID value 0 is implicitly used. The I and J bits of the payload packet (see section 4) MUST be set to zero. If the Length field is 7, then a one-byte session ID is present in the AVP, and this is the value to use in the L2TPHC session ID field. The I bit MUST be set to one in the L2TPHC payload, and the J bit MUST be to zero. Finally, the Length field may be 8, and a two-byte session ID is contained in the Value field. L2TPHC payload MUST be sent with both the I and J bits set to one. The two-byte Value is encoded in network byte order. Note that the Session ID value used in the L2TPHC session is distinct from the value used in the corresponding L2TP session. Also, a single session ID namespace applies to all sizes of this AVP. Thus, the 6- byte variant (implying 0), the 7-byte variant with Session ID1 set to 0, and the 8-byte variant with both Session ID1 and ID2 set to 0 all refer to the same session ID. Valencia expires December 2000 [Page 3] INTERNET DRAFT June 2000 4. Payload Exchange If the L2TPHC-Assigned-Session-ID AVP is sent to and received from the peer, PPP payload packets may be sent to the peer's IP address as raw IP packets, with the IP protocol number set to 115. Such payload may be sent any time it would have been legal to send such payload over the regular UDP-based L2TP tunnel. Similarly, payload over the UDP tunnel MUST always be accepted, even after payload has flowed using the header compressed raw IP packet format. The payload so exchanged is always associated with the tunnel on which the AVP was received, and with the session within that tunnel. Each L2TPHC payload packet is encoded as: 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 2 +-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+ |T|L|J|x|S|I|O|P| Session ID... | PPP packet... | +-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+ x bits indicate reserved bit fields and MUST be set to 0. A packet received with a reserved bit set to 1 MUST be silently discarded, unless the bit is defined for an extension that is known to the implementation. The T bit MUST be set to 0, indicating payload. Control messages are never sent over L2TPHC. The L bit MUST be set to 0, indicating no length field. No length field is ever present in L2TPHC. The S bit MUST be set to 0, indicating no Nr/Ns fields. Control packets are not passed via L2TPHC. If sequencing of data packets is required, L2TPHC MUST NOT be used for those data packets. However, it is legal for data traffic to be mixed, with order-sensitive packets using a sequenced data extension of L2TP/UDP, and other data packets using L2TPHC. In this situation, data packets passed using L2TPHC would have no impact on L2TP sequence numbers. The I and J bits are set based on the Length of the Value portion of the L2TPHC-Assigned-Session-ID AVP. For a Length of 6, neither I nor J is set, and a Session ID of 0 is implicit. For a Length of 7, I is set and J is not, and the one-byte Session ID is inserted between the header bits and the PPP packet. For a Length of 8, both I and J are set, and the two-byte Session ID is inserted between the header bits and the PPP packet. The O bit MUST be set to 0, indicating no offset field. Offsets are never used in L2TPHC. The P bit is the Priority bit, and serves the same function as the bit of the same name in an L2TP packet. Priority packets MUST enjoy priority over traffic queued on both the UDP tunnel as well as the corresponding L2TPHC raw IP tunnel. Valencia expires December 2000 [Page 4] INTERNET DRAFT June 2000 Therefore, an L2TPHC packet will have an L2TPHC header of at least one octet, and optionally one or two additional octets based on the setting of the I and J bits: I J Header size (in bytes) --- --- --- 0 0 1 1 0 2 1 1 3 Following this header would be the PPP frame. 5. Efficiency Considerations Some rough calculations will illustrate the environments in which L2TPHC may be beneficial. Overhead as a percentage of the carried traffic will be calculated for a typical packet size involved in bulk data transfer (700 bytes), and the canonical 64-byte ``small IP packet''. Percentages will be rounded to the nearest whole number. Overhead is tallied for an IP header of 20 bytes, a UDP header of 8 bytes, and an L2TP header of 8 bytes. The worst case is a 64-byte packet carried within a UDP L2TP header. The 64 bytes of payload is carried by an overall header of 36 bytes, resulting in an overhead of 56%. With the larger payload size of 700 bytes, the header is amortized over many more bytes, reducing the overhead to 5%. With L2TPHC, the UDP header is absent and the L2TPHC header is 1 byte for the most compact case. Overall size is thus one byte of L2TPHC and 20 bytes of IP header. The small packet now suffers an overhead of only 32%, and the larger packet 3%. Percentage overhead does not represent all the considerations involved in reducing overhead. Consider a modem connection operating at 14,400 bits per second, which translates to a per-byte real-time cost of 0.6 milliseconds (14400 divided by 8 bits, as async framing characters are not included in the modem-to-modem data transfer). A savings of 16 bytes per packet can also be viewed as a reduction of almost 10 milliseconds of latency per packet. While this latency is short enough to be unnoticeable by a human, it may impact real-time protocols such as streaming audio or video. Thus, L2TP Header Compression provides most of its benefits when carrying streams of small packets. In environments such as downloading of graphic files, or where human interaction is intermingled with the short packets, the benefits of L2TP Header Compression will probably be undetectable. Valencia expires December 2000 [Page 5] INTERNET DRAFT June 2000 6. Security Considerations Because L2TPHC has no security facilities, it is critical that its operation be reconciled with the security policy of its environment. Since L2TPHC has no protocol header at all, it is trivial to spoof a source IP address and inject malicious packets into an ongoing session. There are several suitable techniques for controlling this exposure. In the simplest case, L2TPHC operates across a private network. For instance, a remote user may dial into a private NAS located on this network, and use L2TP (with or without L2TPHC) to cross an IP-only portion of this network to establish a multi-protocol session connected at a convenient point in the network. In this environment, no additional security may be required, and L2TPHC would operate trusting to the integrity of this private network. If the weak protection of a difficult-to-guess protocol header is deemed sufficient, expanded protocol overhead has clearly been determined to be acceptable, and L2TP over UDP can be used without L2TPHC. If PPP encryption under ECP [RFC1968] is active, malicious PPP packets are trivially detected and discarded as they are received on the raw IP port number. Similarly, if an IPsec session is protecting the IP packets themselves, malicious packets will also be discarded. Note that in both cases, an expanded header is implicit in these security facilities, which will greatly reduce the overhead efficiencies gained by L2TPHC. For instance, an MD5 AH IPsec header will add 32 bytes to the packet. The 16 bytes saved by L2TPHC quickly approaches statistical insignificance. 7. Acknowledgments Thanks to Gurdeep Singh Pall of Microsoft for identifying and describing scenarios in which L2TP header size become a concern, and for help in designing the L2TPHC header. Thanks to Bill Palter of Redback Networks and W. Mark Townsley of Cisco Systems for help in reviewing this draft. 8. Contacts Andrew J. Valencia P.O. Box 2928 Vashon, WA 98070 vandys@zendo.com Valencia expires December 2000 [Page 6] INTERNET DRAFT June 2000 9. References [RFC2661] M. Townsley, ``Layer 2 Tunnel Protocol (L2TP)'', RFC 2661, August 1999 [1] G. Zorn, ``RADIUS Attributes for Tunnel Protocol Support'', Internet draft, August 1999 [RFC1968] G. Meyer, ``PPP Encryption Control Protocol (ECP)'', RFC 1968, June 1996 Valencia expires December 2000 [Page 7]