Network Working Group Mark Laubach INTERNET DRAFT Com21, Inc. Expires 13 September 1998 13 March 1998 Logical IP Subnetworks over IEEE 802.14 Services Status of this Memo 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 draft documents are 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." To learn the current status of any Internet-Draft, please check the "1id-abstracts.txt" listing contained in the Internet-Drafts Shadow Directories on ftp.is.co.za (Africa), nic.nordu.net (Europe), munnari.oz.au (Pacific Rim), ds.internic.net (US East Coast), or ftp.isi.edu (US West Coast). Work In Progress This memo is work in progress in support of the activities of the IP over Cable Data Networks (ipcdn) Working Group of the IETF. The IEEE 802.14 working group has reached a layer of stability necessary for the activities the IETF ipcdn working group. This draft should be considered as the initial work that will be updated over time in concert with IEEE 802.14 development. This memo will track IEEE 802.14 progress with the goal of being complete when the IEEE 802.14 work reaches sponsor ballot in the IEEE standards process. The IEEE 802.14 Cable-TV Access Method And Physical Layer Specification is work in progress in the IEEE 802 LAN/MAN standards committee. At the time of this draft, the IEEE 802.14 is planning the release of its next comment ballot for July 1998. In the previous ballot process, variable length (Ethernet) mode was removed so as to differentiate the services from MCNS DOCSIS. Laubach [Page 1] DRAFT Logical IP Subnetworks over IEEE 802.14 Services March 1998 Table of Contents 1. ABSTRACT . . . . . . . . . . . . . . . . . . . . . . . . . . 2 2. ACKNOWLEDGMENT . . . . . . . . . . . . . . . . . . . . . . . 2 3. CONVENTIONS . . . . . . . . . . . . . . . . . . . . . . . . . 3 4. INTRODUCTION . . . . . . . . . . . . . . . . . . . . . . . . 3 5. IP SUBNETWORK CONFIGURATION . . . . . . . . . . . . . . . . . 6 5.1 Background . . . . . . . . . . . . . . . . . . . . . . . . 6 5.2 LIS Configuration Requirements . . . . . . . . . . . . . . 6 5.3 LIS Router Additional Configuration . . . . . . . . . . . . 7 6. IP PACKET FORMAT . . . . . . . . . . . . . . . . . . . . . . 8 7. IP BROADCAST ADDRESS . . . . . . . . . . . . . . . . . . . . 8 8. IP MULTICAST ADDRESS . . . . . . . . . . . . . . . . . . . . 8 9. IP INTEGRATED SERVICES SUPPORT . . . . . . . . . . . . . . . 9 10. FILTERING . . . . . . . . . . . . . . . . . . . . . . . . . 10 11 STATION REQUIREMENTS . . . . . . . . . . . . . . . . . . . 10 12. SECURITY . . . . . . . . . . . . . . . . . . . . . . . . . . 10 13. MIB SPECIFICATION . . . . . . . . . . . . . . . . . . . . . 11 14. OPEN ISSUES . . . . . . . . . . . . . . . . . . . . . . . . 11 15. REFERENCES . . . . . . . . . . . . . . . . . . . . . . . . . 12 16. AUTHOR . . . . . . . . . . . . . . . . . . . . . . . . . . . 13 1. ABSTRACT This memo defines an initial application of classical IP and ARP in an IEEE 802.14 Community Access Television (CATV) Residential Access Network environment. IEEE 802.14 services provide two independent link layer service interfaces which are available to support IP residential access networking services: traditional Ethernet bridging (via IEEE 802.1D layer services) and residential ATM networking services. In this memo, the term Logical IP Subnetwork (LIS) is defined to apply to Classical IP over ATM LIS's operating over IEEE 802.14 services as well as traditional IP over Ethernet operating over IEEE 802.14 services. The recommendations in this draft rely on existing IETF standards for the family of Classical IP and ARP over ATM (IPOA) services and for IP and ARP over Broadcast Ethernet networks. The tree-based hierarchic nature of the IEEE 802.14 MAC subnetwork permits convenient extensions to Classical IPOA model for broadcast and multicast in the downstream direction of the CATV plant. 2. ACKNOWLEDGMENT The author would like to thank the efforts of the IEEE 802.14 working group and the efforts of the IETF ipcdn working group. Randy Frei Laubach [Page 2] DRAFT Logical IP Subnetworks over IEEE 802.14 Services March 1998 from Com21 provided early review of this memo and contributed to the open issues list. 3. CONVENTIONS The following language conventions are used in the items of specification in this document: o MUST, SHALL, or MANDATORY -- the item is an absolute requirement of the specification. o SHOULD or RECOMMEND -- this item should generally be followed for all but exceptional circumstances. o MAY or OPTIONAL -- the item is truly optional and may be followed or ignored according to the needs of the implementor. 4. INTRODUCTION The goal of this specification is to allow compatible and interoperable implementations of Logical IP Subnetworks over IEEE 802.14 services [20], including the transmission of IP datagrams and Address Resolution Protocol (ARP) requests (ARP or ATMARP) and replies. This memo specifies the default operational model which will always be available in IP over IEEE 802.14 implementations. Subsequent memos will build upon and refine this model, however, in the absence or failure of those extensions, operations will default to the specifications contained in this memo. Consequently, this memo will not reference these other extensions. The IEEE 802.14 subnetwork consists of a Head-end Controller (HC) and one or more stations (ST). The HC and each station are 802.14 entities. The HC is responsible for all aspects of packet processing, resource sharing, and management of the 802.14 Media Access Control (MAC) and Physical (PHY) functions. A station is essentially a slave of the HC. The organization of the HC to each station is a strict rooted hierarchy: i.e., it is a two-level tree where the HC is the root and stations are the children. In the downstream direction, a 802.14 MAC Protocol Data Unit (PDU) may be sent to an individual station (unicast) or a group of stations (multicast and broadcast). In the upstream direction, all MAC PDUs (individual or group addressed) are sent from the station to the HC. The HC is active and originates and terminates all upstream MAC PDU flows; that is, the HC processes the MAC PDUs and does not merely repeat upstream MAC PDUs back on the Laubach [Page 3] DRAFT Logical IP Subnetworks over IEEE 802.14 Services March 1998 downstream for station to station communication. The HC MAC layer service function determines whether information will be forwarded back on the downstream; e.g. similar to Ethernet bridge forwarding behavior. The specific format of the IEEE 802.14 MAC PDU is transparent to higher level services, e.g. IP datagrams, and therefore not of specific interest to this draft. However, it is useful to note that IEEE 802.14 HC and ST entities support an ATM format MAC PDU mode. The IEEE 802.14 MAC PDU is not presented to the IP layer. For the purposes of protocol specification, IP may only access IEEE 802.14 services via its ATM cell-based service interface The IEEE 802.14 system employs a DES based link security system between the HC and all stations to protect the confidentiality of communications over the RF channels. The specific mechanisms are beyond the scope of this memo, however it should be noted that 1) the security system is transparent to any higher layer protocol (i.e. IP, ATM, MPEG), 2) the security system does not preclude the use of IPSEC methods for providing additional security for residential IP, 3) each MAC point-to-point connection is managed using different keys making it difficult to snoop on another station's unicast MAC traffic, and 4) each MAC point-to-multipoint connection is managed using different keys (stations only have keys for the MAC multicast groups of which they are a member). The IEEE 802.14 system enables comprehensive traffic management support and Quality of Service (QoS) support for ATM networking purpose. As such, these mechanisms can be exploited to provide for IP integrated services support. The IEEE 802.14 system will provide support of IEEE802.1D/p, with future support for IEEE802.1/Q Virtual LAN (VLAN) extensions. As such, these mechanisms can be exploited for IP integrated services support. The characteristics for residential LISs using IEEE 802.14 ATM cell- based service interface are: o RFC1577, RFC1626, and RFC1755 provide default IP over ATM LIS services. o Other IETF standards can be used to extend these services; e..g MARS, integrated services over ATM, etc. o More than one LIS may be in operation over the same 802.14 subnetwork (MAC domain) . Laubach [Page 4] DRAFT Logical IP Subnetworks over IEEE 802.14 Services March 1998 o An IEEE 802.14 station may be a member of more than one LIS. o Layer management services are available to the ATM layer for the purposes of managing point-to-point services on the downstream and upstream, and point-to-multipoint services on the downstream. o Layer management services are available to the ATM layer for traffic management and Quality of Service (QoS) control. o An IP router/gateway function may be colocated at the HC, e.g. in the case of an IEEE 802.14 "port card" in an IP router; or the router/gateway may be connected via an ATM network to the HC. This specification will not preclude either scenario. The scope of this specification covers implementation, interoperability, and operational extension issues for delivering Logical IP Subnetwork services via a residential access network implemented via the IEEE 802.14 standard. Due to the flexibility provided by the IEEE 802.14 system features, other IETF standards will be relied on when appropriate to do so. For example the ATM nature of the IEEE 802.14 system suggests that the existing IETF classical IP over ATM family of specifications will apply in general, with specific differences outlined in this memo for reasons of operational efficiency or general IP over Cable Data Network issues. For the purposes of this memo, the IEEE 802.14 subnetwork is intended to support residential Logical IP Subnetwork services. This specification does not preclude the operation of other multiple non- IP services which may be in simultaneous service over the IEEE 802.14 subnetwork: e.g., voice or video integrated services. 5. IP SUBNETWORK CONFIGURATION 5.1 Background The IEEE 802.14 subnetwork can support multiple simultaneously operating disjoint LISs over the same MAC domain. For each LIS a separate administrative entity configures its hosts and routers within the LIS. Each LIS operates and communicates independently of other LISs on the same IEEE 802.14 network. In the classical model, hosts communicate directly via IEEE 802.14 to other hosts within the same LIS using the appropriate address resolution service. In the case of the Ethernet frame service, the ARP service is the mechanism for resolving target IP addresses to target 48-bit IEEE MAC addresses. In the case of the ATM service, the ATMARP service is the mechanism for resolving target IP addresses to target ATM endpoint addresses. Laubach [Page 5] DRAFT Logical IP Subnetworks over IEEE 802.14 Services March 1998 As LISs are independent, inter-LIS protocol translation or address resolution conversion services are beyond the scope of this memo. Communication to hosts located outside of a LIS is provided via an IP router. The scope of an Ethernet LIS can span beyond an individual IEEE 802.14 subnetwork using traditional frame-based bridging; e.g., IEEE 802.1D transparent bridging services. The scope of an ATM LIS can span beyond an individual IEEE 802.14 subnetwork using conventional ATM networking. 5.2 Residential LIS Configuration Requirements The requirements for IP members (hosts, routers) operating in an IEEE 802.14-based LIS are: o All members of the LIS MUST have the same IP network/subnet number and address mask [8]. o All members within a ATM cell-based LIS are directly connected to the IEEE 802.14 subnetwork or to an ATM network connected to the IEEE 802.14 subnetwork. o All members of a LIS MUST have a mechanism for resolving IP addresses to link addresses (ARP or ATMARP). o All members of a LIS MUST have a mechanism for resolving link addresses to IP addresses via an inverse address resolution protocol (InARP or InATMARP). o All LIS members connected to the IEEE 802.14 subnetwork via an IEEE 802.14 station MUST be able to communicate via the IEEE 802.14 subnetwork to or beyond the IEEE 802.14 HC. By default, the IEEE 802.14 HC optionally SHOULD not forward upstream communications from one station to another downstream station in the LIS; in this case, an IP router attached to or colocated with the HC should provide the forwarding from upstream to downstream. o All LIS members connected to the IEEE 802.14 subnetwork via an IEEE 802.14 HC MUST be able to communicate via the IEEE 802.14 subnetwork to or beyond any downstream IEEE 802.14 station in the LIS. o A LIS MAY span more than one IEEE 802.14 subnetwork. In the case of frame based, conventional Layer 2 bridging/switching MAY interconnect more than one HC. In the case of ATM based, a backend ATM network MAY interconnect more than one HC. Laubach [Page 6] DRAFT Logical IP Subnetworks over IEEE 802.14 Services March 1998 5.3 LIS Router Additional Configuration Routers providing LIS functionality over the IEEE 802.14 subnetwork MAY also support the ability to interconnect multiple LISs. Routers that wish to provide interconnection of differing LISs MUST be able to support multiple sets of parameters (one set for each connected LIS) and be able to associate each set of parameters to a specific IP network/subnet number. In addition, a router MAY be able to provide this multiple LIS support with a single physical IEEE802.14 interface with a different link address per LIS. 6. IP PACKET FORMAT Implementations built using the IEEE 802.14 ATM cell based layer services MUST support IEEE 802.2 LLC/SNAP encapsulation as described in [2]. LLC/SNAP encapsulation is the default packet format for IP datagrams running via IP over ATM networks. The default MTU of this interface is 9180 octets. This memo recognizes that end-to-end signaling within ATM may allow negotiation of encapsulation method or MTU on a per-VC basis. 7. IP BROADCAST ADDRESS The IEEE 802.14 downstream MAC PDU supports point-to-multipoint addressing. For each LIS, the IP layer service support at the IEEE 802.14 HC MUST create a single downstream point-to-multipoint group whose membership contains all IEEE 802.14 station participating in that LIS. By default, all downstream IP datagrams whose destination address specifies one of the four forms of IP broadcast addresses (limited, directed, subnet directed, or all-subnets directed) [8] or an IP multicast address MUST be sent to members of the LIS using this MAC address group. Note: By default, all upstream IP datagrams are sent from the IEEE 802.14 station to the HC on the single point-to-point connection. Note: the above defaults do not preclude the use of additional downstream point-to-point or point-to-multipoint, or additional upstream point-to-point connections for handling of specific IP flows for integrated-services or multicast distribution support; e.g., mapping IP flows to specific additional connections. In general, it is preferred that downstream data bandwidth resources be used in an efficient manner. Therefore, IP over IEEE802.14 implementations SHOULD only send one copy of a packet downstream per IP broadcast transmission or IP multicast transmission. Laubach [Page 7] DRAFT Logical IP Subnetworks over IEEE 802.14 Services March 1998 8. IP MULTICAST ADDRESS The IEEE 802.14 downstream MAC service supports point-to-multipoint addressing. MAC point-to-multipoint addresses can span LISs. For efficiency reasons, a separate point-to-multipoint group MAY be used to support downstream IP multicast datagram distribution. The specific implementation is beyond the scope of this memo, however it can be noted that single or multiple IP multicast groups MAY be mapped to a MAC point-to-multipoint group subject to the abilities of the IEEE 802.14 HC and participating stations. Note: By default, all upstream IP datagrams are sent from the IEEE 802.14 station to the HC on the single point-to-point connection. Note: the above defaults do not preclude the use of additional downstream point-to-multipoint or additional upstream point-to-point connections for handling of specific IP flows for integrated-services or multicast distribution support; e.g., mapping IP flows to specific additional connections. It is preferred that downstream data bandwidth resources be used in an efficient manner, therefore IP over IEEE 802.14 implementations MUST only send one copy of a packet downstream per IP multicast transmission. Specially, MAC point-to-multipoint groups used for IP multicast datagram distribution may span LISs. For example, there may be two LISs operating via an IEEE 802.14 subnetwork, LIS-1 and LIS-2. LIS1 may have station members ST-A, ST-B, and ST-C. and LIS-2 may have station members ST-X, ST-Y, and ST-Z. The Ethernet layer management services at the HC would have created two point-to-multipoint groups PTM-1 and PTM-2 used for default downstream broadcast and multicast transmission. The membership of PTM-1 would be ST-A, ST-B, and ST-C. The membership of PTM-2 would be ST-X, ST-Y, ST-Z. There may be another point-to- multipoint group for distributing a specific IP multicast group, call this PTM-3. The members of PTM-3 might be ST-B, ST-C, and ST-X therefore PTM-3 spans LIS-1 and LIS-2. The coupling of the IEEE 802.14 layer management services responsible for group management with that of IP Internet Group Management Protocol (IGMP) is TBD. 9. IP INTEGRATED SERVICES SPPORT By default, the IEEE 802.14 service delivers IP traffic on a best effort basis. Laubach [Page 8] DRAFT Logical IP Subnetworks over IEEE 802.14 Services March 1998 The underlying protocol of IEEE 802.14 is designed to support the ATM service classes: Constant Bit Rate (CBR), real-time Variable Bit Rate (rt-VBR), non-real-time Variable Bit Rate (nrt-VBR), Available Bit Rate (ABR), and Unspecified Bit Rate (UBR), and their associated Quality of Service requirements (delay, delay tolerance, cell loss rate) subject to the characteristics of the downstream and upstream channel rates. Mappings from IP integrated services to IP over ATM can be exploited to provide traffic management and Quality of Service (QoS) on a per IP flow basis, for unicast and multicast traffic. As such, these capabilities are available for ATM cell-based access Specifications for the support of integrated services and RSVP over IEEE 802.14 are TBD. 10. FILTERING The IEEE 802.14 system does not preclude the use of filtering for IP and ARP protocol packets. Such filtering is TBD. The IEEE 802.14 system permits filters to be placed in the upstream and downstream at the ST and the HC and independently for point-to- point and point-to-multipoint connections. In addition, filters may be placed at the HC in the service function responsible for forwarding packets from upstream to downstream. Such use of these facilities is TBD. 11. Station Requirements The IP over IEEE 802.14 station MUST be able to separately and simultaneously reassemble or reconstruct packets for each point-to- point or point-to-multipoint downstream connection being used for IP LIS or IP Multicast services. By default, all unicast, broadcast, and multicast communications from an IP over IEEE802.14 station MUST be sent using the point-to-point connection to the IEEE 802.14 HC. It is noted that the default behavior MAY be modified in the future by providing additional connections for IP traffic from the IEEE 802.14 station to the IEEE 802.14 HC. Specifications for optional LIS forwarding requirements are TBD. 12. SECURITY TBD. Laubach [Page 9] DRAFT Logical IP Subnetworks over IEEE 802.14 Services March 1998 13. MIB SPECIFICATION The IEEE 802.14 MIB is TBD. 14. OPEN ISSUES o ATM signaling support by IEEE 802.14 and specific HC functionality in support of IP will be mentioned in a future revision of this memo. o IEEE 802.1D/p and Q extensions, including GARP will be mentioned in a future revision of this memo. o RSVP coupling to IEEE 802.14 layer management is TBD. o IGMP coupling to IEEE 802.14 layer management is TBD. o IETF Integrated Services support by IEEE 802.14 is TBD. o May need to add comments about IP over Ethernet/RFC1483 implementations. o The HC forwarding option results in routing intra-LIS. What about subnet-directed broadcasts (blocked)? ARPs? Will the headend proxy ARP for all stations? If the stations are members of the same LIS, then they will try to talk directly and their packets will have to be forced to the router (in frame mode, have the headend proxy ARP for with the router's MAC for any LIS members that are not local to that station). What about ATMARP issues? ICMP redirects should be disabled from the router. Are we assuming that members of an LIS may just be under the same administrative control, and not not necessarily "friendly"? Like an ISP subnet? This does give the administrator some extra protection. o In frame mode, what about multicast? Unicast packets sent to the router will be routed back to the destination station, but multicast assumes all stations can hear each other? Without a specific broadcast facility upstream, do we have to build one for multicast: receive multicast group membership, facilitate group access control and forward multicast back downstream based on this info? Or does 802.14 address this? For ATM mode would something like MARS be needed? What about NHRP (as opposed to ATM ARP)? From Scott Brim: Laubach [Page 10] DRAFT Logical IP Subnetworks over IEEE 802.14 Services March 1998 The head end needs to be intelligent enough to do various filtering at the PDU (not cell) level. Regardless of whether it's used the code needs to be in there. This brings up two questions -- tell me if I read it right: * doesn't forwarding cells to the outside world (beyond the head end) conflict with having frame-level intelligence? That is, does the head end have to accumulate cells and reassemble frames even if it's forwarding cells to the outside world (under any conditions)? * I can't tell if the head end is recommended to do IP forwarding within the 802.14 LIS (there are 2 conflicting statements) but if it doesn't, it still needs all the intelligence to examine packets. Seems like a waste. Why isn't the head end either dumb or smart? 15. REFERENCES [1] Piscitello, D., and Lawrence, J., "IP and ARP over the SMDS Service", RFC-1209, USC/Information Sciences Institute, March 1991. [2] Heinanen, Juha, "Multiprotocol Encapsulation over ATM Adaptation Layer 5", RFC-1483, USC/Information Sciences Institute, July 1993. [3] Plummer, D., "An Ethernet Address Resolution Protocol - or - Converting Network Addresses to 48.bit Ethernet Address for Transmission on Ethernet Hardware", RFC-826, MIT, November 1982. [4] Reynolds, J., and Postel, J., "Assigned Numbers", RFC-1340, USC/ Information Sciences Institute, July 1992. [5] Postel, J., and Reynolds, J., "A Standard for the Transmission of IP Datagrams over IEEE 802 Networks", RFC-1042, USC/Information Sciences Institute, February 1988. [6] CCITT, "Draft Recommendation I.363", CCITT Study Group XVIII, Geneva, 19-29 January 1993. [7] CCITT, "Draft text for Q.93B", CCITT Study Group XI, 23 September - 2 October 1992. [8] Braden, R., "Requirements for Internet Hosts -- Communication Layers", RFC-1122, USC/Information Sciences Institute, October 1989. Laubach [Page 11] DRAFT Logical IP Subnetworks over IEEE 802.14 Services March 1998 [9] ATM Forum, "ATM User-Network Interface (UNI) Specification Version 3.1.", ISBN 0-13-393828-X, Prentice-Hall, Inc., Upper Saddle River, NJ, 07458, September, 1994. [10] Deering, S, "Host Extensions for IP Multicasting", RFC-1112, USC/Information Sciences Institute, August 1989. [11] Colella, Richard, and Gardner, Ella, and Callon, Ross, "Guidelines for OSI NSAP Allocation in the Internet", RFC-1237, USC/Information Sciences Institute, July 1991. [12] Bradely, T., and Brown, C., "Inverse Address Resolution Protocol", RFC-1293, USC/Information Sciences Institute, January 1992. [13] Bellovin, Steven M., "Security Problems in the TCP/IP Protocol Suite", ACM Computer Communications Review, Vol. 19, Issue 2, pp. 32-48, 1989. [14] Knowles, S., "IESG Advice from Experience with Path MTU Discovery, RFC-1435, IESG, March 1993. [15] Droms, R., "Dynamic Host Configuration Protocol", RFC1541, Bucknell University, October 1993. [16] Kent C., and J. Mogul, "Fragmentation Considered Harmful", Proceedings of the ACM SIGCOMM '87 Workshop on Frontiers in Computer Communications Technology, August 1987. [17] Mogul, J., and S. Deering, "Path MTU Discovery", RFC-1191, DECWRL, Stanford University, November 1990. [18] Green, M., Luciani, J., White, K., Kuo, T., "Definitions of Managed Objects for Classical IP and ARP over ATM Using SMIv2", IETF, draft-ietf-ipatm-mib-01 (work in progress), February, 1996. [19] ATM Forum, "ATM User-Network Interface (UNI) Specification Version 4.0", ATM Forum specification afsig-0061.000, ftp://ftp.atmforum.com/, July, 1996. [20] IEEE 802 LAN/MAN, "IEEE 802.14 Draft 2 Revision 2", IEEE 802.14 Working Group work in progress, July, 1997. [21] Hornig, C.., "A Standard for the Transmission for IP Datagrams over Ethernet Networks", RFC-894, Symbolics Cambridge Research Center, April, 1984. Laubach [Page 12] DRAFT Logical IP Subnetworks over IEEE 802.14 Services March 1998 16. AUTHOR Mark Laubach Com21, Inc. 750 Tasman Drive Milpitas, CA 95035 Phone: 408.953.9175 FAX: 408.953.9299 EMail: laubach@com21.com Laubach [Page 13]