From 4bfd864f10b68b71482b35c818559068ef8d5797 Mon Sep 17 00:00:00 2001 From: Thomas Voss Date: Wed, 27 Nov 2024 20:54:24 +0100 Subject: doc: Add RFC documents --- doc/rfc/rfc1577.txt | 955 ++++++++++++++++++++++++++++++++++++++++++++++++++++ 1 file changed, 955 insertions(+) create mode 100644 doc/rfc/rfc1577.txt (limited to 'doc/rfc/rfc1577.txt') diff --git a/doc/rfc/rfc1577.txt b/doc/rfc/rfc1577.txt new file mode 100644 index 0000000..2041413 --- /dev/null +++ b/doc/rfc/rfc1577.txt @@ -0,0 +1,955 @@ + + + + + + +Network Working Group M. Laubach +Request for Comments: 1577 Hewlett-Packard Laboratories +Category: Standards Track January 1994 + + + Classical IP and ARP over ATM + +Status of this Memo + + This document specifies an Internet standards track protocol for the + Internet community, and requests discussion and suggestions for + improvements. Please refer to the current edition of the "Internet + Official Protocol Standards" (STD 1) for the standardization state + and status of this protocol. Distribution of this memo is unlimited. + +Abstract + + This memo defines an initial application of classical IP and ARP in + an Asynchronous Transfer Mode (ATM) network environment configured as + a Logical IP Subnetwork (LIS) as described in Section 3. This memo + does not preclude the subsequent development of ATM technology into + areas other than a LIS; specifically, as single ATM networks grow to + replace many ethernet local LAN segments and as these networks become + globally connected, the application of IP and ARP will be treated + differently. This memo considers only the application of ATM as a + direct replacement for the "wires" and local LAN segments connecting + IP end-stations ("members") and routers operating in the "classical" + LAN-based paradigm. Issues raised by MAC level bridging and LAN + emulation are beyond the scope of this paper. + + This memo introduces general ATM technology and nomenclature. + Readers are encouraged to review the ATM Forum and ITU-TS (formerly + CCITT) references for more detailed information about ATM + implementation agreements and standards. + +Acknowledgments + + This memo could not have come into being without the critical review + from Jim Forster of Cisco Systems, Drew Perkins of FORE Systems, and + Bryan Lyles, Steve Deering, and Berry Kercheval of XEROX PARC. The + concepts and models presented in [1], written by Dave Piscitello and + Joseph Lawrence, laid the structural groundwork for this work. ARP + [3] written by Dave Plummer and Inverse ARP [12] written by Terry + Bradley and Caralyn Brown are the foundation of ATMARP presented in + this memo. This document could have not been completed without the + expertise of the IP over ATM Working Group of the IETF and the ad hoc + PVC committee at the Amsterdam IETF meeting. + + + + +Laubach [Page 1] + +RFC 1577 Classical IP and ARP over ATM January 1993 + + +1. 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. + +2. Introduction + + The goal of this specification is to allow compatible and + interoperable implementations for transmitting IP datagrams and ATM + Address Resolution Protocol (ATMARP) requests and replies over ATM + Adaptation Layer 5 (AAL5)[2,6]. + + Note: this memo defines only the operation of IP and address + resolution over ATM, and is not meant to describe the operation of + ATM networks. Any reference to virtual connections, permanent virtual + connections, or switched virtual connections applies only to virtual + channel connections used to support IP and address resolution over + ATM, and thus are assumed to be using AAL5. This memo places no + restrictions or requirements on virtual connections used for other + purposes. + + Initial deployment of ATM provides a LAN segment replacement for: + + 1) Local area networks (e.g., Ethernets, Token Rings and FDDI). + + 2) Local-area backbones between existing (non-ATM) LANs. + + 3) Dedicated circuits or frame relay PVCs between IP routers. + + Note: In 1), local IP routers with one or more ATM interfaces will be + able to connect islands of ATM networks. In 3), public or private + ATM Wide Area networks will be used to connect IP routers, which in + turn may or may not connect to local ATM networks. ATM WANs and LANs + may be interconnected. + + Private ATM networks (local or wide area) will use the private ATM + address structure specified in the ATM Forum UNI specification [9]. + This structure is modeled after the format of an OSI Network Service + Access Point Address. A private ATM address uniquely identifies an + + + +Laubach [Page 2] + +RFC 1577 Classical IP and ARP over ATM January 1993 + + + ATM endpoint. Public networks will use either the address structure + specified in ITU-TS recommendation E.164 or the private network ATM + address structure. An E.164 address uniquely identifies an interface + to a public network. + + The characteristics and features of ATM networks are different than + those found in LANs: + + o ATM provides a Virtual Connection (VC) switched environment. VC + setup may be done on either a Permanent Virtual Connection (PVC) + or dynamic Switched Virtual Connection (SVC) basis. SVC call + management signalling is performed via implementations of the + Q.93B protocol [7,9]. + + o Data to be passed by a VC is segmented into 53 octet quantities + called cells (5 octets of ATM header and 48 octets of data). + + o The function of mapping user Protocol Data Units (PDUs) into the + information field of the ATM cell and vice versa is performed in + the ATM Adaptation Layer (AAL). When a VC is created a specific + AAL type is associated with the VC. There are four different AAL + types, which are referred to individually as "AAL1", "AAL2", + "AAL3/4", and "AAL5". (Note: this memo concerns itself with the + mapping of IP and ATMARP over AAL5 only. The other AAL types are + mentioned for introductory purposes only.) The AAL type is known + by the VC end points via the call setup mechanism and is not + carried in the ATM cell header. For PVCs the AAL type is + administratively configured at the end points when the Connection + (circuit) is set up. For SVCs, the AAL type is communicated + along the VC path via Q.93B as part of call setup establishment + and the end points use the signaled information for + configuration. ATM switches generally do not care about the AAL + type of VCs. The AAL5 format specifies a packet format with a + maximum size of (64K - 1) octets of user data. Cells for an AAL5 + PDU are transmitted first to last, the last cell indicating the + end of the PDU. ATM standards guarantee that on a given VC, cell + ordering is preserved end-to-end. NOTE: AAL5 provides a non- + assured data transfer service - it is up to higher-level + protocols to provide retransmission. + + o ATM Forum signalling defines point-to-point and point-to- + multipoint Connection setup [9]. Multipoint-to-multipoint VCs + are not yet specified by ITU-TS or ATM Forum. + + o An ATM Forum ATM endpoint address is either encoded as an NSAP + Address (NSAPA) or is an E.164 Public-UNI address [9]. In some + cases, both an ATM endpoint address and an E.164 Public UNI + address are needed by an ATMARP client to reach another host or + + + +Laubach [Page 3] + +RFC 1577 Classical IP and ARP over ATM January 1993 + + + router. Since the use of ATM endpoint addresses and E.164 public + UNI addresses by ATMARP are analogous to the use of Ethernet + addresses, the notion of "hardware address" is extended to + encompass ATM addresses in the context of ATMARP, even though ATM + addresses need not have hardware significance. ATM Forum NSAPAs + use the same basic format as U.S. GOSIP NSAPAs [11]. Note: ATM + Forum addresses should not be construed as being U.S. GOSIP + NSAPAs. They are not, the administration is different, which + fields get filled out are different, etc. + + This memo describes the initial deployment of ATM within "classical" + IP networks as a direct replacement for local area networks + (ethernets) and for IP links which interconnect routers, either + within or between administrative domains. The "classical" model here + refers to the treatment of the ATM host adapter as a networking + interface to the IP protocol stack operating in a LAN-based paradigm. + + Characteristics of the classical model are: + + o The same maximum transmission unit (MTU) size is used for all VCs + in a LIS [2]. (Refer to Section 5.) + + o Default LLC/SNAP encapsulation of IP packets. + + o End-to-end IP routing architecture stays the same. + + o IP addresses are resolved to ATM addresses by use of an ATMARP + service within the LIS - ATMARPs stay within the LIS. From a + client's perspective, the ATMARP architecture stays faithful to + the basic ARP model presented in [3]. + + o One IP subnet is used for many hosts and routers. Each VC + directly connects two IP members within the same LIS. + + Future memos will describe the operation of IP over ATM when ATM + networks become globally deployed and interconnected. + + The deployment of ATM into the Internet community is just beginning + and will take many years to complete. During the early part of this + period, we expect deployment to follow traditional IP subnet + boundaries for the following reasons: + + o Administrators and managers of IP subnetworks will tend to + initially follow the same models as they currently have deployed. + The mindset of the community will change slowly over time as ATM + increases its coverage and builds its credibility. + + + + + +Laubach [Page 4] + +RFC 1577 Classical IP and ARP over ATM January 1993 + + + o Policy administration practices rely on the security, access, + routing, and filtering capability of IP Internet gateways: i.e., + firewalls. ATM will not be allowed to "back-door" around these + mechanisms until ATM provides better management capability than + the existing services and practices. + + o Standards for global IP over ATM will take some time to complete + and deploy. + + This memo details the treatment of the classical model of IP and + ATMARP over ATM. This memo does not preclude the subsequent treatment + of ATM networks within the IP framework as ATM becomes globally + deployed and interconnected; this will be the subject of future + documents. This memo does not address issues related to transparent + data link layer interoperability. + +3. IP Subnetwork Configuration + + In the LIS scenario, each separate administrative entity configures + its hosts and routers within a closed logical IP subnetwork. Each + LIS operates and communicates independently of other LISs on the same + ATM network. Hosts connected to ATM communicate directly to other + hosts within the same LIS. Communication to hosts outside of the + local LIS is provided via an IP router. This router is an ATM + Endpoint attached to the ATM network that is configured as a member + of one or more LISs. This configuration may result in a number of + disjoint LISs operating over the same ATM network. Hosts of differing + IP subnets MUST communicate via an intermediate IP router even though + it may be possible to open a direct VC between the two IP members + over the ATM network. + + The requirements for IP members (hosts, routers) operating in an ATM + LIS configuration are: + + o All members have the same IP network/subnet number and address + mask [8]. + + o All members within a LIS are directly connected to the ATM + network. + + o All members outside of the LIS are accessed via a router. + + o All members of a LIS MUST have a mechanism for resolving IP + addresses to ATM addresses via ATMARP (based on [3]) and vice + versa via InATMARP (based on [12]) when using SVCs. Refer to + Section 6 "Address Resolution" in this memo. + + + + + +Laubach [Page 5] + +RFC 1577 Classical IP and ARP over ATM January 1993 + + + o All members of a LIS MUST have a mechanism for resolving VCs to + IP addresses via InATMARP (based on [12]) when using PVCs. Refer + to Section 6 "Address Resolution" in this memo. + + o All members within a LIS MUST be able to communicate via ATM with + all other members in the same LIS; i.e., the virtual Connection + topology underlying the intercommunication among the members is + fully meshed. + + The following list identifies a set of ATM specific parameters that + MUST be implemented in each IP station connected to the ATM network: + + o ATM Hardware Address (atm$ha). The ATM address of the individual + IP station. + + o ATMARP Request Address (atm$arp-req). atm$arp-req is the ATM + address of an individual ATMARP server located within the LIS. + In an SVC environment, ATMARP requests are sent to this address + for the resolution of target protocol addresses to target ATM + addresses. That server MUST have authoritative responsibility + for resolving ATMARP requests of all IP members within the LIS. + Note: if the LIS is operating with PVCs only, then this parameter + may be set to null and the IP station is not required to send + ATMARP requests to the ATMARP server. + + It is RECOMMENDED that routers providing LIS functionality over the + ATM network 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 these 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, it is + RECOMMENDED that a router be able to provide this multiple LIS + support with a single physical ATM interface that may have one or + more individual ATM endpoint addresses. Note: this does not + necessarily mean different End System Identifiers (ESIs) when NSAPAs + are used. The last octet of an NSAPA is the NSAPA Selector (SEL) + field which can be used to differentiate up to 256 different LISs for + the same ESI. (Refer to Section 5.1.3.1, "Private Networks" in [9].) + +4. Packet Format + + Implementations MUST support IEEE 802.2 LLC/SNAP encapsulation as + described in [2]. LLC/SNAP encapsulation is the default packet + format for IP datagrams. + + This memo recognizes that other encapsulation methods may be used + however, in the absence of other knowledge or agreement, LLC/SNAP + encapsulation is the default. + + + +Laubach [Page 6] + +RFC 1577 Classical IP and ARP over ATM January 1993 + + + This memo recognizes the future deployment of end-to-end signalling + within ATM that will allow negotiation of encapsulation method on a + per-VC basis. Signalling negotiations are beyond the scope of this + memo. + +5. MTU Size + + The default MTU size for IP members operating over the ATM network + SHALL be 9180 octets. The LLC/SNAP header is 8 octets, therefore the + default ATM AAL5 protocol data unit size is 9188 octets [2]. In + classical IP subnets, values other than the default can be used if + and only if all members in the LIS have been configured to use the + non-default value. + + This memo recognizes the future deployment of end-to-end signalling + within ATM that will allow negotiation of MTU size on a per-VC basis. + Signalling negotiations are beyond the scope of this document. + +6. Address Resolution + + Address resolution within an ATM logical IP subnet SHALL make use of + the ATM Address Resolution Protocol (ATMARP) (based on [3]) and the + Inverse ATM Address Resolution Protocol (InATMARP) (based on [12]) as + defined in this memo. ATMARP is the same protocol as the ARP + protocol presented in [3] with extensions needed to support ARP in a + unicast server ATM environment. InATMARP is the same protocol as the + original InARP protocol presented in [12] but applied to ATM + networks. All IP stations MUST support these protocols as updated + and extended in this memo. Use of these protocols differs depending + on whether PVCs or SVCs are used. + +6.1 Permanent Virtual Connections + + An IP station MUST have a mechanism (eg. manual configuration) for + determining what PVCs it has, and in particular which PVCs are being + used with LLC/SNAP encapsulation. The details of the mechanism are + beyond the scope of this memo. + + All IP members supporting PVCs are required to use the Inverse ATM + Address Resolution Protocol (InATMARP) (refer to [12]) on those VCs + using LLC/SNAP encapsulation. In a strict PVC environment, the + receiver SHALL infer the relevant VC from the VC on which the + InATMARP request (InARP_REQUEST) or response (InARP_REPLY) was + received. When the ATM source and/or target address is unknown, the + corresponding ATM address length in the InATMARP packet MUST be set + to zero (0) indicating a null length, otherwise the appropriate + address field should be filled in and the corresponding length set + appropriately. InATMARP packet format details are presented later in + + + +Laubach [Page 7] + +RFC 1577 Classical IP and ARP over ATM January 1993 + + + this memo. + + Directly from [12]: "When the requesting station receives the InARP + reply, it may complete the [ATM]ARP table entry and use the provided + address information. Note: as with [ATM]ARP, information learned via + In[ATM]ARP may be aged or invalidated under certain circumstances." + It is the responsibility of each IP station supporting PVCs to re- + validate [ATM]ARP table entries as part of the aging process. See + Section 6.5 on "ATMARP Table Aging". + +6.2 Switched Virtual Connections + + SVCs require support for ATMARP in the non-broadcast, non-multicast + environment that ATM networks currently provide. To meet this need a + single ATMARP Server MUST be located within the LIS. This server MUST + have authoritative responsibility for resolving the ATMARP requests + of all IP members within the LIS. + + The server itself does not actively establish connections. It + depends on the clients in the LIS to initiate the ATMARP registration + procedure. An individual client connects to the ATMARP server using + a point-to-point VC. The server, upon the completion of an ATM + call/connection of a new VC specifying LLC/SNAP encapsulation, will + transmit an InATMARP request to determine the IP address of the + client. The InATMARP reply from the client contains the information + necessary for the ATMARP Server to build its ATMARP table cache. This + information is used to generate replies to the ATMARP requests it + receives. + + The ATMARP Server mechanism requires that each client be + administratively configured with the ATM address of the ATMARP Server + atm$arp-req as defined earlier in this memo. There is to be one and + only one ATMARP Server operational per logical IP subnet. It is + RECOMMENDED that the ATMARP Server also be an IP station. This + station MUST be administratively configured to operate and recognize + itself as the ATMARP Server for a LIS. The ATMARP Server MUST be + configured with an IP address for each logical IP subnet it is + serving to support InATMARP requests. + + This memo recognizes that a single ATMARP Server is not as robust as + multiple servers which synchronize their databases correctly. This + document is defining the client-server interaction by using a simple, + single server approach as a reference model, and does not prohibit + more robust approaches which use the same client-server interface. + + + + + + + +Laubach [Page 8] + +RFC 1577 Classical IP and ARP over ATM January 1993 + + +6.3 ATMARP Server Operational Requirements + + The ATMARP server accepts ATM calls/connections from other ATM end + points. At call setup and if the VC supports LLC/SNAP encapsulation, + the ATMARP server will transmit to the originating ATM station an + InATMARP request (InARP_REQUEST) for each logical IP subnet the + server is configured to serve. After receiving an InATMARP reply + (InARP_REPLY), the server will examine the IP address and the ATM + address. The server will add (or update) the map entry and timestamp into its ATMARP table. If the + InATMARP IP address duplicates a table entry IP address and the + InATMARP ATM address does not match the table entry ATM address and + there is an open VC associated with that table entry, the InATMARP + information is discarded and no modifications to the table are made. + ATMARP table entries persist until aged or invalidated. VC call tear + down does not remove ATMARP table entries. + + The ATMARP server, upon receiving an ATMARP request (ARP_REQUEST), + will generate the corresponding ATMARP reply (ARP_REPLY) if it has an + entry in its ATMARP table. Otherwise it will generate a negative + ATMARP reply (ARP_NAK). The ARP_NAK response is an extension to the + ARMARP protocol and is used to improve the robustness of the ATMARP + server mechanism. With ARP_NAK, a client can determine the + difference between a catastrophic server failure and an ATMARP table + lookup failure. The ARP_NAK packet format is the same as the + received ARP_REQUEST packet format with the operation code set to + ARP_NAK, i.e., the ARP_REQUEST packet data is merely copied for + transmission with the ARP_REQUEST operation code reset to ARP_NAK. + + Updating the ATMARP table information timeout, the short form: when + the server receives an ATMARP request over a VC, where the source IP + and ATM address match the association already in the ATMARP table and + the ATM address matches that associated with the VC, the server may + update the timeout on the source ATMARP table entry: i.e., if the + client is sending ATMARP requests to the server over the same VC that + it used to register its ATMARP entry, the server should examine the + ATMARP requests and note that the client is still "alive" by updating + the timeout on the client's ATMARP table entry. + + Adding robustness to the address resolution mechanism using ATMARP: + when the server receives an ARP_REQUEST over a VC, it examines the + source information. If there is no IP address associated with the VC + over which the ATMARP request was received and if the source IP + address is not associated with any other connection, then the server + will add the entry and timestamp into its + ATMARP table and associate the entry with this VC. + + + + + +Laubach [Page 9] + +RFC 1577 Classical IP and ARP over ATM January 1993 + + +6.4 ATMARP Client Operational Requirements + + The ATMARP client is responsible for contacting the ATMARP server to + register its own ATMARP information and to gain and refresh its own + ATMARP entry/information about other IP members. This means, as + noted above, that ATMARP clients MUST be configured with the ATM + address of the ATMARP server. ATMARP clients MUST: + + 1. Initiate the VC connection to the ATMARP server for + transmitting and receiving ATMARP and InATMARP packets. + + 2. Respond to ARP_REQUEST and InARP_REQUEST packets received on + any VC appropriately. (Refer to Section 7, "Protocol Operation" + in [12].) + + 3. Generate and transmit ARP_REQUEST packets to the ATMARP server + and to process ARP_REPLY and ARP_NAK packets from the server + appropriately. ARP_REPLY packets should be used to + build/refresh its own client ATMARP table entries. + + 4. Generate and transmit InARP_REQUEST packets as needed and to + process InARP_REPLY packets appropriately. InARP_REPLY packets + should be used to build/refresh its own client ATMARP table + entries. (Refer to Section 7, "Protocol Operation" in [12].) + + 5. Provide an ATMARP table aging function to remove its own old + client ATMARP tables entries after a convenient period of time. + + Note: if the client does not maintain an open VC to the server, the + client MUST refresh its ATMARP information with the server at least + once every 20 minutes. This is done by opening a VC to the server + and exchanging the initial InATMARP packets. + +6.5 ATMARP Table Aging + + An ATMARP client or server MUST have knowledge of any open VCs it has + (permanent or switched), their association with an ATMARP table + entry, and in particular, which VCs support LLC/SNAP encapsulation. + + Client ATMARP table entries are valid for a maximum time of 15 + minutes. + + Server ATMARP table entries are valid for a minimum time of 20 + minutes. + + Prior to aging an ATMARP table entry, an ATMARP server MUST generate + an InARP_REQUEST on any open VC associated with that entry. If an + InARP_REPLY is received, that table entry is updated and not deleted. + + + +Laubach [Page 10] + +RFC 1577 Classical IP and ARP over ATM January 1993 + + + If there is no open VC associated with the table entry, the entry is + deleted. + + When an ATMARP table entry ages, an ATMARP client MUST invalidate the + table entry. If there is no open VC associated with the invalidated + entry, that entry is deleted. In the case of an invalidated entry and + an open VC, the ATMARP client must revalidate the entry prior to + transmitting any non address resolution traffic on that VC. In the + case of a PVC, the client validates the entry by transmitting an + InARP_REQUEST and updating the entry on receipt of an InARP_REPLY. In + the case of an SVC, the client validates the entry by transmitting an + ARP_REQUEST to the ATMARP Server and updating the entry on receipt of + an ARP_REPLY. If a VC with an associated invalidated ATMARP table + entry is closed, that table entry is removed. + +6.6 ATMARP and InATMARP Packet Format + + Internet addresses are assigned independently of ATM addresses. Each + host implementation MUST know its own IP and ATM address(es) and MUST + respond to address resolution requests appropriately. IP members + MUST also use ATMARP and InATMARP to resolve IP addresses to ATM + addresses when needed. + + The ATMARP and InATMARP protocols use the same hardware type + (ar$hrd), protocol type (ar$pro), and operation code (ar$op) data + formats as the ARP and InARP protocols [3,12]. The location of these + fields within the ATMARP packet are in the same byte position as + those in ARP and InARP packets. A unique hardware type value has + been assigned for ATMARP. In addition, ATMARP makes use of an + additional operation code for ARP_NAK. The remainder of the + ATMARP/InATMARP packet format is different than the ARP/InARP packet + format. + + The ATMARP and InATMARP protocols have several fields that have the + following format and values: + + Data: + ar$hrd 16 bits Hardware type + ar$pro 16 bits Protocol type + ar$shtl 8 bits Type & length of source ATM number (q) + ar$sstl 8 bits Type & length of source ATM subaddress (r) + ar$op 16 bits Operation code (request, reply, or NAK) + ar$spln 8 bits Length of source protocol address (s) + ar$thtl 8 bits Type & length of target ATM number (x) + ar$tstl 8 bits Type & length of target ATM subaddress (y) + ar$tpln 8 bits Length of target protocol address (z) + ar$sha qoctets source ATM number + ar$ssa roctets source ATM subaddress + + + +Laubach [Page 11] + +RFC 1577 Classical IP and ARP over ATM January 1993 + + + ar$spa soctets source protocol address + ar$tha xoctets target ATM number + ar$tsa yoctets target ATM subaddress + ar$tpa zoctets target protocol address + + Where: + + ar$hrd - assigned to ATM Forum address family and is + 19 decimal (0x0013) [4]. + + ar$pro - see Assigned Numbers for protocol type number for + the protocol using ATMARP. (IP is 0x0800). + + ar$op - The operation type value (decimal): + ARP_REQUEST = 1 + ARP_REPLY = 2 + InARP_REQUEST = 8 + InARP_REPLY = 9 + ARP_NAK = 10 + + ar$spln - length in octets of the source protocol address. For + IP ar$spln is 4. + + ar$tpln - length in octets of the target protocol address. For + IP ar$tpln is 4. + + ar$sha - source ATM number (E.164 or ATM Forum NSAPA) + + ar$ssa - source ATM subaddress (ATM Forum NSAPA) + + ar$spa - source protocol address + + ar$tha - target ATM number (E.164 or ATM Forum NSAPA) + + ar$tsa - target ATM subaddress (ATM Forum NSAPA) + + ar$tpa - target protocol address + + + + + + + + + + + + + + +Laubach [Page 12] + +RFC 1577 Classical IP and ARP over ATM January 1993 + + + The encoding of the 8-bit type and length value for ar$shtl, + ar$sstl, ar$thtl, and ar$tstl is as follows: + + MSB 8 7 6 5 4 3 2 1 LSB + +-----+-----+-----+-----+-----+-----+-----+-----+ + | 0 | 1/0 | Octet length of address | + +-----+-----+-----+-----+-----+-----+-----+-----+ + + Where: + + bit.8 (reserved) = 0 (for future use) + + bit.7 (type) = 0 ATM Forum NSAPA format + = 1 E.164 format + + bit.6-1 (length) = 6 bit unsigned octet length of address + (MSB = bit.6, LSB = bit.1) + + ATM addresses in Q.93B (as defined by the ATM Forum UNI 3.0 + signalling specification [9]) include a "Calling Party Number + Information Element" and a "Calling Party Subaddress Information + Element". These Information Elements (IEs) SHOULD map to + ATMARP/InATMARP source ATM number and source ATM subaddress + respectively. Furthermore, ATM Forum defines a "Called Party Number + Information Element" and a "Called Party Subaddress Information + Element". These IEs map to ATMARP/InATMARP target ATM number and + target ATM subaddress respectively. + + The ATM Forum defines three structures for the combined use of number + and subaddress [9]: + + ATM Number ATM Subaddress + -------------- -------------- + Structure 1 ATM Forum NSAPA null + Structure 2 E.164 null + Structure 3 E.164 ATM Forum NSAPA + + IP members MUST register their ATM endpoint address with their ATMARP + server using the ATM address structure appropriate for their ATM + network connection: i.e., LISs implemented over ATM LANs following + ATM Forum UNI 3.0 should register using Structure 1; LISs implemented + over an E.164 "public" ATM network should register using Structure 2. + A LIS implemented over a combination of ATM LANs and public ATM + networks may need to register using Structure 3. Implementations + based on this memo MUST support all three ATM address structures. + + ATMARP and InATMARP requests and replies for ATM address structures 1 + and 2 MUST indicate a null ATM subaddress; i.e., ar$sstl.type = 1 and + + + +Laubach [Page 13] + +RFC 1577 Classical IP and ARP over ATM January 1993 + + + ar$sstl.length = 0 and ar$tstl.type = 1 and ar$tstl.length = 0. When + ar$sstl.length and ar$tstl.length =0, the ar$tsa and ar$ssa fields + are not present. + + Note: the ATMARP packet format presented in this memo is general in + nature in that the ATM number and ATM subaddress fields SHOULD map + directly to the corresponding Q.93B fields used for ATM + call/connection setup signalling messages. The IP over ATM Working + Group expects ATM Forum NSAPA numbers (Structure 1) to predominate + over E.164 numbers (Structure 2) as ATM endpoint identifiers within + ATM LANs. The ATM Forum's VC Routing specification is not complete + at this time and therefore its impact on the operational use of ATM + Address Structure 3 is undefined. The ATM Forum will be defining this + relationship in the future. It is for this reason that IP members + need to support all three ATM address structures. + +6.7 ATMARP/InATMARP Packet Encapsulation + + ATMARP and InATMARP packets are to be encoded in AAL5 PDUs using + LLC/SNAP encapsulation. The format of the AAL5 CPCS-SDU payload field + for ATMARP/InATMARP PDUs is: + + Payload Format for ATMARP/InATMARP PDUs: + +------------------------------+ + | LLC 0xAA-AA-03 | + +------------------------------+ + | OUI 0x00-00-00 | + +------------------------------+ + | Ethertype 0x08-06 | + +------------------------------+ + | | + | ATMARP/InATMARP Packet | + | | + +------------------------------+ + + The LLC value of 0xAA-AA-03 (3 octets) indicates the presence of a + SNAP header. + + The OUI value of 0x00-00-00 (3 octets) indicates that the following + two-bytes is an ethertype. + + The Ethertype value of 0x08-06 (2 octets) indicates ARP [4]. + + The total size of the LLC/SNAP header is fixed at 8-octets. This + aligns the start of the ATMARP packet on a 64-bit boundary relative + to the start of the AAL5 CPCS-SDU. + + + + + +Laubach [Page 14] + +RFC 1577 Classical IP and ARP over ATM January 1993 + + + The LLC/SNAP encapsulation for ATMARP/InATMARP presented here is + consistent with the treatment of multiprotocol encapsulation of IP + over ATM AAL5 as specified in [2] and in the format of ATMARP over + IEEE 802 networks as specified in [5]. + + Traditionally, address resolution requests are broadcast to all + directly connected IP members within a LIS. It is conceivable in the + future that larger scaled ATM networks may handle ATMARP requests to + destinations outside the originating LIS, perhaps even globally; + issues raised by ATMARP'ing outside the LIS or by a global ATMARP + mechanism are beyond the scope of this memo. + +7. IP Broadcast Address + + ATM does not support broadcast addressing, therefore there are no + mappings available from IP broadcast addresses to ATM broadcast + services. Note: this lack of mapping does not restrict members from + transmitting or receiving IP datagrams specifying any of the four + standard IP broadcast address forms as described in [8]. Members, + upon receiving an IP broadcast or IP subnet broadcast for their LIS, + MUST process the packet as if addressed to that station. + +8. IP Multicast Address + + ATM does not support multicast address services, therefore there are + no mappings available from IP multicast addresses to ATM multicast + services. Current IP multicast implementations (i.e., MBONE and IP + tunneling, see [10]) will continue to operate over ATM based logical + IP subnets if operated in the WAN configuration. + + This memo recognizes the future development of ATM multicast service + addressing by the ATM Forum. When available and widely implemented, + the roll-over from the current IP multicast architecture to this new + ATM architecture will be straightforward. + +9. Security + + Not all of the security issues relating to IP over ATM are clearly + understood at this time, due to the fluid state of ATM + specifications, newness of the technology, and other factors. + + It is believed that ATM and IP facilities for authenticated call + management, authenticated end-to-end communications, and data + encryption will be needed in globally connected ATM networks. Such + future security facilities and their use by IP networks are beyond + the scope of this memo. + + + + + +Laubach [Page 15] + +RFC 1577 Classical IP and ARP over ATM January 1993 + + + There are known security issues relating to host impersonation via + the address resolution protocols used in the Internet [13]. No + special security mechanisms have been added to the address resolution + mechanism defined here for use with networks using IP over ATM. + +10. Open Issues + + o Interim Local Management Interface (ILMI) services will not be + generally implemented initially by some providers and vendors and + will not be used to obtain the ATM address network prefix from + the network [9]. Meta-signalling does provide some of this + functionality and in the future we need to document the options. + + o Well known ATM address(es) for ATMARP servers? It would be very + handy if a mechanism were available for determining the "well + known" ATM address(es) for the client's ATMARP server in the LIS. + + o There are many VC management issues which have not yet been + addressed by this specification and which await the unwary + implementor. For example, one problem that has not yet been + resolved is how two IP members decide which of duplicate VCs can + be released without causing VC thrashing. If two IP stations + simultaneously established VCs to each other, it is tempting to + allow only one of these VCs to be established, or to release one + of these VCs immediately after it is established. If both IP + stations simultaneously decide to release opposite VCs, a + thrashing effect can be created where VCs are repeatedly + established and immediately released. For the time being, the + safest strategy is to allow duplicate VCs to be established and + simply age them like any other VCs. + +References + + [1] Piscitello, D., and J. Lawrence, "IP and ARP over the SMDS + Service", RFC 1209, Bell Communications Research, March 1991. + + [2] Heinanen, J., "Multiprotocol Encapsulation over ATM Adaptation + Layer 5", RFC 1483, Telecom Finland, July 1993. + + [3] Plummer, D., "An Ethernet Address Resolution Protocol - or - + Converting Network Addresses to 48.bit Ethernet Address for + Transmission on Ethernet Hardware", STD 37, RFC 826, MIT, + November 1982. + + [4] Reynolds, J., and J. Postel, "Assigned Numbers", STD 2, RFC 1340, + USC/Information Sciences Institute, July 1992. + + + + + +Laubach [Page 16] + +RFC 1577 Classical IP and ARP over ATM January 1993 + + + [5] Postel, J., and J. Reynolds, "A Standard for the Transmission of + IP Datagrams over IEEE 802 Networks", STD 43, 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", STD 3, RFC 1122, USC/Information Sciences Institute, + October 1989. + + [9] ATM Forum, "ATM User-Network Interface Specification Version + 3.0.", ATM Forum, 480 San Antonio Road, Suite 100, Mountain View, + CA 94040, June 1993. + + [10] Deering, S., "Host Extensions for IP Multicasting", STD 5, RFC + 1112, Stanford University, August 1989. + + [11] Colella, R., and Gardner, E., and R. Callon, "Guidelines for OSI + NSAP Allocation in the Internet", RFC 1237, NIST, Mitre, DEC, + July 1991. + + [12] Bradely, T., and C. Brown, "Inverse Address Resolution Protocol", + RFC 1293, Wellfleet Communications, Inc., January 1992. + + [13] Bellovin, S., "Security Problems in the TCP/IP Protocol Suite", + ACM Computer Communications Review, Vol. 19, Issue 2, pp. 32-48, + 1989. + +Security Considerations + + Security issues are discussed in Section 9. + +Author's Address + + Mark Laubach + Hewlett-Packard Laboratories + 1501 Page Mill Road + Palo Alto, CA 94304 + + Phone: 415-857-3513 + Fax: 415-857-8526 + EMail: laubach@hpl.hp.com + + + + + +Laubach [Page 17] + \ No newline at end of file -- cgit v1.2.3