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/rfc1195.txt | 4763 +++++++++++++++++++++++++++++++++++++++++++++++++++ 1 file changed, 4763 insertions(+) create mode 100644 doc/rfc/rfc1195.txt (limited to 'doc/rfc/rfc1195.txt') diff --git a/doc/rfc/rfc1195.txt b/doc/rfc/rfc1195.txt new file mode 100644 index 0000000..2a1fb11 --- /dev/null +++ b/doc/rfc/rfc1195.txt @@ -0,0 +1,4763 @@ + + + + + + +Network Working Working Group R. Callon +Request for Comments: 1195 Digital Equipment Corporation + December 1990 + + + Use of OSI IS-IS for Routing in TCP/IP and Dual Environments + +Status of this Memo + + This RFC specifies a protocol on the IAB Standards Track for the + Internet community, and requests discussion and suggestions for + improvements. Please refer to the current edition of the "IAB + Official Protocol Standards" for the standardization state and status + of this protocol. Distribution of this memo is unlimited. + + This RFC is available in both postscript and text versions. Where + possible, use of the postscript version is recommended. For example, + this text version may have figures which are less informative or + missing. + +Abstract + + This RFC specifies an integrated routing protocol, based on the OSI + Intra-Domain IS-IS Routing Protocol, which may be used as an interior + gateway protocol (IGP) to support TCP/IP as well as OSI. This allows + a single routing protocol to be used to support pure IP environments, + pure OSI environments, and dual environments. This specification was + developed by the IS-IS working group of the Internet Engineering Task + Force. + + The OSI IS-IS protocol has reached a mature state, and is ready for + implementation and operational use. The most recent version of the + OSI IS-IS protocol is contained in ISO DP 10589 [1]. The proposed + standard for using IS-IS for support of TCP/IP will therefore make + use of this version (with a minor bug correction, as discussed in + Annex B). We expect that future versions of this proposed standard + will upgrade to the final International Standard version of IS-IS + when available. + + Comments should be sent to "isis@merit.edu". + +Contents + + 1 Introduction: Overview of the Protocol + 1.1 What the Integrated IS-IS offers + 1.2 Overview of the ISO IS-IS Protocol + 1.3 Overview of the Integrated IS-IS + 1.4 Support of Mixed Routing Domains + + + +Callon [Page 1] + +RFC 1195 OSI ISIS for IP and Dual Environments December 1990 + + + 1.5 Advantages of Using Integrated IS-IS + + 2 Symbols and Abbreviations + + 3 Subnetwork Independent Functions + 3.1 Exchange of Routing Information + 3.2 Hierarchical Abbreviation of IP Reachability Information + 3.3 Addressing Routers in IS-IS Packets + 3.4 External Links + 3.5 Type of Service Routing + 3.6 Multiple LSPs and SNPs + 3.7 IP-Only Operation + 3.8 Encapsulation + 3.9 Authentication + 3.10 Order of Preference of Routes / Dijkstra Computation + + 4 Subnetwork Dependent Functions + 4.1 Link Demultiplexing + 4.2 Multiple IP Addresses per Interface + 4.3 LANs, Designated Routers, and Pseudonodes + 4.4 Maintaining Router Adjacencies + 4.5 Forwarding to Incompatible Routers + + 5 Structure and Encoding of PDUs + 5.1 Overview of IS-IS PDUs + 5.2 Overview of IP-Specific Information for IS-IS + 5.3 Encoding of IP-Specific Fields in IS-IS PDUs + + 6 Security Considerations + + 7 Author's Address + + 8 References + + A Inter-Domain Routing Protocol Information + A.1 Inter-Domain Information Type + A.2 Encoding + + B Encoding of Sequence Number Packets + B.1 Level 1 Complete Sequence Numbers PDU + B.2 Level 2 Complete Sequence Numbers PDU + B.3 Level 1 Partial Sequence Numbers PDU + B.4 Level 2 Partial Sequence Numbers PDU + + C Dijkstra Calculation and Forwarding + C.1 SPF Algorithm for IP and Dual Use + C.2 Forwarding of IP packets + + + + +Callon [Page 2] + +RFC 1195 OSI ISIS for IP and Dual Environments December 1990 + + + D Use of the Authentication Field + D.1 Authentication Field in IS-IS packets + D.2 Authentication Type 1 - Simple Password + + E Interaction of the Integrated IS-IS with Brouters + E.1 The Problem + E.2 Possible Solutions + +Figures + 1 ISO Hierarchical Address Structure + 2 An Example + 3 Encoding of Variable Length Fields + +1 Introduction: Overview of the Protocol + + The TCP/IP protocol suite has been growing in importance as a multi- + vendor communications architecture. With the anticipated emergence of + OSI, we expect coexistence of TCP/IP and OSI to continue for an + extended period of time. There is a critical need for routers to + support both IP traffic and OSI traffic in parallel. + + There are two main methods that are available for routing protocols + to support dual OSI and IP routers. One method, known as "Ships in + the Night", makes use of completely independent routing protocols for + each of the two protocol suites. This specification presents an + alternate approach, which makes use of a single integrated protocol + for interior routing (i.e., for calculating routes within a routing + domain) for both protocol suites. + + This integrated protocol design is based on the OSI Intra-domain IS- + IS routing protocol [1], with IP-specific functions added. This RFC + is considered a companion to the OSI IS-IS Routing spec, and will + only describe the required additional features. + + By supporting both IP and OSI traffic, this integrated protocol + design supports traffic to IP hosts, OSI end systems, and dual end + systems. This approach is "integrated" in the sense that the IS-IS + protocol can be used to support pure-IP environments, pure-OSI + environments, and dual environments. In addition, this approach + allows interconnection of dual (IP and OSI) routing domains with + other dual domains, with IP-only domains, and with OSI-only domains. + + The protocol specified here is based on the work of the IETF IS-IS + working group. + +1.1 What the Integrated IS-IS offers + + The integrated IS-IS provides a single routing protocol which will + + + +Callon [Page 3] + +RFC 1195 OSI ISIS for IP and Dual Environments December 1990 + + + simultaneously provide an efficient routing protocol for TCP/IP, and + for OSI. This design makes use of the OSI IS-IS routing protocol, + augmented with IP-specific information. This design provides explicit + support for IP subnetting, variable subnet masks, TOS-based routing, + and external routing. There is provision for authentication + information, including the use of passwords or other mechanisms. The + precise form of authentication mechanisms (other than passwords) is + outside of the scope of this document. + + Both OSI and IP packets are forwarded "as is" -- i.e., they are + transmitted directly over the underlying link layer services without + the need for mutual encapsulation. The integrated IS-IS is a dynamic + routing protocol, based on the SPF (Dijkstra) routing algorithm. + + The protocol described in this specification allows for mixing of + IP-only, OSI-only, and dual (IP and OSI) routers, as defined below. + + An IP-only IS-IS router (or "IP-only" router) is defined to be a + router which: (i) Uses IS-IS as the routing protocol for IP, as + specified in this report; and (ii) Does not otherwise support OSI + protocols. For example, such routers would not be able to forward OSI + CLNP packets. + + An OSI-only router is defined to be a router which uses IS-IS as the + routing protocol for OSI, as specified in [1]. Generally, OSI-only + routers may be expected to conform to OSI standards, and may be + implemented independent of this specification. + + A dual IS-IS router (or "dual" router) is defined to be a router + which uses IS-IS as a single integrated routing protocol for both IP + and OSI, as specified in this report. + + This approach does not change the way that IP packets are handled. + IP-only and dual routers are required to conform to the requirements + of Internet Gateways [4]. The integrated IS-IS protocol described in + this report outlines an Interior Gateway Protocol (IGP) which will + provide routing within a TCP/IP routing domain (i.e., autonomous + system). Other aspects of router functionality (e.g., operation of + ICMP, ARP, EGP, etc.) are not affected by this proposal. + + Similarly, this approach does not change the way that OSI packets are + handled. There will be no change at all to the contents nor to the + handling of ISO 8473 Data packets and Error Reports, nor to ISO 9542 + Redirects and ES Hellos. ISO 9542 IS Hellos transmitted on LANs are + similarly unchanged. ISO 9542 IS Hellos transmitted on point-to-point + links are unchanged except for the addition of IP-related + information. Similarly, other OSI packets (specifically those + involved in the IS-IS intra-domain routing protocol) remain unchanged + + + +Callon [Page 4] + +RFC 1195 OSI ISIS for IP and Dual Environments December 1990 + + + except for the addition of IP-related information. + + This approach makes use of the existing IS-IS packets, with IP- + specific fields added. Specifically: (i) authentication information + may be added to all IS-IS packets; (ii) the protocols supported by + each router, as well as each router's IP addresses, are specified in + ISO 9542 IS Hello, IS-IS Hello and Link State Packets; (iii) + internally reachable IP addresses are specified in all Link State + Packets; and (iv) externally reachable IP addresses, and external + routing protocol information, may be specified in level 2 Link State + Packets. The detailed encoding and interpretation of this in + formation is specified in sections 3, 4, and 5 of this RFC. + + The protocol described in this report may be used to provide routing + in an IP-only routing domain, in which all routers are IP-only. + Similarly, this protocol may be used to provide routing in a pure + dual domain, in which all routers are dual. Finally, this protocol + may be used to provide routing in a mixed domain, in which some + routers are IP-only, some routers are OSI-only, and some routers are + dual. The specific topological restrictions which apply in this + latter case are described in detail in section 1.4 ("Support of Mixed + Routing Domains"). The use of IS-IS for support of pure OSI domains + is specified in [1]. + + This protocol specification does not constrain which network + management protocol(s) may be used to manage IS-IS-based routers. + Management information bases (MIBs) for managing IP-only, OSI-only, + and dual routers, compatible with CMIP, CMOT, and/or SNMP, are the + subject of a separate, companion document [8]. + +1.2 Overview of the ISO IS-IS Protocol + + The IS-IS Routing Protocol has been developed in ISO to provide + routing for pure OSI environments. In particular, IS-IS is designed + to work in conjunction with ISO 8473 (The ISO Connectionless Network + Layer Protocol [2]), and ISO 9542 (The ISO End System to Intermediate + System Protocol [3]). This section briefly describes the manner in + which IS-IS is used to support pure OSI environments. Enhancements + for support of IP and dual environments are specified elsewhere in + this report. + + In IS-IS, the network is partitioned into "routing domains". The + boundaries of routing domains are defined by network management, by + setting some links to be "exterior links". If a link is marked as + "exterior", no IS-IS routing messages are sent on that link. + + Currently, ISO does not have a standard for inter-domain routing + (i.e., for routing between separate autonomous routing domains). + + + +Callon [Page 5] + +RFC 1195 OSI ISIS for IP and Dual Environments December 1990 + + + Instead, manual configuration is used. The link is statically + configured with the set of address prefixes reachable via that link, + and with the method by which they can be reached (such as the DTE + address to be dialed to reach that address, or the fact that the DTE + address should be extracted from the IDP portion of the ISO address). + + OSI IS-IS routing makes use of two-level hierarchical routing. A + routing domain is partitioned into areas. Level 1 routers know the + topology in their area, including all routers and end systems in + their area. However, level 1 routers do not know the identity of + routers or destinations outside of their area. Level 1 routers + forward all traffic for destinations outside of their area to a level + 2 router in their area. Similarly, level 2 routers know the level 2 + topology, and know which addresses are reachable via each level 2 + router. However, level 2 routers do not need to know the topology + within any level 1 area, except to the extent that a level 2 router + may also be a level 1 router within a single area. Only level 2 + routers can exchange data packets or routing information directly + with external routers located outside of the routing domains. + + +----------------------+-------------------------------+ + | IDP | DSP | + +----------------------+-------------------------------+ + . . . + . . . + . . . + +-----+----------------+----------+--------------+-----+ + | AFI | IDI | HO-DSP | ID | SEL | + +-----+----------------+----------+--------------+-----+ + + Figure 1 - ISO Hierarchical Address Structure + + + As illustrated in figure 1, ISO addresses are subdivided into the + Initial Domain Part (IDP), and the Domain Specific Part (DSP). The + IDP is the part which is standardized by ISO, and specifies the + format and authority responsible for assigning the rest of the + address. The DSP is assigned by whatever addressing authority is + specified by the IDP. The DSP is further subdivided into a "High + Order Part of DSP" (HO-DSP), a system identifier (ID), and an NSAP + selector (SEL). The HO-DSP may use any format desired by the + authority which is identified by the IDP. Together, the combination + of [IDP, HO-DSP] identify both the routing domain and the area within + the routing domain. The combination of [IDP,HO-DSP] may therefore be + referred to as the "Area Address". + + Usually, all nodes in an area have the same area address. However, + sometimes an area might have multiple addresses. Motivations for + + + +Callon [Page 6] + +RFC 1195 OSI ISIS for IP and Dual Environments December 1990 + + + allowing this are: + + - It might be desirable to change the address of an area. The most + graceful way of changing an area from having address A to having + address B is to first allow it to have both addresses A and B, and + then after all nodes in the area have been modified to recognize + both addresses, then one by one the nodes can be modified to + "forget" address A. + + - It might be desirable to merge areas A and B into one area. The + method for accomplishing this is to, one by one, add knowledge of + address B into the A partition, and similarly add knowledge of + address A into the B partition. + + - It might be desirable to partition an area C into two areas, A + and B (where "A" might equal "C", in which case this example + becomes one of removing a portion of an area). This would be + accomplished by first introducing knowledge of address A into + the appropriate nodes (those destined to become area A), and + knowledge of address B into the appropriate nodes, and then one + by one removing knowledge of address C. + + Since OSI addressing explicitly identifies the area, it is very easy + for level 1 routers to identify packets going to destinations outside + of their area, which need to be forwarded to level 2 routers. + + In IS-IS, there are two types of routers: + + - Level 1 intermediate systems -- these nodes route based on the ID + portion of the ISO address. They route within an area. They + recognize, based on the destination address in a packet, whether + the destination is within the area. If so, they route towards + the destination. If not, they route to the nearest level 2 router. + + - Level 2 intermediate systems -- these nodes route based on the area + address (i.e., on the combination of [IDP, HO-DSP]). They route + towards areas, without regard to the internal structure of an area. + A level 2 IS may also be a level 1 IS in one area. + + A level 1 router will have the area portion of its address manually + configured. It will refuse to become a neighbor with a node whose + area addresses do not overlap its area addresses. However, if level 1 + router has area addresses A, B, and C, and a neighbor has area + addresses B and D, then the level 1 router will accept the other node + as a neighbor. + + A level 2 router will accept another level 2 router as a neighbor, + regardless of area address. However, if the area addresses do not + + + +Callon [Page 7] + +RFC 1195 OSI ISIS for IP and Dual Environments December 1990 + + + overlap, the link would be considered by both routers to be "level 2 + only", and only level 2 LSPs would flow on the link. External links + (to other routing domains) must be from level 2 routers. + + IS-IS provides an optional partition repair function. In the unlikely + case that a level 1 area become partitioned, this function, if + implemented, allows the partition to be repaired via use of level 2 + routes. + + IS-IS requires that the set of level 2 routers be connected. Should + the level 2 backbone become partitioned, there is no provision for + use of level 1 links to repair a level 2 partition. + + In unusual cases, a single level 2 router may lose connectivity to + the level 2 backbone. In this case the level 2 router will indicate + in its level 1 LSPs that it is not "attached", thereby allowing level + 1 routers in the area to route traffic for outside of the domain to a + different level 2 router. Level 1 routers therefore route traffic to + destinations outside of their area only to level 2 routers which + indicate in their level 1 LSPs that they are "attached". + + An end system may autoconfigure the area portion of its address by + extracting the area portion of a neighboring router's address. If + this is the case, then an endnode will always accept a router as a + neighbor. Since the standard does not specify that the end system + MUST autoconfigure its area address, an end system may be configured + with an area address. In this case the end system would ignore router + neighbors with non-matching area addresses. + + Special treatment is necessary for broadcast subnetworks, such as + LANs. This solves two sets of issues: (i) In the absence of special + treatment, each router on the subnetwork would announce a link to + every other router on the subnetwork, resulting in n-squared links + reported; (ii) Again, in the absence of special treatment, each + router on the LAN would report the same identical list of end systems + on the LAN, resulting in substantial duplication. + + These problems are avoided by use of a "pseudonode", which represents + the LAN. Each router on the LAN reports that it has a link to the + pseudonode (rather than reporting a link to every other router on the + LAN). One of the routers on the LAN is elected "designated router". + The designated router then sends out an LSP on behalf of the + pseudonode, reporting links to all of the routers on the LAN. This + reduces the potential n-squared links to n links. In addition, only + the pseudonode LSP includes the list of end systems on the LAN, + thereby eliminating the potential duplication (for further + information on designated routers and pseudonodes, see [1]). + + + + +Callon [Page 8] + +RFC 1195 OSI ISIS for IP and Dual Environments December 1990 + + + The IS-IS provides for optional Quality of Service (QOS) routing, + based on throughput (the default metric), delay, expense, or residual + error probability. This is described in greater detail in section + 3.5, and in [1]. + +1.3 Overview of the Integrated IS-IS + + The integrated IS-IS allows a single routing protocol to be used to + route both IP and OSI packets. This implies that the same two-level + hierarchy will be used for both IP and OSI routing. Each area will be + specified to be either IP-only (only IP traffic can be routed in that + particular area), OSI-only (only OSI traffic can be routed in that + area), or dual (both IP and OSI traffic can be routed in the area). + + This proposal does not allow for partial overlap of OSI and IP areas. + For example, if one area is OSI-only, and an other area is IP-only, + then it is not permissible to have some routers be in both areas. + Similarly, a single backbone is used for the routing domain. There is + no provision for independent OSI and IP backbones. + + Similarly, within an IP-only or dual area, the amount of knowledge + maintained by routers about specific IP destinations will be as + similar as possible as for OSI. For example, IP-capable level 1 + routers will maintain the topology within the area, and will be able + to route directly to IP destinations within the area. However, IP- + capable level 1 routers will not maintain information about + destinations outside of the area. Just as in normal OSI routing, + traffic to destinations outside of the area will be forwarded to the + nearest level 2 router. Since IP routes to subnets, rather than to + specific end systems, IP routers will not need to keep nor distribute + lists of IP host identifiers (note that routes to hosts can be + announced by using a subnet mask of all ones). + + The IP address structure allows networks to be partitioned into + subnets, and allows subnets to be recursively subdivided into smaller + subnets. However, it is undesireable to require any specific + relationship between IP subnet addresses and IS-IS areas. For + example, in many cases, the dual routers may be installed into + existing environments, which already have assigned IP and/or OSI + addresses. In addition, even if IP addresses are not already pre- + assigned, the address limitations of IP constrain what addresses may + be assigned. We therefore will not require any specific relationship + between IP addresses and the area structure. The IP addresses can be + assigned completely independently of the OSI addresses and IS-IS area + structure. As will be described in section 3.2 ("Hierarchical + Abbreviation of IP Reachability Information"), greater efficiency and + scaling of the routing algorithm can be achieved if there is some + correspondence between the IP address assignment structure and the + + + +Callon [Page 9] + +RFC 1195 OSI ISIS for IP and Dual Environments December 1990 + + + area structure. + + Within an area, level 1 routers exchange link state packets which + identify the IP addresses reachable by each router. Specifically, + zero or more [IP address, subnet mask, metric] combinations may be + included in each Link State Packet. Each level 1 router is manually + configured with the [IP address, subnet mask, metric] combinations + which are reachable on each interface. A level 1 router routes as + follows: + + - If a specified destination address matches an [IP address, subnet + mask, metric] reachable within the area, the packet is routed via + level 1 routing. + + - If a specified destination address does not match any [IP address, + subnet mask, metric] combination listed as reachable within the + area, the packet is routed towards the nearest level 2 router. + + Flexible use of the limited IP address space is important in order to + cope with the anticipated growth of IP environments. Thus an area + (and by implication a routing domain) may simultaneously make use of + a variety of different address masks for different subnets in the + area (or domain). Generally, if a specified destination address + matches more than one [IP address, subnet mask] pair, the more + specific address is the one routed towards (the one with more "1" + bits in the mask -- this is known as "best match" routing). + + Level 2 routers include in their level 2 LSPs a complete list of [IP + address, subnet mask, metric] specifying all IP addresses reachable + in their area. As described in section 3, this information may be + obtained from a combination of the level 1 LSPs (obtained from level + 1 routers in the same area), and/or by manual configuration. In + addition, Level 2 routers may report external reachability + information, corresponding to addresses which can be reached via + routers in other routing domains (autonomous systems) + + Default routes may be announced by use of a subnet mask containing + all zeroes. Default routes should be used with great care, since they + can result in "black holes". Default routes are permitted only at + level 2 as external routes (i.e., included in the "IP External + Reachability Information" field, as explained in sections 3 and 5). + Default routes are not permitted at level 1. + + The integrated IS-IS provides optional Type of Service (TOS) routing, + through use of the QOS feature from IS-IS. + + + + + + +Callon [Page 10] + +RFC 1195 OSI ISIS for IP and Dual Environments December 1990 + + +1.4 Support of Mixed Routing Domains + + The integrated IS-IS proposal specifically allows for three types of + routing domains: + + - Pure IP + + - Pure OSI + + - Dual + + In a pure IP routing domain, all routers must be IP-capable. IP-only + routers may be freely mixed with dual routers. Some fields + specifically related to OSI operation may be included by dual + routers, and will be ignored by IP-only routers. Only IP traffic will + be routed in an pure IP domain. Any OSI traffic may be discarded + (except for the IS-IS packets necessary for operation of the routing + protocol). + + In a pure OSI routing domain, all routers must be OSI-capable. OSI- + only routers may be freely mixed with dual routers. Some fields + specifically related to IP operation may be included by dual routers, + and will be ignored by OSI-only routers. Only OSI traffic will be + routed in a pure OSI domain. Any IP traffic may be discarded. + + In a dual routing domain, IP-only, OSI-only, and dual routers may be + mixed on a per-area basis. Specifically, each area may itself be + defined to be pure IP, pure OSI, or dual. + + In a pure IP area within a dual domain, IP-only and dual routers may + be freely mixed. Only IP traffic can be routed by level 1 routing + within a pure-IP area. + + In a pure-OSI area within a dual domain, OSI-only and dual routers + may be freely mixed. Only OSI traffic can be routed by level 1 + routing within a pure OSI area. + + In a dual area within a dual routing domain only dual routers may be + used. Both IP and OSI traffic can be routed within a dual area. + + Within a dual domain, if both IP and OSI traffic are to be routed + between areas then all level 2 routers must be dual. + +1.5 Advantages of Using Integrated IS-IS + + Use of the integrated IS-IS protocol, as a single protocol for + routing both IP and OSI packets in a dual environment, has + significant advantages over using separate protocols for + + + +Callon [Page 11] + +RFC 1195 OSI ISIS for IP and Dual Environments December 1990 + + + independently routing IP and OSI traffic. + + An alternative approach is known as "Ships In the Night" (S.I.N.). + With the S.I.N. approach, completely separate routing protocols are + used for IP and for OSI. For example, OSPF [5] may be used for + routing IP traffic, and IS-IS [1] may be used for routing OSI + traffic. With S.I.N., the two routing protocols operate more or less + independently. However, dual routers will need to implement both + routing protocols, and therefore there will be some degree of + competition for resources. + + Note that S.I.N. and the integrated IS-IS approach are not really + completely separate options. In particular, if the integrated IS-IS + is used within a routing domain for routing of IP and OSI traffic, it + is still possible to use other independent routing protocols for + routing other protocol suites. + + In the future, optional extensions to IS-IS may be defined for + routing other common protocol suites. However, such future options + are outside of the scope of this document. This section will compare + integrated IS-IS and S.I.N. for routing of IP and OSI only. + + A primary advantage of the integrated IS-IS relates to the network + management effort required. Since the integrated IS-IS provides a + single routing protocol, within a single coordinated routing domain + using a single backbone, this implies that there is less information + to configure. This combined with a single coordinated MIB simplifies + network management. + + Note that the operation of two routing protocols with the S.I.N. + approach are not really independent, since they must share common + resources. However, with the integrated IS-IS, the interactions are + explicit, whereas with S.I.N., the interactions are implicit. Since + the interactions are explicit, again it may be easier to manage and + debug dual routers. + + Another advantage of the integrated IS-IS is that, since it requires + only one routing protocol, it uses fewer resources. In particular, + less implementation resources are needed (since only one protocol + needs to be implemented), less CPU and memory resources are used in + the router (since only one protocol needs to be run), and less + network resources are used (since only one set of routing packets + need to be transmitted). Primarily this translates into a financial + savings, since each of these three types of resources cost money. + This implies that dual routers based on the integrated IS-IS should + be less expensive to purchase and operate than dual routers based on + S.I.N. + + + + +Callon [Page 12] + +RFC 1195 OSI ISIS for IP and Dual Environments December 1990 + + + Note that the operation of two routing protocols with the S.I.N. + approach are not really independent, since they must share common + resources. For example, if one routing protocol becomes unstable and + starts to use excessive resources, the other protocol is likely to + suffer. A bug in one protocol could crash the other. However, with + the integrated IS-IS, the interactions are explicit and are defined + into the protocol and software interactions. With S.I.N., the + interactions are implicit. + + The use of a single integrated routing protocol similarly reduces the + likely frequency of software upgrades. Specifically, if you have two + different routing protocols in your router, then you have to upgrade + the software any time EITHER of the protocols change. If you make use + of a single integrated routing protocol, then software changes are + still likely to be needed, but less frequently. + + Finally, routing protocols have significant real time requirements. + In IS-IS, these real time requirements have been explicitly + specified. In other routing protocols, these requirements are + implicit. However, in all routing protocols, there are real time + guarantees which must be met in order to ensure correct operation. In + general, it is difficult enough to ensure compliance with real time + requirements in the implementation of a single real time system. With + S.I.N., implementation of two semi-independent real-time protocols in + a single device makes this more difficult. + + Note that both integrated IS-IS and S.I.N. allow for independence of + external routes (for traffic from/to outside of the routing domain), + and allow for independent assignment of OSI and TCP/IP addresses. + +2 Symbols and Abbreviations + +AA Administrative Authority + (a three octet field in the GOSIP version 2.0 NSAP + address format) + +AFI Authority and Format Identifier + (the first octet of all OSI NSAP addresses -- identifies + format of the rest of the address) + +CLNP Connection-Less Network Protocol + (ISO 8473, the OSI connectionless network layer protocol + -- very similar to IP) + +DFI DSP Format Identifier + (a one octet field in the GOSIP version 2.0 NSAP address + format) + + + + +Callon [Page 13] + +RFC 1195 OSI ISIS for IP and Dual Environments December 1990 + + +ES End System + (The OSI term for a host) + +ES-IS End System to Intermediate System Routeing Exchange + Protocol (ISO 9542 -- OSI protocol between routers + and end systems) + +ICD International Code Designator + (ISO standard for identifying organizations) + +IP Internetwork Protocol + (an Internet Standard Network Layer Protocol) + +IS Intermediate System + (The OSI term for a router) + +IS-IS Intermediate System to Intermediate System Routeing + Exchange Protocol + (the ISO protocol for routing within a single + routing domain) + +IS-IS Hello An Hello packet defined by the IS-IS protocol + (a type of packet used by the IS-IS protocol) + +ISH An Hello packet defined by ISO 9542 (ES-IS protocol). + (not the same as IS-IS Hello) + +ISO International Organization for Standardization + (an international body which is authorized to write + standards of many kinds) + +LSP Link State Packet + (a type of packet used by the IS-IS protocol) + +NLPID Network Layer Protocol ID + (A one-octet field identifying a network layer protocol) + +NSAP Network Service Access Point + (a conceptual interface point at which the network + service is made available) + +SEL NSAP Selector + (the last octet of NSAP addresses, also called NSEL) + +OSI Open Systems Interconnection + (an international standard protocol architecture) + + + + + +Callon [Page 14] + +RFC 1195 OSI ISIS for IP and Dual Environments December 1990 + + +RD Routing Domain + (the set of routers and end systems using a single + instance of a routing protocol such as IS-IS) + +SNPA Subnetwork Point of Attachment + (a conceptual interface at which a subnetwork service + is provided) + +TCP Transmission Control Protocol + (an Internet Standard Transport Layer Protocol) + +TCP/IP The protocol suite based on TCP, IP, and related + protocols (the Internet standard protocol + architecture) + +3 Subnetwork Independent Functions + +3.1 Exchange of Routing Information + + The exchange of routing information between routers makes use of the + normal routing packet exchange as defined in the OSI IS-IS routing + spec, with additional IP-specific information added to the IS-IS + routing packets. + + The IS-IS protocol provides for the inclusion of variable length + fields in all IS-IS packets. These fields are encoded using a "Code, + Length, Value" triplet, where the code and length are encoded in one + octet each, and the value has the length specified (from 0 to 254 + octets). IS-IS requires that: "Any codes in a received PDU that are + not recognised are ignored and passed through unchanged". This + requirement applies to all routers implementing IS-IS, including + OSI-only, IP-only, and dual routers. This allows IP-specific + information to be encoded in a manner which OSI-only routers will + ignore, and also allows OSI-specific information to be encoded in a + manner which IP-only routers will ignore. + + IP-capable (i.e., all IP-only and dual) routers need to know what + network layer protocols are supported by other routers in their area. + This information is made available by inclusion of a "protocols + supported" field in all IS-IS Hello and Link State Packets. This + field makes use of the NLPID (Network Layer Protocol Identifier), + which is a one-octet value assigned by ISO to identify network level + protocols. NLPID values have been assigned to ISO 8473 and to IP. + + IP-capable routers need to know the IP address of the adjacent + interface of neighboring routers. This is required for sending ICMP + redirects (when an IP-capable router sends an ICMP redirect to a + host, it must include the IP address of the appropriate interface of + + + +Callon [Page 15] + +RFC 1195 OSI ISIS for IP and Dual Environments December 1990 + + + the correct next-hop router). This information is made available by + inclusion of the IP interface address in the IS-IS Hello packets. + Specifically, each IS-IS Hello packet contains the IP address(es) of + the interface over which the Hello is transmitted. The IS-IS allows + multiple IP addresses to be assigned to each physical interface. + + In some cases, it will be useful for IP-capable routers to be able to + determine an IP address(es) of all other routers at their level + (i.e., for level 1 routers: all other routers in their area; for + level 2 routers: all other level 2 routers in the routing domain). + This is useful whenever an IP packet is to be sent to a router, such + as for encapsulation or for transmission of network management + packets. This information is made available by inclusion of IP + address in LSPs. Specifically, each IS-IS LSP includes one or more IP + addresses of the router which transmits the LSP. An IP-capable router + is required to include at least one of its IP addresses in its LSPs, + and may optionally include several or all of its IP addresses. Where + a single router operates as both a level 1 and a level 2 router, it + is required to include the same IP address(es) in its level 1 and + level 2 LSPs. + + IP-capable routers need to know, for any given IP destination + address, the correct route to that destination. Specifically, level 1 + routers need to know what IP addresses are reachable from each level + 1 router in their area. In addition, level 1 routers need to find + level 2 routers (for traffic to IP addresses outside of their area). + Level 2 routers need to know what IP addresses are reachable + internally (either directly, or via level 1 routing) from other level + 2 routers, and what addresses are reachable externally from other + level 2 routers. All of this information is made available by + inclusion of IP reachable address information in the Link State + Packets. + + Internal (within the routing domain) and external (outside the + domain) reachability information is announced separately in level 2 + LSPs. Reachable IP addresses include a default metric, and may + include multiple TOS-specific metrics. In general, for external + routes, metrics may be of type "internal" (i.e., directly comparable + with internal metrics) or of type "external" (i.e., not comparable + with the internal metric). A route using internal metrics (i.e., + either announced as "IP internal reachability information", or + announced as "IP external reachability information" with an internal + metric) is always preferred to a route using external metrics (i.e., + announced as "IP external reachability information", with an external + metric). + + The detailed encoding of the IP-specific information included in + routing packets is provided in section 5 (Structure and Encoding of + + + +Callon [Page 16] + +RFC 1195 OSI ISIS for IP and Dual Environments December 1990 + + + PDUs). + +3.2 Hierarchical Abbreviation of IP Reachability Information + + Level 2 routers include in their level 2 LSPs a list of all [IP + address, subnet mask, metric] combinations reachable in their area. + In general, this information may be determined from the level 1 LSPs + from all routers in the area. If we ignore resource constraints, then + it would be permissible for a level 2 router to simply duplicate all + [IP address, subnet mask, metric] entries from all level 1 routers in + its area (with appropriate metric adjustment), for inclusion in its + level 2 LSP. However, in order for hierarchical routing to scale to + large routing domain sizes, it is highly desired to abbreviate the + reachable address information. + + This is accomplished by manual configuration of summary addresses. + Each level 2 router may be configured with one or more [IP address, + subnet mask, metric] entries for announcement in their level 2 LSPs. + + The set of reachable addresses obtained from level 1 LSPs is compared + with the configured reachable addresses. Redundant information + obtained from level 1 LSPs is not included in level 2 LSPs. Generally + it is expected that the level 2 configured information will specify + more inclusive addresses (corresponding to a subnet mask with fewer + bits set to 1). This will therefore allow one configured + address/submask pair (or a small number of such pairs) to + hierarchically supercede the information corresponding to multiple + entries in level 1 LSPs. + + The manually configured addresses are included in level 2 LSPs only + if they correspond to at least one address which is reachable in the + area. For manually configured level 2 addresses, the associated + metric values to announce in level 2 LSPs are also manually + configured. The configured addresses will supercede reachable address + entries from level 1 LSPs based only on the IP address and subnet + mask -- metric values are not considered when determining if a given + configured address supercedes an address obtained from a level 1 LSP. + + Any address obtained from a level 1 LSP which is not superceded by + the manually configured information is included in the level 2 LSPs. + In this case, the metric value announced in the level 2 LSPs is + calculated from the sum of the metric value announced in the + corresponding level 1 LSP, plus the distance from the level 2 router + to the appropriate level 1 router. Note: If this sum results in a + metric value greater than 63 (the maximum value that can be reported + in level 2 LSPs), then the value 63 must be used. Delay, expense, and + error metrics (i.e., those TOS metrics other than the default metric) + will be included only if (i) the level 2 router supports the specific + + + +Callon [Page 17] + +RFC 1195 OSI ISIS for IP and Dual Environments December 1990 + + + TOS; (ii) the path from the level 2 router to the appropropriate + level 1 router is made up of links which support the specific TOS; + and (iii) the level 1 router which can reach the address directly + also supports the specific TOS for this route, as indicated in its + level 1 LSP. + + In general, the same [IP address, subnet mask] pair may be announced + in level 1 LSPs sent by multiple level 1 routers in the same area. In + this case (assuming the entry is not superceded by a manually + configured entry), then only one such entry shall be included in the + level 2 LSP. The metric value(s) announced in level 2 LSPs correspond + to the minimum of the metric value(s) that would be calculated for + each of the level 1 LSP entries. + + A level 2 router will have IP addresses which are directly reachable + via its own interfaces. For purposes of inclusion of IP reachable + address information in level 2 LSPs, these "directly reachable" + addresses are treated exactly the same as addresses received in level + 1 LSPs. + + Manually configured addresses may hierarchically supercede multiple + level 1 reachable address entries. However, there may be some IP + addresses which match the manually configured addresses, but which + are not reachable via level 1 routing. If a level 2 router receives + an IP packet whose IP address matches a manually configured address + which it is including in its level 2 LSP, but which is not reachable + via level 1 routing in the area, then the packet must be discarded. + In this case, an error report may be returned (as specified in RFC + 1009), with the reason for discard specifying destination + unreachable. + + + + + + + Figure 2 - An Example Routing Domain (not shown) + + An example is illustrated in figure 2. Suppose that the network + number for the entire routing domain is 17 (a class A network). + Suppose each area is assigned a subnet number consisting of the next + 8 bits. The area may be further subdivided by assigning the next + eight bits to each LAN in the area, giving each a 24 bit subnet mask + (counting the network and subnet fields). Finally 8 bits are left for + the host field. Suppose that for a particular area (given subnet + number 17.133) there are a number of IP capable level 1 routers + announcing (in the special IP entry in their level 1 LSPs) subnets + 17.133.5, 17.133.43, and 17.133.57. + + + +Callon [Page 18] + +RFC 1195 OSI ISIS for IP and Dual Environments December 1990 + + + Suppose that in this example, in order to save space in level 2 LSPs, + the level 2 routers in this area are configured to announce subnet + 17.133. Only this one address needs to be announced in level 2 LSPs. + Thus if an IP packet comes along for an address in subnet 17.133.5, + 17.133.43 or 17.133.57, then other level 2 routers, in other areas, + will know to pass the traffic to this area. + + The inclusion of 17.133 in level 2 LSPs means that the three subnet + addresses starting with 17.133 do not all have to be listed + separately in level 2 LSPs. + + If any traffic comes along that is for an unreachable address such as + 17.133.124.7, then level 2 routers in other areas in this particular + domain will think that this area can handle this traffic, will + forward traffic to level 2 routers in this area, which will have to + discard this traffic. + + Suppose that subnet number 17.133.125 was actually reachable via some + other area, such as the lower right hand area. In this case, the + level 2 router in the left area would be announcing (in its level 2 + LSPs according to manually configured information) reachability to + subnet 17.133. However, the level 2 router in the lower right area + would be announcing (in its level 2 LSPs according to information + taken from its received level 1 LSPs), reachability to subnet + 17.133.125. Due to the use of best match routing, this works + correctly. All traffic from other areas destined to subnet 17.133.125 + would be sent to the level 2 router in the lower right area, and all + other traffic to subnet 17.133 (i.e., traffic to any IP address + starting with 17.133, but not starting with 17.133.125) would be sent + to the level 2 router in the leftmost area. + +3.3 Addressing Routers in IS-IS Packets + + The IS-IS packet formats explicitly require that OSI-style addresses + of routers appear in the IS-IS packets. For example, these addresses + are used to determine area membership of routers. It is therefore + necessary for all routers making use of the IS-IS protocol to have + OSI style addresses assigned. For IP-only routers, these addresses + will be used only in the operation of the IS-IS protocol, and are not + used for any other purpose (such as the operation of EGP, ICMP, or + other TCP/IP protocols). + + For OSI-only and dual routers, assignment of NSAP addresses is + straight forward, but is outside of the scope of this specification. + Address assignment mechanisms are being set up by standards bodies + which allow globally unique OSI NSAP addresses to be assigned. All + OSI-only and dual routers may therefore make use of normal OSI + addresses in the operation of the IS-IS protocol. + + + +Callon [Page 19] + +RFC 1195 OSI ISIS for IP and Dual Environments December 1990 + + + For IP-only routers, there are two ways in which NSAP addresses may + be obtained for use with the IS-IS protocol. + + 1) For those environments in which OSI is being used, or in which it + is anticipated that OSI will be used in the future, it is + permissible to obtain NSAP address assignments in the normal + manner, assign normal NSAP addresses to IP-only routers, and use + these addresses in the operation of IS-IS. This approach is + recommended even for pure IP routing domains, as it will simplify + future migration from IP-only to dual operation. + + 2) In some cases, routers may have only TCP/IP addresses, and it may + be undesireable to have to go through the normal mechanisms for + assignment of NSAP addresses. Instead, an alternate mechanim is + provided below for algorithmically generating a valid OSI style + address from existing IP address and autonomous system number + assignments. + + Where desired, for IP-only routers, for use in IS-IS packet formats + only, OSI-style addresses (compatible with the USA GOSIP version 2.0 + NSAP address format [9]) may be derived as follows: + + AFI 1 octet value "47" (specifies ICD format) + + ICD 2 octet value "00 05" (specifies Internet/Gosip) + + DFI 1 octet value "xx" + + AA 3 octets value "xx xx xx" (specifies special + IP-only use of NSAPs) + + Reserved 2 octets must be "00 00" + + RD 2 octets contains autonomous system number + + Area 2 octets must be assigned as described below + + ID 6 octets must be assigned as described below + + SEL 1 octet used as described below + + The AFI value of "47" and the ICD value of "00 05" specifies the + Gosip Version 2.0 addressing format. The DFI number of "xx" and the + AA of "xx xx xx" specify that this special NSAP address format is + being used, solely for IS-IS packet formats in an IP-only + environment. The reserved field must contain "00 00", as specified in + GOSIP version 2.0. + + + + +Callon [Page 20] + +RFC 1195 OSI ISIS for IP and Dual Environments December 1990 + + + The routing domain field contains the Autonomous System number. + Strictly speaking, this is not necessary, since the IS-IS packets are + exchanged within a single AS only. However, inclusion of the AS + number in this address format will ensure correct operation in the + event that routers from separate routing domains/ASs are incorrectly + placed on the same link. The AS number in this context is used only + for definition of unique NSAP addresses, and does not imply any + coupling with exterior routing protocols. + + The Area field must be assigned by the authority responsible for the + routing domain, such that each area in the routing domain must have a + unique Area value. + + The ID must be assigned by the authority responsible for the routing + domain. The ID must be assigned such that every router in the routing + domain has a unique value. It is recommended that one of the + following methods is used: + + 1)use a unique IEEE 802 48 bit station ID + + 2)use the value hex "02 00" prepended to an IP address of the router. + + IEEE 802 addresses, if used, must appear in IEEE canonical format. + + Since the IEEE 802 station IDs are assigned to be globally unique, + use of these values clearly assures uniqueness in the area. Also, all + assigned IEEE 802 station IDs have the global/local bit set to zero. + Prepending the indicated pattern to the front of the IP address + therefore assures that format (2) illustrated above cannot produce + addresses which collide with format (1). Finally, to the extent that + IP addresses are also globally unique, format (2) will produce unique + IDs for routers. + + The indicated hex value is specified in IEEE 802 canonical form [10]. + In IEEE 802 addresses, the multicast bit is the least significant bit + of the first byte. The global/local bit is the next least significant + bit of the first byte. The indicated prefix therefore sets the + global/local bit to 1, and all other bits in the first two octets to + 0. + + Note that within an area, whether ISO addresses are configured into + the routers through ISO address assignment, or whether the ISO-style + address is generated directly from the AS number and IP address, all + routers within an area must have the same high order part of address + (AFI, ICD, DFI, AA, RD, and Area). This ISO-style address is used in + IS-IS Hello messages and is the basis by which routers recognize + whether neighbor nodes are in or out of their area. + + + + +Callon [Page 21] + +RFC 1195 OSI ISIS for IP and Dual Environments December 1990 + + +3.4 External Links + + External connectivity (i.e., communications with routers outside of + the routing domain) is done only by level 2 routers. The ISO version + of IS-IS allows external OSI routes to be reported as "reachable + address prefixes" in level 2 LSPs. The integrated IS-IS also allows + external IP reachable addresses (i.e., IP addresses reachable via + inter-domain routing) to be reported in level 2 LSPs in the "IP + external reachability information" field. External OSI and external + IP routes are handled independently. + + The routes announced in IP external reachability information entries + include all routes to outside of the routing domain. This includes + routes learned from OSPF, EGP, RIP, or any other external protocol. + + External routes may make use of "internal" or "external" metrics. + Internal metrics are comparable with the metrics used for internal + routes. Thus in choosing between an internal route, and an external + route using internal metrics, the metric values may be directly + compared. In contrast, external metrics cannot be directly compared + with internal metrics. Any route defined solely using internal + metrics is always preferred to any route defined using external + metrics. When an external route using external metrics must be used, + the lowest value of the external metric is preferred regardless of + the internal cost to reach the appropriate exit point. + + It is useful, in the operation of external routing protocols, to + provide a mechanism for border routers (i.e., routers in the same + routing domain, which have the ability to route externally to other + domains) to determine each other's existence, and to exchange + external information (in a form understood only by the border routers + themselves). This is made possible by inclusion of "inter-domain + routing protocol information" fields in level 2 LSPs. The inter- + domain routing protocol information field is not included in + pseudonode LSPs. + + In general there may be multiple types of external inter-domain + routing protocol information exchanged between border routers. The + IS-IS therefore specifies that each occurance of the inter-domain + routing protocol information field include a "type" field, which + indicates the type of inter-domain routing protocol information + enclosed. Values to be used in the type field will be specified in + future versions of the "Assigned Numbers" RFC. Initial values for + this field are specified in Annex A of this specification. + + Information contained in the inter-domain routing protocol + information field will be carried in level 2 LSPs, and will therefore + need to be stored by all level 2 routers in the domain. However, only + + + +Callon [Page 22] + +RFC 1195 OSI ISIS for IP and Dual Environments December 1990 + + + those level 2 routers which are directly involved in external routing + will use this information. In designing the use of this field, it is + important to carefully consider the implications that this may have + on storage requirements in level 2 routers (including those level 2 + routers which are not directly involved in external routing). + + The protocols used to exchange routing information directly between + border routers, and external routers (in other routing domains / + autonomous systems) are outside of the scope of this specification. + +3.5 Type of Service Routing + + The integrated IS-IS protocol provides IP Type of Service (TOS) + routing, through use of the Quality of Service (QOS) feature of IS- + IS. This allows for routing on the basis of throughput (the default + metric), delay, expense, or residual error probability. Note than any + particular packet may be routed on the basis of any one of these four + metrics. Routing on the basis of general combinations of metrics is + not supported. + + The support for TOS/QOS is optional. If a particular packet calls for + a specific TOS, and the correct path from the source to destination + is made up of routers all of which support that particular TOS, then + the packet will be routed on the optimal path. However, if there is + no path from the source to destination made up of routers which + support that particular type of service, then the packet will be + forwarded using the default metric instead. This allows for TOS + service in those environments where it is needed, while still + providing acceptable service in the case where an unsupported TOS is + requested. + + NOTE - IP does not have a cost TOS. There is therefore no mapping of + IP TOS metrics which corresponds to the minimum cost metric. + + The IP TOS field is mapped onto the four available metrics as + follows: + + Bits 0-2 (Precedence): This field does not affect the route, but + rather may affect other aspects of packet + forwarding. + + Bits 3 (Delay), 4 (Throughput) and 5 (Reliability): + + 000 (all normal) Use default metric + + 100 (low delay) Use delay metric + + 010 (high throughput) Use default metric + + + +Callon [Page 23] + +RFC 1195 OSI ISIS for IP and Dual Environments December 1990 + + + 001 (high reliabiity) Use reliability metric + + other Use default metric + +3.6 Multiple LSPs and SNPs + + In some cases, IS-IS packets (specifically Link State Packets and + Complete Sequence Number Packets) may be too large to fit into one + packet. The OSI IS-IS [1] allows for LSPs and CSNPs to be split into + multiple packets. This is independent of ISO 8473 segmentation, and + is also independent of IP fragmentation. Use of independent multiple + packets has the advantages (with respect to segmentation or + fragmentation) that: (i) when information in the IS-IS changes, only + those packets effected need to be re-issued; (ii) when a single + packet is received, it can be processed without the need to receive + all other packets of the same type from the same router before + beginning processing. + + The Integrated IS-IS makes use of the same multiple packet function, + as defined in [1]. IP-specific fields in IS-IS packets may be split + across multiple packets. As specified in section 5 ("Structure and + Encoding of PDUs"), some of the IP-specific fields (those which may + be fairly long) may be split into several occurences of the same + field, thereby allowing splitting of the fields across different + packets. + + Multiple LSPs from the same router are distinguished by LSP number. + Generally, most variable length fields may occur in an LSP with any + LSP number. Some specific variable length fields may be required to + occur in LSP number 0. Except where explicitly stated otherwise, when + an IS-IS router issues multiple LSPs, the IP-specific fields may + occur in an LSP with any LSP number. + + Complete Sequence Number Packets may be split into multiple packets, + with the range to which each packet applies explicitly reported in + the packet. Partial Sequence Number Packets are inherently partial, + and so can easily be split into multiple packets if this is + necessary. Again, where applicable, IP-specific fields may occur in + any SNP. + +3.7 IP-Only Operation + + For IP-only routers, the format for IS-IS packets remains unchanged. + However, there are some variable length fields from the IS-IS packets + that can be omitted. Specifically: + + + + + + +Callon [Page 24] + +RFC 1195 OSI ISIS for IP and Dual Environments December 1990 + + + IS-IS Hello Packets: + + - no change + + IS-IS Link State Packets: + + - the "End Systems Neighbours" entries are omitted + + - the "Prefix Neighbours" entries are omitted + + IS-IS Sequence Number Packets: + + - no change + +3.8 Encapsulation + + Future versions of the Integated IS-IS may specify optional + encapsulation mechanisms for partition repair, and for forwarding + packets through incompatible routers (i.e., for forwarding OSI + packets through IP-only routers, and forwarding IP packets through + OSI-only routers). The details of encapsulation and decapsulation are + for further study. Routers complying with the Integrated IS-IS are + not required to implement encapsulation nor decapsulation. + +3.9 Authentication + + The authentication field allows each IS-IS packet to contain + information used to authenticate the originator and/or contents of + the packet. The authentication information contained in each packet + is used to authenticate the entire packet, including OSI and IP + parts. If a packet is received which contains invalid authentication + information, then the entire packet is discarded. If an LSP or SNP is + split into multiple packets (as described in section 3.6), then each + is authenticated independently. + + Use of the authentication field is optional. Routers are not required + to be able to interpret authentication information. As with other + fields in the integrated IS-IS, if a router does not implement + authentication then it will ignore any authentication field that may + be present in an IS-IS packet. + + Annex D specifies a proposed use of the authentication field. + +3.10 Order of Preference of Routes / Dijkstra Computation + + We define the term "IP reachability entry" to mean the combination of + the [IP address, subnet mask]. The Dijkstra calculation must + calculate routes to each distinct IP reachability entry. For the + + + +Callon [Page 25] + +RFC 1195 OSI ISIS for IP and Dual Environments December 1990 + + + Dijkstra calculation, each IP reachability entry can be treated in + much the same manner as an OSI end system. Naturally, each IP + reachability entry is treated as distinct from any OSI end systems + which may also be reachable in the same area or routing domain. + + For any particular IP reachability entry, this is the same as another + entry if and only if: (i) the subnet masks are identical; and (ii) + for each bit in the subnet mask which has the value "1", the IP + address is identical. This can easily be tested by zeroing those bits + in the IP address which correspond to a zero bit in the mask, and + then treating the entry as a 64 bit quantity, and testing for + equality between different 64 bit quantities. The actual calculation + of routes to IP reachability entries is therefore no more complex + than calculation of routes to OSI end systems (except for the + replacement of a 48-bit test with a 64-bit test). + + The Dijkstra computation does not take into consideration whether a + router is IP-only, OSI-only, or dual. The topological restrictions + specified in section 1.4 ensure that IP packets will only be sent via + IP-capable routers, and OSI packets will only be sent via OSI-capable + routers. + + The Integrated IS-IS prefers routes within the area (via level 1 + routing) whenever possible. If level 2 routes must be used, then + routes within the routing domain (specifically, those routes using + internal metrics) are prefered to routes outside of the routing + domain (using external metrics). + + The Integrated IS-IS protocol makes use of "best match" routing of IP + packets. This implies that a particular destination address may match + more than one entry in the forwarding database. If a particular IP + packet has a destination address which matches two different IP + reachability entries, then the entry who's mask contains the most "1" + bits is preferred. + + IP packets whose destination is a router are routed the same way as + any other IP packet, by forwarding first to the appropriate subnet, + and then forwarding on that subnet to the destination host (which + just happens to be a router in this case). In particular, the IP + forwarding database does not contain explicit routes to the + individual "IP interface addresses" listed by each router in its LSP. + + However, host routes (routes with a subnet mask of all ones) may of + course be included in the IP reachability entries, and will be + handled in the same manner as other IP reachability entries. + + In order to ensure correct interoperation of different router + implementations, it is necessary to specify the order of preference + + + +Callon [Page 26] + +RFC 1195 OSI ISIS for IP and Dual Environments December 1990 + + + of possible routes. For OSI destinations, this is outside of the + scope of this report. For IP destinations, this is specified in + section 3.10.1 and 3.10.2 below. Annex C specifies a detailed + Dijkstra calculation and forwarding algorithm which is compatible + with the order of preference of routes specified here. + + With IS-IS, if a route to a given destination is advertised, or a + link between routers is advertised, then metric values associated + with some or all of the specified TOS metric types may be associated + with that destination or link. However, the default metric must + always be available. Normally this ensures that if a route using any + TOS metric is available, then a route using the default metric will + also be available. The only exception to this is where the + corresponding route using the default metric has a total cost (within + the area, or within the level 2 backbone) greater than MaxPathMetric. + + In determining the route to a particular destination for a specified + TOS, only routes using either the requested TOS metric, or the + default TOS metric, are considered. + +3.10.1 Order of Preference of Routes In Level 1 Routing + + If a given destination is reachable within an area via a route using + either the requested TOS or the default TOS, then the IS-IS will + always make use of a path within the area (via level 1 routing), + regardless of whether an alternate path exists outside of the area + (via level 2 routing). In this case, routes within the area are + selected as follows: + + 1) Amongst routes in the area, if the specified destination + address matches more than one [IP address, subnet mask] pair, + then the more specific address match (the one with more "1" + bits in the mask) is prefered. + + 2) Amongst routes in the area to equally specific address + matches, routes on which the requested TOS (if any) is + supported are always prefered to routes on which the + requested TOS is not supported. + + 3) Amongst routes in the area of the same TOS to equally + specific address matches, the shortest routes are prefered. + For determination of the shortest path, if a route on which + the specified TOS is supported is available, then the + specified TOS metric is used, otherwise the default metric + is used. Amongst routes of equal cost, load splitting may + be performed as specified in [1]. + + For a level 1 only router (i.e., a router which does not take part in + + + +Callon [Page 27] + +RFC 1195 OSI ISIS for IP and Dual Environments December 1990 + + + level 2 routing, or a level 2 router which is not "attached"), if a + given destination is not reachable within an area, level 1 routing + will always route to a level 2 router as follows: + + 1) Amongst routes in the area to attached level 2 routers, + routes on which the requested TOS (if any) is supported + are always prefered to routes on which the requested TOS + is not supported. + + 2) Amongst routes in the area of the same TOS to attached + level 2 routers, the shortest routes are prefered. For + determination of the shortest path, if a route on which + the specified TOS is supported is available, then the + specified TOS metric is used, otherwise the default + metric is used. Amongst routes of equal cost, + loadsplitting may be performed as specified in [1]. + +3.10.2 Order of Preference of Routes in Level 2 Routing + + For those level 2 routers which also take part in level 1 routing, + routes learned via level 1 routing, using either the requested TOS or + the default TOS, are always prefered to routes learned through level + 2 routing. For destinations which are not reachable via level 1 + routing, or for level 2 only routers (routers which do not take part + in level 1 routing), then level 2 routes are selected as follows: + + 1) Routes using internal metrics only are always preferred + to routes using external metrics. + + 2) If a route using internal metrics only is available: + + a) If the specified destination address matches more + than one [IP address, subnet mask] pair, then the more + specific address match (i.e., the largest number of + "1"s present in the subnet mask) is prefered. + + b) Amongst routes with equally specific address matches + (i.e., an equal number of "1"s present in the subnet + mask), routes on which the requested TOS (if any) is + supported are always preferred to routes on which the + requested TOS is not supported. + + c) Amongst routes of the same TOS with an equally specific + address matches, the shortest path is prefered. For + determination of the shortest path, if a route on which + the specified TOS is supported is available, then the + specified TOS metric is used, otherwise the default + metric is used. Amongst routes of equal cost, + + + +Callon [Page 28] + +RFC 1195 OSI ISIS for IP and Dual Environments December 1990 + + + loadsplitting may be performed as specified in [1]. + + NOTE: Internal routes (routes to destinations announced + in the "IP Internal Reachability Information" field), + and external routes using internal metrics (routes to + destinations announced in the "IP External Reachability + Information" field, with a metric of type "internal") + are treated identically for the purpose of the order of + preference of routes, and the Dijkstra calculation. + + 3) If a route using internal metrics only is not available, + but a route using external metrics is available: + + a) If the specified destination address matches more than + one [IP address, subnet mask] pair, then the more + specific address match is prefered. + + NOTE: For external routes, the subnet mask will normally + correspond precisely to the network number. This implies + that this test will always discover equal length matching + strings. However, this test is included to allow future + migration to more general handling of external addresses. + + b) Amongst routes with equally specific matches, routes on + which the requested TOS (if any) is supported are always + preferred to routes on which the requested TOS is not + supported. NOTE: for external routes, the route is + considered to support the requested TOS only if the + internal route to the appropriate border router + supports the requested TOS, and the external route + reported by the border router also supports the + requested TOS. + + c) Amongst routes of the same TOS with an equal length + matching address string, the shortest path is prefered. + For determination of the shortest path: + + (i) Routes with a smaller announced external metric + are always prefered. + + (ii) Amongst routes with an equal external metric, + routes with a shorter internal metric are prefered. + Amongst routes of equal cost, loadsplitting may be + performed as specified in [1]. + + For level 2 routers which are announcing manually configured summary + addresses in their level 2 LSPs, in some cases there will exist IP + addresses which match the manually configured addresses, but which do + + + +Callon [Page 29] + +RFC 1195 OSI ISIS for IP and Dual Environments December 1990 + + + not match any addresses which are actually reachable via level 1 + routing in the area. Generally, packets to such addresses are handled + according to the following rules: + + 1) If the specified destination is reachable via level 1 routing, + then according to the order of preference of routes specified + above, the packet will be delivered via level 1 routing. + + 2) If the specified destination is not reachable via level 1 routing, + but is reachable via 2 routing, and there are other level 2 + routers which offer more desireable routes according to the + rules specified above (for example a route with a more specific + match, or a route with an equally specific match which supports + the correct TOS), then level 2 routing will forward the packet + according to the more desireable route. + + 3) If the specified destination is not reachable via level 1 routing, + and the manually configured summary address advertised by this + router (the router which has received the packet and is trying + to forward it) represents the most desireable route, then the + destination is unreachable and the packet must be discarded. + +4 Subnetwork Dependent Functions + +4.1 Link Demultiplexing + + Dual routers may receive a combination of OSI packets, and IP + packets. It is necessary for the dual routers to be able to clearly + and unambiguously distinguish the two protocol suites. + + This problem is not unique to the integrated IS-IS routing protocol. + In fact, this problem will occur in any multi-protocol environment. + This problem is currently being worked on independently, and is + outside of the scope of this specification. + + In general, the link type is a configuration parameter. For example, + whether to use PPP, HDLC, or some other point-to-point protocol over + a point-to-point link would be configured. For any particular link + type, a method must be defined for encapsulation of both OSI and IP + packets. Definition of such methods for common link types is outside + of the scope of this specification. + + IP packets are encapsulated directly over the underlying link layer + service, using the normal method for transmssion of IP packets over + each type of link. Similarly OSI packets are encapsulated directly + over the underlying link layer service, using the normal method for + transmission of OSI packets over each type of link. Finally, note + that IS-IS packets are encapsulated using the normal method for + + + +Callon [Page 30] + +RFC 1195 OSI ISIS for IP and Dual Environments December 1990 + + + transmission of OSI packets over any particular link type. This + implies that all IS-IS routers, including IP-only routers, must be + able to receive IS-IS packets using the normal encapsulation for OSI + packets. + +4.2 Multiple IP Addresses per Interface + + The integrated IS-IS allows each router to have multiple IP addresses + for each physical interface, up to the maximum number which may be + contained in a single "IP Interface Address" field (i.e., up to a + maximum of 63 addresses per interface). For example, where there are + two logical subnets on the same LAN, the interface may have two IP + addresses, one corresponding to each logical subnet. Each IS-IS Hello + packet contains a list of IP addresses associated with the physical + interface over which the Hello is transmitted. + + It is permissible to implement routers which conform to the + Integrated IS-IS specification which restrict the number of IP + addresses per interface. However, IP-capable routers must be able to + interact correctly with other routers which assign multiple IP + addresses per physical interface (up to the maximum of 63 addresses + per interface). + + Where appropriate (for example, in some cases on point-to-point + links), some interfaces may have no IP addresses assigned. In this + case, the IS-IS Hello transmitted on that interface may omit the IP + Interface Address field, or may include the IP Interface Address + field with zero entries. + +4.3 LANs, Designated Routers, and Pseudonodes + + The maintenance of designated routers and pseudonodes is specified in + [1], and is not changed by this proposal. In the case that IP-only + and dual routers (or OSI-only and dual routers) are mixed on the same + LAN in a pure IP area (or a pure OSI area, respectively), any router + on the LAN may be elected designated router. + + However, there is a fundamental difference in the way that OSI and + TCP/IP deal with LANs, and other broadcast subnetworks. + + With OSI, the use of the ES-IS protocol (ISO 9542) allows the end + systems and routers to automatically determine their connectivity, + thereby allowing all end systems on the LAN to potentially route via + any of the routers on the LAN. + + In contract, TCP/IP explictly assigns subnet identifiers to each + local area network. In some cases, a single physical LAN could have + multiple subnet identifiers assigned to it. In this case, end systems + + + +Callon [Page 31] + +RFC 1195 OSI ISIS for IP and Dual Environments December 1990 + + + (hosts) which have an address on one logical subnet are explicitly + precluded from sending IP packets directly to a router whose address + places it on a different logical subnet. Each router is manually + configured to know which subnets it can reach on each interface. In + the case that there are multiple logical subnets on the same LAN, + each router can only exchange IP packets with those end systems which + are on the same logical subnet. This implies that it is not + sufficient for the pseudonode LSP to announce all subnets on the LAN + (i.e., all [IP address, subnet mask] pairs reachable on the LAN). + + It is therefore necessary for each router to announce in its LSPs + those subnets which it can reach on each interface, including + interfaces to broadcast subnetworks such as LANs. The pseudonode LSP + does not specify the IP addresses which are reachable on the LAN + (i.e., does not contain the the IP reachability field). + + As specified elsewhere (see the forthcoming update to the + "Requirements of IP Gateways" [4]), routers may send ICMP redirects + only if: (i) the IP packet is being forwarded over the same physical + interface over which it arrived; and (ii) the source address of the + forwarded IP packet, the IP address of this router's interface (as + indicated by the source address of the ICMP redirect), and the IP + address of the router to which the packet is being redirected (again, + as indicated in the ICMP redirect) are all on the same IP subnet. + +4.4 Maintaining Router Adjacencies + + The IS-IS determines whether an adjacency is to be established + between two routers using means which are independent of the IP + interface addresses of the routers. Where multiple logical subnets + occur on the same physical LAN, this potentially allows adjacencies + to be brought up between two routers which share physical + connectivity to each other, but which don't have a logical subnet in + common. IP-capable IS-IS routers therefore must be able to forward IP + packets over existing adjacencies to routers with which they share + physical connectivity, even when the IP address of the adjacent + interface of the neighboring router is on a different logical IP + subnet. + + For point-to-point links, IS-IS requires exchange of ISO 9542 ISHs, + as the first step in establishing the link between routers. All IS-IS + routers are therefore required to transmit and receive ISO 9542 ISH + packets on point-to-point links. + + The "protocols supported" field (defined in section 5 below) must be + present in all IS-IS Hello packets sent by dual and IP-only routers. + If this field is missing, then it is assumed that the packet was + transmitted by an OSI-only router. Similarly, those 9542 ISHs sent + + + +Callon [Page 32] + +RFC 1195 OSI ISIS for IP and Dual Environments December 1990 + + + over point-to-point links, where there is (or may be) another IS-IS + router at the other end of the point-to-point link, must also + contains the "protocols supported" field. Note that if this field is + mistakenly sent in a 9542 ISH where there is an ordinary OSI-only End + System at the other end of the link, then (in accordance to ISO 9542) + the End System is required to ignore the field and interpret the ISH + correctly. It is therefore safe to always include this field in ISHs + sent over point-to-point links. + + Dual routers must operate in a dual fashion on every link in the + routing domain over which they are running IS-IS. Thus, the value of + the "protocols supported" field must be identical on every link + (i.e., for any one router running IS-IS, all of the Hellos and LSPs + transmitted by it must contain the same "protocols supported" + values). + +4.5 Forwarding to Incompatible Routers + + There may be times when a dual router has to forward an IP packet to + an OSI-only router, or forward an OSI packet to an IP-only router. In + this case the packet must be discarded. An error report may be + transmitted, in accordance with the IP or ISO 8473 specification + (respectively). The reason for discard specified in the error report + should specify "destination host unreachable" (for IP), or + "destination unreachable" (for OSI). + + Similarly, due to errors, in some cases an IP-only router may have to + forward an IP packet to an OSI-only router. Again, the packet must be + discarded, as specified above. This may only occur if IP-only and + OSI-only routers occur in the same area, which is a configuration + error. + +5 Structure and Encoding of PDUs + + This clause describes the additional packet fields for use of the ISO + IS-IS Intra-Domain Routing protocol in pure IP and dual environments. + Specifically, the same packet types are used as in IS-IS [1], and all + fixed fields remain the same. Additional variable length fields are + defined in this section. + +5.1 Overview of IS-IS PDUs + + The packets used in IS-IS routing protocol fall into three main + classes: (i) Hello Packets; (ii) Link State Packets (LSPs); and (iii) + Sequence Number Packets (SNPs). + + Hello packets are used to initialize and maintain adjacencies between + neighboring routers. There are three types of IS-IS Hello packets: + + + +Callon [Page 33] + +RFC 1195 OSI ISIS for IP and Dual Environments December 1990 + + + (i) "Level 1 LAN IS to IS Hello PDUs" are used by level 1 routers on + broadcast LANs. (ii) "Level 2 LAN IS to IS Hello PDUs" are used by + level 2 routers on broadcast LANs. (iii) "Point-to-Point IS to IS + Hello PDUs" are used on non-broadcast media, such as point-to-point + links, or general topology subnetworks. + + On point-to-point links, the exchange of ISO 9542 ISHs (intermediate + system Hellos) is used to initialize the link, and to allow each + router to know if there is a router on the other end of the link, + before IS-IS Hellos are exchanged. All routers implementing IS-IS + (whether IP-only, OSI-only, or dual), if they have any interfaces on + point-to-point links, must therefore be able to transmit ISO 9542 + ISHs on their point-to-point links. + + Link State Packets (LSPs) are used to exchange link state + information. There are two types of LSPs: (i) "Level 1 Link State + PDUs" are transmitted by level 1 routers. (ii) "Level 2 Link State + PDUs" are transmitted by level 2 routers. Note that level 2 routers + will, in most cases, also be level 1 routers, and will therefore + transmit both sorts of LSPs. + + Sequence number PDUs are used to ensure that neighboring routers have + the same notion of what is the most recent LSP from each other + router. The sequence number PDUs therefore serve a similar function + to acknowledgement packets, but allow more efficient operation. There + are four types of sequence number packets: (i) "Level 1 Complete + Sequence Numbers PDU"; (ii) "Level 2 Complete Sequence Numbers PDU"; + (iii) "Level 1 Partial Sequence Numbers PDU"; and (iv) "Level 2 + Partial Sequence Numbers PDU". A partial sequence number packet lists + the most recent sequence number of one or more LSPs, and operates + much like an acknowlegement. A partial sequence number packet differs + from an conventional acknowledgement in the sense that it may + acknowlege multiple LSPs at once, and in the sense that it may act as + a request for information. A complete sequence number packet contains + the most recent sequence number of all LSPs in the database. A + complete sequence number packet may therefore be used to ensure + synchronization of the database between adjacent routers either + periodically, or when a link first comes up. + +5.2 Overview of IP-Specific Information for IS-IS + + There are six new fields defined for the Integrated IS-IS: (i) + "Protocols Supported"; (ii) "IP Interface Address"; (iii) + "Authentication Information"; (iv) "IP Internal Reachability + Information"; (v) "IP External Reachability Information"; and (vi) + "Inter-Domain Routing Protocol Information". + + The "Protocols Supported" field identifies the protocols which are + + + +Callon [Page 34] + +RFC 1195 OSI ISIS for IP and Dual Environments December 1990 + + + supported by each router. This field must be included in all IS-IS + Hello packets and all LSPs with LSP number 0 transmitted by IP- + capable routers. If this field is not included in an IS-IS Hello + packet or an LSP with LSP number 0, it may be assumed that the packet + was transmitted by an OSI-only router. The "Protocols Supported" + field must also be included in ISO 9542 ISHs send by IP-capable + routers over point-to-point links to other IS-IS routers. + + The "IP Interface Address" is included in all IS-IS Hello packets and + LSPs transmitted by IP-only and dual routers. In the Hello packets, + this field occurs once only, and contains the IP address(es) of the + interface on which the Hello packet is transmitted (up to a maximum + of 63 IP addresses on each interface). If an IS-IS Hello is + transmitted over an interface which does not have an IP address + assigned, then this field may be omitted, or may be included with + zero entries. In Link State Packets, this field contains a list of + one or more IP addresses corresponding to one or more interfaces of + the router which originates the LSP. Each IP-capable router must + include this field in its LSPs. This field may occur multiple times + in an LSP, and may occur in an LSP with any LSP number. + + The "Authentication Information" field is optional in all IS-IS PDUs. + If used, it contains information used to authenticate the packet. All + IS-IS packets (including 9542 IS Hellos) may be authenticated by use + of this field. + + The "IP Internal Reachability Information" field may be present in + all LSPs transmitted by IP-capable routers. If present, it identifies + a list of zero or more [IP address, subnet mask, metrics] reachable + by the router which originates the LSP. Each entry must contain a + default metric, and may contain delay, expense, and error metrics. If + an IP-capable router does not directly reach any IP addresses, then + it may omit this field, or may include the field with zero [IP + address, subnet mask, metrics] entries. If included in level 1 LSPs, + this field includes only entries directly reachable by the router + which originates the LSP, via one of its interfaces. If included in + level 2 LSPs, this field includes only entries reachable by the + router which originates the LSP, either via one of its interfaces, or + indirectly via level 1 routing. This field may occur multiple times + in an LSP, and may occur in an LSP with any LSP number. + + The "IP External Reachability Information" field may be present in + level 2 LSPs transmitted by level 2 IP-capable routers. If present, + it identifies a list of zero or more [IP address, subnet mask, + metrics] entries reachable by the router which originates the level 2 + LSP. Each entry must contain a default metric, and may contain delay, + expense, and error metrics. Each entry may contain metrics of type + "internal", or of type "external". If a level 2 router does not have + + + +Callon [Page 35] + +RFC 1195 OSI ISIS for IP and Dual Environments December 1990 + + + any external routes (via neighboring routers in other routing + domains), when it may omit this field, or may include the field with + zero entries. This field includes only entries reachable by the + router which originates the LSP, via a direct link to an external + router. This field may occur multiple times in a level 2 LSP, and may + occur in an LSP with any LSP number. + + The "Inter-Domain Routing Protocol Information" field may be present + in level 2 LSPs transmitted by level 2 IP-capable routers. This field + is transmitted for the convenience of the external routing protocol, + and is not used by the IS-IS. For example, this may be used to allow + border routers to find each other. This field may occur multiple + times in a level 2 LSP, and may occur in an LSP with any LSP number. + + The DP 10589 version of the OSI IS-IS does not currently allow + addition of TLV-encoded variable length fields to Sequence Number + Packets. However, this is being corrected in future versions of + 10589. In addition, this is expected to be the only correction to + future versions of 10589 that is not backward-compatible with the DP + version. The Integrated IS-IS therefore makes use of a corrected + version of DP 10589, such that the encoding of SNPs has been fixed. + The correct encoding of sequence number packets (as is expected to + appear in future versions of ISO 10589) is given in Annex B of this + specification. + + All IP-specific information is encoded in IS-IS packets as variable + length fields. All variable length fields in IS-IS are encoded as + follows: + + No. of Octets + +---------------------------+ + | CODE | 1 + +---------------------------+ + | LENGTH | 1 + +---------------------------+ + | VALUE | LENGTH + +---------------------------+ + + Figure 3 - Encoding of Variable Length Fields + + Any codes in a received PDU that are not recognised shall be ignored + and, for those packets which are forwarded (specifically Link State + Packets), passed on unchanged. + + In general, an IS-IS PDU may contain multiple variable length fields, + some of which contain OSI-specific information (specified in [1]) and + some of which contain IP-specific information (specified below). + Except where explicitly stated otherwise, these variable length + + + +Callon [Page 36] + +RFC 1195 OSI ISIS for IP and Dual Environments December 1990 + + + fields may occur in any order. + +5.3 Encoding of IP-Specific Fields in IS-IS PDUs + + This section specifies the detailed encoding of all IP-specific + fields in IS-IS PDUs. Where a particular field may be present in more + than one type of PDU, the field is repeated for each type of PDU to + which it applies. + + Bit and octet numbering is the same as in [1]. In particular, octets + in a PDU are numbered starting from 1, in increasing order. Bits in + an octet are numbered from 1 to 8, where bit 1 is the least + significant bit and is pictured on the right. When consecutive octets + are used to represent a number, the lower octet number has the most + significant value. + +5.3.1 Level 1 LAN IS to IS Hello PDU + +- Additional codes for IP support are: + + 7 Protocols Supported -- the set Network Layer Protocol Identifiers + for Network Layer protocols that this Intermediate System is + capable of relaying + + x CODE - 129 + + x LENGTH - total length of the value field (one octet per + protocol supported). + + x VALUE - one octet NLPID (as assigned by ISO/TR 9577) for + each supported data protocol. + No. of Octets + +---------------------------+ + | NLPID | 1 + +---------------------------+ + : : + : : + |---------------------------| + | NLPID | 1 + +---------------------------+ + NLPID - ISO/TR 9577 registered Network Layer Protocol Identifier. + + 7 IP Interface Address -- the IP address(es) of the interface + corresponding to the SNPA over which this PDU is to be transmitted. + + x CODE - 132 + + x LENGTH - total length of the value field (four octets per address). + + + +Callon [Page 37] + +RFC 1195 OSI ISIS for IP and Dual Environments December 1990 + + + x VALUE - + No. of Octets + +----------------------------+ + | IP ADDRESS | 4 + +----------------------------+ + : : + : : + +----------------------------+ + | IP ADDRESS | 4 + +----------------------------+ + IP ADDRESS - 4 octet IP Address of the Interface. + + 7 Authentication Information -- Information used to authenticate the + PDU + + x CODE - 133 + + x LENGTH - total length of the value field. + + x VALUE - TBD. + +5.3.2 Level 2 LAN IS to IS Hello PDU + +- Additional codes for IP support are: + + 7 Protocols Supported -- the set Network Layer Protocol Identifiers + for Network Layer protocols that this Intermediate System is + capable of relaying + + x CODE - 129 + + x LENGTH - total length of the value field (one octet per protocol + supported). + + x VALUE - one octet NLPID (as assigned by ISO/TR 9577) for each + supported data protocol. + No. of Octets + +----------------------------+ + | NLPID | 1 + +----------------------------+ + : : + : : + +----------------------------+ + | NLPID | 1 + +----------------------------+ + NLPID - ISO/TR 9577 registered Network Layer Protocol Identifier. + + 7 IP Interface Address -- The IP address(es) of the interface + + + +Callon [Page 38] + +RFC 1195 OSI ISIS for IP and Dual Environments December 1990 + + + corresponding to the SNPA over which this PDU is to be transmitted. + + x CODE - 132 + + x LENGTH - total length of the value field (four octets per address). + + x VALUE - + No. of Octets + +----------------------------+ + | IP ADDRESS | 4 + +----------------------------+ + : : + : : + +----------------------------+ + | IP ADDRESS | 4 + +----------------------------+ + IP ADDRESS - 4 octet IP Address of the Interface. + + 7 Authentication Information -- Information used to authenticate + the PDU + + x CODE - 133 + + x LENGTH - total length of the value field + + x VALUE - TBD + +5.3.3 Point-to-Point IS to IS Hello PDU + +- Additional codes for IP support are: + + 7 Protocols Supported -- the set Network Layer Protocol Identifiers + for Network Layer protocols that this Intermediate System is + capable of relaying + + x CODE - 129 + + x LENGTH - total length of the value field (one octet per protocol + supported). + + x VALUE - one octet NLPID (as assigned by ISO/TR 9577) for each + supported data protocol. + + + + + + + + + +Callon [Page 39] + +RFC 1195 OSI ISIS for IP and Dual Environments December 1990 + + + No. of Octets + +----------------------------+ + | NLPID | 1 + +----------------------------+ + : : + : : + +----------------------------+ + | NLPID | 1 + +----------------------------+ + NLPID - ISO/TR 9577 registered Network Layer Protocol Identifier. + + 7 IP Interface Address -- The IP address(es) of the interface + corresponding to the SNPA over which this PDU is to be transmitted. + + x CODE - 132 + + x LENGTH - total length of the value field (four octets per address). + + x VALUE - + No. of Octets + +----------------------------+ + | IP ADDRESS | 4 + +----------------------------+ + : : + : : + +----------------------------+ + | IP ADDRESS | 4 + +----------------------------+ + IP ADDRESS - 4 octet IP Address of the Interface. + + 7 Authentication Information -- Information used to authenticate + the PDU + + x CODE - 133 + + x LENGTH - total length of the value field + + x VALUE - TBD + +5.3.4 Level 1 Link State PDU + +- Additional codes for IP support are: + + 7 Protocols Supported -- the set Network Layer Protocol Identifiers + for Network Layer protocols that this Intermediate System is + capable of relaying. + + This must appear once in LSP number 0. + + + +Callon [Page 40] + +RFC 1195 OSI ISIS for IP and Dual Environments December 1990 + + + x CODE - 129 + + x LENGTH - total length of the value field (one octet per protocol + supported). + + x VALUE - one octet NLPID (as assigned by ISO/TR 9577) for each + supported data protocol. + No. of Octets + +----------------------------+ + | NLPID | 1 + +----------------------------+ + : : + : : + +----------------------------+ + | NLPID | 1 + +----------------------------+ + NLPID - ISO/TR 9577 registered Network Layer Protocol Identifier. + + 7 IP Interface Addresses -- The IP addresss of one or more interfaces + corresponding to the SNPAs enabled on this Intermediate system + (i.e., one or more IP addresses of this router). + + This is permitted to appear multiple times, and in an LSP with + any LSP number. + + x CODE - 132 + + x LENGTH - total length of the value field (four octets per address). + + x VALUE - + No. of Octets + +----------------------------+ + | IP ADDRESS | 4 + +----------------------------+ + : : + : : + +----------------------------+ + | IP ADDRESS | 4 + +----------------------------+ + IP ADDRESS - 4 octet IP Address + + 7 Authentication Information -- Information used to authenticate + the PDU + + x CODE - 133 + + x LENGTH - total length of the value field + + + + +Callon [Page 41] + +RFC 1195 OSI ISIS for IP and Dual Environments December 1990 + + + x VALUE - TBD + + 7 IP Internal Reachability Information -- IP addresses within the + routing domain reachable directly via one or more interfaces on + this Intermediate system. + + This is permitted to appear multiple times, and in an LSP with any + LSP number. However, this field must not appear in pseudonode LSPs. + + x CODE - 128. + + x LENGTH - a multiple of 12. + + x VALUE - + No. of Octets + +----------------------------+ + | 0 |I/E| DEFAULT METRIC | 1 + +----------------------------+ + | S | R | DELAY METRIC | 1 + +----------------------------+ + | S | R | EXPENSE METRIC | 1 + +----------------------------+ + | S | R | ERROR METRIC | 1 + +----------------------------+ + | IP ADDRESS | 4 + +----------------------------+ + | SUBNET MASK | 4 + +----------------------------+ + : : + : : + +----------------------------+ + | 0 |I/E| DEFAULT METRIC | 1 + +----------------------------+ + | S | R | DELAY METRIC | 1 + +----------------------------+ + | S | R | EXPENSE METRIC | 1 + +----------------------------+ + | S | R | ERROR METRIC | 1 + +----------------------------+ + | IP ADDRESS | 4 + +----------------------------+ + | SUBNET MASK | 4 + +----------------------------+ + + DEFAULT METRIC is the value of the default metric for the link + to the listed neighbor. Bit 8 of this field is reserved, and + must be set to zero on tranmission and ignored on reception. + Bit 7 of this field (marked I/E) indicates the metric type + + + +Callon [Page 42] + +RFC 1195 OSI ISIS for IP and Dual Environments December 1990 + + + (internal or external) for all four TOS metrics, and must be + set to zero indicating internal metrics. + + DELAY METRIC is the value of the delay metric for the link to the + listed neighbor. If this IS does not support this metric it shall + set the bit "S" to 1 to indicate that the metric is unsupported. + Bit 7 of this field is reserved, and must be set to zero on + transmission and ignored on reception. + + EXPENSE METRIC is the value of the expense metric for the link to + the listed neighbor. If this IS does not support this metric it + shall set the bit "S" to 1 to indicate that the metric is + unsupported. Bit 7 of this field is reserved, and must be set to + zero on transmission and ignored on reception. + + ERROR METRIC is the value of the error metric for the link to + the listed neighbor. If this IS does not support this metric it + shall set the bit "S" to 1 to indicate that the metric is + unsupported. Bit 7 of this field is reserved, and must be set + to zero on transmission and ignored on reception. + + IP ADDRESS is a 4-octet Internet address + + SUBNET MASK is a 4 octet IP subnet mask. + +5.3.5 Level 2 Link State PDU + +- Additional codes for IP support are: + + 7 Protocols Supported -- the set Network Layer Protocol Identifiers + for Network Layer protocols that this Intermediate System is + capable of relaying. + + This must appear once in LSP number 0. + + x CODE - 129 + + x LENGTH - total length of the value field (one octet per + protocol supported). + + + + + + + + + + + + +Callon [Page 43] + +RFC 1195 OSI ISIS for IP and Dual Environments December 1990 + + + x VALUE - one octet NLPID (as assigned by ISO/TR 9577) for + each supported data protocol. + No. of Octets + +----------------------------+ + | NLPID | 1 + +----------------------------+ + : : + : : + +----------------------------+ + | NLPID | 1 + +----------------------------+ + NLPID - ISO/TR 9577 registered Network Layer Protocol Identifier. + + 7 IP Interface Addresses -- The IP addresss of one or more interfaces + corresponding to the SNPAs enabled on this Intermediate system + (i.e., one or more IP addresses of this router). + + This is permitted to appear multiple times, and in an LSP with + any LSP number. Where a router is both a level 1 and level 2 router, + it must include the same IP addresses in its level 1 and level 2 LSPs. + + x CODE - 132 + + x LENGTH - total length of the value field (four octets per address). + + x VALUE- + No. of Octets + +----------------------------+ + | IP ADDRESS | 4 + +----------------------------+ + : : + : : + +----------------------------+ + | IP ADDRESS | 4 + +----------------------------+ + IP ADDRESS - 4 octet IP Address + + 7 Authentication Information -- Information used to authenticate + the PDU + + x CODE - 133 + + x LENGTH - total length of the value field + + x VALUE - TBD + + 7 IP Internal Reachability Information -- IP addresses within the + routing domain reachable directly via one or more interfaces on + + + +Callon [Page 44] + +RFC 1195 OSI ISIS for IP and Dual Environments December 1990 + + + this Intermediate system. + + This is permitted to appear multiple times, and in an LSP with + any LSP number. However, this field must not appear in pseudonode + LSPs. + + x CODE - 128. + + x LENGTH - a multiple of 12. + + x VALUE - + No. of Octets + +----------------------------+ + | 0 |I/E| DEFAULT METRIC | 1 + +----------------------------+ + | S | R | DELAY METRIC | 1 + +----------------------------+ + | S | R | EXPENSE METRIC | 1 + +----------------------------+ + | S | R | ERROR METRIC | 1 + +----------------------------+ + | IP ADDRESS | 4 + +----------------------------+ + | SUBNET MASK | 4 + +----------------------------+ + : : + : : + +----------------------------+ + | 0 |I/E| DEFAULT METRIC | 1 + +----------------------------+ + | S | R | DELAY METRIC | 1 + +----------------------------+ + | S | R | EXPENSE METRIC | 1 + +----------------------------+ + | S | R | ERROR METRIC | 1 + +----------------------------+ + | IP ADDRESS | 4 + +----------------------------+ + | SUBNET MASK | 4 + +----------------------------+ + + DEFAULT METRIC is the value of the default metric for the link + to the listed neighbor. Bit 8 of this field is reserved, and must + be set to zero on transmission and ignored on reception. Bit 7 + of this field indicates the metric type (internal or external) + for all four TOS metrics, and must be set to zero indicating + internal metrics. + + + + +Callon [Page 45] + +RFC 1195 OSI ISIS for IP and Dual Environments December 1990 + + + DELAY METRIC is the value of the delay metric for the link to + the listed neighbor. If this IS does not support this metric it + shall set the bit "S" to 1 to indicate that the metric is + unsupported. Bit 7 of this field is reserved, and must be set + to zero on transmission and ignored on reception. + + EXPENSE METRIC is the value of the expense metric for the link to + the listed neighbor. If this IS does not support this metric it + shall set the bit "S" to 1 to indicate that the metric is + unsupported. Bit 7 of this field is reserved, and must be set + to zero on transmission and ignored on reception. + + ERROR METRIC is the value of the error metric for the link to the + listed neighbor. If this IS does not support this metric it shall + set the bit "S" to 1 to indicate that the metric is unsupported. + Bit 7 of this field is reserved, and must be set to zero on + transmission and ignored on reception. + + IP ADDRESS is a 4-octet Internet address + + SUBNET MASK is a 4 octet IP subnet mask. + + 7 IP External Reachability Information -- IP addresses outside the + routing domain reachable via interfaces on this Intermediate + system. + + This is permitted to appear multiple times, and in an LSP with + any LSP number. However, this field must not appear in pseudonode LSPs. + + x CODE - 130. + + x LENGTH - a multiple of 12. + + x VALUE - + + + + + + + + + + + + + + + + + +Callon [Page 46] + +RFC 1195 OSI ISIS for IP and Dual Environments December 1990 + + + No. of Octets + +----------------------------+ + | 0 |I/E| DEFAULT METRIC | 1 + +----------------------------+ + | S | R | DELAY METRIC | 1 + +----------------------------+ + | S | R | EXPENSE METRIC | 1 + +----------------------------+ + | S | R | ERROR METRIC | 1 + +----------------------------+ + | IP ADDRESS | 4 + +----------------------------+ + | SUBNET MASK | 4 + +----------------------------+ + : : + : : + +----------------------------+ + | 0 |I/E| DEFAULT METRIC | 1 + +----------------------------+ + | S | R | DELAY METRIC | 1 + +----------------------------+ + | S | R | EXPENSE METRIC | 1 + +----------------------------+ + | S | R | ERROR METRIC | 1 + +----------------------------+ + | IP ADDRESS | 4 + +----------------------------+ + | SUBNET MASK | 4 + +----------------------------+ + + DEFAULT METRIC is the value of the default metric for the + path to the listed IP addresses. Bit 8 of this field is + reserved, and must be set to zero on transmission and ignored + on reception. Bit 7 of this field indicates the metric type + (internal or external) for all four TOS metrics, and may be + set to zero indicating internal metrics, or may be set to 1 + indicating external metrics. + + DELAY METRIC is the value of the delay metric for the path + to the listed IP addresses. If this IS does not support this + metric it shall set the bit "S" to 1 to indicate that the metric + is unsupported. Bit 7 of this field is reserved, and must be + set to zero on transmission and ignored on reception. + + EXPENSE METRIC is the value of the expense metric for the link + to the listed IP addresses. If this IS does not support this + metric it shall set the bit "S" to 1 to indicate that the metric + is unsupported. Bit 7 of this field is reserved, and must be + + + +Callon [Page 47] + +RFC 1195 OSI ISIS for IP and Dual Environments December 1990 + + + set to zero on transmission and ignored on reception. + + ERROR METRIC is the value of the error metric for the link to + the listed IP addresses. If this IS does not support this metric + it shall set the bit "S" to 1 to indicate that the metric is + unsupported. Bit 7 of this field is reserved, and must be set to + zero on transmission and ignored on reception. + + IP ADDRESS is a 4-octet Internet address + + SUBNET MASK is a 4 octet IP subnet mask + + 7 Inter-Domain Routing Protocol Information -- Inter-domain routing + protocol information carried transparently through level 2 for + the convenience of any Inter-Domain protocol that may be running + in the boundary ISs. + + This is permitted to appear multiple times, and in an LSP with + any LSP number. + + x CODE - 131. + + x LENGTH - total length of the value field + + x VALUE - + No. of Octets + +-------------------------------+ + | Inter-Domain Information Type | 1 + +-------------------------------+ + | External Information | VARIABLE + +-------------------------------+ + + INTER-DOMAIN INFORMATION TYPE indicates the type of the + external information which is encoded in the field. + + EXTERNAL INFORMATION contains inter-domain routing protocol + information, and is passed transparently by the IS-IS protocol. + +5.3.6 Level 1 Complete Sequence Numbers PDU + +- Additional codes for IP support are: + + 7 Authentication Information -- Information used to authenticate + the PDU + + x CODE - 133 + + x LENGTH - total length of the value field + + + +Callon [Page 48] + +RFC 1195 OSI ISIS for IP and Dual Environments December 1990 + + + x VALUE - TBD + +5.3.7 Level 2 Complete Sequence Numbers PDU + +- Additional codes for IP support are: + + 7 Authentication Information -- Information used to authenticate + the PDU + + x CODE - 133 + + x LENGTH - total length of the value field + + x VALUE - TBD + +5.3.8 Level 1 Partial Sequence Numbers PDU + +- Additional codes for IP support are: + + 7 Authentication Information -- Information used to authenticate + the PDU + + x CODE - 133 + + x LENGTH - total length of the value field + + x VALUE - TBD + +5.3.9 Level 2 Partial Sequence Numbers PDU + +- Additional codes for IP support are: + + 7 Authentication Information -- Information used to authenticate + the PDU + + x CODE - 133 + + x LENGTH - total length of the value field + + x VALUE - TBD + +5.3.10 ISO 9542 ISH PDU + +- Additional codes for IP support are: + + 7 Protocols Supported -- the set Network Layer Protocol Identifiers + for Network Layer protocols that this Intermediate System is + capable of relaying. + + + +Callon [Page 49] + +RFC 1195 OSI ISIS for IP and Dual Environments December 1990 + + + This appears in ISO 9542 ISH PDUs transmitted on point-to-point + links. + + x CODE - 129 + + x LENGTH - total length of the value field (one octet per + protocol supported). + + x VALUE - one octet NLPID (as assigned by ISO/TR 9577) for + each supported data protocol. + No. of Octets + +----------------------------+ + | NLPID | 1 + +----------------------------+ + : : + : : + +----------------------------+ + | NLPID | 1 + +----------------------------+ + NLPID - ISO/TR 9577 registered Network Layer Protocol Identifier. + + 7 Authentication Information -- Information used to authenticate + the PDU + + x CODE - 133 + + x LENGTH - total length of the value field + + x VALUE - TBD + +6 Security Considerations + + The integrated IS-IS has a provision for carrying authentication + information in all IS-IS packets. This is extensible to multiple + authentication mechanisms. However, currently the only defined + mechanism is a simple password, transmitted in the clear without + encryption (see Annex D). The use of a simple password does not + provide useful protection against intentional misbehavior. Rather, + this should be thought of as a weak protection against accidental + errors such as accidental mis-configuration. Definition of other + authentication mechanisms is beyond the scope of this document. + + Other aspects of security are not discussed in this document. + + + + + + + + +Callon [Page 50] + +RFC 1195 OSI ISIS for IP and Dual Environments December 1990 + + +7 Author's Address + + Ross Callon + Digital Equipment Corporation + 550 King Street, LKG 1-2/A19 + Littleton, MA 01460-1289 + 508-486-5009 + +8 References + +[1] "Intermediate System to Intermediate System Intra-Domain + Routeing Exchange Protocol for use in Conjunction with the + Protocol for Providing the Connectionless-mode Network Service + (ISO 8473)", ISO DP 10589, February 1990. + +[2] "Protocol for Providing the Connectionless-Mode Network + Service", ISO 8473, March 1987. + +[3] "End System to Intermediate System Routeing Exchange Protocol + for Use in Conjunction with the Protocol for Providing the + Connectionless-Mode Network Service (ISO 8473)", ISO 9542, + March 1988. + +[4] Braden,R., and Postel,J., "Requirements for Internet Gateways", + RFC 1009, June 1987. + +[5] Moy,J., "The OSPF Specification", RFC 1131, October 1989. + +[6] Postel,J., "Internetwork Protocol", RFC 791, September 1981. + +[7] Postel,J., "Internet Control Message Protocol", RFC 792, + September 1981. + +[8] "MIB for Use with the Extended OSI IS-IS in TCP/IP and Dual + Environments", forthcoming. + +[9] GOSIP Advanced Requirements Group, "Government Open Systems + Interconnection Profile (GOSIP) Version 2.0 [Final Text]", + Federal Information Processing Standard, U.S. Department of + Commerce, National Institute of Standards and Technology, + Gaithersburg, MD, October 1990. + +[10] "Standard for Local Area Networks and Metropolitan Area + Networks: Overview and Architecture of Network Standards", + IEEE Standard 802.1a-1990. + + + + + + +Callon [Page 51] + +RFC 1195 OSI ISIS for IP and Dual Environments December 1990 + + + Annex A + Inter-Domain Routing Protocol Information + + This annex specifies the contents and encoding of the Inter-Domain + Routing Protocol Information (IDRPI) field. This annex is an integral + part of the Integrated IS-IS specification. However, it is expected + that this annex may be augmented or superceded by future efforts + outside of the scope of the IS-IS specification. + +A.1 Inter-Domain Information Type + + As specified in sections 3.4 and 5.3, the IDRPI field consists of a + one-octet inter-domain information type field, plus a variable + external information field. This section specifies initial values for + the inter-domain information type field. Other values for inter- + domain information type will be assigned and maintained in future + versions of the "Assigned Numbers" RFC. + + The following types have been assigned: + + Type = 0 reserved + + Type = 1 local (uses routing-domain specific format) + + Type = 2 AS Number Tag + + Type = 1 indicates that the inter-domain routing protocol information + uses a format which is local to the routing domain. + + Type = 2 indicates that the inter-domain routing protocol information + includes autonomous system information used to tag IP external + reachability information. In this case the inter-domain routing + protocol information entry must include a single AS number, which is + used to tag all subsequent External IP Reachability entries until the + end of the LSP, or until the next occurence of the Inter-Domain + Routing Protocol Information field. + +A.2 Encoding + + As specified in section 5.3.5, the IDPRI entry is encoded as a + variable length field, as follows: + + x CODE - 131 + + x LENGTH - total length of the value field + + x VALUE - + + + + +Callon [Page 52] + +RFC 1195 OSI ISIS for IP and Dual Environments December 1990 + + + No. of Octets + +-------------------------------+ + | Inter-Domain Information Type | 1 + +-------------------------------+ + | External Information | VARIABLE + +-------------------------------+ + + INTER-DOMAIN INFORMATION TYPE indicates the type of the + external information which is encoded in the field. + + EXTERNAL INFORMATION contains inter-domain routing protocol + information, and is passed transparently by the IS-IS protocol. + + The Inter-domain information type field indicates the type of + information which is contained in the external information field, as + follow: + + Type = 0 is reserved (must not be sent, and must be ignored on receipt). + + Type = 1 indicates that the external information field contains + information which follows a locally specified format. + + Type = 2 indicates that the external information field contains an + autonomous system number tag, to be applied to subsequent IP external + reachability information entries. In this case, this "inter-domain + routing protocol information" entry must contain precisely one 2 + octet AS number. The AS tag is associated with subsequent IP External + Reachability entries, until the end of the LSP, or until the next + occurence of the Inter-Domain Routing Protocol Information field. + In this case, the VALUE contains the following: + + x VALUE - + No. of Octets + +---------------------------------+ + | Inter-Domain Information Type=2 | 1 + +---------------------------------+ + | Autonomous System Number | 2 + +---------------------------------+ + + + + + + + + + + + + + +Callon [Page 53] + +RFC 1195 OSI ISIS for IP and Dual Environments December 1990 + + + Annex B + Encoding of Sequence Number Packets + + The Integrated IS-IS protocol defined in this specification makes use + of the ISO Draft Proposed standard for Intra-domain routing (ISO DP + 10589 [1]) as the base routing protocol, upon which IP support may be + added. + + However, DP 10589 contains a bug regarding encoding of the variable + length fields in Sequence Number Packets. In particular, DP 10589 + encodes the variable length fields in SNPs in a manner which is not + flexible (additional variable length fields cannot be defined for + sequence number packets), and which is inconsistent with the encoding + of the variable length fields in all other IS-IS and ES-IS packets. + + The encoding of the variable length fields in SNPs is expected to be + fixed in future versions of 10589. Also, this bug represents the only + expected change to 10589 which cannot be made backward compatible + with existing DP 10589 implementations. For these reasons, the + current version of the Integrated IS-IS will use the anticipated + future encoding of the variable length part of the SNPs. This should + allow future versions of this specification to be compatible with + implementations based on this specification. + + This annex specifies the encoding of SNPs, as amended to fix the + encoding of variable length fields. This annex is an integral part of + the Integrated IS-IS specification. + + The encoding of SNPs for OSI-only use is shown in this section. For + IP-only or Integrated use, the additional variable length fields + specified in sections 5.3.6 through 5.3.9 are also applicable to + SNPs. + + + + + + + + + + + + + + + + + + + +Callon [Page 54] + +RFC 1195 OSI ISIS for IP and Dual Environments December 1990 + + +B.1 Level 1 Complete Sequence Numbers PDU + + No. of Octets + +--------------------------------+ + | INTRA-DOMAIN ROUTEING | 1 + | PROTOCOL DISCRIMINATOR | + +--------------------------------+ + | LENGTH INDICATOR | 1 + +--------------------------------+ + | VERSION/PROTOCOL ID EXT | 1 + +--------------------------------+ + | RESERVED | 1 + +--------------------------------+ + | R | R | R | TYPE | 1 + +--------------------------------+ + | VERSION | 1 + +--------------------------------+ + | ECO | 1 + +--------------------------------+ + | USER ECO | 1 + +--------------------------------+ + | PDU LENGTH | 2 + +--------------------------------+ + | SOURCE ID | 7 + +--------------------------------+ + | START LSP ID | 8 + +--------------------------------+ + | END LSP ID | 8 + +================================+==================== + | VARIABLE LENGTH FIELDS | VARIABLE + +--------------------------------+ + + +- INTRADOMAIN ROUTEING PROTOCOL DISCRIMINATOR - architectural constant + +- LENGTH INDICATOR - Header Length in octets (33.) + +- VERSION/PROTOCOL ID EXTENSION - 1 + +- RESERVED - transmitted as 0, ignored on receipt + +- TYPE (bits 1 through 5) - 24. Note bits 6, 7 and 8 are Reserved, + which means they are transmitted as 0 and ignored on receipt. + +- VERSION - 1 + +- ECO - transmitted as zero, ignored on receipt + + + + +Callon [Page 55] + +RFC 1195 OSI ISIS for IP and Dual Environments December 1990 + + +- USER ECO - transmitted as zero, ignored on receipt + +- PDU LENGTH - Entire Length of this PDU, in octets, including header + +- SOURCE ID - 7 octet ID of Intermediate System (with zero Circuit ID) + generating this Sequence Numbers PDU. + +- START LSP ID - 8 octet ID of first LSP in the range covered by this + Complete Sequence Numbers PDU. + +- END LSP ID - 8 octet ID of last LSP in the range covered by this + Complete Sequence Numbers PDU. + +- VARIABLE LENGTH FIELDS - fields of the form: + + No. of Octets + +--------------------------------+ + | CODE | 1 + +--------------------------------+ + | LENGTH | 1 + +--------------------------------+ + | VALUE | LENGTH + +--------------------------------+ + +Any codes in a received CSNP that are not recognised are ignored. + +Currently defined codes are: + + 7 LSP Entries -- This may appear multiple times. The option fields, + if they appear more than once, shall appear sorted into ascending + LSPID order. + + x CODE - 9 + + x LENGTH - total length of the value field. + + x VALUE - a list of LSP entries of the form: + + + + + + + + + + + + + + +Callon [Page 56] + +RFC 1195 OSI ISIS for IP and Dual Environments December 1990 + + + + No. of Octets + +--------------------------------+ + | REMAINING LIFETIME | 2 + +--------------------------------+ + | LSP ID | 8 + +--------------------------------+ + | LSP SEQ NUMBER | 4 + +--------------------------------+ + | CHECKSUM | 2 + +--------------------------------+ + : : + : : + +--------------------------------+ + | REMAINING LIFETIME | 2 + +--------------------------------+ + | LSP ID | 8 + +--------------------------------+ + | LSP SEQ NUMBER | 4 + +--------------------------------+ + | CHECKSUM | 2 + +--------------------------------+ + +7 REMAINING LIFETIME - Remaining Lifetime of LSP. + +7 LSP ID - 8 octet ID of the LSP to which this entry refers. + +7 LSP SEQ NUMBER - Sequence number of LSP. + +7 CHECKSUM - Checksum reported in LSP. + +The entries shall be sorted into ascending LSPID order (the LSP +number octet of the LSPID is the least significant octet). + + + + + + + + + + + + + + + + + + +Callon [Page 57] + +RFC 1195 OSI ISIS for IP and Dual Environments December 1990 + + +B.2 Level 2 Complete Sequence Numbers PDU + + No. of Octets + +--------------------------------+ + | INTRA-DOMAIN ROUTEING | 1 + | PROTOCOL DISCRIMINATOR | + +--------------------------------+ + | LENGTH INDICATOR | 1 + +--------------------------------+ + | VERSION/PROTOCOL ID EXT | 1 + +--------------------------------+ + | RESERVED | 1 + +--------------------------------+ + | R | R | R | TYPE | 1 + +--------------------------------+ + | VERSION | 1 + +--------------------------------+ + | ECO | 1 + +--------------------------------+ + | USER ECO | 1 + +--------------------------------+ + | PDU LENGTH | 2 + +--------------------------------+ + | SOURCE ID | 7 + +--------------------------------+ + | START LSP ID | 8 + +--------------------------------+ + | END LSP ID | 8 + +================================+==================== + | VARIABLE LENGTH FIELDS | VARIABLE + +--------------------------------+ + + +- INTRADOMAIN ROUTEING PROTOCOL DISCRIMINATOR - architectural constant + +- LENGTH INDICATOR - Header Length in octets (33.) + +- VERSION/PROTOCOL ID EXTENSION - 1 + +- RESERVED - transmitted as 0, ignored on receipt + +- TYPE (bits 1 through 5) - 25. Note bits 6, 7 and 8 are Reserved, + which means they are transmitted as 0 and ignored on receipt. + +- VERSION - 1 + +- ECO - transmitted as zero, ignored on receipt + + + + +Callon [Page 58] + +RFC 1195 OSI ISIS for IP and Dual Environments December 1990 + + +- USER ECO - transmitted as zero, ignored on receipt + +- PDU LENGTH - Entire Length of this PDU, in octets, including header + +- SOURCE ID - 7 octet ID of Intermediate System (with zero Circuit ID) + generating this Sequence Numbers PDU. + +- START LSP ID - 8 octet ID of first LSP in the range covered by this + Complete Sequence Numbers PDU. + +- END LSP ID - 8 octet ID of last LSP in the range covered by this + Complete Sequence Numbers PDU. + +- VARIABLE LENGTH FIELDS - fields of the form: + + No. of Octets + +--------------------------------+ + | CODE | 1 + +--------------------------------+ + | LENGTH | 1 + +--------------------------------+ + | VALUE | LENGTH + +--------------------------------+ + +Any codes in a received CSNP that are not recognised are ignored. + +Currently defined codes are: + +7 LSP Entries -- this may appear multiple times. The option fields, + if they appear more than once, shall appear sorted into ascending + LSPID order. + + x CODE - 9 + + x LENGTH - total length of the value field. + + x VALUE - a list of LSP entries of the form: + + + + + + + + + + + + + + +Callon [Page 59] + +RFC 1195 OSI ISIS for IP and Dual Environments December 1990 + + + No. of Octets + +--------------------------------+ + | REMAINING LIFETIME | 2 + +--------------------------------+ + | LSP ID | 8 + +--------------------------------+ + | LSP SEQ NUMBER | 4 + +--------------------------------+ + | CHECKSUM | 2 + +--------------------------------+ + : : + : : + +--------------------------------+ + | REMAINING LIFETIME | 2 + +--------------------------------+ + | LSP ID | 8 + +--------------------------------+ + | LSP SEQ NUMBER | 4 + +--------------------------------+ + | CHECKSUM | 2 + +--------------------------------+ + +7 REMAINING LIFETIME - Remaining Lifetime of LSP. + +7 LSP ID - 8 octet ID of the LSP to which this entry refers. + +7 LSP SEQ NUMBER - Sequence number of LSP. + +7 CHECKSUM - Checksum reported in LSP. + +The entries shall be sorted into ascending LSPID order (the LSP +number octet of the LSPID is the least significant octet). + + + + + + + + + + + + + + + + + + + +Callon [Page 60] + +RFC 1195 OSI ISIS for IP and Dual Environments December 1990 + + +B.3 Level 1 Partial Sequence Numbers PDU + + No. of Octets + +--------------------------------+ + | INTRA-DOMAIN ROUTEING | 1 + | PROTOCOL DISCRIMINATOR | + +--------------------------------+ + | LENGTH INDICATOR | 1 + +--------------------------------+ + | VERSION/PROTOCOL ID EXT | 1 + +--------------------------------+ + | RESERVED | 1 + +--------------------------------+ + | R | R | R | TYPE | 1 + +--------------------------------+ + | VERSION | 1 + +--------------------------------+ + | ECO | 1 + +--------------------------------+ + | USER ECO | 1 + +--------------------------------+ + | PDU LENGTH | 2 + +--------------------------------+ + | SOURCE ID | 7 + +================================+==================== + | VARIABLE LENGTH FIELDS | VARIABLE + +--------------------------------+ + +- INTRADOMAIN ROUTEING PROTOCOL DISCRIMINATOR - architectural constant + +- LENGTH INDICATOR - Header Length in octets (17.) + +- VERSION/PROTOCOL ID EXTENSION - 1 + +- RESERVED - transmitted as 0, ignored on receipt + +- TYPE (bits 1 through 5) 26. Note bits 6, 7 and 8 are Reserved, + which means they are transmitted as 0 and ignored on receipt. + +- VERSION - 1 + +- ECO - transmitted as zero, ignored on receipt + +- USER ECO - transmitted as zero, ignored on receipt + +- PDU LENGTH - Entire Length of this PDU, in octets, including header + +- SOURCE ID - 7 octet ID of Intermediate system (with zero Circuit ID) + + + +Callon [Page 61] + +RFC 1195 OSI ISIS for IP and Dual Environments December 1990 + + + generating this Sequence Numbers PDU. + +- VARIABLE LENGTH FIELDS - fields of the form: + + No. of Octets + +--------------------------------+ + | CODE | 1 + +--------------------------------+ + | LENGTH | 1 + +--------------------------------+ + | VALUE | LENGTH + +--------------------------------+ + +Any codes in a received PSNP that are not recognised are ignored. + +Currently defined codes are: + +7 LSP Entries - this may appear multiple times. The option fields, + if they appear more than once, shall appear sorted into ascending + LSPID order. + + x CODE - 9 + + x LENGTH - total length of the value field. + + + + + + + + + + + + + + + + + + + + + + + + + + + +Callon [Page 62] + +RFC 1195 OSI ISIS for IP and Dual Environments December 1990 + + + x VALUE - a list of LSP entries of the form: + + No. of Octets + +--------------------------------+ + | REMAINING LIFETIME | 2 + +--------------------------------+ + | LSP ID | 8 + +--------------------------------+ + | LSP SEQ NUMBER | 4 + +--------------------------------+ + | CHECKSUM | 2 + +--------------------------------+ + : : + : : + +--------------------------------+ + | REMAINING LIFETIME | 2 + +--------------------------------+ + | LSP ID | 8 + +--------------------------------+ + | LSP SEQ NUMBER | 4 + +--------------------------------+ + | CHECKSUM | 2 + +--------------------------------+ + +7 REMAINING LIFETIME - Remaining Lifetime of LSP. + +7 LSP ID - 8 octet ID of the LSP to which this entry refers. + +7 LSP SEQ NUMBER - Sequence number of LSP. + +7 CHECKSUM - Checksum reported in LSP. + +The entries shall be sorted into ascending LSPID order (the LSP number +octet of the LSPID is the least significant octet). + + + + + + + + + + + + + + + + + +Callon [Page 63] + +RFC 1195 OSI ISIS for IP and Dual Environments December 1990 + + +B.4 Level 2 Partial Sequence Numbers PDU + + No. of Octets + +--------------------------------+ + | INTRA-DOMAIN ROUTEING | 1 + | PROTOCOL DISCRIMINATOR | + +--------------------------------+ + | LENGTH INDICATOR | 1 + +--------------------------------+ + | VERSION/PROTOCOL ID EXT | 1 + +--------------------------------+ + | RESERVED | 1 + +--------------------------------+ + | R | R | R | TYPE | 1 + +--------------------------------+ + | VERSION | 1 + +--------------------------------+ + | ECO | 1 + +--------------------------------+ + | USER ECO | 1 + +--------------------------------+ + | PDU LENGTH | 2 + +--------------------------------+ + | SOURCE ID | 7 + +================================+==================== + | VARIABLE LENGTH FIELDS | VARIABLE + +--------------------------------+ + +- INTRADOMAIN ROUTEING PROTOCOL DISCRIMINATOR - architectural constant + +- LENGTH INDICATOR - Header Length in octets (17.) + +- VERSION/PROTOCOL ID EXTENSION - 1 + +- RESERVED - transmitted as 0, ignored on receipt + +- TYPE (bits 1 through 5) - 27. Note bits 6, 7 and 8 are Reserved, + which means they are transmitted as 0 and ignored on receipt. + +- VERSION - 1 + +- ECO - transmitted as zero, ignored on receipt + +- USER ECO - transmitted as zero, ignored on receipt + +- PDU LENGTH - Entire Length of this PDU, in octets, including header + +- SOURCE ID - 7 octet ID of Intermediate system (with zero Circuit ID) + + + +Callon [Page 64] + +RFC 1195 OSI ISIS for IP and Dual Environments December 1990 + + + generating this Sequence Numbers PDU. + +- VARIABLE LENGTH FIELDS - fields of the form: + + No. of Octets + +--------------------------------+ + | CODE | 1 + +--------------------------------+ + | LENGTH | 1 + +--------------------------------+ + | VALUE | LENGTH + +--------------------------------+ + +Any codes in a received PSNP that are not recognised are ignored. + +Currently defined codes are: + +7 LSP Entries -- this may appear multiple times. The option fields, + if they appear more than once, shall appear sorted into ascending + LSPID order. + + x CODE - 9 + + x LENGTH - total length of the value field. + + x VALUE - a list of LSP entries of the form: + + + + + + + + + + + + + + + + + + + + + + + + + +Callon [Page 65] + +RFC 1195 OSI ISIS for IP and Dual Environments December 1990 + + + No. of Octets + +--------------------------------+ + | REMAINING LIFETIME | 2 + +--------------------------------+ + | LSP ID | 8 + +--------------------------------+ + | LSP SEQ NUMBER | 4 + +--------------------------------+ + | CHECKSUM | 2 + +--------------------------------+ + : : + : : + +--------------------------------+ + | REMAINING LIFETIME | 2 + +--------------------------------+ + | LSP ID | 8 + +--------------------------------+ + | LSP SEQ NUMBER | 4 + +--------------------------------+ + | CHECKSUM | 2 + +--------------------------------+ + +7 REMAINING LIFETIME - Remaining Lifetime of LSP. + +7 LSP ID - 8 octet ID of the LSP to which this entry refers. + +7 LSP SEQ NUMBER -Sequence number of LSP. + +7 CHECKSUM - Checksum reported in LSP. + +The entries shall be sorted into ascending LSPID order (the LSP +number octet of the LSPID is the least significant octet). + + + + + + + + + + + + + + + + + + + +Callon [Page 66] + +RFC 1195 OSI ISIS for IP and Dual Environments December 1990 + + + Annex C + Dijkstra Calculation and Forwarding + + Annex C.2 of ISO DP 10589 [1] specifies the SPF (Dikskstra) algorithm + for calculating routes with the IS-IS routing protocol. This annex + specifies modifications to the SPF algorithm for supporting IP and + dual routing, and specifies a compatible method for forwarding IP + packets. This will result in an order of preference of routes which + is compatible with that specified in section 3.10. + + This annex is included for informational purposes. + +C.1 SPF Algorithm for IP and Dual Use + + This section specifies an SPF Algorithm for calculating routes with + the IS-IS routing protocol, for support of both TCP/IP and OSI. This + is based on an extention to the algorithm specified in annex C.2 of + ISO DP 10589 [1]. + + An algorithm invented by Dijkstra known as shortest path first (SPF) + is used as the basis for the route calculation. It has a + computational complexity of the square of the number of nodes, which + can be decreased to the number of links in the domain times the log + of the number of nodes for sparse networks (networks which are not + highly connected). + + A number of additional optimizations are possible: + + 1) If the routing metric is defined over a small finite field (as in + this standard), the factor of log n may be removed by using data + structures which maintain a separate list of systems for each value + of the metric rather than sorting the systems by logical distance. + + 2) Updates can be performed incrementally without requiring a complete + recalculation. However, a full update must be done periodically to + ensure recovery from data corruption, and studies suggest that with + a very small number of link changes (perhaps 2) the expected + computation complexity of the incremental update exceeds the + complete recalculation. Thus, this annex specifies the algorithm + only for the full update. + + 3) If only End System LSP information has changed, it is not necessary + to re-compute the entire Dijkstra tree. If the proper data + structures are used, End Systems (including IP reachability + entries) may be attached and detached as leaves of the tree and + their forwarding information base entries altered as appropriate. + + The original SPF algorithm does not support load splitting over + + + +Callon [Page 67] + +RFC 1195 OSI ISIS for IP and Dual Environments December 1990 + + + multiple paths. The algorithm in this annex does permit load + splitting by identifying a set of equal cost paths to each + destination rather than a single least cost path. + +C.1.1 Databases + + PATHS -- This represents an acyclic directed graph of shortest paths + from the system S performing the calculation. It is stored as a set + of triples of the form , where: + + N is a system identifier. In the level 1 algorithm, N is a + 6 octet ID for OSI end systems, a 7 octet ID for routers, or + an 8 octet IP Internal Reachability Information entry. For a + router which is not a pseudonode, it is the 6 octet system ID, + with a 0 appended octet. For a pseudonode it is a true 7 octet + quantity, comprised of the 6 octet Designated Intermediate + System ID and the extra octet assigned by the Destinated Router. + The IP Internal Reachability Information entries consist of a + 4 octet IP address plus a 4 octet subnet mask, and will always + be a leaf, i.e., "End System" in PATHS. + + In the level 2 algorithm, N is either a 7 octet router or + pseudonode ID (as in the level 1 algorithm); a variable + length OSI address prefix; an 8 octet IP Internal Reachability + Information Entry, or an 8 octet IP External Reachability + Information entry. The variable length OSI address prefixes, + and 8 octet IP Reachability Information entries will always + be a leaf, i.e., "End System" in PATHS. As above, the IP + Reachability Information entries consist of an [IP address, + subnet mask] combination. + + d(N) is N's distance from S (i.e., the total metric value + from N to S). + + {Adj(N)} is a set of valid adjacencies that S may use for + forwarding to N. + + When a system is placed on PATHS, the path(s) designated by its + position in the graph is guaranteed to be a shortest path. + + TENT -- This is a list of triples of the form , + where N, d(N), and {Adj(N)} are as defined above for PATHS. + + TENT can intuitively be thought of as a tentative placement + of a system in PATHS. In other words, the triple + in TENT means that if N were placed in PATHS, d(N) would be x, + but N cannot be placed on PATHS until is is guaranteed that + no path shorter than x exists. + + + +Callon [Page 68] + +RFC 1195 OSI ISIS for IP and Dual Environments December 1990 + + + Similarly, the triple in TENT means that if N + were placed in PATHS, then d(N) would be x via either + adjacency A or B. + + Note: It is suggested that the implementation maintain the database + TENT as a set of list of triples of the form <*,Dist,*>, sorted by + distance Dist. In addition, it is necessary to be able to process + those systems which are pseudonodes before any non-pseudonodes at the + same distance Dist. + + The 8 octet system identifiers which specify IP reachability entries + must always be distinguishable from other system identifiers. As + specified in section 3.10, two IP reachability entries which differ + only in the subnet mask are still considered to be separate, and will + therefore have distinct system identifiers N. The SPF algorithm will + therefore calculate routes to each such entry, and the correct entry + will be selected in the forwarding process. + +C.1.2 Use of Metrics in the SPF Algorithm + + Internal metrics are not comparable to external metrics. For external + routes (routes to destinations outside of the routing domain), the + cost d(N) of the path from N to S may include both internal and + external metrics. d(N) may therefore be maintained as a two- + dimensioned vector quantity (specifying internal and external metric + values). + + d(N) is initialized to [internal metric = 0, external metric = 0]. + + In incrementing d(N) by 1, if the internal metric value is less than + the maximum value MaxPathMetric, then the internal metric value is + incremented by one and the external metric value left unchanged; if + the internal metric value is equal to the maximum value + MaxPathMetric, then the internal metric value is set to 0 and the + external metric value is incremented by 1. Note that this can be + implemented in a straightforward manner by maintaining the external + metric as the high order bits of the distance. + + In the code of the algorithm below, the current path length is held + in the variable "tentlength". This variable is a two-dimensional + quantity tentlength=[internal metric, external metric], and is used + for comparing the current path length with d(N) as described above. + Tentlength is incremented in the same manner as d(N). + +C.1.3 Overview of the Algorithm + + The basic algorithm, which builds PATHS from scratch, starts out by + putting the system doing the computation on PATHS (no shorter path to + + + +Callon [Page 69] + +RFC 1195 OSI ISIS for IP and Dual Environments December 1990 + + + SELF can possibly exist). TENT is then pre-loaded from the local + adjacency database. + + Note that a system is not placed on PATHS unless no shorter path to + that system exists. When a system N is placed on PATHS, the path to + each neighbor M of N, through N, is examined, as the path to N plus + the link from N to M. If is in PATHS, this new path will be + longer, and thus ignored. + + If is in TENT, and the new path is shorter, the old entry is + removed from TENT and the new path is placed in TENT. If the new path + is the same length as the one in TENT, then the set of potential + adjacencies {Adj(M)} is set to the union of the old set (in TENT) and + the new set {Adj(N)}. If M is not in TENT, then the path is added to + TENT. + + Next the algorithm finds the triple in TENT, with + minimal x. Note: This is done efficiently because of the optimization + described above. When the list of triples for distance Dist is + exhausted, the algorithm then increments Dist until it finds a list + with a triple of the form <*,Dist,*>. + + N is placed in PATHS. We know that no path to N can be shorter than x + at this point because all paths through systems already in PATHS have + already been considered, and paths through systems in TENT still have + to be greater than x because x is minimal in TENT. + + When TENT is empty, PATHS is complete. + + Note that external metrics can only occur in "IP External + Reachability Information" entries, which correspond to a leaf (i.e., + End System in PATHS). Any route utilizing an entry with an external + metric will always be considered to be less desireable than any entry + which uses an internal metric. This implies that in the addition of + systems to PATHS, all systems reachable via internal routes are + always added before any system reachable via external routes. + +C.1.4 The Algorithm + + The Decision Process Algorithm must be run once for each supported + routing metric (i.e., for each supported Type of Service). A level 1 + router runs the algorithm using the level 1 LSP database to compute + level 1 paths (for those level 1 routers which are not level 2 + routers, this includes the path to the nearest attached level 2 + router). Level 2 routers also separately run the algorithm using the + level 2 LSP database to compute level 2 paths. IP-capable level 2 + routers must keep level 2 internal IP routes separate from level 2 + external IP routes. + + + +Callon [Page 70] + +RFC 1195 OSI ISIS for IP and Dual Environments December 1990 + + + Note that this implies that routers which are both level 1 and level + 2 routers, and which support all four routing metrics, must run the + SPF algorithm 8 times (assuming partition repair is not implemented). + + If this system is a Level 2 Router which supports the partition + repair optional function the Decision Process algorithm for computing + Level 1 paths must be run twice for the default metric. This first + execution is done to determine which of the area's + manualAreaAddresses are reachable in this partition, and to elect a + Partition Designated Level 2 Router for the partition. The partition + Designated Level 2 Router will determine if the area is partitioned + and will create virtual Level 1 links to the other Partition + Designated Level 2 Routers in the area in order to repair the Level 1 + partition. This is further described in section 7.2.10 of [1]. + + The SPF algorithm specified here will calculate routes for both OSI + and IP. In particular, routes are calculated to all system + identifiers N, where N may specify an OSI End System, the OSI address + of a router, or an IP reachability entry. In computing the forwarding + database, it is an implementation specific issue whether the IP + forwarding database is kept separately from the OSI forwarding + database. Where appropriate, this annex will refer separately to + entries in these two forwarding data bases. This is not meant to + preclude any specific implementation method. + + OSI and IP use separate mechanisms to determine whether a packet is + in the area (in particular, OSI makes use of area addresses, and IP + determines that a destination is not in an area by looking in the + level 1 forwarding database and determining that no entry exists for + that destination within the area). The route to the nearest level 2 + router will result in separate entries in the forwarding database for + OSI and IP. For IP, the route to the nearest attached level 2 router + may be entered in the forwarding database as a default route (i.e., a + route with a subnet mask of all 0). + + One approach would be to put the results of each Dijkstra algorithm + in a separate forwarding database. For a router which supports both + level 1 and level 2 routing (including level 2 internal and level 2 + external routes), and which supports all four types of service, this + would result in twelve separate forwarding databases for IP. + Implementations may choose to minimize the number of forwarding + databases by combining the information from the multiple Dijkstra + calculations into a single database per supported TOS. This is + discussed in section C.2 below. + + The SPF algorithm specified in section C.2.3 of [1] is amended to + appear as follows: + + + + +Callon [Page 71] + +RFC 1195 OSI ISIS for IP and Dual Environments December 1990 + + + Step 0: Initialize TENT and PATHS to empty. Initialize tentlength to + [internalmetric=0, externalmetric=0]. + + (tentlength is the pathlength of elements in TENT that we are + examining.) + + 1) Add to PATHS, where W is a special value indicating + traffic to SELF is passed up to internal processes (rather than + forwarded). + + 2) Now pre-load TENT with the local adjacency database (Each + entry made to TENT must be marked as being either an End System + or a router to enable the check at the end of Step 2 to be made + correctly - Note that each local IP reachability entry is + included as an adjacency, and is marked as being an End System). + For each adjacency Adj(N) (including level 1 OSI Manual + Adjacencies, or level 2 OSI enabled reachable addresses, and + IP reachability entries) on enabled circuits, to system N of + SELF in state "Up" compute: + + d(N) = cost of the parent circuit of the adjacency (N), + obtained from metric.k , where k = one of {default metric, + delay metric, monetary metric, error metric} + + Adj(N) = the adjacency number of the adjacency to N + + 3) If a triple is in TENT, then: + + If x = d(N), then {Adj(M)} <--- {Adj(M)} U {Adj(N)}. + + 4) If N is a router or an OSI End System entry, and there are now + more adjacencies in {Adj(M)} than maximumPathSplits, then remove + excess adjacencies as described in Clause 7.2.7 of [1]. If N + is an IP Reachability Entry, then excess adjacencies may be + removed as desired. This will not effect the correctness of + routing, but may eliminate the determinism for IP routes (i.e., + IP packets still follow optimal routes within an area, but + where multiple equally good routes exist, will not necessarily + follow precisely the route that any one particular router + would have anticipated). + + 5) If x < d(N), do nothing. + + 6) If x > d(N), remove from TENT and add the triple + . + + 7) If no triple is in TENT, then add + to TENT. + + + +Callon [Page 72] + +RFC 1195 OSI ISIS for IP and Dual Environments December 1990 + + + 8) Now add systems to which the local router does not have adjacencies, + but which are mentioned in neighboring pseudonode LSPs. The + adjacency for such systems is set to that of the designated router. + Note that this does not include IP reachability entries from + neighboring pseudonode LSPs. In particular, the pseudonode LSPs + do not include IP reachability entries. + + 9) For all broadcast circuits in state "On", find the pseudonode + LSP for that circuit (specifically, the LSP with number zero and + with the first 7 octets of LSPID equal to LnCircuitID for that + circuit, where n is 1 (for level 1 routing) or 2 (level 2 + routing)). If it is present, for all the neighbors N reported in + all the LSPs of this pseudonode which do not exist in TENT add + an entry to TENT, where: + + d(N) = metric.k of the circuit. + Adj(N) = the adjacency number of the adjacency to the DR. + + 10) Go to Step 2. + + Step 1: Examine the zeroeth link state PDU of P, the system just + placed on PATHS (i.e., the LSP with the same first 7 octets of LSPID + as P, and LSP number zero). + + 1) If this LSP is present, and the "Infinite Hippity Cost" bit is + clear, then for each LSP of P (i.e., all LSPs with the same + first 7 octets of LSPID and P, irrespective of the value of + LSP number) compute: + + dist(P,N) = d(P) + metric.k(P,N) + + for each neighbor N (both End System and router) of the system P. If + the "Infinite Hippity Cost" bit is set, only consider the End System + neighbors of the system P. Note that the End Systems neighbors of the + system P includes IP reachable address entries included in the LSPs + from system P. Here, d(P) is the second element of the triple + + + + and metric.k(P,N) is the cost of the link from P to N as reported in + P's link state PDU. + + 2) If dist(P,N) > MaxPathMetric, then do nothing. + + 3) If is in PATHS, then do nothing. + + Note: d(N) must be less than dist(P,N), or else N would not + have been put into PATHS. An additional sanity check may be + + + +Callon [Page 73] + +RFC 1195 OSI ISIS for IP and Dual Environments December 1990 + + + done here to ensure that d(N) is in fact less than dist(P,N) + + 4) If a triple is in TENT, then: + + a) If x = dist(P,N), then {Adj(N)} <-- {Adj(N)} U {Adj(P)}. + + b) If N is a router or an OSI end system, and there are now more + adjacencies in {Adj(N)} than maximumPath Splits, then remove + excess adjacencies, as described in clause 7.2.7 of [1]. For + IP Reachability Entries, excess adjacencies may be removed as + desired. This will not effect the correctness of routing, but + may eliminate the determinism for IP routes (i.e., IP packets + will still follow optimal routes within an area, but where + multiple equally good routes exist, will not necessarily follow + precisely the route that any one particular router would have + anticipated). + + c) if x < dist(P,N), do nothing. + + d) if x > dist(P,N), remove from TENT, and add + + + 5) if no triple is in TENT, then add + to TENT. + + Step 2: If TENT is empty, stop. Else: + + 1) Find the element , with minimal x as follows: + + a) If an element <*,tentlength,*> remains in TENT in the list for + tentlength, choose that element. If there are more than one + elements in the list for tentlength, choose one of the elements + (if any) for a system which is a pseudonode in preference to one + for a non-pseudonode. If there are no more elements in the list + for tentlength, increment tentlength and repeat Step 2. + + b) Remove from TENT. + + c) Add to PATHS. + + d) If this is the Level 2 Decision Process running, and the system + just added to PATHS listed itself as Partition Designated Level 2 + Intermediate system, then additionally add + to PATHS, where AREA.P is the Network Entity Title of the other + end of the Virtual Link, obtained by taking the first AREA + listed in P's LSP and appending P's ID. + + e) If the system just added to PATHS was an end system, go to + + + +Callon [Page 74] + +RFC 1195 OSI ISIS for IP and Dual Environments December 1990 + + + step 2. Else go to Step 1. + + NOTE - In the level 2 context, the "End Systems" are the set of + Reachable Address Prefixes (for OSI), the set of Area Addresses with + zero cost (again, for OSI), plus the set of IP reachability entries + (including both internal and external). + +C.2 Forwarding of IP packets + + The SPF algorithm specified in section C.1 may be used to calculate + (logically) separate IP forwarding tables for each type of service, + and for level 1, level 2 internal, and level 2 external routes. + Section C.2.1 describes how to forward IP packets, based on these + multiple forwarding databases. Section C.2.2 describes how the + multiple forwarding databases can be combined into a single + forwarding database per supported TOS. + +C.2.1 Basic Method for Forwarding IP packets + + For level 1-only routers: + + - Determine if the IP destination address matches any entry in the + level 1 forwarding table for the specified TOS. + + - Determine if the IP destination address matches any entry in the + level 1 forwarding table for the default TOS. + + - If default TOS resulted in more specific entry, forward according + to default TOS. + + - If equally specific entries found, or specified TOS resulted in + more specific entry, forward according to specified TOS + + - If no entry was found (which includes no default route entry), then + destination is unreachable. + + Note: For level 1 only routers, the route to the nearest attached + level 2 router will be entered into the forwarding database as a + default route (i.e., a route with a subnet mask which is all 0). Thus + this last event (no entry found) can occur only if there is no + attached level 2 router reachable in the area. + + For routers which are both level 1 and level 2 routers: + + - Determine if the IP destination address matches any entry in the + level 1 forwarding table for the specified TOS. + + - Determine if the IP destination address matches any entry in the + + + +Callon [Page 75] + +RFC 1195 OSI ISIS for IP and Dual Environments December 1990 + + + level 1 forwarding table for the default TOS. + + - If default TOS resulted in more specific entry (i.e., more bits in + the subnet mask take the value 1), forward according to default TOS. + + - If equally specific entries found, or specified TOS resulted in + more specific entry, forward according to specified TOS + + - If no entry found: + + - Determine if the IP destination address matches any entry in the + level 2 internal forwarding table for the specified TOS. + + - Determine if the IP destination address matches any entry in the + level 2 internal forwarding table for the default TOS. + + - If default TOS resulted in more specific entry, forward according + to default TOS. + + - If equally specific entries found, or specified TOS resulted in + more specific entry, forward according to specified TOS + + - If no entry found: + + - Determine if the IP destination address matches any entry in the + level 2 external forwarding table for the specified TOS. + + - Determine if the IP destination address matches any entry in the + level 2 external forwarding table for the default TOS. + + - If default TOS resulted in more specific entry, forward according + to default TOS. + + - If equally specific entries found, or specified TOS resulted in + more specific entry, forward according to specified TOS + + - If no entry is found, then destination is unreachable + + For level 2-only routers, the above algorithm can be used, except + since there is no level 1 forwarding database, the corresponding + steps can be skipped. + + As discussed in section 3.10.2, for level 2 routers which are + announcing manually configured summary addresses in their level 2 + LSPs, in some cases there will exist IP addresses which match the + manually configured addresses, but which do not match any addresses + which are reachable via level 1 routing in the area. Packets to such + addresses are handled according to the rules specified in section + + + +Callon [Page 76] + +RFC 1195 OSI ISIS for IP and Dual Environments December 1990 + + + 3.10.2. This may be accomplished by adding the manually configured + [IP address, subnet mask] entry to the level 2 forwarding database + (for the appropriate TOS), with a special "next hop" address which + specifies that packets for which this entry is selected are to be + discarded. This will work correctly because more desireable entries + (such as delivering the packet via level 1 routing to the correct + destination, or a more specific level 2 route) will automatically + take precedence according to the forwarding rules specified above. + Less desireable routes (such as using a level 2 external route to the + "default route" entry) are not possible because other level 2 routers + will believe the summary addresses advertised by this router. + +C.2.2 Reduction of IP Forwarding Databases + + The multiple forwarding databases used in the basic forwarding method + in section C.2.1 can be reduced, by combining the multiple databases + into one database for each supported TOS. + + For reduction of IP forwarding databases, it is assumed that for any + two overlapping address entries, either the entries are identical, or + one range contains the other. In other words, for any two [IP + address, subnet mask] entries A and B, if there is at least one IP + address which matches both entries, then either: (i) the two entries + are identical; or (ii) entry A contains entry B (i.e., any IP address + which matches entry B also matches entry A); or (iii) entry B + contains entry A (any IP address which matches entry A also matches + entry B). + + Non-contiguous subnet masks can be configured to violate this + assumption. For example, consider the two entries: + + - A=[address="01010101 00000101 00000000 00000000", + mask="11111111 00001111 00000000 00000000"] + + - B=[address="01010101 01010000 00000000 00000000", + mask="11111111 11110000 00000000 00000000"] + + In this case neither entry contains the other. Specifically; + + - there are IP addresses which match both A and B (e.g., + "01010101 01010101 xxxxxxxx xxxxxxxx"), + + - there are IP addresses which match A but not B (e.g., + "01010101 11110101 xxxxxxxx xxxxxxxx") + + - there are IP addresses which match B but not A (e.g., + "01010101 01011111 xxxxxxxx xxxxxxxx"). + + + + +Callon [Page 77] + +RFC 1195 OSI ISIS for IP and Dual Environments December 1990 + + + The reduction of the multiple forwarding databases for each TOS to a + single database for each TOS is based on the use of "best match" + routing, combined with reduction of the entries placed in the + forwarding database in order to eliminate entries which are not to be + selected (based on the order of preference of routes specified in + section 3.10). The specific algorithm for creation of the IP + forwarding database can be described as follows: + + 1) Make use of the the Dijkstra algorithm described in section C.1 to + create separate forwarding databases for each supported TOS for + level 1 routes, level 2 internal routes, and level 2 external + routes. (Note that each entry in the forwarding database will + specify an [IP address, subnet mask] combination, as well as the + next hop router for IP packets which match that entry). + + 2) For each level 1 route entry which has been placed in the level 1 + IP forwarding database for a specific TOS, copy that entry into + the overall IP forwarding database for that TOS. + + 3) For each route entry X which has been placed in the level 2 internal + IP forwarding database for a specific TOS, search for overlapping + entries in the level 1 IP forwarding database for the specific TOS, + and also for the default TOS: + + a) If there is any overlapping entry Y in the level 1 forwarding + database (for the specfic TOS, or for the default TOS) such + that either (i) Y contains X; or (ii) Y is identically specific + to X; then ignore entry X. + + b) Otherwise, copy entry X into the overall IP forwarding database + for the specific TOS. + + 4) For each route entry X which has been placed in the level 2 + external IP forwarding database for a specific TOS, search for + overlapping entries in the level 1 IP forwarding database for + the specific TOS, and for the default TOS, and the level 2 + internal IP forwarding database for the specific TOS, and for + the default TOS. + + a) If there is an overlapping entry Y such that either (i) Y + contains X; or (ii) Y is identically specific to X; then + ignore entry X. + + b) Otherwise, copy entry X into the overall IP forwarding database + for the specific TOS. + + This method will result in one forwarding database for each supported + TOS. The forwarding of packets can then be simplified to be as follows: + + + +Callon [Page 78] + +RFC 1195 OSI ISIS for IP and Dual Environments December 1990 + + + 1) For IP packets which map to the default TOS metric (or to an + unsupported TOS metric), search the default TOS forwarding + database and select the entry which has the most specific match. + Forward the packet accordingly. + + 2) For packets which map to a specific (non-default) TOS metric, + search the specific TOS forwarding database and select the entry + j which has the most specific match. Also search the default TOS + forwarding database and select the entry k which has the most + specific match. Forward the packet as follows: + + a) If k is more specific than j, forward according to entry k + + b) If j and k are equally specific, forward according to entry j + + c) If j is more specific than k, forward according to entry j + + + + + + + + + + + + + + + + + + + + + + + + + + + + + + + + + + + +Callon [Page 79] + +RFC 1195 OSI ISIS for IP and Dual Environments December 1990 + + + Annex D + Use of the Authentication Field + + The use of the Authentication field is outside of the scope of this + specification. However, there is a urgent need for simple error + detection/authentication mechanisms (such as a simple password) to + protect against certain types of errors. This annex therefore + proposes a possible use of this field. + + This annex is included for informational purposes. + +D.1 Authentication Field in IS-IS packets + + All IS-IS packets may optionally include the authentication field, as + described in sections 3.9 and 5 of this specification. As described + in section 5, the authentication field is encoded as a (Code, Length, + Value) triplet. This annex proposes that the contents of the Value + field consist of a one octet "Authentication Type" field, plus a + variable length "Authentication Information" field. A specific value + of the "Authentication Type" is assigned to passwords, transmitted in + the clear without encryption. The authentication field is encoded as + follows: + + 7 Authentication Information -- Information used to authenticate + the PDU + + x CODE - 133 + + x LENGTH - total length of the value field + + x VALUE - + No. of Octets + +--------------------------------+ + | Authentication Type | 1 + +--------------------------------+ + | Authentication Information | VARIABLE + +--------------------------------+ + +The Authentication Type is assigned as follows: + + Type = 0 reserved + + Type = 1 simple password + + Type > 1 reserved + + + + + + +Callon [Page 80] + +RFC 1195 OSI ISIS for IP and Dual Environments December 1990 + + +D.2 Authentication Type 1 - Simple Password + + Using this authentication type, a variable length password is passed + in the clear (i.e., not encrypted) in the Authentication Information + field. + + WARNING: The use of a simple password does not provide useful + protection against intentional misbehavior. In particular, since the + password is transmitted in the clear without encryption, it is easy + for a hostile system to intercept the passwords, and to transmit + authenticated packets. The use of simple passwords should be + considered only as a weak protection against accidental errors such + as accidental misconfiguration. + + The password shall be configured on a per-link, per-area, and per- + domain basis. Specifically, when this form of authentication is used: + + - IS-IS Hello and 9542 IS Hello packets shall contain the + per-link password + + - Level 1 Link State Packets shall contain the per-area password + + - Level 2 Link State Packets shall contain the per-domain password + + - Level 1 Sequence Number Packets shall contain the per-area password + + - Level 2 Sequence Number Packets shall contain the per-domain + password + + Also, each of these three passwords shall be configured with: (i) + "Transmit Password", whose value is a single password, and (ii) + "Receive Passwords", whose value is a set of passwords. The transmit + password value is always transmitted. However, any password contained + in the receive password set will be accepted on receipt. This method + allows the graceful changing of passwords without temporary loss of + connectivity. + + For example, consider the case that an area has the configured area + password "OLDAREAPASSWORD". In this case, the per-area transmit + password value is set to OLDAREAPASSWORD, and the per-area receive + password value is set to {OLDAREAPASSWORD}. Suppose that it is + desired to change the per-area password to "NEWERPASSWORD". The + first step would be to manually configure all of the routers in the + area to set the per-area receive password value to {OLDAREAPASSWORD, + NEWERPASSWORD}. When this step is complete, then all routers in the + area will still be using the old password OLDAREAPASSWORD in their + level 1 LSPs and SNPs. However, they will also accept the alternate + password NEWERPASSWORD. The second step would be to configure the + + + +Callon [Page 81] + +RFC 1195 OSI ISIS for IP and Dual Environments December 1990 + + + routers in the area to set the per-area transmit password to + NEWERPASSWORD. When the second step is complete, then all routers + will be using the new value of the per-area password, but will accept + the old value as well. Finally, the third step is to change all + routers in the area to have the per-area receive password set to + {NEWERPASSWORD}. + + By configuring transmit and receive values for the passwords in this + manner, it is possible to maintain continuous correct operation. For + example, in the middle of the second step in the above example, some + of the routers in the area will be transmitting level 1 LSPs and SNPs + using the old password OLDAREAPASSWORD, and some will be transmitting + level 1 LSPs and SNPs using the new password NEWERPASSWORD. However, + during the second step of the transition all routers in the area will + accept level 1 LSPs and SNPs using either password. + + + + + + + + + + + + + + + + + + + + + + + + + + + + + + + + + + + + +Callon [Page 82] + +RFC 1195 OSI ISIS for IP and Dual Environments December 1990 + + + Annex E + Interaction of the Integrated IS-IS with Brouters + + A "brouter" is a device which operates an both a bridge and a router. + One possible type of brouter acts as a router for IP traffic, and + acts as a bridge for all other types of traffic. + + Depending upon the manner in which a brouter is implemented, and + depending upon the network topology, there is an obscure bug which + can result from the interaction of the Integrated IS-IS protocol, and + brouters. This appendix gives an example of the bug, and proposes a + simple correction to the operation of brouters to correct the + problem. + + This annex is included for informational purposes. + +E.1 The Problem + + Suppose that we have a brouter which treats IP packets as if it were + a normal IP router, and which treats all other packets as if it is a + bridge. + + Suppose that two routers "X" and "Y" (which implement the integrated + IS-IS protocol), two Ethernets, and a brouter B are all connected as + follows: + + + | | + +----+---+ +----+---+ + | Router | | Router | + | X | | Y | + +----+---+ +----+---+ + | | + -----+------------+- -+------------+---- + | | + +-+-----+-+ + | Brouter | + | B | + +---------+ + + + Here suppose that X and Y are running the Integrated IS-IS protocol, + and are both level 1 routers in the same area. Thus X and Y send IS- + IS Hello packets on the LAN. These Hello packets are received and + forwarded by the brouter (using normal bridge functions). Similarly, + X and Y receive each other's IS-IS LSP packets. In this way, it + appears to the Brouter that X and Y are exchanging OSI packets, and + so they are forwarded using normal bridge functions. It appears to X + + + +Callon [Page 83] + +RFC 1195 OSI ISIS for IP and Dual Environments December 1990 + + + and Y as if they are on the same LAN, and so they learn each others + 48-bit Ethernet addresses and exchange routing information. + + Now, suppose that X receives an IP packet, which it needs to forward + via Y. Since X thinks that it and Y are on the same Ethernet, it just + forwards the IP packet directly, using normal Ethernet encapsulation + and using the 48-bit Ethernet address of Y as the destination address + in the Ethernet header. Brouter B, when thinking as a bridge says: + "this is an IP packet, I don't forward this as a bridge". Brouter B, + when thinking like an IP router says: "this is an IP packet, I know + how to forward IP packets. However, this is sent to an Ethernet + address which is not me, thus I will ignore it". The result is that + the IP packet does not get forwarded. + + This problem relates directly to the fact that X and Y are exchanging + OSI packets to determine the connectivity of the path between them, + but then are trying to send IP packets over the path. Also, there is + a device between X and Y on the path which treats OSI and IP packets + differently. + + Also note that this problem can also occur in more complex + topologies, whenever a brouter is treating OSI and IP packets in a + fundamentally different manner. + +E.2 Possible Solutions + +E.2.1 More Sophisticated Brouter + + One solution is that brouter B needs to be a little more + sophisticated. In particular, it needs to use the following rules: + + - For packets which are not IP packets, act as a bridge (this is the + same as before). + + - For IP packets sent to an Ethernet broadcast or multicast address, + act as an IP router (this is also the same as before). + + - For IP packets sent to my own Ethernet 48-bit address(es), act as + an IP router (this is also the same as before). + + - For IP packets sent to a single station 48-bit address which is not + one of my addresses, act at a bridge (THIS IS NEW). + + With this change, the IP packet transmitted from X to Y is forwarded + by the brouter, acting as a bridge. This allows the Brouter and the + multiprotocol routers to interoperate properly. + + + + + +Callon [Page 84] + +RFC 1195 OSI ISIS for IP and Dual Environments December 1990 + + +E.2.2 Dual Router / Brouter + + An alternate solution would be for the Brouter to route both OSI and + IP equally. If the Brouter used the integrated IS-IS for this + purpose, then it could be part of the same routing domain and + interoperate like any other dual router (except for the ability to + bridge other protocol suites). If it used other protocols for + routing OSI and IP, then it would need to be part of another routing + domain, and could interoperate with integrated IS-IS routers like any + other external router. + + + + + + + + + + + + + + + + + + + + + + + + + + + + + + + + + + + + + + + + + +Callon [Page 85] + \ No newline at end of file -- cgit v1.2.3