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/rfc1142.txt | 12314 ++++++++++++++++++++++++++++++++++++++++++++++++++ 1 file changed, 12314 insertions(+) create mode 100644 doc/rfc/rfc1142.txt (limited to 'doc/rfc/rfc1142.txt') diff --git a/doc/rfc/rfc1142.txt b/doc/rfc/rfc1142.txt new file mode 100644 index 0000000..3f4bf0b --- /dev/null +++ b/doc/rfc/rfc1142.txt @@ -0,0 +1,12314 @@ + +Network Working Group D. Oran, Editor +Request for Comments: 1142 Digital Equipment Corp. + February 1990 + + + OSI IS-IS Intra-domain Routing Protocol + +Status of this Memo + + This RFC is a republication of ISO DP 10589 as a service to the + Internet community. This is not an Internet standard. + Distribution of this memo is unlimited. + + +NOTE: This is a bad ASCII version of this document. The official +document is the PostScript file, which has the diagrams in place. +Please use the PostScript version of this memo. + + +ISO/IEC DIS 10589 + +Information technology Telecommunications and information exchange +between systems Interme diate 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) Technologies de l'information Communication de donnies et +ichange d'information entre systhmes Protocole intra-domain de routage +d'un systhme intermediare ` un systhme intermediare ` utiliser +conjointement avec le protocole fournissant le service de riseau en +mode sans connexion (ISO 8473) UDC 00000.000 : 000.0000000000 +Descriptors: + +Contents + Introduction iv + 1 Scope and Field of Application 1 + 2 References 1 + 3 Definitions 2 + 4 Symbols and Abbreviations 3 + 5 Typographical Conventions 4 + 6 Overview of the Protocol 4 + 7 Subnetwork Independent Functions 9 + 8 Subnetwork Dependent Functions 35 + 9 Structure and Encoding of PDUs 47 + 10 System Environment 65 + 11 System Management 67 + 12 Conformance 95 + Annex A PICS Proforma 99 + Annex B Supporting Technical Material 105 + Annex C Implementation Guidelines and Examples 109 + Annex D Congestion Control and Avoidance 115 + +Introduction + +This Protocol is one of a set of International Standards produced to +facilitate the interconnection of open systems. The set of standards +covers the services and protocols re quired to achieve such +interconnection. This Protocol is positioned with respect to other +related standards by the layers defined in the ISO 7498 and by the +structure defined in the ISO 8648. In particular, it is a protocol of +the Network Layer. This protocol permits Intermediate Systems within a +routeing Domain to exchange configuration and routeing information to +facilitate the operation of the route ing and relaying functions of +the Network Layer. The protocol is designed to operate in close +conjunction with ISO 9542 and ISO 8473. ISO 9542 is used to establish +connectivity and reachability between End Systems and Inter mediate +Systems on individual Subnetworks. Data is carried by ISO 8473. The +related algo rithms for route calculation and maintenance are also +described. The intra-domain ISIS routeing protocol is intended to +support large routeing domains consisting of combinations of many +types of subnetworks. This includes point-to-point links, multipoint +links, X.25 subnetworks, and broadcast subnetworks such as ISO 8802 +LANs. In order to support large routeing domains, provision is made +for Intra-domain routeing to be organised hierarchically. A large +domain may be administratively divided into areas. Each system +resides in exactly one area. Routeing within an area is referred to as +Level 1 routeing. Routeing between areas is referred to as Level 2 +routeing. Level 2 Intermediate systems keep track of the paths to +destination areas. Level 1 Intermediate systems keep track of the +routeing within their own area. For an NPDU destined to another area, +a Level 1 Intermediate system sends the NPDU to the nearest level 2 IS +in its own area, re gardless of what the destination area is. Then the +NPDU travels via level 2 routeing to the destination area, where it +again travels via level 1 routeing to the destination End System. + +Information technology + +Telecommunications and information exchange between systems +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) + +1 Scope and Field of Application + +This International Standard specifies a protocol which is used by +Network Layer entities operating ISO 8473 in In termediate Systems to +maintain routeing information for the purpose of routeing within a +single routeing domain. The protocol herein described relies upon the +provision of a connectionless-mode underlying service.11See ISO 8473 +and its Addendum 3 for the mechanisms necessary to realise this +service on subnetworks based on ISO 8208, ISO 8802, and the OSI Data +Link Service. + +This Standard specifies: + +a)procedures for the transmission of configuration and +routeing information between network entities resid +ing in Intermediate Systems within a single routeing +domain; + +b)the encoding of the protocol data units used for the +transmission of the configuration and routeing infor +mation; + +c)procedures for the correct interpretation of protocol +control information; and + +d)the functional requirements for implementations +claiming conformance to this Standard. + +The procedures are defined in terms of: + +a)the interactions between Intermediate system Network +entities through the exchange of protocol data units; +and + +b)the interactions between a Network entity and an un +derlying service provider through the exchange of +subnetwork service primitives. + +c)the constraints on route determination which must be +observed by each Intermediate system when each has +a routeing information base which is consistent with +the others. + +2 References + +2.1 Normative References + +The following standards contain provisions which, through reference in +this text, constitute provisions of this Interna tional Standard. At +the time of publication, the editions in dicated were valid. All +standards are subject to revision, and parties to agreements based on +this International Stan dard are encouraged to investigate the +possibility of apply ing the most recent editions of the standards +listed below. Members of IEC and ISO maintain registers of currently +valid International Standards. ISO 7498:1984, Information processing +systems Open Systems Interconnection Basic Reference Model. ISO +7498/Add.1:1984, Information processing systems Open Systems +Interconnection Basic Reference Model Addendum 1: Connectionless-mode +Transmission. ISO 7498-3:1989, Information processing systems Open +Systems Interconnection Basic Reference Model Part 3: Naming and +Addressing. ISO 7498-4:1989, Information processing systems Open +Systems Interconnection Basic Reference Model Part 4: Management +Framework. ISO 8348:1987, Information processing systems Data +communications Network Service Definition. ISO 8348/Add.1:1987, +Information processing systems Data communications Network Service +Definition Addendum 1: Connectionless-mode transmission. ISO +8348/Add.2:1988, Information processing systems Data communications +Network Service Definition Addendum 2: Network layer addressing. ISO +8473:1988, Information processing systems Data communications Protocol +for providing the connectionless-mode network service. ISO +8473/Add.3:1989, Information processing systems Telecommunications and +information exchange between +systems Protocol for providing the connectionless- +mode network service Addendum 3: Provision of the +underlying service assumed by ISO 8473 over +subnetworks which provide the OSI data link service. +ISO 8648:1988, Information processing systems Open +Systems Interconnection Internal organisation of the +Network Layer. +ISO 9542:1988, Information processing systems Tele +communications and information exchange between sys +tems End system to Intermediate system Routeing ex +change protocol for use in conjunction with the protocol +for providing the connectionless -mode network service +(ISO 8473). +ISO 8208:1984, Information processing systems Data +communications X.25 packet level protocol for Data +terminal equipment +ISO 8802:1988, Information processing systems Tele +communications and information exchange between sys +tems Local area networks. +ISO/TR 9575:1989, Information technology Telecom +munications and information exchange between systems + OSI Routeing Framework. +ISO/TR 9577:1990, Information technology Telecom +munications and information exchange between systems + Protocol Identification in the Network Layer. +ISO/IEC DIS 10165-4:, Information technology Open +systems interconnection Management Information Serv +ices Structure of Management Information Part 4: +Guidelines for the Definition of Managed Objects. +ISO/IEC 10039:1990, IPS-T&IEBS MAC Service Defini +tion. + +2.2 Other References + +The following references are helpful in describing some of +the routeing algorithms: + +McQuillan, J. et. al., The New Routeing Algorithm for the +ARPANET, IEEE Transactions on Communications, May +1980. + +Perlman, Radia, Fault-Tolerant Broadcast of Routeing In +formation, Computer Networks, Dec. 1983. Also in IEEE +INFOCOM 83, April 1983. + +Aho, Hopcroft, and Ullman, Data Structures and Algo +rithms, P204208 Dijkstra algorithm. + +3 Definitions + +3.1 Reference Model definitions + +This International Standard makes use of the following +terms defined in ISO 7498: + +a)Network Layer +b)Network Service access point +c)Network Service access point address +d)Network entity +e)Routeing +f)Network protocol +g)Network relay +h)Network protocol data unit + +3.2 Network Layer architecture +definitions + +This International Standard makes use of the following +terms defined in ISO 8648: + + +a)Subnetwork +b)End system +c)Intermediate system +d)Subnetwork service +e)Subnetwork Access Protocol +f)Subnetwork Dependent Convergence Protocol +g)Subnetwork Independent Convergence Protocol + +3.3 Network Layer addressing +definitions + +This International Standard makes use of the following +terms defined in ISO 8348/Add.2: + + +a)Subnetwork address +b)Subnetwork point of attachment +c)Network Entity Title +3.4 Local Area Network Definitions + This International Standard makes use of the following +terms defined in ISO 8802: +a)Multi-destination address +b)Media access control +c)Broadcast medium +3.5 Routeing Framework Definitions + This document makes use of the following terms defined in +ISO/TR 9575: +a)Administrative Domain +b)Routeing Domain +c)Hop +d)Black hole + + +3.6 Additional Definitions +For the purposes of this International Standard, the follow +ing definitions apply: +3.6.1 +Area: A routeing subdomain which maintains de +tailed routeing information about its own internal +composition, and also maintains routeing informa +tion which allows it to reach other routeing subdo +mains. It corresponds to the Level 1 subdomain. +3.6.2 +Neighbour: An adjacent system reachable by tra +versal of a single subnetwork by a PDU. +3.6.3 +Adjacency: A portion of the local routeing infor +mation which pertains to the reachability of a sin +gle neighbour ES or IS over a single circuit. +Adjacencies are used as input to the Decision Proc +ess for forming paths through the routeing domain. +A separate adjacency is created for each neighbour +on a circuit, and for each level of routeing (i.e. +level 1 and level 2) on a broadcast circuit. +3.6.4 +Circuit: The subset of the local routeing informa +tion base pertinent to a single local SNPA. +3.6.5 +Link: The communication path between two +neighbours. +A Link is up when communication is possible +between the two SNPAs. +3.6.6 +Designated IS: The Intermediate system on a +LAN which is designated to perform additional du +ties. In particular it generates Link State PDUs on +behalf of the LAN, treating the LAN as a +pseudonode. +3.6.7 +Pseudonode: Where a broadcast subnetwork has n +connected Intermediate systems, the broadcast +subnetwork itself is considered to be a +pseudonode. +The pseudonode has links to each of the n Interme +diate systems and each of the ISs has a single link +to the pseudonode (rather than n-1 links to each of +the other Intermediate systems). Link State PDUs +are generated on behalf of the pseudonode by the +Designated IS. This is depicted below in figure 1. +3.6.8 +Broadcast subnetwork: A subnetwork which sup +ports an arbitrary number of End systems and In + +termediate systems and additionally is capable of +transmitting a single SNPDU to a subset of these +systems in response to a single SN_UNITDATA +request. +3.6.9 +General topology subnetwork: A subnetwork +which supports an arbitrary number of End sys +tems and Intermediate systems, but does not sup +port a convenient multi-destination connectionless +trans + +mission facility, as does a broadcast sub + +net + + +work. +3.6.10 +Routeing Subdomain: a set of Intermediate sys +tems and End systems located within the same +Routeing domain. +3.6.11 +Level 2 Subdomain: the set of all Level 2 Inter +mediate systems in a Routeing domain. +4 Symbols and Abbreviations +4.1 Data Units +PDU Protocol Data Unit +SNSDU Subnetwork Service Data Unit +NSDU Network Service Data Unit +NPDU Network Protocol Data Unit +SNPDU Subnetwork Protocol Data Unit + +4.2 Protocol Data Units +ESH PDU ISO 9542 End System Hello Protocol Data +Unit +ISH PDU ISO 9542 Intermediate System Hello Protocol +Data Unit +RD PDU ISO 9542 Redirect Protocol Data Unit +IIH Intermediate system to Intermediate system +Hello Protocol Data Unit +LSP Link State Protocol Data Unit +SNP Sequence Numbers Protocol Data Unit +CSNP Complete Sequence Numbers Protocol Data +Unit +PSNP Partial Sequence Numbers Protocol Data Unit + + +4.3 Addresses +AFI Authority and Format Indicator +DSP Domain Specific Part +IDI Initial Domain Identifier +IDP Initial Domain Part +NET Network Entity Title +NSAP Network Service Access Point +SNPA Subnetwork Point of Attachment + +4.4 Miscellaneous +DA Dynamically Assigned +DED Dynamically Established Data link +DTE Data Terminal Equipment +ES End System +IS Intermediate System +L1 Level 1 +L2 Level 2 +LAN Local Area Network +MAC Media Access Control +NLPID Network Layer Protocol Identifier +PCI Protocol Control Information +QoS Quality of Service +SN Subnetwork +SNAcP Subnetwork Access Protocol +SNDCP Subnetwork Dependent Convergence Protocol +SNICP Subnetwork Independent Convergence Proto +col +SRM Send Routeing Message +SSN Send Sequence Numbers Message +SVC Switched Virtual Circuit +5 Typographical Conventions +This International Standard makes use of the following ty +pographical conventions: +a)Important terms and concepts appear in italic type +when introduced for the first time; +b)Protocol constants and management parameters appear +in sansSerif type with multiple words run together. +The first word is lower case, with the first character of +subsequent words capitalised; +c)Protocol field names appear in San Serif type with +each word capitalised. +d)Values of constants, parameters, and protocol fields +appear enclosed in double quotes. + +6 Overview of the Protocol +6.1 System Types +There are the following types of system: +End Systems: These systems deliver NPDUs to other sys +tems and receive NPDUs from other systems, but do +not relay NPDUs. This International Standard does +not specify any additional End system functions be +yond those supplied by ISO 8473 and ISO 9542. +Level 1 Intermediate Systems: These systems deliver and +receive NPDUs from other systems, and relay +NPDUs from other source systems to other destina +tion systems. They route directly to systems within +their own area, and route towards a level 2 Interme +diate system when the destination system is in a dif +ferent area. +Level 2 Intermediate Systems: These systems act as Level 1 +Intermediate systems in addition to acting as a sys +tem in the subdomain consisting of level 2 ISs. Sys +tems in the level 2 subdomain route towards a desti +nation area, or another routeing domain. +6.2 Subnetwork Types +There are two generic types of subnetworks supported. +a)broadcast subnetworks: These are multi-access +subnetworks that support the capability of addressing +a group of attached systems with a single NPDU, for +instance ISO 8802.3 LANs. +b)general topology subnetworks: These are modelled as +a set of point-to-point links each of which connects +exactly two systems. +There are several generic types of general topology +subnetworks: +1)multipoint links: These are links between more +than two systems, where one system is a primary +system, and the remaining systems are secondary +(or slave) systems. The primary is capable of direct +communication with any of the secondaries, but +the secondaries cannot communicate directly +among themselves. +2)permanent point-to-point links: These are links +that stay connected at all times (unless broken, or +turned off by system management), for instance +leased lines or private links. +3)dynamically established data links (DEDs): these +are links over connection oriented facilities, for in +stance X.25, X.21, ISDN, or PSTN networks. +Dynamically established data links can be used in one +of two ways: +i)static point-to-point (Static): The call is estab +lished upon system management action and + +cleared only on system management action (or +failure). +ii)dynamically assigned (DA): The call is estab +lished upon receipt of traffic, and brought +down on timer expiration when idle. The ad +dress to which the call is to be established is +determined dynamically from information in +the arriving NPDU(s). No ISIS routeing +PDUs are exchanged between ISs on a DA cir +cuit. +All subnetwork types are treated by the Subnetwork Inde +pendent functions as though they were connectionless +subnetworks, using the Subnetwork Dependent Conver +gence functions of ISO 8473 where necessary to provide a +connectionless subnetwork service. The Subnetwork De +pendent functions do, however, operate differently on +connectionless and connection-oriented subnetworks. +6.3 Topologies +A single organisation may wish to divide its Administrative +Domain into a number of separate Routeing Domains. +This has certain advantages, as described in ISO/TR 9575. +Furthermore, it is desirable for an intra-domain routeing +protocol to aid in the operation of an inter-domain routeing +protocol, where such a protocol exists for interconnecting +multiple administrative domains. +In order to facilitate the construction of such multi-domain +topologies, provision is made for the entering of static +inter-domain routeing information. This information is pro +vided by a set of Reachable Address Prefixes entered by +System Management at the ISs which have links which +cross routeing domain boundaries. The prefix indicates that +any NSAPs whose NSAP address matches the prefix may +be reachable via the SNPA with which the prefix is associ +ated. Where the subnetwork to which this SNPA is con +nected is a general topology subnetwork supporting dy +namically established data links, the prefix also has associ +ated with it the required subnetwork addressing +information, or an indication that it may be derived from +the destination NSAP address (for example, an X.121 DTE +address may sometimes be obtained from the IDI of the +NSAP address). +The Address Prefixes are handled by the level 2 routeing al +gorithm in the same way as information about a level 1 area +within the domain. NPDUs with a destination address +matching any of the prefixes present on any Level 2 Inter +mediate System within the domain can therefore be relayed +(using level 2 routeing) by that IS and delivered out of the +domain. (It is assumed that the routeing functions of the +other domain will then be able to deliver the NPDU to its +destination.) +6.4 Addresses +Within a routeing domain that conforms to this standard, +the Network entity titles of Intermediate systems shall be +structured as described in 7.1.1. +All systems shall be able to generate and forward data +PDUs containing NSAP addresses in any of the formats +specified by ISO 8348/Add.2. However, NSAP addresses + +of End systems should be structured as described in 7.1.1 in +order to take full advantage of ISIS routeing. Within such +a domain it is still possible for some End Systems to have +addresses assigned which do not conform to 7.1.1, provided +they meet the more general requirements of +ISO 8348/Add.2, but they may require additional configura +tion and be subject to inferior routeing performance. +6.5 Functional Organisation +The intra-domain ISIS routeing functions are divided into +two groups +-Subnetwork Independent Functions +-Subnetwork Dependent Functions +6.5.1 Subnetwork Independent Functions +The Subnetwork Independent Functions supply full-duplex +NPDU transmission between any pair of neighbour sys +tems. They are independent of the specific subnetwork or +data link service operating below them, except for recognis +ing two generic types of subnetworks: +-General Topology Subnetworks, which include +HDLC point-to-point, HDLC multipoint, and dynami +cally established data links (such as X.25, X.21, and +PSTN links), and +-Broadcast Subnetworks, which include ISO 8802 +LANs. +The following Subnetwork Independent Functions are iden +tified +-Routeing. The routeing function determines NPDU +paths. A path is the sequence of connected systems +and links between a source ES and a destination ES. +The combined knowledge of all the Network Layer +entities of all the Intermediate systems within a route +ing domain is used to ascertain the existence of a path, +and route the NPDU to its destination. The routeing +component at an Intermediate system has the follow +ing specific functions: +7It extracts and interprets the routeing PCI in an +NPDU. +7It performs NPDU forwarding based on the desti +nation address. +7It manages the characteristics of the path. If a sys +tem or link fails on a path, it finds an alternate +route. +7It interfaces with the subnetwork dependent func +tions to receive reports concerning an SNPA +which has become unavailable, a system that has +failed, or the subsequent recovery of an SNPA or +system. +7It informs the ISO 8473 error reporting function +when the forwarding function cannot relay an +NPDU, for instance when the destination is un +reachable or when the NPDU would have needed + +to be segmented and the NPDU requested no seg +mentation. +-Congestion control. Congestion control manages the +resources used at each Intermediate system. +6.5.2 Subnetwork Dependent Functions +The subnetwork dependent functions mask the characteris +tics of the subnetwork or data link service from the +subnetwork independent functions. These include: +-Operation of the Intermediate system functions of +ISO 9542 on the particular subnetwork, in order to +7Determine neighbour Network entity title(s) and +SNPA address(es) +7Determine the SNPA address(s) of operational In +termediate systems +-Operation of the requisite Subnetwork Dependent +Convergence Function as defined in ISO 8473 and its +Addendum 3, in order to perform +7Data link initialisation +7Hop by hop fragmentation over subnetworks with +small maximum SNSDU sizes +7Call establishment and clearing on dynamically es +tablished data links +6.6 Design Goals +This International Standard supports the following design +requirements. The correspondence with the goals for OSI +routeing stated in ISO/TR 9575 are noted. +-Network Layer Protocol Compatibility. It is com +patible with ISO 8473 and ISO 9542. (See clause 7.5 +of ISO/TR 9575), +-Simple End systems: It requires no changes to end +systems, nor any functions beyond those supplied by +ISO 8473 and ISO 9542. (See clause 7.2.1 of ISO/TR +9575), +-Multiple Organisations: It allows for multiple route +ing and administrative domains through the provision +of static routeing information at domain boundaries. +(See clause 7.3 of ISO/TR 9575), +-Deliverability It accepts and delivers NPDUs ad +dressed to reachable destinations and rejects NPDUs +addressed to destinations known to be unreachable. +-Adaptability. It adapts to topological changes within +the routeing domain, but not to traffic changes, except +potentially as indicated by local queue lengths. It +splits traffic load on multiple equivalent paths. (See +clause 7.7 of ISO/TR 9575), +-Promptness. The period of adaptation to topological +changes in the domain is a reasonable function of the +domain diameter (that is, the maximum logical dis + +tance between End Systems within the domain) and +Data link speeds. (See clause 7.4 of ISO/TR 9575), +-Efficiency. It is both processing and memory effi +cient. It does not create excessive routeing traffic +overhead. (See clause 7.4 of ISO/TR 9575), +-Robustness. It recovers from transient errors such as +lost or temporarily incorrect routeing PDUs. It toler +ates imprecise parameter settings. (See clause 7.7 of +ISO/TR 9575), +-Stability. It stabilises in finite time to good routes, +provided no continuous topological changes or con +tinuous data base corruptions occur. +-System Management control. System Management +can control many routeing functions via parameter +changes, and inspect parameters, counters, and routes. +It will not, however, depend on system management +action for correct behaviour. +-Simplicity. It is sufficiently simple to permit perform +ance tuning and failure isolation. +-Maintainability. It provides mechanisms to detect, +isolate, and repair most common errors that may affect +the routeing computation and data bases. (See clause +7.8 of ISO/TR 9575), +-Heterogeneity. It operates over a mixture of network +and system types, communication technologies, and +topologies. It is capable of running over a wide variety +of subnetworks, including, but not limited to: ISO +8802 LANs, ISO 8208 and X.25 subnetworks, PSTN +networks, and the OSI Data Link Service. (See clause +7.1 of ISO/TR 9575), +-Extensibility. It accommodates increased routeing +functions, leaving earlier functions as a subset. +-Evolution. It allows orderly transition from algorithm +to algorithm without shutting down an entire domain. +-Deadlock Prevention. The congestion control compo +nent prevents buffer deadlock. +-Very Large Domains. With hierarchical routeing, and +a very large address space, domains of essentially un +limited size can be supported. (See clause 7.2 of +ISO/TR 9575), +-Area Partition Repair. It permits the utilisation of +level 2 paths to repair areas which become partitioned +due to failing level 1 links or ISs. (See clause 7.7 of +ISO/TR 9575), +-Determinism. Routes are a function only of the physi +cal topology, and not of history. In other words, the +same topology will always converge to the same set of +routes. +-Protection from Mis-delivery. The probability of +mis-delivering a NPDU, i.e. delivering it to a Trans +port entity in the wrong End System, is extremely low. + +-Availability. For domain topologies with cut set +greater than one, no single point of failure will parti +tion the domain. (See clause 7.7 of ISO/TR 9575), +-Service Classes. The service classes of transit delay, +expense22Expense is referred to as cost in ISO 8473. The latter term is +not used here because of possible confusion with the more general usage +of the term to +indicate path cost according to any routeing metric. +, and residual error probability of ISO 8473 +are supported through the optional inclusion of multi +ple routeing metrics. +-Authentication. The protocol is capable of carrying +information to be used for the authentication of Inter +mediate systems in order to increase the security and +robustness of a routeing domain. The specific mecha +nism supported in this International Standard how +ever, only supports a weak form of authentication us +ing passwords, and thus is useful only for protection +against accidental misconfiguration errors and does +not protect against any serious security threat. In the +future, the algorithms may be enhanced to provide +stronger forms of authentication than can be provided +with passwords without needing to change the PDU +encoding or the protocol exchange machinery. +6.6.1 Non-Goals +The following are not within the design scope of the intra- +domain ISIS routeing protocol described in this Interna +tional Standard: +-Traffic adaptation. It does not automatically modify +routes based on global traffic load. +-Source-destination routeing. It does not determine +routes by source as well as destination. +-Guaranteed delivery. It does not guarantee delivery +of all offered NPDUs. +-Level 2 Subdomain Partition Repair. It will not util +ise Level 1 paths to repair a level 2 subdomain parti +tion. For full logical connectivity to be available, a +connected level 2 subdomain is required. +-Equal treatment for all ES Implementations. The +End system poll function defined in 8.4.5 presumes +that End systems have implemented the Suggested ES +Configuration Timer option of ISO 9542. An End sys +tem which does not implement this option may experi +ence a temporary loss of connectivity following cer +tain types of topology changes on its local +subnetwork. +6.7 Environmental Requirements +For correct operation of the protocol, certain guarantees are +required from the local environment and the Data Link +Layer. +The required local environment guarantees are: +a)Resource allocation such that the certain minimum re +source guarantees can be met, including + +1)memory (for code, data, and buffers) +2)processing; +See 12.2.5 for specific performance levels required for +conformance +b)A quota of buffers sufficient to perform routeing func +tions; +c)Access to a timer or notification of specific timer expi +ration; and +d)A very low probability of corrupting data. +The required subnetwork guarantees for point-to-point links +are: +a)Provision that both source and destination systems +complete start-up before PDU exchange can occur; +b)Detection of remote start-up; +c)Provision that no old PDUs be received after start-up +is complete; +d)Provision that no PDUs transmitted after a particular +startup is complete are delivered out of sequence; +e)Provision that failure to deliver a specific subnetwork +SDU will result in the timely disconnection of the +subnetwork connection in both directions and that this +failure will be reported to both systems; and +f)Reporting of other subnetwork failures and degraded +subnetwork conditions. +The required subnetwork guarantees for broadcast links are: +a)Multicast capability, i.e., the ability to address a subset +of all connected systems with a single PDU; +b)The following events are low probability, which +means that they occur sufficiently rarely so as not to +impact performance, on the order of once per thou +sand PDUs +1)Routeing PDU non-sequentiality, +2)Routeing PDU loss due to detected corruption; and +3)Receiver overrun; +c)The following events are very low probability, +which means performance will be impacted unless +they are extremely rare, on the order of less than one +event per four years +1)Delivery of NPDUs with undetected data corrup +tion; and +2)Non-transitive connectivity, i.e. where system A +can receive transmissions from systems B and C, +but system B cannot receive transmissions from +system C. + +The following services are assumed to be not available +from broadcast links: +a)Reporting of failures and degraded subnetwork condi +tions that result in NPDU loss, for instance receiver +failure. The routeing functions are designed to account +for these failures. +6.8 Functional Organisation of +Subnetwork Independent +Components +The Subnetwork Independent Functions are broken down +into more specific functional components. These are de +scribed briefly in this sub-clause and in detail in clause 7. +This International Standard uses a functional decomposition +adapted from the model of routeing presented in clause 5.1 +of ISO/TR 9575. The decomposition is not identical to that +in ISO/TR 9575, since that model is more general and not +specifically oriented toward a detailed description of intra- +domain routeing functions such as supplied by this proto +col. + +The functional decomposition is shown below in figure 2. +6.8.1 Routeing +The routeing processes are: +-Decision Process +-Update Process +NOTE this comprises both the Information Collection +and Information Distribution components identified in +ISO/TR 9575. +-Forwarding Process +-Receive Process +6.8.1.1 Decision Process +This process calculates routes to each destination in the do +main. It is executed separately for level 1 and level 2 route +ing, and separately within each level for each of the route +ing metrics supported by the Intermediate system. It uses +the Link State Database, which consists of information + +from the latest Link State PDUs from every other Interme +diate system in the area, to compute shortest paths from this +IS to all other systems in the area 9in figure 2. The +Link State Data Base is maintained by the Update Process. +Execution of the Decision Process results in the determina +tion of [circuit, neighbour] pairs (known as adjacencies), +which are stored in the appropriate Forwarding Information +base 10 and used by the Forwarding process as paths +along which to forward NPDUs. +Several of the parameters in the routeing data base that the +Decision Process uses are determined by the implementa +tion. These include: +-maximum number of Intermediate and End systems +within the IS's area; +-maximum number of Intermediate and End system +neighbours of the IS, etc., +so that databases can be sized appropriately. Also parame +ters such as +-routeing metrics for each circuit; and +-timers +can be adjusted for enhanced performance. The complete +list of System Management set-able parameters is listed in +clause 11. +6.8.1.2 Update Process +This process constructs, receives and propagates Link State +PDUs. Each Link State PDU contains information about the +identity and routeing metric values of the adjacencies of +the IS that originated the Link State PDU. +The Update Process receives Link State and Sequence +Numbers PDUs from the Receive Process 4in figure +2. It places new routeing information in the routeing infor +mation base 6 and propagates routeing information to +other Intermediate systems 7and 8 . +General characteristics of the Update Process are: +-Link State PDUs are generated as a result of topologi +cal changes, and also periodically. They may also be +generated indirectly as a result of System Manage +ment actions (such as changing one of the routeing +metrics for a circuit). +-Level 1 Link State PDUs are propagated to all Inter +mediate systems within an area, but are not propa +gated out of an area. +-Level 2 Link State PDUs are propagated to all Level 2 +Intermediate systems in the domain. +-Link State PDUs are not propagated outside of a do +main. + +-The update process, through a set of System Manage +ment parameters, enforces an upper bound on the +amount of routeing traffic overhead it generates. +6.8.1.3 Forwarding Process +This process supplies and manages the buffers necessary to +support NPDU relaying to all destinations. +It receives, via the Receive Process, ISO 8473 PDUs to be +forwarded 5 in figure 2. +It performs a lookup in the appropriate33The appropriate Forwarding +Database is selected by choosing a routeing metric based on fields in +the QoS Maintenance option of ISO 8473. + Forwarding Data +base 11 to determine the possible output adjacencies +to use for forwarding to a given destination, chooses one +adjacency 12, generates error indications to ISO 8473 + 14 , and signals ISO 9542 to issue Redirect PDUs +13. +6.8.1.4 Receive Process +The Receive Process obtains its inputs from the following +sources +-received PDUs with the NPID of Intra-Domain route +ing 2 in figure 2, +-routeing information derived by the ESIS protocol +from the receipt of ISO 9542 PDUs 1; and +-ISO 8473 data PDUs handed to the routeing function +by the ISO 8473 protocol machine 3. +It then performs the appropriate actions, which may involve +passing the PDU to some other function (e.g. to the For +warding Process for forwarding 5). +7 Subnetwork Independent +Functions +This clause describes the algorithms and associated data +bases used by the routeing functions. The managed objects +and attributes defined for System Management purposes are +described in clause 11. +The following processes and data bases are used internally +by the subnetwork independent functions. Following each +process or data base title, in parentheses, is the type of sys +tems which must keep the database. The system types are +L2 (level 2 Intermediate system), and L1 (level 1 Inter +mediate system). Note that a level 2 Intermediate system is +also a level 1 Intermediate system in its home area, so it +must keep level 1 databases as well as level 2 databases. + +Processes: +-Decision Process (L2, L1) +-Update Process (L2, L1) +-Forwarding Process (L2, L1) +-Receive Process (L2, L1) +Databases: +-Level 1 Link State data base (L2, L1) +-Level 2 Link State data base (L2) +-Adjacency Database (L2, L1) +-Circuit Database (L2, L1) +-Level 1 Shortest Paths Database (L2, L1) +-Level 2 Shortest Paths Database (L2) +-Level 1 Forwarding Databases one per routeing +metric (L2, L1) +-Level 2 Forwarding Database one per routeing +metric (L2) +7.1 Addresses +The NSAP addresses and NETs of systems are variable +length quantities that conform to the requirements of ISO +8348/Add.2. The corresponding NPAI contained in ISO +8473 PDUs and in this protocol's PDUs (such as LSPs and +IIHs) must use the preferred binary encoding; the underly +ing syntax for this information may be either abstract binary +syntax or abstract decimal syntax. Any of the AFIs and +their corresponding DSP syntax may be used with this pro +tocol. +7.1.1 NPAI Of Systems Within A Routeing +Domain +Figure 3 illustrates the structure of an encoded NSAP ad +dress or NET. + +The structure of the NPAI will be interpreted in the follow +ing way by the protocol described in this international stan +dard: +Area Address +address of one area within a routeing domain a +variable length quantity consisting of the entire high- +order part of the NPAI, excluding the ID and SEL +fields, defined below. +ID System identifier a variable length field from 1 to +8 octets (inclusive). Each routeing domain employ +ing this protocol shall select a single size for the ID +field and all Intermediate systems in the routeing do +main shall use this length for the system IDs of all +systems in the routeing domain. + The set of ID lengths supported by an implementa +tion is an implementation choice, provided that at +least one value in the permitted range can be ac +cepted. The routeing domain administrator must en +sure that all ISs included in a routeing domain are +able to use the ID length chosen for that domain. +SEL NSAP Selector a 1-octet field which acts as a se +lector for the entity which is to receive the PDU(this +may be a Transport entity or the Intermediate system +Network entity itself). It is the least significant (last) +octet of the NPAI. +7.1.2 Deployment of Systems +For correct operation of the routeing protocol defined in +this international standard, systems deployed in a routeing +domain must meet the following requirements: +a)For all systems: +1)Each system in an area must have a unique sys +temID: that is, no two systems (IS or ES) in an +area can use the same ID value. +2)Each area address must be unique within the global +OSIE: that is, a given area address can be associ +ated with only one area. +3)All systems having a given value of area address +must be located in the same area. + +b)Additional Requirements for Intermediate systems: +1)Each Level 2 Intermediate system within a route +ing domain must have a unique value for its ID +field: that is, no two level 2 ISs in a routeing do +main can have the same value in their ID fields. +c)Additional Requirements for End systems: +1)No two End systems in an area may have ad +dresses that match in all but the SEL fields. +d)An End system can be attached to a level 1 IS only if +its area address matches one of the entries in the adja +cent IS's manual + +Area + +Addresses parameter. +It is the responsibility of the routeing domain's administra +tive authority to enforce the requirements of 7.1.2. The pro +tocol defined in this international standard assumes that +these requirements are met, but has no means to verify +compliance with them. +7.1.3 Manual area addresses +The use of several synonymous area addresses by an IS is +accommodated through the use of the management parame +ter manual + +Area + +Addresses. This parameter is set locally +for each level 1 IS by system management; it contains a list +of all synonymous area addresses associated with the IS, in +cluding the IS's area address as contained in its own NET. +Each level 1 IS distributes its manual + +Area + +Addresses in +its Level 1 LSP's Area Addresses field, thus allowing +level 2 ISs to create a composite list of all area addresses +supported within a given area. Level 2 ISs in turn advertise +the composite list throughout the level 2 subdomain by in +cluding it in their Level 2 LSP's Area Addresses field, +thus distributing information on all the area addresses asso +ciated with the entire routeing domain. The procedures for +establishing an adjacency between two level 1 ISs require +that there be at least one area address in common between +their two manual + +Area + +Addresses lists, and the proce +dures for establishing an adjacency between a level 1 Is and +an End system require that the End system's area address +must match an entry in the IS's manual + +Area + +Addresses +list. Therefore, it is the responsibility of System Manage +ment to ensure that each area address associated with an IS +is included: in particular, system management must ensure +that the area addresses of all ESs and Level 1 ISs adjacent +to a given level 1 IS are included in that IS's manual + + +Area + +Addresses list. +If the area address field for the destination address of an +8473 PDU or for the next entry in its source routeing +field, when present is not listed in the parameter area + + +Addresses of a level 1 IS receiving the PDU, then the +destination system does not reside in the IS's area. Such +PDUs will be routed by level-2 routeing. +7.1.4 Encoding of Level 2 Addresses +When a full NSAP address is encoded according to the pre +ferred binary encoding specified in ISO 8348/Add.2, the + +IDI is padded with leading digits (if necessary) to obtain the +maximum IDP length specified for that AFI. +A Level 2 address prefix consists of a leading sub-string of +a full NSAP address, such that it matches a set of full +NSAP addresses that have the same leading sub-string. +However this truncation and matching is performed on the +NSAP represented by the abstract syntax of the NSAP ad +dress, not on the encoded (and hence padded) form.11An example of +prefix matching may be found in annex B, clause B.1. + +Level 2 address prefixes are encoded in LSPs in the same +way as full NSAP addresses, except when the end of the +prefix falls within the IDP. In this case the prefix is directly +encoded as the string of semi-octets with no padding. +7.1.5 Comparison of Addresses +Unless otherwise stated, numerical comparison of addresses +shall be performed on the encoded form of the address, by +padding the shorter address with trailing zeros to the length +of the longer address, and then performing a numerical +comparison. +The addresses to which this precedure applies include +NSAP addresses, Network Entity Titles, and SNPA ad +dresses. +7.2 The Decision Process +This process uses the database of Link State information to +calculate the forwarding database(s), from which the for +warding process can know the proper next hop for each +NPDU. The Level 1 Link State Database is used for calcu +lating the Level 1 Forwarding Database(s), and the Level 2 +Link State Database is used for calculating the Level 2 For +warding Database(s). +7.2.1 Input and output +INPUT +-Link State Database This database is a set of infor +mation from the latest Link State PDUs from all +known Intermediate systems (within this area, for +Level 1, or within the level 2 subdomain, for Level 2). +This database is received from the Update Process. +-Notification of an Event This is a signal from the +Update Process that a change to a link has occurred +somewhere in the domain. + OUTPUT +-Level 1 Forwarding Databases one per routeing +metric +-(Level 2 Intermediate systems only) Level 2 Forward +ing Databases one per routeing metric +-(Level 2 Intermediate systems only) The Level 1 De +cision Process informs the Level 2 Update Process of +the ID of the Level 2 Intermediate system within the +area with lowest ID reachable with real level 1 links + +(as opposed to a virtual link consisting of a path +through the level 2 subdomain) +-(Level 2 Intermediate systems only) If this Intermedi +ate system is the Partition Designated Level 2 Inter +mediate system in this partition, the Level 2 Decision +Process informs the Level 1 Update Process of the +values of the default routeing metric to and ID of the +partition designated level 2 Intermediate system in +each other partition of this area. +7.2.2 Routeing metrics +There are four routeing metrics defined, corresponding to +the four possible orthogonal qualities of service defined by +the QoS Maintenance field of ISO 8473. Each circuit ema +nating from an Intermediate system shall be assigned a +value for one or more of these metrics by System manage +ment. The four metrics are as follows: +a)Default metric: This is a metric understood by every +Intermediate system in the domain. Each circuit shall +have a positive integral value assigned for this metric. +The value may be associated with any objective func +tion of the circuit, but by convention is intended to +measure the capacity of the circuit for handling traffic, +for example, its throughput in bits-per-second. Higher +values indicate a lower capacity. +b)Delay metric: This metric measures the transit delay +of the associated circuit. It is an optional metric, which +if assigned to a circuit shall have a positive integral +value. Higher values indicate a longer transit delay. +c)Expense metric: This metric measures the monetary +cost of utilising the associated circuit. It is an optional +metric, which if assigned to a circuit shall have a posi +tive integral value22The path computation algorithm utilised in this +International Standard requires that all circuits be assigned a +positive value for a metric. Therefore, it is +not possible to represent a free circuit by a zero value of the expense +metric. By convention, the value 1 is used to indicate a free circuit. +. Higher values indicate a larger +monetary expense. +d)Error metric: This metric measures the residual error +probability of the associated circuit. It is an optional +metric, which if assigned to a circuit shall have a non- +zero value. Higher values indicate a larger probability +of undetected errors on the circuit. +NOTE - The decision process combines metric values by +simple addition. It is important, therefore, that the values of +the metrics be chosen accordingly. +Every Intermediate system shall be capable of calculating +routes based on the default metric. Support of any or all of +the other metrics is optional. If an Intermediate system sup +ports the calculation of routes based on a metric, its update +process may report the metric value in the LSPs for the as +sociated circuit; otherwise, the IS shall not report the met +ric. +When calculating paths for one of the optional routeing +metrics, the decision process only utilises LSPs with a +value reported for the corresponding metric. If no value is + +associated with a metric for any of the IS's circuits the sys +tem shall not calculate routes based on that metric. +NOTE - A consequence of the above is that a system reach +able via the default metric may not be reachable by another +metric. +See 7.4.2 for a description of how the forwarding process +selects one of these metrics based on the contents of the +ISO 8473 QoS Maintenance option. +Each of the four metrics described above may be of two +types: an Internal metric or an External metric. Internal +metrics are used to describe links/routes to destinations in +ternal to the routeing domain. External metrics are used to +describe links/routes to destinations outside of the routeing +domain. These two types of metrics are not directly compa +rable, except the internal routes are always preferred over +external routes. In other words an internal route will always +be selected even if an external route with lower total cost +exists. +7.2.3 Broadcast Subnetworks +Instead of treating a broadcast subnetwork as a fully con +nected topology, the broadcast subnetwork is treated as a +pseudonode, with links to each attached system. Attached +systems shall only report their link to the pseudonode. The +designated Intermediate system, on behalf of the +pseudonode, shall construct Link State PDUs reporting the +links to all the systems on the broadcast subnetwork with a +zero value for each supported routeing metric33They are set to zero +metric values since they have already been assigned metrics by the +link to the pseudonode. Assigning a non-zero value in the +pseudonode LSP would have the effect of doubling the actual value. +. +The pseudonode shall be identified by the sourceID of the +Designated Intermediate system, followed by a non-zero +pseudonodeID assigned by the Designated Intermediate +system. The pseudonodeID is locally unique to the Desig +nated Intermediate system. +Designated Intermediate systems are determined separately +for level 1 and level 2. They are known as the LAN Level 1 +Designated IS and the LAN Level 2 Designated IS respec +tively. See 8.4.4. +An Intermediate system may resign as Designated Interme +diate System on a broadcast circuit either because it (or it's +SNPA on the broadcast subnetwork) is being shut down or +because some other Intermediate system of higher priority +has taken over that function. When an Intermediate system +resigns as Designated Intermediate System, it shall initiate a +network wide purge of its pseudonode Link State PDU(s) +by setting their Remaining Lifetime to zero and performing +the actions described in 7.3.16.4. A LAN Level 1 Desig +nated Intermediate System purges Level 1 Link State PDUs +and a LAN Level 2 Designated Intermediate System purges +Level 2 Link State PDUs. An Intermediate system which +has resigned as both Level 1 and Level 2 Designated Inter +mediate System shall purge both sets of LSPs. + +When an Intermediate system declares itself as designated +Intermediate system and it is in possession of a Link State +PDU of the same level issued by the previous Designated +Intermediate System for that circuit (if any), it shall initiate +a network wide purge of that (or those) Link State PDU(s) +as above. +7.2.4 Links +Two Intermediate systems are not considered neighbours +unless each reports the other as directly reachable over one +of their SNPAs. On a Connection-oriented subnetwork +(either point-to-point or general topology), the two Interme +diate systems in question shall ascertain their neighbour re +lationship when a connection is established and hello PDUs +exchanged. A malfunctioning IS might, however, report an +other IS to be a neighbour when in fact it is not. To detect +this class of failure the decision process checks that each +link reported as up in a LSP is so reported by both Inter +mediate systems. If an Intermediate system considers a link +down it shall not mention the link in its Link State PDUs. +On broadcast subnetworks, this class of failure shall be de +tected by the designated IS, which has the responsibility to +ascertain the set of Intermediate systems that can all com +municate on the subnetwork. The designated IS shall in +clude these Intermediate systems (and no others) in the +Link State PDU it generates for the pseudonode represent +ing the broadcast subnetwork. +7.2.5 Multiple LSPs for the same system +The Update process is capable of dividing a single logical +LSP into a number of separate PDUs for the purpose of +conserving link bandwidth and processing (see 7.3.4). The +Decision Process, on the other hand, shall regard the LSP +with LSP Number zero in a special way. If the LSP with +LSP Number zero and remaining lifetime > 0, is not present +for a particular system then the Decision Process shall not +process any LSPs with non-zero LSP Number which may +be stored for that system. +The following information shall be taken only from the LSP +with LSP Number zero. Any values which may be present +in other LSPs for that system shall be disregarded by the +Decision Process. +a)The setting of the LSP Database Overload bit. +b)The value of the IS Type field. +c)The Area Addresses option. +7.2.6 Routeing Algorithm Overview +The routeing algorithm used by the Decision Process is a +shortest path first (SPF) algorithm. Instances of the algo +rithm are run independently and concurrently by all Inter +mediate systems in a routeing domain. Intra-Domain route +ing of a PDU occurs on a hop-by-hop basis: that is, the al +gorithm determines only the next hop, not the complete +path, that a data PDU will take to reach its destination. To +guarantee correct and consistent route computation by +every Intermediate system in a routeing domain, this Inter +national Standard depends on the following properties: + +a)All Intermediate systems in the routeing domain con +verge to using identical topology information; and +b)Each Intermediate system in the routeing domain gen +erates the same set of routes from the same input to +pology and set of metrics. +The first property is necessary in order to prevent inconsis +tent, potentially looping paths. The second property is nec +essary to meet the goal of determinism stated in 6.6. +A system executes the SPF algorithm to find a set of legal +paths to a destination system in the routeing domain. The +set may consist of: +a)a single path of minimum metric sum: these are +termed minimum cost paths; +b)a set of paths of equal minimum metric sum: these are +termed equal minimum cost paths; or +c)a set of paths which will get a PDU closer to its desti +nation than the local system: these are called down +stream paths. +Paths which do not meet the above conditions are illegal +and shall not be used. +The Decision Process, in determining its paths, also ascer +tains the identity of the adjacency which lies on the first +hop to the destination on each path. These adjacencies are +used to form the Forwarding Database, which the forward +ing process uses for relaying PDUs. +Separate route calculations are made for each pairing of a +level in the routeing hierarchy (i.e. L1 and L2) with a sup +ported routeing metric. Since there are four routeing metrics +and two levels some systems may execute multiple in +stances of the SPF algorithm. For example, +-if an IS is a L2 Intermediate system which supports all +four metrics and computes minimum cost paths for all +metrics, it would execute the SPF calculation eight +times. +-if an IS is a L1 Intermediate system which supports all +four metrics, and additionally computes downstream +paths, it would execute the algorithm 4 W (number of +neighbours + 1) times. +Any implementation of an SPF algorithm meeting both the +static and dynamic conformance requirements of clause 12 +of this International Standard may be used. Recommended +implementations are described in detail in Annex C. +7.2.7 Removal of Excess Paths +When there are more than max + +i + +mum + +Path + +Splits legal +paths to a destination, this set shall be pruned until only +max + +i + +mum + +Path + +Splits remain. The Intermediate system +shall discriminate based upon: +NOTE - The precise precedence among the paths is speci +fied in order to meet the goal of determinism defined in 6.6. + +-adjacency type: Paths associated with End system or +level 2 reachable address prefix adjacencies are re +tained in preference to other adjacencies +-metric sum: Paths having a lesser metric sum are re +tained in preference to paths having a greater metric +sum. By metric sum is understood the sum of the +metrics along the path to the destination. +-neighbour ID: where two or more paths are associ +ated with adjacencies of the same type, an adjacency +with a lower neighbour ID is retained in preference to +an adjacency with a higher neighbour id. +-circuit ID: where two or more paths are associated +with adjacencies of the same type, and same neigh +bour ID, an adjacency with a lower circuit ID is re +tained in preference to an adjacency with a higher cir +cuit ID, where circuit ID is the value of: +7ptPtCircuitID for non-broadcast circuits, +7l1CircuitID for broadcast circuits when running +the Level 1 Decision Process, and +7l2CircuitID for broadcast circuits when running +the Level 2 Decision Process. +-lANAddress: where two or more adjacencies are of +the same type, same neighbour ID, and same circuit +ID (e.g. a system with multiple LAN adapters on the +same circuit) an adjacency with a lower lANAddress +is retained in preference to an adjacency with a higher +lANAddress. +7.2.8 Robustness Checks +7.2.8.1 Computing Routes through Overloaded +Intermediate systems +The Decision Process shall not utilise a link to an Interme +diate system neighbour from an IS whose LSPs have the +LSP Database Overload indication set. Such paths may in +troduce loops since the overloaded IS does not have a com +plete routeing information base. The Decision Process shall, +however utilise the link to reach End system neighbours +since these paths are guaranteed to be non-looping. +7.2.8.2 Two-way connectivity check +The Decision Process shall not utilise a link between two +Intermediate Systems unless both ISs report the link. +NOTE - the check is not applicable to links to an End Sys +tem. +Reporting the link indicates that it has a defined value for at +least the default routeing metric. It is permissible for two +endpoints to report different defined values of the same +metric for the same link. In this case, routes may be asym +metric. + +7.2.9 Construction of a Forwarding Database +The information that is needed in the forwarding database +for routeing metric k is the set of adjacencies for each sys +tem N. +7.2.9.1 Identification of Nearest Level 2 IS by a +Level 1 IS +Level 1 Intermediate systems need one additional piece of +information per routeing metric: the next hop to the nearest +level 2 Intermediate system according to that routeing met +ric. A level 1 IS shall ascertain the set, R, of attached +level 2 Intermediate system(s) for metric k such that the to +tal cost to R for metric k is minimal. +If there are more adjacencies in this set than max + +i + +mum + + +Path + +Splits, then the IS shall remove excess adjacencies as +described in 7.2.7. +7.2.9.2 Setting the Attached Flag in Level 2 +Intermediate Systems +If a level 2 Intermediate system discovers, after computing +the level 2 routes for metric k, that it cannot reach any other +areas using that metric, it shall: +-set AttachedFlag for metric k to False; +-regenerate its Level 1 LSP with LSP number zero; and +-compute the nearest level 2 Intermediate system for +metric k for insertion in the appropriate forwarding +database, according to the algorithm described in +7.2.9.1 for level 1 Intermediate systems. +NOTE - AttachedFlag for each metric k is examined by the +Update Process, so that it will report the value in the ATT +field of its Link State PDUs. +If a level 2 Intermediate system discovers, after computing +the level 2 routes for metric k, that it can reach at least one +other area using that metric, it shall +-set AttachedFlag for metric k to True; +-regenerate its Level 1 LSP with LSP number zero; and +-set the level 1 forwarding database entry for metric k +which corresponds to nearest level 2 Intermediate +system to Self. +7.2.10 Information for Repairing Partitioned +Areas +An area may become partitioned as a result of failure of one +or more links in the area. However, if each of the partitions +has a connection to the level 2 subdomain, it is possible to +repair the partition via the level 2 subdomain, provided that +the level 2 subdomain itself is not partitioned. This is illus +trated in Figure 4. +All the systems A I, R and P are in the same area n. +When the link between D and E is broken, the area be + +comes partitioned. Within each of the partitions the Parti +tion Designated Level 2 Intermediate system is selected +from among the level 2 Intermediate systems in that parti +tion. In the case of partition 1 this is P, and in the case of +partition 2 this is R. The level 1 repair path is then estab +lished between between these two level 2 Intermediate sys +tems. Note that the repaired link is now between P and R, +not between D and E. +The Partition Designated Level 2 Intermediate Systems re +pair the partition by forwarding NPDUs destined for other +partitions of the area through the level 2 subdomain. They +do this by acting in their capacity as Level 1 Intermediate +Systems and advertising in their Level 1 LSPs adjacencies +to each Partition Designated Level 2 Intermediate System +in the area. This adjacency is known as a Virtual Adja +cency or Virtual Link. Thus other Level 1 Intermediate +Systems in a partition calculate paths to the other partitions +through the Partition Designated Level 2 Intermediate Sys +tem. A Partition Designated Level 2 Intermediate System +forwards the Level 1 NPDUs through the level 2 subdomain +by encapsulating them in 8473 Data NPDUs with its Virtual +Network Entity Title as the source NSAP and the adja +cent Partition Designated Level 2 Intermediate System's +Virtual Network Entity Title as the destination NSAP. The +following sub-clauses describe this in more detail. +7.2.10.1 Partition Detection and Virtual Level 1 +Link Creation +Partitions of a Level 1 area are detected by the Level 2 In +termediate System(s) operating within the area. In order to +participate in the partition repair process, these Level 2 In +termediate systems must also act as Level 1 Intermediate +systems in the area. A partition of a given area exists when +ever two or more Level 2 ISs located in that area are re +ported in the L2 LSPs as being a Partition Designated +Level 2 IS. Conversely, when only one Level 2 IS in an +area is reported as being the Partition Designated Level 2 + +IS, then that area is not partitioned. Partition repair is ac +complished by the Partition Designated Level 2 IS. The +election of the Partition Designated Level 2 IS as described +in the next subsection must be done before the detection +and repair process can begin. +In order to repair a partition of a Level 1 area, the Partition +designated Level 2 IS creates a Virtual Network Entity to +represent the partition. The Network Entity Title for this +virtual network entity shall be constructed from the first +listed area address from its Level 2 Link State PDU, and the +ID of the Partition Designated Level 2 IS. The IS shall also +construct a virtual link (represented by a new Virtual Adja +cency managed object) to each Partition Designated Level 2 +IS in the area, with the NET of the partition recorded in the +Identifier attribute. The virtual links are the repair paths for +the partition. They are reported by the Partition Designated +Level 2 IS into the entire Level 1 area by adding the ID of +each adjacent Partition Designated Level 2 IS to the In +termediate System Neighbours field of its Level 1 Link +State PDU. The Virtual Flag shall be set True for these +Intermediate System neighbours. The metric value for this +virtual link shall be the default metric value d(N) obtained +from this system's Level 2 PATHS database, where N is the +adjacent Partition Designated Level 2 IS via the Level 2 +subdomain. +An Intermediate System which operates as the Partition +Designated Level 2 Intermediate System shall perform the +following steps after completing the Level 2 shortest path +computation in order to detect partitions in the Level 1 area +and create repair paths: +a)Examine Level 2 Link State PDUs of all Level 2 Inter +mediate systems. Search area + +Addresses for any ad +dress that matches any of the addresses in partition + + +Area + +Addresses. If a match is found, and the Parti +tion Designated Level 2 Intermediate system's ID +does not equal this system's ID, then inform the level +1 update process at this system of the identity of the + +Partition Designated Level 2 Intermediate system, to +gether with the path cost for the default routeing met +ric to that Intermediate system. +b)Continue examining Level 2 LSPs until all Partition +Designated Level 2 Intermediate systems in other par +titions of this area are found, and inform the Level 1 +Update Process of all of the other Partition Designated +Level 2 Intermediate systems in other partitions of this +area, so that +1)Level 1 Link State PDUs can be propagated to all +other Partition designated level 2 Intermediate sys +tems for this area (via the level 2 subdomain). +2)All the Partition Designated Level 2 Intermediate +systems for other partitions of this area can be re +ported as adjacencies in this system's Level 1 Link +State PDUs. +If a partition has healed, the IS shall destroy the associated +virtual network entity and virtual link by deleting the Vir +tual Adjacency. The Partition Designated Level 2 IS de +tects a healed partition when another Partition Designated +Level 2 IS listed as a virtual link in its Level 1 Link State +PDU was not found after running the partition detection and +virtual link creation algorithm described above. +If such a Virtual Adjacency is created or destroyed, the IS +shall generate a partitionVirtualLinkChange notification. +7.2.10.2 Election of Partition Designated Level 2 +Intermediate System + The Partition Designated Level 2 IS is a Level 2 IS which: +-reports itself as attached by the default metric in its +LSPs; +-reports itself as implementing the partition repair op +tion; +-operates as a Level 1 IS in the area; +-is reachable via Level 1 routeing without traversing +any virtual links; and +-has the lowest ID +The election of the Partition Designated Level 2 IS is per +formed by running the decision process algorithm after the +Level 1 decision process has finished, and before the +Level 2 decision process to determine Level 2 paths is exe +cuted. +In order to guarantee that the correct Partition Designated +Level 2 IS is elected, the decision process is run using only +the Level 1 LSPs for the area, and by examining only the +Intermediate System Neighbours whose Virtual Flag is +FALSE. The results of this decision process is a set of all +the Level 1 Intermediate Systems in the area that can be +reached via Level 1, non-virtual link routeing. From this +set, the Partition Designated Level 2 IS is selected by +choosing the IS for which +-IS Type (as reported in the Level 1 LSP) is Level 2 +Intermediate System; + +-ATT indicates attached by the default metric; +-P indicates support for the partition repair option; and +-ID is the lowest among the subset of attached Level 2 +Intermediate Systems. +7.2.10.3 Computation of Partition area addresses +A Level 2 Intermediate System shall compute the set of +partition + +Area + +Addresses, which is the union of all +manual + +area + +Addresses as reported in the Level 1 Link +State PDUs of all Level 2 Intermediate systems reachable in +the partition by the traversal of non-virtual links. If more +than max + +i + +mum + +Area + +Addresses are present, the Interme +diate system shall retain only those areas with numerically +lowest area address (as described in 7.1.5). If one of the lo +cal system's manual + +Area + +Addresses is so rejected the +notification manualAddressDroppedFromArea shall be +generated. +7.2.10.4 Encapsulation of NPDUs Across the +Virtual Link +All NPDUs sent over virtual links shall be encapsulated as +ISO 8473 Data NPDUs. The encapsulating Data NPDU +shall contain the Virtual Network Entity Title of the Parti +tion Designated Level 2 IS that is forwarding the NPDU +over the virtual link in the Source Address field, and the +Virtual NET of the adjacent Partition Designated Level 2 +IS in the Destination Address field. The SEL field in +both NSAPs shall contain the IS-IS routeing selector +value. The QoS Maintenance field of the outer PDU shall +be set to indicate forwarding via the default routeing metric +(see table 1 on page 32). +For Data and Error Report NPDUs the Segmentation +Permitted and Error Report flags and the Lifetime field +of the outer NPDU shall be copied from the inner NPDU. +When the inner NPDU is decapsulated, its Lifetime field +shall be set to the value of the Lifetime field in the outer +NPDU. +For LSPs and SNPs the Segmentation Permitted flag +shall be set to True and the Error Report flag shall be set +to False. The Lifetime field shall be set to 255. When an +inner LSP is decapsulated, its remaining lifetime shall be +decremented by half the difference between 255 and the +value of the Lifetime field in the outer NPDU. +Data NPDUs shall not be fragmented before encapsulation, +unless the total length of the Data NPDU (including header) +exceeds 65535 octets. In that case, the original Data NPDU +shall first be fragmented, then encapsulated. In all cases, +the encapsulated Data NPDU may need to be fragmented +by ISO 8473 before transmission in which case it must be +reassembled and decapsulated by the destination Partition +Designated Level 2 IS. The encapsulation is further de +scribed as part of the forwarding process in 7.4.3.2. The +decapsulation is described as part of the Receive process in +7.4.4. +7.2.11 Computation of area addresses +A Level 1 or Level 2 Intermediate System shall compute +the values of area + +Addresses (the set of area addresses + +for this Level 1 area), by forming the union of the sets of +manual + +area + +Addresses reported in the Area Addresses +field of all Level 1 LSPs with LSP number zero in the local +Intermediate system's link state database. +NOTE - This includes all source systems, whether currently +reachable or not. It also includes the local Intermediate sys +tem's own Level 1 LSP with LSP number zero. +NOTE - There is no requirement for this set to be updated +immediately on each change to the database contents. It is +permitted to defer the computation until the next running of +the Decision Process. +If more than max + +i + +mum + +Area + +Addresses are present, the +Intermediate system shall retain only those areas with nu +merically lowest area address (as described in 7.1.5). If one +of the local system's manual + +area + +Addresses is rejected +the notification manual + +Address + +Dropped + +From + +Area shall +be generated. +7.2.12 Order of Preference of Routes +If an Intermediate system takes part in level 1 routeing, and +determines (by looking at the area address) that a given des +tination is reachable within its area, then that destination +will be reached exclusively by use of level 1 routeing. In +particular: +a)Level 1 routeing is always based on internal metrics. +b)Amongst routes in the area, routes on which the re +quested QoS (if any) is supported are always preferred +to routes on which the requested QoS is not supported. +c)Amongst routes in the area of the same QoS, the short +est routes are preferred. For determination of the +shortest path, if a route with specific QoS support is +available, then the specified QoS metric is used, other +wise the default metric is used. +d)Amongst routes of equal cost, load splitting may be +performed. +If an Intermediate system takes part in level 1 routeing, +does not take part in level 2 routeing, and determines (by +looking at the area address) that a given destination is not +reachable within its area, and at least one attached level 2 +IS is reachable in the area, then that destination will be +reached by routeing to a level 2 Intermediate system as fol +lows: +a)Level 1 routeing is always based on internal metrics. +b)Amongst routes in the area to attached level 2 ISs, +routes on which the requested QoS (if any) is sup +ported are always preferred to routes on which the re +quested QoS is not supported. +c)Amongst routes in the area of the same QoS to at +tached level 2 ISs, the shortest route is preferred. For +determination of the shortest path, if a route on which +the specified QoS is available, then the specified QoS +metric is used, otherwise the default metric is used. + +d)Amongst routes of equal cost, load splitting may be +performed. +If an Intermediate system takes part in level 2 routeing and +is attached, and the IS determines (by looking at the area +address) that a given destination is not reachable within its +area, then that destination will be reached as follows: +a)Routes on which the requested QoS (if any) is sup +ported are always preferred to routes on which the re +quested QoS is not supported. +b)Amongst routes of the same QoS, routes are priori +tised as follows: +1)Highest precedence: routes matching the area ad +dress of any area in the routeing domain +2)Medium precedence: Routes matching a reachable +address prefix with an internal metric. For destina +tions matching multiple reachable address prefix +entries all with internal metrics, the longest prefix +shall be preferred. +3)Lowest precedence: Routes matching a reachable +address prefix with an external metric. For destina +tions matching multiple reachable address prefix +entries all with external metrics, the longest prefix +shall be preferred. +c)For routes with equal precedence as specified above, +the shortest path shall be preferred. For determination +of the shortest path, a route supporting the specified +QoS is used if available; otherwise a route using the +default metric shall be used. Amongst routes of equal +cost, load splitting may be performed. +7.3 The Update Process +The Update Process is responsible for generating and +propagating Link State information reliably throughout the +routeing domain. +The Link State information is used by the Decision Process +to calculate routes. +7.3.1 Input and Output +INPUT +-Adjacency Database maintained by the Subnetwork +Dependent Functions +-Reachable Address managed objects - maintained by +System Management +-Notification of Adjacency Database Change notifi +cation by the Subnetwork Dependent Functions that +an adjacency has come up, gone down, or changed +cost. (Circuit up, Circuit down, Adjacency Up, Adja +cency Down, and Cost change events) +-AttachedFlag (level 2 Intermediate systems only), +a flag computed by the Level 2 Decision Process indi +cating whether this system can reach (via level 2 +routeing) other areas + +-Link State PDUs The Receive Process passes Link +State PDUs to the Update Process, along with an indi +cation of which adjacency it was received on. +-Sequence Numbers PDUs The Receive Process +passes Sequence Numbers PDUs to the Update Proc +ess, along with an indication of which adjacency it +was received on. +-Other Partitions The Level 2 Decision Process +makes available (to the Level 1 Update Process on a +Level 2 Intermediate system) a list of aPartition Desig +nated Level 2 Intermediate system, Level 2 default +metric valueq pairs, for other partitions of this area. + OUTPUT +-Link State Database +-Signal to the Decision Process of an event, which is +either the receipt of a Link State PDU with different +information from the stored one, or the purging of a +Link State PDU from the database. The reception of a +Link State PDU which has a different sequence num +ber or Remaining Lifetime from one already stored in +the database, but has an identical variable length por +tion, shall not cause such an event. +NOTE - An implementation may compare the checksum of +the stored Link State PDU, modified according to the +change in sequence number, with the checksum of the re +ceived Link State PDU. If they differ, it may assume that the +variable length portions are different and an event signalled +to the Decision Process. However, if the checksums are the +same, an octet for octet comparison must be made in order +to determine whether or not to signal the event. +7.3.2 Generation of Local Link State +Information +The Update Process is responsible for constructing a set of +Link State PDUs. The purpose of these Link State PDUs is +to inform all the other Intermediate systems (in the area, in +the case of Level 1, or in the Level 2 subdomain, in the case +of Level 2), of the state of the links between the Intermedi +ate system that generated the PDUs and its neighbours. +The Update Process in an Intermediate system shall gener +ate one or more new Link State PDUs under the following +circumstances: +a)upon timer expiration; +b)when notified by the Subnetwork Dependent Func +tions of an Adjacency Database Change; +c)when a change to some Network Management charac +teristic would cause the information in the LSP to +change (for example, a change in manual + +area + + +Addresses). +7.3.3 Use of Manual Routeing Information +Manual routeing information is routeing information en +tered by system management. It may be specified in two +forms. + +a)Manual Adjacencies +b)Reachable Addresses +These are described in the following sub-clauses. +7.3.3.1 Manual Adjacencies +An End system adjacency may be created by System Man +agement. Such an adjacency is termed a manual End sys +tem adjacency. In order to create a manual End system ad +jacency, system managements shall specify: +a)the (set of) system IDs reachable over that adjacency; +and +b)the corresponding SNPA Address. + These adjacencies shall appear as adjacencies with type +Manual, neighbourSystemType End system and +state Up. Such adjacencies provide input to the Update +Process in a similar way to adjacencies created through the +operation of ISO 9542. When the state changes to Up the +adjacency information is included in the Intermediate Sys +tem's own Level 1 LSPs. +NOTE - Manual End system adjacencies shall not be in +cluded in a Level 1 LSPs issued on behalf of a pseudonode, +since that would presuppose that all Intermediate systems on +a broadcast subnetwork had the same set of manual adjacen +cies as defined for this circuit. +Metrics assigned to Manual adjacencies must be Internal +metrics. +7.3.3.2 Reachable Addresses +A Level 2 Intermediate system may have a number of +Reachable Address managed objects created by System +management. When a Reachable Address is in state On +and its parent Circuit is also in state On, the name and +each of its defined routeing metrics shall be included in +Level 2 LSPs generated by this system. +Metrics assigned to Reachable Address managed objects +may be either Internal or External. +A reachable address is considered to be active when all +the following conditions are true: +a)The parent circuit is in state On; +b)the Reachable Address is in state On; and +c)the parent circuit is of type broadcast or is in data link +state Running. +Whenever a reachable address changes from being inac +tive to active a signal shall be generated to the Update +process to cause it to include the Address Prefix of the +reachable address in the Level 2 LSPs generated by that +system as described in 7.3.9. +Whenever a reachable address changes from being active +to inactive, a signal shall be generated to the Update + +process to cause it to cease including the Address Prefix of +the reachable address in the Level 2 LSPs. +7.3.4 Multiple LSPs +Because a Link State PDU is limited in size to Receive + + +LSP + +Buffer + +Size, it may not be possible to include infor +mation about all of a system's neighbours in a single LSP. +In such cases, a system may use multiple LSPs to convey +this information. Each LSP in the set carries the same +sourceID field (see clause 9), but sets its own LSP Num +ber field individually. Each of the several LSPs is handled +independently by the Update Process, thus allowing distri +bution of topology updates to be pipelined. However, the +Decision Process recognises that they all pertain to a com +mon originating system because they all use the same +sourceID. +NOTE - Even if the amount of information is small enough +to fit in a single LSP, a system may optionally choose to use +several LSPs to convey it; use of a single LSP in this situ +ation is not mandatory. +NOTE - In order to minimise the transmission of redundant +information, it is advisable for an IS to group Reachable +Address Prefix information by the circuit with which it is as +sociated. Doing so will ensure that the minimum number of +LSP fragments need be transmitted if a circuit to another +routeing domain changes state. +The maximum sized Level 1 or Level 2 LSP which may be +generated by a system is controlled by the values of the +management parameters originating + +L1 + +LSP + +Buf + +fer + +Size or +ori + +ginat + +ing + +L2 + +LSP + +Buffer + +Size respectively. +NOTE - These parameters should be set consistently by sys +tem management. If this is not done, some adjacencies will +fail to initialise. +The IS shall treat the LSP with LSP Number zero in a spe +cial way, as follows: +a)The following fields are meaningful to the decision +process only when they are present in the LSP with +LSP Number zero: +1)The setting of the LSP Database Overload bit. +2)The value of the IS Type field. +3)The Area Addresses option. (This is only present +in the LSP with LSP Number zero, see below). +b)When the values of any of the above items are +changed, an Intermediate System shall re-issue the +LSP with LSP Number zero, to inform other Interme +diate Systems of the change. Other LSPs need not be +reissued. +Once a particular adjacency has been assigned to a particu +lar LSP Number, it is desirable that it not be moved to an +other LSP Number. This is because moving an adjacency +from one LSP to another can cause temporary loss of + +connectivity to that system. This can occur if the new ver +sion of the LSP which originally contained information +about the adjacency (which now does not contain that infor +mation) is propagated before the new version of the other +LSP (which now contains the information about the adja +cency). In order to minimise the impact of this, the follow +ing restrictions are placed on the assignment of information +to LSPs. +a)The Area Addresses option field shall occur only in +the LSP with LSP Number zero. +b)Intermediate System Neighbours options shall occur +after the Area Addresses option and before any End +System (or in the case of Level 2, Prefix) Neigh +bours options. +c)End System (or Prefix) Neighbour options (if any) +shall occur after any Area Address or Intermediate +System Neighbour options. +NOTE In this context, after means at a higher octet +number from the start of the same LSP or in an LSP with +a higher LSP Number. +NOTE An implementation is recommended to ensure +that the number of LSPs generated for a particular system +is within approximately 10% of the optimal number +which would be required if all LSPs were densely packed +with neighbour options. Where possible this should be +accomplished by re-using space in LSPs with a lower +LSP Number for new adjacencies. If it is necessary to +move an adjacency from one LSP to another, the +SRMflags (see 7.3.15) for the two new LSPs shall be +set as an atomic action.44If the two SRMflags are not set atomically, a +race condition will exist in which one of the two LSPs may be +propagated quickly, while the other waits for +an entire propagation cycle. If this occurs, adjacencies will be +falsely eliminated from the topology and routes may become unstable for +period of time +potentially as large as maximumLSPGeneratonInterval. + +When some event requires changing the LSP information +for a system, the system shall reissue that (or those) LSPs +which would have different contents. It is not required to +reissue the unchanged LSPs. Thus a single End system ad +jacency change only requires the reissuing of the LSP con +taining the End System Neighbours option referring to +that adjacency. The parameters max + +imum + +LSP + +Gen + +er + +a + + +tion + +Int + +er + +val and minimumLSPGenerationInterval shall +apply to each LSP individually. +7.3.5 Periodic LSP Generation +The Update Process shall periodically re-generate and +propagate on every circuit with an IS adjacency of the ap +propriate level (by setting SRMflag on each circuit), all the +LSPs (Level 1 and/or Level 2) for the local system and any +pseudonodes for which it is responsible. The Intermediate +system shall re-generate each LSP at intervals of at most +max + +i + +mum + +LSP + +Gen + +era + +tion + +Interval seconds, with jitter +applied as described in 10.1. +These LSPs may all be generated on expiration of a single +timer or alternatively separate timers may be kept for each +LSP Number and the individual LSP generated on expira +tion of this timer. + +7.3.6 Event Driven LSP Generation +In addition to the periodic generation of LSPs, an Interme +diate system shall generate an LSP when an event occurs +which would cause the information content to change. The +following events may cause such a change. +-an Adjacency or Circuit Up/Down event +- a change in Circuit metric +-a change in Reachable Address metric +-a change in manual + +Area + +Addresses +-a change in systemID +-a change in Designated Intermediate System status +-a change in the waiting status +When such an event occurs the IS shall re-generate changed +LSP(s) with a new sequence number. If the event necessi +tated the generation of an LSP which had not previously +been generated (for example, an adjacency Up event for +an adjacency which could not be accommodated in an exist +ing LSP), the sequence number shall be set to one. The IS +shall then propagate the LSP(s) on every circuit by setting +SRMflag for each circuit. The timer maximum + +LSP + +Gen + + +er + +ation + +Interval shall not be reset. +There is a hold-down timer (min + +i + +mum + +LSP + +Generation + + +Interval) on the generation of each individual LSP. +7.3.7 Generation of Level 1 LSPs +(non-pseudonode) +The Level 1 Link State PDU not generated on behalf of a +pseudonode contains the following information in its vari +able length fields. +-In the Area Addresses option the set of manual + + +Area + +Addresses for this Intermediate System. +-In the Intermediate System Neighbours option +the set of Intermediate system IDs of neighbouring In +termediate systems formed from: +7The set of neighbourSystemIDs with an ap +pended zero octet (indicating non-pseudonode) +from adjacencies in the state Up, on circuits of +type Point-Point, In or Out, with +xneighbourSystemType L1 Intermediate +System +xneighbourSystemType L2 Intermediate +System and adjacencyUsage Level 2 or +Level1 and 2. +The metrics shall be set to the values of Level 1 +metrick of the circuit for each supported routeing +metric. +7The set of l1CircuitIDs for all circuits of type +Broadcast (i.e. the neighbouring pseudonode +IDs) . + +The metrics shall be set to the values of Level 1 +metrick of the circuit for each supported routeing +metric. +7The set of IDs with an appended zero octet derived +from the Network Entity Titles of all Virtual Adja +cencies of this IS. (Note that the Virtual Flag is set +when encoding these entries in the LSP see +7.2.10.) +The default metric shall be set to the total cost to +the virtual NET for the default routeing metric. +The remaining metrics shall be set to the value in +dicating unsupported. +-In the End System Neighbours option the set of +IDs of neighbouring End systems formed from: +7The systemID of the Intermediate System itself, +with a value of zero for all supported metrics. +7The set of endSystemIDs from all adjacencies +with type Auto-configured, in state Up, on +circuits of type Point-to-Point, In or Out, +with neighbourSystemType End system. +The metrics shall be set to the values of Level 1 +metrick of the circuit for each supported routeing +metric. +7The set of endSystemIDs from all adjacencies +with type Manual in state Up, on all circuits. +The metrics shall be set to the values of Level 1 +metrick of the circuit for each supported routeing +metric. +-In the Authentication Information field if the +system's areaTransmitPassword is non-null, in +clude the Authentication Information field contain +ing an Authentication Type of Password, and the +value of the areaTransmitPassword. +7.3.8 Generation of Level 1 Pseudonode LSPs +An IS shall generate a Level 1 pseudonode Link State PDU +for each circuit for which this Intermediate System is the +Level 1 LAN Designated Intermediate System. The LSP +shall specify the following information in its variable length +fields. In all cases a value of zero shall be used for all sup +ported routeing metrics +-The Area Addresses option is not present. +Note - This information is not required since the set of +area addresses for the node issuing the pseudonode +LSP will already have been made available via its own +non-pseudonode LSP. +-In the Intermediate System Neighbours option +the set of Intermediate System IDs of neighbouring In +termediate Systems on the circuit for which this +pseudonode LSP is being generated formed from: +7The Designated Intermediate System's own sys +temID with an appended zero octet (indicating +non-pseudonode). + +7The set of neighbourSystemIDs with an ap +pended zero octet (indicating non-pseudonode) +from adjacencies on this circuit in the state Up, +with +xneighbourSystemType L1 Intermediate +System +xL2 Intermediate System and adjacency +Usage Level 1. +-In the End System Neighbours option the set of +IDs of neighbouring End systems formed from: +7The set of endSystemIDs from all adjacencies +with type Auto-configured, in state Up, on +the circuit for which this pseudonode is being gen +erated, with neighbourSystemType End sys +tem. +-In the Authentication Information field if the +system's areaTransmitPassword is non-null, in +clude the Authentication Information field contain +ing an Authentication Type of Password, and the +value of the areaTransmitPassword. +7.3.9 Generation of Level 2 LSPs +(non-pseudonode) +The Level 2 Link State PDU not generated on behalf of a +pseudonode contains the following information in its vari +able length fields: +-In the Area Addresses option the set of area + + +Addresses for this Intermediate system computed as +described in 7.2.11. +-In the Partition Designated Level 2 IS option the +ID of the Partition Designated Level 2 Intermediate +System for the partition. +-In the Intermediate System Neighbours option +the set of Intermediate system IDs of neighbouring In +termediate systems formed from: +7The set of neighbourSystemIDs with an ap +pended zero octet (indicating non-pseudonode) +from adjacencies in the state Up, on circuits of +type Point-to-Point, In or Out, with neigh +bourSystemType L2 Intermediate System. +7The set of l2CircuitIDs for all circuits of type +Broadcast. (i.e. the neighbouring pseudonode +IDs) +The metric and metric type shall be set to the val +ues of Level 2 metrick of the circuit for each sup +ported routeing metric. +-In the Prefix Neighbours option the set of vari +able length prefixes formed from: +7The set of names of all Reachable Address man +aged objects in state On, on all circuits in state +On. + +The metrics shall be set to the values of Level 2 +metrick for the reachable address. +-In the Authentication Information field if the +system's domainTransmitPassword is non-null, +include the Authentication Information field con +taining an Authentication Type of Password, and +the value of the domainTransmitPassword. +7.3.10 Generation of Level 2 Pseudonode LSPs +A Level 2 pseudonode Link State PDU is generated for +each circuit for which this Intermediate System is the +Level 2 LAN Designated Intermediate System and contains +the following information in its variable length fields. In all +cases a value of zero shall be used for all supported route +ing metrics. +-The Area Addresses option is not present. +Note - This information is not required since the set of +area addresses for the node issuing the pseudonode +LSP will already have been made available via its own +non-pseudonode LSP. +-In the Intermediate System Neighbours option +the set of Intermediate System IDs of neighbouring In +termediate Systems on the circuit for which this +pseudonode LSP is being generated formed from: +7The Designated Intermediate System's own sys +temID with an appended zero octet (indicating +non-pseudonode). +7The set of neighbourSystemIDs with an ap +pended zero octet (indicating non-pseudonode) +from adjacencies on this circuit in the state Up +with neighbourSystemType L2 Intermediate +System. +-The Prefix Neighbours option is not present. +-In the Authentication Information field if the +system's domainTransmitPassword is non-null, +include the Authentication Information field con +taining an Authentication Type of Password, and +the value of the domainTransmitPassword. +7.3.11 Generation of the Checksum +This International Standard makes use of the checksum +function defined in ISO 8473. +The source IS shall compute the LSP Checksum when the +LSP is generated. The checksum shall never be modified by +any other system. The checksum allows the detection of +memory corruptions and thus prevents both the use of in +correct routeing information and its further propagation by +the Update Process. +The checksum shall be computed over all fields in the LSP +which appear after the Remaining Lifetime field. This +field (and those appearing before it) are excluded so that the +LSP may be aged by systems without requiring re- +computation. + +As an additional precaution against hardware failure, when +the source computes the Checksum, it shall start with the +two checksum variables (C0 and C1) initialised to what +they would be after computing for the systemID portion +(i.e. the first 6 octets) of its Source ID. (This value is com +puted and stored when the Network entity is enabled and +whenever systemID changes.) The IS shall then resume +Checksum computation on the contents of the PDU after +the first ID Length octets of the Source ID field. +NOTE - All Checksum calculations on the LSP are per +formed treating the Source ID field as the first octet. This +procedure prevents the source from accidentally sending out +Link State PDUs with some other system's ID as source. +7.3.12 Initiating Transmission +The IS shall store the generated Link State PDU in the Link +State Database, overwriting any previous Link State PDU +with the same LSP Number generated by this system. The +IS shall then set all SRMflags for that Link State PDU, in +dicating it is to be propagated on all circuits with Intermedi +ate System adjacencies. +An Intermediate system shall ensure (by reserving re +sources, or otherwise) that it will always be able to store +and internalise its own non-pseudonode zeroth LSP. In the +event that it is not capable of storing and internalising one +of its own LSPs it shall enter the overloaded state as de +scribed in 7.3.19.1. +NOTE - It is recommended that an Intermediate system en +sure (by reserving resources, or otherwise) that it will al +ways be able to store and internalise all its own (zero and +non-zero, pseudonode and non-pseudonode) LSPs. +7.3.13 Preservation of order +When an existing Link State PDU is re-transmitted (with +the same or a different sequence number), but with the +same information content (i.e. the variable length part) as a +result of there having been no changes in the local topology +databases, the order of the information in the variable +length part shall be the same as that in the previously trans +mitted LSP. +NOTE - If a sequence of changes result in the state of the +database returning to some previous value, there is no re +quirement to preserve the ordering. It is only required when +there have been no changes whatever. This allows the re +ceiver to detect that there has been no change in the infor +mation content by performing an octet for octet comparison +of the variable length part, and hence not re-run the decision +process. +7.3.14 Propagation of LSPs +The update process is responsible for propagating Link +State PDUs throughout the domain (or in the case of +Level 1, throughout the area). +The basic mechanism is flooding, in which each Intermedi +ate system propagates to all its neighbour Intermediate sys +tems except that neighbour from which it received the +PDU. Duplicates are detected and dropped. + +Link state PDUs are received from the Receive Process. +The maximum size control PDU (Link State PDU or Se +quence Numbers PDU) which a system expects to receive +shall be Receive + +LSP + +Buffer + +Size octets. (i.e. the Update +process must provide buffers of at least this size for the re +ception, storage and forwarding of received Link State +PDUs and Sequence Numbers PDUs.) If a control PDU +larger than this size is received, it shall be treated as if it +had an invalid checksum (i.e. ignored by the Update Proc +ess and a corruptedLSPReceived notification generated). +Upon receipt of a Link State PDU the Update Process shall +perform the following functions: +a)Level 2 Link State PDUs shall be propagated on cir +cuits which have at least one Level 2 adjacency. +b)Level 1 Link State PDUs shall be propagated on cir +cuits which have at least one Level 1 adjacency or at +least one Level 2 adjacency not marked Level 2 +only. +c)When propagating a Level 1 Link State PDU on a +broadcast subnetwork, the IS shall transmit to the +multi-destination subnetwork address AllL1IS. +d)When propagating a Level 2 Link State PDU on a +broadcast subnetwork, the IS shall transmit to the +multi-destination subnetwork address AllL2IS. +NOTE When propagating a Link State PDU on a +general topology subnetwork the Data Link Address +is unambiguous (because Link State PDUs are not +propagated across Dynamically Assigned circuits). +e)An Intermediate system receiving a Link State PDU +with an incorrect LSP Checksum or with an invalid +PDU syntax shall +1)log a circuit notification, corruptedLSPRe +ceived, +2)overwrite the Checksum and Remaining Lifetime +with 0, and +3)treat the Link State PDU as though its Remaining +Lifetime had expired (see 7.3.16.4.) +f)A Intermediate system receiving a Link State PDU +which is new (as identified in 7.3.16) shall +1)store the Link State PDU into Link State database, +and +2)mark it as needing to be propagated upon all cir +cuits except that upon which it was received. +g)When a Intermediate system receives a Link State +PDU from source S, which it considers older than the +one stored in the database for S, it shall set the +SRMflag for S's Link State PDU associated with the +circuit from which the older Link State PDU was re +ceived. This indicates that the stored Link State PDU +needs to be sent on the link from which the older one +was received. + +h)When a system receives a Link State PDU which is +the same (not newer or older) as the one stored, the In +termediate system shall +1)acknowledge it if necessary, as described in 7.3.17, +and +2)clear the SRMflag for that circuit for that Link +State PDU. +i)A Link State PDU received with a zero checksum +shall be treated as if the Remaining Lifetime were 0. +The age, if not 0, shall be overwritten with 0. +The Update Process scans the Link State Database for Link +State PDUs with SRMflags set. When one is found, pro +vided the timestamp lastSent indicates that it was propa +gated no more recently than min + +i + +mum + +LSP + +Trans + +mis + +sion + + +Int + +er + +val, the IS shall +a)transmit it on all circuits with SRMflags set, and +b)update lastSent. +7.3.15 Manipulation of SRM and SSN Flags +For each Link State PDU, and for each circuit over which +routeing messages are to be exchanged (i.e. not on DA cir +cuits), there are two flags: +Send Routeing Message (SRMflag) if set, indicates that +Link State PDU should be transmitted on that cir +cuit. On broadcast circuits SRMflag is cleared as +soon as the LSP has been transmitted, but on non- +broadcast circuits SRMflag is only cleared on recep +tion of a Link State PDU or Sequence Numbers +PDU as described below. + SRMflag shall never be set for an LSP with se +quence number zero, nor on a circuit whose exter +nalDomain attribute is True (See 7.3.15.2). +Send Sequence Numbers (SSNflag) if set, indicates that +information about that Link State PDU should be in +cluded in a Partial Sequence Numbers PDU trans +mitted on that circuit. When the Sequence Numbers +PDU has been transmitted SSNflag is cleared. Note +that the Partial Sequence Numbers PDU serves as an +acknowledgement that a Link State PDU was re +ceived. + SSNflag shall never be set on a circuit whose ex +ternalDomain attribute is True. +7.3.15.1 Action on Receipt of a Link State PDU + When a Link State PDU is received on a circuit C, the IS +shall perform the following functions +a)Perform the following PDU acceptance tests: +1)If the LSP was received over a circuit whose ex +ternalDomain attribute is True, the IS shall dis +card the PDU. +2)If the ID Length field of the PDU is not equal to +the value of the IS's routeingDomainIDLength, + +the PDU shall be discarded and an iDField +LengthMismatch notification generated. +3)If this is a level 1 LSP, and the set of areaRe +ceivePasswords is non-null, then perform the +following tests: +i)If the PDU does not contain the Authentica +tion Information field then the PDU shall be +discarded and an authenticationFailure no +tification generated. +ii)If the PDU contains the Authentication In +formation field, but the Authentication +Type is not equal to Password, then the +PDU shall be accepted unless the IS imple +ments the authenticatiion procedure indicated +by the Authentication Type. In this case +whether the IS accepts or ignores the PDU is +outside the scope of this International Stan +dard. +iii)Otherwise, the IS shall compare the password +in the received PDU with the passwords in the +set of areaReceivePasswords, augmented +by the value of the areaTransmitPassword. +If the value in the PDU matches any of these +passwords, the IS shall accept the PDU for +further processing. If the value in the PDU +does not match any of the above values, then +the IS shall ignore the PDU and generate an +authenticationFailure notification. +4)If this is a level 2 LSP, and the set of domainRe +ceivePasswords is non-null, then perform the +following tests: +i)If the PDU does not contain the Authentica +tion Information field then the PDU shall be +discarded and an authenticationFailure no +tification generated. +ii)If the PDU contains the Authentication In +formation field, but the Authentication +Type is not equal to Password, then the +PDU shall be accepted unless the IS imple +ments the authenticatiion procedure indicated +by the Authentication Type. In this case +whether the IS accepts or ignores the PDU is +outside the scope of this International Stan +dard. +iii)Otherwise, the IS shall compare the password +in the received PDU with the passwords in the +set of domainReceivePasswords, aug +mented by the value of the domainTransmit +Password. If the value in the PDU matches +any of these passwords, the IS shall accept the +PDU for further processing. If the value in the +PDU does not match any of the above values, +then the IS shall ignore the PDU and generate +an authenticationFailure notification. +b)If the LSP has zero Remaining Lifetime, perform the +actions described in 7.3.16.4. +c)If the source S of the LSP is an IS or pseudonode for +which all but the last octet are equal to the systemID + +of the receiving Intermediate System, and the receiv +ing Intermediate System does not have that LSP in its +database, or has that LSP, but no longer considers it to +be in the set of LSPs generated by this system (e.g. it +was generated by a previous incarnation of the sys +tem), then initiate a network wide purge of that LSP as +described in 7.3.16.4. +d)If the source S of the LSP is a system (pseudonode or +otherwise) for which the first ID Length octets are +equal to the systemID of the receiving Intermediate +system, and the receiving Intermediate system has an +LSP in the set of currently generated LSPs from that +source in its database (i.e. it is an LSP generated by +this Intermediate system), perform the actions de +scribed in 7.3.16.1. +e)Otherwise, (the source S is some other system), +1)If the LSP is newer than the one in the database, or +if an LSP from that source does not yet exist in the +database: +i)Store the new LSP in the database, overwriting +the existing database LSP for that source (if +any) with the received LSP. +ii)Set SRMflag for that LSP for all circuits +other than C. +iii)Clear SRMflag for C. +iv)If C is a non-broadcast circuit, set SSNflag +for that LSP for C. +v)Clear SSNflag for that LSP for the circuits +other than C. +2)If the LSP is equal to the one in the database (same +Sequence Number, Remaining Lifetimes both zero +or both non-zero, same checksums): +i)Clear SRMflag for C. +ii)If C is a non-broadcast circuit, set SSNflag +for that LSP for C. +3)If the LSP is older than the one in the database: +i)Set SRMflag for C. +ii)Clear SSNflag for C. +When storing a new LSP, the Intermediate system shall first +ensure that it has sufficient memory resources to both store +the LSP and generate whatever internal data structures will +be required to process the LSP by the Update Process. If +these resources are not available the LSP shall be ignored. +It shall neither be stored nor acknowledged. When an LSP +is ignored for this reason the IS shall enter the Waiting +State. (See 7.3.19). +When attempting to store a new version of an existing LSP +(with the same LSPID), which has a length less than or +equal to that of the existing LSP, the existing LSP shall be +removed from the routeing information base and the new +LSP stored as a single atomic action. This ensures that such +an LSP (which may be carrying the LSP Database Overload +indication from an overloaded IS) will never be ignored as +a result of a lack of memory resources. + +7.3.15.2 Action on Receipt of a Sequence Numbers +PDU +When a Sequence Numbers PDU (Complete or Partial, see +7.3.17) is received on circuit C the IS shall perform the fol +lowing functions: +a)Perform the following PDU acceptance tests: +1)If the SNP was received over a circuit whose ex +ternalDomain attribute is True, the IS shall dis +card the PDU. +2)If the ID Length field of the PDU is not equal to +the value of the IS's routeingDomainIDLength, +the PDU shall be discarded and an iDField + + +Length + +Mismatch notification generated. +3)If this is a level 1 SNP and the set of areaRe +ceivePasswords is non-null, then perform the +following tests: +i)If the PDU does not contain the Authentica +tion Information field then the PDU shall be +discarded and an authenticationFailure no +tification generated. +ii)If the PDU contains the Authentication In +formation field, but the Authentication +Type is not equal to Password, then the +PDU shall be accepted unless the IS imple +ments the authenticatiion procedure indicated +by the Authentication Type. In this case +whether the IS accepts or ignores the PDU is +outside the scope of this International Stan +dard. +iii)Otherwise, the IS shall compare the password +in the received PDU with the passwords in the +set of areaReceivePasswords, augmented +by the value of the areaTransmitPassword. +If the value in the PDU matches any of these +passwords, the IS shall accept the PDU for +further processing. If the value in the PDU +does not match any of the above values, then +the IS shall ignore the PDU and generate an +authenticationFailure notification. +4)If this is a level 2 SNP, and the set of domainRe +ceivePasswords is non-null, then perform the +following tests: +i)If the PDU does not contain the Authentica +tion Information field then the PDU shall be +discarded and an authenticationFailure no +tification generated. +ii)If the PDU contains the Authentication In +formation field, but the Authentication +Type is not equal to Password, then the +PDU shall be accepted unless the IS imple +ments the authenticatiion procedure indicated +by the Authentication Type. In this case +whether the IS accepts or ignores the PDU is +outside the scope of this International Stan +dard. + +iii)Otherwise, the IS shall compare the password +in the received PDU with the passwords in the +set of domainReceivePasswords, aug +mented by the value of the domainTransmit +Password. If the value in the PDU matches +any of these passwords, the IS shall accept the +PDU for further processing. If the value in the +PDU does not match any of the above values, +then the IS shall ignore the PDU and generate +an authenticationFailure notification. +b)For each LSP reported in the Sequence Numbers +PDU: +1)If the reported value equals the database value and +C is a non-broadcast circuit, Clear SRMflag for C +for that LSP. +2)If the reported value is older than the database +value, Clear SSNflag, and Set SRMflag. +3)If the reported value is newer than the database +value, Set SSNflag, and if C is a non-broadcast +circuit Clear SRMflag. +4)If no database entry exists for the LSP, and the re +ported Remaining Lifetime, Checksum and Se +quence Number fields of the LSP are all non- +zero, create an entry with sequence number 0 (see +7.3.16.1), and set SSNflag for that entry and cir +cuit C. Under no circumstances shall SRMflag be +set for such an LSP with zero sequence number. +NOTE - This is because possessing a zero sequence +number LSP is semantically equivalent to having no +information about that LSP. If such LSPs were +propagated by setting SRMflag it would result in an +unnecessary consumption of both bandwidth and +memory resources. +c)If the Sequence Numbers PDU is a Complete Se +quence Numbers PDU, Set SRMflags for C for all +LSPs in the database (except those with zero sequence +number or zero remaining lifetime) with LSPIDs +within the range specified for the CSNP by the Start +LSPID and End LSPID fields, which were not men +tioned in the Complete Sequence Numbers PDU (i.e. +LSPs this system has, which the neighbour does not +claim to have). +7.3.15.3 Action on expiration of Complete SNP +Interval +The IS shall perform the following actions every +CompleteSNPInterval seconds for circuit C: +a)If C is a broadcast circuit, then +1)If this Intermediate system is a Level 1 Designated +Intermediate System on circuit C, transmit a com +plete set of Level 1 Complete Sequence Numbers +PDUs on circuit C. Ignore the setting of SSNflag +on Level 1 Link State PDUs. +If the value of the IS's areaTransmitPassword +is non-null, then the IS shall include the Authenti +cation Information field in the transmitted + +CSNP, indicating an Authentication Type of +Password and containing the areaTransmit +Password as the authentication value. +2)If this Intermediate system is a Level 2 Designated +Intermediate System on circuit C, transmit a com +plete set of Level 2 Complete Sequence Numbers +PDUs on circuit C. Ignore the setting of SSNflag +on Level 2 Link State PDUs. +If the value of the IS's domainTransmitPass +word is non-null, then the IS shall include the +Authentication Information field in the trans +mitted CSNP, indicating an Authentication Type +of Password and containing the domainTrans +mitPassword as the authentication value. +A complete set of CSNPs is a set whose startLSPID +and endLSPID ranges cover the complete possible +range of LSPIDs. (i.e. there is no possible LSPID +value which does not appear within the range of one +of the CSNPs in the set). Where more than one CSNP +is transmitted on a broadcast circuit, they shall be +separated by an interval of at least min + +i + +mum + +Broad + + +cast + +LSP + +TransmissionInterval seconds. +NOTE An IS is permitted to transmit a small number +of CSNPs (no more than 10) with a shorter separation in +terval, (or even back to back), provided that no more +than 1000/minimum + +Broad + +cast + +LSP + +Trans + +mis + +sion + +Int + +er + + +val CSNPs are transmitted in any one second period. +b)Otherwise (C is a point to point circuit, including non- +DA DED circuits and virtual links), do nothing. +CSNPs are only transmitted on point to point circuits +at initialisation. +7.3.15.4 Action on expiration of Partial SNP +Interval +The maximum sized Level 1 or Level 2 PSNP which may +be generated by a system is controlled by the values of +originating + +L1 + +LSP + +Buf + +fer + +Size or originating + +L2 + +LSP + + +Buffer + +Size respectively. An Intermediate system shall per +form the following actions every partialSNPInterval sec +onds for circuit C with jitter applied as described in 10.1: +a)If C is a broadcast circuit, then +1)If this Intermediate system is a Level 1 Intermedi +ate System or a Level 2 Intermediate System with +manual + +L2 + +Only + +Mode False, but is not a +Level 1 Designated Intermediate System on circuit +C, transmit a Level 1 Partial Sequence Numbers +PDU on circuit C, containing entries for as many +Level 1 Link State PDUs with SSNflag set as will +fit in the PDU, and then clear SSNflag for these +entries. To avoid the possibility of starvation, the +scan of the LSP database for those with SSNflag +set shall commence with the next LSP which was +not included in the previous scan. If there were no +Level 1 Link State PDUs with SSNflag set, do +not transmit a Level 1 Partial Sequence Numbers +PDU. + +If the value of the IS's areaTransmitPassword +is non-null, then the IS shall include the Authenti +cation Information field in the transmitted +PSNP, indicating an Authentication Type of +Password and containing the areaTransmit +Password as the authentication value. +2)If this Intermediate system is a Level 2 Intermedi +ate System, but is not a Level 2 Designated Inter +mediate System on circuit C, transmit a Level 2 +Partial Sequence Numbers PDU on circuit C, con +taining entries for as many Level 2 Link State +PDUs with SSNflag set as will fit in the PDU, +and then clear SSNflag for these entries. To avoid +the possibility of starvation, the scan of the LSP +database for those with SSNflag set shall com +mence with the next LSP which was not included +in the previous scan. If there were no Level 2 Link +State PDUs with SSNflag set, do not transmit a +Level 2 Partial Sequence Numbers PDU. +If the value of the IS's domainTransmitPass +word is non-null, then the IS shall include the +Authentication Information field in the trans +mitted PSNP, indicating an Authentication Type +of Password and containing the domainTrans +mitPassword as the authentication value. +b)Otherwise (C is a point to point circuit, including non- +DA DED circuits and virtual links) +1)If this system is a Level 1 Intermediate system, +transmit a Level 1 Partial Sequence Numbers PDU +on circuit C, containing entries for as many Level +1 Link State PDUs with SSNflag set as will fit in +the PDU, and then clear SSNflag for these en +tries. To avoid the possibility of starvation, the +scan of the LSP database for those with SSNflag +set shall commence with the next LSP which was +not included in the previous scan. If there were no +Level 1 Link State PDUs with SSNflag set, do +not transmit a Partial Sequence Numbers PDU. +If the value of the IS's areaTransmitPassword +is non-null, then the IS shall include the Authenti +cation Information field in the transmitted +PSNP, indicating an Authentication Type of +Password and containing the areaTransmit +Password as the authentication value. +2)If this system is a Level 2 Intermediate system, +transmit a Level 2 Partial Sequence Numbers PDU +on circuit C, containing entries for as many Level +2 Link State PDUs with SSNflag set as will fit in +the PDU, and then clear SSNflag for these en +tries. To avoid the possibility of starvation, the +scan of the LSP database for those with SSNflag +set shall commence with the next LSP which was +not included in the previous scan. If there were no +Level 2 Link State PDUs with SSNflag set, do +not transmit a Partial Sequence Numbers PDU. +If the value of the IS's domainTransmitPass +word is non-null, then the IS shall include the +Authentication Information field in the trans +mitted PSNP, indicating an Authentication Type + +of Password and containing the domainTrans +mitPassword as the authentication value. +7.3.15.5 Action on expiration of Minimum LSP +Transmission Interval +An IS shall perform the following actions every min + +i + +mum + + +LSP + +Trans + +mis + +sion + +Int + +er + +val seconds with jitter applied as +described in 10.1. +a)For all Point to Point circuits C transmit all LSPs that +have SRMflag set on circuit C, but do not clear the +SRMflag. The SRMflag will subsequently be +cleared by receipt of a Complete or Partial Sequence +Numbers PDU. +The interval between two consecutive transmissions of the +same LSP shall be at least min + +i + +mum + +LSP + +Trans + +mis + +sion + +Int + + +er + +val. Clearly, this can only be achieved precisely by keep +ing a separate timer for each LSP. This would be an unwar +ranted overhead. Any technique which ensures the interval +will be between min + +i + +mum + +LSP + +Trans + +mis + +sion + +Int + +er + +val and +2 * min + +i + +mum + +LSP + +Trans + +mis + +sion + +Int + +er + +val is acceptable. +7.3.15.6 Controlling the Rate of Transmission on +Broadcast Circuits +The attribute min + +i + +mum + +Broad + +cast + +LSP + +Trans + +mis + +sion + + +Inter + +val indicates the minimum interval between PDU arri +vals which can be processed by the slowest Intermediate +System on the LAN. +Setting SRMflags on an LSP for a broadcast circuit does +not cause the LSP to be transmitted immediately. Instead +the Intermediate system shall scan the LSP database every +min + +i + +mum + +Broad + +cast + +LSP + +Trans + +mis + +sion + +Int + +er + +val (with +jitter applied as described in 10.1), and from the set of LSPs +which have SRMflags set for this circuit, one LSP shall be +chosen at random. This LSP shall be multicast on the cir +cuit, and SRMflags cleared. +NOTE - In practice it would be very inefficient to scan the +whole database at this rate, particularly when only a few +LSPs had SRMflags set. Implementations may require ad +ditional data structures in order to reduce this overhead. +NOTE - An IS is permitted to transmit a small number of +LSPs (no more than 10) with a shorter separation interval, +(or even back to back), provided that no more than +1000/min + +i + +mum + +Broad + +cast + +LSP + +Trans + +mis + +sion + +Int + +er + +val LSPs +are transmitted in any one second period. +In addition, the presence of any LSPs which have been re +ceived on a particular circuit and are queued awaiting proc +essing shall inhibit transmission of LSPs on that circuit. +However, LSPs may be transmitted at a minimum rate of +one per second even in the presence of such a queue. +7.3.16 Determining the Latest Information +The Update Process is responsible for determining, given a +received link state PDU, whether that received PDU repre +sents new, old, or duplicate information with respect to +what is stored in the database. + +It is also responsible for generating the information upon +which this determination is based, for assigning a sequence +number to its own Link State PDUs upon generation, and +for correctly adjusting the Remaining Lifetime field upon +broadcast of a link state PDU generated originally by any +system in the domain. +7.3.16.1 Sequence Numbers +The sequence number is a 4 octet unsigned value. Sequence +numbers shall increase from zero to (SequenceModulus +- 1). When a system initialises, it shall start with sequence +number 1 for its own Link State PDUs.55It starts with 1 rather than 0 +so that the value 0 can be reserved to be guaranteed to be less than +the sequence number of any actually generated Link State +PDU. This is a useful property for Sequence Numbers PDUs. + +The sequence numbers the Intermediate system generates +for its Link State PDUs with different values for LSP num +ber are independent. The algorithm for choosing the num +bers is the same, but operationally the numbers will not be +synchronised. +If an Intermediate system R somewhere in the domain has +information that the current sequence number for source S +is greater than that held by S, R will return to S a Link State +PDU for S with R's value for the sequence number. When S +receives this LSP it shall change its sequence number to be +the next number greater than the new one received, and +shall generate a link state PDU. +If an Intermediate system needs to increment its sequence +number, but the sequence number is already equal to +SequenceModulus 1, the notification attempt + +To + +Ex + + +ceed + +Maximum + +Se + +quence + +Num + +ber shall be generated and +the Routeing Module shall be disabled for a period of at +least MaxAge + ZeroAgeLifetime, in order to be sure +that any versions of this LSP with the high sequence num +ber have expired. When it is re-enabled the IS shall start +again with sequence number 1. +7.3.16.2 LSP Confusion +It is possible for an LSP generated by a system in a previ +ous incarnation to be alive in the domain and have the same +sequence number as the current LSP. +To ensure database consistency among the Intermediate +Systems, it is essential to distinguish two such PDUs. This +is done efficiently by comparing the checksum on a re +ceived LSP with the one stored in memory. +If the sequence numbers match, but the checksums do not +and the LSP is not in the current set of LSPs generated by +the local system, then the system that notices the mismatch +shall treat the LSP as if its Remaining Lifetime had expired. +It shall store one of the copies of the LSP, with zero written +as the Remaining Lifetime, and flood the LSP. +If the LSP is in the current set of LSPs generated by the lo +cal system then the IS shall change the LSP's sequence +number to be the next number greater than that of the re +ceived LSP and regenerate the LSP. + +7.3.16.3 Remaining Lifetime field +When the source generates a link state PDU, it shall set the +Remaining Lifetime to MaxAge. +When a system holds the information for some time before +successfully transmitting it to a neighbour, that system shall +decrement the Remaining Lifetime field according to the +holding time. Before transmitting a link state PDU to a +neighbour, a system shall decrement the Remaining Life +time in the PDU being transmitted by at least 1, or more +than 1 if the transit time to that neighbour is estimated to +be greater than one second. When the Remaining Lifetime +field reaches 0, the system shall purge that Link State PDU +from its database. In order to keep the Intermediate Sys +tems' databases synchronised, the purging of an LSP due to +Remaining Lifetime expiration is synchronised by flooding +an expired LSP. See 7.3.16.4. +If the RemainingLifetime of the received LSP is zero it +shall be processed as described in 7.3.16.4. If the Remain +ing Lifetime of the received LSP is non-zero, but there is an +LSP in the database with the same sequence number and +zero Remaining Lifetime, the LSP in the database shall be +considered most recent. Otherwise, the PDU with the larger +sequence number shall be considered the most recent. +If the value of Remaining Lifetime is greater than +MaxAge, the LSP shall be processed as if there were a +checksum error. +7.3.16.4 LSP Expiration Synchronisation +When the Remaining Lifetime on an LSP in memory be +comes zero, the IS shall +a)set all SRMflags for that LSP, and +b)retain only the LSP header. +c)record the time at which the Remaining Lifetime for +this LSP became zero. When ZeroAgeLifetime has +elapsed since the LSP Remaining Lifetime became +zero, the LSP header shall be purged from the data +base. +NOTE - A check of the checksum of a zero Remaining Life +time LSP succeeds even though the data portion is not pre +sent +When a purge of an LSP with non-zero Remaining Lifetime +is initiated, the header shall be retained for MaxAge. +If an LSP from source S with zero Remaining Lifetime is +received on circuit C : +a)If no LSP from S is in memory, then the IS shall +1)send an acknowledgement of the LSP on circuit C, +but +2)shall not retain the LSP after the acknowledgement +has been sent. + +b)If an LSP from S is in the database, then +1)If the received LSP is newer than the one in the da +tabase (i.e. received LSP has higher sequence +number, or same sequence number and database +LSP has non-zero Remaining Lifetime) the IS +shall: +i)overwrite the database LSP with the received +LSP, and note the time at which the zero Re +maining Lifetime LSP was received, so that +after ZeroAgeLifetime has elapsed, that LSP +can be purged from the database, +ii)set SRMflag for that LSP for all circuits other +than C, +iii)clear SRMflag for C, +iv)if C is a non-broadcast circuit, set SSNflag +for that LSP for C, and +v)clear SSNflag for that LSP for the circuits +other than C. +2)If the received LSP is equal to the one in the data +base (i.e. same Sequence Number, Remaining +Lifetimes both zero) the IS shall: +i)clear SRMflag for C, and +ii)if C is a non-broadcast circuit, set SSNflag +for that LSP for C. +3)If the received LSP is older than the one in the da +tabase (i.e. received LSP has lower sequence num +ber) the IS shall: +i)set SRMflag for C, and +ii)clear SSNflag for C. +c)If this system (or pseudonode) is S and there is an un- +expired LSP from S (i.e. its own LSP) in memory, +then the IS: +1)shall not overwrite with the received LSP, but +2)shall change the sequence number of the un- +expired LSP from S as described in 7.3.16.1, +3)generate a new LSP; and +4)set SRMflag on all circuits. +7.3.17 Making the Update Reliable +The update process is responsible for making sure the latest +link state PDUs reach every reachable Intermediate System +in the domain. +On point-to-point links the Intermediate system shall send +an explicit acknowledgement encoded as a Partial Sequence +Numbers PDU (PSNP) containing the following informa +tion: +a)source's ID +b)PDU type (Level 1 or 2) +c)sequence number + +d)Remaining Lifetime +e)checksum +This shall be done for all received link state PDUs which +are newer than the one in the database, or duplicates of the +one in the database. Link state PDUs which are older than +that stored in the database are answered instead by a newer +link state PDU, as specified in 7.3.14 above. +On broadcast links, instead of explicit acknowledgements +for each link state PDU by each Intermediate system, a spe +cial PDU known as a Complete Sequence Numbers PDU +(CSNP), shall be multicast periodically by the Designated +Intermediate System. The PDU shall contain a list of all +LSPs in the database, together with enough information so +that Intermediate systems receiving the CSNP can compare +with their LSP database to determine whether they and the +CSNP transmitter have synchronised LSP databases. The +maximum sized Level 1 or Level 2 Sequence Numbers +PDU which may be generated by a system is controlled by +the values of originating + +L1 + +LSP + +Buf + +fer + +Size or originat +ingL2LSPBufferSize respectively. In practice, the infor +mation required to be transmitted in a single CSNP may be +greater than will fit in a single PDU. Therefore each CSNP +carries an inclusive range of LSPIDs to which it refers. The +complete set of information shall be conveyed by transmit +ting a series of individual CSNPs, each referring to a subset +of the complete range. The ranges of the complete set of +CSNPs shall be contiguous (though not necessarily trans +mitted in order) and shall cover the entire range of possible +LSPIDs. +The LAN Level 1 Designated Intermediate System shall +periodically multicast complete sets of Level 1 CSNPs to +the multi-destination address AllL1ISs. The LAN Level 2 +Designated Intermediate System shall periodically multicast +complete sets of Level 2 CSNPs to the multi-destination ad +dress AllL2ISs. +Absence of an LSPID from a Complete Sequence Numbers +PDU whose range includes that LSPID indicates total lack +of information about that LSPID. +If an Intermediate system, upon receipt of a Complete Se +quence Numbers PDU, detects that the transmitter was out +of date, the receiver shall multicast the missing information. +NOTE - Receipt of a link state PDU on a link is the same as +successfully transmitting the Link State PDU on that link, so +once the first Intermediate system responds, no others will, +unless they have already transmitted replies. +If an Intermediate system detects that the transmitter had +more up to date information, the receiving Intermediate sys +tem shall multicast a Partial Sequence Numbers PDU +(PSNP), containing information about LSPs for which it has +older information. This serves as an implicit request for the +missing information. Although the PSNP is multicast, only +the Designated Intermediate System of the appropriate level +shall respond to the PSNP. +NOTE - This is equivalent to the PSNP being transmitted di +rectly to the Designated Intermediate System, in that it +avoids each Intermediate System unnecessarily sending the +same LSP(s) in response. However, it has the advantage of +preserving the property that all routeing messages can be re + +ceived on the multi-destination addresses, and hence by a +LAN adapter dedicated to the multi-destination address. +When a non-broadcast circuit (re)starts, the IS shall: +a)set SRMflag for that circuit on all LSPs, and +b)send a Complete set of Complete Sequence Numbers +PDUs on that circuit. +7.3.18 Validation of Databases +An Intermediate System shall not continue to operate for an +extended period with corrupted routeing information. The +IS shall therefore operate in a fail-stop manner. If a failure +is detected, the Intermediate system Network entity shall be +disabled until the failure is corrected. In the absence of an +implementation-specific method for ensuring this, the IS +shall perform the following checks at least every max + +i + + +mum + +LSPGenerationInterval seconds: +a)On expiration of this timer the IS shall re-check the +checksum of every LSP in the LSP database (except +those with a Remaining Lifetime of zero) in order to +detect corruption of the LSP while in memory. If the +checksum of any LSP is incorrect, the notification +corruptedLSPDetected shall be logged, and as a +minimum the entire Link State Database shall be de +leted and action taken to cause it to be re-acquired. +One way to achieve this is to disable and re-enable the +IS Network entity. +NOTE On point to point links, this requires at least +that a CSNP be transmitted. +b)On completion of these checks the decision process +shall be notified of an event (even if any newly gener +ated LSPs have identical contents to the previous +ones). This causes the decision process to be run and +the forwarding databases re-computed, thus protecting +against possible corruption of the forwarding data +bases in memory, which would not otherwise be de +tected in a stable topology. +c)The IS shall reset the timer for a period of +maximumLSPGenerationInterval with jitter ap +plied as described in 10.1. +7.3.19 LSP Database Overload +As a result of network mis-configuration, or certain transi +tory conditions, it is possible that there may be insufficient +memory resources available to store a received Link State +PDU. When this occurs, an IS needs to take certain steps to +ensure that if its LSP database becomes inconsistent with +the other ISs', that these ISs do not rely on forwarding +paths through the overloaded IS. +7.3.19.1 Entering the Waiting State +When an LSP cannot be stored, the LSP shall be ignored +and Waiting State shall be entered. A timer shall be started +for waitingTime seconds, and the Intermediate System +shall generate and flood its own LSP with zero LSP number +with the LSP Database Overload Bit set. This prevents + +this Intermediate system from being considered as a for +warding path by other Intermediate Systems. +It is possible that although there are sufficient resources to +store an LSP and permit the operation of the Update Proc +ess on that LSP, the Decision Process may subsequently re +quire further resources in order to complete. If these re +sources are not available, the Intermediate system shall then +(i.e. during the attempt to run the Decision Process) enter +Waiting State until such time as they are available and +waitingTime seconds have elapsed since the last LSP was +ignored by the Update Process. +An implementation shall partition the available memory re +sources between the Level 1 and Level 2 databases. An +overload condition can therefore exist independently for +Level 1 or Level 2 (or both). The status attributes l1State +and l2State indicate the condition for the Level 1 and +Level 2 databases respectively. On entering Level 1 Wait +ing State the IS shall generate the lSP + +L1 + +Data + +base + +Over + + +load notification, and on entering Level 2 Waiting State +the IS shall generate the lSP + +L2 + +Data + +base + +Over + +load notifi +cation. +7.3.19.2 Actions in Level 1 Waiting State +While in Level 1 waiting state +a)If a Link State PDU cannot be stored, the IS shall ig +nore it and restart the timer for waitingTime seconds. +b)The IS shall continue to run the Decision and For +warding processes as normal. +c)When the waitingTime timer expires, the IS shall: +1)Generate an lSP + +L1 + +Data + +base + +Over + +load (recov +ered) notification. +2)Clear the LSP Database Overload bit in its own +Level 1 LSP with zero LSP number and re-issue it. +3)Set the l1State to On. +4)Resume normal operation. +7.3.19.3 Actions in Level 2 Waiting State +While in Level 2 waiting state +a)If a Link State PDU cannot be stored, the IS shall ig +nore it and restart the timer for waitingTime seconds. +b)The IS shall continue to run the Decision and For +warding processes as normal. +c)When the waitingTime timer expires, the IS shall: +1)Generate an lSP + +L2 + +Data + +base + +Over + +load (recov +ered) notification. +2)Clear the LSP Database Overload bit in its own +Level 2 LSP with zero LSP number and re-issue it. +3)Set the l2State to On. +4)Resume normal operation. + +7.3.20 Use of the Link State Database +The only portion of the database relevant to the Decision +Process is the data portion of the Link State PDUs. +The Update Process additionally uses the fields Sequence +Number, Remaining Lifetime, and variable SRMflag. +The Remaining Lifetimes in the stored link state PDUs can +either be periodically decremented, or converted upon re +ceipt into an internal timestamp, and converted back into a +Remaining Lifetime upon transmission. +7.3.20.1 Synchronisation with the Decision Process +Since the Update Process and the Decision Process share +the Link State Database, care must be taken that the Update +Process does not modify the Link State Database while the +Decision Process is running. +There are two approaches to this. In one approach, the De +cision Process signals when it is running. During this time, +the Update Process queues incoming Link State PDUs, and +does not write them into the Link State Database. If more +Link State PDUs arrive than can fit into the queue allotted +while the Decision Process is running, the Update Process +drops them and does not acknowledge them. +Another approach is to have two copies of the Link State +Database one in which the Decision Process is comput +ing, and the other in which the Update Process initially cop +ies over the first database, and in which all new Link State +PDUs are written. Additionally, depending on the hashing +scheme, it is likely that a second copy of the address hash +table will be required, so that the Update Process can do a +rehash occasionally for efficiency. +When the Decision Process is ready to run again, it locks +the new copy of the Link State Database, leaving the Up +date Process to copy over the information into the first area, +and write new updates while the Decision Process runs +again. +The advantage of the first approach is that it takes less +memory. The advantage of the second approach is that Link +State PDUs will never need to be dropped. +NOTE - If the decision process is implemented according to +the specification in C.2, a finer level of parallelism is possi +ble, as described below. + +Arrival of a Link State PDU for a system before that system +has been put into TENT is permitted. The new Link State +PDU is used when that system is eventually put into TENT. +Similarly, arrival of a new Link State PDU for a system af +ter that system has been put into PATHS is permitted. That +system has already been completely processed. The arrival +of the new Link State PDU is noted and the decision process +re-executed when the current execution has completed. An +in-progress execution of the decision process shall not be +abandoned, since this could prevent the decision process +from ever completing. + +Arrival of a Link State PDU for a system between that sys +tem being put on TENT and being transferred to PATHS +shall be treated as equivalent to one of the previous two +cases (for example, by buffering, or taking some corrective +action). + +7.3.20.2 Use of Buffers and Link Bandwidth +Implementations shall have a buffer management strategy +that does not prevent other clients of the buffering service +from acquiring buffers due to excessive use by the Update +Process. They shall also ensure that the Update Process +does not consume all the available bandwidth of links. In +particular no type of traffic should experience starvation for +longer than its acceptable latency. Acceptable latencies are +approximately as follows: +-Hello traffic Hello timer W 0.5 +-Data Traffic 10 seconds. +NOTE - The first of these requirements can be met by re +stricting the Update process to the use of a single buffer on +each circuit for transmission. This may also cause the sec +ond requirement to be met, depending on the processor +speed. + +7.3.21 Parameters +MaxAge This is the amount of time that may elapse +since the estimated origination of the stored Link +State PDU by the source before the LSP is consid +ered expired. The expired LSP can be deleted from +the database after a further ZeroAgeLifetime has +expired. MaxAge shall be larger than maximum + + +LSP + +Generation + +Interval, so that a system is not +purged merely because of lack of events for report +ing Link State PDUs. + MaxAge is an architectural constant equal to 20 +minutes. +ZeroAgeLifetime - This is the minimum amount of time +for which the header of an expired LSP shall be re +tained after it has been flooded with zero Remaining +Lifetime. A very safe value for this would be +2 W MaxAge. However all that is required is that +the header be retained until the zero Remaining Life +time LSP has been safely propagated to all the +neighbours. + ZeroAgeLifetime is an architectural constant with +a value of 1 minute. +maximumLSPGenerationInterval This is the maxi +mum amount of time allowed to elapse between gen +eration of Link State PDUs by a source. It shall be +less than MaxAge. + Setting this parameter too fast adds overhead to the +algorithms (a lot of Link State PDUs). Setting this +parameter too slow (and not violating constraints) +causes the algorithm to wait a long time to recover +in the unlikely event that incorrect Link State infor +mation exists somewhere in the domain about the +system. + A reasonable setting is 15 minutes. + +minimumLSPGenerationInterval This is the minimum +time interval between generation of Link State +PDUs. A source Intermediate system shall wait at +least this long before re-generating one of its own +Link State PDUs. + Setting this too large causes a delay in reporting new +information. Setting this too small allows too much +overhead. + A reasonable setting is 30 seconds. +min + +i + +mum + +LSP + +Trans + +mis + +sion + +Int + +er + +val This is the amount +of time an Intermediate system shall wait before fur +ther propagating another Link State PDU from the +same source system. + Setting this too large causes a delay in propagation +of routeing information and stabilisation of the +routeing algorithm. Setting this too small allows the +possibility that the routeing algorithm, under low +probability circumstances, will use too many re +sources (CPU and bandwidth). + Setting min + +i + +mum + +LSP + +Trans + +mis + +sion + +Int + +er + +val greater +than minimumLSPGenerationInterval makes no +sense, because the source would be allowed to gen +erate LSPs more quickly than they'd be allowed to +be broadcast. Setting min + +i + +mum + +LSP + +Trans + +mis + +sion + + +Int + +er + +val smaller than min + +i + +mum + +LSP + +Generation + + +Inter + +val is desirable to recover from lost LSPs. + A reasonable value is 5 seconds. +CompleteSNPInterval This is the amount of time be +tween periodic transmissions of a complete set of +Sequence Number PDUs by the Designated Interme +diate system on a broadcast link. Setting this too low +slows down the convergence of the routeing algo +rithm when Link State PDUs are lost due to the +datagram environment of the Data Link layer on the +broadcast link. + Setting this too high results in extra control traffic +overhead. + A reasonable value is 10 seconds. + +7.4 The Forwarding Process +The forwarding process is responsible both for transmitting +NPDUs originated by this system, and for forwarding +NPDUs originated by other systems +7.4.1 Input and Output +INPUT +-NPDUs from the ISO 8473 protocol machine +-PDUs from Update Process +-PDUs from Receive Process +-Forwarding Databases (Level 1 and 2) one for each +routeing metric +OUTPUT +-PDUs to Data Link Layer +7.4.2 Routeing Metric Selection +The Forwarding process selects a forwarding database for +each NPDU to be relayed based on: +-the level at which the forwarding is to occur: level 1 +or level 2; and +-a mapping of the ISO 8473 QoS Maintenance field +onto one of the Intermediate system's supported route +ing metrics. +The former selection is made by examining the Destination +Address field of the NPDU. +The latter selection is made as follows: +a)If the QoS Maintenance field is not present in the +NPDU, then the IS shall select the forwarding data +base calculated for the default metric. +b)If the QoS Maintenance field is present, the IS shall +examine bits 7 and 8 of the parameter value octet. If +these two bits specify any combination other than 1 +1 (meaning globally unique QoS), then the IS shall +select the forwarding database calculated for the de +fault metric, otherwise +c)The IS shall select a forwarding database by mapping +the values of bits 3, 2 and 1 of the parameter value as +shown below in table 1 and shall proceed as follows: +1)If the IS does not support the selected routeing +metric, the IS shall forward based upon the default +metric; +2)If the forwarding database for one of the optional +routeing metrics is selected and the database either +does not contain an entry for the Destination Ad +dress in the NPDU being relayed, or contains an +entry indicating that the destination is unreachable +using that metric, then the IS shall attempt to for +ward based upon the default metric; + +3)Otherwise, forward based on the selected optional +metric. +Table 1 - QoS Maintenance bits to routeing +metric mappingsSelected Routeing Metric +bit 3 +bit 2 +bit 1 +expense metric +0 +0 +0 +default metric +0 +0 +1 +expense metric +0 +1 +0 +delay metric +1 +0 +0 +error metric +0 +1 +1 +delay metric +1 +0 +1 +error metric +1 +1 +1 +default metric +1 +1 +0 + +7.4.3 Forwarding Decision +7.4.3.1 Basic Operation +Let DEST = the Network Layer destination address of the +PDU to be forwarded, or the next entry in the source route +ing field, if present. It consists of sub-fields Area Address, +ID, and SEL. +NOTE - The SEL field in the destination address is not ex +amined by Intermediate Systems. It is used by End Systems +to select the proper Transport entity to which to deliver NS +DUs. +This system's (the one examining this PDU for proper for +warding decision) address consists of sub-fields area ad +dress and ID. +a)If the local system type is a level 1 Intermediate sys +tem, or the local system type is a level 2 Intermediate +system and AttachedFlagk = False, then: +1)If the Area Address in the PDU to be forwarded +matches any one of the area addresses of this IS, +then consult the level 1 forwarding database to de +termine the adjacency which is the next hop on the +path to the NPDU's destination. Forward the +NPDU on this adjacency. +2)Otherwise, consult the level 1 forwarding database +to determine the adjacency which is the next hop +on the path to the nearest level 2 is in the area, and +forward the NPDU on this adjacency. +b)If the local system type is Level 2, and Attached +Flagk = True then: +1)If the Area Address in the PDU to be forwarded +matches any one of the area addresses of this IS, + +then consult the level 1 forwarding database to de +termine the adjacency which is the next hop on the +path to the NPDU's destination. Forward the +NPDU on this adjacency. +2)Otherwise, consult the level 2 forwarding database +to determine the adjacency which is the next hop +on the path to the destination area, and forward the +NPDU on this adjacency. +7.4.3.2 Encapsulation for Partition Repair +If this Intermediate system is the Partition Designated +Level 2 IS for this partition, and the PDU is being for +warded onto the special adjacency to a Partition Designated +Level 2 Intermediate system in a different partition of this +area, encapsulate the complete PDU as the data field of a +data NPDU (i.e., with an additional layer of header), mak +ing this system the Source address and the other Partition +Designated Level 2 Intermediate system (obtained from the +identifier attribute of the Virtual Adjacency managed ob +ject) the Destination Address field in the outer PDU +header. Set the QoS Maintenance field of the outer PDU +to indicate forwarding via the default routeing metric (see +table 1). Then forward the encapsulated PDU onto an adja +cency ADJ, obtained by calling the Forward procedure, de +scribed below. +7.4.3.3 The Procedure Forward +This procedure chooses, from a Level 1 forwarding data +base if level is level1, or from a Level 2 forwarding da +tabase if level is level2, an adjacency on which to for +ward NPDUs for destination dest. A pointer to the adja +cency is returned in adj, and the procedure returns the value +True. A destination of 0 at level 1 selects the adjacency +for the nearest level 2 IS computed as described in 7.2.9.1. +If there are multiple possible adjacencies, as a result of mul +tiple minimum cost paths, then one of those adjacencies +shall be chosen. An implementation may chose the adja +cency at random, or may use the possible adjacencies in +round robin fashion. +If there is no entry in the selected forwarding database for +the address dest, and the NPDU originated from the a local +Transport entity and the system has one or more Intermedi +ate System adjacencies, then one of those is chosen at ran +dom (or in round robin fashion) and the procedure returns +the value True. Otherwise the procedure returns the value +False.66This is done so that a system in the overloaded state will +still be able to originate or forward NPDUs. If a system with a partial +routeing information base +were prohibited from attempting to forward to an unknown destination, +system management would be unable to either communicate with this system, or +route through it, for the purpose of diagnosing and/or correcting the +underlying fault. + +NOTE - Since the local adjacency database is pre-loaded +into the decision process, there will always be an entry in +the forwarding database for destinations to which an adja +cency exists. +NOTE - The PDU to be forwarded may require fragmenta +tion, depending on which circuit it is to be forwarded over. +Generating Redirect PDUs + +In addition to forwarding an NPDU, the IS shall inform the +local ISO 9542 protocol machine to generate a Redirect +PDU if the PDU is being forwarded onto the same circuit +from which it came, and if the source SNPA address of the +NPDU indicates that the NPDU was received from an End +System. +7.4.4 The Receive Process +The Receive Process is passed information from any of the +following sources. +-received PDUs with the NLPID of Intra-Domain +routeing, +-configuration information from the ISO 9542 protocol +machine, +-ISO 8473 data PDUs handed to the routeing function +by the ISO 8473 protocol machine. +When an area is partitioned, a level 2 path is used as a +level 1 link to repair the partitioned area. When this occurs, +all PDUs (between the neighbours which must utilise a +multi-hop path for communication) shall be encapsulated in +a data NPDU, addressed to the Intra-Domain routeing se +lector. Control traffic (LSPs, Sequence Numbers PDUs) +shall also be encapsulated, as well as data NPDUs that are +to be passed between the neighbours. +NOTE - It is not necessary to transmit encapsulated IIH +PDUs over a virtual link, since virtual adjacencies are estab +lished and monitored by the operation of the Decision Proc +ess and not the Subnetwork Dependent functions +The Receive Process shall perform the following functions: +-If it is a data NPDU, addressed to this system with +SEL = Intra-Domain routeing, then +7decapsulate the NPDU (remove the outer NPDU +header). +7If the decapsulated PDU is a data NPDU, move +the congestion indications to the decapsulated +NPDU, and pass it to the ISO 8473 protocol ma +chine. +7Otherwise, if the decapsulated PDU is not an ISO +8473 PDU, perform the following steps on the de +capsulated PDU: +-If it is a Link State PDU, pass it to the Update Process +-If it is a Sequence Numbers PDU, pass it to the Up +date Process +-If it is an IIH PDU, pass it to the appropriate +Subnetwork Dependent Function +-If it is a data NPDU or Error Report for another desti +nation, pass it to the Forwarding Process +-Otherwise, ignore the PDU + +7.5 Routeing Parameters +The routeing parameters setable by System Management +are listed for each managed object in clause 11. +7.5.1 Architectural Constants +The architectural constants are described in Table 2. + +Table 2 - Routeing architectural constantsName +Value +Description +MaxLinkMetric +63. +Maximum value of a routeing metric assign +able to a circuit +MaxPathMetric +1023. +Maximum total metric value for a complete +path +AllL1ISs +01-80-C2-00-00-14 +The multi-destination address All Level 1 In +termediate Systems +AllL2ISs +01-80-C2-00-00-15 +The multi-destination address All Level 2 In +termediate Systems +AllIntermediateSystems +09-00-2B-00-00-05 +The multi-destination address All Intermedi +ate Systems used by ISO 9542 +ISO-SAP +FE +The SAP for ISO Network Layer on +ISO 8802-3 LANs +IntradomainRoute + +ing- +PD +10000011 +The Network Layer Protocol Discriminator +assigned by ISO/TR 9577 for this Protocol +IntradomainRouteing +Selector +0. +The NSAP selector for the Intermediate Sys +tem Network entity +SequenceModulus +232 +Size of the sequence number space used by +the Update Process +ReceiveLSPBuffer + +Size +1492. +The size of LSP which all Intermediate sys +tems must be capable of receiving. +MaxAge +1200. +Number of seconds before LSP considered ex +pired. +ZeroAgeLifetime +60. +Number of seconds that an LSP with zero Re +maining Lifetime shall be retained after +propagating a purge. +AllEndSystems +09-00-2B-00-00-04 +The multi-destination address All End Sys +tems used by ISO 9542 +Max + +i + +mum + +Area + + +Addresses +3. +The maximum number of area addresses +which may exist for a single area. +HoldingMultiplier +3. +The number by which to multiply hello + +Timer +to obtain Holding Timer for ISH PDUs and +for Point to Point IIH PDUs. +ISISHoldingMultiplier +10. +The number by which to multiply iSISHel +loTimer to obtain Holding Timer for Level 1 +and Level 2 LAN IIH PDUs. +Jitter +25. +The percentage of jitter which is applied to the +generation of periodic PDUs. + + +8 Subnetwork Dependent +Functions +The Subnetwork Dependent Functions mask the charac +teristics of the different kinds of Subnetworks from the +Subnetwork Independent Routeing Functions. The only +two types of circuits the Subnetwork Independent Functions +recognise are broadcast and general topology. +The Subnetwork Dependent Functions include: +-The use of the ISO 8473 Subnetwork Dependent +Convergence Functions (SNDCF) so that this proto +col may transmit and receive PDUs over the same +subnetwork types, using the same techniques, as does +ISO 8473. +-Co-ordination with the operation of the ESIS proto +col (ISO 9542) in order to determine the Network +layer addresses (and on Broadcast subnetworks, the +subnetwork points of attachment) and identities (End +System or Intermediate System) of all adjacent neigh +bours. This information is held in the Adjacency data +base. It is used to construct Link State PDUs. +-The exchange of IIH PDUs. While it is possible for an +Intermediate System to identify that it has an Interme +diate System neighbour by the receipt of an ISO 9542 +ISH PDU, there is no provision within ISO 9542 to in +dicate whether the neighbour is a Level 1 or a Level 2 +Intermediate System. Specific PDUs (LAN Level 1, +LAN Level 2 and Point to point IIH PDUs) are de +fined to convey this information. +8.1 Multi-destination Circuits on ISs at +a Domain Boundary +Routeing information (e.g. Link State PDUs) is not ex +changed across a routeing domain boundary. All routeing +information relating to a circuit connected to another route +ing domain is therefore entered via the Reachable Address +managed objects. This information is disseminated to the +rest of the routeing domain via Link State PDUs as de +scribed in 7.3.3.2. This has the effect of causing NPDUs +destined for NSAPs which are included in the +addressPrefixes of the Reachable Addresses to be re +layed to that Intermediate System at the domain boundary. +On receipt of such an NPDU the Intermediate system shall +forward it onto the appropriate circuit, based on its own +Link State information. However in the case of multi- +destination subnetworks (such as an ISO 8208 subnetwork +using Dynamic Assignment, a broadcast subnetwork, or a +connectionless subnetwork) it is necessary to ascertain ad +ditional subnetwork dependent addressing information in +order to forward the NPDU to a suitable SNPA. (This may +be the target End system or an Intermediate system within +the other domain.) +In general the SNPA address to which an NPDU is to be +forwarded can be derived from the destination NSAP of the +NPDU. It may be possible to perform some algorithmic ma +nipulation of the NSAP address in order to derive the +SNPA address. However there may be some NSAPs where + +this is not possible. In these cases it is necessary to have +pre-configured information relating an address prefix to a +particular SNPA address. +This is achieved by additional information contained in the +Reachable Address managed object. The mappingType +attribute may be specified as Manual, in which case a +particular SNPA address or set of SNPA addresses is speci +fied in the SNPA Address characteristic. Alternatively the +name of an SNPA address extraction algorithm may be +specified. +8.2 Point to Point Subnetworks +This clause describes the identification of neighbours on +both point to point links and Static circuits. +The IS shall operate the ISO 9542 protocol, shall be able to +receive ISO 9542 ISH PDUs from other ISs, and shall store +the information so obtained in the adjacency database. +8.2.1 Receipt of ESH PDUs Database of End +Systems +An IS shall enter an End system into the adjacency database +when an ESH PDU is received on a circuit. If an ESH PDU +is received on the same circuit, but with a different NSAP +address, the new address shall be added to the adjacency, +with a separate timer. A single ESH PDU may contain more +than one NSAP address. When a new data link address or +NSAP address is added to the adjacency database, the IS +shall generate an adjacencyStateChange (Up) notifica +tion on that adjacency. +The IS shall set a timer for the value of Holding Time in +the received ESH PDU. If another ESH PDU is not re +ceived from the ES before that timer expires, the ES shall +be purged from the database, provided that the Subnetwork +Independent Functions associated with initialising the adja +cency have been completed. Otherwise the IS shall clear the +adjacency as soon as those functions are completed. +When the adjacency is cleared, the Subnetwork Independ +ent Functions shall be informed of an adjacencyState +Change (Down) notification, and the adjacency can be re- +used after the Subnetwork Independent Functions associ +ated with bringing down the adjacency have been com +pleted. +8.2.2 Receiving ISH PDUs by an Intermediate +System +On receipt of an ISH PDU by an Intermediate System, the +IS shall create an adjacency (with state Initialising and +neighbourSystemType Unknown), if one does not al +ready exist, and then perform the following actions:. +a)If the Adjacency state is Up and the ID portion of +the NET field in the ISH PDU does not match the +neighbourID of the adjacency then the IS shall: +1)generate an adjacencyStateChange (Down) no +tification; +2)delete the adjacency; and + +3)create a new adjacency with: +i)state set to Initialising, and +ii)neighbourSystemType set to Unknown. +4)perform the following actions.. +b)If the Adjacency state is Initialising, and the +neighbourSystemType status is Intermediate Sys +tem, the ISH PDU shall be ignored. +c)If the Adjacency state is Initialising and the neigh +bourSystemType status is not Intermediate Sys +tem, a point to point IIH PDU shall be transmitted as +described in 8.2.3. +d)The neighbourSystemType status shall be set to In +termediate System indicating that the neighbour is an +Intermediate system, but the type (L1 or L2) is, as yet, +unknown. +8.2.3 Sending Point to Point IIH PDUs +An IS shall send Point-to-Point IIH PDUs on those Point- +to-Point circuits whose externalDomain attribute is set +False. The IIH shall be constructed and transmitted as +follows: +a)The Circuit Type field shall be set according to Ta +ble 3. +b)The Local Circuit ID field shall be set to a value as +signed by this Intermediate system when the circuit is +created. This value shall be unique among all the cir +cuits of this Intermediate system. +c)The first Point to Point IIH PDU (i.e. that transmitted +as a result of receiving an ISH PDU, rather than as a +result of timer expiration) shall be padded (with trail +ing PAD options containing arbitrary valued octets) so +that the SNSDU containing the IIH PDU has a length +of at least maxsize - 1 octets77The minimum length of PAD which may be +added is 2 octets, since that is the size of the option header. Where +possible the PDU should be padded to +maxsize, but if the PDU length is maxsize- 1 octets no padding is +possible (or required). + where maxsize is the +maximum of +1)dataLinkBlocksize +2)originating + +L1 + +LSP + +Buf + +fer + +Size +3)originatingL2LSPBufferSize +This is done to ensure that an adjacency will only be +formed between systems which are capable of ex +changing PDUs of length up to maxsize octets. In the +absence of this check, it would be possible for an adja +cency to exist with a lower maximum block size, with + +the result that some LSPs and SNPs (i.e. those longer +than this maximum, but less than maxsize) would not +be exchanged. +NOTE - It is necessary for the manager to ensure that the +value of dataLinkBlocksize on a circuit which will be +used to form an Intermediate system to Intermediate sys +tem adjacency is set to a value greater than or equal to the +maximum of the LSPBufferSize characteristics listed +above. If this is not done, the adjacency will fail to initial +ise. It is not possible to enforce this requirement, since it +is not known until initialisation time whether or not the +neighbour on the circuit will be an End system or an In +termediate system. An End system adjacency may oper +ate with a lower value for dataLinkBlocksize. +d)If the value of the circuitTransmitPassword for the +circuit is non-null, then the IS shall include the +Authentication Information field in the transmitted +IIH PDU, indicating an Authentication Type of +Password and containing the circuitTransmit +Password as the authentication value. +8.2.4 Receiving Point to Point IIH PDUs +8.2.4.1 PDU Acceptance Tests +On receipt of a Point-to-Point IIH PDU, perform the fol +lowing PDU acceptance tests: +a)If the IIH PDU was received over a circuit whose ex +ternalDomain attribute is set True, the IS shall dis +card the PDU. +b)If the ID Length field of the PDU is not equal to the +value of the IS's routeingDomainIDLength, the +PDU shall be discarded and an iDFieldLengthMis +match notification generated. +c)If the set of circuitReceivePasswords for this cir +cuit is non-null, then perform the following tests: +1)If the PDU does not contain the Authentication +Information field then the PDU shall be discarded +and an authenticationFailure notification gener +ated. +2)If the PDU contains the Authentication Infor +mation field, but the Authentication Type is not +equal to Password, then the PDU shall be ac +cepted unless the IS implements the authentica +tiion procedure indicated by the Authentication + +Type. In this case whether the IS accepts or ig +nores the PDU is outside the scope of this Interna +tional Standard. +3)Otherwise, the IS shall compare the password in +the received PDU with the passwords in the set of +circuitReceivePasswords for the circuit on +which the PDU was received. If the value in the +PDU matches any of these passwords, the IS shall +accept the PDU for further processing. If the value +in the PDU does not match any of the circuitRe +ceivePasswords, then the IS shall ignore the +PDU and generate an authenticationFailure no +tification. +8.2.4.2 IIH PDU Processing +When a Point to Point IIH PDU is received by an Interme +diate system, the area addresses of the two Intermediate +Systems shall be compared to ascertain the validity of the +adjacency. If the two Intermediate systems have an area ad +dress in common, the adjacency is valid for all combina +tions of Intermediate system types (except where a Level 1 +Intermediate system is connected to a Level 2 Intermediate +system with manualL2OnlyMode set True). However, +if they have no area address in common, the adjacency is +only valid if both Intermediate systems are Level 2, and the +IS shall mark the adjacency as Level 2 Only. This is de +scribed in more detail below. +On receipt of a Point to Point IIH PDU, each of the area ad +dresses from the PDU shall be compared with the set of +area addresses in the manual + +Area + +Addresses attribute. +a)If a match is detected between any pair the following +actions are taken. +1)If the local system is of iSType L1 + +Inter + +mediate + + +Sys + +tem the IS shall perform the action indicated +by Table 4. + +2)If the local system is of iSType L2 + +Intermediate + + +System and the Circuit manualL2OnlyMode +has the value False, the IS shall perform the ac +tion indicated by Table 5. +3)If the local system is of iSType L2 + +Intermediate + + +System and the Circuit manualL2OnlyMode +has the value True, the IS shall perform the ac +tion indicated by Table 6. +b)If a no match is detected between any pair, the follow +ing actions shall be performed. +1)If the local system is of iSType L1 + +Inter + +mediate + + +Sys + +tem and the adjacency is not in state Up, +the IS shall delete the adjacency (if any) and gen +erate an initialisationFailure (Area Mismatch) +notification. +2)If the local system is of iSType L1 + +Inter + +mediate + + +Sys + +tem and the adjacency is in state Up, the IS +shall delete the adjacency and generate an adja +cencyStateChange (Down Area Mismatch) +notification . +3)If the local system is of iSType L2 + +Intermediate + + +System the IS shall perform the action indicated +by Table 7 (irrespective of the value of manu +alL2OnlyMode for this circuit). +c)If the action taken is Up, as detailed in the tables +referenced above, the IS shall compare the Source ID +field of the PDU with the local systemID. +1)If the local Intermediate system has the higher +Source ID, the IS shall set the Circuit CircuitID +status to the concatenation of the local systemID +and the Local Circuit ID (as sent in the Local Cir +cuit ID field of point to point IIH PDUs from this +Intermediate System) of this circuit. + +2)If the remote Intermediate system has the higher +Source ID, the IS shall set the Circuit CircuitID +status to the concatenation of the remote system's +Source ID (from the Source ID field of the PDU), +and the remote system's Local Circuit ID (from the +Local Circuit ID field of the PDU). +3)If the two source IDs are the same (i.e. the system +is initialising to itself), the local systemID is used. +NOTE The circuitID status is not used to generate +the Local Circuit ID to be sent in the Local Circuit +ID field of IIH PDUs transmitted by this Intermedi +ate system. The Local Circuit ID value is assigned +once, when the circuit is created and is not subse +quently changed. +d)If the action taken is Accept and the new value com +puted for the circuitID is different from that in the ex +isting adjacency, the IS shall +1)generate an adjacencyStateChange(Down) noti +fication, and +2)delete the adjacency. +e)If the action taken is Up or Accept the IS shall +1)copy the Adjacency neighbourAreas entries +from the PDU, +2)set the holdingTimer to the value of the Holding +Time from the PDU, and + +3)set the neighbourSystemID to the value of the +Source ID from the PDU. +8.2.5 Monitoring Point-to-point Adjacencies +The IS shall keep a holding time (adjacency holding + + +Timer) for the point-to-point adjacency. The value of the +holding + +Timer shall be set to the Holding Time as reported +in the Holding Timer field of the Pt-Pt IIH PDU. If a neigh +bour is not heard from in that time, the IS shall +a)purge it from the database; and +b)generate an adjacencyStateChange (Down) notifi +cation. +8.3 ISO 8208 Subnetworks +8.3.1 Network Layer Protocols +The way in which the underlying service assumed by ISO +8473 is provided for ISO 8208 subnetworks is described in +clause 8 of ISO 8473. This defines a set of Subnetwork De +pendent Convergence Functions (SNDCFs) that relate the +service provided by specific individual ISO-standard +subnetworks to the abstract underlying service defined in +clause 5.5 of ISO 8473. In particular 8.4.3 describes the +Subnetwork Dependent Convergence Functions used with +ISO 8208 Subnetworks. + +8.3.2 SVC Establishment +8.3.2.1 Use of ISO 8473 Subnetwork Dependent +Convergence Functions +SVCs shall be established according to the procedures de +fined in the ISO 8208 Subnetwork Dependent Convergence +Functions of ISO 8473 (this may be on system management +action or on arrival of data depending on the type of cir +cuit). The Call Request shall contain a Protocol Discrimina +tor specifying ISO 8473 in the first octet of Call Userdata. +In the case of a static circuit, an SVC shall be established +only upon system management action. The IS shall use +neighbourSNPAAddress as the called SNPA address. +In the case of a DA circuit, the call establishment proce +dures are initiated by the arrival of traffic for the circuit. +8.3.2.2 Dynamically Assigned Circuits +A dynamically assigned circuit has multiple adjacencies, +and can therefore establish SVCs to multiple SNPAs. In +general the SNPA address to which a call is to be estab +lished can be derived from the NSAP to which an NPDU is +to be forwarded. In the case where all the NSAPs accessible +over the ISO 8208 subnetwork have IDIs which are their +SNPA addresses, the correct SNPA can be ascertained by +extracting the IDI. However there may be some NSAPs, +which it is required to reach over the ISO 8208 subnetwork, +whose IDI does not correspond to the SNPA address of +their point of attachment to the ISO 8208 subnetwork. The +IDI may refer to some other SNPA address which is sub- +optimally connected to the target NSAP (or not even con +nected at all), or the IDP may not contain an X.121 address +at all (e.g. ISO DCC scheme). In these cases the IS shall +have pre-configured information relating an IDP (or address +prefix) to a particular SNPA address to call. +This is achieved, as described in 8.1, by additional informa +tion contained in the Reachable Address managed object. +The address extraction algorithm may be specified to ex +tract the IDI portion where the IDI is the required X.121 ad +dress. An example of a set of Reachable Addresses is +shown in Table 8. +Table 8 - Example of address prefixesAddress Prefix + + +39 +37 aaaaa +37 +* +37 D +SNPA Address +123X +B +Y +Extract X.121 SNPA address +R, S, T + +This is interpreted as follows: +a)For the ISO DCC prefix 39 123, call the SNPA ad +dress X. + +b)For the X.121 IDI address prefix 37 aaaaa, don't +call aaaaa, but call B instead. +c)For all IDPs based on SNPAs with DNIC D (i.e. with +address prefix 37 D), call the address Y (which +would probably be a gateway to a subnetwork with +DNIC D). +d)For any other X.121 IDI (i.e. address prefix 37) call +the SNPA whose address is used as the IDI. +e)Anything else (* in table 8) call one of the SNPA +addresses R, S or T. These would typically be the +SNPA addresses of Level 2 Intermediate Systems +through which any other addresses could potentially +be reached. +NOTE - If a DA circuit is defined with a reachable address +prefix which includes the addresses reachable over a DCM +or STATIC circuit, the cost(s) for the DA circuit must be +greater than those of the STATIC circuit. If this is not the +case, the DA circuit may be used to establish a call to the re +mote SNPA supporting the STATIC circuit, which would +then (wrongly) assume it was the STATIC circuit. +8.3.2.3 Initiating Calls (Level 2 Intermediate +Systems) +When an NPDU is to be forwarded on a dynamically as +signed circuit, for destination NSAP address D, the IS shall: +a)Calculate D's subnetwork address, either as explicitly +stated in the circuit database, or as extracted from the +IDP. +1)If this system is an ES and there is an entry in the +RedirectCache or ReversePathCache for D, use the +subnetwork address in the cache entry. +2)If this system is an ES or Level 2 Intermediate sys +tem, and the address matches one of the listed +reachable address prefixes (including *, if pre +sent), the subnetwork address is that specified ac +cording to the mappingType attribute (either +Manual, indicating that the set of addresses in +the sNPAAddresses attribute of that Reachable +Address are to be used, or Algorithm, indicating +that it is to be extracted from the IDP using the +specified algorithm). If multiple SNPA addresses +are specified, and there is already an adjacency up +to one of those SNPA addresses, then choose that +subnetwork address, otherwise choose the +subnetwork address with the oldest timestamp as +described in 8.3.2.4. +3)If the address does not match one of the listed +reachable address prefixes (and there is no * en +try), invoke the ISO 8473 Discard PDU function. +b)Scan the adjacencies for one already open to D's +subnetwork address (i.e. reserveTimer has not yet +expired). If one is found, transmit the NPDU on that +adjacency. +c)If no adjacency has a call established to the required +subnetwork address, but there is a free adjacency, at + +tempt to establish the call using that subnetwork ad +dress. +d)If there is no free adjacency invoke the ISO 8473 Dis +card PDU function. +NOTE Where possible, when an adjacency is reserved +(when an SVC has been cleared as a result of the +idleTimer expiring, but the reserveTimer has not yet ex +pired), resources within the subnetwork service provider +should be reserved, in order to minimise the probability +that the adjacency will not be able to initiate a call when +required. +8.3.2.4 Call Attempt Failures +The Reachable Address managed objects may contain a set +of SNPA addresses, each of which has an associated time- +stamp. The time-stamps shall be initialised to infinitely +old. +Some of the SNPAs in this set may be unreachable. If a call +attempt fails to one of the SNPA addresses listed, the IS +shall mark that entry in the list with the time of the latest +failed attempt. When an SNPA address is to be chosen from +the list, the IS shall choose the one with the oldest time- +stamp , unless the oldest time-stamp is more recent than +recallTimer. If the oldest time-stamp is more recent than +recallTimer, all SNPAs in the set shall be assumed tempo +rarily unreachable and no call attempt is made. The IS shall +instead invoke the ISO 8473 Discard PDU function. +When attempting to establish a connection to a single spe +cific subnetwork address (not through one of a set of SNPA +addresses), if a call attempt to a particular SNPA address, +A, fails for any reason, the IS shall invoke the ISO 8473 +Discard PDU function. Additionally the adjacency on +which the call attempt was placed shall be placed in +Failed state, and the recall timer set. Until it expires, the +IS shall not attempt call establishment for future NPDUs to +be forwarded over subnetwork address A, but instead the IS +shall invoke the ISO 8473 Discard PDU function. +When the recall timer expires, the IS shall free the adja +cency for calls to a different destination or retry attempts to +subnetwork address A. +NOTE - If an implementation can store the knowledge of +SNPA addresses that have failed along with the time since +the attempt was made in a location other than the adjacency +on which the call was attempted, then that adjacency can be +used for other calls. +8.3.3 Reverse Path Forwarding on DA Circuits +Where a subdomain is attached to a Connection-oriented +subnetwork by two or more SNPAs, the IDP for the ad +dresses within the subdomain may be chosen to be con +structed from the address of one of the points of attachment. +(It need not be. The whole subdomain could be multi- +homed by using both SNPA addresses, or some other IDP +could be chosen; e.g. ISO DCC.) Traffic to the subdomain +from some other SNPA will cause a call to be established to +the SNPA corresponding to the IDP of the addresses in the +subdomain. Traffic from the subdomain may use either of +the SNPAs depending on the routeing decisions made by + +the subdomain. This is illustrated in the diagram below (fig +ure 5). +Figure 5 - B.xB.yC.zISO 8208 SubnetworkBACExample for reverse path +forwarding +The subdomain is attached to the connection-oriented +subnetwork via SNPAs A and B. The addresses on the +subdomain are constructed using the SNPA address of B as +the IDI. If traffic for C.z is sent from B.x, a call will be es +tablished from A to C. The reverse traffic from C.z to B.x +will cause another call to be established from C to B. Thus +two SVCs have been established where only one is re +quired. +This problem is prevented by the local system retaining a +cache (known as the ReversePathCache) of NSAP ad +dresses from which traffic has been received over each ad +jacency. When it has traffic to forward over the connection- +oriented subnetwork, the IS shall it first check to see if the +destination NSAP is in the cache of any of its adjacencies, +and if so forwards the traffic over that adjacency. An NSAP +shall only be added to the cache when the remote SNPA ad +dress of the adjacency over which it is received differs from +the SNPA address to be called which would be generated +by checking against the Circuit Reachable Addresses man +aged objects. If the cache is full, the IS shall overwrite the +least recently used entry. The ReversePathCache, if imple +mented, shall have a size of at least one entry. The IS shall +purge the cache when the adjacency is taken down (i.e. +when the reserve timer expires). +8.3.4 Use of ISO 9542 on ISO 8208 +subnetworks +STATIC and DA circuits are equivalent to point to point +links, and as such permit the operation of ISO 9542 as de +scribed for point to point links in 8.2. +For DA circuits, it is impractical to use ISO 9542 to obtain +configuration information, such as the location of Interme +diate systems, since this would require calls to be estab +lished to all possible SNPA addresses. +The IS shall not send ISO 9542 ISH PDUs on a DA circuit. +The IS shall take no action on receipt of an ESH PDU or +ISH PDU, and the circuit shall complete initialisation with +out waiting for their arrival. +The IS shall not send Point to point IIH PDU on DA cir +cuits. The IS shall ignore receipt of a point-point IIH PDU. +(This would only occur if a STATIC or DA circuit became + +erroneously connected to an SVC being used for a DA cir +cuit.) +8.3.5 Interactions with the Update Process +A dynamically assigned circuit contains a list of tuples. Also, each dy +namically assigned circuit has a specified call establishment +cost measured by call + +Estab + +lish + +ment + +Met + +rick (where k in +dexes the four defined metrics). The call establishment cost +is always an internal metric, and is therefore directly com +parable with the reachable address metric only if the reach +able address metric is also internal. +When the circuit is enabled, the Subnetwork Dependent +functions in an Intermediate system shall report (to the Up +date Process) adjacency cost change events for all ad +dress prefixes in the circuit Reachable Address managed +object, together with the Reachable address metrick + Del +tak increment. If reachable address metrick is internal, then +Deltak = call + +Estab + +lish + +ment + +Met + +rick. If reachable address +metrick is external, then Deltak = 0. +This causes this information to be included in subsequently +generated LSPs as described in 7.3.3.2. +Routeing PDUs (LSPs and Sequence number PDUs) shall +not be sent on dynamically assigned circuits. +NOTE - In the following sub-clauses, it is assumed that the +Reachable Addresses referenced are only those which have +been enabled (i.e. that have state On), and whose parent +circuit is also in state On. +8.3.5.1 Adjacency Creation +After an SVC to SNPA address D is successfully estab +lished and a new adjacency created for it (whether it was in +itiated by the local or the remote system), if call + +Estab + +lish + + +ment + +Met + +rickIncrement is greater than 0, the IS shall scan +the circuit Reachable Address managed objects for all +addressPrefixes listed with D as (one of) the sNPAAd +dress(es). +For Reachable Addresses with mappingType Algo +rithm, the IS shall construct an implied address prefix88i.e. some +address prefix which matches the addressPrefix of the Reachable +Address, and which would generate the SNPA Address D when the extrac +tion algorithm is applied + +from the actual remote SNPA address D and the address ex +traction algorithm. The IS shall generate an Adjacency cost +change event for each such address prefix (both actual and +implied) with the Reachable Address metrick (without the +added call + +Estab + +lish + +ment + +Met + +rickIncrement). This causes +information that those address prefixes are reachable with +the lower cost to be included in subsequently generated +LSPs. The effect of this is to encourage the use of already +established SVCs where possible. +8.3.5.2 Adjacency Deletion +When the adjacency with sNPAAddress D is freed (Re +serve Timer has expired, or the adjacency is deleted by Sys +tem Management action) then if call + +Estab + +lish + +ment + +Met + + +rickIncrement is greater than 0, the IS shall scan the Cir + +cuit Reachable Address managed objects for all those with +mappingType Manual and (one of) their sNPAAd +dresses equal to D. The IS shall generate Adjacency +cost change events to the Update Process for all such ad +dress prefixes with the Reachable Address metrick + Deltak +increment (where Deltak is the same as defined above). For +Reachable Addresses with mappingType X.121 for +which it is possible to construct an implied address prefix +as above, the IS shall generate an adjacencyState +Change notification for that implied prefix. +A cost change event shall only be generated when the count +of the number of subnetwork addresses which have an es +tablished SVC changes between 1 and 0. +8.3.5.3 Circuit Call Establishment Increment +Change +On a dynamically assigned circuit, when system manage +ment changes the Circuit call + + +Estab + +lish + +ment + +Met + + +rickIncrement for that circuit, the IS shall generate adja +cency cost change events for all address prefixes affected +by the change (i.e. those for which calls are not currently +established). +The IS shall scan all the Reachable Address managed ob +jects of that Circuit. If the Reachable Address has +mappingType X.121, the IS shall generate an adja +cency cost change event for that name with the Reach +able Address metrick + the new value of Deltak. If (based +on the new value of callEstab + +lish + +ment + +Met + +rickIncrement) +the Reachable Address has mappingType Manual, the +IS shall scan all the Adjacencies of the Circuit for an Adja +cency with sNPAAddress equal to (one of) the sN +PAAddresses of that Reachable Address. If no such adja +cency is found the IS shall generate an adjacency cost +change event for that name with the Reachable Address +metrick + the new value of Deltak (based on the new value +of callEstlishmentMetrickIncrement). +8.3.5.4 Reachable Address Cost Change +When the metrick characteristic of a Reachable Address in +state On is changed by system management, the IS shall +generate cost change events to the Update Process to reflect +this change. +If the Reachable Address has mappingType Manual, +the IS shall scan all the Adjacencies of the Circuit for an +Adjacency with sNPAAddress equal to (one of) the sN +PAAddresses of that Reachable Address. If one or more +such adjacencies are found, the IS shall generate an adja +cency cost change event for that name with the new +Reachable Address metrick. If no such adjacency is found +the IS shall generate an adjacency cost change event for +that name with the new Reachable Address metrick. +If the Reachable Address has mappingType X.121, the +IS shall generate an adjacency cost change event for that +name with the new Reachable Address metrick + Deltak +(based on the new value of call + +Estab + +lish + +ment + +Met + +rick + + +Increment). In addition, for all Adjacencies of the Circuit + +with an sNPAAddress for which an implied address pre +fix can be generated for this Reachable Address, the IS +shall generate an adjacency cost change event for that im +plied address prefix and the new Reachable Address met +rick. +8.3.5.5 Disabling a Reachable Address +When a Reachable Address managed object is disabled via +management action, the IS shall generate an Adjacency +down event to the Update Process for the name of that +Reachable Address and also for any implied prefixes asso +ciated with that Reachable Address. +8.3.5.6 Enabling a Reachable Address +When a Reachable Address is enabled via system manage +ment action, the IS shall generate Adjacency cost change +events as described for Reachable Address cost change in +8.3.5.4 above. +8.4 Broadcast Subnetworks +8.4.1 Broadcast Subnetwork IIH PDUs +All Intermediate systems on broadcast circuits (both +Level 1 and Level 2) shall transmit LAN IIH PDUs as de +scribed in 8.4.3. Level 1 Intermediate systems shall transmit +only Level 1 LAN IIH PDUs. Level 2 Intermediate Systems +on circuits with manualL2OnlyMode set to the value +True, shall transmit only Level 2 LAN IIH PDUs. +Level 2 Intermediate systems on circuits with manu +alL2OnlyMode set to the value False, shall transmit +both. +Level n LAN IIH PDUs contain the transmitting Intermedi +ate system's ID, holding timer, Level n Priority and +manual + +Area + +Addresses, plus a list containing the lA +NAddresses of all the adjacencies of neighbourSystem +Type Ln Intermediate System (in state Initialising or +Up) on this circuit. +LAN IIH PDUs shall be padded (with trailing PAD options +containing arbitrary valued octets) so that the SNSDU con +taining the IIH PDU has a length of at least maxsize- 1 oc +tets99The minimum length of PAD which may be added is 2 octets, since +that is the size of the option header. Where possible the PDU should be padded to +maxsize, but if the PDU length is maxsize- 1 octets no padding is +possible (or required). + where maxsize for Level 1 IIH PDUs is the maximum +of +-dataLinkBlocksize +-originating + +L1 + +LSP + +Buf + +fer + +Size +and for Level 2 IIH PDUs is the maximum of +-dataLinkBlocksize +-originatingL2LSPBufferSize +This is done to ensure that an adjacency will only be +formed between systems which are capable of exchanging +PDUs of length up to maxsize octets. In the absence of this + +check, it would be possible for an adjacency to exist with a +lower maximum block size, with the result that some LSPs +and SNPs (i.e. those longer than this maximum, but less +than maxsize) would not be exchanged. +NOTE - An example of a topology where this could occur is +one where an extended LAN is constructed from LAN seg +ments with different maximum block sizes. If, as a result of +mis-configuration or some dynamic reconfiguration, a path +exists between two Intermediate systems on separate LAN +segments having a large maximum block size, which in +volves transit of a LAN segment with a smaller maximum +block size, loss of larger PDUs will occur if the Intermediate +systems continue to use the larger maximum block size. It is +better to refuse to bring up the adjacency in these circum +stances. +Level 1 Intermediate systems shall transmit Level 1 LAN +IIH PDUs to the multi-destination address AllL1ISs, and +also listen on that address. They shall also listen for ESH +PDUs on the multi-destination address AllIntermediateSys +tems. The list of neighbour Intermediate systems shall con +tain only Level 1 Intermediate Systems within the same +area. (i.e. Adjacencies of neighbourSystemType L1 In +termediate System.) +Level 2 Only Intermediate systems (i.e. Level 2 Intermedi +ate systems which have the Circuit manualL2OnlyMode +characteristic set to the value True) shall transmit Level 2 +LAN IIH PDUs to the multi-destination address AllL2ISs, +and also listen on that address. The list of neighbour Inter +mediate systems shall contain only Level 2 Intermediate +systems. (i.e. Adjacencies of neighbourSystemType L2 +Intermediate System.) +Level 2 Intermediate systems (with manualL2OnlyMode +False) shall perform both of the above actions. Separate +Level 1 and Level 2 LAN IIH PDUs shall be sent to the +multi-destination addresses AllL1ISs and AllL2ISs de +scribing the neighbour Intermediate systems for Level 1 +and Level 2 respectively. Separate adjacencies shall be cre +ated by the receipt of Level 1 and Level 2 LAN IIH PDUs. +8.4.1.1 IIH PDU Acceptance Tests +On receipt of a Broadcast IIH PDU, perform the following +PDU acceptance tests: +a)If the IIH PDU was received over a circuit whose ex +ternalDomain attribute is True, the IS shall discard +the PDU. +b)If the ID Length field of the PDU is not equal to the +value of the IS's routeingDomainIDLength, the +PDU shall be discarded and an iDFieldLengthMis +match notification generated. +c)If the set of circuitReceivePasswords for this cir +cuit is non-null, then perform the following tests: +1)If the PDU does not contain the Authentication +Information field then the PDU shall be discarded + +and an authenticationFailure notification gener +ated. +2)If the PDU contains the Authentication Infor +mation field, but the Authentication Type is not +equal to Password, then the PDU shall be ac +cepted unless the IS implements the authentica +tiion procedure indicated by the Authentication +Type. In this case whether the IS accepts or ig +nores the PDU is outside the scope of this Interna +tional Standard. +3)Otherwise, the IS shall compare the password in +the received PDU with the passwords in the set of +circuitReceivePasswords for the circuit on +which the PDU was received. If the value in the +PDU matches any of these passwords, the IS shall +accept the PDU for further processing. If the value +in the PDU does not match any of the circuitRe +ceivePasswords, then the IS shall ignore the +PDU and generate an authenticationFailure no +tification. +8.4.1.2 Receipt of Level 1 IIH PDUs +On receipt of a Level 1 LAN IIH PDU on the multi- +destination address AllL1ISs, the IS shall compare each of +the area addresses, from the received IIH PDU with the set +of area addresses in the manual + +Area + +Addresses charac +teristic. If a match is not found between any pair (i.e. the lo +cal and remote system have no area address in common), +the IS shall reject the adjacency and generate an initialisa +tionFailure (area mismatch) notification. Otherwise (a +match is found) the IS shall accept the adjacency and set the +Adjacency neighbourSystemType to L1 Intermediate +System. +8.4.1.3 Receipt of Level 2 IIH PDUs +On receipt of a Level 2 LAN IIH PDU on the multi- +destination address AllL2ISs, the IS shall accept the adja +cency, and set the Adjacency neighbourSystemType to +L2 Intermediate System. +8.4.1.4 Existing Adjacencies +When a Level n LAN IIH PDU (Level 1 or Level 2) is re +ceived from an Intermediate system for which there is al +ready an adjacency with +a)the Adjacency lANAddress equal to the MAC Source +address of the PDU, and +b)the Adjacency neighbourSystemID equal to the +Source ID field from the PDU and +c)the neighbourSystemType equal to Ln Intermedi +ate System, +the IS shall update the holding timer, LAN Priority and +neighbourAreas according to the values in the PDU. + +8.4.1.5 New Adjacencies +When +a)a Level n LAN IIH PDU (Level 1 or Level 2) is re +ceived (from Intermediate system R), and +b)there is no adjacency for which the Adjacency lANAd +dress is equal to the MAC Source address of the +PDU; and +c)the Adjacency neighbourSystemID is equal to the +Source ID field from the PDU, and +d)neighbourSystemType is Ln Intermediate System, +the IS shall create a new adjacency. However, if there is in +sufficient space in the adjacency database, to permit the +creation of a new adjacency the IS shall instead perform the +actions described in 8.4.2. +The IS shall +a)set neighbourSystemType status to Ln Intermedi +ate System (where n is the level of the IIH PDU), +b)set the holding timer, LAN Priority, neighbourID +and neighbourAreas according to the values in the +PDU., and +c)set the lANAddress according to the MAC source ad +dress of the PDU. +The IS shall set the state of the adjacency to initialising, +until it is known that the communication between this sys +tem and the source of the PDU (R) is two-way. However R +shall be included in future Level n LAN IIH PDUs trans +mitted by this system. +When R reports this circuit's lANAddress in its Level n +LAN IIH PDUs, the IS shall +a)set the adjacency's state to Up, and +b)generate an adjacencyStateChange (Up) notifica +tion. +The IS shall keep a separate Holding Time (Adjacency +holding + +Timer) for each Ln Intermediate System adja +cency. The value of holding + +Timer shall be set to the Hold +ing Time as reported in the Holding Timer field of the +Level n LAN IIH PDUs. If a neighbour is not heard from in +that time, the IS shall +a)purge it from the database; and +b)generate an adjacencyStateChange (Down) notifi +cation. +If a Level n LAN IIH PDU is received from neighbour N, +and this system's lANAddress is no longer in N's IIH +PDU, the IS shall +a)set the adjacency's state to initialising, and + +b)generate an adjacencyStateChange (Down) notifi +cation. +8.4.2 Insufficient Space in Adjacency Database +If an IS needs to create a new Intermediate system adja +cency, but there is insufficient space in the adjacency data +base, the adjacency of neighbourSystemType Ln Inter +mediate System with lowest lANPriority (or if more than +one adjacency has the lowest priority, the adjacency with +the lowest lANAddress, from among those with the lowest +priority) shall be purged from the database. If the new adja +cency would have the lowest priority, it shall be ignored, +and a rejectedAdjacency notification generated. +If an old adjacency must be purged, the IS shall generate an +adjacencyStateChange (Down) notification for that adja +cency. After the Subnetwork Independent Functions issue +an adjacency down complete, the IS may create a new ad +jacency. +8.4.3 Transmission of LAN IIH PDUs +A Level 1 IS shall transmit a Level 1 LAN IIH PDU imme +diately when any circuit whose externalDomain attribute +is False has been enabled. A Level 2 Intermediate Sys +tem shall transmit a Level 2 LAN IIH PDU. A Level 2 In +termediate System shall also transmit a Level 1 LAN IIH +PDU unless the circuit is marked as manualL2OnlyMode +True. +The IS shall also transmit a LAN IIH PDU when at least 1 +second has transpired since the last transmission of a LAN +IIH PDU of the same type on this circuit by this system +and: +a)iSIS + +Hello + +Timer seconds have elapsed1010Jitter is applied as described in 10.1. + since the last +periodic LAN IIH PDU transmission +The Holding Time is set to ISISHoldingMultiplier W +iSIS + +Hello + +Timer. For a Designated Intermediate Sys +tem the value of dRISIS + +Hello + +Timer1111 In this case jitter is not applied, since it would result in +intervals of less than one second. + is used instead +of iSISHelloTimer. The Holding Time for this PDU +shall therefore be set to ISISHoldingMultiplier W +dR + +ISIS + +Hello + +Timer seconds. This permits failing +Designated Intermediate Systems to be detected more +rapidly, +or +b)the contents of the next IIH PDU to be transmitted +would differ from the contents of the previous IIH +PDU transmitted by this system, or +c)this system has determined that it is to become or re +sign as LAN Designated Intermediate System for that +level. +To minimise the possibility of the IIH PDU transmissions +of all Intermediate systems on the LAN becoming synchro +nised, the Hello Time timer shall only be reset when a IIH + +PDU is transmitted as a result of timer expiration, or on be +coming or resigning as Designated Intermediate System. +Where an Intermediate system is transmitting both Level 1 +and Level 2 LAN IIH PDUs, it shall maintain a separate +timer (separately jittered) for the transmission of the +Level 1 and Level 2 IIH PDUs. This avoids correlation be +tween the Level 1 and Level 2 IIH PDUs and allows the re +ception buffer requirements to be minimised. +If the value of the circuitTransmitPassword for the cir +cuit is non-null, then the IS shall include the Authentica +tion Information field in the transmitted IIH PDU, indicat +ing an Authentication Type of Password and contain +ing the circuitTransmitPassword as the authentication +value. +8.4.4 LAN Designated Intermediate Systems +A LAN Designated Intermediate System is the highest pri +ority Intermediate system in a particular set on the LAN, +with numerically highest MAC source lANAddress break +ing ties. (See 7.1.5 for how to compare LAN addresses.) +There are, in general, two LAN Designated Intermediate +Systems on each LAN, namely the LAN Level 1 Desig +nated Intermediate System and the LAN Level 2 Desig +nated Intermediate System. They are elected as follows. +a)Level 1 Intermediate systems elect the LAN Level 1 +Designated Intermediate System. +b)Level 2 Only Intermediate systems (i.e. Level 2 Inter +mediate Systems which have the Circuit manual + +L2 + + +Only + +Mode characteristic set to the value True) +elect the LAN Level 2 Designated Intermediate Sys +tem. +c)Level 2 Intermediate systems (with manu +alL2OnlyMode False) elect both the LAN Level 1 +and LAN Level 2 Designated Intermediate Systems. +The set of Intermediate systems to be considered includes +the local Intermediate system, together with all Intermedi +ate systems of the appropriate type as follows. +a)For the LAN Level 1 Designated Intermediate System, +it is the set of Intermediate systems from which LAN +Level 1 IIH PDUs are received and to which Level 1 +adjacencies exist in state Up. When the local sys +tem either becomes or resigns as LAN Level 1 Desig +nated Intermediate System, the IS shall generate a lan +Level1 + +Designated + +Inter + +mediate + +Sys + +tem + +Change +notification. In addition, when it becomes LAN +Level 1 Designated Intermediate System, it shall per +form the following actions. +1)Generate and transmit Level 1 pseudonode LSPs +using the existing End system configuration. + +2)Purge the Level 1 pseudonode LSPs issued by the +previous LAN Level 1 Designated Intermediate +System (if any) as described in 7.2.3. +3)Solicit the new End system configuration as de +scribed in 8.4.5. +b)For the LAN Level 2 Designated Intermediate System, +it is the set of Intermediate systems from which LAN +Level 2 IIH PDUs are received and to which Level 2 +adjacencies exist in state Up. When the local sys +tem either becomes or resigns as LAN Level 2 Desig +nated Intermediate System, the IS shall generate a lan +Level2 + +Designated + +Inter + +mediate + +System + +Change +notification. In addition, when it becomes LAN +Level 2 Designated Intermediate System, it shall per +form the following actions. +1)Generate and transmit a Level 2 pseudonode LSP. +2)Purge the Level 2 pseudonode LSPs issued by the +previous LAN Level 2 Designated Intermediate +System (if any) as described in 7.2.3. +When an Intermediate system resigns as LAN Level 1 or +Level 2 Designated Intermediate System it shall perform +the actions on Link State PDUs described in 7.2.3. +When the broadcast circuit is enabled on an Intermediate +system the IS shall perform the following actions. +a)Commence sending IIH PDUs with the LAN ID field +set to the concatenation of its own systemID and its +locally assigned one octet Local Circuit ID. +b)Solicit the End system configuration as described in +8.4.5. +c)Start listening for ISO 9542 ISH PDUs and ESH +PDUs and acquire adjacencies as appropriate. Do not +run the Designated Intermediate System election proc +ess. +d)After waiting iSIS + +Hello + +Timer * 2 seconds, run the +Level 1 and or the Level 2 Designated Intermediate +System election process depending on the Intermedi +ate system type. This shall be run subsequently when +ever an IIH PDU is received or transmitted as de +scribed in 8.4.3. (For these purposes, the transmission +of the system's own IIH PDU is equivalent to receiv +ing it). If there has been no change to the information +on which the election is performed since the last time +it was run, the previous result can be assumed. The +relevant information is +1)the set of Intermediate system adjacency states, +2)the set of Intermediate System priorities (including +this system's) and +3)the existence (or otherwise) of at least one Up +End system (not including Manual Adjacencies) or +Intermediate system adjacency on the circuit. +An Intermediate system shall not declare itself to be a LAN +Designated Intermediate system of any type until it has at +least one Up End system (not including Manual Adjacen +cies) or Intermediate system adjacency on the circuit. (This + +prevents an Intermediate System which has a defective re +ceiver and is incapable of receiving any PDUs from errone +ously electing itself LAN Designated Intermediate System.) +The LAN ID field in the LAN IIH PDUs transmitted by this +system shall be set to the value of the LAN ID field reported +in the LAN IIH PDU (for the appropriate level) received +from the system which this system considers to be the Des +ignated Intermediate System. This value shall also be +passed to the Update Process, as the pseudonode ID, to en +able Link State PDUs to be issued for this system claiming +connectivity to the pseudonode. +If this system, as a result of the Designated Intermediate +System election process, considers itself to be designated +Intermediate System, the LAN ID field shall be set to the +concatenation of this system's own system ID and the lo +cally assigned one octet Local Circuit ID. +8.4.5 Soliciting the ES configuration +When there is a change in the topology or configuration of +the LAN (for example the partitioning of a LAN into two +segments by the failure of a repeater or bridge), it is desir +able for the (new) Designated Intermediate System to ac +quire the new End system configuration of the LAN as +quickly as possible in order that it may generate Link State +PDUs which accurately reflect the actual configuration. +This is achieved as follows. +When the circuit is enabled, or the Intermediate system de +tects a change in the set of Intermediate systems on the +LAN, or a change in the Designated Intermediate System +ID, the IS shall initiate a poll of the ES configuration by +performing the following actions. +a)Delay a random interval between 0 and iSIS + +Hello + + +Timer seconds. (This is to avoid synchronisation with +other Intermediate systems which have detected the +change.) +b)If (and only if) an Intermediate System had been re +moved from the set of Intermediate systems on the +LAN, reset the entryRemainingTime field in the +endSystemIDs adjacency database record of all adja +cencies on this circuit to the value +(iSIS + +Hello + +Timer + pollESHelloRate) W +HoldingMultiplier +or the existing value whichever is the lower. (This +causes any End systems which are no longer present +on the LAN to be rapidly timed out, but not before +they have a chance to respond to the poll.) +c)Transmit HoldingMultiplier ISH PDUs for each NET +possessed by the Intermediate system with a Sug +gested ES Configuration Timer value of poll + +ES + + +Hello + +Rate at an interval between them of iSIS + +Hello + + +Timer seconds and a holding time of hello + +Timer * +HoldingMultiplier. +d)Resume sending ISH PDUs at intervals of hello + + +Timer seconds with a Suggested ES Configuration +Timer value of defaultESHelloTimer. + +8.4.6 Receipt of ESH PDUs Database of End +Systems +An IS shall enter an End system into the adjacency database +when an ESH PDU is received from a new data link ad +dress. If an ESH PDU is received with the same data link +address as a current adjacency, but with a different NSAP +address, the new address shall be added to the adjacency, +with a separate timer. A single ESH PDU may contain more +than one NSAP address. When a new data link address or +NSAP address is added to the adjacency database, the IS +shall generate an adjacencyStateChange (Up) notifica +tion on that adjacency. +The IS shall set a timer for the value of the Holding Time +field in the received ESH PDU. If another ESH PDU is not +received from the ES before that timer expires, the ES shall +be purged from the database, provided that the Subnetwork +Independent Functions associated with initialising the adja +cency have been completed. Otherwise the IS shall clear the +adjacency as soon as those functions are completed. +When the adjacency is cleared, the Subnetwork Independ +ent Functions shall be informed of an adjacencyState +Change (Down) notification, and the adjacency can be re- +used after the Subnetwork Independent Functions associ +ated with bringing down the adjacency have been com +pleted. +9 Structure and Encoding of PDUs +This clause describes the PDU formats of the Intra-Domain +Routeing protocol. +9.1 General encoding Rules +Octets in a PDU are numbered starting from 1, in increasing +order. Bits in a 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. +Fields marked Reserved (or simply R) are transmitted as +zero, and ignored on receipt, unless otherwise noted. +Values are given in decimal. All numeric fields are un +signed integers, unless otherwise noted. +9.2 Encoding of Network Layer +Addresses +Network Layer addresses (NSAP addresses, NETs, area ad +dresses and Address Prefixes) are encoded in PDUs accord +ing to the preferred binary encoding specified in +ISO 8348/Add.2; the entire address, taken as a whole is rep +resented explicitly as a string of binary octets. This string is +conveyed in its entirety in the address fields of the PDUs. +The rules governing the generation of the preferred binary +encoding are described in ISO 8348/Add.2. The address so +generated is encoded with the most significant octet (i.e. the +AFI) of the address being the first octet transmitted, and the +more significant semi-octet of each pair of semi-octets in + +the address is encoded in the more significant semi-octet of +each octet (i.e. in the high order 4 bits). Thus the address +/371234 is encoded as +Figure 6 - 111No. of Octets3 +7 +1 +2 +3 +4 +Address encoding example +9.3 Encoding of SNPA Addresses +SNPA addresses (e.g. lANAddress) shall be encoded ac +cording to the rules specified for the particular type of +subnetwork being used. In the case of an ISO 8802 +subnetwork, the SNPA address is the MAC address defined +in ISO 10039, which is encoded according to the binary +representation of MAC addresses specified in ISO 10039. +9.4 PDU Types +The types of PDUs are: +-Level 1 LAN IS to IS Hello PDU +-Level 2 LAN IS to IS Hello PDU +-Point-to-Point IS to IS Hello PDU +-Level 1 Link State PDU +-Level 2 Link State PDU +-Level 1 Complete Sequence Numbers PDU +-Level 2 Complete Sequence Numbers PDU +-Level 1 Partial Sequence Numbers PDU +-Level 2 Partial Sequence Numbers PDU +These are described in the following subclauses. + +9.5 Level 1 LAN IS to IS Hello PDU +This PDU is multicast by Intermediate systems on broad +cast circuits to the multi-destination address AllL1ISs. +The purpose of this PDU is for Intermediate systems on +broadcast circuits to discover the identity of other Level 1 +Intermediate systems on that circuit. Trailing Pad options +are inserted to make PDU Length equal to at least maxsize +- 1 where maxsize is the maximum of +-dataLinkBlocksize +-originating + +L1 + +LSP + +Buf + +fer + +Size +(see 8.4.1). 11No. of Octets1111111ID Length2ID Length + +121VARIABLEIntradomain Routeing +Protocol Discriminator +Length Indicator +Version/Protocol ID Extension +ID Length +PDU Type +R +R +R +Version +ECO +User ECO +Reserved/Circuit Type +Source ID +Holding Time +LAN ID +PDU Length +Priority +R +VARIABLE LENGTH FIELDS + +-Intradomain Routeing Protocol Discriminator +architectural constant +-Length Indicator Length of the fixed header in oc +tets +-Version/Protocol ID Extension 1 +-ID Length Length of the ID field of NSAP ad +dresses and NETs used in this routeing domain. This +field shall take on one of the following values: +7An integer between 1 and 8, inclusive, indicating +an ID field of the corresponding length +7The value zero, which indicates a 6 octet ID field +length +7The value 255, whhich means a null ID field (i.e. +zero length) + +All other values are illegal and shall not be used. +-PDU Type (bits 1 through 5) 15. 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 +-Reserved/Circuit Type Most significant 6 bits re +served (Transmitted as zero, ignored on receipt). Low +order bits (bits 1 and 2) indicate: +70 reserved value (if specified the entire PDU +shall be ignored) +71 Level 1 only +72 Level 2 only (sender is Level 2 Intermediate +system with manualL2OnlyMode set True for +this circuit, and will use this link only for Level 2 +traffic) +73 both Level 1 and Level 2 (sender is Level 2 In +termediate system, and will use this link both for +Level 1 and Level 2 traffic) +NOTE In a LAN Level 1 IIH PDU the Circuit +Type shall be either 1 or 3. +-Source ID the system ID of transmitting Intermedi +ate system +-Holding Time Holding Timer to be used for this In +termediate system +-PDU Length Entire length of this PDU, in octets, +including header +-Reserved/Priority Bit 8 reserved (Transmitted as +zero, ignored on receipt). Bits 1 through 7 priority +for being LAN Level 1 Designated Intermediate Sys +tem. Higher number has higher priority for being LAN +Level 1 Designated Intermediate System. Unsigned +integer. +-LAN ID a field composed the system ID (18 octets) +of the LAN Level 1 Designated Intermediate System, +plus a low order octet assigned by LAN Level 1 Des +ignated Intermediate System. Copied from LAN +Level 1 Designated Intermediate System's IIH PDU. +-VARIABLE LENGTH FIELDS fields of the form:11No. of OctetsLENGTHCODE +LENGTH +VALUE + +Any codes in a received PDU that are not recognised +shall be ignored. + +Currently defined codes are: +7Area Addresses the set of manual + +Area + + +Addresses of this Intermediate System. +xCODE 1 +xLENGTH total length of the value field. +xVALUE 1Address Length1Address LengthNo. of OctetsAddress Length +Area Address +Address Length + +Area Address + +7Address Length Length of Area Ad +dress in octets. +7Area Address Area address. +7Intermediate System Neighbours This option +field can occur multiple times. The set of Interme +diate systems on this LAN to which adjacencies of +neighbourSystemType L1 Intermediate Sys +tem exist in state Up or Initialising (i.e. +those from which Level 1 IIH PDUs have been +heard). +xCODE 6 +xLENGTH total length of the value field. +xVALUE 66No. of OctetsLAN Address +LAN Address + +7LAN Address 6 octet MAC Address of +Intermediate System neighbour. +7Padding This option may occur multiple times. +It is used to pad the PDU to at least maxsize - 1. +xCODE 8. +xLENGTH total length of the value field (may +be zero). +xVALUE LENGTH octets of arbitrary value. +7Authentication Information information for +performing authentication of the originator of the +PDU. +xCODE 10. +xLENGTH variable from 1254 octets + +xVALUE 1VARIABLENo. of OctetsAuthentication Type + +Authentication Value + +7Authentication Type a one octet iden +tifier for the type of authentication to be +carried out. The following values are de +fined: +0 RESERVED +1 Cleartext Password +2254 RESERVED +255 Routeing Domain private +authentication method +7Authentication Value determined by +the value of the authentication type. If +Cleartext Password as defined in this Inter +national Standard is used, then the authenti +cation value is an octet string. + +9.6 Level 2 LAN IS to IS Hello PDU +This PDU is multicast by Intermediate systems on broad +cast circuits to the multi-destination address AllL2ISs. +The purpose of this PDU is for Intermediate systems on +broadcast circuits to discover the identity of other Level 2 +Intermediate systems on that circuit. Trailing Pad options +are inserted to make PDU Length equal to at least maxsize +- 1 where +-dataLinkBlocksize +-originatingL2LSPBufferSize +(see 8.4.1). 11No. of Octets1111111ID Length2ID Length + +121VARIABLEIntradomain Routeing +Protocol Discriminator +Length Indicator +Version/Protocol ID Extension +ID Length +PDU Type +R +R +R +Version +ECO +User ECO +Reserved/Circuit Type +Source ID +Holding Time +LAN ID +PDU Length +Priority +R +VARIABLE LENGTH FIELDS + +-Intradomain Routeing Protocol Discriminator ar +chitectural constant +-Length Indicator Length of fixed header in octets +-Version/Protocol ID Extension 1 +-ID Length Length of the ID field of NSAP ad +dresses and NETs used in this routeing domain. This +field shall take on one of the following values: +7An integer between 1 and 8, inclusive, indicating +an ID field of the corresponding length +7The value zero, which indicates a 6 octet ID field +length +7The value 255, whhich means a null ID field (i.e. +zero length) +All other values are illegal and shall not be used. + +-PDU Type (bits 1 through 5) 16. 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 +-Reserved/Circuit Type Most significant 6 bits re +served (Transmitted as zero, ignored on receipt). Low +order bits (bits 1 and 2) indicate: +70 reserved value (if specified the entire PDU +shall be ignored) +71 Level 1 only +72 Level 2 only (sender is Level 2 Intermediate +System with manualL2OnlyMode set True for +this circuit, and will use this link only for Level 2 +traffic) +73 both Level 1 and Level 2 (sender is Level 2 In +termediate System, and will use this link both for +Level 1 and Level 2 traffic) +NOTE In a LAN Level 2 IIH PDU the Circuit Type +shall be either 2 or 3. +-Source ID the system ID of transmitting Intermedi +ate System +-Holding Time Holding Timer to be used for this In +termediate System +-PDU Length Entire length of this PDU, in octets, +including header +-Reserved/Priority Bit 8 reserved (Transmitted as +zero, ignored on receipt). Bits 1 through 7 priority +for being LAN Level 2 Designated Intermediate Sys +tem. Higher number has higher priority for being LAN +Level 2 Designated Intermediate System. Unsigned +integer. +-LAN ID a field composed the system ID (18 octets) +of the LAN Level 1 Designated Intermediate System, +plus a low order octet assigned by LAN Level 1 Des +ignated Intermediate System. Copied from LAN +Level 1 Designated Intermediate System's IIH PDU. +-VARIABLE LENGTH FIELDS fields of the form:11No. of OctetsLENGTHCODE +LENGTH +VALUE + +Any codes in a received PDU that are not recognised +shall be ignored. +Currently defined codes are: + +7Area addresses the set of manual + +Area + + +Addresses of this Intermediate system. +xCODE 1 +xLENGTH total length of the value field. +xVALUE 1Address Length1Address LengthNo. of OctetsAddress Length +Area Address +Address Length + +Area Address + +7Address Length Length of area address +in octets. +7Area Address Area address. +7Intermediate System Neighbours This option +can occur multiple times. The set of Intermediate +systems on this LAN to which adjacencies of +neighbourSystemType L2 Intermediate Sys +tem exist in state Up or Initialising (i.e. +those from which Level 2 IIH PDUs have been +heard). +xCODE 6 +xLENGTH total length of the value field. +xVALUE 66No. of OctetsLAN Address +LAN Address + +xLAN Address 6 octet MAC Address of In +termediate System neighbour +7Padding This option may occur multiple times. +It is used to pad the PDU to at least maxsize 1. +xCODE 8. +xLENGTH total length of the value field (may +be zero). +xVALUE LENGTH octets of arbitrary value. +7Authentication Information information for +performing authentication of the originator of the +PDU. +xCODE 10. +xLENGTH variable from 1254 octets + +xVALUE 1VARIABLENo. of OctetsAuthentication Type + +Authentication Value + +7Authentication Type a one octet iden +tifier for the type of authentication to be +carried out. The following values are de +fined: +0 RESERVED +1 Cleartext Password +2254 RESERVED +255 Routeing Domain private +authentication method +7Authentication Value determined by +the value of the authentication type. If +Cleartext Password as defined in this Inter +national Standard is used, then the authenti +cation value is an octet string. + +9.7 Point-to-Point IS to IS Hello PDU +This PDU is transmitted by Intermediate systems on non- +broadcast circuits, after receiving an ISH PDU from the +neighbour system. Its purpose is to determine whether the +neighbour is a Level 1 or a Level 2 Intermediate System. +Trailing pad options are inserted to make PDU Length +equal to at least maxsize 1 where maxsize is the maxi +mum of +-dataLinkBlocksize +-originating + +L1 + +LSP + +Buf + +fer + +Size +-originatingL2LSPBufferSize +(see 8.2.3).11No. of Octets1111111ID Length212VARIABLEIntradomain Routeing +Protocol Discriminator +Length Indicator +Version/Protocol ID Extension +ID Length +PDU Type +R +R +R +Version +ECO +User ECO +Reserved/Circuit Type +Source ID +Holding Time +Local Circuit ID +PDU Length +VARIABLE LENGTH FIELDS + +-Intradomain Routeing Protocol Discriminator +architectural constant +-Length Indicator Length of fixed header in octets +-Version/Protocol ID Extension 1 +-ID Length Length of the ID field of NSAP ad +dresses and NETs used in this routeing domain. This +field shall take on one of the following values: +7An integer between 1 and 8, inclusive, indicating +an ID field of the corresponding length +7The value zero, which indicates a 6 octet ID field +length +7The value 255, whhich means a null ID field (i.e. +zero length) +All other values are illegal and shall not be used. + +-PDU Type (bits 1 through 5) 17. 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 +-Reserved/Circuit Type Most significant 6 bits re +served (Transmitted as zero, ignored on receipt). Low +order bits (bits 1 and 2) indicate: +70 reserved value (if specified the entire PDU +shall be ignored) +71 Level 1 only +72 Level 2 only (sender is Level 2 Intermediate +system with manualL2OnlyMode set True for +this circuit, and will use this link only for Level 2 +traffic) +73 both Level 1 and Level 2 (sender is Level 2 In +termediate system and will use this link both for +Level 1 and Level 2 traffic) +-Source ID the system ID of transmitting Intermedi +ate system +-Holding Time Holding Timer to be used for this In +termediate system +-PDU Length Entire length of this PDU, in octets, +including header +-Local Circuit ID 1 octet unique ID assigned to this +circuit when it is created by this Intermediate system. +The actual ID by which the circuit is known to both +ends of the link is determined by the Intermediate sys +tem with the lower Source ID. +-VARIABLE LENGTH FIELDS fields of the form:11No. of OctetsLENGTHCODE +LENGTH +VALUE + +Any codes in a received PDU that are not recognised +shall be ignored. +Currently defined codes are: +7Area addresses the set of manual + +Area + + +Addresses of this Intermediate system +xCODE 1 +xLENGTH total length of the value field. + +xVALUE 1Address Length1Address LengthNo. of OctetsAddress Length +Area Address +Address Length +Area Address + +7Address Length Length of area address +in octets. +7Area Address Area address. +7Padding This option may occur multiple times. +It is used to pad the PDU to at least maxsize 1. +xCODE 8. +xLENGTH total length of the value field (may +be zero). +xVALUE LENGTH octets of arbitrary value. +7Authentication Information information for +performing authentication of the originator of the +PDU. +xCODE 10. +xLENGTH variable from 1254 octets +xVALUE 1VARIABLENo. of OctetsAuthentication Type + +Authentication Value + +7Authentication Type a one octet iden +tifier for the type of authentication to be +carried out. The following values are de +fined: +0 RESERVED +1 Cleartext Password +2254 RESERVED +255 Routeing Domain private +authentication method +7Authentication Value determined by +the value of the authentication type. If +Cleartext Password as defined in this Inter +national Standard is used, then the authenti +cation value is an octet string. + +9.8 Level 1 Link State PDU +Level 1 Link State PDUs are generated by Level 1 and +Level 2 Intermediate systems, and propagated throughout +an area. The contents of the Level 1 Link State PDU indi +cates the state of the adjacencies to neighbour Intermediate +Systems, or pseudonodes, and End systems of the Interme +diate system that originally generated the PDU.11No. of +Octets11111122ID Length + 214VARIABLE2Intradomain Routeing +Protocol Discriminator +Length Indicator +Version/Protocol ID Extension +ID Length +PDU Type +R +R +R +Version +ECO +User ECO +PDU Length +Remaining Lifetime +LSP ID +P +Sequence Number +VARIABLE LENGTH FIELDS +LSPDBOL +IS Type + +Checksum +ATT + +-Intradomain Routeing Protocol Discriminator ar +chitectural constant +-Length Indicator Length if fixed header in octets +-Version/Protocol ID Extension 1 +-ID Length Length of the ID field of NSAP ad +dresses and NETs used in this routeing domain. This +field shall take on one of the following values: +7An integer between 1 and 8, inclusive, indicating +an ID field of the corresponding length +7The value zero, which indicates a 6 octet ID field +length +7The value 255, whhich means a null ID field (i.e. +zero length) +All other values are illegal and shall not be used. +-PDU Type (bits 1 through 5) 18. 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 +-Remaining Lifetime Number of seconds before +LSP considered expired +-LSP ID the system ID of the source of the Link +State PDU. It is structured as follows:ID Length1No. of Octets1Source ID +Pseudonode ID +LSP Number + +-Sequence Number sequence number of LSP +-Checksum Checksum of contents of LSP from +Source ID to end. Checksum is computed as de +scribed in 7.3.11. +-P/ATT/LSPDBOL/IS Type +-P Bit 8, indicates when set that the issuing Interme +diate System supports the Partition Repair optional +function. +7ATT - Bits 7-4 indicate, when set, that the issuing +Intermediate System is `attached' to other areas +using: +xBit 4 - the Default Metric +xBit 5 - the Delay Metric +xBit 6 - the Expense Metric +xBit 7 - the Error Metric. +7LSPDBOL Bit 3 A value of 0 indicates no +LSP Database Overload, and a value of 1 indicates +that the LSP Database is Overloaded. An LSP with +this bit set will not be used by any decision proc +ess to calculate routes to another IS through the +originating system. +7IS Type Bits 1 and 2 indicate the type of Inter +mediate System One of the following values: +x0 Unused value +x1 ( i.e. bit 1 set) Level 1 Intermediate system +x2 Unused value +x3 (i.e. bits 1 and 2 set) Level 2 Intermediate +system. +-VARIABLE LENGTH FIELDS fields of the form:11No. of OctetsLENGTHCODE +LENGTH +VALUE + + +Any codes in a received LSP that are not recognised +are ignored and passed through unchanged. +Currently defined codes are: +7Area Addresses the set of manual + +Area + + +Addresses of this Intermediate system. For +LSPs not generated on behalf of the pseudonode +this option shall always be present in the LSP with +LSP number zero, and shall never be present in an +LSP with non-zero LSP number. It shall appear +before any Intermediate System Neighbours or +End System Neighbours options. This option +shall never be present in pseudonode LSPs. +xCODE 1 +xLENGTH total length of the value field. +xVALUE 1Address Length1Address LengthNo. of OctetsAddress Length +Area Address +Address Length +Area Address + +7Address Length Length of area address +in octets. +7Area Address Area address. +7Intermediate System Neighbours Intermedi +ate system and pseudonode neighbours. +This is permitted to appear multiple times, and in +an LSP with any LSP number. However, all the +Intermediate System Neighbours options +shall precede the End System Neighbours op +tions. i.e. they shall appear before any End system +Neighbour options in the same LSP and no End +system Neighbour options shall appear in an LSP +with lower LSP number. +xCODE 2. +xLENGTH 1. plus a multiple of 11. + +xVALUE No. of Octets11ID Length + 11111ID Length + 1111Virtual Flag +Default Metric +Neighbour ID +Delay Metric +Expense Metric +Error Metric +I/E +0 +I/E +S +I/E +S +I/E +S +Default Metric +Neighbour ID +Delay Metric +Expense Metric +Error Metric +I/E +0 +I/E +S +I/E +S +I/E +S + + +7Virtual Flag is a Boolean. If equal to 1, this +indicates the link is really a Level 2 path to +repair an area partition. (Level 1 Intermedi +ate Systems would always report this octet +as 0 to all neighbours). +7Default Metric is the value of the default +metric for the link to the listed neighbour. +Bit 8 of this field is reserved. Bit 7 of this +field (marked I/E) indicates the metric type, +and shall contain the value 0, indicating +an Internal metric. +7Delay Metric is the value of the delay met +ric for the link to the listed neighbour. If +this IS does not support this metric it shall +set the bit S to 1 to indicate that the met +ric is unsupported. Bit 7 of this field +(marked I/E) indicates the metric type, and +shall contain the value 0, indicating an +Internal metric. +7Expense Metric is the value of the ex +pense metric for the link to the listed neigh +bour. 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 +(marked I/E) indicates the metric type, and +shall contain the value 0, indicating an +Internal metric. +7Error Metric is the value of the error metric +for the link to the listed neighbour. 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 (marked +I/E) indicates the metric type, and shall +contain the value 0, indicating an Internal +metric. +7Neighbour ID. For Intermediate System +neighbours, the first ID Length octets are +the neighbour's system ID, and the last oc +tet is 0. For pseudonode neighbours, the +first ID Length octets is the LAN Level 1 + +Designated Intermediate System's ID, and +the last octet is a non-zero quantity defined +by the LAN Level 1 Designated Intermedi +ate System. +7End System Neighbours End system neigh +bours +This may appear multiple times, and in an LSP +with any LSP number. See the description of the +Intermediate System Neighbours option +above for the relative ordering constraints. Only +adjacencies with identical costs can appear in the +same list. +xCODE 3. +xLENGTH 4. plus a multiple of 6. +xVALUE ID LengthNo. of Octets1ID Length111Neighbour ID +Default Metric +Neighbour ID +Delay Metric + +Expense Metric + +Error Metric +I/E + +0 + +I/E + +S + +I/E + +S + +I/E +S + +7Default Metric is the value of the default +metric for the link to each of the listed +neighbours. Bit 8 of this field is reserved. +Bit 7 of this field (marked I/E) indicates the +metric type, and shall contain the value 0, +indicating an Internal metric. +7Delay Metric is the value of the delay met +ric for the link to each of the listed neigh +bours. If this IS does not support this met +ric it shall set the bit S to 1 to indicate +that the metric is unsupported. Bit 7 of this +field (marked I/E) indicates the metric type, +and shall contain the value 0, indicating +an Internal metric. +7Expense Metric is the value of the ex +pense metric for the link to each of the +listed neighbours. If this IS does not sup +port this metric it shall set the bit S to 1 +to indicate that the metric is unsupported. +Bit 7 of this field (marked I/E) indicates the +metric type, and shall contain the value 0, +indicating an Internal metric. +7Error Metric is the value of the error metric +for the link to each of the listed neighbour. +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 +(marked I/E) indicates the metric type, and +shall contain the value 0, indicating an +Internal metric. +7Neighbour ID system ID of End system +neighbour. + +7Authentication Information information for +performing authentication of the originator of the +PDU. +xCODE 10. +xLENGTH variable from 1254 octets +xVALUE 1VARIABLENo. of OctetsAuthentication Type + +Authentication Value + +7Authentication Type a one octet iden +tifier for the type of authentication to be +carried out. The following values are de +fined: +0 RESERVED +1 Cleartext Password +2254 RESERVED +255 Routeing Domain private +authentication method +7Authentication Value determined by +the value of the authentication type. If +Cleartext Password as defined in this Inter +national Standard is used, then the authenti +cation value is an octet string. + +9.9 Level 2 Link State PDU +Level 2 Link State PDUs are generated by Level 2 Interme +diate systems, and propagated throughout the level 2 do +main. The contents of the Level 2 Link State PDU indicates +the state of the adjacencies to neighbour Level 2 Intermedi +ate Systems, or pseudonodes, and to reachable address pre +fixes of the Intermediate system that originally generated +the PDU.11No. of Octets11111122ID Length + 214VARIABLE2Intradomain Routeing +Protocol Discriminator + +Length Indicator +Version/Protocol ID Extension +ID Length +PDU Type + +R +R +R +Version +ECO +User ECO +PDU Length +Remaining Lifetime +LSP ID +P +Sequence Number +VARIABLE LENGTH FIELDS +LSPDBOL +IS Type + +Checksum +ATT + +-Intradomain Routeing Protocol Discriminator ar +chitectural constant +-Length Indicator Length of fixed header in octets +-Version/Protocol ID Extension 1 +-ID Length Length of the ID field of NSAP ad +dresses and NETs used in this routeing domain. This +field shall take on one of the following values: +7An integer between 1 and 8, inclusive, indicating +an ID field of the corresponding length +7The value zero, which indicates a 6 octet ID field +length +7The value 255, whhich means a null ID field (i.e. +zero length) +All other values are illegal and shall not be used. +-PDU Type (bits 1 through 5) 20. 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. +-Remaining Lifetime Number of seconds before +LSP considered expired +-LSP ID the system ID of the source of the Link +State PDU. It is structured as follows:ID Length1No. of Octets1Source ID +Pseudonode ID +LSP Number + +-Sequence Number sequence number of LSP +-Checksum Checksum of contents of LSP from +Source ID to end. Checksum is computed as de +scribed in 7.3.11. +-P/ATT/LSPDBOL/IS Type +7P Bit 8, indicates when set that the issuing Inter +mediate System supports the Partition Repair op +tional function. +7ATT - Bits 7-4 indicate, when set, that the issuing +Intermediate System is `attached' to other areas +using: +xBit 4 - the Default Metric +xBit 5 - the Delay Metric +xBit 6 - the Expense Metric +xBit 7 - the Error Metric. +7LSPDBOL Bit 3 A value of 0 indicates no +LSP Database Overload, and a value of 1 indicates +that the LSP Database is Overloaded. An LSP with +this bit set will not be used by any decision proc +ess to calculate routes to another IS through the +originating system. +7IS Type Bits 1 and 2 indicate the type of Inter +mediate System One of the following values: +x0 Unused value +x1 ( i.e. bit 1 set) Level 1 Intermediate system +x2 Unused value +x3 (i.e. bits 1 and 2 set) Level 2 Intermediate +system. +NOTE In a Level 2 Link State PDU, IS Type +shall be 3. + +-VARIABLE LENGTH FIELDS fields of the form:11No. of OctetsLENGTHCODE +LENGTH +VALUE + +Any codes in a received LSP that are not recognised +are ignored and passed through unchanged. +Currently defined codes are: +7Area Addresses the set of partition + +Area + + +Addresses of this Intermediate system. For non- +pseudonode LSPs this option shall always be pre +sent in the LSP with LSP number zero, and shall +never be present in an LSP with non-zero LSP +number. It shall appear before any Intermediate +System Neighbours or Prefix Neighbours op +tions. This option shall never be present in +pseudonode LSPs. +xCODE 1 +xLENGTH total length of the value field. +xVALUE 1Address Length1Address LengthNo. of OctetsAddress Length +Area Address +Address Length + +Area Address + +7Address Length Length of area address +in octets. +7Area Address Area address. +7Partition Designated Level 2 Intermediate +System ID of Designated Level 2 Intermediate +System for the partition. For non-pseudonode +LSPs issued by Intermediate Systems which sup +port the partition repair optional function this op +tion shall always be present in the LSP with LSP +number zero, and shall never be present in an LSP +with non-zero LSP number. It shall appear before +any Intermediate System Neighbours or Prefix +Neighbours options. This option shall never be +present in pseudonode LSPs. +xCODE 4. +xLENGTH 6 +xVALUE ID of Partition Designated Level 2 +Intermediate System for the partition. +7Intermediate System Neighbours Intermedi +ate system and pseudonode neighbours. +This is permitted to appear multiple times, and in +an LSP with any LSP number. However, all the +Intermediate System Neighbours options + +shall precede the Prefix Neighbours options. +i.e. they shall appear before any Prefix Neighbour +options in the same LSP and no Prefix Neighbour +options shall appear in an LSP with lower LSP +number. +xCODE 2. +xLENGTH 1. plus a multiple of 11. +xVALUE No. of Octets11ID Length + 11111ID Length + 1111Virtual Flag +Default Metric +Neighbour ID +Delay Metric +Expense Metric +Error Metric +I/E +0 +I/E +S +I/E +S +I/E +S +Default Metric +Neighbour ID +Delay Metric +Expense Metric +Error Metric +I/E +0 +I/E +S +I/E +S +I/E +S + +7Virtual Flag is a Boolean. If equal to 1, this +indicates the link is really a Level 2 path to +repair an area partition. (Level 1 Intermedi +ate Systems would always report this octet +as 0 to all neighbours). +7Default Metric is the value of the default +metric for the link to the listed neighbour. +Bit 8 of this field is reserved. Bit 7 of this +field (marked I/E) indicates the metric type, +and shall contain the value 0, indicating +an Internal metric. +7Delay Metric is the value of the delay met +ric for the link to the listed neighbour. If +this IS does not support this metric it shall +set bit S to 1 to indicate that the metric is +unsupported. Bit 7 of this field (marked +I/E) indicates the metric type, and shall +contain the value 0, indicating an Internal +metric. +7Expense Metric is the value of the ex +pense metric for the link to the listed neigh +bour. If this IS does not support this metric +it shall set bit S to 1 to indicate that the +metric is unsupported. Bit 7 of this field +(marked I/E) indicates the metric type, and +shall contain the value 0, indicating an +Internal metric. +7Error Metric is the value of the error metric +for the link to the listed neighbour. If this +IS does not support this metric it shall set +bit S to 1 to indicate that the metric is un +supported. Bit 7 of this field (marked I/E) + +indicates the metric type, and shall contain +the value 0, indicating an Internal metric. +7Neighbour ID. For Intermediate System +neighbours, the first ID Length octets are +the neighbour's system ID, and the last oc +tet is 0. For pseudonode neighbours, the +first ID Length octets is the LAN Level 1 +Designated Intermediate System's ID, and +the last octet is a non-zero quantity defined +by the LAN Level 1 Designated Intermedi +ate System. +7Prefix Neighbours reachable address prefix +neighbours +This may appear multiple times, and in an LSP +with any LSP number. See the description of the +Intermediate System Neighbours option +above for the relative ordering constraints. Only +adjacencies with identical costs can appear in the +same list. +xCODE 5. +xLENGTH Total length of the VALUE field. +xVALUE 1iAddress Prefix Length /2y1No. of OctetsiAddress Prefix Length +/2y1111Address Prefix Length +Address Prefix +Address Prefix Length + +Address Prefix +Default Metric + +Delay Metric + +Expense Metric + +Error Metric + +I/E + +0 + +I/E + +S + + +I/E + +S + + +I/E + +S + + + +7Default Metric is the value of the default +metric for the link to each of the listed +neighbours. Bit 8 of this field is reserved. +Bit 7 (marked I/E) indicates the metric +type, and may be set to zero indicating an +internal metric, or may be set to 1 indicat +ing an external metric. +7Delay Metric is the value of the delay met +ric for the link to each of the listed neigh +bours. If this IS does not support this met +ric it shall set the bit S to 1 to indicate +that the metric is unsupported. Bit 7 +(marked I/E) indicates the metric type, and +may be set to zero indicating an internal +metric, or may be set to 1 indicating an ex +ternal metric. +7Expense Metric is the value of the ex +pense metric for the link to each of the +listed neighbours. If this IS does not sup +port this metric it shall set the bit S to 1 +to indicate that the metric is unsupported. + +Bit 7 (marked I/E) indicates the metric +type, and may be set to zero indicating an +internal metric, or may be set to 1 indicat +ing an external metric. +7Error Metric is the value of the error metric +for the link to each of the listed neighbour. +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 (marked I/E) +indicates the metric type, and may be set to +zero indicating an internal metric, or may +be set to 1 indicating an external metric. +7Address Prefix Length is the length in +semi-octets of the following prefix. A +length of zero indicates a prefix that +matches all NSAPs. +7Address Prefix is a reachable address pre +fix encoded as described in 7.1.4. If the +length in semi-octets is odd, the prefix is +padded out to an integral number of octets +with a trailing zero semi-octet. +Note that the area addresses listed in the Area Ad +dresses option of Level 2 Link State PDU with +LSP number zero, are understood to be reachable +address neighbours with cost 0. They are not listed +separately in the Prefix Neighbours options. +7Authentication Information information for +performing authentication of the originator of the +PDU. +xCODE 10. +xLENGTH variable from 1254 octets +xVALUE 1VARIABLENo. of OctetsAuthentication Type + +Authentication Value + +7Authentication Type a one octet iden +tifier for the type of authentication to be +carried out. The following values are de +fined: +0 RESERVED +1 Cleartext Password +2254 RESERVED +255 Routeing Domain private +authentication method +7Authentication Value determined by +the value of the authentication type. If +Cleartext Password as defined in this Inter +national Standard is used, then the authenti +cation value is an octet string. + +9.10 Level 1 Complete Sequence +Numbers PDU11No. of Octets1111112ID Length + 1ID Length + 2ID Length + +2VARIABLEIntradomain Routeing +Protocol Discriminator + +Length Indicator +Version/Protocol ID Extension +ID Length +PDU Type + +R +R +R +Version +ECO +User ECO +PDU Length +Source ID +Start LSP ID +End LSP ID +VARIABLE LENGTH FIELDS + +-Intradomain Routeing Protocol Discriminator ar +chitectural constant +-Length Indicator Length of fixed header in octets +-Version/Protocol ID Extension 1 +-ID Length Length of the ID field of NSAP ad +dresses and NETs used in this routeing domain. This +field shall take on one of the following values: +7An integer between 1 and 8, inclusive, indicating +an ID field of the corresponding length +7The value zero, which indicates a 6 octet ID field +length +7The value 255, whhich means a null ID field (i.e. +zero length) +All other values are illegal and shall not be used. +-PDU 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 +-User ECO transmitted as zero, ignored on receipt +-PDU Length Entire Length of this PDU, in octets, +including header +-Source ID the system ID of Intermediate System +(with zero Circuit ID) generating this Sequence Num +bers PDU. + +-Start LSP ID the system ID of first LSP in the +range covered by this Complete Sequence Numbers +PDU. +-End LSP ID the system ID of last LSP in the range +covered by this Complete Sequence Numbers PDU. +-VARIABLE LENGTH FIELDS fields of the form:11No. of OctetsLENGTHCODE +LENGTH +VALUE + +Any codes in a received CSNP that are not recognised +are ignored. +Currently defined codes are: +7LSP Entries This may appear multiple times. +The option fields, if they appear more than once, +shall appear sorted into ascending LSPID order. +xCODE 9 +xLENGTH total length of the value field. +xVALUE a list of LSP entries of the form:4No. of Octets2ID Length + +2242ID Length + 22LSP Sequence Number +Checksum +Remaining Lifetime +LSP ID +LSP Sequence Number +Checksum +Remaining Lifetime +LSP ID + +7Remaining Lifetime Remaining Life +time of LSP. +7LSP ID system ID of the LSP to which +this entry refers. +7LSP Sequence Number Sequence +number of LSP. +7Checksum 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). +7Authentication Information information for +performing authentication of the originator of the +PDU. +xCODE 10. +xLENGTH variable from 1254 octets + +xVALUE 1VARIABLENo. of OctetsAuthentication Type + +Authentication Value + +7Authentication Type a one octet iden +tifier for the type of authentication to be +carried out. The following values are de +fined: +0 RESERVED +1 Cleartext Password +2254 RESERVED +255 Routeing Domain private +authentication method +7Authentication Value determined by +the value of the authentication type. If +Cleartext Password as defined in this Inter +national Standard is used, then the authenti +cation value is an octet string. + +9.11 Level 2 Complete Sequence +Numbers PDU +11No. of Octets1111112ID Length + 1ID Length + 2ID Length + +2VARIABLEIntradomain Routeing +Protocol Discriminator + +Length Indicator +Version/Protocol ID Extension +ID Length +PDU Type + +R +R +R +Version +ECO +User ECO +PDU Length +Source ID +Start LSP ID +End LSP ID +VARIABLE LENGTH FIELDS + +-Intradomain Routeing Protocol Discriminator ar +chitectural constant +-Length Indicator Length of fixed header in octets +-Version/Protocol ID Extension 1 +-ID Length Length of the ID field of NSAP ad +dresses and NETs used in this routeing domain. This +field shall take on one of the following values: +7An integer between 1 and 8, inclusive, indicating +an ID field of the corresponding length +7The value zero, which indicates a 6 octet ID field +length +7The value 255, whhich means a null ID field (i.e. +zero length) +All other values are illegal and shall not be used. +-PDU 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 +-User ECO transmitted as zero, ignored on receipt +-PDU Length Entire Length of this PDU, in octets, +including header + +-Source ID the system ID of Intermediate System +(with zero Circuit ID) generating this Sequence Num +bers PDU. +-Start LSP ID the system ID of first LSP in the +range covered by this Complete Sequence Numbers +PDU. +-End LSP ID the system ID of last LSP in the range +covered by this Complete Sequence Numbers PDU. +-VARIABLE LENGTH FIELDS fields of the form:11No. of OctetsLENGTHCODE +LENGTH +VALUE + +Any codes in a received CSNP that are not recognised +are ignored. +Currently defined codes are: +7LSP Entries this may appear multiple times. +The option fields, if they appear more than once, +shall appear sorted into ascending LSPID order. +xCODE 9 +xLENGTH total length of the value field. +xVALUE a list of LSP entries of the form:4No. of Octets2ID Length + +2242ID Length + 22LSP Sequence Number +Checksum +Remaining Lifetime +LSP ID +LSP Sequence Number +Checksum +Remaining Lifetime +LSP ID + +7Remaining Lifetime Remaining Life +time of LSP. +7LSP ID the system ID of the LSP to +which this entry refers. +7LSP Sequence Number Sequence +number of LSP. +7Checksum 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). +7Authentication Information information for +performing authentication of the originator of the +PDU. + +xCODE 10. +xLENGTH variable from 1254 octets +xVALUE 1VARIABLENo. of OctetsAuthentication Type + +Authentication Value + +7Authentication Type a one octet iden +tifier for the type of authentication to be +carried out. The following values are de +fined: +0 RESERVED +1 Cleartext Password +2254 RESERVED +255 Routeing Domain private +authentication method +7Authentication Value determined by +the value of the authentication type. If +Cleartext Password as defined in this Inter +national Standard is used, then the authenti +cation value is an octet string. + +9.12 Level 1 Partial Sequence Numbers +PDU +11No. of Octets1111112ID Length + 1VARIABLEIntradomain Routeing +Protocol Discriminator + +Length Indicator +Version/Protocol ID Extension +ID Length +PDU Type + +R +R +R +Version +ECO +User ECO +PDU Length +Source ID +VARIABLE LENGTH FIELDS + +-Intradomain Routeing Protocol Discriminator ar +chitectural constant +-Length Indicator Length of fixed header in octets +-Version/Protocol ID Extension 1 +-ID Length Length of the ID field of NSAP ad +dresses and NETs used in this routeing domain. This +field shall take on one of the following values: +7An integer between 1 and 8, inclusive, indicating +an ID field of the corresponding length +7The value zero, which indicates a 6 octet ID field +length +7The value 255, whhich means a null ID field (i.e. +zero length) +All other values are illegal and shall not be used. +-PDU 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 the system ID of Intermediate system +(with zero Circuit ID) generating this Sequence Num +bers PDU. + +-VARIABLE LENGTH FIELDS fields of the form:11No. of OctetsLENGTHCODE +LENGTH +VALUE + +Any codes in a received PSNP that are not recognised +are ignored. +Currently defined codes are: +7LSP Entries this may appear multiple times. +The option fields, if they appear more than once, +shall appear sorted into ascending LSPID order. +xCODE 9 +xLENGTH total length of the value field. +xVALUE a list of LSP entries of the form:4No. of Octets2ID Length + +2242ID Length + 22LSP Sequence Number +Checksum +Remaining Lifetime +LSP ID +LSP Sequence Number +Checksum +Remaining Lifetime +LSP ID + +7Remaining Lifetime Remaining Life +time of LSP. +7LSP ID the system ID of the LSP to +which this entry refers. +7LSP Sequence Number Sequence +number of LSP. +7Checksum 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). +7Authentication Information information for +performing authentication of the originator of the +PDU. +xCODE 10. +xLENGTH variable from 1254 octets + +xVALUE 1VARIABLENo. of OctetsAuthentication Type + +Authentication Value + +7Authentication Type a one octet iden +tifier for the type of authentication to be +carried out. The following values are de +fined: +0 RESERVED +1 Cleartext Password +2254 RESERVED +255 Routeing Domain private +authentication method +7Authentication Value determined by +the value of the authentication type. If +Cleartext Password as defined in this Inter +national Standard is used, then the authenti +cation value is an octet string. + +9.13 Level 2 Partial Sequence Numbers +PDU +11No. of Octets1111112ID Length + 1VARIABLEIntradomain Routeing +Protocol Discriminator + +Length Indicator +Version/Protocol ID Extension +ID Length +PDU Type + +R +R +R +Version +ECO +User ECO +PDU Length +Source ID +VARIABLE LENGTH FIELDS + +-Intradomain Routeing Protocol Discriminator ar +chitectural constant +-Length Indicator Length of fixed header in octets +-Version/Protocol ID Extension 1 +-ID Length Length of the ID field of NSAP ad +dresses and NETs used in this routeing domain. This +field shall take on one of the following values: +7An integer between 1 and 8, inclusive, indicating +an ID field of the corresponding length +7The value zero, which indicates a 6 octet ID field +length +7The value 255, whhich means a null ID field (i.e. +zero length) +All other values are illegal and shall not be used. +-PDU 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 the system ID of Intermediate system +(with zero Circuit ID) generating this Sequence Num +bers PDU. + +-VARIABLE LENGTH FIELDS fields of the form:11No. of OctetsLENGTHCODE +LENGTH +VALUE + +Any codes in a received PSNP that are not recognised +are ignored. +Currently defined codes are: +7LSP Entries this may appear multiple times. +The option fields, if they appear more than once, +shall appear sorted into ascending LSPID order. +xCODE 9 +xLENGTH total length of the value field. +xVALUE a list of LSP entries of the form:4No. of Octets2ID Length + +2242ID Length + 22LSP Sequence Number +Checksum +Remaining Lifetime +LSP ID +LSP Sequence Number +Checksum +Remaining Lifetime +LSP ID + +7Remaining Lifetime Remaining Life +time of LSP. +7LSP ID the system ID of the LSP to +which this entry refers. +7LSP Sequence Number Sequence +number of LSP. +7Checksum 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). +7Authentication Information information for +performing authentication of the originator of the +PDU. +xCODE 10. +xLENGTH variable from 1254 octets + +xVALUE 1VARIABLENo. of OctetsAuthentication Type + +Authentication Value + +7Authentication Type a one octet iden +tifier for the type of authentication to be +carried out. The following values are de +fined: +0 RESERVED +1 Cleartext Password +2254 RESERVED +255 Routeing Domain private +authentication method +7Authentication Value determined by +the value of the authentication type. If +Cleartext Password as defined in this Inter +national Standard is used, then the authenti +cation value is an octet string. + +10 System Environment +10.1 Generating Jitter on Timers +When PDUs are transmitted as a result of timer expiration, +there is a danger that the timers of individual systems may +become synchronised. The result of this is that the traffic +distribution will contain peaks. Where there are a large +number of synchronised systems, this can cause overload +ing of both the transmission medium and the systems re +ceiving the PDUs. In order to prevent this from occurring, +all periodic timers, the expiration of which can cause the +transmission of PDUs, shall have jitter introduced as de +fined in the following algorithm. +CONSTANT +Jitter = 25; +(* The percentage jitter as defined in the architectural +constant Jitter *) +Resolution = 100; +(* The timer resolution in milliseconds *) + +PROCEDURE Random(max : Integer): Integer; + (* This procedure delivers a Uniformly distributed +random integer R such that 0 < R < max *) + +PROCEDURE +DefineJitteredTimer(baseTimeValueInSeconds: Integer; +expirationAction : Procedure); + +VAR +baseTimeValue, maximumTimeModifier, waitTime : +Integer; +nextexpiration : Time; + +BEGIN +baseTimeValue := baseTimeValueInSeconds * 1000 / +Resolution; +maximumTimeModifier := baseTimeValue * Jitter / +100; (* Compute maximum possible jitter *) +WHILE running DO +BEGIN +(* First compute next expiration time *) +randomTimeModifier := +Random(maximumTimeModifier); +waitTime := baseTimeValue - +randomTimeModifier; +nextexpiration := CurrentTime + waitTime; +(* Then perform expiration Action *) +expirationAction; +WaitUntil(nextexpiration); +END (* of Loop *) +END (* of DefineJitteredTimer *) +Thus the call DefineJitteredTimer(HelloTime, SendHel +loPDU); where HelloTime is 10 seconds, will cause the +action SendHelloPDU to be performed at random inter +vals of between 7.5 and 10 seconds. The essential point of +this algorithm is that the value of randomTimeModifier is +randomised within the inner loop. Note that the new expira +tion time is set immediately on expiration of the last inter +val, rather than when the expiration action has been com +pleted. + +The time resolution shall be less than or equal to 100 milli +seconds. It is recommended to be less than or equal to 10 +milliseconds. The time resolution is the maximum interval +that can elapse without there being any change in the value +of the timer. The periodic transmission period shall be ran +dom or pseudo-random in the specified range, with uniform +distribution across similar implementations. +10.2 Resolution of Timers +All timers specified in units of seconds shall have a resolu +tion of no less than 11 second. +All timers specified in units of milliseconds shall have a +resolution of no less than 110 milliseconds +10.3 Requirements on the Operation of +ISO 9542 +This International Standard places certain requirements on +the use of ISO 9542 by Intermediate systems which go be +yond those mandatory requirements stated in the +conformance clause of ISO 9542. These requirements are: +a)The IS shall operate the Configuration Information +functions on all types of subnetworks supported by the +IS. This includes the reception of ESH PDUs, and the +reception and transmission of ISH PDUs. +b)The IS shall enable the All Intermediate Systems +multi-destination subnetwork address. + + +11 System Management +11.1 General +The operation of the Intra-domain ISIS routeing functions +may be monitored and controlled using System Manage +ment. This clause is the management specification for ISO +10589 in the GDMO notation as defined in ISO 10165-4. +11.1.1 Naming Hierarchy +The containment hierarchy for ISO 10589 is illustrated be +low in figure +8NetworkVirtualAdjacencyAdjacencyDestinationSystemDestinationAreaCircuit +ReachableAddressEntityCLNS(ISO 10589 Package)(ISO 10589 +Package)ManualAdjacencyLevel 2 OnlyFigure 8 - Containment and Naming Hierarchy + +. +11.1.2 Resetting of Timers +Many of the attributes defined herein represent the values +of timers. They specify the interval between certain events +in the operation of the routeing state machines. If the value +of one of these characteristics is changed to a new value t +while the routeing state machine is in operation the imple +mentation shall take the necessary actions to ensure that for +any time interval which was in progress when the corre +sponding attribute was changed, the next expiration of that +interval takes place t seconds from the original start of that +interval, or immediately, whichever is the later. + +Where this action is necessary it is indicated in the applica +ble behaviour clause of the GDMO. See 11.2.16 +11.1.3 Resource Limiting Characteristics +Certain attributes place limits on some resource, such as +max + +imum + +SVC + +Adjacencies. In general, implementa +tions may allocate memory resources up to this limit when +the managed object is enabled and it may be impossible to +change the allocation without first disabling and re-enabling +the corresponding Network entity. Therefore this Interna +tional Standard only requires that system management shall +be able to change these attributes when the managed object +is disabled (i.e. in the state off). +However some implementations may be able to change the +allocation of resources without first disabling the Network +entity. In this case it is permitted to increase the value of +the characteristic at any time, but it shall not be decreased +below the currently used value of the resource. For exam +ple, maximumSVCAdjacencies shall not be decreased +below the current number of SVCs which have been cre +ated. +Characteristics of this type are indicated in the behaviour +clause of the GDMO. See 11.2.16. + +11.2 GDMO Definition +11.2.1 Name Bindings +iSO10589-NB NAME BINDING +SUBORDINATE OBJECT CLASS cLNS; +NAMED BY +SUPERIOR OBJECT CLASS +"ISO/IEC xxxxx":networkEntity; +WITH ATTRIBUTE +"ISO/IEC xxxxx":cLNS-MO-Name; +CREATE with-automatic-instance-naming +iSO10589-NB-p1; +DELETE only-if-no-contained-objects; +REGISTERED AS {ISO10589-ISIS.nboi iSO10589-NB +(1)}; + +level1ISO10589Circuit-NB NAME BINDING +SUBORDINATE OBJECT CLASS circuit; +NAMED BY +SUPERIOR OBJECT CLASS cLNS; +WITH ATTRIBUTE +"ISO/IEC xxxxx":circuit-MO-Name; +CREATE with-reference-object +iSO10589Circuit-MO-p1; +DELETE only-if-no-contained-objects; +REGISTERED AS {ISO10589-ISIS.nboi +level1ISO10589Circuit-NB (2)}; + +destinationSystem-NB NAME BINDING +SUBORDINATE OBJECT CLASS destinationSystem; +NAMED BY +SUPERIOR OBJECT CLASS cLNS; +WITH ATTRIBUTE networkEntityTitle; +REGISTERED AS {ISO10589-ISIS.nboi +destinationSystem-NB (3)}; + +destinationArea-NB NAME BINDING +SUBORDINATE OBJECT CLASS destinationArea; +NAMED BY +SUPERIOR OBJECT CLASS cLNS; +WITH ATTRIBUTE addressPrefix; +BEHAVIOUR destinationArea-NB-B BEHAVIOUR +DEFINED AS This name binding is only applicable +where the superior object has an iSType of Level2;; +REGISTERED AS {ISO10589-ISIS.nboi +destinationArea-NB (4)}; + +virtualAdjacency-NB NAME BINDING +SUBORDINATE OBJECT CLASS virtualAdjacency; +NAMED BY +SUPERIOR OBJECT CLASS cLNS; +WITH ATTRIBUTE networkEntityTitle; +BEHAVIOUR virtualAdjacency-NB-B BEHAVIOUR +DEFINED AS This name binding is only applicable +where the superior object has an iSType of Level2;; +REGISTERED AS {ISO10589-ISIS.nboi +virtualAdjacency-NB (5)}; + + +reachableAddress-NB NAME BINDING +SUBORDINATE OBJECT CLASS reachableAddress; +NAMED BY +SUPERIOR OBJECT CLASS circuit; +WITH ATTRIBUTE addressPrefix; +BEHAVIOUR reachableAddress-NB-B BEHAVIOUR +DEFINED AS This name binding is only applicable +where the superior object of the Circuit instance is +an object with iSType level2IS;; +CREATE with-reference-object reachableAddressP1 +reachableAddressP2; +DELETE only-if-no-contained-objects; +REGISTERED AS {ISO10589-ISIS.nboi +reachableAddress-NB (6)}; + +adjacency-NB NAME BINDING +SUBORDINATE OBJECT CLASS adjacency; +NAMED BY +SUPERIOR OBJECT CLASS circuit; +WITH ATTRIBUTE adjacencyName; +REGISTERED AS {ISO10589-ISIS.nboi adjacency-NB +(7)}; + +manualAdjacency-NB NAME BINDING +SUBORDINATE OBJECT CLASS manualAdjacency; +NAMED BY +SUPERIOR OBJECT CLASS circuit; +WITH ATTRIBUTE adjacencyName; +BEHAVIOUR manualAdjacency-NB-B BEHAVIOUR +DEFINED AS When an instance name is specified in +the CREATE operation, that value shall be used for +the adjacencyName, otherwise automatic instance +naming shall be used;; +CREATE with-reference-object, +with-automatic-instance-naming +manualAdjacencyP1 manualAdjacencyP2; +DELETE only-if-no-contained-objects; +REGISTERED AS {ISO10589-ISIS.nboi +manualAdjacency-NB (8)}; + + +11.2.2 The CLNS Managed Object for ISO +10589 +cLNS MANAGED OBJECT CLASS +DERIVED FROM "ISO/IEC xxxx":cLNS; +-- To be replaced by the number of the network layer +MO definitions when assigned. +CONDITIONAL PACKAGES +level1ISO10589Package +PRESENT IF The Intermediate System is a Level 1 +Intermediate System, +level2ISO10589Package +PRESENT IF The Intermediate System is a Level 2 +Intermediate System (i.e. the value of iSType is +Level2), +partitionRepairPackage +PRESENT IF The Intermediate System is a Level 2 +Intermediate System and the partition repair option +is implemented, +level1AuthenticationPackage +PRESENT IF The authentication procedures are im +plemented, +level2AuthenticationPackage +PRESENT IF The Intermediate System is a Level 2 +Intermediate System and the authentication proce +dures are implemented; +REGISTERED AS {ISO10589-ISIS.moi cLNS (1)}; + +level1ISO10589Package PACKAGE +ATTRIBUTES +version GET, +iSType GET, +maximumPathSplits +REPLACE-WITH-DEFAULT +DEFAULT VALUE +ISO10589-ISIS.maximumPathSplits-Default +PERMITTED VALUES +ISO10589-ISIS.MaximumPathSplits-Permitted +GET-REPLACE, +maximumBuffers +REPLACE-WITH-DEFAULT +DEFAULT VALUE +ISO10589-ISIS.maximumBuffers-Default +PERMITTED VALUES +ISO10589-ISIS.MaximumBuffers-Permitted +GET-REPLACE, +minimumLSPTransmissionInterval +REPLACE-WITH-DEFAULT +DEFAULT VALUE +ISO10589-ISIS.minimumLSPTransmissionInterval- +Default +PERMITTED VALUES +ISO10589-ISIS.MinimumLSPTransmissionInterval- +Permitted +GET-REPLACE, +maximumLSPGenerationInterval +REPLACE-WITH-DEFAULT +DEFAULT VALUE +ISO10589-ISIS.maximumLSPGenerationInterval-D +efault +PERMITTED VALUES +ISO10589-ISIS.MaximumLSPGenerationInterval-Pe +rmitted +GET-REPLACE, +minimumBroadcastLSPTransmissionInterval +REPLACE-WITH-DEFAULT + +DEFAULT VALUE +ISO10589-ISIS.minimumBroadcastLSPTransmissio +nInterval-Default +PERMITTED VALUES +ISO10589-ISIS.MinimumBroadcastLSPTransmissio +nInterval-Permitted +GET-REPLACE, +-- Note this is defined for all Circuits, but would only +be required if one of them were a broadcast Circuit +completeSNPInterval +REPLACE-WITH-DEFAULT +DEFAULT VALUE +ISO10589-ISIS.completeSNPInterval-Default +PERMITTED VALUES +ISO10589-ISIS.CompleteSNPInterval-Permitted +GET-REPLACE, +-- Ditto +originatingL1LSPBufferSize +REPLACE-WITH-DEFAULT +DEFAULT VALUE +ISO10589-ISIS.originatingL1LSPBufferSize-Defaul +t +PERMITTED VALUES +ISO10589-ISIS.OriginatingL1LSPBufferSize-Permit +ted +GET-REPLACE, +-- Note: redirectHoldingTime moved to +ISO9542ISPackage +manualAreaAddresses +REPLACE-WITH-DEFAULT +DEFAULT VALUE +ISO10589-ISIS.manualAreaAddresses-Default +PERMITTED VALUES +ISO10589-ISIS.ManualAreaAddresses-Permitted +GET ADD-REMOVE, +minimumLSPGenerationInterval +REPLACE-WITH-DEFAULT +DEFAULT VALUE +ISO10589-ISIS.minimumLSPGenerationInterval-De +fault +PERMITTED VALUES +ISO10589-ISIS.MinimumLSPGenerationInterval-Pe +rmitted +GET-REPLACE, +defaultESHelloTimer +REPLACE-WITH-DEFAULT +DEFAULT VALUE +ISO10589-ISIS.defaultESHelloTime-Default +PERMITTED VALUES +ISO10589-ISIS.DefaultESHelloTime-Permitted +GET-REPLACE, +pollESHelloRate +REPLACE-WITH-DEFAULT +DEFAULT VALUE +ISO10589-ISIS.pollESHelloRate-Default +PERMITTED VALUES +ISO10589-ISIS.PollESHelloRate-Permitted +GET-REPLACE, +partialSNPInterval +REPLACE-WITH-DEFAULT +DEFAULT VALUE +ISO10589-ISIS.partialSNPInterval-Default +PERMITTED VALUES +ISO10589-ISIS.PartialSNPInterval-Permitted +GET-REPLACE, +waitingTime +REPLACE-WITH-DEFAULT + +DEFAULT VALUE +ISO10589-ISIS.waitingTime-Default +PERMITTED VALUES +ISO10589-ISIS.WaitingTime-Permitted +GET-REPLACE, +dRISISHelloTimer +REPLACE-WITH-DEFAULT +DEFAULT VALUE +ISO10589-ISIS.dRISISHelloTimer-Default +PERMITTED VALUES +ISO10589-ISIS.DRISISHelloTimer-Permitted +GET-REPLACE, +l1State GET, +areaAddresses GET, +-- PDUFormatErrors now in network layer MO +corruptedLSPsDetected GET, +lSPL1DatabaseOverloads GET, +manualAddressesDroppedFromArea GET, +attemptsToExceedMaximumSequenceNumber GET, +sequenceNumberSkips GET, +ownLSPPurges GET, +iDFieldLengthMismatches GET; +ATTRIBUTE GROUPS +counters +-- PDUFormatErrors now in Network Layer MO +corruptedLSPsDetected +lSPL1DatabaseOverloads +manualAddressesDroppedFromArea +attemptsToExceedMaximumSequenceNumber +sequenceNumberSkips +ownLSPPurges +iDFieldLengthMismatches; +-- activate and deactivate actions now in Network Layer +MO +NOTIFICATIONS +"ISO/IEC xxxxx":pduFormatError +notificationReceivingAdjacency, +-- extra parameter for ISO 10589 +corruptedLSPDetected, +lSPL1DatabaseOverload, +manualAddressDroppedFromArea, +attemptToExceedMaximumSequenceNumber, +sequenceNumberSkip, +ownLSPPurge, +iDFieldLengthMismatch; +REGISTERED AS {ISO10589-ISIS.poi +level1ISO10589Package (1)}; + +level2ISO10589Package PACKAGE +ATTRIBUTES +originatingL2LSPBufferSize +REPLACE-WITH-DEFAULT +DEFAULT VALUE +ISO10589-ISIS.originatingL2LSPBufferSize-Defaul +t +PERMITTED VALUES +ISO10589-ISIS.OriginatingL2LSPBufferSize-Permit +ted +GET-REPLACE, +l2State GET, +lSPL2DatabaseOverloads GET; +ATTRIBUTE GROUPS +counters +lSPL2DatabaseOverloads; +NOTIFICATIONS +lSPL2DatabaseOverload; + +REGISTERED AS {ISO10589-ISIS.poi +level2ISO10589Package (2)}; + +partitionRepairPackage PACKAGE +BEHAVIOUR DEFINITIONS partitionRepairPackage-B +BEHAVIOUR +DEFINED AS Present when the partition repair option +is implemented;; +ATTRIBUTES +maximumVirtualAdjacencies +REPLACE-WITH-DEFAULT +DEFAULT VALUE +ISO10589-ISIS.maximumVirtualAdjacencies-Defau +lt +PERMITTED VALUES +ISO10589-ISIS.MaximumVirtualAdjacencies-Permi +tted +GET-REPLACE, +partitionAreaAddresses GET, +partitionDesignatedL2IntermediateSystem GET, +partitionVirtualLinkChanges GET; +ATTRIBUTE GROUPS +counters +partitionVirtualLinkChanges; +NOTIFICATIONS +partitionVirtualLinkChange; +REGISTERED AS {ISO10589-ISIS.poi +partitionRepairPackage (3)}; + +level1AuthenticationPackage PACKAGE +BEHAVIOUR DEFINITIONS +level1AuthenticationPackage-B BEHAVIOUR +DEFINED AS Present when the authentication proce +dures option is implemented;; +ATTRIBUTES +areaTransmitPassword +REPLACE-WITH-DEFAULT +DEFAULT VALUE +ISO10589-ISIS.password-Default +GET-REPLACE, +areaReceivePasswords +REPLACE-WITH-DEFAULT +DEFAULT VALUE +ISO10589-ISIS.passwords-Default +GET-REPLACE +ADD-REMOVE, +authenticationFailures +GET; +ATTRIBUTE GROUPS +counters +authenticationFailures; +NOTIFICATIONS +authenticationFailure; +REGISTERED AS {ISO10589-ISIS.poi +level1AuthenticationPackage (4)}; + +level2AuthenticationPackage PACKAGE +BEHAVIOUR DEFINITIONS +level2AuthenticationPackage-B BEHAVIOUR +DEFINED AS Present when the authentication proce +dures option is implemented and the value of the +iSType attribute is Level2;; +ATTRIBUTES +domainTransmitPassword +REPLACE-WITH-DEFAULT + +DEFAULT VALUE +ISO10589-ISIS.password-Default +GET-REPLACE, +domainReceivePasswords +REPLACE-WITH-DEFAULT +DEFAULT VALUE +ISO10589-ISIS.passwords-Default +GET-REPLACE +ADD-REMOVE; +REGISTERED AS {ISO10589-ISIS.poi +level2AuthenticationPackage (5)}; + +11.2.3 The Circuit Managed Object for ISO +10589 +circuit MANAGED OBJECT CLASS +DERIVED FROM "ISO/IEC xxxx":circuit; +-- xxxx to be replaced with the number of the network +layer managed object definitions when one is +assigned +CONDITIONAL PACKAGES +level1ISO10589CircuitPackage +PRESENT IF the Circuit is a level 1 ISO 10589 Cir +cuit, +level1ISO10589BroadcastCircuitPackage +PRESENT IF the Circuit is a level 1 ISO 10589 +broadcast Circuit, +level1ISO10589PtToPtCircuitPackage +PRESENT IF the Circuit is a level 1 ISO 10589 Point +to Point Circuit, +level2ISO10589DACircuitPackage +PRESENT IF the Circuit is a level 2 ISO 10589 X.25 +DA Circuit, +level1ISO10589StaticCircuitPackage +PRESENT IF the Circuit is a level 1 ISO10589 X.25 +STATIC Circuit (IN or OUT), +level1ISO10589StaticOutCircuitPackage +PRESENT IF the Circuit is a level1 ISO 10589 X.25 +STATIC OUT SNAP, +level2ISO10589CircuitPackage +PRESENT IF the IS is a Level2 ISO 10589 IS, +level2ISO10589BroadcastCircuitPackage +PRESENT IF the Circuit is a level 1 ISO 10589 +broadcast Circuit and the IS is a L2 IS, +dACircuitCallEstablishmentMetricIncrementPackage +PRESENT IF the Circuit is an X.25 DA circuit and +support is implemented for call establishement met +ric increment values greater than zero, +circuitAuthenticationPackage +PRESENT IF the authentication procedures are im +plemented on this IS; +REGISTERED AS {ISO10589-ISIS.moi circuit (2)}; + +level1ISO10589CircuitPackage PACKAGE +ATTRIBUTES +type GET, +helloTimer +REPLACE-WITH-DEFAULT +DEFAULT VALUE +ISO10589-ISIS.helloTimer-Default +PERMITTED VALUES +ISO10589-ISIS.HelloTimer-Permitted +GET-REPLACE, +l1DefaultMetric +REPLACE-WITH-DEFAULT + +DEFAULT VALUE +ISO10589-ISIS.defaultMetric-Default +PERMITTED VALUES +ISO10589-ISIS.DefaultMetric-Permitted +GET-REPLACE, +l1DelayMetric +REPLACE-WITH-DEFAULT +DEFAULT VALUE +ISO10589-ISIS.optionalMetric-Default +PERMITTED VALUES +ISO10589-ISIS.OptionalMetric-Permitted +GET-REPLACE, +l1ExpenseMetric +REPLACE-WITH-DEFAULT +DEFAULT VALUE +ISO10589-ISIS.optionalMetric-Default +PERMITTED VALUES +ISO10589-ISIS.OptionalMetric-Permitted +GET-REPLACE, +l1ErrorMetric +REPLACE-WITH-DEFAULT +DEFAULT VALUE +ISO10589-ISIS.optionalMetric-Default +PERMITTED VALUES +ISO10589-ISIS.OptionalMetric-Permitted +GET-REPLACE, +externalDomain +REPLACE-WITH-DEFAULT +DEFAULT VALUE +ISO10589-ISIS.externalDomain-Default +GET-REPLACE, +circuitChanges GET, +changesInAdjacencyState GET, +initializationFailures GET, +rejectedAdjacencies GET, +controlPDUsSent GET, +controlPDUsReceived GET, +iDFieldLengthMismatches GET; +ATTRIBUTE GROUPS +counters +circuitChanges +changesInAdjacencyState +initializationFailures +rejectedAdjacencies +controlPDUsSent +controlPDUsReceived +iDFieldLengthMismatches; +-- Note: activate and deactivate are now imported from +the network layer definition of circuit MO +NOTIFICATIONS +circuitChange, +adjacencyStateChange, +initializationFailure, +rejectedAdjacency, +iDFieldLengthMismatch; +REGISTERED AS {ISO10589-ISIS.poi +level1ISO10589CircuitPackage (6)}; + +level1ISO10589BroadcastCircuitPackage PACKAGE +BEHAVIOUR DEFINITIONS +level1BroadcastCircuitPackage-B BEHAVIOUR +DEFINED AS Present when the Circuit is of type +Broadcast;; +ATTRIBUTES +iSISHelloTimer +REPLACE-WITH-DEFAULT + +DEFAULT VALUE +ISO10589-ISIS.iSISHelloTimer-Default +PERMITTED VALUES +ISO10589-ISIS.ISISHelloTimer-Permitted +GET-REPLACE, +l1IntermediateSystemPriority +REPLACE-WITH-DEFAULT +DEFAULT VALUE +ISO10589-ISIS.l1IntermediateSystemPriority-Defau +lt +PERMITTED VALUES +ISO10589-ISIS.L1IntermediateSystemPriority-Perm +itted +GET-REPLACE, +l1CircuitID GET, +l1DesignatedIntermediateSystem GET, +lanL1DesignatedIntermediateSystemChanges GET; +ATTRIBUTE GROUPS +counters +lanL1DesignatedIntermediateSystemChanges; +NOTIFICATIONS +lanL1DesignatedIntermediateSystemChange; +REGISTERED AS {ISO10589-ISIS.poi +level1ISO10589BroadcastCircuitPackage (7)}; + +level1ISO10589PtToPtCircuitPackage PACKAGE +BEHAVIOUR DEFINITIONS +level1PtToPtCircuitPackage-B BEHAVIOUR +DEFINED AS Present when the Circuit is of type Pt +ToPt;; +ATTRIBUTES +ptPtCircuitID GET; +REGISTERED AS {ISO10589-ISIS.poi +level1ISO10589PtToPtCircuitPackage (8)}; + +dACircuitCallEstablishmentMetricIncrementPackage +PACKAGE +BEHAVIOUR DEFINITIONS +dACircuitCallEstablishmentMetricIncrementPackag +e-B BEHAVIOUR +DEFINED AS Present when values of call establish +ment metric increment greater than zero are sup +ported and the parent iS MO has iSType Level2;; +ATTRIBUTES +callEstablishmentDefaultMetricIncrement +REPLACE-WITH-DEFAULT +DEFAULT VALUE +ISO10589-ISIS.callEstablishmentMetricIncrement- +Default +PERMITTED VALUES +ISO10589-ISIS.CallEstablishmentMetricIncrement- +Permitted +GET-REPLACE, +callEstablishmentDelayMetricIncrement +REPLACE-WITH-DEFAULT +DEFAULT VALUE +ISO10589-ISIS.callEstablishmentMetricIncrement- +Default +PERMITTED VALUES +ISO10589-ISIS.CallEstablishmentMetricIncrement- +Permitted +GET-REPLACE, +callEstablishmentExpenseMetricIncrement +REPLACE-WITH-DEFAULT +DEFAULT VALUE +ISO10589-ISIS.callEstablishmentMetricIncrement- + +Default +PERMITTED VALUES +ISO10589-ISIS.CallEstablishmentMetricIncrement- +Permitted +GET-REPLACE, +callEstablishmentErrorMetricIncrement +REPLACE-WITH-DEFAULT +DEFAULT VALUE +ISO10589-ISIS.callEstablishmentMetricIncrement- +Default +PERMITTED VALUES +ISO10589-ISIS.CallEstablishmentMetricIncrement- +Permitted +GET-REPLACE; +REGISTERED AS {ISO10589-ISIS.poi +dACircuitCallEstablishmentMetricIncrementPackag +e (9)}; + +level2ISO10589DACircuitPackage PACKAGE +BEHAVIOUR DEFINITIONS +level2ISO10589DACircuitPackage-B +BEHAVIOUR +DEFINED AS Present when the Circuit is of type DA, +and the IS is operating as a L2 IS;; +-- Note: a DA Circuit is only permitted on an L2 IS +ATTRIBUTES +recallTimer +REPLACE-WITH-DEFAULT +DEFAULT VALUE +ISO10589-ISIS.recallTimer-Default +PERMITTED VALUES +ISO10589-ISIS.RecallTimer-Permitted +GET-REPLACE, +idleTimer +REPLACE-WITH-DEFAULT +DEFAULT VALUE +ISO10589-ISIS.idleTimer-Default +PERMITTED VALUES +ISO10589-ISIS.IdleTimer-Permitted +GET-REPLACE, +initialMinimumTimer +REPLACE-WITH-DEFAULT +DEFAULT VALUE +ISO10589-ISIS.initialMinimumTimer-Default +PERMITTED VALUES +ISO10589-ISIS.InitialMinimumTimer-Permitted +GET-REPLACE, +reserveTimer +REPLACE-WITH-DEFAULT +DEFAULT VALUE +ISO10589-ISIS.reserveTimer-Default +PERMITTED VALUES +ISO10589-ISIS.ReserveTimer-Permitted +GET-REPLACE, +maximumSVCAdjacencies +REPLACE-WITH-DEFAULT +DEFAULT VALUE +ISO10589-ISIS.maximumSVCAdjacencies-Default +PERMITTED VALUES +ISO10589-ISIS.MaximumSVCAdjacencies-Permitte +d +GET-REPLACE, +reservedAdjacency +REPLACE-WITH-DEFAULT +DEFAULT VALUE +ISO10589-ISIS.reservedAdjacency-Default + +GET-REPLACE, +-- Note: it is not clear that this attribute is required +callsPlaced GET, +callsFailed GET, +timesExceededMaximumSVCAdjacencies GET; +ATTRIBUTE GROUPS +counters +callsPlaced +callsFailed +timesExceededMaximumSVCAdjacencies; +NOTIFICATIONS +exceededMaximumSVCAdjacencies; +REGISTERED AS {ISO10589-ISIS.poi +level2ISO10589DACircuitPackage (10)}; + +level1ISO10589StaticCircuitPackage PACKAGE +BEHAVIOUR DEFINITIONS +level1StaticCircuitPackage-B BEHAVIOUR +DEFINED AS Present when the Circuit is of type +Static;; +ATTRIBUTES +neighbourSNPAAddress +REPLACE-WITH-DEFAULT +DEFAULT VALUE +ISO10589-ISIS.neighbourSNPAAddress-Default +GET-REPLACE, +-- Note: should this be handled by an X.25 IVMO? +ptPtCircuitID GET; +REGISTERED AS {ISO10589-ISIS.poi +level1ISO10589StaticCircuitPackage (11)}; + +level1ISO10589StaticOutCircuitPackage PACKAGE +BEHAVIOUR DEFINITIONS +level1StsticOutCircuitPackage-B BEHAVIOUR +DEFINED AS Present when the Circuit is of type Static +Out;; +ATTRIBUTES +recallTimer +REPLACE-WITH-DEFAULT +DEFAULT VALUE +ISO10589-ISIS.recallTimer-Default +PERMITTED VALUES +ISO10589-ISIS.RecallTimer-Permitted +GET-REPLACE, +maximumCallAttempts +REPLACE-WITH-DEFAULT +DEFAULT VALUE +ISO10589-ISIS.maximumCallAttempts-Default +PERMITTED VALUES +ISO10589-ISIS.MaximumCallAttempts-Permitted +GET-REPLACE, +callsPlaced GET, +callsFailed GET, +timesExceededMaximumCallAttempts GET; +ATTRIBUTE GROUPS +counters +callsPlaced +callsFailed +timesExceededMaximumCallAttempts; +NOTIFICATIONS +exceededMaximumCallAttempts ; +REGISTERED AS {ISO10589-ISIS.poi +level1ISO10589StaticOutCircuitPackage (12)}; + + +level2ISO10589CircuitPackage PACKAGE +BEHAVIOUR DEFINITIONS level2CircuitPackage-B +BEHAVIOUR +DEFINED AS Present when IS is an L2 IS;; +ATTRIBUTES +l2DefaultMetric +REPLACE-WITH-DEFAULT +DEFAULT VALUE +ISO10589-ISIS.defaultMetric-Default +PERMITTED VALUES +ISO10589-ISIS.DefaultMetric-Permitted +GET-REPLACE, +l2DelayMetric +REPLACE-WITH-DEFAULT +DEFAULT VALUE +ISO10589-ISIS.optionalMetric-Default +PERMITTED VALUES +ISO10589-ISIS.OptionalMetric-Permitted +GET-REPLACE, +l2ExpenseMetric +REPLACE-WITH-DEFAULT +DEFAULT VALUE +ISO10589-ISIS.optionalMetric-Default +PERMITTED VALUES +ISO10589-ISIS.OptionalMetric-Permitted +GET-REPLACE, +l2ErrorMetric +REPLACE-WITH-DEFAULT +DEFAULT VALUE +ISO10589-ISIS.optionalMetric-Default +PERMITTED VALUES +ISO10589-ISIS.OptionalMetric-Permitted +GET-REPLACE, +manualL2OnlyMode +REPLACE-WITH-DEFAULT +DEFAULT VALUE +ISO10589-ISIS.manualL2OnlyMode-Default +GET-REPLACE; +REGISTERED AS {ISO10589-ISIS.poi +level2ISO10589CircuitPackage (13)}; + +level2ISO10589BroadcastCircuitPackage PACKAGE +BEHAVIOUR DEFINITIONS +level2BroadcastCircuitPackage-B BEHAVIOUR +DEFINED AS Present when the Circuit is of type +Broadcast and the IS is an L2 IS;; +ATTRIBUTES +l2IntermediateSystemPriority +REPLACE-WITH-DEFAULT +DEFAULT VALUE +ISO10589-ISIS.l2IntermediateSystemPriority-Defau +lt +PERMITTED VALUES +ISO10589-ISIS.L2IntermediateSystemPriority-Perm +itted +GET-REPLACE, +l2CircuitID GET, +l2DesignatedIntermediateSystem GET, +lanL2DesignatedIntermediateSystemChanges GET; +ATTRIBUTE GROUPS +counters +lanL2DesignatedIntermediateSystemChanges; +NOTIFICATIONS +lanL2DesignatedIntermediateSystemChange; +REGISTERED AS {ISO10589-ISIS.poi +level2ISO10589BroadcastCircuitPackage (14)}; + + +circuitAuthenticationPackage PACKAGE +BEHAVIOUR DEFINITIONS +circuitAuthenticationPackage-B BEHAVIOUR +DEFINED AS Present when the authentication proce +dures option is implemented;; +ATTRIBUTES +circuitTransmitPassword +REPLACE-WITH-DEFAULT +DEFAULT VALUE +ISO10589-ISIS.password-Default +GET-REPLACE, +circuitReceivePasswords +REPLACE-WITH-DEFAULT +DEFAULT VALUE +ISO10589-ISIS.passwords-Default +GET-REPLACE +ADD-REMOVE, +authenticationFailures GET; +ATTRIBUTE GROUPS +counters +authenticationFailures; +NOTIFICATIONS +authenticationFailure; +REGISTERED AS {ISO10589-ISIS.poi +circuitAuthenticationPackage (15)}; + +11.2.4 The Adjacency managed Object +adjacency MANAGED OBJECT CLASS +DERIVED FROM "ISO/IEC 10165-2":top; +CHARACTERIZED BY adjacencyPackage PACKAGE +ATTRIBUTES +adjacencyName GET, +adjacencyState GET; +-- Note: this is NOT operational state +;; +CONDITIONAL PACKAGES +broadcastAdjacencyPackage +PRESENT IF the parent Circuit is of type broadcast, +dAAdjacencyPackage +PRESENT IF the parent Circuit is of type DA, +ptToPtAdjacencyPackage +PRESENT IF the parent Circuit is of type PtToPt or +STATIC, +iSAdjacencyPackage +PRESENT IF the adjacency is to an IS (i.e the +neighbourSystemType is Intermediate System L1 +Intermediate System or L2 Intermediate System), +broadcastISAdjacencyPackage +PRESENT IF the parent Circuit is of type broadcast +and is to an IS as above, +eSAdjacencyPackage +PRESENT IF the adjacency is to an ES (i.e. the +neighbourSystemType is EndSystem; +REGISTERED AS {ISO10589-ISIS.moi adjacency (3)}; + + +broadcastAdjacencyPackage PACKAGE +BEHAVIOUR DEFINITIONS +broadcastAdjacencyPackage-B BEHAVIOUR +DEFINED AS present if the parent Circuit is of type +broadcast;; +ATTRIBUTES +neighbourLANAddress GET, +neighbourSystemType GET; +REGISTERED AS {ISO10589-ISIS.poi +broadcastAdjacencyPackage (16)}; + +dAAdjacencyPackage PACKAGE +BEHAVIOUR DEFINITIONS dAAdjacencyPackage-B +BEHAVIOUR +DEFINED AS present if the parent Circuit is of type +DA;; +ATTRIBUTES +sNPAAddress GET; +REGISTERED AS {ISO10589-ISIS.poi +dAAdjacencyPackage (17)}; + +ptToPtAdjacencyPackage PACKAGE +BEHAVIOUR DEFINITIONS +ptToPtAdjacencyPackage-B BEHAVIOUR +DEFINED AS present if the parent Circuit is of type +PtToPt;; +ATTRIBUTES +neighbourSystemType GET; +REGISTERED AS {ISO10589-ISIS.poi +ptToPtAdjacencyPackage (18)}; + +iSAdjacencyPackage PACKAGE +BEHAVIOUR DEFINITIONS iSAdjacencyPackage-B +BEHAVIOUR +DEFINED AS present if the adjacency is to an IS;; +ATTRIBUTES +adjacencyUsageType GET, +neighbourSystemID GET, +neighbourAreas GET, +holdingTimer GET; +REGISTERED AS {ISO10589-ISIS.poi +iSAdjacencyPackage (19)}; + +broadcastISAdjacencyPackage PACKAGE +BEHAVIOUR DEFINITIONS +broadcastISAdjacencyPackage-B BEHAVIOUR +DEFINED AS present if the parent Circuit is of type +broadcast and the adjacency is to an IS;; +ATTRIBUTES +lANPriority GET; +REGISTERED AS {ISO10589-ISIS.poi +broadcastISAdjacencyPackage (20)}; + +eSAdjacencyPackage PACKAGE +BEHAVIOUR DEFINITIONS eSAdjacencyPackage-B +BEHAVIOUR +DEFINED AS present if the adjacency is to an ES;; +ATTRIBUTES +endSystemIDs GET; +REGISTERED AS {ISO10589-ISIS.poi +eSAdjacencyPackage (21)}; + + +11.2.5 The Manual Adjacency Managed +Object +manualAdjacency MANAGED OBJECT CLASS +DERIVED FROM "ISO/IEC 10165-2":top; +CHARACTERIZED BY manualAdjacencyPackage +PACKAGE +ATTRIBUTES +adjacencyName GET, +neighbourLANAddress GET, +endSystemIDs GET; +;; +REGISTERED AS {ISO10589-ISIS.moi +manualAdjacency (4)}; + +11.2.6 The Virtual Adjacency managed Object +virtualAdjacency MANAGED OBJECT CLASS +DERIVED FROM "ISO/IEC 10165-2":top; +CHARACTERIZED BY virtualAdjacencyPackage +PACKAGE +ATTRIBUTES +networkEntityTitle GET, +metric GET; +;; +REGISTERED AS {ISO10589-ISIS.moi virtualAdjacency +(5)}; + +11.2.7 The Destination Managed Object +-- The destination MO class is never instantiated. It exists +only to allow the destinationSystem and +destinationArea MO classes to be derived from it. +destination MANAGED OBJECT CLASS +DERIVED FROM "ISO/IEC 10165-2":top; +CHARACTERIZED BY destinationPackage +PACKAGE +ATTRIBUTES +defaultMetricPathCost GET, +defaultMetricOutputAdjacencies GET, +delayMetricPathCost GET, +delayMetricOutputAdjacencies GET, +expenseMetricPathCost GET, +expenseMetricOutputAdjacencies GET, +errorMetricPathCost GET, +errorMetricOutputAdjacencies GET; +;; -- no need for an object ID since it is never +instantiated, but GDMO needs one +REGISTERED AS {ISO10589-ISIS.moi destination (6)}; + +11.2.8 The Destination System Managed +Object +destinationSystem MANAGED OBJECT CLASS +DERIVED FROM destination; +CHARACTERIZED BY destinationSystemPackage +PACKAGE +ATTRIBUTES +networkEntityTitle GET; +;; +REGISTERED AS {ISO10589-ISIS.moi +destinationSystem (7)}; + + +11.2.9 The Destination Area Managed Object +destinationArea MANAGED OBJECT CLASS +DERIVED FROM destination; +CHARACTERIZED BY destinationAreaPackage +PACKAGE +ATTRIBUTES +addressPrefix GET; +;; +REGISTERED AS {ISO10589-ISIS.moi destinationArea +(8)}; + +11.2.10 The Reachable Address Managed +Object +reachableAddress MANAGED OBJECT CLASS +DERIVED FROM "ISO/IEC 10165-2":top; +CHARACTERIZED BY reachableAddressPackage +PACKAGE +ATTRIBUTES +addressPrefix GET, +defaultMetric +REPLACE-WITH-DEFAULT +DEFAULT VALUE +ISO10589-ISIS.defaultMetric-Default +PERMITTED VALUES +ISO10589-ISIS.DefaultMetric-Permitted +GET-REPLACE, +delayMetric +REPLACE-WITH-DEFAULT +DEFAULT VALUE +ISO10589-ISIS.optionalMetric-Default +PERMITTED VALUES +ISO10589-ISIS.OptionalMetric-Permitted +GET-REPLACE, +expenseMetric +REPLACE-WITH-DEFAULT +DEFAULT VALUE +ISO10589-ISIS.optionalMetric-Default +PERMITTED VALUES +ISO10589-ISIS.OptionalMetric-Permitted +GET-REPLACE, +errorMetric +REPLACE-WITH-DEFAULT +DEFAULT VALUE +ISO10589-ISIS.optionalMetric-Default +PERMITTED VALUES +ISO10589-ISIS.OptionalMetric-Permitted +GET-REPLACE, +defaultMetricType +REPLACE-WITH-DEFAULT +DEFAULT VALUE +ISO10589-ISIS.metricType-Default +GET-REPLACE, +delayMetricType +REPLACE-WITH-DEFAULT +DEFAULT VALUE +ISO10589-ISIS.metricType-Default +GET-REPLACE, +expenseMetricType +REPLACE-WITH-DEFAULT +DEFAULT VALUE +ISO10589-ISIS.metricType-Default +GET-REPLACE, +errorMetricType + +REPLACE-WITH-DEFAULT +DEFAULT VALUE +ISO10589-ISIS.metricType-Default +GET-REPLACE, +"ISO/IEC 10165-2":operationalState GET; +ACTIONS +activate, +deactivate; +;; +CONDITIONAL PACKAGES +mappingRAPackage +PRESENT IF the parent Circuit is of type broadcast +or DA, +broadcastRAPackage +PRESENT IF the parent Circuit is of type broadcast +and the value of mappingType is `manual', +dARAPackage +PRESENT IF the parent Circuit is of type DA and +the value of mappingType is `manual'; +REGISTERED AS {ISO10589-ISIS.moi +reachableAddress (9)}; + +mappingRAPackage PACKAGE +BEHAVIOUR DEFINITIONS mappingRAPackage-B +BEHAVIOUR +DEFINED AS When present, the NSAP to Circuit +mapping is controlled by the value of the map +pingType attribute;; +ATTRIBUTES +mappingType GET; +REGISTERED AS {ISO10589-ISIS.poi +mappingRAPackage (22)}; + +broadcastRAPackage PACKAGE +BEHAVIOUR DEFINITIONS broadcastRAPackage-B +BEHAVIOUR +DEFINED AS When present, the remote SNPA address +is determined by the value of the lANAddress attrib +ute;; +ATTRIBUTES +lANAddress +REPLACE-WITH-DEFAULT +DEFAULT VALUE +ISO10589-ISIS.lANAddress-Default +GET-REPLACE; +REGISTERED AS {ISO10589-ISIS.poi +broadcastRAPackage (23)}; + +dARAPackage PACKAGE +BEHAVIOUR DEFINITIONS dARAPackage-B +BEHAVIOUR +DEFINED AS When present, the remote SNPA address +is determined by the value of the sNPAAddresses at +tribute;; +ATTRIBUTES +sNPAAddresses +REPLACE-WITH-DEFAULT +DEFAULT VALUE +ISO10589-ISIS.sNPAAddresses-Default +GET-REPLACE; +REGISTERED AS {ISO10589-ISIS.poi dARAPackage +(24)}; + + +11.2.11 Attribute Definitions +version ATTRIBUTE +WITH ATTRIBUTE SYNTAX ISO10589-ISIS.Version; +MATCHES FOR Equality, Ordering; +BEHAVIOUR version-B BEHAVIOUR +DEFINED AS The version number of this International +Standard to which the implementation conforms;; +REGISTERED AS {ISO10589-ISIS.aoi version (1)}; + +iSType ATTRIBUTE +WITH ATTRIBUTE SYNTAX ISO10589-ISIS.ISType; +MATCHES FOR Equality; +BEHAVIOUR iSType-B BEHAVIOUR +DEFINED AS The type of this Intermediate System. +The value of this attribute is only settable via the +create parameter;; +REGISTERED AS {ISO10589-ISIS.aoi iSType (2)}; + +maximumPathSplits ATTRIBUTE +WITH ATTRIBUTE SYNTAX +ISO10589-ISIS.MaximumPathSplits; +MATCHES FOR Equality, Ordering; +BEHAVIOUR maximumPathSplits-B BEHAVIOUR +DEFINED AS Maximum number of paths with equal +routeing metric value which it is permitted to split +between;, +replaceOnlyWhileDisabled-B; +PARAMETERS constraintViolation; +REGISTERED AS {ISO10589-ISIS.aoi +maximumPathSplits (3)}; + +maximumBuffers ATTRIBUTE +WITH ATTRIBUTE SYNTAX +ISO10589-ISIS.MaximumBuffers; +MATCHES FOR Equality, Ordering; +BEHAVIOUR maximumBuffers-B BEHAVIOUR +DEFINED AS Maximum guaranteed number of buffers +for forwarding. This is the number of forwarding +buffers that is to be reserved, more may be used if +they are available. (See clause D.1.1);, +resourceLimiting-B; +PARAMETERS constraintViolation; +REGISTERED AS {ISO10589-ISIS.aoi maximumBuffers +(4)}; + +minimumLSPTransmissionInterval ATTRIBUTE +WITH ATTRIBUTE SYNTAX +ISO10589-ISIS.MinimumLSPTransmissionInterval; +MATCHES FOR Equality, Ordering; +BEHAVIOUR minimumLSPTransmissionInterval-B +BEHAVIOUR +DEFINED AS Minimum interval, in seconds, between +re- transmissions of an LSP;, +resettingTimer-B; +REGISTERED AS {ISO10589-ISIS.aoi +minimumLSPTransmissionInterval (5)}; + + +maximumLSPGenerationInterval ATTRIBUTE +WITH ATTRIBUTE SYNTAX +ISO10589-ISIS.MaximumLSPGenerationInterval; +MATCHES FOR Equality, Ordering; +BEHAVIOUR maximumLSPGenerationInterval-B +BEHAVIOUR +DEFINED AS Maximum interval, in seconds, between +generated LSPs by this system;, +resettingTimer-B; +REGISTERED AS {ISO10589-ISIS.aoi +maximumLSPGenerationInterval (6)}; + +minimumBroadcastLSPTransmissionInterval ATTRIBUTE +WITH ATTRIBUTE SYNTAX +ISO10589-ISIS.MinimumBroadcastLSPTransmissio +nInterval; +MATCHES FOR Equality, Ordering; +BEHAVIOUR +minimumBroadcastLSPTransmissionInterval-B +BEHAVIOUR +DEFINED AS Minimum interval, in milliseconds, be +tween transmission of LSPs on a broadcast circuit +(See clause 7.3.15.6);, +resettingTimer-B; +REGISTERED AS {ISO10589-ISIS.aoi +minimumBroadcastLSPTransmissionInterval (7)}; + +completeSNPInterval ATTRIBUTE +WITH ATTRIBUTE SYNTAX +ISO10589-ISIS.CompleteSNPInterval; +MATCHES FOR Equality, Ordering; +BEHAVIOUR completeSNPInterval-B BEHAVIOUR +DEFINED AS Interval, in seconds, between generation +of Complete Sequence Numbers PDUs by a Desig +nated Intermediate System on a broadcast circuit;, +resettingTimer-B; +REGISTERED AS {ISO10589-ISIS.aoi +completeSNPInterval (8)}; + +originatingL1LSPBufferSize ATTRIBUTE +WITH ATTRIBUTE SYNTAX +ISO10589-ISIS.OriginatingLSPBufferSize; +MATCHES FOR Equality, Ordering; +BEHAVIOUR originatingL1LSPBufferSize-B +BEHAVIOUR +DEFINED AS The maximum size of Level 1 LSPs and +SNPs originated by this system;, +replaceOnlyWhileDisabled-B; +PARAMETERS constraintViolation; +REGISTERED AS {ISO10589-ISIS.aoi +originatingL1LSPBufferSize (9)}; + +manualAreaAddresses ATTRIBUTE +WITH ATTRIBUTE SYNTAX +ISO10589-ISIS.AreaAddresses; +MATCHES FOR Equality, Set Comparison, Set +Intersection; +BEHAVIOUR manualAreaAddresses-B BEHAVIOUR +DEFINED AS Area Addresses to be used for this Inter +mediate System. At least one value must be sup +plied. The maximum number of Area Addresses +which may exist in the set is MaximumAreaAd +dresses;; +REGISTERED AS {ISO10589-ISIS.aoi +manualAreaAddresses (10)}; + + +minimumLSPGenerationInterval ATTRIBUTE +WITH ATTRIBUTE SYNTAX +ISO10589-ISIS.MinimumLSPGenerationInterval; +MATCHES FOR Equality, Ordering; +BEHAVIOUR minimumLSPGenerationInterval-B +BEHAVIOUR +DEFINED AS Maximum interval in seconds between +successive generation of LSPs with the same LSPID +by this IS;, +resettingTimer-B; +REGISTERED AS {ISO10589-ISIS.aoi +minimumLSPGenerationInterval (11)}; + +defaultESHelloTimer ATTRIBUTE +WITH ATTRIBUTE SYNTAX +ISO10589-ISIS.DefaultESHelloTimer; +MATCHES FOR Equality, Ordering; +BEHAVIOUR defaultESHelloTimer-B BEHAVIOUR +DEFINED AS The value to be used for the suggested +ES configuration timer in ISH PDUs when not solic +iting the ES configuration;; +REGISTERED AS {ISO10589-ISIS.aoi +defaultESHelloTimer (12)}; + +pollESHelloRate ATTRIBUTE +WITH ATTRIBUTE SYNTAX +ISO10589-ISIS.PollESHelloRate; +MATCHES FOR Equality, Ordering; +BEHAVIOUR pollESHelloRate-B BEHAVIOUR +DEFINED AS The value to be used for the suggested +ES configuration timer in ISH PDUs when soliciting +the ES configuration;; +REGISTERED AS {ISO10589-ISIS.aoi pollESHelloRate +(13)}; + +partialSNPInterval ATTRIBUTE +WITH ATTRIBUTE SYNTAX +ISO10589-ISIS.PartialSNPInterval; +MATCHES FOR Equality, Ordering; +BEHAVIOUR partialSNPInterval-B BEHAVIOUR +DEFINED AS Minimum interval between sending Par +tial Sequence Number PDUs;, +resettingTimer-B; +REGISTERED AS {ISO10589-ISIS.aoi +partialSNPInterval (14)}; + +waitingTime ATTRIBUTE +WITH ATTRIBUTE SYNTAX +ISO10589-ISIS.WaitingTime; +MATCHES FOR Equality, Ordering; +BEHAVIOUR waitingTime-B BEHAVIOUR +DEFINED AS Number of seconds to delay in waiting +state before entering On state;, +resettingTimer-B; +REGISTERED AS {ISO10589-ISIS.aoi waitingTime +(15)}; + + +dRISISHelloTimer ATTRIBUTE +WITH ATTRIBUTE SYNTAX +ISO10589-ISIS.DRISISHelloTimer; +MATCHES FOR Equality, Ordering; +BEHAVIOUR dRISISHelloTimer-B BEHAVIOUR +DEFINED AS The interval in seconds between the +generation of IIH PDUs by the designated IS on a +LAN;, +resettingTimer-B; +REGISTERED AS {ISO10589-ISIS.aoi +dRISISHelloTimer (16)}; + +l1State ATTRIBUTE +WITH ATTRIBUTE SYNTAX +ISO10589-ISIS.DatabaseState; +MATCHES FOR Equality; +BEHAVIOUR l1State-B BEHAVIOUR +DEFINED AS The state of the Level 1 database;; +REGISTERED AS {ISO10589-ISIS.aoi l1State (17)}; + +areaAddresses ATTRIBUTE +WITH ATTRIBUTE SYNTAX +ISO10589-ISIS.AreaAddresses; +MATCHES FOR Equality, Set Comparison, Set +Intersection; +BEHAVIOUR areaAddresses-B BEHAVIOUR +DEFINED AS The union of the sets of manualAreaAd +dresses reported in all Level 1 Link State PDUs re +ceived by this Intermediate System;; +REGISTERED AS {ISO10589-ISIS.aoi areaAddresses +(18)}; + +corruptedLSPsDetected ATTRIBUTE +DERIVED FROM nonWrappingCounter; +BEHAVIOUR corruptedLSPsDetected-B BEHAVIOUR +DEFINED AS Number of Corrupted LSP Detected +events generated;; +REGISTERED AS {ISO10589-ISIS.aoi +corruptedLSPsDetected (19)}; + +lSPL1DatabaseOverloads ATTRIBUTE +DERIVED FROM nonWrappingCounter; +BEHAVIOUR lSPL1DatabaseOverloads-B +BEHAVIOUR +DEFINED AS Number of times the LSP L1 Database +Overload event has been generated;; +REGISTERED AS {ISO10589-ISIS.aoi +lSPL1DatabaseOverloads (20)}; + +manualAddressesDroppedFromArea ATTRIBUTE +DERIVED FROM nonWrappingCounter; +BEHAVIOUR manualAddressesDroppedFromArea-B +BEHAVIOUR +DEFINED AS Number of times the Manual Addresses +Dropped From Area event has been generated;; +REGISTERED AS {ISO10589-ISIS.aoi +manualAddressesDroppedFromArea (21)}; + + +attemptsToExceedMaximumSequenceNumber +ATTRIBUTE +DERIVED FROM nonWrappingCounter; +BEHAVIOUR +attemptsToExceedMaximumSequenceNumber-B +BEHAVIOUR +DEFINED AS Number of times the Attempt To Exceed +Maximum Sequence Number event has been +generated;; +REGISTERED AS {ISO10589-ISIS.aoi +attemptsToExceedMaximumSequenceNumber +(22)}; + +sequenceNumberSkips ATTRIBUTE +DERIVED FROM nonWrappingCounter; +BEHAVIOUR sequenceNumberSkips-B BEHAVIOUR +DEFINED AS Number of times the Sequence Number +Skipped event has been generated;; +REGISTERED AS {ISO10589-ISIS.aoi +sequenceNumberSkips (23)}; + +ownLSPPurges ATTRIBUTE +DERIVED FROM nonWrappingCounter; +BEHAVIOUR ownLSPPurges-B BEHAVIOUR +DEFINED AS Number of times the Own LSP Purged +event has been generated;; +REGISTERED AS {ISO10589-ISIS.aoi ownLSPPurges +(24)}; + +iDFieldLengthMismatches ATTRIBUTE +DERIVED FROM nonWrappingCounter; +BEHAVIOUR iDFieldLengthMismatches-B +BEHAVIOUR +DEFINED AS Number of times the iDFieldLengthMis +match event has been generated;; +REGISTERED AS {ISO10589-ISIS.aoi +iDFieldLengthMismatches (25)}; + +originatingL2LSPBufferSize ATTRIBUTE +WITH ATTRIBUTE SYNTAX +ISO10589-ISIS.OriginatingLSPBufferSize; +MATCHES FOR Equality, Ordering; +BEHAVIOUR originatingL2LSPBufferSize-B +BEHAVIOUR +DEFINED AS The maximum size of Level 2 LSPs and +SNPs originated by this system;, +replaceOnlyWhileDisabled-B; +PARAMETERS constraintViolation; +REGISTERED AS {ISO10589-ISIS.aoi +originatingL2LSPBufferSize (26)}; + +maximumVirtualAdjacencies ATTRIBUTE +WITH ATTRIBUTE SYNTAX +ISO10589-ISIS.MaximumVirtualAdjacencies; +MATCHES FOR Equality, Ordering; +BEHAVIOUR maximumVirtualAdjacencies-B +BEHAVIOUR +DEFINED AS Maximum number of Virtual Adjacen +cies which may be created to repair partitioned +Level 1 domains;; +REGISTERED AS {ISO10589-ISIS.aoi +maximumVirtualAdjacencies (27)}; + + +l2State ATTRIBUTE +WITH ATTRIBUTE SYNTAX +ISO10589-ISIS.DatabaseState; +MATCHES FOR Equality, Ordering; +BEHAVIOUR l2State-B BEHAVIOUR +DEFINED AS The state of the Level 2 database;; +REGISTERED AS {ISO10589-ISIS.aoi l2State (28)}; + +partitionAreaAddresses ATTRIBUTE +WITH ATTRIBUTE SYNTAX +ISO10589-ISIS.AreaAddresses; +MATCHES FOR Equality, Set Comparison, Set +Intersection; +BEHAVIOUR partitionAreaAddresses-B BEHAVIOUR +DEFINED AS The set union of all manualAreaAd +dresses of all Intermediate systems in the partition +reachable by non-virtual links (calculated from their +Level 1 LSPs);; +REGISTERED AS {ISO10589-ISIS.aoi +partitionAreaAddresses (29)}; + +partitionDesignatedL2IntermediateSystem ATTRIBUTE +WITH ATTRIBUTE SYNTAX +ISO10589-ISIS.SystemID; +MATCHES FOR Equality; +BEHAVIOUR +partitionDesignatedL2IntermediateSystem-B +BEHAVIOUR +DEFINED AS The ID of the Partition Designated +Level 2 Intermediate System for this system;; +REGISTERED AS {ISO10589-ISIS.aoi +partitionDesignatedL2IntermediateSystem (30)}; + +partitionVirtualLinkChanges ATTRIBUTE +DERIVED FROM nonWrappingCounter; +BEHAVIOUR partitionVirtualLinkChanges-B +BEHAVIOUR +DEFINED AS Number of times the Partition Virtual +Link Change Notification has been generated;; +REGISTERED AS {ISO10589-ISIS.aoi +partitionVirtualLinkChanges (31)}; + +lSPL2DatabaseOverloads ATTRIBUTE +DERIVED FROM nonWrappingCounter; +BEHAVIOUR lSPL2DatabaseOverloads-B +BEHAVIOUR +DEFINED AS Number of times the LSP L2 Database +Overload event has been generated;; +REGISTERED AS {ISO10589-ISIS.aoi +lSPL2DatabaseOverloads (32)}; + +type ATTRIBUTE +WITH ATTRIBUTE SYNTAX +ISO10589-ISIS.CircuitType; +MATCHES FOR Equality; +BEHAVIOUR type-B BEHAVIOUR +DEFINED AS The type of the circuit. This attribute +may only be set when the Circuit is created. Subse +quently it is read-only;; +REGISTERED AS {ISO10589-ISIS.aoi type (33)}; + + +helloTimer ATTRIBUTE +WITH ATTRIBUTE SYNTAX +ISO10589-ISIS.HelloTimer; +MATCHES FOR Equality, Ordering; +BEHAVIOUR helloTimer-B BEHAVIOUR +DEFINED AS The period, in seconds, between ISH +PDUs;, +resettingTimer-B; +REGISTERED AS {ISO10589-ISIS.aoi helloTimer (34)}; + +l1DefaultMetric ATTRIBUTE +WITH ATTRIBUTE SYNTAX +ISO10589-ISIS.HopMetric; +MATCHES FOR Equality, Ordering; +BEHAVIOUR l1defaultMetric-B BEHAVIOUR +DEFINED AS The default metric value of this circuit +for Level 1 traffic. The value of zero is reserved to +indicate that this metric is not supported;; +REGISTERED AS {ISO10589-ISIS.aoi l1DefaultMetric +(35)}; + +l1DelayMetric ATTRIBUTE +WITH ATTRIBUTE SYNTAX +ISO10589-ISIS.HopMetric; +MATCHES FOR Equality, Ordering; +BEHAVIOUR l1DelayMetric-B BEHAVIOUR +DEFINED AS The delay metric value of this circuit for +Level 1 traffic. The value of zero is reserved to indi +cate that this metric is not supported;; +REGISTERED AS {ISO10589-ISIS.aoi l1DelayMetric +(36)}; + +l1ExpenseMetric ATTRIBUTE +WITH ATTRIBUTE SYNTAX +ISO10589-ISIS.HopMetric; +MATCHES FOR Equality, Ordering; +BEHAVIOUR l1ExpenseMetric-B BEHAVIOUR +DEFINED AS The expense metric value of this circuit +for Level 1 traffic. The value of zero is reserved to +indicate that this metric is not supported;; +REGISTERED AS {ISO10589-ISIS.aoi l1ExpenseMetric +(37)}; + +l1ErrorMetric ATTRIBUTE +WITH ATTRIBUTE SYNTAX +ISO10589-ISIS.HopMetric; +MATCHES FOR Equality, Ordering; +BEHAVIOUR l1ErrorMetric-B BEHAVIOUR +DEFINED AS The error metric value of this circuit for +Level 1 traffic. The value of zero is reserved to indi +cate that this metric is not supported;; +REGISTERED AS {ISO10589-ISIS.aoi l1ErrorMetric +(38)}; + +circuitChanges ATTRIBUTE +DERIVED FROM nonWrappingCounter; +BEHAVIOUR circuitChanges-B BEHAVIOUR +DEFINED AS Number of times this Circuit state +changed between On and Off and vice versa;; +REGISTERED AS {ISO10589-ISIS.aoi circuitChanges +(39)}; + + +changesInAdjacencyState ATTRIBUTE +DERIVED FROM nonWrappingCounter; +BEHAVIOUR changesInAdjacencyState-B +BEHAVIOUR +DEFINED AS Number of Adjacency State Change +events generated;; +REGISTERED AS {ISO10589-ISIS.aoi +changesInAdjacencyState (40)}; + +initializationFailures ATTRIBUTE +DERIVED FROM nonWrappingCounter; +BEHAVIOUR initializationFailures-B BEHAVIOUR +DEFINED AS Number of Initialization Failure events +generated;; +REGISTERED AS {ISO10589-ISIS.aoi +initializationFailures (41)}; + +rejectedAdjacencies ATTRIBUTE +DERIVED FROM nonWrappingCounter; +BEHAVIOUR rejectedAdjacencies-B BEHAVIOUR +DEFINED AS Number of Rejected Adjacency events +generated;; +REGISTERED AS {ISO10589-ISIS.aoi +rejectedAdjacencies (42)}; + +controlPDUsSent ATTRIBUTE +DERIVED FROM nonWrappingCounter; +BEHAVIOUR controlPDUsSent-B BEHAVIOUR +DEFINED AS Number of control PDUs sent on this +circuit;; +REGISTERED AS {ISO10589-ISIS.aoi controlPDUsSent +(43)}; + +controlPDUsReceived ATTRIBUTE +DERIVED FROM nonWrappingCounter; +BEHAVIOUR controlPDUsReceived-B BEHAVIOUR +DEFINED AS Number of control PDUs received on +this circuit;; +REGISTERED AS {ISO10589-ISIS.aoi +controlPDUsReceived (44)}; + +iSISHelloTimer ATTRIBUTE +WITH ATTRIBUTE SYNTAX +ISO10589-ISIS.ISISHelloTimer; +MATCHES FOR Equality, Ordering; +BEHAVIOUR iSISHelloTimer-B BEHAVIOUR +DEFINED AS The period, in seconds, between LAN +Level 1 and Level 2 IIH PDUs. It is also used as the +period between ISH PDUs when polling the ES con +figuration;, +resettingTimer-B; +REGISTERED AS {ISO10589-ISIS.aoi iSISHelloTimer +(45)}; + +externalDomain ATTRIBUTE +WITH ATTRIBUTE SYNTAX ISO10589-ISIS.Boolean; +MATCHES FOR Equality; +BEHAVIOUR externalDomain-B BEHAVIOUR +DEFINED AS If TRUE, suppress notmal transmission +of and interpretation of Intra-domain ISIS PDUs on +this circuit.;; +REGISTERED AS {ISO10589-ISIS.aoi externalDomain +(46)}; + + +l1IntermediateSystemPriority ATTRIBUTE +WITH ATTRIBUTE SYNTAX +ISO10589-ISIS.IntermediateSystemPriority; +MATCHES FOR Equality, Ordering; +BEHAVIOUR l1IntermediateSystemPriority-B +BEHAVIOUR +DEFINED AS Priority for becoming LAN Level 1 +Designated Intermediate System;; +REGISTERED AS {ISO10589-ISIS.aoi +l1IntermediateSystemPriority (47)}; + +l1CircuitID ATTRIBUTE +WITH ATTRIBUTE SYNTAX +ISO10589-ISIS.CircuitID; +MATCHES FOR Equality; +BEHAVIOUR l1CircuitID-B BEHAVIOUR +DEFINED AS The LAN ID allocated by the LAN +Level 1 Designated Intermediate System. Where this +system is not aware of the value (because it is not +participating in the Level 1 Designated Intermediate +System election), this attribute has the value which +would be proposed for this circuit. (i.e. the concate +nation of the local system ID and the one octet local +Circuit ID for this circuit.;; +REGISTERED AS {ISO10589-ISIS.aoi l1CircuitID +(48)}; + +l1DesignatedIntermediateSystem ATTRIBUTE +WITH ATTRIBUTE SYNTAX +ISO10589-ISIS.SystemID; +MATCHES FOR Equality; +BEHAVIOUR l1DesignatedIntermediateSystem-B +BEHAVIOUR +DEFINED AS The ID of the LAN Level 1 Designated +Intermediate System on this circuit. If, for any rea +son this system is not partaking in the relevant Des +ignated Intermediate System election process, then +the value returned is zero;; +REGISTERED AS {ISO10589-ISIS.aoi +l1DesignatedIntermediateSystem (49)}; + +lanL1DesignatedIntermediateSystemChanges +ATTRIBUTE +DERIVED FROM nonWrappingCounter; +BEHAVIOUR +lanL1DesignatedIntermediateSystemChanges-B +BEHAVIOUR +DEFINED AS Number of LAN L1 Designated Inter +mediate System Change events generated;; +REGISTERED AS {ISO10589-ISIS.aoi +lanL1DesignatedIntermediateSystemChanges (50)}; + + +ptPtCircuitID ATTRIBUTE +WITH ATTRIBUTE SYNTAX +ISO10589-ISIS.CircuitID; +MATCHES FOR Equality; +BEHAVIOUR ptPtCircuitID-B BEHAVIOUR +DEFINED AS The ID of the circuit allocated during +initialization. If no value has been negotiated (either +because the adjacency is to an End system, or +because initialization has not yet successfully +completed), this attribute has the value which would +be proposed for this circuit. (i.e. the concatenation of +the local system ID and the one octet local Circuit +ID for this circuit.;; +REGISTERED AS {ISO10589-ISIS.aoi ptPtCircuitID +(51)}; + +callEstablishmentDefaultMetricIncrement ATTRIBUTE +WITH ATTRIBUTE SYNTAX +ISO10589-ISIS.MetricIncrement; +MATCHES FOR Equality, Ordering; +BEHAVIOUR +callEstablishmentDefaultMetricIncrement-B +BEHAVIOUR +DEFINED AS Additional value to be reported for the +default metric value of unestablished DA adjacen +cies;; +REGISTERED AS {ISO10589-ISIS.aoi +callEstablishmentDefaultMetricIncrement (52)}; + +callEstablishmentDelayMetricIncrement ATTRIBUTE +WITH ATTRIBUTE SYNTAX +ISO10589-ISIS.MetricIncrement; +MATCHES FOR Equality, Ordering; +BEHAVIOUR +callEstablishmentDelayMetricIncrement-B +BEHAVIOUR +DEFINED AS Additional value to be reported for the +delay metric value of unestablished DA adjacen +cies;; +REGISTERED AS {ISO10589-ISIS.aoi +callEstablishmentDelayMetricIncrement (53)}; + +callEstablishmentExpenseMetricIncrement ATTRIBUTE +WITH ATTRIBUTE SYNTAX +ISO10589-ISIS.MetricIncrement; +MATCHES FOR Equality, Ordering; +BEHAVIOUR +callEstablishmentExpenseMetricIncrement-B +BEHAVIOUR +DEFINED AS Additional value to be reported for the +Expense metric value of unestablished DA adjacen +cies;; +REGISTERED AS {ISO10589-ISIS.aoi +callEstablishmentExpenseMetricIncrement (54)}; + +callEstablishmentErrorMetricIncrement ATTRIBUTE +WITH ATTRIBUTE SYNTAX +ISO10589-ISIS.MetricIncrement; +MATCHES FOR Equality, Ordering; +BEHAVIOUR callEstablishmentErrorMetricIncrement-B +BEHAVIOUR +DEFINED AS Additional value to be reported for the +Error metric value of unestablished DA adjacencies;; +REGISTERED AS {ISO10589-ISIS.aoi +callEstablishmentErrorMetricIncrement (55)}; + + +recallTimer ATTRIBUTE +WITH ATTRIBUTE SYNTAX +ISO10589-ISIS.RecallTimer; +MATCHES FOR Equality, Ordering; +BEHAVIOUR recallTimer-B BEHAVIOUR +DEFINED AS Number of seconds that must elapse be +tween a call failure on a DED circuit and a recall;, +resettingTimer-B; +REGISTERED AS {ISO10589-ISIS.aoi recallTimer +(56)}; + +idleTimer ATTRIBUTE +WITH ATTRIBUTE SYNTAX +ISO10589-ISIS.IdleTimer; +MATCHES FOR Equality, Ordering; +BEHAVIOUR idleTimer-B BEHAVIOUR +DEFINED AS Number of seconds of idle time before +call is cleared;, +resettingTimer-B; +REGISTERED AS {ISO10589-ISIS.aoi idleTimer (57)}; + +initialMinimumTimer ATTRIBUTE +WITH ATTRIBUTE SYNTAX +ISO10589-ISIS.InitialMinimumTimer; +MATCHES FOR Equality, Ordering; +BEHAVIOUR initialMinimumTimer-B BEHAVIOUR +DEFINED AS Number of seconds that a call remains +connected after being established, irrespective of +traffic. (Note. This should be set small enough so +that the call is cleared before the start of the next +charging interval.);, +resettingTimer-B; +REGISTERED AS {ISO10589-ISIS.aoi +initialMinimumTimer (58)}; + +reserveTimer ATTRIBUTE +WITH ATTRIBUTE SYNTAX +ISO10589-ISIS.ReserveTimer; +MATCHES FOR Equality, Ordering; +BEHAVIOUR reserveTimer-B BEHAVIOUR +DEFINED AS Number of seconds, after call is cleared +due to lack of traffic, during which the SVC remains +reserved for the previous SNPA address;, +resettingTimer-B; +REGISTERED AS {ISO10589-ISIS.aoi reserveTimer +(59)}; + +maximumSVCAdjacencies ATTRIBUTE +WITH ATTRIBUTE SYNTAX +ISO10589-ISIS.MaximumSVCAdjacencies; +MATCHES FOR Equality, Ordering; +BEHAVIOUR maximumSVCAdjacencies-B +BEHAVIOUR +DEFINED AS Number of Adjacencies to reserve for +SVCs for this circuit. This is the maximum number +of simultaneous calls which are possible on this cir +cuit;, +resourceLimiting-B; +PARAMETERS constraintViolation; +REGISTERED AS {ISO10589-ISIS.aoi +maximumSVCAdjacencies (60)}; + + +reservedAdjacency ATTRIBUTE +WITH ATTRIBUTE SYNTAX ISO10589-ISIS.Boolean; +MATCHES FOR Equality; +BEHAVIOUR reservedAdjacency-B BEHAVIOUR +DEFINED AS When True, indicates that one SVC +must be reserved for a connection to an Intermediate +System;, +replaceOnlyWhileDisabled-B; +PARAMETERS constraintViolation; +REGISTERED AS {ISO10589-ISIS.aoi +reservedAdjacency (61)}; + +callsPlaced ATTRIBUTE +DERIVED FROM nonWrappingCounter; +BEHAVIOUR callsPlaced-B BEHAVIOUR +DEFINED AS Number of Call attempts (successful or +unsuccessful);; +REGISTERED AS {ISO10589-ISIS.aoi callsPlaced (62)}; + +callsFailed ATTRIBUTE +DERIVED FROM nonWrappingCounter; +BEHAVIOUR callsFailed-B BEHAVIOUR +DEFINED AS Number of Unsuccessful Call attempts;; +REGISTERED AS {ISO10589-ISIS.aoi callsFailed (63)}; + +timesExceededMaximumSVCAdjacencies ATTRIBUTE +DERIVED FROM nonWrappingCounter; +BEHAVIOUR +timesExceededMaximumSVCAdjacencies-B +BEHAVIOUR +DEFINED AS Number of Exceeded Maximum SVC +Adjacencies events generated;; +REGISTERED AS {ISO10589-ISIS.aoi +timesExceededMaximumSVCAdjacencies (64)}; + +neighbourSNPAAddress ATTRIBUTE +WITH ATTRIBUTE SYNTAX +ISO10589-ISIS.SNPAAddress; +MATCHES FOR Equality; +BEHAVIOUR neighbourSNPAAddress-B +BEHAVIOUR +DEFINED AS SNPA Address to call, or SNPA Ad +dress from which to accept call;; +REGISTERED AS {ISO10589-ISIS.aoi +neighbourSNPAAddress (65)}; + +maximumCallAttempts ATTRIBUTE +WITH ATTRIBUTE SYNTAX +ISO10589-ISIS.MaximumCallAttempts; +MATCHES FOR Equality, Ordering; +BEHAVIOUR maximumCallAttempts-B BEHAVIOUR +DEFINED AS Maximum number of successive call +failures before halting. (A value of zero means infi +nite retries.;; +REGISTERED AS {ISO10589-ISIS.aoi +maximumCallAttempts (66)}; + +timesExceededMaximumCallAttempts ATTRIBUTE +DERIVED FROM nonWrappingCounter; +BEHAVIOUR timesExceededMaximumCallAttempts-B + +BEHAVIOUR +DEFINED AS Number of Exceeded Maximum Call +Attempts events generated;; +REGISTERED AS {ISO10589-ISIS.aoi +timesExceededMaximumCallAttempts (67)}; + +l2DefaultMetric ATTRIBUTE +WITH ATTRIBUTE SYNTAX +ISO10589-ISIS.HopMetric; +MATCHES FOR Equality, Ordering; +BEHAVIOUR l2defaultMetric-B BEHAVIOUR +DEFINED AS The default metric value of this circuit +for Level 2 traffic. The value of zero is reserved to +indicate that this metric is not supported;; +REGISTERED AS {ISO10589-ISIS.aoi l2DefaultMetric +(68)}; + +l2DelayMetric ATTRIBUTE +WITH ATTRIBUTE SYNTAX +ISO10589-ISIS.HopMetric; +MATCHES FOR Equality, Ordering; +BEHAVIOUR l2DelayMetric-B BEHAVIOUR +DEFINED AS The delay metric value of this circuit for +Level 2 traffic. The value of zero is reserved to indi +cate that this metric is not supported;; +REGISTERED AS {ISO10589-ISIS.aoi l2DelayMetric +(69)}; + +l2ExpenseMetric ATTRIBUTE +WITH ATTRIBUTE SYNTAX +ISO10589-ISIS.HopMetric; +MATCHES FOR Equality, Ordering; +BEHAVIOUR l2ExpenseMetric-B BEHAVIOUR +DEFINED AS The expense metric value of this circuit +for Level 2 traffic. The value of zero is reserved to +indicate that this metric is not supported;; +REGISTERED AS {ISO10589-ISIS.aoi l2ExpenseMetric +(70)}; + +l2ErrorMetric ATTRIBUTE +WITH ATTRIBUTE SYNTAX +ISO10589-ISIS.HopMetric; +MATCHES FOR Equality, Ordering; +BEHAVIOUR l2ErrorMetric-B BEHAVIOUR +DEFINED AS The error metric value of this circuit for +Level 2 traffic. The value of zero is reserved to indi +cate that this metric is not supported;; +REGISTERED AS {ISO10589-ISIS.aoi l2ErrorMetric +(71)}; + +manualL2OnlyMode ATTRIBUTE +WITH ATTRIBUTE SYNTAX ISO10589-ISIS.Boolean; +MATCHES FOR Equality; +BEHAVIOUR manualL2OnlyMode-B BEHAVIOUR +DEFINED AS When True, indicates that this Circuit is +to be used only for Level 2;, +replaceOnlyWhileDisabled-B; +PARAMETERS constraintViolation; +REGISTERED AS {ISO10589-ISIS.aoi +manualL2OnlyMode (72)}; + + +l2IntermediateSystemPriority ATTRIBUTE +WITH ATTRIBUTE SYNTAX +ISO10589-ISIS.IntermediateSystemPriority; +MATCHES FOR Equality, Ordering; +BEHAVIOUR l2IntermediateSystemPriority-B +BEHAVIOUR +DEFINED AS Priority for becoming LAN Level 2 +Designated Intermediate System;; +REGISTERED AS {ISO10589-ISIS.aoi +l2IntermediateSystemPriority (73)}; + +l2CircuitID ATTRIBUTE +WITH ATTRIBUTE SYNTAX +ISO10589-ISIS.CircuitID; +MATCHES FOR Equality; +BEHAVIOUR l2CircuitID-B BEHAVIOUR +DEFINED AS The LAN ID allocated by the LAN +Level 2 Designated Intermediate System. Where this +system is not aware of the value (because it is not +participating in the Level 2 Designated Intermediate +System election), this attribute has the value which +would be proposed for this circuit. (i.e. the concate +nation of the local system ID and the one octet local +Circuit ID for this circuit.;; +REGISTERED AS {ISO10589-ISIS.aoi l2CircuitID +(74)}; + +l2DesignatedIntermediateSystem ATTRIBUTE +WITH ATTRIBUTE SYNTAX +ISO10589-ISIS.SystemID; +MATCHES FOR Equality; +BEHAVIOUR l2DesignatedIntermediateSystem-B +BEHAVIOUR +DEFINED AS The ID of the LAN Level 2 Designated +Intermediate System on this circuit. If, for any rea +son this system is not partaking in the relevant Des +ignated Intermediate System election process, then +the value returned is ;; +REGISTERED AS {ISO10589-ISIS.aoi +l2DesignatedIntermediateSystem (75)}; + +lanL2DesignatedIntermediateSystemChanges +ATTRIBUTE +DERIVED FROM nonWrappingCounter; +BEHAVIOUR +lanL2DesignatedIntermediateSystemChanges-B +BEHAVIOUR +DEFINED AS Number of LAN L2 Designated Inter +mediate System Change events generated;; +REGISTERED AS {ISO10589-ISIS.aoi +lanL2DesignatedIntermediateSystemChanges (76)}; + +adjacencyName ATTRIBUTE +WITH ATTRIBUTE SYNTAX +ISO10589-ISIS.GraphicString; +MATCHES FOR Equality, Substrings; + +BEHAVIOUR adjacencyName-B BEHAVIOUR +DEFINED AS A string which is the Identifier for the +Adjacency and which is unique amongst the set of +Adjacencies maintained for this Circuit. If this is a +manually created adjacency (i.e. the type is Manual) +it is set by the System Manager when the Adjacency +is created, otherwise it is generated by the imple +mentation such that it is unique. The set of identifier +containing the leading string "Auto" are reserved for +Automatic Adjacencies. An attempt to create a Man +ual Adjacency with such an identifier will cause an +exception to be raised;; +REGISTERED AS {ISO10589-ISIS.aoi adjacencyName +(77)}; + +adjacencyState ATTRIBUTE +WITH ATTRIBUTE SYNTAX +ISO10589-ISIS.AdjacencyState; +MATCHES FOR Equality; +BEHAVIOUR adjacencyState-B BEHAVIOUR +DEFINED AS The state of the adjacency;; +REGISTERED AS {ISO10589-ISIS.aoi adjacencyState +(78)}; + +neighbourLANAddress ATTRIBUTE +WITH ATTRIBUTE SYNTAX +ISO10589-ISIS.LANAddress; +MATCHES FOR Equality; +BEHAVIOUR neighbourLANAddress-B BEHAVIOUR +DEFINED AS The MAC address of the neighbour sys +tem on a broadcast circuit;, +replaceOnlyWhileDisabled-B; +PARAMETERS constraintViolation; +REGISTERED AS {ISO10589-ISIS.aoi +neighbourLANAddress (79)}; + +neighbourSystemType ATTRIBUTE +WITH ATTRIBUTE SYNTAX +ISO10589-ISIS.NeighbourSystemType; +MATCHES FOR Equality; +BEHAVIOUR neighbourSystemType-B BEHAVIOUR +DEFINED AS The type of the neighbour system one +of: Unknown End system Intermediate system L1 +Intermediate system L2 Intermediate system;; +REGISTERED AS {ISO10589-ISIS.aoi +neighbourSystemType (80)}; + +sNPAAddress ATTRIBUTE +WITH ATTRIBUTE SYNTAX +ISO10589-ISIS.SNPAAddress; +MATCHES FOR Equality; +BEHAVIOUR sNPAAddress-B BEHAVIOUR +DEFINED AS The SNPA Address of the neighbour +system on an X.25 circuit;, +replaceOnlyWhileDisabled-B; +PARAMETERS constraintViolation; +REGISTERED AS {ISO10589-ISIS.aoi sNPAAddress +(81)}; + + +adjacencyUsageType ATTRIBUTE +WITH ATTRIBUTE SYNTAX +ISO10589-ISIS.AdjacencyUsageType; +MATCHES FOR Equality; +BEHAVIOUR level-B BEHAVIOUR +DEFINED AS The usage of the Adjacency. An +Adjacency of type Level 1" will be used for Level 1 +traffic only. An adjacency of type Level 2" will be +used for Level 2 traffic only. An adjacency of type +Level 1 and 2" will be used for both Level 1 and +Level 2 traffic. There may be two adjacencies (of +types Level 1" and Level 2" between the same pair +of Intermediate Systems.;; +REGISTERED AS {ISO10589-ISIS.aoi +adjacencyUsageType (82)}; + +neighbourSystemID ATTRIBUTE +WITH ATTRIBUTE SYNTAX +ISO10589-ISIS.SystemID; +MATCHES FOR Equality; +BEHAVIOUR neighbourSystemID-B BEHAVIOUR +DEFINED AS The SystemID of the neighbouring In +termediate system from the Source ID field of the +neighbour's IIH PDU. The Intermediate System ID +for this neighbour is derived by appending zero to +this value.;; +REGISTERED AS {ISO10589-ISIS.aoi +neighbourSystemID (83)}; + +neighbourAreas ATTRIBUTE +WITH ATTRIBUTE SYNTAX +ISO10589-ISIS.AreaAddresses; +MATCHES FOR Equality, Set Comparison, Set +Intersection; +BEHAVIOUR neighbourAreas-B BEHAVIOUR +DEFINED AS This contains the Area Addresses of a +neighbour Intermediate System from the IIH PDU.;; +REGISTERED AS {ISO10589-ISIS.aoi neighbourAreas +(84)}; + +holdingTimer ATTRIBUTE +WITH ATTRIBUTE SYNTAX +ISO10589-ISIS.HoldingTimer; +MATCHES FOR Equality, Ordering; +BEHAVIOUR holdingTimer-B BEHAVIOUR +DEFINED AS Holding time for this adjacency updated +from the IIH PDUs;; +REGISTERED AS {ISO10589-ISIS.aoi holdingTimer +(85)}; + +lANPriority ATTRIBUTE +WITH ATTRIBUTE SYNTAX +ISO10589-ISIS.IntermediateSystemPriority; +MATCHES FOR Equality, Ordering; +BEHAVIOUR lANPriority-B BEHAVIOUR +DEFINED AS Priority of neighbour on this adjacency +for becoming LAN Level 1 Designated Intermediate +System if adjacencyType is L1 Intermediate System +or LAN Level 2 Designated Intermediate System if +adjacencyType is L2 Intermediate System;; +REGISTERED AS {ISO10589-ISIS.aoi lANPriority +(86)}; + + +endSystemIDs ATTRIBUTE +WITH ATTRIBUTE SYNTAX +ISO10589-ISIS.EndSystemIDs; +MATCHES FOR Equality, Set Comparison, Set +Intersection; +BEHAVIOUR endSystemIDs-B BEHAVIOUR +DEFINED AS This contains the system ID(s) of a +neighbour End system. Where (in a Intermediate +System) an adjacency has been created manually, +these will be the set of IDs given in the manualIDs +parameter of the create directive.;; +REGISTERED AS {ISO10589-ISIS.aoi endSystemIDs +(87)}; + +networkEntityTitle ATTRIBUTE +WITH ATTRIBUTE SYNTAX +ISO10589-ISIS.NetworkEntityTitle; +MATCHES FOR Equality, Ordering; +BEHAVIOUR networkEntityTitle-B BEHAVIOUR +DEFINED AS The Network entity Title which is the +destination of a Virtual link being used to repair a +partitioned Level 1 area (see clause 7.2.10);; +REGISTERED AS {ISO10589-ISIS.aoi +networkEntityTitle (88)}; + +metric ATTRIBUTE +WITH ATTRIBUTE SYNTAX +ISO10589-ISIS.PathMetric; +MATCHES FOR Equality, Ordering; +BEHAVIOUR metric-B BEHAVIOUR +DEFINED AS Cost of least cost L2 path(s) to destina +tion area based on the default metric;; +REGISTERED AS {ISO10589-ISIS.aoi metric (89)}; + +defaultMetricPathCost ATTRIBUTE +WITH ATTRIBUTE SYNTAX +ISO10589-ISIS.PathMetric; +MATCHES FOR Equality, Ordering; +BEHAVIOUR defaultMetricPathCost-B BEHAVIOUR +DEFINED AS Cost of least cost path(s) using the de +fault metric to destination;; +REGISTERED AS {ISO10589-ISIS.aoi +defaultMetricPathCost (90)}; + +defaultMetricOutputAdjacencies ATTRIBUTE +WITH ATTRIBUTE SYNTAX +ISO10589-ISIS.OutputAdjacencies; +MATCHES FOR Equality, Set Comparison, Set +Intersection; +BEHAVIOUR defaultMetricOutputAdjacencies-B +BEHAVIOUR +DEFINED AS The set of Adjacency (or Reachable Ad +dress) managed object identifiers representing the +forwarding decisions based upon the default metric +for the destination;; +REGISTERED AS {ISO10589-ISIS.aoi +defaultMetricOutputAdjacencies (91)}; + +delayMetricPathCost ATTRIBUTE +WITH ATTRIBUTE SYNTAX +ISO10589-ISIS.PathMetric; +MATCHES FOR Equality, Ordering; + +BEHAVIOUR delayMetricPathCost-B BEHAVIOUR +DEFINED AS Cost of least cost path(s) using the delay +metric to destination;; +REGISTERED AS {ISO10589-ISIS.aoi +delayMetricPathCost (92)}; + +delayMetricOutputAdjacencies ATTRIBUTE +WITH ATTRIBUTE SYNTAX +ISO10589-ISIS.OutputAdjacencies; +MATCHES FOR Equality, Set Comparison, Set +Intersection; +BEHAVIOUR delayMetricOutputAdjacencies-B +BEHAVIOUR +DEFINED AS The set of Adjacency (or Reachable Ad +dress) managed object identifiers representing the +forwarding decisions based upon the delay metric +for the destination;; +REGISTERED AS {ISO10589-ISIS.aoi +delayMetricOutputAdjacencies (93)}; + +expenseMetricPathCost ATTRIBUTE +WITH ATTRIBUTE SYNTAX +ISO10589-ISIS.PathMetric; +MATCHES FOR Equality, Ordering; +BEHAVIOUR expenseMetricPathCost-B BEHAVIOUR +DEFINED AS Cost of least cost path(s) using the ex +pense metric to destination;; +REGISTERED AS {ISO10589-ISIS.aoi +expenseMetricPathCost (94)}; + +expenseMetricOutputAdjacencies ATTRIBUTE +WITH ATTRIBUTE SYNTAX +ISO10589-ISIS.OutputAdjacencies; +MATCHES FOR Equality, Set Comparison, Set +Intersection; +BEHAVIOUR expenseMetricOutputAdjacencies-B +BEHAVIOUR +DEFINED AS The set of Adjacency (or Reachable Ad +dress) managed object identifiers representing the +forwarding decisions based upon the expense metric +for the destination;; +REGISTERED AS {ISO10589-ISIS.aoi +expenseMetricOutputAdjacencies (95)}; + +errorMetricPathCost ATTRIBUTE +WITH ATTRIBUTE SYNTAX +ISO10589-ISIS.PathMetric; +MATCHES FOR Equality, Ordering; +BEHAVIOUR errorMetricPathCost-B BEHAVIOUR +DEFINED AS Cost of least cost path(s) using the error +metric to destination;; +REGISTERED AS {ISO10589-ISIS.aoi +errorMetricPathCost (96)}; + +errorMetricOutputAdjacencies ATTRIBUTE +WITH ATTRIBUTE SYNTAX +ISO10589-ISIS.OutputAdjacencies; +MATCHES FOR Equality, Set Comparison, Set +Intersection; +BEHAVIOUR errorMetricOutputAdjacencies-B + +BEHAVIOUR +DEFINED AS The set of Adjacency (or Reachable Ad +dress) managed object identifiers representing the +forwarding decisions based upon the error metric for +the destination;; +REGISTERED AS {ISO10589-ISIS.aoi +errorMetricOutputAdjacencies (97)}; + +addressPrefix ATTRIBUTE +WITH ATTRIBUTE SYNTAX +ISO10589-ISIS.AddressPrefix; +MATCHES FOR Equality, Substrings; +BEHAVIOUR addressPrefix-B BEHAVIOUR +DEFINED AS An Area Address (or prefix) of a desti +nation area;; +REGISTERED AS {ISO10589-ISIS.aoi addressPrefix +(98)}; + +defaultMetric ATTRIBUTE +WITH ATTRIBUTE SYNTAX +ISO10589-ISIS.HopMetric; +MATCHES FOR Equality, Ordering; +BEHAVIOUR defaultMetric-B BEHAVIOUR +DEFINED AS The default metric value for reaching +the specified prefix over this Circuit. If this attribute +is changed while both the Reachable Address and +the Circuit are Enabled (i.e. state On), the actions +described in clause 8.3.5.4 must be taken. The value +of zero is reserved to indicate that this metric is not +supported;; +REGISTERED AS {ISO10589-ISIS.aoi defaultMetric +(99)}; + +delayMetric ATTRIBUTE +WITH ATTRIBUTE SYNTAX +ISO10589-ISIS.HopMetric; +MATCHES FOR Equality, Ordering; +BEHAVIOUR delayMetric-B BEHAVIOUR +DEFINED AS The delay metric value for reaching the +specified prefix over this Circuit.BEHAVIOURIf +this attribute is changed while both the Reachable +Address and the Circuit are Enabled (i.e. state On), +the actions described in clause 8.3.5.4 must be taken. +The value of zero is reserved to indicate that this +metric is not supported;; +REGISTERED AS {ISO10589-ISIS.aoi delayMetric +(100)}; + +expenseMetric ATTRIBUTE +WITH ATTRIBUTE SYNTAX +ISO10589-ISIS.HopMetric; +MATCHES FOR Equality, Ordering; +BEHAVIOUR expenseMetric-B BEHAVIOUR +DEFINED AS The expense metric value for reaching +the specified prefix over this Circuit. If this attribute +is changed while both the Reachable Address and +the Circuit are Enabled (i.e. state On), the actions +described in clause 8.3.5.4 must be taken. The value +of zero is reserved to indicate that this metric is not +supported;; +REGISTERED AS {ISO10589-ISIS.aoi expenseMetric +(101)}; + + +errorMetric ATTRIBUTE +WITH ATTRIBUTE SYNTAX +ISO10589-ISIS.HopMetric; +MATCHES FOR Equality, Ordering; +BEHAVIOUR errorMetric-B BEHAVIOUR +DEFINED AS The error metric value for reaching the +specified prefix over this Circuit. If this attribute is +changed while both the Reachable Address and the +Circuit are Enabled (i.e. state On), the actions de +scribed in clause 8.3.5.4 must be taken. The value of +zero is reserved to indicate that this metric is not +supported;; +REGISTERED AS {ISO10589-ISIS.aoi errorMetric +(102)}; + +defaultMetricType ATTRIBUTE +WITH ATTRIBUTE SYNTAX +ISO10589-ISIS.MetricType; +MATCHES FOR Equality; +BEHAVIOUR defaultMetricType-B BEHAVIOUR +DEFINED AS Indicates whether the default metric is +internal or external;; +REGISTERED AS {ISO10589-ISIS.aoi +defaultMetricType (103)}; + +delayMetricType ATTRIBUTE +WITH ATTRIBUTE SYNTAX +ISO10589-ISIS.MetricType; +MATCHES FOR Equality; +BEHAVIOUR delayMetricType-B BEHAVIOUR +DEFINED AS Indicates whether the delay metric is in +ternal or external;; +REGISTERED AS {ISO10589-ISIS.aoi delayMetricType +(104)}; + +expenseMetricType ATTRIBUTE +WITH ATTRIBUTE SYNTAX +ISO10589-ISIS.MetricType; +MATCHES FOR Equality; +BEHAVIOUR expenseMetricType-B BEHAVIOUR +DEFINED AS Indicates whether the expense metric is +internal or external;; +REGISTERED AS {ISO10589-ISIS.aoi +expenseMetricType (105)}; + +errorMetricType ATTRIBUTE +WITH ATTRIBUTE SYNTAX +ISO10589-ISIS.MetricType; +MATCHES FOR Equality; +BEHAVIOUR errorMetricType-B BEHAVIOUR +DEFINED AS Indicates whether the error metric is in +ternal or extternal;; +REGISTERED AS {ISO10589-ISIS.aoi errorMetricType +(106)}; + +mappingType ATTRIBUTE +WITH ATTRIBUTE SYNTAX +ISO10589-ISIS.MappingType; +MATCHES FOR Equality; + +BEHAVIOUR mappingType-B BEHAVIOUR +DEFINED AS The type of mapping to be employed to +ascertain the SNPA Address to which a call should +be placed for this prefix. X.121 indicates that the +X.121 address extraction algorithm is to be em +ployed. This will extract the SNPA address from the +IDI of an X.121 format IDP of the NSAP address to +which the NPDU is to be forwarded. Manual indi +cates that the set of addresses in the sNPAAddresses +or LANAddresses characteristic are to be used. For +Broadcast circuits, only the value Manual is permit +ted;; +REGISTERED AS {ISO10589-ISIS.aoi mappingType +(107)}; + +lANAddress ATTRIBUTE +WITH ATTRIBUTE SYNTAX +ISO10589-ISIS.LANAddress; +MATCHES FOR Equality; +BEHAVIOUR lANAddress-B BEHAVIOUR +DEFINED AS Asingle LAN addresses to which an +NPDU may be directed in order to reach an address +which matches the address prefix of the Reachable +Address. An exception is raised if an attempt is +made to enable the Reachable Address with the de +fault value;; +REGISTERED AS {ISO10589-ISIS.aoi lANAddress +(108)}; + +sNPAAddresses ATTRIBUTE +WITH ATTRIBUTE SYNTAX +ISO10589-ISIS.SNPAAddresses; +MATCHES FOR Equality; +BEHAVIOUR sNPAAddresses-B BEHAVIOUR +DEFINED AS A set of SNPA addresses to which a call +may be directed in order to reach an address which +matches the address prefix of the Reachable Ad +dress. Associated with each SNPA Address, but not +visible to System Management, is a variable lastFail +ure of Type BinaryAbsoluteTime;; +REGISTERED AS {ISO10589-ISIS.aoi sNPAAddresses +(109)}; + +nonWrappingCounter ATTRIBUTE +WITH ATTRIBUTE SYNTAX +ISO10589-ISIS.NonWrappingCounter; +MATCHES FOR Equality, Ordering; +BEHAVIOUR nonWrappingCounter-B BEHAVIOUR +DEFINED AS Non-replaceable, non-wrapping +counter;; +-- This attibute is only defined in order to allow other +counter attributes to be derived from it. +REGISTERED AS {ISO10589-ISIS.aoi +nonWrappingCounter (110)}; + +areaTransmitPassword ATTRIBUTE +WITH ATTRIBUTE SYNTAX +ISO10589-ISIS.Password; +MATCHES FOR Equality; +BEHAVIOUR areaTransmitPassword-B BEHAVIOUR +DEFINED AS The value to be used as a transmit pass +word in Level 1 LSP, and SNP PDUs transmitted by +this Intermediate System;; +REGISTERED AS {ISO10589-ISIS.aoi +areaTransmitPassword (111)}; + + +areaReceivePasswords ATTRIBUTE +WITH ATTRIBUTE SYNTAX +ISO10589-ISIS.Passwords; +MATCHES FOR Equality; +BEHAVIOUR areaReceivePasswords-B BEHAVIOUR +DEFINED AS The values to be used as receive pass +words to check the receipt of Level 1 LSP, and SNP +PDUs;; +REGISTERED AS {ISO10589-ISIS.aoi +areaReceivePasswords (112)}; + +domainTransmitPassword ATTRIBUTE +WITH ATTRIBUTE SYNTAX +ISO10589-ISIS.Password; +MATCHES FOR Equality; +BEHAVIOUR domainTransmitPassword-B +BEHAVIOUR +DEFINED AS The value to be used as a transmit pass +word in Level 2 LSP, and SNP PDUs transmitted by +this Intermediate System;; +REGISTERED AS {ISO10589-ISIS.aoi +domainTransmitPassword (113)}; + +domainReceivePasswords ATTRIBUTE +WITH ATTRIBUTE SYNTAX +ISO10589-ISIS.Passwords; +MATCHES FOR Equality; +BEHAVIOUR domainReceivePasswords-B +BEHAVIOUR +DEFINED AS The values to be used as receive pass +words to check the receipt of Level 2 LSP, and SNP +PDUs;; +REGISTERED AS {ISO10589-ISIS.aoi +domainReceivePasswords (114)}; + +circuitTransmitPassword ATTRIBUTE +WITH ATTRIBUTE SYNTAX +ISO10589-ISIS.Password; +MATCHES FOR Equality; +BEHAVIOUR circuitTransmitPassword-B +BEHAVIOUR +DEFINED AS The value to be used as a transmit pass +word in IIH PDUs transmitted by this Intermediate +System;; +REGISTERED AS {ISO10589-ISIS.aoi +circuitTransmitPassword (115)}; + +circuitReceivePasswords ATTRIBUTE +WITH ATTRIBUTE SYNTAX +ISO10589-ISIS.Passwords; +MATCHES FOR Equality; +BEHAVIOUR circuitReceivePasswords-B +BEHAVIOUR +DEFINED AS The values to be used as receive pass +words to check the receipt of IIH PDUs;; +REGISTERED AS {ISO10589-ISIS.aoi +circuitReceivePasswords (116)}; + +authenticationFailures ATTRIBUTE +DERIVED FROM nonWrappingCounter; + +BEHAVIOUR authenticationFailures-B BEHAVIOUR +DEFINED AS Count of authentication Failure notifica +tions generated;; +REGISTERED AS {ISO10589-ISIS.aoi +authenticationFailures (117)}; + +11.2.12 Notification Definitions +-- Note pduFormatError notification now included in +Network layer definitions +corruptedLSPDetected NOTIFICATION +BEHAVIOUR corruptedLSPDetected-B BEHAVIOUR +DEFINED AS The Corrupted LSP Detected Notifica +tion is generated when a corrupted Link State PDU +is detected in memory. The occurance of this event +is counted by the corruptedLSPsDetected counter.;; +MODE NON-CONFIRMED; +WITH INFORMATION SYNTAX +ISO10589-ISIS.NotificationInfo; +REGISTERED AS {ISO10589-ISIS.noi +corruptedLSPDetected (1)}; + +lSPL1DatabaseOverload NOTIFICATION +BEHAVIOUR lSPL1DatabaseOverload-B +BEHAVIOUR +DEFINED AS The LSP L1 Database Overload Notifi +cation is generated when the l1State of the system +changes between On and Waiting or Waiting and +On. The stateChange argument is set to indicate the +resulting state, and in the case of Waiting the sour +ceID is set to indicate the source of the LSP which +precipitated the overload. The occurance of this +event is counted by the lSPL1DatabaseOverloads +counter.;; +MODE NON-CONFIRMED; +PARAMETERS +notificationOverloadStateChange, +notificationSourceID; +WITH INFORMATION SYNTAX +ISO10589-ISIS.NotificationInfo; +REGISTERED AS {ISO10589-ISIS.noi +lSPL1DatabaseOverload (2)}; + +manualAddressDroppedFromArea NOTIFICATION +BEHAVIOUR manualAddressDroppedFromArea-B +BEHAVIOUR +DEFINED AS The Manual Address Dropped From +Area Notification is generated when one of the man +ualAreaAddresses (specified on this system) is ig +nored when computing partitionAreaAddresses or +areaAddresses because there are more than Maximu +mAreaAddresses distinct Area Addresses. The +areaAddress argument is set to the ignored Area Ad +dress. It is generated once for each Area Address in +manualAreaAddresses which is dropped. It is not +logged again for that Area Address until after it has +been reinstated into areaAddresses (i.e. it is only the +action of dropping the Area Address and not the +state of being dropped, which causes the event to be +generated). The occurance of this event is counted +by the manualAddressDroppedFromAreas counter.;; +MODE NON-CONFIRMED; +PARAMETERS +notificationAreaAddress; +WITH INFORMATION SYNTAX + +ISO10589-ISIS.NotificationInfo; +REGISTERED AS {ISO10589-ISIS.noi +manualAddressDroppedFromArea (3)}; + +attemptToExceedMaximumSequenceNumber +NOTIFICATION +BEHAVIOUR +attemptToExceedMaximumSequenceNumber-B +BEHAVIOUR +DEFINED AS The Attempt To Exceed Maximum Se +quence Number Notification is generated when an +attempt is made to increment the sequence number +of an LSP beyond the maximum sequence number. +Following the generation of this event the operation +of the Routeing state machine shall be disabled for at +least (MaxAge + ZeroAgeLifetime) seconds. The +occurance of this event is counted by the +attemptsToExceedMaximumSequenceNumber +counter.;; +MODE NON-CONFIRMED; +WITH INFORMATION SYNTAX +ISO10589-ISIS.NotificationInfo; +REGISTERED AS {ISO10589-ISIS.noi +attemptToExceedMaximumSequenceNumber (4)}; + +sequenceNumberSkip NOTIFICATION +BEHAVIOUR sequenceNumberSkip-B BEHAVIOUR +DEFINED AS The Sequence Number Skipped Notifi +cation is generated when the sequence number of an +LSP is incremented by more than one. The occur +ance of this event is counted by the sequenceNum +berSkips counter.;; +MODE NON-CONFIRMED; +WITH INFORMATION SYNTAX +ISO10589-ISIS.NotificationInfo; +REGISTERED AS {ISO10589-ISIS.noi +sequenceNumberSkip (5)}; + +ownLSPPurge NOTIFICATION +BEHAVIOUR ownLSPPurge-B BEHAVIOUR +DEFINED AS The Own LSP Purged Notification is +generated when a zero aged copy of a system's own +LSP is received from some other system. This repre +sents an erroneous attempt to purge the local sys +tem's LSP. The occurance of this event is counted +by the ownLSPPurges counter.;; +MODE NON-CONFIRMED; +WITH INFORMATION SYNTAX +ISO10589-ISIS.NotificationInfo; +REGISTERED AS {ISO10589-ISIS.noi ownLSPPurge +(6)}; + +partitionVirtualLinkChange NOTIFICATION +BEHAVIOUR partitionVirtualLinkChange-B +BEHAVIOUR +DEFINED AS The Partition Virtual Link Change Noti +fication is generated when a virtual link (for the pur +poses of Level 1 partition repair) is either created or +deleted. The relative order of events relating to the +same Virtual Link must be preserved. The occur +ance of this event is counted by the partitionVirtual +LinkChanges counter.;; +MODE NON-CONFIRMED; +PARAMETERS +notificationVirtualLinkChange, + +notificationVirtualLinkAddress; +WITH INFORMATION SYNTAX +ISO10589-ISIS.NotificationInfo; +REGISTERED AS {ISO10589-ISIS.noi +partitionVirtualLinkChange (7)}; + +lSPL2DatabaseOverload NOTIFICATION +BEHAVIOUR lSPL2DatabaseOverload-B +BEHAVIOUR +DEFINED AS The LSP L2 Database Overload Notifi +cation is generated when the l2State of the system +changes between On and Waiting or Waiting and +On. The stateChange argument is set to indicate the +resulting state, and in the case of Waiting the sour +ceID is set to indicate the source of the LSP which +precipitated the overload. The occurance of this +event is counted by the lSPL2DatabaseOverloads +counter.;; +MODE NON-CONFIRMED; +PARAMETERS +notificationOverloadStateChange, +notificationSourceID; +WITH INFORMATION SYNTAX +ISO10589-ISIS.NotificationInfo; +REGISTERED AS {ISO10589-ISIS.noi +lSPL2DatabaseOverload (8)}; + +iDFieldLengthMismatch NOTIFICATION +BEHAVIOUR iDFieldLengthMismatch-B +BEHAVIOUR +DEFINED AS The iDFieldLengthMismatch Notifica +tion is generated when a PDU is received with a dif +ferent value for ID field length to that of the +receiving Intermediate system. The occurance of this +event is counted by the iDFieldLengthMismatches +counter.;; +MODE NON-CONFIRMED; +PARAMETERS +notificationIDLength, +notificationSourceID; +WITH INFORMATION SYNTAX +ISO10589-ISIS.NotificationInfo; +REGISTERED AS {ISO10589-ISIS.noi +iDFieldLengthMismatch (9)}; + +circuitChange NOTIFICATION +BEHAVIOUR circuitChange-B BEHAVIOUR +DEFINED AS The Circuit Change Notification is gen +erated when the state of the Circuit changes from On +to Off or from Off to On. The relative order of +events relating to the same Circuit must be pre +served. The occurance of this event is counted by +the circuitChanges counter.;; +MODE NON-CONFIRMED; +PARAMETERS +notificationNewCircuitState; +WITH INFORMATION SYNTAX +ISO10589-ISIS.NotificationInfo; +REGISTERED AS {ISO10589-ISIS.noi circuitChange +(10)}; + + +adjacencyStateChange NOTIFICATION +BEHAVIOUR adjacencyStateChange-B BEHAVIOUR +DEFINED AS The Adjacency State Change Notifica +tion is generated when the state of an Adjacency on +the Circuit changes from Up to Down or Down to +Up (in the latter case the Reason argument is omit +ted). For these purposes the states Up and +Up/dormant are considered to be Up, and any other +state is considered to be Down. The relative order of +events relating to the same Adjacency must be pre +served. The occurance of this event is counted by +the adjacencyStateChanges counter.;; +MODE NON-CONFIRMED; +PARAMETERS +notificationAdjacentSystem, +notificationNewAdjacencyState, +notificationReason, +notificationPDUHeader, +notificationCalledAddress, +notificationVersion; +WITH INFORMATION SYNTAX +ISO10589-ISIS.NotificationInfo; +REGISTERED AS {ISO10589-ISIS.noi +adjacencyStateChange (11)}; + +initializationFailure NOTIFICATION +BEHAVIOUR initializationFailure-B BEHAVIOUR +DEFINED AS The Initialisation Failure Notification is +generated when an attempt to initialise with an adja +cent system fails as a result of either Version Skew +or Area Mismatch. In the case of Version Skew, the +Adjacent system argument is not present. The oc +curance of this event is counted by the initialization +Failures counter.;; +MODE NON-CONFIRMED; +PARAMETERS +notificationAdjacentSystem, +notificationReason, +notificationPDUHeader, +notificationCalledAddress, +notificationVersion; +WITH INFORMATION SYNTAX +ISO10589-ISIS.NotificationInfo; +REGISTERED AS {ISO10589-ISIS.noi +initializationFailure (12)}; + +rejectedAdjacency NOTIFICATION +BEHAVIOUR rejectedAdjacency-B BEHAVIOUR +DEFINED AS The Rejected Adjacency Notification is +generated when an attempt to create a new adja +cency is rejected, because of a lack of resources. +The occurance of this event is counted by the reject +edAdjacencies counter.;; +MODE NON-CONFIRMED; +PARAMETERS +notificationAdjacentSystem, +notificationReason, +notificationPDUHeader, +notificationCalledAddress, +notificationVersion; +WITH INFORMATION SYNTAX +ISO10589-ISIS.NotificationInfo; +REGISTERED AS {ISO10589-ISIS.noi +rejectedAdjacency (13)}; + + +lanL1DesignatedIntermediateSystemChange +NOTIFICATION +BEHAVIOUR +lanL1DesignatedIntermediateSystemChange-B +BEHAVIOUR +DEFINED AS The LAN L1 Designated Intermediate +System Change Notification is generated when the +local system either elects itself or resigns as being +the LAN L1 Designated Intermediate System on this +circuit. The relative order of these events must be +preserved. The occurance of this event is counted by +the lanL1DesignatedIntermediateSystemChanges +counter.;; +MODE NON-CONFIRMED; +PARAMETERS +notificationDesignatedIntermediateSystemChange; +WITH INFORMATION SYNTAX +ISO10589-ISIS.NotificationInfo; +REGISTERED AS {ISO10589-ISIS.noi +lanL1DesignatedIntermediateSystemChange (14)}; + +exceededMaximumSVCAdjacencies NOTIFICATION +BEHAVIOUR exceededMaximumSVCAdjacencies-B +BEHAVIOUR +DEFINED AS The Exceeded Maximum SVC Adjacen +cies Notification is generated when there is no free +adjacency on which to establish an SVC for a new +destination.(see clause 8.3.2.3) The occurance of +this event is counted by the +timesExceededMaximumSVCAdjacencies counter.;; +MODE NON-CONFIRMED; +WITH INFORMATION SYNTAX +ISO10589-ISIS.NotificationInfo; +REGISTERED AS {ISO10589-ISIS.noi +exceededMaximumSVCAdjacencies (15)}; + +exceededMaximumCallAttempts NOTIFICATION +BEHAVIOUR exceededMaximumCallAttempts-B +BEHAVIOUR +DEFINED AS The Exceeded Maximum Call Attempts +Notification is generated when recallCount becomes +equal to maximumCallAttempts. The occurance of +this event is counted by the timesExceededMaxi +mumCallAttempts counter.;; +MODE NON-CONFIRMED; +WITH INFORMATION SYNTAX +ISO10589-ISIS.NotificationInfo; +REGISTERED AS {ISO10589-ISIS.noi +exceededMaximumCallAttempts (16)}; + +lanL2DesignatedIntermediateSystemChange +NOTIFICATION +BEHAVIOUR +lanL2DesignatedIntermediateSystemChange-B +BEHAVIOUR +DEFINED AS The LAN L2 Designated Intermediate +System Change Notification is generated when the +local system either elects itself or resigns as being +the LAN L2 Designated Intermediate System on this +circuit. The relative order of these events must be +preserved. The occurance of this event is counted by +the lanL2DesignatedIntermediateSystemChanges +counter.;; +MODE NON-CONFIRMED; + +PARAMETERS +notificationDesignatedIntermediateSystemChange; +WITH INFORMATION SYNTAX +ISO10589-ISIS.NotificationInfo; +REGISTERED AS {ISO10589-ISIS.noi +lanL2DesignatedIntermediateSystemChange (17)}; + +authenticationFailure NOTIFICATION +BEHAVIOUR authenticationFailure-B BEHAVIOUR +DEFINED AS Generated when a PDU is received with +an incorrect Authentication information field;; +MODE NON-CONFIRMED; +PARAMETERS +notificationAdjacentSystem; +WITH INFORMATION SYNTAX +ISO10589-ISIS.NotificationInfo; +REGISTERED AS {ISO10589-ISIS.noi +authenticationFailure (18)}; + +11.2.13 Action Definitions +-- Note: The following actions have been proposed (in +SC21 N4977) for inclusion in DMI. Until such time +as this is completed, the definitions of these actions +are given here. +-- +activate ACTION +BEHAVIOUR activate-B BEHAVIOUR +DEFINED AS Sets OperationalState to `enabled' and +commences operation;; +MODE CONFIRMED; +PARAMETERS successResponse, failureResponse, +failureReason; +WITH INFORMATION SYNTAX +ISO10589-ISIS.ActionInfo; +WITH REPLY SYNTAX ISO10589-ISIS.ActionReply; +REGISTERED AS {ISO10589-ISIS.acoi activate (1)}; + +deactivate ACTION +BEHAVIOUR deactivate-B BEHAVIOUR +DEFINED AS Sets OperationalState to `disabled' and +ceases operation;; +MODE CONFIRMED; +PARAMETERS successResponse, failureResponse, +failureReason; +WITH INFORMATION SYNTAX +ISO10589-ISIS.ActionInfo; +WITH REPLY SYNTAX ISO10589-ISIS.ActionReply; +REGISTERED AS {ISO10589-ISIS.acoi deactivate (2)}; + +11.2.14 Parameter Definitions +iSO10589-NB-p1 PARAMETER +CONTEXT CREATE-INFO; +WITH SYNTAX ISO10589-ISIS.ISType; +BEHAVIOUR iSO10589-NB-p1-B BEHAVIOUR +DEFINED AS The value to be given to the iStype at +tribute on MO creation. This parameter is manda +tory;; +REGISTERED AS {ISO10589-ISIS.proi +iSO10589-NB-p1 (1)}; + + +iSO10589Circuit-MO-p1 PARAMETER +CONTEXT CREATE-INFO; +WITH SYNTAX ISO10589-ISIS.CircuitType; +BEHAVIOUR iSO10589Circuit-MO-p1-B +BEHAVIOUR +DEFINED AS The value to be given to the type attrib +ute on MO creation. This parameter is mandatory;; +REGISTERED AS {ISO10589-ISIS.proi +iSO10589Circuit-MO-p1 (2)}; + +reachableAddressP1 PARAMETER +CONTEXT CREATE-INFO; +WITH SYNTAX ISO10589-ISIS.AddressPrefix; +BEHAVIOUR reachableAddressp1-B BEHAVIOUR +DEFINED AS The value to be given to the addressPre +fix attribute on MO creation. This parameter is man +datory;; +REGISTERED AS {ISO10589-ISIS.proi +reachableAddressP1 (3)}; + +reachableAddressP2 PARAMETER +CONTEXT CREATE-INFO; +WITH SYNTAX ISO10589-ISIS.MappingType; +BEHAVIOUR reachableAddressp2-B BEHAVIOUR +DEFINED AS The value to be given to the map +pingType attribute on MO creation. This parameter +is only permitted when the `type' of the parent cir +cuit is either `broadcast' or `DA'. In those cases the +default value is `manual';; +REGISTERED AS {ISO10589-ISIS.proi +reachableAddressP2 (4)}; + +manualAdjacencyP1 PARAMETER +CONTEXT CREATE-INFO; +WITH SYNTAX ISO10589-ISIS.LANAddress; +BEHAVIOUR manualAdjacencyP1-B BEHAVIOUR +DEFINED AS The value to be given to the lANAd +dress attribute on MO creation;; +REGISTERED AS {ISO10589-ISIS.proi +manualAdjacencyP1 (5)}; + +manualAdjacencyP2 PARAMETER +CONTEXT CREATE-INFO; +WITH SYNTAX ISO10589-ISIS.EndSystemIDs; +BEHAVIOUR manualAdjacencyP2-B BEHAVIOUR +DEFINED AS The value to be given to the endSys +temIDs attribute on MO creation;; +REGISTERED AS {ISO10589-ISIS.proi +manualAdjacencyP2 (6)}; + +successResponse PARAMETER +CONTEXT ACTION-REPLY; +WITH SYNTAX ISO10589-ISIS.ResponseCode; +BEHAVIOUR successResponse-B BEHAVIOUR +DEFINED AS Returned in the responseCode field of +an ActionReply when the action has completed suc +cessfully.;; +REGISTERED AS {ISO10589-ISIS.proi successResponse +(7)}; + +failureResponse PARAMETER +CONTEXT ACTION-REPLY; +WITH SYNTAX ISO10589-ISIS.ResponseCode; + +BEHAVIOUR failureResponse-B BEHAVIOUR +DEFINED AS Returned in the responseCode field of +an ActionReply when the action failed to complete. +The failureReason parameter is returned with this re +sponseCode, giving additional information;; +REGISTERED AS {ISO10589-ISIS.proi failureResponse +(8)}; + +failureReason PARAMETER +CONTEXT ACTION-REPLY; +WITH SYNTAX ISO10589-ISIS.ActionFailureReason; +BEHAVIOUR failureReason-B BEHAVIOUR +DEFINED AS Gives the reason why an entity failed to +activate or deactivate.;; +REGISTERED AS {ISO10589-ISIS.proi failureReason +(9)}; + +constraintViolation PARAMETER +CONTEXT SPECIFIC-ERROR; +WITH SYNTAX +ISO10589-ISIS.ConstraintViolationReason; +BEHAVIOUR constraintViolation-B BEHAVIOUR +DEFINED AS The specific error returned on failure of +a REPLACE operation when the MO prohibits such +operations under certain conditions, for example +while the MO is in the disabled operational state.;; +REGISTERED AS {ISO10589-ISIS.proi +constraintViolation (10)}; + +notificationReceivingAdjacency PARAMETER +CONTEXT EVENT-INFO; +WITH SYNTAX +ISO10589-ISIS.LocalDistinguishedName; +BEHAVIOUR notificationReceivingAdjacency-B +BEHAVIOUR +DEFINED AS The local managed object name of the +adjacency upon which the NPDU was received;; +REGISTERED AS {ISO10589-ISIS.proi +notificationReceivingAdjacency (11)}; + +notificationIDLength PARAMETER +CONTEXT EVENT-INFO; +WITH SYNTAX ISO10589-ISIS.IDLength; +BEHAVIOUR notificationIDLength-B BEHAVIOUR +DEFINED AS The IDLength specified in the ignored +PDU;; +REGISTERED AS {ISO10589-ISIS.proi +notificationIDLength (12)}; + +notificationAreaAddress PARAMETER +CONTEXT EVENT-INFO; +WITH SYNTAX ISO10589-ISIS.AreaAddress; +BEHAVIOUR notificationAreaAddress-B BEHAVIOUR +DEFINED AS The Area Address which caused Maxi +mumAreaAddresses to be exceeded;; +REGISTERED AS {ISO10589-ISIS.proi +notificationAreaAddress (13)}; + +notificationSourceID PARAMETER +CONTEXT EVENT-INFO; +WITH SYNTAX ISO10589-ISIS.SourceID; + +BEHAVIOUR notificationSourceID-B BEHAVIOUR +DEFINED AS The source ID of the LSP;; +REGISTERED AS {ISO10589-ISIS.proi +notificationSourceID (14)}; + +notificationVirtualLinkChange PARAMETER +CONTEXT EVENT-INFO; +WITH SYNTAX ISO10589-ISIS.VirtualLinkChange; +BEHAVIOUR notificationVirtualLinkChange-B +BEHAVIOUR +DEFINED AS This indicates whether the event was +genrated as a result of the creation or deletion of a +Virtual Link between two Level 2 Intermediate Sys +tems.;; +REGISTERED AS {ISO10589-ISIS.proi +notificationVirtualLinkChange (15)}; + +notificationVirtualLinkAddress PARAMETER +CONTEXT EVENT-INFO; +WITH SYNTAX ISO10589-ISIS.NetworkEntityTitle; +BEHAVIOUR notificationVirtualLinkAddress-B +BEHAVIOUR +DEFINED AS The Network Entity Title of the Level 2 +Intermediate System at the remote end of the virtual +link;; +REGISTERED AS {ISO10589-ISIS.proi +notificationVirtualLinkAddress (16)}; + +notificationNewCircuitState PARAMETER +CONTEXT EVENT-INFO; +WITH SYNTAX ISO10589-ISIS.NewCircuitState; +BEHAVIOUR notificationNewCircuitState-B +BEHAVIOUR +DEFINED AS The direction of the Circuit state change +specified as the resulting state. i.e. a change from On +to Off is specified as Off;; +REGISTERED AS {ISO10589-ISIS.proi +notificationNewCircuitState (17)}; + +notificationNewAdjacencyState PARAMETER +CONTEXT EVENT-INFO; +WITH SYNTAX ISO10589-ISIS.NewAdjacencyState; +BEHAVIOUR notificationNewAdjacencyState-B +BEHAVIOUR +DEFINED AS The direction of the Adjacency state +change specified as the resulting state. i.e. a change +from Up to Down is specified as Down. Any state +other than Up is considered to be Down.;; +REGISTERED AS {ISO10589-ISIS.proi +notificationNewAdjacencyState (18)}; + +notificationAdjacentSystem PARAMETER +CONTEXT EVENT-INFO; +WITH SYNTAX ISO10589-ISIS.SystemID; +BEHAVIOUR notificationAdjacentSystem-B +BEHAVIOUR +DEFINED AS The system ID of the adjacent system;; +REGISTERED AS {ISO10589-ISIS.proi +notificationAdjacentSystem (19)}; + +notificationReason PARAMETER +CONTEXT EVENT-INFO; +WITH SYNTAX ISO10589-ISIS.Reason; + +BEHAVIOUR notificationReason-B BEHAVIOUR +DEFINED AS The associated Reason;; +REGISTERED AS {ISO10589-ISIS.proi +notificationReason (20)}; + +notificationPDUHeader PARAMETER +CONTEXT EVENT-INFO; +WITH SYNTAX ISO10589-ISIS.PDUHeader; +BEHAVIOUR notificationPDUHeader-B BEHAVIOUR +DEFINED AS The header of the PDU which caused +the notification;; +REGISTERED AS {ISO10589-ISIS.proi +notificationPDUHeader (21)}; + +notificationCalledAddress PARAMETER +CONTEXT EVENT-INFO; +WITH SYNTAX ISO10589-ISIS.SNPAAddress; +BEHAVIOUR notificationCalledAddres-B +BEHAVIOUR +DEFINED AS The SNPA Address which was being +called when the Adjacency was taken down as a re +sult of a call reject;; +REGISTERED AS {ISO10589-ISIS.proi +notificationCalledAddress (22)}; + +notificationVersion PARAMETER +CONTEXT EVENT-INFO; +WITH SYNTAX ISO10589-ISIS.Version; +BEHAVIOUR notificationVersion-B BEHAVIOUR +DEFINED AS The version number reported by the +other system;; +REGISTERED AS {ISO10589-ISIS.proi +notificationVersion (23)}; + +notificationDesignatedIntermediateSystemChange +PARAMETER +CONTEXT EVENT-INFO; +WITH SYNTAX ISO10589-ISIS.DesignatedISChange; +BEHAVIOUR +notificationDesignatedIntermediateSystemChange-B +BEHAVIOUR +DEFINED AS The direction of the change in Desig +nated Intermediate System status of this system;; +REGISTERED AS {ISO10589-ISIS.proi +notificationDesignatedIntermediateSystemChange +(24)}; + +notificationOverloadStateChange PARAMETER +CONTEXT EVENT-INFO; +WITH SYNTAX ISO10589-ISIS.OverloadStateChange; +BEHAVIOUR notificationOverloadStateChange-B +BEHAVIOUR +DEFINED AS The direction of the change in Overload +status;; +REGISTERED AS {ISO10589-ISIS.proi +notificationOverloadStateChange (25)}; + +11.2.15 Attribute Groups +counters ATTRIBUTE GROUP +DESCRIPTION The group of all counters; +REGISTERED AS {ISO10589-ISIS.agoi counters (1)}; + + +11.2.16 Behaviour Definitions +resettingTimer-B BEHAVIOUR +DEFINED AS This attribute specifies the interval be +tween certain events in the operation of the protocol +state machine. If the value of this attribute is +changed to a new value t while the protocol state +machine is in operation, the implementation shall +take the necessary steps to ensure that for any time +interval which was in progress when the correspond +ing attribute was changed, the next expiration of the +that interval takes place t seconds from the original +start of that interval, or immediately, whichever is +later. The precision with which this time shall be im +plemented shall be the same as that associated with +the basic operation of the timer attribute; + +replaceOnlyWhileDisabled-B BEHAVIOUR +DEFINED AS This attribute shall only permit the RE +PLACE operation to be performed on it while the +MO is in the Disabled Operational State. An at +tempt to perform a REPLACE operation while the +MO is in the Enabled Operation State shall fail with +the generation of the constraintViolation specific er +ror.; + +resourceLimiting-B BEHAVIOUR +DEFINED AS This attribute places limits on some re +source". In general implementations may allocate +reources up to this limit when the managed object is +enabled and it may be impossible to change the allo +cation without first disabling and re-enabling the +managed object. Therefore this International Stan +dard only requires that it shall be possible to perform +a REPLACE operation on this attribute while the +MO is disabled. However some implementations +may be able to to change the allocation of resources +without first disabling the MO. In this case it is per +mitted to increase the value of the atribute at any +time, but it shall not be decreased below the cur +rently used" value of the resource. Where an at +tempt to perform a REPLACE operation fails either +because the MO is enabled, or because an attempt +has been made to decrease the value, the REPLACE +operation shall fail with the generation of the con +straintViolation specific error.; +11.2.17 ASN1 Modules +ISO10589-ISIS{tbd1} +DEFINITIONS ::= BEGIN +-- object identifier definitions +sc6 OBJECT IDENTIFIER ::= {joint-iso-ccitt sc6(?)} +-- value to be assigned by SC21 secretariat +isisoi OBJECT IDENTIFIER ::= {sc6 iSO10589(?)} +-- value to be assigned by SC6 secretariat +moi OBJECT IDENTIFIER ::= {isisoi objectClass (3)} +poi OBJECT IDENTIFIER ::= {isisoi package (4)} +proi OBJECT IDENTIFIER ::= {isisoi parameter (5)} +nboi OBJECT IDENTIFIER ::= {isisoi nameBinding (6)} +aoi OBJECT IDENTIFIER ::= {isisoi attribute (7)} +agoi OBJECT IDENTIFIER ::= {isisoi attributeGroup +(8)} +acoi OBJECT IDENTIFIER ::= {isisoi action (10)} +noi OBJECT IDENTIFIER ::= {isisoi notification (11)} + + +ActionFailureReason ::= ENUMERATED{ +reason1(0), +reason2(1)} +-- Note: actual reasons TBS +ActionInfo ::= SET OF Parameter +ActionReply ::= SEQUENCE{ +responseCode OBJECT IDENTIFIER, +responseArgs SET OF Parameter OPTIONAL} +AddressPrefix ::= OCTETSTRING(SIZE(0..20)) +AdjacencyState ::= ENUMERATED{ +initializing(0), +up(1), +failed(2)}-- was 4 in N5821 , is it required at all? +AreaAddress ::= OCTETSTRING(SIZE(1..20)) +AreaAddresses ::= SET OF AreaAddress +Boolean ::= BOOLEAN +CircuitID ::= OCTETSTRING(SIZE(1..10)) +CompleteSNPInterval ::= INTEGER(1..600) +ConstraintViolationReason ::= OBJECT IDENTIFIER; +DRISISHelloTimer ::= INTEGER(1..65535) +DatabaseState ::= ENUMERATED{ +off(0), +on(1), +waiting(2)} +DesignatedISChange ::= ENUMERATED{ +resigned(0), +elected(1)} +DefaultESHelloTimer ::= INTEGER(1..65535) +EndSystemIDs ::= SET OF SystemID +GraphicString ::= GRAPHICSTRING +HelloTimer ::= INTEGER(1..65535) +HoldingTimer ::= INTEGER(1..65535) +HopMetric ::= INTEGER(0..63) +ISISHelloTimer ::= INTEGER(1..65535) +IDLength ::= INTEGER(0..9) +IdleTimer ::= INTEGER(1..65535) +InitialMinimumTimer ::= INTEGER(1..65535) +IntermediateSystemPriority ::= INTEGER(1..127) +ISType ::= ENUMERATED{ +level1IS(1), +level2IS(2)} +LANAddress ::= OCTETSTRING(SIZE(6)) +AdjacencyUsageType::= ENUMERATED{ +undefined(0), +level1(1), +level2(2), +level1and2(3)} +LocalDistinguishedName ::= CMIP-1.ObjectInstance +-- A suitable free standing definition is requred +LSPID ::= OCTETSTRING(SIZE(2..11)) +MappingType ::= ENUMERATED{ +manual(0), +x121(1)} +MaximumBuffers ::= INTEGER(1..65535) +MaximumCallAttempts ::= INTEGER(1..65535) +MaximumLSPGenerationInterval ::= INTEGER(1..65535) +MaximumPathSplits ::= INTEGER(1..32) +MaximumSVCAdjacencies ::= INTEGER(1..65535) +MaximumVirtualAdjacencies ::= INTEGER(0..32) +MetricIncrement ::= INTEGER(0..63) +MetricType ::= ENUMERATED{ +internal(0), +external(1)} +MinimumBroadcastLSPTransmissionInterval ::= +INTEGER(1..65535) +MinimumLSPGenerationInterval ::= INTEGER(1..65535) +MinimumLSPTransmissionInterval ::= + +INTEGER(1..65535) +NeighbourSystemType ::= ENUMERATED{ +unknown(0), +endSystem(1), +intermediateSystem(2), +l1IntermediateSystem(3), +l2IntermediateSystem(4)} +NetworkEntityTitle ::= OCTETSTRING(SIZE(1..19)) +NewAdjacencyState ::= ENUMERATED{ +down(0), +up(1)} +NewCircuitState ::= ENUMERATED{ +off(0), +on(1)} +NonWrappingCounter ::= INTEGER(0..264-1) +NotificationInfo ::= SET OF Parameter +NSAPAddress ::= OCTETSTRING(SIZE(1..20)) +OctetString ::= OCTETSTRING +OriginatingLSPBufferSize ::= INTEGER(512..1492) +OutputAdjacencies ::= SET OF LocalDistinguishedName +OverloadStateChange ::= ENUMERATED{ +on(0), +waiting(1)} +Parameter ::= SEQUENCE{ +paramIdOBJECT IDENTIFIER, +paramInfoANY DEFINED BY paramID} +PartialSNPInterval ::= INTEGER(1..65535) +Password ::= OCTETSTRING(SIZE(0..254) +Passwords ::= SET OF Password +PathMetric ::= INTEGER(0..1023) +PDUHeader ::= OCTETSTRING(SIZE(0..255)) +PollESHelloRate ::= INTEGER(1..65535) +Reason ::= ENUMERATED{ +holdingTimerExpired(0), +checksumError(1), +oneWayConnectivity(2), +callRejected(3), +reserveTimerExpired(4), +circuitDisabled(5), +versionSkew(6), +areaMismatch(7), +maximumBroadcastIntermediateSystemsExceeded(8), +maximumBroadcastEndSystemsExceeded(9), +wrongSystemType(10)} +ResponseCode ::= OBJECT IDENTIFIER +RecallTimer ::= INTEGER(1..65535) +ReserveTimer ::= INTEGER(1..65535) +SNPAAddress ::= +NUMERICSTRING(FROM("0"|"1"|"2"|"3"|"4"|"5"| +"6"|"7"|"8"|"9"))(SIZE(0..15)) +-- Up to 15 Digits 0..9 +SNPAAddresses ::= SET OF SNPAAddress +CircuitType ::= ENUMERATED{ +broadcast(0), +ptToPt(1), +staticIN(2), +staticOut(3), +dA(4)} +SourceID ::= OCTETSTRING(SIZE(1..10)) +SystemID ::= OCTETSTRING(SIZE(0..9)) +VirtualLinkChange ::= ENUMERATED{ +deleted(0), +created(1)} +Version ::= GRAPHICSTRING +WaitingTime ::= INTEGER(1..65535) +maximumPathSplits-Default INTEGER ::= 2 +MaximumPathSplits-Permitted ::= INTEGER(1..32) + +maximumBuffers-Default INTEGER ::= ImpSpecific +MaximumBuffers-Permitted ::= INTEGER(1..ImpSpecific) +minimumLSPTransmissionInterval-Default INTEGER ::= +5 +MinimumLSPTransmissionInterval-Permitted ::= +INTEGER(5..30) +maximumLSPGenerationInterval-Default INTEGER ::= +900 +MaximumLSPGenerationInterval-Permitted ::= +INTEGER(60..900) +minimumBroadcastLSPTransmissionInterval-Default +INTEGER ::=33 +MinimumBroadcastLSPTransmissionInterval-Permitted ::= +INTEGER(1..65535) +completeSNPInterval-Default INTEGER ::= 10 +CompleteSNPInterval-Permitted ::= INTEGER(1..600) +originatingL1LSPBufferSize-Default INTEGER ::= +receiveLSPBufferSize +OriginatingL1LSPBufferSize-Permitted ::= +INTEGER(512..receiveLSPBufferSize) +manualAreaAddresses-Default AreaAddresses ::= {} +ManualAreaAddresses-Permitted ::= AreaAddresses +(SIZE(0..MaximumAreaAddresses)) +minimumLSPGenerationInterval-Default INTEGER ::= 30 +MinimumLSPGenerationInterval-Permitted ::= +INTEGER(5..300) +defaultESHelloTime-Default INTEGER ::= 600 +DefaultESHelloTime-Permitted ::= INTEGER(1..65535) +pollESHelloRate-Default INTEGER ::= 50 +PollESHelloRate-Permitted ::= INTEGER(1..65535) +partialSNPInterval-Default INTEGER ::= 2 +PartialSNPInterval-Permitted ::= INTEGER(1..65535) +waitingTime-Default INTEGER ::= 60 +WaitingTime-Permitted ::= INTEGER(1..65535) +dRISISHelloTimer-Default INTEGER ::= 1 +DRISISHelloTimer-Permitted ::= INTEGER(1..65535) +originatingL2LSPBufferSize-Default INTEGER ::= +receiveLSPBufferSize +OriginatingL2LSPBufferSize-Permitted ::= +INTEGER(512..receiveLSPBufferSize) +maximumVirtualAdjacencies-Default INTEGER ::= 2 +MaximumVirtualAdjacencies-Permitted ::= +INTEGER(0..32) +helloTimer-Default INTEGER ::= 10 +HelloTimer-Permitted ::= INTEGER(1..21845) +defaultMetric-Default INTEGER ::= 20 +DefaultMetric-Permitted ::= INTEGER(1..MaxLinkMetric) +optionalMetric-Default INTEGER ::= 0 +OptionalMetric-Permitted ::= +INTEGER(0..MaxLinkMetric) +metricType-Default MetricType ::= Internal +iSISHelloTimer-Default INTEGER ::= 3 +ISISHelloTimer-Permitted ::= INTEGER(1..21845) +externalDomain-Default BOOLEAN ::= TRUE +l1IntermediateSystemPriority-Default INTEGER ::= 64 +L1IntermediateSystemPriority-Permitted ::= +INTEGER(1..127) +callEstablishmentMetricIncrement-Default INTEGER ::= 0 +CallEstablishmentMetricIncrement-Permitted ::= +INTEGER(0..MaxLinkMetric) +idleTimer-Default INTEGER ::= 30 +IdleTimer-Permitted ::= INTEGER(0..65535) +initialMinimumTimer-Default INTEGER ::= 55 +InitialMinimumTimer-Permitted ::= INTEGER(1..65535) +reserveTimer-Default INTEGER ::= 600 +ReserveTimer-Permitted ::= INTEGER(1..65535) +maximumSVCAdjacencies-Default INTEGER ::= 1 + +MaximumSVCAdjacencies-Permitted ::= +INTEGER(1..65535) +reservedAdjacency-Default BOOLEAN ::= FALSE +neighbourSNPAAddress-Default INTEGER ::= 0 +recallTimer-Default INTEGER ::= 60 +RecallTimer-Permitted ::= INTEGER(0..65535) +maximumCallAttempts-Default INTEGER ::= 10 +MaximumCallAttempts-Permitted ::= INTEGER(0..255) +manualL2OnlyMode-Default BOOLEAN ::= FALSE +l2IntermediateSystemPriority-Default INTEGER ::= 64 +L2IntermediateSystemPriority-Permitted ::= +INTEGER(1..127) +lANAddress-Default LANAddress ::= 000000000000 +sNPAAddresses-Default SNPAAddresses::= {} +password-Default Password ::= {} +passwords-Default Passwords ::= {} -- The empty set +END + +12 Conformance +12.1 Static Conformance Requirements +12.1.1 Protocol Implementation Conformance +Statement +A Protocol Implementation Conformance Statement (PICS) +shall be completed in respect of any claim for conformance +of an implementation to this International Standard: the +PICS shall be produced in accordance with the relevant +PICS pro-forma in Annex A. +12.1.2 Static Conformance for all ISs +A system claiming conformance to this International Stan +dard shall be capable of: +a)calculating a single minimum cost route to each desti +nation according to 7.2.6 for the default metric speci +fied in 7.2.2; +b)utilising Link State information from a system only +when an LSP with LSP number 0 and remaining life +time>0 is present according to 7.2.5; +c)removing excess paths according to 7.2.7 +d)performing the robustness checks according to 7.2.8; +e)constructing a forwarding database according to 7.2.9; +f)if (and only if) Area Partition Repair is supported, +1)performing the operations according to 7.2.10; +2)performing the encapsulation operations in the for +warding process according to 7.4.3.2; and +3)performing the decapsulation operations in the re +ceive process according to 7.4.4; +TEMPORARY NOTE may need to reor +ganise clause 7.4.4 in order to make it crystal +clear what is required in the receive process in +the presence/absence of partition repair +g)computing area addresses according to 7.2.11; +h)generating local Link State information as required by +7.3.2; +i)including information from Manual Adjacencies ac +cording to 7.3.3.1; +j)if (and only if) Reachable Addresses are supported, in +cluding information from Reachable Addresses ac +cording to 7.3.3.2; +k)generating multiple LSPs according to 7.3.4; +l)generating LSPs periodically according to 7.3.5; +m)generating LSPs on the occurrence of events accord +ing to 7.3.6; + +n)generating an LSP checksum according to 7.3.11; +o)operating the Update Process according to 7.3.12 +7.3.17 including controlling the rate of LSP transmis +sion only for each broadcast circuit (if any) according +to 7.3.15.6; +p)operating the LSP database overload procedures ac +cording to 7.3.19.1; +q)selecting the appropriate forwarding database accord +ing to 7.4.2; +r)forwarding ISO 8473 PDUs according to 7.4.3.1 and +7.4.3.3; +s)operating the receive process according to 7.4.4; +TEMPORARY NOTE item 1 of the second bulleted +list is only required if you implement partition repair. +We need to reorganise the structure so we can pull +this out. +t)performing on each supported Point-to-Point circuit (if +any): +1)forming and maintaining adjacencies according to +8.2; +u)performing on each supported ISO 8208 circuit (if +any) +1)SVC establishment according to 8.3.2.1 using the +network layer protocols according to 8.3.1; +2)If Reachable Addresses are supported, the opera +tions specified in 8.3.2.2 8.3.5.6. +3)If call + +Estab + +lish + +ment + +Met + +ricIncrement greater +than zero are supported, the operations specified in +8.3.5.3. +4)If the Reverse Path Cache is supported, the opera +tions specified in 8.3.3 +v)performing on each supported broadcast circuit (if +any) +1)the pseudonode operations according to 7.2.3; +2)controlling the rate of LSP transmission according +to 7.3.15.6; +3)the operations specified in 8.4.18.4.4 and 8.4.6; +4)the operations specified in 8.4.5. +w)constructing and correctly parsing all PDUs according +to clause 9; +x)providing a system environment in accordance with +clause 10; +y)being managed via the system management attributes +defined in clause 11. For all attributes referenced inthe +normative text, the default value (if any) shall be sup +ported. Other values shall be supported if referenced +in a REQUIRED VALUES clause of the GDMO +definition; + +z)If authentication procedures are implemented: +1)the authentication field processing functions of +clauses 7.3.77.3.10, 7.3.15.17.3.15.4, 8.2.3 +8.2.4, and 8.4.1.1; +2)the Authentication Information field of the +PDU in clauses 9.59.13. +12.1.3 Static Conformance Requirements for +level 1 ISs +A system claiming conformance to this International Stan +dard as a level 1 IS shall conform to the requirements of +12.1.2 and in addition shall be capable of +a)identifying the nearest Level 2 IS according to 7.2.9.1; +b)generating Level 1 LSPs according to 7.3.7; +c)generating Level 1 pseudonode LSPs for each sup +ported broadcast circuit (if any) according to 7.3.8; +d)performing the actions in Level 1 Waiting State ac +cording to 7.3.19.2 +12.1.4 Static Conformance Requirements for +level 2 ISs +A system claiming conformance to this International Stan +dard as a level 2 IS shall conform to the requirements of +12.1.2 and in addition shall be capable of +a)setting the attached flag according to 7.2.9.2; +b)generating Level 2 LSPs according to 7.3.9; +c)generating Level 2 pseudonode LSPs for each sup +ported broadcast circuit (if any) according to 7.3.10; +d)performing the actions in Level 2 Waiting State ac +cording to 7.3.19.3. +12.2 Dynamic Conformance +12.2.1 Receive Process Conformance +Requirements +Any protocol function supported shall be implemented in +accordance with 7.4.4. +12.2.2 Update Process Conformance +Requirements +Any protocol function supported shall be implemented in +accordance with 7.3 and its subclauses. +Any PDU transmitted shall be constructed in accordance +with the appropriate subclauses of 9. + +12.2.3 Decision Process Conformance +Requirements +Any protocol function supported shall be implemented in +accordance with 7.2 and its subclauses. +12.2.4 Forwarding Process Conformance +Requirements +Any protocol function supported shall be implemented in +accordance with 7.4 and its subclauses. +12.2.5 Performance Requirements +This International Standard requires that the following per +formance criteria be met. These requirements apply regard +less of other demands on the system; if an Intermediate sys +tem has other tasks as well, those will only get resources +not required to meet these criteria. +Each Intermediate system implementation shall specify (in +its PICS): +a)the maximum number of other Intermediate systems it +can handle. (For L1 Intermediate systems that means +Intermediate systems in the area; for L2 Intermediate +systems that is the sum of Intermediate systems in the +area and Intermediate systems in the L2 subdomain.) +Call this limit N. +b)the maximum supported forwarding rate in ISO 8473 +PDUs per second. +12.2.5.1 Performance requirements on the Update +process +The implementation shall guarantee the update process +enough resources to process N LSPs per 30 seconds. (Re +sources = CPU, memory, buffers, etc.) +In a stable topology the arrival of a single new LSP on a +circuit shall result in the propagation of that new LSP over +the other circuits of the IS within one second, irrespective +of the forwarding load for ISO 8473 data PDUs. +12.2.5.2 Performance requirement on the Decision +process +The implementation shall guarantee the decision process +enough resources to complete (i.e. start to finish) within 5 +seconds, in a stable topology while forwarding at the maxi +mum rate. (For L2 Intermediate Systems, this applies to the +two levels together, not each level separately.) +12.2.5.3 Reception and Processing of PDUs +An ideal Intermediate system would be able to correctly +process all PDUs, both control and data, with which it was +presented, while simultaneously running the decision proc +ess and responding to management requests. However, in +the implementations of real Intermediate systems some +compromises must be made. The way in which these com +promises are made can dramatically affect the correctness + +of operation of the Intermediate system. The following gen +eral principles apply. +a)A stable topology should result in stable routes when +forwarding at the maximum rated forwarding rate. +b)Some forwarding progress should always be made (al +beit over incorrect routes) even in the presence of a +maximally unstable topology. +In order to further characterise the required behaviour, it is +necessary to identify the following types of traffic. +a)IIH traffic. This traffic is important for maintaining In +termediate system adjacencies and hence the Interme +diate system topology. In order to prevent gratuitous +topology changes it is essential that Intermediate sys +tem adjacencies are not caused to go down errone +ously. In order to achieve this no more than +ISISHoldingMultiplier - 1 IIH PDUs may be +dropped between any pair of Intermediate systems. A +safer requirement is that no IIH PDUs are dropped. +The rate of arrival of IIH PDUs is approximately con +stant and is limited on Pointto-Point links to 1/iSIS + + +Hello + +Timer and on LANs to a value of approxi +mately 2(n/iSIS + +Hello + +Timer) + 2, where n is the +number of Intermediate systems on the LAN (assum +ing the worst case that they are all Level 2 Intermedi +ate systems). +b)ESH PDU traffic. This traffic is important for main +taining End system adjacencies, and has relatively low +processing latency. As with IIH PDUs, loss of End +system adjacencies will cause gratuitous topology +changes which will result in extra control traffic. +The rate of arrival of ESH PDUs on Pointto-Point +links is limited to approximately 1/Default + +ES + +Hello + + +Timer under all conditions. On LANs the background +rate is approximately n/DefaultESHelloTimer +where n is the number of End systems on the LAN. +The maximum rate during polling is limited to ap +proximately n/pollESHelloRate averaged over a pe +riod of about 2 minutes. (Note that the actual peak ar +rival rate over a small interval may be much higher +than this.) +c)LSP (and SNP) traffic. This traffic will be +retransmitted indefinitely by the update process if it is +dropped, so there is no requirement to be able to proc +ess every received PDU. However, if a substantial +proportion are lost, the rate of convergence to correct +routes will be affected, and bandwidth and processing +power will be wasted. +On Point-to-Point links the peak rate of arrival is lim +ited only by the speed of the data link and the other +traffic flowing on that link. The maximum average +rate is determined by the topology. +On LANs the rate is limited at a first approximation to +a maximum rate of 1000/min + +i + +mum + +Broad + +cast + +LSP + + +Trans + +mis + +sion + +Int + +er + +val, however it is possible that +this may be multiplied by a factor of up to n, where n +is the number of Intermediate systems on the LAN, for + +short periods. A Intermediate system shall be able to +receive and process at least the former rate without +loss, even if presented with LSPs at the higher rate. +(i.e. it is permitted to drop LSPs, but must process at +least 1000/min + +i + +mum + +Broad + +cast + +LSP + +Trans + +mis + +sion + + +Int + +er + +val per second of those presented.) +The maximum background rate of LSP traffic (for a +stable topology) is dependent on the maximum sup +ported configuration size and the settings of +maximumLSPGenerationInterval. For these pur +poses the default value of 900 seconds can be as +sumed. The number of LSPs per second is then very +approximately (n1 + n2 +ne/x)/900 where n1 is the +number of level 1 Intermediate systems, n2 the num +ber of level 2 Intermediate systems, ne the number of +End system IDs and x the number of ID which can be +fitted into a single LSP. +NOTE This gives a value around 1 per second for +typical maximum configurations of: +4000 IDs +100 L1 Intermediate systems per area +400 L2 Intermediate systems. +d)Data Traffic. This is theoretically unlimited and can +arrive at the maximum data rate of the Pointto-Point +link or LAN (for ISO 8802.3 this is 14,000 PDUs per +second). In practice it will be limited by the operation +of the congestion avoidance and control algorithms, +but owing to the relatively slow response time of these +algorithms, substantial peaks are likely to occur. +An Intermediate system shall state in its PICS its +maximum forwarding rate. This shall be quoted under +at least the following conditions. +1)A stable topology of maximum size. +2)A maximally unstable topology. This figure shall +be non-zero, but may reasonably be as low as 1 +PDU per second. +The following constraints must be met. +a)The implementation shall be capable of receiving the +maximum rate of ISH PDUs without loss whenever +the following conditions hold +1)The data forwarding traffic rate averaged over any +period of one second does not exceed the rate +which the implementation claims to support +2)The ESH and LSP rates do not exceed the back +ground (stable topology) rate. +b)If it is unavoidable that PDUs are dropped, it is a goal +that the order of retaining PDUs shall be as follows +(i.e. It is least desirable for IIH PDUs to be dropped). +1)IIH PDUs +2)ESH PDUs +3)LSPs and SNPs +4)data PDUs. + +However, no class of traffic shall be completely +starved. One way to achieve this is to allocate a queue +of suitable length to each class of traffic and place the +PDUs onto the appropriate queue as they arrive. If the +queue is full the PDUs are discarded. Processor re +sources shall be allocated to the queues to ensure that +they all make progress with the same priorities as +above. This model assumes that an implementation is +capable of receiving PDUs and selecting their correct +queue at the maximum possible data rate (14,000 +PDUs per second for a LAN). If this is not the case, +reception of data traffic at a rate greater than some +limit (which must be greater than the maximum rated +limit) will cause loss of some IIH PDUs even in a sta +ble topology. This limit shall be quoted in the PICS if +it exists. +NOTE - Starting from the stable topology condition at maxi +mum data forwarding rate, an increase in the arrival rate of +data PDUs will initially only cause some data NPDUs to be +lost. As the rate of arrival of data NPDUs is further in +creased a point may be reached at which random PDUs are +dropped. This is the rate which must be quoted in the PICS +12.2.5.4 Transmission +Sufficient processor resources shall be allocated to the +transmission process to enable it to keep pace with recep +tion for each PDU type. Where prioritisation is required, the +same order as for reception of PDU types applies. + + +Annex A +PICS Proforma +(This annex is normative) + +A.1 Introduction +The supplier of a protocol implementation which is claimed +to conform to International Standard ISO 10589, whether as +a level 1 or level 2 Intermediate system implementation, +shall complete the applicable Protocol Implementation +Conformance Statement (PICS) proforma. +A completed PICS proforma is the PICS for the implemen +tation in question. The PICS is a statement of which capa +bilities and options of the protocol have been implemented. +The PICS can have a number of uses, including use: +-by the protocol implementor, as a check-list to reduce +the risk of failure to conform to the standard through +oversight; +-by the supplier and acquirer or potential acquirer + of the implementation, as a detailed indication of +the capabilities of the implementation, stated relative +to the common basis for understanding provided by +the standard PICS proforma; +-by the user or potential user of the implementa +tion, as a basis for initially checking the possibility of +interworking with another implementation (note that, +while interworking can never be guaranteed, failure to +interwork can often be predicted from incompatible +PICS's); +-by a protocol tester, as the basis for selecting appropri +ate tests against which to assess the claim for +conformance of the implementation. +A.2 Abbreviations and Special Symbols +A.2.1 Status-related symbols +M mandatory +O optional +O. optional, but support of at least one of the +group of options labelled by the same numeral + is required. +X prohibited + not applicable +c.

conditional requirement, according to condi +tion

+ + +A.3 Instructions for Completing the +PICS Proformas +A.3.1 General structure of the PICS proforma +The first part of the PICS proforma Implementation +Identification and Protocol Summary is to be completed +as indicated with the information necessary to identify fully +both the supplier and the implementation. +The main part of the PICS proforma is a fixed-format ques +tionnaire divided into subclauses each containing a group of +individual items. Answers to the questionnaire items are to +be provided in the rightmost column, either by simply +marking an answer to indicate a restricted choice (usually +Yes or No), or by entering a value or a set or range of val +ues. (Note that there are some items where two or more +choices from a set of possible answers can apply: all rele +vant choices are to be marked.) +Each item is identified by an item reference in the first col +umn; the second column contains the question to be an +swered; the third column contains the reference or refer +ences to the material that specifies the item in the main +body of the standard. the remaining columns record the +status of the item whether support is mandatory, optional +or conditional and provide the space for the answers: see +A.3.4 below. +A supplier may also provide or be required to provide +further information, categorised as either Additional Infor +mation or Exception Information. When present, each kind +of further information is to be provided in a further sub +clause of items labelled A or X respectively for +cross-referencing purposes, where is any unambiguous +identification for the item (e.g. simply a number): there are +no other restrictions on its format and presentation. +A completed PICS proforma, including any Additional In +formation and Exception Information, is the Protocol Im +plementation Conformance Statement for the implementa +tion in question. +NOTE - Where an implementation is capable of being con +figured in more than one way, a single PICS may be able to +describe all such configurations. However, the supplier has +the choice of providing more than one PICS, each covering +some subset of the implementation's configuration capabili +ties, in case this makes for easier and clearer presentation of +the information. +A.3.2 Additional Information +Items of Additional Information allow a supplier to provide +further information intended to assist the interpretation of +the PICS. It is not intended or expected that a large quantity +will be supplied, and a PICS can be considered complete + +without any such information. Examples might be an out +line of the ways in which a (single) implementation can be +set up to operate in a variety of environments and configu +rations. +References to items of Additional information may be en +tered next to any answer in the questionnaire, and may be +included in items of Exception Information. +A.3.3 Exception Information +It may occasionally happen that a supplier will wish to an +swer an item with mandatory or prohibited status (after any +conditions have been applied) in a way that conflicts with +the indicated requirement. No pre-printed answer will be +found in the Support column for this, but the Supplier may +write the desired answer into the Support column. If this is +done, the supplier is required to provide an item of Excep +tion Information containing the appropriate rationale, and a +cross-reference from the inserted answer to the Exception +item. +An implementation for which an Exception item is required +in this way does not conform to ISO 10589. +NOTE - A possible reason for the situation described above +is that a defect report is being progressed, which is expected +to change the requirement that is not met by the implemen +tation. +A.3.4 Conditional Status +A.3.4.1 Conditional items +The PICS proforma contains a number of conditional items. +These are items for which the status mandatory, optional +or prohibited that applies is dependent upon whether or +not certain other items are supported, or upon the values +supported for other items. In many cases, whether or not the +item applies at all is conditional in this way, as well as the +status when the item does apply. +Individual conditional items are indicated by a conditional +symbol in the Status column as described in A.3.4.2 below. +Where a group of items are subject to the same condition +for applicability, a separate preliminary question about the +condition appears at the head of the group, with an instruc +tion to skip to a later point in the questionnaire if the Not +Applicable answer is selected. +A.3.4.2 Conditional symbols and conditions +A conditional symbol is of the form c. or c.G where + is a numeral. For the first form, the numeral identifies +a condition appearing in a list at the end of the subclause +containing the item. For the second form, c.G, the nu +meral identifies a condition appearing in the list of global +conditions at the end of the PICS. +A simple condition is of the form:if

then else + +where

is a predicate (see A.3.4.3 below), and and + are either basic status symbols (M,O,O., or X) or + +the symbol . An extended condition is of the formif then else +else if then +[else if ...] +else + +where etc. are predicates and etc. are basic +status symbols or . +The status symbol applicable to an item governed by a sim +ple condition is if the predicate of the condition is +true, and otherwise; the status symbol applicable to an +item governed by an extended condition is where +is the first true predicate, if any, in the sequence , +..., and if no predicate is true. +A.3.4.3 Predicates +A simple predicate in a condition is either +a)a single item reference; or +b)a relation containing a comparison operator (=, <, etc.) +with one (or both) of its operands being an item refer +ence for an item taking numerical values as its answer. +In case (a) the predicate is true if the item referred to is +marked as supported, and false otherwise. In case (b), the +predicate is true if the relation holds when each item refer +ence is replaced by the value entered in the Support column +as answer to the item referred to. +Compound predicates are boolean expressions constructed +by combining simple predicates using the boolean operators +AND, OR and NOT, and parentheses, in the usual way. A +compound predicate is true if and only if the boolean ex +pression evaluates to true when the simple predicates are in +terpreted as described above. +Items whose references are used in predicates are indicated +by an asterisk in the Item column. +A.3.4.4 Answering conditional items +To answer a conditional item, the predicate(s) of the condi +tion is (are) evaluated as described in A.3.4.3 above, and +the applicable status symbol is determined as described in +A.3.4.2. If the status symbol is this indicates that the +item is to be marked in this case; otherwise, the Support +column is to be completed in the usual way. +When two or more basic status symbols appear in a condi +tion for an item, the Support column for the item contains +one line for each such symbol, labelled by the relevant sym +bol. the answer for the item is to be marked in the line la +belled by the symbol selected according to the value of the +condition (unselected lines may be crossed out for added +clarity). +For example, in the item illustrated below, the N/A column +would be marked if neither predicate were true; the answer + +line labelled M: would be marked if item A4 was marked as supported, +and the answer line labelled O: would be marked if +the condition including items D1 and B52 applied.Item + +References +Status +N/A +Support +H3 +Is ... supported? +42.3(d) +C.1 + +M: Yes +O: Yes No +C.1if A4 then M +else if D1 AND (B52 < 3) then O else + + +A.4 Identification +A.4.1 Implementation IdentificationSupplierContact point for +queriesabout this PICSImplementation Name(s)and Version(s)Operating +systemName(s and Version(s)Other Hardware and Operating +SystemsClaimedSystem Name(s)(if different)Notes: +a)Only the first three items are required for all implementations; others may be +completed as appropriate in meeting the requirements for full identification. +b)The terms Name and Version should be interpreted appropriately to correspond +with a supplier's terminology (using, e.g., Type, Series, Model) + +A.4.2 Protocol Summary: ISO 10589:19xxProtocol VersionAddenda +Implemented(if applicable)AmmendmentsImplementedDate of StatementHave +any Exception items been required (see A.3.3)? No Yes +(The answer Yes means that the implementation does not conform to ISO 10589) + + +PICS Proforma: Item + +References +Status +N/A +Support +AllIS +Are all basic ISIS routeing functions +implemented? +12.1.2 +M + +M: Yes + +C.1if L2IS then O else +C.2if 8208 then O else +PartitionRe +pair +Is Level 1 Partition Repair imple +mented? +12.1.2.f +C.1 + +O: Yes No +L1IS +Are Level 1 ISIS routeing functions +implemented? +12.1.3 +M + +M: Yes +L2IS +Are Level 2 ISIS routeing functions +implemented? +12.1.4 +O + +O: Yes No +PtPt +Are point-to-point circuits imple +mented? +12.1.2.t +O.1 + +O: Yes No +8208 +Are ISO 8208 circuits implemented? +12.1.2.u +O.1 + +O: Yes No +LAN +Are broadcast circuits implemented? +12.1.2.v +O.1 + +O: Yes No +EqualCost +Paths +Is computation of equal minimum cost +paths implemented? +7.2.6 +O + +O: Yes No +Downstream +Is computation of downstream routes +implemented? +7.2.6 +O + +O: Yes No +DelayMetric +Is path computation based on the delay +metric implemented? +7.2.2 +O + +O: Yes No +ExpenseMet +ric +Is path computation based on the Ex +pense metric implemented? +7.2.2 +O + +O: Yes No +Prefixes +Are Reachable Address Prefixes imple +mented? +12.1.2.j +C.1 + +O: Yes No +Forward + + +ingRate +How many ISO 8473 PDUs can the im +plementation forward per second? +12.2.5.1.b +M + + PDUs/sec +L2 ISCount +How many Level 2 ISs does the imple +mentation support? +12.2.5.1. +C.1 + +N = +call + +Estab + +lish + + +ment + +Met + + +ricIncrement +Are non-zero values of the call + +Estab + + +lish + +ment + +Met + +ricIncrement supported? +12.1.2.u.3 +C.2 + +O: Yes No +L1 ISCount +How many Level 1 ISs does the imple +mentation support? +12.2.5.1. +M + +N = +ReversePath +Cache +Is the 8208 Reverse Path Cache sup +ported? +12.1.2.u.4 +C.2 + +O: Yes No +ErrorMetric +Is path computation based on the Error +metric implemented? +7.2.2 +O + +O: Yes No +ISO 10589:19xx + +PICS Proforma: Item + +References +Status +N/A +Support +C.1if L2IS then O else +C.2if 8208 then O else +ID field +Length +What values of the routeingDomain + + +ID + +Length are supported by this imple +mentation? +7.1.1 +M + +Values = +Is the value Se +table by System +Man + +agement? +Yes No +PDU Authen +tication +Is PDU Authentication based on Pass +words implemented? +12.1.2.z +O + +O: Yes No +ISO 10589:19xx (continued) + +Annex B +Supporting Technical Material +(This annex is informative) + +B.1 Matching of Address Prefixes +The following example shows how address prefixes may be +matched according to the rules defined in 7.1.4. +The prefix + 37-123 +matches both the full NSAP addresses + 37-1234::AF< and + 37-123::AF< +which are encoded as + 3700000000001234AF< and + 3700000000000123AF< +respectively. +This can be achieved by first converting the address to be +compared to an internal decoded form (i.e. any padding, as +indicated by the particular AFI, is removed), which corre +sponds to the external representation of the address. The +position of the end of the IDP must be marked, since it can +no longer be deduced. This is done by inserting the semi- +octet F after the last semi-octet of the IDP. (There can be +no confusion, since the abstract syntax of the IDP is deci +mal digits). +Thus the examples above become in decoded form + 371234FAF< and + 37123FAF< + and the prefix 37-123 matches as a leading sub-string of +both of them. +For comparison purposes the prefix is converted to the in +ternal decoded form as above. +B.2 Addressing and Routeing +In order to ensure the unambiguous identification of Net +work and Transport entities across the entire OSIE, some +form of address administration is mandatory. ISO +8348/Add.2 specifies a hierarchical structure for network +addresses, with a number of top-level domains responsible +for administering addresses on a world-wide basis. These +address registration authorities in turn delegate to sub- +authorities the task of administering portions of the address +space. There is a natural tendency to repeat this sub- +division to a relatively fine level of granularity in order to +ease the task of each sub-authority, and to assign responsi +bility for addresses to the most localised administrative + +body feasible. This results in (at least in theory) reduced +costs of address administration and reduced danger of mas +sive address duplication through administrative error. Fur +thermore, political factors come into play which require the +creation of sub-authorities in order to give competing inter +ests the impression of hierarchical parity. For example at +the top level of the ISO geographic address space, every +country is assigned an equally-sized portion of the address +space even though some countries are small and might in +practice never want to undertake administration of their +own addresses. Other examples abound at lower levels of +the hierarchy, where divisions of a corporation each wish to +operate as an independent address assignment authority +even though this is inefficient operationally and may waste +monumental amounts of potential address space. +If network topologies and traffic matrices aligned naturally +with the hierarchical organisation of address administration +authorities, this profligate use of hierarchy would pose little +problem, given the large size (20 octets) of the N-address +space. Unfortunately, this is not usually the case, especially +at higher levels of the hierarchy. Network topologies may +cross address administration boundaries in many cases, for +example: +-Multi-national Corporations with a backbone network +that spans several countries +-Community-of-interest networks, such as academic or +research networks, which span organisations and ge +ographies +-Military networks, which follow treaty alignments +rather than geographic or national administrations +-Corporate networks where divisions at times operate +as part of a contractor's network, such as with trade +consortia or government procurements. +These kinds of networks also exhibit rich internal topolo +gies and large scale (105 systems), which require sophisti +cated routeing technology such as that provided by this In +ternational Standard. In order to deploy such networks ef +fectively, a considerable amount of address space must be +left over for assignment in a way which produces efficient +routes without undue consumption of memory and +bandwidth for routeing overhead11This is just a fancy way of saying +that hierarchical routing, with its natural effect on address +assignment, is a mandatory requirement for such net +works. +. +Similarly important is the inter-connection of these net +works via Inter-domain routeing technology. If all of the as +signment flexibility of the addressing scheme is exhausted +in purely administrative hierarchy (at the high-order end of +the address) and in Intra-Domain routeing assignment (at +the low end of the address) there may be little or no address + +space left to customise to the needs of inter-domain routing. +The considerations for how addresses may be structured for +the Intra- and Inter-domain cases are discussed in more de +tail in the following two clauses. +B.2.1 Address Structure for Intra-domain +Routeing +The IS-IS Intra-domain routeing protocol uses a preferred +addressing scheme. There are a number of reasons the de +signers of this protocol chose to specify a single address +structure, rather than leaving the matter entirely open to the +address assignment authorities and the routeing domain ad +ministrators: +a)If one address structure is very common and known a +priori, the forwarding functions can be made much +faster; +b)If part of the address is known to be assigned locally +to an end system, then the routeing can be simpler, use +less memory, and be potentially faster, by not having +to discriminate based on that portion of the address. +c)If part of the address can be designated as globally +unique by itself (as opposed to only the entire address +having this property) a number of benefits accrue: +1)Errors in address administration causing duplicate +addresses become much less likely +2)Automatic and dynamic NSAP address assignment +becomes feasible without global knowledge or +synchronisation +3)Routeing on this part of the address can be made +simple and fast, since no address collisions will oc +cur in the forwarding database. +d)If a part of the address can be reserved for assignment +purely on the basis of topological efficiency (as op +posed to political or address administration ease), hier +archical routeing becomes much more memory and +bandwidth efficient, since the addresses and the topol +ogy are in close correspondence. +e)If an upper bound can be placed on the amount of ad +dress space consumed by the Intra-domain routeing + +scheme, then the use of address space by Inter-domain +routeing can be made correspondingly more flexible. +The preferred address format of the Intra-domain ISIS +protocol achieves these goals by being structured into two +fixed-sized fields as follows shown in figure 91#ID#81Used by level 1 +routeingKey:Used by level 2 routeingID +SEL +HO-DSP +IDP +IDP Initial Domain Part +HO-DSP High Order Domain Specific Part +ID System Identifier +SEL NSAP Selector +Figure 9 - Preferred Address Format + + below: +The field marked IDP in the figure is precisely the IDP +specified in ISO 8348/Add.2. The field marked HO-DSP +is that portion of the DSP from ISO 8348/Add.2 whose +structure, assignment, and meaning are not specified or +constrained by the Intra-domain ISIS routeing protocol. +However, the design presumes that the routeing domain ad +ministrator has at least some flexibility in assigning a por +tion of the HO-DSP field. The purpose and usage of the +fields specified by the Intra-domain ISIS routeing protocol +is explained in the following paragraphs. +B.2.1.1 The IDP + HO-DSP +Since the Intra-domain ISIS protocol is customised for op +eration with ISO 8473, all addresses are specified to use the +preferred binary encoding of ISO 8348/Add.2. +B.2.1.2 The Selector (SEL) Field +The SEL field is intended for two purposes. Its main use is +to allow for multiple higher-layer entities in End systems +(such as multiple transport entities) for those systems which +need this capability. This allows up to 256 NSAPs in a sin +gle End system. The advantage of reserving this field exclu +sively for local system administration the Intra-domain +routing functions need not store routeing information about, +nor even look at this field. If each individual NSAP were +represented explicitly in routing tables, the size of these ta +bles would grow with the number of NSAPs, rather than +with the number of End systems. Since Intra-domain rout +ing routes to systems, explicit recording of each NSAP +brings no efficiency benefit and potentially consumes large +amounts of memory in the Intermediate systems. +A second use for the SEL field is in Intermediate systems. +Certain ISIS functions require that PDUs be encapsulated +and sent to the Network Entity in an Intermediate system +rather than to an NSAP and upward to a Transport entity. +An example of this is the Partition Repair function of this +International Standard. In order to use a level 2 path as if it +were a single subnetwork in a level 1 area, PDUs are encap + +sulated and addressed to an IS on the other side of the parti +tion11This is a gross oversimplification for the purpose of +illustrating the need for the SEL field. See 7.2.10. +. By reserving certain values of the SEL field in Inter +mediate systems for direct addressing of Intermediate sys +tem Network entities, the normal addressing and relaying +functions of other Intermediate systems can be transpar +ently used for such purposes. +B.2.1.3 The Identifier (ID) Field +The ID field is a flat, large identifier space for identifying +OSI systems. The purpose of this field is to allow very fast, +simple routeing to a large (but not unconstrained) number +of End systems in a routeing domain. The Intra-Domain IS +IS protocol uses this field for routeing within a area. While +this field is only required to be unambiguous within a single +area, if the values are chosen to be globally unambiguous +the Intra-domain ISIS design can exploit this fact in the +following ways. +First, a certain amount of parallelism can be obtained dur +ing relaying. An IS can be simultaneously processing the ID +field along with other fields (i.e. IDP, HO-DSP). If the ID +is found in the forwarding table, the IS can initiate forward +ing while checking to make sure that the other fields have +the expected value. Conversely, if the ID is not found the +IS can assume that either the addressed NSAP is unreach +able or exists only in some other area or routeing domain. +In the case where the ID is not globally unique, the for +warding table can indicate this fact and relaying delayed +until the entire address is analysed and the route looked up. +Second, a considerable savings can be obtained in manual +address administration for all systems in the routeing do +main. If the ID is chosen from the ISO 8802 48-bit address +space, the ID is known to be globally unique. Furthermore, +since LAN systems conforming to ISO 8802 often have +their 48-bit MAC address stored in ROM locally, each sys +tem can be guaranteed to have a globally unambiguous +NET and NSAP(s) without centralised address administra +tion at the area level.22Note, however, that the use of the ISO 8802 +addresses does not avoid the necessity to run ISO 9542 or to maintain +tables mapping NSAP addresses to +MAC (i.e. SNPA) addresses on the ISO 8802 subnetwork. This is because +there is no guarantee that a particular MAC address is always enabled (the LAN +controller may be turned off) or that a system has only a single MAC address. + This not only eliminates administra +tive overhead, but also drastically reduces the possibility of +duplicate NSAP addresses, which are illegal, difficult to di +agnose, and often extremely difficult to isolate. +An alternative to a large, flat space for the lowest level of +routeing would be to hierarchically subdivide this field to +allow more levels of routeing within a single routeing do +main. The designers of the Intra-domain ISIS protocol +considered that this would lead to an inferior routeing archi +tecture, since: +a)The cost of memory in the ISs was sufficiently reason +able that large (e.g. 104 system) areas were quite fea +sible, thus requiring at least 2 octets per level to ad +dress +b)Two levels of routeing within a routeing domain were +sufficient (allowing domains of 106107 systems) be +cause it was unlikely that a single organisation would +wish to operate and manage a routeing domain much +larger than that. + +c)Administrative boundaries often become the dominant +concern once routeing domains reach a certain size. +d)The additional burdens and potential for error in man +ual address assignment were deemed serious enough +to permit the use of a large, flat space. +B.3 Use of the HO-DSP field in +Intra-domain routeing +Use of a portion of the HO-DSP field provides for hierar +chical routeing within a routeing domain. A value is as +signed to a set of ISs in order to group the ISs into a single +area for the usual benefits of hierarchical routeing: +a)Limiting the size of routeing tables in the ISs; +b)conserving bandwidth by hierarchical summarisation +of routeing information; +c)designating portions of the network which are to have +optimal routeing within themselves; and +d)moderate firewalling of portions of the routeing do +main from failures in other portions. +It is important to note that the assignment of HO-DSP val +ues is intended to provide the routeing domain administra +tor with a mechanism to optimise the routeing within a +large routeing domain. The Intra-domain ISIS designers +did not intend the HO-DSP to be entirely consumed by +many levels of address registration authority. Reserving the +assignment of a portion of the HO-DSP field to the route +ing domain administrator also allows the administrator to +start with a single assigned IDP+HO-DSP and run the +routing domain as a single area. As the routeing domain +grows, the routeing domain administrator can then add ar +eas without the need to go back to the address administra +tion authority for further assignments. Areas can be added +and re-assigned within the routeing domain without involv +ing the external address administration authority. +A useful field to reserve as part of the HO-DSP would be 2 +octets,permitting up to 65,536 areas in a routeing domain. +This is viewed as a reasonable compromise between route +ing domain size and address space consumption. The field +may be specified as flat for the same reasons that the ID +field may be flat. +B.3.1 Addressing considerations for +Inter-domain Routeing +It is in the Inter-domain arena where the goals of routeing +efficiency and administrative independence collide most +strongly. Although the OSI Routeing Framework explicitly +gives priority in Inter-domain routeing to considerations of +autonomy and firewalls over efficiency, it must be feasible +to construct an Inter-Domain topology that both produces +isolable domains and relays data at acceptable cost. Since + +no routeing information is exchanged across domain +boundaries with static routeing, the practicality of a given +Inter-domain topology is essentially determined by the size +of the routeing tables that are present at the boundary ISs. If +these tables become too large, the memory needed to store +them, the processing needed to search them, and the +bandwidth needed to transmit them within the routeing do +main all combine to disallow certain forms of +interconnection. +Inter-domain routeing primarily computes routes to other +routeing domains33This International Standard also uses static +Inter-domain tables for routeing to individual End systems across +dynamically assigned circuits, and also to +End systems whose addresses do not conform to the address construction rules. +. If there is no correspondence between +the address registration hierarchy and the organisation of +routeing domains (and their interconnection) then the task +of static table maintenance quickly becomes a nightmare, +since each and every routeing domain in the OSIE would +need a table entry potentially at every boundary IS of every +other routeing domain. Luckily, there is some reason to be +lieve that a natural correspondence exists, since at least at +the global level the address registration authorities fall +within certain topological regions. For example, most of the +routeing domains which obtained their IDP+HO-DSP +from a hierarchy of French authorities are likely to reside in +France and be more strongly connected with other routeing +domains in France that with routeing domains in other +countries. +There are enough exceptions to this rule, however, to be a +cause for concern. The scenarios cited in B.2 all exist today +and may be expected to remain common for the foreseeable +future. Consider as a practical case the High Energy Phys +ics Network (HEPnet), which contains some 17000 End +systems, and an unknown number of intermediate systems44The number of +ISs is hard to estimate since some ISs and links are in fact shared +with other networks, such as the similarly organised NASA Space +Physics network, or SPAN. +. +This network operates as a single routeing domain in order +to provide a known set of services to a known community +of users, and is funded and cost-justified on this basis. This +network is international in scope (at least 10 countries in +North America, Europe, and the far east) and yet its topol +ogy does not map well onto existing national boundaries. +Connectivity is richer between CERN and FERMIlab, for +example than between many points within the U.S. +More importantly, this network has rich connectivity with a +number of other networks, including the PDNs of the vari +ous countries, the NSFnet in the U.S., the international +ESnet (Energy Sciences Network), the general research +Internet, and military networks in the U.S. and elsewhere. +None of these other networks shares a logical part of the +NSAP address hierarchy with HEPnet55It is conceivable that ISO would +sanction such networks by assigning a top-level IDI from the ISO +non-geographic AFI, but this is unlikely and would +only exacerbate the problem if many such networks were assigned +top-level registrations. + . If the only method +of routing from the HEPnet to these other networks was to +place each within one and only one of the existing registra +tion authorities, and to build static tables showing these re +lationships, the tables would clearly grow as O(n2). +It seems therefore, that some means must be available to as +sign addresses in a way that captures the Inter-Domain to +pology, and which co-exists cleanly with both the adminis +trative needs of the registration authorities, and the algo +rithms employed by both the Intra- and Inter-domain + +routeing protocols. As alluded to in an earlier clause, it +seems prudent to leave some portion of the address space +(most likely from the HO-DSP part) sufficiently undefined +and flexible that various Inter-domain topologies may be +efficiently constructed. + +Annex C +Implementation Guidelines and Examples +(This annex is informative) + +C.1 Routeing Databases +Each database contains records as defined in the following +sub-clauses. The following datatypes are defined. +FROM CommonMgmt IMPORT NSAPAddress, +AddressPrefix, BinaryAbsoluteTime; +PDU Type + +lspID = ARRAY [0..7] OF Octet; +systemID = ARRAY [0..5] OF Octet; +octetTimeStamp = BinaryAbsoluteTime; + +C.1.1 Level 1 Link State Database +This database is kept by Level 1 and Level 2 Intermediate +Systems, and consists of the latest Level 1 Link State PDUs +from each Intermediate System (or pseudonode) in the area. +The Level 1 Link State PDU lists Level 1 links to the Inter +mediate System that originally generated the Link State +PDU. +RECORD +adr: lspID; (* 8 octet ID of LSP originator +*) +type: (Level1IntermediateSystem, +AttachedLevel2IntermediateSystem, +UnattachedLevel2IntermediateSystem); +seqnum: [0..SequenceModulus 1]; +LSPage: [0..MaxAge]; (*Remaining Lifetime *) + +expirationTime: TimeStamp; +(*Time at which LSP age +became zero (see 7.3.16.4). *) +SRMflags: ARRAY[1..(maximumCircuits + +maximumVirtualAdjacencies)] +OF BOOLEAN; +(*Indicates this LSP to be sent on this circuit. Note +that level 2 Intermediate systems may send level 1 +LSPs to other partitions (if any exist). Only one level +2 Intermediate system per partition does this. For +level 1 Intermediate Systems the array is just +maximumCircuits long. *) +SSNflags: ARRAY[1..maximumCircuits + +maximumVirtualAdjacencies] +OF BOOLEAN; +(*Indicates that information about this LSP shall be +included in the next partial sequence number PDU +transmitted on this circuit. *) +POINTER TO LSP; (*The received LSP *) +END; + +C.1.2 Level 2 Link State Database +This database is kept by Level 2 Intermediate Systems, and +consists of the latest Level 2 Link State PDUs from each +Level 2 Intermediate System (or pseudonode) in the do +main. The Level 2 Link State PDU lists Level 2 links to the +Intermediate System that originally generated the Link +State PDU. +RECORD +adr: lspID; (* 8 octet ID of LSP originator *) +type: (AttachedLevel2IntermediateSystem, +UnattachedLevel2IntermediateSystem); +seqnum: [0..SequenceModulus 1]; +LSPage: [0..MaxAge]; (*Remaining Lifetime *) +expirationTime: TimeStamp; +(*Time at which LSP age +became zero (see 7.3.16.4). *) +SRMflags: ARRAY[1..(maximumCircuits)] OF +BOOLEAN; +(*Indicates this LSP to be sent on this circuit. *) +SSNflags: ARRAY[1..maximumCircuits] OF +BOOLEAN; +(*Indicates that information about this LSP must be +included in the next partial sequence number PDU +transmitted on this circuit. *) +POINTER TO LSP; (*The received LSP *) +END; +C.1.3 Adjacency Database + This database is kept by all systems. Its purpose is to keep +track of neighbours. +For Intermediate systems, the adjacency database comprises +a database with an entry for each: +-Adjacency on a Point to Point circuit. +-Broadcast Intermediate System Adjacency. (Note that +both a Level 1 and a Level 2 adjacency can exist be +tween the same pair of systems.) +-Broadcast End system Adjacency. +-potential SVC on a DED circuit (max + +i + +mum + +SVC + + +Adja + +cencies for a DA circuit, or 1 for a Static cir +cuit). +-Virtual Link Adjacency. +Each entry contains the parameters in Clause 11 for the Ad +jacency managed object. It also contains the variable used +to store the remaining holding time for each Adjacency +IDEntry and NETEntry entry, as defined below. + +IDEntry = RECORD +ID: systemID; +(* The 6 octet System ID of a neighbour End system +extracted from the SOURCE ADDRESS field of its +ESH PDUs. *) +entryRemainingTime: Unsigned [1..65535] +(* The remaining holding time in seconds for this +entry. This value is not accessible to system +management. An implementation may choose to +implement the timer rules without an explicit +remainingTime being maintained. For example by +the use of asynchronous timers. It is present here in +order to permit a consistent description of the timer +rules. *) +END + +NETEntry = RECORD +NET: NetworkEntityTitle; +(* The NET of a neighbour Intermediate system +as reported in its IIH PDUs. *) +entryRemainingTime: Unsigned [1..65535] + (* The remaining holding time in seconds for this +entry. This value is not accessible to system +management. An implementation may choose to +implement the timer rules without an explicit +remainingTime being maintained. For example by +the use of asynchronous timers. It is present here in +order to permit a consistent description of the timer +rules. *) +END; +C.1.4 Circuit Database +This database is kept by all systems. Its purpose is to keep +information about a circuit. It comprises an AR +RAY[1..maximumCircuits]. +Each entry contains the parameters in Clause 11 for a Cir +cuit managed object (see 11.3). It also contains the remain +ingHelloTime (WordUnsigned [1..65535] seconds) vari +able for the Circuit. This variable not accessible to system +management. An implementation may choose to implement +the timer rules without an explicit remainingHelloTime +being maintained. For example by the use of asynchronous +timers. It is present here in order to permit a consistent de +scription of the timer rules. Additionally, for Circuits of +type X.25 Static Outgoing or X.25 DA, it contains the +recallCount (Unsigned[0..255]) variable for the Circuit. +This variable is not accessible to system management. It +used to keep track of recall attempts. +C.1.5 Level 1 Shortest Paths Database +This database is kept by Level 1 and Level 2 Intermediate +Systems (unless each circuit is Level 2 Only). It is com +puted by the Level 1 Decision Process, using the Level 1 +Link State Database. The Level 1 Forwarding Database is a +subset of this database. +RECORD +adr: systemId; (*6 octet ID of destination system *) +cost: [1..MaxPathMetric]; +(*Cost of best path to destination system *) +adjacencies: ARRAY[1..max + +i + +mum + +Path + +Splits] +OF POINTER TO Adjacency; + +(*Pointer to adjacency for forwarding to system adr +*) +END; +C.1.6 Level 2 Shortest Paths Database +This database is kept by Level 2 Intermediate Systems. It is +computed by the Level 2 Decision Process, using the +Level 2 Link State Database. The Level 2 Forwarding Data +base is a subset of this database. +RECORD +adr: AddressPrefix; (*destination prefix *) +cost: [1..MaxPathMetric]; +(*Cost of best path to destination prefix *) +adjacencies: ARRAY[1..max + +i + +mum + +Path + +Splits] +OF POINTER TO Adjacency; +(*Pointer to adjacency for forwarding to prefix adr +*) +END; + +C.1.7 Level 1 Forwarding Database +This database is kept by Level 1 and Level 2 Intermediate +Systems (unless each circuit is Level 2 Only). It is used +to determine where to forward a data NPDU with destina +tion within this system's area. It is also used to determine +how to reach a Level 2 Intermediate System within the area, +for data PDUs with destinations outside this system's area. +RECORD +adr:systemId; +(*6 octet ID of destination system. Destination +0 is special, meaningnearest level 2 +Intermediate system *) +splits: [0..max + +i + +mum + +Path + +Splits]; +(* Number of valid output adj's for reachingadr +(0 indicates it is unreachable) *) + nextHop: ARRAY[1..max + +i + +mum + +Path + +Splits] OF +POINTER TO adjacency; +(*Pointer to adjacency for forwarding to destination +system *) +END; + +C.1.8 Level 2 Forwarding Database +This database is kept by Level 2 Intermediate systems. It is +used to determine where to forward a data NPDU with des +tination outside this system's area. +RECORD +adr: AddressPrefix; (*address of destination area. +*) +splits: [0..max + +i + +mum + +Path + +Splits]; +(*Number of valid output adj's for reaching adr +(0 indicates it is unreachable) *) +nextHop: ARRAY[1..max + +i + +mum + +Path + +Splits] OF +POINTER TO adjacency; +(*Pointer to adjacency for forwarding to destination +area. *) +END; + + +C.2 SPF Algorithm for Computing +Equal Cost Paths +An algorithm invented by Dijkstra (see references) 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 num +ber of nodes for sparse networks (networks which are not +highly connected). +A number of additional optimisations are possible: +a)If the routeing metric is defined over a small finite +field (as in this International 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. +b)Updates can be performed incrementally without re +quiring a complete recalculation. However, a full up +date must be done periodically to recover from data +corruption, and studies suggest that with a very small +number of link changes (perhaps 2) the expected com +putation complexity of the incremental update exceeds +the complete recalculation. Thus, this International +Standard specifies the algorithm only for the full up +date. +c)If only End system LSP information has changed, it is +not necessary to re-compute the entire Dijkstra tree for +the IS. If the proper data structures exist, End Systems +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 multiple paths. The algorithm in this International +Standard does permit load splitting by identifying a set of +equal cost paths to each destination rather than a single +least cost path. +C.2.1 Databases +PATHS This represents an a + +cyclic directed graph of +shortest paths from the system S performing the cal +culation. It is stored as a set of triples of the form +aN,d(N),{Adj(N)}q, where: + N is a system Identifier. In the level 1 algorithm, N is +a 7 octet ID. For a non-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 Designated Interme +diate System. In the level 2 algorithm it is either a +7 octet Intermediate System or pseudonode ID (as in +the level 1 algorithm), or it is a variable length ad +dress prefix (which will always be a leaf, i.e. End +system, in PATHS). + 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 +aN,d(N),{Adj(N)}q, 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 aN,x,{A}q in TENT means that if N were +placed in PATHS, d(N) would be x, but N cannot be +placed on PATHS until it is guaranteed that no path +shorter than x exists. + The triple aN,x,{A,B}q in TENT means that if N +were placed in PATHS, d(N) would be x via either +adjacency A or B +NOTE - As described above, (see 7.2.6), it is suggested that +the implementation keep the database TENT as a set of lists +of triples of the form a*,Dist,*q, for each possible 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. +C.2.2 Use of Metrics in the SPF Calculation +Internal metrics are not comparable to external metrics. +Therefore, the cost of the path from N to S for external +routes (routes to destinations outside of the routing domain) +may include both internal and external metrics. The cost of +the path from N to S (called d(N) below in database +PATHS) may therefore be maintained as a two- +dimensioned vector quantity (specifying internal and exter +nal metric values). In incrementing d(N) by 1, if the internal +metric value is less than the maximum value +MaxPathMetric, then the internal metric value is incre +mented by one and the external metric value left un +changed; if the internal metric value is equal to the maxi +mum 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. +NOTE - In the code of the algorithm below, the current path +length is held in a variable tentlength. This variable is a +two-dimensional quantity tentlength=(internal,external) +and is used for comparing the current path length with d(N) +as described above. +C.2.3 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 SELF can possibly exist). +TENT is then pre-loaded from the local adjacency data +base. +Note that a system is not placed in PATHS unless no +shorter path to that system exists. When a system N is +placed in PATHS, the path to each neighbour M of N, + +through N, is examined, as the path to N plus the link from +N to M. If aM,*,*q is in PATHS, this new path will be +longer, and thus ignored. +If aM,*,*q 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 aN,x,{Adj(N)}q in +TENT, with minimal x. +NOTE - This is done efficiently because of the optimisation +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 a*,Dist,*q. +N is placed in PATHS. We know that no path to N can be +shorter than x at this point because all paths through sys +tems already in PATHS have already been considered, and +paths through systems in TENT will have to be greater than +x because x is minimal in TENT. +When TENT is empty, PATHS is complete. +C.2.4 The Algorithm +The Decison Process Algorithm must be run once for each +supported routeing metric. A Level 1 Intermediate System +runs the algorithm using the Level 1 LSP database to com +pute Level 1 paths. In addition a Level 2 Intermediate Sys +tem runs the algorithm using the Level 2 LSP database to +compute Level 2 paths. +If this system is a Level 2 Intermediate System which sup +ports the partition repair optional function the Decision +Process algorithm for computing Level 1 paths must be run +twice for the default metric. The first execution is done to +determine which of the area's manual + +Area + +Addresses +are reachable in this partition, and elect a Partition Desig +nated Level 2 Intermediate System for the partition. The +Partition Designated Level 2 Intermediate System will de +termine if the area is partitioned and will create virtual +Level 1 links to the other Partition Designated Level 2 In +termediate Systems in the area in order to repair the Level 1 +partition. This is further described in 7.2.10. +Step 0: Initialise TENT and PATHS to empty. Initialise +tentlength to (0,0). +(tentlength is the pathlength of elements in TENT +we are examining.) +a)Add aSELF, 0, Wq to PATHS, where W is a special +value indicating traffic to SELF is passed up to Trans +port (rather than forwarded). +b)Now pre-load TENT with the local adjacency data +base. (Each entry made to TENT must be marked as +being either an End system or an Intermediate System +to enable the check at the end of Step 2 to be made +correctly.) For each adjacency Adj(N), (including +Manual Adjacencies, or for Level 2 enabled Reach + +able Addresses) 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 metrick, where k = one of de +fault metric, delay metric, monetary metric, er +ror metric. +Adj(N) = the adjacency number of the adjacency +to N +c)If a triple aN,x,{Adj(M)}q is in TENT, then: +If x = d(N), then Adj(M) , {Adj(M)} H Adj(N). +d)If there are now more adjacencies in {Adj(M)} than +max + +i + +mum + +Path + +Splits, then remove excess adjacen +cies as described in 7.2.7. +e)If x < d(N), do nothing. +f)If x > d(N), remove aN,x,{Adj(M)}q from TENT and +add the triple aN,d(N),Adj(N)q. +g)If no triple aN, x,{Adj(M)}q is in TENT, then add aN, +d(N),Adj(N)q to TENT. +h)Now add any systems to which the local Intermediate +system does not have adjacencies, but which are men +tioned in neighbouring pseudonode LSPs. The adja +cency for such systems is set to that of the Designated +Intermediate System. +i)For all broadcast circuits in state On, find the LSP +with LSP number zero and with the first 7 octets of +LSPID equal to the LnCircuitID for that circuit (i.e. +pseudonode LSP for that circuit). If it is present, for +all the neighbours N reported in all the LSPs of this +pseudonode which do not exist in TENT add an entry +aN,d(N),Adj(N)q to TENT, where +d(N) = metrick of the circuit. +Adj(N) = the adjacency number of the adjacency to the +DR. +j)Go to Step 2. +Step 1: Examine the zeroth Link State PDU of P, the sys +tem just placed on PATHS (i.e. the Link State PDU with +the same first 7 octets of LSPID as P, and LSP number +zero). +a)If this LSP is present, and the LSP Database Over +load bit is clear, then for each LSP of P (i.e. all the +Link State PDUs with the same first 7 octets of LSPID +as P, irrespective of the value of LSP number) com +pute +dist(P,N) = d(P) + metrick(P,N). + +for each neighbour N (both Intermediate System and +End system) of the system P. If the LSP Database +Overload bit is set, only consider the End system +neighbours of the system P. d(P) is the second ele +ment of the triple + +aP,d(P),{Adj(P)q + +and metrick(P,N) is the cost of the link from P to N as +reported in P's Link State PDU +b)If dist(P,N) > MaxPathMetric, then do nothing. +c)If aN,d(N),{Adj(N)}q 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 san +ity check may be done here to ensure d(N) is in fact less +than dist(P,N). +d)If a triple aN,x,{Adj(N)}q is in TENT, then: +1)If x = dist(P,N), then Adj(N) , {Adj(N)} H +Adj(P). +2)If there are now more adjacencies in {Adj(N)} than +max + +i + +mum + +Path + +Splits, then remove excess adja +cencies, as described in 7.2.7. +3)If x < dist(P,N), do nothing. +4)If x > dist(P,N), remove aN,x,{Adj(N)}q from +TENT and add aN,dist(P,N),{Adj(P)}q. +e)If no triple aN, x,{Adj(N)}q is in TENT, then add aN, +dist(P,N),{P}q to TENT. +Step 2: If TENT is empty, stop, else: +a)Find the element aP,x,{Adj(P)}q, with minimal x as +follows: +1)If an element a*,tentlength,*q 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 ten +tlength and repeat Step 2. +2)Remove aP,tentlength,{Adj(P)}q from TENT. +3)Add aP,d(P),{Adj(P)}q to PATHS. +4)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 aAREA.P, d(P), {adj(P)}q 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 Level 2 LSP +and appending P's ID. +5)If the system just added to PATHS was an End +system, go to Step 2, Else go to Step 1. +NOTE - In the Level 2 context, the End systems are the +set of Reachable Address Prefixes and the set of area ad +dresses with zero cost. + +C.3 Forwarding Process +C.3.1 Example pseudo-code for the forwarding +procedure described in 7.4.3 +This procedure chooses, from the Level 1 forwarding data +base if level is level1, or from the Level 2 forwarding +database if level is level2, an adjacency on which to for +ward PDUs for destination dest. A pointer to the adjacency +is returned in adj, and the procedure returns the value +True. If no suitable adjacency exists the procedure returns +the value False, in which case a call should be made to +Drop(Destination Address Unreachable, octetNumber). +If queue length values are available to the forwarding proc +ess, the minimal queue length of all candidate circuits is +chosen, otherwise, they are used in round robin fashion. +PROCEDURE Forward( +level: (level1, level2), +dest: NetworkLayerAddress, +VAR adj: POINTER TO adjacency) : +BOOLEAN + +VAR +adjArray: ARRAY OF +ForwardingDatabaseRecords; +temp, index, minQueue: CARDINAL; + +BEGIN +(*Set adjArray to appropriate database} *) +IF level = level1 THEN +adjArray := level1ForwardingDatabase +ELSE +adjArray := level2ForwardingDatabase +END; + (*Perform appropriate hashing function to obtain an +index into the database *) + IF Hash(level, dest, index) THEN +IF adjArray[index].splits > 0 THEN +(*Find minimum queue size for all equal cost +paths *) +minQueue := MaxUnsigned; +temp := adjArray[index].lastChosen + 1; +(*start off after last time *) +FOR i := 1 TO adjArray[index].splits DO +(*for all equal cost paths to dest *) +IF temp > adjArray[index].splits THEN +(*after end of valid entries, wrap to first +*) +temp := 1 +ELSE +temp := temp + 1 +END; +IF +QueueSize(adjArray[index].nextHop[temp]) +< minQueue THEN +minQueue := +QueueSize(adjArray[index].nextHop[tem +p]); +adj := adjArray[index].nextHop[temp]; +adjArray[index].lastChosen := temp; +END; +Forward := true +END; + +ELSE +Forward := false (*There must be at least one +valid output adjacency *) +END +ELSE +Forward := false (*Hash returned destination +unknown *) +END +END forward; + + +Annex D +Congestion Control and Avoidance +(This annex is informative) + +D.1 Congestion Control +The transmit management subroutine handles congestion +control. Transmit management consists of the following +components: +Square root limiter. Reduces buffer occupancy +time per PDU by using a square root limiter algo +rithm. The square root limiter also queues PDUs for +an output circuit, and prevents buffer deadlock by +discarding PDUs when the buffer pool is exhausted. +Clause D.1.1 specifies the Square Root Limiter +Process. +Originating PDU limiter. Limits originating NPDU +traffic when necessary to ensure that transit NPDUs +are not rejected. An originating NPDU is an NPDU +resulting from an NSDU from the Transport at this +ES. A transit NPDU is an NPDU from another sys +tem to be relayed to another destination ES. +Flusher. Flushes PDUs queued for an adjacency that +has gone down. +Information for higher layer (Transport) congestion control +procedures is provided by the setting of the congestion ex +perienced bit in the forwarded data NPDUs. +D.1.1 Square Root Limiter +The square root limiter discards a data NPDU by calling the +ISO 8473 discard PDU function with the reason PDU +Discarded due to Congestion when the number of data +NPDUs on the circuit output queue exceeds the discard +threshold, Ud. Ud is given as follows:= +where: +Nb = Number of Routeing Layer buffers +(maximumBuffers) for all output circuits. +Nc = Number of active output circuits (i.e. Circuits in state +On). +The output queue is a queue of buffers containing data +NPDUs which have been output to that circuit by the for +warding process, and which have not yet been transmitted +by the circuit. It does not include NPDUs which are held +by the data link layer for the purpose of retransmission. +Where a data NPDU is to be fragmented by this Intermedi +ate system over this circuit, each fragment shall occupy a + +separate buffer and shall be counted as such in the queue +length. If the addition of all the buffers required for the +fragmentation of a single input data NPDU would cause the +discard threshold for that queue to be exceeded, it is recom +mended that all those fragments (including those which +could be added without causing the threshold to be ex +ceeded) be discarded. +D.1.2 Originating PDU Limiter +TEMPORARY NOTE - Strictly this function is an End Sys +tem function. However it is closely coupled to the routeing +function, particularly in the case of real systems which are +performing the functions of both an Intermediate System +and an End System (i.e. systems which can both initiate and +terminate data NPDUs and perform relaying functions). +Therefore, until a more appropriate location for this infor +mation can be determined, this function is described here. +The originating PDU limiter first distinguishes between +originating NPDUs and transit NPDUs. It then imposes a +limit on the number of buffers that originating NPDUs can +occupy on a per circuit basis. In times of heavy load, origi +nating NPDUs may be rejected while transit NPDUs con +tinue to be routed. This is done because originating NPDUs +have a relatively short wait, whereas transit NPDUs, if re +jected, have a long wait a transport retransmission period. +The originating PDU limiter accepts as input: +-An NSDU received from Transport Layer +-A transmit complete signal from the circuit for an ISO +8473 Data PDU. +The originating PDU limiter produces the following as out +put: +-PDU accepted +-PDU rejected +-Modifications to originating PDU counter +There is a counter, N, and an originating PDU limit, +originatingQueueLimit, for each active output circuit. +Each N is initialised to 0. The originatingQueueLimit is +set by management to the number of buffers necessary to +prevent the circuit from idling. +D.1.3 Flusher +The flusher ensures that no NPDU is queued on a circuit +whose state is not ON, or on a non-existent adjacency, or +one whose state is not Up. + +D.2 Congestion Avoidance +D.2.1 Buffer Management +The Forwarding Process supplies and manages the buffers +necessary for relaying. PDUs shall be discarded if buffer +thresholds are exceeded. If the average queue length on the +input circuit or the forwarding processor or the output cir +cuit exceeds QueueThreshold, the congestion experi +enced bit shall be set in the QoS maintenance option of the +forwarded data PDU (provided the QoS maintenance option +is present). + + +Security Considerations + + Security issues are not discussed in this memo. + +Author's Address + + David R. Oran + Digital Equipment Corporation + LKG 1-2/a 19 + 550 King Street + Littleton, MA 01460 + + Email: Oran@Oran.enet.dec.com + + Phone: (508) 4866-7377 -- cgit v1.2.3