RFC1765

Network Working Group J. Moy Request for Comments: 1765 Cascade Category: Experimental March 1995

                     OSPF Database Overflow

Status of this Memo

This memo defines an Experimental Protocol for the Internet community. This memo does not specify an Internet standard of any kind. Discussion and suggestions for improvement are requested. Distribution of this memo is unlimited.

Abstract

Proper operation of the OSPF protocol requires that all OSPF routers maintain an identical copy of the OSPF link-state database. However, when the size of the link-state database becomes very large, some routers may be unable to keep the entire database due to resource shortages; we term this "database overflow". When database overflow is anticipated, the routers with limited resources can be accommodated by configuring OSPF stub areas and NSSAs. This memo details a way of gracefully handling unanticipated database overflows.

This memo is a product of the OSPF Working Group. Please send comments to [email protected].

Overview

OSPF requires that all OSPF routers within a single area maintain an identical copy of the OSPF link-state database. However, when the size of the link-state database becomes very large, some routers may be unable to keep the entire database due to resource shortages; we term this "database overflow". For example, a regional network may have a very large OSPF database because it is importing a large number of external routes into OSPF. Unless database overflow is handled correctly, routers will end up with inconsistent views of the network, possibly leading to incorrect routing.

One way of handling database overflow is to encase routers having limited resources within OSPF stub areas (see Section 3.6 of [1]) or NSSAs ([2]). AS-external-LSAs are omitted from these areas' link- state databases, thereby controlling database size.

However, unexpected database overflows cannot be handled in the above manner. This memo describes a way of dynamically limiting database size under overflow conditions. The basic mechanism is as follows:

(1) A parameter, ospfExtLsdbLimit, is configured in each router
    indicating the maximum number of AS-external-LSAs (excluding
    those describing the default route) that are allowed in the
    link-state database. This parameter must be the same in all
    routers in the routing domain (see Section 2.1); synchronization
    of the parameter is achieved via network management.

(2) In any router's database, the number of AS-external-LSAs
    (excluding default) is never allowed to exceed ospfExtLsdbLimit.
    If a router receives a non-default AS-external-LSA that would
    cause the limit of ospfExtLsdbLimit to be exceeded, it drops the
    LSA and does NOT acknowledge it.

(3) If the number of non-default AS-external-LSAs in a router's
    database hits ospfExtLsdbLimit, the router a) flushes all non-
    default AS-external-LSAs that it has itself originated (see
    Section 2.2) and b) goes into "OverflowState".

(4) While in OverflowState, the router refuses to originate any
    non-default AS-external-LSAs (see Section 2.3.2).

(5) Optionally, the router can attempt to leave OverflowState after
    the configurable parameter ospfExitOverflowInterval has elapsed
    since entering OverflowState (see Section 2.4). Only at this
    point can the router resume originating non-default AS-
    external-LSAs.

The reason for limiting non-default AS-external-LSAs, but not other LSA types, is twofold. First of all, the non-default AS-external LSAs are the most likely to dominate database size in those networks with huge databases (e.g., regional networks; see [5]). Second, the non- default AS-external-LSAs can be viewed as "optional" in the following sense: the router can probably be monitored/reconfigured without them. (However, using similar strategies, other LSA types can also be limited; see Section 5.)

The method of dealing with database overflow described herein has the following desirable properties:

o   After a short period of convergence, all routers will have
    identical link-state databases. This database will contain less
    than ospfExtLsdbLimit non-default AS-external-LSAs.

o   At all times, routing WITHIN the OSPF Autonomous System will
    remain intact. Among other things, this means that the routers
    will continue to be manageable.

o   Default routing to external destinations will also remain
    intact. This hopefully will mean that a large amount of external
    connectivity will be preserved, although possibly taking less
    efficient routes.

o   If parameter ospfExitOverflowInterval is configured, the OSPF
    system will recover fully and automatically (i.e., without
    network management intervention) from transient database
    overflow conditions (see Section 2.4).

Implementation details

This section describes the mechanism for dealing with database overflow in more detail. The section is organized around the concept OverflowState, describing how routers enter the OverflowState, the operation of the router while in OverflowState, and when the router leaves OverflowState.

2.1. Configuration

  The following configuration parameters are added to support the
  database overflow functionality. These parameters are set by
  network management.

    ospfExtLsdbLimit
        When the number of non-default AS-external-LSAs in a
        router's link-state database reaches ospfExtLsdbLimit, the
        router enters OverflowState. The router never holds more

        than ospfExtLsdbLimit non-default AS-external-LSAs in its
        database.

        ospfExtLsdbLimit MUST be set identically in all routers
        attached to the OSPF backbone and/or any "regular" OSPF
        area. (This memo does not pertain to routers contained
        within OSPF stub areas nor NSSAs, since such routers do not
        receive AS-external-LSAs.) If ospfExtLsdbLimit is not set
        identically in all routers, then when the database
        overflows: 1) the routers will NOT converge on a common
        link-state database, 2) incorrect routing, possibly
        including routing loops, will result and 3) constant
        retransmission of AS-external-LSAs will occur. Identical
        setting of ospfExtLsdbLimit is achieved/ensured by network
        management.

        When ospfExtLsdbLimit is set in a router, the router must
        have some way to guarantee that it can hold that many non-
        default AS-external-LSAs in its link-state database. One way
        of doing this is to preallocate resources (e.g., memory) for
        the configured number of LSAs.

    ospfExitOverflowInterval
        The number of seconds that, after entering OverflowState, a
        router will attempt to leave OverflowState. This allows the
        router to again originate non-default AS-external-LSAs. When
        set to 0, the router will not leave OverflowState until
        restarted. The default setting for ospfExitOverflowInterval
        is 0.

        It is not necessary for ospfExitOverflowInterval to be
        configured the same in all routers. A smaller value may be
        configured in those routers that originate the "more
        important" AS-external-LSAs. In fact, setting
        ospfExitOverflowInterval the same may cause problems, as
        multiple routers attempt to leave OverflowState
        simultaneously. For this reason, the value of
        ospfExitOverflowInterval must be "jittered" by randomly
        varying its value within the range of plus or minus 10
        percent before using.

2.2. Entering OverflowState

  The router enters OverflowState when the number of non-default
  AS-external-LSAs in the database hits ospfExtLsdbLimit. There are
  two cases when this can occur. First, when receiving an LSA during
  flooding. In this case, an LSA which does not already have a
  database instance is added in Step 5 of Section 13 of [1].  The

  second case is when the router originates a non-default AS-
  external-LSA itself.

  Whenever the router enters OverflowState it flushes all non-
  default AS-external-LSAs that it itself had originated. Flushing
  is accomplished through the premature aging scheme described in
  Section 14.1 of [1].  Only self-originated LSAs are flushed; those
  originated by other routers are kept in the link-state database.

2.3. Operation while in OverflowState

  While in OverflowState, the flooding and origination of non-
  default AS-external-LSAs are modified in the following fashion.

  2.3.1.  Modifications to Flooding

     Flooding while in OverflowState is modified as follows. If in
     Step 5 of Section 13 of [1], a non-default AS-external-LSA has
     been received that a) has no current database instance and b)
     would cause the count of non-default AS-external-LSAs to exceed
     ospfExtLsdbLimit, then that LSA is discarded. Such an LSA is
     not installed in the link-state database, nor is it
     acknowledged.

     When all routers have identical values for ospfExtLsdbLimit (as
     required), the above flooding modification will only be invoked
     during a short period of convergence. During convergence, there
     will be retransmissions of LSAs. However, after convergence the
     retransmissions will cease, as the routers settle on a database
     having less than ospfExtLsdbLimit non-default As-external-LSAs.

     In OverflowState, non-default AS-external-LSAs ARE still
     accepted in the following conditions:

        (1) If the LSA updates an LSA that currently exists in the
            router's link-state database.

        (2) LSAs having LS age of MaxAge are always accepted. The
            processing of these LSAs follows the procedures
            described in Sections 13 and 14 of [1].

        (3) If adding the LSA to the router's database would keep
            the number of non-default AS-external-LSAs less than or
            equal to ospfExtLsdbLimit, the LSA is accepted.

  2.3.2.  Originating AS-external-LSAs

     Originating AS-external-LSAs is described in Section 12.4.5 of
     [1].  When a router is in OverflowState, it does not originate
     non-default AS-external-LSAs. In other words, the only AS-
     external-LSAs originated by a router in OverflowState have Link
     State ID 0.0.0.0.

  2.3.3.  Receiving self-originated LSAs

     Receiving self-originated LSAs is described in Section 13.4 of
     [1].  When in OverflowState, a router receiving a self-
     originated non-default AS-external-LSA responds by flushing it
     from the routing domain using the premature aging scheme
     described in Section 14.1 of [1].

2.4. Leaving OverflowState

  If ospfExitOverflowInterval is non-zero, then as soon as a router
  enters OverflowState, it sets a timer equal to the value of
  ospfExitOverflowInterval (plus or minus a random value in the
  range of 10 percent). When this timer fires, the router leaves
  OverflowState and begins originating non-default AS-external-LSAs
  again.

  This allows a router to automatically recover from transient
  overflow conditions. For example, an AS boundary router that
  imports a great many AS-external-LSAs may crash. Other routers may
  then start importing the routes, but until the crashed AS boundary
  router is either a) restarted or b) its AS-external-LSAs age out,
  there will be a much larger database than usual.  Since such an
  overflow is guaranteed to go away in MaxAge seconds (1 hour),
  automatic recovery may be appropriate (and fast enough) if the
  overflow happens off-hours.

  As soon as the router leaves OverflowState, it is again eligible
  to reenter OverflowState according to the text of Section 2.2.

An example

As an example, suppose that a router implements the database overflow logic, and that its ospfExtLsdbLimit is 10,000 and its ospfExitOverflowInterval is set to 600 seconds. Suppose further that the router itself is originating 400 non-default AS-external-LSAs, and that the current number of non-default AS-external-LSAs in the router's database is equal to 9,997.

Next, it receives a Link State Update packet from a neighbor, containing 6 non-default AS-external-LSAs, none of which have current database copies. The first two LSAs are then installed in the database. The third LSA is also installed in the database, but causes the router to go into OverflowState. Going into OverflowState causes the router to flush (via premature aging) its 400 self-originated non-default LSAs. However, these 400 LSAs are still considered to be part of the link-state database until their re-flooding (with age set to MaxAge) is acknowledged (see Section 14 of [1]); for this reason, the last three LSAs in the received update are discarded without being acknowledged.

After some small period of time all routers will converge on a common database, having less than 10,000 non-default AS-external-LSAs. During this convergence period there may be some link-state retransmissions; for example, the sender of the above Link State Update packet may retransmit the three LSAs that were discarded. If this retransmission happens after the flushing of the 400 self- originated LSAs is acknowledged, the 3 LSAs will then be accepted.

Going into OverflowState also causes the router to set a timer that will fire some time between 540 and 660 seconds later. When this timer fires, the router will leave OverflowState and re-originate its 400 non-default AS-external-LSAs, provided that the current database has less than 9600 (10,000 - 400) non-default AS-external-LSAs. If there are more than 9600, the timer is simply restarted.

Administrative response to database overflow

Once the link-state database has overflowed, it may take intervention by network management before all routing is restored. (If the overflow condition is transient, routing may be restored automatically; see Section 2.4 for details.) An overflow condition is indicated by SNMP traps (see Appendix B). Possible responses by a network manager may include:

o   Increasing the value of ospfExtLsdbLimit. Perhaps it had been
    set too conservatively, and the routers are able to support
    larger databases than they are currently configured for.

o   Isolating routers having limited resources within OSPF stub
    areas or NSSAs.  This would allow increasing the value of
    ospfExtLsdbLimit in the remaining routers.

o   Reevaluating the need to import certain external routes. If
    ospfExtLsdbLimit cannot be increased, the network manager will
    want to make sure that the more important routes continue to be
    imported; this is accomplished by turning off the importing of

    less important routes.

Operational experience

The database overflow scheme described in this memo has been implemented in the Proteon router for a number of years, with the following differences. First, the router did not leave OverflowState until it was restarted (i.e., ospfExitOverflowInterval was always 0). Second, default AS-external-LSAs were not separated from non-default AS-external-LSAs. Operationally the scheme performed as expected: during overflow conditions, the routers converged on a common database having less than a configured number of AS-external-LSAs.

Possible enhancements

Possible enhancements to the overflow scheme include the following:

o   Other LSA types, with the exception of the transit LSAs
    (router-LSAs and network-LSAs), could be limited in a similar
    fashion. For example, one could limit the number of summary-
    LSAs, or group-membership-LSAs (see [6]).

o   Rather than flushing all of its non-default AS-external-LSAs
    when entering OverflowState, a router could flush a fixed number
    whenever the database size hits ospfExtLsdbLimit. This would
    allow the router to prioritize its AS-external-LSAs, flushing
    the least important ones first.

A. Related MIB parameters

The following OSPF MIB variables have been defined to support the database overflow procedure described in this memo (see [4] for more information):

ospfExtLsdbLimit
    As in Section 2.1 of this memo, the maximum number of non-
    default AS-external-LSAs that can be stored within the database.
    If set to -1, there is no limit.

ospfExitOverflowInterval
    As in Section 2.1 of this memo, the number of seconds that,
    after entering OverflowState, a router will attempt to leave
    OverflowState. This allows the router to again originate non-
    default AS-external-LSAs.  When set to 0, the router will not
    leave OverflowState until restarted.

ospfLsdbOverflow
    A trap indicating that the number of non-default AS-external-
    LSAs has exceeded or equaled ospfExtLsdbLimit. In other words,
    this trap indicates that the router is entering OverflowState.

ospfLsdbApproachingOverflow
    A trap indicating that the number of non-default AS-external-
    LSAs has exceeded ninety percent of "ospfExtLsdbLimit".

References

[1] Moy, J., "OSPF Version 2", RFC 1583, Proteon, Inc., March 1994.

[2] Coltun, R., and V. Fuller, "The OSPF NSSA Option", RFC 1587,

   RainbowBridge Communications, Stanford University, March 1994.

[3] Moy, J., Editor, "OSPF Protocol Analysis", RFC 1245, Proteon,

   Inc., July 1991.

[4] Baker F., and R. Coltun, "OSPF Version 2 Management Information

   Base", Work in Progress.

[5] Moy, J., Editor, "Experience with the OSPF Protocol", RFC 1246,

   Proteon, Inc., July 1991.

[6] Moy, J., "Multicast Extensions to OSPF", RFC 1584, Proteon, Inc.,

   March 1994.

Security Considerations

Security issues are not discussed in this memo.

Author's Address

John Moy Cascade Communications Corp. 5 Carlisle Road Westford, MA 01886

Phone: 508-692-2600 Ext. 394 Fax: 508-692-9214 EMail: [email protected]