Network Working Group G. Huston
Request for Comments: 3765 Telstra
Category: Informational April 2004
NOPEER Community for Border Gateway Protocol (BGP)
Route Scope Control
Status of this Memo
This memo provides information for the Internet community. It does
not specify an Internet standard of any kind. Distribution of this
memo is unlimited.
Copyright Notice
Copyright (C) The Internet Society (2004). All Rights Reserved.
Abstract
This document describes the use of a scope control Border Gateway
Protocol (BGP) community. This well-known advisory transitive
community allows an origin AS to specify the extent to which a
specific route should be externally propagated. In particular this
community, NOPEER, allows an origin AS to specify that a route with
this attribute need not be advertised across bilateral peer
connections.
BGP today has a limited number of commonly defined mechanisms that
allow a route to be propagated across some subset of the routing
system. The NOEXPORT community allows a BGP speaker to specify that
redistribution should extend only to the neighbouring AS. Providers
commonly define a number of communities that allow their neighbours
to specify how advertised routes should be re-advertised. Current
operational practice is that such communities are defined on as AS by
AS basis, and while they allow an AS to influence the re-
advertisement behaviour of routes passed from a neighbouring AS, they
do not allow this scope definition ability to be passed in a
transitive fashion to a remote AS.
Advertisement scope specification is of most use in specifying the
boundary conditions of route propagation. The specification can take
on a number of forms, including as AS transit hop count, a set of
target ASs, the presence of a particular route object, or a
particular characteristic of the inter-AS connection.
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There are a number of motivations for controlling the scope of
advertisement of route prefixes, including support of limited transit
services where advertisements are restricted to certain transit
providers, and various forms of selective transit in a multi-homed
environment.
This memo does not attempt to address all such motivations of scope
control, and addresses in particular the situation of both multi-
homing and traffic engineering. The commonly adopted operational
technique is that the originating AS advertises an encompassing
aggregate route to all multi-home neighbours, and also selectively
advertises a collection of more specific routes. This implements a
form of destination-based traffic engineering with some level of fail
over protection. The more specific routes typically cease to lever
any useful traffic engineering outcome beyond a certain radius of
redistribution, and a means of advising that such routes need not to
be distributed beyond such a point is of some value in moderating one
of the factors of continued route table growth.
Analysis of the BGP routing tables reveals a significant use of the
technique of advertising more specific prefixes in addition to
advertising a covering aggregate. In an effort to ameliorate some of
the effects of this practice, in terms of overall growth of the BGP
routing tables in the Internet and the associated burden of global
propagation of dynamic changes in the reachability of such more
specific address prefixes, this memo describes the use of a
transitive BGP route attribute that allows more specific route tables
entries to be discarded from the BGP tables under appropriate
conditions. Specifically, this attribute, NOPEER, allows a remote AS
not to advertise a route object to a neighbour AS when the two AS's
are interconnected under the conditions of some form of sender keep
all arrangement, as distinct from some form of provider / customer
arrangement.
This memo defines the use a new well-known bgp transitive community,
NOPEER.
The semantics of this attribute is to allow an AS to interpret the
presence of this community as an advisory qualification to
readvertisement of a route prefix, permitting an AS not to
readvertise the route prefix to all external bilateral peer neighbour
AS's. It is consistent with these semantics that an AS may filter
received prefixes that are received across a peering session that the
receiver regards as a bilateral peer sessions.
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The size of the BGP routing table has been increasing at an
accelerating rate since late 1998. At the time of publication of
this memo the BGP forwarding table contains over 118,000 entries, and
the three year growth rate of this table shows a trend rate which can
be correlated to a compound growth rate of no less than 10% per year
[2].
One of the aspects of the current BGP routing table is the widespread
use of the technique of advertising both an aggregate and a number of
more specific address prefixes. For example, the table may contain a
routing entry for the prefix 10.0.0.0/23 and also contain entries for
the prefixes 10.0.0.0/24 and 10.0.1.0/24. In this example the
specific routes fully cover the aggregate announcement. Sparse
coverage of aggregates with more specifics is also observed, where,
for example, routing entries for 10.0.0.0/8 and 10.0.1.0/24 both
exist in the routing table. In total, these more specific route
entries occupy some 51% of the routing table, so that more than one
half of the routing table does not add additional address
reachability information into the routing system, but instead is used
to impose a finer level of detail on existing reachability
information.
There are a number of motivations for having both an aggregate route
and a number of more specific routes in the routing table, including
various forms of multi-homed configurations, where there is a
requirement to specify a different reachability policy for a part of
the advertised address space.
One of the observed common requirements in the multi-homed network
configuration is that of undertaking some form of load balancing of
incoming traffic across a number of external connections to a number
of different neighbouring ASs. If, for example, an AS wishes to use
a multi-homed configuration for routing-based load balancing and some
form of mutual fail over between the multiple access connections for
incoming traffic, then one approach is for the AS to advertise the
same aggregate address prefix to a number of its upstream transit
providers, and then advertise a number of more specifics to
individual upstream providers. In such a case all of the traffic
destined to the more specific address prefixes will be received only
over those connections where the more specific has been advertised.
If the neighbour BGP peering session of the more specific
advertisement fails, the more specific will cease to be announced and
incoming traffic will then be passed to the originating network based
on the path associated with the advertisement of the encompassing
aggregate. In this situation the more specific routes are not
automatically subsumed by the presence of the aggregate at any remote
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RFC 3765 NOPEER April 2004
AS. Both the aggregate and the associated more specific routes are
redistributed across the entire external BGP routing domain. In many
cases, particularly those associated with desire to undertake traffic
engineering and service resilience, the more specific routes are
redistributed well beyond the scope where there is any outcomes in
terms of traffic differentiation.
To the extent that remote analysis of BGP tables can observe this
form of configuration, the number of entries in the BGP forwarding
table where more specific entries share a common origin AS with their
immediately enclosing aggregates comprise some 20% of the total
number of FIB entries. Using a slightly stricter criteria where the
AS path of the more specific route matches the immediately enclosing
aggregate, the number of more specific routes comprises some 14% of
the number of FIB entries.
One protocol mechanism that could be useful in this context is to
allow the originator of an advertisement to state some additional
qualification on the redistribution of the advertisement, allowing a
remote AS to suppress further redistribution under some originator-
specified criteria.
The redistribution qualification condition can be specified either by
enumeration or by classification. Enumeration would encompass the
use of a well-known transitive extended community to specify a list
of remote AS's where further redistribution is not advised. The
weakness of this approach is that the originating AS would need to
constantly revise this enumerated AS list to reflect the changes in
inter-AS topology, as, otherwise, the more specific routes would leak
beyond the intended redistribution scope. An approach of
classification allows an originating AS to specify the conditions
where further redistribution is not advised without having to refer
to the particular AS's where a match to such conditions are
anticipated.
The approach described here to specifying the redistribution boundary
condition is one based on the type of bilateral inter-AS peering.
Where one AS can be considered as a customer, and the other AS can be
considered as a contracted agent of the customer, or provider, then
the relationship is one where the provider, as an agent of the
customer, carries the routes and associated policy associated with
the routes. Where neither AS can be considered as a customer of the
other, then the relationship is one of bilateral peering, and neither
AS can be considered as an agent of the other in redistributing
policies associated with routes. This latter arrangement is commonly
referred to as a "sender keep all peer" relationship, or "peering".
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This peer boundary can be regarded as a logical point where the
redistribution of additional reachability policy imposed by the
origin AS on a route is no longer an imposed requirement.
This approach allows an originator of a prefix to attach a commonly
defined policy to a route prefix, indicate that a route should be
re-advertised conditionally, based on the characteristics of the
inter-AS connection.
The IANA has registered NOPEER as a well-known community, as defined
in [1], as having global significance.
NOPEER (0xFFFFFF04)
This is an advisory qualification to readvertisement of a route
prefix, permitting an AS not to readvertise the route prefix to all
external bilateral peer neighbour AS's. It is consistent with these
semantics that an AS may filter received prefixes that are received
across a peering session that the receiver regards as a bilateral
peer sessions
BGP is an instance of a relaying protocol, where route information is
received, processed and forwarded. BGP contains no specific
mechanisms to prevent the unauthorized modification of the
information by a forwarding agent, allowing routing information to be
modified, deleted or false information to be inserted without the
knowledge of the originator of the routing information or any of the
recipients.
The NOPEER community does not alter this overall situation concerning
the integrity of BGP as a routing system.
Use of the NOPEER community has the capability to introduce
additional attack mechanisms into BGP by allowing the potential for
man-in-the-middle, session-hijacking, or denial of service attacks
for an address prefix range being launched by a remote AS.
Unauthorized addition of this community to a route prefix by a
transit provider where there is no covering aggregate route prefix
may cause a denial of service attack based on denial of reachability
to the prefix. Even in the case that there is a covering aggregate,
if the more specific route has a different origin AS than the
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RFC 3765 NOPEER April 2004
aggregate, the addition of this community by a transit AS may cause a
denial of service attack on the origin AS of the more specific
prefix.
BGP is already vulnerable to a denial of service attack based on the
injection of false routing information. It is possible to use this
community to limit the redistribution of a false route entry such
that its visibility can be limited and detection and rectification of
the problem can be more difficult under the circumstances of limited
redistribution.
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