Route reflector: Difference between revisions
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A '''route reflector''' is a technique for interconnecting | A '''route reflector''' is a technique for interconnecting Border Gateway Protocol (BGP) routers, inside an [[autonomous system]], to improve scalability. One of the major scalability problems of BGP running over TCP is that TCP takes a substantial amount of processing, as can the per-interface issues of BGP setup, advertising, and acceptance. Two techniques, route reflectors and BGP confederations can reduce the need for the high overhead of full meshing. The methods can be used in conjunction with one another. | ||
BGP Route Reflection: An Alternative to Full Mesh Internal BGP (IBGP) | ===Architecture=== | ||
The basic rule of iBGP is that all BGP speakers within an AS must peer with one another, which leads to an exponential growth of BGP sessions. Session maintenance, both of the BGP session proper and the [[Transmission Control Protocol|TCP]] connection over which it runs, are processor-intensive and may require more powerful router [[control plane]] hardware. | |||
BGP route reflector introduce hierarchy, a well-recognized means of scaling, into iBGP. '''Route reflector clusters''' have at least one '''route reflector''' that acts as a server to other iBGP speakers within the cluster, and some number of '''route reflector clients'''. There must be full iBGP meshing inside the cluster, but only the route reflector server needs to peer, via iBGP, with other iBGP speakers (including other clusters) inside the AS. <ref name=RFC4456>{{citation | |||
| title = BGP Route Reflection: An Alternative to Full Mesh Internal BGP (IBGP) | |||
| author = Bates T., Chen E., Chandra R. | |||
| date = April 2006 | |||
| id = RFC4456 | |||
| url = http://www.ietf.org/rfc/rfc4456.txt}}</ref>Route reflection improves iBGP scalability by removing the need to have a full mesh of BGP sessions among all routers in the AS; it allows the creation of hierarchies of routers, with full mesh only on the "route servers" in each "cluster" of BGP speakers. | |||
==Basic cluster structure== | ==Basic cluster structure== | ||
A basic cluster has a reflector that connects, in a full mesh, to all other iBGP nodes not in clusters, and some number of route reflector clients, which have iBGP sessions with the reflector but none outside the reflector cluster. | |||
==Fault tolerance== | ==Fault tolerance== | ||
To improve fault tolerance, there can be more than one reflector. The reflectors have iBGP sessions with one another, and with each client. | |||
==Hierarchies of clusters== | ==Hierarchies of clusters== | ||
A reflector in one cluster can simultaneously be a client in a hierarchically higher cluster, as long as the protocol messages in each cluster are disambiguated with a cluster identifier parameter. | |||
==Pathologies of route reflection== | ==Pathologies of route reflection== | ||
<ref>Border Gateway Protocol (BGP) Persistent Route Oscillation Condition | Both major techniques can suffer from instability <ref name=RFC1997>{{citation | ||
| title = Border Gateway Protocol (BGP) Persistent Route Oscillation Condition | |||
| author = D. McPherson ''et al.'' | |||
| date = August 2002 | |||
| id = RFC3544 | |||
| url = http://www.ietf.org/rfc/rfc3544.txt}}</ref> unless you use an [[OSPF]]-like rule. In OSPF, intra-area routes are always preferred, regardless of metric. The equivalent, for avoiding oscillation, is always to prefer cluster-local or confederation-internal routes. | |||
==Route reflectors and confederations== | ==Route reflectors and confederations== | ||
While both techniques allow increased iBGP scalability, they do it in different ways, and indeed the two techniques may be used in the same AS. Confederations give more policy control than do route reflectors, but with greater complexity. | While both techniques allow increased iBGP scalability, they do it in different ways, and indeed the two techniques may be used in the same AS. Confederations give more policy control than do route reflectors, but with greater complexity and overhead. It is perfectly reasonable, however, to have route reflector clusters, or even hierarchies of clusters, inside confederation-specific [[autonomous system]]s. | ||
==References== | ==References== | ||
{{reflist}} | {{reflist|2}}[[Category:Suggestion Bot Tag]] |
Latest revision as of 16:00, 13 October 2024
A route reflector is a technique for interconnecting Border Gateway Protocol (BGP) routers, inside an autonomous system, to improve scalability. One of the major scalability problems of BGP running over TCP is that TCP takes a substantial amount of processing, as can the per-interface issues of BGP setup, advertising, and acceptance. Two techniques, route reflectors and BGP confederations can reduce the need for the high overhead of full meshing. The methods can be used in conjunction with one another.
Architecture
The basic rule of iBGP is that all BGP speakers within an AS must peer with one another, which leads to an exponential growth of BGP sessions. Session maintenance, both of the BGP session proper and the TCP connection over which it runs, are processor-intensive and may require more powerful router control plane hardware.
BGP route reflector introduce hierarchy, a well-recognized means of scaling, into iBGP. Route reflector clusters have at least one route reflector that acts as a server to other iBGP speakers within the cluster, and some number of route reflector clients. There must be full iBGP meshing inside the cluster, but only the route reflector server needs to peer, via iBGP, with other iBGP speakers (including other clusters) inside the AS. [1]Route reflection improves iBGP scalability by removing the need to have a full mesh of BGP sessions among all routers in the AS; it allows the creation of hierarchies of routers, with full mesh only on the "route servers" in each "cluster" of BGP speakers.
Basic cluster structure
A basic cluster has a reflector that connects, in a full mesh, to all other iBGP nodes not in clusters, and some number of route reflector clients, which have iBGP sessions with the reflector but none outside the reflector cluster.
Fault tolerance
To improve fault tolerance, there can be more than one reflector. The reflectors have iBGP sessions with one another, and with each client.
Hierarchies of clusters
A reflector in one cluster can simultaneously be a client in a hierarchically higher cluster, as long as the protocol messages in each cluster are disambiguated with a cluster identifier parameter.
Pathologies of route reflection
Both major techniques can suffer from instability [2] unless you use an OSPF-like rule. In OSPF, intra-area routes are always preferred, regardless of metric. The equivalent, for avoiding oscillation, is always to prefer cluster-local or confederation-internal routes.
Route reflectors and confederations
While both techniques allow increased iBGP scalability, they do it in different ways, and indeed the two techniques may be used in the same AS. Confederations give more policy control than do route reflectors, but with greater complexity and overhead. It is perfectly reasonable, however, to have route reflector clusters, or even hierarchies of clusters, inside confederation-specific autonomous systems.
References
- ↑ Bates T., Chen E., Chandra R. (April 2006), BGP Route Reflection: An Alternative to Full Mesh Internal BGP (IBGP), RFC4456
- ↑ D. McPherson et al. (August 2002), Border Gateway Protocol (BGP) Persistent Route Oscillation Condition, RFC3544