GROW Working Group R. Raszuk, Ed.
Internet-Draft NTT MCL
Intended status: Informational R. Fernando
Expires: November 4, 2012 K. Patel
Cisco Systems
D. McPherson
Verisign
K. Kumaki
KDDI Corporation
May 3, 2012
Distribution of diverse BGP paths.
draft-ietf-grow-diverse-bgp-path-dist-07
Abstract
The BGP4 protocol specifies the selection and propagation of a single
best path for each prefix. As defined and widely deployed today BGP
has no mechanisms to distribute alternate paths which are not
considered best path between its speakers. This behaviour results in
number of disadvantages for new applications and services.
This document presents an alternative mechanism for solving the
problem based on the concept of parallel route reflector planes.
Such planes can be built in parallel or they can co-exist on the
current route reflection platforms. Document also compares existing
solutions and proposed ideas that enable distribution of more paths
than just the best path.
This proposal does not specify any changes to the BGP protocol
definition. It does not require upgrades to provider edge or core
routers nor does it need network wide upgrades.
Status of this Memo
This Internet-Draft is submitted in full conformance with the
provisions of BCP 78 and BCP 79.
Internet-Drafts are working documents of the Internet Engineering
Task Force (IETF). Note that other groups may also distribute
working documents as Internet-Drafts. The list of current Internet-
Drafts is at http://datatracker.ietf.org/drafts/current/.
Internet-Drafts are draft documents valid for a maximum of six months
and may be updated, replaced, or obsoleted by other documents at any
time. It is inappropriate to use Internet-Drafts as reference
material or to cite them other than as "work in progress."
Raszuk, et al. Expires November 4, 2012 [Page 1]
Internet-Draft diverse-bgp-path-dist May 2012
This Internet-Draft will expire on November 4, 2012.
Copyright Notice
Copyright (c) 2012 IETF Trust and the persons identified as the
document authors. All rights reserved.
This document is subject to BCP 78 and the IETF Trust's Legal
Provisions Relating to IETF Documents
(http://trustee.ietf.org/license-info) in effect on the date of
publication of this document. Please review these documents
carefully, as they describe your rights and restrictions with respect
to this document. Code Components extracted from this document must
include Simplified BSD License text as described in Section 4.e of
the Trust Legal Provisions and are provided without warranty as
described in the Simplified BSD License.
Raszuk, et al. Expires November 4, 2012 [Page 2]
Internet-Draft diverse-bgp-path-dist May 2012
Table of Contents
1. Introduction . . . . . . . . . . . . . . . . . . . . . . . . . 4
2. History . . . . . . . . . . . . . . . . . . . . . . . . . . . 4
2.1. BGP Add-Paths Proposal . . . . . . . . . . . . . . . . . . 4
3. Goals . . . . . . . . . . . . . . . . . . . . . . . . . . . . 6
4. Multi plane route reflection . . . . . . . . . . . . . . . . . 6
4.1. Co-located best and backup path RRs . . . . . . . . . . . 9
4.2. Randomly located best and backup path RRs . . . . . . . . 11
4.3. Multi plane route servers for Internet Exchanges . . . . . 13
5. Discussion on current models of IBGP route distribution . . . 14
5.1. Full Mesh . . . . . . . . . . . . . . . . . . . . . . . . 14
5.2. Confederations . . . . . . . . . . . . . . . . . . . . . . 15
5.3. Route reflectors . . . . . . . . . . . . . . . . . . . . . 16
6. Deployment considerations . . . . . . . . . . . . . . . . . . 16
7. Summary of benefits . . . . . . . . . . . . . . . . . . . . . 18
8. Applications . . . . . . . . . . . . . . . . . . . . . . . . . 19
9. Security considerations . . . . . . . . . . . . . . . . . . . 19
10. IANA Considerations . . . . . . . . . . . . . . . . . . . . . 19
11. Contributors . . . . . . . . . . . . . . . . . . . . . . . . . 20
12. Acknowledgments . . . . . . . . . . . . . . . . . . . . . . . 20
13. References . . . . . . . . . . . . . . . . . . . . . . . . . . 20
13.1. Normative References . . . . . . . . . . . . . . . . . . . 20
13.2. Informative References . . . . . . . . . . . . . . . . . . 21
Authors' Addresses . . . . . . . . . . . . . . . . . . . . . . . . 22
Raszuk, et al. Expires November 4, 2012 [Page 3]
Internet-Draft diverse-bgp-path-dist May 2012
1. Introduction
Current BGP4 [RFC4271] protocol specification allows for the
selection and propagation of only one best path for each prefix. The
BGP protocol as defined today has no mechanism to distribute other
then best path between its speakers. This behaviour results in a
number of problems in the deployment of new applications and
services.
This document presents an alternative mechanism for solving the
problem based on the concept of parallel route reflector planes. It
also compares existing solutions and proposed ideas that enable
distribution of more paths than just the best path. The parallel
route reflector planes solution brings very significant benefits at a
negligible capex and opex deployment price as compared to the
alternative techniques and is being considered by a number of network
operators for deployment in their networks.
This proposal does not specify any changes to the BGP protocol
definition. It does not require upgrades to provider edge or core
routers nor does it need network wide upgrades. The only upgrade
required is the new functionality on the new or current route
reflectors.
2. History
The need to disseminate more paths than just the best path is
primarily driven by three requirements. First is the problem of BGP
oscillations [I-D.ietf-idr-route-oscillation]. The second is the
desire for faster reachability restoration in the event of network or
network element's failure. Third requirement is to enhance BGP load
balancing capabilities. Those reasons have lead to the proposal of
BGP add-paths [I-D.ietf-idr-add-paths].
2.1. BGP Add-Paths Proposal
As it has been proven that distribution of only the best path of a
route is not sufficient to meet the needs of continuously growing
number of services carried over BGP the add-paths proposal was
submitted in 2002 to enable BGP to distribute more then one path.
This is achieved by including as a part of the NLRI an additional
four octet value called the Path Identifier.
The implication of this change on a BGP implementation is that it
must now maintain per path, instead of per prefix, peer advertisement
state to track which of the peers each path was advertised to. This
new requirement has its own memory and processing cost. Suffice to
Raszuk, et al. Expires November 4, 2012 [Page 4]
Internet-Draft diverse-bgp-path-dist May 2012
say that it took over 9 years for some commercial BGP implementation
to support the new add-path behaviour in production code, in major
part due to this resource overhead.
An important observation is that distribution of more than one best
path by Autonomous System Border Routers (ASBRs) with multiple EBGP
peers attached to it where no "next hop self" is set may result in
bestpath selection inconsistency within the autonomous system.
Therefore it is also required to attach in the form of a new
attribute the possible tie breakers and propagate those within the
domain. The example of such attribute for the purpose of fast
connectivity restoration to address that very case of ASBR injecting
multiple external paths into the IBGP mesh has been presented and
discussed in Fast Connectivity Restoration Using BGP Add-paths
[I-D.ietf-idr-add-paths] document. Based on the additionally
propagated information also best path selection is recommended to be
modified to make sure that best and backup path selection within the
domain stays consistent. More discussion on this particular point
will be contained in the deployment considerations section below. In
the proposed solution in this document we observe that in order to
address most of the applications just use of best external
advertisement is required. For ASBRs which are peering to multiple
upstream ASs setting "next hop self" is recommended.
The add paths protocol extensions have to be implemented by all the
routers within an AS in order for the system to work correctly. It
remains quite a research topic to analyze benefits or risk associated
with partial add-paths deployments. The risk becomes even greater in
networks not using some form of edge to edge encapsulation.
The required code modifications include enhancements such as the Fast
Connectivity Restoration Using BGP Add-path
[I-D.pmohapat-idr-fast-conn-restore]. The deployment of such
technology in an entire service provider network requires software
and perhaps sometimes in the cases of End-of-Engineering or End-of-
Life equipment even hardware upgrades. Such operation may or may not
be economically feasible. Even if add-path functionality was
available today on all commercial routing equipment and across all
vendors, experience indicates that to achieve 100% deployment
coverage within any medium or large global network may easily take
years.
While it needs to be clearly acknowledged that the add-path mechanism
provides the most general way to address the problem of distributing
many paths between BGP speakers, this document provides a much easier
to deploy solution that requires no modification to the BGP protocol
where only a few additional paths may be required. The alternative
method presented is capable of addressing critical service provider
Raszuk, et al. Expires November 4, 2012 [Page 5]
Internet-Draft diverse-bgp-path-dist May 2012
requirements for disseminating more than a single path across an AS
with a significantly lower deployment cost what in the light of set
general network scaling concerns documented in RFC4984 [RFC4271]
"Report from the IAB Workshop on Routing and Addressing" may provide
a significant advantage.
3. Goals
The proposal described in this document is not intended to compete
with add-paths. Instead if deployed it is to be used as a very easy
method to accommodate the majority of applications which may require
presence of alternative BGP exit points.
It is presented to network operators as a possible choice and
provides those operators who need additional paths today an
alternative from the need to transition to a full mesh.
It is intended as a way to buy more time allowing for a smoother and
gradual migration where router upgrades will be required for perhaps
different reasons. It will also allow the time required where
standard RP/RE memory size can easily accommodate the associated
overhead with other techniques without any compromises.
4. Multi plane route reflection
The idea contained in the proposal assumes the use of route
reflection within the network. Other techniques as described in the
following sections already provide means for distribution of
alternate paths today.
Raszuk, et al. Expires November 4, 2012 [Page 6]
Internet-Draft diverse-bgp-path-dist May 2012
Let's observe today's picture of simple route reflected domain:
ASBR3
***
* *
+------------* *-----------+
| AS1 * * |
| *** |
| |
| |
| |
| RR1 *** RR2 |
| *** * * *** |
|* * * P * * *|
|* * * * * *|
| *** *** *** |
| |
| IBGP |
| |
| |
| *** *** |
| * * * * |
+-----* *---------* *----+
* * * *
*** ***
ASBR1 ASBR2
EBGP
Figure1: Simple route reflection
Figure 1 shows an AS that is connected via EBGP peering at ASBR1 and
ASBR2 to an upstream AS or set of ASes. For a given destination "D"
ASBR1 and ASBR2 will each have an external path P1 and P2
respectively. The AS network uses two route reflectors RR1 and RR2
for redundancy reasons. The route reflectors propagate the single
BGP best path for each route to all clients. All ASBRs are clients
of RR1 and RR2.
Below are the possible cases of the path information that ASBR3 may
receive from route reflectors RR1 and RR2:
1. When best path tie breaker is the IGP distance: When paths P1 and
P2 are considered to be equally good best path candidates the
selection will depend on the distance of the path next-hops from
the route reflector making the decision. Depending on the
positioning of the route reflectors in the IGP topology they may
choose the same best path or a different one. In such a case
Raszuk, et al. Expires November 4, 2012 [Page 7]
Internet-Draft diverse-bgp-path-dist May 2012
ASBR3 may receive either the same path or different paths from
each of the route reflectors.
2. When best path tie breaker is Multi-Exit-Discriminator or Local
Preference: In this case only one path from preferred exit point
ASBR will be available to RRs since the other peering ASBR will
consider the IBGP path as best and will not announce (or if
already announced will withdraw) its own external path. The
exception here is the use of BGP Best-External proposal which
will allow stated ASBR to still propagate to the RRs its own
external path. Unfortunately RRs will not be able to distribute
it any further to other clients as only the overall best path
will be reflected.
The proposed solution is based on the use of additional route
reflectors or new functionality enabled on the existing route
reflectors that instead of distributing the best path for each route
will distribute an alternative path other then best. The best path
(main) reflector plane distributes the best path for each route as it
does today. The second plane distributes the second best path for
each route and so on. Distribution of N paths for each route can be
achieved by using N reflector planes.
As diverse-path functionality may be enabled on a per peer basis one
of the deployment model can be realized to continue advertisement of
overall best path from both route reflectors while in addition new
session can be provisioned to get additional path. That will allow
the non interupted use of best path even if one of the RRs goes down
provided that the overall best path is still a valid one.
Each plane of route reflectors is a logical entity and may or may not
be co-located with the existing best path route reflectors. Adding a
route reflector plane to a network may be as easy as enabling a
logical router partition, new BGP process or just a new configuration
knob on an existing route reflector and configuring an additional
IBGP session from the current clients if required. There are no code
changes required on the route reflector clients for this mechanism to
work. It is easy to observe that the installation of one or more
additional route reflector control planes is much cheaper and an
easier than the need of upgrading 100s of route reflector clients in
the entire network to support different bgp protocol encoding.
Diverse path route reflectors need the new ability to calculate and
propagate the Nth best path instead of the overall best path. An
implementation is encouraged to enable this new functionality on a
per neighbor basis.
While this is an implementation detail, the code to calculate Nth
Raszuk, et al. Expires November 4, 2012 [Page 8]
Internet-Draft diverse-bgp-path-dist May 2012
best path is also required by other BGP solutions. For example in
the application of fast connectivity restoration BGP must calculate a
backup path for installation into the RIB and FIB ahead of the actual
failure.
To address the problem of external paths not being available to route
reflectors due to local preference or MED factors it is recommended
that ASBRs enable the best-external functionality in order to always
inject their external paths to the route reflectors.
4.1. Co-located best and backup path RRs
To simplify the description let's assume that we only use two route
reflector planes (N=2). When co-located the additional 2nd best path
reflectors are connected to the network at the same points from the
perspective of the IGP as the existing best path RRs. Let's also
assume that best-external is enabled on all ASBRs.
ASBR3
***
* *
+------------* *-----------+
| AS1 * * |
| *** |
| |
| RR1 RR2 |
| *** *** |
|* * *** * *|
|* * * * * *|
| *** * P * *** |
|* * * * * *|
|* * *** * *|
| *** *** |
| RR1' IBGP RR2'|
| |
| |
| *** *** |
| * * * * |
+-----* *---------* *----+
* * * *
*** ***
ASBR1 ASBR2
EBGP
Figure2: Co-located 2nd best RR plane
Raszuk, et al. Expires November 4, 2012 [Page 9]
Internet-Draft diverse-bgp-path-dist May 2012
The following is a list of configuration changes required to enable
the 2nd best path route reflector plane:
1. Unless same RR1/RR2 platform is being used adding RR1' and RR2'
either as logical or physical new control plane RRs in the same
IGP points as RR1 and RR2 respectively.
2. Enabling best-external on ASBRs
3. Enabling RR1' and RR2' for 2nd plane route reflection.
Alternatively instructing existing RR1 and RR2 to calculate also
2nd best path.
4. Unless one of the existing RRs is turned to advertise only
diverse path to it's current clients configuring new ASBRs-RR'
IBGP sessions
The expected behaviour is that under any BGP condition the ASBR3 and
P routers will receive both paths P1 and P2 for destination D. The
availability of both paths will allow them to implement a number of
new services as listed in the applications section below.
As an alternative to fully meshing all RRs and RRs' an operator who
has a large number of reflectors deployed today may choose to peer
newly introduced RRs' to a hierarchical RR' which would be an IBGP
interconnect point within the 2nd plane as well as between planes.
One of the deployment model of this scenario can be achieved by
simple upgrade of the existing route reflectors without the need to
deploy any new logical or physical platforms. Such upgrade would
allow route reflectors to service both upgraded to add-paths peers as
well as those peers which can not be immediately upgraded while in
the same time allowing to distribute more then single best path. The
obvious protocol benefit of using existing RRs to distribute towards
their clients best and diverse bgp paths over different IBGP session
is the automatic assurance that such client would always get
different paths with their next hop being different.
The way to accomplish this would be to create a separate IBGP session
for each N-th BGP path. Such session should be preferably terminated
at a different loopback address of the route reflector. At the BGP
OPEN stage of each such session a different bgp_router_id may be
used. Correspondingly route reflector should also allow its clients
to use the same bgp_router_id on each such session.
Raszuk, et al. Expires November 4, 2012 [Page 10]
Internet-Draft diverse-bgp-path-dist May 2012
4.2. Randomly located best and backup path RRs
Now let's consider a deployment case where an operator wishes to
enable a 2nd RR' plane using only a single additional router in a
different network location to his current route reflectors. This
model would be of particular use in networks where some form of end-
to-end encapsulation (IP or MPLS) is enabled between provider edge
routers.
Note that this model of operation assumes that the present best path
route reflectors are only control plane devices. If the route
reflector is in the data forwarding path then the implementation must
be able to clearly separate the Nth best-path selection from the
selection of the paths to be used for data forwarding. The basic
premise of this mode of deployment assumes that all reflector planes
have the same information to choose from which includes the same set
of BGP paths. It also requires the ability to ignore the step of
comparison of the IGP metric to reach the bgp next hop during best-
path calculation.
Raszuk, et al. Expires November 4, 2012 [Page 11]
Internet-Draft diverse-bgp-path-dist May 2012
ASBR3
***
* *
+------------* *-----------+
| AS1 * * |
| IBGP *** |
| |
| *** |
| * * |
| RR1 * P * RR2 |
| *** * * *** |
|* * *** * *|
|* * * *|
| *** RR' *** |
| *** |
| * * |
| * * |
| *** |
| *** *** |
| * * * * |
+-----* *---------* *----+
* * * *
*** ***
ASBR1 ASBR2
EBGP
Figure3: Experimental deployment of 2nd best RR
The following is a list of configuration changes required to enable
the 2nd best path route reflector RR' as a single platform or to
enable one of the existing control plane RRs for diverse-path
functionality:
1. If needed adding RR' logical or physical as new route reflector
anywhere in the network
2. Enabling best-external on ASBRs
3. Disabling IGP metric check in BGP best path on all route
reflectors.
4. Enabling RR' or any of the existing RR for 2nd plane path
calculation
5. If required fully meshing newly added RRs' with the all other
reflectors in both planes. That condition does not apply if the
Raszuk, et al. Expires November 4, 2012 [Page 12]
Internet-Draft diverse-bgp-path-dist May 2012
newly added RR'(s) already have peering to all ASBRs/PEs.
6. Unless one of the existing RRs is turned to advertise only
diverse path to it's current clients configuring new ASBRs-RR'
IBGP sessions
In this scenario the operator has the flexibility to introduce the
new additional route reflector functionality on any existing or new
hardware in the network. Any of the existing routers that are not
already members of the best path route reflector plane can be easily
configured to serve the 2nd plane either via using a logical /
virtual router partition or by having their bgp implementation
compliant to this specification.
Even if the IGP metric is not taken into consideration when comparing
paths during the bestpath calculation, an implementation still has to
consider paths with unreachable nexthops as invalid. It is worth
pointing out that some implementations today already allow for
configuration which results in no IGP metric comparison during the
best path calculation.
The additional planes of route reflectors do not need to be fully
redundant as the primary one does. If we are preparing for a single
network failure event, a failure of a non backed up N-th best-path
route reflector would not result in an connectivity outage of the
actual data plane. The reason is that this would at most affect the
presence of a backup path (not an active one) on same parts of the
network. If the operator chooses to create the N-th best path plane
redundantly by installing not one, but two or more route reflectors
serving each additional plane the additional robustness will be
achieved.
As a result of this solution ASBR3 and other ASBRs peering to RR'
will be receiving the 2nd best path.
Similarly to section 4.1 as an alternative to fully meshing all RRs &
RRs' an operator who may have a large number of reflectors already
deployed today may choose to peer newly introduced RRs' to a
hierarchical RR' which would be an IBGP interconnect point between
planes.
4.3. Multi plane route servers for Internet Exchanges
Another group of devices where the proposed multi-plane architecture
may be of particular applicability are EBGP route servers used at
many of internet exchange points.
In such cases 100s of ISPs are interconnected on a common LAN.
Raszuk, et al. Expires November 4, 2012 [Page 13]
Internet-Draft diverse-bgp-path-dist May 2012
Instead of having 100s of direct EBGP sessions on each exchange
client, a single peering is created to the transparent route server.
The route server can only propagate a single best path. Mandating
the upgrade for 100s of different service providers in order to
implement add-path may be much more difficult as compared to asking
them for provisioning one new EBGP session to an Nth best-path route
server plane. That will allow to distribute more then single best
BGP path from a given route server to such IX peer.
The solution proposed in this document fits very well with the
requirement of having broader EBGP path diversity among the members
of any Internet Exchange Point.
5. Discussion on current models of IBGP route distribution
In today's networks BGP4 operates as specified in [RFC4271]
There are a number of technology choices for intra-AS BGP route
distribution:
1. Full mesh
2. Confederations
3. Route reflectors
5.1. Full Mesh
A full mesh, the most basic iBGP architecture, exists when all the
BGP speaking routers within the AS peer directly with all other BGP
speaking routers within the AS, irrespective of where a given router
resides within the AS (e.g., P router, PE router, etc..).
While this is the simplest intra-domain path distribution method,
historically there have been a number of challenges in realizing such
an IBGP full mesh in a large scale network. While some of these
challenges are no longer applicable today some may still apply, to
include the following:
1. Number of TCP sessions: The number of IBGP sessions on a single
router in a full mesh topology of a large scale service provider
can easily reach 100s. While on hardware and software used in
the late 70s, 80s and 90s such numbers could be of concern, today
customer requirements for the number of BGP sessions per box are
reaching 1000s. This is already an order of magnitude more then
the potential number of IBGP sessions. Advancement in hardware
and software used in production routers mean that running a full
Raszuk, et al. Expires November 4, 2012 [Page 14]
Internet-Draft diverse-bgp-path-dist May 2012
mesh of IBGP sessions should not be dismissed due to the
resulting number of TCP sessions alone.
2. Provisioning: When operating and troubleshooting large networks
one of the top-most requirements is to keep the design as simple
as possible. When the autonomous systems network is composed of
hundreds of nodes it becomes very difficult to manually provision
a full mesh of IBGP sessions. Adding or removing a router
requires reconfiguration of all the other routers in the AS.
While this is a real concern today there is already work in
progress in the IETF to define IBGP peering automation through an
IBGP Auto Discovery [I-D.raszuk-idr-ibgp-auto-mesh] mechanism.
3. Number of paths: Another concern when deploying a full IBGP mesh
is the number of BGP paths for each route that have to be stored
at every node. This number is very tightly related to the number
of external peerings of an AS, the use of local preference or
multi-exit-discriminator techniques and the presence of best-
external [I-D.ietf-idr-best-external] advertisement
configuration. If we make a rough assumption that the BGP4 path
data structure consumes about 80-100 bytes the resulting control
plane memory requirement for 500,000 IPv4 routes with one
additional external path is 38-48 MB while for 1 million IPv4
routes it grows linearly to 76-95 MB. It is not possible to
reach a general conclusion if this condition is negligible or if
it is a show stopper for a full mesh deployment without direct
reference to a given network.
To summarize, a full mesh IBGP peering can offer natural
dissemination of multiple external paths among BGP speakers. When
realized with the help of IBGP Auto Discovery peering automation this
seems like a viable deployment especially in medium and small scale
networks.
5.2. Confederations
For the purpose of this document let's observe that confederations
[RFC5065] can be viewed as a hierarchical full mesh model.
Within each sub-AS BGP speakers are fully meshed and as discussed in
section 2.1 all full mesh characteristics (number of TCP sessions,
provisioning and potential concern over number of paths still apply
in the sub-AS scale).
In addition to the direct peering of all BGP speakers within each
sub-AS, all sub-AS border routers must also be fully meshed with each
other. Sub-AS border routers configured with best-external
functionality can inject additional exit paths within a sub-AS.
Raszuk, et al. Expires November 4, 2012 [Page 15]
Internet-Draft diverse-bgp-path-dist May 2012
To summarize, it is technically sound to use confederations with the
combination of best-external to achieve distribution of more than a
single best path per route in a large autonomous systems.
In topologies where route reflectors are deployed within the
confederation sub-ASes the technique describe here does apply.
5.3. Route reflectors
The main motivation behind the use of route reflectors [RFC4456] is
the avoidance of the full mesh session management problem described
above. Route reflectors, for good or for bad, are the most common
solution today for interconnecting BGP speakers within an internal
routing domain.
Route reflector peerings follow the advertisement rules defined by
the BGP4 protocol. As a result only a single best path per prefix is
sent to client BGP peers. That is the main reason why many current
networks are exposed to a phenomenon called BGP path starvation which
essentially results in inability to deliver a number of applications
discussed later.
The route reflection equivalent when interconnecting BGP speakers
between domains is popularly called the Route Server and is globally
deployed today in many internet exchange points.
6. Deployment considerations
The diverse BGP path dissemination proposal allows the distribution
of more paths than just the best-path to route reflector or route
server clients of today's BGP4 implementations. As deployment
recommendation it needs to be mentioned that fast connectivty
restoration as well as majority of intra-domain BGP level load
balancing needs can be accomodated with only two paths (overall best
as well as second best). Therefor as deployment recommendation this
document suggests use of N=2 with diverse-path.
From the client's point of view receiving additional paths via
separate IBGP sessions terminated at the new router reflector plane
is functionally equivalent to constructing a full mesh peering
without the problems that such a full mesh would come with set of
problems as discussed in earlier section.
By precisely defining the number of reflector planes, network
operators have full control over the number of redundant paths in the
network. This number can be defined to address the needs of the
service(s) being deployed.
Raszuk, et al. Expires November 4, 2012 [Page 16]
Internet-Draft diverse-bgp-path-dist May 2012
The Nth plane route reflectors should be acting as control plane
network entities. While they can be provisioned on the current
production routers selected Nth best BGP paths should not be used
directly in the date plane with the exception of such paths being BGP
multipath eligible and such functionality is enabled. On RRs being
in the data plane unless multipath is enabled 2nd best path is
expected to be a backup path and should be installed as such into
local RIB/FIB.
The use of terminology of "planes" in this document is more of a
conceptual nature. In practice all paths are still kept in the
single table where normal best path is calculated. That means that
tools like looking glass should not observe any changes nor impact
when diverse-path has been enabled.
The proposed architecture deployed along with the BGP best-external
functionality covers all three cases where the classic BGP route
reflection paradigm would fail to distribute alternate exit points
paths.
1. ASBRs advertising their single best external paths with no local-
preference or multi-exit-discriminator present.
2. ASBRs advertising their single best external paths with local-
preference or multi-exit-discriminator present and with BGP best-
external functionality enabled.
3. ASBRs with multiple external paths.
Let's discuss the 3rd above case in more detail. This describes the
scenario of a single ASBR connected to multiple EBGP peers. In
practice this peering scenario is quite common. It is mostly due to
the geographic location of EBGP peers and the diversity of those
peers (for example peering to multiple tier 1 ISPs etc...). It is
not designed for failure recovery scenarios as single failure of the
ASBR would simultaneously result in loss of connectivity to all of
the peers. In most medium and large geographically distributed
networks there is always another ASBR or multiple ASBRs providing
peering backups, typically in other geographically diverse locations
in the network.
When an operator uses ASBRs with multiple peerings setting next hop
self will effectively allow to locally repair the atomic failure of
any external peer without any compromise to the data plane. The most
common reason for not setting next hop self is traditionally the
associated drawback of loosing ability to signal the external
failures of peering ASBRs or links to those ASBRs by fast IGP
flooding. Such potential drawback can be easily avoided by using
Raszuk, et al. Expires November 4, 2012 [Page 17]
Internet-Draft diverse-bgp-path-dist May 2012
different peering address from the address used for next hop mapping
as well as removing such next hop from IGP at the last possible BGP
path failure.
Herein one may correctly observe that in the case of setting next hop
self on an ASBR, attributes of other external paths such ASBR is
peering with may be different from the attributes of its best
external path. Therefore, not injecting all of those external paths
with their corresponding attribute can not be compared to equivalent
paths for the same prefix coming from different ASBRs.
While such observation in principle is correct one should put things
in perspective of the overall goal which is to provide data plane
connectivity upon a single failure with minimal interruption/packet
loss. During such transient conditions, using even potentially
suboptimal exit points is reasonable, so long as forwarding
information loops are not introduced. In the mean time BGP control
plane will on its own re-advertise newly elected best external path,
route reflector planes will calculate their Nth best paths and
propagate to its clients. The result is that after seconds even if
potential sub-optimality were encountered it will be quickly and
naturally healed.
7. Summary of benefits
The diverse BGP path dissemination proposal provides the following
benefits when compared to the alternatives:
1. No modifications to BGP4 protocol.
2. No requirement for upgrades to edge and core routers. Backward
compatible with the existing BGP deployments.
3. Can be easily enabled by introduction of a new route reflector,
route server plane dedicated to the selection and distribution of
Nth best-path or just by new configuration of the upgraded
current route reflector(s).
4. Does not require major modification to BGP implementations in the
entire network which will result in an unnecessary increase of
memory and CPU consumption due to the shift from today's per
prefix to a per path advertisement state tracking.
5. Can be safely deployed gradually on a RR cluster basis.
6. The proposed solution is equally applicable to any BGP address
family as described in Multiprotocol Extensions for BGP-4 RFC4760
Raszuk, et al. Expires November 4, 2012 [Page 18]
Internet-Draft diverse-bgp-path-dist May 2012
[RFC4760]. In particular it can be used "as is" without any
modifications to both IPv4 and IPv6 address families.
8. Applications
This section lists the most common applications which require
presence of redundant BGP paths:
1. Fast connectivity restoration where backup paths with alternate
exit points would be pre-installed as well as pre-resolved in the
FIB of routers. That would allow for a local action upon
reception of a critical event notification of network / node
failure. This failure recovery mechaism based on the presence of
backup paths is also suitable for gracefully addressing scheduled
maintenane requirements as described in
[I-D.decraene-bgp-graceful-shutdown-requirements].
2. Multi-path load balancing for both IBGP and EBGP.
3. BGP control plane churn reduction both intra-domain and inter-
domain.
An important point to observe is that all of the above intra-domain
applications based on the use of reflector planes but are also
applicable in the inter-domain Internet exchange point examples. As
discussed in section 4.3 an internet exchange can conceptually deploy
shadow route server planes each responsible for distribution of an
Nth best path to its EBGP peers. In practice it may just equal to
new short configuration and establishment of new BGP sessions to IX
peers.
9. Security considerations
The new mechanism for diverse BGP path dissemination proposed in this
document does not introduce any new security concerns as compared to
base BGP4 specification [RFC4271].
10. IANA Considerations
The new mechanism for diverse BGP path dissemination does not require
any new allocations from IANA.
Raszuk, et al. Expires November 4, 2012 [Page 19]
Internet-Draft diverse-bgp-path-dist May 2012
11. Contributors
The following people contributed significantly to the content of the
document:
Selma Yilmaz
Cisco Systems
170 West Tasman Drive
San Jose, CA 95134
US
Email: seyilmaz@cisco.com
Satish Mynam
Cisco Systems
170 West Tasman Drive
San Jose, CA 95134
US
Email: mynam@cisco.com
Isidor Kouvelas
Cisco Systems
170 West Tasman Drive
San Jose, CA 95134
US
Email: kouvelas@cisco.com
12. Acknowledgments
The authors would like to thank Bruno Decraene, Bart Peirens, Eric
Rosen, Jim Uttaro, Renwei Li and Wes George for their valuable input.
The authors would also like to express special thank you to number of
operators who helped to optimize the provided solution to be as close
as possible to their daily operational practices. Especially many
thx goes to Ted Seely, Shan Amante, Benson Schliesser and Seiichi
Kawamura.
13. References
13.1. Normative References
[RFC2119] Bradner, S., "Key words for use in RFCs to Indicate
Requirement Levels", BCP 14, RFC 2119, March 1997.
Raszuk, et al. Expires November 4, 2012 [Page 20]
Internet-Draft diverse-bgp-path-dist May 2012
[RFC4271] Rekhter, Y., Li, T., and S. Hares, "A Border Gateway
Protocol 4 (BGP-4)", RFC 4271, January 2006.
[RFC4760] Bates, T., Chandra, R., Katz, D., and Y. Rekhter,
"Multiprotocol Extensions for BGP-4", RFC 4760,
January 2007.
[RFC5226] Narten, T. and H. Alvestrand, "Guidelines for Writing an
IANA Considerations Section in RFCs", BCP 26, RFC 5226,
May 2008.
13.2. Informative References
[I-D.decraene-bgp-graceful-shutdown-requirements]
Decraene, B., Francois, P., pelsser, c., Ahmad, Z., and A.
Armengol, "Requirements for the graceful shutdown of BGP
sessions",
draft-decraene-bgp-graceful-shutdown-requirements-01 (work
in progress), March 2009.
[I-D.ietf-idr-add-paths]
Walton, D., Chen, E., Retana, A., and J. Scudder,
"Advertisement of Multiple Paths in BGP",
draft-ietf-idr-add-paths-06 (work in progress),
September 2011.
[I-D.ietf-idr-best-external]
Marques, P., Fernando, R., Chen, E., Mohapatra, P., and H.
Gredler, "Advertisement of the best external route in
BGP", draft-ietf-idr-best-external-05 (work in progress),
January 2012.
[I-D.ietf-idr-route-oscillation]
McPherson, D., "BGP Persistent Route Oscillation
Condition", draft-ietf-idr-route-oscillation-01 (work in
progress), February 2002.
[I-D.pmohapat-idr-fast-conn-restore]
Mohapatra, P., Fernando, R., Filsfils, C., and R. Raszuk,
"Fast Connectivity Restoration Using BGP Add-path",
draft-pmohapat-idr-fast-conn-restore-02 (work in
progress), October 2011.
[I-D.raszuk-idr-ibgp-auto-mesh]
Raszuk, R., "IBGP Auto Mesh",
draft-raszuk-idr-ibgp-auto-mesh-00 (work in progress),
June 2003.
Raszuk, et al. Expires November 4, 2012 [Page 21]
Internet-Draft diverse-bgp-path-dist May 2012
[RFC4456] Bates, T., Chen, E., and R. Chandra, "BGP Route
Reflection: An Alternative to Full Mesh Internal BGP
(IBGP)", RFC 4456, April 2006.
[RFC4984] Meyer, D., Zhang, L., and K. Fall, "Report from the IAB
Workshop on Routing and Addressing", RFC 4984,
September 2007.
[RFC5065] Traina, P., McPherson, D., and J. Scudder, "Autonomous
System Confederations for BGP", RFC 5065, August 2007.
Authors' Addresses
Robert Raszuk (editor)
NTT MCL
101 S Ellsworth Avenue Suite 350
San Mateo, CA 94401
US
Email: robert@raszuk.net
Rex Fernando
Cisco Systems
170 West Tasman Drive
San Jose, CA 95134
US
Email: rex@cisco.com
Keyur Patel
Cisco Systems
170 West Tasman Drive
San Jose, CA 95134
US
Email: keyupate@cisco.com
Raszuk, et al. Expires November 4, 2012 [Page 22]
Internet-Draft diverse-bgp-path-dist May 2012
Danny McPherson
Verisign
21345 Ridgetop Circle
Dulles, VA 20166
US
Email: dmcpherson@verisign.com
Kenji Kumaki
KDDI Corporation
Garden Air Tower
Iidabashi, Chiyoda-ku, Tokyo 102-8460
Japan
Email: ke-kumaki@kddi.com
Raszuk, et al. Expires November 4, 2012 [Page 23]