INTERNET-DRAFT Enke Chen
<draft-ietf-idr-symm-multi-prov-02.txt> Tony Bates
MCI
January 1996
Expires in six months
Current Practice of Implementing
Symmetric Routing and Load Sharing
in the Multi-Provider Internet
<draft-ietf-idr-symm-multi-prov-02.txt>
Status of this Memo
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Abstract
In the current multi-provider Internet, it is common for an entity to
have multiple service providers. Symmetric routing becomes
increasingly important for various reasons. This memo documents and
analyzes the current practice in implementing symmetric inter-domain
routing using BGP for several representative topologies of Internet
connections.
1. Introduction
In the multi-provider Internet, it is common for an entity to have
multiple connections to the Internet. For example,
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o A Regional Service Provider (RSP) may be connected to multiple
transit Internet Service Providers (ISPs).
o A service subscriber may be connected to multiple RSPs or ISPs.
o Subscribers of different providers may wish to backup each
other.
These connections would provide for the capability of load sharing,
path diversification and backup. The Internet is a mesh of ISPs,
RSPs and service subscribers and is generally sparsely connected.
Symmetric routing is generally preferred as it facilitates problem
resolution, and provides for better resource (especially network
capacity) planning and utilization. Routing symmetry is also desir-
able in achieving optimal traffic flow in terms of reliability, delay
character, cost and other QoS metrics. Several applications such as
NTP, RSVP and MBONE rely upon routing symmetry. In the multi-
provider Internet, routing asymmetry, especially at the inter-domain
level, may have serious economic and legal ramifications.
This paper presents several representative topologies of Internet
connection and their inter-domain routing requirements. It then doc-
uments and analyzes the current practice in implementing symmetric
inter-domain routing in these cases using BGP.
This paper assumes that in general an ISP treats other ISPs equally
(in terms of the "local_pref" parameter) in the route selection pro-
cess. It also assumes that the following order of preference is fol-
lowed for the purpose of route selection: first the "local_pref"
parameter, followed by the shortest AS-path, the MED, and the IGP
metric.
It is noted that the length of the AS-path has not been specified in
the BGP document [1] as a route selection criteria. However, it has
been included in more than one implementations, and has been widely
used as such.
2. Internet Connection and Routing
The Internet is a mesh of transit Internet Service Providers (ISPs),
Regional Service Providers (RSPs), and service subscribers. In gen-
eral this mesh is rather sparsely connected with loose hierarchy. In
the multi-provider Internet, a good routing plan for an entity (i.e.,
autonomous system) requires good understanding of its internal net-
work topology, its connection to direct providers (and neighboring
ASs), and its path to the major interconnection points (or network
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access points, NAPs).
In this section, we present several typical topologies of Internet
connections, and their inter-domain routing requirements. Although
these cases are not meant to be exhaustive, they are expected to
cover the vast majority of Internet connection topologies.
2.1 An Entity with a Single Direct Provider
+-----+ +-----+ +-----+
| ISP | | ISP | | ISP |
+-----+ +-----+ +-----+
| | |
+-----+ +-----+ +-----+
| AS1 | | RSP | | RSP |
+-----+ +-----+ +-----+
|
+-----+
| AS1 |
+-----+
(a) (b) (c)
Figure 1
The routing is always symmetric at the inter-domain level. Routing
policies can be achieved using the current version of BGP. AS1 can
either take full routing or use default.
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2.2 Backup of Entities with Different Direct Providers
Several topologies are shown in Figure 2. Both AS1 and AS2 have
their direct provider(s), and they would like to backup each other.
That is, if the link between AS1 and its direct provider is down, the
link between AS1 and AS2 would be used to reach the Internet.
+-----+ +------+ +------+
| ISP | | ISP3 | | ISP3 |
+-----+ +------+ +------+
/ \ / \ / \
/ \ / (NAP) \ / (NAP) \
+-----+ +-----+ +------+ +------+ +------+ +------+
| AS1 |----| AS2 | | ISP1 |------| ISP2 | | ISP1 |-------| ISP2 |
+-----+ +-----+ +------+ +------+ +------+ +------+
| | | |
+------+ +------+ +------+ +------+
| AS1 |------| AS2 | | RSP1 | | RSP2 |
+------+ +------+ +------+ +------+
| |
+------+ +------+
| AS1 |------| AS2 |
+------+ +------+
(a) (b) (c)
Figure 2
Note that in Figures 2(a)-2(b), AS1 and AS2 could be RSPs.
In all cases of Figure 2, in order to provide for backup, AS1 shall
permit the acceptance of AS2's routes from both AS2 and AS1's direct
provider, and permit their announcements to its direct providers.
Similar configuration is required for AS2.
There are two common routing policies depending upon how the link
between AS1 and AS2 is used.
Policy 1: Used solely as a backup link
The routing policy can be implemented by coordinating "LOCAL_PREF"
values between neighboring ASs. This can be acheived using AS-
based configuration or comunity based configuration [8].
In all cases of Figure 2, the "LOCAL_PREF" value for the peer of
AS1 or AS2 with its direct provider shall be higher than that for
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the peer between AS1 and AS2. Either full routing or partial
routing can be configured.
For example, in Figure 2(a), AS1 can take full routing from ISP
and AS2. An alternative is for AS1 to take only AS2's routes
from ISP and AS2, and configure default routes (with different
weights) at its border routers and then propagate them into its
own AS (via, e.g., iBGP). The ISP needs to make sure that the
"LOCAL_PREF" values are equal for the peers with AS1 and AS2 so
that the shorter AS-path would be selected.
Policy 2: Used for traffic between AS1 and AS2, and as backup in gen-
eral
In general this routing policy can be implemented by coordinating
"LOCAL_PREF" values [8] among the neighboring ASs and direct
providers.
In Figure 2(a), equal "LOCAL_PREF" values could be configured for
all the peers. Then the length of AS path would be used as tie-
breaker in the route selection. AS1 can either take full routing
from AS2 and its direct provider. It can also choose to take only
AS2's routes from its direct provider and AS2, and configure
default routes (with a different weights) at its border routers
and then propagate them into its own AS (via, e.g., iBGP). Simi-
lar configuration for AS2.
In Figures 2(b)-(c), AS1 can either take full routing from AS2 and
its direct provider, and configure the "LOCAL_PREF" parameter so
that traffic to AS2 prefers the AS1 - AS2 link over the link to
its direct provider. AS1 can choose to take only AS2's routes from
its direct provider and AS2, and configure default routes (with
different weight) at its border routers and then propagate them
into its own AS (via, e.g., iBGP). Similar configuration for AS2.
AS1's direct provider (and possible its ISP) needs to configure
the "LOCAL_PREF" parameter so that traffic to AS2 does not prefer
the link to AS1. Similar configuration is required for AS2's
direct provider.
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2.3 An Entity with Multiple Direct Providers
As shown in Figure 3, AS1 has two direct providers. X and Y are
routes of AS1. Note that AS1 could be an RSP.
+------+ +-----+ +------+
| ISP3 | | ISP | | ISP3 |
+------+ +-----+ +------+
/ \ / \ / \
/ (NAP) \ / \ / (NAP)\
+------+ +------+ +------+ +------+ +------+ +-----+
| ISP1 |------| ISP2 | | RSP1 | | RSP2 | | ISP1 |-----| ISP2|
+------+ +------+ +------+ +------+ +------+ +-----+
\ / \ / | |
\L1 /L2 \L1 /L2 | |
+------+ +------+ +------+ +-----+
| AS1 | | AS1 | | RSP1 | | RSP2|
|X Y| |X Y| +------+ +-----+
+------+ +------+ \ /
\L1 /L2
+------+
| AS1 |
|X Y|
+------+
(a) (b) (c)
Figure 3
Depending upon the quality of these links and the internal network
topology of the AS, there are several common routing policies.
Policy 1: One link is used as primary, the other as pure backup
This policy is common when the quality of these links differ dra-
matically.
This policy can be implemented by coordinating AS-based
"LOCAL_PREF" values between the entity and its direct providers.
The AS can either take full routing or use default routes. In the
case of default, each border router can configure a default route
and then propagate it into the AS (via, e.g., iBGP).
Policy 2: Each link is used for traffic with the respective direct
provider. In general one link is used as primary, and the other as
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backup.
If the traffic between AS1 and its direct providers (and their
customers) shall take the direct link, AS1 needs to be configured:
o either with partial routing (only routes of the direct
providers and their customers) and defaults with different
weights.
o or with full routing and configure "LOCAL_PREF" values.
The difficulty is that the indirect providers (e.g., ISP3 in
Figure 3(a)) may have to be involved to achieve symmetric rout-
ing. More specifically,
o In Figure 3(a), ISP3 would receive routes X and Y from both
ISP1 and ISP2 with identical length of AS paths. In order
for L1 to be favored by ISP3 to AS1, ISP1 would need to
manipulate the AS-path length, which is discussed in Section
3.1. Another approach is for ISP3 to configure "LOCAL_PREF"
parameter, which certainly does not scale well as there are
many ISPs at an NAP. In addition, it is almost impossible to
do as AS1 is not a customer of ISP3.
o In Figure 3(b), ISP would receive routes X and Y from both
RSP1 and RSP2 with identical length of AS paths. Either RSP1
needs to manipulate the AS-path length, or ISP needs to con-
figure "LOCAL_PREF" parameter.
o In Figure 3(c), ISP1 would receive routes X and Y from both
RSP1 and ISP2. In order for traffic from ISP1 to AS1 to
favor the ISP1 - ISP2 link, either RSP1 needs to manipulate
the AS-path length, or ISP1 needs to configure "LOCAL_PREF"
parameter.
Another problem is that it is difficult for AS1 to implement
"full routing", as AS1 needs to update the AS list for the
"LOCAL_PREF" parameter each time its direct providers acquire a
new AS as a customer. Nevertheless, some entities still prefer
full routing.
Policy 3: Partial load-sharing among these links
That is, the direct link is used for traffic between AS1 and its
direct providers including its customers. However, the closest
exit point would be taken for traffic beyond these direct
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providers and their customers. For example, in Figure 3(a) traffic
between AS1 and ISP1 (and its customers) would use the direct link
between AS1 and ISP1; traffic between AS1 and ISP2 (and its cus-
tomers) would use the direct link between AS1 and ISP2. For traf-
fic destined to ISP3, either ISP1 or ISP2 would be used depending
on where the traffic is originated in AS1.
AS1 can take full routing. It can also take partial routing
(routes of direct providers and their customers), and configure
equal-weight default routes at its border routers and propagate
them into its AS.
The problem is how to make sure the return traffic from a 4th
party (e.g., ISP3 in Figure 3(a)) is symmetric.
Policy 4: Complete load-sharing among these links
That is, each network in AS1 sends packets to the closer (in terms
of internal route preference) border router that peers with a
direct providers. The return traffic is expected to take a sym-
metric path. For example, in Figure 3(a) a packet, which is orig-
inated from network X and is destined outside AS1, would be for-
warded to ISP1, even when the destination is in ISP2.
The simpler approach is for AS1 to use default. That is, AS1
would first configure default route at each connection to a
provider and propagate (e.g., via iBGP) them into the AS. Then,
each network in AS1 choose the closest exit point (determined by
IGP metric). The problem is how to make sure the return traffic
to X and Y takes symmetric paths. Currently this is achieved by
manipulating the AS-path length or other approaches detailed in
the following section.
If AS1 still prefers to take full routing, more coordination would
be required for using the AS path manipulation or other techniques
as described in Section 3.
3. Current Practices
Currently there are mainly three approaches to implement Polices 2-4
for Figure 3. This section presents analysis and critique of these
approaches. Without loss of generality, Figure 3(a) is used as an
example.
3.1 Manipulation of AS Path Length
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Although the length of the AS path was not specified in [1] as a
parameter in the route selection process, it has been widely used as
such.
Some router software offers the ability of prepending AS numbers to
the AS path for the purpose of influencing the route selection. Here
is how the feature can be used. First, AS1 categorizes all of its
routes and prepends an AS number (either its own AS or a different AS
number):
AS1 Prepend AS Path
Route To ISP1 To ISP2 ISP1 ISP2
===== ======= ======= ======= ======
X AS1 AS1 AS1 AS1
Y AS1 AS1 AS1 AS1
In general the different AS paths can be used by ISP1 and ISP2 to
configure AS-based "LOCAL_PREF" values to implement the desired rout-
ing policy. The "LOCAL_PREF" configuration would not be necessary if
there are sufficient number of ASs inserted.
With this approach the AS that originates the preference has full
control, and only that AS needs to manipulate the AS path on a per-
route basis.
The drawbacks of this approach includes:
o It extends the AS path with superfluous information. In par-
ticular, the superfluous information in the AS path would be
propagated upstream and to the whole Internet.
o The number of ASs that need to be preprended is in general
proportional to the number of direct providers.
o Compatibility with other BGP implementation may be a problem.
3.2 Splitting AS
This approach requires an AS to be split into multiple ASs and run
external BGP between these ASs (possibly with MEDs configured for
load balancing among these ASs). Then the cases in Figure 3 can be
reduced to the cases in Figure 2, which have been discussed in Sec-
tion 2.
This is probably the cleanest approach the current BGP version can
offer. However, there is a great deal of reluctance in using this
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approach. Practical problems with this approach include:
o It does not work with the partial load-sharing case where the
connections to multiple providers originate from one router.
o Splitting ASs and having them maintained could be quite
involved depending upon the internal network topology.
o Extra AS numbers are required [7]. It would be necessary to
apply for AS numbers at the InterNIC.
o The number of split ASs is proportional to the number of
direct providers.
o Wasting of AS numbers. The exhaustion of the AS number space
could become real with the ever-increasing number of such
needs.
o The increased number of ASs would add complexity to the Inter-
net topology, and therefore complicate problem resolution.
o An AS number has been traditionally tied to an organization.
Splitting AS means loss of coherence for some customers.
3.3 NLRI-based Preference Specification
This is the approach that has been used for the NSFNET. Here is how
it is done with Figure 3(a). ISP1 and ISP2 configure net-based pref-
erence on their routers, according to preference provided by AS1.
For example, for route X, ISP1 would configure higher preference for
its direct link with AS1, and lower preference for its direct link
with ISP2.
This approach requires NRLI-based customization with the direct
providers and sometimes indirect providers as well as the originating
AS. The NSFNET configuration experience has shown that this approach
requires non-trivial administrative coordination and full topology
information. In addition, it places a burden on routers with limited
memory capacity. For these reasons, the NLRI-based preference con-
figuration should be avoided at the provider level if possible.
Instead, such a configuration should be pushed as close to the origi-
nating AS as possible. The technique presented in [8] makes use of
the BGP community attribute to allow one to acheive NLRI based
LOCAL_PREF configuration without provider level customization.
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3.4 Perfect Aggregation and Addressing
In the cases that all routes in the AS are covered by an aggregate
and address assignment is completely consistent with the network
topology, the rule of the longest prefix match can be used to help
achieve routing symmetry and load sharing. That is, a portion of the
aggregate, along with the aggregate itself, can be announced to one
direct provider. The remaining portion of the aggregate, along with
the aggregate itself, can be announced to the other direct provider.
It does not work with the partial load-sharing case where the connec-
tions to multiple providers originate from one router. More impor-
tantly, the requirement of this approach is not likely to be met in
practice. So, this approach is listed just for the sake of complete-
ness.
4. Discussion
As has been illustrated in Section 3, it is not easy to implement
routing symmetry and load sharing for an entity with multiple direct
providers using the current functionality of BGP. There are many
drawbacks with the current practice of implementation. Even the
implementation of the AS-based "LOCAL_PREF" parameter can sometimes
be quite involved. The difficulty is caused by the lack of a glob-
ally transitive preference an AS (with multiple direct providers) can
specify, and be used in the route selection process.
A new BGP attribute termed "Destination Preference Attribute" (DPA)
has been proposed in [3] to address such need. As illustrated in
[4], the routing policies presented in Section 2 can be implemented
with ease by using the DPA attribute. In particular, only the AS
that originates this preference needs to specify this preference on a
per-route basis.
5. Security Considerations
Security considerations are not discussed in this memo.
6. Acknowledgments
The authors would like to thank Roy Alcala, Dennis Ferguson, John
Stewart, and Jack Waters of MCI for the many interesting hallway dis-
cussions related to this work. We also acknowledge helpful comments
and suggestions by Yakov Rekhter of Cisco.
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7. References
[1] Rekhter, Y., and Li, T., "A Border Gateway Protocol 4 (BGP-4)",
RFC1771, March 1995.
[2] Y. Rekhter, and P. Gross, "Application of the Border Gateway Pro-
tocol in the Internet", RFC1772, March 1995.
[3] Chen, E., and Bates, T., "Destination Preference Attribute for
BGP", INTERNET-DRAFT, <draft-ietf-idr-bgp-dpa-04.txt>, January 1996.
[4] Chen, E., and Bates, T., "Application of the BGP Destination
Preference Attribute in Implementing Symmetric Routing", INTERNET-
DRAFT, <draft-ietf-idr-dpa-application-02.txt>, January 1996.
[5] Antonov, V., "BGP AS Path Metrics", INTERNET DRAFT, <draft-ietf-
idr-bgp-metrics-00.txt>, March 1995.
[6] Rekhter, Y., "Routing in a Multi-provider Internet", RFC1787,
April 1995.
[7] Hawkinsin, J., and Bates, T., "Guidelines for creation, selec-
tion, and registration of an Autonomous System (AS)", INTERNET-DRAFT,
<draft-ietf-idr-autosys-guide-04.txt>, December 1995.
[8] Chen, E., and Bates, T., "An Application of the BGP Community
Attribute in Multi-home Routing", INTERNET-DRAFT, <draft-chen-
community-usage-00.txt>, January 1996.
8. Author's Addresses
Enke Chen
MCI
2100 Reston Parkway
Reston, VA 22091
phone: +1 703 715 7087
email: enke@mci.net
Tony Bates
MCI
2100 Reston Parkway
Reston, VA 22091
phone: +1 703 715 7521
email: Tony.Bates@mci.net
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