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RFC 7789 - Impact of BGP Filtering on Inter-Domain Routing Polic

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Internet Engineering Task Force (IETF)                        C. Cardona
Request for Comments: 7789                           IMDEA Networks/UC3M
Category: Informational                                      P. Francois
ISSN: 2070-1721                                               P. Lucente
                                                           Cisco Systems
                                                              April 2016

        Impact of BGP Filtering on Inter-Domain Routing Policies


   This document describes how unexpected traffic flows can emerge
   across an autonomous system as the result of other autonomous systems
   filtering or restricting the propagation of more-specific prefixes.
   We provide a review of the techniques to detect the occurrence of
   this issue and defend against it.

Status of This Memo

   This document is not an Internet Standards Track specification; it is
   published for informational purposes.

   This document is a product of the Internet Engineering Task Force
   (IETF).  It represents the consensus of the IETF community.  It has
   received public review and has been approved for publication by the
   Internet Engineering Steering Group (IESG).  Not all documents
   approved by the IESG are a candidate for any level of Internet
   Standard; see Section 2 of RFC 5741.

   Information about the current status of this document, any errata,
   and how to provide feedback on it may be obtained at

Copyright Notice

   Copyright (c) 2016 IETF Trust and the persons identified as the
   document authors.  All rights reserved.

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   the Trust Legal Provisions and are provided without warranty as
   described in the Simplified BSD License.

Table of Contents

   1.  Introduction  . . . . . . . . . . . . . . . . . . . . . . . .   2
     1.1.  Terminology . . . . . . . . . . . . . . . . . . . . . . .   3
   2.  Unexpected Traffic Flows  . . . . . . . . . . . . . . . . . .   4
     2.1.  Local Filtering . . . . . . . . . . . . . . . . . . . . .   4
       2.1.1.  Unexpected Traffic Flows Caused by Local Filtering of
               More-Specific Prefixes  . . . . . . . . . . . . . . .   5
     2.2.  Remote Filtering  . . . . . . . . . . . . . . . . . . . .   6
       2.2.1.  Unexpected Traffic Flows Caused by Remotely Triggered
               Filtering of More-Specific Prefixes . . . . . . . . .   7
   3.  Techniques to Detect Unexpected Traffic Flows Caused by
       Filtering of More-Specific Prefixes . . . . . . . . . . . . .   8
     3.1.  Existence of Unexpected Traffic Flows within an AS  . . .   8
     3.2.  Contribution to the Existence of Unexpected Traffic Flows
           in Another AS . . . . . . . . . . . . . . . . . . . . . .   9
   4.  Techniques to Traffic Engineer Unexpected Flows . . . . . . .  10
     4.1.  Reactive Traffic Engineering  . . . . . . . . . . . . . .  11
     4.2.  Proactive Measures  . . . . . . . . . . . . . . . . . . .  12
       4.2.1.  Access Lists  . . . . . . . . . . . . . . . . . . . .  12
       4.2.2.  Neighbor-Specific Forwarding  . . . . . . . . . . . .  13
   5.  Conclusions . . . . . . . . . . . . . . . . . . . . . . . . .  14
   6.  Security Considerations . . . . . . . . . . . . . . . . . . .  14
   7.  References  . . . . . . . . . . . . . . . . . . . . . . . . .  14
     7.1.  Normative References  . . . . . . . . . . . . . . . . . .  14
     7.2.  Informative References  . . . . . . . . . . . . . . . . .  15
   Acknowledgements  . . . . . . . . . . . . . . . . . . . . . . . .  16
   Authors' Addresses  . . . . . . . . . . . . . . . . . . . . . . .  16

1.  Introduction

   It is common practice for network operators to propagate a more-
   specific prefix in the BGP routing system along with the less-
   specific prefix that they originate.  It is also possible for some
   Autonomous Systems (ASes) to apply different policies to the more
   specific and the less-specific prefix.

   Although BGP makes independent, policy-driven decisions for the
   selection of the best path to be used for a given IP prefix, routers
   must forward packets using the longest-prefix-match rule, which
   "precedes" any BGP policy [RFC1812].  The existence of a prefix p
   that is more specific than a prefix p' in the Forwarding Information
   Base (FIB) will let packets whose destination matches p be forwarded
   according to the next hop selected as best for p (the more-specific
   prefix).  This process takes place by disregarding the policies
   applied in the control plane for the selection of the best next hop
   for p'.  When an AS filters more-specific prefixes and forwards
   packets according to the less-specific prefix, the discrepancy among

   the routing policies applied to the less and the more-specific
   prefixes can create unexpected traffic flows.  These may infringe on
   the policies of other ASes still holding a path towards the more-
   specific prefix.

   The objective of this document is to shed light on possible side
   effects associated with more-specific prefix filtering.  Such actions
   can be explained by traffic engineering action, misconfiguration, or
   malicious intent.  This document presents examples of such side
   effects and discusses approaches towards solutions to the problem.

   The rest of the document is organized as follows: in Section 2 we
   provide some scenarios in which the filtering of more-specific
   prefixes leads to the creation of unexpected traffic flows; Section 3
   and Section 4 discuss some techniques that ASes can use for,
   respectively, detecting and reacting to unexpected traffic flows; and
   the document concludes in Section 5.

1.1.  Terminology

   More-specific prefix:  A prefix in the routing table with an address
      range that is covered by a shorter prefix also present in the
      routing table.

   Less-specific prefix:  A prefix in the routing table with an address
      range partially covered by other prefixes.

   Customer-provider peering:  A peering arrangement in which a transit
      network provides connectivity to a customer in exchange of a fee,
      as derived from RFC 4384 [RFC4384].

   Settlement-free peering:  A peering arrangement in which two networks
      agree on a settlement-free traffic exchange, typically covering
      only their customer traffic, as derived from RFC 4384 [RFC4384].

   Selective advertisement:  The behavior of only advertising a self
      originated BGP path for a prefix over a strict subset of the
      External BGP (eBGP) sessions of the AS.

   Selective propagation:  The behavior of only propagating a BGP path
      for a prefix over a strict subset of the eBGP sessions of an AS.

   Local filtering:  The behavior of explicitly ignoring a BGP path
      received over an eBGP session.

   Remote filtering:  The behavior of triggering selective propagation
      of a BGP path at a distant AS.  Note that this is typically
      achieved by tagging a self-originated path with BGP communities
      defined by the distant AS.

   Unexpected traffic flow:  Traffic flowing between two neighboring
      ASes of an AS, although the transit policy of that AS is to not
      provide connectivity between these two neighbors.  A traffic flow
      across an AS between two of its transit providers or between a
      transit provider and one of its settlement-free peers are classic
      examples of unexpected traffic flows.

2.  Unexpected Traffic Flows

   In this section, we describe how more-specific prefix filtering can
   lead to unexpected traffic flows in other, remote, ASes.  We
   differentiate cases in which the filtering is performed locally from
   those where the filtering is triggered remotely.

2.1.  Local Filtering

   Different reasons motivate local filtering, for example:

   Traffic engineering:  An ISP can decide to filter more-specific
      prefixes when it wants to control their local outbound traffic
      distribution using only the policy applied to the less-specific
      prefix.  Such a practice was notably documented in a presentation
      by Init7 [INIT7-RIPE63].

   Enforcing contract compliance:  An ISP can decide to filter more-
      specific prefixes to enforce clauses of their peering agreements.
      For instance, a settlement-free peer of an ISP can use selective
      advertisement of more-specific prefixes to attract traffic to one
      link.  If this practice is not allowed by their peering agreement,
      the ISP can filter the more-specific prefixes to prevent it.

   Memory preservation:  An ISP can decide to filter more-specific
      prefixes in order to preserve FIB memory of their routers.

   Figure 1 illustrates a scenario where one AS performs local filtering
   due to outbound traffic engineering.  The figure depicts AS64504 and
   two of its neighboring ASes, AS64502 and AS64505.  AS64504 has a
   settlement-free peering with AS64502 and is a customer of AS64505.
   AS64504 receives from AS64505 prefixes 2001:DB8::/32 and
   2001:DB8::/34.  AS64504 only receives the less-specific prefix
   2001:DB8::/32 from AS64502.

                /       \
               ( AS64505 )
                \       /
    2001:DB8::/32 | |
    2001:DB8::/34 v |
                 ,--+--.  2001:DB8::/32  ,-----.
                /       \           <-- /       \
               ( AS64504 )-------------( AS64502 )
                \       /               \       /
                 `-----'                 `-----'

                         Figure 1: Local Filtering

   Due to economic reasons, AS64504 might prefer to send traffic to
   AS64502 instead of AS64505.  However, even if paths received from
   AS64502 are given a large local preference, routers in AS64504 will
   still send traffic to prefix 2001:DB8::/34 via neighbor AS64505.
   This situation may push AS64504 to apply an inbound filter for the
   more-specific prefix, 2001:DB8::/34, on the session with AS64505.
   After applying the filter, AS64504 will send traffic for the more-
   specific prefix to AS64502.

2.1.1.  Unexpected Traffic Flows Caused by Local Filtering of More-
        Specific Prefixes

   In this section, we show how the decision of AS64504 to perform local
   filtering creates unexpected traffic flows in AS64502.  Figure 2
   shows the whole picture of the scenario where AS64501 is a customer
   of AS64503 and AS64502.  AS64503 is a settlement-free peer with
   AS64502.  AS64503 and AS64502 are customers of AS64505.  The AS
   originating the two prefixes, AS64501, performs selective
   advertisement with the more-specific prefix and only announces it to

   After AS64504 locally filters the more-specific prefix, traffic from
   AS64504 to prefix 2001:DB8::/34 is forwarded towards AS64502.
   Because AS64502 receives the more-specific prefix from AS64503,
   traffic from AS64504 to 2001:DB8::/34 follows the path
   AS64504-AS64502-AS64503-AS64501.  AS64502's BGP policies are
   implemented to avoid transporting traffic between AS64504 and
   AS64503.  However, due to the discrepancies of routes between the
   more and the less-specific prefixes, unexpected traffic flows between
   AS64504 and AS64503 exist in AS64502's network.

                _,.---''''                            `''---..._
            ,-''   AS64505                                      `-.
            [                                                      /
             -.._                                             __.-'
              .  `'---....______                ______...---''
            + |/32              `'''''''''''''''         |
            | |/34               + |/32                  |
            v |                  v |/34                  |
              |                    |                   ^ |
              |                  ^ |/32                | |/32
              |                  + |                   + |/34
       _,,---.:_               _,,---.._              _,,---.._
     ,'         `.           ,'         `.          ,'         `.
    /  AS64504    \     <-+ /  AS64502    \        /  AS64503    \
    |             |_________|             |________|             |
    |             |     /32 |             |/32  /32|             |
    '.           ,'          .           ,'     /34 .           ,'
      `.       ,'             `.       ,'  +->  <-+  `.       ,'
        ``---''                 ``---''                ``---''
                                    |                  ^ |
                                  ^ |2001:DB8::/32     | |2001:DB8::/32
                                  | |                  + |2001:DB8::/34
                                  + | _....---------...._|
                                   ,-'AS64501            ``-.
                                 /'                          `.
                                 `.                         _,
                                   `-.._               _,,,'

         Figure 2: Unexpected Traffic Flows Due to Local Filtering

2.2.  Remote Filtering

   ISPs can tag the BGP paths that they propagate to neighboring ASes
   with communities in order to tweak the propagation behavior of the
   ASes that handle these paths; see a paper from 2008 by Donnet and
   Bonaventure [on_BGP_communities].  Some ISPs allow their customers to
   use such communities to let the receiving AS not export the path to
   some selected neighboring ASes.  By combining communities, the prefix
   could be advertised only to a given peer of the AS providing this
   feature.  A network operator can leverage remote filtering to, for
   instance, limit the scope of prefixes and hence perform more granular
   inbound traffic engineering.

   Figure 3 illustrates a scenario in which an AS uses BGP communities
   to command its provider to selectively propagate a more-specific
   prefix.  Let AS64501 be a customer of AS64502 and AS64503.  AS64501
   originates prefix 2001:DB8::/32, which it advertises to AS64502 and
   AS64503.  AS64502 and AS64503 are settlement-free peers.  Let AS64501
   do selective advertisement and only propagate 2001:DB8::/34 over
   AS64503.  AS64503 would normally propagate this prefix to its
   customers, providers, and peers, including AS64502.

   Let us consider that AS64501 decides to limit the scope of the more-
   specific prefix.  AS64501 can make this decision based on its traffic
   engineering strategy.  To achieve this, AS64501 can tag the more-
   specific prefix with a set of communities that leads AS64503 to only
   propagate the path to AS64502.

      ^     \         /     ^       ^    \         /    ^
      |  /32 \       / /32  |       | /32 \       / /32 |
               ,-----.                     ,-----.
             ,'       `.                 ,'       `.
            / AS64502   \               / AS64503   \
           (             )-------------(             )
            \           / /32       /32 \           /
             `.       ,'   ->       /34  `.       ,'
               '-----;              <-  /  '-----'
                      \                /
                    ^  \              /    ^
                    |   \            /     |
                    |    \          /      |
                    |     \ ,-----.'       |  2001:DB8::/32
                    |     ,'       `.      |  2001:DB8::/34
      2001:DB8::/32 +--  / AS64501   \   --+
                        (             )
                         \           /
                          `.       ,'

                   Figure 3: Remote-Triggered Filtering

2.2.1.  Unexpected Traffic Flows Caused by Remotely Triggered Filtering
        of More-Specific Prefixes

   Figure 4 expands the scenario from Figure 3 and includes other ASes
   peering with AS64502 and AS64503.  Due to the limitation on the scope
   performed on the more-specific prefix, ASes that are not customers of
   AS64502 will not receive a path for 2001:DB8::/34.  These ASes will
   forward packets destined to 2001:DB8::/34 according to their routing
   state for 2001:DB8::/32.  Let us assume that AS64505 is such an AS
   and that its best path towards 2001:DB8::/32 is through AS64502.

   Packets sent towards 2001:DB8::1 by AS64505 will reach AS64502.
   However, in the data plane of the nodes of AS64502, the longest
   prefix match for 2001:DB8::1 is 2001:DB8::/34, which is reached
   through AS64503, a settlement-free peer of AS64502.  Since AS64505 is
   not in the customer branch of AS64502, traffic flows between two
   noncustomer ASes in AS64502.

                        ,'       `.
                       / AS64505   \
                      (             )
                       \           /
                       ,`.       ,' \
                      /   '-----'    \
                     /   ^       ^    \
                    /32  |       | /32 '
            ,-----.'     +       +      ,-----.
          ,'       `.                 ,'       `.
         / AS64502   \               / AS64503   \
        (             )-------------(             )
         \           / /32       /32 \           /
          `.       ,'  +->       /34  `.       ,'
            '-----;              <-+ /  '-----'
                   \                /
                 ^  \              /    ^
                 |   \            /     |
                 |    \          /      |
                 |     \ ,-----.'       |  2001:DB8::/32
                 |     ,'       `.      |  2001:DB8::/34
   2001:DB8::/32 +--+ / AS64501   \  +--+
                     (             )
                      \           /
                       `.       ,'

   Figure 4: Unexpected Traffic Flows Due to Remote-Triggered Filtering

3.  Techniques to Detect Unexpected Traffic Flows Caused by Filtering of
    More-Specific Prefixes

3.1.  Existence of Unexpected Traffic Flows within an AS

   To detect if unexpected traffic flows are taking place in its
   network, an ISP can monitor its traffic data to check if it is
   providing transit between two of its peers, although its policy is
   configured to not provide such transit.  IPFIX [RFC7011] is an
   example of a technology that can be used to export information
   regarding traffic flows across the network.  Traffic information must

   be analyzed under the perspective of the business relationships with
   neighboring ASes to detect the flows not fitting the policy.
   Operators can use collection systems that combine traffic statistics
   with policy information for this end.  See the pmacct project
   [PMACCT] for an open-source application meeting these requirements.

   Note that the AS detecting the unexpected traffic flow may simply
   realize that its policy configuration is broken.  The first
   recommended action upon detection of an unexpected traffic flow is to
   verify the correctness of the BGP configuration.

   Once the local configuration is confirmed correct, the operator
   should check if the unexpected flow arose due to filtering of BGP
   paths for more-specific prefixes by neighboring ASes.  This can be
   performed in two steps.  First, the operator should check whether the
   neighboring AS originating the unexpected flow is forwarding traffic
   using a less-specific prefix that is announced to it by the affected
   network.  The second step is to try to infer the reason why the
   neighboring AS does not use the more-specific path for forwarding,
   i.e., finding why the more-specific prefix was filtered.  Due to the
   distributed nature and restricted visibility of the steering of BGP
   policies, this second step does not identify the origin of the
   problem with guaranteed accuracy.

   For the first step, the operator should check if the destination
   address of the unexpected traffic flow is locally routed as per a
   more-specific prefix only received from noncustomer peers.  The
   operator should also check if there are paths to a less-specific
   prefix received from a customer and hence propagated to peers.  If
   these two situations happen at the same time, the neighboring AS at
   the entry point of the unexpected flow is routing the traffic based
   on the less-specific prefix, although the ISP is actually forwarding
   the traffic via noncustomer links.

   For the second step, one can rely on human interaction or looking
   glasses to find out whether local filtering, remote filtering, or
   selective propagation was performed on the more-specific prefix.  No
   openly available tools that can automatically perform this operation
   have been identified.

3.2.  Contribution to the Existence of Unexpected Traffic Flows in
      Another AS

   It can be considered problematic to trigger unexpected traffic flows
   in another AS.  It is thus advisable for an AS to assess the risks of
   filtering more-specific prefixes before implementing them by
   obtaining as much information as possible about its surrounding
   routing environment.

   There may be justifiable reasons for one ISP to perform filtering:
   either to enforce established policies or to provide prefix-
   advertisement scoping features to its customers.  These can vary from
   troubleshooting purposes to business-relationship implementations.
   Restricting the use of these features for the sake of avoiding the
   creation of unexpected traffic flows is not a practical option.

   In order to assess the risk of filtering more-specific prefixes, the
   AS would need information on the routing policies and the
   relationships among external ASes to detect if its actions could
   trigger the appearance of unexpected traffic flows.  With this
   information, the operator could detect other ASes receiving the more-
   specific prefix from noncustomer ASes while announcing the less-
   specific prefix to other noncustomer ASes.  If the filtering of the
   more-specific prefix leads other ASes to send traffic for the more-
   specific prefix to these ASes, an unexpected traffic flow can arise.
   However, the information required for this operation is difficult to
   obtain since it is frequently considered confidential.

4.  Techniques to Traffic Engineer Unexpected Flows

   Network operators can adopt different approaches with respect to
   unexpected traffic flows.  Note that due to the complexity of inter-
   domain routing policies, there is not a single solution that can be
   applied to all situations.  This section provides potential solutions
   that ISPs must evaluate against each particular case.  We classify
   these actions according to whether they are proactive or reactive.

   Reactive approaches are those in which the operator tries to detect
   the situations via monitoring and solve unexpected traffic flows
   manually on a case-by-case basis.

   Anticipant or preventive approaches are those in which the routing
   system will not let the unexpected traffic flows actually take place
   when the scenario arises.

   We use the scenario depicted in Figure 5 to describe these two kinds
   of approaches.  Since proactive approaches can be complex to
   implement and can lead to undesired effects, the reactive approach is
   the more reasonable recommendation to deal with unexpected flows.

               _,.---''''                            `''---..._
           ,-''   AS64505                                      `-.
           [                                                      /
            -.._                                             __.-'
             .  `'---....______                ______...---''
           + |/32              `'''''''''''''''         |
           | |/34               + |/32                  |
           v |                  v |/34                  |
             |                    |                   ^ |
             |                  ^ |/32                | |/32
             |                  + |                   + |/34
      _,,---.:_               _,,---.._              _,,---.._
    ,'         `.           ,'         `.          ,'         `.
   /  AS64504    \     <-+ /  AS64502    \        /  AS64503    \
   |             |_________|             |        |             |
   |             |     /32 |             |        |             |
   '.           ,'          .           ,'         .           ,'
     `.       ,'             `.       ,'            `.       ,'
       ``---''                 ``---''                ``---''
                                   |                  ^ |
                                 ^ |2001:DB8::/32     | |2001:DB8::/32
                                 | |                  + |2001:DB8::/34
                                 + | _....---------...._|
                                  ,-'AS64501            ``-.
                                /'                          `.
                                `.                         _,
                                  `-.._               _,,,'

        Figure 5: Traffic Engineering of Unexpected Traffic Flows -
                               Base Example

4.1.  Reactive Traffic Engineering

   An operator who detects unexpected traffic flows originated by any of
   the cases described in Section 2 can contact the ASes that are likely
   to have performed the propagation tweaks, inform them of the
   situation, and persuade them to change their behavior.

   If the situation remains, the operator can implement prefix filtering
   in order to stop the unexpected flows.  The operator can decide to
   perform this action over the session with the operator announcing the
   more-specific prefix or over the session with the neighboring AS from
   which it is receiving the traffic.  Each of these options carry a
   different repercussion for the affected AS.  We briefly describe the
   two alternatives.

   o  An operator can decide to stop announcing the less-specific prefix
      at the peering session with the neighboring AS from which it is
      receiving traffic to the more-specific prefix.  In the example of
      Figure 5, AS64502 would filter out the prefix 2001:DB8::/32 from
      the eBGP session with AS64504.  In this case, traffic heading to
      the prefix 2001:DB8::/32 from AS64501 would no longer traverse
      AS64502.  AS64502 should evaluate if solving the issues originated
      by the unexpected traffic flows are worth the loss of this traffic

   o  An operator can decide to filter out the more-specific prefix at
      the peering session over which it was received.  In the example of
      Figure 5, AS64502 would filter out the incoming prefix
      2001:DB8::/34 from the eBGP session with AS64505.  As a result,
      the traffic destined to that /32 would be forwarded by AS64502
      along its link with AS64501, despite the actions performed by
      AS64501 to have this traffic coming in through its link with
      AS64503.  However, as AS64502 will no longer know a route to the
      more-specific prefix, it risks losing the traffic share from
      customers different from AS64501 to that prefix.  Furthermore,
      this action can generate conflicts between AS64502 and AS64501,
      since AS64502 does not follow the routing information expressed by
      AS64501 in its BGP announcements.

   Note that it is possible that the behavior of the neighboring AS
   causing the unexpected traffic flows violates a contractual agreement
   between the two networks.

4.2.  Proactive Measures

4.2.1.  Access Lists

   An operator could install access lists to prevent unexpected traffic
   flows from happening in the first place.  In the example of Figure 5,
   AS64502 would install an access list denying packets matching
   2001:DB8::/34 associated with the interface connecting to AS64504.
   As a result, traffic destined to that prefix would be dropped despite
   the existence of a valid route towards 2001:DB8::/32.

   The operational overhead of such a solution is considered high, as
   the operator would have to constantly adapt these access lists to
   accommodate inter-domain routing changes.  Moreover, this technique
   lets packets destined to a valid prefix be dropped while they are
   sent from a neighboring AS that may not know about the policy
   conflict and hence had no means to avoid the creation of unexpected
   traffic flows.  For this reason, this technique can be considered

4.2.2.  Neighbor-Specific Forwarding

   An operator can technically ensure that traffic destined to a given
   prefix will be forwarded from an entry point of the network based
   only on the set of paths that have been advertised over that entry

   As an example, let us analyze the scenario of Figure 5 from the point
   of view of AS64502.  The edge router connecting to the AS64504
   forwards packets destined to prefix 2001:DB8::/34 towards AS64505.
   Likewise, it forwards packets destined to prefix 2001:DB8::/32
   towards AS64501.  The router, however, only propagates the path of
   the less-specific prefix (2001:DB8::/32) to AS64504.  An operator
   could implement the necessary techniques to force the edge router to
   forward packets coming from AS64504 based only on the paths
   propagated to AS64504.  Thus, the edge router would forward packets
   destined to 2001:DB8::/34 towards AS64501, in which case no
   unexpected traffic flow would occur.

   Different techniques could provide this functionality; however, their
   technical implementation can be complex to design and operate.  An
   operator could, for instance, employ VPN Routing and Forwarding (VRF)
   tables [RFC4364] to store the routes announced to a neighbor and
   forward traffic exclusively based on those routes.  A presentation
   from 2009 [on_BGP_RS_VPNs] describes the use of such an architecture
   for Internet routing and provides a description of its limitations.

   In such architecture, packets received from a peer would be forwarded
   solely based on the paths that fit the path propagation policy for
   that peer and not based on the global routing table of the router.
   As a result, a more-specific path that would not be propagated to a
   peer will not be used to forward a packet from that peer, and the
   unexpected flow will not take place.  Packets will be forwarded based
   on the policy-compliant, less-specific prefix.  However, note that an
   operator must make sure that all their routers could support the
   potential performance impact of this approach.

   Note that similar to the solution described in Section 4.1, this
   approach could create conflicts between AS64502 and AS64501, since
   the traffic forwarding performed by AS64502 goes against the policy
   of AS64501.

5.  Conclusions

   This document describes how filtering and selective propagation of
   more-specific prefixes can potentially create unexpected traffic
   flows across some ASes.  We provided examples of scenarios where
   these practices lead to unexpected traffic flows and introduce some
   techniques for their detection and prevention.  Although there are
   reasonable situations in which ASes could filter more-specific
   prefixes, network operators are encouraged to implement this type of
   filter considering the cases described in this document.  Operators
   can implement monitoring systems to detect unexpected traffic flows
   and react to them according to their own policy.

6.  Security Considerations

   It is possible for an AS to use any of the methods described in this
   document to deliberately reroute traffic flowing through another AS.
   This document described the potential routing security issue and
   analyzed ways for operators to defend against it.

   It must be noted that, at the time of this document, there are no
   existing or proposed tools to automatically protect against such
   behavior.  Operators can use network monitoring and collection tools
   to detect unexpected flows and deal with them on a case-by-case

7.  References

7.1.  Normative References

   [RFC1812]  Baker, F., Ed., "Requirements for IP Version 4 Routers",
              RFC 1812, DOI 10.17487/RFC1812, June 1995,

   [RFC4364]  Rosen, E. and Y. Rekhter, "BGP/MPLS IP Virtual Private
              Networks (VPNs)", RFC 4364, DOI 10.17487/RFC4364, February
              2006, <http://www.rfc-editor.org/info/rfc4364>.

   [RFC4384]  Meyer, D., "BGP Communities for Data Collection", BCP 114,
              RFC 4384, DOI 10.17487/RFC4384, February 2006,

   [RFC7011]  Claise, B., Ed., Trammell, B., Ed., and P. Aitken,
              "Specification of the IP Flow Information Export (IPFIX)
              Protocol for the Exchange of Flow Information", STD 77,
              RFC 7011, DOI 10.17487/RFC7011, September 2013,

7.2.  Informative References

              Kunzler, F., "How More Specifics increase your transit
              bill (and ways to avoid it)", Reseaux IP Europeens
              (RIPE) 63rd Meeting, October 2011,

              Donnet, B. and O. Bonaventure, "On BGP Communities", ACM
              SIGCOMM Computer Communication Review, Volume 38, Number
              2, pp. 55-59, DOI 10.1145/1355734.1355743, April 2008,

              Vanbever, L., Francois, P., Bonaventure, O., and J.
              Rexford, "Customized BGP Route Selection Using BGP/MPLS
              VPNs", Cisco Systems, Routing Symposium, October 2009,

   [PMACCT]   "pmacct project: IP accounting iconoclasm",


   The authors would like to thank Wes George, Jon Mitchell, Bruno
   Decraene, and Job Snijders for their useful suggestions and comments.

Authors' Addresses

   Camilo Cardona
   IMDEA Networks/UC3M
   Avenida del Mar Mediterraneo, 22
   Leganes  28919

   Email: juancamilo.cardona@imdea.org

   Pierre Francois
   Cisco Systems
   170 W. Tasman Drive
   San Jose, CA  95134
   United States

   Email: pifranco@cisco.com

   Paolo Lucente
   Cisco Systems
   170 W. Tasman Drive
   San Jose, CA  95134
   United States

   Email: plucente@cisco.com


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