Network Working Group                                         A. Kirkham
Internet-Draft                                        Palo Alto Networks
Obsoletes:  None (if approved)                            March 28, 2012
Intended status:  Informational
Expires:  September 29, 2012

           Issues with Private IP Addressing in the Internet


   The purpose of this document is to provide a discussion of the
   potential problems of using private, RFC1918, or non-globally-
   routable addressing within the core of an SP network.  The discussion
   focuses on link addresses and to a small extent loopback addresses.
   While many of the issues are well recognised within the ISP
   community, there appears to be no document that collectively
   describes the issues.


   This documents and the information contained therein are provided on

Status of this Memo

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   material or to cite them other than as "work in progress."

   This Internet-Draft will expire on September 29, 2012.

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Copyright Notice

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Table of Contents

   1.  Introduction . . . . . . . . . . . . . . . . . . . . . . . . .  3
   2.  Conservation of Address Space  . . . . . . . . . . . . . . . .  3
   3.  Effects on Traceroute  . . . . . . . . . . . . . . . . . . . .  4
   4.  Effects on Path MTU Discovery  . . . . . . . . . . . . . . . .  7
   5.  Unexpected interactions with some NAT implementations  . . . .  8
   6.  Interactions with edge anti-spoofing techniques  . . . . . . . 10
   7.  Peering using loopbacks  . . . . . . . . . . . . . . . . . . . 11
   8.  DNS Interaction  . . . . . . . . . . . . . . . . . . . . . . . 11
   9.  Operational and Troubleshooting issues . . . . . . . . . . . . 11
   10. Security Considerations  . . . . . . . . . . . . . . . . . . . 12
   11. Alternate approaches to core network security  . . . . . . . . 13
   12. Normative References . . . . . . . . . . . . . . . . . . . . . 14
   Appendix A.  Acknowledgments . . . . . . . . . . . . . . . . . . . 14
   Index  . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 15
   Author's Address . . . . . . . . . . . . . . . . . . . . . . . . . 15

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1.  Introduction

   In the mid to late 90's, some Internet Service Providers (ISPs)
   adopted the practice of utilising private (or non-globally unique) IP
   (i.e.  RFC1918) addresses for the infrastructure links and in some
   cases the loopback interfaces within their networks.  The reasons for
   this approach centered on conservation of address space (i.e.
   scarcity of public IPv4 address space), and security of the core
   network (also known as core hiding).

   However, a number of technical and operational issues occurred as a
   result of using private (or non-globally unique) IP addresses, and
   virtually all these ISPs moved away from the practice.  Tier 1 ISPs
   are considered the benchmark of the industry and as of the time of
   writing, there is no known tier 1 ISP that utilises the practice of
   private addressing within their core network.

   The following sections will discuss the various issues associated
   with deploying private IP (i.e.  RFC1918) addresses within ISP core

   The intent of this document is not to suggest that private IP can not
   be used with the core of an SP network as some providers use this
   practice and operate successfully.  The intent is to outline the
   potential issues or effects of such a practice.

   Note:  The practice of ISPs using 'stolen' address space (also known
   as 'squat' space) has many of the same issues (or effects) as that of
   using private IP address space within core networks.  The term
   "stolen IP address space" refers to the practice of an ISP using
   address space for its own infrastructure/core network addressing that
   has been officially allocated by an RIR to another provider, but that
   provider is not currently using or advertising within the Internet.
   Stolen addressing is not discussed further in this document.  It is
   simply noted as an associated issue.

2.  Conservation of Address Space

   One of the original intents for the use of private IP addressing
   within an ISP core was the conservation of IP address space.  When an
   ISP is allocated a block of public IP addresses (from a RIR), this
   address block was traditionally split in order to dedicate some
   portion for infrastructure use (i.e. for the core network), and the
   other portion for customer (subscriber) or other address pool use.
   Typically, the number of infrastructure addresses needed is
   relatively small in comparison to the total address count.  So unless
   the ISP was only granted a small public block, dedicating some

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   portion to infrastructure links and loopback addresses (/32) is
   rarely a large enough issue to outweigh the problems that are
   potentially caused when private address space is used.

   Additionally, specifications and equipment capability improvements
   now allow for the use of /31 subnets [RFC3021] for link addresses in
   place of the original /30 subnets - further minimising the impact of
   dedicating public addresses to infrastructure links by only using two
   (2) IP addresses per point to point link versus four (4)

   The use of private addressing as a conservation technique within an
   Internet Service Provider (ISP) core can cause a number of technical
   and operational issues or effects.  The main effects are described

3.  Effects on Traceroute

   The single biggest effect caused by the use of private (RFC1918)
   addressing within an Internet core is the fact that it can disrupt
   the operation of traceroute in some situations.  This section
   provides some examples of the issues that can occur.

   A first example illustrates the situation where the traceroute
   crosses an AS boundary and one of the networks has utilised private
   addressing.  The following simple network is used to show the

              AS64496                 EBGP                AS64497
                    IBGP Mesh <--------------->  IBGP Mesh

R1 Pool -                                                      R6 Pool -                                

                               .9          .10
    .1       .2  .5       .6    ------------    .6      .5  .2      .1
  R1-----------R2-----------R3--|          |--R4----------R5----------R6

  R1 Loopback:                    R4 Loopback:
  R2 Loopback:                    R5 Loopback:
  R3 Loopback:                    R6 Loopback:

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   Using this example, performing the traceroute from AS64497 to
   AS64496, we can see the private addresses of the infrastructure links
   in AS64496 are returned.

   Type escape sequence to abort.
   Tracing the route to

     1 40 msec 20 msec 32 msec
     2 16 msec 20 msec 20 msec
     3 20 msec 20 msec 32 msec
     4 20 msec 20 msec 20 msec
     5 20 msec 20 msec 20 msec

   This effect in itself is often not a problem.  However, if anti-
   spoofing controls are applied at network perimeters, then responses
   returned from hops with private IP addresses will be dropped.  Anti-
   spoofing refers to a security control where traffic with an invalid
   source address is discarded.  Anti-spoofing is further described in
   BCP 38/RFC 2827.

   The effects are illustrated in a second example below.  The same
   network as example 1 is used, but with the addition of anti-spoofing
   deployed at the ingress of R4 on the R3-R4 interface (ip address


   Type escape sequence to abort.
   Tracing the route to

     1 24 msec 20 msec 20 msec
     2 20 msec 52 msec 44 msec
     3 44 msec 20 msec 32 msec
     4  *  *  *
     5  *  *  *
     6  *  *  *
     7  *  *  *
     8  *  *  *
     9  *  *  *
    10  *  *  *
    11  *  *  *
    12  *  *  *

   In a third example, a similar effect is caused.  If a traceroute is
   initiated from a router with a private (source) IP address, located

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   in AS64496 and the destination is outside of the ISPs AS (AS64497),
   then in this situation the traceroute will fail completely beyond the
   AS boundary.

   R1# traceroute
   Type escape sequence to abort.
   Tracing the route to

     1 20 msec 20 msec 20 msec
     2 52 msec 24 msec 40 msec
     3  *  *  *
     4  *  *  *
     5  *  *  *
     6  *  *  *

   While it is completely unreasonable to expect a packet with a private
   source address to be successfully returned in a typical SP
   environment, the case is included to show the effect as it can have
   implications for troubleshooting.  This case will be referenced in a
   later section.

   In a complex topology, with multiple paths and exit points, the
   provider will lose their ability to trace paths originating within
   their own AS, through their network, to destinations within other
   ASs.  Such a situation could be a severe troubleshooting impediment.

   For completeness, a fourth example is included to show that a
   successful traceroute can be achieved by specifying a public source
   address as the source address of the traceroute.  Such an approach
   can be used in many operational situations if the router initiating
   the traceroute has at least one public address configured.  However,
   the approach is more cumbersome.

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   Protocol [ip]:
   Target IP address:
   Source address:
   Numeric display [n]:
   Timeout in seconds [3]:
   Probe count [3]:
   Minimum Time to Live [1]:
   Maximum Time to Live [30]: 10
   Port Number [33434]:
   Loose, Strict, Record, Timestamp, Verbose[none]:
   Type escape sequence to abort.
   Tracing the route to

     1 0 msec 4 msec 0 msec
     2 0 msec 4 msec 0 msec
     3 [AS 64497] 0 msec 4 msec 0 msec
     4 [AS 64497] 0 msec 0 msec 4 msec
     5 [AS 64497] 0 msec 0 msec 4 msec

   It should be noted that some solutions to this problem have been
   proposed in RFC 5837 which provides extensions to ICMP to allow the
   identification of interfaces and their components by any combination
   of the following:  ifIndex, IPv4 address, IPv6 address, name, and
   MTU.  However at the time of writing, little or no deployment was
   known to be in place.

4.  Effects on Path MTU Discovery

   The Path MTU Discovery (PMTUD) process was designed to allow hosts to
   make an accurate assessment of the maximum packet size that can be
   sent across a path without fragmentation.  Path MTU Discovery is
   supported for TCP (and other protocols that support PMTUD such as GRE
   and IPsec) and works as follows:

   o When a router attempts to forward an IP datagram with the Do Not
   Fragment (DF) bit set out a link that has a lower MTU than the size
   of the packet, the router MUST drop the packet and return an Internet
   Control Message Protocol (ICMP) 'destination unreachable -
   fragmentation needed and DF set (type 3, code 4)' message to the
   source of the IP datagram.  This message includes the MTU of that
   next-hop network.  As a result, the source station which receives the
   ICMP message, will lower the send Maximum Segment Size (MSS).

   It is obviously desirable that packets be sent between two
   communicating hosts without fragmentation as this process imposes

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   extra load on the fragmenting router (process of fragmentation),
   intermediate routers (forwarding additional packets), as well as the
   receiving host (reassembly of the fragmented packets).  Additionally,
   many applications, including some web servers, set the DF (do not
   fragment) bit causing undesirable interactions if the path MTU is
   insufficient.  Other TCP implementations may set an MTU size of 576
   bytes if PMTUD is unavailable.  In addition, IPsec and other
   tunneling protocols will often require MTUs greater than 1500 bytes
   and often rely on PMTUD.

   While it is uncommon these days for core SP networks not to support
   path MTUs in excess of 1500 bytes (with 4470 or greater being
   common), the situation of 1500 byte path MTUs is still common in many
   ethernet edge or aggregation networks.

   The issue is as follows:

   o When an ICMP Type 3 Code 4 message is issued from an infrastructure
   link that uses a private (RFC1918) address, it must be routed back to
   the originating host.  As the originating host will typically be a
   globally routable IP address, its source address is used as the
   destination address of the returned ICMP Type 3 packet.  At this
   point there are normally no problems.

   o As the returned packet will have an RFC1918 source address,
   problems can occur when the returned packet passes through an anti-
   spoofing security control (such as Unicast RPF (uRPF)), other anti-
   spoofing ACLs, or virtually any perimeter firewall.  These devices
   will typically drop packets with an RFC1918 source address, breaking
   the successful operation of PMTUD.

   As a result, the potential for application level issues may be

5.  Unexpected interactions with some NAT implementations

   Private addressing is legitimately used within many enterprise,
   corporate or government networks for internal network addressing.
   When users on the inside of the network require Internet access, they
   will typically connect through a perimeter router, firewall, or
   network proxy, that provides Network Address Translation (NAT) or
   Network Address Port Translation (NAPT) services to a public

   Scarcity of public IPv4 addresses, and the transition to IPv6, is
   forcing many service providers to make use of NAT.  CGN (Carrier
   Grade NAT) will enable service providers to assign private RFC 1918

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   IPv4 addresses to their customers rather than public, globally unique
   IPv4 addresses.  NAT444 will make use of a double NAT process.

   Unpredictable or confusing interactions could occur if traffic such
   as traceroute, PMTUD and possibly other applications were launched
   from the NAT IPv4 'inside address' and it passed over the same
   address range in the public IP core.  While such a situation would be
   unlikely to occur if the NAT pools and the private infrastructure
   addressing were under the same administration, such a situation could
   occur in the more typical situation of a NAT'ed corporate network
   connecting to an ISP.  For example, say if is used to
   internally number the corporate network.  A traceroute or PMTUD
   request is initiated inside the corporate network from say
   The packet passes through a NAT (or NAPT) gateway, then over an ISP
   core numbered from the same range.  When the responses are delivered
   back to the originator, the returned packets from the privately
   addressed part of the ISP core could have an identical source and
   destination address of

            NAT Pool -

    .1       .2  .14     .13  .1           .2  .6      .5  .2      .1
                                                          R6 Loopback:


   Type escape sequence to abort.
   Tracing the route to

     1 0 msec 0 msec 0 msec
     2 0 msec 4 msec 0 msec
     3 0 msec 4 msec 0 msec        <<<<
     4 4 msec 0 msec 4 msec
     5 0 msec 0 msec 0 msec

   This example has been included to illustrate an effect.  Whether that
   effect would be problematic would depend on both the deployment

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   scenario and the application in use.

   Certainly a scenario where the same RFC1918 address space becomes
   utilised on both the inside and outside interfaces of a NAT/NAPT
   device can be problematic.  For example, the same private address
   range is assigned by both the administrator of a corporate network
   and their ISP.  Some applications discover the outside address of
   their local CPE to determine if that address is reserver for special
   use.  Application behavior may then be based on this determination.
   [weil-shared-transition-space-request] provides further analysis of
   this situation.

   To address this scenario and others, at the time of writing, work was
   in progress to obtain a dedicated /10 address block for the purpose
   of Shared CGN (Carrier Grade NAT) Address Space.  Please refer to
   [bdgks-arin-shared-transition-space] and [weil-shared-transition-
   space-request] for details.  The purpose of Shared CGN Address Space
   is to number CPE (Customer Premise Equipment) interfaces that connect
   to CGN devices.  As explained in [weil-shared-transition-space-
   request], RFC1918 addressing has issues when used in this deployment

6.  Interactions with edge anti-spoofing techniques

   Denial of service attacks and distributed denial of attacks can make
   use of spoofed source IP addresses in an attempt to obfuscate the
   source of an attack.  RFC2827 (Network Ingress Filtering) strongly
   recommends that providers of Internet connectivity implement
   filtering to prevent packets using source addresses outside of their
   legitimately assigned and advertised prefix ranges.  Such filtering
   should also prevent packets with private source addresses from
   egressing the AS.

   Best security practices for ISPs also strongly recommend that packets
   with illegitimate source addresses should be dropped at the AS
   perimeter.  Illegitimate source addresses includes private IP
   (RFC1918) addresses, addresses within the provider's assigned prefix
   ranges, and bogons (legitimate but unassigned IP addresses).
   Additionally, packets with private IP destination addresses should
   also be dropped at the AS perimeter.

   If such filtering is properly deployed, then traffic either sourced
   from, or destined for privately addressed portions of the network
   should be dropped.  Hence the negative consequences on traceroute,
   PMTUD and regular ping type traffic.

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7.  Peering using loopbacks

   Although not a common technique, some ISPs use the loopback addresses
   of border routers (ASBRs) for peering, in particular where multiple
   connections or exchange points exist between the two ISPs.  Such a
   technique is used by some ISPs as the foundation of fine grained
   traffic engineering and load balancing through the combination of IGP
   metrics and multi-hop BGP.  When private or non-globally reachable
   addresses are used as loopback addresses, this technique is either
   not possible, or considerably more complex to implement.

8.  DNS Interaction

   Many ISPs utilise their DNS to perform both forward and reverse
   resolution for the infrastructure devices and infrastructure
   addresses.  With a privately numbered core, the ISP itself will still
   have the capability to perform name resolution of their own
   infrastructure.  However others outside of the autonomous system will
   not have this capability.  At best, they will get a number of
   unidentified RFC1918 IP addresses returned from a traceroute.

   It is also worth noting that in some cases the reverse resolution
   requests may leak outside of the AS.  Such a situation can add load
   to public DNS servers.  Further information on this problem is
   documented in the internet draft "AS112 Nameserver Operations".

9.  Operational and Troubleshooting issues

   Previous sections of the document have noted issues relating to
   network operations and troubleshooting.  In particular when private
   IP addressing within an ISP core is used, the ability to easily
   troubleshoot across the AS boundary may be limited.  In some cases
   this may be a serious troubleshooting impediment.  In other cases, it
   may be solved through the use of alternative troubleshooting

   The key point is that the flexibility of initiating an outbound ping
   or traceroute from a privately numbered section of the network is
   lost.  In a complex topology, with multiple paths and exit points
   from the AS, the provider may be restricted in their ability to trace
   paths through the network to other ASs.  Such a situation could be a
   severe troubleshooting impediment.

   For users outside of the AS, the loss of the ability to use a
   traceroute for troubleshooting is very often a serious issue.  As
   soon as many of these people see a row of "* * *" in a traceroute

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   they often incorrectly assume that a large part of the network is
   down or inaccessible (e.g. behind a firewall).  Operational
   experience in many large providers has shown that significant
   confusion can result.

10.  Security Considerations

   One of the arguments often put forward for the use of private
   addressing within an ISP is an improvement in the network security.
   It has been argued that if private addressing is used within the
   core, the network infrastructure becomes unreachable from outside the
   providers autonomous system, hence protecting the infrastructure.
   There is legitimacy to this argument.  Certainly if the core is
   privately numbered and unreachable, it potentially provides a level
   of isolation in addition to what can be achieved with other
   techniques, such as infrastructure ACLs, on their own.  This is
   especially true in the event of an ACL misconfiguration, something
   that does commonly occur as the result of human error.

   There are three key security gaps that exist in a privately addressed
   IP core.

      The approach does not protect against reflection attacks if edge
      anti-spoofing is not deployed.  For example, if a packet with
      spoofed source address corresponding to the networks
      infrastructure address range, is sent to a host (or other device)
      attached to the network, that host will send its response directly
      to the infrastructure address.  If such an attack was performed
      across a large number of hosts, then a successful large scale
      denial of service attack on the infrastructure could be achieved.
      This is not to say that a publicly numbered core will protect from
      the same attack, it won't.  The key point is that a reflection
      attack does get around the apparent security offered in a
      privately addressed core.

      Even if anti-spoofing is deployed at the AS boundary, the border
      routers will potentially carry routing information for the
      privately addressed network infrastructure.  This can mean that
      packets with spoofed addresses, corresponding to the private
      infrastructure addressing, may be considered legitimate by edge
      anti-spoofing techniques such as Unicast Reverse Path Forwarding -
      Loose Mode, and forwarded.  To avoid this situation, an edge anti-
      spoofing algorithm such as Unicast Reverse Path Forwarding -
      Strict Mode, would be required.  Strict approaches can be
      problematic in some environments or where asymmetric traffic paths

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      The approach on its own does not protect the network
      infrastructure from directly connected customers (i.e. within the
      same AS).  Unless other security controls, such as access control
      lists (ACLs), are deployed at the ingress point of the network,
      customer devices will normally be able to reach, and potentially
      attack, both core and edge infrastructure devices.

11.  Alternate approaches to core network security

   Today, hardware-based ACLs, which have minimal to no performance
   impact, are now widespread.  Applying an ACL at the AS perimeter to
   prevent access to the network core may be a far simpler approach and
   provide comparable protection to using private addressing, Such a
   technique is known as an infrastructure ACL (iACL).

   In concept, iACLs provide filtering at the edge network which allows
   traffic to cross the network core, but not to terminate on
   infrastructure addresses within the core.  Proper iACL deployment
   will normally allow required network management traffic to be passed,
   such that traceroutes and PMTUD can still operate successfully.  For
   an iACL deployment to be practical, the core network needs to have
   been addressed with a relatively small number of contiguous address
   blocks.  For this reason, the technique may or may not be practical.

   A second approach to preventing external access to the core is IS-IS
   core hiding.  This technique makes use of a fundamental property of
   the IS-IS protocol which allows link addresses to be removed from the
   routing table while still allowing loopback addresses to be resolved
   as next hops for BGP.  The technique prevents parties outside the AS
   from being able to route to infrastructure addresses, while still
   allowing traceroutes to operate successfully.  IS-IS core hiding does
   not have the same practical requirement for the core to be addressed
   from a small number of contiguous address blocks as with iACLs.  From
   an operational and troubleshooting perspective, care must be taken to
   ensure that pings and traceroutes are using source and destination
   addresses that exist in the routing tables of all routers in the
   path. i.e.  Not hidden link addresses.

   A third approach is the use of either an MPLS based IP VPN, or an
   MPLS based IP Core where the 'P' routers (or Label Switch Routers) do
   not carry global routing information.  As the core 'P' routers (or
   Label Switch Routers) are only switching labeled traffic, they are
   effectively not reachable from outside of the MPLS domain.  The 'P'
   routers can optionally be hidden such they do not appear in a
   traceroute.  While this approach isolates the 'P' routers from
   directed attacks, it does not protect the edge routers - being either
   a 'PE' router or a Label Edge Router (LER).  Obviously there are

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   numerous other engineering considerations in such an approach, we
   simply note it as an option.

   These techniques may not be suitable for every network, however,
   there are many circumstances where they can be used successfully
   without the associated effects of a privately addressing the core.

12.  Normative References

   [RFC1191]  Mogul, J. and S. Deering, "Path MTU Discovery",
              November 1990.

   [RFC1393]  Malkin, G., "Traceroute Using an IP Option", January 1993.

   [RFC1918]  Rekhter , Y., Moskowitz, R., Karrenberg, D., Jan de Groot,
              G., and E. Lear , "RFC1918 Address Allocation for Private
              Internets, BCP 5", Febuary  1996.

   [RFC2728]  Ferguson, P. and D. Senie , "RFC 2827 Network Ingress
              Filtering, BCP 38", May 2000.

   [RFC3021]  Retana, A., White, R., Fuller, V., and D. McPherson,
              "Using 31-Bit Prefixes on IPv4 Point-to-Point Links",
              December 2000.

   [RFC6304]  Abley, J. and W. Maton, "AS112 Nameserver Operations",
              July 2011.

   [RFC792]   Postel, J., "RFC792 Internet Control Message Protocol",
              September 1981.

              Barber, S., Delong, O., Grundemann, C., Kuarsingh, V., and
              B. Schliesser, "ARIN Draft Policy 2011-5: Shared
              Transition Space".

              Weil, J., Kuarsingh, V., Donley, C., Liljenstolpe, C., and
              M. Azinger, "IANA Reserved IPv4 Prefix for Shared CGN

Appendix A.  Acknowledgments

   The author would like to thank the following people for their input
   and review - Dan Wing (Cisco Systems), Roland Dobbins (Arbor
   Networks), Philip Smith (APNIC), Barry Greene (ISC), Anton Ivanov

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   (, Ryan Mcdowell (Cisco Systems), Russ White (Cisco
   Systems), Gregg Schudel (Cisco Systems), Michael Behringer (Cisco
   Systems), Stephan Millet (Cisco Systems), Tom Petch (BT Connect), Wes
   George (Time Warner Cable).

   The author would also like to acknowledge the use of a variety of
   NANOG mail archives as references.


   H  11  5

Author's Address

   Anthony Kirkham
   Palo Alto Networks
   Level 32, 100 Miller St
   North Sydney, New South Wales  2060

   Phone:  +61 7 33530902

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