One document matched: draft-stiemerling-hip-nat-02.txt
Differences from draft-stiemerling-hip-nat-01.txt
Internet Draft M. Stiemerling
Document: draft-stiemerling-hip-nat-02.txt J. Quittek
Expires: April 2005 NEC Europe Ltd.
October 2004
Problem Statement: HIP operation over Network Address Translators
<draft-stiemerling-hip-nat-02.txt>
Status of this Memo
This document is an Internet-Draft and is subject to all provisions
of section 3 of RFC 3667. By submitting this Internet-Draft, each
author represents that any applicable patent or other IPR claims of
which he or she is aware have been or will be disclosed, and any of
which he or she become aware will be disclosed, in accordance with
RFC 3668.
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Copyright Notice
Copyright (C) The Internet Society (2004). All Rights Reserved.
Abstract
This memo investigates issues for Host Identity Protocol (HIP) nodes
that communicate over a network path that includes Network Address
Translators (NATs). There are two groups of issues: Operating HIP
itself across NATs and operating the IPsec-based data transmission
initiated by HIP across NATs. For both groups problems are
summarized.
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Table of Contents
1 Introduction ................................................. 3
2 Terminology .................................................. 3
3 HIP Network Environment ...................................... 4
4 Problems with operating HIP across NATs ...................... 5
4.1 HIP Base Exchange .......................................... 5
4.1.1 HIP over IPv6 ............................................ 6
4.1.2 HIP over IPv4 ............................................ 6
4.2 IPsec Data Exchange ........................................ 7
5 Extensions to HIP ............................................ 7
6 Extension to NATs ............................................ 8
7 HIP unaware NATs ............................................. 8
8 HIP across Twice-NAT ......................................... 9
9 Middleboxes .................................................. 11
9.1 Firewalls .................................................. 11
10 Security Considerations ..................................... 11
11 Acknowledgements ............................................ 12
12 References .................................................. 12
13 Authors' Addresses .......................................... 13
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1. Introduction
The Host Identity Protocol (HIP) architecture [HIP-ARCH] introduces a
new kind of identifier for each host. Instead of using the IP
address as host identity, a new Host Identifier is introduced. This
additional namespace, separates the host identity from the routing
information contained in the IP address.
The current version of the HIP Architecture is based on the
assumption of full reachability between the IP addresses assigned to
the participating hosts. This is usually given if both hosts have IP
addresses belonging to the same address realm, for example, if both
have public addresses. But if the host's addresses belong to
different realms, for example one has a private IP address and the
other one a public one, then network address translation must be
provided between the realms. So far, network address translation is
not integrated into the HIP architecture and HIP [HIP-PROTO] does not
have particular means to support it.
Problems arising in conjunction with Network Address Translators
(NATs) are two-fold. First the HIP base exchange needs to traverse
NATs and then the IPsec encoded transport initiated by HIP needs to
traverse it (see [RFC2401] for an introduction to IPsec). In
general, both protocols have the risk of being blocked by NATs.
This document discusses the problems encountered when using HIP in
the presence of NATs in Section 4. Impacts on HIP itself and the
used IPsec mechanism are elaborated. Section 5 discusses extensions
to HIP that potentially can solve some of the problems. Section 6
suggests extensions to the functions provided by today's NATs
complementing the HIP extensions. NATs that are not aware of HIP are
handled in Section 7 and operating HIP together with twice-NATs is
briefly summarized in Section 8. Section 9 gives an outlook an the
impact of different other types of middleboxes on HIP.
It is not the intend of this memo to promoted the use of NATs in the
context of HIP, but since NATs are widely deployed it is necessary to
take them into account while developing HIP.
2. Terminology
Terms used throughout this document are consistent with IPsec
terminology [RFC2401], HIP terminology [HIP-ARCH][HIP-PROTO][HIP-MM],
and NAT terminology [RFC2663]. For an introduction to NATs readers
are recommended to read [RFC2663]. In this memo the term NAT refers
to NAT and NAPT. Twice-NATs are handled separately.
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3. HIP Network Environment
The HIP Architecture described in [HIP-ARCH] assumes full
reachability between the IP addresses assigned to the participating
hosts.
+---------+ -------- +---------+
| HIP | / \ | HIP |
| peer |----| Internet |---| peer |
| A | \ realm / | B |
+---------+ -------- +---------+
Figure 1: Assumed network environment for HIP
This is usually given if both hosts have IP addresses belonging to
the same address realm, for instance, if both have public addresses
or if both have addresses belonging to the same private address realm
as shown by Figure 1. Within one realm, IP addresses provide end-to-
end routing information between hosts A and B. If A wants to send a
packet to B, it is sufficient for A to know the IP address assigned
to B.
The scenario sketched by Figure 1 is an ideal one. It does not
(anymore) match today's current scenarios where an increasing number
of hosts use private IP addresses, mainly, because of lack of IP
addresses in IPv4. Furthermore, a separation of an organization's
network from the public Internet realm hides the organization's
network structure and enables more flexible internal renumbering of
IP addresses.
If the host's addresses belong to different realms, then
communication between these hosts requires network address
translation between the realms. Network Address Translators (NATs,
[RFC2663]) provide this service. Figure 2 shows an example of a host
B with a private IP address and a host A with a public IP address.
The scenario in Figure 2 is limited to a NAT on peer B's side only,
but in general both peers might be located behind NATs.
+--+
+---------+ -------- | | -------- +---------+
| HIP | / public \ |N | / private \ | HIP |
| peer |--| Internet |--|A |--| Internet |--| peer |
| A | \ realm / |T | \ realm / | B |
+---------+ -------- | | -------- +---------+
+--+
Figure 2: Network environment with NAT
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The translation performed by NATs affects the IP header and (in most
existing cases) also the transport header. IP addresses and
transport port numbers are translated between the address realms. In
the scenario illustrated by Figure 2, host A would address all HIP
messages that it intends to send to host B to a public IP address
that is provided by the NAT. The NAT receives the message for this
address (typically in combination with a dynamically chosen port
number) and replaces the destination IP address (and typically also
the TCP or UPD port number) before it forwards the packet into the
private realm.
The public IP address (and port number) that the NAT uses for this
translation service is in general not known to host A. Therefore,
applications that carry address information in their payload or
applications that rely on static protocol header fields experience
severe problems. Often, the application-level signaling can traverse
NATs, but subsequent data exchange fails (see [NATP2P]).
NATs are heavily used in IPv4 networks when there is a significant
lack of address space. Initially, they were expected not to be
present in IPv6 networks, but the authors believe that NATs will also
be used in IPv6 networks, despite the availability of a much larger
address space. Today, even organizations owning a sufficiently large
IPv4 address space tend to use private Internet realms, because this
hides their internal network structure and allows to renumber the
internal network addresses without communicating this to the public
network.
4. Problems with operating HIP across NATs
HIP operation can be divided into two phases. The first one is the
HIP base exchange using HIP only. The second one is the actual
application data exchange via IPsec. This section separately
describes the problems that occur in each of the phases when network
address translation is integrated into the HIP architecture.
4.1. HIP Base Exchange
The HIP base exchange uses different transport mechanisms for IPv6
and IPv4.
o IPv6
When IPv6 is used, a HIP-specific IPv6 extension header carries
all information necessary (see Section 6 of [HIP-PROTO]).
o IPv4
When IPv4 is used, HIP messages are transmitted as UDP payload.
(see Appendix E of [HIP-PROTO]).
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4.1.1. HIP over IPv6
Current implementations use plain IPv6 packets without any payload
other than the HIP extension header. This causes problems in
combination with NATs that multiplex many private IP addresses into a
few public addresses. Usually, this kind of multiplexing is
performed on a combination of IP address and TCP or UDP port number.
In the absence of a TCP or UDP transport header, typical network
address and port translation will fail. Currently there is no
specific scheme defined for translating IPv6 HIP extension headers in
the absence of TCP or UDP headers. This all is a minor concern right
now, since the likelihood of NATs in IPv6 is small.
Another problem (that also applies to IPv4) is that HIP provides no
explicit means for transmitting the IP address used by a host other
than using the source IP address of the packet carrying HIP messages.
Even if a host B in Figure 2 would know the public IP address used by
the NAT for translation, it has no means of providing this
information to host A.
4.1.2. HIP over IPv4
The use of UDP encapsulation for IPv4 transmission enables the HIP
base exchange to traverse NATs and to reach their final destination.
This encapsulation scheme replaces the IPv6 extension header with a
UDP header followed by a HIP header. All HITs and HIP parameters are
appended to this new HIP UDP header. UDP transport suffers from many
well known problems when traversing NATs (compare Section 2.2 of
[RFC3715] also for some issues on UDP traversal). One problem is
that often NATs are not able or do not allow to traverse UDP packets,
they are blocked and discarded. If NATs do allow UDP packets to
traverse, it is not determinable which UDP port number and IP address
is used for outgoing UDP packets. HIP over UDP is mandating a fixed
port number of 272 for source and destination ports. NATs may change
the source port number to any possible port number, for instance, a
source port of 272 may be changed by the NAT to 34657.
The above paragraph implies that outgoing packets (packets origin in
a private address realm and traversing towards the public address
realm) are allowed to traverse, but for the opposite way, incoming
packets, this is not necessary given. Only incoming packets that are
replies to outgoing packets are able to traverse the NAT. For
incoming packets, from flows originating in the public address realm,
there is no way of traversing. The destination address in the
private address realm (more precise the IP address NAT binding) is
not given, thus no address mapping is possible. So transmissions
originating in the public Internet are unable to traverse (or even
reach the NAT), unless the NAT has some pre-configured
configurations.
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4.2. IPsec Data Exchange
IPsec secures data transmission between two HIP nodes after their
base exchange is completed. Well-known issues with IPsec and NAT are
listed in [RFC3715] and apply to the IPsec use of HIP as well. Those
issues are separated into NAT intrinsic issues, NAT implementation
issues and helper incompatibilities. The NAT intrinsic issues
related to IPsec (IKE issues are omitted) are:
1. By using ESP all upper layer headers are invisible to the NAT.
So changes of the IP header during NAT traversal invalidate any
upper layer checksums that are protected within ESP after ESP
decryption. HIP takes care about not invalidating upper layer
checksums, by using HITs instead of IP addresses for checksum
calculations (see Section 3.5 of [HIP-PROTO]). So this is not
applicable here.
2. It is possible to use ESP encrypted packets through a NAT, but
as [RFC3715] remarks, the used SPI values have only one-way
significance. Furthermore, SPI values may collide at the NAT,
meaning that two different peers behind the NAT are using the
same SPI value.
3 SPI could be use for multiplexing different IPsec flows at the
NAT. But since SPI have only this one-way significance, NATs
can only learn the SPI value of outgoing ESP flows, but not the
SPI value of the response ESP flow.
A possible way of carrying IPsec traffic through NATs has been
proposed in [IPSEC-UDP]. IPsec traffic is encapsulated in UDP
packets.
5. Extensions to HIP
[HIP-MM][HIP-PA] propose new extensions to HIP to make it usable for
end host mobility and multi-homing.
Out of those proposals, one extension to HIP can be used for HIP and
NAT traversal: HIP peers are able to notify other HIP peers about
new addresses they have obtained with the REA packet exchange (see
Section 4 of [HIP-MM]). With REA a HIP node can notify other HIP
nodes about new addresses, for example, about its new address at a
NAT. This functionality has been already described and can be used
for NAT traversal.
The issue is how to determine the publicly reachable IP address, so
that it can be announced within the REA packet to the HIP peer.
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6. Extension to NATs
As described in Section 4.2, IPsec SPIs have only one-way
significance, meaning that NATs can learn SPI values of outgoing
packets, but they cannot learn the corresponding SPI values of
incoming packets. Therefore, a matching between SPI values used for
outgoing flows to SPI values used for incoming flows is not possible.
NATs must learn the corresponding SPI values for outgoing and
incoming IPsec flows. There are two ways in doing so. First, NATs
can monitor the HIP base exchange and learn the SPI values agreed by
both HIP peers. Afterwards, NATs can remember these values and map
outgoing and incoming IPsec flows accordingly.
Second, HIP peers can use a NAT signaling protocol and signal the
appropriate SPI values with IP addresses. NATs can so learn the SPI
values out of the signaling protocol.
Both approaches require changes to NATs. The first approach would
require changes that are only benificial to HIP, the second one would
be beneficial for other protocols as well. Possible solutions for
signaling NATs SPI values are NSIS NAT/FW traversal [NSIS-NATFW] and
MIDCOM.
Using MIDCOM in the context of HIP would require some additional
knowledge about network topology, for instance, in multihomed
environments with different border NATS, host must know which of the
multiple NATs to signal for. Therefore, this solution is hard to
deploy.
By using the NSIS NAT/FW traversal (NATFW NSLP) mechanism HIP nodes
could signal the later on used SPI values for both directions. NATFW
NSLP always ensures that signaling messages will reach an appropriate
NAT and those messages follow exactly the data path (path-coupled
signaling). NSIS requires usually both ends, i.e., both HIP peers,
to support this new signaling protocol. However, NATFW NSLP offers
support for only one end supporting this protocol. HIP peers behind
a NATFW NSLP enabled NAT could so configure the local NATs without
impacting other networks. An add-on is given through NATFW
traversal, too, since on-path firewalls are configured as well.
7. HIP unaware NATs
The solutions outlined in Section 6 require that NATs are updated to
support new functions, such as HIP itself or NSIS NATFW signaling.
By today's measures, NATs are widely deployed and are currently
getting a push through low-cost devices rolled-out to broadband
connection users, for instance, DSL lines. NATs are deployed in
various places, enterprise borders, mobile phone networks offering
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IP-based services, and many more.
Since there many NATs deployed, it will be impossible to upgrade or
replace all of them to support HIP or HIP-related extensions. It is
the intent of this section to explore how HIP works even in the
presence of these HIP unaware NATs. Deployed NATs are currently IPv4
only, so that this section takes them into account only.
For HIP over IPv4, UDP encapsulated HIP messages solve already some
problems in traversing NATs. Usually, UDP packets can traverse NATs
from inside (private Network) to outside (public network) and vice
versa when they have been initiated from inside. The other way
around, initiated from outside, will be blocked or impossible since
the destination IP address of the NAT is not known a priory. In the
case that UDP encapsulation works fine for the HIP message exchange,
IPsec is still troublesome (see [RFC3715]). Some NAT implementations
offer some sort of so-called VPN passthrough, where the NAT learns
about IPsec flows and tries to correlate outgoing and incoming SPI
values (see [AIREXT] for an example). This works probably only for a
small numbers of nodes behind a single NAT, until there will be SPI
collisions.
The solution for running IPsec through NATs is documented in [IPSEC-
UDP] and applicable here, too. HIP should support IPsec over UDP
transport through an extension to the signaling. This extension
would indicate when to use IPsec over UDP, instead of plain IPsec.
8. HIP across Twice-NAT
A type of Network Address Translation is not mentioned in previous
sections about traditional NAT and NAPT. These so-called twice-NATs
(see [RFC2663]) are translating source and destination address at
once while a datagram is translated from one address realm into
another. Typically, twice-NATs are used when two private address
realms have address collisions, for example, if two enterprises merge
their networks and both of them are using the same address realm.
Twice-NATs are used for IPv4 networks, but some networks use NAT with
protocol translation (NAT-PT, [RFC2766]). These NAT-PT translate
from IPv6 to IPV4 and vice versa. This form of NAT is not considered
within this memo, since HIP facilitates its own IPv4 to IPv6
mechanism.
Figure 3 sketches a scenario where HIP peers A and C are in
overlapping address realms, due to address conflicts and HIP peer B
is in the public Internet.
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+--+
+---------+ -------- | | -------- +---------+
| HIP | / private \ |T | / public \ | HIP |
| peer |--| Internet |--|W |--| Internet |--| peer |
| A | \ realm1 / |I | \ realm / | B |
+---------+ -------- |C | -------- +---------+
|E |
+---------+ -------- | |
| HIP | / private \ |N |
| peer |--| Internet |--|A |
| C | \ realm2 / |T |
+---------+ -------- | |
+--+
Figure 3: Network Environment with twice-NAT
Twice-NATs are usually operated with application level support, such
as DNS proxies or SIP proxies. These proxies intercept application
signaling and configure the twice-NAT box according the request.
Configuring means allocating the first IP address in one address
realm (e.g., realm1) and a second IP address in another address realm
(e.g., reaml2). The configuration assures that data from the private
realm is sent to one of the twice-NAT's addresses and afterwards
mapped^into the other address realm. Furthermore, the proxies will
modify the application signaling to reflect the address changes. HIP
peer A would see data from HIP peer C actually coming from the twice-
NAT's address in realm1. HIP^peer C would see data coming from HIP
peer A coming from the twice-NAT's address in realm2. For HIP peer B
data from peer A and B would come from one of the public IP addresses
of the twice-NAT. For further studies it is assumed that the twice-
NAT is running a n:m translation with n=m and n(realm1)=n(realm2),
where n is the number of internal IP addresses in each realm and m
the number of public IP addresses. It should be noted that traffic
either from peer A or C to peer B does not necessarily be traversed
through twice-NAT; traditional NAT or NAPT is sufficient.
While using DNS queries to find another peer's IP address behind the
same twice-NAT, the DNS proxy is configuring the NAT to forward
traffic between both peers (peer A and peer C in Figure 3). The HIP
base exchange and IPSec traffic should be able to traverse the twice-
NAT without any problem since only the address translation is done,
but it should be considered that both source and destination address
will be changed. There is port mapping, since the address
translation is 1:1 and the multiplexing is done on an IP address
base. The IPSec traffic is valid for processing at both peers as
long as ESP is used only, but the use of AH will result in broken
checks, since the IP addresses were changed.
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The advent of non-DNS based lookup mechanisms (such as described in
[RRPROP]) is challenging for HIP with twice-NATs. Either a new type
of proxy for this lookup mechanism must be installed at every twice-
NAT device or as mentioned in Section 6 a new signaling protocol
between HIP peer and twice-NAT can be used.
9. Middleboxes
This memo currently investigates the impact of NAT on HIP only. But
NATs are belonging to the class of middleboxes, where a middlebox is
according to [RFC3234] "any intermediary box performing functions
apart from normal, standard functions of an IP router on the data
path between a source host and destination host."
The intention of this section is to allude on the variety of
middleboxes that HIP might expect in the Internet. The list of
possible middleboxes can be found in [RFC3234]. Future versions of
this memo will elaborate the impact of each middlebox type on HIP.
Currently, the impact of firewalls is listed here as an example.
9.1. Firewalls
It is assumed that HIP peer A and peer B in Figure 2 are located
within the same address realm and only separated by an IP firewall
middlebox. IP firewalls, usually as known as packet filter
firewalls, do inspection on a packet base and decided whether to
forward or discard a packet. This type of middlebox is first of all
not an obstacle for HIP, as long as the policy rule set defining the
filtering allows the HIP base exchange and IPsec traffic to traverse.
However, it is common to block traffic with unknown IPv6 extension
headers, such as HIP is using, therefore preventing to exchange the
HIP base exchange messages. Furthermore, outbound traffic initiated
in the protected part is allowed to traverse and corresponding
inbound traffic too. On the other hand, traffic initiated from
outside and headed inbound is blocked by default. This issue is a
problem for the IPsec traffic, since the correlation between outbound
IPsec (defined through IP source, IP destination, outbound SPI value)
and inbound (defined through IP source, IP destination, inbound SPI
value) is impossible to learn for the IP firewall. No correlation is
possible, as long as the firewall is unable to learn these
corresponding outbound and inbound SPI values.
10. Security Considerations
To be done.
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11. Acknowledgements
The authors like to thank Lars Eggert for his valuable comments.
12. References
[RFC2401] Kent, S., and R. Atkinson, "Security Architecture for the
Internet Protocol", RFC 2401, November 1998.
[RFC2402] Kent, S., and R. Atkinson, "IP Authentication Header", RFC
2402, November 1998.
[RFC2406] Kent, S., and R. Atkinson, "IP Encapsulating Security
Payload (ESP)", RFC 2406, November 1998.
[IPSEC-UDP] Huttunen, A., et al, "UDP Encapsulation of IPsec Packets ",
draft-ietf-ipsec-udp-encaps-09.txt, Internet Draft ( work in
progress), May 2004.
[RFC3715] Aboba, B., and W. Dixon, "IPsec-NAT Compatibility
Requirements ", RFC 3715, March 2004.
[HIP-ARCH] Moskowitz, R., and P. Nikander, "Host Identity Protocol
Architecture", draft-moskowitz-hip-arch-06.txt, Internet
Draft (work in progress), June 2004.
[HIP-PROTO] Moskowitz, R., Nikander, P., and T. Henderson, "Host
Identity Protocol", draft-moskowitz-hip-09.txt, Internet
Draft (work in progress), February 2004.
[HIP-MM] Nikander, P., and P. Jokela, "End-Host Mobility and Multi-
Homing with Host Identity Protocol", draft-nikander-hip-
mm02.txt, Internet Draft (work in progress), July 2004.
[HIP-PA] Nikander, P., Ylitalo, J., and J. Wall, "Integrating
Security, Mobility, and Multi-Homing in a HIP way", NDSS
2003, 2003.
[NATP2P] Ford, B., Srisuresh, P., and D. Kegel, *(lqPeer-to-Peer
(P2P) communication across middleboxes*(rq, draft-ford-
midcom-p2p-03.txt, Internet Draft (work in progress), June
2004
[RFC2663] Srisuresh, P., and M. Holdrege, "IP Network Address
Translator (NAT) Terminology and Considerations", RFC 2663,
August 1999
Stiemerling, Quittek [Page 12]
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[RFC793] Postel, J., "Transmission Control Protocol", RFC 793,
September 1981
[RFC768] Postel, J., "User Datagram Protocol", RFC 768, August 1980
[RF3234] Carpenter, B., and S. Brim, "Middleboxes: Taxonomy and
Issues", RFC 3234, February 2002
[RFC2766] Tsirtsis, G., and P. Srisuresh, "Network Address Translation
- Protocol Translation (NAT-PT)", RFC 2766, February 2000
[NSIS-NATFW]
Stiemerling, M., Tschofenig, H., Martin, M., and C. Aoun,
"NAT/Firewall NSIS Signaling Layer Protocol (NSLP)", draft-
ietf-nsis-nslp-natfw-03.txt, Internet Draft (work in
progress), July 2004
[RRPROB]
Eggert, L, and J. Laganier, "HIP Resolution and Rendezvous Problem
Description", Internet draft, draft-eggert-hiprg-rr-prob-
desc-00.txt, (work in progress), October 2004
[AIREXT] Apple Airport stations with VPN passthrough support,
http://www.apple.com/airportexpress/specs.html, July 2004,
13. Authors' Addresses
Martin Stiemerling
NEC Europe Ltd.
Network Laboratories
Kurfuersten-Anlage 36
69115 Heidelberg
Germany
Phone: +49 6221 90511-13
Email: stiemerling@netlab.nec.de
Juergen Quittek
NEC Europe Ltd.
Network Laboratories
Kurfuersten-Anlage 36
69115 Heidelberg
Germany
Phone: +49 6221 90511-15
EMail: quittek@netlab.nec.de
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