Network Working Group P. Hoffman
Request for Comments: 4894 VPN Consortium
Category: Informational May 2007
Use of Hash Algorithms in Internet Key Exchange (IKE) and IPsec
Status of This Memo
This memo provides information for the Internet community. It does
not specify an Internet standard of any kind. Distribution of this
memo is unlimited.
Copyright Notice
Copyright (C) The IETF Trust (2007).
Abstract
This document describes how the IKEv1 (Internet Key Exchange version
1), IKEv2, and IPsec protocols use hash functions, and explains the
level of vulnerability of these protocols to the reduced collision
resistance of the MD5 and SHA-1 hash algorithms.
Recently, attacks on the collision-resistance properties of MD5 and
SHA-1 hash functions have been discovered; [HashAttacks] summarizes
the discoveries. The security community is now reexamining how
various Internet protocols use hash functions. The goal of this
reexamination is to be sure that the current usage is safe in the
face of these new attacks, and whether protocols can easily use new
hash functions when they become recommended.
Different protocols use hash functions quite differently. Because of
this, the IETF has asked for reviews of all protocols that use hash
functions. This document reviews the many ways that three protocols
(IKEv1 [IKEv1], IKEv2 [IKEv2], and IPsec [ESP] and [AH]) use hash
functions.
In this document, "IKEv1" refers to only "Phase 1" of IKEv1 and the
agreement process. "IKEv2" refers to the IKE_SA_INIT and IKE_AUTH
exchanges. "IPsec" refers to IP encapsulated in either the
Authentication Header (AH) or Encapsulating Security Payload (ESP).
2. Hashes in IKEv1 and IKEv2
Both IKEv1 and IKEv2 can use hash functions as pseudo-random
functions (PRFs). The inputs to the PRFs always contain nonce values
from both the initiator and the responder that the other party cannot
predict in advance. In IKEv1, the length of this nonce is at least
64 bits; in IKEv2, it is at least 128 bits. Because of this, the use
of hash functions in IKEv1 and IKEv2 are not susceptible to any known
collision-reduction attack.
IKEv1 also uses hash functions on the inputs to the PRF. The inputs
are a combination of values from both the initiator and responder,
and thus the hash function here is not susceptible to any known
collision-reduction attack.
In IKEv2, hashes are used as integrity protection for all messages
after the IKE_SA_INIT Exchange. These hashes are used in Hashed
Message Authentication Codes (HMACs). As described in
[HMAC-reduction], MD5 used in HMACs is susceptible to forgery, and it
is suspected that full SHA-1 used in HMAC is susceptible to forgery.
There is no known reason for the person who creates legitimate
integrity protection to want to spoof it.
Both IKEv1 and IKEv2 have authentication modes that use digital
signatures. Digital signatures use hashes to make unique digests of
the message being signed. With the current known attacks, the only
party that can create the two messages that collide is the IKE entity
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that generates the message. As shown in [Target-collisions], an
attacker can create two different Public Key Infrastructure using
X.509 (PKIX) certificates with different identities that have the
same signatures.
IKEv1 has two modes, "public key encryption" and "revised public key
encryption", that use hashes to identify the public key used. The
hash function here is used simply to reduce the size of the
identifier. In IKEv2 with public-key certificates, a hash function
is used for similar purposes, both for identifying the sender's
public key and the trust anchors. Using a collision-reduction
attack, an individual could create two public keys that have the same
hash value. This is not considered to be a useful attack because the
key generator holds both private keys.
IKEv1 can be used together with Network Access Translator (NAT)
traversal support, as described in [NAT-T]; IKEv2 includes this NAT
traversal support. In both of these cases, hash functions are used
to obscure the IP addresses used by the initiator and/or the
responder. The hash function here is not susceptible to any known
collision-reduction attack.
3. Hashes in IPsec
AH uses hash functions for authenticating packets; the same is true
for ESP when ESP is using its own authentication. For both uses of
IPsec, hash functions are always used in hashed MACs (HMACs). As
described in [HMAC-reduction], MD5 used in HMACs is susceptible to
forgery, and it is suspected that full SHA-1 used in HMAC is
susceptible to forgery. There is no known reason for the person who
creates legitimate packet authentication to want to spoof it.
4. PKIX Certificates in IKEv1 and IKEv2
Some implementations of IKEv1 and IKEv2 use PKIX certificates for
authentication. Any weaknesses in PKIX certificates due to
particular ways hash functions are used, or due to weaknesses in
particular hash functions used in certificates, will be inherited in
IKEv1 and IKEv2 implementations that use PKIX-based authentication.
5. Choosing Cryptographic Functions
Recently, there has been more discussion in the IETF about the
ability of one party in a protocol to tell the other party which
cryptographic functions the first party prefers the second party to
use. The discussion was spurred in part by [Deploying]. Although
that paper focuses on hash functions, it is relevant to other
cryptographic functions as well.
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There are (at least) three distinct subtopics related to choosing
cryptographic functions in protocols:
o The ability to pick between different cryptographic functions
instead of having just one specified in the protocol
o If there are multiple functions, the ability to agree on which
function will be used in the main protocol
o The ability to suggest to the other party which kinds of
cryptographic functions should be used in the other party's public
key certificates
5.1. Different Cryptographic Functions
Protocols that use cryptographic functions can either specify a
single function, or can allow different functions. Protocols in the
first category are susceptible to attack if the specified function is
later found to be too weak for the stated purpose; protocols in the
second category can usually avoid such attacks, but at a cost of
increased protocol complexity. In the IETF, protocols that allow a
choice of cryptographic functions are strongly preferred.
IKEv1, IKEv2, and IPsec already allow different hash functions in
every significant place where hash functions are used (that is, in
every place that has any susceptibility to a collision-reduction
attack).
5.2. Specifying Cryptographic Functions in the Protocol
Protocols that allow a choice of cryptographic functions need to have
a way for all parties to agree on which function is going to be used.
Some protocols, such as secure electronic mail, allow the initiator
to simply pick a set of cryptographic functions; if the responder
does not understand the functions used, the transmission fails.
Other protocols allow for the two parties to agree on which
cryptographic functions will be used. This is sometimes called
"negotiation", but the term "negotiation" is inappropriate for
protocols in which one party (the "proposer") lists all the functions
it is willing to use, and the other party (the "chooser") simply
picks the ones that will be used.
When a new cryptographic function is introduced, one party may want
to tell the other party that they can use the new function. If it is
the proposer who wants to use the new function, the situation is
easy: the proposer simply adds the new function to its list, possibly
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removing other parallel functions that the proposer no longer wants
to use.
On the other hand, if it is the chooser who wants to use the new
function and the proposer didn't list it, the chooser may want to
signal the proposer that they are capable of using the new function
or the chooser may want to say that it is only willing to use the new
function. If a protocol wants to handle either of these cases, it
has to have a way for the chooser to specify this information to the
proposer in its acceptance and/or rejection message.
It is not clear from a design standpoint how important it might be to
let the chooser specify the additional functions it knows. As long
as the proposer offers all the functions it wants to use, there is no
reason for the chooser to say "I know one you don't know". The only
place where the chooser is able to signal the proposer with different
functions is in protocols where listing all the functions might be
prohibitive, such as where they would add additional round trips or
significant packet length.
IKEv1 and IKEv2 allow the proposer to list all functions. Neither
allows the chooser to specify which functions that were not proposed
it could have used, either in a successful or unsuccessful Security
Association (SA) establishment.
5.3. Specifying Cryptographic Functions in Authentication
Passing public key certificates and signatures used in authentication
creates additional issues for protocols. When specifying
cryptographic functions for a protocol, it is an agreement between
the proposer and the chooser. When choosing cryptographic functions
for public key certificates, however, the proposer and the chooser
are beholden to functions used by the trusted third parties, the
certification authorities (CAs). It doesn't really matter what
either party wants the other party to use, since the other party is
not the one issuing the certificates.
In this discussion, the term "certificate" does not necessarily mean
a PKIX certificate. Instead, it means any message that binds an
identity to a public key, where the message is signed by a trusted
third party. This can be non-PKIX certificates or other types of
cryptographic identity-binding structures that may be used in the
future.
The question of specifying cryptographic functions is only relevant
if one party has multiple certificates or signatures with different
cryptographic functions. In this section, the terms "proposer" and
"chooser" have a different meaning than in the previous section.
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Here, both parties act as proposers of the identity they want to use
and the certificates with which they are backing up that identity,
and both parties are choosers of the other party's identity and
certificate.
Some protocols allow the proposer to send multiple certificates or
signatures, while other protocols only allow the proposer to send a
single certificate or signature. Some protocols allow the proposer
to send multiple certificates but advise against it, given that
certificates can be fairly large (particularly when the CA loads the
certificate with lots of information).
IKEv1 and IKEv2 allow both parties to list all the certificates that
they want to use. [PKI4IPsec] proposes to restrict this by saying
that all the certificates for a proposer have to have the same
identity.
6. Suggested Changes
In investigating how protocols use hash functions, the IETF is
looking at (at least) two areas of possible changes to individual
protocols: how the IETF might need to change the protocols, and how
implementors of current protocols might change what they do. This
section describes both of these areas with respect to IKEv1, IKEv2,
and IPsec.
6.1. Suggested Changes for the Protocols
Protocols might need to be changed if they rely on the collision-
resistance of particular hash functions. They might also need to be
changed if they do not allow for the agreement of hash functions
because it is expected that the "preferred" hash function for
different users will change over time.
IKEv1 and IKEv2 already allow for the agreement of hash functions for
both IKE and IPsec, and thus do not need any protocol change.
IKEv1 and IKEv2, when used with public key authentication, already
allow each party to send multiple PKIX certificates, and thus do not
need any protocol change.
There are known weaknesses in PKIX with respect to collision-
resistance of some hash functions. Because of this, it is hoped that
there will be changes to PKIX fostered by the PKIX Working Group.
Some of the changes to PKIX may be usable in IKEv1 and IKEv2 without
having to change IKEv1 and IKEv2. Other changes to PKIX may require
changes to IKEv1 and IKEv2 in order to incorporate them, but that
will not be known until the changes to PKIX are finalized.
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6.2. Suggested Changes for Implementors
As described in earlier sections, IKE and IPsec themselves are not
susceptible to any known collision-reduction attacks on hash
functions. Thus, implementors do not need to make changes such as
prohibiting the use of MD5 or SHA-1. The mandatory and suggested
algorithms for IKEv2 and IPsec are given in [IKEv2Algs] and
[IPsecAlgs].
Note that some IKE and IPsec users will misunderstand the relevance
of the known attacks and want to use "stronger" hash functions.
Thus, implementors should strongly consider adding support for
alternatives, particularly the AES-XCBC-PRF-128 [AES-PRF] and AES-
XCBC-MAC-96 [AES-MAC] algorithms, as well as forthcoming algorithms
based on the SHA-2 family [SHA2-HMAC].
Implementations of IKEv1 and IKEv2 that use PKIX certificates for
authentication may be susceptible to attacks based on weaknesses in
PKIX. It is widely expected that PKIX certificates in the future
will use hash functions other than MD5 and SHA-1. Implementors of
IKE that allow certificate authentication should strongly consider
allowing the use of certificates that are signed with the SHA-256,
SHA-384, and SHA-512 hash algorithms. Similarly, those implementors
should also strongly consider allowing the sending of multiple
certificates for identification.
7. Security Considerations
This entire document is about the security implications of reduced
collision-resistance of common hash algorithms for the IKE and IPsec
protocols.
The Security Considerations section of [HashAttacks] gives much more
detail about the security of hash functions.
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8. Informative References
[AES-MAC] Frankel, S. and H. Herbert, "The AES-XCBC-MAC-96
Algorithm and Its Use With IPsec", RFC 3566,
September 2003.
[AES-PRF] Hoffman, P., "The AES-XCBC-PRF-128 Algorithm for
the Internet Key Exchange Protocol (IKE)",
RFC 4434, February 2006.
[AH] Kent, S., "IP Authentication Header", RFC 4302,
December 2005.
[Deploying] Bellovin, S. and E. Rescorla, "Deploying a New
Hash Algorithm", NDSS '06, February 2006.
[HashAttacks] Hoffman, P. and B. Schneier, "Attacks on
Cryptographic Hashes in Internet Protocols",
RFC 4270, November 2005.
[HMAC-reduction] Contini, S. and YL. Yin, "Forgery and Partial
Key-Recovery Attacks on HMAC and NMAC Using Hash
Collisions", Cryptology ePrint Report 2006/319,
September 2006.
[IKEv1] Harkins, D. and D. Carrel, "The Internet Key
Exchange (IKE)", RFC 2409, November 1998.
[IKEv2Algs] Schiller, J., "Cryptographic Algorithms for use
in the Internet Key Exchange Version 2",
RFC 4307, December 2005.
[IPsecAlgs] Eastlake, D., "Cryptographic Algorithm
Implementation Requirements For ESP And AH",
RFC 4305, December 2005.
[NAT-T] Kivinen, T., Swander, B., Huttunen, A., and V.
Volpe, "Negotiation of NAT-Traversal in the
IKE", RFC 3947, January 2005.
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[PKI4IPsec] Korver, B., "The Internet IP Security PKI
Profile of IKEv1/ISAKMP, IKEv2, and PKIX", Work
in Progress, April 2007.
[SHA2-HMAC] Kelly, S. and S. Frankel, "Using HMAC-SHA-256,
HMAC-SHA-384, and HMAC-SHA-512 With IPsec",
RFC 4868, May 2007.
[Target-collisions] Stevens, M., Lenstra, A., and B. de Weger,
"Target Collisions for MD5 and Colliding X.509
Certificates for Different Identities",
Cryptology ePrint Report 2006/360, October 2006.
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Appendix A. Acknowledgments
Tero Kivinen helped with ideas in the first version of this document.
Many participants on the SAAG and IPsec mailing lists contributed
ideas in later versions. In particular, suggestions were made by
Alfred Hoenes, Michael Richardson, Hugo Krawczyk, Steve Bellovin,
David McGrew, Russ Housley, Arjen Lenstra, and Pasi Eronen.
Author's Address
Paul Hoffman
VPN Consortium
127 Segre Place
Santa Cruz, CA 95060
US
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