IPv6 Part 10: “NAT breaks IPsec”

It’s often commented that NAT (any form of NAT) breaks IPsec. In the case of Authentication Headers (AH) this is by design. The integrity check value (ICV) included in each AH packet covers every immutable field of the IP header; the ICV excludes only the fields such as TTL which are modified or can be modified in transit. So if either the source or destination IP address is modified by a NAT device then the ICV will be invalidated and the datagram discarded. However because AH doesn’t provide encryption, its use cases are pretty limited: for example, you might have to use it in countries where encryption is tightly regulated.

In some ways things are simpler with Encapsulated Security Payload (ESP): ESP ICVs don’t cover the addresses in the IP header. ESP in tunnel mode isn’t affected by the checksum problem. ESP in transport mode is more problematic: a NAT device will be unable to update the transport-level checksums which lie within the encrypted payload (if it is applying a checksum-neutral NAT such as NPTv6 then it won’t need to).

As I mentioned in my previous post, in either mode, tunnel or transport, if the encrypted ESP application data includes IP addresses then this will be opaque to any ALG on the NAT device. RFC 3715 specifies other problems that are more specifically related to NAPT:

  • Rather than ports, IPsec packets are identified by the Security Parameters Index (SPI) of the destination Security Association (SA). There is a separate IPsec SA for each direction, and the IKE exchange that defines the SA pair is encrypted. How then is a NAT device to know that an inbound IPsec packet with SPI x relates to the outbound SPI y and should be routed back to the relevant host?
  • Endpoints have problems in selecting correct entries in the Security Policy or Security Assocation databases, if multiple peers are hidden behind the same IP address.

NAT also causes problems for Internet Key Exchange (IKE):

  • Where IP addresses are used as peer identifiers, then NAT will cause a mismatch between the ID and the address in the datagram header, and the recipient should discard the datagram.
  • By default IKE uses UDP port 500 for both source and destination, but NAPT will typically modify the source port to overload multiple clients onto one external address.

In order to deal with these problems, NAT Traversal for IKE (NAT-T) was developed. NAT Discovery takes place during the Phase 1 IKE exchange: as soon as NAT is detected, then the IKE responder should switch to UDP port 4500. The IPsec packets are also encapsulated in UDP port 4500, so that NAPT devices can use the UDP source port to distinguish between IPsec conversations. NAT-T can also fix the checksum problem for IPsec transport mode, by transmitting the original IP addresses that were used to generate the checksums in the first place.

As RFC 3947 points out, with NAT in the picture, authentication based on IP address is no longer valid. Certificates form a much more secure method of authentication.

IPsec works at Layer 3 and NAPT depends on hacking around with Layer 4, so it’s not surprising that the two can clash. NAT-T is a widely-implemented work-around; moreover, given the almost-universal use of NAPT, secure (encrypted) communications have generally been implemented at a higher level in the protocol stack (specifically SSL/TLS). IPsec was originally developed for IPv6, with the vision of secure communication as a standard feature. However, as we move to an Internet where all communication is encrypted, it’s more likely to be implemented through TLS than it is through IPsec’s transport mode.

In the next post, I’ll look at whether NAT is a security feature.

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