Internet Key Exchange

In computing, Internet Key Exchange (IKE, sometimes IKEv1 or IKEv2, depending on version) is the protocol used to set up a security association (SA) in the IPsec protocol suite. IKE builds upon the Oakley protocol and ISAKMP.[1] IKE uses X.509 certificates for authentication ‒ either pre-shared or distributed using DNS (preferably with DNSSEC) and a Diffie–Hellman key exchange ‒ to set up a shared session secret from which cryptographic keys are derived.[2][3] In addition, a security policy for every peer which will connect must be manually maintained.[2]

History

The Internet Engineering Task Force (IETF) originally defined IKE in November 1998 in a series of publications (Request for Comments) known as RFC 2407, RFC 2408 and RFC 2409:

RFC 4306 updated IKE to version two (IKEv2) in December 2005.[7] RFC 4718 clarified some open details in October 2006.[8] RFC 5996 combined these two documents plus additional clarifications into the updated IKEv2,[9] published in September 2010. A later update upgraded the document from Proposed Standard to Internet Standard, published as RFC 7296 in October 2014.

The parent organization of the IETF, The Internet Society (ISOC), has maintained the copyrights of these standards as freely available to the Internet community.

Architecture

Most IPsec implementations consist of an IKE daemon that runs in user space and an IPsec stack in the kernel that processes the actual IP packets.

User-space daemons have easy access to mass storage containing configuration information, such as the IPsec endpoint addresses, keys and certificates, as required. Kernel modules, on the other hand, can process packets efficiently and with minimum overhead—which is important for performance reasons.

The IKE protocol uses UDP packets, usually on port 500, and generally requires 4–6 packets with 2–3 turn-around times to create an SA on both sides. The negotiated key material is then given to the IPsec stack. For instance, this could be an AES key, information identifying the IP endpoints and ports that are to be protected, as well as what type of IPsec tunnel has been created. The IPsec stack, in turn, intercepts the relevant IP packets if and where appropriate and performs encryption/decryption as required. Implementations vary on how the interception of the packets is done—for example, some use virtual devices, others take a slice out of the firewall, etc.

IKEv1 consists of two phases: phase 1 and phase 2.[10]

IKEv1 phases

IKE phase one's purpose is to establish a secure authenticated communication channel by using the Diffie–Hellman key exchange algorithm to generate a shared secret key to encrypt further IKE communications. This negotiation results in one single bi-directional ISAKMP Security Association (SA).[11] The authentication can be performed using either pre-shared key (shared secret), signatures, or public key encryption.[12] Phase 1 operates in either Main Mode or Aggressive Mode. Main Mode protects the identity of the peers and the hash of the shared key by encrypting them; Aggressive Mode does not.[10]

During IKE phase two, the IKE peers use the secure channel established in Phase 1 to negotiate Security Associations on behalf of other services like IPsec. The negotiation results in a minimum of two unidirectional security associations (one inbound and one outbound).[13] Phase 2 operates only in Quick Mode.[10]

Problems with IKE

Originally, IKE had numerous configuration options but lacked a general facility for automatic negotiation of a well-known default case that is universally implemented. Consequently, both sides of an IKE had to exactly agree on the type of security association they wanted to create – option by option – or a connection could not be established. Further complications arose from the fact that in many implementations the debug output was difficult to interpret, if there was any facility to produce diagnostic output at all.

The IKE specifications were open to a significant degree of interpretation, bordering on design faults (Dead-Peer-Detection being a case in point), giving rise to different IKE implementations not being able to create an agreed-upon security association at all for many combinations of options, however correctly configured they might appear at either end.

Improvements with IKEv2

The need and intent of an overhaul of the IKE protocol was described in Appendix A of RFC 4306. The following issues were addressed:

This can be explained like this:

Suppose HostA has a Security Parameter Index (SPI) A and HostB has an SPI B.

The scenario is like this:

      HostA---------------HostB

If HostB is experiencing large amount of half-open IKE init connection, the responder will send an unencrypted reply message of the ike_sa_init with a notify message of type cookie and the responder will expect an ike_sa_init request with that cookie value in a notify payload. This is to ensure that the initiator is really capable of handling a response from the responder.

     HostA-------------------------------------------------HostB
     HDR(A,0),sai1,kei,Ni----------------------------->
                  <----------------------------HDR(A,0),N(cookie)
     HDR(A,0),N(cookie),sai1,kei,Ni------------------->
                  <--------------------------HDR(A,B),SAr1,ker,Nr

Protocol extensions

The IETF ipsecme working group has standardized a number of extensions, with the goal of modernizing the IKEv2 protocol and adapting it better to high volume, production environments. These extensions include:

Implementations

IKE is supported as part of the IPsec implementation in Windows 2000, Windows XP, Windows Server 2003, Windows Vista and Windows Server 2008.[15] The ISAKMP/IKE implementation was jointly developed by Cisco and Microsoft.[16]

Microsoft Windows 7 and Windows Server 2008 R2 partially support IKEv2 (RFC 7296) as well as MOBIKE (RFC 4555) through the VPN Reconnect feature (also known as Agile VPN).

There are several open source implementations of IPsec with associated IKE capabilities. On Linux, Libreswan, Openswan and strongSwan implementations provide an IKE daemon called pluto, which can configure (i.e., establish SAs) to the KLIPS or NETKEY kernel-based IPsec stacks. NETKEY is the Linux 2.6 kernel's native IPsec implementation.

The Berkeley Software Distributions also have an IPsec implementation and IKE daemon, and most importantly a cryptographic framework (OpenBSD Cryptographic Framework, OCF), which makes supporting cryptographic accelerators much easier. OCF has recently been ported to Linux.

A significant number of network equipment vendors have created their own IKE daemons (and IPsec implementations), or license a stack from one another.

There are a number of implementations of IKEv2 and some of the companies dealing in IPsec certification and interoperability testing are starting to hold workshops for testing as well as updated certification requirements to deal with IKEv2 testing. ICSA Labs held its latest IKEv2 Interoperability Workshop in Orlando, FL in March 2007 with 13 vendors from around the world.

The following open source implementations of IKEv2 are currently available:

Vulnerabilities

Leaked NSA presentations released by Der Spiegel indicate that IKE is being exploited in an unknown manner to decrypt IPSec traffic, as is ISAKMP.[17] The researchers who discovered the Logjam attack state that breaking a 1024-bit Diffie–Hellman group would break 66% of VPN servers, 18% of the top million HTTPS domains, and 26% of SSH servers, which the researchers claim is consistent with the leaks.[18]

See also

References

  1. The Internet Key Exchange (IKE), RFC 2409, §1 Abstract
  2. 1 2 RFC 3129: Requirements for Kerberized Internet Negotiation of Keys, Internet Engineering Task Force, June 2001, p. 1
  3. RFC 4322: Opportunistic Encryption using the Internet Key Exchange (IKE), Internet Engineering Task Force, June 2001, p. 5
  4. "RFC 2407 The Internet IP Security Domain of Interpretation for ISAKMP". Internet Engineering Task Force (IETF).
  5. "RFC 2408 Internet Security Association and Key Management Protocol (ISAKMP)". Internet Engineering Task Force (IETF).
  6. D. Harkins. "RFC 2409 The Internet Key Exchange (IKE)". Internet Engineering Task Force (IETF).
  7. C. Kaufman (Microsoft) (December 2005). "RFC 4306 Internet Key Exchange (IKEv2) Protocol". Internet Engineering Task Force (IETF).
  8. P. Eronen (Nokia), P. Hoffman (VPN Consortium) (October 2006). "RFC 4718 IKEv2 Clarifications and Implementation Guidelines". Internet Engineering Task Force (IETF).
  9. C. Kaufman (Microsoft), P. Hoffman (VPN Consortium), Y. Nir (Check Point), P. Eronen (Independent) (September 2010). "RFC 5996 Internet Key Exchange (IKEv2) Protocol". Internet Engineering Task Force (IETF).
  10. 1 2 3 "RFC 2409 The Internet Key Exchange (IKE)", Internet Engineering Task Force (IETF), p. 5
  11. "RFC 2409 The Internet Key Exchange (IKE)", Internet Engineering Task Force (IETF), p. 6
  12. "RFC 2409 The Internet Key Exchange (IKE)", Internet Engineering Task Force (IETF), p. 10-16
  13. "RFC 4306 Internet Key Exchange (IKEv2) Protocol", Internet Engineering Task Force (IETF), p. 11,33
  14. "RFC 4306: Internet Key Exchange (IKEv2) Protocol", Internet Engineering Task Force (IETF), p 38-40
  15. Internet Key Exchange: Internet Protocol Security (IPsec): Technet
  16. Using IPSec in Windows 2000 and XP, Part 1
  17. Fielded Capability: End-to-end VPN SPIN9 Design Review (PDF), NSA via 'Der Spiegel', p. 5
  18. Adrian, David; Bhargavan, Karthikeyan; Durumeric, Zakir; Gaudry, Pierrick; Green, Matthew; Halderman, J. Alex; Heninger, Nadia; Springall, Drew; Thomé, Emmanuel; Valenta, Luke; VanderSloot, Benjamin; Wustrow, Eric; Zanella-Béguelin, Santiago; Zimmermann, Paul (October 2015). Imperfect Forward Secrecy: How Diffie-Hellman Fails in Practice (PDF). 22nd ACM Conference on Computer and Communications Security (CCS ’15). Denver. Retrieved 15 June 2016.
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