Routing Working Group M. Jethanandani
Internet-Draft Ciena Corporation
Intended status: Informational K. Patel
Expires: December 23, 2012 Cisco Systems, Inc
L. Zheng
Huawei
June 23, 2012

Analysis of BGP, LDP, PCEP and MSDP Issues According to KARP Design Guide
draft-ietf-karp-routing-tcp-analysis-02.txt

Abstract

This document analyzes BGP, LDP, PCEP and MSDP according to guidelines set forth in section 4.2 of Keying and Authentication for Routing Protocols Design Guidelines [RFC6518].

The key words "MUST", "MUST NOT", "REQUIRED", "SHALL", "SHALL NOT", "SHOULD", "SHOULD NOT", "RECOMMENDED", "MAY", and "OPTIONAL" in this document are to be interpreted as described in RFC 2119 [RFC2119]..

Status of this Memo

This Internet-Draft is submitted in full conformance with the provisions of BCP 78 and BCP 79.

Internet-Drafts are working documents of the Internet Engineering Task Force (IETF). Note that other groups may also distribute working documents as Internet-Drafts. The list of current Internet- Drafts is at http://datatracker.ietf.org/drafts/current/.

Internet-Drafts are draft documents valid for a maximum of six months and may be updated, replaced, or obsoleted by other documents at any time. It is inappropriate to use Internet-Drafts as reference material or to cite them other than as "work in progress."

This Internet-Draft will expire on December 23, 2012.

Copyright Notice

Copyright (c) 2012 IETF Trust and the persons identified as the document authors. All rights reserved.

This document is subject to BCP 78 and the IETF Trust's Legal Provisions Relating to IETF Documents (http://trustee.ietf.org/license-info) in effect on the date of publication of this document. Please review these documents carefully, as they describe your rights and restrictions with respect to this document. Code Components extracted from this document must include Simplified BSD License text as described in Section 4.e of the Trust Legal Provisions and are provided without warranty as described in the Simplified BSD License.


Table of Contents

1. Introduction

In March 2006 the Internet Architecture Board (IAB) in its "Unwanted Internet Traffic" workshop documented in Report from the IAB workshop on Unwanted Traffic March 9-10, 2006 [RFC4948] described an attack on core routing infrastructure as an ideal attack with the most amount of damage. Four main steps were identified for that tightening:

  1. Create secure mechanisms and practices for operating routers.
  2. Clean up the Internet Routing Registry [IRR] repository, and securing both the database and the access, so that it can be used for routing verifications.
  3. Create specifications for cryptographic validation of routing message content.
  4. Secure the routing protocols' packets on the wire.

This document looking at the last bullet performs the initial analysis of the current state of BGP, LDP, PCEP and MSDP according to the requirements of KARP Design Guidelines [RFC6518]. This draft builds on several previous analysis efforts into routing security. The OPSEC working group put together Issues with existing Cryptographic Protection Methods for Routing Protocols [RFC6039] an analysis of cryptographic issues with routing protocols and Analysis of OSPF Security According to KARP Design Guide [draft-ietf-karp-ospf-analysis-03].

Section 2 looks at the current state of the four routing protocols. Section 3 goes into what the optimal state would be for the three routing protocols according to KARP Design Guidelines [RFC6518] and Section 4 does a analysis of the gap between the existing state and the optimal state of the protocols and suggest some areas where we need to improve.

1.1. Contributing Authors

Anantha Ramaiah, Mach Chen

1.2. Abbreviations

BGP - Border Gateway Protocol

DoS - Denial of Service

KARP - Key and Authentication for Routing Protocols

KDF - Key Derivation Function

KEK - Key Encrypting Key

KMP - Key Management Protocol

LDP - Label Distribution Protocol

LSR - Label Switch Routers

MAC - Message Authentication Code

MKT - Master Key Tuple

MSDP - Multicast Source Distribution Protocol

MD5 - Message Digest algorithm 5

OSPF - OPen Shortest Path First

PCEP - Path Computation Element Protocol

TCP - Transmission Control Protocol

UDP - User Datagram Protocol

2. Current State of BGP, LDP, PCEP and MSDP

This section looks at the underlying transport protocol and key mechanisms built for the protocol. It describes the security mechanisms built into BGP, LDP, PCEP and MSDP.

2.1. Transport level

At a transport level, routing protocols are subject to a variety of DoS attacks. Such attacks can cause the routing protocol to become congested with the result that routing updates are supplied too slowly to be useful or in extreme case prevent route convergence after a change.

Routing protocols use several methods to protect themselves. Those that run use TCP as a transport protocol use access list to permit packets from know sources only. These access lists also help edge routers from attacks originating from outside the protected cloud. In addition for edge routers running eBGP, TCP LISTEN is run only on interfaces on which its peers have been discovered or that are configured to expect routing sessions on.

GTSM [RFC5082] describes a generalized Time to Live (TTL) security mechanism to protect a protocol stack from CPU-utilization based attacks.TCP Robustness [RFC5961] recommends some TCP level mitigations against spoofing attacks targeted towards long lived routing protocol sessions.

Even when BGP, LDP, PCEP and MSDP sessions use access list they are subject to spoofing and man in the middle attacks. Authentication and integrity checks allow the receiver of a routing protocol update to know that the message genuinely comes from the node that purports to have sent it and to know whether the message has been modified. Sometimes routers can be subjected to a large number of authentication and integrity checks which can result in genuine requests failing.

TCP MD5 [RFC2385] specifies a mechanism to protect BGP and other TCP based routing protocols via the TCP MD5 option. TCP MD5 option provides a way for carrying an MD5 digest in a TCP segment. This digest acts like a signature for that segment, incorporating information known only to the connection end points. The MD5 key used to compute the digest is stored locally on the router. This option is used by routing protocols to provide for session level protection against the introduction of spoofed TCP segments into any existing TCP streams, in particular TCP Reset segments. TCP MD5 does not provide a generic mechanism to support key roll-over.

However, the Message Authentication Codes (MACs) used by MD5 to compute the signature are considered to be too weak. TCP-AO [RFC5925] and its companion document Crypto Algorithms for TCP-AO [RFC5926] describe steps towards correcting both the MAC weakness and KMP. For MAC it specifies two MAC algorithms that MUST be supported. They are HMAC-SHA-1-96 as specified in HMAC [RFC2104] and AES-128-CMAC-96 as specified in NIST-SP800-38B [NIST-SP800-38B]. Cryptographic research suggests that both these MAC algorithms defined are fairly secure and are not known to be broken in any ways. It also provides for additional MACs to be added in the future.

2.2. Keying mechanisms

For TCP-AO [RFC5925] there is no Key Management Protocol (KMP) used to manage the keys that are used for generating the Message Authentication Code (MAC). It allows for a master key to be configured manually or for it to be managed from a out of band mechanism. Most routers are configured with a static key that does not change over the life of the session.

It should also be mentioned that those routers that have been configured with static keys have not seen the key changed. The common reason given for not changing the key is the difficulty in coordinating the change, at least with TCP MD5. It is well known that longer the same key is used, higher is the chance that it can be guessed, particularly if it is not a strong key.

For point-to-point key management IKE [RFC2409] tries to solve the issue of key exchange under a SA.

2.3. LDP

Section 5 of LDP [RFC5036] states that LDP is subject to three different types of attacks. These are spoofing, protection of privacy of label distribution and denial of service attacks.

2.3.1. Spoofing attacks

Spoofing attack for LDP occur both during the discovery phase and during the session communication phase.

2.3.1.1. Discovery exchanges using UDP

Label Switching Routers (LSRs) indicate their willingness to establish and maintain LDP sessions by periodically sending Hello messages. Receipt of a Hello message serves to create a new "Hello adjacency", if one does not already exist, or to refresh an existing one.

Unlike all other LDP messages, the Hello messages are sent using UDP not TCP. This means that they cannot benefit from the security mechanisms available with TCP. LDP [RFC5036] does not provide any security mechanisms for use with Hello messages except to note that some configuration may help protect against bogus discovery events.

Spoofing a Hello packet for an existing adjacency can cause the adjacency to time out and that can result in termination of the associated session. This can occur when the spoofed Hello message specifies a small Hold Time, causing the receiver to expect Hello messages within this interval, while the true neighbor continues sending Hello messages at the lower, previously agreed to, frequency.

Spoofing a Hello packet can also cause the LDP session to be terminated directly. This can occur when the spoofed Hello specifies a different Transport Address from the previously agreed one between neighbors. Spoofed Hello messages are observed and reported as real problem in production networks.

2.3.1.2. Session communication using TCP

LDP like other TCP based routing protocols specifies use of the TCP MD5 Signature Option to provide for the authenticity and integrity of session messages. As stated above, some assert that MD5 authentication is now considered by some to be too weak for this application. A stronger hashing algorithm e.g SHA1, could be deployed to take care of the weakness.

Alternatively, one could move to using TCP-AO which provides for stronger MACs and protects against replays.

2.3.2. Privacy Issues

LDP provides no mechanism for protecting the privacy of label distribution. The security requirements of label distribution are similar to other routing protocols that need to distribute routing information.

2.3.3. Denial of Service Attacks

LDP is subject to Denial of Service (DoS) attacks both in its discovery mode as well as during the session mode.

The discovery mode attack is similar to the spoofing attack except that when the spoofed Hello messages are sent with a high enough frequency can cause the adjacency to time out.

2.4. PCEP

Attacks on PCEP [RFC5440] may result in damage to active networks. This may include computation responses, which if changed can cause protocols like LDP to setup sub-optimal or inappropriate LSPs. In addition, PCE itself can be attacked by a variety of DoS attacks. Such attacks can cause path computations to be supplied too slowly to be of any value particularly as it relates to recovery or establishment of LSPs.

As the RFC states, PCEP could be the target of the following attacks.

According to the RFC, inter-AS scenarios when PCE-to-PCE communication is required, attacks may be particularly significant with commercial as well as service-level implications.

Additionally, snooping of PCEP requests and responses may give an attacker information about the operation of the network. Simply by viewing the PCEP messages someone can determine the pattern of service establishment in the network and can know where traffic is being routed, thereby making the network susceptible to targeted attacks and the data within specific LSPs vulnerable.

Ensuring PCEP communication privacy is of key importance, especially in an inter-AS context, where PCEP communication end-points do not reside in the same AS, as an attacker that intercepts a PCE message could obtain sensitive information related to computed paths and resources.

2.5. MSDP

Similar to BGP and LDP, TCP MD5 [RFC2385] specifies a mechanism to protect TCP sessions via the TCP MD5 option. But with a weak MD5 authentication, TCP MD5 is not considered strong enough for this application.

MSDP also advocates imposing a limit on number of source address and group addresses (S,G) that can be stored within the protocol and thereby mitigate state explosion due to any denial of service and other attacks.

3. Optimal State for BGP, LDP, PCEP, and MSDP

The ideal state for BGP, LDP and MSDP protocols are when they can withstand any of the known types of attacks.

Additionally, Key Management Protocol (KMP) for the routing sessions should help negotiate unique, pair wise random keys without administrator involvement. It should also negotiate Security Association (SA) parameter required for the session connection, including key life times. It should keep track of those lifetimes and negotiate new keys and parameters before they expire and do so without administrator involvement. In the event of a breach, including when an administrator with knowledge of the keys leaves the company, the keys should be changed immediately.

The DoS attacks for BGP, LDP, PCEP and MSDP are attacks to the transport protocol, TCP in this case. TCP should be able to withstand any of DoS scenarios by dropping packets that are attack packets in a way that does not impact legitimate packets.

The routing protocols should provide a mechanism to determine authenticate and validate the routing information carried within the payload.

3.1. LDP

For the spoofing kind of attacks that LDP is vulnerable to during the discovery phase, it should be able to determine the authenticity of the neighbors sending the Hello message.

There is currently no requirement to protect the privacy of label distribution as labels are carried in the clear like other routing information.

4. Gap Analysis for BGP, LDP, PCEP and MSDP

This section outlines the differences between the current state of the routing protocol and the desired state as outlined in section 4.2 of KARP Design Guidelines [RFC6518]. As that document states, these routing protocols fall into the category of the one-to-one peering messages and will use peer keying protocol. It covers issues that are common to the four protocols leaving protocol specific issues to sub-sections.

At a transport level the routing protocols are subject to some of the same attacks that TCP applications are subject to. These include but are not limited to DoS attacks. Defending TCP Against Spoofing Attacks [RFC4953] recommends ways to do just that. In addition Improving TCP's Robustness to Blind In-Window Attacks. [RFC5961] should also be followed and implemented.

From a security perspective there is a lack of comprehensive KMP. As an example TCP-AO [RFC5925] talks about coordinating keys derived from MKT between endpoints, but the MKT itself has to be configured manually or through a out of band mechanism. Even when keys are configured manually, a method for when to start using the new keys or stop using old keys has not been defined. This leads to keys not being updated regularly which in itself increases the security risk. Also TCP-AO does not address the issue of connectionless reset, as it applies to routers that do not store MKT across reboots.

Authentication, tamper protection, and encryption all require the use of keys by sender and receiver. An automated KMP therefore has to include a way to distribute MKT between two end points with little or no administration overhead. It has to cover automatic key rollover. It is expected that authentication will cover the packet, i.e. the payload and the TCP header and will not cover the frame i.e. the link layer 2 header.

There are two methods of automatic key rollover. Implicit key rollover can be initiated after certain volume of data gets exchanged or when a certain time has elapsed. This does not require explicit signaling nor should it result in a reset of the TCP connection in a way that the links/adjacencies are affected. On the other hand, explicit key rollover requires a out of band key signaling mechanism. It can be triggered by either side and can be done anytime a security parameter changes e.g. an attack has happened, or a system administrator with access to the keys has left the company. An example of this is IKE [RFC2409] but it could be any other new mechanisms also.

As stated earlier TCP-AO [RFC5925] and its accompanying document Crypto Algorithms for TCP-AO [RFC5926] suggest that two MAC algorithms that MUST be supported are HMAC-SHA-1-96 as specified in HMAC [RFC2104] and AES-128-CMAC-96 as specified in NIST-SP800-38B [NIST-SP800-38B].

There is a need to protect authenticity and validity of the routing/label information that is carried in the payload of the sessions. However, we believe that is outside the scope of this document at this time and is being addressed by SIDR WG. Similar mechanisms could be used for intra-domain protocols.

4.1. LDP

As described in LDP [RFC5036], the threat of spoofed Basic Hellos can be reduced by accepting Basic Hellos on interfaces that LSRs trust, employing GTSM [RFC5082] and ignoring Basic Hellos not addressed to the "all routers on this subnet" multicast group. Spoofing attacks via Extended Hellos are potentially a more serious threat. An LSR can reduce the threat of spoofed Extended Hellos by filtering them and accepting Hellos from sources permitted by an access list. However, performing the filtering using access lists requires LSR resource, and the LSR is still vulnerable to the IP source address spoofing. Spoofing attacks can be solved by being able to authenticate the Hello messages, and an LSR can be configured to only accept Hello messages from specific peers when authentication is in use.

LDP Hello Cryptographic Authentication [draft-zheng-mpls-ldp-hello-crypto-auth-01] suggest a new Cryptographic Authentication TLV that can be used as an authentication mechanism to secure Hello messages.

4.2. PCEP

PCE discovery according to its RFC is a significant feature for the successful deployment of PCEP in large networks. This mechanism allows a PCC to discover the existence of suitable PCEs within the network without the necessity of configuration. It should be obvious that, where PCEs are discovered and not configured, the PCC cannot know the correct key to use. There are different approaches to retain some aspect of security, but all of them require use of a keys and a keying mechanism, the need for which has been discussed above.

5. Transition and Deployment Considerations

As stated in KARP Design Guidelines [RFC6518] it is imperative that the new authentication and security mechanisms defined support incremental deployment, as it is not feasible to deploy the new routing protocol authentication mechansim overnight.

Typically authentication and security in a peer-to-peer protocol requires that both parties agree to the mechanisms that will be used. If an agreement is not reached the setup of the new mechanism will fail or will be deferred. Upon failure, the routing protocols can fallback to the mechanisms that were already in place e.g. use static keys if that was the mechanism in place. It is usually not possible for one end to use the new mechanism while the other end uses the old. Policies can be put in place to retry upgrading after a said period of time, so a manual coordiantion is not required.

If the automatic KMP requires use of public/private keys to exchange key material, the required CA root certificates may need to be installed to verify authenticity of requests initiated by a peer. Such a step does not require coordination with the peer except to decide what CA authority will be used.

6. Security Requirements

This section describes requirements for BGP, LDP, PCEP and MSDP security that should be met within the routing protocol.

As with all routing protocols, they need protection from both on-path and off-path blind attacks. A better way to protect them would be with per-packet protection using a cryptographic MAC. In order to provide for the MAC, keys are needed.

Once keys are used, mechanisms are required to support key rollover. This should cover both manual and automatic key rollover. Multiple approaches could be used. However since the existing mechanisms provide a protocol field to identify the key as well as management mechanisms to introduce and retire new keys, focusing on the existing mechanism as a starting point is prudent.

Finally, replay protection is required. The replay mechanism needs to be sufficient to prevent an attacker from creating a denial of service or disrupting the integrity of the routing protocol by replaying packets. It is important that an attacker not be able to disrupt service by capturing packets and waiting for replay state to be lost.

7. Acknowledgements

We would like to thank Brian Weis for encouraging us to write this draft and providing comments on it.

8. References

8.1. Normative References

[draft-ietf-karp-threats-reqs] Lebovitz, G and M Bhatia, "KARP Threats and Requirements", March 2012.
[RFC6518] Lebovitz, G. and M. Bhatia, "Keying and Authentication for Routing Protocols (KARP) Design Guidelines", RFC 6518, February 2012.
[RFC2385] Heffernan, A., "Protection of BGP Sessions via the TCP MD5 Signature Option", RFC 2385, August 1998.
[RFC5926] Lebovitz, G. and E. Rescorla, "Cryptographic Algorithms for the TCP Authentication Option (TCP-AO)", RFC 5926, June 2010.

8.2. Informative References

[RFC2104] Krawczyk, H., Bellare, M. and R. Canetti, "HMAC: Keyed-Hashing for Message Authentication", RFC 2104, February 1997.
[RFC2119] Bradner, S., "Key words for use in RFCs to Indicate Requirement Levels", BCP 14, RFC 2119, March 1997.
[RFC2409] Harkins, D. and D. Carrel, "The Internet Key Exchange (IKE)", RFC 2409, November 1998.
[RFC3547] Baugher, M., Weis, B., Hardjono, T. and H. Harney, "The Group Domain of Interpretation", RFC 3547, July 2003.
[RFC4271] Rekhter, Y., Li, T. and S. Hares, "A Border Gateway Protocol 4 (BGP-4)", RFC 4271, January 2006.
[RFC4948] Andersson, L., Davies, E. and L. Zhang, "Report from the IAB workshop on Unwanted Traffic March 9-10, 2006", RFC 4948, August 2007.
[RFC4953] Touch, J., "Defending TCP Against Spoofing Attacks", RFC 4953, July 2007.
[RFC5036] Andersson, L., Minei, I. and B. Thomas, "LDP Specification", RFC 5036, October 2007.
[RFC5082] Gill, V., Heasley, J., Meyer, D., Savola, P. and C. Pignataro, "The Generalized TTL Security Mechanism (GTSM)", RFC 5082, October 2007.
[RFC5440] Vasseur, JP. and JL. Le Roux, "Path Computation Element (PCE) Communication Protocol (PCEP)", RFC 5440, March 2009.
[RFC5925] Touch, J., Mankin, A. and R. Bonica, "The TCP Authentication Option", RFC 5925, June 2010.
[RFC5961] Ramaiah, A., Stewart, R. and M. Dalal, "Improving TCP's Robustness to Blind In-Window Attacks", RFC 5961, August 2010.
[RFC6039] Manral, V., Bhatia, M., Jaeggli, J. and R. White, "Issues with Existing Cryptographic Protection Methods for Routing Protocols", RFC 6039, October 2010.
[draft-ietf-karp-ospf-analysis-03] Hartman, S, "Analysis of OSPF Security According to KARP Design Guide", March 2012.
[NIST-SP800-38B] Dworking, , "Recommendation for Block Cipher Modes of Operation: The CMAC Mode for Authentication", May 2005.
[draft-zheng-mpls-ldp-hello-crypto-auth-01] Zheng, , "LDP Hello Cryptographic Authentication", March 2011.

Authors' Addresses

Mahesh Jethanandani Ciena Corporation 1741 Technology Drive San Jose, CA 95110 USA Phone: + (408) 436-3313 EMail: mjethanandani@gmail.com
Keyur Patel Cisco Systems, Inc 170 Tasman Drive San Jose, CA 95134 USA Phone: +1 (408) 526-7183 EMail: keyupate@cisco.com
Lianshu Zheng Huawei No. 3 Xinxi Road, Hai-Dian District Beijing, 100085 China Phone: +86 (10) 82882008 EMail: verozheng@huawei.com