KARP | S. Hartman |
Internet-Draft | Painless Security |
Intended status: Informational | D. Zhang |
Expires: December 06, 2012 | Huawei Technologies co. ltd |
June 06, 2012 |
Analysis of OSPF Security According to KARP Design Guide
draft-ietf-karp-ospf-analysis-04.txt
This document analyzes OSPFv2 and OSPFv3 according to the guidelines set forth in section 4.2 of draft-ietf-karp-design-guide.
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].
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This document performs the initial analysis of the current state of OSPFv2 and OSPFv3 according to the requirements of [RFC6518]. This draft builds on several previous analysis efforts into routing security. The OPSEC working group put together [RFC6039] an analysis of cryptographic issues with routing protocols. Earlier, the RPSEC working group put together [I-D.ietf-rpsec-ospf-vuln] a detailed analysis of OSPF vulnerabilities.
OSPF meets many of the requirements expected from a manually keyed routing protocol. Integrity protection is provided with modern cryptographic algorithms. Algorithm agility is provided: the algorithm can be changed as part of re-keying an interface or peer. Intra-connection re-keying is provided by the specifications, although apparently some implementations have trouble with this in practice. OSPFv2 security does not interfere with prioritization of packets.
However, some gaps remain between the current state and the requirements for manually keyed routing security expressed in [I-D.ietf-karp-threats-reqs] the requirements. This document explores these gaps and proposes directions for addressing the gaps.
There are a number of requirements described in section 3 of [I-D.ietf-karp-threats-reqs] that OSPF does not currently meet:
The remainder of this document explains the details of how these requirements fail to be met and proposes mechanisms for addressing them.
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 [RFC2119].
This section describes the security mechanisms built into OSPFv2 and OSPFv3. There are two goals to this section. First, this section gives a brief explanation of the OSPF security mechanisms to those familiar with connectionless integrity mechanisms but not with OSPF. Second, this section explains the background necessary to understand how OSPF fails to meet some of the requirements proposed for routing security.
Appendix D of [RFC2328] describes the basic procedure for cryptographic authentication in OSPFv2. An authentication data field in the OSPF packet header contains a key ID, the length of the authentication data and a sequence number. A message authentication code (MAC) is appended to the OSPF packet. This code protects all fields of the packet including the sequence number but not the IP header.
RFC 2328 defined the use of a keyed-MD5 MAC. While MD5 has not been broken as a MAC, it is not the algorithm of choice for new MACs.
However, RFC 5709 [RFC5709] adds support for the SHA [FIPS180] family of hashes to OSPFv2. The cryptographic authentication described in RFC 5709 meets modern standards for per-packet integrity protection. Thus, OSPFv2 meets the requirement for strong algorithms. Since multiple algorithms are defined and a new algorithm can be selected with each key, OSPFv2 meets the requirement for algorithm agility. In order to provide cryptographic algorithms believed to have a relatively long useful life, RFC 5709 mandates support for SHA-2 rather than SHA-1.
These security services provide integrity protection on each packet. In addition, limited replay detection is provided. The sequence number is non-decreasing. So, once a router has increased its sequence number, an attacker cannot replay an old packet. Unfortunately, sequence numbers are not required to increase for each packet. For instance, because existing OSPF security solutions do not specify how to set the sequence number, it is possible that some implementation use, e.g., "seconds since reboot" as their sequence numbers. The sequence numbers is thus only increased by every second. Also, no mechanism is provided to deal with the loss of anti-replay state; if sequence numbers are reused when a router reboots, then inter-connection replays are straight forward. In [I-D.ietf-ospf-security-extension-manual-keying], the OSPFv2 sequence number is expanded to 64-bits with the least significant 32-bit value containing a strictly increasing sequence number and the most significant 32-bit value containing the boot count. The boot count is retained in non-volatile storage for the deployment life of a OSPF router. Therefore, the sequence number will never decrease even after a cold reboot.
Also, because the IP header is not protected, the sequence number may not be associated with the right neighbor; this opens up opportunities for outsiders to perform replay attacks. See Section 3 for analysis of these attacks. In [I-D.ietf-ospf-security-extension-manual-keying], this issue is addressed by changing the definition of Apad from a constant defined in [RFC5709] to the source address from the IP header of the OSPFv2 protocol packet. In this way, the source address from the IP header is incorporated in the cryptographic authentication computation, and any change of the IP source address will be detected.
The mechanism provides good support for key rollover. There is a key ID; in addition mechanisms are described for managing key lifetimes and starting the use of a new key in an orderly manner. Performing orderly key rollover requires that implementations support accepting a new key for received packets before using that key to generate packets. Section D.3 of RFC 2328 requires this support in the form of four configurable lifetimes for each key: two lifetimes control the beginning and ending period for acceptance while two lifetimes control the beginning and ending period for generation. This provides a superset of the functionality in the key table [I-D.ietf-karp-crypto-key-table] regarding lifetime.
The OSPFv2 replay mechanism does not handle packet priorities as described. If packets are processed out-of-order, then if the sequence number increases, packets processed later will be discarded.
RFC 4552 [RFC4552] describes how the authentication header and encapsulating security payload mechanism can be used to protect OSPFv3 packets. This mechanism provides per-packet integrity and optional confidentiality using a wide variety of cryptographic algorithms. Because OSPF uses multicast traffic, only manual key management is supported. This mechanism meets requirements related to algorithm selection and agility.
The Security Parameter Index (SPI) provides an identifier for the security association. This along with other IPsec facilities provides a mechanism for moving from one key to another, meeting the key rollover requirements.
Because manual keying is used, no replay protection is provided for OSPFv3. Thus the intra-connection and inter-connection replay requirements are not met.
There is another serious problem with the OSPFv3 security: rather than being integrated into OSPF, it is based on IPsec. In practice, this has lead to deployment problems.
OSPF implementations generally prioritize packets in order to minimize disruption when router resources such as CPU or memory experience contention. When IPsec is used with OSPFv3, the offset of the packet type, which is used to prioritize packets, depends on what integrity transform is used. For this reason, prioritizing packets may be more complex for OSPFv3. One approach is to establish per-SPI filters to find the packet type and act accordingly.
As discussed, neither version of OSPF meets the requirements of inter-connection or intra-connection replay protection. This section discusses the impacts of OSPF replays.
In OSPFv2, two facilities limit the scope of replay attacks. First, when cryptographic authentication is used, each packet includes a sequence number that is non-decreasing. In the current specifications, the sequence number is remembered as part of an adjacency: if an attacker can cause an adjacency to go down, then replay state is lost. Database Description packets also include a per-LSA sequence number that is part of the information that is flooded. Even if a packet is replayed, the per-LSA sequence number will prevent an old LSA from being installed. Unlike the per-packet sequence number, the per-LSA sequence number must increase when an LSA is changed. As a result, replays cannot be used to install old routing information.
While the LSA sequence number provides some defense, there are a number of attacks that are possible because of a per-packet replay. The RPSEC analysis [I-D.ietf-rpsec-ospf-vuln] describes a number of attacks that are possible because of per-packet replays. The most serious appear to be attacks against Hello packets, which may cause an adjacency to fail. Other attacks may cause excessive flooding or excessive use of CPU.
Another serious attack concerns Database Description packets. In addition to the per-packet sequence number that is part of cryptographic authentication for OSPFv2 and the per-LSA sequence numbers, Database Description packets also include a Database Description sequence number. If a Database Description packet with the incorrect sequence number is received, then the database exchange process will be restarted.
The per-packet OSPFv2 sequence number can be used to reduce the window in which a replay is valid. A receiver will harmlessly reject a packet whose per-packet sequence number is older than the one most recently received from a neighbor. Replaying the most recent packet from a neighbor does not appear to create problems. So, if the per- packet sequence number is incremented on every packet sent, then replay attacks should not disrupt OSPFv2. Unfortunately, OSPFv2 does not have a procedure for dealing with sequence numbers reaching the maximum age. It may be possible to figure out a set of rules sufficient to disrupt the damage of packet replays while minimizing the use of the sequence number space.
As mentioned previously, when an adjacency is dropped, replay state is lost. So, after rebooting or when all adjacencies are lost, a router may allow its sequence number to decrease. An attacker can cause significant damage by replaying a packet captured before the sequence number decrease at a time after the sequence number decrease. If this happens, then the replayed packet will be accepted and the sequence number will be updated. However, the legitimate sender will be using a lower sequence number, so legitimate packets will be rejected. A similar attack is possible in cases where OSPF identifies a neighbor based on source address. An attacker can change the source address of a captured packet and replay it. If the attacker causes a replay from a neighbor with a high sequence number to appear to be from a low sequence number neighbor, then connectivity with that neighbor will be disrupted until the adjacency fails.
OSPFv3 lacks the per-packet sequence number but has the per-LSA sequence number. As such, OSPFv3 has no defense against denial of service attacks that exploit replay.
The design guide requires each design team to enumerate a set of requirements for the routing protocol. The only concerns identified with OSPF are areas where it fails to meet general requirements outlined in the threats and requirements document. This section explains how some of these general requirements map specifically onto the OSPF protocol and enumerates the specific gaps that need to be addressed.
There is a general requirement for inter-connection replay protection. In the context of OSPF, this means that if an adjacency goes down between two neighbors and later is re-established, replaying packets from before the adjacency went down cannot disrupt the adjacency. In the context of OSPF, intra-connection replay protection means that replaying a packet cannot prevent an adjacency from forming or disrupt an adjacency. Meeting the requirements for intra-connection and inter-connection replay protection is a significant gap between the optimal state and where OSPF is today.
Since OSPF uses fields in the IP header, the general requirement to protect the IP header and handle neighbor identification applies. This is another gap that needs to be addressed. Because the replay protection will depend on neighbor identification, the replay protection cannot be adequately addressed without handling this issue as well.
In order to encourage deployment of OSPFv3 security, an authentication option is required that does not have the deployment challenges of IPsec.
In order to support the requirement for simple preshared keys, OSPF needs to make sure that when the same key is used for two different purposes, no problems result.
In order to support packet prioritization, the information needed to prioritize OSPF packets (the packet type) MUST be at a constant location in the packet.
A security solution will be developed for OSPFv2 and OSPFv3 based on the OSPFv2 cryptographic authentication option. This solution will have the following improvements over the existing OSPFv2 option:
The key components of this solution work are already underway. OSPFv3 now supports an authentication option [RFC6506] that meets the requirements of this section, except that it does not describe how the key tables are used for OSPF. OSPFv2 is being enhanced [I-D.ietf-ospf-security-extension-manual-keying] to protect the source address, provide inter-connection replay and describe how to use the key table.
This memo discusses and compiles vulnerabilities in the existing OSPF cryptographic handling.
In analyzing proposed improvements to OSPF per-packet security, it is desirable to consider how these improvements interact with potential improvements in overall routing security. For example, the impact of replay attacks currently depends on the LSA sequence number mechanism. If cryptographic protections against insider attackers are considered by future work, then that work will need to provide a solution that meets the needs of the per-packet replay defense as well as protection of routing data from insider attack. RFC 2154 [RFC2154] provides an experimental solution for end-to-end protection of routing data in OSPF. It may be beneficial to consider how improvements to the per-packet protections would interact with such a mechanism to future-proof these mechanisms.
Implementations have a number of options in minimizing the potential denial of service impact of OSPF cryptographic authentication. The Generalized TTL Security Mechanism (GTSM) [RFC5082] might be appropriate for OSPF packets other than those traversing virtual links. Using this mechanism requires support of the sender; new OSPF cryptographic authentication could specify this behavior if desired. Alternatively implementations can limit the source addresses from which they accept packets. Non-hello packets need only be accepted from existing neighbors. If a system is under attack hello packets from existing neighbors could be prioritized over hellos from new neighbors. These mechanisms can be considered to limit the potential impact of denial of service attacks on the cryptographic authentication mechanism itself.
Funding for Sam Hartman's work on this memo is provided by Huawei.
The authors would like to thank Ran Atkinson, Michael Barnes, and Manav Bhatia for valuable comments.
[RFC2119] | Bradner, S., "Key words for use in RFCs to Indicate Requirement Levels", BCP 14, RFC 2119, March 1997. |
[RFC2328] | Moy, J., "OSPF Version 2", STD 54, RFC 2328, April 1998. |
[RFC4552] | Gupta, M. and N. Melam, "Authentication/Confidentiality for OSPFv3", RFC 4552, June 2006. |
[RFC5709] | Bhatia, M., Manral, V., Fanto, M., White, R., Barnes, M., Li, T. and R. Atkinson, "OSPFv2 HMAC-SHA Cryptographic Authentication", RFC 5709, October 2009. |