dnsop | W. Hardaker |
Internet-Draft | Parsons, Inc. |
Intended status: Standards Track | W. Kumari |
Expires: August 6, 2017 | |
February 2, 2017 |
Security Considerations for RFC5011 Publishers
draft-hardaker-rfc5011-security-considerations-03
This document describes the math behind the minimum time-length that a DNS zone publisher must wait before using a new DNSKEY to sign records when supporting the RFC5011 rollover strategies.
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RFC5011 [RFC5011] defines a mechanism by which DNSSEC validators can extend their list of trust anchors when they've seen a new key published in a zone. However, RFC5011 [intentionally] provides no guidance to the publishers of DNSKEYs about how long they must wait before switching to the newly published key for signing records. Because of this lack of guidance, zone publishers may derive incorrect assumptions about safe usage of the RFC5011 DNSKEY advertising and rolling process. This document describes the minimum security requirements from a publishers point of view and is intended to compliment the guidance offered in RFC5011 (which is written to provide timing guidance solely to the Validating Resolvers point of view).
To verify this lack of understanding is wide-spread, the authors reached out to 5 DNSSEC experts to ask them how long they thought they must wait before using a new KSK that was being rolled according to the 5011 process. All 5 experts answered with an insecure value, and thus we have determined that this lack of operational guidance is causing security concerns today. We hope that this document will rectify this understanding and provide better guidance to zone publishers that wish to make use of the RFC5011 rollover process.
One important note about ICANN's upcoming 2017 KSK rollover plan for the root zone: the timing values chosen for rolling the KSK in the root zone appear completely safe, and are not in any way affected by the timing concerns introduced by this draft
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].
The RFC5011 process describes a process by which a Validating Resolver may accept a newly published KSK as a trust anchor for validating future DNSSEC signed records. This document augments that information with additional constraints, as required from the DNSKEY publication point of view. Note that it does not define any other operational guidance or recommendations about the RFC5011 process from a publication point of view and restricts itself to solely the security and operational ramifications of switching to a new key too soon. Failure of a DNSKEY publisher to follow the minimum recommendations associated with this draft will result in potential denial-of-service attack opportunities against validating resolvers.
RFC5011's process of safely publishing a new key and then making use of that key falls into a number of high-level steps:
This document discusses step 2 of the above process. Some interpretations of RFC5011 have erroneously determined that the wait time is equal to RFC5011's "hold down time".
This document describes an attack based on this (common) erroneous belief, which results in a denial of service attack against the zone if that value is used.
If an attacker is able to provide a RFC5011 validating engine with past responses, such as when it is in-path or able to otherwise perform any number of cache poisoning attacks, the attacker may be able to leave the RFC5011-compliant validator without an appropriate DNSKEY trust anchor. This scenario will remain until an administrator manually fixes the situation.
The following timeline illustrates this situation.
The following example settings are used in the example scenario within this section:
Given these settings, the following sequence of events depicts how a Trust Anchor Publisher that waits for only the RFC5011 hold time timer length of 30 days subjects its users to a potential Denial of Service attack. The timing schedule listed below is based on a new trust anchor (a Key Signing Key (KSK)) being published at time T+0. All numbers in this sequence refer to days before and after such an event. Thus, T-1 is the day before the introduction of the new key, and T+15 is the 15th day after the key was introduced into the fictitious zone being discussed.
In this dialog, we consider two keys being published:
In this dialog, the following actors are playing roles in this situation:
The following series of steps depicts the timeline in which an attack occurs that foils the adoption of a new DNSKEY by a Trust Anchor Publisher that revokes the old key too quickly.
waitTime = addHoldDownTime + MIN(3 * (DNSKEY RRSIG Signature Validity) / 2, 3 * MAX(original TTL of K_old DNSKEY RRSet) / 2, 15 days) + 2 * MAX(TTL of all records)
Given the attack description in Section 5, the correct minimum length of time required for the Zone Signer to wait before using K_new is:
The most confusing element of the above equation comes from the "3 * (DNSKEY RRSIG Signature Validity) / 2" element, but is the most critical to understand and get right.
A resolver that has been configured for an automatic update of keys from a particular trust point MUST query that trust point (e.g., do a lookup for the DNSKEY RRSet and related RRSIG records) no less often than the lesser of 15 days, half the original TTL for the DNSKEY RRSet, or half the RRSIG expiration interval and no more often than once per hour.
The RFC5011 "Active Refresh" requirements state that:
The important timing constraint that must be considered is the last point at which a validating resolver may have received a replayed the original DNSKEY set (K_old) without the new key. It's the next query of the RFC5011 validator that the assured K_new will be seen. For the following paragraph, we use the more common case where (DNSKEY RRSIG Signature Validity) is greater than (original TTL for the DNSKEY RRSet), although the equation above takes both cases into account.
Thus, the worst case scenario of this attack is when the attacker can replay K_old at just before (DNSKEY RRSIG Signature Validity). If a RFC5011 validator picks up K_old at this this point, it will not have a hold down timer started at all. It's not until the next "Active Refresh" time that they'll pick up K_new with assurance, and thus start their hold down timer. Thus, this is not at (DNSKEY RRSIG Signature Validity) time past publication, but rather 3 * (DNSKEY RRSIG Signature Validity) / 2.
The extra 2 * MAX(TTL of all records) is the standard added safety margin when dealing with DNSSEC due to caching that can take place. Because the 5011 steps require direct validation using the signature validity, the authors aren't yet convinced it is needed in this particular case.
waitTime = 30 + 3 * (10) / 2 + 2 * (1) (days) waitTime = 47 (days)
For the parameters listed in Section 5.1, our example:
This hold-down time of 47 days is 12 days longer than the frequently perceived 35 days in T+35 above.
This document contains no IANA considerations.
A companion document to RFC5011 was expected to be published that describes the best operational practice considerations from the perspective of a zone publisher and Trust Anchor Publisher. However, this companion document was never written. The authors of this document hope that it will at some point in the future, as RFC5011 timing can be tricky as we have shown. This document is intended only to fill a single operational void that results in security ramifications (specifically a denial of service attack against an RFC5011 Validator). This document does not attempt to document any other missing operational guidance for zone publishers.
This document, is solely about the security considerations with respect to the Trust Anchor Publisher of RFC5011 trust anchors / keys. Thus the entire document is a discussion of Security Considerations
The authors would like to especially thank to Michael StJohns for his help and advice. We would also like to thank Bob Harold, Shane Kerr, Matthijs Mekking, Duane Wessels, and everyone else who assisted with this document.
[RFC2119] | Bradner, S., "Key words for use in RFCs to Indicate Requirement Levels", BCP 14, RFC 2119, DOI 10.17487/RFC2119, March 1997. |
[RFC5011] | StJohns, M., "Automated Updates of DNS Security (DNSSEC) Trust Anchors", STD 74, RFC 5011, DOI 10.17487/RFC5011, September 2007. |
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