Network Working Group S. Weiler
Request for Comments: 3755 SPARTA, Inc.
Updates: 3658, 2535 May 2004
Category: Standards Track
Legacy Resolver Compatibility for Delegation Signer (DS)
Status of this Memo
This document specifies an Internet standards track protocol for the
Internet community, and requests discussion and suggestions for
improvements. Please refer to the current edition of the "Internet
Official Protocol Standards" (STD 1) for the standardization state
and status of this protocol. Distribution of this memo is unlimited.
Copyright Notice
Copyright (C) The Internet Society (2004). All Rights Reserved.
Abstract
As the DNS Security (DNSSEC) specifications have evolved, the syntax
and semantics of the DNSSEC resource records (RRs) have changed.
Many deployed nameservers understand variants of these semantics.
Dangerous interactions can occur when a resolver that understands an
earlier version of these semantics queries an authoritative server
that understands the new delegation signer semantics, including at
least one failure scenario that will cause an unsecured zone to be
unresolvable. This document changes the type codes and mnemonics of
the DNSSEC RRs (SIG, KEY, and NXT) to avoid those interactions.
The DNSSEC protocol has been through many iterations whose syntax and
semantics are not completely compatible. This has occurred as part
of the ordinary process of proposing a protocol, implementing it,
testing it in the increasingly complex and diverse environment of the
Internet, and refining the definitions of the initial Proposed
Standard. In the case of DNSSEC, the process has been complicated by
DNS's criticality and wide deployment and the need to add security
while minimizing daily operational complexity.
A weak area for previous DNS specifications has been lack of detail
in specifying resolver behavior, leaving implementors largely on
their own to determine many details of resolver function. This,
combined with the number of iterations the DNSSEC specifications have
been through, has resulted in fielded code with a wide variety of
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behaviors. This variety makes it difficult to predict how a protocol
change will be handled by all deployed resolvers. The risk that a
change will cause unacceptable or even catastrophic failures makes it
difficult to design and deploy a protocol change. One strategy for
managing that risk is to structure protocol changes so that existing
resolvers can completely ignore input that might confuse them or
trigger undesirable failure modes.
This document addresses a specific problem caused by Delegation
Signer's (DS) [RFC3658] introduction of new semantics for the NXT RR
that are incompatible with the semantics in [RFC2535]. Answers
provided by DS-aware servers can trigger an unacceptable failure mode
in some resolvers that implement RFC 2535, which provides a great
disincentive to sign zones with DS. The changes defined in this
document allow for the incremental deployment of DS.
In this document, the term "unsecure delegation" means any delegation
for which no DS record appears at the parent. An "unsecure referral"
is an answer from the parent containing an NS RRset and a proof that
no DS record exists for that name.
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].
Delegation Signer (DS) introduces new semantics for the NXT RR that
are incompatible with the semantics in RFC 2535. In RFC 2535, NXT
records were only required to be returned as part of a non-existence
proof. With DS, an unsecure referral returns, in addition to the NS,
a proof of non-existence of a DS RR in the form of an NXT and
SIG(NXT). RFC 2535 didn't specify how a resolver was to interpret a
response with RCODE=0, AA=0, and both an NS and an NXT in the
authority section. Some widely deployed 2535-aware resolvers
interpret any answer with an NXT as a proof of non-existence of the
requested record. This results in unsecure delegations being
invisible to 2535-aware resolvers and violates the basic
architectural principle that DNSSEC must do no harm -- the signing of
zones must not prevent the resolution of unsecured delegations.
This section presents several solutions that were considered.
Section 3 describes the one selected.
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To avoid the problem described above, legacy (RFC2535-aware)
resolvers need to be kept from seeing unsecure referrals that include
NXT records in the authority section. The simplest way to do that is
to change the type codes for SIG, KEY, and NXT.
The obvious drawback to this is that new resolvers will not be able
to validate zones signed with the old RRs. This problem already
exists, however, because of the changes made by DS, and resolvers
that understand the old RRs (and have compatibility issues with DS)
are far more prevalent than 2535-signed zones.
The observed problem with unsecure referrals could be addressed by
changing only the NXT type code or another subset of the type codes
that includes NXT. This has the virtue of apparent simplicity, but
it risks introducing new problems or not going far enough. It's
quite possible that more incompatibilities exist between DS and
earlier semantics. Legacy resolvers may also be confused by seeing
records they recognize (SIG and KEY) while being unable to find NXTs.
Although it may seem unnecessary to fix that which is not obviously
broken, it's far cleaner to change all of the type codes at once.
This will leave legacy resolvers and tools completely blinded to
DNSSEC -- they will see only unknown RRs.
Another way to keep legacy resolvers from ever seeing DNSSEC records
with DS semantics is to have authoritative servers only send that
data to DS-aware resolvers. It's been proposed that assigning a new
EDNS0 flag bit to signal DS-awareness (tentatively called "DA"), and
having authoritative servers send DNSSEC data only in response to
queries with the DA bit set, would accomplish this. This bit would
presumably supplant the DO bit described in [RFC3225].
This solution is sufficient only if all 2535-aware resolvers zero out
EDNS0 flags that they don't understand. If one passed through the DA
bit unchanged, it would still see the new semantics, and it would
probably fail to see unsecure delegations. Since it's impractical to
know how every DNS implementation handles unknown EDNS0 flags, this
is not a universal solution. It could, though, be considered in
addition to changing the RR type codes.
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Another possible solution is to increment the EDNS version number as
defined in [RFC2671], on the assumption that all existing
implementations will reject higher versions than they support, and
retain the DO bit as the signal for DNSSEC awareness. This approach
has not been tested.
There is a large deployed base of DNS resolvers that understand
DNSSEC as defined by the standards track RFC 2535 and [RFC2065] and,
due to under specification in those documents, interpret any answer
with an NXT as a non-existence proof. So long as that is the case,
zone owners will have a strong incentive to not sign any zones that
contain unsecure delegations, lest those delegations be invisible to
such a large installed base. This will dramatically slow DNSSEC
adoption.
Unfortunately, without signed zones there's no clear incentive for
operators of resolvers to upgrade their software to support the new
version of DNSSEC, as defined in RFC 3658. Historical data suggests
that resolvers are rarely upgraded, and that old nameserver code
never dies.
Rather than wait years for resolvers to be upgraded through natural
processes before signing zones with unsecure delegations, addressing
this problem with a protocol change will immediately remove the
disincentive for signing zones and allow widespread deployment of
DNSSEC.
This document changes the type codes of SIG, KEY, and NXT. This
approach is the cleanest and safest of those discussed above, largely
because the behavior of resolvers that receive unknown type codes is
well understood. This approach has also received the most testing.
To avoid operational confusion, it's also necessary to change the
mnemonics for these RRs. DNSKEY will be the replacement for KEY,
with the mnemonic indicating that these keys are not for application
use, per [RFC3445]. RRSIG (Resource Record SIGnature) will replace
SIG, and NSEC (Next SECure) will replace NXT. These new types
completely replace the old types, except that SIG(0) [RFC2931] and
TKEY [RFC2930] will continue to use SIG and KEY.
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The new types will have exactly the same syntax and semantics as
specified for SIG, KEY, and NXT in RFC 2535 and RFC 3658 except for
the following:
1) Consistent with [RFC3597], domain names embedded in RRSIG and NSEC
RRs MUST NOT be compressed,
2) Embedded domain names in RRSIG and NSEC RRs are not downcased for
purposes of DNSSEC canonical form and ordering nor for equality
comparison, and
3) An RRSIG with a type-covered field of zero has undefined
semantics. The meaning of such a resource record may only be
defined by IETF Standards Action.
If a resolver receives the old types, it SHOULD treat them as unknown
RRs and SHOULD NOT assign any special meaning to them or give them
any special treatment. It MUST NOT use them for DNSSEC validations
or other DNS operational decision making. For example, a resolver
MUST NOT use DNSKEYs to validate SIGs or use KEYs to validate RRSIGs.
If SIG, KEY, or NXT RRs are included in a zone, they MUST NOT receive
special treatment. As an example, if a SIG is included in a signed
zone, there MUST be an RRSIG for it. Authoritative servers may wish
to give error messages when loading zones containing SIG or NXT
records (KEY records may be included for SIG(0) or TKEY).
As a clarification to previous documents, some positive responses,
particularly wildcard proofs and unsecure referrals, will contain
NSEC RRs. Resolvers MUST NOT treat answers with NSEC RRs as negative
answers merely because they contain an NSEC.
This document updates the IANA registry for DNS Resource Record Types
by assigning types 46, 47, and 48 to the RRSIG, NSEC, and DNSKEY RRs,
respectively.
Types 24 and 25 (SIG and KEY) are retained for SIG(0) [RFC2931] and
TKEY [RFC2930] use only.
Type 30 (NXT) should be marked as Obsolete.
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To allow zone signing (DNSSEC) and transaction security mechanisms
(SIG(0) and TKEY) to use different sets of algorithms, the existing
"DNS Security Algorithm Numbers" registry is modified to include the
applicability of each algorithm. Specifically, two new columns are
added to the registry, showing whether each algorithm may be used for
zone signing, transaction security mechanisms, or both. Only
algorithms usable for zone signing may be used in DNSKEY, RRSIG, and
DS RRs. Only algorithms usable for SIG(0) and/or TSIG may be used in
SIG and KEY RRs.
All currently defined algorithms except for Indirect (algorithm 252)
remain usable for transaction security mechanisms. Only RSA/SHA-1
[RFC3110], DSA/SHA-1 [RFC2536], and private algorithms (types 253 and
254) may be used for zone signing. Note that the registry does not
contain the requirement level of each algorithm, only whether or not
an algorithm may be used for the given purposes. For example,
RSA/MD5, while allowed for transaction security mechanisms, is NOT
RECOMMENDED, per [RFC3110].
Additionally, the presentation format algorithm mnemonics from
[RFC2535] Section 7 are added to the registry. This document assigns
RSA/SHA-1 the mnemonic RSASHA1.
As before, assignment of new algorithms in this registry requires
IETF Standards Action. Additionally, modification of algorithm
mnemonics or applicability requires IETF Standards Action. Documents
defining a new algorithm must address the applicability of the
algorithm and should assign a presentation mnemonic to the algorithm.
Like the KEY resource record, DNSKEY contains a 16-bit flags field.
This document creates a new registry for the DNSKEY flags field.
Initially, this registry only contains an assignment for bit 7 (the
ZONE bit). Bits 0-6 and 8-15 are available for assignment by IETF
Standards Action.
Like the KEY resource record, DNSKEY contains an eight bit protocol
field. The only defined value for this field is 3 (DNSSEC). No
other values are allowed, hence no IANA registry is needed for this
field.
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The changes introduced here do not materially affect security. The
implications of trying to use both new and legacy types together are
not well understood, and attempts to do so would probably lead to
unintended and dangerous results.
Changing type codes will leave code paths in legacy resolvers that
are never exercised. Unexercised code paths are a frequent source of
security holes, largely because those code paths do not get frequent
scrutiny.
Doing nothing, as described in section 2.5, will slow DNSSEC
deployment. While this does not decrease security, it also fails to
increase it.
[RFC2119] Bradner, S., "Key words for use in RFCs to Indicate
Requirement Levels", BCP 14, RFC 2119, March 1997.
[RFC2535] Eastlake, D., "Domain Name System Security Extensions", RFC
2535, March 1999.
[RFC2536] Eastlake, D., "DSA KEYs and SIGs in the Domain Name System
(DNS)", RFC 2536, March 1999.
[RFC2930] Eastlake, D., "Secret Key Establishment for DNS (TKEY RR)",
RFC 2930, September 2000.
[RFC2931] Eastlake, D., "DNS Request and Transaction Signatures
(SIG(0)s)", RFC 2931, September 2000.
[RFC3110] Eastlake, D., "RSA/SHA-1 SIGs and RSA KEYs in the Domain
Name System (DNS)", RFC 3110, May 2001.
[RFC3658] Gudmundsson, O., "Delegation Signer (DS) Resource Record
(RR)", RFC 3658, December 2003.
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[RFC2065] Eastlake, 3rd, D. and C. Kaufman, "Domain Name System
Security Extensions", RFC 2065, January 1997.
[RFC2671] Vixie, P., "Extension Mechanisms for DNS (EDNS0)", RFC
2671, August 1999.
[RFC3225] Conrad, D., "Indicating Resolver Support of DNSSEC", RFC
3225, December 2001.
[RFC3445] Massey, D., and S. Rose, "Limiting the Scope of the KEY
Resource Record (RR)", RFC 3445, December 2002.
[RFC3597] Gustafsson, A., "Handling of Unknown DNS Resource Record
(RR) Types", RFC 3597, September 2003.
The changes introduced here and the analysis of alternatives had many
contributors. With apologies to anyone overlooked, those include:
Michael Graff, Johan Ihren, Olaf Kolkman, Mark Kosters, Ed Lewis,
Bill Manning, Paul Vixie, and Suzanne Woolf.
Thanks to Jakob Schlyter and Mark Andrews for identifying the
incompatibility described in section 1.2.
In addition to the above, the author would like to thank Scott Rose,
Olafur Gudmundsson, and Sandra Murphy for their substantive comments.
Samuel Weiler
SPARTA, Inc.
7075 Samuel Morse Drive
Columbia, MD 21046
USA
EMail: weiler@tislabs.com
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