One document matched: draft-barwood-dnsext-fr-resolver-mitigations-01.txt
Differences from draft-barwood-dnsext-fr-resolver-mitigations-00.txt
DNS Extensions Working Group G. Barwood
Internet-Draft
Intended status: Informational September 7, 2008
Expires: March 2009
Resolver side mitigations
draft-barwood-dnsext-fr-resolver-mitigations-01
Status of This Memo
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Abstract
Describes mitigations against spoofing attacks on DNS.
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Table of Contents
1. Introduction . . . . . . . . . . . . . . . . . . . . . . . . . 3
2. Criteria . . . . . . . . . . . . . . . . . . . . . . . . . . . 3
3. Mitigations . . . . . . . . . . . . . . . . . . . . . . . . . 4
3.1. Prepend a random nonce label to the question. . . . . . . 4
3.2. Repeat the query . . . . . . . . . . . . . . . . . . . . 6
3.3 Include Bad IDs in entropy calculation . . . . . . . . . . 8
3.4 Use of calculated entropy . . . . . . . . . . . . . . . . 8
4. Analyis . . . . . . . . . . . . . . . . . . . . . . . . . . . . 9
4.1. Random nonce . . . . . . . . . . . . . . . . . . . . . . . . 9
4.2. Query repetition . . . . . . . . . . . . . . . . . . . . . . 9
4.3. Impact on Root and TLD . . . . . . . . . . . . . . . . . . . 9
4.4. Impact on other levels . . . . . . . . . . . . . . . . . . . 10
4.5. Impact of the Kaminsky check . . . . . . . . . . . . . . . . 10
5. Security Considerations . . . . . . . . . . . . . . . . . . . 11
6. IANA Considerations . . . . . . . . . . . . . . . . . . . . . 11
7. Acknowledgments . . . . . . . . . . . . . . . . . . . . . . . 11
8. Informative References . . . . . . . . . . . . . . . . . . . . 11
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1. Introduction
This document describes mitigations that a resolver can currently
deploy to resist spoofing attacks on DNS, without server software
being updated.
2. Criteria
These are resolver side solutions, thus only the resolver needs to be
redeployed, or the software updated, for this to work. This allows
deployment in the short term.
The solutions have to follow the DNS protocol.
The solutions have to be practical, non disruptive, and not
anti-social.
The context in which these solutions were explored is CERT
Vulnerability Note VU#800113, "Multiple DNS implementations
vulnerable to cache poisoning".
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3. Mitigations
Below, the resolver side mitigations are described.
Not described are port randomization, and 0x20 ( which are both
nevertheless recommmended ). The techniques are especially, but not
solely applicable where port randomization is not possible, due
to NAT devices or other reasons.
3.1. Prepend a random nonce label to the question.
This should be used where a referral is probable.
It allows an amount of entropy to be encoded limited only by the 256
character limit on a question, provided the authority server returns a
copy of the question in the response.
If the response is a Name Error (due to the server being authoritative
for the question), or an Answer is given ( due to a wildcard ), the
response should be discarded, and the query repeated without the
nonce.
A simple heuristic for deciding where a referral probable is:
(1) If the Bailiwick is Root, and the last label in the question is
a known TLD, a referral is probable.
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(2) If the Bailiwick is a TLD, a referral is probable.
(3) Otherwise a referral is not probable.
If the heuristic fails, this may be recorded so subsequent retries
are avoided.
A static list of TLDs (or other domains) may be used to initialise
the heuristic. If this list is not up to date, extra queries may be
generated, but no loss of functionality will occur.
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3.2. Query repetition
By repeating the query, additional entropy may be obtained. A
practical problem occurs when responses are non-deterministic, that
is many different responses are obtained for the same question.
In this case, the resolver will need to perform an analysis to
produce a converged result, or to report server failure (or a
security warning, if this is possible) if convergence has not
been achieved after some iteration limit.
RFC 2181 introduced the concept of "RRset Integrity", and this needs
to be taken into account.
Resolvers may decide to ditch RRset Integrity for some Types, for
non-deterministic servers, if the alternative is unacceptable security
or failure to resolve a name.
In particular, for most of the types defined in RFC 1034/1035, RRset
integrity may not be essential.
One model is to accumulate entropy for various attributes of each
observed RRset, such as Number of values, Value, TTL. Provided these
converge, a plausible synthesised RRset may be constructed.
For example, suppose the question is MX records for example.com.
First response:
example.com MX mail1.example.com
example.com MX mail2.example.com
Second response:
example.com MX mail2.example.com ( mail2.example.com confirmed)
example.com MX mail3.example.com
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Third response:
example.com MX mail3.example.com ( mail3.example.com confirmed )
example.com MX mail4.example.com
Plausible result:
example.com MX mail2.example.com
example.com MX mail3.example.com
The semantic model here is that 2 MX records are to be offered,
but the selection does not matter.
Another possibility where convergence is slow is to resolve glue. For
example:
First response:
example.com NS ns1.example.com
example.com NS ns2.example.com
..
example.com NS ns9.example.com
ns1.example.com A 0.0.0.1
ns2.example.com A 0.0.0.2
..
ns9.example.com A 0.0.0.9
Second response:
example.com NS ns1.example.com
example.com NS ns2.example.com
..
example.com NS ns9.example.com
ns1.example.com A 0.0.0.2
ns2.example.com A 0.0.0.3
..
ns8.example.com A 0.0.0.9
ns9.example.com A 0.0.0.1
Converged result:
example.com NSA 0.0.0.1
example.com NSA 0.0.0.2
..
example.com NSA 0.0.0.9
where NSA is an internal pseudo-type with the obvious meaning.
Some in-essential information is lost, but resolution can
still proceed.
This may all sound quite daunting, but early practical experiments
show that commonly encountered non-deterministic servers select
values from very small pools (in short time intervals), and show
simple behavior. A more comprehensive survey of such servers would
be useful, unfortunately the author does not have access to
the resources needed to carry out such a survey properly.
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3.3. Include observed Bad IDs in entropy calculation
When a response is received, an entropy calculation may be performed
to estimate how many bits have been checked.
It will typically include 16 bits for the ID, 0x20 bits,
bits from the prepended nonce, and discount for unusual /
non-standard features (such as IP mismatch, question not copied).
The number of incorrect IDs observed while waiting for a response
should be included in the calculation, for example the logarithm
(base 2) of the number of Bad IDs could be subtracted.
The result of the calculation should be used to decide whether to
repeat the query. This allows a smooth response to attacks, while
not detracting from performance in the normal situation where Bad
IDs are not observed.
While this measure does not reduce the number of packets required
for a successful attack, it does increase the time required, since
an attacker gains nothing from sending spoof packets at a very
high rate.
3.4. Use of calculated entropy
The entropy calculated in 3.3 should be used to decide whether
a value is to be accepted as valid, which in turn affects whether
the query needs to be repeated as described in 3.2.
Other factors in this decision should be:
(1) Whether the value is already in the cache.
(2) If so, the TTL status of the cache entry.
(3) Whether the name of the record being updated matchs
( ends with ) the query question. This is intended
to be a further mitigation (in addition to 3.3) against
Kaminsky attacks.
For example, the test for whether a value is valid could be
E + [C] > 50 + K
where
E is the value computed in 3.3
C is Zero if the value is not already in the cache
Otherwise 30 - [D/1000]
where D is the number of seconds since the cache entry expired
K is 10 if the RR name does not match the question otherwise 0
and [] denotes that zero is substituted if enclosed term is negative.
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4. Analysis
This section is intended to be less formal, to give some insight
into the rationale for the recommendations given in section 3,
and to discuss possible adverse effects.
The intention is that these mitigations have minimal effects, other
than to make DNS spoof attacks impractical.
4.1. Random nonce
It is conceiveable that the random prepended nonce cause problems
with memory management for some servers.
For example if a server normalised all incoming strings, and
never reclaimed the memory, failure would rapidly occur.
Such servers, if they exist, are severely broken and subject to
denial of service attacks.
It is expected that high performance authoritative servers
reclaim all memory allocated to process a query on completion
of the transaction.
Nevertheless it would be wise to research this issue before large
scale deployment.
4.2. Query repetition
Query repetition should have no impact other than on server load.
Servers do not normally retain any state information about clients
after the query/response transaction completes.
4.3. Impact on Root and TLD servers
The random nonce (3.1) is valuable because it means that no
extra queries to Root and top level servers are needed in normal
operation (except in very rare cases). This is important because
these servers constitute the shared public base of the DNS, so the
stability of these servers is very important.
The exception is queries for non-existent domains. Since the value
to an attacker of fooling a client into believing a domain does
not exist is limited, it is recommended that the amount of entropy
required be lower than for normal operation.
Clients in general should implement user interfaces that make it
unlikely that users will enter invalid domain names, and that
errors are properly notified, so they can be corrected. However
this is outside the scope of this document.
In practice, the bulk of such queries emanate from mis-configured
software, so in any case proportional effect on root servers will
be small. It is important that negative results be cached, and
a progressive back-off algorithm be used.
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4.4. Impact on other levels
For the example test given in 3.4, two queries are usually
required the first time a record is fetched. However when the
TTL expires, the refresh operation only requires a single query.
It is expected that such refresh operations dominate proper
DNS traffic, so the impact should be minimal.
Operators of authoritative servers have several options if
the query repetition may cause overload.
(a) Increase unreasonably low TTLs.
(b) Use names with more alpha characters (to take advantage of 0x20).
(c) Implement support for the proposed AL record type.
The latter implies that agreeing a specification for the AL record
type (or equivalent) and assigning a TYPE code should be given a
high priority, as it allows implementors of secure resolvers to
include AL support, which in turn gives server operators a means of
resolving any problems that might occur, especially for the case
of non-deterministic servers. Universal support for the AL record
(or equivalent) is desirable, but not necessary.
4.5. Impact of the Kaminsky check
In practice, this check ( for the example test given in 3.4 ), very
rarely causes additional queries to be generated. It mainly affects
NS and glue records, which are normally already established in the
cache.
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5. Security Considerations
All of the mitigations aim to provide more security. Query repetition
has an obvious adverse effect on performance and bandwith.
Each query repetition provides an extra attack opportunity, so the
total entropy requirement may be adjusted to reflect this.
The random nonce may expose internal state to an attacker who
controls a name server. It is essential that a cryptographically
strong source of random numbers be used to generate IDs, 0x20 bits
and prepended nonces. This must be seeded from data that cannot be
guessed by an attacker, such as thermal noise or other random
physical fluctuations.
A sufficently determined attacker may cause a denial of service,
due to a very large number of Bad IDs reducing the effective entropy
to zero. In practice, denial of service would probably occur due
to the extreme number of incoming packets.
6. IANA Considerations
No direct considerations.
Indirectly, the TYPE code for AL record described in 4.4.
7. Acknowledgments
Thanks to Nicholas Weaver (ICSI Berkeley) and Wouter Wijngaards (NLnet
Labs). The idea of prepending a nonce may be due to Paul Vixie (ISC).
8. Informative References
[RFC2181] Elz, R. and R. Bush, "Clarifications to the DNS
Specification", RFC 2181, July 1997.
Author's Address
George Barwood
33 Sandpiper Close
Gloucester GL2 4LZ
United Kingdom
Phone: +44 452 722670
EMail: george.barwood@blueyonder.co.uk
Skype: george.barwood
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