One document matched: draft-ietf-dkim-ssp-requirements-03.txt
Differences from draft-ietf-dkim-ssp-requirements-02.txt
DKIM Working Group M. Thomas
Internet-Draft Cisco Systems
Intended status: Informational March 6, 2007
Expires: September 7, 2007
Requirements for a DKIM Signing Practices Protocol
draft-ietf-dkim-ssp-requirements-03
Status of this Memo
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Copyright Notice
Copyright (C) The IETF Trust (2007).
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Abstract
DomainKeys Identified Mail (DKIM) provides a cryptographic mechanism
for domains to assert responsibility for the messages they handle. A
related mechanism will allow an administrator to publish various
statements about their DKIM signing practices. This document defines
requirements for this mechanism.
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Requirements Language
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].
Table of Contents
1. Introduction . . . . . . . . . . . . . . . . . . . . . . . . . 5
2. Definitions . . . . . . . . . . . . . . . . . . . . . . . . . 6
3. SSP Problem Scenarios . . . . . . . . . . . . . . . . . . . . 7
3.1. Problem Scenario 1: All Mail Signed with DKIM . . . . . . 7
3.2. Problem Scenario 2: Illegitimate Domain Name Use . . . . . 8
4. SSP Deployment Scenarios . . . . . . . . . . . . . . . . . . . 10
4.1. Deployment Scenario 1: Outsourced Signing . . . . . . . . 10
4.2. Deployment Scenario 2: Determinism in Lookup Mechanism
and Subdomain Coverage . . . . . . . . . . . . . . . . . . 10
4.3. Deployment Scenario 3: Resent Original Mail . . . . . . . 10
4.4. Deployment Scenario 4: Incremental Deployment of
Signing . . . . . . . . . . . . . . . . . . . . . . . . . 11
4.5. Deployment Scenario 5: Transport Scenarios . . . . . . . . 11
4.6. Deployment Scenario 6: Human Legibility of Practices . . . 12
4.7. Deployment Scenario 7: Cryptographic Downgrade Attacks . . 12
4.8. Deployment Scenario 8: Extensibility . . . . . . . . . . . 12
4.9. Deployment Scenario 9: Security . . . . . . . . . . . . . 12
5. Requirements . . . . . . . . . . . . . . . . . . . . . . . . . 13
5.1. Discovery Requirements . . . . . . . . . . . . . . . . . . 13
5.2. SSP Transport Requirements . . . . . . . . . . . . . . . . 14
5.3. Practice and Expectation Requirements . . . . . . . . . . 14
5.4. Extensibility and Forward Compatibility Requirements . . . 17
6. Security Requirements . . . . . . . . . . . . . . . . . . . . 18
7. IANA Considerations . . . . . . . . . . . . . . . . . . . . . 19
8. Security Considerations . . . . . . . . . . . . . . . . . . . 20
9. Acknowledgments . . . . . . . . . . . . . . . . . . . . . . . 21
10. References . . . . . . . . . . . . . . . . . . . . . . . . . . 22
10.1. Normative References . . . . . . . . . . . . . . . . . . . 22
10.2. Informative References . . . . . . . . . . . . . . . . . . 22
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Author's Address . . . . . . . . . . . . . . . . . . . . . . . . . 23
Intellectual Property and Copyright Statements . . . . . . . . . . 24
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1. Introduction
DomainKeys Identified Mail [I-D.ietf-dkim-base]defines a message
level signing and verification mechanism for email. While a DKIM
signed message speaks for itself, there is ambiguity if a message
doesn't have a valid first party signature: is this to be expected or
not?. For email this is an especially difficult problem since there
is no expectation of a priori knowledge of a sending domain's
practices. This ambiguity can be used to mount a bid down attack
which is inherent with systems that allow optional authentication
like email: if a receiver doesn't know otherwise, it should not
assume that the lack of a valid signature is a priori invalid. Thus,
an attacker can take advantage of the ambiguity and simply not sign
messages. If a protocol could be developed for a domain to publish
its DKIM signing practices, a message verifier could take that into
account when it receives an unsigned piece of email.
This document defines the requirements for a mechanism that permits
the publication of Sender Signing Practices (SSP). The document is
organized into two main sections: a Problem and Deployment Scenario
section which describes the problems that SSP is intended to address
as well as the deployment issues surrounding the base problems. The
second section is the Requirements that arise because of those
scenarios.
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2. Definitions
o Domain Holder: the entity that controls the contents of the DNS
subtree starting at the domain, either directly or by delegation
via NS records it controls.
o First Party Address: For DKIM, a first party address is defined to
be the [RFC2822].From address in the message header; a first party
address is also known as an Author address
o First Party Signature: a first party signature is a valid
signature where the domain tag (d= or the more specific identity
i= tag) matches the first party address. "Matches" in this
context is defined in [I-D.ietf-dkim-base]
o Third Party Signature: a third party signature is a valid
signature that does not qualify as a First Party Signature. Note
that a DKIM third party signature is not required to correspond to
a third party address such as Sender or Listid, etc.
o Practice: a statement according to the [RFC2822].From domain
holder of externally verifiable behavior in the email messages it
sends. A practice should always be true when received by a
topologically adjacent SMTP.
o Expectation: an Expectation combines with a Practice to convey
what the domain holder considers the likely survivability of the
Practice for a non-topologically adjacent receiver.
o DKIM Signing Complete: a Practice where the domain holder asserts
that all legitimate mail will be sent with a valid First Party
Signature.
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3. SSP Problem Scenarios
The email world is a diverse place with many deployment scenarios.
This section tries to outline some usage scenarios that it is
expected that DKIM signing/verifying will take place in, and how a
new protocol might be helpful to clarify the relevance of DKIM signed
mail.
3.1. Problem Scenario 1: All Mail Signed with DKIM
After auditing their outgoing mail and deploying DKIM signing for all
of their legitimate outgoing mail, a domain could be said to be DKIM
signing complete. That is, the domain has to the best of its ability
insured that all mail legitimately purporting to have come from that
domain contains a valid DKIM signature.
A receiver in the general case doesn't know what the practices are
for a given domain, or what their expectations are for unsigned mail.
Thus the receiver is at a disadvantage in that it does not know if it
should expect mail to be signed from a given domain or not. This
knowledge gap leads to a trivially exploitable bid-down attack where
the attacker merely sends unsigned mail; since the receiver doesn't
know the practices of the signing domain, it cannot treat the message
any more harshly for lack of a valid signature.
An information service which allowed a receiver to query for the
practices and expectations of the first party domain when no valid
first party signature is found could be useful in closing this gap.
A receiver could use this information to treat such questionable mail
with varying degrees of prejudice.
Note that for the foreseeable future, unrestricted use patterns of
mail (eg where users may be members of mailing lists, etc) will
likely suffer occasional non-malicious signature failure in transit.
While probably not a large percentage of total traffic, the kind of
breakage may be a significant concern for those usage patterns. This
scenario defines where the sender cannot set any expectation as to
whether an individual message will arrive intact.
Even without that expectation, a receiver may be able to take
advantage of the knowledge that the domain's practice is to sign all
mail and bias filters against unsigned or damaged in transit mail.
This information should not be expected to be used in a binary yes/no
fashion, but instead as a data point among others in a filtering
system.
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1. Mail with a [RFC2822].From A purportedly sends to B with a
missing or broken DKIM first party signature from A
2. B would like to know whether that is an expected state of
affairs.
3. A provides information that it signs all outgoing mail, but
places no expectation on whether it will arrive with an intact
first party signature.
4. B could use this information to bias its filters such that it
looks somewhat more suspicious.
3.2. Problem Scenario 2: Illegitimate Domain Name Use
A class of mail typified by transactional mail from high value
domains is the target of phishing attacks. In particular, many
phishing scams forge the [RFC2822].From address in addition to
spoofing much of the content to trick unsuspecting users into
revealing sensitive information. Domain holders sending this kind of
mail would like the ability to give an enhanced guarantee that mail
sent in their name should always arrive with the proof that the
domain holder consented to its transmission. That is, the message
should contain a valid first party signature as defined above.
From a receiver's standpoint, knowing that a domain not only signs
all of its mail, but places a very high value on the receipt of a
valid first party signature from that domain is helpful. Hence a
receiver can know that the domain not only signs all of its mail, but
also feels it essential that legitimate mail must have its first
party signatures survive transit. A receiver with the knowledge of
the sender's expectations in hand might choose to process messages
not conforming to the published practices in a special manner.
[Informative Note: in terms of a receiving filter, one may choose
to treat scenario 2 much more harshly than scenario 1; where
scenario 1 looks odd, scenario 2 looks like something is very
wrong]
1. Mail with a [RFC2822].From A purportedly sends to B with a
missing or broken first party DKIM signature from A
2. B would like to know whether that is an expected state of
affairs.
3. A provides information that it signs all outgoing mail, but
places an expectation that it should arrive with an intact first
party signature, and that the receiver should be suspicious if it
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does not.
4. B could use this information to bias its filters such that it
looks much more suspicious.
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4. SSP Deployment Scenarios
Given the problems enumerated above for which we'd like SSP to
provide information to recipients, there are a number of scenarios
that are not related to the problems that are to be solved, per se,
but the actual mechanics of implementing/deploying the information
service that SSP would provide.
4.1. Deployment Scenario 1: Outsourced Signing
Many domains do not run their own mail infrastructure, or may
outsource parts of it to third parties. It is desirable for a domain
holder to have the ability delegate to other entities the ability to
sign for the domain holder. One obvious use scenario is a domain
holder from a small domain that needs to have the ability for their
outgoing ISP to sign all of their mail on behalf of the domain
holder. Other use scenarios include outsourced bulk mail for
marketing campaigns, as well as outsourcing various business
functions such as insurance benefits, etc.
4.2. Deployment Scenario 2: Determinism in Lookup Mechanism and
Subdomain Coverage
SSP's client will generally be deployed on incoming mail streams to
provide the information as proposed in the problem scenarios. The
RFC2822.From address will be used as a basis for the lookup. More
precisely the domain part of the first address of the RFC2822.From
will form the trust basis to fetch the published information. A
trivial attack to circumvent finding the published information could
be mounted by simply using a subdomain of the parent which doesn't
have published information. This attack is called the subdomain
attack: that is, a domain needs to not only publish a policy for a
given DNS label it controls, but it also may need to protect all
subdomains of that label as well. If this characteristic is not met,
an attacker would need only create a possibly fictitious subdomain
which was not covered by SSP's information service. Thus, it would
be advantageous for The Protocol to not only cover a given domain,
but all subdomains of that domain as well.
4.3. Deployment Scenario 3: Resent Original Mail
Resent mail is a common occurrence in many scenarios in the email
world of today. For example, Alice sends a DKIM signed message with
a published practice of signing all messages to Bob's mailing list.
Bob, being a good net citizen, wants to be able to take his part of
the responsibility of the message in question, so he DKIM signs the
message, perhaps corresponding to the Sender address.
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Note that this scenario is completely orthogonal to whether Alice's
signature survived Bob's mailing list: Bob merely wants to assert his
part in the chain of accountability for the benefit of the ultimate
receivers. It would be useful for this practice to be encouraged as
it gives a more accurate view of who handled the message. It also
has the side benefit that remailers that are not friendly to DKIM
first party signatures (ie, break them) can be potentially assessed
by the receiver based on the receiver's opinion of the signing
domains that actually survived.
4.4. Deployment Scenario 4: Incremental Deployment of Signing
As a practical matter, it may be difficult for a domain to roll out
DKIM signing such that they can publish the DKIM Signing Complete
practice given the complexities of the user population, outsourced
vendors sending on its behalf, etc. This leaves open an exploit that
high-value mail such as in Problem Scenario 2 must be classified to
the least common denominator of the published practices. It would be
desirable to allow a domain holder to publish a list of exceptions
which would have a stronger practices statement.
For example, bigbank.example.com might be ready to say that
statements@bigbank.example.com is always signed, but the rest of the
domain, say, is not. Another situation is that the practices of some
address local parts in a given domain are not the same as practices
of other local parts. Using the same example of
statements@bigbank.example.com being a transactional kind of email
which would like to publish very strong practices, mixed in with the
rest of the user population local parts which may go through mailing
lists, etc, for which a less strong statement is appropriate.
It should be said that DKIM, through the use of subdomains, can
already support this kind of differentiation. That is, in order to
publish a strong practice, one only has to segregate those cases into
different subdomains. For example: accounts.bigbank.example.com
would publish constrained practices while
corporateusers.bigbank.example.com might publish more permissive
practices.
4.5. Deployment Scenario 5: Transport Scenarios
Email service provides an any-any mesh of potential connections: all
that is required is the publication of an MX record and a SMTP
listener to receive mail. Thus the use of SSP is likely to fall into
two main scenarios, the first of which are large, well known domains
who are in constant contact with one another. In this case caching
of records is essential for performance, including the caching of the
non-existence of records (ie, negative caching).
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The second main scenario is when a domain exchanges mail with a much
smaller volume domain. This scenario can be both perfectly normal as
with the case of vanity domains, and sadly a vector for those sending
mail for anti-social reasons. In this case we'd like the burden to
SSP querier to be low, since many of the lookups will not provide a
useful answer. Likewise, it would be advantageous to have upstream
caching here as well so that, say, a mailing list exploder on a small
domain does not result in an explosion of queries back at the root
server for the small domain.
4.6. Deployment Scenario 6: Human Legibility of Practices
While SSP records are likely to be primarily consumed by an
automaton, for the foreseeable future they are also likely to be
inspected by hand. It would be nice to have the practices stated in
a fashion which is also intuitive to the human inspectors.
4.7. Deployment Scenario 7: Cryptographic Downgrade Attacks
There is a downgrade attack possible when a DKIM signature is hashed
with a previously acceptable but now insecure hash algorithm. This
could allow attackers to send their chosen text which is apparently
signed by the targeted domain. It would be advantageous for a domain
to publish what the allowable signing/hashing algorithms are to
prevent this downgrade attack.
4.8. Deployment Scenario 8: Extensibility
While this document pertains only to requirements surrounding DKIM
signing practices, it would be beneficial for the protocol to be able
to extend to other protocols.
4.9. Deployment Scenario 9: Security
SSP must be able to withstand life in a hostile open internet
environment. These include DoS attacks, and especially DoS attacks
that leverage themselves through amplification inherent in the
protocol. In addition, while a useful protocol may be built without
strong source authentication provided by the information service, a
path to strong source authentication should be provided by the
protocol, or underlying protocols.
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5. Requirements
This section defines the requirements for SSP. As with most
requirements documents, these requirements define the MINIMUM
requirements that a candidate protocol must provide. It should also
be noted that SSP must fulfill all of the requirements.
5.1. Discovery Requirements
Receivers need a means of obtaining information about a sender's DKIM
practices. This requires a means of discovering where the
information is and what it contains.
1. The author is the first-party sender of a message, as specified
in the [rfc2822].From field. SSP's information is associated
with the author's domain name and is published subordinate to
that domain name.
2. In order to limit the cost of its use, any query service
supplying SSP's information MUST provide a definitive responsive
within a small, deterministic number of query exchanges.
[Informative Note: this, for all intents and purposes is a
prohibition on anything that might produce loops or result in
extended delays and overhead; also though "deterministic"
doesn't specify how many exchanges, the expectation is "few".]
[Refs: Deployment Scenario 2]
3. SSP's publishing mechanism MUST be defined such that it does not
lead to multiple records of different protocols residing at the
same location.
[Informative note: An example is multiple resource record of
the same type within a common DNS leaf. Hence, uniquely
defined leaf names or uniquely defined resource record types
will ensure unambiguous reference.]
[Refs: Deployment Scenario 2]
4. SSP must be capable of providing coverage for not only the domain
but all of its subdomains as well. If all subdomains cannot be
directly associated with the parent's information, the protocol
MUST be able to communicate that the domain name is suspicious.
The process of obtaining the parent domain's practices MUST
complete in a deterministic number of steps, preferably few. In
widening the scope to have the possibility of all subdomains
inherit the parent practice, a number of algorithms could be
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employed -- all seemingly with their own set of engineering
tradeoffs. A common theme in the production of this document was
that the number of lookups, on average should be small, and that
the discovery process should always be bound to some small finite
number of queries.
[Refs: Deployment Scenario 2
5.2. SSP Transport Requirements
The publication and query mechanism will operate over the Internet
message exchange. This lower layer service must exhibit basic
characteristics:
1. Widespread deployment of the transport layer would be highly
desirable, especially if riding on top of a true transport layer
(eg, TCP, UDP).
[Refs: Deployment Scenario 5, 8]
2. A low-cost query/response in terms of latency time and the number
of packets involved is highly desirable.
[Refs: Deployment Scenario 5]
3. If the infrastructure doesn't provide caching (ala DNS), the
records retrieved will need time-to-live values to allow querying
verifiers to maintain their own caches. Existing caching
infrastructure is, however, highly desirable.
[Refs: Deployment Scenario 5]
4. Multiple geographically and topologically diverse servers must be
supported for high availability
[Refs: Deployment Scenario 5, 8]
5.3. Practice and Expectation Requirements
As stated in the definitions a Practice is a statement according to
the [RFC2822].From domain holder of externally verifiable behavior in
the email messages it sends. As a silly example, a Practice might be
defined that all email messages will contain an X-Silly header.
Since there is a possibility of alteration between what a sender
sends and a receiver examines, an Expectation combines with a
Practice to convey what the domain holder considers the likely
outcome of the survivability of the Practice for at a receiver. For
example, a Practice that X-Silly is present when it is sent from the
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domain, and an Expectation that it will remain present for receivers
whether topologically adjacent or not.
1. SSP MUST be able to make Practices and Expectation assertions
about the [RFC2822].From address in the context of DKIM. SSP
will not make assertions about other addresses for DKIM at this
time.
[Refs: Problem Scenario 1,2]
2. SSP MUST provide a concise linkage between the [RFC2822].From
and the identity in the DKIM i= tag, or its default if it is
missing in the signature. That is, SSP MUST precisely define
the semantics of what qualifies as a First Party Signature.
[Refs: Problem Scenario 1,2]
3. SSP MUST be able to publish a Practice that the domain's signing
behavior is "DKIM Signing Complete". That is, all messages were
transmitted with a valid first party signature.
[Refs: Problem Scenario 1]
4. SSP MUST be able to publish an Expectation that a verifiable
first party DKIM Signature should be expected on receipt of a
message.
[Refs: Problem Scenario 2]
5. Practices and Expectations MUST be presented in SSP syntax using
as intuitive a descriptor as possible. For example, p=? would
be better represented as p=unknown.
[Refs: Deployment Scenario 6]
6. Because DKIM uses DNS to store selectors, there is always the
ability for a domain holder to delegate all or parts of the
_domainkey subdomain to an affiliated party of the domain
holder's choosing. That is, the domain holder may be able to
set a NS record for _domainkey.example.com to, say, an email
provider who manages that namespace. There is also the ability
for the domain holder to partition its namespace into subdomains
to further constrain third parties. For example, a domain
holder could delegate only _domainkey.benefits.example.com to a
third party to constrain the third party to only be able to
produce valid signatures in the benefits.example.com subdomain.
Last, a domain holder can even use CNAME's to delegate
individual leaf nodes. Thus SSP need not invent a different
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means of allowing affiliated parties to sign on a domain's
behalf at this time.
7. Practices and Expectations MUST be presented as an information
service from the signing domain to be consumed as an added
factor to the receiver's local policy. In particular, a
Practice or Expectation MUST NOT mandate any disposition stance
on the receiver.
[Refs: Problem Scenario 1, 2, 3]
8. There is no requirement that SSP publish a Practices of any/all
third parties that MUST NOT sign on the domain holder's behalf.
This should be considered out of scope.
[INFORMATIVE NOTE: this is essentially saying that the
protocol doesn't have to concern itself with being a
blacklist repository.]
[Refs: Problem Scenario 1-2]
9. SSP MUST NOT be required to be invoked if a valid first party
signature is found.
[Refs: Deployment Scenario 2]
10. [PROVISIONAL] The signing policy statement MUST be capable of
fully describing a signing practice in which multiple signatures
are always provided such that the policy is of utility to any
verifier is capable of verifying any of the signatures that are
always provided. Such a mechanism MUST NOT:
* Require the verifier to perform any additional DNS lookups
* Require duplication of configuration data
* In particular not require the policy record to provide for
the description of any cryptographic or cannonicalization
algorithm
INFORMATIVE NOTE: The ability to specify multiple signatures
is necessary in order to permit orderly transitions to new
cryptographic and canonicalization algorithms. Unless the
policy language is not sufficiently expressive to allow the
signer to describe the actual signature practice in this case
there is an opportunity for an attacker to exploit the fact
that there are verifiers that do not yet support the new
algorithm.
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[Refs: Deployment Scenario 7]
11. SSP MUST NOT provide a mechanism which impugns the existence of
non-first party signatures in a message. A corollary of this
requirement is that the protocol MUST NOT link practices of
first party signers with the practices of third party signers.
[INFORMATIVE NOTE: the main thrust of this requirement is
that practices should only be published for that which the
publisher has control, and should not meddle in what is
ultimately the local policy of the receiver.]
[Refs: Deployment Scenario 3]
5.4. Extensibility and Forward Compatibility Requirements
1. SSP MUST NOT extend to any other protocol than DKIM for email at
this time. SSP SHOULD be able to extend for protocols other than
DKIM.
[Refs: Deployment Scenario 8]
2. SSP MUST be able to add new Practices and Expectations within the
existing discovery/transport/practices in a backward compatible
fashion.
[Refs: Deployment Scenario 8]
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6. Security Requirements
1. Minimize DoS potential: SSP for a high-value domain is
potentially a high-value DoS target, especially since the
unavailability of SSP's record could make unsigned messages less
suspicious.
2. Amplification Attacks: SSP MUST NOT make highly leveraged
amplification or make-work attacks possible. In particular any
amplification must be O(1).
[Author's question: is it really O(1)? or O(n)?]
[Refs: Deployment Scenario 9]
3. Authenticity: SSP MUST have the ability for a domain holder to
provide SSP's data such that a receiver can determine that it is
authentically from the domain holder with a large degree of
certainty. SSP may provide means which provide less certainty in
trade off for ease of deployment.
[Refs: Deployment Scenario 9]
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7. IANA Considerations
This document makes no request of IANA.
Note to RFC Editor: this section may be removed on publication as an
RFC.
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8. Security Considerations
This document defines requirements for a new protocol and the
security related requirements are defined above. There is an
expectation that SSP will not always be required to have source
authentication of the practices information which is noteworthy.
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9. Acknowledgments
Due to flipping in the market and raising interest rates, this home
is no longer free. Dave Crocker and Jim Fenton helped me raise the
walls on this document and are accorded a room at the inn. The inn
is not yet full, however.
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10. References
10.1. Normative References
[I-D.ietf-dkim-base]
Allman, E., "DomainKeys Identified Mail (DKIM)
Signatures", draft-ietf-dkim-base-04 (work in progress),
July 2006.
[RFC2119] Bradner, S., "Key words for use in RFCs to Indicate
Requirement Levels", BCP 14, RFC 2119, March 1997.
[RFC2822] Resnick, P., "Internet Message Format", RFC 2822,
April 2001.
10.2. Informative References
[I-D.ietf-dkim-overview]
Hansen, T., "DomainKeys Identified Mail (DKIM) Service
Overview", draft-ietf-dkim-overview-01 (work in progress),
June 2006.
[I-D.ietf-dkim-threats]
Fenton, J., "Analysis of Threats Motivating DomainKeys
Identified Mail (DKIM)", draft-ietf-dkim-threats-03 (work
in progress), May 2006.
Thomas Expires September 7, 2007 [Page 22]
Internet-Draft DKIM-SSP-REQ March 2007
Author's Address
Michael Thomas
Cisco Systems
606 Sanchez St
San Francisco, California 94114
USA
Phone: +1-408-525-5386
Fax: +1-408-525-5386
Email: mat@cisco.com
Thomas Expires September 7, 2007 [Page 23]
Internet-Draft DKIM-SSP-REQ March 2007
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Thomas Expires September 7, 2007 [Page 24]
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