DomainKeys Identified Mail | T. Hansen |
Request for Comments: 5585 | AT&T Laboratories |
Category: Informational | D. Crocker |
Brandenburg InternetWorking | |
P. Hallam-Baker | |
Default Deny Security, Inc. | |
June 2009 |
DomainKeys Identified Mail (DKIM) Service Overview
This memo provides information for the Internet community. It does not specify an Internet standard of any kind. Distribution of this memo is unlimited.
Copyright © 2009 IETF Trust and the persons identified as the document authors. All rights reserved.
This document is subject to BCP 78 and the IETF Trust's Legal Provisions Relating to IETF Documents in effect on the date of publication of this document (http://trustee.ietf.org/license-info). Please review these documents carefully, as they describe your rights and restrictions with respect to this document.
This document provides an overview of the DomainKeys Identified Mail (DKIM) service and describes how it can fit into a messaging service. It also describes how DKIM relates to other IETF message signature technologies. It is intended for those who are adopting, developing, or deploying DKIM. DKIM allows an organization to take responsibility for transmitting a message, in a way that can be verified by a recipient. The organization can be the author's, the originating sending site, an intermediary, or one of their agents. A message can contain multiple signatures from the same or different organizations involved with the message. DKIM defines a domain-level digital signature authentication framework for email, using public-key cryptography, with the domain name service as its key server technology (RFC 4871). This permits verification of a responsible organization, as well as the integrity of the message contents. DKIM also enables a mechanism that permits potential email signers to publish information about their email signing practices; this will permit email receivers to make additional assessments about messages. DKIM's authentication of email identity can assist in the global control of "spam" and "phishing".
This document provides a description of the architecture and functionality for DomainKeys Identified Mail (DKIM), that is, the core mechanism for signing and verifying messages. It is intended for those who are adopting, developing, or deploying DKIM. It will also be helpful for those who are considering extending DKIM, either into other areas of use or to support additional features. This overview does not provide information on threats to DKIM or email or details on the protocol specifics, which can be found in [RFC4686] and [RFC4871], respectively. Because the scope of this overview is restricted to the technical details of signing and verifying using DKIM, it does not explore operational issues, the details of services that DKIM uses, or those that, in turn, use DKIM. Nor does it discuss services that build upon DKIM for enforcement of policies or assessments. The document assumes a background in basic email and network security technology and services.
DKIM allows an organization to take responsibility for a message in a way that can be verified by a recipient. The organization can be a direct handler of the message, such as the author's, the originating sending site's, or an intermediary's along the transit path. However, it can also be an indirect handler, such as an independent service that is providing assistance to a direct handler. DKIM defines a domain-level digital signature authentication framework for email through the use of public-key cryptography and using the domain name service as its key server technology [RFC4871]. It permits verification of the signer of a message, as well as the integrity of its contents. DKIM will also provide a mechanism that permits potential email signers to publish information about their email signing practices; this will permit email receivers to make additional assessments of unsigned messages. DKIM's authentication of email identity can assist in the global control of "spam" and "phishing".
Neither this document nor DKIM attempts to provide solutions to the world's problems with spam, phishing, viruses, worms, joe jobs, etc. DKIM provides one basic tool, in what needs to be a large arsenal, for improving basic trust in the Internet mail service. However, by itself, DKIM is not sufficient to that task and this overview does not pursue the issues of integrating DKIM into these larger efforts, beyond a simple reference within a system diagram. Rather, it is a basic introduction to the technology and its use.
A person or organization has an "identity" -- that is, a constellation of characteristics that distinguish them from any other identity. Associated with this abstraction can be a label used as a reference, or "identifier". This is the distinction between a thing and the name of the thing. DKIM uses a domain name as an identifier, to refer to the identity of a responsible person or organization. In DKIM, this identifier is called the Signing Domain IDentifier (SDID) and is contained in the DKIM-Signature header fields "d=" tag. Note that the same identity can have multiple identifiers.
A DKIM signature can be created by a direct handler of a message, such as the message's author or by an intermediary. A signature also can be created by an independent service that is providing assistance to a handler of the message. Whoever does the signing chooses the SDID to be used as the basis for later assessments. Hence, the reputation associated with that domain name might be an additional basis for evaluating whether to trust the message for delivery. The owner of the SDID is declaring that they accept responsibility for the message and can thus be held accountable for it.
DKIM is intended as a value-added feature for email. Mail that is not signed by DKIM is handled in the same way as it was before DKIM was defined. The message will be evaluated by established analysis and filtering techniques. (A signing policy can provide additional information for that analysis and filtering.) Over time, widespread DKIM adoption could permit stricter handling of messages that are not signed. However, early benefits do not require this and probably do not warrant this.
DKIM has a narrow scope. It is an enabling technology, intended for use in the larger context of determining message legitimacy. This larger context is complex, so it is easy to assume that a component like DKIM, which actually provides only a limited service, instead satisfies the broader set of requirements.
By itself, a DKIM signature:
Historically, the IP Address of the system that directly sent the message -- that is, the previous email "hop" -- has been treated as an identity to use for making assessments. For example, see [RFC4408], [RFC4406], and [RFC4407] for some current uses of the sending system's IP Address. The IP Address is obtained via underlying Internet information mechanisms and is therefore trusted to be accurate. Besides having some known security weaknesses, the use of addresses presents a number of functional and operational problems. Consequently, there is a widespread desire to use an identifier that has better correspondence to organizational boundaries. Domain names can satisfy this need.
There have been four previous IETF Internet Mail signature standards. Their goals have differed from those of DKIM. PEM and MOSS are only of historical interest.
Development of both S/MIME and OpenPGP has continued. While each has achieved a significant user base, neither one has achieved ubiquity in deployment or use.
To the extent that other message-signing services might have been adapted to do the job that DKIM is designed to perform, it was felt that repurposing any of those would be more problematic than creating a separate service. That said, DKIM only uses cryptographic components that have a long history, including use within some of those other messaging security services.
DKIM is differentiated by its reliance on an identifier that is specific to DKIM use.
DKIM also has a distinctive approach for distributing and vouching for keys. It uses a key-centric, public-key management scheme, rather than the more typical approaches based on a certificate in the styles of Kohnfelder (X.509) [Kohnfelder] or Zimmermann (web of trust) [WebofTrust]. For DKIM, the owner of the SDID asserts the validity of a key, rather than having the validity of the key attested to by a trusted third party, often including other assertions, such as a quality assessment of the key's owner. DKIM treats quality assessment as an independent, value-added service, beyond the initial work of deploying a signature verification service.
Further, DKIM's key management is provided by adding information records to the existing Domain Name System (DNS) [RFC1034], rather than requiring deployment of a new query infrastructure. This approach has significant operational advantages. First, it avoids the considerable barrier of creating a new global infrastructure; hence, it leverages a global base of administrative experience and highly reliable distributed operation. Second, the technical aspect of the DNS is already known to be efficient. Any new service would have to undergo a period of gradual maturation, with potentially problematic early-stage behaviors. By (re-)using the DNS, DKIM avoids these growing pains.
The basic Internet email service has evolved extensively over its several decades of continuous operation. Its modern architecture comprises a number of specialized components. A discussion about Mail User Agents (MUAs), Mail Handling Services (MHSs), Mail Transfer Agents (MTAs), Mail Submission Agents (MSAs), Mail Delivery Agents (MDAs), Mail Service Providers (MSPs), Administrative Management Domains (ADMDs), Mediators, and their relationships can be found in Appendix A.
The nature and origins of a message often are falsely stated. Such misrepresentations may be employed for legitimate or nefarious reasons. DKIM provides a foundation for distinguishing legitimate mail, and thus a means of associating a verifiable identifier with a message. Given the presence of that identifier, a receiver can make decisions about further handling of the message, based upon assessments of the identity that is associated with the identifier.
Receivers who successfully verify a signature can use information about the signer as part of a program to limit spam, spoofing, phishing, or other undesirable behaviors. DKIM does not, itself, prescribe any specific actions by the recipient; rather, it is an enabling technology for services that do.
These services will typically:
The role of DKIM is to perform the first of these; DKIM is an enabler for the second.
Consider an attack made against an organization or against customers of an organization. The name of the organization is linked to particular Internet domain names (identifiers). Attackers can leverage using either a legitimate domain name, one without authorization, or a "cousin" name that is similar to one that is legitimate, but is not controlled by the target organization. An assessment service that uses DKIM can differentiate between a domain (SDID) used by a known organization and a domain used by others. As such, DKIM performs the positive step of identifying messages associated with verifiable identities, rather than the negative step of identifying messages with problematic use of identities. Whether a verified identity belongs to a Good Actor or a Bad Actor is a question for later stages of assessment.
Email receiving services are faced with a basic decision: whether to accept and deliver a newly arrived message to the indicated recipient? That is, does the receiving service trust that the message is sufficiently "safe" to be viewed? For the modern Internet, most receiving services have an elaborate engine that formulates this quality assessment. These engines take a variety of information as input to the decision, such as from reputation lists and accreditation services. As the engine processes information, it raises or lowers its trust assessment for the message.
In order to formulate reputation information, an accurate, stable identifier is needed. Otherwise, the information might not pertain to the identified organization's own actions. When using an IP Address, accuracy is based on the belief that the underlying Internet infrastructure supplies an accurate address. When using domain-based reputation data, some other form of verification is needed, since it is not supplied independently by the infrastructure.
DKIM satisfies this requirement by declaring a valid "responsible" identity -- referenced through the SDID -- about which the engine can make quality assessments and by using a digital signature to ensure that use of the identifier is authorized. However, by itself, a valid DKIM signature neither lowers nor raises the level of trust associated with the message, but it enables other mechanisms to be used for doing so.
An organization might build upon its use of DKIM by publishing information about its Signing Practices (SP). This could permit detecting some messages that purport to be associated with a domain, but which are not. As such, an SP can cause the trust assessment to be reduced, or leave it unchanged.
Though man-in-the-middle attacks are historically rare in email, it is nevertheless theoretically possible for a message to be modified during transit. An interesting side effect of the cryptographic method used by DKIM is that it is possible to be certain that a signed message (or, if l= is used, the signed portion of a message) has not been modified between the time of signing and the time of verifying. If it has been changed in any way, then the message will not be verified successfully with DKIM.
As described above, this validity neither lowers nor raises the level of trust associated with the message. If it was an untrustworthy message when initially sent, the verifier can be certain that the message will be equally untrustworthy upon receipt and successful verification.
DKIM adds an end-to-end authentication capability to the existing email transfer infrastructure. That is, there can be multiple email relaying hops between signing and verifying. Hence, it defines a mechanism that only needs to be supported by the signer and the verifier, rather than any of the functional components along the handling path. This motivates functional goals about the authentication itself and operational goals about its integration with the rest of the Internet email service.
DKIM provides accountability at the coarse granularity of an organization or, perhaps, a department. An existing construct that enables this granularity is the Domain Name [RFC1034]. DKIM binds a signing key record to a Domain Name as the SDID. Further benefits of using domain names include simplifying key management, enabling signing by the infrastructure as opposed to the MUA, and reducing privacy concerns.
Contrast this with OpenPGP and S/MIME, which associate verification with individual authors, using their full email addresses.
Any party, anywhere along the transit path, can implement DKIM signing. Its use is not confined to particular systems, such as the author's MUA or the inbound boundary MTA, and there can be more than one signature per message.
Different parties have different roles in the process of email exchange. Some are easily visible to end users and others are primarily visible to operators of the service. DKIM was designed to support signing by any of these different parties and to permit them to sign with any domain name that they deem appropriate (and for which they hold authorized signing keys). As an example, an organization that creates email content often delegates portions of its processing or transmission to an outsourced group. DKIM supports this mode of activity, in a manner that is not normally visible to end users. Similarly, a reputation provider can delegate a signing key for a domain under the control of the provider, to be used by an organization for which the provider is prepared to vouch.
An authenticated identity can be subject to a variety of assessment policies, either ad hoc or standardized. DKIM separates basic authentication from assessment. The only semantics inherent to a DKIM signature are that the signer is asserting some kind of responsibility for the message. Any interpretation of this kind of responsibility is the job of services building on DKIM, but the details are beyond the scope of that core. One such mechanism might assert a relationship between the SDID and the author, as specified in the rfc5322.From: header field's domain identity. Another might specify how to treat an unsigned message with that rfc5322.From: field domain.
The ability to send a message that does not identify its author is considered to be a valuable quality of the current email service that needs to be retained. DKIM is compatible with this goal since it permits authentication of the email system operator, rather than the content author. If it is possible to obtain effectively anonymous accounts at example.com, knowing that a message definitely came from example.com does not threaten the anonymity of the user who authored it.
In order to facilitate incremental adoption, DKIM is designed to be transparent to recipients that do not support it. A DKIM signature does not "get in the way" for such recipients.
Contrast this with S/MIME and OpenPGP, which modify the message body. Hence, their presence is potentially visible to email recipients, whose user software needs to process the associated constructs.
DKIM must also be transparent to existing assessment mechanisms. Consequently, a DKIM signature verifier is to treat messages with signatures that fail as if they were unsigned. Hence, the message will revert to normal handling, through the receiver's existing filtering mechanisms. Thus, DKIM specifies that an assessing site is not to take a message that has a broken signature and treat it any differently than if the signature weren't there.
Contrast this with OpenPGP and S/MIME, which were designed for strong cryptographic protection. This included treating verification failure as message failure.
DKIM can be used by any two organizations that exchange email and implement DKIM; it does not require adoption within the open Internet's email infrastructure. In the usual manner of "network effects", the benefits of DKIM increase as its adoption increases.
Although this mechanism can be used in association with independent assessment services, such services are not essential in order to obtain initial benefit. For example, DKIM allows (possibly large) pairwise sets of email providers and spam filtering companies to distinguish mail that is associated with a known organization, versus mail that might deceptively purport to have the affiliation. This in turn allows the development of "whitelist" schemes whereby authenticated mail from a known source with good reputation is allowed to bypass some anti-abuse filters.
In effect, the email receiver can use their set of known relationships to generate their own reputation data. This works particularly well for traffic between large sending providers and large receiving providers. However, it also works well for any operator, public or private, that has mail traffic dominated by exchanges among a stable set of organizations.
Management of email delivery problems currently represents a significant pain point for email administrators at every point on the mail transit path. Administrators who have deployed DKIM verification have an incentive to encourage senders (who might subsequently complain that their email is not being delivered) to use DKIM signatures.
In order to allow early adopters to gain early benefit, DKIM makes no changes to the core Internet Mail service and, instead, can provide a useful benefit for any individual pair of signers and verifiers who are exchanging mail. Similarly, DKIM's reliance on the Domain Name System greatly reduces the amount of new administrative infrastructure that is needed across the open Internet.
DKIM can be deployed at a variety of places within an organization's email service. This affords flexibility in terms of who administers its use, as well as what traffic carries a DKIM signature. For example, employing DKIM at an outbound boundary MTA will mean that it is administered by the organization's central IT department and that internal messages are not signed.
DKIM has a very constrained set of capabilities, primarily targeting email while it is in transit from an author to a set of recipients. It associates verifiable information with a message, especially a responsible identity. When a message does not have a valid signature associated with the author, a DKIM SP will permit the domain name of the author to be used for obtaining information about their signing practices.
With the DKIM signature mechanism, a signer chooses an SDID, performs digital signing on the message, and adds the signature information using a DKIM header field. A verifier obtains the domain name and the "selector" from the DKIM header field, obtains the public key associated with the name, and verifies the signature.
DKIM permits any domain name to be used as the SDID, and supports extensible choices for various algorithms. As is typical for Internet standards, there is a core set of algorithms that all implementations are required to support, in order to guarantee basic interoperability.
DKIM permits restricting the use of a signature key to signing messages for particular types of services, such as only for a single source of email. This is intended to be helpful when delegating signing authority, such as to a particular department or to a third-party outsourcing service.
With DKIM, the signer explicitly lists the headers that are signed, such as From:, Date:, and Subject:. By choosing the minimal set of headers needed, the signature is likely to be considerably more robust against the handling vagaries of intermediary MTAs.
A DKIM signature applies to the message body and selected header fields. The signer computes a hash of the selected header fields and another hash of the body. The signer then uses a private key to cryptographically encode this information, along with other signing parameters. Signature information is placed into DKIM-Signature:, a new [RFC5322] message header field.
The key for a signature is associated with an SDID. That domain name provides the complete identity used for making assessments about the signer. (The DKIM specification does not give any guidance on how to do an assessment.) However, this name is not sufficient for making a DNS query to obtain the key needed to verify the signature.
A single SDID can have multiple signing keys and/or multiple potential signers. To support this, DKIM identifies a particular signature as using a combination of the SDID and an added field, called the "selector", specified in a separate DKIM-Signature: header field parameter.
After a message has been signed, any agent in the message transit path can verify the signature to determine that the owner of the SDID took responsibility for the message. Message recipients can verify the signature by querying the DNS for the signer's domain directly, to retrieve the appropriate public key, and thereby confirm that the message was signed by a party in possession of the private key for the SDID. Typically, verification will be done by an agent in the Administrative Management Domain (ADMD) of the message recipient.
Signers often need to support multiple assessments about their organization, such as to distinguish one type of message from another, or one portion of the organization from another. To permit assessments that are independent, one method is for an organization to use different sub-domains as the SDID tag, such as "transaction.example.com" versus "newsletter.example.com", or "productA.example.com" versus "productB.example.com". These can be entirely separate from the rfc5322.From header field domain.
DKIM uses external service components, such as for key retrieval and relaying email. This specification defines an initial set, using DNS and SMTP, for basic interoperability.
| |- RFC5322 Message V +--------+ +--------------------------------+ | Private| | ORIGINATING OR RELAYING ADMD | | Key +...>| Sign Message with SDID | | Store | +---------------+----------------+ +--------+ | (paired) [Internet] +--------+ | +-----------+ | Public | +--------------------------------+ | Remote | | Key | | RELAYING OR DELIVERING ADMD | | Sender | | Store | | Message Signed? | | Practices | +----+---+ +-----+--------------------+-----+ +-----+-----+ . |yes |no . . V | . . +-------------+ | . +.......>| Verify +--------+ | . | Signature | | | . +------+------+ | | . pass| fail| | . V | | . +-------------+ | | . | | | | . +.......>| Assessments | | | . . | | V V . . +-----+--+----+ +-------+ . . | | / Check \<............+ . | +-------->/ Signing \ . | / Practices \<..........+ . | +-------+-------+ . . | | . . | V . +----+--------+ | +-----------+ +------+-----+ |Reputation/ | | | Message | | Local Info | |Accreditation| +----------->| Filtering | | on Sender | |Info | | Engine | | Practices | +-------------+ +-----------+ +------------+
Figure 1: DKIM Service Architecture
As shown in Figure 1, basic message processing is divided between a signing Administrative Management Domain (ADMD) and a verifying ADMD. At its simplest, this is between the originating ADMD and the delivering ADMD, but can involve other ADMDs in the handling path.
If a message has more than one valid signature, the order in which the signers are assessed and the interactions among the assessments are not defined by the DKIM specification.
A number of tables and services are used to provide external information. Each of these introduces administration and maintenance requirements.
Signing can be performed by a component of the ADMD that creates the message, and/or within any ADMD along the relay path. The signer uses the appropriate private key that is associated with the SDID.
Verification can be performed by any functional component along the relay and delivery path. Verifiers retrieve the public key based upon the parameters stored in the message.
Messages lacking a valid author signature (a signature associated with the author of the message as opposed to a signature associated with an intermediary) can prompt a query for any published "signing practices" information, as an aid in determining whether the author information has been used without authorization.
Figure 1 shows the verified identity as being used to assess an associated reputation, but it could be applied to other tasks, such as management tracking of mail. Local policy guidelines may cause signing practices to be checked or the message may be sent directly to the message Filtering Engine.
A popular use of reputation information is as input to a Filtering Engine that decides whether to deliver -- and possibly whether to specially mark -- a message. Filtering Engines have become complex and sophisticated. Their details are outside of the scope of DKIM, other than the expectation that the verified identity produced by DKIM can accumulate its own reputation, and will be added to the varied soup of rules used by the engines. The rules can cover signed messages and can deal with unsigned messages from a domain, if the domain has published information about its practices.
It is expected that the most common venue for a DKIM implementation will be within the infrastructures of the authoring organization's outbound service and the receiving organization's inbound service, such as a department or a boundary MTA. DKIM can be implemented in an author's or recipient's MUA, but this is expected to be less typical, since it has higher administration and support costs.
A Mediator is an MUA that receives a message and can repost a modified version of it, such as to a mailing list. A DKIM signature can survive some types of modifications through this process. Furthermore, the Mediator can add its own signature. This can be added by the Mediator software itself, or by any outbound component in the Mediator's ADMD.
The security considerations of the DKIM protocol are described in the DKIM base specification [RFC4871], with [RFC4686] as their basis.
Many people contributed to the development of the DomainKeys Identified Mail and the effort of the DKIM Working Group is gratefully acknowledged. In particular, we would like to thank Jim Fenton for his extensive feedback diligently provided on every version of this document.
[Kohnfelder] | Kohnfelder, L., “Towards a Practical Public-key Cryptosystem”, May 1978. |
[RFC0989] | Linn, J. and IAB Privacy Task Force, “Privacy enhancement for Internet electronic mail: Part I: Message encipherment and authentication procedures”, RFC 989, February 1987. |
[RFC1034] | Mockapetris, P., “Domain names - concepts and facilities”, STD 13, RFC 1034, November 1987. |
[RFC1113] | Linn, J., “Privacy enhancement for Internet electronic mail: Part I - message encipherment and authentication procedures”, RFC 1113, August 1989. |
[RFC1848] | Crocker, S., Galvin, J., Murphy, S., and N. Freed, “MIME Object Security Services”, RFC 1848, October 1995. |
[RFC1991] | Atkins, D., Stallings, W., and P. Zimmermann, “PGP Message Exchange Formats”, RFC 1991, August 1996. |
[RFC2440] | Callas, J., Donnerhacke, L., Finney, H., and R. Thayer, “OpenPGP Message Format”, RFC 2440, November 1998. |
[RFC3156] | Elkins, M., Del Torto, D., Levien, R., and T. Roessler, “MIME Security with OpenPGP”, RFC 3156, August 2001. |
[RFC3851] | Ramsdell, B., “Secure/Multipurpose Internet Mail Extensions (S/MIME) Version 3.1 Message Specification”, RFC 3851, July 2004. |
[RFC4406] | Lyon, J. and M. Wong, “Sender ID: Authenticating E-Mail”, RFC 4406, April 2006. |
[RFC4407] | Lyon, J., “Purported Responsible Address in E-Mail Messages”, RFC 4407, April 2006. |
[RFC4408] | Wong, M. and W. Schlitt, “Sender Policy Framework (SPF) for Authorizing Use of Domains in E-Mail, Version 1”, RFC 4408, April 2006. |
[RFC4686] | Fenton, J., “Analysis of Threats Motivating DomainKeys Identified Mail (DKIM)”, RFC 4686, September 2006. |
[RFC4871] | Allman, E., Callas, J., Delany, M., Libbey, M., Fenton, J., and M. Thomas, “DomainKeys Identified Mail (DKIM) Signatures”, RFC 4871, May 2007. |
[RFC4880] | Callas, J., Donnerhacke, L., Finney, H., Shaw, D., and R. Thayer, “OpenPGP Message Format”, RFC 4880, November 2007. |
[RFC5322] | Resnick, P., Ed., “Internet Message Format”, RFC 5322, October 2008. |
[WebofTrust] | Network Associates, Inc. and its Affiliated Companies, “How PGP works, in Introduction to Cryptography”, 1999, <http://www.pgpi.org/doc/pgpintro/>. |
Internet Mail is split between the user world, in the form of Mail User Agents (MUA), and the transmission world, in the form of the Mail Handling Service (MHS) composed of Mail Transfer Agents (MTA). The MHS is responsible for accepting a message from one user, the author, and delivering it to one or more other users, the recipients. This creates a virtual MUA-to-MUA exchange environment. The first component of the MHS is called the Mail Submission Agent (MSA) and the last is called the Mail Delivery Agent (MDA).
An email Mediator is both an inbound MDA and outbound MSA. It takes delivery of a message, makes changes appropriate to its service, and then reposts it for further distribution. Typically, the new message will retain the original rfc5322.From: header field. A mailing list is a common example of a Mediator.
The modern Internet Mail service is marked by many independent operators, many different components for providing users with service and many other components for performing message transfer. Consequently, it is necessary to distinguish administrative boundaries that surround sets of functional components, which are subject to coherent operational policies.
As elaborated on below, every MSA is a candidate for signing using DKIM, and every MDA is a candidate for doing DKIM verification.
Operation of Internet Mail services is apportioned to different providers (or operators). Each can be composed of an independent ADministrative Management Domain (ADMD). An ADMD operates with an independent set of policies and interacts with other ADMDs according to differing types and amounts of trust. Examples include an end user operating a desktop client that connects to an independent email service, a department operating a submission agent or a local Relay, an organization's IT group that operates enterprise Relays, and an ISP operating a public shared email service.
Each of these can be configured into many combinations of administrative and operational relationships, with each ADMD potentially having a complex arrangement of functional components. Figure 2 depicts the relationships among ADMDs. Perhaps the most salient aspect of an ADMD is the differential trust that determines its policies for activities within the ADMD, versus those involving interactions with other ADMDs.
Basic types of ADMDs include:
Note that Transit services are quite different from packet-level transit operation. Whereas end-to-end packet transfers usually go through intermediate routers, email exchange across the open Internet often is directly between the Edge ADMDs, at the email level.
+--------+ +--------+ +--------+ | ADMD#1 | | ADMD#3 | | ADMD#4 | | ------ | | ------ | | ------ | | | +----------------------->| | | | | User | | |--Edge--+--->|--User | | | | | +--->| | | | | V | | | +--------+ +--------+ | Edge---+---+ | | | | +----------+ | +--------+ | | ADMD#2 | | | | ------ | | | | | | +--->|-Transit--+---+ | | +----------+
Figure 2: ADministrative Management Domains (ADMD) Example
In Figure 2, ADMD numbers 1 and 2 are candidates for doing DKIM signing, and ADMD numbers 2, 3, and 4 are candidates for doing DKIM verification.
The distinction between Transit network and Edge network transfer services is primarily significant because it highlights the need for concern over interaction and protection between independent administrations. The interactions between functional components within a single ADMD are subject to the policies of that domain. Although any pair of ADMDs can arrange for whatever policies they wish, Internet Mail is designed to permit inter-operation without prior arrangement.
Common ADMD examples are: