Domain-based Message Authentication, Reporting and Conformance
(DMARC) superuser@gmail.comYahoo!zwicky@yahoo-inc.com
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Network Working GroupdomainemailsecuritymessagingdkimspfauthenticationreportingconformanceDomain-based Message Authentication, Reporting and Conformance (DMARC) is a scalable mechanism by which a mail-originating
organization can express domain-level policies and
preferences for message validation, disposition, and reporting, that a mail receiving
organization can use to improve mail handling. Originators of Internet Mail need to be able to associate reliable
and authenticated domain identifiers with messages, communicate policies
about messages that use those identifiers, and report about mail using
those identifiers. These abilities have several benefits: Receivers can provide
feedback to domain owners about the use of their domains, which can
provide valuable insight about the management of internal operations and
the presence of external domain name abuse.
DMARC does not produce or encourage elevated
delivery privilege of authenticated email. DMARC is a mechanism for
policy distribution that enables increasingly strict handling of
messages that fail authentication checks, ranging from no action, through altered
delivery, up to message rejection. The Sender Policy Framework
() and DomainKeys Identified Mail
() provide domain-level authentication.
They enable cooperating email receivers to detect mail
authorized to use the domain name, which can permit differential
handling.
(A detailed discussion of the threats these systems attempt
to address can be found in .) However, there has been no single widely accepted or
publicly available mechanism to communication of domain-specific message handling policiies for receivers,
or to request reporting of authentication and disposition of received
mail. Absent the ability to obtain feedback reports, originators who have implemented email authentication have
difficulty determining how effective their authentication is. As a consequence,
use of authentication failures to filter mail typically does not succeed. Over time, one-on-one relationships were established between select senders and
receivers with privately communicated means to assert policy and receive message
traffic and authentication disposition reporting. Although these ad hoc practices
have been generally successful, they require significant manual coordination between
parties, and this model does not scale for general use on the Internet.This document defines Domain-based Message Authentication, Reporting and Compliance
(DMARC), a mechanism by which email operators leverage existing authentication and
policy advertisement technologies to enable both message-stream feedback and
enforcement of policies against unauthenticated email.DMARC allows domain owners and receivers to collaborate by: Providing receivers with assertions about domain owners' policiesProviding feedback to senders so they can monitor authentication and judge
threatsThe basic outline of DMARC is:
Domain owners publish policy assertions about domains via the DNS.Receivers compare the RFC5322 From: address in the mail to the SPF and
DKIM results, if present, and the DMARC policy in DNS. These receivers can use these results to determine how the mail should be
handled.The receiver sends reports to the domain owner or its designee about mail claiming to be
from their domain.Security terms used in this document are defined in . DMARC differs from previous approaches to policy advertisement (e.g., and ) in that:
Authentication technologies are:
decoupled from any technology-specific policy mechanisms; andused solely to establish reliable per-message domain-level
identifiers.Multiple authentication technologies are used to:
reduce the impact of transient authentication errorsreduce the impact of site-specific configuration errors and
deployment gapsenable more use cases than any individual technology supports
aloneReceiver-generated feedback is supported, allowing senders to establish
confidence in authentication practices.The domain name extracted from a message's RFC5322.From field is the primary
identifier in the DMARC mechanism. This identifier is used in conjunction
with the results of the underlying authentication technologies to evaluate
results under DMARC.Specification of DMARC is guided by the following high-level goals, security
dependencies, detailed requirements, and items that are documented as
out-of-scope. DMARC has the following high-level goals:
Allow Domain Owners to assert the preferred handling of authentication failures,
for messages purporting to have authorship within the domain. Allow Domain Owners to verify their authentication deployment.Minimize implementation complexity for both senders and receivers, as well as the impact on handling and delivery of legitimate messages.Reduce the amount of successfully delivered spoofed email.Work at Internet scale.Several topics and issues are specifically out of scope for the initial version of this work. This includes the following:
different treatment of messages that are not authenticated versus those that fail authentication; evaluation of anything other than RFC5322.From; multiple reporting formats; publishing policy other than via the DNS; reporting or otherwise evaluating other than the last-hop IP address; attacks in the RFC5322.From field, also known as "display-name" attacks; authentication of entities other than domains, since DMARC is built upon SPF and DKIM which authenticate domains; and content analysis. Scalability is a major issue for systems that need to operate in a system as
widely deployed as current SMTP email. For this reason, DMARC seeks to avoid the
need for third parties or pre-sending agreements between senders and
receivers. This preserves the positive aspects of the current email
infrastructure. Although DMARC does not introduce third parties to the email
handling flow, it also does not preclude them. Third parties
are free to provide services in conjunction with DMARC. DMARC is designed to prevent bad actors from sending mail that claims to come
from legitimate senders, particularly senders of transactional email
(official mail that is about business transactions). One of the
primary uses of this kind of spoofed mail is phishing (enticing users to provide
information by pretending to be the legitimate service requesting the information).
Thus, DMARC is significantly informed by ongoing efforts to enact large-scale,
Internet-wide, anti-phishing measures. Although DMARC can only be used to combat specific forms of exact-domain spoofing
directly, the DMARC mechanism has been found to be useful in the creation of
reliable and defensible message streams.DMARC does not attempt to solve all problems with spoofed or otherwise fraudulent email. In particular, it
does not address the use of visually similar domain names ("cousin domains") or
abuse of the RFC5322.From human readable
<display-name>.This section defines terms used in the rest of the document.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 .Readers are encouraged to be familiar with
the contents of . In particular, that document defines
various roles in the messaging infrastructure that can appear the same or separate
in various contexts. For example, a Domain Owner could, via the messaging security
mechanisms on which DMARC is based, delegate the ability to send mail as the Domain
Owner to a third party with another role. This document does not address the distinctions among such
roles; the reader is encouraged to become familiar with that material before
continuing. The following terms are also used: Domain-level identifiers that are
validated using authentication technologies are referred to as
"Authenticated Identifiers". See for details
about the supported mechanisms. The domain name of the apparent author,
as extracted from the RFC5322.From field. An entity or organization that owns a DNS domain.
The term "owns" here indicates that the entity or organization being
referenced holds the registration of that DNS domain.
Domain Owners range from complex, globally-distributed organizations, to
service providers working on behalf of non-technical clients, to individuals
responsible for maintaining personal domains. This specification uses this
term as analogous to an Administrative Management Domain as defined in . It can also refer to delegates, such as
Report Receivers, when those are outside of their immediate
management domain. When the domain in the RFC5322.From address
matches a domain validated by SPF or DKIM (or both), it has Identifier Alignment. The entity or organization that receives and
processes email. Mail Receivers operate one or more Internet-facing Mail
Transport Agents (MTAs). The domain that was registered with a domain name
registrar. In the absence of more accurate methods, heuristics are used to
determine this, since it is not always the case that the registered domain
name is simply a top-level DNS domain plus one component (e.g.,
"example.com", where "com" is a top-level domain). The Organizational Domain
is determined by applying the algorithm found in . An operator that receives reports from another operator
implementing the reporting mechanism described in this document.
Such an operator might be receiving reports about its own messages,
or reports about the messages claiming to be from a third party.
This term applies collectively to the system components that
receive and process these reports and the organizations that
operate them. This section provides a general overview of the design and operation
of the DMARC environment. The following mechanisms for determining Authenticated Identifiers are supported
in this version of DMARC:
, which provides a domain-level identifier in the
content of the "d=" tag of a validated DKIM-Signature header field. , which authenticates the domain found in an
MAIL command when it is the authorized domain. DMARC policies are published by the Domain Owner, and retrieved by the Mail Receiver during the SMTP session, via the DNS. DMARC's filtering function is based on whether SPF or DKIM can provide an authenticated,
aligned identifier for the message under consideration. Messages
that purport to be from a Domain Owner's domain and arrive from servers that are
not authorized by that domain's SPF record and do not contain an appropriate DKIM signature can be
affected by DMARC policies. It is important to note that the authentication mechanisms
employed by DMARC authenticate only a DNS domain, and do
not authenticate the local-part of any email address
identifier found in a message, nor does it validate
the legitimacy of message content. DMARC's feedback component involves the collection of information about received
messages claiming to be from the Organizational Domain for periodic aggregate reports to
the Domain Owner. The parameters and format for such reports are discussed in
later sections of this document.A DMARC-enabled Mail Receiver might also generate per-message reports that
contain information related to individual messages that fail SPF and/or DKIM.
Per-message failure reports are a useful source of information when debugging deployments
(if messages can be determined to be legitimate even though failing
authentication) or in analyzing attacks. The capability for such services is
enabled by DMARC but defined in other referenced material such
as .A message satisfies the DMARC checks if at least one of the supported
authentication mechanisms:
produces a "pass" result; and produces that result based on an identifier that is
in alignment, as defined in
. The above diagram shows a simple flow of messages through a DMARC-aware
system. Solid lines denote the actual message flow, dotted lines
involve Domain Name System queries used to retrieve message policy
related to the supported message authentication schemes, and asterisk
lines indicate data exchange between message handling modules
and message authentication modules. "sMTA" is the sending MTA, and
"rMTA" is the receiving MTA. In essence the steps are as follows:
Domain Owner constructs an SPF policy and publishes it in its
DNS database as per . Domain Owner also
configures its system for DKIM signing as described
in . Finally, Domain Owner publishes via
the DNS a DMARC message handling policy. Author generates a message and hands the message to Domain Owner's
designated mail submission service. Submission service passes relevant details to the DKIM
signing module in order to generate a DKIM signature to be
applied to the message. Submission service relays the now-signed message to
its designated transport service for routing to its
intended recipient(s). Message may pass through other relays, but eventually
arrives at a recipient's transport service. Recipient delivery service conducts SPF and DKIM
authentication checks by passing the necessary data to
their respective modules, each of which require queries
to the Author Domain's DNS data (when identifiers are
aligned; see below). The results of these are passed to the DMARC module
along with the Author's domain. The DMARC module attempts to
retrieve a policy from the DNS for that domain. If none is
found, the DMARC module determines the Organizational Domain
and repeats the attempt to retrieve a policy from the DNS. (This
is described in further detail in
.) If a policy is found, it is combined with the Author's domain
and the SPF and DKIM results to produce a DMARC policy result
(a "pass" or "fail"), and can optionally cause one of two kinds of
reports to be generated (not shown). Recipient transport service either delivers the message
to the recipient inbox, or takes other local policy action
based on the DMARC result (not shown). Email authentication technologies authenticate various (and disparate) aspects of
an individual message. For example, authenticates the
domain that affixed a signature to the message, while
authenticates either the domain that appears in the RFC5321.MailFrom portion of
or the RFC5321.EHLO/HELO domain if the
RFC5321.MailFrom is null (in the case of Delivery Status Notifications). These
may be different domains, and they are typically not visible
to the end user.DMARC uses the RFC5322.From domain to evaluate the
applicability of Authenticated Identifiers. The RFC5322.From domain was selected as the central identity of the
DMARC mechanism because it is a required message header field and therefore guaranteed to be
present in compliant messages, and most MUAs represent the RFC5322.From field as the originator of the message and render some
or all of this header field's content to end users. Thus, this field is the one used by end users to identify the source
of the message, and therefore is a prime target for abuse.
Many high-profile email sources, such as email service providers,
require that the sending agent have authenticated before email
can be generated. Thus, for these mailboxes, the mechanism described
in this document provides recipient end users with strong evidence
that the message was indeed originated by the agent they
associate with that mailbox, if the end user knows that these various
protections have been provided. Domain names in this context are to be compared in a case-insensitive manner, per
. It is important to note that identifier alignment cannot occur with a message that
is not valid per , particularly one with a malformed, absent, or
repeated RFC5322.From field, since in that case there is no reliable way to determine
a DMARC policy that applies to the message. Accordingly, DMARC operation
is predicated on the input being a valid RFC5322 message object, and handling
of such non-compliant cases is outside of the scope of this specification.
Further discussion of this can be found in . Each of the underlying authentication technologies that DMARC takes as input
yield authenticated domains as their outputs when they succeed. From the perspective
of DMARC, each
can be operated in a "strict" mode or a "relaxed" mode. A Domain Owner
would normally select "strict" mode if it wanted Mail Receivers
to apply DMARC processing only to messages bearing an RFC5322.From domain exactly matching
the domains those mechanisms will verify. Using "relaxed" mode
can be used when the operator also wishes to affect message flows bearing
subdomains of the verified domains. DMARC provides the option of applying DKIM in a strict or relaxed
identifier alignment mode. (Note that these are not related to DKIM's "simple" and "relaxed"
canonicalization modes.) In relaxed mode, the Organizational Domains of both the -authenticated signing domain (taken from the value of the "d=" tag in
the signature) and that of the RFC5322.From domain must be equal if the identifiers
are to be considered aligned. In strict
mode, only an exact match between both of the Fully Qualified Domain Names (FQDN) is considered to produce identifier alignment. To illustrate, in relaxed mode, if a validated DKIM signature successfully
verifies with a "d=" domain of "example.com", and the RFC5322.From address is
"alerts@news.example.com", the DKIM "d=" domain and the RFC5322.From domain
are considered to be "in alignment". In strict mode, this test would
fail since the "d=" domain does not exactly match the FQDN of the address.However, a DKIM signature bearing a value of "d=com" would never allow an "in
alignment" result as "com" should appear on all public suffix lists (see ), and
therefore cannot be an Organizational Domain.Identifier alignment is required because a message can bear a valid
signature from any domain, including domains used by a mailing
list or even a bad actor. Therefore, merely bearing a valid signature
is not enough to infer authenticity of the Author Domain. Note that a single email can contain multiple DKIM signatures, and it is
considered to be a DMARC "pass" if any DKIM signature is aligned and
verifies. DMARC provides the option of applying SPF in a strict or relaxed identifier alignment mode. In relaxed mode, the -authenticated domain and
RFC5322.From domain must have the same Organizational Domain. In strict
mode, only an exact DNS domain match is considered to produce identifier
alignment.For example, if a message passes an SPF check with an RFC5321.MailFrom domain
of "cbg.bounces.example.com", and the address portion of the RFC5322.From
field contains "payments@example.com", the Authenticated RFC5321.MailFrom
domain identifier and the RFC5322.From domain are considered to be "in
alignment" in relaxed mode, but not in strict mode. If in the future DMARC is extended to include the use of other authentication mechanisms,
the extensions will need to allow for domain identifier extraction so that
alignment with the RFC5322.From domain can be verified. The Organizational Domain is determined using the following algorithm: Acquire a "public suffix" list, i.e., a list of DNS domain names
reserved for registrations. Some country TLDs make specific
registration requirements, e.g. the United Kingdom places company
registrations under ".co.uk"; other TLDs such as ".com" appear in
the IANA registry of top-level DNS domains. A public suffix list is
the union of all of these. contains some
discussion about obtaining a public suffix list. Break the subject DNS domain name into a set of "n" ordered labels.
Number these labels from right-to-left; e.g. for "example.com",
"com" would be label 1 and "example" would be label 2. Search the public suffix list for the name that matches the largest
number of labels found in the subject DNS domain. Let that number be
"x". Construct a new DNS domain name using the name that matched from the
public suffix list and prefixing to it the "x+1"th label from the
subject domain. This new name is the Organizational Domain. Thus, since "com" is an IANA-registered TLD, a subject domain of
"a.b.c.d.example.com" would have an Organizational Domain of
"example.com". The process of determining a suffix is currently a heuristic one. No list is
guaranteed to be accurate or current. One of the most obvious points of security scrutiny for DMARC is the choice to
focus on an identifier, namely the RFC5322.From address, which is part of a body of data that has been
trivially forged throughout the history of email. Several points suggest it is the most correct and safest thing to do in this
context: Of all the identifiers that are part of the message itself, this is the
only one guaranteed to be present. It seems the best choice of an identifier on which to focus as most MUAs
display some or all of the contents of that field in
a manner strongly suggesting those data as reflective of the true
originator of the message. The absence of a single, properly-formed RFC5322.From field renders the message
invalid. Handling of such a message is outside of the scope of this specification. Since the sorts of mail typically protected by DMARC participants
tend to only have single Authors, DMARC participants generally operate under a slightly restricted profile
of RFC5322 with respect to the expected syntax of this field.
See for details. DMARC policies are published by Domain Owners and applied by Mail Receivers. A Domain Owner advertises DMARC participation of one or more of its domains by adding a DNS TXT record (described
in ) to those domains. In doing so, Domain
Owners make specific requests of Mail Receivers regarding the disposition of
messages purporting to be from one of the Domain Owner's domains and the provision
of feedback about those messages. A Domain Owner may choose not to participate in DMARC evaluation by Mail
Receivers. In this case, the Domain Owner simply declines to advertise participation
in those schemes. For example, if the results of path authorization
checks ought not be considered as part of the overall DMARC result for
a given Author Domain, then the Domain Owner does not publish an
SPF policy record that can produce an SPF pass result. A Mail Receiver implementing the DMARC mechanism SHOULD make a best-effort attempt to
adhere to the Domain Owner's published DMARC policy when a message fails the DMARC
test. Since email streams can be complicated (due to forwarding, existing
RFC5322.From domain-spoofing services, etc.), Mail Receivers MAY deviate from a
Domain Owner's published policy during message processing and SHOULD make available
the fact of and reason for the deviation to the Domain Owner via feedback reporting,
specifically using the "PolicyOverride" feature of the aggregate
report (see ).
Domain Owner DMARC preferences are stored as DNS TXT records in subdomains named
"_dmarc". For example, the Domain Owner of "example.com" would post DMARC
preferences in a TXT record at "_dmarc.example.com". Similarly, a Mail Receiver
wishing to query for DMARC preferences regarding mail with an RFC5322.From domain of
"example.com" would issue a TXT query to the DNS for the subdomain of
"_dmarc.example.com". The DNS-located DMARC preference data will hereafter be called
the "DMARC record". DMARC's use of the Domain Name Service is driven
by DMARC's use of domain names and the nature of the query it performs. The
query requirement matches with the DNS, for obtaining simple
parametric information. It uses an established method of storing the
information, associated with the target domain name, namely an isolated TXT
record that is restricted to the DMARC context. Use of the DNS as the query
service has the benefit of re-using an extremely
well-established operations, administration and management infrastructure,
rather than creating a new one. Per , a TXT record can comprise several "character-string"
objects. Where this is the case, the module performing DMARC evaluation MUST
concatenate these strings by joining together the objects in order and parsing the
result as a single string. defines a generic syntax for identifying a resource. The
DMARC mechanism uses this as the format by which a Domain Owner specifies the
destination for the two report types (RUA and RUF) that are supported. The place such URIs are specified (see ) allows a
list of these to be provided. A report is normally sent to each listed URI in the order
provided by the Domain Owner.
Receivers MAY impose a limit on the number of URIs to which they will send reports, but
MUST support the ability to send to at least two. The list of URIs is separated by commas (ASCII 0x2C). Each URI can have associated with it a maximum report size that may be sent to
it. This is accomplished by appending an exclamation point (ASCII 0x21),
followed by a maximum size indication, before a separating comma or terminating
semi-colon. Thus, a DMARC URI is a URI within which any commas or exclamation points are
percent-encoded per , followed by an OPTIONAL exclamation
point and a maximum size specification, and, if there are additional reporting
URIs in the list, a comma and the next URI. For example, the URI "mailto:reports@example.com!50m" would request a report be
sent via email to "reports@example.com" so long as the report payload does not
exceed 50 megabytes. A formal definition is provided in . DMARC records follow the extensible "tag-value" syntax for DNS-based key records
defined in DKIM. creates a registry for known DMARC tags
and registers the initial set defined in this document. Only tags defined in this
document or in later extensions, and thus added to that registry, are to be
processed; unknown tags MUST be ignored. The following tags are introduced as the initial valid DMARC tags: (plain-text; OPTIONAL, default is "r".) Indicates
whether strict or relaxed DKIM identifier alignment mode is required by the
Domain Owner. See for details.
Valid values are as follows:
relaxed mode strict mode (plain-text; OPTIONAL, default is "r".) Indicates
whether strict or relaxed SPF identifier alignment mode is required by the Domain
Owner. See for details.
Valid values are as follows:
relaxed mode strict mode Failure reporting options (plain-text; OPTIONAL, default
"0") Provides requested options for generation of failure reports.
Report generators MAY choose to adhere to the requested options. This
tag's content MUST be ignored if a "ruf" tag (below) is not also
specified. The value of this tag is a colon-separated list of characters
that indicate failure reporting options as follows: Generate a DMARC failure report if all underlying
authentication mechanisms fail to produce an aligned "pass"
result. Generate a DMARC failure report if any underlying
authentication mechanism produced something other than
an aligned "pass" result. Generate a DKIM failure report if the message had
a signature that failed evaluation, regardless of its alignment.
DKIM-specific reporting is described in . Generate an SPF failure report if the message
failed SPF evaluation, regardless of its alignment. SPF-specific
reporting is described in . Requested Mail Receiver policy (plain-text; REQUIRED for
policy records). Indicates the policy to be enacted by the Receiver at
the request of the Domain Owner. Policy applies to the domain queried
and to sub-domains unless sub-domain policy is explicitly described
using the "sp" tag. This tag is mandatory for policy records only, but
not for third-party reporting records (see ).
Possible values are as follows: The Domain Owner requests no specific action be
taken regarding delivery of messages. The Domain Owner wishes to have email
that fails the DMARC mechanism check to be treated by Mail
Receivers as suspicious. Depending on the capabilities of the
Mail Receiver, this can mean "place into spam folder",
"scrutinize with additional intensity", and/or "flag as
suspicious". The Domain Owner wishes for Mail Receivers to
reject email that fails the DMARC mechanism check. Rejection
SHOULD occur during the SMTP transaction. See for some discussion of SMTP
rejection methods and their implications. (plain-text integer between 0 and 100, inclusive;
OPTIONAL; default is 100). Percentage of messages from the Domain Owner's
mail stream to which the DMARC policy is to be applied. However, this
MUST NOT be applied to the DMARC-generated reports, all of which must be
sent and received unhindered. The purpose of the "pct" tag is to allow
Domain Owners to enact a slow rollout enforcement of the DMARC
mechanism. The prospect of "all or nothing" is recognized as preventing
many organizations from experimenting with strong authentication-based
mechanisms. See for details. Note that
random selection based on this percentage, such as the following pseudocode,
is adequate:
Format to be used for message-specific failure reports
(colon-separated plain-text list of values; OPTIONAL; default "afrf").
The value of this tag is a list of one or more report formats as
requested by the Domain Owner to be used when a message fails both and tests to report details
of the individual failure. The values MUST be present in the registry of
reporting formats defined in ; a
Mail Receiver observing a different value SHOULD ignore it, or MAY
ignore the entire DMARC record. For this version, only "afrf"
(defined in ) is presently supported.
See for details. For interoperability, the AFRF
format MUST be supported. Interval requested between aggregate reports (plain-text,
32-bit unsigned integer; OPTIONAL; default 86400). Indicates a request
to Receivers to generate aggregate reports separated by no more than the
requested number of seconds. DMARC implementations MUST be able to
provide daily reports and SHOULD be able to provide hourly reports when
requested. However, anything other than a daily report is understood to
be accommodated on a best-effort basis. Addresses to which aggregate feedback is to be sent
(comma-separated plain-text list of DMARC URIs; OPTIONAL). A comma or
exclamation point that is part of such a DMARC URI MUST be encoded per
Section 2.1 of so as to distinguish it from the
list delimiter or an OPTIONAL size limit.
discusses considerations that apply when the domain name of a URI
differs from that of the domain advertising the policy. See for additional considerations. Any valid
URI can be specified. A Mail Receiver MUST implement support for a
"mailto:" URI, i.e. the ability to send a DMARC report via electronic
mail. If not provided, Mail Receivers MUST NOT generate aggregate
feedback reports. URIs not supported by Mail Receivers MUST be ignored.
The aggregate feedback report format is described in . Addresses to which message-specific failure information
is to be reported (comma-separated plain-text list of DMARC URIs;
OPTIONAL). If present, the Domain Owner is requesting Mail Receivers to
send detailed failure reports about messages that fail the DMARC
evaluation in specific ways (see the "fo" tag above). The format of the
message to be generated MUST follow that specified in the "rf" tag.
discusses considerations that apply when
the domain name of a URI differs from that of the domain advertising the
policy. A Mail Receiver MUST implement support for a "mailto:" URI, i.e.
the ability to send a DMARC report via electronic mail. If not provided,
Mail Receivers MUST NOT generate failure reports. See for additional considerations. Requested Mail Receiver policy for all subdomains
(plain-text; OPTIONAL). Indicates the policy to be enacted by the
Receiver at the request of the Domain Owner. It applies only to
subdomains of the domain queried and not to the domain itself. Its
syntax is identical to that of the "p" tag defined above. If absent, the
policy specified by the "p" tag MUST be applied for subdomains. Note that
"sp" will be ignored for DMARC records published on sub-domains of
Organizational Domains due to the effect of the DMARC Policy Discovery mechanism
described in . Version (plain-text; REQUIRED). Identifies the record
retrieved as a DMARC record. It MUST have the value of "DMARC1". The
value of this tag MUST match precisely; if it does not or it is absent,
the entire retrieved record MUST be ignored. It MUST be the first tag in
the list. A DMARC policy record MUST comply with the formal specification found in in that the "v" and "p" tags MUST be present and MUST
appear in that order. Unknown tags MUST be ignored. Syntax errors in the
remainder of the record SHOULD be discarded in favor of default values (if any)
or ignored outright. Note that given the rules of the previous paragraph, addition of a new tag into
the registered list of tags does not itself require a new version of DMARC to be
generated (with a corresponding change to the "v" tag's value), but a change to
any existing tags does require a new version of DMARC. The formal definition of the DMARC format using is as
follows: "Keyword" is imported from Section 4.1.2 of
. A size limitation in a dmarc-uri, if provided, is interpreted as a count of
units followed by an OPTIONAL unit size ("k" for kilobytes, "m" for megabytes,
"g" for gigabytes, "t" for terabytes). Without a unit, the number is presumed to
be a basic byte count. Note that the units are considered to be powers of two; a
kilobyte is 2^10, a megabyte is 2^20, etc. To implement the DMARC mechanism, the only action required of a Domain Owner is the
creation of the DMARC policy record in the DNS. However, in order to make meaningful
use of DMARC, a Domain Owner must at minimum either establish an address to receive
reports, or deploy authentication technologies and ensure identifier alignment. Most Domain Owners will want to do both. DMARC reports will be of significant size and the addresses that receive them are
publicly visible, so we encourage Domain Owners to set up dedicated email addresses
to receive and process reports, and to deploy abuse countermeasures on those email addresses as
appropriate. Authentication technologies are discussed in (see also and ) and . This section describes receiver actions in the DMARC environment. The domain in the RFC5322.From field is extracted as the domain to be evaluated
by DMARC. If the domain is encoded with UTF-8, the domain name must be converted
to an A-label, as described in Section 2.3 of
, for further processing. In order to be processed by DMARC, a message typically needs
to contain exactly one RFC5322 From: domain (a single From:
field with a single domain in it). Not all messages meet
this requirement, and handling of them is outside of the
scope of this document. Typical exceptions, and they way they
have been historically handled by DMARC participants, are as
follows:
Messages with multiple RFC5322.From fields are
typically rejected since that form is
forbidden under
RFC 5322; Messages bearing a single RFC5322.From field
containing multiple addresses (and, thus, multiple
domain names to be evaluated) are typically
rejected because the sorts of mail normally
protected by DMARC do not use this format; Messages that have no RFC5322.From field at all
are typically rejected since that form is
forbidden under
RFC 5322; Messages with an RFC5322.From field that contains
no meaningful domains, such as
RFC 5322's
"group" syntax are typically ignored. The case of a syntactically valid multi-valued
RFC5322.From field presents a particular challenge.
The process in this case is to apply the DMARC check using
each of those domains found in the RFC5322.From field as the
Author Domain, and apply the most strict policy selected
among the checks that fail. To arrive at a policy for an individual message, Mail Receivers MUST
perform the following actions or their semantic equivalents. Steps 2-4 MAY be
done in parallel, whereas steps 5 and 6 require input from previous steps.The steps are as follows: Extract the RFC5322.From domain from the message (as above). Query the DNS for a DMARC policy record. Continue if one is found, or
terminate DMARC evaluation otherwise. See
for details. Perform DKIM signature verification checks. A single email could contain
multiple DKIM signatures. The results of this step are passed to the
remainder of the algorithm and MUST include the value of the "d=" tag
from each checked DKIM signature. Perform SPF validation checks. The results of this step are passed to
the remainder of the algorithm and MUST include the domain name used to
complete the SPF check. Conduct identifier alignment checks. With authentication checks and
policy discovery performed, the Mail Receiver checks if Authenticated
Identifiers fall into alignment as described in . If one or more of the Authenticated
Identifiers align with the RFC5322.From domain, the message is
considered to pass the DMARC mechanism check. All other conditions
(authentication failures, identifier mismatches) are considered to be
DMARC mechanism check failures. Apply policy. Emails that fail the DMARC mechanism check are disposed of
in accordance with the discovered DMARC policy of the Domain Owner. See
for details. Heuristics applied in the absence of use by a Domain Owner of either SPF or DKIM
(e.g., ) SHOULD NOT be used, as it may be the
case that the Domain Owner wishes a Message Receiver not to consider the results
of that underlying authentication protocol at all. DMARC evaluation can only complete and yield a "pass"
result when one of the underlying authentication
mechanisms passes for an aligned identifier. If this
is not the case and either or both of them suffered some
kind of temporary error (such as a transient DNS problem),
the Receiver evaluating the message is also unable to
conclude that the DMARC mechanism failed and thereby
apply the advertised DMARC policy. Rather, the Receiver
can either skip DMARC processing for this message due to
incomplete evaluation, or it can arrange to defer handling
of the message in the hope that the temporary error will
be resolved when the message is retried. When otherwise
appropriate due to DMARC policy, receivers MAY send
feedback reports regarding temporary errors. Handling of messages for which SPF and/or DKIM evaluation
encounters a permanent DNS error is left to the discretion
of the Mail Receiver. As stated above, the DMARC mechanism uses DNS TXT records to advertise policy.
Policy discovery is accomplished via a method similar to the method used for SPF
records. This method and the important differences between DMARC and SPF mechanisms
are discussed below. To balance the conflicting requirements of supporting wildcarding, allowing
subdomain policy overrides, and limiting DNS query load, the following DNS lookup
scheme is employed: Mail Receivers MUST query the DNS for a DMARC TXT record at the DNS domain
matching the one found in the RFC5322.From domain in the message. A possibly
empty set of records is returned. Records that do not start with a "v=" tag that identifies the
current version of DMARC are discarded. If the set is now empty, the Mail Receiver MUST query the DNS for a DMARC
TXT record at the DNS domain matching the Organizational Domain in place of
the RFC5322.From domain in the message (if different). This record can
contain policy to be asserted for subdomains of the Organizational Domain. A
possibly empty set of records is returned. Records that do not start with a "v=" tag that identifies the current version
of DMARC are discarded. If the remaining set contains multiple records or no records, policy discovery terminates and DMARC processing is not applied to this message. If a retrieved policy record does not contain a valid "p" tag, or contains
an "sp" tag that is not valid, then: if an "rua" tag is present and contains at least one syntactically
valid reporting URI, the Mail Receiver SHOULD act as if a record
containing a valid "v" tag and "p=none" was retrieved, and continue
processing; otherwise, the Mail Receiver applies no DMARC processing to this message. If the set produced by the mechanism above contains no DMARC policy record (i.e.,
any indication that there is no such record as opposed to a transient DNS error),
Mail Receivers SHOULD NOT apply the DMARC mechanism to the message. Handling of DNS errors when querying for the DMARC policy record is left to the
discretion of the Mail Receiver. For example, to ensure minimal disruption of mail
flow, transient errors could result in delivery of the message ("fail open"), or
they could result in the message being temporarily rejected (i.e., an SMTP 4yx
reply) which invites the sending MTA to try again after the condition has possibly
cleared, allowing a definite DMARC conclusion to be reached ("fail closed"). If the "pct" tag is present in the policy record, the Mail Receiver MUST NOT enact the
requested policy ("p" tag or "sp" tag") on more than the stated percent of the
totality of affected messages. However, regardless of whether or not the "pct"
tag is present, the Mail Receiver MUST include all relevant message data in any
reports produced. If email is subject to the DMARC policy of "quarantine", the Mail Receiver
SHOULD quarantine the message. If the email is not subject to the "quarantine"
policy (due to the "pct" tag), the Mail Receiver SHOULD apply local message
classification as normal. If email is subject to the DMARC policy of "reject", the Mail Receiver SHOULD
reject the message (see ). If the email is not
subject to the "reject" policy (due to the "pct" tag), the Mail Receiver SHOULD
treat the email as though the "quarantine" policy applies. This behavior allows
senders to experiment with progressively stronger policies without relaxing
existing policy.Mail receivers implement "pct" via statistical mechanisms that achieve a close
approximation to the requested percentage and provide a representative sample across a reporting period. The results of Mail Receiver-based DMARC processing should be stored for eventual
presentation back to the Domain Owner in the form of aggregate feedback reports.
and
discuss aggregate feedback. Mail Receivers MAY choose to reject or quarantine email even if email passes the
DMARC mechanism check. The DMARC mechanism does not inform Mail Receivers whether an
email stream is "good". Mail Receivers are encouraged to maintain anti-abuse
technologies to combat the possibility of DMARC-enabled criminal campaigns. Mail Receivers MAY choose to accept email that fails the DMARC mechanism check even
if the Domain Owner has published a "reject" policy. Mail Receivers need to make a
best effort not to increase the likelihood of accepting abusive mail if they choose
not to comply with a Domain Owner's reject, against policy. At a minimum, addition
of the Authentication-Results header field (see ) is
RECOMMENDED when delivery of failing mail is done. When this is done, the DNS domain
name thus recorded MUST be encoded as an A-label. Mail Receivers are only obligated to report reject or quarantine policy actions in
aggregate feedback reports that are due to DMARC policy. They are not required to
report reject or quarantine actions that are the result of local policy. If local
policy information is exposed, abusers can gain insight into the effectiveness and
delivery rates of spam campaigns. Final disposition of a message is always a matter of local policy.
An operator that wishes to favor DMARC policy over SPF policy, for example,
will disregard the SPF policy since enacting an SPF-determined rejection
prevents evaluation of DKIM; DKIM might otherwise pass, satisfying the DMARC
evaluation. There is a trade-off to doing so, namely acceptance and processing
of the entire message body in exchange for the enhanced protection DMARC
provides. DMARC-compliant Mail Receivers typically disregard any mail handling directive discovered as
part of an authentication mechanism (e.g., ADSP, SPF) where a DMARC record is also
discovered that specifies a policy other than "none". Deviating from this practice
introduces inconsistency among DMARC operators in terms of handling of the message. However, such deviation is not
proscribed. To enable Domain Owners to
receive DMARC feedback without impacting existing mail processing, discovered
policies of "p=none" SHOULD NOT modify existing mail disposition processing. Mail Receivers SHOULD also implement reporting instructions of DMARC in place of any
extensions to SPF or DKIM that might enable such reporting. Providing Domain Owners with visibility into how Mail Receivers implement and
enforce the DMARC mechanism in the form of feedback is critical to establishing and
maintaining accurate authentication deployments. When Domain Owners can see what
effect their policies and practices are having, they are better willing and able to
use quarantine and reject policies. It is possible to specify destinations for the different reports that are
outside the authority of the Domain Owner making the request. This allows domains that do
not operate mail servers to request reports and have them go someplace that is able
to receive and process them. Without checks, this would allow a bad actor to publish a DMARC policy record
that requests reports be sent to a victim address, and then send a large volume
of mail that will fail both DKIM and SPF checks to a wide variety of
destinations, which will in turn flood the victim with unwanted reports.
Therefore, a verification mechanism is included. When a Mail Receiver discovers a DMARC policy in the DNS, and the Organizational
Domain at which that record was discovered is not identical to the Organizational
Domain of the host part of the authority component of a
specified in the "rua" or "ruf" tag, the following verification steps are to be
taken:
Extract the host portion of the authority component of the URI. Call
this the "destination host", as it refers to a Report Receiver. Prepend the string "_report._dmarc". Prepend the domain name from which the policy was retrieved, after
conversion to an A-label if needed. Query the DNS for a TXT record at the constructed name. If the result of
this request is a temporary DNS error of some kind (e.g., a timeout),
the Mail Receiver MAY elect to temporarily fail the delivery so the
verification test can be repeated later. For each record returned, parse the result as a series of "tag=value"
pairs, i.e., the same overall format as the policy record (see ). In particular, the "v=DMARC1" tag is
mandatory and MUST appear first in the list. Discard any that do not
pass this test. If the result includes no TXT resource records that pass basic parsing,
a positive determination of the external reporting relationship cannot
be made; stop. If at least one TXT resource record remains in the set after parsing,
then the external reporting arrangement was authorized by the
Report Receiver. If a "rua" or "ruf" tag is thus discovered, replace the corresponding
value extracted from the domain's DMARC policy record with the one found
in this record. This permits the Report Receiver to override the report
destination. However, to prevent loops or indirect abuse, the overriding
URI MUST use the same destination host from the first step. For example, if a DMARC policy query for "blue.example.com" contained
"rua=mailto:reports@red.example.net", the host extracted from the latter
("red.example.net") does not match "blue.example.com", so this procedure is
enacted. A TXT query for "blue.example.com._report._dmarc.red.example.net" is
issued. If a single reply comes back containing a tag of "v=DMARC1", then the
relationship between the two is confirmed. Moreover, "red.example.net" has the
opportunity to override the report destination requested by "blue.example.com"
if needed. Where the above algorithm fails to confirm that the external reporting was
authorized by the Report Receiver, the URI MUST be ignored by the Mail
Receiver generating the report. Further, if the confirming record includes a URI
whose host is again different than the domain publishing that override, the Mail
Receiver generating the report MUST NOT generate a report to either the original
or the override URI. A Report Receiver publishes such a record in its DNS if it wishes to receive
reports for other domains. A Report Receiver that is willing to receive
reports for any domain can use a wildcard DNS record.
For example, a TXT resource record at "*._report._dmarc.example.com"
containing at least "v=DMARC1" confirms that example.com is willing to receive
DMARC reports for any domain. If the Report Receiver is overcome by volume, it can simply remove
the confirming DNS record. However, due to positive caching, the change could
take as long as the time-to-live on the record to go into effect. A Mail Receiver might decide not to enact this procedure if, for example, it
relies on a local list of domains for which external reporting addresses are
permitted. The DMARC aggregate feedback report is designed to provide Domain Owners with precise insight into: authentication resultscorrective action that needs to be taken by Domain Owners, andthe effect of Domain Owner DMARC policy on email streams processed by Mail
Receivers.Aggregate DMARC feedback provides visibility into real-world email streams that
Domain Owners need to make informed decisions regarding the publication of DMARC
policy. When Domain Owners know what legitimate mail they are sending, what the
authentication results are on that mail, and what forged mail receivers are getting,
they can make better decisions about the policies they need and the steps they need
to take to enable those policies. When Domain Owners set policies appropriately and
understand their effects, Mail Receivers can act on them confidently. Visibility comes in the form of daily (or more frequent) Mail
Receiver-originated feedback reports that contain aggregate data on message
streams relevant to the Domain Owner. This information includes data about
messages that passed DMARC authentication as well as those that did not. The format for these reports is defined in . The report SHOULD include the following data: The DMARC policy discovered and applied, if any The selected message disposition The identifier evaluated by SPF and the SPF result,
if any The identifier evaluated by DKIM and the DKIM result,
if any For both DKIM and SPF, in indication of whether the
identifier was in alignment Data for each sender subdomain separately from mail from the sender's
organizational domain, even if there is no explicit subdomain policy. Sending and receiving domains The policy requested by the Domain Owner and the policy actually applied
(if different) The number of successful authentications The counts of messages based on all messages received even if their
delivery is ultimately blocked by other filtering agents Note that Domain Owners or their agents may change the published DMARC policy
for a domain or subdomain at any time. From a Mail Receiver's perspective this
will occur during a reporting period and may be noticed during that period, at
the end of that period when reports are generated, or during a subsequent
reporting period, all depending on the Mail Receiver's implementation. Under
these conditions it is possible that a Mail Receiver could do any of the
following: generate a single aggregate report for such a reporting period that
includes message dispositions based on the old policy, or a mix of the
two policies, even though the report only contains a single
"policy_published" element; generate multiple reports for the same period, one for each published
policy occurring during the reporting period; generate a report whose end time occurs when the updated policy was
detected, regardless of any requested report interval. Such policy changes are expected to be infrequent for any given domain, whereas
more stringent policy monitoring requirements on the Mail Receiver would produce
a very large burden at Internet scale. Therefore it is the responsibility of
report consumers and Domain Owners to be aware of this situation and allow for
such mixed reports during the propagation of the new policy to Mail Receivers. Aggregate reports are most useful when they all cover a common time period. By
contrast, correlation of these reports from multiple generators when they cover
incongruent time periods is difficult or impossible. Report generators SHOULD,
wherever possible, adhere to hour boundaries for the reporting period they are
using. For example, starting a per-day report at 00:00; starting per-hour
reports at 00:00, 01:00, 02:00; et cetera. Report Generators using a 24-hour
report period are strongly encouraged to begin that period at 00:00 UTC,
regardless of local timezone or time of report production, in order to
facilitate correlation. A Mail Receiver discovers reporting requests when it looks up a DMARC policy
record that corresponds to a RFC5322 From: domain on received mail. The
presence of the "rua" tag specifies where to send feedback. Where the URI specified in an "rua" tag does not specify otherwise, a Mail
Receiver generating a feedback report SHOULD employ a secure transport
mechanism.The Mail Receiver, after preparing a report, MUST evaluate the provided reporting
URIs in the order given. Any reporting URI that includes a size limitation
exceeded by the generated report (after compression and after any encoding
required by the particular transport mechanism) MUST NOT be used. An attempt
MUST be made to deliver an aggregate report to every remaining URI, up to the
receiver's limits on supported URIs. If transport is not possible because the services advertised by the published
URIs are not able to accept reports (e.g., the URI refers to a service that is
unreachable, or all provided URIs specify size limits exceeded by the generated
record), the Mail Receiver SHOULD send a short report (see ) indicating that a report is available but could
not be sent. The Mail Receiver MAY cache that data and try again later, or MAY
discard data that could not be sent. The message generated by the Mail Receiver MUST be a
formatted message. The aggregate report itself MUST
be included in one of the parts of the message. A human-readable portion MAY
be included as a MIME part (such as a text/plain part). The aggregate data MUST be an XML file that SHOULD be subjected to GZIP compression. Declining
to apply compression can cause the report to be too large for a receiver to process
(a commonly-observed receiver limit is ten megabytes);
doing the compression increases the chances of acceptance of the report at some compute cost. The
aggregate data SHOULD be present using the media type "application/gzip" if
compressed (see ), and "text/xml" otherwise.
The filename is typically constructed using the following ABNF:
The extension MUST be "xml" for a plain XML file,
or "xml.gz" for an XML file compressed using GZIP. "unique-id" allows an optional unique ID generated by the Mail Receiver to
distinguish among multiple reports generated simultaneously by different
sources within the same Domain Owner. For example, this is a possible filename for the gzip file of a report to the
Domain Owner "example.com" from the Mail Receiver
"mail.receiver.example".
No specific MIME message structure is required. It is presumed that the
aggregate reporting address will be equipped to extract MIME parts with the
prescribed media type and filename and ignore the rest. Email streams carrying DMARC feedback data MUST conform to the DMARC
mechanism, thereby resulting in an aligned "pass" (see ). This practice minimizes the risk of
report consumers processing fraudulent reports. The RFC5322.Subject field for individual report submissions SHOULD conform to
the following ABNF:
The first domain-name indicates the DNS domain name about which the report
was generated. The second domain-name indicates the DNS domain name
representing the Mail Receiver generating the report. The purpose of the
Report-ID: portion of the field is to enable the Domain Owner to identify
and ignore duplicate reports that might be sent by a Mail Receiver. For instance, this is a possible Subject field for a report to the Domain
Owner "example.com" from the Mail Receiver
"mail.receiver.example". It is line-wrapped as allowed by
. This transport mechanism potentially encounters a problem when feedback data
size exceeds maximum allowable attachment sizes for either the generator or
the consumer. See for further discussion.
The specification as written allows for the addition of
other registered URI schemes to be supported in later
versions.
When a Mail Receiver is unable to complete delivery of a report via any of
the URIs listed by the Domain Owner, the Mail Receiver SHOULD generate an
error message. An attempt MUST be made to send this report to all listed
"mailto" URIs and it MAY also be sent to any or all other listed
URIs. The error report MUST be formatted per . A text/plain
part MUST be included that contains field-value pairs such as those found in
Section 2 of . The fields required, which may appear in
any order, are: A -formatted date
expression indicating when the transport failure occurred. The domain-name about which the failed
report was generated. The Report-ID: that the report tried to use. The size, in bytes, of the report that was
unable to be sent. This MUST represent the number of bytes that the
Mail Receiver attempted to send. Where more than one transport
system was attempted, the sizes may be different; in such cases,
separate error reports MUST be generated so that this value matches
the actual attempt that was made. The domain-name representing the Mail Receiver
that generated, but was unable to submit, the report. The URI(s) to which the Mail Receiver
tried, but failed, to submit the report. An additional text/plain part MAY be included that gives a human-readable
explanation of the above, and MAY also include a URI that can be used to
seek assistance. Failure reports are normally generated and sent almost
immediately after the Mail Receiver detects a
DMARC failure. Rather than waiting for an
aggregate report, these reports are useful for quickly
notifying the Domain Owners when there is an
authentication failure. Whether the failure is due to an
infrastructure problem or the message is inauthentic,
failure reports also provide more information about the
failed message than is available in an aggregate
report. These reports SHOULD include any URI(s) from the message
that failed authentication. These reports SHOULD include
as much of the message and message header as is reasonable
to support the Domain Owner's investigation into what
caused the message to fail authentication and track down
the sender. When a Domain Owner requests failure reports for the purpose of forensic
analysis, and the Mail Receiver is willing to provide such reports, the Mail
Receiver generates and sends a message using the format described in . This document updates the AFRF format as described in
. The format for failure reports is defined in . The destination(s) and nature of the reports are defined by the "ruf" and "fo"
tags as defined in . Where multiple URIs are selected to receive failure reports the report generator
MUST make an attempt to deliver to each of them. An obvious consideration is the denial of service attack that can be perpetrated
by an attacker who sends numerous messages purporting to be from the intended
victim Domain Owner but which fail both SPF and DKIM; this would cause
participating Mail Receivers to send failure reports to the Domain Owner or its
delegate in potentially huge volumes. Accordingly, participating Mail Receivers
are encouraged to aggregate these reports as much as is practical, using the
Incidents field of the Abuse Reporting Format (). Various
aggregation techniques are possible, including: only send a report to the first recipient of multi-recipient messages; store reports for a period of time before sending them, allowing
detection, collection, and reporting of like incidents; apply rate limiting, such as a maximum number of reports per minute that
will be generated (and the remainder discarded).
Operators implementing this specification also implement an augmented version of as follows: A DMARC failure report
includes the following ARF header fields, with the indicated
normative requirement levels: Identity-Alignment (REQUIRED; defined below) Delivery-Result (OPTIONAL) DKIM-Domain, DKIM-Identity, DKIM-Selector (REQUIRED if the
message was signed by DKIM) DKIM-Canonicalized-Header, DKIM-Canonicalized-Body (OPTIONAL
if the message was signed by DKIM) SPF-DNS (REQUIRED) The "Identity-Alignment" field is defined to
contain a comma-separated list of authentication mechanism names
that produced an aligned identity, or the keyword "none" if none
did. ABNF: Authentication Failure Type "dmarc" is defined,
which is to be used when a failure report is generated because some
or all of the authentication mechanisms failed to produce aligned
identifiers. Note that a failure report generator MAY also
independently produce an AFRF message for any or all of the
underlying authentication methods. A minimum implementation of DMARC has the following characteristics: Is able to send and/or receive reports at least daily; Is able to send and/or receive reports using "mailto" URIs; Other than in exceptional circumstances such as resource exhaustion, can
generate or accept a report up to ten megabytes in size; If acting as a Mail Receiver, fully implements the provisions of . This section discusses security issues specific to private data that may be
included in the interactions that are part of DMARC. Aggregate reports are limited in scope to DMARC policy and disposition
results, to information pertaining to the underlying authentication
mechanisms, and to the identifiers involved in DMARC validation. Failed message reporting provides message-specific details pertaining to
authentication failures. Individual reports can contain message content as
well as trace header fields. Domain Owners are able to analyze individual
reports and attempt to determine root causes of authentication mechanism
failures, gain insight into misconfigurations or other problems with email
and network infrastructure, or inspect messages for insight into abusive
practices. Both report types may expose sender and recipient identifiers (e.g.,
RFC5322.From addresses), and although the format used
for failed message reporting supports redaction, failed message reporting is
capable of exposing the entire message to the report recipient. Domain Owners requesting reports will receive information about mail
claiming to be from them, which includes mail that was not, in fact, from
them. Information about the final destination of mail where it might
otherwise be obscured by intermediate systems will therefore be exposed.
When message forwarding arrangements exist, Domain Owners requesting reports
will also receive information about mail forwarded to domains that were not
originally part of their messages' recipient lists. This means destination
domains previously unknown to the Domain Owner may now become visible. Disclosure of information about the messages is being requested by the entity generating
the email in the first place, i.e., the Domain Owner and not the Mail Receiver, so this may not fit
squarely within existing privacy policy provisions. For some providers,
aggregate and failed message reporting are viewed as a function similar to
complaint reporting about spamming or phishing, and treated similarly under
the privacy policy. Report generators (i.e., Mail Receivers) are encouraged
to review their reporting limitations under such policies before enabling
DMARC reporting. A DMARC record can specify that reports should be sent to an intermediary
operating on behalf of the Domain Owner. This is done when the Domain Owner
contracts with an entity to monitor mail-streams for abuse and performance
issues. Receipt by third parties of such data may or may not be permitted by
the Mail Receiver's privacy policy, terms of use, or other similar governing
document. Domain Owners and Mail Receivers should both review and understand
if their own internal policies constrain the use and transmission of DMARC
reporting. Some potential exists for report recipients to perform traffic analysis,
making it possible to obtain metadata about the receiver's traffic. In addition to
verifying compliance with policies, receivers need to consider that
before sending reports to a third party. This section discusses some topics regarding choices made in the
development of DMARC, largely to commit the history to
record. Though DMARC does not inherently change the semantics of an SPF policy record,
historically lax enforcement of such policies has led many to publish extremely
broad records containing many large network ranges. Domain Owners are strongly
encouraged to carefully review their SPF records to understand which networks
are authorized to send on behalf of the Domain Owner before publishing a DMARC
record. Some receiver architectures might implement SPF in advance of any DMARC
operations. This means a "-" prefix on a Sender's SPF mechanism, such as "-all",
could cause that rejection go into effect early in handling, causing message
rejection before any DMARC processing takes place. Operators choosing to use
"-all" should be aware of this. DMARC policies are communicated using the DNS, and therefore inherit a number of
considerations related to DNS caching. The inherent conflict between freshness
and the impact of caching on the reduction of DNS-lookup overhead should be
considered from the Mail Receiver's point of view. Should Domain Owners publish
a DNS record with a very short TTL, Mail Receivers can be provoked through the
injection of large volumes of messages to overwhelm the Domain Owner's DNS.
Although this is not a concern specific to DMARC, the implications of a very
short TTL should be considered when publishing DMARC policies. Conversely, long TTLs will cause records to be cached for long periods of time.
This can cause a critical change to DMARC parameters advertised by a Domain
Owner to go unnoticed for the length of the TTL (while waiting for DNS caches to
expire). Avoiding this problem can mean shorter TTLs, with the potential
problems described above. A balance should be sought to maintain responsiveness
of DMARC preference changes while preserving the benefits of DNS caching. This proposal calls for rejection of a message during the SMTP session under
certain circumstances. This is preferable to generation of a Delivery Status
notification () since fraudulent messages caught
and rejected using DMARC would then result in annoying generation
of such failure reports that go back to the RFC5321.MailFrom address. This synchronous rejection is typically done in one of two ways: Full rejection, wherein the SMTP server issues a 5xy reply code as an
indication to the SMTP client that the transaction failed; the SMTP
client is then responsible for generating notification that delivery
failed (see Section 4.2.5 of ). A "silent discard", wherein the SMTP server returns a 2xy reply code
implying to the client that delivery (or, at least, relay) was
successfully completed, but then simply discarding the message with no
further action. Each of these has a cost. For instance, a silent discard can help to prevent
backscatter, but it also effectively means the SMTP server has to be programmed to give a
false result, which can confound external debugging efforts. Similarly, the text portion of the SMTP reply may be important to consider. For
example, when rejecting a message, revealing the reason for the rejection might
give an attacker enough information to bypass those efforts on a later attempt,
though it might also assist a legitimate client to determine the source of some
local issue that caused the rejection. In the latter case, when doing an SMTP rejection, providing a clear hint can be
useful in resolving issues. A receiver might indicate in plain text the reason
for the rejection by using the word "DMARC" somewhere in the reply text. Many
systems are able to scan the SMTP reply text to determine the nature of the
rejection, thus providing a machine-detectable reason for rejection allows
automated sorting of rejection causes so they can be properly addressed. For
example: If a Mail Receiver elects to defer delivery due to inability to retrieve or
apply DMARC policy, this is best done with a 4xy SMTP reply code. The DMARC mechanism allows both DKIM and SPF-authenticated identifiers to
authenticate email on behalf of a Domain Owner and, possibly, on
behalf of different subdomains. If malicious or unaware users can gain control
of the SPF record or DKIM selector records for a subdomain, the subdomain can be
used to generate DMARC-passing email on behalf of the Organizational Domain. For example, an attacker who controls the SPF record for "evil.example.com" can
send mail with an RFC5322.From field containing "foo@example.com" that can pass both
authentication and the DMARC check against "example.com". The Organizational Domain administrator should be careful not to delegate control of
sub-domains if this is an issue, and to consider using the "strict" Identifier
Alignment option if appropriate. DMARC limits which end-to-end scenarios can achieve a
"pass" result. Because DMARC relies on and/or
to achieve a "pass",
their limitations also apply. Additional DMARC constraints occur when a message is
processed by some Mediators, such as mailing lists.
Transiting a Mediator often causes either the
authentication to fail or identity alignment to be lost.
These transformations may conform to standards but will
still prevent a DMARC "pass". In addition to Mediators, mail that is sent by
authorized, independent third-parties might not be sent
with Identifier Alignment, also preventing a "pass"
result. Issues specific to the use of policy mechanisms alongside
DKIM are further discussed in
, particularly Section 5.2. This section describes actions requested of IANA. IANA is requested to add the following to the Email Authentication Method Name
Registry: dmarc [this document] header from the domain portion of the RFC5322.From field IANA has added the following in the Email Authentication Result Name Registry:
none existing dmarc (added) No DMARC policy record was published for the aligned
identifier, or no aligned identifier could be extracted. pass existing dmarc (added) A DMARC policy record was published for the aligned
identifier, and at least one of the authentication mechanisms passed.
fail existing dmarc (added) A DMARC policy record was published for the aligned
identifier, and none of the authentication mechanisms passed. temperror existing dmarc (added) A temporary error occurred during DMARC evaluation.
A later attempt might produce a final result. permerror existing dmarc (added) A permanent error occurred during DMARC evaluation,
such as encountering a syntactically incorrect DMARC record. A later
attempt is unlikely to produce a final result. The following is added to the Feedback Report Header Fields Registry:
Identity-Alignment indicates whether the message
about which a report is being generated had
any identifiers in alignment as defined in [this RFC] no auth-failure [this RFC] current A new registry tree called "Domain-based Message
Authentication, Reporting and Conformance (DMARC)
Parameters" is to be created. Within it, a new
sub-registry called the "DMARC Tag Registry" is also
to be created. Names of DMARC tags must be registered with IANA in this new
sub-registry. New entries are assigned only
for values that have been documented in a manner that satisfies the terms of
Specification Required, per . Each registration must
include the tag name, the specification that defines it, a brief description,
and its status which must be one of "current", "experimental" or "historic".
The Designated Expert needs to confirm that the provided specification
adequately describes the new tag and clearly presents how it would
be used within the DMARC context by Domain Owners and Mail Receivers. To avoid version compatibility issues,
tags added to the DMARC specification are to avoid changing the semantics of
existing records when processed by implementations conforming to prior
specifications.The initial set of entries in this registry is as follows:
Also within "Domain-based Message
Authentication, Reporting and Conformance (DMARC)
Parameters", a new sub-registry called "DMARC Report
Format Registry" is to be created. Names of DMARC failure reporting formats must be registered with IANA in this registry. New
entries are assigned only for values that satisfy the definition of
Specification Required, per . In addition to a reference to a permanent specification, each
registration must include the tag name, the specification that defines it, a
brief description, and its status which must be one of "current", "experimental"
or "historic". The Designated Expert needs to confirm that the provided specification
adequately describes the report format and clearly presents how it would
be used within the DMARC context by Domain Owners and Mail Receivers. The initial set of entries in this registry is as follows: This section discusses security issues and possible
remediations (where available) for DMARC. Security considerations from the authentication methods used by
DMARC are incorporated here by reference. URIs published in DNS TXT records are well-understood possible targets for
attack. Specifications such as and
either expose or cause the exposure of email addresses that could be flooded by
an attacker, for example; MX, NS and other records found in the DNS advertise
potential attack destinations; common DNS names such as "www" plainly identify
the locations at which particular services can be found, providing destinations
for targeted denial-of-service or penetration attacks. Thus, Domain Owners will need to harden these addresses against various attacks,
including but not limited to: high-volume denial-of-service attacks; deliberate construction of malformed reports intended to identify or
exploit parsing or processing vulnerabilities; deliberate construction of reports containing false claims for the
Submitter or Reported-Domain fields, including the possibility of false
data from compromised but known Mail Receivers. The DMARC mechanism and its underlying technologies (SPF, DKIM) depend on the
security of the DNS. To reduce the risk of subversion of the DMARC mechanism due
to DNS-based exploits, serious consideration should be given to the deployment
of DNSSEC in parallel with the deployment of DMARC by both Domain Owners
and Mail Receivers. Publication of data using DNSSEC is relevant to Domain Owners and
third-party Report Receivers. DNSSEC-aware resolution is relevant
to Mail Receivers and Report Receivers. A common attack in messaging abuse is the presentation of false information in
the display-name portion of the RFC5322.From field. For example, it is
possible for the email address in that field to be an arbitrary address or
domain name, while containing a well-known name (a person, brand, role, etc.) in
the display name, intending to fool the end user into believing that the name is
used legitimately. The attack is predicated on the notion that most common
MUAs will show the display name and not the email address when
both are available. Generally, display name attacks are out of scope for DMARC as further
exploration of possible defenses against these attacks needs to be undertaken. There are a few possible mechanisms that attempt mitigation of these attacks,
such as: If the display name is found to include an email address (as specified
in ), execute the DMARC mechanism on the domain
name found there rather than the domain name discovered originally.
However, this addresses only a very specific attack space and is easily
circumvented by spoofers simply by not using an email address in the
display name. There are also known cases of legitimate uses of an email
address in the display name with a domain different from the one in the
address portion, e.g.:
In the MUA, only show the display name if the DMARC mechanism succeeds.
This too is easily defeated, as an attacker could arrange to pass the
DMARC tests while fraudulently using another domain name in the display
name. In the MUA, only show the display name if the DMARC mechanism passes and
the email address thus validated matches one found in the receiving
user's list of known addresses. To avoid abuse by bad actors, reporting addresses generally have to be inside the
domains about which reports are requested. In order to accommodate special cases
such as a need to get reports about domains that cannot actually receive mail,
describes a DNS-based mechanism for verifying
approved external reporting. The obvious consideration here is an increased DNS load against domains that are
claimed as external recipients. Negative caching will mitigate this problem, but
only to a limited extent, mostly dependent on the default time-to-live in the
domain's SOA record. Where possible, external reporting is best achieved by having the report be
directed to domains that can receive mail and simply having it automatically
forwarded to the desired external destination. Note that the addresses shown in the "ruf" tag receive more information that
might be considered private data, since it is possible for actual email content
to appear in the failure reports. The URIs identified there are thus more
attractive targets for intrusion attempts than those found in the "rua" tag.
Moreover, attacking the DNS of the subject domain to cause failure data to be
routed fraudulently to an attacker's systems may be an attractive prospect.
Deployment of is advisable if this is a concern. The verification mechanism presented in is currently
not mandatory ("MUST") but strongly recommended ("SHOULD"). It is possible that
it would be elevated to a "MUST" by later security review. This document encourages use of secure transport mechanisms to prevent loss
of private data to third parties that may be able to monitor such
transmissions. Unencrypted mechanisms should be avoided. In particular, a message that was originally encrypted or otherwise
secured might appear in a report that is not sent securely, which
could reveal private information. Augmented BNF for Syntax Specifications: ABNF Brandenburg InternetWorking THUS plc. Authentication Failure Reporting using the Abuse Report
Format Extensions to DomainKeys Identified Mail (DKIM) for
Failure Reporting Sender Policy Framework (SPF) Authentication Failure
Reporting Using the Abuse Reporting Format DomainKeys Identified Mail (DKIM) Signatures Domain names -
implementation and specification USC/ISI Domain Name System (DNS) Case
Insensitivity Clarification Motorola Laboratories The 'application/zlib' and 'application/gzip' Media Types Taughannock Networks Internationalized Domain Names for Applications (IDNA): Definitions and
Document Framework Key words for use in RFCs to Indicate Requirement
LevelsHarvard UniversityInternet Message Format Qualcomm Incorporated Multipurpose Internet Mail Extensions
(MIME) Part One: Format of Internet Message Bodies Innosoft International, Inc. First Virtual Holdings Internet Security Glossary, Version 2Simple Mail Transfer Protocol Sender Policy Framework (SPF) for Authorizing Use of Domains in E-Mail,
Version 1 Uniform Resource Identifier (URI): Generic Syntax W3C/MIT Day Software Adobe Systems DomainKeys Identified Mail (DKIM) Author Domain Signing Practices (ADSP) Sendmail, Inc. Cisco Systems, Inc. Yahoo!, Inc. Taughannock Networks An Extensible Format for Email Feedback Reports ShafTek Enterprises Taughannock Networks Cloudmark Message Header Field for Indicating Message Authentication Status Sendmail, Inc. Sender Policy Framework: Best guess record (FAQ entry) DomainKeys Identified Mail (DKIM) Development, Deployment, and
Operations AT&T Laboratories Brandenburg InternetWorking Default Deny Security, Inc. DomainKeys Identified Mail (DKIM) and Mailing Lists Cloudmark DomainKeys Identified Mail (DKIM) Service Overview AT&T Laboratories Brandenburg InternetWorking Default Deny Security, Inc. Analysis of Threats Motivating DomainKeys Identified Mail (DKIM) DNS Security Introduction and Requirements Telematica Instituut ISC VeriSign Colorado State University NIST An Extensible Message Format for Delivery Status Notifications University of Tennessee Lucent Technologies Internet Mail Architecture Brandenburg InternetWorking Guidelines for Writing an IANA Considerations Section in RFCs Mailbox Names for Common Services, Roles and Functions Internet Mail Consortium This section documents some design decisions that were made in the development of
DMARC. Specifically, addressed here are some suggestions that were considered but
not included in the design. This text is included to explain why they were
considered and not included in this version. S/MIME, or Secure Multipurpose Internet Mail Extensions, is a standard for
encryption and signing of MIME data in a message. This was suggested and
considered as a third security protocol for authenticating the source of a
message. DMARC is focused on authentication at the domain level (i.e., the Domain Owner
taking responsibility for the message), while S/MIME is really intended for
user-to-user authentication and encryption. This alone appears to make it a bad
fit for DMARC's goals. S/MIME also suffers from the heavyweight problem of Public Key Infrastructure,
which means distribution of keys used to verify signatures needs to be
incorporated. In many instances, this alone is a showstopper. There have been
consistent promises that PKI usability and deployment will improve, but these
have yet to materialize. DMARC can revisit this choice after those barriers are
addressed. S/MIME has extensive deployment in specific market segments (government, for
example), but does not enjoy similar widespread deployment over the general
Internet, and this shows no signs of changing. DKIM and SPF both are deployed
widely over the general Internet and their adoption rates continue to be
positive. Finally, experiments have shown that including S/MIME support in the initial
version of DMARC would neither cause nor enable a substantial increase in the
accuracy of the overall mechanism. It was suggested that DMARC include a mechanism by which a Domain Owner could
tell Message Receivers not to attempt validation by one of the supported methods
(e.g., "check DKIM, but not SPF"). Specifically, consider a Domain Owner that has deployed one of the technologies,
and that technology fails for some messages, but such failures don't cause
enforcement action. Deploying DMARC would cause enforcement action for policies
other than "none", which would appear to exclude participation by that Domain
Owner. The DMARC development team evaluated the idea of policy exception mechanisms on
several occasions and invariably concluded that there was not a strong enough
use case to include them. The specific target audience for DMARC does not appear
to have concerns about the failure modes of one or the other being a barrier to
DMARC's adoption. In the scenario described above, the Domain Owner has a few options: Tighten up its infrastructure to minimize the failure modes of the
single deployed technology. Deploy the other supported authentication mechanism, to offset the
failure modes of the first. Deploy DMARC in a reporting-only mode. It has been suggested in several message authentication efforts that the Sender
header field be checked for an identifier of interest, as the standards indicate
this as the proper way to indicate a re-mailing of content such as through a
mailing list. Most recently, it was a protocol-level option for DomainKeys, but
on evolution to DKIM, this property was removed. The DMARC development team considered this and decided not to include support
for doing so, for the following reasons: The main user protection approach is to be concerned with what the user
sees when a message is rendered. There is no consistent behavior among
MUAs regarding what to do with the content of the Sender field, if
present. Accordingly, supporting checking of the Sender identifier would
mean applying policy to an identifier the end user might never actually
see, which can create a vector for attack against end users by simply
forging a Sender field containing some identifier that DMARC will like. Although it is certainly true that this is what Sender is for, its use
in this way is also unreliable, making it a poor candidate for inclusion
in the DMARC evaluation algorithm. Allowing multiple ways to discover policy introduces unacceptable
ambiguity into the DMARC evaluation algorithm in terms of which policy
is to be applied and when. A common practice among MTA operators, and indeed one documented in , is a test to determine domain existence prior to any more
expensive processing. This is typically done by querying the DNS for MX, A or
AAAA resource records for the name being evaluated, and assuming the domain is
non-existent if it could be determined that no such records were published for
that domain name. The original pre-standardization version of this protocol included a mandatory
check of this nature. It was ultimately removed, as the method's error rate was
too high without substantial manual tuning and heuristic work. There are indeed
use cases this work needs to address where such a method would return a negative
result about a domain for which reporting is desired, such as a registered
domain name that never sends legitimate mail and thus has none of these records
present in the DNS. DMARC has been characterized as a "super-ADSP" of sorts. Contributors to DMARC have compiled a list of issues associated with ADSP, gained
from operational experience, that have influenced the direction of DMARC: ADSP has no support for subdomains, i.e., the ADSP record for
example.com does not explicitly or implicitly apply to
subdomain.example.com. If wildcarding is not applied, then spammers can
trivially bypass ADSP by sending from a subdomain with no ADSP record. Non-existent subdomains are explicitly out of scope in ADSP. There is
nothing in ADSP that states receivers should simply reject mail from
NXDOMAINs regardless of ADSP policy (which of course allows spammers to
trivially bypass ADSP by sending email from non-existent subdomains). ADSP has no operational advice on when to look up the ADSP record. ADSP has no support for using SPF as an auxiliary mechanism to DKIM. ADSP has no support for a slow roll-out, i.e., no way to configure a
percentage of email on which the receiver should apply the policy. This
is important for large-volume senders. ADSP has no explicit support for an intermediate phase where the
receiver quarantines (e.g., sends to the recipient's "spam" folder)
rather than rejects the email. The binding between the "From" header domain and DKIM is too tight for
ADSP; they must match exactly. Although protocols like ADSP are useful for "protecting" a specific domain name,
they are not helpful at protecting subdomains. If one wished to protect
"example.com" by requiring via ADSP that all mail bearing an RFC5322.From domain
of "example.com" be signed, this would "protect" that domain; however, one could
then craft an email whose RFC5322.From domain is "security.example.com", and
ADSP would not provide any protection. One could use a DNS wildcard, but this
can undesirably interfere with other DNS activity; one could add ADSP records as
fraudulent domains are discovered, but this solution does not scale and is a
purely reactive measure against abuse. The DNS does not provide a method by which the "domain of record", or the domain
that was actually registered with a domain registrar, can be determined given an
arbitrary domain name. Suggestions have been made that attempt to glean such
information from SOA or NS resource records, but these too are not fully
reliable as the partitioning of the DNS is not always done at administrative
boundaries. When seeking domain-specific policy based on an arbitrary domain name, one could
"climb the tree", dropping labels off the left end of the name until the root is
reached or a policy is discovered, but then one could craft a name that has a
large number of nonsense labels; this would cause a Mail Receiver to attempt a
large number of queries in search of a policy record. Sending many such messages
constitutes an amplified denial-of-service attack. The Organizational Domain mechanism is a necessary component to the goals of
DMARC. The method described in is far from perfect,
but serves this purpose reasonably well without adding undue burden or semantics
to the DNS. If a method is created to do so that is more reliable and secure than
the use of a public suffix list, DMARC should be amended to use that method as soon
as it is generally available. A public suffix list for the purposes of determining the Organizational
Domain can be obtained from various sources. The most common one is
maintained by the Mozilla Foundation and made public at
http://publicsuffix.org. License terms governing the use of that list are
available at that URI. Note that if operators use a variety of public suffix lists,
interoperability will be difficult or impossible to guarantee. This section illustrates both the Domain Owner side and the Mail Receiver side of a
DMARC exchange. The following examples illustrate the DMARC mechanism's use of Identifier
Alignment. For brevity's sake, only message headers are shown as message bodies
are not considered when conducting DMARC checks. The following SPF examples assume that SPF produces a passing result. In this case, the RFC5321.MailFrom parameter and the RFC5322.From field have
identical DNS domains. Thus, the identifiers are in alignment. In this case, the RFC5322.From parameter includes a DNS domain that is a
parent of the RFC5321.MailFrom domain. Thus, the identifiers are in alignment if
"relaxed" SPF mode is requested by the Domain Owner, and not in alignment if
"strict" SPF mode is requested. In this case, the RFC5321.MailFrom parameter includes a DNS domain that is
neither the same as nor a parent of the RFC5322.From domain. Thus, the
identifiers are not in alignment. The examples below assume the DKIM signatures pass verification. Alignment
cannot exist with a DKIM signature that does not verify. In this case, the DKIM "d=" parameter and the RFC5322.From field have
identical DNS domains. Thus, the identifiers are in alignment. In this case, the DKIM signature's "d=" parameter includes a DNS domain that
is a parent of the RFC5322.From domain. Thus, the identifiers are in
alignment for "relaxed" mode, but not for "strict" mode. In this case, the DKIM signature's "d=" parameter includes a DNS domain that
is neither the same as nor a parent of the RFC5322.From domain. Thus, the
identifiers are not in alignment. A Domain Owner that wants to use DMARC should have already deployed and tested
SPF and DKIM. The next step is to publish a DNS record that advertises a DMARC
policy for the Domain Owner's organizational domain. The owner of the domain "example.com" has deployed SPF and DKIM on its
messaging infrastructure. The owner wishes to begin using DMARC with a
policy that will solicit aggregate feedback from receivers without affecting
how the messages are processed, in order to: Confirm that its legitimate messages are authenticating correctly Verify that all authorized message sources have implemented
authentication measures Determine how many messages from other sources would be affected by
a blocking policy The Domain Owner accomplishes this by constructing a policy record
indicating that: The version of DMARC being used is "DMARC1" ("v=DMARC1") Receivers should not alter how they treat these messages because of
this DMARC policy record ("p=none") Aggregate feedback reports should be sent via email to the address
"dmarc-feedback@example.com"
("rua=mailto:dmarc-feedback@example.com") All messages from this organizational domain are subject to this
policy (no "pct" tag present, so the default of 100% applies) The DMARC policy record might look like this when retrieved using a common
command-line tool: To publish such a record, the DNS administrator for the Domain Owner creates
an entry like the following in the appropriate zone file (following the
conventional zone file format): The Domain Owner from the previous example has used the aggregate reporting
to discover some messaging systems that had not yet implemented DKIM
correctly, but they are still seeing periodic authentication failures. In
order to diagnose these intermittent problems they wish to request
per-message failure reports when authentication failures occur. Not all Receivers will honor such a request, but the Domain Owner feels that
any reports it does receive will be helpful enough to justify publishing
this record. The default per-message report format ()
meets the Domain Owner's needs in this scenario. The Domain Owner accomplishes this by adding the following to its policy
record from ): Per-message failure reports should be sent via email to the address
"auth-reports@example.com" ("ruf=mailto:auth-reports@example.com")
The DMARC policy record might look like this when retrieved using a common
command-line tool (the output shown would appear on a single line, but is
wrapped here for publication):
To publish such a record, the DNS administrator for the Domain Owner might
create an entry like the following in the appropriate zone file (following
the conventional zone file format):
The Domain Owner from the previous example is maintaining the same policy,
but now wishes to have a third party receive and process the per-message
failure reports. Again, not all Receivers will honor this request, but those
that do may implement additional checks to validate that the third party
wishes to receive the failure reports for this domain. The Domain Owner needs to alter its policy record from as follows: Per message failure reports should be send via email to the address
"auth-reports@thirdparty.example.net"
("ruf=mailto:auth-reports@thirdparty.example.net") The DMARC policy record might look like this when retrieved using a common
command-line tool (the output shown would appear on a single line, but is
wrapped here for publication):
To publish such a record, the DNS administrator for the Domain Owner might
create an entry like the following in the appropriate zone file (following
the conventional zone file format): Because the address used in the "ruf" tag is outside the Organizational
Domain in which this record is published, conforming Receivers will
implement additional checks as described in of
this document. In order to pass these additional checks, the third party
will need to publish an additional DNS record as follows: Given the DMARC record published by the Domain Owner at
"_dmarc.example.com", the DNS administrator for the third party will
need to publish a TXT resource record at
"example.com._report._dmarc.thirdparty.example.net" with the value
"v=DMARC1". The resulting DNS record might look like this when retrieved using a common
command-line tool (the output shown would appear on a single line, but is
wrapped here for publication): To publish such a record, the DNS administrator for example.net might create
an entry like the following in the appropriate zone file (following the
conventional zone file format): Intermediaries and other third parties should refer to for the full details of this mechanism. The Domain Owner has implemented SPF and DKIM in a sub-domain used for
pre-production testing of messaging services. It now wishes to request that
participating receivers act to reject messages from this sub-domain that
fail to authenticate. As a first step it will ask that a portion (1/4 in this example) of failing
messages be quarantined, enabling examination of messages sent to mailboxes
hosted by participating receivers. Aggregate feedback reports will be sent
to a mailbox within the Organizational Domain, and to a mailbox at a third
party selected and authorized to receive same by the Domain Owner. Aggregate
reports sent to the third party are limited to a maximum size of ten
megabytes. The Domain Owner will accomplish this by constructing a policy record
indicating that: The version of DMARC being used is "DMARC1" ("v=DMARC1") It is applied only to this sub-domain (record is published at
"_dmarc.test.example.com" and not "_dmarc.example.com") Receivers should quarantine messages from this organizational domain
that fail to authenticate ("p=quarantine") Aggregate feedback reports should be sent via email to the addresses
"dmarc-feedback@example.com" and
"example-tld-test@thirdparty.example.net", with the latter subjected
to a maximum size limit
("rua=mailto:dmarc-feedback@example.com,mailto:tld-test@thirdparty.example.net!10m") 25% of messages from this Organizational Domain are subject to
action based on this policy ("pct=25") The DMARC policy record might look like this when retrieved using a common
command-line tool (the output shown would appear on a single line, but is
wrapped here for publication): To publish such a record, the DNS administrator for the Domain Owner might
create an entry like the following in the appropriate zone file: A Mail Receiver that wants to use DMARC should already be checking SPF and DKIM,
and possess the ability to collect relevant information from various email
processing stages to provide feedback to Domain Owners (possibly
via Report Receivers). An optimal DMARC-enabled Mail Receiver performs authentication and
identifier alignment checking during the
conversation. Prior to returning a final reply to the DATA command, the Mail Receiver's MTA has
performed: An SPF check to determine an SPF-authenticated Identifier. DKIM checks that yield one or more DKIM-authenticated Identifiers. A DMARC policy lookup. The presence of an Author Domain DMARC record indicates that the Mail
Receiver should continue with DMARC-specific processing before returning a
reply to the DATA command. Given a DMARC record and the set of Authenticated Identifiers, the Mail
Receiver checks to see if the Authenticated Identifiers align with the
Author Domain (taking into consideration any "strict" vs "relaxed" options
found in the DMARC record). For example, the following sample data is considered to be from a piece of
email originating from the Domain Owner of "example.com":
In the above sample, both the SPF and the DKIM-authenticated Identifiers
align with the Author Domain. The Mail Receiver considers the above email to
pass the DMARC check, avoiding the "reject" policy that is to be applied to
email that fails to pass the DMARC check. If no Authenticated Identifiers align with the Author Domain, then the Mail
Receiver applies the DMARC-record-specified policy. However, before this
action is taken, the Mail Receiver can consult external information to
override the Domain Owner's policy. For example, if the Mail Receiver knows
that this particular email came from a known and trusted forwarder (that
happens to break both SPF and DKIM), then the Mail Receiver may choose to
ignore the Domain Owner's policy. The Mail Receiver is now ready to reply to the DATA command. If the DMARC
check yields that the message is to be rejected, then the Mail Receiver
replies with a 5xy code to inform the sender of failure. If the DMARC check
cannot be resolved due to transient network errors, then the Mail Receiver
replies with a 4xy code to inform the sender as to the need to reattempt
delivery later. If the DMARC check yields a passing message, then the Mail
Receiver continues on with email processing, perhaps using the result of the
DMARC check as an input to additional processing modules such as a domain
reputation query. Before exiting DMARC-specific processing, the Mail Receiver checks to see if
the Author Domain DMARC record requests AFRF-based reporting. If so, then
the Mail Receiver can emit an AFRF to the reporting address supplied in the
DMARC record. At the exit of DMARC-specific processing, the Mail Receiver captures
(through logging or direct insertion into a data store) the result of DMARC
processing. Captured information is used to build feedback for Domain Owner
consumption. This is not necessary if the Domain Owner has not requested
aggregate reports, i.e., no "rua" tag was found in the policy record. Aggregate feedback is consumed by Domain Owners to verify the Domain Owners
understanding of how the Domain Owner's Domain is being processed by the Mail
Receiver. Aggregate reporting data on emails that pass all DMARC-supporting
authentication checks is used by Domain Owners to verify that authentication
practices remain accurate. For example, if a third party is sending on behalf of
a Domain Owner, the Domain Owner can use aggregate report data to verify ongoing
authentication practices of the third party. Data on email that only partially passes underlying authentication checks
provides visibility into problems that need to be addressed by the Domain Owner.
For example, if either SPF or DKIM fail to pass, the Domain Owner is provided
with enough information to either directly correct the problem or to understand
where authentication-breaking changes are being introduced in the email
transmission path. If authentication-breaking changes due to email transmission
path cannot be directly corrected, then the Domain Owner at least maintains an
understanding of the effect of DMARC-based policies upon the Domain Owner's
email. Data on email that fails all underlying authentication checks provides baseline
visibility on how the Domain Owner's Domain is being received at the Mail
Receiver. Based on this visibility, the Domain Owner can begin deployment of
authentication technologies across uncovered email sources. Additionally, the
Domain Owner may come to an understanding of how its Domain is being misused.
A DMARC record can contain a "mailto" reporting address, such as: A sample aggregate report from the Mail Receiver at mail.receiver.example
follows: Not shown in the above example is that the Mail Receiver's feedback should be
authenticated using SPF. Also, the value of the "filename" MIME parameter is
wrapped for printing in this specification but would normally appear as one
continuous string. The following is the proposed initial schema for producing XML formatted aggregate
reports as described in this document. NOTE: Per the definition of XML, unless otherwise specified in the schema below, the
minOccurs and maxOccurs values for each element is set to 1.
Descriptions of the PolicyOverrideTypes: Message was relayed via a known forwarder, or local
heuristics identified the message as likely having been forwarded. There is
no expectation that authentication would pass. The Mail Receiver's local policy exempted the
message from being subjected to the Domain Owner's requested policy action. Local heuristics determined that the message
arrived via a mailing list, and thus authentication of the original message
was not expected to succeed. Some policy exception not covered by the other entries in
this list occurred. Additional detail can be found in the
PolicyOverrideReason's "comment" field. Message was exempted from application of policy by
the "pct" setting in the DMARC policy record. Message authentication failure was anticipated
by other evidence linking the message to a locally-maintained list of known
and trusted forwarders. The "version" for reports generated per this specification MUST be the value 1.0.
Public discussion of the DMARC proposal documents is taking place on the
dmarc-discuss@dmarc.org mailing list. Subscription is available at
http://www.dmarc.org/mailman/listinfo/dmarc-discuss. [RFC Editor: Please remove this section prior to publication.] DMARC and the version of this document submitted to the IETF were the result of
lengthy efforts by an informal industry consortium: DMARC.org. Participating companies included: Agari, American Greetings,
AOL, Bank of America, Cloudmark, Comcast, Facebook, Fidelity Investments, Google,
JPMorgan Chase & Company, LinkedIn, Microsoft, Netease, Paypal, ReturnPath,
Trusted Domain Project, and Yahoo!. Although the number of contributors and
supporters are too numerous to mention, notable individual contributions were made
by J. Trent Adams, Michael Adkins, Monica Chew, Dave Crocker, Tim Draegen,
Steve Jones, Franck Martin, Brett McDowell, and Paul Midgen. The
contributors would also like to recognize the invaluable input and guidance that was
provided early on by J.D. Falk. Additional contributions within the IETF context were made by Les Barstow, Jim Fenton, J. Gomez, Mike Jones, Scott Kitterman, Eliot Lear, John Levine, S. Moonesamy, Rolf Sonneveld, Henry
Timmes, and Stephen J. Turnbull.