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INTERNET-DRAFT Hadmut Danisch
Category: Experimental Oct 2003
Expires: Apr 1, 2004
The RMX DNS RR and method for lightweight SMTP sender authorization
draft-danisch-dns-rr-smtp-03.txt
Status of this Memo
This document is an Internet-Draft and is subject to all provisions
of Section 10 of RFC2026.
Internet-Drafts are working documents of the Internet Engineering
Task Force (IETF), its areas, and its working groups. Note that
other groups may also distribute working documents as Internet-
Drafts.
Internet-Drafts are draft documents valid for a maximum of six
months and may be updated, replaced, or obsoleted by other
documents at any time. It is inappropriate to use Internet-Drafts
as reference material or to cite them other than as "work in
progress."
The list of current Internet-Drafts can be accessed at
http://www.ietf.org/1id-abstracts.html
The list of Internet-Draft Shadow Directories can be accessed at
http://www.ietf.org/shadow.html
Abstract
This memo introduces a new authorization scheme for SMTP e-mail
transport. It is designed to be a simple and robust protection
against e-mail fraud, spam and worms. It is based solely on
organisational security mechanisms and does not require but still
allow use of cryptography. This memo also focuses on security and
privacy problems and requirements in context of spam defense. In
contrast to prior versions of the draft a new RR type is not
required anymore.
Hadmut Danisch Experimental [Page 1]
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Table of Contents
1. General Issues . . . . . . . . . . . . . . . . . . . . . . . . . 4
2. Problem and threat description . . . . . . . . . . . . . . . . . 4
2.1. Mail sender forgery . . . . . . . . . . . . . . . . . . . 4
2.1.1 Definition of sender forgery . . . . . . . . . . . 4
2.1.2 Spam . . . . . . . . . . . . . . . . . . . . . . . 5
2.1.3 E-Mail Worms . . . . . . . . . . . . . . . . . . . 5
2.1.4 E-Mail spoofing and fraud . . . . . . . . . . . . . 5
2.2. Indirect damage caused by forgery . . . . . . . . . . . . 6
2.3. Technical problem analysis . . . . . . . . . . . . . . . . 6
2.4. Shortcomings of cryptographical approaches . . . . . . . . 7
3. A DNS based sender address verification . . . . . . . . . . . . 7
3.1. Overview . . . . . . . . . . . . . . . . . . . . . . . . . 7
3.2. Envelope vs. header sender address . . . . . . . . . . . . 9
3.3. Domain part vs. full sender address . . . . . . . . . . . 9
4. Mapping of E-Mail addresses to DNS names . . . . . . . . . . . . 10
4.1. Domain part only . . . . . . . . . . . . . . . . . . . . . 10
4.2. Full address . . . . . . . . . . . . . . . . . . . . . . . 11
4.3. Empty address . . . . . . . . . . . . . . . . . . . . . . 11
5. Mandatory entry types and their syntax . . . . . . . . . . . . . 11
5.1. Overall structure . . . . . . . . . . . . . . . . . . . . 11
5.2. Unused . . . . . . . . . . . . . . . . . . . . . . . . . . 12
5.3. IPv4 and IPv6 address ranges . . . . . . . . . . . . . . . 12
5.4. DNS Hostname . . . . . . . . . . . . . . . . . . . . . . . 13
5.4.1 Road warriors and DynDNS entries . . . . . . . . . 13
5.5. APL Reference . . . . . . . . . . . . . . . . . . . . . . 14
5.6. Domain Member . . . . . . . . . . . . . . . . . . . . . . 14
5.7. Full Address Query . . . . . . . . . . . . . . . . . . . . 15
5.8. DNS mapped authorization . . . . . . . . . . . . . . . . . 15
5.9. RMX reference . . . . . . . . . . . . . . . . . . . . . . 16
6. Optional and experimental entry types . . . . . . . . . . . . . 16
6.1. TLS fingerprint . . . . . . . . . . . . . . . . . . . . . 16
6.2. TLS and LDAP . . . . . . . . . . . . . . . . . . . . . . . 16
6.3. PGP or S/MIME signature . . . . . . . . . . . . . . . . . 16
6.4. Transparent Challenge/Response . . . . . . . . . . . . . . 17
6.5. SASL Challenge/Response . . . . . . . . . . . . . . . . . 17
7. Encoding . . . . . . . . . . . . . . . . . . . . . . . . . . . . 17
7.1. Alternative encoding as TXT records . . . . . . . . . . . 17
7.2. RMX Records . . . . . . . . . . . . . . . . . . . . . . . 17
7.2.1 Overall structure . . . . . . . . . . . . . . . . . 18
7.2.2 Record encoding . . . . . . . . . . . . . . . . . . 18
7.2.3 Encoding of IPv4 and IPv6 address ranges . . . . . 18
7.2.4 Encoding of DNS . . . . . . . . . . . . . . . . . . 18
7.2.5 Encoding of unused and full query . . . . . . . . . 19
7.2.6 Additional Records . . . . . . . . . . . . . . . . 19
8. Message Headers . . . . . . . . . . . . . . . . . . . . . . . . 19
Hadmut Danisch Experimental [Page 2]
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9. SMTP error messages . . . . . . . . . . . . . . . . . . . . . . 20
10. Message relaying and forwarding . . . . . . . . . . . . . . . . 20
10.1. Problem description . . . . . . . . . . . . . . . . . . . 20
10.2. Trusted relaying/forwarding . . . . . . . . . . . . . . . 21
10.3. Untrusted relaying/forwarding . . . . . . . . . . . . . . 21
11. Security Considerations . . . . . . . . . . . . . . . . . . . . 22
11.1. Draft specific considerations . . . . . . . . . . . . . . 22
11.1.1 Authentication strength . . . . . . . . . . . . . 22
11.1.2 Where Authentication and Authorization end . . . . 22
11.1.3 Vulnerability of DNS . . . . . . . . . . . . . . . 23
11.1.4 Sneaking RMX attack? . . . . . . . . . . . . . . 25
11.1.5 Open SMTP relays . . . . . . . . . . . . . . . . . 25
11.1.6 Unforged Spam . . . . . . . . . . . . . . . . . . 25
11.1.7 Reliability of Whois Entries . . . . . . . . . . . 26
11.1.8 Hazards for Freedom of Speech . . . . . . . . . . 26
11.2. General Considerations about spam defense . . . . . . . . 27
11.2.1 Action vs. reaction . . . . . . . . . . . . . . . 27
11.2.2 Content based Denial of Service attacks . . . . . 27
12. Privacy Considerations . . . . . . . . . . . . . . . . . . . . 28
12.1. Draft specific considerations . . . . . . . . . . . . . . 28
12.1.1 No content leaking . . . . . . . . . . . . . . . . 28
12.1.2 Message reception and sender domain . . . . . . . 28
12.1.3 Network structure . . . . . . . . . . . . . . . . 29
12.1.4 Owner information distribution . . . . . . . . . . 29
12.2. General Considerations about spam defense . . . . . . . . 29
12.2.1 Content leaking of content filters . . . . . . . . 29
12.2.2 Black- and Whitelists . . . . . . . . . . . . . . 30
13. Deployment Considerations . . . . . . . . . . . . . . . . . . . 30
13.1. Compatibility . . . . . . . . . . . . . . . . . . . . . . 30
13.1.1 Compatibility with old mail receivers . . . . . . 30
13.1.2 Compatibility with old mail senders . . . . . . . 30
13.1.3 Compatibility with old DNS clients . . . . . . . . 30
13.1.4 Compatibility with old DNS servers . . . . . . . . 30
13.2. Enforcement policy . . . . . . . . . . . . . . . . . . . 31
14. General considerations about fighting spam . . . . . . . . . . 31
14.1. The economical problem . . . . . . . . . . . . . . . . . 31
14.2. The POP problem . . . . . . . . . . . . . . . . . . . . . 32
14.3. The network structure problem . . . . . . . . . . . . . . 33
14.4. The mentality problem . . . . . . . . . . . . . . . . . . 33
14.5. The identity problem . . . . . . . . . . . . . . . . . . 33
14.6. The multi-legislation problem . . . . . . . . . . . . . . 34
Implementation and further Information . . . . . . . . . . . . . . . 34
References . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 34
Draft History . . . . . . . . . . . . . . . . . . . . . . . . . . . 35
Author's Address . . . . . . . . . . . . . . . . . . . . . . . . . . 35
Hadmut Danisch Experimental [Page 3]
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1. General Issues
The key words "MUST", "MUST NOT", "REQUIRED", "SHALL", "SHALL NOT",
"SHOULD", "SHOULD NOT", "RECOMMENDED", "MAY", and "OPTIONAL" in
this document are to be interpreted as described in RFC 2119 [1].
2. Problem and threat description
2.1. Mail sender forgery
The amount of e-mails with forged sender addresses has dramatically
increased. As a consequence, damages and annoyances caused by such
e-mails increased as well. In the majority of examined e-mails the
domain name of the envelope sender address was forged, and the e-
mail was sent from an IP address which does not belong to a network
used by the actual owner of the domain.
2.1.1. Definition of sender forgery
As discussions, comments to prior versions of this draft, and
different approaches to stop forgery showed, different perceptions
of "mail forgery" exist. For example, there are mechanisms to
verify e-mail addresses for mailing lists, web servers, or to stop
spam, which do send a message with a random number to the given
address and expect the user to send a reply. Here, someone is
considered to be allowed to use a particular e-mail address, if and
only if he is able to receive informations sent to this address,
and is able to reply to such a message. While this definition
appears to be quite plausible and natural, it can't be used for a
simple technical solution. Sending back a challenge and expecting a
reply is simply too much overhead and time delay, and not every
authorized sender is able or willing to reply (e.g. because he went
offline or is not a human).
Within the scope of this memo, sender forgery means that the
initiator of an e-mail transfer (which is the original sender in
contrast to relays) uses a sender address which he was not
authorized to use. Being authorized to use an address means that
the owner (administrator) of the internet domain has given
permission, i.e. agrees with the use of the address by that
particular sender. This memo will cover both the permission of the
full e-mail address and the domain part only for simplicity.
Within context of Internet and SMTP, the sender address usually
occurs twice, once as the envelope sender address in SMTP, and once
as the address given in the RFC822 mail header. While the following
considerations apply to both addresses in principle, it is
important to stress that both addresses have distinct semantics and
Hadmut Danisch Experimental [Page 4]
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are not neccessarily the same. The envelope address identifies the
initiator of the transport, while the header identifies the author
of the message content. Since this memo deals with the message
transport only and completely ignores the message content, the
method should naturally be applied to the envelope sender address.
2.1.2. Spam
A common and well known problem is the dramatic increase of
unsolicited e-mail, commonly called "spam". Again, the majority of
examined e-mails had forged sender addresses. The abused domains
were mainly those of common webmailers as hotmail or yahoo, or
well-known companies.
Unfortunately, there is no accurate definition of spam availabe
yet, and neither are the concise technical criterions to filter or
block spam with technical mechanisms. There are efforts to design
content based filters, but these filters are expensive in
calculation time (and sometimes money), and they do not reliably
provide predictable results. Usually they give false positives
and/or require user interaction. Content filters in general suffer
from a design problem described later in this memo. Therefore,
this proposal does not use the content based approach to block
spam.
As analysis of spam messages showed, most of spam messages were
sent with forged envelope sender addresses. This has mainly three
reasons. The first reason is, that spam senders usually do not
want to be contacted by e-mail. The second reason is, that they do
not want to be blacklisted easily. The third reason is, that spam
is or is going to be unlawful in many countries, and the sender
does not want to reveal his identity. Therefore, spam is considered
to be a special case of sender forgery.
2.1.3. E-Mail Worms
Another example of sender forgery is the reproduction of e-mail
worms. Most worms do choose random sender addresses, e.g. using
the addresses found in mailboxes on the infected system. In most
cases analyzed by the author, the e-mails sent by the reproduction
process can also be categorized as forged, since the infected
system would under normal circumstances not be authorized to send
e-mails with such e-mail addresses. So forgery does not require a
malicious human to be directly involved. This memo covers any kind
of e-mail sender address forgery, included those generated by
malicious software.
2.1.4. E-Mail spoofing and fraud
Hadmut Danisch Experimental [Page 5]
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Forging e-mail sender addresses for fraud or other kinds of
deception ("human engineering") has also dramatically increased.
There are many known cases where single or mass e-mails were sent
with wrong sender addresses, pretending to come from service
provider, software manufacturers etc., and asking the receiver to
install any software or patches, or to reply with any confidential
information. The Internet is becoming more and more a scene of
crime, and so are it's services, including e-mail. It is obvious
that crime based on e-mail is eased by the fact that SMTP allows
arbitrary sender address spoofing.
2.2. Indirect damage caused by forgery
As observed by the author, mass mails and worms with forged sender
addresses can cause a severe damage for the real owner of the
abused sender addresses. If a sender A is sending an e-mail to the
receiver B, pretending to be C by using a sender address of C's
domain, then C has currently no chance to prevent this, since C's
machines and software are not involved in any way in the delivery
process between A and B. B will nevertheless send any error
messages (virus/spam alert, "no such user", etc.) to C, erroneously
assuming that the message was sent by C. The author found several
cases where this flood of error messages caused a severe denial of
service or a dramatic increase of costs, e.g. when C was
downloading the e-mail through expensive or low bandwidth
connections (e.g. modem or mobile phones), or where disk space was
limited. The author examined mass mailings, where several tens or
hundreds of thousands of messages were sent to several addresses
around the world, where these messages caused only annoyance. But
since several thousands of these addresses were invalid or didn't
accept the message, the owner of the DNS domain which was abused by
the spammer to forge sender addresses was flooded for several
months with thousands of error messages, jamming the e-mail system
and causing severe costs and damages.
As a consequence, when A sends a message to B, pretending to be C,
there must be any mechanism to allow C to inform B about the fact,
that A is not authorized to use C as a sender address. This is what
this memo is about.
2.3. Technical problem analysis
Why does e-mail forgery actually exist? Because of the lack of the
Simple Mail Transfer Protocol SMTP[2] to provide any kind of sender
authentication, authorisation, or verification. This protocol was
designed at a time where security was not an issue. Efforts have
been made to block forged e-mails by requiring the sender address
domain part to be resolvable. This method provides protection from
Hadmut Danisch Experimental [Page 6]
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e-mails with non-existing sender domains, and indeed, for some time
it blocked most spam e-mails. However, since attackers and spam
senders began to abuse existing domain names, this method was
rendered ineffective.
2.4. Shortcomings of cryptographical approaches
At a first glance, the problem of sender address forgery might
appear to be solvable with cryptographic methods such as challenge
response authentications or digital signatures. A deeper analysis
shows that only a small, closed user group could be covered with
cryptographical methods. Any method used to stop spam forgery must
be suitable to detect forgery not only for a small number of
particular addresses, but for all addresses on the world. An
attacker does not need to know the secrets belonging to a
particular address. It is sufficient to be able to forge any
address and thus to know any secret key. Since there are several
hundreds of millions of users, there will always be a large amount
of compromised keys, thus spoiling any common cryptographic method.
Furthermore, cryptography has proven to be far too complicated and
error prone to be commonly administered and reliably implemented.
Many e-mail and DNS administrators do not have the knowledge
required to deal with cryptographic mechanisms. Many legislations
do not allow the general deployment of cryptography and a directory
service with public keys. For these reasons, cryptography is
applicable only to a small and closed group of users, but not to
all participants of the e-mail service.
3. A DNS based sender address verification
3.1. Overview
To gain improvement in e-mail authenticity while keeping as much
SMTP compatibility as possible, a method is suggested which doesn't
change SMTP at all.
The idea is to store informations about how to verify who is
authorized to transmit e-mails through SMTP with a particular
sender address (either full address or - for simplicity - only the
domain part of the address) in a directory service, which is
currently the DNS. To be precise, the verification consists of two
steps, the classical pair of authentication and authorization:
The first step is the authentication. While several methods are
possible to perform authentication (see below), the most important
and robust method is the verification of the sender's IP address.
This is done implicitely by TCP/IP and the TCP sequence number. The
authenticated identity is the IP address. It has to be stressed
Hadmut Danisch Experimental [Page 7]
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that this TCP/IP "authentication" is a weak authentication and
vulnerable to several attacks. It is nevertheless sufficient for
this purpose, especially for blocking spam. It doesn't take any
implementation and it doesn't cost: It is already there, it is a
functionality of TCP/IP. An incoming SMTP connection based on
TCP/IP already carries the sender's IP address without any
modification of SMTP. See below (section Entry types) for more
details about authentication methods.
The second step is the authorization. It is based on the identity
given by the previous authentication step, e.g. the IP address of
the originator of the incoming SMTP connection, and on the
envelope sender address. The mechanism proposed in this memo
answers the question "Is that particular sender (IP address,...)
allowed to send with that sender address" by querying and
processing informations stored in a directory service, which is
DNS.
When the sender has issued the "MAIL FROM:" SMTP command, the
receiving mail transfer agent (MTA) can - and modern MTAs do -
perform some authorization checks, e.g. run a local rule database
or check whether the sender domain is resolvable.
The suggested method is to let the DNS server for the sender domain
provide informations about who - this means for example which IP
address - is authorized to use an address or a domain as a part of
it. After receiving the "MAIL FROM:" SMTP command, the receiving
MTA can verify, whether e. g. the IP address of the sending MTA is
authorized to send mails with this domain name. Therefore, a list
of entries with authorized IP addresses or other informations is
provided by the authoritative DNS server of that domain. The entry
types are described in the subsequent chapters. Some of these
methods are
- An IPv4 or IPv6 network address and mask
- A fully qualified domain name referring to an A record
- A fully qualified domain name referring to an APL record
RMX records of these types would look like this:
somedomain.de. IN RMX ipv4:10.0.0.0/8
rmxtest.de. IN RMX host:relay.provider.com
danisch.de. IN RMX apl:relays.rackland.de
relays.rackland.de. IN APL 1:213.133.101.23/32 1:1.2.3.0/24
where the machine with the example address 213.133.101.23 and the
machines in the example subnet 1.2.3.0/24 are the only machines
allowed to send e-mails with an envelope sender address of domain
Hadmut Danisch Experimental [Page 8]
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danisch.de. Since the APL records do not necessarily belong to the
same domain or zone table as the RMX records, this easily allows to
refer to APL records defined by someone else, e.g. the internet
access or server hosting provider, thus reducing administrative
overhead to a minimum. In the example given above, the domain
danisch.de and several other domains are hosted by the service
provider Rackland. So if the relay structure of Rackland is
modified, only the zone of rackland.de needs to be modified. The
domain owners don't need to care about such details.
3.2. Envelope vs. header sender address
Questions were raised why the proposed mechanism is based on the
envelope sender address, and not on the sender address given in the
message header. Technically, both can be used. Actually, it makes
sense to use the envelope address.
In common, the header sender address identifies the author of the
content, while the envelope sender tells who caused the
transmission. The approach proposed in this memo is transmission
based, not content based. We can not authorize the author of a
message if we don't have contact with him, if the message does not
already contain a signature. In contrast, the sending MTA is linked
to an IP address which can be used for authentication. This
mechanism might not be very strong, but it is available and
sufficient to solve today's e-mail security problems.
Some people argued that it is the header address and not the sender
address, which is displayed in common mail readers (MUAs), and
where the receiver believes the mail comes from. That's true, but
it doesn't help. There are many cases where the header sender
differs from the envelope sender for good reasons (see below in the
consequences chapter for the discussion about relaying). Relaying,
mailing lists etc. require to replace the sender address used for
RMX. If this were the header address, the message header would have
to be modified. This is undesirable.
3.3. Domain part vs. full sender address
Former versions of this draft were limited to the domain part of
the sender address. The first reason is that it is common and MX-
like, to lookup only the domain part of an e-mail address in DNS.
The second reason is, that it was left to the private business of
the domain administration to handle details of user verification.
The idea was that the domain administration takes care to verify
the left part of an e-mail address with an arbitrary method of
their individual taste. RMX was originally designed to ignore the
left part of the address and to expect the domain administration to
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take over responsibility for enforcing their policy. If, e.g., a
spam message arrived and passed the RMX mechanism, it is known to
be authorized by the domain administration and they can be blamed,
no matter what is on the left side of the sender address - it's
their private problem what happens on the left side of the @. By
far the most of the comments to prior versions of this draft agreed
with that. A few comments asked for a finer granularity.
And indeed, there is no technical reason against a finer
granularity. All it takes is a mapping from a given envelope
sender address to a DNS name, and the RMX lookup for that
particular e-mail address could be done instead of a lookup for the
domain part only. However, to my knowledge, most domain
administrators would not like to provide an RMX entry for every
single e-mail address. In many cases, this would also overload DNS
servers.
It is to be discussed how to cover both views. One method could be
to query the full address, and if no RMX records were found to
query the domain part only. A different approach would be to query
the domain part only, and if it's RMX record contain a special
entry, then a new query for the full address is triggered. A third
way would be to always query the full address and to leave the
problem to the wildcard mechanism of DNS. This still has to be
discussed and will be described in future versions of this draft.
4. Mapping of E-Mail addresses to DNS names
To perform the RMX query, a mapping is needed from E-Mail addresses
to DNS fully qualified domain names.
This chapter is under development and just a first approach.
4.1. Domain part only
Mapping of the domain part is trivial, since the domain part of an
e-mail address itself is a valid DNS name and does not need
translation. It might be nevertheless desirable to distinguish the
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RMX entries from other entries, depending of the encoding of the
records. If the RMX entries are encoded in TXT record types, they
might collide with other uses of TXT records. It might be
necessary to prepend the domain part with a special prefix, e.g.
_rmx. So the e-mail address some.user@example.com could be mapped
to example.com or _rmx.example.com.
4.2. Full address
Mapping a full address is slightly more difficult. The @ sign must
be unambiguously translated, and therefore can not be simply
translated into a dot. The e-mail addresses some.user@example.com
and some@user.example.com must have different mappings. Therefore,
the @ sign could be translated into _rmx, implicitely assuming that
this is not an allowed domain name component of normal domain
names. Then the rightmost _rmx in the mapped DNS name always
corresponds to the @ sign. some.user@example.com would e translated
into some.user._rmx.example.com and can be covered by a wildcard
entry like *._rmx.example.com.
Character encoding and character sets are still to be discussed.
4.3. Empty address
Unfortunately, SMTP allows empty envelope sender addresses to be
used for error messages. Empty sender addresses can therefore not
be prohibited. As observed, a significant amount of spam was sent
with such an empty sender address. To solve this problem, the host
name given in the HELO or EHLO command is taken to lookup the RMX
records instead. This makes sense, since such messages were
generated by the machine, not a human.
5. Mandatory entry types and their syntax
The entry types described in this section MUST be supported by any
implementation of this draft.
5.1. Overall structure
Similar to APL, an RMX record is just a concatenation of zero or
more RMX entries. The entries within one record form an ordered
rule base as commonly usual in packet filtes and firewall rulesets,
i. e. they are processed one ofter another until the first entry
matches. This entry determines the result of the query. Once a
matching entry is found, the RMX processing is finished.
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For any domain name there should not exist more than a single RMX
record. Due to the structure of DNS, it is nevertheless possible to
have more than a single RMX record. Multiple RMX records are
treated as a single record consisting of the concatenation of all
records. While the entries in a record are ordered, the records are
not ordered and may be processed in arbitrary order. If the order
of the entries matters, it is the zone maintainer's responsibility
to keep those entries in a single record. For example, there are
negative entries, which exclude IP addresses from authorization.
It is important that these entries are processed before positive
entries giving permission to a wider address range. Since order is
guaranteed only within a record, corresponding negative and
positive entries must be put in the same record.
An RMX record may consist of one or more entries, where the entries
are separated by whitespace. An entry must not contain white space.
Each entry consists of an optional exclamation sign, a tag, a
colon, and the entry data:
[!] TAG : ENTRY-SPECIFIC-DATA
If the entry starts with an exclamation sign, the entry is negated.
See the entry type description below for details.
The TAG is the mnemonic type identifier or the decimal number of
the entry. The TAG is case-insensitive. It is immediately followed
by a colon.
The syntax and semantics of ENTRY-SPECIFIC-DATA depends of the the
entry type. See description below.
Example:
danisch.de. IN RMX apl:relays.rackland.de !ipv4:1.2.3.5
ipv4:1.2.3.0/24
5.2. Unused
This is a primitive entry which just says that this sender address
will never be used as a sender address under any circumstances.
Example:
testdomain.danisch.de IN RMX unused:
5.3. IPv4 and IPv6 address ranges
These entry types contain a bit sequence representing a CIDR
address part. If that bit sequence matches the given IP address,
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authorization is granted or denied, depending on the negation flag.
The entry is prepended with the tag "IPv4" or "IPv6". The colon is
followed with an IPv4 or IPv6 address in standard notation,
optionally followed by a slash and a mask length. If the negation
flag is set, then the given address range is excluded. Examples:
danisch.de IN RMX ipv4:213.133.101.23 ipv6:fe00::0
IN RMX ipv4:10.0.0.0/8 ipv6:fec0::0/16
IN RMX !ipv4:1.2.3.4
(Please note that it does not make much sense to use
RFC1918-Addresses in RMX records, this is just to give a syntax
example.)
5.4. DNS Hostname
This entry type simply contains a regular DNS name, which is to be
resolved as a host name (fetch the A record or IPv6 equivalent). If
the given IP address matches the result, authorization is granted
or denied, depending on the negation flag. It is still to be
defined how to treat unresolvable entries.
The entry is prepended with the tag "host", followed by a colon and
the hostname. Examples:
danisch.de IN RMX host:relay.provider.de
IN RMX !host:badmachine.domain.de apl:relays.domain.de
5.4.1. Road warriors and DynDNS entries
Several people argued against RMX that it would break their
existing installation which delivers e-mail from dynamically
assigned IP addresses, because their IP providers didn't assign a
static address, or because they are a road warrior, plugging their
notebook in any hotel room on the world.
RMX provides a simple solution. If such a machine has a dynamically
updated DNS entry (e.g. DynDNS), all it takes is an RMX entry of
the hostname type pointing to this dynamic DNS entry.
The cleaner solution would be to deliver mail the same way as it is
received: If downloaded by POP from a central relay with a static
address, where the MX points to, then it would be a good idea to
deliver e-mail the same way in reverse direction. Unfortunately,
plain POP does not support uploading yet.
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5.5. APL Reference
This entry type simply contains a regular DNS name, which is to be
resolved as an APL record index (fetch the APL record). If the
given IP address positively matches the APL, authorization is
granted. Details of the semantic (espially when the negation bit is
set) are still to be defined. It is still to be defined how to
treat unresolvable entries.
The entry is prepended with the tag "host", followed by a colon and
the hostname. Example:
danisch.de IN RMX apl:relays.rackland.de
5.6. Domain Member
In many cases it is desirable to cover all hosts of a given domain
with an RMX record without the need to duplicate the list of these
hosts. This entry type does it (thanks to Eric A. Hall for pointing
out this entry type). It contains a regular DNS name.
If this entry type is given, a reverse DNS query for the IP address
of the sending MTA is performed to find its official fully
qualified domain name. To prevent spoofing, this domain name is
accepted only if a subsequent address query to the given domain
name points to exactly the IP address of the sending MTA (the usual
procedure to verify PTR records).
The entry matches if the fully qualified domain name of the sending
MTA ends in the given domain. The negation flag works as usual.
The tag for this entry type is "domain". After the colon the domain
name is given, but might be empty, thus pointing to itself.
Example:
somedomain.org IN RMX domain:somedomain.org domain:provider.com
would authorize all machines which's hostname can be verified
through an PTR and A query, and which ends in "somedomain.org" or
"provider.com".
With such an entry, large companies with different networks can
easily be covered with just a single and simple RMX entry.
Obviously, it requires proper PTR records.
As a special shortcut, the DNS name may be empty. In this case the
domain name of the zone itself is taken. Thus, with a very simple
entry of the type
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somecompany.com IN RMX domain:
a company could authorize all machines which's IP addresses map to
DNS names end in somecompany.com, which applies in the majority of
companies.
5.7. Full Address Query
As described above, RMX records will in most cases apply to the
domain part of the sender address. In special cases it might be
desirable to query the RMX record for a particular address. An RMX
entry of the Full Address Query type may occur in a domain RMX
record only. It signals that the RMX record for the full address is
to be fetched and processed.
This entry type does not take arguments. The negation flag is not
supported. The tag is "full".
If such a full address query is to be performed, the mail address
must be mapped to a valid and non-ambiguos DNS name. This mapping
is still to be defined. It is not sufficient to simply replace the
@ with a dot, because of case sensitivity, character sets, etc. The
e-mail addresses
john.doe@example.org
John.Doe@example.org
john@doe.example.org
must all be mapped to different DNS entries. This entry type might
vanish in future versions of the draft, depending on the discussion
about whether to query the domain name part only or the full
address.
5.8. DNS mapped authorization
As I learned from comments to prior versions of the draft and from
alternative proposals, many users wish to have a DNS mapped
authorization table, i. e. the client queries a DNS entry of the
form a.b.c.d.domain, where a.b.c.d is the sender's IP address.
Since people wish to have this, RMX will now include such a mapping
entry. The entry has a parameter giving the DNS domain name where
to look at. If the parameter is empty, then the same domain is
taken as for the RMX lookup.
As this is currently under construction and discussion in an IETF
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group, details will be published in future versions of this draft.
5.9. RMX reference
This entry type has no parameters. It means that all those machines
are authorized, which are pointed to by an MX record.
6. Optional and experimental entry types
The following subsections roughly describe further entry types
which might not be supported by all implementations and might not
be allowed in all legislations. These methods might vanish in
future versions of the draft and are just considerations about what
to include in RMX and what to not include. The main purpose of this
section is to start discussion about such entry types.
The disadvantage of the following methods is that they violate the
basic idea of RMX, i. e. to be simple, robust, easy to implement
and easy to administer. I personally do not believe that it is a
good idea or even feasible to implement cryptography for a world
wide e-mail transfer network. Keep in mind that cryptographic keys
can be copied. If only <0.1% of cryptographic keys were revealed,
this completely compromises and spoils RMX. Cryptography is simply
the wrong tool for the problem RMX is intended to solve. I
nevertheless like to discuss these methods.
6.1. TLS fingerprint
The sender is considered to be authorized if the message was
transmitted through SMTP and TLS, and the sender used a certificate
matching the fingerprint given in the RMX record.
6.2. TLS and LDAP
This means that the receiver should perform an LDAP query for the
sender address (through the LDAP SRV record or given in the RMX
record), fetch the X.509 certificate for the sender. The sender is
considered to be authorized when the message was transmitted
through SMTP and TLS using this certificate.
6.3. PGP or S/MIME signature
It would be possible to accept a message only if it was signed with
PGP or S/MIME with a key which's fingerprint is given in the RMX
record or to be fetched from LDAP or any PGP database. This is
just for discussion, since it violates the idea of RMX to focus on
the transport, not on the content. It would also allow replay
attacks and not cover the envelope sender address or message
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header.
6.4. Transparent Challenge/Response
It would also be possible to implement a challenge-response
mechanism without modifying the syntax of SMTP. For example, the
receiving MTA could issue a challenge with it's very first greeting
message, the sending MTA could hide the response in the HELO
parameter and when the receiving MTA later learns the sender
envelope address, it could verify the response based on
informations in the RMX record.
6.5. SASL Challenge/Response
Modern SMTP implementations already include a SASL mechanisms,
which easily allows to plugin new authentication mechanisms. While
common SASL mechanisms require to use a previously shared password,
a new mechanism could perform a challenge response authentication
as a SASL method.
7. Encoding
7.1. Alternative encoding as TXT records
The main objection against the prior versions of this draft was
that it requires a new RR entry type and upgrading all DNS servers.
Therefore and alternative encoding is proposed. Instead of using a
new RR type, the TXT record type is used to contain the RMX record.
The records would simply look as described in the entry type
chapters above, e.g.
_rmx.danisch.de. IN TXT "apl:relays.rackland.de"
To allow smooth introduction of RMX without the need to immediately
upgrade all DNS servers, all clients (which have to be newly
installed anyway) MUST support both the TXT and the RMX records. A
client has to perform an ANY or a TXT and a RMX query. Servers/zone
tables may currently use TXT entries but SHOULD use RMX entries in
future.
7.2. RMX Records
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7.2.1. Overall structure
Each entry starts with an octet containting the entry type and the
negation flag:
+---+---+---+---+---+---+---+---+------
| N | Entry Type Code | Parameters...
+---+---+---+---+---+---+---+---+------
N If this bit (MSB) is set, an IP address
matching this entry is not authorized,
but explicitely rejected. See entry
type descriptions for details.
Entry Type A 7bit number simply determining the entry
type.
Currently, entries do not have an explicit length field, the entry
length is determined implicitely by the entry type. Applications
are required to abort if an unknown entry type is found, instead of
skipping unknown entries.
7.2.2. Record encoding
A RMX record is simply a concatenation of RMX entries.
7.2.3. Encoding of IPv4 and IPv6 address ranges
After the entry type tag as described above, one octet follows
giving the length L of the bit sequence. Then a sequence of exactly
as many octets follows as needed to carry L bits of information (=
trunc((L+7)/8) ).
+---+---+---+---+---+---+---+---+
| N | Entry Type Code (1 or 2) |
+---+---+---+---+---+---+---+---+
| Length Field L |
+---+---+---+---+---+---+---+---+
| Bit Field |
/ ((L+7)/8) Octets /
+---+---+---+---+---+---+---+---+
7.2.4. Encoding of DNS
After the entry type tag immediately follows a DNS encoded and
compressed [3] domain name.
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+---+---+---+---+---+---+---+---+
| N | Entry Type Code (3..5) |
+---+---+---+---+---+---+---+---+
| Length Field L |
+---+---+---+---+---+---+---+---+
| Encoded DNS |
/ Name as described in RFC1035 /
+---+---+---+---+---+---+---+---+
In contrast to earlier versions of this draft, the DNS name cannot
be compressed, since this would cause decompression errors when a
DNS server is part of the query chain which does not know this
particular RR type.
7.2.5. Encoding of unused and full query
These entries do not contain parameters and does not allow the
negation flag. So the encoding is quite simple:
+---+---+---+---+---+---+---+---+
| 0 | Entry Type Code (6 or 7)|
+---+---+---+---+---+---+---+---+
7.2.6. Additional Records
In order to avoid the need of a second query to resolve the given
host name, a DNS server should enclose the A record for that domain
name in the additional section of the additional section of the DNS
reply, if the server happens to be authoritative.
In order to avoid the need of a second query to resolve the given
host name, a DNS server should enclose the APL record for that
domain name in the additional section of the additional section of
the DNS reply, if the server happens to be authoritative.
8. Message Headers
An RMX query must be followed by any kind of action depending on
the RMX result. One action might be to reject the message. Another
action might be to add a header line to the message body, thus
allowing MUAs and delivery programs to filter or sort messages.
In future, the RMX result might be melted into the Received: header
line.
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The details of such entries are to be discussed. As a proposal the
following form is suggested:
X-RMX: RESULT addr ADDRESS by HOST on DATE mechanism MECHANISM
where
RESULT is one of "Granted", "Denied", "NotInRMX", "NoRMX",
"TempFail", "BadData", "Trusted".
ADDRESS is the IP address of the sending machine
HOST is the name of the machine performing the RMX query.
DATE is the date of the query.
MECHANISM is the RMX method used to authorize the sender.
9. SMTP error messages
If a message is rejected because of RMX records, an error message
should be issued which explains the details. It is to be discussed
whether new SMTP error codes are to be defined.
10. Message relaying and forwarding
10.1. Problem description
Message forwarding and relaying means that an MTA which received an
e-mail by SMTP does not deliver it locally, but resends the message
- usually unchanged except for an additional Received header line
and maybe the recipient's address rewritten - to the next SMTP MTA.
Message forwarding is an essential functionality of e-mail
transport services, for example:
- Message transport from outer MX relay to the intranet
- Message forwarding and Cc-ing by .forward or .procmail-alike
mechanisms
- Mailing list processing
- Message reception by mail relays with low MX priority,
usually provided by third parties as a stand-by service
in case of relay failure or maintenance
- "Forwarding" and "Bouncing" as a MUA functionality
In all these cases a message is sent by SMTP from a host which is
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not covered by the original sender domain's RMX records. While the
RMX records would forbid accepting this message, it still must be
accepted. The following subsections explain how to cope with
relaying.
10.2. Trusted relaying/forwarding
In some cases the receiving MTA trusts the sending MTA to not fake
messages and to already have checked the RMX records at message
reception. As a typical example, a company might have an outer mail
relay which receives messages from the Internet and checks the RMX
records. This relay then forwards the messages to the different
department's mail servers. It does not make sense for these
department mail servers to check the RMX record, since the RMX
records have already been checked and - since the message was
relayed by the outer relay - always would deny the message. In this
case there is a trust relationship between the department relays
and the outer relay. So RMX checking is turned off for trusted
relays. In this example, the department relays would not check
messages from the outer relay (but for intranet security, they
could still check RMX records of the other departments sub-domains
to avoid internal forgery between departments).
Another common example are the low-priority MX relays, which
receive and cache e-mails when the high-priority relays are down.
In this case, the high-priority relay would trust the low-priority
relay to have verified the sender authorization and would not
perform another RMX verification (which would obviously fail).
When a relay forwards a message to a trusting machine, the envelope
sender address should remain unchanged.
10.3. Untrusted relaying/forwarding
If the receiving MTA does not trust the forwarding MTA, then there
is no chance to leave the sender envelope address unchanged. At a
first glance this might appear impracticable, but this is
absolutely necessary. If an untrusted MTA could claim to have
forwarded a message from a foreign sender address, it could have
forged the message as well. Spammers and forgers would just have to
act as such a relay.
Therefore, it is required that, when performing untrusted
forwarding, the envelope sender address has to be replaced by the
sender address of someone responsible for the relaying mechanism,
e.g. the owner of the mailing list or the mail address of the user
who's .forward caused the transmission. It is important to stress
that untrusted relaying/forwarding means taking over responsibility
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for the message. It is the idea of RMX records to tie
responsibility to message transmission. Untrusted relaying without
replacing the sender address would mean to transmit without taking
responsibility.
The disadvantage is that the original sender address is lost.
Therefore, whenever a sender address replacement happens, the
Received-Line must contain the old address. Many of today's MTAs
already insert the envelope recipient address, but not the sender
address into the Received header line. It seems reasonable to
require every Received line to include both the sender and
recipient address of the incoming SMTP connection.
11. Security Considerations
11.1. Draft specific considerations
11.1.1. Authentication strength
It is important to stress, that the suggested method does not
provide high level security and does not completely prevent forged
e-mails or spam under any circumstances. It is a robust, but not
highly reliable and completely secure security mechanism. Keep in
mind that it is based on DNS, and DNS is not secure today.
Authorization is based on the IP address. The very same machine
with the very same IP address could be authorized to send e-mail
with a given sender address and sending spam at the same time.
Maybe because several users are logged in. Or because several
customers use the same relay of the same ISP, where one customer
could use the sender address of a different customer. It is up to
the ISP to prevent this or not. Machines can still be hijacked.
Spammers are also domain owners. They can simply use their own
domain and authorize themselves. You will always find people on the
world who do not care about security and open their relays and RMX
records for others to abuse them. RMX is to be considered as a
very cheap and simple light weight mechanism, which can
nevertheless provide a significant improvement in mail security
against a certain class of attacks, until a successor of SMTP has
been defined and commonly accepted.
11.1.2. Where Authentication and Authorization end
Previous versions of RMX records did not cover the local part of
the e-mail address, i.e. what's on the left side of the @ sign.
This is still to be discussed. Authentication and authorization are
limited to the sending MTA's IP address. The authentication is
limited to the TCP functionality, which is sufficient for light
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weight authentication. The RMX records authorize the IP address of
the sending host only, not the particular sender of the message. So
if a machine is authorized to use sender addresses of more than a
single domain, the authentication scheme does not prevent that any
user on this machine can send with any of these domains. RMX is not
a substitute for the host security of the involved machines.
The proposed authentication scheme can be seen as a "half way
authentication": It does not track back an e-mail to the effective
sender. It tracks only half of the way, i. e. it tracks back to the
domain and it's DNS administrators who authorized that particular
sender IP address to use it for sending e-mail. How the party
responsible for that domain performs user authentication, whom it
grants access to, how it helds people responsible for abuse, is
completely left as the private business of those who are in charge
of that domain. So this draft does not interfere with the domain's
individual security policy or any legislation about such policies.
On the other hand, the proposed authentication scheme does not give
any statement about the nature and quality of the domain's security
policy. This is an essential feature of the proposal: E-mail
authentication must be deployed world wide, otherwise it won't do
the job. Any security scheme interfering with the local
legislations or the domain's security policy will not be accepted
and can't effectively deployed. Therefore, the security policy must
remain the domain's private business, no matter how lousy the
policy might be.
In order to achieve this and to make use of the only existing world
wide Internet directory scheme (DNS), the approach of this proposal
is to just ignore the local part of the sender address (i.e. what's
left of the @ part) and limit view to the domain part. After all,
that's what we do anyway when delivering to a given address with
SMTP.
11.1.3. Vulnerability of DNS
DNS is an essential part of the proposed authentication scheme,
since it requires any directory service, and DNS is currently the
only one available. Unfortunately, DNS is vulnerable and can be
spoofed and poisoned. This flaw is commonly known and weakens many
network services, but for reasons beyond that draft DNS has not
been significantly improved yet. After the first version of this
draft, I received several comments who asked me not to use DNS
because of its lack of security. I took this into consideration,
but came to the conclusion that this is unfeasible: Any
authentication scheme linked to some kind of symbolic identity (in
this case the domain name) needs some kind of infrastructure and
trusted assignment. There are basically two ways to do it: Do it
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yourself and trust nobody else, or let someone else do it. There
are methods to do it the former way, e.g. to give someone some kind
of authentication information after a first successful e-mail
exchange, e.g. some kind of cookie or special e-mail address. This
is certainly interesting and powerful, but it does not solve the
problem on a world wide scale and is far to complicated and error
prone for the average user, i. e. 99% of the users.
The latter method to let someone else do the symbolic name
assignment and create the authentication framework is well known.
It context of public key cryptography, this is called a Public Key
Infrastructure (PKI). On of the best known facts about PKIs is
that, until now, we don't have any covering a significant part of
the Internet. And we won't have any in near future. The complexity
is far too high, it is too expensive, and it involves cooperation
of every single user, which is simply unrealistic and extremely
error prone. So what do we have we can use? All we have is the DNS
and the Whois database. And we have countries who don't allow
cryptography. So the proposal was designed to use DNS without
cryptography. It does not avoid DNS because of its vulnerability,
it asks for a better DNS, but accepts the DNS as it is for the
moment. Currently there are two main threats caused by the DNS
weakness:
- A spammer/forger could spoof DNS in order to gain false
authorization to send fake e-mails.
- An attacker could spoof DNS in order to block delivery from
authorized machines, i. e. perform a Denial of Service attack.
The first one is rather unrealistic, because it would require an
average spammer to poison a significant part of the DNS servers of
its victims. A spammer sending messages to one million receipients
would need to poison at least 1-10% which is 10,000 to 100,000
receipient's DNS servers. This should be unfeasible in most cases.
In contrast, the second threat is a severe one. If an attacker
wanted to block messages from one company to another, he just needs
to poison the recipients DNS server with a wrong RMX record in
order to make the recipient's SMTP machine reject all messages. And
this is feasible since the attacker needs to poison only a single
DNS server. But does this make SMTP more vulnerable? No. Because
the attacker can already do even more without RMX. By poisoning the
sender's DNS server with wrong MX records, the attacker can also
block message delivery or even redirect the messages to the
attacker's machine, thus preventing any delivery error messages and
furthermore getting access to the messages.
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As a consequence, e-mail delivery by SMTP requires a better DNS
anyway. The requirements are not significantly expanded by RMX.
11.1.4. Sneaking RMX attack?
While writing a test implementation, a certain kind of attack came
into my mind. I'm still not sure, whether this attack is possible
on any DNS server, but I believe it should be mentioned:
Imagine an unauthorized sender is sending a forged mail (e.g.
spam). At connection time, before querying the RMX record, the
receiving MTA usually performs a PTR query for the IP address of
the sending MTA. If the sender has control over the authoritative
name server for that particular IP address, the sender could give a
normal PTR answer, but could append a wrong RMX, APL, or A record
in the additional section of the query. A subsequent RMX query
could receive wrong DNS data if the DNS server used by the
receiving MTA accepted those forged records.
11.1.5. Open SMTP relays
Open SMTP relays (i.e. machines who accept any e-mail message from
anyone and deliver to the world) abused by spammers are a one of
the main problems of spam defense and sender backtracking. In most
cases this problem just vanishes because foreign open relay
machines will not be covered by the RMX records of the forged
sender address. But there are two special cases:
If the spammer knows about a domain which authorizes this
particular machine, that domain can be used for forgery. But in
this case, the IP address of the relay machine and the RMX records
of the domain track back to the persons responsible. Both can be
demanded to fix the relay or remove the RMX record for this
machine. An open relay is a security flaw like leaving the machine
open for everybody to login and send random mails from inside. Once
the administrative persons refuse to solve the problem, they can be
identified as spammers and held responsible.
The second special case is when a domain authorizes all IP
addresses by having the network 0.0.0.0/0 in the RMX/APL record. In
this case, open relays don't make things worse. It's up to the
recipient's MTA to reject mails from domains with loose security
policies.
11.1.6. Unforged Spam
This proposal does not prevent spam (which is, by the way, not yet
exactly defined), it prevents forgery. Since spam is against law
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and violates the recipients rights, spam depends on untracability
of the sender. In practice the sender forges the sender address
(other cases see below). This proposal is designed to detect such
forgeries.
However, the RMX approach is rendered ineffective, if the sender
doesn't forge. If the sender uses just a normal address of it's own
domain, this is just a plain, normal e-mail, which needs to be let
through. Since it is up to the human's taste whether this is spam
or not, there's no technical way to reliably identify this as spam.
But since the sender domain is known, this domain can be
blacklisted or legal steps can be gone into.
11.1.7. Reliability of Whois Entries
Once the RMX infrastructure gets deployed, what's the security
gain? It allows to determine the domain which's DNS zone
authorized the sending machine. What's that good for? There are
some immediate uses of the domain name, e.g. in black- and
whitelisting. But in most cases this is just the starting point of
further investigations, either performed automatically before
message acceptance, or manually after spam has been received and
complainted about.
The next step after determining the domain is determining the
people responsible for this domain. This can sometimes be achieved
by querying the Whois databases. Unfortunately, many whois entries
are useless because they are incomplete, wrong, obsolete, or in
uncommon languages. Furthermore, there are several formats of
address informations which make it difficult to automatically
extract the address. Sometimes the whois entry identifies the
provider and not the owner of the domain. Whois servers are not
built for high availability and sometimes unreachable.
Therefore, a mandatory standard is required about the contents and
the format of whois entries, and the availability of the servers.
After receiving the MAIL FROM SMTP command with the sender envelope
address, the receiving MTA could check the RMX record and Whois
entry. If it doesn't point to a real human, the message could be
rejected and an error message like "Ask your provider to fix your
Whois entry" could be issued. Obviously, domain providers must be
held responsible for wrong entries. It might still be acceptable to
allow anonymous domains, i. e. domains which don't point to a
responsible human. But it is the receivers choice to accept e-mails
from such domains or not.
11.1.8. Hazards for Freedom of Speech
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Currently, some governments try to enforce limitations of internet
traffic in order to cut unwanted content providers from the
network. Some of these governments try to hide a whole country
behind firewalls, others try to force Internet providers to poison
DNS servers with wrong A records for web servers, e.g. one county
administration in Germany tries to do so. If message reception
depends on DNS entries, the same governments will try to block not
only HTTP, but SMTP also.
However, since most MTAs already reject messages from unresolvable
domain names this is not a new threat.
11.2. General Considerations about spam defense
After discussing security requirements of the proposal, now the
security advantages of the RMX approach over content based filters
will be explained. Basically, there are three kinds of content
filters:
- Those who upload the message or some digest to an external
third party and ask "Is this spam"?
- Those who download a set of patterns and rules from a third
party and apply this set to incoming messages in order to
determine whether it is spam.
- Those who are independent and don't contact any third party,
but try to learn themselves what is spam and what isn't.
The message filters provided by some e-mail service providers are
usually not a kind of their own, but a combination of the first two
kinds.
11.2.1. Action vs. reaction
Content filters suffer from a fundamental design problem: They are
late. They need to see some content of the same kind before in
order to learn and to block further distribution.
This works for viruses and worms, which redistribute. This doesn't
work for spam, since spam is usually not redistributed after the
first delivery. When the filters have learned or downloaded new
pattern sets, it's too late.
This proposal does not have this problem.
11.2.2. Content based Denial of Service attacks
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All three kinds of content filters, but especially the second and
the third kind are vulnerable to content based Denial of Service
attacks.
If some kind of third party (e.g. non-democratic government,
intellectual property warriors, religious groups, military, secret
services, patriots, public relation agents, etc.) wants certain
contents not to be distributed, they could either poison the
pattern/rule databases or feed wrong sets to particular receivers.
Such pattern/rule sets are the perfect tool for censoring e-mail
traffic and denial of service attacks by governments and other
parties, and a similar threat are virus filters. E. g. the content
industry could demand to teach all virus and spam filters to delete
all e-mails containing the URL of an MP3 web server outside the
legislations. Software manufacturers could try to block all e-mails
containing software license keys, thus trying to make unallowed
distribution more difficult. Governments could try to block
distribution of unwanted informations.
This proposal does not have this problem.
12. Privacy Considerations
(It was proposed on the 56th IETF meeting to have a privacy section
in drafts and RFCs.)
12.1. Draft specific considerations
12.1.1. No content leaking
Since the RMX approach doesn't touch the contents of a message in
any way, there is obviously no way of leaking out any information
about the content of the message. RMX is based solely on the
envelope recipient address. However, methods to fix problems not
covered by RMX might allow content leaking, e.g. if the acceptance
of a message with an empty sender address requires the reference to
the message id of an e-mail recently sent, this allows an attacker
to verify whether a certain message was delivered from there.
12.1.2. Message reception and sender domain
Message delivery triggers RMX and APL requests by the recipient.
Thus, the admin of the DNS server or an eavesdropper could learn
that the given machine has just received a message with a sender
from this address, even if the SMTP traffic itself had been
encrypted.
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However, most of today's MTAs do query the MX and A records of the
domain after the MAIL FROM command, so this is not a real new
threat.
12.1.3. Network structure
Since RMX and its associated APL records provide a complete list of
all IP addresses of hosts authorized to send messages from this
address, they do reveal informations about the network structure
and maybe the lifestyle of the domain owner, since a growing number
of domains are owned by single persons or families. E.g. the RMX
records could reveal where someone has his job or spends his time
at weekends.
If such informations are to be kept secret, it is the user's job to
not sent e-mails from there and to relay them from non-compromising
IP addresses.
12.1.4. Owner information distribution
As described above, RMX depends partly on the reliability of the
whois database entries. It does not make anonymous domains
impossible, but it requires to keep the database entries "true", i.
e. if a whois entry does not contain informations about the
responsible person, this must be unambigously labeled as anonymous.
It must not contain fake names and addresses to pretend a non-
existing person. However, since most Internet users on the world
feel extremely annoyed by spam, they will urge their MTA admin to
reject messages from anonymous domains. The domain owner will have
the choice to either remain anonymous but be not able to send e-
mail to everyone in the world, or to be able but to reveal his
identity to everyone on the world.
It would be possible to provide whois-like services only to
recipients of recent messages, but this would make things too
complicated to be commonly adopted.
12.2. General Considerations about spam defense
12.2.1. Content leaking of content filters
As described above in the Security chapter, there are spam filters
which inherently allow leakage of the message body. Those filters
upload either the message body, or in most cases just some kind of
checksum to a third party, which replies whether this is to be seen
as spam or not. The idea is to keep a databases of all digests of
all messages. If a message is sent more often than some threshold,
it is to be considered as a mass mail and therefore tagged as spam.
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While the digest itself does not reveal the content of the message,
it perfectly reveals where a particular message has been delivered
to. If a government finds just a single unwanted message, if a
software manufacturer finds a single message with a stolen product
license key, if someone finds a message with unpatriotic content,
it takes just a single database lookup to get a list of all people
who received this particular message. Content filters with digest
upload are the perfect "Big Brother".
12.2.2. Black- and Whitelists
Some proposals against spam are based on a central database of
white- or blacklisted IP addresses, Sender names, Message IDs or
whatever. Again, there is a central database which learns who has
received which e-mail or from which sender with every query. This
allows tracking relations between persons, which is also a breach
of privacy.
13. Deployment Considerations
13.1. Compatibility
13.1.1. Compatibility with old mail receivers
Since the suggested extension doesn't change the SMTP protocol at
all, it is fully compatible with old mail receivers. They simply
don't ask for the RMX records and don't perform the check.
13.1.2. Compatibility with old mail senders
Since the SMTP protocol is unchanged and the SMTP sender is not
involved in the check, the method is fully compatible with old mail
senders.
13.1.3. Compatibility with old DNS clients
Since the RMX is a new RR, the existing DNS protocol and zone
informations remain completely untouched.
If RMX is provided as a TXT record instead, it must be ensured that
no other software is misinterpreting this entry.
13.1.4. Compatibility with old DNS servers
Full compatibility: If the server does not support RMX records, RMX
in TXT records can be used.
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13.2. Enforcement policy
Obviously, for reasons of backward compatibility and smooth
introduction of this scheme, RMX records can't be required
immediately. Domains without RMX records must temporarily be
treated the same way as they are treated right now, i.e. e-mail
must be accepted from anywhere. But once the scheme becomes
sufficiently widespread, mail relays can start to refuse e-mails
with sender addresses from domains without RMX records, thus
forcing the owner of the domain to include a statement of
authorization into the domain's zone table. Domain owners will
still be free to have an RMX record with a network and mask
0.0.0.0/0, i.e. to allow e-mails with that domain from everywhere.
On the other hand, mail receivers will be free to refuse mails from
domains without RMX records or RMX records which are too loose.
Advanced MTAs might have a configuration option to set the maximum
number of IP addresses authorized to use a domain. E-mails from a
domain, which's RMX records exceed this limit, would be rejected.
For example, a relay could reject e-mails from domains which
authorize more than 8 IP addresses. That allows to accept e-mails
only from domains with a reasonable security policy.
14. General considerations about fighting spam
Is there a concise technical solution against spam? Yes.
Will it be deployed? Certainly not.
Why not? Because of the strong non-technical interests of several
parties against a solution to the problem, as described below.
Since these are non-technical reasons, they might be beyond the
scope of such a draft. But since they are the main problems that
prevent fighting spam, it is unavoidable to address them. This
chapter exists temporarily only and should support the discussion
of solutions. It is not supposed to be included in a later RFC.
14.1. The economical problem
As has been recently illustrated in the initial session of the
IRTF's Anti Spam Research Group (ASRG) on the 56th IETF meeting,
sending spam is a business with significant revenues.
But a much bigger business is selling Anti-Spam software. This is a
billion dollar market, and it is rapidly growing. Any simple and
effective solution against spam would defeat revenues and drive
several companies into bankrupt, would make consultants jobless.
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Therefore, spam is essential for the Anti-Spam business. If there
is no spam, then no Anti-Spam software can be sold, similar to the
Anti-Virus business. There are extremely strong efforts to keep
this market growing. Viruses, Worms, and now spam are just perfect
to keep this market alive: It is not sufficient to just buy a
software. Databases need to be updated continuously, thus making
the cash flow continuously. Have a single, simple, and permanent
solution to the problem and - boom - this billion dollar market is
dead.
That's one of the reasons why people are expected to live with
spam. They have to live with it to make them buy Anti-Spam
software. Content filters are perfect products to keep this market
alive.
14.2. The POP problem
Another problem is the history of mail delivery. Once upon a time,
there used to be very few SMTP relays which handled the e-mail
traffic of all the world, and everybody was happy with that. Then
odd things like Personal Computers, which are sometimes switched
off, portable computers, dynamicly assigned IP addresses, IP access
from hotel rooms, etc. was invented, and people became unhappy,
because SMTP does not support delivery to such machines. To make
them happy again, the Post Office Protocol[4] was invented, which
turned the last part of message delivery from SMTP's push style
into a pull style, thus making virtually every computer on the
world with any random IP address a potential receiver of mails for
random domains. Unfortunately, only receiving e-mail was covered,
but sending e-mail was left to SMTP.
The result is that today we have only very few SMTP relays pointed
to by MX records, but an extreme number of hosts sending e-mail
with SMTP from any IP address with sender addresses from any
domain. Mail delivery has become very asymmetric. Insecurity,
especially forgeability, has become an essential part of mail
transport.
That problem could easily be fixed: Use protocols which allow
uploading of messages to be delivered. If a host doesn't receive
messages by SMTP, it shouldn't deliver by SMTP. Mail delivery
should go the same way back that incoming mail went in. This is
not a limitation to those people on the road who plug their
portable computer in any hotel room's phone plug and use any
provider. If there is a POP server granting download access from
anywhere, then the same server should be ready to accept uploading
of outgoing messages.
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But as I saw from the comments on the first version of this draft,
people religiously insist on sending e-mail with their domain from
any computer with any IP address in the world, e.g. when visiting a
friend using her computer. It appears to be impossible to convince
people that stopping mail forgery requires every one of them to
give up forging.
14.3. The network structure problem
A subsequent problem is that many organisations failed to implement
a proper mail delivery structure and heavily based their network on
this asymmetry. I received harsh comments from Universities who
were unable to give their network a good structure. While they do
have a central mail relay for incoming mail to the universities
domain, they developed a structure where every member of the
University randomly sends e-mails with that University's domain as
a sender address from home or everywhere in the world with any
dynamically assigned IP address from any provider. So this domain
is to be used from every possible IP address on earth, and they are
unable to operate any authentication scheme. Furthermore, they were
unable to understand that such a policy heavily supports spam and
that they have to expect that people don't accept such e-mails
anymore once they become blacklisted.
As long as organisations insist on having such policies, spammers
will have a perfect playground.
14.4. The mentality problem
Another problem is the mentality of many internet users of certain
countries. I received harsh comments from people who strongly
insisted on the freedom to send any e-mail with any sender address
from anywhere, and who heavily refused any kind of authentication
step or any limitation, because they claimed that this would
infringe their constitutional "Freedom of speech". They are
undeviatingly convinced that "Freedom of speech" guarantees their
right to talk to everybody with any sender address, and that is has
to be kept the recipient's own problem to sort out what he doesn't
want to read - on the recipient's expense.
It requires a clear statement that the constitutional "Freedom of
Speech" does not cover molesting people with unsolicited e-mail
with forged sender address.
14.5. The identity problem
How does one fight against mail forgery? With authentication. What
is authentication? In simple words: Making sure that the sender's
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real identity meets the recipients idea of who is the sender, based
on the sender address which came with the message.
What is identity? It is the main problem. Several countries have
different ideas of "identity", which turn out to be somehow
incompatible. In some countries people have identity cards and
never change their name and birthday. Identities are created by
human birth, not by identity changes. Other countries do not have
such a tight idea about identity. People's temporary identity is
based on nothing more than a driving license and a social security
number. With this background, it is virtually impossible to create
a trustworthy PKI covering all Internet users. I learned that it is
extremely difficult to convince some people to give up random e-
mail sending.
14.6. The multi-legislation problem
Many proposals about fighting spam are feasible under certain
legislations only, and are inacceptable under some of the
legislations. But a world wide applicable method is required.
That's why the approach to ask everone on the world to sign
messages with cryptographic keys is not feasible.
Implementation and further Information
Further informations and a test implementation are available at
http://www.danisch.de/work/security/antispam.html
http://www.danisch.de/software/rmx/
Additional informations and a technology overview are also
available at
http://www.mikerubel.org/computers/rmx_records/
References
1. S. Bradner, "Key words for use in RFCs to Indicate Requirement Lev-
els," RFC 2119 (March 1997).
2. J. Klensin, "Simple Mail Transfer Protocol," RFC 2821 (April 2001).
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3. P. Mockapetris, "DOMAIN NAMES - IMPLEMENTATION AND SPECIFICATION,"
RFC 1035 (November 1987).
4. J. Myers, M. Rose, "Post Office Protocol - Version 3," RFC 1939
(May 1996).
Draft History
00 Dec 2002
01 Apr 2003
02 Jun 2003
03 Oct 2003
Author's Address
Hadmut Danisch
Tennesseeallee 58
76149 Karlsruhe
Germany
Phone: ++49-721-843004 or ++49-351-4850477
E-Mail: rfc@danisch.de
Comments
Please send comments to rfc@danisch.de.
Expiry
This drafts expires on Apr 1, 2004.
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