One document matched: draft-ietf-enum-experiences-05.txt
Differences from draft-ietf-enum-experiences-04.txt
ENUM L. Conroy
Internet-Draft RMRL
Expires: December 27, 2006 K. Fujiwara
JPRS
June 25, 2006
ENUM Implementation Issues and Experiences
<draft-ietf-enum-experiences-05.txt>
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This Internet-Draft will expire on December 27, 2006.
Copyright Notice
Copyright (C) The Internet Society (2006).
Abstract
This document captures experience in implementing systems based on
the ENUM protocol, and experience of ENUM data that have been created
by others. As such, it is advisory, and produced as a help to others
in reporting what is "out there" and the potential pitfalls in
interpreting the set of documents that specify the protocol.
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Table of Contents
1. Terminology . . . . . . . . . . . . . . . . . . . . . . . . . 3
2. Introduction . . . . . . . . . . . . . . . . . . . . . . . . . 4
2.1. Interpretation of Recommendations . . . . . . . . . . . . 4
3. Character Sets and ENUM . . . . . . . . . . . . . . . . . . . 6
3.1. Character Sets - Non-ASCII considered harmful . . . . . . 6
3.2. Case Sensitivity . . . . . . . . . . . . . . . . . . . . . 9
3.3. RegExp field delimiter . . . . . . . . . . . . . . . . . . 9
3.4. RegExp Meta-character Issue . . . . . . . . . . . . . . . 10
4. ORDER/PRIORITY Processing . . . . . . . . . . . . . . . . . . 11
4.1. Order/Priority values - general processing . . . . . . . . 11
4.2. NAPTRs with identical ORDER/PRIORITY values . . . . . . . 13
4.2.1. Compound NAPTRs and implicit ORDER/REFERENCE Values . 13
4.3. Compound NAPTR Processing . . . . . . . . . . . . . . . . 14
4.4. Processing Order value across Zones . . . . . . . . . . . 14
5. Non-Terminal NAPTR Processing . . . . . . . . . . . . . . . . 16
5.1. Non-Terminal NAPTRs - necessity . . . . . . . . . . . . . 16
5.2. Non-Terminal NAPTRs - future implementation . . . . . . . 17
5.2.1. Non-Terminal NAPTRs - general . . . . . . . . . . . . 17
5.2.2. Non-Terminal NAPTRs - loop detection and response . . 17
5.3. Interpretation of RFC 3403 and RFC 3761 . . . . . . . . . 18
5.3.1. Flags field content with Non-Terminal NAPTRs . . . . . 18
5.3.2. Services field content with Non-Terminal NAPTRs . . . 18
5.3.3. Regular Expression and Replacement field content
with non-terminal NAPTRs . . . . . . . . . . . . . . . 19
6. General DNS Issues . . . . . . . . . . . . . . . . . . . . . . 22
6.1. DNS Specifications . . . . . . . . . . . . . . . . . . . . 22
6.2. ENUM needs EDNS0 support . . . . . . . . . . . . . . . . . 22
6.3. ENUM EDNS0 message size support . . . . . . . . . . . . . 24
6.4. Intermediary Devices . . . . . . . . . . . . . . . . . . . 25
6.5. Times To Live and NAPTRs . . . . . . . . . . . . . . . . . 26
7. Backwards Compatibility . . . . . . . . . . . . . . . . . . . 28
7.1. Services field syntax . . . . . . . . . . . . . . . . . . 28
8. Security Considerations . . . . . . . . . . . . . . . . . . . 30
9. IANA Considerations . . . . . . . . . . . . . . . . . . . . . 31
10. Acknowledgements . . . . . . . . . . . . . . . . . . . . . . . 32
11. References . . . . . . . . . . . . . . . . . . . . . . . . . . 33
11.1. Normative References . . . . . . . . . . . . . . . . . . . 33
11.2. Informative References . . . . . . . . . . . . . . . . . . 34
Authors' Addresses . . . . . . . . . . . . . . . . . . . . . . . . 35
Intellectual Property and Copyright Statements . . . . . . . . . . 36
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1. Terminology
This document is Advisory, and does not specify a standard of any
kind. Note that recommendations here contain the words "MUST",
"REQUIRE", "SHOULD", and "MAY". This particular document does not
form a standard and so these terms DO NOT hold their normative
definitions. The proposals include these terms from observation of
behaviour and for internal consistency, where Client and Server
recommendations have to match.
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2. Introduction
The ENUM protocol ([1]) and the Dynamic Delegation Discovery System
(DDDS, [2] [3] [4] [5] [6]) are defined elsewhere, and those
documents alone form the normative definition of the ENUM system.
Unfortunately, this document cannot provide an overview of the
specifications, so the reader is assumed to have read and understood
the complete set of ENUM normative documents.
From experience of creating ENUM data and of developing client
systems to process that data it is apparent that there are some
subtleties in the specifications that have led to different
interpretations; in addition there are common syntactic mistakes in
data currently "out there" on the Internet.
This document is intended to help others avoid the potential pitfalls
in interpreting the set of documents that specify the protocol. It
also reports the kind of data they will "find" and so how to process
the intent of the publisher of that ENUM data, regardless of the
syntax used. As such, it is in keeping with the principle evinced in
RFC 791 that "In general, an implementation must be conservative in
its sending behavior, and liberal in its receiving behavior".
Of course, no client should fail if it receives data that is illegal;
typical "defensive programming" techniques should be applied with
ENUM clients as with any other protocol handler. DNS processing does
add some factors not typical for other protocols. For example, it is
legal (but unwise) for a string within a NAPTR to include a NUL
character (U+0000). Such a character can even legally be used as a
delimiter in the RegExp field. This may well cause problems for many
clients that rely on simplistic 'C' string processing libraries.
Whilst we advise specifically against that (see Section 3.3), and
more generally, use of "non-printable" characters (see Section 3.1),
a client may encounter these and must not assume that everyone shares
the same assumptions on design or data validity; a string has a very
specific meaning in DNS. Finally, note that the DDDS system is
intricate and so in some places there are several potential
interpretations of the specifications. This document proposes a
suggested interpretation for some of these points, but they are just
that; suggestions.
2.1. Interpretation of Recommendations
Any ENUM implementation issue has two sides:
o the "Server" side covering the expected behaviour of the ENUM zone
provisioning system and expectations Registrants may make, and
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o the "Client" side covering behaviour that has been observed and
that can be expected of the Client, together with the expectations
that an end user who requests an ENUM lookup may make.
For each of the issues, we have split the recommendations into
"Client" and "Server" proposals. In three cases, we have indicated
proposals that relate to ENUMservice specifications, rather than
implementations; these are labelled as "Spec". Also, there is one
recommendation that concerns "Middleboxes" (such as any intervening
Firewalls) rather than the DNS entities involved directly in an ENUM
query. This recommendation is labelled as "MidBox".
Few if any Client programs handling ENUM NAPTRs have implemented all
of the features described in RFC 3761 and in the DDDS specifications.
Thus the recommendations have tried to follow best practice rather
than leaving interpretation to each of the individual implementation
teams. Likewise, we have reflected the likely behaviour of Client
programs, rather than being purely prescriptive. Any developer of
Provisioning Systems that populate ENUM NAPTRs will need to know what
his or her "opposite number" developing Client programs has decided -
to do anything else would be a disservice.
There are undoubtedly other issues, and developers are asked to raise
any others they find on the appropriate IETF Working group's mailing
list and/or by e-mail to the authors (see later for contact
information). Finally, note that the authors are not aware of any
IPR issues that are involved in the suggestions made in this
document.
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3. Character Sets and ENUM
3.1. Character Sets - Non-ASCII considered harmful
RFC 3761 and RFC 3403 ([1] and [2]) specify respectively that ENUM
and NAPTRs support Unicode using the UTF-8 encoding specified in [7].
This raises an issue where implementations use "single byte" string
processing routines. If there are multi-byte characters within an
ENUM NAPTR, incorrect processing may well result from these "UTF-8
unaware" systems.
The UTF-8 encoding has a "US-ASCII equivalent range", so that all
characters in US-ASCII [20] from 0x00 to 0x7F hexadecimal have an
identity map to the UTF-8 encoding; the encodings are the same. In
UTF-8, characters with Unicode code points above this range will be
encoded using more than one byte, all of which will be in the range
0x80 to 0xFF hexadecimal. Thus it is important to consider the
different fields of a NAPTR and whether or not multi-byte characters
can or should appear in them.
In addition, characters in the "non-printable" portion of US-ASCII
(0x00 to 0x1F hexadecimal, plus 0x7F hexadecimal) are "difficult".
Although NAPTRs are processed by machine, they may sometimes need to
be written in a "human readable" form. Similarly, if NAPTR content
is shown to an end user so that he or she may choose, it is important
that the content is "human readable". Thus it is unwise to use non-
printable characters within the US-ASCII range; the ENUM client may
have good reason to reject NAPTRs that include these characters as
they cannot readily be presented to an end-user.
There are two numeric fields in a NAPTR; the ORDER and PREFERENCE/
PRIORITY fields. As these contain binary values, no risk is involved
as string processing should not be applied to them. The "string
based" fields are the Flags, Services, and RegExp fields. The
Replacement field holds a domain name encoded according to the
standard DNS mechanism [8][9]. With the introduction of
Internationalized Domain Name (IDN) support, this domain name MUST be
further encoded using Punycode [10]. As this holds a domain name
that is not subject to replacement or modification (other than
Punycode processing), it is not of concern here.
Taking the string fields in turn, the Flags field contains characters
that indicate the disposition of the NAPTR. This may be empty, in
which case the NAPTR is "non-terminal", or it may include a flag
character as specified in RFC 3761. These characters all fall into
the US-ASCII equivalent range, so multi-byte characters cannot occur.
The Services field includes the DDDS Application identifier ("E2U")
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used for ENUM, the '+' character used to separate tokens, and a set
of ENUMservice identifiers, any of which may include the ':'
separator character. In section 2.4.2 of RFC 3761 these identifiers
are specified as 1*32 ALPHA/DIGIT, so there is no possibility of non-
ASCII characters in the Services field.
The RegExp field is more complex. It forms a sed-like substitution
expression, defined in [2], and consists of two sub-fields:
o the POSIX Extended Regular Expression (ERE) sub-field [11]
o a replacement (repl) sub-field [2].
Additionally, RFC 3403 specifies that a flag character may be
appended, but the only flag currently defined there (the 'i' case
insensitivity flag) is not appropriate for ENUM - see later in this
document.
The ERE sub-field matches against the "Application Unique String";
for ENUM, this is defined in RFC 3761 to consist of digit characters,
with an initial '+' character. It is similar to a global-number-
digits production of a tel: URI, as specified in [12], but with
visual-separators removed. In short, it is a telephone number (see
[13]) in restricted format. All of these characters fall into the
US-ASCII equivalent range of UTF-8 encoding, as do the characters
significant to the ERE processing. Thus, for ENUM, there will be no
multi-byte characters within this sub-field.
The repl sub-field can include a mixture of explicit text used to
construct a URI and characters significant to the substitution
expression, as defined in RFC 3403. Whilst the latter set all fall
into the US-ASCII equivalent range of UTF-8 encoding, this might not
be the case for all conceivable text used to construct a URI.
Presence of multi-byte characters could complicate URI generation and
processing routines.
URI generic syntax is defined in [14] as a sequence of characters
chosen from a limited subset of the repertoire of US-ASCII
characters. The current URIs use the standard URI character
"escaping" rules specified in the URI generic syntax, and so any
multi-byte characters will be pre-processed; they will not occur in
the explicit text used to construct a URI within the repl sub-field.
However, the Internationalized Resource Identifier (IRI) is defined
in [15] as extending the syntax of URIs, and specifies a mapping from
an IRI to a URI. IRI syntax allows characters with multi-byte UTF-8
encoding.
Given that this is the only place within an ENUM NAPTR where such
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multi-byte encodings might reasonably be found, a simple solution is
to use the mapping method specified in section 3.1 of [15] to convert
any IRI into its equivalent URI.
This process consists of two elements; the domain part of an IRI MUST
be processed using Punycode if it has a non-ASCII domain name, and
the remainder MUST be processed using the extended "escaping" rules
specified in the IRI document if it contains characters outside the
normal URI repertoire. Using this process, there will be no non-
ASCII characters in any part of any URI, even if it has been
converted from an IRI that contains such characters.
Taking into account the existing client base, it is RECOMMENDED that:
Spec ENUMservice registrations should REQUIRE that any static
text in the repl sub-field is encoded using only characters
in the US-ASCII equivalent range that are "printable". If
any of the static text characters do fall outside this
range then they MUST be pre-processed using an IRI/
URI-specific "escape" mechanism to re-encode them only
using US-ASCII equivalent printable characters (those in
the range U+0020 to U+007E).
At the least, it is RECOMMENDED that:
Spec Any ENUMservice registration that allows characters
requiring multi-byte UTF-8 encoding to be present in the
repl sub-field must have a clear indication that there may
be characters outside of the US-ASCII equivalent range.
Such an ENUMservice registration is strongly discouraged,
as the mechanisms specified in section 3.1 of [15] will
suffice.
Finally, the majority of ENUM clients in use today do not support
multi-byte encodings of the Unicode Consortium's Universal Character
Set (UCS). This is a reasonable choice, particularly for "small
footprint" implementations, and they may not be able to support NAPTR
content that is non-printable as they need to present the content to
an end user for selection. Thus, it is RECOMMENDED that:
Client ENUM clients may discard NAPTRs in which they detect
characters not in the US-ASCII "printable" range (0x20 to
0x7E hexadecimal).
ENUM zone provisioning systems should consider this. It is
RECOMMENDED that:
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Server ENUM zone provisioning systems should not use non-ASCII
characters in the NAPTRs they generate unless it is clear
that all ENUM clients they are designed to support will be
able correctly to process such characters.
3.2. Case Sensitivity
The only place where NAPTR field content is case sensitive is in any
static text in the repl sub-field of the RegExp field. Everywhere
else, case insensitive processing can be used.
The case insensitivity flag ('i') could be added at the end of the
RegExp field. However, in ENUM, the ERE sub-field operates on a
string defined as the '+' character, followed by a sequence of digit
characters. Thus this flag is redundant for E2U NAPTRs, as it does
not act on the repl sub-field contents.
To avoid the confusion that this generates, It is RECOMMENDED that:
Server When populating ENUM zones with NAPTRs, provisioning
systems should not use the 'i' RegExp field flag, as it has
no effect and some ENUM clients do not expect it.
Client ENUM clients should not assume that the delimiter is the
last character of the field.
3.3. RegExp field delimiter
It is not possible to select a delimiter character that cannot appear
in one of the sub-fields. Some old clients are "hardwired" to expect
the character '!' as a delimiter. This is used in an example in RFC
3403.
It is RECOMMENDED that:
Server ENUM zone provisioning systems should use '!' (U+0021) as
their RegExp delimiter character.
Client ENUM clients may discard NAPTRs that do not use '!' as a
RegExp delimiter.
This character cannot appear in the ERE sub-field. It may appear in
the content of some URIs, as it is a valid character (e.g. in http
URLs). Thus, it is further RECOMMENDED that:
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Server ENUM zone provisioning systems must ensure that, if the
RegExp delimiter is a character in the static text of the
repl sub-field, it must be "escaped" using the escaped-
delimiter production of the BNF specification shown in
section 3.2 of RFC 3402 (i.e. "\!", U+005C U+0021).
Finally, in keeping with RFC 3402:
Client ENUM clients should discard NAPTRs that have more or less
than 3 "unescaped" instances of the delimiter character
within the RegExp field.
3.4. RegExp Meta-character Issue
In ENUM, the ERE sub-field may include a literal character '+', as
the Application Unique String on which it operates includes this.
However, if it is present, then '+' must be "escaped" using a single
backslash character as '+' is a meta-character in POSIX Extended
Regular Expression syntax.
The following NAPTR example is incorrect:
* IN NAPTR 100 10 "u" "E2U+sip" "!^+46555(.*)$!sip:\1@example.net!" .
This example MUST be written as:
* IN NAPTR 100 10 "u" "E2U+sip" "!^\+46555(.*)$!sip:\1@example.net!"
.
Thus, it is RECOMMENDED that:
Server If present in the ERE sub-field of an ENUM NAPTR, '+' must
be written as "\+" (i.e. U+005C U+002B).
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4. ORDER/PRIORITY Processing
4.1. Order/Priority values - general processing
RFC 3761 and RFC 3403 state that the ENUM client MUST sort the NAPTRs
using the ORDER field value ("lowest value is first") and SHOULD
order the NAPTRs using the PREFERENCE/PRIORITY field value as the
minor sort term (again, lowest value first). The NAPTRs in the
sorted list must be processed in order. Subsequent NAPTRs with less
preferred ORDER values must only be dealt with once the current ones
with a "winning" ORDER value have been processed.
However, this expected behaviour is a simplification; ENUM clients
may not behave this way in practice, and so there is a conflict
between the specification and practice. For example, ENUM clients
will be incapable of using most NAPTRs as they do not support the
ENUMservice (and the URI generated by those NAPTRs). As such, they
will discard the "unusable" NAPTRs and continue with processing the
"next best" NAPTR in the list.
The end user may have pre-specified his or her own preference for
services to be used. Thus, an end user may specify that he or she
would prefer to use contacts with a "sip" ENUMservice, and then those
with "email:mailto" service, and is not interested in any other
options. Thus the sorted list as proposed by the Registrant (and
published via ENUM) may be reordered. For example, a NAPTR with a
"sip" ENUMservice may have a "losing" ORDER field value, and yet is
chosen before a NAPTR with an "h323" ENUMservice and a "winning"
ORDER value. This may occur even if the node the end user controls
is capable of handling other ENUMservices.
ENUM clients may also include the end user "in the decision loop",
offering the end user the choice from a list of possible NAPTRs.
Given that the ORDER field value is the major sort term, one would
expect a conforming ENUM client to present only those NAPTRs with a
"winning" ORDER field value as choices. However, if all the options
presented had been rejected, then the ENUM client might offer those
with the "next best" ORDER field value, and so on. As this may be
confusing for the end user, some clients simply offer all of the
available NAPTRs as options to the end user for his or her selection
"in one go".
In summary, some ENUM clients will take into account the Services
field value along with the ORDER and PREFERENCE/PRIORITY field
values, and may consider the preferences of the end user.
The Registrant and the ENUM zone provisioning system he or she uses
must be aware of this and should not rely on ENUM clients taking
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account of the value of the ORDER and the PREFERENCE/PRIORITY fields.
Specifically, it is unsafe to assume that a ENUM client will not
consider another NAPTR until it has discarded one with a "winning"
ORDER value. The instruction (in RFC 3403 section 4.1 and section 8)
may or may not be followed strictly by different ENUM clients for
perfectly justifiable reasons.
To avoid the risk of variable behaviour, it is RECOMMENDED that:
Server ENUM zone provisioning systems should not use different
ORDER values for NAPTRs within a zone.
In our experience, incorrect ORDER values in ENUM zones is a major
source of problems. Although it is by no means required, it is
further RECOMMENDED that:
Server ENUM zone provisioning systems should use a value of 100 as
the default ORDER value to be used with all NAPTRs.
As such, when populating a zone with NAPTRs, it is RECOMMENDED that:
Server A Registrant should not expect the ENUM client to ignore
NAPTRs with higher ORDER field values - the "winning" ones
may have been discarded.
Server A Registrant should not expect ENUM clients to conform to
the ORDER and PREFERENCE/PRIORITY sort order he or she has
specified for NAPTRs; end users may have their own
preferences for ENUMservices.
Client Each ENUM client may reorder the NAPTRs it receives only to
match an explicit preference pre-specified by its end user.
Client ENUM clients that offer a list of contacts to the end user
for his or her choice may present all NAPTRs, not just the
ones with the highest currently unprocessed ORDER field
value.
Server A Registrant should not assume which NAPTR choices will be
presented "at once".
The impact of this is that a Registrant should place into his or her
zone only contacts that he or she is willing to support; even those
with the "least preferred" ORDER and PREFERENCE/PRIORITY values may
be selected by an end user.
Finally, we have noticed a number of ENUM zones with NAPTRs that have
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identical PREFERENCE/PRIORITY field values and different ORDER
values. This may be the result of an ENUM zone provisioning system
"bug" or a misunderstanding over the uses of the two fields.
To clarify, the ORDER field value is the major sort term, and the
PREFERENCE/PRIORITY field value is the minor sort term. Thus one
should expect to have a set of NAPTRs in a zone with identical ORDER
field values and different PREFERENCE/PRIORITY field values.
4.2. NAPTRs with identical ORDER/PRIORITY values
From experience, there are zones that hold discrete NAPTRs with
identical ORDER and identical PREFERENCE/PRIORITY field values. This
will lead to indeterminate client behaviour and so should not occur.
However, in the spirit of being liberal in what is allowed:
It is RECOMMENDED that:
Client ENUM clients should accept all NAPTRs with identical ORDER
and identical PREFERENCE/PRIORITY field values, and process
them in the sequence in which they appear in the DNS
response.
(There is no benefit in further randomising the order in
which these are processed, as intervening DNS Servers may
do this already).
Conversely, populating the records with these identical values is
unwise, as it may lead to indeterminate client behaviour, and so it
is RECOMMENDED that:
Server When populating ENUM zones with NAPTRs, ENUM zone
provisioning systems should not have more than one NAPTR
with the same ORDER and the same PREFERENCE/PRIORITY field
values in any given zone, as ENUM clients may reject the
response, and the sequence in which these NAPTRs are
delivered to the client may vary.
4.2.1. Compound NAPTRs and implicit ORDER/REFERENCE Values
There is one special case in which one could derive a set of NAPTRs
with identical ORDER and identical PREFERENCE/PRIORITY fields. This
will not exist explicitly in the Resource Record Set ("RRSet")
delivered to the client, but may occur whilst processing a "Compound"
NAPTR, and is dealt with next.
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4.3. Compound NAPTR Processing
With RFC 3761, it is possible to have more than one ENUMservice
associated with a single NAPTR. Of course, the different
ENUMservices share the same RegExp field and so generate the same
URI. Such a "compound" NAPTR could well be used to indicate, for
example, a mobile phone that supports both "voice:tel" and "sms:tel"
ENUMservices.
This compound NAPTR may be reconstructed into a set of NAPTRs each
holding a single ENUMservice. However, in this case the members of
this set all logically hold the same ORDER and PREFERENCE/PRIORITY
field values.
In this case, it is RECOMMENDED that:
Client ENUM clients receiving compound NAPTRs (i.e. ones with more
than one ENUMservice) should process these ENUMservices
using a left-to-right sort ordering, so that the first
ENUMservice to be processed will be the leftmost one, and
the last will be the rightmost one.
Server An ENUM zone provisioning system should assume that, if it
generates compound NAPTRs, the ENUMservices will normally
be processed in left to right order within such NAPTRs.
As a final point on ENUM client processing of compound NAPTRs, it is
quite possible that the client is incapable of processing one of the
ENUMservices indicated.
To clarify, it is RECOMMENDED that:
Client When an ENUM client encounters a compound NAPTR and cannot
process one of the ENUMservices within it, that ENUM client
should ignore it and continue with the next ENUMservice
within this NAPTR's Services field, discarding the NAPTR
only if it cannot handle any of the ENUMservices contained.
4.4. Processing Order value across Zones
Using a different ORDER field value in different zones is unimportant
for most queries. However, DDDS includes a mechanism for continuing
a search for NAPTRs in another zone by including a reference to that
other zone in a "non-terminal" NAPTR. The treatment of non-terminal
NAPTRs is covered in the next section, but if these are supported
then it does have a bearing on the way that ORDER and PREFERENCE/
PRIORITY field values are processed.
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Two main questions remain from the specifications of DDDS and RFC
3671:
o If there is a different (lower) order field value in a zone
referred to by a non-terminal NAPTR, then does this mean that the
ENUM client discards any remaining NAPTRs in the referring zone?
o Conversely, if the zone referred to by a non-terminal NAPTR
contains entries that have a higher ORDER field value, then does
the ENUM client ignore those NAPTRs in the referenced zone?
Whilst one interpretation of section 1.3 of RFC 3761 is that the
answer to both questions is "yes", this is not the way that those
examples of non-terminal NAPTRs that do exist (and those ENUM clients
that support them) seem to be designed.
Thus, to reflect the interpretation that is made by those systems
that have implemented non-terminal NAPTRs, it is RECOMMENDED that:
Server ENUM zone provisioning systems should assume that, once a
non-terminal NAPTR has been selected for processing, the
ORDER field value in a zone referred to by that non-
terminal NAPTR will be considered only within the context
of that referenced zone (i.e. the ORDER value will be used
only to sort within the current zone, and will not be used
in the processing of NAPTRs in any other zone).
Client ENUM clients should consider the ORDER field value only
when sorting NAPTRs within a single RRSet. The ORDER field
value should not be taken into account when processing
NAPTRs across a sequence of DNS queries created by
traversal of non-terminal NAPTR references.
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5. Non-Terminal NAPTR Processing
5.1. Non-Terminal NAPTRs - necessity
Consider an ENUM RRSet that contains a non-terminal NAPTR record.
This non-terminal NAPTR "points to" another domain that has a set of
NAPTRs. In effect, this is similar to the non-terminal NAPTR being
replaced by the NAPTRs contained in the domain to which it points.
It is possible to have a non-terminal NAPTR in a domain that is,
itself, pointed to by another non-terminal NAPTR. Thus a set of
domains forms a "chain", and the list of NAPTRs to be considered is
the set of all NAPTRs contained in all of the domains in that chain.
For an ENUM management system to support non-terminal NAPTRs, it is
necessary for it to be able to analyse, validate and (where needed)
correct not only the NAPTRs in its current ENUM domain but also those
"pointed to" by non-terminal NAPTRs in other domains. If the domains
pointed to have non-terminal NAPTRs of their own, the management
system will have to check each of the referenced domains in turn, as
their contents forms part of the result of a query on the "main" ENUM
domain. The domain content in the referenced domains may well not be
under the control of the ENUM management system, and so it may not be
possible to correct any errors in those RRSets. This is both complex
and prone to error in the management system design, and any reported
errors in validation may well be non-intuitive for users.
For an ENUM client, supporting non-terminal NAPTRs can also be
difficult. Processing non-terminal NAPTRs causes a set of sequential
DNS queries that can take an indeterminate time, and requires extra
resources and complexity to handle fault conditions like non-terminal
loops. The indeterminacy of response time makes ENUM supported
Telephony Applications difficult (such as in an "ENUM-aware" PBX),
whilst the added complexity and resources needed makes support
problematic in embedded devices like "ENUM-aware" mobile phones.
Given that, in principle, a non-terminal NAPTR can be replaced by the
NAPTRs in the domain to which it points, support of non-terminal
NAPTRs is not needed and non-terminal NAPTRs may not be useful.
Furthermore, most existing ENUM clients do not support non-terminal
NAPTRs and ignore them if received. To avoid interoperability
problems, some kind of acceptable requirement is needed on non-
terminal NAPTRs. Given the lack of current support and the issues
raised, we propose that in general one should not use non-terminal
NAPTRs in ENUM.
Thus, it is RECOMMENDED that:
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Server ENUM zone provisioning systems should not generate non-
terminal NAPTRs (i.e. NAPTRs with an empty Flags field)
unless it is clear that all ENUM clients they are designed
to support can process these.
Client ENUM clients may discard non-terminal NAPTRs (i.e. they may
only support ENUM NAPTRs with a Flags field value of "u").
5.2. Non-Terminal NAPTRs - future implementation
The following specific issues need to be considered if non-terminal
NAPTRs are to be supported in the future. These issues are gleaned
from experience, and indicate the kinds of conditions that should be
considered before support for non-terminal NAPTRs is contemplated.
Note that these issues are in addition to the point just mentioned on
ENUM provisioning or management system complexity and the potential
for that management system to have no control over the zone contents
to which non-terminal NAPTRs in "its" managed zones refer.
5.2.1. Non-Terminal NAPTRs - general
As mentioned earlier, a non-terminal NAPTR in one zone refers to the
NAPTRs contained in another zone. The NAPTRs in the zone referred to
by the non-terminal NAPTR may have a different ORDER value from that
in the referring non-terminal NAPTR. See Section 4.4 for details.
In addition, to Clarify, it is RECOMMENDED that:
Client If all NAPTRs in a domain traversed as a result of a
reference in a non-terminal NAPTR have been discarded, then
the ENUM client should continue its processing with the
next NAPTR in the "referring" RRSet (i.e. the one including
the non-terminal NAPTR that caused the traversal).
5.2.2. Non-Terminal NAPTRs - loop detection and response
Where a "chain" of non-terminal NAPTRs refers back to a domain
already traversed in the current query, this implies a "non-terminal
loop". To ensure consistent behaviour, it is RECOMMENDED that:
Client ENUM clients should consider that processing a chain of
more than 5 "non-terminal" NAPTRs in a single ENUM query
indicates that a loop may have been detected, and act
accordingly.
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Server When populating a set of domains with NAPTRs, ENUM zone
provisioning systems should not configure non-terminal
NAPTRs so that more than 5 such NAPTRs will be processed in
an ENUM query.
Client Where a domain is about to be entered as the result of a
reference in a non-terminal NAPTR, and the ENUM client has
detected a potential "non-terminal loop", then the client
should discard the non-terminal NAPTR from its processing
and continue with the next NAPTR in its list. It should
not make the DNS query indicated by that non-terminal
NAPTR.
5.3. Interpretation of RFC 3403 and RFC 3761
The set of specifications defining DDDS and its applications are
complex and multi-layered. This reflects the flexibility that the
system provides, but it does mean that some of the specifications
need clarification as to their interpretation, particularly where
non-terminal rules are concerned.
5.3.1. Flags field content with Non-Terminal NAPTRs
RFC 3761, section 2.4.1 states that the only flag character valid for
use with the "E2U" DDDS Application is 'u'. The flag 'u' is defined
(in RFC 3404 [5], section 4.3) thus: 'The "u" flag means that the
output of the Rule is a URI'.
RFC 3761 section 2.4.1 also states that an empty Flags field
indicates a non-terminal NAPTR. This is also the case for other DDDS
Application specifications, such as that specified in RFC 3404. One
could well argue that this is a feature potentially common to all
DDDS Applications, and so should have been specified in RFC 3402 or
RFC 3403.
5.3.2. Services field content with Non-Terminal NAPTRs
Furthermore, RFC 3761 section 3.1.1 states that any ENUMservice
Specification requires definition of the URI that is the expected
output of this ENUMservice. This means that, at present, there is no
way to specify an ENUMservice that is non-terminal. Such a non-
terminal NAPTR has, by definition, no URI as its expected output,
instead returning a key (DNS domain name) that is to be used in the
"next round" of DDDS processing.
This in turn means that there can be no valid (non-empty) Services
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field content for a NAPTR to be used with the "E2U" DDDS application.
Section 2.4.2 of RFC 3761 specifies the syntax for this field
content, and requires at least one element of type <servicespec>
(i.e. at least one ENUMservice identifier). Given that there can be
no definition of a non-terminal ENUMservice (and so no such
Registered ENUMservice identifier), this syntax cannot be met with a
non-terminal NAPTR.
A reasonable interpretation of the specifications in their current
state is that the Services field must also be empty; this appears to
be the approach taken by those clients that do either process non-
terminal NAPTRs or check the validity of the fields. To ensure
consistent behaviour, it is RECOMMENDED that:
Client ENUM clients should ignore any content of the Services
field when encountering a non-terminal NAPTR with an empty
Flags field.
Server ENUM zone provisioning systems should ensure that the
Services field of any non-terminal NAPTR (with an empty
Flags field) is also empty.
5.3.3. Regular Expression and Replacement field content with non-
terminal NAPTRs
The descriptive text in section 4.1 of RFC 3403 is intended to
explain how the fields are to be used in a NAPTR. However, the
descriptions associated with the RegExp and Replacement elements have
led to some confusion over which of these should be considered when
dealing with non-terminal NAPTRs.
RFC 3403 is specific; these two elements are mutually exclusive.
This means that if the RegExp element is not empty then the
Replacement element must be empty, and vice versa. However, is does
not specify which is used with terminal and non-terminal rules.
The descriptive text of section 4.1 of RFC 3403 for the NAPTR
Replacement element shows that this element holds an uncompressed
domain name. Thus it is clear that this element cannot be used to
deliver the terminal string for any DDDS application that does not
have a domain name as its intended terminal output.
However, the first paragraph of descriptive text for the NAPTR RegExp
element has led to some confusion. It appears that the RegExp
element is to be used to find "the next domain name to lookup". This
might be interpreted as meaning that a client program processing the
DDDS application could need to examine each non-terminal NAPTR to
decide whether the RegExp element or instead the Replacement element
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were to be used to construct the key (a domain name) to be used next
in non-terminal rule processing.
Given that a NAPTR holding a terminal rule (a "terminal NAPTR") must
use the Substitution expression field to generate the expected output
of that DDDS application, the RegExp element is also used in such
rules. Indeed, unless that DDDS application has a domain name as its
terminal output, the RegExp element is the only possibility.
Thus from the descriptive text of this section, a Replacement element
can be used only in NAPTRs holding a non-terminal rule (a "non-
terminal NAPTR") unless that DDDS Application has a domain name as
its terminal output, whilst the alternative RegExp element may be
used either to generate a domain name as the next key to be used in
the non-terminal case, or to generate the output of the DDDS
application.
Note that each DDDS Application is free to specify the set of flags
to be used with that application. This includes specifying whether a
particular flag is associated with a terminal or non-terminal rule,
and also to specify the interpretation of an empty Flags field (i.e.
whether this is to be interpreted as a terminal or non-terminal rule,
and if it is terminal, then the expected output). ENUM (as specified
in section 2.4.1 of RFC 3761) specifies only the 'u' flag, with an
empty Flags field indicating a non-terminal NAPTR.
The general case in which a client program must check which of the
two elements to use in non-terminal NAPTR processing complicates
implementation, and this interpretation has NOT been made in current
ENUM examples "out in the wild". It would be useful to define
exactly when a client program can expect to process the RegExp
element and when to expect to process the Replacement element, if
only to improve robustness.
In keeping with current implementations, we suggest that a non-
terminal NAPTR with an empty Flags field must be provisioned using
the (non-empty) Replacement element to hold the domain name that
forms the "next key" output from this non-terminal rule.
Thus it is RECOMMENDED that:
Client ENUM clients receiving a non-terminal NAPTR with an empty
Flags field must treat the Replacement field as holding the
domain name to be used in the next round of the ENUM query.
An ENUM client must discard such a non-terminal NAPTR if
the Replacement field is empty or does not contain a valid
domain name. By definition, it follows that the RegExp
field will be empty in such a non-terminal NAPTR, and
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should be ignored by ENUM clients
Server with an empty Flags field into an ENUM zone must ensure
that the "target" domain name is set into the Replacement
field of this NAPTR. It must not use the RegExp field in
such a non-terminal NAPTR.
In the future, it would be possible to update RFC 3761 (sections
3.1.1 and 2.4.1) to add a new flag to indicate a non-terminal NAPTR,
and to change the ENUMservice template to permit specification of an
ENUMservice that operates with this new flag in non-terminal NAPTRs.
In doing this, it would be possible to include a syntactically valid
non-empty Services field in such non-terminal NAPTRs. To
differentiate from the case of an empty Flags field, this new flag
could also indicate that the RegExp field was to be non-empty, and to
be processed - by implication, this would mean that the Replacement
field would be empty. However, such a change would require an update
to RFC 3761, and so will have to wait.
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6. General DNS Issues
Whilst these issues covered in this section are not ENUM-specific,
they do "bite" when developing ENUM-aware systems, and are important
for ENUM deployment. This section makes strong recommendations over
support for EDNS0 and TCP. These are crucial, as they will have a
major impact on ENUM deployments, particularly when ENUM Clients are
connected to the Internet over access networks that exhibit higher
latencies (such as cellular mobile networks, where latencies can be
of the order of hundreds of milliseconds or more).
In addition, there are several elements of behaviour of the DNS that
can complicate testing. As advice to developers, some of the more
subtle issues are covered here, gleaned from the experience of those
groups already developing and deploying ENUM systems.
6.1. DNS Specifications
The DNS protocol is defined in RFC 1034 [8] and RFC 1035 [9], and is
clarified in RFC 2181 [16], whilst Requirements for Internet Hosts
are specified in RFC 1123 [17]. Security threats to DNS are covered
in RFC 3833 [21], and DNSSEC (DNS Security) is specified in RFC 4033
[22], RFC 4034 [23], and in RFC 4035 [24], whilst EDNS0 (an extension
mechanism for DNS) is specified in RFC 2671 [18].
Supporting UDP queries is mandatory, but support for TCP queries is
recommended also, and is (in effect) required as RFC 1123 requires
that a DNS client discard a truncated response sent in response to
its initial (UDP) query and retry using another transport protocol.
In effect, Authoritative Name Servers that do not answer TCP queries
after returning truncated responses are not able to answer queries
correctly.
Amongst other things, the EDNS0 mechanism allows the querying client
to indicate the size of UDP packet that it can process. RFC 1035
restricts the maximum size of a UDP DNS response to 512 bytes. This
limit has proven to be too low for reasonably sized NAPTR Resource
Record Sets. EDNS0 provides a mechanism for DNS clients and servers
to use larger UDP payloads. Partially due to the larger response
sizes involved and the need for extended flags, support for DNSSEC
also requires the use of EDNS0.
6.2. ENUM needs EDNS0 support
The performance of ENUM resolution is much reduced if a mechanism to
handle larger responses efficiently is not available. ENUM RRSets
often have more records than will fit into a basic "RFC 1035" UDP
response. EDNS0 (as specified in RFC 2671 [18]) with a suitably
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large buffer size is the current official mechanism to support these
larger messages with maximum efficiency. Lack of EDNS0 support and
use of its size option by querying clients causes degradation of the
system by requiring retransmission via TCP once a basic RFC 1035 UDP
query results a "truncated" error response from the queried DNS
Server. As ENUM RRSets typically contain more records than are
returned for other queries, this is a much more frequent condition.
Processing truncated responses adds latency to ENUM resolution and
may consume excessive TCP resources on the DNS Server, such as data
structures needed to maintain connection state.
(see section 4.2.2 of [9] for the requirement for a DNS server to
leave each TCP port used for queries open for several minutes,
otherwise relying on the client to close the port explicitly when no
longer needed).
The impact of larger response messages where EDNS0 is not used can be
significant. Instead of two messages (the query indicating EDNS0
support, and its response, using EDNS0), if the method described in
RFC 1035 and RFC 1123 is used there will be many more - two messages
for the query and the truncated UDP response, several messages to
make the TCP connection, at least one for the query, and at least one
for the response, with several more messages being needed to tear
down the TCP connection. Especially if these messages are exchanged
via an access network with significant latency for data transport,
the total time needed to perform ENUM resolution can be excessive (of
the order of seconds over a cellular access network), and much more
than would be needed for the UDP query. In practice, not using EDNS0
where clients may be connected via these networks means that ENUM
deployment will not meet acceptable performance targets for RRSets
with larger sets of records.
Note that this is not ENUM-specific but instead a standard feature of
DNS - it just comes into play more often with ENUM and other queries
that return large response messages.
Thus to ensure efficient resolution of ENUM queries, it is
RECOMMENDED that:
Server All servers involved in ENUM resolution that carry messages
including NAPTR RRsets must support EDNS0.
Client ENUM Clients should use EDNS0 in their queries. The sole
exception to this is when the Client knows that a server
does not support EDNS0 (due to some misconfiguration).
This adaptation is normal behaviour for a DNS Resolver that
supports EDNS0 (see section 5 of [18]).
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6.3. ENUM EDNS0 message size support
The next issue has no deterministic answer. Whilst it is impossible
to be definitive over the size of messages exchanged during ENUM
resolution, it is possible to state that the message sizes are
considerably larger than has typically been the case for most DNS
queries so far. Selecting appropriate sizes for EDNS0 support aims
to ensure that the percentage of queries that still require a
"fallback" to TCP is minimal for all realistically populated ENUM
RRSets.
In practice, zones "seen" so far have rarely required more than 2
kilobytes in response size. However, with the introduction of IPv6
and DNSSEC support, this is very likely to increase in the near
future, so we recommend that ENUM Clients should indicate their
support for a larger buffer size than might be necessary at this
point. It should be noted that the penalty of choosing too low a
size for EDNS0 support may be even more severe that the standard
method described in RFC 1035 and RFC 1123. Thus it is good practice
to select a larger size than is likely to be needed, to counteract
that greater cost where fallbacks still occur. Sections 2.4 and
particularly 2.5 of [24] explain the rationale for using the size
option of EDNS0 for queries that return larger responses. In that
document, section 3.1 describes expected server behaviour, section
4.1 describes expected Resolver behaviour, whilst section 3
summarises the proposed message sizes to be supported by Servers and
Resolvers. These same size recommendations are repeated here, as it
is felt that ENUM already has a similar issue with larger responses,
and will certainly need the larger messages sizes with the
introduction of IPv6 and DNSSEC support.
It is RECOMMENDED that:
Client An ENUM Client should be willing to handle DNS responses of
up to 4000 bytes in length, and should indicate in its
queries that it supports responses up to 4000 bytes in
length using the EDNS0 technique specified in [18].
It is further RECOMMENDED that:
Client An ENUM Client should consider an indicated supported value
of 1220 bytes in its EDNS0 queries to be a bare minimum
whilst avoiding fragmentation of response packets over most
deployed networks.
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6.4. Intermediary Devices
From our experiences a Name Server may support TCP queries, but there
may well be an intervening packet filter that does not allow TCP
traffic to pass correctly. It is unfortunately common for people
managing a firewall to block traffic to or from the DNS TCP port
without considering the impact. Thus if TCP queries do not seem to
work, it is worthwhile considering this possibility; the Name Server
may be operating correctly, but the TCP SYN or SYN-ACK packets may be
blocked, effectively disabling the Server from contact with the World
beyond the firewall.
An incorrect assumption is made by some deployed packet filters that
MAY affect transport of EDNS0 responses. It has been noticed that
some older equipment may be configured by default to discard all UDP
packets containing DNS messages if these are more than 512 bytes in
size. Since the introduction of EDNS0 in 1999, such a configuration
has been and is incorrect. Both of these behaviours can be very hard
to debug.
In particular, odd behaviour has been detected within several
cellular networks that claim to provide Internet access; it appears
that these networks include firewalls or application level proxies
that do not handle larger DNS messages carried over UDP well. This
is a basic error in network infrastructure configuration that may
affect their customers, particularly when these customers attempt
ENUM resolution. Experimental results have shown that such access
network components typically seem to behave as "transparent" proxies
for all traffic sent to the default DNS port (port 53), discarding
larger packets regardless of content.
Thus, although it should be obvious, we RECOMMEND that:
MidBox Name Servers should support TCP queries, and must support
EDNS0 if they are to host ENUM data. Thus intermediate
systems such as firewalls should not be configured to
filter traffic to or from a Name Server; notably, these
should not block TCP transport for DNS queries, and must
not simply block DNS messages of greater than 512 bytes in
size without examining them for correct EDNS0 support.
Note that this may require stateful packet inspection.
Unfortunately, it is still necessary to note that:
Client Developers of ENUM clients should be aware of these
potential problems and clients must be able to adapt to
such misconfigured systems, in accordance with RFC 2671
[18]. However, developers should also be aware that, in
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the case of malfunctioning intermediary systems, the
proposal made there (to "probe" for DNS server capability
prior to placing requests) may not succeed in exposing an
infrastructure that will disable normally functioning
servers. Small "probe" messages may pass, indicating EDNS0
support, whilst longer messages in subsequent queries do
not.
6.5. Times To Live and NAPTRs
Section 5.2 of [16] clarifies the normal operation of DNS where more
than one Resource Record (RR) is returned in a response. It defines
the requirement that Time To Live (TTL) values must be the same in
those circumstances, and the treatment by Resolvers of response
messages containing sets of Resource Records. As a query on an ENUM
zone for NAPTRs will typically return a set of resource records
consisting of more than one record, this has an impact on ENUM
processing, and it is worth exploring it in this document.
It is important that all NAPTRs in a zone have Time To Live fields
set to the same value, or else "strange things" will happen with
Recursive Resolvers that are hard to debug. A query for type NAPTR
will return the available collection of such RRs. From the
perspective of the Recursive Resolver, if records in this set have
different TTL, then the zone will be re-queried only once ALL queried
Records have expired.
Given this behaviour by DNS Resolvers, it is unwise to have different
TTL in the various NAPTRs in a zone. Some of these resource records
will seem to "disappear" over time from the list of available records
returned and that will lead to variable and often unexpected
behaviour - if nothing else, it may well confuse the end user as the
list of options he or she is offered grows and shrinks.
This is true for RR type-specific queries, but it is also true for
general queries within a zone. For example, a DNS query with a Query
Type value of 255 asks for "ANY Resource Records for that domain name
that you you have". Thus if a Recursive Resolver holds RRs for a
zone in its cache, and a cached RR from that zone has a long TTL,
then it will be returned even after others have expired - no onward
query will be made unless there are no RRs at all available at the
Recursive Resolver for the queried zone. In this case, however, the
TTL of ALL the records that may well exist in a queried zone have to
be taken into account, rather than just those of the NAPTR records
themselves. This may well not be the case, so this kind of query
should be avoided.
In summary, in keeping with the standards:
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Server ENUM provisioning systems must follow the guidance of
section 5.2 of RFC 2181 [16]. All TTL values must be
identical for Resource Records of a given class and type.
Client ENUM clients must follow the guidance of section 5.2 of RFC
2181 [16].
Client ENUM clients should not issue queries with Query Type = 255
(commonly known as an 'ANY' query), as the results may well
be unexpected.
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7. Backwards Compatibility
7.1. Services field syntax
RFC 3761 is the current standard for the syntax for NAPTRs supporting
the ENUM DDDS application. This obsoletes the original specification
that was given in RFC 2916. There has been a change to the syntax of
the Services field of the NAPTR that reflects a refinement of the
concept of ENUM processing.
As defined in RFC 3403, there is now a single identifier that
indicates the DDDS Application. In the obsolete specification (RFC
2915), there were zero or more "Resolution Service" identifiers (the
equivalent of the DDDS Application). The same identifier string is
defined in both RFC 3761 and in the old RFC 2916 specifications for
the DDDS identifier or the Resolution Service; "E2U".
Also, RFC 3761 defines at least one but potentially several
ENUMservice sub-fields; in the obsolete specification, only one
"protocol" sub-field was allowed.
In many ways, the most important change for implementations is that
the order of the sub-fields has been reversed. RFC 3761 specifies
that the DDDS Application identifier is the leftmost sub-field,
followed by one or more ENUMservice sub-fields, each separated by the
'+' character delimiter. RFC 2916 specified that the protocol sub-
field was the leftmost, followed by the '+' delimiter, in turn
followed by the "E2U" resolution service tag.
RFC 2915 and RFC 2916 have been obsoleted by RFC 3401 - RFC 3404 and
by RFC 3761. Thus it is RECOMMENDED that:
Server ENUM zone provisioning systems must not generate NAPTRs
according to the syntax defined in RFC 2916. All zones
must hold ENUM NAPTRs according to RFC 3761 (and
ENUMservice specifications according to the framework
specified there).
However, RFC 3824 [19] suggests that ENUM clients should be prepared
to accept NAPTRs with the obsolete syntax. Thus, an ENUM client
implementation may have to deal with both forms.
It is RECOMMENDED that:
Client ENUM clients must support ENUM NAPTRs according to RFC 3761
syntax. ENUM clients should also support ENUM NAPTRs
according to the obsolete syntax of RFC 2916; there are
still zones that hold "old" syntax NAPTRs.
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This need not be difficult. For example, an implementation could
process the Services field into a set of tokens, and expect exactly
one of these tokens to be "E2U". In this way, the ENUM client might
be designed to handle both the old and the current forms without
added complexity.
There is one subtle implication of this scheme. It is RECOMMENDED
that:
Spec Registrations for an ENUMservice with the type string of
"E2U" and an empty sub-type string must not be accepted.
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8. Security Considerations
This document does not specify any standard. It does however make
some recommendations, and so the implications of following those
suggestions have to be considered.
In addition to these issues, those in the basic use of ENUM (and
specified in the normative documents for this protocol) should be
considered as well; this document does not negate those in any way.
The clarifications throughout this document are intended only as
that; clarifications of text in the normative documents. They do not
appear to have any security implications above those mentioned in the
normative documents.
The suggestions in Section 3, Section 4, and Section 7 do not appear
to have any security considerations (either positive or negative).
The suggestions in Section 5.2.2 are a valid approach to a known
security threat. It does not open an advantage to an attacker in
causing excess processing or memory usage in the client. It does,
however, mean that an ENUM client will traverse a "tight loop" of
non-terminal NAPTRs in two domains 5 times before the client detects
this as a loop; this does introduce slightly higher processing load
than would be provided using other methods, but avoids the risks they
incur.
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9. IANA Considerations
This document is only advisory, and does not include any IANA
considerations other than the proposals labelled as "Spec". These
are the recommendation (in Section 3.1) that ENUMservice
Registrations should at least indicate if characters outside of the
US-ASCII equivalent range are permitted, and the suggestion (at the
end of Section 7.1) that no-one should specify an ENUMservice with
the identifying tag "E2U".
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10. Acknowledgements
We would like to thank the various development teams who implemented
ENUM (both creation systems and clients) and who read the normative
documents differently - without these differences it would have been
harder for us all to develop robust clients and suitably conservative
management systems. We would also thank those who allowed us to
check their implementations to explore behaviour; their trust and
help were much appreciated.
In particular, thanks to Richard Stastny for his hard work on a
similar task TS 102 172 [25] under the aegis of ETSI, and for
supporting some of the ENUM implementations that exist today.
Finally, thanks for the dedication of Michael Mealling in giving us
such detailed DDDS specifications, without which the ENUM development
effort would have had a less rigourous framework on which to build.
This document reflects how complex a system it is: Without the
intricacy of RFC 3401 - RFC 3404 and the work that went into them, it
could have been quite different.
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11. References
11.1. Normative References
[1] Faltstrom, P. and M. Mealling, "The E.164 to Uniform Resource
Identifiers (URI) Dynamic Delegation Discovery System (DDDS)
Application (ENUM)", RFC 3761, April 2004.
[2] Mealling, M., "Dynamic Delegation Discovery System (DDDS) Part
Three: The Domain Name System (DNS) Database", RFC 3403,
October 2002.
[3] Mealling, M., "Dynamic Delegation Discovery System (DDDS) Part
One: The Comprehensive DDDS", RFC 3401, October 2002.
[4] Mealling, M., "Dynamic Delegation Discovery System (DDDS) Part
Two: The Algorithm", RFC 3402, October 2002.
[5] Mealling, M., "Dynamic Delegation Discovery System (DDDS) Part
Four: The Uniform Resource Identifiers (URI)", RFC 3404,
October 2002.
[6] Mealling, M., "Dynamic Delegation Discovery System (DDDS) Part
Five: URI.ARPA Assignment Procedures", RFC 3405, October 2002.
[7] Yergeau, F., "UTF-8, a transformation format of ISO 10646",
STD 63, RFC 3629, November 2003.
[8] Mockapetris, P., "DOMAIN NAMES - CONCEPTS AND FACILITIES",
RFC 1034, November 1987.
[9] Mockapetris, P., "Domain names - implementation and
specification", STD 13, RFC 1035, November 1987.
[10] Costello, A., "Punycode: A Bootstring encoding of Unicode for
Internationalized Domain Names in Applications (IDNA)",
RFC 3492, March 2003.
[11] Institute of Electrical and Electronics Engineers, "Information
Technology - Portable Operating System Interface (POSIX) - Part
2: Shell and Utilities (Vol. 1)", IEEE Standard 1003.2,
January 1993.
[12] Schulzrinne, H., "The tel URI for Telephone Numbers", RFC 3966,
December 2004.
[13] ITU-T, "The International Public Telecommunication Number
Plan", Recommendation E.164, May 1997.
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[14] Berners-Lee, T., Fielding, R., and L. Masinter, "Uniform
Resource Identifier (URI): Generic Syntax", RFC 3986,
January 2005.
[15] Duerst, M. and M. Suignard, "Internationalized Resource
Identifiers (IRIs)", RFC 3987, January 2005.
[16] Elz, R. and R. Bush, "Clarifications to the DNS Specification",
RFC 2181, July 1997.
[17] Braden, R., "Requirements for Internet Hosts -- Application and
Support", RFC 1123, October 1989.
[18] Vixie, P., "Extension Mechanisms for DNS (EDNS0)", RFC 2671,
August 1999.
[19] Peterson, J., Liu, H., Yu, J., and B. Campbell, "Using E.164
numbers with the Session Initiation Protocol (SIP)", RFC 3824,
June 2004.
11.2. Informative References
[20] American National Standards Institute, "Coded Character Set --
7-bit American Standard Code for Information Interchange",
ANSI X3.4, 1986.
[21] Atkins, D. and R. Austein, "Threat Analysis of the Domain Name
System (DNS)", RFC 3833, August 2004.
[22] Arends, R., Austein, R., Larson, M., Massey, D., and S. Rose,
"DNS Security Introduction and Requirements", RFC 4033,
March 2005.
[23] Arends, R., Austein, R., Larson, M., Massey, D., and S. Rose,
"Resource Records for the DNS Security Extensions", RFC 4034,
March 2005.
[24] Arends, R., Austein, R., Larson, M., Massey, D., and S. Rose,
"Protocol Modifications for the DNS Security Extensions",
RFC 4035, March 2005.
[25] ETSI, "Minimum Requirements for Interoperability of European
ENUM Implementations", ETSI TS 102 172, October 2004.
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Authors' Addresses
Lawrence Conroy
Roke Manor Research
Roke Manor
Old Salisbury Lane
Romsey
United Kingdom
Phone: +44-1794-833666
Email: lconroy@insensate.co.uk
URI: http://www.sienum.co.uk
Kazunori Fujiwara
Japan Registry Service Co., Ltd.
Chiyoda First Bldg. East 13F
3-8-1 Nishi-Kanda Chiyoda-ku
Tokyo 101-0165
JAPAN
Email: fujiwara@jprs.co.jp
URI: http://jprs.jp/en/
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