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Network Working Group P. Faltstrom
Request for Comments: 3490 Cisco
Category: Standards Track P. Hoffman
IMC & VPNC
A. Costello
UC Berkeley
March 2003
Internationalizing Domain Names in Applications (IDNA)
Status of this Memo
This document specifies an Internet standards track protocol for the
Internet community, and requests discussion and suggestions for
improvements. Please refer to the current edition of the "Internet
Official Protocol Standards" (STD 1) for the standardization state
and status of this protocol. Distribution of this memo is unlimited.
Copyright Notice
Copyright (C) The Internet Society (2003). All Rights Reserved.
Abstract
Until now, there has been no standard method for domain names to use
characters outside the ASCII repertoire. This document defines
internationalized domain names (IDNs) and a mechanism called
Internationalizing Domain Names in Applications (IDNA) for handling
them in a standard fashion. IDNs use characters drawn from a large
repertoire (Unicode), but IDNA allows the non-ASCII characters to be
represented using only the ASCII characters already allowed in so-
called host names today. This backward-compatible representation is
required in existing protocols like DNS, so that IDNs can be
introduced with no changes to the existing infrastructure. IDNA is
only meant for processing domain names, not free text.
Table of Contents
1. Introduction.................................................. 2
1.1 Problem Statement......................................... 3
1.2 Limitations of IDNA....................................... 3
1.3 Brief overview for application developers................. 4
2. Terminology................................................... 5
3. Requirements and applicability................................ 7
3.1 Requirements.............................................. 7
3.2 Applicability............................................. 8
3.2.1. DNS resource records................................ 8
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3.2.2. Non-domain-name data types stored in domain names... 9
4. Conversion operations......................................... 9
4.1 ToASCII................................................... 10
4.2 ToUnicode................................................. 11
5. ACE prefix.................................................... 12
6. Implications for typical applications using DNS............... 13
6.1 Entry and display in applications......................... 14
6.2 Applications and resolver libraries....................... 15
6.3 DNS servers............................................... 15
6.4 Avoiding exposing users to the raw ACE encoding........... 16
6.5 DNSSEC authentication of IDN domain names................ 16
7. Name server considerations.................................... 17
8. Root server considerations.................................... 17
9. References.................................................... 18
9.1 Normative References...................................... 18
9.2 Informative References.................................... 18
10. Security Considerations...................................... 19
11. IANA Considerations.......................................... 20
12. Authors' Addresses........................................... 21
13. Full Copyright Statement..................................... 22
1. Introduction
IDNA works by allowing applications to use certain ASCII name labels
(beginning with a special prefix) to represent non-ASCII name labels.
Lower-layer protocols need not be aware of this; therefore IDNA does
not depend on changes to any infrastructure. In particular, IDNA
does not depend on any changes to DNS servers, resolvers, or protocol
elements, because the ASCII name service provided by the existing DNS
is entirely sufficient for IDNA.
This document does not require any applications to conform to IDNA,
but applications can elect to use IDNA in order to support IDN while
maintaining interoperability with existing infrastructure. If an
application wants to use non-ASCII characters in domain names, IDNA
is the only currently-defined option. Adding IDNA support to an
existing application entails changes to the application only, and
leaves room for flexibility in the user interface.
A great deal of the discussion of IDN solutions has focused on
transition issues and how IDN will work in a world where not all of
the components have been updated. Proposals that were not chosen by
the IDN Working Group would depend on user applications, resolvers,
and DNS servers being updated in order for a user to use an
internationalized domain name. Rather than rely on widespread
updating of all components, IDNA depends on updates to user
applications only; no changes are needed to the DNS protocol or any
DNS servers or the resolvers on user's computers.
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1.1 Problem Statement
The IDNA specification solves the problem of extending the repertoire
of characters that can be used in domain names to include the Unicode
repertoire (with some restrictions).
IDNA does not extend the service offered by DNS to the applications.
Instead, the applications (and, by implication, the users) continue
to see an exact-match lookup service. Either there is a single
exactly-matching name or there is no match. This model has served
the existing applications well, but it requires, with or without
internationalized domain names, that users know the exact spelling of
the domain names that the users type into applications such as web
browsers and mail user agents. The introduction of the larger
repertoire of characters potentially makes the set of misspellings
larger, especially given that in some cases the same appearance, for
example on a business card, might visually match several Unicode code
points or several sequences of code points.
IDNA allows the graceful introduction of IDNs not only by avoiding
upgrades to existing infrastructure (such as DNS servers and mail
transport agents), but also by allowing some rudimentary use of IDNs
in applications by using the ASCII representation of the non-ASCII
name labels. While such names are very user-unfriendly to read and
type, and hence are not suitable for user input, they allow (for
instance) replying to email and clicking on URLs even though the
domain name displayed is incomprehensible to the user. In order to
allow user-friendly input and output of the IDNs, the applications
need to be modified to conform to this specification.
IDNA uses the Unicode character repertoire, which avoids the
significant delays that would be inherent in waiting for a different
and specific character set be defined for IDN purposes by some other
standards developing organization.
1.2 Limitations of IDNA
The IDNA protocol does not solve all linguistic issues with users
inputting names in different scripts. Many important language-based
and script-based mappings are not covered in IDNA and need to be
handled outside the protocol. For example, names that are entered in
a mix of traditional and simplified Chinese characters will not be
mapped to a single canonical name. Another example is Scandinavian
names that are entered with U+00F6 (LATIN SMALL LETTER O WITH
DIAERESIS) will not be mapped to U+00F8 (LATIN SMALL LETTER O WITH
STROKE).
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An example of an important issue that is not considered in detail in
IDNA is how to provide a high probability that a user who is entering
a domain name based on visual information (such as from a business
card or billboard) or aural information (such as from a telephone or
radio) would correctly enter the IDN. Similar issues exist for ASCII
domain names, for example the possible visual confusion between the
letter 'O' and the digit zero, but the introduction of the larger
repertoire of characters creates more opportunities of similar
looking and similar sounding names. Note that this is a complex
issue relating to languages, input methods on computers, and so on.
Furthermore, the kind of matching and searching necessary for a high
probability of success would not fit the role of the DNS and its
exact matching function.
1.3 Brief overview for application developers
Applications can use IDNA to support internationalized domain names
anywhere that ASCII domain names are already supported, including DNS
master files and resolver interfaces. (Applications can also define
protocols and interfaces that support IDNs directly using non-ASCII
representations. IDNA does not prescribe any particular
representation for new protocols, but it still defines which names
are valid and how they are compared.)
The IDNA protocol is contained completely within applications. It is
not a client-server or peer-to-peer protocol: everything is done
inside the application itself. When used with a DNS resolver
library, IDNA is inserted as a "shim" between the application and the
resolver library. When used for writing names into a DNS zone, IDNA
is used just before the name is committed to the zone.
There are two operations described in section 4 of this document:
- The ToASCII operation is used before sending an IDN to something
that expects ASCII names (such as a resolver) or writing an IDN
into a place that expects ASCII names (such as a DNS master file).
- The ToUnicode operation is used when displaying names to users,
for example names obtained from a DNS zone.
It is important to note that the ToASCII operation can fail. If it
fails when processing a domain name, that domain name cannot be used
as an internationalized domain name and the application has to have
some method of dealing with this failure.
IDNA requires that implementations process input strings with
Nameprep [NAMEPREP], which is a profile of Stringprep [STRINGPREP],
and then with Punycode [PUNYCODE]. Implementations of IDNA MUST
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fully implement Nameprep and Punycode; neither Nameprep nor Punycode
are optional.
2. Terminology
The key words "MUST", "SHALL", "REQUIRED", "SHOULD", "RECOMMENDED",
and "MAY" in this document are to be interpreted as described in BCP
14, RFC 2119 [RFC2119].
A code point is an integer value associated with a character in a
coded character set.
Unicode [UNICODE] is a coded character set containing tens of
thousands of characters. A single Unicode code point is denoted by
"U+" followed by four to six hexadecimal digits, while a range of
Unicode code points is denoted by two hexadecimal numbers separated
by "..", with no prefixes.
ASCII means US-ASCII [USASCII], a coded character set containing 128
characters associated with code points in the range 0..7F. Unicode
is an extension of ASCII: it includes all the ASCII characters and
associates them with the same code points.
The term "LDH code points" is defined in this document to mean the
code points associated with ASCII letters, digits, and the hyphen-
minus; that is, U+002D, 30..39, 41..5A, and 61..7A. "LDH" is an
abbreviation for "letters, digits, hyphen".
[STD13] talks about "domain names" and "host names", but many people
use the terms interchangeably. Further, because [STD13] was not
terribly clear, many people who are sure they know the exact
definitions of each of these terms disagree on the definitions. In
this document the term "domain name" is used in general. This
document explicitly cites [STD3] whenever referring to the host name
syntax restrictions defined therein.
A label is an individual part of a domain name. Labels are usually
shown separated by dots; for example, the domain name
"www.example.com" is composed of three labels: "www", "example", and
"com". (The zero-length root label described in [STD13], which can
be explicit as in "www.example.com." or implicit as in
"www.example.com", is not considered a label in this specification.)
IDNA extends the set of usable characters in labels that are text.
For the rest of this document, the term "label" is shorthand for
"text label", and "every label" means "every text label".
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An "internationalized label" is a label to which the ToASCII
operation (see section 4) can be applied without failing (with the
UseSTD3ASCIIRules flag unset). This implies that every ASCII label
that satisfies the [STD13] length restriction is an internationalized
label. Therefore the term "internationalized label" is a
generalization, embracing both old ASCII labels and new non-ASCII
labels. Although most Unicode characters can appear in
internationalized labels, ToASCII will fail for some input strings,
and such strings are not valid internationalized labels.
An "internationalized domain name" (IDN) is a domain name in which
every label is an internationalized label. This implies that every
ASCII domain name is an IDN (which implies that it is possible for a
name to be an IDN without it containing any non-ASCII characters).
This document does not attempt to define an "internationalized host
name". Just as has been the case with ASCII names, some DNS zone
administrators may impose restrictions, beyond those imposed by DNS
or IDNA, on the characters or strings that may be registered as
labels in their zones. Such restrictions have no impact on the
syntax or semantics of DNS protocol messages; a query for a name that
matches no records will yield the same response regardless of the
reason why it is not in the zone. Clients issuing queries or
interpreting responses cannot be assumed to have any knowledge of
zone-specific restrictions or conventions.
In IDNA, equivalence of labels is defined in terms of the ToASCII
operation, which constructs an ASCII form for a given label, whether
or not the label was already an ASCII label. Labels are defined to
be equivalent if and only if their ASCII forms produced by ToASCII
match using a case-insensitive ASCII comparison. ASCII labels
already have a notion of equivalence: upper case and lower case are
considered equivalent. The IDNA notion of equivalence is an
extension of that older notion. Equivalent labels in IDNA are
treated as alternate forms of the same label, just as "foo" and "Foo"
are treated as alternate forms of the same label.
To allow internationalized labels to be handled by existing
applications, IDNA uses an "ACE label" (ACE stands for ASCII
Compatible Encoding). An ACE label is an internationalized label
that can be rendered in ASCII and is equivalent to an
internationalized label that cannot be rendered in ASCII. Given any
internationalized label that cannot be rendered in ASCII, the ToASCII
operation will convert it to an equivalent ACE label (whereas an
ASCII label will be left unaltered by ToASCII). ACE labels are
unsuitable for display to users. The ToUnicode operation will
convert any label to an equivalent non-ACE label. In fact, an ACE
label is formally defined to be any label that the ToUnicode
operation would alter (whereas non-ACE labels are left unaltered by
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ToUnicode). Every ACE label begins with the ACE prefix specified in
section 5. The ToASCII and ToUnicode operations are specified in
section 4.
The "ACE prefix" is defined in this document to be a string of ASCII
characters that appears at the beginning of every ACE label. It is
specified in section 5.
A "domain name slot" is defined in this document to be a protocol
element or a function argument or a return value (and so on)
explicitly designated for carrying a domain name. Examples of domain
name slots include: the QNAME field of a DNS query; the name argument
of the gethostbyname() library function; the part of an email address
following the at-sign (@) in the From: field of an email message
header; and the host portion of the URI in the src attribute of an
HTML <IMG> tag. General text that just happens to contain a domain
name is not a domain name slot; for example, a domain name appearing
in the plain text body of an email message is not occupying a domain
name slot.
An "IDN-aware domain name slot" is defined in this document to be a
domain name slot explicitly designated for carrying an
internationalized domain name as defined in this document. The
designation may be static (for example, in the specification of the
protocol or interface) or dynamic (for example, as a result of
negotiation in an interactive session).
An "IDN-unaware domain name slot" is defined in this document to be
any domain name slot that is not an IDN-aware domain name slot.
Obviously, this includes any domain name slot whose specification
predates IDNA.
3. Requirements and applicability
3.1 Requirements
IDNA conformance means adherence to the following four requirements:
1) Whenever dots are used as label separators, the following
characters MUST be recognized as dots: U+002E (full stop), U+3002
(ideographic full stop), U+FF0E (fullwidth full stop), U+FF61
(halfwidth ideographic full stop).
2) Whenever a domain name is put into an IDN-unaware domain name slot
(see section 2), it MUST contain only ASCII characters. Given an
internationalized domain name (IDN), an equivalent domain name
satisfying this requirement can be obtained by applying the
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ToASCII operation (see section 4) to each label and, if dots are
used as label separators, changing all the label separators to
U+002E.
3) ACE labels obtained from domain name slots SHOULD be hidden from
users when it is known that the environment can handle the non-ACE
form, except when the ACE form is explicitly requested. When it
is not known whether or not the environment can handle the non-ACE
form, the application MAY use the non-ACE form (which might fail,
such as by not being displayed properly), or it MAY use the ACE
form (which will look unintelligle to the user). Given an
internationalized domain name, an equivalent domain name
containing no ACE labels can be obtained by applying the ToUnicode
operation (see section 4) to each label. When requirements 2 and
3 both apply, requirement 2 takes precedence.
4) Whenever two labels are compared, they MUST be considered to match
if and only if they are equivalent, that is, their ASCII forms
(obtained by applying ToASCII) match using a case-insensitive
ASCII comparison. Whenever two names are compared, they MUST be
considered to match if and only if their corresponding labels
match, regardless of whether the names use the same forms of label
separators.
3.2 Applicability
IDNA is applicable to all domain names in all domain name slots
except where it is explicitly excluded.
This implies that IDNA is applicable to many protocols that predate
IDNA. Note that IDNs occupying domain name slots in those protocols
MUST be in ASCII form (see section 3.1, requirement 2).
3.2.1. DNS resource records
IDNA does not apply to domain names in the NAME and RDATA fields of
DNS resource records whose CLASS is not IN. This exclusion applies
to every non-IN class, present and future, except where future
standards override this exclusion by explicitly inviting the use of
IDNA.
There are currently no other exclusions on the applicability of IDNA
to DNS resource records; it depends entirely on the CLASS, and not on
the TYPE. This will remain true, even as new types are defined,
unless there is a compelling reason for a new type to complicate
matters by imposing type-specific rules.
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3.2.2. Non-domain-name data types stored in domain names
Although IDNA enables the representation of non-ASCII characters in
domain names, that does not imply that IDNA enables the
representation of non-ASCII characters in other data types that are
stored in domain names. For example, an email address local part is
sometimes stored in a domain label (hostmaster@example.com would be
represented as hostmaster.example.com in the RDATA field of an SOA
record). IDNA does not update the existing email standards, which
allow only ASCII characters in local parts. Therefore, unless the
email standards are revised to invite the use of IDNA for local
parts, a domain label that holds the local part of an email address
SHOULD NOT begin with the ACE prefix, and even if it does, it is to
be interpreted literally as a local part that happens to begin with
the ACE prefix.
4. Conversion operations
An application converts a domain name put into an IDN-unaware slot or
displayed to a user. This section specifies the steps to perform in
the conversion, and the ToASCII and ToUnicode operations.
The input to ToASCII or ToUnicode is a single label that is a
sequence of Unicode code points (remember that all ASCII code points
are also Unicode code points). If a domain name is represented using
a character set other than Unicode or US-ASCII, it will first need to
be transcoded to Unicode.
Starting from a whole domain name, the steps that an application
takes to do the conversions are:
1) Decide whether the domain name is a "stored string" or a "query
string" as described in [STRINGPREP]. If this conversion follows
the "queries" rule from [STRINGPREP], set the flag called
"AllowUnassigned".
2) Split the domain name into individual labels as described in
section 3.1. The labels do not include the separator.
3) For each label, decide whether or not to enforce the restrictions
on ASCII characters in host names [STD3]. (Applications already
faced this choice before the introduction of IDNA, and can
continue to make the decision the same way they always have; IDNA
makes no new recommendations regarding this choice.) If the
restrictions are to be enforced, set the flag called
"UseSTD3ASCIIRules" for that label.
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4) Process each label with either the ToASCII or the ToUnicode
operation as appropriate. Typically, you use the ToASCII
operation if you are about to put the name into an IDN-unaware
slot, and you use the ToUnicode operation if you are displaying
the name to a user; section 3.1 gives greater detail on the
applicable requirements.
5) If ToASCII was applied in step 4 and dots are used as label
separators, change all the label separators to U+002E (full stop).
The following two subsections define the ToASCII and ToUnicode
operations that are used in step 4.
This description of the protocol uses specific procedure names, names
of flags, and so on, in order to facilitate the specification of the
protocol. These names, as well as the actual steps of the
procedures, are not required of an implementation. In fact, any
implementation which has the same external behavior as specified in
this document conforms to this specification.
4.1 ToASCII
The ToASCII operation takes a sequence of Unicode code points that
make up one label and transforms it into a sequence of code points in
the ASCII range (0..7F). If ToASCII succeeds, the original sequence
and the resulting sequence are equivalent labels.
It is important to note that the ToASCII operation can fail. ToASCII
fails if any step of it fails. If any step of the ToASCII operation
fails on any label in a domain name, that domain name MUST NOT be
used as an internationalized domain name. The method for dealing
with this failure is application-specific.
The inputs to ToASCII are a sequence of code points, the
AllowUnassigned flag, and the UseSTD3ASCIIRules flag. The output of
ToASCII is either a sequence of ASCII code points or a failure
condition.
ToASCII never alters a sequence of code points that are all in the
ASCII range to begin with (although it could fail). Applying the
ToASCII operation multiple times has exactly the same effect as
applying it just once.
ToASCII consists of the following steps:
1. If the sequence contains any code points outside the ASCII range
(0..7F) then proceed to step 2, otherwise skip to step 3.
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2. Perform the steps specified in [NAMEPREP] and fail if there is an
error. The AllowUnassigned flag is used in [NAMEPREP].
3. If the UseSTD3ASCIIRules flag is set, then perform these checks:
(a) Verify the absence of non-LDH ASCII code points; that is, the
absence of 0..2C, 2E..2F, 3A..40, 5B..60, and 7B..7F.
(b) Verify the absence of leading and trailing hyphen-minus; that
is, the absence of U+002D at the beginning and end of the
sequence.
4. If the sequence contains any code points outside the ASCII range
(0..7F) then proceed to step 5, otherwise skip to step 8.
5. Verify that the sequence does NOT begin with the ACE prefix.
6. Encode the sequence using the encoding algorithm in [PUNYCODE] and
fail if there is an error.
7. Prepend the ACE prefix.
8. Verify that the number of code points is in the range 1 to 63
inclusive.
4.2 ToUnicode
The ToUnicode operation takes a sequence of Unicode code points that
make up one label and returns a sequence of Unicode code points. If
the input sequence is a label in ACE form, then the result is an
equivalent internationalized label that is not in ACE form, otherwise
the original sequence is returned unaltered.
ToUnicode never fails. If any step fails, then the original input
sequence is returned immediately in that step.
The ToUnicode output never contains more code points than its input.
Note that the number of octets needed to represent a sequence of code
points depends on the particular character encoding used.
The inputs to ToUnicode are a sequence of code points, the
AllowUnassigned flag, and the UseSTD3ASCIIRules flag. The output of
ToUnicode is always a sequence of Unicode code points.
1. If all code points in the sequence are in the ASCII range (0..7F)
then skip to step 3.
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2. Perform the steps specified in [NAMEPREP] and fail if there is an
error. (If step 3 of ToASCII is also performed here, it will not
affect the overall behavior of ToUnicode, but it is not
necessary.) The AllowUnassigned flag is used in [NAMEPREP].
3. Verify that the sequence begins with the ACE prefix, and save a
copy of the sequence.
4. Remove the ACE prefix.
5. Decode the sequence using the decoding algorithm in [PUNYCODE] and
fail if there is an error. Save a copy of the result of this
step.
6. Apply ToASCII.
7. Verify that the result of step 6 matches the saved copy from step
3, using a case-insensitive ASCII comparison.
8. Return the saved copy from step 5.
5. ACE prefix
The ACE prefix, used in the conversion operations (section 4), is two
alphanumeric ASCII characters followed by two hyphen-minuses. It
cannot be any of the prefixes already used in earlier documents,
which includes the following: "bl--", "bq--", "dq--", "lq--", "mq--",
"ra--", "wq--" and "zq--". The ToASCII and ToUnicode operations MUST
recognize the ACE prefix in a case-insensitive manner.
The ACE prefix for IDNA is "xn--" or any capitalization thereof.
This means that an ACE label might be "xn--de-jg4avhby1noc0d", where
"de-jg4avhby1noc0d" is the part of the ACE label that is generated by
the encoding steps in [PUNYCODE].
While all ACE labels begin with the ACE prefix, not all labels
beginning with the ACE prefix are necessarily ACE labels. Non-ACE
labels that begin with the ACE prefix will confuse users and SHOULD
NOT be allowed in DNS zones.
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6. Implications for typical applications using DNS
In IDNA, applications perform the processing needed to input
internationalized domain names from users, display internationalized
domain names to users, and process the inputs and outputs from DNS
and other protocols that carry domain names.
The components and interfaces between them can be represented
pictorially as:
+------+
| User |
+------+
^
| Input and display: local interface methods
| (pen, keyboard, glowing phosphorus, ...)
+-------------------|-------------------------------+
| v |
| +-----------------------------+ |
| | Application | |
| | (ToASCII and ToUnicode | |
| | operations may be | |
| | called here) | |
| +-----------------------------+ |
| ^ ^ | End system
| | | |
| Call to resolver: | | Application-specific |
| ACE | | protocol: |
| v | ACE unless the |
| +----------+ | protocol is updated |
| | Resolver | | to handle other |
| +----------+ | encodings |
| ^ | |
+-----------------|----------|----------------------+
DNS protocol: | |
ACE | |
v v
+-------------+ +---------------------+
| DNS servers | | Application servers |
+-------------+ +---------------------+
The box labeled "Application" is where the application splits a
domain name into labels, sets the appropriate flags, and performs the
ToASCII and ToUnicode operations. This is described in section 4.
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6.1 Entry and display in applications
Applications can accept domain names using any character set or sets
desired by the application developer, and can display domain names in
any charset. That is, the IDNA protocol does not affect the
interface between users and applications.
An IDNA-aware application can accept and display internationalized
domain names in two formats: the internationalized character set(s)
supported by the application, and as an ACE label. ACE labels that
are displayed or input MUST always include the ACE prefix.
Applications MAY allow input and display of ACE labels, but are not
encouraged to do so except as an interface for special purposes,
possibly for debugging, or to cope with display limitations as
described in section 6.4.. ACE encoding is opaque and ugly, and
should thus only be exposed to users who absolutely need it. Because
name labels encoded as ACE name labels can be rendered either as the
encoded ASCII characters or the proper decoded characters, the
application MAY have an option for the user to select the preferred
method of display; if it does, rendering the ACE SHOULD NOT be the
default.
Domain names are often stored and transported in many places. For
example, they are part of documents such as mail messages and web
pages. They are transported in many parts of many protocols, such as
both the control commands and the RFC 2822 body parts of SMTP, and
the headers and the body content in HTTP. It is important to
remember that domain names appear both in domain name slots and in
the content that is passed over protocols.
In protocols and document formats that define how to handle
specification or negotiation of charsets, labels can be encoded in
any charset allowed by the protocol or document format. If a
protocol or document format only allows one charset, the labels MUST
be given in that charset.
In any place where a protocol or document format allows transmission
of the characters in internationalized labels, internationalized
labels SHOULD be transmitted using whatever character encoding and
escape mechanism that the protocol or document format uses at that
place.
All protocols that use domain name slots already have the capacity
for handling domain names in the ASCII charset. Thus, ACE labels
(internationalized labels that have been processed with the ToASCII
operation) can inherently be handled by those protocols.
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6.2 Applications and resolver libraries
Applications normally use functions in the operating system when they
resolve DNS queries. Those functions in the operating system are
often called "the resolver library", and the applications communicate
with the resolver libraries through a programming interface (API).
Because these resolver libraries today expect only domain names in
ASCII, applications MUST prepare labels that are passed to the
resolver library using the ToASCII operation. Labels received from
the resolver library contain only ASCII characters; internationalized
labels that cannot be represented directly in ASCII use the ACE form.
ACE labels always include the ACE prefix.
An operating system might have a set of libraries for performing the
ToASCII operation. The input to such a library might be in one or
more charsets that are used in applications (UTF-8 and UTF-16 are
likely candidates for almost any operating system, and script-
specific charsets are likely for localized operating systems).
IDNA-aware applications MUST be able to work with both non-
internationalized labels (those that conform to [STD13] and [STD3])
and internationalized labels.
It is expected that new versions of the resolver libraries in the
future will be able to accept domain names in other charsets than
ASCII, and application developers might one day pass not only domain
names in Unicode, but also in local script to a new API for the
resolver libraries in the operating system. Thus the ToASCII and
ToUnicode operations might be performed inside these new versions of
the resolver libraries.
Domain names passed to resolvers or put into the question section of
DNS requests follow the rules for "queries" from [STRINGPREP].
6.3 DNS servers
Domain names stored in zones follow the rules for "stored strings"
from [STRINGPREP].
For internationalized labels that cannot be represented directly in
ASCII, DNS servers MUST use the ACE form produced by the ToASCII
operation. All IDNs served by DNS servers MUST contain only ASCII
characters.
If a signaling system which makes negotiation possible between old
and new DNS clients and servers is standardized in the future, the
encoding of the query in the DNS protocol itself can be changed from
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ACE to something else, such as UTF-8. The question whether or not
this should be used is, however, a separate problem and is not
discussed in this memo.
6.4 Avoiding exposing users to the raw ACE encoding
Any application that might show the user a domain name obtained from
a domain name slot, such as from gethostbyaddr or part of a mail
header, will need to be updated if it is to prevent users from seeing
the ACE.
If an application decodes an ACE name using ToUnicode but cannot show
all of the characters in the decoded name, such as if the name
contains characters that the output system cannot display, the
application SHOULD show the name in ACE format (which always includes
the ACE prefix) instead of displaying the name with the replacement
character (U+FFFD). This is to make it easier for the user to
transfer the name correctly to other programs. Programs that by
default show the ACE form when they cannot show all the characters in
a name label SHOULD also have a mechanism to show the name that is
produced by the ToUnicode operation with as many characters as
possible and replacement characters in the positions where characters
cannot be displayed.
The ToUnicode operation does not alter labels that are not valid ACE
labels, even if they begin with the ACE prefix. After ToUnicode has
been applied, if a label still begins with the ACE prefix, then it is
not a valid ACE label, and is not equivalent to any of the
intermediate Unicode strings constructed by ToUnicode.
6.5 DNSSEC authentication of IDN domain names
DNS Security [RFC2535] is a method for supplying cryptographic
verification information along with DNS messages. Public Key
Cryptography is used in conjunction with digital signatures to
provide a means for a requester of domain information to authenticate
the source of the data. This ensures that it can be traced back to a
trusted source, either directly, or via a chain of trust linking the
source of the information to the top of the DNS hierarchy.
IDNA specifies that all internationalized domain names served by DNS
servers that cannot be represented directly in ASCII must use the ACE
form produced by the ToASCII operation. This operation must be
performed prior to a zone being signed by the private key for that
zone. Because of this ordering, it is important to recognize that
DNSSEC authenticates the ASCII domain name, not the Unicode form or
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RFC 3490 IDNA March 2003
the mapping between the Unicode form and the ASCII form. In the
presence of DNSSEC, this is the name that MUST be signed in the zone
and MUST be validated against.
One consequence of this for sites deploying IDNA in the presence of
DNSSEC is that any special purpose proxies or forwarders used to
transform user input into IDNs must be earlier in the resolution flow
than DNSSEC authenticating nameservers for DNSSEC to work.
7. Name server considerations
Existing DNS servers do not know the IDNA rules for handling non-
ASCII forms of IDNs, and therefore need to be shielded from them.
All existing channels through which names can enter a DNS server
database (for example, master files [STD13] and DNS update messages
[RFC2136]) are IDN-unaware because they predate IDNA, and therefore
requirement 2 of section 3.1 of this document provides the needed
shielding, by ensuring that internationalized domain names entering
DNS server databases through such channels have already been
converted to their equivalent ASCII forms.
It is imperative that there be only one ASCII encoding for a
particular domain name. Because of the design of the ToASCII and
ToUnicode operations, there are no ACE labels that decode to ASCII
labels, and therefore name servers cannot contain multiple ASCII
encodings of the same domain name.
[RFC2181] explicitly allows domain labels to contain octets beyond
the ASCII range (0..7F), and this document does not change that.
Note, however, that there is no defined interpretation of octets
80..FF as characters. If labels containing these octets are returned
to applications, unpredictable behavior could result. The ASCII form
defined by ToASCII is the only standard representation for
internationalized labels in the current DNS protocol.
8. Root server considerations
IDNs are likely to be somewhat longer than current domain names, so
the bandwidth needed by the root servers is likely to go up by a
small amount. Also, queries and responses for IDNs will probably be
somewhat longer than typical queries today, so more queries and
responses may be forced to go to TCP instead of UDP.
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9. References
9.1 Normative References
[RFC2119] Bradner, S., "Key words for use in RFCs to Indicate
Requirement Levels", BCP 14, RFC 2119, March 1997.
[STRINGPREP] Hoffman, P. and M. Blanchet, "Preparation of
Internationalized Strings ("stringprep")", RFC 3454,
December 2002.
[NAMEPREP] Hoffman, P. and M. Blanchet, "Nameprep: A Stringprep
Profile for Internationalized Domain Names (IDN)", RFC
3491, March 2003.
[PUNYCODE] Costello, A., "Punycode: A Bootstring encoding of
Unicode for use with Internationalized Domain Names in
Applications (IDNA)", RFC 3492, March 2003.
[STD3] Braden, R., "Requirements for Internet Hosts --
Communication Layers", STD 3, RFC 1122, and
"Requirements for Internet Hosts -- Application and
Support", STD 3, RFC 1123, October 1989.
[STD13] Mockapetris, P., "Domain names - concepts and
facilities", STD 13, RFC 1034 and "Domain names -
implementation and specification", STD 13, RFC 1035,
November 1987.
9.2 Informative References
[RFC2535] Eastlake, D., "Domain Name System Security Extensions",
RFC 2535, March 1999.
[RFC2181] Elz, R. and R. Bush, "Clarifications to the DNS
Specification", RFC 2181, July 1997.
[UAX9] Unicode Standard Annex #9, The Bidirectional Algorithm,
<http://www.unicode.org/unicode/reports/tr9/>.
[UNICODE] The Unicode Consortium. The Unicode Standard, Version
3.2.0 is defined by The Unicode Standard, Version 3.0
(Reading, MA, Addison-Wesley, 2000. ISBN 0-201-61633-5),
as amended by the Unicode Standard Annex #27: Unicode
3.1 (http://www.unicode.org/reports/tr27/) and by the
Unicode Standard Annex #28: Unicode 3.2
(http://www.unicode.org/reports/tr28/).
Faltstrom, et al. Standards Track [Page 18]
RFC 3490 IDNA March 2003
[USASCII] Cerf, V., "ASCII format for Network Interchange", RFC
20, October 1969.
10. Security Considerations
Security on the Internet partly relies on the DNS. Thus, any change
to the characteristics of the DNS can change the security of much of
the Internet.
This memo describes an algorithm which encodes characters that are
not valid according to STD3 and STD13 into octet values that are
valid. No security issues such as string length increases or new
allowed values are introduced by the encoding process or the use of
these encoded values, apart from those introduced by the ACE encoding
itself.
Domain names are used by users to identify and connect to Internet
servers. The security of the Internet is compromised if a user
entering a single internationalized name is connected to different
servers based on different interpretations of the internationalized
domain name.
When systems use local character sets other than ASCII and Unicode,
this specification leaves the the problem of transcoding between the
local character set and Unicode up to the application. If different
applications (or different versions of one application) implement
different transcoding rules, they could interpret the same name
differently and contact different servers. This problem is not
solved by security protocols like TLS that do not take local
character sets into account.
Because this document normatively refers to [NAMEPREP], [PUNYCODE],
and [STRINGPREP], it includes the security considerations from those
documents as well.
If or when this specification is updated to use a more recent Unicode
normalization table, the new normalization table will need to be
compared with the old to spot backwards incompatible changes. If
there are such changes, they will need to be handled somehow, or
there will be security as well as operational implications. Methods
to handle the conflicts could include keeping the old normalization,
or taking care of the conflicting characters by operational means, or
some other method.
Implementations MUST NOT use more recent normalization tables than
the one referenced from this document, even though more recent tables
may be provided by operating systems. If an application is unsure of
which version of the normalization tables are in the operating
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RFC 3490 IDNA March 2003
system, the application needs to include the normalization tables
itself. Using normalization tables other than the one referenced
from this specification could have security and operational
implications.
To help prevent confusion between characters that are visually
similar, it is suggested that implementations provide visual
indications where a domain name contains multiple scripts. Such
mechanisms can also be used to show when a name contains a mixture of
simplified and traditional Chinese characters, or to distinguish zero
and one from O and l. DNS zone adminstrators may impose restrictions
(subject to the limitations in section 2) that try to minimize
homographs.
Domain names (or portions of them) are sometimes compared against a
set of privileged or anti-privileged domains. In such situations it
is especially important that the comparisons be done properly, as
specified in section 3.1 requirement 4. For labels already in ASCII
form, the proper comparison reduces to the same case-insensitive
ASCII comparison that has always been used for ASCII labels.
The introduction of IDNA means that any existing labels that start
with the ACE prefix and would be altered by ToUnicode will
automatically be ACE labels, and will be considered equivalent to
non-ASCII labels, whether or not that was the intent of the zone
adminstrator or registrant.
11. IANA Considerations
IANA has assigned the ACE prefix in consultation with the IESG.
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12. Authors' Addresses
Patrik Faltstrom
Cisco Systems
Arstaangsvagen 31 J
S-117 43 Stockholm Sweden
EMail: paf@cisco.com
Paul Hoffman
Internet Mail Consortium and VPN Consortium
127 Segre Place
Santa Cruz, CA 95060 USA
EMail: phoffman@imc.org
Adam M. Costello
University of California, Berkeley
URL: http://www.nicemice.net/amc/
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RFC 3490 IDNA March 2003
13. Full Copyright Statement
Copyright (C) The Internet Society (2003). All Rights Reserved.
This document and translations of it may be copied and furnished to
others, and derivative works that comment on or otherwise explain it
or assist in its implementation may be prepared, copied, published
and distributed, in whole or in part, without restriction of any
kind, provided that the above copyright notice and this paragraph are
included on all such copies and derivative works. However, this
document itself may not be modified in any way, such as by removing
the copyright notice or references to the Internet Society or other
Internet organizations, except as needed for the purpose of
developing Internet standards in which case the procedures for
copyrights defined in the Internet Standards process must be
followed, or as required to translate it into languages other than
English.
The limited permissions granted above are perpetual and will not be
revoked by the Internet Society or its successors or assigns.
This document and the information contained herein is provided on an
"AS IS" basis and THE INTERNET SOCIETY AND THE INTERNET ENGINEERING
TASK FORCE DISCLAIMS ALL WARRANTIES, EXPRESS OR IMPLIED, INCLUDING
BUT NOT LIMITED TO ANY WARRANTY THAT THE USE OF THE INFORMATION
HEREIN WILL NOT INFRINGE ANY RIGHTS OR ANY IMPLIED WARRANTIES OF
MERCHANTABILITY OR FITNESS FOR A PARTICULAR PURPOSE.
Acknowledgement
Funding for the RFC Editor function is currently provided by the
Internet Society.
Faltstrom, et al. Standards Track [Page 22]
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