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564 lines
21 KiB
Plaintext
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Network Working Group F. Yergeau
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Request for Comments: 2279 Alis Technologies
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Obsoletes: 2044 January 1998
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Category: Standards Track
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UTF-8, a transformation format of ISO 10646
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Status of this Memo
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This document specifies an Internet standards track protocol for the
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Internet community, and requests discussion and suggestions for
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improvements. Please refer to the current edition of the "Internet
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Official Protocol Standards" (STD 1) for the standardization state
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and status of this protocol. Distribution of this memo is unlimited.
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Copyright Notice
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Copyright (C) The Internet Society (1998). All Rights Reserved.
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Abstract
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ISO/IEC 10646-1 defines a multi-octet character set called the
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Universal Character Set (UCS) which encompasses most of the world's
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writing systems. Multi-octet characters, however, are not compatible
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with many current applications and protocols, and this has led to the
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development of a few so-called UCS transformation formats (UTF), each
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with different characteristics. UTF-8, the object of this memo, has
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the characteristic of preserving the full US-ASCII range, providing
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compatibility with file systems, parsers and other software that rely
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on US-ASCII values but are transparent to other values. This memo
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updates and replaces RFC 2044, in particular addressing the question
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of versions of the relevant standards.
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1. Introduction
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ISO/IEC 10646-1 [ISO-10646] defines a multi-octet character set
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called the Universal Character Set (UCS), which encompasses most of
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the world's writing systems. Two multi-octet encodings are defined,
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a four-octet per character encoding called UCS-4 and a two-octet per
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character encoding called UCS-2, able to address only the first 64K
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characters of the UCS (the Basic Multilingual Plane, BMP), outside of
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which there are currently no assignments.
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It is noteworthy that the same set of characters is defined by the
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Unicode standard [UNICODE], which further defines additional
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character properties and other application details of great interest
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to implementors, but does not have the UCS-4 encoding. Up to the
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Yergeau Standards Track [Page 1]
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RFC 2279 UTF-8 January 1998
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present time, changes in Unicode and amendments to ISO/IEC 10646 have
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tracked each other, so that the character repertoires and code point
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assignments have remained in sync. The relevant standardization
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committees have committed to maintain this very useful synchronism.
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The UCS-2 and UCS-4 encodings, however, are hard to use in many
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current applications and protocols that assume 8 or even 7 bit
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characters. Even newer systems able to deal with 16 bit characters
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cannot process UCS-4 data. This situation has led to the development
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of so-called UCS transformation formats (UTF), each with different
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characteristics.
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UTF-1 has only historical interest, having been removed from ISO/IEC
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10646. UTF-7 has the quality of encoding the full BMP repertoire
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using only octets with the high-order bit clear (7 bit US-ASCII
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values, [US-ASCII]), and is thus deemed a mail-safe encoding
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([RFC2152]). UTF-8, the object of this memo, uses all bits of an
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octet, but has the quality of preserving the full US-ASCII range:
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US-ASCII characters are encoded in one octet having the normal US-
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ASCII value, and any octet with such a value can only stand for an
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US-ASCII character, and nothing else.
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UTF-16 is a scheme for transforming a subset of the UCS-4 repertoire
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into pairs of UCS-2 values from a reserved range. UTF-16 impacts
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UTF-8 in that UCS-2 values from the reserved range must be treated
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specially in the UTF-8 transformation.
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UTF-8 encodes UCS-2 or UCS-4 characters as a varying number of
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octets, where the number of octets, and the value of each, depend on
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the integer value assigned to the character in ISO/IEC 10646. This
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transformation format has the following characteristics (all values
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are in hexadecimal):
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- Character values from 0000 0000 to 0000 007F (US-ASCII repertoire)
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correspond to octets 00 to 7F (7 bit US-ASCII values). A direct
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consequence is that a plain ASCII string is also a valid UTF-8
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string.
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- US-ASCII values do not appear otherwise in a UTF-8 encoded
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character stream. This provides compatibility with file systems
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or other software (e.g. the printf() function in C libraries) that
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parse based on US-ASCII values but are transparent to other
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values.
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- Round-trip conversion is easy between UTF-8 and either of UCS-4,
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UCS-2.
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Yergeau Standards Track [Page 2]
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RFC 2279 UTF-8 January 1998
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- The first octet of a multi-octet sequence indicates the number of
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octets in the sequence.
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- The octet values FE and FF never appear.
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- Character boundaries are easily found from anywhere in an octet
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stream.
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- The lexicographic sorting order of UCS-4 strings is preserved. Of
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course this is of limited interest since the sort order is not
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culturally valid in either case.
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- The Boyer-Moore fast search algorithm can be used with UTF-8 data.
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- UTF-8 strings can be fairly reliably recognized as such by a
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simple algorithm, i.e. the probability that a string of characters
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in any other encoding appears as valid UTF-8 is low, diminishing
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with increasing string length.
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UTF-8 was originally a project of the X/Open Joint
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Internationalization Group XOJIG with the objective to specify a File
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System Safe UCS Transformation Format [FSS-UTF] that is compatible
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with UNIX systems, supporting multilingual text in a single encoding.
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The original authors were Gary Miller, Greger Leijonhufvud and John
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Entenmann. Later, Ken Thompson and Rob Pike did significant work for
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the formal UTF-8.
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A description can also be found in Unicode Technical Report #4 and in
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the Unicode Standard, version 2.0 [UNICODE]. The definitive
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reference, including provisions for UTF-16 data within UTF-8, is
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Annex R of ISO/IEC 10646-1 [ISO-10646].
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2. UTF-8 definition
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In UTF-8, characters are encoded using sequences of 1 to 6 octets.
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The only octet of a "sequence" of one has the higher-order bit set to
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0, the remaining 7 bits being used to encode the character value. In
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a sequence of n octets, n>1, the initial octet has the n higher-order
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bits set to 1, followed by a bit set to 0. The remaining bit(s) of
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that octet contain bits from the value of the character to be
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encoded. The following octet(s) all have the higher-order bit set to
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1 and the following bit set to 0, leaving 6 bits in each to contain
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bits from the character to be encoded.
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The table below summarizes the format of these different octet types.
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The letter x indicates bits available for encoding bits of the UCS-4
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character value.
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Yergeau Standards Track [Page 3]
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RFC 2279 UTF-8 January 1998
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UCS-4 range (hex.) UTF-8 octet sequence (binary)
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0000 0000-0000 007F 0xxxxxxx
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0000 0080-0000 07FF 110xxxxx 10xxxxxx
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0000 0800-0000 FFFF 1110xxxx 10xxxxxx 10xxxxxx
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0001 0000-001F FFFF 11110xxx 10xxxxxx 10xxxxxx 10xxxxxx
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0020 0000-03FF FFFF 111110xx 10xxxxxx 10xxxxxx 10xxxxxx 10xxxxxx
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0400 0000-7FFF FFFF 1111110x 10xxxxxx ... 10xxxxxx
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Encoding from UCS-4 to UTF-8 proceeds as follows:
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1) Determine the number of octets required from the character value
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and the first column of the table above. It is important to note
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that the rows of the table are mutually exclusive, i.e. there is
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only one valid way to encode a given UCS-4 character.
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2) Prepare the high-order bits of the octets as per the second column
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of the table.
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3) Fill in the bits marked x from the bits of the character value,
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starting from the lower-order bits of the character value and
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putting them first in the last octet of the sequence, then the
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next to last, etc. until all x bits are filled in.
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The algorithm for encoding UCS-2 (or Unicode) to UTF-8 can be
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obtained from the above, in principle, by simply extending each
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UCS-2 character with two zero-valued octets. However, pairs of
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UCS-2 values between D800 and DFFF (surrogate pairs in Unicode
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parlance), being actually UCS-4 characters transformed through
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UTF-16, need special treatment: the UTF-16 transformation must be
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undone, yielding a UCS-4 character that is then transformed as
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above.
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Decoding from UTF-8 to UCS-4 proceeds as follows:
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1) Initialize the 4 octets of the UCS-4 character with all bits set
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to 0.
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2) Determine which bits encode the character value from the number of
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octets in the sequence and the second column of the table above
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(the bits marked x).
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3) Distribute the bits from the sequence to the UCS-4 character,
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first the lower-order bits from the last octet of the sequence and
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proceeding to the left until no x bits are left.
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If the UTF-8 sequence is no more than three octets long, decoding
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can proceed directly to UCS-2.
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Yergeau Standards Track [Page 4]
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RFC 2279 UTF-8 January 1998
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NOTE -- actual implementations of the decoding algorithm above
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should protect against decoding invalid sequences. For
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instance, a naive implementation may (wrongly) decode the
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invalid UTF-8 sequence C0 80 into the character U+0000, which
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may have security consequences and/or cause other problems. See
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the Security Considerations section below.
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A more detailed algorithm and formulae can be found in [FSS_UTF],
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[UNICODE] or Annex R to [ISO-10646].
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3. Versions of the standards
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ISO/IEC 10646 is updated from time to time by published amendments;
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similarly, different versions of the Unicode standard exist: 1.0, 1.1
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and 2.0 as of this writing. Each new version obsoletes and replaces
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the previous one, but implementations, and more significantly data,
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are not updated instantly.
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In general, the changes amount to adding new characters, which does
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not pose particular problems with old data. Amendment 5 to ISO/IEC
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10646, however, has moved and expanded the Korean Hangul block,
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thereby making any previous data containing Hangul characters invalid
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under the new version. Unicode 2.0 has the same difference from
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Unicode 1.1. The official justification for allowing such an
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incompatible change was that no implementations and no data
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containing Hangul existed, a statement that is likely to be true but
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remains unprovable. The incident has been dubbed the "Korean mess",
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and the relevant committees have pledged to never, ever again make
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such an incompatible change.
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New versions, and in particular any incompatible changes, have q
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conseuences regarding MIME character encoding labels, to be discussed
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in section 5.
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4. Examples
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The UCS-2 sequence "A<NOT IDENTICAL TO><ALPHA>." (0041, 2262, 0391,
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002E) may be encoded in UTF-8 as follows:
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41 E2 89 A2 CE 91 2E
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The UCS-2 sequence representing the Hangul characters for the Korean
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word "hangugo" (D55C, AD6D, C5B4) may be encoded as follows:
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ED 95 9C EA B5 AD EC 96 B4
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Yergeau Standards Track [Page 5]
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RFC 2279 UTF-8 January 1998
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The UCS-2 sequence representing the Han characters for the Japanese
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word "nihongo" (65E5, 672C, 8A9E) may be encoded as follows:
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E6 97 A5 E6 9C AC E8 AA 9E
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5. MIME registration
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This memo is meant to serve as the basis for registration of a MIME
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character set parameter (charset) [CHARSET-REG]. The proposed
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charset parameter value is "UTF-8". This string labels media types
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containing text consisting of characters from the repertoire of
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ISO/IEC 10646 including all amendments at least up to amendment 5
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(Korean block), encoded to a sequence of octets using the encoding
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scheme outlined above. UTF-8 is suitable for use in MIME content
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types under the "text" top-level type.
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It is noteworthy that the label "UTF-8" does not contain a version
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identification, referring generically to ISO/IEC 10646. This is
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intentional, the rationale being as follows:
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A MIME charset label is designed to give just the information needed
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to interpret a sequence of bytes received on the wire into a sequence
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of characters, nothing more (see RFC 2045, section 2.2, in [MIME]).
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As long as a character set standard does not change incompatibly,
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version numbers serve no purpose, because one gains nothing by
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learning from the tag that newly assigned characters may be received
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that one doesn't know about. The tag itself doesn't teach anything
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about the new characters, which are going to be received anyway.
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Hence, as long as the standards evolve compatibly, the apparent
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advantage of having labels that identify the versions is only that,
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apparent. But there is a disadvantage to such version-dependent
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labels: when an older application receives data accompanied by a
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newer, unknown label, it may fail to recognize the label and be
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completely unable to deal with the data, whereas a generic, known
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label would have triggered mostly correct processing of the data,
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which may well not contain any new characters.
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Now the "Korean mess" (ISO/IEC 10646 amendment 5) is an incompatible
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change, in principle contradicting the appropriateness of a version
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independent MIME charset label as described above. But the
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compatibility problem can only appear with data containing Korean
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Hangul characters encoded according to Unicode 1.1 (or equivalently
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ISO/IEC 10646 before amendment 5), and there is arguably no such data
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to worry about, this being the very reason the incompatible change
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was deemed acceptable.
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Yergeau Standards Track [Page 6]
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RFC 2279 UTF-8 January 1998
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In practice, then, a version-independent label is warranted, provided
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the label is understood to refer to all versions after Amendment 5,
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and provided no incompatible change actually occurs. Should
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incompatible changes occur in a later version of ISO/IEC 10646, the
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MIME charset label defined here will stay aligned with the previous
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version until and unless the IETF specifically decides otherwise.
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It is also proposed to register the charset parameter value
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"UNICODE-1-1-UTF-8", for the exclusive purpose of labelling text data
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containing Hangul syllables encoded to UTF-8 without taking into
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account Amendment 5 of ISO/IEC 10646 (i.e. using the pre-amendment 5
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code point assignments). Any other UTF-8 data SHOULD NOT use this
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label, in particular data not containing any Hangul syllables, and it
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is felt important to strongly recommend against creating any new
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Hangul-containing data without taking Amendment 5 of ISO/IEC 10646
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into account.
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6. Security Considerations
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Implementors of UTF-8 need to consider the security aspects of how
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they handle illegal UTF-8 sequences. It is conceivable that in some
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circumstances an attacker would be able to exploit an incautious
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UTF-8 parser by sending it an octet sequence that is not permitted by
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the UTF-8 syntax.
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A particularly subtle form of this attack could be carried out
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against a parser which performs security-critical validity checks
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against the UTF-8 encoded form of its input, but interprets certain
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illegal octet sequences as characters. For example, a parser might
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prohibit the NUL character when encoded as the single-octet sequence
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00, but allow the illegal two-octet sequence C0 80 and interpret it
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as a NUL character. Another example might be a parser which
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prohibits the octet sequence 2F 2E 2E 2F ("/../"), yet permits the
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illegal octet sequence 2F C0 AE 2E 2F.
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Acknowledgments
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The following have participated in the drafting and discussion of
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this memo:
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James E. Agenbroad Andries Brouwer
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Martin J. D|rst Ned Freed
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David Goldsmith Edwin F. Hart
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Kent Karlsson Markus Kuhn
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Michael Kung Alain LaBonte
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John Gardiner Myers Murray Sargent
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Keld Simonsen Arnold Winkler
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Yergeau Standards Track [Page 7]
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RFC 2279 UTF-8 January 1998
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Bibliography
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[CHARSET-REG] Freed, N., and J. Postel, "IANA Charset Registration
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Procedures", BCP 19, RFC 2278, January 1998.
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[FSS_UTF] X/Open CAE Specification C501 ISBN 1-85912-082-2 28cm.
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22p. pbk. 172g. 4/95, X/Open Company Ltd., "File
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System Safe UCS Transformation Format (FSS_UTF)",
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X/Open Preleminary Specification, Document Number
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P316. Also published in Unicode Technical Report #4.
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||
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[ISO-10646] ISO/IEC 10646-1:1993. International Standard --
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Information technology -- Universal Multiple-Octet
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Coded Character Set (UCS) -- Part 1: Architecture and
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Basic Multilingual Plane. Five amendments and a
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technical corrigendum have been published up to now.
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UTF-8 is described in Annex R, published as Amendment
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2. UTF-16 is described in Annex Q, published as
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||
Amendment 1. 17 other amendments are currently at
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various stages of standardization.
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||
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[MIME] Freed, N., and N. Borenstein, "Multipurpose Internet
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||
Mail Extensions (MIME) Part One: Format of Internet
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||
Message Bodies", RFC 2045. N. Freed, N. Borenstein,
|
||
"Multipurpose Internet Mail Extensions (MIME) Part
|
||
Two: Media Types", RFC 2046. K. Moore, "MIME
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||
(Multipurpose Internet Mail Extensions) Part Three:
|
||
Message Header Extensions for Non-ASCII Text", RFC
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||
2047. N. Freed, J. Klensin, J. Postel, "Multipurpose
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Internet Mail Extensions (MIME) Part Four:
|
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Registration Procedures", RFC 2048. N. Freed, N.
|
||
Borenstein, " Multipurpose Internet Mail Extensions
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(MIME) Part Five: Conformance Criteria and Examples",
|
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RFC 2049. All November 1996.
|
||
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[RFC2152] Goldsmith, D., and M. Davis, "UTF-7: A Mail-safe
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Transformation Format of Unicode", RFC 1642, Taligent
|
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inc., May 1997. (Obsoletes RFC1642)
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[UNICODE] The Unicode Consortium, "The Unicode Standard --
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Version 2.0", Addison-Wesley, 1996.
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[US-ASCII] Coded Character Set--7-bit American Standard Code for
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Information Interchange, ANSI X3.4-1986.
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Yergeau Standards Track [Page 8]
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RFC 2279 UTF-8 January 1998
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Author's Address
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Francois Yergeau
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Alis Technologies
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100, boul. Alexis-Nihon
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Suite 600
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Montreal QC H4M 2P2
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Canada
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Phone: +1 (514) 747-2547
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Fax: +1 (514) 747-2561
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EMail: fyergeau@alis.com
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Yergeau Standards Track [Page 9]
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RFC 2279 UTF-8 January 1998
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Full Copyright Statement
|
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Copyright (C) The Internet Society (1998). All Rights Reserved.
|
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|
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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
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developing Internet standards in which case the procedures for
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copyrights defined in the Internet Standards process must be
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followed, or as required to translate it into languages other than
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English.
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|
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The limited permissions granted above are perpetual and will not be
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revoked by the Internet Society or its successors or assigns.
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|
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This document and the information contained herein is provided on an
|
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"AS IS" basis and THE INTERNET SOCIETY AND THE INTERNET ENGINEERING
|
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TASK FORCE DISCLAIMS ALL WARRANTIES, EXPRESS OR IMPLIED, INCLUDING
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BUT NOT LIMITED TO ANY WARRANTY THAT THE USE OF THE INFORMATION
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HEREIN WILL NOT INFRINGE ANY RIGHTS OR ANY IMPLIED WARRANTIES OF
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MERCHANTABILITY OR FITNESS FOR A PARTICULAR PURPOSE.
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|
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Yergeau Standards Track [Page 10]
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