This section describes the collations available for Unicode character sets and their differentiating properties. For general information about Unicode, see Section 1.9, “Unicode Support”.
MySQL supports multiple Unicode character sets:
utf8mb4
: A UTF-8 encoding of the Unicode character set using one to four bytes per character.utf8mb3
: A UTF-8 encoding of the Unicode character set using one to three bytes per character.utf8
: An alias forutf8mb3
.ucs2
: The UCS-2 encoding of the Unicode character set using two bytes per character.utf16
: The UTF-16 encoding for the Unicode character set using two or four bytes per character. Likeucs2
but with an extension for supplementary characters.utf16le
: The UTF-16LE encoding for the Unicode character set. Likeutf16
but little-endian rather than big-endian.utf32
: The UTF-32 encoding for the Unicode character set using four bytes per character.
utf8mb4
, utf16
,
utf16le
, and utf32
support
Basic Multilingual Plane (BMP) characters and supplementary
characters that lie outside the BMP. utf8
and
ucs2
support only BMP characters.
Most Unicode character sets have a general collation (indicated
by _general
in the name or by the absence of
a language specifier), a binary collation (indicated by
_bin
in the name), and several
language-specific collations (indicated by language specifiers).
For example, for utf8mb4
,
utf8mb4_general_ci
and
utf8mb4_bin
are its general and binary
collations, and utf8mb4_danish_ci
is one of
its language-specific collations.
Collation support for utf16le
is limited. The
only collations available are
utf16le_general_ci
and
utf16le_bin
. These are similar to
utf16_general_ci
and
utf16_bin
.
MySQL implements the
collations according to the Unicode Collation Algorithm (UCA)
described at
http://www.unicode.org/reports/tr10/. The
collation uses the version-4.0.0 UCA weight keys:
http://www.unicode.org/Public/UCA/4.0.0/allkeys-4.0.0.txt.
The
xxx
_unicode_ci
collations have only partial support for the Unicode Collation
Algorithm. Some characters are not supported, and combining
marks are not fully supported. This affects primarily
Vietnamese, Yoruba, and some smaller languages such as Navajo.
A combined character is considered different from the same
character written with a single unicode character in string
comparisons, and the two characters are considered to have a
different length (for example, as returned by the
xxx
_unicode_ciCHAR_LENGTH()
function or in
result set metadata).
Unicode collations based on UCA versions higher than 4.0.0
include the version in the collation name. Thus,
utf8_unicode_520_ci
is based on UCA 5.2.0
weight keys
(http://www.unicode.org/Public/UCA/5.2.0/allkeys.txt).
The LOWER()
and
UPPER()
functions perform case
folding according to the collation of their argument. A
character that has uppercase and lowercase versions only in a
Unicode version higher than 4.0.0 is converted by these
functions only if the argument collation uses a high enough
UCA version.
MySQL implements language-specific Unicode collations if the ordering based only on the Unicode Collation Algorithm (UCA) does not work well for a language. Language-specific collations are UCA-based, with additional language tailoring rules. Examples of such rules appear later in this section. For questions about particular language orderings, http://unicode.org provides Common Locale Data Repository (CLDR) collation charts at http://www.unicode.org/cldr/charts/30/collation/index.html.
A language name shown in the following table indicates a language-specific collation. Unicode character sets may include collations for one or more of these languages.
Table 1.3 Unicode Collation Language Specifiers
Language | Language Specifier |
---|---|
Classical Latin | roman |
Croatian | croatian |
Czech | czech |
Danish | danish |
Esperanto | esperanto |
Estonian | estonian |
German phone book order | german2 |
Hungarian | hungarian |
Icelandic | icelandic |
Latvian | latvian |
Lithuanian | lithuanian |
Persian | persian |
Polish | polish |
Romanian | romanian |
Sinhala | sinhala |
Slovak | slovak |
Slovenian | slovenian |
Modern Spanish | spanish |
Traditional Spanish | spanish2 |
Swedish | swedish |
Turkish | turkish |
Vietnamese | vietnamese |
Croatian collations are tailored for these Croatian letters:
Č
, Ć
,
Dž
, Đ
,
Lj
, Nj
,
Š
, Ž
.
Danish collations may also be used for Norwegian.
For Classical Latin collations, I
and
J
compare as equal, and
U
and V
compare as
equal.
Spanish collations are available for modern and traditional
Spanish. For both, ñ
(n-tilde) is a
separate letter between n
and
o
. In addition, for traditional Spanish,
ch
is a separate letter between
c
and d
, and
ll
is a separate letter between
l
and m
.
Traditional Spanish collations may also be used for Asturian and Galician.
Swedish collations include Swedish rules. For example, in Swedish, the following relationship holds, which is not something expected by a German or French speaker:
Ü = Y < Ö
For any Unicode character set, operations performed using the
collation are faster than those for the
xxx
_general_ci
collation. For example, comparisons for the
xxx
_unicode_ciutf8_general_ci
collation are faster, but
slightly less correct, than comparisons for
utf8_unicode_ci
. The reason is that
utf8_unicode_ci
supports mappings such as
expansions; that is, when one character compares as equal to
combinations of other characters. For example,
ß
is equal to ss
in
German and some other languages.
utf8_unicode_ci
also supports contractions
and ignorable characters. utf8_general_ci
is a legacy collation that does not support expansions,
contractions, or ignorable characters. It can make only
one-to-one comparisons between characters.
To further illustrate, the following equalities hold in both
utf8_general_ci
and
utf8_unicode_ci
(for the effect of this in
comparisons or searches, see
Section 1.8.6, “Examples of the Effect of Collation”):
Ä = A
Ö = O
Ü = U
A difference between the collations is that this is true for
utf8_general_ci
:
ß = s
Whereas this is true for utf8_unicode_ci
,
which supports the German DIN-1 ordering (also known as
dictionary order):
ß = ss
MySQL implements utf8
language-specific
collations if the ordering with
utf8_unicode_ci
does not work well for a
language. For example, utf8_unicode_ci
works fine for German dictionary order and French, so there is
no need to create special utf8
collations.
utf8_general_ci
also is satisfactory for
both German and French, except that ß
is
equal to s
, and not to
ss
. If this is acceptable for your
application, you should use utf8_general_ci
because it is faster. If this is not acceptable (for example,
if you require German dictionary order), use
utf8_unicode_ci
because it is more
accurate.
If you require German DIN-2 (phone book) ordering, use the
utf8_german2_ci
collation, which compares
the following sets of characters equal:
Ä = Æ = AE
Ö = Œ = OE
Ü = UE
ß = ss
utf8_german2_ci
is similar to
latin1_german2_ci
, but the latter does not
compare Æ
equal to AE
or Œ
equal to OE
. There
is no utf8_german_ci
corresponding to
latin1_german_ci
for German dictionary
order because utf8_general_ci
suffices.
A character's collating weight is determined as follows:
For all Unicode collations except the
_bin
(binary) collations, MySQL performs a table lookup to find a character's collating weight.For
_bin
collations, the weight is based on the code point, possibly with leading zero bytes added.
Collating weights can be displayed using the
WEIGHT_STRING()
function. (See
String Functions and Operators.) If a collation uses a
weight lookup table, but a character is not in the table (for
example, because it is a “new” character),
collating weight determination becomes more complex:
For BMP characters in general collations (
), the weight is the code point.xxx
_general_ciFor BMP characters in UCA collations (for example,
and language-specific collations), the following algorithm applies:xxx
_unicode_ciif (code >= 0x3400 && code <= 0x4DB5) base= 0xFB80; /* CJK Ideograph Extension */ else if (code >= 0x4E00 && code <= 0x9FA5) base= 0xFB40; /* CJK Ideograph */ else base= 0xFBC0; /* All other characters */ aaaa= base + (code >> 15); bbbb= (code & 0x7FFF) | 0x8000;
The result is a sequence of two collating elements,
aaaa
followed bybbbb
. For example:mysql> SELECT HEX(WEIGHT_STRING(_ucs2 0x04CF COLLATE ucs2_unicode_ci)); +----------------------------------------------------------+ | HEX(WEIGHT_STRING(_ucs2 0x04CF COLLATE ucs2_unicode_ci)) | +----------------------------------------------------------+ | FBC084CF | +----------------------------------------------------------+
Thus,
U+04cf CYRILLIC SMALL LETTER PALOCHKA
is, with all UCA 4.0.0 collations, greater thanU+04c0 CYRILLIC LETTER PALOCHKA
. With UCA 5.2.0 collations, all palochkas sort together.For supplementary characters in general collations, the weight is the weight for
0xfffd REPLACEMENT CHARACTER
. For supplementary characters in UCA 4.0.0 collations, their collating weight is0xfffd
. That is, to MySQL, all supplementary characters are equal to each other, and greater than almost all BMP characters.An example with Deseret characters and
COUNT(DISTINCT)
:CREATE TABLE t (s1 VARCHAR(5) CHARACTER SET utf32 COLLATE utf32_unicode_ci); INSERT INTO t VALUES (0xfffd); /* REPLACEMENT CHARACTER */ INSERT INTO t VALUES (0x010412); /* DESERET CAPITAL LETTER BEE */ INSERT INTO t VALUES (0x010413); /* DESERET CAPITAL LETTER TEE */ SELECT COUNT(DISTINCT s1) FROM t;
The result is 2 because in the MySQL
collations, the replacement character has a weight ofxxx
_unicode_ci0x0dc6
, whereas Deseret Bee and Deseret Tee both have a weight of0xfffd
. (Were theutf32_general_ci
collation used instead, the result is 1 because all three characters have a weight of0xfffd
in that collation.)An example with cuneiform characters and
WEIGHT_STRING()
:/* The four characters in the INSERT string are 00000041 # LATIN CAPITAL LETTER A 0001218F # CUNEIFORM SIGN KAB 000121A7 # CUNEIFORM SIGN KISH 00000042 # LATIN CAPITAL LETTER B */ CREATE TABLE t (s1 CHAR(4) CHARACTER SET utf32 COLLATE utf32_unicode_ci); INSERT INTO t VALUES (0x000000410001218f000121a700000042); SELECT HEX(WEIGHT_STRING(s1)) FROM t;
The result is:
0E33 FFFD FFFD 0E4A
0E33
and0E4A
are primary weights as in UCA 4.0.0.FFFD
is the weight for KAB and also for KISH.The rule that all supplementary characters are equal to each other is nonoptimal but is not expected to cause trouble. These characters are very rare, so it is very rare that a multi-character string consists entirely of supplementary characters. In Japan, since the supplementary characters are obscure Kanji ideographs, the typical user does not care what order they are in, anyway. If you really want rows sorted by the MySQL rule and secondarily by code point value, it is easy:
ORDER BY s1 COLLATE utf32_unicode_ci, s1 COLLATE utf32_bin
For supplementary characters based on UCA versions higher than 4.0.0 (for example,
), supplementary characters do not necessarily all have the same collating weight. Some have explicit weights from the UCAxxx
_unicode_520_ciallkeys.txt
file. Others have weights calculated from this algorithm:aaaa= base + (code >> 15); bbbb= (code & 0x7FFF) | 0x8000;
There is a difference between “ordering by the
character's code value” and “ordering by the
character's binary representation,” a difference that
appears only with utf16_bin
, because of
surrogates.
Suppose that utf16_bin
(the binary
collation for utf16
) was a binary
comparison “byte by byte” rather than
“character by character.” If that were so, the
order of characters in utf16_bin
would
differ from the order in utf8_bin
. For
example, the following chart shows two rare characters. The
first character is in the range
E000
-FFFF
, so it is
greater than a surrogate but less than a supplementary. The
second character is a supplementary.
Code point Character utf8 utf16
---------- --------- ---- -----
0FF9D HALFWIDTH KATAKANA LETTER N EF BE 9D FF 9D
10384 UGARITIC LETTER DELTA F0 90 8E 84 D8 00 DF 84
The two characters in the chart are in order by code point
value because 0xff9d
<
0x10384
. And they are in order by
utf8
value because 0xef
< 0xf0
. But they are not in order by
utf16
value, if we use byte-by-byte
comparison, because 0xff
>
0xd8
.
So MySQL's utf16_bin
collation is not
“byte by byte.” It is “by code
point.” When MySQL sees a supplementary-character
encoding in utf16
, it converts to the
character's code-point value, and then compares. Therefore,
utf8_bin
and utf16_bin
are the same ordering. This is consistent with the SQL:2008
standard requirement for a UCS_BASIC collation:
“UCS_BASIC is a collation in which the ordering is
determined entirely by the Unicode scalar values of the
characters in the strings being sorted. It is applicable to
the UCS character repertoire. Since every character repertoire
is a subset of the UCS repertoire, the UCS_BASIC collation is
potentially applicable to every character set. NOTE 11: The
Unicode scalar value of a character is its code point treated
as an unsigned integer.”
If the character set is ucs2
, comparison is
byte-by-byte, but ucs2
strings should not
contain surrogates, anyway.