Chapter 10. Character Set Support

Table of Contents

10.1. Character Sets and Collations in General
10.2. Character Sets and Collations in MySQL
10.3. Specifying Character Sets and Collations
10.3.1. Server Character Set and Collation
10.3.2. Database Character Set and Collation
10.3.3. Table Character Set and Collation
10.3.4. Column Character Set and Collation
10.3.5. Character String Literal Character Set and Collation
10.3.6. National Character Set
10.3.7. Examples of Character Set and Collation Assignment
10.3.8. Compatibility with Other DBMSs
10.4. Connection Character Sets and Collations
10.5. Collation Issues
10.5.1. Using COLLATE in SQL Statements
10.5.2. COLLATE Clause Precedence
10.5.3. BINARY Operator
10.5.4. Some Special Cases Where the Collation Determination Is Tricky
10.5.5. Collations Must Be for the Right Character Set
10.5.6. An Example of the Effect of Collation
10.6. Operations Affected by Character Set Support
10.6.1. Result Strings
10.6.2. CONVERT() and CAST()
10.6.3. SHOW Statements and INFORMATION_SCHEMA
10.7. Unicode Support
10.8. UTF-8 for Metadata
10.9. Column Character Set Conversion
10.10. Character Sets and Collations That MySQL Supports
10.10.1. Unicode Character Sets
10.10.2. West European Character Sets
10.10.3. Central European Character Sets
10.10.4. South European and Middle East Character Sets
10.10.5. Baltic Character Sets
10.10.6. Cyrillic Character Sets
10.10.7. Asian Character Sets

MySQL includes character set support that enables you to store data using a variety of character sets and perform comparisons according to a variety of collations. You can specify character sets at the server, database, table, and column level. MySQL supports the use of character sets for the MyISAM, MEMORY, NDBCluster, and InnoDB storage engines.

This chapter discusses the following topics:

Character set issues affect data storage, but also communication between client programs and the MySQL server. If you want the client program to communicate with the server using a character set different from the default, you'll need to indicate which one. For example, to use the utf8 Unicode character set, issue this statement after connecting to the server:

SET NAMES 'utf8';

For more information about character set-related issues in client/server communication, see Section 10.4, “Connection Character Sets and Collations”.

10.1. Character Sets and Collations in General

A character set is a set of symbols and encodings. A collation is a set of rules for comparing characters in a character set. Let's make the distinction clear with an example of an imaginary character set.

Suppose that we have an alphabet with four letters: ‘A’, ‘B’, ‘a’, ‘b’. We give each letter a number: ‘A’ = 0, ‘B’ = 1, ‘a’ = 2, ‘b’ = 3. The letter ‘A’ is a symbol, the number 0 is the encoding for ‘A’, and the combination of all four letters and their encodings is a character set.

Suppose that we want to compare two string values, ‘A’ and ‘B’. The simplest way to do this is to look at the encodings: 0 for ‘A’ and 1 for ‘B’. Because 0 is less than 1, we say ‘A’ is less than ‘B’. What we've just done is apply a collation to our character set. The collation is a set of rules (only one rule in this case): “compare the encodings.” We call this simplest of all possible collations a binary collation.

But what if we want to say that the lowercase and uppercase letters are equivalent? Then we would have at least two rules: (1) treat the lowercase letters ‘a’ and ‘b’ as equivalent to ‘A’ and ‘B’; (2) then compare the encodings. We call this a case-insensitive collation. It's a little more complex than a binary collation.

In real life, most character sets have many characters: not just ‘A’ and ‘B’ but whole alphabets, sometimes multiple alphabets or eastern writing systems with thousands of characters, along with many special symbols and punctuation marks. Also in real life, most collations have many rules, not just for whether to distinguish lettercase, but also for whether to distinguish accents (an “accent” is a mark attached to a character as in German ‘Ö’), and for multiple-character mappings (such as the rule that ‘Ö’ = ‘OE’ in one of the two German collations).

MySQL can do these things for you:

  • Store strings using a variety of character sets

  • Compare strings using a variety of collations

  • Mix strings with different character sets or collations in the same server, the same database, or even the same table

  • Allow specification of character set and collation at any level

In these respects, MySQL is far ahead of most other database management systems. However, to use these features effectively, you need to know what character sets and collations are available, how to change the defaults, and how they affect the behavior of string operators and functions.

10.2. Character Sets and Collations in MySQL

The MySQL server can support multiple character sets. To list the available character sets, use the SHOW CHARACTER SET statement. A partial listing follows. For more complete information, see Section 10.10, “Character Sets and Collations That MySQL Supports”.

mysql> SHOW CHARACTER SET;
+----------+-----------------------------+---------------------+--------+
| Charset  | Description                 | Default collation   | Maxlen |
+----------+-----------------------------+---------------------+--------+
| big5     | Big5 Traditional Chinese    | big5_chinese_ci     |      2 |
| dec8     | DEC West European           | dec8_swedish_ci     |      1 |
| cp850    | DOS West European           | cp850_general_ci    |      1 |
| hp8      | HP West European            | hp8_english_ci      |      1 |
| koi8r    | KOI8-R Relcom Russian       | koi8r_general_ci    |      1 |
| latin1   | cp1252 West European        | latin1_swedish_ci   |      1 |
| latin2   | ISO 8859-2 Central European | latin2_general_ci   |      1 |
| swe7     | 7bit Swedish                | swe7_swedish_ci     |      1 |
| ascii    | US ASCII                    | ascii_general_ci    |      1 |
| ujis     | EUC-JP Japanese             | ujis_japanese_ci    |      3 |
| sjis     | Shift-JIS Japanese          | sjis_japanese_ci    |      2 |
| hebrew   | ISO 8859-8 Hebrew           | hebrew_general_ci   |      1 |
| tis620   | TIS620 Thai                 | tis620_thai_ci      |      1 |
| euckr    | EUC-KR Korean               | euckr_korean_ci     |      2 |
| koi8u    | KOI8-U Ukrainian            | koi8u_general_ci    |      1 |
| gb2312   | GB2312 Simplified Chinese   | gb2312_chinese_ci   |      2 |
| greek    | ISO 8859-7 Greek            | greek_general_ci    |      1 |
| cp1250   | Windows Central European    | cp1250_general_ci   |      1 |
| gbk      | GBK Simplified Chinese      | gbk_chinese_ci      |      2 |
| latin5   | ISO 8859-9 Turkish          | latin5_turkish_ci   |      1 |
...

Any given character set always has at least one collation. It may have several collations. To list the collations for a character set, use the SHOW COLLATION statement. For example, to see the collations for the latin1 (cp1252 West European) character set, use this statement to find those collation names that begin with latin1:

mysql> SHOW COLLATION LIKE 'latin1%';
+---------------------+---------+----+---------+----------+---------+
| Collation           | Charset | Id | Default | Compiled | Sortlen |
+---------------------+---------+----+---------+----------+---------+
| latin1_german1_ci   | latin1  |  5 |         |          |       0 |
| latin1_swedish_ci   | latin1  |  8 | Yes     | Yes      |       1 |
| latin1_danish_ci    | latin1  | 15 |         |          |       0 |
| latin1_german2_ci   | latin1  | 31 |         | Yes      |       2 |
| latin1_bin          | latin1  | 47 |         | Yes      |       1 |
| latin1_general_ci   | latin1  | 48 |         |          |       0 |
| latin1_general_cs   | latin1  | 49 |         |          |       0 |
| latin1_spanish_ci   | latin1  | 94 |         |          |       0 |
+---------------------+---------+----+---------+----------+---------+

The latin1 collations have the following meanings:

CollationMeaning
latin1_german1_ciGerman DIN-1
latin1_swedish_ciSwedish/Finnish
latin1_danish_ciDanish/Norwegian
latin1_german2_ciGerman DIN-2
latin1_binBinary according to latin1 encoding
latin1_general_ciMultilingual (Western European)
latin1_general_csMultilingual (ISO Western European), case sensitive
latin1_spanish_ciModern Spanish

Collations have these general characteristics:

  • Two different character sets cannot have the same collation.

  • Each character set has one collation that is the default collation. For example, the default collation for latin1 is latin1_swedish_ci. The output for SHOW CHARACTER SET indicates which collation is the default for each displayed character set.

  • There is a convention for collation names: They start with the name of the character set with which they are associated, they usually include a language name, and they end with _ci (case insensitive), _cs (case sensitive), or _bin (binary).

10.3. Specifying Character Sets and Collations

There are default settings for character sets and collations at four levels: server, database, table, and column. The following description may appear complex, but it has been found in practice that multiple-level defaulting leads to natural and obvious results.

CHARACTER SET is used in clauses that specify a character set. CHARSET may be used as a synonym for CHARACTER SET.

10.3.1. Server Character Set and Collation

MySQL Server has a server character set and a server collation. These can be set at server startup and changed at runtime.

Initially, the server character set and collation depend on the options that you use when you start mysqld. You can use --character-set-server for the character set. Along with it, you can add --collation-server for the collation. If you don't specify a character set, that is the same as saying --character-set-server=latin1. If you specify only a character set (for example, latin1) but not a collation, that is the same as saying --character-set-server=latin1 --collation-server=latin1_swedish_ci because latin1_swedish_ci is the default collation for latin1. Therefore, the following three commands all have the same effect:

shell> mysqld
shell> mysqld --character-set-server=latin1
shell> mysqld --character-set-server=latin1 \
           --collation-server=latin1_swedish_ci

One way to change the settings is by recompiling. If you want to change the default server character set and collation when building from sources, use: --with-charset and --with-collation as arguments for configure. For example:

shell> ./configure --with-charset=latin1

Or:

shell> ./configure --with-charset=latin1 \
           --with-collation=latin1_german1_ci

Both mysqld and configure verify that the character set/collation combination is valid. If not, each program displays an error message and terminates.

The current server character set and collation can be determined from the values of the character_set_server and collation_server system variables. These variables can be changed at runtime.

10.3.2. Database Character Set and Collation

Every database has a database character set and a database collation. The CREATE DATABASE and ALTER DATABASE statements have optional clauses for specifying the database character set and collation:

CREATE DATABASE db_name
    [[DEFAULT] CHARACTER SET charset_name]
    [[DEFAULT] COLLATE collation_name]

ALTER DATABASE db_name
    [[DEFAULT] CHARACTER SET charset_name]
    [[DEFAULT] COLLATE collation_name]

The keyword SCHEMA can be used instead of DATABASE.

All database options are stored in a text file named db.opt that can be found in the database directory.

The CHARACTER SET and COLLATE clauses make it possible to create databases with different character sets and collations on the same MySQL server.

Example:

CREATE DATABASE db_name CHARACTER SET latin1 COLLATE latin1_swedish_ci;

MySQL chooses the database character set and database collation in the following manner:

  • If both CHARACTER SET X and COLLATE Y were specified, then character set X and collation Y.

  • If CHARACTER SET X was specified without COLLATE, then character set X and its default collation.

  • If COLLATE Y was specified without CHARACTER SET, then the character set associated with Y and collation Y.

  • Otherwise, the server character set and server collation.

The database character set and collation are used as default values if the table character set and collation are not specified in CREATE TABLE statements. They have no other purpose.

The character set and collation for the default database can be determined from the values of the character_set_database and collation_database system variables. The server sets these variables whenever the default database changes. If there is no default database, the variables have the same value as the corresponding server-level system variables, character_set_server and collation_server.

10.3.3. Table Character Set and Collation

Every table has a table character set and a table collation. The CREATE TABLE and ALTER TABLE statements have optional clauses for specifying the table character set and collation:

CREATE TABLE tbl_name (column_list)
    [[DEFAULT] CHARACTER SET charset_name] [COLLATE collation_name]]

ALTER TABLE tbl_name
    [[DEFAULT] CHARACTER SET charset_name] [COLLATE collation_name]

Example:

CREATE TABLE t1 ( ... ) CHARACTER SET latin1 COLLATE latin1_danish_ci;

MySQL chooses the table character set and collation in the following manner:

  • If both CHARACTER SET X and COLLATE Y were specified, then character set X and collation Y.

  • If CHARACTER SET X was specified without COLLATE, then character set X and its default collation.

  • If COLLATE Y was specified without CHARACTER SET, then the character set associated with Y and collation Y.

  • Otherwise, the database character set and collation.

The table character set and collation are used as default values if the column character set and collation are not specified in individual column definitions. The table character set and collation are MySQL extensions; there are no such things in standard SQL.

10.3.4. Column Character Set and Collation

Every “character” column (that is, a column of type CHAR, VARCHAR, or TEXT) has a column character set and a column collation. Column definition syntax has optional clauses for specifying the column character set and collation:

col_name {CHAR | VARCHAR | TEXT} (col_length)
    [CHARACTER SET charset_name] [COLLATE collation_name]

Example:

CREATE TABLE Table1
(
    column1 VARCHAR(5) CHARACTER SET latin1 COLLATE latin1_german1_ci
);

MySQL chooses the column character set and collation in the following manner:

  • If both CHARACTER SET X and COLLATE Y were specified, then character set X and collation Y are used.

  • If CHARACTER SET X was specified without COLLATE, then character set X and its default collation are used.

  • If COLLATE Y was specified without CHARACTER SET, then the character set associated with Y and collation Y.

  • Otherwise, the table character set and collation are used.

The CHARACTER SET and COLLATE clauses are standard SQL.

10.3.5. Character String Literal Character Set and Collation

Every character string literal has a character set and a collation.

A character string literal may have an optional character set introducer and COLLATE clause:

[_charset_name]'string' [COLLATE collation_name]

Examples:

SELECT 'string';
SELECT _latin1'string';
SELECT _latin1'string' COLLATE latin1_danish_ci;

For the simple statement SELECT 'string', the string has the character set and collation defined by the character_set_connection and collation_connection system variables.

The _charset_name expression is formally called an introducer. It tells the parser, “the string that is about to follow uses character set X.” Because this has confused people in the past, we emphasize that an introducer does not cause any conversion; it is strictly a signal that does not change the string's value. An introducer is also legal before standard hex literal and numeric hex literal notation (x'literal' and 0xnnnn)>.

Examples:

SELECT _latin1 x'AABBCC';
SELECT _latin1 0xAABBCC;

MySQL determines a literal's character set and collation in the following manner:

  • If both _X and COLLATE Y were specified, then character set X and collation Y are used.

  • If _X is specified but COLLATE is not specified, then character set X and its default collation are used.

  • Otherwise, the character set and collation given by the character_set_connection and collation_connection system variables are used.

Examples:

  • A string with latin1 character set and latin1_german1_ci collation:

    SELECT _latin1'Müller' COLLATE latin1_german1_ci;
    
  • A string with latin1 character set and its default collation (that is, latin1_swedish_ci):

    SELECT _latin1'Müller';
    
  • A string with the connection default character set and collation:

    SELECT 'Müller';
    

Character set introducers and the COLLATE clause are implemented according to standard SQL specifications.

An introducer indicates the character set for the following string, but does not change now how the parser performs escape processing within the string. Escapes are always interpreted by the parser according to the character set given by character_set_connection.

The following examples show that escape processsing occurs using character_set_connection even in the presence of an introducer. The examples use SET NAMES (which changes character_set_connection, as discussed in Section 10.4, “Connection Character Sets and Collations”), and display the resulting strings using the HEX() function so that the exact string contents can be seen.

Example 1:

mysql> SET NAMES latin1;
Query OK, 0 rows affected (0.01 sec)

mysql> SELECT HEX('à\n'), HEX(_sjis'à\n');
+------------+-----------------+
| HEX('à\n') | HEX(_sjis'à\n') |
+------------+-----------------+
| E00A       | E00A            | 
+------------+-----------------+
1 row in set (0.00 sec)

Here, ‘à’ (hex value E0) is followed by ‘\n’, the escape sequence for newline. The escape sequence is interpreted using the character_set_connection value of latin1 to produce a literal newline (hex value 0A). This happens even for the second string. That is, the introducer of _sjis does not affect the parser's escape processing.

Example 2:

mysql> SET NAMES sjis;
Query OK, 0 rows affected (0.00 sec)

mysql> SELECT HEX('à\n'), HEX(_latin1'à\n');
+------------+-------------------+
| HEX('à\n') | HEX(_latin1'à\n') |
+------------+-------------------+
| E05C6E     | E05C6E            | 
+------------+-------------------+
1 row in set (0.04 sec)

Here, character_set_connection is sjis, a character set in which the sequence of ‘à’ followed by ‘\’ (hex values 05 and 5C) is a valid multi-byte character. Hence, the first two bytes of the string are interpreted as a single sjis character, and the ‘\’ is not intrepreted as an escape character. The following ‘n’ (hex value 6E) is not interpreted as part of an escape sequence. This is true even for the second string; the introducer of _latin1 does not affect escape processing.

10.3.6. National Character Set

Standard SQL defines NCHAR or NATIONAL CHAR as a way to indicate that a CHAR column should use some predefined character set. MySQL 5.1 uses utf8 as this predefined character set. For example, these data type declarations are equivalent:

CHAR(10) CHARACTER SET utf8
NATIONAL CHARACTER(10)
NCHAR(10)

As are these:

VARCHAR(10) CHARACTER SET utf8
NATIONAL VARCHAR(10)
NCHAR VARCHAR(10)
NATIONAL CHARACTER VARYING(10)
NATIONAL CHAR VARYING(10)

You can use N'literal' to create a string in the national character set. These two statements are equivalent:

SELECT N'some text';
SELECT _utf8'some text';

For information on upgrading character sets to MySQL 5.1 from versions prior to 4.1, see the MySQL 3.23, 4.0, 4.1 Reference Manual.

10.3.7. Examples of Character Set and Collation Assignment

The following examples show how MySQL determines default character set and collation values.

Example 1: Table and Column Definition

CREATE TABLE t1
(
    c1 CHAR(10) CHARACTER SET latin1 COLLATE latin1_german1_ci
) DEFAULT CHARACTER SET latin2 COLLATE latin2_bin;

Here we have a column with a latin1 character set and a latin1_german1_ci collation. The definition is explicit, so that's straightforward. Notice that there is no problem with storing a latin1 column in a latin2 table.

Example 2: Table and Column Definition

CREATE TABLE t1
(
    c1 CHAR(10) CHARACTER SET latin1
) DEFAULT CHARACTER SET latin1 COLLATE latin1_danish_ci;

This time we have a column with a latin1 character set and a default collation. Although it might seem natural, the default collation is not taken from the table level. Instead, because the default collation for latin1 is always latin1_swedish_ci, column c1 has a collation of latin1_swedish_ci (not latin1_danish_ci).

Example 3: Table and Column Definition

CREATE TABLE t1
(
    c1 CHAR(10)
) DEFAULT CHARACTER SET latin1 COLLATE latin1_danish_ci;

We have a column with a default character set and a default collation. In this circumstance, MySQL checks the table level to determine the column character set and collation. Consequently, the character set for column c1 is latin1 and its collation is latin1_danish_ci.

Example 4: Database, Table, and Column Definition

CREATE DATABASE d1
    DEFAULT CHARACTER SET latin2 COLLATE latin2_czech_ci;
USE d1;
CREATE TABLE t1
(
    c1 CHAR(10)
);

We create a column without specifying its character set and collation. We're also not specifying a character set and a collation at the table level. In this circumstance, MySQL checks the database level to determine the table settings, which thereafter become the column settings.) Consequently, the character set for column c1 is latin2 and its collation is latin2_czech_ci.

10.3.8. Compatibility with Other DBMSs

For MaxDB compatibility these two statements are the same:

CREATE TABLE t1 (f1 CHAR(N) UNICODE);
CREATE TABLE t1 (f1 CHAR(N) CHARACTER SET ucs2);

10.4. Connection Character Sets and Collations

Several character set and collation system variables relate to a client's interaction with the server. Some of these have been mentioned in earlier sections:

  • The server character set and collation can be determined from the values of the character_set_server and collation_server system variables.

  • The character set and collation of the default database can be determined from the values of the character_set_database and collation_database system variables.

Additional character set and collation system variables are involved in handling traffic for the connection between a client and the server. Every client has connection-related character set and collation system variables.

Consider what a “connection” is: It's what you make when you connect to the server. The client sends SQL statements, such as queries, over the connection to the server. The server sends responses, such as result sets, over the connection back to the client. This leads to several questions about character set and collation handling for client connections, each of which can be answered in terms of system variables:

  • What character set is the statement in when it leaves the client?

    The server takes the character_set_client system variable to be the character set in which statements are sent by the client.

  • What character set should the server translate a statement to after receiving it?

    For this, the server uses the character_set_connection and collation_connection system variables. It converts statements sent by the client from character_set_client to character_set_connection (except for string literals that have an introducer such as _latin1 or _utf8). collation_connection is important for comparisons of literal strings. For comparisons of strings with column values, collation_connection does not matter because columns have their own collation, which has a higher collation precedence.

  • What character set should the server translate to before shipping result sets or error messages back to the client?

    The character_set_results system variable indicates the character set in which the server returns query results to the client. This includes result data such as column values, and result metadata such as column names.

You can fine-tune the settings for these variables, or you can depend on the defaults (in which case, you can skip the rest of this section).

There are two statements that affect the connection character sets:

SET NAMES 'charset_name'
SET CHARACTER SET charset_name

SET NAMES indicates what character set the client will use to send SQL statements to the server. Thus, SET NAMES 'cp1251' tells the server “future incoming messages from this client are in character set cp1251.” It also specifies the character set that the server should use for sending results back to the client. (For example, it indicates what character set to use for column values if you use a SELECT statement.)

A SET NAMES 'x' statement is equivalent to these three statements:

SET character_set_client = x;
SET character_set_results = x;
SET character_set_connection = x;

Setting character_set_connection to x also sets collation_connection to the default collation for x. It is not necessary to set that collation explicitly. To specify a particular collation for the character sets, use the optional COLLATE clause:

SET NAMES 'charset_name' COLLATE 'collation_name'

SET CHARACTER SET is similar to SET NAMES but sets character_set_connection and collation_connection to character_set_database and collation_database. A SET CHARACTER SET x statement is equivalent to these three statements:

SET character_set_client = x;
SET character_set_results = x;
SET collation_connection = @@collation_database;

Setting collation_connection also sets character_set_connection to the character set associated with the collation (equivalent to executing SET character_set_connection = @@character_set_database). It is not necessary to set character_set_connection explicitly.

When a client connects, it sends to the server the name of the character set that it wants to use. The server uses the name to set the character_set_client, character_set_results, and character_set_connection system variables. In effect, the server performs a SET NAMES operation using the character set name.

With the mysql client, it is not necessary to execute SET NAMES every time you start up if you want to use a character set different from the default. You can add the --default-character-set option setting to your mysql statement line, or in your option file. For example, the following option file setting changes the three character set variables set to koi8r each time you invoke mysql:

[mysql]
default-character-set=koi8r

If you are using the mysql client with auto-reconnect enabled (which is not recommended), it is preferable to use the charset command rather than SET NAMES. For example:

mysql> charset utf8
Charset changed

The charset command issues a SET NAMES statement, and also changes the default character set that is used if mysql reconnects after the connection has dropped.

Example: Suppose that column1 is defined as CHAR(5) CHARACTER SET latin2. If you do not say SET NAMES or SET CHARACTER SET, then for SELECT column1 FROM t, the server sends back all the values for column1 using the character set that the client specified when it connected. On the other hand, if you say SET NAMES 'latin1' or SET CHARACTER SET latin1 before issuing the SELECT statement, the server converts the latin2 values to latin1 just before sending results back. Conversion may be lossy if there are characters that are not in both character sets.

If you do not want the server to perform any conversion of result sets, set character_set_results to NULL:

SET character_set_results = NULL;

Note: Currently, UCS-2 cannot be used as a client character set, which means that SET NAMES 'ucs2' does not work.

To see the values of the character set and collation system variables that apply to your connection, use these statements:

SHOW VARIABLES LIKE 'character_set%';
SHOW VARIABLES LIKE 'collation%';

10.5. Collation Issues

The following sections various aspects of character set collations.

10.5.1. Using COLLATE in SQL Statements

With the COLLATE clause, you can override whatever the default collation is for a comparison. COLLATE may be used in various parts of SQL statements. Here are some examples:

  • With ORDER BY:

    SELECT k
    FROM t1
    ORDER BY k COLLATE latin1_german2_ci;
    
  • With AS:

    SELECT k COLLATE latin1_german2_ci AS k1
    FROM t1
    ORDER BY k1;
    
  • With GROUP BY:

    SELECT k
    FROM t1
    GROUP BY k COLLATE latin1_german2_ci;
    
  • With aggregate functions:

    SELECT MAX(k COLLATE latin1_german2_ci)
    FROM t1;
    
  • With DISTINCT:

    SELECT DISTINCT k COLLATE latin1_german2_ci
    FROM t1;
    
  • With WHERE:

         SELECT *
         FROM t1
         WHERE _latin1 'Müller' COLLATE latin1_german2_ci = k;
    
         SELECT *
         FROM t1
         WHERE k LIKE _latin1 'Müller' COLLATE latin1_german2_ci;
    
  • With HAVING:

    SELECT k
    FROM t1
    GROUP BY k
    HAVING k = _latin1 'Müller' COLLATE latin1_german2_ci;
    

10.5.2. COLLATE Clause Precedence

The COLLATE clause has high precedence (higher than ||), so the following two expressions are equivalent:

x || y COLLATE z
x || (y COLLATE z)

10.5.3. BINARY Operator

The BINARY operator casts the string following it to a binary string. This is an easy way to force a comparison to be done byte by byte rather than character by character. BINARY also causes trailing spaces to be significant.

mysql> SELECT 'a' = 'A';
        -> 1
mysql> SELECT BINARY 'a' = 'A';
        -> 0
mysql> SELECT 'a' = 'a ';
        -> 1
mysql> SELECT BINARY 'a' = 'a ';
        -> 0

BINARY str is shorthand for CAST(str AS BINARY).

The BINARY attribute in character column definitions has a different effect. A character column defined with the BINARY attribute is assigned the binary collation of the column's character set. Every character set has a binary collation. For example, the binary collation for the latin1 character set is latin1_bin, so if the table default character set is latin1, these two column definitions are equivalent:

CHAR(10) BINARY
CHAR(10) CHARACTER SET latin1 COLLATE latin1_bin

The effect of BINARY as a column attribute differs from its effect prior to MySQL 4.1. Formerly, BINARY resulted in a column that was treated as a binary string. A binary string is a string of bytes that has no character set or collation, which differs from a non-binary character string that has a binary collation. For both types of strings, comparisons are based on the numeric values of the string unit, but for non-binary strings the unit is the character and some character sets allow multi-byte characters. Section 11.4.2, “The BINARY and VARBINARY Types”.

The use of CHARACTER SET binary in the definition of a CHAR, VARCHAR, or TEXT column causes the column to be treated as a binary data type. For example, the following pairs of definitions are equivalent:

CHAR(10) CHARACTER SET binary
BINARY(10)

VARCHAR(10) CHARACTER SET binary
VARBINARY(10)

TEXT CHARACTER SET binary
BLOB

10.5.4. Some Special Cases Where the Collation Determination Is Tricky

In the great majority of statements, it is obvious what collation MySQL uses to resolve a comparison operation. For example, in the following cases, it should be clear that the collation is the collation of column x:

SELECT x FROM T ORDER BY x;
SELECT x FROM T WHERE x = x;
SELECT DISTINCT x FROM T;

However, when multiple operands are involved, there can be ambiguity. For example:

SELECT x FROM T WHERE x = 'Y';

Should this query use the collation of the column x, or of the string literal 'Y'?

Standard SQL resolves such questions using what used to be called “coercibility” rules. Basically, this means: Both x and 'Y' have collations, so which collation takes precedence? This can be difficult to resolve, but the following rules cover most situations:

  • An explicit COLLATE clause has a coercibility of 0. (Not coercible at all.)

  • The concatenation of two strings with different collations has a coercibility of 1.

  • The collation of a column or a stored routine parameter or local variable has a coercibility of 2.

  • A “system constant” (the string returned by functions such as USER() or VERSION()) has a coercibility of 3.

  • A literal's collation has a coercibility of 4.

  • NULL or an expression that is derived from NULL has a coercibility of 5.

The preceding coercibility values are current for MySQL 5.1.

Those rules resolve ambiguities in the following manner:

  • Use the collation with the lowest coercibility value.

  • If both sides have the same coercibility, then it is an error if the collations aren't the same.

Examples:

column1 = 'A'Use collation of column1
column1 = 'A' COLLATE xUse collation of 'A' COLLATE x
column1 COLLATE x = 'A' COLLATE yError

The COERCIBILITY() function can be used to determine the coercibility of a string expression:

mysql> SELECT COERCIBILITY('A' COLLATE latin1_swedish_ci);
        -> 0
mysql> SELECT COERCIBILITY(VERSION());
        -> 3
mysql> SELECT COERCIBILITY('A');
        -> 4

See Section 12.10.3, “Information Functions”.

10.5.5. Collations Must Be for the Right Character Set

Each character set has one or more collations, but each collation is associated with one and only one character set. Therefore, the following statement causes an error message because the latin2_bin collation is not legal with the latin1 character set:

mysql> SELECT _latin1 'x' COLLATE latin2_bin;
ERROR 1253 (42000): COLLATION 'latin2_bin' is not valid
for CHARACTER SET 'latin1'

10.5.6. An Example of the Effect of Collation

Suppose that column X in table T has these latin1 column values:

Muffler
Müller
MX Systems
MySQL

Suppose also that the column values are retrieved using the following statement:

SELECT X FROM T ORDER BY X COLLATE collation_name;

The following table shows the resulting order of the values if we use ORDER BY with different collations:

latin1_swedish_cilatin1_german1_cilatin1_german2_ci
MufflerMufflerMüller
MX SystemsMüllerMuffler
MüllerMX SystemsMX Systems
MySQLMySQLMySQL

The character that causes the different sort orders in this example is the U with two dots over it (ü), which the Germans call “U-umlaut.

  • The first column shows the result of the SELECT using the Swedish/Finnish collating rule, which says that U-umlaut sorts with Y.

  • The second column shows the result of the SELECT using the German DIN-1 rule, which says that U-umlaut sorts with U.

  • The third column shows the result of the SELECT using the German DIN-2 rule, which says that U-umlaut sorts with UE.

10.6. Operations Affected by Character Set Support

This section describes operations that take character set information into account.

10.6.1. Result Strings

MySQL has many operators and functions that return a string. This section answers the question: What is the character set and collation of such a string?

For simple functions that take string input and return a string result as output, the output's character set and collation are the same as those of the principal input value. For example, UPPER(X) returns a string whose character string and collation are the same as that of X. The same applies for INSTR(), LCASE(), LOWER(), LTRIM(), MID(), REPEAT(), REPLACE(), REVERSE(), RIGHT(), RPAD(), RTRIM(), SOUNDEX(), SUBSTRING(), TRIM(), UCASE(), and UPPER().

Note: The REPLACE() function, unlike all other functions, always ignores the collation of the string input and performs a case-sensitive comparison.

If a string input or function result is a binary string, the string has no character set or collation. This can be checked by using the CHARSET() and COLLATION() functions, both of which return binary to indicate that their argument is a binary string:

mysql> SELECT CHARSET(BINARY 'a'), COLLATION(BINARY 'a');
+---------------------+-----------------------+
| CHARSET(BINARY 'a') | COLLATION(BINARY 'a') |
+---------------------+-----------------------+
| binary              | binary                |
+---------------------+-----------------------+

For operations that combine multiple string inputs and return a single string output, the “aggregation rules” of standard SQL apply for determining the collation of the result:

  • If an explicit COLLATE X occurs, use X.

  • If explicit COLLATE X and COLLATE Y occur, raise an error.

  • Otherwise, if all collations are X, use X.

  • Otherwise, the result has no collation.

For example, with CASE ... WHEN a THEN b WHEN b THEN c COLLATE X END, the resulting collation is X. The same applies for UNION, ||, CONCAT(), ELT(), GREATEST(), IF(), and LEAST().

For operations that convert to character data, the character set and collation of the strings that result from the operations are defined by the character_set_connection and collation_connection system variables. This applies only to CAST(), CONV(), FORMAT(), HEX(), and SPACE().

If you are uncertain about the character set or collation of the result returned by a string function, you can use the CHARSET() or COLLATE() function to find out:

mysql> SELECT USER(), CHARSET(USER()), COLLATION(USER());
+----------------+-----------------+-------------------+
| USER()         | CHARSET(USER()) | COLLATION(USER()) |
+----------------+-----------------+-------------------+
| test@localhost | utf8            | utf8_general_ci   | 
+----------------+-----------------+-------------------+

10.6.2. CONVERT() and CAST()

CONVERT() provides a way to convert data between different character sets. The syntax is:

CONVERT(expr USING transcoding_name)

In MySQL, transcoding names are the same as the corresponding character set names.

Examples:

SELECT CONVERT(_latin1'Müller' USING utf8);
INSERT INTO utf8table (utf8column)
    SELECT CONVERT(latin1field USING utf8) FROM latin1table;

CONVERT(... USING ...) is implemented according to the standard SQL specification.

You may also use CAST() to convert a string to a different character set. The syntax is:

CAST(character_string AS character_data_type CHARACTER SET charset_name)

Example:

SELECT CAST(_latin1'test' AS CHAR CHARACTER SET utf8);

If you use CAST() without specifying CHARACTER SET, the resulting character set and collation are defined by the character_set_connection and collation_connection system variables. If you use CAST() with CHARACTER SET X, the resulting character set and collation are X and the default collation of X.

You may not use a COLLATE clause inside a CAST(), but you may use it outside. That is, CAST(... COLLATE ...) is illegal, but CAST(...) COLLATE ... is legal.

Example:

SELECT CAST(_latin1'test' AS CHAR CHARACTER SET utf8) COLLATE utf8_bin;

10.6.3. SHOW Statements and INFORMATION_SCHEMA

Several SHOW statements provide additional character set information. These include SHOW CHARACTER SET, SHOW COLLATION, SHOW CREATE DATABASE, SHOW CREATE TABLE and SHOW COLUMNS. These statements are described here briefly.

For more information, see Section 13.5.4, “SHOW Syntax”.

INFORMATION_SCHEMA has several tables that contain information similar to that displayed by the SHOW statements. For example, the CHARACTER_SETS and COLLATIONS tables contain the information displayed by SHOW CHARACTER SET and SHOW COLLATION. Chapter 22, The INFORMATION_SCHEMA Database.

The SHOW CHARACTER SET command shows all available character sets. It takes an optional LIKE clause that indicates which character set names to match. For example:

mysql> SHOW CHARACTER SET LIKE 'latin%';
+---------+-----------------------------+-------------------+--------+
| Charset | Description                 | Default collation | Maxlen |
+---------+-----------------------------+-------------------+--------+
| latin1  | cp1252 West European        | latin1_swedish_ci |      1 |
| latin2  | ISO 8859-2 Central European | latin2_general_ci |      1 |
| latin5  | ISO 8859-9 Turkish          | latin5_turkish_ci |      1 |
| latin7  | ISO 8859-13 Baltic          | latin7_general_ci |      1 |
+---------+-----------------------------+-------------------+--------+

The output from SHOW COLLATION includes all available character sets. It takes an optional LIKE clause that indicates which collation names to match. For example:

mysql> SHOW COLLATION LIKE 'latin1%';
+-------------------+---------+----+---------+----------+---------+
| Collation         | Charset | Id | Default | Compiled | Sortlen |
+-------------------+---------+----+---------+----------+---------+
| latin1_german1_ci | latin1  |  5 |         |          |       0 |
| latin1_swedish_ci | latin1  |  8 | Yes     | Yes      |       0 |
| latin1_danish_ci  | latin1  | 15 |         |          |       0 |
| latin1_german2_ci | latin1  | 31 |         | Yes      |       2 |
| latin1_bin        | latin1  | 47 |         | Yes      |       0 |
| latin1_general_ci | latin1  | 48 |         |          |       0 |
| latin1_general_cs | latin1  | 49 |         |          |       0 |
| latin1_spanish_ci | latin1  | 94 |         |          |       0 |
+-------------------+---------+----+---------+----------+---------+

SHOW CREATE DATABASE displays the CREATE DATABASE statement that creates a given database:

mysql> SHOW CREATE DATABASE test;
+----------+-----------------------------------------------------------------+
| Database | Create Database                                                 |
+----------+-----------------------------------------------------------------+
| test     | CREATE DATABASE `test` /*!40100 DEFAULT CHARACTER SET latin1 */ |
+----------+-----------------------------------------------------------------+

If no COLLATE clause is shown, the default collation for the character set applies.

SHOW CREATE TABLE is similar, but displays the CREATE TABLE statement to create a given table. The column definitions indicate any character set specifications, and the table options include character set information.

The SHOW COLUMNS statement displays the collations of a table's columns when invoked as SHOW FULL COLUMNS. Columns with CHAR, VARCHAR, or TEXT data types have collations. Numeric and other non-character types have no collation (indicated by NULL as the Collation value). For example:

mysql> SHOW FULL COLUMNS FROM person\G
*************************** 1. row ***************************
     Field: id
      Type: smallint(5) unsigned
 Collation: NULL
      Null: NO
       Key: PRI
   Default: NULL
     Extra: auto_increment
Privileges: select,insert,update,references
   Comment:
*************************** 2. row ***************************
     Field: name
      Type: char(60)
 Collation: latin1_swedish_ci
      Null: NO
       Key:
   Default:
     Extra:
Privileges: select,insert,update,references
   Comment:

The character set is not part of the display but is implied by the collation name.

10.7. Unicode Support

MySQL 5.1 supports two character sets for storing Unicode data:

  • ucs2, the UCS-2 Unicode character set.

  • utf8, the UTF-8 encoding of the Unicode character set.

In UCS-2 (binary Unicode representation), every character is represented by a two-byte Unicode code with the most significant byte first. For example: LATIN CAPITAL LETTER A has the code 0x0041 and it is stored as a two-byte sequence: 0x00 0x41. CYRILLIC SMALL LETTER YERU (Unicode 0x044B) is stored as a two-byte sequence: 0x04 0x4B. For Unicode characters and their codes, please refer to the Unicode Home Page.

Currently, UCS-2 cannot be used as a client character set, which means that SET NAMES 'ucs2' does not work.

UTF-8 (Unicode Transform representation) is an alternative way to store Unicode data. It is implemented according to RFC 3629. The idea of UTF-8 is that various Unicode characters are encoded using byte sequences of different lengths:

  • Basic Latin letters, digits, and punctuation signs use one byte.

  • Most European and Middle East script letters fit into a two-byte sequence: extended Latin letters (with tilde, macron, acute, grave and other accents), Cyrillic, Greek, Armenian, Hebrew, Arabic, Syriac, and others.

  • Korean, Chinese, and Japanese ideographs use three-byte sequences.

RFC 3629 describes encoding sequences that take from one to four bytes. Currently, MySQL support for UTF-8 does not include four-byte sequences. (An older standard for UTF-8 encoding is given by RFC 2279, which describes UTF-8 sequences that take from one to six bytes. RFC 3629 renders RFC 2279 obsolete; for this reason, sequences with five and six bytes are no longer used.)

Tip: To save space with UTF-8, use VARCHAR instead of CHAR. Otherwise, MySQL must reserve three bytes for each character in a CHAR CHARACTER SET utf8 column because that is the maximum possible length. For example, MySQL must reserve 30 bytes for a CHAR(10) CHARACTER SET utf8 column.

10.8. UTF-8 for Metadata

Metadata is “the data about the data.” Anything that describes the database — as opposed to being the contents of the database — is metadata. Thus column names, database names, usernames, version names, and most of the string results from SHOW are metadata. This is also true of the contents of tables in INFORMATION_SCHEMA, because those tables by definition contain information about database objects.

Representation of metadata must satisfy these requirements:

  • All metadata must be in the same character set. Otherwise, neither the SHOW commands nor SELECT statements for tables in INFORMATION_SCHEMA would work properly because different rows in the same column of the results of these operations would be in different character sets.

  • Metadata must include all characters in all languages. Otherwise, users would not be able to name columns and tables using their own languages.

To satisfy both requirements, MySQL stores metadata in a Unicode character set, namely UTF-8. This does not cause any disruption if you never use accented or non-Latin characters. But if you do, you should be aware that metadata is in UTF-8.

The metadata requirements mean that the return values of the USER(), CURRENT_USER(), SESSION_USER(), SYSTEM_USER(), DATABASE(), and VERSION() functions have the UTF-8 character set by default.

The server sets the character_set_system system variable to the name of the metadata character set:

mysql> SHOW VARIABLES LIKE 'character_set_system';
+----------------------+-------+
| Variable_name        | Value |
+----------------------+-------+
| character_set_system | utf8  |
+----------------------+-------+

Storage of metadata using Unicode does not mean that the server returns headers of columns and the results of DESCRIBE functions in the character_set_system character set by default. When you use SELECT column1 FROM t, the name column1 itself is returned from the server to the client in the character set determined by the value of the character_set_results system variable, which has a default value of latin1. If you want the server to pass metadata results back in a different character set, use the SET NAMES statement to force the server to perform character set conversion. SET NAMES sets the character_set_results and other related system variables. (See Section 10.4, “Connection Character Sets and Collations”.) Alternatively, a client program can perform the conversion after receiving the result from the server. It is more efficient for the client perform the conversion, but this option is not always available for all clients.

If character_set_results is set to NULL, no conversion is performed and the server returns metadata using its original character set (the set indicated by character_set_system).

Error messages returned from the server to the client are converted to the client character set automatically, as with metadata.

If you are using (for example) the USER() function for comparison or assignment within a single statement, don't worry. MySQL performs some automatic conversion for you.

SELECT * FROM Table1 WHERE USER() = latin1_column;

This works because the contents of latin1_column are automatically converted to UTF-8 before the comparison.

INSERT INTO Table1 (latin1_column) SELECT USER();

This works because the contents of USER() are automatically converted to latin1 before the assignment. Automatic conversion is not fully implemented yet, but should work correctly in a later version.

Although automatic conversion is not in the SQL standard, the SQL standard document does say that every character set is (in terms of supported characters) a “subset” of Unicode. Because it is a well-known principle that “what applies to a superset can apply to a subset,” we believe that a collation for Unicode can apply for comparisons with non-Unicode strings.

10.9. Column Character Set Conversion

To convert a binary or non-binary string column to use a particular character set, use ALTER TABLE. For successful conversion to occur, one of the following conditions must apply:

  • If the column has a binary data type (BINARY, VARBINARY, BLOB), all the values that it contains must be encoded using a single character set (the character set you're converting the column to). If you use a binary column to store information in multiple character sets, MySQL has no way to know which values use which character set and cannot convert the data properly.

  • If the column has a non-binary data type (CHAR, VARCHAR, TEXT), its contents should be encoded in the column's character set, not some other character set. If the contents are encoded in a different character set, you can convert the column to use a binary data type first, and then to a non-binary column with the desired character set.

Suppose that a table t has a binary column named col1 defined as BINARY(50). Assuming that the information in the column is encoded using a single character set, you can convert it to a non-binary column that has that character set. For example, if col1 contains binary data representing characters in the greek character set, you can convert it as follows:

ALTER TABLE t MODIFY col1 CHAR(50) CHARACTER SET greek;

Suppose that table t has a non-binary column named col1 defined as CHAR(50) CHARACTER SET latin1 but you want to convert it to use utf8 so that you can store values from many languages. The following statement accomplishes this:

ALTER TABLE t MODIFY col1 CHAR(50) CHARACTER SET utf8;

Conversion may be lossy if the column contains characters that are not in both character sets.

A special case occurs if if you have old tables from MySQL 4.0 or earlier where a non-binary column contains values that actually are encoded in a character set different from the server's default character set. For example, an application might have stored sjis values in a column, even though MySQL's default character set was latin1. It is possible to convert the column to use the proper character set but an additional step is required. Suppose that the server's default character set was latin1 and col1 is defined as CHAR(50) but its contents are sjis values. The first step is to convert the column to a binary data type, which removes the existing character set information without performing any character conversion:

ALTER TABLE t MODIFY col1 BINARY(50);

The next step is to convert the column to a non-binary data type with the proper character set:

ALTER TABLE t MODIFY col1 CHAR(50) CHARACTER SET sjis;

This procedure requires that the table not have been modified already with statements such as INSERT or UPDATE after an upgrade to MySQL 4.1 or later. In that case, MySQL would store new values in the column using latin1, and the column will contain a mix of sjis and latin1 values and cannot be converted properly.

If you specified attributes when creating a column initially, you should also specify them when altering the table with ALTER TABLE. For example, if you specified NOT NULL and an explicit DEFAULT value, you should also provide them in the ALTER TABLE statement. Otherwise, the resulting column definition will not include those attributes.

10.10. Character Sets and Collations That MySQL Supports

MySQL supports 70+ collations for 30+ character sets. This section indicates which character sets MySQL supports. There is one subsection for each group of related character sets. For each character set, the allowable collations are listed.

You can always list the available character sets and their default collations with the SHOW CHARACTER SET statement:

mysql> SHOW CHARACTER SET;
+----------+-----------------------------+---------------------+
| Charset  | Description                 | Default collation   |
+----------+-----------------------------+---------------------+
| big5     | Big5 Traditional Chinese    | big5_chinese_ci     |
| dec8     | DEC West European           | dec8_swedish_ci     |
| cp850    | DOS West European           | cp850_general_ci    |
| hp8      | HP West European            | hp8_english_ci      |
| koi8r    | KOI8-R Relcom Russian       | koi8r_general_ci    |
| latin1   | cp1252 West European        | latin1_swedish_ci   |
| latin2   | ISO 8859-2 Central European | latin2_general_ci   |
| swe7     | 7bit Swedish                | swe7_swedish_ci     |
| ascii    | US ASCII                    | ascii_general_ci    |
| ujis     | EUC-JP Japanese             | ujis_japanese_ci    |
| sjis     | Shift-JIS Japanese          | sjis_japanese_ci    |
| hebrew   | ISO 8859-8 Hebrew           | hebrew_general_ci   |
| tis620   | TIS620 Thai                 | tis620_thai_ci      |
| euckr    | EUC-KR Korean               | euckr_korean_ci     |
| koi8u    | KOI8-U Ukrainian            | koi8u_general_ci    |
| gb2312   | GB2312 Simplified Chinese   | gb2312_chinese_ci   |
| greek    | ISO 8859-7 Greek            | greek_general_ci    |
| cp1250   | Windows Central European    | cp1250_general_ci   |
| gbk      | GBK Simplified Chinese      | gbk_chinese_ci      |
| latin5   | ISO 8859-9 Turkish          | latin5_turkish_ci   |
| armscii8 | ARMSCII-8 Armenian          | armscii8_general_ci |
| utf8     | UTF-8 Unicode               | utf8_general_ci     |
| ucs2     | UCS-2 Unicode               | ucs2_general_ci     |
| cp866    | DOS Russian                 | cp866_general_ci    |
| keybcs2  | DOS Kamenicky Czech-Slovak  | keybcs2_general_ci  |
| macce    | Mac Central European        | macce_general_ci    |
| macroman | Mac West European           | macroman_general_ci |
| cp852    | DOS Central European        | cp852_general_ci    |
| latin7   | ISO 8859-13 Baltic          | latin7_general_ci   |
| cp1251   | Windows Cyrillic            | cp1251_general_ci   |
| cp1256   | Windows Arabic              | cp1256_general_ci   |
| cp1257   | Windows Baltic              | cp1257_general_ci   |
| binary   | Binary pseudo charset       | binary              |
| geostd8  | GEOSTD8 Georgian            | geostd8_general_ci  |
| cp932    | SJIS for Windows Japanese   | cp932_japanese_ci   |
| eucjpms  | UJIS for Windows Japanese   | eucjpms_japanese_ci |
+----------+-----------------------------+---------------------+

10.10.1. Unicode Character Sets

MySQL has two Unicode character sets. You can store text in about 650 languages using these character sets.

  • ucs2 (UCS-2 Unicode) collations:

    • ucs2_bin

    • ucs2_czech_ci

    • ucs2_danish_ci

    • ucs2_esperanto_ci

    • ucs2_estonian_ci

    • ucs2_general_ci (default)

    • ucs2_hungarian_ci

    • ucs2_icelandic_ci

    • ucs2_latvian_ci

    • ucs2_lithuanian_ci

    • ucs2_persian_ci

    • ucs2_polish_ci

    • ucs2_roman_ci

    • ucs2_romanian_ci

    • ucs2_slovak_ci

    • ucs2_slovenian_ci

    • ucs2_spanish2_ci

    • ucs2_spanish_ci

    • ucs2_swedish_ci

    • ucs2_turkish_ci

    • ucs2_unicode_ci

  • utf8 (UTF-8 Unicode) collations:

    • utf8_bin

    • utf8_czech_ci

    • utf8_danish_ci

    • utf8_esperanto_ci

    • utf8_estonian_ci

    • utf8_general_ci (default)

    • utf8_hungarian_ci

    • utf8_icelandic_ci

    • utf8_latvian_ci

    • utf8_lithuanian_ci

    • utf8_persian_ci

    • utf8_polish_ci

    • utf8_roman_ci

    • utf8_romanian_ci

    • utf8_slovak_ci

    • utf8_slovenian_ci

    • utf8_spanish2_ci

    • utf8_spanish_ci

    • utf8_swedish_ci

    • utf8_turkish_ci

    • utf8_unicode_ci

Note that in the ucs2_roman_ci and utf8_roman_ci collations, I and J compare as equals, and U and V compare as equals.

The ucs2_hungarian_ci and utf8_hungarian_ci collations were added in MySQL 5.1.5.

MySQL implements the utf8_unicode_ci collation 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 following discussion uses utf8_unicode_ci, but it is also true for ucs2_unicode_ci.

Currently, the utf8_unicode_ci collation has only partial support for the Unicode Collation Algorithm. Some characters are not supported yet. Also, combining marks are not fully supported. This affects primarily Vietnamese and some minority languages in Russia such as Udmurt, Tatar, Bashkir, and Mari.

The most significant feature in utf8_unicode_ci is that it supports expansions; that is, when one character compares as equal to combinations of other characters. For example, in German and some other languages ‘ß’ is equal to ‘ss’.

utf8_general_ci is a legacy collation that does not support expansions. It can make only one-to-one comparisons between characters. This means that comparisons for the utf8_general_ci collation are faster, but slightly less correct, than comparisons for utf8_unicode_ci.

For example, the following equalities hold in both utf8_general_ci and utf8_unicode_ci:

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:

ß = ss

MySQL implements language-specific collations for the utf8 character set only if the ordering with utf8_unicode_ci does not work well for a language. For example, utf8_unicode_ci works fine for German and French, so there is no need to create special utf8 collations for these two languages.

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, then you should use utf8_general_ci because it is faster. Otherwise, use utf8_unicode_ci because it is more accurate.

utf8_swedish_ci, like other utf8 language-specific collations, is derived from utf8_unicode_ci with additional language rules. For example, in Swedish, the following relationship holds, which is not something expected by a German or French speaker:

Ü = Y < Ö

The utf8_spanish_ci and utf8_spanish2_ci collations correspond to modern Spanish and traditional Spanish, respectively. In both collations, ‘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

10.10.2. West European Character Sets

Western European character sets cover most West European languages, such as French, Spanish, Catalan, Basque, Portuguese, Italian, Albanian, Dutch, German, Danish, Swedish, Norwegian, Finnish, Faroese, Icelandic, Irish, Scottish, and English.

  • ascii (US ASCII) collations:

    • ascii_bin

    • ascii_general_ci (default)

  • cp850 (DOS West European) collations:

    • cp850_bin

    • cp850_general_ci (default)

  • dec8 (DEC Western European) collations:

    • dec8_bin

    • dec8_swedish_ci (default)

  • hp8 (HP Western European) collations:

    • hp8_bin

    • hp8_english_ci (default)

  • latin1 (cp1252 West European) collations:

    • latin1_bin

    • latin1_danish_ci

    • latin1_general_ci

    • latin1_general_cs

    • latin1_german1_ci

    • latin1_german2_ci

    • latin1_spanish_ci

    • latin1_swedish_ci (default)

    latin1 is the default character set. MySQL's latin1 is the same as the Windows cp1252 character set. This means it is the same as the official ISO 8859-1 or IANA (Internet Assigned Numbers Authority) latin1, but IANA latin1 treats the code points between 0x80 and 0x9f as “undefined,” whereas cp1252, and therefore MySQL's latin1, assign characters for those positions. For example, 0x80 is the Euro sign. For the “undefined” entries in cp1252, MySQL translates 0x81 to Unicode 0x0081, 0x8d to 0x008d, 0x8f to 0x008f, 0x90 to 0x0090, and 0x9d to 0x009d.

    The latin1_swedish_ci collation is the default that probably is used by the majority of MySQL customers. Although it is frequently said that it is based on the Swedish/Finnish collation rules, there are Swedes and Finns who disagree with this statement.

    The latin1_german1_ci and latin1_german2_ci collations are based on the DIN-1 and DIN-2 standards, where DIN stands for Deutsches Institut für Normung (the German equivalent of ANSI). DIN-1 is called the “dictionary collation” and DIN-2 is called the “phone book collation.

    • latin1_german1_ci (dictionary) rules:

      Ä = A
      Ö = O
      Ü = U
      ß = s
      
    • latin1_german2_ci (phone-book) rules:

      Ä = AE
      Ö = OE
      Ü = UE
      ß = ss
      

    In the latin1_spanish_ci collation, ‘ñ’ (n-tilde) is a separate letter between ‘n’ and ‘o’.

  • macroman (Mac West European) collations:

    • macroman_bin

    • macroman_general_ci (default)

  • swe7 (7bit Swedish) collations:

    • swe7_bin

    • swe7_swedish_ci (default)

10.10.3. Central European Character Sets

MySQL provides some support for character sets used in the Czech Republic, Slovakia, Hungary, Romania, Slovenia, Croatia, Poland, and Serbia (Latin).

  • cp1250 (Windows Central European) collations:

    • cp1250_bin

    • cp1250_croatian_ci

    • cp1250_czech_cs

    • cp1250_general_ci (default)

    • cp1250_polish_ci

  • cp852 (DOS Central European) collations:

    • cp852_bin

    • cp852_general_ci (default)

  • keybcs2 (DOS Kamenicky Czech-Slovak) collations:

    • keybcs2_bin

    • keybcs2_general_ci (default)

  • latin2 (ISO 8859-2 Central European) collations:

    • latin2_bin

    • latin2_croatian_ci

    • latin2_czech_cs

    • latin2_general_ci (default)

    • latin2_hungarian_ci

  • macce (Mac Central European) collations:

    • macce_bin

    • macce_general_ci (default)

10.10.4. South European and Middle East Character Sets

South European and Middle Eastern character sets supported by MySQL include Armenian, Arabic, Georgian, Greek, Hebrew, and Turkish.

  • armscii8 (ARMSCII-8 Armenian) collations:

    • armscii8_bin

    • armscii8_general_ci (default)

  • cp1256 (Windows Arabic) collations:

    • cp1256_bin

    • cp1256_general_ci (default)

  • geostd8 (GEOSTD8 Georgian) collations:

    • geostd8_bin

    • geostd8_general_ci (default)

  • greek (ISO 8859-7 Greek) collations:

    • greek_bin

    • greek_general_ci (default)

  • hebrew (ISO 8859-8 Hebrew) collations:

    • hebrew_bin

    • hebrew_general_ci (default)

  • latin5 (ISO 8859-9 Turkish) collations:

    • latin5_bin

    • latin5_turkish_ci (default)

10.10.5. Baltic Character Sets

The Baltic character sets cover Estonian, Latvian, and Lithuanian languages.

  • cp1257 (Windows Baltic) collations:

    • cp1257_bin

    • cp1257_general_ci (default)

    • cp1257_lithuanian_ci

  • latin7 (ISO 8859-13 Baltic) collations:

    • latin7_bin

    • latin7_estonian_cs

    • latin7_general_ci (default)

    • latin7_general_cs

10.10.6. Cyrillic Character Sets

The Cyrillic character sets and collations are for use with Belarusian, Bulgarian, Russian, Ukrainian, and Serbian (Cyrillic) languages.

  • cp1251 (Windows Cyrillic) collations:

    • cp1251_bin

    • cp1251_bulgarian_ci

    • cp1251_general_ci (default)

    • cp1251_general_cs

    • cp1251_ukrainian_ci

  • cp866 (DOS Russian) collations:

    • cp866_bin

    • cp866_general_ci (default)

  • koi8r (KOI8-R Relcom Russian) collations:

    • koi8r_bin

    • koi8r_general_ci (default)

  • koi8u (KOI8-U Ukrainian) collations:

    • koi8u_bin

    • koi8u_general_ci (default)

10.10.7. Asian Character Sets

The Asian character sets that we support include Chinese, Japanese, Korean, and Thai. These can be complicated. For example, the Chinese sets must allow for thousands of different characters. See Section 10.10.7.1, “The cp932 Character Set”, for additional information about the cp932 and sjis character sets.

For answers to some common questions and problems relating support for Asian character sets in MySQL, see Section A.12, “MySQL 5.1 FAQ — MySQL Chinese, Japanese, and Korean Character Sets”.

  • big5 (Big5 Traditional Chinese) collations:

    • big5_bin

    • big5_chinese_ci (default)

  • cp932 (SJIS for Windows Japanese) collations:

    • cp932_bin

    • cp932_japanese_ci (default)

  • eucjpms (UJIS for Windows Japanese) collations:

    • eucjpms_bin

    • eucjpms_japanese_ci (default)

  • euckr (EUC-KR Korean) collations:

    • euckr_bin

    • euckr_korean_ci (default)

  • gb2312 (GB2312 Simplified Chinese) collations:

    • gb2312_bin

    • gb2312_chinese_ci (default)

  • gbk (GBK Simplified Chinese) collations:

    • gbk_bin

    • gbk_chinese_ci (default)

  • sjis (Shift-JIS Japanese) collations:

    • sjis_bin

    • sjis_japanese_ci (default)

  • tis620 (TIS620 Thai) collations:

    • tis620_bin

    • tis620_thai_ci (default)

  • ujis (EUC-JP Japanese) collations:

    • ujis_bin

    • ujis_japanese_ci (default)

10.10.7.1. The cp932 Character Set

Why is cp932 needed?

In MySQL, the sjis character set corresponds to the Shift_JIS character set defined by IANA, which supports JIS X0201 and JIS X0208 characters. (See http://www.iana.org/assignments/character-sets.)

However, the meaning of “SHIFT JIS” as a descriptive term has become very vague and it often includes the extensions to Shift_JIS that are defined by various vendors.

For example, “SHIFT JIS” used in Japanese Windows environments is a Microsoft extension of Shift_JIS and its exact name is Microsoft Windows Codepage : 932 or cp932. In addition to the characters supported by Shift_JIS, cp932 supports extension characters such as NEC special characters, NEC selected — IBM extended characters, and IBM extended characters.

Many Japanese users have experienced problems using these extension characters. These problems stem from the following factors:

  • MySQL automatically converts character sets.

  • Character sets are converted via Unicode (ucs2).

  • The sjis character set does not support the conversion of these extension characters.

  • There are several conversion rules from so-called “SHIFT JIS” to Unicode, and some characters are converted to Unicode differently depending on the conversion rule. MySQL supports only one of these rules (described later).

The MySQL cp932 character set is designed to solve these problems.

Because MySQL supports character set conversion, it is important to separate IANA Shift_JIS and cp932 into two different character sets because they provide different conversion rules.

How does cp932 differ from sjis?

The cp932 character set differs from sjis in the following ways:

For some characters, conversion to and from ucs2 is different for sjis and cp932. The following tables illustrate these differences.

Conversion to ucs2:

sjis/cp932 Valuesjis -> ucs2 Conversioncp932 -> ucs2 Conversion
5C005C005C
7E007E007E
815C20152015
815F005CFF3C
8160301CFF5E
816120162225
817C2212FF0D
819100A2FFE0
819200A3FFE1
81CA00ACFFE2

Conversion from ucs2:

ucs2 valueucs2 -> sjis Conversionucs2 -> cp932 Conversion
005C815F5C
007E7E7E
00A281913F
00A381923F
00AC81CA3F
2015815C815C
201681613F
2212817C3F
22253F8161
301C81603F
FF0D3F817C
FF3C3F815F
FF5E3F8160
FFE03F8191
FFE13F8192
FFE23F81CA

Users of any Japanese character sets should be aware that using --character-set-client-handshake (or --skip-character-set-client-handshake) has an important effect. See Section 5.2.2, “Command Options”.