A string is a sequence of characters, surrounded by either single quote (`'') or double quote (`"') characters (only the single quote if you run in ANSI mode). Examples:
'a string' "another string"
Within a string, certain sequences have special meaning. Each of these sequences begins with a backslash (`\'), known as the escape character. MySQL recognizes the following escape sequences:
\0
NUL
) character.
\n
\t
\r
\b
\'
\"
\\
\%
\_
Note that if you use `\%' or `\_' in some string contexts, these will return the strings `\%' and `\_' and not `%' and `_'.
There are several ways to include quotes within a string:
The SELECT
statements shown below demonstrate how quoting and
escaping work:
mysql> SELECT 'hello', '"hello"', '""hello""', 'hel''lo', '\'hello'; +-------+---------+-----------+--------+--------+ | hello | "hello" | ""hello"" | hel'lo | 'hello | +-------+---------+-----------+--------+--------+ mysql> SELECT "hello", "'hello'", "''hello''", "hel""lo", "\"hello"; +-------+---------+-----------+--------+--------+ | hello | 'hello' | ''hello'' | hel"lo | "hello | +-------+---------+-----------+--------+--------+ mysql> SELECT "This\nIs\nFour\nlines"; +--------------------+ | This Is Four lines | +--------------------+
If you want to insert binary data into a BLOB
column, the following
characters must be represented by escape sequences:
NUL
\
'
"
If you write C code, you can use the C API function
mysql_escape_string()
to escape characters for the INSERT
statement. See section 23.3 C API Function Overview. In Perl, you can use the
quote
method of the DBI
package to convert special
characters to the proper escape sequences. See section 23.5.2 The DBI
Interface.
You should use an escape function on any string that might contain any of the special characters listed above!
Integers are represented as a sequence of digits. Floats use `.' as a decimal separator. Either type of number may be preceded by `-' to indicate a negative value.
Examples of valid integers:
1221 0 -32
Examples of valid floating-point numbers:
294.42 -32032.6809e+10 148.00
An integer may be used in a floating-point context; it is interpreted as the equivalent floating-point number.
MySQL supports hexadecimal values. In number context these act like an integer (64-bit precision). In string context these act like a binary string where each pair of hex digits is converted to a character:
mysql> SELECT 0xa+0 -> 10 mysql> select 0x5061756c; -> Paul
Hexadecimal strings are often used by ODBC to give values for BLOB columns.
NULL
Values
The NULL
value means ``no data'' and is different from values such
as 0
for numeric types or the empty string for string types.
See section 20.17 Problems with NULL
Values.
NULL
may be represented by \N
when using the text file import
or export formats (LOAD DATA INFILE
, SELECT ... INTO OUTFILE
).
See section 7.23 LOAD DATA INFILE
Syntax.
Database, table, index, column, and alias names all follow the same rules in MySQL.
Note that the rules changed starting with MySQL Version 3.23.6 when we introduced quoting of identifiers (database, table, and column names) with ``'. `"' will also work to quote identifiers if you run in ANSI mode. See section 5.2 Running MySQL in ANSI Mode.
Identifier | Max length | Allowed characters |
Database | 64 | Any character that is allowed in a directory name except `/'. |
Table | 64 | Any character that is allowed in a file name, except `/' or `.'. |
Column | 64 | All characters. |
Alias | 255 | All characters. |
Note that in addition to the above, you can't have ASCII(0) or ASCII(255) in an identifier.
Note that if the identifer is a restricted word or contains special characters
you must always quote it with `
when you use it:
SELECT * from `select` where `select`.id > 100;
In previous versions of MySQL, the name rules are as follows:
--default-character-set
option
to mysqld
.
See section 10.1.1 The Character Set Used for Data and Sorting.
It is recommended that you do not use names like 1e
, because
an expression like 1e+1
is ambiguous. It may be interpreted as the
expression 1e + 1
or as the number 1e+1
.
In MySQL you can refer to a column using any of the following forms:
Column reference | Meaning |
col_name | Column col_name
from whichever table used in the query contains a column of that name.
|
tbl_name.col_name | Column col_name from table
tbl_name of the current database.
|
db_name.tbl_name.col_name | Column col_name from table
tbl_name of the database db_name . This form is available in
MySQL Version 3.22 or later.
|
`column_name` | A column that is a keyword or contains special characters. |
You need not specify a tbl_name
or db_name.tbl_name
prefix for
a column reference in a statement unless the reference would be ambiguous.
For example, suppose tables t1
and t2
each contain a column
c
, and you retrieve c
in a SELECT
statement that uses
both t1
and t2
. In this case, c
is ambiguous because it
is not unique among the tables used in the statement, so you must indicate
which table you mean by writing t1.c
or t2.c
. Similarly, if
you are retrieving from a table t
in database db1
and from a
table t
in database db2
, you must refer to columns in those
tables as db1.t.col_name
and db2.t.col_name
.
The syntax .tbl_name
means the table tbl_name
in the current
database. This syntax is accepted for ODBC compatibility, because some ODBC
programs prefix table names with a `.' character.
In MySQL, databases and tables correspond to directories and files within those directories. Consequently, the case sensitivity of the underlying operating system determines the case sensitivity of database and table names. This means database and table names are case sensitive in Unix and case insensitive in Windows. See section 5.1 MySQL Extensions to ANSI SQL92.
NOTE: Although database and table names are case insensitive for
Windows, you should not refer to a given database or table using different
cases within the same query. The following query would not work because it
refers to a table both as my_table
and as MY_TABLE
:
mysql> SELECT * FROM my_table WHERE MY_TABLE.col=1;
Column names are case insensitive in all cases.
Aliases on tables are case sensitive. The following query would not work
because it refers to the alias both as a
and as A
:
mysql> SELECT col_name FROM tbl_name AS a WHERE a.col_name = 1 OR A.col_name = 2;
Aliases on columns are case insensitive.
If you have a problem remembering the used cases for a table names, adopt a consistent convention, such as always creating databases and tables using lowercase names.
One way to avoid this problem is to start mysqld
with -O
lower_case_table_names=1
.
In this case MySQL will convert all table names to lower case on
storage and lookup. Note that you need to first convert your old table
names to lower case before starting mysqld
with this option.
MySQL supports thread-specific variables with the
@variablename
syntax. A variable name may consist of
alphanumeric characters from the current character set and also
`_', `$', and `.' . The default character set is
ISO-8859-1 Latin1; this may be changed with the
--default-character-set
option to mysqld
. See section 10.1.1 The Character Set Used for Data and Sorting.
Variables don't have to be initialized. They contain NULL
by default
and can store an integer, real, or string value. All variables for
a thread are automatically freed when the thread exits.
You can set a variable with the SET
syntax:
SET @variable= { integer expression | real expression | string expression } [,@variable= ...].
You can also set a variable in an expression with the @variable:=expr
syntax:
select @t1:=(@t2:=1)+@t3:=4,@t1,@t2,@t3; +----------------------+------+------+------+ | @t1:=(@t2:=1)+@t3:=4 | @t1 | @t2 | @t3 | +----------------------+------+------+------+ | 5 | 5 | 1 | 4 | +----------------------+------+------+------+
(We had to use the :=
syntax here, because =
was reserved for
comparisons.)
User variables may be used where expressions are allowed. Note that
this does not currently include use in contexts where a number is explicitly
required, such as in the LIMIT
clause of a SELECT
statement,
or the IGNORE number LINES
clause of a LOAD DATA
statement.
NOTE: In a SELECT
statement, each expression is only
evaluated when it's sent to the client. This means that in the HAVING
,
GROUP BY
, or ORDER BY
clause, you can't refer to an expression
that involves variables that are set in the SELECT
part. For example,
the following statement will NOT work as expected:
SELECT (@aa:=id) AS a, (@aa+3) AS b FROM table_name HAVING b=5;
The reason is that @aa
will not contain the value of the current
row, but the value of id
for the previous accepted row.
MySQL supports a number of column types, which may be grouped into three categories: numeric types, date and time types, and string (character) types. This section first gives an overview of the types available and summarizes the storage requirements for each column type, then provides a more detailed description of the properties of the types in each category. The overview is intentionally brief. The more detailed descriptions should be consulted for additional information about particular column types, such as the allowable formats in which you can specify values.
The column types supported by MySQL are listed below. The following code letters are used in the descriptions:
M
D
M
-2.
Square brackets (`[' and `]') indicate parts of type specifiers that are optional.
Note that if you specify ZEROFILL
for a column, MySQL will
automatically add the UNSIGNED
attribute to the column.
TINYINT[(M)] [UNSIGNED] [ZEROFILL]
-128
to 127
. The
unsigned range is 0
to 255
.
SMALLINT[(M)] [UNSIGNED] [ZEROFILL]
-32768
to 32767
. The
unsigned range is 0
to 65535
.
MEDIUMINT[(M)] [UNSIGNED] [ZEROFILL]
-8388608
to
8388607
. The unsigned range is 0
to 16777215
.
INT[(M)] [UNSIGNED] [ZEROFILL]
-2147483648
to
2147483647
. The unsigned range is 0
to 4294967295
.
INTEGER[(M)] [UNSIGNED] [ZEROFILL]
INT
.
BIGINT[(M)] [UNSIGNED] [ZEROFILL]
-9223372036854775808
to
9223372036854775807
. The unsigned range is 0
to
18446744073709551615
. Note that all arithmetic is done using
signed BIGINT
or DOUBLE
values, so you shouldn't use
unsigned big integers larger than 9223372036854775807
(63 bits)
except with bit functions! Note that `-', `+', and `*'
will use BIGINT
arithmetic when both arguments are INTEGER
values! This means that if you multiply two big integers (or results
from functions that return integers) you may get unexpected results if
the result is larger than 9223372036854775807
.
FLOAT(precision) [ZEROFILL]
precision
can be
<=24
for a single-precision floating-point number and between 25
and 53 for a double-precision floating-point number. These types are like
the FLOAT
and DOUBLE
types described immediately below.
FLOAT(X)
has the same range as the corresponding FLOAT
and
DOUBLE
types, but the display size and number of decimals is undefined.
In MySQL Version 3.23, this is a true floating-point value. In
earlier MySQL versions, FLOAT(precision)
always has 2 decimals.
Note that using FLOAT
may give you some unexpected problems as
all calculation in MySQL is done with double precision.
See section 20.20 Solving Problems with No Matching Rows.
This syntax is provided for ODBC compatibility.
FLOAT[(M,D)] [ZEROFILL]
-3.402823466E+38
to
-1.175494351E-38
, 0
, and 1.175494351E-38
to
3.402823466E+38
. The M is the display width and D is the
number of decimals. FLOAT
without an argument or with an argument of
<= 24 stands for a single-precision floating-point number.
DOUBLE[(M,D)] [ZEROFILL]
-1.7976931348623157E+308
to
-2.2250738585072014E-308
, 0
, and
2.2250738585072014E-308
to 1.7976931348623157E+308
. The M
is the display width and D is the number of decimals. DOUBLE
without an argument or FLOAT(X)
where 25 <= X <= 53 stands for a
double-precision floating-point number.
DOUBLE PRECISION[(M,D)] [ZEROFILL]
REAL[(M,D)] [ZEROFILL]
DOUBLE
.
DECIMAL[(M[,D])] [ZEROFILL]
CHAR
column: ``unpacked'' means the number is stored as a string,
using one character for each digit of the value. The decimal point and,
for negative numbers, the `-' sign, are not counted in M (but space
for these are reserved). If D
is 0, values will have no decimal
point or fractional part. The maximum range of DECIMAL
values is
the same as for DOUBLE
, but the actual range for a given
DECIMAL
column may be constrained by the choice of M
and
D
.
If D
is left out it's set to 0. If M
is left out it's set to 10.
Note that in MySQL Version 3.22 the M
argument had to
includes the space needed for the sign and the decimal point.
NUMERIC(M,D) [ZEROFILL]
DECIMAL
.
DATE
'1000-01-01'
to '9999-12-31'
.
MySQL displays DATE
values in 'YYYY-MM-DD'
format, but
allows you to assign values to DATE
columns using either strings or
numbers. See section 7.3.3.2 The DATETIME
, DATE
, and TIMESTAMP
Types.
DATETIME
'1000-01-01
00:00:00'
to '9999-12-31 23:59:59'
. MySQL displays
DATETIME
values in 'YYYY-MM-DD HH:MM:SS'
format, but allows you
to assign values to DATETIME
columns using either strings or numbers.
See section 7.3.3.2 The DATETIME
, DATE
, and TIMESTAMP
Types.
TIMESTAMP[(M)]
'1970-01-01 00:00:00'
to sometime in the
year 2037
. MySQL displays TIMESTAMP
values in
YYYYMMDDHHMMSS
, YYMMDDHHMMSS
, YYYYMMDD
, or YYMMDD
format, depending on whether M
is 14
(or missing), 12
,
8
, or 6
, but allows you to assign values to TIMESTAMP
columns using either strings or numbers. A TIMESTAMP
column is useful
for recording the date and time of an INSERT
or UPDATE
operation because it is automatically set to the date and time of the most
recent operation if you don't give it a value yourself. You can also set it
to the current date and time by assigning it a NULL
value. See section 7.3.3 Date and Time Types.
A TIMESTAMP
is always stored in 4 bytes. The M
argument only
affects how the TIMESTAMP
column is displayed.
Note that TIMESTAMP(X)
columns where X is 8 or 14 are reported to
be numbers while other TIMESTAMP(X)
columns are reported to be
strings. This is just to ensure that one can reliably dump and restore
the table with these types!
See section 7.3.3.2 The DATETIME
, DATE
, and TIMESTAMP
Types.
TIME
'-838:59:59'
to '838:59:59'
.
MySQL displays TIME
values in 'HH:MM:SS'
format, but
allows you to assign values to TIME
columns using either strings or
numbers. See section 7.3.3.3 The TIME
Type.
YEAR[(2|4)]
1901
to 2155
, 0000
in the 4-digit year format,
and 1970-2069 if you use the 2-digit format (70-69). MySQL displays
YEAR
values in YYYY
format, but allows you to assign values to
YEAR
columns using either strings or numbers. (The YEAR
type is
new in MySQL Version 3.22.). See section 7.3.3.4 The YEAR
Type.
[NATIONAL] CHAR(M) [BINARY]
M
is 1 to 255 characters.
Trailing spaces are removed when the value is retrieved. CHAR
values
are sorted and compared in case-insensitive fashion according to the
default character set unless the BINARY
keyword is given.
NATIONAL CHAR
(short form NCHAR
) is the ANSI SQL way to
define that a CHAR column should use the default CHARACTER set. This is
the default in MySQL.
CHAR
is a shorthand for CHARACTER
.
MySQL allows you to create a column of type
CHAR(0)
. This is mainly useful when you have to be compliant with
some old applications that depend on the existence of a column but that do not
actually use the value. This is also quite nice when you need a
column that only can take 2 values: A CHAR(0)
, that is not defined
as NOT NULL
, will only occupy one bit and can only take 2 values:
NULL
or ""
. See section 7.3.4.1 The CHAR
and VARCHAR
Types.
[NATIONAL] VARCHAR(M) [BINARY]
M
is 1 to 255 characters. VARCHAR
values are sorted and
compared in case-insensitive fashion unless the BINARY
keyword is
given. See section 7.7.1 Silent Column Specification Changes.
VARCHAR
is a shorthand for CHARACTER VARYING
.
See section 7.3.4.1 The CHAR
and VARCHAR
Types.
TINYBLOB
TINYTEXT
BLOB
or TEXT
column with a maximum length of 255 (2^8 - 1)
characters. See section 7.7.1 Silent Column Specification Changes. See section 7.3.4.2 The BLOB
and TEXT
Types.
BLOB
TEXT
BLOB
or TEXT
column with a maximum length of 65535 (2^16 - 1)
characters. See section 7.7.1 Silent Column Specification Changes. See section 7.3.4.2 The BLOB
and TEXT
Types.
MEDIUMBLOB
MEDIUMTEXT
BLOB
or TEXT
column with a maximum length of 16777215
(2^24 - 1) characters. See section 7.7.1 Silent Column Specification Changes. See section 7.3.4.2 The BLOB
and TEXT
Types.
LONGBLOB
LONGTEXT
BLOB
or TEXT
column with a maximum length of 4294967295
(2^32 - 1) characters. See section 7.7.1 Silent Column Specification Changes. Note that because
the server/client protocol and MyISAM tables has currently a limit of
16M per communication packet / table row, you can't yet use this
the whole range of this type. See section 7.3.4.2 The BLOB
and TEXT
Types.
ENUM('value1','value2',...)
'value1'
, 'value2'
, ...
,
NULL
or the special ""
error value. An ENUM
can
have a maximum of 65535 distinct values. See section 7.3.4.3 The ENUM
Type.
SET('value1','value2',...)
'value1'
, 'value2'
,
...
A SET
can have a maximum of 64 members. See section 7.3.4.4 The SET
Type.
The storage requirements for each of the column types supported by MySQL are listed below by category.
Column type | Storage required |
TINYINT | 1 byte |
SMALLINT | 2 bytes |
MEDIUMINT | 3 bytes |
INT | 4 bytes |
INTEGER | 4 bytes |
BIGINT | 8 bytes |
FLOAT(X) | 4 if X <= 24 or 8 if 25 <= X <= 53 |
FLOAT | 4 bytes |
DOUBLE | 8 bytes |
DOUBLE PRECISION | 8 bytes |
REAL | 8 bytes |
DECIMAL(M,D) | M+2 bytes if D > 0, M+1 bytes if D = 0 (D +2, if M < D )
|
NUMERIC(M,D) | M+2 bytes if D > 0, M+1 bytes if D = 0 (D +2, if M < D )
|
Column type | Storage required |
DATE | 3 bytes |
DATETIME | 8 bytes |
TIMESTAMP | 4 bytes |
TIME | 3 bytes |
YEAR | 1 byte |
Column type | Storage required |
CHAR(M) | M bytes, 1 <= M <= 255
|
VARCHAR(M) | L +1 bytes, where L <= M and
1 <= M <= 255
|
TINYBLOB , TINYTEXT | L +1 bytes,
where L < 2^8
|
BLOB , TEXT | L +2 bytes,
where L < 2^16
|
MEDIUMBLOB , MEDIUMTEXT | L +3 bytes,
where L < 2^24
|
LONGBLOB , LONGTEXT | L +4 bytes,
where L < 2^32
|
ENUM('value1','value2',...) | 1 or 2 bytes, depending on the number of enumeration values (65535 values maximum) |
SET('value1','value2',...) | 1, 2, 3, 4 or 8 bytes, depending on the number of set members (64 members maximum) |
VARCHAR
and the BLOB
and TEXT
types are variable-length
types, for which the storage requirements depend on the actual length of
column values (represented by L
in the preceding table), rather than
on the type's maximum possible size. For example, a VARCHAR(10)
column can hold a string with a maximum length of 10 characters. The actual
storage required is the length of the string (L
), plus 1 byte to
record the length of the string. For the string 'abcd'
, L
is 4
and the storage requirement is 5 bytes.
The BLOB
and TEXT
types require 1, 2, 3, or 4 bytes to record
the length of the column value, depending on the maximum possible length of
the type. See section 7.3.4.2 The BLOB
and TEXT
Types.
If a table includes any variable-length column types, the record format will also be variable-length. Note that when a table is created, MySQL may, under certain conditions, change a column from a variable-length type to a fixed-length type, or vice-versa. See section 7.7.1 Silent Column Specification Changes.
The size of an ENUM
object is determined by the number of
different enumeration values. One byte is used for enumerations with up
to 255 possible values. Two bytes are used for enumerations with up to
65535 values. See section 7.3.4.3 The ENUM
Type.
The size of a SET
object is determined by the number of different
set members. If the set size is N
, the object occupies (N+7)/8
bytes, rounded up to 1, 2, 3, 4, or 8 bytes. A SET
can have a maximum
of 64 members. See section 7.3.4.4 The SET
Type.
MySQL supports all of the ANSI/ISO SQL92 numeric types. These
types include the exact numeric data types (NUMERIC
,
DECIMAL
, INTEGER
, and SMALLINT
), as well as the
approximate numeric data types (FLOAT
, REAL
, and
DOUBLE PRECISION
). The keyword INT
is a synonym for
INTEGER
, and the keyword DEC
is a synonym for
DECIMAL
.
The NUMERIC
and DECIMAL
types are implemented as the same
type by MySQL, as permitted by the SQL92 standard. They are
used for values for which it is important to preserve exact precision,
for example with monetary data. When declaring a column of one of these
types the precision and scale can be (and usually is) specified; for
example:
salary DECIMAL(9,2)
In this example, 9
(precision
) represents the number of
significant decimal digits that will be stored for values, and
2
(scale
) represents the number of digits that will be
stored following the decimal point. In this case, therefore, the range
of values that can be stored in the salary
column is from
-9999999.99
to 9999999.99
. In ANSI/ISO SQL92, the syntax
DECIMAL(p)
is equivalent to DECIMAL(p,0)
. Similarly, the
syntax DECIMAL
is equivalent to DECIMAL(p,0)
, where the
implementation is allowed to decide the value of p
.
MySQL does not currently support either of these variant forms
of the DECIMAL
/NUMERIC
data types. This is not generally
a serious problem, as the principal benefits of these types derive from
the ability to control both precision and scale explicitly.
DECIMAL
and NUMERIC
values are stored as strings, rather
than as binary floating-point numbers, in order to preserve the decimal
precision of those values. One character is used for each digit of the
value, the decimal point (if scale
> 0), and the `-' sign
(for negative numbers). If scale
is 0, DECIMAL
and
NUMERIC
values contain no decimal point or fractional part.
The maximum range of DECIMAL
and NUMERIC
values is the
same as for DOUBLE
, but the actual range for a given
DECIMAL
or NUMERIC
column can be constrained by the
precision
or scale
for a given column. When such a column
is assigned a value with more digits following the decimal point than
are allowed by the specified scale
, the value is rounded to that
scale
. When a DECIMAL
or NUMERIC
column is
assigned a value whose magnitude exceeds the range implied by the
specified (or defaulted) precision
and scale
,
MySQL stores the value representing the corresponding end
point of that range.
As an extension to the ANSI/ISO SQL92 standard, MySQL also
supports the integral types TINYINT
, MEDIUMINT
, and
BIGINT
as listed in the tables above. Another extension is
supported by MySQL for optionally specifying the display width
of an integral value in parentheses following the base keyword for the
type (for example, INT(4)
). This optional width specification is
used to left-pad the display of values whose width is less than the
width specified for the column, but does not constrain the range of
values that can be stored in the column, nor the number of digits that
will be displayed for values whose width exceeds that specified for the
column. When used in conjunction with the optional extension attribute
ZEROFILL
, the default padding of spaces is replaced with zeroes.
For example, for a column declared as INT(5) ZEROFILL
, a value
of 4
is retrieved as 00004
. Note that if you store larger
values than the display width in an integer column, you may experience
problems when MySQL generates temporary tables for some
complicated joins, as in these cases MySQL trusts that the
data did fit into the original column width.
All integral types can have an optional (non-standard) attribute
UNSIGNED
. Unsigned values can be used when you want to allow
only positive numbers in a column and you need a little bigger numeric
range for the column.
The FLOAT
type is used to represent approximate numeric data
types. The ANSI/ISO SQL92 standard allows an optional specification of
the precision (but not the range of the exponent) in bits following the
keyword FLOAT
in parentheses. The MySQL implementation
also supports this optional precision specification. When the keyword
FLOAT
is used for a column type without a precision
specification, MySQL uses four bytes to store the values. A
variant syntax is also supported, with two numbers given in parentheses
following the FLOAT
keyword. With this option, the first number
continues to represent the storage requirements for the value in bytes,
and the second number specifies the number of digits to be stored and
displayed following the decimal point (as with DECIMAL
and
NUMERIC
). When MySQL is asked to store a number for
such a column with more decimal digits following the decimal point than
specified for the column, the value is rounded to eliminate the extra
digits when the value is stored.
The REAL
and DOUBLE PRECISION
types do not accept
precision specifications. As an extension to the ANSI/ISO SQL92
standard, MySQL recognizes DOUBLE
as a synonym for the
DOUBLE PRECISION
type. In contrast with the standard's
requirement that the precision for REAL
be smaller than that used
for DOUBLE PRECISION
, MySQL implements both as 8-byte
double-precision floating-point values (when not running in ``ANSI mode'').
For maximum portability, code requiring storage of approximate numeric
data values should use FLOAT
or DOUBLE PRECISION
with no
specification of precision or number of decimal points.
When asked to store a value in a numeric column that is outside the column type's allowable range, MySQL clips the value to the appropriate endpoint of the range and stores the resulting value instead.
For example, the range of an INT
column is -2147483648
to
2147483647
. If you try to insert -9999999999
into an
INT
column, the value is clipped to the lower endpoint of the range,
and -2147483648
is stored instead. Similarly, if you try to insert
9999999999
, 2147483647
is stored instead.
If the INT
column is UNSIGNED
, the size of the column's
range is the same but its endpoints shift up to 0
and 4294967295
.
If you try to store -9999999999
and 9999999999
,
the values stored in the column become 0
and 4294967296
.
Conversions that occur due to clipping are reported as ``warnings'' for
ALTER TABLE
, LOAD DATA INFILE
, UPDATE
, and
multi-row INSERT
statements.
The date and time types are DATETIME
, DATE
,
TIMESTAMP
, TIME
, and YEAR
. Each of these has a
range of legal values, as well as a ``zero'' value that is used when you
specify a really illegal value. Note that MySQL allows you to store
certain 'not strictly' legal date values, for example 1999-11-31
.
The reason for this is that we think it's the responsibility of the
application to handle date checking, not the SQL servers. To make the
date checking 'fast', MySQL only checks that the month is in
the range of 0-12 and the day is in the range of 0-31. The above ranges
are defined this way because MySQL allows you to store, in a
DATE
or DATETIME
column, dates where the day or month-day
is zero. This is extremely useful for applications that need to store
a birth-date for which you don't know the exact date. In this case you
simply store the date like 1999-00-00
or 1999-01-00
. (You
cannot expect to get a correct value from functions like DATE_SUB()
or DATE_ADD
for dates like these.)
Here are some general considerations to keep in mind when working with date and time types:
'98-09-04'
), rather than
in the month-day-year or day-month-year orders commonly used elsewhere (for
example, '09-04-98'
, '04-09-98'
).
TIME
values are clipped to
the appropriate endpoint of the TIME
range.) The table below
shows the format of the ``zero'' value for each type:
Column type | ``Zero'' value |
DATETIME | '0000-00-00 00:00:00'
|
DATE | '0000-00-00'
|
TIMESTAMP | 00000000000000 (length depends on display size)
|
TIME | '00:00:00'
|
YEAR | 0000
|
'0'
or 0
, which are easier to write.
NULL
in MyODBC Version 2.50.12 and above,
because ODBC can't handle such values.
MySQL itself is Y2K-safe (see section 1.8 Year 2000 Compliance), but input values presented to MySQL may not be. Any input containing 2-digit year values is ambiguous, because the century is unknown. Such values must be interpreted into 4-digit form because MySQL stores years internally using four digits.
For DATETIME
, DATE
, TIMESTAMP
, and YEAR
types,
MySQL interprets dates with ambiguous year values using the
following rules:
00-69
are converted to 2000-2069
.
70-99
are converted to 1970-1999
.
Remember that these rules provide only reasonable guesses as to what your data mean. If the heuristics used by MySQL don't produce the correct values, you should provide unambiguous input containing 4-digit year values.
ORDER BY
will sort 2-digit YEAR/DATE/DATETIME
types properly.
Note also that some functions like MIN()
and MAX()
will convert a
TIMESTAMP/DATE
to a number. This means that a timestamp with a
2-digit year will not work properly with these functions. The fix in this
case is to convert the TIMESTAMP/DATE
to 4-digit year format or
use something like MIN(DATE_ADD(timestamp,INTERVAL 0 DAYS))
.
DATETIME
, DATE
, and TIMESTAMP
Types
The DATETIME
, DATE
, and TIMESTAMP
types are related.
This section describes their characteristics, how they are similar, and how
they differ.
The DATETIME
type is used when you need values that contain both date
and time information. MySQL retrieves and displays DATETIME
values in 'YYYY-MM-DD HH:MM:SS'
format. The supported range is
'1000-01-01 00:00:00'
to '9999-12-31 23:59:59'
. (``Supported''
means that although earlier values might work, there is no guarantee that
they will.)
The DATE
type is used when you need only a date value, without a time
part. MySQL retrieves and displays DATE
values in
'YYYY-MM-DD'
format. The supported range is '1000-01-01'
to
'9999-12-31'
.
The TIMESTAMP
column type provides a type that you can use to
automatically mark INSERT
or UPDATE
operations with the current
date and time. If you have multiple TIMESTAMP
columns, only the first
one is updated automatically.
Automatic updating of the first TIMESTAMP
column occurs under any of
the following conditions:
INSERT
or
LOAD DATA INFILE
statement.
UPDATE
statement and some
other column changes value. (Note that an UPDATE
that sets a column
to the value it already has will not cause the TIMESTAMP
column to be
updated, because if you set a column to its current value, MySQL
ignores the update for efficiency.)
TIMESTAMP
column to NULL
.
TIMESTAMP
columns other than the first may also be set to the current
date and time. Just set the column to NULL
or to NOW()
.
You can set any TIMESTAMP
column to a value different than the current
date and time by setting it explicitly to the desired value. This is true
even for the first TIMESTAMP
column. You can use this property if,
for example, you want a TIMESTAMP
to be set to the current date and
time when you create a row, but not to be changed whenever the row is updated
later:
TIMESTAMP
column explicitly to its current value.
On the other hand, you may find it just as easy to use a DATETIME
column that you initialize to NOW()
when the row is created and
leave alone for subsequent updates.
TIMESTAMP
values may range from the beginning of 1970 to sometime in
the year 2037, with a resolution of one second. Values are displayed as
numbers.
The format in which MySQL retrieves and displays TIMESTAMP
values depends on the display size, as illustrated by the table below. The
`full' TIMESTAMP
format is 14 digits, but TIMESTAMP
columns may
be created with shorter display sizes:
Column type | Display format |
TIMESTAMP(14) | YYYYMMDDHHMMSS
|
TIMESTAMP(12) | YYMMDDHHMMSS
|
TIMESTAMP(10) | YYMMDDHHMM
|
TIMESTAMP(8) | YYYYMMDD
|
TIMESTAMP(6) | YYMMDD
|
TIMESTAMP(4) | YYMM
|
TIMESTAMP(2) | YY
|
All TIMESTAMP
columns have the same storage size, regardless of
display size. The most common display sizes are 6, 8, 12, and 14. You can
specify an arbitrary display size at table creation time, but values of 0 or
greater than 14 are coerced to 14. Odd-valued sizes in the range from 1 to
13 are coerced to the next higher even number.
You can specify DATETIME
, DATE
, and TIMESTAMP
values using
any of a common set of formats:
'YYYY-MM-DD HH:MM:SS'
or 'YY-MM-DD
HH:MM:SS'
format. A ``relaxed'' syntax is allowed--any punctuation
character may be used as the delimiter between date parts or time parts.
For example, '98-12-31 11:30:45'
, '98.12.31 11+30+45'
,
'98/12/31 11*30*45'
, and '98@12@31 11^30^45'
are
equivalent.
'YYYY-MM-DD'
or 'YY-MM-DD'
format.
A ``relaxed'' syntax is allowed here, too. For example, '98-12-31'
,
'98.12.31'
, '98/12/31'
, and '98@12@31'
are
equivalent.
'YYYYMMDDHHMMSS'
or
'YYMMDDHHMMSS'
format, provided that the string makes sense as a
date. For example, '19970523091528'
and '970523091528'
are
interpreted as '1997-05-23 09:15:28'
, but '971122129015'
is
illegal (it has a nonsensical minute part) and becomes '0000-00-00
00:00:00'
.
'YYYYMMDD'
or 'YYMMDD'
format, provided that the string makes sense as a date. For example,
'19970523'
and '970523'
are interpreted as
'1997-05-23'
, but '971332'
is illegal (it has nonsensical month
and day parts) and becomes '0000-00-00'
.
YYYYMMDDHHMMSS
or YYMMDDHHMMSS
format, provided that the number makes sense as a date. For example,
19830905132800
and 830905132800
are interpreted as
'1983-09-05 13:28:00'
.
YYYYMMDD
or YYMMDD
format, provided that the number makes sense as a date. For example,
19830905
and 830905
are interpreted as '1983-09-05'
.
DATETIME
, DATE
, or TIMESTAMP
context, such as
NOW()
or CURRENT_DATE
.
Illegal DATETIME
, DATE
, or TIMESTAMP
values are converted
to the ``zero'' value of the appropriate type ('0000-00-00 00:00:00'
,
'0000-00-00'
, or 00000000000000
).
For values specified as strings that include date part delimiters, it is not
necessary to specify two digits for month or day values that are less than
10
. '1979-6-9'
is the same as '1979-06-09'
. Similarly,
for values specified as strings that include time part delimiters, it is not
necessary to specify two digits for hour, month, or second values that are
less than 10
. '1979-10-30 1:2:3'
is the same as
'1979-10-30 01:02:03'
.
Values specified as numbers should be 6, 8, 12, or 14 digits long. If the
number is 8 or 14 digits long, it is assumed to be in YYYYMMDD
or
YYYYMMDDHHMMSS
format and that the year is given by the first 4
digits. If the number is 6 or 12 digits long, it is assumed to be in
YYMMDD
or YYMMDDHHMMSS
format and that the year is given by the
first 2 digits. Numbers that are not one of these lengths are interpreted
as though padded with leading zeros to the closest length.
Values specified as non-delimited strings are interpreted using their length
as given. If the string is 8 or 14 characters long, the year is assumed to
be given by the first 4 characters. Otherwise the year is assumed to be
given by the first 2 characters. The string is interpreted from left to
right to find year, month, day, hour, minute, and second values, for as many
parts as are present in the string. This means you should not use strings
that have fewer than 6 characters. For example, if you specify '9903'
,
thinking that will represent March, 1999, you will find that MySQL
inserts a ``zero'' date into your table. This is because the year and month
values are 99
and 03
, but the day part is missing (zero), so
the value is not a legal date.
TIMESTAMP
columns store legal values using the full precision with
which the value was specified, regardless of the display size. This has
several implications:
TIMESTAMP(4)
or TIMESTAMP(2)
. Otherwise, the value will not
be a legal date and 0
will be stored.
ALTER TABLE
to widen a narrow TIMESTAMP
column,
information will be displayed that previously was ``hidden''.
TIMESTAMP
column does not cause information to
be lost, except in the sense that less information is shown when the values
are displayed.
TIMESTAMP
values are stored to full precision, the only
function that operates directly on the underlying stored value is
UNIX_TIMESTAMP()
. Other functions operate on the formatted retrieved
value. This means you cannot use functions such as HOUR()
or
SECOND()
unless the relevant part of the TIMESTAMP
value is
included in the formatted value. For example, the HH
part of a
TIMESTAMP
column is not displayed unless the display size is at least
10, so trying to use HOUR()
on shorter TIMESTAMP
values
produces a meaningless result.
You can to some extent assign values of one date type to an object of a different date type. However, there may be some alteration of the value or loss of information:
DATE
value to a DATETIME
or TIMESTAMP
object, the time part of the resulting value is set to '00:00:00'
,
because the DATE
value contains no time information.
DATETIME
or TIMESTAMP
value to a DATE
object, the time part of the resulting value is deleted, because the
DATE
type stores no time information.
DATETIME
, DATE
, and TIMESTAMP
values all can be specified using the same set of formats, the types do not
all have the same range of values. For example, TIMESTAMP
values
cannot be earlier than 1970
or later than 2037
. This means
that a date such as '1968-01-01'
, while legal as a DATETIME
or
DATE
value, is not a valid TIMESTAMP
value and will be
converted to 0
if assigned to such an object.
Be aware of certain pitfalls when specifying date values:
'10:11:12'
might look like a time value
because of the `:' delimiter, but if used in a date context will be
interpreted as the year '2010-11-12'
. The value '10:45:15'
will be converted to '0000-00-00'
because '45'
is not a legal
month.
00-69
are converted to 2000-2069
.
70-99
are converted to 1970-1999
.
TIME
Type
MySQL retrieves and displays TIME
values in 'HH:MM:SS'
format (or 'HHH:MM:SS'
format for large hours values). TIME
values may range from '-838:59:59'
to '838:59:59'
. The reason
the hours part may be so large is that the TIME
type may be used not
only to represent a time of day (which must be less than 24 hours), but also
elapsed time or a time interval between two events (which may be much greater
than 24 hours, or even negative).
You can specify TIME
values in a variety of formats:
'D HH:MM:SS.fraction'
format. (Note that
MySQL doesn't yet store the fraction for the time column). One
can also use one of the following ``relaxed'' syntax:
HH:MM:SS.fraction
, HH:MM:SS
, HH:MM
, D HH:MM:SS
,
D HH:MM
, D HH
or SS
. Here D
is days between 0-33.
'HHMMSS'
format, provided that
it makes sense as a time. For example, '101112'
is understood as
'10:11:12'
, but '109712'
is illegal (it has a nonsensical
minute part) and becomes '00:00:00'
.
HHMMSS
format, provided that it makes sense as a time.
For example, 101112
is understood as '10:11:12'
. The following
alternative formats are also understood: SS
, MMSS
,HHMMSS
,
HHMMSS.fraction
. Note that MySQL doesn't yet store the
fraction part.
TIME
context, such as CURRENT_TIME
.
For TIME
values specified as strings that include a time part
delimiter, it is not necessary to specify two digits for hours, minutes, or
seconds values that are less than 10
. '8:3:2'
is the same as
'08:03:02'
.
Be careful about assigning ``short'' TIME
values to a TIME
column. MySQL interprets values using the assumption that the
rightmost digits represent seconds. (MySQL interprets TIME
values as elapsed time rather than as time of day.) For example, you might
think of '11:12'
, '1112'
, and 1112
as meaning
'11:12:00'
(12 minutes after 11 o'clock), but MySQL
interprets them as '00:11:12'
(11 minutes, 12 seconds). Similarly,
'12'
and 12
are interpreted as '00:00:12'
.
Values that lie outside the TIME
range
but are otherwise legal are clipped to the appropriate
endpoint of the range. For example, '-850:00:00'
and
'850:00:00'
are converted to '-838:59:59'
and
'838:59:59'
.
Illegal TIME
values are converted to '00:00:00'
. Note that
because '00:00:00'
is itself a legal TIME
value, there is no way
to tell, from a value of '00:00:00'
stored in a table, whether the
original value was specified as '00:00:00'
or whether it was illegal.
YEAR
Type
The YEAR
type is a 1-byte type used for representing years.
MySQL retrieves and displays YEAR
values in YYYY
format. The range is 1901
to 2155
.
You can specify YEAR
values in a variety of formats:
'1901'
to '2155'
.
1901
to 2155
.
'00'
to '99'
. Values in the
ranges '00'
to '69'
and '70'
to '99'
are
converted to YEAR
values in the ranges 2000
to 2069
and
1970
to 1999
.
1
to 99
. Values in the
ranges 1
to 69
and 70
to 99
are converted to
YEAR
values in the ranges 2001
to 2069
and 1970
to 1999
. Note that the range for two-digit numbers is slightly
different than the range for two-digit strings, because you cannot specify zero
directly as a number and have it be interpreted as 2000
. You
must specify it as a string '0'
or '00'
or it will be
interpreted as 0000
.
YEAR
context, such as NOW()
.
Illegal YEAR
values are converted to 0000
.
The string types are CHAR
, VARCHAR
, BLOB
, TEXT
,
ENUM
, and SET
.
CHAR
and VARCHAR
Types
The CHAR
and VARCHAR
types are similar, but differ in the
way they are stored and retrieved.
The length of a CHAR
column is fixed to the length that you declare
when you create the table. The length can be any value between 1 and 255.
(As of MySQL Version 3.23, the length of CHAR
may be 0 to 255.)
When CHAR
values are stored, they are right-padded with spaces to the
specified length. When CHAR
values are retrieved, trailing spaces are
removed.
Values in VARCHAR
columns are variable-length strings. You can
declare a VARCHAR
column to be any length between 1 and 255, just as
for CHAR
columns. However, in contrast to CHAR
, VARCHAR
values are stored using only as many characters as are needed, plus one byte
to record the length. Values are not padded; instead, trailing spaces are
removed when values are stored. (This space removal differs from the ANSI
SQL specification.)
If you assign a value to a CHAR
or VARCHAR
column that
exceeds the column's maximum length, the value is truncated to fit.
The table below illustrates the differences between the two types of columns
by showing the result of storing various string values into CHAR(4)
and VARCHAR(4)
columns:
Value | CHAR(4) | Storage required | VARCHAR(4) | Storage required |
'' | ' ' | 4 bytes | '' | 1 byte |
'ab' | 'ab ' | 4 bytes | 'ab' | 3 bytes |
'abcd' | 'abcd' | 4 bytes | 'abcd' | 5 bytes |
'abcdefgh' | 'abcd' | 4 bytes | 'abcd' | 5 bytes |
The values retrieved from the CHAR(4)
and VARCHAR(4)
columns
will be the same in each case, because trailing spaces are removed from
CHAR
columns upon retrieval.
Values in CHAR
and VARCHAR
columns are sorted and compared
in case-insensitive fashion, unless the BINARY
attribute was
specified when the table was created. The BINARY
attribute means
that column values are sorted and compared in case-sensitive fashion
according to the ASCII order of the machine where the MySQL
server is running. BINARY
doesn't affect how the column is stored
or retrieved.
The BINARY
attribute is sticky. This means that if a column marked
BINARY
is used in an expression, the whole expression is compared as a
BINARY
value.
MySQL may silently change the type of a CHAR
or VARCHAR
column at table creation time.
See section 7.7.1 Silent Column Specification Changes.
BLOB
and TEXT
Types
A BLOB
is a binary large object that can hold a variable amount of
data. The four BLOB
types TINYBLOB
, BLOB
,
MEDIUMBLOB
, and LONGBLOB
differ only in the maximum length of
the values they can hold.
See section 7.3.1 Column Type Storage Requirements.
The four TEXT
types TINYTEXT
, TEXT
, MEDIUMTEXT
,
and LONGTEXT
correspond to the four BLOB
types and have the
same maximum lengths and storage requirements. The only difference between
BLOB
and TEXT
types is that sorting and comparison is performed
in case-sensitive fashion for BLOB
values and case-insensitive fashion
for TEXT
values. In other words, a TEXT
is a case-insensitive
BLOB
.
If you assign a value to a BLOB
or TEXT
column that exceeds
the column type's maximum length, the value is truncated to fit.
In most respects, you can regard a TEXT
column as a VARCHAR
column that can be as big as you like. Similarly, you can regard a
BLOB
column as a VARCHAR BINARY
column. The differences are:
BLOB
and TEXT
columns with
MySQL Version 3.23.2 and newer. Older versions of
MySQL did not support this.
BLOB
and TEXT
columns
when values are stored, as there is for VARCHAR
columns.
BLOB
and TEXT
columns cannot have DEFAULT
values.
MyODBC defines BLOB
values as LONGVARBINARY
and
TEXT
values as LONGVARCHAR
.
Because BLOB
and TEXT
values may be extremely long, you
may run up against some constraints when using them:
GROUP BY
or ORDER BY
on a BLOB
or
TEXT
column, you must convert the column value into a fixed-length
object. The standard way to do this is with the SUBSTRING
function. For example:
mysql> select comment from tbl_name,substring(comment,20) as substr ORDER BY substr;If you don't do this, only the first
max_sort_length
bytes of the
column are used when sorting. The default value of max_sort_length
is
1024; this value can be changed using the -O
option when starting the
mysqld
server. You can group on an expression involving BLOB
or
TEXT
values by specifying the column position or by using an alias:
mysql> select id,substring(blob_col,1,100) from tbl_name GROUP BY 2; mysql> select id,substring(blob_col,1,100) as b from tbl_name GROUP BY b;
BLOB
or TEXT
object is determined by its
type, but the largest value you can actually transmit between the client and
server is determined by the amount of available memory and the size of the
communications buffers. You can change the message buffer size, but you must
do so on both the server and client ends. See section 12.2.3 Tuning Server Parameters.
Note that each BLOB
or TEXT
value is represented
internally by a separately allocated object. This is in contrast to all
other column types, for which storage is allocated once per column when
the table is opened.
ENUM
Type
An ENUM
is a string object whose value normally is chosen from a list
of allowed values that are enumerated explicitly in the column specification
at table creation time.
The value may also be the empty string (""
) or NULL
under
certain circumstances:
ENUM
(that is, a string not
present in the list of allowed values), the empty string is inserted
instead as a special error value.
ENUM
is declared NULL
, NULL
is also a legal value
for the column, and the default value is NULL
. If an ENUM
is
declared NOT NULL
, the default value is the first element of the
list of allowed values.
Each enumeration value has an index:
SELECT
statement to find rows into which invalid
ENUM
values were assigned:
mysql> SELECT * FROM tbl_name WHERE enum_col=0;
NULL
value is NULL
.
For example, a column specified as ENUM("one", "two", "three")
can
have any of the values shown below. The index of each value is also shown:
Value | Index |
NULL | NULL
|
"" | 0 |
"one" | 1 |
"two" | 2 |
"three" | 3 |
An enumeration can have a maximum of 65535 elements.
Lettercase is irrelevant when you assign values to an ENUM
column.
However, values retrieved from the column later have lettercase matching the
values that were used to specify the allowable values at table creation time.
If you retrieve an ENUM
in a numeric context, the column value's
index is returned. For example, you can retrieve numeric values from
an ENUM
column like this:
mysql> SELECT enum_col+0 FROM tbl_name;
If you store a number into an ENUM
, the number is treated as an
index, and the value stored is the enumeration member with that index.
(However, this will not work with LOAD DATA
, which treats all
input as strings.)
ENUM
values are sorted according to the order in which the enumeration
members were listed in the column specification. (In other words,
ENUM
values are sorted according to their index numbers.) For
example, "a"
sorts before "b"
for ENUM("a", "b")
, but
"b"
sorts before "a"
for ENUM("b", "a")
. The empty
string sorts before non-empty strings, and NULL
values sort before
all other enumeration values.
If you want to get all possible values for an ENUM
column, you should
use: SHOW COLUMNS FROM table_name LIKE enum_column_name
and parse
the ENUM
definition in the second column.
SET
Type
A SET
is a string object that can have zero or more values, each of
which must be chosen from a list of allowed values specified when the table
is created. SET
column values that consist of multiple set members
are specified with members separated by commas (`,'). A consequence of
this is that SET
member values cannot themselves contain commas.
For example, a column specified as SET("one", "two") NOT NULL
can have
any of these values:
"" "one" "two" "one,two"
A SET
can have a maximum of 64 different members.
MySQL stores SET
values numerically, with the low-order bit
of the stored value corresponding to the first set member. If you retrieve a
SET
value in a numeric context, the value retrieved has bits set
corresponding to the set members that make up the column value. For example,
you can retrieve numeric values from a SET
column like this:
mysql> SELECT set_col+0 FROM tbl_name;
If a number is stored into a SET
column, the bits that
are set in the binary representation of the number determine the
set members in the column value. Suppose a column is specified as
SET("a","b","c","d")
. Then the members have the following bit
values:
SET member | Decimal value | Binary value |
a | 1 | 0001
|
b | 2 | 0010
|
c | 4 | 0100
|
d | 8 | 1000
|
If you assign a value of 9
to this column, that is 1001
in
binary, so the first and fourth SET
value members "a"
and
"d"
are selected and the resulting value is "a,d"
.
For a value containing more than one SET
element, it does not matter
what order the elements are listed in when you insert the value. It also
does not matter how many times a given element is listed in the value.
When the value is retrieved later, each element in the value will appear
once, with elements listed according to the order in which they were
specified at table creation time. For example, if a column is specified as
SET("a","b","c","d")
, then "a,d"
, "d,a"
, and
"d,a,a,d,d"
will all appear as "a,d"
when retrieved.
SET
values are sorted numerically. NULL
values sort before
non-NULL
SET
values.
Normally, you perform a SELECT
on a SET
column using
the LIKE
operator or the FIND_IN_SET()
function:
mysql> SELECT * FROM tbl_name WHERE set_col LIKE '%value%'; mysql> SELECT * FROM tbl_name WHERE FIND_IN_SET('value',set_col)>0;
But the following will also work:
mysql> SELECT * FROM tbl_name WHERE set_col = 'val1,val2'; mysql> SELECT * FROM tbl_name WHERE set_col & 1;
The first of these statements looks for an exact match. The second looks for values containing the first set member.
If you want to get all possible values for a SET
column, you should
use: SHOW COLUMNS FROM table_name LIKE set_column_name
and parse
the SET
definition in the second column.
For the most efficient use of storage, try to use the most precise type in
all cases. For example, if an integer column will be used for values in the
range between 1
and 99999
, MEDIUMINT UNSIGNED
is the
best type.
Accurate representation of monetary values is a common problem. In
MySQL, you should use the DECIMAL
type. This is stored as
a string, so no loss of accuracy should occur. If accuracy is not
too important, the DOUBLE
type may also be good enough.
For high precision, you can always convert to a fixed-point type stored
in a BIGINT
. This allows you to do all calculations with integers
and convert results back to floating-point values only when necessary.
All MySQL column types can be indexed. Use of indexes on the
relevant columns is the best way to improve the performance of SELECT
operations.
A table may have up to 16 indexes. The maximum index length is 256 bytes, although this may be changed when compiling MySQL.
For CHAR
and VARCHAR
columns, you can index a prefix of a
column. This is much faster and requires less disk space than indexing the
whole column. The syntax to use in the CREATE TABLE
statement to
index a column prefix looks like this:
KEY index_name (col_name(length))
The example below creates an index for the first 10 characters of the
name
column:
mysql> CREATE TABLE test ( name CHAR(200) NOT NULL, KEY index_name (name(10)));
For BLOB
and TEXT
columns, you must index a prefix of the
column. You cannot index the entire column.
In MySQL Version 3.23.23 or later, you can also create special
FULLTEXT indexes. They are used for full-text search. Only the
MyISAM
table type supports FULLTEXT
indexes. They can be
created only from VARCHAR
and TEXT
columns.
Indexing always happens over the entire column and partial indexing is not
supported. See section 25.2 MySQL Full-text Search for details.
MySQL can create indexes on multiple columns. An index may
consist of up to 15 columns. (On CHAR
and VARCHAR
columns you
can also use a prefix of the column as a part of an index).
A multiple-column index can be considered a sorted array containing values that are created by concatenating the values of the indexed columns.
MySQL uses multiple-column indexes in such a way that queries are
fast when you specify a known quantity for the first column of the index in a
WHERE
clause, even if you don't specify values for the other columns.
Suppose a table is created using the following specification:
mysql> CREATE TABLE test ( id INT NOT NULL, last_name CHAR(30) NOT NULL, first_name CHAR(30) NOT NULL, PRIMARY KEY (id), INDEX name (last_name,first_name));
Then the index name
is an index over last_name
and
first_name
. The index will be used for queries that specify
values in a known range for last_name
, or for both last_name
and first_name
.
Therefore, the name
index will be used in the following queries:
mysql> SELECT * FROM test WHERE last_name="Widenius"; mysql> SELECT * FROM test WHERE last_name="Widenius" AND first_name="Michael"; mysql> SELECT * FROM test WHERE last_name="Widenius" AND (first_name="Michael" OR first_name="Monty"); mysql> SELECT * FROM test WHERE last_name="Widenius" AND first_name >="M" AND first_name < "N";
However, the name
index will NOT be used in the following queries:
mysql> SELECT * FROM test WHERE first_name="Michael"; mysql> SELECT * FROM test WHERE last_name="Widenius" OR first_name="Michael";
For more information on the manner in which MySQL uses indexes to improve query performance, see section 12.4 How MySQL Uses Indexes.
To make it easier to use code written for SQL implementations from other vendors, MySQL maps column types as shown in the table below. These mappings make it easier to move table definitions from other database engines to MySQL:
Other vendor type | MySQL type |
BINARY(NUM) | CHAR(NUM) BINARY
|
CHAR VARYING(NUM) | VARCHAR(NUM)
|
FLOAT4 | FLOAT
|
FLOAT8 | DOUBLE
|
INT1 | TINYINT
|
INT2 | SMALLINT
|
INT3 | MEDIUMINT
|
INT4 | INT
|
INT8 | BIGINT
|
LONG VARBINARY | MEDIUMBLOB
|
LONG VARCHAR | MEDIUMTEXT
|
MIDDLEINT | MEDIUMINT
|
VARBINARY(NUM) | VARCHAR(NUM) BINARY
|
Column type mapping occurs at table creation time. If you create a table
with types used by other vendors and then issue a DESCRIBE tbl_name
statement, MySQL reports the table structure using the equivalent
MySQL types.
SELECT
and WHERE
Clauses
A select_expression
or where_definition
in a SQL statement
can consist of any expression using the functions described below.
An expression that contains NULL
always produces a NULL
value
unless otherwise indicated in the documentation for the operators and
functions involved in the expression.
NOTE: There must be no whitespace between a function name and the parenthesis following it. This helps the MySQL parser distinguish between function calls and references to tables or columns that happen to have the same name as a function. Spaces around arguments are permitted, though.
You can force MySQL to accept spaces after the function name by
starting mysqld
with --ansi
or using the
CLIENT_IGNORE_SPACE
to mysql_connect()
, but in this case all
function names will become reserved words. See section 5.2 Running MySQL in ANSI Mode.
For the sake of brevity, examples display the output from the mysql
program in abbreviated form. So this:
mysql> select MOD(29,9); 1 rows in set (0.00 sec) +-----------+ | mod(29,9) | +-----------+ | 2 | +-----------+
is displayed like this:
mysql> select MOD(29,9); -> 2
( ... )
mysql> select 1+2*3; -> 7 mysql> select (1+2)*3; -> 9
The usual arithmetic operators are available. Note that in the case of
`-', `+', and `*', the result is calculated with
BIGINT
(64-bit) precision if both arguments are integers!
+
mysql> select 3+5; -> 8
-
mysql> select 3-5; -> -2
*
mysql> select 3*5; -> 15 mysql> select 18014398509481984*18014398509481984.0; -> 324518553658426726783156020576256.0 mysql> select 18014398509481984*18014398509481984; -> 0The result of the last expression is incorrect because the result of the integer multiplication exceeds the 64-bit range of
BIGINT
calculations.
/
mysql> select 3/5; -> 0.60Division by zero produces a
NULL
result:
mysql> select 102/(1-1); -> NULLA division will be calculated with
BIGINT
arithmetic only if performed
in a context where its result is converted to an integer!
MySQL uses BIGINT
(64-bit) arithmetic for bit operations, so
these operators have a maximum range of 64 bits.
|
mysql> select 29 | 15; -> 31
&
mysql> select 29 & 15; -> 13
<<
BIGINT
) number to the left:
mysql> select 1 << 2 -> 4
>>
BIGINT
) number to the right:
mysql> select 4 >> 2 -> 1
~
mysql> select 5 & ~1 -> 4
BIT_COUNT(N)
N
:
mysql> select BIT_COUNT(29); -> 4
All logical functions return 1
(TRUE), 0
(FALSE) or
NULL
(unknown, which is in most cases the same as FALSE):
NOT
!
1
if the argument is 0
, otherwise returns
0
.
Exception: NOT NULL
returns NULL
:
mysql> select NOT 1; -> 0 mysql> select NOT NULL; -> NULL mysql> select ! (1+1); -> 0 mysql> select ! 1+1; -> 1The last example returns
1
because the expression evaluates
the same way as (!1)+1
.
OR
||
1
if either argument is not 0
and not
NULL
:
mysql> select 1 || 0; -> 1 mysql> select 0 || 0; -> 0 mysql> select 1 || NULL; -> 1
AND
&&
0
if either argument is 0
or NULL
,
otherwise returns 1
:
mysql> select 1 && NULL; -> 0 mysql> select 1 && 0; -> 0
Comparison operations result in a value of 1
(TRUE), 0
(FALSE),
or NULL
. These functions work for both numbers and strings. Strings
are automatically converted to numbers and numbers to strings as needed (as
in Perl).
MySQL performs comparisons using the following rules:
NULL
, the result of the comparison
is NULL
, except for the <=>
operator.
TIMESTAMP
or DATETIME
column and
the other argument is a constant, the constant is converted
to a timestamp before the comparison is performed. This is done to be more
ODBC-friendly.
By default, string comparisons are done in case-independent fashion using the current character set (ISO-8859-1 Latin1 by default, which also works excellently for English).
The examples below illustrate conversion of strings to numbers for comparison operations:
mysql> SELECT 1 > '6x'; -> 0 mysql> SELECT 7 > '6x'; -> 1 mysql> SELECT 0 > 'x6'; -> 0 mysql> SELECT 0 = 'x6'; -> 1
=
mysql> select 1 = 0; -> 0 mysql> select '0' = 0; -> 1 mysql> select '0.0' = 0; -> 1 mysql> select '0.01' = 0; -> 0 mysql> select '.01' = 0.01; -> 1
<>
!=
mysql> select '.01' <> '0.01'; -> 1 mysql> select .01 <> '0.01'; -> 0 mysql> select 'zapp' <> 'zappp'; -> 1
<=
mysql> select 0.1 <= 2; -> 1
<
mysql> select 2 <= 2; -> 1
>=
mysql> select 2 >= 2; -> 1
>
mysql> select 2 > 2; -> 0
<=>
mysql> select 1 <=> 1, NULL <=> NULL, 1 <=> NULL; -> 1 1 0
IS NULL
IS NOT NULL
NULL
:
mysql> select 1 IS NULL, 0 IS NULL, NULL IS NULL: -> 0 0 1 mysql> select 1 IS NOT NULL, 0 IS NOT NULL, NULL IS NOT NULL; -> 1 1 0
expr BETWEEN min AND max
expr
is greater than or equal to min
and expr
is
less than or equal to max
, BETWEEN
returns 1
,
otherwise it returns 0
. This is equivalent to the expression
(min <= expr AND expr <= max)
if all the arguments are of the
same type. The first argument (expr
) determines how the
comparison is performed as follows:
expr
is a TIMESTAMP
, DATE
, or DATETIME
column, MIN()
and MAX()
are formatted to the same format if
they are constants.
expr
is a case-insensitive string expression, a case-insensitive
string comparison is done.
expr
is a case-sensitive string expression, a case-sensitive
string comparison is done.
expr
is an integer expression, an integer comparison is done.
mysql> select 1 BETWEEN 2 AND 3; -> 0 mysql> select 'b' BETWEEN 'a' AND 'c'; -> 1 mysql> select 2 BETWEEN 2 AND '3'; -> 1 mysql> select 2 BETWEEN 2 AND 'x-3'; -> 0
expr IN (value,...)
1
if expr
is any of the values in the IN
list,
else returns 0
. If all values are constants, then all values are
evaluated according to the type of expr
and sorted. The search for the
item is then done using a binary search. This means IN
is very quick
if the IN
value list consists entirely of constants. If expr
is a case-sensitive string expression, the string comparison is performed in
case-sensitive fashion:
mysql> select 2 IN (0,3,5,'wefwf'); -> 0 mysql> select 'wefwf' IN (0,3,5,'wefwf'); -> 1
expr NOT IN (value,...)
NOT (expr IN (value,...))
.
ISNULL(expr)
expr
is NULL
, ISNULL()
returns 1
, otherwise
it returns 0
:
mysql> select ISNULL(1+1); -> 0 mysql> select ISNULL(1/0); -> 1Note that a comparison of
NULL
values using =
will always be
false!
COALESCE(list)
NULL
element in list:
mysql> select COALESCE(NULL,1); -> 1 mysql> select COALESCE(NULL,NULL,NULL); -> NULL
INTERVAL(N,N1,N2,N3,...)
0
if N
< N1
, 1
if N
< N2
and so on. All arguments are treated as integers. It is required that
N1
< N2
< N3
< ...
< Nn
for this function
to work correctly. This is because a binary search is used (very fast):
mysql> select INTERVAL(23, 1, 15, 17, 30, 44, 200); -> 3 mysql> select INTERVAL(10, 1, 10, 100, 1000); -> 2 mysql> select INTERVAL(22, 23, 30, 44, 200); -> 0
Normally, if any expression in a string comparison is case sensitive, the comparison is performed in case-sensitive fashion.
expr LIKE pat [ESCAPE 'escape-char']
1
(TRUE) or 0
(FALSE). With LIKE
you can use the following two wild-card characters
in the pattern:
% | Matches any number of characters, even zero characters |
_ | Matches exactly one character |
mysql> select 'David!' LIKE 'David_'; -> 1 mysql> select 'David!' LIKE '%D%v%'; -> 1To test for literal instances of a wild-card character, precede the character with the escape character. If you don't specify the
ESCAPE
character,
`\' is assumed:
\% | Matches one % character
|
\_ | Matches one _ character
|
mysql> select 'David!' LIKE 'David\_'; -> 0 mysql> select 'David_' LIKE 'David\_'; -> 1To specify a different escape character, use the
ESCAPE
clause:
mysql> select 'David_' LIKE 'David|_' ESCAPE '|'; -> 1
LIKE
is allowed on numeric expressions! (This is a MySQL
extension to the ANSI SQL LIKE
.)
mysql> select 10 LIKE '1%'; -> 1Note: Because MySQL uses the C escape syntax in strings (for example, `\n'), you must double any `\' that you use in your
LIKE
strings. For example, to search for `\n', specify it as `\\n'. To
search for `\', specify it as `\\\\' (the backslashes are stripped
once by the parser and another time when the pattern match is done, leaving
a single backslash to be matched).
expr NOT LIKE pat [ESCAPE 'escape-char']
NOT (expr LIKE pat [ESCAPE 'escape-char'])
.
expr REGEXP pat
expr RLIKE pat
expr
against a pattern
pat
. The pattern can be an extended regular expression.
See section J Description of MySQL regular expression syntax. Returns 1
if expr
matches pat
, otherwise
returns 0
. RLIKE
is a synonym for REGEXP
, provided for
mSQL
compatibility. Note: Because MySQL uses the C escape
syntax in strings (for example, `\n'), you must double any `\' that
you use in your REGEXP
strings. As of MySQL Version 3.23.4,
REGEXP
is case insensitive for normal (not binary) strings:
mysql> select 'Monty!' REGEXP 'm%y%%'; -> 0 mysql> select 'Monty!' REGEXP '.*'; -> 1 mysql> select 'new*\n*line' REGEXP 'new\\*.\\*line'; -> 1 mysql> select "a" REGEXP "A", "a" REGEXP BINARY "A"; -> 1 0 mysql> select "a" REGEXP "^[a-d]"; -> 1
REGEXP
and RLIKE
use the current character set (ISO-8859-1
Latin1 by default) when deciding the type of a character.
expr NOT REGEXP pat
expr NOT RLIKE pat
NOT (expr REGEXP pat)
.
STRCMP(expr1,expr2)
STRCMP()
returns 0
if the strings are the same, -1
if the first
argument is smaller than the second according to the current sort order,
and 1
otherwise:
mysql> select STRCMP('text', 'text2'); -> -1 mysql> select STRCMP('text2', 'text'); -> 1 mysql> select STRCMP('text', 'text'); -> 0
MATCH (col1,col2,...) AGAINST (expr)
MATCH ... AGAINST()
is used for full-text search and returns
relevance - similarity measure between the text in columns
(col1,col2,...)
and the query expr
. Relevance is a
positive floating-point number. Zero relevance means no similarity.
For MATCH ... AGAINST()
to work, a FULLTEXT index
must be created first. See section 7.7 CREATE TABLE
Syntax.
MATCH ... AGAINST()
is available in MySQL Version
3.23.23 or later. For details and usage examples
see section 25.2 MySQL Full-text Search.
BINARY
BINARY
operator casts the string following it to a binary string.
This is an easy way to force a column comparison to be case sensitive even
if the column isn't defined as BINARY
or BLOB
:
mysql> select "a" = "A"; -> 1 mysql> select BINARY "a" = "A"; -> 0
BINARY
was introduced in MySQL Version 3.23.0.
Note that in some context MySQL will not be able to use the
index efficiently when you cast an indexed column to BINARY
.
If you want to compare a blob case-insensitively you can always convert the blob to upper case before doing the comparison:
SELECT 'A' LIKE UPPER(blob_col) FROM table_name;
We plan to soon introduce casting between different character sets to make string comparison even more flexible.
IFNULL(expr1,expr2)
expr1
is not NULL
, IFNULL()
returns expr1
,
else it returns expr2
. IFNULL()
returns a numeric or string
value, depending on the context in which it is used:
mysql> select IFNULL(1,0); -> 1 mysql> select IFNULL(NULL,10); -> 10 mysql> select IFNULL(1/0,10); -> 10 mysql> select IFNULL(1/0,'yes'); -> 'yes'
NULLIF(expr1,expr2)
expr1 = expr2
is true, return NULL
else return expr1
.
This is the same as CASE WHEN x = y THEN NULL ELSE x END
:
mysql> select NULLIF(1,1); -> NULL mysql> select NULLIF(1,2); -> 1Note that
expr1
is evaluated twice in MySQL if the arguments
are equal.
IF(expr1,expr2,expr3)
expr1
is TRUE (expr1 <> 0
and expr1 <> NULL
) then
IF()
returns expr2
, else it returns expr3
.
IF()
returns a numeric or string value, depending on the context
in which it is used:
mysql> select IF(1>2,2,3); -> 3 mysql> select IF(1<2,'yes','no'); -> 'yes' mysql> select IF(strcmp('test','test1'),'no','yes'); -> 'no'
expr1
is evaluated as an integer value, which means that if you are
testing floating-point or string values, you should do so using a comparison
operation:
mysql> select IF(0.1,1,0); -> 0 mysql> select IF(0.1<>0,1,0); -> 1In the first case above,
IF(0.1)
returns 0
because 0.1
is converted to an integer value, resulting in a test of IF(0)
. This
may not be what you expect. In the second case, the comparison tests the
original floating-point value to see whether it is non-zero. The result
of the comparison is used as an integer.
The default return type of IF()
(which may matter when it is
stored into a temporary table) is calculated in MySQL Version
3.23 as follows:
Expression | Return value |
expr2 or expr3 returns string | string |
expr2 or expr3 returns a floating-point value | floating-point |
expr2 or expr3 returns an integer | integer |
CASE value WHEN [compare-value] THEN result [WHEN [compare-value] THEN result ...] [ELSE result] END
CASE WHEN [condition] THEN result [WHEN [condition] THEN result ...] [ELSE result] END
result
where
value=compare-value
. The second version returns the result for
the first condition, which is true. If there was no matching result
value, then the result after ELSE
is returned. If there is no
ELSE
part then NULL
is returned:
mysql> SELECT CASE 1 WHEN 1 THEN "one" WHEN 2 THEN "two" ELSE "more" END; -> "one" mysql> SELECT CASE WHEN 1>0 THEN "true" ELSE "false" END; -> "true" mysql> SELECT CASE BINARY "B" when "a" then 1 when "b" then 2 END; -> NULL
The type of the return value (INTEGER
, DOUBLE
or
STRING
) is the same as the type of the first returned value (the
expression after the first THEN
).
All mathematical functions return NULL
in case of an error.
-
mysql> select - 2; -> -2Note that if this operator is used with a
BIGINT
, the return value is a
BIGINT
! This means that you should avoid using -
on integers that
may have the value of -2^63
!
ABS(X)
X
:
mysql> select ABS(2); -> 2 mysql> select ABS(-32); -> 32This function is safe to use with
BIGINT
values.
SIGN(X)
-1
, 0
, or 1
, depending
on whether X
is negative, zero, or positive:
mysql> select SIGN(-32); -> -1 mysql> select SIGN(0); -> 0 mysql> select SIGN(234); -> 1
MOD(N,M)
%
%
operator in C).
Returns the remainder of N
divided by M
:
mysql> select MOD(234, 10); -> 4 mysql> select 253 % 7; -> 1 mysql> select MOD(29,9); -> 2This function is safe to use with
BIGINT
values.
FLOOR(X)
X
:
mysql> select FLOOR(1.23); -> 1 mysql> select FLOOR(-1.23); -> -2Note that the return value is converted to a
BIGINT
!
CEILING(X)
X
:
mysql> select CEILING(1.23); -> 2 mysql> select CEILING(-1.23); -> -1Note that the return value is converted to a
BIGINT
!
ROUND(X)
X
, rounded to the nearest integer:
mysql> select ROUND(-1.23); -> -1 mysql> select ROUND(-1.58); -> -2 mysql> select ROUND(1.58); -> 2
ROUND(X,D)
X
, rounded to a number with D
decimals.
If D
is 0
, the result will have no decimal point or fractional
part:
mysql> select ROUND(1.298, 1); -> 1.3 mysql> select ROUND(1.298, 0); -> 1
EXP(X)
e
(the base of natural logarithms) raised to
the power of X
:
mysql> select EXP(2); -> 7.389056 mysql> select EXP(-2); -> 0.135335
LOG(X)
X
:
mysql> select LOG(2); -> 0.693147 mysql> select LOG(-2); -> NULLIf you want the log of a number
X
to some arbitary base B
, use
the formula LOG(X)/LOG(B)
.
LOG10(X)
X
:
mysql> select LOG10(2); -> 0.301030 mysql> select LOG10(100); -> 2.000000 mysql> select LOG10(-100); -> NULL
POW(X,Y)
POWER(X,Y)
X
raised to the power of Y
:
mysql> select POW(2,2); -> 4.000000 mysql> select POW(2,-2); -> 0.250000
SQRT(X)
X
:
mysql> select SQRT(4); -> 2.000000 mysql> select SQRT(20); -> 4.472136
PI()
mysql> select PI(); -> 3.141593
COS(X)
X
, where X
is given in radians:
mysql> select COS(PI()); -> -1.000000
SIN(X)
X
, where X
is given in radians:
mysql> select SIN(PI()); -> 0.000000
TAN(X)
X
, where X
is given in radians:
mysql> select TAN(PI()+1); -> 1.557408
ACOS(X)
X
, that is, the value whose cosine is
X
. Returns NULL
if X
is not in the range -1
to
1
:
mysql> select ACOS(1); -> 0.000000 mysql> select ACOS(1.0001); -> NULL mysql> select ACOS(0); -> 1.570796
ASIN(X)
X
, that is, the value whose sine is
X
. Returns NULL
if X
is not in the range -1
to
1
:
mysql> select ASIN(0.2); -> 0.201358 mysql> select ASIN('foo'); -> 0.000000
ATAN(X)
X
, that is, the value whose tangent is
X
:
mysql> select ATAN(2); -> 1.107149 mysql> select ATAN(-2); -> -1.107149
ATAN2(Y,X)
X
and Y
. It is
similar to calculating the arc tangent of Y / X
, except that the
signs of both arguments are used to determine the quadrant of the
result:
mysql> select ATAN(-2,2); -> -0.785398 mysql> select ATAN(PI(),0); -> 1.570796
COT(X)
X
:
mysql> select COT(12); -> -1.57267341 mysql> select COT(0); -> NULL
RAND()
RAND(N)
0
to 1.0
.
If an integer argument N
is specified, it is used as the seed value:
mysql> select RAND(); -> 0.5925 mysql> select RAND(20); -> 0.1811 mysql> select RAND(20); -> 0.1811 mysql> select RAND(); -> 0.2079 mysql> select RAND(); -> 0.7888You can't use a column with
RAND()
values in an ORDER BY
clause, because ORDER BY
would evaluate the column multiple times.
In MySQL Version 3.23, you can, however, do:
SELECT * FROM table_name ORDER BY RAND()
This is useful to get a random sample of a set SELECT * FROM
table1,table2 WHERE a=b AND c<d ORDER BY RAND() LIMIT 1000
.
Note that a RAND()
in a WHERE
clause will be re-evaluated
every time the WHERE
is executed.
LEAST(X,Y,...)
INTEGER
context, or all arguments
are integer-valued, they are compared as integers.
REAL
context, or all arguments are
real-valued, they are compared as reals.
mysql> select LEAST(2,0); -> 0 mysql> select LEAST(34.0,3.0,5.0,767.0); -> 3.0 mysql> select LEAST("B","A","C"); -> "A"In MySQL versions prior to Version 3.22.5, you can use
MIN()
instead of LEAST
.
GREATEST(X,Y,...)
LEAST
:
mysql> select GREATEST(2,0); -> 2 mysql> select GREATEST(34.0,3.0,5.0,767.0); -> 767.0 mysql> select GREATEST("B","A","C"); -> "C"In MySQL versions prior to Version 3.22.5, you can use
MAX()
instead of GREATEST
.
DEGREES(X)
X
, converted from radians to degrees:
mysql> select DEGREES(PI()); -> 180.000000
RADIANS(X)
X
, converted from degrees to radians:
mysql> select RADIANS(90); -> 1.570796
TRUNCATE(X,D)
X
, truncated to D
decimals. If D
is 0
, the result will have no decimal point or fractional part:
mysql> select TRUNCATE(1.223,1); -> 1.2 mysql> select TRUNCATE(1.999,1); -> 1.9 mysql> select TRUNCATE(1.999,0); -> 1
String-valued functions return NULL
if the length of the result would
be greater than the max_allowed_packet
server parameter. See section 12.2.3 Tuning Server Parameters.
For functions that operate on string positions, the first position is numbered 1.
ASCII(str)
str
. Returns 0
if str
is the empty string. Returns
NULL
if str
is NULL
:
mysql> select ASCII('2'); -> 50 mysql> select ASCII(2); -> 50 mysql> select ASCII('dx'); -> 100See also the
ORD()
function.
ORD(str)
((first byte ASCII code)*256+(second byte ASCII code))[*256+third byte ASCII code...]
.
If the leftmost character is not a multi-byte character, returns the same
value as the like ASCII()
function does:
mysql> select ORD('2'); -> 50
CONV(N,from_base,to_base)
N
, converted from base from_base
to base to_base
. Returns NULL
if any argument is NULL
.
The argument N
is interpreted as an integer, but may be specified as
an integer or a string. The minimum base is 2
and the maximum base is
36
. If to_base
is a negative number, N
is regarded as a
signed number. Otherwise, N
is treated as unsigned. CONV
works
with 64-bit precision:
mysql> select CONV("a",16,2); -> '1010' mysql> select CONV("6E",18,8); -> '172' mysql> select CONV(-17,10,-18); -> '-H' mysql> select CONV(10+"10"+'10'+0xa,10,10); -> '40'
BIN(N)
N
, where
N
is a longlong (BIGINT
) number. This is equivalent to
CONV(N,10,2)
. Returns NULL
if N
is NULL
:
mysql> select BIN(12); -> '1100'
OCT(N)
N
, where
N
is a longlong number. This is equivalent to CONV(N,10,8)
.
Returns NULL
if N
is NULL
:
mysql> select OCT(12); -> '14'
HEX(N)
N
, where
N
is a longlong (BIGINT
) number. This is equivalent to
CONV(N,10,16)
. Returns NULL
if N
is NULL
:
mysql> select HEX(255); -> 'FF'
CHAR(N,...)
CHAR()
interprets the arguments as integers and returns a string
consisting of the characters given by the ASCII code values of those
integers. NULL
values are skipped:
mysql> select CHAR(77,121,83,81,'76'); -> 'MySQL' mysql> select CHAR(77,77.3,'77.3'); -> 'MMM'
CONCAT(str1,str2,...)
NULL
if any argument is NULL
. May have more than 2 arguments.
A numeric argument is converted to the equivalent string form:
mysql> select CONCAT('My', 'S', 'QL'); -> 'MySQL' mysql> select CONCAT('My', NULL, 'QL'); -> NULL mysql> select CONCAT(14.3); -> '14.3'
CONCAT_WS(separator, str1, str2,...)
CONCAT_WS()
stands for CONCAT With Separator and is a special form of
CONCAT()
. The first argument is the separator for the rest of the
arguments. The separator can be a string as well as the rest of the
arguments. If the separator is NULL
, the result will be NULL
.
The function will skip any NULL
s and empty strings, after the
separator argument. The separator will be added between the strings to be
concatenated:
mysql> select CONCAT_WS(",","First name","Second name","Last Name"); -> 'First name,Second name,Last Name' mysql> select CONCAT_WS(",","First name",NULL,"Last Name"); -> 'First name,Last Name'
LENGTH(str)
OCTET_LENGTH(str)
CHAR_LENGTH(str)
CHARACTER_LENGTH(str)
str
:
mysql> select LENGTH('text'); -> 4 mysql> select OCTET_LENGTH('text'); -> 4Note that for
CHAR_LENGTH()
, multi-byte characters are only counted
once.
LOCATE(substr,str)
POSITION(substr IN str)
substr
in string str
. Returns 0
if substr
is not in str
:
mysql> select LOCATE('bar', 'foobarbar'); -> 4 mysql> select LOCATE('xbar', 'foobar'); -> 0This function is multi-byte safe.
LOCATE(substr,str,pos)
substr
in
string str
, starting at position pos
.
Returns 0
if substr
is not in str
:
mysql> select LOCATE('bar', 'foobarbar',5); -> 7This function is multi-byte safe.
INSTR(str,substr)
substr
in
string str
. This is the same as the two-argument form of
LOCATE()
, except that the arguments are swapped:
mysql> select INSTR('foobarbar', 'bar'); -> 4 mysql> select INSTR('xbar', 'foobar'); -> 0This function is multi-byte safe.
LPAD(str,len,padstr)
str
, left-padded with the string padstr
until str
is len
characters long. If str
is longer
than len'
then it will be shortened to len
characters.
mysql> select LPAD('hi',4,'??'); -> '??hi'
RPAD(str,len,padstr)
str
, right-padded with the string
padstr
until str
is len
characters long. If
str
is longer than len'
then it will be shortened to
len
characters.
mysql> select RPAD('hi',5,'?'); -> 'hi???'
LEFT(str,len)
len
characters from the string str
:
mysql> select LEFT('foobarbar', 5); -> 'fooba'This function is multi-byte safe.
RIGHT(str,len)
len
characters from the string str
:
mysql> select RIGHT('foobarbar', 4); -> 'rbar'This function is multi-byte safe.
SUBSTRING(str,pos,len)
SUBSTRING(str FROM pos FOR len)
MID(str,pos,len)
len
characters long from string str
,
starting at position pos
.
The variant form that uses FROM
is ANSI SQL92 syntax:
mysql> select SUBSTRING('Quadratically',5,6); -> 'ratica'This function is multi-byte safe.
SUBSTRING(str,pos)
SUBSTRING(str FROM pos)
str
starting at position pos
:
mysql> select SUBSTRING('Quadratically',5); -> 'ratically' mysql> select SUBSTRING('foobarbar' FROM 4); -> 'barbar'This function is multi-byte safe.
SUBSTRING_INDEX(str,delim,count)
str
before count
occurrences of the delimiter delim
.
If count
is positive, everything to the left of the final delimiter
(counting from the left) is returned.
If count
is negative, everything to the right of the final delimiter
(counting from the right) is returned:
mysql> select SUBSTRING_INDEX('www.mysql.com', '.', 2); -> 'www.mysql' mysql> select SUBSTRING_INDEX('www.mysql.com', '.', -2); -> 'mysql.com'This function is multi-byte safe.
LTRIM(str)
str
with leading space characters removed:
mysql> select LTRIM(' barbar'); -> 'barbar'
RTRIM(str)
str
with trailing space characters removed:
mysql> select RTRIM('barbar '); -> 'barbar'This function is multi-byte safe.
TRIM([[BOTH | LEADING | TRAILING] [remstr] FROM] str)
str
with all remstr
prefixes and/or suffixes
removed. If none of the specifiers BOTH
, LEADING
or
TRAILING
are given, BOTH
is assumed. If remstr
is not
specified, spaces are removed:
mysql> select TRIM(' bar '); -> 'bar' mysql> select TRIM(LEADING 'x' FROM 'xxxbarxxx'); -> 'barxxx' mysql> select TRIM(BOTH 'x' FROM 'xxxbarxxx'); -> 'bar' mysql> select TRIM(TRAILING 'xyz' FROM 'barxxyz'); -> 'barx'This function is multi-byte safe.
SOUNDEX(str)
str
. Two strings that sound almost the
same should have identical soundex strings. A standard soundex string
is 4 characters long, but the SOUNDEX()
function returns an
arbitrarily long string. You can use SUBSTRING()
on the result to get
a standard soundex string. All non-alphanumeric characters are ignored
in the given string. All international alpha characters outside the A-Z range
are treated as vowels:
mysql> select SOUNDEX('Hello'); -> 'H400' mysql> select SOUNDEX('Quadratically'); -> 'Q36324'
SPACE(N)
N
space characters:
mysql> select SPACE(6); -> ' '
REPLACE(str,from_str,to_str)
str
with all all occurrences of the string
from_str
replaced by the string to_str
:
mysql> select REPLACE('www.mysql.com', 'w', 'Ww'); -> 'WwWwWw.mysql.com'This function is multi-byte safe.
REPEAT(str,count)
str
repeated count
times. If count <= 0
, returns an empty string. Returns NULL
if
str
or count
are NULL
:
mysql> select REPEAT('MySQL', 3); -> 'MySQLMySQLMySQL'
REVERSE(str)
str
with the order of the characters reversed:
mysql> select REVERSE('abc'); -> 'cba'This function is multi-byte safe.
INSERT(str,pos,len,newstr)
str
, with the substring beginning at position
pos
and len
characters long replaced by the string
newstr
:
mysql> select INSERT('Quadratic', 3, 4, 'What'); -> 'QuWhattic'This function is multi-byte safe.
ELT(N,str1,str2,str3,...)
str1
if N
= 1
, str2
if N
=
2
, and so on. Returns NULL
if N
is less than 1
or greater than the number of arguments. ELT()
is the complement of
FIELD()
:
mysql> select ELT(1, 'ej', 'Heja', 'hej', 'foo'); -> 'ej' mysql> select ELT(4, 'ej', 'Heja', 'hej', 'foo'); -> 'foo'
FIELD(str,str1,str2,str3,...)
str
in the str1
, str2
,
str3
, ...
list.
Returns 0
if str
is not found.
FIELD()
is the complement of ELT()
:
mysql> select FIELD('ej', 'Hej', 'ej', 'Heja', 'hej', 'foo'); -> 2 mysql> select FIELD('fo', 'Hej', 'ej', 'Heja', 'hej', 'foo'); -> 0
FIND_IN_SET(str,strlist)
1
to N
if the string str
is in the list
strlist
consisting of N
substrings. A string list is a string
composed of substrings separated by `,' characters. If the first
argument is a constant string and the second is a column of type SET
,
the FIND_IN_SET()
function is optimized to use bit arithmetic!
Returns 0
if str
is not in strlist
or if strlist
is the empty string. Returns NULL
if either argument is NULL
.
This function will not work properly if the first argument contains a
`,':
mysql> SELECT FIND_IN_SET('b','a,b,c,d'); -> 2
MAKE_SET(bits,str1,str2,...)
bits
set. str1
corresponds to bit 0, str2
to bit 1,
etc. NULL
strings in str1
, str2
, ...
are not appended to the result:
mysql> SELECT MAKE_SET(1,'a','b','c'); -> 'a' mysql> SELECT MAKE_SET(1 | 4,'hello','nice','world'); -> 'hello,world' mysql> SELECT MAKE_SET(0,'a','b','c'); -> ''
EXPORT_SET(bits,on,off,[separator,[number_of_bits]])
mysql> select EXPORT_SET(5,'Y','N',',',4) -> Y,N,Y,N
LCASE(str)
LOWER(str)
str
with all characters changed to lowercase
according to the current character set mapping (the default is ISO-8859-1
Latin1):
mysql> select LCASE('QUADRATICALLY'); -> 'quadratically'This function is multi-byte safe.
UCASE(str)
UPPER(str)
str
with all characters changed to uppercase
according to the current character set mapping (the default is ISO-8859-1
Latin1):
mysql> select UCASE('Hej'); -> 'HEJ'This function is multi-byte safe.
LOAD_FILE(file_name)
max_allowed_packet
.
If the file doesn't exist or can't be read due to one of the above reasons,
the function returns NULL
:
mysql> UPDATE table_name SET blob_column=LOAD_FILE("/tmp/picture") WHERE id=1;
If you are not using MySQL Version 3.23, you have to do the reading
of the file inside your application and create an INSERT
statement
to update the database with the file information. One way to do this, if
you are using the MySQL++ library, can be found at
http://www.mysql.com/documentation/mysql++/mysql++-examples.html.
MySQL automatically converts numbers to strings as necessary, and vice-versa:
mysql> SELECT 1+"1"; -> 2 mysql> SELECT CONCAT(2,' test'); -> '2 test'
If you want to convert a number to a string explicitly, pass it as the
argument to CONCAT()
.
If a string function is given a binary string as an argument, the resulting string is also a binary string. A number converted to a string is treated as a binary string. This only affects comparisons.
See section 7.3.3 Date and Time Types for a description of the range of values each type has and the valid formats in which date and time values may be specified.
Here is an example that uses date functions. The query below selects
all records with a date_col
value from within the last 30 days:
mysql> SELECT something FROM table WHERE TO_DAYS(NOW()) - TO_DAYS(date_col) <= 30;
DAYOFWEEK(date)
date
(1
= Sunday, 2
= Monday, ... 7
=
Saturday). These index values correspond to the ODBC standard:
mysql> select DAYOFWEEK('1998-02-03'); -> 3
WEEKDAY(date)
date
(0
= Monday, 1
= Tuesday, ... 6
= Sunday):
mysql> select WEEKDAY('1997-10-04 22:23:00'); -> 5 mysql> select WEEKDAY('1997-11-05'); -> 2
DAYOFMONTH(date)
date
, in the range 1
to
31
:
mysql> select DAYOFMONTH('1998-02-03'); -> 3
DAYOFYEAR(date)
date
, in the range 1
to
366
:
mysql> select DAYOFYEAR('1998-02-03'); -> 34
MONTH(date)
date
, in the range 1
to 12
:
mysql> select MONTH('1998-02-03'); -> 2
DAYNAME(date)
date
:
mysql> select DAYNAME("1998-02-05"); -> 'Thursday'
MONTHNAME(date)
date
:
mysql> select MONTHNAME("1998-02-05"); -> 'February'
QUARTER(date)
date
, in the range 1
to 4
:
mysql> select QUARTER('98-04-01'); -> 2
WEEK(date)
WEEK(date,first)
date
, in the range
0
to 53
(yes, there may be the beginnings of a week 53),
for locations where Sunday is the first day of the week. The
two-argument form of WEEK()
allows you to specify whether the
week starts on Sunday or Monday. The week starts on Sunday if the
second argument is 0
, on Monday if the second argument is
1
:
mysql> select WEEK('1998-02-20'); -> 7 mysql> select WEEK('1998-02-20',0); -> 7 mysql> select WEEK('1998-02-20',1); -> 8 mysql> select WEEK('1998-12-31',1); -> 53
YEAR(date)
date
, in the range 1000
to 9999
:
mysql> select YEAR('98-02-03'); -> 1998
YEARWEEK(date)
YEARWEEK(date,first)
WEEK()
. Note that the year may be
different from the year in the date argument for the first and the last
week of the year:
mysql> select YEARWEEK('1987-01-01'); -> 198653
HOUR(time)
time
, in the range 0
to 23
:
mysql> select HOUR('10:05:03'); -> 10
MINUTE(time)
time
, in the range 0
to 59
:
mysql> select MINUTE('98-02-03 10:05:03'); -> 5
SECOND(time)
time
, in the range 0
to 59
:
mysql> select SECOND('10:05:03'); -> 3
PERIOD_ADD(P,N)
N
months to period P
(in the format YYMM
or
YYYYMM
). Returns a value in the format YYYYMM
.
Note that the period argument P
is not a date value:
mysql> select PERIOD_ADD(9801,2); -> 199803
PERIOD_DIFF(P1,P2)
P1
and P2
.
P1
and P2
should be in the format YYMM
or YYYYMM
.
Note that the period arguments P1
and P2
are not
date values:
mysql> select PERIOD_DIFF(9802,199703); -> 11
DATE_ADD(date,INTERVAL expr type)
DATE_SUB(date,INTERVAL expr type)
ADDDATE(date,INTERVAL expr type)
SUBDATE(date,INTERVAL expr type)
ADDDATE()
and SUBDATE()
are synonyms for
DATE_ADD()
and DATE_SUB()
.
In MySQL Version 3.23, you can use +
and -
instead of
DATE_ADD()
and DATE_SUB()
if the expression on the right side is
a date or datetime column. (See example)
date
is a DATETIME
or DATE
value specifying the starting
date. expr
is an expression specifying the interval value to be added
or substracted from the starting date. expr
is a string; it may start
with a `-' for negative intervals. type
is a keyword indicating
how the expression should be interpreted.
The EXTRACT(type FROM date)
function returns the 'type'
interval from the date.
The following table shows how the type
and expr
arguments
are related:
type value | Expected expr format
|
SECOND | SECONDS
|
MINUTE | MINUTES
|
HOUR | HOURS
|
DAY | DAYS
|
MONTH | MONTHS
|
YEAR | YEARS
|
MINUTE_SECOND | "MINUTES:SECONDS"
|
HOUR_MINUTE | "HOURS:MINUTES"
|
DAY_HOUR | "DAYS HOURS"
|
YEAR_MONTH | "YEARS-MONTHS"
|
HOUR_SECOND | "HOURS:MINUTES:SECONDS"
|
DAY_MINUTE | "DAYS HOURS:MINUTES"
|
DAY_SECOND | "DAYS HOURS:MINUTES:SECONDS"
|
expr
format.
Those shown in the table are the suggested delimiters. If the date
argument is a DATE
value and your calculations involve only
YEAR
, MONTH
, and DAY
parts (that is, no time parts), the
result is a DATE
value. Otherwise the result is a DATETIME
value:
mysql> SELECT "1997-12-31 23:59:59" + INTERVAL 1 SECOND; -> 1998-01-01 00:00:00 mysql> SELECT INTERVAL 1 DAY + "1997-12-31"; -> 1998-01-01 mysql> SELECT "1998-01-01" - INTERVAL 1 SECOND; -> 1997-12-31 23:59:59 mysql> SELECT DATE_ADD("1997-12-31 23:59:59", INTERVAL 1 SECOND); -> 1998-01-01 00:00:00 mysql> SELECT DATE_ADD("1997-12-31 23:59:59", INTERVAL 1 DAY); -> 1998-01-01 23:59:59 mysql> SELECT DATE_ADD("1997-12-31 23:59:59", INTERVAL "1:1" MINUTE_SECOND); -> 1998-01-01 00:01:00 mysql> SELECT DATE_SUB("1998-01-01 00:00:00", INTERVAL "1 1:1:1" DAY_SECOND); -> 1997-12-30 22:58:59 mysql> SELECT DATE_ADD("1998-01-01 00:00:00", INTERVAL "-1 10" DAY_HOUR); -> 1997-12-30 14:00:00 mysql> SELECT DATE_SUB("1998-01-02", INTERVAL 31 DAY); -> 1997-12-02 mysql> SELECT EXTRACT(YEAR FROM "1999-07-02"); -> 1999 mysql> SELECT EXTRACT(YEAR_MONTH FROM "1999-07-02 01:02:03"); -> 199907 mysql> SELECT EXTRACT(DAY_MINUTE FROM "1999-07-02 01:02:03"); -> 20102If you specify an interval value that is too short (does not include all the interval parts that would be expected from the
type
keyword),
MySQL assumes you have left out the leftmost parts of the interval
value. For example, if you specify a type
of DAY_SECOND
, the
value of expr
is expected to have days, hours, minutes, and seconds
parts. If you specify a value like "1:10"
, MySQL assumes
that the days and hours parts are missing and the value represents minutes
and seconds. In other words, "1:10" DAY_SECOND
is interpreted in such
a way that it is equivalent to "1:10" MINUTE_SECOND
. This is
analogous to the way that MySQL interprets TIME
values
as representing elapsed time rather than as time of day.
Note that if you add or subtract a date value against something that
contains a time part, the date value will be automatically converted to a
datetime value:
mysql> select date_add("1999-01-01", interval 1 day); -> 1999-01-02 mysql> select date_add("1999-01-01", interval 1 hour); -> 1999-01-01 01:00:00If you use really incorrect dates, the result is
NULL
. If you add
MONTH
, YEAR_MONTH
, or YEAR
and the resulting date
has a day that is larger than the maximum day for the new month, the day is
adjusted to the maximum days in the new month:
mysql> select DATE_ADD('1998-01-30', Interval 1 month); -> 1998-02-28Note from the preceding example that the word
INTERVAL
and the
type
keyword are not case sensitive.
TO_DAYS(date)
date
, returns a daynumber (the number of days since year
0):
mysql> select TO_DAYS(950501); -> 728779 mysql> select TO_DAYS('1997-10-07'); -> 729669
TO_DAYS()
is not intended for use with values that precede the advent
of the Gregorian calendar (1582), because it doesn't take into account the
days that were lost when the calender was changed.
FROM_DAYS(N)
N
, returns a DATE
value:
mysql> select FROM_DAYS(729669); -> '1997-10-07'
FROM_DAYS()
is not intended for use with values that precede the
advent of the Gregorian calendar (1582), because it doesn't take into account
the days that were lost when the calender was changed.
DATE_FORMAT(date,format)
date
value according to the format
string. The
following specifiers may be used in the format
string:
%M | Month name (January ..December )
|
%W | Weekday name (Sunday ..Saturday )
|
%D | Day of the month with English suffix (1st , 2nd , 3rd , etc.)
|
%Y | Year, numeric, 4 digits |
%y | Year, numeric, 2 digits |
%X | Year for the week where Sunday is the first day of the week, numeric, 4 digits, used with '%V' |
%x | Year for the week, where Monday is the first day of the week, numeric, 4 digits, used with '%v' |
%a | Abbreviated weekday name (Sun ..Sat )
|
%d | Day of the month, numeric (00 ..31 )
|
%e | Day of the month, numeric (0 ..31 )
|
%m | Month, numeric (01 ..12 )
|
%c | Month, numeric (1 ..12 )
|
%b | Abbreviated month name (Jan ..Dec )
|
%j | Day of year (001 ..366 )
|
%H | Hour (00 ..23 )
|
%k | Hour (0 ..23 )
|
%h | Hour (01 ..12 )
|
%I | Hour (01 ..12 )
|
%l | Hour (1 ..12 )
|
%i | Minutes, numeric (00 ..59 )
|
%r | Time, 12-hour (hh:mm:ss [AP]M )
|
%T | Time, 24-hour (hh:mm:ss )
|
%S | Seconds (00 ..59 )
|
%s | Seconds (00 ..59 )
|
%p | AM or PM
|
%w | Day of the week (0 =Sunday..6 =Saturday)
|
%U | Week (0 ..53 ), where Sunday is the first day of the week
|
%u | Week (0 ..53 ), where Monday is the first day of the week
|
%V | Week (1 ..53 ), where Sunday is the first day of the week. Used with '%X'
|
%v | Week (1 ..53 ), where Monday is the first day of the week. Used with '%x'
|
%% | A literal `%'. |
mysql> select DATE_FORMAT('1997-10-04 22:23:00', '%W %M %Y'); -> 'Saturday October 1997' mysql> select DATE_FORMAT('1997-10-04 22:23:00', '%H:%i:%s'); -> '22:23:00' mysql> select DATE_FORMAT('1997-10-04 22:23:00', '%D %y %a %d %m %b %j'); -> '4th 97 Sat 04 10 Oct 277' mysql> select DATE_FORMAT('1997-10-04 22:23:00', '%H %k %I %r %T %S %w'); -> '22 22 10 10:23:00 PM 22:23:00 00 6' mysql> select DATE_FORMAT('1999-01-01', '%X %V'); -> '1998 52'As of MySQL Version 3.23, the `%' character is required before format specifier characters. In earlier versions of MySQL, `%' was optional.
TIME_FORMAT(time,format)
DATE_FORMAT()
function above, but the
format
string may contain only those format specifiers that handle
hours, minutes, and seconds. Other specifiers produce a NULL
value or
0
.
CURDATE()
CURRENT_DATE
'YYYY-MM-DD'
or YYYYMMDD
format, depending on whether the function is used in a string or numeric
context:
mysql> select CURDATE(); -> '1997-12-15' mysql> select CURDATE() + 0; -> 19971215
CURTIME()
CURRENT_TIME
'HH:MM:SS'
or HHMMSS
format, depending on whether the function is used in a string or numeric
context:
mysql> select CURTIME(); -> '23:50:26' mysql> select CURTIME() + 0; -> 235026
NOW()
SYSDATE()
CURRENT_TIMESTAMP
'YYYY-MM-DD HH:MM:SS'
or YYYYMMDDHHMMSS
format, depending on whether the function is used in
a string or numeric context:
mysql> select NOW(); -> '1997-12-15 23:50:26' mysql> select NOW() + 0; -> 19971215235026
UNIX_TIMESTAMP()
UNIX_TIMESTAMP(date)
'1970-01-01 00:00:00'
GMT). If UNIX_TIMESTAMP()
is called with
a date
argument, it returns the value of the argument as seconds since
'1970-01-01 00:00:00'
GMT. date
may be a DATE
string,
a DATETIME
string, a TIMESTAMP
, or a number in the format
YYMMDD
or YYYYMMDD
in local time:
mysql> select UNIX_TIMESTAMP(); -> 882226357 mysql> select UNIX_TIMESTAMP('1997-10-04 22:23:00'); -> 875996580When
UNIX_TIMESTAMP
is used on a TIMESTAMP
column, the function
will receive the value directly, with no implicit
``string-to-unix-timestamp'' conversion.
If you give UNIX_TIMESTAMP()
a wrong or out-of-range date, it will
return 0.
FROM_UNIXTIME(unix_timestamp)
unix_timestamp
argument as a value in
'YYYY-MM-DD HH:MM:SS'
or YYYYMMDDHHMMSS
format, depending on
whether the function is used in a string or numeric context:
mysql> select FROM_UNIXTIME(875996580); -> '1997-10-04 22:23:00' mysql> select FROM_UNIXTIME(875996580) + 0; -> 19971004222300
FROM_UNIXTIME(unix_timestamp,format)
format
string. format
may contain the same specifiers as
those listed in the entry for the DATE_FORMAT()
function:
mysql> select FROM_UNIXTIME(UNIX_TIMESTAMP(), '%Y %D %M %h:%i:%s %x'); -> '1997 23rd December 03:43:30 x'
SEC_TO_TIME(seconds)
seconds
argument, converted to hours, minutes, and seconds,
as a value in 'HH:MM:SS'
or HHMMSS
format, depending on whether
the function is used in a string or numeric context:
mysql> select SEC_TO_TIME(2378); -> '00:39:38' mysql> select SEC_TO_TIME(2378) + 0; -> 3938
TIME_TO_SEC(time)
time
argument, converted to seconds:
mysql> select TIME_TO_SEC('22:23:00'); -> 80580 mysql> select TIME_TO_SEC('00:39:38'); -> 2378
DATABASE()
mysql> select DATABASE(); -> 'test'If there is no current database,
DATABASE()
returns the empty string.
USER()
SYSTEM_USER()
SESSION_USER()
mysql> select USER(); -> 'davida@localhost'In MySQL Version 3.22.11 or later, this includes the client hostname as well as the user name. You can extract just the user name part like this (which works whether or not the value includes a hostname part):
mysql> select substring_index(USER(),"@",1); -> 'davida'
PASSWORD(str)
str
. This is
the function that is used for encrypting MySQL passwords for storage
in the Password
column of the user
grant table:
mysql> select PASSWORD('badpwd'); -> '7f84554057dd964b'
PASSWORD()
encryption is non-reversible.
PASSWORD()
does not perform password encryption in the same way that
Unix passwords are encrypted. You should not assume that if your Unix
password and your MySQL password are the same, PASSWORD()
will result in the same encrypted value as is stored in the Unix password
file. See ENCRYPT()
.
ENCRYPT(str[,salt])
str
using the Unix crypt()
system call. The
salt
argument should be a string with two characters.
(As of MySQL Version 3.22.16, salt
may be longer than two characters.):
mysql> select ENCRYPT("hello"); -> 'VxuFAJXVARROc'If
crypt()
is not available on your system, ENCRYPT()
always
returns NULL
.
ENCRYPT()
ignores all but the first 8 characters of str
, at
least on some systems. This will be determined by the behavior of the
underlying crypt()
system call.
ENCODE(str,pass_str)
str
using pass_str
as the password.
To decrypt the result, use DECODE()
.
The results is a binary string of the same length as string
.
If you want to save it in a column, use a BLOB
column type.
DECODE(crypt_str,pass_str)
crypt_str
using pass_str
as the
password. crypt_str
should be a string returned from
ENCODE()
.
MD5(string)
mysql> select MD5("testing") -> 'ae2b1fca515949e5d54fb22b8ed95575'This is an "RSA Data Security, Inc. MD5 Message-Digest Algorithm".
LAST_INSERT_ID([expr])
AUTO_INCREMENT
column.
See section 23.4.30 mysql_insert_id()
.
mysql> select LAST_INSERT_ID(); -> 195The last ID that was generated is maintained in the server on a per-connection basis. It will not be changed by another client. It will not even be changed if you update another
AUTO_INCREMENT
column with a
non-magic value (that is, a value that is not NULL
and not 0
).
If expr
is given as an argument to LAST_INSERT_ID()
in an
UPDATE
clause, then the value of the argument is returned as a
LAST_INSERT_ID()
value. This can be used to simulate sequences.
First create the table:
mysql> create table sequence (id int not null); mysql> insert into sequence values (0);Then the table can be used to generate sequence numbers like this:
mysql> update sequence set id=LAST_INSERT_ID(id+1);You can generate sequences without calling
LAST_INSERT_ID()
, but the
utility of using the function this way is that the ID value is maintained in
the server as the last automatically generated value. You can retrieve the
new ID as you would read any normal AUTO_INCREMENT
value in
MySQL. For example, LAST_INSERT_ID()
(without an argument)
will return the new ID. The C API function mysql_insert_id()
can also be used to get the value.
FORMAT(X,D)
X
to a format like '#,###,###.##'
, rounded
to D
decimals. If D
is 0
, the result will have no
decimal point or fractional part:
mysql> select FORMAT(12332.123456, 4); -> '12,332.1235' mysql> select FORMAT(12332.1,4); -> '12,332.1000' mysql> select FORMAT(12332.2,0); -> '12,332'
VERSION()
mysql> select VERSION(); -> '3.23.13-log'Note that if your version ends with
-log
this means that logging is
enabled.
CONNECTION_ID()
thread_id
) for the connection.
Every connection has its own unique id:
mysql> select CONNECTION_ID(); -> 1
GET_LOCK(str,timeout)
str
, with a
timeout of timeout
seconds. Returns 1
if the lock was obtained
successfully, 0
if the attempt timed out, or NULL
if an error
occurred (such as running out of memory or the thread was killed with
mysqladmin kill
). A lock is released when you execute
RELEASE_LOCK()
, execute a new GET_LOCK()
, or the thread
terminates. This function can be used to implement application locks or to
simulate record locks. It blocks requests by other clients for locks with
the same name; clients that agree on a given lock string name can use the
string to perform cooperative advisory locking:
mysql> select GET_LOCK("lock1",10); -> 1 mysql> select GET_LOCK("lock2",10); -> 1 mysql> select RELEASE_LOCK("lock2"); -> 1 mysql> select RELEASE_LOCK("lock1"); -> NULLNote that the second
RELEASE_LOCK()
call returns NULL
because
the lock "lock1"
was automatically released by the second
GET_LOCK()
call.
RELEASE_LOCK(str)
str
that was obtained with
GET_LOCK()
. Returns 1
if the lock was released, 0
if the
lock wasn't locked by this thread (in which case the lock is not released),
and NULL
if the named lock didn't exist. The lock will not exist if
it was never obtained by a call to GET_LOCK()
or if it already has
been released.
BENCHMARK(count,expr)
BENCHMARK()
function executes the expression expr
repeatedly count
times. It may be used to time how fast MySQL
processes the expression. The result value is always 0
. The intended
use is in the mysql
client, which reports query execution times:
mysql> select BENCHMARK(1000000,encode("hello","goodbye")); +----------------------------------------------+ | BENCHMARK(1000000,encode("hello","goodbye")) | +----------------------------------------------+ | 0 | +----------------------------------------------+ 1 row in set (4.74 sec)The time reported is elapsed time on the client end, not CPU time on the server end. It may be advisable to execute
BENCHMARK()
several
times, and interpret the result with regard to how heavily loaded the
server machine is.
INET_NTOA(expr)
mysql> select INET_NTOA(3520061480); -> "209.207.224.40"
INET_ATON(expr)
mysql> select INET_ATON("209.207.224.40"); -> 3520061480
MASTER_POS_WAIT(log_name, log_pos)
GROUP BY
Clauses
If you use a group function in a statement containing no GROUP BY
clause, it is equivalent to grouping on all rows.
COUNT(expr)
NULL
values in the rows
retrieved by a SELECT
statement:
mysql> select student.student_name,COUNT(*) from student,course where student.student_id=course.student_id GROUP BY student_name;
COUNT(*)
is somewhat different in that it returns a count of
the number of rows retrieved, whether or not they contain NULL
values.
COUNT(*)
is optimized to
return very quickly if the SELECT
retrieves from one table, no
other columns are retrieved, and there is no WHERE
clause.
For example:
mysql> select COUNT(*) from student;
COUNT(DISTINCT expr,[expr...])
NULL
values:
mysql> select COUNT(DISTINCT results) from student;In MySQL you can get the number of distinct expression combinations that don't contain NULL by giving a list of expressions. In ANSI SQL you would have to do a concatenation of all expressions inside
CODE(DISTINCT ..)
.
AVG(expr)
expr
:
mysql> select student_name, AVG(test_score) from student GROUP BY student_name;
MIN(expr)
MAX(expr)
expr
. MIN()
and
MAX()
may take a string argument; in such cases they return the
minimum or maximum string value. See section 12.4 How MySQL Uses Indexes.
mysql> select student_name, MIN(test_score), MAX(test_score) from student GROUP BY student_name;
SUM(expr)
expr
. Note that if the return set has no rows,
it returns NULL!
STD(expr)
STDDEV(expr)
expr
. This is an extension to
ANSI SQL. The STDDEV()
form of this function is provided for Oracle
compatability.
BIT_OR(expr)
OR
of all bits in expr
. The calculation is
performed with 64-bit (BIGINT
) precision.
BIT_AND(expr)
AND
of all bits in expr
. The calculation is
performed with 64-bit (BIGINT
) precision.
MySQL has extended the use of GROUP BY
. You can use columns or
calculations in the SELECT
expressions that don't appear in
the GROUP BY
part. This stands for any possible value for this
group. You can use this to get better performance by avoiding sorting and
grouping on unnecessary items. For example, you don't need to group on
customer.name
in the following query:
mysql> select order.custid,customer.name,max(payments) from order,customer where order.custid = customer.custid GROUP BY order.custid;
In ANSI SQL, you would have to add customer.name
to the GROUP
BY
clause. In MySQL, the name is redundant if you don't run in
ANSI mode.
Don't use this feature if the columns you omit from the GROUP BY
part
aren't unique in the group!
In some cases, you can use MIN()
and MAX()
to obtain a specific
column value even if it isn't unique. The following gives the value of
column
from the row containing the smallest value in the sort
column:
substr(MIN(concat(sort,space(6-length(sort)),column),7,length(column)))
Note that if you are using MySQL Version 3.22 (or earlier) or if
you are trying to follow ANSI SQL, you can't use expressions in GROUP
BY
or ORDER BY
clauses. You can work around this limitation by
using an alias for the expression:
mysql> SELECT id,FLOOR(value/100) AS val FROM tbl_name GROUP BY id,val ORDER BY val;
In MySQL Version 3.23 you can do:
mysql> SELECT id,FLOOR(value/100) FROM tbl_name ORDER BY RAND();
CREATE DATABASE
SyntaxCREATE DATABASE [IF NOT EXISTS] db_name
CREATE DATABASE
creates a database with the given name. Rules for
allowable database names are given in section 7.1.5 Database, Table, Index, Column, and Alias Names. An error occurs if
the database already exists and you didn't specify IF NOT EXISTS
.
Databases in MySQL are implemented as directories containing files
that correspond to tables in the database. Because there are no tables in a
database when it is initially created, the CREATE DATABASE
statement
only creates a directory under the MySQL data directory.
You can also create databases with mysqladmin
.
See section 14.1 Overview of the Different MySQL Programs.
DROP DATABASE
SyntaxDROP DATABASE [IF EXISTS] db_name
DROP DATABASE
drops all tables in the database and deletes the
database. If you do a DROP DATABASE
on a symbolic linked
database, both the link and the original database is deleted. Be
VERY careful with this command!
DROP DATABASE
returns the number of files that were removed from
the database directory. Normally, this is three times the number of
tables, because normally each table corresponds to a `.MYD' file, a
`.MYI' file, and a `.frm' file.
The DROP DATABASE
command removes from the given database
directory all files with the following extensions:
.BAK | .DAT | .HSH | .ISD |
.ISM | .ISM | .MRG | .MYD |
.MYI | .db | .frm |
All subdirectories that consists of 2 digits (RAID
directories)
are also removed.
In MySQL Version 3.22 or later, you can use the keywords
IF EXISTS
to prevent an error from occurring if the database doesn't
exist.
You can also drop databases with mysqladmin
. See section 14.1 Overview of the Different MySQL Programs.
CREATE TABLE
SyntaxCREATE [TEMPORARY] TABLE [IF NOT EXISTS] tbl_name [(create_definition,...)] [table_options] [select_statement] create_definition: col_name type [NOT NULL | NULL] [DEFAULT default_value] [AUTO_INCREMENT] [PRIMARY KEY] [reference_definition] or PRIMARY KEY (index_col_name,...) or KEY [index_name] (index_col_name,...) or INDEX [index_name] (index_col_name,...) or UNIQUE [INDEX] [index_name] (index_col_name,...) or FULLTEXT [INDEX] [index_name] (index_col_name,...) or [CONSTRAINT symbol] FOREIGN KEY index_name (index_col_name,...) [reference_definition] or CHECK (expr) type: TINYINT[(length)] [UNSIGNED] [ZEROFILL] or SMALLINT[(length)] [UNSIGNED] [ZEROFILL] or MEDIUMINT[(length)] [UNSIGNED] [ZEROFILL] or INT[(length)] [UNSIGNED] [ZEROFILL] or INTEGER[(length)] [UNSIGNED] [ZEROFILL] or BIGINT[(length)] [UNSIGNED] [ZEROFILL] or REAL[(length,decimals)] [UNSIGNED] [ZEROFILL] or DOUBLE[(length,decimals)] [UNSIGNED] [ZEROFILL] or FLOAT[(length,decimals)] [UNSIGNED] [ZEROFILL] or DECIMAL(length,decimals) [UNSIGNED] [ZEROFILL] or NUMERIC(length,decimals) [UNSIGNED] [ZEROFILL] or CHAR(length) [BINARY] or VARCHAR(length) [BINARY] or DATE or TIME or TIMESTAMP or DATETIME or TINYBLOB or BLOB or MEDIUMBLOB or LONGBLOB or TINYTEXT or TEXT or MEDIUMTEXT or LONGTEXT or ENUM(value1,value2,value3,...) or SET(value1,value2,value3,...) index_col_name: col_name [(length)] reference_definition: REFERENCES tbl_name [(index_col_name,...)] [MATCH FULL | MATCH PARTIAL] [ON DELETE reference_option] [ON UPDATE reference_option] reference_option: RESTRICT | CASCADE | SET NULL | NO ACTION | SET DEFAULT table_options: TYPE = {BDB | HEAP | ISAM | INNOBASE | MERGE | MYISAM } or AUTO_INCREMENT = # or AVG_ROW_LENGTH = # or CHECKSUM = {0 | 1} or COMMENT = "string" or MAX_ROWS = # or MIN_ROWS = # or PACK_KEYS = {0 | 1} or PASSWORD = "string" or DELAY_KEY_WRITE = {0 | 1} or ROW_FORMAT= { default | dynamic | static | compressed } or RAID_TYPE= {1 | STRIPED | RAID0 } RAID_CHUNKS=# RAID_CHUNKSIZE=# or UNION = (table_name,[table_name...]) select_statement: [IGNORE | REPLACE] SELECT ... (Some legal select statement)
CREATE TABLE
creates a table with the given name in the current database. Rules for
allowable table names are given in section 7.1.5 Database, Table, Index, Column, and Alias Names. An error occurs if
there is no current database or if the table already exists.
In MySQL Version 3.22 or later, the table name can be specified as
db_name.tbl_name
. This works whether or not there is a current
database.
In MySQL Version 3.23, you can use the TEMPORARY
keyword when
you create a table. A temporary table will automatically be deleted if a
connection dies and the name is per connection. This means that two different
connections can both use the same temporary table name without conflicting
with each other or with an existing table of the same name. (The existing table
is hidden until the temporary table is deleted).
In MySQL Version 3.23 or later, you can use the keywords
IF NOT EXISTS
so that an error does not occur if the table already
exists. Note that there is no verification that the table structures are
identical.
Each table tbl_name
is represented by some files in the database
directory. In the case of MyISAM-type tables you will get:
File | Purpose |
tbl_name.frm | Table definition (form) file |
tbl_name.MYD | Data file |
tbl_name.MYI | Index file |
For more information on the properties of the various column types, see section 7.3 Column Types:
NULL
nor NOT NULL
is specified, the column
is treated as though NULL
had been specified.
AUTO_INCREMENT
.
When you insert a value of NULL
(recommended) or 0
into an
AUTO_INCREMENT
column, the column is set to value+1
, where
value
is the largest value for the column currently in the table.
AUTO_INCREMENT
sequences begin with 1
.
See section 23.4.30 mysql_insert_id()
.
If you delete the row containing the maximum value for an
AUTO_INCREMENT
column, the value will be reused with an ISAM
table but not with a MyISAM
table. If you delete all rows in the
table with DELETE FROM table_name
(without a WHERE
) in
AUTOCOMMIT
mode, the sequence starts over for both table types.
NOTE: There can be only one AUTO_INCREMENT
column per
table, and it must be indexed. MySQL Version 3.23 will also only
work properly if the auto_increment column only has positive
values. Inserting a negative number is regarded as inserting a very large
positive number. This is done to avoid precision problems when
numbers 'wrap' over from positive to negative and also to ensure that one
doesn't accidently get an auto_increment column that contains 0.
To make MySQL compatible with some ODBC applications, you can find
the last inserted row with the following query:
SELECT * FROM tbl_name WHERE auto_col IS NULL
NULL
values are handled differently for TIMESTAMP
columns than
for other column types. You cannot store a literal NULL
in a
TIMESTAMP
column; setting the column to NULL
sets it to the
current date and time. Because TIMESTAMP
columns behave this way, the
NULL
and NOT NULL
attributes do not apply in the normal way and
are ignored if you specify them.
On the other hand, to make it easier for MySQL clients to use
TIMESTAMP
columns, the server reports that such columns may be
assigned NULL
values (which is true), even though TIMESTAMP
never actually will contain a NULL
value. You can see this when you
use DESCRIBE tbl_name
to get a description of your table.
Note that setting a TIMESTAMP
column to 0
is not the same
as setting it to NULL
, because 0
is a valid TIMESTAMP
value.
DEFAULT
value is specified for a column, MySQL
automatically assigns one.
If the column may take NULL
as a value, the default value is
NULL
.
If the column is declared as NOT NULL
, the default value depends on
the column type:
AUTO_INCREMENT
attribute, the default is 0
. For an AUTO_INCREMENT
column, the
default value is the next value in the sequence.
TIMESTAMP
, the default is the
appropriate zero value for the type. For the first TIMESTAMP
column in a table, the default value is the current date and time.
See section 7.3.3 Date and Time Types.
ENUM
, the default value is the empty string.
For ENUM
, the default is the first enumeration value.
NOW()
or CURRENT_DATE
.
KEY
is a synonym for INDEX
.
UNIQUE
key can have only distinct values. An
error occurs if you try to add a new row with a key that matches an existing
row.
PRIMARY KEY
is a unique KEY
with the extra constraint
that all key columns must be defined as NOT NULL
. In MySQL
the key is named PRIMARY
. A table can have only one PRIMARY KEY
.
If you don't have a PRIMARY KEY
and some applications ask for the
PRIMARY KEY
in your tables, MySQL will return the first
UNIQUE
key, which doesn't have any NULL
columns, as the
PRIMARY KEY
.
PRIMARY KEY
can be a multiple-column index. However, you cannot
create a multiple-column index using the PRIMARY KEY
key attibute in a
column specification. Doing so will mark only that single column as primary.
You must use the PRIMARY KEY(index_col_name, ...)
syntax.
PRIMARY
or UNIQUE
key consists of only one column and this
is of type integer, you can also refer to it as _rowid
(new in Version 3.23.11).
index_col_name
, with an optional suffix (_2
,
_3
, ...
) to make it unique. You can see index names for a
table using SHOW INDEX FROM tbl_name
.
See section 7.28 SHOW
Syntax (Get Information About Tables, Columns,...).
MyISAM
table type supports indexes on columns that can have
NULL
values. In other cases you must declare such columns
NOT NULL
or an error results.
col_name(length)
syntax, you can specify an index that
uses only a part of a CHAR
or VARCHAR
column. This can
make the index file much smaller.
See section 7.3.6 Column Indexes.
MyISAM
table type supports indexing on BLOB
and
TEXT
columns. When putting an index on a BLOB
or TEXT
column you MUST always specify the length of the index:
CREATE TABLE test (blob_col BLOB, index(blob_col(10)));
ORDER BY
or GROUP BY
with a TEXT
or
BLOB
column, only the first max_sort_length
bytes are used.
See section 7.3.4.2 The BLOB
and TEXT
Types.
MyISAM
table type supports FULLTEXT
indexes. They can be created
only from VARCHAR
and TEXT
columns.
Indexing always happens over the entire column, partial indexing is not
supported. See section 25.2 MySQL Full-text Search for details of operation.
FOREIGN KEY
, CHECK
, and REFERENCES
clauses don't
actually do anything. The syntax for them is provided only for compatibility,
to make it easier to port code from other SQL servers and to run applications
that create tables with references.
See section 5.4 Functionality Missing from MySQL.
NULL
column takes one bit extra, rounded up to the nearest byte.
row length = 1 + (sum of column lengths) + (number of NULL columns + 7)/8 + (number of variable-length columns)
table_options
and SELECT
options are only
implemented in MySQL Version 3.23 and above.
The different table types are:
BDB or Berkeley_db | Transaction-safe tables with page locking. See section 8.5 BDB or Berkeley_db Tables. |
HEAP | The data for this table is only stored in memory. See section 8.4 HEAP Tables. |
ISAM | The original table handler. See section 8.3 ISAM Tables. |
INNOBASE | Transaction-safe tables with row locking. See section 8.6 INNOBASE Tables. |
MERGE | A collection of MyISAM tables used as one table. See section 8.2 MERGE Tables. |
MyISAM | The new binary portable table handler that is replacing ISAM. See section 8.1 MyISAM Tables. |
TYPE=BDB
is specified, and that distribution
of MySQL does not support BDB
tables, the table will be created
as MyISAM
instead.
The other table options are used to optimize the behavior of the
table. In most cases, you don't have to specify any of them.
The options work for all table types, if not otherwise indicated:
AUTO_INCREMENT | The next auto_increment value you want to set for your table (MyISAM). |
AVG_ROW_LENGTH | An approximation of the average row length for your table. You only need to set this for large tables with variable size records. |
CHECKSUM | Set this to 1 if you want MySQL to maintain a checksum for all rows (makes the table a little slower to update but makes it easier to find corrupted tables) (MyISAM). |
COMMENT | A 60-character comment for your table. |
MAX_ROWS | Max number of rows you plan to store in the table. |
MIN_ROWS | Minimum number of rows you plan to store in the table. |
PACK_KEYS | Set this to 1 if you want to have a smaller index. This usually makes updates slower and reads faster (MyISAM, ISAM). |
PASSWORD | Encrypt the .frm file with a password. This option doesn't do anything in the standard MySQL version.
|
DELAY_KEY_WRITE | Set this to 1 if want to delay key table updates until the table is closed (MyISAM). |
ROW_FORMAT | Defines how the rows should be stored (for the future). |
MyISAM
table, MySQL uses the product of
max_rows * avg_row_length
to decide how big the resulting table
will be. If you don't specify any of the above options, the maximum size
for a table will be 4G (or 2G if your operating systems only supports 2G
tables). The reason for this is just to keep down the pointer sizes
to make the index smaller and faster if you don't really need big files.
If you don't use PACK_KEYS
, the default is to only pack strings,
not numbers. If you use PACK_KEYS=1
, numbers will be packed as well.
When packing binary number keys, MySQL will use prefix compression.
This means that you will only get a big benefit of this if you have
many numbers that are the same. Prefix compression means that every
key needs one extra byte to indicate how many bytes of the previous key are
the same for the next key (note that the pointer to the row is stored
in high-byte-first-order directly after the key, to improve
compression.) This means that if you have many equal keys on two rows
in a row, all following 'same' keys will usually only take 2 bytes
(including the pointer to the row). Compare this to the ordinary case
where the following keys will take storage_size_for_key +
pointer_size (usually 4). On the other hand, if all keys are
totally different, you will lose 1 byte per key, if the key isn't a
key that can have NULL
values (In this case the packed key length will
be stored in the same byte that is used to mark if a key is NULL
.)
SELECT
after the CREATE STATEMENT
,
MySQL will create new fields for all elements in the
SELECT
. For example:
mysql> CREATE TABLE test (a int not null auto_increment, primary key (a), key(b)) TYPE=MyISAM SELECT b,c from test2;This will create a
MyISAM
table with 3 columns. Note that the
table will automatically be deleted if any errors occur while copying
data into the table.
RAID_TYPE
option will help you to break the 2G/4G limit for
the MyISAM data file (not the index file) on
operating systems that don't support big files. You can get also more speed
from the I/O bottleneck by putting RAID
directories on different
physical disks. RAID_TYPE
will work on any OS, as long as you have
configured MySQL with --with-raid
. For now the only allowed
RAID_TYPE
is STRIPED
(1
and RAID0
are aliases
for this).
If you specify RAID_TYPE=STRIPED
for a MyISAM
table,
MyISAM
will create RAID_CHUNKS
subdirectories named 00,
01, 02 in the database directory. In each of these directories
MyISAM
will create a table_name.MYD
. When writing data
to the data file, the RAID
handler will map the first
RAID_CHUNKSIZE
*1024 bytes to the first file, the next
RAID_CHUNKSIZE
*1024 bytes to the next file and so on.
UNION
is used when you want to use a collection of identical
tables as one. This only works with MERGE tables. See section 8.2 MERGE Tables.
For the moment you need to have SELECT
, UPDATE
, and
DELETE
privileges on the tables you map to a MERGE
table.
All mapped tables must be in the same database as the MERGE
table.
PRIMARY
key will be placed first, followed
by all UNIQUE
keys and then the normal keys. This helps the
MySQL optimizer to prioritize which key to use and also more quickly
detect duplicated UNIQUE
keys.
In some cases, MySQL silently changes a column specification from
that given in a CREATE TABLE
statement. (This may also occur with
ALTER TABLE
.):
VARCHAR
columns with a length less than four are changed to
CHAR
.
VARCHAR
, TEXT
, or BLOB
),
all CHAR
columns longer than three characters are changed to
VARCHAR
columns. This doesn't affect how you use the columns in
any way; in MySQL, VARCHAR
is just a different way to
store characters. MySQL performs this conversion because it
saves space and makes table operations faster. See section 8 MySQL Table Types.
TIMESTAMP
display sizes must be even and in the range from 2 to 14.
If you specify a display size of 0 or greater than 14, the size is coerced
to 14. Odd-valued sizes in the range from 1 to 13 are coerced
to the next higher even number.
NULL
in a TIMESTAMP
column; setting
it to NULL
sets it to the current date and time. Because
TIMESTAMP
columns behave this way, the NULL
and NOT NULL
attributes do not apply in the normal way and are ignored if you specify
them. DESCRIBE tbl_name
always reports that a TIMESTAMP
column may be assigned NULL
values.
If you want to see whether or not MySQL used a column type other
than the one you specified, issue a DESCRIBE tbl_name
statement after
creating or altering your table.
Certain other column type changes may occur if you compress a table
using myisampack
. See section 8.1.2.3 Compressed Table Characteristics.
ALTER TABLE
SyntaxALTER [IGNORE] TABLE tbl_name alter_spec [, alter_spec ...] alter_specification: ADD [COLUMN] create_definition [FIRST | AFTER column_name ] or ADD [COLUMN] (create_definition, create_definition,...) or ADD INDEX [index_name] (index_col_name,...) or ADD PRIMARY KEY (index_col_name,...) or ADD UNIQUE [index_name] (index_col_name,...) or ADD FULLTEXT [index_name] (index_col_name,...) or ADD [CONSTRAINT symbol] FOREIGN KEY index_name (index_col_name,...) [reference_definition] or ALTER [COLUMN] col_name {SET DEFAULT literal | DROP DEFAULT} or CHANGE [COLUMN] old_col_name create_definition or MODIFY [COLUMN] create_definition or DROP [COLUMN] col_name or DROP PRIMARY KEY or DROP INDEX index_name or RENAME [TO] new_tbl_name or ORDER BY col or table_options
ALTER TABLE
allows you to change the structure of an existing table.
For example, you can add or delete columns, create or destroy indexes, change
the type of existing columns, or rename columns or the table itself. You can
also change the comment for the table and type of the table.
See section 7.7 CREATE TABLE
Syntax.
If you use ALTER TABLE
to change a column specification but
DESCRIBE tbl_name
indicates that your column was not changed, it is
possible that MySQL ignored your modification for one of the reasons
described in section 7.7.1 Silent Column Specification Changes. For example, if you try to change
a VARCHAR
column to CHAR
, MySQL will still use
VARCHAR
if the table contains other variable-length columns.
ALTER TABLE
works by making a temporary copy of the original table.
The alteration is performed on the copy, then the original table is
deleted and the new one is renamed. This is done in such a way that
all updates are automatically redirected to the new table without
any failed updates. While ALTER TABLE
is executing, the original
table is readable by other clients. Updates and writes to the table
are stalled until the new table is ready:
ALTER TABLE
, you need select, insert,
delete, update, create, and drop
privileges on the table.
IGNORE
is a MySQL extension to ANSI SQL92.
It controls how ALTER TABLE
works if there are duplicates on
unique keys in the new table.
If IGNORE
isn't specified, the copy is aborted and rolled back.
If IGNORE
is specified, then for rows with duplicates on a unique
key, only the first row is used; the others are deleted.
ADD
, ALTER
, DROP
, and
CHANGE
clauses in a single ALTER TABLE
statement. This is a
MySQL extension to ANSI SQL92, which allows only one of each clause
per ALTER TABLE
statement.
CHANGE col_name
, DROP col_name
, and DROP
INDEX
are MySQL extensions to ANSI SQL92.
MODIFY
is an Oracle extension to ALTER TABLE
.
TRUNCATE
is an Oracle extension. See section 7.18 TRUNCATE
Syntax.
COLUMN
is a pure noise word and can be omitted.
ALTER TABLE tbl_name RENAME TO new_name
without any other
options, MySQL simply renames the files that correspond to the table
tbl_name
. There is no need to create the temporary table.
See section 7.9 RENAME TABLE
Syntax.
create_definition
clauses use the same syntax for ADD
and
CHANGE
as for CREATE TABLE
. Note that this syntax includes
the column name, not just the column type.
See section 7.7 CREATE TABLE
Syntax.
CHANGE old_col_name create_definition
clause. To do so, specify the old and new column names and the type that
the column currently has. For example, to rename an INTEGER
column
from a
to b
, you can do this:
mysql> ALTER TABLE t1 CHANGE a b INTEGER;If you want to change a column's type but not the name,
CHANGE
syntax still requires two column names even if they are the same. For
example:
mysql> ALTER TABLE t1 CHANGE b b BIGINT NOT NULL;However, as of MySQL Version 3.22.16a, you can also use
MODIFY
to change a column's type without renaming it:
mysql> ALTER TABLE t1 MODIFY b BIGINT NOT NULL;
CHANGE
or MODIFY
to shorten a column for which
an index exists on part of the column (for instance, if you have an index
on the first 10 characters of a VARCHAR
column), you cannot make
the column shorter than the number of characters that are indexed.
CHANGE
or MODIFY
,
MySQL tries to convert data to the new type as well as possible.
FIRST
or
ADD ... AFTER col_name
to add a column at a specific position within
a table row. The default is to add the column last.
ALTER COLUMN
specifies a new default value for a column
or removes the old default value.
If the old default is removed and the column can be NULL
, the new
default is NULL
. If the column cannot be NULL
, MySQL
assigns a default value.
Default value assignment is described in
section 7.7 CREATE TABLE
Syntax.
DROP INDEX
removes an index. This is a MySQL extension to
ANSI SQL92.
DROP PRIMARY KEY
drops the primary index. If no such
index exists, it drops the first UNIQUE
index in the table.
(MySQL marks the first UNIQUE
key as the PRIMARY KEY
if no PRIMARY KEY
was specified explicitly.)
ORDER BY
allows you to create the new table with the rows in a
specific order. Note that the table will not remain in this order after
inserts and deletes. In some cases, it may make sorting easier for
MySQL if the table is in order by the column that you wish to
order it by later. This option is mainly useful when you know that you
are mostly going to query the rows in a certain order; By using this
option after big changes to the table, you may be able to get higher
performance.
ALTER TABLE
on a MyISAM
table, all non-unique
indexes are created in a separate batch (like in REPAIR
).
This should make ALTER TABLE
much faster when you have many indexes.
mysql_info()
, you can find out how many
records were copied, and (when IGNORE
is used) how many records were
deleted due to duplication of unique key values.
FOREIGN KEY
, CHECK
, and REFERENCES
clauses don't
actually do anything. The syntax for them is provided only for compatibility,
to make it easier to port code from other SQL servers and to run applications
that create tables with references.
See section 5.4 Functionality Missing from MySQL.
Here is an example that shows some of the uses of ALTER TABLE
. We
begin with a table t1
that is created as shown below:
mysql> CREATE TABLE t1 (a INTEGER,b CHAR(10));
To rename the table from t1
to t2
:
mysql> ALTER TABLE t1 RENAME t2;
To change column a
from INTEGER
to TINYINT NOT NULL
(leaving the name the same), and to change column b
from
CHAR(10)
to CHAR(20)
as well as renaming it from b
to
c
:
mysql> ALTER TABLE t2 MODIFY a TINYINT NOT NULL, CHANGE b c CHAR(20);
To add a new TIMESTAMP
column named d
:
mysql> ALTER TABLE t2 ADD d TIMESTAMP;
To add an index on column d
, and make column a
the primary key:
mysql> ALTER TABLE t2 ADD INDEX (d), ADD PRIMARY KEY (a);
To remove column c
:
mysql> ALTER TABLE t2 DROP COLUMN c;
To add a new AUTO_INCREMENT
integer column named c
:
mysql> ALTER TABLE t2 ADD c INT UNSIGNED NOT NULL AUTO_INCREMENT, ADD INDEX (c);
Note that we indexed c
, because AUTO_INCREMENT
columns must be
indexed, and also that we declare c
as NOT NULL
, because
indexed columns cannot be NULL
.
When you add an AUTO_INCREMENT
column, column values are filled in
with sequence numbers for you automatically. You can set the first
sequence number by executing SET INSERT_ID=#
before
ALTER TABLE
or using the AUTO_INCREMENT = #
table option.
See section 7.33 SET
Syntax.
See section 20.21 Problems with ALTER TABLE
..
RENAME TABLE
SyntaxRENAME TABLE tbl_name TO new_table_name[, tbl_name2 TO new_table_name2,...]
The rename is done atomically, which means that no other thread can access any of the tables while the rename is running. This makes it possible to replace a table with an empty one:
CREATE TABLE new_table (...); RENAME TABLE old_table TO backup_table, new_table TO old_table;
The rename is done from left to right, which means that if you want to swap two tables names, you have to:
RENAME TABLE old_table TO backup_table, new_table TO old_table, backup_table TO new_table;
As long as two databases are on the same disk you can also rename from one database to another:
RENAME TABLE current_database.table_name TO other_database.table_name;
When you execute RENAME
, you can't have any locked tables or
active transactions. You must also have the ALTER
and DROP
privilege on the original table and CREATE
and INSERT
privilege on the new table.
If MySQL encounters any errors in a multiple table rename, it will do a reverse rename for all renamed tables to get everything back to the original state.
DROP TABLE
SyntaxDROP TABLE [IF EXISTS] tbl_name [, tbl_name,...] [RESTRICT | CASCADE]
DROP TABLE
removes one or more tables. All table data and the table
definition are removed, so be careful with this command!
In MySQL Version 3.22 or later, you can use the keywords
IF EXISTS
to prevent an error from occurring for tables that don't
exist.
RESTRICT
and CASCADE
are allowed to make porting easier.
For the moment they don't do anything.
NOTE: DROP TABLE
is not transaction safe and will
automaticly commit any active transactions.
OPTIMIZE TABLE
SyntaxOPTIMIZE TABLE tbl_name[,tbl_name]...
OPTIMIZE TABLE
should be used if you have deleted a large part of a
table or if you have made many changes to a table with variable-length rows
(tables that have VARCHAR
, BLOB
, or TEXT
columns).
Deleted records are maintained in a linked list and subsequent INSERT
operations reuse old record positions. You can use OPTIMIZE TABLE
to
reclaim the unused space and to defragment the data file.
For the moment OPTIMIZE TABLE
only works on MyISAM and
BDB
tables. For BDB
tables, OPTIMIZE TABLE
is
currently mapped to ANALYZE TABLE
. See section 7.15 ANALYZE TABLE
Syntax.
You can get optimize table to work on other table types by starting
mysqld
with --skip-new
or --safe-mode
, but in this
case OPTIMIZE TABLE
is just mapped to ALTER TABLE
.
OPTIMIZE TABLE
works the following way:
OPTIMIZE TABLE
for MyISAM
tables is equvialent of running
myisamchk --quick --check-changed-tables --sort-index --analyze
on the table.
Note that the table is locked during the time OPTIMIZE TABLE
is
running!
CHECK TABLE
SyntaxCHECK TABLE tbl_name[,tbl_name...] [option [option...]] option = QUICK | FAST | MEDIUM | EXTEND | CHANGED
CHECK TABLE
only works on MyISAM
tables. On
MyISAM
tables it's the same thing as running myisamchk -m
table_name
on the table.
If you don't specify any option MEDIUM
is used.
Checks the table(s) for errors. For MyISAM
tables the key statistics
is updated. The command returns a table with the following columns:
Column | Value |
Table | Table name. |
Op | Always ``check''. |
Msg_type | One of status , error , info , or warning .
|
Msg_text | The message. |
Note that you can get many rows of information for each checked
table. The last row will be of Msg_type status
and should
normally be OK
. If you don't get OK
, or Not
checked
you should normally run a repair of the table. See section 15.1 Using myisamchk
for Table Maintenance and Crash Recovery. Not checked
means that the table the given TYPE
told MySQL that there wasn't any need to check the table.
The different check types stand for the following:
Type | Meaning |
QUICK | Don't scan the rows to check for wrong links. |
FAST | Only check tables which haven't been closed properly. |
CHANGED | Only check tables which have been changed since last check or haven't been closed properly. |
MEDIUM | Scan rows to verify that deleted links are ok. This also calculates a key checksum for the rows and verifies this with a calcualted checksum for the keys. |
EXTENDED | Do a full key lookup for all keys for each row. This ensures that the table is 100 % consistent, but will take a long time! |
For dynamic sized MyISAM
tables a started check will always
do a MEDIUM
check. For static size rows we skip the row scan
for QUICK
and FAST
as the rows are very seldom corrupted.
You can combine check options as in:
CHECK TABLE test_table FAST QUICK;
Which only would do a quick check on the table if it wasn't closed properly.
NOTE: that in some case CHECK TABLE
will change the
table! This happens if the table is marked as 'corrupted' or 'not
closed properly' but CHECK TABLE
didn't find any problems in the
table. In this case CHECK TABLE
will mark the table as ok.
If a table is corrupted, then it's most likely that the problem is in the indexes and not in the data part. All of the above check types checks the indexes throughly and should thus find most errors.
If you just want to check a table that you assume is ok, you should use
no check options or the QUICK
option. The later should be used
when you are in a hurry and can take the very small risk that
QUICK
didn't find an error in the data file (In most cases
MySQL should find, under normal usage, any error in the data
file. If this happens then the table will be marked as 'corrupted',
in which case the table can't be used until it's repaired).
FAST
and CHANGED
are mostly intended to be used from a
script (for example to be executed from cron) if you want to check your
table from time to time. In most cases you FAST
is to be prefered
over CHANGED
. (The only case when it isn't is when you suspect a
bug you have found a bug in the MyISAM
code.).
EXTENDED
is only to be used after you have run a normal check but
still get strange errors from a table when MySQL tries to
update a row or find a row by key (this is VERY unlikely to happen if a
normal check has succeeded!).
BACKUP TABLE
SyntaxBACKUP TABLE tbl_name[,tbl_name...] TO '/path/to/backup/directory'
Make a copy of all the table files to the backup directory that are the
minimum needed to restore it. Currenlty only works for MyISAM
tables. For MyISAM
table, copies .frm
(definition) and
.MYD
(data) files. The index file can be rebuilt from those two.
During the backup, read lock will be held for each table, one at time,
as they are being backed up. If you want to backup several tables as
a snapshot, you must first issue LOCK TABLES
obtaining a read
lock for each table in the group.
The command returns a table with the following columns:
Column | Value |
Table | Table name |
Op | Always ``backup'' |
Msg_type | One of status , error , info or warning .
|
Msg_text | The message. |
Note that BACKUP TABLE
is only available in MySQL
version 3.23.25 and later.
RESTORE TABLE
SyntaxRESTORE TABLE tbl_name[,tbl_name...] FROM '/path/to/backup/directory'
Restores the table(s) from the backup that was made with
BACKUP TABLE
. Existing tables will not be overwritten - if you
try to restore over an existing table, you will get an error. Restore
will take longer than BACKUP due to the need to rebuilt the index. The
more keys you have, the longer it is going to take. Just as
BACKUP TABLE
, currently only works of MyISAM
tables.
The command returns a table with the following columns:
Column | Value |
Table | Table name |
Op | Always ``restore'' |
Msg_type | One of status , error , info or warning .
|
Msg_text | The message. |
ANALYZE TABLE
SyntaxANALYZE TABLE tbl_name[,tbl_name...]
Analyze and store the key distribution for the table. During the
analyze the table is locked with a read lock. This works on
MyISAM
and BDB
tables.
This is equivalent to running myisamchk -a
on the table.
MySQL uses the stored key distribution to decide in which order tables should be joined when one does a join on something else than a constant.
The command returns a table with the following columns:
Column | Value |
Table | Table name |
Op | Always ``analyze'' |
Msg_type | One of status , error , info or warning .
|
Msg_text | The message. |
You can check the stored key distribution with the SHOW INDEX
command.
See section 7.28.1 SHOW Information About Databases, Tables, Columns, and Indexes.
If the table hasn't changed since the last ANALYZE TABLE
command,
the table will not be analyzed again.
REPAIR TABLE
SyntaxREPAIR TABLE tbl_name[,tbl_name...] [QUICK] [EXTENDED]
REPAIR TABLE
only works on MyISAM
tables and is the same
as running myisamchk -r table_name
on the table.
Repair the corrupted table. The command returns a table with the following columns:
Column | Value |
Table | Table name |
Op | Always ``repair'' |
Msg_type | One of status , error , info or warning .
|
Msg_text | The message. |
Note that you can get many rows of information for each repaired
table. The last one row will be of Msg_type status
and should
normally be OK
. If you don't get OK
, you should try
repairing the table with myisamchk -o
, as REPAIR TABLE
does not yet implement all the options of myisamchk
. In the near
future, we will make it more flexible.
If QUICK
is given then MySQL will try to do a
REPAIR
of only the index tree.
If you use EXTENDED
then MySQL will create the index row
by row instead of creating one index at a time with sorting; This may be
better than sorting on fixed-length keys if you have long char()
keys that compress very good.
DELETE
SyntaxDELETE [LOW_PRIORITY] FROM tbl_name [WHERE where_definition] [LIMIT rows]
DELETE
deletes rows from tbl_name
that satisfy the condition
given by where_definition
, and returns the number of records deleted.
If you issue a DELETE
with no WHERE
clause, all rows are
deleted. If you do this in AUTOCOMMIT
mode, this works as
TRUNCATE
. See section 7.18 TRUNCATE
Syntax. One problem with this is that
DELETE
will return zero as the number of affected records, but
this will be fixed in 4.0.
If you really want to know how many records are deleted when you are deleting
all rows, and are willing to suffer a speed penalty, you can use a
DELETE
statement of this form:
mysql> DELETE FROM tbl_name WHERE 1>0;
Note that this is MUCH slower than DELETE FROM tbl_name
with no
WHERE
clause, because it deletes rows one at a time.
If you specify the keyword LOW_PRIORITY
, execution of the
DELETE
is delayed until no other clients are reading from the table.
Deleted records are maintained in a linked list and subsequent INSERT
operations reuse old record positions. To reclaim unused space and reduce
file sizes, use the OPTIMIZE TABLE
statement or the myisamchk
utility to reorganize tables. OPTIMIZE TABLE
is easier, but
myisamchk
is faster.
See section 7.11 OPTIMIZE TABLE
Syntax and section 15.4.3 Table Optimization.
The MySQL-specific LIMIT rows
option to DELETE
tells
the server the maximum number of rows to be deleted before control is
returned to the client. This can be used to ensure that a specific
DELETE
command doesn't take too much time. You can simply repeat
the DELETE
command until the number of affected rows is less than
the LIMIT
value.
TRUNCATE
SyntaxTRUNCATE TABLE table_name
Is in 3.23 and the same thing as DELETE FROM table_name
. See section 7.17 DELETE
Syntax.
The differences are:
TRUNCATE TABLE
will automaticly end the current
transaction as if COMMIT
would have been called.
SELECT
SyntaxSELECT [STRAIGHT_JOIN] [SQL_SMALL_RESULT] [SQL_BIG_RESULT] [SQL_BUFFER_RESULT] [HIGH_PRIORITY] [DISTINCT | DISTINCTROW | ALL] select_expression,... [INTO {OUTFILE | DUMPFILE} 'file_name' export_options] [FROM table_references [WHERE where_definition] [GROUP BY {unsigned_integer | col_name | formula} [ASC | DESC], ...] [HAVING where_definition] [ORDER BY {unsigned_integer | col_name | formula} [ASC | DESC] ,...] [LIMIT [offset,] rows] [PROCEDURE procedure_name] ]
SELECT
is used to retrieve rows selected from one or more tables.
select_expression
indicates the columns you want to retrieve.
SELECT
may also be used to retrieve rows computed without reference to
any table. For example:
mysql> SELECT 1 + 1; -> 2
All keywords used must be given in exactly the order shown above. For example,
a HAVING
clause must come after any GROUP BY
clause and before
any ORDER BY
clause.
SELECT
expression may be given an alias using AS
. The alias
is used as the expression's column name and can be used with
ORDER BY
or HAVING
clauses. For example:
mysql> select concat(last_name,', ',first_name) AS full_name from mytable ORDER BY full_name;
FROM table_references
clause indicates the tables from which to
retrieve rows. If you name more than one table, you are performing a
join. For information on join syntax, see section 7.20 JOIN
Syntax.
col_name
, tbl_name.col_name
, or
db_name.tbl_name.col_name
. You need not specify a tbl_name
or
db_name.tbl_name
prefix for a column reference in a SELECT
statement unless the reference would be ambiguous. See section 7.1.5 Database, Table, Index, Column, and Alias Names,
for examples of ambiguity that require the more explicit column reference
forms.
tbl_name [AS] alias_name
:
mysql> select t1.name, t2.salary from employee AS t1, info AS t2 where t1.name = t2.name; mysql> select t1.name, t2.salary from employee t1, info t2 where t1.name = t2.name;
ORDER BY
and
GROUP BY
clauses using column names, column aliases, or column
positions. Column positions begin with 1:
mysql> select college, region, seed from tournament ORDER BY region, seed; mysql> select college, region AS r, seed AS s from tournament ORDER BY r, s; mysql> select college, region, seed from tournament ORDER BY 2, 3;To sort in reverse order, add the
DESC
(descending) keyword to the
name of the column in the ORDER BY
clause that you are sorting by.
The default is ascending order; this may be specified explicitly using
the ASC
keyword.
WHERE
clause use any of the functions that
MySQL support. See section 7.4 Functions for Use in SELECT
and WHERE
Clauses.
HAVING
clause can refer to any column or alias named in the
select_expression
. It is applied last, just before items are sent to
the client, with no optimization. Don't use HAVING
for items that
should be in the WHERE
clause. For example, do not write this:
mysql> select col_name from tbl_name HAVING col_name > 0;Write this instead:
mysql> select col_name from tbl_name WHERE col_name > 0;In MySQL Version 3.22.5 or later, you can also write queries like this:
mysql> select user,max(salary) from users group by user HAVING max(salary)>10;In older MySQL versions, you can write this instead:
mysql> select user,max(salary) AS sum from users group by user HAVING sum>10;
SQL_SMALL_RESULT
, SQL_BIG_RESULT
, SQL_BUFFER_RESULT
,
STRAIGHT_JOIN
, and HIGH_PRIORITY
are MySQL extensions
to ANSI SQL92.
HIGH_PRIORITY
will give the SELECT
higher priority than
a statement that updates a table. You should only use this for queries
that are very fast and must be done at once. A SELECT HIGH_PRIORITY
query will run if the table is locked for read even if there is an update
statement that is waiting for the table to be free.
SQL_BIG_RESULT
can be used with GROUP BY
or DISTINCT
to tell the optimizer that the result set will have many rows. In this case,
MySQL will directly use disk-based temporary tables if needed.
MySQL will also, in this case, prefer sorting to doing a
temporary table with a key on the GROUP BY
elements.
GROUP BY
, the output rows will be sorted according to the
GROUP BY
as if you would have had an ORDER BY
over all the fields
in the GROUP BY
. MySQL has extended the GROUP BY
so that
you can also specify ASC
and DESC
to GROUP BY
:
SELECT a,COUNT(b) FROM test_table GROUP BY a DESC
SQL_BUFFER_RESULT
will force the result to be put into a temporary
table. This will help MySQL free the table locks early and will help
in cases where it takes a long time to send the result set to the client.
SQL_SMALL_RESULT
, a MySQL-specific option, can be used
with GROUP BY
or DISTINCT
to tell the optimizer that the
result set will be small. In this case, MySQL will use fast
temporary tables to store the resulting table instead of using sorting. In
MySQL Version 3.23 this shouldn't normally be needed.
STRAIGHT_JOIN
forces the optimizer to join the tables in the order in
which they are listed in the FROM
clause. You can use this to speed up
a query if the optimizer joins the tables in non-optimal order.
See section 7.29 EXPLAIN
Syntax (Get Information About a SELECT
).
LIMIT
clause can be used to constrain the number of rows returned
by the SELECT
statement. LIMIT
takes one or two numeric
arguments.
If two arguments are given, the first specifies the offset of the first row to
return, the second specifies the maximum number of rows to return.
The offset of the initial row is 0 (not 1):
mysql> select * from table LIMIT 5,10; # Retrieve rows 6-15If one argument is given, it indicates the maximum number of rows to return:
mysql> select * from table LIMIT 5; # Retrieve first 5 rowsIn other words,
LIMIT n
is equivalent to LIMIT 0,n
.
SELECT ... INTO OUTFILE 'file_name'
form of SELECT
writes
the selected rows to a file. The file is created on the server host and
cannot already exist (among other things, this prevents database tables and
files such as `/etc/passwd' from being destroyed). You must have the
file privilege on the server host to use this form of SELECT
.
SELECT ... INTO OUTFILE
is mainly intended to let you very
quickly dump a table on the server machine. If you want to create the
resulting file on some other host than the server host you can't use
SELECT ... INTO OUTFILE
. In this case you should instead use some
client program like mysqldump --tab
or mysql -e "SELECT
..." > outfile
to generate the file.
SELECT ... INTO OUTFILE
is the complement of LOAD DATA
INFILE
; the syntax for the export_options
part of the statement
consists of the same FIELDS
and LINES
clauses that are used
with the LOAD DATA INFILE
statement.
See section 7.23 LOAD DATA INFILE
Syntax.
In the resulting text file, only the following characters are escaped by
the ESCAPED BY
character:
ESCAPED BY
character
FIELDS TERMINATED BY
LINES TERMINATED BY
ASCII 0
is converted to ESCAPED BY
followed by 0
(ASCII 48
).
The reason for the above is that you MUST escape any FIELDS
TERMINATED BY
, ESCAPED BY
, or LINES TERMINATED BY
characters to reliably be able to read the file back. ASCII 0
is
escaped to make it easier to view with some pagers.
As the resulting file doesn't have to conform to the SQL syntax, nothing
else need be escaped.
Here follows an example of getting a file in the format used by many
old programs.
SELECT a,b,a+b INTO OUTFILE "/tmp/result.text" FIELDS TERMINATED BY ',' OPTIONALLY ENCLOSED BY '"' LINES TERMINATED BY "\n" FROM test_table;
INTO DUMPFILE
instead of INTO OUTFILE
, MySQL
will only write one row into the file, without any column or line
terminations and without any escaping. This is useful if you want to
store a blob in a file.
JOIN
Syntax
MySQL supports the following JOIN
syntaxes for use in
SELECT
statements:
table_reference, table_reference table_reference [CROSS] JOIN table_reference table_reference INNER JOIN table_reference join_condition table_reference STRAIGHT_JOIN table_reference table_reference LEFT [OUTER] JOIN table_reference join_condition table_reference LEFT [OUTER] JOIN table_reference table_reference NATURAL [LEFT [OUTER]] JOIN table_reference { oj table_reference LEFT OUTER JOIN table_reference ON conditional_expr } table_reference RIGHT [OUTER] JOIN table_reference join_condition table_reference RIGHT [OUTER] JOIN table_reference table_reference NATURAL [RIGHT [OUTER]] JOIN table_reference
Where table_reference
is defined as:
table_name [[AS] alias] [USE INDEX (key_list)] [IGNORE INDEX (key_list)]
and join_condition
is defined as:
ON conditional_expr | USING (column_list)
Note that in versions before Version 3.23.16, the INNER JOIN
didn't take
a join condition!
The last LEFT OUTER JOIN
syntax shown above exists only for
compatibility with ODBC:
tbl_name AS alias_name
or
tbl_name alias_name
:
mysql> select t1.name, t2.salary from employee AS t1, info AS t2 where t1.name = t2.name;
INNER JOIN
and ,
(comma) are semantically equivalent.
Both do a full join between the tables used. Normally, you specify how
the tables should be linked in the WHERE
condition.
ON
conditional is any conditional of the form that may be used in
a WHERE
clause.
ON
or
USING
part in a LEFT JOIN
, a row with all columns set to
NULL
is used for the right table. You can use this fact to find
records in a table that have no counterpart in another table:
mysql> select table1.* from table1 LEFT JOIN table2 ON table1.id=table2.id where table2.id is NULL;This example finds all rows in
table1
with an id
value that is
not present in table2
(that is, all rows in table1
with no
corresponding row in table2
). This assumes that table2.id
is
declared NOT NULL
, of course. See section 12.5.5 How MySQL Optimizes LEFT JOIN
and RIGHT JOIN
.
USING
(column_list)
clause names a list of columns that must
exist in both tables. A USING
clause such as:
A LEFT JOIN B USING (C1,C2,C3,...)is defined to be semantically identical to an
ON
expression like
this:
A.C1=B.C1 AND A.C2=B.C2 AND A.C3=B.C3,...
NATURAL [LEFT] JOIN
of two tables is defined to be
semantically equivalent to an INNER JOIN
or a LEFT JOIN
with a USING
clause that names all columns that exist in both
tables.
RIGHT JOIN
works analogously as LEFT JOIN
. To keep code
portable across databases, it's recommended to use LEFT JOIN
instead of RIGHT JOIN
.
STRAIGHT_JOIN
is identical to JOIN
, except that the left table
is always read before the right table. This can be used for those (few)
cases where the join optimizer puts the tables in the wrong order.
EXPLAIN
shows that MySQL is
using the wrong index. By specifying USE INDEX (key_list)
, you
can tell MySQL to use only one of the specified indexes to
find rows in the table. The alternative syntax IGNORE INDEX
(key_list)
can be used to tell MySQL to not use some
particular index.
Some examples:
mysql> select * from table1,table2 where table1.id=table2.id; mysql> select * from table1 LEFT JOIN table2 ON table1.id=table2.id; mysql> select * from table1 LEFT JOIN table2 USING (id); mysql> select * from table1 LEFT JOIN table2 ON table1.id=table2.id LEFT JOIN table3 ON table2.id=table3.id; mysql> select * from table1 USE INDEX (key1,key2) WHERE key1=1 and key2=2 AND key3=3; mysql> select * from table1 IGNORE INDEX (key3) WHERE key1=1 and key2=2 AND key3=3;
See section 12.5.5 How MySQL Optimizes LEFT JOIN
and RIGHT JOIN
.
INSERT
SyntaxINSERT [LOW_PRIORITY | DELAYED] [IGNORE] [INTO] tbl_name [(col_name,...)] VALUES (expression,...),(...),... or INSERT [LOW_PRIORITY | DELAYED] [IGNORE] [INTO] tbl_name [(col_name,...)] SELECT ... or INSERT [LOW_PRIORITY | DELAYED] [IGNORE] [INTO] tbl_name SET col_name=expression, col_name=expression, ...
INSERT
inserts new rows into an existing table. The INSERT ...
VALUES
form of the statement inserts rows based on explicitly specified
values. The INSERT ... SELECT
form inserts rows selected from another
table or tables. The INSERT ... VALUES
form with multiple value lists
is supported in MySQL Version 3.22.5 or later. The
col_name=expression
syntax is supported in MySQL Version 3.22.10 or
later.
tbl_name
is the table into which rows should be inserted. The column
name list or the SET
clause indicates which columns the statement
specifies values for:
INSERT ... VALUES
or INSERT
... SELECT
, values for all columns must be provided in the
VALUES()
list or by the SELECT
. If you don't know the order of
the columns in the table, use DESCRIBE tbl_name
to find out.
CREATE TABLE
Syntax.
expression
may refer to any column that was set earlier in a value
list. For example, you can say this:
mysql> INSERT INTO tbl_name (col1,col2) VALUES(15,col1*2);But not this:
mysql> INSERT INTO tbl_name (col1,col2) VALUES(col2*2,15);
LOW_PRIORITY
, execution of the
INSERT
is delayed until no other clients are reading from the table.
In this case the client has to wait until the insert statement is completed,
which may take a long time if the table is in heavy use. This is in
contrast to INSERT DELAYED
, which lets the client continue at once.
Note that LOW_PRIORITY
should normally not be used with MyISAM
tables as this disables concurrent inserts.See section 8.1 MyISAM Tables.
IGNORE
in an INSERT
with many value
rows, any rows that duplicate an existing PRIMARY
or UNIQUE
key in the table are ignored and are not inserted. If you do not specify
IGNORE
, the insert is aborted if there is any row that duplicates an
existing key value. You can determine with the C API function
mysql_info()
how many rows were inserted into the table.
DONT_USE_DEFAULT_FIELDS
option, INSERT
statements generate an error unless you explicitly
specify values for all columns that require a non-NULL
value.
See section 4.7.3 Typical configure
Options.
AUTO_INCREMENT
column
with the mysql_insert_id
function.
See section 23.4.30 mysql_insert_id()
.
INSERT INTO ... SELECT
statement:
ORDER BY
clause.
INSERT
statement cannot appear in the
FROM
clause of the SELECT
part of the query because it's
forbidden in ANSI SQL to SELECT
from the same table into which you are
inserting. (The problem is that the SELECT
possibly would
find records that were inserted earlier during the same run. When using
sub-select clauses, the situation could easily be very confusing!)
AUTO_INCREMENT
columns work as usual.
If you use INSERT ... SELECT
or an INSERT ... VALUES
statement with multiple value lists, you can use the C API function
mysql_info()
to get information about the query. The format of the
information string is shown below:
Records: 100 Duplicates: 0 Warnings: 0
Duplicates
indicates the number of rows that couldn't be inserted
because they would duplicate some existing unique index value.
Warnings
indicates the number of attempts to insert column values that
were problematic in some way. Warnings can occur under any of the following
conditions:
NULL
into a column that has been declared NOT NULL
.
The column is set to its default value.
'10.34 a'
. The trailing
garbage is stripped and the remaining numeric part is inserted. If the value
doesn't make sense as a number at all, the column is set to 0
.
CHAR
, VARCHAR
, TEXT
, or
BLOB
column that exceeds the column's maximum length. The value is
truncated to the column's maximum length.
The DELAYED
option
for the
INSERT
statement is a MySQL-specific option that is very
useful if you have clients that can't wait for the INSERT
to complete.
This is a common problem when you use MySQL for logging and you also
periodically run SELECT
statements that take a long time to complete.
DELAYED
was introduced in MySQL Version 3.22.15. It is a
MySQL extension to ANSI SQL92.
When you use INSERT DELAYED
, the client will get an OK at once
and the row will be inserted when the table is not in use by any other thread.
Another major benefit of using INSERT DELAYED
is that inserts
from many clients are bundled together and written in one block. This is much
faster than doing many separate inserts.
Note that currently the queued rows are only stored in memory until they are
inserted into the table. This means that if you kill mysqld
the hard way (kill -9
) or if mysqld
dies unexpectedly, any
queued rows that weren't written to disk are lost!
The following describes in detail what happens when you use the
DELAYED
option to INSERT
or REPLACE
. In this
description, the ``thread'' is the thread that received an INSERT
DELAYED
command and ``handler'' is the thread that handles all
INSERT DELAYED
statements for a particular table.
DELAYED
statement for a table, a handler
thread is created to process all DELAYED
statements for the table, if
no such handler already exists.
DELAYED
lock already; if not, it tells the handler thread to do so. The
DELAYED
lock can be obtained even if other threads have a READ
or WRITE
lock on the table. However, the handler will wait for all
ALTER TABLE
locks or FLUSH TABLES
to ensure that the table
structure is up to date.
INSERT
statement, but instead of writing
the row to the table, it puts a copy of the final row into a queue that
is managed by the handler thread. Any syntax errors are noticed by the
thread and reported to the client program.
AUTO_INCREMENT
value for the resulting row; it can't obtain them from the server, because
the INSERT
returns before the insert operation has been completed. If
you use the C API, the mysql_info()
function doesn't return anything
meaningful, for the same reason.
delayed_insert_limit
rows are written, the handler checks
whether or not any SELECT
statements are still pending. If so, it
allows these to execute before continuing.
INSERT DELAYED
commands are received within
delayed_insert_timeout
seconds, the handler terminates.
delayed_queue_size
rows are pending already in a
specific handler queue, the thread requesting INSERT DELAYED
waits until there is room in the queue. This is done to ensure that
the mysqld
server doesn't use all memory for the delayed memory
queue.
delayed_insert
in the Command
column. It will
be killed if you execute a FLUSH TABLES
command or kill it with
KILL thread_id
. However, it will first store all queued rows into the
table before exiting. During this time it will not accept any new
INSERT
commands from another thread. If you execute an INSERT
DELAYED
command after this, a new handler thread will be created.
INSERT DELAYED
commands have higher
priority than normal INSERT
commands if there is an INSERT
DELAYED
handler already running! Other update commands will have to wait
until the INSERT DELAYED
queue is empty, someone kills the handler
thread (with KILL thread_id
), or someone executes FLUSH TABLES
.
INSERT
DELAYED
commands:
Variable | Meaning |
Delayed_insert_threads | Number of handler threads |
Delayed_writes | Number of rows written with INSERT DELAYED
|
Not_flushed_delayed_rows | Number of rows waiting to be written |
SHOW STATUS
statement or
by executing a mysqladmin extended-status
command.
Note that INSERT DELAYED
is slower than a normal INSERT if the
table is not in use. There is also the additional overhead for the
server to handle a separate thread for each table on which you use
INSERT DELAYED
. This means that you should only use INSERT
DELAYED
when you are really sure you need it!
REPLACE
SyntaxREPLACE [LOW_PRIORITY | DELAYED] [INTO] tbl_name [(col_name,...)] VALUES (expression,...) or REPLACE [LOW_PRIORITY | DELAYED] [INTO] tbl_name [(col_name,...)] SELECT ... or REPLACE [LOW_PRIORITY | DELAYED] [INTO] tbl_name SET col_name=expression, col_name=expression,...
REPLACE
works exactly like INSERT
, except that if an old
record in the table has the same value as a new record on a unique index,
the old record is deleted before the new record is inserted.
See section 7.21 INSERT
Syntax.
In other words, you can't access the values of the old row from a
REPLACE
statement. In some old MySQL version it looked
like you could do this, but that was a bug that has been corrected.
LOAD DATA INFILE
SyntaxLOAD DATA [LOW_PRIORITY] [LOCAL] INFILE 'file_name.txt' [REPLACE | IGNORE] INTO TABLE tbl_name [FIELDS [TERMINATED BY '\t'] [[OPTIONALLY] ENCLOSED BY ''] [ESCAPED BY '\\' ] ] [LINES TERMINATED BY '\n'] [IGNORE number LINES] [(col_name,...)]
The LOAD DATA INFILE
statement reads rows from a text file into a
table at a very high speed. If the LOCAL
keyword is specified, the
file is read from the client host. If LOCAL
is not specified, the
file must be located on the server. (LOCAL
is available in
MySQL Version 3.22.6 or later.)
For security reasons, when reading text files located on the server, the
files must either reside in the database directory or be readable by all.
Also, to use LOAD DATA INFILE
on server files, you must have the
file privilege on the server host.
See section 6.8 Privileges Provided by MySQL.
If you specify the keyword LOW_PRIORITY
, execution of the
LOAD DATA
statement is delayed until no other clients are reading
from the table.
Using LOCAL
will be a bit slower than letting the server access the
files directly, because the contents of the file must travel from the client
host to the server host. On the other hand, you do not need the
file privilege to load local files.
If you are using MySQL before Version 3.23.24 you can't read from a
FIFO with LOAD DATA INFILE
. If you need to read from a FIFO (for
example the output from gunzip), use LOAD DATA LOCAL INFILE
instead.
You can also load data files by using the mysqlimport
utility; it
operates by sending a LOAD DATA INFILE
command to the server. The
--local
option causes mysqlimport
to read data files from the
client host. You can specify the --compress
option to get better
performance over slow networks if the client and server support the
compressed protocol.
When locating files on the server host, the server uses the following rules:
Note that these rules mean a file given as `./myfile.txt' is read from
the server's data directory, whereas a file given as `myfile.txt' is
read from the database directory of the current database. For example,
the following LOAD DATA
statement reads the file `data.txt'
from the database directory for db1
because db1
is the current
database, even though the statement explicitly loads the file into a
table in the db2
database:
mysql> USE db1; mysql> LOAD DATA INFILE "data.txt" INTO TABLE db2.my_table;
The REPLACE
and IGNORE
keywords control handling of input
records that duplicate existing records on unique key values. If you specify
REPLACE
, new rows replace existing rows that have the same unique key
value. If you specify IGNORE
, input rows that duplicate an existing
row on a unique key value are skipped. If you don't specify either option, an
error occurs when a duplicate key value is found, and the rest of the text
file is ignored.
If you load data from a local file using the LOCAL
keyword, the server
has no way to stop transmission of the file in the middle of the operation,
so the default bahavior is the same as if IGNORE
is specified.
If you use LOAD DATA INFILE
on an empty MyISAM
table,
all non-unique indexes are created in a separate batch (like in REPAIR
).
This normally makes LOAD DATA INFILE
much faster when you have many
indexes.
LOAD DATA INFILE
is the complement of SELECT ... INTO OUTFILE
.
See section 7.19 SELECT
Syntax.
To write data from a database to a file, use SELECT ... INTO OUTFILE
.
To read the file back into the database, use LOAD DATA INFILE
.
The syntax of the FIELDS
and LINES
clauses is the same for
both commands. Both clauses are optional, but FIELDS
must precede LINES
if both are specified.
If you specify a FIELDS
clause,
each of its subclauses (TERMINATED BY
, [OPTIONALLY] ENCLOSED
BY
, and ESCAPED BY
) is also optional, except that you must
specify at least one of them.
If you don't specify a FIELDS
clause, the defaults are the
same as if you had written this:
FIELDS TERMINATED BY '\t' ENCLOSED BY '' ESCAPED BY '\\'
If you don't specify a LINES
clause, the default
is the same as if you had written this:
LINES TERMINATED BY '\n'
In other words, the defaults cause LOAD DATA INFILE
to act as follows
when reading input:
Conversely, the defaults cause SELECT ... INTO OUTFILE
to act as
follows when writing output:
Note that to write FIELDS ESCAPED BY '\\'
, you must specify two
backslashes for the value to be read as a single backslash.
The IGNORE number LINES
option can be used to ignore a header of
column names at the start of the file:
mysql> LOAD DATA INFILE "/tmp/file_name" into table test IGNORE 1 LINES;
When you use SELECT ... INTO OUTFILE
in tandem with LOAD
DATA INFILE
to write data from a database into a file and then read
the file back into the database later, the field and line handling
options for both commands must match. Otherwise, LOAD DATA
INFILE
will not interpret the contents of the file properly. Suppose
you use SELECT ... INTO OUTFILE
to write a file with
fields delimited by commas:
mysql> SELECT * INTO OUTFILE 'data.txt' FIELDS TERMINATED BY ',' FROM ...
To read the comma-delimited file back in, the correct statement would be:
mysql> LOAD DATA INFILE 'data.txt' INTO TABLE table2 FIELDS TERMINATED BY ',';
If instead you tried to read in the file with the statement shown below, it
wouldn't work because it instructs LOAD DATA INFILE
to look for
tabs between fields:
mysql> LOAD DATA INFILE 'data.txt' INTO TABLE table2 FIELDS TERMINATED BY '\t';
The likely result is that each input line would be interpreted as a single field.
LOAD DATA INFILE
can be used to read files obtained from
external sources, too. For example, a file in dBASE format will have
fields separated by commas and enclosed in double quotes. If lines in
the file are terminated by newlines, the command shown below
illustrates the field and line handling options you would use to load
the file:
mysql> LOAD DATA INFILE 'data.txt' INTO TABLE tbl_name FIELDS TERMINATED BY ',' ENCLOSED BY '"' LINES TERMINATED BY '\n';
Any of the field or line handling options may specify an empty string
(''
). If not empty, the FIELDS [OPTIONALLY] ENCLOSED BY
and FIELDS ESCAPED BY
values must be a single character. The
FIELDS TERMINATED BY
and LINES TERMINATED BY
values may
be more than one character. For example, to write lines that are
terminated by carriage return-linefeed pairs, or to read a file
containing such lines, specify a LINES TERMINATED BY '\r\n'
clause.
FIELDS [OPTIONALLY] ENCLOSED BY
controls quoting of fields. For
output (SELECT ... INTO OUTFILE
), if you omit the word
OPTIONALLY
, all fields are enclosed by the ENCLOSED BY
character. An example of such output (using a comma as the field
delimiter) is shown below:
"1","a string","100.20" "2","a string containing a , comma","102.20" "3","a string containing a \" quote","102.20" "4","a string containing a \", quote and comma","102.20"
If you specify OPTIONALLY
, the ENCLOSED BY
character is
used only to enclose CHAR
and VARCHAR
fields:
1,"a string",100.20 2,"a string containing a , comma",102.20 3,"a string containing a \" quote",102.20 4,"a string containing a \", quote and comma",102.20
Note that occurrences of the ENCLOSED BY
character within a
field value are escaped by prefixing them with the ESCAPED BY
character. Also note that if you specify an empty ESCAPED BY
value, it is possible to generate output that cannot be read properly by
LOAD DATA INFILE
. For example, the output just shown above would
appear as shown below if the escape character is empty. Observe that the
second field in the fourth line contains a comma following the quote, which
(erroneously) appears to terminate the field:
1,"a string",100.20 2,"a string containing a , comma",102.20 3,"a string containing a " quote",102.20 4,"a string containing a ", quote and comma",102.20
For input, the ENCLOSED BY
character, if present, is stripped from the
ends of field values. (This is true whether or not OPTIONALLY
is
specified; OPTIONALLY
has no effect on input interpretation.)
Occurrences of the ENCLOSED BY
character preceded by the
ESCAPED BY
character are interpreted as part of the current field
value. In addition, duplicated ENCLOSED BY
characters occurring
within fields are interpreted as single ENCLOSED BY
characters if the
field itself starts with that character. For example, if ENCLOSED BY
'"'
is specified, quotes are handled as shown below:
"The ""BIG"" boss" -> The "BIG" boss The "BIG" boss -> The "BIG" boss The ""BIG"" boss -> The ""BIG"" boss
FIELDS ESCAPED BY
controls how to write or read special characters.
If the FIELDS ESCAPED BY
character is not empty, it is used to prefix
the following characters on output:
FIELDS ESCAPED BY
character
FIELDS [OPTIONALLY] ENCLOSED BY
character
FIELDS TERMINATED BY
and
LINES TERMINATED BY
values
0
(what is actually written following the escape character is
ASCII '0'
, not a zero-valued byte)
If the FIELDS ESCAPED BY
character is empty, no characters are escaped.
It is probably not a good idea to specify an empty escape character,
particularly if field values in your data contain any of the characters in
the list just given.
For input, if the FIELDS ESCAPED BY
character is not empty, occurrences
of that character are stripped and the following character is taken literally
as part of a field value. The exceptions are an escaped `0' or
`N' (for example, \0
or \N
if the escape character is
`\'). These sequences are interpreted as ASCII 0
(a zero-valued
byte) and NULL
. See below for the rules on NULL
handling.
For more information about `\'-escape syntax, see section 7.1 Literals: How to Write Strings and Numbers.
In certain cases, field and line handling options interact:
LINES TERMINATED BY
is an empty string and FIELDS
TERMINATED BY
is non-empty, lines are also terminated with
FIELDS TERMINATED BY
.
FIELDS TERMINATED BY
and FIELDS ENCLOSED BY
values are
both empty (''
), a fixed-row (non-delimited) format is used. With
fixed-row format, no delimiters are used between fields. Instead, column
values are written and read using the ``display'' widths of the columns. For
example, if a column is declared as INT(7)
, values for the column are
written using 7-character fields. On input, values for the column are
obtained by reading 7 characters. Fixed-row format also affects handling of
NULL
values; see below. Note that fixed-size format will not work
if you are using a multi-byte character set.
Handling of NULL
values varies, depending on the FIELDS
and
LINES
options you use:
FIELDS
and LINES
values,
NULL
is written as \N
for output and \N
is read
as NULL
for input (assuming the ESCAPED BY
character
is `\').
FIELDS ENCLOSED BY
is not empty, a field containing the literal
word NULL
as its value is read as a NULL
value (this differs
from the word NULL
enclosed within FIELDS ENCLOSED BY
characters, which is read as the string 'NULL'
).
FIELDS ESCAPED BY
is empty, NULL
is written as the word
NULL
.
FIELDS TERMINATED BY
and
FIELDS ENCLOSED BY
are both empty), NULL
is written as an empty
string. Note that this causes both NULL
values and empty strings in
the table to be indistinguishable when written to the file because they are
both written as empty strings. If you need to be able to tell the two apart
when reading the file back in, you should not use fixed-row format.
Some cases are not supported by LOAD DATA INFILE
:
FIELDS TERMINATED BY
and FIELDS ENCLOSED
BY
both empty) and BLOB
or TEXT
columns.
LOAD DATA INFILE
won't be able to interpret the input properly.
For example, the following FIELDS
clause would cause problems:
FIELDS TERMINATED BY '"' ENCLOSED BY '"'
FIELDS ESCAPED BY
is empty, a field value that contains an occurrence
of FIELDS ENCLOSED BY
or LINES TERMINATED BY
followed by the FIELDS TERMINATED BY
value will cause LOAD
DATA INFILE
to stop reading a field or line too early.
This happens because LOAD DATA INFILE
cannot properly determine
where the field or line value ends.
The following example loads all columns of the persondata
table:
mysql> LOAD DATA INFILE 'persondata.txt' INTO TABLE persondata;
No field list is specified, so LOAD DATA INFILE
expects input rows
to contain a field for each table column. The default FIELDS
and
LINES
values are used.
If you wish to load only some of a table's columns, specify a field list:
mysql> LOAD DATA INFILE 'persondata.txt' INTO TABLE persondata (col1,col2,...);
You must also specify a field list if the order of the fields in the input file differs from the order of the columns in the table. Otherwise, MySQL cannot tell how to match up input fields with table columns.
If a row has too few fields, the columns for which no input field is present
are set to default values. Default value assignment is described in
section 7.7 CREATE TABLE
Syntax.
An empty field value is interpreted differently than if the field value is missing:
0
.
TIMESTAMP
columns are only set to the current date and time if there
is a NULL
value for the column, or (for the first TIMESTAMP
column only) if the TIMESTAMP
column is left out from the field list
when a field list is specified.
If an input row has too many fields, the extra fields are ignored and the number of warnings is incremented.
LOAD DATA INFILE
regards all input as strings, so you can't use
numeric values for ENUM
or SET
columns the way you can with
INSERT
statements. All ENUM
and SET
values must be
specified as strings!
If you are using the C API, you can get information about the query by
calling the API function mysql_info()
when the LOAD DATA INFILE
query finishes. The format of the information string is shown below:
Records: 1 Deleted: 0 Skipped: 0 Warnings: 0
Warnings occur under the same circumstances as when values are inserted
via the INSERT
statement (see section 7.21 INSERT
Syntax), except
that LOAD DATA INFILE
also generates warnings when there are too few
or too many fields in the input row. The warnings are not stored anywhere;
the number of warnings can only be used as an indication if everything went
well. If you get warnings and want to know exactly why you got them, one way
to do this is to use SELECT ... INTO OUTFILE
into another file and
compare this to your original input file.
If you need LOAD DATA
to read from a pipe, you can use the
following trick:
mkfifo /mysql/db/x/x chmod 666 /mysql/db/x/x cat < /dev/tcp/10.1.1.12/4711 > /nt/mysql/db/x/x mysql -e "LOAD DATA INFILE 'x' INTO TABLE x" x
If you are using a version of MySQL older than 3.23.25
you can only do the above with LOAD DATA LOCAL INFILE
.
For more information about the efficiency of INSERT
versus
LOAD DATA INFILE
and speeding up LOAD DATA INFILE
,
See section 12.5.7 Speed of INSERT
Queries.
UPDATE
SyntaxUPDATE [LOW_PRIORITY] [IGNORE] tbl_name SET col_name1=expr1, [col_name2=expr2, ...] [WHERE where_definition] [ORDER BY ...] [LIMIT #]
UPDATE
updates columns in existing table rows with new values.
The SET
clause indicates which columns to modify and the values
they should be given. The WHERE
clause, if given, specifies
which rows should be updated. Otherwise all rows are updated. If the
ORDER BY
clause is specified, the rows will be updated in the
order that is specified.
If you specify the keyword LOW_PRIORITY
, execution of the
UPDATE
is delayed until no other clients are reading from the table.
If you specify the keyword IGNORE
, the update statement will not
abort even if we get duplicate key errors during the update. Rows that
would cause conflicts will not be updated.
If you access a column from tbl_name
in an expression,
UPDATE
uses the current value of the column. For example, the
following statement sets the age
column to one more than its
current value:
mysql> UPDATE persondata SET age=age+1;
UPDATE
assignments are evaluated from left to right. For example, the
following statement doubles the age
column, then increments it:
mysql> UPDATE persondata SET age=age*2, age=age+1;
If you set a column to the value it currently has, MySQL notices this and doesn't update it.
UPDATE
returns the number of rows that were actually changed.
In MySQL Version 3.22 or later, the C API function mysql_info()
returns the number of rows that were matched and updated and the number of
warnings that occurred during the UPDATE
.
In MySQL Version 3.23, you can use LIMIT #
to ensure that
only a given number of rows are changed.
USE
SyntaxUSE db_name
The USE db_name
statement tells MySQL to use the db_name
database as the default database for subsequent queries. The database remains
current until the end of the session or until another USE
statement
is issued:
mysql> USE db1; mysql> SELECT count(*) FROM mytable; # selects from db1.mytable mysql> USE db2; mysql> SELECT count(*) FROM mytable; # selects from db2.mytable
Making a particular database current by means of the USE
statement
does not preclude you from accessing tables in other databases. The example
below accesses the author
table from the db1
database and the
editor
table from the db2
database:
mysql> USE db1; mysql> SELECT author_name,editor_name FROM author,db2.editor WHERE author.editor_id = db2.editor.editor_id;
The USE
statement is provided for Sybase compatibility.
FLUSH
Syntax (Clearing Caches)FLUSH flush_option [,flush_option]
You should use the FLUSH
command if you want to clear some of the
internal caches MySQL uses. To execute FLUSH
, you must have
the reload privilege.
flush_option
can be any of the following:
HOSTS | Empties the host cache tables. You should flush the
host tables if some of your hosts change IP number or if you get the
error message Host ... is blocked . When more than
max_connect_errors errors occur in a row for a given host while
connection to the MySQL server, MySQL assumes
something is wrong and blocks the host from further connection requests.
Flushing the host tables allows the host to attempt to connect
again. See section 20.4.3 Host '...' is blocked Error.) You can start mysqld with
-O max_connection_errors=999999999 to avoid this error message.
|
LOGS | Closes and reopens all log files. If you have specified the update log file or a binary log file without an extension, the extension number of the log file will be incremented by one relative to the previous file. If you have used an extension in the file name, MySQL will close and reopen the update log file. See section 22.3 The Update Log. |
PRIVILEGES | Reloads the privileges from the grant tables in
the mysql database.
|
TABLES | Closes all open tables and force all tables in use to be closed. |
[TABLE | TABLES] table_name [,table_name...] | Flushes only the given tables. |
TABLES WITH READ LOCK | Closes all open tables and locks all tables for all databases with a read until one executes UNLOCK TABLES . This is very convinient way to get backups if you have a file system, like Veritas,that can take snapshots in time.
|
STATUS | Resets most status variables to zero. |
You can also access each of the commands shown above with the mysqladmin
utility, using the flush-hosts
, flush-logs
, reload
,
or flush-tables
commands.
KILL
SyntaxKILL thread_id
Each connection to mysqld
runs in a separate thread. You can see
which threads are running with the SHOW PROCESSLIST
command and kill
a thread with the KILL thread_id
command.
If you have the process privilege, you can see and kill all threads. Otherwise, you can see and kill only your own threads.
You can also use the mysqladmin processlist
and mysqladmin kill
commands to examine and kill threads.
SHOW
Syntax (Get Information About Tables, Columns,...)SHOW DATABASES [LIKE wild] or SHOW [OPEN] TABLES [FROM db_name] [LIKE wild] or SHOW [FULL] COLUMNS FROM tbl_name [FROM db_name] [LIKE wild] or SHOW INDEX FROM tbl_name [FROM db_name] or SHOW TABLE STATUS [FROM db_name] [LIKE wild] or SHOW STATUS [LIKE wild] or SHOW VARIABLES [LIKE wild] or SHOW LOGS or SHOW [FULL] PROCESSLIST or SHOW GRANTS FOR user or SHOW CREATE TABLE table_name or SHOW MASTER STATUS or SHOW MASTER LOGS or SHOW SLAVE STATUS
SHOW
provides information about databases, tables, columns, or
status information about the server. If the LIKE wild
part is
used, the wild
string can be a string that uses the SQL `%'
and `_' wild-card characters.
You can use db_name.tbl_name
as an alternative to the tbl_name
FROM db_name
syntax. These two statements are equivalent:
mysql> SHOW INDEX FROM mytable FROM mydb; mysql> SHOW INDEX FROM mydb.mytable;
SHOW DATABASES
lists the databases on the MySQL server
host. You can also get this list using the mysqlshow
command.
SHOW TABLES
lists the tables in a given database. You can also
get this list using the mysqlshow db_name
command.
NOTE: If a user doesn't have any privileges for a table, the table
will not show up in the output from SHOW TABLES
or mysqlshow
db_name
.
SHOW OPEN TABLES
lists the tables that are currently open in
the table cache. See section 12.2.4 How MySQL Opens and Closes Tables. The Comment
field tells
how many times the table is cached
and in_use
.
SHOW COLUMNS
lists the columns in a given table. If you specify
the FULL
option, you will also get the privileges you have for
each column. If the column types are different than you expect them to
be based on a CREATE TABLE
statement, note that MySQL
sometimes changes column types. See section 7.7.1 Silent Column Specification Changes.
The DESCRIBE
statement provides information similar to
SHOW COLUMNS
.
See section 7.30 DESCRIBE
Syntax (Get Information About Columns).
SHOW FIELDS
is a synonym for SHOW COLUMNS
, and
SHOW KEYS
is a synonym for SHOW INDEX
. You can also
list a table's columns or indexes with mysqlshow db_name tbl_name
or mysqlshow -k db_name tbl_name
.
SHOW INDEX
returns the index information in a format that closely
resembles the SQLStatistics
call in ODBC. The following columns
are returned:
Column | Meaning |
Table | Name of the table. |
Non_unique | 0 if the index can't contain duplicates. |
Key_name | Name of the index. |
Seq_in_index | Column sequence number in index, starting with 1. |
Column_name | Column name. |
Collation | How the column is sorted in the index. In
MySQL, this can have values A (Ascending) or NULL
(Not sorted).
|
Cardinality | Number of unique values in the index.
This is updated by running isamchk -a .
|
Sub_part | Number of indexed characters if the column is
only partly indexed. NULL if the entire key is indexed.
|
Comment | Various remarks. For now, it tells whether index is FULLTEXT or not. |
SHOW TABLE STATUS
(new in Version 3.23) works likes SHOW
STATUS
, but provides a lot of information about each table. You can
also get this list using the mysqlshow --status db_name
command.
The following columns are returned:
Column | Meaning |
Name | Name of the table. |
Type | Type of table. See section 8 MySQL Table Types. |
Row_format | The row storage format (Fixed, Dynamic, or Compressed). |
Rows | Number of rows. |
Avg_row_length | Average row length. |
Data_length | Length of the data file. |
Max_data_length | Max length of the data file. |
Index_length | Length of the index file. |
Data_free | Number of allocated but not used bytes. |
Auto_increment | Next autoincrement value. |
Create_time | When the table was created. |
Update_time | When the data file was last updated. |
Check_time | When the table was last checked. |
Create_options | Extra options used with CREATE TABLE .
|
Comment | The comment used when creating the table (or some information why MySQL couldn't access the table information). |
INNOBASE
tables will report the free space in the tablespace
in the table comment.
SHOW STATUS
provides server status information
(like mysqladmin extended-status
). The output resembles that shown
below, though the format and numbers probably differ:
+--------------------------+--------+ | Variable_name | Value | +--------------------------+--------+ | Aborted_clients | 0 | | Aborted_connects | 0 | | Bytes_received | 629539 | | Bytes_sent | 736394 | | Connections | 62 | | Created_tmp_disk_tables | 0 | | Created_tmp_tables | 0 | | Created_tmp_files | 0 | | Delayed_insert_threads | 0 | | Delayed_writes | 0 | | Delayed_errors | 0 | | Flush_commands | 1 | | Handler_delete | 0 | | Handler_read_first | 1 | | Handler_read_key | 9201 | | Handler_read_next | 0 | | Handler_read_prev | 0 | | Handler_read_rnd | 0 | | Handler_read_rnd_next | 45 | | Handler_update | 5998 | | Handler_write | 0 | | Key_blocks_used | 407 | | Key_read_requests | 27683 | | Key_reads | 407 | | Key_write_requests | 0 | | Key_writes | 0 | | Max_used_connections | 60 | | Not_flushed_key_blocks | 0 | | Not_flushed_delayed_rows | 0 | | Open_tables | 60 | | Open_files | 66 | | Open_streams | 0 | | Opened_tables | 66 | | Questions | 9308 | | Select_full_join | 0 | | Select_full_range_join | 0 | | Select_range | 0 | | Select_range_check | 0 | | Select_scan | 0 | | Slave_running | OFF | | Slave_open_temp_tables | 0 | | Slow_launch_threads | 0 | | Slow_queries | 0 | | Sort_merge_passes | 0 | | Sort_range | 0 | | Sort_rows | 0 | | Sort_scan | 0 | | Table_locks_immediate | 3183 | | Table_locks_waited | 6030 | | Threads_cached | 30 | | Threads_created | 61 | | Threads_connected | 31 | | Threads_running | 31 | | Uptime | 135 | +--------------------------+--------+
The status variables listed above have the following meaning:
Variable | Meaning |
Aborted_clients | Number of connections aborted because the client died without closing the connection properly. See section 20.4.7 Communication Errors / Aborted Connection. |
Aborted_connects | Number of tries to connect to the MySQL server that failed. See section 20.4.7 Communication Errors / Aborted Connection. |
Bytes_received | Number of bytes received from all clients. |
Bytes_sent | Number of bytes sent to all clients. |
Connections | Number of connection attempts to the MySQL server. |
Created_tmp_disk_tables | Number of implicit temporary tables on disk created while executing statements. |
Created_tmp_tables | Number of implicit temporary tables in memory created while executing statements. |
Created_tmp_files | How many temporary files mysqld have created.
|
Delayed_insert_threads | Number of delayed insert handler threads in use. |
Delayed_writes | Number of rows written with INSERT DELAYED .
|
Delayed_errors | Number of rows written with INSERT DELAYED for which some error occurred (probably duplicate key ).
|
Flush_commands | Number of executed FLUSH commands.
|
Handler_delete | Number of times a row was deleted from a table. |
Handler_read_first | Number of times the first entry was read from an index.
If this is high, it suggests that the server is doing a lot of full index scans, for example,
SELECT col1 FROM foo , assuming that col1 is indexed.
|
Handler_read_key | Number of requests to read a row based on a key. If this is high, it is a good indication that your queries and tables are properly indexed. |
Handler_read_next | Number of requests to read next row in key order. This will be incremented if you are querying an index column with a range contraint. This also will be incremented if you are doing an index scan. |
Handler_read_rnd | Number of requests to read a row based on a fixed position. This will be high if you are doing a lot of queries that require sorting of the result. |
Handler_read_rnd_next | Number of requests to read the next row in the datafile. This will be high if you are doing a lot of table scans. Generally this suggests that your tables are not properly indexed or that your queries are not written to take advantage of the indexes you have. |
Handler_update | Number of requests to update a row in a table. |
Handler_write | Number of requests to insert a row in a table. |
Key_blocks_used | The number of used blocks in the key cache. |
Key_read_requests | The number of requests to read a key block from the cache. |
Key_reads | The number of physical reads of a key block from disk. |
Key_write_requests | The number of requests to write a key block to the cache. |
Key_writes | The number of physical writes of a key block to disk. |
Max_used_connections | The maximum number of connections in use simultaneously. |
Not_flushed_key_blocks | Keys blocks in the key cache that has changed but hasn't yet been flushed to disk. |
Not_flushed_delayed_rows | Number of rows waiting to be written in INSERT DELAY queues.
|
Open_tables | Number of tables that are open. |
Open_files | Number of files that are open. |
Open_streams | Number of streams that are open (used mainly for logging). |
Opened_tables | Number of tables that have been opened. |
Select_full_join | Number of joins without keys (Should be 0). |
Select_full_range_join | Number of joins where we used a range search on reference table. |
Select_range | Number of joins where we used ranges on the first table. (It's normally not critical even if this is big.) |
Select_scan | Number of joins where we scanned the first table. |
Select_range_check | Number of joins without keys where we check for key usage after each row (Should be 0). |
Questions | Number of queries sent to the server. |
Slave_open_temp_tables | Number of temporary tables currently open by the slave thread |
Slow_launch_threads | Number of threads that have taken more than slow_launch_time to connect.
|
Slow_queries | Number of queries that have taken more than long_query_time . See section 22.5 The Slow Query Log.
|
Sort_merge_passes | Number of merges the sort has to do. If this value is large you should consider increasing sort_buffer .
|
Sort_range | Number of sorts that where done with ranges. |
Sort_rows | Number of sorted rows. |
Sort_scan | Number of sorts that where done by scanning the table. |
Table_locks_immediate | Number of times a table lock was acquired immediately. Available after 3.23.33. |
Table_locks_waited | Number of times a table lock could not be acquired immediately and a wait was needed. If this is high, and you have performance problems, you should first optimize your queries, and then either split your table(s) or use replication. Available after 3.23.33. |
Threads_cached | Number of threads in the thread cache. |
Threads_connected | Number of currently open connections. |
Threads_created | Number of threads created to handle connections. |
Threads_running | Number of threads that are not sleeping. |
Uptime | How many seconds the server has been up. |
Some comments about the above:
Opened_tables
is big, then your table_cache
variable is probably too small.
key_reads
is big, then your key_cache
is probably too
small. The cache hit rate can be calculated with
key_reads
/key_read_requests
.
Handler_read_rnd
is big, then you probably have a lot of
queries that require MySQL to scan whole tables or you have
joins that don't use keys properly.
Threads_created
is big, you may want to increase the
thread_cache_size
variable.
SHOW VARIABLES
shows the values of some MySQL system
variables. You can also get this information using the mysqladmin
variables
command. If the default values are unsuitable, you can set most
of these variables using command-line options when mysqld
starts up.
See section 4.16.4 Command-line Options.
The output resembles that shown below, though the format and numbers may differ somewhat:
+-------------------------+---------------------------+ | Variable_name | Value | +-------------------------+---------------------------+ | ansi_mode | OFF | | back_log | 50 | | basedir | /my/monty/ | | bdb_cache_size | 16777216 | | bdb_log_buffer_size | 32768 | | bdb_home | /my/monty/data/ | | bdb_max_lock | 10000 | | bdb_logdir | | | bdb_shared_data | OFF | | bdb_tmpdir | /tmp/ | | binlog_cache_size | 32768 | | concurrent_insert | ON | | connect_timeout | 5 | | datadir | /my/monty/data/ | | delay_key_write | ON | | delayed_insert_limit | 100 | | delayed_insert_timeout | 300 | | delayed_queue_size | 1000 | | flush | OFF | | flush_time | 0 | | have_bdb | YES | | have_gemini | NO | | have_innobase | YES | | have_raid | YES | | have_ssl | NO | | init_file | | | interactive_timeout | 28800 | | join_buffer_size | 131072 | | key_buffer_size | 16776192 | | language | /my/monty/share/english/ | | large_files_support | ON | | log | OFF | | log_update | OFF | | log_bin | OFF | | log_slave_updates | OFF | | long_query_time | 10 | | low_priority_updates | OFF | | lower_case_table_names | 0 | | max_allowed_packet | 1048576 | | max_binlog_cache_size | 4294967295 | | max_connections | 100 | | max_connect_errors | 10 | | max_delayed_threads | 20 | | max_heap_table_size | 16777216 | | max_join_size | 4294967295 | | max_sort_length | 1024 | | max_tmp_tables | 32 | | max_write_lock_count | 4294967295 | | myisam_recover_options | DEFAULT | | myisam_sort_buffer_size | 8388608 | | net_buffer_length | 16384 | | net_read_timeout | 30 | | net_retry_count | 10 | | net_write_timeout | 60 | | open_files_limit | 0 | | pid_file | /my/monty/data/donna.pid | | port | 3306 | | protocol_version | 10 | | record_buffer | 131072 | | query_buffer_size | 0 | | safe_show_database | OFF | | server_id | 0 | | skip_locking | ON | | skip_networking | OFF | | skip_show_database | OFF | | slow_launch_time | 2 | | socket | /tmp/mysql.sock | | sort_buffer | 2097116 | | table_cache | 64 | | table_type | MYISAM | | thread_cache_size | 4 | | thread_stack | 65536 | | tmp_table_size | 1048576 | | tmpdir | /tmp/ | | version | 3.23.29a-gamma-debug | | wait_timeout | 28800 | +-------------------------+---------------------------+
Each option is described below. Values for buffer sizes, lengths, and stack
sizes are given in bytes. You can specify values with a suffix of `K'
or `M' to indicate kilobytes or megabytes. For example, 16M
indicates 16 megabytes. The case of suffix letters does not matter;
16M
and 16m
are equivalent:
ansi_mode
.
ON
if mysqld
was started with --ansi
.
See section 5.2 Running MySQL in ANSI Mode.
back_log
back_log
value indicates how many requests can be
stacked during this short time before MySQL momentarily stops
answering new requests. You need to increase this only if you expect a large
number of connections in a short period of time.
In other words, this value is the size of the listen queue for incoming
TCP/IP connections. Your operating system has its own limit on the size
of this queue. The manual page for the Unix listen(2)
system
call should have more details. Check your OS documentation for the
maximum value for this variable. Attempting to set back_log
higher than your operating system limit will be ineffective.
basedir
--basedir
option.
bdb_cache_size
BDB
tables. If you don't use BDB
tables, you should start
mysqld
with --skip-bdb
to not waste memory for this
cache.
bdb_log_buffer_size
BDB
tables. If you don't use BDB
tables, you should set this to 0 or
start mysqld
with --skip-bdb
to not waste memory for this
cache.
bdb_home
--bdb-home
option.
bdb_max_lock
bdb:
Lock table is out of available locks
or Got error 12 from ...
when you have do long transactions or when mysqld
has to examine
a lot of rows to calculate the query.
bdb_logdir
--bdb-logdir
option.
bdb_shared_data
ON
if you are using --bdb-shared-data
.
bdb_tmpdir
--bdb-tmpdir
option.
binlog_cache_size
. The size of the cache to hold the SQL
BEGIN/COMMIT/ROLLBACK
Syntax.
character_set
character_sets
concurrent_inserts
ON
(the default), MySQL will allow you to use INSERT
on MyISAM
tables at the same time as you run SELECT
queries
on them. You can turn this option off by starting mysqld with --safe
or --skip-new
.
connect_timeout
mysqld
server is waiting for a connect
packet before responding with Bad handshake
.
datadir
--datadir
option.
delay_key_write
delay_key_write
option CREATE TABLE
. This means that the
key buffer for tables with this option will not get flushed on every
index update, but only when a table is closed. This will speed up
writes on keys a lot, but you should add automatic checking of all tables
with myisamchk --fast --force
if you use this. Note that if you
start mysqld
with the --delay-key-write-for-all-tables
option this means that all tables will be treated as if they were
created with the delay_key_write
option. You can clear this flag
by starting mysqld
with --skip-new
or --safe-mode
.
delayed_insert_limit
delayed_insert_limit
rows, the INSERT
DELAYED
handler will check if there are any SELECT
statements
pending. If so, it allows these to execute before continuing.
delayed_insert_timeout
INSERT DELAYED
thread should wait for INSERT
statements before terminating.
delayed_queue_size
INSERT
DELAYED
. If the queue becomes full, any client that does INSERT
DELAYED
will wait until there is room in the queue again.
flush
ON
if you have started MySQL with the --flush
option.
flush_time
flush_time
seconds all
tables will be closed (to free up resources and sync things to disk). We
only recommend this option on Win95, Win98, or on systems where you have
very little resources.
have_bdb
YES
if mysqld
supports Berkeley DB tables. DISABLED
if --skip-bdb
is used.
have_gemini
YES
if mysqld
supports Gemini tables. DISABLED
if --skip-gemini
is used.
have_innobase
YES
if mysqld
supports Innobase tables. DISABLED
if --skip-innobase
is used.
have_raid
YES
if mysqld
supports the RAID
option.
have_ssl
YES
if mysqld
supports SSL (encryption) on the client/server
protocol.
init_file
--init-file
option when
you start the server. This is a file of SQL statements you want the
server to execute when it starts.
interactive_timeout
CLIENT_INTERACTIVE
option to
mysql_real_connect()
. See also wait_timeout
.
join_buffer_size
key_buffer_size
key_buffer_size
is the size of the buffer used for index blocks.
Increase this to get better index handling (for all reads and multiple
writes) to as much as you can afford; 64M on a 256M machine that mainly
runs MySQL is quite common. If you, however, make this too big
(more than 50% of your total memory?) your system may start to page and
become REALLY slow. Remember that because MySQL does not cache
data read, that you will have to leave some room for the OS filesystem
cache.
You can check the performance of the key buffer by doing show
status
and examine the variables Key_read_requests
,
Key_reads
, Key_write_requests
, and Key_writes
. The
Key_reads/Key_read_request
ratio should normally be < 0.01.
The Key_write/Key_write_requests
is usually near 1 if you are
using mostly updates/deletes but may be much smaller if you tend to
do updates that affect many at the same time or if you are
using delay_key_write
. See section 7.28 SHOW
Syntax (Get Information About Tables, Columns,...).
To get even more speed when writing many rows at the same time, use
LOCK TABLES
. See section 7.32 LOCK TABLES/UNLOCK TABLES
Syntax.
language
large_file_support
mysqld
was compiled with options for big file support.
locked_in_memory
mysqld
was locked in memory with --memlock
log
log_update
log_bin
log_slave_updates
long_query_time
Slow_queries
counter
will be incremented. If you are using --log-slow-queries
, the query
will be logged to the slow query logfile. See section 22.5 The Slow Query Log.
lower_case_table_names
max_allowed_packet
net_buffer_length
bytes, but can grow up to max_allowed_packet
bytes when needed. This value by default is small, to catch big (possibly
wrong) packets. You must increase this value if you are using big
BLOB
columns. It should be as big as the biggest BLOB
you want
to use. The current protocol limits max_allowed_packet
to 16M.
max_binlog_cache_size
. If a multi-statement transaction
max_binlog_size
. Available after 3.23.33. If a write to the
max_connections
mysqld
requires. See below for
comments on file descriptor limits. See section 20.4.4 Too many connections
Error.
max_connect_errors
FLUSH HOSTS
.
max_delayed_threads
INSERT DELAYED
statements. If you try to insert data into a new table after all INSERT
DELAYED
threads are in use, the row will be inserted as if the
DELAYED
attribute wasn't specified.
max_heap_table_size
max_join_size
max_join_size
records return an error. Set this value if your users tend to perform joins
that lack a WHERE
clause, that take a long time, and that return
millions of rows.
max_sort_length
BLOB
or TEXT
values (only the first max_sort_length
bytes of each value
are used; the rest are ignored).
max_user_connections
max_tmp_tables
max_write_lock_count
myisam_recover_options
--myisam-recover
option.
myisam_sort_buffer_size
REPAIR
or when creating indexes with CREATE INDEX
or
ALTER TABLE
.
net_buffer_length
max_allowed_packet
bytes.)
net_read_timeout
write_timeout
.
net_retry_count
FreeBSD
as
internal interrupts are sent to all threads.
net_write_timeout
open_files_limit
mysqld
will use this value to reserve file
descriptors to use with getrlimit()
. If this value is 0 then
mysqld
will reserve max_connections*5
or
max_connections + table_cache*2
(whichever is larger) number of
files. You should try increasing this if mysqld
gives you the
error 'Too many open files'.
pid_file
--pid-file
option.
port
--port
option.
protocol_version
record_buffer
query_buffer_size
safe_show_databases
skip_show_databases
.
server_id
--server-id
option.
skip_locking
mysqld
uses external locking.
skip_networking
skip_show_databases
SHOW DATABASES
if they don't have
the PROCESS_PRIV
privilege. This can improve security if you're
concerned about people being able to see what databases other users
have. See also safe_show_databases
.
slow_launch_time
Slow_launch_threads
counter will be incremented.
socket
sort_buffer
ORDER BY
or GROUP BY
operations.
See section 20.7 Where MySQL Stores Temporary Files.
table_cache
mysqld
requires.
MySQL needs two file descriptors for each unique open table.
See below for comments on file descriptor limits. You can check if you
need to increase the table cache by checking the Opened_tables
variable. See section 7.28 SHOW
Syntax (Get Information About Tables, Columns,...). If this variable is big and you don't do
FLUSH TABLES
a lot (which just forces all tables to be closed and
reopenend), then you should increase the value of this variable.
Make sure that your operating system can handle the number of open file
descriptors implied by the table_cache
setting. If table_cache
is set too high, MySQL may run out of file descriptors and refuse
connections, fail to perform queries, and be very unreliable.
For information about how the table cache works, see section 12.2.4 How MySQL Opens and Closes Tables.
table_type
thread_cache_size
thread_cache_size
threads from before. All new
threads are first taken from the cache, and only when the cache is empty
is a new thread created. This variable can be increased to improve
performance if you have a lot of new connections. (Normally this doesn't
give a notable performance improvement if you have a good
thread implementation.) By examing the difference between
the Connections
and Threads_created
you can see how efficient
the current thread cache is for you.
thread_concurrency
mysqld
will call thr_setconcurrency()
with
this value. thr_setconcurrency()
permits the application to give
the threads system a hint for the desired number of threads that should
be run at the same time.
thread_stack
crash-me
test are dependent on this value. The default is
large enough for normal operation. See section 12.7 Using Your Own Benchmarks.
timezone
tmp_table_size
MyISAM
table.
Increase the value of tmp_table_size
if you do many advanced
GROUP BY
queries and you have lots of memory.
tmpdir
version
wait_timeout
interactive_timeout
.
The manual section that describes tuning MySQL contains some information of how to tune the above variables. See section 12.2.3 Tuning Server Parameters.
SHOW LOGS
shows you status information about existing log
files. It currently only displays information about Berkeley DB log
files.
File
shows the full path to the log file
Type
shows the type of the log file (BDB
for Berkeley
DB log files)
Status
shows the status of the log file (FREE
if the
file can be removed, or IN USE
if the file is needed by the transaction
subsystem)
SHOW PROCESSLIST
shows you which threads are running. You can
also get this information using the mysqladmin processlist
command. If you have the process privilege, you can see all
threads. Otherwise, you can see only your own threads. See section 7.27 KILL
Syntax. If you don't use the FULL
option, then only
the first 100 characters of each query will be shown.
This command is very useful if you get the 'too many connections' error
message and want to find out what's going on. MySQL reserves
one extra connection for a client with the Process_priv
privilege
to ensure that you should always be able to login and check the system
(assuming you are not giving this privilege to all your users).
SHOW GRANTS FOR user
lists the grant commands that must be issued to
duplicate the grants for a user.
mysql> SHOW GRANTS FOR root@localhost; +---------------------------------------------------------------------+ | Grants for root@localhost | +---------------------------------------------------------------------+ | GRANT ALL PRIVILEGES ON *.* TO 'root'@'localhost' WITH GRANT OPTION | +---------------------------------------------------------------------+
Shows a CREATE TABLE
statement that will create the given table:
mysql> show create table t\G *************************** 1. row *************************** Table: t Create Table: CREATE TABLE t ( id int(11) default NULL auto_increment, s char(60) default NULL, PRIMARY KEY (id) ) TYPE=MyISAM
SHOW CREATE TABLE
will quote table and column names according to
SQL_QUOTE_SHOW_CREATE
option.
section 7.33 SET
Syntax.
EXPLAIN
Syntax (Get Information About a SELECT
)EXPLAIN tbl_name or EXPLAIN SELECT select_options
EXPLAIN tbl_name
is a synonym for DESCRIBE tbl_name
or
SHOW COLUMNS FROM tbl_name
.
When you precede a SELECT
statement with the keyword EXPLAIN
,
MySQL explains how it would process the SELECT
, providing
information about how tables are joined and in which order.
With the help of EXPLAIN
, you can see when you must add indexes
to tables to get a faster SELECT
that uses indexes to find the
records. You can also see if the optimizer joins the tables in an optimal
order. To force the optimizer to use a specific join order for a
SELECT
statement, add a STRAIGHT_JOIN
clause.
For non-simple joins, EXPLAIN
returns a row of information for each
table used in the SELECT
statement. The tables are listed in the order
they would be read. MySQL resolves all joins using a single-sweep
multi-join method. This means that MySQL reads a row from the first
table, then finds a matching row in the second table, then in the third table
and so on. When all tables are processed, it outputs the selected columns and
backtracks through the table list until a table is found for which there are
more matching rows. The next row is read from this table and the process
continues with the next table.
Output from EXPLAIN
includes the following columns:
table
type
possible_keys
possible_keys
column indicates which indexes MySQL
could use to find the rows in this table. Note that this column is
totally independent of the order of the tables. That means that some of
the keys in possible_keys may not be usable in practice with the
generated table order.
If this column is empty, there are no relevant indexes. In this case,
you may be able to improve the performance of your query by examining
the WHERE
clause to see if it refers to some column or columns
that would be suitable for indexing. If so, create an appropriate index
and check the query with EXPLAIN
again. See section 7.8 ALTER TABLE
Syntax.
To see what indexes a table has, use SHOW INDEX FROM tbl_name
.
key
key
column indicates the key that MySQL actually
decided to use. The key is NULL
if no index was chosen. If
MySQL chooses the wrong index, you can probably force
MySQL to use another index by using myisamchk --analyze
,
See section 15.1.1 myisamchk
Invocation Syntax, or by using USE INDEX/IGNORE INDEX
.
See section 7.20 JOIN
Syntax.
key_len
key_len
column indicates the length of the key that
MySQL decided to use. The length is NULL
if the
key
is NULL
. Note that this tells us how many parts of a
multi-part key MySQL will actually use.
ref
ref
column shows which columns or constants are used with the
key
to select rows from the table.
rows
rows
column indicates the number of rows MySQL
believes it must examine to execute the query.
Extra
Distinct
Not exists
LEFT JOIN
optimization on the
query and will not examine more rows in this table for a row combination
after it finds one row that matches the LEFT JOIN
criteria.
range checked for each record (index map: #)
Using filesort
join type
and storing the sort key + pointer to
the row for all rows that match the WHERE
. Then the keys are
sorted. Finally the rows are retrieved in sorted order.
Using index
Using temporary
ORDER BY
on a different column set than you did a GROUP
BY
on.
Where used
WHERE
clause will be used to restrict which rows will be
matched against the next table or sent to the client. If you don't have
this information and the table is of type ALL
or index
,
you may have something wrong in your query (if you don't intend to
fetch/examine all rows from the table).
Using filesort
and Using temporary
.
The different join types are listed below, ordered from best to worst type:
system
const
join type.
const
const
tables are very fast as they are read only once!
eq_ref
const
types. It is used when all parts of an index are used by
the join and the index is UNIQUE
or a PRIMARY KEY
.
ref
ref
is used if the join
uses only a leftmost prefix of the key, or if the key is not UNIQUE
or a PRIMARY KEY
(in other words, if the join cannot select a single
row based on the key value). If the key that is used matches only a few rows,
this join type is good.
range
key
column indicates which index is used.
The key_len
contains the longest key part that was used.
The ref
column will be NULL for this type.
index
ALL
, except that only the index tree is
scanned. This is usually faster than ALL
, as the index file is usually
smaller than the data file.
ALL
const
, and usually very bad in all other
cases. You normally can avoid ALL
by adding more indexes, so that
the row can be retrieved based on constant values or column values from
earlier tables.
You can get a good indication of how good a join is by multiplying all values
in the rows
column of the EXPLAIN
output. This should tell you
roughly how many rows MySQL must examine to execute the query. This
number is also used when you restrict queries with the max_join_size
variable.
See section 12.2.3 Tuning Server Parameters.
The following example shows how a JOIN
can be optimized progressively
using the information provided by EXPLAIN
.
Suppose you have the SELECT
statement shown below, that you examine
using EXPLAIN
:
EXPLAIN SELECT tt.TicketNumber, tt.TimeIn, tt.ProjectReference, tt.EstimatedShipDate, tt.ActualShipDate, tt.ClientID, tt.ServiceCodes, tt.RepetitiveID, tt.CurrentProcess, tt.CurrentDPPerson, tt.RecordVolume, tt.DPPrinted, et.COUNTRY, et_1.COUNTRY, do.CUSTNAME FROM tt, et, et AS et_1, do WHERE tt.SubmitTime IS NULL AND tt.ActualPC = et.EMPLOYID AND tt.AssignedPC = et_1.EMPLOYID AND tt.ClientID = do.CUSTNMBR;
For this example, assume that:
Table | Column | Column type |
tt | ActualPC | CHAR(10)
|
tt | AssignedPC | CHAR(10)
|
tt | ClientID | CHAR(10)
|
et | EMPLOYID | CHAR(15)
|
do | CUSTNMBR | CHAR(15)
|
Table | Index |
tt | ActualPC
|
tt | AssignedPC
|
tt | ClientID
|
et | EMPLOYID (primary key)
|
do | CUSTNMBR (primary key)
|
tt.ActualPC
values aren't evenly distributed.
Initially, before any optimizations have been performed, the EXPLAIN
statement produces the following information:
table type possible_keys key key_len ref rows Extra et ALL PRIMARY NULL NULL NULL 74 do ALL PRIMARY NULL NULL NULL 2135 et_1 ALL PRIMARY NULL NULL NULL 74 tt ALL AssignedPC,ClientID,ActualPC NULL NULL NULL 3872 range checked for each record (key map: 35)
Because type
is ALL
for each table, this output indicates that
MySQL is doing a full join for all tables! This will take quite a
long time, as the product of the number of rows in each table must be
examined! For the case at hand, this is 74 * 2135 * 74 * 3872 =
45,268,558,720
rows. If the tables were bigger, you can only imagine how
long it would take.
One problem here is that MySQL can't (yet) use indexes on columns
efficiently if they are declared differently. In this context,
VARCHAR
and CHAR
are the same unless they are declared as
different lengths. Because tt.ActualPC
is declared as CHAR(10)
and et.EMPLOYID
is declared as CHAR(15)
, there is a length
mismatch.
To fix this disparity between column lengths, use ALTER TABLE
to
lengthen ActualPC
from 10 characters to 15 characters:
mysql> ALTER TABLE tt MODIFY ActualPC VARCHAR(15);
Now tt.ActualPC
and et.EMPLOYID
are both VARCHAR(15)
.
Executing the EXPLAIN
statement again produces this result:
table type possible_keys key key_len ref rows Extra tt ALL AssignedPC,ClientID,ActualPC NULL NULL NULL 3872 where used do ALL PRIMARY NULL NULL NULL 2135 range checked for each record (key map: 1) et_1 ALL PRIMARY NULL NULL NULL 74 range checked for each record (key map: 1) et eq_ref PRIMARY PRIMARY 15 tt.ActualPC 1
This is not perfect, but is much better (the product of the rows
values is now less by a factor of 74). This version is executed in a couple
of seconds.
A second alteration can be made to eliminate the column length mismatches
for the tt.AssignedPC = et_1.EMPLOYID
and tt.ClientID =
do.CUSTNMBR
comparisons:
mysql> ALTER TABLE tt MODIFY AssignedPC VARCHAR(15), MODIFY ClientID VARCHAR(15);
Now EXPLAIN
produces the output shown below:
table type possible_keys key key_len ref rows Extra et ALL PRIMARY NULL NULL NULL 74 tt ref AssignedPC,ClientID,ActualPC ActualPC 15 et.EMPLOYID 52 where used et_1 eq_ref PRIMARY PRIMARY 15 tt.AssignedPC 1 do eq_ref PRIMARY PRIMARY 15 tt.ClientID 1
This is almost as good as it can get.
The remaining problem is that, by default, MySQL assumes that values
in the tt.ActualPC
column are evenly distributed, and that isn't the
case for the tt
table. Fortunately, it is easy to tell MySQL
about this:
shell> myisamchk --analyze PATH_TO_MYSQL_DATABASE/tt shell> mysqladmin refresh
Now the join is perfect, and EXPLAIN
produces this result:
table type possible_keys key key_len ref rows Extra tt ALL AssignedPC,ClientID,ActualPC NULL NULL NULL 3872 where used et eq_ref PRIMARY PRIMARY 15 tt.ActualPC 1 et_1 eq_ref PRIMARY PRIMARY 15 tt.AssignedPC 1 do eq_ref PRIMARY PRIMARY 15 tt.ClientID 1
Note that the rows
column in the output from EXPLAIN
is an
educated guess from the MySQL join optimizer. To optimize a
query, you should check if the numbers are even close to the truth. If not,
you may get better performance by using STRAIGHT_JOIN
in your
SELECT
statement and trying to list the tables in a different order in
the FROM
clause.
DESCRIBE
Syntax (Get Information About Columns){DESCRIBE | DESC} tbl_name {col_name | wild}
DESCRIBE
provides information about a table's columns. col_name
may be a column name or a string containing the SQL `%' and `_'
wild-card characters.
If the column types are different than you expect them to be based on a
CREATE TABLE
statement, note that MySQL sometimes
changes column types. See section 7.7.1 Silent Column Specification Changes.
This statement is provided for Oracle compatibility.
The SHOW
statement provides similar information.
See section 7.28 SHOW
Syntax (Get Information About Tables, Columns,...).
BEGIN/COMMIT/ROLLBACK
Syntax
By default, MySQL runs in autocommit
mode. This means that
as soon as you execute an update, MySQL will store the update on
disk.
If you are using transactions safe tables (like BDB
,
INNOBASE
or GEMINI
), you can put MySQL into
non-autocommit
mode with the following command:
SET AUTOCOMMIT=0
After this you must use COMMIT
to store your changes to disk or
ROLLBACK
if you want to ignore the changes you have made since
the beginning of your transaction.
If you want to switch from AUTOCOMMIT
mode for one series of
statements, you can use the BEGIN
or BEGIN WORK
statement:
BEGIN; SELECT @A:=SUM(salary) FROM table1 WHERE type=1; UPDATE table2 SET summmary=@A WHERE type=1; COMMIT;
Note that if you are using non-transaction-safe tables, the changes will be
stored at once, independent of the status of the autocommit
mode.
If you do a ROLLBACK
when you have updated a non-transactional
table you will get an error (ER_WARNING_NOT_COMPLETE_ROLLBACK
) as
a warning. All transactional safe tables will be restored but any
non-transactional table will not change.
If you are using BEGIN
or SET AUTO_COMMIT=0
, you
should use the MySQL binary log for backups instead of the
old update log; The transaction is stored in the binary log
in one chunk, during COMMIT
, the to ensure and ROLLBACK
:ed
transactions are not stored. See section 22.4 The Binary Log.
The following commands automaticly ends an transaction (as if you had done
a COMMIT
before executing the command):
ALTER TABLE | BEGIN | CREATE INDEX
|
DROP DATABASE | DROP TABLE | RENAME TABLE
|
TRUNCATE
|
LOCK TABLES/UNLOCK TABLES
SyntaxLOCK TABLES tbl_name [AS alias] {READ | [READ LOCAL] | [LOW_PRIORITY] WRITE} [, tbl_name {READ | [LOW_PRIORITY] WRITE} ...] ... UNLOCK TABLES
LOCK TABLES
locks tables for the current thread. UNLOCK
TABLES
releases any locks held by the current thread. All tables that
are locked by the current thread are automatically unlocked when the
thread issues another LOCK TABLES
, or when the connection to the
server is closed.
If a thread obtains a READ
lock on a table, that thread (and all other
threads) can only read from the table. If a thread obtains a WRITE
lock on a table, then only the thread holding the lock can READ
from
or WRITE
to the table. Other threads are blocked.
The difference between READ LOCAL
and READ
is that
READ LOCAL
allows non-conflicting INSERT
statements to
execute while the lock is held. This can't however be used if you are
going to manipulate the database files outside MySQL while you
hold the lock.
Each thread waits (without timing out) until it obtains all the locks it has requested.
WRITE
locks normally have higher priority than READ
locks, to
ensure that updates are processed as soon as possible. This means that if one
thread obtains a READ
lock and then another thread requests a
WRITE
lock, subsequent READ
lock requests will wait until the
WRITE
thread has gotten the lock and released it. You can use
LOW_PRIORITY WRITE
locks to allow other threads to obtain READ
locks while the thread is waiting for the WRITE
lock. You should only
use LOW_PRIORITY WRITE
locks if you are sure that there will
eventually be a time when no threads will have a READ
lock.
When you use LOCK TABLES
, you must lock all tables that you are
going to use and you must use the same alias that you are going to use
in your queries! If you are using a table multiple times in a query
(with aliases), you must get a lock for each alias! This policy ensures
that table locking is deadlock free and makes the locking code smaller,
simpler and much faster.
Note that you should NOT lock any tables that you are using with
INSERT DELAYED
. This is because that in this case the INSERT
is done by a separate thread.
Normally, you don't have to lock tables, as all single UPDATE
statements
are atomic; no other thread can interfere with any other currently executing
SQL statement. There are a few cases when you would like to lock tables
anyway:
READ
-locked table and no other
thread can read a WRITE
-locked table.
LOCK TABES
if you want to ensure that no other thread comes between a
SELECT
and an UPDATE
. The example shown below
requires LOCK TABLES
in order to execute safely:
mysql> LOCK TABLES trans READ, customer WRITE; mysql> select sum(value) from trans where customer_id= some_id; mysql> update customer set total_value=sum_from_previous_statement where customer_id=some_id; mysql> UNLOCK TABLES;Without
LOCK TABLES
, there is a chance that another thread might
insert a new row in the trans
table between execution of the
SELECT
and UPDATE
statements.
By using incremental updates (UPDATE customer SET
value=value+new_value
) or the LAST_INSERT_ID()
function, you can
avoid using LOCK TABLES
in many cases.
You can also solve some cases by using the user-level lock functions
GET_LOCK()
and RELEASE_LOCK()
. These locks are saved in a hash
table in the server and implemented with pthread_mutex_lock()
and
pthread_mutex_unlock()
for high speed.
See section 7.4.12 Miscellaneous Functions.
See section 12.2.8 How MySQL Locks Tables, for more information on locking policy.
You can also lock all tables in all databases with read locks with the
FLUSH TABLES WITH READ LOCK
command. See section 7.26 FLUSH
Syntax (Clearing Caches). This is very
convinient way to get backups if you have a file system, like Veritas,
that can take snapshots in time.
NOTE: LOCK TABLES
is not transaction safe and will
automaticly commit any active transactions before attempting to lock the
tables.
SET
SyntaxSET [OPTION] SQL_VALUE_OPTION= value, ...
SET OPTION
sets various options that affect the operation of the
server or your client. Any option you set remains in effect until the
current session ends, or until you set the option to a different value.
CHARACTER SET character_set_name | DEFAULT
character_set_name
is
cp1251_koi8
, but you can easily add new mappings by editing the
`sql/convert.cc' file in the MySQL source distribution. The
default mapping can be restored by using a character_set_name
value of
DEFAULT
.
Note that the syntax for setting the CHARACTER SET
option differs
from the syntax for setting the other options.
PASSWORD = PASSWORD('some password')
PASSWORD FOR user = PASSWORD('some password')
mysql
database can do this. The user should be
given in user@hostname
format, where user
and hostname
are exactly as they are listed in the User
and Host
columns of
the mysql.user
table entry. For example, if you had an entry with
User
and Host
fields of 'bob'
and '%.loc.gov'
,
you would write:
mysql> SET PASSWORD FOR bob@"%.loc.gov" = PASSWORD("newpass"); or mysql> UPDATE mysql.user SET password=PASSWORD("newpass") where user="bob' and host="%.loc.gov";
SQL_AUTO_IS_NULL = 0 | 1
1
(default) then one can find the last inserted row
for a table with an auto_increment row with the following construct:
WHERE auto_increment_column IS NULL
. This is used by some
ODBC programs like Access.
AUTOCOMMIT= 0 | 1
1
all changes to a table will be done at once. To start
a multi-command transaction, you have to use the BEGIN
statement. See section 7.31 BEGIN/COMMIT/ROLLBACK
Syntax. If set to 0
you have to use COMMIT
/
ROLLBACK
to accept/revoke that transaction. See section 7.31 BEGIN/COMMIT/ROLLBACK
Syntax. Note
that when you change from not AUTOCOMMIT
mode to
AUTOCOMMIT
mode, MySQL will do an automatic
COMMIT
on any open transactions.
SQL_BIG_TABLES = 0 | 1
1
, all temporary tables are stored on disk rather than in
memory. This will be a little slower, but you will not get the error
The table tbl_name is full
for big SELECT
operations that
require a large temporary table. The default value for a new connection is
0
(that is, use in-memory temporary tables).
SQL_BIG_SELECTS = 0 | 1
0
, MySQL will abort if a SELECT
is attempted
that probably will take a very long time. This is useful when an inadvisable
WHERE
statement has been issued. A big query is defined as a
SELECT
that probably will have to examine more than
max_join_size
rows. The default value for a new connection is
1
(which will allow all SELECT
statements).
SQL_BUFFER_RESULT = 0 | 1
SQL_BUFFER_RESULT
will force the result from SELECT
's
to be put into a temporary table. This will help MySQL free the
table locks early and will help in cases where it takes a long time to
send the result set to the client.
SQL_LOW_PRIORITY_UPDATES = 0 | 1
1
, all INSERT
, UPDATE
, DELETE
, and
and LOCK TABLE WRITE
statements wait until there is no pending
SELECT
or LOCK TABLE READ
on the affected table.
SQL_MAX_JOIN_SIZE = value | DEFAULT
SELECT
s that will probably need to examine more than
value
row combinations. By setting this value, you can catch
SELECT
s where keys are not used properly and that would probably
take a long time. Setting this to a value other than DEFAULT
will reset
the SQL_BIG_SELECTS
flag. If you set the SQL_BIG_SELECTS
flag again, the SQL_MAX_JOIN_SIZE
variable will be ignored.
You can set a default value for this variable by starting mysqld
with
-O max_join_size=#
.
SQL_SAFE_MODE = 0 | 1
1
, MySQL will abort if an UPDATE
or
DELETE
is attempted that doesn't use a key or LIMIT
in the
WHERE
clause. This makes it possible to catch wrong updates
when creating SQL commands by hand.
SQL_SELECT_LIMIT = value | DEFAULT
SELECT
statements. If
a SELECT
has a LIMIT
clause, the LIMIT
takes precedence
over the value of SQL_SELECT_LIMIT
. The default value for a new
connection is ``unlimited.'' If you have changed the limit, the default value
can be restored by using a SQL_SELECT_LIMIT
value of DEFAULT
.
SQL_LOG_OFF = 0 | 1
1
, no logging will be done to the standard log for this
client, if the client has the process privilege. This does not
affect the update log!
SQL_LOG_UPDATE = 0 | 1
0
, no logging will be done to the update log for the client,
if the client has the process privilege. This does not affect the
standard log!
SQL_QUOTE_SHOW_CREATE = 0 | 1
1
, SHOW CREATE TABLE
will quote
table and column names. This is on by default,
for replication of tables with fancy column names to work.
section 7.28.8 SHOW CREATE TABLE.
TIMESTAMP = timestamp_value | DEFAULT
LAST_INSERT_ID = #
LAST_INSERT_ID()
. This is stored in
the update log when you use LAST_INSERT_ID()
in a command that updates
a table.
INSERT_ID = #
INSERT
or ALTER TABLE
command when inserting an AUTO_INCREMENT
value. This is mainly used
with the update log.
GRANT
and REVOKE
SyntaxGRANT priv_type [(column_list)] [, priv_type [(column_list)] ...] ON {tbl_name | * | *.* | db_name.*} TO user_name [IDENTIFIED BY 'password'] [, user_name [IDENTIFIED BY 'password'] ...] [WITH GRANT OPTION] REVOKE priv_type [(column_list)] [, priv_type [(column_list)] ...] ON {tbl_name | * | *.* | db_name.*} FROM user_name [, user_name ...]
GRANT
is implemented in MySQL Version 3.22.11 or later. For
earlier MySQL versions, the GRANT
statement does nothing.
The GRANT
and REVOKE
commands allow system administrators to
grant and revoke rights to MySQL users at four privilege levels:
mysql.user
table.
mysql.db
and mysql.host
tables.
mysql.tables_priv
table.
mysql.columns_priv
table.
For examples of how GRANT
works, see section 6.14 Adding New User Privileges to MySQL.
For the GRANT
and REVOKE
statements, priv_type
may be
specified as any of the following:
ALL PRIVILEGES FILE RELOAD ALTER INDEX SELECT CREATE INSERT SHUTDOWN DELETE PROCESS UPDATE DROP REFERENCES USAGE
ALL
is a synonym for ALL PRIVILEGES
. REFERENCES
is not
yet implemented. USAGE
is currently a synonym for ``no privileges.''
It can be used when you want to create a user that has no privileges.
To revoke the grant privilege from a user, use a priv_type
value of GRANT OPTION
:
REVOKE GRANT OPTION ON ... FROM ...;
The only priv_type
values you can specify for a table are SELECT
,
INSERT
, UPDATE
, DELETE
, CREATE
, DROP
,
GRANT
, INDEX
, and ALTER
.
The only priv_type
values you can specify for a column (that is, when
you use a column_list
clause) are SELECT
, INSERT
, and
UPDATE
.
You can set global privileges by using ON *.*
syntax. You can set
database privileges by using ON db_name.*
syntax. If you specify
ON *
and you have a current database, you will set the privileges for
that database. (WARNING: If you specify ON *
and you
don't have a current database, you will affect the global privileges!)
In order to accommodate granting rights to users from arbitrary hosts,
MySQL supports specifying the user_name
value in the form
user@host
. If you want to specify a user
string
containing special characters (such as `-'), or a host
string
containing special characters or wild-card characters (such as `%'), you
can quote the user or host name (for example, 'test-user'@'test-hostname'
).
You can specify wild cards in the hostname. For example,
user@"%.loc.gov"
applies to user
for any host in the
loc.gov
domain, and user@"144.155.166.%"
applies to user
for any host in the 144.155.166
class C subnet.
The simple form user
is a synonym for user@"%"
.
NOTE: If you allow anonymous users to connect to the MySQL
server (which is the default), you should also add all local users as
user@localhost
because otherwise the anonymous user entry for the
local host in the mysql.user
table will be used when the user tries to
log into the MySQL server from the local machine! Anonymous users
are defined by inserting entries with User=''
into the
mysql.user
table. You can verify if this applies to you by executing
this query:
mysql> SELECT Host,User FROM mysql.user WHERE User='';
For the moment, GRANT
only supports host, table, database, and
column names up to 60 characters long. A user name can be up to 16
characters.
The privileges for a table or column are formed from the
logical OR of the privileges at each of the four privilege
levels. For example, if the mysql.user
table specifies that a
user has a global select privilege, this can't be denied by an
entry at the database, table, or column level.
The privileges for a column can be calculated as follows:
global privileges OR (database privileges AND host privileges) OR table privileges OR column privileges
In most cases, you grant rights to a user at only one of the privilege levels, so life isn't normally as complicated as above. The details of the privilege-checking procedure are presented in section 6 The MySQL Access Privilege System.
If you grant privileges for a user/hostname combination that does not exist
in the mysql.user
table, an entry is added and remains there until
deleted with a DELETE
command. In other words, GRANT
may
create user
table entries, but REVOKE
will not remove them;
you must do that explicitly using DELETE
.
In MySQL Version 3.22.12 or later,
if a new user is created or if you have global grant privileges, the user's
password will be set to the password specified by the IDENTIFIED BY
clause, if one is given. If the user already had a password, it is replaced
by the new one.
WARNING: If you create a new user but do not specify an
IDENTIFIED BY
clause, the user has no password. This is insecure.
Passwords can also be set with the SET PASSWORD
command.
See section 7.33 SET
Syntax.
If you grant privileges for a database, an entry in the mysql.db
table is created if needed. When all privileges for the database have been
removed with REVOKE
, this entry is deleted.
If a user doesn't have any privileges on a table, the table is not displayed
when the user requests a list of tables (for example, with a SHOW TABLES
statement).
The WITH GRANT OPTION
clause gives the user the ability to give
to other users any privileges the user has at the specified privilege level.
You should be careful to whom you give the grant privilege, as two
users with different privileges may be able to join privileges!
You cannot grant another user a privilege you don't have yourself; the grant privilege allows you to give away only those privileges you possess.
Be aware that when you grant a user the grant privilege at a
particular privilege level, any privileges the user already possesses (or
is given in the future!) at that level are also grantable by that user.
Suppose you grant a user the insert privilege on a database. If
you then grant the select privilege on the database and specify
WITH GRANT OPTION
, the user can give away not only the select
privilege, but also insert. If you then grant the update
privilege to the user on the database, the user can give away the
insert, select and update.
You should not grant alter privileges to a normal user. If you do that, the user can try to subvert the privilege system by renaming tables!
Note that if you are using table or column privileges for even one user, the server examines table and column privileges for all users and this will slow down MySQL a bit.
When mysqld
starts, all privileges are read into memory.
Database, table, and column privileges take effect at once, and
user-level privileges take effect the next time the user connects.
Modifications to the grant tables that you perform using GRANT
or
REVOKE
are noticed by the server immediately.
If you modify the grant tables manually (using INSERT
, UPDATE
,
etc.), you should execute a FLUSH PRIVILEGES
statement or run
mysqladmin flush-privileges
to tell the server to reload the grant
tables.
See section 6.12 When Privilege Changes Take Effect.
The biggest differences between the ANSI SQL and MySQL versions of
GRANT
are:
TRIGGER
, EXECUTE
or
UNDER
privileges.
INSERT
grant on only part of the
columns in a table, you can execute INSERT
statements on the
table; The columns for which you don't have the INSERT
privilege
will set to their default values. ANSI SQL requires you to have the
INSERT
privilege on all columns.
REVOKE
commands or by manipulating the
MySQL grant tables.
CREATE INDEX
SyntaxCREATE [UNIQUE|FULLTEXT] INDEX index_name ON tbl_name (col_name[(length)],... )
The CREATE INDEX
statement doesn't do anything in MySQL prior
to Version 3.22. In Version 3.22 or later, CREATE INDEX
is mapped to an
ALTER TABLE
statement to create indexes.
See section 7.8 ALTER TABLE
Syntax.
Normally, you create all indexes on a table at the time the table itself
is created with CREATE TABLE
.
See section 7.7 CREATE TABLE
Syntax.
CREATE INDEX
allows you to add indexes to existing tables.
A column list of the form (col1,col2,...)
creates a multiple-column
index. Index values are formed by concatenating the values of the given
columns.
For CHAR
and VARCHAR
columns, indexes can be created that
use only part of a column, using col_name(length)
syntax. (On
BLOB
and TEXT
columns the length is required). The
statement shown below creates an index using the first 10 characters of
the name
column:
mysql> CREATE INDEX part_of_name ON customer (name(10));
Because most names usually differ in the first 10 characters, this index should
not be much slower than an index created from the entire name
column.
Also, using partial columns for indexes can make the index file much smaller,
which could save a lot of disk space and might also speed up INSERT
operations!
Note that you can only add an index on a column that can have NULL
values or on a BLOB
/TEXT
column if you are using
MySQL Version 3.23.2 or newer and are using the MyISAM
table type.
For more information about how MySQL uses indexes, see section 12.4 How MySQL Uses Indexes.
FULLTEXT
indexes can index only VARCHAR
and
TEXT
columns, and only in MyISAM
tables. FULLTEXT
indexes
are available in MySQL Version 3.23.23 and later.
section 25.2 MySQL Full-text Search.
DROP INDEX
SyntaxDROP INDEX index_name ON tbl_name
DROP INDEX
drops the index named index_name
from the table
tbl_name
. DROP INDEX
doesn't do anything in MySQL
prior to Version 3.22. In Version 3.22 or later, DROP INDEX
is mapped to an
ALTER TABLE
statement to drop the index.
See section 7.8 ALTER TABLE
Syntax.
The MySQL server supports the # to end of line
, --
to end of line
and /* in-line or multiple-line */
comment
styles:
mysql> select 1+1; # This comment continues to the end of line mysql> select 1+1; -- This comment continues to the end of line mysql> select 1 /* this is an in-line comment */ + 1; mysql> select 1+ /* this is a multiple-line comment */ 1;
Note that the --
comment style requires you to have at least one space
after the --
!
Although the server understands the comment syntax just described,
there are some limitations on the way that the mysql
client
parses /* ... */
comments:
mysql
interactively, you can tell that it
has gotten confused like this because the prompt changes from mysql>
to '>
or ">
.
These limitations apply both when you run mysql
interactively
and when you put commands in a file and tell mysql
to read its
input from that file with mysql < some-file
.
MySQL doesn't support the `--' ANSI SQL comment style. See section 5.4.7 `--' as the Start of a Comment.
CREATE FUNCTION/DROP FUNCTION
SyntaxCREATE [AGGREGATE] FUNCTION function_name RETURNS {STRING|REAL|INTEGER} SONAME shared_library_name DROP FUNCTION function_name
A user-definable function (UDF) is a way to extend MySQL with a new
function that works like native (built in) MySQL functions such as
ABS()
and CONCAT()
.
AGGREGATE
is a new option for MySQL Version 3.23. An
AGGREGATE
function works exactly like a native MySQL
GROUP
function like SUM
or COUNT()
.
CREATE FUNCTION
saves the function's name, type, and shared library
name in the mysql.func
system table. You must have the
insert and delete privileges for the mysql
database
to create and drop functions.
All active functions are reloaded each time the server starts, unless
you start mysqld
with the --skip-grant-tables
option. In
this case, UDF initialization is skipped and UDFs are unavailable.
(An active function is one that has been loaded with CREATE FUNCTION
and not removed with DROP FUNCTION
.)
For instructions on writing user-definable functions, see section 16 Adding New Functions to MySQL. For the UDF mechanism to work, functions must be written in C or
C++, your operating system must support dynamic loading and you must have
compiled mysqld
dynamically (not statically).
A common problem stems from trying to create a table with column names that
use the names of datatypes or functions built into MySQL, such as
TIMESTAMP
or GROUP
. You're allowed to do it (for example,
ABS
is an allowed column name), but whitespace is not allowed between
a function name and the `(' when using functions whose names are also
column names.
The following words are explicitly reserved in MySQL. Most of
them are forbidden by ANSI SQL92 as column and/or table names
(for example, group
).
A few are reserved because MySQL needs them and is
(currently) using a yacc
parser:
action | add | aggregate | all
|
alter | after | and | as
|
asc | avg | avg_row_length | auto_increment
|
between | bigint | bit | binary
|
blob | bool | both | by
|
cascade | case | char | character
|
change | check | checksum | column
|
columns | comment | constraint | create
|
cross | current_date | current_time | current_timestamp
|
data | database | databases | date
|
datetime | day | day_hour | day_minute
|
day_second | dayofmonth | dayofweek | dayofyear
|
dec | decimal | default | delayed
|
delay_key_write | delete | desc | describe
|
distinct | distinctrow | double | drop
|
end | else | escape | escaped
|
enclosed | enum | explain | exists
|
fields | file | first | float
|
float4 | float8 | flush | foreign
|
from | for | full | function
|
global | grant | grants | group
|
having | heap | high_priority | hour
|
hour_minute | hour_second | hosts | identified
|
ignore | in | index | infile
|
inner | insert | insert_id | int
|
integer | interval | int1 | int2
|
int3 | int4 | int8 | into
|
if | is | isam | join
|
key | keys | kill | last_insert_id
|
leading | left | length | like
|
lines | limit | load | local
|
lock | logs | long | longblob
|
longtext | low_priority | max | max_rows
|
match | mediumblob | mediumtext | mediumint
|
middleint | min_rows | minute | minute_second
|
modify | month | monthname | myisam
|
natural | numeric | no | not
|
null | on | optimize | option
|
optionally | or | order | outer
|
outfile | pack_keys | partial | password
|
precision | primary | procedure | process
|
processlist | privileges | read | real
|
references | reload | regexp | rename
|
replace | restrict | returns | revoke
|
rlike | row | rows | second
|
select | set | show | shutdown
|
smallint | soname | sql_big_tables | sql_big_selects
|
sql_low_priority_updates | sql_log_off | sql_log_update | sql_select_limit
|
sql_small_result | sql_big_result | sql_warnings | straight_join
|
starting | status | string | table
|
tables | temporary | terminated | text
|
then | time | timestamp | tinyblob
|
tinytext | tinyint | trailing | to
|
type | use | using | unique
|
unlock | unsigned | update | usage
|
values | varchar | variables | varying
|
varbinary | with | write | when
|
where | year | year_month | zerofill
|
The following symbols (from the table above) are disallowed by ANSI SQL but allowed by MySQL as column/table names. This is because some of these names are very natural names and a lot of people have already used them.
ACTION
BIT
DATE
ENUM
NO
TEXT
TIME
TIMESTAMP
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