Table 11.17. Information Functions
Name | Description |
---|---|
BENCHMARK() |
Repeatedly execute an expression |
CHARSET() (v4.1.0) |
Return the character set of the argument |
COERCIBILITY() (v4.1.1) |
Return the collation coercibility value of the string argument |
COLLATION() (v4.1.0) |
Return the collation of the string argument |
CONNECTION_ID() |
Return the connection ID (thread ID) for the connection |
CURRENT_USER() , CURRENT_USER |
The authenticated user name and host name |
DATABASE() |
Return the default (current) database name |
FOUND_ROWS() |
For a SELECT with a LIMIT clause, the number of rows that would be returned were there no LIMIT clause |
LAST_INSERT_ID() |
Value of the AUTOINCREMENT column for the last INSERT |
ROW_COUNT() (v5.0.1) |
The number of rows updated |
SCHEMA() (v5.0.2) |
A synonym for DATABASE() |
SESSION_USER() |
Synonym for USER() |
SYSTEM_USER() |
Synonym for USER() |
USER() |
The user name and host name provided by the client |
VERSION() |
Returns a string that indicates the MySQL server version |
The BENCHMARK()
function
executes the expression expr
repeatedly count
times. It may be
used to time how quickly MySQL processes the expression. The
result value is always 0
. The intended
use is from within 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 is advisable to execute
BENCHMARK()
several times,
and to interpret the result with regard to how heavily
loaded the server machine is.
BENCHMARK()
is intended for
measuring the runtime performance of scalar expressions,
which has some significant implications for the way that you
use it and interpret the results:
Only scalar expressions can be used. Although the
expression can be a subquery, it must return a single
column and at most a single row. For example,
BENCHMARK(10, (SELECT * FROM
t))
will fail if the table
t
has more than one column or more
than one row.
Executing a SELECT
statement
expr
N
times differs from
executing SELECT
BENCHMARK(
in terms of
the amount of overhead involved. The two have very
different execution profiles and you should not expect
them to take the same amount of time. The former
involves the parser, optimizer, table locking, and
runtime evaluation N
,
expr
)N
times
each. The latter involves only runtime evaluation
N
times, and all the other
components just once. Memory structures already
allocated are reused, and runtime optimizations such as
local caching of results already evaluated for aggregate
functions can alter the results. Use of
BENCHMARK()
thus measures
performance of the runtime component by giving more
weight to that component and removing the
“noise” introduced by the network, parser,
optimizer, and so forth.
Returns the character set of the string argument.
mysql>SELECT CHARSET('abc');
-> 'latin1' mysql>SELECT CHARSET(CONVERT('abc' USING utf8));
-> 'utf8' mysql>SELECT CHARSET(USER());
-> 'utf8'
Returns the collation coercibility value of the string argument.
mysql>SELECT COERCIBILITY('abc' COLLATE latin1_swedish_ci);
-> 0 mysql>SELECT COERCIBILITY(USER());
-> 3 mysql>SELECT COERCIBILITY('abc');
-> 4
The return values have the meanings shown in the following table. Lower values have higher precedence.
Coercibility | Meaning | Example |
0 |
Explicit collation | Value with COLLATE clause |
1 |
No collation | Concatenation of strings with different collations |
2 |
Implicit collation | Column value |
3 |
System constant |
USER() return value |
4 |
Coercible | Literal string |
5 |
Ignorable |
NULL or an expression derived from
NULL
|
Before MySQL 5.0.3, the return values are shown as follows,
and functions such as USER()
have a coercibility of 2:
Coercibility | Meaning | Example |
0 |
Explicit collation | Value with COLLATE clause |
1 |
No collation | Concatenation of strings with different collations |
2 |
Implicit collation | Column value, stored routine parameter or local variable |
3 |
Coercible | Literal string |
Returns the collation of the string argument.
mysql>SELECT COLLATION('abc');
-> 'latin1_swedish_ci' mysql>SELECT COLLATION(_utf8'abc');
-> 'utf8_general_ci'
Returns the connection ID (thread ID) for the connection. Every connection has an ID that is unique among the set of currently connected clients.
mysql> SELECT CONNECTION_ID();
-> 23786
Returns the user name and host name combination for the
MySQL account that the server used to authenticate the
current client. This account determines your access
privileges. The return value is a string in the
utf8
character set.
The value of CURRENT_USER()
can differ from the value of
USER()
.
mysql>SELECT USER();
-> 'davida@localhost' mysql>SELECT * FROM mysql.user;
ERROR 1044: Access denied for user ''@'localhost' to database 'mysql' mysql>SELECT CURRENT_USER();
-> '@localhost'
The example illustrates that although the client specified a
user name of davida
(as indicated by the
value of the USER()
function), the server authenticated the client using an
anonymous user account (as seen by the empty user name part
of the CURRENT_USER()
value).
One way this might occur is that there is no account listed
in the grant tables for davida
.
Within a stored program or view,
CURRENT_USER()
returns the
account for the user who defined the object (as given by its
DEFINER
value). This applies to stored
programs as of MySQL 5.0.10 and to views as of MySQL 5.0.24.
(For older versions,
CURRENT_USER()
returns the
account for the object's invoker.) For stored procedures and
functions and views defined with the SQL SECURITY
INVOKER
characteristic,
CURRENT_USER()
returns the
object's invoker.
Returns the default (current) database name as a string in
the utf8
character set. If there is no
default database, DATABASE()
returns NULL
. Within a stored routine,
the default database is the database that the routine is
associated with, which is not necessarily the same as the
database that is the default in the calling context.
mysql> SELECT DATABASE();
-> 'test'
A SELECT
statement may
include a LIMIT
clause to restrict the
number of rows the server returns to the client. In some
cases, it is desirable to know how many rows the statement
would have returned without the LIMIT
,
but without running the statement again. To obtain this row
count, include a SQL_CALC_FOUND_ROWS
option in the SELECT
statement, and then invoke
FOUND_ROWS()
afterward:
mysql>SELECT SQL_CALC_FOUND_ROWS * FROM
->tbl_name
WHERE id > 100 LIMIT 10;
mysql>SELECT FOUND_ROWS();
The second SELECT
returns a
number indicating how many rows the first
SELECT
would have returned
had it been written without the LIMIT
clause.
In the absence of the SQL_CALC_FOUND_ROWS
option in the most recent successful
SELECT
statement,
FOUND_ROWS()
returns the
number of rows in the result set returned by that statement.
If the statement includes a LIMIT
clause,
FOUND_ROWS()
returns the
number of rows up to the limit. For example,
FOUND_ROWS()
returns 10 or
60, respectively, if the statement includes LIMIT
10
or LIMIT 50, 10
.
The row count available through
FOUND_ROWS()
is transient and
not intended to be available past the statement following
the SELECT SQL_CALC_FOUND_ROWS
statement.
If you need to refer to the value later, save it:
mysql>SELECT SQL_CALC_FOUND_ROWS * FROM ... ;
mysql>SET @rows = FOUND_ROWS();
If you are using SELECT
SQL_CALC_FOUND_ROWS
, MySQL must calculate how many
rows are in the full result set. However, this is faster
than running the query again without
LIMIT
, because the result set need not be
sent to the client.
SQL_CALC_FOUND_ROWS
and
FOUND_ROWS()
can be useful in
situations when you want to restrict the number of rows that
a query returns, but also determine the number of rows in
the full result set without running the query again. An
example is a Web script that presents a paged display
containing links to the pages that show other sections of a
search result. Using
FOUND_ROWS()
allows you to
determine how many other pages are needed for the rest of
the result.
The use of SQL_CALC_FOUND_ROWS
and
FOUND_ROWS()
is more complex
for UNION
statements than for
simple SELECT
statements,
because LIMIT
may occur at multiple
places in a UNION
. It may be
applied to individual SELECT
statements in the UNION
, or
global to the UNION
result as
a whole.
The intent of SQL_CALC_FOUND_ROWS
for
UNION
is that it should
return the row count that would be returned without a global
LIMIT
. The conditions for use of
SQL_CALC_FOUND_ROWS
with
UNION
are:
The SQL_CALC_FOUND_ROWS
keyword must
appear in the first
SELECT
of the
UNION
.
The value of FOUND_ROWS()
is exact only if
UNION
ALL
is used. If
UNION
without
ALL
is used, duplicate removal occurs
and the value of
FOUND_ROWS()
is only
approximate.
If no LIMIT
is present in the
UNION
,
SQL_CALC_FOUND_ROWS
is ignored and
returns the number of rows in the temporary table that
is created to process the
UNION
.
Beyond the cases described here, the behavior of
FOUND_ROWS()
is undefined
(for example, its value following a
SELECT
statement that fails
with an error).
FOUND_ROWS()
is not
replicated reliably, and should not be used with databases
that are to be replicated.
LAST_INSERT_ID()
,
LAST_INSERT_ID(
expr
)
LAST_INSERT_ID()
(with no
argument) returns the first
automatically generated value that was set for an
AUTO_INCREMENT
column by the
most recently executed
INSERT
statement to affect
such a column. For example, after inserting a row that
generates an AUTO_INCREMENT
value, you
can get the value like this:
mysql> SELECT LAST_INSERT_ID();
-> 195
if a table contains an AUTO_INCREMENT
column and
INSERT
... ON DUPLICATE KEY UPDATE
updates (rather than
inserts) a row, the value of
LAST_INSERT_ID()
is not
meaningful. For a workaround, see
Section 12.2.5.3, “INSERT ... ON
DUPLICATE KEY UPDATE
Syntax”.
The currently executing statement does not affect the value
of LAST_INSERT_ID()
. Suppose
that you generate an AUTO_INCREMENT
value
with one statement, and then refer to
LAST_INSERT_ID()
in a
multiple-row INSERT
statement
that inserts rows into a table with its own
AUTO_INCREMENT
column. The value of
LAST_INSERT_ID()
will remain
stable in the second statement; its value for the second and
later rows is not affected by the earlier row insertions.
(However, if you mix references to
LAST_INSERT_ID()
and
LAST_INSERT_ID(
,
the effect is undefined.)
expr
)
If the previous statement returned an error, the value of
LAST_INSERT_ID()
is
undefined. For transactional tables, if the statement is
rolled back due to an error, the value of
LAST_INSERT_ID()
is left
undefined. For manual
ROLLBACK
,
the value of LAST_INSERT_ID()
is not restored to that before the transaction; it remains
as it was at the point of the
ROLLBACK
.
Within the body of a stored routine (procedure or function)
or a trigger, the value of
LAST_INSERT_ID()
changes the
same way as for statements executed outside the body of
these kinds of objects. The effect of a stored routine or
trigger upon the value of
LAST_INSERT_ID()
that is seen
by following statements depends on the kind of routine:
If a stored procedure executes statements that change
the value of
LAST_INSERT_ID()
, the
changed value will be seen by statements that follow the
procedure call.
For stored functions and triggers that change the value, the value is restored when the function or trigger ends, so following statements will not see a changed value.
The ID that was generated is maintained in the server on a
per-connection basis. This means that
the value returned by the function to a given client is the
first AUTO_INCREMENT
value generated for
most recent statement affecting an
AUTO_INCREMENT
column by that
client. This value cannot be affected by other
clients, even if they generate
AUTO_INCREMENT
values of their own. This
behavior ensures that each client can retrieve its own ID
without concern for the activity of other clients, and
without the need for locks or transactions.
The value of LAST_INSERT_ID()
is not changed if you set the
AUTO_INCREMENT
column of a row to a
non-“magic” value (that is, a value that is not
NULL
and not 0
).
If you insert multiple rows using a single
INSERT
statement,
LAST_INSERT_ID()
returns
the value generated for the first
inserted row only. The reason for
this is to make it possible to reproduce easily the same
INSERT
statement against
some other server.
For example:
mysql>USE test;
Database changed mysql>CREATE TABLE t (
->id INT AUTO_INCREMENT NOT NULL PRIMARY KEY,
->name VARCHAR(10) NOT NULL
->);
Query OK, 0 rows affected (0.09 sec) mysql>INSERT INTO t VALUES (NULL, 'Bob');
Query OK, 1 row affected (0.01 sec) mysql>SELECT * FROM t;
+----+------+ | id | name | +----+------+ | 1 | Bob | +----+------+ 1 row in set (0.01 sec) mysql>SELECT LAST_INSERT_ID();
+------------------+ | LAST_INSERT_ID() | +------------------+ | 1 | +------------------+ 1 row in set (0.00 sec) mysql>INSERT INTO t VALUES
->(NULL, 'Mary'), (NULL, 'Jane'), (NULL, 'Lisa');
Query OK, 3 rows affected (0.00 sec) Records: 3 Duplicates: 0 Warnings: 0 mysql> SELECT * FROM t; +----+------+ | id | name | +----+------+ | 1 | Bob | | 2 | Mary | | 3 | Jane | | 4 | Lisa | +----+------+ 4 rows in set (0.01 sec) mysql>SELECT LAST_INSERT_ID();
+------------------+ | LAST_INSERT_ID() | +------------------+ | 2 | +------------------+ 1 row in set (0.00 sec)
Although the second INSERT
statement inserted three new rows into t
,
the ID generated for the first of these rows was
2
, and it is this value that is returned
by LAST_INSERT_ID()
for the
following SELECT
statement.
If you use INSERT
IGNORE
and the row is ignored, the
AUTO_INCREMENT
counter is not incremented
and LAST_INSERT_ID()
returns
0
, which reflects that no row was
inserted.
If expr
is given as an argument
to LAST_INSERT_ID()
, the
value of the argument is returned by the function and is
remembered as the next value to be returned by
LAST_INSERT_ID()
. This can be
used to simulate sequences:
Create a table to hold the sequence counter and initialize it:
mysql>CREATE TABLE sequence (id INT NOT NULL);
mysql>INSERT INTO sequence VALUES (0);
Use the table to generate sequence numbers like this:
mysql>UPDATE sequence SET id=LAST_INSERT_ID(id+1);
mysql>SELECT LAST_INSERT_ID();
The UPDATE
statement
increments the sequence counter and causes the next call
to LAST_INSERT_ID()
to
return the updated value. The
SELECT
statement
retrieves that value. The
mysql_insert_id()
C API
function can also be used to get the value. See
Section 20.8.3.37, “mysql_insert_id()
”.
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. It is multi-user safe because multiple
clients can issue the UPDATE
statement and get their own sequence value with the
SELECT
statement (or
mysql_insert_id()
), without
affecting or being affected by other clients that generate
their own sequence values.
Note that mysql_insert_id()
is only updated after INSERT
and UPDATE
statements, so you
cannot use the C API function to retrieve the value for
LAST_INSERT_ID(
after executing other SQL statements like
expr
)SELECT
or
SET
.
ROW_COUNT()
returns the
number of rows updated, inserted, or deleted by the
preceding statement. This is the same as the row count that
the mysql client displays and the value
from the
mysql_affected_rows()
C API
function.
mysql>INSERT INTO t VALUES(1),(2),(3);
Query OK, 3 rows affected (0.00 sec) Records: 3 Duplicates: 0 Warnings: 0 mysql>SELECT ROW_COUNT();
+-------------+ | ROW_COUNT() | +-------------+ | 3 | +-------------+ 1 row in set (0.00 sec) mysql>DELETE FROM t WHERE i IN(1,2);
Query OK, 2 rows affected (0.00 sec) mysql>SELECT ROW_COUNT();
+-------------+ | ROW_COUNT() | +-------------+ | 2 | +-------------+ 1 row in set (0.00 sec)
ROW_COUNT()
was added in
MySQL 5.0.1.
ROW_COUNT()
is not
replicated reliably.
This function is a synonym for
DATABASE()
. It was added in
MySQL 5.0.2.
SESSION_USER()
is a synonym
for USER()
.
SYSTEM_USER()
is a synonym
for USER()
.
Returns the current MySQL user name and host name as a
string in the utf8
character set.
mysql> SELECT USER();
-> 'davida@localhost'
The value indicates the user name you specified when
connecting to the server, and the client host from which you
connected. The value can be different from that of
CURRENT_USER()
.
You can extract only the user name part like this:
mysql> SELECT SUBSTRING_INDEX(USER(),'@',1);
-> 'davida'
Returns a string that indicates the MySQL server version.
The string uses the utf8
character set.
mysql> SELECT VERSION();
-> '5.0.91-standard'
Note that if your version string ends with
-log
this means that logging is enabled.
User Comments
I was issuing my query "select sql_calc_found_rows statement1 union statement2 union statement3 limit whatever" and getting a count from found_rows() that was incorrect. It was running as if I had run the query as "union all" because it was returning duplicates. After rereading the union syntax page I reissued the query with parens around each individual statement. "(select sql_calc_found_rows statement1) union (statement2) union (statement3) limit whatever" This yielded the expected result.
Hi,
if you want to perform a complex benchmark, you need to put doble quotes around your expression:
SELECT BENCHMARK(1000000, "ENCODE('hello','goodbye')");
And remember to but a SELECT in front of BENCHMARK.
The above reads "If the preceding SELECT statement does not include the SQL_CALC_FOUND_ROWS option, then FOUND_ROWS() may return a different result when LIMIT is used than when it is not."
The word "may" seems to be an understatement. Everytime I run a SELECT with LIMIT, FOUND_ROWS() returns whatever number I put after LIMIT. E.g. after
SELECT * FROM table LIMIT 50
FOUND_ROWS() will return 50.
But if I do
SELECT * FROM table LIMIT 10, 10,
FOUND_ROWS() will return 20 though. :)
This is annoying, since I need this information from a 20,000-row table fulltext search, and a 0,008 second search then suddenly takes about 20 seconds... Haven't found a workaround yet...
This is the desired result though, as:
SELECT * FROM table LIMIT 50
FOUND_ROWS() will return 50 cause it actually found 50 entries in the table before it stopped and returned the result
But if I do
SELECT * FROM table LIMIT 10, 10,
FOUND_ROWS() will return 20 cause it had to find the first 10 you skipped over, then the second 10 it returned to you, so it found 20 entries before stopping and giving you the result
Be aware that using SQL_CALC_FOUND_ROWS and FOUND_ROWS() disables ORDER BY ... LIMIT optimizations (see bugs http://bugs.mysql.com/bug.php?id=18454 and http://bugs.mysql.com/bug.php?id=19553). Until it's fixed, you should run your own benchmarks with and without it.
The text says "include a SQL_CALC_FOUND_ROWS option in the SELECT statement". What it doesn't say is that SQL_CALC_FOUND_ROWS must be at the front of any fields in the SELECT statement!
An alternative to the previously discussed issue:
SELECT * FROM table LIMIT 10, 10,
FOUND_ROWS() will return 20
If rows are counted from the client, the "expected" number of rows can be calcualted. This, of course, requires that the result set is passed to the client.
about "LIMIT 10,10" issue...
manual says:
"... The intent of SQL_CALC_FOUND_ROWS for UNION is that it should return the row count that would be returned without a global LIMIT."
though that means 'select * from tableX limit 50' returns 50 as a result of 'Found_rows()' just because tableX has 50 records, and 'select * from tableX limit 10,10' will return also 50 and not 10 or 20 as a result!
and don't forget use SQL_CALC_FOUND_ROWS modifier.
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