Table of Contents
This chapter discusses stored database objects that are defined in terms of SQL code that is stored on the server for later execution.
Stored objects include these object types:
Stored procedure: An object created with
CREATE PROCEDURE and invoked
using the CALL statement. A
procedure does not have a return value but can modify its
parameters for later inspection by the caller. It can also
generate result sets to be returned to the client program.
Stored function: An object created with
CREATE FUNCTION and used much
like a built-in function. You invoke it in an expression and it
returns a value during expression evaluation.
Trigger: An object created with CREATE
TRIGGER that is associated with a table. A trigger is
activated when a particular event occurs for the table, such as
an insert or update.
Event: An object created with CREATE
EVENT and invoked by the server according to schedule.
View: An object created with CREATE
VIEW that when referenced produces a result set. A
view acts as a virtual table.
Terminology used in this document reflects the stored object hierarchy:
Stored routines include stored procedures and functions.
Stored programs include stored routines, triggers, and events.
Stored objects include stored programs and views.
This chapter describes how to use stored objects. The following sections provide additional information about SQL syntax for statements related to these objects, and about object processing:
For each object type, there are CREATE,
ALTER, and DROP statements
that control which objects exist and how they are defined. See
Section 13.1, “Data Definition Statements”.
The CALL statement is used to
invoke stored procedures. See Section 13.2.1, “CALL Statement”.
Stored program definitions include a body that may use compound statements, loops, conditionals, and declared variables. See Section 13.6, “Compound Statements”.
Metadata changes to objects referred to by stored programs are detected and cause automatic reparsing of the affected statements when the program is next executed. For more information, see Section 8.10.4, “Caching of Prepared Statements and Stored Programs”.
Each stored program contains a body that consists of an SQL
statement. This statement may be a compound statement made up of
several statements separated by semicolon (;)
characters. For example, the following stored procedure has a body
made up of a BEGIN ...
END block that contains a
SET
statement and a REPEAT loop that
itself contains another
SET
statement:
CREATE PROCEDURE dorepeat(p1 INT) BEGIN SET @x = 0; REPEAT SET @x = @x + 1; UNTIL @x > p1 END REPEAT; END;
If you use the mysql client program to define a stored program containing semicolon characters, a problem arises. By default, mysql itself recognizes the semicolon as a statement delimiter, so you must redefine the delimiter temporarily to cause mysql to pass the entire stored program definition to the server.
To redefine the mysql delimiter, use the
delimiter command. The following example shows
how to do this for the dorepeat() procedure
just shown. The delimiter is changed to // to
enable the entire definition to be passed to the server as a
single statement, and then restored to ; before
invoking the procedure. This enables the ;
delimiter used in the procedure body to be passed through to the
server rather than being interpreted by mysql
itself.
mysql>delimiter //mysql>CREATE PROCEDURE dorepeat(p1 INT)->BEGIN->SET @x = 0;->REPEAT SET @x = @x + 1; UNTIL @x > p1 END REPEAT;->END->//Query OK, 0 rows affected (0.00 sec) mysql>delimiter ;mysql>CALL dorepeat(1000);Query OK, 0 rows affected (0.00 sec) mysql>SELECT @x;+------+ | @x | +------+ | 1001 | +------+ 1 row in set (0.00 sec)
You can redefine the delimiter to a string other than
//, and the delimiter can consist of a single
character or multiple characters. You should avoid the use of the
backslash (\) character because that is the
escape character for MySQL.
The following is an example of a function that takes a parameter,
performs an operation using an SQL function, and returns the
result. In this case, it is unnecessary to use
delimiter because the function definition
contains no internal ; statement delimiters:
mysql>CREATE FUNCTION hello (s CHAR(20))mysql>RETURNS CHAR(50) DETERMINISTIC->RETURN CONCAT('Hello, ',s,'!');Query OK, 0 rows affected (0.00 sec) mysql>SELECT hello('world');+----------------+ | hello('world') | +----------------+ | Hello, world! | +----------------+ 1 row in set (0.00 sec)
MySQL supports stored routines (procedures and functions). A stored routine is a set of SQL statements that can be stored in the server. Once this has been done, clients don't need to keep reissuing the individual statements but can refer to the stored routine instead.
Stored routines require the proc table in the
mysql database. This table is created during the
MySQL installation procedure. If you are upgrading to MySQL
5.7 from an earlier version, be sure to update your
grant tables to make sure that the proc table
exists. See Section 4.4.7, “mysql_upgrade — Check and Upgrade MySQL Tables”.
Stored routines can be particularly useful in certain situations:
When multiple client applications are written in different languages or work on different platforms, but need to perform the same database operations.
When security is paramount. Banks, for example, use stored procedures and functions for all common operations. This provides a consistent and secure environment, and routines can ensure that each operation is properly logged. In such a setup, applications and users would have no access to the database tables directly, but can only execute specific stored routines.
Stored routines can provide improved performance because less information needs to be sent between the server and the client. The tradeoff is that this does increase the load on the database server because more of the work is done on the server side and less is done on the client (application) side. Consider this if many client machines (such as Web servers) are serviced by only one or a few database servers.
Stored routines also enable you to have libraries of functions in the database server. This is a feature shared by modern application languages that enable such design internally (for example, by using classes). Using these client application language features is beneficial for the programmer even outside the scope of database use.
MySQL follows the SQL:2003 syntax for stored routines, which is also used by IBM's DB2. All syntax described here is supported and any limitations and extensions are documented where appropriate.
You may find the Stored Procedures User Forum of use when working with stored procedures and functions.
For answers to some commonly asked questions regarding stored routines in MySQL, see Section A.4, “MySQL 5.7 FAQ: Stored Procedures and Functions”.
There are some restrictions on the use of stored routines. See Section 23.8, “Restrictions on Stored Programs”.
Binary logging for stored routines takes place as described in Section 23.7, “Stored Program Binary Logging”.
A stored routine is either a procedure or a function. Stored
routines are created with the CREATE
PROCEDURE and CREATE
FUNCTION statements (see
Section 13.1.16, “CREATE PROCEDURE and CREATE FUNCTION Statements”). A procedure is invoked using
a CALL statement (see
Section 13.2.1, “CALL Statement”), and can only pass back values using
output variables. A function can be called from inside a statement
just like any other function (that is, by invoking the function's
name), and can return a scalar value. The body of a stored routine
can use compound statements (see
Section 13.6, “Compound Statements”).
Stored routines can be dropped with the DROP
PROCEDURE and DROP
FUNCTION statements (see
Section 13.1.27, “DROP PROCEDURE and DROP FUNCTION Statements”), and altered with the
ALTER PROCEDURE and
ALTER FUNCTION statements (see
Section 13.1.6, “ALTER PROCEDURE Statement”).
A stored procedure or function is associated with a particular database. This has several implications:
When the routine is invoked, an implicit USE
is performed (and
undone when the routine terminates).
db_nameUSE statements within stored
routines are not permitted.
You can qualify routine names with the database name. This can
be used to refer to a routine that is not in the current
database. For example, to invoke a stored procedure
p or function f that is
associated with the test database, you can
say CALL test.p() or
test.f().
When a database is dropped, all stored routines associated with it are dropped as well.
Stored functions cannot be recursive.
Recursion in stored procedures is permitted but disabled by
default. To enable recursion, set the
max_sp_recursion_depth server
system variable to a value greater than zero. Stored procedure
recursion increases the demand on thread stack space. If you
increase the value of
max_sp_recursion_depth, it may be
necessary to increase thread stack size by increasing the value of
thread_stack at server startup.
See Section 5.1.7, “Server System Variables”, for more
information.
MySQL supports a very useful extension that enables the use of
regular SELECT statements (that is,
without using cursors or local variables) inside a stored
procedure. The result set of such a query is simply sent directly
to the client. Multiple SELECT
statements generate multiple result sets, so the client must use a
MySQL client library that supports multiple result sets. This
means the client must use a client library from a version of MySQL
at least as recent as 4.1. The client should also specify the
CLIENT_MULTI_RESULTS option when it connects.
For C programs, this can be done with the
mysql_real_connect() C API
function. See Section 27.7.6.54, “mysql_real_connect()”, and
Section 27.7.15, “C API Multiple Statement Execution Support”.
The MySQL grant system takes stored routines into account as follows:
The CREATE ROUTINE privilege is
needed to create stored routines.
The ALTER ROUTINE privilege is
needed to alter or drop stored routines. This privilege is
granted automatically to the creator of a routine if
necessary, and dropped from the creator when the routine is
dropped.
The EXECUTE privilege is
required to execute stored routines. However, this privilege
is granted automatically to the creator of a routine if
necessary (and dropped from the creator when the routine is
dropped). Also, the default SQL SECURITY
characteristic for a routine is DEFINER,
which enables users who have access to the database with which
the routine is associated to execute the routine.
If the
automatic_sp_privileges
system variable is 0, the
EXECUTE and
ALTER ROUTINE privileges are
not automatically granted to and dropped from the routine
creator.
The creator of a routine is the account used to execute the
CREATE statement for it. This might not be
the same as the account named as the
DEFINER in the routine definition.
The server manipulates the mysql.proc table in
response to statements that create, alter, or drop stored
routines. It is not supported that the server will notice manual
manipulation of this table.
Metadata about stored routines can be obtained as follows:
Query the ROUTINES table of the
INFORMATION_SCHEMA database. See
Section 24.21, “The INFORMATION_SCHEMA ROUTINES Table”.
Use the SHOW CREATE PROCEDURE
and SHOW CREATE FUNCTION
statements to see routine definitions. See
Section 13.7.5.9, “SHOW CREATE PROCEDURE Statement”.
Use the SHOW PROCEDURE STATUS
and SHOW FUNCTION STATUS
statements to see routine characteristics. See
Section 13.7.5.28, “SHOW PROCEDURE STATUS Statement”.
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 (see Section 12.15, “Information Functions”). 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 is 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 do not see a changed value.
A trigger is a named database object that is associated with a table, and that activates when a particular event occurs for the table. Some uses for triggers are to perform checks of values to be inserted into a table or to perform calculations on values involved in an update.
A trigger is defined to activate when a statement inserts, updates,
or deletes rows in the associated table. These row operations are
trigger events. For example, rows can be inserted by
INSERT or LOAD
DATA statements, and an insert trigger activates for each
inserted row. A trigger can be set to activate either before or
after the trigger event. For example, you can have a trigger
activate before each row that is inserted into a table or after each
row that is updated.
MySQL triggers activate only for changes made to tables by SQL
statements. This includes changes to base tables that underlie
updatable views. Triggers do not activate for changes to tables
made by APIs that do not transmit SQL statements to the MySQL
Server. This means that triggers are not activated by updates made
using the NDB API.
Triggers are not activated by changes in
INFORMATION_SCHEMA or
performance_schema tables. Those tables are
actually views and triggers are not permitted on views.
The following sections describe the syntax for creating and dropping triggers, show some examples of how to use them, and indicate how to obtain trigger metadata.
You may find the Triggers User Forum of use when working with triggers.
For answers to commonly asked questions regarding triggers in MySQL, see Section A.5, “MySQL 5.7 FAQ: Triggers”.
There are some restrictions on the use of triggers; see Section 23.8, “Restrictions on Stored Programs”.
Binary logging for triggers takes place as described in Section 23.7, “Stored Program Binary Logging”.
To create a trigger or drop a trigger, use the
CREATE TRIGGER or
DROP TRIGGER statement, described
in Section 13.1.20, “CREATE TRIGGER Statement”, and
Section 13.1.31, “DROP TRIGGER Statement”.
Here is a simple example that associates a trigger with a table,
to activate for INSERT operations.
The trigger acts as an accumulator, summing the values inserted
into one of the columns of the table.
mysql>CREATE TABLE account (acct_num INT, amount DECIMAL(10,2));Query OK, 0 rows affected (0.03 sec) mysql>CREATE TRIGGER ins_sum BEFORE INSERT ON accountFOR EACH ROW SET @sum = @sum + NEW.amount;Query OK, 0 rows affected (0.01 sec)
The CREATE TRIGGER statement
creates a trigger named ins_sum that is
associated with the account table. It also
includes clauses that specify the trigger action time, the
triggering event, and what to do when the trigger activates:
The keyword BEFORE indicates the trigger
action time. In this case, the trigger activates before each
row inserted into the table. The other permitted keyword here
is AFTER.
The keyword INSERT indicates the trigger
event; that is, the type of operation that activates the
trigger. In the example, INSERT
operations cause trigger activation. You can also create
triggers for DELETE and
UPDATE operations.
The statement following FOR EACH ROW
defines the trigger body; that is, the statement to execute
each time the trigger activates, which occurs once for each
row affected by the triggering event. In the example, the
trigger body is a simple
SET
that accumulates into a user variable the values inserted into
the amount column. The statement refers to
the column as NEW.amount which means
“the value of the amount column to be
inserted into the new row.”
To use the trigger, set the accumulator variable to zero, execute
an INSERT statement, and then see
what value the variable has afterward:
mysql>SET @sum = 0;mysql>INSERT INTO account VALUES(137,14.98),(141,1937.50),(97,-100.00);mysql>SELECT @sum AS 'Total amount inserted';+-----------------------+ | Total amount inserted | +-----------------------+ | 1852.48 | +-----------------------+
In this case, the value of @sum after the
INSERT statement has executed is
14.98 + 1937.50 - 100, or
1852.48.
To destroy the trigger, use a DROP
TRIGGER statement. You must specify the schema name if
the trigger is not in the default schema:
mysql> DROP TRIGGER test.ins_sum;
If you drop a table, any triggers for the table are also dropped.
Trigger names exist in the schema namespace, meaning that all triggers must have unique names within a schema. Triggers in different schemas can have the same name.
As of MySQL 5.7.2, it is possible to define multiple triggers for
a given table that have the same trigger event and action time.
For example, you can have two BEFORE UPDATE
triggers for a table. By default, triggers that have the same
trigger event and action time activate in the order they were
created. To affect trigger order, specify a clause after
FOR EACH ROW that indicates
FOLLOWS or PRECEDES and the
name of an existing trigger that also has the same trigger event
and action time. With FOLLOWS, the new trigger
activates after the existing trigger. With
PRECEDES, the new trigger activates before the
existing trigger.
For example, the following trigger definition defines another
BEFORE INSERT trigger for the
account table:
mysql>CREATE TRIGGER ins_transaction BEFORE INSERT ON accountFOR EACH ROW PRECEDES ins_sumSET@deposits = @deposits + IF(NEW.amount>0,NEW.amount,0),@withdrawals = @withdrawals + IF(NEW.amount<0,-NEW.amount,0);Query OK, 0 rows affected (0.01 sec)
This trigger, ins_transaction, is similar to
ins_sum but accumulates deposits and
withdrawals separately. It has a PRECEDES
clause that causes it to activate before
ins_sum; without that clause, it would activate
after ins_sum because it is created after
ins_sum.
Before MySQL 5.7.2, there cannot be multiple triggers for a given
table that have the same trigger event and action time. For
example, you cannot have two BEFORE UPDATE
triggers for a table. To work around this, you can define a
trigger that executes multiple statements by using the
BEGIN ... END
compound statement construct after FOR EACH
ROW. (An example appears later in this section.)
Within the trigger body, the OLD and
NEW keywords enable you to access columns in
the rows affected by a trigger. OLD and
NEW are MySQL extensions to triggers; they are
not case-sensitive.
In an INSERT trigger, only
NEW. can be
used; there is no old row. In a col_nameDELETE trigger,
only OLD.
can be used; there is no new row. In an col_nameUPDATE
trigger, you can use
OLD. to
refer to the columns of a row before it is updated and
col_nameNEW. to
refer to the columns of the row after it is updated.
col_name
A column named with OLD is read only. You can
refer to it (if you have the SELECT
privilege), but not modify it. You can refer to a column named
with NEW if you have the
SELECT privilege for it. In a
BEFORE trigger, you can also change its value
with SET NEW. if you have the
col_name =
valueUPDATE privilege for it. This means
you can use a trigger to modify the values to be inserted into a
new row or used to update a row. (Such a SET
statement has no effect in an AFTER trigger
because the row change will have already occurred.)
In a BEFORE trigger, the NEW
value for an AUTO_INCREMENT column is 0, not
the sequence number that is generated automatically when the new
row actually is inserted.
By using the BEGIN ...
END construct, you can define a trigger that executes
multiple statements. Within the BEGIN block,
you also can use other syntax that is permitted within stored
routines such as conditionals and loops. However, just as for
stored routines, if you use the mysql program
to define a trigger that executes multiple statements, it is
necessary to redefine the mysql statement
delimiter so that you can use the ; statement
delimiter within the trigger definition. The following example
illustrates these points. It defines an UPDATE
trigger that checks the new value to be used for updating each
row, and modifies the value to be within the range from 0 to 100.
This must be a BEFORE trigger because the value
must be checked before it is used to update the row:
mysql>delimiter //mysql>CREATE TRIGGER upd_check BEFORE UPDATE ON accountFOR EACH ROWBEGINIF NEW.amount < 0 THENSET NEW.amount = 0;ELSEIF NEW.amount > 100 THENSET NEW.amount = 100;END IF;END;//mysql>delimiter ;
It can be easier to define a stored procedure separately and then
invoke it from the trigger using a simple
CALL statement. This is also
advantageous if you want to execute the same code from within
several triggers.
There are limitations on what can appear in statements that a trigger executes when activated:
The trigger cannot use the CALL
statement to invoke stored procedures that return data to the
client or that use dynamic SQL. (Stored procedures are
permitted to return data to the trigger through
OUT or INOUT
parameters.)
The trigger cannot use statements that explicitly or
implicitly begin or end a transaction, such as
START
TRANSACTION, COMMIT,
or ROLLBACK.
(ROLLBACK to
SAVEPOINT is permitted because it does not end a
transaction.).
See also Section 23.8, “Restrictions on Stored Programs”.
MySQL handles errors during trigger execution as follows:
If a BEFORE trigger fails, the operation on
the corresponding row is not performed.
A BEFORE trigger is activated by the
attempt to insert or modify the row,
regardless of whether the attempt subsequently succeeds.
An AFTER trigger is executed only if any
BEFORE triggers and the row operation
execute successfully.
An error during either a BEFORE or
AFTER trigger results in failure of the
entire statement that caused trigger invocation.
For transactional tables, failure of a statement should cause rollback of all changes performed by the statement. Failure of a trigger causes the statement to fail, so trigger failure also causes rollback. For nontransactional tables, such rollback cannot be done, so although the statement fails, any changes performed prior to the point of the error remain in effect.
Triggers can contain direct references to tables by name, such as
the trigger named testref shown in this
example:
CREATE TABLE test1(a1 INT);
CREATE TABLE test2(a2 INT);
CREATE TABLE test3(a3 INT NOT NULL AUTO_INCREMENT PRIMARY KEY);
CREATE TABLE test4(
a4 INT NOT NULL AUTO_INCREMENT PRIMARY KEY,
b4 INT DEFAULT 0
);
delimiter |
CREATE TRIGGER testref BEFORE INSERT ON test1
FOR EACH ROW
BEGIN
INSERT INTO test2 SET a2 = NEW.a1;
DELETE FROM test3 WHERE a3 = NEW.a1;
UPDATE test4 SET b4 = b4 + 1 WHERE a4 = NEW.a1;
END;
|
delimiter ;
INSERT INTO test3 (a3) VALUES
(NULL), (NULL), (NULL), (NULL), (NULL),
(NULL), (NULL), (NULL), (NULL), (NULL);
INSERT INTO test4 (a4) VALUES
(0), (0), (0), (0), (0), (0), (0), (0), (0), (0);
Suppose that you insert the following values into table
test1 as shown here:
mysql>INSERT INTO test1 VALUES(1), (3), (1), (7), (1), (8), (4), (4);Query OK, 8 rows affected (0.01 sec) Records: 8 Duplicates: 0 Warnings: 0
As a result, the four tables contain the following data:
mysql>SELECT * FROM test1;+------+ | a1 | +------+ | 1 | | 3 | | 1 | | 7 | | 1 | | 8 | | 4 | | 4 | +------+ 8 rows in set (0.00 sec) mysql>SELECT * FROM test2;+------+ | a2 | +------+ | 1 | | 3 | | 1 | | 7 | | 1 | | 8 | | 4 | | 4 | +------+ 8 rows in set (0.00 sec) mysql>SELECT * FROM test3;+----+ | a3 | +----+ | 2 | | 5 | | 6 | | 9 | | 10 | +----+ 5 rows in set (0.00 sec) mysql>SELECT * FROM test4;+----+------+ | a4 | b4 | +----+------+ | 1 | 3 | | 2 | 0 | | 3 | 1 | | 4 | 2 | | 5 | 0 | | 6 | 0 | | 7 | 1 | | 8 | 1 | | 9 | 0 | | 10 | 0 | +----+------+ 10 rows in set (0.00 sec)
Metadata about triggers can be obtained as follows:
Query the TRIGGERS table of the
INFORMATION_SCHEMA database. See
Section 24.29, “The INFORMATION_SCHEMA TRIGGERS Table”.
Use the SHOW CREATE TRIGGER
statement. See Section 13.7.5.11, “SHOW CREATE TRIGGER Statement”.
Use the SHOW TRIGGERS
statement. See Section 13.7.5.38, “SHOW TRIGGERS Statement”.
The MySQL Event Scheduler manages the scheduling and execution of events, that is, tasks that run according to a schedule. The following discussion covers the Event Scheduler and is divided into the following sections:
Section 23.4.1, “Event Scheduler Overview”, provides an introduction to and conceptual overview of MySQL Events.
Section 23.4.3, “Event Syntax”, discusses the SQL statements for creating, altering, and dropping MySQL Events.
Section 23.4.4, “Event Metadata”, shows how to obtain information about events and how this information is stored by the MySQL Server.
Section 23.4.6, “The Event Scheduler and MySQL Privileges”, discusses the privileges required to work with events and the ramifications that events have with regard to privileges when executing.
Stored routines require the event table in the
mysql database. This table is created during the
MySQL 5.7 installation procedure. If you are upgrading
to MySQL 5.7 from an earlier version, be sure to update
your grant tables to make sure that the event
table exists. See Section 2.11, “Upgrading MySQL”.
You may find the MySQL Event Scheduler User Forum of use when working with scheduled events.
There are some restrictions on the use of events; see Section 23.8, “Restrictions on Stored Programs”.
Binary logging for events takes place as described in Section 23.7, “Stored Program Binary Logging”.
MySQL Events are tasks that run according to a schedule.
Therefore, we sometimes refer to them as
scheduled events. When you create an event,
you are creating a named database object containing one or more
SQL statements to be executed at one or more regular intervals,
beginning and ending at a specific date and time. Conceptually,
this is similar to the idea of the Unix crontab
(also known as a “cron job”) or the Windows Task
Scheduler.
Scheduled tasks of this type are also sometimes known as “temporal triggers”, implying that these are objects that are triggered by the passage of time. While this is essentially correct, we prefer to use the term events to avoid confusion with triggers of the type discussed in Section 23.3, “Using Triggers”. Events should more specifically not be confused with “temporary triggers”. Whereas a trigger is a database object whose statements are executed in response to a specific type of event that occurs on a given table, a (scheduled) event is an object whose statements are executed in response to the passage of a specified time interval.
While there is no provision in the SQL Standard for event scheduling, there are precedents in other database systems, and you may notice some similarities between these implementations and that found in the MySQL Server.
MySQL Events have the following major features and properties:
In MySQL, an event is uniquely identified by its name and the schema to which it is assigned.
An event performs a specific action according to a schedule.
This action consists of an SQL statement, which can be a
compound statement in a
BEGIN ...
END block if desired (see
Section 13.6, “Compound Statements”). An event's
timing can be either
one-time or
recurrent. A one-time
event executes one time only. A recurrent event repeats its
action at a regular interval, and the schedule for a recurring
event can be assigned a specific start day and time, end day
and time, both, or neither. (By default, a recurring event's
schedule begins as soon as it is created, and continues
indefinitely, until it is disabled or dropped.)
If a repeating event does not terminate within its scheduling
interval, the result may be multiple instances of the event
executing simultaneously. If this is undesirable, you should
institute a mechanism to prevent simultaneous instances. For
example, you could use the
GET_LOCK() function, or row or
table locking.
Users can create, modify, and drop scheduled events using SQL statements intended for these purposes. Syntactically invalid event creation and modification statements fail with an appropriate error message. A user may include statements in an event's action which require privileges that the user does not actually have. The event creation or modification statement succeeds but the event's action fails. See Section 23.4.6, “The Event Scheduler and MySQL Privileges” for details.
Many of the properties of an event can be set or modified using SQL statements. These properties include the event's name, timing, persistence (that is, whether it is preserved following the expiration of its schedule), status (enabled or disabled), action to be performed, and the schema to which it is assigned. See Section 13.1.2, “ALTER EVENT Statement”.
The default definer of an event is the user who created the
event, unless the event has been altered, in which case the
definer is the user who issued the last
ALTER EVENT statement affecting
that event. An event can be modified by any user having the
EVENT privilege on the database
for which the event is defined. See
Section 23.4.6, “The Event Scheduler and MySQL Privileges”.
An event's action statement may include most SQL statements permitted within stored routines. For restrictions, see Section 23.8, “Restrictions on Stored Programs”.
Events are executed by a special event
scheduler thread; when we refer to the Event Scheduler,
we actually refer to this thread. When running, the event
scheduler thread and its current state can be seen by users having
the PROCESS privilege in the output
of SHOW PROCESSLIST, as shown in
the discussion that follows.
The global event_scheduler system
variable determines whether the Event Scheduler is enabled and
running on the server. It has one of these 3 values, which affect
event scheduling as described here:
OFF: The Event Scheduler is stopped. The
event scheduler thread does not run, is not shown in the
output of SHOW PROCESSLIST, and
no scheduled events are executed. OFF is
the default value for
event_scheduler.
When the Event Scheduler is stopped
(event_scheduler is
OFF), it can be started by setting the
value of event_scheduler to
ON. (See next item.)
ON: The Event Scheduler is started; the
event scheduler thread runs and executes all scheduled events.
When the Event Scheduler is ON, the event
scheduler thread is listed in the output of
SHOW PROCESSLIST as a daemon
process, and its state is represented as shown here:
mysql> SHOW PROCESSLIST\G
*************************** 1. row ***************************
Id: 1
User: root
Host: localhost
db: NULL
Command: Query
Time: 0
State: NULL
Info: show processlist
*************************** 2. row ***************************
Id: 2
User: event_scheduler
Host: localhost
db: NULL
Command: Daemon
Time: 3
State: Waiting for next activation
Info: NULL
2 rows in set (0.00 sec)
Event scheduling can be stopped by setting the value of
event_scheduler to
OFF.
DISABLED: This value renders the Event
Scheduler nonoperational. When the Event Scheduler is
DISABLED, the event scheduler thread does
not run (and so does not appear in the output of
SHOW PROCESSLIST). In addition,
the Event Scheduler state cannot be changed at runtime.
If the Event Scheduler status has not been set to
DISABLED,
event_scheduler can be toggled
between ON and OFF (using
SET). It
is also possible to use 0 for
OFF, and 1 for
ON when setting this variable. Thus, any of the
following 4 statements can be used in the mysql
client to turn on the Event Scheduler:
SET GLOBAL event_scheduler = ON; SET @@GLOBAL.event_scheduler = ON; SET GLOBAL event_scheduler = 1; SET @@GLOBAL.event_scheduler = 1;
Similarly, any of these 4 statements can be used to turn off the Event Scheduler:
SET GLOBAL event_scheduler = OFF; SET @@GLOBAL.event_scheduler = OFF; SET GLOBAL event_scheduler = 0; SET @@GLOBAL.event_scheduler = 0;
Although ON and OFF have
numeric equivalents, the value displayed for
event_scheduler by
SELECT or SHOW
VARIABLES is always one of OFF,
ON, or DISABLED.
DISABLED has no numeric
equivalent. For this reason, ON and
OFF are usually preferred over
1 and 0 when setting this
variable.
Note that attempting to set
event_scheduler without
specifying it as a global variable causes an error:
mysql< SET @@event_scheduler = OFF;
ERROR 1229 (HY000): Variable 'event_scheduler' is a GLOBAL
variable and should be set with SET GLOBAL
It is possible to set the Event Scheduler to
DISABLED only at server startup. If
event_scheduler is
ON or OFF, you cannot set
it to DISABLED at runtime. Also, if the Event
Scheduler is set to DISABLED at startup, you
cannot change the value of
event_scheduler at runtime.
To disable the event scheduler, use one of the following two methods:
As a command-line option when starting the server:
--event-scheduler=DISABLED
In the server configuration file (my.cnf,
or my.ini on Windows systems), include
the line where it will be read by the server (for example, in
a [mysqld] section):
event_scheduler=DISABLED
To enable the Event Scheduler, restart the server without the
--event-scheduler=DISABLED
command-line option, or after removing or commenting out the line
containing event-scheduler=DISABLED
in the server configuration file, as appropriate. Alternatively,
you can use ON (or 1) or
OFF (or 0) in place of the
DISABLED value when starting the server.
You can issue event-manipulation statements when
event_scheduler is set to
DISABLED. No warnings or errors are generated
in such cases (provided that the statements are themselves
valid). However, scheduled events cannot execute until this
variable is set to ON (or
1). Once this has been done, the event
scheduler thread executes all events whose scheduling conditions
are satisfied.
Starting the MySQL server with the
--skip-grant-tables option causes
event_scheduler to be set to
DISABLED, overriding any other value set either
on the command line or in the my.cnf or
my.ini file (Bug #26807).
For SQL statements used to create, alter, and drop events, see Section 23.4.3, “Event Syntax”.
MySQL provides an EVENTS table in the
INFORMATION_SCHEMA database. This table can be
queried to obtain information about scheduled events which have
been defined on the server. See Section 23.4.4, “Event Metadata”,
and Section 24.8, “The INFORMATION_SCHEMA EVENTS Table”, for more information.
For information regarding event scheduling and the MySQL privilege system, see Section 23.4.6, “The Event Scheduler and MySQL Privileges”.
MySQL provides several SQL statements for working with scheduled events:
New events are defined using the CREATE
EVENT statement. See Section 13.1.12, “CREATE EVENT Statement”.
The definition of an existing event can be changed by means of
the ALTER EVENT statement. See
Section 13.1.2, “ALTER EVENT Statement”.
When a scheduled event is no longer wanted or needed, it can
be deleted from the server by its definer using the
DROP EVENT statement. See
Section 13.1.23, “DROP EVENT Statement”. Whether an event persists past
the end of its schedule also depends on its ON
COMPLETION clause, if it has one. See
Section 13.1.12, “CREATE EVENT Statement”.
An event can be dropped by any user having the
EVENT privilege for the
database on which the event is defined. See
Section 23.4.6, “The Event Scheduler and MySQL Privileges”.
Metadata about events can be obtained as follows:
Query the event table of the
mysql database.
Query the EVENTS table of the
INFORMATION_SCHEMA database. See
Section 24.8, “The INFORMATION_SCHEMA EVENTS Table”.
Use the SHOW CREATE EVENT
statement. See Section 13.7.5.7, “SHOW CREATE EVENT Statement”.
Use the SHOW EVENTS statement.
See Section 13.7.5.18, “SHOW EVENTS Statement”.
Event Scheduler Time Representation
Each session in MySQL has a session time zone (STZ). This is the
session time_zone value that is
initialized from the server's global
time_zone value when the session
begins but may be changed during the session.
The session time zone that is current when a
CREATE EVENT or
ALTER EVENT statement executes is
used to interpret times specified in the event definition. This
becomes the event time zone (ETZ); that is, the time zone that is
used for event scheduling and is in effect within the event as it
executes.
For representation of event information in the
mysql.event table, the
execute_at, starts, and
ends times are converted to UTC and stored
along with the event time zone. This enables event execution to
proceed as defined regardless of any subsequent changes to the
server time zone or daylight saving time effects. The
last_executed time is also stored in UTC.
If you select information from mysql.event, the
times just mentioned are retrieved as UTC values. These times can
also be obtained by selecting from the
INFORMATION_SCHEMA.EVENTS table or
from SHOW EVENTS, but they are
reported as ETZ values. Other times available from these sources
indicate when an event was created or last altered; these are
displayed as STZ values. The following table summarizes
representation of event times.
| Value | mysql.event |
INFORMATION_SCHEMA.EVENTS |
SHOW EVENTS |
|---|---|---|---|
| Execute at | UTC | ETZ | ETZ |
| Starts | UTC | ETZ | ETZ |
| Ends | UTC | ETZ | ETZ |
| Last executed | UTC | ETZ | n/a |
| Created | STZ | STZ | n/a |
| Last altered | STZ | STZ | n/a |
The Event Scheduler writes information about event execution that terminates with an error or warning to the MySQL Server's error log. See Section 23.4.6, “The Event Scheduler and MySQL Privileges” for an example.
To obtain information about the state of the Event Scheduler for debugging and troubleshooting purposes, run mysqladmin debug (see Section 4.5.2, “mysqladmin — Client for Administering a MySQL Server”); after running this command, the server's error log contains output relating to the Event Scheduler, similar to what is shown here:
Events status: LLA = Last Locked At LUA = Last Unlocked At WOC = Waiting On Condition DL = Data Locked Event scheduler status: State : INITIALIZED Thread id : 0 LLA : init_scheduler:313 LUA : init_scheduler:318 WOC : NO Workers : 0 Executed : 0 Data locked: NO Event queue status: Element count : 1 Data locked : NO Attempting lock : NO LLA : init_queue:148 LUA : init_queue:168 WOC : NO Next activation : 0000-00-00 00:00:00
In statements that occur as part of events executed by the Event
Scheduler, diagnostics messages (not only errors, but also
warnings) are written to the error log, and, on Windows, to the
application event log. For frequently executed events, it is
possible for this to result in many logged messages. For example,
for SELECT ... INTO
statements, if the
query returns no rows, a warning with error code 1329 occurs
(var_listNo data), and the variable values remain
unchanged. If the query returns multiple rows, error 1172 occurs
(Result consisted of more than one row). For
either condition, you can avoid having the warnings be logged by
declaring a condition handler; see
Section 13.6.7.2, “DECLARE ... HANDLER Statement”. For statements that may
retrieve multiple rows, another strategy is to use LIMIT
1 to limit the result set to a single row.
To enable or disable the execution of scheduled events, it is
necessary to set the value of the global
event_scheduler system variable.
This requires privileges sufficient to set global system
variables. See Section 5.1.8.1, “System Variable Privileges”.
The EVENT privilege governs the
creation, modification, and deletion of events. This privilege can
be bestowed using GRANT. For
example, this GRANT statement
confers the EVENT privilege for the
schema named myschema on the user
jon@ghidora:
GRANT EVENT ON myschema.* TO jon@ghidora;
(We assume that this user account already exists, and that we wish for it to remain unchanged otherwise.)
To grant this same user the EVENT
privilege on all schemas, use the following statement:
GRANT EVENT ON *.* TO jon@ghidora;
The EVENT privilege has global or
schema-level scope. Therefore, trying to grant it on a single
table results in an error as shown:
mysql> GRANT EVENT ON myschema.mytable TO jon@ghidora;
ERROR 1144 (42000): Illegal GRANT/REVOKE command; please
consult the manual to see which privileges can be used
It is important to understand that an event is executed with the
privileges of its definer, and that it cannot perform any actions
for which its definer does not have the requisite privileges. For
example, suppose that jon@ghidora has the
EVENT privilege for
myschema. Suppose also that this user has the
SELECT privilege for
myschema, but no other privileges for this
schema. It is possible for jon@ghidora to
create a new event such as this one:
CREATE EVENT e_store_ts
ON SCHEDULE
EVERY 10 SECOND
DO
INSERT INTO myschema.mytable VALUES (UNIX_TIMESTAMP());
The user waits for a minute or so, and then performs a
SELECT * FROM mytable; query, expecting to see
several new rows in the table. Instead, the table is empty. Since
the user does not have the INSERT
privilege for the table in question, the event has no effect.
If you inspect the MySQL error log
(hostname.err
2013-09-24T12:41:31.261992Z 25 [ERROR] Event Scheduler: [jon@ghidora][cookbook.e_store_ts] INSERT command denied to user 'jon'@'ghidora' for table 'mytable' 2013-09-24T12:41:31.262022Z 25 [Note] Event Scheduler: [jon@ghidora].[myschema.e_store_ts] event execution failed. 2013-09-24T12:41:41.271796Z 26 [ERROR] Event Scheduler: [jon@ghidora][cookbook.e_store_ts] INSERT command denied to user 'jon'@'ghidora' for table 'mytable' 2013-09-24T12:41:41.272761Z 26 [Note] Event Scheduler: [jon@ghidora].[myschema.e_store_ts] event execution failed.
Since this user very likely does not have access to the error log, it is possible to verify whether the event's action statement is valid by executing it directly:
mysql> INSERT INTO myschema.mytable VALUES (UNIX_TIMESTAMP());
ERROR 1142 (42000): INSERT command denied to user
'jon'@'ghidora' for table 'mytable'
Inspection of the
INFORMATION_SCHEMA.EVENTS table shows
that e_store_ts exists and is enabled, but its
LAST_EXECUTED column is
NULL:
mysql>SELECT * FROM INFORMATION_SCHEMA.EVENTS>WHERE EVENT_NAME='e_store_ts'>AND EVENT_SCHEMA='myschema'\G*************************** 1. row *************************** EVENT_CATALOG: NULL EVENT_SCHEMA: myschema EVENT_NAME: e_store_ts DEFINER: jon@ghidora EVENT_BODY: SQL EVENT_DEFINITION: INSERT INTO myschema.mytable VALUES (UNIX_TIMESTAMP()) EVENT_TYPE: RECURRING EXECUTE_AT: NULL INTERVAL_VALUE: 5 INTERVAL_FIELD: SECOND SQL_MODE: NULL STARTS: 0000-00-00 00:00:00 ENDS: 0000-00-00 00:00:00 STATUS: ENABLED ON_COMPLETION: NOT PRESERVE CREATED: 2006-02-09 22:36:06 LAST_ALTERED: 2006-02-09 22:36:06 LAST_EXECUTED: NULL EVENT_COMMENT: 1 row in set (0.00 sec)
To rescind the EVENT privilege, use
the REVOKE statement. In this
example, the EVENT privilege on the
schema myschema is removed from the
jon@ghidora user account:
REVOKE EVENT ON myschema.* FROM jon@ghidora;
Revoking the EVENT privilege from
a user does not delete or disable any events that may have been
created by that user.
An event is not migrated or dropped as a result of renaming or dropping the user who created it.
Suppose that the user jon@ghidora has been
granted the EVENT and
INSERT privileges on the
myschema schema. This user then creates the
following event:
CREATE EVENT e_insert
ON SCHEDULE
EVERY 7 SECOND
DO
INSERT INTO myschema.mytable;
After this event has been created, root revokes
the EVENT privilege for
jon@ghidora. However,
e_insert continues to execute, inserting a new
row into mytable each seven seconds. The same
would be true if root had issued either of
these statements:
DROP USER jon@ghidora;
RENAME USER jon@ghidora TO
someotherguy@ghidora;
You can verify that this is true by examining the
mysql.event table (discussed later in this
section) or the
INFORMATION_SCHEMA.EVENTS table (see
Section 24.8, “The INFORMATION_SCHEMA EVENTS Table”) before and after issuing a
DROP USER or
RENAME USER statement.
Event definitions are stored in the mysql.event
table. To drop an event created by another user account, the MySQL
root user (or another user with the necessary
privileges) can delete rows from this table. For example, to
remove the event e_insert shown previously,
root can use the following statement:
DELETE FROM mysql.event
WHERE db = 'myschema'
AND name = 'e_insert';
It is very important to match the event name and database schema
name when deleting rows from the mysql.event
table. This is because different events of the same name can exist
in different schemas.
Users' EVENT privileges are stored
in the Event_priv columns of the
mysql.user and mysql.db
tables. In both cases, this column holds one of the values
'Y' or 'N'.
'N' is the default.
mysql.user.Event_priv is set to
'Y' for a given user only if that user has the
global EVENT privilege (that is, if
the privilege was bestowed using GRANT EVENT ON
*.*). For a schema-level
EVENT privilege,
GRANT creates a row in
mysql.db and sets that row's
Db column to the name of the schema, the
User column to the name of the user, and the
Event_priv column to 'Y'.
There should never be any need to manipulate these tables
directly, since the GRANT
EVENT and REVOKE EVENT statements
perform the required operations on them.
Five status variables provide counts of event-related operations (but not of statements executed by events; see Section 23.8, “Restrictions on Stored Programs”). These are:
Com_create_event: The number of
CREATE EVENT statements
executed since the last server restart.
Com_alter_event: The number of
ALTER EVENT statements executed
since the last server restart.
Com_drop_event: The number of
DROP EVENT statements executed
since the last server restart.
Com_show_create_event: The number of
SHOW CREATE EVENT statements
executed since the last server restart.
Com_show_events: The number of
SHOW EVENTS statements executed
since the last server restart.
You can view current values for all of these at one time by
running the statement SHOW STATUS LIKE
'%event%';.
MySQL supports views, including updatable views. Views are stored queries that when invoked produce a result set. A view acts as a virtual table.
The following discussion describes the syntax for creating and dropping views, and shows some examples of how to use them.
You may find the Views User Forum of use when working with views.
For answers to some commonly asked questions regarding views in MySQL, see Section A.6, “MySQL 5.7 FAQ: Views”.
There are some restrictions on the use of views; see Section 23.9, “Restrictions on Views”.
The CREATE VIEW statement creates a
new view (see Section 13.1.21, “CREATE VIEW Statement”). To alter the
definition of a view or drop a view, use
ALTER VIEW (see
Section 13.1.10, “ALTER VIEW Statement”), or DROP
VIEW (see Section 13.1.32, “DROP VIEW Statement”).
A view can be created from many kinds of
SELECT statements. It can refer to
base tables or other views. It can use joins,
UNION, and subqueries. The
SELECT need not even refer to any
tables. The following example defines a view that selects two
columns from another table, as well as an expression calculated
from those columns:
mysql>CREATE TABLE t (qty INT, price INT);mysql>INSERT INTO t VALUES(3, 50), (5, 60);mysql>CREATE VIEW v AS SELECT qty, price, qty*price AS value FROM t;mysql>SELECT * FROM v;+------+-------+-------+ | qty | price | value | +------+-------+-------+ | 3 | 50 | 150 | | 5 | 60 | 300 | +------+-------+-------+ mysql>SELECT * FROM v WHERE qty = 5;+------+-------+-------+ | qty | price | value | +------+-------+-------+ | 5 | 60 | 300 | +------+-------+-------+
The optional ALGORITHM clause for
CREATE VIEW or
ALTER VIEW is a MySQL extension to
standard SQL. It affects how MySQL processes the view.
ALGORITHM takes three values:
MERGE, TEMPTABLE, or
UNDEFINED.
For MERGE, the text of a statement that
refers to the view and the view definition are merged such
that parts of the view definition replace corresponding parts
of the statement.
For TEMPTABLE, the results from the view
are retrieved into a temporary table, which then is used to
execute the statement.
For UNDEFINED, MySQL chooses which
algorithm to use. It prefers MERGE over
TEMPTABLE if possible, because
MERGE is usually more efficient and because
a view cannot be updatable if a temporary table is used.
If no ALGORITHM clause is present,
UNDEFINED is the default algorithm prior to
MySQL 5.7.6. As of 5.7.6, the default algorithm is determined
by the value of the derived_merge flag of
the optimizer_switch system
variable. For additional discussion, see
Section 8.2.2.4, “Optimizing Derived Tables and View References with Merging or
Materialization”.
A reason to specify TEMPTABLE explicitly is
that locks can be released on underlying tables after the
temporary table has been created and before it is used to finish
processing the statement. This might result in quicker lock
release than the MERGE algorithm so that other
clients that use the view are not blocked as long.
A view algorithm can be UNDEFINED for three
reasons:
No ALGORITHM clause is present in the
CREATE VIEW statement.
The CREATE VIEW statement has
an explicit ALGORITHM = UNDEFINED clause.
ALGORITHM = MERGE is specified for a view
that can be processed only with a temporary table. In this
case, MySQL generates a warning and sets the algorithm to
UNDEFINED.
As mentioned earlier, MERGE is handled by
merging corresponding parts of a view definition into the
statement that refers to the view. The following examples briefly
illustrate how the MERGE algorithm works. The
examples assume that there is a view v_merge
that has this definition:
CREATE ALGORITHM = MERGE VIEW v_merge (vc1, vc2) AS SELECT c1, c2 FROM t WHERE c3 > 100;
Example 1: Suppose that we issue this statement:
SELECT * FROM v_merge;
MySQL handles the statement as follows:
v_merge becomes t
* becomes vc1, vc2,
which corresponds to c1, c2
The view WHERE clause is added
The resulting statement to be executed becomes:
SELECT c1, c2 FROM t WHERE c3 > 100;
Example 2: Suppose that we issue this statement:
SELECT * FROM v_merge WHERE vc1 < 100;
This statement is handled similarly to the previous one, except
that vc1 < 100 becomes c1 <
100 and the view WHERE clause is
added to the statement WHERE clause using an
AND connective (and parentheses are
added to make sure the parts of the clause are executed with
correct precedence). The resulting statement to be executed
becomes:
SELECT c1, c2 FROM t WHERE (c3 > 100) AND (c1 < 100);
Effectively, the statement to be executed has a
WHERE clause of this form:
WHERE (select WHERE) AND (view WHERE)
If the MERGE algorithm cannot be used, a
temporary table must be used instead. Constructs that prevent
merging are the same as those that prevent merging in derived
tables. Examples are SELECT DISTINCT or
LIMIT in the subquery. For details, see
Section 8.2.2.4, “Optimizing Derived Tables and View References with Merging or
Materialization”.
Some views are updatable and references to them can be used to
specify tables to be updated in data change statements. That is,
you can use them in statements such as
UPDATE,
DELETE, or
INSERT to update the contents of
the underlying table. Derived tables can also be specified in
multiple-table UPDATE and
DELETE statements, but can only be
used for reading data to specify rows to be updated or deleted.
Generally, the view references must be updatable, meaning that
they may be merged and not materialized. Composite views have more
complex rules.
For a view to be updatable, there must be a one-to-one relationship between the rows in the view and the rows in the underlying table. There are also certain other constructs that make a view nonupdatable. To be more specific, a view is not updatable if it contains any of the following:
Aggregate functions (SUM(),
MIN(),
MAX(),
COUNT(), and so forth)
DISTINCT
GROUP BY
HAVING
Subquery in the select list
Before MySQL 5.7.11, subqueries in the select list fail for
INSERT, but are okay for
UPDATE,
DELETE. As of MySQL 5.7.11,
that is still true for nondependent subqueries. For dependent
subqueries in the select list, no data change statements are
permitted.
Certain joins (see additional join discussion later in this section)
Reference to nonupdatable view in the FROM
clause
Subquery in the WHERE clause that refers to
a table in the FROM clause
Refers only to literal values (in this case, there is no underlying table to update)
ALGORITHM = TEMPTABLE (use of a temporary
table always makes a view nonupdatable)
Multiple references to any column of a base table (fails for
INSERT, okay for
UPDATE,
DELETE)
A generated column in a view is considered updatable because it is
possible to assign to it. However, if such a column is updated
explicitly, the only permitted value is
DEFAULT. For information about generated
columns, see Section 13.1.18.8, “CREATE TABLE and Generated Columns”.
It is sometimes possible for a multiple-table view to be
updatable, assuming that it can be processed with the
MERGE algorithm. For this to work, the view
must use an inner join (not an outer join or a
UNION). Also, only a single table
in the view definition can be updated, so the
SET clause must name only columns from one of
the tables in the view. Views that use
UNION ALL are not
permitted even though they might be theoretically updatable.
With respect to insertability (being updatable with
INSERT statements), an updatable
view is insertable if it also satisfies these additional
requirements for the view columns:
There must be no duplicate view column names.
The view must contain all columns in the base table that do not have a default value.
The view columns must be simple column references. They must not be expressions, such as these:
3.14159
col1 + 3
UPPER(col2)
col3 / col4
(subquery)
MySQL sets a flag, called the view updatability flag, at
CREATE VIEW time. The flag is set
to YES (true) if
UPDATE and
DELETE (and similar operations) are
legal for the view. Otherwise, the flag is set to
NO (false). The IS_UPDATABLE
column in the
INFORMATION_SCHEMA.VIEWS table
displays the status of this flag.
If a view is not updatable, statements such
UPDATE,
DELETE, and
INSERT are illegal and are
rejected. (Even if a view is updatable, it might not be possible
to insert into it, as described elsewhere in this section.)
The IS_UPDATABLE flag may be unreliable if a
view depends on one or more other views, and one of these
underlying views is updated. Regardless of the
IS_UPDATABLE value, the server keeps track of
the updatability of a view and correctly rejects data change
operations to views that are not updatable. If the
IS_UPDATABLE value for a view has become
inaccurate to due to changes to underlying views, the value can be
updated by deleting and re-creating the view.
The updatability of views may be affected by the value of the
updatable_views_with_limit system
variable. See Section 5.1.7, “Server System Variables”.
For the following discussion, suppose that these tables and views exist:
CREATE TABLE t1 (x INTEGER); CREATE TABLE t2 (c INTEGER); CREATE VIEW vmat AS SELECT SUM(x) AS s FROM t1; CREATE VIEW vup AS SELECT * FROM t2; CREATE VIEW vjoin AS SELECT * FROM vmat JOIN vup ON vmat.s=vup.c;
INSERT,
UPDATE, and
DELETE statements are permitted as
follows:
INSERT: The insert table of an
INSERT statement may be a view
reference that is merged. If the view is a join view, all
components of the view must be updatable (not materialized).
For a multiple-table updatable view,
INSERT can work if it inserts
into a single table.
This statement is invalid because one component of the join view is nonupdatable:
INSERT INTO vjoin (c) VALUES (1);
This statement is valid; the view contains no materialized components:
INSERT INTO vup (c) VALUES (1);
UPDATE: The table or tables to
be updated in an UPDATE
statement may be view references that are merged. If a view is
a join view, at least one component of the view must be
updatable (this differs from
INSERT).
In a multiple-table UPDATE
statement, the updated table references of the statement must
be base tables or updatable view references. Nonupdated table
references may be materialized views or derived tables.
This statement is valid; column c is from
the updatable part of the join view:
UPDATE vjoin SET c=c+1;
This statement is invalid; column x is from
the nonupdatable part:
UPDATE vjoin SET x=x+1;
This statement is valid; the updated table reference of the
multiple-table UPDATE is an
updatable view (vup):
UPDATE vup JOIN (SELECT SUM(x) AS s FROM t1) AS dt ON ... SET c=c+1;
This statement is invalid; it tries to update a materialized derived table:
UPDATE vup JOIN (SELECT SUM(x) AS s FROM t1) AS dt ON ... SET s=s+1;
DELETE: The table or tables to
be deleted from in a DELETE
statement must be merged views. Join views are not allowed
(this differs from INSERT and
UPDATE).
This statement is invalid because the view is a join view:
DELETE vjoin WHERE ...;
This statement is valid because the view is a merged (updatable) view:
DELETE vup WHERE ...;
This statement is valid because it deletes from a merged (updatable) view:
DELETE vup FROM vup JOIN (SELECT SUM(x) AS s FROM t1) AS dt ON ...;
Additional discussion and examples follow.
Earlier discussion in this section pointed out that a view is not insertable if not all columns are simple column references (for example, if it contains columns that are expressions or composite expressions). Although such a view is not insertable, it can be updatable if you update only columns that are not expressions. Consider this view:
CREATE VIEW v AS SELECT col1, 1 AS col2 FROM t;
This view is not insertable because col2 is an
expression. But it is updatable if the update does not try to
update col2. This update is permissible:
UPDATE v SET col1 = 0;
This update is not permissible because it attempts to update an expression column:
UPDATE v SET col2 = 0;
If a table contains an AUTO_INCREMENT column,
inserting into an insertable view on the table that does not
include the AUTO_INCREMENT column does not
change the value of
LAST_INSERT_ID(), because the side
effects of inserting default values into columns not part of the
view should not be visible.
The WITH CHECK OPTION clause can be given for
an updatable view to prevent inserts to rows for which the
WHERE clause in the
select_statement is not true. It also
prevents updates to rows for which the WHERE
clause is true but the update would cause it to be not true (in
other words, it prevents visible rows from being updated to
nonvisible rows).
In a WITH CHECK OPTION clause for an updatable
view, the LOCAL and CASCADED
keywords determine the scope of check testing when the view is
defined in terms of another view. When neither keyword is given,
the default is CASCADED.
Before MySQL 5.7.6, WITH CHECK OPTION testing
works like this:
With LOCAL, the view
WHERE clause is checked, but no underlying
views are checked.
With CASCADED, the view
WHERE clause is checked, then checking
recurses to underlying views, adds WITH CASCADED
CHECK OPTION to them (for purposes of the check;
their definitions remain unchanged), and applies the same
rules.
With no check option, the view WHERE clause
is not checked, and no underlying views are checked.
As of MySQL 5.7.6, WITH CHECK OPTION testing is
standard-compliant (with changed semantics from previously for
LOCAL and no check clause):
With LOCAL, the view
WHERE clause is checked, then checking
recurses to underlying views and applies the same rules.
With CASCADED, the view
WHERE clause is checked, then checking
recurses to underlying views, adds WITH CASCADED
CHECK OPTION to them (for purposes of the check;
their definitions remain unchanged), and applies the same
rules.
With no check option, the view WHERE clause
is not checked, then checking recurses to underlying views,
and applies the same rules.
Consider the definitions for the following table and set of views:
CREATE TABLE t1 (a INT); CREATE VIEW v1 AS SELECT * FROM t1 WHERE a < 2 WITH CHECK OPTION; CREATE VIEW v2 AS SELECT * FROM v1 WHERE a > 0 WITH LOCAL CHECK OPTION; CREATE VIEW v3 AS SELECT * FROM v1 WHERE a > 0 WITH CASCADED CHECK OPTION;
Here the v2 and v3 views are
defined in terms of another view, v1. Before
MySQL 5.7.6, because v2 has a
LOCAL check option, inserts are tested only
against the v2 check. v3 has
a CASCADED check option, so inserts are tested
not only against the v3 check, but against
those of underlying views. The following statements illustrate
these differences:
mysql>INSERT INTO v2 VALUES (2);Query OK, 1 row affected (0.00 sec) mysql>INSERT INTO v3 VALUES (2);ERROR 1369 (HY000): CHECK OPTION failed 'test.v3'
As of MySQL 5.7.6, the semantics for LOCAL
differ from previously: Inserts for v2 are
checked against its LOCAL check option, then
(unlike before 5.7.6), the check recurses to v1
and the rules are applied again. The rules for
v1 cause a check failure. The check for
v3 fails as before:
mysql>INSERT INTO v2 VALUES (2);ERROR 1369 (HY000): CHECK OPTION failed 'test.v2' mysql>INSERT INTO v3 VALUES (2);ERROR 1369 (HY000): CHECK OPTION failed 'test.v3'
Metadata about views can be obtained as follows:
Query the VIEWS table of the
INFORMATION_SCHEMA database. See
Section 24.31, “The INFORMATION_SCHEMA VIEWS Table”.
Use the SHOW CREATE VIEW
statement. See Section 13.7.5.13, “SHOW CREATE VIEW Statement”.
Stored programs (procedures, functions, triggers, and events) and
views are defined prior to use and, when referenced, execute
within a security context that determines their privileges. These
privileges are controlled by their DEFINER
attribute and SQL SECURITY characteristic.
All stored object definitions can include a
DEFINER attribute that names a MySQL account.
If a definition omits the DEFINER attribute,
the default definer is the user who creates the object.
MySQL uses the following rules to control which accounts a user
can specify in an object DEFINER attribute:
If you have the SUPER
privilege, you can specify any account as the
DEFINER value, although a warning is
generated if the account does not exist.
Otherwise, the only permitted account is your own, either
specified literally or as
CURRENT_USER or
CURRENT_USER(). You cannot
set the definer to some other account.
Creating a stored object with a nonexistent
DEFINER account may have negative
consequences:
For a stored routine, an error occurs at routine execution
time if the SQL SECURITY value is
DEFINER but the definer account does not
exist.
For a trigger, it is not a good idea for trigger activation to occur until the account actually does exist. Otherwise, the behavior with respect to privilege checking is undefined.
For an event, an error occurs at event execution time if the account does not exist.
For a view, an error occurs when the view is referenced if
the SQL SECURITY value is
DEFINER but the definer account does not
exist.
Definitions for stored routines (procedures and functions) and
views can include an SQL SECURITY
characteristic with a value of DEFINER or
INVOKER to specify whether the object
executes in definer or invoker context. If a definition omits
the SQL SECURITY characteristic, the default
is definer context.
Triggers and events have no SQL SECURITY
characteristic and always execute in definer context. The server
invokes these objects automatically as necessary, so there is no
invoking user.
Definer and invoker security contexts differ as follows:
A stored object that executes in definer security context
executes with the privileges of the account named by its
DEFINER attribute. These privileges may
be entirely different from those of the invoking user. The
invoker must have appropriate privileges to reference the
object (for example, EXECUTE
to call a stored procedure or
SELECT to select from a
view), but during object execution, the invoker's privileges
are ignored and only the DEFINER account
privileges matter. If the DEFINER account
has few privileges, the object is correspondingly limited in
the operations it can perform. If the
DEFINER account is highly privileged
(such as a root account), the object can
perform powerful operations no matter who invokes
it.
A stored routine or view that executes in invoker security
context can perform only operations for which the invoker
has privileges. The DEFINER attribute has
no effect during object execution.
Consider the following stored procedure, which is declared with
SQL SECURITY DEFINER to execute in definer
security context:
CREATE DEFINER = 'admin'@'localhost' PROCEDURE p1() SQL SECURITY DEFINER BEGIN UPDATE t1 SET counter = counter + 1; END;
Any user who has the EXECUTE
privilege for p1 can invoke it with a
CALL statement. However, when
p1 executes, it does so in definer security
context and thus executes with the privileges of
'admin'@'localhost', the account named in the
DEFINER attribute. This account must have the
EXECUTE privilege for
p1 as well as the
UPDATE privilege for the table
t1 referenced within the object body.
Otherwise, the procedure fails.
Now consider this stored procedure, which is identical to
p1 except that its SQL
SECURITY characteristic is INVOKER:
CREATE DEFINER = 'admin'@'localhost' PROCEDURE p2() SQL SECURITY INVOKER BEGIN UPDATE t1 SET counter = counter + 1; END;
Unlike p1, p2 executes in
invoker security context and thus with the privileges of the
invoking user regardless of the DEFINER
attribute value. p2 fails if the invoker
lacks the EXECUTE privilege for
p2 or the
UPDATE privilege for the table
t1.
To minimize the risk potential for stored object creation and use, follow these guidelines:
For a stored routine or view, use SQL SECURITY
INVOKER in the object definition when possible so
that it can be used only by users with permissions
appropriate for the operations performed by the object.
If you create definer-context stored objects while using an
account that has the SUPER
privilege, specify an explicit DEFINER
attribute that names an account possessing only the
privileges required for the operations performed by the
object. Specify a highly privileged
DEFINER account only when absolutely
necessary.
Administrators can prevent users from creating stored
objects that specify highly privileged
DEFINER accounts by not granting them the
SUPER privilege.
Definer-context objects should be written keeping in mind that they may be able to access data for which the invoking user has no privileges. In some cases, you can prevent references to these objects by not granting unauthorized users particular privileges:
However, no such control exists for triggers and events because they always execute in definer context. The server invokes these objects automatically as necessary; users do not reference them directly:
A trigger is activated by access to the table with which it is associated, even ordinary table accesses by users with no special privileges.
An event is executed by the server on a scheduled basis.
In both cases, if the DEFINER account is
highly privileged, the object may be able to perform
sensitive or dangerous operations. This remains true if the
privileges needed to create the object are revoked from the
account of the user who created it. Administrators should be
especially careful about granting users object-creation
privileges.
The binary log contains information about SQL statements that modify database contents. This information is stored in the form of “events” that describe the modifications. (Binary log events differ from scheduled event stored objects.) The binary log has two important purposes:
For replication, the binary log is used on master replication servers as a record of the statements to be sent to slave servers. The master server sends the events contained in its binary log to its slaves, which execute those events to make the same data changes that were made on the master. See Section 16.2, “Replication Implementation”.
Certain data recovery operations require use of the binary log. After a backup file has been restored, the events in the binary log that were recorded after the backup was made are re-executed. These events bring databases up to date from the point of the backup. See Section 7.3.2, “Using Backups for Recovery”.
However, if logging occurs at the statement level, there are certain binary logging issues with respect to stored programs (stored procedures and functions, triggers, and events):
In some cases, a statement might affect different sets of rows on master and slave.
Replicated statements executed on a slave are processed by the slave SQL thread, which has full privileges. It is possible for a procedure to follow different execution paths on master and slave servers, so a user can write a routine containing a dangerous statement that will execute only on the slave where it is processed by a thread that has full privileges.
If a stored program that modifies data is nondeterministic, it is not repeatable. This can result in different data on master and slave, or cause restored data to differ from the original data.
This section describes how MySQL handles binary logging for stored programs. It states the current conditions that the implementation places on the use of stored programs, and what you can do to avoid logging problems. It also provides additional information about the reasons for these conditions.
In general, the issues described here result when binary logging
occurs at the SQL statement level (statement-based binary
logging). If you use row-based binary logging, the log contains
changes made to individual rows as a result of executing SQL
statements. When routines or triggers execute, row changes are
logged, not the statements that make the changes. For stored
procedures, this means that the
CALL statement is not logged. For
stored functions, row changes made within the function are logged,
not the function invocation. For triggers, row changes made by the
trigger are logged. On the slave side, only the row changes are
seen, not the stored program invocation.
Mixed format binary logging
(binlog_format=MIXED) uses
statement-based binary logging, except for cases where only
row-based binary logging is guaranteed to lead to proper results.
With mixed format, when a stored function, stored procedure,
trigger, event, or prepared statement contains anything that is
not safe for statement-based binary logging, the entire statement
is marked as unsafe and logged in row format. The statements used
to create and drop procedures, functions, triggers, and events are
always safe, and are logged in statement format. For more
information about row-based, mixed, and statement-based logging,
and how safe and unsafe statements are determined, see
Section 16.2.1, “Replication Formats”.
Unless noted otherwise, the remarks here assume that binary logging is enabled on the server (see Section 5.4.4, “The Binary Log”.) If the binary log is not enabled, replication is not possible, nor is the binary log available for data recovery.
The conditions on the use of stored functions in MySQL can be summarized as follows. These conditions do not apply to stored procedures or Event Scheduler events and they do not apply unless binary logging is enabled.
To create or alter a stored function, you must have the
SUPER privilege, in addition to
the CREATE ROUTINE or
ALTER ROUTINE privilege that is
normally required. (Depending on the
DEFINER value in the function definition,
SUPER might be required
regardless of whether binary logging is enabled. See
Section 13.1.16, “CREATE PROCEDURE and CREATE FUNCTION Statements”.)
When you create a stored function, you must declare either that it is deterministic or that it does not modify data. Otherwise, it may be unsafe for data recovery or replication.
By default, for a CREATE
FUNCTION statement to be accepted, at least one of
DETERMINISTIC, NO SQL,
or READS SQL DATA must be specified
explicitly. Otherwise an error occurs:
ERROR 1418 (HY000): This function has none of DETERMINISTIC, NO SQL, or READS SQL DATA in its declaration and binary logging is enabled (you *might* want to use the less safe log_bin_trust_function_creators variable)
This function is deterministic (and does not modify data), so it is safe:
CREATE FUNCTION f1(i INT) RETURNS INT DETERMINISTIC READS SQL DATA BEGIN RETURN i; END;
This function uses UUID(),
which is not deterministic, so the function also is not
deterministic and is not safe:
CREATE FUNCTION f2() RETURNS CHAR(36) CHARACTER SET utf8 BEGIN RETURN UUID(); END;
This function modifies data, so it may not be safe:
CREATE FUNCTION f3(p_id INT) RETURNS INT BEGIN UPDATE t SET modtime = NOW() WHERE id = p_id; RETURN ROW_COUNT(); END;
Assessment of the nature of a function is based on the
“honesty” of the creator. MySQL does not check
that a function declared DETERMINISTIC is
free of statements that produce nondeterministic results.
When you attempt to execute a stored function, if
binlog_format=STATEMENT is
set, the DETERMINISTIC keyword must be
specified in the function definition. If this is not the case,
an error is generated and the function does not run, unless
log_bin_trust_function_creators=1
is specified to override this check (see below). For recursive
function calls, the DETERMINISTIC keyword
is required on the outermost call only. If row-based or mixed
binary logging is in use, the statement is accepted and
replicated even if the function was defined without the
DETERMINISTIC keyword.
Because MySQL does not check if a function really is
deterministic at creation time, the invocation of a stored
function with the DETERMINISTIC keyword
might carry out an action that is unsafe for statement-based
logging, or invoke a function or procedure containing unsafe
statements. If this occurs when
binlog_format=STATEMENT is
set, a warning message is issued. If row-based or mixed binary
logging is in use, no warning is issued, and the statement is
replicated in row-based format.
To relax the preceding conditions on function creation (that
you must have the SUPER
privilege and that a function must be declared deterministic
or to not modify data), set the global
log_bin_trust_function_creators
system variable to 1. By default, this variable has a value of
0, but you can change it like this:
mysql> SET GLOBAL log_bin_trust_function_creators = 1;
You can also set this variable at server startup.
If binary logging is not enabled,
log_bin_trust_function_creators
does not apply. SUPER is not
required for function creation unless, as described
previously, the DEFINER value in the
function definition requires it.
For information about built-in functions that may be unsafe for replication (and thus cause stored functions that use them to be unsafe as well), see Section 16.4.1, “Replication Features and Issues”.
Triggers are similar to stored functions, so the preceding remarks
regarding functions also apply to triggers with the following
exception: CREATE TRIGGER does not
have an optional DETERMINISTIC characteristic,
so triggers are assumed to be always deterministic. However, this
assumption might be invalid in some cases. For example, the
UUID() function is nondeterministic
(and does not replicate). Be careful about using such functions in
triggers.
Triggers can update tables, so error messages similar to those for
stored functions occur with CREATE
TRIGGER if you do not have the required privileges. On
the slave side, the slave uses the trigger
DEFINER attribute to determine which user is
considered to be the creator of the trigger.
The rest of this section provides additional detail about the
logging implementation and its implications. You need not read it
unless you are interested in the background on the rationale for
the current logging-related conditions on stored routine use. This
discussion applies only for statement-based logging, and not for
row-based logging, with the exception of the first item:
CREATE and DROP statements
are logged as statements regardless of the logging mode.
The server writes CREATE EVENT,
CREATE PROCEDURE,
CREATE FUNCTION,
ALTER EVENT,
ALTER PROCEDURE,
ALTER FUNCTION,
DROP EVENT,
DROP PROCEDURE, and
DROP FUNCTION statements to the
binary log.
A stored function invocation is logged as a
SELECT statement if the
function changes data and occurs within a statement that would
not otherwise be logged. This prevents nonreplication of data
changes that result from use of stored functions in nonlogged
statements. For example, SELECT
statements are not written to the binary log, but a
SELECT might invoke a stored
function that makes changes. To handle this, a SELECT
statement is
written to the binary log when the given function makes a
change. Suppose that the following statements are executed on
the master:
func_name()
CREATE FUNCTION f1(a INT) RETURNS INT
BEGIN
IF (a < 3) THEN
INSERT INTO t2 VALUES (a);
END IF;
RETURN 0;
END;
CREATE TABLE t1 (a INT);
INSERT INTO t1 VALUES (1),(2),(3);
SELECT f1(a) FROM t1;
When the SELECT statement
executes, the function f1() is invoked
three times. Two of those invocations insert a row, and MySQL
logs a SELECT statement for
each of them. That is, MySQL writes the following statements
to the binary log:
SELECT f1(1); SELECT f1(2);
The server also logs a SELECT
statement for a stored function invocation when the function
invokes a stored procedure that causes an error. In this case,
the server writes the SELECT
statement to the log along with the expected error code. On
the slave, if the same error occurs, that is the expected
result and replication continues. Otherwise, replication
stops.
Logging stored function invocations rather than the statements executed by a function has a security implication for replication, which arises from two factors:
It is possible for a function to follow different execution paths on master and slave servers.
Statements executed on a slave are processed by the slave SQL thread which has full privileges.
The implication is that although a user must have the
CREATE ROUTINE privilege to
create a function, the user can write a function containing a
dangerous statement that will execute only on the slave where
it is processed by a thread that has full privileges. For
example, if the master and slave servers have server ID values
of 1 and 2, respectively, a user on the master server could
create and invoke an unsafe function
unsafe_func() as follows:
mysql>delimiter //mysql>CREATE FUNCTION unsafe_func () RETURNS INT->BEGIN->IF @@server_id=2 THEN->dangerous_statement; END IF;RETURN 1;->END;->//mysql>delimiter ;mysql>INSERT INTO t VALUES(unsafe_func());
The CREATE FUNCTION and
INSERT statements are written
to the binary log, so the slave will execute them. Because the
slave SQL thread has full privileges, it will execute the
dangerous statement. Thus, the function invocation has
different effects on the master and slave and is not
replication-safe.
To guard against this danger for servers that have binary
logging enabled, stored function creators must have the
SUPER privilege, in addition to
the usual CREATE ROUTINE
privilege that is required. Similarly, to use
ALTER FUNCTION, you must have
the SUPER privilege in addition
to the ALTER ROUTINE privilege.
Without the SUPER privilege, an
error will occur:
ERROR 1419 (HY000): You do not have the SUPER privilege and binary logging is enabled (you *might* want to use the less safe log_bin_trust_function_creators variable)
If you do not want to require function creators to have the
SUPER privilege (for example,
if all users with the CREATE
ROUTINE privilege on your system are experienced
application developers), set the global
log_bin_trust_function_creators
system variable to 1. You can also set this variable at server
startup. If binary logging is not enabled,
log_bin_trust_function_creators
does not apply. SUPER is not
required for function creation unless, as described
previously, the DEFINER value in the
function definition requires it.
If a function that performs updates is nondeterministic, it is not repeatable. This can have two undesirable effects:
It will make a slave different from the master.
Restored data will be different from the original data.
To deal with these problems, MySQL enforces the following requirement: On a master server, creation and alteration of a function is refused unless you declare the function to be deterministic or to not modify data. Two sets of function characteristics apply here:
The DETERMINISTIC and NOT
DETERMINISTIC characteristics indicate whether a
function always produces the same result for given inputs.
The default is NOT DETERMINISTIC if
neither characteristic is given. To declare that a
function is deterministic, you must specify
DETERMINISTIC explicitly.
The CONTAINS SQL, NO
SQL, READS SQL DATA, and
MODIFIES SQL DATA characteristics
provide information about whether the function reads or
writes data. Either NO SQL or
READS SQL DATA indicates that a
function does not change data, but you must specify one of
these explicitly because the default is CONTAINS
SQL if no characteristic is given.
By default, for a CREATE
FUNCTION statement to be accepted, at least one of
DETERMINISTIC, NO SQL,
or READS SQL DATA must be specified
explicitly. Otherwise an error occurs:
ERROR 1418 (HY000): This function has none of DETERMINISTIC, NO SQL, or READS SQL DATA in its declaration and binary logging is enabled (you *might* want to use the less safe log_bin_trust_function_creators variable)
If you set
log_bin_trust_function_creators
to 1, the requirement that functions be deterministic or not
modify data is dropped.
Stored procedure calls are logged at the statement level
rather than at the CALL level.
That is, the server does not log the
CALL statement, it logs those
statements within the procedure that actually execute. As a
result, the same changes that occur on the master will be
observed on slave servers. This prevents problems that could
result from a procedure having different execution paths on
different machines.
In general, statements executed within a stored procedure are written to the binary log using the same rules that would apply were the statements to be executed in standalone fashion. Some special care is taken when logging procedure statements because statement execution within procedures is not quite the same as in nonprocedure context:
A statement to be logged might contain references to local procedure variables. These variables do not exist outside of stored procedure context, so a statement that refers to such a variable cannot be logged literally. Instead, each reference to a local variable is replaced by this construct for logging purposes:
NAME_CONST(var_name,var_value)
var_name is the local variable
name, and var_value is a
constant indicating the value that the variable has at the
time the statement is logged.
NAME_CONST() has a value of
var_value, and a
“name” of
var_name. Thus, if you invoke
this function directly, you get a result like this:
mysql> SELECT NAME_CONST('myname', 14);
+--------+
| myname |
+--------+
| 14 |
+--------+
NAME_CONST() enables a
logged standalone statement to be executed on a slave with
the same effect as the original statement that was
executed on the master within a stored procedure.
The use of NAME_CONST() can
result in a problem for
CREATE TABLE
... SELECT statements when the source column
expressions refer to local variables. Converting these
references to NAME_CONST()
expressions can result in column names that are different
on the master and slave servers, or names that are too
long to be legal column identifiers. A workaround is to
supply aliases for columns that refer to local variables.
Consider this statement when myvar has
a value of 1:
CREATE TABLE t1 SELECT myvar;
That will be rewritten as follows:
CREATE TABLE t1 SELECT NAME_CONST(myvar, 1);
To ensure that the master and slave tables have the same column names, write the statement like this:
CREATE TABLE t1 SELECT myvar AS myvar;
The rewritten statement becomes:
CREATE TABLE t1 SELECT NAME_CONST(myvar, 1) AS myvar;
A statement to be logged might contain references to
user-defined variables. To handle this, MySQL writes a
SET
statement to the binary log to make sure that the variable
exists on the slave with the same value as on the master.
For example, if a statement refers to a variable
@my_var, that statement will be
preceded in the binary log by the following statement,
where value is the value of
@my_var on the master:
SET @my_var = value;
Procedure calls can occur within a committed or
rolled-back transaction. Transactional context is
accounted for so that the transactional aspects of
procedure execution are replicated correctly. That is, the
server logs those statements within the procedure that
actually execute and modify data, and also logs
BEGIN,
COMMIT, and
ROLLBACK
statements as necessary. For example, if a procedure
updates only transactional tables and is executed within a
transaction that is rolled back, those updates are not
logged. If the procedure occurs within a committed
transaction,
BEGIN
and COMMIT statements are
logged with the updates. For a procedure that executes
within a rolled-back transaction, its statements are
logged using the same rules that would apply if the
statements were executed in standalone fashion:
Updates to transactional tables are not logged.
Updates to nontransactional tables are logged because rollback does not cancel them.
Updates to a mix of transactional and nontransactional
tables are logged surrounded by
BEGIN
and
ROLLBACK
so that slaves will make the same changes and
rollbacks as on the master.
A stored procedure call is not written to
the binary log at the statement level if the procedure is
invoked from within a stored function. In that case, the only
thing logged is the statement that invokes the function (if it
occurs within a statement that is logged) or a
DO statement (if it occurs
within a statement that is not logged). For this reason, care
should be exercised in the use of stored functions that invoke
a procedure, even if the procedure is otherwise safe in
itself.
These restrictions apply to the features described in Chapter 23, Stored Objects.
Some of the restrictions noted here apply to all stored routines; that is, both to stored procedures and stored functions. There are also some restrictions specific to stored functions but not to stored procedures.
The restrictions for stored functions also apply to triggers. There are also some restrictions specific to triggers.
The restrictions for stored procedures also apply to the
DO clause of Event Scheduler event
definitions. There are also some
restrictions
specific to events.
Stored routines cannot contain arbitrary SQL statements. The following statements are not permitted:
The locking statements LOCK
TABLES and
UNLOCK
TABLES.
LOAD DATA and LOAD
TABLE.
SQL prepared statements
(PREPARE,
EXECUTE,
DEALLOCATE PREPARE) can be
used in stored procedures, but not stored functions or
triggers. Thus, stored functions and triggers cannot use
dynamic SQL (where you construct statements as strings and
then execute them).
Generally, statements not permitted in SQL prepared
statements are also not permitted in stored programs. For a
list of statements supported as prepared statements, see
Section 13.5, “Prepared Statements”. Exceptions
are SIGNAL,
RESIGNAL, and
GET DIAGNOSTICS, which are
not permissible as prepared statements but are permitted in
stored programs.
Because local variables are in scope only during stored
program execution, references to them are not permitted in
prepared statements created within a stored program.
Prepared statement scope is the current session, not the
stored program, so the statement could be executed after the
program ends, at which point the variables would no longer
be in scope. For example, SELECT ... INTO
cannot be
used as a prepared statement. This restriction also applies
to stored procedure and function parameters. See
Section 13.5.1, “PREPARE Statement”.
local_var
Within all stored programs (stored procedures and functions,
triggers, and events), the parser treats
BEGIN
[WORK] as the beginning of a
BEGIN ...
END block. To begin a transaction in this context,
use START
TRANSACTION instead.
The following additional statements or operations are not
permitted within stored functions. They are permitted within
stored procedures, except stored procedures that are invoked
from within a stored function or trigger. For example, if you
use FLUSH in a stored procedure,
that stored procedure cannot be called from a stored function or
trigger.
Statements that perform explicit or implicit commit or rollback. Support for these statements is not required by the SQL standard, which states that each DBMS vendor may decide whether to permit them.
Statements that return a result set. This includes
SELECT statements that do not
have an INTO
clause and
other statements such as
var_listSHOW,
EXPLAIN, and
CHECK TABLE. A function can
process a result set either with
SELECT ... INTO
or by using a
cursor and var_listFETCH statements.
See Section 13.2.9.1, “SELECT ... INTO Statement”, and
Section 13.6.6, “Cursors”.
FLUSH statements.
Stored functions cannot be used recursively.
A stored function or trigger cannot modify a table that is already being used (for reading or writing) by the statement that invoked the function or trigger.
If you refer to a temporary table multiple times in a stored
function under different aliases, a Can't reopen
table:
'
error occurs, even if the references occur in different
statements within the function.
tbl_name'
HANDLER ...
READ statements that invoke stored functions can
cause replication errors and are disallowed.
For triggers, the following additional restrictions apply:
Triggers are not activated by foreign key actions.
When using row-based replication, triggers on the slave are not activated by statements originating on the master. The triggers on the slave are activated when using statement-based replication. For more information, see Section 16.4.1.34, “Replication and Triggers”.
The RETURN statement is not
permitted in triggers, which cannot return a value. To exit
a trigger immediately, use the
LEAVE statement.
Triggers are not permitted on tables in the
mysql database. Nor are they permitted on
INFORMATION_SCHEMA or
performance_schema tables. Those tables
are actually views and triggers are not permitted on views.
The trigger cache does not detect when metadata of the underlying objects has changed. If a trigger uses a table and the table has changed since the trigger was loaded into the cache, the trigger operates using the outdated metadata.
The same identifier might be used for a routine parameter, a local variable, and a table column. Also, the same local variable name can be used in nested blocks. For example:
CREATE PROCEDURE p (i INT)
BEGIN
DECLARE i INT DEFAULT 0;
SELECT i FROM t;
BEGIN
DECLARE i INT DEFAULT 1;
SELECT i FROM t;
END;
END;In such cases, the identifier is ambiguous and the following precedence rules apply:
A local variable takes precedence over a routine parameter or table column.
A routine parameter takes precedence over a table column.
A local variable in an inner block takes precedence over a local variable in an outer block.
The behavior that variables take precedence over table columns is nonstandard.
Use of stored routines can cause replication problems. This issue is discussed further in Section 23.7, “Stored Program Binary Logging”.
The
--replicate-wild-do-table=
option applies to tables, views, and triggers. It does not apply
to stored procedures and functions, or events. To filter
statements operating on the latter objects, use one or more of
the db_name.tbl_name--replicate-*-db options.
The MySQL stored routine syntax is based on the SQL:2003 standard. The following items from that standard are not currently supported:
UNDO handlers
FOR loops
To prevent problems of interaction between sessions, when a client issues a statement, the server uses a snapshot of routines and triggers available for execution of the statement. That is, the server calculates a list of procedures, functions, and triggers that may be used during execution of the statement, loads them, and then proceeds to execute the statement. While the statement executes, it does not see changes to routines performed by other sessions.
For maximum concurrency, stored functions should minimize their side-effects; in particular, updating a table within a stored function can reduce concurrent operations on that table. A stored function acquires table locks before executing, to avoid inconsistency in the binary log due to mismatch of the order in which statements execute and when they appear in the log. When statement-based binary logging is used, statements that invoke a function are recorded rather than the statements executed within the function. Consequently, stored functions that update the same underlying tables do not execute in parallel. In contrast, stored procedures do not acquire table-level locks. All statements executed within stored procedures are written to the binary log, even for statement-based binary logging. See Section 23.7, “Stored Program Binary Logging”.
The following limitations are specific to the Event Scheduler:
Event names are handled in case-insensitive fashion. For
example, you cannot have two events in the same database
with the names anEvent and
AnEvent.
An event may not be created, altered, or dropped from within a stored program, if the event name is specified by means of a variable. An event also may not create, alter, or drop stored routines or triggers.
DDL statements on events are prohibited while a
LOCK TABLES statement is in
effect.
Event timings using the intervals YEAR,
QUARTER, MONTH, and
YEAR_MONTH are resolved in months; those
using any other interval are resolved in seconds. There is
no way to cause events scheduled to occur at the same second
to execute in a given order. In addition—due to
rounding, the nature of threaded applications, and the fact
that a nonzero length of time is required to create events
and to signal their execution—events may be delayed by
as much as 1 or 2 seconds. However, the time shown in the
INFORMATION_SCHEMA.EVENTS
table's LAST_EXECUTED column or the
mysql.event table's
last_executed column is always accurate
to within one second of the actual event execution time.
(See also Bug #16522.)
Each execution of the statements contained in the body of an
event takes place in a new connection; thus, these
statements has no effect in a given user session on the
server's statement counts such as
Com_select and
Com_insert that are displayed by
SHOW STATUS. However, such
counts are updated in the global scope.
(Bug #16422)
Events do not support times later than the end of the Unix Epoch; this is approximately the beginning of the year 2038. Such dates are specifically not permitted by the Event Scheduler. (Bug #16396)
References to stored functions, user-defined functions, and
tables in the ON SCHEDULE clauses of
CREATE EVENT and
ALTER EVENT statements are
not supported. These sorts of references are not permitted.
(See Bug #22830 for more information.)
Stored routines and triggers in NDB Cluster.
Stored procedures, stored functions, and triggers are all
supported by tables using the NDB
storage engine; however, it is important to keep in mind that
they do not propagate automatically
between MySQL Servers acting as Cluster SQL nodes. This is
because of the following:
Stored routine definitions are kept in tables in the
mysql system database using the
MyISAM storage engine, and so do not
participate in clustering.
The .TRN and
.TRG files containing trigger
definitions are not read by the
NDB storage engine, and are
not copied between Cluster nodes.
Any stored routine or trigger that interacts with NDB Cluster
tables must be re-created by running the appropriate
CREATE PROCEDURE,
CREATE FUNCTION, or
CREATE TRIGGER statements on
each MySQL Server that participates in the cluster where you
wish to use the stored routine or trigger. Similarly, any
changes to existing stored routines or triggers must be
carried out explicitly on all Cluster SQL nodes, using the
appropriate ALTER or
DROP statements on each MySQL Server
accessing the cluster.
Do not attempt to work around the
issue described in the first item mentioned previously by
converting any mysql database tables to
use the NDB storage engine.
Altering the system tables in the
mysql database is not
supported and is very likely to produce
undesirable results.
The maximum number of tables that can be referenced in the definition of a view is 61.
View processing is not optimized:
It is not possible to create an index on a view.
Indexes can be used for views processed using the merge algorithm. However, a view that is processed with the temptable algorithm is unable to take advantage of indexes on its underlying tables (although indexes can be used during generation of the temporary tables).
Before MySQL 5.7.7, subqueries cannot be used in the
FROM clause of a view.
There is a general principle that you cannot modify a table and select from the same table in a subquery. See Section 13.2.10.12, “Restrictions on Subqueries”.
The same principle also applies if you select from a view that selects from the table, if the view selects from the table in a subquery and the view is evaluated using the merge algorithm. Example:
CREATE VIEW v1 AS SELECT * FROM t2 WHERE EXISTS (SELECT 1 FROM t1 WHERE t1.a = t2.a); UPDATE t1, v2 SET t1.a = 1 WHERE t1.b = v2.b;
If the view is evaluated using a temporary table, you
can select from the table in the view
subquery and still modify that table in the outer query. In this
case the view will be stored in a temporary table and thus you are
not really selecting from the table in a subquery and modifying it
“at the same time.” (This is another reason you might
wish to force MySQL to use the temptable algorithm by specifying
ALGORITHM = TEMPTABLE in the view definition.)
You can use DROP TABLE or
ALTER TABLE to drop or alter a
table that is used in a view definition. No warning results from
the DROP or ALTER operation,
even though this invalidates the view. Instead, an error occurs
later, when the view is used. CHECK
TABLE can be used to check for views that have been
invalidated by DROP or ALTER
operations.
With regard to view updatability, the overall goal for views is that if any view is theoretically updatable, it should be updatable in practice. MySQL as quickly as possible. Many theoretically updatable views can be updated now, but limitations still exist. For details, see Section 23.5.3, “Updatable and Insertable Views”.
There exists a shortcoming with the current implementation of
views. If a user is granted the basic privileges necessary to
create a view (the CREATE VIEW and
SELECT privileges), that user will
be unable to call SHOW CREATE VIEW
on that object unless the user is also granted the
SHOW VIEW privilege.
That shortcoming can lead to problems backing up a database with mysqldump, which may fail due to insufficient privileges. This problem is described in Bug #22062.
The workaround to the problem is for the administrator to manually
grant the SHOW VIEW privilege to
users who are granted CREATE VIEW,
since MySQL doesn't grant it implicitly when views are created.
Views do not have indexes, so index hints do not apply. Use of index hints when selecting from a view is not permitted.
SHOW CREATE VIEW displays view
definitions using an AS
clause for each
column. If a column is created from an expression, the default
alias is the expression text, which can be quite long. Aliases for
column names in alias_nameCREATE VIEW
statements are checked against the maximum column length of 64
characters (not the maximum alias length of 256 characters). As a
result, views created from the output of SHOW
CREATE VIEW fail if any column alias exceeds 64
characters. This can cause problems in the following circumstances
for views with too-long aliases:
View definitions fail to replicate to newer slaves that enforce the column-length restriction.
Dump files created with mysqldump cannot be loaded into servers that enforce the column-length restriction.
A workaround for either problem is to modify each problematic view
definition to use aliases that provide shorter column names. Then
the view will replicate properly, and can be dumped and reloaded
without causing an error. To modify the definition, drop and
create the view again with DROP
VIEW and CREATE VIEW, or
replace the definition with
CREATE OR REPLACE
VIEW.
For problems that occur when reloading view definitions in dump
files, another workaround is to edit the dump file to modify its
CREATE VIEW statements. However,
this does not change the original view definitions, which may
cause problems for subsequent dump operations.