The optimizer_switch
system
variable enables control over optimizer behavior. Its value is a
set of flags, each of which has a value of on
or off
to indicate whether the corresponding
optimizer behavior is enabled or disabled. This variable has
global and session values and can be changed at runtime. The
global default can be set at server startup.
To see the current set of optimizer flags, select the variable value:
mysql> SELECT @@optimizer_switch\G
*************************** 1. row ***************************
@@optimizer_switch: index_merge=on,index_merge_union=on,
index_merge_sort_union=on,index_merge_intersection=on,
engine_condition_pushdown=on,index_condition_pushdown=on,
mrr=on,mrr_cost_based=on,block_nested_loop=on,
batched_key_access=off,materialization=on,semijoin=on,
loosescan=on,firstmatch=on,duplicateweedout=on,
subquery_materialization_cost_based=on,
use_index_extensions=on,condition_fanout_filter=on,
derived_merge=on,use_invisible_indexes=off,skip_scan=on,
hash_join=on,subquery_to_derived=off,
prefer_ordering_index=on,hypergraph_optimizer=off,
derived_condition_pushdown=on,hash_set_operations=on
1 row in set (0.00 sec)
To change the value of
optimizer_switch
, assign a
value consisting of a comma-separated list of one or more
commands:
SET [GLOBAL|SESSION] optimizer_switch='command[,command]...';
Each command
value should have one of
the forms shown in the following table.
Command Syntax | Meaning |
---|---|
default |
Reset every optimization to its default value |
|
Set the named optimization to its default value |
|
Disable the named optimization |
|
Enable the named optimization |
The order of the commands in the value does not matter, although
the default
command is executed first if
present. Setting an opt_name
flag to
default
sets it to whichever of
on
or off
is its default
value. Specifying any given opt_name
more than once in the value is not permitted and causes an
error. Any errors in the value cause the assignment to fail with
an error, leaving the value of
optimizer_switch
unchanged.
The following list describes the permissible
opt_name
flag names, grouped by
optimization strategy:
Batched Key Access Flags
batched_key_access
(defaultoff
)Controls use of BKA join algorithm.
For
batched_key_access
to have any effect when set toon
, themrr
flag must also beon
. Currently, the cost estimation for MRR is too pessimistic. Hence, it is also necessary formrr_cost_based
to beoff
for BKA to be used.For more information, see Section 10.2.1.12, “Block Nested-Loop and Batched Key Access Joins”.
Block Nested-Loop Flags
block_nested_loop
(defaulton
)Controls use of hash joins, as do the
BNL
andNO_BNL
optimizer hints.
For more information, see Section 10.2.1.12, “Block Nested-Loop and Batched Key Access Joins”.
Condition Filtering Flags
condition_fanout_filter
(defaulton
)Controls use of condition filtering.
For more information, see Section 10.2.1.13, “Condition Filtering”.
Derived Condition Pushdown Flags
derived_condition_pushdown
(defaulton
)Controls derived condition pushdown.
For more information, see Section 10.2.2.5, “Derived Condition Pushdown Optimization”
Derived Table Merging Flags
derived_merge
(defaulton
)Controls merging of derived tables and views into outer query block.
The
derived_merge
flag controls whether the optimizer attempts to merge derived tables, view references, and common table expressions into the outer query block, assuming that no other rule prevents merging; for example, anALGORITHM
directive for a view takes precedence over thederived_merge
setting. By default, the flag ison
to enable merging.For more information, see Section 10.2.2.4, “Optimizing Derived Tables, View References, and Common Table Expressions with Merging or Materialization”.
Engine Condition Pushdown Flags
engine_condition_pushdown
(defaulton
)Controls engine condition pushdown.
For more information, see Section 10.2.1.5, “Engine Condition Pushdown Optimization”.
Hash Join Flags
hash_join
(defaulton
)Has no effect in MySQL 9.0. Use the
block_nested_loop
flag, instead.
For more information, see Section 10.2.1.4, “Hash Join Optimization”.
Index Condition Pushdown Flags
index_condition_pushdown
(defaulton
)Controls index condition pushdown.
For more information, see Section 10.2.1.6, “Index Condition Pushdown Optimization”.
Index Extensions Flags
use_index_extensions
(defaulton
)Controls use of index extensions.
For more information, see Section 10.3.10, “Use of Index Extensions”.
Index Merge Flags
index_merge
(defaulton
)Controls all Index Merge optimizations.
index_merge_intersection
(defaulton
)Controls the Index Merge Intersection Access optimization.
index_merge_sort_union
(defaulton
)Controls the Index Merge Sort-Union Access optimization.
index_merge_union
(defaulton
)Controls the Index Merge Union Access optimization.
For more information, see Section 10.2.1.3, “Index Merge Optimization”.
Index Visibility Flags
use_invisible_indexes
(defaultoff
)Controls use of invisible indexes.
For more information, see Section 10.3.12, “Invisible Indexes”.
Limit Optimization Flags
prefer_ordering_index
(defaulton
)Controls whether, in the case of a query having an
ORDER BY
orGROUP BY
with aLIMIT
clause, the optimizer tries to use an ordered index instead of an unordered index, a filesort, or some other optimization. This optimization is performed by default whenever the optimizer determines that using it would allow for faster execution of the query.Because the algorithm that makes this determination cannot handle every conceivable case (due in part to the assumption that the distribution of data is always more or less uniform), there are cases in which this optimization may not be desirable. This optimization can be disabled by setting the
prefer_ordering_index
flag tooff
.
For more information and examples, see Section 10.2.1.19, “LIMIT Query Optimization”.
Multi-Range Read Flags
mrr
(defaulton
)Controls the Multi-Range Read strategy.
mrr_cost_based
(defaulton
)Controls use of cost-based MRR if
mrr=on
.
For more information, see Section 10.2.1.11, “Multi-Range Read Optimization”.
Semijoin Flags
duplicateweedout
(defaulton
)Controls the semijoin Duplicate Weedout strategy.
firstmatch
(defaulton
)Controls the semijoin FirstMatch strategy.
loosescan
(defaulton
)Controls the semijoin LooseScan strategy (not to be confused with Loose Index Scan for
GROUP BY
).semijoin
(defaulton
)Controls all semijoin strategies.
This also applies to the antijoin optimization.
The
semijoin
,firstmatch
,loosescan
, andduplicateweedout
flags enable control over semijoin strategies. Thesemijoin
flag controls whether semijoins are used. If it is set toon
, thefirstmatch
andloosescan
flags enable finer control over the permitted semijoin strategies.If the
duplicateweedout
semijoin strategy is disabled, it is not used unless all other applicable strategies are also disabled.If
semijoin
andmaterialization
are bothon
, semijoins also use materialization where applicable. These flags areon
by default.For more information, see Optimizing IN and EXISTS Subquery Predicates with Semijoin Transformations.
Set Operations Flags
hash_set_operations
(defaulton
)Enables the hash table optimization for set operations involving
EXCEPT
andINTERSECT
); enabled by default. Otherwise, temporary table based de-duplication is used, as in previous versions of MySQL.The amount of memory used for hashing by this optimization can be controlled using the
set_operations_buffer_size
system variable; increasing this generally results in faster execution times for statements using these operations.
Skip Scan Flags
skip_scan
(defaulton
)Controls use of Skip Scan access method.
For more information, see Skip Scan Range Access Method.
Subquery Materialization Flags
materialization
(defaulton
)Controls materialization (including semijoin materialization).
subquery_materialization_cost_based
(defaulton
)Use cost-based materialization choice.
The
materialization
flag controls whether subquery materialization is used. Ifsemijoin
andmaterialization
are bothon
, semijoins also use materialization where applicable. These flags areon
by default.The
subquery_materialization_cost_based
flag enables control over the choice between subquery materialization andIN
-to-EXISTS
subquery transformation. If the flag ison
(the default), the optimizer performs a cost-based choice between subquery materialization andIN
-to-EXISTS
subquery transformation if either method could be used. If the flag isoff
, the optimizer chooses subquery materialization overIN
-to-EXISTS
subquery transformation.For more information, see Section 10.2.2, “Optimizing Subqueries, Derived Tables, View References, and Common Table Expressions”.
Subquery Transformation Flags
subquery_to_derived
(defaultoff
)The optimizer is able in many cases to transform a scalar subquery in a
SELECT
,WHERE
,JOIN
, orHAVING
clause into a left outer joins on a derived table. (Depending on the nullability of the derived table, this can sometimes be simplified further to an inner join.) This can be done for a subquery which meets the following conditions:The subquery does not make use of any nondeterministic functions, such as
RAND()
.The subquery is not an
ANY
orALL
subquery which can be rewritten to useMIN()
orMAX()
.The parent query does not set a user variable, since rewriting it may affect the order of execution, which could lead to unexpected results if the variable is accessed more than once in the same query.
The subquery should not be correlated, that is, it should not reference a column from a table in the outer query, or contain an aggregate that is evaluated in the outer query.
This optimization can also be applied to a table subquery which is the argument to
IN
,NOT IN
,EXISTS
, orNOT EXISTS
, that does not contain aGROUP BY
.The default value for this flag is
off
, since, in most cases, enabling this optimization does not produce any noticeable improvement in performance (and in many cases can even make queries run more slowly), but you can enable the optimization by setting thesubquery_to_derived
flag toon
. It is primarily intended for use in testing.Example, using a scalar subquery:
d mysql> CREATE TABLE t1(a INT); mysql> CREATE TABLE t2(a INT); mysql> INSERT INTO t1 VALUES ROW(1), ROW(2), ROW(3), ROW(4); mysql> INSERT INTO t2 VALUES ROW(1), ROW(2); mysql> SELECT * FROM t1 -> WHERE t1.a > (SELECT COUNT(a) FROM t2); +------+ | a | +------+ | 3 | | 4 | +------+ mysql> SELECT @@optimizer_switch LIKE '%subquery_to_derived=off%'; +-----------------------------------------------------+ | @@optimizer_switch LIKE '%subquery_to_derived=off%' | +-----------------------------------------------------+ | 1 | +-----------------------------------------------------+ mysql> EXPLAIN SELECT * FROM t1 WHERE t1.a > (SELECT COUNT(a) FROM t2)\G *************************** 1. row *************************** id: 1 select_type: PRIMARY table: t1 partitions: NULL type: ALL possible_keys: NULL key: NULL key_len: NULL ref: NULL rows: 4 filtered: 33.33 Extra: Using where *************************** 2. row *************************** id: 2 select_type: SUBQUERY table: t2 partitions: NULL type: ALL possible_keys: NULL key: NULL key_len: NULL ref: NULL rows: 2 filtered: 100.00 Extra: NULL mysql> SET @@optimizer_switch='subquery_to_derived=on'; mysql> SELECT @@optimizer_switch LIKE '%subquery_to_derived=off%'; +-----------------------------------------------------+ | @@optimizer_switch LIKE '%subquery_to_derived=off%' | +-----------------------------------------------------+ | 0 | +-----------------------------------------------------+ mysql> SELECT @@optimizer_switch LIKE '%subquery_to_derived=on%'; +----------------------------------------------------+ | @@optimizer_switch LIKE '%subquery_to_derived=on%' | +----------------------------------------------------+ | 1 | +----------------------------------------------------+ mysql> EXPLAIN SELECT * FROM t1 WHERE t1.a > (SELECT COUNT(a) FROM t2)\G *************************** 1. row *************************** id: 1 select_type: PRIMARY table: <derived2> partitions: NULL type: ALL possible_keys: NULL key: NULL key_len: NULL ref: NULL rows: 1 filtered: 100.00 Extra: NULL *************************** 2. row *************************** id: 1 select_type: PRIMARY table: t1 partitions: NULL type: ALL possible_keys: NULL key: NULL key_len: NULL ref: NULL rows: 4 filtered: 33.33 Extra: Using where; Using join buffer (hash join) *************************** 3. row *************************** id: 2 select_type: DERIVED table: t2 partitions: NULL type: ALL possible_keys: NULL key: NULL key_len: NULL ref: NULL rows: 2 filtered: 100.00 Extra: NULL
As can be seen from executing
SHOW WARNINGS
immediately following the secondEXPLAIN
statement, with the optimization enabled, the querySELECT * FROM t1 WHERE t1.a > (SELECT COUNT(a) FROM t2)
is rewritten in a form similar to what is shown here:SELECT t1.a FROM t1 JOIN ( SELECT COUNT(t2.a) AS c FROM t2 ) AS d WHERE t1.a > d.c;
Example, using a query with
IN (
:subquery
)mysql> DROP TABLE IF EXISTS t1, t2; mysql> CREATE TABLE t1 (a INT, b INT); mysql> CREATE TABLE t2 (a INT, b INT); mysql> INSERT INTO t1 VALUES ROW(1,10), ROW(2,20), ROW(3,30); mysql> INSERT INTO t2 -> VALUES ROW(1,10), ROW(2,20), ROW(3,30), ROW(1,110), ROW(2,120), ROW(3,130); mysql> SELECT * FROM t1 -> WHERE t1.b < 0 -> OR -> t1.a IN (SELECT t2.a + 1 FROM t2); +------+------+ | a | b | +------+------+ | 2 | 20 | | 3 | 30 | +------+------+ mysql> SET @@optimizer_switch="subquery_to_derived=off"; mysql> EXPLAIN SELECT * FROM t1 -> WHERE t1.b < 0 -> OR -> t1.a IN (SELECT t2.a + 1 FROM t2)\G *************************** 1. row *************************** id: 1 select_type: PRIMARY table: t1 partitions: NULL type: ALL possible_keys: NULL key: NULL key_len: NULL ref: NULL rows: 3 filtered: 100.00 Extra: Using where *************************** 2. row *************************** id: 2 select_type: DEPENDENT SUBQUERY table: t2 partitions: NULL type: ALL possible_keys: NULL key: NULL key_len: NULL ref: NULL rows: 6 filtered: 100.00 Extra: Using where mysql> SET @@optimizer_switch="subquery_to_derived=on"; mysql> EXPLAIN SELECT * FROM t1 -> WHERE t1.b < 0 -> OR -> t1.a IN (SELECT t2.a + 1 FROM t2)\G *************************** 1. row *************************** id: 1 select_type: PRIMARY table: t1 partitions: NULL type: ALL possible_keys: NULL key: NULL key_len: NULL ref: NULL rows: 3 filtered: 100.00 Extra: NULL *************************** 2. row *************************** id: 1 select_type: PRIMARY table: <derived2> partitions: NULL type: ref possible_keys: <auto_key0> key: <auto_key0> key_len: 9 ref: std2.t1.a rows: 2 filtered: 100.00 Extra: Using where; Using index *************************** 3. row *************************** id: 2 select_type: DERIVED table: t2 partitions: NULL type: ALL possible_keys: NULL key: NULL key_len: NULL ref: NULL rows: 6 filtered: 100.00 Extra: Using temporary
Checking and simplifying the result of
SHOW WARNINGS
after executingEXPLAIN
on this query shows that, when thesubquery_to_derived
flag enabled,SELECT * FROM t1 WHERE t1.b < 0 OR t1.a IN (SELECT t2.a + 1 FROM t2)
is rewritten in a form similar to what is shown here:SELECT a, b FROM t1 LEFT JOIN (SELECT DISTINCT a + 1 AS e FROM t2) d ON t1.a = d.e WHERE t1.b < 0 OR d.e IS NOT NULL;
Example, using a query with
EXISTS (
and the same tables and data as in the previous example:subquery
)mysql> SELECT * FROM t1 -> WHERE t1.b < 0 -> OR -> EXISTS(SELECT * FROM t2 WHERE t2.a = t1.a + 1); +------+------+ | a | b | +------+------+ | 1 | 10 | | 2 | 20 | +------+------+ mysql> SET @@optimizer_switch="subquery_to_derived=off"; mysql> EXPLAIN SELECT * FROM t1 -> WHERE t1.b < 0 -> OR -> EXISTS(SELECT * FROM t2 WHERE t2.a = t1.a + 1)\G *************************** 1. row *************************** id: 1 select_type: PRIMARY table: t1 partitions: NULL type: ALL possible_keys: NULL key: NULL key_len: NULL ref: NULL rows: 3 filtered: 100.00 Extra: Using where *************************** 2. row *************************** id: 2 select_type: DEPENDENT SUBQUERY table: t2 partitions: NULL type: ALL possible_keys: NULL key: NULL key_len: NULL ref: NULL rows: 6 filtered: 16.67 Extra: Using where mysql> SET @@optimizer_switch="subquery_to_derived=on"; mysql> EXPLAIN SELECT * FROM t1 -> WHERE t1.b < 0 -> OR -> EXISTS(SELECT * FROM t2 WHERE t2.a = t1.a + 1)\G *************************** 1. row *************************** id: 1 select_type: PRIMARY table: t1 partitions: NULL type: ALL possible_keys: NULL key: NULL key_len: NULL ref: NULL rows: 3 filtered: 100.00 Extra: NULL *************************** 2. row *************************** id: 1 select_type: PRIMARY table: <derived2> partitions: NULL type: ALL possible_keys: NULL key: NULL key_len: NULL ref: NULL rows: 6 filtered: 100.00 Extra: Using where; Using join buffer (hash join) *************************** 3. row *************************** id: 2 select_type: DERIVED table: t2 partitions: NULL type: ALL possible_keys: NULL key: NULL key_len: NULL ref: NULL rows: 6 filtered: 100.00 Extra: Using temporary
If we execute
SHOW WARNINGS
after runningEXPLAIN
on the querySELECT * FROM t1 WHERE t1.b < 0 OR EXISTS(SELECT * FROM t2 WHERE t2.a = t1.a + 1)
whensubquery_to_derived
has been enabled, and simplify the second row of the result, we see that it has been rewritten in a form which resembles this:SELECT a, b FROM t1 LEFT JOIN (SELECT DISTINCT 1 AS e1, t2.a AS e2 FROM t2) d ON t1.a + 1 = d.e2 WHERE t1.b < 0 OR d.e1 IS NOT NULL;
For more information, see Section 10.2.2.4, “Optimizing Derived Tables, View References, and Common Table Expressions with Merging or Materialization”, as well as Section 10.2.1.19, “LIMIT Query Optimization”, and Optimizing IN and EXISTS Subquery Predicates with Semijoin Transformations.
When you assign a value to
optimizer_switch
, flags that
are not mentioned keep their current values. This makes it
possible to enable or disable specific optimizer behaviors in a
single statement without affecting other behaviors. The
statement does not depend on what other optimizer flags exist
and what their values are. Suppose that all Index Merge
optimizations are enabled:
mysql> SELECT @@optimizer_switch\G
*************************** 1. row ***************************
@@optimizer_switch: index_merge=on,index_merge_union=on,
index_merge_sort_union=on,index_merge_intersection=on,
engine_condition_pushdown=on,index_condition_pushdown=on,
mrr=on,mrr_cost_based=on,block_nested_loop=on,
batched_key_access=off,materialization=on,semijoin=on,
loosescan=on, firstmatch=on,
subquery_materialization_cost_based=on,
use_index_extensions=on,condition_fanout_filter=on,
derived_merge=on,use_invisible_indexes=off,skip_scan=on,
hash_join=on,subquery_to_derived=off,
prefer_ordering_index=on
If the server is using the Index Merge Union or Index Merge Sort-Union access methods for certain queries and you want to check whether the optimizer can perform better without them, set the variable value like this:
mysql> SET optimizer_switch='index_merge_union=off,index_merge_sort_union=off';
mysql> SELECT @@optimizer_switch\G
*************************** 1. row ***************************
@@optimizer_switch: index_merge=on,index_merge_union=off,
index_merge_sort_union=off,index_merge_intersection=on,
engine_condition_pushdown=on,index_condition_pushdown=on,
mrr=on,mrr_cost_based=on,block_nested_loop=on,
batched_key_access=off,materialization=on,semijoin=on,
loosescan=on, firstmatch=on,
subquery_materialization_cost_based=on,
use_index_extensions=on,condition_fanout_filter=on,
derived_merge=on,use_invisible_indexes=off,skip_scan=on,
hash_join=on,subquery_to_derived=off,
prefer_ordering_index=on