ANALYZE Statement
The ANALYZE statement
was introduced in MariaDB 10.1.0.
Description
The ANALYZE statement
is similar to the EXPLAIN statement
. ANALYZE statement
will invoke the optimizer, execute the statement, and then produce EXPLAIN
output instead of the result set. The EXPLAIN
output will be annotated with statistics from statement execution.
This lets one check how close the optimizer's estimates about the query plan are to the reality. ANALYZE
produces an overview, while the ANALYZE FORMAT=JSON
command provides a more detailed view of the query plan and the query execution.
The syntax is
ANALYZE explainable_statement;
where the statement is any statement for which one can run EXPLAIN
.
Command Output
Consider an example:
ANALYZE SELECT * FROM tbl1 WHERE key1 BETWEEN 10 AND 200 AND col1 LIKE 'foo%'\G
*************************** 1. row *************************** id: 1 select_type: SIMPLE table: tbl1 type: range possible_keys: key1 key: key1 key_len: 5 ref: NULL rows: 181 r_rows: 181 filtered: 100.00 r_filtered: 10.50 Extra: Using index condition; Using where
Compared to EXPLAIN
, ANALYZE
produces two extra columns:
-
r_rows
is an observation-based counterpart of the rows column. It shows how many rows were actually read from the table. -
r_filtered
is an observation-based counterpart of the filtered column. It shows which fraction of rows was left after applying the WHERE condition.
Interpreting the Output
Joins
Let's consider a more complicated example.
ANALYZE SELECT * FROM orders, customer WHERE customer.c_custkey=orders.o_custkey AND customer.c_acctbal < 0 AND orders.o_totalprice > 200*1000
+----+-------------+----------+------+---------------+-------------+---------+--------------------+--------+--------+----------+------------+-------------+ | id | select_type | table | type | possible_keys | key | key_len | ref | rows | r_rows | filtered | r_filtered | Extra | +----+-------------+----------+------+---------------+-------------+---------+--------------------+--------+--------+----------+------------+-------------+ | 1 | SIMPLE | customer | ALL | PRIMARY,... | NULL | NULL | NULL | 149095 | 150000 | 18.08 | 9.13 | Using where | | 1 | SIMPLE | orders | ref | i_o_custkey | i_o_custkey | 5 | customer.c_custkey | 7 | 10 | 100.00 | 30.03 | Using where | +----+-------------+----------+------+---------------+-------------+---------+--------------------+--------+--------+----------+------------+-------------+
Here, one can see that
- For table customer, customer.rows=149095, customer.r_rows=150000. The estimate for number of rows we will read was fairly precise
- customer.filtered=18.08, customer.r_filtered=9.13. The optimizer somewhat overestimated the number of records that will match selectivity of condition attached to `customer` table (in general, when you have a full scan and r_filtered is less than 15%, it's time to consider adding an appropriate index).
- For table orders, orders.rows=7, orders.r_rows=10. This means that on average, there are 7 orders for a given c_custkey, but in our case there were 10, which is close to the expectation (when this number is consistently far from the expectation, it may be time to run ANALYZE TABLE, or even edit the table statistics manually to get better query plans).
- orders.filtered=100, orders.r_filtered=30.03. The optimizer didn't have any way to estimate which fraction of records will be left after it checks the condition that is attached to table orders (it's orders.o_totalprice > 200*1000). So, it used 100%. In reality, it is 30%. 30% is typically not selective enough to warrant adding new indexes. For joins with many tables, it might be worth to collect and use column statistics for columns in question, this may help the optimizer to pick a better query plan.
Meaning of NULL in r_rows and r_filtered
Let's modify the previous example slightly
ANALYZE SELECT * FROM orders, customer WHERE customer.c_custkey=orders.o_custkey AND customer.c_acctbal < -0 AND customer.c_comment LIKE '%foo%' AND orders.o_totalprice > 200*1000;
+----+-------------+----------+------+---------------+-------------+---------+--------------------+--------+--------+----------+------------+-------------+ | id | select_type | table | type | possible_keys | key | key_len | ref | rows | r_rows | filtered | r_filtered | Extra | +----+-------------+----------+------+---------------+-------------+---------+--------------------+--------+--------+----------+------------+-------------+ | 1 | SIMPLE | customer | ALL | PRIMARY,... | NULL | NULL | NULL | 149095 | 150000 | 18.08 | 0.00 | Using where | | 1 | SIMPLE | orders | ref | i_o_custkey | i_o_custkey | 5 | customer.c_custkey | 7 | NULL | 100.00 | NULL | Using where | +----+-------------+----------+------+---------------+-------------+---------+--------------------+--------+--------+----------+------------+-------------+
Here, one can see that orders.r_rows=NULL and orders.r_filtered=NULL. This means that table orders was not scanned even once. Indeed, we can also see customer.r_filtered=0.00. This shows that a part of WHERE attached to table `customer` was never satisfied (or, satisfied in less than 0.01% of cases).
ANALYZE FORMAT=JSON
ANALYZE FORMAT=JSON produces JSON output. It produces much more information than tabular ANALYZE
.
Notes
-
ANALYZE UPDATE
orANALYZE DELETE
will actually make updates/deletes (ANALYZE SELECT
will perform the select operation and then discard the resultset). - PostgreSQL has a similar command,
EXPLAIN ANALYZE
. - The EXPLAIN in the slow query log feature allows MariaDB to have
ANALYZE
output of slow queries printed into the slow query log (see MDEV-6388).
See Also
- ANALYZE FORMAT=JSON
- ANALYZE TABLE
- JIRA task for ANALYZE statement, MDEV-406
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Licensed under the Creative Commons Attribution 3.0 Unported License and the GNU Free Documentation License.
https://mariadb.com/kb/en/analyze-statement/