F.41. pg_stat_statements
The pg_stat_statements
module provides a means for tracking planning and execution statistics of all SQL statements executed by a server.
The module must be loaded by adding pg_stat_statements
to shared_preload_libraries in postgresql.conf
, because it requires additional shared memory. This means that a server restart is needed to add or remove the module.
When pg_stat_statements
is loaded, it tracks statistics across all databases of the server. To access and manipulate these statistics, the module provides a view, pg_stat_statements
, and the utility functions pg_stat_statements_reset
and pg_stat_statements
. These are not available globally but can be enabled for a specific database with CREATE EXTENSION pg_stat_statements
.
F.41.1. The pg_stat_statements
View
The statistics gathered by the module are made available via a view named pg_stat_statements
. This view contains one row for each distinct database ID, user ID and query ID (up to the maximum number of distinct statements that the module can track). The columns of the view are shown in Table F.100.
Table F.100. pg_stat_statements
Columns
Column Type Description |
---|
OID of user who executed the statement |
OID of database in which the statement was executed |
Internal hash code, computed from the statement's parse tree |
Text of a representative statement |
Number of times the statement was planned (if |
Total time spent planning the statement, in milliseconds (if |
Minimum time spent planning the statement, in milliseconds (if |
Maximum time spent planning the statement, in milliseconds (if |
Mean time spent planning the statement, in milliseconds (if |
Population standard deviation of time spent planning the statement, in milliseconds (if |
Number of times the statement was executed |
Total time spent executing the statement, in milliseconds |
Minimum time spent executing the statement, in milliseconds |
Maximum time spent executing the statement, in milliseconds |
Mean time spent executing the statement, in milliseconds |
Population standard deviation of time spent executing the statement, in milliseconds |
Total number of rows retrieved or affected by the statement |
Total number of shared block cache hits by the statement |
Total number of shared blocks read by the statement |
Total number of shared blocks dirtied by the statement |
Total number of shared blocks written by the statement |
Total number of local block cache hits by the statement |
Total number of local blocks read by the statement |
Total number of local blocks dirtied by the statement |
Total number of local blocks written by the statement |
Total number of temp blocks read by the statement |
Total number of temp blocks written by the statement |
Total time the statement spent reading blocks, in milliseconds (if track_io_timing is enabled, otherwise zero) |
Total time the statement spent writing blocks, in milliseconds (if track_io_timing is enabled, otherwise zero) |
Total number of WAL records generated by the statement |
Total number of WAL full page images generated by the statement |
Total amount of WAL generated by the statement in bytes |
For security reasons, only superusers and members of the pg_read_all_stats
role are allowed to see the SQL text and queryid
of queries executed by other users. Other users can see the statistics, however, if the view has been installed in their database.
Plannable queries (that is, SELECT
, INSERT
, UPDATE
, and DELETE
) are combined into a single pg_stat_statements
entry whenever they have identical query structures according to an internal hash calculation. Typically, two queries will be considered the same for this purpose if they are semantically equivalent except for the values of literal constants appearing in the query. Utility commands (that is, all other commands) are compared strictly on the basis of their textual query strings, however.
When a constant's value has been ignored for purposes of matching the query to other queries, the constant is replaced by a parameter symbol, such as $1
, in the pg_stat_statements
display. The rest of the query text is that of the first query that had the particular queryid
hash value associated with the pg_stat_statements
entry.
In some cases, queries with visibly different texts might get merged into a single pg_stat_statements
entry. Normally this will happen only for semantically equivalent queries, but there is a small chance of hash collisions causing unrelated queries to be merged into one entry. (This cannot happen for queries belonging to different users or databases, however.)
Since the queryid
hash value is computed on the post-parse-analysis representation of the queries, the opposite is also possible: queries with identical texts might appear as separate entries, if they have different meanings as a result of factors such as different search_path
settings.
Consumers of pg_stat_statements
may wish to use queryid
(perhaps in combination with dbid
and userid
) as a more stable and reliable identifier for each entry than its query text. However, it is important to understand that there are only limited guarantees around the stability of the queryid
hash value. Since the identifier is derived from the post-parse-analysis tree, its value is a function of, among other things, the internal object identifiers appearing in this representation. This has some counterintuitive implications. For example, pg_stat_statements
will consider two apparently-identical queries to be distinct, if they reference a table that was dropped and recreated between the executions of the two queries. The hashing process is also sensitive to differences in machine architecture and other facets of the platform. Furthermore, it is not safe to assume that queryid
will be stable across major versions of Postgres Pro.
Two servers participating in replication based on physical WAL replay can be expected to have identical queryid
values for the same query. However, logical replication schemes do not promise to keep replicas identical in all relevant details, so queryid
will not be a useful identifier for accumulating costs across a set of logical replicas. If in doubt, direct testing is recommended.
Generally, it can be assumed that queryid
values are stable between minor version releases of PostgreSQL, providing that instances are running on the same machine architecture and the catalog metadata details match. Compatibility will only be broken between minor versions as a last resort.
The parameter symbols used to replace constants in representative query texts start from the next number after the highest $
n
parameter in the original query text, or $1
if there was none. It's worth noting that in some cases there may be hidden parameter symbols that affect this numbering. For example, PL/pgSQL uses hidden parameter symbols to insert values of function local variables into queries, so that a PL/pgSQL statement like SELECT i + 1 INTO j
would have representative text like SELECT i + $2
.
The representative query texts are kept in an external disk file, and do not consume shared memory. Therefore, even very lengthy query texts can be stored successfully. However, if many long query texts are accumulated, the external file might grow unmanageably large. As a recovery method if that happens, pg_stat_statements
may choose to discard the query texts, whereupon all existing entries in the pg_stat_statements
view will show null query
fields, though the statistics associated with each queryid
are preserved. If this happens, consider reducing pg_stat_statements.max
to prevent recurrences.
plans
and calls
aren't always expected to match because planning and execution statistics are updated at their respective end phase, and only for successful operations. For example, if a statement is successfully planned but fails during the execution phase, only its planning statistics will be updated. If planning is skipped because a cached plan is used, only its execution statistics will be updated.
F.41.2. Functions
-
pg_stat_statements_reset(userid Oid, dbid Oid, queryid bigint) returns void
pg_stat_statements_reset
discards statistics gathered so far bypg_stat_statements
corresponding to the specifieduserid
,dbid
andqueryid
. If any of the parameters are not specified, the default value0
(invalid) is used for each of them and the statistics that match with other parameters will be reset. If no parameter is specified or all the specified parameters are0
(invalid), it will discard all statistics. By default, this function can only be executed by superusers. Access may be granted to others usingGRANT
.-
pg_stat_statements(showtext boolean) returns setof record
The
pg_stat_statements
view is defined in terms of a function also namedpg_stat_statements
. It is possible for clients to call thepg_stat_statements
function directly, and by specifyingshowtext := false
have query text be omitted (that is, theOUT
argument that corresponds to the view'squery
column will return nulls). This feature is intended to support external tools that might wish to avoid the overhead of repeatedly retrieving query texts of indeterminate length. Such tools can instead cache the first query text observed for each entry themselves, since that is allpg_stat_statements
itself does, and then retrieve query texts only as needed. Since the server stores query texts in a file, this approach may reduce physical I/O for repeated examination of thepg_stat_statements
data.
F.41.3. Configuration Parameters
-
pg_stat_statements.max
(integer
) pg_stat_statements.max
is the maximum number of statements tracked by the module (i.e., the maximum number of rows in thepg_stat_statements
view). If more distinct statements than that are observed, information about the least-executed statements is discarded. The default value is 5000. This parameter can only be set at server start.-
pg_stat_statements.track
(enum
) pg_stat_statements.track
controls which statements are counted by the module. Specifytop
to track top-level statements (those issued directly by clients),all
to also track nested statements (such as statements invoked within functions), ornone
to disable statement statistics collection. The default value istop
. Only superusers can change this setting.-
pg_stat_statements.track_utility
(boolean
) pg_stat_statements.track_utility
controls whether utility commands are tracked by the module. Utility commands are all those other thanSELECT
,INSERT
,UPDATE
andDELETE
. The default value ison
. Only superusers can change this setting.-
pg_stat_statements.track_planning
(boolean
) pg_stat_statements.track_planning
controls whether planning operations and duration are tracked by the module. Enabling this parameter may incur a noticeable performance penalty, especially when statements with identical query structure are executed by many concurrent connections which compete to update a small number ofpg_stat_statements
entries. The default value isoff
. Only superusers can change this setting.-
pg_stat_statements.save
(boolean
) pg_stat_statements.save
specifies whether to save statement statistics across server shutdowns. If it isoff
then statistics are not saved at shutdown nor reloaded at server start. The default value ison
. This parameter can only be set in thepostgresql.conf
file or on the server command line.
The module requires additional shared memory proportional to pg_stat_statements.max
. Note that this memory is consumed whenever the module is loaded, even if pg_stat_statements.track
is set to none
.
These parameters must be set in postgresql.conf
. Typical usage might be:
# postgresql.conf shared_preload_libraries = 'pg_stat_statements' pg_stat_statements.max = 10000 pg_stat_statements.track = all
F.41.4. Sample Output
bench=# SELECT pg_stat_statements_reset(); $ pgbench -i bench $ pgbench -c10 -t300 bench bench=# \x bench=# SELECT query, calls, total_exec_time, rows, 100.0 * shared_blks_hit / nullif(shared_blks_hit + shared_blks_read, 0) AS hit_percent FROM pg_stat_statements ORDER BY total_exec_time DESC LIMIT 5; -[ RECORD 1 ]---+-------------------------------------------------------------------- query | UPDATE pgbench_branches SET bbalance = bbalance + $1 WHERE bid = $2 calls | 3000 total_exec_time | 25565.855387 rows | 3000 hit_percent | 100.0000000000000000 -[ RECORD 2 ]---+-------------------------------------------------------------------- query | UPDATE pgbench_tellers SET tbalance = tbalance + $1 WHERE tid = $2 calls | 3000 total_exec_time | 20756.669379 rows | 3000 hit_percent | 100.0000000000000000 -[ RECORD 3 ]---+-------------------------------------------------------------------- query | copy pgbench_accounts from stdin calls | 1 total_exec_time | 291.865911 rows | 100000 hit_percent | 100.0000000000000000 -[ RECORD 4 ]---+-------------------------------------------------------------------- query | UPDATE pgbench_accounts SET abalance = abalance + $1 WHERE aid = $2 calls | 3000 total_exec_time | 271.232977 rows | 3000 hit_percent | 98.8454011741682975 -[ RECORD 5 ]---+-------------------------------------------------------------------- query | alter table pgbench_accounts add primary key (aid) calls | 1 total_exec_time | 160.588563 rows | 0 hit_percent | 100.0000000000000000 bench=# SELECT pg_stat_statements_reset(0,0,s.queryid) FROM pg_stat_statements AS s WHERE s.query = 'UPDATE pgbench_branches SET bbalance = bbalance + $1 WHERE bid = $2'; bench=# SELECT query, calls, total_exec_time, rows, 100.0 * shared_blks_hit / nullif(shared_blks_hit + shared_blks_read, 0) AS hit_percent FROM pg_stat_statements ORDER BY total_exec_time DESC LIMIT 5; -[ RECORD 1 ]---+-------------------------------------------------------------------- query | UPDATE pgbench_tellers SET tbalance = tbalance + $1 WHERE tid = $2 calls | 3000 total_exec_time | 20756.669379 rows | 3000 hit_percent | 100.0000000000000000 -[ RECORD 2 ]---+-------------------------------------------------------------------- query | copy pgbench_accounts from stdin calls | 1 total_exec_time | 291.865911 rows | 100000 hit_percent | 100.0000000000000000 -[ RECORD 3 ]---+-------------------------------------------------------------------- query | UPDATE pgbench_accounts SET abalance = abalance + $1 WHERE aid = $2 calls | 3000 total_exec_time | 271.232977 rows | 3000 hit_percent | 98.8454011741682975 -[ RECORD 4 ]---+-------------------------------------------------------------------- query | alter table pgbench_accounts add primary key (aid) calls | 1 total_exec_time | 160.588563 rows | 0 hit_percent | 100.0000000000000000 -[ RECORD 5 ]---+-------------------------------------------------------------------- query | vacuum analyze pgbench_accounts calls | 1 total_exec_time | 136.448116 rows | 0 hit_percent | 99.9201915403032721 bench=# SELECT pg_stat_statements_reset(0,0,0); bench=# SELECT query, calls, total_exec_time, rows, 100.0 * shared_blks_hit / nullif(shared_blks_hit + shared_blks_read, 0) AS hit_percent FROM pg_stat_statements ORDER BY total_exec_time DESC LIMIT 5; -[ RECORD 1 ]---+----------------------------------------------------------------------------- query | SELECT pg_stat_statements_reset(0,0,0) calls | 1 total_exec_time | 0.189497 rows | 1 hit_percent | -[ RECORD 2 ]---+----------------------------------------------------------------------------- query | SELECT query, calls, total_exec_time, rows, $1 * shared_blks_hit / + | nullif(shared_blks_hit + shared_blks_read, $2) AS hit_percent+ | FROM pg_stat_statements ORDER BY total_exec_time DESC LIMIT $3 calls | 0 total_exec_time | 0 rows | 0 hit_percent |
F.41.5. Authors
Takahiro Itagaki <itagaki.takahiro@oss.ntt.co.jp>
. Query normalization added by Peter Geoghegan <peter@2ndquadrant.com>
.