The pg_query_state
module provides facility to know the current state of query execution on working backend. To enable this extension you have to patch the stable version of PostgreSQL, recompile it and deploy new binaries. All patch files are located in patches/
directory and tagged with suffix of PostgreSQL version number.
Each nonutility query statement (SELECT/INSERT/UPDATE/DELETE) after optimization/planning stage is translated into plan tree which is kind of imperative representation of SQL query execution algorithm. EXPLAIN ANALYZE request allows to demonstrate execution statistics gathered from each node of plan tree (full time of execution, number rows emitted to upper nodes, etc). But this statistics is collected after execution of query. This module allows to show actual statistics of query running gathered from external backend. At that, format of resulting output is almost identical to ordinal EXPLAIN ANALYZE. Thus users are able to track of query execution in progress.
In fact, this module is able to explore external backend and determine its actual state. Particularly it's helpful when backend executes a heavy query and gets stuck.
Using this module there can help in the following things:
- detect a long query (along with other monitoring tools)
- overwatch the query execution
To install pg_query_state
, please apply corresponding patches custom_signal_(PG_VERSION).patch
and runtime_explain_(PG_VERSION).patch
(or runtime_explain.patch
for PG version <= 10.0) from the patches/
directory to reqired stable version of PostgreSQL and rebuild PostgreSQL.
To do this, run the following commands from the postgresql directory:
patch -p1 < path_to_pg_query_state_folder/patches/runtime_explain_(PG_VERSION).patch
patch -p1 < path_to_pg_query_state_folder/patches/custom_signals_(PG_VERSION).patch
Then execute this in the module's directory:
make install USE_PGXS=1
To execute the command correctly, make sure you have the PATH or PG_CONFIG variable set.
export PATH=path_to_your_bin_folder:$PATH
# or
export PG_CONFIG=path_to_your_bin_folder/pg_config
Add module name to the shared_preload_libraries
parameter in postgresql.conf
:
shared_preload_libraries = 'pg_query_state'
It is essential to restart the PostgreSQL instance. After that, execute the following query in psql:
CREATE EXTENSION pg_query_state;
Done!
Test using parallel sessions with Python 3+ compatible script:
python3 tests/pg_qs_test_runner.py [OPTION]...
prerequisite packages:
psycopg2
version 2.6 or laterPyYAML
version 3.11 or laterprogressbar2
for stress test progress reporting
options:
- - -host --- postgres server host, default value is localhost
- - -port --- postgres server port, default value is 5432
- - -database --- database name, default value is postgres
- - -user --- user name, default value is postgres
- - -password --- user's password, default value is empty
- - -tpc-ds-setup --- setup database to run TPC-DS benchmark
- - -tpc-ds-run --- runs only stress tests on TPC-DS benchmark
Or run all tests in Docker
using:
export LEVEL=hardcore
export USE_TPCDS=1
export PG_VERSION=12
./mk_dockerfile.sh
docker-compose build
docker-compose run tests
There are different test levels: hardcore
, nightmare
(runs tests under valgrind
) and stress
(runs tests under TPC-DS
load).
pg_query_state(
integer pid,
verbose boolean DEFAULT FALSE,
costs boolean DEFAULT FALSE,
timing boolean DEFAULT FALSE,
buffers boolean DEFAULT FALSE,
triggers boolean DEFAULT FALSE,
format text DEFAULT 'text'
) returns TABLE (
pid integer,
frame_number integer,
query_text text,
plan text,
leader_pid integer
)
extracts the current query state from backend with specified pid
. Since parallel query can spawn multiple workers and function call causes nested subqueries so that state of execution may be viewed as stack of running queries, return value of pg_query_state
has type TABLE (pid integer, frame_number integer, query_text text, plan text, leader_pid integer)
. It represents tree structure consisting of leader process and its spawned workers identified by pid
. Each worker refers to leader through leader_pid
column. For leader process the value of this column is null
. The state of each process is represented as stack of function calls. Each frame of that stack is specified as correspondence between frame_number
starting from zero, query_text
and plan
with online statistics columns.
Thus, user can see the states of main query and queries generated from function calls for leader process and all workers spawned from it.
In process of execution some nodes of plan tree can take loops of full execution. Therefore statistics for each node consists of two parts: average statistics for previous loops just like in EXPLAIN ANALYZE output and statistics for current loop if node have not finished.
Optional arguments:
verbose
--- use EXPLAIN VERBOSE for plan printing;costs
--- add costs for each node;timing
--- print timing data for each node, if collecting of timing statistics is turned off on called side resulting output will contain WARNING messagetiming statistics disabled
;buffers
--- print buffers usage, if collecting of buffers statistics is turned off on called side resulting output will contain WARNING messagebuffers statistics disabled
;triggers
--- include triggers statistics in result plan trees;format
--- EXPLAIN format to be used for plans printing, possible values: {text
,xml
,json
,yaml
}.
If callable backend is not executing any query the function prints INFO message about backend's state taken from pg_stat_activity
view if it exists there.
Warning: Calling role have to be superuser or member of the role whose backend is being called. Otherwise function prints ERROR message permission denied
.
There are several user-accessible GUC variables designed to toggle the whole module and the collecting of specific statistic parameters while query is running:
pg_query_state.enable
--- disable (or enable)pg_query_state
completely, default value istrue
pg_query_state.enable_timing
--- collect timing data for each node, default value isfalse
pg_query_state.enable_buffers
--- collect buffers usage, default value isfalse
This parameters is set on called side before running any queries whose states are attempted to extract. Warning: if pg_query_state.enable_timing
is turned off the calling side cannot get time statistics, similarly for pg_query_state.enable_buffers
parameter.
Set maximum number of parallel workers on gather
node equals 2
:
postgres=# set max_parallel_workers_per_gather = 2;
Assume one backend with pid = 49265 performs a simple query:
postgres=# select pg_backend_pid();
pg_backend_pid
----------------
49265
(1 row)
postgres=# select count(*) from foo join bar on foo.c1=bar.c1;
Other backend can extract intermediate state of execution that query:
postgres=# \x
postgres=# select * from pg_query_state(49265);
-[ RECORD 1 ]+-------------------------------------------------------------------------------------------------------------------------
pid | 49265
frame_number | 0
query_text | select count(*) from foo join bar on foo.c1=bar.c1;
plan | Finalize Aggregate (Current loop: actual rows=0, loop number=1) +
| -> Gather (Current loop: actual rows=0, loop number=1) +
| Workers Planned: 2 +
| Workers Launched: 2 +
| -> Partial Aggregate (Current loop: actual rows=0, loop number=1) +
| -> Nested Loop (Current loop: actual rows=12, loop number=1) +
| Join Filter: (foo.c1 = bar.c1) +
| Rows Removed by Join Filter: 5673232 +
| -> Parallel Seq Scan on foo (Current loop: actual rows=12, loop number=1) +
| -> Seq Scan on bar (actual rows=500000 loops=11) (Current loop: actual rows=173244, loop number=12)
leader_pid | (null)
-[ RECORD 2 ]+-------------------------------------------------------------------------------------------------------------------------
pid | 49324
frame_number | 0
query_text | <parallel query>
plan | Partial Aggregate (Current loop: actual rows=0, loop number=1) +
| -> Nested Loop (Current loop: actual rows=10, loop number=1) +
| Join Filter: (foo.c1 = bar.c1) +
| Rows Removed by Join Filter: 4896779 +
| -> Parallel Seq Scan on foo (Current loop: actual rows=10, loop number=1) +
| -> Seq Scan on bar (actual rows=500000 loops=9) (Current loop: actual rows=396789, loop number=10)
leader_pid | 49265
-[ RECORD 3 ]+-------------------------------------------------------------------------------------------------------------------------
pid | 49323
frame_number | 0
query_text | <parallel query>
plan | Partial Aggregate (Current loop: actual rows=0, loop number=1) +
| -> Nested Loop (Current loop: actual rows=11, loop number=1) +
| Join Filter: (foo.c1 = bar.c1) +
| Rows Removed by Join Filter: 5268783 +
| -> Parallel Seq Scan on foo (Current loop: actual rows=11, loop number=1) +
| -> Seq Scan on bar (actual rows=500000 loops=10) (Current loop: actual rows=268794, loop number=11)
leader_pid | 49265
In example above working backend spawns two parallel workers with pids 49324
and 49323
. Their leader_pid
column's values clarify that these workers belong to the main backend.
Seq Scan
node has statistics on passed loops (average number of rows delivered to Nested Loop
and number of passed loops are shown) and statistics on current loop. Other nodes has statistics only for current loop as this loop is first (loop number
= 1).
Assume first backend executes some function:
postgres=# select n_join_foo_bar();
Other backend can get the follow output:
postgres=# select * from pg_query_state(49265);
-[ RECORD 1 ]+------------------------------------------------------------------------------------------------------------------
pid | 49265
frame_number | 0
query_text | select n_join_foo_bar();
plan | Result (Current loop: actual rows=0, loop number=1)
leader_pid | (null)
-[ RECORD 2 ]+------------------------------------------------------------------------------------------------------------------
pid | 49265
frame_number | 1
query_text | SELECT (select count(*) from foo join bar on foo.c1=bar.c1)
plan | Result (Current loop: actual rows=0, loop number=1) +
| InitPlan 1 (returns $0) +
| -> Aggregate (Current loop: actual rows=0, loop number=1) +
| -> Nested Loop (Current loop: actual rows=51, loop number=1) +
| Join Filter: (foo.c1 = bar.c1) +
| Rows Removed by Join Filter: 51636304 +
| -> Seq Scan on bar (Current loop: actual rows=52, loop number=1) +
| -> Materialize (actual rows=1000000 loops=51) (Current loop: actual rows=636355, loop number=52)+
| -> Seq Scan on foo (Current loop: actual rows=1000000, loop number=1)
leader_pid | (null)
First row corresponds to function call, second - to query which is in the body of that function.
We can get result plans in different format (e.g. json
):
postgres=# select * from pg_query_state(pid := 49265, format := 'json');
-[ RECORD 1 ]+------------------------------------------------------------
pid | 49265
frame_number | 0
query_text | select * from n_join_foo_bar();
plan | { +
| "Plan": { +
| "Node Type": "Function Scan", +
| "Parallel Aware": false, +
| "Function Name": "n_join_foo_bar", +
| "Alias": "n_join_foo_bar", +
| "Current loop": { +
| "Actual Loop Number": 1, +
| "Actual Rows": 0 +
| } +
| } +
| }
leader_pid | (null)
-[ RECORD 2 ]+------------------------------------------------------------
pid | 49265
frame_number | 1
query_text | SELECT (select count(*) from foo join bar on foo.c1=bar.c1)
plan | { +
| "Plan": { +
| "Node Type": "Result", +
| "Parallel Aware": false, +
| "Current loop": { +
| "Actual Loop Number": 1, +
| "Actual Rows": 0 +
| }, +
| "Plans": [ +
| { +
| "Node Type": "Aggregate", +
| "Strategy": "Plain", +
| "Partial Mode": "Simple", +
| "Parent Relationship": "InitPlan", +
| "Subplan Name": "InitPlan 1 (returns $0)", +
| "Parallel Aware": false, +
| "Current loop": { +
| "Actual Loop Number": 1, +
| "Actual Rows": 0 +
| }, +
| "Plans": [ +
| { +
| "Node Type": "Nested Loop", +
| "Parent Relationship": "Outer", +
| "Parallel Aware": false, +
| "Join Type": "Inner", +
| "Current loop": { +
| "Actual Loop Number": 1, +
| "Actual Rows": 610 +
| }, +
| "Join Filter": "(foo.c1 = bar.c1)", +
| "Rows Removed by Join Filter": 610072944, +
| "Plans": [ +
| { +
| "Node Type": "Seq Scan", +
| "Parent Relationship": "Outer", +
| "Parallel Aware": false, +
| "Relation Name": "bar", +
| "Alias": "bar", +
| "Current loop": { +
| "Actual Loop Number": 1, +
| "Actual Rows": 611 +
| } +
| }, +
| { +
| "Node Type": "Materialize", +
| "Parent Relationship": "Inner", +
| "Parallel Aware": false, +
| "Actual Rows": 1000000, +
| "Actual Loops": 610, +
| "Current loop": { +
| "Actual Loop Number": 611, +
| "Actual Rows": 73554 +
| }, +
| "Plans": [ +
| { +
| "Node Type": "Seq Scan", +
| "Parent Relationship": "Outer", +
| "Parallel Aware": false, +
| "Relation Name": "foo", +
| "Alias": "foo", +
| "Current loop": { +
| "Actual Loop Number": 1, +
| "Actual Rows": 1000000 +
| } +
| } +
| ] +
| } +
| ] +
| } +
| ] +
| } +
| ] +
| } +
| }
leader_pid | (null)
Do not hesitate to post your issues, questions and new ideas at the issues page.
Maksim Milyutin
Alexey Kondratov a.kondratov@postgrespro.ru Postgres Professional Ltd., Russia