F.27. pg_buffercache - inspect PostgreSQL buffer cache state
The
pg_buffercache
module provides a means for
examining what's happening in the shared buffer cache in real time.
This module provides the
pg_buffercache_pages()
function (wrapped in the
pg_buffercache
view),
the
pg_buffercache_summary()
function, and the
pg_buffercache_usage_counts()
function.
The
pg_buffercache_pages()
function returns a set of
records, each row describing the state of one shared buffer entry. The
pg_buffercache
view wraps the function for
convenient use.
The
pg_buffercache_summary()
function returns a single
row summarizing the state of the shared buffer cache.
The
pg_buffercache_usage_counts()
function returns a set
of records, each row describing the number of buffers with a given usage
count.
By default, use is restricted to superusers and roles with privileges of the
pg_monitor
role. Access may be granted to others
using
GRANT
.
F.27.1. The
pg_buffercache
View
#
The definitions of the columns exposed by the view are shown in Table F.15 .
Table F.15.
pg_buffercache
Columns
|
Column Type Description |
|---|
|
ID, in the range 1..
|
|
Filenode number of the relation |
|
Tablespace OID of the relation |
|
Database OID of the relation |
|
Fork number within the relation; see
|
|
Page number within the relation |
|
Is the page dirty? |
|
Clock-sweep access count |
|
Number of backends pinning this buffer |
There is one row for each buffer in the shared cache. Unused buffers are
shown with all fields null except
bufferid
. Shared system
catalogs are shown as belonging to database zero.
Because the cache is shared by all the databases, there will normally be
pages from relations not belonging to the current database. This means
that there may not be matching join rows in
pg_class
for
some rows, or that there could even be incorrect joins. If you are
trying to join against
pg_class
, it's a good idea to
restrict the join to rows having
reldatabase
equal to
the current database's OID or zero.
Since buffer manager locks are not taken to copy the buffer state data that
the view will display, accessing
pg_buffercache
view
has less impact on normal buffer activity but it doesn't provide a consistent
set of results across all buffers. However, we ensure that the information of
each buffer is self-consistent.
F.27.2. The
pg_buffercache_summary()
Function
#
The definitions of the columns exposed by the function are shown in Table F.16 .
Table F.16.
pg_buffercache_summary()
Output Columns
|
Column Type Description |
|---|
|
Number of used shared buffers |
|
Number of unused shared buffers |
|
Number of dirty shared buffers |
|
Number of pinned shared buffers |
|
Average usage count of used shared buffers |
The
pg_buffercache_summary()
function returns a
single row summarizing the state of all shared buffers. Similar and more
detailed information is provided by the
pg_buffercache
view, but
pg_buffercache_summary()
is significantly cheaper.
Like the
pg_buffercache
view,
pg_buffercache_summary()
does not acquire buffer
manager locks. Therefore concurrent activity can lead to minor inaccuracies
in the result.
F.27.3. The
pg_buffercache_usage_counts()
Function
#
The definitions of the columns exposed by the function are shown in Table F.17 .
Table F.17.
pg_buffercache_usage_counts()
Output Columns
|
Column Type Description |
|---|
|
A possible buffer usage count |
|
Number of buffers with the usage count |
|
Number of dirty buffers with the usage count |
|
Number of pinned buffers with the usage count |
The
pg_buffercache_usage_counts()
function returns a
set of rows summarizing the states of all shared buffers, aggregated over
the possible usage count values. Similar and more detailed information is
provided by the
pg_buffercache
view, but
pg_buffercache_usage_counts()
is significantly cheaper.
Like the
pg_buffercache
view,
pg_buffercache_usage_counts()
does not acquire buffer
manager locks. Therefore concurrent activity can lead to minor inaccuracies
in the result.
F.27.4. Sample Output #
regression=# SELECT n.nspname, c.relname, count(*) AS buffers
FROM pg_buffercache b JOIN pg_class c
ON b.relfilenode = pg_relation_filenode(c.oid) AND
b.reldatabase IN (0, (SELECT oid FROM pg_database
WHERE datname = current_database()))
JOIN pg_namespace n ON n.oid = c.relnamespace
GROUP BY n.nspname, c.relname
ORDER BY 3 DESC
LIMIT 10;
nspname | relname | buffers
------------+------------------------+---------
public | delete_test_table | 593
public | delete_test_table_pkey | 494
pg_catalog | pg_attribute | 472
public | quad_poly_tbl | 353
public | tenk2 | 349
public | tenk1 | 349
public | gin_test_idx | 306
pg_catalog | pg_largeobject | 206
public | gin_test_tbl | 188
public | spgist_text_tbl | 182
(10 rows)
regression=# SELECT * FROM pg_buffercache_summary();
buffers_used | buffers_unused | buffers_dirty | buffers_pinned | usagecount_avg
--------------+----------------+---------------+----------------+----------------
248 | 2096904 | 39 | 0 | 3.141129
(1 row)
regression=# SELECT * FROM pg_buffercache_usage_counts();
usage_count | buffers | dirty | pinned
-------------+---------+-------+--------
0 | 14650 | 0 | 0
1 | 1436 | 671 | 0
2 | 102 | 88 | 0
3 | 23 | 21 | 0
4 | 9 | 7 | 0
5 | 164 | 106 | 0
(6 rows)
F.27.5. Authors #
Mark Kirkwood
<
markir@paradise.net.nz
>
Design suggestions: Neil Conway
<
neilc@samurai.com
>
Debugging advice: Tom Lane
<
tgl@sss.pgh.pa.us
>