I want a random selection of rows in PostgreSQL, I tried this:

select * from table where random() < 0.01;

But some other recommend this:

select * from table order by random() limit 1000;

I have a very large table with 500 Million rows, I want it to be fast.

Which approach is better? What are the differences? What is the best way to select random rows?

  • 1
    Hi Jack, thanks for your response, the execution time is slower in order by, but I would like to know which is the different if any... – nanounanue Dec 29 '11 at 23:36
  • Uhhh...you're welcome. So, have you tried benchmarking the different approaches? – user554546 Dec 29 '11 at 23:36
  • There are also much faster ways. It all depends on your requirements and what you have to work with. Do you need exactly 1000 rows? Does the table have a numeric id? With no / few / many gaps? How important is speed? How many requests per time unit? Does every request need a different set or can they be the same for a defined time slice? – Erwin Brandstetter Dec 29 '11 at 23:53
  • Hi Erwin, I need 1M rows or in that order. I am doing some data mining research, so 1M rows, is the set for training... The table has a numeric id, and there are gaps but they are little. Me and another two guys are the only users of the database. – nanounanue Dec 30 '11 at 0:01
  • The first option "(random() < 0.01)" is mathematically incorrect as you could get no rows in response if no random number is below 0.01, that could happen in any case (albeit less likely), no matter how big is the table or higher the threshold. The second option is always right – Herme Sep 16 '16 at 13:32

11 Answers 11

up vote 161 down vote accepted

Given your specifications (plus additional info in the comments),

  • You have a numeric ID column (integer numbers) with only few (or moderately few) gaps.
  • Obviously no or few write operations.
  • Your ID column has to be indexed! A primary key serves nicely.

The query below does not need a sequential scan of the big table, only an index scan.

First, get estimates for the main query:

SELECT count(*) AS ct              -- optional
     , min(id)  AS min_id
     , max(id)  AS max_id
     , max(id) - min(id) AS id_span
FROM   big;

The only possibly expensive part is the count(*) (for huge tables). Given above specifications, you don't need it. An estimate will do just fine, available at almost no cost (detailed explanation here):

SELECT reltuples AS ct FROM pg_class WHERE oid = 'schema_name.big'::regclass;

As long as ct isn't much smaller than id_span, the query will outperform other approaches.

WITH params AS (
    SELECT 1       AS min_id           -- minimum id <= current min id
         , 5100000 AS id_span          -- rounded up. (max_id - min_id + buffer)
    )
SELECT *
FROM  (
    SELECT p.min_id + trunc(random() * p.id_span)::integer AS id
    FROM   params p
          ,generate_series(1, 1100) g  -- 1000 + buffer
    GROUP  BY 1                        -- trim duplicates
    ) r
JOIN   big USING (id)
LIMIT  1000;                           -- trim surplus
  • Generate random numbers in the id space. You have "few gaps", so add 10 % (enough to easily cover the blanks) to the number of rows to retrieve.

  • Each id can be picked multiple times by chance (though very unlikely with a big id space), so group the generated numbers (or use DISTINCT).

  • Join the ids to the big table. This should be very fast with the index in place.

  • Finally trim surplus ids that have not been eaten by dupes and gaps. Every row has a completely equal chance to be picked.

Short version

You can simplify this query. The CTE in the query above is just for educational purposes:

SELECT *
FROM  (
    SELECT DISTINCT 1 + trunc(random() * 5100000)::integer AS id
    FROM   generate_series(1, 1100) g
    ) r
JOIN   big USING (id)
LIMIT  1000;

Refine with rCTE

Especially if you are not so sure about gaps and estimates.

WITH RECURSIVE random_pick AS (
   SELECT *
   FROM  (
      SELECT 1 + trunc(random() * 5100000)::int AS id
      FROM   generate_series(1, 1030)  -- 1000 + few percent - adapt to your needs
      LIMIT  1030                      -- hint for query planner
      ) r
   JOIN   big b USING (id)             -- eliminate miss

   UNION                               -- eliminate dupe
   SELECT b.*
   FROM  (
      SELECT 1 + trunc(random() * 5100000)::int AS id
      FROM   random_pick r             -- plus 3 percent - adapt to your needs
      LIMIT  999                       -- less than 1000, hint for query planner
      ) r
   JOIN   big b USING (id)             -- eliminate miss
   )
SELECT *
FROM   random_pick
LIMIT  1000;  -- actual limit

We can work with a smaller surplus in the base query. If there are too many gaps so we don't find enough rows in the first iteration, the rCTE continues to iterate with the recursive term. We still need relatively few gaps in the ID space or the recursion may run dry before the limit is reached - or we have to start with a large enough buffer which defies the purpose of optimizing performance.

Duplicates are eliminated by the UNION in the rCTE.

The outer LIMIT makes the CTE stop as soon as we have enough rows.

This query is carefully drafted to use the available index, generate actually random rows and not stop until we fulfill the limit (unless the recursion runs dry). There are a number of pitfalls here if you are going to rewrite it.

Wrap into function

For repeated use with varying parameters:

CREATE OR REPLACE FUNCTION f_random_sample(_limit int = 1000, _gaps real = 1.03)
  RETURNS SETOF big AS
$func$
DECLARE
   _surplus  int := _limit * _gaps;
   _estimate int := (           -- get current estimate from system
      SELECT c.reltuples * _gaps
      FROM   pg_class c
      WHERE  c.oid = 'big'::regclass);
BEGIN

   RETURN QUERY
   WITH RECURSIVE random_pick AS (
      SELECT *
      FROM  (
         SELECT 1 + trunc(random() * _estimate)::int
         FROM   generate_series(1, _surplus) g
         LIMIT  _surplus           -- hint for query planner
         ) r (id)
      JOIN   big USING (id)        -- eliminate misses

      UNION                        -- eliminate dupes
      SELECT *
      FROM  (
         SELECT 1 + trunc(random() * _estimate)::int
         FROM   random_pick        -- just to make it recursive
         LIMIT  _limit             -- hint for query planner
         ) r (id)
      JOIN   big USING (id)        -- eliminate misses
   )
   SELECT *
   FROM   random_pick
   LIMIT  _limit;
END
$func$  LANGUAGE plpgsql VOLATILE ROWS 1000;

Call:

SELECT * FROM f_random_sample();
SELECT * FROM f_random_sample(500, 1.05);

You could even make this generic to work for any table: Take the name of the PK column and the table as polymorphic type and use EXECUTE ... But that's beyond the scope of this question. See:

Possible alternative

IF your requirements allow identical sets for repeated calls (and we are talking about repeated calls) I would consider a materialized view. Execute above query once and write the result to a table. Users get a quasi random selection at lightening speed. Refresh your random pick at intervals or events of your choosing.

Postgres 9.5 introduces TABLESAMPLE SYSTEM (n)

It's very fast, but the result is not exactly random. The manual:

The SYSTEM method is significantly faster than the BERNOULLI method when small sampling percentages are specified, but it may return a less-random sample of the table as a result of clustering effects.

And the number of rows returned can vary wildly. For our example, to get roughly 1000 rows, try:

SELECT * FROM big TABLESAMPLE SYSTEM ((1000 * 100) / 5100000.0);

Where n is a percentage. The manual:

The BERNOULLI and SYSTEM sampling methods each accept a single argument which is the fraction of the table to sample, expressed as a percentage between 0 and 100. This argument can be any real-valued expression.

Bold emphasis mine.

Related:

Or install the additional module tsm_system_rows to get the number of requested rows exactly (if there are enough) and allow for the more convenient syntax:

SELECT * FROM big TABLESAMPLE SYSTEM_ROWS(1000);

See Evan's answer for details.

But that's still not exactly random.

  • Where is defined the t table ? Should it r instead of t ? – Luc M Jan 1 '12 at 17:13
  • 1
    @LucM: It is defined here: JOIN bigtbl t, which is short for JOIN bigtbl AS t. t is a table alias for bigtbl. Its purpose is to shorten the syntax but it would not be needed in this particular case. I simplified the query in my answer and added a simple version. – Erwin Brandstetter Jan 1 '12 at 17:18
  • Thanks. I didn't see it the first time. – Luc M Jan 3 '12 at 15:47
  • What's the purpose of the range of values from generate_series(1,1100)? – Awesome-o Feb 24 '14 at 6:12
  • @Awesome-o: The goal is to retrieve 1000 rows, I start with an extra 10 % to compensate for a few gaps or (unlikely but possible) duplicate random numbers ... the explanation is in my answer. – Erwin Brandstetter Feb 24 '14 at 12:53

You can examine and compare the execution plan of both by using

EXPLAIN select * from table where random() < 0.01;
EXPLAIN select * from table order by random() limit 1000;

A quick test on a large table1 shows, that the ORDER BY first sorts the complete table and then picks the first 1000 items. Sorting a large table not only reads that table but also involves reading and writing temporary files. The where random() < 0.1 only scans the complete table once.

For large tables this might not what you want as even one complete table scan might take to long.

A third proposal would be

select * from table where random() < 0.01 limit 1000;

This one stops the table scan as soon as 1000 rows have been found and therefore returns sooner. Of course this bogs down the randomness a bit, but perhaps this is good enough in your case.

Edit: Besides of this considerations, you might check out the already asked questions for this. Using the query [postgresql] random returns quite a few hits.

And a linked article of depez outlining several more approaches:


1 "large" as in "the complete table will not fit into the memory".

  • 1
    Good point about writing the temporary file for doing the ordering. That's a big hit indeed. I guess we could do random() < 0.02 and then shuffle that list, then limit 1000! The sort will be less expensive on a few thousand rows (lol). – Donald Miner Dec 29 '11 at 23:54
  • The "select * from table where random() < 0.05 limit 500;" is one of the easier methods for postgresql. We made use of this in one of our projects where we needed to select 5% of the results and no more then 500 rows at a time for processing. – tgharold Jan 29 '14 at 15:10

postgresql order by random(), select rows in random order:

select your_columns from your_table ORDER BY random()

postgresql order by random() with a distinct:

select * from 
  (select distinct your_columns from your_table) table_alias
ORDER BY random()

postgresql order by random limit one row:

select your_columns from your_table ORDER BY random() limit 1

Starting with PostgreSQL 9.5, there's a new syntax dedicated to getting random elements from a table :

SELECT * FROM mytable TABLESAMPLE SYSTEM (5);

This example will give you 5% of elements from mytable.

See more explanation on this blog post: http://www.postgresql.org/docs/current/static/sql-select.html

  • 2
    An important note from the docs: "The SYSTEM method does block-level sampling with each block having the specified chance of being selected; all rows in each selected block are returned. The SYSTEM method is significantly faster than the BERNOULLI method when small sampling percentages are specified, but it may return a less-random sample of the table as a result of clustering effects." – HasFiveVowels Nov 22 '16 at 1:57
  • Is there way to specify a number of rows instead of a percentage? – Flimm May 30 at 8:23
  • You can use TABLESAMPLE SYSTEM_ROWS(400) to get a sample of 400 random rows. You need to enable the built-in tsm_system_rows extension to use this statement. – Mickaël Le Baillif May 31 at 10:15

The one with the ORDER BY is going to be the slower one.

select * from table where random() < 0.01; goes record by record, and decides to randomly filter it or not. This is going to be O(N) because it only needs to check each record once.

select * from table order by random() limit 1000; is going to sort the entire table, then pick the first 1000. Aside of any voodoo magic behind the scenes, the order by is O(N * log N).

The downside to the random() < 0.01 one is that you'll get a variable number of output records.


Note, there is a better way to shuffling a set of data than sorting by random: The Fisher-Yates Shuffle, which runs in O(N). Implementing the shuffle in SQL sounds like quite the challenge, though.

  • Grat explanation :) I will see (only for curiosity) the fisher-yates shuffle ... – nanounanue Dec 30 '11 at 0:02
  • 2
    There's no reason you can't add a Limit 1 to the end of your first example though. Only problem is there's a potential that you'd get no records back, so you'd have to consider that in your code. – Relequestual May 3 '16 at 13:11

Here is a decision that works for me. I guess it's very simple to understand and execute.

SELECT 
  field_1, 
  field_2, 
  field_2, 
  random() as ordering
FROM 
  big_table
WHERE 
  some_conditions
ORDER BY
  ordering 
LIMIT 1000;
  • you some kind of genius man! – Worker May 17 at 7:35
  • I think this solution is working as ORDER BY random() which works but might not efficient when working with a large table. – Anh Cao Jul 12 at 10:10

If you want just one row, you can use a calculated offset derived from count.

select * from table_name limit 1
offset floor(random() * (select count(*) from table_name));
select * from table order by random() limit 1000;

If you know how many rows you want, check out tsm_system_rows.

tsm_system_rows

module provides the table sampling method SYSTEM_ROWS, which can be used in the TABLESAMPLE clause of a SELECT command.

This table sampling method accepts a single integer argument that is the maximum number of rows to read. The resulting sample will always contain exactly that many rows, unless the table does not contain enough rows, in which case the whole table is selected. Like the built-in SYSTEM sampling method, SYSTEM_ROWS performs block-level sampling, so that the sample is not completely random but may be subject to clustering effects, especially if only a small number of rows are requested.

First install the extension

CREATE EXTENSION tsm_system_rows;

Then your query,

SELECT *
FROM table
TABLESAMPLE SYSTEM_ROWS(1000);
  • 1
    I added a link to your added answer, it's a notable improvement over the built-in SYSTEM method. – Erwin Brandstetter Dec 27 '16 at 1:18

A variation of the materialized view "Possible alternative" outlined by Erwin Brandstetter is possible.

Say, for example, that you don't want duplicates in the randomized values that are returned. So you will need to set a boolean value on the primary table containing your (non-randomized) set of values.

Assuming this is the input table:

id_values  id  |   used
           ----+--------
           1   |   FALSE
           2   |   FALSE
           3   |   FALSE
           4   |   FALSE
           5   |   FALSE
           ...

Populate the ID_VALUES table as needed. Then, as described by Erwin, create a materialized view that randomizes the ID_VALUES table once:

CREATE MATERIALIZED VIEW id_values_randomized AS
  SELECT id
  FROM id_values
  ORDER BY random();

Note that the materialized view does not contain the used column, because this will quickly become out-of-date. Nor does the view need to contain other columns that may be in the id_values table.

In order to obtain (and "consume") random values, use an UPDATE-RETURNING on id_values, selecting id_values from id_values_randomized with a join, and applying the desired criteria to obtain only relevant possibilities. For example:

UPDATE id_values
SET used = TRUE
WHERE id_values.id IN 
  (SELECT i.id
    FROM id_values_randomized r INNER JOIN id_values i ON i.id = r.id
    WHERE (NOT i.used)
    LIMIT 5)
RETURNING id;

Change LIMIT as necessary -- if you only need one random value at a time, change LIMIT to 1.

With the proper indexes on id_values, I believe the UPDATE-RETURNING should execute very quickly with little load. It returns randomized values with one database round-trip. The criteria for "eligible" rows can be as complex as required. New rows can be added to the id_values table at any time, and they will become accessible to the application as soon as the materialized view is refreshed (which can likely be run at an off-peak time). Creation and refresh of the materialized view will be slow, but it only needs to be executed when new id's are added to the id_values table.

  • very interesting. Would that work if I need not only to select but also update using select..for update with a pg_try_advisory_xact_lock ? (i.e i need many concurrent reads AND writes) – Mathieu Oct 26 '15 at 18:16
  • Please explain your downvote with a comment. – Raman Dec 28 '16 at 13:53

Add a column called r with type serial. Index r.

Assume we have 200,000 rows, we are going to generate a random number n, where 0 < n <= 200, 000.

Select rows with r > n, sort them ASC and select the smallest one.

Code:

select * from YOUR_TABLE 
where r > (
    select (
        select reltuples::bigint AS estimate
        from   pg_class
        where  oid = 'public.YOUR_TABLE'::regclass) * random()
    )
order by r asc limit(1);

The code is self-explanatory. The subquery in the middle is used to quickly estimate the table row counts from https://stackoverflow.com/a/7945274/1271094 .

In application level you need to execute the statement again if n > the number of rows or need to select multiple rows.

  • I like this because it's short and elegant :) And I even found a way to improve it: EXPLAIN ANALYZE tells me that like this, a PKEY index will not be used because random() returns a double, whereas the PKEY needs a BIGINT. – fxtentacle Sep 20 '16 at 15:49
  • select * from YOUR_TABLE where r > ( select ( select reltuples::bigint AS estimate from pg_class where oid = 'public.YOUR_TABLE'::regclass) * random() )::BIGINT order by r asc limit(1); – fxtentacle Sep 20 '16 at 15:51

I know I'm a little late to the party, but I just found this awesome tool called pg_sample:

pg_sample - extract a small, sample dataset from a larger PostgreSQL database while maintaining referential integrity.

I tried this with a 350M rows database and it was really fast, don't know about the randomness.

./pg_sample --limit="small_table = *" --limit="large_table = 100000" -U postgres source_db | psql -U postgres target_db

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