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I'm dealing with a Postgres table (called "lives") that contains records with columns for time_stamp, usr_id, transaction_id, and lives_remaining. I need a query that will give me the most recent lives_remaining total for each usr_id

  1. There are multiple users (distinct usr_id's)
  2. time_stamp is not a unique identifier: sometimes user events (one by row in the table) will occur with the same time_stamp.
  3. trans_id is unique only for very small time ranges: over time it repeats
  4. remaining_lives (for a given user) can both increase and decrease over time

example:

time_stamp|lives_remaining|usr_id|trans_id
-----------------------------------------
  07:00  |       1       |   1  |   1    
  09:00  |       4       |   2  |   2    
  10:00  |       2       |   3  |   3    
  10:00  |       1       |   2  |   4    
  11:00  |       4       |   1  |   5    
  11:00  |       3       |   1  |   6    
  13:00  |       3       |   3  |   1    

As I will need to access other columns of the row with the latest data for each given usr_id, I need a query that gives a result like this:

time_stamp|lives_remaining|usr_id|trans_id
-----------------------------------------
  11:00  |       3       |   1  |   6    
  10:00  |       1       |   2  |   4    
  13:00  |       3       |   3  |   1    

As mentioned, each usr_id can gain or lose lives, and sometimes these timestamped events occur so close together that they have the same timestamp! Therefore this query won't work:

SELECT b.time_stamp,b.lives_remaining,b.usr_id,b.trans_id FROM 
      (SELECT usr_id, max(time_stamp) AS max_timestamp 
       FROM lives GROUP BY usr_id ORDER BY usr_id) a 
JOIN lives b ON a.max_timestamp = b.time_stamp

Instead, I need to use both time_stamp (first) and trans_id (second) to identify the correct row. I also then need to pass that information from the subquery to the main query that will provide the data for the other columns of the appropriate rows. This is the hacked up query that I've gotten to work:

SELECT b.time_stamp,b.lives_remaining,b.usr_id,b.trans_id FROM 
      (SELECT usr_id, max(time_stamp || '*' || trans_id) 
       AS max_timestamp_transid
       FROM lives GROUP BY usr_id ORDER BY usr_id) a 
JOIN lives b ON a.max_timestamp_transid = b.time_stamp || '*' || b.trans_id 
ORDER BY b.usr_id

Okay, so this works, but I don't like it. It requires a query within a query, a self join, and it seems to me that it could be much simpler by grabbing the row that MAX found to have the largest timestamp and trans_id. The table "lives" has tens of millions of rows to parse, so I'd like this query to be as fast and efficient as possible. I'm new to RDBM and Postgres in particular, so I know that I need to make effective use of the proper indexes. I'm a bit lost on how to optimize.

I found a similar discussion here. Can I perform some type of Postgres equivalent to an Oracle analytic function?

Any advice on accessing related column information used by an aggregate function (like MAX), creating indexes, and creating better queries would be much appreciated!

P.S. You can use the following to create my example case:

create TABLE lives (time_stamp timestamp, lives_remaining integer, 
                    usr_id integer, trans_id integer);
insert into lives values ('2000-01-01 07:00', 1, 1, 1);
insert into lives values ('2000-01-01 09:00', 4, 2, 2);
insert into lives values ('2000-01-01 10:00', 2, 3, 3);
insert into lives values ('2000-01-01 10:00', 1, 2, 4);
insert into lives values ('2000-01-01 11:00', 4, 1, 5);
insert into lives values ('2000-01-01 11:00', 3, 1, 6);
insert into lives values ('2000-01-01 13:00', 3, 3, 1);
share|improve this question
    
Josh, you may not like the fact that the query self-joins etc., but that's OK as far as the RDBMS is concerned. –  vladr Feb 26 '09 at 8:10
1  
What the self-join will actually end up translating to is a simple index mapping, where the inner SELECT (the one with MAX) scans the index throwing away irrelevant entries, and where the outer SELECT just grabs the rest of the columns from the table corresponding to the narrowed-down index. –  vladr Feb 26 '09 at 8:11
    
Vlad, thanks for the tips and explanation. It's opened my eyes to how to begin understanding the inner workings of the database and how to optimize queries. Quassnoi, thanks for the great query and tip on primary key; Bill too. Very helpful. –  Joshua Berry Feb 26 '09 at 16:55
    
thank you for showing me how to get a MAX BY 2 columns! –  user1382306 Oct 9 '13 at 22:22

6 Answers 6

up vote 28 down vote accepted

On a table with 158k pseudo-random rows (usr_id uniformly distributed between 0 and 10k, trans_id uniformly distributed between 0 and 30),

By query cost, below, I am referring to Postgres' cost based optimizer's cost estimate (with Postgres' default xxx_cost values), which is a weighed function estimate of required I/O and CPU resources; you can obtain this by firing up PgAdminIII and running "Query/Explain (F7)" on the query with "Query/Explain options" set to "Analyze"

  • Quassnoy's query has a cost estimate of 745k (!), and completes in 1.3 seconds (given a compound index on (usr_id, trans_id, times_tamp))
  • Bill's query has a cost estimate of 93k, and completes in 2.9 seconds (given a compound index on (usr_id, trans_id))
  • Query #1 below has a cost estimate of 16k, and completes in 800ms (given a compound index on (usr_id, trans_id, times_tamp))
  • Query #2 below has a cost estimate of 14k, and completes in 800ms (given a compound function index on (usr_id, EXTRACT(EPOCH FROM time_stamp), trans_id))
    • this is Postgres-specific
  • Query #3 below (Postgres 8.4+) has a cost estimate and completion time comparable to (or better than) query #2 (given a compound index on (usr_id, time_stamp, trans_id)); it has the advantage of scanning the lives table only once and, should you temporarily increase (if needed) work_mem to accommodate the sort in memory, it will be by far the fastest of all queries.

All times above include retrieval of the full 10k rows result-set.

Your goal is minimal cost estimate and minimal query execution time, with an emphasis on estimated cost. Query execution can dependent significantly on runtime conditions (e.g. whether relevant rows are already fully cached in memory or not), whereas the cost estimate is not. On the other hand, keep in mind that cost estimate is exactly that, an estimate.

The best query execution time is obtained when running on a dedicated database without load (e.g. playing with pgAdminIII on a development PC.) Query time will vary in production based on actual machine load/data access spread. When one query appears slightly faster (<20%) than the other but has a much higher cost, it will generally be wiser to choose the one with higher execution time but lower cost.

When you expect that there will be no competition for memory on your production machine at the time the query is run (e.g. the RDBMS cache and filesystem cache won't be thrashed by concurrent queries and/or filesystem activity) then the query time you obtained in standalone (e.g. pgAdminIII on a development PC) mode will be representative. If there is contention on the production system, query time will degrade proportionally to the estimated cost ratio, as the query with the lower cost does not rely as much on cache whereas the query with higher cost will revisit the same data over and over (triggering additional I/O in the absence of a stable cache), e.g.:

              cost | time (dedicated machine) |     time (under load) |
-------------------+--------------------------+-----------------------+
some query A:   5k | (all data cached)  900ms | (less i/o)     1000ms |
some query B:  50k | (all data cached)  900ms | (lots of i/o) 10000ns |

Do not forget to run ANALYZE lives once after creating the necessary indices.


Query #1

-- incrementally narrow down the result set via inner joins
--  the CBO may elect to perform one full index scan combined
--  with cascading index lookups, or as hash aggregates terminated
--  by one nested index lookup into lives - on my machine
--  the latter query plan was selected given my memory settings and
--  histogram
SELECT
  l1.*
 FROM
  lives AS l1
 INNER JOIN (
    SELECT
      usr_id,
      MAX(time_stamp) AS time_stamp_max
     FROM
      lives
     GROUP BY
      usr_id
  ) AS l2
 ON
  l1.usr_id     = l2.usr_id AND
  l1.time_stamp = l2.time_stamp_max
 INNER JOIN (
    SELECT
      usr_id,
      time_stamp,
      MAX(trans_id) AS trans_max
     FROM
      lives
     GROUP BY
      usr_id, time_stamp
  ) AS l3
 ON
  l1.usr_id     = l3.usr_id AND
  l1.time_stamp = l3.time_stamp AND
  l1.trans_id   = l3.trans_max

Query #2

-- cheat to obtain a max of the (time_stamp, trans_id) tuple in one pass
-- this results in a single table scan and one nested index lookup into lives,
--  by far the least I/O intensive operation even in case of great scarcity
--  of memory (least reliant on cache for the best performance)
SELECT
  l1.*
 FROM
  lives AS l1
 INNER JOIN (
   SELECT
     usr_id,
     MAX(ARRAY[EXTRACT(EPOCH FROM time_stamp),trans_id])
       AS compound_time_stamp
    FROM
     lives
    GROUP BY
     usr_id
  ) AS l2
ON
  l1.usr_id = l2.usr_id AND
  EXTRACT(EPOCH FROM l1.time_stamp) = l2.compound_time_stamp[1] AND
  l1.trans_id = l2.compound_time_stamp[2]

2013/01/29 update

Finally, as of version 8.4, Postgres supports Window Function meaning you can write something as simple and efficient as:

Query #3

-- use Window Functions
-- performs a SINGLE scan of the table
SELECT DISTINCT ON (usr_id)
  last_value(time_stamp) OVER wnd,
  last_value(lives_remaining) OVER wnd,
  usr_id,
  last_value(trans_id) OVER wnd
 FROM lives
 WINDOW wnd AS (
   PARTITION BY usr_id ORDER BY time_stamp, trans_id
   ROWS BETWEEN UNBOUNDED PRECEDING AND UNBOUNDED FOLLOWING
 );
share|improve this answer
    
By a compound index on (usr_id, trans_id, times_tamp), do you mean something like "CREATE INDEX lives_blah_idx ON lives (usr_id, trans_id, time_stamp)"? Or should I create three separate indexes for each column? I should stick with the default of "USING btree", right? –  Joshua Berry Feb 26 '09 at 17:02
1  
Yes to the first choice: I mean CREATE INDEX lives_blah_idx ON lives (usr_id, trans_id, time_stamp). :) Cheers. –  vladr Feb 26 '09 at 19:52
    
Thanks for even doing the cost comparison vladr! Very complete answer! –  Adam Nov 30 '10 at 0:34
    
@vladr I just came across your answer. I am a bit confused, as you say query 1 has a cost of 16k and query 2 a cost of 14k. But further down in the table you say query 1 has a cost of 5k and query 2 has a cost of 50k. So which query is a preferred one to use? :) thanks –  Hooman Jul 30 '12 at 12:50
1  
@Kave, the table is for a hypothetical pair of queries to illustrate an example, not the OP's two queries. Renaming to reduce confusion. –  vladr Aug 13 '12 at 20:15

Here's another method, which happens to use no correlated subqueries or GROUP BY. I'm not expert in PostgreSQL performance tuning, so I suggest you try both this and the solutions given by other folks to see which works better for you.

SELECT l1.*
FROM lives l1 LEFT OUTER JOIN lives l2
  ON (l1.usr_id = l2.usr_id AND (l1.time_stamp < l2.time_stamp 
   OR (l1.time_stamp = l2.time_stamp AND l1.trans_id < l2.trans_id)))
WHERE l2.usr_id IS NULL
ORDER BY l1.usr_id;

I am assuming that trans_id is unique at least over any given value of time_stamp.

share|improve this answer

Actaully there's a hacky solution for this problem. Let's say you want to select the biggest tree of each forest in a region.

SELECT (array_agg(tree.id ORDER BY tree_size.size)))[1] FROM tree JOIN forest ON (tree.forest = forest.id) GROUP BY forest.id

When you group trees by forests there will be an unsorted list of trees and you need to find the biggest one. First thing you should do is to sort the rows by their sizes and select the first one of your list. It may seems inefficient but if you have millions of rows it will be quite faster than the solutions that includes JOIN's and WHERE conditions.

BTW, note that ORDER_BY for array_agg is introduced in Postgresql 9.0

share|improve this answer
    
You have an error. You need to write ORDER BY tree_size.size DESC. Also, for author's task the code will look like this: SELECT usr_id, (array_agg(time_stamp ORDER BY time_stamp DESC))[1] AS timestamp, (array_agg(lives_remaining ORDER BY time_stamp DESC))[1] AS lives_remaining, (array_agg(trans_id ORDER BY time_stamp DESC))[1] AS trans_id FROM lives GROUP BY usr_id –  alexkovelsky Aug 21 at 14:45
SELECT  l.*
FROM    (
        SELECT DISTINCT usr_id
        FROM   lives
        ) lo, lives l
WHERE   l.ctid = (
        SELECT ctid
        FROM   lives li
        WHERE  li.usr_id = lo.usr_id
        ORDER BY
          time_stamp DESC, trans_id DESC
        LIMIT 1
        )

Creating an index on (usr_id, time_stamp, trans_id) will greatly improve this query.

You should always, always have some kind of PRIMARY KEY in your tables.

share|improve this answer

I think you've got one major problem here: there's no monotonically increasing "counter" to guarantee that a given row has happened later in time than another. Take this example:

timestamp   lives_remaining   user_id   trans_id
10:00       4                 3         5
10:00       5                 3         6
10:00       3                 3         1
10:00       2                 3         2

You cannot determine from this data which is the most recent entry. Is it the second one or the last one? There is no sort or max() function you can apply to any of this data to give you the correct answer.

Increasing the resolution of the timestamp would be a huge help. Since the database engine serializes requests, with sufficient resolution you can guarantee that no two timestamps will be the same.

Alternatively, use a trans_id that won't roll over for a very, very long time. Having a trans_id that rolls over means you can't tell (for the same timestamp) whether trans_id 6 is more recent than trans_id 1 unless you do some complicated math.

share|improve this answer
    
Yes, ideally a sequence (autoincrement) column would be in order. –  vladr Feb 26 '09 at 2:20
    
The assumption from above was that for small time increments, trans_id would not roll over. I agree that the table needs a unique primary index --like a non-repeating trans_id. (P.S. I'm happy that I now have enough karma/reputation points to comment!) –  Joshua Berry Feb 26 '09 at 11:55
    
Vlad states that trans_id has a rather short cycle which turns over frequently. Even if you consider only the middle two rows from my table (trans_id = 6 and 1), you still can't tell which is the most recent. Therefore, using the max(trans_id) for a given timestamp won't work. –  Barry Brown Feb 26 '09 at 18:32
    
Yep, I'm relying on the application author's guarantee that the (time_stamp,trans_id) tuple is unique for a given user. If it's not the case then "SELECT l1.usr_id,l1.lives_left,... FROM ... WHERE ..." must become "SELECT l1.usr_id,MAX/MIN(l1.lives_left),... FROM ... WHERE ... GROUP BY l1.usr_id,... –  vladr Feb 26 '09 at 19:56

I like the style of Mike Woodhouse's answer on the other page you mentioned. It's especially concise when the thing being maximised over is just a single column, in which case the subquery can just use MAX(some_col) and GROUP BY the other columns, but in your case you have a 2-part quantity to be maximised, you can still do so by using ORDER BY plus LIMIT 1 instead (as done by Quassnoi):

SELECT * 
FROM lives outer
WHERE (usr_id, time_stamp, trans_id) IN (
    SELECT usr_id, time_stamp, trans_id
    FROM lives sq
    WHERE sq.usr_id = outer.usr_id
    ORDER BY trans_id, time_stamp
    LIMIT 1
)

I find using the row-constructor syntax WHERE (a, b, c) IN (subquery) nice because it cuts down on the amount of verbiage needed.

share|improve this answer

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