In PostgreSQL this is typically simpler and faster (more performance optimization below):
SELECT DISTINCT ON (customer)
id, customer, total
ORDER BY customer, total DESC, id
Or shorter with ordinal numbers of output columns:
SELECT DISTINCT ON (2)
id, customer, total
ORDER BY 2, 3 DESC, 1
DISTINCT ON is a PostgreSQL extension of the standard (where only
DISTINCT on the whole
SELECT list is defined).
DISTINCT ON can be combined with
ORDER BY. Leading expressions of
ORDER BY have to match expressions in
DISTINCT ON in that order, but you can add additional columns / expressions to pick a particular row from each group of peers. I added
ORDER BY to break ties:
"Pick the row with the smallest
id from each group sharing the highest total."
For more complex requirements (not needed in this simple case):
You don't have to include any of the columns / expression used in
ORDER BY or
DISTINCT ON in the
You can include any other column from the base tables in the
SELECT list. This is instrumental in replacing much more complex queries with subqueries and aggregate / window functions.
I tested with versions 8.3 – 9.3. But the feature has been there at least since version 7.1 (= for ever).
I ran three tests with PostgreSQL 9.1 on a real life table of 65579 rows and single-column b-tree indexes on each of the three columns involved and took the best of 5 runs.
Comparing @OMGPonies' first query (
A) to the above
DISTINCT ON solution (
Select the whole table, results in 5958 rows in this case.
A: Total runtime: 567.218 ms
B: Total runtime: 386.673 ms
WHERE customer BETWEEN x AND y resulting in 1000 rows.
A: Total runtime: 249.136 ms
B: Total runtime: 55.111 ms
Select a single customer with
WHERE customer = x.
A: Total runtime: 0.143 ms
B: Total runtime: 0.072 ms
The perfect index for the above query would be a multi-column index spanning all three columns in matching sequence and with matching sort order:
CREATE INDEX purchases_3c_idx ON purchases (customer, total DESC, id);
That may be too specialized for real world applications. If read performance for this case is crucial, use it, though. Same test repeated:
A: Total runtime: 277.953 ms
B: Total runtime: 193.547 ms
A: Total runtime: 249.796 ms -- special index not used
B: Total runtime: 28.679 ms
A: Total runtime: 0.120 ms
B: Total runtime: 0.048 ms
Effectiveness / Performance optimization
You have to weigh cost and benefit before you create a tailored index for every query. The potential of above index largely depends on data distribution.
The index is used because it delivers pre-sorted data, and in Postgres 9.2 or later the query can also benefit from an index only scan if the width of the index is smaller than the underlying table. The index has to be scanned in its entirety, though.
For many customers with few rows each, this is very efficient, even more so if you need sorted output anyway. The benefit shrinks with a growing number of rows per customer.
For few customers with many rows, the equivalent of a loose index scan would be much more efficient, but that's not currently implemented in Postgres (up to 9.4).
There are faster query techniques to substitute for this. In particular, if you have a separate table holding unique customers (which often is the case). But also if you don't: