The effect of table growth on performance will depend on the query plan chosen, available indexes, the selectivity of the query, and lots of other factors.
EXPLAIN ANALYZE on the query might help. In short, if your query only selects a few rows and can use a simple b-tree index then it won't usually slow down tons, only a little as the index grows. On the other hand queries using complex non-indexed conditions or returning lots of rows could perform very badly indeed.
Your issue appears to mirror that in the question How should we handle rows which won't be queried once they are old in PostgreSQL?
The advice given there should apply:
For example, you might:
CREATE INDEX create_dt_when_not_deleted_idx
ON tn (create_dt)
WHERE (NOT deleted);
This includes only rows where
deleted = 'f' (assuming
deleted is `not null) in the index. This isn't the same as having them gone from the table completely.
- Nothing changes with full table sequential scans, the
deleted='t' rows must still be scanned; and
- There's more I/O than if the
deleted = 't' rows weren't there because any given heap page is likely to contain a mix of
deleted = 't' and
deleted = 'f' rows.
You can reduce the impact of the latter by
CLUSTERing on an index that includes
deleted. Again, this will have no effect on sequential scans. To help with sequential scans you would have to partition the table on
Pg 9.2's index only scans should (I think, haven't tested) use the partial index. When an index only scan is possible the partial index should be as fast as an index on a table containing only the
deleted = 'f' rows.
Note that you'll need to keep table and index bloat under control. Ensure autovaccum runs very frequently and use a current version of PostgreSQL that doesn't need things like manually-managed free space map and has the latest, best-behaved autovacuum. I'd recommend 9.0 or above, preferably 9.1 or 9.2. Tune autovacuum to run aggressively.
When tuning and testing performance - test your queries with
EXPLAIN ANALYZE, don't just guess.