0

Adding a seemingly perfectly index is having an unexpectedly adverse affect on a query performance...

-- [Data] has a predictable structure and a simple clustered index of the primary key:
ALTER TABLE [dbo].[Data] ADD PRIMARY KEY CLUSTERED ( [ID] )

-- Joins on itself looking for a certain kind of "overlapping" records
SELECT DISTINCT
    [Data].ID AS [ID]
FROM 
    dbo.[Data] AS [Data]
JOIN
    dbo.[Data] AS [Compared] ON
    [Data].[A] = [Compared].[A] AND
    [Data].[B] = [Compared].[B] AND
    [Data].[C] = [Compared].[C] AND
    ([Data].[D] = [Compared].[D] OR [Data].[E] = [Compared].[E]) AND
    [Data].[F] <> [Compared].[F]
WHERE 1=1
    AND [Data].[A] = @A
    AND @CS <= [Data].[C] AND [Data].[C] < @CE -- Between a range

[Data] has about a quarter-million records so far, 10% to 50% of the data satisfies the where clause depending on @A, @CS, and @CE. As is, the query takes 1 second to return about 300 rows when querying 10%, and 30 seconds to return 3000 rows when querying 50% of the data.

Curiously, the estimated/actual execution plan indicates two parallel Clustered Index Scans, but the clustered index is only of the ID, which isn't part of the conditions of the query, only the output. ??

If I add this hand-crafted [IDX_A_B_C_D_E_F] index which I fully expected to improve performance, the query slows down by a factor of 8 (8 seconds for 10% & 4 minutes for 50%). The estimated/actual execution plans show an Index Seek, which seems like the right thing to be doing, but why so slow??

CREATE UNIQUE INDEX [IDX_A_B_C_D_E_F] 
    ON [dbo].[Data] ([A], [B], [C], [D], [E], [F])
    INCLUDE ([ID], [X], [Y], [Z]);

The Data Engine Tuning wizard suggests a similar index with no noticeable difference in performance from this one. Moving AND [Data].[F] <> [Compared].[F] from the join condition to the where clause makes no difference in performance.

I need these and other indexes for other queries. I'm sure I could hint that the query should refer to the Clustered Index, since that's currently winning - but we all know it is not as optimized as it could be, and without a proper index, I can expect the performance will get much worse with additional data.

What gives?

== Edit ==

For Gail, here are the execution plans. Of course, the one that references the index is the one queried with the index available. This is a little different than my original description of the clustered index scan - I deleted the auto-gen PK index for testing and can't get it back(?), so this is without ANY indexes at all, hence the table scan. Different look to the query plan, but no noticeable change in performance. (Table Scan is the fast one)

execution plans http://www.imagechicken.com/uploads/1276732894073081600.png

Indexed.sqlplan

Nonindexed.sqlplan

7
  • Is there any chance that you can upload the execution plans somewhere? Both when that nonclustered index is present and when it's not. Jun 16, 2010 at 22:27
  • I meant the plan, not a picture of the plan. There's lots and lots of info in the properties that's critically important. Can you save, zip and upload the .sqlplan files? Jun 17, 2010 at 5:33
  • Ok, links are at the bottom. You should be able to "download" as .sqlplan and it will open, but I figured the XML is what you're after, so that's pasted for browsing. Jun 17, 2010 at 16:20
  • Will take a look. Out of interest, what happens if you run the query when the indexes aren't there and add the hint OPTION (MAXDOP 1). Still faster than the index seeks or slower? Jun 19, 2010 at 9:43
  • Hi Gail, just tried OPTION (MAXDOP 1) -- No apparent difference. Thanks. Jun 21, 2010 at 19:51

1 Answer 1

2

It's doing the CI scan because the CI is the actual data. An index is just a placeholder to the actual data.

An index seek is definitely the incorrect thing to do on a 50% return query, and it's rare to see one used even on a 10% return rate. Usually if it's over a couple of percent, it's going to scan (that's why on smaller tables you can count on a scan to happened nearly every time).

I would suggest making sure the stats are up to date for that table, and possibly make sure that the index isn't in need of maintenance itself.

UPDATE STATS - http://msdn.microsoft.com/en-us/library/ms187348.aspx

11
  • Oh, I thought it would say "Table Scan". Makes sense. Thanks. I don't understand the rest though - won't the index seek be able to get to the A and B and C and (D or E) neighborhood much quicker than doing an unsorted table scan? Even ABC neighborhood would reduce the self-joined comparisons to only hundreds per ABC group. Basically, I can't see how trudging though the table couldn't be improved by the pre-sorted index. This is all fresh data, fresh indexes - the statistics should already be updated, as the article you referenced suggests they would be. Jun 16, 2010 at 20:27
  • As much as I want to understand the problem, I also want to achieve the practical result of getting the same output faster. Any ideas on how to do this quicker? Jun 16, 2010 at 20:33
  • 2
    I'm not entirely sure how everything works internally to say why the seek is so much more expensive than the scan. If anyone can post that I'd be very interested in reading, as well. Gail Shaw, a very well respected SQL Server MVP, has a post on this as well. She found that (even with a covering index), that it switched from a seek to a scan at approximately 0.4(!!!)% return. sqlinthewild.co.za/index.php/2009/01/09/seek-or-scan
    – Mike M.
    Jun 16, 2010 at 20:42
  • Yeah, and in this case it isn't switching - it's stupidly using the slow way, even advising to make the index if I don't already have one. Jun 16, 2010 at 21:46
  • 2
    Mike, that blog post you cite is only for the case of a non-covering index. The reason SQL switches to a table/clustered index scan is because of the cost of key lookups, and there are no key lookups when the index is covering. In the case of a covering nonclustered index, SQL happily (and correctly) seeks right up to 100% of the rows affected, because all the info it needs is in the nonclustered index and typically nonclustered indexes are smaller (and hence faster) than clustered indexes. Jun 16, 2010 at 22:26

Your Answer

By clicking “Post Your Answer”, you agree to our terms of service, privacy policy and cookie policy

Not the answer you're looking for? Browse other questions tagged or ask your own question.