This post has been imported from the old blog and has not yet been converted to the new syntax yet.
Today I was made aware by Filip, a colleague of mine, about the importance of columns used in a where clause with a compound index. I decided to investigate this a bit more in detail, with proper profiling and comparisons on a large data set.

I created a test table, DemoTable, which looks as follows:

[sql]
ColumnA varchar(6)
ColumnB int
ColumnC int
ColumnD varchar(3)
..30 more columns..
[/sql]

The primary key consists out of ColumnA, ColumnB and ColumnC. Which implicitly means it acts as a compound index.

There are about 6.5 million records in the table.

Full Primary Key Lookup

The most obvious query to get data from this table is a simple select, using all values of the primary key, as follows:

[sql]
SELECT *
FROM DemoTable
WHERE ColumnA = 'DCU'
AND ColumnB = 1
AND ColumnC = 1
[/sql]

Taking a look at the query plan, this does exactly what most people expect it to do, it uses a very efficient Index Seek to pick out the matching record.

A, B, C

Partial Primary Key Lookup

A variation to the above query, is the following one, using only part of the primary key.

[sql]
SELECT *
FROM DemoTable
WHERE ColumnA = 'DCU'
AND ColumnB = 1
[/sql]

The query plan shows us that this query is also very efficient, since it can make full use of the index to get the results back.

A, B

Out of curiosity and to be thorough, I also checked the results of the following query:

[sql]
SELECT *
FROM DemoTable
WHERE ColumnA = 'DCU'
[/sql]

Same story, our index is ordered on ColumnA, ColumnB and ColumnC, so it can easily use a binary search on it and give back all results for ColumnA.

A

The fun stuff begins when we don't just remove columns from the where clause in the same order the index is created, for example this query:

[sql]
SELECT *
FROM DemoTable
WHERE ColumnA = 'DCU'
AND ColumnC = 1
[/sql]

SQL Server will first use an efficient index seek to get all results for the correct ColumnA, since the index is ordered by ColumnA first, and will then search in the remaining results for the correct ColumnC.

In the query plan, you can identify this as the Predicate, which displays ColumnC. In the end, this is still an efficient query, but if the majority of your queries would be filtering on ColumnA and ColumnC, it would be a good idea to change your column order to ColumnA, ColumnC, ColumnB in the index. This way, the overall efficiency of your index would increase.

A, C

Another variation of a partial key lookup is the following query:

[sql]
SELECT *
FROM DemoTable
WHERE ColumnB = 1
AND ColumnC = 1
[/sql]

And it's at this point you can say goodbye to performance. To get the requested results, SQL Server will do a full scan on every value in your index to find matches. Making it go over 6.5 million pieces of data in my example.

If lots of your queries would be like this, I'd suggest to consider changing the column order, or add an index on ColumnB and ColumnC. Keep in mind that adding indexes has a drawback on performance of INSERTs and DELETEs, it's up to each project to define this delicate balance.

B, C

Partial Primary Key Lookup Sorted

Another case I wanted to check, was how SQL Server handles ORDER BY clauses with regards to columns in an index.

I started simple by doing:

[sql]
SELECT *
FROM DemoTable
WHERE ColumnA = 'DCU'
AND ColumnB = 1
ORDER BY ColumnC
[/sql]

As expected, SQL Server simply does an index scan for ColumnA and ColumnB and returns the results, since they are already ordered by ColumnC in the index. As efficient as possible.

A, B Order C

A small variation to this query leaves out the first column of the index, resulting in:

[sql]
SELECT *
FROM DemoTable
WHERE ColumnB = 1
ORDER BY ColumnC
[/sql]

Again, since our WHERE clause is not using the columns in the order of the index, we are invoking a full index scan for the value of ColumnB. Afterwards SQL Server calls Sort on the results to get them in the correct order. As inefficient as possible :)

B, Order C

Conclusions

It should be clear that the order of your columns in an index are very important. I've made up some guidelines for myself regarding this:


  • Place the most limiting columns first in an index.
    By this, I mean to first determine which queries I will be running against the database, determining their frequency and then ordering the columns according to the most frequently run queries.
     


  • Place an additional index if needed
    After I've ordered my columns to be as efficient as possible and see that another set of queries is run almost as frequently that they need optimization, possibly add another index on a subset of the columns in the first index. Keeping in mind for which purpose the table should be optimised (eg: SELECT vs INSERT/DELETE).



I'll be more than happy to receive some comments on possible additional tests to analyze and make my conclusions better.
 
This post has been imported from the old blog and has not yet been converted to the new syntax yet.
Some nifty SQL statements I made last week:

Firstly, listing all databases on a server.

[sql]
-- Get Databases
SELECT name FROM master.dbo.sysdatabases ORDER BY name
[/sql]

Secondly, a way to get all the user-created stored procedures from a database.

[sql]
-- Get Stored Procedures
-- Type = 'P' --> Stored Procedure.
-- Category = 0 --> User Created.
SELECT * FROM sysobjects WHERE type = 'P' AND category = 0 ORDER BY name
[/sql]

Then we can retrieve the content of the stored procedure with the following query:

[sql]
- Get Stored Procedure Content
-- Name = Stored Procedure Name.
-- Colid = Multiple lines, their sequence.
SELECT text
FROM syscomments
WHERE id = (SELECT id FROM sysobjects WHERE name = '{0}')
ORDER BY colid
[/sql]

In C# you could concatenate the returned records to get the full stored procedure content.

However, do mind the encrypted column in syscomments. The above queries work fine when this is 0. So you might want to add some checking, and in case it's encrypted you could first decrypt it and then display it. But you'll have to figure out how to do that yourself :)