While studying for the 70-433 exam I noticed you can create a covering index in one of the following two ways.

CREATE INDEX idx1 ON MyTable (Col1, Col2, Col3)

-- OR --

CREATE INDEX idx1 ON MyTable (Col1) INCLUDE (Col2, Col3)

The INCLUDE clause is new to me. Why would you use it and what guidelines would you suggest in determining whether to create a covering index with or without the INCLUDE clause?


If the column is not in the WHERE/JOIN/GROUP BY/ORDER BY, but only in the column list in the SELECT clause.

The INCLUDE clause adds the data at the lowest/leaf level, rather than in the index tree. This makes the index smaller because it's not part of the tree

INCLUDE columns are not key columns in the index, so they are not ordered. This means it isn't really useful for predicates, sorting etc as I mentioned above. However, it may be useful if you have a residual lookup in a few rows from the key column(s)

Another MSDN article with a worked example

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    So then, this would be a technique for creating a less expensive version of a covered index? – JMarsch Sep 15 '12 at 2:56
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    @gbn, would you mind explaining this sentence in more detail, and explain why it means that the include clause is not useful for sorting, etc: "The INCLUDE clause adds the data at the lowest/leaf level, rather than in the index tree. This makes the index smaller because it's not part of the tree" – Tola Odejayi May 7 '13 at 21:20
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    @JMarsch: sorry for the late reply, but yes, this is exactly what it is. – gbn May 8 '13 at 7:45
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    @Tola Odejayi: INCLUDE columns are not key columns in the index, so they are not ordered. This makes them not typically useful for JOINs or sorting. And because they are not key columns, they don't sit in the whole B-tree structure like key columns – gbn May 8 '13 at 7:51
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    While this is the most accepted answer, I think further explanation is needed, what if for some queries the column is part of the SELECT and for some not?\ – Chisko Mar 8 '17 at 3:37

You would use the INCLUDE to add one or more columns to the leaf level of a non-clustered index, if by doing so, you can "cover" your queries.

Imagine you need to query for an employee's ID, department ID, and lastname.

SELECT EmployeeID, DepartmentID, LastName
FROM Employee
WHERE DepartmentID = 5

If you happen to have a non-clustered index on (EmployeeID, DepartmentID), once you find the employees for a given department, you now have to do "bookmark lookup" to get the actual full employee record, just to get the lastname column. That can get pretty expensive in terms of performance, if you find a lot of employees.

If you had included that lastname in your index:

  ON Employee(EmployeeID, DepartmentID)
  INCLUDE (Lastname)

then all the information you need is available in the leaf level of the non-clustered index. Just by seeking in the non-clustered index and finding your employees for a given department, you have all the necessary information, and the bookmark lookup for each employee found in the index is no longer necessary --> you save a lot of time.

Obviously, you cannot include every column in every non-clustered index - but if you do have queries which are missing just one or two columns to be "covered" (and that get used a lot), it can be very helpful to INCLUDE those into a suitable non-clustered index.

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    Are you sure you'd use this index? Why EmployeeID? You only need DepartmentID in the key columns? You have been quoted here as authoratitive: stackoverflow.com/q/6187904/27535 – gbn May 31 '11 at 13:05
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    Your explanation is good but doesn't actually line up with the use case that you outline. The key column(s) should be on the filter or JOIN keys in the query, and the INCLUDEs need to be the data you are retrieving but not sorting. – JNK Feb 1 '12 at 13:53
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    First of all the index Employee(EmployeeID, DepartmentID) will not be used to filter DepartmentID = 5. Because its order is not matching – AnandPhadke Apr 2 '13 at 11:38

This discussion is missing out on the important point: The question is not if the "non-key-columns" are better to include as index-columns or as included-columns.

The question is how expensive it is to use the include-mechanism to include columns that are not really needed in index? (typically not part of where-clauses, but often included in selects). So your dilemma is always:

  1. Use index on id1, id2 ... idN alone or
  2. Use index on id1, id2 ... idN plus include col1, col2 ... colN

Where: id1, id2 ... idN are columns often used in restrictions and col1, col2 ... colN are columns often selected, but typically not used in restrictions

(The option to include all of these columns as part of the index-key is just always silly (unless they are also used in restrictions) - cause it would always be more expensive to maintain since the index must be updated and sorted even when the "keys" have not changed).

So use option 1 or 2?

Answer: If your table is rarely updated - mostly inserted into/deleted from - then it is relatively inexpensive to use the include-mechanism to include some "hot columns" (that are often used in selects - but not often used on restrictions) since inserts/deletes require the index to be updated/sorted anyway and thus little extra overhead is associated with storing off a few extra columns while already updating the index. The overhead is the extra memory and CPU used to store redundant info on the index.

If the columns you consider to add as included-columns are often updated (without the index-key-columns being updated) - or - if it is so many of them that the index becomes close to a copy of your table - use option 1 I'd suggest! Also if adding certain include-column(s) turns out to make no performance-difference - you might want to skip the idea of adding them:) Verify that they are useful!

The average number of rows per same values in keys (id1, id2 ... idN) can be of some importance as well.

Notice that if a column - that is added as an included-column of index - is used in the restriction: As long as the index as such can be used (based on restriction against index-key-columns) - then SQL Server is matching the column-restriction against the index (leaf-node-values) instead of going the expensive way around the table itself.


Basic index columns are sorted, but included columns are not sorted. This saves resources in maintaining the index, while still making it possible to provide the data in the included columns to cover a query. So, if you want to cover queries, you can put the search criteria to locate rows into the sorted columns of the index, but then "include" additional, unsorted columns with non-search data. It definitely helps with reducing the amount of sorting and fragmentation in index maintenance.


The reasons why (including the data in the leaf level of the index) have been nicely explained. The reason that you give two shakes about this, is that when you run your query, if you don't have the additional columns included (new feature in SQL 2005) the SQL Server has to go to the clustered index to get the additional columns which takes more time, and adds more load to the SQL Server service, the disks, and the memory (buffer cache to be specific) as new data pages are loaded into memory, potentially pushing other more often needed data out of the buffer cache.

  • is there a way to prove that it is actually using less memory? it's what i'd expect too but i'm getting some static about this at work – Asken Nov 16 '12 at 15:06
  • Given that you have to load the page from the heap or clustered index into memory as well as the index page which means that you are putting duplicate data into memory the math becomes pretty simple. As for a way to specifically measure it, no there's not. – mrdenny Nov 16 '12 at 23:50

An additional consideraion that I have not seen in the answers already given, is that included columns can be of data types that are not allowed as index key columns, such as varchar(max).

This allows you to include such columns in a covering index. I recently had to do this to provide a nHibernate generated query, which had a lot of columns in the SELECT, with a useful index.


There is a limit to the total size of all columns inlined into the index definition. That said though, I have never had to create index that wide. To me, the bigger advantage is the fact that you can cover more queries with one index that has included columns as they don't have to be defined in any particular order. Think about is as an index within the index. One example would be the StoreID (where StoreID is low selectivity meaning that each store is associated with a lot of customers) and then customer demographics data (LastName, FirstName, DOB): If you just inline those columns in this order (StoreID, LastName, FirstName, DOB), you can only efficiently search for customers for which you know StoreID and LastName.

On the other hand, defining the index on StoreID and including LastName, FirstName, DOB columns would let you in essence do two seeks- index predicate on StoreID and then seek predicate on any of the included columns. This would let you cover all possible search permutationsas as long as it starts with StoreID.

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