Subqueries in SQL Server

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Few elements within a Transact-SQL statement are as versatile as the subquery. A subquery-also referred to as an inner query or inner select-is a SELECT statement embedded within a data manipulation language (DML) statement or nested within another subquery. You can use subqueries in SELECT, INSERT, UPDATE, and DELETE statements wherever expressions are allowed. For instance, you can use a subquery as one of the column expressions in a SELECT list or as a table expression in the FROM clause.

A DML statement that includes a subquery is referred to as the outer query. The following guidelines provide details about how to implement subqueries in your outer queries or in other subqueries:

  • You must enclose a subquery in parenthesis.
  • A subquery must include a SELECT clause and a FROM clause.
  • A subquery can include optional WHERE, GROUP BY, and HAVING clauses.
  • A subquery cannot include COMPUTE or FOR BROWSE clauses.
  • You can include an ORDER BY clause only when a TOP clause is included.
  • You can nest subqueries up to 32 levels.

There are several ways you can categorize subqueries-by the number of results they returns, whether they’re correlated (linked to the outer query), or where they’re used within a DML statement. For the purposes of this article, I take the last approach and explain how subqueries can be implemented in the SELECT, FROM, and WHERE clauses of a SELECT statement. Although you can implement subqueries in other clauses and other statement types, the examples I provide should demonstrate the essential principles of how subqueries can be used in any circumstances. (The examples all return data from the AdventureWorks2008 database on a local instance of SQL Server 2008.)

NOTE: Microsoft documentation states that subqueries perform about the same as statements that are semantically equivalent, such as subqueries and joins. However, if existence must be checked (as will be described later in the article), a join often performs better if the subquery must be processed for each row returned by the outer query.

Adding Subqueries to the SELECT Clause

You can add a subquery to a SELECT clause as a column expression in the SELECT list. The subquery must return a scalar (single) value for each row returned by the outer query. For example, in the following SELECT statement, I use a subquery to define the TotalQuantity column:

Notice I’ve inserted the subquery as the fourth column expression in the SELECT list and named the column TotalQuantity. The subquery itself is enclosed in parentheses and made up of a single SELECT statement. The statement retrieves the total number of items sold for sales order 43659. Because there are multiple line items in this order, I used the SUM aggregate function to add the numbers together and return a single value. The following table shows the result set returned by the outer SELECT statement.

SalesOrderNumber

SubTotal

OrderDate

TotalQuantity

SO43659

24643.9362

2001-07-01 00:00:00.000

26

As the results show, the outer SELECT statement returns a single row from the SalesOrderHeader table for order 43659, and the TotalQuantity column itself returns a value of 26. If you were to run the subquery’s SELECT statement on its own (without running the outer query), you would also receive a value of 26. However, by running the SELECT statement as a subquery within the outer SELECT statement, the total number of items sold is now provided as part of the order information.

You can use a subquery anywhere in a SQL Statement where an expression is allowed. For the next example we’ll use it as part of a CASE statement. In the following example, I use a CASE expression and subquery to check whether line item sales totals in the SalesOrderDetail table equals the sales subtotal listed in the SalesOrderHeader table:

I’ve included the CASE expression as part of the fourth column expression. The CASE expression uses the subquery to total the line item sales in the SalesOrderDetail table for order 43659. Notice that, as in the preceding example, the subquery is enclosed in parentheses and uses the SUM aggregate function to return a single value. I then use an equal (=) operator to compare the subquery’s result to the SubTotal column in the SalesOrderHeader table. If the amounts are equal, the CASE expression returns a value of balanced. It the values are not equal, CASE returns not balanced. The following table shows the results returned by the outer SELECT statement.

SalesOrderNumber

SubTotal

OrderDate

LineTotals

SO43659

24643.9362

2001-07-01 00:00:00.000

not balanced

As you can see, the line item sales total in the SalesOrderDetail table does not match the subtotal in the SalesOrderHeader table, at least not for sale 43659. However, suppose you want to verify all the sales listed in the two tables to see whether the totals balance. To do so, you must modify both the subquery and the outer query in order to create the condition necessary to support a correlated subquery. A correlated subquery, also known as a repeating subquery, is one that depends on the outer query for specific values. This is particularly important if your outer query returns multiple rows.

The best way to understand how correlated subqueries work is to look at an example. In the following SELECT statement, I include a CASE expression as one of the column expressions, as you saw in the preceding example:

As before, the CASE expression includes a subquery that returns the total amount for line item sales. However, notice that the subquery’s WHERE clause is different from the previous example. Instead of specifying an order ID, the WHERE clause references the SalesOrderID column from the outer query. I do this by using table aliases to distinguish the two columns-h for SalesOrderHeader and d for SalesOrderDetail-and then specifying that the column values must be equal for the WHERE condition to evaluate to true. That means that, for each row in the SalesOrderHeader table returned by the outer query, the SalesOrderID value associated with that row is plugged into the subquery and compared with the SalesOrderID value of the SalesOrderDetail table. As a result, the subquery is executed for each row returned by the outer query.

The value returned by the subquery is then compared to the SubTotal column of the SalesOrderHeader table and a value for the LineTotals column is provided, a process repeated for each row. The following table provides a sample of the data returned by the outer query.

SalesOrderNumber

SubTotal

OrderDate

LineTotals

SO61168

1170.48

2003-12-31 00:00:00.000

balanced

SO61169

619.46

2003-12-31 00:00:00.000

balanced

SO61170

607.96

2003-12-31 00:00:00.000

balanced

SO61171

553.97

2003-12-31 00:00:00.000

balanced

SO61172

2398.05

2003-12-31 00:00:00.000

balanced

SO61173

34851.8445

2004-01-01 00:00:00.000

not balanced

SO61174

8261.4247

2004-01-01 00:00:00.000

not balanced

SO61175

30966.9005

2004-01-01 00:00:00.000

not balanced

SO61176

1570.725

2004-01-01 00:00:00.000

not balanced

SO61177

25599.8392

2004-01-01 00:00:00.000

not balanced

SO61178

3227.0112

2004-01-01 00:00:00.000

not balanced

SO61179

47199.0054

2004-01-01 00:00:00.000

not balanced

SO61180

4208.8078

2004-01-01 00:00:00.000

not balanced

SO61181

36564.9023

2004-01-01 00:00:00.000

not balanced

SO61182

63162.5722

2004-01-01 00:00:00.000

not balanced

SO61183

35.0935

2004-01-01 00:00:00.000

not balanced

SO61184

113451.8266

2004-01-01 00:00:00.000

not balanced

SO61185

554.0328

2004-01-01 00:00:00.000

not balanced

SO61186

39441.4489

2004-01-01 00:00:00.000

not balanced

SO61187

65.988

2004-01-01 00:00:00.000

balanced

SO61188

58992.9256

2004-01-01 00:00:00.000

not balanced

As you can see, some of the totals balance out, and others do not. Again, the important thing to keep in mind with correlated subqueries is that the subquery is executed for each row returned by the outer query. The correlated subquery then uses a value supplied by the outer query to return its results. For more details about correlated subqueries, see the topic “Correlated Subqueries” in SQL Server Books Online.

Adding Subqueries to the FROM Clause

The subquery examples in the previous section each return a single value, which they must do in order to be used in the SELECT clause. However, not all subquery results are limited in this way. A subquery can also be used in the FROM clause to return multiple rows and columns. The results returned by such a subquery are referred to as a derived table. A derived table is useful when you want to work with a subset of data from one or more tables without needing to create a view or temporary table. For instance, in the following example, I create a subquery that retrieves product subcategory information from the ProductSubcategory table, but only for those products that include the word “bike” in their name:

The first thing to notice is that the subquery returns a derived table that includes two columns and multiple rows. Because the subquery returns a table, I can join that table, which I’ve named ps, to the results from the Product table (p). As the join demonstrates, you treat a subquery used in the FROM clause just as you would treat any table. I could have just as easily created a view or temporary table-or even added a regular table to the database-that accesses the same data as that available through the subquery.

I defined the join based on the subcategory ID in the derived table and Product table. I was then able to include columns from both these tables in the SELECT list, as I would any type of join. The following table shows a subset of the results returned by the outer query.

ProductID

PeoductName

SubcategoryID

SubcategoryName

786

Mountain-300 Black, 40

1

Mountain Bikes

787

Mountain-300 Black, 44

1

Mountain Bikes

788

Mountain-300 Black, 48

1

Mountain Bikes

789

Road-250 Red, 44

2

Road Bikes

790

Road-250 Red, 48

2

Road Bikes

791

Road-250 Red, 52

2

Road Bikes

792

Road-250 Red, 58

2

Road Bikes

793

Road-250 Black, 44

2

Road Bikes

794

Road-250 Black, 48

2

Road Bikes

795

Road-250 Black, 52

2

Road Bikes

796

Road-250 Black, 58

2

Road Bikes

797

Road-550-W Yellow, 38

2

Road Bikes

798

Road-550-W Yellow, 40

2

Road Bikes

799

Road-550-W Yellow, 42

2

Road Bikes

800

Road-550-W Yellow, 44

2

Road Bikes

801

Road-550-W Yellow, 48

2

Road Bikes

953

Touring-2000 Blue, 60

3

Touring Bikes

954

Touring-1000 Yellow, 46

3

Touring Bikes

955

Touring-1000 Yellow, 50

3

Touring Bikes

As you can see, the results include the subcategory names, which are taken from the derived table returned by the subquery. Because I was able to join the Product table to the derived table, I was able to match the subcategory names to the product names in the outer query’s result set.

Adding Subqueries to the WHERE Clause

Another common way of implementing subqueries in a DML statement is to use them to help define conditions in the WHERE clause. For instance, you can use comparison operators to compare a column’s value to a value returned by the subquery. In the following example, I use the equal (=) operator to compare the BusinessEntityID value in the Person table to the value returned by a subquery:

The subquery retrieves the BusinessEntityID value from the Employee table for the employee whose national ID is 895209680. The BusinessEntityID value from the subquery is then compared to the BusinessEntityID value in the Person table. If the two values are equal, the row is returned, as shown in the following results.

In the subquery, I use the AVG aggregate function to find the average sales quota figure. This way, the subquery returns only one value. I can then compare that value to the SalesQuota column. If the SalesQuota figure is greater than the average, the WHERE expression evaluates to true, and the row is returned by the outer query. Otherwise, the expression evaluates to false and the row is not returned. As the following table shows, only three rows have a SalesQuota value greater than the average.

BusinessEntityID

FirstName

LastName

SalesQuota

275

Michael

Blythe

300000.00

279

Tsvi

Reiter

300000.00

284

Tete

Mensa-Annan

300000.00

At times, you might want to compare your column to a list of values, rather than a single value, in which case you can use one of the following keywords to modify the comparison modifier:

  • ALL: The column value is compared to all values returned by the subquery.
  • ANY: The column value is compared to the one most applicable distinct value.
  • SOME: The ISO equivalent to ANY.

The best way to understand how these modifiers work is to see them in action. In the following example, I use the ANY modifier along with the greater than (>) operator to compare the SalesQuota column to the list of SalesQuota values returned by the subquery:

In this case, the subquery returns a list of values, rather than one value. I can return a list because I’m using the ANY modifier. As a result, the SalesQuota value for each row returned must be greater than any of the values returned by the subquery. In other words, as long as the SalesQuota value exceeds any one value returned by the subquery, that row is returned. As the following results indicate, only three rows in the SalesPerson table have SalesQuota values that exceed at least one of the values returned by the subquery.

BusinessEntityID

FirstName

LastName

SalesQuota

275

Michael

Blythe

300000.00

279

Tsvi

Reiter

300000.00

284

Tete

Mensa-Annan

300000.00

The next example is identical to the preceding one, except that I use the ALL modifier to qualify the comparison operator:

Because I’ve used the ALL modifier, each row returned must have a SalesQuota value that exceeds all the values returned by the subquery. In other words, the SalesQuota value must exceed the highest value returned by the subquery. As it turns out, no row has a SalesQuota value that exceeds all the values returned by the subquery, so the statement now returns no rows.

Another operator that lets you work with a subquery that returns a list is the IN operator. The column value is compared to the list, and the WHERE expression evaluates to true if any of the subquery values matches the column value. For example, the following SELECT statement includes a subquery that returns a list of IDs for sales representatives:

The BusinessEntityID value from the outer query is compared to the list of ID values returned by the subquery. If the BusinessEntityID value matches one of the values in the subquery list, the row is included in the outer query’s results, as shown in the following results:

BusinessEntityID

FirstName

LastName

275

Michael

Blythe

276

Linda

Mitchell

277

Jillian

Carson

278

Garrett

Vargas

279

Tsvi

Reiter

280

Pamela

Ansman-Wolfe

281

Shu

Ito

282

José

Saraiva

283

David

Campbell

284

Tete

Mensa-Annan

286

Lynn

Tsoflias

288

Rachel

Valdez

289

Jae

Pak

290

Ranjit

Varkey Chudukatil

If you want to return only those rows whose BusinessEntityID value does not match any values in the list returned by the subquery, you can instead use the NOT IN operator, as in the following example:

This statement is exactly the same as the preceding example except for the use of the NOT IN operator, but the results are quite different. Rather than returning 14 rows, one for each sales representative, the statement now returns nearly 20,000 rows, one for each person who is not a sales representative.

One other method you can use when including a subquery in your WHERE clause is to check for existence. In this case, you use the EXIST keyword to verify whether the subquery returns a row that matches your search criteria. The subquery doesn’t produce any data but instead returns a value of true or false, depending on whether the row exists. For example, in the following SELECT statement, I use a correlated subquery to check the name of each product’s subcategory to determine whether that name is Mountain Bikes:

For each row returned by the outer query, the existence of a row returned by the correlated subquery is checked. If a row is returned by the subquery, the existence test evaluates to true, and the outer query’s row is included in the result set. The following table shows a partial list of the results returned by the outer query, after checking for existence.

ProductID

ProductName

771

Mountain-100 Silver, 38

772

Mountain-100 Silver, 42

773

Mountain-100 Silver, 44

774

Mountain-100 Silver, 48

775

Mountain-100 Black, 38

776

Mountain-100 Black, 42

777

Mountain-100 Black, 44

778

Mountain-100 Black, 48

779

Mountain-200 Silver, 38

780

Mountain-200 Silver, 42

781

Mountain-200 Silver, 46

782

Mountain-200 Black, 38

783

Mountain-200 Black, 42

784

Mountain-200 Black, 46

785

Mountain-300 Black, 38

786

Mountain-300 Black, 40

For each row included in the results, the existence test evaluated to true. In other words, the returned rows are part of the Mountain Bikes subcategory.

You can also return results for rows whose existence test returns false by using the NOT EXIST operator, as shown in the following example:

Now the statement returns only those rows that are not part of the Mountain Bikes subcategory. Any row whose existence test returns a true is not included in the results.

Conclusion

As the examples in the article demonstrate, subqueries are a flexible and versatile tool. You can define them wherever an expression is allowed in a SELECT, INSERT, UPDATE, or DELETE statement. You can then use the data returned by the subquery in your outer query to make those statements more powerful and ultimately more useful to your various applications. For more information about subqueries, see the topic “Subquery Fundamentals” as well as other topics that address how to use subqueries in SQL Server Books Online.

1297-SelectClause.png

The Select clause, showing how scalar subqueries can be used within them (A full-size PDF version is available in the downloads below.

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Robert Sheldon

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Robert is a freelance technology writer based in the Pacific Northwest. He’s worked as a technical consultant and has written hundreds of articles about technology for both print and online publications, with topics ranging from predictive analytics to 5D storage to the dark web. He’s also contributed to over a dozen books on technology, developed courseware for Microsoft’s training program, and served as a developmental editor on Microsoft certification exams. When not writing about technology, he’s working on a novel or venturing out into the spectacular Northwest woods.