Query Syntax and Method Syntax in LINQ (C#)
Most queries in the introductory Language Integrated Query (LINQ) documentation are written by using the LINQ declarative query syntax. However, the query syntax must be translated into method calls for the .NET common language runtime (CLR) when the code is compiled. These method calls invoke the standard query operators, which have names such as Where, Select, GroupBy, Join, Max, and Average. You can call them directly by using method syntax instead of query syntax.
Query syntax and method syntax are semantically identical, but many people find query syntax simpler and easier to read. Some queries must be expressed as method calls. For example, you must use a method call to express a query that retrieves the number of elements that match a specified condition. You also must use a method call for a query that retrieves the element that has the maximum value in a source sequence. The reference documentation for the standard query operators in the System.Linq namespace generally uses method syntax. Therefore, even when getting started writing LINQ queries, it is useful to be familiar with how to use method syntax in queries and in query expressions themselves.
Standard Query Operator Extension Methods
The following example shows a simple query expression and the semantically equivalent query written as a method-based query.
class QueryVMethodSyntax
{
static void Main()
{
int[] numbers = { 5, 10, 8, 3, 6, 12};
//Query syntax:
IEnumerable<int> numQuery1 =
from num in numbers
where num % 2 == 0
orderby num
select num;
//Method syntax:
IEnumerable<int> numQuery2 = numbers.Where(num => num % 2 == 0).OrderBy(n => n);
foreach (int i in numQuery1)
{
Console.Write(i + " ");
}
Console.WriteLine(System.Environment.NewLine);
foreach (int i in numQuery2)
{
Console.Write(i + " ");
}
// Keep the console open in debug mode.
Console.WriteLine(System.Environment.NewLine);
Console.WriteLine("Press any key to exit");
Console.ReadKey();
}
}
/*
Output:
6 8 10 12
6 8 10 12
*/
The output from the two examples is identical. You can see that the type of the query variable is the same in both forms: IEnumerable<T>.
To understand the method-based query, let's examine it more closely. On the right side of the expression, notice that the where clause is now expressed as an instance method on the numbers object, which as you will recall has a type of IEnumerable<int>. If you are familiar with the generic IEnumerable<T> interface, you know that it does not have a Where method. However, if you invoke the IntelliSense completion list in the Visual Studio IDE, you will see not only a Where method, but many other methods such as Select, SelectMany, Join, and Orderby. These are all the standard query operators.
Although it looks as if IEnumerable<T> has been redefined to include these additional methods, in fact this is not the case. The standard query operators are implemented as a new kind of method called extension methods. Extensions methods "extend" an existing type; they can be called as if they were instance methods on the type. The standard query operators extend IEnumerable<T> and that is why you can write numbers.Where(...).
To get started using LINQ, all that you really have to know about extension methods is how to bring them into scope in your application by using the correct using directives. This is explained additionally in How to: Create a LINQ Project. From your application's point of view, an extension method and a regular instance method are the same.
For more information about extension methods, see Extension Methods (C# Programming Guide). For more information about standard query operators, see Standard Query Operators Overview. Some LINQ providers, such as LINQ to SQL and LINQ to XML, implement their own standard query operators and additional extension methods for other types besides IEnumerable<T>.
Lambda Expressions
In the previous example, notice that the conditional expression (num % 2 == 0) is passed as an in-line argument to the Where method: Where(num => num % 2 == 0). This inline expression is called a lambda expression. It is a convenient way to write code that would otherwise have to be written in more cumbersome form as an anonymous method or a generic delegate or an expression tree. In C# => is the lambda operator, which is read as "goes to". The num on the left of the operator is the input variable which corresponds to num in the query expression. The compiler can infer the type of num because it knows that numbers is a generic IEnumerable<T> type. The body of the lambda is just the same as the expression in query syntax or in any other C# expression or statement; it can include method calls and other complex logic. The "return value" is just the expression result.
To get started using LINQ, you do not have to use lambdas extensively. However, certain queries can only be expressed in method syntax and some of those require lambda expressions. After you become more familiar with lambdas, you will find that they are a powerful and flexible tool in your LINQ toolbox. For more information, see Lambda Expressions (C# Programming Guide).
Composability of Queries
In the previous code example, note that the OrderBy method is invoked by using the dot operator on the call to Where. Where produces a filtered sequence, and then Orderby operates on that sequence by sorting it. Because queries return an IEnumerable, you compose them in method syntax by chaining the method calls together. This is what the compiler does behind the scenes when you write queries by using query syntax. And because a query variable does not store the results of the query, you can modify it or use it as the basis for a new query at any time, even after it has been executed.