The above language features help make querying data a first class programming concept. We call this overall querying programming model "LINQ" - which stands for .NET Language Integrated Query.
Developers can use LINQ with any data source. They can express efficient query behavior in their programming language of choice, optionally transform/shape data query results into whatever format they want, and then easily manipulate the results. LINQ-enabled languages can provide full type-safety and compile-time checking of query expressions, and development tools can provide full intellisense, debugging, and rich refactoring support when writing LINQ code.
LINQ supports a very rich extensibility model that facilitates the creation of very efficient domain-specific operators for data sources. The "Orcas" version of the .NET Framework ships with built-in libraries that enable LINQ support against Objects, XML, and Databases.
What Is LINQ to SQL?
LINQ to SQL is an O/RM (object relational mapping) implementation that ships in the .NET Framework "Orcas" release, and which allows you to model a relational database using .NET classes. You can then query the database using LINQ, as well as update/insert/delete data from it.
LINQ to SQL fully supports transactions, views, and stored procedures. It also provides an easy way to integrate data validation and business logic rules into your data model.
Using the LINQ to SQL designer I can easily create a representation of the sample "Northwind" database like below:
My LINQ to SQL design-surface above defines four entity classes: Product, Category, Order and OrderDetail. The properties of each class map to the columns of a corresponding table in the database. Each instance of a class entity represents a row within the database table.
The arrows between the four entity classes above represent associations/relationships between the different entities. These are typically modeled using primary-key/foreign-key relationships in the database. The direction of the arrows on the design-surface indicate whether the association is a one-to-one or one-to-many relationship. Strongly-typed properties will be added to the entity classes based on this. For example, the Category class above has a one-to-many relationship with the Product class. This means it will have a "Categories" property which is a collection of Product objects within that category. The Product class then has a "Category" property that points to a Category class instance that represents the Category to which the Product belongs.
The right-hand method pane within the LINQ to SQL design surface above contains a list of stored procedures that interact with our database model. In the sample above I added a single "GetProductsByCategory" SPROC. It takes a categoryID as an input argument, and returns a sequence of Product entities as a result. We'll look at how to call this SPROC in a code sample below.
Understanding the DataContext Class
When you press the "save" button within the LINQ to SQL designer surface, Visual Studio will persist out .NET classes that represent the entities and database relationships that we modeled. For each LINQ to SQL designer file added to our solution, a custom DataContext class will also be generated. This DataContext class is the main conduit by which we'll query entities from the database as well as apply changes. The DataContext class created will have properties that represent each Table we modeled within the database, as well as methods for each Stored Procedure we added.
For example, below is the NorthwindDataContext class that is persisted based on the model we designed above:
