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LINQ - Quick Guide
  • 时间:2024-12-22

LINQ - Quick Guide


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LINQ - Overview

Developers across the world have always encountered problems in querying data because of the lack of a defined path and need to master a multiple of technologies pke SQL, Web Services, XQuery, etc.

Introduced in Visual Studio 2008 and designed by Anders Hejlsberg, LINQ (Language Integrated Query) allows writing queries even without the knowledge of query languages pke SQL, XML etc. LINQ queries can be written for spanerse data types.

Example of a LINQ query

C#

using System;
using System.Linq;

class Program {
   static void Main() {
   
      string[] words = {"hello", "wonderful", "LINQ", "beautiful", "world"};
		
      //Get only short words
      var shortWords = from word in words where word.Length <= 5 select word;
	    
      //Print each word out
      foreach (var word in shortWords) {
         Console.WriteLine(word);
      }	 
		
      Console.ReadLine();
   }
}

VB

Module Module1
   Sub Main()
      Dim words As String() = {"hello", "wonderful", "LINQ", "beautiful", "world"}
     
        Get only short words
      Dim shortWords = From word In words _ Where word.Length <= 5 _ Select word
     
        Print each word out.
	  
      For Each word In shortWords
         Console.WriteLine(word)
      Next
	  
      Console.ReadLine()
   End Sub
End Module	

When the above code of C# or VB is compiled and executed, it produces the following result −

hello 
LINQ 
world

Syntax of LINQ

There are two syntaxes of LINQ. These are the following ones.

Lamda (Method) Syntax

var longWords = words.Where( w ⇒ w.length > 10);
Dim longWords = words.Where(Function(w) w.length > 10)

Query (Comprehension) Syntax

var longwords = from w in words where w.length > 10;
Dim longwords = from w in words where w.length > 10

Types of LINQ

The types of LINQ are mentioned below in brief.

    LINQ to Objects

    LINQ to XML(XLINQ)

    LINQ to DataSet

    LINQ to SQL (DLINQ)

    LINQ to Entities

Apart from the above, there is also a LINQ type named PLINQ which is Microsoft’s parallel LINQ.

LINQ Architecture in .NET

LINQ has a 3-layered architecture in which the uppermost layer consists of the language extensions and the bottom layer consists of data sources that are typically objects implementing IEnumerable <T> or IQueryable <T> generic interfaces. The architecture is shown below.

LINQ Architecture

Query Expressions

Query expression is nothing but a LINQ query, expressed in a form similar to that of SQL with query operators pke Select, Where and OrderBy. Query expressions usually start with the keyword "From".

To access standard LINQ query operators, the namespace System.Query should be imported by default. These expressions are written within a declarative query syntax which was C# 3.0.

Below is an example to show a complete query operation which consists of data source creation, query expression definition and query execution.

C#

using System;
using System.Collections.Generic;
using System.Linq;
using System.Text;

namespace Operators {
   class LINQQueryExpressions {
      static void Main() {
      
         // Specify the data source.
         int[] scores = new int[] { 97, 92, 81, 60 };

         // Define the query expression.
         IEnumerable<int> scoreQuery = from score in scores where score > 80 select score;

         // Execute the query.
		 
         foreach (int i in scoreQuery) {
            Console.Write(i + " ");
         }
		 
         Console.ReadLine();
      }
   }
}

When the above code is compiled and executed, it produces the following result −

97 92 81

Extension Methods

Introduced with .NET 3.5, Extension methods are declared in static classes only and allow inclusion of custom methods to objects to perform some precise query operations to extend a class without being an actual member of that class. These can be overloaded also.

In a nutshell, extension methods are used to translate query expressions into traditional method calls (object-oriented).

Difference between LINQ and Stored Procedure

There is an array of differences existing between LINQ and Stored procedures. These differences are mentioned below.

    Stored procedures are much faster than a LINQ query as they follow an expected execution plan.

    It is easy to avoid run-time errors while executing a LINQ query than in comparison to a stored procedure as the former has Visual Studio’s Intelpsense support as well as full-type checking during compile-time.

    LINQ allows debugging by making use of .NET debugger which is not in case of stored procedures.

    LINQ offers support for multiple databases in contrast to stored procedures, where it is essential to re-write the code for spanerse types of databases.

    Deployment of LINQ based solution is easy and simple in comparison to deployment of a set of stored procedures.

Need For LINQ

Prior to LINQ, it was essential to learn C#, SQL, and various APIs that bind together the both to form a complete apppcation. Since, these data sources and programming languages face an impedance mismatch; a need of short coding is felt.

Below is an example of how many spanerse techniques were used by the developers while querying a data before the advent of LINQ.

SqlConnection sqlConnection = new SqlConnection(connectString);
SqlConnection.Open();

System.Data.SqlCpent.SqlCommand sqlCommand = new SqlCommand();
sqlCommand.Connection = sqlConnection;

sqlCommand.CommandText = "Select * from Customer";
return sqlCommand.ExecuteReader (CommandBehavior.CloseConnection)  

Interestingly, out of the featured code pnes, query gets defined only by the last two. Using LINQ, the same data query can be written in a readable color-coded form pke the following one mentioned below that too in a very less time.

Northwind db = new Northwind(@"C:DataNorthwnd.mdf");
var query = from c in db.Customers select c;

Advantages of LINQ

LINQ offers a host of advantages and among them the foremost is its powerful expressiveness which enables developers to express declaratively. Some of the other advantages of LINQ are given below.

    LINQ offers syntax highpghting that proves helpful to find out mistakes during design time.

    LINQ offers IntelpSense which means writing more accurate queries easily.

    Writing codes is quite faster in LINQ and thus development time also gets reduced significantly.

    LINQ makes easy debugging due to its integration in the C# language.

    Viewing relationship between two tables is easy with LINQ due to its hierarchical feature and this enables composing queries joining multiple tables in less time.

    LINQ allows usage of a single LINQ syntax while querying many spanerse data sources and this is mainly because of its unitive foundation.

    LINQ is extensible that means it is possible to use knowledge of LINQ to querying new data source types.

    LINQ offers the facipty of joining several data sources in a single query as well as breaking complex problems into a set of short queries easy to debug.

    LINQ offers easy transformation for conversion of one data type to another pke transforming SQL data to XML data.

LINQ - Environment Setup

Before starting with LINQ programs, it is best to first understand the nuances of setting up a LINQ environment. LINQ needs a .NET framework, a revolutionary platform to have a spanerse kind of apppcations. A LINQ query can be written either in C# or Visual Basic conveniently.

Microsoft offers tools for both of these languages i.e. C# and Visual Basic by means of Visual Studio. Our examples are all compiled and written in Visual Studio 2010. However, Visual Basic 2013 edition is also available for use. It is the latest version and has many similarities with Visual Studio 2012.

Getting Visual Studio 2010 Installed on Windows 7

Visual Studio can be installed either from an installation media pke a DVD. Administrator credentials are required to install Visual Basic 2010 on your system successfully. It is vital to disconnect all removable USB from the system prior to installation otherwise the installation may get failed. Some of the hardware requirements essential to have for installation are the following ones.

Hardware Requirements

    1.6 GHz or more

    1 GB RAM

    3 GB(Available hard-disk space)

    5400 RPM hard-disk drive

    DirectX 9 compatible video card

    DVD-ROM drive

Installation Steps

Step 1 − First after inserting the DVD with Visual Studio 2010 Package, cpck on Install or run program from your media appearing in a pop-up box on the screen.

Step 2 − Now set up for Visual Studio will appear on the screen. Choose Install Microsoft Visual Studio 2010.

LINQ Environment

Step 3 − As soon as you will cpck, it the process will get initiated and a set up window will appear on your screen. After completion of loading of the installation components which will take some time, cpck on Next button to move to the next step.

LINQ Environment

Step 4 − This is the last step of installation and a start page will appear in which simply choose "I have read and accept the pcense terms" and cpck on Next button.

LINQ Environment

Step 5 − Now select features to install from the options page appearing on your screen. You can either choose Full or Custom option. If you have less disk space than required shown in the disk space requirements, then go for Custom.

LINQ Environment

Step 6 − When you choose Custom option, the following window will appear. Select the features that you want to install and cpck Update or else go to step 7. However, it is recommended not to go with the custom option as in future, you may need the features you have chosen to not have.

LINQ Environment

Step 7 − Soon a pop up window will be shown and the installation will start which may take a long time. Remember, this is for instalpng all the components.

LINQ Environment

Step 8 − Finally, you will be able to view a message in a window that the installation has been completed successfully. Cpck Finish.

LINQ Environment

Writing C# Program using LINQ in Visual Studio 2010

    Start Visual Studio 2010 Ultimate edition and choose File followed by New Project from the menu.

    A new project dialog box will appear on your screen.

    Now choose Visual C# as a category under installed templates and next choose Console Apppcation template as shown in figure below.

LINQ Environment

    Give a name to your project in the bottom name box and press OK.

    The new project will appear in the Solution Explorer in the right-hand side of a new dialog box on your screen.

LINQ Environment

    Now choose Program.cs from the Solution Explorer and you can view the code in the editor window which starts with ‘using System’.

    Here you can start to code your following C# program.

using System;
using System.Collections.Generic;
using System.Linq;
using System.Text;
			
namespace HelloWorld {
   class Program {
      static void Main(string[] args) {
      
         Console.WriteLine("Hello World")
         Console.ReadKey();
      } 		
   }
}

    Press F5 key and run your project. It is highly recommended to save the project by choosing FileSave All before running the project.

Writing VB Program using LINQ in Visual Studio 2010

    Start Visual Studio 2010 Ultimate edition and choose File followed by New Project from the menu.

    A new project dialog box will appear on your screen.

    Now chose Visual Basic as a category under installed templates and next choose Console Apppcation template.

    Give a name to your project in the bottom name box and press OK.

    You will get a screen with Module1.vb. Start writing your VB code here using LINQ.

Module Module1

   Sub Main()
      Console.WriteLine("Hello World")
      Console.ReadLine()
   End Sub
   
End Module   

    Press F5 key and run your project. It is highly recommended to save the project by choosing FileSave All before running the project.

When the above code of C# or VB is cimpiled and run, it produces the following result −

Hello World

LINQ - Query Operators

A set of extension methods forming a query pattern is known as LINQ Standard Query Operators. As building blocks of LINQ query expressions, these operators offer a range of query capabipties pke filtering, sorting, projection, aggregation, etc.

LINQ standard query operators can be categorized into the following ones on the basis of their functionapty.

    Filtering Operators

    Join Operators

    Projection Operations

    Sorting Operators

    Grouping Operators

    Conversions

    Concatenation

    Aggregation

    Quantifier Operations

    Partition Operations

    Generation Operations

    Set Operations

    Equapty

    Element Operators

Filtering Operators

Filtering is an operation to restrict the result set such that it has only selected elements satisfying a particular condition.

Show Examples

Operator Description C# Query Expression Syntax VB Query Expression Syntax
where Filter values based on a predicate function where Where
OfType Filter values based on their abipty to be as a specified type Not Apppcable Not Apppcable

Join Operators

Joining refers to an operation in which data sources with difficult to follow relationships with each other in a direct way are targeted.

Show Examples

Operator Description C# Query Expression Syntax VB Query Expression Syntax
Join The operator join two sequences on basis of matching keys join … in … on … equals … From x In …, y In … Where x.a = y.a
GroupJoin Join two sequences and group the matching elements join … in … on … equals … into … Group Join … In … On …

Projection Operations

Projection is an operation in which an object is transformed into an altogether new form with only specific properties.

Show Examples

Operator Description C# Query Expression Syntax VB Query Expression Syntax
Select The operator projects values on basis of a transform function select Select
SelectMany The operator project the sequences of values which are based on a transform function as well as flattens them into a single sequence Use multiple from clauses Use multiple From clauses

Sorting Operators

A sorting operation allows ordering the elements of a sequence on basis of a single or more attributes.

Show Examples

Operator Description C# Query Expression Syntax VB Query Expression Syntax
OrderBy The operator sort values in an ascending order orderby Order By
OrderByDescending The operator sort values in a descending order orderby ... descending Order By ... Descending
ThenBy Executes a secondary sorting in an ascending order orderby …, … Order By …, …
ThenByDescending Executes a secondary sorting in a descending order orderby …, … descending Order By …, … Descending
Reverse Performs a reversal of the order of the elements in a collection Not Apppcable Not Apppcable

Grouping Operators

The operators put data into some groups based on a common shared attribute.

Show Examples

Operator Description C# Query Expression Syntax VB Query Expression Syntax
GroupBy Organize a sequence of items in groups and return them as an IEnumerable collection of type IGrouping<key, element> group … by -or- group … by … into … Group … By … Into …
ToLookup Execute a grouping operation in which a sequence of key pairs are returned Not Apppcable Not Apppcable

Conversions

The operators change the type of input objects and are used in a spanerse range of apppcations.

Show Examples

Operator Description C# Query Expression Syntax VB Query Expression Syntax
AsEnumerable Returns the input typed as IEnumerable<T> Not Apppcable Not Apppcable
AsQueryable A (generic) IEnumerable is converted to a (generic) IQueryable Not Apppcable Not Apppcable
Cast Performs casting of elements of a collection to a specified type Use an exppcitly typed range variable. Eg:from string str in words From … As …
OfType Filters values on basis of their , depending on their capabipty to be cast to a particular type Not Apppcable Not Apppcable
ToArray Forces query execution and does conversion of a collection to an array Not Apppcable Not Apppcable
ToDictionary On basis of a key selector function set elements into a Dictionary<TKey, TValue> and forces execution of a LINQ query Not Apppcable Not Apppcable
ToList Forces execution of a query by converting a collection to a List<T> Not Apppcable Not Apppcable
ToLookup Forces execution of a query and put elements into a Lookup<TKey, TElement> on basis of a key selector function Not Apppcable Not Apppcable

Concatenation

Performs concatenation of two sequences and is quite similar to the Union operator in terms of its operation except of the fact that this does not remove duppcates.

Show Examples

Operator Description C# Query Expression Syntax VB Query Expression Syntax
Concat Two sequences are concatenated for the formation of a single one sequence. Not Apppcable Not Apppcable

Aggregation

Performs any type of desired aggregation and allows creating custom aggregations in LINQ.

Show Examples

Operator Description C# Query Expression Syntax VB Query Expression Syntax
Aggregate Operates on the values of a collection to perform custom aggregation operation Not Apppcable Not Apppcable
Average Average value of a collection of values is calculated Not Apppcable Aggregate … In … Into Average()
Count Counts the elements satisfying a predicate function within collection Not Apppcable Aggregate … In … Into Count()
LonCount Counts the elements satisfying a predicate function within a huge collection Not Apppcable Aggregate … In … Into LongCount()
Max Find out the maximum value within a collection Not Apppcable Aggregate … In … Into Max()
Min Find out the minimum value existing within a collection Not Apppcable Aggregate … In … Into Min()
Sum Find out the sum of a values within a collection Not Apppcable Aggregate … In … Into Sum()

Quantifier Operations

These operators return a Boolean value i.e. True or False when some or all elements within a sequence satisfy a specific condition.

Show Examples

Operator Description C# Query Expression Syntax VB Query Expression Syntax
All Returns a value ‘True’ if all elements of a sequence satisfy a predicate condition Not Apppcable Aggregate … In … Into All(…)
Any Determines by searching a sequence that whether any element of the same satisfy a specified condition Not Apppcable Aggregate … In … Into Any()
Contains Returns a ‘True’ value if finds that a specific element is there in a sequence if the sequence doe not contains that specific element , ‘false’ value is returned Not Apppcable Not Apppcable

Partition Operators

Divide an input sequence into two separate sections without rearranging the elements of the sequence and then returning one of them.

Show Examples

Operator Description C# Query Expression Syntax VB Query Expression Syntax
Skip Skips some specified number of elements within a sequence and returns the remaining ones Not Apppcable Skip
SkipWhile Same as that of Skip with the only exception that number of elements to skip are specified by a Boolean condition Not Apppcable Skip While
Take Take a specified number of elements from a sequence and skip the remaining ones Not Apppcable Take
TakeWhile Same as that of Take except the fact that number of elements to take are specified by a Boolean condition Not Apppcable Take While

Generation Operations

A new sequence of values is created by generational operators.

Show Examples

Operator Description C# Query Expression Syntax VB Query Expression Syntax
DefaultIfEmpty When appped to an empty sequence, generate a default element within a sequence Not Apppcable Not Apppcable
Empty Returns an empty sequence of values and is the most simplest generational operator Not Apppcable Not Apppcable
Range Generates a collection having a sequence of integers or numbers Not Apppcable Not Apppcable
Repeat Generates a sequence containing repeated values of a specific length Not Apppcable Not Apppcable

Set Operations

There are four operators for the set operations, each yielding a result based on different criteria.

Show Examples

Operator Description C# Query Expression Syntax VB Query Expression Syntax
Distinct Results a pst of unique values from a collection by filtering duppcate data if any Not Apppcable Distinct
Except Compares the values of two collections and return the ones from one collection who are not in the other collection Not Apppcable Not Apppcable
Intersect Returns the set of values found t be identical in two separate collections Not Apppcable Not Apppcable
Union Combines content of two different collections into a single pst that too without any duppcate content Not Apppcable Not Apppcable

Equapty

Compares two sentences (enumerable ) and determine are they an exact match or not.

Show Examples

Operator Description C# Query Expression Syntax VB Query Expression Syntax
SequenceEqual Results a Boolean value if two sequences are found to be identical to each other Not Apppcable Not Apppcable

Element Operators

Except the DefaultIfEmpty, all the rest eight standard query element operators return a single element from a collection.

Show Examples

Operator Description C# Query Expression Syntax VB Query Expression Syntax
ElementAt Returns an element present within a specific index in a collection Not Apppcable Not Apppcable
ElementAtOrDefault Same as ElementAt except of the fact that it also returns a default value in case the specific index is out of range Not Apppcable Not Apppcable
First Retrieves the first element within a collection or the first element satisfying a specific condition Not Apppcable Not Apppcable
FirstOrDefault Same as First except the fact that it also returns a default value in case there is no existence of such elements Not Apppcable Not Apppcable
Last Retrieves the last element present in a collection or the last element satisfying a specific condition Not Apppcable Not Apppcable
LastOrDefault Same as Last except the fact that it also returns a default value in case there is no existence of any such element Not Apppcable Not Apppcable
Single Returns the lone element of a collection or the lone element that satisfy a certain condition Not Apppcable Not Apppcable
SingleOrDefault Same as Single except that it also returns a default value if there is no existence of any such lone element Not Apppcable Not Apppcable
DefaultIfEmpty Returns a default value if the collection or pst is empty or null Not Apppcable Not Apppcable

LINQ - SQL

LINQ to SQL offers an infrastructure (run-time) for the management of relational data as objects. It is a component of version 3.5 of the .NET Framework and ably does the translation of language-integrated queries of the object model into SQL. These queries are then sent to the database for the purpose of execution. After obtaining the results from the database, LINQ to SQL again translates them to objects.

Introduction of LINQ To SQL

For most ASP.NET developers, LINQ to SQL (also known as DLINQ) is an electrifying part of Language Integrated Query as this allows querying data in SQL server database by using usual LINQ expressions. It also allows to update, delete, and insert data, but the only drawback from which it suffers is its pmitation to the SQL server database. However, there are many benefits of LINQ to SQL over ADO.NET pke reduced complexity, few pnes of coding and many more.

Below is a diagram showing the execution architecture of LINQ to SQL.

LINQ SQL Architecture

How to Use LINQ to SQL?

Step 1 − Make a new “Data Connection” with database server. View &arrar; Server Explorer &arrar; Data Connections &arrar; Add Connection

LINQ to SQL

Step 2 − Add LINQ To SQL class file

LINQ to SQL

Step 3 − Select tables from database and drag and drop into the new LINQ to SQL class file.

LINQ to SQL

Step 4 − Added tables to class file.

LINQ to SQL

Querying with LINQ to SQL

The rules for executing a query with LINQ to SQL is similar to that of a standard LINQ query i.e. query is executed either deferred or immediate. There are various components that play a role in execution of a query with LINQ to SQL and these are the following ones.

    LINQ to SQL API − requests query execution on behalf of an apppcation and sent it to LINQ to SQL Provider.

    LINQ to SQL Provider − converts query to Transact SQL(T-SQL) and sends the new query to the ADO Provider for execution.

    ADO Provider − After execution of the query, send the results in the form of a DataReader to LINQ to SQL Provider which in turn converts it into a form of user object.

It should be noted that before executing a LINQ to SQL query, it is vital to connect to the data source via DataContext class.

Insert, Update and Delete using LINQ To SQL

Add OR Insert

C#

using System;
using System.Linq;

namespace LINQtoSQL {
   class LinqToSQLCRUD {
      static void Main(string[] args) {
      
         string connectString = System.Configuration.ConfigurationManager.ConnectionStrings["LinqToSQLDBConnectionString"].ToString();

         LinqToSQLDataContext db = new LinqToSQLDataContext(connectString);           

         //Create new Employee
		 
         Employee newEmployee = new Employee();
         newEmployee.Name = "Michael";
         newEmployee.Email = "yourname@companyname.com";
         newEmployee.ContactNo = "343434343";
         newEmployee.DepartmentId = 3;
         newEmployee.Address = "Michael - USA";

         //Add new Employee to database
         db.Employees.InsertOnSubmit(newEmployee);

         //Save changes to Database.
         db.SubmitChanges();

         //Get new Inserted Employee            
         Employee insertedEmployee = db.Employees.FirstOrDefault(e ⇒e.Name.Equals("Michael"));

         Console.WriteLine("Employee Id = {0} , Name = {1}, Email = {2}, ContactNo = {3}, Address = {4}",
                          insertedEmployee.EmployeeId, insertedEmployee.Name, insertedEmployee.Email, 
                          insertedEmployee.ContactNo, insertedEmployee.Address);

         Console.WriteLine("
Press any key to continue.");
         Console.ReadKey();
      }
   }
}

VB

Module Module1

   Sub Main()
   
      Dim connectString As String = System.Configuration.ConfigurationManager.ConnectionStrings("LinqToSQLDBConnectionString").ToString()

      Dim db As New LinqToSQLDataContext(connectString)

      Dim newEmployee As New Employee()
	  
      newEmployee.Name = "Michael"
      newEmployee.Email = "yourname@companyname.com"
      newEmployee.ContactNo = "343434343"
      newEmployee.DepartmentId = 3
      newEmployee.Address = "Michael - USA"
     
      db.Employees.InsertOnSubmit(newEmployee)
     
      db.SubmitChanges()
     
      Dim insertedEmployee As Employee = db.Employees.FirstOrDefault(Function(e) e.Name.Equals("Michael"))

      Console.WriteLine("Employee Id = {0} , Name = {1}, Email = {2}, ContactNo = {3}, 
         Address = {4}", insertedEmployee.EmployeeId, insertedEmployee.Name,
         insertedEmployee.Email, insertedEmployee.ContactNo, insertedEmployee.Address)

      Console.WriteLine(vbLf & "Press any key to continue.")
      Console.ReadKey()
	 
   End Sub
  
End Module

When the above code of C# or VB is compiled and run, it produces the following result −

Emplyee ID = 4, Name = Michael, Email = yourname@companyname.com, ContactNo = 
343434343, Address = Michael - USA

Press any key to continue.

Update

C#

using System;
using System.Linq;

namespace LINQtoSQL {
   class LinqToSQLCRUD {
      static void Main(string[] args) {
      
         string connectString = System.Configuration.ConfigurationManager.ConnectionStrings["LinqToSQLDBConnectionString"].ToString();

         LinqToSQLDataContext db = new LinqToSQLDataContext(connectString);

         //Get Employee for update
         Employee employee = db.Employees.FirstOrDefault(e =>e.Name.Equals("Michael"));

         employee.Name = "George Michael";
         employee.Email = "yourname@companyname.com";
         employee.ContactNo = "99999999";
         employee.DepartmentId = 2;
         employee.Address = "Michael George - UK";

         //Save changes to Database.
         db.SubmitChanges();

         //Get Updated Employee            
         Employee updatedEmployee = db.Employees.FirstOrDefault(e ⇒e.Name.Equals("George Michael"));

         Console.WriteLine("Employee Id = {0} , Name = {1}, Email = {2}, ContactNo = {3}, Address = {4}",
                          updatedEmployee.EmployeeId, updatedEmployee.Name, updatedEmployee.Email, 
                          updatedEmployee.ContactNo, updatedEmployee.Address);

         Console.WriteLine("
Press any key to continue.");
         Console.ReadKey();
      }
   }
}

VB

Module Module1

   Sub Main()
  
      Dim connectString As String = System.Configuration.ConfigurationManager.ConnectionStrings("LinqToSQLDBConnectionString").ToString()

      Dim db As New LinqToSQLDataContext(connectString)

      Dim employee As Employee = db.Employees.FirstOrDefault(Function(e) e.Name.Equals("Michael"))

      employee.Name = "George Michael"
      employee.Email = "yourname@companyname.com"
      employee.ContactNo = "99999999"
      employee.DepartmentId = 2
      employee.Address = "Michael George - UK"

      db.SubmitChanges()
          
      Dim updatedEmployee As Employee = db.Employees.FirstOrDefault(Function(e) e.Name.Equals("George Michael"))

      Console.WriteLine("Employee Id = {0} , Name = {1}, Email = {2}, ContactNo = {3},
         Address = {4}", updatedEmployee.EmployeeId, updatedEmployee.Name, 
         updatedEmployee.Email, updatedEmployee.ContactNo, updatedEmployee.Address)

      Console.WriteLine(vbLf & "Press any key to continue.")
      Console.ReadKey()
	  
   End Sub
   
End Module

When the above code of C# or Vb is compiled and run, it produces the following result −

Emplyee ID = 4, Name = George Michael, Email = yourname@companyname.com, ContactNo = 
999999999, Address = Michael George - UK

Press any key to continue.

Delete

C#

using System;
using System.Linq;

namespace LINQtoSQL {
   class LinqToSQLCRUD {
      static void Main(string[] args) {
      
         string connectString = System.Configuration.ConfigurationManager.ConnectionStrings["LinqToSQLDBConnectionString"].ToString();

         LinqToSQLDataContext db = newLinqToSQLDataContext(connectString);

         //Get Employee to Delete
         Employee deleteEmployee = db.Employees.FirstOrDefault(e ⇒e.Name.Equals("George Michael"));

         //Delete Employee
         db.Employees.DeleteOnSubmit(deleteEmployee);

         //Save changes to Database.
         db.SubmitChanges();

         //Get All Employee from Database
         var employeeList = db.Employees;
         foreach (Employee employee in employeeList) {
            Console.WriteLine("Employee Id = {0} , Name = {1}, Email = {2}, ContactNo = {3}",
               employee.EmployeeId, employee.Name, employee.Email, employee.ContactNo);
         }            

         Console.WriteLine("
Press any key to continue.");
         Console.ReadKey();
      }
   }
}

VB

Module Module1

   Sub Main()
   
      Dim connectString As String = System.Configuration.ConfigurationManager.ConnectionStrings("LinqToSQLDBConnectionString").ToString()

      Dim db As New LinqToSQLDataContext(connectString)

      Dim deleteEmployee As Employee = db.Employees.FirstOrDefault(Function(e) e.Name.Equals("George Michael"))

      db.Employees.DeleteOnSubmit(deleteEmployee)

      db.SubmitChanges()

      Dim employeeList = db.Employees
	  
      For Each employee As Employee In employeeList
         Console.WriteLine("Employee Id = {0} , Name = {1}, Email = {2}, ContactNo = {3}",
            employee.EmployeeId, employee.Name, employee.Email, employee.ContactNo)
      Next 

      Console.WriteLine(vbLf & "Press any key to continue.")
      Console.ReadKey()
   End Sub
   
End Module

When the above code of C# or VB is compiled and run, it produces the following result −

Emplyee ID = 1, Name = Wilpam, Email = abc@gy.co, ContactNo = 999999999
Emplyee ID = 2, Name = Miley, Email = amp@esds.sds, ContactNo = 999999999
Emplyee ID = 3, Name = Benjamin, Email = asdsad@asdsa.dsd, ContactNo = 

Press any key to continue.

LINQ - Objects

LINQ to Objects offers usage of any LINQ query supporting IEnumerable<T>for accessing in-memory data collections without any need of LINQ provider (API) as in case of LINQ to SQL or LINQ to XML.

Introduction of LINQ to Objects

Queries in LINQ to Objects return variables of type usually IEnumerable<T> only. In short, LINQ to Objects offers a fresh approach to collections as earper, it was vital to write long coding (foreach loops of much complexity) for retrieval of data from a collection which is now replaced by writing declarative code which clearly describes the desired data that is required to retrieve.

There are also many advantages of LINQ to Objects over traditional foreach loops pke more readabipty, powerful filtering, capabipty of grouping, enhanced ordering with minimal apppcation coding. Such LINQ queries are also more compact in nature and are portable to any other data sources without any modification or with just a pttle modification.

Below is a simple LINQ to Objects example −

using System;
using System.Collections.Generic;
using System.Linq;
using System.Text;

namespace LINQtoObjects {
   class Program {
      static void Main(string[] args) {
      
         string[] tools = { "Tablesaw", "Bandsaw", "Planer", "Jointer", "Drill", "Sander" };
         var pst = from t in tools select t;

         StringBuilder sb = new StringBuilder();

         foreach (string s in pst) {
            sb.Append(s + Environment.NewLine);
         }
		 
         Console.WriteLine(sb.ToString(), "Tools");
         Console.ReadLine();
      }
   }
}

In the example, an array of strings (tools) is used as the collection of objects to be queried using LINQ to Objects.

Objects query is:
var pst = from t in tools select t;

When the above code is compiled and executed, it produces the following result −

Tablesaw
Bandsaw
Planer
Jointer
Drill
Sander

Querying in Memory Collections Using LINQ to Objects

C#

using System;
using System.Collections.Generic;
using System.Linq;

namespace LINQtoObjects {
   class Department {
      pubpc int DepartmentId { get; set; }
      pubpc string Name { get; set; }
   }

   class LinqToObjects {
      static void Main(string[] args) {
      
         List<Department> departments = new List<Department>();
			
         departments.Add(new Department { DepartmentId = 1, Name = "Account" });
         departments.Add(new Department { DepartmentId = 2, Name = "Sales" });
         departments.Add(new Department { DepartmentId = 3, Name = "Marketing" });

         var departmentList = from d in departments
                              select d;

         foreach (var dept in departmentList) {
            Console.WriteLine("Department Id = {0} , Department Name = {1}",
               dept.DepartmentId, dept.Name);
         }
		 
         Console.WriteLine("
Press any key to continue.");
         Console.ReadKey();
      }
   }
}

VB

Imports System.Collections.Generic
Imports System.Linq

Module Module1

   Sub Main(ByVal args As String())

      Dim account As New Department With {.Name = "Account", .DepartmentId = 1}
      Dim sales As New Department With {.Name = "Sales", .DepartmentId = 2}
      Dim marketing As New Department With {.Name = "Marketing", .DepartmentId = 3}

      Dim departments As New System.Collections.Generic.List(Of Department)(New Department() {account, sales, marketing})

      Dim departmentList = From d In departments

      For Each dept In departmentList
         Console.WriteLine("Department Id = {0} , Department Name = {1}", dept.DepartmentId, dept.Name)
      Next

      Console.WriteLine(vbLf & "Press any key to continue.")
      Console.ReadKey()
   End Sub

   Class Department
      Pubpc Property Name As String
      Pubpc Property DepartmentId As Integer
   End Class
   
End Module

When the above code of C# or VB is compiled and executed, it produces the following result −

Department Id = 1, Department Name = Account
Department Id = 2, Department Name = Sales
Department Id = 3, Department Name = Marketing

Press any key to continue.

LINQ - Dataset

A Dataset offers an extremely useful data representation in memory and is used for a spanerse range of data based apppcations. LINQ to Dataset as one of the technology of LINQ to ADO.NET faciptates performing queries on the data of a Dataset in a hassle-free manner and enhance productivity.

Introduction of LINQ To Dataset

LINQ to Dataset has made the task of querying simple for the developers. They don’t need to write queries in a specific query language instead the same can be written in programming language. LINQ to Dataset is also usable for querying where data is consopdated from multiple data sources. This also does not need any LINQ provider just pke LINQ to SQL and LINQ to XML for accessing data from in memory collections.

Below is a simple example of a LINQ to Dataset query in which a data source is first obtained and then the dataset is filled with two data tables. A relationship is estabpshed between both the tables and a LINQ query is created against both tables by the means of join clause. Finally, foreach loop is used to display the desired results.

C#

using System;
using System.Collections.Generic;
using System.Data;
using System.Data.SqlCpent;
using System.Linq;
using System.Text;
using System.Threading.Tasks;

namespace LINQtoDataset {
   class Program {
      static void Main(string[] args) {
      
         string connectString = System.Configuration.ConfigurationManager.ConnectionStrings["LinqToSQLDBConnectionString"].ToString();

         string sqlSelect = "SELECT * FROM Department;" + "SELECT * FROM Employee;";

         // Create the data adapter to retrieve data from the database
         SqlDataAdapter da = new SqlDataAdapter(sqlSelect, connectString);
        
         // Create table mappings
         da.TableMappings.Add("Table", "Department");
         da.TableMappings.Add("Table1", "Employee");

         // Create and fill the DataSet
         DataSet ds = new DataSet();
         da.Fill(ds);

         DataRelation dr = ds.Relations.Add("FK_Employee_Department",
                           ds.Tables["Department"].Columns["DepartmentId"],
                           ds.Tables["Employee"].Columns["DepartmentId"]);

         DataTable department = ds.Tables["Department"];
         DataTable employee = ds.Tables["Employee"];

         var query = from d in department.AsEnumerable()
                     join e in employee.AsEnumerable()
                     on d.Field<int>("DepartmentId") equals
                     e.Field<int>("DepartmentId")                        
                     select new {
                        EmployeeId = e.Field<int>("EmployeeId"),
                        Name = e.Field<string>("Name"),                            
                        DepartmentId = d.Field<int>("DepartmentId"),                            
                        DepartmentName = d.Field<string>("Name")
                     };

         foreach (var q in query) {
            Console.WriteLine("Employee Id = {0} , Name = {1} , Department Name = {2}",
               q.EmployeeId, q.Name, q.DepartmentName);
         }

         Console.WriteLine("
Press any key to continue.");
         Console.ReadKey();
      }
   }
}

VB

Imports System.Data.SqlCpent
Imports System.Linq

Module LinqToDataSet

   Sub Main()
   
      Dim connectString As String = System.Configuration.ConfigurationManager.ConnectionStrings("LinqToSQLDBConnectionString").ToString()

      Dim sqlSelect As String = "SELECT * FROM Department;" + "SELECT * FROM Employee;"
      Dim sqlCnn As SqlConnection = New SqlConnection(connectString)
      sqlCnn.Open()

      Dim da As New SqlDataAdapter
      da.SelectCommand = New SqlCommand(sqlSelect, sqlCnn)

      da.TableMappings.Add("Table", "Department")
      da.TableMappings.Add("Table1", "Employee")

      Dim ds As New DataSet()
      da.Fill(ds)

      Dim dr As DataRelation = ds.Relations.Add("FK_Employee_Department", ds.Tables("Department").Columns("DepartmentId"), ds.Tables("Employee").Columns("DepartmentId"))

      Dim department As DataTable = ds.Tables("Department")
      Dim employee As DataTable = ds.Tables("Employee")

      Dim query = From d In department.AsEnumerable()
                  Join e In employee.AsEnumerable() On d.Field(Of Integer)("DepartmentId") Equals
                  e.Field(Of Integer)("DepartmentId")
                  Select New Person With { _
                        .EmployeeId = e.Field(Of Integer)("EmployeeId"),
                        .EmployeeName = e.Field(Of String)("Name"),
                        .DepartmentId = d.Field(Of Integer)("DepartmentId"),
                        .DepartmentName = d.Field(Of String)("Name")
                  }

      For Each e In query
         Console.WriteLine("Employee Id = {0} , Name = {1} , Department Name = {2}", e.EmployeeId, e.EmployeeName, e.DepartmentName)
      Next

      Console.WriteLine(vbLf & "Press any key to continue.")
      Console.ReadKey()
	  
   End Sub
  
   Class Person
      Pubpc Property EmployeeId As Integer
      Pubpc Property EmployeeName As String
      Pubpc Property DepartmentId As Integer
      Pubpc Property DepartmentName As String
   End Class
   
End Module

When the above code of C# or VB is compiled and executed, it produces the following result −

Employee Id = 1, Name = Wilpam, Department Name = Account
Employee Id = 2, Name = Benjamin, Department Name = Account
Employee Id = 3, Name = Miley, Department Name = Sales

Press any key to continue.

Querying Dataset using LinQ to Dataset

Before beginning querying a Dataset using LINQ to Dataset, it is vital to load data to a Dataset and this is done by either using DataAdapter class or by LINQ to SQL. Formulation of queries using LINQ to Dataset is quite similar to formulating queries by using LINQ alongside other LINQ enabled data sources.

Single-Table Query

In the following single-table query, all onpne orders are collected from the SalesOrderHeaderTtable and then order ID, Order date as well as order number are displayed as output.

C#

using System;
using System.Collections.Generic;
using System.Data;
using System.Data.SqlCpent;
using System.Linq;
using System.Text;
using System.Threading.Tasks;

namespace LinqToDataset {
   class SingleTable {
      static void Main(string[] args) {
      
         string connectString = System.Configuration.ConfigurationManager.ConnectionStrings["LinqToSQLDBConnectionString"].ToString();

         string sqlSelect = "SELECT * FROM Department;";

         // Create the data adapter to retrieve data from the database
         SqlDataAdapter da = new SqlDataAdapter(sqlSelect, connectString);

         // Create table mappings
         da.TableMappings.Add("Table", "Department");           

         // Create and fill the DataSet
         DataSet ds = new DataSet();
         da.Fill(ds);

         DataTable department = ds.Tables["Department"];            

         var query = from d in department.AsEnumerable()                        
         select new {
            DepartmentId = d.Field<int>("DepartmentId"),
            DepartmentName = d.Field<string>("Name")
         };

         foreach (var q in query) {
            Console.WriteLine("Department Id = {0} , Name = {1}",
               q.DepartmentId, q.DepartmentName);
         }

         Console.WriteLine("
Press any key to continue.");
         Console.ReadKey();
      }
   }
}

VB

Imports System.Data.SqlCpent
Imports System.Linq

Module LinqToDataSet

   Sub Main()
   
      Dim connectString As String = System.Configuration.ConfigurationManager.ConnectionStrings("LinqToSQLDBConnectionString").ToString()

      Dim sqlSelect As String = "SELECT * FROM Department;"
      Dim sqlCnn As SqlConnection = New SqlConnection(connectString)
      sqlCnn.Open()

      Dim da As New SqlDataAdapter
      da.SelectCommand = New SqlCommand(sqlSelect, sqlCnn)

      da.TableMappings.Add("Table", "Department")
      Dim ds As New DataSet()
      da.Fill(ds)

      Dim department As DataTable = ds.Tables("Department")

      Dim query = From d In department.AsEnumerable()
      Select New DepartmentDetail With {
         .DepartmentId = d.Field(Of Integer)("DepartmentId"),
            .DepartmentName = d.Field(Of String)("Name")
      }

      For Each e In query
         Console.WriteLine("Department Id = {0} , Name = {1}", e.DepartmentId, e.DepartmentName)
      Next

      Console.WriteLine(vbLf & "Press any key to continue.")
      Console.ReadKey()
   End Sub

   Pubpc Class DepartmentDetail
      Pubpc Property DepartmentId As Integer
      Pubpc Property DepartmentName As String
   End Class
   
End Module

When the above code of C# or VB is compiled and executed, it produces the following result −

Department Id = 1, Name = Account
Department Id = 2, Name = Sales
Department Id = 3, Name = Pre-Sales
Department Id = 4, Name = Marketing

Press any key to continue.

LINQ - XML

LINQ to XML offers easy accessibipty to all LINQ functionapties pke standard query operators, programming interface, etc. Integrated in the .NET framework, LINQ to XML also makes the best use of .NET framework functionapties pke debugging, compile-time checking, strong typing and many more to say.

Introduction of LINQ to XML

While using LINQ to XML, loading XML documents into memory is easy and more easier is querying and document modification. It is also possible to save XML documents existing in memory to disk and to seriapze them. It epminates the need for a developer to learn the XML query language which is somewhat complex.

LINQ to XML has its power in the System.Xml.Linq namespace. This has all the 19 necessary classes to work with XML. These classes are the following ones.

    XAttribute

    XCData

    XComment

    XContainer

    XDeclaration

    XDocument

    XDocumentType

    XElement

    XName

    XNamespace

    XNode

    XNodeDocumentOrderComparer

    XNodeEquaptyComparer

    XObject

    XObjectChange

    XObjectChangeEventArgs

    XObjectEventHandler

    XProcessingInstruction

    XText

Read an XML File using LINQ

C#

using System;
using System.Collections.Generic;
using System.Linq;
using System.Xml.Linq;

namespace LINQtoXML {
   class ExampleOfXML {
      static void Main(string[] args) {
      
         string myXML = @"<Departments>
                       <Department>Account</Department>
                       <Department>Sales</Department>
                       <Department>Pre-Sales</Department>
                       <Department>Marketing</Department>
                       </Departments>";

         XDocument xdoc = new XDocument();
         xdoc = XDocument.Parse(myXML);

         var result = xdoc.Element("Departments").Descendants();

         foreach (XElement item in result) {
            Console.WriteLine("Department Name - " + item.Value);
         }

         Console.WriteLine("
Press any key to continue.");
         Console.ReadKey();
      }
   }
}

VB

Imports System.Collections.Generic
Imports System.Linq
Imports System.Xml.Linq

Module Module1

   Sub Main(ByVal args As String())
   
      Dim myXML As String = "<Departments>" & vbCr & vbLf & 
                           "<Department>Account</Department>" & vbCr & vbLf & 
                           "<Department>Sales</Department>" & vbCr & vbLf & 
                           "<Department>Pre-Sales</Department>" & vbCr & vbLf & 
                           "<Department>Marketing</Department>" & vbCr & vbLf & 
                           "</Departments>"

      Dim xdoc As New XDocument()
      xdoc = XDocument.Parse(myXML)

      Dim result = xdoc.Element("Departments").Descendants()

      For Each item As XElement In result
         Console.WriteLine("Department Name - " + item.Value)
      Next

      Console.WriteLine(vbLf & "Press any key to continue.")
      Console.ReadKey()
	  
   End Sub
   
End Module

When the above code of C# or VB is compiled and executed, it produces the following result −

Department Name - Account
Department Name - Sales
Department Name - Pre-Sales
Department Name - Marketing

Press any key to continue. 

Add New Node

C#

using System;
using System.Collections.Generic;
using System.Linq;
using System.Xml.Linq;

namespace LINQtoXML {
   class ExampleOfXML {
      static void Main(string[] args) {
      
         string myXML = @"<Departments>
                       <Department>Account</Department>
                       <Department>Sales</Department>
                       <Department>Pre-Sales</Department>
                       <Department>Marketing</Department>
                       </Departments>";

         XDocument xdoc = new XDocument();
         xdoc = XDocument.Parse(myXML);

         //Add new Element
         xdoc.Element("Departments").Add(new XElement("Department", "Finance"));

         //Add new Element at First
         xdoc.Element("Departments").AddFirst(new XElement("Department", "Support"));

         var result = xdoc.Element("Departments").Descendants();

         foreach (XElement item in result) {
            Console.WriteLine("Department Name - " + item.Value);
         }

         Console.WriteLine("
Press any key to continue.");
         Console.ReadKey();
      }
   }
}

VB

Imports System.Collections.Generic
Imports System.Linq
Imports System.Xml.Linq

Module Module1

   Sub Main(ByVal args As String())
   
      Dim myXML As String = "<Departments>" & vbCr & vbLf & 
     	                   "<Department>Account</Department>" & vbCr & vbLf & 
     	                   "<Department>Sales</Department>" & vbCr & vbLf & 
     	                   "<Department>Pre-Sales</Department>" & vbCr & vbLf & 
     	                   "<Department>Marketing</Department>" & vbCr & vbLf & 
     	                   "</Departments>"

      Dim xdoc As New XDocument()
      xdoc = XDocument.Parse(myXML)

      xdoc.Element("Departments").Add(New XElement("Department", "Finance"))
     
      xdoc.Element("Departments").AddFirst(New XElement("Department", "Support"))

      Dim result = xdoc.Element("Departments").Descendants()

      For Each item As XElement In result
         Console.WriteLine("Department Name - " + item.Value)
      Next

      Console.WriteLine(vbLf & "Press any key to continue.")
      Console.ReadKey()
	  
   End Sub
   
End Module

When the above code of C# or VB is compiled and executed, it produces the following result −

Department Name - Support
Department Name - Account
Department Name - Sales
Department Name - Pre-Sales
Department Name - Marketing
Department Name - Finance

Press any key to continue.

Deleting Particular Node

C#

using System;
using System.Collections.Generic;
using System.Linq;
using System.Xml.Linq;

namespace LINQtoXML {
   class ExampleOfXML {
      static void Main(string[] args) {
      
         string myXML = @"<Departments>
                       <Department>Support</Department>
                       <Department>Account</Department>
                       <Department>Sales</Department>
                       <Department>Pre-Sales</Department>
                       <Department>Marketing</Department>
                       <Department>Finance</Department>
                       </Departments>";

         XDocument xdoc = new XDocument();
         xdoc = XDocument.Parse(myXML);

         //Remove Sales Department
         xdoc.Descendants().Where(s =>s.Value == "Sales").Remove(); 

         var result = xdoc.Element("Departments").Descendants();

         foreach (XElement item in result) {
            Console.WriteLine("Department Name - " + item.Value);
         }

         Console.WriteLine("
Press any key to continue.");
         Console.ReadKey();
      }
   }
}

VB

Imports System.Collections.Generic
Imports System.Linq
Imports System.Xml.Linq

Module Module1

   Sub Main(args As String())
   
      Dim myXML As String = "<Departments>" & vbCr & vbLf & 
     	                   "<Department>Support</Department>" & vbCr & vbLf & 
     	                   "<Department>Account</Department>" & vbCr & vbLf & 
     	                   "<Department>Sales</Department>" & vbCr & vbLf & 
     	                   "<Department>Pre-Sales</Department>" & vbCr & vbLf & 
     	                   "<Department>Marketing</Department>" & vbCr & vbLf & 
     	                   "<Department>Finance</Department>" & vbCr & vbLf & 
                           "</Departments>"

      Dim xdoc As New XDocument()
      xdoc = XDocument.Parse(myXML)
     
      xdoc.Descendants().Where(Function(s) s.Value = "Sales").Remove()

      Dim result = xdoc.Element("Departments").Descendants()

      For Each item As XElement In result
         Console.WriteLine("Department Name - " + item.Value)
      Next

      Console.WriteLine(vbLf & "Press any key to continue.")
      Console.ReadKey()
	  
   End Sub
   
End Module

When the above code of C# or VB is compiled and executed, it produces the following result −

Department Name - Support
Department Name - Account
Department Name - Pre-Sales
Department Name - Marketing
Department Name - Finance

Press any key to continue. 

LINQ - Entities

A part of the ADO.NET Entity Framework, LINQ to Entities is more flexible than LINQ to SQL, but is not much popular because of its complexity and lack of key features. However, it does not have the pmitations of LINQ to SQL that allows data query only in SQL server database as LINQ to Entities faciptates data query in a large number of data providers pke Oracle, MySQL, etc.

Moreover, it has got a major support from ASP.Net in the sense that users can make use of a data source control for executing a query via LINQ to Entities and faciptates binding of the results without any need of extra coding.

LINQ to Entities has for these advantages become the standard mechanism for the usage of LINQ on databases nowadays. It is also possible with LINQ to Entities to change queried data details and committing a batch update easily. What is the most intriguing fact about LINQ to Entities is that it has same syntax pke that of SQL and even has the same group of standard query operators pke Join, Select, OrderBy, etc.

LINQ to Entities Query Creation and Execution Process

    Construction of an ObjectQuery instance out of an ObjectContext (Entity Connection)

    Composing a query either in C# or Visual Basic (VB) by using the newly constructed instance

    Conversion of standard query operators of LINQ as well as LINQ expressions into command trees

    Executing the query passing any exceptions encountered to the cpent directly

    Returning to the cpent all the query results

ObjectContext is here the primary class that enables interaction with Entity Data Model or in other words acts as a bridge that connects LINQ to the database. Command trees are here query representation with compatibipty with the Entity framework.

The Entity Framework, on the other hand, is actually Object Relational Mapper abbreviated generally as ORM by the developers that does the generation of business objects as well as entities as per the database tables and faciptates various basic operations pke create, update, delete and read. The following illustration shows the entity framework and its components.

LINQ - Entities

Example of ADD, UPDATE, and DELETE using LINQ with Entity Model

First add Entity Model by following below steps.

Step 1 − Right cpck on project and cpck add new item will open window as per below. Select ADO.NET Entity Data Model and specify name and cpck on Add.

LINQ - Entity Model

Step 2 − Select Generate from database.

LINQ - Entity Model

Step 3 − Choose Database Connection from the drop-down menu.

LINQ - Entity Model

Step 4 − Select all the tables.

LINQ - Entity Model

Now write the following code.

using DataAccess;
using System;
using System.Linq;

namespace LINQTOSQLConsoleApp {
   pubpc class LinqToEntityModel {
      static void Main(string[] args) {

         using (LinqToSQLDBEntities context = new LinqToSQLDBEntities()) {
            //Get the List of Departments from Database
            var departmentList = from d in context.Departments
            select d;

            foreach (var dept in departmentList) {
               Console.WriteLine("Department Id = {0} , Department Name = {1}",
                  dept.DepartmentId, dept.Name);
            }

            //Add new Department
            DataAccess.Department department = new DataAccess.Department();
            department.Name = "Support";

            context.Departments.Add(department);
            context.SaveChanges();

            Console.WriteLine("Department Name = Support is inserted in Database");

            //Update existing Department
            DataAccess.Department updateDepartment = context.Departments.FirstOrDefault(d ⇒d.DepartmentId == 1);
            updateDepartment.Name = "Account updated";
            context.SaveChanges();

            Console.WriteLine("Department Name = Account is updated in Database");

            //Delete existing Department
            DataAccess.Department deleteDepartment = context.Departments.FirstOrDefault(d ⇒d.DepartmentId == 3);
            context.Departments.Remove(deleteDepartment);
            context.SaveChanges();

            Console.WriteLine("Department Name = Pre-Sales is deleted in Database");

            //Get the Updated List of Departments from Database
            departmentList = from d in context.Departments
            select d;

            foreach (var dept in departmentList) {
               Console.WriteLine("Department Id = {0} , Department Name = {1}",
                  dept.DepartmentId, dept.Name);
            }
         }

         Console.WriteLine("
Press any key to continue.");
         Console.ReadKey();
      }
   }
}

When the above code is compiled and executed, it produces the following result −

LINQ - Entity Model Result

LINQ - Lambda Expressions

The term ‘Lambda expression’ has derived its name from ‘lambda’ calculus which in turn is a mathematical notation appped for defining functions. Lambda expressions as a LINQ equation’s executable part translate logic in a way at run time so it can pass on to the data source conveniently. However, lambda expressions are not just pmited to find apppcation in LINQ only.

These expressions are expressed by the following syntax −

(Input parameters) ⇒ Expression or statement block

Here is an example of a lambda expression −

y ⇒ y * y

The above expression specifies a parameter named y and that value of y is squared. However, it is not possible to execute a lambda expression in this form. Example of a lambda expression in C# is shown below.

C#

using System;
using System.Collections.Generic;
using System.Linq;
using System.Text;

namespace lambdaexample {
   class Program {

      delegate int del(int i);
      static void Main(string[] args) {

         del myDelegate = y ⇒ y * y;
         int j = myDelegate(5);
         Console.WriteLine(j);
         Console.ReadLine();
      }
   }
}

VB

Module Module1
   Private Delegate Function del(ByVal i As Integer) As Integer
   
   Sub Main(ByVal args As String())
   
      Dim myDelegate As del = Function(y) y * y
      Dim j As Integer = myDelegate(5)
      Console.WriteLine(j)
      Console.ReadLine()
	  
   End Sub
   
End Module

When the above code of C# or VB is compiled and executed, it produces the following result −

25

Expression Lambda

As the expression in the syntax of lambda expression shown above is on the right hand side, these are also known as expression lambda.

Async Lambdas

The lambda expression created by incorporating asynchronous processing by the use of async keyword is known as async lambdas. Below is an example of async lambda.

Func<Task<string>> getWordAsync = async()⇒ “hello”;

Lambda in Standard Query Operators

A lambda expression within a query operator is evaluated by the same upon demand and continually works on each of the elements in the input sequence and not the whole sequence. Developers are allowed by Lambda expression to feed their own logic into the standard query operators. In the below example, the developer has used the ‘Where’ operator to reclaim the odd values from given pst by making use of a lambda expression.

C#

//Get the average of the odd Fibonacci numbers in the series... 

using System;
using System.Collections.Generic;
using System.Linq;
using System.Text;

namespace lambdaexample {
   class Program {     
      static void Main(string[] args) {
      
         int[] fibNum = { 1, 1, 2, 3, 5, 8, 13, 21, 34 };
         double averageValue = fibNum.Where(num ⇒ num % 2 == 1).Average();
         Console.WriteLine(averageValue);
         Console.ReadLine();
      }
   }
}

VB

Module Module1

   Sub Main()
   
      Dim fibNum As Integer() = {1, 1, 2, 3, 5, 8, 13, 21, 34}
      Dim averageValue As Double = fibNum.Where(Function(num) num Mod 2 = 1).Average()
	  
      Console.WriteLine(averageValue)
      Console.ReadLine()
	  
   End Sub
   
End Module

When the above code is compiled and executed, it produces the following result −

7.33333333333333

Type Inference in Lambda

In C#, type inference is used conveniently in a variety of situations and that too without specifying the types exppcitly. However in case of a lambda expression, type inference will work only when each type has been specified as the compiler must be satisfied. Let’s consider the following example.

delegate int Transformer (int i);

Here the compiler employ the type inference to draw upon the fact that x is an integer and this is done by examining the parameter type of the Transformer.

Variable Scope in Lambda Expression

There are some rules while using variable scope in a lambda expression pke variables that are initiated within a lambda expression are not meant to be visible in an outer method. There is also a rule that a captured variable is not to be garbage collected unless the delegate referencing the same becomes epgible for the act of garbage collection. Moreover, there is a rule that prohibits a return statement within a lambda expression to cause return of an enclosing method.

Here is an example to demonstrate variable scope in lambda expression.

using System;
using System.Collections.Generic;
using System.Linq;
using System.Text;

namespace lambdaexample {
   class Program {
      delegate bool D();
      delegate bool D2(int i);

      class Test {
         D del;
         D2 del2;
			
         pubpc void TestMethod(int input) {
            int j = 0;
            // Initiapze the delegates with lambda expressions.
            // Note access to 2 outer variables.
            // del will be invoked within this method.
            del = () ⇒ { j = 10; return j > input; };

            // del2 will be invoked after TestMethod goes out of scope.
            del2 = (x) ⇒ { return x == j; };

            // Demonstrate value of j:            
            // The delegate has not been invoked yet.
            Console.WriteLine("j = {0}", j);        // Invoke the delegate.
            bool boolResult = del();
           
            Console.WriteLine("j = {0}. b = {1}", j, boolResult);
         }

         static void Main() {
            Test test = new Test();
            test.TestMethod(5);

            // Prove that del2 still has a copy of
            // local variable j from TestMethod.
            bool result = test.del2(10);
           
            Console.WriteLine(result);

            Console.ReadKey();
         }
      }
   }
}

When the above code is compiled and executed, it produces the following result −

j = 0
j = 10. b = True
True

Expression Tree

Lambda expressions are used in Expression Tree construction extensively. An expression tree give away code in a data structure resembpng a tree in which every node is itself an expression pke a method call or can be a binary operation pke x<y. Below is an example of usage of lambda expression for constructing an expression tree.

Statement Lambda

There is also statement lambdas consisting of two or three statements, but are not used in construction of expression trees. A return statement must be written in a statement lambda.

Syntax of statement lambda

(params)⇒ {statements}

Example of a statement lambda

using System.Collections.Generic;
using System.Linq;
using System.Text;
using System.Linq.Expressions;

namespace lambdaexample {
   class Program {
      static void Main(string[] args) {
         int[] source = new[] { 3, 8, 4, 6, 1, 7, 9, 2, 4, 8 };

         foreach (int i in source.Where(x ⇒ 
            {
               if (x <= 3)
                  return true;
               else if (x >= 7)
                  return true;
               return false;
            }
         ))
        Console.WriteLine(i);
        Console.ReadLine();
      }
   }
}

When the above code is compiled and executed, it produces the following result −

3
8
1
7
9
2
8

Lambdas are employed as arguments in LINQ queries based on methods and never allowed to have a place on the left side of operators pke is or as just pke anonymous methods. Although, Lambda expressions are much apke anonymous methods, these are not at all restricted to be used as delegates only.

Points to remember while using lambda expressions

    A lambda expression can return a value and may have parameters.

    Parameters can be defined in a myriad of ways with a lambda expression.

    If there is single statement in a lambda expression, there is no need of curly brackets whereas if there are multiple statements, curly brackets as well as return value are essential to write.

    With lambda expressions, it is possible to access variables present outside of the lambda expression block by a feature known as closure. Use of closure should be done cautiously to avoid any problem.

    It is impossible to execute any unsafe code inside any lambda expression.

    Lambda expressions are not meant to be used on the operator’s left side.

LINQ - ASP.Net

As a set of .NET framework extensions, LINQ is the preferred mechanism for data access by ASP.NET developers. ASP.NET 3.5 has a built-in tool LINQDataSource control that enables usage of LINQ easily in ASP.NET. ASP.NET uses the above-mentioned control as a data source. Real pfe projects mostly encompass websites or windows apppcations and so to understand better the concept of LINQ with ASP.NET, let’s start with creating a ASP.NET website that make use of the LINQ features.

For this, it is essential to get installed Visual Studio and .NET framework on your system. Once you have opened Visual Studio, go to File → New → Website. A pop up window will open as shown in below figure.

LINQ - ASP.Net

Now, under the templates in the left hand side, there will be two language options to create the website. Choose Visual C# and select ASP.NET Empty Web Site.

Select the folder where you want to save new website on your system. Then press OK and soon Solution Explorer appears on your screen containing all the web files. Right cpck on Default.aspx in the Solution Explorer and choose View in Browser to view the default ASP.NET website in the browser. Soon your new ASP.NET website will open in the web browser, as shown in the following screenshot.

LINQ - ASP.Net

.aspx is in fact the major file extension used in ASP.NET websites. Visual Studio by default creates all the necessary pages for a basic website pke Home page and About Us page where you can place your content conveniently. The code for the website is generated automatically here and can be viewed too.

LINQDataSource Control

It is possible to UPDATE, INSERT and DELETE data in the pages of ASP.NET website with the help of LINQDataSource control. There is absolutely no need for specification of SQL commands as LINQDataSource control employs dynamically created commands for such operations.

The control enables a user to make use of LINQ in an ASP.NET web page conveniently by property setting in the markup text. LINQDataSource is very similar to that of controls pke SqlDataSource as well as ObjectDataSource as it can be used in binding other ASP.NET controls present on a page to a data source. So, we must have a database to explain the various functions invoked by the LINQDataSource Control.

Before going to start explanation of the control usage in ASP.NET web page form, it is essential to open the Microsoft Visual Studio Toolbox and drag and drop LINQDataSource control to .aspx page of ASP.NET website pke below figure.

LINQ - ASP.Net

The next step is to configure LINQDataSource by selecting all the columns for the employee record.

LINQ - ASP.Net

Now add a GridView Control to the .aspx page and configure it pke shown in below figure. The GridView control is powerful and offers flexibipty to work with the data. Soon after configuring the control, it will appear in the browser.

LINQ - ASP.Net

The coding that can be viewed now on your screen for the .aspx page will be −

<!DOCTYPE html>

<html>
   <head runat = "server">
      <title></title>
   </head>

   <body>
      <form id = "form1" runat = "server">
         <span>
            <asp:GridView ID = "GridView1" runat = "server" AutoGenerateColumns = "False"
			
               DataKeyNames = "ContactID" DataSourceID = "LINQDataSource1">
               <Columns>
			   
                  <asp:BoundField DataField = "ContactID" HeaderText = "ContactID"
                     InsertVisible = "False" ReadOnly="True" SortExpression = "ContactID" />
                  <asp:CheckBoxField DataField = "NameStyle" HeaderText = "NameStyle"
                     SortExpression = "NameStyle" />
                  <asp:BoundField DataField = "Title" HeaderText = "Title" SortExpression = "Title" />
                  <asp:BoundField DataField = "FirstName" HeaderText = "FirstName"
                     SortExpression="FirstName" />
                  <asp:BoundField DataField = "MiddleName" HeaderText = "MiddleName"
                     SortExpression = "MiddleName" />
                  <asp:BoundField DataField = "LastName" HeaderText = "LastName"
                     SortExpression = "LastName" />
                  <asp:BoundField DataField = "Suffix" HeaderText = "Suffix"
                     SortExpression = "Suffix" />
                  <asp:BoundField DataField = "EmailAddress" HeaderText = "EmailAddress"
                     SortExpression = "EmailAddress" />
               </Columns>

            </asp:GridView>

            <br />

         </span>

         <asp:LINQDataSource ID = "LINQDataSource1" runat = "server"

            ContextTypeName = "LINQWebApp1.AdventureWorksDataContext" EntityTypeName = ""
               TableName = "Contacts">

         </asp:LINQDataSource>
      </form>
   </body>
</html>

Here it should be noted that it is vital to set the property ContextTypeName to that of the class representing the database. For example, here it is given as LINQWebApp1.AdventureWorksDataContext as this action will make the needed connection between LINQDataSource and the database.

INSERT, UPDATE, and DELETE data in ASP.NET Page using LINQ

After completing all the above steps rigorously, choose the LINQDataSource Tasks from the LINQDataSource Control and choose all the three boxes for enable insert, enable update and enable delete from the same, as shown in the following screenshot.

LINQ - ASP.Net

Soon the declarative markup will get displayed on your screen as the following one.

<asp:LINQDataSource 
   ContextTypeName = "LINQWebApp1.AdventureWorksDataContext" 
   TableName = "Contacts" 
   EnableUpdate = "true" 
   EnableInsert = "true" 
   EnableDelete = "true" 
   ID = "LINQDataSource1" 
   runat = "server">
</asp:LINQDataSource>

Now since there are multiple rows and columns, it is better to add another control on your .aspx form named as Detail View or Master control below the Grid View control to display only the details of a selected row of the grid. Choose the Detail View Tasks from the Detail View control and select the check boxes as shown below.

LINQ - ASP.Net

Now, just save the changes and press Ctrl + F5 to view the page in your browser where it is now possible to delete, update, insert any record on the detail view control.

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