Wednesday, 3 February 2016

NET Framework and Architecture

What is the .NET Framework?

 

The .NET Framework is a new and revolutionary platform created by Microsoft for developing applications.  

It is a platform for application developers.

It is a Framework that supports Multiple Language and Cross language integration.

IT has IDE (Integrated Development Environment).

Framework is a set of utilities or can say building blocks of your application system.

.NET Framework provides GUI in a GUI manner.

.NET is a platform independent but with help of Mono Compilation System (MCS). MCS is a middle level interface.

.NET Framework provides interoperability between languages i.e. Common Type System (CTS) .

.NET Framework also includes the .NET Common Language Runtime (CLR), which is responsible for maintaining the execution of all applications developed using the .NET library.

The .NET Framework consists primarily of a gigantic library of code.

Definition: A programming infrastructure created by Microsoft for building, deploying, and running applications and services that use .NET technologies, such as desktop applications and Web services.

 

Cross Language integration

 

You can use a utility of a language in another language (It uses Class Language Integration).

 

.NET Framework includes no restriction on the type of applications that are possible. The .NET Framework allows the creation of Windows applications, Web applications, Web services, and lot more.

 

The .NET Framework has been designed so that it can be used from any language, including C#, C++, Visual Basic, JScript, and even older languages such as COBOL.

 

Difference between Visual Studio and Visual Studio .NET

 

Visual Studio

Visual Studio

It is object based

It is object oriented

Internet based application

- Web Application

- Web services

- Internet enable application

- Third party API

- Peer to peer Application

All developing facilities in internet based application

Poor error handling Exception/Error

Advance error handler and debugger

Memory Management System Level Task

Memory Management Application Domain with help of GC (Garbage Collector)

DLL HELL

VS .NET has solved DLL HELL Problem

 

Simple explanation of definition used in the above comparision:

 

Web Application

 

All websites are example of web application. They use a web server.

 

Internet Enabled Application

 

They are desktop application. Yahoo messenger is an example of desktop application.

 

Peer to Peer

 

Communication through computers through some system.

 

Web Services

 

It doesn't use web-based server. Internet payment systems are example of web services.

 

DLL Hell

 

"DLL Hell" refers to the set of problems caused when multiple applications attempt to share a common component like a dynamic link library (DLL) or a Component Object Model (COM) class.

 

The reason for this issue was that the version information about the different components of an application was not recorded by the system. (Windows Registry cannot support the multiple versions of same COM component this is called the dll hell problem.)

 

.Net Framework provides operating systems with a Global Assembly Cache (GAC). This Cache is a repository for all the .Net components that are shared globally on a particular machine. When a .Net component is installed onto the machine, the Global Assembly Cache looks at its version, its public key, and its language information and creates a strong name for the component. The component is then registered in the repository and indexed by its strong name, so there is no confusion between different versions of the same component, or DLL.

 

Architecture of .NET Framework


 

Architecture of CLR

CLS (Common Language Specification)

 

It is a subset of CTS. All instruction is in CLS i.e. instruction of CTS is written in CLS.

 

Code Manager

 

Code manager invokes class loader for execution.

 

.NET supports two kind of coding

 

1) Managed Code

2) Unmanaged Code

 

Managed Code

 

The resource, which is with in your application domain is, managed code. The resources that are within domain are faster.

 

The code, which is developed in .NET framework, is known as managed code. This code is directly executed by CLR with help of managed code execution. Any language that is written in .NET Framework is managed code.

 

Managed code uses CLR which in turns looks after your applications by managing memory, handling security, allowing cross - language debugging, and so on.


 

Unmanaged Code

 

The code, which is developed outside .NET, Framework is known as unmanaged code.

 

Applications that do not run under the control of the CLR are said to be unmanaged, and certain languages such as C++ can be used to write such applications, which, for example, access low - level functions of the operating system. Background compatibility with code of VB, ASP and COM are examples of unmanaged code.

 

Unmanaged code can be unmanaged source code and unmanaged compile code.

 

Unmanaged code is executed with help of wrapper classes.

 

Wrapper classes are of two types: CCW (COM callable wrapper) and RCW (Runtime Callable Wrapper).

 

Wrapper is used to cover difference with the help of CCW and RCW.

COM callable wrapper unmanaged code

Runtime Callable Wrapper unmanaged code

Native Code

 

The code to be executed must be converted into a language that the target operating system understands, known as native code. This conversion is called compiling code, an act that is performed by a compiler.

 

Under the .NET Framework, however, this is a two - stage process. With help of MSIL and JIT.

 

MSIL (Microsoft Intermediate Language)

 

It is language independent code. When you compile code that uses the .NET Framework library, you don't immediately create operating system - specific native code.

 

Instead, you compile your code into Microsoft Intermediate Language (MSIL) code. The MSIL code is not specific to any operating system or to any language.

 

JIT (Just-in-Time)

 

Just - in - Time (JIT) compiler, which compiles MSIL into native code that is specific to the OS and machine architecture being targeted. Only at this point can the OS execute the application. The just - in - time part of the name reflects the fact that MSIL code is only compiled as, and when, it is needed.

 

In the past, it was often necessary to compile your code into several applications, each of which targeted a specific operating system and CPU architecture. Often, this was a form of optimization.

 

This is now unnecessary, because JIT compilers (as their name suggests) use MSIL code, which is independent of the machine, operating system, and CPU. Several JIT compilers exist, each targeting a different architecture, and the appropriate one will be used to create the native code required.

 

The beauty of all this is that it requires a lot less work on your part - in fact, you can forget about system - dependent details and concentrate on the more interesting functionality of your code.

 

JIT are of three types:

Pre JITEcono JITNormal JITPre JIT

 

It converts all the code in executable code and it is slow

 

Econo JIT

 

It will convert the called executable code only. But it will convert code every time when a code is called again.

 

Normal JIT

 

It will only convert the called code and will store in cache so that it will not require converting code again. Normal JIT is fast.

 

Assemblies

 

When you compile an application, the MSIL code created is stored in an assembly. Assemblies include both executable application files that you can run directly from Windows without the need for any other programs (these have a .exe file extension), and libraries (which have a .dll extension) for use by other applications.

 

In addition to containing MSIL, assemblies also include meta information (that is, information about the information contained in the assembly, also known as metadata) and optional resources (additional data used by the MSIL, such as sound files and pictures).

 

The meta information enables assemblies to be fully self - descriptive. You need no other information to use an assembly, meaning you avoid situations such as failing to add required data to the system registry and so on, which was often a problem when developing with other platforms.

 

This means that deploying applications is often as simple as copying the files into a directory on a remote computer. Because no additional information is required on the target systems, you can just run an executable file from this directory and (assuming the .NET CLR is installed) you're good to go.

 

Of course, you won't necessarily want to include everything required to run an application in one place. You might write some code that performs tasks required by multiple applications. In situations like that, it is often useful to place the reusable code in a place accessible to all applications. In the .NET Framework, this is the Global Assembly Cache (GAC). Placing code in the GAC is simple - you just place the assembly containing the code in the directory containing this cache.

 

Garbage Collection (GC)

 

One of the most important features of managed code is the concept of garbage collection. This is the .NET method of making sure that the memory used by an application is freed up completely when the application is no longer in use.

 

Prior to .NET this was mostly the responsibility of programmers, and a few simple errors in code could result in large blocks of memory mysteriously disappearing as a result of being allocated to the wrong place in memory. That usually meant a progressive slowdown of your computer followed by a system crash.

 

.NET garbage collection works by inspecting the memory of your computer every so often and removing anything from it that is no longer needed. There is no set time frame for this; it might happen thousands of times a second, once every few seconds, or whenever, but you can rest assured that it will happen.

 

Will try to explain the processing in terms of C# code which is written using .NET Framework.

 

Step 1- Application code is written using a .NET - compatible language C#.

 

Step 2 - Code is compiled into MSIL, which is stored in an assembly (see Figure 1 - 2).

 

Step 3 - When this code is executed (either in its own right if it is an executable or when it is used from other code), it must first be compiled into native code using a JIT compiler.

 

Step 4 - The native code is executed in the context of the managed CLR, along with any other running applications or processes.
 


 

Note:  One additional point concerning this process. The C# code that compiles into MSIL in step 2 needn't be contained in a single file. It's possible to split application code across multiple source code files, which are then compiled together into a single assembly. This extremely useful process is known as linking.

 

This is because it is far easier to work with several smaller files than one enormous one. You can separate out logically related code into an individual file so that it can be worked on independently and then practically forgotten about when completed.

 

This also makes it easy to locate specific pieces of code when you need them and enables teams of developers to divide up the programming burden into manageable chunks, whereby individuals can check out pieces of code to work on without risking damage to otherwise satisfactory sections or sections other people are working on.

 

Conclusion

 

I hope that this article would have helped you in understanding .NET Framework and have built a simple and clear understanding of .NET.

 

Have taken some definition and lines from some references for technically explanation and understanding. Your feedback and constructive contributions are welcome.  Please feel free to contact me for feedback or comments you may have about this article

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