This is an old question (with an already selected answer) but I do not believe the question has really been answered well.

First, a little background…

How does .NET work?

A traditional Windows .EXE file is a binary file that represents a series of machine language instructions that your computer understands and that makes calls into the Win32 API which are parts of Windows that deliver services that applications can take advantage of. The machine language used is very specific to your kind of computer and the Win32 calls make the executable very dependent on Windows. A .NET executable is not like that.

It is important to realize that a .NET executable (.EXE file) is not actually a native Windows application. Windows itself does not understand how to run the code in a .NET executable. Your computer does not understand it either.

Much like Java, a .NET application is made up of instructions in a language called CIL (Common Intermediate Language) that you can think of as the machine language for an idealized computer that does not really exist. In .NET, the software implementation of this idealized machine is called the Common Language Runtime (CLR). The equivalent in the Java world is called the Java Virtual Machine (JVM). In Java, the equivalent to CIL is called Java bytecode. CIL is sometimes called MSIL (Microsoft Intermediate Language).

CIL is designed to run on the CLR (an idealized machine) but is otherwise platform independent, which means that the CIL does not care what kind of computer you have or what operating system you are running.

Just as you need a native version of the Java JVM on each platform on which you want to run Java, you need a native version of the CLR to run .NET CIL executables. The CLR is a native Windows application just like the traditional Win32 EXE files described above. The CLR itself is specific to the Windows implementation and computer architecture on which it was designed to run.

It does not matter what .NET language you start with (C#, VisualBasic, F#, IronPython, IronRuby, Boo, etc.), they all get compiled down to CIL bytecode. You can easily “disassemble” a CIL program into a form of object-oriented assembly language that is easily readable by humans. You can write a program in CIL directly yourself but few people do.

On Windows, the CLR compiles this CIL code Just-in-Time (JIT) right when you run the executable–just before the code is actually run. This means that the CIL bytecode is converted (compiled) to actual machine code that runs natively on your computer. This part of the CLR is called the JIT compiler or often just the JIT.

To date, Microsoft has released four versions of the CLR: 1.0, 1.1, 2.0, and 4.0. You need to have the right version of the CLR installed on your machine if you want to run .NET executables targeting that runtime. The CLR 2.0 supports .NET 2.0, 3.0, and 3.5 applications. For other versions of .NET, the .NET version maps cleanly to the CLR version.

In addition to the JIT/CLR, .NET provides a host of libraries (assemblies) that make up the rest of the .NET framework and that provide a host of capabilities and services that .NET applications can call upon. The great majority of these assemblies are pure CIL code which runs on the CLR. On Windows, a some make calls into the Win32 API as well. When you install .NET, you are installing the CLR, the class libraries (framework), and a bunch of development tools. Each version of the CLR generally requires a complete set of these “framework” assemblies. Some versions of .NET (eg. 3.0 and 3.5) added additional framework assemblies without updating the CLR or the existing assemblies associated with that CLR.

The Portable Executable (PE) file format that a Windows .EXE file is delivered in contains a header that describes the executable and identifies the file as a .NET file or a native Win32 file. When Windows tries to run a .NET file, it sees this header and automatically invokes the CLR on your behalf. This is why .NET EXE files appear to run natively on Windows.

Ok, so how does Mono work?

Mono implements the CLR on Linux, Mac, and other platforms. The Mono runtime (the CLR) is a native application written mostly in the C language and compiled down to machine language code for the computer system on which is designed to run. Like on Windows, the Mono runtime is specific to the Operating System and kind of machine you are using.

Just like on Windows, the Mono runtime (the CLR) compiles the CIL bytecode in your .NET executable Just-in-time to native code that your computer can understand and execute. In this way, a .NET file is just as “native” to Linux as it is to Windows.

To port Mono to a new architecture you need to port the JIT/CLR. This is just like porting any native application to a new platform.

How well .NET code runs on Linux or Mac is really just a question of how well the CLR is implemented on these systems. In theory, the Mono CLR could execute .NET code on these systems much better than the MS version of .NET does on Windows. In practice, the MS implementation is generally superior (though not in all cases).

In addition to the CLR, Mono provides most of the rest of the libraries (assemblies) that make up the .NET framework. Just as with the Microsoft version of .NET (in fact more so) the Mono assemblies are provided as CIL bytecode. This makes it possible to take a *.dll or *.exe file from Mono and run it unmodified on Windows, Mac, or Linux as CIL is the “native” language of the CLR implementations on these systems.

Just like on Windows, Mono supports multiple versions of the CLR and the associated assemblies:

Very early versions of Mono (before 1.2?) only supported CLR 1.0 or 1.1.
Mono did not support big chunks of the 2.0 framework until it’s own 2.0 version.

Mono versions up to version 2.4 supported both CLR 1.1 and CLR 2.0 applications.

Starting with Mono 2.6, CLR 4.0 was added but CLR 2.0 was still the default.

Starting with Mono 2.8 the CLR 4.0 became the default and the CLR 1.1 is no longer supported.

Mono 2.10 continues to use the CLR 4.0 as default and also to support the CLR 2.0.

Just like the real .NET (but in far fewer cases) there are some Mono assemblies that call into native libraries. In order to make the System.Drawing assembly work on Mono, the Mono team wrote a Linux program to simulate the GDI+ portion of the Win32 API on Linux. This library is called ‘libgdiplus’. If you compile Mono from source, you will notice that you need to build this ‘libgdiplus’ file before you can build ‘mono’. You do not need ‘libgdiplus’ on Windows because the GDI+ portion of the Win32 API is already part of Windows. A full port of Mono to new platforms requires this ‘libgdiplus’ library to be ported as well.

In areas where the design of the .NET library is overly influenced by the design of Windows, and a poor fit for systems like Mac or Linux, the Mono team has written extensions to the .NET framework. The Mono extensions are also just CIL bytecode and generally work just fine on .NET.

Unlike on Windows, Linux generally does not detect .NET executables and launch the CLR by default. The user must usually run the CLR directly by typing ‘mono appname.exe’ or something similar. Here ‘mono’ is the application that implements the CLR and ‘appname.exe’ is the EXE file that contains the .NET code to be executed.

To make things easier for users, Mono applications are often wrapped in a shell script that launches the CLR. This hides the fact that the CLR is being used just as in Windows. It is also possible to tell Linux to launch the CLR when a file using the PE file format is encountered. This is usually not done as the PE file format is also used for native Win32 Windows executables which of course the CLR (Mono) does not support.

There is no technical reason why a PE launcher could not be used by Linux which then launches either a system that understands native Windows code (like Wine) or the CLR (Mono) as appropriate. This has simply not been done to my knowledge.

Back and forth

Any .NET code that sticks to “fully managed” code, which means it does not call into non-.NET code, should work fine on Mono on all platforms. I routinely use compiled .NET assemblies from Windows (for which I do not have the code) on Linux and Mac.

I can also take any code that I compile on Mono and run that on .NET on Windows. I can provide a client some code I compiled with Mono and not worry if he is on 32-bit or 64-bit Windows for example. The client does need to have the right version of .NET (the right CLR) installed fo course. CLR 2.0 has been around for a very long time and you can bet almost all Windows users have it installed. The Mono compilers and other code are also just CIL executables and so they run fine on Windows if you like.

Mono compatibility is good enough that large chunks of actual Microsoft code, like ASP.NET MVC, can be taken (where legal to do so) from the actual MS version of .NET and run on Mac or Linux. In general, the Mono team has done a great job of implementing both the CLR and the rest of the framework (class libraries/assemblies).

ASP.NET

On Windows, the Internet Information Server (IIS) knows how to call into the CLR to execute .NET as part of a web application. On Linux/Mac there is an Apache module (mod_mono) that provides similar capabilities to the Apache webserver. This application is written in C and must also be ported to new architectures.

Porting Mono

This discussion has identified parts of Mono that are built as “native” executables and must exist on a system on which you want to run .NET applications.

• The CLR (including JIT compiler) – generally known as Mono
• libgdiplus (for systems which do not natively support the GDI+ API [only Windows does])
• mod_mono (to allow Apache to invoke the CLR for .NET web applications)

These three components, with the addition of the class libraries, provide a .NET environment that looks “native” to the .NET executable files you need to run.

That is how Mono works.