In full emulation the I/O devices, CPU, main memory are virtualized. The guest operating system would access virtual devices not physical devices. But what exactly is full virtualization? Is it the same as full emulation or something totally different?
Emulation and virtualization are related but not the same.
Emulation is using software to provide a different execution environment or architecture. For example, you might have an Android emulator run on a Windows box. The Windows box doesn't have the same processor that an Android device does so the emulator actually executes the Android application through software.
Virtualization is more about creating virtual barriers between multiple virtual environments running in the same physical environment. The big difference is that the virtualized environment is the same architecture. A virtualized application may provide virtualized devices that then get translated to physical devices and the virtualization host has control over which virtual machine has access to each device or portion of a device. The actual execution is most often still executed natively though, not through software. Therefore virtualization performance is usually much better than emulation.
There's also a separate concept of a Virtual Machine such as those that run Java, .NET, or Flash code. They can vary from one implementation to the next and may include aspects of either emulation or virtualization or both. For example, the JVM provides a mechanism to execute Java byte codes. However, the JVM spec doesn't dictate that the byte codes must be executed by software or that they must be compiled to native code. Each JVM can do it's own thing and in fact most JVMs do a combination of both using emulation where appropriate and using a JIT where appropriate (the Hotspot JIT I think is what it's called for Sun/Oracle's JVM).
In full emulation the I/O devices , CPU , main memory are virtualized.
No, they are emulated in software. Emulated means that their behavior is completely replicated in software.
But what exactly is full virtualization?
With virtualization, you try to run as much code as you can on the on hardware to speed up the process. This is especially a problem with code that had to be run in kernel mode, as that could potentially change the global state of the host (machine the Hypervisor or VMM is running on) and thereby affect other virtual machines.
This is an attempt to answer my own question.
Virtualization as a concept enables multiple/diverse applications to co-exist on the same underlying hardware without being aware of each other.
As an example, full blown operating systems such as Windows, Linux, Symbian etc along with their applications can coexist on the same platform. All computing resources are virtualized.
What this means is none of the aforesaid machines have access to physical resources. The only entity having access to physical resources is a program known as Virtual Machine Monitor (aka Hypervisor).
Now this is important. Please read and re-read carefully.
The hypervisor provides a virtualized environment to each of the machines above. Since these machines access NOT the physical hardware BUT virtualized hardware, they are known as Virtual Machines.
As an example, the Windows kernel may want to start a physical timer (System Resource). Assume that ther timer is memory mapped IO. The Windows kernel issues a series of Load/Store instructions on the Timer addresses. In a Non-Virtualized environment, these Load/Store would have resulted in programming of the timer hardware.
However in a virtualized environment, these Load/Store based accesses of physical resources will result in a trap/Fault. The trap is handled by the hypervisor. The Hypervisor knows that windows tried to program timer. The hypervisor maintains Timer data structures for each of the virtual machines. In this case, the hypervisor updates the timer data structure which it has created for Windows. It then programs the real timer. Any interrupt generated by the timer is handled by the hypervisor first. Data structures of virtual machines are updated and the latter's interrupt service routines are called.
To cut a long story short, Windows did everything that it would have done in a Non-Virtualized environment. In this case, its actions resulted in NOT the real system resource being updated, but virtual resources (The data structures above) getting updated.
Thus all virtual machines think they are accessing the underlying hardware; In reality unknown to them, all accesses to physical hardware is mediated through by the hypervisor.
Everything described above is full/classic virtualization. Most modern CPUs are unfit for classic virtualization. The trap/fault does not apply to all instructions. So the hypervisor is easily bypassed on modern devices.
Here is where para-virtualization comes into being. The sensitive instructions in the source code of virtual machines are replaced by a call to Hypervisor. The load/store snippet above may be replaced by a call such as
Hypervisor_Service(Timer Start, Windows, 10ms);
Emulation is a topic related to virtualization. Imagine a scenario where a program originally compiled for ARM is made to run on ATMEL CPU. The ATMEL CPU runs an Emulator program which interprets each ARM instruction and emulates necessary actions on ATMEL platform. Thus the Emulator provides a virtualized environment.
In this case, virtualization of system resources is NOT performed via trap and execute model.
A more recent response:
From my research i can say that this is a better response to understand how concept appear:
The first concept of emulation actually dates back to the first computer, the Colossus. It was used by the British government in 1941 to mimic the functions of the Nazi Enigma code machine. Emulation theory was developed in 1962 and was conceived by three IBM engineers working from three different angles.
Emulation means to mimic the behavior of the target which can be hardware, like the emu8086 emulator, or can be software like emulation of a service from some network port.
You want to immitate the set of functions provided by the target and maybe you are not interested in the internal mechanism.
Why would you want that? For controlling that functions. Why control? For multiple reason which is very large subject to be discuss here. But keep in mind that you want to be behind the things.
But such process is costly for performance. You have an instruction for which are executed a lot of other instruction. Maybe you are interested to control only some of that instructions. So we would like to permit some of instructions to be executed native.
So what happens when all of this instructions execution became native? Then you have ideal virtualization. You can virtualize any software, but the trend today is to pass from virtualization of operating systems to that of application. Also i say ideal because this software have a different execution on each hardware so it will be need to also emulate some instructions.Is important to understand that most of virtualize technologies from today are not only about virtualize, but also about emulation.
Also notice that in our transition from emulation to virtualization, the input which of system is reduced, because virtualization accept only software as input. The controller of these flow of instructions is named HyperVisor.
Without either emulation or virtualization, code runs directly on the hardware. Its instructions are executed natively by the CPU, and its I/O accesses directly access the hardware.
Virtualization is when the guest code runs natively at least some of the time, and only traps to host code running outside the virtual-machine (e.g. a hypervisor) for privileged operations or I/O accesses.
To handle these traps (aka VM exits), the VM may actually emulate what the guest was trying to do. E.g. the guest might be running a device driver for a simple network card, but the NIC is implemented purely in software in the VM. If the VM used a pass-through to send the guest's I/O accesses to a real network card on the host, that would be virtualization of that hardware. (Especially if it did it in a way that let multiple guest use it at once, otherwise it's really just giving it to one guest, not virtualizing it.)
Hardware support for virtualization (like Intel's and AMD's separate x86 virtualization extensions) can let the guest do things that would normally affect the whole machine, like modify the memory mappings in a page table. So instead of triggering a VM exit and making the VM figure out what the guest was doing and then modifying things from the outside to achieve the result, the CPU just has an extra translation layer built in. (See the linked wiki article for a much better but longer description of software-based virtualization vs. hardware-assisted virtualization.)
Pure emulation means that guest code never runs natively, and never sees the "real" hardware of the host. An emulator doesn't need privileged access to the host. (Some might want privileged access to the host for device pass-through, or for raw network sockets to let a guest look like it's really attached to the same network as the host).
An ARM emulator running on an x86 host always has to work this way, because the host hardware can't run ARM instructions in the first place.
But you can still emulate an x86 guest on an x86 host, for example. The fact that the guest and host architectures match doesn't mean the emulator has to take advantage of that fact.
For example, BOCHS is an x86 PC emulator written in portable C++. One of its main uses is for debugging bootloaders and OSes.
BOCHS doesn't care if it's running on an x86 host or not. It's just a C++ program that reads binary files (disk images) and draws in a window (contents of guest video memory). As far as the host is concerned, it's not particularly different from a JPG viewer or a game.
Some emulators use binary translation to JIT-compile the guest code into host code, but this is still emulation, not virtualization. See http://wiki.osdev.org/Emulator_Comparison.
BOCHS is relatively slow, since it reads and decodes guest instructions directly, without doing binary translation. But it tries to do this as efficiently as possible. See How Bochs Works Under the Hood for some of the tricks it uses to efficiently keep track of the guest state. Since emulation is the only option for running x86 software on non-x86 hardware, it's useful to have a high-performance emulator. BOCHS has some very smart and experienced emulator developers working on it, notably Darek Mihocka, who has some interesting articles about optimizing emulation on his site.
Virtualization may happen at different layers of a computer architecture, which are (from higher to lower): 1: Application, 2: Library, 3: Operating System, 4: Hardware Abstraction (HAL), 5: Instruction Set Architecture (ISA). Below the latter layer there is the Hardware.
Tipically a certain layer utilizes services from a lower layer by utilizing the instructions the lower layer exposes in its interface.
Note that the usage of service is not strictly related to the layering, in the sense that certain layers can skip the layer immediately below and utilize instruction from lower layers. As an example an Applications may provide certain instructions directly to the HAL layer, skipping the Library and O.S. layers.
To "emulate an instruction" means to intercept and map an instruction intended for a certain layer of a computer architecture (virtual) into a sequence (one or more) instruction(s) for the same layer of a different computer architecture (non-virtual). It is possible to place the virtualization layer at different layers of a Computer Architecture. This point may introduce confusion. As an example, when virtualizing at the level of the Hardware Abstraction Layer (e.g. VMware, VirtualBox), a virtual layer is placed between the HAL layer and the Operating system Layer. The Operating system utilizes instructions of the virtual HAL Layer, then certain virtual ISA (Instruction Set Architecture) are mapped by the hypervisor to ISA for the physical system. When ALL the instruction are emulated, we talk about full emulation, which is a special case of virtualization. In virtualization tipically we try to make a layer to execute directly instruction of the non-virtual layer as much as possible for performance reasons. In another example, the virtualization layer is placed over the Operative System (Virtualization at Operative System Level): in this case a Virtual Machine is named Container (e.g. Docker). It includes the levels from Application to the O.S. (included).
To conclude, emulation is related to single instruction, while "full emulation" happens when we intercept and map ALL the instructions of a certain layer. Tipically, the term "full emulation" is used when the virtualization layer is placed at the ISA level (lower level possible). In this case a Virtual Machine includes all the levels from the Application to the ISA, and ALL the ISA are intercepted and mapped. This is tipically used to virtualize niche products, such as Cisco routers (e.g. with QEMU) or 90's video game consoles, having a completely different architecture from the usual commonly available computers. Note however that there may be a "full emulation" also at other levels, which is tipically not necessary.
Virtualization and Emulation are pretty much the same thing. There is one underlying concept that these two words hint at. That is, these two words are aspects of one thing. This is demonstrated in QEMU, a Quick Emulator that performs hardware virtualization.
You can think of that one thing as Simulation. Simulation can also be a confusing word though.
First we can define the common meaning of the words.
- Simulation: Making one thing do what another thing does.
- Emulation: Making one system replicate another system exactly.
- Virtualization: Allow for running of a system within another system.
Now we show that the words all mean pretty much the same thing. For example, in simulation you are creating a replica of one system with another system. That is the common meaning of emulation. In virtualization, you want to have your virtualized system act like the real system. That is, ideally it acts like a replica, even though it may be implemented differently and may not "emulate" the hardware exactly. That is the same as simulation pretty much. In an emulation, you simulate another system, etc..
So we can see that the words are somewhat interchangeable. The underlying concept is simulation.
In virtualization, such as operating system virtualization ("virtual machines"), we are creating a system which acts like the operating system. It might use tricks from the underlying hardware, or hypervisors, or other things, for performance and security. But in the end it is just a simulation of an operating system. Typically when the word "virtual machine" is used, it is not an exact replica of the machine (as in an emulator). It just does enough to allow programs to run as you would expect on the real operating system.
In emulation, it is typically meant that the simulation is "exact". In hardware emulation, you replicate all of the features of the hardware system. This means that you have created a simulation of the hardware. You could say that you created a virtualization of the hardware, but here is where virtualization slightly differs. Virtualization implies creating an isolated environment, which emulation doesn't necessarily imply. So a hardware emulator might provide the same interface to the hardware as the hardware itself, but the implementation of the emulator might rely on global memory, so if you try to run two emulators at the same time, they would interfere with each other. This is what virtualization solves, it isolates the simulations.
Hope that helps.