Xen supported virtualization types
Xen supports running two different
types of guests. Xen guests are often
called as domUs (unprivileged
domains). Both guest types (PV, HVM)
can be used at the same time on a
single Xen system.
Xen Paravirtualization (PV)
Paravirtualization is an efficient and
lightweight virtualization technique
introduced by Xen, later adopted also
by other virtualization solutions.
Paravirtualization doesn't require
virtualization extensions from the
host CPU. However paravirtualized
guests require special kernel that is
ported to run natively on Xen, so the
guests are aware of the hypervisor and
can run efficiently without emulation
or virtual emulated hardware. Xen PV
guest kernels exist for Linux, NetBSD,
FreeBSD, OpenSolaris and Novell
Netware operating systems.
PV guests don't have any kind of
virtual emulated hardware, but
graphical console is still possible
using guest pvfb (paravirtual
framebuffer). PV guest graphical
console can be viewed using VNC
client, or Redhat's virt-viewer.
There's a separate VNC server in dom0
for each guest's PVFB.
Upstream kernel.org Linux kernels
since Linux 2.6.24 include Xen PV
guest (domU) support based on the
Linux pvops framework, so every
upstream Linux kernel can be
automatically used as Xen PV guest
kernel without any additional patches
or modifications.
See XenParavirtOps wiki page for more
information about Linux pvops Xen
support.
Xen Full virtualization (HVM)
Fully virtualized aka HVM (Hardware
Virtual Machine) guests require CPU
virtualization extensions from the
host CPU (Intel VT, AMD-V). Xen uses
modified version of Qemu to emulate
full PC hardware, including BIOS, IDE
disk controller, VGA graphic adapter,
USB controller, network adapter etc
for HVM guests. CPU virtualization
extensions are used to boost
performance of the emulation. Fully
virtualized guests don't require
special kernel, so for example Windows
operating systems can be used as Xen
HVM guest. Fully virtualized guests
are usually slower than
paravirtualized guests, because of the
required emulation.
To boost performance fully virtualized
HVM guests can use special paravirtual
device drivers to bypass the emulation
for disk and network IO. Xen Windows
HVM guests can use the opensource
GPLPV drivers. See
XenLinuxPVonHVMdrivers wiki page for
more information about Xen PV-on-HVM
drivers for Linux HVM guests.
KVM is not Xen at all, it is another technology, where KVM is a Linux native kernel module and not an additional kernel, like Xen. Which makes KVM a better design. the downside here is that KVM is newer than Xen, so it might be lacking some of the features.
Best Answer
Qemu:
QEmu is a complete and standalone software of its own. You use it to emulate machines, it is very flexible and portable. Mainly it works by a special 'recompiler' that transforms binary code written for a given processor into another one (say, to run MIPS code on a PPC mac, or ARM in an x86 PC).
To emulate more than just the processor, Qemu includes a long list of peripheral emulators: disk, network, VGA, PCI, USB, serial/parallel ports, etc.
KQemu:
In the specific case where both source and target are the same architecture (like the common case of x86 on x86), it still has to parse the code to remove any 'privileged instructions' and replace them with context switches. To make it as efficient as possible on x86 Linux, there's a kernel module called KQemu that handles this.
Being a kernel module, KQemu is able to execute most code unchanged, replacing only the lowest-level ring0-only instructions. In that case, userspace Qemu still allocates all the RAM for the emulated machine, and loads the code. The difference is that instead of recompiling the code, it calls KQemu to scan/patch/execute it. All the peripheral hardware emulation is done in Qemu.
This is a lot faster than plain Qemu because most code is unchanged, but still has to transform ring0 code (most of the code in the VM's kernel), so performance still suffers.
KVM:
KVM is a couple of things: first it is a Linux kernel module—now included in mainline—that switches the processor into a new 'guest' state. The guest state has its own set of ring states, but privileged ring0 instructions fall back to the hypervisor code. Since it is a new processor mode of execution, the code doesn't have to be modified in any way.
Apart from the processor state switching, the kernel module also handles a few low-level parts of the emulation like the MMU registers (used to handle VM) and some parts of the PCI emulated hardware.
Second, KVM is a fork of the Qemu executable. Both teams work actively to keep differences at a minimum, and there are advances in reducing it. Eventually, the goal is that Qemu should work anywhere, and if a KVM kernel module is available, it could be automatically used. But for the foreseeable future, the Qemu team focuses on hardware emulation and portability, while KVM folks focus on the kernel module (sometimes moving small parts of the emulation there, if it improves performance), and interfacing with the rest of the userspace code.
The kvm-qemu executable works like normal Qemu: allocates RAM, loads the code, and instead of recompiling it, or calling KQemu, it spawns a thread (this is important). The thread calls the KVM kernel module to switch to guest mode and proceeds to execute the VM code. On a privileged instruction, it switches back to the KVM kernel module, which, if necessary, signals the Qemu thread to handle most of the hardware emulation.
One of the nice things of this architecture is that the guest code is emulated in a posix thread which you can manage with normal Linux tools. If you want a VM with 2 or 4 cores, kvm-qemu creates 2 or 4 threads, each of them calls the KVM kernel module to start executing. The concurrency—if you have enough real cores—or scheduling—if not—is managed by the normal Linux scheduler, keeping code small and surprises limited.