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1. Introduction
Virtualization is a proven software technology that is rapidly transforming the IT
landscape and fundamentally changing the way that people compute. Today’s powerful
x86 computer hardware was designed to run a single operating system and a single
application. This leaves most machines vastly underutilized. Virtualization lets you run
multiple virtual machines on a single physical machine, sharing the resources of that single
computer across multiple environments. Different virtual machines can run different
operating systems and multiple applications on the same physical computer.
Virtualization is a framework or methodology of dividing the resources of a computer
into multiple execution environments, by applying one or more concepts or technologies such
as hardware and software partitioning, time-sharing, partial or complete machine simulation,
emulation, quality of service, and many others.
Virtualization is technology for supporting execution of computer program code, from
applications to entire operating systems, in a software-controlled environment. Such a Virtual
Machine (VM) environment abstracts available system resources (memory, storage, CPU
core(s), I/O, etc.) and presents them in a regular fashion, such that “guest” software cannot
distinguish VM-based execution from running on bare physical hardware.
A virtual machine provides a software environment that allows software to run on
bare hardware. This environment is created by a virtual-machine monitor, also known as a
hypervisor. A virtual machine is an efficient, isolated duplicate of the real machine. The
hypervisor presents an interface that looks like hardware to the “guest” operating system. It
allows multiple operating system instances to run concurrently on a single computer; it is a
means of separating hardware from a single operating system. It can control the guests’ use of
CPU, memory, and storage, even allowing a guest OS to migrate from one machine to
another.
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Fig (1): Virtual Machine
Virtualization commonly refers to native virtualization, where the VM platform and
the guest software target the same microprocessor instruction set and comparable system
architectures. Virtualization can also involve execution of guest software cross-compiled for a
different instruction set or CPU architecture; such emulation or simulation environments help
developers bring up new processors and cross-debug embedded hardware.
It is also a method of partitioning one physical server computer into multiple “virtual”
servers, giving each the appearance and capabilities of running on its own dedicated machine.
Each virtual server functions as a full-fledged server and can be independently rebooted.
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2. History of Virtuali zation
Virtualization is a proven concept that was first developed in the 1960s by IBM as a
way to logically partition large, mainframe hardware into separate virtual machines.
These partitions allowed mainframes to "multitask"; run multiple applications and
processes at the same time.
Virtualization was effectively abandoned during the 1980s and 1990s when client-
server applications and inexpensive x86 servers and desktops established the model of
distributed computing. The growth in x86 server and desktop deployments has
introduced new IT infrastructure and operational challenges. These challenges include:
Low Infrastructure Utilization - Typical x86 server deployments achieve an
average utilization of only 10% to 15% of total capacity. Organizations typically run one
application per server to avoid the risk of vulnerabilities in one application affecting the
availability of another application on the same server.
Increasing Physical Infrastructure Costs - The operational costs to support
growing physical infrastructure have steadily increased. Most computing infrastructure
must remain operational at all times, resulting in power consumption, cooling and
facilities costs that do not vary with utilization levels.
Increasing IT Management Costs - As computing environments become more complex,
the level of specialized education and experience required for infrastructure
management personnel and the associated costs of such personnel have increased.
Organizations spend disproportionate time and resources on manual tasks associated with
server maintenance, and thus require more personnel to complete these tasks.
Insufficient Failover and Disaster Protection - Organizations are increasingly affected
by the downtime of critical server applications and inaccessibility of critical end user
desktops. The threat of security attacks, natural disasters, health pandemics and terrorism
has elevated the importance of business continuity planning for both desktops and servers.
High Maintenance end-user desktops - Managing and securing enterprise desktops
present numerous challenges. Controlling a distributed desktop environment and
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enforcing management, access and security policies without impairing users' ability to
work effectively is complex and expensive.
Today, computers based on x86architecture are faced with the same problems of
rigidity and underutilization that mainframes faced in the 1960s.
Today's powerful x86 computer hardware was originally designed to run only a single
operating system and a single application, but virtualization breaks that bond, making
it possible to run multiple operating systems and multiple applications on the same
computer at the same time, increasing the utilization and flexibility of hardware.
Why Virtuali zation: A List of
Reasons
Following are some reasons for and benefits of virtualization:
○ Virtual machines can be used to consolidate the workloads of several under-utilized
servers to fewer machines, perhaps a single machine (server consolidation).
○ The need to run legacy applications is served well by virtual machines. A legacy
application might simply not run on newer hardware and/or operating systems. Even
if it does, if may under-utilize the server,
○ Virtual machines can be used to provide secure, isolated sandboxes for running
untrusted applications. You could even create such an execution environment
dynamically - on the fly - as you download something from the Internet and run it.
○ Virtual machines can be used to create operating systems, or execution environments
with resource limits, and given the right schedulers, resource guarantees.
○ Virtual machines can provide the illusion of hardware, or hardware configuration that
you do not have (such as SCSI devices, multiple processors,) Virtualization can also be used to simulate networks of independent computers.
○ Virtual machines can be used to run multiple operating systems simultaneously:
different versions, or even entirely different systems, which can be on hot standby.
Some such systems may be hard or impossible to run on newer real hardware.
○ Virtual machines allow for powerful debugging and performance monitoring.
○ Virtual machines can isolate what they run, so they provide fault and error
containment. You can inject faults proactively into software to study its subsequent
behavior.
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○ Virtual machines are great tools for research and academic experiments. Since they
provide isolation, they are safer to work with. They encapsulate the entire state of a
running system: you can save the state, examine it, modify it, reload it, and so on. The
state also provides an abstraction of the workload being run.
○ Virtualization can enable existing operating systems to run on shared memory
multiprocessors.
3.Virtual machine & Hyp ervisor
VIRTUAL MACHINE
Virtual machine (VM) is a software implementation of a machine (computer) that
executes programs like a real machine.
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Fig(4): Connectix Virtual PC version 3 in Mac OS 9, running a Windows 95
A virtual machine was originally defined by Popek and Goldberg as "an efficient,
isolated duplicate of a real machine".
Virtual machines are separated into two major categories, based on their use
and degree of correspondence to any real machine. A system virtual machine provides a
complete system platform which supports the execution of a complete operating system
(OS). Process virtual machine is designed to run a single program, which means that it
supports a single process. An essential characteristic of a virtual machine is that the
software running inside is limited to the resources and abstractions provided by the virtual
machine -- it cannot break out of its virtual world.
System virtual machines
System virtual machines (sometimes called hardware virtual machines) allow
the sharing of the underlying physical machine resources between different virtual
machines, each running its own operating system. The software layer providing the
virtualization is called a virtual machine monitor or hypervisor. A hypervisor can run
on bare hardware
(Type 1 or native VM) or on top of an operating system (Type 2 or hosted
VM). The main advantages of system VMs are:
○ multiple OS environments can co-exist on the same computer, in strong isolation from
each other
○ the virtual machine can provide an instruction set architecture (ISA) that is
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somewhat different from that of the real machine.
The guest OS’s do not have to be all the same, making it possible to run different OS’s on
the same computer (e.g., Microsoft Windows and Linux, or older versions of an OS in
order to support software that has not yet been ported to the latest version).
Process virtual machines
A process VM, sometimes called an application virtual machine, runs as a
normal application inside an OS and supports a single process. It is created when that
process is started and destroyed when it exits. Its purpose is to provide a platform-
independent programming environment that abstracts away details of the
underlying hardware or operating system, and allows a program to execute in the same
way on any platform.
A process VM provides a high-level abstraction — that of a high-level
programming language (compared to the low-level ISA abstraction of the system VM).
Process VMs are implemented using an interpreter; performance comparable to compiled
programming languages is achieved by the use of just-in-time compilation.
4 . Hypervisor
A hypervisor, also called virtual machine monitor (VMM ), is a computer hardware platform virtualization software that allows multiple operating systems to run
on a host computer concurrently.
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In computing, a hypervisor, also called virtual Machine Manager (VMM), is one of many
virtualization techniques which allow multiple operating systems, termed guests, to run
concurrently on a host computer, a feature called hardware virtualization. It is so named because it
is conceptually one level higher than a supervisor. The hypervisor presents to the guest operating
systems a virtual operating platform and manages the execution of the guest operating systems.
Multiple instances of a variety of operating systems may share the virtualized hardware resources.
Hypervisors are installed on server hardware whose only task is to run guest operating systems.
Non-hypervisor virtualization systems are used for similar tasks on dedicated server hardware, but
also commonly on desktop.
Classifications
Hypervisors are classified in two types:
Type 1 (or native, bare-metal ) hypervisors are software systems that run directly on the host's
hardware as a hardware control and guest operating system monitor. A guest operating system thus
runs on another level above the hypervisor.
Type 2 (or hosted ) hypervisors are software applications running within a conventional operating
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system environment. Considering the hypervisor layer being a distinct software layer, guest operating
systems thus run at the third level above the hardware.
5.Popek and Goldberg virtualization requirements
The Popek and Goldberg virtualization requirements are a set of
sufficient conditions for computer architecture to efficiently support system
virtualization. They were introduced by Gerald J. Popek and Robert P. Goldberg in their
1974 article " Formal Requirements for Virtualizable Third Generation Architectures".
There are three properties of interest when analyzing the environment created by aVMM:
Equivalence: A program running under the VMM should exhibit a behavior essentially identicalto that demonstrated when running on an equivalent machine directly.
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Resource control : The VMM must be in complete control of the virtualized resources.
Efficiency: A statistically dominant fraction of machine instructions must be executed withoutVMM intervention.
In Popek and Goldberg terminology, a VMM must present all three properties.
VMM are typically assumed to satisfy the equivalence and resource control properties.
So, in a sense, Popek and Goldberg's VMMs are today's efficient VMM.
The main result of Popek and Goldberg's analysis can then be expressed asfollows.
Theorem 1. For any conventional third-generation computer, a VMM may be constructedif the set of sensitive instructions for that computer is a subset of the set of
privileged instructions.
Theorem 2. A conventional third-generation computer is recursively Virtualizable if
1. It is Virtualizable and
2. A VMM without any timing dependencies can be constructed for it.
6.Classification o f Virtuali zation
Here we discuss about different types of virtualization.
Platform virtualization, which separates an operating system from the underlying platform
resources
o Full virtualization
o Hardware-assisted virtualization
o Partial virtualization
Resource virtualization, the virtualization of specific system resources, such as storage volumes,
name spaces, and network resources
Storage virtualization, the process of completely abstracting logical storage
from physical storage
RAID - redundant array of independent disks
Disk partitioning
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Network virtualization, creation of a virtualized network addressing space within or across
network subnets.
Application virtualization, the hosting of individual applications on alien hardware/software
Desktop virtualization, the remote manipulation of a computer desktop
7. Platform virtuali zation
Platform virtualization is a virtualization of computers or operating systems. It hides the
physical characteristics of computing platform from the users, instead showing another
abstract, emulated computing platform.
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Concept
The creation and management of virtual machines has been called
platform virtualization, or server virtualization.
Platform virtualization is performed on a given hardware platform by host software
(a control program), which creates a simulated computer environment, a virtual machine,
for its guest software. The guest software, which is often itself a complete operating
system, runs just as if it were installed on a stand-alone hardware platform. Typically,
many such virtual machines are simulated on a single physical machine, their number
limited by the host’s hardware resources. Typically there is no requirement for a guest
OS to be the same as the host one. The guest system often requires access to specific
peripheral devices to function, so the simulation must support the guest's interfaces to
those devices. Trivial examples of such devices are hard disk drive or network interface
card.
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There are several approaches to platformvirtualization.
Fullvirtualization
In full virtualization, the virtual machine simulates enough hardware to allow
an unmodified "guest" OS (one designed for the same instruction set) to be run in isolation.
This approach was pioneered in 1966 with IBM CP-40 and CP-67, predecessors of VM
family.
Hardware-assistedvirtualization
In hardware-assisted virtualization, the hardware provides architectural support that
facilitates building a virtual machine monitor and allows guest OSes to be run in isolation.
In
2005 and 2006, Intel and AMD provided additional hardware to support virtualization.
Examples include Linux KVM, VMware Workstation, VMware Fusion, Microsoft
Virtual PC, Xen, Parallels Desktop for Mac, VirtualBox and Parallels Workstation.
Partial
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The virtualization of specific system resources, such as storage volumes, name
spaces, and network resources is the resource virtualization.
Storage Virtuali zation\Server Virtualization
Storage virtualization is the pooling of multiple physical storage resources into
what appears to be a single storage resource that is centrally managed. Storage
virtualization automates tedious and extremely time-consuming storage administration
tasks. This means the storage administrator can perform the tasks of backup, archiving,
and recovery more easily and in less time, because the overall complexity of the
storage infrastructure is disguised. Storage virtualization is commonly used in file
systems, storage area networks (SANs), switches and virtual tape systems. Users can
implement storage virtualization with software, hybrid hardware or software appliances.
Virtualization hides the physical complexity of storage from storage administrators and
applications, making it possible to manage all storage as a single resource. In addition to
easing the storage management burden, this approach dramatically improves the efficiency
and cuts overall costs.
The A dvantages of Storage V i rtua liz ation
Storage virtualization provides many advantages.
First, it enables the pooling of multiple physical resources into a smaller number
of resources or even a single resource, which reduces complexity. Many environments
have become complex, which increases the storage management gap. With regard to
resources, pooling is an important way to achieve simplicity. A second advantage of
using storage virtualization is that it automates many time-consuming tasks. In other
words, policy-driven virtualization tools take people out of the loop of addressing eachalert or interrupt in the storage business. A third advantage of storage virtualization is that
it can be used to disguise the overall complexity of the infrastructure.
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Fig (8): VMware Workstation 6.5 running Ubuntu The Snapshot Manager in VMware
Workstation 6
VMware Workstation is a virtual machine software suite for x86 and x86-64
computers from VMware, a division of EMC Corporation. This software suite allows users
to set up multiple x86 and x86-64 virtual computers and to use one or more of these virtual
machines simultaneously with the hosting operating system. Each virtual machine instance
can execute its own guest operating system, such as Windows, Linux, BSD variants, or
others. In simple terms, VMware Workstation allows one physical machine to run multiple
operating systems simultaneously.
Microsoft VirtualServer
Microsoft Virtual Server is a virtualization solution that facilitates the creation
of virtual machines on the Windows XP, Windows Vista and Windows Server 2003
operating systems. Originally developed by Connectix, it was acquired by Microsoft
prior to release. Virtual PC is Microsoft's related desktop virtualization software package.
Virtual machines are created and managed through an IIS web-based interface
or through a Windows client application tool called VMRCplus.
Microsoft VirtualPC
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Microsoft Virtual PC is a virtualization suite for Microsoft Windows operating
systems, and an emulation suite for Mac OS X on PowerPC-based systems. The software
was originally written by Connectix, and was subsequently acquired by Microsoft. In
July 2006
Microsoft released the Windows-hosted version as a free product. In August 2006
Microsoft announced the Macintosh-hosted version would not be ported to Intel-based
Macintoshes, effectively discontinuing the product as PowerPC-based Macintoshes
are no longer manufactured.
VirtualBox
VirtualBox is an x86 virtualization software package, originally created by
German software company innotek, now developed by Sun Microsystems as part of its
Sun xVM virtualization platform. It is installed on an existing host operating system;
within this application, additional operating systems, each known as a Guest OS , can be
loaded and run, each with its own virtual environment.
Xen
Xen is a virtual machine monitor for IA-32, x86, x86-64, IA-64 and PowerPC
970 architectures. It allows several guest operating systems to be executed on the same
computer hardware concurrently. Xen was initially created by the University of
Cambridge Computer
1 1 .C onclusion
Virtualization dramatically improves the efficiency and availability of resources and
applications. Earlier Internal resources are underutilized under the old “one server,
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one application” model and users spend too much time managing servers rather innovating.
By virtualization platform, users can respond faster and more efficiently than ever before.
Users can save50-70% on overall IT costs by consolidating their resource pools and
delivering highly available machines.
Other major improvements by using virtualization are that they can:
○ Reduce capital costs by requiring less hardware and lowering operational
costs while increasing your server to admin ratio
○ Ensure enterprise applications perform with the highest availability and
performance
○ Build up business continuity through improved disaster recovery
solutions and deliver high availability throughout the datacenter
○ Improve desktop management with faster deployment of desktops and fewer
support calls due to application conflicts.
○ Even after the implementations of distributed computing and other
technologies, virtualization proved to be an effective in using the available
resources of a system fully in an efficient way.
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R eferences
Websites:
1) http:// www.wikipedia.com
2) http://w w w .v mware.c o m
3) http:// w w w .kernalthread.com
4) http:// w w w .virt u alizationad m in . com
5) http:// w w w .virt u alization.o r g
6) http:// w w w . m icrosft.co m/ v irtualization.aspx
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