Kenneth Westrom ELEC-6620 ELEC6200, Fall 07, Oct 29 Westrom: Virtual

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Kenneth Westrom ELEC-6620 ELEC6200, Fall 07, Oct 29 Westrom: Virtual Machines 1

Overview Intro Abstraction versus Virtualization Interfaces Process Virtual Machines System Virtual Machines Conclusion References ELEC6200, Fall 07, Oct 29 Westrom: Virtual Machines 2

Intro Virtual machines are “an efficient, isolated duplicate of a real machine” -Popek and Goldberg Popek and Goldberg introduced conditions for computer architecture to efficiently support system virtualization. ELEC6200, Fall 07, Oct 29 Westrom: Virtual Machines 3

Abstraction versus Virtualization Computer architecture benefits from Abstraction Well-defined interfaces for hardware and software to use Hard Drives, Networking, I/O devices Limits based on the hardware implementation Virtualization Maps interfaces and resources to various hardware, even different architectures ELEC6200, Fall 07, Oct 29 Westrom: Virtual Machines 4

Architecture Interfaces Virtualization can take place at these junctures ISA – Instruction Set Architecture ABI – Application Binary Interface API – Application Programming Interface ELEC6200, Fall 07, Oct 29 Westrom: Virtual Machines 5

Process Virtual Machines Also known as Application VM Virtualization below the API or ABI, providing virtual resources to a single process executed on a machine Created for the process alone, destroyed when process finishes ELEC6200, Fall 07, Oct 29 Westrom: Virtual Machines 6

Process VM, continued Multiprogrammed systems Each application is given effectively separate access to resources, managed by the OS Emulators and translators Executes program binaries compiled for different instruction sets. Slower, requiring hardware interpretation Optimization through storing blocks of converted code for repeated execution ELEC6200, Fall 07, Oct 29 Westrom: Virtual Machines 7

Process VM, continued Optimizers, Same ISA Perform code optimization during translation and execution High-level-language VM Cross-platform compatibiltiy Programs written for an abstract machine, which is mapped to real hardware through a virtual machine Sun Microsystems Java VM Microsoft Common Language Infrastructure, .NET framework ELEC6200, Fall 07, Oct 29 Westrom: Virtual Machines 8

System Virtual Machines Virtualized hardware below the ISA Single host can run multiple isolated operating systems Servers running different operating systems Isolation between concurrent systems, security Hardware Managed by the VMM – Virtual Machine Manager ELEC6200, Fall 07, Oct 29 Westrom: Virtual Machines 9

System VM, continued Classically, VMM runs on bare hardware, directly interacting with resources, Intercepts and interprets guest OS actions Hosted VM Installed application that relies on the OS to access hardware, using same ISA Whole System VM Emulate both application and system code for different ISAs Classically: Virtual PC, run windows on old Mac hardware ELEC6200, Fall 07, Oct 29 Westrom: Virtual Machines 10

System VM, continued Multiple operating systems on one machine Processor/resources timeshared Quality-of-service isolation Testing of insecure or questionable software and systems Better debugging ELEC6200, Fall 07, Oct 29 Westrom: Virtual Machines 11

Conclusions Virtual Machines can be useful in crossing boundaries based on ISA differences Hardware consolidation Cross-platform compatability ELEC6200, Fall 07, Oct 29 Westrom: Virtual Machines 12

References Smith, Daniel E.; Nair, Ravi. "The Architecture of Virtual Machines". Computer 38 (5): 32–38. IEEE Computer Society. Wikipedia, “Virtual Machine”. http://en.wikipedia.org/wiki/Virtual machine ELEC6200, Fall 07, Oct 29 Westrom: Virtual Machines 13

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