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Operating System Support

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Title: 08 Operating System Support Author: Adrian J Pullin Last modified by: lcrum Created Date: 4/23/1999 3:59:55 PM Document presentation format – PowerPoint PPT presentation

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Title: Operating System Support


1
Chapter 8
  • Operating System Support
  • Focus on Architecture

2
Functions of Operating System
  • Managing Resources
  • Access to System Utilities
  • Access to files
  • Access to I/O devices
  • Managing Interrupts Bus Control
  • Error detection and response
  • Accounting
  • Scheduling Processes (or tasks)
  • Program creation
  • Program execution
  • I/O Processing
  • Managing Memory Utilization
  • Partitioning,
  • Paging,
  • Virtual memory,
  • Segmentation

3
Types of Operating Systems
  • Interactive
  • Batch
  • Uni-tasking
  • Multi-tasking
  • Real-Time

4
Batch Operating System Model
  • Jobs are batched in queue
  • Monitor handles scheduling
  • Monitor controls sequence of
  • events to process batch
  • When one job is finished,
  • control returns to Monitor
  • which loads next job

5
Desirable Hardware Support for OS
  • Memory protection
  • To protect the Monitor Utilities
  • Timer
  • To prevent a job monopolizing the system
  • Privileged instructions
  • Only executed by Monitor
  • e.g. I/O, files
  • Interrupts
  • Allows for relinquishing and regaining control
  • DMA
  • Allows for optimizing bus usage

6
The Case for Multi-programmed Batch Systems
  • I/O devices are very slow
  • ? Waiting is inefficient use of computer
  • When one program is waiting for I/O, another can
    use the CPU

7
Multi-Programming with Three Programs
8
Utilization Uni-programmed vs Multi-programmed
9
Multiprogramming Resource Utilization
10
Types of Scheduling
11
A Five State Process Model
12
Process Control Block Layout
13
Scheduling Time Sequence Example
14
Key Elements of O/S
15
Process Scheduling
16
Memory Management
  • Uni-programming
  • Memory split into two
  • One for Operating System (monitor)
  • One for currently executing program
  • Multi-programming
  • User part is sub-divided and shared among
    active processes
  • Note Memory size implications
  • - 16 bits ? 64K memory addresses
  • - 24 bits ? 16M memory addresses
  • - 32 bits ? 4G memory addresses

17
Swapping
  • Problem I/O is so slow compared with CPU that
    even in multi-programming system, CPU can be idle
    most of the time
  • Solutions
  • Increase amount of main memory
  • Expensive
  • Swapping

18
What is Swapping?
  • Long term queue of processes stored on disk
  • Processes swapped in as space becomes available
  • As a process completes it is moved out of main
    memory
  • If none of the processes in memory are ready
    (i.e. all I/O blocked)
  • Swap out a blocked process to intermediate queue
  • Swap in a ready process or a new process

But swapping is an I/O process Isnt I/O
slow? So why does swapping make sense ?

19
Implementation of Swapping
20
Partitioning
  • Partitioning
  • May not be equal size
  • Splitting memory into sections to
    allocate to processes
  • (including Operating System!)
  • Fixed-sized partitions
  • Potentially a lot of wasted memory
  • Variable-sized partitions
  • Process is stored into smallest reasonable hole
  • Dynamic partitions
  • no room for additional memory allocation
  • memory leak need periodic coalescing, or
  • need periodic compaction

21
Fixed Partitioning
22
Effect of Dynamic Partitioning memory leaks
23
Relocation Challenges
  • Cant expect that process will load into the same
    place in memory as last time
  • Instructions contain addresses
  • Locations of data
  • Addresses for instructions (branching)
  • Logical address - relative to beginning of
    program
  • Physical address - actual location in memory
  • (this time)
  • A Solution
  • Use Base Address
  • Automatic (hardware) Conversion

24
Paging
  • Split memory into equal sized, small chunks
  • - page frames
  • Operating System maintains list of free frames
  • Then
  • Split programs (processes) into equal sized small
    chunks
  • pages
  • Allocate the required number page frames to a
    process
  • - A process does not require contiguous page
    frames
  • - Each process has its own page table

25
Allocation of Free Frames
26
Paging - Logical and Physical Addresses
27
Paging Implementations
  • Demand paging
  • Do not require all pages of a process in memory
  • Bring in pages as required
  • Page fault
  • Required page is not in memory
  • Operating System must swap in required page
  • May need to swap out a page to make space
  • Perhaps select page to throw out based on recent
    history

28
Thrashing
  • Too many processes in too little memory
  • Operating System spends all its time swapping
  • Little or no real work is done
  • Solutions
  • Good page replacement algorithms
  • Reduce number of processes running
  • Add more memory

29
Virtual Memory
  • We do not need all of a process in memory for it
    to run - We can swap in pages as required
  • So - we can now run processes that are bigger
    than total memory available!
  • Differentialtions
  • Main memory is called real memory
  • User/programmer can see much bigger memory space
    - virtual memory
  • Implications
  • Tables can become huge that cant fit into memory
    need multiple level tables yech!

30
Alternate Inverted Page Table Structure
31
Translation Lookaside Buffer
  • Every virtual memory reference causes two
    physical memory access
  • Fetch page table entry
  • Fetch data
  • Use special cache for page table(s)

32
TLB and Cache Operation (special Cache for
tables)
33
Segmentation
  • What is it?
  • Segmentation is visible to the programmer
  • - Paging is not (usually) visible to the
  • programmer
  • Usually different segments allocated to program
    and data
  • May be a number of program and data segments,
    e.g. to support protection levels, priority
    levels, organization, flexibility, etc.

34
Advantages of Segmentation
  • Simplifies handling of growing data structures
  • Allows programs to be altered and recompiled
    independently, without re-linking and re-loading
  • Lends itself to sharing among processes
  • Lends itself to protection
  • Some systems combine segmentation with paging

35

OS Review
  • Scheduling
  • uni-programming
  • multi-programming
  • time-sharing
  • long-term scheduler (queue of all jobs
    potentially schedulable)
  • short-term scheduler (queue of processes that
    are ready to execute)
  • medium-term scheduling (queue of jobs that can
    reside in memory)
  • blocked monitoring (queue of processes blocked
    for resources)
  • new ready running blocked exit state
    machine
  • Memory management
  • partitioning
  • paging frames, pages, page fault, page table,
    logical/physical addr
  • virtual memory inverted page table,
    Translation Lookaside Buffer
  • segmentation

36
Pentium and Power PC
  • Pentium Intel
  • Power PC Motorola IBM
  • A 32 bit memory address space is 4 G Bytes
  • A 46 bit memory address space is 64 T Bytes
  • 1.25 terabytes has been claimed as the capacity
    of a human being's functional memory (according
    to Raymond Kurzweil).
  • A Holographic Versatile Disc (HVD) can hold up to
    3.9 terabytes.
  • One hour of uncompressed Ultra High Definition
    Video (UHDV) consumes approximately 11.5
    terabytes of data.
  • The U.S. Library of Congress has claimed that "as
    of December 31, 2005, the Library has collected
    more than 40 terabytes of data."
  • A Protein-coated disc (PCD) can hold 50 terabytes
    of data.
  • A 64 bit memory address space is ? (Who cares!)
  • The point is that it is not clear to me why we
    care for some at least some years to come.

37
Pentium II (Uses hardware for segmentation
paging)
  • Unsegmented, unpaged
  • virtual address physical address
  • Used in Low complexity, High performance systems
  • Unsegmented, paged
  • Memory viewed as paged linear address space
  • Protection and management via paging (Ex
    Berkeley UNIX)
  • Segmented, unpaged
  • Collection of local address spaces
  • Protection to single byte level, Translation
    table needed is on chip when segment is in
    memory, provide predictable access times
  • Segmented, paged
  • Segmentation used to define logical memory
    partitions subject to access control
  • Paging manages allocation of memory within
    partitions (Ex Unix System V)

38
Pentium II Address Translation Mechanism
  • Segment uses 2 bits to provide 4 levels of
    protection, typically
  • 0 OS kernel, 1 OS, 2 apps needing
    special security, 3 general apps

39
Pentium II Paging
  • Segmentation may be disabled
  • In which case linear address space is used
  • Two level page table lookup
  • First, page directory
  • 1024 entries max
  • Splits 4G linear memory into 1024 page groups of
    4Mbyte
  • Each page table has 1024 entries corresponding to
    4Kbyte pages
  • Can use one page directory for all processes, one
    per process or mixture
  • Page directory for current process always in
    memory
  • Use TLB holding 32 page table entries
  • Two page sizes available 4k or 4M

40
PowerPC 32-bit Address Translation
41
PowerPC Memory Management Hardware
  • 32 bit paging with simple segmentation
  • or 64 bit paging with more powerful segmentation
  • Or, both do block address translation
  • Map 4 large blocks of instructions 4 of memory
    to bypass paging
  • e.g. OS tables or graphics frame buffers
  • 32 bit effective address
  • 12 bit byte selector
  • 4kbyte pages
  • 16 bit page id
  • 64k pages per segment
  • 4 bits indicate one of 16 segment registers
  • Segment registers under OS control

42
PowerPC 32-bit Memory Management Formats
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