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William Stallings Computer Organization and Architecture 7th Edition

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Title: William Stallings Computer Organization and Architecture 7th Edition


1
William Stallings Computer Organization and
Architecture7th Edition
  • Chapter 5
  • Internal Memory

2
Semiconductor Memory Types
3
Semiconductor Memory
  • RAM
  • Misnamed as all semiconductor memory is random
    access
  • Read/Write
  • Volatile
  • Temporary storage
  • Static or dynamic

4
Memory Cell Operation
5
Dynamic RAM
  • Bits stored as charge in capacitors
  • Charges leak
  • Need refreshing even when powered
  • Simpler construction
  • Smaller per bit
  • Less expensive
  • Need refresh circuits
  • Slower
  • Main memory
  • Essentially analogue
  • Level of charge determines value

6
Dynamic RAM Structure
7
DRAM Operation
  • Address line active when bit read or written
  • Transistor switch closed (current flows)
  • Write
  • Voltage to bit line
  • High for 1 low for 0
  • Then signal address line
  • Transfers charge to capacitor
  • Read
  • Address line selected
  • transistor turns on
  • Charge from capacitor fed via bit line to sense
    amplifier
  • Compares with reference value to determine 0 or 1
  • Capacitor charge must be restored

8
Static RAM
  • Bits stored as on/off switches
  • No charges to leak
  • No refreshing needed when powered
  • More complex construction
  • Larger per bit
  • More expensive
  • Does not need refresh circuits
  • Faster
  • Cache
  • Digital
  • Uses flip-flops

9
SRAM v DRAM
  • Both volatile
  • Power needed to preserve data
  • Dynamic cell
  • Simpler to build, smaller
  • More dense
  • Less expensive
  • Needs refresh
  • Larger memory units
  • Static
  • Faster
  • Cache

10
Read Only Memory (ROM)
  • Permanent storage
  • Nonvolatile
  • Microprogramming (see later)
  • Library subroutines
  • Systems programs (BIOS)
  • Function tables

11
Types of ROM
  • Written during manufacture
  • Very expensive for small runs
  • Programmable (once)
  • PROM
  • Needs special equipment to program
  • Read mostly
  • Erasable Programmable (EPROM)
  • Erased by UV
  • Electrically Erasable (EEPROM)
  • Takes much longer to write than read
  • Flash memory
  • Erase whole memory electrically

12
Organisation in detail
  • A 16Mbit chip can be organised as 1M of 16 bit
    words
  • A bit per chip system has 16 lots of 1Mbit chip
    with bit 1 of each word in chip 1 and so on
  • A 16Mbit chip can be organised as a 2048 x 2048 x
    4bit array
  • Reduces number of address pins
  • Multiplex row address and column address
  • 11 pins to address (2112048)
  • Adding one more pin doubles range of values so x4
    capacity

13
William Stallings Computer Organization and
Architecture7th Edition
  • Chapter 4
  • Cache Memory

14
Location
  • CPU
  • Internal
  • External

15
Locality of Reference
  • During the course of the execution of a program,
    memory references tend to cluster
  • e.g. loops

16
Cache
  • Small amount of fast memory
  • Sits between normal main memory and CPU
  • May be located on CPU chip or module

17
Cache/Main Memory Structure
18
Cache operation overview
  • CPU requests contents of memory location
  • Check cache for this data
  • If present, get from cache (fast)
  • If not present, read required block from main
    memory to cache
  • Then deliver from cache to CPU
  • Cache includes tags to identify which block of
    main memory is in each cache slot

19
Cache Read Operation - Flowchart
20
Typical Cache Organization
21
Performace of Cache Systems
  • Let
  • tc cache access time
  • h hit ratio
  • tm memory access time
  • Average access time ( AT ) htc(1-h)(tc
    tm )
  • Ration of memory access time to cache access time
    (g ) tm / tc
  • Efficiency tc / AT
  • Example
  • Let tc 160 ns, tm 960ns, h0.90
  • Calculate Effceincy, AT, and g
  • AT0.9160 (1-0.9)(960160)
  • 144112256 ns
  • g 960/1606
  • Efficiency 160/2560.625

22
Direct Mapping
  • Each block of main memory maps to only one cache
    line
  • i.e. if a block is in cache, it must be in one
    specific place
  • Address is in two parts
  • Least Significant w bits identify unique word
  • Most Significant s bits specify one memory block
  • The MSBs are split into a cache line field r and
    a tag of s-r (most significant)

23
Cache Memory Techniques
  • Fully Associative Mapping
  • Direct Mapping
  • Set Associative Mapping

24
Fully Associative Mapping
  • In fully Associative Mapping, a main memory block
    i can be mapped to any cache block j.

25
  • To determine which block of main memory is stored
    into cache, a tag is required for each cache
    block
  • Tag(j) address of memory block stored in cache
    block j
  • ?Assume that M2m then the tag should at least
    store the m bits
  • When CPU generates an address, the main memory
    block is extracted and then associatively
    compared with the tags for a match. If a match
    occurs, the corresponding cache block number is
    retrieved and the cache is accessed for the
    required data

26
Direct Mapping
  • To reduce the cost of the associated memory,
    direct mapping is used. The memory block i is
    always mapped into cache I mode N.

27
Associative set
  • Instead of directly map the memory block into a
    certain block in the cache, the memory block can
    be mapped in a set of cache blocks. These blocks
    can be then associatively mapped.
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