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Manchester Mark I and Atlas: A Historical Perspective

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Manchester Mark I and Atlas: A Historical Perspective. Presented by: Aurel Cami ... 1946-1976: Five computer systems at Manchester University. ... – PowerPoint PPT presentation

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Title: Manchester Mark I and Atlas: A Historical Perspective


1
Manchester Mark I and Atlas A Historical
Perspective
  • Presented by Aurel Cami
  • CDA5106 - Advanced Computer Architecture I
  • Instructor Prof. Euripides Montagne

2
Introduction
  • 1946-1976 Five computer systems at Manchester
    University. We focus on 2 of them Mark I and
    Atlas.

University Project Industrial Derivative
Manchester Mark I 1946-1949 hardware dev. June 1948 first prototype 1949 enhancements Ferranti Mark I 1951 first installation 1957 last one delivered
Manchester Atlas 1956-1962 hardware dev. 1962 first installation Ferranti Atlas 1962 first installation 1965 last one delivered
3
Introduction (contd)
  • Continuous advancement from Mark I to Atlas in
  • Instruction format
  • Operand address generation
  • Memory management
  • Use of high-level programming languages
  • Focus of this talk (for each computer)
  • Objectives of the project
  • Technology, Architecture, System software
  • Evaluation

4
Mark I Objectives
  • Original objective Testing evironment for
    William Tubes storage
  • Prototype Mark I
  • Operational in June, 1948
  • First GP stored-program computer (Baby)
  • Objective after the first prototype Enough
    memory and computing power to solve number-theory
    problems

5
Mark I Technology
  • Logic
  • EF50 EF55 pentodes
  • EA50 vacuum tube diodes
  • Fast Storage
  • Registers (William Tubes)
  • RAM (William Tubes)
  • Backing Storage
  • Drum - 30 msec revolution time
  • I/O devices
  • Input 5-track paper tape reader
  • Output tape and printer

6
Mark I Architecture
  • Serial-ALU, single-address computer
  • Hardware add, subtract, multiply and logic
  • Word length 32 bits ( in 1949 40 bits )
  • Accumulator register 80 bits ( 2 words )
  • 2 B-lines (index registers) 20 bits each
  • Instruction length 20 bits ( 2 instructions per
    word)
  • Instruction Set 26 op codes (in 1949)
  • RAM 128 words
  • Drum Memory 1024 words

7
Mark I Architecture (contd)
ADDRESS B FUNCTION
  • 10 3 1
    6
  • Instruction Format
  • Address ( 10 bits )
  • B-line ( 3 bits )
  • Function (op-code) ( 6 bits )
  • Operands 40 bit words
  • Transfer to/from drum peripheral devices
    through control words of two kinds
  • Drum transfers control word
  • I/O transfers control word

8
Mark I Architecture (contd)
  • Paging
  • RAM 8 pages ( on 8 William Tubes )
  • Single/Double page transfers
  • Track address stored with each page on drum
  • When page became resident in main store an extra
    20 bit on each Williams tube held page
    track-address

9
Mark I System Software
  • In 1949 no system software for Mark I
  • Programming using 5-bit teleprinter code (one
    character 5 bits)
  • 1954 Autocode, scientific PL for Mark I
  • Arithmetic on floating-point variables v1,v2,
  • Integers n1,n2, used as indices/counters
  • Simple conventions for control transfers, I/O,
    intrinsic functions etc.,
  • Simulated one-level store programmer did not
    have to organize his own drum transfers

10
Mark I Evaluation
  • Performance
  • Drum transfers 16 of the time
  • Multiplication 28 of the time
  • Other arithmetic ops. 56 of the time
  • Multiplication 2.16 msec
  • Other accumulator instr. 1.2 msec
  • Long-term significance
  • Proved viability of digital storage via William
    tubes
  • Inspired British government to support Ferranti
    Ltd.
  • Focused on linking fast RAM with slower
    sequential
  • access rotating memory (drum)
  • Autocode allowed users to program in a virtual
    (drum) address space

11
Atlas Objectives
  • Goal build a high-performance machine to stay in
    competition
  • Higher computing speed (1 microsec/instruction)
  • More memory (RAM size 100K words)
  • Ability to attach more I/O devices
  • Efficient and economic utilization of the system
    (intended to be sold in open market)

12
Atlas Technology
  • Logic circuits
  • OC170 germanium junction transistor INVERTER
  • Diodes GATING
  • Parallel adder Special symmetrical transistor
    (SB240)
  • 80,000 transistors mounted on printed-circuit
    boards
  • Storage
  • Main store (16K-48K) core memory, 4-way
    interleaved
  • Backup store 4 drums each 24K
  • High speed ROM (fixed store) 8K
  • OS working storage 1-4K
  • Bulk storage tapes, disks
  • I/O devices
  • 17 I/O devices attached
  • Interrupt mechanism allowed up to 512 peripheral
    units

13
Atlas Architecture
  • Parallel computer
  • 2 independent ALUs ( A and B)
  • Pipelined
  • Overlap 3 A instructions
  • Any B instruction in parallel with A
  • 48-bit word
  • One-address instruction. Format

FUNCTION Ba Bm ADDRESS
10 7 7 24
14
Atlas Architecture (contnd)
  • Two types of instructions
  • Normal instructions
  • Extracode (implemented in software routines
    stored in fixed store, e.g sqrt, log, cosine)
  • Three types of normal instructions
  • Accumulator instructions
  • Index register instructions
  • Test-and-count instructions
  • Peripheral devices incorporated into the total
    address space (through peripheral device
    registers part of V-Store )

15
Atlas Architecture (contd)
  • Paging
  • 512 word pages
  • Introduced page address register (32 of them)
  • Address translation time 40 of total OF time
  • Pages for several programs could be in core
    memory concurrently (managed through locking)
  • Programmer treated the drum and core as a
    One-Level store ( 576Kb)

16
Atlas System Software
  • OS Atlas Supervisor
  • Multiprogramming (up to 16 jobs)
  • On-line spooling of I/O
  • Job scheduling (based on priority, volume etc.,)
  • Compilers
  • First Atlas Autocode
  • Block-structured language
  • Similar to Algol 60
  • Later compilers for Algol, Cobol, Fortran

17
Atlas Evaluation
  • Performance
  • Fixed-point B-addition 1.59 microsec
  • Floating-point add 1.61 microsec
  • Floating-point multiply 4.97 microsec
  • Floating-point divide 10.66 microsec
  • Throughput
  • 1 Atlas 4 IBM 7094s
  • 1967 benchmark comparison
  • Atlass Univac CDC 6600
  • 1 2.1 5.9

18
Atlas Evaluation (contd)
  • Long-term significance
  • Pipeline techniques
  • Paging and virtual memory
  • OS features multiprogramming, job scheduling
  • One of the first computers to design hardware to
    aid OS (e.g. interrupts, store management)

19
CONCLUSIONS
  • Mark I and Atlas demonstrate a clear progression
    of design concepts in computer systems
  • Many of the innovations introduced in Mark 1 and
    Atlas stored-program, virtual memory, pipeline,
    OS modern features have become the standard in
    todays computer systems

20
REFERENCES
  • S.H.Lavington.(1978). The Manchester Mark I and
    Atlas A Historical Perspective, Communications
    of the ACM, 21(1), 4-12
  • http//www.computer50.org/mark1 - the University
    of Manchester website on the Mark 1 system
  • http//www.science.uva.nl/faculteit/museum/CoreMem
    ory.html - an overview of the core memory (used
    with Atlas)
  • http//www.ukuug.org/events/linux2001/papers/html/
    DAspinall.html - a discussion of the Atlas
    computer technology and architecture
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