COSC 1107理论

Computing Theory
COSC 1107/1105
Assignment 2: Computability
Assessment Type Individual assignment. Submit online via Canvas → As-
signments → Assignment 2. Marks awarded for meeting re-
quirements as closely as possible. Clarifications/updates may
be made via announcements/relevant discussion forums.
Due Date Tuesday 19th October 2021, 11:59pm (note new date)
Marks 100 worth 25% of your final assessment
1 Overview
This assignment requires you to demonstrate your knowledge of some key issues in com-
putability, and of non-determinism. There is also a part which deals with the Platypus
game.
2 Assessment details

  1. Passwords (8 marks)
    The Dwarves of the Lonely Mountain have a lot of time on their hands, and are
    very worried about information about the size of their horde of gold getting around
    various parts of Middle-Earth, as they fear invasion by all and sundry if any hint
    of their true wealth were to be revealed. Accordingly King Durin XIII decrees
    that all records are to be written only in encrypted Khuzdul, in which there are
  2. distinct characters. The encryption process is based on a Khuzdul keyword of
    n characters in length. Durin’s advisors inform him that an evil wizard with an
    army of orc-slaves at his disposal (or a few of the lesser intelligent hobbits :-)) could
    exhaustively search through all possible keywords at a rate of 100,000 keywords per
    day. Durin decrees that the royal Khuzdul keyword must be secure ”until the end
    of the age”.
    (a) Determine an appropriate interpretation of Durin’s statement ”until the end
    of the age”. In other words, define what you think this means and hence what
    the maximum such time would be. (2 marks)
    (b) Given your previous answer, how long should the royal keyword be? Explain
    your answer. (2 marks)
    (c) Sillibo, a passing hobbit, happens to point out to Durin that not all of the
  3. Khuzdul characters are equally likely to be used, as there are 18 that are
    only used very rarely. Hence an outsider might concentrate on the other 14
    and make significant progress. Assuming Sillibo is correct, calculate how long
    it would take an evil wizard to discover a Khuzdul keyword of length given in
    your previous answer, assuming that at most 14 different Khuzdul characters
    are used in the keyword. (2 marks)
    (d) Sillibo also tells Durin, who is very impressed with the hobbit’s knowledge,
    that the royal keyword should not include a Khuzdul translation of the name
    ”Arkenpebble” (a famous jewel revered by all dwarves), as this is very well
    known to all in Middle-Earth, and hence will certainly be known to any evil
    wizard. Given the translation of Arkenpebble into Khuzdul uses 6 characters,
    evaluate Sillibo’s claim. In other words, is the royal keyword still as secure as
    Durin would like if it does contain the translation of Arkenpebble and the evil
    wizard correctly guesses this. (2 marks)
  4. Computability (14 marks)
    The generalised 3-player Platypus game is defined as follows. Let M1, M2, and M3
    be Turing machines, which share the same tape. The tape is initially blank. The
    initial configuration of the three machines is as shown below.
    As in the Platypus game, each machine takes turns to move (but there is no scoring
    involved).
    (a) Show that the halting problem for the 3-player generalised Platypus game is
    undecidable. You may use any reduction you like. (6 marks)
    (b) Suppose the 3-player generalised Platypus game is played on a Turing machine
    with a finite tape (making the halting problem decidable), and that this prob-
    lem has been shown to be NP-complete. Given your above reduction from
    some problem A to the 3-player generalised Platypus game, can this reduction
    be used to conclude that A is NP-complete? Why or why not? Explain your
    answer. (2 marks)
    (c) Consider the two Turing machines M1 and M2 below.
    M1: Whatever the input is, M1 overwrites each character in the input, resulting
    in a totally blank tape. M1 then terminates.
    M2: Given an input string w, M2 outputs another Turing machine Mw which
    will take a blank tape as input, print w on the tape and then terminate.
    Explain how these two Turing machines are used in at least three reductions
    of the Halting problem to other undecidable problems. (6 marks)
    2
  5. Nondeterminism (8 marks)
    Consider the incomplete NFA M0 below, whose alphabet is {0, 1}.
    Use M0 to create three more NFAs M1, M2 and M3 according to the constraints
    below. Explain in one or two English sentences how you constructed each NFA.
    ? Each of M1, M2 and M3 must contain at least 10 transitions (potentially but
    not necessarily including λ-transitions) and must be an NFA but not a DFA.
    Specifically there must be at least one combination of state and input (either
  6. or 1) for which there are at least two possible states. Put another way,
    removing all λ-transitions must not result in a DFA.
    Use JFLAP to transform M1, M2 and M3 into equivalent DFAs.
    The sizes of the DFA resulting from the determinising algorithm must be as
    below. Note that the JFLAP implementation of this often omits an “error”
    state, i.e. it may be necessary to add an extra state to the result from JFLAP
    in order to account for this. The size constraints below assume a fully deter-
    ministic DFA; one way to check for this is that if the DFA has k states, there
    must be exactly 2k transitions (one for each of 0 and 1 in each state).
    (a) The size of the DFA corresponding to M1 is 2. (3 marks)
    (b) The size of the DFA corresponding to M2 is 5 (2 marks)
    (c) The size of the DFA corresponding to M3 is at least 9 (this may be harder
    than you think!) (3 marks)
  7. Pumping Lemma (20 marks)
    (a) There are three errors in the statement of the Pumping Lemma for regular
    languages below. Find all three, and state how to correct them. Explain each
    of your corrections. (4 marks)
    Let L be a regular language. Then ?n ≥ 1 such that for some w ∈ L such that
    |w| ≥ n, ?x, y, z such that w = xyz where
    i. |xy| < n+ 1
    ii. y 6= λ
    iii. xyiz ∈ L for all i ≥ 1
    3
    (b) One fine day, as soon as lockdown was over, Elladan and Elrohir talk an
    afternoon walk in the gardens of Lothlorien. While contemplating the meaning
    of existence underneath the massive ancient trees, they come across ten pieces
    of parchment, which appear to have been hastily ripped up during the recent
    War of the Ring, on which are written some strange runes that they cannot
    read. Desperate to find out what these mean, they send the fragments to
    Imladris for analysis, where the wisest still in Middle Earth would be found.
    After several anxious weeks, a passing eagle delivers a package to them. Inside
    they find a letter from Elrond himself, explaining that despite their best efforts,
    they were unable to fully translate the runes, and so there are some places
    where there are several possible translations of particular phrases. Elladan
    and Elrohir therefore have two tasks. The first one is to arrange the fragments
    in the most likely order. Then they have to select from each of the possible
    translations so that the overall message makes sense.
    The fragments are below, with the parts where there are alternative transla-
    tions labelled with capital letters, like this:
    (Translated text) A (Translated text)
    A1: Alternative 1
    A2: Alternative 2
    A3: Alternative 3
    1: Let w be A
    A1: 0n2n1210n2n. A2: 2n1212n. A3: 0n1210n. A4: 1n1211n.
    2: and so xyiz is B
    B1: 2n0n+j1212n0n B2: 2n+j1212n B3: 0n+j1210n B4: 1n+j1211n
    3: Then ?n ≥ 1 such that C and D,
    C1: for all w ∈ L and |w| ≥ n C2: for some w ∈ L and |w| ≥ n C3: for all
    w ∈ L and |w| ≤ n C4: for some w ∈ L and |w| ≤ n
    D1: ?x, y, z such that w = xyz, |xy| ≤ n D2: ?x, y, z such that w = xyz, |xy| ≤
    n D3: ?x, y, z such that w = xyz, |xy| ≥ n D4: ?x, y, z such that w =
    xyz, |xy| ≥ n
    4: Finrod’s Tale: A proof that the language L =E is F .
    E1: {w121|w ∈ {0, 1, 2}?} E2: {121w|w ∈ {0, 1, 2}?} E3: {w000w|w ∈
    {0, 1, 2}?} E4: {w121w|w ∈ {0, 1, 2}?}
    F1: regular F2: context-free F3: not regular F4: empty
    5: As the Pumping Lemma requires xyiz ∈ L, this is a G
    G1: problem G2: paradox G3: contradiction G4: tautology
    6: and so we have shown that our assumption is false, i.e. that L is H.
    H1: regular H2: context-free H3: not regular H4: empty
    7: Assume L is I.
    I1: regular I2: context-free I3: not regular I4: empty
    8: Now consider J
    J1: i = 0 J2: i = 1 J3: i = 2 J4: i = 3
    9: so we have w ∈ L, K and |xy| ≤ n, and so we have L for some 1 ≤ j ≤ n.
    4
    K1: |w| ≤ n K2: |w| < n K3: |w| ≥ n K4: |w| > n
    L1: y = 0j L2: y = 1j L3: y = (02)j L4: y = (12)j
    10: y 6= λ and M
    M1: xyiz 6∈ L for all i ≥ 0 M2: xyiz 6∈ L for some i ≥ 0 M3: xyiz ∈ L for all
    i ≥ 0 M4: xyiz ∈ L for some i ≥ 0
    You do not need to write the proof out in full. Just indicate the
    fragment order and your choice for each of the letters in a sequence like the
    one below.
    9K2 8J3 4E4 ...
    (6 marks)
    (c) Let L be any regular language and let M be a DFA for it with n states. Explain
    how you can use the Pumping Lemma to show that L is infinite iff there is a
    string w ∈ L such that n ≤ |w| ≤ 2n? 1. (4 marks)
    (d) Let L be any regular language over {a, b, c}. Show how the Pumping Lemma
    can be used to demonstrate that in order to determine whether or not L is
    empty, we need only test at most (3n ? 1)/2 strings. (2 marks)
    (e) The Pumping Lemma for context-free languages is below.
    Let L be a context-free language. Then there is an n ≥ 1 such that for any
    string w ∈ L with |w| ≥ n there exists strings x, y, z, u, v such that w = xyzuv
    and
    i. |yzu| ≤ n
    ii. |y|+ |u| > 0
    iii. xyizuiv ∈ L for all i ≥ 0
    Use this to show that the language L = {ai2+i | i ≥ 0} is not context-free by
    filling in the gaps below. (4 marks)
    Proof: Assume . So the Pumping Lemma applies, and so for
    any string w ∈ L with |w| ≥ n there exist strings x, y, z, u, v such that w =
    xyzuv and
    i. |yzu| ≤ n
    ii. |y|+ |u| > 0
    iii. xyizuiv ∈ L for all i ≥ 0
    Let . So w ∈ L and |w| ≥ n, and w = xyzuv, |yzu| ≤ n, |y| + |u| > 0
    and xyizuiv ∈ L for all i ≥ 0. Now as , this means |yzu| = |y|+ |z|+
    |u| ≤ n and so |y|+ |u| ≤ n.
    Let i = 0 and consider |xy0zu0v| = |xzv| = ?|y| ? |u| = n2 + n ?
    (|y| + |u|) ≥ n2 + n ? n > = (n ? 1)2 + (n ? 1). So n2 + n =

    |xy0zu0v| > (n? 1)2 + (n? 1), and so xy0zu0v 6∈ L. This is a contradiction,
    and so L is not context-free.
  8. Intractable problems (10 marks)
    Intractable problems are decidable problems, but for which the best known solution
    is exponential (or worse). Describe two intractable problems and their practical
    5
    application. You should write one introductory paragraph on intractable problems,
    and two further paragraphs, one on each problem, and a reason that you selected
    each one. Some suggestions will be given in class and on Canvas.
    Please note that I am not at all interested in what you can find on Google or
    Wikipedia or anything like that. What I really want to see is some evidence of
    you thinking about intractable problems and what effect these have, such as the
    relationship between the vertex cover problem and sensor networks.
    Perhaps an interesting way to address this is to consider what differences it would
    make if your intractable problem could be solved efficiently. For example, if we
    could solve say the Travelling Salesperson problem in O(nn) time, what would be
    possible that is impossible now?
    Another possibility is to consider how intractability can be a useful thing, such
    as keeping information secure in cryptosystems or in related applications such as
    blockchain.
    Whatever problems you choose, please avoid the temptation to ’cut, copy and edit’;
    as soon as you do that, you have done something wrong. I would far prefer to read
    your own words and your own perspective on these problems.
  9. Universality (24 marks)
    In a nutshell, you are expected to revise and extend your work on this topic in
    Assignment 1.
    In Assignment 1, you investigated one of the following three topics, or came up
    with your own related topic or creative story.
    ? Two-dimensional Turing machines
    ? Small universal Turing machines
    ? Notable universal Turing machines
    For this assignment, you are expected to either continue your investiga-
    tion from Assignment 1 on the same topic in more depth, or to make a
    different choice. In other words, you can either continue with your choice from
    Assignment 1, or make a different one now. Whatever your decision, you are ex-
    pected to write about 1800-2000 words (9 or 10 paragraphs) overall. This
    should include a revised version of your Assignment 1 submission, so that if you
    continue with the same choice as in Assignment 1, this is will be an extended form
    of that work. If you make a different choice, that is fine, but you should include your
    (potentially revised) Assignment 1 submission as part of this submission. So you
    have two different choices for the two assignments, you are expected to write about
    the same length on each; if you have the same choice for each, you should write
    about 1800-2000 words overall. Either way, the submission for Assignment 2
    will involve around 1000 words over and above what you submitted for
    Assignment 1.
    As in Assignment 1, you may also propose an alternative topic, or write a creative
    story involving a Turing machine of some kind. You can do this even if you did not
    choose either of these in Assignment 1. However, for any alternative topic or
    creative story, please seek approval from the lecturer before commencing
    6
    work on it. This is to make sure that what you are doing is appropriate for this
    assignment — I would hate to see an outcome where you do a lot of work, only for
    it not to count because it does not address the intended content.
    One alternative topic of particular interest is quantum computing; if anyone is
    interested in pursuing this, you are strongly encouraged to do so (but as above,
    please do consult me first). Another possibility is zero-knowledge proofs, but
    again please consult me before doing this.
    A further point is that you can present your information in other ways
    that a formal report if you wish . Some suggestions are below. Please keep in
    mind that you still need to discuss the technical content; the point is to find a way
    that assists you with this, rather than being a blockage for you.
    Pick a side in the debate about the 2007 universal TM competition
    Langton’s Ant vs Paterson’s worm
    ‘Cellular automata are better than Turing machines’
    Write a children’s story, movie scene, poem, . . .
    2D TMs as a game, map, drawing a picture, annotating photos, . . .
    Implementation of some aspects (be careful of rabbit holes!)
    Experiment with Java implementation of 2D Universal TM
    Langton’s ant with ‘boundaries’ (see an example here)
    You will be marked according to the rubric below.
    Points Description Details
    18-24 Exemplary You have explored your chosen topic well.
    Your report is clear and well-written,
    and has the appropriate length.
    This is interesting and informative.
    12-17 Accomplished You have explored your chosen topic reasonably well.
    Your report is generally good,
    but can be improved with some more attention to detail,
    particularly concerning the amount of technical detail.
    6-11 Developing Your report needs some further work,
    either to increase the level of content or
    to improve the choice of material and its presentation.
    0-5 Beginning Your report does not show evidence
    of sufficient investigation, and is lacking in detail.
  10. The Platypus game. (16 marks)
    We have previously talked about running as large a tournament as possible with the
    Platypus game. The way we will do this in this assignment is for each of your to run
    a tournament of 2,500 machines. From these, you will report your top 10 machines
    (see below for details). These 10 will then be part of a knock-out tournament to
    determine the overall winner.
    Before answering the questions below, do the following.
    7
    Get your allocation of 2,500 machines. These will in a OneDrive directory
    that will be shared with you. Once you have the link, look for a file in the
    folder with your student number, i.e. if your student number is 7654321, look
    for the file 7654321.pl. Store this somewhere that suits you with a name like
    machines.pl for convenience.
    Open a new SWI-Prolog shell and consult both platypus.pl and machines.pl
    (or whatever you called it). Then run the command below. This will classify
    your list of machines into three categories, and will generate one file each cate-
    gory named none.pl, reachable.pl and unreachable.pl, as per the descrip-
    tion below. This will be in the directory specified by the results directory
    predicate in platypus.pl; you can change this to something more convenient
    for you if you like.
  11. classify machines.
    None The machine has no platypus state in the fourth row of columns 1-6
    Reachable It is possible reach the platypus state from the kangaroo state
    Unreachable It is not possible reach the platypus state from the kangaroo state
    The point of this analysis is to work out whether it is possible for the machine
    to terminate the game or not. An example of each class of machine is below.
    In the first case, the machine cannot terminate the game, as it is not possible
    for it to go from the start state (kangaroo) to the platypus state as there is
    no transition that will move the machine into the platypus state.
    Y G Y G Y G Y
    K K E E W W P
    g y y g y y g
    Emu Emu Wombat Kangaroo Wombat Emu Kangaroo
    w gg gg w w w gg
    The second and third cases occur when there is indeed such a platypus state.
    When it is possible to move from the kangaroo state to the platypus state
    (depending on the cells on the tape of course), then the machine is classified
    as reachable, as in the machine below. This is because it is possible to move
    from the kangaroo state to the emu state (column 1 or 2), from the emu state
    to the wombat state (column 3) and from the wombat state to the platypus
    state (column 6).
    Y G Y G Y G Y
    K K E E W W P
    g y y g y y g
    Emu Emu Wombat Kangaroo Wombat Platypus Kangaroo
    w gg gg w w w gg
    It is also possible that even if such a platypus state exists, it is not possible
    to move into that state from the kangaroo state. In this case, the machine is
    classified as unreachable, as in the machine below. In this machine we can get
    from the kangaroo state to the wombat state and vice-versa, but we can never
    get to the emu state or platypus state from either of these.
    8
    Y G Y G Y G Y
    K K E E W W P
    g y y g y y g
    Wombat Wombat Platypus Kangaroo Wombat Kangaroo Kangaroo
    w gg gg w w w gg
    Intuitively, machines classified as reachable are in some sense “genuine” with
    the others being “imposters”. Accordingly, having separate tournaments for
    each seems only fair.
    Run a tournament for each of the following classes of machines
    – All 2,500 machines
    – Only machines classified as reachable
    – Only machines classified none or unreachable (ie all those not classified as
    reachable).
    To do this, you will first have to prepare a file containing only the machines
    as above (the above classify machines command will more or less do this
    for you). You will also need to use the command below, which will run the
    tournament with all of the options below.
  12. my tournament([competition]).
    Variation Description
    Tree 5 points for whenever either tree is reached
    Green 2 points rather than 1 for changing green to yellow
    Animal 1 point every time a change of animal occurs
    Tiebreaker A random starting configuration is chosen with game length is 200
    (a) For each of your tournaments, report the overall time taken, the top 10 ma-
    chines (by ’football’ ranking), the overall number of wins and draws, and the
    number of winless machines. How many machines were classified as none,
    reachable and unreachable respectively? Report your results in a table as be-
    low. (2
    marks)
    Class Number Percentage
    Reachable
    Unreachable
    None
    (b) Re-run your tournament of all machines, but this time you are to include 10
    extra machines of your own choice. These should be different from any ma-
    chines in your list already, but otherwise you are free to choose them however
    you like.
    You can use platypus.pl from Canvas (link here) to assist with this if you
    wish. This will check whether your 10 added machines are ’legal’, and whether
    or not they were already part of your allocation. To do this, consult platypus.pl
    and machines.pl as above, and a third file extra.pl. Then run the command
    ?- check new.
    This will then output whether your added machines are legal, and whether
    they are already part of your allocation or not (and if they are, which ones are
    already in their allocation).
    9
    You should report where each of these 10 machines finish in the ’football’
    ranking, and your reasons for choosing each of them. (2 marks)
    (c) Were you surprised how your chosen 10 machines performed? What can you
    conclude from this about high performing Platypus machines? If you had to
    choose one machine to represent you in a tournament, what machine would it
    be Briefly explain your decision. (4 marks)
    (d) In the previous assignment, your calculated the largest Platypus tournament
    you can play on your machine in 4 hours, ie 4 × 60 × 60 = 14, 400 seconds.
    This is of course for the ’standard’ 2-player game. 3-player and 4-player tour-
    naments will of course take longer. Calculate the largest 3- and 4-player tour-
    naments you can play on your machine in 4 hours. You may assume that a 3-
    or 4-player match takes the same time as a 2-player one. You may also find
    the following table useful (see the notes on 3- and 4-player tournaments for
    how these are derived). (2 marks)
    Players Matches required
  13. n(n+ 1)/2
  14. n(n+ 1)(n+ 2)/6
  15. n(n+ 1)(n+ 2)(n+ 3)/24
    (e) If the Platypus tournament were to be run again, what alterations would you
    recommend? Some ideas are below; you can add others as you see fit. You
    should have at least three suggestions. (6 marks)
    Once students are allocated their machines, they play a tournament amongst
    these to find the best 10. These 10 then take on the best 10 from other
    students. This could include the possibility of students choosing their 10
    machines from their allocation or from the set of machines which are not
    allocated to any student.
    The initial tape and scoring processes are changed from tournament to
    tournament. These are announced in advance, and allow choices to be
    made for which machines will be used.
    Non-player machines can be added. These are not competitors, but may
    change the tape in ways that influence the game. Such machines would
    not be allowed to terminate the game (presumably by allowing them tran-
    sitions for a green cell with a platypus).
    When a player has a platypus on a green cell, the game does not halt,
    but is “rebooted”, i.e. the tape reverts to its initial state, the player which
    ’halted’ the game gets a bonus or a penalty, and the machines involved
    are changed in some way. This change could be swapping rows 3, 4 and
  16. of column 1 and 2 (kangaroo), and the same for columns 3 and 4 (emu)
    and 5 and 6 (wombat). There could be a maximum of say 5 reboots per
    game.
    (insert your idea here!)
  17. Submission
    You should submit a PDF file, and all tournament.csv files from your tournaments. Do
    not use a zip file. Just add attach all relevant files to the submission on Canvas. No
    10
    other file formats will be accepted.
    In addition, for Questions 4b and 4e, you must fill in your answers on the Canvas
    Quiz here. As noted in announcements, this will assist with marking assignments more
    quickly.
  18. Marking guidelines
    Your assessment will be marked according to the criteria below.
    Completeness and accuracy of your answers to the first five questions.
    Completion of your section of the Platypus game tournament.
    Quality of your comments on the Platypus game tournament.

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