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Nondeterministic Space is Closed Under Complement

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Theory of Computation II Professor: Geoffrey Smith Nondeterministic Space is Closed Under Complement Presented by Jing Zhang and Yingbo Wang – PowerPoint PPT presentation

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Title: Nondeterministic Space is Closed Under Complement


1
Nondeterministic Space is Closed Under Complement
Theory of Computation II Professor Geoffrey
Smith
  • Presented by Jing Zhang and Yingbo Wang

2
Definition of L and NL
  • L is the class of languages that are decidable in
    logarithmic space on a deterministic TM.
  • LSPACE(logn)
  • NL is the class of languages that are decidable
    in logarithmic space on a nondeterministic TM.
  • NLNSPACE(logn)

3
NL-Completeness
  • Analogous to the question of whether PNP, we
    have the question of whether LNL.
  • We can exhibit certain languages that are
    NL-complete.
  • NL-complete language is the one which is in NL
    and any other language in NL is reducible.

4
Reducing Problems
  • We have seen that polynomial time reducibility is
    a very useful concept for classifying problems in
    NP. In particular, it allowed us to identify the
    class of the hardest problems in NP-NP complete
    problems
  • But we will see this concept is not suitable for
    classifying problems in NL
  • So we need a weaker version of reducibility..

5
Log Space Reducibility
  • Log Space Transducer
  • A log space transducer is a TM with
  • a read-only input tape
  • a write-only output tape and
  • a read/write work tape that may contain
    O(logn) symbols
  • A log space transducer M computes a function f?
    ? ? where f(w) is the string remaining on the
    output tape after M halts when it started with w
    on the input tape.
  • In this case f is said to be Log space computable
    function

6
Log Space Reduction
  • Definition Language L1 is log space reducible to
    L2, denoted L1L L2, if a log-space computation
    function f exists such that
  • x?L1 ? f(x)?L2
  • Recall that a TM that uses f(n) space runs in
  • time. So a function
    computable in log space is computable in
    polynomial time,so
  • L1L L2 ? L1 L2

7
Definition of PATH
  • PATHltG,s,tgt G is a directed graph that has a
    directed path from s to t
  • PATH ? NL
  • Proof Idea we prove it by showing a
    nondeterministic log space algorithm for PATH
  • This TM starts at node s and nondeterministically
    guesses the steps of a path form s to t.
  • It records only the position of the current node
    at each step on the work tape, not entire path
    and nondeterministically selects the next node
    from among those pointed at by the current node.
  • Repeat this action until reaches node t and
    accepts, or until it has gone on for m steps and
    rejects.

8
Definition of NL-Completeness
  • Like the definition of NP-complete
  • A language B is NL-complete if
  • 1. B?NL, and
  • 2. every A in NL is log space reducible to
  • B

9
Theorem PATH is NL-Complete
  • Proof Idea
  • We have showed PATH is in NL, we only need to
    show PATH is NL-hard.
  • For any nondeterministic log-space machine, and
    any input w, construct, in log space, a graph G
    whose nodes are the possible configurations, and
    whose edges are the possible transitions.
  • Then the machine accepts w iff some path from the
    node corresponding to the start configuration
    leads to the node corresponding to the accepting
    configuration.

10
Definition of coNL
  • coNL is the class of all languages L such that
    belongs to NL.
  • Trivially, all deterministic complexity classes
    are closed under complementation. With
    nonderterministic complexity classes, the
    situation is complicated.
  • NL?coNL

11
Theorem NLcoNL
  • Proof Idea
  • Exactly as for NP and coNP, we have
  • if L is NL complete then is coNL
    complete
  • if a coNP complete problem belongs to NL
    then
  • NLcoNL.
  • We already proves PATH is NL complete, so it
    suffices to show is in NL.
  • Must find a nondeterministic algorithm which uses
    log space, and which has an accepting computation
    whenever the input graph G does not contain a
    path from s to t.

12
Proof
13
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14
Construct M Calculate c
  • Were going to do this inductively,
  • Define A(i) the collection of nodes reachable
    from s in i steps, c(i) A(i). Now the c
    were looking for is c(m) where m is the number
    of nodes in the graph
  • Base case A(0) s and c(0) 1.
  • For each node v in G
  • Go through all nodes and guess whether each node
    is in A(i)
  • For each u verified to be in A(i), test if (u, v)
    is an edge of G. If it is, v is in A(i1)
  • Count nodes number verified to be in A(i),
    computation branch rejects if is not c(i).
  • Repeat until we get c(m) A(m)

15
From c(i) to c(i1)
  • For every node v in G,
  • Go through all the nodes of G and guess whether
    each one is in A(i). For each node u that is
    guessed to be in A(i), verify it by guessing a
    path from s to u in i steps. If the verification
    fails, reject that branch of the computation.
  • Count all nodes verified to be in A(i). If the
    number counted is not c(i), which means not all
    of A(i) have been found, then reject this branch
    of the computation.
  • Now we find all the nodes in A(i), count them,
    and check whether each on has an edge to v.
  • We keep a running tally of the nodes in A(i) and
    compare each one with v as we go, deleting each
    one before writing the next, and somewhere
    keeping a number of how many of the nodes of G
    weve checked for membership in A(i).

16
How M runs after obtaining c?
reject
Yes
Is u t?
Yes
No
Increase d, Go to next node
Is u verified reachable from s?
No
reject
Accept
Yes
Is d c?
No
Reject
17
Construct M Guess reachable nodes from s
  • for each node u in G, M non-deterministically
    guesses if u is reachable from s.
  • If it guesses it is, then it verifies by guessing
    a path of length m from s to u. If the
    verification fails, reject that computation
    branch.
  • If, at any point, we guess that t is reachable
    from s, we reject.
  • Keep counting how many nodes have been verified
    as d
  • again, we have to delete them after checking
    them to avoid linear space.
  • After checking and guessing all nodes of G, we
    compare d with c. If d is not equal to c, we did
    not guess all reachable nodes from s, so we
    reject this branch of computation.
  • If d c, and t has not been guessed, then we
    have guessed all the nodes reachable from s on
    the graph G, and t was not among them, so we
    accept.

18
Algorithm
  • On input ltG, s, tgt
  • Let c(0) 1
  • For I 0 to m 1
  • Let c(i1)0
  • Let d0
  • For each node v in G
  • For each node u in G
  • Nondeterministically either perform or skip these
    steps
  • Nondeterministically follow a path of length i
    from s and if none of the nodes encountered are
    u, reject.
  • Increment d
  • If (u, v) is an edge of G, increment c(i 1).
    Repeat for next node v
  • If d is not equal with c(i), reject
  • For each node u in G
  • Nondeterministically either perform or skip these
    steps
  • Nondeternimistically follow a path of length m
    from s and if none of the nodes encountered are
    u, reject
  • If u t, the reject
  • Increment d
  • If d is not equal with c(m), reject otherwise,
    accept.

19
Space Complexity
  • At any time, this algorithm only needs to store
    c(i), d, i, m and a pointer to the head of a
    path.
  • It runs in log space.

Conclusion NL coNL
20
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