Presentation is loading. Please wait.

Presentation is loading. Please wait.

Fall 2013 CMU CS 15-855 Computational Complexity Lecture 2 Diagonalization, 9/12/2013.

Published byBerenice Hunter Modified over 8 years ago

Similar presentations

Presentation on theme: "Fall 2013 CMU CS 15-855 Computational Complexity Lecture 2 Diagonalization, 9/12/2013."— Presentation transcript:

1 Fall 2013 CMU CS 15-855 Computational Complexity Lecture 2 Diagonalization, 9/12/2013

2 2 Languages Let ∑ be any finite alphabet. L µ ∑ * L is a language. The decision problem corresponding to L is the function: f:∑ * ! {yes, no} deciding membership in L, i.e., {x | f(x)=‘yes}

3 9/12/20133 Model for this class; Multi-tape Turing Machines Read-only Input tape; write only output... finite control abab aa bbcd... k tapes δ:Q x ∑ k ! Q x ∑ k x {L,R,-} k (input tape)

4 9/12/20134 Turing Machines Q finite set of states ∑ alphabet including blank: “_” q start, q accept, q reject in Q δ:Q x ∑ k ! Q x ∑ k x {L,R,-} k transition fn. input written on tape, head on 1 st square, state q start sequence of steps specified by δ if reach q accept or q reject then halt

5 9/12/20135 TIME and SPACE TIME(f(n)) = languages decidable by a multi- tape TM in at most f(n) steps, where n is the input length, and f :N ! N SPACE(f(n)) = languages decidable by a multi- tape TM that touches at most f(n) squares of its work tapes, where n is the input length, and f :N ! N

6 9/12/20136 Time and Space Classes L = SPACE(log n) PSPACE =  k SPACE(n k ) P =  k TIME(n k ) EXP =  k TIME(2 n k )

7 9/12/20137 Outline Why big-oh? Linear Speedup Theorem Hierarchy Theorems Robust Time and Space Classes Relationships between classes Some complete problems

8 9/12/20138 Linear Speedup Theorem: Suppose TM M decides language L in time f(n). Then for any  > 0, there exists TM M’ that decides L in time  f(n) + n + 2. Proof: –simple idea: increase “word length” –M’ will have one more tape than M m-tuples of symbols of M ∑ new = ∑ old  ∑ old m many more states

9 9/12/20139 Linear Speedup part 1: compress input onto fresh tape... ababbaaa ababbaaa_

10 9/12/201310 Linear Speedup part 2: simulate M, m steps at a time bbaababaaab... abbaababaaababa... mm –4 (L,R,R,L) steps to read relevant symbols, “remember” in state –2 (L,R or R,L) to make M’s changes

11 9/12/201311 Linear Speedup accounting: –part 1 (copying): n + 2 steps –part 2 (simulation): 6 (f(n)/m) –set m = 6/  –total:  f(n) + n + 2 Theorem: Suppose TM M decides language L in space f(n). Then for any  > 0, there exists TM M’ that decides L in space  f(n) + 2. Proof: same.

12 9/12/201312 Time and Space Moral: big-oh notation necessary given our model of computation –Recall: f(n) = O(g(n)) if there exists c such that f(n) ≤ c g(n) for all sufficiently large n. –TM model incapable of making distinctions between time and space usage that differs by a constant. In general: interested in course distinctions not affected by model –e.g. simulation of k-string TM running in time f(n) by single-string TM running in time O(f(n) 2 )

13 9/12/201313 Hierarchy Theorems Does genuinely more time permit us to decide new languages? how can we construct a language L that is not in TIME(f(n))… idea: same as “HALT undecidable” diagonalization and simulation

14 9/12/201314 Recall proof for Halting Problem Turing Machines inputs Y n Y n n Y n YnYYnnY H’ : box (M, x): does M halt on x? The existence of H which tells us yes/no for each box allows us to construct a TM H’ that cannot be in the table.

15 9/12/201315 Time Hierarchy Theorem Turing Machines inputs Y n Y n n Y n YnYYnnY D : box (M, x): does M accept x in time f(n)? TM SIM tells us yes/no for each box in time g(n) rows include all of TIME(f(n)) construct TM D running in time g(2n) that is not in table

16 9/12/201316 Time Hierarchy Theorem Theorem (Time Hierarchy Theorem): For every proper complexity function f(n) ≥ n: TIME(f(n)) ( TIME(f(2n) 3 ). more on “proper complexity functions” later…

17 9/12/201317 Proof of Time Hierarchy Theorem Proof: –SIM is TM deciding language { : M accepts x in ≤ f(|x|) steps } –Claim: SIM runs in time g(n) = f(n) 3. –define new TM D: on input if SIM accepts, reject if SIM rejects, accept –D runs in time g(2n)

18 9/12/201318 Proof of Time Hierarchy Theorem Proof (continued): –suppose M in TIME(f(n)) decides L(D) M( ) = SIM( ) ≠ D( ) but M( ) = D( ) –contradiction.

19 9/12/201319 Proof of Time Hierarchy Theorem Claim: there is a TM SIM that decides { : M accepts x in ≤ f(|x|) steps} and runs in time g(n) = f(n) 3. Proof sketch: SIM has 4 work tapes contents and “virtual head” positions for M’s tapes M’s transition function and state f(|x|) “+”s used as a clock scratch space

20 9/12/201320 Proof of Time Hierarchy Theorem contents and “virtual head” positions for M’s tapes M’s transition function and state f(|x|) “+”s used as a clock scratch space –initialize tapes –simulate step of M, advance head on tape 3; repeat. –can check running time is as claimed. Important detail: need to initialize tape 3 in time O(f(n))

21 9/12/201321 Proper Complexity Functions Definition: f is a proper complexity function if –f(n) ≥ f(n-1) for all n –there exists a TM M that outputs exactly f(n) symbols on input 1 n, and runs in time O(f(n) + n) and space O(f(n)).

22 9/12/201322 Proper Complexity Functions includes all reasonable functions we will work with –log n, √n, n 2, 2 n, n!, … –if f and g are proper then f + g, fg, f(g), f g, 2 g are all proper can mostly ignore, but be aware it is a genuine concern: Theorem: 9 non-proper f such that TIME(f(n)) = TIME(2 f(n) ).

23 9/12/201323 Hierarchy Theorems Does genuinely more space permit us to decide new languages? Theorem (Space Hierarchy Theorem): For every proper complexity function f(n) ≥ log n: SPACE(f(n)) ( SPACE(f(n) log f(n)). Proof: same ideas.

24 9/12/201324 Best Hierarchy Theorems Theorem (Time Hierarchy Theorem): For every proper complexity function f(n) ≥ n: TIME(f(n)) ( TIME(  (f(n)log(f(n))). Theorem (Space Hierarchy Theorem): For every proper complexity function f(n) ≥ log n: SPACE(f(n)) ( SPACE(  f(n)). 

25 9/12/201325 Time and Space Classes L = SPACE(log n) PSPACE =  k SPACE(n k ) P =  k TIME(n k ) EXP =  k TIME(2 n k )

26 9/12/201326 Hierarchy Separations Time Hierarchy Theorem implies P ( EXP –P µ TIME(2 n ) ( TIME(2 (2n)3 ) µ EXP Space Hierarchy Theorem implies L ( PSPACE –L = SPACE(log n) ( SPACE(log 2 n) µ PSPACE

27 9/12/201327 TIME(f(n))  SPACE(f(n)) Any time step can only affect constant number of tape cells : P µ PSPACE

28 9/12/201328 SPACE(f(n))  TIME(2 O(f(n)) ) T in TIME(f(n)) says yes or no – never loops So T can’t repeat a configuration. log(n) + klog(f(n))+ c + O(f(n) bits = O(f(n)) bits if f(n)>=log(n) 28 input-tape head position work-tape head position state work-tape contents

29 SPACE(f(n))  TIME(2 O(f(n)) ) L µ P PSPACE µ EXP So far: L µ P µ PSPACE µ EXP Open: L = P ??? P = PSPACE ?? 9/12/201329

30 9/12/201330 Reductions reductions are the main tool for relating problems to each other given two languages L 1 and L 2 we say “L 1 reduces to L 2 ” and we write “L 1 ≤ L 2 ” to mean: –there exists an efficient (logspace) algorithm that computes a function f s.t. x  L 1 implies f(x)  L 2 x  L 1 implies f(x)  L 2

31 9/12/201331 Reductions positive use: given new problem L 1 reduce it to L 2 that we know to be in P. Conclude L 1 in P (how?) –e.g. bipartite matching ≤ max flow –formalizes “L 1 as easy as L 2 ” yes no yes no L1L1 L2L2 f f

32 9/12/201332 Reductions negative use: given new problem L 2 reduce L 1 (that we believe not to be in P) to it. Conclude L 2 not in P if L 1 not in P (how?) –e.g. satisfiability ≤ graph 3-coloring –formalizes “L 2 as hard as L 1 ” yes no yes no L1L1 L2L2 f f

33 9/12/201333 Reductions Example reduction: –3SAT = { φ : φ is a 3-CNF Boolean formula that has a satisfying assignment } (3-CNF = AND of OR of ≤ 3 literals) –IS = { (G, k) | G is a graph with an independent set V’ µ V of size ≥ k } (ind. set = set of vertices no two of which are connected by an edge)

34 9/12/201334 Ind. Set is as easy as 3-SAT The reduction f: given φ = (x  y   z)  (  x  w  z)  …  (…) we produce graph G φ : x y zz  x x wz one triangle for each of m clauses edge between every pair of contradictory literals set k = m …

35 9/12/201335 Reductions φ = (x  y   z)  (  x  w  z)  …  (…) Claim: φ has a satisfying assignment if and only if G has an independent set of size at least k –proof? Conclude that 3SAT ≤ IS. x y zz  x x wz …

36 9/12/201336 Hardness L is C-hard if –every language in C reduces to L

37 9/12/201337 Completeness complexity class C language L is C-complete if –L is in C –L is C-hard

Download ppt "Fall 2013 CMU CS 15-855 Computational Complexity Lecture 2 Diagonalization, 9/12/2013."

Similar presentations

Variants of Turing machines

Variants of Turing machines
Lecture 24 MAS 714 Hartmut Klauck

Lecture 24 MAS 714 Hartmut Klauck
Fall 2013 CMU CS 15-855 Computational Complexity Lecture 5 Savich’s theorem, and IS theorems. These slides are mostly a resequencing of Chris Umans’ slides.

Fall 2013 CMU CS Computational Complexity Lecture 5 Savich’s theorem, and IS theorems. These slides are mostly a resequencing of Chris Umans’ slides.
CSCI 4325 / 6339 Theory of Computation Zhixiang Chen.

CSCI 4325 / 6339 Theory of Computation Zhixiang Chen.
Umans Complexity Theory Lectures Lecture 2a: Reductions & Completeness.

Umans Complexity Theory Lectures Lecture 2a: Reductions & Completeness.
Complexity 12-1 Complexity Andrei Bulatov Non-Deterministic Space.

Complexity 12-1 Complexity Andrei Bulatov Non-Deterministic Space.
Complexity 15-1 Complexity Andrei Bulatov Hierarchy Theorem.

Complexity 15-1 Complexity Andrei Bulatov Hierarchy Theorem.
Complexity 11-1 Complexity Andrei Bulatov Space Complexity.

Complexity 11-1 Complexity Andrei Bulatov Space Complexity.
Computability and Complexity 22-1 Computability and Complexity Andrei Bulatov Hierarchy Theorem.

Computability and Complexity 22-1 Computability and Complexity Andrei Bulatov Hierarchy Theorem.
Complexity 13-1 Complexity Andrei Bulatov Hierarchy Theorem.

Complexity 13-1 Complexity Andrei Bulatov Hierarchy Theorem.
Computability and Complexity 14-1 Computability and Complexity Andrei Bulatov Cook’s Theorem.

Computability and Complexity 14-1 Computability and Complexity Andrei Bulatov Cook’s Theorem.
Measuring Time Complexity Sipser 7.1 (pages 247-256)

Measuring Time Complexity Sipser 7.1 (pages )
CS151 Complexity Theory Lecture 3 April 6, 2015. 2 Nondeterminism: introduction A motivating question: Can computers replace mathematicians? L = { (x,

CS151 Complexity Theory Lecture 3 April 6, Nondeterminism: introduction A motivating question: Can computers replace mathematicians? L = { (x,
February 23, 2015CS21 Lecture 201 CS21 Decidability and Tractability Lecture 20 February 23, 2015.

February 23, 2015CS21 Lecture 201 CS21 Decidability and Tractability Lecture 20 February 23, 2015.
CPSC 411, Fall 2008: Set 12 1 CPSC 411 Design and Analysis of Algorithms Set 12: Undecidability Prof. Jennifer Welch Fall 2008.

CPSC 411, Fall 2008: Set 12 1 CPSC 411 Design and Analysis of Algorithms Set 12: Undecidability Prof. Jennifer Welch Fall 2008.
Complexity ©D.Moshkovitz 1 Turing Machines. Complexity ©D.Moshkovitz 2 Motivation Our main goal in this course is to analyze problems and categorize them.

Complexity ©D.Moshkovitz 1 Turing Machines. Complexity ©D.Moshkovitz 2 Motivation Our main goal in this course is to analyze problems and categorize them.
CS151 Complexity Theory Lecture 1 March 30, 2015.

CS151 Complexity Theory Lecture 1 March 30, 2015.
FORMAL LANGUAGES, AUTOMATA AND COMPUTABILITY 15-453 Read sections 7.1 – 7.3 of the book for next time.

FORMAL LANGUAGES, AUTOMATA AND COMPUTABILITY Read sections 7.1 – 7.3 of the book for next time.
NP-Completeness CS 51 Summer 2008 TexPoint fonts used in EMF. Read the TexPoint manual before you delete this box.: A AA A A AAA.

NP-Completeness CS 51 Summer 2008 TexPoint fonts used in EMF. Read the TexPoint manual before you delete this box.: A AA A A AAA.
Computability and Complexity 20-1 Computability and Complexity Andrei Bulatov Class NL.

Computability and Complexity 20-1 Computability and Complexity Andrei Bulatov Class NL.

Similar presentations

Ads by Google