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CMSC 330: Organization of Programming Languages Finite Automata NFAs  DFAs.

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Presentation on theme: "CMSC 330: Organization of Programming Languages Finite Automata NFAs  DFAs."— Presentation transcript:

1 CMSC 330: Organization of Programming Languages Finite Automata NFAs  DFAs

2 CMSC 3302 Review How are DFAs and NFAs different? When does an NFA accept a string? How do we convert from a regular expression to an NFA? What is the  -closure of a state?

3 CMSC 3303 Relating REs to DFAs and NFAs DFANFA RE can transform can transform can transform (we’ll discuss this next)

4 CMSC 3304 Reduction Complexity Regular expression to NFA reduction: –O(n) NFA to DFA reduction –Intuition: Build DFA where each DFA state represents a set of NFA states –How many states could there be in the DFA? –Given NFA with n states, DFA may have 2 n states –This is not so good, but we can implement DFAs more easily

5 CMSC 3305 NFA  DFA reduction Example: {A} {B,D} a b {C,D}

6 CMSC 3306 NFA  DFA reduction Algorithm Let r 0 =  -closure(q 0 ), R = {r 0 },  R = ∅ While there is an unmarked state r i in R –Mark r i –For each a   Let S = {s | {q, a, s}  and q  r i } Let E =  -closure(S) If E  R, then R = R  E  R =  R  {r i, a, E} Let F R = {r i |  s  r i with s  q f } Notes: Let ( , Q, q 0, F Q,  ) be the NFA and ( , R, r 0, F R,  R ) be the DFA. All new states in R are unmarked at creation.

7 CMSC 3307 NFA  DFA example {A,E} R = {{A,E}, } {B,D,E} a {B,D,E}, {C,D} {C,D}, b b{E} a b a Language? All strings that have exactly 1 b and end in b or the string a Regular expression? a*b|a

8 CMSC 3308 Practice Convert the NFA to a DFA:

9 CMSC 3309 Equivalence of DFAs and NFAs Any string from A to either D or CD in the DFA represents a path from A to D in the original NFA.

10 CMSC 33010 Relating RE's to DFAs and NFAs Regular expressions, NFAs, and DFAs accept the same languages! DFANFA RE can transform can transform can transform High-level idea next

11 CMSC 33011 Converting from DFAs to REs General idea: –Remove states one by one, labeling transitions with regular expressions –When two states are left (start and final), the transition label is the regular expression for the DFA

12 CMSC 33012 Relating REs to DFAs and NFAs Why do we want to convert between these? –Easier to express ideas (regexes/NFAs) –Easier to implement (DFAs)

13 CMSC 33013 Implementing DFAs cur_state = 0; while (1) { symbol = getchar(); switch (cur_state) { case 0: switch (symbol) { case '0': cur_state = 0; break; case '1': cur_state = 1; break; case '\n': printf("rejected\n"); return 0; default: printf("rejected\n"); return 0; } break; case 1: switch (symbol) { case '0': cur_state = 0; break; case '1': cur_state = 1; break; case '\n': printf("accepted\n"); return 1; default: printf("rejected\n"); return 0; } break; default: printf("unknown state; I'm confused\n"); break; } It's easy to build a program which mimics a DFA

14 CMSC 33014 Implementing DFAs (Alternative) Alternatively, use generic table-driven DFA –q is just an integer –Represent δ using 2d array or nested hash tables –Represent F as a set given components (Σ, Q, q 0, F, δ) of a DFA: let q = q 0 while (there exists another symbol s of the input string) q := δ(q, s); if q ∊  F then accept else reject

15 CMSC 33015 Run Time of Algorithm Given a string s, how long does algorithm take to decide whether s is accepted? –Assume we can compute δ(q0, c) in constant time –Time per string s to determine acceptance is O(|s|) –Can’t get much faster! But recall that constructing the DFA from the regular expression A may take O(2 |A| ) time –But this is usually not the case in practice So there’s the initial overhead, but then accepting strings is fast

16 CMSC 33016 Regular Expressions in Practice Regular expressions are typically “compiled” into tables for the generic algorithm –Can think of this as a simple byte code interpreter –But really just a representation of (Σ, Q A, q A, {f A }, δ A ), the components of the DFA produced from the RE

17 CMSC 33017 Complement of DFA Given a DFA accepting language L, how can we create a DFA accepting its complement? (the alphabet = {a,b})

18 CMSC 33018 Complement Steps Add implicit transitions to a dead state Change every accepting state to a non- accepting state and every non-accepting state to an accepting state Note: this only works with DFAs - Why?

19 CMSC 33019 Practice Make the DFA which accepts the complement of the language accepted by the DFA below. S3

20 Review and Practice CMSC 330

21 21 Deterministic Finite Automaton (DFA) A DFA is a 5-tuple (Σ, Q, q 0, F, δ) where –Σ is an alphabet –Q is a nonempty set of states –q 0 ∊ Q is the start state –F ⊆ Q is the set of final states –δ : Q x Σ → Q specifies the DFA's transitions

22 CMSC 33022 Nondeterministic Finite Automaton (NFA) A NFA is a 5-tuple (Σ, Q, q 0, F, δ) where –Σ is an alphabet –Q is a nonempty set of states –q 0 ∊ Q is the start state –F ⊆ Q is the set of final states –δ : Q x (Σ  {ε}) → Q specifies the NFA's transitions

23 CMSC 33023 Practice Give the English descriptions and the DFA or regular expression of the following languages: ((0|1)(0|1)(0|1))* (01)*|(10)*|(01)*0|(10)*1

24 CMSC 33024 Practice Give the DFAs for the following languages: All valid strings including only “A”, “C”, “G”, “T” and appearing in multiples of 3 All binary strings containing an even, non-zero length substring of all 1’s All binary strings containing exactly two 1’s All binary strings that start and end with the same number

25 CMSC 33025 Practice Make the DFA which accepts all strings with a substring of 330 Take the complement of this DFA

26 CMSC 33026 Practice Draw NFAs for the following regular expressions and languages: (0|1)*110* 101*|111 all binary strings ending in 1 (odd numbers) (ab*c|d*a|ab)d

27 CMSC 33027 Example Find the  -closure for each of the states in this NFA:

28 CMSC 33028 Practice Convert to a DFA: Convert to an NFA and then to a DFA: (0|1)*11|0* aba*|(ba|b)

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