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Regular Expressions Chapter 6 1. Regular Languages Regular Language Regular Expression Finite State Machine L Accepts 2.

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Presentation on theme: "Regular Expressions Chapter 6 1. Regular Languages Regular Language Regular Expression Finite State Machine L Accepts 2."— Presentation transcript:

1 Regular Expressions Chapter 6 1

2 Regular Languages Regular Language Regular Expression Finite State Machine L Accepts 2

3 Regular Expressions The regular expressions over an alphabet  are all and only the strings that can be obtained as follows: 1.  is a regular expression. 2.  is a regular expression. 3. Every element of  is a regular expression. 4. If ,  are regular expressions, then so is . 5. If ,  are regular expressions, then so is . 6. If  is a regular expression, then so is  *. 7.  is a regular expression, then so is  +. 8. If  is a regular expression, then so is (  ). 3

4 Regular Expression Examples If  = { a, b }, the following are regular expressions:   a ( a  b )* abba   4

5 Regular Expressions Define Languages Define L, a semantic interpretation function for regular expressions: 1. L(  ) = . 2. L(  ) = {  }. 3. L(c), where c   = {c}. 4. L(  ) = L(  ) L(  ). 5. L(    ) = L(  )  L(  ). 6. L(  *) = (L(  ))*. 7. L(  + ) = L(  *) = L(  ) (L(  ))*. If L(  ) is equal to , then L(  + ) is also equal to . Otherwise L(  + ) is the language that is formed by concatenating together one or more strings drawn from L(  ). 8. L((  )) = L(  ). 5

6 The Role of the Rules Rules 1, 3, 4, 5, and 6 give the language its power to define sets. Rule 8 has as its only role grouping other operators. Rules 2 and 7 appear to add functionality to the regular expression language, but they don’t. 2.  is a regular expression. 7.  is a regular expression, then so is  +. 6

7 Analyzing a Regular Expression L(( a  b )* b ) = L(( a  b )*) L( b ) = (L(( a  b )))* L( b ) = (L( a )  L( b ))* L( b ) = ({ a }  { b })* { b } = { a, b }* { b }. 7

8 Examples L( a * b * ) = L( ( a  b )* ) = L( ( a  b )* a * b * ) = L( ( a  b )* abba ( a  b )* ) = 8

9 Going the Other Way L = {w  { a, b }*: |w| is even} 9

10 Going the Other Way L = {w  { a, b }*: |w| is even} (( a  b ) ( a  b ))* ( aa  ab  ba  bb )* 10

11 Going the Other Way L = {w  { a, b }*: |w| is even} (( a  b ) ( a  b ))* ( aa  ab  ba  bb )* L = {w  { a, b }*: w contains an odd number of a ’s} 11

12 Going the Other Way L = {w  { a, b }*: |w| is even} (( a  b ) ( a  b ))* ( aa  ab  ba  bb )* L = {w  { a, b }*: w contains an odd number of a ’s} b * ( ab * ab *)* a b * b * a b * ( ab * ab *)* 12

13 More Regular Expression Examples L ( ( aa *)   ) = L ( ( a   )* ) = L = {w  { a, b }*: there is no more than one b in w} L = {w  { a, b }* : no two consecutive letters in w are the same} 13

14 Common Idioms (  )(  ) optional  ( a  b )*  *, where  = {a, b} 14

15 Operator Precedence in Regular Expressions RegularArithmeticExpressions HighestKleene starexponentiation concatenationmultiplication Lowestunionaddition a b *  c d *x y 2 + i j 2 15

16 The Details Matter a *  b *  ( a  b )* ( ab )*  a * b * 16

17 Kleene’s Theorem Finite state machines and regular expressions define the same class of languages. To prove this, we must show: Theorem: Any language that can be defined with a regular expression can be accepted by some FSM and so is regular. Theorem: Every regular language (i.e., every language that can be accepted by some DFSM) can be defined with a regular expression. To prove A = B, we have to prove: 1. A  B and 2. B  A 17

18 For Every Regular Expression There is a Corresponding FSM We’ll show this by construction. An FSM for:  : 18

19 For Every Regular Expression There is a Corresponding FSM We’ll show this by construction. An FSM for:  : 19

20 For Every Regular Expression There is a Corresponding FSM We’ll show this by construction. An FSM for:  : A single element c of  : 20

21 For Every Regular Expression There is a Corresponding FSM We’ll show this by construction. An FSM for:  : A single element c of  : 21

22 For Every Regular Expression There is a Corresponding FSM We’ll show this by construction. An FSM for:  : A single element c of  :  (  *): 22

23 For Every Regular Expression There is a Corresponding FSM We’ll show this by construction. An FSM for:  : A single element c of  :  (  *): 23

24 Union If  is the regular expression    and if both L(  ) and L(  ) are regular: 24

25 Union S3S3   25

26 Concatenation If  is the regular expression  and if both L(  ) and L(  ) are regular: 26

27 Concatenation   27

28 Kleene Star If  is the regular expression  * and if L(  ) is regular: 28

29 Kleene Star S2S2    29

30 An Example (b  ab )* An FSM for b An FSM for a An FSM for b An FSM for ab : 30

31 An Example ( b  ab )* An FSM for ( b  ab ): 31

32 An Example ( b  ab )* An FSM for ( b  ab )*: 32

33 The Algorithm regextofsm regextofsm(  : regular expression) = Beginning with the primitive subexpressions of  and working outwards until an FSM for all of  has been built do: Construct an FSM as described above. 33

34 For Every FSM There is a Corresponding Regular Expression We’ll show this by construction. The key idea is that we’ll allow arbitrary regular expressions to label the transitions of an FSM. 34

35 A Simple Example Let M be: Suppose we rip out state 2: 35

36 The Algorithm fsmtoregexheuristic fsmtoregexheuristic(M: FSM) = 1. Remove unreachable states from M. 2. If M has no accepting states then return . 3. If the start state of M is part of a loop, create a new start state s and connect s to M’s start state via an  -transition. 4. If there is more than one accepting state of M or there are any transitions out of any of them, create a new accepting state and connect each of M’s accepting states to it via an  -transition. The old accepting states no longer accept. 5. If M has only one state then return . 6. Until only the start state and the accepting state remain do: 6.1 Select rip (not s or an accepting state). 6.2 Remove rip from M. 6.3 *Modify the transitions among the remaining states so M accepts the same strings. 7. Return the regular expression that labels the one remaining transition from the start state to the accepting state. 36

37 An Example 1. Create a new initial state and a new, unique accepting state, neither of which is part of a loop. 37

38 An Example, Continued 2. Remove states and arcs and replace with arcs labelled with larger and larger regular expressions. It’s to create a source and a sink! 38

39 An Example, Continued Remove state 3: 39

40 An Example, Continued Remove state 2: 40

41 An Example, Continued Remove state 1: 41 The goal is to keep the source and the sink only!

42 It’s not always easy M = 42 Try removing state [2]!

43 Further Modifications to M Before We Start We require that, from every state other than the accepting state there must be exactly one transition to every state (including itself) except the start state. And into every state other than the start state there must be exactly one transition from every state (including itself) except the accepting state. 1. If there is more than one transition between states p and q, collapse them into a single transition: becomes: 43

44 Further Modifications to M Before We Start 2. If any of the required transitions are missing, add them: becomes: 44

45 Ripping Out States 3. Choose a state. Rip it out. Restore functionality. Suppose we rip state 2. 45

46 What Happens When We Rip? Consider any pair of states p and q. Once we remove rip, how can M get from p to q? ● It can still take the transition that went directly from p to q, or ● It can take the transition from p to rip. Then, it can take the transition from rip back to itself zero or more times. Then it can take the transition from rip to q. 46

47 Defining R(p, q) After removing rip, the new regular expression that should label the transition from p to q is: R(p, q) /* Go directly from p to q  /* or R(p, rip) /* Go from p to rip, then R(rip, rip)* /* Go from rip back to itself any number of times, then R(rip, q) /* Go from rip to q Without the comments, we have: R = R(p, q)  R(p, rip) R(rip, rip)* R(rip, q) 47

48 Returning to Our Example R = R(p, q)  R(p, rip) R(rip, rip)* R(p, rip) Let rip be state 2. Then: R (1, 3) = R(1, 3)  R(1, rip)R(rip, rip)*R(rip, 3) = R(1, 3)  R(1, 2)R(2, 2)*R(2, 3) =   a b * a = ab * a 48

49 Returning to Our Example 49 R (4, 4) = R(4, 3)  R(4, 2)R(2, 2)*R(2, 4) =   b b *  =  14 3  bb * a ab * a b R (4, 3) = R(4, 3)  R(4, 2)R(2, 2)*R(2, 3) =   b b * a = bb * a R (1, 4) = R(1, 4)  R(1, 2)R(2, 2)*R(2, 4) = b  a b *  = b Rip state 4: R (1, 3) = R(1, 3)  R(1, 4)R(4, 4)*R(4, 3) = ab * a  b  * bb * a = ab * a  b  bb * a = ab * a  bbb * a

50 The Algorithm fsmtoregex fsmtoregex(M: FSM) = 1. M = standardize(M: FSM). 2. Return buildregex(M). standardize(M: FSM) = 1. Remove unreachable states from M. 2. If necessary, create a new start state. 3. If necessary, create a new accepting state. 4. If there is more than one transition between states p and q, collapse them. 5. If any transitions are missing, create them with label . 50

51 The Algorithm fsmtoregex buildregex(M: FSM) = 1. If M has no accepting states then return . 2. If M has only one state, then return . 3. Until only the start and accepting states remain do: 3.1 Select some state rip of M. 3.2 For every transition from p to q, if both p and q are not rip then do Compute the new label R for the transition from p to q: R (p, q) = R(p, q)  R(p, rip) R(rip, rip)* R(rip, q) 3.3 Remove rip and all transitions into and out of it. 4. Return the regular expression that labels the transition from the start state to the accepting state. 51 The case of p = q should also be considered!

52 Regular Expression or FSM Kleene’s Theorem –Regular expression  FSM Q: when to use regular expression and when to use FSM to describe a regular language? Order –Regular expression: must specify the order in which a sequence of symbols must occur Phone number, email address, etc. –FSM: order doesn’t matter Vending machine, parity checking, etc. Sometimes it’s easier to do it one way, sometimes the other. 52

53 Sometimes Writing Regular Expressions is Easy No two consecutive letters are the same –(b   )(ab)*(a   ) or (a   )(ba)*(b   ) Floating point number –(   +  -)D + (  .D + )(   (E(   +  -)D + )) where D = (0  1  2  3  4  5  6  7  8  9) 53

54 Sometimes Building a DFSM is Easy A Special Case of Pattern Matching Suppose that we want to match a pattern that is composed of a set of keywords. Then we can write a regular expression of the form: (  * (k 1  k 2  …  k n )  *) + We can use regextofsm to build an FSM. But … We can instead use buildkeywordFSM. 54

55 Recognize {cat, bat, cab} The single keyword cat: 55

56 {cat, bat, cab} Adding bat and cab: 56

57 {cat, bat, cab} Adding transitions to recover after a path dies: 57

58 Using Regular Expressions in the Real World Matching numbers Matching IP addresses Scanning valid email address Determining legal password Finding doubled words (e.g., “the the” in word processor) Identifying spam 58

59 Using Substitution Building a chatbot: On input: is the chatbot will reply: Why is ? Example: The food there is awful Why is the food there awful? 59

60 Simplifying Regular Expressions Regular expression as sets: ● Union is commutative:    =    ● Union is associative: (    )   =   (    ) ●  is the identity for union:    =    =  ● Union is idempotent:    =  ● If B  A, A  B = A Concatenation: ● Concatenation is associative: (  )  =  (  ) ●  is the identity for concatenation:   =   =  ●  is a zero for concatenation:   =   =  Concatenation distributes over union: ● (    )  = (   )  (   ) ●  (    ) = (   )  (   ) 60

61 Simplifying Regular Expressions Kleene star: ●  * =  ●  * =  ● (  *)* =  * ●  *  * =  * ● If L(  *)  L(  *) then  *  * =  * ● (    )* = (  *  *)* ● If L(  )  L(  *) then (    )* =  * 61

62 Example ● ((a* U  )*  aa)(b  bb)* b* ((a  b)* b*  ab)* = ((a* )*  aa)(b  bb)* b* ((a  b)* b*  ab)* = (a*  aa)(b  bb)* b* ((a  b)* b*  ab)* = a* (b  bb)* b* ((a  b)* b*  ab)* = a* b* b* ((a  b)* b*  ab)* = a* b* ((a  b)* b*  ab)* = a* b* ((a  b)*  ab)* = a* b* (a  b)* = a* (a  b)* = (a  b)* 62

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