Presentation is loading. Please wait.

Presentation is loading. Please wait.

The Pumping Lemma for CFL’s

Published by Modified over 9 years ago

Similar presentations

Presentation on theme: "The Pumping Lemma for CFL’s"— Presentation transcript:

1 The Pumping Lemma for CFL’s
Statement Applications

2 Intuition Recall the pumping lemma for regular languages.
It told us that if there was a string long enough to cause a cycle in the DFA for the language, then we could “pump” the cycle and discover an infinite sequence of strings that had to be in the language.

3 Intuition – (2) For CFL’s the situation is a little more complicated.
We can always find two pieces of any sufficiently long string to “pump” in tandem. That is: if we repeat each of the two pieces the same number of times, we get another string in the language.

4 Statement of the CFL Pumping Lemma
For every context-free language L There is an integer n, such that For every string z in L of length > n There exists z = uvwxy such that: |vwx| < n. |vx| > 0. For all i > 0, uviwxiy is in L.

5 Proof of the Pumping Lemma
Start with a CNF grammar for L – {ε}. Let the grammar have m variables. Pick n = 2m. Let |z| > n. We claim (“Lemma 1 ”) that a parse tree with yield z must have a path of length m+2 or more.

6 Proof of Lemma 1 If all paths in the parse tree of a CNF grammar are of length < m+1, then the longest yield has length 2m-1, as in: m variables one terminal 2m-1 terminals

7 Back to the Proof of the Pumping Lemma
Now we know that the parse tree for z has a path with at least m+1 variables. Consider some longest path. There are only m different variables, so among the lowest m+1 we can find two nodes with the same label, say A. The parse tree thus looks like:

8 Parse Tree in the Pumping-Lemma Proof
v y x w Can’t both be ε. < 2m = n because a longest path chosen

9 Pump Zero Times u y u y A w A v x A w

10 Pump Twice u y u y A v x A v x A v x A w A w

11 Pump Thrice Etc., Etc. u y u y A v x A v x A v x A w A v x A w

12 Using the Pumping Lemma
Non-CFL’s typically involve trying to match two pairs of counts or match two strings. Example: The text uses the pumping lemma to show that {ww | w in (0+1)*} is not a CFL.

13 Using the Pumping Lemma – (2)
{0i10i | i > 1} is a CFL. We can match one pair of counts. But L = {0i10i10i | i > 1} is not. We can’t match two pairs, or three counts as a group. Proof using the pumping lemma. Suppose L were a CFL. Let n be L’s pumping-lemma constant.

14 Using the Pumping Lemma – (3)
Consider z = 0n10n10n. We can write z = uvwxy, where |vwx| < n, and |vx| > 1. Case 1: vx has no 0’s. Then at least one of them is a 1, and uwy has at most one 1, which no string in L does.

15 Using the Pumping Lemma – (4)
Still considering z = 0n10n10n. Case 2: vx has at least one 0. vwx is too short (length < n) to extend to all three blocks of 0’s in 0n10n10n. Thus, uwy has at least one block of n 0’s, and at least one block with fewer than n 0’s. Thus, uwy is not in L.

Download ppt "The Pumping Lemma for CFL’s"

Similar presentations

The Pumping Lemma for CFL’s

The Pumping Lemma for CFL’s
1 Parse Trees Definitions Relationship to Left- and Rightmost Derivations Ambiguity in Grammars.

1 Parse Trees Definitions Relationship to Left- and Rightmost Derivations Ambiguity in Grammars.
CS 3240: Languages and Computation Properties of Context-Free Languages.

CS 3240: Languages and Computation Properties of Context-Free Languages.
Turing machines Sipser 2.3 and 3.1 (pages 123-144)

Turing machines Sipser 2.3 and 3.1 (pages )
Turing machines Sipser 2.3 and 3.1 (pages 123-144)

Turing machines Sipser 2.3 and 3.1 (pages )
1 Introduction to Computability Theory Lecture7: The Pumping Lemma for Context Free Languages Prof. Amos Israeli.

1 Introduction to Computability Theory Lecture7: The Pumping Lemma for Context Free Languages Prof. Amos Israeli.
Lecture 15UofH - COSC 3340 - Dr. Verma 1 COSC 3340: Introduction to Theory of Computation University of Houston Dr. Verma Lecture 15.

Lecture 15UofH - COSC Dr. Verma 1 COSC 3340: Introduction to Theory of Computation University of Houston Dr. Verma Lecture 15.
1 Module 33 Non-context free languages –Intuition and Examples CFL Pumping Lemma –Comparison to regular language pumping lemma –What it means –Proof overview.

1 Module 33 Non-context free languages –Intuition and Examples CFL Pumping Lemma –Comparison to regular language pumping lemma –What it means –Proof overview.
127 The Chomsky Hierarchy(review) Recursively Enumerable Sets Turing Machines Post System Markov Algorithms,  -recursive Functions Regular Expression.

127 The Chomsky Hierarchy(review) Recursively Enumerable Sets Turing Machines Post System Markov Algorithms,  -recursive Functions Regular Expression.
Costas Busch - RPI1 Standard Representations of Regular Languages Regular Languages DFAs NFAs Regular Expressions Regular Grammars.

Costas Busch - RPI1 Standard Representations of Regular Languages Regular Languages DFAs NFAs Regular Expressions Regular Grammars.
Normal Forms for CFG’s Eliminating Useless Variables Removing Epsilon

Normal Forms for CFG’s Eliminating Useless Variables Removing Epsilon
Courtesy Costas Busch - RPI1 The Pumping Lemma for Context-Free Languages.

Courtesy Costas Busch - RPI1 The Pumping Lemma for Context-Free Languages.
Transparency No. P2C5-1 Formal Language and Automata Theory Part II Chapter 5 The Pumping Lemma and Closure properties for Context-free Languages.

Transparency No. P2C5-1 Formal Language and Automata Theory Part II Chapter 5 The Pumping Lemma and Closure properties for Context-free Languages.
1 1. Show the result of each of the following set operations in terms of set property. Write your sets as simple as possible. (a) L 0  L 4 (b) L 0  L.

1 1. Show the result of each of the following set operations in terms of set property. Write your sets as simple as possible. (a) L 0  L 4 (b) L 0  L.
1 The Pumping Lemma for Context-Free Languages. 2 Take an infinite context-free language Example: Generates an infinite number of different strings.

1 The Pumping Lemma for Context-Free Languages. 2 Take an infinite context-free language Example: Generates an infinite number of different strings.
Costas Busch - RPI1 The Pumping Lemma for Context-Free Languages.

Costas Busch - RPI1 The Pumping Lemma for Context-Free Languages.
1 Module 36 Non context-free languages –Examples and Intuition Pumping lemma for CFL’s –Pumping condition –No proof of pumping lemma –Applying pumping.

1 Module 36 Non context-free languages –Examples and Intuition Pumping lemma for CFL’s –Pumping condition –No proof of pumping lemma –Applying pumping.
1 More Applications of the Pumping Lemma. 2 The Pumping Lemma: Given a infinite regular language there exists an integer for any string with length we.

1 More Applications of the Pumping Lemma. 2 The Pumping Lemma: Given a infinite regular language there exists an integer for any string with length we.
CS5371 Theory of Computation Lecture 9: Automata Theory VII (Pumping Lemma, Non-CFL)

CS5371 Theory of Computation Lecture 9: Automata Theory VII (Pumping Lemma, Non-CFL)
Fall 2004COMP 3351 Standard Representations of Regular Languages Regular Languages DFAs NFAs Regular Expressions Regular Grammars.

Fall 2004COMP 3351 Standard Representations of Regular Languages Regular Languages DFAs NFAs Regular Expressions Regular Grammars.

Similar presentations

Ads by Google