FIT2014 Theory of Computation Lecture 6 Regular Expressions
Monash University
Faculty of Information Technology
FIT2014 Theory of Computation
Lecture 6
Regular Expressions
slides by
based in part on previous slides by
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Overview
I Some Problems
I Applications of Regular Expressions
I Regular Expressions
I Regular Languages
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Some Problems
I Find all the files which contain old subject course codes.
I Find all the e-mail addresses in a set of mail files.
I Change the way comments in programs are formatted in your web pages.
I Using web server access files, record how many times each page is visited, and
how many times each link is used.
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Applications of Regular Expressions
I Useful way to describe simple patterns.
I Used in several programs:
I Editors: vi, emacs
I Filters: egrep, sed, gawk
I Programming languages: JFlex, CUP, Perl
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Filters
egrep
I A program which searches a file for a pattern described by a regular expression.
sed
I A program which enables stream editing of files.
awk, nawk, gawk
I Programming languages which enable text manipulation.
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Programming Languages
JFlex, flex, lex
I Languages used to generate lexical analysers.
CUP, bison, yacc
I Languages used to generate compilers.
Perl
I A powerful scripting language, developed in the 1980s by .
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Regular Expressions for Small Languages
The empty language ∅
Language {ε} consisting only of the empty word ε
Language {w} consisting only of the single word w w
E.g.:
the language {abbab} abbab
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Alternatives, Grouping
Alternatives
are indicated by ∪.
E.g.:
1 ∪ 2 ∪ 3 ∪ 4 ∪ 5 ∪ 6 ∪ 7 ∪ 8 ∪ 9
is a regular expression for:
{1, 2, 3, 4, 5, 6, 7, 8, 9}
Grouping
is indicated by ( ).
E.g.:
(ab ∪ ba)(e ∪ g)
is a regular expression for:
{abe, abg, bae, bag}
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Finite Languages
consist of finite number of words.
E.g.:
{abaaba, abbbba, abbaba}
Regular Expression:
abaaba ∪ abbbba ∪ abbaba
. . . or:
ab(aa ∪ bb ∪ ba)ba
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Kleene Star
Matching an expression zero or more times is indicated by ∗
For example:
a∗ represents {ε, a, aa, aaa, aaaa, . . .}
(ab)∗ represents {ε, ab, abab, ababab, . . .}
ab∗ represents {a, ab, abb, abbb, abbbb, . . .}
Note: ab∗ 6= (ab)∗
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Kleene Star
(aa ∪ bb)∗ = (aa ∪ bb)0 ∪ (aa ∪ bb)1 ∪ (aa ∪ bb)2 ∪ · · ·
= ε ∪ (aa ∪ bb) ∪ (aa ∪ bb)(aa ∪ bb) ∪ · · ·
represents:
{ ε, aa, bb, aaaa, aabb, bbaa, bbbb, aaaaaa, aaaabb, aabbaa, . . . }
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Parse Tree
(a ∪ ε)b∗
(a ∪ ε) b∗
a ∪ ε b
a ε
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Definition
1. ∅ and ε are regular expressions
2. All letters in the alphabet are regular expressions.
3. If R and S are regular expressions, then so are:
(i) (R)
(ii) RS
(iii) R ∪ S
(iv) R∗
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Regular Language
A language which can be described by a regular expression is called a regular
language.
If a word belongs to the language described by a regular expression, then we say it is
matched by the regular expression.
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Example: EVEN-EVEN
Recall:
EVEN-EVEN = {All strings in which a and b each occur an even number of times }
= {ε, aa, bb, aaaa, aabb, abab, abba, . . .}.
Regular Expression:
( aa ∪ bb ∪ (ab ∪ ba)(aa ∪ bb)∗(ab ∪ ba) )∗
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Things to think about . . .
Is the set of all English words (in some standard dictionary) a regular language?
Is DOUBLEWORD (see Lecture 1) a regular language?
Is PALINDROME a regular language?
Is the set of all grammatical English sentences a regular language?
How would you determine, for a given string and regular expression, whether the string
matches the regular expression?
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Example: Floating Point Number
A floating point number has one or more digits, which may begin with a minus sign (−),
and which may contain a decimal point.
E.g.,
0 1.2 − 3 − 4.675 002 023.50
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Sequence of Digits
One Digit
0 ∪ 1 ∪ 2 ∪ 3 ∪ 4 ∪ 5 ∪ 6 ∪ 7 ∪ 8 ∪ 9
Two Digits
(0 ∪ 1 ∪ 2 ∪ 3 ∪ 4 ∪ 5 ∪ 6 ∪ 7 ∪ 8 ∪ 9)(0 ∪ 1 ∪ 2 ∪ 3 ∪ 4 ∪ 5 ∪ 6 ∪ 7 ∪ 8 ∪ 9)
Three Digits
(0∪1∪2∪3∪4∪5∪6∪7∪8∪9)(0∪1∪2∪3∪4∪5∪6∪7∪8∪9)(0∪1∪2∪3∪4∪5∪6∪7∪8∪9)
One or more Digits
(0 ∪ 1 ∪ 2 ∪ 3 ∪ 4 ∪ 5 ∪ 6 ∪ 7 ∪ 8 ∪ 9)(0 ∪ 1 ∪ 2 ∪ 3 ∪ 4 ∪ 5 ∪ 6 ∪ 7 ∪ 8 ∪ 9)∗
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Sequences of Digits
Digit
D = (0 ∪ 1 ∪ 2 ∪ 3 ∪ 4 ∪ 5 ∪ 6 ∪ 7 ∪ 8 ∪ 9)
Two Digits
DD or D2
Three Digits
DDD or D3
One or more Digits
DD∗
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Numbers
One Digit
D = (0 ∪ 1 ∪ 2 ∪ 3 ∪ 4 ∪ 5 ∪ 6 ∪ 7 ∪ 8 ∪ 9)
Nonnegative Integers
N = DD∗ e.g.: 1 123 1209 002 020
Integers
Z = N ∪ (−N)
Floating Point Number
F = Z ∪ (Z .) ∪ (.N) ∪ (−.N) ∪ (Z .N)
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Other Notations
alternative notation
R ∪ S R | S
0 ∪ 1 ∪ 2 ∪ 3 ∪ 4 ∪ 5 ∪ 6 ∪ 7 ∪ 8 ∪ 9 [0-9]
any letter a to z [a-z]
RR∗ R+
ε ∪ R R?
Be careful! Many variations exist. Tools that use regexps differ in many details:
I whether or not they use the above special meanings of + and ? ;
I how they handle the parentheses and vertical bar for alternatives
I sometimes (· · · |· · · )
I sometimes \(· · · \|· · · \)
I how they use full stop (often represents any non-newline character);
I how they represent newline characters
I . . .
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Revision
I Regular Expressions
I Definitions
I How to use them to define languages
I Regular languages
Read Sipser, §1.3, pp 63–66.
Additional Reading
I Jeffrey E.F. Friedl, Mastering Regular Expressions: Powerful Techniques for Perl
and Other Tools, O’Reilly, 1997.
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