Theoretical Aspects of Lexical Analysis/Exercise 1: Difference between revisions

Latest revision as of 18:22, 26 April 2026

Problem

Use Thompson's algorithm to build the NFA for the following regular expression. Build the corresponding DFA and minimize it.

(a|b)*

Solution

The non-deterministic finite automaton (NFA), built by applying Thompson's algorithm to the regular expression (a|b)* is the following:

NFA for (a\|b)*

Applying the determination algorithm to the above NFA, the following determination table is obtained:

I_n	α∈Σ	move(I_n, α)	ε-closure(move(I_n, α))	I_n+1 = ε-closure(move(I_n, α))
-	-	0	0, 1, 2, 4, 7	0
0	a	3	1, 2, 3, 4, 6, 7	1
0	b	5	1, 2, 4, 5, 6, 7	2
1	a	3	1, 2, 3, 4, 6, 7	1
1	b	5	1, 2, 4, 5, 6, 7	2
2	a	3	1, 2, 3, 4, 6, 7	1
2	b	5	1, 2, 4, 5, 6, 7	2

Graphically, the DFA is represented as follows: Given the minimization tree to the right, the final minimal DFA is:	The minimization tree is as follows. As can be seen, the states are indistinguishable.

@@ Line 1: / Line 1: @@
+__NOTOC__
+<div class="section-container auto" data-section>
+  <div class="section">
+    <p class="title" data-section-title>Problem</p>
+    <div class="content" data-section-content>
+<!-- ====================== START OF PROBLEM ====================== -->
 Use Thompson's algorithm to build the NFA for the following regular expression. Build the corresponding DFA and minimize it.
-* <nowiki>(a|b)*</nowiki>
+* '''<nowiki>(a|b)*</nowiki>'''
+<!-- ====================== END OF PROBLEM ====================== -->
+    </div>
+  </div>
+  <div class="section">
+    <p class="title" data-section-title>Solution</p>
+    <div class="content" data-section-content>
+<!-- ====================== START OF SOLUTION ====================== -->
+The non-deterministic finite automaton (NFA), built by applying Thompson's algorithm to the regular expression '''<nowiki>(a|b)*</nowiki>''' is the following:
+{{CollapsedCode|NFA for <nowiki>(a|b)*</nowiki>|
+<kroki lang="graphviz">
+digraph nfa {
+     { node [shape=circle style=invis] start }
+  rankdir=LR; ratio=0.5
+  node [shape=doublecircle,fixedsize=true,width=0.2,fontsize=10]; 7
+  node [shape=circle,fixedsize=true,width=0.2,fontsize=10];
+  start -> 0
+-> 1
+-> 2
+-> 4
+-> 3 [label="a",fontsize=10]
+-> 5 [label="b",fontsize=10]
+-> 6
+-> 6
+-> 1
+-> 7
+-> 7
+  fontsize=10
+}
+</kroki>
+}}
+Applying the determination algorithm to the above NFA, the following determination table is obtained:
+{| cellspacing="2"
+! style="padding-left: 20px; padding-right: 20px; background: wheat;" | I<sub>n</sub>
+! style="padding-left: 20px; padding-right: 20px; background: wheat;" | α∈Σ
+! style="padding-left: 20px; padding-right: 20px; background: wheat;" | move(I<sub>n</sub>, α)
+! style="padding-left: 20px; padding-right: 20px; background: wheat;" | ε-closure(move(I<sub>n</sub>, α))
+! style="padding-left: 20px; padding-right: 20px; background: wheat;" | I<sub>n+1</sub> = ε-closure(move(I<sub>n</sub>, α))
+|-
+! style="font-weight: normal; align: center; background: #ffffcc;" | -
+! style="font-weight: normal; align: center; background: #ffffcc;" | -
+! style="font-weight: normal; align: center; background: #ffffcc;" | 0
+! style="font-weight: normal; align: left;   background: #ffffcc;" | 0, 1, 2, 4, '''7'''
+! style="font-weight: normal; align: center; background: #ffffcc;" | '''0'''
+|-
+! style="font-weight: normal; align: center; background: #e6e6e6;" | 0
+! style="font-weight: normal; align: center; background: #e6e6e6;" | a
+! style="font-weight: normal; align: center; background: #e6e6e6;" | 3
+! style="font-weight: normal; align: left;   background: #e6e6e6;" | 1, 2, 3, 4, 6, '''7'''
+! style="font-weight: normal; align: center; background: #e6e6e6;" | '''1'''
+|-
+! style="font-weight: normal; align: center; background: #e6e6e6;" | 0
+! style="font-weight: normal; align: center; background: #e6e6e6;" | b
+! style="font-weight: normal; align: center; background: #e6e6e6;" | 5
+! style="font-weight: normal; align: left;   background: #e6e6e6;" | 1, 2, 4, 5, 6, '''7'''
+! style="font-weight: normal; align: center; background: #e6e6e6;" | '''2'''
+|-
+! style="font-weight: normal; align: center; background: #ffffcc;" | 1
+! style="font-weight: normal; align: center; background: #ffffcc;" | a
+! style="font-weight: normal; align: center; background: #ffffcc;" | 3
+! style="font-weight: normal; align: left;   background: #ffffcc;" | 1, 2, 3, 4, 6, '''7'''
+! style="font-weight: normal; align: center; background: #ffffcc;" | '''1'''
+|-
+! style="font-weight: normal; align: center; background: #ffffcc;" | 1
+! style="font-weight: normal; align: center; background: #ffffcc;" | b
+! style="font-weight: normal; align: center; background: #ffffcc;" | 5
+! style="font-weight: normal; align: left;   background: #ffffcc;" | 1, 2, 4, 5, 6, '''7'''
+! style="font-weight: normal; align: center; background: #ffffcc;" | '''2'''
+|-
+! style="font-weight: normal; align: center; background: #e6e6e6;" | 2
+! style="font-weight: normal; align: center; background: #e6e6e6;" | a
+! style="font-weight: normal; align: center; background: #e6e6e6;" | 3
+! style="font-weight: normal; align: left;   background: #e6e6e6;" | 1, 2, 3, 4, 6, '''7'''
+! style="font-weight: normal; align: center; background: #e6e6e6;" | '''1'''
+|-
+! style="font-weight: normal; align: center; background: #e6e6e6;" | 2
+! style="font-weight: normal; align: center; background: #e6e6e6;" | b
+! style="font-weight: normal; align: center; background: #e6e6e6;" | 5
+! style="font-weight: normal; align: left;   background: #e6e6e6;" | 1, 2, 4, 5, 6, '''7'''
+! style="font-weight: normal; align: center; background: #e6e6e6;" | '''2'''
+|}
+{| width="100%"
+! style="text-align: left; font-weight:normal; vertical-align: top; width: 50%;" |Graphically, the DFA is represented as follows:
+<kroki lang="graphviz">
+digraph dfa {
+     { node [shape=circle style=invis] start }
+  rankdir=LR; ratio=0.5
+  node [shape=doublecircle,fixedsize=true,width=0.2,fontsize=10]; 0 1 2
+  node [shape=circle,fixedsize=true,width=0.2,fontsize=10];
+  start -> 0
+-> 1 [label="a"]
+-> 2 [label="b"]
+-> 1  [label="a"]
+-> 2  [label="b"]
+-> 1 [label="a"]
+-> 2 [label="b"]
+  fontsize=10
+}
+</kroki>
+Given the minimization tree to the right, the final minimal DFA is:
+<kroki lang="graphviz">
+digraph dfamin {
+     { node [shape=circle style=invis] start }
+  rankdir=LR; ratio=0.5
+  node [shape=doublecircle,fixedsize=true,width=0.4,fontsize=10]; 012
+  node [shape=circle,fixedsize=true,width=0.2,fontsize=10];
+  start -> 012
+-> 012 [label="a"]
+-> 012 [label="b"]
+  fontsize=10
+  /*label="DFA for (a|b)*"*/
+}
+</kroki>
+! style="text-align: left; font-weight:normal; vertical-align: top; width: 50%;" | The minimization tree is as follows. As can be seen, the states are indistinguishable.
+<kroki lang="graphviz">
+digraph mintree {
+  node [shape=none,fixedsize=true,width=0.2,fontsize=10]
+  " {0, 1, 2}" -> "{}" [label="NF",fontsize=10]
+  " {0, 1, 2}" -> "{0, 1, 2}" [label="F",fontsize=10]
+  "{0, 1, 2}" -> "{0, 1, 2} " [label="a,b",fontsize=10]
+  fontsize=10
+  /*label="Minimization tree"*/
+}
+</kroki>
+|}
+<!-- ====================== END OF SOLUTION ====================== -->
+    </div>
+  </div>
+</div>
+[[category:Compiladores]]
+[[category:Ensino]]
+[[en:Theoretical Aspects of Lexical Analysis]]

Theoretical Aspects of Lexical Analysis/Exercise 1: Difference between revisions

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Latest revision as of 18:22, 26 April 2026