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lfa:2022:lab06-dfa-to-regex [2022/11/11 18:54]
mihai.udubasa reformat 		lfa:2022:lab06-dfa-to-regex [2022/11/19 10:34] (current)
alexandra.udrescu01
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 ====== 6. Dfa to Regex conversions ====== ====== 6. Dfa to Regex conversions ======
  
-==== 6.1. TBD ====+==== 6.1. State elimination ​====
  
 Consider the following DFAs: Consider the following DFAs:
  
-**DFA1**+**DFA1** ​^ **DFA2** ^ 
 +|{{ :​lfa:​screenshot_2021-11-04_at_15.33.10.png?​400 |}}| {{ :​lfa:​2022:​lfa2022_lab5_ex2_4_cerinta.png?​300 |}} |
  
-{{ :​lfa:​screenshot_2021-11-04_at_15.33.10.png?​400 |}} 
- 
-**DFA2** 
- 
-{{ :​lfa:​2022:​lfa2022_lab5_ex2_4_cerinta.png?​300 |}} 
  
 Convert the given DFAs to a Regex (using the state-elimination strategy). ​ Convert the given DFAs to a Regex (using the state-elimination strategy). ​
 Hint: is it easier to apply conversion on another DFA? Hint: is it easier to apply conversion on another DFA?
 +
 +
 +
 <hidden On what DFA should the algorithm be applied?>​ <hidden On what DFA should the algorithm be applied?>​
 It is recommended to apply the State elimination algorithm on the minimal DFA. It is recommended to apply the State elimination algorithm on the minimal DFA.
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   - first, we apply the minimisation algorithm   - first, we apply the minimisation algorithm
     * {{ :​lfa:​2022:​lab6_1_dfa1_1.png?​500 |}}     * {{ :​lfa:​2022:​lab6_1_dfa1_1.png?​500 |}}
 +  - we add the new final and initial states
 +    * {{ :​lfa:​2022:​lab6_1_dfa1_2.png?​500 |}}
   - we eliminate the state 8   - we eliminate the state 8
     - as it has no outgoing transitions,​ we can just remove it     - as it has no outgoing transitions,​ we can just remove it
-    * {{ :lfa:2022:lab6_1_dfa1_2.png?500 |}}+    * {{ :lfa:2022:lab6_1_dfa1_3.png?500 |}}
   - we eliminate the state 0,1   - we eliminate the state 0,1
     - in:     - in:
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       * init --(0*)-->​ fin       * init --(0*)-->​ fin
       * init --(0*1)-->​ 2       * init --(0*1)-->​ 2
-    * {{ :lfa:2022:lab6_1_dfa1_3.png?500 |}}+    * {{ :lfa:2022:lab6_1_dfa1_4.png?500 |}}
   - we eliminate the state 2   - we eliminate the state 2
     - in:     - in:
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       * 3 --(10)-->​ 3       * 3 --(10)-->​ 3
       * 3 --(11)-->​ 4       * 3 --(11)-->​ 4
-    * {{ :lfa:2022:lab6_1_dfa1_4.png?500 |}}+    * {{ :lfa:2022:lab6_1_dfa1_5.png?500 |}}
   - we eliminate the state 4   - we eliminate the state 4
     - in:     - in:
       * init --(0*11)-->​ 4       * init --(0*11)-->​ 4
       * 3 --(11)-->​ 4       * 3 --(11)-->​ 4
-      * 6,7 --(0)--> 4+      * 6,7 --(1)--> 4
     - out:     - out:
-      * 4 --(1)--> 6,7+      * 4 --(0)--> 6,7
     - we add:     - we add:
-      * init --(0*111)--> 6,7 +      * init --(0*110)--> 6,7 
-      * 3 --(111)--> 6,7 +      * 3 --(110)--> 6,7 
-      * 6,7 --(01)--> 6,7 +      * 6,7 --(10)--> 6,7 
-    * {{ :lfa:2022:lab6_1_dfa1_5.png?500 |}}+    * {{ :lfa:2022:lab6_1_dfa1_6.png?500 |}}
   - we eliminate the state 6,7   - we eliminate the state 6,7
     - in:     - in:
-      * init --(0*111)--> 6,7 +      * init --(0*110)--> 6,7 
-      * 3 --(111)--> 6,7 +      * 3 --(110)--> 6,7 
-      * 5 --(0)--> 6,7+      * 5 --(1)--> 6,7
     - out:     - out:
-      * 6,7 --(1)--> 5+      * 6,7 --(0)--> 5
       * 6,7 --(ε)-->​ fin       * 6,7 --(ε)-->​ fin
     - loop:     - loop:
-      * 6,7 --(01)--> 6,7+      * 6,7 --(10)--> 6,7
     - we add:     - we add:
-      * init --(0*111(01)*1)--> 5 +      * init --(0*110(10)*0)--> 5 
-      * init --(0*111(01)*)--> fin +      * init --(0*110(10)*)--> fin 
-      * 3 --(111(01)*1)--> 5 +      * 3 --(110(10)*0)--> 5 
-      * 3 --(111(01)*)--> fin +      * 3 --(110(10)*)--> fin 
-      * 5 --(0(01)*1)--> 5 +      * 5 --(1(10)*0)--> 5 
-      * 5 --(0(01)*)--> fin +      * 5 --(1(10)*)--> fin 
-    * {{ :lfa:2022:lab6_1_dfa1_6.png?500 |}}+    * {{ :lfa:2022:lab6_1_dfa1_7.png?500 |}}
   - we eliminate the state 3   - we eliminate the state 3
     - in:     - in:
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     - out:     - out:
       * 3 --(ε|1)-->​ fin       * 3 --(ε|1)-->​ fin
-      * 3 --(0|111(01)*1)--> 5+      * 3 --(0|110(10)*0)--> 5
     - loop:     - loop:
-      * 3 --(01)--> 3+      * 3 --(10)--> 3
     - we add:     - we add:
-      * init --(0*10(01)*(ε|1) )--> fin +      * init --(0*10(10)*(ε|1) )--> fin 
-      * init --(0*10(01)*(0|111(01)*1) )-->5 +      * init --(0*10(10)*(0|110(10)*0) )-->5 
-    * {{ :lfa:2022:lab6_1_dfa1_7.png?500 |}}+    * {{ :lfa:2022:lab6_1_dfa1_8.png?500 |}}
   - we eliminate the state 5   - we eliminate the state 5
     - in:     - in:
-      * init --(0*111(01)*1|0*10(01)*(0|111(01)*1) )--> 5+      * init --(0*110(10)*0|0*10(10)*(0|110(10)*0) )--> 5
     - out:     - out:
-      * 5 --(0(01)*)--> fin+      * 5 --(1(10)*)--> fin
     - loop:     - loop:
-      * 5 --(0(01)*1)--> 5+      * 5 --(1(10)*0)--> 5
     - we add:     - we add:
-      * init --( (0*111(01)*1|0*10(01)*(0|111(01)*1) ) (0(01)*1)*0(01)*)--> fin +      * init --( (0*110(10)*0|0*10(10)*(0|110(10)*0) ) (1(10)*0)*1(10)*)--> fin
-    * {{ :​lfa:​2022:​lab6_1_dfa1_8.png?​500 |}}+
   - the final regex is ''​   - the final regex is ''​
-0*|0*1|0*111(01)*|0*10(01)*(ε|1)|(0*111(01)*1|0*10(01)*(0|111(01)*1))(0(01)*1)*0(01)*''​+0*|0*1|0*110(10)*|0*10(10)*(ε|1|110(10)*)|(0*110(10)*0|0*10(10)*(0|110(10)*0))(1(10)*0)*1(10)*''​
  
 </​hidden>​ </​hidden>​
 +
 +
  
 ==== 6.2. Brzozowsky'​s algebraic method ==== ==== 6.2. Brzozowsky'​s algebraic method ====
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 === Dfa to regex conversion === === Dfa to regex conversion ===
  
-For each state $math[q], build an equation of the form: $math[q = c_1 q_1 \cup c_2 q_2 \ldots c_n q_n], such that: $math[\delta(q,​c_i) = q_i]. Here $math[c_i\in\Sigma],​ thus $math[q_i] are the $math[c_i]-successors of $math[q]. Additionally,​ if $math[q] is a final state, ​and an $math[\epsilon]:​ $math[q = c_1 q_1 \cup c_2 q_2 \ldots c_n q_n \cup \epsilon].+For each state $math[q], build an equation of the form: $math[q = c_1 q_1 \cup c_2 q_2 \ldots c_n q_n], such that: $math[\delta(q,​c_i) = q_i]. Here $math[c_i\in\Sigma],​ thus $math[q_i] are the $math[c_i]-successors of $math[q]. Additionally,​ if $math[q] is a final state, ​add an $math[\epsilon]:​ $math[q = c_1 q_1 \cup c_2 q_2 \ldots c_n q_n \cup \epsilon].
  
 ^ ^ ^ ^ ^ ^
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 === Reducing the system of equations === === Reducing the system of equations ===
  
-We can choose *any** equation **except** that corresponding to the initial state, and eliminate it, by exploiting **Arden'​s Lemma**:+We can choose ​**any** equation **except** that corresponding to the initial state, and eliminate it, by exploiting **Arden'​s Lemma**:
   * the solution to any equation of the form $math[q = e\cdot q \cup e'] is $math[q = e^*e'​].   * the solution to any equation of the form $math[q = e\cdot q \cup e'] is $math[q = e^*e'​].
  
 **Example** **Example**
  
-Goind back to the previous system of equations, we can find the solution to $math[q_2] which is: $math[(A \cup B)^*]. Next, we can replace the solution to $math[q_2] in $math[q_1] which yields:+Going back to the previous system of equations, we can find the solution to $math[q_2] which is: $math[(A \cup B)^*]. Next, we can replace the solution to $math[q_2] in $math[q_1] which yields:
   * $math[q_1 = A q_1 \cup B(A\cup B)^*].   * $math[q_1 = A q_1 \cup B(A\cup B)^*].
   * We apply Arden'​s Lemma one more time and yield: $math[q_1 = A^*B(A \cup B)^*].   * We apply Arden'​s Lemma one more time and yield: $math[q_1 = A^*B(A \cup B)^*].
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  ​6.2.1. Apply Brzozowsky'​s method to find a regex for the following DFA:  ​6.2.1. Apply Brzozowsky'​s method to find a regex for the following DFA:
 ^ {{ :​lfa:​2022:​screenshot_2022-11-09_at_15.46.23.png?​200 |}} ^ ^ {{ :​lfa:​2022:​screenshot_2022-11-09_at_15.46.23.png?​200 |}} ^
 +
 +
 +
 <hidden Solution>​ <hidden Solution>​