Latest revision as of 13:03, 10 October 2023

Automatons

Usually, a finite automaton defined as: $(Q,\Sigma ,\delta ,q_{0},F)$ where Q represents states, next is input alphabet, then transitions ( $Q\times \Sigma \rightarrow Q$ ), $q_{0}$ is starting state and finally there is a set of final states.

In our case, a finite automaton is represented by types:

type Transition = (Int, Char, Int)
type Automaton = (Int, String, [Transition], Int, [Int])

where:

first number N defines number of states - states will be coded by integer numbers in interval $<0,N)$ ;
second element is a string containing the input symbols - you can safely assume; it contains no duplicities;
third is a list defining the trasition function - elementary transition is a triple (q1, a, q2) representing a transition: $q_{1}\times a\rightarrow q_{2}$ ;
$q_{0}$ is a number from interval $<0,N)$ ;
finally, there is a list of number representing possible states that are final in defined automaton.

As examples we can use following automatons:

ex1 :: Automaton 
ex1 = (3, "ab", [(0,'a',1), (0,'b',0), (1,'a',1), (1,'b',2), (2,'a',1), (2,'b',0)], 0, [2],)

ex2 :: Automaton 
ex2 = (3, "ab", [(0,'a',1), (0,'a',0), (0,'b',0), (1,'b',2)], 0, [2])

Your task will be to create three functions:

First function checks if a given finite automaton is a deterministic finite automaton.

isDeterministic:: Automaton  -> Bool

ghci>isDeterministic ex1
True
ghci>isDeterministic ex2
False

Second function runs automaton for given string and establishes, if given input string is accepted by the given automaton. It should work for both deterministic and non-deterministic finite automatons.

isAccepting:: Automaton -> String -> Bool

ghci>isAccepting ex1 "aab"
True
ghci>isAccepting ex2 "aaa"
False

Finally, create a function that takes a non-deterministic automaton and produces it's deterministic equivalent (the output can be very different based on used methodology).

convert:: Automaton -> Automaton

ghci>convert ex2
(3, "ab", [(0,'a',1), (0,'b',0), (1,'a',1), (1,'b',2), (2,'a',1), (2,'b',0)], 0, [2],)

@@ Line 1: / Line 1: @@
-= PFP Homework 1 =
+= Automatons =
+Usually, a finite automaton defined as: <math>(Q, \Sigma, \delta, q_0, F)</math> where Q represents states, next is input alphabet, then transitions (<math>Q \times \Sigma \rightarrow Q</math>), <math>q_0</math> is starting state and finally there is a set of final states.
-== Automatons ==
+In our case, a finite automaton is represented by types:
-* Create a function, that sorts an array using quicksort algorithm [https://en.wikipedia.org/wiki/Quicksort <code>quicksort</code>]. Inside, you must use the mutable array [https://hackage.haskell.org/package/array-0.5.4.0/docs/Data-Array-ST.html#t:STArray <code>STArray</code>].
+<syntaxhighlight lang="Haskell">
-<syntaxhighlight lang="Haskell">quickSort :: Array Int Int -> Array Int Int</syntaxhighlight>
+type Transition = (Int, Char, Int)
+type Automaton = (Int, String, [Transition], Int, [Int])
+</syntaxhighlight>
+where:
+* first number <code>N</code> defines number of states - states will be coded by integer numbers in interval <math><0, N)</math>;
+* second element is a string containing the input symbols - you can safely assume; it contains no duplicities;
+* third is a list defining the trasition function - elementary transition is a triple <code>(q1, a, q2)</code> representing a transition: <math>q_1 \times a \rightarrow q_2</math>;
+* <math>q_0</math> is a number from interval <math><0, N)</math>;
+* finally, there is a list of number representing possible states that are final in defined automaton.
+As examples we can use following automatons:
+<syntaxhighlight lang="Haskell">
+ex1 :: Automaton
+ex1 = (3, "ab", [(0,'a',1), (0,'b',0), (1,'a',1), (1,'b',2), (2,'a',1), (2,'b',0)], 0, [2],)
+ex2 :: Automaton
+ex2 = (3, "ab", [(0,'a',1), (0,'a',0), (0,'b',0), (1,'b',2)], 0, [2])
+</syntaxhighlight>
+Your task will be to create three functions:
+* First function checks if a given finite automaton is a '''deterministic''' finite automaton.
+<syntaxhighlight lang="Haskell">isDeterministic:: Automaton  -> Bool</syntaxhighlight>
+<syntaxhighlight lang="Haskell" class="myDark">
+ghci>isDeterministic ex1
+True
+ghci>isDeterministic ex2
+False
+</syntaxhighlight>
+* Second function runs automaton for given string and establishes, if given input string is accepted by the given automaton. It should work for both deterministic and non-deterministic finite automatons.
+<syntaxhighlight lang="Haskell">isAccepting:: Automaton -> String -> Bool</syntaxhighlight>
+<syntaxhighlight lang="Haskell" class="myDark">
+ghci>isAccepting ex1 "aab"
+True
+ghci>isAccepting ex2 "aaa"
+False
+</syntaxhighlight>
+* Finally, create a function that takes a non-deterministic automaton and produces it's deterministic equivalent (the output can be very '''different''' based on used methodology).
+<syntaxhighlight lang="Haskell">convert:: Automaton -> Automaton</syntaxhighlight>
 <syntaxhighlight lang="Haskell" class="myDark">
-ghci> elems $ quickSort $  listArray (0,5) [8,4,9,6,7,1]
+ghci>convert ex2
-[1,4,6,7,8,9]
+(3, "ab", [(0,'a',1), (0,'b',0), (1,'a',1), (1,'b',2), (2,'a',1), (2,'b',0)], 0, [2],)
 </syntaxhighlight>

Difference between revisions of "PFP Homework 1"

Latest revision as of 13:03, 10 October 2023

Automatons

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