Difference between revisions of "PFP Homework 1"

From Marek Běhálek Wiki
Jump to navigation Jump to search
Line 1: Line 1:
 
= Automatons =  
 
= Automatons =  
Usually, a finite automaton defined as: <math>(Q, \Sigma, \delta, q_0, F)</math> where Q represents a states, next is input aplhabet, then transitions (<math>Q \times \Sigma \rightarrow q</math>, <math>q_0</math> is starting state and finaly there is a set of final states.
+
Usually, a finite automaton defined as: <math>(Q, \Sigma, \delta, q_0, F)</math> where Q represents a states, next is input alphabet, then transitions (<math>Q \times \Sigma \rightarrow Q</math>), <math>q_0</math> is starting state and finaly there is a set of final states.
  
 
In our case, an finite automaton is represented by types:
 
In our case, an finite automaton is represented by types:
Line 9: Line 9:
 
where:
 
where:
 
* first number <code>N</code> defines number of states - states will be coded by integer numbers in interval <math><0, N)</math>;
 
* 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.
+
* 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 (
+
* 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>;
where states are coded with numbers from 0 to n
+
* <math>q_0</math> is a number from interval <math><0, N)</math>;
 +
* finally, there is a list of number representing posible states that are final in defined automaton.
  
 +
As examples we can use following automatons:
 
<syntaxhighlight lang="Haskell">
 
<syntaxhighlight lang="Haskell">
 
ex1 :: Automaton  
 
ex1 :: Automaton  

Revision as of 12:16, 10 October 2023

Automatons

Usually, a finite automaton defined as: where Q represents a states, next is input alphabet, then transitions (), is starting state and finaly there is a set of final states.

In our case, an 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 ;
  • 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: ;
  • is a number from interval ;
  • finally, there is a list of number representing posible states that are final in defined automaton.

As examples we can use following automatons:

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

ex2 :: Automaton 
ex2 = (3, [0], [2], "ab", [(0,'a',1), (0,'a',0), (0,'b',0), (1,'b',2)])
  • Create a function, that sorts an array using quicksort algorithm quicksort. Inside, you must use the mutable array STArray.
quickSort :: Array Int Int -> Array Int Int
ghci> elems $ quickSort $  listArray (0,5) [8,4,9,6,7,1] 
[1,4,6,7,8,9]