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Deterministic Finite Automata

πŸ”„ Description πŸ”„

Deterministic Finite Automata (DFA) simulator written in Prolog.

Table of Contents:


πŸ“ƒ Definitions πŸ“ƒ

We define a deterministic finite automaton (DFA) as a tuple:

$$ \langle Q, \Sigma, \delta, q_0, F \rangle $$

where:

  • $Q$ is a finite set of states
  • $\Sigma$ is a finite alphabet
  • $\delta: Q \times \Sigma \rightarrow Q$ is a transition function
  • $q_0 \in Q$ is an initial state
  • $F \subseteq Q$ is a set of accept states

We say that an automaton accepts a word $w = a_1a_2\dots a_n,\ n \geq 0$ if:

$$ \delta(q_0, a_1) = q_1, \delta(q_1, a_2) = q_2, \dots,\delta(q_{n-1}, a_n) = q_n $$

and state $q_n$ is an accept state.

A language accepted by an automaton $A$ is defined as a set of words accepted by that automaton:

$$ L(A) = \{ w: \text{automaton} \ A \ \text{accepts the word} \ w \} $$


πŸ”€ Specification πŸ”€

A DFA is represented by terms of the form:

dfa(+TransitionFunction, +InitialState, -AcceptStatesSet)

where:

  • TransitionFunction is a list of terms of form fp(S1, C, S2) meaning, that $\delta(S1, C) = S2$
  • InitialState is an initial state of automaton
  • AcceptStatesSet is a list of all unique accept states of an automaton

⏺ Predicates ⏺

correct(+Automaton, -Representation)

True $\iff$ Automaton is a term representing a deterministic finite automaton and Representation is a non-complex term representing internal automaton structure.


accept(+Automaton, ?Word)

True $\iff$ given Automaton accepts the word Word. The parameter Word can be a non-complex term (a list of elements), as well as a complex term.

In case when Word is a complex term but a closed list, the predicate acts as a generator of words that complies with given pattern and therefore is accepted by the given Automaton.

In case when Word is a variable, the predicate acts as a generator of all the words belonging to the language accepted by the Automaton.


empty(+Automaton)

True $\iff$ the language accepted by the Automaton is empty.


equal(+Automaton1, +Automaton2)

True $\iff$ $L($Automaton1$) = L($Automaton2$)$ and the alphabets of both automata are equal.


subsetEq(+Automaton1, +Automaton2)

True $\iff$ $L($Automaton1$) \subseteq L($Automaton2$)$ and the alphabets of both automata are equal.


✨ Examples ✨

example(+AutomatonId, +Automaton)

example(a11, dfa([fp(1,a,1), fp(1,b,2), fp(2,a,2), fp(2,b,1)], 1, [2,1])).

example(a12, dfa([fp(x,a,y), fp(x,b,x), fp(y,a,x), fp(y,b,x)], x, [x,y])).

example(a2, dfa([fp(1,a,2), fp(2,b,1), fp(1,b,3), fp(2,a,3), fp(3,b,3), fp(3,a,3)], 1, [1])).

example(a3, dfa([fp(0,a,1), fp(1,a,0)], 0, [0])).

example(a4, dfa([fp(x,a,y), fp(y,a,z), fp(z,a,x)], x, [x])).

example(a5, dfa([fp(x,a,y), fp(y,a,z), fp(z,a,zz), fp(zz,a,x)], x, [x])).

example(a6, dfa([fp(1,a,1), fp(1,b,2), fp(2,a,2), fp(2,b,1)], 1, [])).

example(a7, dfa([fp(1,a,1), fp(1,b,2), fp(2,a,2), fp(2,b,1), fp(3,b,3), fp(3,a,3)], 1, [3])).

Automata a11 and a12 accept words of form $\{ a, b \}*$, so words over the alphabet $\Sigma = \{ a, b \}$.

Automaton a2 accepts words of form $(ab)^n, \ n \geq 0$.

Automaton a3 accepts words of form $(aa)^n, \ n \geq 0$, automaton a4 accepts words of form $(aaa)^n, \ n \geq 0$ and automaton a5 accepts words of form $(aaaa)^n, \ n \geq 0$.

The languages accepted by automata a6 and a7 are empty, since the set of accept states of automaton a6 is empty, and the only accept state of automaton a7 is not reachable from the initial state.


⏩ Example usage ⏩

sudo apt-get update && sudo apt-get install swi-prolog
swipl
consult('dfa.pl').
consult('examples.pl').

The following predicates should be true:

example(a11, A), example(a12, B), equal(A, B).
example(a2, A), example(a11, B), subsetEq(A, B).
example(a5, A), example(a3, B), subsetEq(A, B).
example(a6, A), empty(A).
example(a7, A), empty(A).
example(a2, A), accept(A, []).
example(a2, A), accept(A, [a,b]).
example(a2, A), accept(A, [a,b,a,b]).

The following predicates should be false:

example(a2, A), empty(A).
example(a3, A), example(a4, B), equal(A, B).
example(a4, A), example(a3, B), subsetEq(A, B).
example(a2, A), accept(A, [a]).

Predicate example(a11, A), accept(A, [X,Y,Z]). will generate 8 answers corresponding to all 3-letter words over the two-letter alphabet.

Predicate example(a11, A), accept(A, Var). will generate every word in the language accepted accepted by the automaton in a finite time.

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