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the automata-lab project is a implements various automata, including DFA, NFA,DPDA.

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DFA(Deterministic Finite Automata)

This is a Python implementation of a Deterministic Finite Automata (DFA), which is a simple abstract machine that recognizes patterns in strings. The implementation provides a basic framework for defining and working with DFAs.

ClassDFA

The DFA class represents a DFA. It has the following methods:

def __init__(self, states, input_symbols, transitions, initial_state, final_states)

This method is the constructor for the DFA class. It takes the following parameters:

  • states: A list of the states in the DFA.
  • input_symbols: A list of the symbols in the alphabet that the DFA will accept.
  • transitions: A dictionary that defines the transition function of the DFA. The keys are pairs of states and symbols, and the values are the states to which the DFA transitions when it is in the key's state and reads the key's symbol.
  • initial_state: The state in which the DFA starts.
  • final_states: A list of the accept states of the DFA.

ExampleUsage

Here's an example of how to use the DFA class to define:

DFA (states={'q0', 'q1', 'q2'},
    input_symbols={'0', '1'},
    transitions={
        'q0': {'0': 'q0', '1': 'q1'},
        'q1': {'0': 'q0', '1': 'q2'},
        'q2': {'0': 'q2', '1': 'q1'}
    },
    initial_state='q0',
    final_states={'q1'})

Methods

accept_string (self, string)

The accept_string method checks if a given string is accepted by the DFA. It iterates over the characters in the string and uses the transition function to move from one state to another. If the final state is in the set of accept states, the method returns True, indicating the string is accepted. Otherwise, it returns False.

DFA.accept_string('0101')
# True

union (self, other)

DFA.union(dfa1,dfa2)
# return a new DFA that accepts the union of the language of dfa1 and dfa2

intersection (self, other)

DFA.intersection(dfa1,dfa2)
# return a new DFA that accepts the intersection of the language of dfa1 and dfa2

complement (self)

DFA.complement(dfa)
# return a new DFA that accepts the complement of the language of dfa

difference (self, other)

DFA.difference(dfa1,dfa2)
# return a new DFA that accepts the difference of the language of dfa1 and dfa2

separate (self,dfa)

DFA.separate(dfa1,dfa2)
# return a TRUE if dfa1 and dfa2 are separable

is_empty (self)

DFA.is_empty(dfa)
# return a TRUE if dfa is empty

all_string_accepte (self, min_lenght, max_lenght, answer)

DFA.all_string_accepte(dfa, min_lenght, max_lenght, answer)
# return all string accepted by dfa between min_lenght and max_lenght

is_finite (self)

DFA.is_finite(dfa)
# return a TRUE if dfa is finite

shortest_string (self)

DFA.shortest_string(dfa)
# return the shortest string accepted by dfa

longest_string (self)

DFA.longest_string(dfa)
# return the longest string accepted by dfa

minimize (self)

DFA.minimize(dfa)
# return a new DFA that accepts the same language as dfa but with the minimum number of states

regex_to_dfa (self, regex)

DFA.regex_to_dfa(regex)
# return a new DFA that accepts the same language as regex

dfa_to_regex (self, dfa)

DFA.dfa_to_regex(dfa)
# return a new regex that accepts the same language as dfa

NFA (Non-Deterministic Finite Automata)

This is a Python implementation of a Non-Deterministic Finite Automata (NFA), which is a simple abstract machine that recognizes patterns in strings. The implementation provides a basic framework for defining and working with NFAs.

Class NFA

The NFA class represents a DFA. It has the following methods:

def __init__(self, states, input_symbols, transitions, initial_state, final_states)

This method is the constructor for the DFA class. It takes the following parameters:

  • states: A list of the states in the DFA.
  • input_symbols: A list of the symbols in the alphabet that the DFA will accept.
  • transitions: A dictionary that defines the transition function of the DFA. The keys are pairs of states and symbols, and the values are the states to which the DFA transitions when it is in the key's state and reads the key's symbol.
  • initial_state: The state in which the DFA starts.
  • final_states: A list of the accept states of the DFA.

ExampleUsage

Here's an example of how to use the NFA class to define:

NFA(
    states=['q0','q1', 'q2', 'q3','q4'],
    input_symbols=['a', 'b'],
    transitions={
        'q0': {'a':['q1','q2'],'b':['q4']},
        'q1': {'a': ['q0']},
        'q2': {'a': ['q3']},
        'q3': {'b': ['q0']},
        'q4': {},
        
    },
    initial_state='q0',
    final_states=['q4']

Methods

eliminate_nondeterminism(self)

NFA.eliminate_nondeterminism(nfa)
# return a new DFA that accepts the same language as nfa

lambda_closure(states_set, transitions)

NFA.lambda_closure(states_set, transitions)
# returns the lambda-closure set of a set of states

DPDA (Deterministic Pushdown Automata)

This is a Python implementation of a Deterministic Pushdown Automata (DPDA), which is a simple abstract machine that recognizes patterns in strings. The implementation provides a basic framework for defining and working with DPDA.

Class DPDA

The DPDA class is initialized with several parameters that define the properties of the DPDA:

  • states: a list of all states in the DPDA
  • input_symbols: the set of all input symbols that the DPDA can accept
  • stack_symbols: the set of all stack symbols that the DPDA uses
  • transitions: a dictionary that defines the transition function for the DPDA, where the keys are state-input symbol pairs and the values are lists of tuples that specify the next state, the symbol to be pushed onto the stack, and the symbol to be popped from the stack for that transition
  • initial_state: the start state for the DPDA
  • initial_stack_symbol: the start symbol for the stack
  • final_states: a set of states that are designated as accept states

ExampleUsage

Here's an example of how to use the DPDA class to define:

DPDA(
    states={'q0', 'q1', 'q2','q3'},
    input_symbols={'a', 'b'},
    stack_symbols = {'a','b','Z0'},
    initial_stack_symbol = 'Z0',
    transitions={
        'q0': {['a','Z0']: ['q1',['a','Z0']]},
        'q1': {['a','a']: ['q1',['a','a']], ['b','a']: ['q2',[]]}, # [] or ['']
        'q2': {['b','a']: ['q2',[]], ['','Z0']: ['q3',['Z0']]}
    },
    initial_state='q0',
    final_states={'q3'}
)

Methods

accept_string (self, string)

DPDA.accept_string(dpda, string)
# return a TRUE if dpda accepts string

Authors

this document was generated by AI

License

This project is licensed under the MIT License - see the LICENSE file for details

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the automata-lab project is a implements various automata, including DFA, NFA,DPDA.

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automata automata-theory computing-theory

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