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#include <deque>
#include <iostream>
#include <tuple>
#include <unordered_set>
#include <vector>
struct State;
struct Transition {
char symbol;
State *successor;
};
struct State {
std::vector<State *> epsilon_transitions;
std::vector<Transition> transitions;
std::unordered_set<std::string> visited_strings;
};
struct Automaton {
State *initial_state;
State *final_state;
};
Automaton Eps() {
Automaton c;
c.initial_state = c.final_state = new State;
return c;
}
Automaton Sym(char symbol) {
Automaton c;
c.initial_state = new State;
c.final_state = new State;
c.initial_state->transitions.push_back({symbol, c.final_state});
return c;
}
Automaton Star(Automaton a) {
Automaton c;
c.initial_state = c.final_state = new State;
c.final_state->epsilon_transitions.push_back(a.initial_state);
a.final_state->epsilon_transitions.push_back(c.final_state);
return c;
}
Automaton Cat(Automaton a, Automaton b) {
Automaton c;
c.initial_state = a.initial_state;
c.final_state = b.final_state;
a.final_state->epsilon_transitions.push_back(b.initial_state);
return c;
}
Automaton Alt(Automaton a, Automaton b) {
Automaton c;
c.initial_state = new State;
c.final_state = new State;
c.initial_state->epsilon_transitions.push_back(a.initial_state);
c.initial_state->epsilon_transitions.push_back(b.initial_state);
a.final_state->epsilon_transitions.push_back(c.final_state);
b.final_state->epsilon_transitions.push_back(c.final_state);
return c;
}
void Enumerate(Automaton a, std::size_t size_limit = 4) // Kleene-Star operator, manages limited size to avoid infinity
{
std::deque<std::pair<State *, std::string>> queue = {
{a.initial_state, std::string()}};
do {
auto state = queue.front().first;
auto string = queue.front().second;
if (string.size() > size_limit) {
std::cout << "...\n";
break;
}
queue.pop_front();
if (!state->visited_strings.insert(string).second) {
continue;
}
if (state == a.final_state) {
std::cout << "\"" << string << "\"\n";
}
for (State *successor : state->epsilon_transitions) {
queue.push_front({successor, string});
}
for (auto transition : state->transitions) {
auto symbol = transition.symbol;
auto successor = transition.successor;
queue.push_back({successor, string + std::string(1, symbol)});
}
} while (!queue.empty());
std::cout << "\n";
}
#include <cctype>
#include <cstdio>
#include <istream>
#include <sstream>
char Peek(std::istream &input) {
input >> std::ws;
return input.peek();
}
bool Match(std::istream &input, char c) {
if (Peek(input) == c) {
input.get();
return true;
}
return false;
}
bool ParseSymbol(std::istream &input, char& result) {
if (std::isalpha(Peek(input))) {
result = input.get();
return true;
}
return false;
}
bool Parse(std::istream &input, Automaton& result);
bool ParsePrimitive(std::istream &input, Automaton& result) {
char symbol;
if (ParseSymbol(input, symbol)) {
result = Sym(symbol);
return true;
}
if (Match(input, '(')) {
Automaton a;
if (Parse(input, a)) {
if (Match(input, ')')) {
result = a;
return true;
}
}
}
return false;
}
bool ParseFactor(std::istream &input, Automaton& result) {
Automaton a;
if (ParsePrimitive(input, a)) {
if (Match(input, '*')) {
result = Star(a);
return true;
}
result = a;
return true;
}
return false;
}
bool ParseTerm(std::istream &input, Automaton& result) {
Automaton a;
if (ParseFactor(input, a)) {
while (Match(input, '.')) {
Automaton b;
if (ParseFactor(input, b)) {
a = Cat(a, b);
} else {
return false;
}
}
result = a;
return true;
}
return false;
}
bool Parse(std::istream &input, Automaton& result) {
Automaton a;
if (ParseTerm(input, a)) {
while (Match(input, '|')) {
Automaton b;
if (ParseTerm(input, b)) {
a = Alt(a, b);
} else {
return false;
}
}
result = a;
return true;
}
return false;
}
bool Parse(const std::string &input, Automaton& result) {
std::stringstream stream(input);
Automaton a;
if (Parse(stream, a)) {
if (Peek(stream) == EOF) {
result = a;
return true;
}
}
return false;
}
int main() {
// Parse parameters won't allow number chars, how so?
Automaton result;
if (Parse("a", result)) { Enumerate(result); } else std::cout << "Failed to parse\n";
if (Parse("a|b", result)) { Enumerate(result); } else std::cout << "Failed to parse\n";
if (Parse("a.b", result)) { Enumerate(result); } else std::cout << "Failed to parse\n";
if (Parse("(a|b).c", result)) { Enumerate(result); } else std::cout << "Failed to parse\n";
if (Parse("(c|d).(a|b)", result)) { Enumerate(result); } else std::cout << "Failed to parse\n";
if (Parse("a*", result)) { Enumerate(result); } else std::cout << "Failed to parse\n";
if (Parse("(a|b)*", result)) { Enumerate(result); } else std::cout << "Failed to parse\n";
}
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