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Location: Regular-Expresso/src/regexp.rs
c532c271f407
7.3 KiB
application/rls-services+xml
refactoring: rules as a vector instead of a hashmap
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mod token;
pub use token::ParsingError;
use token::parse;
const START_NFA: usize = usize::MAX;
const START_DFA: usize = 0;
const FAIL: usize = usize::MAX>>1;
fn encode_set(set: &HashSet<usize>) -> String {
let mut v = Vec::from_iter(set.iter());
v.sort();
let res: Vec<String> = v.into_iter().map(|x| x.to_string()).collect();
return res.join(",");
}
#[derive(Debug)]
pub struct Regexp {
rules: HashMap<(usize, char), HashSet<usize>>,
end_states: HashSet<usize>,
alphabet: Vec<char>
}
impl Regexp {
pub fn new(pattern: &String) -> Result<Regexp, ParsingError> {
let r = parse(pattern, 0)?;
let pattern_chars = Vec::from_iter(pattern.chars());
let mut rules: HashMap<(usize, char), HashSet<usize>> = HashMap::new();
let mut alphabet: HashSet<char> = HashSet::new();
for i in r.list_first() {
let c = pattern_chars[i];
alphabet.insert(c);
let key = (START_NFA, c);
match rules.get_mut(&key) {
Some(set) => {set.insert(i);},
None => {rules.insert(key, HashSet::from([i]));}
};
}
for (i, j) in r.list_neighbours() {
let c = pattern_chars[j];
alphabet.insert(c);
let key = (i, c);
match rules.get_mut(&key) {
Some(set) => {set.insert(j);},
None => {rules.insert(key, HashSet::from([j]));}
};
}
let mut end_states = HashSet::from_iter(r.list_last().into_iter());
if r.is_skippable() {
end_states.insert(START_NFA);
}
let mut alphabet_vec = Vec::from_iter(alphabet.into_iter());
alphabet_vec.sort();
return Ok(Regexp{rules, end_states, alphabet: alphabet_vec});
}
pub fn eval(&self, s: String) -> bool {
let mut multistate = HashSet::from([START_NFA]);
for c in s.chars() {
let mut new_multistate = HashSet::new();
for state in multistate {
if let Some(x) = self.rules.get(&(state, c)) {
new_multistate = new_multistate.union(&x).map(|&y| y).collect();
} else if let Some(x) = self.rules.get(&(state, '.')) {
new_multistate = new_multistate.union(&x).map(|&y| y).collect();
}
}
multistate = new_multistate;
}
return multistate.iter().any(|x| self.end_states.contains(x));
}
pub fn determinize(&self) -> RegexpDFA {
let alphabet_index: HashMap<char, usize> = self.alphabet.iter().enumerate().map(|(i, c)| (*c, i)).collect();
let n = alphabet_index.len();
let mut compact_rules = vec![FAIL; n];
let mut end_states: HashSet<usize> = HashSet::new();
if self.end_states.contains(&START_NFA) {end_states.insert(START_DFA);}
// string hash -> single int DFA state
let mut index_new = HashMap::from([(START_NFA.to_string(), START_DFA)]);
// string hash -> HashSet NFA multistate
let mut index_multi = HashMap::from([(START_NFA.to_string(), HashSet::from([START_NFA]))]);
let mut stack = Vec::from([START_NFA.to_string()]);
while !stack.is_empty() {
let state_hash = stack.pop().unwrap();
let multistate = &index_multi[&state_hash];
let mut new_rules: HashMap<char, HashSet<usize>> = HashMap::new();
for key in self.rules.keys().filter(|key| multistate.contains(&key.0)) {
let (_st, c) = key;
if !new_rules.contains_key(c) {
new_rules.insert(*c, HashSet::new());
}
for target in &self.rules[key] {
new_rules.get_mut(c).unwrap().insert(*target);
}
}
for (c, target_set) in new_rules.into_iter() {
let target_hash = encode_set(&target_set);
let is_end = target_set.iter().any(|st| self.end_states.contains(st));
if !index_new.contains_key(&target_hash) {
let target_new = index_new.len();
index_new.insert(target_hash.clone(), target_new);
index_multi.insert(target_hash.clone(), target_set);
compact_rules.extend(iter::repeat(FAIL).take(n));
stack.push(target_hash.clone());
}
compact_rules[index_new[&state_hash]*n + alphabet_index[&c]] = index_new[&target_hash];
if is_end {
end_states.insert(index_new[&target_hash]);
}
}
}
return RegexpDFA{rules: compact_rules, end_states, alphabet_index};
}
}
pub struct RegexpDFA {
rules: Vec<usize>,
end_states: HashSet<usize>,
alphabet_index: HashMap<char, usize>
}
impl RegexpDFA {
pub fn eval(&self, s: String) -> bool {
let n = self.alphabet_index.len();
let mut state = START_DFA;
for c in s.chars() {
if let Some(ci) = self.alphabet_index.get(&c) {
state = self.rules[state*n + ci];
} else {
return false;
}
if state == FAIL {
return false;
}
}
return self.end_states.contains(&state);
}
pub fn reduce(&self) -> RegexpDFA {
if self.alphabet_index.len() == 0 {
return RegexpDFA{rules: self.rules.clone(), end_states: self.end_states.clone(), alphabet_index: self.alphabet_index.clone()};
}
let equivalents = self.find_equivalent_states();
return self.collapse_states(equivalents);
}
pub fn normalize(&self) -> RegexpDFA {
let n = self.alphabet_index.len();
if n == 0 {
return RegexpDFA{rules: self.rules.clone(), end_states: self.end_states.clone(), alphabet_index: self.alphabet_index.clone()};
}
let m = self.rules.len()/n;
let mut index: Vec<usize> = vec![FAIL;m];
index[0] = 0;
let mut queue = VecDeque::from([START_DFA]);
let mut rules = vec![];
let mut k = 1;
while !queue.is_empty() {
let si = queue.pop_front().unwrap();
let row = &self.rules[si*n..(si+1)*n];
for &sj in row {
if sj != FAIL && index[sj] == FAIL {
index[sj] = k;
k += 1;
queue.push_back(sj);
}
}
rules.extend(row.iter().map(|&st| if st != FAIL {index[st]} else {FAIL}));
}
let end_states = self.end_states.iter().map(|st| index[*st]).collect();
return RegexpDFA{rules, end_states, alphabet_index: self.alphabet_index.clone()};
}
fn find_equivalent_states(&self) -> Vec<(usize, usize)> {
let n = self.alphabet_index.len();
let state_vec: Vec<usize> = (0..self.rules.len()/n).collect();
let mut equivalents = HashSet::new();
state_vec.iter().enumerate().for_each(|(i, s1)| {
equivalents.extend(
state_vec[i+1..].iter()
.filter(|s2| !(self.end_states.contains(s1)^self.end_states.contains(s2)))
.map(|s2| (*s1, *s2))
);
});
let mut m = usize::MAX;
while equivalents.len() < m {
m = equivalents.len();
equivalents = equivalents.iter().filter(|(s1, s2)| {
!(0..n).any(|ci| {
let t1 = self.rules[s1*n + ci];
let t2 = self.rules[s2*n + ci];
let key = (t1.min(t2), t2.max(t1));
return t1 != t2 && !equivalents.contains(&key);
})
}).copied().collect();
}
return Vec::from_iter(equivalents.into_iter());
}
fn collapse_states(&self, equivalents: Vec<(usize, usize)>) -> RegexpDFA {
let n = self.alphabet_index.len();
let m = self.rules.len()/n;
let mut rules = Vec::new();
let mut eq_mapping: Vec<usize> = ((0..m)).collect();
for (s1, s2) in equivalents.into_iter() {
eq_mapping[s2] = eq_mapping[s2].min(s1);
}
let mut discard_mapping: Vec<usize> = ((0..m)).collect();
let mut discard_count = 0;
for si in 0..m {
if eq_mapping[si] != si {
discard_count += 1;
continue;
}
discard_mapping[si] = si-discard_count;
rules.extend(self.rules[si*n..(si+1)*n].iter().map(|&st| if st!=FAIL {eq_mapping[st]} else {FAIL}));
}
rules = rules.into_iter().map(|st| if st!=FAIL {discard_mapping[st]} else {FAIL}).collect();
let end_states = self.end_states.iter().map(|st| discard_mapping[eq_mapping[*st]]).collect();
return RegexpDFA{rules, end_states, alphabet_index: self.alphabet_index.clone()};
}
}
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