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string_proc.rs
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string_proc.rs
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//! String processing algorithms.
use std::cmp::{max, min};
use std::collections::{hash_map::Entry, HashMap, VecDeque};
/// Prefix trie, easily augmentable by adding more fields and/or methods
pub struct Trie<C: std::hash::Hash + Eq> {
links: Vec<HashMap<C, usize>>,
}
impl<C: std::hash::Hash + Eq> Default for Trie<C> {
/// Creates an empty trie with a root node.
fn default() -> Self {
Self {
links: vec![HashMap::new()],
}
}
}
impl<C: std::hash::Hash + Eq> Trie<C> {
/// Inserts a word into the trie, and returns the index of its node.
pub fn insert(&mut self, word: impl IntoIterator<Item = C>) -> usize {
let mut node = 0;
for ch in word {
let len = self.links.len();
node = match self.links[node].entry(ch) {
Entry::Occupied(entry) => *entry.get(),
Entry::Vacant(entry) => {
entry.insert(len);
self.links.push(HashMap::new());
len
}
}
}
node
}
/// Finds a word in the trie, and returns the index of its node.
pub fn get(&self, word: impl IntoIterator<Item = C>) -> Option<usize> {
let mut node = 0;
for ch in word {
node = *self.links[node].get(&ch)?;
}
Some(node)
}
}
/// Single-pattern matching with the Knuth-Morris-Pratt algorithm
pub struct Matcher<'a, C: Eq> {
/// The string pattern to search for.
pub pattern: &'a [C],
/// KMP match failure automaton: fail[i] is the length of the longest
/// string that's both a proper prefix and a proper suffix of pattern[0..=i].
pub fail: Vec<usize>,
}
impl<'a, C: Eq> Matcher<'a, C> {
/// Precomputes the automaton that allows linear-time string matching.
///
/// # Example
///
/// ```
/// use contest_algorithms::string_proc::Matcher;
/// let byte_string: &[u8] = b"hello";
/// let utf8_string: &str = "hello";
/// let vec_char: Vec<char> = utf8_string.chars().collect();
///
/// let match_from_byte_literal = Matcher::new(byte_string);
/// let match_from_utf8 = Matcher::new(utf8_string.as_bytes());
/// let match_from_chars = Matcher::new(&vec_char);
///
/// let vec_int = vec![4, -3, 1];
/// let match_from_ints = Matcher::new(&vec_int);
/// ```
///
/// # Panics
///
/// Panics if pattern is empty.
pub fn new(pattern: &'a [C]) -> Self {
let mut fail = Vec::with_capacity(pattern.len());
fail.push(0);
let mut len = 0;
for ch in &pattern[1..] {
while len > 0 && pattern[len] != *ch {
len = fail[len - 1];
}
if pattern[len] == *ch {
len += 1;
}
fail.push(len);
}
Self { pattern, fail }
}
/// KMP algorithm, sets @return[i] = length of longest prefix of pattern
/// matching a suffix of text[0..=i].
pub fn kmp_match(&self, text: impl IntoIterator<Item = C>) -> Vec<usize> {
let mut len = 0;
text.into_iter()
.map(|ch| {
if len == self.pattern.len() {
len = self.fail[len - 1];
}
while len > 0 && self.pattern[len] != ch {
len = self.fail[len - 1];
}
if self.pattern[len] == ch {
len += 1;
}
len
})
.collect()
}
}
/// Multi-pattern matching with the Aho-Corasick algorithm
pub struct MultiMatcher<C: std::hash::Hash + Eq> {
/// A prefix trie storing the string patterns to search for.
pub trie: Trie<C>,
/// Stores which completed pattern string each node corresponds to.
pub pat_id: Vec<Option<usize>>,
/// Aho-Corasick failure automaton. fail[i] is the node corresponding to the
/// longest prefix-suffix of the node corresponding to i.
pub fail: Vec<usize>,
/// Shortcut to the next match along the failure chain, or to the root.
pub fast: Vec<usize>,
}
impl<C: std::hash::Hash + Eq> MultiMatcher<C> {
fn next(trie: &Trie<C>, fail: &[usize], mut node: usize, ch: &C) -> usize {
loop {
if let Some(&child) = trie.links[node].get(ch) {
return child;
} else if node == 0 {
return 0;
}
node = fail[node];
}
}
/// Precomputes the automaton that allows linear-time string matching.
/// If there are duplicate patterns, all but one copy will be ignored.
pub fn new(patterns: impl IntoIterator<Item = impl IntoIterator<Item = C>>) -> Self {
let mut trie = Trie::default();
#[allow(clippy::needless_collect)] // It's not needless: it affects trie.links.len()
let pat_nodes: Vec<usize> = patterns.into_iter().map(|pat| trie.insert(pat)).collect();
let mut pat_id = vec![None; trie.links.len()];
for (i, node) in pat_nodes.into_iter().enumerate() {
pat_id[node] = Some(i);
}
let mut fail = vec![0; trie.links.len()];
let mut fast = vec![0; trie.links.len()];
let mut q: VecDeque<usize> = trie.links[0].values().cloned().collect();
while let Some(node) = q.pop_front() {
for (ch, &child) in &trie.links[node] {
let nx = Self::next(&trie, &fail, fail[node], ch);
fail[child] = nx;
fast[child] = if pat_id[nx].is_some() { nx } else { fast[nx] };
q.push_back(child);
}
}
Self {
trie,
pat_id,
fail,
fast,
}
}
/// Aho-Corasick algorithm, sets @return[i] = node corresponding to
/// longest prefix of some pattern matching a suffix of text[0..=i].
pub fn ac_match(&self, text: impl IntoIterator<Item = C>) -> Vec<usize> {
let mut node = 0;
text.into_iter()
.map(|ch| {
node = Self::next(&self.trie, &self.fail, node, &ch);
node
})
.collect()
}
/// For each non-empty match, returns where in the text it ends, and the index
/// of the corresponding pattern.
pub fn get_end_pos_and_pat_id(&self, match_nodes: &[usize]) -> Vec<(usize, usize)> {
let mut res = vec![];
for (text_pos, &(mut node)) in match_nodes.iter().enumerate() {
while node != 0 {
if let Some(id) = self.pat_id[node] {
res.push((text_pos + 1, id));
}
node = self.fast[node];
}
}
res
}
}
/// Suffix array data structure, useful for a variety of string queries.
pub struct SuffixArray {
/// The suffix array itself, holding suffix indices in sorted order.
pub sfx: Vec<usize>,
/// rank[i][j] = rank of the j'th suffix, considering only 2^i chars.
/// In other words, rank[i] is a ranking of the substrings text[j..j+2^i].
pub rank: Vec<Vec<usize>>,
}
impl SuffixArray {
/// O(n + max_key) stable sort on the items generated by vals.
/// Items v in vals are sorted according to val_to_key[v].
fn counting_sort(
vals: impl Iterator<Item = usize> + Clone,
val_to_key: &[usize],
max_key: usize,
) -> Vec<usize> {
let mut counts = vec![0; max_key];
for v in vals.clone() {
counts[val_to_key[v]] += 1;
}
let mut total = 0;
for c in counts.iter_mut() {
total += *c;
*c = total - *c;
}
let mut result = vec![0; total];
for v in vals {
let c = &mut counts[val_to_key[v]];
result[*c] = v;
*c += 1;
}
result
}
/// Suffix array construction in O(n log n) time.
pub fn new(text: impl IntoIterator<Item = u8>) -> Self {
let init_rank = text.into_iter().map(|ch| ch as usize).collect::<Vec<_>>();
let n = init_rank.len();
let mut sfx = Self::counting_sort(0..n, &init_rank, 256);
let mut rank = vec![init_rank];
// Invariant at the start of every loop iteration:
// suffixes are sorted according to the first skip characters.
for skip in (0..).map(|i| 1 << i).take_while(|&skip| skip < n) {
let prev_rank = rank.last().unwrap();
let mut cur_rank = prev_rank.clone();
let pos = (n - skip..n).chain(sfx.into_iter().filter_map(|p| p.checked_sub(skip)));
sfx = Self::counting_sort(pos, prev_rank, max(n, 256));
let mut prev = sfx[0];
cur_rank[prev] = 0;
for &cur in sfx.iter().skip(1) {
if max(prev, cur) + skip < n
&& prev_rank[prev] == prev_rank[cur]
&& prev_rank[prev + skip] == prev_rank[cur + skip]
{
cur_rank[cur] = cur_rank[prev];
} else {
cur_rank[cur] = cur_rank[prev] + 1;
}
prev = cur;
}
rank.push(cur_rank);
}
Self { sfx, rank }
}
/// Computes the length of longest common prefix of text[i..] and text[j..].
pub fn longest_common_prefix(&self, mut i: usize, mut j: usize) -> usize {
let mut len = 0;
for (k, rank) in self.rank.iter().enumerate().rev() {
if rank[i] == rank[j] {
i += 1 << k;
j += 1 << k;
len += 1 << k;
if max(i, j) >= self.sfx.len() {
break;
}
}
}
len
}
}
/// Manacher's algorithm for computing palindrome substrings in linear time.
/// pal[2*i] = odd length of palindrome centred at text[i].
/// pal[2*i+1] = even length of palindrome centred at text[i+0.5].
///
/// # Panics
///
/// Panics if text is empty.
pub fn palindromes(text: &[impl Eq]) -> Vec<usize> {
let mut pal = Vec::with_capacity(2 * text.len() - 1);
pal.push(1);
while pal.len() < pal.capacity() {
let i = pal.len() - 1;
let max_len = min(i + 1, pal.capacity() - i);
while pal[i] < max_len && text[(i - pal[i] - 1) / 2] == text[(i + pal[i] + 1) / 2] {
pal[i] += 2;
}
if let Some(a) = 1usize.checked_sub(pal[i]) {
pal.push(a);
} else {
for d in 1.. {
let (a, b) = (pal[i - d], pal[i] - d);
if a < b {
pal.push(a);
} else {
pal.push(b);
break;
}
}
}
}
pal
}
/// Z algorithm: computes the array Z[..], where Z[i] is the length of the
/// longest text prefix of text[i..] that is **also a prefix** of text.
///
/// It runs in O(n) time, maintaining the invariant that l <= i and
/// text[0..r-l] == text[l..r]. It can be embedded in a larger algorithm,
/// or used for string searching as an alternative to KMP.
///
/// # Example
///
/// ```
/// use contest_algorithms::string_proc::z_algorithm;
/// let z = z_algorithm(b"ababbababbabababbabababbababbaba");
/// assert_eq!(
/// z,
/// vec![
/// 32, 0, 2, 0, 0, 9, 0, 2, 0, 0, 4, 0, 9, 0, 2, 0, 0, 4, 0, 13, 0, 2,
/// 0, 0, 8, 0, 2, 0, 0, 3, 0, 1,
/// ],
/// );
/// ```
pub fn z_algorithm(text: &[impl Eq]) -> Vec<usize> {
let n = text.len();
let (mut l, mut r) = (1, 1);
let mut z = Vec::with_capacity(n);
z.push(n);
for i in 1..n {
if r > i + z[i - l] {
z.push(z[i - l]);
} else {
l = i;
while r < i || (r < n && text[r - i] == text[r]) {
r += 1;
}
z.push(r - i);
}
}
z
}
#[cfg(test)]
mod test {
use super::*;
#[test]
fn test_trie() {
let dict = vec!["banana", "benefit", "banapple", "ban"];
let trie = dict.into_iter().fold(Trie::default(), |mut trie, word| {
trie.insert(word.bytes());
trie
});
assert_eq!(trie.get("".bytes()), Some(0));
assert_eq!(trie.get("b".bytes()), Some(1));
assert_eq!(trie.get("banana".bytes()), Some(6));
assert_eq!(trie.get("be".bytes()), Some(7));
assert_eq!(trie.get("bane".bytes()), None);
}
#[test]
fn test_kmp_matching() {
let pattern = "ana";
let text = "banana";
let matches = Matcher::new(pattern.as_bytes()).kmp_match(text.bytes());
assert_eq!(matches, vec![0, 1, 2, 3, 2, 3]);
}
#[test]
fn test_ac_matching() {
let dict = vec!["banana", "benefit", "banapple", "ban", "fit"];
let text = "banana bans, apple benefits.";
let matcher = MultiMatcher::new(dict.iter().map(|s| s.bytes()));
let match_nodes = matcher.ac_match(text.bytes());
let end_pos_and_id = matcher.get_end_pos_and_pat_id(&match_nodes);
assert_eq!(
end_pos_and_id,
vec![(3, 3), (6, 0), (10, 3), (26, 1), (26, 4)]
);
}
#[test]
fn test_suffix_array() {
let text1 = "bobocel";
let text2 = "banana";
let sfx1 = SuffixArray::new(text1.bytes());
let sfx2 = SuffixArray::new(text2.bytes());
assert_eq!(sfx1.sfx, vec![0, 2, 4, 5, 6, 1, 3]);
assert_eq!(sfx2.sfx, vec![5, 3, 1, 0, 4, 2]);
assert_eq!(sfx1.longest_common_prefix(0, 2), 2);
assert_eq!(sfx2.longest_common_prefix(1, 3), 3);
// Check that sfx and rank.last() are essentially inverses of each other.
for (p, &r) in sfx1.rank.last().unwrap().iter().enumerate() {
assert_eq!(sfx1.sfx[r], p);
}
for (p, &r) in sfx2.rank.last().unwrap().iter().enumerate() {
assert_eq!(sfx2.sfx[r], p);
}
}
#[test]
fn test_palindrome() {
let text = "banana";
let pal_len = palindromes(text.as_bytes());
assert_eq!(pal_len, vec![1, 0, 1, 0, 3, 0, 5, 0, 3, 0, 1]);
}
}