mirror of
https://github.com/meilisearch/MeiliSearch
synced 2024-11-24 22:04:27 +01:00
463 lines
17 KiB
Rust
463 lines
17 KiB
Rust
use std::mem;
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use std::ops::RangeInclusive;
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use charabia::normalizer::NormalizedTokenIter;
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use charabia::{SeparatorKind, TokenKind};
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use fst::automaton::Str;
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use fst::{Automaton, IntoStreamer, Streamer};
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use heed::types::DecodeIgnore;
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use heed::RoTxn;
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use itertools::Itertools;
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use super::interner::{Interned, Interner};
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use super::SearchContext;
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use crate::search::fst_utils::{Complement, Intersection, StartsWith, Union};
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use crate::search::{build_dfa, get_first};
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use crate::{CboRoaringBitmapLenCodec, Index, Result};
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/// A phrase in the user's search query, consisting of several words
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/// that must appear side-by-side in the search results.
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#[derive(Default, Clone, PartialEq, Eq, Hash)]
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pub struct Phrase {
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pub words: Vec<Option<Interned<String>>>,
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}
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impl Phrase {
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pub fn description(&self, interner: &Interner<String>) -> String {
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self.words.iter().flatten().map(|w| interner.get(*w)).join(" ")
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}
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}
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/// A structure storing all the different ways to match
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/// a term in the user's search query.
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#[derive(Clone, PartialEq, Eq, Hash)]
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pub struct WordDerivations {
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/// The original word
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pub original: Interned<String>,
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// TODO: original should only be used for debugging purposes?
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// TODO: pub zero_typo: Option<Interned<String>>,
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// TODO: pub prefix_of: Box<[Interned<String>]>,
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/// All the synonyms of the original word
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pub synonyms: Box<[Interned<Phrase>]>,
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/// The original word split into multiple consecutive words
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pub split_words: Option<Interned<Phrase>>,
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/// The original words and words which are prefixed by it
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pub zero_typo: Box<[Interned<String>]>,
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/// Words that are 1 typo away from the original word
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pub one_typo: Box<[Interned<String>]>,
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/// Words that are 2 typos away from the original word
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pub two_typos: Box<[Interned<String>]>,
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/// True if the prefix databases must be used to retrieve
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/// the words which are prefixed by the original word.
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pub use_prefix_db: bool,
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}
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impl WordDerivations {
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/// Return an iterator over all the single words derived from the original word.
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///
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/// This excludes synonyms, split words, and words stored in the prefix databases.
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pub fn all_single_word_derivations_except_prefix_db(
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&'_ self,
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) -> impl Iterator<Item = Interned<String>> + Clone + '_ {
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self.zero_typo.iter().chain(self.one_typo.iter()).chain(self.two_typos.iter()).copied()
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}
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pub fn is_empty(&self) -> bool {
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self.zero_typo.is_empty()
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&& self.one_typo.is_empty()
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&& self.two_typos.is_empty()
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&& self.synonyms.is_empty()
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&& self.split_words.is_none()
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&& !self.use_prefix_db
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}
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}
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/// Compute the word derivations for the given word
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pub fn word_derivations(
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ctx: &mut SearchContext,
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word: &str,
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max_typo: u8,
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is_prefix: bool,
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) -> Result<WordDerivations> {
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let fst = ctx.index.words_fst(ctx.txn)?;
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let word_interned = ctx.word_interner.insert(word.to_owned());
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let use_prefix_db = is_prefix
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&& ctx
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.index
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.word_prefix_docids
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.remap_data_type::<DecodeIgnore>()
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.get(ctx.txn, word)?
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.is_some();
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let mut zero_typo = vec![];
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let mut one_typo = vec![];
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let mut two_typos = vec![];
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if max_typo == 0 {
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if is_prefix && !use_prefix_db {
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let prefix = Str::new(word).starts_with();
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let mut stream = fst.search(prefix).into_stream();
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while let Some(derived_word) = stream.next() {
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let derived_word = std::str::from_utf8(derived_word)?.to_owned();
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let derived_word_interned = ctx.word_interner.insert(derived_word);
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zero_typo.push(derived_word_interned);
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}
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} else if fst.contains(word) {
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zero_typo.push(word_interned);
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}
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} else if max_typo == 1 {
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let dfa = build_dfa(word, 1, is_prefix);
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let starts = StartsWith(Str::new(get_first(word)));
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let mut stream = fst.search_with_state(Intersection(starts, &dfa)).into_stream();
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// TODO: There may be wayyy too many matches (e.g. in the thousands), how to reduce them?
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while let Some((derived_word, state)) = stream.next() {
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let derived_word = std::str::from_utf8(derived_word)?;
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let d = dfa.distance(state.1);
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let derived_word_interned = ctx.word_interner.insert(derived_word.to_owned());
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match d.to_u8() {
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0 => {
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zero_typo.push(derived_word_interned);
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}
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1 => {
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one_typo.push(derived_word_interned);
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}
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_ => panic!(),
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}
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}
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} else {
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let starts = StartsWith(Str::new(get_first(word)));
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let first = Intersection(build_dfa(word, 1, is_prefix), Complement(&starts));
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let second_dfa = build_dfa(word, 2, is_prefix);
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let second = Intersection(&second_dfa, &starts);
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let automaton = Union(first, &second);
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let mut stream = fst.search_with_state(automaton).into_stream();
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// TODO: There may be wayyy too many matches (e.g. in the thousands), how to reduce them?
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while let Some((derived_word, state)) = stream.next() {
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let derived_word = std::str::from_utf8(derived_word)?;
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let derived_word_interned = ctx.word_interner.insert(derived_word.to_owned());
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// in the case the typo is on the first letter, we know the number of typo
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// is two
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if get_first(derived_word) != get_first(word) {
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two_typos.push(derived_word_interned);
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} else {
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// Else, we know that it is the second dfa that matched and compute the
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// correct distance
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let d = second_dfa.distance((state.1).0);
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match d.to_u8() {
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0 => {
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zero_typo.push(derived_word_interned);
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}
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1 => {
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one_typo.push(derived_word_interned);
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}
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2 => {
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two_typos.push(derived_word_interned);
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}
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_ => panic!(),
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}
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}
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}
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}
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let split_words = split_best_frequency(ctx.index, ctx.txn, word)?.map(|(l, r)| {
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ctx.phrase_interner.insert(Phrase {
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words: vec![Some(ctx.word_interner.insert(l)), Some(ctx.word_interner.insert(r))],
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})
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});
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let synonyms = ctx.index.synonyms(ctx.txn)?;
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let synonyms = synonyms
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.get(&vec![word.to_owned()])
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.cloned()
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.unwrap_or_default()
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.into_iter()
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.map(|words| {
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let words = words.into_iter().map(|w| Some(ctx.word_interner.insert(w))).collect();
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ctx.phrase_interner.insert(Phrase { words })
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})
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.collect();
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Ok(WordDerivations {
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original: ctx.word_interner.insert(word.to_owned()),
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synonyms,
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split_words,
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zero_typo: zero_typo.into_boxed_slice(),
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one_typo: one_typo.into_boxed_slice(),
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two_typos: two_typos.into_boxed_slice(),
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use_prefix_db,
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})
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}
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/// Split the original word into the two words that appear the
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/// most next to each other in the index.
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///
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/// Return `None` if the original word cannot be split.
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fn split_best_frequency(
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index: &Index,
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txn: &RoTxn,
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original: &str,
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) -> Result<Option<(String, String)>> {
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let chars = original.char_indices().skip(1);
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let mut best = None;
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for (i, _) in chars {
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let (left, right) = original.split_at(i);
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let key = (1, left, right);
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let frequency = index
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.word_pair_proximity_docids
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.remap_data_type::<CboRoaringBitmapLenCodec>()
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.get(txn, &key)?
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.unwrap_or(0);
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if frequency != 0 && best.map_or(true, |(old, _, _)| frequency > old) {
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best = Some((frequency, left, right));
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}
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}
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Ok(best.map(|(_, left, right)| (left.to_owned(), right.to_owned())))
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}
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#[derive(Clone, PartialEq, Eq, Hash)]
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pub enum QueryTerm {
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Phrase { phrase: Interned<Phrase> },
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// TODO: change to `Interned<WordDerivations>`?
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Word { derivations: Interned<WordDerivations> },
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}
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impl QueryTerm {
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/// Return the original word from the given query term
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pub fn original_single_word<'interner>(
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&self,
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word_interner: &'interner Interner<String>,
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derivations_interner: &'interner Interner<WordDerivations>,
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) -> Option<&'interner str> {
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match self {
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QueryTerm::Phrase { phrase: _ } => None,
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QueryTerm::Word { derivations } => {
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let derivations = derivations_interner.get(*derivations);
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if derivations.is_empty() {
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None
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} else {
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Some(word_interner.get(derivations.original))
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}
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}
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}
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}
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}
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/// A query term term coupled with its position in the user's search query.
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#[derive(Clone)]
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pub struct LocatedQueryTerm {
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pub value: QueryTerm,
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pub positions: RangeInclusive<i8>,
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}
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impl LocatedQueryTerm {
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/// Return `true` iff the word derivations within the query term are empty
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pub fn is_empty(&self, interner: &Interner<WordDerivations>) -> bool {
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match self.value {
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// TODO: phrases should be greedily computed, so that they can be excluded from
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// the query graph right from the start?
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QueryTerm::Phrase { phrase: _ } => false,
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QueryTerm::Word { derivations, .. } => interner.get(derivations).is_empty(),
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}
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}
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}
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/// Convert the tokenised search query into a list of located query terms.
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pub fn located_query_terms_from_string<'search>(
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ctx: &mut SearchContext<'search>,
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query: NormalizedTokenIter<Vec<u8>>,
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words_limit: Option<usize>,
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) -> Result<Vec<LocatedQueryTerm>> {
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let authorize_typos = ctx.index.authorize_typos(ctx.txn)?;
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let min_len_one_typo = ctx.index.min_word_len_one_typo(ctx.txn)?;
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let min_len_two_typos = ctx.index.min_word_len_two_typos(ctx.txn)?;
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// TODO: should `exact_words` also disable prefix search, ngrams, split words, or synonyms?
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let exact_words = ctx.index.exact_words(ctx.txn)?;
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let nbr_typos = |word: &str| {
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if !authorize_typos
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|| word.len() < min_len_one_typo as usize
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|| exact_words.as_ref().map_or(false, |fst| fst.contains(word))
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{
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0
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} else if word.len() < min_len_two_typos as usize {
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1
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} else {
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2
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}
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};
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let mut located_terms = Vec::new();
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let mut phrase = Vec::new();
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let mut quoted = false;
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let parts_limit = words_limit.unwrap_or(usize::MAX);
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let mut position = -1i8;
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let mut phrase_start = -1i8;
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let mut phrase_end = -1i8;
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let mut peekable = query.peekable();
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while let Some(token) = peekable.next() {
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// early return if word limit is exceeded
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if located_terms.len() >= parts_limit {
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return Ok(located_terms);
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}
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match token.kind {
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TokenKind::Word | TokenKind::StopWord => {
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position += 1;
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// 1. if the word is quoted we push it in a phrase-buffer waiting for the ending quote,
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// 2. if the word is not the last token of the query and is not a stop_word we push it as a non-prefix word,
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// 3. if the word is the last token of the query we push it as a prefix word.
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if quoted {
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phrase_end = position;
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if phrase.is_empty() {
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phrase_start = position;
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}
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if let TokenKind::StopWord = token.kind {
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phrase.push(None);
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} else {
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let word = ctx.word_interner.insert(token.lemma().to_string());
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// TODO: in a phrase, check that every word exists
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// otherwise return WordDerivations::Empty
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phrase.push(Some(word));
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}
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} else if peekable.peek().is_some() {
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match token.kind {
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TokenKind::Word => {
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let word = token.lemma();
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let derivations = word_derivations(ctx, word, nbr_typos(word), false)?;
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let located_term = LocatedQueryTerm {
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value: QueryTerm::Word {
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derivations: ctx.derivations_interner.insert(derivations),
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},
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positions: position..=position,
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};
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located_terms.push(located_term);
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}
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TokenKind::StopWord | TokenKind::Separator(_) | TokenKind::Unknown => {}
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}
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} else {
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let word = token.lemma();
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let derivations = word_derivations(ctx, word, nbr_typos(word), true)?;
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let located_term = LocatedQueryTerm {
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value: QueryTerm::Word {
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derivations: ctx.derivations_interner.insert(derivations),
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},
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positions: position..=position,
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};
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located_terms.push(located_term);
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}
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}
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TokenKind::Separator(separator_kind) => {
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match separator_kind {
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SeparatorKind::Hard => {
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position += 1;
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}
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SeparatorKind::Soft => {
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position += 0;
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}
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}
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let quote_count = token.lemma().chars().filter(|&s| s == '"').count();
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// swap quoted state if we encounter a double quote
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if quote_count % 2 != 0 {
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quoted = !quoted;
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}
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// if there is a quote or a hard separator we close the phrase.
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if !phrase.is_empty() && (quote_count > 0 || separator_kind == SeparatorKind::Hard)
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{
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let located_query_term = LocatedQueryTerm {
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value: QueryTerm::Phrase {
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phrase: ctx
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.phrase_interner
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.insert(Phrase { words: mem::take(&mut phrase) }),
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},
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positions: phrase_start..=phrase_end,
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};
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located_terms.push(located_query_term);
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}
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}
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_ => (),
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}
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}
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// If a quote is never closed, we consider all of the end of the query as a phrase.
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if !phrase.is_empty() {
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let located_query_term = LocatedQueryTerm {
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value: QueryTerm::Phrase {
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phrase: ctx.phrase_interner.insert(Phrase { words: mem::take(&mut phrase) }),
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},
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positions: phrase_start..=phrase_end,
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};
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located_terms.push(located_query_term);
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}
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Ok(located_terms)
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}
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// TODO: return a word derivations instead?
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pub fn ngram2(
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ctx: &mut SearchContext,
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x: &LocatedQueryTerm,
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y: &LocatedQueryTerm,
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) -> Option<(Interned<String>, RangeInclusive<i8>)> {
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if *x.positions.end() != y.positions.start() - 1 {
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return None;
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}
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match (
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&x.value.original_single_word(&ctx.word_interner, &ctx.derivations_interner),
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&y.value.original_single_word(&ctx.word_interner, &ctx.derivations_interner),
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) {
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(Some(w1), Some(w2)) => {
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let term = (
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ctx.word_interner.insert(format!("{w1}{w2}")),
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*x.positions.start()..=*y.positions.end(),
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);
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Some(term)
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}
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_ => None,
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}
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}
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// TODO: return a word derivations instead?
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pub fn ngram3(
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ctx: &mut SearchContext,
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x: &LocatedQueryTerm,
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y: &LocatedQueryTerm,
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z: &LocatedQueryTerm,
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) -> Option<(Interned<String>, RangeInclusive<i8>)> {
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if *x.positions.end() != y.positions.start() - 1
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|| *y.positions.end() != z.positions.start() - 1
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{
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return None;
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}
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match (
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&x.value.original_single_word(&ctx.word_interner, &ctx.derivations_interner),
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&y.value.original_single_word(&ctx.word_interner, &ctx.derivations_interner),
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&z.value.original_single_word(&ctx.word_interner, &ctx.derivations_interner),
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) {
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(Some(w1), Some(w2), Some(w3)) => {
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let term = (
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ctx.word_interner.insert(format!("{w1}{w2}{w3}")),
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*x.positions.start()..=*z.positions.end(),
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);
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Some(term)
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}
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_ => None,
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}
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}
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