use indexmap::IndexSet; use std::collections::BTreeMap; use std::collections::HashMap; use std::collections::HashSet; use unicase::UniCase; type Dict = BTreeMap, IndexSet>; #[test] fn verify() { let asset_path = "assets/words.csv"; let typos_dict = parse_dict(asset_path); let new_dict = process(typos_dict); let mut content = vec![]; let mut wtr = csv::WriterBuilder::new() .flexible(true) .from_writer(&mut content); for (typo, corrections) in new_dict { let mut row = vec![typo.as_str().to_owned()]; row.extend(corrections); wtr.write_record(&row).unwrap(); } wtr.flush().unwrap(); drop(wtr); let content = String::from_utf8(content).unwrap(); snapbox::assert_eq_path(asset_path, content); } fn parse_dict(path: &str) -> Vec<(String, Vec)> { let data = std::fs::read(path).unwrap(); let mut reader = csv::ReaderBuilder::new() .has_headers(false) .flexible(true) .from_reader(&*data); reader .records() .map(Result::unwrap) .map(|record| { let mut iter = record.into_iter(); let typo = iter.next().expect("typo"); ( typo.to_owned(), iter.map(ToOwned::to_owned).collect::>(), ) }) .collect() } fn dict_from_iter>( iter: impl IntoIterator)>, ) -> Dict { let mut dict = Dict::new(); for (typo, corrections) in iter { let typo = UniCase::new(typo.into().to_ascii_lowercase()); // duplicate entries are merged dict.entry(typo) .or_default() .extend(corrections.into_iter().map(|c| { let mut c = c.into(); c.make_ascii_lowercase(); c })); } dict } fn process>( iter: impl IntoIterator)>, ) -> Dict { let dict = dict_from_iter(iter); let rows: Dict = dict .into_iter() .filter(|(t, _)| is_word(t)) .map(|(t, c)| { let new_c: IndexSet<_> = c.into_iter().filter(|c| is_word(c)).collect(); (t, new_c) }) .collect(); let varcon_words = varcon_words(); let allowed_words = allowed_words(); let word_variants = proper_word_variants(); let rows: Vec<_> = rows .into_iter() .filter(|(typo, _)| { let is_disallowed = varcon_words.contains(&unicase::UniCase::new(typo)); if is_disallowed { eprintln!("{:?} is disallowed; in varcon", typo); } !is_disallowed }) .filter(|(typo, _)| { if let Some(reason) = allowed_words.get(typo.as_ref()) { eprintln!("{:?} is disallowed; {}", typo, reason); false } else { true } }) .map(|(typo, corrections)| { let mut new_corrections = IndexSet::new(); for correction in corrections { let correction = word_variants .get(correction.as_str()) .and_then(|words| find_best_match(&typo, correction.as_str(), words)) .unwrap_or(&correction); new_corrections.insert(correction.to_owned()); } (typo, new_corrections) }) .collect(); let mut dict = Dict::new(); for (bad, good) in rows { let current = dict.entry(bad).or_default(); current.extend(good); } let corrections: HashMap<_, _> = dict .iter() .flat_map(|(bad, good)| good.iter().map(|good| (good.to_owned(), bad.to_owned()))) .collect(); dict.into_iter() .filter(|(typo, _)| { if let Some(correction) = corrections.get(typo.as_str()) { eprintln!("{typo} <-> {correction} cycle detected"); false } else { true } }) .collect() } #[test] fn test_preserve_correction_order() { let dict = process([("foo", ["xyz", "abc"])]); let mut corrections = dict.get(&UniCase::new("foo".into())).unwrap().iter(); assert_eq!(corrections.next().unwrap(), "xyz"); assert_eq!(corrections.next().unwrap(), "abc"); } #[test] fn test_merge_duplicates() { assert_eq!( process([("foo", ["bar"]), ("foo", ["baz"])]), dict_from_iter([("foo", ["bar", "baz"])]) ); } #[test] fn test_duplicate_correction_removal() { let dict = process([("foo", ["bar", "bar"])]); assert_eq!(dict, dict_from_iter([("foo", ["bar"])])); } #[test] fn test_cycle_removal() { assert!(process([("foo", ["foobar"]), ("foobar", ["foo"])]).is_empty()); } #[test] fn test_varcon_removal() { assert!(process([("colour", ["color"])]).is_empty()); } #[test] fn test_varcon_best_match() { assert_eq!( process([( "neighourhood", // note the missing 'b' ["neighborhood"], )]), dict_from_iter([( "neighourhood", ["neighbourhood"] // note that 'bor' has become 'bour' to match the typo )]) ); } fn is_word(word: &str) -> bool { word.chars().all(|c| c.is_alphabetic()) } fn varcon_words() -> HashSet> { // Even include improper ones because we should be letting varcon handle that rather than our // dictionary varcon::VARCON .iter() .flat_map(|c| c.entries.iter()) .flat_map(|e| e.variants.iter()) .map(|v| unicase::UniCase::new(v.word)) .collect() } fn proper_word_variants() -> HashMap<&'static str, HashSet<&'static str>> { let mut words: HashMap<&'static str, HashSet<&'static str>> = HashMap::new(); for entry in varcon::VARCON.iter().flat_map(|c| c.entries.iter()) { let variants: HashSet<_> = entry .variants .iter() .filter(|v| v.types.iter().any(|t| t.tag != Some(varcon::Tag::Improper))) .map(|v| v.word) .collect(); for variant in variants.iter() { let set = words.entry(variant).or_insert_with(HashSet::new); set.extend(variants.iter().filter(|v| *v != variant)); } } words } fn find_best_match<'c>( typo: &'c str, correction: &'c str, word_variants: &HashSet<&'static str>, ) -> Option<&'c str> { assert!(!word_variants.contains(correction)); #[allow(clippy::single_match)] match (typo, correction) { // Picking the worst option due to a letter swap being an edit distance of two ("alinging", "aligning") => { return None; } _ => {} } let current = edit_distance::edit_distance(typo, correction); let mut matches: Vec<_> = word_variants .iter() .map(|r| (edit_distance::edit_distance(typo, r), *r)) .filter(|(d, _)| *d < current) .collect(); matches.sort_unstable(); matches.into_iter().next().map(|(_, r)| r) } fn allowed_words() -> std::collections::HashMap { let allowed_path = "assets/english.csv"; let english_data = std::fs::read(allowed_path).unwrap(); let mut allowed_english = csv::ReaderBuilder::new() .has_headers(false) .flexible(true) .from_reader(english_data.as_slice()); let allowed_english = allowed_english.records().map(Result::unwrap).map(|r| { let mut i = r.iter(); let mut typo = i.next().expect("typo").to_owned(); typo.make_ascii_lowercase(); (typo, String::from("english word")) }); let allowed_path = "assets/allowed.csv"; let local_data = std::fs::read(allowed_path).unwrap(); let mut allowed_local = csv::ReaderBuilder::new() .has_headers(false) .flexible(true) .from_reader(local_data.as_slice()); let allowed_local = allowed_local.records().map(Result::unwrap).map(|r| { let mut i = r.iter(); let mut typo = i.next().expect("typo").to_owned(); typo.make_ascii_lowercase(); let reason = i.next().expect("reason").to_owned(); (typo, reason) }); allowed_english.chain(allowed_local).collect() }