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use regex_automata::DFA; use ext_slice::ByteSlice; use unicode::fsm::simple_word_fwd::SIMPLE_WORD_FWD; use unicode::fsm::word_break_fwd::WORD_BREAK_FWD; use utf8; /// An iterator over words in a byte string. /// /// This iterator is typically constructed by /// [`ByteSlice::words`](trait.ByteSlice.html#method.words). /// /// This is similar to the [`WordsWithBreaks`](struct.WordsWithBreaks.html) /// iterator, except it only returns elements that contain a "word" character. /// A word character is defined by UTS #18 (Annex C) to be the combination /// of the `Alphabetic` and `Join_Control` properties, along with the /// `Decimal_Number`, `Mark` and `Connector_Punctuation` general categories. /// /// Since words are made up of one or more codepoints, this iterator yields /// `&str` elements. When invalid UTF-8 is encountered, replacement codepoints /// are [substituted](index.html#handling-of-invalid-utf-8). /// /// This iterator yields words in accordance with the default word boundary /// rules specified in /// [UAX #29](https://www.unicode.org/reports/tr29/tr29-33.html#Word_Boundaries). /// In particular, this may not be suitable for Japanese and Chinese scripts /// that do not use spaces between words. #[derive(Clone, Debug)] pub struct Words<'a>(WordsWithBreaks<'a>); impl<'a> Words<'a> { pub(crate) fn new(bs: &'a [u8]) -> Words<'a> { Words(WordsWithBreaks::new(bs)) } /// View the underlying data as a subslice of the original data. /// /// The slice returned has the same lifetime as the original slice, and so /// the iterator can continue to be used while this exists. /// /// # Examples /// /// ``` /// use bstr::ByteSlice; /// /// let mut it = b"foo bar baz".words(); /// /// assert_eq!(b"foo bar baz", it.as_bytes()); /// it.next(); /// it.next(); /// assert_eq!(b" baz", it.as_bytes()); /// it.next(); /// assert_eq!(b"", it.as_bytes()); /// ``` #[inline] pub fn as_bytes(&self) -> &'a [u8] { self.0.as_bytes() } } impl<'a> Iterator for Words<'a> { type Item = &'a str; #[inline] fn next(&mut self) -> Option<&'a str> { while let Some(word) = self.0.next() { if SIMPLE_WORD_FWD.is_match(word.as_bytes()) { return Some(word); } } None } } /// An iterator over words in a byte string and their byte index positions. /// /// This iterator is typically constructed by /// [`ByteSlice::word_indices`](trait.ByteSlice.html#method.word_indices). /// /// This is similar to the /// [`WordsWithBreakIndices`](struct.WordsWithBreakIndices.html) iterator, /// except it only returns elements that contain a "word" character. A /// word character is defined by UTS #18 (Annex C) to be the combination /// of the `Alphabetic` and `Join_Control` properties, along with the /// `Decimal_Number`, `Mark` and `Connector_Punctuation` general categories. /// /// Since words are made up of one or more codepoints, this iterator /// yields `&str` elements (along with their start and end byte offsets). /// When invalid UTF-8 is encountered, replacement codepoints are /// [substituted](index.html#handling-of-invalid-utf-8). Because of this, the /// indices yielded by this iterator may not correspond to the length of the /// word yielded with those indices. For example, when this iterator encounters /// `\xFF` in the byte string, then it will yield a pair of indices ranging /// over a single byte, but will provide an `&str` equivalent to `"\u{FFFD}"`, /// which is three bytes in length. However, when given only valid UTF-8, then /// all indices are in exact correspondence with their paired word. /// /// This iterator yields words in accordance with the default word boundary /// rules specified in /// [UAX #29](https://www.unicode.org/reports/tr29/tr29-33.html#Word_Boundaries). /// In particular, this may not be suitable for Japanese and Chinese scripts /// that do not use spaces between words. #[derive(Clone, Debug)] pub struct WordIndices<'a>(WordsWithBreakIndices<'a>); impl<'a> WordIndices<'a> { pub(crate) fn new(bs: &'a [u8]) -> WordIndices<'a> { WordIndices(WordsWithBreakIndices::new(bs)) } /// View the underlying data as a subslice of the original data. /// /// The slice returned has the same lifetime as the original slice, and so /// the iterator can continue to be used while this exists. /// /// # Examples /// /// ``` /// use bstr::ByteSlice; /// /// let mut it = b"foo bar baz".word_indices(); /// /// assert_eq!(b"foo bar baz", it.as_bytes()); /// it.next(); /// it.next(); /// assert_eq!(b" baz", it.as_bytes()); /// it.next(); /// it.next(); /// assert_eq!(b"", it.as_bytes()); /// ``` #[inline] pub fn as_bytes(&self) -> &'a [u8] { self.0.as_bytes() } } impl<'a> Iterator for WordIndices<'a> { type Item = (usize, usize, &'a str); #[inline] fn next(&mut self) -> Option<(usize, usize, &'a str)> { while let Some((start, end, word)) = self.0.next() { if SIMPLE_WORD_FWD.is_match(word.as_bytes()) { return Some((start, end, word)); } } None } } /// An iterator over all word breaks in a byte string. /// /// This iterator is typically constructed by /// [`ByteSlice::words_with_breaks`](trait.ByteSlice.html#method.words_with_breaks). /// /// This iterator yields not only all words, but the content that comes between /// words. In particular, if all elements yielded by this iterator are /// concatenated, then the result is the original string (subject to Unicode /// replacement codepoint substitutions). /// /// Since words are made up of one or more codepoints, this iterator yields /// `&str` elements. When invalid UTF-8 is encountered, replacement codepoints /// are [substituted](index.html#handling-of-invalid-utf-8). /// /// This iterator yields words in accordance with the default word boundary /// rules specified in /// [UAX #29](https://www.unicode.org/reports/tr29/tr29-33.html#Word_Boundaries). /// In particular, this may not be suitable for Japanese and Chinese scripts /// that do not use spaces between words. #[derive(Clone, Debug)] pub struct WordsWithBreaks<'a> { bs: &'a [u8], } impl<'a> WordsWithBreaks<'a> { pub(crate) fn new(bs: &'a [u8]) -> WordsWithBreaks<'a> { WordsWithBreaks { bs } } /// View the underlying data as a subslice of the original data. /// /// The slice returned has the same lifetime as the original slice, and so /// the iterator can continue to be used while this exists. /// /// # Examples /// /// ``` /// use bstr::ByteSlice; /// /// let mut it = b"foo bar baz".words_with_breaks(); /// /// assert_eq!(b"foo bar baz", it.as_bytes()); /// it.next(); /// assert_eq!(b" bar baz", it.as_bytes()); /// it.next(); /// it.next(); /// assert_eq!(b" baz", it.as_bytes()); /// it.next(); /// it.next(); /// assert_eq!(b"", it.as_bytes()); /// ``` #[inline] pub fn as_bytes(&self) -> &'a [u8] { self.bs } } impl<'a> Iterator for WordsWithBreaks<'a> { type Item = &'a str; #[inline] fn next(&mut self) -> Option<&'a str> { let (word, size) = decode_word(self.bs); if size == 0 { return None; } self.bs = &self.bs[size..]; Some(word) } } /// An iterator over all word breaks in a byte string, along with their byte /// index positions. /// /// This iterator is typically constructed by /// [`ByteSlice::words_with_break_indices`](trait.ByteSlice.html#method.words_with_break_indices). /// /// This iterator yields not only all words, but the content that comes between /// words. In particular, if all elements yielded by this iterator are /// concatenated, then the result is the original string (subject to Unicode /// replacement codepoint substitutions). /// /// Since words are made up of one or more codepoints, this iterator /// yields `&str` elements (along with their start and end byte offsets). /// When invalid UTF-8 is encountered, replacement codepoints are /// [substituted](index.html#handling-of-invalid-utf-8). Because of this, the /// indices yielded by this iterator may not correspond to the length of the /// word yielded with those indices. For example, when this iterator encounters /// `\xFF` in the byte string, then it will yield a pair of indices ranging /// over a single byte, but will provide an `&str` equivalent to `"\u{FFFD}"`, /// which is three bytes in length. However, when given only valid UTF-8, then /// all indices are in exact correspondence with their paired word. /// /// This iterator yields words in accordance with the default word boundary /// rules specified in /// [UAX #29](https://www.unicode.org/reports/tr29/tr29-33.html#Word_Boundaries). /// In particular, this may not be suitable for Japanese and Chinese scripts /// that do not use spaces between words. #[derive(Clone, Debug)] pub struct WordsWithBreakIndices<'a> { bs: &'a [u8], forward_index: usize, } impl<'a> WordsWithBreakIndices<'a> { pub(crate) fn new(bs: &'a [u8]) -> WordsWithBreakIndices<'a> { WordsWithBreakIndices { bs: bs, forward_index: 0 } } /// View the underlying data as a subslice of the original data. /// /// The slice returned has the same lifetime as the original slice, and so /// the iterator can continue to be used while this exists. /// /// # Examples /// /// ``` /// use bstr::ByteSlice; /// /// let mut it = b"foo bar baz".words_with_break_indices(); /// /// assert_eq!(b"foo bar baz", it.as_bytes()); /// it.next(); /// assert_eq!(b" bar baz", it.as_bytes()); /// it.next(); /// it.next(); /// assert_eq!(b" baz", it.as_bytes()); /// it.next(); /// it.next(); /// assert_eq!(b"", it.as_bytes()); /// ``` #[inline] pub fn as_bytes(&self) -> &'a [u8] { self.bs } } impl<'a> Iterator for WordsWithBreakIndices<'a> { type Item = (usize, usize, &'a str); #[inline] fn next(&mut self) -> Option<(usize, usize, &'a str)> { let index = self.forward_index; let (word, size) = decode_word(self.bs); if size == 0 { return None; } self.bs = &self.bs[size..]; self.forward_index += size; Some((index, index + size, word)) } } fn decode_word(bs: &[u8]) -> (&str, usize) { if bs.is_empty() { ("", 0) } else if let Some(end) = WORD_BREAK_FWD.find(bs) { // Safe because a match can only occur for valid UTF-8. let word = unsafe { bs[..end].to_str_unchecked() }; (word, word.len()) } else { const INVALID: &'static str = "\u{FFFD}"; // No match on non-empty bytes implies we found invalid UTF-8. let (_, size) = utf8::decode_lossy(bs); (INVALID, size) } } #[cfg(test)] mod tests { use ucd_parse::WordBreakTest; use ext_slice::ByteSlice; #[test] fn forward_ucd() { for (i, test) in ucdtests().into_iter().enumerate() { let given = test.words.concat(); let got = words(given.as_bytes()); assert_eq!( test.words, got, "\n\nword forward break test {} failed:\n\ given: {:?}\n\ expected: {:?}\n\ got: {:?}\n", i, given, strs_to_bstrs(&test.words), strs_to_bstrs(&got), ); } } // Some additional tests that don't seem to be covered by the UCD tests. // // It's pretty amazing that the UCD tests miss these cases. I only found // them by running this crate's segmenter and ICU's segmenter on the same // text and comparing the output. #[test] fn forward_additional() { assert_eq!(vec!["a", ".", " ", "Y"], words(b"a. Y")); assert_eq!(vec!["r", ".", " ", "Yo"], words(b"r. Yo")); assert_eq!( vec!["whatsoever", ".", " ", "You", " ", "may"], words(b"whatsoever. You may") ); assert_eq!( vec!["21stcentury'syesterday"], words(b"21stcentury'syesterday") ); assert_eq!(vec!["Bonta_", "'", "s"], words(b"Bonta_'s")); assert_eq!(vec!["_vhat's"], words(b"_vhat's")); assert_eq!(vec!["__on'anima"], words(b"__on'anima")); assert_eq!(vec!["123_", "'", "4"], words(b"123_'4")); assert_eq!(vec!["_123'4"], words(b"_123'4")); assert_eq!(vec!["__12'345"], words(b"__12'345")); assert_eq!( vec!["tomorrowat4", ":", "00", ","], words(b"tomorrowat4:00,") ); assert_eq!(vec!["RS1", "'", "s"], words(b"RS1's")); assert_eq!(vec!["X38"], words(b"X38")); assert_eq!(vec!["4abc", ":", "00", ","], words(b"4abc:00,")); assert_eq!(vec!["12S", "'", "1"], words(b"12S'1")); assert_eq!(vec!["1XY"], words(b"1XY")); assert_eq!(vec!["\u{FEFF}", "Ты"], words("\u{FEFF}Ты".as_bytes())); } fn words(bytes: &[u8]) -> Vec<&str> { bytes.words_with_breaks().collect() } fn strs_to_bstrs<S: AsRef<str>>(strs: &[S]) -> Vec<&[u8]> { strs.iter().map(|s| s.as_ref().as_bytes()).collect() } /// Return all of the UCD for word breaks. fn ucdtests() -> Vec<WordBreakTest> { const TESTDATA: &'static str = include_str!("data/WordBreakTest.txt"); let mut tests = vec![]; for mut line in TESTDATA.lines() { line = line.trim(); if line.starts_with("#") || line.contains("surrogate") { continue; } tests.push(line.parse().unwrap()); } tests } }