use std::borrow::Cow; use std::collections::HashMap; use std::fmt; use std::iter::FusedIterator; use std::ops::{Index, Range}; use std::str::FromStr; use std::sync::Arc; use find_byte::find_byte; use syntax; use error::Error; use exec::{Exec, ExecNoSyncStr}; use expand::expand_str; use re_builder::unicode::RegexBuilder; use re_trait::{self, RegularExpression, SubCapturesPosIter}; /// Escapes all regular expression meta characters in `text`. /// /// The string returned may be safely used as a literal in a regular /// expression. pub fn escape(text: &str) -> String { syntax::escape(text) } /// Match represents a single match of a regex in a haystack. /// /// The lifetime parameter `'t` refers to the lifetime of the matched text. #[derive(Copy, Clone, Debug, Eq, PartialEq)] pub struct Match<'t> { text: &'t str, start: usize, end: usize, } impl<'t> Match<'t> { /// Returns the starting byte offset of the match in the haystack. #[inline] pub fn start(&self) -> usize { self.start } /// Returns the ending byte offset of the match in the haystack. #[inline] pub fn end(&self) -> usize { self.end } /// Returns the range over the starting and ending byte offsets of the /// match in the haystack. #[inline] pub fn range(&self) -> Range { self.start..self.end } /// Returns the matched text. #[inline] pub fn as_str(&self) -> &'t str { &self.text[self.range()] } /// Creates a new match from the given haystack and byte offsets. #[inline] fn new(haystack: &'t str, start: usize, end: usize) -> Match<'t> { Match { text: haystack, start: start, end: end } } } impl<'t> From> for &'t str { fn from(m: Match<'t>) -> &'t str { m.as_str() } } impl<'t> From> for Range { fn from(m: Match<'t>) -> Range { m.range() } } /// A compiled regular expression for matching Unicode strings. /// /// It is represented as either a sequence of bytecode instructions (dynamic) /// or as a specialized Rust function (native). It can be used to search, split /// or replace text. All searching is done with an implicit `.*?` at the /// beginning and end of an expression. To force an expression to match the /// whole string (or a prefix or a suffix), you must use an anchor like `^` or /// `$` (or `\A` and `\z`). /// /// While this crate will handle Unicode strings (whether in the regular /// expression or in the search text), all positions returned are **byte /// indices**. Every byte index is guaranteed to be at a Unicode code point /// boundary. /// /// The lifetimes `'r` and `'t` in this crate correspond to the lifetime of a /// compiled regular expression and text to search, respectively. /// /// The only methods that allocate new strings are the string replacement /// methods. All other methods (searching and splitting) return borrowed /// pointers into the string given. /// /// # Examples /// /// Find the location of a US phone number: /// /// ```rust /// # use regex::Regex; /// let re = Regex::new("[0-9]{3}-[0-9]{3}-[0-9]{4}").unwrap(); /// let mat = re.find("phone: 111-222-3333").unwrap(); /// assert_eq!((mat.start(), mat.end()), (7, 19)); /// ``` /// /// # Using the `std::str::pattern` methods with `Regex` /// /// > **Note**: This section requires that this crate is compiled with the /// > `pattern` Cargo feature enabled, which **requires nightly Rust**. /// /// Since `Regex` implements `Pattern`, you can use regexes with methods /// defined on `&str`. For example, `is_match`, `find`, `find_iter` /// and `split` can be replaced with `str::contains`, `str::find`, /// `str::match_indices` and `str::split`. /// /// Here are some examples: /// /// ```rust,ignore /// # use regex::Regex; /// let re = Regex::new(r"\d+").unwrap(); /// let haystack = "a111b222c"; /// /// assert!(haystack.contains(&re)); /// assert_eq!(haystack.find(&re), Some(1)); /// assert_eq!(haystack.match_indices(&re).collect::>(), /// vec![(1, 4), (5, 8)]); /// assert_eq!(haystack.split(&re).collect::>(), vec!["a", "b", "c"]); /// ``` #[derive(Clone)] pub struct Regex(Exec); impl fmt::Display for Regex { /// Shows the original regular expression. fn fmt(&self, f: &mut fmt::Formatter) -> fmt::Result { write!(f, "{}", self.as_str()) } } impl fmt::Debug for Regex { /// Shows the original regular expression. fn fmt(&self, f: &mut fmt::Formatter) -> fmt::Result { fmt::Display::fmt(self, f) } } #[doc(hidden)] impl From for Regex { fn from(exec: Exec) -> Regex { Regex(exec) } } impl FromStr for Regex { type Err = Error; /// Attempts to parse a string into a regular expression fn from_str(s: &str) -> Result { Regex::new(s) } } /// Core regular expression methods. impl Regex { /// Compiles a regular expression. Once compiled, it can be used repeatedly /// to search, split or replace text in a string. /// /// If an invalid expression is given, then an error is returned. pub fn new(re: &str) -> Result { RegexBuilder::new(re).build() } /// Returns true if and only if there is a match for the regex in the /// string given. /// /// It is recommended to use this method if all you need to do is test /// a match, since the underlying matching engine may be able to do less /// work. /// /// # Example /// /// Test if some text contains at least one word with exactly 13 /// Unicode word characters: /// /// ```rust /// # extern crate regex; use regex::Regex; /// # fn main() { /// let text = "I categorically deny having triskaidekaphobia."; /// assert!(Regex::new(r"\b\w{13}\b").unwrap().is_match(text)); /// # } /// ``` pub fn is_match(&self, text: &str) -> bool { self.is_match_at(text, 0) } /// Returns the start and end byte range of the leftmost-first match in /// `text`. If no match exists, then `None` is returned. /// /// Note that this should only be used if you want to discover the position /// of the match. Testing the existence of a match is faster if you use /// `is_match`. /// /// # Example /// /// Find the start and end location of the first word with exactly 13 /// Unicode word characters: /// /// ```rust /// # extern crate regex; use regex::Regex; /// # fn main() { /// let text = "I categorically deny having triskaidekaphobia."; /// let mat = Regex::new(r"\b\w{13}\b").unwrap().find(text).unwrap(); /// assert_eq!(mat.start(), 2); /// assert_eq!(mat.end(), 15); /// # } /// ``` pub fn find<'t>(&self, text: &'t str) -> Option> { self.find_at(text, 0) } /// Returns an iterator for each successive non-overlapping match in /// `text`, returning the start and end byte indices with respect to /// `text`. /// /// # Example /// /// Find the start and end location of every word with exactly 13 Unicode /// word characters: /// /// ```rust /// # extern crate regex; use regex::Regex; /// # fn main() { /// let text = "Retroactively relinquishing remunerations is reprehensible."; /// for mat in Regex::new(r"\b\w{13}\b").unwrap().find_iter(text) { /// println!("{:?}", mat); /// } /// # } /// ``` pub fn find_iter<'r, 't>(&'r self, text: &'t str) -> Matches<'r, 't> { Matches(self.0.searcher_str().find_iter(text)) } /// Returns the capture groups corresponding to the leftmost-first /// match in `text`. Capture group `0` always corresponds to the entire /// match. If no match is found, then `None` is returned. /// /// You should only use `captures` if you need access to the location of /// capturing group matches. Otherwise, `find` is faster for discovering /// the location of the overall match. /// /// # Examples /// /// Say you have some text with movie names and their release years, /// like "'Citizen Kane' (1941)". It'd be nice if we could search for text /// looking like that, while also extracting the movie name and its release /// year separately. /// /// ```rust /// # extern crate regex; use regex::Regex; /// # fn main() { /// let re = Regex::new(r"'([^']+)'\s+\((\d{4})\)").unwrap(); /// let text = "Not my favorite movie: 'Citizen Kane' (1941)."; /// let caps = re.captures(text).unwrap(); /// assert_eq!(caps.get(1).unwrap().as_str(), "Citizen Kane"); /// assert_eq!(caps.get(2).unwrap().as_str(), "1941"); /// assert_eq!(caps.get(0).unwrap().as_str(), "'Citizen Kane' (1941)"); /// // You can also access the groups by index using the Index notation. /// // Note that this will panic on an invalid index. /// assert_eq!(&caps[1], "Citizen Kane"); /// assert_eq!(&caps[2], "1941"); /// assert_eq!(&caps[0], "'Citizen Kane' (1941)"); /// # } /// ``` /// /// Note that the full match is at capture group `0`. Each subsequent /// capture group is indexed by the order of its opening `(`. /// /// We can make this example a bit clearer by using *named* capture groups: /// /// ```rust /// # extern crate regex; use regex::Regex; /// # fn main() { /// let re = Regex::new(r"'(?P[^']+)'\s+\((?P<year>\d{4})\)") /// .unwrap(); /// let text = "Not my favorite movie: 'Citizen Kane' (1941)."; /// let caps = re.captures(text).unwrap(); /// assert_eq!(caps.name("title").unwrap().as_str(), "Citizen Kane"); /// assert_eq!(caps.name("year").unwrap().as_str(), "1941"); /// assert_eq!(caps.get(0).unwrap().as_str(), "'Citizen Kane' (1941)"); /// // You can also access the groups by name using the Index notation. /// // Note that this will panic on an invalid group name. /// assert_eq!(&caps["title"], "Citizen Kane"); /// assert_eq!(&caps["year"], "1941"); /// assert_eq!(&caps[0], "'Citizen Kane' (1941)"); /// /// # } /// ``` /// /// Here we name the capture groups, which we can access with the `name` /// method or the `Index` notation with a `&str`. Note that the named /// capture groups are still accessible with `get` or the `Index` notation /// with a `usize`. /// /// The `0`th capture group is always unnamed, so it must always be /// accessed with `get(0)` or `[0]`. pub fn captures<'t>(&self, text: &'t str) -> Option<Captures<'t>> { let mut locs = self.capture_locations(); self.captures_read_at(&mut locs, text, 0).map(move |_| Captures { text: text, locs: locs.0, named_groups: self.0.capture_name_idx().clone(), }) } /// Returns an iterator over all the non-overlapping capture groups matched /// in `text`. This is operationally the same as `find_iter`, except it /// yields information about capturing group matches. /// /// # Example /// /// We can use this to find all movie titles and their release years in /// some text, where the movie is formatted like "'Title' (xxxx)": /// /// ```rust /// # extern crate regex; use regex::Regex; /// # fn main() { /// let re = Regex::new(r"'(?P<title>[^']+)'\s+\((?P<year>\d{4})\)") /// .unwrap(); /// let text = "'Citizen Kane' (1941), 'The Wizard of Oz' (1939), 'M' (1931)."; /// for caps in re.captures_iter(text) { /// println!("Movie: {:?}, Released: {:?}", /// &caps["title"], &caps["year"]); /// } /// // Output: /// // Movie: Citizen Kane, Released: 1941 /// // Movie: The Wizard of Oz, Released: 1939 /// // Movie: M, Released: 1931 /// # } /// ``` pub fn captures_iter<'r, 't>( &'r self, text: &'t str, ) -> CaptureMatches<'r, 't> { CaptureMatches(self.0.searcher_str().captures_iter(text)) } /// Returns an iterator of substrings of `text` delimited by a match of the /// regular expression. Namely, each element of the iterator corresponds to /// text that *isn't* matched by the regular expression. /// /// This method will *not* copy the text given. /// /// # Example /// /// To split a string delimited by arbitrary amounts of spaces or tabs: /// /// ```rust /// # extern crate regex; use regex::Regex; /// # fn main() { /// let re = Regex::new(r"[ \t]+").unwrap(); /// let fields: Vec<&str> = re.split("a b \t c\td e").collect(); /// assert_eq!(fields, vec!["a", "b", "c", "d", "e"]); /// # } /// ``` pub fn split<'r, 't>(&'r self, text: &'t str) -> Split<'r, 't> { Split { finder: self.find_iter(text), last: 0 } } /// Returns an iterator of at most `limit` substrings of `text` delimited /// by a match of the regular expression. (A `limit` of `0` will return no /// substrings.) Namely, each element of the iterator corresponds to text /// that *isn't* matched by the regular expression. The remainder of the /// string that is not split will be the last element in the iterator. /// /// This method will *not* copy the text given. /// /// # Example /// /// Get the first two words in some text: /// /// ```rust /// # extern crate regex; use regex::Regex; /// # fn main() { /// let re = Regex::new(r"\W+").unwrap(); /// let fields: Vec<&str> = re.splitn("Hey! How are you?", 3).collect(); /// assert_eq!(fields, vec!("Hey", "How", "are you?")); /// # } /// ``` pub fn splitn<'r, 't>( &'r self, text: &'t str, limit: usize, ) -> SplitN<'r, 't> { SplitN { splits: self.split(text), n: limit } } /// Replaces the leftmost-first match with the replacement provided. /// The replacement can be a regular string (where `$N` and `$name` are /// expanded to match capture groups) or a function that takes the matches' /// `Captures` and returns the replaced string. /// /// If no match is found, then a copy of the string is returned unchanged. /// /// # Replacement string syntax /// /// All instances of `$name` in the replacement text is replaced with the /// corresponding capture group `name`. /// /// `name` may be an integer corresponding to the index of the /// capture group (counted by order of opening parenthesis where `0` is the /// entire match) or it can be a name (consisting of letters, digits or /// underscores) corresponding to a named capture group. /// /// If `name` isn't a valid capture group (whether the name doesn't exist /// or isn't a valid index), then it is replaced with the empty string. /// /// The longest possible name is used. e.g., `$1a` looks up the capture /// group named `1a` and not the capture group at index `1`. To exert more /// precise control over the name, use braces, e.g., `${1}a`. /// /// To write a literal `$` use `$$`. /// /// # Examples /// /// Note that this function is polymorphic with respect to the replacement. /// In typical usage, this can just be a normal string: /// /// ```rust /// # extern crate regex; use regex::Regex; /// # fn main() { /// let re = Regex::new("[^01]+").unwrap(); /// assert_eq!(re.replace("1078910", ""), "1010"); /// # } /// ``` /// /// But anything satisfying the `Replacer` trait will work. For example, /// a closure of type `|&Captures| -> String` provides direct access to the /// captures corresponding to a match. This allows one to access /// capturing group matches easily: /// /// ```rust /// # extern crate regex; use regex::Regex; /// # use regex::Captures; fn main() { /// let re = Regex::new(r"([^,\s]+),\s+(\S+)").unwrap(); /// let result = re.replace("Springsteen, Bruce", |caps: &Captures| { /// format!("{} {}", &caps[2], &caps[1]) /// }); /// assert_eq!(result, "Bruce Springsteen"); /// # } /// ``` /// /// But this is a bit cumbersome to use all the time. Instead, a simple /// syntax is supported that expands `$name` into the corresponding capture /// group. Here's the last example, but using this expansion technique /// with named capture groups: /// /// ```rust /// # extern crate regex; use regex::Regex; /// # fn main() { /// let re = Regex::new(r"(?P<last>[^,\s]+),\s+(?P<first>\S+)").unwrap(); /// let result = re.replace("Springsteen, Bruce", "$first $last"); /// assert_eq!(result, "Bruce Springsteen"); /// # } /// ``` /// /// Note that using `$2` instead of `$first` or `$1` instead of `$last` /// would produce the same result. To write a literal `$` use `$$`. /// /// Sometimes the replacement string requires use of curly braces to /// delineate a capture group replacement and surrounding literal text. /// For example, if we wanted to join two words together with an /// underscore: /// /// ```rust /// # extern crate regex; use regex::Regex; /// # fn main() { /// let re = Regex::new(r"(?P<first>\w+)\s+(?P<second>\w+)").unwrap(); /// let result = re.replace("deep fried", "${first}_$second"); /// assert_eq!(result, "deep_fried"); /// # } /// ``` /// /// Without the curly braces, the capture group name `first_` would be /// used, and since it doesn't exist, it would be replaced with the empty /// string. /// /// Finally, sometimes you just want to replace a literal string with no /// regard for capturing group expansion. This can be done by wrapping a /// byte string with `NoExpand`: /// /// ```rust /// # extern crate regex; use regex::Regex; /// # fn main() { /// use regex::NoExpand; /// /// let re = Regex::new(r"(?P<last>[^,\s]+),\s+(\S+)").unwrap(); /// let result = re.replace("Springsteen, Bruce", NoExpand("$2 $last")); /// assert_eq!(result, "$2 $last"); /// # } /// ``` pub fn replace<'t, R: Replacer>( &self, text: &'t str, rep: R, ) -> Cow<'t, str> { self.replacen(text, 1, rep) } /// Replaces all non-overlapping matches in `text` with the replacement /// provided. This is the same as calling `replacen` with `limit` set to /// `0`. /// /// See the documentation for `replace` for details on how to access /// capturing group matches in the replacement string. pub fn replace_all<'t, R: Replacer>( &self, text: &'t str, rep: R, ) -> Cow<'t, str> { self.replacen(text, 0, rep) } /// Replaces at most `limit` non-overlapping matches in `text` with the /// replacement provided. If `limit` is 0, then all non-overlapping matches /// are replaced. /// /// See the documentation for `replace` for details on how to access /// capturing group matches in the replacement string. pub fn replacen<'t, R: Replacer>( &self, text: &'t str, limit: usize, mut rep: R, ) -> Cow<'t, str> { // If we know that the replacement doesn't have any capture expansions, // then we can fast path. The fast path can make a tremendous // difference: // // 1) We use `find_iter` instead of `captures_iter`. Not asking for // captures generally makes the regex engines faster. // 2) We don't need to look up all of the capture groups and do // replacements inside the replacement string. We just push it // at each match and be done with it. if let Some(rep) = rep.no_expansion() { let mut it = self.find_iter(text).enumerate().peekable(); if it.peek().is_none() { return Cow::Borrowed(text); } let mut new = String::with_capacity(text.len()); let mut last_match = 0; for (i, m) in it { if limit > 0 && i >= limit { break; } new.push_str(&text[last_match..m.start()]); new.push_str(&rep); last_match = m.end(); } new.push_str(&text[last_match..]); return Cow::Owned(new); } // The slower path, which we use if the replacement needs access to // capture groups. let mut it = self.captures_iter(text).enumerate().peekable(); if it.peek().is_none() { return Cow::Borrowed(text); } let mut new = String::with_capacity(text.len()); let mut last_match = 0; for (i, cap) in it { if limit > 0 && i >= limit { break; } // unwrap on 0 is OK because captures only reports matches let m = cap.get(0).unwrap(); new.push_str(&text[last_match..m.start()]); rep.replace_append(&cap, &mut new); last_match = m.end(); } new.push_str(&text[last_match..]); Cow::Owned(new) } } /// Advanced or "lower level" search methods. impl Regex { /// Returns the end location of a match in the text given. /// /// This method may have the same performance characteristics as /// `is_match`, except it provides an end location for a match. In /// particular, the location returned *may be shorter* than the proper end /// of the leftmost-first match. /// /// # Example /// /// Typically, `a+` would match the entire first sequence of `a` in some /// text, but `shortest_match` can give up as soon as it sees the first /// `a`. /// /// ```rust /// # extern crate regex; use regex::Regex; /// # fn main() { /// let text = "aaaaa"; /// let pos = Regex::new(r"a+").unwrap().shortest_match(text); /// assert_eq!(pos, Some(1)); /// # } /// ``` pub fn shortest_match(&self, text: &str) -> Option<usize> { self.shortest_match_at(text, 0) } /// Returns the same as shortest_match, but starts the search at the given /// offset. /// /// The significance of the starting point is that it takes the surrounding /// context into consideration. For example, the `\A` anchor can only /// match when `start == 0`. pub fn shortest_match_at( &self, text: &str, start: usize, ) -> Option<usize> { self.0.searcher_str().shortest_match_at(text, start) } /// Returns the same as is_match, but starts the search at the given /// offset. /// /// The significance of the starting point is that it takes the surrounding /// context into consideration. For example, the `\A` anchor can only /// match when `start == 0`. pub fn is_match_at(&self, text: &str, start: usize) -> bool { self.shortest_match_at(text, start).is_some() } /// Returns the same as find, but starts the search at the given /// offset. /// /// The significance of the starting point is that it takes the surrounding /// context into consideration. For example, the `\A` anchor can only /// match when `start == 0`. pub fn find_at<'t>( &self, text: &'t str, start: usize, ) -> Option<Match<'t>> { self.0 .searcher_str() .find_at(text, start) .map(|(s, e)| Match::new(text, s, e)) } /// This is like `captures`, but uses /// [`CaptureLocations`](struct.CaptureLocations.html) /// instead of /// [`Captures`](struct.Captures.html) in order to amortize allocations. /// /// To create a `CaptureLocations` value, use the /// `Regex::capture_locations` method. /// /// This returns the overall match if this was successful, which is always /// equivalence to the `0`th capture group. pub fn captures_read<'t>( &self, locs: &mut CaptureLocations, text: &'t str, ) -> Option<Match<'t>> { self.captures_read_at(locs, text, 0) } /// Returns the same as captures, but starts the search at the given /// offset and populates the capture locations given. /// /// The significance of the starting point is that it takes the surrounding /// context into consideration. For example, the `\A` anchor can only /// match when `start == 0`. pub fn captures_read_at<'t>( &self, locs: &mut CaptureLocations, text: &'t str, start: usize, ) -> Option<Match<'t>> { self.0 .searcher_str() .captures_read_at(&mut locs.0, text, start) .map(|(s, e)| Match::new(text, s, e)) } /// An undocumented alias for `captures_read_at`. /// /// The `regex-capi` crate previously used this routine, so to avoid /// breaking that crate, we continue to provide the name as an undocumented /// alias. #[doc(hidden)] pub fn read_captures_at<'t>( &self, locs: &mut CaptureLocations, text: &'t str, start: usize, ) -> Option<Match<'t>> { self.captures_read_at(locs, text, start) } } /// Auxiliary methods. impl Regex { /// Returns the original string of this regex. pub fn as_str(&self) -> &str { &self.0.regex_strings()[0] } /// Returns an iterator over the capture names. pub fn capture_names(&self) -> CaptureNames { CaptureNames(self.0.capture_names().iter()) } /// Returns the number of captures. pub fn captures_len(&self) -> usize { self.0.capture_names().len() } /// Returns an empty set of capture locations that can be reused in /// multiple calls to `captures_read` or `captures_read_at`. pub fn capture_locations(&self) -> CaptureLocations { CaptureLocations(self.0.searcher_str().locations()) } /// An alias for `capture_locations` to preserve backward compatibility. /// /// The `regex-capi` crate uses this method, so to avoid breaking that /// crate, we continue to export it as an undocumented API. #[doc(hidden)] pub fn locations(&self) -> CaptureLocations { CaptureLocations(self.0.searcher_str().locations()) } } /// An iterator over the names of all possible captures. /// /// `None` indicates an unnamed capture; the first element (capture 0, the /// whole matched region) is always unnamed. /// /// `'r` is the lifetime of the compiled regular expression. #[derive(Clone, Debug)] pub struct CaptureNames<'r>(::std::slice::Iter<'r, Option<String>>); impl<'r> Iterator for CaptureNames<'r> { type Item = Option<&'r str>; fn next(&mut self) -> Option<Option<&'r str>> { self.0 .next() .as_ref() .map(|slot| slot.as_ref().map(|name| name.as_ref())) } fn size_hint(&self) -> (usize, Option<usize>) { self.0.size_hint() } fn count(self) -> usize { self.0.count() } } impl<'r> ExactSizeIterator for CaptureNames<'r> {} impl<'r> FusedIterator for CaptureNames<'r> {} /// Yields all substrings delimited by a regular expression match. /// /// `'r` is the lifetime of the compiled regular expression and `'t` is the /// lifetime of the string being split. #[derive(Debug)] pub struct Split<'r, 't> { finder: Matches<'r, 't>, last: usize, } impl<'r, 't> Iterator for Split<'r, 't> { type Item = &'t str; fn next(&mut self) -> Option<&'t str> { let text = self.finder.0.text(); match self.finder.next() { None => { if self.last > text.len() { None } else { let s = &text[self.last..]; self.last = text.len() + 1; // Next call will return None Some(s) } } Some(m) => { let matched = &text[self.last..m.start()]; self.last = m.end(); Some(matched) } } } } impl<'r, 't> FusedIterator for Split<'r, 't> {} /// Yields at most `N` substrings delimited by a regular expression match. /// /// The last substring will be whatever remains after splitting. /// /// `'r` is the lifetime of the compiled regular expression and `'t` is the /// lifetime of the string being split. #[derive(Debug)] pub struct SplitN<'r, 't> { splits: Split<'r, 't>, n: usize, } impl<'r, 't> Iterator for SplitN<'r, 't> { type Item = &'t str; fn next(&mut self) -> Option<&'t str> { if self.n == 0 { return None; } self.n -= 1; if self.n > 0 { return self.splits.next(); } let text = self.splits.finder.0.text(); if self.splits.last > text.len() { // We've already returned all substrings. None } else { // self.n == 0, so future calls will return None immediately Some(&text[self.splits.last..]) } } fn size_hint(&self) -> (usize, Option<usize>) { (0, Some(self.n)) } } impl<'r, 't> FusedIterator for SplitN<'r, 't> {} /// CaptureLocations is a low level representation of the raw offsets of each /// submatch. /// /// You can think of this as a lower level /// [`Captures`](struct.Captures.html), where this type does not support /// named capturing groups directly and it does not borrow the text that these /// offsets were matched on. /// /// Primarily, this type is useful when using the lower level `Regex` APIs /// such as `read_captures`, which permits amortizing the allocation in which /// capture match locations are stored. /// /// In order to build a value of this type, you'll need to call the /// `capture_locations` method on the `Regex` being used to execute the search. /// The value returned can then be reused in subsequent searches. #[derive(Clone, Debug)] pub struct CaptureLocations(re_trait::Locations); /// A type alias for `CaptureLocations` for backwards compatibility. /// /// Previously, we exported `CaptureLocations` as `Locations` in an /// undocumented API. To prevent breaking that code (e.g., in `regex-capi`), /// we continue re-exporting the same undocumented API. #[doc(hidden)] pub type Locations = CaptureLocations; impl CaptureLocations { /// Returns the start and end positions of the Nth capture group. Returns /// `None` if `i` is not a valid capture group or if the capture group did /// not match anything. The positions returned are *always* byte indices /// with respect to the original string matched. #[inline] pub fn get(&self, i: usize) -> Option<(usize, usize)> { self.0.pos(i) } /// Returns the total number of capturing groups. /// /// This is always at least `1` since every regex has at least `1` /// capturing group that corresponds to the entire match. #[inline] pub fn len(&self) -> usize { self.0.len() } /// An alias for the `get` method for backwards compatibility. /// /// Previously, we exported `get` as `pos` in an undocumented API. To /// prevent breaking that code (e.g., in `regex-capi`), we continue /// re-exporting the same undocumented API. #[doc(hidden)] #[inline] pub fn pos(&self, i: usize) -> Option<(usize, usize)> { self.get(i) } } /// Captures represents a group of captured strings for a single match. /// /// The 0th capture always corresponds to the entire match. Each subsequent /// index corresponds to the next capture group in the regex. If a capture /// group is named, then the matched string is *also* available via the `name` /// method. (Note that the 0th capture is always unnamed and so must be /// accessed with the `get` method.) /// /// Positions returned from a capture group are always byte indices. /// /// `'t` is the lifetime of the matched text. pub struct Captures<'t> { text: &'t str, locs: re_trait::Locations, named_groups: Arc<HashMap<String, usize>>, } impl<'t> Captures<'t> { /// Returns the match associated with the capture group at index `i`. If /// `i` does not correspond to a capture group, or if the capture group /// did not participate in the match, then `None` is returned. /// /// # Examples /// /// Get the text of the match with a default of an empty string if this /// group didn't participate in the match: /// /// ```rust /// # use regex::Regex; /// let re = Regex::new(r"[a-z]+(?:([0-9]+)|([A-Z]+))").unwrap(); /// let caps = re.captures("abc123").unwrap(); /// /// let text1 = caps.get(1).map_or("", |m| m.as_str()); /// let text2 = caps.get(2).map_or("", |m| m.as_str()); /// assert_eq!(text1, "123"); /// assert_eq!(text2, ""); /// ``` pub fn get(&self, i: usize) -> Option<Match<'t>> { self.locs.pos(i).map(|(s, e)| Match::new(self.text, s, e)) } /// Returns the match for the capture group named `name`. If `name` isn't a /// valid capture group or didn't match anything, then `None` is returned. pub fn name(&self, name: &str) -> Option<Match<'t>> { self.named_groups.get(name).and_then(|&i| self.get(i)) } /// An iterator that yields all capturing matches in the order in which /// they appear in the regex. If a particular capture group didn't /// participate in the match, then `None` is yielded for that capture. /// /// The first match always corresponds to the overall match of the regex. pub fn iter<'c>(&'c self) -> SubCaptureMatches<'c, 't> { SubCaptureMatches { caps: self, it: self.locs.iter() } } /// Expands all instances of `$name` in `replacement` to the corresponding /// capture group `name`, and writes them to the `dst` buffer given. /// /// `name` may be an integer corresponding to the index of the capture /// group (counted by order of opening parenthesis where `0` is the /// entire match) or it can be a name (consisting of letters, digits or /// underscores) corresponding to a named capture group. /// /// If `name` isn't a valid capture group (whether the name doesn't exist /// or isn't a valid index), then it is replaced with the empty string. /// /// The longest possible name consisting of the characters `[_0-9A-Za-z]` /// is used. e.g., `$1a` looks up the capture group named `1a` and not the /// capture group at index `1`. To exert more precise control over the /// name, or to refer to a capture group name that uses characters outside /// of `[_0-9A-Za-z]`, use braces, e.g., `${1}a` or `${foo[bar].baz}`. When /// using braces, any sequence of characters is permitted. If the sequence /// does not refer to a capture group name in the corresponding regex, then /// it is replaced with an empty string. /// /// To write a literal `$` use `$$`. pub fn expand(&self, replacement: &str, dst: &mut String) { expand_str(self, replacement, dst) } /// Returns the number of captured groups. /// /// This is always at least `1`, since every regex has at least one capture /// group that corresponds to the full match. #[inline] pub fn len(&self) -> usize { self.locs.len() } } impl<'t> fmt::Debug for Captures<'t> { fn fmt(&self, f: &mut fmt::Formatter) -> fmt::Result { f.debug_tuple("Captures").field(&CapturesDebug(self)).finish() } } struct CapturesDebug<'c, 't: 'c>(&'c Captures<'t>); impl<'c, 't> fmt::Debug for CapturesDebug<'c, 't> { fn fmt(&self, f: &mut fmt::Formatter) -> fmt::Result { // We'd like to show something nice here, even if it means an // allocation to build a reverse index. let slot_to_name: HashMap<&usize, &String> = self.0.named_groups.iter().map(|(a, b)| (b, a)).collect(); let mut map = f.debug_map(); for (slot, m) in self.0.locs.iter().enumerate() { let m = m.map(|(s, e)| &self.0.text[s..e]); if let Some(name) = slot_to_name.get(&slot) { map.entry(&name, &m); } else { map.entry(&slot, &m); } } map.finish() } } /// Get a group by index. /// /// `'t` is the lifetime of the matched text. /// /// The text can't outlive the `Captures` object if this method is /// used, because of how `Index` is defined (normally `a[i]` is part /// of `a` and can't outlive it); to do that, use `get()` instead. /// /// # Panics /// /// If there is no group at the given index. impl<'t> Index<usize> for Captures<'t> { type Output = str; fn index(&self, i: usize) -> &str { self.get(i) .map(|m| m.as_str()) .unwrap_or_else(|| panic!("no group at index '{}'", i)) } } /// Get a group by name. /// /// `'t` is the lifetime of the matched text and `'i` is the lifetime /// of the group name (the index). /// /// The text can't outlive the `Captures` object if this method is /// used, because of how `Index` is defined (normally `a[i]` is part /// of `a` and can't outlive it); to do that, use `name` instead. /// /// # Panics /// /// If there is no group named by the given value. impl<'t, 'i> Index<&'i str> for Captures<'t> { type Output = str; fn index<'a>(&'a self, name: &'i str) -> &'a str { self.name(name) .map(|m| m.as_str()) .unwrap_or_else(|| panic!("no group named '{}'", name)) } } /// An iterator that yields all capturing matches in the order in which they /// appear in the regex. /// /// If a particular capture group didn't participate in the match, then `None` /// is yielded for that capture. The first match always corresponds to the /// overall match of the regex. /// /// The lifetime `'c` corresponds to the lifetime of the `Captures` value, and /// the lifetime `'t` corresponds to the originally matched text. #[derive(Clone, Debug)] pub struct SubCaptureMatches<'c, 't: 'c> { caps: &'c Captures<'t>, it: SubCapturesPosIter<'c>, } impl<'c, 't> Iterator for SubCaptureMatches<'c, 't> { type Item = Option<Match<'t>>; fn next(&mut self) -> Option<Option<Match<'t>>> { self.it .next() .map(|cap| cap.map(|(s, e)| Match::new(self.caps.text, s, e))) } } impl<'c, 't> FusedIterator for SubCaptureMatches<'c, 't> {} /// An iterator that yields all non-overlapping capture groups matching a /// particular regular expression. /// /// The iterator stops when no more matches can be found. /// /// `'r` is the lifetime of the compiled regular expression and `'t` is the /// lifetime of the matched string. #[derive(Debug)] pub struct CaptureMatches<'r, 't>( re_trait::CaptureMatches<'t, ExecNoSyncStr<'r>>, ); impl<'r, 't> Iterator for CaptureMatches<'r, 't> { type Item = Captures<'t>; fn next(&mut self) -> Option<Captures<'t>> { self.0.next().map(|locs| Captures { text: self.0.text(), locs: locs, named_groups: self.0.regex().capture_name_idx().clone(), }) } } impl<'r, 't> FusedIterator for CaptureMatches<'r, 't> {} /// An iterator over all non-overlapping matches for a particular string. /// /// The iterator yields a `Match` value. The iterator stops when no more /// matches can be found. /// /// `'r` is the lifetime of the compiled regular expression and `'t` is the /// lifetime of the matched string. #[derive(Debug)] pub struct Matches<'r, 't>(re_trait::Matches<'t, ExecNoSyncStr<'r>>); impl<'r, 't> Iterator for Matches<'r, 't> { type Item = Match<'t>; fn next(&mut self) -> Option<Match<'t>> { let text = self.0.text(); self.0.next().map(|(s, e)| Match::new(text, s, e)) } } impl<'r, 't> FusedIterator for Matches<'r, 't> {} /// Replacer describes types that can be used to replace matches in a string. /// /// In general, users of this crate shouldn't need to implement this trait, /// since implementations are already provided for `&str` along with other /// variants of string types and `FnMut(&Captures) -> String` (or any /// `FnMut(&Captures) -> T` where `T: AsRef<str>`), which covers most use cases. pub trait Replacer { /// Appends text to `dst` to replace the current match. /// /// The current match is represented by `caps`, which is guaranteed to /// have a match at capture group `0`. /// /// For example, a no-op replacement would be /// `dst.push_str(caps.get(0).unwrap().as_str())`. fn replace_append(&mut self, caps: &Captures, dst: &mut String); /// Return a fixed unchanging replacement string. /// /// When doing replacements, if access to `Captures` is not needed (e.g., /// the replacement byte string does not need `$` expansion), then it can /// be beneficial to avoid finding sub-captures. /// /// In general, this is called once for every call to `replacen`. fn no_expansion<'r>(&'r mut self) -> Option<Cow<'r, str>> { None } /// Return a `Replacer` that borrows and wraps this `Replacer`. /// /// This is useful when you want to take a generic `Replacer` (which might /// not be cloneable) and use it without consuming it, so it can be used /// more than once. /// /// # Example /// /// ``` /// use regex::{Regex, Replacer}; /// /// fn replace_all_twice<R: Replacer>( /// re: Regex, /// src: &str, /// mut rep: R, /// ) -> String { /// let dst = re.replace_all(src, rep.by_ref()); /// let dst = re.replace_all(&dst, rep.by_ref()); /// dst.into_owned() /// } /// ``` fn by_ref<'r>(&'r mut self) -> ReplacerRef<'r, Self> { ReplacerRef(self) } } /// By-reference adaptor for a `Replacer` /// /// Returned by [`Replacer::by_ref`](trait.Replacer.html#method.by_ref). #[derive(Debug)] pub struct ReplacerRef<'a, R: ?Sized + 'a>(&'a mut R); impl<'a, R: Replacer + ?Sized + 'a> Replacer for ReplacerRef<'a, R> { fn replace_append(&mut self, caps: &Captures, dst: &mut String) { self.0.replace_append(caps, dst) } fn no_expansion(&mut self) -> Option<Cow<str>> { self.0.no_expansion() } } impl<'a> Replacer for &'a str { fn replace_append(&mut self, caps: &Captures, dst: &mut String) { caps.expand(*self, dst); } fn no_expansion(&mut self) -> Option<Cow<str>> { no_expansion(self) } } impl<'a> Replacer for &'a String { fn replace_append(&mut self, caps: &Captures, dst: &mut String) { self.as_str().replace_append(caps, dst) } fn no_expansion(&mut self) -> Option<Cow<str>> { no_expansion(self) } } impl Replacer for String { fn replace_append(&mut self, caps: &Captures, dst: &mut String) { self.as_str().replace_append(caps, dst) } fn no_expansion(&mut self) -> Option<Cow<str>> { no_expansion(self) } } impl<'a> Replacer for Cow<'a, str> { fn replace_append(&mut self, caps: &Captures, dst: &mut String) { self.as_ref().replace_append(caps, dst) } fn no_expansion(&mut self) -> Option<Cow<str>> { no_expansion(self) } } impl<'a> Replacer for &'a Cow<'a, str> { fn replace_append(&mut self, caps: &Captures, dst: &mut String) { self.as_ref().replace_append(caps, dst) } fn no_expansion(&mut self) -> Option<Cow<str>> { no_expansion(self) } } fn no_expansion<T: AsRef<str>>(t: &T) -> Option<Cow<str>> { let s = t.as_ref(); match find_byte(b'$', s.as_bytes()) { Some(_) => None, None => Some(Cow::Borrowed(s)), } } impl<F, T> Replacer for F where F: FnMut(&Captures) -> T, T: AsRef<str>, { fn replace_append(&mut self, caps: &Captures, dst: &mut String) { dst.push_str((*self)(caps).as_ref()); } } /// `NoExpand` indicates literal string replacement. /// /// It can be used with `replace` and `replace_all` to do a literal string /// replacement without expanding `$name` to their corresponding capture /// groups. This can be both convenient (to avoid escaping `$`, for example) /// and performant (since capture groups don't need to be found). /// /// `'t` is the lifetime of the literal text. #[derive(Clone, Debug)] pub struct NoExpand<'t>(pub &'t str); impl<'t> Replacer for NoExpand<'t> { fn replace_append(&mut self, _: &Captures, dst: &mut String) { dst.push_str(self.0); } fn no_expansion(&mut self) -> Option<Cow<str>> { Some(Cow::Borrowed(self.0)) } }