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#[cfg(feature = "std")] use dense::{self, DenseDFA}; use dfa::DFA; #[cfg(feature = "std")] use error::Result; #[cfg(feature = "std")] use sparse::SparseDFA; #[cfg(feature = "std")] use state_id::StateID; /// A regular expression that uses deterministic finite automata for fast /// searching. /// /// A regular expression is comprised of two DFAs, a "forward" DFA and a /// "reverse" DFA. The forward DFA is responsible for detecting the end of a /// match while the reverse DFA is responsible for detecting the start of a /// match. Thus, in order to find the bounds of any given match, a forward /// search must first be run followed by a reverse search. A match found by /// the forward DFA guarantees that the reverse DFA will also find a match. /// /// The type of the DFA used by a `Regex` corresponds to the `D` type /// parameter, which must satisfy the [`DFA`](trait.DFA.html) trait. Typically, /// `D` is either a [`DenseDFA`](enum.DenseDFA.html) or a /// [`SparseDFA`](enum.SparseDFA.html), where dense DFAs use more memory but /// search faster, while sparse DFAs use less memory but search more slowly. /// /// By default, a regex's DFA type parameter is set to /// `DenseDFA<Vec<usize>, usize>`. For most in-memory work loads, this is the /// most convenient type that gives the best search performance. /// /// # Sparse DFAs /// /// Since a `Regex` is generic over the `DFA` trait, it can be used with any /// kind of DFA. While this crate constructs dense DFAs by default, it is easy /// enough to build corresponding sparse DFAs, and then build a regex from /// them: /// /// ``` /// use regex_automata::Regex; /// /// # fn example() -> Result<(), regex_automata::Error> { /// // First, build a regex that uses dense DFAs. /// let dense_re = Regex::new("foo[0-9]+")?; /// /// // Second, build sparse DFAs from the forward and reverse dense DFAs. /// let fwd = dense_re.forward().to_sparse()?; /// let rev = dense_re.reverse().to_sparse()?; /// /// // Third, build a new regex from the constituent sparse DFAs. /// let sparse_re = Regex::from_dfas(fwd, rev); /// /// // A regex that uses sparse DFAs can be used just like with dense DFAs. /// assert_eq!(true, sparse_re.is_match(b"foo123")); /// # Ok(()) }; example().unwrap() /// ``` #[cfg(feature = "std")] #[derive(Clone, Debug)] pub struct Regex<D: DFA = DenseDFA<Vec<usize>, usize>> { forward: D, reverse: D, } /// A regular expression that uses deterministic finite automata for fast /// searching. /// /// A regular expression is comprised of two DFAs, a "forward" DFA and a /// "reverse" DFA. The forward DFA is responsible for detecting the end of a /// match while the reverse DFA is responsible for detecting the start of a /// match. Thus, in order to find the bounds of any given match, a forward /// search must first be run followed by a reverse search. A match found by /// the forward DFA guarantees that the reverse DFA will also find a match. /// /// The type of the DFA used by a `Regex` corresponds to the `D` type /// parameter, which must satisfy the [`DFA`](trait.DFA.html) trait. Typically, /// `D` is either a [`DenseDFA`](enum.DenseDFA.html) or a /// [`SparseDFA`](enum.SparseDFA.html), where dense DFAs use more memory but /// search faster, while sparse DFAs use less memory but search more slowly. /// /// When using this crate without the standard library, the `Regex` type has /// no default type parameter. /// /// # Sparse DFAs /// /// Since a `Regex` is generic over the `DFA` trait, it can be used with any /// kind of DFA. While this crate constructs dense DFAs by default, it is easy /// enough to build corresponding sparse DFAs, and then build a regex from /// them: /// /// ``` /// use regex_automata::Regex; /// /// # fn example() -> Result<(), regex_automata::Error> { /// // First, build a regex that uses dense DFAs. /// let dense_re = Regex::new("foo[0-9]+")?; /// /// // Second, build sparse DFAs from the forward and reverse dense DFAs. /// let fwd = dense_re.forward().to_sparse()?; /// let rev = dense_re.reverse().to_sparse()?; /// /// // Third, build a new regex from the constituent sparse DFAs. /// let sparse_re = Regex::from_dfas(fwd, rev); /// /// // A regex that uses sparse DFAs can be used just like with dense DFAs. /// assert_eq!(true, sparse_re.is_match(b"foo123")); /// # Ok(()) }; example().unwrap() /// ``` #[cfg(not(feature = "std"))] #[derive(Clone, Debug)] pub struct Regex<D> { forward: D, reverse: D, } #[cfg(feature = "std")] impl Regex { /// Parse the given regular expression using a default configuration and /// return the corresponding regex. /// /// The default configuration uses `usize` for state IDs, premultiplies /// them and reduces the alphabet size by splitting bytes into equivalence /// classes. The underlying DFAs are *not* minimized. /// /// If you want a non-default configuration, then use the /// [`RegexBuilder`](struct.RegexBuilder.html) /// to set your own configuration. /// /// # Example /// /// ``` /// use regex_automata::Regex; /// /// # fn example() -> Result<(), regex_automata::Error> { /// let re = Regex::new("foo[0-9]+bar")?; /// assert_eq!(Some((3, 14)), re.find(b"zzzfoo12345barzzz")); /// # Ok(()) }; example().unwrap() /// ``` pub fn new(pattern: &str) -> Result<Regex> { RegexBuilder::new().build(pattern) } } #[cfg(feature = "std")] impl Regex<SparseDFA<Vec<u8>, usize>> { /// Parse the given regular expression using a default configuration and /// return the corresponding regex using sparse DFAs. /// /// The default configuration uses `usize` for state IDs, reduces the /// alphabet size by splitting bytes into equivalence classes. The /// underlying DFAs are *not* minimized. /// /// If you want a non-default configuration, then use the /// [`RegexBuilder`](struct.RegexBuilder.html) /// to set your own configuration. /// /// # Example /// /// ``` /// use regex_automata::Regex; /// /// # fn example() -> Result<(), regex_automata::Error> { /// let re = Regex::new_sparse("foo[0-9]+bar")?; /// assert_eq!(Some((3, 14)), re.find(b"zzzfoo12345barzzz")); /// # Ok(()) }; example().unwrap() /// ``` pub fn new_sparse( pattern: &str, ) -> Result<Regex<SparseDFA<Vec<u8>, usize>>> { RegexBuilder::new().build_sparse(pattern) } } impl<D: DFA> Regex<D> { /// Returns true if and only if the given bytes match. /// /// This routine may short circuit if it knows that scanning future input /// will never lead to a different result. In particular, if the underlying /// DFA enters a match state or a dead state, then this routine will return /// `true` or `false`, respectively, without inspecting any future input. /// /// # Example /// /// ``` /// use regex_automata::Regex; /// /// # fn example() -> Result<(), regex_automata::Error> { /// let re = Regex::new("foo[0-9]+bar")?; /// assert_eq!(true, re.is_match(b"foo12345bar")); /// assert_eq!(false, re.is_match(b"foobar")); /// # Ok(()) }; example().unwrap() /// ``` pub fn is_match(&self, input: &[u8]) -> bool { self.is_match_at(input, 0) } /// Returns the first position at which a match is found. /// /// This routine stops scanning input in precisely the same circumstances /// as `is_match`. The key difference is that this routine returns the /// position at which it stopped scanning input if and only if a match /// was found. If no match is found, then `None` is returned. /// /// # Example /// /// ``` /// use regex_automata::Regex; /// /// # fn example() -> Result<(), regex_automata::Error> { /// let re = Regex::new("foo[0-9]+")?; /// assert_eq!(Some(4), re.shortest_match(b"foo12345")); /// /// // Normally, the end of the leftmost first match here would be 3, /// // but the shortest match semantics detect a match earlier. /// let re = Regex::new("abc|a")?; /// assert_eq!(Some(1), re.shortest_match(b"abc")); /// # Ok(()) }; example().unwrap() /// ``` pub fn shortest_match(&self, input: &[u8]) -> Option<usize> { self.shortest_match_at(input, 0) } /// Returns the start and end offset of the leftmost first match. If no /// match exists, then `None` is returned. /// /// The "leftmost first" match corresponds to the match with the smallest /// starting offset, but where the end offset is determined by preferring /// earlier branches in the original regular expression. For example, /// `Sam|Samwise` will match `Sam` in `Samwise`, but `Samwise|Sam` will /// match `Samwise` in `Samwise`. /// /// Generally speaking, the "leftmost first" match is how most backtracking /// regular expressions tend to work. This is in contrast to POSIX-style /// regular expressions that yield "leftmost longest" matches. Namely, /// both `Sam|Samwise` and `Samwise|Sam` match `Samwise` when using /// leftmost longest semantics. /// /// # Example /// /// ``` /// use regex_automata::Regex; /// /// # fn example() -> Result<(), regex_automata::Error> { /// let re = Regex::new("foo[0-9]+")?; /// assert_eq!(Some((3, 11)), re.find(b"zzzfoo12345zzz")); /// /// // Even though a match is found after reading the first byte (`a`), /// // the leftmost first match semantics demand that we find the earliest /// // match that prefers earlier parts of the pattern over latter parts. /// let re = Regex::new("abc|a")?; /// assert_eq!(Some((0, 3)), re.find(b"abc")); /// # Ok(()) }; example().unwrap() /// ``` pub fn find(&self, input: &[u8]) -> Option<(usize, usize)> { self.find_at(input, 0) } /// 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, if the DFA is anchored, then /// a match can only occur when `start == 0`. pub fn is_match_at(&self, input: &[u8], start: usize) -> bool { self.forward().is_match_at(input, start) } /// 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, if the DFA is anchored, then /// a match can only occur when `start == 0`. pub fn shortest_match_at( &self, input: &[u8], start: usize, ) -> Option<usize> { self.forward().shortest_match_at(input, start) } /// 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, if the DFA is anchored, then /// a match can only occur when `start == 0`. pub fn find_at( &self, input: &[u8], start: usize, ) -> Option<(usize, usize)> { let end = match self.forward().find_at(input, start) { None => return None, Some(end) => end, }; let start = self .reverse() .rfind(&input[start..end]) .map(|i| start + i) .expect("reverse search must match if forward search does"); Some((start, end)) } /// Returns an iterator over all non-overlapping leftmost first matches /// in the given bytes. If no match exists, then the iterator yields no /// elements. /// /// Note that if the regex can match the empty string, then it is /// possible for the iterator to yield a zero-width match at a location /// that is not a valid UTF-8 boundary (for example, between the code units /// of a UTF-8 encoded codepoint). This can happen regardless of whether /// [`allow_invalid_utf8`](struct.RegexBuilder.html#method.allow_invalid_utf8) /// was enabled or not. /// /// # Example /// /// ``` /// use regex_automata::Regex; /// /// # fn example() -> Result<(), regex_automata::Error> { /// let re = Regex::new("foo[0-9]+")?; /// let text = b"foo1 foo12 foo123"; /// let matches: Vec<(usize, usize)> = re.find_iter(text).collect(); /// assert_eq!(matches, vec![(0, 4), (5, 10), (11, 17)]); /// # Ok(()) }; example().unwrap() /// ``` pub fn find_iter<'r, 't>(&'r self, input: &'t [u8]) -> Matches<'r, 't, D> { Matches::new(self, input) } /// Build a new regex from its constituent forward and reverse DFAs. /// /// This is useful when deserializing a regex from some arbitrary /// memory region. This is also useful for building regexes from other /// types of DFAs. /// /// # Example /// /// This example is a bit a contrived. The usual use of these methods /// would involve serializing `initial_re` somewhere and then deserializing /// it later to build a regex. /// /// ``` /// use regex_automata::Regex; /// /// # fn example() -> Result<(), regex_automata::Error> { /// let initial_re = Regex::new("foo[0-9]+")?; /// assert_eq!(true, initial_re.is_match(b"foo123")); /// /// let (fwd, rev) = (initial_re.forward(), initial_re.reverse()); /// let re = Regex::from_dfas(fwd, rev); /// assert_eq!(true, re.is_match(b"foo123")); /// # Ok(()) }; example().unwrap() /// ``` /// /// This example shows how you might build smaller DFAs, and then use those /// smaller DFAs to build a new regex. /// /// ``` /// use regex_automata::Regex; /// /// # fn example() -> Result<(), regex_automata::Error> { /// let initial_re = Regex::new("foo[0-9]+")?; /// assert_eq!(true, initial_re.is_match(b"foo123")); /// /// let fwd = initial_re.forward().to_u16()?; /// let rev = initial_re.reverse().to_u16()?; /// let re = Regex::from_dfas(fwd, rev); /// assert_eq!(true, re.is_match(b"foo123")); /// # Ok(()) }; example().unwrap() /// ``` /// /// This example shows how to build a `Regex` that uses sparse DFAs instead /// of dense DFAs: /// /// ``` /// use regex_automata::Regex; /// /// # fn example() -> Result<(), regex_automata::Error> { /// let initial_re = Regex::new("foo[0-9]+")?; /// assert_eq!(true, initial_re.is_match(b"foo123")); /// /// let fwd = initial_re.forward().to_sparse()?; /// let rev = initial_re.reverse().to_sparse()?; /// let re = Regex::from_dfas(fwd, rev); /// assert_eq!(true, re.is_match(b"foo123")); /// # Ok(()) }; example().unwrap() /// ``` pub fn from_dfas(forward: D, reverse: D) -> Regex<D> { Regex { forward, reverse } } /// Return the underlying DFA responsible for forward matching. pub fn forward(&self) -> &D { &self.forward } /// Return the underlying DFA responsible for reverse matching. pub fn reverse(&self) -> &D { &self.reverse } } /// An iterator over all non-overlapping matches for a particular search. /// /// The iterator yields a `(usize, usize)` value until no more matches could be /// found. The first `usize` is the start of the match (inclusive) while the /// second `usize` is the end of the match (exclusive). /// /// `S` is the type used to represent state identifiers in the underlying /// regex. The lifetime variables are as follows: /// /// * `'r` is the lifetime of the regular expression value itself. /// * `'t` is the lifetime of the text being searched. #[derive(Clone, Debug)] pub struct Matches<'r, 't, D: DFA + 'r> { re: &'r Regex<D>, text: &'t [u8], last_end: usize, last_match: Option<usize>, } impl<'r, 't, D: DFA> Matches<'r, 't, D> { fn new(re: &'r Regex<D>, text: &'t [u8]) -> Matches<'r, 't, D> { Matches { re, text, last_end: 0, last_match: None } } } impl<'r, 't, D: DFA> Iterator for Matches<'r, 't, D> { type Item = (usize, usize); fn next(&mut self) -> Option<(usize, usize)> { if self.last_end > self.text.len() { return None; } let (s, e) = match self.re.find_at(self.text, self.last_end) { None => return None, Some((s, e)) => (s, e), }; if s == e { // This is an empty match. To ensure we make progress, start // the next search at the smallest possible starting position // of the next match following this one. self.last_end = e + 1; // Don't accept empty matches immediately following a match. // Just move on to the next match. if Some(e) == self.last_match { return self.next(); } } else { self.last_end = e; } self.last_match = Some(e); Some((s, e)) } } /// A builder for a regex based on deterministic finite automatons. /// /// This builder permits configuring several aspects of the construction /// process such as case insensitivity, Unicode support and various options /// that impact the size of the underlying DFAs. In some cases, options (like /// performing DFA minimization) can come with a substantial additional cost. /// /// This builder generally constructs two DFAs, where one is responsible for /// finding the end of a match and the other is responsible for finding the /// start of a match. If you only need to detect whether something matched, /// or only the end of a match, then you should use a /// [`dense::Builder`](dense/struct.Builder.html) /// to construct a single DFA, which is cheaper than building two DFAs. #[cfg(feature = "std")] #[derive(Clone, Debug)] pub struct RegexBuilder { dfa: dense::Builder, } #[cfg(feature = "std")] impl RegexBuilder { /// Create a new regex builder with the default configuration. pub fn new() -> RegexBuilder { RegexBuilder { dfa: dense::Builder::new() } } /// Build a regex from the given pattern. /// /// If there was a problem parsing or compiling the pattern, then an error /// is returned. pub fn build(&self, pattern: &str) -> Result<Regex> { self.build_with_size::<usize>(pattern) } /// Build a regex from the given pattern using sparse DFAs. /// /// If there was a problem parsing or compiling the pattern, then an error /// is returned. pub fn build_sparse( &self, pattern: &str, ) -> Result<Regex<SparseDFA<Vec<u8>, usize>>> { self.build_with_size_sparse::<usize>(pattern) } /// Build a regex from the given pattern using a specific representation /// for the underlying DFA state IDs. /// /// If there was a problem parsing or compiling the pattern, then an error /// is returned. /// /// The representation of state IDs is determined by the `S` type /// parameter. In general, `S` is usually one of `u8`, `u16`, `u32`, `u64` /// or `usize`, where `usize` is the default used for `build`. The purpose /// of specifying a representation for state IDs is to reduce the memory /// footprint of the underlying DFAs. /// /// When using this routine, the chosen state ID representation will be /// used throughout determinization and minimization, if minimization was /// requested. Even if the minimized DFAs can fit into the chosen state ID /// representation but the initial determinized DFA cannot, then this will /// still return an error. To get a minimized DFA with a smaller state ID /// representation, first build it with a bigger state ID representation, /// and then shrink the sizes of the DFAs using one of its conversion /// routines, such as [`DenseDFA::to_u16`](enum.DenseDFA.html#method.to_u16). /// Finally, reconstitute the regex via /// [`Regex::from_dfa`](struct.Regex.html#method.from_dfa). pub fn build_with_size<S: StateID>( &self, pattern: &str, ) -> Result<Regex<DenseDFA<Vec<S>, S>>> { let forward = self.dfa.build_with_size(pattern)?; let reverse = self .dfa .clone() .anchored(true) .reverse(true) .longest_match(true) .build_with_size(pattern)?; Ok(Regex::from_dfas(forward, reverse)) } /// Build a regex from the given pattern using a specific representation /// for the underlying DFA state IDs using sparse DFAs. pub fn build_with_size_sparse<S: StateID>( &self, pattern: &str, ) -> Result<Regex<SparseDFA<Vec<u8>, S>>> { let re = self.build_with_size(pattern)?; let fwd = re.forward().to_sparse()?; let rev = re.reverse().to_sparse()?; Ok(Regex::from_dfas(fwd, rev)) } /// Set whether matching must be anchored at the beginning of the input. /// /// When enabled, a match must begin at the start of the input. When /// disabled, the regex will act as if the pattern started with a `.*?`, /// which enables a match to appear anywhere. /// /// By default this is disabled. pub fn anchored(&mut self, yes: bool) -> &mut RegexBuilder { self.dfa.anchored(yes); self } /// Enable or disable the case insensitive flag by default. /// /// By default this is disabled. It may alternatively be selectively /// enabled in the regular expression itself via the `i` flag. pub fn case_insensitive(&mut self, yes: bool) -> &mut RegexBuilder { self.dfa.case_insensitive(yes); self } /// Enable verbose mode in the regular expression. /// /// When enabled, verbose mode permits insigificant whitespace in many /// places in the regular expression, as well as comments. Comments are /// started using `#` and continue until the end of the line. /// /// By default, this is disabled. It may be selectively enabled in the /// regular expression by using the `x` flag regardless of this setting. pub fn ignore_whitespace(&mut self, yes: bool) -> &mut RegexBuilder { self.dfa.ignore_whitespace(yes); self } /// Enable or disable the "dot matches any character" flag by default. /// /// By default this is disabled. It may alternatively be selectively /// enabled in the regular expression itself via the `s` flag. pub fn dot_matches_new_line(&mut self, yes: bool) -> &mut RegexBuilder { self.dfa.dot_matches_new_line(yes); self } /// Enable or disable the "swap greed" flag by default. /// /// By default this is disabled. It may alternatively be selectively /// enabled in the regular expression itself via the `U` flag. pub fn swap_greed(&mut self, yes: bool) -> &mut RegexBuilder { self.dfa.swap_greed(yes); self } /// Enable or disable the Unicode flag (`u`) by default. /// /// By default this is **enabled**. It may alternatively be selectively /// disabled in the regular expression itself via the `u` flag. /// /// Note that unless `allow_invalid_utf8` is enabled (it's disabled by /// default), a regular expression will fail to parse if Unicode mode is /// disabled and a sub-expression could possibly match invalid UTF-8. pub fn unicode(&mut self, yes: bool) -> &mut RegexBuilder { self.dfa.unicode(yes); self } /// When enabled, the builder will permit the construction of a regular /// expression that may match invalid UTF-8. /// /// When disabled (the default), the builder is guaranteed to produce a /// regex that will only ever match valid UTF-8 (otherwise, the builder /// will return an error). pub fn allow_invalid_utf8(&mut self, yes: bool) -> &mut RegexBuilder { self.dfa.allow_invalid_utf8(yes); self } /// Set the nesting limit used for the regular expression parser. /// /// The nesting limit controls how deep the abstract syntax tree is allowed /// to be. If the AST exceeds the given limit (e.g., with too many nested /// groups), then an error is returned by the parser. /// /// The purpose of this limit is to act as a heuristic to prevent stack /// overflow when building a finite automaton from a regular expression's /// abstract syntax tree. In particular, construction currently uses /// recursion. In the future, the implementation may stop using recursion /// and this option will no longer be necessary. /// /// This limit is not checked until the entire AST is parsed. Therefore, /// if callers want to put a limit on the amount of heap space used, then /// they should impose a limit on the length, in bytes, of the concrete /// pattern string. In particular, this is viable since the parser will /// limit itself to heap space proportional to the lenth of the pattern /// string. /// /// Note that a nest limit of `0` will return a nest limit error for most /// patterns but not all. For example, a nest limit of `0` permits `a` but /// not `ab`, since `ab` requires a concatenation AST item, which results /// in a nest depth of `1`. In general, a nest limit is not something that /// manifests in an obvious way in the concrete syntax, therefore, it /// should not be used in a granular way. pub fn nest_limit(&mut self, limit: u32) -> &mut RegexBuilder { self.dfa.nest_limit(limit); self } /// Minimize the underlying DFAs. /// /// When enabled, the DFAs powering the resulting regex will be minimized /// such that it is as small as possible. /// /// Whether one enables minimization or not depends on the types of costs /// you're willing to pay and how much you care about its benefits. In /// particular, minimization has worst case `O(n*k*logn)` time and `O(k*n)` /// space, where `n` is the number of DFA states and `k` is the alphabet /// size. In practice, minimization can be quite costly in terms of both /// space and time, so it should only be done if you're willing to wait /// longer to produce a DFA. In general, you might want a minimal DFA in /// the following circumstances: /// /// 1. You would like to optimize for the size of the automaton. This can /// manifest in one of two ways. Firstly, if you're converting the /// DFA into Rust code (or a table embedded in the code), then a minimal /// DFA will translate into a corresponding reduction in code size, and /// thus, also the final compiled binary size. Secondly, if you are /// building many DFAs and putting them on the heap, you'll be able to /// fit more if they are smaller. Note though that building a minimal /// DFA itself requires additional space; you only realize the space /// savings once the minimal DFA is constructed (at which point, the /// space used for minimization is freed). /// 2. You've observed that a smaller DFA results in faster match /// performance. Naively, this isn't guaranteed since there is no /// inherent difference between matching with a bigger-than-minimal /// DFA and a minimal DFA. However, a smaller DFA may make use of your /// CPU's cache more efficiently. /// 3. You are trying to establish an equivalence between regular /// languages. The standard method for this is to build a minimal DFA /// for each language and then compare them. If the DFAs are equivalent /// (up to state renaming), then the languages are equivalent. /// /// This option is disabled by default. pub fn minimize(&mut self, yes: bool) -> &mut RegexBuilder { self.dfa.minimize(yes); self } /// Premultiply state identifiers in the underlying DFA transition tables. /// /// When enabled, state identifiers are premultiplied to point to their /// corresponding row in the DFA's transition table. That is, given the /// `i`th state, its corresponding premultiplied identifier is `i * k` /// where `k` is the alphabet size of the DFA. (The alphabet size is at /// most 256, but is in practice smaller if byte classes is enabled.) /// /// When state identifiers are not premultiplied, then the identifier of /// the `i`th state is `i`. /// /// The advantage of premultiplying state identifiers is that is saves /// a multiplication instruction per byte when searching with the DFA. /// This has been observed to lead to a 20% performance benefit in /// micro-benchmarks. /// /// The primary disadvantage of premultiplying state identifiers is /// that they require a larger integer size to represent. For example, /// if your DFA has 200 states, then its premultiplied form requires /// 16 bits to represent every possible state identifier, where as its /// non-premultiplied form only requires 8 bits. /// /// This option is enabled by default. pub fn premultiply(&mut self, yes: bool) -> &mut RegexBuilder { self.dfa.premultiply(yes); self } /// Shrink the size of the underlying DFA alphabet by mapping bytes to /// their equivalence classes. /// /// When enabled, each DFA will use a map from all possible bytes to their /// corresponding equivalence class. Each equivalence class represents a /// set of bytes that does not discriminate between a match and a non-match /// in the DFA. For example, the pattern `[ab]+` has at least two /// equivalence classes: a set containing `a` and `b` and a set containing /// every byte except for `a` and `b`. `a` and `b` are in the same /// equivalence classes because they never discriminate between a match /// and a non-match. /// /// The advantage of this map is that the size of the transition table can /// be reduced drastically from `#states * 256 * sizeof(id)` to /// `#states * k * sizeof(id)` where `k` is the number of equivalence /// classes. As a result, total space usage can decrease substantially. /// Moreover, since a smaller alphabet is used, compilation becomes faster /// as well. /// /// The disadvantage of this map is that every byte searched must be /// passed through this map before it can be used to determine the next /// transition. This has a small match time performance cost. /// /// This option is enabled by default. pub fn byte_classes(&mut self, yes: bool) -> &mut RegexBuilder { self.dfa.byte_classes(yes); self } /// Apply best effort heuristics to shrink the NFA at the expense of more /// time/memory. /// /// This may be exposed in the future, but for now is exported for use in /// the `regex-automata-debug` tool. #[doc(hidden)] pub fn shrink(&mut self, yes: bool) -> &mut RegexBuilder { self.dfa.shrink(yes); self } } #[cfg(feature = "std")] impl Default for RegexBuilder { fn default() -> RegexBuilder { RegexBuilder::new() } }