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use crate::Automaton; use regex_syntax; use std::fmt; use utf8_ranges; mod compile; mod dfa; mod error; mod sparse; pub use self::error::Error; /// A regular expression for searching FSTs with Unicode support. /// /// Regular expressions are compiled down to a deterministic finite automaton /// that can efficiently search any finite state transducer. Notably, most /// regular expressions only need to explore a small portion of a finite state /// transducer without loading all of it into memory. /// /// # Syntax /// /// `Regex` supports fully featured regular expressions. Namely, it supports /// all of the same constructs as the standard `regex` crate except for the /// following things: /// /// 1. Lazy quantifiers, since a regular expression automaton only reports /// whether a key matches at all, and not its location. Namely, lazy /// quantifiers such as `+?` only modify the location of a match, but never /// change a non-match into a match or a match into a non-match. /// 2. Word boundaries (i.e., `\b`). Because such things are hard to do in /// a deterministic finite automaton, but not impossible. As such, these /// may be allowed some day. /// 3. Other zero width assertions like `^` and `$`. These are easier to /// support than word boundaries, but are still tricky and usually aren't /// as useful when searching dictionaries. /// /// Otherwise, the [full syntax of the `regex` /// crate](http://doc.rust-lang.org/regex/regex/index.html#syntax) /// is supported. This includes all Unicode support and relevant flags. /// (The `U` and `m` flags are no-ops because of (1) and (3) above, /// respectively.) /// /// # Matching semantics /// /// A regular expression matches a key in a finite state transducer if and only /// if it matches from the start of a key all the way to end. Stated /// differently, every regular expression `(re)` is matched as if it were /// `^(re)$`. This means that if you want to do a substring match, then you /// must use `.*substring.*`. /// /// **Caution**: Starting a regular expression with `.*` means that it could /// potentially match *any* key in a finite state transducer. This implies that /// all keys could be visited, which could be slow. It is possible that this /// crate will grow facilities for detecting regular expressions that will /// scan a large portion of a transducer and optionally disallow them. /// pub struct Regex { original: String, dfa: dfa::Dfa, } #[derive(Eq, PartialEq)] pub enum Inst { Match, Jump(usize), Split(usize, usize), Range(u8, u8), } impl Regex { /// Create a new regular expression query. /// /// The query finds all terms matching the regular expression. /// /// If the regular expression is malformed or if it results in an automaton /// that is too big, then an error is returned. /// /// A `Regex` value satisfies the `Automaton` trait, which means it can be /// used with the `search` method of any finite state transducer. #[inline] pub fn new(re: &str) -> Result<Regex, Error> { Regex::with_size_limit(10 * (1 << 20), re) } fn with_size_limit(size: usize, re: &str) -> Result<Regex, Error> { let expr = regex_syntax::Expr::parse(re)?; let insts = self::compile::Compiler::new(size).compile(&expr)?; let dfa = self::dfa::DfaBuilder::new(insts).build()?; Ok(Regex { original: re.to_owned(), dfa, }) } } impl Automaton for Regex { type State = Option<usize>; #[inline] fn start(&self) -> Option<usize> { Some(0) } #[inline] fn is_match(&self, state: &Option<usize>) -> bool { state.map(|state| self.dfa.is_match(state)).unwrap_or(false) } #[inline] fn can_match(&self, state: &Option<usize>) -> bool { state.is_some() } #[inline] fn accept(&self, state: &Option<usize>, byte: u8) -> Option<usize> { state.and_then(|state| self.dfa.accept(state, byte)) } } impl fmt::Debug for Regex { fn fmt(&self, f: &mut fmt::Formatter) -> fmt::Result { writeln!(f, "Regex({:?})", self.original)?; self.dfa.fmt(f) } } impl fmt::Debug for Inst { fn fmt(&self, f: &mut fmt::Formatter) -> fmt::Result { use self::Inst::*; match *self { Match => write!(f, "Match"), Jump(ip) => write!(f, "JUMP {}", ip), Split(ip1, ip2) => write!(f, "SPLIT {}, {}", ip1, ip2), Range(s, e) => write!(f, "RANGE {:X}-{:X}", s, e), } } }