/*! A DFA that can return spans for matching capturing groups. This module is the home of a [one-pass DFA](DFA). This module also contains a [`Builder`] and a [`Config`] for building and configuring a one-pass DFA. */ // A note on naming and credit: // // As far as I know, Russ Cox came up with the practical vision and // implementation of a "one-pass regex engine." He mentions and describes it // briefly in the third article of his regexp article series: // https://swtch.com/~rsc/regexp/regexp3.html // // Cox's implementation is in RE2, and the implementation below is most // heavily inspired by RE2's. The key thing they have in common is that // their transitions are defined over an alphabet of bytes. In contrast, // Go's regex engine also has a one-pass engine, but its transitions are // more firmly rooted on Unicode codepoints. The ideas are the same, but the // implementations are different. // // RE2 tends to call this a "one-pass NFA." Here, we call it a "one-pass DFA." // They're both true in their own ways: // // * The "one-pass" criterion is generally a property of the NFA itself. In // particular, it is said that an NFA is one-pass if, after each byte of input // during a search, there is at most one "VM thread" remaining to take for the // next byte of input. That is, there is never any ambiguity as to the path to // take through the NFA during a search. // // * On the other hand, once a one-pass NFA has its representation converted // to something where a constant number of instructions is used for each byte // of input, the implementation looks a lot more like a DFA. It's technically // more powerful than a DFA since it has side effects (storing offsets inside // of slots activated by a transition), but it is far closer to a DFA than an // NFA simulation. // // Thus, in this crate, we call it a one-pass DFA. use alloc::{vec, vec::Vec}; use crate::{ dfa::{remapper::Remapper, DEAD}, nfa::thompson::{self, NFA}, util::{ alphabet::ByteClasses, captures::Captures, escape::DebugByte, int::{Usize, U32, U64, U8}, look::{Look, LookSet, UnicodeWordBoundaryError}, primitives::{NonMaxUsize, PatternID, StateID}, search::{Anchored, Input, Match, MatchError, MatchKind, Span}, sparse_set::SparseSet, }, }; /// The configuration used for building a [one-pass DFA](DFA). /// /// A one-pass DFA configuration is a simple data object that is typically used /// with [`Builder::configure`]. It can be cheaply cloned. /// /// A default configuration can be created either with `Config::new`, or /// perhaps more conveniently, with [`DFA::config`]. #[derive(Clone, Debug, Default)] pub struct Config { match_kind: Option, starts_for_each_pattern: Option, byte_classes: Option, size_limit: Option>, } impl Config { /// Return a new default one-pass DFA configuration. pub fn new() -> Config { Config::default() } /// Set the desired match semantics. /// /// The default is [`MatchKind::LeftmostFirst`], which corresponds to the /// match semantics of Perl-like regex engines. That is, when multiple /// patterns would match at the same leftmost position, the pattern that /// appears first in the concrete syntax is chosen. /// /// Currently, the only other kind of match semantics supported is /// [`MatchKind::All`]. This corresponds to "classical DFA" construction /// where all possible matches are visited. /// /// When it comes to the one-pass DFA, it is rarer for preference order and /// "longest match" to actually disagree. Since if they did disagree, then /// the regex typically isn't one-pass. For example, searching `Samwise` /// for `Sam|Samwise` will report `Sam` for leftmost-first matching and /// `Samwise` for "longest match" or "all" matching. However, this regex is /// not one-pass if taken literally. The equivalent regex, `Sam(?:|wise)` /// is one-pass and `Sam|Samwise` may be optimized to it. /// /// The other main difference is that "all" match semantics don't support /// non-greedy matches. "All" match semantics always try to match as much /// as possible. pub fn match_kind(mut self, kind: MatchKind) -> Config { self.match_kind = Some(kind); self } /// Whether to compile a separate start state for each pattern in the /// one-pass DFA. /// /// When enabled, a separate **anchored** start state is added for each /// pattern in the DFA. When this start state is used, then the DFA will /// only search for matches for the pattern specified, even if there are /// other patterns in the DFA. /// /// The main downside of this option is that it can potentially increase /// the size of the DFA and/or increase the time it takes to build the DFA. /// /// You might want to enable this option when you want to both search for /// anchored matches of any pattern or to search for anchored matches of /// one particular pattern while using the same DFA. (Otherwise, you would /// need to compile a new DFA for each pattern.) /// /// By default this is disabled. /// /// # Example /// /// This example shows how to build a multi-regex and then search for /// matches for a any of the patterns or matches for a specific pattern. /// /// ``` /// use regex_automata::{ /// dfa::onepass::DFA, Anchored, Input, Match, PatternID, /// }; /// /// let re = DFA::builder() /// .configure(DFA::config().starts_for_each_pattern(true)) /// .build_many(&["[a-z]+", "[0-9]+"])?; /// let (mut cache, mut caps) = (re.create_cache(), re.create_captures()); /// let haystack = "123abc"; /// let input = Input::new(haystack).anchored(Anchored::Yes); /// /// // A normal multi-pattern search will show pattern 1 matches. /// re.try_search(&mut cache, &input, &mut caps)?; /// assert_eq!(Some(Match::must(1, 0..3)), caps.get_match()); /// /// // If we only want to report pattern 0 matches, then we'll get no /// // match here. /// let input = input.anchored(Anchored::Pattern(PatternID::must(0))); /// re.try_search(&mut cache, &input, &mut caps)?; /// assert_eq!(None, caps.get_match()); /// /// # Ok::<(), Box>(()) /// ``` pub fn starts_for_each_pattern(mut self, yes: bool) -> Config { self.starts_for_each_pattern = Some(yes); self } /// Whether to attempt to shrink the size of the DFA's alphabet or not. /// /// This option is enabled by default and should never be disabled unless /// one is debugging a one-pass DFA. /// /// When enabled, the 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 class 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 (approximately) `#states * 256 * /// sizeof(StateID)` to `#states * k * sizeof(StateID)` where `k` is the /// number of equivalence classes (rounded up to the nearest power of 2). /// As a result, total space usage can decrease substantially. Moreover, /// since a smaller alphabet is used, DFA compilation becomes faster as /// well. /// /// **WARNING:** This is only useful for debugging DFAs. Disabling this /// does not yield any speed advantages. Namely, even when this is /// disabled, a byte class map is still used while searching. The only /// difference is that every byte will be forced into its own distinct /// equivalence class. This is useful for debugging the actual generated /// transitions because it lets one see the transitions defined on actual /// bytes instead of the equivalence classes. pub fn byte_classes(mut self, yes: bool) -> Config { self.byte_classes = Some(yes); self } /// Set a size limit on the total heap used by a one-pass DFA. /// /// This size limit is expressed in bytes and is applied during /// construction of a one-pass DFA. If the DFA's heap usage exceeds /// this configured limit, then construction is stopped and an error is /// returned. /// /// The default is no limit. /// /// # Example /// /// This example shows a one-pass DFA that fails to build because of /// a configured size limit. This particular example also serves as a /// cautionary tale demonstrating just how big DFAs with large Unicode /// character classes can get. /// /// ``` /// # if cfg!(miri) { return Ok(()); } // miri takes too long /// use regex_automata::{dfa::onepass::DFA, Match}; /// /// // 6MB isn't enough! /// DFA::builder() /// .configure(DFA::config().size_limit(Some(6_000_000))) /// .build(r"\w{20}") /// .unwrap_err(); /// /// // ... but 7MB probably is! /// // (Note that DFA sizes aren't necessarily stable between releases.) /// let re = DFA::builder() /// .configure(DFA::config().size_limit(Some(7_000_000))) /// .build(r"\w{20}")?; /// let (mut cache, mut caps) = (re.create_cache(), re.create_captures()); /// let haystack = "A".repeat(20); /// re.captures(&mut cache, &haystack, &mut caps); /// assert_eq!(Some(Match::must(0, 0..20)), caps.get_match()); /// /// # Ok::<(), Box>(()) /// ``` /// /// While one needs a little more than 3MB to represent `\w{20}`, it /// turns out that you only need a little more than 4KB to represent /// `(?-u:\w{20})`. So only use Unicode if you need it! pub fn size_limit(mut self, limit: Option) -> Config { self.size_limit = Some(limit); self } /// Returns the match semantics set in this configuration. pub fn get_match_kind(&self) -> MatchKind { self.match_kind.unwrap_or(MatchKind::LeftmostFirst) } /// Returns whether this configuration has enabled anchored starting states /// for every pattern in the DFA. pub fn get_starts_for_each_pattern(&self) -> bool { self.starts_for_each_pattern.unwrap_or(false) } /// Returns whether this configuration has enabled byte classes or not. /// This is typically a debugging oriented option, as disabling it confers /// no speed benefit. pub fn get_byte_classes(&self) -> bool { self.byte_classes.unwrap_or(true) } /// Returns the DFA size limit of this configuration if one was set. /// The size limit is total number of bytes on the heap that a DFA is /// permitted to use. If the DFA exceeds this limit during construction, /// then construction is stopped and an error is returned. pub fn get_size_limit(&self) -> Option { self.size_limit.unwrap_or(None) } /// Overwrite the default configuration such that the options in `o` are /// always used. If an option in `o` is not set, then the corresponding /// option in `self` is used. If it's not set in `self` either, then it /// remains not set. pub(crate) fn overwrite(&self, o: Config) -> Config { Config { match_kind: o.match_kind.or(self.match_kind), starts_for_each_pattern: o .starts_for_each_pattern .or(self.starts_for_each_pattern), byte_classes: o.byte_classes.or(self.byte_classes), size_limit: o.size_limit.or(self.size_limit), } } } /// A builder for a [one-pass DFA](DFA). /// /// This builder permits configuring options for the syntax of a pattern, the /// NFA construction and the DFA construction. This builder is different from a /// general purpose regex builder in that it permits fine grain configuration /// of the construction process. The trade off for this is complexity, and /// the possibility of setting a configuration that might not make sense. For /// example, there are two different UTF-8 modes: /// /// * [`syntax::Config::utf8`](crate::util::syntax::Config::utf8) controls /// whether the pattern itself can contain sub-expressions that match invalid /// UTF-8. /// * [`thompson::Config::utf8`] controls whether empty matches that split a /// Unicode codepoint are reported or not. /// /// Generally speaking, callers will want to either enable all of these or /// disable all of these. /// /// # Example /// /// This example shows how to disable UTF-8 mode in the syntax and the NFA. /// This is generally what you want for matching on arbitrary bytes. /// /// ``` /// # if cfg!(miri) { return Ok(()); } // miri takes too long /// use regex_automata::{ /// dfa::onepass::DFA, /// nfa::thompson, /// util::syntax, /// Match, /// }; /// /// let re = DFA::builder() /// .syntax(syntax::Config::new().utf8(false)) /// .thompson(thompson::Config::new().utf8(false)) /// .build(r"foo(?-u:[^b])ar.*")?; /// let (mut cache, mut caps) = (re.create_cache(), re.create_captures()); /// /// let haystack = b"foo\xFFarzz\xE2\x98\xFF\n"; /// re.captures(&mut cache, haystack, &mut caps); /// // Notice that `(?-u:[^b])` matches invalid UTF-8, /// // but the subsequent `.*` does not! Disabling UTF-8 /// // on the syntax permits this. /// // /// // N.B. This example does not show the impact of /// // disabling UTF-8 mode on a one-pass DFA Config, /// // since that only impacts regexes that can /// // produce matches of length 0. /// assert_eq!(Some(Match::must(0, 0..8)), caps.get_match()); /// /// # Ok::<(), Box>(()) /// ``` #[derive(Clone, Debug)] pub struct Builder { config: Config, #[cfg(feature = "syntax")] thompson: thompson::Compiler, } impl Builder { /// Create a new one-pass DFA builder with the default configuration. pub fn new() -> Builder { Builder { config: Config::default(), #[cfg(feature = "syntax")] thompson: thompson::Compiler::new(), } } /// Build a one-pass DFA from the given pattern. /// /// If there was a problem parsing or compiling the pattern, then an error /// is returned. #[cfg(feature = "syntax")] pub fn build(&self, pattern: &str) -> Result { self.build_many(&[pattern]) } /// Build a one-pass DFA from the given patterns. /// /// When matches are returned, the pattern ID corresponds to the index of /// the pattern in the slice given. #[cfg(feature = "syntax")] pub fn build_many>( &self, patterns: &[P], ) -> Result { let nfa = self.thompson.build_many(patterns).map_err(BuildError::nfa)?; self.build_from_nfa(nfa) } /// Build a DFA from the given NFA. /// /// # Example /// /// This example shows how to build a DFA if you already have an NFA in /// hand. /// /// ``` /// use regex_automata::{dfa::onepass::DFA, nfa::thompson::NFA, Match}; /// /// // This shows how to set non-default options for building an NFA. /// let nfa = NFA::compiler() /// .configure(NFA::config().shrink(true)) /// .build(r"[a-z0-9]+")?; /// let re = DFA::builder().build_from_nfa(nfa)?; /// let (mut cache, mut caps) = (re.create_cache(), re.create_captures()); /// re.captures(&mut cache, "foo123bar", &mut caps); /// assert_eq!(Some(Match::must(0, 0..9)), caps.get_match()); /// /// # Ok::<(), Box>(()) /// ``` pub fn build_from_nfa(&self, nfa: NFA) -> Result { // Why take ownership if we're just going to pass a reference to the // NFA to our internal builder? Well, the first thing to note is that // an NFA uses reference counting internally, so either choice is going // to be cheap. So there isn't much cost either way. // // The real reason is that a one-pass DFA, semantically, shares // ownership of an NFA. This is unlike other DFAs that don't share // ownership of an NFA at all, primarily because they want to be // self-contained in order to support cheap (de)serialization. // // But then why pass a '&nfa' below if we want to share ownership? // Well, it turns out that using a '&NFA' in our internal builder // separates its lifetime from the DFA we're building, and this turns // out to make code a bit more composable. e.g., We can iterate over // things inside the NFA while borrowing the builder as mutable because // we know the NFA cannot be mutated. So TL;DR --- this weirdness is // "because borrow checker." InternalBuilder::new(self.config.clone(), &nfa).build() } /// Apply the given one-pass DFA configuration options to this builder. pub fn configure(&mut self, config: Config) -> &mut Builder { self.config = self.config.overwrite(config); self } /// Set the syntax configuration for this builder using /// [`syntax::Config`](crate::util::syntax::Config). /// /// This permits setting things like case insensitivity, Unicode and multi /// line mode. /// /// These settings only apply when constructing a one-pass DFA directly /// from a pattern. #[cfg(feature = "syntax")] pub fn syntax( &mut self, config: crate::util::syntax::Config, ) -> &mut Builder { self.thompson.syntax(config); self } /// Set the Thompson NFA configuration for this builder using /// [`nfa::thompson::Config`](crate::nfa::thompson::Config). /// /// This permits setting things like whether additional time should be /// spent shrinking the size of the NFA. /// /// These settings only apply when constructing a DFA directly from a /// pattern. #[cfg(feature = "syntax")] pub fn thompson(&mut self, config: thompson::Config) -> &mut Builder { self.thompson.configure(config); self } } /// An internal builder for encapsulating the state necessary to build a /// one-pass DFA. Typical use is just `InternalBuilder::new(..).build()`. /// /// There is no separate pass for determining whether the NFA is one-pass or /// not. We just try to build the DFA. If during construction we discover that /// it is not one-pass, we bail out. This is likely to lead to some undesirable /// expense in some cases, so it might make sense to try an identify common /// patterns in the NFA that make it definitively not one-pass. That way, we /// can avoid ever trying to build a one-pass DFA in the first place. For /// example, '\w*\s' is not one-pass, and since '\w' is Unicode-aware by /// default, it's probably not a trivial cost to try and build a one-pass DFA /// for it and then fail. /// /// Note that some (immutable) fields are duplicated here. For example, the /// 'nfa' and 'classes' fields are both in the 'DFA'. They are the same thing, /// but we duplicate them because it makes composition easier below. Otherwise, /// since the borrow checker can't see through method calls, the mutable borrow /// we use to mutate the DFA winds up preventing borrowing from any other part /// of the DFA, even though we aren't mutating those parts. We only do this /// because the duplication is cheap. #[derive(Debug)] struct InternalBuilder<'a> { /// The DFA we're building. dfa: DFA, /// An unordered collection of NFA state IDs that we haven't yet tried to /// build into a DFA state yet. /// /// This collection does not ultimately wind up including every NFA state /// ID. Instead, each ID represents a "start" state for a sub-graph of the /// NFA. The set of NFA states we then use to build a DFA state consists /// of that "start" state and all states reachable from it via epsilon /// transitions. uncompiled_nfa_ids: Vec, /// A map from NFA state ID to DFA state ID. This is useful for easily /// determining whether an NFA state has been used as a "starting" point /// to build a DFA state yet. If it hasn't, then it is mapped to DEAD, /// and since DEAD is specially added and never corresponds to any NFA /// state, it follows that a mapping to DEAD implies the NFA state has /// no corresponding DFA state yet. nfa_to_dfa_id: Vec, /// A stack used to traverse the NFA states that make up a single DFA /// state. Traversal occurs until the stack is empty, and we only push to /// the stack when the state ID isn't in 'seen'. Actually, even more than /// that, if we try to push something on to this stack that is already in /// 'seen', then we bail out on construction completely, since it implies /// that the NFA is not one-pass. stack: Vec<(StateID, Epsilons)>, /// The set of NFA states that we've visited via 'stack'. seen: SparseSet, /// Whether a match NFA state has been observed while constructing a /// one-pass DFA state. Once a match state is seen, assuming we are using /// leftmost-first match semantics, then we don't add any more transitions /// to the DFA state we're building. matched: bool, /// The config passed to the builder. /// /// This is duplicated in dfa.config. config: Config, /// The NFA we're building a one-pass DFA from. /// /// This is duplicated in dfa.nfa. nfa: &'a NFA, /// The equivalence classes that make up the alphabet for this DFA> /// /// This is duplicated in dfa.classes. classes: ByteClasses, } impl<'a> InternalBuilder<'a> { /// Create a new builder with an initial empty DFA. fn new(config: Config, nfa: &'a NFA) -> InternalBuilder { let classes = if !config.get_byte_classes() { // A one-pass DFA will always use the equivalence class map, but // enabling this option is useful for debugging. Namely, this will // cause all transitions to be defined over their actual bytes // instead of an opaque equivalence class identifier. The former is // much easier to grok as a human. ByteClasses::singletons() } else { nfa.byte_classes().clone() }; // Normally a DFA alphabet includes the EOI symbol, but we don't need // that in the one-pass DFA since we handle look-around explicitly // without encoding it into the DFA. Thus, we don't need to delay // matches by 1 byte. However, we reuse the space that *would* be used // by the EOI transition by putting match information there (like which // pattern matches and which look-around assertions need to hold). So // this means our real alphabet length is 1 fewer than what the byte // classes report, since we don't use EOI. let alphabet_len = classes.alphabet_len().checked_sub(1).unwrap(); let stride2 = classes.stride2(); let dfa = DFA { config: config.clone(), nfa: nfa.clone(), table: vec![], starts: vec![], // Since one-pass DFAs have a smaller state ID max than // StateID::MAX, it follows that StateID::MAX is a valid initial // value for min_match_id since no state ID can ever be greater // than it. In the case of a one-pass DFA with no match states, the // min_match_id will keep this sentinel value. min_match_id: StateID::MAX, classes: classes.clone(), alphabet_len, stride2, pateps_offset: alphabet_len, // OK because PatternID::MAX*2 is guaranteed not to overflow. explicit_slot_start: nfa.pattern_len().checked_mul(2).unwrap(), }; InternalBuilder { dfa, uncompiled_nfa_ids: vec![], nfa_to_dfa_id: vec![DEAD; nfa.states().len()], stack: vec![], seen: SparseSet::new(nfa.states().len()), matched: false, config, nfa, classes, } } /// Build the DFA from the NFA given to this builder. If the NFA is not /// one-pass, then return an error. An error may also be returned if a /// particular limit is exceeded. (Some limits, like the total heap memory /// used, are configurable. Others, like the total patterns or slots, are /// hard-coded based on representational limitations.) fn build(mut self) -> Result { self.nfa.look_set_any().available().map_err(BuildError::word)?; for look in self.nfa.look_set_any().iter() { // This is a future incompatibility check where if we add any // more look-around assertions, then the one-pass DFA either // needs to reject them (what we do here) or it needs to have its // Transition representation modified to be capable of storing the // new assertions. if look.as_repr() > Look::WordUnicodeNegate.as_repr() { return Err(BuildError::unsupported_look(look)); } } if self.nfa.pattern_len().as_u64() > PatternEpsilons::PATTERN_ID_LIMIT { return Err(BuildError::too_many_patterns( PatternEpsilons::PATTERN_ID_LIMIT, )); } if self.nfa.group_info().explicit_slot_len() > Slots::LIMIT { return Err(BuildError::not_one_pass( "too many explicit capturing groups (max is 16)", )); } assert_eq!(DEAD, self.add_empty_state()?); // This is where the explicit slots start. We care about this because // we only need to track explicit slots. The implicit slots---two for // each pattern---are tracked as part of the search routine itself. let explicit_slot_start = self.nfa.pattern_len() * 2; self.add_start_state(None, self.nfa.start_anchored())?; if self.config.get_starts_for_each_pattern() { for pid in self.nfa.patterns() { self.add_start_state( Some(pid), self.nfa.start_pattern(pid).unwrap(), )?; } } // NOTE: One wonders what the effects of treating 'uncompiled_nfa_ids' // as a stack are. It is really an unordered *set* of NFA state IDs. // If it, for example, in practice led to discovering whether a regex // was or wasn't one-pass later than if we processed NFA state IDs in // ascending order, then that would make this routine more costly in // the somewhat common case of a regex that isn't one-pass. while let Some(nfa_id) = self.uncompiled_nfa_ids.pop() { let dfa_id = self.nfa_to_dfa_id[nfa_id]; // Once we see a match, we keep going, but don't add any new // transitions. Normally we'd just stop, but we have to keep // going in order to verify that our regex is actually one-pass. self.matched = false; // The NFA states we've already explored for this DFA state. self.seen.clear(); // The NFA states to explore via epsilon transitions. If we ever // try to push an NFA state that we've already seen, then the NFA // is not one-pass because it implies there are multiple epsilon // transition paths that lead to the same NFA state. In other // words, there is ambiguity. self.stack_push(nfa_id, Epsilons::empty())?; while let Some((id, epsilons)) = self.stack.pop() { match *self.nfa.state(id) { thompson::State::ByteRange { ref trans } => { self.compile_transition(dfa_id, trans, epsilons)?; } thompson::State::Sparse(ref sparse) => { for trans in sparse.transitions.iter() { self.compile_transition(dfa_id, trans, epsilons)?; } } thompson::State::Dense(ref dense) => { for trans in dense.iter() { self.compile_transition(dfa_id, &trans, epsilons)?; } } thompson::State::Look { look, next } => { let looks = epsilons.looks().insert(look); self.stack_push(next, epsilons.set_looks(looks))?; } thompson::State::Union { ref alternates } => { for &sid in alternates.iter().rev() { self.stack_push(sid, epsilons)?; } } thompson::State::BinaryUnion { alt1, alt2 } => { self.stack_push(alt2, epsilons)?; self.stack_push(alt1, epsilons)?; } thompson::State::Capture { next, slot, .. } => { let slot = slot.as_usize(); let epsilons = if slot < explicit_slot_start { // If this is an implicit slot, we don't care // about it, since we handle implicit slots in // the search routine. We can get away with that // because there are 2 implicit slots for every // pattern. epsilons } else { // Offset our explicit slots so that they start // at index 0. let offset = slot - explicit_slot_start; epsilons.set_slots(epsilons.slots().insert(offset)) }; self.stack_push(next, epsilons)?; } thompson::State::Fail => { continue; } thompson::State::Match { pattern_id } => { // If we found two different paths to a match state // for the same DFA state, then we have ambiguity. // Thus, it's not one-pass. if self.matched { return Err(BuildError::not_one_pass( "multiple epsilon transitions to match state", )); } self.matched = true; // Shove the matching pattern ID and the 'epsilons' // into the current DFA state's pattern epsilons. The // 'epsilons' includes the slots we need to capture // before reporting the match and also the conditional // epsilon transitions we need to check before we can // report a match. self.dfa.set_pattern_epsilons( dfa_id, PatternEpsilons::empty() .set_pattern_id(pattern_id) .set_epsilons(epsilons), ); // N.B. It is tempting to just bail out here when // compiling a leftmost-first DFA, since we will never // compile any more transitions in that case. But we // actually need to keep going in order to verify that // we actually have a one-pass regex. e.g., We might // see more Match states (e.g., for other patterns) // that imply that we don't have a one-pass regex. // So instead, we mark that we've found a match and // continue on. When we go to compile a new DFA state, // we just skip that part. But otherwise check that the // one-pass property is upheld. } } } } self.shuffle_states(); Ok(self.dfa) } /// Shuffle all match states to the end of the transition table and set /// 'min_match_id' to the ID of the first such match state. /// /// The point of this is to make it extremely cheap to determine whether /// a state is a match state or not. We need to check on this on every /// transition during a search, so it being cheap is important. This /// permits us to check it by simply comparing two state identifiers, as /// opposed to looking for the pattern ID in the state's `PatternEpsilons`. /// (Which requires a memory load and some light arithmetic.) fn shuffle_states(&mut self) { let mut remapper = Remapper::new(&self.dfa); let mut next_dest = self.dfa.last_state_id(); for i in (0..self.dfa.state_len()).rev() { let id = StateID::must(i); let is_match = self.dfa.pattern_epsilons(id).pattern_id().is_some(); if !is_match { continue; } remapper.swap(&mut self.dfa, next_dest, id); self.dfa.min_match_id = next_dest; next_dest = self.dfa.prev_state_id(next_dest).expect( "match states should be a proper subset of all states", ); } remapper.remap(&mut self.dfa); } /// Compile the given NFA transition into the DFA state given. /// /// 'Epsilons' corresponds to any conditional epsilon transitions that need /// to be satisfied to follow this transition, and any slots that need to /// be saved if the transition is followed. /// /// If this transition indicates that the NFA is not one-pass, then /// this returns an error. (This occurs, for example, if the DFA state /// already has a transition defined for the same input symbols as the /// given transition, *and* the result of the old and new transitions is /// different.) fn compile_transition( &mut self, dfa_id: StateID, trans: &thompson::Transition, epsilons: Epsilons, ) -> Result<(), BuildError> { let next_dfa_id = self.add_dfa_state_for_nfa_state(trans.next)?; for byte in self .classes .representatives(trans.start..=trans.end) .filter_map(|r| r.as_u8()) { let oldtrans = self.dfa.transition(dfa_id, byte); let newtrans = Transition::new(self.matched, next_dfa_id, epsilons); // If the old transition points to the DEAD state, then we know // 'byte' has not been mapped to any transition for this DFA state // yet. So set it unconditionally. Otherwise, we require that the // old and new transitions are equivalent. Otherwise, there is // ambiguity and thus the regex is not one-pass. if oldtrans.state_id() == DEAD { self.dfa.set_transition(dfa_id, byte, newtrans); } else if oldtrans != newtrans { return Err(BuildError::not_one_pass( "conflicting transition", )); } } Ok(()) } /// Add a start state to the DFA corresponding to the given NFA starting /// state ID. /// /// If adding a state would blow any limits (configured or hard-coded), /// then an error is returned. /// /// If the starting state is an anchored state for a particular pattern, /// then callers must provide the pattern ID for that starting state. /// Callers must also ensure that the first starting state added is the /// start state for all patterns, and then each anchored starting state for /// each pattern (if necessary) added in order. Otherwise, this panics. fn add_start_state( &mut self, pid: Option, nfa_id: StateID, ) -> Result { match pid { // With no pid, this should be the start state for all patterns // and thus be the first one. None => assert!(self.dfa.starts.is_empty()), // With a pid, we want it to be at self.dfa.starts[pid+1]. Some(pid) => assert!(self.dfa.starts.len() == pid.one_more()), } let dfa_id = self.add_dfa_state_for_nfa_state(nfa_id)?; self.dfa.starts.push(dfa_id); Ok(dfa_id) } /// Add a new DFA state corresponding to the given NFA state. If adding a /// state would blow any limits (configured or hard-coded), then an error /// is returned. If a DFA state already exists for the given NFA state, /// then that DFA state's ID is returned and no new states are added. /// /// It is not expected that this routine is called for every NFA state. /// Instead, an NFA state ID will usually correspond to the "start" state /// for a sub-graph of the NFA, where all states in the sub-graph are /// reachable via epsilon transitions (conditional or unconditional). That /// sub-graph of NFA states is ultimately what produces a single DFA state. fn add_dfa_state_for_nfa_state( &mut self, nfa_id: StateID, ) -> Result { // If we've already built a DFA state for the given NFA state, then // just return that. We definitely do not want to have more than one // DFA state in existence for the same NFA state, since all but one of // them will likely become unreachable. And at least some of them are // likely to wind up being incomplete. let existing_dfa_id = self.nfa_to_dfa_id[nfa_id]; if existing_dfa_id != DEAD { return Ok(existing_dfa_id); } // If we don't have any DFA state yet, add it and then add the given // NFA state to the list of states to explore. let dfa_id = self.add_empty_state()?; self.nfa_to_dfa_id[nfa_id] = dfa_id; self.uncompiled_nfa_ids.push(nfa_id); Ok(dfa_id) } /// Unconditionally add a new empty DFA state. If adding it would exceed /// any limits (configured or hard-coded), then an error is returned. The /// ID of the new state is returned on success. /// /// The added state is *not* a match state. fn add_empty_state(&mut self) -> Result { let state_limit = Transition::STATE_ID_LIMIT; // Note that unlike dense and lazy DFAs, we specifically do NOT // premultiply our state IDs here. The reason is that we want to pack // our state IDs into 64-bit transitions with other info, so the fewer // the bits we use for state IDs the better. If we premultiply, then // our state ID space shrinks. We justify this by the assumption that // a one-pass DFA is just already doing a fair bit more work than a // normal DFA anyway, so an extra multiplication to compute a state // transition doesn't seem like a huge deal. let next_id = self.dfa.table.len() >> self.dfa.stride2(); let id = StateID::new(next_id) .map_err(|_| BuildError::too_many_states(state_limit))?; if id.as_u64() > Transition::STATE_ID_LIMIT { return Err(BuildError::too_many_states(state_limit)); } self.dfa .table .extend(core::iter::repeat(Transition(0)).take(self.dfa.stride())); // The default empty value for 'PatternEpsilons' is sadly not all // zeroes. Instead, a special sentinel is used to indicate that there // is no pattern. So we need to explicitly set the pattern epsilons to // the correct "empty" PatternEpsilons. self.dfa.set_pattern_epsilons(id, PatternEpsilons::empty()); if let Some(size_limit) = self.config.get_size_limit() { if self.dfa.memory_usage() > size_limit { return Err(BuildError::exceeded_size_limit(size_limit)); } } Ok(id) } /// Push the given NFA state ID and its corresponding epsilons (slots and /// conditional epsilon transitions) on to a stack for use in a depth first /// traversal of a sub-graph of the NFA. /// /// If the given NFA state ID has already been pushed on to the stack, then /// it indicates the regex is not one-pass and this correspondingly returns /// an error. fn stack_push( &mut self, nfa_id: StateID, epsilons: Epsilons, ) -> Result<(), BuildError> { // If we already have seen a match and we are compiling a leftmost // first DFA, then we shouldn't add any more states to look at. This is // effectively how preference order and non-greediness is implemented. // if !self.config.get_match_kind().continue_past_first_match() // && self.matched // { // return Ok(()); // } if !self.seen.insert(nfa_id) { return Err(BuildError::not_one_pass( "multiple epsilon transitions to same state", )); } self.stack.push((nfa_id, epsilons)); Ok(()) } } /// A one-pass DFA for executing a subset of anchored regex searches while /// resolving capturing groups. /// /// A one-pass DFA can be built from an NFA that is one-pass. An NFA is /// one-pass when there is never any ambiguity about how to continue a search. /// For example, `a*a` is not one-pass becuase during a search, it's not /// possible to know whether to continue matching the `a*` or to move on to /// the single `a`. However, `a*b` is one-pass, because for every byte in the /// input, it's always clear when to move on from `a*` to `b`. /// /// # Only anchored searches are supported /// /// In this crate, especially for DFAs, unanchored searches are implemented by /// treating the pattern as if it had a `(?s-u:.)*?` prefix. While the prefix /// is one-pass on its own, adding anything after it, e.g., `(?s-u:.)*?a` will /// make the overall pattern not one-pass. Why? Because the `(?s-u:.)` matches /// any byte, and there is therefore ambiguity as to when the prefix should /// stop matching and something else should start matching. /// /// Therefore, one-pass DFAs do not support unanchored searches. In addition /// to many regexes simply not being one-pass, it implies that one-pass DFAs /// have limited utility. With that said, when a one-pass DFA can be used, it /// can potentially provide a dramatic speed up over alternatives like the /// [`BoundedBacktracker`](crate::nfa::thompson::backtrack::BoundedBacktracker) /// and the [`PikeVM`](crate::nfa::thompson::pikevm::PikeVM). In particular, /// a one-pass DFA is the only DFA capable of reporting the spans of matching /// capturing groups. /// /// To clarify, when we say that unanchored searches are not supported, what /// that actually means is: /// /// * The high level routines, [`DFA::is_match`] and [`DFA::captures`], always /// do anchored searches. /// * Since iterators are most useful in the context of unanchored searches, /// there is no `DFA::captures_iter` method. /// * For lower level routines like [`DFA::try_search`], an error will be /// returned if the given [`Input`] is configured to do an unanchored search or /// search for an invalid pattern ID. (Note that an [`Input`] is configured to /// do an unanchored search by default, so just giving a `Input::new` is /// guaranteed to return an error.) /// /// # Other limitations /// /// In addition to the [configurable heap limit](Config::size_limit) and /// the requirement that a regex pattern be one-pass, there are some other /// limitations: /// /// * There is an internal limit on the total number of explicit capturing /// groups that appear across all patterns. It is somewhat small and there is /// no way to configure it. If your pattern(s) exceed this limit, then building /// a one-pass DFA will fail. /// * If the number of patterns exceeds an internal unconfigurable limit, then /// building a one-pass DFA will fail. This limit is quite large and you're /// unlikely to hit it. /// * If the total number of states exceeds an internal unconfigurable limit, /// then building a one-pass DFA will fail. This limit is quite large and /// you're unlikely to hit it. /// /// # Other examples of regexes that aren't one-pass /// /// One particularly unfortunate example is that enabling Unicode can cause /// regexes that were one-pass to no longer be one-pass. Consider the regex /// `(?-u)\w*\s` for example. It is one-pass because there is exactly no /// overlap between the ASCII definitions of `\w` and `\s`. But `\w*\s` /// (i.e., with Unicode enabled) is *not* one-pass because `\w` and `\s` get /// translated to UTF-8 automatons. And while the *codepoints* in `\w` and `\s` /// do not overlap, the underlying UTF-8 encodings do. Indeed, because of the /// overlap between UTF-8 automata, the use of Unicode character classes will /// tend to vastly increase the likelihood of a regex not being one-pass. /// /// # How does one know if a regex is one-pass or not? /// /// At the time of writing, the only way to know is to try and build a one-pass /// DFA. The one-pass property is checked while constructing the DFA. /// /// This does mean that you might potentially waste some CPU cycles and memory /// by optimistically trying to build a one-pass DFA. But this is currently the /// only way. In the future, building a one-pass DFA might be able to use some /// heuristics to detect common violations of the one-pass property and bail /// more quickly. /// /// # Resource usage /// /// Unlike a general DFA, a one-pass DFA has stricter bounds on its resource /// usage. Namely, construction of a one-pass DFA has a time and space /// complexity of `O(n)`, where `n ~ nfa.states().len()`. (A general DFA's time /// and space complexity is `O(2^n)`.) This smaller time bound is achieved /// because there is at most one DFA state created for each NFA state. If /// additional DFA states would be required, then the pattern is not one-pass /// and construction will fail. /// /// Note though that currently, this DFA uses a fully dense representation. /// This means that while its space complexity is no worse than an NFA, it may /// in practice use more memory because of higher constant factors. The reason /// for this trade off is two-fold. Firstly, a dense representation makes the /// search faster. Secondly, the bigger an NFA, the more unlikely it is to be /// one-pass. Therefore, most one-pass DFAs are usually pretty small. /// /// # Example /// /// This example shows that the one-pass DFA implements Unicode word boundaries /// correctly while simultaneously reporting spans for capturing groups that /// participate in a match. (This is the only DFA that implements full support /// for Unicode word boundaries.) /// /// ``` /// # if cfg!(miri) { return Ok(()); } // miri takes too long /// use regex_automata::{dfa::onepass::DFA, Match, Span}; /// /// let re = DFA::new(r"\b(?P\w+)[[:space:]]+(?P\w+)\b")?; /// let (mut cache, mut caps) = (re.create_cache(), re.create_captures()); /// /// re.captures(&mut cache, "Шерлок Холмс", &mut caps); /// assert_eq!(Some(Match::must(0, 0..23)), caps.get_match()); /// assert_eq!(Some(Span::from(0..12)), caps.get_group_by_name("first")); /// assert_eq!(Some(Span::from(13..23)), caps.get_group_by_name("last")); /// # Ok::<(), Box>(()) /// ``` /// /// # Example: iteration /// /// Unlike other regex engines in this crate, this one does not provide /// iterator search functions. This is because a one-pass DFA only supports /// anchored searches, and so iterator functions are generally not applicable. /// /// However, if you know that all of your matches are /// directly adjacent, then an iterator can be used. The /// [`util::iter::Searcher`](crate::util::iter::Searcher) type can be used for /// this purpose: /// /// ``` /// # if cfg!(miri) { return Ok(()); } // miri takes too long /// use regex_automata::{ /// dfa::onepass::DFA, /// util::iter::Searcher, /// Anchored, Input, Span, /// }; /// /// let re = DFA::new(r"\w(\d)\w")?; /// let (mut cache, caps) = (re.create_cache(), re.create_captures()); /// let input = Input::new("a1zb2yc3x").anchored(Anchored::Yes); /// /// let mut it = Searcher::new(input).into_captures_iter(caps, |input, caps| { /// Ok(re.try_search(&mut cache, input, caps)?) /// }).infallible(); /// let caps0 = it.next().unwrap(); /// assert_eq!(Some(Span::from(1..2)), caps0.get_group(1)); /// /// # Ok::<(), Box>(()) /// ``` #[derive(Clone)] pub struct DFA { /// The configuration provided by the caller. config: Config, /// The NFA used to build this DFA. /// /// NOTE: We probably don't need to store the NFA here, but we use enough /// bits from it that it's convenient to do so. And there really isn't much /// cost to doing so either, since an NFA is reference counted internally. nfa: NFA, /// The transition table. Given a state ID 's' and a byte of haystack 'b', /// the next state is `table[sid + classes[byte]]`. /// /// The stride of this table (i.e., the number of columns) is always /// a power of 2, even if the alphabet length is smaller. This makes /// converting between state IDs and state indices very cheap. /// /// Note that the stride always includes room for one extra "transition" /// that isn't actually a transition. It is a 'PatternEpsilons' that is /// used for match states only. Because of this, the maximum number of /// active columns in the transition table is 257, which means the maximum /// stride is 512 (the next power of 2 greater than or equal to 257). table: Vec, /// The DFA state IDs of the starting states. /// /// `starts[0]` is always present and corresponds to the starting state /// when searching for matches of any pattern in the DFA. /// /// `starts[i]` where i>0 corresponds to the starting state for the pattern /// ID 'i-1'. These starting states are optional. starts: Vec, /// Every state ID >= this value corresponds to a match state. /// /// This is what a search uses to detect whether a state is a match state /// or not. It requires only a simple comparison instead of bit-unpacking /// the PatternEpsilons from every state. min_match_id: StateID, /// The alphabet of this DFA, split into equivalence classes. Bytes in the /// same equivalence class can never discriminate between a match and a /// non-match. classes: ByteClasses, /// The number of elements in each state in the transition table. This may /// be less than the stride, since the stride is always a power of 2 and /// the alphabet length can be anything up to and including 256. alphabet_len: usize, /// The number of columns in the transition table, expressed as a power of /// 2. stride2: usize, /// The offset at which the PatternEpsilons for a match state is stored in /// the transition table. /// /// PERF: One wonders whether it would be better to put this in a separate /// allocation, since only match states have a non-empty PatternEpsilons /// and the number of match states tends be dwarfed by the number of /// non-match states. So this would save '8*len(non_match_states)' for each /// DFA. The question is whether moving this to a different allocation will /// lead to a perf hit during searches. You might think dealing with match /// states is rare, but some regexes spend a lot of time in match states /// gobbling up input. But... match state handling is already somewhat /// expensive, so maybe this wouldn't do much? Either way, it's worth /// experimenting. pateps_offset: usize, /// The first explicit slot index. This refers to the first slot appearing /// immediately after the last implicit slot. It is always 'patterns.len() /// * 2'. /// /// We record this because we only store the explicit slots in our DFA /// transition table that need to be saved. Implicit slots are handled /// automatically as part of the search. explicit_slot_start: usize, } impl DFA { /// Parse the given regular expression using the default configuration and /// return the corresponding one-pass DFA. /// /// If you want a non-default configuration, then use the [`Builder`] to /// set your own configuration. /// /// # Example /// /// ``` /// use regex_automata::{dfa::onepass::DFA, Match}; /// /// let re = DFA::new("foo[0-9]+bar")?; /// let (mut cache, mut caps) = (re.create_cache(), re.create_captures()); /// /// re.captures(&mut cache, "foo12345barzzz", &mut caps); /// assert_eq!(Some(Match::must(0, 0..11)), caps.get_match()); /// # Ok::<(), Box>(()) /// ``` #[cfg(feature = "syntax")] #[inline] pub fn new(pattern: &str) -> Result { DFA::builder().build(pattern) } /// Like `new`, but parses multiple patterns into a single "multi regex." /// This similarly uses the default regex configuration. /// /// # Example /// /// ``` /// use regex_automata::{dfa::onepass::DFA, Match}; /// /// let re = DFA::new_many(&["[a-z]+", "[0-9]+"])?; /// let (mut cache, mut caps) = (re.create_cache(), re.create_captures()); /// /// re.captures(&mut cache, "abc123", &mut caps); /// assert_eq!(Some(Match::must(0, 0..3)), caps.get_match()); /// /// re.captures(&mut cache, "123abc", &mut caps); /// assert_eq!(Some(Match::must(1, 0..3)), caps.get_match()); /// /// # Ok::<(), Box>(()) /// ``` #[cfg(feature = "syntax")] #[inline] pub fn new_many>(patterns: &[P]) -> Result { DFA::builder().build_many(patterns) } /// Like `new`, but builds a one-pass DFA directly from an NFA. This is /// useful if you already have an NFA, or even if you hand-assembled the /// NFA. /// /// # Example /// /// This shows how to hand assemble a regular expression via its HIR, /// compile an NFA from it and build a one-pass DFA from the NFA. /// /// ``` /// use regex_automata::{ /// dfa::onepass::DFA, /// nfa::thompson::NFA, /// Match, /// }; /// use regex_syntax::hir::{Hir, Class, ClassBytes, ClassBytesRange}; /// /// let hir = Hir::class(Class::Bytes(ClassBytes::new(vec![ /// ClassBytesRange::new(b'0', b'9'), /// ClassBytesRange::new(b'A', b'Z'), /// ClassBytesRange::new(b'_', b'_'), /// ClassBytesRange::new(b'a', b'z'), /// ]))); /// /// let config = NFA::config().nfa_size_limit(Some(1_000)); /// let nfa = NFA::compiler().configure(config).build_from_hir(&hir)?; /// /// let re = DFA::new_from_nfa(nfa)?; /// let (mut cache, mut caps) = (re.create_cache(), re.create_captures()); /// let expected = Some(Match::must(0, 0..1)); /// re.captures(&mut cache, "A", &mut caps); /// assert_eq!(expected, caps.get_match()); /// /// # Ok::<(), Box>(()) /// ``` pub fn new_from_nfa(nfa: NFA) -> Result { DFA::builder().build_from_nfa(nfa) } /// Create a new one-pass DFA that matches every input. /// /// # Example /// /// ``` /// use regex_automata::{dfa::onepass::DFA, Match}; /// /// let dfa = DFA::always_match()?; /// let mut cache = dfa.create_cache(); /// let mut caps = dfa.create_captures(); /// /// let expected = Match::must(0, 0..0); /// dfa.captures(&mut cache, "", &mut caps); /// assert_eq!(Some(expected), caps.get_match()); /// dfa.captures(&mut cache, "foo", &mut caps); /// assert_eq!(Some(expected), caps.get_match()); /// # Ok::<(), Box>(()) /// ``` pub fn always_match() -> Result { let nfa = thompson::NFA::always_match(); Builder::new().build_from_nfa(nfa) } /// Create a new one-pass DFA that never matches any input. /// /// # Example /// /// ``` /// use regex_automata::dfa::onepass::DFA; /// /// let dfa = DFA::never_match()?; /// let mut cache = dfa.create_cache(); /// let mut caps = dfa.create_captures(); /// /// dfa.captures(&mut cache, "", &mut caps); /// assert_eq!(None, caps.get_match()); /// dfa.captures(&mut cache, "foo", &mut caps); /// assert_eq!(None, caps.get_match()); /// # Ok::<(), Box>(()) /// ``` pub fn never_match() -> Result { let nfa = thompson::NFA::never_match(); Builder::new().build_from_nfa(nfa) } /// Return a default configuration for a DFA. /// /// This is a convenience routine to avoid needing to import the `Config` /// type when customizing the construction of a DFA. /// /// # Example /// /// This example shows how to change the match semantics of this DFA from /// its default "leftmost first" to "all." When using "all," non-greediness /// doesn't apply and neither does preference order matching. Instead, the /// longest match possible is always returned. (Although, by construction, /// it's impossible for a one-pass DFA to have a different answer for /// "preference order" vs "longest match.") /// /// ``` /// use regex_automata::{dfa::onepass::DFA, Match, MatchKind}; /// /// let re = DFA::builder() /// .configure(DFA::config().match_kind(MatchKind::All)) /// .build(r"(abc)+?")?; /// let mut cache = re.create_cache(); /// let mut caps = re.create_captures(); /// /// re.captures(&mut cache, "abcabc", &mut caps); /// // Normally, the non-greedy repetition would give us a 0..3 match. /// assert_eq!(Some(Match::must(0, 0..6)), caps.get_match()); /// # Ok::<(), Box>(()) /// ``` #[inline] pub fn config() -> Config { Config::new() } /// Return a builder for configuring the construction of a DFA. /// /// This is a convenience routine to avoid needing to import the /// [`Builder`] type in common cases. /// /// # Example /// /// This example shows how to use the builder to disable UTF-8 mode. /// /// ``` /// # if cfg!(miri) { return Ok(()); } // miri takes too long /// use regex_automata::{ /// dfa::onepass::DFA, /// nfa::thompson, /// util::syntax, /// Match, /// }; /// /// let re = DFA::builder() /// .syntax(syntax::Config::new().utf8(false)) /// .thompson(thompson::Config::new().utf8(false)) /// .build(r"foo(?-u:[^b])ar.*")?; /// let (mut cache, mut caps) = (re.create_cache(), re.create_captures()); /// /// let haystack = b"foo\xFFarzz\xE2\x98\xFF\n"; /// let expected = Some(Match::must(0, 0..8)); /// re.captures(&mut cache, haystack, &mut caps); /// assert_eq!(expected, caps.get_match()); /// /// # Ok::<(), Box>(()) /// ``` #[inline] pub fn builder() -> Builder { Builder::new() } /// Create a new empty set of capturing groups that is guaranteed to be /// valid for the search APIs on this DFA. /// /// A `Captures` value created for a specific DFA cannot be used with any /// other DFA. /// /// This is a convenience function for [`Captures::all`]. See the /// [`Captures`] documentation for an explanation of its alternative /// constructors that permit the DFA to do less work during a search, and /// thus might make it faster. #[inline] pub fn create_captures(&self) -> Captures { Captures::all(self.nfa.group_info().clone()) } /// Create a new cache for this DFA. /// /// The cache returned should only be used for searches for this /// DFA. If you want to reuse the cache for another DFA, then you /// must call [`Cache::reset`] with that DFA (or, equivalently, /// [`DFA::reset_cache`]). #[inline] pub fn create_cache(&self) -> Cache { Cache::new(self) } /// Reset the given cache such that it can be used for searching with the /// this DFA (and only this DFA). /// /// A cache reset permits reusing memory already allocated in this cache /// with a different DFA. /// /// # Example /// /// This shows how to re-purpose a cache for use with a different DFA. /// /// ``` /// # if cfg!(miri) { return Ok(()); } // miri takes too long /// use regex_automata::{dfa::onepass::DFA, Match}; /// /// let re1 = DFA::new(r"\w")?; /// let re2 = DFA::new(r"\W")?; /// let mut caps1 = re1.create_captures(); /// let mut caps2 = re2.create_captures(); /// /// let mut cache = re1.create_cache(); /// assert_eq!( /// Some(Match::must(0, 0..2)), /// { re1.captures(&mut cache, "Δ", &mut caps1); caps1.get_match() }, /// ); /// /// // Using 'cache' with re2 is not allowed. It may result in panics or /// // incorrect results. In order to re-purpose the cache, we must reset /// // it with the one-pass DFA we'd like to use it with. /// // /// // Similarly, after this reset, using the cache with 're1' is also not /// // allowed. /// re2.reset_cache(&mut cache); /// assert_eq!( /// Some(Match::must(0, 0..3)), /// { re2.captures(&mut cache, "☃", &mut caps2); caps2.get_match() }, /// ); /// /// # Ok::<(), Box>(()) /// ``` #[inline] pub fn reset_cache(&self, cache: &mut Cache) { cache.reset(self); } /// Return the config for this one-pass DFA. #[inline] pub fn get_config(&self) -> &Config { &self.config } /// Returns a reference to the underlying NFA. #[inline] pub fn get_nfa(&self) -> &NFA { &self.nfa } /// Returns the total number of patterns compiled into this DFA. /// /// In the case of a DFA that contains no patterns, this returns `0`. #[inline] pub fn pattern_len(&self) -> usize { self.get_nfa().pattern_len() } /// Returns the total number of states in this one-pass DFA. /// /// Note that unlike dense or sparse DFAs, a one-pass DFA does not expose /// a low level DFA API. Therefore, this routine has little use other than /// being informational. #[inline] pub fn state_len(&self) -> usize { self.table.len() >> self.stride2() } /// Returns the total number of elements in the alphabet for this DFA. /// /// That is, this returns the total number of transitions that each /// state in this DFA must have. The maximum alphabet size is 256, which /// corresponds to each possible byte value. /// /// The alphabet size may be less than 256 though, and unless /// [`Config::byte_classes`] is disabled, it is typically must less than /// 256. Namely, bytes are grouped into equivalence classes such that no /// two bytes in the same class can distinguish a match from a non-match. /// For example, in the regex `^[a-z]+$`, the ASCII bytes `a-z` could /// all be in the same equivalence class. This leads to a massive space /// savings. /// /// Note though that the alphabet length does _not_ necessarily equal the /// total stride space taken up by a single DFA state in the transition /// table. Namely, for performance reasons, the stride is always the /// smallest power of two that is greater than or equal to the alphabet /// length. For this reason, [`DFA::stride`] or [`DFA::stride2`] are /// often more useful. The alphabet length is typically useful only for /// informational purposes. /// /// Note also that unlike dense or sparse DFAs, a one-pass DFA does /// not have a special end-of-input (EOI) transition. This is because /// a one-pass DFA handles look-around assertions explicitly (like the /// [`PikeVM`](crate::nfa::thompson::pikevm::PikeVM)) and does not build /// them into the transitions of the DFA. #[inline] pub fn alphabet_len(&self) -> usize { self.alphabet_len } /// Returns the total stride for every state in this DFA, expressed as the /// exponent of a power of 2. The stride is the amount of space each state /// takes up in the transition table, expressed as a number of transitions. /// (Unused transitions map to dead states.) /// /// The stride of a DFA is always equivalent to the smallest power of /// 2 that is greater than or equal to the DFA's alphabet length. This /// definition uses extra space, but possibly permits faster translation /// between state identifiers and their corresponding offsets in this DFA's /// transition table. /// /// For example, if the DFA's stride is 16 transitions, then its `stride2` /// is `4` since `2^4 = 16`. /// /// The minimum `stride2` value is `1` (corresponding to a stride of `2`) /// while the maximum `stride2` value is `9` (corresponding to a stride /// of `512`). The maximum in theory should be `8`, but because of some /// implementation quirks that may be relaxed in the future, it is one more /// than `8`. (Do note that a maximal stride is incredibly rare, as it /// would imply that there is almost no redundant in the regex pattern.) /// /// Note that unlike dense or sparse DFAs, a one-pass DFA does not expose /// a low level DFA API. Therefore, this routine has little use other than /// being informational. #[inline] pub fn stride2(&self) -> usize { self.stride2 } /// Returns the total stride for every state in this DFA. This corresponds /// to the total number of transitions used by each state in this DFA's /// transition table. /// /// Please see [`DFA::stride2`] for more information. In particular, this /// returns the stride as the number of transitions, where as `stride2` /// returns it as the exponent of a power of 2. /// /// Note that unlike dense or sparse DFAs, a one-pass DFA does not expose /// a low level DFA API. Therefore, this routine has little use other than /// being informational. #[inline] pub fn stride(&self) -> usize { 1 << self.stride2() } /// Returns the memory usage, in bytes, of this DFA. /// /// The memory usage is computed based on the number of bytes used to /// represent this DFA. /// /// This does **not** include the stack size used up by this DFA. To /// compute that, use `std::mem::size_of::()`. #[inline] pub fn memory_usage(&self) -> usize { use core::mem::size_of; self.table.len() * size_of::() + self.starts.len() * size_of::() } } impl DFA { /// Executes an anchored leftmost forward search, and returns true if and /// only if this one-pass DFA matches the given haystack. /// /// 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, then this routine will return /// `true` immediately without inspecting any future input. (Consider how /// this might make a difference given the regex `a+` on the haystack /// `aaaaaaaaaaaaaaa`. This routine can stop after it sees the first `a`, /// but routines like `find` need to continue searching because `+` is /// greedy by default.) /// /// The given `Input` is forcefully set to use [`Anchored::Yes`] if the /// given configuration was [`Anchored::No`] (which is the default). /// /// # Panics /// /// This routine panics if the search could not complete. This can occur /// in the following circumstances: /// /// * When the provided `Input` configuration is not supported. For /// example, by providing an unsupported anchor mode. Concretely, /// this occurs when using [`Anchored::Pattern`] without enabling /// [`Config::starts_for_each_pattern`]. /// /// When a search panics, callers cannot know whether a match exists or /// not. /// /// Use [`DFA::try_search`] if you want to handle these panics as error /// values instead. /// /// # Example /// /// This shows basic usage: /// /// ``` /// use regex_automata::dfa::onepass::DFA; /// /// let re = DFA::new("foo[0-9]+bar")?; /// let mut cache = re.create_cache(); /// /// assert!(re.is_match(&mut cache, "foo12345bar")); /// assert!(!re.is_match(&mut cache, "foobar")); /// # Ok::<(), Box>(()) /// ``` /// /// # Example: consistency with search APIs /// /// `is_match` is guaranteed to return `true` whenever `captures` returns /// a match. This includes searches that are executed entirely within a /// codepoint: /// /// ``` /// use regex_automata::{dfa::onepass::DFA, Input}; /// /// let re = DFA::new("a*")?; /// let mut cache = re.create_cache(); /// /// assert!(!re.is_match(&mut cache, Input::new("☃").span(1..2))); /// # Ok::<(), Box>(()) /// ``` /// /// Notice that when UTF-8 mode is disabled, then the above reports a /// match because the restriction against zero-width matches that split a /// codepoint has been lifted: /// /// ``` /// use regex_automata::{dfa::onepass::DFA, nfa::thompson::NFA, Input}; /// /// let re = DFA::builder() /// .thompson(NFA::config().utf8(false)) /// .build("a*")?; /// let mut cache = re.create_cache(); /// /// assert!(re.is_match(&mut cache, Input::new("☃").span(1..2))); /// # Ok::<(), Box>(()) /// ``` #[inline] pub fn is_match<'h, I: Into>>( &self, cache: &mut Cache, input: I, ) -> bool { let mut input = input.into().earliest(true); if matches!(input.get_anchored(), Anchored::No) { input.set_anchored(Anchored::Yes); } self.try_search_slots(cache, &input, &mut []).unwrap().is_some() } /// Executes an anchored leftmost forward search, and returns a `Match` if /// and only if this one-pass DFA matches the given haystack. /// /// This routine only includes the overall match span. To get access to the /// individual spans of each capturing group, use [`DFA::captures`]. /// /// The given `Input` is forcefully set to use [`Anchored::Yes`] if the /// given configuration was [`Anchored::No`] (which is the default). /// /// # Panics /// /// This routine panics if the search could not complete. This can occur /// in the following circumstances: /// /// * When the provided `Input` configuration is not supported. For /// example, by providing an unsupported anchor mode. Concretely, /// this occurs when using [`Anchored::Pattern`] without enabling /// [`Config::starts_for_each_pattern`]. /// /// When a search panics, callers cannot know whether a match exists or /// not. /// /// Use [`DFA::try_search`] if you want to handle these panics as error /// values instead. /// /// # Example /// /// Leftmost first match semantics 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. (This crate does not currently support /// leftmost longest semantics.) /// /// ``` /// use regex_automata::{dfa::onepass::DFA, Match}; /// /// let re = DFA::new("foo[0-9]+")?; /// let mut cache = re.create_cache(); /// let expected = Match::must(0, 0..8); /// assert_eq!(Some(expected), re.find(&mut cache, "foo12345")); /// /// // 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 later parts. /// let re = DFA::new("abc|a")?; /// let mut cache = re.create_cache(); /// let expected = Match::must(0, 0..3); /// assert_eq!(Some(expected), re.find(&mut cache, "abc")); /// /// # Ok::<(), Box>(()) /// ``` #[inline] pub fn find<'h, I: Into>>( &self, cache: &mut Cache, input: I, ) -> Option { let mut input = input.into(); if matches!(input.get_anchored(), Anchored::No) { input.set_anchored(Anchored::Yes); } if self.get_nfa().pattern_len() == 1 { let mut slots = [None, None]; let pid = self.try_search_slots(cache, &input, &mut slots).unwrap()?; let start = slots[0].unwrap().get(); let end = slots[1].unwrap().get(); return Some(Match::new(pid, Span { start, end })); } let ginfo = self.get_nfa().group_info(); let slots_len = ginfo.implicit_slot_len(); let mut slots = vec![None; slots_len]; let pid = self.try_search_slots(cache, &input, &mut slots).unwrap()?; let start = slots[pid.as_usize() * 2].unwrap().get(); let end = slots[pid.as_usize() * 2 + 1].unwrap().get(); Some(Match::new(pid, Span { start, end })) } /// Executes an anchored leftmost forward search and writes the spans /// of capturing groups that participated in a match into the provided /// [`Captures`] value. If no match was found, then [`Captures::is_match`] /// is guaranteed to return `false`. /// /// The given `Input` is forcefully set to use [`Anchored::Yes`] if the /// given configuration was [`Anchored::No`] (which is the default). /// /// # Panics /// /// This routine panics if the search could not complete. This can occur /// in the following circumstances: /// /// * When the provided `Input` configuration is not supported. For /// example, by providing an unsupported anchor mode. Concretely, /// this occurs when using [`Anchored::Pattern`] without enabling /// [`Config::starts_for_each_pattern`]. /// /// When a search panics, callers cannot know whether a match exists or /// not. /// /// Use [`DFA::try_search`] if you want to handle these panics as error /// values instead. /// /// # Example /// /// This shows a simple example of a one-pass regex that extracts /// capturing group spans. /// /// ``` /// use regex_automata::{dfa::onepass::DFA, Match, Span}; /// /// let re = DFA::new( /// // Notice that we use ASCII here. The corresponding Unicode regex /// // is sadly not one-pass. /// "(?P[[:alpha:]]+)[[:space:]]+(?P[[:alpha:]]+)", /// )?; /// let (mut cache, mut caps) = (re.create_cache(), re.create_captures()); /// /// re.captures(&mut cache, "Bruce Springsteen", &mut caps); /// assert_eq!(Some(Match::must(0, 0..17)), caps.get_match()); /// assert_eq!(Some(Span::from(0..5)), caps.get_group(1)); /// assert_eq!(Some(Span::from(6..17)), caps.get_group_by_name("last")); /// /// # Ok::<(), Box>(()) /// ``` #[inline] pub fn captures<'h, I: Into>>( &self, cache: &mut Cache, input: I, caps: &mut Captures, ) { let mut input = input.into(); if matches!(input.get_anchored(), Anchored::No) { input.set_anchored(Anchored::Yes); } self.try_search(cache, &input, caps).unwrap(); } /// Executes an anchored leftmost forward search and writes the spans /// of capturing groups that participated in a match into the provided /// [`Captures`] value. If no match was found, then [`Captures::is_match`] /// is guaranteed to return `false`. /// /// The differences with [`DFA::captures`] are: /// /// 1. This returns an error instead of panicking if the search fails. /// 2. Accepts an `&Input` instead of a `Into`. This permits reusing /// the same input for multiple searches, which _may_ be important for /// latency. /// 3. This does not automatically change the [`Anchored`] mode from `No` /// to `Yes`. Instead, if [`Input::anchored`] is `Anchored::No`, then an /// error is returned. /// /// # Errors /// /// This routine errors if the search could not complete. This can occur /// in the following circumstances: /// /// * When the provided `Input` configuration is not supported. For /// example, by providing an unsupported anchor mode. Concretely, /// this occurs when using [`Anchored::Pattern`] without enabling /// [`Config::starts_for_each_pattern`]. /// /// When a search returns an error, callers cannot know whether a match /// exists or not. /// /// # Example: specific pattern search /// /// This example shows how to build a multi-regex that permits searching /// for specific patterns. Note that this is somewhat less useful than /// in other regex engines, since a one-pass DFA by definition has no /// ambiguity about which pattern can match at a position. That is, if it /// were possible for two different patterns to match at the same starting /// position, then the multi-regex would not be one-pass and construction /// would have failed. /// /// Nevertheless, this can still be useful if you only care about matches /// for a specific pattern, and want the DFA to report "no match" even if /// some other pattern would have matched. /// /// Note that in order to make use of this functionality, /// [`Config::starts_for_each_pattern`] must be enabled. It is disabled /// by default since it may result in higher memory usage. /// /// ``` /// use regex_automata::{ /// dfa::onepass::DFA, Anchored, Input, Match, PatternID, /// }; /// /// let re = DFA::builder() /// .configure(DFA::config().starts_for_each_pattern(true)) /// .build_many(&["[a-z]+", "[0-9]+"])?; /// let (mut cache, mut caps) = (re.create_cache(), re.create_captures()); /// let haystack = "123abc"; /// let input = Input::new(haystack).anchored(Anchored::Yes); /// /// // A normal multi-pattern search will show pattern 1 matches. /// re.try_search(&mut cache, &input, &mut caps)?; /// assert_eq!(Some(Match::must(1, 0..3)), caps.get_match()); /// /// // If we only want to report pattern 0 matches, then we'll get no /// // match here. /// let input = input.anchored(Anchored::Pattern(PatternID::must(0))); /// re.try_search(&mut cache, &input, &mut caps)?; /// assert_eq!(None, caps.get_match()); /// /// # Ok::<(), Box>(()) /// ``` /// /// # Example: specifying the bounds of a search /// /// This example shows how providing the bounds of a search can produce /// different results than simply sub-slicing the haystack. /// /// ``` /// # if cfg!(miri) { return Ok(()); } // miri takes too long /// use regex_automata::{dfa::onepass::DFA, Anchored, Input, Match}; /// /// // one-pass DFAs fully support Unicode word boundaries! /// // A sad joke is that a Unicode aware regex like \w+\s is not one-pass. /// // :-( /// let re = DFA::new(r"\b[0-9]{3}\b")?; /// let (mut cache, mut caps) = (re.create_cache(), re.create_captures()); /// let haystack = "foo123bar"; /// /// // Since we sub-slice the haystack, the search doesn't know about /// // the larger context and assumes that `123` is surrounded by word /// // boundaries. And of course, the match position is reported relative /// // to the sub-slice as well, which means we get `0..3` instead of /// // `3..6`. /// let expected = Some(Match::must(0, 0..3)); /// let input = Input::new(&haystack[3..6]).anchored(Anchored::Yes); /// re.try_search(&mut cache, &input, &mut caps)?; /// assert_eq!(expected, caps.get_match()); /// /// // But if we provide the bounds of the search within the context of the /// // entire haystack, then the search can take the surrounding context /// // into account. (And if we did find a match, it would be reported /// // as a valid offset into `haystack` instead of its sub-slice.) /// let expected = None; /// let input = Input::new(haystack).range(3..6).anchored(Anchored::Yes); /// re.try_search(&mut cache, &input, &mut caps)?; /// assert_eq!(expected, caps.get_match()); /// /// # Ok::<(), Box>(()) /// ``` #[inline] pub fn try_search( &self, cache: &mut Cache, input: &Input<'_>, caps: &mut Captures, ) -> Result<(), MatchError> { let pid = self.try_search_slots(cache, input, caps.slots_mut())?; caps.set_pattern(pid); Ok(()) } /// Executes an anchored leftmost forward search and writes the spans /// of capturing groups that participated in a match into the provided /// `slots`, and returns the matching pattern ID. The contents of the /// slots for patterns other than the matching pattern are unspecified. If /// no match was found, then `None` is returned and the contents of all /// `slots` is unspecified. /// /// This is like [`DFA::try_search`], but it accepts a raw slots slice /// instead of a `Captures` value. This is useful in contexts where you /// don't want or need to allocate a `Captures`. /// /// It is legal to pass _any_ number of slots to this routine. If the regex /// engine would otherwise write a slot offset that doesn't fit in the /// provided slice, then it is simply skipped. In general though, there are /// usually three slice lengths you might want to use: /// /// * An empty slice, if you only care about which pattern matched. /// * A slice with /// [`pattern_len() * 2`](crate::dfa::onepass::DFA::pattern_len) /// slots, if you only care about the overall match spans for each matching /// pattern. /// * A slice with /// [`slot_len()`](crate::util::captures::GroupInfo::slot_len) slots, which /// permits recording match offsets for every capturing group in every /// pattern. /// /// # Errors /// /// This routine errors if the search could not complete. This can occur /// in the following circumstances: /// /// * When the provided `Input` configuration is not supported. For /// example, by providing an unsupported anchor mode. Concretely, /// this occurs when using [`Anchored::Pattern`] without enabling /// [`Config::starts_for_each_pattern`]. /// /// When a search returns an error, callers cannot know whether a match /// exists or not. /// /// # Example /// /// This example shows how to find the overall match offsets in a /// multi-pattern search without allocating a `Captures` value. Indeed, we /// can put our slots right on the stack. /// /// ``` /// use regex_automata::{dfa::onepass::DFA, Anchored, Input, PatternID}; /// /// let re = DFA::new_many(&[ /// r"[a-zA-Z]+", /// r"[0-9]+", /// ])?; /// let mut cache = re.create_cache(); /// let input = Input::new("123").anchored(Anchored::Yes); /// /// // We only care about the overall match offsets here, so we just /// // allocate two slots for each pattern. Each slot records the start /// // and end of the match. /// let mut slots = [None; 4]; /// let pid = re.try_search_slots(&mut cache, &input, &mut slots)?; /// assert_eq!(Some(PatternID::must(1)), pid); /// /// // The overall match offsets are always at 'pid * 2' and 'pid * 2 + 1'. /// // See 'GroupInfo' for more details on the mapping between groups and /// // slot indices. /// let slot_start = pid.unwrap().as_usize() * 2; /// let slot_end = slot_start + 1; /// assert_eq!(Some(0), slots[slot_start].map(|s| s.get())); /// assert_eq!(Some(3), slots[slot_end].map(|s| s.get())); /// /// # Ok::<(), Box>(()) /// ``` #[inline] pub fn try_search_slots( &self, cache: &mut Cache, input: &Input<'_>, slots: &mut [Option], ) -> Result, MatchError> { let utf8empty = self.get_nfa().has_empty() && self.get_nfa().is_utf8(); if !utf8empty { return self.try_search_slots_imp(cache, input, slots); } // See PikeVM::try_search_slots for why we do this. let min = self.get_nfa().group_info().implicit_slot_len(); if slots.len() >= min { return self.try_search_slots_imp(cache, input, slots); } if self.get_nfa().pattern_len() == 1 { let mut enough = [None, None]; let got = self.try_search_slots_imp(cache, input, &mut enough)?; // This is OK because we know `enough_slots` is strictly bigger // than `slots`, otherwise this special case isn't reached. slots.copy_from_slice(&enough[..slots.len()]); return Ok(got); } let mut enough = vec![None; min]; let got = self.try_search_slots_imp(cache, input, &mut enough)?; // This is OK because we know `enough_slots` is strictly bigger than // `slots`, otherwise this special case isn't reached. slots.copy_from_slice(&enough[..slots.len()]); Ok(got) } #[inline(never)] fn try_search_slots_imp( &self, cache: &mut Cache, input: &Input<'_>, slots: &mut [Option], ) -> Result, MatchError> { let utf8empty = self.get_nfa().has_empty() && self.get_nfa().is_utf8(); match self.search_imp(cache, input, slots)? { None => return Ok(None), Some(pid) if !utf8empty => return Ok(Some(pid)), Some(pid) => { // These slot indices are always correct because we know our // 'pid' is valid and thus we know that the slot indices for it // are valid. let slot_start = pid.as_usize().wrapping_mul(2); let slot_end = slot_start.wrapping_add(1); // OK because we know we have a match and we know our caller // provided slots are big enough (which we make true above if // the caller didn't). Namely, we're only here when 'utf8empty' // is true, and when that's true, we require slots for every // pattern. let start = slots[slot_start].unwrap().get(); let end = slots[slot_end].unwrap().get(); // If our match splits a codepoint, then we cannot report is // as a match. And since one-pass DFAs only support anchored // searches, we don't try to skip ahead to find the next match. // We can just quit with nothing. if start == end && !input.is_char_boundary(start) { return Ok(None); } Ok(Some(pid)) } } } } impl DFA { fn search_imp( &self, cache: &mut Cache, input: &Input<'_>, slots: &mut [Option], ) -> Result, MatchError> { // PERF: Some ideas. I ran out of steam after my initial impl to try // many of these. // // 1) Try doing more state shuffling. Right now, all we do is push // match states to the end of the transition table so that we can do // 'if sid >= self.min_match_id' to know whether we're in a match // state or not. But what about doing something like dense DFAs and // pushing dead, match and states with captures/looks all toward the // beginning of the transition table. Then we could do 'if sid <= // self.max_special_id', in which case, we need to do some special // handling of some sort. Otherwise, we get the happy path, just // like in a DFA search. The main argument against this is that the // one-pass DFA is likely to be used most often with capturing groups // and if capturing groups are common, then this might wind up being a // pessimization. // // 2) Consider moving 'PatternEpsilons' out of the transition table. // It is only needed for match states and usually a small minority of // states are match states. Therefore, we're using an extra 'u64' for // most states. // // 3) I played around with the match state handling and it seems like // there is probably a lot left on the table for improvement. The // key tension is that the 'find_match' routine is a giant mess, but // splitting it out into a non-inlineable function is a non-starter // because the match state might consume input, so 'find_match' COULD // be called quite a lot, and a function call at that point would trash // perf. In theory, we could detect whether a match state consumes // input and then specialize our search routine based on that. In that // case, maybe an extra function call is OK, but even then, it might be // too much of a latency hit. Another idea is to just try and figure // out how to reduce the code size of 'find_match'. RE2 has a trick // here where the match handling isn't done if we know the next byte of // input yields a match too. Maybe we adopt that? // // This just might be a tricky DFA to optimize. if input.is_done() { return Ok(None); } // We unfortunately have a bit of book-keeping to do to set things // up. We do have to setup our cache and clear all of our slots. In // particular, clearing the slots is necessary for the case where we // report a match, but one of the capturing groups didn't participate // in the match but had a span set from a previous search. That would // be bad. In theory, we could avoid all this slot clearing if we knew // that every slot was always activated for every match. Then we would // know they would always be overwritten when a match is found. let explicit_slots_len = core::cmp::min( Slots::LIMIT, slots.len().saturating_sub(self.explicit_slot_start), ); cache.setup_search(explicit_slots_len); for slot in cache.explicit_slots() { *slot = None; } for slot in slots.iter_mut() { *slot = None; } // We set the starting slots for every pattern up front. This does // increase our latency somewhat, but it avoids having to do it every // time we see a match state (which could be many times in a single // search if the match state consumes input). for pid in self.nfa.patterns() { let i = pid.as_usize() * 2; if i >= slots.len() { break; } slots[i] = NonMaxUsize::new(input.start()); } let mut pid = None; let mut next_sid = match input.get_anchored() { Anchored::Yes => self.start(), Anchored::Pattern(pid) => self.start_pattern(pid)?, Anchored::No => { // If the regex is itself always anchored, then we're fine, // even if the search is configured to be unanchored. if !self.nfa.is_always_start_anchored() { return Err(MatchError::unsupported_anchored( Anchored::No, )); } self.start() } }; let leftmost_first = matches!(self.config.get_match_kind(), MatchKind::LeftmostFirst); for at in input.start()..input.end() { let sid = next_sid; let trans = self.transition(sid, input.haystack()[at]); next_sid = trans.state_id(); let epsilons = trans.epsilons(); if sid >= self.min_match_id { if self.find_match(cache, input, at, sid, slots, &mut pid) { if input.get_earliest() || (leftmost_first && trans.match_wins()) { return Ok(pid); } } } if sid == DEAD || (!epsilons.looks().is_empty() && !self.nfa.look_matcher().matches_set_inline( epsilons.looks(), input.haystack(), at, )) { return Ok(pid); } epsilons.slots().apply(at, cache.explicit_slots()); } if next_sid >= self.min_match_id { self.find_match( cache, input, input.end(), next_sid, slots, &mut pid, ); } Ok(pid) } /// Assumes 'sid' is a match state and looks for whether a match can /// be reported. If so, appropriate offsets are written to 'slots' and /// 'matched_pid' is set to the matching pattern ID. /// /// Even when 'sid' is a match state, it's possible that a match won't /// be reported. For example, when the conditional epsilon transitions /// leading to the match state aren't satisfied at the given position in /// the haystack. #[cfg_attr(feature = "perf-inline", inline(always))] fn find_match( &self, cache: &mut Cache, input: &Input<'_>, at: usize, sid: StateID, slots: &mut [Option], matched_pid: &mut Option, ) -> bool { debug_assert!(sid >= self.min_match_id); let pateps = self.pattern_epsilons(sid); let epsilons = pateps.epsilons(); if !epsilons.looks().is_empty() && !self.nfa.look_matcher().matches_set_inline( epsilons.looks(), input.haystack(), at, ) { return false; } let pid = pateps.pattern_id_unchecked(); // This calculation is always correct because we know our 'pid' is // valid and thus we know that the slot indices for it are valid. let slot_end = pid.as_usize().wrapping_mul(2).wrapping_add(1); // Set the implicit 'end' slot for the matching pattern. (The 'start' // slot was set at the beginning of the search.) if slot_end < slots.len() { slots[slot_end] = NonMaxUsize::new(at); } // If the caller provided enough room, copy the previously recorded // explicit slots from our scratch space to the caller provided slots. // We *also* need to set any explicit slots that are active as part of // the path to the match state. if self.explicit_slot_start < slots.len() { // NOTE: The 'cache.explicit_slots()' slice is setup at the // beginning of every search such that it is guaranteed to return a // slice of length equivalent to 'slots[explicit_slot_start..]'. slots[self.explicit_slot_start..] .copy_from_slice(cache.explicit_slots()); epsilons.slots().apply(at, &mut slots[self.explicit_slot_start..]); } *matched_pid = Some(pid); true } } impl DFA { /// Returns the anchored start state for matching any pattern in this DFA. fn start(&self) -> StateID { self.starts[0] } /// Returns the anchored start state for matching the given pattern. If /// 'starts_for_each_pattern' /// was not enabled, then this returns an error. If the given pattern is /// not in this DFA, then `Ok(None)` is returned. fn start_pattern(&self, pid: PatternID) -> Result { if !self.config.get_starts_for_each_pattern() { return Err(MatchError::unsupported_anchored(Anchored::Pattern( pid, ))); } // 'starts' always has non-zero length. The first entry is always the // anchored starting state for all patterns, and the following entries // are optional and correspond to the anchored starting states for // patterns at pid+1. Thus, starts.len()-1 corresponds to the total // number of patterns that one can explicitly search for. (And it may // be zero.) Ok(self.starts.get(pid.one_more()).copied().unwrap_or(DEAD)) } /// Returns the transition from the given state ID and byte of input. The /// transition includes the next state ID, the slots that should be saved /// and any conditional epsilon transitions that must be satisfied in order /// to take this transition. fn transition(&self, sid: StateID, byte: u8) -> Transition { let offset = sid.as_usize() << self.stride2(); let class = self.classes.get(byte).as_usize(); self.table[offset + class] } /// Set the transition from the given state ID and byte of input to the /// transition given. fn set_transition(&mut self, sid: StateID, byte: u8, to: Transition) { let offset = sid.as_usize() << self.stride2(); let class = self.classes.get(byte).as_usize(); self.table[offset + class] = to; } /// Return an iterator of "sparse" transitions for the given state ID. /// "sparse" in this context means that consecutive transitions that are /// equivalent are returned as one group, and transitions to the DEAD state /// are ignored. /// /// This winds up being useful for debug printing, since it's much terser /// to display runs of equivalent transitions than the transition for every /// possible byte value. Indeed, in practice, it's very common for runs /// of equivalent transitions to appear. fn sparse_transitions(&self, sid: StateID) -> SparseTransitionIter<'_> { let start = sid.as_usize() << self.stride2(); let end = start + self.alphabet_len(); SparseTransitionIter { it: self.table[start..end].iter().enumerate(), cur: None, } } /// Return the pattern epsilons for the given state ID. /// /// If the given state ID does not correspond to a match state ID, then the /// pattern epsilons returned is empty. fn pattern_epsilons(&self, sid: StateID) -> PatternEpsilons { let offset = sid.as_usize() << self.stride2(); PatternEpsilons(self.table[offset + self.pateps_offset].0) } /// Set the pattern epsilons for the given state ID. fn set_pattern_epsilons(&mut self, sid: StateID, pateps: PatternEpsilons) { let offset = sid.as_usize() << self.stride2(); self.table[offset + self.pateps_offset] = Transition(pateps.0); } /// Returns the state ID prior to the one given. This returns None if the /// given ID is the first DFA state. fn prev_state_id(&self, id: StateID) -> Option { if id == DEAD { None } else { // CORRECTNESS: Since 'id' is not the first state, subtracting 1 // is always valid. Some(StateID::new_unchecked(id.as_usize().checked_sub(1).unwrap())) } } /// Returns the state ID of the last state in this DFA's transition table. /// "last" in this context means the last state to appear in memory, i.e., /// the one with the greatest ID. fn last_state_id(&self) -> StateID { // CORRECTNESS: A DFA table is always non-empty since it always at // least contains a DEAD state. Since every state has the same stride, // we can just compute what the "next" state ID would have been and // then subtract 1 from it. StateID::new_unchecked( (self.table.len() >> self.stride2()).checked_sub(1).unwrap(), ) } /// Move the transitions from 'id1' to 'id2' and vice versa. /// /// WARNING: This does not update the rest of the transition table to have /// transitions to 'id1' changed to 'id2' and vice versa. This merely moves /// the states in memory. pub(super) fn swap_states(&mut self, id1: StateID, id2: StateID) { let o1 = id1.as_usize() << self.stride2(); let o2 = id2.as_usize() << self.stride2(); for b in 0..self.stride() { self.table.swap(o1 + b, o2 + b); } } /// Map all state IDs in this DFA (transition table + start states) /// according to the closure given. pub(super) fn remap(&mut self, map: impl Fn(StateID) -> StateID) { for i in 0..self.state_len() { let offset = i << self.stride2(); for b in 0..self.alphabet_len() { let next = self.table[offset + b].state_id(); self.table[offset + b].set_state_id(map(next)); } } for i in 0..self.starts.len() { self.starts[i] = map(self.starts[i]); } } } impl core::fmt::Debug for DFA { fn fmt(&self, f: &mut core::fmt::Formatter) -> core::fmt::Result { fn debug_state_transitions( f: &mut core::fmt::Formatter, dfa: &DFA, sid: StateID, ) -> core::fmt::Result { for (i, (start, end, trans)) in dfa.sparse_transitions(sid).enumerate() { let next = trans.state_id(); if i > 0 { write!(f, ", ")?; } if start == end { write!( f, "{:?} => {:?}", DebugByte(start), next.as_usize(), )?; } else { write!( f, "{:?}-{:?} => {:?}", DebugByte(start), DebugByte(end), next.as_usize(), )?; } if trans.match_wins() { write!(f, " (MW)")?; } if !trans.epsilons().is_empty() { write!(f, " ({:?})", trans.epsilons())?; } } Ok(()) } writeln!(f, "onepass::DFA(")?; for index in 0..self.state_len() { let sid = StateID::must(index); let pateps = self.pattern_epsilons(sid); if sid == DEAD { write!(f, "D ")?; } else if pateps.pattern_id().is_some() { write!(f, "* ")?; } else { write!(f, " ")?; } write!(f, "{:06?}", sid.as_usize())?; if !pateps.is_empty() { write!(f, " ({:?})", pateps)?; } write!(f, ": ")?; debug_state_transitions(f, self, sid)?; write!(f, "\n")?; } writeln!(f, "")?; for (i, &sid) in self.starts.iter().enumerate() { if i == 0 { writeln!(f, "START(ALL): {:?}", sid.as_usize())?; } else { writeln!( f, "START(pattern: {:?}): {:?}", i - 1, sid.as_usize(), )?; } } writeln!(f, "state length: {:?}", self.state_len())?; writeln!(f, "pattern length: {:?}", self.pattern_len())?; writeln!(f, ")")?; Ok(()) } } /// An iterator over groups of consecutive equivalent transitions in a single /// state. #[derive(Debug)] struct SparseTransitionIter<'a> { it: core::iter::Enumerate>, cur: Option<(u8, u8, Transition)>, } impl<'a> Iterator for SparseTransitionIter<'a> { type Item = (u8, u8, Transition); fn next(&mut self) -> Option<(u8, u8, Transition)> { while let Some((b, &trans)) = self.it.next() { // Fine because we'll never have more than u8::MAX transitions in // one state. let b = b.as_u8(); let (prev_start, prev_end, prev_trans) = match self.cur { Some(t) => t, None => { self.cur = Some((b, b, trans)); continue; } }; if prev_trans == trans { self.cur = Some((prev_start, b, prev_trans)); } else { self.cur = Some((b, b, trans)); if prev_trans.state_id() != DEAD { return Some((prev_start, prev_end, prev_trans)); } } } if let Some((start, end, trans)) = self.cur.take() { if trans.state_id() != DEAD { return Some((start, end, trans)); } } None } } /// A cache represents mutable state that a one-pass [`DFA`] requires during a /// search. /// /// For a given one-pass DFA, its corresponding cache may be created either via /// [`DFA::create_cache`], or via [`Cache::new`]. They are equivalent in every /// way, except the former does not require explicitly importing `Cache`. /// /// A particular `Cache` is coupled with the one-pass DFA from which it was /// created. It may only be used with that one-pass DFA. A cache and its /// allocations may be re-purposed via [`Cache::reset`], in which case, it can /// only be used with the new one-pass DFA (and not the old one). #[derive(Clone, Debug)] pub struct Cache { /// Scratch space used to store slots during a search. Basically, we use /// the caller provided slots to store slots known when a match occurs. /// But after a match occurs, we might continue a search but ultimately /// fail to extend the match. When continuing the search, we need some /// place to store candidate capture offsets without overwriting the slot /// offsets recorded for the most recently seen match. explicit_slots: Vec>, /// The number of slots in the caller-provided 'Captures' value for the /// current search. This is always at most 'explicit_slots.len()', but /// might be less than it, if the caller provided fewer slots to fill. explicit_slot_len: usize, } impl Cache { /// Create a new [`onepass::DFA`](DFA) cache. /// /// A potentially more convenient routine to create a cache is /// [`DFA::create_cache`], as it does not require also importing the /// `Cache` type. /// /// If you want to reuse the returned `Cache` with some other one-pass DFA, /// then you must call [`Cache::reset`] with the desired one-pass DFA. pub fn new(re: &DFA) -> Cache { let mut cache = Cache { explicit_slots: vec![], explicit_slot_len: 0 }; cache.reset(re); cache } /// Reset this cache such that it can be used for searching with a /// different [`onepass::DFA`](DFA). /// /// A cache reset permits reusing memory already allocated in this cache /// with a different one-pass DFA. /// /// # Example /// /// This shows how to re-purpose a cache for use with a different one-pass /// DFA. /// /// ``` /// # if cfg!(miri) { return Ok(()); } // miri takes too long /// use regex_automata::{dfa::onepass::DFA, Match}; /// /// let re1 = DFA::new(r"\w")?; /// let re2 = DFA::new(r"\W")?; /// let mut caps1 = re1.create_captures(); /// let mut caps2 = re2.create_captures(); /// /// let mut cache = re1.create_cache(); /// assert_eq!( /// Some(Match::must(0, 0..2)), /// { re1.captures(&mut cache, "Δ", &mut caps1); caps1.get_match() }, /// ); /// /// // Using 'cache' with re2 is not allowed. It may result in panics or /// // incorrect results. In order to re-purpose the cache, we must reset /// // it with the one-pass DFA we'd like to use it with. /// // /// // Similarly, after this reset, using the cache with 're1' is also not /// // allowed. /// re2.reset_cache(&mut cache); /// assert_eq!( /// Some(Match::must(0, 0..3)), /// { re2.captures(&mut cache, "☃", &mut caps2); caps2.get_match() }, /// ); /// /// # Ok::<(), Box>(()) /// ``` pub fn reset(&mut self, re: &DFA) { let explicit_slot_len = re.get_nfa().group_info().explicit_slot_len(); self.explicit_slots.resize(explicit_slot_len, None); self.explicit_slot_len = explicit_slot_len; } /// Returns the heap memory usage, in bytes, of this cache. /// /// This does **not** include the stack size used up by this cache. To /// compute that, use `std::mem::size_of::()`. pub fn memory_usage(&self) -> usize { self.explicit_slots.len() * core::mem::size_of::>() } fn explicit_slots(&mut self) -> &mut [Option] { &mut self.explicit_slots[..self.explicit_slot_len] } fn setup_search(&mut self, explicit_slot_len: usize) { self.explicit_slot_len = explicit_slot_len; } } /// Represents a single transition in a one-pass DFA. /// /// The high 21 bits corresponds to the state ID. The bit following corresponds /// to the special "match wins" flag. The remaining low 42 bits corresponds to /// the transition epsilons, which contains the slots that should be saved when /// this transition is followed and the conditional epsilon transitions that /// must be satisfied in order to follow this transition. #[derive(Clone, Copy, Eq, PartialEq)] struct Transition(u64); impl Transition { const STATE_ID_BITS: u64 = 21; const STATE_ID_SHIFT: u64 = 64 - Transition::STATE_ID_BITS; const STATE_ID_LIMIT: u64 = 1 << Transition::STATE_ID_BITS; const MATCH_WINS_SHIFT: u64 = 64 - (Transition::STATE_ID_BITS + 1); const INFO_MASK: u64 = 0x000003FF_FFFFFFFF; /// Return a new transition to the given state ID with the given epsilons. fn new(match_wins: bool, sid: StateID, epsilons: Epsilons) -> Transition { let match_wins = if match_wins { 1 << Transition::MATCH_WINS_SHIFT } else { 0 }; let sid = sid.as_u64() << Transition::STATE_ID_SHIFT; Transition(sid | match_wins | epsilons.0) } /// Returns true if and only if this transition points to the DEAD state. fn is_dead(self) -> bool { self.state_id() == DEAD } /// Return whether this transition has a "match wins" property. /// /// When a transition has this property, it means that if a match has been /// found and the search uses leftmost-first semantics, then that match /// should be returned immediately instead of continuing on. /// /// The "match wins" name comes from RE2, which uses a pretty much /// identical mechanism for implementing leftmost-first semantics. fn match_wins(&self) -> bool { (self.0 >> Transition::MATCH_WINS_SHIFT & 1) == 1 } /// Return the "next" state ID that this transition points to. fn state_id(&self) -> StateID { // OK because a Transition has a valid StateID in its upper bits by // construction. The cast to usize is also correct, even on 16-bit // targets because, again, we know the upper bits is a valid StateID, // which can never overflow usize on any supported target. StateID::new_unchecked( (self.0 >> Transition::STATE_ID_SHIFT).as_usize(), ) } /// Set the "next" state ID in this transition. fn set_state_id(&mut self, sid: StateID) { *self = Transition::new(self.match_wins(), sid, self.epsilons()); } /// Return the epsilons embedded in this transition. fn epsilons(&self) -> Epsilons { Epsilons(self.0 & Transition::INFO_MASK) } } impl core::fmt::Debug for Transition { fn fmt(&self, f: &mut core::fmt::Formatter) -> core::fmt::Result { if self.is_dead() { return write!(f, "0"); } write!(f, "{}", self.state_id().as_usize())?; if self.match_wins() { write!(f, "-MW")?; } if !self.epsilons().is_empty() { write!(f, "-{:?}", self.epsilons())?; } Ok(()) } } /// A representation of a match state's pattern ID along with the epsilons for /// when a match occurs. /// /// A match state in a one-pass DFA, unlike in a more general DFA, has exactly /// one pattern ID. If it had more, then the original NFA would not have been /// one-pass. /// /// The "epsilons" part of this corresponds to what was found in the epsilon /// transitions between the transition taken in the last byte of input and the /// ultimate match state. This might include saving slots and/or conditional /// epsilon transitions that must be satisfied before one can report the match. /// /// Technically, every state has room for a 'PatternEpsilons', but it is only /// ever non-empty for match states. #[derive(Clone, Copy)] struct PatternEpsilons(u64); impl PatternEpsilons { const PATTERN_ID_BITS: u64 = 22; const PATTERN_ID_SHIFT: u64 = 64 - PatternEpsilons::PATTERN_ID_BITS; // A sentinel value indicating that this is not a match state. We don't // use 0 since 0 is a valid pattern ID. const PATTERN_ID_NONE: u64 = 0x00000000_003FFFFF; const PATTERN_ID_LIMIT: u64 = PatternEpsilons::PATTERN_ID_NONE; const PATTERN_ID_MASK: u64 = 0xFFFFFC00_00000000; const EPSILONS_MASK: u64 = 0x000003FF_FFFFFFFF; /// Return a new empty pattern epsilons that has no pattern ID and has no /// epsilons. This is suitable for non-match states. fn empty() -> PatternEpsilons { PatternEpsilons( PatternEpsilons::PATTERN_ID_NONE << PatternEpsilons::PATTERN_ID_SHIFT, ) } /// Whether this pattern epsilons is empty or not. It's empty when it has /// no pattern ID and an empty epsilons. fn is_empty(self) -> bool { self.pattern_id().is_none() && self.epsilons().is_empty() } /// Return the pattern ID in this pattern epsilons if one exists. fn pattern_id(self) -> Option { let pid = self.0 >> PatternEpsilons::PATTERN_ID_SHIFT; if pid == PatternEpsilons::PATTERN_ID_LIMIT { None } else { Some(PatternID::new_unchecked(pid.as_usize())) } } /// Returns the pattern ID without checking whether it's valid. If this is /// called and there is no pattern ID in this `PatternEpsilons`, then this /// will likely produce an incorrect result or possibly even a panic or /// an overflow. But safety will not be violated. /// /// This is useful when you know a particular state is a match state. If /// it's a match state, then it must have a pattern ID. fn pattern_id_unchecked(self) -> PatternID { let pid = self.0 >> PatternEpsilons::PATTERN_ID_SHIFT; PatternID::new_unchecked(pid.as_usize()) } /// Return a new pattern epsilons with the given pattern ID, but the same /// epsilons. fn set_pattern_id(self, pid: PatternID) -> PatternEpsilons { PatternEpsilons( (pid.as_u64() << PatternEpsilons::PATTERN_ID_SHIFT) | (self.0 & PatternEpsilons::EPSILONS_MASK), ) } /// Return the epsilons part of this pattern epsilons. fn epsilons(self) -> Epsilons { Epsilons(self.0 & PatternEpsilons::EPSILONS_MASK) } /// Return a new pattern epsilons with the given epsilons, but the same /// pattern ID. fn set_epsilons(self, epsilons: Epsilons) -> PatternEpsilons { PatternEpsilons( (self.0 & PatternEpsilons::PATTERN_ID_MASK) | (u64::from(epsilons.0) & PatternEpsilons::EPSILONS_MASK), ) } } impl core::fmt::Debug for PatternEpsilons { fn fmt(&self, f: &mut core::fmt::Formatter) -> core::fmt::Result { if self.is_empty() { return write!(f, "N/A"); } if let Some(pid) = self.pattern_id() { write!(f, "{}", pid.as_usize())?; } if !self.epsilons().is_empty() { if self.pattern_id().is_some() { write!(f, "/")?; } write!(f, "{:?}", self.epsilons())?; } Ok(()) } } /// Epsilons represents all of the NFA epsilons transitions that went into a /// single transition in a single DFA state. In this case, it only represents /// the epsilon transitions that have some kind of non-consuming side effect: /// either the transition requires storing the current position of the search /// into a slot, or the transition is conditional and requires the current /// position in the input to satisfy an assertion before the transition may be /// taken. /// /// This folds the cumulative effect of a group of NFA states (all connected /// by epsilon transitions) down into a single set of bits. While these bits /// can represent all possible conditional epsilon transitions, it only permits /// storing up to a somewhat small number of slots. /// /// Epsilons is represented as a 42-bit integer. For example, it is packed into /// the lower 42 bits of a `Transition`. (Where the high 22 bits contains a /// `StateID` and a special "match wins" property.) #[derive(Clone, Copy)] struct Epsilons(u64); impl Epsilons { const SLOT_MASK: u64 = 0x000003FF_FFFFFC00; const SLOT_SHIFT: u64 = 10; const LOOK_MASK: u64 = 0x00000000_000003FF; /// Create a new empty epsilons. It has no slots and no assertions that /// need to be satisfied. fn empty() -> Epsilons { Epsilons(0) } /// Returns true if this epsilons contains no slots and no assertions. fn is_empty(self) -> bool { self.0 == 0 } /// Returns the slot epsilon transitions. fn slots(self) -> Slots { Slots((self.0 >> Epsilons::SLOT_SHIFT).low_u32()) } /// Set the slot epsilon transitions. fn set_slots(self, slots: Slots) -> Epsilons { Epsilons( (u64::from(slots.0) << Epsilons::SLOT_SHIFT) | (self.0 & Epsilons::LOOK_MASK), ) } /// Return the set of look-around assertions in these epsilon transitions. fn looks(self) -> LookSet { LookSet { bits: (self.0 & Epsilons::LOOK_MASK).low_u32() } } /// Set the look-around assertions on these epsilon transitions. fn set_looks(self, look_set: LookSet) -> Epsilons { Epsilons( (self.0 & Epsilons::SLOT_MASK) | (u64::from(look_set.bits) & Epsilons::LOOK_MASK), ) } } impl core::fmt::Debug for Epsilons { fn fmt(&self, f: &mut core::fmt::Formatter) -> core::fmt::Result { let mut wrote = false; if !self.slots().is_empty() { write!(f, "{:?}", self.slots())?; wrote = true; } if !self.looks().is_empty() { if wrote { write!(f, "/")?; } write!(f, "{:?}", self.looks())?; wrote = true; } if !wrote { write!(f, "N/A")?; } Ok(()) } } /// The set of epsilon transitions indicating that the current position in a /// search should be saved to a slot. /// /// This *only* represents explicit slots. So for example, the pattern /// `[a-z]+([0-9]+)([a-z]+)` has: /// /// * 3 capturing groups, thus 6 slots. /// * 1 implicit capturing group, thus 2 implicit slots. /// * 2 explicit capturing groups, thus 4 explicit slots. /// /// While implicit slots are represented by epsilon transitions in an NFA, we /// do not explicitly represent them here. Instead, implicit slots are assumed /// to be present and handled automatically in the search code. Therefore, /// that means we only need to represent explicit slots in our epsilon /// transitions. /// /// Its representation is a bit set. The bit 'i' is set if and only if there /// exists an explicit slot at index 'c', where 'c = (#patterns * 2) + i'. That /// is, the bit 'i' corresponds to the first explicit slot and the first /// explicit slot appears immediately following the last implicit slot. (If /// this is confusing, see `GroupInfo` for more details on how slots works.) /// /// A single `Slots` represents all the active slots in a sub-graph of an NFA, /// where all the states are connected by epsilon transitions. In effect, when /// traversing the one-pass DFA during a search, all slots set in a particular /// transition must be captured by recording the current search position. /// /// The API of `Slots` requires the caller to handle the explicit slot offset. /// That is, a `Slots` doesn't know where the explicit slots start for a /// particular NFA. Thus, if the callers see's the bit 'i' is set, then they /// need to do the arithmetic above to find 'c', which is the real actual slot /// index in the corresponding NFA. #[derive(Clone, Copy)] struct Slots(u32); impl Slots { const LIMIT: usize = 32; /// Insert the slot at the given bit index. fn insert(self, slot: usize) -> Slots { debug_assert!(slot < Slots::LIMIT); Slots(self.0 | (1 << slot.as_u32())) } /// Remove the slot at the given bit index. fn remove(self, slot: usize) -> Slots { debug_assert!(slot < Slots::LIMIT); Slots(self.0 & !(1 << slot.as_u32())) } /// Returns true if and only if this set contains no slots. fn is_empty(self) -> bool { self.0 == 0 } /// Returns an iterator over all of the set bits in this set. fn iter(self) -> SlotsIter { SlotsIter { slots: self } } /// For the position `at` in the current haystack, copy it to /// `caller_explicit_slots` for all slots that are in this set. /// /// Callers may pass a slice of any length. Slots in this set bigger than /// the length of the given explicit slots are simply skipped. /// /// The slice *must* correspond only to the explicit slots and the first /// element of the slice must always correspond to the first explicit slot /// in the corresponding NFA. fn apply( self, at: usize, caller_explicit_slots: &mut [Option], ) { if self.is_empty() { return; } let at = NonMaxUsize::new(at); for slot in self.iter() { if slot >= caller_explicit_slots.len() { break; } caller_explicit_slots[slot] = at; } } } impl core::fmt::Debug for Slots { fn fmt(&self, f: &mut core::fmt::Formatter) -> core::fmt::Result { write!(f, "S")?; for slot in self.iter() { write!(f, "-{:?}", slot)?; } Ok(()) } } /// An iterator over all of the bits set in a slot set. /// /// This returns the bit index that is set, so callers may need to offset it /// to get the actual NFA slot index. #[derive(Debug)] struct SlotsIter { slots: Slots, } impl Iterator for SlotsIter { type Item = usize; fn next(&mut self) -> Option { // Number of zeroes here is always <= u8::MAX, and so fits in a usize. let slot = self.slots.0.trailing_zeros().as_usize(); if slot >= Slots::LIMIT { return None; } self.slots = self.slots.remove(slot); Some(slot) } } /// An error that occurred during the construction of a one-pass DFA. /// /// This error does not provide many introspection capabilities. There are /// generally only two things you can do with it: /// /// * Obtain a human readable message via its `std::fmt::Display` impl. /// * Access an underlying [`thompson::BuildError`] type from its `source` /// method via the `std::error::Error` trait. This error only occurs when using /// convenience routines for building a one-pass DFA directly from a pattern /// string. /// /// When the `std` feature is enabled, this implements the `std::error::Error` /// trait. #[derive(Clone, Debug)] pub struct BuildError { kind: BuildErrorKind, } /// The kind of error that occurred during the construction of a one-pass DFA. #[derive(Clone, Debug)] enum BuildErrorKind { NFA(crate::nfa::thompson::BuildError), Word(UnicodeWordBoundaryError), TooManyStates { limit: u64 }, TooManyPatterns { limit: u64 }, UnsupportedLook { look: Look }, ExceededSizeLimit { limit: usize }, NotOnePass { msg: &'static str }, } impl BuildError { fn nfa(err: crate::nfa::thompson::BuildError) -> BuildError { BuildError { kind: BuildErrorKind::NFA(err) } } fn word(err: UnicodeWordBoundaryError) -> BuildError { BuildError { kind: BuildErrorKind::Word(err) } } fn too_many_states(limit: u64) -> BuildError { BuildError { kind: BuildErrorKind::TooManyStates { limit } } } fn too_many_patterns(limit: u64) -> BuildError { BuildError { kind: BuildErrorKind::TooManyPatterns { limit } } } fn unsupported_look(look: Look) -> BuildError { BuildError { kind: BuildErrorKind::UnsupportedLook { look } } } fn exceeded_size_limit(limit: usize) -> BuildError { BuildError { kind: BuildErrorKind::ExceededSizeLimit { limit } } } fn not_one_pass(msg: &'static str) -> BuildError { BuildError { kind: BuildErrorKind::NotOnePass { msg } } } } #[cfg(feature = "std")] impl std::error::Error for BuildError { fn source(&self) -> Option<&(dyn std::error::Error + 'static)> { use self::BuildErrorKind::*; match self.kind { NFA(ref err) => Some(err), Word(ref err) => Some(err), _ => None, } } } impl core::fmt::Display for BuildError { fn fmt(&self, f: &mut core::fmt::Formatter<'_>) -> core::fmt::Result { use self::BuildErrorKind::*; match self.kind { NFA(_) => write!(f, "error building NFA"), Word(_) => write!(f, "NFA contains Unicode word boundary"), TooManyStates { limit } => write!( f, "one-pass DFA exceeded a limit of {:?} for number of states", limit, ), TooManyPatterns { limit } => write!( f, "one-pass DFA exceeded a limit of {:?} for number of patterns", limit, ), UnsupportedLook { look } => write!( f, "one-pass DFA does not support the {:?} assertion", look, ), ExceededSizeLimit { limit } => write!( f, "one-pass DFA exceeded size limit of {:?} during building", limit, ), NotOnePass { msg } => write!( f, "one-pass DFA could not be built because \ pattern is not one-pass: {}", msg, ), } } } #[cfg(all(test, feature = "syntax"))] mod tests { use alloc::string::ToString; use super::*; #[test] fn fail_conflicting_transition() { let predicate = |err: &str| err.contains("conflicting transition"); let err = DFA::new(r"a*[ab]").unwrap_err().to_string(); assert!(predicate(&err), "{}", err); } #[test] fn fail_multiple_epsilon() { let predicate = |err: &str| { err.contains("multiple epsilon transitions to same state") }; let err = DFA::new(r"(^|$)a").unwrap_err().to_string(); assert!(predicate(&err), "{}", err); } #[test] fn fail_multiple_match() { let predicate = |err: &str| { err.contains("multiple epsilon transitions to match state") }; let err = DFA::new_many(&[r"^", r"$"]).unwrap_err().to_string(); assert!(predicate(&err), "{}", err); } // This test is meant to build a one-pass regex with the maximum number of // possible slots. // // NOTE: Remember that the slot limit only applies to explicit capturing // groups. Any number of implicit capturing groups is supported (up to the // maximum number of supported patterns), since implicit groups are handled // by the search loop itself. #[test] fn max_slots() { // One too many... let pat = r"(a)(b)(c)(d)(e)(f)(g)(h)(i)(j)(k)(l)(m)(n)(o)(p)(q)"; assert!(DFA::new(pat).is_err()); // Just right. let pat = r"(a)(b)(c)(d)(e)(f)(g)(h)(i)(j)(k)(l)(m)(n)(o)(p)"; assert!(DFA::new(pat).is_ok()); } // This test ensures that the one-pass DFA works with all look-around // assertions that we expect it to work with. // // The utility of this test is that each one-pass transition has a small // amount of space to store look-around assertions. Currently, there is // logic in the one-pass constructor to ensure there aren't more than ten // possible assertions. And indeed, there are only ten possible assertions // (at time of writing), so this is okay. But conceivably, more assertions // could be added. So we check that things at least work with what we // expect them to work with. #[test] fn assertions() { // haystack anchors assert!(DFA::new(r"^").is_ok()); assert!(DFA::new(r"$").is_ok()); // line anchors assert!(DFA::new(r"(?m)^").is_ok()); assert!(DFA::new(r"(?m)$").is_ok()); assert!(DFA::new(r"(?Rm)^").is_ok()); assert!(DFA::new(r"(?Rm)$").is_ok()); // word boundaries if cfg!(feature = "unicode-word-boundary") { assert!(DFA::new(r"\b").is_ok()); assert!(DFA::new(r"\B").is_ok()); } assert!(DFA::new(r"(?-u)\b").is_ok()); assert!(DFA::new(r"(?-u)\B").is_ok()); } #[cfg(not(miri))] // takes too long on miri #[test] fn is_one_pass() { use crate::util::syntax; assert!(DFA::new(r"a*b").is_ok()); if cfg!(feature = "unicode-perl") { assert!(DFA::new(r"\w").is_ok()); } assert!(DFA::new(r"(?-u)\w*\s").is_ok()); assert!(DFA::new(r"(?s:.)*?").is_ok()); assert!(DFA::builder() .syntax(syntax::Config::new().utf8(false)) .build(r"(?s-u:.)*?") .is_ok()); } #[test] fn is_not_one_pass() { assert!(DFA::new(r"a*a").is_err()); assert!(DFA::new(r"(?s-u:.)*?").is_err()); assert!(DFA::new(r"(?s:.)*?a").is_err()); } #[cfg(not(miri))] #[test] fn is_not_one_pass_bigger() { assert!(DFA::new(r"\w*\s").is_err()); } }