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Diffstat (limited to 'vendor/regex-automata/src/util/captures.rs')
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diff --git a/vendor/regex-automata/src/util/captures.rs b/vendor/regex-automata/src/util/captures.rs new file mode 100644 index 000000000..cd3a5f8f7 --- /dev/null +++ b/vendor/regex-automata/src/util/captures.rs @@ -0,0 +1,2547 @@ +/*! +Provides types for dealing with capturing groups. + +Capturing groups refer to sub-patterns of regexes that some regex engines can +report matching offsets for. For example, matching `[a-z]([0-9]+)` against +`a789` would give `a789` as the overall match (for the implicit capturing group +at index `0`) and `789` as the match for the capturing group `([0-9]+)` (an +explicit capturing group at index `1`). + +Not all regex engines can report match offsets for capturing groups. Indeed, +to a first approximation, regex engines that can report capturing group offsets +tend to be quite a bit slower than regex engines that can't. This is because +tracking capturing groups at search time usually requires more "power" that +in turn adds overhead. + +Other regex implementations might call capturing groups "submatches." + +# Overview + +The main types in this module are: + +* [`Captures`] records the capturing group offsets found during a search. It +provides convenience routines for looking up capturing group offsets by either +index or name. +* [`GroupInfo`] records the mapping between capturing groups and "slots," +where the latter are how capturing groups are recorded during a regex search. +This also keeps a mapping from capturing group name to index, and capture +group index to name. A `GroupInfo` is used by `Captures` internally to +provide a convenient API. It is unlikely that you'll use a `GroupInfo` +directly, but for example, if you've compiled an Thompson NFA, then you can use +[`thompson::NFA::group_info`](crate::nfa::thompson::NFA::group_info) to get its +underlying `GroupInfo`. +*/ + +use alloc::{string::String, sync::Arc, vec, vec::Vec}; + +use crate::util::{ + interpolate, + primitives::{ + NonMaxUsize, PatternID, PatternIDError, PatternIDIter, SmallIndex, + }, + search::{Match, Span}, +}; + +/// The span offsets of capturing groups after a match has been found. +/// +/// This type represents the output of regex engines that can report the +/// offsets at which capturing groups matches or "submatches" occur. For +/// example, the [`PikeVM`](crate::nfa::thompson::pikevm::PikeVM). When a match +/// occurs, it will at minimum contain the [`PatternID`] of the pattern that +/// matched. Depending upon how it was constructed, it may also contain the +/// start/end offsets of the entire match of the pattern and the start/end +/// offsets of each capturing group that participated in the match. +/// +/// Values of this type are always created for a specific [`GroupInfo`]. It is +/// unspecified behavior to use a `Captures` value in a search with any regex +/// engine that has a different `GroupInfo` than the one the `Captures` were +/// created with. +/// +/// # Constructors +/// +/// There are three constructors for this type that control what kind of +/// information is available upon a match: +/// +/// * [`Captures::all`]: Will store overall pattern match offsets in addition +/// to the offsets of capturing groups that participated in the match. +/// * [`Captures::matches`]: Will store only the overall pattern +/// match offsets. The offsets of capturing groups (even ones that participated +/// in the match) are not available. +/// * [`Captures::empty`]: Will only store the pattern ID that matched. No +/// match offsets are available at all. +/// +/// If you aren't sure which to choose, then pick the first one. The first one +/// is what convenience routines like, +/// [`PikeVM::create_captures`](crate::nfa::thompson::pikevm::PikeVM::create_captures), +/// will use automatically. +/// +/// The main difference between these choices is performance. Namely, if you +/// ask for _less_ information, then the execution of regex search may be able +/// to run more quickly. +/// +/// # Notes +/// +/// It is worth pointing out that this type is not coupled to any one specific +/// regex engine. Instead, its coupling is with [`GroupInfo`], which is the +/// thing that is responsible for mapping capturing groups to "slot" offsets. +/// Slot offsets are indices into a single sequence of memory at which matching +/// haystack offsets for the corresponding group are written by regex engines. +/// +/// # Example +/// +/// This example shows how to parse a simple date and extract the components of +/// the date via capturing groups: +/// +/// ``` +/// use regex_automata::{nfa::thompson::pikevm::PikeVM, Span}; +/// +/// let re = PikeVM::new(r"^([0-9]{4})-([0-9]{2})-([0-9]{2})$")?; +/// let (mut cache, mut caps) = (re.create_cache(), re.create_captures()); +/// +/// re.captures(&mut cache, "2010-03-14", &mut caps); +/// assert!(caps.is_match()); +/// assert_eq!(Some(Span::from(0..4)), caps.get_group(1)); +/// assert_eq!(Some(Span::from(5..7)), caps.get_group(2)); +/// assert_eq!(Some(Span::from(8..10)), caps.get_group(3)); +/// +/// # Ok::<(), Box<dyn std::error::Error>>(()) +/// ``` +/// +/// # Example: named capturing groups +/// +/// This example is like the one above, but leverages the ability to name +/// capturing groups in order to make the code a bit clearer: +/// +/// ``` +/// use regex_automata::{nfa::thompson::pikevm::PikeVM, Span}; +/// +/// let re = PikeVM::new(r"^(?P<y>[0-9]{4})-(?P<m>[0-9]{2})-(?P<d>[0-9]{2})$")?; +/// let (mut cache, mut caps) = (re.create_cache(), re.create_captures()); +/// +/// re.captures(&mut cache, "2010-03-14", &mut caps); +/// assert!(caps.is_match()); +/// assert_eq!(Some(Span::from(0..4)), caps.get_group_by_name("y")); +/// assert_eq!(Some(Span::from(5..7)), caps.get_group_by_name("m")); +/// assert_eq!(Some(Span::from(8..10)), caps.get_group_by_name("d")); +/// +/// # Ok::<(), Box<dyn std::error::Error>>(()) +/// ``` +#[derive(Clone)] +pub struct Captures { + /// The group info that these capture groups are coupled to. This is what + /// gives the "convenience" of the `Captures` API. Namely, it provides the + /// slot mapping and the name|-->index mapping for capture lookups by name. + group_info: GroupInfo, + /// The ID of the pattern that matched. Regex engines must set this to + /// None when no match occurs. + pid: Option<PatternID>, + /// The slot values, i.e., submatch offsets. + /// + /// In theory, the smallest sequence of slots would be something like + /// `max(groups(pattern) for pattern in regex) * 2`, but instead, we use + /// `sum(groups(pattern) for pattern in regex) * 2`. Why? + /// + /// Well, the former could be used in theory, because we don't generally + /// have any overlapping APIs that involve capturing groups. Therefore, + /// there's technically never any need to have slots set for multiple + /// patterns. However, this might change some day, in which case, we would + /// need to have slots available. + /// + /// The other reason is that during the execution of some regex engines, + /// there exists a point in time where multiple slots for different + /// patterns may be written to before knowing which pattern has matched. + /// Therefore, the regex engines themselves, in order to support multiple + /// patterns correctly, must have all slots available. If `Captures` + /// doesn't have all slots available, then regex engines can't write + /// directly into the caller provided `Captures` and must instead write + /// into some other storage and then copy the slots involved in the match + /// at the end of the search. + /// + /// So overall, at least as of the time of writing, it seems like the path + /// of least resistance is to just require allocating all possible slots + /// instead of the conceptual minimum. Another way to justify this is that + /// the most common case is a single pattern, in which case, there is no + /// inefficiency here since the 'max' and 'sum' calculations above are + /// equivalent in that case. + /// + /// N.B. The mapping from group index to slot is maintained by `GroupInfo` + /// and is considered an API guarantee. See `GroupInfo` for more details on + /// that mapping. + /// + /// N.B. `Option<NonMaxUsize>` has the same size as a `usize`. + slots: Vec<Option<NonMaxUsize>>, +} + +impl Captures { + /// Create new storage for the offsets of all matching capturing groups. + /// + /// This routine provides the most information for matches---namely, the + /// spans of matching capturing groups---but also requires the regex search + /// routines to do the most work. + /// + /// It is unspecified behavior to use the returned `Captures` value in a + /// search with a `GroupInfo` other than the one that is provided to this + /// constructor. + /// + /// # Example + /// + /// This example shows that all capturing groups---but only ones that + /// participated in a match---are available to query after a match has + /// been found: + /// + /// ``` + /// use regex_automata::{ + /// nfa::thompson::pikevm::PikeVM, + /// util::captures::Captures, + /// Span, Match, + /// }; + /// + /// let re = PikeVM::new( + /// r"^(?:(?P<lower>[a-z]+)|(?P<upper>[A-Z]+))(?P<digits>[0-9]+)$", + /// )?; + /// let mut cache = re.create_cache(); + /// let mut caps = Captures::all(re.get_nfa().group_info().clone()); + /// + /// re.captures(&mut cache, "ABC123", &mut caps); + /// assert!(caps.is_match()); + /// assert_eq!(Some(Match::must(0, 0..6)), caps.get_match()); + /// // The 'lower' group didn't match, so it won't have any offsets. + /// assert_eq!(None, caps.get_group_by_name("lower")); + /// assert_eq!(Some(Span::from(0..3)), caps.get_group_by_name("upper")); + /// assert_eq!(Some(Span::from(3..6)), caps.get_group_by_name("digits")); + /// + /// # Ok::<(), Box<dyn std::error::Error>>(()) + /// ``` + pub fn all(group_info: GroupInfo) -> Captures { + let slots = group_info.slot_len(); + Captures { group_info, pid: None, slots: vec![None; slots] } + } + + /// Create new storage for only the full match spans of a pattern. This + /// does not include any capturing group offsets. + /// + /// It is unspecified behavior to use the returned `Captures` value in a + /// search with a `GroupInfo` other than the one that is provided to this + /// constructor. + /// + /// # Example + /// + /// This example shows that only overall match offsets are reported when + /// this constructor is used. Accessing any capturing groups other than + /// the 0th will always return `None`. + /// + /// ``` + /// use regex_automata::{ + /// nfa::thompson::pikevm::PikeVM, + /// util::captures::Captures, + /// Match, + /// }; + /// + /// let re = PikeVM::new( + /// r"^(?:(?P<lower>[a-z]+)|(?P<upper>[A-Z]+))(?P<digits>[0-9]+)$", + /// )?; + /// let mut cache = re.create_cache(); + /// let mut caps = Captures::matches(re.get_nfa().group_info().clone()); + /// + /// re.captures(&mut cache, "ABC123", &mut caps); + /// assert!(caps.is_match()); + /// assert_eq!(Some(Match::must(0, 0..6)), caps.get_match()); + /// // We didn't ask for capturing group offsets, so they aren't available. + /// assert_eq!(None, caps.get_group_by_name("lower")); + /// assert_eq!(None, caps.get_group_by_name("upper")); + /// assert_eq!(None, caps.get_group_by_name("digits")); + /// + /// # Ok::<(), Box<dyn std::error::Error>>(()) + /// ``` + pub fn matches(group_info: GroupInfo) -> Captures { + // This is OK because we know there are at least this many slots, + // and GroupInfo construction guarantees that the number of slots fits + // into a usize. + let slots = group_info.pattern_len().checked_mul(2).unwrap(); + Captures { group_info, pid: None, slots: vec![None; slots] } + } + + /// Create new storage for only tracking which pattern matched. No offsets + /// are stored at all. + /// + /// It is unspecified behavior to use the returned `Captures` value in a + /// search with a `GroupInfo` other than the one that is provided to this + /// constructor. + /// + /// # Example + /// + /// This example shows that only the pattern that matched can be accessed + /// from a `Captures` value created via this constructor. + /// + /// ``` + /// use regex_automata::{ + /// nfa::thompson::pikevm::PikeVM, + /// util::captures::Captures, + /// PatternID, + /// }; + /// + /// let re = PikeVM::new_many(&[r"[a-z]+", r"[A-Z]+"])?; + /// let mut cache = re.create_cache(); + /// let mut caps = Captures::empty(re.get_nfa().group_info().clone()); + /// + /// re.captures(&mut cache, "aABCz", &mut caps); + /// assert!(caps.is_match()); + /// assert_eq!(Some(PatternID::must(0)), caps.pattern()); + /// // We didn't ask for any offsets, so they aren't available. + /// assert_eq!(None, caps.get_match()); + /// + /// re.captures(&mut cache, &"aABCz"[1..], &mut caps); + /// assert!(caps.is_match()); + /// assert_eq!(Some(PatternID::must(1)), caps.pattern()); + /// // We didn't ask for any offsets, so they aren't available. + /// assert_eq!(None, caps.get_match()); + /// + /// # Ok::<(), Box<dyn std::error::Error>>(()) + /// ``` + pub fn empty(group_info: GroupInfo) -> Captures { + Captures { group_info, pid: None, slots: vec![] } + } + + /// Returns true if and only if this capturing group represents a match. + /// + /// This is a convenience routine for `caps.pattern().is_some()`. + /// + /// # Example + /// + /// When using the PikeVM (for example), the lightest weight way of + /// detecting whether a match exists is to create capturing groups that + /// only track the ID of the pattern that match (if any): + /// + /// ``` + /// use regex_automata::{ + /// nfa::thompson::pikevm::PikeVM, + /// util::captures::Captures, + /// }; + /// + /// let re = PikeVM::new(r"[a-z]+")?; + /// let mut cache = re.create_cache(); + /// let mut caps = Captures::empty(re.get_nfa().group_info().clone()); + /// + /// re.captures(&mut cache, "aABCz", &mut caps); + /// assert!(caps.is_match()); + /// + /// # Ok::<(), Box<dyn std::error::Error>>(()) + /// ``` + #[inline] + pub fn is_match(&self) -> bool { + self.pid.is_some() + } + + /// Returns the identifier of the pattern that matched when this + /// capturing group represents a match. If no match was found, then this + /// always returns `None`. + /// + /// This returns a pattern ID in precisely the cases in which `is_match` + /// returns `true`. Similarly, the pattern ID returned is always the + /// same pattern ID found in the `Match` returned by `get_match`. + /// + /// # Example + /// + /// When using the PikeVM (for example), the lightest weight way of + /// detecting which pattern matched is to create capturing groups that only + /// track the ID of the pattern that match (if any): + /// + /// ``` + /// use regex_automata::{ + /// nfa::thompson::pikevm::PikeVM, + /// util::captures::Captures, + /// PatternID, + /// }; + /// + /// let re = PikeVM::new_many(&[r"[a-z]+", r"[A-Z]+"])?; + /// let mut cache = re.create_cache(); + /// let mut caps = Captures::empty(re.get_nfa().group_info().clone()); + /// + /// re.captures(&mut cache, "ABC", &mut caps); + /// assert_eq!(Some(PatternID::must(1)), caps.pattern()); + /// // Recall that offsets are only available when using a non-empty + /// // Captures value. So even though a match occurred, this returns None! + /// assert_eq!(None, caps.get_match()); + /// + /// # Ok::<(), Box<dyn std::error::Error>>(()) + /// ``` + #[inline] + pub fn pattern(&self) -> Option<PatternID> { + self.pid + } + + /// Returns the pattern ID and the span of the match, if one occurred. + /// + /// This always returns `None` when `Captures` was created with + /// [`Captures::empty`], even if a match was found. + /// + /// If this routine returns a non-`None` value, then `is_match` is + /// guaranteed to return `true` and `pattern` is also guaranteed to return + /// a non-`None` value. + /// + /// # Example + /// + /// This example shows how to get the full match from a search: + /// + /// ``` + /// use regex_automata::{nfa::thompson::pikevm::PikeVM, Match}; + /// + /// let re = PikeVM::new_many(&[r"[a-z]+", r"[A-Z]+"])?; + /// let (mut cache, mut caps) = (re.create_cache(), re.create_captures()); + /// + /// re.captures(&mut cache, "ABC", &mut caps); + /// assert_eq!(Some(Match::must(1, 0..3)), caps.get_match()); + /// + /// # Ok::<(), Box<dyn std::error::Error>>(()) + /// ``` + #[inline] + pub fn get_match(&self) -> Option<Match> { + Some(Match::new(self.pattern()?, self.get_group(0)?)) + } + + /// Returns the span of a capturing group match corresponding to the group + /// index given, only if both the overall pattern matched and the capturing + /// group participated in that match. + /// + /// This returns `None` if `index` is invalid. `index` is valid if and only + /// if it's less than [`Captures::group_len`] for the matching pattern. + /// + /// This always returns `None` when `Captures` was created with + /// [`Captures::empty`], even if a match was found. This also always + /// returns `None` for any `index > 0` when `Captures` was created with + /// [`Captures::matches`]. + /// + /// If this routine returns a non-`None` value, then `is_match` is + /// guaranteed to return `true`, `pattern` is guaranteed to return a + /// non-`None` value and `get_match` is guaranteed to return a non-`None` + /// value. + /// + /// By convention, the 0th capture group will always return the same + /// span as the span returned by `get_match`. This is because the 0th + /// capture group always corresponds to the entirety of the pattern's + /// match. (It is similarly always unnamed because it is implicit.) This + /// isn't necessarily true of all regex engines. For example, one can + /// hand-compile a [`thompson::NFA`](crate::nfa::thompson::NFA) via a + /// [`thompson::Builder`](crate::nfa::thompson::Builder), which isn't + /// technically forced to make the 0th capturing group always correspond to + /// the entire match. + /// + /// # Example + /// + /// This example shows how to get the capturing groups, by index, from a + /// match: + /// + /// ``` + /// # if cfg!(miri) { return Ok(()); } // miri takes too long + /// # if !cfg!(target_pointer_width = "64") { return Ok(()); } // see #1039 + /// use regex_automata::{nfa::thompson::pikevm::PikeVM, Span, Match}; + /// + /// let re = PikeVM::new(r"^(?P<first>\pL+)\s+(?P<last>\pL+)$")?; + /// 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(2)); + /// // Looking for a non-existent capturing group will return None: + /// assert_eq!(None, caps.get_group(3)); + /// assert_eq!(None, caps.get_group(9944060567225171988)); + /// + /// # Ok::<(), Box<dyn std::error::Error>>(()) + /// ``` + #[inline] + pub fn get_group(&self, index: usize) -> Option<Span> { + let pid = self.pattern()?; + // There's a little bit of work needed to map captures to slots in the + // fully general case. But in the overwhelming common case of a single + // pattern, we can just do some simple arithmetic. + let (slot_start, slot_end) = if self.group_info().pattern_len() == 1 { + (index.checked_mul(2)?, index.checked_mul(2)?.checked_add(1)?) + } else { + self.group_info().slots(pid, index)? + }; + let start = self.slots.get(slot_start).copied()??; + let end = self.slots.get(slot_end).copied()??; + Some(Span { start: start.get(), end: end.get() }) + } + + /// Returns the span of a capturing group match corresponding to the group + /// name given, only if both the overall pattern matched and the capturing + /// group participated in that match. + /// + /// This returns `None` if `name` does not correspond to a valid capturing + /// group for the pattern that matched. + /// + /// This always returns `None` when `Captures` was created with + /// [`Captures::empty`], even if a match was found. This also always + /// returns `None` for any `index > 0` when `Captures` was created with + /// [`Captures::matches`]. + /// + /// If this routine returns a non-`None` value, then `is_match` is + /// guaranteed to return `true`, `pattern` is guaranteed to return a + /// non-`None` value and `get_match` is guaranteed to return a non-`None` + /// value. + /// + /// # Example + /// + /// This example shows how to get the capturing groups, by name, from a + /// match: + /// + /// ``` + /// # if cfg!(miri) { return Ok(()); } // miri takes too long + /// use regex_automata::{nfa::thompson::pikevm::PikeVM, Span, Match}; + /// + /// let re = PikeVM::new(r"^(?P<first>\pL+)\s+(?P<last>\pL+)$")?; + /// 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_by_name("first")); + /// assert_eq!(Some(Span::from(6..17)), caps.get_group_by_name("last")); + /// // Looking for a non-existent capturing group will return None: + /// assert_eq!(None, caps.get_group_by_name("middle")); + /// + /// # Ok::<(), Box<dyn std::error::Error>>(()) + /// ``` + pub fn get_group_by_name(&self, name: &str) -> Option<Span> { + let index = self.group_info().to_index(self.pattern()?, name)?; + self.get_group(index) + } + + /// Returns an iterator of possible spans for every capturing group in the + /// matching pattern. + /// + /// If this `Captures` value does not correspond to a match, then the + /// iterator returned yields no elements. + /// + /// Note that the iterator returned yields elements of type `Option<Span>`. + /// A span is present if and only if it corresponds to a capturing group + /// that participated in a match. + /// + /// # Example + /// + /// This example shows how to collect all capturing groups: + /// + /// ``` + /// # if cfg!(miri) { return Ok(()); } // miri takes too long + /// use regex_automata::{nfa::thompson::pikevm::PikeVM, Span}; + /// + /// let re = PikeVM::new( + /// // Matches first/last names, with an optional middle name. + /// r"^(?P<first>\pL+)\s+(?:(?P<middle>\pL+)\s+)?(?P<last>\pL+)$", + /// )?; + /// let (mut cache, mut caps) = (re.create_cache(), re.create_captures()); + /// + /// re.captures(&mut cache, "Harry James Potter", &mut caps); + /// assert!(caps.is_match()); + /// let groups: Vec<Option<Span>> = caps.iter().collect(); + /// assert_eq!(groups, vec![ + /// Some(Span::from(0..18)), + /// Some(Span::from(0..5)), + /// Some(Span::from(6..11)), + /// Some(Span::from(12..18)), + /// ]); + /// + /// # Ok::<(), Box<dyn std::error::Error>>(()) + /// ``` + /// + /// This example uses the same regex as the previous example, but with a + /// haystack that omits the middle name. This results in a capturing group + /// that is present in the elements yielded by the iterator but without a + /// match: + /// + /// ``` + /// # if cfg!(miri) { return Ok(()); } // miri takes too long + /// use regex_automata::{nfa::thompson::pikevm::PikeVM, Span}; + /// + /// let re = PikeVM::new( + /// // Matches first/last names, with an optional middle name. + /// r"^(?P<first>\pL+)\s+(?:(?P<middle>\pL+)\s+)?(?P<last>\pL+)$", + /// )?; + /// let (mut cache, mut caps) = (re.create_cache(), re.create_captures()); + /// + /// re.captures(&mut cache, "Harry Potter", &mut caps); + /// assert!(caps.is_match()); + /// let groups: Vec<Option<Span>> = caps.iter().collect(); + /// assert_eq!(groups, vec![ + /// Some(Span::from(0..12)), + /// Some(Span::from(0..5)), + /// None, + /// Some(Span::from(6..12)), + /// ]); + /// + /// # Ok::<(), Box<dyn std::error::Error>>(()) + /// ``` + pub fn iter(&self) -> CapturesPatternIter<'_> { + let names = self + .pattern() + .map_or(GroupInfoPatternNames::empty().enumerate(), |pid| { + self.group_info().pattern_names(pid).enumerate() + }); + CapturesPatternIter { caps: self, names } + } + + /// Return the total number of capturing groups for the matching pattern. + /// + /// If this `Captures` value does not correspond to a match, then this + /// always returns `0`. + /// + /// This always returns the same number of elements yielded by + /// [`Captures::iter`]. That is, the number includes capturing groups even + /// if they don't participate in the match. + /// + /// # Example + /// + /// This example shows how to count the total number of capturing groups + /// associated with a pattern. Notice that it includes groups that did not + /// participate in a match (just like `Captures::iter` does). + /// + /// ``` + /// # if cfg!(miri) { return Ok(()); } // miri takes too long + /// use regex_automata::nfa::thompson::pikevm::PikeVM; + /// + /// let re = PikeVM::new( + /// // Matches first/last names, with an optional middle name. + /// r"^(?P<first>\pL+)\s+(?:(?P<middle>\pL+)\s+)?(?P<last>\pL+)$", + /// )?; + /// let (mut cache, mut caps) = (re.create_cache(), re.create_captures()); + /// + /// re.captures(&mut cache, "Harry Potter", &mut caps); + /// assert_eq!(4, caps.group_len()); + /// + /// # Ok::<(), Box<dyn std::error::Error>>(()) + /// ``` + pub fn group_len(&self) -> usize { + let pid = match self.pattern() { + None => return 0, + Some(pid) => pid, + }; + self.group_info().group_len(pid) + } + + /// Returns a reference to the underlying group info on which these + /// captures are based. + /// + /// The difference between `GroupInfo` and `Captures` is that the former + /// defines the structure of capturing groups where as the latter is what + /// stores the actual match information. So where as `Captures` only gives + /// you access to the current match, `GroupInfo` lets you query any + /// information about all capturing groups, even ones for patterns that + /// weren't involved in a match. + /// + /// Note that a `GroupInfo` uses reference counting internally, so it may + /// be cloned cheaply. + /// + /// # Example + /// + /// This example shows how to get all capturing group names from the + /// underlying `GroupInfo`. Notice that we don't even need to run a + /// search. + /// + /// ``` + /// use regex_automata::{nfa::thompson::pikevm::PikeVM, PatternID}; + /// + /// let re = PikeVM::new_many(&[ + /// r"(?P<foo>a)", + /// r"(a)(b)", + /// r"ab", + /// r"(?P<bar>a)(?P<quux>a)", + /// r"(?P<foo>z)", + /// ])?; + /// let caps = re.create_captures(); + /// + /// let expected = vec![ + /// (PatternID::must(0), 0, None), + /// (PatternID::must(0), 1, Some("foo")), + /// (PatternID::must(1), 0, None), + /// (PatternID::must(1), 1, None), + /// (PatternID::must(1), 2, None), + /// (PatternID::must(2), 0, None), + /// (PatternID::must(3), 0, None), + /// (PatternID::must(3), 1, Some("bar")), + /// (PatternID::must(3), 2, Some("quux")), + /// (PatternID::must(4), 0, None), + /// (PatternID::must(4), 1, Some("foo")), + /// ]; + /// // We could also just use 're.get_nfa().group_info()'. + /// let got: Vec<(PatternID, usize, Option<&str>)> = + /// caps.group_info().all_names().collect(); + /// assert_eq!(expected, got); + /// + /// # Ok::<(), Box<dyn std::error::Error>>(()) + /// ``` + pub fn group_info(&self) -> &GroupInfo { + &self.group_info + } + + /// Interpolates the capture references in `replacement` with the + /// corresponding substrings in `haystack` matched by each reference. The + /// interpolated string is returned. + /// + /// See the [`interpolate` module](interpolate) for documentation on the + /// format of the replacement string. + /// + /// # Example + /// + /// This example shows how to use interpolation, and also shows how it + /// can work with multi-pattern regexes. + /// + /// ``` + /// use regex_automata::{nfa::thompson::pikevm::PikeVM, PatternID}; + /// + /// let re = PikeVM::new_many(&[ + /// r"(?<day>[0-9]{2})-(?<month>[0-9]{2})-(?<year>[0-9]{4})", + /// r"(?<year>[0-9]{4})-(?<month>[0-9]{2})-(?<day>[0-9]{2})", + /// ])?; + /// let mut cache = re.create_cache(); + /// let mut caps = re.create_captures(); + /// + /// let replacement = "year=$year, month=$month, day=$day"; + /// + /// // This matches the first pattern. + /// let hay = "On 14-03-2010, I became a Tenneessee lamb."; + /// re.captures(&mut cache, hay, &mut caps); + /// let result = caps.interpolate_string(hay, replacement); + /// assert_eq!("year=2010, month=03, day=14", result); + /// + /// // And this matches the second pattern. + /// let hay = "On 2010-03-14, I became a Tenneessee lamb."; + /// re.captures(&mut cache, hay, &mut caps); + /// let result = caps.interpolate_string(hay, replacement); + /// assert_eq!("year=2010, month=03, day=14", result); + /// + /// # Ok::<(), Box<dyn std::error::Error>>(()) + /// ``` + pub fn interpolate_string( + &self, + haystack: &str, + replacement: &str, + ) -> String { + let mut dst = String::new(); + self.interpolate_string_into(haystack, replacement, &mut dst); + dst + } + + /// Interpolates the capture references in `replacement` with the + /// corresponding substrings in `haystack` matched by each reference. The + /// interpolated string is written to `dst`. + /// + /// See the [`interpolate` module](interpolate) for documentation on the + /// format of the replacement string. + /// + /// # Example + /// + /// This example shows how to use interpolation, and also shows how it + /// can work with multi-pattern regexes. + /// + /// ``` + /// use regex_automata::{nfa::thompson::pikevm::PikeVM, PatternID}; + /// + /// let re = PikeVM::new_many(&[ + /// r"(?<day>[0-9]{2})-(?<month>[0-9]{2})-(?<year>[0-9]{4})", + /// r"(?<year>[0-9]{4})-(?<month>[0-9]{2})-(?<day>[0-9]{2})", + /// ])?; + /// let mut cache = re.create_cache(); + /// let mut caps = re.create_captures(); + /// + /// let replacement = "year=$year, month=$month, day=$day"; + /// + /// // This matches the first pattern. + /// let hay = "On 14-03-2010, I became a Tenneessee lamb."; + /// re.captures(&mut cache, hay, &mut caps); + /// let mut dst = String::new(); + /// caps.interpolate_string_into(hay, replacement, &mut dst); + /// assert_eq!("year=2010, month=03, day=14", dst); + /// + /// // And this matches the second pattern. + /// let hay = "On 2010-03-14, I became a Tenneessee lamb."; + /// re.captures(&mut cache, hay, &mut caps); + /// let mut dst = String::new(); + /// caps.interpolate_string_into(hay, replacement, &mut dst); + /// assert_eq!("year=2010, month=03, day=14", dst); + /// + /// # Ok::<(), Box<dyn std::error::Error>>(()) + /// ``` + pub fn interpolate_string_into( + &self, + haystack: &str, + replacement: &str, + dst: &mut String, + ) { + interpolate::string( + replacement, + |index, dst| { + let span = match self.get_group(index) { + None => return, + Some(span) => span, + }; + dst.push_str(&haystack[span]); + }, + |name| self.group_info().to_index(self.pattern()?, name), + dst, + ); + } + + /// Interpolates the capture references in `replacement` with the + /// corresponding substrings in `haystack` matched by each reference. The + /// interpolated byte string is returned. + /// + /// See the [`interpolate` module](interpolate) for documentation on the + /// format of the replacement string. + /// + /// # Example + /// + /// This example shows how to use interpolation, and also shows how it + /// can work with multi-pattern regexes. + /// + /// ``` + /// use regex_automata::{nfa::thompson::pikevm::PikeVM, PatternID}; + /// + /// let re = PikeVM::new_many(&[ + /// r"(?<day>[0-9]{2})-(?<month>[0-9]{2})-(?<year>[0-9]{4})", + /// r"(?<year>[0-9]{4})-(?<month>[0-9]{2})-(?<day>[0-9]{2})", + /// ])?; + /// let mut cache = re.create_cache(); + /// let mut caps = re.create_captures(); + /// + /// let replacement = b"year=$year, month=$month, day=$day"; + /// + /// // This matches the first pattern. + /// let hay = b"On 14-03-2010, I became a Tenneessee lamb."; + /// re.captures(&mut cache, hay, &mut caps); + /// let result = caps.interpolate_bytes(hay, replacement); + /// assert_eq!(&b"year=2010, month=03, day=14"[..], result); + /// + /// // And this matches the second pattern. + /// let hay = b"On 2010-03-14, I became a Tenneessee lamb."; + /// re.captures(&mut cache, hay, &mut caps); + /// let result = caps.interpolate_bytes(hay, replacement); + /// assert_eq!(&b"year=2010, month=03, day=14"[..], result); + /// + /// # Ok::<(), Box<dyn std::error::Error>>(()) + /// ``` + pub fn interpolate_bytes( + &self, + haystack: &[u8], + replacement: &[u8], + ) -> Vec<u8> { + let mut dst = vec![]; + self.interpolate_bytes_into(haystack, replacement, &mut dst); + dst + } + + /// Interpolates the capture references in `replacement` with the + /// corresponding substrings in `haystack` matched by each reference. The + /// interpolated byte string is written to `dst`. + /// + /// See the [`interpolate` module](interpolate) for documentation on the + /// format of the replacement string. + /// + /// # Example + /// + /// This example shows how to use interpolation, and also shows how it + /// can work with multi-pattern regexes. + /// + /// ``` + /// use regex_automata::{nfa::thompson::pikevm::PikeVM, PatternID}; + /// + /// let re = PikeVM::new_many(&[ + /// r"(?<day>[0-9]{2})-(?<month>[0-9]{2})-(?<year>[0-9]{4})", + /// r"(?<year>[0-9]{4})-(?<month>[0-9]{2})-(?<day>[0-9]{2})", + /// ])?; + /// let mut cache = re.create_cache(); + /// let mut caps = re.create_captures(); + /// + /// let replacement = b"year=$year, month=$month, day=$day"; + /// + /// // This matches the first pattern. + /// let hay = b"On 14-03-2010, I became a Tenneessee lamb."; + /// re.captures(&mut cache, hay, &mut caps); + /// let mut dst = vec![]; + /// caps.interpolate_bytes_into(hay, replacement, &mut dst); + /// assert_eq!(&b"year=2010, month=03, day=14"[..], dst); + /// + /// // And this matches the second pattern. + /// let hay = b"On 2010-03-14, I became a Tenneessee lamb."; + /// re.captures(&mut cache, hay, &mut caps); + /// let mut dst = vec![]; + /// caps.interpolate_bytes_into(hay, replacement, &mut dst); + /// assert_eq!(&b"year=2010, month=03, day=14"[..], dst); + /// + /// # Ok::<(), Box<dyn std::error::Error>>(()) + /// ``` + pub fn interpolate_bytes_into( + &self, + haystack: &[u8], + replacement: &[u8], + dst: &mut Vec<u8>, + ) { + interpolate::bytes( + replacement, + |index, dst| { + let span = match self.get_group(index) { + None => return, + Some(span) => span, + }; + dst.extend_from_slice(&haystack[span]); + }, + |name| self.group_info().to_index(self.pattern()?, name), + dst, + ); + } + + /// This is a convenience routine for extracting the substrings + /// corresponding to matching capture groups in the given `haystack`. The + /// `haystack` should be the same substring used to find the match spans in + /// this `Captures` value. + /// + /// This is identical to [`Captures::extract_bytes`], except it works with + /// `&str` instead of `&[u8]`. + /// + /// # Panics + /// + /// This panics if the number of explicit matching groups in this + /// `Captures` value is less than `N`. This also panics if this `Captures` + /// value does not correspond to a match. + /// + /// Note that this does *not* panic if the number of explicit matching + /// groups is bigger than `N`. In that case, only the first `N` matching + /// groups are extracted. + /// + /// # Example + /// + /// ``` + /// use regex_automata::nfa::thompson::pikevm::PikeVM; + /// + /// let re = PikeVM::new(r"([0-9]{4})-([0-9]{2})-([0-9]{2})")?; + /// let mut cache = re.create_cache(); + /// let mut caps = re.create_captures(); + /// + /// let hay = "On 2010-03-14, I became a Tenneessee lamb."; + /// re.captures(&mut cache, hay, &mut caps); + /// assert!(caps.is_match()); + /// let (full, [year, month, day]) = caps.extract(hay); + /// assert_eq!("2010-03-14", full); + /// assert_eq!("2010", year); + /// assert_eq!("03", month); + /// assert_eq!("14", day); + /// + /// // We can also ask for fewer than all capture groups. + /// let (full, [year]) = caps.extract(hay); + /// assert_eq!("2010-03-14", full); + /// assert_eq!("2010", year); + /// + /// # Ok::<(), Box<dyn std::error::Error>>(()) + /// ``` + pub fn extract<'h, const N: usize>( + &self, + haystack: &'h str, + ) -> (&'h str, [&'h str; N]) { + let mut matched = self.iter().flatten(); + let whole_match = &haystack[matched.next().expect("a match")]; + let group_matches = [0; N].map(|_| { + let sp = matched.next().expect("too few matching groups"); + &haystack[sp] + }); + (whole_match, group_matches) + } + + /// This is a convenience routine for extracting the substrings + /// corresponding to matching capture groups in the given `haystack`. The + /// `haystack` should be the same substring used to find the match spans in + /// this `Captures` value. + /// + /// This is identical to [`Captures::extract`], except it works with + /// `&[u8]` instead of `&str`. + /// + /// # Panics + /// + /// This panics if the number of explicit matching groups in this + /// `Captures` value is less than `N`. This also panics if this `Captures` + /// value does not correspond to a match. + /// + /// Note that this does *not* panic if the number of explicit matching + /// groups is bigger than `N`. In that case, only the first `N` matching + /// groups are extracted. + /// + /// # Example + /// + /// ``` + /// use regex_automata::nfa::thompson::pikevm::PikeVM; + /// + /// let re = PikeVM::new(r"([0-9]{4})-([0-9]{2})-([0-9]{2})")?; + /// let mut cache = re.create_cache(); + /// let mut caps = re.create_captures(); + /// + /// let hay = b"On 2010-03-14, I became a Tenneessee lamb."; + /// re.captures(&mut cache, hay, &mut caps); + /// assert!(caps.is_match()); + /// let (full, [year, month, day]) = caps.extract_bytes(hay); + /// assert_eq!(b"2010-03-14", full); + /// assert_eq!(b"2010", year); + /// assert_eq!(b"03", month); + /// assert_eq!(b"14", day); + /// + /// // We can also ask for fewer than all capture groups. + /// let (full, [year]) = caps.extract_bytes(hay); + /// assert_eq!(b"2010-03-14", full); + /// assert_eq!(b"2010", year); + /// + /// # Ok::<(), Box<dyn std::error::Error>>(()) + /// ``` + pub fn extract_bytes<'h, const N: usize>( + &self, + haystack: &'h [u8], + ) -> (&'h [u8], [&'h [u8]; N]) { + let mut matched = self.iter().flatten(); + let whole_match = &haystack[matched.next().expect("a match")]; + let group_matches = [0; N].map(|_| { + let sp = matched.next().expect("too few matching groups"); + &haystack[sp] + }); + (whole_match, group_matches) + } +} + +/// Lower level "slot" oriented APIs. One does not typically need to use these +/// when executing a search. They are instead mostly intended for folks that +/// are writing their own regex engine while reusing this `Captures` type. +impl Captures { + /// Clear this `Captures` value. + /// + /// After clearing, all slots inside this `Captures` value will be set to + /// `None`. Similarly, any pattern ID that it was previously associated + /// with (for a match) is erased. + /// + /// It is not usually necessary to call this routine. Namely, a `Captures` + /// value only provides high level access to the capturing groups of the + /// pattern that matched, and only low level access to individual slots. + /// Thus, even if slots corresponding to groups that aren't associated + /// with the matching pattern are set, then it won't impact the higher + /// level APIs. Namely, higher level APIs like [`Captures::get_group`] will + /// return `None` if no pattern ID is present, even if there are spans set + /// in the underlying slots. + /// + /// Thus, to "clear" a `Captures` value of a match, it is usually only + /// necessary to call [`Captures::set_pattern`] with `None`. + /// + /// # Example + /// + /// This example shows what happens when a `Captures` value is cleared. + /// + /// ``` + /// # if cfg!(miri) { return Ok(()); } // miri takes too long + /// use regex_automata::nfa::thompson::pikevm::PikeVM; + /// + /// let re = PikeVM::new(r"^(?P<first>\pL+)\s+(?P<last>\pL+)$")?; + /// let (mut cache, mut caps) = (re.create_cache(), re.create_captures()); + /// + /// re.captures(&mut cache, "Bruce Springsteen", &mut caps); + /// assert!(caps.is_match()); + /// let slots: Vec<Option<usize>> = + /// caps.slots().iter().map(|s| s.map(|x| x.get())).collect(); + /// // Note that the following ordering is considered an API guarantee. + /// assert_eq!(slots, vec![ + /// Some(0), + /// Some(17), + /// Some(0), + /// Some(5), + /// Some(6), + /// Some(17), + /// ]); + /// + /// // Now clear the slots. Everything is gone and it is no longer a match. + /// caps.clear(); + /// assert!(!caps.is_match()); + /// let slots: Vec<Option<usize>> = + /// caps.slots().iter().map(|s| s.map(|x| x.get())).collect(); + /// assert_eq!(slots, vec![ + /// None, + /// None, + /// None, + /// None, + /// None, + /// None, + /// ]); + /// + /// # Ok::<(), Box<dyn std::error::Error>>(()) + /// ``` + #[inline] + pub fn clear(&mut self) { + self.pid = None; + for slot in self.slots.iter_mut() { + *slot = None; + } + } + + /// Set the pattern on this `Captures` value. + /// + /// When the pattern ID is `None`, then this `Captures` value does not + /// correspond to a match (`is_match` will return `false`). Otherwise, it + /// corresponds to a match. + /// + /// This is useful in search implementations where you might want to + /// initially call `set_pattern(None)` in order to avoid the cost of + /// calling `clear()` if it turns out to not be necessary. + /// + /// # Example + /// + /// This example shows that `set_pattern` merely overwrites the pattern ID. + /// It does not actually change the underlying slot values. + /// + /// ``` + /// # if cfg!(miri) { return Ok(()); } // miri takes too long + /// use regex_automata::nfa::thompson::pikevm::PikeVM; + /// + /// let re = PikeVM::new(r"^(?P<first>\pL+)\s+(?P<last>\pL+)$")?; + /// let (mut cache, mut caps) = (re.create_cache(), re.create_captures()); + /// + /// re.captures(&mut cache, "Bruce Springsteen", &mut caps); + /// assert!(caps.is_match()); + /// assert!(caps.pattern().is_some()); + /// let slots: Vec<Option<usize>> = + /// caps.slots().iter().map(|s| s.map(|x| x.get())).collect(); + /// // Note that the following ordering is considered an API guarantee. + /// assert_eq!(slots, vec![ + /// Some(0), + /// Some(17), + /// Some(0), + /// Some(5), + /// Some(6), + /// Some(17), + /// ]); + /// + /// // Now set the pattern to None. Note that the slot values remain. + /// caps.set_pattern(None); + /// assert!(!caps.is_match()); + /// assert!(!caps.pattern().is_some()); + /// let slots: Vec<Option<usize>> = + /// caps.slots().iter().map(|s| s.map(|x| x.get())).collect(); + /// // Note that the following ordering is considered an API guarantee. + /// assert_eq!(slots, vec![ + /// Some(0), + /// Some(17), + /// Some(0), + /// Some(5), + /// Some(6), + /// Some(17), + /// ]); + /// + /// # Ok::<(), Box<dyn std::error::Error>>(()) + /// ``` + #[inline] + pub fn set_pattern(&mut self, pid: Option<PatternID>) { + self.pid = pid; + } + + /// Returns the underlying slots, where each slot stores a single offset. + /// + /// Every matching capturing group generally corresponds to two slots: one + /// slot for the starting position and another for the ending position. + /// Typically, either both are present or neither are. (The weasel word + /// "typically" is used here because it really depends on the regex engine + /// implementation. Every sensible regex engine likely adheres to this + /// invariant, and every regex engine in this crate is sensible.) + /// + /// Generally speaking, callers should prefer to use higher level routines + /// like [`Captures::get_match`] or [`Captures::get_group`]. + /// + /// An important note here is that a regex engine may not reset all of the + /// slots to `None` values when no match occurs, or even when a match of + /// a different pattern occurs. But this depends on how the regex engine + /// implementation deals with slots. + /// + /// # Example + /// + /// This example shows how to get the underlying slots from a regex match. + /// + /// ``` + /// use regex_automata::{ + /// nfa::thompson::pikevm::PikeVM, + /// util::primitives::{PatternID, NonMaxUsize}, + /// }; + /// + /// let re = PikeVM::new_many(&[ + /// r"[a-z]+", + /// r"[0-9]+", + /// ])?; + /// let (mut cache, mut caps) = (re.create_cache(), re.create_captures()); + /// + /// re.captures(&mut cache, "123", &mut caps); + /// assert_eq!(Some(PatternID::must(1)), caps.pattern()); + /// // Note that the only guarantee we have here is that slots 2 and 3 + /// // are set to correct values. The contents of the first two slots are + /// // unspecified since the 0th pattern did not match. + /// let expected = &[ + /// None, + /// None, + /// NonMaxUsize::new(0), + /// NonMaxUsize::new(3), + /// ]; + /// assert_eq!(expected, caps.slots()); + /// + /// # Ok::<(), Box<dyn std::error::Error>>(()) + /// ``` + #[inline] + pub fn slots(&self) -> &[Option<NonMaxUsize>] { + &self.slots + } + + /// Returns the underlying slots as a mutable slice, where each slot stores + /// a single offset. + /// + /// This tends to be most useful for regex engine implementations for + /// writing offsets for matching capturing groups to slots. + /// + /// See [`Captures::slots`] for more information about slots. + #[inline] + pub fn slots_mut(&mut self) -> &mut [Option<NonMaxUsize>] { + &mut self.slots + } +} + +impl core::fmt::Debug for Captures { + fn fmt(&self, f: &mut core::fmt::Formatter) -> core::fmt::Result { + let mut dstruct = f.debug_struct("Captures"); + dstruct.field("pid", &self.pid); + if let Some(pid) = self.pid { + dstruct.field("spans", &CapturesDebugMap { pid, caps: self }); + } + dstruct.finish() + } +} + +/// A little helper type to provide a nice map-like debug representation for +/// our capturing group spans. +struct CapturesDebugMap<'a> { + pid: PatternID, + caps: &'a Captures, +} + +impl<'a> core::fmt::Debug for CapturesDebugMap<'a> { + fn fmt(&self, f: &mut core::fmt::Formatter) -> core::fmt::Result { + struct Key<'a>(usize, Option<&'a str>); + + impl<'a> core::fmt::Debug for Key<'a> { + fn fmt(&self, f: &mut core::fmt::Formatter) -> core::fmt::Result { + write!(f, "{}", self.0)?; + if let Some(name) = self.1 { + write!(f, "/{:?}", name)?; + } + Ok(()) + } + } + + let mut map = f.debug_map(); + let names = self.caps.group_info().pattern_names(self.pid); + for (group_index, maybe_name) in names.enumerate() { + let key = Key(group_index, maybe_name); + match self.caps.get_group(group_index) { + None => map.entry(&key, &None::<()>), + Some(span) => map.entry(&key, &span), + }; + } + map.finish() + } +} + +/// An iterator over all capturing groups in a `Captures` value. +/// +/// This iterator includes capturing groups that did not participate in a +/// match. See the [`Captures::iter`] method documentation for more details +/// and examples. +/// +/// The lifetime parameter `'a` refers to the lifetime of the underlying +/// `Captures` value. +#[derive(Clone, Debug)] +pub struct CapturesPatternIter<'a> { + caps: &'a Captures, + names: core::iter::Enumerate<GroupInfoPatternNames<'a>>, +} + +impl<'a> Iterator for CapturesPatternIter<'a> { + type Item = Option<Span>; + + fn next(&mut self) -> Option<Option<Span>> { + let (group_index, _) = self.names.next()?; + Some(self.caps.get_group(group_index)) + } + + fn size_hint(&self) -> (usize, Option<usize>) { + self.names.size_hint() + } + + fn count(self) -> usize { + self.names.count() + } +} + +impl<'a> ExactSizeIterator for CapturesPatternIter<'a> {} +impl<'a> core::iter::FusedIterator for CapturesPatternIter<'a> {} + +/// Represents information about capturing groups in a compiled regex. +/// +/// The information encapsulated by this type consists of the following. For +/// each pattern: +/// +/// * A map from every capture group name to its corresponding capture group +/// index. +/// * A map from every capture group index to its corresponding capture group +/// name. +/// * A map from capture group index to its corresponding slot index. A slot +/// refers to one half of a capturing group. That is, a capture slot is either +/// the start or end of a capturing group. A slot is usually the mechanism +/// by which a regex engine records offsets for each capturing group during a +/// search. +/// +/// A `GroupInfo` uses reference counting internally and is thus cheap to +/// clone. +/// +/// # Mapping from capture groups to slots +/// +/// One of the main responsibilities of a `GroupInfo` is to build a mapping +/// from `(PatternID, u32)` (where the `u32` is a capture index) to something +/// called a "slot." As mentioned above, a slot refers to one half of a +/// capturing group. Both combined provide the start and end offsets of +/// a capturing group that participated in a match. +/// +/// **The mapping between group indices and slots is an API guarantee.** That +/// is, the mapping won't change within a semver compatible release. +/// +/// Slots exist primarily because this is a convenient mechanism by which +/// regex engines report group offsets at search time. For example, the +/// [`nfa::thompson::State::Capture`](crate::nfa::thompson::State::Capture) +/// NFA state includes the slot index. When a regex engine transitions through +/// this state, it will likely use the slot index to write the current haystack +/// offset to some region of memory. When a match is found, those slots are +/// then reported to the caller, typically via a convenient abstraction like a +/// [`Captures`] value. +/// +/// Because this crate provides first class support for multi-pattern regexes, +/// and because of some performance related reasons, the mapping between +/// capturing groups and slots is a little complex. However, in the case of a +/// single pattern, the mapping can be described very simply: for all capture +/// group indices `i`, its corresponding slots are at `i * 2` and `i * 2 + 1`. +/// Notice that the pattern ID isn't involved at all here, because it only +/// applies to a single-pattern regex, it is therefore always `0`. +/// +/// In the multi-pattern case, the mapping is a bit more complicated. To talk +/// about it, we must define what we mean by "implicit" vs "explicit" +/// capturing groups: +/// +/// * An **implicit** capturing group refers to the capturing group that is +/// present for every pattern automatically, and corresponds to the overall +/// match of a pattern. Every pattern has precisely one implicit capturing +/// group. It is always unnamed and it always corresponds to the capture group +/// index `0`. +/// * An **explicit** capturing group refers to any capturing group that +/// appears in the concrete syntax of the pattern. (Or, if an NFA was hand +/// built without any concrete syntax, it refers to any capturing group with an +/// index greater than `0`.) +/// +/// Some examples: +/// +/// * `\w+` has one implicit capturing group and zero explicit capturing +/// groups. +/// * `(\w+)` has one implicit group and one explicit group. +/// * `foo(\d+)(?:\pL+)(\d+)` has one implicit group and two explicit groups. +/// +/// Turning back to the slot mapping, we can now state it as follows: +/// +/// * Given a pattern ID `pid`, the slots for its implicit group are always +/// at `pid * 2` and `pid * 2 + 1`. +/// * Given a pattern ID `0`, the slots for its explicit groups start +/// at `group_info.pattern_len() * 2`. +/// * Given a pattern ID `pid > 0`, the slots for its explicit groups start +/// immediately following where the slots for the explicit groups of `pid - 1` +/// end. +/// +/// In particular, while there is a concrete formula one can use to determine +/// where the slots for the implicit group of any pattern are, there is no +/// general formula for determining where the slots for explicit capturing +/// groups are. This is because each pattern can contain a different number +/// of groups. +/// +/// The intended way of getting the slots for a particular capturing group +/// (whether implicit or explicit) is via the [`GroupInfo::slot`] or +/// [`GroupInfo::slots`] method. +/// +/// See below for a concrete example of how capturing groups get mapped to +/// slots. +/// +/// # Example +/// +/// This example shows how to build a new `GroupInfo` and query it for +/// information. +/// +/// ``` +/// use regex_automata::util::{captures::GroupInfo, primitives::PatternID}; +/// +/// let info = GroupInfo::new(vec![ +/// vec![None, Some("foo")], +/// vec![None], +/// vec![None, None, None, Some("bar"), None], +/// vec![None, None, Some("foo")], +/// ])?; +/// // The number of patterns being tracked. +/// assert_eq!(4, info.pattern_len()); +/// // We can query the number of groups for any pattern. +/// assert_eq!(2, info.group_len(PatternID::must(0))); +/// assert_eq!(1, info.group_len(PatternID::must(1))); +/// assert_eq!(5, info.group_len(PatternID::must(2))); +/// assert_eq!(3, info.group_len(PatternID::must(3))); +/// // An invalid pattern always has zero groups. +/// assert_eq!(0, info.group_len(PatternID::must(999))); +/// // 2 slots per group +/// assert_eq!(22, info.slot_len()); +/// +/// // We can map a group index for a particular pattern to its name, if +/// // one exists. +/// assert_eq!(Some("foo"), info.to_name(PatternID::must(3), 2)); +/// assert_eq!(None, info.to_name(PatternID::must(2), 4)); +/// // Or map a name to its group index. +/// assert_eq!(Some(1), info.to_index(PatternID::must(0), "foo")); +/// assert_eq!(Some(2), info.to_index(PatternID::must(3), "foo")); +/// +/// # Ok::<(), Box<dyn std::error::Error>>(()) +/// ``` +/// +/// # Example: mapping from capture groups to slots +/// +/// This example shows the specific mapping from capture group indices for +/// each pattern to their corresponding slots. The slot values shown in this +/// example are considered an API guarantee. +/// +/// ``` +/// use regex_automata::util::{captures::GroupInfo, primitives::PatternID}; +/// +/// let info = GroupInfo::new(vec![ +/// vec![None, Some("foo")], +/// vec![None], +/// vec![None, None, None, Some("bar"), None], +/// vec![None, None, Some("foo")], +/// ])?; +/// +/// // We first show the slots for each pattern's implicit group. +/// assert_eq!(Some((0, 1)), info.slots(PatternID::must(0), 0)); +/// assert_eq!(Some((2, 3)), info.slots(PatternID::must(1), 0)); +/// assert_eq!(Some((4, 5)), info.slots(PatternID::must(2), 0)); +/// assert_eq!(Some((6, 7)), info.slots(PatternID::must(3), 0)); +/// +/// // And now we show the slots for each pattern's explicit group. +/// assert_eq!(Some((8, 9)), info.slots(PatternID::must(0), 1)); +/// assert_eq!(Some((10, 11)), info.slots(PatternID::must(2), 1)); +/// assert_eq!(Some((12, 13)), info.slots(PatternID::must(2), 2)); +/// assert_eq!(Some((14, 15)), info.slots(PatternID::must(2), 3)); +/// assert_eq!(Some((16, 17)), info.slots(PatternID::must(2), 4)); +/// assert_eq!(Some((18, 19)), info.slots(PatternID::must(3), 1)); +/// assert_eq!(Some((20, 21)), info.slots(PatternID::must(3), 2)); +/// +/// // Asking for the slots for an invalid pattern ID or even for an invalid +/// // group index for a specific pattern will return None. So for example, +/// // you're guaranteed to not get the slots for a different pattern than the +/// // one requested. +/// assert_eq!(None, info.slots(PatternID::must(5), 0)); +/// assert_eq!(None, info.slots(PatternID::must(1), 1)); +/// +/// # Ok::<(), Box<dyn std::error::Error>>(()) +/// ``` +#[derive(Clone, Debug, Default)] +pub struct GroupInfo(Arc<GroupInfoInner>); + +impl GroupInfo { + /// Creates a new group info from a sequence of patterns, where each + /// sequence of patterns yields a sequence of possible group names. The + /// index of each pattern in the sequence corresponds to its `PatternID`, + /// and the index of each group in each pattern's sequence corresponds to + /// its corresponding group index. + /// + /// While this constructor is very generic and therefore perhaps hard to + /// chew on, an example of a valid concrete type that can be passed to + /// this constructor is `Vec<Vec<Option<String>>>`. The outer `Vec` + /// corresponds to the patterns, i.e., one `Vec<Option<String>>` per + /// pattern. The inner `Vec` corresponds to the capturing groups for + /// each pattern. The `Option<String>` corresponds to the name of the + /// capturing group, if present. + /// + /// It is legal to pass an empty iterator to this constructor. It will + /// return an empty group info with zero slots. An empty group info is + /// useful for cases where you have no patterns or for cases where slots + /// aren't being used at all (e.g., for most DFAs in this crate). + /// + /// # Errors + /// + /// This constructor returns an error if the given capturing groups are + /// invalid in some way. Those reasons include, but are not necessarily + /// limited to: + /// + /// * Too many patterns (i.e., `PatternID` would overflow). + /// * Too many capturing groups (e.g., `u32` would overflow). + /// * A pattern is given that has no capturing groups. (All patterns must + /// have at least an implicit capturing group at index `0`.) + /// * The capturing group at index `0` has a name. It must be unnamed. + /// * There are duplicate capturing group names within the same pattern. + /// (Multiple capturing groups with the same name may exist, but they + /// must be in different patterns.) + /// + /// An example below shows how to trigger some of the above error + /// conditions. + /// + /// # Example + /// + /// This example shows how to build a new `GroupInfo` and query it for + /// information. + /// + /// ``` + /// use regex_automata::util::captures::GroupInfo; + /// + /// let info = GroupInfo::new(vec![ + /// vec![None, Some("foo")], + /// vec![None], + /// vec![None, None, None, Some("bar"), None], + /// vec![None, None, Some("foo")], + /// ])?; + /// // The number of patterns being tracked. + /// assert_eq!(4, info.pattern_len()); + /// // 2 slots per group + /// assert_eq!(22, info.slot_len()); + /// + /// # Ok::<(), Box<dyn std::error::Error>>(()) + /// ``` + /// + /// # Example: empty `GroupInfo` + /// + /// This example shows how to build a new `GroupInfo` and query it for + /// information. + /// + /// ``` + /// use regex_automata::util::captures::GroupInfo; + /// + /// let info = GroupInfo::empty(); + /// // Everything is zero. + /// assert_eq!(0, info.pattern_len()); + /// assert_eq!(0, info.slot_len()); + /// + /// # Ok::<(), Box<dyn std::error::Error>>(()) + /// ``` + /// + /// # Example: error conditions + /// + /// This example shows how to provoke some of the ways in which building + /// a `GroupInfo` can fail. + /// + /// ``` + /// use regex_automata::util::captures::GroupInfo; + /// + /// // Either the group info is empty, or all patterns must have at least + /// // one capturing group. + /// assert!(GroupInfo::new(vec![ + /// vec![None, Some("a")], // ok + /// vec![None], // ok + /// vec![], // not ok + /// ]).is_err()); + /// // Note that building an empty group info is OK. + /// assert!(GroupInfo::new(Vec::<Vec<Option<String>>>::new()).is_ok()); + /// + /// // The first group in each pattern must correspond to an implicit + /// // anonymous group. i.e., One that is not named. By convention, this + /// // group corresponds to the overall match of a regex. Every other group + /// // in a pattern is explicit and optional. + /// assert!(GroupInfo::new(vec![vec![Some("foo")]]).is_err()); + /// + /// // There must not be duplicate group names within the same pattern. + /// assert!(GroupInfo::new(vec![ + /// vec![None, Some("foo"), Some("foo")], + /// ]).is_err()); + /// // But duplicate names across distinct patterns is OK. + /// assert!(GroupInfo::new(vec![ + /// vec![None, Some("foo")], + /// vec![None, Some("foo")], + /// ]).is_ok()); + /// + /// # Ok::<(), Box<dyn std::error::Error>>(()) + /// ``` + /// + /// There are other ways for building a `GroupInfo` to fail but are + /// difficult to show. For example, if the number of patterns given would + /// overflow `PatternID`. + pub fn new<P, G, N>(pattern_groups: P) -> Result<GroupInfo, GroupInfoError> + where + P: IntoIterator<Item = G>, + G: IntoIterator<Item = Option<N>>, + N: AsRef<str>, + { + let mut group_info = GroupInfoInner { + slot_ranges: vec![], + name_to_index: vec![], + index_to_name: vec![], + memory_extra: 0, + }; + for (pattern_index, groups) in pattern_groups.into_iter().enumerate() { + // If we can't convert the pattern index to an ID, then the caller + // tried to build capture info for too many patterns. + let pid = PatternID::new(pattern_index) + .map_err(GroupInfoError::too_many_patterns)?; + + let mut groups_iter = groups.into_iter().enumerate(); + match groups_iter.next() { + None => return Err(GroupInfoError::missing_groups(pid)), + Some((_, Some(_))) => { + return Err(GroupInfoError::first_must_be_unnamed(pid)) + } + Some((_, None)) => {} + } + group_info.add_first_group(pid); + // Now iterate over the rest, which correspond to all of the + // (conventionally) explicit capture groups in a regex pattern. + for (group_index, maybe_name) in groups_iter { + // Just like for patterns, if the group index can't be + // converted to a "small" index, then the caller has given too + // many groups for a particular pattern. + let group = SmallIndex::new(group_index).map_err(|_| { + GroupInfoError::too_many_groups(pid, group_index) + })?; + group_info.add_explicit_group(pid, group, maybe_name)?; + } + } + group_info.fixup_slot_ranges()?; + Ok(GroupInfo(Arc::new(group_info))) + } + + /// This creates an empty `GroupInfo`. + /// + /// This is a convenience routine for calling `GroupInfo::new` with an + /// iterator that yields no elements. + /// + /// # Example + /// + /// This example shows how to build a new empty `GroupInfo` and query it + /// for information. + /// + /// ``` + /// use regex_automata::util::captures::GroupInfo; + /// + /// let info = GroupInfo::empty(); + /// // Everything is zero. + /// assert_eq!(0, info.pattern_len()); + /// assert_eq!(0, info.all_group_len()); + /// assert_eq!(0, info.slot_len()); + /// + /// # Ok::<(), Box<dyn std::error::Error>>(()) + /// ``` + pub fn empty() -> GroupInfo { + GroupInfo::new(core::iter::empty::<[Option<&str>; 0]>()) + .expect("empty group info is always valid") + } + + /// Return the capture group index corresponding to the given name in the + /// given pattern. If no such capture group name exists in the given + /// pattern, then this returns `None`. + /// + /// If the given pattern ID is invalid, then this returns `None`. + /// + /// This also returns `None` for all inputs if these captures are empty + /// (e.g., built from an empty [`GroupInfo`]). To check whether captures + /// are are present for a specific pattern, use [`GroupInfo::group_len`]. + /// + /// # Example + /// + /// This example shows how to find the capture index for the given pattern + /// and group name. + /// + /// Remember that capture indices are relative to the pattern, such that + /// the same capture index value may refer to different capturing groups + /// for distinct patterns. + /// + /// ``` + /// # if cfg!(miri) { return Ok(()); } // miri takes too long + /// use regex_automata::{nfa::thompson::NFA, PatternID}; + /// + /// let (pid0, pid1) = (PatternID::must(0), PatternID::must(1)); + /// + /// let nfa = NFA::new_many(&[ + /// r"a(?P<quux>\w+)z(?P<foo>\s+)", + /// r"a(?P<foo>\d+)z", + /// ])?; + /// let groups = nfa.group_info(); + /// assert_eq!(Some(2), groups.to_index(pid0, "foo")); + /// // Recall that capture index 0 is always unnamed and refers to the + /// // entire pattern. So the first capturing group present in the pattern + /// // itself always starts at index 1. + /// assert_eq!(Some(1), groups.to_index(pid1, "foo")); + /// + /// // And if a name does not exist for a particular pattern, None is + /// // returned. + /// assert!(groups.to_index(pid0, "quux").is_some()); + /// assert!(groups.to_index(pid1, "quux").is_none()); + /// + /// # Ok::<(), Box<dyn std::error::Error>>(()) + /// ``` + #[inline] + pub fn to_index(&self, pid: PatternID, name: &str) -> Option<usize> { + let indices = self.0.name_to_index.get(pid.as_usize())?; + indices.get(name).cloned().map(|i| i.as_usize()) + } + + /// Return the capture name for the given index and given pattern. If the + /// corresponding group does not have a name, then this returns `None`. + /// + /// If the pattern ID is invalid, then this returns `None`. + /// + /// If the group index is invalid for the given pattern, then this returns + /// `None`. A group `index` is valid for a pattern `pid` in an `nfa` if and + /// only if `index < nfa.pattern_capture_len(pid)`. + /// + /// This also returns `None` for all inputs if these captures are empty + /// (e.g., built from an empty [`GroupInfo`]). To check whether captures + /// are are present for a specific pattern, use [`GroupInfo::group_len`]. + /// + /// # Example + /// + /// This example shows how to find the capture group name for the given + /// pattern and group index. + /// + /// ``` + /// # if cfg!(miri) { return Ok(()); } // miri takes too long + /// use regex_automata::{nfa::thompson::NFA, PatternID}; + /// + /// let (pid0, pid1) = (PatternID::must(0), PatternID::must(1)); + /// + /// let nfa = NFA::new_many(&[ + /// r"a(?P<foo>\w+)z(\s+)x(\d+)", + /// r"a(\d+)z(?P<foo>\s+)", + /// ])?; + /// let groups = nfa.group_info(); + /// assert_eq!(None, groups.to_name(pid0, 0)); + /// assert_eq!(Some("foo"), groups.to_name(pid0, 1)); + /// assert_eq!(None, groups.to_name(pid0, 2)); + /// assert_eq!(None, groups.to_name(pid0, 3)); + /// + /// assert_eq!(None, groups.to_name(pid1, 0)); + /// assert_eq!(None, groups.to_name(pid1, 1)); + /// assert_eq!(Some("foo"), groups.to_name(pid1, 2)); + /// // '3' is not a valid capture index for the second pattern. + /// assert_eq!(None, groups.to_name(pid1, 3)); + /// + /// # Ok::<(), Box<dyn std::error::Error>>(()) + /// ``` + #[inline] + pub fn to_name(&self, pid: PatternID, group_index: usize) -> Option<&str> { + let pattern_names = self.0.index_to_name.get(pid.as_usize())?; + pattern_names.get(group_index)?.as_deref() + } + + /// Return an iterator of all capture groups and their names (if present) + /// for a particular pattern. + /// + /// If the given pattern ID is invalid or if this `GroupInfo` is empty, + /// then the iterator yields no elements. + /// + /// The number of elements yielded by this iterator is always equal to + /// the result of calling [`GroupInfo::group_len`] with the same + /// `PatternID`. + /// + /// # Example + /// + /// This example shows how to get a list of all capture group names for + /// a particular pattern. + /// + /// ``` + /// use regex_automata::{nfa::thompson::NFA, PatternID}; + /// + /// let nfa = NFA::new(r"(a)(?P<foo>b)(c)(d)(?P<bar>e)")?; + /// // The first is the implicit group that is always unnammed. The next + /// // 5 groups are the explicit groups found in the concrete syntax above. + /// let expected = vec![None, None, Some("foo"), None, None, Some("bar")]; + /// let got: Vec<Option<&str>> = + /// nfa.group_info().pattern_names(PatternID::ZERO).collect(); + /// assert_eq!(expected, got); + /// + /// // Using an invalid pattern ID will result in nothing yielded. + /// let got = nfa.group_info().pattern_names(PatternID::must(999)).count(); + /// assert_eq!(0, got); + /// + /// # Ok::<(), Box<dyn std::error::Error>>(()) + /// ``` + #[inline] + pub fn pattern_names(&self, pid: PatternID) -> GroupInfoPatternNames<'_> { + GroupInfoPatternNames { + it: self + .0 + .index_to_name + .get(pid.as_usize()) + .map(|indices| indices.iter()) + .unwrap_or([].iter()), + } + } + + /// Return an iterator of all capture groups for all patterns supported by + /// this `GroupInfo`. Each item yielded is a triple of the group's pattern + /// ID, index in the pattern and the group's name, if present. + /// + /// # Example + /// + /// This example shows how to get a list of all capture groups found in + /// one NFA, potentially spanning multiple patterns. + /// + /// ``` + /// use regex_automata::{nfa::thompson::NFA, PatternID}; + /// + /// let nfa = NFA::new_many(&[ + /// r"(?P<foo>a)", + /// r"a", + /// r"(a)", + /// ])?; + /// let expected = vec![ + /// (PatternID::must(0), 0, None), + /// (PatternID::must(0), 1, Some("foo")), + /// (PatternID::must(1), 0, None), + /// (PatternID::must(2), 0, None), + /// (PatternID::must(2), 1, None), + /// ]; + /// let got: Vec<(PatternID, usize, Option<&str>)> = + /// nfa.group_info().all_names().collect(); + /// assert_eq!(expected, got); + /// + /// # Ok::<(), Box<dyn std::error::Error>>(()) + /// ``` + /// + /// Unlike other capturing group related routines, this routine doesn't + /// panic even if captures aren't enabled on this NFA: + /// + /// ``` + /// use regex_automata::nfa::thompson::{NFA, WhichCaptures}; + /// + /// let nfa = NFA::compiler() + /// .configure(NFA::config().which_captures(WhichCaptures::None)) + /// .build_many(&[ + /// r"(?P<foo>a)", + /// r"a", + /// r"(a)", + /// ])?; + /// // When captures aren't enabled, there's nothing to return. + /// assert_eq!(0, nfa.group_info().all_names().count()); + /// + /// # Ok::<(), Box<dyn std::error::Error>>(()) + /// ``` + #[inline] + pub fn all_names(&self) -> GroupInfoAllNames<'_> { + GroupInfoAllNames { + group_info: self, + pids: PatternID::iter(self.pattern_len()), + current_pid: None, + names: None, + } + } + + /// Returns the starting and ending slot corresponding to the given + /// capturing group for the given pattern. The ending slot is always one + /// more than the starting slot returned. + /// + /// Note that this is like [`GroupInfo::slot`], except that it also returns + /// the ending slot value for convenience. + /// + /// If either the pattern ID or the capture index is invalid, then this + /// returns None. + /// + /// # Example + /// + /// This example shows that the starting slots for the first capturing + /// group of each pattern are distinct. + /// + /// ``` + /// use regex_automata::{nfa::thompson::NFA, PatternID}; + /// + /// let nfa = NFA::new_many(&["a", "b"])?; + /// assert_ne!( + /// nfa.group_info().slots(PatternID::must(0), 0), + /// nfa.group_info().slots(PatternID::must(1), 0), + /// ); + /// + /// // Also, the start and end slot values are never equivalent. + /// let (start, end) = nfa.group_info().slots(PatternID::ZERO, 0).unwrap(); + /// assert_ne!(start, end); + /// + /// # Ok::<(), Box<dyn std::error::Error>>(()) + /// ``` + #[inline] + pub fn slots( + &self, + pid: PatternID, + group_index: usize, + ) -> Option<(usize, usize)> { + // Since 'slot' only even returns valid starting slots, we know that + // there must also be an end slot and that end slot is always one more + // than the start slot. + self.slot(pid, group_index).map(|start| (start, start + 1)) + } + + /// Returns the starting slot corresponding to the given capturing group + /// for the given pattern. The ending slot is always one more than the + /// value returned. + /// + /// If either the pattern ID or the capture index is invalid, then this + /// returns None. + /// + /// # Example + /// + /// This example shows that the starting slots for the first capturing + /// group of each pattern are distinct. + /// + /// ``` + /// use regex_automata::{nfa::thompson::NFA, PatternID}; + /// + /// let nfa = NFA::new_many(&["a", "b"])?; + /// assert_ne!( + /// nfa.group_info().slot(PatternID::must(0), 0), + /// nfa.group_info().slot(PatternID::must(1), 0), + /// ); + /// + /// # Ok::<(), Box<dyn std::error::Error>>(()) + /// ``` + #[inline] + pub fn slot(&self, pid: PatternID, group_index: usize) -> Option<usize> { + if group_index >= self.group_len(pid) { + return None; + } + // At this point, we know that 'pid' refers to a real pattern and that + // 'group_index' refers to a real group. We therefore also know that + // the pattern and group can be combined to return a correct slot. + // That's why we don't need to use checked arithmetic below. + if group_index == 0 { + Some(pid.as_usize() * 2) + } else { + // As above, we don't need to check that our slot is less than the + // end of our range since we already know the group index is a + // valid index for the given pattern. + let (start, _) = self.0.slot_ranges[pid]; + Some(start.as_usize() + ((group_index - 1) * 2)) + } + } + + /// Returns the total number of patterns in this `GroupInfo`. + /// + /// This may return zero if the `GroupInfo` was constructed with no + /// patterns. + /// + /// This is guaranteed to be no bigger than [`PatternID::LIMIT`] because + /// `GroupInfo` construction will fail if too many patterns are added. + /// + /// # Example + /// + /// ``` + /// use regex_automata::nfa::thompson::NFA; + /// + /// let nfa = NFA::new_many(&["[0-9]+", "[a-z]+", "[A-Z]+"])?; + /// assert_eq!(3, nfa.group_info().pattern_len()); + /// + /// let nfa = NFA::never_match(); + /// assert_eq!(0, nfa.group_info().pattern_len()); + /// + /// let nfa = NFA::always_match(); + /// assert_eq!(1, nfa.group_info().pattern_len()); + /// + /// # Ok::<(), Box<dyn std::error::Error>>(()) + /// ``` + #[inline] + pub fn pattern_len(&self) -> usize { + self.0.pattern_len() + } + + /// Return the number of capture groups in a pattern. + /// + /// If the pattern ID is invalid, then this returns `0`. + /// + /// # Example + /// + /// This example shows how the values returned by this routine may vary + /// for different patterns and NFA configurations. + /// + /// ``` + /// use regex_automata::{nfa::thompson::{NFA, WhichCaptures}, PatternID}; + /// + /// let nfa = NFA::new(r"(a)(b)(c)")?; + /// // There are 3 explicit groups in the pattern's concrete syntax and + /// // 1 unnamed and implicit group spanning the entire pattern. + /// assert_eq!(4, nfa.group_info().group_len(PatternID::ZERO)); + /// + /// let nfa = NFA::new(r"abc")?; + /// // There is just the unnamed implicit group. + /// assert_eq!(1, nfa.group_info().group_len(PatternID::ZERO)); + /// + /// let nfa = NFA::compiler() + /// .configure(NFA::config().which_captures(WhichCaptures::None)) + /// .build(r"abc")?; + /// // We disabled capturing groups, so there are none. + /// assert_eq!(0, nfa.group_info().group_len(PatternID::ZERO)); + /// + /// let nfa = NFA::compiler() + /// .configure(NFA::config().which_captures(WhichCaptures::None)) + /// .build(r"(a)(b)(c)")?; + /// // We disabled capturing groups, so there are none, even if there are + /// // explicit groups in the concrete syntax. + /// assert_eq!(0, nfa.group_info().group_len(PatternID::ZERO)); + /// + /// # Ok::<(), Box<dyn std::error::Error>>(()) + /// ``` + #[inline] + pub fn group_len(&self, pid: PatternID) -> usize { + self.0.group_len(pid) + } + + /// Return the total number of capture groups across all patterns. + /// + /// This includes implicit groups that represent the entire match of a + /// pattern. + /// + /// # Example + /// + /// This example shows how the values returned by this routine may vary + /// for different patterns and NFA configurations. + /// + /// ``` + /// use regex_automata::{nfa::thompson::{NFA, WhichCaptures}, PatternID}; + /// + /// let nfa = NFA::new(r"(a)(b)(c)")?; + /// // There are 3 explicit groups in the pattern's concrete syntax and + /// // 1 unnamed and implicit group spanning the entire pattern. + /// assert_eq!(4, nfa.group_info().all_group_len()); + /// + /// let nfa = NFA::new(r"abc")?; + /// // There is just the unnamed implicit group. + /// assert_eq!(1, nfa.group_info().all_group_len()); + /// + /// let nfa = NFA::new_many(&["(a)", "b", "(c)"])?; + /// // Each pattern has one implicit groups, and two + /// // patterns have one explicit group each. + /// assert_eq!(5, nfa.group_info().all_group_len()); + /// + /// let nfa = NFA::compiler() + /// .configure(NFA::config().which_captures(WhichCaptures::None)) + /// .build(r"abc")?; + /// // We disabled capturing groups, so there are none. + /// assert_eq!(0, nfa.group_info().all_group_len()); + /// + /// let nfa = NFA::compiler() + /// .configure(NFA::config().which_captures(WhichCaptures::None)) + /// .build(r"(a)(b)(c)")?; + /// // We disabled capturing groups, so there are none, even if there are + /// // explicit groups in the concrete syntax. + /// assert_eq!(0, nfa.group_info().group_len(PatternID::ZERO)); + /// + /// # Ok::<(), Box<dyn std::error::Error>>(()) + /// ``` + #[inline] + pub fn all_group_len(&self) -> usize { + self.slot_len() / 2 + } + + /// Returns the total number of slots in this `GroupInfo` across all + /// patterns. + /// + /// The total number of slots is always twice the total number of capturing + /// groups, including both implicit and explicit groups. + /// + /// # Example + /// + /// This example shows the relationship between the number of capturing + /// groups and slots. + /// + /// ``` + /// use regex_automata::util::captures::GroupInfo; + /// + /// // There are 11 total groups here. + /// let info = GroupInfo::new(vec![ + /// vec![None, Some("foo")], + /// vec![None], + /// vec![None, None, None, Some("bar"), None], + /// vec![None, None, Some("foo")], + /// ])?; + /// // 2 slots per group gives us 11*2=22 slots. + /// assert_eq!(22, info.slot_len()); + /// + /// # Ok::<(), Box<dyn std::error::Error>>(()) + /// ``` + #[inline] + pub fn slot_len(&self) -> usize { + self.0.small_slot_len().as_usize() + } + + /// Returns the total number of slots for implicit capturing groups. + /// + /// This is like [`GroupInfo::slot_len`], except it doesn't include the + /// explicit slots for each pattern. Since there are always exactly 2 + /// implicit slots for each pattern, the number of implicit slots is always + /// equal to twice the number of patterns. + /// + /// # Example + /// + /// This example shows the relationship between the number of capturing + /// groups, implicit slots and explicit slots. + /// + /// ``` + /// use regex_automata::util::captures::GroupInfo; + /// + /// // There are 11 total groups here. + /// let info = GroupInfo::new(vec![vec![None, Some("foo"), Some("bar")]])?; + /// // 2 slots per group gives us 11*2=22 slots. + /// assert_eq!(6, info.slot_len()); + /// // 2 implicit slots per pattern gives us 2 implicit slots since there + /// // is 1 pattern. + /// assert_eq!(2, info.implicit_slot_len()); + /// // 2 explicit capturing groups gives us 2*2=4 explicit slots. + /// assert_eq!(4, info.explicit_slot_len()); + /// + /// # Ok::<(), Box<dyn std::error::Error>>(()) + /// ``` + #[inline] + pub fn implicit_slot_len(&self) -> usize { + self.pattern_len() * 2 + } + + /// Returns the total number of slots for explicit capturing groups. + /// + /// This is like [`GroupInfo::slot_len`], except it doesn't include the + /// implicit slots for each pattern. (There are always 2 implicit slots for + /// each pattern.) + /// + /// For a non-empty `GroupInfo`, it is always the case that `slot_len` is + /// strictly greater than `explicit_slot_len`. For an empty `GroupInfo`, + /// both the total number of slots and the number of explicit slots is + /// `0`. + /// + /// # Example + /// + /// This example shows the relationship between the number of capturing + /// groups, implicit slots and explicit slots. + /// + /// ``` + /// use regex_automata::util::captures::GroupInfo; + /// + /// // There are 11 total groups here. + /// let info = GroupInfo::new(vec![vec![None, Some("foo"), Some("bar")]])?; + /// // 2 slots per group gives us 11*2=22 slots. + /// assert_eq!(6, info.slot_len()); + /// // 2 implicit slots per pattern gives us 2 implicit slots since there + /// // is 1 pattern. + /// assert_eq!(2, info.implicit_slot_len()); + /// // 2 explicit capturing groups gives us 2*2=4 explicit slots. + /// assert_eq!(4, info.explicit_slot_len()); + /// + /// # Ok::<(), Box<dyn std::error::Error>>(()) + /// ``` + #[inline] + pub fn explicit_slot_len(&self) -> usize { + self.slot_len().saturating_sub(self.implicit_slot_len()) + } + + /// Returns the memory usage, in bytes, of this `GroupInfo`. + /// + /// This does **not** include the stack size used up by this `GroupInfo`. + /// To compute that, use `std::mem::size_of::<GroupInfo>()`. + #[inline] + pub fn memory_usage(&self) -> usize { + use core::mem::size_of as s; + + s::<GroupInfoInner>() + + self.0.slot_ranges.len() * s::<(SmallIndex, SmallIndex)>() + + self.0.name_to_index.len() * s::<CaptureNameMap>() + + self.0.index_to_name.len() * s::<Vec<Option<Arc<str>>>>() + + self.0.memory_extra + } +} + +/// A map from capture group name to its corresponding capture group index. +/// +/// This type is actually wrapped inside a Vec indexed by pattern ID on a +/// `GroupInfo`, since multiple patterns may have the same capture group name. +/// That is, each pattern gets its own namespace of capture group names. +/// +/// Perhaps a more memory efficient representation would be +/// HashMap<(PatternID, Arc<str>), usize>, but this makes it difficult to look +/// up a capture index by name without producing a `Arc<str>`, which requires +/// an allocation. To fix this, I think we'd need to define our own unsized +/// type or something? Anyway, I didn't give this much thought since it +/// probably doesn't matter much in the grand scheme of things. But it did +/// stand out to me as mildly wasteful. +#[cfg(feature = "std")] +type CaptureNameMap = std::collections::HashMap<Arc<str>, SmallIndex>; +#[cfg(not(feature = "std"))] +type CaptureNameMap = alloc::collections::BTreeMap<Arc<str>, SmallIndex>; + +/// The inner guts of `GroupInfo`. This type only exists so that it can +/// be wrapped in an `Arc` to make `GroupInfo` reference counted. +#[derive(Debug, Default)] +struct GroupInfoInner { + slot_ranges: Vec<(SmallIndex, SmallIndex)>, + name_to_index: Vec<CaptureNameMap>, + index_to_name: Vec<Vec<Option<Arc<str>>>>, + memory_extra: usize, +} + +impl GroupInfoInner { + /// This adds the first unnamed group for the given pattern ID. The given + /// pattern ID must be zero if this is the first time this method is + /// called, or must be exactly one more than the pattern ID supplied to the + /// previous call to this method. (This method panics if this rule is + /// violated.) + /// + /// This can be thought of as initializing the GroupInfo state for the + /// given pattern and closing off the state for any previous pattern. + fn add_first_group(&mut self, pid: PatternID) { + assert_eq!(pid.as_usize(), self.slot_ranges.len()); + assert_eq!(pid.as_usize(), self.name_to_index.len()); + assert_eq!(pid.as_usize(), self.index_to_name.len()); + // This is the start of our slots for the explicit capturing groups. + // Note that since the slots for the 0th group for every pattern appear + // before any slots for the nth group (where n > 0) in any pattern, we + // will have to fix up the slot ranges once we know how many patterns + // we've added capture groups for. + let slot_start = self.small_slot_len(); + self.slot_ranges.push((slot_start, slot_start)); + self.name_to_index.push(CaptureNameMap::new()); + self.index_to_name.push(vec![None]); + self.memory_extra += core::mem::size_of::<Option<Arc<str>>>(); + } + + /// Add an explicit capturing group for the given pattern with the given + /// index. If the group has a name, then that must be given as well. + /// + /// Note that every capturing group except for the first or zeroth group is + /// explicit. + /// + /// This returns an error if adding this group would result in overflowing + /// slot indices or if a capturing group with the same name for this + /// pattern has already been added. + fn add_explicit_group<N: AsRef<str>>( + &mut self, + pid: PatternID, + group: SmallIndex, + maybe_name: Option<N>, + ) -> Result<(), GroupInfoError> { + // We also need to check that the slot index generated for + // this group is also valid. Although, this is a little weird + // because we offset these indices below, at which point, we'll + // have to recheck them. Gosh this is annoying. Note that + // the '+2' below is OK because 'end' is guaranteed to be less + // than isize::MAX. + let end = &mut self.slot_ranges[pid].1; + *end = SmallIndex::new(end.as_usize() + 2).map_err(|_| { + GroupInfoError::too_many_groups(pid, group.as_usize()) + })?; + if let Some(name) = maybe_name { + let name = Arc::<str>::from(name.as_ref()); + if self.name_to_index[pid].contains_key(&*name) { + return Err(GroupInfoError::duplicate(pid, &name)); + } + let len = name.len(); + self.name_to_index[pid].insert(Arc::clone(&name), group); + self.index_to_name[pid].push(Some(name)); + // Adds the memory used by the Arc<str> in both maps. + self.memory_extra += + 2 * (len + core::mem::size_of::<Option<Arc<str>>>()); + // And also the value entry for the 'name_to_index' map. + // This is probably an underestimate for 'name_to_index' since + // hashmaps/btrees likely have some non-zero overhead, but we + // assume here that they have zero overhead. + self.memory_extra += core::mem::size_of::<SmallIndex>(); + } else { + self.index_to_name[pid].push(None); + self.memory_extra += core::mem::size_of::<Option<Arc<str>>>(); + } + // This is a sanity assert that checks that our group index + // is in line with the number of groups added so far for this + // pattern. + assert_eq!(group.one_more(), self.group_len(pid)); + // And is also in line with the 'index_to_name' map. + assert_eq!(group.one_more(), self.index_to_name[pid].len()); + Ok(()) + } + + /// This corrects the slot ranges to account for the slots corresponding + /// to the zeroth group of each pattern. That is, every slot range is + /// offset by 'pattern_len() * 2', since each pattern uses two slots to + /// represent the zeroth group. + fn fixup_slot_ranges(&mut self) -> Result<(), GroupInfoError> { + use crate::util::primitives::IteratorIndexExt; + // Since we know number of patterns fits in PatternID and + // PatternID::MAX < isize::MAX, it follows that multiplying by 2 will + // never overflow usize. + let offset = self.pattern_len().checked_mul(2).unwrap(); + for (pid, &mut (ref mut start, ref mut end)) in + self.slot_ranges.iter_mut().with_pattern_ids() + { + let group_len = 1 + ((end.as_usize() - start.as_usize()) / 2); + let new_end = match end.as_usize().checked_add(offset) { + Some(new_end) => new_end, + None => { + return Err(GroupInfoError::too_many_groups( + pid, group_len, + )) + } + }; + *end = SmallIndex::new(new_end).map_err(|_| { + GroupInfoError::too_many_groups(pid, group_len) + })?; + // Since start <= end, if end is valid then start must be too. + *start = SmallIndex::new(start.as_usize() + offset).unwrap(); + } + Ok(()) + } + + /// Return the total number of patterns represented by this capture slot + /// info. + fn pattern_len(&self) -> usize { + self.slot_ranges.len() + } + + /// Return the total number of capturing groups for the given pattern. If + /// the given pattern isn't valid for this capture slot info, then 0 is + /// returned. + fn group_len(&self, pid: PatternID) -> usize { + let (start, end) = match self.slot_ranges.get(pid.as_usize()) { + None => return 0, + Some(range) => range, + }; + // The difference between any two SmallIndex values always fits in a + // usize since we know that SmallIndex::MAX <= isize::MAX-1. We also + // know that start<=end by construction and that the number of groups + // never exceeds SmallIndex and thus never overflows usize. + 1 + ((end.as_usize() - start.as_usize()) / 2) + } + + /// Return the total number of slots in this capture slot info as a + /// "small index." + fn small_slot_len(&self) -> SmallIndex { + // Since slots are allocated in order of pattern (starting at 0) and + // then in order of capture group, it follows that the number of slots + // is the end of the range of slots for the last pattern. This is + // true even when the last pattern has no capturing groups, since + // 'slot_ranges' will still represent it explicitly with an empty + // range. + self.slot_ranges.last().map_or(SmallIndex::ZERO, |&(_, end)| end) + } +} + +/// An error that may occur when building a `GroupInfo`. +/// +/// Building a `GroupInfo` does a variety of checks to make sure the +/// capturing groups satisfy a number of invariants. This includes, but is not +/// limited to, ensuring that the first capturing group is unnamed and that +/// there are no duplicate capture groups for a specific pattern. +#[derive(Clone, Debug)] +pub struct GroupInfoError { + kind: GroupInfoErrorKind, +} + +/// The kind of error that occurs when building a `GroupInfo` fails. +/// +/// We keep this un-exported because it's not clear how useful it is to +/// export it. +#[derive(Clone, Debug)] +enum GroupInfoErrorKind { + /// This occurs when too many patterns have been added. i.e., It would + /// otherwise overflow a `PatternID`. + TooManyPatterns { err: PatternIDError }, + /// This occurs when too many capturing groups have been added for a + /// particular pattern. + TooManyGroups { + /// The ID of the pattern that had too many groups. + pattern: PatternID, + /// The minimum number of groups that the caller has tried to add for + /// a pattern. + minimum: usize, + }, + /// An error that occurs when a pattern has no capture groups. Either the + /// group info must be empty, or all patterns must have at least one group + /// (corresponding to the unnamed group for the entire pattern). + MissingGroups { + /// The ID of the pattern that had no capturing groups. + pattern: PatternID, + }, + /// An error that occurs when one tries to provide a name for the capture + /// group at index 0. This capturing group must currently always be + /// unnamed. + FirstMustBeUnnamed { + /// The ID of the pattern that was found to have a named first + /// capturing group. + pattern: PatternID, + }, + /// An error that occurs when duplicate capture group names for the same + /// pattern are added. + /// + /// NOTE: At time of writing, this error can never occur if you're using + /// regex-syntax, since the parser itself will reject patterns with + /// duplicate capture group names. This error can only occur when the + /// builder is used to hand construct NFAs. + Duplicate { + /// The pattern in which the duplicate capture group name was found. + pattern: PatternID, + /// The duplicate name. + name: String, + }, +} + +impl GroupInfoError { + fn too_many_patterns(err: PatternIDError) -> GroupInfoError { + GroupInfoError { kind: GroupInfoErrorKind::TooManyPatterns { err } } + } + + fn too_many_groups(pattern: PatternID, minimum: usize) -> GroupInfoError { + GroupInfoError { + kind: GroupInfoErrorKind::TooManyGroups { pattern, minimum }, + } + } + + fn missing_groups(pattern: PatternID) -> GroupInfoError { + GroupInfoError { kind: GroupInfoErrorKind::MissingGroups { pattern } } + } + + fn first_must_be_unnamed(pattern: PatternID) -> GroupInfoError { + GroupInfoError { + kind: GroupInfoErrorKind::FirstMustBeUnnamed { pattern }, + } + } + + fn duplicate(pattern: PatternID, name: &str) -> GroupInfoError { + GroupInfoError { + kind: GroupInfoErrorKind::Duplicate { + pattern, + name: String::from(name), + }, + } + } +} + +#[cfg(feature = "std")] +impl std::error::Error for GroupInfoError { + fn source(&self) -> Option<&(dyn std::error::Error + 'static)> { + match self.kind { + GroupInfoErrorKind::TooManyPatterns { .. } + | GroupInfoErrorKind::TooManyGroups { .. } + | GroupInfoErrorKind::MissingGroups { .. } + | GroupInfoErrorKind::FirstMustBeUnnamed { .. } + | GroupInfoErrorKind::Duplicate { .. } => None, + } + } +} + +impl core::fmt::Display for GroupInfoError { + fn fmt(&self, f: &mut core::fmt::Formatter<'_>) -> core::fmt::Result { + use self::GroupInfoErrorKind::*; + + match self.kind { + TooManyPatterns { ref err } => { + write!(f, "too many patterns to build capture info: {}", err) + } + TooManyGroups { pattern, minimum } => { + write!( + f, + "too many capture groups (at least {}) were \ + found for pattern {}", + minimum, + pattern.as_usize() + ) + } + MissingGroups { pattern } => write!( + f, + "no capturing groups found for pattern {} \ + (either all patterns have zero groups or all patterns have \ + at least one group)", + pattern.as_usize(), + ), + FirstMustBeUnnamed { pattern } => write!( + f, + "first capture group (at index 0) for pattern {} has a name \ + (it must be unnamed)", + pattern.as_usize(), + ), + Duplicate { pattern, ref name } => write!( + f, + "duplicate capture group name '{}' found for pattern {}", + name, + pattern.as_usize(), + ), + } + } +} + +/// An iterator over capturing groups and their names for a specific pattern. +/// +/// This iterator is created by [`GroupInfo::pattern_names`]. +/// +/// The lifetime parameter `'a` refers to the lifetime of the `GroupInfo` +/// from which this iterator was created. +#[derive(Clone, Debug)] +pub struct GroupInfoPatternNames<'a> { + it: core::slice::Iter<'a, Option<Arc<str>>>, +} + +impl GroupInfoPatternNames<'static> { + fn empty() -> GroupInfoPatternNames<'static> { + GroupInfoPatternNames { it: [].iter() } + } +} + +impl<'a> Iterator for GroupInfoPatternNames<'a> { + type Item = Option<&'a str>; + + fn next(&mut self) -> Option<Option<&'a str>> { + self.it.next().map(|x| x.as_deref()) + } + + fn size_hint(&self) -> (usize, Option<usize>) { + self.it.size_hint() + } + + fn count(self) -> usize { + self.it.count() + } +} + +impl<'a> ExactSizeIterator for GroupInfoPatternNames<'a> {} +impl<'a> core::iter::FusedIterator for GroupInfoPatternNames<'a> {} + +/// An iterator over capturing groups and their names for a `GroupInfo`. +/// +/// This iterator is created by [`GroupInfo::all_names`]. +/// +/// The lifetime parameter `'a` refers to the lifetime of the `GroupInfo` +/// from which this iterator was created. +#[derive(Debug)] +pub struct GroupInfoAllNames<'a> { + group_info: &'a GroupInfo, + pids: PatternIDIter, + current_pid: Option<PatternID>, + names: Option<core::iter::Enumerate<GroupInfoPatternNames<'a>>>, +} + +impl<'a> Iterator for GroupInfoAllNames<'a> { + type Item = (PatternID, usize, Option<&'a str>); + + fn next(&mut self) -> Option<(PatternID, usize, Option<&'a str>)> { + // If the group info has no captures, then we never have anything + // to yield. We need to consider this case explicitly (at time of + // writing) because 'pattern_capture_names' will panic if captures + // aren't enabled. + if self.group_info.0.index_to_name.is_empty() { + return None; + } + if self.current_pid.is_none() { + self.current_pid = Some(self.pids.next()?); + } + let pid = self.current_pid.unwrap(); + if self.names.is_none() { + self.names = Some(self.group_info.pattern_names(pid).enumerate()); + } + let (group_index, name) = match self.names.as_mut().unwrap().next() { + Some((group_index, name)) => (group_index, name), + None => { + self.current_pid = None; + self.names = None; + return self.next(); + } + }; + Some((pid, group_index, name)) + } +} |