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use {
grep_matcher::{
ByteSet, Captures, LineMatchKind, LineTerminator, Match, Matcher,
NoError,
},
regex_automata::{
meta::Regex, util::captures::Captures as AutomataCaptures, Input,
PatternID,
},
};
use crate::{config::Config, error::Error, literal::InnerLiterals};
/// A builder for constructing a `Matcher` using regular expressions.
///
/// This builder re-exports many of the same options found on the regex crate's
/// builder, in addition to a few other options such as smart case, word
/// matching and the ability to set a line terminator which may enable certain
/// types of optimizations.
///
/// The syntax supported is documented as part of the regex crate:
/// <https://docs.rs/regex/#syntax>.
#[derive(Clone, Debug)]
pub struct RegexMatcherBuilder {
config: Config,
}
impl Default for RegexMatcherBuilder {
fn default() -> RegexMatcherBuilder {
RegexMatcherBuilder::new()
}
}
impl RegexMatcherBuilder {
/// Create a new builder for configuring a regex matcher.
pub fn new() -> RegexMatcherBuilder {
RegexMatcherBuilder { config: Config::default() }
}
/// Build a new matcher using the current configuration for the provided
/// pattern.
///
/// The syntax supported is documented as part of the regex crate:
/// <https://docs.rs/regex/#syntax>.
pub fn build(&self, pattern: &str) -> Result<RegexMatcher, Error> {
self.build_many(&[pattern])
}
/// Build a new matcher using the current configuration for the provided
/// patterns. The resulting matcher behaves as if all of the patterns
/// given are joined together into a single alternation. That is, it
/// reports matches where at least one of the given patterns matches.
pub fn build_many<P: AsRef<str>>(
&self,
patterns: &[P],
) -> Result<RegexMatcher, Error> {
let mut chir = self.config.build_many(patterns)?;
// 'whole_line' is a strict subset of 'word', so when it is enabled,
// we don't need to both with any specific to word matching.
if chir.config().whole_line {
chir = chir.into_whole_line();
} else if chir.config().word {
chir = chir.into_word();
}
let regex = chir.to_regex()?;
log::trace!("final regex: {:?}", chir.hir().to_string());
let non_matching_bytes = chir.non_matching_bytes();
// If we can pick out some literals from the regex, then we might be
// able to build a faster regex that quickly identifies candidate
// matching lines. The regex engine will do what it can on its own, but
// we can specifically do a little more when a line terminator is set.
// For example, for a regex like `\w+foo\w+`, we can look for `foo`,
// and when a match is found, look for the line containing `foo` and
// then run the original regex on only that line. (In this case, the
// regex engine is likely to handle this case for us since it's so
// simple, but the idea applies.)
let fast_line_regex = InnerLiterals::new(&chir, ®ex).one_regex()?;
// We override the line terminator in case the configured HIR doesn't
// support it.
let mut config = self.config.clone();
config.line_terminator = chir.line_terminator();
Ok(RegexMatcher { config, regex, fast_line_regex, non_matching_bytes })
}
/// Build a new matcher from a plain alternation of literals.
///
/// Depending on the configuration set by the builder, this may be able to
/// build a matcher substantially faster than by joining the patterns with
/// a `|` and calling `build`.
pub fn build_literals<B: AsRef<str>>(
&self,
literals: &[B],
) -> Result<RegexMatcher, Error> {
self.build_many(literals)
}
/// Set the value for the case insensitive (`i`) flag.
///
/// When enabled, letters in the pattern will match both upper case and
/// lower case variants.
pub fn case_insensitive(&mut self, yes: bool) -> &mut RegexMatcherBuilder {
self.config.case_insensitive = yes;
self
}
/// Whether to enable "smart case" or not.
///
/// When smart case is enabled, the builder will automatically enable
/// case insensitive matching based on how the pattern is written. Namely,
/// case insensitive mode is enabled when both of the following things
/// are true:
///
/// 1. The pattern contains at least one literal character. For example,
/// `a\w` contains a literal (`a`) but `\w` does not.
/// 2. Of the literals in the pattern, none of them are considered to be
/// uppercase according to Unicode. For example, `foo\pL` has no
/// uppercase literals but `Foo\pL` does.
pub fn case_smart(&mut self, yes: bool) -> &mut RegexMatcherBuilder {
self.config.case_smart = yes;
self
}
/// Set the value for the multi-line matching (`m`) flag.
///
/// When enabled, `^` matches the beginning of lines and `$` matches the
/// end of lines.
///
/// By default, they match beginning/end of the input.
pub fn multi_line(&mut self, yes: bool) -> &mut RegexMatcherBuilder {
self.config.multi_line = yes;
self
}
/// Set the value for the any character (`s`) flag, where in `.` matches
/// anything when `s` is set and matches anything except for new line when
/// it is not set (the default).
///
/// N.B. "matches anything" means "any byte" when Unicode is disabled and
/// means "any valid UTF-8 encoding of any Unicode scalar value" when
/// Unicode is enabled.
pub fn dot_matches_new_line(
&mut self,
yes: bool,
) -> &mut RegexMatcherBuilder {
self.config.dot_matches_new_line = yes;
self
}
/// Set the value for the greedy swap (`U`) flag.
///
/// When enabled, a pattern like `a*` is lazy (tries to find shortest
/// match) and `a*?` is greedy (tries to find longest match).
///
/// By default, `a*` is greedy and `a*?` is lazy.
pub fn swap_greed(&mut self, yes: bool) -> &mut RegexMatcherBuilder {
self.config.swap_greed = yes;
self
}
/// Set the value for the ignore whitespace (`x`) flag.
///
/// When enabled, whitespace such as new lines and spaces will be ignored
/// between expressions of the pattern, and `#` can be used to start a
/// comment until the next new line.
pub fn ignore_whitespace(
&mut self,
yes: bool,
) -> &mut RegexMatcherBuilder {
self.config.ignore_whitespace = yes;
self
}
/// Set the value for the Unicode (`u`) flag.
///
/// Enabled by default. When disabled, character classes such as `\w` only
/// match ASCII word characters instead of all Unicode word characters.
pub fn unicode(&mut self, yes: bool) -> &mut RegexMatcherBuilder {
self.config.unicode = yes;
self
}
/// Whether to support octal syntax or not.
///
/// Octal syntax is a little-known way of uttering Unicode codepoints in
/// a regular expression. For example, `a`, `\x61`, `\u0061` and
/// `\141` are all equivalent regular expressions, where the last example
/// shows octal syntax.
///
/// While supporting octal syntax isn't in and of itself a problem, it does
/// make good error messages harder. That is, in PCRE based regex engines,
/// syntax like `\0` invokes a backreference, which is explicitly
/// unsupported in Rust's regex engine. However, many users expect it to
/// be supported. Therefore, when octal support is disabled, the error
/// message will explicitly mention that backreferences aren't supported.
///
/// Octal syntax is disabled by default.
pub fn octal(&mut self, yes: bool) -> &mut RegexMatcherBuilder {
self.config.octal = yes;
self
}
/// Set the approximate size limit of the compiled regular expression.
///
/// This roughly corresponds to the number of bytes occupied by a single
/// compiled program. If the program exceeds this number, then a
/// compilation error is returned.
pub fn size_limit(&mut self, bytes: usize) -> &mut RegexMatcherBuilder {
self.config.size_limit = bytes;
self
}
/// Set the approximate size of the cache used by the DFA.
///
/// This roughly corresponds to the number of bytes that the DFA will
/// use while searching.
///
/// Note that this is a *per thread* limit. There is no way to set a global
/// limit. In particular, if a regex is used from multiple threads
/// simultaneously, then each thread may use up to the number of bytes
/// specified here.
pub fn dfa_size_limit(
&mut self,
bytes: usize,
) -> &mut RegexMatcherBuilder {
self.config.dfa_size_limit = bytes;
self
}
/// Set the nesting limit for this parser.
///
/// The nesting limit controls how deep the abstract syntax tree is allowed
/// to be. If the AST exceeds the given limit (e.g., with too many nested
/// groups), then an error is returned by the parser.
///
/// The purpose of this limit is to act as a heuristic to prevent stack
/// overflow for consumers that do structural induction on an `Ast` using
/// explicit recursion. While this crate never does this (instead using
/// constant stack space and moving the call stack to the heap), other
/// crates may.
///
/// This limit is not checked until the entire Ast is parsed. Therefore,
/// if callers want to put a limit on the amount of heap space used, then
/// they should impose a limit on the length, in bytes, of the concrete
/// pattern string. In particular, this is viable since this parser
/// implementation will limit itself to heap space proportional to the
/// length of the pattern string.
///
/// Note that a nest limit of `0` will return a nest limit error for most
/// patterns but not all. For example, a nest limit of `0` permits `a` but
/// not `ab`, since `ab` requires a concatenation, which results in a nest
/// depth of `1`. In general, a nest limit is not something that manifests
/// in an obvious way in the concrete syntax, therefore, it should not be
/// used in a granular way.
pub fn nest_limit(&mut self, limit: u32) -> &mut RegexMatcherBuilder {
self.config.nest_limit = limit;
self
}
/// Set an ASCII line terminator for the matcher.
///
/// The purpose of setting a line terminator is to enable a certain class
/// of optimizations that can make line oriented searching faster. Namely,
/// when a line terminator is enabled, then the builder will guarantee that
/// the resulting matcher will never be capable of producing a match that
/// contains the line terminator. Because of this guarantee, users of the
/// resulting matcher do not need to slowly execute a search line by line
/// for line oriented search.
///
/// If the aforementioned guarantee about not matching a line terminator
/// cannot be made because of how the pattern was written, then the builder
/// will return an error when attempting to construct the matcher. For
/// example, the pattern `a\sb` will be transformed such that it can never
/// match `a\nb` (when `\n` is the line terminator), but the pattern `a\nb`
/// will result in an error since the `\n` cannot be easily removed without
/// changing the fundamental intent of the pattern.
///
/// If the given line terminator isn't an ASCII byte (`<=127`), then the
/// builder will return an error when constructing the matcher.
pub fn line_terminator(
&mut self,
line_term: Option<u8>,
) -> &mut RegexMatcherBuilder {
self.config.line_terminator = line_term.map(LineTerminator::byte);
self
}
/// Ban a byte from occurring in a regular expression pattern.
///
/// If this byte is found in the regex pattern, then an error will be
/// returned at construction time.
///
/// This is useful when binary detection is enabled. Callers will likely
/// want to ban the same byte that is used to detect binary data, i.e.,
/// the NUL byte. The reason for this is that when binary detection is
/// enabled, it's impossible to match a NUL byte because binary detection
/// will either quit when one is found, or will convert NUL bytes to line
/// terminators to avoid exorbitant heap usage.
pub fn ban_byte(&mut self, byte: Option<u8>) -> &mut RegexMatcherBuilder {
self.config.ban = byte;
self
}
/// Set the line terminator to `\r\n` and enable CRLF matching for `$` in
/// regex patterns.
///
/// This method sets two distinct settings:
///
/// 1. It causes the line terminator for the matcher to be `\r\n`. Namely,
/// this prevents the matcher from ever producing a match that contains
/// a `\r` or `\n`.
/// 2. It enables CRLF mode for `^` and `$`. This means that line anchors
/// will treat both `\r` and `\n` as line terminators, but will never
/// match between a `\r` and `\n`.
///
/// Note that if you do not wish to set the line terminator but would
/// still like `$` to match `\r\n` line terminators, then it is valid to
/// call `crlf(true)` followed by `line_terminator(None)`. Ordering is
/// important, since `crlf` sets the line terminator, but `line_terminator`
/// does not touch the `crlf` setting.
pub fn crlf(&mut self, yes: bool) -> &mut RegexMatcherBuilder {
if yes {
self.config.line_terminator = Some(LineTerminator::crlf());
} else {
self.config.line_terminator = None;
}
self.config.crlf = yes;
self
}
/// Require that all matches occur on word boundaries.
///
/// Enabling this option is subtly different than putting `\b` assertions
/// on both sides of your pattern. In particular, a `\b` assertion requires
/// that one side of it match a word character while the other match a
/// non-word character. This option, in contrast, merely requires that
/// one side match a non-word character.
///
/// For example, `\b-2\b` will not match `foo -2 bar` since `-` is not a
/// word character. However, `-2` with this `word` option enabled will
/// match the `-2` in `foo -2 bar`.
pub fn word(&mut self, yes: bool) -> &mut RegexMatcherBuilder {
self.config.word = yes;
self
}
/// Whether the patterns should be treated as literal strings or not. When
/// this is active, all characters, including ones that would normally be
/// special regex meta characters, are matched literally.
pub fn fixed_strings(&mut self, yes: bool) -> &mut RegexMatcherBuilder {
self.config.fixed_strings = yes;
self
}
/// Whether each pattern should match the entire line or not. This is
/// equivalent to surrounding the pattern with `(?m:^)` and `(?m:$)`.
pub fn whole_line(&mut self, yes: bool) -> &mut RegexMatcherBuilder {
self.config.whole_line = yes;
self
}
}
/// An implementation of the `Matcher` trait using Rust's standard regex
/// library.
#[derive(Clone, Debug)]
pub struct RegexMatcher {
/// The configuration specified by the caller.
config: Config,
/// The regular expression compiled from the pattern provided by the
/// caller.
regex: Regex,
/// A regex that never reports false negatives but may report false
/// positives that is believed to be capable of being matched more quickly
/// than `regex`. Typically, this is a single literal or an alternation
/// of literals.
fast_line_regex: Option<Regex>,
/// A set of bytes that will never appear in a match.
non_matching_bytes: ByteSet,
}
impl RegexMatcher {
/// Create a new matcher from the given pattern using the default
/// configuration.
pub fn new(pattern: &str) -> Result<RegexMatcher, Error> {
RegexMatcherBuilder::new().build(pattern)
}
/// Create a new matcher from the given pattern using the default
/// configuration, but matches lines terminated by `\n`.
///
/// This is meant to be a convenience constructor for
/// using a `RegexMatcherBuilder` and setting its
/// [`line_terminator`](RegexMatcherBuilder::method.line_terminator) to
/// `\n`. The purpose of using this constructor is to permit special
/// optimizations that help speed up line oriented search. These types of
/// optimizations are only appropriate when matches span no more than one
/// line. For this reason, this constructor will return an error if the
/// given pattern contains a literal `\n`. Other uses of `\n` (such as in
/// `\s`) are removed transparently.
pub fn new_line_matcher(pattern: &str) -> Result<RegexMatcher, Error> {
RegexMatcherBuilder::new().line_terminator(Some(b'\n')).build(pattern)
}
}
// This implementation just dispatches on the internal matcher impl except
// for the line terminator optimization, which is possibly executed via
// `fast_line_regex`.
impl Matcher for RegexMatcher {
type Captures = RegexCaptures;
type Error = NoError;
#[inline]
fn find_at(
&self,
haystack: &[u8],
at: usize,
) -> Result<Option<Match>, NoError> {
let input = Input::new(haystack).span(at..haystack.len());
Ok(self.regex.find(input).map(|m| Match::new(m.start(), m.end())))
}
#[inline]
fn new_captures(&self) -> Result<RegexCaptures, NoError> {
Ok(RegexCaptures::new(self.regex.create_captures()))
}
#[inline]
fn capture_count(&self) -> usize {
self.regex.captures_len()
}
#[inline]
fn capture_index(&self, name: &str) -> Option<usize> {
self.regex.group_info().to_index(PatternID::ZERO, name)
}
#[inline]
fn try_find_iter<F, E>(
&self,
haystack: &[u8],
mut matched: F,
) -> Result<Result<(), E>, NoError>
where
F: FnMut(Match) -> Result<bool, E>,
{
for m in self.regex.find_iter(haystack) {
match matched(Match::new(m.start(), m.end())) {
Ok(true) => continue,
Ok(false) => return Ok(Ok(())),
Err(err) => return Ok(Err(err)),
}
}
Ok(Ok(()))
}
#[inline]
fn captures_at(
&self,
haystack: &[u8],
at: usize,
caps: &mut RegexCaptures,
) -> Result<bool, NoError> {
let input = Input::new(haystack).span(at..haystack.len());
let caps = caps.captures_mut();
self.regex.search_captures(&input, caps);
Ok(caps.is_match())
}
#[inline]
fn shortest_match_at(
&self,
haystack: &[u8],
at: usize,
) -> Result<Option<usize>, NoError> {
let input = Input::new(haystack).span(at..haystack.len());
Ok(self.regex.search_half(&input).map(|hm| hm.offset()))
}
#[inline]
fn non_matching_bytes(&self) -> Option<&ByteSet> {
Some(&self.non_matching_bytes)
}
#[inline]
fn line_terminator(&self) -> Option<LineTerminator> {
self.config.line_terminator
}
#[inline]
fn find_candidate_line(
&self,
haystack: &[u8],
) -> Result<Option<LineMatchKind>, NoError> {
Ok(match self.fast_line_regex {
Some(ref regex) => {
let input = Input::new(haystack);
regex
.search_half(&input)
.map(|hm| LineMatchKind::Candidate(hm.offset()))
}
None => {
self.shortest_match(haystack)?.map(LineMatchKind::Confirmed)
}
})
}
}
/// Represents the match offsets of each capturing group in a match.
///
/// The first, or `0`th capture group, always corresponds to the entire match
/// and is guaranteed to be present when a match occurs. The next capture
/// group, at index `1`, corresponds to the first capturing group in the regex,
/// ordered by the position at which the left opening parenthesis occurs.
///
/// Note that not all capturing groups are guaranteed to be present in a match.
/// For example, in the regex, `(?P<foo>\w)|(?P<bar>\W)`, only one of `foo`
/// or `bar` will ever be set in any given match.
///
/// In order to access a capture group by name, you'll need to first find the
/// index of the group using the corresponding matcher's `capture_index`
/// method, and then use that index with `RegexCaptures::get`.
#[derive(Clone, Debug)]
pub struct RegexCaptures {
/// Where the captures are stored.
caps: AutomataCaptures,
}
impl Captures for RegexCaptures {
#[inline]
fn len(&self) -> usize {
self.caps.group_info().all_group_len()
}
#[inline]
fn get(&self, i: usize) -> Option<Match> {
self.caps.get_group(i).map(|sp| Match::new(sp.start, sp.end))
}
}
impl RegexCaptures {
#[inline]
pub(crate) fn new(caps: AutomataCaptures) -> RegexCaptures {
RegexCaptures { caps }
}
#[inline]
pub(crate) fn captures_mut(&mut self) -> &mut AutomataCaptures {
&mut self.caps
}
}
#[cfg(test)]
mod tests {
use super::*;
// Test that enabling word matches does the right thing and demonstrate
// the difference between it and surrounding the regex in `\b`.
#[test]
fn word() {
let matcher =
RegexMatcherBuilder::new().word(true).build(r"-2").unwrap();
assert!(matcher.is_match(b"abc -2 foo").unwrap());
let matcher =
RegexMatcherBuilder::new().word(false).build(r"\b-2\b").unwrap();
assert!(!matcher.is_match(b"abc -2 foo").unwrap());
}
// Test that enabling a line terminator prevents it from matching through
// said line terminator.
#[test]
fn line_terminator() {
// This works, because there's no line terminator specified.
let matcher = RegexMatcherBuilder::new().build(r"abc\sxyz").unwrap();
assert!(matcher.is_match(b"abc\nxyz").unwrap());
// This doesn't.
let matcher = RegexMatcherBuilder::new()
.line_terminator(Some(b'\n'))
.build(r"abc\sxyz")
.unwrap();
assert!(!matcher.is_match(b"abc\nxyz").unwrap());
}
// Ensure that the builder returns an error if a line terminator is set
// and the regex could not be modified to remove a line terminator.
#[test]
fn line_terminator_error() {
assert!(RegexMatcherBuilder::new()
.line_terminator(Some(b'\n'))
.build(r"a\nz")
.is_err())
}
// Test that enabling CRLF permits `$` to match at the end of a line.
#[test]
fn line_terminator_crlf() {
// Test normal use of `$` with a `\n` line terminator.
let matcher = RegexMatcherBuilder::new()
.multi_line(true)
.build(r"abc$")
.unwrap();
assert!(matcher.is_match(b"abc\n").unwrap());
// Test that `$` doesn't match at `\r\n` boundary normally.
let matcher = RegexMatcherBuilder::new()
.multi_line(true)
.build(r"abc$")
.unwrap();
assert!(!matcher.is_match(b"abc\r\n").unwrap());
// Now check the CRLF handling.
let matcher = RegexMatcherBuilder::new()
.multi_line(true)
.crlf(true)
.build(r"abc$")
.unwrap();
assert!(matcher.is_match(b"abc\r\n").unwrap());
}
// Test that smart case works.
#[test]
fn case_smart() {
let matcher =
RegexMatcherBuilder::new().case_smart(true).build(r"abc").unwrap();
assert!(matcher.is_match(b"ABC").unwrap());
let matcher =
RegexMatcherBuilder::new().case_smart(true).build(r"aBc").unwrap();
assert!(!matcher.is_match(b"ABC").unwrap());
}
// Test that finding candidate lines works as expected.
// FIXME: Re-enable this test once inner literal extraction works.
#[test]
#[ignore]
fn candidate_lines() {
fn is_confirmed(m: LineMatchKind) -> bool {
match m {
LineMatchKind::Confirmed(_) => true,
_ => false,
}
}
fn is_candidate(m: LineMatchKind) -> bool {
match m {
LineMatchKind::Candidate(_) => true,
_ => false,
}
}
// With no line terminator set, we can't employ any optimizations,
// so we get a confirmed match.
let matcher = RegexMatcherBuilder::new().build(r"\wfoo\s").unwrap();
let m = matcher.find_candidate_line(b"afoo ").unwrap().unwrap();
assert!(is_confirmed(m));
// With a line terminator and a regex specially crafted to have an
// easy-to-detect inner literal, we can apply an optimization that
// quickly finds candidate matches.
let matcher = RegexMatcherBuilder::new()
.line_terminator(Some(b'\n'))
.build(r"\wfoo\s")
.unwrap();
let m = matcher.find_candidate_line(b"afoo ").unwrap().unwrap();
assert!(is_candidate(m));
}
}