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repo: move all source code in crates directory

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The top-level listing was just getting a bit too long for my taste. So
put all of the code in one directory and shrink the large top-level mess
to a small top-level mess.

NOTE: This commit only contains renames. The subsequent commit will
actually make ripgrep build again. We do it this way with the naive hope
that this will make it easier for git history to track the renames.
Sigh.
This commit is contained in:
Andrew Gallant
2020-02-17 18:19:19 -05:00
parent 0bc4f0447b
commit fdd8510fdd
113 changed files with 0 additions and 0 deletions
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59
crates/pcre2/src/error.rs Normal file
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use std::error;
use std::fmt;
/// An error that can occur in this crate.
///
/// Generally, this error corresponds to problems building a regular
/// expression, whether it's in parsing, compilation or a problem with
/// guaranteeing a configured optimization.
#[derive(Clone, Debug)]
pub struct Error {
kind: ErrorKind,
}
impl Error {
pub(crate) fn regex<E: error::Error>(err: E) -> Error {
Error { kind: ErrorKind::Regex(err.to_string()) }
}
/// Return the kind of this error.
pub fn kind(&self) -> &ErrorKind {
&self.kind
}
}
/// The kind of an error that can occur.
#[derive(Clone, Debug)]
pub enum ErrorKind {
/// An error that occurred as a result of parsing a regular expression.
/// This can be a syntax error or an error that results from attempting to
/// compile a regular expression that is too big.
///
/// The string here is the underlying error converted to a string.
Regex(String),
/// Hints that destructuring should not be exhaustive.
///
/// This enum may grow additional variants, so this makes sure clients
/// don't count on exhaustive matching. (Otherwise, adding a new variant
/// could break existing code.)
#[doc(hidden)]
__Nonexhaustive,
}
impl error::Error for Error {
fn description(&self) -> &str {
match self.kind {
ErrorKind::Regex(_) => "regex error",
ErrorKind::__Nonexhaustive => unreachable!(),
}
}
}
impl fmt::Display for Error {
fn fmt(&self, f: &mut fmt::Formatter) -> fmt::Result {
match self.kind {
ErrorKind::Regex(ref s) => write!(f, "{}", s),
ErrorKind::__Nonexhaustive => unreachable!(),
}
}
}

16
crates/pcre2/src/lib.rs Normal file
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/*!
An implementation of `grep-matcher`'s `Matcher` trait for
[PCRE2](https://www.pcre.org/).
*/
#![deny(missing_docs)]
extern crate grep_matcher;
extern crate pcre2;
pub use error::{Error, ErrorKind};
pub use matcher::{RegexCaptures, RegexMatcher, RegexMatcherBuilder};
pub use pcre2::{is_jit_available, version};
mod error;
mod matcher;

456
crates/pcre2/src/matcher.rs Normal file
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use std::collections::HashMap;
use grep_matcher::{Captures, Match, Matcher};
use pcre2::bytes::{CaptureLocations, Regex, RegexBuilder};
use error::Error;
/// A builder for configuring the compilation of a PCRE2 regex.
#[derive(Clone, Debug)]
pub struct RegexMatcherBuilder {
builder: RegexBuilder,
case_smart: bool,
word: bool,
}
impl RegexMatcherBuilder {
/// Create a new matcher builder with a default configuration.
pub fn new() -> RegexMatcherBuilder {
RegexMatcherBuilder {
builder: RegexBuilder::new(),
case_smart: false,
word: false,
}
}
/// Compile the given pattern into a PCRE matcher using the current
/// configuration.
///
/// If there was a problem compiling the pattern, then an error is
/// returned.
pub fn build(&self, pattern: &str) -> Result<RegexMatcher, Error> {
let mut builder = self.builder.clone();
if self.case_smart && !has_uppercase_literal(pattern) {
builder.caseless(true);
}
let res = if self.word {
let pattern = format!(r"(?<!\w)(?:{})(?!\w)", pattern);
builder.build(&pattern)
} else {
builder.build(pattern)
};
res.map_err(Error::regex).map(|regex| {
let mut names = HashMap::new();
for (i, name) in regex.capture_names().iter().enumerate() {
if let Some(ref name) = *name {
names.insert(name.to_string(), i);
}
}
RegexMatcher { regex, names }
})
}
/// Enables case insensitive matching.
///
/// If the `utf` option is also set, then Unicode case folding is used
/// to determine case insensitivity. When the `utf` option is not set,
/// then only standard ASCII case insensitivity is considered.
///
/// This option corresponds to the `i` flag.
pub fn caseless(&mut self, yes: bool) -> &mut RegexMatcherBuilder {
self.builder.caseless(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 believed to be 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.
///
/// Note that the implementation of this is not perfect. Namely, `\p{Ll}`
/// will prevent case insensitive matching even though it is part of a meta
/// sequence. This bug will probably never be fixed.
pub fn case_smart(&mut self, yes: bool) -> &mut RegexMatcherBuilder {
self.case_smart = yes;
self
}
/// Enables "dot all" matching.
///
/// When enabled, the `.` metacharacter in the pattern matches any
/// character, include `\n`. When disabled (the default), `.` will match
/// any character except for `\n`.
///
/// This option corresponds to the `s` flag.
pub fn dotall(&mut self, yes: bool) -> &mut RegexMatcherBuilder {
self.builder.dotall(yes);
self
}
/// Enable "extended" mode in the pattern, where whitespace is ignored.
///
/// This option corresponds to the `x` flag.
pub fn extended(&mut self, yes: bool) -> &mut RegexMatcherBuilder {
self.builder.extended(yes);
self
}
/// Enable multiline matching mode.
///
/// When enabled, the `^` and `$` anchors will match both at the beginning
/// and end of a subject string, in addition to matching at the start of
/// a line and the end of a line. When disabled, the `^` and `$` anchors
/// will only match at the beginning and end of a subject string.
///
/// This option corresponds to the `m` flag.
pub fn multi_line(&mut self, yes: bool) -> &mut RegexMatcherBuilder {
self.builder.multi_line(yes);
self
}
/// Enable matching of CRLF as a line terminator.
///
/// When enabled, anchors such as `^` and `$` will match any of the
/// following as a line terminator: `\r`, `\n` or `\r\n`.
///
/// This is disabled by default, in which case, only `\n` is recognized as
/// a line terminator.
pub fn crlf(&mut self, yes: bool) -> &mut RegexMatcherBuilder {
self.builder.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.word = yes;
self
}
/// Enable Unicode matching mode.
///
/// When enabled, the following patterns become Unicode aware: `\b`, `\B`,
/// `\d`, `\D`, `\s`, `\S`, `\w`, `\W`.
///
/// When set, this implies UTF matching mode. It is not possible to enable
/// Unicode matching mode without enabling UTF matching mode.
///
/// This is disabled by default.
pub fn ucp(&mut self, yes: bool) -> &mut RegexMatcherBuilder {
self.builder.ucp(yes);
self
}
/// Enable UTF matching mode.
///
/// When enabled, characters are treated as sequences of code units that
/// make up a single codepoint instead of as single bytes. For example,
/// this will cause `.` to match any single UTF-8 encoded codepoint, where
/// as when this is disabled, `.` will any single byte (except for `\n` in
/// both cases, unless "dot all" mode is enabled).
///
/// Note that when UTF matching mode is enabled, every search performed
/// will do a UTF-8 validation check, which can impact performance. The
/// UTF-8 check can be disabled via the `disable_utf_check` option, but it
/// is undefined behavior to enable UTF matching mode and search invalid
/// UTF-8.
///
/// This is disabled by default.
pub fn utf(&mut self, yes: bool) -> &mut RegexMatcherBuilder {
self.builder.utf(yes);
self
}
/// When UTF matching mode is enabled, this will disable the UTF checking
/// that PCRE2 will normally perform automatically. If UTF matching mode
/// is not enabled, then this has no effect.
///
/// UTF checking is enabled by default when UTF matching mode is enabled.
/// If UTF matching mode is enabled and UTF checking is enabled, then PCRE2
/// will return an error if you attempt to search a subject string that is
/// not valid UTF-8.
///
/// # Safety
///
/// It is undefined behavior to disable the UTF check in UTF matching mode
/// and search a subject string that is not valid UTF-8. When the UTF check
/// is disabled, callers must guarantee that the subject string is valid
/// UTF-8.
pub unsafe fn disable_utf_check(&mut self) -> &mut RegexMatcherBuilder {
self.builder.disable_utf_check();
self
}
/// Enable PCRE2's JIT and return an error if it's not available.
///
/// This generally speeds up matching quite a bit. The downside is that it
/// can increase the time it takes to compile a pattern.
///
/// If the JIT isn't available or if JIT compilation returns an error, then
/// regex compilation will fail with the corresponding error.
///
/// This is disabled by default, and always overrides `jit_if_available`.
pub fn jit(&mut self, yes: bool) -> &mut RegexMatcherBuilder {
self.builder.jit(yes);
self
}
/// Enable PCRE2's JIT if it's available.
///
/// This generally speeds up matching quite a bit. The downside is that it
/// can increase the time it takes to compile a pattern.
///
/// If the JIT isn't available or if JIT compilation returns an error,
/// then a debug message with the error will be emitted and the regex will
/// otherwise silently fall back to non-JIT matching.
///
/// This is disabled by default, and always overrides `jit`.
pub fn jit_if_available(&mut self, yes: bool) -> &mut RegexMatcherBuilder {
self.builder.jit_if_available(yes);
self
}
/// Set the maximum size of PCRE2's JIT stack, in bytes. If the JIT is
/// not enabled, then this has no effect.
///
/// When `None` is given, no custom JIT stack will be created, and instead,
/// the default JIT stack is used. When the default is used, its maximum
/// size is 32 KB.
///
/// When this is set, then a new JIT stack will be created with the given
/// maximum size as its limit.
///
/// Increasing the stack size can be useful for larger regular expressions.
///
/// By default, this is set to `None`.
pub fn max_jit_stack_size(
&mut self,
bytes: Option<usize>,
) -> &mut RegexMatcherBuilder {
self.builder.max_jit_stack_size(bytes);
self
}
}
/// An implementation of the `Matcher` trait using PCRE2.
#[derive(Clone, Debug)]
pub struct RegexMatcher {
regex: Regex,
names: HashMap<String, usize>,
}
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)
}
}
impl Matcher for RegexMatcher {
type Captures = RegexCaptures;
type Error = Error;
fn find_at(
&self,
haystack: &[u8],
at: usize,
) -> Result<Option<Match>, Error> {
Ok(self
.regex
.find_at(haystack, at)
.map_err(Error::regex)?
.map(|m| Match::new(m.start(), m.end())))
}
fn new_captures(&self) -> Result<RegexCaptures, Error> {
Ok(RegexCaptures::new(self.regex.capture_locations()))
}
fn capture_count(&self) -> usize {
self.regex.captures_len()
}
fn capture_index(&self, name: &str) -> Option<usize> {
self.names.get(name).map(|i| *i)
}
fn try_find_iter<F, E>(
&self,
haystack: &[u8],
mut matched: F,
) -> Result<Result<(), E>, Error>
where
F: FnMut(Match) -> Result<bool, E>,
{
for result in self.regex.find_iter(haystack) {
let m = result.map_err(Error::regex)?;
match matched(Match::new(m.start(), m.end())) {
Ok(true) => continue,
Ok(false) => return Ok(Ok(())),
Err(err) => return Ok(Err(err)),
}
}
Ok(Ok(()))
}
fn captures_at(
&self,
haystack: &[u8],
at: usize,
caps: &mut RegexCaptures,
) -> Result<bool, Error> {
Ok(self
.regex
.captures_read_at(&mut caps.locs, haystack, at)
.map_err(Error::regex)?
.is_some())
}
}
/// 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 locations are stored.
locs: CaptureLocations,
}
impl Captures for RegexCaptures {
fn len(&self) -> usize {
self.locs.len()
}
fn get(&self, i: usize) -> Option<Match> {
self.locs.get(i).map(|(s, e)| Match::new(s, e))
}
}
impl RegexCaptures {
pub(crate) fn new(locs: CaptureLocations) -> RegexCaptures {
RegexCaptures { locs }
}
}
/// Determine whether the pattern contains an uppercase character which should
/// negate the effect of the smart-case option.
///
/// Ideally we would be able to check the AST in order to correctly handle
/// things like '\p{Ll}' and '\p{Lu}' (which should be treated as explicitly
/// cased), but PCRE doesn't expose enough details for that kind of analysis.
/// For now, our 'good enough' solution is to simply perform a semi-naïve
/// scan of the input pattern and ignore all characters following a '\'. The
/// This at least lets us support the most common cases, like 'foo\w' and
/// 'foo\S', in an intuitive manner.
fn has_uppercase_literal(pattern: &str) -> bool {
let mut chars = pattern.chars();
while let Some(c) = chars.next() {
if c == '\\' {
chars.next();
} else if c.is_uppercase() {
return true;
}
}
false
}
#[cfg(test)]
mod tests {
use super::*;
use grep_matcher::{LineMatchKind, Matcher};
// 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 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.
#[test]
fn candidate_lines() {
fn is_confirmed(m: LineMatchKind) -> bool {
match m {
LineMatchKind::Confirmed(_) => true,
_ => false,
}
}
let matcher = RegexMatcherBuilder::new().build(r"\wfoo\s").unwrap();
let m = matcher.find_candidate_line(b"afoo ").unwrap().unwrap();
assert!(is_confirmed(m));
}
}