Struct regex_automata::hybrid::regex::Regex
source · pub struct Regex { /* private fields */ }
Expand description
A regular expression that uses hybrid NFA/DFAs (also called “lazy DFAs”) for searching.
A regular expression is comprised of two lazy DFAs, a “forward” DFA and a “reverse” DFA. The forward DFA is responsible for detecting the end of a match while the reverse DFA is responsible for detecting the start of a match. Thus, in order to find the bounds of any given match, a forward search must first be run followed by a reverse search. A match found by the forward DFA guarantees that the reverse DFA will also find a match.
Fallibility
Most of the search routines defined on this type will panic when the
underlying search fails. This might be because the DFA gave up because it
saw a quit byte, whether configured explicitly or via heuristic Unicode
word boundary support, although neither are enabled by default. It might
also fail if the underlying DFA determines it isn’t making effective use of
the cache (which also never happens by default). Or it might fail because
an invalid Input
configuration is given, for example, with an unsupported
Anchored
mode.
If you need to handle these error cases instead of allowing them to trigger
a panic, then the lower level Regex::try_search
provides a fallible API
that never panics.
Example
This example shows how to cause a search to terminate if it sees a
\n
byte, and handle the error returned. This could be useful if, for
example, you wanted to prevent a user supplied pattern from matching
across a line boundary.
use regex_automata::{hybrid::{dfa, regex::Regex}, Input, MatchError};
let re = Regex::builder()
.dfa(dfa::Config::new().quit(b'\n', true))
.build(r"foo\p{any}+bar")?;
let mut cache = re.create_cache();
let input = Input::new("foo\nbar");
// Normally this would produce a match, since \p{any} contains '\n'.
// But since we instructed the automaton to enter a quit state if a
// '\n' is observed, this produces a match error instead.
let expected = MatchError::quit(b'\n', 3);
let got = re.try_search(&mut cache, &input).unwrap_err();
assert_eq!(expected, got);
Implementations§
source§impl Regex
impl Regex
Convenience routines for regex and cache construction.
sourcepub fn new(pattern: &str) -> Result<Regex, BuildError>
pub fn new(pattern: &str) -> Result<Regex, BuildError>
Parse the given regular expression using the default configuration and return the corresponding regex.
If you want a non-default configuration, then use the Builder
to
set your own configuration.
Example
use regex_automata::{hybrid::regex::Regex, Match};
let re = Regex::new("foo[0-9]+bar")?;
let mut cache = re.create_cache();
assert_eq!(
Some(Match::must(0, 3..14)),
re.find(&mut cache, "zzzfoo12345barzzz"),
);
sourcepub fn new_many<P: AsRef<str>>(patterns: &[P]) -> Result<Regex, BuildError>
pub fn new_many<P: AsRef<str>>(patterns: &[P]) -> Result<Regex, BuildError>
Like new
, but parses multiple patterns into a single “multi regex.”
This similarly uses the default regex configuration.
Example
use regex_automata::{hybrid::regex::Regex, Match};
let re = Regex::new_many(&["[a-z]+", "[0-9]+"])?;
let mut cache = re.create_cache();
let mut it = re.find_iter(&mut cache, "abc 1 foo 4567 0 quux");
assert_eq!(Some(Match::must(0, 0..3)), it.next());
assert_eq!(Some(Match::must(1, 4..5)), it.next());
assert_eq!(Some(Match::must(0, 6..9)), it.next());
assert_eq!(Some(Match::must(1, 10..14)), it.next());
assert_eq!(Some(Match::must(1, 15..16)), it.next());
assert_eq!(Some(Match::must(0, 17..21)), it.next());
assert_eq!(None, it.next());
sourcepub fn builder() -> Builder
pub fn builder() -> Builder
Return a builder for configuring the construction of a Regex
.
This is a convenience routine to avoid needing to import the
Builder
type in common cases.
Example
This example shows how to use the builder to disable UTF-8 mode everywhere.
use regex_automata::{
hybrid::regex::Regex, nfa::thompson, util::syntax, Match,
};
let re = Regex::builder()
.syntax(syntax::Config::new().utf8(false))
.thompson(thompson::Config::new().utf8(false))
.build(r"foo(?-u:[^b])ar.*")?;
let mut cache = re.create_cache();
let haystack = b"\xFEfoo\xFFarzz\xE2\x98\xFF\n";
let expected = Some(Match::must(0, 1..9));
let got = re.find(&mut cache, haystack);
assert_eq!(expected, got);
sourcepub fn create_cache(&self) -> Cache
pub fn create_cache(&self) -> Cache
Create a new cache for this Regex
.
The cache returned should only be used for searches for this
Regex
. If you want to reuse the cache for another Regex
, then
you must call Cache::reset
with that Regex
(or, equivalently,
Regex::reset_cache
).
sourcepub fn reset_cache(&self, cache: &mut Cache)
pub fn reset_cache(&self, cache: &mut Cache)
Reset the given cache such that it can be used for searching with the
this Regex
(and only this Regex
).
A cache reset permits reusing memory already allocated in this cache
with a different Regex
.
Resetting a cache sets its “clear count” to 0. This is relevant if the
Regex
has been configured to “give up” after it has cleared the cache
a certain number of times.
Example
This shows how to re-purpose a cache for use with a different Regex
.
use regex_automata::{hybrid::regex::Regex, Match};
let re1 = Regex::new(r"\w")?;
let re2 = Regex::new(r"\W")?;
let mut cache = re1.create_cache();
assert_eq!(
Some(Match::must(0, 0..2)),
re1.find(&mut cache, "Δ"),
);
// Using 'cache' with re2 is not allowed. It may result in panics or
// incorrect results. In order to re-purpose the cache, we must reset
// it with the Regex we'd like to use it with.
//
// Similarly, after this reset, using the cache with 're1' is also not
// allowed.
re2.reset_cache(&mut cache);
assert_eq!(
Some(Match::must(0, 0..3)),
re2.find(&mut cache, "☃"),
);
source§impl Regex
impl Regex
Standard infallible search routines for finding and iterating over matches.
sourcepub fn is_match<'h, I: Into<Input<'h>>>(
&self,
cache: &mut Cache,
input: I
) -> bool
pub fn is_match<'h, I: Into<Input<'h>>>( &self, cache: &mut Cache, input: I ) -> bool
Returns true if and only if this regex matches the given haystack.
This routine may short circuit if it knows that scanning future input
will never lead to a different result. In particular, if the underlying
DFA enters a match state or a dead state, then this routine will return
true
or false
, respectively, without inspecting any future input.
Panics
This routine panics if the search could not complete. This can occur in a number of circumstances:
- The configuration of the lazy DFA may permit it to “quit” the search. For example, setting quit bytes or enabling heuristic support for Unicode word boundaries. The default configuration does not enable any option that could result in the lazy DFA quitting.
- The configuration of the lazy DFA may also permit it to “give up” on a search if it makes ineffective use of its transition table cache. The default configuration does not enable this by default, although it is typically a good idea to.
- When the provided
Input
configuration is not supported. For example, by providing an unsupported anchor mode.
When a search panics, callers cannot know whether a match exists or not.
Use Regex::try_search
if you want to handle these error conditions.
Example
use regex_automata::hybrid::regex::Regex;
let re = Regex::new("foo[0-9]+bar")?;
let mut cache = re.create_cache();
assert!(re.is_match(&mut cache, "foo12345bar"));
assert!(!re.is_match(&mut cache, "foobar"));
sourcepub fn find<'h, I: Into<Input<'h>>>(
&self,
cache: &mut Cache,
input: I
) -> Option<Match>
pub fn find<'h, I: Into<Input<'h>>>( &self, cache: &mut Cache, input: I ) -> Option<Match>
Returns the start and end offset of the leftmost match. If no match
exists, then None
is returned.
Panics
This routine panics if the search could not complete. This can occur in a number of circumstances:
- The configuration of the lazy DFA may permit it to “quit” the search. For example, setting quit bytes or enabling heuristic support for Unicode word boundaries. The default configuration does not enable any option that could result in the lazy DFA quitting.
- The configuration of the lazy DFA may also permit it to “give up” on a search if it makes ineffective use of its transition table cache. The default configuration does not enable this by default, although it is typically a good idea to.
- When the provided
Input
configuration is not supported. For example, by providing an unsupported anchor mode.
When a search panics, callers cannot know whether a match exists or not.
Use Regex::try_search
if you want to handle these error conditions.
Example
use regex_automata::{Match, hybrid::regex::Regex};
let re = Regex::new("foo[0-9]+")?;
let mut cache = re.create_cache();
assert_eq!(
Some(Match::must(0, 3..11)),
re.find(&mut cache, "zzzfoo12345zzz"),
);
// Even though a match is found after reading the first byte (`a`),
// the default leftmost-first match semantics demand that we find the
// earliest match that prefers earlier parts of the pattern over latter
// parts.
let re = Regex::new("abc|a")?;
let mut cache = re.create_cache();
assert_eq!(Some(Match::must(0, 0..3)), re.find(&mut cache, "abc"));
sourcepub fn find_iter<'r, 'c, 'h, I: Into<Input<'h>>>(
&'r self,
cache: &'c mut Cache,
input: I
) -> FindMatches<'r, 'c, 'h> ⓘ
pub fn find_iter<'r, 'c, 'h, I: Into<Input<'h>>>( &'r self, cache: &'c mut Cache, input: I ) -> FindMatches<'r, 'c, 'h> ⓘ
Returns an iterator over all non-overlapping leftmost matches in the given bytes. If no match exists, then the iterator yields no elements.
Panics
This routine panics if the search could not complete. This can occur in a number of circumstances:
- The configuration of the lazy DFA may permit it to “quit” the search. For example, setting quit bytes or enabling heuristic support for Unicode word boundaries. The default configuration does not enable any option that could result in the lazy DFA quitting.
- The configuration of the lazy DFA may also permit it to “give up” on a search if it makes ineffective use of its transition table cache. The default configuration does not enable this by default, although it is typically a good idea to.
- When the provided
Input
configuration is not supported. For example, by providing an unsupported anchor mode.
When a search panics, callers cannot know whether a match exists or not.
The above conditions also apply to the iterator returned as well. For example, if the lazy DFA gives up or quits during a search using this method, then a panic will occur during iteration.
Use Regex::try_search
with util::iter::Searcher
if you want to handle these error conditions.
Example
use regex_automata::{hybrid::regex::Regex, Match};
let re = Regex::new("foo[0-9]+")?;
let mut cache = re.create_cache();
let text = "foo1 foo12 foo123";
let matches: Vec<Match> = re.find_iter(&mut cache, text).collect();
assert_eq!(matches, vec![
Match::must(0, 0..4),
Match::must(0, 5..10),
Match::must(0, 11..17),
]);
source§impl Regex
impl Regex
Lower level “search” primitives that accept a &Input
for cheap reuse
and return an error if one occurs instead of panicking.
sourcepub fn try_search(
&self,
cache: &mut Cache,
input: &Input<'_>
) -> Result<Option<Match>, MatchError>
pub fn try_search( &self, cache: &mut Cache, input: &Input<'_> ) -> Result<Option<Match>, MatchError>
Returns the start and end offset of the leftmost match. If no match
exists, then None
is returned.
This is like Regex::find
but with two differences:
- It is not generic over
Into<Input>
and instead accepts a&Input
. This permits reusing the sameInput
for multiple searches without needing to create a new one. This may help with latency. - It returns an error if the search could not complete where as
Regex::find
will panic.
Errors
This routine errors if the search could not complete. This can occur in a number of circumstances:
- The configuration of the lazy DFA may permit it to “quit” the search. For example, setting quit bytes or enabling heuristic support for Unicode word boundaries. The default configuration does not enable any option that could result in the lazy DFA quitting.
- The configuration of the lazy DFA may also permit it to “give up” on a search if it makes ineffective use of its transition table cache. The default configuration does not enable this by default, although it is typically a good idea to.
- When the provided
Input
configuration is not supported. For example, by providing an unsupported anchor mode.
When a search returns an error, callers cannot know whether a match exists or not.
source§impl Regex
impl Regex
Non-search APIs for querying information about the regex and setting a prefilter.
sourcepub fn forward(&self) -> &DFA
pub fn forward(&self) -> &DFA
Return the underlying lazy DFA responsible for forward matching.
This is useful for accessing the underlying lazy DFA and using it directly if the situation calls for it.
sourcepub fn reverse(&self) -> &DFA
pub fn reverse(&self) -> &DFA
Return the underlying lazy DFA responsible for reverse matching.
This is useful for accessing the underlying lazy DFA and using it directly if the situation calls for it.
sourcepub fn pattern_len(&self) -> usize
pub fn pattern_len(&self) -> usize
Returns the total number of patterns matched by this regex.
Example
use regex_automata::hybrid::regex::Regex;
let re = Regex::new_many(&[r"[a-z]+", r"[0-9]+", r"\w+"])?;
assert_eq!(3, re.pattern_len());