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/*!

A library for finding occurrences of many patterns at once. This library

provides multiple pattern search principally through an implementation of the

[Aho-Corasick algorithm](https://en.wikipedia.org/wiki/Aho%E2%80%93Corasick_algorithm),

which builds a fast finite state machine for executing searches in linear time.

Additionally, this library provides a number of configuration options for

building the automaton that permit controlling the space versus time trade

off. Other features include simple ASCII case insensitive matching, finding

overlapping matches, replacements, searching streams and even searching and

replacing text in streams.

Finally, unlike most other Aho-Corasick implementations, this one

supports enabling [leftmost-first](MatchKind::LeftmostFirst) or

[leftmost-longest](MatchKind::LeftmostLongest) match semantics, using a

(seemingly) novel alternative construction algorithm. For more details on what

match semantics means, see the [`MatchKind`] type.

# Overview

This section gives a brief overview of the primary types in this crate:

* [`AhoCorasick`] is the primary type and represents an Aho-Corasick automaton.

This is the type you use to execute searches.

* [`AhoCorasickBuilder`] can be used to build an Aho-Corasick automaton, and

supports configuring a number of options.

* [`Match`] represents a single match reported by an Aho-Corasick automaton.

Each match has two pieces of information: the pattern that matched and the

start and end byte offsets corresponding to the position in the haystack at

which it matched.

# Example: basic searching

This example shows how to search for occurrences of multiple patterns

simultaneously. Each match includes the pattern that matched along with the

byte offsets of the match.

```

use aho_corasick::{AhoCorasick, PatternID};

let patterns = &["apple", "maple", "Snapple"];

let haystack = "Nobody likes maple in their apple flavored Snapple.";

let ac = AhoCorasick::new(patterns).unwrap();

let mut matches = vec![];

for mat in ac.find_iter(haystack) {

    matches.push((mat.pattern(), mat.start(), mat.end()));

assert_eq!(matches, vec![

    (PatternID::must(1), 13, 18),

    (PatternID::must(0), 28, 33),

    (PatternID::must(2), 43, 50),

]);

```

# Example: case insensitivity

This is like the previous example, but matches `Snapple` case insensitively

using `AhoCorasickBuilder`:

```

use aho_corasick::{AhoCorasick, PatternID};

let patterns = &["apple", "maple", "snapple"];

let haystack = "Nobody likes maple in their apple flavored Snapple.";

let ac = AhoCorasick::builder()

    .ascii_case_insensitive(true)

    .build(patterns)

    .unwrap();

let mut matches = vec![];

for mat in ac.find_iter(haystack) {

    matches.push((mat.pattern(), mat.start(), mat.end()));

assert_eq!(matches, vec![

    (PatternID::must(1), 13, 18),

    (PatternID::must(0), 28, 33),

    (PatternID::must(2), 43, 50),

]);

```

# Example: replacing matches in a stream

This example shows how to execute a search and replace on a stream without

loading the entire stream into memory first.

```

# #[cfg(feature = "std")] {

use aho_corasick::AhoCorasick;

# fn example() -> Result<(), std::io::Error> {

let patterns = &["fox", "brown", "quick"];

let replace_with = &["sloth", "grey", "slow"];

// In a real example, these might be `std::fs::File`s instead. All you need to

// do is supply a pair of `std::io::Read` and `std::io::Write` implementations.

let rdr = "The quick brown fox.";

let mut wtr = vec![];

let ac = AhoCorasick::new(patterns).unwrap();

ac.try_stream_replace_all(rdr.as_bytes(), &mut wtr, replace_with)?;

assert_eq!(b"The slow grey sloth.".to_vec(), wtr);

# Ok(()) }; example().unwrap()

# }

```

# Example: finding the leftmost first match

In the textbook description of Aho-Corasick, its formulation is typically

structured such that it reports all possible matches, even when they overlap

with another. In many cases, overlapping matches may not be desired, such as

the case of finding all successive non-overlapping matches like you might with

a standard regular expression.

Unfortunately the "obvious" way to modify the Aho-Corasick algorithm to do

this doesn't always work in the expected way, since it will report matches as

soon as they are seen. For example, consider matching the regex `Samwise|Sam`

against the text `Samwise`. Most regex engines (that are Perl-like, or

non-POSIX) will report `Samwise` as a match, but the standard Aho-Corasick

algorithm modified for reporting non-overlapping matches will report `Sam`.

A novel contribution of this library is the ability to change the match

semantics of Aho-Corasick (without additional search time overhead) such that

`Samwise` is reported instead. For example, here's the standard approach:

```

use aho_corasick::AhoCorasick;

let patterns = &["Samwise", "Sam"];

let haystack = "Samwise";

let ac = AhoCorasick::new(patterns).unwrap();

let mat = ac.find(haystack).expect("should have a match");

assert_eq!("Sam", &haystack[mat.start()..mat.end()]);

```

And now here's the leftmost-first version, which matches how a Perl-like

regex will work:

```

use aho_corasick::{AhoCorasick, MatchKind};

let patterns = &["Samwise", "Sam"];

let haystack = "Samwise";

let ac = AhoCorasick::builder()

    .match_kind(MatchKind::LeftmostFirst)

    .build(patterns)

    .unwrap();

let mat = ac.find(haystack).expect("should have a match");

assert_eq!("Samwise", &haystack[mat.start()..mat.end()]);

```

In addition to leftmost-first semantics, this library also supports

leftmost-longest semantics, which match the POSIX behavior of a regular

expression alternation. See [`MatchKind`] for more details.

# Prefilters

While an Aho-Corasick automaton can perform admirably when compared to more

naive solutions, it is generally slower than more specialized algorithms that

are accelerated using vector instructions such as SIMD.

For that reason, this library will internally use a "prefilter" to attempt

to accelerate searches when possible. Currently, this library has several

different algorithms it might use depending on the patterns provided. Once the

number of patterns gets too big, prefilters are no longer used.

While a prefilter is generally good to have on by default since it works

well in the common case, it can lead to less predictable or even sub-optimal

performance in some cases. For that reason, prefilters can be explicitly

disabled via [`AhoCorasickBuilder::prefilter`].

# Lower level APIs

This crate also provides several sub-modules that collectively expose many of

the implementation details of the main [`AhoCorasick`] type. Most users of this

library can completely ignore the submodules and their contents, but if you

needed finer grained control, some parts of them may be useful to you. Here is

a brief overview of each and why you might want to use them:

* The [`packed`] sub-module contains a lower level API for using fast

vectorized routines for finding a small number of patterns in a haystack.

You might want to use this API when you want to completely side-step using

Aho-Corasick automata. Otherwise, the fast vectorized routines are used

automatically as prefilters for `AhoCorasick` searches whenever possible.

* The [`automaton`] sub-module provides a lower level finite state

machine interface that the various Aho-Corasick implementations in

this crate implement. This sub-module's main contribution is the

[`Automaton`](automaton::Automaton) trait, which permits manually walking the

state transitions of an Aho-Corasick automaton.

* The [`dfa`] and [`nfa`] sub-modules provide DFA and NFA implementations of

the aforementioned `Automaton` trait. The main reason one might want to use

these sub-modules is to get access to a type that implements the `Automaton`

trait. (The top-level `AhoCorasick` type does not implement the `Automaton`

trait.)

As mentioned above, if you aren't sure whether you need these sub-modules,

you should be able to safely ignore them and just focus on the [`AhoCorasick`]

type.

# Crate features

This crate exposes a few features for controlling dependency usage and whether

this crate can be used without the standard library.

* **std** -

  Enables support for the standard library. This feature is enabled by

  default. When disabled, only `core` and `alloc` are used. At an API

  level, enabling `std` enables `std::error::Error` trait impls for the

  various error types, and higher level stream search routines such as

  [`AhoCorasick::try_stream_find_iter`]. But the `std` feature is also required

  to enable vectorized prefilters. Prefilters can greatly accelerate searches,

  but generally only apply when the number of patterns is small (less than

  ~100).

* **perf-literal** -

  Enables support for literal prefilters that use vectorized routines from

  external crates. This feature is enabled by default. If you're only using

  Aho-Corasick for large numbers of patterns or otherwise can abide lower

  throughput when searching with a small number of patterns, then it is

  reasonable to disable this feature.

* **logging** -

  Enables a dependency on the `log` crate and emits messages to aide in

  diagnostics. This feature is disabled by default.

*/

#![no_std]

#![deny(missing_docs)]

#![deny(rustdoc::broken_intra_doc_links)]

#![cfg_attr(docsrs, feature(doc_auto_cfg))]

extern crate alloc;

#[cfg(any(test, feature = "std"))]

extern crate std;

#[cfg(doctest)]

doc_comment::doctest!("../README.md");

#[cfg(feature = "std")]

pub use crate::ahocorasick::StreamFindIter;

pub use crate::{

    ahocorasick::{

        AhoCorasick, AhoCorasickBuilder, AhoCorasickKind, FindIter,

        FindOverlappingIter,

},

    util::{

        error::{BuildError, MatchError, MatchErrorKind},

        primitives::{PatternID, PatternIDError},

        search::{Anchored, Input, Match, MatchKind, Span, StartKind},

},

};

#[macro_use]

mod macros;

mod ahocorasick;

pub mod automaton;

pub mod dfa;

pub mod nfa;

pub mod packed;

#[cfg(test)]

mod tests;

// I wrote out the module for implementing fst::Automaton only to later realize

// that this would make fst a public dependency and fst is not at 1.0 yet. I

// decided to just keep the code in tree, but build it only during tests.

//

// TODO: I think I've changed my mind again. I'm considering pushing it out

// into either a separate crate or into 'fst' directly as an optional feature.

// #[cfg(test)]

// #[allow(dead_code)]

// mod transducer;

pub(crate) mod util;

#[cfg(test)]

mod testoibits {

    use std::panic::{RefUnwindSafe, UnwindSafe};

    use super::*;

    fn assert_all<T: Send + Sync + UnwindSafe + RefUnwindSafe>() {}

    #[test]

    fn oibits_main() {

        assert_all::<AhoCorasick>();

        assert_all::<AhoCorasickBuilder>();

        assert_all::<AhoCorasickKind>();

        assert_all::<FindIter>();

        assert_all::<FindOverlappingIter>();

        assert_all::<BuildError>();

        assert_all::<MatchError>();

        assert_all::<MatchErrorKind>();

        assert_all::<Anchored>();

        assert_all::<Input>();

        assert_all::<Match>();

        assert_all::<MatchKind>();

        assert_all::<Span>();

        assert_all::<StartKind>();

    #[test]

    fn oibits_automaton() {

        use crate::{automaton, dfa::DFA};

        assert_all::<automaton::FindIter<DFA>>();

        assert_all::<automaton::FindOverlappingIter<DFA>>();

        #[cfg(feature = "std")]

        assert_all::<automaton::StreamFindIter<DFA, std::io::Stdin>>();

        assert_all::<automaton::OverlappingState>();

        assert_all::<automaton::Prefilter>();

        assert_all::<automaton::Candidate>();

    #[test]

    fn oibits_packed() {

        use crate::packed;

        assert_all::<packed::Config>();

        assert_all::<packed::Builder>();

        assert_all::<packed::Searcher>();

        assert_all::<packed::FindIter>();

        assert_all::<packed::MatchKind>();