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diff --git a/vendor/regex-automata/src/dfa/mod.rs b/vendor/regex-automata/src/dfa/mod.rs new file mode 100644 index 0000000..fd58cac --- /dev/null +++ b/vendor/regex-automata/src/dfa/mod.rs @@ -0,0 +1,360 @@ +/*! +A module for building and searching with deterministic finite automata (DFAs). + +Like other modules in this crate, DFAs support a rich regex syntax with Unicode +features. DFAs also have extensive options for configuring the best space vs +time trade off for your use case and provides support for cheap deserialization +of automata for use in `no_std` environments. + +If you're looking for lazy DFAs that build themselves incrementally during +search, then please see the top-level [`hybrid` module](crate::hybrid). + +# Overview + +This section gives a brief overview of the primary types in this module: + +* A [`regex::Regex`] provides a way to search for matches of a regular +expression using DFAs. This includes iterating over matches with both the start +and end positions of each match. +* A [`dense::DFA`] provides low level access to a DFA that uses a dense +representation (uses lots of space, but fast searching). +* A [`sparse::DFA`] provides the same API as a `dense::DFA`, but uses a sparse +representation (uses less space, but slower searching). +* An [`Automaton`] trait that defines an interface that both dense and sparse +DFAs implement. (A `regex::Regex` is generic over this trait.) +* Both dense DFAs and sparse DFAs support serialization to raw bytes (e.g., +[`dense::DFA::to_bytes_little_endian`]) and cheap deserialization (e.g., +[`dense::DFA::from_bytes`]). + +There is also a [`onepass`] module that provides a [one-pass +DFA](onepass::DFA). The unique advantage of this DFA is that, for the class +of regexes it can be built with, it supports reporting the spans of matching +capturing groups. It is the only DFA in this crate capable of such a thing. + +# Example: basic regex searching + +This example shows how to compile a regex using the default configuration +and then use it to find matches in a byte string: + +``` +use regex_automata::{Match, dfa::regex::Regex}; + +let re = Regex::new(r"[0-9]{4}-[0-9]{2}-[0-9]{2}")?; +let text = b"2018-12-24 2016-10-08"; +let matches: Vec<Match> = re.find_iter(text).collect(); +assert_eq!(matches, vec![ + Match::must(0, 0..10), + Match::must(0, 11..21), +]); +# Ok::<(), Box<dyn std::error::Error>>(()) +``` + +# Example: searching with regex sets + +The DFAs in this module all fully support searching with multiple regexes +simultaneously. You can use this support with standard leftmost-first style +searching to find non-overlapping matches: + +``` +# if cfg!(miri) { return Ok(()); } // miri takes too long +use regex_automata::{Match, dfa::regex::Regex}; + +let re = Regex::new_many(&[r"\w+", r"\S+"])?; +let text = b"@foo bar"; +let matches: Vec<Match> = re.find_iter(text).collect(); +assert_eq!(matches, vec![ + Match::must(1, 0..4), + Match::must(0, 5..8), +]); +# Ok::<(), Box<dyn std::error::Error>>(()) +``` + +# Example: use sparse DFAs + +By default, compiling a regex will use dense DFAs internally. This uses more +memory, but executes searches more quickly. If you can abide slower searches +(somewhere around 3-5x), then sparse DFAs might make more sense since they can +use significantly less space. + +Using sparse DFAs is as easy as using `Regex::new_sparse` instead of +`Regex::new`: + +``` +use regex_automata::{Match, dfa::regex::Regex}; + +let re = Regex::new_sparse(r"[0-9]{4}-[0-9]{2}-[0-9]{2}").unwrap(); +let text = b"2018-12-24 2016-10-08"; +let matches: Vec<Match> = re.find_iter(text).collect(); +assert_eq!(matches, vec![ + Match::must(0, 0..10), + Match::must(0, 11..21), +]); +# Ok::<(), Box<dyn std::error::Error>>(()) +``` + +If you already have dense DFAs for some reason, they can be converted to sparse +DFAs and used to build a new `Regex`. For example: + +``` +use regex_automata::{Match, dfa::regex::Regex}; + +let dense_re = Regex::new(r"[0-9]{4}-[0-9]{2}-[0-9]{2}").unwrap(); +let sparse_re = Regex::builder().build_from_dfas( + dense_re.forward().to_sparse()?, + dense_re.reverse().to_sparse()?, +); +let text = b"2018-12-24 2016-10-08"; +let matches: Vec<Match> = sparse_re.find_iter(text).collect(); +assert_eq!(matches, vec![ + Match::must(0, 0..10), + Match::must(0, 11..21), +]); +# Ok::<(), Box<dyn std::error::Error>>(()) +``` + +# Example: deserialize a DFA + +This shows how to first serialize a DFA into raw bytes, and then deserialize +those raw bytes back into a DFA. While this particular example is a +bit contrived, this same technique can be used in your program to +deserialize a DFA at start up time or by memory mapping a file. + +``` +use regex_automata::{Match, dfa::{dense, regex::Regex}}; + +let re1 = Regex::new(r"[0-9]{4}-[0-9]{2}-[0-9]{2}").unwrap(); +// serialize both the forward and reverse DFAs, see note below +let (fwd_bytes, fwd_pad) = re1.forward().to_bytes_native_endian(); +let (rev_bytes, rev_pad) = re1.reverse().to_bytes_native_endian(); +// now deserialize both---we need to specify the correct type! +let fwd: dense::DFA<&[u32]> = dense::DFA::from_bytes(&fwd_bytes[fwd_pad..])?.0; +let rev: dense::DFA<&[u32]> = dense::DFA::from_bytes(&rev_bytes[rev_pad..])?.0; +// finally, reconstruct our regex +let re2 = Regex::builder().build_from_dfas(fwd, rev); + +// we can use it like normal +let text = b"2018-12-24 2016-10-08"; +let matches: Vec<Match> = re2.find_iter(text).collect(); +assert_eq!(matches, vec![ + Match::must(0, 0..10), + Match::must(0, 11..21), +]); +# Ok::<(), Box<dyn std::error::Error>>(()) +``` + +There are a few points worth noting here: + +* We need to extract the raw DFAs used by the regex and serialize those. You +can build the DFAs manually yourself using [`dense::Builder`], but using +the DFAs from a `Regex` guarantees that the DFAs are built correctly. (In +particular, a `Regex` constructs a reverse DFA for finding the starting +location of matches.) +* To convert the DFA to raw bytes, we use the `to_bytes_native_endian` method. +In practice, you'll want to use either [`dense::DFA::to_bytes_little_endian`] +or [`dense::DFA::to_bytes_big_endian`], depending on which platform you're +deserializing your DFA from. If you intend to deserialize on either platform, +then you'll need to serialize both and deserialize the right one depending on +your target's endianness. +* Safely deserializing a DFA requires verifying the raw bytes, particularly if +they are untrusted, since an invalid DFA could cause logical errors, panics +or even undefined behavior. This verification step requires visiting all of +the transitions in the DFA, which can be costly. If cheaper verification is +desired, then [`dense::DFA::from_bytes_unchecked`] is available that only does +verification that can be performed in constant time. However, one can only use +this routine if the caller can guarantee that the bytes provided encoded a +valid DFA. + +The same process can be achieved with sparse DFAs as well: + +``` +use regex_automata::{Match, dfa::{sparse, regex::Regex}}; + +let re1 = Regex::new(r"[0-9]{4}-[0-9]{2}-[0-9]{2}").unwrap(); +// serialize both +let fwd_bytes = re1.forward().to_sparse()?.to_bytes_native_endian(); +let rev_bytes = re1.reverse().to_sparse()?.to_bytes_native_endian(); +// now deserialize both---we need to specify the correct type! +let fwd: sparse::DFA<&[u8]> = sparse::DFA::from_bytes(&fwd_bytes)?.0; +let rev: sparse::DFA<&[u8]> = sparse::DFA::from_bytes(&rev_bytes)?.0; +// finally, reconstruct our regex +let re2 = Regex::builder().build_from_dfas(fwd, rev); + +// we can use it like normal +let text = b"2018-12-24 2016-10-08"; +let matches: Vec<Match> = re2.find_iter(text).collect(); +assert_eq!(matches, vec![ + Match::must(0, 0..10), + Match::must(0, 11..21), +]); +# Ok::<(), Box<dyn std::error::Error>>(()) +``` + +Note that unlike dense DFAs, sparse DFAs have no alignment requirements. +Conversely, dense DFAs must be be aligned to the same alignment as a +[`StateID`](crate::util::primitives::StateID). + +# Support for `no_std` and `alloc`-only + +This crate comes with `alloc` and `std` features that are enabled by default. +When the `alloc` or `std` features are enabled, the API of this module will +include the facilities necessary for compiling, serializing, deserializing +and searching with DFAs. When only the `alloc` feature is enabled, then +implementations of the `std::error::Error` trait are dropped, but everything +else generally remains the same. When both the `alloc` and `std` features are +disabled, the API of this module will shrink such that it only includes the +facilities necessary for deserializing and searching with DFAs. + +The intended workflow for `no_std` environments is thus as follows: + +* Write a program with the `alloc` or `std` features that compiles and +serializes a regular expression. You may need to serialize both little and big +endian versions of each DFA. (So that's 4 DFAs in total for each regex.) +* In your `no_std` environment, follow the examples above for deserializing +your previously serialized DFAs into regexes. You can then search with them as +you would any regex. + +Deserialization can happen anywhere. For example, with bytes embedded into a +binary or with a file memory mapped at runtime. + +The `regex-cli` command (found in the same repository as this crate) can be +used to serialize DFAs to files and generate Rust code to read them. + +# Syntax + +This module supports the same syntax as the `regex` crate, since they share the +same parser. You can find an exhaustive list of supported syntax in the +[documentation for the `regex` crate](https://docs.rs/regex/1/regex/#syntax). + +There are two things that are not supported by the DFAs in this module: + +* Capturing groups. The DFAs (and [`Regex`](regex::Regex)es built on top +of them) can only find the offsets of an entire match, but cannot resolve +the offsets of each capturing group. This is because DFAs do not have the +expressive power necessary. +* Unicode word boundaries. These present particularly difficult challenges for +DFA construction and would result in an explosion in the number of states. +One can enable [`dense::Config::unicode_word_boundary`] though, which provides +heuristic support for Unicode word boundaries that only works on ASCII text. +Otherwise, one can use `(?-u:\b)` for an ASCII word boundary, which will work +on any input. + +There are no plans to lift either of these limitations. + +Note that these restrictions are identical to the restrictions on lazy DFAs. + +# Differences with general purpose regexes + +The main goal of the [`regex`](https://docs.rs/regex) crate is to serve as a +general purpose regular expression engine. It aims to automatically balance low +compile times, fast search times and low memory usage, while also providing +a convenient API for users. In contrast, this module provides a lower level +regular expression interface based exclusively on DFAs that is a bit less +convenient while providing more explicit control over memory usage and search +times. + +Here are some specific negative differences: + +* **Compilation can take an exponential amount of time and space** in the size +of the regex pattern. While most patterns do not exhibit worst case exponential +time, such patterns do exist. For example, `[01]*1[01]{N}` will build a DFA +with approximately `2^(N+2)` states. For this reason, untrusted patterns should +not be compiled with this module. (In the future, the API may expose an option +to return an error if the DFA gets too big.) +* This module does not support sub-match extraction via capturing groups, which +can be achieved with the regex crate's "captures" API. +* While the regex crate doesn't necessarily sport fast compilation times, +the regexes in this module are almost universally slow to compile, especially +when they contain large Unicode character classes. For example, on my system, +compiling `\w{50}` takes about 1 second and almost 15MB of memory! (Compiling +a sparse regex takes about the same time but only uses about 1.2MB of +memory.) Conversely, compiling the same regex without Unicode support, e.g., +`(?-u)\w{50}`, takes under 1 millisecond and about 15KB of memory. For this +reason, you should only use Unicode character classes if you absolutely need +them! (They are enabled by default though.) +* This module does not support Unicode word boundaries. ASCII word bondaries +may be used though by disabling Unicode or selectively doing so in the syntax, +e.g., `(?-u:\b)`. There is also an option to +[heuristically enable Unicode word boundaries](crate::dfa::dense::Config::unicode_word_boundary), +where the corresponding DFA will give up if any non-ASCII byte is seen. +* As a lower level API, this module does not do literal optimizations +automatically. Although it does provide hooks in its API to make use of the +[`Prefilter`](crate::util::prefilter::Prefilter) trait. Missing literal +optimizations means that searches may run much slower than what you're +accustomed to, although, it does provide more predictable and consistent +performance. +* There is no `&str` API like in the regex crate. In this module, all APIs +operate on `&[u8]`. By default, match indices are +guaranteed to fall on UTF-8 boundaries, unless either of +[`syntax::Config::utf8`](crate::util::syntax::Config::utf8) or +[`thompson::Config::utf8`](crate::nfa::thompson::Config::utf8) are disabled. + +With some of the downsides out of the way, here are some positive differences: + +* Both dense and sparse DFAs can be serialized to raw bytes, and then cheaply +deserialized. Deserialization can be done in constant time with the unchecked +APIs, since searching can be performed directly on the raw serialized bytes of +a DFA. +* This module was specifically designed so that the searching phase of a +DFA has minimal runtime requirements, and can therefore be used in `no_std` +environments. While `no_std` environments cannot compile regexes, they can +deserialize pre-compiled regexes. +* Since this module builds DFAs ahead of time, it will generally out-perform +the `regex` crate on equivalent tasks. The performance difference is likely +not large. However, because of a complex set of optimizations in the regex +crate (like literal optimizations), an accurate performance comparison may be +difficult to do. +* Sparse DFAs provide a way to build a DFA ahead of time that sacrifices search +performance a small amount, but uses much less storage space. Potentially even +less than what the regex crate uses. +* This module exposes DFAs directly, such as [`dense::DFA`] and +[`sparse::DFA`], which enables one to do less work in some cases. For example, +if you only need the end of a match and not the start of a match, then you can +use a DFA directly without building a `Regex`, which always requires a second +DFA to find the start of a match. +* This module provides more control over memory usage. Aside from choosing +between dense and sparse DFAs, one can also choose a smaller state identifier +representation to use less space. Also, one can enable DFA minimization +via [`dense::Config::minimize`], but it can increase compilation times +dramatically. +*/ + +#[cfg(feature = "dfa-search")] +pub use crate::dfa::{ + automaton::{Automaton, OverlappingState, StartError}, + start::StartKind, +}; + +/// This is an alias for a state ID of zero. It has special significance +/// because it always corresponds to the first state in a DFA, and the first +/// state in a DFA is always "dead." That is, the dead state always has all +/// of its transitions set to itself. Moreover, the dead state is used as a +/// sentinel for various things. e.g., In search, reaching a dead state means +/// that the search must stop. +const DEAD: crate::util::primitives::StateID = + crate::util::primitives::StateID::ZERO; + +#[cfg(feature = "dfa-search")] +pub mod dense; +#[cfg(feature = "dfa-onepass")] +pub mod onepass; +#[cfg(feature = "dfa-search")] +pub mod regex; +#[cfg(feature = "dfa-search")] +pub mod sparse; + +#[cfg(feature = "dfa-search")] +pub(crate) mod accel; +#[cfg(feature = "dfa-search")] +mod automaton; +#[cfg(feature = "dfa-build")] +mod determinize; +#[cfg(feature = "dfa-build")] +mod minimize; +#[cfg(any(feature = "dfa-build", feature = "dfa-onepass"))] +mod remapper; +#[cfg(feature = "dfa-search")] +mod search; +#[cfg(feature = "dfa-search")] +mod special; +#[cfg(feature = "dfa-search")] +mod start; |