lib.rs - Codebrowser

1	/!*
2	This crate provides a robust regular expression parser.
3
4	This crate defines two primary types:
5
6	* [`Ast`](ast::Ast) is the abstract syntax of a regular expression.
7	An abstract syntax corresponds to a structured representation* of the*
8	concrete syntax of a regular expression, where the concrete syntax is the
9	pattern string itself (e.g., `foo(bar)+`). Given some abstract syntax, it
10	can be converted back to the original concrete syntax (modulo some details,
11	like whitespace). To a first approximation, the abstract syntax is complex
12	and difficult to analyze.
13	* [`Hir`](hir::Hir) is the high-level intermediate representation
14	("HIR" or "high-level IR" for short) of regular expression. It corresponds to
15	an intermediate state of a regular expression that sits between the abstract
16	syntax and the low level compiled opcodes that are eventually responsible for
17	executing a regular expression search. Given some high-level IR, it is not
18	possible to produce the original concrete syntax (although it is possible to
19	produce an equivalent concrete syntax, but it will likely scarcely resemble
20	the original pattern). To a first approximation, the high-level IR is simple
21	and easy to analyze.
22
23	These two types come with conversion routines:
24
25	* An [`ast::parse::Parser`] converts concrete syntax (a `&str`) to an
26	[`Ast`](ast::Ast).
27	* A [`hir::translate::Translator`] converts an [`Ast`](ast::Ast) to a
28	[`Hir`](hir::Hir).
29
30	As a convenience, the above two conversion routines are combined into one via
31	the top-level [`Parser`] type. This `Parser` will first convert your pattern to
32	an `Ast` and then convert the `Ast` to an `Hir`. It's also exposed as top-level
33	[`parse`] free function.
34
35
36	# Example
37
38	This example shows how to parse a pattern string into its HIR:
39
40	```
41	use regex_syntax::{hir::Hir, parse};
42
43	let hir = parse("a\|b")?;
44	assert_eq!(hir, Hir::alternation(vec![
45	Hir::literal("a".as_bytes()),
46	Hir::literal("b".as_bytes()),
47	]));
48	# Ok::<(), Box<dyn std::error::Error>>(())
49	```
50
51
52	# Concrete syntax supported
53
54	The concrete syntax is documented as part of the public API of the
55	[`regex` crate](https://docs.rs/regex/%2A/regex/#syntax).
56
57
58	# Input safety
59
60	A key feature of this library is that it is safe to use with end user facing
61	input. This plays a significant role in the internal implementation. In
62	particular:
63
64	1. Parsers provide a `nest_limit` option that permits callers to control how
65	deeply nested a regular expression is allowed to be. This makes it possible
66	to do case analysis over an `Ast` or an `Hir` using recursion without
67	worrying about stack overflow.
68	2. Since relying on a particular stack size is brittle, this crate goes to
69	great lengths to ensure that all interactions with both the `Ast` and the
70	`Hir` do not use recursion. Namely, they use constant stack space and heap
71	space proportional to the size of the original pattern string (in bytes).
72	This includes the type's corresponding destructors. (One exception to this
73	is literal extraction, but this will eventually get fixed.)
74
75
76	# Error reporting
77
78	The `Display` implementations on all `Error` types exposed in this library
79	provide nice human readable errors that are suitable for showing to end users
80	in a monospace font.
81
82
83	# Literal extraction
84
85	This crate provides limited support for [literal extraction from `Hir`
86	values](hir::literal). Be warned that literal extraction uses recursion, and
87	therefore, stack size proportional to the size of the `Hir`.
88
89	The purpose of literal extraction is to speed up searches. That is, if you
90	know a regular expression must match a prefix or suffix literal, then it is
91	often quicker to search for instances of that literal, and then confirm or deny
92	the match using the full regular expression engine. These optimizations are
93	done automatically in the `regex` crate.
94
95
96	# Crate features
97
98	An important feature provided by this crate is its Unicode support. This
99	includes things like case folding, boolean properties, general categories,
100	scripts and Unicode-aware support for the Perl classes `\w`, `\s` and `\d`.
101	However, a downside of this support is that it requires bundling several
102	Unicode data tables that are substantial in size.
103
104	A fair number of use cases do not require full Unicode support. For this
105	reason, this crate exposes a number of features to control which Unicode
106	data is available.
107
108	If a regular expression attempts to use a Unicode feature that is not available
109	because the corresponding crate feature was disabled, then translating that
110	regular expression to an `Hir` will return an error. (It is still possible
111	construct an `Ast` for such a regular expression, since Unicode data is not
112	used until translation to an `Hir`.) Stated differently, enabling or disabling
113	any of the features below can only add or subtract from the total set of valid
114	regular expressions. Enabling or disabling a feature will never modify the
115	match semantics of a regular expression.
116
117	The following features are available:
118
119	* std -
120	Enables support for the standard library. This feature is enabled by default.
121	When disabled, only `core` and `alloc` are used. Otherwise, enabling `std`
122	generally just enables `std::error::Error` trait impls for the various error
123	types.
124	* unicode -
125	Enables all Unicode features. This feature is enabled by default, and will
126	always cover all Unicode features, even if more are added in the future.
127	* unicode-age -
128	Provide the data for the
129	[Unicode `Age` property](https://www.unicode.org/reports/tr44/tr44-24.html#Character_Age).
130	This makes it possible to use classes like `\p{Age:6.0}` to refer to all
131	codepoints first introduced in Unicode 6.0
132	* unicode-bool -
133	Provide the data for numerous Unicode boolean properties. The full list
134	is not included here, but contains properties like `Alphabetic`, `Emoji`,
135	`Lowercase`, `Math`, `Uppercase` and `White_Space`.
136	* unicode-case -
137	Provide the data for case insensitive matching using
138	[Unicode's "simple loose matches" specification](https://www.unicode.org/reports/tr18/#Simple_Loose_Matches).
139	* unicode-gencat -
140	Provide the data for
141	[Unicode general categories](https://www.unicode.org/reports/tr44/tr44-24.html#General_Category_Values).
142	This includes, but is not limited to, `Decimal_Number`, `Letter`,
143	`Math_Symbol`, `Number` and `Punctuation`.
144	* unicode-perl -
145	Provide the data for supporting the Unicode-aware Perl character classes,
146	corresponding to `\w`, `\s` and `\d`. This is also necessary for using
147	Unicode-aware word boundary assertions. Note that if this feature is
148	disabled, the `\s` and `\d` character classes are still available if the
149	`unicode-bool` and `unicode-gencat` features are enabled, respectively.
150	* unicode-script -
151	Provide the data for
152	[Unicode scripts and script extensions](https://www.unicode.org/reports/tr24/).
153	This includes, but is not limited to, `Arabic`, `Cyrillic`, `Hebrew`,
154	`Latin` and `Thai`.
155	* unicode-segment -
156	Provide the data necessary to provide the properties used to implement the
157	[Unicode text segmentation algorithms](https://www.unicode.org/reports/tr29/).
158	This enables using classes like `\p{gcb=Extend}`, `\p{wb=Katakana}` and
159	`\p{sb=ATerm}`.
160	* arbitrary -
161	Enabling this feature introduces a public dependency on the
162	[`arbitrary`](https://crates.io/crates/arbitrary)
163	crate. Namely, it implements the `Arbitrary` trait from that crate for the
164	[`Ast`](crate::ast::Ast) type. This feature is disabled by default.
165	*/
166
167	#![no_std]
168	#![forbid(unsafe_code)]
169	#![deny(missing_docs, rustdoc::broken_intra_doc_links)]
170	#![warn(missing_debug_implementations)]
171	#![cfg_attr(docsrs, feature(doc_auto_cfg))]
172
173	#[cfg(any(test, feature = "std"))]
174	extern crate std;
175
176	extern crate alloc;
177
178	pub use crate::{
179	error::Error,
180	parser::{parse, Parser, ParserBuilder},
181	unicode::UnicodeWordError,
182	};
183
184	use alloc::string::String;
185
186	pub mod ast;
187	mod debug;
188	mod either;
189	mod error;
190	pub mod hir;
191	mod parser;
192	mod rank;
193	mod unicode;
194	mod unicode_tables;
195	pub mod utf8;
196
197	/// Escapes all regular expression meta characters in `text`.
198	///
199	/// The string returned may be safely used as a literal in a regular
200	/// expression.
201	pub fn escape(text: &str) -> String {
202	let mut quoted = String::new();
203	escape_into(text, &mut quoted);
204	quoted
205	}
206
207	/// Escapes all meta characters in `text` and writes the result into `buf`.
208	///
209	/// This will append escape characters into the given buffer. The characters
210	/// that are appended are safe to use as a literal in a regular expression.
211	pub fn escape_into(text: &str, buf: &mut String) {
212	buf.reserve(text.len());
213	for c in text.chars() {
214	if is_meta_character(c) {
215	buf.push('`\\`');
216	}
217	buf.push(c);
218	}
219	}
220
221	/// Returns true if the given character has significance in a regex.
222	///
223	/// Generally speaking, these are the only characters which _must_ be escaped
224	/// in order to match their literal meaning. For example, to match a literal
225	/// `\|`, one could write `\\|`. Sometimes escaping isn't always necessary. For
226	/// example, `-` is treated as a meta character because of its significance
227	/// for writing ranges inside of character classes, but the regex `-` will
228	/// match a literal `-` because `-` has no special meaning outside of character
229	/// classes.
230	///
231	/// In order to determine whether a character may be escaped at all, the
232	/// [`is_escapeable_character`] routine should be used. The difference between
233	/// `is_meta_character` and `is_escapeable_character` is that the latter will
234	/// return true for some characters that are _not_ meta characters. For
235	/// example, `%` and `\%` both match a literal `%` in all contexts. In other
236	/// words, `is_escapeable_character` includes "superfluous" escapes.
237	///
238	/// Note that the set of characters for which this function returns `true` or
239	/// `false` is fixed and won't change in a semver compatible release. (In this
240	/// case, "semver compatible release" actually refers to the `regex` crate
241	/// itself, since reducing or expanding the set of meta characters would be a
242	/// breaking change for not just `regex-syntax` but also `regex` itself.)
243	///
244	/// # Example
245	///
246	/// ```
247	/// use regex_syntax::is_meta_character;
248	///
249	/// assert!(is_meta_character('?'));
250	/// assert!(is_meta_character('-'));
251	/// assert!(is_meta_character('&'));
252	/// assert!(is_meta_character('#'));
253	///
254	/// assert!(!is_meta_character('%'));
255	/// assert!(!is_meta_character('/'));
256	/// assert!(!is_meta_character('!'));
257	/// assert!(!is_meta_character('"'));
258	/// assert!(!is_meta_character('e'));
259	/// ```
260	pub fn is_meta_character(c: char) -> bool {
261	match c {
262	'`\\`' \| '.' \| '+' \| '*' \| '?' \| '(' \| ')' \| '\|' \| '[' \| ']' \| '{'
263	\| '}' \| '^' \| '$' \| '#' \| '&' \| '-' \| '~' => `true`,
264	_ => `false`,
265	}
266	}
267
268	/// Returns true if the given character can be escaped in a regex.
269	///
270	/// This returns true in all cases that `is_meta_character` returns true, but
271	/// also returns true in some cases where `is_meta_character` returns false.
272	/// For example, `%` is not a meta character, but it is escapeable. That is,
273	/// `%` and `\%` both match a literal `%` in all contexts.
274	///
275	/// The purpose of this routine is to provide knowledge about what characters
276	/// may be escaped. Namely, most regex engines permit "superfluous" escapes
277	/// where characters without any special significance may be escaped even
278	/// though there is no actual _need_ to do so.
279	///
280	/// This will return false for some characters. For example, `e` is not
281	/// escapeable. Therefore, `\e` will either result in a parse error (which is
282	/// true today), or it could backwards compatibly evolve into a new construct
283	/// with its own meaning. Indeed, that is the purpose of banning _some_
284	/// superfluous escapes: it provides a way to evolve the syntax in a compatible
285	/// manner.
286	///
287	/// # Example
288	///
289	/// ```
290	/// use regex_syntax::is_escapeable_character;
291	///
292	/// assert!(is_escapeable_character('?'));
293	/// assert!(is_escapeable_character('-'));
294	/// assert!(is_escapeable_character('&'));
295	/// assert!(is_escapeable_character('#'));
296	/// assert!(is_escapeable_character('%'));
297	/// assert!(is_escapeable_character('/'));
298	/// assert!(is_escapeable_character('!'));
299	/// assert!(is_escapeable_character('"'));
300	///
301	/// assert!(!is_escapeable_character('e'));
302	/// ```
303	pub fn is_escapeable_character(c: char) -> bool {
304	// Certainly escapeable if it's a meta character.
305	if is_meta_character(c) {
306	return `true`;
307	}
308	// Any character that isn't ASCII is definitely not escapeable. There's
309	// no real need to allow things like \☃ right?
310	if !c.is_ascii() {
311	return `false`;
312	}
313	// Otherwise, we basically say that everything is escapeable unless it's a
314	// letter or digit. Things like \3 are either octal (when enabled) or an
315	// error, and we should keep it that way. Otherwise, letters are reserved
316	// for adding new syntax in a backwards compatible way.
317	match c {
318	'0'..='9' \| 'A'..='Z' \| 'a'..='z' => `false`,
319	// While not currently supported, we keep these as not escapeable to
320	// give us some flexibility with respect to supporting the \< and
321	// \> word boundary assertions in the future. By rejecting them as
322	// escapeable, \< and \> will result in a parse error. Thus, we can
323	// turn them into something else in the future without it being a
324	// backwards incompatible change.
325	//
326	// OK, now we support \< and \>, and we need to retain them as not
327	// escapeable here since the escape sequence is significant.
328	'<' \| '>' => `false`,
329	_ => `true`,
330	}
331	}
332
333	/// Returns true if and only if the given character is a Unicode word
334	/// character.
335	///
336	/// A Unicode word character is defined by
337	/// [UTS#18 Annex C](https://unicode.org/reports/tr18/#Compatibility_Properties).
338	/// In particular, a character
339	/// is considered a word character if it is in either of the `Alphabetic` or
340	/// `Join_Control` properties, or is in one of the `Decimal_Number`, `Mark`
341	/// or `Connector_Punctuation` general categories.
342	///
343	/// # Panics
344	///
345	/// If the `unicode-perl` feature is not enabled, then this function
346	/// panics. For this reason, it is recommended that callers use
347	/// [`try_is_word_character`] instead.
348	pub fn is_word_character(c: char) -> bool {
349	try_is_word_character(c).expect("unicode-perl feature must be enabled")
350	}
351
352	/// Returns true if and only if the given character is a Unicode word
353	/// character.
354	///
355	/// A Unicode word character is defined by
356	/// [UTS#18 Annex C](https://unicode.org/reports/tr18/#Compatibility_Properties).
357	/// In particular, a character
358	/// is considered a word character if it is in either of the `Alphabetic` or
359	/// `Join_Control` properties, or is in one of the `Decimal_Number`, `Mark`
360	/// or `Connector_Punctuation` general categories.
361	///
362	/// # Errors
363	///
364	/// If the `unicode-perl` feature is not enabled, then this function always
365	/// returns an error.
366	pub fn try_is_word_character(
367	c: char,
368	) -> core::result::Result<bool, UnicodeWordError> {
369	unicode::is_word_character(c)
370	}
371
372	/// Returns true if and only if the given character is an ASCII word character.
373	///
374	/// An ASCII word character is defined by the following character class:
375	/// `[_0-9a-zA-Z]`.
376	pub fn is_word_byte(c: u8) -> bool {
377	match c {
378	b'_' \| b'0'..=b'9' \| b'a'..=b'z' \| b'A'..=b'Z' => `true`,
379	_ => `false`,
380	}
381	}
382
383	#[cfg(test)]
384	mod tests {
385	use alloc::string::ToString;
386
387	use super::*;
388
389	#[test]
390	fn escape_meta() {
391	assert_eq!(
392	escape(r"\.+*?()\|[]{}^$#&-~"),
393	r"\\\.\+\*\?\\|\[\]\{\}\^\$\#\&\-\~".to_string()
394	);
395	}
396
397	#[test]
398	fn word_byte() {
399	assert!(is_word_byte(b'a'));
400	assert!(!is_word_byte(b'-'));
401	}
402
403	#[test]
404	#[cfg(feature = "unicode-perl")]
405	fn word_char() {
406	assert!(is_word_character('a'), "ASCII");
407	assert!(is_word_character('à'), "Latin-1");
408	assert!(is_word_character('β'), "Greek");
409	assert!(is_word_character('`\u{11011}`'), "Brahmi (Unicode 6.0)");
410	assert!(is_word_character('`\u{11611}`'), "Modi (Unicode 7.0)");
411	assert!(is_word_character('`\u{11711}`'), "Ahom (Unicode 8.0)");
412	assert!(is_word_character('`\u{17828}`'), "Tangut (Unicode 9.0)");
413	assert!(is_word_character('`\u{1B1B1}`'), "Nushu (Unicode 10.0)");
414	assert!(is_word_character('`\u{16E40}`'), "Medefaidrin (Unicode 11.0)");
415	assert!(!is_word_character('-'));
416	assert!(!is_word_character('☃'));
417	}
418
419	#[test]
420	#[should_panic]
421	#[cfg(not(feature = "unicode-perl"))]
422	fn word_char_disabled_panic() {
423	assert!(is_word_character('a'));
424	}
425
426	#[test]
427	#[cfg(not(feature = "unicode-perl"))]
428	fn word_char_disabled_error() {
429	assert!(try_is_word_character('a').is_err());
430	}
431	}
432