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/*!
Defines a high-level intermediate representation for regular expressions.
*/
use std::char;
use std::cmp;
use std::error;
use std::fmt;
use std::result;
use std::u8;
use crate::ast::Span;
use crate::hir::interval::{Interval, IntervalSet, IntervalSetIter};
use crate::unicode;
pub use crate::hir::visitor::{visit, Visitor};
pub use crate::unicode::CaseFoldError;
mod interval;
pub mod literal;
pub mod print;
pub mod translate;
mod visitor;
/// An error that can occur while translating an `Ast` to a `Hir`.
#[derive(Clone, Debug, Eq, PartialEq)]
pub struct Error {
/// The kind of error.
kind: ErrorKind,
/// The original pattern that the translator's Ast was parsed from. Every
/// span in an error is a valid range into this string.
pattern: String,
/// The span of this error, derived from the Ast given to the translator.
span: Span,
}
impl Error {
/// Return the type of this error.
pub fn kind(&self) -> &ErrorKind {
&self.kind
}
/// The original pattern string in which this error occurred.
///
/// Every span reported by this error is reported in terms of this string.
pub fn pattern(&self) -> &str {
&self.pattern
}
/// Return the span at which this error occurred.
pub fn span(&self) -> &Span {
&self.span
}
}
/// The type of an error that occurred while building an `Hir`.
#[derive(Clone, Debug, Eq, PartialEq)]
pub enum ErrorKind {
/// This error occurs when a Unicode feature is used when Unicode
/// support is disabled. For example `(?-u:\pL)` would trigger this error.
UnicodeNotAllowed,
/// This error occurs when translating a pattern that could match a byte
/// sequence that isn't UTF-8 and `allow_invalid_utf8` was disabled.
InvalidUtf8,
/// This occurs when an unrecognized Unicode property name could not
/// be found.
UnicodePropertyNotFound,
/// This occurs when an unrecognized Unicode property value could not
/// be found.
UnicodePropertyValueNotFound,
/// This occurs when a Unicode-aware Perl character class (`\w`, `\s` or
/// `\d`) could not be found. This can occur when the `unicode-perl`
/// crate feature is not enabled.
UnicodePerlClassNotFound,
/// This occurs when the Unicode simple case mapping tables are not
/// available, and the regular expression required Unicode aware case
/// insensitivity.
UnicodeCaseUnavailable,
/// This occurs when the translator attempts to construct a character class
/// that is empty.
///
/// Note that this restriction in the translator may be removed in the
/// future.
EmptyClassNotAllowed,
/// 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 ErrorKind {
// TODO: Remove this method entirely on the next breaking semver release.
#[allow(deprecated)]
fn description(&self) -> &str {
use self::ErrorKind::*;
match *self {
UnicodeNotAllowed => "Unicode not allowed here",
InvalidUtf8 => "pattern can match invalid UTF-8",
UnicodePropertyNotFound => "Unicode property not found",
UnicodePropertyValueNotFound => "Unicode property value not found",
UnicodePerlClassNotFound => {
"Unicode-aware Perl class not found \
(make sure the unicode-perl feature is enabled)"
}
UnicodeCaseUnavailable => {
"Unicode-aware case insensitivity matching is not available \
(make sure the unicode-case feature is enabled)"
}
EmptyClassNotAllowed => "empty character classes are not allowed",
__Nonexhaustive => unreachable!(),
}
}
}
impl error::Error for Error {
// TODO: Remove this method entirely on the next breaking semver release.
#[allow(deprecated)]
fn description(&self) -> &str {
self.kind.description()
}
}
impl fmt::Display for Error {
fn fmt(&self, f: &mut fmt::Formatter<'_>) -> fmt::Result {
crate::error::Formatter::from(self).fmt(f)
}
}
impl fmt::Display for ErrorKind {
fn fmt(&self, f: &mut fmt::Formatter<'_>) -> fmt::Result {
// TODO: Remove this on the next breaking semver release.
#[allow(deprecated)]
f.write_str(self.description())
}
}
/// A high-level intermediate representation (HIR) for a regular expression.
///
/// The HIR of a regular expression represents an intermediate step between its
/// abstract syntax (a structured description of the concrete syntax) and
/// compiled byte codes. The purpose of HIR is to make regular expressions
/// easier to analyze. In particular, the AST is much more complex than the
/// HIR. For example, while an AST supports arbitrarily nested character
/// classes, the HIR will flatten all nested classes into a single set. The HIR
/// will also "compile away" every flag present in the concrete syntax. For
/// example, users of HIR expressions never need to worry about case folding;
/// it is handled automatically by the translator (e.g., by translating `(?i)A`
/// to `[aA]`).
///
/// If the HIR was produced by a translator that disallows invalid UTF-8, then
/// the HIR is guaranteed to match UTF-8 exclusively.
///
/// This type defines its own destructor that uses constant stack space and
/// heap space proportional to the size of the HIR.
///
/// The specific type of an HIR expression can be accessed via its `kind`
/// or `into_kind` methods. This extra level of indirection exists for two
/// reasons:
///
/// 1. Construction of an HIR expression *must* use the constructor methods
/// on this `Hir` type instead of building the `HirKind` values directly.
/// This permits construction to enforce invariants like "concatenations
/// always consist of two or more sub-expressions."
/// 2. Every HIR expression contains attributes that are defined inductively,
/// and can be computed cheaply during the construction process. For
/// example, one such attribute is whether the expression must match at the
/// beginning of the text.
///
/// Also, an `Hir`'s `fmt::Display` implementation prints an HIR as a regular
/// expression pattern string, and uses constant stack space and heap space
/// proportional to the size of the `Hir`.
#[derive(Clone, Debug, Eq, PartialEq)]
pub struct Hir {
/// The underlying HIR kind.
kind: HirKind,
/// Analysis info about this HIR, computed during construction.
info: HirInfo,
}
/// The kind of an arbitrary `Hir` expression.
#[derive(Clone, Debug, Eq, PartialEq)]
pub enum HirKind {
/// The empty regular expression, which matches everything, including the
/// empty string.
Empty,
/// A single literal character that matches exactly this character.
Literal(Literal),
/// A single character class that matches any of the characters in the
/// class. A class can either consist of Unicode scalar values as
/// characters, or it can use bytes.
Class(Class),
/// An anchor assertion. An anchor assertion match always has zero length.
Anchor(Anchor),
/// A word boundary assertion, which may or may not be Unicode aware. A
/// word boundary assertion match always has zero length.
WordBoundary(WordBoundary),
/// A repetition operation applied to a child expression.
Repetition(Repetition),
/// A possibly capturing group, which contains a child expression.
Group(Group),
/// A concatenation of expressions. A concatenation always has at least two
/// child expressions.
///
/// A concatenation matches only if each of its child expression matches
/// one after the other.
Concat(Vec<Hir>),
/// An alternation of expressions. An alternation always has at least two
/// child expressions.
///
/// An alternation matches only if at least one of its child expression
/// matches. If multiple expressions match, then the leftmost is preferred.
Alternation(Vec<Hir>),
}
impl Hir {
/// Returns a reference to the underlying HIR kind.
pub fn kind(&self) -> &HirKind {
&self.kind
}
/// Consumes ownership of this HIR expression and returns its underlying
/// `HirKind`.
pub fn into_kind(mut self) -> HirKind {
use std::mem;
mem::replace(&mut self.kind, HirKind::Empty)
}
/// Returns an empty HIR expression.
///
/// An empty HIR expression always matches, including the empty string.
pub fn empty() -> Hir {
let mut info = HirInfo::new();
info.set_always_utf8(true);
info.set_all_assertions(true);
info.set_anchored_start(false);
info.set_anchored_end(false);
info.set_line_anchored_start(false);
info.set_line_anchored_end(false);
info.set_any_anchored_start(false);
info.set_any_anchored_end(false);
info.set_match_empty(true);
info.set_literal(false);
info.set_alternation_literal(false);
Hir { kind: HirKind::Empty, info }
}
/// Creates a literal HIR expression.
///
/// If the given literal has a `Byte` variant with an ASCII byte, then this
/// method panics. This enforces the invariant that `Byte` variants are
/// only used to express matching of invalid UTF-8.
pub fn literal(lit: Literal) -> Hir {
if let Literal::Byte(b) = lit {
assert!(b > 0x7F);
}
let mut info = HirInfo::new();
info.set_always_utf8(lit.is_unicode());
info.set_all_assertions(false);
info.set_anchored_start(false);
info.set_anchored_end(false);
info.set_line_anchored_start(false);
info.set_line_anchored_end(false);
info.set_any_anchored_start(false);
info.set_any_anchored_end(false);
info.set_match_empty(false);
info.set_literal(true);
info.set_alternation_literal(true);
Hir { kind: HirKind::Literal(lit), info }
}
/// Creates a class HIR expression.
pub fn class(class: Class) -> Hir {
let mut info = HirInfo::new();
info.set_always_utf8(class.is_always_utf8());
info.set_all_assertions(false);
info.set_anchored_start(false);
info.set_anchored_end(false);
info.set_line_anchored_start(false);
info.set_line_anchored_end(false);
info.set_any_anchored_start(false);
info.set_any_anchored_end(false);
info.set_match_empty(false);
info.set_literal(false);
info.set_alternation_literal(false);
Hir { kind: HirKind::Class(class), info }
}
/// Creates an anchor assertion HIR expression.
pub fn anchor(anchor: Anchor) -> Hir {
let mut info = HirInfo::new();
info.set_always_utf8(true);
info.set_all_assertions(true);
info.set_anchored_start(false);
info.set_anchored_end(false);
info.set_line_anchored_start(false);
info.set_line_anchored_end(false);
info.set_any_anchored_start(false);
info.set_any_anchored_end(false);
info.set_match_empty(true);
info.set_literal(false);
info.set_alternation_literal(false);
if let Anchor::StartText = anchor {
info.set_anchored_start(true);
info.set_line_anchored_start(true);
info.set_any_anchored_start(true);
}
if let Anchor::EndText = anchor {
info.set_anchored_end(true);
info.set_line_anchored_end(true);
info.set_any_anchored_end(true);
}
if let Anchor::StartLine = anchor {
info.set_line_anchored_start(true);
}
if let Anchor::EndLine = anchor {
info.set_line_anchored_end(true);
}
Hir { kind: HirKind::Anchor(anchor), info }
}
/// Creates a word boundary assertion HIR expression.
pub fn word_boundary(word_boundary: WordBoundary) -> Hir {
let mut info = HirInfo::new();
info.set_always_utf8(true);
info.set_all_assertions(true);
info.set_anchored_start(false);
info.set_anchored_end(false);
info.set_line_anchored_start(false);
info.set_line_anchored_end(false);
info.set_any_anchored_start(false);
info.set_any_anchored_end(false);
info.set_literal(false);
info.set_alternation_literal(false);
// A negated word boundary matches '', so that's fine. But \b does not
// match \b, so why do we say it can match the empty string? Well,
// because, if you search for \b against 'a', it will report [0, 0) and
// [1, 1) as matches, and both of those matches correspond to the empty
// string. Thus, only *certain* empty strings match \b, which similarly
// applies to \B.
info.set_match_empty(true);
// Negated ASCII word boundaries can match invalid UTF-8.
if let WordBoundary::AsciiNegate = word_boundary {
info.set_always_utf8(false);
}
Hir { kind: HirKind::WordBoundary(word_boundary), info }
}
/// Creates a repetition HIR expression.
pub fn repetition(rep: Repetition) -> Hir {
let mut info = HirInfo::new();
info.set_always_utf8(rep.hir.is_always_utf8());
info.set_all_assertions(rep.hir.is_all_assertions());
// If this operator can match the empty string, then it can never
// be anchored.
info.set_anchored_start(
!rep.is_match_empty() && rep.hir.is_anchored_start(),
);
info.set_anchored_end(
!rep.is_match_empty() && rep.hir.is_anchored_end(),
);
info.set_line_anchored_start(
!rep.is_match_empty() && rep.hir.is_anchored_start(),
);
info.set_line_anchored_end(
!rep.is_match_empty() && rep.hir.is_anchored_end(),
);
info.set_any_anchored_start(rep.hir.is_any_anchored_start());
info.set_any_anchored_end(rep.hir.is_any_anchored_end());
info.set_match_empty(rep.is_match_empty() || rep.hir.is_match_empty());
info.set_literal(false);
info.set_alternation_literal(false);
Hir { kind: HirKind::Repetition(rep), info }
}
/// Creates a group HIR expression.
pub fn group(group: Group) -> Hir {
let mut info = HirInfo::new();
info.set_always_utf8(group.hir.is_always_utf8());
info.set_all_assertions(group.hir.is_all_assertions());
info.set_anchored_start(group.hir.is_anchored_start());
info.set_anchored_end(group.hir.is_anchored_end());
info.set_line_anchored_start(group.hir.is_line_anchored_start());
info.set_line_anchored_end(group.hir.is_line_anchored_end());
info.set_any_anchored_start(group.hir.is_any_anchored_start());
info.set_any_anchored_end(group.hir.is_any_anchored_end());
info.set_match_empty(group.hir.is_match_empty());
info.set_literal(false);
info.set_alternation_literal(false);
Hir { kind: HirKind::Group(group), info }
}
/// Returns the concatenation of the given expressions.
///
/// This flattens the concatenation as appropriate.
pub fn concat(mut exprs: Vec<Hir>) -> Hir {
match exprs.len() {
0 => Hir::empty(),
1 => exprs.pop().unwrap(),
_ => {
let mut info = HirInfo::new();
info.set_always_utf8(true);
info.set_all_assertions(true);
info.set_any_anchored_start(false);
info.set_any_anchored_end(false);
info.set_match_empty(true);
info.set_literal(true);
info.set_alternation_literal(true);
// Some attributes require analyzing all sub-expressions.
for e in &exprs {
let x = info.is_always_utf8() && e.is_always_utf8();
info.set_always_utf8(x);
let x = info.is_all_assertions() && e.is_all_assertions();
info.set_all_assertions(x);
let x = info.is_any_anchored_start()
|| e.is_any_anchored_start();
info.set_any_anchored_start(x);
let x =
info.is_any_anchored_end() || e.is_any_anchored_end();
info.set_any_anchored_end(x);
let x = info.is_match_empty() && e.is_match_empty();
info.set_match_empty(x);
let x = info.is_literal() && e.is_literal();
info.set_literal(x);
let x = info.is_alternation_literal()
&& e.is_alternation_literal();
info.set_alternation_literal(x);
}
// Anchored attributes require something slightly more
// sophisticated. Normally, WLOG, to determine whether an
// expression is anchored to the start, we'd only need to check
// the first expression of a concatenation. However,
// expressions like `$\b^` are still anchored to the start,
// but the first expression in the concatenation *isn't*
// anchored to the start. So the "first" expression to look at
// is actually one that is either not an assertion or is
// specifically the StartText assertion.
info.set_anchored_start(
exprs
.iter()
.take_while(|e| {
e.is_anchored_start() || e.is_all_assertions()
})
.any(|e| e.is_anchored_start()),
);
// Similarly for the end anchor, but in reverse.
info.set_anchored_end(
exprs
.iter()
.rev()
.take_while(|e| {
e.is_anchored_end() || e.is_all_assertions()
})
.any(|e| e.is_anchored_end()),
);
// Repeat the process for line anchors.
info.set_line_anchored_start(
exprs
.iter()
.take_while(|e| {
e.is_line_anchored_start() || e.is_all_assertions()
})
.any(|e| e.is_line_anchored_start()),
);
info.set_line_anchored_end(
exprs
.iter()
.rev()
.take_while(|e| {
e.is_line_anchored_end() || e.is_all_assertions()
})
.any(|e| e.is_line_anchored_end()),
);
Hir { kind: HirKind::Concat(exprs), info }
}
}
}
/// Returns the alternation of the given expressions.
///
/// This flattens the alternation as appropriate.
pub fn alternation(mut exprs: Vec<Hir>) -> Hir {
match exprs.len() {
0 => Hir::empty(),
1 => exprs.pop().unwrap(),
_ => {
let mut info = HirInfo::new();
info.set_always_utf8(true);
info.set_all_assertions(true);
info.set_anchored_start(true);
info.set_anchored_end(true);
info.set_line_anchored_start(true);
info.set_line_anchored_end(true);
info.set_any_anchored_start(false);
info.set_any_anchored_end(false);
info.set_match_empty(false);
info.set_literal(false);
info.set_alternation_literal(true);
// Some attributes require analyzing all sub-expressions.
for e in &exprs {
let x = info.is_always_utf8() && e.is_always_utf8();
info.set_always_utf8(x);
let x = info.is_all_assertions() && e.is_all_assertions();
info.set_all_assertions(x);
let x = info.is_anchored_start() && e.is_anchored_start();
info.set_anchored_start(x);
let x = info.is_anchored_end() && e.is_anchored_end();
info.set_anchored_end(x);
let x = info.is_line_anchored_start()
&& e.is_line_anchored_start();
info.set_line_anchored_start(x);
let x = info.is_line_anchored_end()
&& e.is_line_anchored_end();
info.set_line_anchored_end(x);
let x = info.is_any_anchored_start()
|| e.is_any_anchored_start();
info.set_any_anchored_start(x);
let x =
info.is_any_anchored_end() || e.is_any_anchored_end();
info.set_any_anchored_end(x);
let x = info.is_match_empty() || e.is_match_empty();
info.set_match_empty(x);
let x = info.is_alternation_literal() && e.is_literal();
info.set_alternation_literal(x);
}
Hir { kind: HirKind::Alternation(exprs), info }
}
}
}
/// Build an HIR expression for `.`.
///
/// A `.` expression matches any character except for `\n`. To build an
/// expression that matches any character, including `\n`, use the `any`
/// method.
///
/// If `bytes` is `true`, then this assumes characters are limited to a
/// single byte.
pub fn dot(bytes: bool) -> Hir {
if bytes {
let mut cls = ClassBytes::empty();
cls.push(ClassBytesRange::new(b'\0', b'\x09'));
cls.push(ClassBytesRange::new(b'\x0B', b'\xFF'));
Hir::class(Class::Bytes(cls))
} else {
let mut cls = ClassUnicode::empty();
cls.push(ClassUnicodeRange::new('\0', '\x09'));
cls.push(ClassUnicodeRange::new('\x0B', '\u{10FFFF}'));
Hir::class(Class::Unicode(cls))
}
}
/// Build an HIR expression for `(?s).`.
///
/// A `(?s).` expression matches any character, including `\n`. To build an
/// expression that matches any character except for `\n`, then use the
/// `dot` method.
///
/// If `bytes` is `true`, then this assumes characters are limited to a
/// single byte.
pub fn any(bytes: bool) -> Hir {
if bytes {
let mut cls = ClassBytes::empty();
cls.push(ClassBytesRange::new(b'\0', b'\xFF'));
Hir::class(Class::Bytes(cls))
} else {
let mut cls = ClassUnicode::empty();
cls.push(ClassUnicodeRange::new('\0', '\u{10FFFF}'));
Hir::class(Class::Unicode(cls))
}
}
/// Return true if and only if this HIR will always match valid UTF-8.
///
/// When this returns false, then it is possible for this HIR expression
/// to match invalid UTF-8.
pub fn is_always_utf8(&self) -> bool {
self.info.is_always_utf8()
}
/// Returns true if and only if this entire HIR expression is made up of
/// zero-width assertions.
///
/// This includes expressions like `^$\b\A\z` and even `((\b)+())*^`, but
/// not `^a`.
pub fn is_all_assertions(&self) -> bool {
self.info.is_all_assertions()
}
/// Return true if and only if this HIR is required to match from the
/// beginning of text. This includes expressions like `^foo`, `^(foo|bar)`,
/// `^foo|^bar` but not `^foo|bar`.
pub fn is_anchored_start(&self) -> bool {
self.info.is_anchored_start()
}
/// Return true if and only if this HIR is required to match at the end
/// of text. This includes expressions like `foo$`, `(foo|bar)$`,
/// `foo$|bar$` but not `foo$|bar`.
pub fn is_anchored_end(&self) -> bool {
self.info.is_anchored_end()
}
/// Return true if and only if this HIR is required to match from the
/// beginning of text or the beginning of a line. This includes expressions
/// like `^foo`, `(?m)^foo`, `^(foo|bar)`, `^(foo|bar)`, `(?m)^foo|^bar`
/// but not `^foo|bar` or `(?m)^foo|bar`.
///
/// Note that if `is_anchored_start` is `true`, then
/// `is_line_anchored_start` will also be `true`. The reverse implication
/// is not true. For example, `(?m)^foo` is line anchored, but not
/// `is_anchored_start`.
pub fn is_line_anchored_start(&self) -> bool {
self.info.is_line_anchored_start()
}
/// Return true if and only if this HIR is required to match at the
/// end of text or the end of a line. This includes expressions like
/// `foo$`, `(?m)foo$`, `(foo|bar)$`, `(?m)(foo|bar)$`, `foo$|bar$`,
/// `(?m)(foo|bar)$`, but not `foo$|bar` or `(?m)foo$|bar`.
///
/// Note that if `is_anchored_end` is `true`, then
/// `is_line_anchored_end` will also be `true`. The reverse implication
/// is not true. For example, `(?m)foo$` is line anchored, but not
/// `is_anchored_end`.
pub fn is_line_anchored_end(&self) -> bool {
self.info.is_line_anchored_end()
}
/// Return true if and only if this HIR contains any sub-expression that
/// is required to match at the beginning of text. Specifically, this
/// returns true if the `^` symbol (when multiline mode is disabled) or the
/// `\A` escape appear anywhere in the regex.
pub fn is_any_anchored_start(&self) -> bool {
self.info.is_any_anchored_start()
}
/// Return true if and only if this HIR contains any sub-expression that is
/// required to match at the end of text. Specifically, this returns true
/// if the `$` symbol (when multiline mode is disabled) or the `\z` escape
/// appear anywhere in the regex.
pub fn is_any_anchored_end(&self) -> bool {
self.info.is_any_anchored_end()
}
/// Return true if and only if the empty string is part of the language
/// matched by this regular expression.
///
/// This includes `a*`, `a?b*`, `a{0}`, `()`, `()+`, `^$`, `a|b?`, `\b`
/// and `\B`, but not `a` or `a+`.
pub fn is_match_empty(&self) -> bool {
self.info.is_match_empty()
}
/// Return true if and only if this HIR is a simple literal. This is only
/// true when this HIR expression is either itself a `Literal` or a
/// concatenation of only `Literal`s.
///
/// For example, `f` and `foo` are literals, but `f+`, `(foo)`, `foo()`,
/// `` are not (even though that contain sub-expressions that are literals).
pub fn is_literal(&self) -> bool {
self.info.is_literal()
}
/// Return true if and only if this HIR is either a simple literal or an
/// alternation of simple literals. This is only
/// true when this HIR expression is either itself a `Literal` or a
/// concatenation of only `Literal`s or an alternation of only `Literal`s.
///
/// For example, `f`, `foo`, `a|b|c`, and `foo|bar|baz` are alternation
/// literals, but `f+`, `(foo)`, `foo()`, ``
/// are not (even though that contain sub-expressions that are literals).
pub fn is_alternation_literal(&self) -> bool {
self.info.is_alternation_literal()
}
}
impl HirKind {
/// Return true if and only if this HIR is the empty regular expression.
///
/// Note that this is not defined inductively. That is, it only tests if
/// this kind is the `Empty` variant. To get the inductive definition,
/// use the `is_match_empty` method on [`Hir`](struct.Hir.html).
pub fn is_empty(&self) -> bool {
match *self {
HirKind::Empty => true,
_ => false,
}
}
/// Returns true if and only if this kind has any (including possibly
/// empty) subexpressions.
pub fn has_subexprs(&self) -> bool {
match *self {
HirKind::Empty
| HirKind::Literal(_)
| HirKind::Class(_)
| HirKind::Anchor(_)
| HirKind::WordBoundary(_) => false,
HirKind::Group(_)
| HirKind::Repetition(_)
| HirKind::Concat(_)
| HirKind::Alternation(_) => true,
}
}
}
/// Print a display representation of this Hir.
///
/// The result of this is a valid regular expression pattern string.
///
/// This implementation uses constant stack space and heap space proportional
/// to the size of the `Hir`.
impl fmt::Display for Hir {
fn fmt(&self, f: &mut fmt::Formatter<'_>) -> fmt::Result {
use crate::hir::print::Printer;
Printer::new().print(self, f)
}
}
/// The high-level intermediate representation of a literal.
///
/// A literal corresponds to a single character, where a character is either
/// defined by a Unicode scalar value or an arbitrary byte. Unicode characters
/// are preferred whenever possible. In particular, a `Byte` variant is only
/// ever produced when it could match invalid UTF-8.
#[derive(Clone, Debug, Eq, PartialEq)]
pub enum Literal {
/// A single character represented by a Unicode scalar value.
Unicode(char),
/// A single character represented by an arbitrary byte.
Byte(u8),
}
impl Literal {
/// Returns true if and only if this literal corresponds to a Unicode
/// scalar value.
pub fn is_unicode(&self) -> bool {
match *self {
Literal::Unicode(_) => true,
Literal::Byte(b) if b <= 0x7F => true,
Literal::Byte(_) => false,
}
}
}
/// The high-level intermediate representation of a character class.
///
/// A character class corresponds to a set of characters. A character is either
/// defined by a Unicode scalar value or a byte. Unicode characters are used
/// by default, while bytes are used when Unicode mode (via the `u` flag) is
/// disabled.
///
/// A character class, regardless of its character type, is represented by a
/// sequence of non-overlapping non-adjacent ranges of characters.
///
/// Note that unlike [`Literal`](enum.Literal.html), a `Bytes` variant may
/// be produced even when it exclusively matches valid UTF-8. This is because
/// a `Bytes` variant represents an intention by the author of the regular
/// expression to disable Unicode mode, which in turn impacts the semantics of
/// case insensitive matching. For example, `(?i)k` and `(?i-u)k` will not
/// match the same set of strings.
#[derive(Clone, Debug, Eq, PartialEq)]
pub enum Class {
/// A set of characters represented by Unicode scalar values.
Unicode(ClassUnicode),
/// A set of characters represented by arbitrary bytes (one byte per
/// character).
Bytes(ClassBytes),
}
impl Class {
/// Apply Unicode simple case folding to this character class, in place.
/// The character class will be expanded to include all simple case folded
/// character variants.
///
/// If this is a byte oriented character class, then this will be limited
/// to the ASCII ranges `A-Z` and `a-z`.
pub fn case_fold_simple(&mut self) {
match *self {
Class::Unicode(ref mut x) => x.case_fold_simple(),
Class::Bytes(ref mut x) => x.case_fold_simple(),
}
}
/// Negate this character class in place.
///
/// After completion, this character class will contain precisely the
/// characters that weren't previously in the class.
pub fn negate(&mut self) {
match *self {
Class::Unicode(ref mut x) => x.negate(),
Class::Bytes(ref mut x) => x.negate(),
}
}
/// Returns true if and only if this character class will only ever match
/// valid UTF-8.
///
/// A character class can match invalid UTF-8 only when the following
/// conditions are met:
///
/// 1. The translator was configured to permit generating an expression
/// that can match invalid UTF-8. (By default, this is disabled.)
/// 2. Unicode mode (via the `u` flag) was disabled either in the concrete
/// syntax or in the parser builder. By default, Unicode mode is
/// enabled.
pub fn is_always_utf8(&self) -> bool {
match *self {
Class::Unicode(_) => true,
Class::Bytes(ref x) => x.is_all_ascii(),
}
}
}
/// A set of characters represented by Unicode scalar values.
#[derive(Clone, Debug, Eq, PartialEq)]
pub struct ClassUnicode {
set: IntervalSet<ClassUnicodeRange>,
}
impl ClassUnicode {
/// Create a new class from a sequence of ranges.
///
/// The given ranges do not need to be in any specific order, and ranges
/// may overlap.
pub fn new<I>(ranges: I) -> ClassUnicode
where
I: IntoIterator<Item = ClassUnicodeRange>,
{
ClassUnicode { set: IntervalSet::new(ranges) }
}
/// Create a new class with no ranges.
pub fn empty() -> ClassUnicode {
ClassUnicode::new(vec![])
}
/// Add a new range to this set.
pub fn push(&mut self, range: ClassUnicodeRange) {
self.set.push(range);
}
/// Return an iterator over all ranges in this class.
///
/// The iterator yields ranges in ascending order.
pub fn iter(&self) -> ClassUnicodeIter<'_> {
ClassUnicodeIter(self.set.iter())
}
/// Return the underlying ranges as a slice.
pub fn ranges(&self) -> &[ClassUnicodeRange] {
self.set.intervals()
}
/// Expand this character class such that it contains all case folded
/// characters, according to Unicode's "simple" mapping. For example, if
/// this class consists of the range `a-z`, then applying case folding will
/// result in the class containing both the ranges `a-z` and `A-Z`.
///
/// # Panics
///
/// This routine panics when the case mapping data necessary for this
/// routine to complete is unavailable. This occurs when the `unicode-case`
/// feature is not enabled.
///
/// Callers should prefer using `try_case_fold_simple` instead, which will
/// return an error instead of panicking.
pub fn case_fold_simple(&mut self) {
self.set
.case_fold_simple()
.expect("unicode-case feature must be enabled");
}
/// Expand this character class such that it contains all case folded
/// characters, according to Unicode's "simple" mapping. For example, if
/// this class consists of the range `a-z`, then applying case folding will
/// result in the class containing both the ranges `a-z` and `A-Z`.
///
/// # Error
///
/// This routine returns an error when the case mapping data necessary
/// for this routine to complete is unavailable. This occurs when the
/// `unicode-case` feature is not enabled.
pub fn try_case_fold_simple(
&mut self,
) -> result::Result<(), CaseFoldError> {
self.set.case_fold_simple()
}
/// Negate this character class.
///
/// For all `c` where `c` is a Unicode scalar value, if `c` was in this
/// set, then it will not be in this set after negation.
pub fn negate(&mut self) {
self.set.negate();
}
/// Union this character class with the given character class, in place.
pub fn union(&mut self, other: &ClassUnicode) {
self.set.union(&other.set);
}
/// Intersect this character class with the given character class, in
/// place.
pub fn intersect(&mut self, other: &ClassUnicode) {
self.set.intersect(&other.set);
}
/// Subtract the given character class from this character class, in place.
pub fn difference(&mut self, other: &ClassUnicode) {
self.set.difference(&other.set);
}
/// Compute the symmetric difference of the given character classes, in
/// place.
///
/// This computes the symmetric difference of two character classes. This
/// removes all elements in this class that are also in the given class,
/// but all adds all elements from the given class that aren't in this
/// class. That is, the class will contain all elements in either class,
/// but will not contain any elements that are in both classes.
pub fn symmetric_difference(&mut self, other: &ClassUnicode) {
self.set.symmetric_difference(&other.set);
}
/// Returns true if and only if this character class will either match
/// nothing or only ASCII bytes. Stated differently, this returns false
/// if and only if this class contains a non-ASCII codepoint.
pub fn is_all_ascii(&self) -> bool {
self.set.intervals().last().map_or(true, |r| r.end <= '\x7F')
}
}
/// An iterator over all ranges in a Unicode character class.
///
/// The lifetime `'a` refers to the lifetime of the underlying class.
#[derive(Debug)]
pub struct ClassUnicodeIter<'a>(IntervalSetIter<'a, ClassUnicodeRange>);
impl<'a> Iterator for ClassUnicodeIter<'a> {
type Item = &'a ClassUnicodeRange;
fn next(&mut self) -> Option<&'a ClassUnicodeRange> {
self.0.next()
}
}
/// A single range of characters represented by Unicode scalar values.
///
/// The range is closed. That is, the start and end of the range are included
/// in the range.
#[derive(Clone, Copy, Default, Eq, PartialEq, PartialOrd, Ord)]
pub struct ClassUnicodeRange {
start: char,
end: char,
}
impl fmt::Debug for ClassUnicodeRange {
fn fmt(&self, f: &mut fmt::Formatter<'_>) -> fmt::Result {
let start = if !self.start.is_whitespace() && !self.start.is_control()
{
self.start.to_string()
} else {
format!("0x{:X}", self.start as u32)
};
let end = if !self.end.is_whitespace() && !self.end.is_control() {
self.end.to_string()
} else {
format!("0x{:X}", self.end as u32)
};
f.debug_struct("ClassUnicodeRange")
.field("start", &start)
.field("end", &end)
.finish()
}
}
impl Interval for ClassUnicodeRange {
type Bound = char;
#[inline]
fn lower(&self) -> char {
self.start
}
#[inline]
fn upper(&self) -> char {
self.end
}
#[inline]
fn set_lower(&mut self, bound: char) {
self.start = bound;
}
#[inline]
fn set_upper(&mut self, bound: char) {
self.end = bound;
}
/// Apply simple case folding to this Unicode scalar value range.
///
/// Additional ranges are appended to the given vector. Canonical ordering
/// is *not* maintained in the given vector.
fn case_fold_simple(
&self,
ranges: &mut Vec<ClassUnicodeRange>,
) -> Result<(), unicode::CaseFoldError> {
if !unicode::contains_simple_case_mapping(self.start, self.end)? {
return Ok(());
}
let start = self.start as u32;
let end = (self.end as u32).saturating_add(1);
let mut next_simple_cp = None;
for cp in (start..end).filter_map(char::from_u32) {
if next_simple_cp.map_or(false, |next| cp < next) {
continue;
}
let it = match unicode::simple_fold(cp)? {
Ok(it) => it,
Err(next) => {
next_simple_cp = next;
continue;
}
};
for cp_folded in it {
ranges.push(ClassUnicodeRange::new(cp_folded, cp_folded));
}
}
Ok(())
}
}
impl ClassUnicodeRange {
/// Create a new Unicode scalar value range for a character class.
///
/// The returned range is always in a canonical form. That is, the range
/// returned always satisfies the invariant that `start <= end`.
pub fn new(start: char, end: char) -> ClassUnicodeRange {
ClassUnicodeRange::create(start, end)
}
/// Return the start of this range.
///
/// The start of a range is always less than or equal to the end of the
/// range.
pub fn start(&self) -> char {
self.start
}
/// Return the end of this range.
///
/// The end of a range is always greater than or equal to the start of the
/// range.
pub fn end(&self) -> char {
self.end
}
}
/// A set of characters represented by arbitrary bytes (where one byte
/// corresponds to one character).
#[derive(Clone, Debug, Eq, PartialEq)]
pub struct ClassBytes {
set: IntervalSet<ClassBytesRange>,
}
impl ClassBytes {
/// Create a new class from a sequence of ranges.
///
/// The given ranges do not need to be in any specific order, and ranges
/// may overlap.
pub fn new<I>(ranges: I) -> ClassBytes
where
I: IntoIterator<Item = ClassBytesRange>,
{
ClassBytes { set: IntervalSet::new(ranges) }
}
/// Create a new class with no ranges.
pub fn empty() -> ClassBytes {
ClassBytes::new(vec![])
}
/// Add a new range to this set.
pub fn push(&mut self, range: ClassBytesRange) {
self.set.push(range);
}
/// Return an iterator over all ranges in this class.
///
/// The iterator yields ranges in ascending order.
pub fn iter(&self) -> ClassBytesIter<'_> {
ClassBytesIter(self.set.iter())
}
/// Return the underlying ranges as a slice.
pub fn ranges(&self) -> &[ClassBytesRange] {
self.set.intervals()
}
/// Expand this character class such that it contains all case folded
/// characters. For example, if this class consists of the range `a-z`,
/// then applying case folding will result in the class containing both the
/// ranges `a-z` and `A-Z`.
///
/// Note that this only applies ASCII case folding, which is limited to the
/// characters `a-z` and `A-Z`.
pub fn case_fold_simple(&mut self) {
self.set.case_fold_simple().expect("ASCII case folding never fails");
}
/// Negate this byte class.
///
/// For all `b` where `b` is a any byte, if `b` was in this set, then it
/// will not be in this set after negation.
pub fn negate(&mut self) {
self.set.negate();
}
/// Union this byte class with the given byte class, in place.
pub fn union(&mut self, other: &ClassBytes) {
self.set.union(&other.set);
}
/// Intersect this byte class with the given byte class, in place.
pub fn intersect(&mut self, other: &ClassBytes) {
self.set.intersect(&other.set);
}
/// Subtract the given byte class from this byte class, in place.
pub fn difference(&mut self, other: &ClassBytes) {
self.set.difference(&other.set);
}
/// Compute the symmetric difference of the given byte classes, in place.
///
/// This computes the symmetric difference of two byte classes. This
/// removes all elements in this class that are also in the given class,
/// but all adds all elements from the given class that aren't in this
/// class. That is, the class will contain all elements in either class,
/// but will not contain any elements that are in both classes.
pub fn symmetric_difference(&mut self, other: &ClassBytes) {
self.set.symmetric_difference(&other.set);
}
/// Returns true if and only if this character class will either match
/// nothing or only ASCII bytes. Stated differently, this returns false
/// if and only if this class contains a non-ASCII byte.
pub fn is_all_ascii(&self) -> bool {
self.set.intervals().last().map_or(true, |r| r.end <= 0x7F)
}
}
/// An iterator over all ranges in a byte character class.
///
/// The lifetime `'a` refers to the lifetime of the underlying class.
#[derive(Debug)]
pub struct ClassBytesIter<'a>(IntervalSetIter<'a, ClassBytesRange>);
impl<'a> Iterator for ClassBytesIter<'a> {
type Item = &'a ClassBytesRange;
fn next(&mut self) -> Option<&'a ClassBytesRange> {
self.0.next()
}
}
/// A single range of characters represented by arbitrary bytes.
///
/// The range is closed. That is, the start and end of the range are included
/// in the range.
#[derive(Clone, Copy, Default, Eq, PartialEq, PartialOrd, Ord)]
pub struct ClassBytesRange {
start: u8,
end: u8,
}
impl Interval for ClassBytesRange {
type Bound = u8;
#[inline]
fn lower(&self) -> u8 {
self.start
}
#[inline]
fn upper(&self) -> u8 {
self.end
}
#[inline]
fn set_lower(&mut self, bound: u8) {
self.start = bound;
}
#[inline]
fn set_upper(&mut self, bound: u8) {
self.end = bound;
}
/// Apply simple case folding to this byte range. Only ASCII case mappings
/// (for a-z) are applied.
///
/// Additional ranges are appended to the given vector. Canonical ordering
/// is *not* maintained in the given vector.
fn case_fold_simple(
&self,
ranges: &mut Vec<ClassBytesRange>,
) -> Result<(), unicode::CaseFoldError> {
if !ClassBytesRange::new(b'a', b'z').is_intersection_empty(self) {
let lower = cmp::max(self.start, b'a');
let upper = cmp::min(self.end, b'z');
ranges.push(ClassBytesRange::new(lower - 32, upper - 32));
}
if !ClassBytesRange::new(b'A', b'Z').is_intersection_empty(self) {
let lower = cmp::max(self.start, b'A');
let upper = cmp::min(self.end, b'Z');
ranges.push(ClassBytesRange::new(lower + 32, upper + 32));
}
Ok(())
}
}
impl ClassBytesRange {
/// Create a new byte range for a character class.
///
/// The returned range is always in a canonical form. That is, the range
/// returned always satisfies the invariant that `start <= end`.
pub fn new(start: u8, end: u8) -> ClassBytesRange {
ClassBytesRange::create(start, end)
}
/// Return the start of this range.
///
/// The start of a range is always less than or equal to the end of the
/// range.
pub fn start(&self) -> u8 {
self.start
}
/// Return the end of this range.
///
/// The end of a range is always greater than or equal to the start of the
/// range.
pub fn end(&self) -> u8 {
self.end
}
}
impl fmt::Debug for ClassBytesRange {
fn fmt(&self, f: &mut fmt::Formatter<'_>) -> fmt::Result {
let mut debug = f.debug_struct("ClassBytesRange");
if self.start <= 0x7F {
debug.field("start", &(self.start as char));
} else {
debug.field("start", &self.start);
}
if self.end <= 0x7F {
debug.field("end", &(self.end as char));
} else {
debug.field("end", &self.end);
}
debug.finish()
}
}
/// The high-level intermediate representation for an anchor assertion.
///
/// A matching anchor assertion is always zero-length.
#[derive(Clone, Debug, Eq, PartialEq)]
pub enum Anchor {
/// Match the beginning of a line or the beginning of text. Specifically,
/// this matches at the starting position of the input, or at the position
/// immediately following a `\n` character.
StartLine,
/// Match the end of a line or the end of text. Specifically,
/// this matches at the end position of the input, or at the position
/// immediately preceding a `\n` character.
EndLine,
/// Match the beginning of text. Specifically, this matches at the starting
/// position of the input.
StartText,
/// Match the end of text. Specifically, this matches at the ending
/// position of the input.
EndText,
}
/// The high-level intermediate representation for a word-boundary assertion.
///
/// A matching word boundary assertion is always zero-length.
#[derive(Clone, Debug, Eq, PartialEq)]
pub enum WordBoundary {
/// Match a Unicode-aware word boundary. That is, this matches a position
/// where the left adjacent character and right adjacent character
/// correspond to a word and non-word or a non-word and word character.
Unicode,
/// Match a Unicode-aware negation of a word boundary.
UnicodeNegate,
/// Match an ASCII-only word boundary. That is, this matches a position
/// where the left adjacent character and right adjacent character
/// correspond to a word and non-word or a non-word and word character.
Ascii,
/// Match an ASCII-only negation of a word boundary.
AsciiNegate,
}
impl WordBoundary {
/// Returns true if and only if this word boundary assertion is negated.
pub fn is_negated(&self) -> bool {
match *self {
WordBoundary::Unicode | WordBoundary::Ascii => false,
WordBoundary::UnicodeNegate | WordBoundary::AsciiNegate => true,
}
}
}
/// The high-level intermediate representation for a group.
///
/// This represents one of three possible group types:
///
/// 1. A non-capturing group (e.g., `(?:expr)`).
/// 2. A capturing group (e.g., `(expr)`).
/// 3. A named capturing group (e.g., `(?P<name>expr)`).
#[derive(Clone, Debug, Eq, PartialEq)]
pub struct Group {
/// The kind of this group. If it is a capturing group, then the kind
/// contains the capture group index (and the name, if it is a named
/// group).
pub kind: GroupKind,
/// The expression inside the capturing group, which may be empty.
pub hir: Box<Hir>,
}
/// The kind of group.
#[derive(Clone, Debug, Eq, PartialEq)]
pub enum GroupKind {
/// A normal unnamed capturing group.
///
/// The value is the capture index of the group.
CaptureIndex(u32),
/// A named capturing group.
CaptureName {
/// The name of the group.
name: String,
/// The capture index of the group.
index: u32,
},
/// A non-capturing group.
NonCapturing,
}
/// The high-level intermediate representation of a repetition operator.
///
/// A repetition operator permits the repetition of an arbitrary
/// sub-expression.
#[derive(Clone, Debug, Eq, PartialEq)]
pub struct Repetition {
/// The kind of this repetition operator.
pub kind: RepetitionKind,
/// Whether this repetition operator is greedy or not. A greedy operator
/// will match as much as it can. A non-greedy operator will match as
/// little as it can.
///
/// Typically, operators are greedy by default and are only non-greedy when
/// a `?` suffix is used, e.g., `(expr)*` is greedy while `(expr)*?` is
/// not. However, this can be inverted via the `U` "ungreedy" flag.
pub greedy: bool,
/// The expression being repeated.
pub hir: Box<Hir>,
}
impl Repetition {
/// Returns true if and only if this repetition operator makes it possible
/// to match the empty string.
///
/// Note that this is not defined inductively. For example, while `a*`
/// will report `true`, `()+` will not, even though `()` matches the empty
/// string and one or more occurrences of something that matches the empty
/// string will always match the empty string. In order to get the
/// inductive definition, see the corresponding method on
/// [`Hir`](struct.Hir.html).
pub fn is_match_empty(&self) -> bool {
match self.kind {
RepetitionKind::ZeroOrOne => true,
RepetitionKind::ZeroOrMore => true,
RepetitionKind::OneOrMore => false,
RepetitionKind::Range(RepetitionRange::Exactly(m)) => m == 0,
RepetitionKind::Range(RepetitionRange::AtLeast(m)) => m == 0,
RepetitionKind::Range(RepetitionRange::Bounded(m, _)) => m == 0,
}
}
}
/// The kind of a repetition operator.
#[derive(Clone, Debug, Eq, PartialEq)]
pub enum RepetitionKind {
/// Matches a sub-expression zero or one times.
ZeroOrOne,
/// Matches a sub-expression zero or more times.
ZeroOrMore,
/// Matches a sub-expression one or more times.
OneOrMore,
/// Matches a sub-expression within a bounded range of times.
Range(RepetitionRange),
}
/// The kind of a counted repetition operator.
#[derive(Clone, Debug, Eq, PartialEq)]
pub enum RepetitionRange {
/// Matches a sub-expression exactly this many times.
Exactly(u32),
/// Matches a sub-expression at least this many times.
AtLeast(u32),
/// Matches a sub-expression at least `m` times and at most `n` times.
Bounded(u32, u32),
}
/// A custom `Drop` impl is used for `HirKind` such that it uses constant stack
/// space but heap space proportional to the depth of the total `Hir`.
impl Drop for Hir {
fn drop(&mut self) {
use std::mem;
match *self.kind() {
HirKind::Empty
| HirKind::Literal(_)
| HirKind::Class(_)
| HirKind::Anchor(_)
| HirKind::WordBoundary(_) => return,
HirKind::Group(ref x) if !x.hir.kind.has_subexprs() => return,
HirKind::Repetition(ref x) if !x.hir.kind.has_subexprs() => return,
HirKind::Concat(ref x) if x.is_empty() => return,
HirKind::Alternation(ref x) if x.is_empty() => return,
_ => {}
}
let mut stack = vec![mem::replace(self, Hir::empty())];
while let Some(mut expr) = stack.pop() {
match expr.kind {
HirKind::Empty
| HirKind::Literal(_)
| HirKind::Class(_)
| HirKind::Anchor(_)
| HirKind::WordBoundary(_) => {}
HirKind::Group(ref mut x) => {
stack.push(mem::replace(&mut x.hir, Hir::empty()));
}
HirKind::Repetition(ref mut x) => {
stack.push(mem::replace(&mut x.hir, Hir::empty()));
}
HirKind::Concat(ref mut x) => {
stack.extend(x.drain(..));
}
HirKind::Alternation(ref mut x) => {
stack.extend(x.drain(..));
}
}
}
}
}
/// A type that documents various attributes of an HIR expression.
///
/// These attributes are typically defined inductively on the HIR.
#[derive(Clone, Debug, Eq, PartialEq)]
struct HirInfo {
/// Represent yes/no questions by a bitfield to conserve space, since
/// this is included in every HIR expression.
///
/// If more attributes need to be added, it is OK to increase the size of
/// this as appropriate.
bools: u16,
}
// A simple macro for defining bitfield accessors/mutators.
macro_rules! define_bool {
($bit:expr, $is_fn_name:ident, $set_fn_name:ident) => {
fn $is_fn_name(&self) -> bool {
self.bools & (0b1 << $bit) > 0
}
fn $set_fn_name(&mut self, yes: bool) {
if yes {
self.bools |= 1 << $bit;
} else {
self.bools &= !(1 << $bit);
}
}
};
}
impl HirInfo {
fn new() -> HirInfo {
HirInfo { bools: 0 }
}
define_bool!(0, is_always_utf8, set_always_utf8);
define_bool!(1, is_all_assertions, set_all_assertions);
define_bool!(2, is_anchored_start, set_anchored_start);
define_bool!(3, is_anchored_end, set_anchored_end);
define_bool!(4, is_line_anchored_start, set_line_anchored_start);
define_bool!(5, is_line_anchored_end, set_line_anchored_end);
define_bool!(6, is_any_anchored_start, set_any_anchored_start);
define_bool!(7, is_any_anchored_end, set_any_anchored_end);
define_bool!(8, is_match_empty, set_match_empty);
define_bool!(9, is_literal, set_literal);
define_bool!(10, is_alternation_literal, set_alternation_literal);
}
#[cfg(test)]
mod tests {
use super::*;
fn uclass(ranges: &[(char, char)]) -> ClassUnicode {
let ranges: Vec<ClassUnicodeRange> = ranges
.iter()
.map(|&(s, e)| ClassUnicodeRange::new(s, e))
.collect();
ClassUnicode::new(ranges)
}
fn bclass(ranges: &[(u8, u8)]) -> ClassBytes {
let ranges: Vec<ClassBytesRange> =
ranges.iter().map(|&(s, e)| ClassBytesRange::new(s, e)).collect();
ClassBytes::new(ranges)
}
fn uranges(cls: &ClassUnicode) -> Vec<(char, char)> {
cls.iter().map(|x| (x.start(), x.end())).collect()
}
#[cfg(feature = "unicode-case")]
fn ucasefold(cls: &ClassUnicode) -> ClassUnicode {
let mut cls_ = cls.clone();
cls_.case_fold_simple();
cls_
}
fn uunion(cls1: &ClassUnicode, cls2: &ClassUnicode) -> ClassUnicode {
let mut cls_ = cls1.clone();
cls_.union(cls2);
cls_
}
fn uintersect(cls1: &ClassUnicode, cls2: &ClassUnicode) -> ClassUnicode {
let mut cls_ = cls1.clone();
cls_.intersect(cls2);
cls_
}
fn udifference(cls1: &ClassUnicode, cls2: &ClassUnicode) -> ClassUnicode {
let mut cls_ = cls1.clone();
cls_.difference(cls2);
cls_
}
fn usymdifference(
cls1: &ClassUnicode,
cls2: &ClassUnicode,
) -> ClassUnicode {
let mut cls_ = cls1.clone();
cls_.symmetric_difference(cls2);
cls_
}
fn unegate(cls: &ClassUnicode) -> ClassUnicode {
let mut cls_ = cls.clone();
cls_.negate();
cls_
}
fn branges(cls: &ClassBytes) -> Vec<(u8, u8)> {
cls.iter().map(|x| (x.start(), x.end())).collect()
}
fn bcasefold(cls: &ClassBytes) -> ClassBytes {
let mut cls_ = cls.clone();
cls_.case_fold_simple();
cls_
}
fn bunion(cls1: &ClassBytes, cls2: &ClassBytes) -> ClassBytes {
let mut cls_ = cls1.clone();
cls_.union(cls2);
cls_
}
fn bintersect(cls1: &ClassBytes, cls2: &ClassBytes) -> ClassBytes {
let mut cls_ = cls1.clone();
cls_.intersect(cls2);
cls_
}
fn bdifference(cls1: &ClassBytes, cls2: &ClassBytes) -> ClassBytes {
let mut cls_ = cls1.clone();
cls_.difference(cls2);
cls_
}
fn bsymdifference(cls1: &ClassBytes, cls2: &ClassBytes) -> ClassBytes {
let mut cls_ = cls1.clone();
cls_.symmetric_difference(cls2);
cls_
}
fn bnegate(cls: &ClassBytes) -> ClassBytes {
let mut cls_ = cls.clone();
cls_.negate();
cls_
}
#[test]
fn class_range_canonical_unicode() {
let range = ClassUnicodeRange::new('\u{00FF}', '\0');
assert_eq!('\0', range.start());
assert_eq!('\u{00FF}', range.end());
}
#[test]
fn class_range_canonical_bytes() {
let range = ClassBytesRange::new(b'\xFF', b'\0');
assert_eq!(b'\0', range.start());
assert_eq!(b'\xFF', range.end());
}
#[test]
fn class_canonicalize_unicode() {
let cls = uclass(&[('a', 'c'), ('x', 'z')]);
let expected = vec![('a', 'c'), ('x', 'z')];
assert_eq!(expected, uranges(&cls));
let cls = uclass(&[('x', 'z'), ('a', 'c')]);
let expected = vec![('a', 'c'), ('x', 'z')];
assert_eq!(expected, uranges(&cls));
let cls = uclass(&[('x', 'z'), ('w', 'y')]);
let expected = vec![('w', 'z')];
assert_eq!(expected, uranges(&cls));
let cls = uclass(&[
('c', 'f'),
('a', 'g'),
('d', 'j'),
('a', 'c'),
('m', 'p'),
('l', 's'),
]);
let expected = vec![('a', 'j'), ('l', 's')];
assert_eq!(expected, uranges(&cls));
let cls = uclass(&[('x', 'z'), ('u', 'w')]);
let expected = vec![('u', 'z')];
assert_eq!(expected, uranges(&cls));
let cls = uclass(&[('\x00', '\u{10FFFF}'), ('\x00', '\u{10FFFF}')]);
let expected = vec![('\x00', '\u{10FFFF}')];
assert_eq!(expected, uranges(&cls));
let cls = uclass(&[('a', 'a'), ('b', 'b')]);
let expected = vec![('a', 'b')];
assert_eq!(expected, uranges(&cls));
}
#[test]
fn class_canonicalize_bytes() {
let cls = bclass(&[(b'a', b'c'), (b'x', b'z')]);
let expected = vec![(b'a', b'c'), (b'x', b'z')];
assert_eq!(expected, branges(&cls));
let cls = bclass(&[(b'x', b'z'), (b'a', b'c')]);
let expected = vec![(b'a', b'c'), (b'x', b'z')];
assert_eq!(expected, branges(&cls));
let cls = bclass(&[(b'x', b'z'), (b'w', b'y')]);
let expected = vec![(b'w', b'z')];
assert_eq!(expected, branges(&cls));
let cls = bclass(&[
(b'c', b'f'),
(b'a', b'g'),
(b'd', b'j'),
(b'a', b'c'),
(b'm', b'p'),
(b'l', b's'),
]);
let expected = vec![(b'a', b'j'), (b'l', b's')];
assert_eq!(expected, branges(&cls));
let cls = bclass(&[(b'x', b'z'), (b'u', b'w')]);
let expected = vec![(b'u', b'z')];
assert_eq!(expected, branges(&cls));
let cls = bclass(&[(b'\x00', b'\xFF'), (b'\x00', b'\xFF')]);
let expected = vec![(b'\x00', b'\xFF')];
assert_eq!(expected, branges(&cls));
let cls = bclass(&[(b'a', b'a'), (b'b', b'b')]);
let expected = vec![(b'a', b'b')];
assert_eq!(expected, branges(&cls));
}
#[test]
#[cfg(feature = "unicode-case")]
fn class_case_fold_unicode() {
let cls = uclass(&[
('C', 'F'),
('A', 'G'),
('D', 'J'),
('A', 'C'),
('M', 'P'),
('L', 'S'),
('c', 'f'),
]);
let expected = uclass(&[
('A', 'J'),
('L', 'S'),
('a', 'j'),
('l', 's'),
('\u{17F}', '\u{17F}'),
]);
assert_eq!(expected, ucasefold(&cls));
let cls = uclass(&[('A', 'Z')]);
let expected = uclass(&[
('A', 'Z'),
('a', 'z'),
('\u{17F}', '\u{17F}'),
('\u{212A}', '\u{212A}'),
]);
assert_eq!(expected, ucasefold(&cls));
let cls = uclass(&[('a', 'z')]);
let expected = uclass(&[
('A', 'Z'),
('a', 'z'),
('\u{17F}', '\u{17F}'),
('\u{212A}', '\u{212A}'),
]);
assert_eq!(expected, ucasefold(&cls));
let cls = uclass(&[('A', 'A'), ('_', '_')]);
let expected = uclass(&[('A', 'A'), ('_', '_'), ('a', 'a')]);
assert_eq!(expected, ucasefold(&cls));
let cls = uclass(&[('A', 'A'), ('=', '=')]);
let expected = uclass(&[('=', '='), ('A', 'A'), ('a', 'a')]);
assert_eq!(expected, ucasefold(&cls));
let cls = uclass(&[('\x00', '\x10')]);
assert_eq!(cls, ucasefold(&cls));
let cls = uclass(&[('k', 'k')]);
let expected =
uclass(&[('K', 'K'), ('k', 'k'), ('\u{212A}', '\u{212A}')]);
assert_eq!(expected, ucasefold(&cls));
let cls = uclass(&[('@', '@')]);
assert_eq!(cls, ucasefold(&cls));
}
#[test]
#[cfg(not(feature = "unicode-case"))]
fn class_case_fold_unicode_disabled() {
let mut cls = uclass(&[
('C', 'F'),
('A', 'G'),
('D', 'J'),
('A', 'C'),
('M', 'P'),
('L', 'S'),
('c', 'f'),
]);
assert!(cls.try_case_fold_simple().is_err());
}
#[test]
#[should_panic]
#[cfg(not(feature = "unicode-case"))]
fn class_case_fold_unicode_disabled_panics() {
let mut cls = uclass(&[
('C', 'F'),
('A', 'G'),
('D', 'J'),
('A', 'C'),
('M', 'P'),
('L', 'S'),
('c', 'f'),
]);
cls.case_fold_simple();
}
#[test]
fn class_case_fold_bytes() {
let cls = bclass(&[
(b'C', b'F'),
(b'A', b'G'),
(b'D', b'J'),
(b'A', b'C'),
(b'M', b'P'),
(b'L', b'S'),
(b'c', b'f'),
]);
let expected =
bclass(&[(b'A', b'J'), (b'L', b'S'), (b'a', b'j'), (b'l', b's')]);
assert_eq!(expected, bcasefold(&cls));
let cls = bclass(&[(b'A', b'Z')]);
let expected = bclass(&[(b'A', b'Z'), (b'a', b'z')]);
assert_eq!(expected, bcasefold(&cls));
let cls = bclass(&[(b'a', b'z')]);
let expected = bclass(&[(b'A', b'Z'), (b'a', b'z')]);
assert_eq!(expected, bcasefold(&cls));
let cls = bclass(&[(b'A', b'A'), (b'_', b'_')]);
let expected = bclass(&[(b'A', b'A'), (b'_', b'_'), (b'a', b'a')]);
assert_eq!(expected, bcasefold(&cls));
let cls = bclass(&[(b'A', b'A'), (b'=', b'=')]);
let expected = bclass(&[(b'=', b'='), (b'A', b'A'), (b'a', b'a')]);
assert_eq!(expected, bcasefold(&cls));
let cls = bclass(&[(b'\x00', b'\x10')]);
assert_eq!(cls, bcasefold(&cls));
let cls = bclass(&[(b'k', b'k')]);
let expected = bclass(&[(b'K', b'K'), (b'k', b'k')]);
assert_eq!(expected, bcasefold(&cls));
let cls = bclass(&[(b'@', b'@')]);
assert_eq!(cls, bcasefold(&cls));
}
#[test]
fn class_negate_unicode() {
let cls = uclass(&[('a', 'a')]);
let expected = uclass(&[('\x00', '\x60'), ('\x62', '\u{10FFFF}')]);
assert_eq!(expected, unegate(&cls));
let cls = uclass(&[('a', 'a'), ('b', 'b')]);
let expected = uclass(&[('\x00', '\x60'), ('\x63', '\u{10FFFF}')]);
assert_eq!(expected, unegate(&cls));
let cls = uclass(&[('a', 'c'), ('x', 'z')]);
let expected = uclass(&[
('\x00', '\x60'),
('\x64', '\x77'),
('\x7B', '\u{10FFFF}'),
]);
assert_eq!(expected, unegate(&cls));
let cls = uclass(&[('\x00', 'a')]);
let expected = uclass(&[('\x62', '\u{10FFFF}')]);
assert_eq!(expected, unegate(&cls));
let cls = uclass(&[('a', '\u{10FFFF}')]);
let expected = uclass(&[('\x00', '\x60')]);
assert_eq!(expected, unegate(&cls));
let cls = uclass(&[('\x00', '\u{10FFFF}')]);
let expected = uclass(&[]);
assert_eq!(expected, unegate(&cls));
let cls = uclass(&[]);
let expected = uclass(&[('\x00', '\u{10FFFF}')]);
assert_eq!(expected, unegate(&cls));
let cls =
uclass(&[('\x00', '\u{10FFFD}'), ('\u{10FFFF}', '\u{10FFFF}')]);
let expected = uclass(&[('\u{10FFFE}', '\u{10FFFE}')]);
assert_eq!(expected, unegate(&cls));
let cls = uclass(&[('\x00', '\u{D7FF}')]);
let expected = uclass(&[('\u{E000}', '\u{10FFFF}')]);
assert_eq!(expected, unegate(&cls));
let cls = uclass(&[('\x00', '\u{D7FE}')]);
let expected = uclass(&[('\u{D7FF}', '\u{10FFFF}')]);
assert_eq!(expected, unegate(&cls));
let cls = uclass(&[('\u{E000}', '\u{10FFFF}')]);
let expected = uclass(&[('\x00', '\u{D7FF}')]);
assert_eq!(expected, unegate(&cls));
let cls = uclass(&[('\u{E001}', '\u{10FFFF}')]);
let expected = uclass(&[('\x00', '\u{E000}')]);
assert_eq!(expected, unegate(&cls));
}
#[test]
fn class_negate_bytes() {
let cls = bclass(&[(b'a', b'a')]);
let expected = bclass(&[(b'\x00', b'\x60'), (b'\x62', b'\xFF')]);
assert_eq!(expected, bnegate(&cls));
let cls = bclass(&[(b'a', b'a'), (b'b', b'b')]);
let expected = bclass(&[(b'\x00', b'\x60'), (b'\x63', b'\xFF')]);
assert_eq!(expected, bnegate(&cls));
let cls = bclass(&[(b'a', b'c'), (b'x', b'z')]);
let expected = bclass(&[
(b'\x00', b'\x60'),
(b'\x64', b'\x77'),
(b'\x7B', b'\xFF'),
]);
assert_eq!(expected, bnegate(&cls));
let cls = bclass(&[(b'\x00', b'a')]);
let expected = bclass(&[(b'\x62', b'\xFF')]);
assert_eq!(expected, bnegate(&cls));
let cls = bclass(&[(b'a', b'\xFF')]);
let expected = bclass(&[(b'\x00', b'\x60')]);
assert_eq!(expected, bnegate(&cls));
let cls = bclass(&[(b'\x00', b'\xFF')]);
let expected = bclass(&[]);
assert_eq!(expected, bnegate(&cls));
let cls = bclass(&[]);
let expected = bclass(&[(b'\x00', b'\xFF')]);
assert_eq!(expected, bnegate(&cls));
let cls = bclass(&[(b'\x00', b'\xFD'), (b'\xFF', b'\xFF')]);
let expected = bclass(&[(b'\xFE', b'\xFE')]);
assert_eq!(expected, bnegate(&cls));
}
#[test]
fn class_union_unicode() {
let cls1 = uclass(&[('a', 'g'), ('m', 't'), ('A', 'C')]);
let cls2 = uclass(&[('a', 'z')]);
let expected = uclass(&[('a', 'z'), ('A', 'C')]);
assert_eq!(expected, uunion(&cls1, &cls2));
}
#[test]
fn class_union_bytes() {
let cls1 = bclass(&[(b'a', b'g'), (b'm', b't'), (b'A', b'C')]);
let cls2 = bclass(&[(b'a', b'z')]);
let expected = bclass(&[(b'a', b'z'), (b'A', b'C')]);
assert_eq!(expected, bunion(&cls1, &cls2));
}
#[test]
fn class_intersect_unicode() {
let cls1 = uclass(&[]);
let cls2 = uclass(&[('a', 'a')]);
let expected = uclass(&[]);
assert_eq!(expected, uintersect(&cls1, &cls2));
let cls1 = uclass(&[('a', 'a')]);
let cls2 = uclass(&[('a', 'a')]);
let expected = uclass(&[('a', 'a')]);
assert_eq!(expected, uintersect(&cls1, &cls2));
let cls1 = uclass(&[('a', 'a')]);
let cls2 = uclass(&[('b', 'b')]);
let expected = uclass(&[]);
assert_eq!(expected, uintersect(&cls1, &cls2));
let cls1 = uclass(&[('a', 'a')]);
let cls2 = uclass(&[('a', 'c')]);
let expected = uclass(&[('a', 'a')]);
assert_eq!(expected, uintersect(&cls1, &cls2));
let cls1 = uclass(&[('a', 'b')]);
let cls2 = uclass(&[('a', 'c')]);
let expected = uclass(&[('a', 'b')]);
assert_eq!(expected, uintersect(&cls1, &cls2));
let cls1 = uclass(&[('a', 'b')]);
let cls2 = uclass(&[('b', 'c')]);
let expected = uclass(&[('b', 'b')]);
assert_eq!(expected, uintersect(&cls1, &cls2));
let cls1 = uclass(&[('a', 'b')]);
let cls2 = uclass(&[('c', 'd')]);
let expected = uclass(&[]);
assert_eq!(expected, uintersect(&cls1, &cls2));
let cls1 = uclass(&[('b', 'c')]);
let cls2 = uclass(&[('a', 'd')]);
let expected = uclass(&[('b', 'c')]);
assert_eq!(expected, uintersect(&cls1, &cls2));
let cls1 = uclass(&[('a', 'b'), ('d', 'e'), ('g', 'h')]);
let cls2 = uclass(&[('a', 'h')]);
let expected = uclass(&[('a', 'b'), ('d', 'e'), ('g', 'h')]);
assert_eq!(expected, uintersect(&cls1, &cls2));
let cls1 = uclass(&[('a', 'b'), ('d', 'e'), ('g', 'h')]);
let cls2 = uclass(&[('a', 'b'), ('d', 'e'), ('g', 'h')]);
let expected = uclass(&[('a', 'b'), ('d', 'e'), ('g', 'h')]);
assert_eq!(expected, uintersect(&cls1, &cls2));
let cls1 = uclass(&[('a', 'b'), ('g', 'h')]);
let cls2 = uclass(&[('d', 'e'), ('k', 'l')]);
let expected = uclass(&[]);
assert_eq!(expected, uintersect(&cls1, &cls2));
let cls1 = uclass(&[('a', 'b'), ('d', 'e'), ('g', 'h')]);
let cls2 = uclass(&[('h', 'h')]);
let expected = uclass(&[('h', 'h')]);
assert_eq!(expected, uintersect(&cls1, &cls2));
let cls1 = uclass(&[('a', 'b'), ('e', 'f'), ('i', 'j')]);
let cls2 = uclass(&[('c', 'd'), ('g', 'h'), ('k', 'l')]);
let expected = uclass(&[]);
assert_eq!(expected, uintersect(&cls1, &cls2));
let cls1 = uclass(&[('a', 'b'), ('c', 'd'), ('e', 'f')]);
let cls2 = uclass(&[('b', 'c'), ('d', 'e'), ('f', 'g')]);
let expected = uclass(&[('b', 'f')]);
assert_eq!(expected, uintersect(&cls1, &cls2));
}
#[test]
fn class_intersect_bytes() {
let cls1 = bclass(&[]);
let cls2 = bclass(&[(b'a', b'a')]);
let expected = bclass(&[]);
assert_eq!(expected, bintersect(&cls1, &cls2));
let cls1 = bclass(&[(b'a', b'a')]);
let cls2 = bclass(&[(b'a', b'a')]);
let expected = bclass(&[(b'a', b'a')]);
assert_eq!(expected, bintersect(&cls1, &cls2));
let cls1 = bclass(&[(b'a', b'a')]);
let cls2 = bclass(&[(b'b', b'b')]);
let expected = bclass(&[]);
assert_eq!(expected, bintersect(&cls1, &cls2));
let cls1 = bclass(&[(b'a', b'a')]);
let cls2 = bclass(&[(b'a', b'c')]);
let expected = bclass(&[(b'a', b'a')]);
assert_eq!(expected, bintersect(&cls1, &cls2));
let cls1 = bclass(&[(b'a', b'b')]);
let cls2 = bclass(&[(b'a', b'c')]);
let expected = bclass(&[(b'a', b'b')]);
assert_eq!(expected, bintersect(&cls1, &cls2));
let cls1 = bclass(&[(b'a', b'b')]);
let cls2 = bclass(&[(b'b', b'c')]);
let expected = bclass(&[(b'b', b'b')]);
assert_eq!(expected, bintersect(&cls1, &cls2));
let cls1 = bclass(&[(b'a', b'b')]);
let cls2 = bclass(&[(b'c', b'd')]);
let expected = bclass(&[]);
assert_eq!(expected, bintersect(&cls1, &cls2));
let cls1 = bclass(&[(b'b', b'c')]);
let cls2 = bclass(&[(b'a', b'd')]);
let expected = bclass(&[(b'b', b'c')]);
assert_eq!(expected, bintersect(&cls1, &cls2));
let cls1 = bclass(&[(b'a', b'b'), (b'd', b'e'), (b'g', b'h')]);
let cls2 = bclass(&[(b'a', b'h')]);
let expected = bclass(&[(b'a', b'b'), (b'd', b'e'), (b'g', b'h')]);
assert_eq!(expected, bintersect(&cls1, &cls2));
let cls1 = bclass(&[(b'a', b'b'), (b'd', b'e'), (b'g', b'h')]);
let cls2 = bclass(&[(b'a', b'b'), (b'd', b'e'), (b'g', b'h')]);
let expected = bclass(&[(b'a', b'b'), (b'd', b'e'), (b'g', b'h')]);
assert_eq!(expected, bintersect(&cls1, &cls2));
let cls1 = bclass(&[(b'a', b'b'), (b'g', b'h')]);
let cls2 = bclass(&[(b'd', b'e'), (b'k', b'l')]);
let expected = bclass(&[]);
assert_eq!(expected, bintersect(&cls1, &cls2));
let cls1 = bclass(&[(b'a', b'b'), (b'd', b'e'), (b'g', b'h')]);
let cls2 = bclass(&[(b'h', b'h')]);
let expected = bclass(&[(b'h', b'h')]);
assert_eq!(expected, bintersect(&cls1, &cls2));
let cls1 = bclass(&[(b'a', b'b'), (b'e', b'f'), (b'i', b'j')]);
let cls2 = bclass(&[(b'c', b'd'), (b'g', b'h'), (b'k', b'l')]);
let expected = bclass(&[]);
assert_eq!(expected, bintersect(&cls1, &cls2));
let cls1 = bclass(&[(b'a', b'b'), (b'c', b'd'), (b'e', b'f')]);
let cls2 = bclass(&[(b'b', b'c'), (b'd', b'e'), (b'f', b'g')]);
let expected = bclass(&[(b'b', b'f')]);
assert_eq!(expected, bintersect(&cls1, &cls2));
}
#[test]
fn class_difference_unicode() {
let cls1 = uclass(&[('a', 'a')]);
let cls2 = uclass(&[('a', 'a')]);
let expected = uclass(&[]);
assert_eq!(expected, udifference(&cls1, &cls2));
let cls1 = uclass(&[('a', 'a')]);
let cls2 = uclass(&[]);
let expected = uclass(&[('a', 'a')]);
assert_eq!(expected, udifference(&cls1, &cls2));
let cls1 = uclass(&[]);
let cls2 = uclass(&[('a', 'a')]);
let expected = uclass(&[]);
assert_eq!(expected, udifference(&cls1, &cls2));
let cls1 = uclass(&[('a', 'z')]);
let cls2 = uclass(&[('a', 'a')]);
let expected = uclass(&[('b', 'z')]);
assert_eq!(expected, udifference(&cls1, &cls2));
let cls1 = uclass(&[('a', 'z')]);
let cls2 = uclass(&[('z', 'z')]);
let expected = uclass(&[('a', 'y')]);
assert_eq!(expected, udifference(&cls1, &cls2));
let cls1 = uclass(&[('a', 'z')]);
let cls2 = uclass(&[('m', 'm')]);
let expected = uclass(&[('a', 'l'), ('n', 'z')]);
assert_eq!(expected, udifference(&cls1, &cls2));
let cls1 = uclass(&[('a', 'c'), ('g', 'i'), ('r', 't')]);
let cls2 = uclass(&[('a', 'z')]);
let expected = uclass(&[]);
assert_eq!(expected, udifference(&cls1, &cls2));
let cls1 = uclass(&[('a', 'c'), ('g', 'i'), ('r', 't')]);
let cls2 = uclass(&[('d', 'v')]);
let expected = uclass(&[('a', 'c')]);
assert_eq!(expected, udifference(&cls1, &cls2));
let cls1 = uclass(&[('a', 'c'), ('g', 'i'), ('r', 't')]);
let cls2 = uclass(&[('b', 'g'), ('s', 'u')]);
let expected = uclass(&[('a', 'a'), ('h', 'i'), ('r', 'r')]);
assert_eq!(expected, udifference(&cls1, &cls2));
let cls1 = uclass(&[('a', 'c'), ('g', 'i'), ('r', 't')]);
let cls2 = uclass(&[('b', 'd'), ('e', 'g'), ('s', 'u')]);
let expected = uclass(&[('a', 'a'), ('h', 'i'), ('r', 'r')]);
assert_eq!(expected, udifference(&cls1, &cls2));
let cls1 = uclass(&[('x', 'z')]);
let cls2 = uclass(&[('a', 'c'), ('e', 'g'), ('s', 'u')]);
let expected = uclass(&[('x', 'z')]);
assert_eq!(expected, udifference(&cls1, &cls2));
let cls1 = uclass(&[('a', 'z')]);
let cls2 = uclass(&[('a', 'c'), ('e', 'g'), ('s', 'u')]);
let expected = uclass(&[('d', 'd'), ('h', 'r'), ('v', 'z')]);
assert_eq!(expected, udifference(&cls1, &cls2));
}
#[test]
fn class_difference_bytes() {
let cls1 = bclass(&[(b'a', b'a')]);
let cls2 = bclass(&[(b'a', b'a')]);
let expected = bclass(&[]);
assert_eq!(expected, bdifference(&cls1, &cls2));
let cls1 = bclass(&[(b'a', b'a')]);
let cls2 = bclass(&[]);
let expected = bclass(&[(b'a', b'a')]);
assert_eq!(expected, bdifference(&cls1, &cls2));
let cls1 = bclass(&[]);
let cls2 = bclass(&[(b'a', b'a')]);
let expected = bclass(&[]);
assert_eq!(expected, bdifference(&cls1, &cls2));
let cls1 = bclass(&[(b'a', b'z')]);
let cls2 = bclass(&[(b'a', b'a')]);
let expected = bclass(&[(b'b', b'z')]);
assert_eq!(expected, bdifference(&cls1, &cls2));
let cls1 = bclass(&[(b'a', b'z')]);
let cls2 = bclass(&[(b'z', b'z')]);
let expected = bclass(&[(b'a', b'y')]);
assert_eq!(expected, bdifference(&cls1, &cls2));
let cls1 = bclass(&[(b'a', b'z')]);
let cls2 = bclass(&[(b'm', b'm')]);
let expected = bclass(&[(b'a', b'l'), (b'n', b'z')]);
assert_eq!(expected, bdifference(&cls1, &cls2));
let cls1 = bclass(&[(b'a', b'c'), (b'g', b'i'), (b'r', b't')]);
let cls2 = bclass(&[(b'a', b'z')]);
let expected = bclass(&[]);
assert_eq!(expected, bdifference(&cls1, &cls2));
let cls1 = bclass(&[(b'a', b'c'), (b'g', b'i'), (b'r', b't')]);
let cls2 = bclass(&[(b'd', b'v')]);
let expected = bclass(&[(b'a', b'c')]);
assert_eq!(expected, bdifference(&cls1, &cls2));
let cls1 = bclass(&[(b'a', b'c'), (b'g', b'i'), (b'r', b't')]);
let cls2 = bclass(&[(b'b', b'g'), (b's', b'u')]);
let expected = bclass(&[(b'a', b'a'), (b'h', b'i'), (b'r', b'r')]);
assert_eq!(expected, bdifference(&cls1, &cls2));
let cls1 = bclass(&[(b'a', b'c'), (b'g', b'i'), (b'r', b't')]);
let cls2 = bclass(&[(b'b', b'd'), (b'e', b'g'), (b's', b'u')]);
let expected = bclass(&[(b'a', b'a'), (b'h', b'i'), (b'r', b'r')]);
assert_eq!(expected, bdifference(&cls1, &cls2));
let cls1 = bclass(&[(b'x', b'z')]);
let cls2 = bclass(&[(b'a', b'c'), (b'e', b'g'), (b's', b'u')]);
let expected = bclass(&[(b'x', b'z')]);
assert_eq!(expected, bdifference(&cls1, &cls2));
let cls1 = bclass(&[(b'a', b'z')]);
let cls2 = bclass(&[(b'a', b'c'), (b'e', b'g'), (b's', b'u')]);
let expected = bclass(&[(b'd', b'd'), (b'h', b'r'), (b'v', b'z')]);
assert_eq!(expected, bdifference(&cls1, &cls2));
}
#[test]
fn class_symmetric_difference_unicode() {
let cls1 = uclass(&[('a', 'm')]);
let cls2 = uclass(&[('g', 't')]);
let expected = uclass(&[('a', 'f'), ('n', 't')]);
assert_eq!(expected, usymdifference(&cls1, &cls2));
}
#[test]
fn class_symmetric_difference_bytes() {
let cls1 = bclass(&[(b'a', b'm')]);
let cls2 = bclass(&[(b'g', b't')]);
let expected = bclass(&[(b'a', b'f'), (b'n', b't')]);
assert_eq!(expected, bsymdifference(&cls1, &cls2));
}
#[test]
#[should_panic]
fn hir_byte_literal_non_ascii() {
Hir::literal(Literal::Byte(b'a'));
}
// We use a thread with an explicit stack size to test that our destructor
// for Hir can handle arbitrarily sized expressions in constant stack
// space. In case we run on a platform without threads (WASM?), we limit
// this test to Windows/Unix.
#[test]
#[cfg(any(unix, windows))]
fn no_stack_overflow_on_drop() {
use std::thread;
let run = || {
let mut expr = Hir::empty();
for _ in 0..100 {
expr = Hir::group(Group {
kind: GroupKind::NonCapturing,
hir: Box::new(expr),
});
expr = Hir::repetition(Repetition {
kind: RepetitionKind::ZeroOrOne,
greedy: true,
hir: Box::new(expr),
});
expr = Hir {
kind: HirKind::Concat(vec![expr]),
info: HirInfo::new(),
};
expr = Hir {
kind: HirKind::Alternation(vec![expr]),
info: HirInfo::new(),
};
}
assert!(!expr.kind.is_empty());
};
// We run our test on a thread with a small stack size so we can
// force the issue more easily.
thread::Builder::new()
.stack_size(1 << 10)
.spawn(run)
.unwrap()
.join()
.unwrap();
}
}