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634 lines
22 KiB
C++
634 lines
22 KiB
C++
// Copyright 2006 The RE2 Authors. All Rights Reserved.
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// Use of this source code is governed by a BSD-style
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// license that can be found in the LICENSE file.
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// --- SPONSORED LINK --------------------------------------------------
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// If you want to use this library for regular expression matching,
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// you should use re2/re2.h, which provides a class RE2 that
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// mimics the PCRE interface provided by PCRE's C++ wrappers.
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// This header describes the low-level interface used to implement RE2
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// and may change in backwards-incompatible ways from time to time.
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// In contrast, RE2's interface will not.
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// ---------------------------------------------------------------------
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// Regular expression library: parsing, execution, and manipulation
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// of regular expressions.
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//
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// Any operation that traverses the Regexp structures should be written
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// using Regexp::Walker (see walker-inl.h), not recursively, because deeply nested
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// regular expressions such as x++++++++++++++++++++... might cause recursive
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// traversals to overflow the stack.
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//
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// It is the caller's responsibility to provide appropriate mutual exclusion
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// around manipulation of the regexps. RE2 does this.
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//
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// PARSING
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//
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// Regexp::Parse parses regular expressions encoded in UTF-8.
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// The default syntax is POSIX extended regular expressions,
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// with the following changes:
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//
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// 1. Backreferences (optional in POSIX EREs) are not supported.
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// (Supporting them precludes the use of DFA-based
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// matching engines.)
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//
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// 2. Collating elements and collation classes are not supported.
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// (No one has needed or wanted them.)
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//
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// The exact syntax accepted can be modified by passing flags to
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// Regexp::Parse. In particular, many of the basic Perl additions
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// are available. The flags are documented below (search for LikePerl).
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//
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// If parsed with the flag Regexp::Latin1, both the regular expression
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// and the input to the matching routines are assumed to be encoded in
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// Latin-1, not UTF-8.
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//
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// EXECUTION
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//
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// Once Regexp has parsed a regular expression, it provides methods
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// to search text using that regular expression. These methods are
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// implemented via calling out to other regular expression libraries.
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// (Let's call them the sublibraries.)
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//
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// To call a sublibrary, Regexp does not simply prepare a
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// string version of the regular expression and hand it to the
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// sublibrary. Instead, Regexp prepares, from its own parsed form, the
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// corresponding internal representation used by the sublibrary.
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// This has the drawback of needing to know the internal representation
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// used by the sublibrary, but it has two important benefits:
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//
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// 1. The syntax and meaning of regular expressions is guaranteed
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// to be that used by Regexp's parser, not the syntax expected
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// by the sublibrary. Regexp might accept a restricted or
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// expanded syntax for regular expressions as compared with
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// the sublibrary. As long as Regexp can translate from its
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// internal form into the sublibrary's, clients need not know
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// exactly which sublibrary they are using.
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//
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// 2. The sublibrary parsers are bypassed. For whatever reason,
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// sublibrary regular expression parsers often have security
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// problems. For example, plan9grep's regular expression parser
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// has a buffer overflow in its handling of large character
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// classes, and PCRE's parser has had buffer overflow problems
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// in the past. Security-team requires sandboxing of sublibrary
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// regular expression parsers. Avoiding the sublibrary parsers
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// avoids the sandbox.
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//
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// The execution methods we use now are provided by the compiled form,
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// Prog, described in prog.h
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//
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// MANIPULATION
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//
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// Unlike other regular expression libraries, Regexp makes its parsed
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// form accessible to clients, so that client code can analyze the
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// parsed regular expressions.
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#ifndef RE2_REGEXP_H__
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#define RE2_REGEXP_H__
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#include "util/util.h"
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#include "re2/stringpiece.h"
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namespace re2 {
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// Keep in sync with string list kOpcodeNames[] in testing/dump.cc
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enum RegexpOp {
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// Matches no strings.
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kRegexpNoMatch = 1,
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// Matches empty string.
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kRegexpEmptyMatch,
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// Matches rune_.
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kRegexpLiteral,
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// Matches runes_.
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kRegexpLiteralString,
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// Matches concatenation of sub_[0..nsub-1].
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kRegexpConcat,
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// Matches union of sub_[0..nsub-1].
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kRegexpAlternate,
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// Matches sub_[0] zero or more times.
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kRegexpStar,
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// Matches sub_[0] one or more times.
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kRegexpPlus,
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// Matches sub_[0] zero or one times.
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kRegexpQuest,
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// Matches sub_[0] at least min_ times, at most max_ times.
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// max_ == -1 means no upper limit.
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kRegexpRepeat,
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// Parenthesized (capturing) subexpression. Index is cap_.
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// Optionally, capturing name is name_.
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kRegexpCapture,
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// Matches any character.
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kRegexpAnyChar,
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// Matches any byte [sic].
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kRegexpAnyByte,
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// Matches empty string at beginning of line.
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kRegexpBeginLine,
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// Matches empty string at end of line.
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kRegexpEndLine,
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// Matches word boundary "\b".
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kRegexpWordBoundary,
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// Matches not-a-word boundary "\B".
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kRegexpNoWordBoundary,
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// Matches empty string at beginning of text.
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kRegexpBeginText,
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// Matches empty string at end of text.
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kRegexpEndText,
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// Matches character class given by cc_.
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kRegexpCharClass,
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// Forces match of entire expression right now,
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// with match ID match_id_ (used by RE2::Set).
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kRegexpHaveMatch,
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kMaxRegexpOp = kRegexpHaveMatch,
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};
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// Keep in sync with string list in regexp.cc
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enum RegexpStatusCode {
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// No error
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kRegexpSuccess = 0,
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// Unexpected error
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kRegexpInternalError,
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// Parse errors
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kRegexpBadEscape, // bad escape sequence
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kRegexpBadCharClass, // bad character class
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kRegexpBadCharRange, // bad character class range
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kRegexpMissingBracket, // missing closing ]
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kRegexpMissingParen, // missing closing )
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kRegexpTrailingBackslash, // at end of regexp
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kRegexpRepeatArgument, // repeat argument missing, e.g. "*"
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kRegexpRepeatSize, // bad repetition argument
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kRegexpRepeatOp, // bad repetition operator
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kRegexpBadPerlOp, // bad perl operator
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kRegexpBadUTF8, // invalid UTF-8 in regexp
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kRegexpBadNamedCapture, // bad named capture
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};
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// Error status for certain operations.
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class RegexpStatus {
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public:
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RegexpStatus() : code_(kRegexpSuccess), tmp_(NULL) {}
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~RegexpStatus() { delete tmp_; }
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void set_code(enum RegexpStatusCode code) { code_ = code; }
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void set_error_arg(const StringPiece& error_arg) { error_arg_ = error_arg; }
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void set_tmp(string* tmp) { delete tmp_; tmp_ = tmp; }
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enum RegexpStatusCode code() const { return code_; }
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const StringPiece& error_arg() const { return error_arg_; }
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bool ok() const { return code() == kRegexpSuccess; }
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// Copies state from status.
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void Copy(const RegexpStatus& status);
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// Returns text equivalent of code, e.g.:
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// "Bad character class"
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static string CodeText(enum RegexpStatusCode code);
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// Returns text describing error, e.g.:
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// "Bad character class: [z-a]"
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string Text() const;
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private:
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enum RegexpStatusCode code_; // Kind of error
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StringPiece error_arg_; // Piece of regexp containing syntax error.
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string* tmp_; // Temporary storage, possibly where error_arg_ is.
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DISALLOW_EVIL_CONSTRUCTORS(RegexpStatus);
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};
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// Walker to implement Simplify.
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class SimplifyWalker;
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// Compiled form; see prog.h
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class Prog;
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struct RuneRange {
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RuneRange() : lo(0), hi(0) { }
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RuneRange(int l, int h) : lo(l), hi(h) { }
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Rune lo;
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Rune hi;
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};
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// Less-than on RuneRanges treats a == b if they overlap at all.
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// This lets us look in a set to find the range covering a particular Rune.
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struct RuneRangeLess {
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bool operator()(const RuneRange& a, const RuneRange& b) const {
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return a.hi < b.lo;
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}
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};
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class CharClassBuilder;
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class CharClass {
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public:
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void Delete();
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typedef RuneRange* iterator;
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iterator begin() { return ranges_; }
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iterator end() { return ranges_ + nranges_; }
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int size() { return nrunes_; }
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bool empty() { return nrunes_ == 0; }
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bool full() { return nrunes_ == Runemax+1; }
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bool FoldsASCII() { return folds_ascii_; }
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bool Contains(Rune r);
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CharClass* Negate();
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private:
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CharClass(); // not implemented
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~CharClass(); // not implemented
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static CharClass* New(int maxranges);
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friend class CharClassBuilder;
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bool folds_ascii_;
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int nrunes_;
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RuneRange *ranges_;
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int nranges_;
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DISALLOW_EVIL_CONSTRUCTORS(CharClass);
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};
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class Regexp {
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public:
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// Flags for parsing. Can be ORed together.
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enum ParseFlags {
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NoParseFlags = 0,
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FoldCase = 1<<0, // Fold case during matching (case-insensitive).
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Literal = 1<<1, // Treat s as literal string instead of a regexp.
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ClassNL = 1<<2, // Allow char classes like [^a-z] and \D and \s
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// and [[:space:]] to match newline.
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DotNL = 1<<3, // Allow . to match newline.
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MatchNL = ClassNL | DotNL,
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OneLine = 1<<4, // Treat ^ and $ as only matching at beginning and
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// end of text, not around embedded newlines.
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// (Perl's default)
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Latin1 = 1<<5, // Regexp and text are in Latin1, not UTF-8.
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NonGreedy = 1<<6, // Repetition operators are non-greedy by default.
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PerlClasses = 1<<7, // Allow Perl character classes like \d.
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PerlB = 1<<8, // Allow Perl's \b and \B.
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PerlX = 1<<9, // Perl extensions:
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// non-capturing parens - (?: )
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// non-greedy operators - *? +? ?? {}?
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// flag edits - (?i) (?-i) (?i: )
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// i - FoldCase
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// m - !OneLine
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// s - DotNL
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// U - NonGreedy
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// line ends: \A \z
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// \Q and \E to disable/enable metacharacters
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// (?P<name>expr) for named captures
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// \C to match any single byte
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UnicodeGroups = 1<<10, // Allow \p{Han} for Unicode Han group
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// and \P{Han} for its negation.
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NeverNL = 1<<11, // Never match NL, even if the regexp mentions
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// it explicitly.
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NeverCapture = 1<<12, // Parse all parens as non-capturing.
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// As close to Perl as we can get.
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LikePerl = ClassNL | OneLine | PerlClasses | PerlB | PerlX |
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UnicodeGroups,
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// Internal use only.
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WasDollar = 1<<15, // on kRegexpEndText: was $ in regexp text
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};
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// Get. No set, Regexps are logically immutable once created.
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RegexpOp op() { return static_cast<RegexpOp>(op_); }
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int nsub() { return nsub_; }
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bool simple() { return simple_; }
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enum ParseFlags parse_flags() { return static_cast<ParseFlags>(parse_flags_); }
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int Ref(); // For testing.
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Regexp** sub() {
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if(nsub_ <= 1)
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return &subone_;
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else
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return submany_;
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}
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int min() { DCHECK_EQ(op_, kRegexpRepeat); return min_; }
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int max() { DCHECK_EQ(op_, kRegexpRepeat); return max_; }
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Rune rune() { DCHECK_EQ(op_, kRegexpLiteral); return rune_; }
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CharClass* cc() { DCHECK_EQ(op_, kRegexpCharClass); return cc_; }
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int cap() { DCHECK_EQ(op_, kRegexpCapture); return cap_; }
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const string* name() { DCHECK_EQ(op_, kRegexpCapture); return name_; }
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Rune* runes() { DCHECK_EQ(op_, kRegexpLiteralString); return runes_; }
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int nrunes() { DCHECK_EQ(op_, kRegexpLiteralString); return nrunes_; }
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int match_id() { DCHECK_EQ(op_, kRegexpHaveMatch); return match_id_; }
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// Increments reference count, returns object as convenience.
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Regexp* Incref();
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// Decrements reference count and deletes this object if count reaches 0.
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void Decref();
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// Parses string s to produce regular expression, returned.
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// Caller must release return value with re->Decref().
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// On failure, sets *status (if status != NULL) and returns NULL.
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static Regexp* Parse(const StringPiece& s, ParseFlags flags,
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RegexpStatus* status);
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// Returns a _new_ simplified version of the current regexp.
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// Does not edit the current regexp.
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// Caller must release return value with re->Decref().
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// Simplified means that counted repetition has been rewritten
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// into simpler terms and all Perl/POSIX features have been
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// removed. The result will capture exactly the same
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// subexpressions the original did, unless formatted with ToString.
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Regexp* Simplify();
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friend class SimplifyWalker;
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// Parses the regexp src and then simplifies it and sets *dst to the
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// string representation of the simplified form. Returns true on success.
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// Returns false and sets *status (if status != NULL) on parse error.
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static bool SimplifyRegexp(const StringPiece& src, ParseFlags flags,
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string* dst,
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RegexpStatus* status);
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// Returns the number of capturing groups in the regexp.
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int NumCaptures();
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friend class NumCapturesWalker;
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// Returns a map from names to capturing group indices,
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// or NULL if the regexp contains no named capture groups.
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// The caller is responsible for deleting the map.
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map<string, int>* NamedCaptures();
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// Returns a map from capturing group indices to capturing group
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// names or NULL if the regexp contains no named capture groups. The
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// caller is responsible for deleting the map.
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map<int, string>* CaptureNames();
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// Returns a string representation of the current regexp,
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// using as few parentheses as possible.
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string ToString();
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// Convenience functions. They consume the passed reference,
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// so in many cases you should use, e.g., Plus(re->Incref(), flags).
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// They do not consume allocated arrays like subs or runes.
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static Regexp* Plus(Regexp* sub, ParseFlags flags);
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static Regexp* Star(Regexp* sub, ParseFlags flags);
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static Regexp* Quest(Regexp* sub, ParseFlags flags);
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static Regexp* Concat(Regexp** subs, int nsubs, ParseFlags flags);
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static Regexp* Alternate(Regexp** subs, int nsubs, ParseFlags flags);
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static Regexp* Capture(Regexp* sub, ParseFlags flags, int cap);
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static Regexp* Repeat(Regexp* sub, ParseFlags flags, int min, int max);
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static Regexp* NewLiteral(Rune rune, ParseFlags flags);
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static Regexp* NewCharClass(CharClass* cc, ParseFlags flags);
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static Regexp* LiteralString(Rune* runes, int nrunes, ParseFlags flags);
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static Regexp* HaveMatch(int match_id, ParseFlags flags);
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// Like Alternate but does not factor out common prefixes.
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static Regexp* AlternateNoFactor(Regexp** subs, int nsubs, ParseFlags flags);
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// Debugging function. Returns string format for regexp
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// that makes structure clear. Does NOT use regexp syntax.
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string Dump();
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// Helper traversal class, defined fully in walker-inl.h.
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template<typename T> class Walker;
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// Compile to Prog. See prog.h
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// Reverse prog expects to be run over text backward.
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// Construction and execution of prog will
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// stay within approximately max_mem bytes of memory.
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// If max_mem <= 0, a reasonable default is used.
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Prog* CompileToProg(int64 max_mem);
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Prog* CompileToReverseProg(int64 max_mem);
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// Whether to expect this library to find exactly the same answer as PCRE
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// when running this regexp. Most regexps do mimic PCRE exactly, but a few
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// obscure cases behave differently. Technically this is more a property
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// of the Prog than the Regexp, but the computation is much easier to do
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// on the Regexp. See mimics_pcre.cc for the exact conditions.
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bool MimicsPCRE();
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// Benchmarking function.
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void NullWalk();
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// Whether every match of this regexp must be anchored and
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// begin with a non-empty fixed string (perhaps after ASCII
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// case-folding). If so, returns the prefix and the sub-regexp that
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// follows it.
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bool RequiredPrefix(string* prefix, bool *foldcase, Regexp** suffix);
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private:
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// Constructor allocates vectors as appropriate for operator.
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explicit Regexp(RegexpOp op, ParseFlags parse_flags);
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// Use Decref() instead of delete to release Regexps.
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// This is private to catch deletes at compile time.
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~Regexp();
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void Destroy();
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bool QuickDestroy();
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// Helpers for Parse. Listed here so they can edit Regexps.
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class ParseState;
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friend class ParseState;
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friend bool ParseCharClass(StringPiece* s, Regexp** out_re,
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RegexpStatus* status);
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// Helper for testing [sic].
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friend bool RegexpEqualTestingOnly(Regexp*, Regexp*);
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// Computes whether Regexp is already simple.
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bool ComputeSimple();
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// Constructor that generates a concatenation or alternation,
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// enforcing the limit on the number of subexpressions for
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// a particular Regexp.
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static Regexp* ConcatOrAlternate(RegexpOp op, Regexp** subs, int nsubs,
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ParseFlags flags, bool can_factor);
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// Returns the leading string that re starts with.
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// The returned Rune* points into a piece of re,
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// so it must not be used after the caller calls re->Decref().
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static Rune* LeadingString(Regexp* re, int* nrune, ParseFlags* flags);
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// Removes the first n leading runes from the beginning of re.
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// Edits re in place.
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static void RemoveLeadingString(Regexp* re, int n);
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// Returns the leading regexp in re's top-level concatenation.
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// The returned Regexp* points at re or a sub-expression of re,
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// so it must not be used after the caller calls re->Decref().
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static Regexp* LeadingRegexp(Regexp* re);
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// Removes LeadingRegexp(re) from re and returns the remainder.
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// Might edit re in place.
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static Regexp* RemoveLeadingRegexp(Regexp* re);
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// Simplifies an alternation of literal strings by factoring out
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// common prefixes.
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static int FactorAlternation(Regexp** sub, int nsub, ParseFlags flags);
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static int FactorAlternationRecursive(Regexp** sub, int nsub,
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ParseFlags flags, int maxdepth);
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// Is a == b? Only efficient on regexps that have not been through
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// Simplify yet - the expansion of a kRegexpRepeat will make this
|
|
// take a long time. Do not call on such regexps, hence private.
|
|
static bool Equal(Regexp* a, Regexp* b);
|
|
|
|
// Allocate space for n sub-regexps.
|
|
void AllocSub(int n) {
|
|
if (n < 0 || static_cast<uint16>(n) != n)
|
|
LOG(FATAL) << "Cannot AllocSub " << n;
|
|
if (n > 1)
|
|
submany_ = new Regexp*[n];
|
|
nsub_ = n;
|
|
}
|
|
|
|
// Add Rune to LiteralString
|
|
void AddRuneToString(Rune r);
|
|
|
|
// Swaps this with that, in place.
|
|
void Swap(Regexp *that);
|
|
|
|
// Operator. See description of operators above.
|
|
// uint8 instead of RegexpOp to control space usage.
|
|
uint8 op_;
|
|
|
|
// Is this regexp structure already simple
|
|
// (has it been returned by Simplify)?
|
|
// uint8 instead of bool to control space usage.
|
|
uint8 simple_;
|
|
|
|
// Flags saved from parsing and used during execution.
|
|
// (Only FoldCase is used.)
|
|
// uint16 instead of ParseFlags to control space usage.
|
|
uint16 parse_flags_;
|
|
|
|
// Reference count. Exists so that SimplifyRegexp can build
|
|
// regexp structures that are dags rather than trees to avoid
|
|
// exponential blowup in space requirements.
|
|
// uint16 to control space usage.
|
|
// The standard regexp routines will never generate a
|
|
// ref greater than the maximum repeat count (100),
|
|
// but even so, Incref and Decref consult an overflow map
|
|
// when ref_ reaches kMaxRef.
|
|
uint16 ref_;
|
|
static const uint16 kMaxRef = 0xffff;
|
|
|
|
// Subexpressions.
|
|
// uint16 to control space usage.
|
|
// Concat and Alternate handle larger numbers of subexpressions
|
|
// by building concatenation or alternation trees.
|
|
// Other routines should call Concat or Alternate instead of
|
|
// filling in sub() by hand.
|
|
uint16 nsub_;
|
|
static const uint16 kMaxNsub = 0xffff;
|
|
union {
|
|
Regexp** submany_; // if nsub_ > 1
|
|
Regexp* subone_; // if nsub_ == 1
|
|
};
|
|
|
|
// Extra space for parse and teardown stacks.
|
|
Regexp* down_;
|
|
|
|
// Arguments to operator. See description of operators above.
|
|
union {
|
|
struct { // Repeat
|
|
int max_;
|
|
int min_;
|
|
};
|
|
struct { // Capture
|
|
int cap_;
|
|
string* name_;
|
|
};
|
|
struct { // LiteralString
|
|
int nrunes_;
|
|
Rune* runes_;
|
|
};
|
|
struct { // CharClass
|
|
// These two could be in separate union members,
|
|
// but it wouldn't save any space (there are other two-word structs)
|
|
// and keeping them separate avoids confusion during parsing.
|
|
CharClass* cc_;
|
|
CharClassBuilder* ccb_;
|
|
};
|
|
Rune rune_; // Literal
|
|
int match_id_; // HaveMatch
|
|
void *the_union_[2]; // as big as any other element, for memset
|
|
};
|
|
|
|
DISALLOW_EVIL_CONSTRUCTORS(Regexp);
|
|
};
|
|
|
|
// Character class set: contains non-overlapping, non-abutting RuneRanges.
|
|
typedef set<RuneRange, RuneRangeLess> RuneRangeSet;
|
|
|
|
class CharClassBuilder {
|
|
public:
|
|
CharClassBuilder();
|
|
|
|
typedef RuneRangeSet::iterator iterator;
|
|
iterator begin() { return ranges_.begin(); }
|
|
iterator end() { return ranges_.end(); }
|
|
|
|
int size() { return nrunes_; }
|
|
bool empty() { return nrunes_ == 0; }
|
|
bool full() { return nrunes_ == Runemax+1; }
|
|
|
|
bool Contains(Rune r);
|
|
bool FoldsASCII();
|
|
bool AddRange(Rune lo, Rune hi); // returns whether class changed
|
|
CharClassBuilder* Copy();
|
|
void AddCharClass(CharClassBuilder* cc);
|
|
void Negate();
|
|
void RemoveAbove(Rune r);
|
|
CharClass* GetCharClass();
|
|
void AddRangeFlags(Rune lo, Rune hi, Regexp::ParseFlags parse_flags);
|
|
|
|
private:
|
|
static const uint32 AlphaMask = (1<<26) - 1;
|
|
uint32 upper_; // bitmap of A-Z
|
|
uint32 lower_; // bitmap of a-z
|
|
int nrunes_;
|
|
RuneRangeSet ranges_;
|
|
DISALLOW_EVIL_CONSTRUCTORS(CharClassBuilder);
|
|
};
|
|
|
|
// Tell g++ that bitwise ops on ParseFlags produce ParseFlags.
|
|
inline Regexp::ParseFlags operator|(Regexp::ParseFlags a, Regexp::ParseFlags b)
|
|
{
|
|
return static_cast<Regexp::ParseFlags>(static_cast<int>(a) | static_cast<int>(b));
|
|
}
|
|
|
|
inline Regexp::ParseFlags operator^(Regexp::ParseFlags a, Regexp::ParseFlags b)
|
|
{
|
|
return static_cast<Regexp::ParseFlags>(static_cast<int>(a) ^ static_cast<int>(b));
|
|
}
|
|
|
|
inline Regexp::ParseFlags operator&(Regexp::ParseFlags a, Regexp::ParseFlags b)
|
|
{
|
|
return static_cast<Regexp::ParseFlags>(static_cast<int>(a) & static_cast<int>(b));
|
|
}
|
|
|
|
inline Regexp::ParseFlags operator~(Regexp::ParseFlags a)
|
|
{
|
|
return static_cast<Regexp::ParseFlags>(~static_cast<int>(a));
|
|
}
|
|
|
|
|
|
|
|
} // namespace re2
|
|
|
|
#endif // RE2_REGEXP_H__
|