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편집 파일: regex_compiler.h
// class template regex -*- C++ -*- // Copyright (C) 2010-2018 Free Software Foundation, Inc. // // This file is part of the GNU ISO C++ Library. This library is free // software; you can redistribute it and/or modify it under the // terms of the GNU General Public License as published by the // Free Software Foundation; either version 3, or (at your option) // any later version. // This library is distributed in the hope that it will be useful, // but WITHOUT ANY WARRANTY; without even the implied warranty of // MERCHANTABILITY or FITNESS FOR A PARTICULAR PURPOSE. See the // GNU General Public License for more details. // Under Section 7 of GPL version 3, you are granted additional // permissions described in the GCC Runtime Library Exception, version // 3.1, as published by the Free Software Foundation. // You should have received a copy of the GNU General Public License and // a copy of the GCC Runtime Library Exception along with this program; // see the files COPYING3 and COPYING.RUNTIME respectively. If not, see // <http://www.gnu.org/licenses/>. /** * @file bits/regex_compiler.h * This is an internal header file, included by other library headers. * Do not attempt to use it directly. @headername{regex} */ namespace std _GLIBCXX_VISIBILITY(default) { _GLIBCXX_BEGIN_NAMESPACE_VERSION _GLIBCXX_BEGIN_NAMESPACE_CXX11 template<typename> class regex_traits; _GLIBCXX_END_NAMESPACE_CXX11 namespace __detail { /** * @addtogroup regex-detail * @{ */ template<typename, bool, bool> struct _BracketMatcher; /** * @brief Builds an NFA from an input iterator range. * * The %_TraitsT type should fulfill requirements [28.3]. */ template<typename _TraitsT> class _Compiler { public: typedef typename _TraitsT::char_type _CharT; typedef const _CharT* _IterT; typedef _NFA<_TraitsT> _RegexT; typedef regex_constants::syntax_option_type _FlagT; _Compiler(_IterT __b, _IterT __e, const typename _TraitsT::locale_type& __traits, _FlagT __flags); shared_ptr<const _RegexT> _M_get_nfa() { return std::move(_M_nfa); } private: typedef _Scanner<_CharT> _ScannerT; typedef typename _TraitsT::string_type _StringT; typedef typename _ScannerT::_TokenT _TokenT; typedef _StateSeq<_TraitsT> _StateSeqT; typedef std::stack<_StateSeqT> _StackT; typedef std::ctype<_CharT> _CtypeT; // accepts a specific token or returns false. bool _M_match_token(_TokenT __token); void _M_disjunction(); void _M_alternative(); bool _M_term(); bool _M_assertion(); bool _M_quantifier(); bool _M_atom(); bool _M_bracket_expression(); template<bool __icase, bool __collate> void _M_insert_any_matcher_ecma(); template<bool __icase, bool __collate> void _M_insert_any_matcher_posix(); template<bool __icase, bool __collate> void _M_insert_char_matcher(); template<bool __icase, bool __collate> void _M_insert_character_class_matcher(); template<bool __icase, bool __collate> void _M_insert_bracket_matcher(bool __neg); // Cache of the last atom seen in a bracketed range expression. struct _BracketState { enum class _Type : char { _None, _Char, _Class } _M_type = _Type::_None; _CharT _M_char; void set(_CharT __c) noexcept { _M_type = _Type::_Char; _M_char = __c; } _GLIBCXX_NODISCARD _CharT get() const noexcept { return _M_char; } void reset(_Type __t = _Type::_None) noexcept { _M_type = __t; } explicit operator bool() const noexcept { return _M_type != _Type::_None; } // Previous token was a single character. _GLIBCXX_NODISCARD bool _M_is_char() const noexcept { return _M_type == _Type::_Char; } // Previous token was a character class, equivalent class, // collating symbol etc. _GLIBCXX_NODISCARD bool _M_is_class() const noexcept { return _M_type == _Type::_Class; } }; template<bool __icase, bool __collate> using _BracketMatcher = std::__detail::_BracketMatcher<_TraitsT, __icase, __collate>; // Returns true if successfully parsed one term and should continue // compiling a bracket expression. // Returns false if the compiler should move on. template<bool __icase, bool __collate> bool _M_expression_term(_BracketState& __last_char, _BracketMatcher<__icase, __collate>& __matcher); int _M_cur_int_value(int __radix); bool _M_try_char(); _StateSeqT _M_pop() { auto ret = _M_stack.top(); _M_stack.pop(); return ret; } _FlagT _M_flags; _ScannerT _M_scanner; shared_ptr<_RegexT> _M_nfa; _StringT _M_value; _StackT _M_stack; const _TraitsT& _M_traits; const _CtypeT& _M_ctype; }; template<typename _Tp> struct __has_contiguous_iter : std::false_type { }; template<typename _Ch, typename _Tr, typename _Alloc> struct __has_contiguous_iter<std::basic_string<_Ch, _Tr, _Alloc>> : std::true_type { }; template<typename _Tp, typename _Alloc> struct __has_contiguous_iter<std::vector<_Tp, _Alloc>> : std::true_type { }; template<typename _Tp> struct __is_contiguous_normal_iter : std::false_type { }; template<typename _CharT> struct __is_contiguous_normal_iter<_CharT*> : std::true_type { }; template<typename _Tp, typename _Cont> struct __is_contiguous_normal_iter<__gnu_cxx::__normal_iterator<_Tp, _Cont>> : __has_contiguous_iter<_Cont>::type { }; template<typename _Iter, typename _TraitsT> using __enable_if_contiguous_normal_iter = typename enable_if< __is_contiguous_normal_iter<_Iter>::value, std::shared_ptr<const _NFA<_TraitsT>> >::type; template<typename _Iter, typename _TraitsT> using __disable_if_contiguous_normal_iter = typename enable_if< !__is_contiguous_normal_iter<_Iter>::value, std::shared_ptr<const _NFA<_TraitsT>> >::type; template<typename _TraitsT, typename _FwdIter> inline __enable_if_contiguous_normal_iter<_FwdIter, _TraitsT> __compile_nfa(_FwdIter __first, _FwdIter __last, const typename _TraitsT::locale_type& __loc, regex_constants::syntax_option_type __flags) { size_t __len = __last - __first; const auto* __cfirst = __len ? std::__addressof(*__first) : nullptr; using _Cmplr = _Compiler<_TraitsT>; return _Cmplr(__cfirst, __cfirst + __len, __loc, __flags)._M_get_nfa(); } template<typename _TraitsT, typename _FwdIter> inline __disable_if_contiguous_normal_iter<_FwdIter, _TraitsT> __compile_nfa(_FwdIter __first, _FwdIter __last, const typename _TraitsT::locale_type& __loc, regex_constants::syntax_option_type __flags) { const basic_string<typename _TraitsT::char_type> __str(__first, __last); return __compile_nfa<_TraitsT>(__str.data(), __str.data() + __str.size(), __loc, __flags); } // [28.13.14] template<typename _TraitsT, bool __icase, bool __collate> class _RegexTranslatorBase { public: typedef typename _TraitsT::char_type _CharT; typedef typename _TraitsT::string_type _StringT; typedef _StringT _StrTransT; explicit _RegexTranslatorBase(const _TraitsT& __traits) : _M_traits(__traits) { } _CharT _M_translate(_CharT __ch) const { if (__icase) return _M_traits.translate_nocase(__ch); else if (__collate) return _M_traits.translate(__ch); else return __ch; } _StrTransT _M_transform(_CharT __ch) const { _StrTransT __str(1, __ch); return _M_traits.transform(__str.begin(), __str.end()); } // See LWG 523. It's not efficiently implementable when _TraitsT is not // std::regex_traits<>, and __collate is true. See specializations for // implementations of other cases. bool _M_match_range(const _StrTransT& __first, const _StrTransT& __last, const _StrTransT& __s) const { return __first <= __s && __s <= __last; } protected: bool _M_in_range_icase(_CharT __first, _CharT __last, _CharT __ch) const { typedef std::ctype<_CharT> __ctype_type; const auto& __fctyp = use_facet<__ctype_type>(this->_M_traits.getloc()); auto __lower = __fctyp.tolower(__ch); auto __upper = __fctyp.toupper(__ch); return (__first <= __lower && __lower <= __last) || (__first <= __upper && __upper <= __last); } const _TraitsT& _M_traits; }; template<typename _TraitsT, bool __icase, bool __collate> class _RegexTranslator : public _RegexTranslatorBase<_TraitsT, __icase, __collate> { public: typedef _RegexTranslatorBase<_TraitsT, __icase, __collate> _Base; using _Base::_Base; }; template<typename _TraitsT, bool __icase> class _RegexTranslator<_TraitsT, __icase, false> : public _RegexTranslatorBase<_TraitsT, __icase, false> { public: typedef _RegexTranslatorBase<_TraitsT, __icase, false> _Base; typedef typename _Base::_CharT _CharT; typedef _CharT _StrTransT; using _Base::_Base; _StrTransT _M_transform(_CharT __ch) const { return __ch; } bool _M_match_range(_CharT __first, _CharT __last, _CharT __ch) const { if (!__icase) return __first <= __ch && __ch <= __last; return this->_M_in_range_icase(__first, __last, __ch); } }; template<typename _CharType> class _RegexTranslator<std::regex_traits<_CharType>, true, true> : public _RegexTranslatorBase<std::regex_traits<_CharType>, true, true> { public: typedef _RegexTranslatorBase<std::regex_traits<_CharType>, true, true> _Base; typedef typename _Base::_CharT _CharT; typedef typename _Base::_StrTransT _StrTransT; using _Base::_Base; bool _M_match_range(const _StrTransT& __first, const _StrTransT& __last, const _StrTransT& __str) const { __glibcxx_assert(__first.size() == 1); __glibcxx_assert(__last.size() == 1); __glibcxx_assert(__str.size() == 1); return this->_M_in_range_icase(__first[0], __last[0], __str[0]); } }; template<typename _TraitsT> class _RegexTranslator<_TraitsT, false, false> { public: typedef typename _TraitsT::char_type _CharT; typedef _CharT _StrTransT; explicit _RegexTranslator(const _TraitsT&) { } _CharT _M_translate(_CharT __ch) const { return __ch; } _StrTransT _M_transform(_CharT __ch) const { return __ch; } bool _M_match_range(_CharT __first, _CharT __last, _CharT __ch) const { return __first <= __ch && __ch <= __last; } }; template<typename _TraitsT, bool __is_ecma, bool __icase, bool __collate> struct _AnyMatcher; template<typename _TraitsT, bool __icase, bool __collate> struct _AnyMatcher<_TraitsT, false, __icase, __collate> { typedef _RegexTranslator<_TraitsT, __icase, __collate> _TransT; typedef typename _TransT::_CharT _CharT; explicit _AnyMatcher(const _TraitsT& __traits) : _M_translator(__traits) { } bool operator()(_CharT __ch) const { static auto __nul = _M_translator._M_translate('\0'); return _M_translator._M_translate(__ch) != __nul; } _TransT _M_translator; }; template<typename _TraitsT, bool __icase, bool __collate> struct _AnyMatcher<_TraitsT, true, __icase, __collate> { typedef _RegexTranslator<_TraitsT, __icase, __collate> _TransT; typedef typename _TransT::_CharT _CharT; explicit _AnyMatcher(const _TraitsT& __traits) : _M_translator(__traits) { } bool operator()(_CharT __ch) const { return _M_apply(__ch, typename is_same<_CharT, char>::type()); } bool _M_apply(_CharT __ch, true_type) const { auto __c = _M_translator._M_translate(__ch); auto __n = _M_translator._M_translate('\n'); auto __r = _M_translator._M_translate('\r'); return __c != __n && __c != __r; } bool _M_apply(_CharT __ch, false_type) const { auto __c = _M_translator._M_translate(__ch); auto __n = _M_translator._M_translate('\n'); auto __r = _M_translator._M_translate('\r'); auto __u2028 = _M_translator._M_translate(u'\u2028'); auto __u2029 = _M_translator._M_translate(u'\u2029'); return __c != __n && __c != __r && __c != __u2028 && __c != __u2029; } _TransT _M_translator; }; template<typename _TraitsT, bool __icase, bool __collate> struct _CharMatcher { typedef _RegexTranslator<_TraitsT, __icase, __collate> _TransT; typedef typename _TransT::_CharT _CharT; _CharMatcher(_CharT __ch, const _TraitsT& __traits) : _M_translator(__traits), _M_ch(_M_translator._M_translate(__ch)) { } bool operator()(_CharT __ch) const { return _M_ch == _M_translator._M_translate(__ch); } _TransT _M_translator; _CharT _M_ch; }; /// Matches a character range (bracket expression) template<typename _TraitsT, bool __icase, bool __collate> struct _BracketMatcher { public: typedef _RegexTranslator<_TraitsT, __icase, __collate> _TransT; typedef typename _TransT::_CharT _CharT; typedef typename _TransT::_StrTransT _StrTransT; typedef typename _TraitsT::string_type _StringT; typedef typename _TraitsT::char_class_type _CharClassT; public: _BracketMatcher(bool __is_non_matching, const _TraitsT& __traits) : _M_class_set(0), _M_translator(__traits), _M_traits(__traits), _M_is_non_matching(__is_non_matching) { } bool operator()(_CharT __ch) const { _GLIBCXX_DEBUG_ASSERT(_M_is_ready); return _M_apply(__ch, _UseCache()); } void _M_add_char(_CharT __c) { _M_char_set.push_back(_M_translator._M_translate(__c)); _GLIBCXX_DEBUG_ONLY(_M_is_ready = false); } _StringT _M_add_collate_element(const _StringT& __s) { auto __st = _M_traits.lookup_collatename(__s.data(), __s.data() + __s.size()); if (__st.empty()) __throw_regex_error(regex_constants::error_collate, "Invalid collate element."); _M_char_set.push_back(_M_translator._M_translate(__st[0])); _GLIBCXX_DEBUG_ONLY(_M_is_ready = false); return __st; } void _M_add_equivalence_class(const _StringT& __s) { auto __st = _M_traits.lookup_collatename(__s.data(), __s.data() + __s.size()); if (__st.empty()) __throw_regex_error(regex_constants::error_collate, "Invalid equivalence class."); __st = _M_traits.transform_primary(__st.data(), __st.data() + __st.size()); _M_equiv_set.push_back(__st); _GLIBCXX_DEBUG_ONLY(_M_is_ready = false); } // __neg should be true for \D, \S and \W only. void _M_add_character_class(const _StringT& __s, bool __neg) { auto __mask = _M_traits.lookup_classname(__s.data(), __s.data() + __s.size(), __icase); if (__mask == 0) __throw_regex_error(regex_constants::error_collate, "Invalid character class."); if (!__neg) _M_class_set |= __mask; else _M_neg_class_set.push_back(__mask); _GLIBCXX_DEBUG_ONLY(_M_is_ready = false); } void _M_make_range(_CharT __l, _CharT __r) { if (__l > __r) __throw_regex_error(regex_constants::error_range, "Invalid range in bracket expression."); _M_range_set.push_back(make_pair(_M_translator._M_transform(__l), _M_translator._M_transform(__r))); _GLIBCXX_DEBUG_ONLY(_M_is_ready = false); } void _M_ready() { std::sort(_M_char_set.begin(), _M_char_set.end()); auto __end = std::unique(_M_char_set.begin(), _M_char_set.end()); _M_char_set.erase(__end, _M_char_set.end()); _M_make_cache(_UseCache()); _GLIBCXX_DEBUG_ONLY(_M_is_ready = true); } private: // Currently we only use the cache for char typedef typename std::is_same<_CharT, char>::type _UseCache; static constexpr size_t _S_cache_size() { return 1ul << (sizeof(_CharT) * __CHAR_BIT__ * int(_UseCache::value)); } struct _Dummy { }; typedef typename std::conditional<_UseCache::value, std::bitset<_S_cache_size()>, _Dummy>::type _CacheT; typedef typename std::make_unsigned<_CharT>::type _UnsignedCharT; bool _M_apply(_CharT __ch, false_type) const; bool _M_apply(_CharT __ch, true_type) const { return _M_cache[static_cast<_UnsignedCharT>(__ch)]; } void _M_make_cache(true_type) { for (unsigned __i = 0; __i < _M_cache.size(); __i++) _M_cache[__i] = _M_apply(static_cast<_CharT>(__i), false_type()); } void _M_make_cache(false_type) { } private: std::vector<_CharT> _M_char_set; std::vector<_StringT> _M_equiv_set; std::vector<pair<_StrTransT, _StrTransT>> _M_range_set; std::vector<_CharClassT> _M_neg_class_set; _CharClassT _M_class_set; _TransT _M_translator; const _TraitsT& _M_traits; bool _M_is_non_matching; _CacheT _M_cache; #ifdef _GLIBCXX_DEBUG bool _M_is_ready = false; #endif }; //@} regex-detail } // namespace __detail _GLIBCXX_END_NAMESPACE_VERSION } // namespace std #include <bits/regex_compiler.tcc>