/* * * Copyright (c) 2004 * John Maddock * * Use, modification and distribution are subject to the * Boost Software License, Version 1.0. (See accompanying file * LICENSE_1_0.txt or copy at http://www.boost.org/LICENSE_1_0.txt) * */ /* * LOCATION: see http://www.boost.org for most recent version. * FILE w32_regex_traits.hpp * VERSION see * DESCRIPTION: Declares regular expression traits class w32_regex_traits. */ #ifndef BOOST_W32_REGEX_TRAITS_HPP_INCLUDED #define BOOST_W32_REGEX_TRAITS_HPP_INCLUDED #ifndef BOOST_REGEX_NO_WIN32_LOCALE #include #include #ifdef BOOST_HAS_THREADS #include #endif #include #include #define VC_EXTRALEAN #define WIN32_LEAN_AND_MEAN #include #if defined(_MSC_VER) && !defined(_WIN32_WCE) && !defined(UNDER_CE) #pragma comment(lib, "user32.lib") #endif #ifdef BOOST_REGEX_MSVC #pragma warning(push) #pragma warning(disable:4786) #if BOOST_REGEX_MSVC < 1910 #pragma warning(disable:4800) #endif #endif namespace boost{ // // forward declaration is needed by some compilers: // template class w32_regex_traits; namespace BOOST_REGEX_DETAIL_NS{ // // start by typedeffing the types we'll need: // typedef std::uint32_t lcid_type; // placeholder for LCID. typedef std::shared_ptr cat_type; // placeholder for dll HANDLE. // // then add wrappers around the actual Win32 API's (ie implementation hiding): // lcid_type w32_get_default_locale(); bool w32_is_lower(char, lcid_type); #ifndef BOOST_NO_WREGEX bool w32_is_lower(wchar_t, lcid_type); #endif bool w32_is_upper(char, lcid_type); #ifndef BOOST_NO_WREGEX bool w32_is_upper(wchar_t, lcid_type); #endif cat_type w32_cat_open(const std::string& name); std::string w32_cat_get(const cat_type& cat, lcid_type state_id, int i, const std::string& def); #ifndef BOOST_NO_WREGEX std::wstring w32_cat_get(const cat_type& cat, lcid_type state_id, int i, const std::wstring& def); #endif std::string w32_transform(lcid_type state_id, const char* p1, const char* p2); #ifndef BOOST_NO_WREGEX std::wstring w32_transform(lcid_type state_id, const wchar_t* p1, const wchar_t* p2); #endif char w32_tolower(char c, lcid_type); #ifndef BOOST_NO_WREGEX wchar_t w32_tolower(wchar_t c, lcid_type); #endif char w32_toupper(char c, lcid_type); #ifndef BOOST_NO_WREGEX wchar_t w32_toupper(wchar_t c, lcid_type); #endif bool w32_is(lcid_type, std::uint32_t mask, char c); #ifndef BOOST_NO_WREGEX bool w32_is(lcid_type, std::uint32_t mask, wchar_t c); #endif // // class w32_regex_traits_base: // acts as a container for locale and the facets we are using. // template struct w32_regex_traits_base { w32_regex_traits_base(lcid_type l) { imbue(l); } lcid_type imbue(lcid_type l); lcid_type m_locale; }; template inline lcid_type w32_regex_traits_base::imbue(lcid_type l) { lcid_type result(m_locale); m_locale = l; return result; } // // class w32_regex_traits_char_layer: // implements methods that require specialisation for narrow characters: // template class w32_regex_traits_char_layer : public w32_regex_traits_base { typedef std::basic_string string_type; typedef std::map map_type; typedef typename map_type::const_iterator map_iterator_type; public: w32_regex_traits_char_layer(const lcid_type l); regex_constants::syntax_type syntax_type(charT c)const { map_iterator_type i = m_char_map.find(c); return ((i == m_char_map.end()) ? 0 : i->second); } regex_constants::escape_syntax_type escape_syntax_type(charT c) const { map_iterator_type i = m_char_map.find(c); if(i == m_char_map.end()) { if(::boost::BOOST_REGEX_DETAIL_NS::w32_is_lower(c, this->m_locale)) return regex_constants::escape_type_class; if(::boost::BOOST_REGEX_DETAIL_NS::w32_is_upper(c, this->m_locale)) return regex_constants::escape_type_not_class; return 0; } return i->second; } charT tolower(charT c)const { return ::boost::BOOST_REGEX_DETAIL_NS::w32_tolower(c, this->m_locale); } bool isctype(std::uint32_t mask, charT c)const { return ::boost::BOOST_REGEX_DETAIL_NS::w32_is(this->m_locale, mask, c); } private: string_type get_default_message(regex_constants::syntax_type); // TODO: use a hash table when available! map_type m_char_map; }; template w32_regex_traits_char_layer::w32_regex_traits_char_layer(::boost::BOOST_REGEX_DETAIL_NS::lcid_type l) : w32_regex_traits_base(l) { // we need to start by initialising our syntax map so we know which // character is used for which purpose: cat_type cat; std::string cat_name(w32_regex_traits::get_catalog_name()); if(cat_name.size()) { cat = ::boost::BOOST_REGEX_DETAIL_NS::w32_cat_open(cat_name); if(!cat) { std::string m("Unable to open message catalog: "); std::runtime_error err(m + cat_name); boost::BOOST_REGEX_DETAIL_NS::raise_runtime_error(err); } } // // if we have a valid catalog then load our messages: // if(cat) { for(regex_constants::syntax_type i = 1; i < regex_constants::syntax_max; ++i) { string_type mss = ::boost::BOOST_REGEX_DETAIL_NS::w32_cat_get(cat, this->m_locale, i, get_default_message(i)); for(typename string_type::size_type j = 0; j < mss.size(); ++j) { this->m_char_map[mss[j]] = i; } } } else { for(regex_constants::syntax_type i = 1; i < regex_constants::syntax_max; ++i) { const char* ptr = get_default_syntax(i); while(ptr && *ptr) { this->m_char_map[static_cast(*ptr)] = i; ++ptr; } } } } template typename w32_regex_traits_char_layer::string_type w32_regex_traits_char_layer::get_default_message(regex_constants::syntax_type i) { const char* ptr = get_default_syntax(i); string_type result; while(ptr && *ptr) { result.append(1, static_cast(*ptr)); ++ptr; } return result; } // // specialised version for narrow characters: // template <> class w32_regex_traits_char_layer : public w32_regex_traits_base { typedef std::string string_type; public: w32_regex_traits_char_layer(::boost::BOOST_REGEX_DETAIL_NS::lcid_type l) : w32_regex_traits_base(l) { init(); } regex_constants::syntax_type syntax_type(char c)const { return m_char_map[static_cast(c)]; } regex_constants::escape_syntax_type escape_syntax_type(char c) const { return m_char_map[static_cast(c)]; } char tolower(char c)const { return m_lower_map[static_cast(c)]; } bool isctype(std::uint32_t mask, char c)const { return m_type_map[static_cast(c)] & mask; } private: regex_constants::syntax_type m_char_map[1u << CHAR_BIT]; char m_lower_map[1u << CHAR_BIT]; std::uint16_t m_type_map[1u << CHAR_BIT]; template void init(); }; // // class w32_regex_traits_implementation: // provides pimpl implementation for w32_regex_traits. // template class w32_regex_traits_implementation : public w32_regex_traits_char_layer { public: typedef typename w32_regex_traits::char_class_type char_class_type; static const char_class_type mask_word = 0x0400; // must be C1_DEFINED << 1 static const char_class_type mask_unicode = 0x0800; // must be C1_DEFINED << 2 static const char_class_type mask_horizontal = 0x1000; // must be C1_DEFINED << 3 static const char_class_type mask_vertical = 0x2000; // must be C1_DEFINED << 4 static const char_class_type mask_base = 0x3ff; // all the masks used by the CT_CTYPE1 group typedef std::basic_string string_type; typedef charT char_type; w32_regex_traits_implementation(::boost::BOOST_REGEX_DETAIL_NS::lcid_type l); std::string error_string(regex_constants::error_type n) const { if(!m_error_strings.empty()) { std::map::const_iterator p = m_error_strings.find(n); return (p == m_error_strings.end()) ? std::string(get_default_error_string(n)) : p->second; } return get_default_error_string(n); } char_class_type lookup_classname(const charT* p1, const charT* p2) const { char_class_type result = lookup_classname_imp(p1, p2); if(result == 0) { typedef typename string_type::size_type size_type; string_type temp(p1, p2); for(size_type i = 0; i < temp.size(); ++i) temp[i] = this->tolower(temp[i]); result = lookup_classname_imp(&*temp.begin(), &*temp.begin() + temp.size()); } return result; } string_type lookup_collatename(const charT* p1, const charT* p2) const; string_type transform_primary(const charT* p1, const charT* p2) const; string_type transform(const charT* p1, const charT* p2) const { return ::boost::BOOST_REGEX_DETAIL_NS::w32_transform(this->m_locale, p1, p2); } private: std::map m_error_strings; // error messages indexed by numberic ID std::map m_custom_class_names; // character class names std::map m_custom_collate_names; // collating element names unsigned m_collate_type; // the form of the collation string charT m_collate_delim; // the collation group delimiter // // helpers: // char_class_type lookup_classname_imp(const charT* p1, const charT* p2) const; }; template typename w32_regex_traits_implementation::string_type w32_regex_traits_implementation::transform_primary(const charT* p1, const charT* p2) const { string_type result; // // What we do here depends upon the format of the sort key returned by // sort key returned by this->transform: // switch(m_collate_type) { case sort_C: case sort_unknown: // the best we can do is translate to lower case, then get a regular sort key: { result.assign(p1, p2); typedef typename string_type::size_type size_type; for(size_type i = 0; i < result.size(); ++i) result[i] = this->tolower(result[i]); result = this->transform(&*result.begin(), &*result.begin() + result.size()); break; } case sort_fixed: { // get a regular sort key, and then truncate it: result.assign(this->transform(p1, p2)); result.erase(this->m_collate_delim); break; } case sort_delim: // get a regular sort key, and then truncate everything after the delim: result.assign(this->transform(p1, p2)); std::size_t i; for(i = 0; i < result.size(); ++i) { if(result[i] == m_collate_delim) break; } result.erase(i); break; } if(result.empty()) result = string_type(1, charT(0)); return result; } template typename w32_regex_traits_implementation::string_type w32_regex_traits_implementation::lookup_collatename(const charT* p1, const charT* p2) const { typedef typename std::map::const_iterator iter_type; if(m_custom_collate_names.size()) { iter_type pos = m_custom_collate_names.find(string_type(p1, p2)); if(pos != m_custom_collate_names.end()) return pos->second; } std::string name(p1, p2); name = lookup_default_collate_name(name); if(name.size()) return string_type(name.begin(), name.end()); if(p2 - p1 == 1) return string_type(1, *p1); return string_type(); } template w32_regex_traits_implementation::w32_regex_traits_implementation(::boost::BOOST_REGEX_DETAIL_NS::lcid_type l) : w32_regex_traits_char_layer(l) { cat_type cat; std::string cat_name(w32_regex_traits::get_catalog_name()); if(cat_name.size()) { cat = ::boost::BOOST_REGEX_DETAIL_NS::w32_cat_open(cat_name); if(!cat) { std::string m("Unable to open message catalog: "); std::runtime_error err(m + cat_name); boost::BOOST_REGEX_DETAIL_NS::raise_runtime_error(err); } } // // if we have a valid catalog then load our messages: // if(cat) { // // Error messages: // for(boost::regex_constants::error_type i = static_cast(0); i <= boost::regex_constants::error_unknown; i = static_cast(i + 1)) { const char* p = get_default_error_string(i); string_type default_message; while(*p) { default_message.append(1, static_cast(*p)); ++p; } string_type s = ::boost::BOOST_REGEX_DETAIL_NS::w32_cat_get(cat, this->m_locale, i+200, default_message); std::string result; for(std::string::size_type j = 0; j < s.size(); ++j) { result.append(1, static_cast(s[j])); } m_error_strings[i] = result; } // // Custom class names: // static const char_class_type masks[14] = { 0x0104u, // C1_ALPHA | C1_DIGIT 0x0100u, // C1_ALPHA 0x0020u, // C1_CNTRL 0x0004u, // C1_DIGIT (~(0x0020u|0x0008u) & 0x01ffu) | 0x0400u, // not C1_CNTRL or C1_SPACE 0x0002u, // C1_LOWER (~0x0020u & 0x01ffu) | 0x0400, // not C1_CNTRL 0x0010u, // C1_PUNCT 0x0008u, // C1_SPACE 0x0001u, // C1_UPPER 0x0080u, // C1_XDIGIT 0x0040u, // C1_BLANK w32_regex_traits_implementation::mask_word, w32_regex_traits_implementation::mask_unicode, }; static const string_type null_string; for(unsigned int j = 0; j <= 13; ++j) { string_type s(::boost::BOOST_REGEX_DETAIL_NS::w32_cat_get(cat, this->m_locale, j+300, null_string)); if(s.size()) this->m_custom_class_names[s] = masks[j]; } } // // get the collation format used by m_pcollate: // m_collate_type = BOOST_REGEX_DETAIL_NS::find_sort_syntax(this, &m_collate_delim); } template typename w32_regex_traits_implementation::char_class_type w32_regex_traits_implementation::lookup_classname_imp(const charT* p1, const charT* p2) const { static const char_class_type masks[22] = { 0, 0x0104u, // C1_ALPHA | C1_DIGIT 0x0100u, // C1_ALPHA 0x0040u, // C1_BLANK 0x0020u, // C1_CNTRL 0x0004u, // C1_DIGIT 0x0004u, // C1_DIGIT (~(0x0020u|0x0008u|0x0040) & 0x01ffu) | 0x0400u, // not C1_CNTRL or C1_SPACE or C1_BLANK w32_regex_traits_implementation::mask_horizontal, 0x0002u, // C1_LOWER 0x0002u, // C1_LOWER (~0x0020u & 0x01ffu) | 0x0400, // not C1_CNTRL 0x0010u, // C1_PUNCT 0x0008u, // C1_SPACE 0x0008u, // C1_SPACE 0x0001u, // C1_UPPER w32_regex_traits_implementation::mask_unicode, 0x0001u, // C1_UPPER w32_regex_traits_implementation::mask_vertical, 0x0104u | w32_regex_traits_implementation::mask_word, 0x0104u | w32_regex_traits_implementation::mask_word, 0x0080u, // C1_XDIGIT }; if(m_custom_class_names.size()) { typedef typename std::map, char_class_type>::const_iterator map_iter; map_iter pos = m_custom_class_names.find(string_type(p1, p2)); if(pos != m_custom_class_names.end()) return pos->second; } std::size_t state_id = 1u + (std::size_t)BOOST_REGEX_DETAIL_NS::get_default_class_id(p1, p2); if(state_id < sizeof(masks) / sizeof(masks[0])) return masks[state_id]; return masks[0]; } template std::shared_ptr > create_w32_regex_traits(::boost::BOOST_REGEX_DETAIL_NS::lcid_type l) { // TODO: create a cache for previously constructed objects. return boost::object_cache< ::boost::BOOST_REGEX_DETAIL_NS::lcid_type, w32_regex_traits_implementation >::get(l, 5); } } // BOOST_REGEX_DETAIL_NS template class w32_regex_traits { public: typedef charT char_type; typedef std::size_t size_type; typedef std::basic_string string_type; typedef ::boost::BOOST_REGEX_DETAIL_NS::lcid_type locale_type; typedef std::uint_least32_t char_class_type; struct boost_extensions_tag{}; w32_regex_traits() : m_pimpl(BOOST_REGEX_DETAIL_NS::create_w32_regex_traits(::boost::BOOST_REGEX_DETAIL_NS::w32_get_default_locale())) { } static size_type length(const char_type* p) { return std::char_traits::length(p); } regex_constants::syntax_type syntax_type(charT c)const { return m_pimpl->syntax_type(c); } regex_constants::escape_syntax_type escape_syntax_type(charT c) const { return m_pimpl->escape_syntax_type(c); } charT translate(charT c) const { return c; } charT translate_nocase(charT c) const { return this->m_pimpl->tolower(c); } charT translate(charT c, bool icase) const { return icase ? this->m_pimpl->tolower(c) : c; } charT tolower(charT c) const { return this->m_pimpl->tolower(c); } charT toupper(charT c) const { return ::boost::BOOST_REGEX_DETAIL_NS::w32_toupper(c, this->m_pimpl->m_locale); } string_type transform(const charT* p1, const charT* p2) const { return ::boost::BOOST_REGEX_DETAIL_NS::w32_transform(this->m_pimpl->m_locale, p1, p2); } string_type transform_primary(const charT* p1, const charT* p2) const { return m_pimpl->transform_primary(p1, p2); } char_class_type lookup_classname(const charT* p1, const charT* p2) const { return m_pimpl->lookup_classname(p1, p2); } string_type lookup_collatename(const charT* p1, const charT* p2) const { return m_pimpl->lookup_collatename(p1, p2); } bool isctype(charT c, char_class_type f) const { if((f & BOOST_REGEX_DETAIL_NS::w32_regex_traits_implementation::mask_base) && (this->m_pimpl->isctype(f & BOOST_REGEX_DETAIL_NS::w32_regex_traits_implementation::mask_base, c))) return true; else if((f & BOOST_REGEX_DETAIL_NS::w32_regex_traits_implementation::mask_unicode) && BOOST_REGEX_DETAIL_NS::is_extended(c)) return true; else if((f & BOOST_REGEX_DETAIL_NS::w32_regex_traits_implementation::mask_word) && (c == '_')) return true; else if((f & BOOST_REGEX_DETAIL_NS::w32_regex_traits_implementation::mask_vertical) && (::boost::BOOST_REGEX_DETAIL_NS::is_separator(c) || (c == '\v'))) return true; else if((f & BOOST_REGEX_DETAIL_NS::w32_regex_traits_implementation::mask_horizontal) && this->isctype(c, 0x0008u) && !this->isctype(c, BOOST_REGEX_DETAIL_NS::w32_regex_traits_implementation::mask_vertical)) return true; return false; } std::intmax_t toi(const charT*& p1, const charT* p2, int radix)const { return ::boost::BOOST_REGEX_DETAIL_NS::global_toi(p1, p2, radix, *this); } int value(charT c, int radix)const { int result = (int)::boost::BOOST_REGEX_DETAIL_NS::global_value(c); return result < radix ? result : -1; } locale_type imbue(locale_type l) { ::boost::BOOST_REGEX_DETAIL_NS::lcid_type result(getloc()); m_pimpl = BOOST_REGEX_DETAIL_NS::create_w32_regex_traits(l); return result; } locale_type getloc()const { return m_pimpl->m_locale; } std::string error_string(regex_constants::error_type n) const { return m_pimpl->error_string(n); } // // extension: // set the name of the message catalog in use (defaults to "boost_regex"). // static std::string catalog_name(const std::string& name); static std::string get_catalog_name(); private: std::shared_ptr > m_pimpl; // // catalog name handler: // static std::string& get_catalog_name_inst(); #ifdef BOOST_HAS_THREADS static std::mutex& get_mutex_inst(); #endif }; template std::string w32_regex_traits::catalog_name(const std::string& name) { #ifdef BOOST_HAS_THREADS std::lock_guard lk(get_mutex_inst()); #endif std::string result(get_catalog_name_inst()); get_catalog_name_inst() = name; return result; } template std::string& w32_regex_traits::get_catalog_name_inst() { static std::string s_name; return s_name; } template std::string w32_regex_traits::get_catalog_name() { #ifdef BOOST_HAS_THREADS std::lock_guard lk(get_mutex_inst()); #endif std::string result(get_catalog_name_inst()); return result; } #ifdef BOOST_HAS_THREADS template std::mutex& w32_regex_traits::get_mutex_inst() { static std::mutex s_mutex; return s_mutex; } #endif namespace BOOST_REGEX_DETAIL_NS { #ifdef BOOST_NO_ANSI_APIS inline UINT get_code_page_for_locale_id(lcid_type idx) { WCHAR code_page_string[7]; if (::GetLocaleInfoW(idx, LOCALE_IDEFAULTANSICODEPAGE, code_page_string, 7) == 0) return 0; return static_cast(_wtol(code_page_string)); } #endif template inline void w32_regex_traits_char_layer::init() { // we need to start by initialising our syntax map so we know which // character is used for which purpose: std::memset(m_char_map, 0, sizeof(m_char_map)); cat_type cat; std::string cat_name(w32_regex_traits::get_catalog_name()); if (cat_name.size()) { cat = ::boost::BOOST_REGEX_DETAIL_NS::w32_cat_open(cat_name); if (!cat) { std::string m("Unable to open message catalog: "); std::runtime_error err(m + cat_name); ::boost::BOOST_REGEX_DETAIL_NS::raise_runtime_error(err); } } // // if we have a valid catalog then load our messages: // if (cat) { for (regex_constants::syntax_type i = 1; i < regex_constants::syntax_max; ++i) { string_type mss = ::boost::BOOST_REGEX_DETAIL_NS::w32_cat_get(cat, this->m_locale, i, get_default_syntax(i)); for (string_type::size_type j = 0; j < mss.size(); ++j) { m_char_map[static_cast(mss[j])] = i; } } } else { for (regex_constants::syntax_type i = 1; i < regex_constants::syntax_max; ++i) { const char* ptr = get_default_syntax(i); while (ptr && *ptr) { m_char_map[static_cast(*ptr)] = i; ++ptr; } } } // // finish off by calculating our escape types: // unsigned char i = 'A'; do { if (m_char_map[i] == 0) { if (::boost::BOOST_REGEX_DETAIL_NS::w32_is(this->m_locale, 0x0002u, (char)i)) m_char_map[i] = regex_constants::escape_type_class; else if (::boost::BOOST_REGEX_DETAIL_NS::w32_is(this->m_locale, 0x0001u, (char)i)) m_char_map[i] = regex_constants::escape_type_not_class; } } while (0xFF != i++); // // fill in lower case map: // char char_map[1 << CHAR_BIT]; for (int ii = 0; ii < (1 << CHAR_BIT); ++ii) char_map[ii] = static_cast(ii); #ifndef BOOST_NO_ANSI_APIS int r = ::LCMapStringA(this->m_locale, LCMAP_LOWERCASE, char_map, 1 << CHAR_BIT, this->m_lower_map, 1 << CHAR_BIT); BOOST_REGEX_ASSERT(r != 0); #else UINT code_page = get_code_page_for_locale_id(this->m_locale); BOOST_REGEX_ASSERT(code_page != 0); WCHAR wide_char_map[1 << CHAR_BIT]; int conv_r = ::MultiByteToWideChar(code_page, 0, char_map, 1 << CHAR_BIT, wide_char_map, 1 << CHAR_BIT); BOOST_REGEX_ASSERT(conv_r != 0); WCHAR wide_lower_map[1 << CHAR_BIT]; int r = ::LCMapStringW(this->m_locale, LCMAP_LOWERCASE, wide_char_map, 1 << CHAR_BIT, wide_lower_map, 1 << CHAR_BIT); BOOST_REGEX_ASSERT(r != 0); conv_r = ::WideCharToMultiByte(code_page, 0, wide_lower_map, r, this->m_lower_map, 1 << CHAR_BIT, NULL, NULL); BOOST_REGEX_ASSERT(conv_r != 0); #endif if (r < (1 << CHAR_BIT)) { // if we have multibyte characters then not all may have been given // a lower case mapping: for (int jj = r; jj < (1 << CHAR_BIT); ++jj) this->m_lower_map[jj] = static_cast(jj); } #ifndef BOOST_NO_ANSI_APIS r = ::GetStringTypeExA(this->m_locale, CT_CTYPE1, char_map, 1 << CHAR_BIT, this->m_type_map); #else r = ::GetStringTypeExW(this->m_locale, CT_CTYPE1, wide_char_map, 1 << CHAR_BIT, this->m_type_map); #endif BOOST_REGEX_ASSERT(0 != r); } inline lcid_type w32_get_default_locale() { return ::GetUserDefaultLCID(); } inline bool w32_is_lower(char c, lcid_type idx) { #ifndef BOOST_NO_ANSI_APIS WORD mask; if (::GetStringTypeExA(idx, CT_CTYPE1, &c, 1, &mask) && (mask & C1_LOWER)) return true; return false; #else UINT code_page = get_code_page_for_locale_id(idx); if (code_page == 0) return false; WCHAR wide_c; if (::MultiByteToWideChar(code_page, 0, &c, 1, &wide_c, 1) == 0) return false; WORD mask; if (::GetStringTypeExW(idx, CT_CTYPE1, &wide_c, 1, &mask) && (mask & C1_LOWER)) return true; return false; #endif } inline bool w32_is_lower(wchar_t c, lcid_type idx) { WORD mask; if (::GetStringTypeExW(idx, CT_CTYPE1, &c, 1, &mask) && (mask & C1_LOWER)) return true; return false; } inline bool w32_is_upper(char c, lcid_type idx) { #ifndef BOOST_NO_ANSI_APIS WORD mask; if (::GetStringTypeExA(idx, CT_CTYPE1, &c, 1, &mask) && (mask & C1_UPPER)) return true; return false; #else UINT code_page = get_code_page_for_locale_id(idx); if (code_page == 0) return false; WCHAR wide_c; if (::MultiByteToWideChar(code_page, 0, &c, 1, &wide_c, 1) == 0) return false; WORD mask; if (::GetStringTypeExW(idx, CT_CTYPE1, &wide_c, 1, &mask) && (mask & C1_UPPER)) return true; return false; #endif } inline bool w32_is_upper(wchar_t c, lcid_type idx) { WORD mask; if (::GetStringTypeExW(idx, CT_CTYPE1, &c, 1, &mask) && (mask & C1_UPPER)) return true; return false; } inline void free_module(void* mod) { ::FreeLibrary(static_cast(mod)); } inline cat_type w32_cat_open(const std::string& name) { #ifndef BOOST_NO_ANSI_APIS cat_type result(::LoadLibraryA(name.c_str()), &free_module); return result; #else LPWSTR wide_name = (LPWSTR)_alloca((name.size() + 1) * sizeof(WCHAR)); if (::MultiByteToWideChar(CP_ACP, 0, name.c_str(), name.size(), wide_name, name.size() + 1) == 0) return cat_type(); cat_type result(::LoadLibraryW(wide_name), &free_module); return result; #endif } inline std::string w32_cat_get(const cat_type& cat, lcid_type, int i, const std::string& def) { #ifndef BOOST_NO_ANSI_APIS char buf[256]; if (0 == ::LoadStringA( static_cast(cat.get()), i, buf, 256 )) { return def; } #else WCHAR wbuf[256]; int r = ::LoadStringW( static_cast(cat.get()), i, wbuf, 256 ); if (r == 0) return def; int buf_size = 1 + ::WideCharToMultiByte(CP_ACP, 0, wbuf, r, NULL, 0, NULL, NULL); LPSTR buf = (LPSTR)_alloca(buf_size); if (::WideCharToMultiByte(CP_ACP, 0, wbuf, r, buf, buf_size, NULL, NULL) == 0) return def; // failed conversion. #endif return std::string(buf); } #ifndef BOOST_NO_WREGEX inline std::wstring w32_cat_get(const cat_type& cat, lcid_type, int i, const std::wstring& def) { wchar_t buf[256]; if (0 == ::LoadStringW( static_cast(cat.get()), i, buf, 256 )) { return def; } return std::wstring(buf); } #endif inline std::string w32_transform(lcid_type idx, const char* p1, const char* p2) { #ifndef BOOST_NO_ANSI_APIS int bytes = ::LCMapStringA( idx, // locale identifier LCMAP_SORTKEY, // mapping transformation type p1, // source string static_cast(p2 - p1), // number of characters in source string 0, // destination buffer 0 // size of destination buffer ); if (!bytes) return std::string(p1, p2); std::string result(++bytes, '\0'); bytes = ::LCMapStringA( idx, // locale identifier LCMAP_SORTKEY, // mapping transformation type p1, // source string static_cast(p2 - p1), // number of characters in source string &*result.begin(), // destination buffer bytes // size of destination buffer ); #else UINT code_page = get_code_page_for_locale_id(idx); if (code_page == 0) return std::string(p1, p2); int src_len = static_cast(p2 - p1); LPWSTR wide_p1 = (LPWSTR)_alloca((src_len + 1) * 2); if (::MultiByteToWideChar(code_page, 0, p1, src_len, wide_p1, src_len + 1) == 0) return std::string(p1, p2); int bytes = ::LCMapStringW( idx, // locale identifier LCMAP_SORTKEY, // mapping transformation type wide_p1, // source string src_len, // number of characters in source string 0, // destination buffer 0 // size of destination buffer ); if (!bytes) return std::string(p1, p2); std::string result(++bytes, '\0'); bytes = ::LCMapStringW( idx, // locale identifier LCMAP_SORTKEY, // mapping transformation type wide_p1, // source string src_len, // number of characters in source string (LPWSTR) & *result.begin(), // destination buffer bytes // size of destination buffer ); #endif if (bytes > static_cast(result.size())) return std::string(p1, p2); while (result.size() && result[result.size() - 1] == '\0') { result.erase(result.size() - 1); } return result; } #ifndef BOOST_NO_WREGEX inline std::wstring w32_transform(lcid_type idx, const wchar_t* p1, const wchar_t* p2) { int bytes = ::LCMapStringW( idx, // locale identifier LCMAP_SORTKEY, // mapping transformation type p1, // source string static_cast(p2 - p1), // number of characters in source string 0, // destination buffer 0 // size of destination buffer ); if (!bytes) return std::wstring(p1, p2); std::string result(++bytes, '\0'); bytes = ::LCMapStringW( idx, // locale identifier LCMAP_SORTKEY, // mapping transformation type p1, // source string static_cast(p2 - p1), // number of characters in source string reinterpret_cast(&*result.begin()), // destination buffer *of bytes* bytes // size of destination buffer ); if (bytes > static_cast(result.size())) return std::wstring(p1, p2); while (result.size() && result[result.size() - 1] == L'\0') { result.erase(result.size() - 1); } std::wstring r2; for (std::string::size_type i = 0; i < result.size(); ++i) r2.append(1, static_cast(static_cast(result[i]))); return r2; } #endif inline char w32_tolower(char c, lcid_type idx) { char result[2]; #ifndef BOOST_NO_ANSI_APIS int b = ::LCMapStringA( idx, // locale identifier LCMAP_LOWERCASE, // mapping transformation type &c, // source string 1, // number of characters in source string result, // destination buffer 1); // size of destination buffer if (b == 0) return c; #else UINT code_page = get_code_page_for_locale_id(idx); if (code_page == 0) return c; WCHAR wide_c; if (::MultiByteToWideChar(code_page, 0, &c, 1, &wide_c, 1) == 0) return c; WCHAR wide_result; int b = ::LCMapStringW( idx, // locale identifier LCMAP_LOWERCASE, // mapping transformation type &wide_c, // source string 1, // number of characters in source string &wide_result, // destination buffer 1); // size of destination buffer if (b == 0) return c; if (::WideCharToMultiByte(code_page, 0, &wide_result, 1, result, 2, NULL, NULL) == 0) return c; // No single byte lower case equivalent available #endif return result[0]; } #ifndef BOOST_NO_WREGEX inline wchar_t w32_tolower(wchar_t c, lcid_type idx) { wchar_t result[2]; int b = ::LCMapStringW( idx, // locale identifier LCMAP_LOWERCASE, // mapping transformation type &c, // source string 1, // number of characters in source string result, // destination buffer 1); // size of destination buffer if (b == 0) return c; return result[0]; } #endif inline char w32_toupper(char c, lcid_type idx) { char result[2]; #ifndef BOOST_NO_ANSI_APIS int b = ::LCMapStringA( idx, // locale identifier LCMAP_UPPERCASE, // mapping transformation type &c, // source string 1, // number of characters in source string result, // destination buffer 1); // size of destination buffer if (b == 0) return c; #else UINT code_page = get_code_page_for_locale_id(idx); if (code_page == 0) return c; WCHAR wide_c; if (::MultiByteToWideChar(code_page, 0, &c, 1, &wide_c, 1) == 0) return c; WCHAR wide_result; int b = ::LCMapStringW( idx, // locale identifier LCMAP_UPPERCASE, // mapping transformation type &wide_c, // source string 1, // number of characters in source string &wide_result, // destination buffer 1); // size of destination buffer if (b == 0) return c; if (::WideCharToMultiByte(code_page, 0, &wide_result, 1, result, 2, NULL, NULL) == 0) return c; // No single byte upper case equivalent available. #endif return result[0]; } #ifndef BOOST_NO_WREGEX inline wchar_t w32_toupper(wchar_t c, lcid_type idx) { wchar_t result[2]; int b = ::LCMapStringW( idx, // locale identifier LCMAP_UPPERCASE, // mapping transformation type &c, // source string 1, // number of characters in source string result, // destination buffer 1); // size of destination buffer if (b == 0) return c; return result[0]; } #endif inline bool w32_is(lcid_type idx, std::uint32_t m, char c) { WORD mask; #ifndef BOOST_NO_ANSI_APIS if (::GetStringTypeExA(idx, CT_CTYPE1, &c, 1, &mask) && (mask & m & w32_regex_traits_implementation::mask_base)) return true; #else UINT code_page = get_code_page_for_locale_id(idx); if (code_page == 0) return false; WCHAR wide_c; if (::MultiByteToWideChar(code_page, 0, &c, 1, &wide_c, 1) == 0) return false; if (::GetStringTypeExW(idx, CT_CTYPE1, &wide_c, 1, &mask) && (mask & m & w32_regex_traits_implementation::mask_base)) return true; #endif if ((m & w32_regex_traits_implementation::mask_word) && (c == '_')) return true; return false; } #ifndef BOOST_NO_WREGEX inline bool w32_is(lcid_type idx, std::uint32_t m, wchar_t c) { WORD mask; if (::GetStringTypeExW(idx, CT_CTYPE1, &c, 1, &mask) && (mask & m & w32_regex_traits_implementation::mask_base)) return true; if ((m & w32_regex_traits_implementation::mask_word) && (c == '_')) return true; if ((m & w32_regex_traits_implementation::mask_unicode) && (c > 0xff)) return true; return false; } #endif } // BOOST_REGEX_DETAIL_NS } // boost #ifdef BOOST_REGEX_MSVC #pragma warning(pop) #endif #endif // BOOST_REGEX_NO_WIN32_LOCALE #endif