// Locale support -*- C++ -*- // Copyright (C) 1997, 1998, 1999, 2000, 2001, 2002 // 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 2, 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. // You should have received a copy of the GNU General Public License along // with this library; see the file COPYING. If not, write to the Free // Software Foundation, 59 Temple Place - Suite 330, Boston, MA 02111-1307, // USA. // As a special exception, you may use this file as part of a free software // library without restriction. Specifically, if other files instantiate // templates or use macros or inline functions from this file, or you compile // this file and link it with other files to produce an executable, this // file does not by itself cause the resulting executable to be covered by // the GNU General Public License. This exception does not however // invalidate any other reasons why the executable file might be covered by // the GNU General Public License. // Warning: this file is not meant for user inclusion. Use . #ifndef _CPP_BITS_LOCFACETS_TCC #define _CPP_BITS_LOCFACETS_TCC 1 #include #include // For localeconv #include // For strof, strtold #include // For ceil #include // For isspace #include // For numeric_limits #include // For auto_ptr #include #include #include // For bad_cast. namespace std { template locale locale::combine(const locale& __other) const { _Impl* __tmp = new _Impl(*_M_impl, 1); __tmp->_M_replace_facet(__other._M_impl, &_Facet::id); return locale(__tmp); } template bool locale::operator()(const basic_string<_CharT, _Traits, _Alloc>& __s1, const basic_string<_CharT, _Traits, _Alloc>& __s2) const { typedef std::collate<_CharT> __collate_type; const __collate_type& __collate = use_facet<__collate_type>(*this); return (__collate.compare(__s1.data(), __s1.data() + __s1.length(), __s2.data(), __s2.data() + __s2.length()) < 0); } template const _Facet& use_facet(const locale& __loc) { size_t __i = _Facet::id._M_index; locale::_Impl::__vec_facet* __facet = __loc._M_impl->_M_facets; const locale::facet* __fp = (*__facet)[__i]; if (__fp == 0 || __i >= __facet->size()) __throw_bad_cast(); return static_cast(*__fp); } template bool has_facet(const locale& __loc) throw() { size_t __i = _Facet::id._M_index; locale::_Impl::__vec_facet* __facet = __loc._M_impl->_M_facets; return (__i < __facet->size() && (*__facet)[__i] != 0); } // Stage 1: Determine a conversion specifier. template _InIter num_get<_CharT, _InIter>:: _M_extract_float(_InIter __beg, _InIter __end, ios_base& __io, ios_base::iostate& __err, string& __xtrc) const { const locale __loc = __io.getloc(); const ctype<_CharT>& __ctype = use_facet >(__loc); const numpunct<_CharT>& __np = use_facet >(__loc); // First check for sign. const char_type __plus = __ctype.widen('+'); const char_type __minus = __ctype.widen('-'); int __pos = 0; char_type __c = *__beg; if ((__c == __plus || __c == __minus) && __beg != __end) { __xtrc += __ctype.narrow(__c, char()); ++__pos; __c = *(++__beg); } // Next, strip leading zeros. const char_type __zero = __ctype.widen(_S_atoms[_M_zero]); bool __found_zero = false; while (__c == __zero && __beg != __end) { __c = *(++__beg); __found_zero = true; } if (__found_zero) { __xtrc += _S_atoms[_M_zero]; ++__pos; } // Only need acceptable digits for floating point numbers. const size_t __len = _M_E - _M_zero + 1; char_type __watoms[__len]; __ctype.widen(_S_atoms, _S_atoms + __len, __watoms); bool __found_dec = false; bool __found_sci = false; const char_type __dec = __np.decimal_point(); string __found_grouping; const string __grouping = __np.grouping(); bool __check_grouping = __grouping.size(); int __sep_pos = 0; const char_type __sep = __np.thousands_sep(); while (__beg != __end) { // Only look in digits. typedef char_traits<_CharT> __traits_type; const char_type* __p = __traits_type::find(__watoms, 10, __c); // NB: strchr returns true for __c == 0x0 if (__p && __c) { // Try first for acceptable digit; record it if found. ++__pos; __xtrc += _S_atoms[__p - __watoms]; ++__sep_pos; __c = *(++__beg); } else if (__c == __sep && __check_grouping && !__found_dec) { // NB: Thousands separator at the beginning of a string // is a no-no, as is two consecutive thousands separators. if (__sep_pos) { __found_grouping += static_cast(__sep_pos); __sep_pos = 0; __c = *(++__beg); } else { __err |= ios_base::failbit; break; } } else if (__c == __dec && !__found_dec) { __found_grouping += static_cast(__sep_pos); ++__pos; __xtrc += '.'; __c = *(++__beg); __found_dec = true; } else if ((__c == __watoms[_M_e] || __c == __watoms[_M_E]) && !__found_sci && __pos) { // Scientific notation. ++__pos; __xtrc += __ctype.narrow(__c, char()); __c = *(++__beg); // Remove optional plus or minus sign, if they exist. if (__c == __plus || __c == __minus) { ++__pos; __xtrc += __ctype.narrow(__c, char()); __c = *(++__beg); } __found_sci = true; } else // Not a valid input item. break; } // Digit grouping is checked. If grouping and found_grouping don't // match, then get very very upset, and set failbit. if (__check_grouping && __found_grouping.size()) { // Add the ending grouping if a decimal wasn't found. if (!__found_dec) __found_grouping += static_cast(__sep_pos); if (!__verify_grouping(__grouping, __found_grouping)) __err |= ios_base::failbit; } // Finish up __xtrc += char(); if (__beg == __end) __err |= ios_base::eofbit; return __beg; } // Stage 1: Determine a conversion specifier. template _InIter num_get<_CharT, _InIter>:: _M_extract_int(_InIter __beg, _InIter __end, ios_base& __io, ios_base::iostate& __err, char* __xtrc, int __max, int& __base) const { const locale __loc = __io.getloc(); const ctype<_CharT>& __ctype = use_facet >(__loc); const numpunct<_CharT>& __np = use_facet >(__loc); // NB: Iff __basefield == 0, this can change based on contents. ios_base::fmtflags __basefield = __io.flags() & ios_base::basefield; if (__basefield == ios_base::oct) __base = 8; else if (__basefield == ios_base::hex) __base = 16; else __base = 10; // Check first for sign. int __pos = 0; char_type __c = *__beg; if ((__c == __ctype.widen('+') || __c == __ctype.widen('-')) && __beg != __end) { __xtrc[__pos++] = __ctype.narrow(__c, char()); __c = *(++__beg); } // Next, strip leading zeros and check required digits for base formats. const char_type __zero = __ctype.widen(_S_atoms[_M_zero]); const char_type __x = __ctype.widen('x'); const char_type __X = __ctype.widen('X'); if (__base == 10) { bool __found_zero = false; while (__c == __zero && __beg != __end) { __c = *(++__beg); __found_zero = true; } if (__found_zero) { __xtrc[__pos++] = _S_atoms[_M_zero]; if (__basefield == 0) { if ((__c == __x || __c == __X) && __beg != __end) { __xtrc[__pos++] = __ctype.narrow(__c, char()); __c = *(++__beg); __base = 16; } else __base = 8; } } } else if (__base == 16) { if (__c == __zero && __beg != __end) { __xtrc[__pos++] = _S_atoms[_M_zero]; __c = *(++__beg); if ((__c == __x || __c == __X) && __beg != __end) { __xtrc[__pos++] = __ctype.narrow(__c, char()); __c = *(++__beg); } } } // At this point, base is determined. If not hex, only allow // base digits as valid input. size_t __len; if (__base == 16) __len = _M_size; else __len = __base; // Figure out the maximum number of digits that can be extracted // for the given type, using the determined base. int __max_digits; if (__base == 16) __max_digits = static_cast(ceil(__max * _S_scale_hex)); else if (__base == 8) __max_digits = static_cast(ceil(__max * _S_scale_oct)); else __max_digits = __max; // Add in what's already been extracted. __max_digits += __pos; // Extract. char_type __watoms[_M_size]; __ctype.widen(_S_atoms, _S_atoms + __len, __watoms); string __found_grouping; const string __grouping = __np.grouping(); bool __check_grouping = __grouping.size() && __base == 10; int __sep_pos = 0; const char_type __sep = __np.thousands_sep(); while (__beg != __end && __pos <= __max_digits) { typedef char_traits<_CharT> __traits_type; const char_type* __p = __traits_type::find(__watoms, __len, __c); // NB: strchr returns true for __c == 0x0 if (__p && __c) { // Try first for acceptable digit; record it if found. __xtrc[__pos++] = _S_atoms[__p - __watoms]; ++__sep_pos; __c = *(++__beg); } else if (__c == __sep && __check_grouping) { // NB: Thousands separator at the beginning of a string // is a no-no, as is two consecutive thousands separators. if (__sep_pos) { __found_grouping += static_cast(__sep_pos); __sep_pos = 0; __c = *(++__beg); } else { __err |= ios_base::failbit; break; } } else // Not a valid input item. break; } // If one more than the maximum number of digits is extracted. if (__pos > __max_digits) __err |= ios_base::failbit; // Digit grouping is checked. If grouping and found_grouping don't // match, then get very very upset, and set failbit. if (__check_grouping && __found_grouping.size()) { // Add the ending grouping. __found_grouping += static_cast(__sep_pos); if (!__verify_grouping(__grouping, __found_grouping)) __err |= ios_base::failbit; } // Finish up __xtrc[__pos] = char(); if (__beg == __end) __err |= ios_base::eofbit; return __beg; } #ifdef _GLIBCPP_RESOLVE_LIB_DEFECTS //17. Bad bool parsing template _InIter num_get<_CharT, _InIter>:: do_get(iter_type __beg, iter_type __end, ios_base& __io, ios_base::iostate& __err, bool& __v) const { // Parse bool values as unsigned long if (!(__io.flags() & ios_base::boolalpha)) { // NB: We can't just call do_get(long) here, as it might // refer to a derived class. // Assuming leading zeros eliminated, thus the size of 32 for // integral types char __xtrc[32]; int __base; // According to 18.2.1.2.9, digits10 is "Number of base 10 digits // that can be represented without change" so we have to add 1 to it // in order to obtain the max number of digits. The same for the // other do_get for integral types below. __beg = _M_extract_int(__beg, __end, __io, __err, __xtrc, numeric_limits::digits10 + 1, __base); unsigned long __ul; __convert_to_v(__xtrc, __ul, __err, _S_c_locale, __base); if (!(__err & ios_base::failbit) && __ul <= 1) __v = __ul; else __err |= ios_base::failbit; } // Parse bool values as alphanumeric else { locale __loc = __io.getloc(); const numpunct<_CharT>& __np = use_facet >(__loc); const char_type* __true = __np.truename().c_str(); const char_type* __false = __np.falsename().c_str(); const size_t __truen = __np.truename().size() - 1; const size_t __falsen = __np.falsename().size() - 1; for (size_t __n = 0; __beg != __end; ++__n) { char_type __c = *__beg++; bool __testf = __n <= __falsen ? __c == __false[__n] : false; bool __testt = __n <= __truen ? __c == __true[__n] : false; if (!(__testf || __testt)) { __err |= ios_base::failbit; break; } else if (__testf && __n == __falsen) { __v = 0; break; } else if (__testt && __n == __truen) { __v = 1; break; } } if (__beg == __end) __err |= ios_base::eofbit; } return __beg; } #endif template _InIter num_get<_CharT, _InIter>:: do_get(iter_type __beg, iter_type __end, ios_base& __io, ios_base::iostate& __err, long& __v) const { // Assuming leading zeros eliminated, thus the size of 32 for // integral types. char __xtrc[32]; int __base; __beg = _M_extract_int(__beg, __end, __io, __err, __xtrc, numeric_limits::digits10 + 1, __base); __convert_to_v(__xtrc, __v, __err, _S_c_locale, __base); return __beg; } template _InIter num_get<_CharT, _InIter>:: do_get(iter_type __beg, iter_type __end, ios_base& __io, ios_base::iostate& __err, unsigned short& __v) const { // Assuming leading zeros eliminated, thus the size of 32 for // integral types. char __xtrc[32]; int __base; __beg = _M_extract_int(__beg, __end, __io, __err, __xtrc, numeric_limits::digits10 + 1, __base); unsigned long __ul; __convert_to_v(__xtrc, __ul, __err, _S_c_locale, __base); if (!(__err & ios_base::failbit) && __ul <= USHRT_MAX) __v = static_cast(__ul); else __err |= ios_base::failbit; return __beg; } template _InIter num_get<_CharT, _InIter>:: do_get(iter_type __beg, iter_type __end, ios_base& __io, ios_base::iostate& __err, unsigned int& __v) const { // Assuming leading zeros eliminated, thus the size of 32 for // integral types. char __xtrc[32]; int __base; __beg = _M_extract_int(__beg, __end, __io, __err, __xtrc, numeric_limits::digits10 + 1, __base); unsigned long __ul; __convert_to_v(__xtrc, __ul, __err, _S_c_locale, __base); if (!(__err & ios_base::failbit) && __ul <= UINT_MAX) __v = static_cast(__ul); else __err |= ios_base::failbit; return __beg; } template _InIter num_get<_CharT, _InIter>:: do_get(iter_type __beg, iter_type __end, ios_base& __io, ios_base::iostate& __err, unsigned long& __v) const { // Assuming leading zeros eliminated, thus the size of 32 for // integral types. char __xtrc[32]; int __base; __beg = _M_extract_int(__beg, __end, __io, __err, __xtrc, numeric_limits::digits10 + 1, __base); __convert_to_v(__xtrc, __v, __err, _S_c_locale, __base); return __beg; } #ifdef _GLIBCPP_USE_LONG_LONG template _InIter num_get<_CharT, _InIter>:: do_get(iter_type __beg, iter_type __end, ios_base& __io, ios_base::iostate& __err, long long& __v) const { // Assuming leading zeros eliminated, thus the size of 32 for // integral types. char __xtrc[32]; int __base; __beg = _M_extract_int(__beg, __end, __io, __err, __xtrc, numeric_limits::digits10 + 1, __base); __convert_to_v(__xtrc, __v, __err, _S_c_locale, __base); return __beg; } template _InIter num_get<_CharT, _InIter>:: do_get(iter_type __beg, iter_type __end, ios_base& __io, ios_base::iostate& __err, unsigned long long& __v) const { // Assuming leading zeros eliminated, thus the size of 32 for // integral types. char __xtrc[32]; int __base; __beg = _M_extract_int(__beg, __end, __io, __err, __xtrc, numeric_limits::digits10 + 1, __base); __convert_to_v(__xtrc, __v, __err, _S_c_locale, __base); return __beg; } #endif template _InIter num_get<_CharT, _InIter>:: do_get(iter_type __beg, iter_type __end, ios_base& __io, ios_base::iostate& __err, float& __v) const { string __xtrc; __xtrc.reserve(32); __beg = _M_extract_float(__beg, __end, __io, __err, __xtrc); __convert_to_v(__xtrc.c_str(), __v, __err, _S_c_locale); return __beg; } template _InIter num_get<_CharT, _InIter>:: do_get(iter_type __beg, iter_type __end, ios_base& __io, ios_base::iostate& __err, double& __v) const { string __xtrc; __xtrc.reserve(32); __beg = _M_extract_float(__beg, __end, __io, __err, __xtrc); __convert_to_v(__xtrc.c_str(), __v, __err, _S_c_locale); return __beg; } template _InIter num_get<_CharT, _InIter>:: do_get(iter_type __beg, iter_type __end, ios_base& __io, ios_base::iostate& __err, long double& __v) const { string __xtrc; __xtrc.reserve(32); __beg = _M_extract_float(__beg, __end, __io, __err, __xtrc); __convert_to_v(__xtrc.c_str(), __v, __err, _S_c_locale); return __beg; } template _InIter num_get<_CharT, _InIter>:: do_get(iter_type __beg, iter_type __end, ios_base& __io, ios_base::iostate& __err, void*& __v) const { // Prepare for hex formatted input typedef ios_base::fmtflags fmtflags; fmtflags __fmt = __io.flags(); fmtflags __fmtmask = ~(ios_base::showpos | ios_base::basefield | ios_base::uppercase | ios_base::internal); __io.flags(__fmt & __fmtmask | (ios_base::hex | ios_base::showbase)); // Assuming leading zeros eliminated, thus the size of 32 for // integral types. char __xtrc[32]; int __base; __beg = _M_extract_int(__beg, __end, __io, __err, __xtrc, numeric_limits::digits10 + 1, __base); // Reset from hex formatted input __io.flags(__fmt); unsigned long __ul; __convert_to_v(__xtrc, __ul, __err, _S_c_locale, __base); if (!(__err & ios_base::failbit)) __v = reinterpret_cast(__ul); else __err |= ios_base::failbit; return __beg; } // The following code uses sprintf() to convert floating point // values for insertion into a stream. An optimization would be to // replace sprintf() with code that works directly on a wide buffer // and then use __pad to do the padding. It would be good // to replace sprintf() anyway to avoid accidental buffer overruns // and to gain back the efficiency that C++ provides by knowing up // front the type of the values to insert. This implementation // follows the C++ standard fairly directly as outlined in 22.2.2.2 // [lib.locale.num.put] template template _OutIter num_put<_CharT, _OutIter>:: _M_convert_float(_OutIter __s, ios_base& __io, _CharT __fill, char __mod, _ValueT __v) const { const int __max_digits = numeric_limits<_ValueT>::digits10; streamsize __prec = __io.precision(); // Protect against sprintf() buffer overflows. if (__prec > static_cast(__max_digits)) __prec = static_cast(__max_digits); // Long enough for the max format spec. char __fbuf[16]; // Consider the possibility of long ios_base::fixed outputs const bool __fixed = __io.flags() & ios_base::fixed; const int __max_exp = numeric_limits<_ValueT>::max_exponent10; // ios_base::fixed outputs may need up to __max_exp+1 chars // for the integer part + up to __max_digits chars for the // fractional part + 3 chars for sign, decimal point, '\0'. On // the other hand, for non-fixed outputs __max_digits*3 chars // are largely sufficient. const int __cs_size = __fixed ? __max_exp + __max_digits + 4 : __max_digits * 3; char* __cs = static_cast(__builtin_alloca(__cs_size)); int __len; // [22.2.2.2.2] Stage 1, numeric conversion to character. if (_S_format_float(__io, __fbuf, __mod, __prec)) __len = __convert_from_v(__cs, __fbuf, __v, _S_c_locale, __prec); else __len = __convert_from_v(__cs, __fbuf, __v, _S_c_locale); return _M_widen_float(__s, __io, __fill, __cs, __len); } template template _OutIter num_put<_CharT, _OutIter>:: _M_convert_int(_OutIter __s, ios_base& __io, _CharT __fill, char __mod, char __modl, _ValueT __v) const { // [22.2.2.2.2] Stage 1, numeric conversion to character. // Leave room for "+/-," "0x," and commas. This size is // arbitrary, but should work. char __cs[64]; // Long enough for the max format spec. char __fbuf[16]; _S_format_int(__io, __fbuf, __mod, __modl); int __len = __convert_from_v(__cs, __fbuf, __v, _S_c_locale); return _M_widen_int(__s, __io, __fill, __cs, __len); } template _OutIter num_put<_CharT, _OutIter>:: _M_widen_float(_OutIter __s, ios_base& __io, _CharT __fill, char* __cs, int __len) const { // [22.2.2.2.2] Stage 2, convert to char_type, using correct // numpunct.decimal_point() values for '.' and adding grouping. const locale __loc = __io.getloc(); const ctype<_CharT>& __ctype = use_facet >(__loc); _CharT* __ws = static_cast<_CharT*>(__builtin_alloca(sizeof(_CharT) * __len)); // Grouping can add (almost) as many separators as the number of // digits, but no more. _CharT* __ws2 = static_cast<_CharT*>(__builtin_alloca(sizeof(_CharT) * __len * 2)); __ctype.widen(__cs, __cs + __len, __ws); // Replace decimal point. const _CharT* __p; const numpunct<_CharT>& __np = use_facet >(__loc); if (__p = char_traits<_CharT>::find(__ws, __len, __ctype.widen('.'))) __ws[__p - __ws] = __np.decimal_point(); #ifdef _GLIBCPP_RESOLVE_LIB_DEFECTS //282. What types does numpunct grouping refer to? // Add grouping, if necessary. const string __grouping = __np.grouping(); ios_base::fmtflags __basefield = __io.flags() & ios_base::basefield; if (__grouping.size()) { _CharT* __p2; int __declen = __p ? __p - __ws : __len; __p2 = __add_grouping(__ws2, __np.thousands_sep(), __grouping.c_str(), __grouping.c_str() + __grouping.size(), __ws, __ws + __declen); int __newlen = __p2 - __ws2; // Tack on decimal part. if (__p) { char_traits<_CharT>::copy(__p2, __p, __len - __declen); __newlen += __len - __declen; } // Switch strings, establish correct new length. __ws = __ws2; __len = __newlen; } #endif return _M_insert(__s, __io, __fill, __ws, __len); } template _OutIter num_put<_CharT, _OutIter>:: _M_widen_int(_OutIter __s, ios_base& __io, _CharT __fill, char* __cs, int __len) const { // [22.2.2.2.2] Stage 2, convert to char_type, using correct // numpunct.decimal_point() values for '.' and adding grouping. const locale __loc = __io.getloc(); const ctype<_CharT>& __ctype = use_facet >(__loc); _CharT* __ws = static_cast<_CharT*>(__builtin_alloca(sizeof(_CharT) * __len)); // Grouping can add (almost) as many separators as the number of // digits, but no more. _CharT* __ws2 = static_cast<_CharT*>(__builtin_alloca(sizeof(_CharT) * __len * 2)); __ctype.widen(__cs, __cs + __len, __ws); // Add grouping, if necessary. const numpunct<_CharT>& __np = use_facet >(__loc); const string __grouping = __np.grouping(); ios_base::fmtflags __basefield = __io.flags() & ios_base::basefield; bool __dec = __basefield != ios_base::oct && __basefield != ios_base::hex; if (__grouping.size() && __dec) { _CharT* __p; __p = __add_grouping(__ws2, __np.thousands_sep(), __grouping.c_str(), __grouping.c_str() + __grouping.size(), __ws, __ws + __len); __len = __p - __ws2; // Switch strings. __ws = __ws2; } return _M_insert(__s, __io, __fill, __ws, __len); } // For use by integer and floating-point types after they have been // converted into a char_type string. template _OutIter num_put<_CharT, _OutIter>:: _M_insert(_OutIter __s, ios_base& __io, _CharT __fill, const _CharT* __ws, int __len) const { // [22.2.2.2.2] Stage 3. streamsize __w = __io.width(); _CharT* __ws2 = static_cast<_CharT*>(__builtin_alloca(sizeof(_CharT) * __w)); if (__w > static_cast(__len)) { __pad(__io, __fill, __ws2, __ws, __w, __len, true); __len = static_cast(__w); // Switch strings. __ws = __ws2; } __io.width(0); // [22.2.2.2.2] Stage 4. // Write resulting, fully-formatted string to output iterator. for (int __j = 0; __j < __len; ++__j, ++__s) *__s = __ws[__j]; return __s; } template _OutIter num_put<_CharT, _OutIter>:: do_put(iter_type __s, ios_base& __io, char_type __fill, bool __v) const { ios_base::fmtflags __flags = __io.flags(); if ((__flags & ios_base::boolalpha) == 0) { unsigned long __uv = __v; __s = _M_convert_int(__s, __io, __fill, 'u', char_type(), __uv); } else { locale __loc = __io.getloc(); const numpunct<_CharT>& __np = use_facet >(__loc); const char_type* __ws; int __len; if (__v) { __ws = __np.truename().c_str(); __len = __np.truename().size(); } else { __ws = __np.falsename().c_str(); __len = __np.falsename().size(); } __s = _M_insert(__s, __io, __fill, __ws, __len); } return __s; } template _OutIter num_put<_CharT, _OutIter>:: do_put(iter_type __s, ios_base& __io, char_type __fill, long __v) const { return _M_convert_int(__s, __io, __fill, 'd', char_type(), __v); } template _OutIter num_put<_CharT, _OutIter>:: do_put(iter_type __s, ios_base& __io, char_type __fill, unsigned long __v) const { return _M_convert_int(__s, __io, __fill, 'u', char_type(), __v); } #ifdef _GLIBCPP_USE_LONG_LONG template _OutIter num_put<_CharT, _OutIter>:: do_put(iter_type __s, ios_base& __b, char_type __fill, long long __v) const { return _M_convert_int(__s, __b, __fill, 'd', 'l', __v); } template _OutIter num_put<_CharT, _OutIter>:: do_put(iter_type __s, ios_base& __io, char_type __fill, unsigned long long __v) const { return _M_convert_int(__s, __io, __fill, 'u', 'l', __v); } #endif template _OutIter num_put<_CharT, _OutIter>:: do_put(iter_type __s, ios_base& __io, char_type __fill, double __v) const { return _M_convert_float(__s, __io, __fill, char_type(), __v); } template _OutIter num_put<_CharT, _OutIter>:: do_put(iter_type __s, ios_base& __io, char_type __fill, long double __v) const { return _M_convert_float(__s, __io, __fill, 'L', __v); } template _OutIter num_put<_CharT, _OutIter>:: do_put(iter_type __s, ios_base& __io, char_type __fill, const void* __v) const { ios_base::fmtflags __flags = __io.flags(); ios_base::fmtflags __fmt = ~(ios_base::showpos | ios_base::basefield | ios_base::uppercase | ios_base::internal); __io.flags(__flags & __fmt | (ios_base::hex | ios_base::showbase)); try { __s = _M_convert_int(__s, __io, __fill, 'u', char_type(), reinterpret_cast(__v)); __io.flags(__flags); } catch (...) { __io.flags(__flags); __throw_exception_again; } return __s; } template _InIter money_get<_CharT, _InIter>:: do_get(iter_type __beg, iter_type __end, bool __intl, ios_base& __io, ios_base::iostate& __err, long double& __units) const { string_type __str; __beg = this->do_get(__beg, __end, __intl, __io, __err, __str); const int __n = numeric_limits::digits10; char* __cs = static_cast(__builtin_alloca(sizeof(char) * __n)); const locale __loc = __io.getloc(); const ctype<_CharT>& __ctype = use_facet >(__loc); const _CharT* __wcs = __str.c_str(); __ctype.narrow(__wcs, __wcs + __str.size() + 1, char(), __cs); __convert_to_v(__cs, __units, __err, _S_c_locale); return __beg; } template _InIter money_get<_CharT, _InIter>:: do_get(iter_type __beg, iter_type __end, bool __intl, ios_base& __io, ios_base::iostate& __err, string_type& __units) const { // These contortions are quite unfortunate. typedef moneypunct<_CharT, true> __money_true; typedef moneypunct<_CharT, false> __money_false; typedef money_base::part part; typedef typename string_type::size_type size_type; const locale __loc = __io.getloc(); const __money_true& __mpt = use_facet<__money_true>(__loc); const __money_false& __mpf = use_facet<__money_false>(__loc); const ctype<_CharT>& __ctype = use_facet >(__loc); const money_base::pattern __p = __intl ? __mpt.neg_format() : __mpf.neg_format(); const string_type __pos_sign =__intl ? __mpt.positive_sign() : __mpf.positive_sign(); const string_type __neg_sign =__intl ? __mpt.negative_sign() : __mpf.negative_sign(); const char_type __d = __intl ? __mpt.decimal_point() : __mpf.decimal_point(); const char_type __sep = __intl ? __mpt.thousands_sep() : __mpf.thousands_sep(); const string __grouping = __intl ? __mpt.grouping() : __mpf.grouping(); // Set to deduced positive or negative sign, depending. string_type __sign; // String of grouping info from thousands_sep plucked from __units. string __grouping_tmp; // Marker for thousands_sep position. int __sep_pos = 0; // If input iterator is in a valid state. bool __testvalid = true; // Flag marking when a decimal point is found. bool __testdecfound = false; char_type __c = *__beg; char_type __eof = static_cast(char_traits::eof()); for (int __i = 0; __beg != __end && __i < 4 && __testvalid; ++__i) { part __which = static_cast(__p.field[__i]); switch (__which) { case money_base::symbol: if (__io.flags() & ios_base::showbase) { // Symbol is required. const string_type __symbol = __intl ? __mpt.curr_symbol() : __mpf.curr_symbol(); size_type __len = __symbol.size(); size_type __i = 0; while (__beg != __end && __i < __len && __symbol[__i] == __c) { __c = *(++__beg); ++__i; } if (__i != __len) __testvalid = false; } break; case money_base::sign: // Sign might not exist, or be more than one character long. if (__pos_sign.size() && __neg_sign.size()) { // Sign is mandatory. if (__c == __pos_sign[0]) { __sign = __pos_sign; __c = *(++__beg); } else if (__c == __neg_sign[0]) { __sign = __neg_sign; __c = *(++__beg); } else __testvalid = false; } else if (__pos_sign.size() && __c == __pos_sign[0]) { __sign = __pos_sign; __c = *(++__beg); } else if (__neg_sign.size() && __c == __neg_sign[0]) { __sign = __neg_sign; __c = *(++__beg); } break; case money_base::value: // Extract digits, remove and stash away the // grouping of found thousands separators. while (__beg != __end && (__ctype.is(ctype_base::digit, __c) || (__c == __d && !__testdecfound) || __c == __sep)) { if (__c == __d) { __grouping_tmp += static_cast(__sep_pos); __sep_pos = 0; __testdecfound = true; } else if (__c == __sep) { if (__grouping.size()) { // Mark position for later analysis. __grouping_tmp += static_cast(__sep_pos); __sep_pos = 0; } else { __testvalid = false; break; } } else { __units += __c; ++__sep_pos; } __c = *(++__beg); } break; case money_base::space: case money_base::none: // Only if not at the end of the pattern. if (__i != 3) while (__beg != __end && __ctype.is(ctype_base::space, __c)) __c = *(++__beg); break; } } // Need to get the rest of the sign characters, if they exist. if (__sign.size() > 1) { size_type __len = __sign.size(); size_type __i = 1; for (; __c != __eof && __i < __len; ++__i) while (__beg != __end && __c != __sign[__i]) __c = *(++__beg); if (__i != __len) __testvalid = false; } // Strip leading zeros. while (__units[0] == __ctype.widen('0')) __units.erase(__units.begin()); if (__sign.size() && __sign == __neg_sign) __units.insert(__units.begin(), __ctype.widen('-')); // Test for grouping fidelity. if (__grouping.size() && __grouping_tmp.size()) { if (!__verify_grouping(__grouping, __grouping_tmp)) __testvalid = false; } // Iff no more characters are available. if (__c == __eof) __err |= ios_base::eofbit; // Iff valid sequence is not recognized. if (!__testvalid || !__units.size()) __err |= ios_base::failbit; return __beg; } template _OutIter money_put<_CharT, _OutIter>:: do_put(iter_type __s, bool __intl, ios_base& __io, char_type __fill, long double __units) const { const locale __loc = __io.getloc(); const ctype<_CharT>& __ctype = use_facet >(__loc); const int __n = numeric_limits::digits10; char* __cs = static_cast(__builtin_alloca(sizeof(char) * __n)); _CharT* __ws = static_cast<_CharT*>(__builtin_alloca(sizeof(_CharT) * __n)); int __len = __convert_from_v(__cs, "%.01Lf", __units, _S_c_locale); __ctype.widen(__cs, __cs + __len, __ws); string_type __digits(__ws); return this->do_put(__s, __intl, __io, __fill, __digits); } template _OutIter money_put<_CharT, _OutIter>:: do_put(iter_type __s, bool __intl, ios_base& __io, char_type __fill, const string_type& __digits) const { typedef typename string_type::size_type size_type; typedef money_base::part part; const locale __loc = __io.getloc(); const size_type __width = static_cast(__io.width()); // These contortions are quite unfortunate. typedef moneypunct<_CharT, true> __money_true; typedef moneypunct<_CharT, false> __money_false; const __money_true& __mpt = use_facet<__money_true>(__loc); const __money_false& __mpf = use_facet<__money_false>(__loc); const ctype<_CharT>& __ctype = use_facet >(__loc); // Determine if negative or positive formats are to be used, and // discard leading negative_sign if it is present. const char_type* __beg = __digits.data(); const char_type* __end = __beg + __digits.size(); money_base::pattern __p; string_type __sign; if (*__beg != __ctype.widen('-')) { __p = __intl ? __mpt.pos_format() : __mpf.pos_format(); __sign =__intl ? __mpt.positive_sign() : __mpf.positive_sign(); } else { __p = __intl ? __mpt.neg_format() : __mpf.neg_format(); __sign =__intl ? __mpt.negative_sign() : __mpf.negative_sign(); ++__beg; } // Look for valid numbers in the current ctype facet within input digits. __end = __ctype.scan_not(ctype_base::digit, __beg, __end); if (__beg != __end) { // Assume valid input, and attempt to format. // Break down input numbers into base components, as follows: // final_value = grouped units + (decimal point) + (digits) string_type __res; string_type __value; const string_type __symbol = __intl ? __mpt.curr_symbol() : __mpf.curr_symbol(); // Deal with decimal point, decimal digits. const int __frac = __intl ? __mpt.frac_digits() : __mpf.frac_digits(); if (__frac > 0) { const char_type __d = __intl ? __mpt.decimal_point() : __mpf.decimal_point(); if (__end - __beg >= __frac) { __value = string_type(__end - __frac, __end); __value.insert(__value.begin(), __d); __end -= __frac; } else { // Have to pad zeros in the decimal position. __value = string_type(__beg, __end); int __paddec = __frac - (__end - __beg); char_type __zero = __ctype.widen('0'); __value.insert(__value.begin(), __paddec, __zero); __value.insert(__value.begin(), __d); __beg = __end; } } // Add thousands separators to non-decimal digits, per // grouping rules. if (__beg != __end) { const string __grouping = __intl ? __mpt.grouping() : __mpf.grouping(); if (__grouping.size()) { const char_type __sep = __intl ? __mpt.thousands_sep() : __mpf.thousands_sep(); const char* __gbeg = __grouping.c_str(); const char* __gend = __gbeg + __grouping.size(); const int __n = numeric_limits::digits10 * 2; _CharT* __ws2 = static_cast<_CharT*>(__builtin_alloca(sizeof(_CharT) * __n)); _CharT* __ws_end = __add_grouping(__ws2, __sep, __gbeg, __gend, __beg, __end); __value.insert(0, __ws2, __ws_end - __ws2); } else __value.insert(0, string_type(__beg, __end)); } // Calculate length of resulting string. ios_base::fmtflags __f = __io.flags() & ios_base::adjustfield; size_type __len = __value.size() + __sign.size(); __len += (__io.flags() & ios_base::showbase) ? __symbol.size() : 0; bool __testipad = __f == ios_base::internal && __len < __width; // Fit formatted digits into the required pattern. for (int __i = 0; __i < 4; ++__i) { part __which = static_cast(__p.field[__i]); switch (__which) { case money_base::symbol: if (__io.flags() & ios_base::showbase) __res += __symbol; break; case money_base::sign: // Sign might not exist, or be more than one // charater long. In that case, add in the rest // below. if (__sign.size()) __res += __sign[0]; break; case money_base::value: __res += __value; break; case money_base::space: // At least one space is required, but if internal // formatting is required, an arbitrary number of // fill spaces will be necessary. if (__testipad) __res += string_type(__width - __len, __fill); else __res += __ctype.widen(' '); break; case money_base::none: if (__testipad) __res += string_type(__width - __len, __fill); break; } } // Special case of multi-part sign parts. if (__sign.size() > 1) __res += string_type(__sign.begin() + 1, __sign.end()); // Pad, if still necessary. __len = __res.size(); if (__width > __len) { if (__f == ios_base::left) // After. __res.append(__width - __len, __fill); else // Before. __res.insert(0, string_type(__width - __len, __fill)); __len = __width; } // Write resulting, fully-formatted string to output iterator. for (size_type __j = 0; __j < __len; ++__j, ++__s) *__s = __res[__j]; } __io.width(0); return __s; } // NB: Not especially useful. Without an ios_base object or some // kind of locale reference, we are left clawing at the air where // the side of the mountain used to be... template time_base::dateorder time_get<_CharT, _InIter>::do_date_order() const { return time_base::no_order; } template void time_get<_CharT, _InIter>:: _M_extract_via_format(iter_type& __beg, iter_type& __end, ios_base& __io, ios_base::iostate& __err, tm* __tm, const _CharT* __format) const { locale __loc = __io.getloc(); __timepunct<_CharT> const& __tp = use_facet<__timepunct<_CharT> >(__loc); const ctype<_CharT>& __ctype = use_facet >(__loc); size_t __len = char_traits<_CharT>::length(__format); for (size_t __i = 0; __beg != __end && __i < __len && !__err; ++__i) { char __c = __format[__i]; if (__c == '%') { // Verify valid formatting code, attempt to extract. __c = __format[++__i]; char __mod = 0; int __mem = 0; if (__c == 'E' || __c == 'O') { __mod = __c; __c = __format[++__i]; } switch (__c) { const char* __cs; _CharT __wcs[10]; case 'a': // Abbreviated weekday name [tm_wday] const char_type* __days1[7]; __tp._M_days_abbreviated(__days1); _M_extract_name(__beg, __end, __tm->tm_wday, __days1, 7, __err); break; case 'A': // Weekday name [tm_wday]. const char_type* __days2[7]; __tp._M_days(__days2); _M_extract_name(__beg, __end, __tm->tm_wday, __days2, 7, __err); break; case 'h': case 'b': // Abbreviated month name [tm_mon] const char_type* __months1[12]; __tp._M_months_abbreviated(__months1); _M_extract_name(__beg, __end, __tm->tm_mon, __months1, 12, __err); break; case 'B': // Month name [tm_mon]. const char_type* __months2[12]; __tp._M_months(__months2); _M_extract_name(__beg, __end, __tm->tm_mon, __months2, 12, __err); break; case 'c': // Default time and date representation. const char_type* __dt[2]; __tp._M_date_time_formats(__dt); _M_extract_via_format(__beg, __end, __io, __err, __tm, __dt[0]); break; case 'd': // Day [01, 31]. [tm_mday] _M_extract_num(__beg, __end, __tm->tm_mday, 1, 31, 2, __ctype, __err); break; case 'D': // Equivalent to %m/%d/%y.[tm_mon, tm_mday, tm_year] __cs = "%m/%d/%y"; __ctype.widen(__cs, __cs + 9, __wcs); _M_extract_via_format(__beg, __end, __io, __err, __tm, __wcs); break; case 'H': // Hour [00, 23]. [tm_hour] _M_extract_num(__beg, __end, __tm->tm_hour, 0, 23, 2, __ctype, __err); break; case 'I': // Hour [01, 12]. [tm_hour] _M_extract_num(__beg, __end, __tm->tm_hour, 1, 12, 2, __ctype, __err); break; case 'm': // Month [01, 12]. [tm_mon] _M_extract_num(__beg, __end, __mem, 1, 12, 2, __ctype, __err); if (!__err) __tm->tm_mon = __mem - 1; break; case 'M': // Minute [00, 59]. [tm_min] _M_extract_num(__beg, __end, __tm->tm_min, 0, 59, 2, __ctype, __err); break; case 'n': if (__ctype.narrow(*__beg, 0) == '\n') ++__beg; else __err |= ios_base::failbit; break; case 'R': // Equivalent to (%H:%M). __cs = "%H:%M"; __ctype.widen(__cs, __cs + 6, __wcs); _M_extract_via_format(__beg, __end, __io, __err, __tm, __wcs); break; case 'S': // Seconds. _M_extract_num(__beg, __end, __tm->tm_sec, 0, 59, 2, __ctype, __err); break; case 't': if (__ctype.narrow(*__beg, 0) == '\t') ++__beg; else __err |= ios_base::failbit; break; case 'T': // Equivalent to (%H:%M:%S). __cs = "%H:%M:%S"; __ctype.widen(__cs, __cs + 9, __wcs); _M_extract_via_format(__beg, __end, __io, __err, __tm, __wcs); break; case 'x': // Locale's date. const char_type* __dates[2]; __tp._M_date_formats(__dates); _M_extract_via_format(__beg, __end, __io, __err, __tm, __dates[0]); break; case 'X': // Locale's time. const char_type* __times[2]; __tp._M_time_formats(__times); _M_extract_via_format(__beg, __end, __io, __err, __tm, __times[0]); break; case 'y': // Two digit year. [tm_year] _M_extract_num(__beg, __end, __tm->tm_year, 0, 99, 2, __ctype, __err); break; case 'Y': // Year [1900). [tm_year] _M_extract_num(__beg, __end, __mem, 0, numeric_limits::max(), 4, __ctype, __err); if (!__err) __tm->tm_year = __mem - 1900; break; case 'Z': // Timezone info. if (__ctype.is(ctype_base::upper, *__beg)) { int __tmp; _M_extract_name(__beg, __end, __tmp, __timepunct<_CharT>::_S_timezones, 14, __err); // GMT requires special effort. char_type __c = *__beg; if (!__err && __tmp == 0 && (__c == __ctype.widen('-') || __c == __ctype.widen('+'))) { _M_extract_num(__beg, __end, __tmp, 0, 23, 2, __ctype, __err); _M_extract_num(__beg, __end, __tmp, 0, 59, 2, __ctype, __err); } } else __err |= ios_base::failbit; break; default: // Not recognized. __err |= ios_base::failbit; } } else { // Verify format and input match, extract and discard. if (__c == __ctype.narrow(*__beg, 0)) ++__beg; else __err |= ios_base::failbit; } } } template void time_get<_CharT, _InIter>:: _M_extract_num(iter_type& __beg, iter_type& __end, int& __member, int __min, int __max, size_t __len, const ctype<_CharT>& __ctype, ios_base::iostate& __err) const { size_t __i = 0; string __digits; bool __testvalid = true; char_type __c = *__beg; while (__beg != __end && __i < __len && __ctype.is(ctype_base::digit, __c)) { __digits += __ctype.narrow(__c, 0); __c = *(++__beg); ++__i; } if (__i == __len) { int __value = atoi(__digits.c_str()); if (__min <= __value && __value <= __max) __member = __value; else __testvalid = false; } else __testvalid = false; if (!__testvalid) __err |= ios_base::failbit; } // Assumptions: // All elements in __names are unique. template void time_get<_CharT, _InIter>:: _M_extract_name(iter_type& __beg, iter_type& __end, int& __member, const _CharT** __names, size_t __indexlen, ios_base::iostate& __err) const { typedef char_traits __traits_type; int* __matches = static_cast(__builtin_alloca(sizeof(int) * __indexlen)); size_t __nmatches = 0; size_t __pos = 0; bool __testvalid = true; const char_type* __name; char_type __c = *__beg; // Look for initial matches. for (size_t __i1 = 0; __i1 < __indexlen; ++__i1) if (__c == __names[__i1][0]) __matches[__nmatches++] = __i1; while(__nmatches > 1) { // Find smallest matching string. size_t __minlen = 10; for (size_t __i2 = 0; __i2 < __nmatches; ++__i2) __minlen = min(__minlen, __traits_type::length(__names[__matches[__i2]])); if (__pos < __minlen && __beg != __end) { ++__pos; __c = *(++__beg); for (size_t __i3 = 0; __i3 < __nmatches; ++__i3) { __name = __names[__matches[__i3]]; if (__name[__pos] != __c) __matches[__i3] = __matches[--__nmatches]; } } else break; } if (__nmatches == 1) { // Make sure found name is completely extracted. __name = __names[__matches[0]]; const size_t __len = __traits_type::length(__name); while (__pos < __len && __beg != __end && __name[__pos] == *__beg) ++__beg, ++__pos; if (__len == __pos) __member = __matches[0]; else __testvalid = false; } else __testvalid = false; if (!__testvalid) __err |= ios_base::failbit; } template _InIter time_get<_CharT, _InIter>:: do_get_time(iter_type __beg, iter_type __end, ios_base& __io, ios_base::iostate& __err, tm* __tm) const { _CharT __wcs[3]; const char* __cs = "%X"; locale __loc = __io.getloc(); ctype<_CharT> const& __ctype = use_facet >(__loc); __ctype.widen(__cs, __cs + 3, __wcs); _M_extract_via_format(__beg, __end, __io, __err, __tm, __wcs); if (__beg == __end) __err |= ios_base::eofbit; return __beg; } template _InIter time_get<_CharT, _InIter>:: do_get_date(iter_type __beg, iter_type __end, ios_base& __io, ios_base::iostate& __err, tm* __tm) const { _CharT __wcs[3]; const char* __cs = "%x"; locale __loc = __io.getloc(); ctype<_CharT> const& __ctype = use_facet >(__loc); __ctype.widen(__cs, __cs + 3, __wcs); _M_extract_via_format(__beg, __end, __io, __err, __tm, __wcs); if (__beg == __end) __err |= ios_base::eofbit; return __beg; } template _InIter time_get<_CharT, _InIter>:: do_get_weekday(iter_type __beg, iter_type __end, ios_base& __io, ios_base::iostate& __err, tm* __tm) const { typedef char_traits __traits_type; locale __loc = __io.getloc(); __timepunct<_CharT> const& __tp = use_facet<__timepunct<_CharT> >(__loc); const char_type* __days[7]; __tp._M_days_abbreviated(__days); int __tmpwday; _M_extract_name(__beg, __end, __tmpwday, __days, 7, __err); // Check to see if non-abbreviated name exists, and extract. // NB: Assumes both _M_days and _M_days_abbreviated organized in // exact same order, first to last, such that the resulting // __days array with the same index points to a day, and that // day's abbreviated form. // NB: Also assumes that an abbreviated name is a subset of the name. if (!__err) { size_t __pos = __traits_type::length(__days[__tmpwday]); __tp._M_days(__days); const char_type* __name = __days[__tmpwday]; if (__name[__pos] == *__beg) { // Extract the rest of it. const size_t __len = __traits_type::length(__name); while (__pos < __len && __beg != __end && __name[__pos] == *__beg) ++__beg, ++__pos; if (__len != __pos) __err |= ios_base::failbit; } if (!__err) __tm->tm_wday = __tmpwday; } if (__beg == __end) __err |= ios_base::eofbit; return __beg; } template _InIter time_get<_CharT, _InIter>:: do_get_monthname(iter_type __beg, iter_type __end, ios_base& __io, ios_base::iostate& __err, tm* __tm) const { typedef char_traits __traits_type; locale __loc = __io.getloc(); __timepunct<_CharT> const& __tp = use_facet<__timepunct<_CharT> >(__loc); const char_type* __months[12]; __tp._M_months_abbreviated(__months); int __tmpmon; _M_extract_name(__beg, __end, __tmpmon, __months, 12, __err); // Check to see if non-abbreviated name exists, and extract. // NB: Assumes both _M_months and _M_months_abbreviated organized in // exact same order, first to last, such that the resulting // __months array with the same index points to a month, and that // month's abbreviated form. // NB: Also assumes that an abbreviated name is a subset of the name. if (!__err) { size_t __pos = __traits_type::length(__months[__tmpmon]); __tp._M_months(__months); const char_type* __name = __months[__tmpmon]; if (__name[__pos] == *__beg) { // Extract the rest of it. const size_t __len = __traits_type::length(__name); while (__pos < __len && __beg != __end && __name[__pos] == *__beg) ++__beg, ++__pos; if (__len != __pos) __err |= ios_base::failbit; } if (!__err) __tm->tm_mon = __tmpmon; } if (__beg == __end) __err |= ios_base::eofbit; return __beg; } template _InIter time_get<_CharT, _InIter>:: do_get_year(iter_type __beg, iter_type __end, ios_base& __io, ios_base::iostate& __err, tm* __tm) const { locale __loc = __io.getloc(); const ctype<_CharT>& __ctype = use_facet >(__loc); char_type __c = *__beg; size_t __i = 0; string __digits; while (__i < 4 && __beg != __end && __ctype.is(ctype_base::digit, __c)) { __digits += __ctype.narrow(__c, 0); __c = *(++__beg); ++__i; } if (__i == 2 || __i == 4) { long __l; __convert_to_v(__digits.c_str(), __l, __err, _S_c_locale); if (!(__err & ios_base::failbit) && __l <= INT_MAX) { __l = __i == 2 ? __l : __l - 1900; __tm->tm_year = static_cast(__l); } } else __err |= ios_base::failbit; if (__beg == __end) __err |= ios_base::eofbit; return __beg; } template _OutIter time_put<_CharT, _OutIter>:: put(iter_type __s, ios_base& __io, char_type, const tm* __tm, const _CharT* __beg, const _CharT* __end) const { locale __loc = __io.getloc(); ctype<_CharT> const& __ctype = use_facet >(__loc); while (__beg != __end) { char __c = __ctype.narrow(*__beg, 0); ++__beg; if (__c == '%') { char __format; char __mod = 0; size_t __len = 1; __c = __ctype.narrow(*__beg, 0); ++__beg; if (__c == 'E' || __c == 'O') { __mod = __c; __format = __ctype.narrow(*__beg, 0); ++__beg; } else __format = __c; __s = this->do_put(__s, __io, char_type(), __tm, __format, __mod); } else { *__s = __c; ++__s; } } return __s; } template _OutIter time_put<_CharT, _OutIter>:: do_put(iter_type __s, ios_base& __io, char_type, const tm* __tm, char __format, char __mod) const { locale __loc = __io.getloc(); ctype<_CharT> const& __ctype = use_facet >(__loc); __timepunct<_CharT> const& __tp = use_facet<__timepunct<_CharT> >(__loc); // NB: This size is arbitrary. Should this be a data member, // initialized at construction? const size_t __maxlen = 64; char_type* __res = static_cast(__builtin_alloca(__maxlen)); // NB: In IEE 1003.1-200x, and perhaps other locale models, it // is possible that the format character will be longer than one // character. Possibilities include 'E' or 'O' followed by a // format character: if __mod is not the default argument, assume // it's a valid modifier. char_type __fmt[4]; __fmt[0] = __ctype.widen('%'); if (!__mod) { __fmt[1] = __format; __fmt[2] = char_type(); } else { __fmt[1] = __mod; __fmt[2] = __format; __fmt[3] = char_type(); } __tp._M_put_helper(__res, __maxlen, __fmt, __tm); // Write resulting, fully-formatted string to output iterator. size_t __len = char_traits::length(__res); for (size_t __i = 0; __i < __len; ++__i, ++__s) *__s = __res[__i]; return __s; } // Generic version does nothing. template int collate<_CharT>::_M_compare_helper(const _CharT*, const _CharT*) const { return 0; } // Generic version does nothing. template size_t collate<_CharT>::_M_transform_helper(_CharT*, const _CharT*, size_t) const { return 0; } template int collate<_CharT>:: do_compare(const _CharT* __lo1, const _CharT* __hi1, const _CharT* __lo2, const _CharT* __hi2) const { const string_type __one(__lo1, __hi1); const string_type __two(__lo2, __hi2); return _M_compare_helper(__one.c_str(), __two.c_str()); } template typename collate<_CharT>::string_type collate<_CharT>:: do_transform(const _CharT* __lo, const _CharT* __hi) const { size_t __len = __hi - __lo; _CharT* __c = static_cast<_CharT*>(__builtin_alloca(sizeof(_CharT) * __len)); size_t __res = _M_transform_helper(__c, __lo, __len); if (__res >= __len) { // Try to increment size of translated string. size_t __len2 = __len * 2; _CharT* __c2 = static_cast<_CharT*>(__builtin_alloca(sizeof(_CharT) * __len2)); __res = _M_transform_helper(__c2, __lo, __len); // XXX Throw exception if still indeterminate? } return string_type(__c); } template long collate<_CharT>:: do_hash(const _CharT* __lo, const _CharT* __hi) const { unsigned long __val = 0; for (; __lo < __hi; ++__lo) __val = *__lo + ((__val << 7) | (__val >> (numeric_limits::digits - 1))); return static_cast(__val); } // Convert string to numeric value of type T and store results. // NB: This is specialized for all required types, there is no // generic definition. template void __convert_to_v(const char* __in, _T& __out, ios_base::iostate& __err, const __c_locale& __cloc, int __base = 10); // Convert numeric value of type T to string and return length of string. template int __convert_from_v(char* __out, const char* __fmt, _T __v, const __c_locale&, int __prec = -1) { int __ret; const char* __old = setlocale(LC_ALL, "C"); if (__prec >= 0) __ret = sprintf(__out, __fmt, __prec, __v); else __ret = sprintf(__out, __fmt, __v); setlocale(LC_ALL, __old); return __ret; } // Construct correctly padded string, as per 22.2.2.2.2 // Assumes // __newlen > __oldlen // __news is allocated for __newlen size // Used by both num_put and ostream inserters: if __num, // internal-adjusted objects are padded according to the rules below // concerning 0[xX] and +-, otherwise, exactly as right-adjusted // ones are. template void __pad(ios_base& __io, _CharT __fill, _CharT* __news, const _CharT* __olds, const streamsize __newlen, const streamsize __oldlen, const bool __num) { typedef _CharT char_type; typedef _Traits traits_type; typedef typename traits_type::int_type int_type; int_type __plen = static_cast(__newlen - __oldlen); char_type* __pads = static_cast(__builtin_alloca(sizeof(char_type) * __plen)); traits_type::assign(__pads, __plen, __fill); char_type* __beg; char_type* __end; size_t __mod = 0; size_t __beglen; //either __plen or __oldlen ios_base::fmtflags __adjust = __io.flags() & ios_base::adjustfield; if (__adjust == ios_base::left) { // Padding last. __beg = const_cast(__olds); __beglen = __oldlen; __end = __pads; } else if (__adjust == ios_base::internal && __num) { // Pad after the sign, if there is one. // Pad after 0[xX], if there is one. // Who came up with these rules, anyway? Jeeze. locale __loc = __io.getloc(); const ctype<_CharT>& __ctype = use_facet >(__loc); const char_type __minus = __ctype.widen('-'); const char_type __plus = __ctype.widen('+'); bool __testsign = __olds[0] == __minus || __olds[0] == __plus; bool __testhex = __ctype.widen('0') == __olds[0] && (__ctype.widen('x') == __olds[1] || __ctype.widen('X') == __olds[1]); if (__testhex) { __news[0] = __olds[0]; __news[1] = __olds[1]; __mod += 2; __news += 2; __beg = __pads; __beglen = __plen; __end = const_cast(__olds + __mod); } else if (__testsign) { __news[0] = __olds[0] == __plus ? __plus : __minus; ++__mod; ++__news; __beg = __pads; __beglen = __plen; __end = const_cast(__olds + __mod); } else { // Padding first. __beg = __pads; __beglen = __plen; __end = const_cast(__olds); } } else { // Padding first. __beg = __pads; __beglen = __plen; __end = const_cast(__olds); } traits_type::copy(__news, __beg, __beglen); traits_type::copy(__news + __beglen, __end, __newlen - __beglen - __mod); } // NB: Can't have default argument on non-member template, and // num_put doesn't have a _Traits template parameter, so this // forwarding template adds in the default template argument. template void __pad(ios_base& __io, _CharT __fill, _CharT* __news, const _CharT* __olds, const streamsize __newlen, const streamsize __oldlen, const bool __num) { return __pad<_CharT, char_traits<_CharT> >(__io, __fill, __news, __olds, __newlen, __oldlen, __num); } // Used by both numeric and monetary facets. // Check to make sure that the __grouping_tmp string constructed in // money_get or num_get matches the canonical grouping for a given // locale. // __grouping_tmp is parsed L to R // 1,222,444 == __grouping_tmp of "/1/3/3" // __grouping is parsed R to L // 1,222,444 == __grouping of "/3" == "/3/3/3" template bool __verify_grouping(const basic_string<_CharT>& __grouping, basic_string<_CharT>& __grouping_tmp) { int __i = 0; int __j = 0; const int __len = __grouping.size(); const int __n = __grouping_tmp.size(); bool __test = true; // Parsed number groupings have to match the // numpunct::grouping string exactly, starting at the // right-most point of the parsed sequence of elements ... while (__test && __i < __n - 1) for (__j = 0; __test && __j < __len && __i < __n - 1; ++__j,++__i) __test &= __grouping[__j] == __grouping_tmp[__n - __i - 1]; // ... but the last parsed grouping can be <= numpunct // grouping. __j == __len ? __j = 0 : __j; __test &= __grouping[__j] >= __grouping_tmp[__n - __i - 1]; return __test; } // Used by both numeric and monetary facets. // Inserts "group separator" characters into an array of characters. // It's recursive, one iteration per group. It moves the characters // in the buffer this way: "xxxx12345" -> "12,345xxx". Call this // only with __gbeg != __gend. template _CharT* __add_grouping(_CharT* __s, _CharT __sep, const char* __gbeg, const char* __gend, const _CharT* __first, const _CharT* __last) { if (__last - __first > *__gbeg) { __s = __add_grouping(__s, __sep, (__gbeg + 1 == __gend ? __gbeg : __gbeg + 1), __gend, __first, __last - *__gbeg); __first = __last - *__gbeg; *__s++ = __sep; } do *__s++ = *__first++; while (__first != __last); return __s; } } // namespace std #endif