// -*- C++ -*- //===----------------------------------------------------------------------===// // // Part of the LLVM Project, under the Apache License v2.0 with LLVM Exceptions. // See https://llvm.org/LICENSE.txt for license information. // SPDX-License-Identifier: Apache-2.0 WITH LLVM-exception // //===----------------------------------------------------------------------===// #ifndef _LIBCPP___CHRONO_FORMATTER_H #define _LIBCPP___CHRONO_FORMATTER_H #include <__chrono/calendar.h> #include <__chrono/concepts.h> #include <__chrono/convert_to_tm.h> #include <__chrono/day.h> #include <__chrono/duration.h> #include <__chrono/file_clock.h> #include <__chrono/hh_mm_ss.h> #include <__chrono/month.h> #include <__chrono/month_weekday.h> #include <__chrono/monthday.h> #include <__chrono/ostream.h> #include <__chrono/parser_std_format_spec.h> #include <__chrono/statically_widen.h> #include <__chrono/system_clock.h> #include <__chrono/time_point.h> #include <__chrono/weekday.h> #include <__chrono/year.h> #include <__chrono/year_month.h> #include <__chrono/year_month_day.h> #include <__chrono/year_month_weekday.h> #include <__concepts/arithmetic.h> #include <__concepts/same_as.h> #include <__config> #include <__format/concepts.h> #include <__format/format_error.h> #include <__format/format_functions.h> #include <__format/format_parse_context.h> #include <__format/formatter.h> #include <__format/parser_std_format_spec.h> #include <__format/write_escaped.h> #include <__memory/addressof.h> #include #include #include #include #if !defined(_LIBCPP_HAS_NO_PRAGMA_SYSTEM_HEADER) # pragma GCC system_header #endif _LIBCPP_BEGIN_NAMESPACE_STD #if _LIBCPP_STD_VER >= 20 namespace __formatter { /// Formats a time based on a tm struct. /// /// This formatter passes the formatting to time_put which uses strftime. When /// the value is outside the valid range it's unspecified what strftime will /// output. For example weekday 8 can print 1 when the day is processed modulo /// 7 since that handles the Sunday for 0-based weekday. It can also print 8 if /// 7 is handled as a special case. /// /// The Standard doesn't specify what to do in this case so the result depends /// on the result of the underlying code. /// /// \pre When the (abbreviated) weekday or month name are used, the caller /// validates whether the value is valid. So the caller handles that /// requirement of Table 97: Meaning of conversion specifiers /// [tab:time.format.spec]. /// /// When no chrono-specs are provided it uses the stream formatter. // For tiny ratios it's not possible to convert a duration to a hh_mm_ss. This // fails compile-time due to the limited precision of the ratio (64-bit is too // small). Therefore a duration uses its own conversion. template _LIBCPP_HIDE_FROM_ABI void __format_sub_seconds(const chrono::duration<_Rep, _Period>& __value, basic_stringstream<_CharT>& __sstr) { __sstr << std::use_facet>(__sstr.getloc()).decimal_point(); using __duration = chrono::duration<_Rep, _Period>; auto __fraction = __value - chrono::duration_cast(__value); if constexpr (chrono::treat_as_floating_point_v<_Rep>) // When the floating-point value has digits itself they are ignored based // on the wording in [tab:time.format.spec] // If the precision of the input cannot be exactly represented with // seconds, then the format is a decimal floating-point number with a // fixed format and a precision matching that of the precision of the // input (or to a microseconds precision if the conversion to // floating-point decimal seconds cannot be made within 18 fractional // digits). // // This matches the behaviour of MSVC STL, fmtlib interprets this // differently and uses 3 decimals. // https://godbolt.org/z/6dsbnW8ba std::format_to(std::ostreambuf_iterator<_CharT>{__sstr}, _LIBCPP_STATICALLY_WIDEN(_CharT, "{:0{}.0f}"), chrono::duration_cast::precision>(__fraction).count(), chrono::hh_mm_ss<__duration>::fractional_width); else std::format_to(std::ostreambuf_iterator<_CharT>{__sstr}, _LIBCPP_STATICALLY_WIDEN(_CharT, "{:0{}}"), chrono::duration_cast::precision>(__fraction).count(), chrono::hh_mm_ss<__duration>::fractional_width); } template _LIBCPP_HIDE_FROM_ABI void __format_sub_seconds(const _Tp& __value, basic_stringstream<_CharT>& __sstr) { __formatter::__format_sub_seconds(__value.time_since_epoch(), __sstr); } template _LIBCPP_HIDE_FROM_ABI void __format_sub_seconds(const chrono::hh_mm_ss<_Duration>& __value, basic_stringstream<_CharT>& __sstr) { __sstr << std::use_facet>(__sstr.getloc()).decimal_point(); if constexpr (chrono::treat_as_floating_point_v) std::format_to(std::ostreambuf_iterator<_CharT>{__sstr}, _LIBCPP_STATICALLY_WIDEN(_CharT, "{:0{}.0f}"), __value.subseconds().count(), __value.fractional_width); else std::format_to(std::ostreambuf_iterator<_CharT>{__sstr}, _LIBCPP_STATICALLY_WIDEN(_CharT, "{:0{}}"), __value.subseconds().count(), __value.fractional_width); } template consteval bool __use_fraction() { if constexpr (__is_time_point<_Tp>) return chrono::hh_mm_ss::fractional_width; else if constexpr (chrono::__is_duration<_Tp>::value) return chrono::hh_mm_ss<_Tp>::fractional_width; else if constexpr (__is_hh_mm_ss<_Tp>) return _Tp::fractional_width; else return false; } template _LIBCPP_HIDE_FROM_ABI void __format_year(int __year, basic_stringstream<_CharT>& __sstr) { if (__year < 0) { __sstr << _CharT('-'); __year = -__year; } // TODO FMT Write an issue // If the result has less than four digits it is zero-padded with 0 to two digits. // is less -> has less // left-padded -> zero-padded, otherwise the proper value would be 000-0. // Note according to the wording it should be left padded, which is odd. __sstr << std::format(_LIBCPP_STATICALLY_WIDEN(_CharT, "{:04}"), __year); } template _LIBCPP_HIDE_FROM_ABI void __format_century(int __year, basic_stringstream<_CharT>& __sstr) { // TODO FMT Write an issue // [tab:time.format.spec] // %C The year divided by 100 using floored division. If the result is a // single decimal digit, it is prefixed with 0. bool __negative = __year < 0; int __century = (__year - (99 * __negative)) / 100; // floored division __sstr << std::format(_LIBCPP_STATICALLY_WIDEN(_CharT, "{:02}"), __century); } template _LIBCPP_HIDE_FROM_ABI void __format_chrono_using_chrono_specs( const _Tp& __value, basic_stringstream<_CharT>& __sstr, basic_string_view<_CharT> __chrono_specs) { tm __t = std::__convert_to_tm(__value); const auto& __facet = std::use_facet>(__sstr.getloc()); for (auto __it = __chrono_specs.begin(); __it != __chrono_specs.end(); ++__it) { if (*__it == _CharT('%')) { auto __s = __it; ++__it; // We only handle the types that can't be directly handled by time_put. // (as an optimization n, t, and % are also handled directly.) switch (*__it) { case _CharT('n'): __sstr << _CharT('\n'); break; case _CharT('t'): __sstr << _CharT('\t'); break; case _CharT('%'): __sstr << *__it; break; case _CharT('C'): { // strftime's output is only defined in the range [00, 99]. int __year = __t.tm_year + 1900; if (__year < 1000 || __year > 9999) __formatter::__format_century(__year, __sstr); else __facet.put( {__sstr}, __sstr, _CharT(' '), std::addressof(__t), std::to_address(__s), std::to_address(__it + 1)); } break; case _CharT('j'): if constexpr (chrono::__is_duration<_Tp>::value) // Converting a duration where the period has a small ratio to days // may fail to compile. This due to loss of precision in the // conversion. In order to avoid that issue convert to seconds as // an intemediate step. __sstr << chrono::duration_cast(chrono::duration_cast(__value)).count(); else __facet.put( {__sstr}, __sstr, _CharT(' '), std::addressof(__t), std::to_address(__s), std::to_address(__it + 1)); break; case _CharT('q'): if constexpr (chrono::__is_duration<_Tp>::value) { __sstr << chrono::__units_suffix<_CharT, typename _Tp::period>(); break; } __builtin_unreachable(); case _CharT('Q'): // TODO FMT Determine the proper ideas // - Should it honour the precision? // - Shoult it honour the locale setting for the separators? // The wording for Q doesn't use the word locale and the effect of // precision is unspecified. // // MSVC STL ignores precision but uses separator // FMT honours precision and has a bug for separator // https://godbolt.org/z/78b7sMxns if constexpr (chrono::__is_duration<_Tp>::value) { __sstr << std::format(_LIBCPP_STATICALLY_WIDEN(_CharT, "{}"), __value.count()); break; } __builtin_unreachable(); case _CharT('S'): case _CharT('T'): __facet.put( {__sstr}, __sstr, _CharT(' '), std::addressof(__t), std::to_address(__s), std::to_address(__it + 1)); if constexpr (__use_fraction<_Tp>()) __formatter::__format_sub_seconds(__value, __sstr); break; // Unlike time_put and strftime the formatting library requires %Y // // [tab:time.format.spec] // The year as a decimal number. If the result is less than four digits // it is left-padded with 0 to four digits. // // This means years in the range (-1000, 1000) need manual formatting. // It's unclear whether %EY needs the same treatment. For example the // Japanese EY contains the era name and year. This is zero-padded to 2 // digits in time_put (note that older glibc versions didn't do // padding.) However most eras won't reach 100 years, let alone 1000. // So padding to 4 digits seems unwanted for Japanese. // // The same applies to %Ex since that too depends on the era. // // %x the locale's date representation is currently doesn't handle the // zero-padding too. // // The 4 digits can be implemented better at a later time. On POSIX // systems the required information can be extracted by nl_langinfo // https://man7.org/linux/man-pages/man3/nl_langinfo.3.html // // Note since year < -1000 is expected to be rare it uses the more // expensive year routine. // // TODO FMT evaluate the comment above. # if defined(__GLIBC__) || defined(_AIX) || defined(_WIN32) case _CharT('y'): // Glibc fails for negative values, AIX for positive values too. __sstr << std::format(_LIBCPP_STATICALLY_WIDEN(_CharT, "{:02}"), (std::abs(__t.tm_year + 1900)) % 100); break; # endif // defined(__GLIBC__) || defined(_AIX) || defined(_WIN32) case _CharT('Y'): // Depending on the platform's libc the range of supported years is // limited. Intead of of testing all conditions use the internal // implementation unconditionally. __formatter::__format_year(__t.tm_year + 1900, __sstr); break; case _CharT('F'): { int __year = __t.tm_year + 1900; if (__year < 1000) { __formatter::__format_year(__year, __sstr); __sstr << std::format(_LIBCPP_STATICALLY_WIDEN(_CharT, "-{:02}-{:02}"), __t.tm_mon + 1, __t.tm_mday); } else __facet.put( {__sstr}, __sstr, _CharT(' '), std::addressof(__t), std::to_address(__s), std::to_address(__it + 1)); } break; case _CharT('Z'): // TODO FMT Add proper timezone support. __sstr << _LIBCPP_STATICALLY_WIDEN(_CharT, "UTC"); break; case _CharT('O'): if constexpr (__use_fraction<_Tp>()) { // Handle OS using the normal representation for the non-fractional // part. There seems to be no locale information regarding how the // fractional part should be formatted. if (*(__it + 1) == 'S') { ++__it; __facet.put( {__sstr}, __sstr, _CharT(' '), std::addressof(__t), std::to_address(__s), std::to_address(__it + 1)); __formatter::__format_sub_seconds(__value, __sstr); break; } } [[fallthrough]]; case _CharT('E'): ++__it; [[fallthrough]]; default: __facet.put( {__sstr}, __sstr, _CharT(' '), std::addressof(__t), std::to_address(__s), std::to_address(__it + 1)); break; } } else { __sstr << *__it; } } } template _LIBCPP_HIDE_FROM_ABI constexpr bool __weekday_ok(const _Tp& __value) { if constexpr (__is_time_point<_Tp>) return true; else if constexpr (same_as<_Tp, chrono::day>) return true; else if constexpr (same_as<_Tp, chrono::month>) return __value.ok(); else if constexpr (same_as<_Tp, chrono::year>) return true; else if constexpr (same_as<_Tp, chrono::weekday>) return true; else if constexpr (same_as<_Tp, chrono::weekday_indexed>) return true; else if constexpr (same_as<_Tp, chrono::weekday_last>) return true; else if constexpr (same_as<_Tp, chrono::month_day>) return true; else if constexpr (same_as<_Tp, chrono::month_day_last>) return true; else if constexpr (same_as<_Tp, chrono::month_weekday>) return true; else if constexpr (same_as<_Tp, chrono::month_weekday_last>) return true; else if constexpr (same_as<_Tp, chrono::year_month>) return true; else if constexpr (same_as<_Tp, chrono::year_month_day>) return __value.ok(); else if constexpr (same_as<_Tp, chrono::year_month_day_last>) return __value.ok(); else if constexpr (same_as<_Tp, chrono::year_month_weekday>) return __value.weekday().ok(); else if constexpr (same_as<_Tp, chrono::year_month_weekday_last>) return __value.weekday().ok(); else if constexpr (__is_hh_mm_ss<_Tp>) return true; else static_assert(sizeof(_Tp) == 0, "Add the missing type specialization"); } template _LIBCPP_HIDE_FROM_ABI constexpr bool __weekday_name_ok(const _Tp& __value) { if constexpr (__is_time_point<_Tp>) return true; else if constexpr (same_as<_Tp, chrono::day>) return true; else if constexpr (same_as<_Tp, chrono::month>) return __value.ok(); else if constexpr (same_as<_Tp, chrono::year>) return true; else if constexpr (same_as<_Tp, chrono::weekday>) return __value.ok(); else if constexpr (same_as<_Tp, chrono::weekday_indexed>) return __value.weekday().ok(); else if constexpr (same_as<_Tp, chrono::weekday_last>) return __value.weekday().ok(); else if constexpr (same_as<_Tp, chrono::month_day>) return true; else if constexpr (same_as<_Tp, chrono::month_day_last>) return true; else if constexpr (same_as<_Tp, chrono::month_weekday>) return __value.weekday_indexed().ok(); else if constexpr (same_as<_Tp, chrono::month_weekday_last>) return __value.weekday_indexed().ok(); else if constexpr (same_as<_Tp, chrono::year_month>) return true; else if constexpr (same_as<_Tp, chrono::year_month_day>) return __value.ok(); else if constexpr (same_as<_Tp, chrono::year_month_day_last>) return __value.ok(); else if constexpr (same_as<_Tp, chrono::year_month_weekday>) return __value.weekday().ok(); else if constexpr (same_as<_Tp, chrono::year_month_weekday_last>) return __value.weekday().ok(); else if constexpr (__is_hh_mm_ss<_Tp>) return true; else static_assert(sizeof(_Tp) == 0, "Add the missing type specialization"); } template _LIBCPP_HIDE_FROM_ABI constexpr bool __date_ok(const _Tp& __value) { if constexpr (__is_time_point<_Tp>) return true; else if constexpr (same_as<_Tp, chrono::day>) return true; else if constexpr (same_as<_Tp, chrono::month>) return __value.ok(); else if constexpr (same_as<_Tp, chrono::year>) return true; else if constexpr (same_as<_Tp, chrono::weekday>) return true; else if constexpr (same_as<_Tp, chrono::weekday_indexed>) return true; else if constexpr (same_as<_Tp, chrono::weekday_last>) return true; else if constexpr (same_as<_Tp, chrono::month_day>) return true; else if constexpr (same_as<_Tp, chrono::month_day_last>) return true; else if constexpr (same_as<_Tp, chrono::month_weekday>) return true; else if constexpr (same_as<_Tp, chrono::month_weekday_last>) return true; else if constexpr (same_as<_Tp, chrono::year_month>) return true; else if constexpr (same_as<_Tp, chrono::year_month_day>) return __value.ok(); else if constexpr (same_as<_Tp, chrono::year_month_day_last>) return __value.ok(); else if constexpr (same_as<_Tp, chrono::year_month_weekday>) return __value.ok(); else if constexpr (same_as<_Tp, chrono::year_month_weekday_last>) return __value.ok(); else if constexpr (__is_hh_mm_ss<_Tp>) return true; else static_assert(sizeof(_Tp) == 0, "Add the missing type specialization"); } template _LIBCPP_HIDE_FROM_ABI constexpr bool __month_name_ok(const _Tp& __value) { if constexpr (__is_time_point<_Tp>) return true; else if constexpr (same_as<_Tp, chrono::day>) return true; else if constexpr (same_as<_Tp, chrono::month>) return __value.ok(); else if constexpr (same_as<_Tp, chrono::year>) return true; else if constexpr (same_as<_Tp, chrono::weekday>) return true; else if constexpr (same_as<_Tp, chrono::weekday_indexed>) return true; else if constexpr (same_as<_Tp, chrono::weekday_last>) return true; else if constexpr (same_as<_Tp, chrono::month_day>) return __value.month().ok(); else if constexpr (same_as<_Tp, chrono::month_day_last>) return __value.month().ok(); else if constexpr (same_as<_Tp, chrono::month_weekday>) return __value.month().ok(); else if constexpr (same_as<_Tp, chrono::month_weekday_last>) return __value.month().ok(); else if constexpr (same_as<_Tp, chrono::year_month>) return __value.month().ok(); else if constexpr (same_as<_Tp, chrono::year_month_day>) return __value.month().ok(); else if constexpr (same_as<_Tp, chrono::year_month_day_last>) return __value.month().ok(); else if constexpr (same_as<_Tp, chrono::year_month_weekday>) return __value.month().ok(); else if constexpr (same_as<_Tp, chrono::year_month_weekday_last>) return __value.month().ok(); else if constexpr (__is_hh_mm_ss<_Tp>) return true; else static_assert(sizeof(_Tp) == 0, "Add the missing type specialization"); } template _LIBCPP_HIDE_FROM_ABI auto __format_chrono(const _Tp& __value, _FormatContext& __ctx, __format_spec::__parsed_specifications<_CharT> __specs, basic_string_view<_CharT> __chrono_specs) { basic_stringstream<_CharT> __sstr; // [time.format]/2 // 2.1 - the "C" locale if the L option is not present in chrono-format-spec, otherwise // 2.2 - the locale passed to the formatting function if any, otherwise // 2.3 - the global locale. // Note that the __ctx's locale() call does 2.2 and 2.3. if (__specs.__chrono_.__locale_specific_form_) __sstr.imbue(__ctx.locale()); else __sstr.imbue(locale::classic()); if (__chrono_specs.empty()) __sstr << __value; else { if constexpr (chrono::__is_duration<_Tp>::value) { if (__value < __value.zero()) __sstr << _CharT('-'); __formatter::__format_chrono_using_chrono_specs(chrono::abs(__value), __sstr, __chrono_specs); // TODO FMT When keeping the precision it will truncate the string. // Note that the behaviour what the precision does isn't specified. __specs.__precision_ = -1; } else { // Test __weekday_name_ before __weekday_ to give a better error. if (__specs.__chrono_.__weekday_name_ && !__formatter::__weekday_name_ok(__value)) std::__throw_format_error("Formatting a weekday name needs a valid weekday"); if (__specs.__chrono_.__weekday_ && !__formatter::__weekday_ok(__value)) std::__throw_format_error("Formatting a weekday needs a valid weekday"); if (__specs.__chrono_.__day_of_year_ && !__formatter::__date_ok(__value)) std::__throw_format_error("Formatting a day of year needs a valid date"); if (__specs.__chrono_.__week_of_year_ && !__formatter::__date_ok(__value)) std::__throw_format_error("Formatting a week of year needs a valid date"); if (__specs.__chrono_.__month_name_ && !__formatter::__month_name_ok(__value)) std::__throw_format_error("Formatting a month name from an invalid month number"); if constexpr (__is_hh_mm_ss<_Tp>) { // Note this is a pedantic intepretation of the Standard. A hh_mm_ss // is no longer a time_of_day and can store an arbitrary number of // hours. A number of hours in a 12 or 24 hour clock can't represent // 24 hours or more. The functions std::chrono::make12 and // std::chrono::make24 reaffirm this view point. // // Interestingly this will be the only output stream function that // throws. // // TODO FMT The wording probably needs to be adapted to // - The displayed hours is hh_mm_ss.hours() % 24 // - It should probably allow %j in the same fashion as duration. // - The stream formatter should change its output when hours >= 24 // - Write it as not valid, // - or write the number of days. if (__specs.__chrono_.__hour_ && __value.hours().count() > 23) std::__throw_format_error("Formatting a hour needs a valid value"); if (__value.is_negative()) __sstr << _CharT('-'); } __formatter::__format_chrono_using_chrono_specs(__value, __sstr, __chrono_specs); } } return __formatter::__write_string(__sstr.view(), __ctx.out(), __specs); } } // namespace __formatter template <__fmt_char_type _CharT> struct _LIBCPP_TEMPLATE_VIS __formatter_chrono { public: template _LIBCPP_HIDE_FROM_ABI constexpr typename _ParseContext::iterator __parse(_ParseContext& __ctx, __format_spec::__fields __fields, __format_spec::__flags __flags) { return __parser_.__parse(__ctx, __fields, __flags); } template _LIBCPP_HIDE_FROM_ABI typename _FormatContext::iterator format(const _Tp& __value, _FormatContext& __ctx) const { return __formatter::__format_chrono( __value, __ctx, __parser_.__parser_.__get_parsed_chrono_specifications(__ctx), __parser_.__chrono_specs_); } __format_spec::__parser_chrono<_CharT> __parser_; }; template struct _LIBCPP_TEMPLATE_VIS formatter, _CharT> : public __formatter_chrono<_CharT> { public: using _Base = __formatter_chrono<_CharT>; template _LIBCPP_HIDE_FROM_ABI constexpr typename _ParseContext::iterator parse(_ParseContext& __ctx) { return _Base::__parse(__ctx, __format_spec::__fields_chrono, __format_spec::__flags::__clock); } }; template struct _LIBCPP_TEMPLATE_VIS formatter, _CharT> : public __formatter_chrono<_CharT> { public: using _Base = __formatter_chrono<_CharT>; template _LIBCPP_HIDE_FROM_ABI constexpr typename _ParseContext::iterator parse(_ParseContext& __ctx) { return _Base::__parse(__ctx, __format_spec::__fields_chrono, __format_spec::__flags::__clock); } }; template struct _LIBCPP_TEMPLATE_VIS formatter, _CharT> : public __formatter_chrono<_CharT> { public: using _Base = __formatter_chrono<_CharT>; template _LIBCPP_HIDE_FROM_ABI constexpr typename _ParseContext::iterator parse(_ParseContext& __ctx) { // The flags are not __clock since there is no associated time-zone. return _Base::__parse(__ctx, __format_spec::__fields_chrono, __format_spec::__flags::__date_time); } }; template struct formatter, _CharT> : public __formatter_chrono<_CharT> { public: using _Base = __formatter_chrono<_CharT>; template _LIBCPP_HIDE_FROM_ABI constexpr typename _ParseContext::iterator parse(_ParseContext& __ctx) { // [time.format]/1 // Giving a precision specification in the chrono-format-spec is valid only // for std::chrono::duration types where the representation type Rep is a // floating-point type. For all other Rep types, an exception of type // format_error is thrown if the chrono-format-spec contains a precision // specification. // // Note this doesn't refer to chrono::treat_as_floating_point_v<_Rep>. if constexpr (std::floating_point<_Rep>) return _Base::__parse(__ctx, __format_spec::__fields_chrono_fractional, __format_spec::__flags::__duration); else return _Base::__parse(__ctx, __format_spec::__fields_chrono, __format_spec::__flags::__duration); } }; template <__fmt_char_type _CharT> struct _LIBCPP_TEMPLATE_VIS formatter : public __formatter_chrono<_CharT> { public: using _Base = __formatter_chrono<_CharT>; template _LIBCPP_HIDE_FROM_ABI constexpr typename _ParseContext::iterator parse(_ParseContext& __ctx) { return _Base::__parse(__ctx, __format_spec::__fields_chrono, __format_spec::__flags::__day); } }; template <__fmt_char_type _CharT> struct _LIBCPP_TEMPLATE_VIS formatter : public __formatter_chrono<_CharT> { public: using _Base = __formatter_chrono<_CharT>; template _LIBCPP_HIDE_FROM_ABI constexpr typename _ParseContext::iterator parse(_ParseContext& __ctx) { return _Base::__parse(__ctx, __format_spec::__fields_chrono, __format_spec::__flags::__month); } }; template <__fmt_char_type _CharT> struct _LIBCPP_TEMPLATE_VIS formatter : public __formatter_chrono<_CharT> { public: using _Base = __formatter_chrono<_CharT>; template _LIBCPP_HIDE_FROM_ABI constexpr typename _ParseContext::iterator parse(_ParseContext& __ctx) { return _Base::__parse(__ctx, __format_spec::__fields_chrono, __format_spec::__flags::__year); } }; template <__fmt_char_type _CharT> struct _LIBCPP_TEMPLATE_VIS formatter : public __formatter_chrono<_CharT> { public: using _Base = __formatter_chrono<_CharT>; template _LIBCPP_HIDE_FROM_ABI constexpr typename _ParseContext::iterator parse(_ParseContext& __ctx) { return _Base::__parse(__ctx, __format_spec::__fields_chrono, __format_spec::__flags::__weekday); } }; template <__fmt_char_type _CharT> struct _LIBCPP_TEMPLATE_VIS formatter : public __formatter_chrono<_CharT> { public: using _Base = __formatter_chrono<_CharT>; template _LIBCPP_HIDE_FROM_ABI constexpr typename _ParseContext::iterator parse(_ParseContext& __ctx) { return _Base::__parse(__ctx, __format_spec::__fields_chrono, __format_spec::__flags::__weekday); } }; template <__fmt_char_type _CharT> struct _LIBCPP_TEMPLATE_VIS formatter : public __formatter_chrono<_CharT> { public: using _Base = __formatter_chrono<_CharT>; template _LIBCPP_HIDE_FROM_ABI constexpr typename _ParseContext::iterator parse(_ParseContext& __ctx) { return _Base::__parse(__ctx, __format_spec::__fields_chrono, __format_spec::__flags::__weekday); } }; template <__fmt_char_type _CharT> struct _LIBCPP_TEMPLATE_VIS formatter : public __formatter_chrono<_CharT> { public: using _Base = __formatter_chrono<_CharT>; template _LIBCPP_HIDE_FROM_ABI constexpr typename _ParseContext::iterator parse(_ParseContext& __ctx) { return _Base::__parse(__ctx, __format_spec::__fields_chrono, __format_spec::__flags::__month_day); } }; template <__fmt_char_type _CharT> struct _LIBCPP_TEMPLATE_VIS formatter : public __formatter_chrono<_CharT> { public: using _Base = __formatter_chrono<_CharT>; template _LIBCPP_HIDE_FROM_ABI constexpr typename _ParseContext::iterator parse(_ParseContext& __ctx) { return _Base::__parse(__ctx, __format_spec::__fields_chrono, __format_spec::__flags::__month); } }; template <__fmt_char_type _CharT> struct _LIBCPP_TEMPLATE_VIS formatter : public __formatter_chrono<_CharT> { public: using _Base = __formatter_chrono<_CharT>; template _LIBCPP_HIDE_FROM_ABI constexpr typename _ParseContext::iterator parse(_ParseContext& __ctx) { return _Base::__parse(__ctx, __format_spec::__fields_chrono, __format_spec::__flags::__month_weekday); } }; template <__fmt_char_type _CharT> struct _LIBCPP_TEMPLATE_VIS formatter : public __formatter_chrono<_CharT> { public: using _Base = __formatter_chrono<_CharT>; template _LIBCPP_HIDE_FROM_ABI constexpr typename _ParseContext::iterator parse(_ParseContext& __ctx) { return _Base::__parse(__ctx, __format_spec::__fields_chrono, __format_spec::__flags::__month_weekday); } }; template <__fmt_char_type _CharT> struct _LIBCPP_TEMPLATE_VIS formatter : public __formatter_chrono<_CharT> { public: using _Base = __formatter_chrono<_CharT>; template _LIBCPP_HIDE_FROM_ABI constexpr typename _ParseContext::iterator parse(_ParseContext& __ctx) { return _Base::__parse(__ctx, __format_spec::__fields_chrono, __format_spec::__flags::__year_month); } }; template <__fmt_char_type _CharT> struct _LIBCPP_TEMPLATE_VIS formatter : public __formatter_chrono<_CharT> { public: using _Base = __formatter_chrono<_CharT>; template _LIBCPP_HIDE_FROM_ABI constexpr typename _ParseContext::iterator parse(_ParseContext& __ctx) { return _Base::__parse(__ctx, __format_spec::__fields_chrono, __format_spec::__flags::__date); } }; template <__fmt_char_type _CharT> struct _LIBCPP_TEMPLATE_VIS formatter : public __formatter_chrono<_CharT> { public: using _Base = __formatter_chrono<_CharT>; template _LIBCPP_HIDE_FROM_ABI constexpr typename _ParseContext::iterator parse(_ParseContext& __ctx) { return _Base::__parse(__ctx, __format_spec::__fields_chrono, __format_spec::__flags::__date); } }; template <__fmt_char_type _CharT> struct _LIBCPP_TEMPLATE_VIS formatter : public __formatter_chrono<_CharT> { public: using _Base = __formatter_chrono<_CharT>; template _LIBCPP_HIDE_FROM_ABI constexpr typename _ParseContext::iterator parse(_ParseContext& __ctx) { return _Base::__parse(__ctx, __format_spec::__fields_chrono, __format_spec::__flags::__date); } }; template <__fmt_char_type _CharT> struct _LIBCPP_TEMPLATE_VIS formatter : public __formatter_chrono<_CharT> { public: using _Base = __formatter_chrono<_CharT>; template _LIBCPP_HIDE_FROM_ABI constexpr typename _ParseContext::iterator parse(_ParseContext& __ctx) { return _Base::__parse(__ctx, __format_spec::__fields_chrono, __format_spec::__flags::__date); } }; template struct formatter, _CharT> : public __formatter_chrono<_CharT> { public: using _Base = __formatter_chrono<_CharT>; template _LIBCPP_HIDE_FROM_ABI constexpr typename _ParseContext::iterator parse(_ParseContext& __ctx) { return _Base::__parse(__ctx, __format_spec::__fields_chrono, __format_spec::__flags::__time); } }; #endif // if _LIBCPP_STD_VER >= 20 _LIBCPP_END_NAMESPACE_STD #endif // _LIBCPP___CHRONO_FORMATTER_H