// -*- 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_UTC_CLOCK_H #define _LIBCPP___CHRONO_UTC_CLOCK_H #include // Enable the contents of the header only when libc++ was built with experimental features enabled. #if _LIBCPP_HAS_EXPERIMENTAL_TZDB # include <__chrono/duration.h> # include <__chrono/leap_second.h> # include <__chrono/system_clock.h> # include <__chrono/time_point.h> # include <__chrono/tzdb.h> # include <__chrono/tzdb_list.h> # include <__config> # include <__type_traits/common_type.h> # if !defined(_LIBCPP_HAS_NO_PRAGMA_SYSTEM_HEADER) # pragma GCC system_header # endif _LIBCPP_BEGIN_NAMESPACE_STD # if _LIBCPP_STD_VER >= 20 && _LIBCPP_HAS_TIME_ZONE_DATABASE && _LIBCPP_HAS_FILESYSTEM && _LIBCPP_HAS_LOCALIZATION namespace chrono { class utc_clock; template using utc_time = time_point; using utc_seconds = utc_time; class utc_clock { public: using rep = system_clock::rep; using period = system_clock::period; using duration = chrono::duration; using time_point = chrono::time_point; static constexpr bool is_steady = false; // The system_clock is not steady. [[nodiscard]] _LIBCPP_HIDE_FROM_ABI static time_point now() { return from_sys(system_clock::now()); } template [[nodiscard]] _LIBCPP_HIDE_FROM_ABI static sys_time> to_sys(const utc_time<_Duration>& __time); template [[nodiscard]] _LIBCPP_HIDE_FROM_ABI static utc_time> from_sys(const sys_time<_Duration>& __time) { using _Rp = utc_time>; // TODO TZDB investigate optimizations. // // The leap second database stores all transitions, this mean to calculate // the current number of leap seconds the code needs to iterate over all // leap seconds to accumulate the sum. Then the sum can be used to determine // the sys_time. Accessing the database involves acquiring a mutex. // // The historic entries in the database are immutable. Hard-coding these // values in a table would allow: // - To store the sum, allowing a binary search on the data. // - Avoid acquiring a mutex. // The disadvantage are: // - A slightly larger code size. // // There are two optimization directions // - hard-code the database and do a linear search for future entries. This // search can start at the back, and should probably contain very few // entries. (Adding leap seconds is quite rare and new release of libc++ // can add the new entries; they are announced half a year before they are // added.) // - During parsing the leap seconds store an additional database in the // dylib with the list of the sum of the leap seconds. In that case there // can be a private function __get_utc_to_sys_table that returns the // table. // // Note for to_sys there are no optimizations to be done; it uses // get_leap_second_info. The function get_leap_second_info could benefit // from optimizations as described above; again both options apply. // Both UTC and the system clock use the same epoch. The Standard // specifies from 1970-01-01 even when UTC starts at // 1972-01-01 00:00:10 TAI. So when the sys_time is before epoch we can be // sure there both clocks return the same value. const tzdb& __tzdb = chrono::get_tzdb(); _Rp __result{__time.time_since_epoch()}; for (const auto& __leap_second : __tzdb.leap_seconds) { if (__leap_second > __time) return __result; __result += __leap_second.value(); } return __result; } }; struct leap_second_info { bool is_leap_second; seconds elapsed; }; template [[nodiscard]] _LIBCPP_HIDE_FROM_ABI leap_second_info get_leap_second_info(const utc_time<_Duration>& __time) { const tzdb& __tzdb = chrono::get_tzdb(); if (__tzdb.leap_seconds.empty()) [[unlikely]] return {false, chrono::seconds{0}}; sys_seconds __sys{chrono::floor(__time).time_since_epoch()}; seconds __elapsed{0}; for (const auto& __leap_second : __tzdb.leap_seconds) { if (__sys == __leap_second.date() + __elapsed) // A time point may only be a leap second during a positive leap second // insertion, since time points that occur during a (theoretical) // negative leap second don't exist. return {__leap_second.value() > 0s, __elapsed + __leap_second.value()}; if (__sys < __leap_second.date() + __elapsed) return {false, __elapsed}; __elapsed += __leap_second.value(); } return {false, __elapsed}; } template [[nodiscard]] _LIBCPP_HIDE_FROM_ABI sys_time> utc_clock::to_sys(const utc_time<_Duration>& __time) { using _Dp = common_type_t<_Duration, seconds>; leap_second_info __info = chrono::get_leap_second_info(__time); // [time.clock.utc.members]/2 // Returns: A sys_time t, such that from_sys(t) == u if such a mapping // exists. Otherwise u represents a time_point during a positive leap // second insertion, the conversion counts that leap second as not // inserted, and the last representable value of sys_time prior to the // insertion of the leap second is returned. sys_time> __result{__time.time_since_epoch() - __info.elapsed}; if (__info.is_leap_second) return chrono::floor(__result) + chrono::seconds{1} - _Dp{1}; return __result; } } // namespace chrono # endif // _LIBCPP_STD_VER >= 20 && _LIBCPP_HAS_TIME_ZONE_DATABASE && _LIBCPP_HAS_FILESYSTEM && // _LIBCPP_HAS_LOCALIZATION _LIBCPP_END_NAMESPACE_STD #endif // _LIBCPP_HAS_EXPERIMENTAL_TZDB #endif // _LIBCPP___CHRONO_UTC_CLOCK_H