tvl-depot/absl/time/civil_time.h
Abseil Team bf29470384 Export of internal Abseil changes.
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bdce7e57e9e886eff1114d0266781b443f7ec639 by Derek Mauro <dmauro@google.com>:

Change {Get|Set}EnvironmentVariable to {Get|Set}EnvironmentVariableA for
compatibility with /DUNICODE.

PiperOrigin-RevId: 239229514

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2276ed502326a044a84060d34eb19d499e3a3be2 by Derek Mauro <dmauro@google.com>:

Import of CCTZ from GitHub.

PiperOrigin-RevId: 239228622

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a462efb970ff43b08a362ef2343fb75ac1295a50 by Derek Mauro <dmauro@google.com>:

Adding linking of CoreFoundation to CMakeLists in absl/time.
Import https://github.com/abseil/abseil-cpp/pull/280.

Fix #283

PiperOrigin-RevId: 239220785

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fc23327b97f940c682aae1956cf7a1bf87f88c06 by Derek Mauro <dmauro@google.com>:

Add hermetic test script that uses Docker to build with a very recent
version of gcc (8.3.0 today) with libstdc++ and bazel.

PiperOrigin-RevId: 239220448

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418c08a8f6a53e63b84e39473035774417ca3aa7 by Derek Mauro <dmauro@google.com>:

Disable part of the variant exeception safety test on move assignment
when using versions of libstd++ that contain a bug.
https://gcc.gnu.org/bugzilla/show_bug.cgi?id=87431#c7

PiperOrigin-RevId: 239062455

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799722217aeda79679577843c91d5be62cbcbb42 by Matt Calabrese <calabrese@google.com>:

Add internal-only IsSwappable traits corresponding to std::is_swappable and std::is_nothrow_swappable, which are used with the swap implementations of optional and variant.

PiperOrigin-RevId: 239049448

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aa46a036038a3de5c68ac5e5d3b4bf76f818d2ea by CJ Johnson <johnsoncj@google.com>:

Make InlinedVectorStorage constructor explicit

PiperOrigin-RevId: 239044361

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17949715b3aa21c794701f69f2154e91b6acabc3 by CJ Johnson <johnsoncj@google.com>:

Add absl namesapce to internal/inlined_vector.h

PiperOrigin-RevId: 239030789

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834628325953078cc08ed10d23bb8890e5bec897 by Derek Mauro <dmauro@google.com>:

Add test script that uses Docker to build Abseil with gcc-4.8,
libstdc++, and cmake.

PiperOrigin-RevId: 239028433

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80fe24149ed73ed2ced995ad1e372fb060c60427 by CJ Johnson <johnsoncj@google.com>:

Factors data members of InlinedVector into an impl type called InlinedVectorStorage so that (in future changes) the contents of a vector can be grouped together with a single pointer.

PiperOrigin-RevId: 239021086

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585331436d5d4d79f845e45dcf79d918a0dc6169 by Derek Mauro <dmauro@google.com>:

Add -Wno-missing-field-initializers to gcc compiler flags.
gcc-4.x has spurious missing field initializer warnings.
https://gcc.gnu.org/bugzilla/show_bug.cgi?id=36750

PiperOrigin-RevId: 239017217

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94602fe4e33ee3a552a7f2939c0f57a992f55075 by Abseil Team <absl-team@google.com>:

Formatting fixes.

PiperOrigin-RevId: 238983038

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a1c1b63c08505574e0a8c491561840cecb2bb93e by Derek Mauro <dmauro@google.com>:

Add hermetic test script that uses Docker to build with a very recent
version of clang with libc++ and bazel.

PiperOrigin-RevId: 238669118

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e525f8d20bc2f79a0d69336b902f63858f3bff9d by Derek Mauro <dmauro@google.com>:

Disable the test optionalTest.InPlaceTSFINAEBug until libc++ is updated.

PiperOrigin-RevId: 238661703

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f99a2a0b5ec424a059678f7f226600f137b4c74e by Derek Mauro <dmauro@google.com>:

Correct the check for the FlatHashMap-Any test bug (list conditions
instead of platforms when possible)

PiperOrigin-RevId: 238653344

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777928035dbcbf39f361eb7d10dc3696822f692f by Jon Cohen <cohenjon@google.com>:

Add install rules for Abseil CMake.

These are attempted to be limited to in-project installation.  This serves two purposes -- first it's morally the same as using Abseil in-source, except you don't have to rebuild us every time.  Second, the presence of an install rule makes life massively simpler for package manager maintainers.

Currently this doesn't install absl tests or testonly libraries.  This can be added in a follow-up patch.

Fixes #38, Fixes #80, Closes #182

PiperOrigin-RevId: 238645836

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ded1c6ce697c191b7a6ff14572b3e6d183117b2c by Derek Mauro <dmauro@google.com>:

Add hermetic test script that uses Docker to build with a very recent
version of clang with libstdc++ and bazel.

PiperOrigin-RevId: 238517815
GitOrigin-RevId: bdce7e57e9e886eff1114d0266781b443f7ec639
Change-Id: I6f745869cb8ef63851891ccac05ae9a7dd241c4f
2019-03-19 14:19:10 -04:00

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// Copyright 2018 The Abseil Authors.
//
// Licensed under the Apache License, Version 2.0 (the "License");
// you may not use this file except in compliance with the License.
// You may obtain a copy of the License at
//
// https://www.apache.org/licenses/LICENSE-2.0
//
// Unless required by applicable law or agreed to in writing, software
// distributed under the License is distributed on an "AS IS" BASIS,
// WITHOUT WARRANTIES OR CONDITIONS OF ANY KIND, either express or implied.
// See the License for the specific language governing permissions and
// limitations under the License.
//
// -----------------------------------------------------------------------------
// File: civil_time.h
// -----------------------------------------------------------------------------
//
// This header file defines abstractions for computing with "civil time".
// The term "civil time" refers to the legally recognized human-scale time
// that is represented by the six fields `YYYY-MM-DD hh:mm:ss`. A "date"
// is perhaps the most common example of a civil time (represented here as
// an `absl::CivilDay`).
//
// Modern-day civil time follows the Gregorian Calendar and is a
// time-zone-independent concept: a civil time of "2015-06-01 12:00:00", for
// example, is not tied to a time zone. Put another way, a civil time does not
// map to a unique point in time; a civil time must be mapped to an absolute
// time *through* a time zone.
//
// Because a civil time is what most people think of as "time," it is common to
// map absolute times to civil times to present to users.
//
// Time zones define the relationship between absolute and civil times. Given an
// absolute or civil time and a time zone, you can compute the other time:
//
// Civil Time = F(Absolute Time, Time Zone)
// Absolute Time = G(Civil Time, Time Zone)
//
// The Abseil time library allows you to construct such civil times from
// absolute times; consult time.h for such functionality.
//
// This library provides six classes for constructing civil-time objects, and
// provides several helper functions for rounding, iterating, and performing
// arithmetic on civil-time objects, while avoiding complications like
// daylight-saving time (DST):
//
// * `absl::CivilSecond`
// * `absl::CivilMinute`
// * `absl::CivilHour`
// * `absl::CivilDay`
// * `absl::CivilMonth`
// * `absl::CivilYear`
//
// Example:
//
// // Construct a civil-time object for a specific day
// const absl::CivilDay cd(1969, 07, 20);
//
// // Construct a civil-time object for a specific second
// const absl::CivilSecond cd(2018, 8, 1, 12, 0, 1);
//
// Note: In C++14 and later, this library is usable in a constexpr context.
//
// Example:
//
// // Valid in C++14
// constexpr absl::CivilDay cd(1969, 07, 20);
#ifndef ABSL_TIME_CIVIL_TIME_H_
#define ABSL_TIME_CIVIL_TIME_H_
#include <string>
#include "absl/strings/string_view.h"
#include "absl/time/internal/cctz/include/cctz/civil_time.h"
namespace absl {
namespace time_internal {
struct second_tag : cctz::detail::second_tag {};
struct minute_tag : second_tag, cctz::detail::minute_tag {};
struct hour_tag : minute_tag, cctz::detail::hour_tag {};
struct day_tag : hour_tag, cctz::detail::day_tag {};
struct month_tag : day_tag, cctz::detail::month_tag {};
struct year_tag : month_tag, cctz::detail::year_tag {};
} // namespace time_internal
// -----------------------------------------------------------------------------
// CivilSecond, CivilMinute, CivilHour, CivilDay, CivilMonth, CivilYear
// -----------------------------------------------------------------------------
//
// Each of these civil-time types is a simple value type with the same
// interface for construction and the same six accessors for each of the civil
// time fields (year, month, day, hour, minute, and second, aka YMDHMS). These
// classes differ only in their alignment, which is indicated by the type name
// and specifies the field on which arithmetic operates.
//
// CONSTRUCTION
//
// Each of the civil-time types can be constructed in two ways: by directly
// passing to the constructor up to six integers representing the YMDHMS fields,
// or by copying the YMDHMS fields from a differently aligned civil-time type.
// Omitted fields are assigned their minimum valid value. Hours, minutes, and
// seconds will be set to 0, month and day will be set to 1. Since there is no
// minimum year, the default is 1970.
//
// Examples:
//
// absl::CivilDay default_value; // 1970-01-01 00:00:00
//
// absl::CivilDay a(2015, 2, 3); // 2015-02-03 00:00:00
// absl::CivilDay b(2015, 2, 3, 4, 5, 6); // 2015-02-03 00:00:00
// absl::CivilDay c(2015); // 2015-01-01 00:00:00
//
// absl::CivilSecond ss(2015, 2, 3, 4, 5, 6); // 2015-02-03 04:05:06
// absl::CivilMinute mm(ss); // 2015-02-03 04:05:00
// absl::CivilHour hh(mm); // 2015-02-03 04:00:00
// absl::CivilDay d(hh); // 2015-02-03 00:00:00
// absl::CivilMonth m(d); // 2015-02-01 00:00:00
// absl::CivilYear y(m); // 2015-01-01 00:00:00
//
// m = absl::CivilMonth(y); // 2015-01-01 00:00:00
// d = absl::CivilDay(m); // 2015-01-01 00:00:00
// hh = absl::CivilHour(d); // 2015-01-01 00:00:00
// mm = absl::CivilMinute(hh); // 2015-01-01 00:00:00
// ss = absl::CivilSecond(mm); // 2015-01-01 00:00:00
//
// Each civil-time class is aligned to the civil-time field indicated in the
// class's name after normalization. Alignment is performed by setting all the
// inferior fields to their minimum valid value (as described above). The
// following are examples of how each of the six types would align the fields
// representing November 22, 2015 at 12:34:56 in the afternoon. (Note: the
// string format used here is not important; it's just a shorthand way of
// showing the six YMDHMS fields.)
//
// absl::CivilSecond : 2015-11-22 12:34:56
// absl::CivilMinute : 2015-11-22 12:34:00
// absl::CivilHour : 2015-11-22 12:00:00
// absl::CivilDay : 2015-11-22 00:00:00
// absl::CivilMonth : 2015-11-01 00:00:00
// absl::CivilYear : 2015-01-01 00:00:00
//
// Each civil-time type performs arithmetic on the field to which it is
// aligned. This means that adding 1 to an absl::CivilDay increments the day
// field (normalizing as necessary), and subtracting 7 from an absl::CivilMonth
// operates on the month field (normalizing as necessary). All arithmetic
// produces a valid civil time. Difference requires two similarly aligned
// civil-time objects and returns the scalar answer in units of the objects'
// alignment. For example, the difference between two absl::CivilHour objects
// will give an answer in units of civil hours.
//
// ALIGNMENT CONVERSION
//
// The alignment of a civil-time object cannot change, but the object may be
// used to construct a new object with a different alignment. This is referred
// to as "realigning". When realigning to a type with the same or more
// precision (e.g., absl::CivilDay -> absl::CivilSecond), the conversion may be
// performed implicitly since no information is lost. However, if information
// could be discarded (e.g., CivilSecond -> CivilDay), the conversion must
// be explicit at the call site.
//
// Examples:
//
// void UseDay(absl::CivilDay day);
//
// absl::CivilSecond cs;
// UseDay(cs); // Won't compile because data may be discarded
// UseDay(absl::CivilDay(cs)); // OK: explicit conversion
//
// absl::CivilDay cd;
// UseDay(cd); // OK: no conversion needed
//
// absl::CivilMonth cm;
// UseDay(cm); // OK: implicit conversion to absl::CivilDay
//
// NORMALIZATION
//
// Normalization takes invalid values and adjusts them to produce valid values.
// Within the civil-time library, integer arguments passed to the Civil*
// constructors may be out-of-range, in which case they are normalized by
// carrying overflow into a field of courser granularity to produce valid
// civil-time objects. This normalization enables natural arithmetic on
// constructor arguments without worrying about the field's range.
//
// Examples:
//
// // Out-of-range; normalized to 2016-11-01
// absl::CivilDay d(2016, 10, 32);
// // Out-of-range, negative: normalized to 2016-10-30T23
// absl::CivilHour h1(2016, 10, 31, -1);
// // Normalization is cumulative: normalized to 2016-10-30T23
// absl::CivilHour h2(2016, 10, 32, -25);
//
// Note: If normalization is undesired, you can signal an error by comparing
// the constructor arguments to the normalized values returned by the YMDHMS
// properties.
//
// COMPARISON
//
// Comparison between civil-time objects considers all six YMDHMS fields,
// regardless of the type's alignment. Comparison between differently aligned
// civil-time types is allowed.
//
// Examples:
//
// absl::CivilDay feb_3(2015, 2, 3); // 2015-02-03 00:00:00
// absl::CivilDay mar_4(2015, 3, 4); // 2015-03-04 00:00:00
// // feb_3 < mar_4
// // absl::CivilYear(feb_3) == absl::CivilYear(mar_4)
//
// absl::CivilSecond feb_3_noon(2015, 2, 3, 12, 0, 0); // 2015-02-03 12:00:00
// // feb_3 < feb_3_noon
// // feb_3 == absl::CivilDay(feb_3_noon)
//
// // Iterates all the days of February 2015.
// for (absl::CivilDay d(2015, 2, 1); d < absl::CivilMonth(2015, 3); ++d) {
// // ...
// }
//
// ARITHMETIC
//
// Civil-time types support natural arithmetic operators such as addition,
// subtraction, and difference. Arithmetic operates on the civil-time field
// indicated in the type's name. Difference operators require arguments with
// the same alignment and return the answer in units of the alignment.
//
// Example:
//
// absl::CivilDay a(2015, 2, 3);
// ++a; // 2015-02-04 00:00:00
// --a; // 2015-02-03 00:00:00
// absl::CivilDay b = a + 1; // 2015-02-04 00:00:00
// absl::CivilDay c = 1 + b; // 2015-02-05 00:00:00
// int n = c - a; // n = 2 (civil days)
// int m = c - absl::CivilMonth(c); // Won't compile: different types.
//
// ACCESSORS
//
// Each civil-time type has accessors for all six of the civil-time fields:
// year, month, day, hour, minute, and second.
//
// civil_year_t year()
// int month()
// int day()
// int hour()
// int minute()
// int second()
//
// Recall that fields inferior to the type's aligment will be set to their
// minimum valid value.
//
// Example:
//
// absl::CivilDay d(2015, 6, 28);
// // d.year() == 2015
// // d.month() == 6
// // d.day() == 28
// // d.hour() == 0
// // d.minute() == 0
// // d.second() == 0
//
// CASE STUDY: Adding a month to January 31.
//
// One of the classic questions that arises when considering a civil time
// library (or a date library or a date/time library) is this:
// "What is the result of adding a month to January 31?"
// This is an interesting question because it is unclear what is meant by a
// "month", and several different answers are possible, depending on context:
//
// 1. March 3 (or 2 if a leap year), if "add a month" means to add a month to
// the current month, and adjust the date to overflow the extra days into
// March. In this case the result of "February 31" would be normalized as
// within the civil-time library.
// 2. February 28 (or 29 if a leap year), if "add a month" means to add a
// month, and adjust the date while holding the resulting month constant.
// In this case, the result of "February 31" would be truncated to the last
// day in February.
// 3. An error. The caller may get some error, an exception, an invalid date
// object, or perhaps return `false`. This may make sense because there is
// no single unambiguously correct answer to the question.
//
// Practically speaking, any answer that is not what the programmer intended
// is the wrong answer.
//
// The Abseil time library avoids this problem by making it impossible to
// ask ambiguous questions. All civil-time objects are aligned to a particular
// civil-field boundary (such as aligned to a year, month, day, hour, minute,
// or second), and arithmetic operates on the field to which the object is
// aligned. This means that in order to "add a month" the object must first be
// aligned to a month boundary, which is equivalent to the first day of that
// month.
//
// Of course, there are ways to compute an answer the question at hand using
// this Abseil time library, but they require the programmer to be explicit
// about the answer they expect. To illustrate, let's see how to compute all
// three of the above possible answers to the question of "Jan 31 plus 1
// month":
//
// Example:
//
// const absl::CivilDay d(2015, 1, 31);
//
// // Answer 1:
// // Add 1 to the month field in the constructor, and rely on normalization.
// const auto normalized = absl::CivilDay(d.year(), d.month() + 1, d.day());
// // normalized == 2015-03-03 (aka Feb 31)
//
// // Answer 2:
// // Add 1 to month field, capping to the end of next month.
// const auto next_month = absl::CivilMonth(d) + 1;
// const auto last_day_of_next_month = absl::CivilDay(next_month + 1) - 1;
// const auto capped = std::min(normalized, last_day_of_next_month);
// // capped == 2015-02-28
//
// // Answer 3:
// // Signal an error if the normalized answer is not in next month.
// if (absl::CivilMonth(normalized) != next_month) {
// // error, month overflow
// }
//
using CivilSecond =
time_internal::cctz::detail::civil_time<time_internal::second_tag>;
using CivilMinute =
time_internal::cctz::detail::civil_time<time_internal::minute_tag>;
using CivilHour =
time_internal::cctz::detail::civil_time<time_internal::hour_tag>;
using CivilDay =
time_internal::cctz::detail::civil_time<time_internal::day_tag>;
using CivilMonth =
time_internal::cctz::detail::civil_time<time_internal::month_tag>;
using CivilYear =
time_internal::cctz::detail::civil_time<time_internal::year_tag>;
// civil_year_t
//
// Type alias of a civil-time year value. This type is guaranteed to (at least)
// support any year value supported by `time_t`.
//
// Example:
//
// absl::CivilSecond cs = ...;
// absl::civil_year_t y = cs.year();
// cs = absl::CivilSecond(y, 1, 1, 0, 0, 0); // CivilSecond(CivilYear(cs))
//
using civil_year_t = time_internal::cctz::year_t;
// civil_diff_t
//
// Type alias of the difference between two civil-time values.
// This type is used to indicate arguments that are not
// normalized (such as parameters to the civil-time constructors), the results
// of civil-time subtraction, or the operand to civil-time addition.
//
// Example:
//
// absl::civil_diff_t n_sec = cs1 - cs2; // cs1 == cs2 + n_sec;
//
using civil_diff_t = time_internal::cctz::diff_t;
// Weekday::monday, Weekday::tuesday, Weekday::wednesday, Weekday::thursday,
// Weekday::friday, Weekday::saturday, Weekday::sunday
//
// The Weekday enum class represents the civil-time concept of a "weekday" with
// members for all days of the week.
//
// absl::Weekday wd = absl::Weekday::thursday;
//
using Weekday = time_internal::cctz::weekday;
// GetWeekday()
//
// Returns the absl::Weekday for the given absl::CivilDay.
//
// Example:
//
// absl::CivilDay a(2015, 8, 13);
// absl::Weekday wd = absl::GetWeekday(a); // wd == absl::Weekday::thursday
//
inline Weekday GetWeekday(CivilDay cd) {
return time_internal::cctz::get_weekday(cd);
}
// NextWeekday()
// PrevWeekday()
//
// Returns the absl::CivilDay that strictly follows or precedes a given
// absl::CivilDay, and that falls on the given absl::Weekday.
//
// Example, given the following month:
//
// August 2015
// Su Mo Tu We Th Fr Sa
// 1
// 2 3 4 5 6 7 8
// 9 10 11 12 13 14 15
// 16 17 18 19 20 21 22
// 23 24 25 26 27 28 29
// 30 31
//
// absl::CivilDay a(2015, 8, 13);
// // absl::GetWeekday(a) == absl::Weekday::thursday
// absl::CivilDay b = absl::NextWeekday(a, absl::Weekday::thursday);
// // b = 2015-08-20
// absl::CivilDay c = absl::PrevWeekday(a, absl::Weekday::thursday);
// // c = 2015-08-06
//
// absl::CivilDay d = ...
// // Gets the following Thursday if d is not already Thursday
// absl::CivilDay thurs1 = absl::PrevWeekday(d, absl::Weekday::thursday) + 7;
// // Gets the previous Thursday if d is not already Thursday
// absl::CivilDay thurs2 = absl::NextWeekday(d, absl::Weekday::thursday) - 7;
//
inline CivilDay NextWeekday(CivilDay cd, Weekday wd) {
return CivilDay(time_internal::cctz::next_weekday(cd, wd));
}
inline CivilDay PrevWeekday(CivilDay cd, Weekday wd) {
return CivilDay(time_internal::cctz::prev_weekday(cd, wd));
}
// GetYearDay()
//
// Returns the day-of-year for the given absl::CivilDay.
//
// Example:
//
// absl::CivilDay a(2015, 1, 1);
// int yd_jan_1 = absl::GetYearDay(a); // yd_jan_1 = 1
// absl::CivilDay b(2015, 12, 31);
// int yd_dec_31 = absl::GetYearDay(b); // yd_dec_31 = 365
//
inline int GetYearDay(CivilDay cd) {
return time_internal::cctz::get_yearday(cd);
}
// FormatCivilTime()
//
// Formats the given civil-time value into a string value of the following
// format:
//
// Type | Format
// ---------------------------------
// CivilSecond | YYYY-MM-DDTHH:MM:SS
// CivilMinute | YYYY-MM-DDTHH:MM
// CivilHour | YYYY-MM-DDTHH
// CivilDay | YYYY-MM-DD
// CivilMonth | YYYY-MM
// CivilYear | YYYY
//
// Example:
//
// absl::CivilDay d = absl::CivilDay(1969, 7, 20);
// std::string day_string = absl::FormatCivilTime(d); // "1969-07-20"
//
std::string FormatCivilTime(CivilSecond c);
std::string FormatCivilTime(CivilMinute c);
std::string FormatCivilTime(CivilHour c);
std::string FormatCivilTime(CivilDay c);
std::string FormatCivilTime(CivilMonth c);
std::string FormatCivilTime(CivilYear c);
namespace time_internal { // For functions found via ADL on civil-time tags.
// Streaming Operators
//
// Each civil-time type may be sent to an output stream using operator<<().
// The result matches the string produced by `FormatCivilTime()`.
//
// Example:
//
// absl::CivilDay d = absl::CivilDay("1969-07-20");
// std::cout << "Date is: " << d << "\n";
//
std::ostream& operator<<(std::ostream& os, CivilYear y);
std::ostream& operator<<(std::ostream& os, CivilMonth m);
std::ostream& operator<<(std::ostream& os, CivilDay d);
std::ostream& operator<<(std::ostream& os, CivilHour h);
std::ostream& operator<<(std::ostream& os, CivilMinute m);
std::ostream& operator<<(std::ostream& os, CivilSecond s);
} // namespace time_internal
} // namespace absl
#endif // ABSL_TIME_CIVIL_TIME_H_