src/lib/support/TimeUtils.cpp - third_party/github/project-chip/connectedhomeip - Git at Google

 /*
  *
  *    Copyright (c) 2020-2021 Project CHIP Authors
  *    Copyright (c) 2013-2017 Nest Labs, Inc.
  *    All rights reserved.
  *
  *    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
  *
  *        http://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
  *      Various utility functions for dealing with time and dates.
  *
  */

 #include <limits>
 #include <stdint.h>
 #include <type_traits>

 #include <lib/core/CHIPCore.h>
 #include <lib/support/SafeInt.h>

 #include "TimeUtils.h"

 namespace chip {

 enum
 {
     // Number of days during the invariant part of the year (after the leap day).
     kDaysFromMarch1ToDecember31 = 306,

     // Number of years in a Gregorian "cycle", where a cycle is the 400-year period
     // over which the Gregorian calendar repeats.
     kYearsPerCycle = 400,

     // Total number of days within cycle.
     kDaysPerCycle = 146097,

     // Total number of days between 0000/03/01 and 1970/01/01.
     kEpochOffsetDays = 719468
 };

 /* Returns the number of days between January 1st and March 1st for a given year.
  */
 static inline uint8_t DaysToMarch1(uint16_t year)
 {
     if (IsLeapYear(year))
         return 60;
     return 59;
 }

 /* Converts a March-based month number (0=March, 1=April, etc.) to a March-1st based day of year (0=March 1st, 1=March 2nd, etc.).
  *
  * NOTE: This is based on the math described in http://howardhinnant.github.io/date_algorithms.html.
  */
 static uint16_t MarchBasedMonthToDayOfYear(uint8_t month)
 {
     return static_cast<uint16_t>((153 * month + 2) / 5);
 }

 /* Converts a March-1st based day of year (0=March 1st, 1=March 2nd, etc.) to a March-based month number (0=March, 1=April, etc.).
  */
 static uint8_t MarchBasedDayOfYearToMonth(uint16_t dayOfYear)
 {
     // This assumes dayOfYear is not using the full uint16_t range, so the cast
     // to uint8_t doesn't overflow.
     return static_cast<uint8_t>((5 * dayOfYear + 2) / 153);
 }

 /**
  *  @def IsLeapYear
  *
  *  @brief
  *    Returns true if the given year is a leap year according to the Gregorian calendar.
  *
  *  @param year
  *    Gregorian calendar year.
  *
  */
 bool IsLeapYear(uint16_t year)
 {
     return (year % kLeapYearInterval) == 0 && ((year % kYearsPerCentury) != 0 || (year % kYearsPerCycle) == 0);
 }

 /**
  *  @def DaysInMonth
  *
  *  @brief
  *    Returns the number of days in the given month/year.
  *
  *  @param year
  *    Gregorian calendar year.
  *
  *  @param month
  *    Month in standard form (1=January ... 12=December).
  *
  *  @return
  *    Number of days in the given month.
  */
 uint8_t DaysInMonth(uint16_t year, uint8_t month)
 {
     static const uint8_t daysInMonth[] = { 31, 28, 31, 30, 31, 30, 31, 31, 30, 31, 30, 31 };

     if (month == kFebruary && IsLeapYear(year))
         return 29;
     if (month >= kJanuary && month <= kDecember)
         return daysInMonth[month - 1];
     return 0;
 }

 /**
  *  @def FirstWeekdayOfYear
  *
  *  @brief
  *    Returns the day of the week for January 1st of the given year.
  *
  *  @param year
  *    Gregorian calendar year.
  *
  *  @return
  *    The day-of-week (0=Sunday...6=Saturday).
  */
 uint8_t FirstWeekdayOfYear(uint16_t year)
 {
     // Compute the day of the week for the first day of the given year using Gauss' algorithm.
     return static_cast<uint8_t>(
         (1 + 5 * ((year - 1) % kLeapYearInterval) + 4 * ((year - 1) % kYearsPerCentury) + 6 * ((year - 1) % kYearsPerCycle)) %
         kDaysPerWeek);
 }

 /**
  *  @def OrdinalDateToCalendarDate
  *
  *  @brief
  *    Convert an ordinal date (year/day-of-year) to a calendar date.
  *
  *  @param year
  *    Gregorian calendar year.
  *
  *  @param dayOfYear
  *    Ordinal day of year, base 1 (1=January 1st, 2=January 2nd, etc.).
  *
  *  @param month
  *    [OUTPUT] Corresponding month in standard form (1=January ... 12=December).
  *
  *  @param dayOfMonth
  *    [OUTPUT] Corresponding day-of-month in standard form (1=1st, 2=2nd, etc.).
  *
  */
 void OrdinalDateToCalendarDate(uint16_t year, uint16_t dayOfYear, uint8_t & month, uint8_t & dayOfMonth)
 {
     uint8_t daysToMarch1 = DaysToMarch1(year);

     // Make dayOfYear base 0.
     dayOfYear = static_cast<uint16_t>(dayOfYear - 1);

     // Adjust dayOfYear to a March 1st base (i.e. 0 = March 1, 1 = March 2, etc.).  This numbers January
     // and February at the end of the range, with the benefit that day numbering is identical between
     // standard and leap years with the exception of the leap day itself.
     if (dayOfYear < daysToMarch1)
         dayOfYear = static_cast<uint16_t>(dayOfYear + kDaysFromMarch1ToDecember31);
     else
         dayOfYear = static_cast<uint16_t>(dayOfYear - daysToMarch1);

     // Compute a March-based month number (i.e. 0=March...11=February) from the day of year.  This is based
     // on the logic in http://howardhinnant.github.io/date_algorithms.html.
     month = MarchBasedDayOfYearToMonth(dayOfYear);

     // Compute the days from March 1st to the start of the corresponding month.
     uint16_t daysFromMarch1ToStartOfMonth = MarchBasedMonthToDayOfYear(month);

     // Compute the day of month in standard form (1=1st, 2=2nd, etc.).
     dayOfMonth = static_cast<uint8_t>(dayOfYear - daysFromMarch1ToStartOfMonth + 1);

     // Convert the month number to standard form (1=January...12=December).
     month = static_cast<uint8_t>(month + (month < 10 ? 3 : -9));
 }

 /**
  *  @def CalendarDateToOrdinalDate
  *
  *  @brief
  *    Convert an calendar date to ordinal form (year/day-of-year).
  *
  *  @param year
  *    Gregorian calendar year.
  *
  *  @param month
  *    Month in standard form (1=January ... 12=December).
  *
  *  @param dayOfMonth
  *    Day-of-month in standard form (1=1st, 2=2nd, etc.).
  *
  *  @param dayOfYear
  *    [OUTPUT] Ordinal day of year, base 1 (1=January 1st, 2=January 2nd, etc.).
  *
  */
 void CalendarDateToOrdinalDate(uint16_t year, uint8_t month, uint8_t dayOfMonth, uint16_t & dayOfYear)
 {
     // Convert month to a March-based month number (i.e. 0=March, 1=April, ...11=February).
     month = static_cast<uint8_t>(month + (month > kFebruary ? -3 : 9));

     // Compute the days from March 1st to the start of the corresponding month.
     dayOfYear = MarchBasedMonthToDayOfYear(month);

     // Adjust dayOfYear to be January-based (0=January 1st, 1=January 2nd...).
     if (dayOfYear < kDaysFromMarch1ToDecember31)
         dayOfYear = static_cast<uint16_t>(dayOfYear + DaysToMarch1(year));
     else
         dayOfYear = static_cast<uint16_t>(dayOfYear - kDaysFromMarch1ToDecember31);

     // Add in day of month, converting to base 1 in the process.
     dayOfYear = static_cast<uint16_t>(dayOfYear + dayOfMonth);
 }

 /**
  *  @def CalendarDateToDaysSinceUnixEpoch
  *
  *  @brief
  *    Convert a calendar date to the number of days since 1970-01-01.
  *
  *  @param year
  *    Gregorian calendar year in the range 1970 to 28276.
  *
  *  @param month
  *    Month in standard form (1=January ... 12=December).
  *
  *  @param dayOfMonth
  *    Day-of-month in standard form (1=1st, 2=2nd, etc.).
  *
  *  @param daysSinceEpoch
  *    [OUTPUT] Number of days since 1970-01-01.
  *
  *  @return
  *    True if the date was converted successfully.  False if the given year falls outside the
  *    representable range.
  *
  *  @note
  *    This function makes no attempt to verify the correct range of any arguments other than year.
  *    Therefore callers must make sure the supplied values are valid prior to calling the function.
  */
 bool CalendarDateToDaysSinceUnixEpoch(uint16_t year, uint8_t month, uint8_t dayOfMonth, uint32_t & daysSinceEpoch)
 {
     // NOTE: This algorithm is based on the logic described in http://howardhinnant.github.io/date_algorithms.html.

     // Return immediately if the year is out of range.
     if (year < kUnixEpochYear || year > kMaxYearInDaysSinceUnixEpoch32)
     {
         daysSinceEpoch = UINT32_MAX;
         return false;
     }

     // Adjust the year and month to be March-based (i.e. 0=March, 1=April, ...11=February).
     if (month <= kFebruary)
     {
         year--;
         month = static_cast<uint8_t>(month + 9);
     }
     else
         month = static_cast<uint8_t>(month - 3);

     // Compute the days from March 1st to the start of the specified day.
     uint16_t dayOfYear = static_cast<uint16_t>(MarchBasedMonthToDayOfYear(month) + (dayOfMonth - 1));

     // Compute the 400-year Gregorian "cycle" within which the given year falls.
     uint16_t cycle = static_cast<uint16_t>(year / kYearsPerCycle);

     // Compute the relative year within the cycle.
     uint32_t yearOfCycle = year - (cycle * kYearsPerCycle);

     // Compute the relative day within the cycle, accounting for leap-years.
     uint32_t dayOfCycle =
         (yearOfCycle * kDaysPerStandardYear) + dayOfYear - (yearOfCycle / kYearsPerCentury) + (yearOfCycle / kLeapYearInterval);

     // Compute the total number of days since the start of the logical calendar (0000-03-01).
     uint32_t daysSinceCalendarStart = (cycle * kDaysPerCycle) + dayOfCycle;

     // Adjust the days value to be days since 1970-01-01.
     daysSinceEpoch = daysSinceCalendarStart - kEpochOffsetDays;

     return true;
 }

 /**
  *  @def DaysSinceUnixEpochToCalendarDate
  *
  *  @brief
  *    Convert the number of days since 1970-01-01 to a calendar date.
  *
  *  @param daysSinceEpoch
  *    Number of days since 1970-01-01.
  *
  *  @param year
  *    [OUTPUT] Gregorian calendar year.
  *
  *  @param month
  *    [OUTPUT] Month in standard form (1=January ... 12=December).
  *
  *  @param dayOfMonth
  *    [OUTPUT] Day-of-month in standard form (1=1st, 2=2nd, etc.).
  *
  *  @return
  *     True if the conversion was successful.  False if the year would not fit
  *     in uint16_t.
  */
 bool DaysSinceUnixEpochToCalendarDate(uint32_t daysSinceEpoch, uint16_t & year, uint8_t & month, uint8_t & dayOfMonth)
 {
     // NOTE: This algorithm is based on the logic described in http://howardhinnant.github.io/date_algorithms.html.
     if (daysSinceEpoch / kDaysPerStandardYear + 1 > std::numeric_limits<std::remove_reference<decltype(year)>::type>::max())
     {
         // Our year calculation will likely overflow.
         return false;
     }

     // Adjust days value to be relative to 0000-03-01.
     daysSinceEpoch += kEpochOffsetDays;

     // Compute the 400-year Gregorian cycle in which the given day resides.
     uint32_t cycle = daysSinceEpoch / kDaysPerCycle;

     // Compute the relative day within the cycle.
     uint32_t dayOfCycle = daysSinceEpoch - (cycle * kDaysPerCycle);

     // Compute the relative year within the cycle, adjusting for leap-years.
     uint16_t yearOfCycle =
         static_cast<uint16_t>((dayOfCycle - dayOfCycle / 1460 + dayOfCycle / 36524 - dayOfCycle / 146096) / kDaysPerStandardYear);

     // Compute the relative day with the year.
     uint16_t dayOfYear = static_cast<uint16_t>(
         dayOfCycle - (yearOfCycle * kDaysPerStandardYear + yearOfCycle / kLeapYearInterval - yearOfCycle / kYearsPerCentury));

     // Compute a March-based month number (i.e. 0=March...11=February) from the day of year.
     month = MarchBasedDayOfYearToMonth(dayOfYear);

     // Compute the days from March 1st to the start of the corresponding month.
     uint16_t daysFromMarch1ToStartOfMonth = MarchBasedMonthToDayOfYear(month);

     // Compute the day of month in standard form (1=1st, 2=2nd, etc.).
     dayOfMonth = static_cast<uint8_t>(dayOfYear - daysFromMarch1ToStartOfMonth + 1);

     // Convert the month number to standard form (1=January...12=December).
     month = static_cast<uint8_t>(month + (month < 10 ? 3 : -9));

     // Compute the year, adjusting for the standard start of year (January).
     year = static_cast<uint16_t>(yearOfCycle + cycle * kYearsPerCycle);
     if (month <= kFebruary)
         year++;
     return true;
 }

 /**
  *  @def AdjustCalendarDate
  *
  *  @brief
  *    Adjust a calendar date by a given number of days (positive or negative).
  *
  *  @param year
  *    [INPUT/OUTPUT] Gregorian calendar year.
  *
  *  @param month
  *    [INPUT/OUTPUT] Month in standard form (1=January ... 12=December).
  *
  *  @param dayOfMonth
  *    [INPUT/OUTPUT] Day-of-month in standard form (1=1st, 2=2nd, etc.).
  *
  *  @param relativeDays
  *    Number of days to add/subtract from given calendar date.
  *
  *  @return
  *    True if the adjustment succeeded.  False if the adjustment would put us
  *    outside the representable date range.
  *
  *  @note
  *    Given date must be equal to or greater than 1970-01-01.
  */
 bool AdjustCalendarDate(uint16_t & year, uint8_t & month, uint8_t & dayOfMonth, int32_t relativeDays)
 {
     uint32_t daysSinceEpoch;
     if (!CalendarDateToDaysSinceUnixEpoch(year, month, dayOfMonth, daysSinceEpoch))
     {
         return false;
     }

     // Make sure we can do our additions without overflowing.
     int64_t adjustedDays = static_cast<int64_t>(daysSinceEpoch) + relativeDays;
     if (!CanCastTo<uint32_t>(adjustedDays))
     {
         return false;
     }

     return DaysSinceUnixEpochToCalendarDate(static_cast<uint32_t>(adjustedDays), year, month, dayOfMonth);
 }

 /**
  *  @def CalendarTimeToSecondsSinceUnixEpoch
  *
  *  @brief
  *    Convert a calendar date and time to the number of seconds since 1970-01-01 00:00:00 UTC.
  *
  *  @details
  *    This function is roughly equivalent to the POSIX gmtime() function with the exception
  *    that the output time value is limited to positive values up to 2^32-1.  This limits the
  *    representable date range to the year 2105.
  *
  *  @note
  *    This function makes no attempt to verify the correct range of any arguments other than year.
  *    Therefore callers must make sure the supplied values are valid prior to invocation.
  *
  *  @param secondsSinceEpoch
  *    Number of seconds since 1970-01-01 00:00:00 UTC.  Note: this value is compatible with
  *    *positive* values of the POSIX time_t value up to the year 2105.
  *
  *  @param year
  *    Gregorian calendar year in the range 1970 to 2105.
  *
  *  @param month
  *    Month in standard form (1=January ... 12=December).
  *
  *  @param dayOfMonth
  *    Day-of-month in standard form (1=1st, 2=2nd, etc.).
  *
  *  @param hour
  *    Hour (0-23).
  *
  *  @param minute
  *    Minute (0-59).
  *
  *  @param second
  *    Second (0-59).
  *
  *  @return
  *    True if the date/time was converted successfully.  False if the given year falls outside the
  *    representable range.
  */
 bool CalendarTimeToSecondsSinceUnixEpoch(uint16_t year, uint8_t month, uint8_t dayOfMonth, uint8_t hour, uint8_t minute,
                                          uint8_t second, uint32_t & secondsSinceEpoch)
 {
     uint32_t daysSinceEpoch;

     // Return immediately if the year is out of range.
     if (year < kUnixEpochYear || year > kMaxYearInSecondsSinceUnixEpoch32)
     {
         secondsSinceEpoch = UINT32_MAX;
         return false;
     }

     CalendarDateToDaysSinceUnixEpoch(year, month, dayOfMonth, daysSinceEpoch);

     secondsSinceEpoch = (daysSinceEpoch * kSecondsPerDay) + (hour * kSecondsPerHour) + (minute * kSecondsPerMinute) + second;

     return true;
 }
 /**
  *  @brief
  *    Convert the number of seconds since 1970-01-01 00:00:00 UTC to a calendar date and time.
  *
  *  @note
  *    If secondsSinceEpoch is large enough this function will generate bad result. The way it is
  *    used in this file the generated result should be valid. Specifically, the largest
  *    possible value of secondsSinceEpoch input is (UINT32_MAX + kChipEpochSecondsSinceUnixEpoch),
  *    when it is called from ChipEpochToCalendarTime().
  */
 static void SecondsSinceUnixEpochToCalendarTime(uint64_t secondsSinceEpoch, uint16_t & year, uint8_t & month, uint8_t & dayOfMonth,
                                                 uint8_t & hour, uint8_t & minute, uint8_t & second)
 {
     uint32_t daysSinceEpoch = static_cast<uint32_t>(secondsSinceEpoch / kSecondsPerDay);
     static_assert((static_cast<uint64_t>(UINT32_MAX) + kChipEpochSecondsSinceUnixEpoch) / kSecondsPerDay <=
                       std::numeric_limits<decltype(daysSinceEpoch)>::max(),
                   "daysSinceEpoch would overflow");
     uint32_t timeOfDay = static_cast<uint32_t>(secondsSinceEpoch - (daysSinceEpoch * kSecondsPerDay));

     // Note: This call to DaysSinceUnixEpochToCalendarDate can't fail, because we
     // can't overflow a uint16_t year with a muximum possible value of the
     // secondsSinceEpoch input.
     static_assert((static_cast<uint64_t>(UINT32_MAX) + kChipEpochSecondsSinceUnixEpoch) / (kDaysPerStandardYear * kSecondsPerDay) +
                           1 <=
                       std::numeric_limits<std::remove_reference<decltype(year)>::type>::max(),
                   "What happened to our year or day lengths?");
     DaysSinceUnixEpochToCalendarDate(daysSinceEpoch, year, month, dayOfMonth);

     hour = static_cast<uint8_t>(timeOfDay / kSecondsPerHour);
     timeOfDay -= (hour * kSecondsPerHour);
     minute = static_cast<uint8_t>(timeOfDay / kSecondsPerMinute);
     timeOfDay -= (minute * kSecondsPerMinute);
     second = static_cast<uint8_t>(timeOfDay);
 }

 /**
  *  @def SecondsSinceUnixEpochToCalendarTime
  *
  *  @brief
  *    Convert the number of seconds since 1970-01-01 00:00:00 UTC to a calendar date and time.
  *
  *  @details
  *    This function is roughly equivalent to the POSIX mktime() function, with the following
  *    exceptions:
  *
  *    - Input time values are limited to positive values up to 2^32-1.  This limits the
  *    representable date range to the year 2105.
  *
  *    - The output time is always UTC (unlike mktime() which outputs time in the process's
  *    configured timezone).
  *
  *  @param secondsSinceEpoch
  *    Number of seconds since 1970-01-01 00:00:00 UTC.  Note: this value is compatible with
  *    *positive* values of the POSIX time_t value up to the year 2105.
  *
  *  @param year
  *    [OUTPUT] Gregorian calendar year.
  *
  *  @param month
  *    [OUTPUT] Month in standard form (1=January ... 12=December).
  *
  *  @param dayOfMonth
  *    [OUTPUT] Day-of-month in standard form (1=1st, 2=2nd, etc.).
  *
  *  @param hour
  *    [OUTPUT] Hour (0-23).
  *
  *  @param minute
  *    [OUTPUT] Minute (0-59).
  *
  *  @param second
  *    [OUTPUT] Second (0-59).
  */
 void SecondsSinceUnixEpochToCalendarTime(uint32_t secondsSinceEpoch, uint16_t & year, uint8_t & month, uint8_t & dayOfMonth,
                                          uint8_t & hour, uint8_t & minute, uint8_t & second)
 {
     SecondsSinceUnixEpochToCalendarTime(static_cast<uint64_t>(secondsSinceEpoch), year, month, dayOfMonth, hour, minute, second);
 }

 bool CalendarToChipEpochTime(uint16_t year, uint8_t month, uint8_t dayOfMonth, uint8_t hour, uint8_t minute, uint8_t second,
                              uint32_t & chipEpochTime)
 {
     VerifyOrReturnError(year >= kChipEpochBaseYear && year <= kChipEpochMaxYear, false);

     uint32_t daysSinceUnixEpoch;
     CalendarDateToDaysSinceUnixEpoch(year, month, dayOfMonth, daysSinceUnixEpoch);

     chipEpochTime = ((daysSinceUnixEpoch - kChipEpochDaysSinceUnixEpoch) * kSecondsPerDay) + (hour * kSecondsPerHour) +
         (minute * kSecondsPerMinute) + second;

     return true;
 }

 void ChipEpochToCalendarTime(uint32_t chipEpochTime, uint16_t & year, uint8_t & month, uint8_t & dayOfMonth, uint8_t & hour,
                              uint8_t & minute, uint8_t & second)
 {
     SecondsSinceUnixEpochToCalendarTime(static_cast<uint64_t>(chipEpochTime) + kChipEpochSecondsSinceUnixEpoch, year, month,
                                         dayOfMonth, hour, minute, second);
 }

 bool ChipEpochToUnixEpochMicros(uint64_t chipEpochTimeMicros, uint64_t & outUnixEpochTimeMicros)
 {
     if ((chipEpochTimeMicros + kChipEpochUsSinceUnixEpoch) < kChipEpochUsSinceUnixEpoch)
     {
         return false;
     }

     outUnixEpochTimeMicros = chipEpochTimeMicros + kChipEpochUsSinceUnixEpoch;
     return true;
 }

 bool UnixEpochToChipEpochMicros(uint64_t unixEpochTimeMicros, uint64_t & outChipEpochTimeMicros)
 {
     VerifyOrReturnValue(unixEpochTimeMicros >= kChipEpochUsSinceUnixEpoch, false);
     outChipEpochTimeMicros = unixEpochTimeMicros - kChipEpochUsSinceUnixEpoch;

     return true;
 }

 bool UnixEpochToChipEpochTime(uint32_t unixEpochTimeSeconds, uint32_t & outChipEpochTimeSeconds)
 {
     VerifyOrReturnError(unixEpochTimeSeconds >= kChipEpochSecondsSinceUnixEpoch, false);

     outChipEpochTimeSeconds = unixEpochTimeSeconds - kChipEpochSecondsSinceUnixEpoch;

     return true;
 }

 } // namespace chip
	/*
	*
	* Copyright (c) 2020-2021 Project CHIP Authors
	* Copyright (c) 2013-2017 Nest Labs, Inc.
	* All rights reserved.
	*
	* 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
	*
	* http://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
	* Various utility functions for dealing with time and dates.
	*
	*/

	#include <limits>
	#include <stdint.h>
	#include <type_traits>

	#include <lib/core/CHIPCore.h>
	#include <lib/support/SafeInt.h>

	#include "TimeUtils.h"

	namespace chip {

	enum
	{
	// Number of days during the invariant part of the year (after the leap day).
	kDaysFromMarch1ToDecember31 = 306,

	// Number of years in a Gregorian "cycle", where a cycle is the 400-year period
	// over which the Gregorian calendar repeats.
	kYearsPerCycle = 400,

	// Total number of days within cycle.
	kDaysPerCycle = 146097,

	// Total number of days between 0000/03/01 and 1970/01/01.
	kEpochOffsetDays = 719468
	};

	/* Returns the number of days between January 1st and March 1st for a given year.
	*/
	static inline uint8_t DaysToMarch1(uint16_t year)
	{
	if (IsLeapYear(year))
	return 60;
	return 59;
	}

	/* Converts a March-based month number (0=March, 1=April, etc.) to a March-1st based day of year (0=March 1st, 1=March 2nd, etc.).
	*
	* NOTE: This is based on the math described in http://howardhinnant.github.io/date_algorithms.html.
	*/
	static uint16_t MarchBasedMonthToDayOfYear(uint8_t month)
	{
	return static_cast<uint16_t>((153 * month + 2) / 5);
	}

	/* Converts a March-1st based day of year (0=March 1st, 1=March 2nd, etc.) to a March-based month number (0=March, 1=April, etc.).
	*/
	static uint8_t MarchBasedDayOfYearToMonth(uint16_t dayOfYear)
	{
	// This assumes dayOfYear is not using the full uint16_t range, so the cast
	// to uint8_t doesn't overflow.
	return static_cast<uint8_t>((5 * dayOfYear + 2) / 153);
	}

	/**
	* @def IsLeapYear
	*
	* @brief
	* Returns true if the given year is a leap year according to the Gregorian calendar.
	*
	* @param year
	* Gregorian calendar year.
	*
	*/
	bool IsLeapYear(uint16_t year)
	{
	return (year % kLeapYearInterval) == 0 && ((year % kYearsPerCentury) != 0 \|\| (year % kYearsPerCycle) == 0);
	}

	/**
	* @def DaysInMonth
	*
	* @brief
	* Returns the number of days in the given month/year.
	*
	* @param year
	* Gregorian calendar year.
	*
	* @param month
	* Month in standard form (1=January ... 12=December).
	*
	* @return
	* Number of days in the given month.
	*/
	uint8_t DaysInMonth(uint16_t year, uint8_t month)
	{
	static const uint8_t daysInMonth[] = { 31, 28, 31, 30, 31, 30, 31, 31, 30, 31, 30, 31 };

	if (month == kFebruary && IsLeapYear(year))
	return 29;
	if (month >= kJanuary && month <= kDecember)
	return daysInMonth[month - 1];
	return 0;
	}

	/**
	* @def FirstWeekdayOfYear
	*
	* @brief
	* Returns the day of the week for January 1st of the given year.
	*
	* @param year
	* Gregorian calendar year.
	*
	* @return
	* The day-of-week (0=Sunday...6=Saturday).
	*/
	uint8_t FirstWeekdayOfYear(uint16_t year)
	{
	// Compute the day of the week for the first day of the given year using Gauss' algorithm.
	return static_cast<uint8_t>(
	(1 + 5 * ((year - 1) % kLeapYearInterval) + 4 * ((year - 1) % kYearsPerCentury) + 6 * ((year - 1) % kYearsPerCycle)) %
	kDaysPerWeek);
	}

	/**
	* @def OrdinalDateToCalendarDate
	*
	* @brief
	* Convert an ordinal date (year/day-of-year) to a calendar date.
	*
	* @param year
	* Gregorian calendar year.
	*
	* @param dayOfYear
	* Ordinal day of year, base 1 (1=January 1st, 2=January 2nd, etc.).
	*
	* @param month
	* [OUTPUT] Corresponding month in standard form (1=January ... 12=December).
	*
	* @param dayOfMonth
	* [OUTPUT] Corresponding day-of-month in standard form (1=1st, 2=2nd, etc.).
	*
	*/
	void OrdinalDateToCalendarDate(uint16_t year, uint16_t dayOfYear, uint8_t & month, uint8_t & dayOfMonth)
	{
	uint8_t daysToMarch1 = DaysToMarch1(year);

	// Make dayOfYear base 0.
	dayOfYear = static_cast<uint16_t>(dayOfYear - 1);

	// Adjust dayOfYear to a March 1st base (i.e. 0 = March 1, 1 = March 2, etc.). This numbers January
	// and February at the end of the range, with the benefit that day numbering is identical between
	// standard and leap years with the exception of the leap day itself.
	if (dayOfYear < daysToMarch1)
	dayOfYear = static_cast<uint16_t>(dayOfYear + kDaysFromMarch1ToDecember31);
	else
	dayOfYear = static_cast<uint16_t>(dayOfYear - daysToMarch1);

	// Compute a March-based month number (i.e. 0=March...11=February) from the day of year. This is based
	// on the logic in http://howardhinnant.github.io/date_algorithms.html.
	month = MarchBasedDayOfYearToMonth(dayOfYear);

	// Compute the days from March 1st to the start of the corresponding month.
	uint16_t daysFromMarch1ToStartOfMonth = MarchBasedMonthToDayOfYear(month);

	// Compute the day of month in standard form (1=1st, 2=2nd, etc.).
	dayOfMonth = static_cast<uint8_t>(dayOfYear - daysFromMarch1ToStartOfMonth + 1);

	// Convert the month number to standard form (1=January...12=December).
	month = static_cast<uint8_t>(month + (month < 10 ? 3 : -9));
	}

	/**
	* @def CalendarDateToOrdinalDate
	*
	* @brief
	* Convert an calendar date to ordinal form (year/day-of-year).
	*
	* @param year
	* Gregorian calendar year.
	*
	* @param month
	* Month in standard form (1=January ... 12=December).
	*
	* @param dayOfMonth
	* Day-of-month in standard form (1=1st, 2=2nd, etc.).
	*
	* @param dayOfYear
	* [OUTPUT] Ordinal day of year, base 1 (1=January 1st, 2=January 2nd, etc.).
	*
	*/
	void CalendarDateToOrdinalDate(uint16_t year, uint8_t month, uint8_t dayOfMonth, uint16_t & dayOfYear)
	{
	// Convert month to a March-based month number (i.e. 0=March, 1=April, ...11=February).
	month = static_cast<uint8_t>(month + (month > kFebruary ? -3 : 9));

	// Compute the days from March 1st to the start of the corresponding month.
	dayOfYear = MarchBasedMonthToDayOfYear(month);

	// Adjust dayOfYear to be January-based (0=January 1st, 1=January 2nd...).
	if (dayOfYear < kDaysFromMarch1ToDecember31)
	dayOfYear = static_cast<uint16_t>(dayOfYear + DaysToMarch1(year));
	else
	dayOfYear = static_cast<uint16_t>(dayOfYear - kDaysFromMarch1ToDecember31);

	// Add in day of month, converting to base 1 in the process.
	dayOfYear = static_cast<uint16_t>(dayOfYear + dayOfMonth);
	}

	/**
	* @def CalendarDateToDaysSinceUnixEpoch
	*
	* @brief
	* Convert a calendar date to the number of days since 1970-01-01.
	*
	* @param year
	* Gregorian calendar year in the range 1970 to 28276.
	*
	* @param month
	* Month in standard form (1=January ... 12=December).
	*
	* @param dayOfMonth
	* Day-of-month in standard form (1=1st, 2=2nd, etc.).
	*
	* @param daysSinceEpoch
	* [OUTPUT] Number of days since 1970-01-01.
	*
	* @return
	* True if the date was converted successfully. False if the given year falls outside the
	* representable range.
	*
	* @note
	* This function makes no attempt to verify the correct range of any arguments other than year.
	* Therefore callers must make sure the supplied values are valid prior to calling the function.
	*/
	bool CalendarDateToDaysSinceUnixEpoch(uint16_t year, uint8_t month, uint8_t dayOfMonth, uint32_t & daysSinceEpoch)
	{
	// NOTE: This algorithm is based on the logic described in http://howardhinnant.github.io/date_algorithms.html.

	// Return immediately if the year is out of range.
	if (year < kUnixEpochYear \|\| year > kMaxYearInDaysSinceUnixEpoch32)
	{
	daysSinceEpoch = UINT32_MAX;
	return false;
	}

	// Adjust the year and month to be March-based (i.e. 0=March, 1=April, ...11=February).
	if (month <= kFebruary)
	{
	year--;
	month = static_cast<uint8_t>(month + 9);
	}
	else
	month = static_cast<uint8_t>(month - 3);

	// Compute the days from March 1st to the start of the specified day.
	uint16_t dayOfYear = static_cast<uint16_t>(MarchBasedMonthToDayOfYear(month) + (dayOfMonth - 1));

	// Compute the 400-year Gregorian "cycle" within which the given year falls.
	uint16_t cycle = static_cast<uint16_t>(year / kYearsPerCycle);

	// Compute the relative year within the cycle.
	uint32_t yearOfCycle = year - (cycle * kYearsPerCycle);

	// Compute the relative day within the cycle, accounting for leap-years.
	uint32_t dayOfCycle =
	(yearOfCycle * kDaysPerStandardYear) + dayOfYear - (yearOfCycle / kYearsPerCentury) + (yearOfCycle / kLeapYearInterval);

	// Compute the total number of days since the start of the logical calendar (0000-03-01).
	uint32_t daysSinceCalendarStart = (cycle * kDaysPerCycle) + dayOfCycle;

	// Adjust the days value to be days since 1970-01-01.
	daysSinceEpoch = daysSinceCalendarStart - kEpochOffsetDays;

	return true;
	}

	/**
	* @def DaysSinceUnixEpochToCalendarDate
	*
	* @brief
	* Convert the number of days since 1970-01-01 to a calendar date.
	*
	* @param daysSinceEpoch
	* Number of days since 1970-01-01.
	*
	* @param year
	* [OUTPUT] Gregorian calendar year.
	*
	* @param month
	* [OUTPUT] Month in standard form (1=January ... 12=December).
	*
	* @param dayOfMonth
	* [OUTPUT] Day-of-month in standard form (1=1st, 2=2nd, etc.).
	*
	* @return
	* True if the conversion was successful. False if the year would not fit
	* in uint16_t.
	*/
	bool DaysSinceUnixEpochToCalendarDate(uint32_t daysSinceEpoch, uint16_t & year, uint8_t & month, uint8_t & dayOfMonth)
	{
	// NOTE: This algorithm is based on the logic described in http://howardhinnant.github.io/date_algorithms.html.
	if (daysSinceEpoch / kDaysPerStandardYear + 1 > std::numeric_limits<std::remove_reference<decltype(year)>::type>::max())
	{
	// Our year calculation will likely overflow.
	return false;
	}

	// Adjust days value to be relative to 0000-03-01.
	daysSinceEpoch += kEpochOffsetDays;

	// Compute the 400-year Gregorian cycle in which the given day resides.
	uint32_t cycle = daysSinceEpoch / kDaysPerCycle;

	// Compute the relative day within the cycle.
	uint32_t dayOfCycle = daysSinceEpoch - (cycle * kDaysPerCycle);

	// Compute the relative year within the cycle, adjusting for leap-years.
	uint16_t yearOfCycle =
	static_cast<uint16_t>((dayOfCycle - dayOfCycle / 1460 + dayOfCycle / 36524 - dayOfCycle / 146096) / kDaysPerStandardYear);

	// Compute the relative day with the year.
	uint16_t dayOfYear = static_cast<uint16_t>(
	dayOfCycle - (yearOfCycle * kDaysPerStandardYear + yearOfCycle / kLeapYearInterval - yearOfCycle / kYearsPerCentury));

	// Compute a March-based month number (i.e. 0=March...11=February) from the day of year.
	month = MarchBasedDayOfYearToMonth(dayOfYear);

	// Compute the days from March 1st to the start of the corresponding month.
	uint16_t daysFromMarch1ToStartOfMonth = MarchBasedMonthToDayOfYear(month);

	// Compute the day of month in standard form (1=1st, 2=2nd, etc.).
	dayOfMonth = static_cast<uint8_t>(dayOfYear - daysFromMarch1ToStartOfMonth + 1);

	// Convert the month number to standard form (1=January...12=December).
	month = static_cast<uint8_t>(month + (month < 10 ? 3 : -9));

	// Compute the year, adjusting for the standard start of year (January).
	year = static_cast<uint16_t>(yearOfCycle + cycle * kYearsPerCycle);
	if (month <= kFebruary)
	year++;
	return true;
	}

	/**
	* @def AdjustCalendarDate
	*
	* @brief
	* Adjust a calendar date by a given number of days (positive or negative).
	*
	* @param year
	* [INPUT/OUTPUT] Gregorian calendar year.
	*
	* @param month
	* [INPUT/OUTPUT] Month in standard form (1=January ... 12=December).
	*
	* @param dayOfMonth
	* [INPUT/OUTPUT] Day-of-month in standard form (1=1st, 2=2nd, etc.).
	*
	* @param relativeDays
	* Number of days to add/subtract from given calendar date.
	*
	* @return
	* True if the adjustment succeeded. False if the adjustment would put us
	* outside the representable date range.
	*
	* @note
	* Given date must be equal to or greater than 1970-01-01.
	*/
	bool AdjustCalendarDate(uint16_t & year, uint8_t & month, uint8_t & dayOfMonth, int32_t relativeDays)
	{
	uint32_t daysSinceEpoch;
	if (!CalendarDateToDaysSinceUnixEpoch(year, month, dayOfMonth, daysSinceEpoch))
	{
	return false;
	}

	// Make sure we can do our additions without overflowing.
	int64_t adjustedDays = static_cast<int64_t>(daysSinceEpoch) + relativeDays;
	if (!CanCastTo<uint32_t>(adjustedDays))
	{
	return false;
	}

	return DaysSinceUnixEpochToCalendarDate(static_cast<uint32_t>(adjustedDays), year, month, dayOfMonth);
	}

	/**
	* @def CalendarTimeToSecondsSinceUnixEpoch
	*
	* @brief
	* Convert a calendar date and time to the number of seconds since 1970-01-01 00:00:00 UTC.
	*
	* @details
	* This function is roughly equivalent to the POSIX gmtime() function with the exception
	* that the output time value is limited to positive values up to 2^32-1. This limits the
	* representable date range to the year 2105.
	*
	* @note
	* This function makes no attempt to verify the correct range of any arguments other than year.
	* Therefore callers must make sure the supplied values are valid prior to invocation.
	*
	* @param secondsSinceEpoch
	* Number of seconds since 1970-01-01 00:00:00 UTC. Note: this value is compatible with
	* positive values of the POSIX time_t value up to the year 2105.
	*
	* @param year
	* Gregorian calendar year in the range 1970 to 2105.
	*
	* @param month
	* Month in standard form (1=January ... 12=December).
	*
	* @param dayOfMonth
	* Day-of-month in standard form (1=1st, 2=2nd, etc.).
	*
	* @param hour
	* Hour (0-23).
	*
	* @param minute
	* Minute (0-59).
	*
	* @param second
	* Second (0-59).
	*
	* @return
	* True if the date/time was converted successfully. False if the given year falls outside the
	* representable range.
	*/
	bool CalendarTimeToSecondsSinceUnixEpoch(uint16_t year, uint8_t month, uint8_t dayOfMonth, uint8_t hour, uint8_t minute,
	uint8_t second, uint32_t & secondsSinceEpoch)
	{
	uint32_t daysSinceEpoch;

	// Return immediately if the year is out of range.
	if (year < kUnixEpochYear \|\| year > kMaxYearInSecondsSinceUnixEpoch32)
	{
	secondsSinceEpoch = UINT32_MAX;
	return false;
	}

	CalendarDateToDaysSinceUnixEpoch(year, month, dayOfMonth, daysSinceEpoch);

	secondsSinceEpoch = (daysSinceEpoch * kSecondsPerDay) + (hour * kSecondsPerHour) + (minute * kSecondsPerMinute) + second;

	return true;
	}
	/**
	* @brief
	* Convert the number of seconds since 1970-01-01 00:00:00 UTC to a calendar date and time.
	*
	* @note
	* If secondsSinceEpoch is large enough this function will generate bad result. The way it is
	* used in this file the generated result should be valid. Specifically, the largest
	* possible value of secondsSinceEpoch input is (UINT32_MAX + kChipEpochSecondsSinceUnixEpoch),
	* when it is called from ChipEpochToCalendarTime().
	*/
	static void SecondsSinceUnixEpochToCalendarTime(uint64_t secondsSinceEpoch, uint16_t & year, uint8_t & month, uint8_t & dayOfMonth,
	uint8_t & hour, uint8_t & minute, uint8_t & second)
	{
	uint32_t daysSinceEpoch = static_cast<uint32_t>(secondsSinceEpoch / kSecondsPerDay);
	static_assert((static_cast<uint64_t>(UINT32_MAX) + kChipEpochSecondsSinceUnixEpoch) / kSecondsPerDay <=
	std::numeric_limits<decltype(daysSinceEpoch)>::max(),
	"daysSinceEpoch would overflow");
	uint32_t timeOfDay = static_cast<uint32_t>(secondsSinceEpoch - (daysSinceEpoch * kSecondsPerDay));

	// Note: This call to DaysSinceUnixEpochToCalendarDate can't fail, because we
	// can't overflow a uint16_t year with a muximum possible value of the
	// secondsSinceEpoch input.
	static_assert((static_cast<uint64_t>(UINT32_MAX) + kChipEpochSecondsSinceUnixEpoch) / (kDaysPerStandardYear * kSecondsPerDay) +
	1 <=
	std::numeric_limits<std::remove_reference<decltype(year)>::type>::max(),
	"What happened to our year or day lengths?");
	DaysSinceUnixEpochToCalendarDate(daysSinceEpoch, year, month, dayOfMonth);

	hour = static_cast<uint8_t>(timeOfDay / kSecondsPerHour);
	timeOfDay -= (hour * kSecondsPerHour);
	minute = static_cast<uint8_t>(timeOfDay / kSecondsPerMinute);
	timeOfDay -= (minute * kSecondsPerMinute);
	second = static_cast<uint8_t>(timeOfDay);
	}

	/**
	* @def SecondsSinceUnixEpochToCalendarTime
	*
	* @brief
	* Convert the number of seconds since 1970-01-01 00:00:00 UTC to a calendar date and time.
	*
	* @details
	* This function is roughly equivalent to the POSIX mktime() function, with the following
	* exceptions:
	*
	* - Input time values are limited to positive values up to 2^32-1. This limits the
	* representable date range to the year 2105.
	*
	* - The output time is always UTC (unlike mktime() which outputs time in the process's
	* configured timezone).
	*
	* @param secondsSinceEpoch
	* Number of seconds since 1970-01-01 00:00:00 UTC. Note: this value is compatible with
	* positive values of the POSIX time_t value up to the year 2105.
	*
	* @param year
	* [OUTPUT] Gregorian calendar year.
	*
	* @param month
	* [OUTPUT] Month in standard form (1=January ... 12=December).
	*
	* @param dayOfMonth
	* [OUTPUT] Day-of-month in standard form (1=1st, 2=2nd, etc.).
	*
	* @param hour
	* [OUTPUT] Hour (0-23).
	*
	* @param minute
	* [OUTPUT] Minute (0-59).
	*
	* @param second
	* [OUTPUT] Second (0-59).
	*/
	void SecondsSinceUnixEpochToCalendarTime(uint32_t secondsSinceEpoch, uint16_t & year, uint8_t & month, uint8_t & dayOfMonth,
	uint8_t & hour, uint8_t & minute, uint8_t & second)
	{
	SecondsSinceUnixEpochToCalendarTime(static_cast<uint64_t>(secondsSinceEpoch), year, month, dayOfMonth, hour, minute, second);
	}

	bool CalendarToChipEpochTime(uint16_t year, uint8_t month, uint8_t dayOfMonth, uint8_t hour, uint8_t minute, uint8_t second,
	uint32_t & chipEpochTime)
	{
	VerifyOrReturnError(year >= kChipEpochBaseYear && year <= kChipEpochMaxYear, false);

	uint32_t daysSinceUnixEpoch;
	CalendarDateToDaysSinceUnixEpoch(year, month, dayOfMonth, daysSinceUnixEpoch);

	chipEpochTime = ((daysSinceUnixEpoch - kChipEpochDaysSinceUnixEpoch) * kSecondsPerDay) + (hour * kSecondsPerHour) +
	(minute * kSecondsPerMinute) + second;

	return true;
	}

	void ChipEpochToCalendarTime(uint32_t chipEpochTime, uint16_t & year, uint8_t & month, uint8_t & dayOfMonth, uint8_t & hour,
	uint8_t & minute, uint8_t & second)
	{
	SecondsSinceUnixEpochToCalendarTime(static_cast<uint64_t>(chipEpochTime) + kChipEpochSecondsSinceUnixEpoch, year, month,
	dayOfMonth, hour, minute, second);
	}

	bool ChipEpochToUnixEpochMicros(uint64_t chipEpochTimeMicros, uint64_t & outUnixEpochTimeMicros)
	{
	if ((chipEpochTimeMicros + kChipEpochUsSinceUnixEpoch) < kChipEpochUsSinceUnixEpoch)
	{
	return false;
	}

	outUnixEpochTimeMicros = chipEpochTimeMicros + kChipEpochUsSinceUnixEpoch;
	return true;
	}

	bool UnixEpochToChipEpochMicros(uint64_t unixEpochTimeMicros, uint64_t & outChipEpochTimeMicros)
	{
	VerifyOrReturnValue(unixEpochTimeMicros >= kChipEpochUsSinceUnixEpoch, false);
	outChipEpochTimeMicros = unixEpochTimeMicros - kChipEpochUsSinceUnixEpoch;

	return true;
	}

	bool UnixEpochToChipEpochTime(uint32_t unixEpochTimeSeconds, uint32_t & outChipEpochTimeSeconds)
	{
	VerifyOrReturnError(unixEpochTimeSeconds >= kChipEpochSecondsSinceUnixEpoch, false);

	outChipEpochTimeSeconds = unixEpochTimeSeconds - kChipEpochSecondsSinceUnixEpoch;

	return true;
	}

	} // namespace chip