JulianCalendar.cs source code in C# .NET

Source code for the .NET framework in C#

                        

Code:

/ Dotnetfx_Win7_3.5.1 / Dotnetfx_Win7_3.5.1 / 3.5.1 / DEVDIV / depot / DevDiv / releases / whidbey / NetFXspW7 / ndp / clr / src / BCL / System / Globalization / JulianCalendar.cs / 1 / JulianCalendar.cs

                            // ==++== 
//
//   Copyright (c) Microsoft Corporation.  All rights reserved.
//
// ==--== 
namespace System.Globalization {
 
    using System; 
    //
    // This class implements the Julian calendar. In 48 B.C. Julius Caesar ordered a calendar reform, and this calendar 
    // is called Julian calendar. It consisted of a solar year of twelve months and of 365 days with an extra day
    // every fourth year.
    //*
    //*  Calendar support range: 
    //*      Calendar    Minimum     Maximum
    //*      ==========  ==========  ========== 
    //*      Gregorian   0001/01/01   9999/12/31 
    //*      Julia       0001/01/03   9999/10/19
 
    [Serializable]
[System.Runtime.InteropServices.ComVisible(true)]
    public class JulianCalendar : Calendar {
 

        public static readonly int JulianEra = 1; 
 
        private const int DatePartYear = 0;
        private const int DatePartDayOfYear = 1; 
        private const int DatePartMonth = 2;
        private const int DatePartDay = 3;

        // Number of days in a non-leap year 
        private const int JulianDaysPerYear      = 365;
        // Number of days in 4 years 
        private const int JulianDaysPer4Years    = JulianDaysPerYear * 4 + 1; 

        //internal static Calendar m_defaultInstance; 

        private static readonly int[] DaysToMonth365 =
        {
            0, 31, 59, 90, 120, 151, 181, 212, 243, 273, 304, 334, 365 
        };
 
        private static readonly int[] DaysToMonth366 = 
        {
            0, 31, 60, 91, 121, 152, 182, 213, 244, 274, 305, 335, 366 
        };

        // Gregorian Calendar 9999/12/31 = Julian Calendar 9999/10/19
        // keep it as variable field for serialization compat. 
        internal int MaxYear = 9999;
 
 
        [System.Runtime.InteropServices.ComVisible(false)]
        public override DateTime MinSupportedDateTime 
        {
            get
            {
                return (DateTime.MinValue); 
            }
        } 
 
        [System.Runtime.InteropServices.ComVisible(false)]
        public override DateTime MaxSupportedDateTime 
        {
            get
            {
                return (DateTime.MaxValue); 
            }
        } 
 
        // Return the type of the Julian calendar.
        // 

        [System.Runtime.InteropServices.ComVisible(false)]
        public override CalendarAlgorithmType AlgorithmType
        { 
            get
            { 
                return CalendarAlgorithmType.SolarCalendar; 
            }
        } 

        /*=================================GetDefaultInstance==========================
        **Action: Internal method to provide a default intance of JulianCalendar.  Used by NLS+ implementation
        **       and other calendars. 
        **Returns:
        **Arguments: 
        **Exceptions: 
        ============================================================================*/
        /* 
        internal static Calendar GetDefaultInstance() {
            if (m_defaultInstance == null) {
                m_defaultInstance = new JulianCalendar();
            } 
            return (m_defaultInstance);
        } 
        */ 

        // Construct an instance of gregorian calendar. 

        public JulianCalendar() {
            // There is no system setting of TwoDigitYear max, so set the value here.
            twoDigitYearMax = 2029; 
        }
 
        internal override int ID { 
            get {
                return (CAL_JULIAN); 
            }
        }

        internal void CheckEraRange(int era) { 
            if (era != CurrentEra && era != JulianEra) {
                throw new ArgumentOutOfRangeException("era", Environment.GetResourceString("ArgumentOutOfRange_InvalidEraValue")); 
            } 
        }
 
        internal void CheckYearEraRange(int year, int era) {
            CheckEraRange(era);
            if (year <= 0 || year > MaxYear) {
                throw new ArgumentOutOfRangeException( 
                            "year",
                            String.Format( 
                                CultureInfo.CurrentCulture, 
                                Environment.GetResourceString("ArgumentOutOfRange_Range"),
                                1, 
                                MaxYear));
            }
        }
 
        internal void CheckMonthRange(int month) {
            if (month < 1 || month > 12) { 
                throw new ArgumentOutOfRangeException("month", Environment.GetResourceString("ArgumentOutOfRange_Month")); 
            }
        } 

        /*=================================GetDefaultInstance==========================
        **Action: Check for if the day value is valid.
        **Returns: 
        **Arguments:
        **Exceptions: 
        **Notes: 
        **  Before calling this method, call CheckYearEraRange()/CheckMonthRange() to make
        **  sure year/month values are correct. 
        ============================================================================*/

        internal void CheckDayRange(int year, int month, int day) {
            if (year == 1 && month == 1) 
            {
                // The mimimum supported Julia date is Julian 0001/01/03. 
                if (day < 3) { 
                    throw new ArgumentOutOfRangeException(null,
                        Environment.GetResourceString("ArgumentOutOfRange_BadYearMonthDay")); 
                }
            }
            bool isLeapYear = (year % 4) == 0;
            int[] days = isLeapYear ? DaysToMonth366 : DaysToMonth365; 
            int monthDays = days[month] - days[month - 1];
            if (day < 1 || day > monthDays) { 
                throw new ArgumentOutOfRangeException( 
                            "day",
                            String.Format( 
                                CultureInfo.CurrentCulture,
                                Environment.GetResourceString("ArgumentOutOfRange_Range"),
                                1,
                                monthDays)); 
            }
        } 
 

        // Returns a given date part of this DateTime. This method is used 
        // to compute the year, day-of-year, month, or day part.
        internal int GetDatePart(long ticks, int part)
        {
            // Gregorian 1/1/0001 is Julian 1/3/0001. Remember DateTime(0) is refered to Gregorian 1/1/0001. 
            // The following line convert Gregorian ticks to Julian ticks.
            long julianTicks = ticks + TicksPerDay * 2; 
            // n = number of days since 1/1/0001 
            int n = (int)(julianTicks / TicksPerDay);
            // y4 = number of whole 4-year periods within 100-year period 
            int y4 = n / JulianDaysPer4Years;
            // n = day number within 4-year period
            n -= y4 * JulianDaysPer4Years;
            // y1 = number of whole years within 4-year period 
            int y1 = n / JulianDaysPerYear;
            // Last year has an extra day, so decrement result if 4 
            if (y1 == 4) y1 = 3; 
            // If year was requested, compute and return it
            if (part == DatePartYear) 
            {
                return (y4 * 4 + y1 + 1);
            }
            // n = day number within year 
            n -= y1 * JulianDaysPerYear;
            // If day-of-year was requested, return it 
            if (part == DatePartDayOfYear) 
            {
                return (n + 1); 
            }
            // Leap year calculation looks different from IsLeapYear since y1, y4,
            // and y100 are relative to year 1, not year 0
            bool leapYear = (y1 == 3); 
            int[] days = leapYear? DaysToMonth366: DaysToMonth365;
            // All months have less than 32 days, so n >> 5 is a good conservative 
            // estimate for the month 
            int m = n >> 5 + 1;
            // m = 1-based month number 
            while (n >= days[m]) m++;
            // If month was requested, return it
            if (part == DatePartMonth) return (m);
            // Return 1-based day-of-month 
            return (n - days[m - 1] + 1);
        } 
 
        // Returns the tick count corresponding to the given year, month, and day.
        internal long DateToTicks(int year, int month, int day) 
        {
            int[] days = (year % 4 == 0)? DaysToMonth366: DaysToMonth365;
            int y = year - 1;
            int n = y * 365 + y / 4 + days[month - 1] + day - 1; 
            // Gregorian 1/1/0001 is Julian 1/3/0001. n * TicksPerDay is the ticks in JulianCalendar.
            // Therefore, we subtract two days in the following to convert the ticks in JulianCalendar 
            // to ticks in Gregorian calendar. 
            return ((n - 2) * TicksPerDay);
        } 


        public override DateTime AddMonths(DateTime time, int months)
        { 
            if (months < -120000 || months > 120000) {
                throw new ArgumentOutOfRangeException( 
                            "months", 
                            String.Format(
                                CultureInfo.CurrentCulture, 
                                Environment.GetResourceString("ArgumentOutOfRange_Range"),
                                -120000,
                                120000));
            } 
            int y = GetDatePart(time.Ticks, DatePartYear);
            int m = GetDatePart(time.Ticks, DatePartMonth); 
            int d = GetDatePart(time.Ticks, DatePartDay); 
            int i = m - 1 + months;
            if (i >= 0) { 
                m = i % 12 + 1;
                y = y + i / 12;
            }
            else { 
                m = 12 + (i + 1) % 12;
                y = y + (i - 11) / 12; 
            } 
            int[] daysArray = (y % 4 == 0 && (y % 100 != 0 || y % 400 == 0)) ? DaysToMonth366: DaysToMonth365;
            int days = (daysArray[m] - daysArray[m - 1]); 

            if (d > days) {
                d = days;
            } 
            long ticks = DateToTicks(y, m, d) + time.Ticks % TicksPerDay;
            Calendar.CheckAddResult(ticks, MinSupportedDateTime, MaxSupportedDateTime); 
            return (new DateTime(ticks)); 
        }
 

        public override DateTime AddYears(DateTime time, int years) {
            return (AddMonths(time, years * 12));
        } 

 
        public override int GetDayOfMonth(DateTime time) { 
            return (GetDatePart(time.Ticks, DatePartDay));
        } 


        public override DayOfWeek GetDayOfWeek(DateTime time) {
            return ((DayOfWeek)((int)(time.Ticks / TicksPerDay + 1) % 7)); 
        }
 
 
        public override int GetDayOfYear(DateTime time) {
            return (GetDatePart(time.Ticks, DatePartDayOfYear)); 
        }


        public override int GetDaysInMonth(int year, int month, int era) { 
            CheckYearEraRange(year, era);
            CheckMonthRange(month); 
            int[] days = (year % 4 == 0) ? DaysToMonth366: DaysToMonth365; 
            return (days[month] - days[month - 1]);
        } 


        public override int GetDaysInYear(int year, int era) {
            // Year/Era range is done in IsLeapYear(). 
            return (IsLeapYear(year, era) ? 366:365);
        } 
 

        public override int GetEra(DateTime time) 
        {
            return (JulianEra);
        }
 

        public override int GetMonth(DateTime time) 
        { 
            return (GetDatePart(time.Ticks, DatePartMonth));
        } 


        public override int[] Eras {
            get { 
                return (new int[] {JulianEra});
            } 
        } 

 
        public override int GetMonthsInYear(int year, int era)
        {
            CheckYearEraRange(year, era);
            return (12); 
        }
 
 
        public override int GetYear(DateTime time)
        { 
            return (GetDatePart(time.Ticks, DatePartYear));
        }

 
        public override bool IsLeapDay(int year, int month, int day, int era)
        { 
            CheckMonthRange(month); 
            // Year/Era range check is done in IsLeapYear().
            if (IsLeapYear(year, era)) { 
                CheckDayRange(year, month, day);
                return (month == 2 && day == 29);
            }
            CheckDayRange(year, month, day); 
            return (false);
        } 
 
        // Returns  the leap month in a calendar year of the specified era. This method returns 0
        // if this calendar does not have leap month, or this year is not a leap year. 
        //

        [System.Runtime.InteropServices.ComVisible(false)]
        public override int GetLeapMonth(int year, int era) 
        {
            CheckYearEraRange(year, era); 
            return (0); 
        }
 

        public override bool IsLeapMonth(int year, int month, int era)
        {
            CheckYearEraRange(year, era); 
            CheckMonthRange(month);
            return (false); 
        } 

        // Checks whether a given year in the specified era is a leap year. This method returns true if 
        // year is a leap year, or false if not.
        //

        public override bool IsLeapYear(int year, int era) 
        {
            CheckYearEraRange(year, era); 
            return (year % 4 == 0); 
        }
 

        public override DateTime ToDateTime(int year, int month, int day, int hour, int minute, int second, int millisecond, int era)
        {
            CheckYearEraRange(year, era); 
            CheckMonthRange(month);
            CheckDayRange(year, month, day); 
            if (millisecond < 0 || millisecond >= MillisPerSecond) { 
                throw new ArgumentOutOfRangeException(
                            "millisecond", 
                            String.Format(
                                CultureInfo.CurrentCulture,
                                Environment.GetResourceString("ArgumentOutOfRange_Range"),
                                0, 
                                MillisPerSecond - 1));
            } 
 
            if (hour >= 0 && hour < 24 && minute >= 0 && minute < 60 && second >=0 && second < 60)
            { 
                return new DateTime(DateToTicks(year, month, day) + (new TimeSpan(0, hour, minute, second, millisecond)).Ticks);
            } else
            {
                throw new ArgumentOutOfRangeException(null, Environment.GetResourceString("ArgumentOutOfRange_BadHourMinuteSecond")); 
            }
        } 
 

        public override int TwoDigitYearMax { 
            get {
                return (twoDigitYearMax);
            }
 
            set {
                VerifyWritable(); 
                if (value < 99 || value > MaxYear) { 
                    throw new ArgumentOutOfRangeException(
                                "year", 
                                String.Format(
                                    CultureInfo.CurrentCulture,
                                    Environment.GetResourceString("ArgumentOutOfRange_Range"),
                                    99, 
                                    MaxYear));
 
                } 
                twoDigitYearMax = value;
            } 
        }


        public override int ToFourDigitYear(int year) { 
            if (year > MaxYear) {
                throw new ArgumentOutOfRangeException( 
                            "year", 
                            String.Format(
                                CultureInfo.CurrentCulture, 
                                Environment.GetResourceString("ArgumentOutOfRange_Bounds_Lower_Upper"),
                                1,
                                MaxYear));
            } 
            return (base.ToFourDigitYear(year));
        } 
    } 

} 

// File provided for Reference Use Only by Microsoft Corporation (c) 2007.
// ==++== 
//
//   Copyright (c) Microsoft Corporation.  All rights reserved.
//
// ==--== 
namespace System.Globalization {
 
    using System; 
    //
    // This class implements the Julian calendar. In 48 B.C. Julius Caesar ordered a calendar reform, and this calendar 
    // is called Julian calendar. It consisted of a solar year of twelve months and of 365 days with an extra day
    // every fourth year.
    //*
    //*  Calendar support range: 
    //*      Calendar    Minimum     Maximum
    //*      ==========  ==========  ========== 
    //*      Gregorian   0001/01/01   9999/12/31 
    //*      Julia       0001/01/03   9999/10/19
 
    [Serializable]
[System.Runtime.InteropServices.ComVisible(true)]
    public class JulianCalendar : Calendar {
 

        public static readonly int JulianEra = 1; 
 
        private const int DatePartYear = 0;
        private const int DatePartDayOfYear = 1; 
        private const int DatePartMonth = 2;
        private const int DatePartDay = 3;

        // Number of days in a non-leap year 
        private const int JulianDaysPerYear      = 365;
        // Number of days in 4 years 
        private const int JulianDaysPer4Years    = JulianDaysPerYear * 4 + 1; 

        //internal static Calendar m_defaultInstance; 

        private static readonly int[] DaysToMonth365 =
        {
            0, 31, 59, 90, 120, 151, 181, 212, 243, 273, 304, 334, 365 
        };
 
        private static readonly int[] DaysToMonth366 = 
        {
            0, 31, 60, 91, 121, 152, 182, 213, 244, 274, 305, 335, 366 
        };

        // Gregorian Calendar 9999/12/31 = Julian Calendar 9999/10/19
        // keep it as variable field for serialization compat. 
        internal int MaxYear = 9999;
 
 
        [System.Runtime.InteropServices.ComVisible(false)]
        public override DateTime MinSupportedDateTime 
        {
            get
            {
                return (DateTime.MinValue); 
            }
        } 
 
        [System.Runtime.InteropServices.ComVisible(false)]
        public override DateTime MaxSupportedDateTime 
        {
            get
            {
                return (DateTime.MaxValue); 
            }
        } 
 
        // Return the type of the Julian calendar.
        // 

        [System.Runtime.InteropServices.ComVisible(false)]
        public override CalendarAlgorithmType AlgorithmType
        { 
            get
            { 
                return CalendarAlgorithmType.SolarCalendar; 
            }
        } 

        /*=================================GetDefaultInstance==========================
        **Action: Internal method to provide a default intance of JulianCalendar.  Used by NLS+ implementation
        **       and other calendars. 
        **Returns:
        **Arguments: 
        **Exceptions: 
        ============================================================================*/
        /* 
        internal static Calendar GetDefaultInstance() {
            if (m_defaultInstance == null) {
                m_defaultInstance = new JulianCalendar();
            } 
            return (m_defaultInstance);
        } 
        */ 

        // Construct an instance of gregorian calendar. 

        public JulianCalendar() {
            // There is no system setting of TwoDigitYear max, so set the value here.
            twoDigitYearMax = 2029; 
        }
 
        internal override int ID { 
            get {
                return (CAL_JULIAN); 
            }
        }

        internal void CheckEraRange(int era) { 
            if (era != CurrentEra && era != JulianEra) {
                throw new ArgumentOutOfRangeException("era", Environment.GetResourceString("ArgumentOutOfRange_InvalidEraValue")); 
            } 
        }
 
        internal void CheckYearEraRange(int year, int era) {
            CheckEraRange(era);
            if (year <= 0 || year > MaxYear) {
                throw new ArgumentOutOfRangeException( 
                            "year",
                            String.Format( 
                                CultureInfo.CurrentCulture, 
                                Environment.GetResourceString("ArgumentOutOfRange_Range"),
                                1, 
                                MaxYear));
            }
        }
 
        internal void CheckMonthRange(int month) {
            if (month < 1 || month > 12) { 
                throw new ArgumentOutOfRangeException("month", Environment.GetResourceString("ArgumentOutOfRange_Month")); 
            }
        } 

        /*=================================GetDefaultInstance==========================
        **Action: Check for if the day value is valid.
        **Returns: 
        **Arguments:
        **Exceptions: 
        **Notes: 
        **  Before calling this method, call CheckYearEraRange()/CheckMonthRange() to make
        **  sure year/month values are correct. 
        ============================================================================*/

        internal void CheckDayRange(int year, int month, int day) {
            if (year == 1 && month == 1) 
            {
                // The mimimum supported Julia date is Julian 0001/01/03. 
                if (day < 3) { 
                    throw new ArgumentOutOfRangeException(null,
                        Environment.GetResourceString("ArgumentOutOfRange_BadYearMonthDay")); 
                }
            }
            bool isLeapYear = (year % 4) == 0;
            int[] days = isLeapYear ? DaysToMonth366 : DaysToMonth365; 
            int monthDays = days[month] - days[month - 1];
            if (day < 1 || day > monthDays) { 
                throw new ArgumentOutOfRangeException( 
                            "day",
                            String.Format( 
                                CultureInfo.CurrentCulture,
                                Environment.GetResourceString("ArgumentOutOfRange_Range"),
                                1,
                                monthDays)); 
            }
        } 
 

        // Returns a given date part of this DateTime. This method is used 
        // to compute the year, day-of-year, month, or day part.
        internal int GetDatePart(long ticks, int part)
        {
            // Gregorian 1/1/0001 is Julian 1/3/0001. Remember DateTime(0) is refered to Gregorian 1/1/0001. 
            // The following line convert Gregorian ticks to Julian ticks.
            long julianTicks = ticks + TicksPerDay * 2; 
            // n = number of days since 1/1/0001 
            int n = (int)(julianTicks / TicksPerDay);
            // y4 = number of whole 4-year periods within 100-year period 
            int y4 = n / JulianDaysPer4Years;
            // n = day number within 4-year period
            n -= y4 * JulianDaysPer4Years;
            // y1 = number of whole years within 4-year period 
            int y1 = n / JulianDaysPerYear;
            // Last year has an extra day, so decrement result if 4 
            if (y1 == 4) y1 = 3; 
            // If year was requested, compute and return it
            if (part == DatePartYear) 
            {
                return (y4 * 4 + y1 + 1);
            }
            // n = day number within year 
            n -= y1 * JulianDaysPerYear;
            // If day-of-year was requested, return it 
            if (part == DatePartDayOfYear) 
            {
                return (n + 1); 
            }
            // Leap year calculation looks different from IsLeapYear since y1, y4,
            // and y100 are relative to year 1, not year 0
            bool leapYear = (y1 == 3); 
            int[] days = leapYear? DaysToMonth366: DaysToMonth365;
            // All months have less than 32 days, so n >> 5 is a good conservative 
            // estimate for the month 
            int m = n >> 5 + 1;
            // m = 1-based month number 
            while (n >= days[m]) m++;
            // If month was requested, return it
            if (part == DatePartMonth) return (m);
            // Return 1-based day-of-month 
            return (n - days[m - 1] + 1);
        } 
 
        // Returns the tick count corresponding to the given year, month, and day.
        internal long DateToTicks(int year, int month, int day) 
        {
            int[] days = (year % 4 == 0)? DaysToMonth366: DaysToMonth365;
            int y = year - 1;
            int n = y * 365 + y / 4 + days[month - 1] + day - 1; 
            // Gregorian 1/1/0001 is Julian 1/3/0001. n * TicksPerDay is the ticks in JulianCalendar.
            // Therefore, we subtract two days in the following to convert the ticks in JulianCalendar 
            // to ticks in Gregorian calendar. 
            return ((n - 2) * TicksPerDay);
        } 


        public override DateTime AddMonths(DateTime time, int months)
        { 
            if (months < -120000 || months > 120000) {
                throw new ArgumentOutOfRangeException( 
                            "months", 
                            String.Format(
                                CultureInfo.CurrentCulture, 
                                Environment.GetResourceString("ArgumentOutOfRange_Range"),
                                -120000,
                                120000));
            } 
            int y = GetDatePart(time.Ticks, DatePartYear);
            int m = GetDatePart(time.Ticks, DatePartMonth); 
            int d = GetDatePart(time.Ticks, DatePartDay); 
            int i = m - 1 + months;
            if (i >= 0) { 
                m = i % 12 + 1;
                y = y + i / 12;
            }
            else { 
                m = 12 + (i + 1) % 12;
                y = y + (i - 11) / 12; 
            } 
            int[] daysArray = (y % 4 == 0 && (y % 100 != 0 || y % 400 == 0)) ? DaysToMonth366: DaysToMonth365;
            int days = (daysArray[m] - daysArray[m - 1]); 

            if (d > days) {
                d = days;
            } 
            long ticks = DateToTicks(y, m, d) + time.Ticks % TicksPerDay;
            Calendar.CheckAddResult(ticks, MinSupportedDateTime, MaxSupportedDateTime); 
            return (new DateTime(ticks)); 
        }
 

        public override DateTime AddYears(DateTime time, int years) {
            return (AddMonths(time, years * 12));
        } 

 
        public override int GetDayOfMonth(DateTime time) { 
            return (GetDatePart(time.Ticks, DatePartDay));
        } 


        public override DayOfWeek GetDayOfWeek(DateTime time) {
            return ((DayOfWeek)((int)(time.Ticks / TicksPerDay + 1) % 7)); 
        }
 
 
        public override int GetDayOfYear(DateTime time) {
            return (GetDatePart(time.Ticks, DatePartDayOfYear)); 
        }


        public override int GetDaysInMonth(int year, int month, int era) { 
            CheckYearEraRange(year, era);
            CheckMonthRange(month); 
            int[] days = (year % 4 == 0) ? DaysToMonth366: DaysToMonth365; 
            return (days[month] - days[month - 1]);
        } 


        public override int GetDaysInYear(int year, int era) {
            // Year/Era range is done in IsLeapYear(). 
            return (IsLeapYear(year, era) ? 366:365);
        } 
 

        public override int GetEra(DateTime time) 
        {
            return (JulianEra);
        }
 

        public override int GetMonth(DateTime time) 
        { 
            return (GetDatePart(time.Ticks, DatePartMonth));
        } 


        public override int[] Eras {
            get { 
                return (new int[] {JulianEra});
            } 
        } 

 
        public override int GetMonthsInYear(int year, int era)
        {
            CheckYearEraRange(year, era);
            return (12); 
        }
 
 
        public override int GetYear(DateTime time)
        { 
            return (GetDatePart(time.Ticks, DatePartYear));
        }

 
        public override bool IsLeapDay(int year, int month, int day, int era)
        { 
            CheckMonthRange(month); 
            // Year/Era range check is done in IsLeapYear().
            if (IsLeapYear(year, era)) { 
                CheckDayRange(year, month, day);
                return (month == 2 && day == 29);
            }
            CheckDayRange(year, month, day); 
            return (false);
        } 
 
        // Returns  the leap month in a calendar year of the specified era. This method returns 0
        // if this calendar does not have leap month, or this year is not a leap year. 
        //

        [System.Runtime.InteropServices.ComVisible(false)]
        public override int GetLeapMonth(int year, int era) 
        {
            CheckYearEraRange(year, era); 
            return (0); 
        }
 

        public override bool IsLeapMonth(int year, int month, int era)
        {
            CheckYearEraRange(year, era); 
            CheckMonthRange(month);
            return (false); 
        } 

        // Checks whether a given year in the specified era is a leap year. This method returns true if 
        // year is a leap year, or false if not.
        //

        public override bool IsLeapYear(int year, int era) 
        {
            CheckYearEraRange(year, era); 
            return (year % 4 == 0); 
        }
 

        public override DateTime ToDateTime(int year, int month, int day, int hour, int minute, int second, int millisecond, int era)
        {
            CheckYearEraRange(year, era); 
            CheckMonthRange(month);
            CheckDayRange(year, month, day); 
            if (millisecond < 0 || millisecond >= MillisPerSecond) { 
                throw new ArgumentOutOfRangeException(
                            "millisecond", 
                            String.Format(
                                CultureInfo.CurrentCulture,
                                Environment.GetResourceString("ArgumentOutOfRange_Range"),
                                0, 
                                MillisPerSecond - 1));
            } 
 
            if (hour >= 0 && hour < 24 && minute >= 0 && minute < 60 && second >=0 && second < 60)
            { 
                return new DateTime(DateToTicks(year, month, day) + (new TimeSpan(0, hour, minute, second, millisecond)).Ticks);
            } else
            {
                throw new ArgumentOutOfRangeException(null, Environment.GetResourceString("ArgumentOutOfRange_BadHourMinuteSecond")); 
            }
        } 
 

        public override int TwoDigitYearMax { 
            get {
                return (twoDigitYearMax);
            }
 
            set {
                VerifyWritable(); 
                if (value < 99 || value > MaxYear) { 
                    throw new ArgumentOutOfRangeException(
                                "year", 
                                String.Format(
                                    CultureInfo.CurrentCulture,
                                    Environment.GetResourceString("ArgumentOutOfRange_Range"),
                                    99, 
                                    MaxYear));
 
                } 
                twoDigitYearMax = value;
            } 
        }


        public override int ToFourDigitYear(int year) { 
            if (year > MaxYear) {
                throw new ArgumentOutOfRangeException( 
                            "year", 
                            String.Format(
                                CultureInfo.CurrentCulture, 
                                Environment.GetResourceString("ArgumentOutOfRange_Bounds_Lower_Upper"),
                                1,
                                MaxYear));
            } 
            return (base.ToFourDigitYear(year));
        } 
    } 

} 

// File provided for Reference Use Only by Microsoft Corporation (c) 2007.

                        

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