TimeSpan.cs source code in C# .NET

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Code:

/ 4.0 / 4.0 / DEVDIV_TFS / Dev10 / Releases / RTMRel / ndp / clr / src / BCL / System / TimeSpan.cs / 1305376 / TimeSpan.cs

                            // ==++== 
//
//   Copyright (c) Microsoft Corporation.  All rights reserved.
//
// ==--== 
namespace System {
    using System.Text; 
    using System; 
    using System.Runtime;
    using System.Runtime.CompilerServices; 
    using System.Runtime.Versioning;
    using System.Diagnostics.Contracts;
    using System.Globalization;
 
    // TimeSpan represents a duration of time.  A TimeSpan can be negative
    // or positive. 
    // 
    // TimeSpan is internally represented as a number of milliseconds.  While
    // this maps well into units of time such as hours and days, any 
    // periods longer than that aren't representable in a nice fashion.
    // For instance, a month can be between 28 and 31 days, while a year
    // can contain 365 or 364 days.  A decade can have between 1 and 3 leapyears,
    // depending on when you map the TimeSpan into the calendar.  This is why 
    // we do not provide Years() or Months().
    // 
[System.Runtime.InteropServices.ComVisible(true)] 
    [Serializable] public struct TimeSpan : IComparable
#if GENERICS_WORK 
        , IComparable, IEquatable, IFormattable
#endif
    {
        public const long    TicksPerMillisecond =  10000; 
        private const double MillisecondsPerTick = 1.0 / TicksPerMillisecond;
 
        public const long TicksPerSecond = TicksPerMillisecond * 1000; 
        private const double SecondsPerTick =  1.0 / TicksPerSecond;
 
        public const long TicksPerMinute = TicksPerSecond * 60;
        private const double MinutesPerTick = 1.0 / TicksPerMinute;

        public const long TicksPerHour = TicksPerMinute * 60; 
        private const double HoursPerTick = 1.0 / TicksPerHour;
 
        public const long TicksPerDay = TicksPerHour * 24; 
        private const double DaysPerTick = 1.0 / TicksPerDay;
 
        private const int MillisPerSecond = 1000;
        private const int MillisPerMinute = MillisPerSecond * 60;
        private const int MillisPerHour = MillisPerMinute * 60;
        private const int MillisPerDay = MillisPerHour * 24; 

        internal const long MaxSeconds = Int64.MaxValue / TicksPerSecond; 
        internal const long MinSeconds = Int64.MinValue / TicksPerSecond; 

        internal const long MaxMilliSeconds = Int64.MaxValue / TicksPerMillisecond; 
        internal const long MinMilliSeconds = Int64.MinValue / TicksPerMillisecond;

        internal const long TicksPerTenthSecond = TicksPerMillisecond * 100;
 
        public static readonly TimeSpan Zero = new TimeSpan(0);
 
        public static readonly TimeSpan MaxValue = new TimeSpan(Int64.MaxValue); 
        public static readonly TimeSpan MinValue = new TimeSpan(Int64.MinValue);
 
        // internal so that DateTime doesn't have to call an extra get
        // method for some arithmetic operations.
        internal long _ticks;
 
        //public TimeSpan() {
        //    _ticks = 0; 
        //} 

        public TimeSpan(long ticks) { 
            this._ticks = ticks;
        }

#if !FEATURE_CORECLR 
        [TargetedPatchingOptOut("Performance critical to inline across NGen image boundaries")]
#endif 
        public TimeSpan(int hours, int minutes, int seconds) { 
            _ticks = TimeToTicks(hours, minutes, seconds);
        } 

        public TimeSpan(int days, int hours, int minutes, int seconds)
            : this(days,hours,minutes,seconds,0)
        { 
        }
 
        public TimeSpan(int days, int hours, int minutes, int seconds, int milliseconds) 
        {
            Int64 totalMilliSeconds = ((Int64)days * 3600 * 24 + (Int64)hours * 3600 + (Int64)minutes * 60 + seconds) * 1000 + milliseconds; 
            if (totalMilliSeconds > MaxMilliSeconds || totalMilliSeconds < MinMilliSeconds)
                throw new ArgumentOutOfRangeException(null, Environment.GetResourceString("Overflow_TimeSpanTooLong"));
            _ticks =  (long)totalMilliSeconds * TicksPerMillisecond;
        } 

        public long Ticks { 
            get { return _ticks; } 
        }
 
        public int Days {
            get { return (int)(_ticks / TicksPerDay); }
        }
 
        public int Hours {
            get { return (int)((_ticks / TicksPerHour) % 24); } 
        } 

        public int Milliseconds { 
            get { return (int)((_ticks / TicksPerMillisecond) % 1000); }
        }

        public int Minutes { 
            get { return (int)((_ticks / TicksPerMinute) % 60); }
        } 
 
        public int Seconds {
            get { return (int)((_ticks / TicksPerSecond) % 60); } 
        }

        public double TotalDays {
            get { return ((double)_ticks) * DaysPerTick; } 
        }
 
        public double TotalHours { 
            get { return (double)_ticks * HoursPerTick; }
        } 

        public double TotalMilliseconds {
            get {
                double temp = (double)_ticks * MillisecondsPerTick; 
                if (temp > MaxMilliSeconds)
                    return (double)MaxMilliSeconds; 
 
                if (temp < MinMilliSeconds)
                    return (double)MinMilliSeconds; 

                return temp;
            }
        } 

        public double TotalMinutes { 
            get { return (double)_ticks * MinutesPerTick; } 
        }
 
        public double TotalSeconds {
#if !FEATURE_CORECLR
            [TargetedPatchingOptOut("Performance critical to inline across NGen image boundaries")]
#endif 
            get { return (double)_ticks * SecondsPerTick; }
        } 
 
        public TimeSpan Add(TimeSpan ts) {
            long result = _ticks + ts._ticks; 
            // Overflow if signs of operands was identical and result's
            // sign was opposite.
            // >> 63 gives the sign bit (either 64 1's or 64 0's).
            if ((_ticks >> 63 == ts._ticks >> 63) && (_ticks >> 63 != result >> 63)) 
                throw new OverflowException(Environment.GetResourceString("Overflow_TimeSpanTooLong"));
            return new TimeSpan(result); 
        } 

 
        // Compares two TimeSpan values, returning an integer that indicates their
        // relationship.
        //
        public static int Compare(TimeSpan t1, TimeSpan t2) { 
            if (t1._ticks > t2._ticks) return 1;
            if (t1._ticks < t2._ticks) return -1; 
            return 0; 
        }
 
        // Returns a value less than zero if this  object
        public int CompareTo(Object value) {
            if (value == null) return 1;
            if (!(value is TimeSpan)) 
                throw new ArgumentException(Environment.GetResourceString("Arg_MustBeTimeSpan"));
            long t = ((TimeSpan)value)._ticks; 
            if (_ticks > t) return 1; 
            if (_ticks < t) return -1;
            return 0; 
        }

#if GENERICS_WORK
        public int CompareTo(TimeSpan value) { 
            long t = value._ticks;
            if (_ticks > t) return 1; 
            if (_ticks < t) return -1; 
            return 0;
        } 
#endif

        public static TimeSpan FromDays(double value) {
            return Interval(value, MillisPerDay); 
        }
 
        public TimeSpan Duration() { 
            if (Ticks==TimeSpan.MinValue.Ticks)
                throw new OverflowException(Environment.GetResourceString("Overflow_Duration")); 
            Contract.EndContractBlock();
            return new TimeSpan(_ticks >= 0? _ticks: -_ticks);
        }
 
        public override bool Equals(Object value) {
            if (value is TimeSpan) { 
                return _ticks == ((TimeSpan)value)._ticks; 
            }
            return false; 
        }

        public bool Equals(TimeSpan obj)
        { 
            return _ticks == obj._ticks;
        } 
 
        public static bool Equals(TimeSpan t1, TimeSpan t2) {
            return t1._ticks == t2._ticks; 
        }

        public override int GetHashCode() {
            return (int)_ticks ^ (int)(_ticks >> 32); 
        }
 
        public static TimeSpan FromHours(double value) { 
            return Interval(value, MillisPerHour);
        } 

        private static TimeSpan Interval(double value, int scale) {
            if (Double.IsNaN(value))
                throw new ArgumentException(Environment.GetResourceString("Arg_CannotBeNaN")); 
            Contract.EndContractBlock();
            double tmp = value * scale; 
            double millis = tmp + (value >= 0? 0.5: -0.5); 
            if ((millis > Int64.MaxValue / TicksPerMillisecond) || (millis < Int64.MinValue / TicksPerMillisecond))
                throw new OverflowException(Environment.GetResourceString("Overflow_TimeSpanTooLong")); 
            return new TimeSpan((long)millis * TicksPerMillisecond);
        }

        public static TimeSpan FromMilliseconds(double value) { 
            return Interval(value, 1);
        } 
 
        public static TimeSpan FromMinutes(double value) {
            return Interval(value, MillisPerMinute); 
        }

        public TimeSpan Negate() {
            if (Ticks==TimeSpan.MinValue.Ticks) 
                throw new OverflowException(Environment.GetResourceString("Overflow_NegateTwosCompNum"));
            Contract.EndContractBlock(); 
            return new TimeSpan(-_ticks); 
        }
 
        public static TimeSpan FromSeconds(double value) {
            return Interval(value, MillisPerSecond);
        }
 
        public TimeSpan Subtract(TimeSpan ts) {
            long result = _ticks - ts._ticks; 
            // Overflow if signs of operands was different and result's 
            // sign was opposite from the first argument's sign.
            // >> 63 gives the sign bit (either 64 1's or 64 0's). 
            if ((_ticks >> 63 != ts._ticks >> 63) && (_ticks >> 63 != result >> 63))
                throw new OverflowException(Environment.GetResourceString("Overflow_TimeSpanTooLong"));
            return new TimeSpan(result);
        } 

#if !FEATURE_CORECLR 
        [TargetedPatchingOptOut("Performance critical to inline across NGen image boundaries")] 
#endif
        public static TimeSpan FromTicks(long value) { 
            return new TimeSpan(value);
        }

        internal static long TimeToTicks(int hour, int minute, int second) { 
            // totalSeconds is bounded by 2^31 * 2^12 + 2^31 * 2^8 + 2^31,
            // which is less than 2^44, meaning we won't overflow totalSeconds. 
            long totalSeconds = (long)hour * 3600 + (long)minute * 60 + (long)second; 
            if (totalSeconds > MaxSeconds || totalSeconds < MinSeconds)
                throw new ArgumentOutOfRangeException(null, Environment.GetResourceString("Overflow_TimeSpanTooLong")); 
            return totalSeconds * TicksPerSecond;
        }

        // See System.Globalization.TimeSpanParse and System.Globalization.TimeSpanFormat 
        #region ParseAndFormat
        public static TimeSpan Parse(String s) { 
            /* Constructs a TimeSpan from a string.  Leading and trailing white space characters are allowed. */ 
            return TimeSpanParse.Parse(s, null);
        } 
        public static TimeSpan Parse(String input, IFormatProvider formatProvider) {
            return TimeSpanParse.Parse(input, formatProvider);
        }
        public static TimeSpan ParseExact(String input, String format, IFormatProvider formatProvider) { 
            return TimeSpanParse.ParseExact(input, format, formatProvider, TimeSpanStyles.None);
        } 
        public static TimeSpan ParseExact(String input, String[] formats, IFormatProvider formatProvider) { 
            return TimeSpanParse.ParseExactMultiple(input, formats, formatProvider, TimeSpanStyles.None);
        } 
        public static TimeSpan ParseExact(String input, String format, IFormatProvider formatProvider, TimeSpanStyles styles) {
            TimeSpanParse.ValidateStyles(styles, "styles");
            return TimeSpanParse.ParseExact(input, format, formatProvider, styles);
        } 
        public static TimeSpan ParseExact(String input, String[] formats, IFormatProvider formatProvider, TimeSpanStyles styles) {
            TimeSpanParse.ValidateStyles(styles, "styles"); 
            return TimeSpanParse.ParseExactMultiple(input, formats, formatProvider, styles); 
        }
        public static Boolean TryParse(String s, out TimeSpan result) { 
            return TimeSpanParse.TryParse(s, null, out result);
        }
        public static Boolean TryParse(String input, IFormatProvider formatProvider, out TimeSpan result) {
            return TimeSpanParse.TryParse(input, formatProvider, out result); 
        }
        public static Boolean TryParseExact(String input, String format, IFormatProvider formatProvider, out TimeSpan result) { 
            return TimeSpanParse.TryParseExact(input, format, formatProvider, TimeSpanStyles.None, out result); 
        }
        public static Boolean TryParseExact(String input, String[] formats, IFormatProvider formatProvider, out TimeSpan result) { 
            return TimeSpanParse.TryParseExactMultiple(input, formats, formatProvider, TimeSpanStyles.None, out result);
        }
        public static Boolean TryParseExact(String input, String format, IFormatProvider formatProvider, TimeSpanStyles styles, out TimeSpan result) {
            TimeSpanParse.ValidateStyles(styles, "styles"); 
            return TimeSpanParse.TryParseExact(input, format, formatProvider, styles, out result);
        } 
        public static Boolean TryParseExact(String input, String[] formats, IFormatProvider formatProvider, TimeSpanStyles styles, out TimeSpan result) { 
            TimeSpanParse.ValidateStyles(styles, "styles");
            return TimeSpanParse.TryParseExactMultiple(input, formats, formatProvider, styles, out result); 
        }
        public override String ToString() {
            return TimeSpanFormat.Format(this, null, null);
        } 
        public String ToString(String format) {
            return TimeSpanFormat.Format(this, format, null); 
        } 
        public String ToString(String format, IFormatProvider formatProvider) {
            if (LegacyMode) { 
                return TimeSpanFormat.Format(this, null, null);
            }
            else {
                return TimeSpanFormat.Format(this, format, formatProvider); 
            }
        } 
        #endregion 

        public static TimeSpan operator -(TimeSpan t) { 
            if (t._ticks==TimeSpan.MinValue._ticks)
                throw new OverflowException(Environment.GetResourceString("Overflow_NegateTwosCompNum"));
            return new TimeSpan(-t._ticks);
        } 

#if !FEATURE_CORECLR 
        [TargetedPatchingOptOut("Performance critical to inline across NGen image boundaries")] 
#endif
        public static TimeSpan operator -(TimeSpan t1, TimeSpan t2) { 
            return t1.Subtract(t2);
        }

        public static TimeSpan operator +(TimeSpan t) { 
            return t;
        } 
 
        public static TimeSpan operator +(TimeSpan t1, TimeSpan t2) {
            return t1.Add(t2); 
        }

#if !FEATURE_CORECLR
        [TargetedPatchingOptOut("Performance critical to inline across NGen image boundaries")] 
#endif
        public static bool operator ==(TimeSpan t1, TimeSpan t2) { 
            return t1._ticks == t2._ticks; 
        }
 
#if !FEATURE_CORECLR
        [TargetedPatchingOptOut("Performance critical to inline across NGen image boundaries")]
#endif
        public static bool operator !=(TimeSpan t1, TimeSpan t2) { 
            return t1._ticks != t2._ticks;
        } 
 
#if !FEATURE_CORECLR
        [TargetedPatchingOptOut("Performance critical to inline across NGen image boundaries")] 
#endif
        public static bool operator <(TimeSpan t1, TimeSpan t2) {
            return t1._ticks < t2._ticks;
        } 

#if !FEATURE_CORECLR 
        [TargetedPatchingOptOut("Performance critical to inline across NGen image boundaries")] 
#endif
        public static bool operator <=(TimeSpan t1, TimeSpan t2) { 
            return t1._ticks <= t2._ticks;
        }

#if !FEATURE_CORECLR 
        [TargetedPatchingOptOut("Performance critical to inline across NGen image boundaries")]
#endif 
        public static bool operator >(TimeSpan t1, TimeSpan t2) { 
            return t1._ticks > t2._ticks;
        } 

#if !FEATURE_CORECLR
        [TargetedPatchingOptOut("Performance critical to inline across NGen image boundaries")]
#endif 
        public static bool operator >=(TimeSpan t1, TimeSpan t2) {
            return t1._ticks >= t2._ticks; 
        } 

 
        //
        // In .NET Framework v1.0 - v3.5 System.TimeSpan did not implement IFormattable
        //    The composite formatter ignores format specifiers on types that do not implement
        //    IFormattable, so the following code would 'just work' by using TimeSpan.ToString() 
        //    under the hood:
        //        String.Format("{0:_someRandomFormatString_}", myTimeSpan); 
        // 
        // In .NET Framework v4.0 System.TimeSpan implements IFormattable.  This causes the
        //    composite formatter to call TimeSpan.ToString(string format, FormatProvider provider) 
        //    and pass in "_someRandomFormatString_" for the format parameter.  When the format
        //    parameter is invalid a FormatException is thrown.
        //
        // The 'NetFx40_TimeSpanLegacyFormatMode' per-AppDomain configuration option and the 'TimeSpan_LegacyFormatMode' 
        // process-wide configuration option allows applications to run with the v1.0 - v3.5 legacy behavior.  When
        // either switch is specified the format parameter is ignored and the default output is returned. 
        // 
        // There are three ways to use the process-wide configuration option:
        // 
        // 1) Config file (MyApp.exe.config)
        //        
        //        
        //          
        //          
        //          
        //         
        // 2) Environment variable
        //        set COMPLUS_TimeSpan_LegacyFormatMode=1 
        // 3) RegistryKey
        //        [HKEY_LOCAL_MACHINE\SOFTWARE\Microsoft\.NETFramework]
        //        "TimeSpan_LegacyFormatMode"=dword:00000001
        // 
#if !FEATURE_CORECLR
        [System.Security.SecurityCritical] 
        [ResourceExposure(ResourceScope.None)] 
        [MethodImplAttribute(MethodImplOptions.InternalCall)]
        private static extern bool LegacyFormatMode(); 
#endif // !FEATURE_CORECLR
        //
        // In Silverlight v4, specifying the APP_EARLIER_THAN_SL4.0 quirks mode allows applications to
        // run in v2 - v3 legacy behavior. 
        //
        [System.Security.SecuritySafeCritical] 
        private static bool GetLegacyFormatMode() { 
#if !FEATURE_CORECLR
            if (LegacyFormatMode()) // FCALL to check COMPLUS_TimeSpan_LegacyFormatMode 
                return true;
            Nullable compatSwitch = AppDomain.CurrentDomain.IsCompatibilitySwitchSet("NetFx40_TimeSpanLegacyFormatMode");
#else
            Nullable compatSwitch = AppDomain.CurrentDomain.IsCompatibilitySwitchSet("APP_EARLIER_THAN_SL4.0"); 
#endif // !FEATURE_CORECLR
            return ((compatSwitch.HasValue && compatSwitch.Value)); 
        } 

        private static bool _legacyConfigChecked; 
        private static bool _legacyMode;

        private static bool LegacyMode {
            [System.Security.SecuritySafeCritical] 
            get {
                if (!_legacyConfigChecked) { 
                    // no need to lock - idempotent 
                    _legacyMode = GetLegacyFormatMode();
                    _legacyConfigChecked = true; 
                }
                return _legacyMode;
            }
        } 
    }
} 

// File provided for Reference Use Only by Microsoft Corporation (c) 2007.
// ==++== 
//
//   Copyright (c) Microsoft Corporation.  All rights reserved.
//
// ==--== 
namespace System {
    using System.Text; 
    using System; 
    using System.Runtime;
    using System.Runtime.CompilerServices; 
    using System.Runtime.Versioning;
    using System.Diagnostics.Contracts;
    using System.Globalization;
 
    // TimeSpan represents a duration of time.  A TimeSpan can be negative
    // or positive. 
    // 
    // TimeSpan is internally represented as a number of milliseconds.  While
    // this maps well into units of time such as hours and days, any 
    // periods longer than that aren't representable in a nice fashion.
    // For instance, a month can be between 28 and 31 days, while a year
    // can contain 365 or 364 days.  A decade can have between 1 and 3 leapyears,
    // depending on when you map the TimeSpan into the calendar.  This is why 
    // we do not provide Years() or Months().
    // 
[System.Runtime.InteropServices.ComVisible(true)] 
    [Serializable] public struct TimeSpan : IComparable
#if GENERICS_WORK 
        , IComparable, IEquatable, IFormattable
#endif
    {
        public const long    TicksPerMillisecond =  10000; 
        private const double MillisecondsPerTick = 1.0 / TicksPerMillisecond;
 
        public const long TicksPerSecond = TicksPerMillisecond * 1000; 
        private const double SecondsPerTick =  1.0 / TicksPerSecond;
 
        public const long TicksPerMinute = TicksPerSecond * 60;
        private const double MinutesPerTick = 1.0 / TicksPerMinute;

        public const long TicksPerHour = TicksPerMinute * 60; 
        private const double HoursPerTick = 1.0 / TicksPerHour;
 
        public const long TicksPerDay = TicksPerHour * 24; 
        private const double DaysPerTick = 1.0 / TicksPerDay;
 
        private const int MillisPerSecond = 1000;
        private const int MillisPerMinute = MillisPerSecond * 60;
        private const int MillisPerHour = MillisPerMinute * 60;
        private const int MillisPerDay = MillisPerHour * 24; 

        internal const long MaxSeconds = Int64.MaxValue / TicksPerSecond; 
        internal const long MinSeconds = Int64.MinValue / TicksPerSecond; 

        internal const long MaxMilliSeconds = Int64.MaxValue / TicksPerMillisecond; 
        internal const long MinMilliSeconds = Int64.MinValue / TicksPerMillisecond;

        internal const long TicksPerTenthSecond = TicksPerMillisecond * 100;
 
        public static readonly TimeSpan Zero = new TimeSpan(0);
 
        public static readonly TimeSpan MaxValue = new TimeSpan(Int64.MaxValue); 
        public static readonly TimeSpan MinValue = new TimeSpan(Int64.MinValue);
 
        // internal so that DateTime doesn't have to call an extra get
        // method for some arithmetic operations.
        internal long _ticks;
 
        //public TimeSpan() {
        //    _ticks = 0; 
        //} 

        public TimeSpan(long ticks) { 
            this._ticks = ticks;
        }

#if !FEATURE_CORECLR 
        [TargetedPatchingOptOut("Performance critical to inline across NGen image boundaries")]
#endif 
        public TimeSpan(int hours, int minutes, int seconds) { 
            _ticks = TimeToTicks(hours, minutes, seconds);
        } 

        public TimeSpan(int days, int hours, int minutes, int seconds)
            : this(days,hours,minutes,seconds,0)
        { 
        }
 
        public TimeSpan(int days, int hours, int minutes, int seconds, int milliseconds) 
        {
            Int64 totalMilliSeconds = ((Int64)days * 3600 * 24 + (Int64)hours * 3600 + (Int64)minutes * 60 + seconds) * 1000 + milliseconds; 
            if (totalMilliSeconds > MaxMilliSeconds || totalMilliSeconds < MinMilliSeconds)
                throw new ArgumentOutOfRangeException(null, Environment.GetResourceString("Overflow_TimeSpanTooLong"));
            _ticks =  (long)totalMilliSeconds * TicksPerMillisecond;
        } 

        public long Ticks { 
            get { return _ticks; } 
        }
 
        public int Days {
            get { return (int)(_ticks / TicksPerDay); }
        }
 
        public int Hours {
            get { return (int)((_ticks / TicksPerHour) % 24); } 
        } 

        public int Milliseconds { 
            get { return (int)((_ticks / TicksPerMillisecond) % 1000); }
        }

        public int Minutes { 
            get { return (int)((_ticks / TicksPerMinute) % 60); }
        } 
 
        public int Seconds {
            get { return (int)((_ticks / TicksPerSecond) % 60); } 
        }

        public double TotalDays {
            get { return ((double)_ticks) * DaysPerTick; } 
        }
 
        public double TotalHours { 
            get { return (double)_ticks * HoursPerTick; }
        } 

        public double TotalMilliseconds {
            get {
                double temp = (double)_ticks * MillisecondsPerTick; 
                if (temp > MaxMilliSeconds)
                    return (double)MaxMilliSeconds; 
 
                if (temp < MinMilliSeconds)
                    return (double)MinMilliSeconds; 

                return temp;
            }
        } 

        public double TotalMinutes { 
            get { return (double)_ticks * MinutesPerTick; } 
        }
 
        public double TotalSeconds {
#if !FEATURE_CORECLR
            [TargetedPatchingOptOut("Performance critical to inline across NGen image boundaries")]
#endif 
            get { return (double)_ticks * SecondsPerTick; }
        } 
 
        public TimeSpan Add(TimeSpan ts) {
            long result = _ticks + ts._ticks; 
            // Overflow if signs of operands was identical and result's
            // sign was opposite.
            // >> 63 gives the sign bit (either 64 1's or 64 0's).
            if ((_ticks >> 63 == ts._ticks >> 63) && (_ticks >> 63 != result >> 63)) 
                throw new OverflowException(Environment.GetResourceString("Overflow_TimeSpanTooLong"));
            return new TimeSpan(result); 
        } 

 
        // Compares two TimeSpan values, returning an integer that indicates their
        // relationship.
        //
        public static int Compare(TimeSpan t1, TimeSpan t2) { 
            if (t1._ticks > t2._ticks) return 1;
            if (t1._ticks < t2._ticks) return -1; 
            return 0; 
        }
 
        // Returns a value less than zero if this  object
        public int CompareTo(Object value) {
            if (value == null) return 1;
            if (!(value is TimeSpan)) 
                throw new ArgumentException(Environment.GetResourceString("Arg_MustBeTimeSpan"));
            long t = ((TimeSpan)value)._ticks; 
            if (_ticks > t) return 1; 
            if (_ticks < t) return -1;
            return 0; 
        }

#if GENERICS_WORK
        public int CompareTo(TimeSpan value) { 
            long t = value._ticks;
            if (_ticks > t) return 1; 
            if (_ticks < t) return -1; 
            return 0;
        } 
#endif

        public static TimeSpan FromDays(double value) {
            return Interval(value, MillisPerDay); 
        }
 
        public TimeSpan Duration() { 
            if (Ticks==TimeSpan.MinValue.Ticks)
                throw new OverflowException(Environment.GetResourceString("Overflow_Duration")); 
            Contract.EndContractBlock();
            return new TimeSpan(_ticks >= 0? _ticks: -_ticks);
        }
 
        public override bool Equals(Object value) {
            if (value is TimeSpan) { 
                return _ticks == ((TimeSpan)value)._ticks; 
            }
            return false; 
        }

        public bool Equals(TimeSpan obj)
        { 
            return _ticks == obj._ticks;
        } 
 
        public static bool Equals(TimeSpan t1, TimeSpan t2) {
            return t1._ticks == t2._ticks; 
        }

        public override int GetHashCode() {
            return (int)_ticks ^ (int)(_ticks >> 32); 
        }
 
        public static TimeSpan FromHours(double value) { 
            return Interval(value, MillisPerHour);
        } 

        private static TimeSpan Interval(double value, int scale) {
            if (Double.IsNaN(value))
                throw new ArgumentException(Environment.GetResourceString("Arg_CannotBeNaN")); 
            Contract.EndContractBlock();
            double tmp = value * scale; 
            double millis = tmp + (value >= 0? 0.5: -0.5); 
            if ((millis > Int64.MaxValue / TicksPerMillisecond) || (millis < Int64.MinValue / TicksPerMillisecond))
                throw new OverflowException(Environment.GetResourceString("Overflow_TimeSpanTooLong")); 
            return new TimeSpan((long)millis * TicksPerMillisecond);
        }

        public static TimeSpan FromMilliseconds(double value) { 
            return Interval(value, 1);
        } 
 
        public static TimeSpan FromMinutes(double value) {
            return Interval(value, MillisPerMinute); 
        }

        public TimeSpan Negate() {
            if (Ticks==TimeSpan.MinValue.Ticks) 
                throw new OverflowException(Environment.GetResourceString("Overflow_NegateTwosCompNum"));
            Contract.EndContractBlock(); 
            return new TimeSpan(-_ticks); 
        }
 
        public static TimeSpan FromSeconds(double value) {
            return Interval(value, MillisPerSecond);
        }
 
        public TimeSpan Subtract(TimeSpan ts) {
            long result = _ticks - ts._ticks; 
            // Overflow if signs of operands was different and result's 
            // sign was opposite from the first argument's sign.
            // >> 63 gives the sign bit (either 64 1's or 64 0's). 
            if ((_ticks >> 63 != ts._ticks >> 63) && (_ticks >> 63 != result >> 63))
                throw new OverflowException(Environment.GetResourceString("Overflow_TimeSpanTooLong"));
            return new TimeSpan(result);
        } 

#if !FEATURE_CORECLR 
        [TargetedPatchingOptOut("Performance critical to inline across NGen image boundaries")] 
#endif
        public static TimeSpan FromTicks(long value) { 
            return new TimeSpan(value);
        }

        internal static long TimeToTicks(int hour, int minute, int second) { 
            // totalSeconds is bounded by 2^31 * 2^12 + 2^31 * 2^8 + 2^31,
            // which is less than 2^44, meaning we won't overflow totalSeconds. 
            long totalSeconds = (long)hour * 3600 + (long)minute * 60 + (long)second; 
            if (totalSeconds > MaxSeconds || totalSeconds < MinSeconds)
                throw new ArgumentOutOfRangeException(null, Environment.GetResourceString("Overflow_TimeSpanTooLong")); 
            return totalSeconds * TicksPerSecond;
        }

        // See System.Globalization.TimeSpanParse and System.Globalization.TimeSpanFormat 
        #region ParseAndFormat
        public static TimeSpan Parse(String s) { 
            /* Constructs a TimeSpan from a string.  Leading and trailing white space characters are allowed. */ 
            return TimeSpanParse.Parse(s, null);
        } 
        public static TimeSpan Parse(String input, IFormatProvider formatProvider) {
            return TimeSpanParse.Parse(input, formatProvider);
        }
        public static TimeSpan ParseExact(String input, String format, IFormatProvider formatProvider) { 
            return TimeSpanParse.ParseExact(input, format, formatProvider, TimeSpanStyles.None);
        } 
        public static TimeSpan ParseExact(String input, String[] formats, IFormatProvider formatProvider) { 
            return TimeSpanParse.ParseExactMultiple(input, formats, formatProvider, TimeSpanStyles.None);
        } 
        public static TimeSpan ParseExact(String input, String format, IFormatProvider formatProvider, TimeSpanStyles styles) {
            TimeSpanParse.ValidateStyles(styles, "styles");
            return TimeSpanParse.ParseExact(input, format, formatProvider, styles);
        } 
        public static TimeSpan ParseExact(String input, String[] formats, IFormatProvider formatProvider, TimeSpanStyles styles) {
            TimeSpanParse.ValidateStyles(styles, "styles"); 
            return TimeSpanParse.ParseExactMultiple(input, formats, formatProvider, styles); 
        }
        public static Boolean TryParse(String s, out TimeSpan result) { 
            return TimeSpanParse.TryParse(s, null, out result);
        }
        public static Boolean TryParse(String input, IFormatProvider formatProvider, out TimeSpan result) {
            return TimeSpanParse.TryParse(input, formatProvider, out result); 
        }
        public static Boolean TryParseExact(String input, String format, IFormatProvider formatProvider, out TimeSpan result) { 
            return TimeSpanParse.TryParseExact(input, format, formatProvider, TimeSpanStyles.None, out result); 
        }
        public static Boolean TryParseExact(String input, String[] formats, IFormatProvider formatProvider, out TimeSpan result) { 
            return TimeSpanParse.TryParseExactMultiple(input, formats, formatProvider, TimeSpanStyles.None, out result);
        }
        public static Boolean TryParseExact(String input, String format, IFormatProvider formatProvider, TimeSpanStyles styles, out TimeSpan result) {
            TimeSpanParse.ValidateStyles(styles, "styles"); 
            return TimeSpanParse.TryParseExact(input, format, formatProvider, styles, out result);
        } 
        public static Boolean TryParseExact(String input, String[] formats, IFormatProvider formatProvider, TimeSpanStyles styles, out TimeSpan result) { 
            TimeSpanParse.ValidateStyles(styles, "styles");
            return TimeSpanParse.TryParseExactMultiple(input, formats, formatProvider, styles, out result); 
        }
        public override String ToString() {
            return TimeSpanFormat.Format(this, null, null);
        } 
        public String ToString(String format) {
            return TimeSpanFormat.Format(this, format, null); 
        } 
        public String ToString(String format, IFormatProvider formatProvider) {
            if (LegacyMode) { 
                return TimeSpanFormat.Format(this, null, null);
            }
            else {
                return TimeSpanFormat.Format(this, format, formatProvider); 
            }
        } 
        #endregion 

        public static TimeSpan operator -(TimeSpan t) { 
            if (t._ticks==TimeSpan.MinValue._ticks)
                throw new OverflowException(Environment.GetResourceString("Overflow_NegateTwosCompNum"));
            return new TimeSpan(-t._ticks);
        } 

#if !FEATURE_CORECLR 
        [TargetedPatchingOptOut("Performance critical to inline across NGen image boundaries")] 
#endif
        public static TimeSpan operator -(TimeSpan t1, TimeSpan t2) { 
            return t1.Subtract(t2);
        }

        public static TimeSpan operator +(TimeSpan t) { 
            return t;
        } 
 
        public static TimeSpan operator +(TimeSpan t1, TimeSpan t2) {
            return t1.Add(t2); 
        }

#if !FEATURE_CORECLR
        [TargetedPatchingOptOut("Performance critical to inline across NGen image boundaries")] 
#endif
        public static bool operator ==(TimeSpan t1, TimeSpan t2) { 
            return t1._ticks == t2._ticks; 
        }
 
#if !FEATURE_CORECLR
        [TargetedPatchingOptOut("Performance critical to inline across NGen image boundaries")]
#endif
        public static bool operator !=(TimeSpan t1, TimeSpan t2) { 
            return t1._ticks != t2._ticks;
        } 
 
#if !FEATURE_CORECLR
        [TargetedPatchingOptOut("Performance critical to inline across NGen image boundaries")] 
#endif
        public static bool operator <(TimeSpan t1, TimeSpan t2) {
            return t1._ticks < t2._ticks;
        } 

#if !FEATURE_CORECLR 
        [TargetedPatchingOptOut("Performance critical to inline across NGen image boundaries")] 
#endif
        public static bool operator <=(TimeSpan t1, TimeSpan t2) { 
            return t1._ticks <= t2._ticks;
        }

#if !FEATURE_CORECLR 
        [TargetedPatchingOptOut("Performance critical to inline across NGen image boundaries")]
#endif 
        public static bool operator >(TimeSpan t1, TimeSpan t2) { 
            return t1._ticks > t2._ticks;
        } 

#if !FEATURE_CORECLR
        [TargetedPatchingOptOut("Performance critical to inline across NGen image boundaries")]
#endif 
        public static bool operator >=(TimeSpan t1, TimeSpan t2) {
            return t1._ticks >= t2._ticks; 
        } 

 
        //
        // In .NET Framework v1.0 - v3.5 System.TimeSpan did not implement IFormattable
        //    The composite formatter ignores format specifiers on types that do not implement
        //    IFormattable, so the following code would 'just work' by using TimeSpan.ToString() 
        //    under the hood:
        //        String.Format("{0:_someRandomFormatString_}", myTimeSpan); 
        // 
        // In .NET Framework v4.0 System.TimeSpan implements IFormattable.  This causes the
        //    composite formatter to call TimeSpan.ToString(string format, FormatProvider provider) 
        //    and pass in "_someRandomFormatString_" for the format parameter.  When the format
        //    parameter is invalid a FormatException is thrown.
        //
        // The 'NetFx40_TimeSpanLegacyFormatMode' per-AppDomain configuration option and the 'TimeSpan_LegacyFormatMode' 
        // process-wide configuration option allows applications to run with the v1.0 - v3.5 legacy behavior.  When
        // either switch is specified the format parameter is ignored and the default output is returned. 
        // 
        // There are three ways to use the process-wide configuration option:
        // 
        // 1) Config file (MyApp.exe.config)
        //        
        //        
        //          
        //          
        //          
        //         
        // 2) Environment variable
        //        set COMPLUS_TimeSpan_LegacyFormatMode=1 
        // 3) RegistryKey
        //        [HKEY_LOCAL_MACHINE\SOFTWARE\Microsoft\.NETFramework]
        //        "TimeSpan_LegacyFormatMode"=dword:00000001
        // 
#if !FEATURE_CORECLR
        [System.Security.SecurityCritical] 
        [ResourceExposure(ResourceScope.None)] 
        [MethodImplAttribute(MethodImplOptions.InternalCall)]
        private static extern bool LegacyFormatMode(); 
#endif // !FEATURE_CORECLR
        //
        // In Silverlight v4, specifying the APP_EARLIER_THAN_SL4.0 quirks mode allows applications to
        // run in v2 - v3 legacy behavior. 
        //
        [System.Security.SecuritySafeCritical] 
        private static bool GetLegacyFormatMode() { 
#if !FEATURE_CORECLR
            if (LegacyFormatMode()) // FCALL to check COMPLUS_TimeSpan_LegacyFormatMode 
                return true;
            Nullable compatSwitch = AppDomain.CurrentDomain.IsCompatibilitySwitchSet("NetFx40_TimeSpanLegacyFormatMode");
#else
            Nullable compatSwitch = AppDomain.CurrentDomain.IsCompatibilitySwitchSet("APP_EARLIER_THAN_SL4.0"); 
#endif // !FEATURE_CORECLR
            return ((compatSwitch.HasValue && compatSwitch.Value)); 
        } 

        private static bool _legacyConfigChecked; 
        private static bool _legacyMode;

        private static bool LegacyMode {
            [System.Security.SecuritySafeCritical] 
            get {
                if (!_legacyConfigChecked) { 
                    // no need to lock - idempotent 
                    _legacyMode = GetLegacyFormatMode();
                    _legacyConfigChecked = true; 
                }
                return _legacyMode;
            }
        } 
    }
} 

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

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