|
// Licensed to the .NET Foundation under one or more agreements.
// The .NET Foundation licenses this file to you under the MIT license.
using System.ComponentModel;
using System.Diagnostics;
using System.Diagnostics.CodeAnalysis;
using System.Globalization;
using System.Numerics;
using System.Runtime.CompilerServices;
using System.Runtime.InteropServices;
using System.Runtime.Serialization;
using System.Runtime.Versioning;
namespace System
{
// This value type represents a date and time. Every DateTime
// object has a private field (Ticks) of type Int64 that stores the
// date and time as the number of 100 nanosecond intervals since
// 12:00 AM January 1, year 1 A.D. in the proleptic Gregorian Calendar.
//
// Starting from V2.0, DateTime also stored some context about its time
// zone in the form of a 3-state value representing Unspecified, Utc or
// Local. This is stored in the two top bits of the 64-bit numeric value
// with the remainder of the bits storing the tick count. This information
// is only used during time zone conversions and is not part of the
// identity of the DateTime. Thus, operations like Compare and Equals
// ignore this state. This is to stay compatible with earlier behavior
// and performance characteristics and to avoid forcing people into dealing
// with the effects of daylight savings. Note, that this has little effect
// on how the DateTime works except in a context where its specific time
// zone is needed, such as during conversions and some parsing and formatting
// cases.
//
// There is also 4th state stored that is a special type of Local value that
// is used to avoid data loss when round-tripping between local and UTC time.
// See below for more information on this 4th state, although it is
// effectively hidden from most users, who just see the 3-state DateTimeKind
// enumeration.
//
// For compatibility, DateTime does not serialize the Kind data when used in
// binary serialization.
//
// For a description of various calendar issues, look at
//
//
[StructLayout(LayoutKind.Auto)]
[Serializable]
[TypeForwardedFrom("mscorlib, Version=4.0.0.0, Culture=neutral, PublicKeyToken=b77a5c561934e089")]
public readonly partial struct DateTime
: IComparable,
ISpanFormattable,
IConvertible,
IComparable<DateTime>,
IEquatable<DateTime>,
ISerializable,
ISpanParsable<DateTime>,
IUtf8SpanFormattable
{
// Number of days in a non-leap year
private const int DaysPerYear = 365;
// Number of days in 4 years
private const int DaysPer4Years = DaysPerYear * 4 + 1; // 1461
// Number of days in 100 years
private const int DaysPer100Years = DaysPer4Years * 25 - 1; // 36524
// Number of days in 400 years
private const int DaysPer400Years = DaysPer100Years * 4 + 1; // 146097
// Number of days from 1/1/0001 to 12/31/1600
private const int DaysTo1601 = DaysPer400Years * 4; // 584388
// Number of days from 1/1/0001 to 12/30/1899
private const int DaysTo1899 = DaysPer400Years * 4 + DaysPer100Years * 3 - 367;
// Number of days from 1/1/0001 to 12/31/1969
internal const int DaysTo1970 = DaysPer400Years * 4 + DaysPer100Years * 3 + DaysPer4Years * 17 + DaysPerYear; // 719,162
// Number of days from 1/1/0001 to 12/31/9999
internal const int DaysTo10000 = DaysPer400Years * 25 - 366; // 3652059
internal const long MinTicks = 0;
internal const long MaxTicks = DaysTo10000 * TimeSpan.TicksPerDay - 1;
private const long MaxMicroseconds = MaxTicks / TimeSpan.TicksPerMicrosecond;
private const long MaxMillis = MaxTicks / TimeSpan.TicksPerMillisecond;
private const long MaxSeconds = MaxTicks / TimeSpan.TicksPerSecond;
private const long MaxMinutes = MaxTicks / TimeSpan.TicksPerMinute;
private const long MaxHours = MaxTicks / TimeSpan.TicksPerHour;
private const long MaxDays = (long)DaysTo10000 - 1;
internal const long UnixEpochTicks = DaysTo1970 * TimeSpan.TicksPerDay;
private const long FileTimeOffset = DaysTo1601 * TimeSpan.TicksPerDay;
private const long DoubleDateOffset = DaysTo1899 * TimeSpan.TicksPerDay;
// The minimum OA date is 0100/01/01 (Note it's year 100).
// The maximum OA date is 9999/12/31
private const long OADateMinAsTicks = (DaysPer100Years - DaysPerYear) * TimeSpan.TicksPerDay;
// All OA dates must be greater than (not >=) OADateMinAsDouble
private const double OADateMinAsDouble = -657435.0;
// All OA dates must be less than (not <=) OADateMaxAsDouble
private const double OADateMaxAsDouble = 2958466.0;
// Euclidean Affine Functions Algorithm (EAF) constants
// Constants used for fast calculation of following subexpressions
// x / DaysPer4Years
// x % DaysPer4Years / 4
private const uint EafMultiplier = (uint)(((1UL << 32) + DaysPer4Years - 1) / DaysPer4Years); // 2,939,745
private const uint EafDivider = EafMultiplier * 4; // 11,758,980
private const ulong TicksPer6Hours = TimeSpan.TicksPerHour * 6;
private const int March1BasedDayOfNewYear = 306; // Days between March 1 and January 1
internal static ReadOnlySpan<uint> DaysToMonth365 => [0, 31, 59, 90, 120, 151, 181, 212, 243, 273, 304, 334, 365];
internal static ReadOnlySpan<uint> DaysToMonth366 => [0, 31, 60, 91, 121, 152, 182, 213, 244, 274, 305, 335, 366];
private static ReadOnlySpan<byte> DaysInMonth365 => [31, 28, 31, 30, 31, 30, 31, 31, 30, 31, 30, 31];
private static ReadOnlySpan<byte> DaysInMonth366 => [31, 29, 31, 30, 31, 30, 31, 31, 30, 31, 30, 31];
public static readonly DateTime MinValue;
public static readonly DateTime MaxValue = new DateTime(MaxTicks, DateTimeKind.Unspecified);
public static readonly DateTime UnixEpoch = new DateTime(UnixEpochTicks, DateTimeKind.Utc);
private const ulong TicksMask = 0x3FFFFFFFFFFFFFFF;
private const ulong FlagsMask = 0xC000000000000000;
private const long TicksCeiling = 0x4000000000000000;
internal const ulong KindUtc = 0x4000000000000000;
private const ulong KindLocal = 0x8000000000000000;
private const ulong KindLocalAmbiguousDst = 0xC000000000000000;
private const int KindShift = 62;
private const string TicksField = "ticks"; // Do not rename (binary serialization)
private const string DateDataField = "dateData"; // Do not rename (binary serialization)
// The data is stored as an unsigned 64-bit integer
// Bits 01-62: The value of 100-nanosecond ticks where 0 represents 1/1/0001 12:00am, up until the value
// 12/31/9999 23:59:59.9999999
// Bits 63-64: A four-state value that describes the DateTimeKind value of the date time, with a 2nd
// value for the rare case where the date time is local, but is in an overlapped daylight
// savings time hour and it is in daylight savings time. This allows distinction of these
// otherwise ambiguous local times and prevents data loss when round tripping from Local to
// UTC time.
internal readonly ulong _dateData;
// Constructs a DateTime from a tick count. The ticks
// argument specifies the date as the number of 100-nanosecond intervals
// that have elapsed since 1/1/0001 12:00am.
//
public DateTime(long ticks)
{
if ((ulong)ticks > MaxTicks) ThrowTicksOutOfRange();
_dateData = (ulong)ticks;
}
private DateTime(ulong dateData)
{
Debug.Assert((dateData & TicksMask) <= MaxTicks);
_dateData = dateData;
}
internal static DateTime CreateUnchecked(long ticks) => new DateTime((ulong)ticks);
public DateTime(long ticks, DateTimeKind kind)
{
if ((ulong)ticks > MaxTicks) ThrowTicksOutOfRange();
if ((uint)kind > (uint)DateTimeKind.Local) ThrowInvalidKind();
_dateData = (ulong)ticks | ((ulong)(uint)kind << KindShift);
}
/// <summary>
/// Initializes a new instance of the <see cref="DateTime"/> structure to the specified <see cref="DateOnly"/> and <see cref="TimeOnly"/>.
/// The new instance will have the <see cref="DateTimeKind.Unspecified"/> kind.
/// </summary>
/// <param name="date">
/// The date part.
/// </param>
/// <param name="time">
/// The time part.
/// </param>
public DateTime(DateOnly date, TimeOnly time)
{
_dateData = (ulong)(date.DayNumber * TimeSpan.TicksPerDay + time.Ticks);
}
/// <summary>
/// Initializes a new instance of the <see cref="DateTime"/> structure to the specified <see cref="DateOnly"/> and <see cref="TimeOnly"/> respecting a <see cref="DateTimeKind"/>.
/// </summary>
/// <param name="date">
/// The date part.
/// </param>
/// <param name="time">
/// The time part.
/// </param>
/// <param name="kind">
/// One of the enumeration values that indicates whether <paramref name="date"/>
/// and <paramref name="time"/> specify a local time, Coordinated Universal Time (UTC), or neither.
/// </param>
public DateTime(DateOnly date, TimeOnly time, DateTimeKind kind)
{
if ((uint)kind > (uint)DateTimeKind.Local) ThrowInvalidKind();
_dateData = (ulong)(date.DayNumber * TimeSpan.TicksPerDay + time.Ticks) | ((ulong)(uint)kind << KindShift);
}
internal DateTime(long ticks, DateTimeKind kind, bool isAmbiguousDst)
{
if ((ulong)ticks > MaxTicks) ThrowTicksOutOfRange();
Debug.Assert(kind == DateTimeKind.Local, "Internal Constructor is for local times only");
_dateData = ((ulong)ticks | (isAmbiguousDst ? KindLocalAmbiguousDst : KindLocal));
}
private static void ThrowTicksOutOfRange() => throw new ArgumentOutOfRangeException("ticks", SR.ArgumentOutOfRange_DateTimeBadTicks);
private static void ThrowInvalidKind() => throw new ArgumentException(SR.Argument_InvalidDateTimeKind, "kind");
internal static void ThrowMillisecondOutOfRange() => throw new ArgumentOutOfRangeException("millisecond", SR.Format(SR.ArgumentOutOfRange_Range, 0, TimeSpan.MillisecondsPerSecond - 1));
internal static void ThrowMicrosecondOutOfRange() => throw new ArgumentOutOfRangeException("microsecond", SR.Format(SR.ArgumentOutOfRange_Range, 0, TimeSpan.MicrosecondsPerMillisecond - 1));
private static void ThrowDateArithmetic(int param) => throw new ArgumentOutOfRangeException(param switch { 0 => "value", 1 => "t", _ => "months" }, SR.ArgumentOutOfRange_DateArithmetic);
private static void ThrowAddOutOfRange() => throw new ArgumentOutOfRangeException("value", SR.ArgumentOutOfRange_AddValue);
// Constructs a DateTime from a given year, month, and day. The
// time-of-day of the resulting DateTime is always midnight.
//
public DateTime(int year, int month, int day)
{
_dateData = DateToTicks(year, month, day);
}
// Constructs a DateTime from a given year, month, and day for
// the specified calendar. The
// time-of-day of the resulting DateTime is always midnight.
//
public DateTime(int year, int month, int day, Calendar calendar)
: this(year, month, day, 0, 0, 0, calendar)
{
}
/// <summary>
/// Initializes a new instance of the <see cref="DateTime"/> structure to the specified year, month, day, hour, minute, second,
/// millisecond, and Coordinated Universal Time (UTC) or local time for the specified calendar.
/// </summary>
/// <param name="year">The year (1 through the number of years in <paramref name="calendar"/>).</param>
/// <param name="month">The month (1 through the number of months in <paramref name="calendar"/>).</param>
/// <param name="day">The day (1 through the number of days in <paramref name="month"/>).</param>
/// <param name="hour">The hours (0 through 23).</param>
/// <param name="minute">The minutes (0 through 59).</param>
/// <param name="second">The seconds (0 through 59).</param>
/// <param name="millisecond">The milliseconds (0 through 999).</param>
/// <param name="calendar">The calendar that is used to interpret <paramref name="year"/>, <paramref name="month"/>, and <paramref name="day"/>.</param>
/// <param name="kind">
/// One of the enumeration values that indicates whether <paramref name="year"/>, <paramref name="month"/>, <paramref name="day"/>,
/// <paramref name="hour"/>, <paramref name="minute"/>, <paramref name="second"/>, and <paramref name="millisecond"/>
/// specify a local time, Coordinated Universal Time (UTC), or neither.</param>
/// <exception cref="ArgumentNullException">
/// <paramref name="calendar"/> is <see langword="null"/>
/// </exception>
/// <exception cref="ArgumentOutOfRangeException">
/// <paramref name="year"/> is not in the range supported by <paramref name="calendar"/>.
///
/// -or-
///
/// <paramref name="month"/> is less than 1 or greater than the number of months in <paramref name="calendar"/>.
///
/// -or-
///
/// <paramref name="day"/> is less than 1 or greater than the number of days in <paramref name="month"/>.
///
/// -or-
///
/// <paramref name="hour"/> is less than 0 or greater than 23.
///
/// -or-
///
/// <paramref name="minute"/> is less than 0 or greater than 59.
///
/// -or-
///
/// <paramref name="second"/> is less than 0 or greater than 59.
///
/// -or-
///
/// <paramref name="millisecond"/> is less than 0 or greater than 999.
/// </exception>
/// <exception cref="ArgumentException">
/// <paramref name="kind"/> is not one of the <see cref="DateTimeKind"/> values.
/// </exception>
/// <remarks>
/// The allowable values for <paramref name="year"/>, <paramref name="month"/>, and <paramref name="day"/> parameters
/// depend on the <paramref name="calendar"/> parameter. An exception is thrown if the specified date and time cannot
/// be expressed using <paramref name="calendar"/>.
///
/// For applications in which portability of date and time data or a limited degree of time zone awareness is important,
/// you can use the corresponding <see cref="DateTimeOffset"/> constructor.
/// </remarks>
public DateTime(int year, int month, int day, int hour, int minute, int second, int millisecond, Calendar calendar, DateTimeKind kind)
{
ArgumentNullException.ThrowIfNull(calendar);
if ((uint)millisecond >= TimeSpan.MillisecondsPerSecond) ThrowMillisecondOutOfRange();
if ((uint)kind > (uint)DateTimeKind.Local) ThrowInvalidKind();
if (second != 60 || !SystemSupportsLeapSeconds)
{
ulong ticks = calendar.ToDateTime(year, month, day, hour, minute, second, millisecond).UTicks;
_dateData = ticks | ((ulong)(uint)kind << KindShift);
}
else
{
_dateData = WithLeapSecond(calendar, year, month, day, hour, minute, millisecond, kind);
}
}
[MethodImpl(MethodImplOptions.NoInlining)]
private static ulong WithLeapSecond(Calendar calendar, int year, int month, int day, int hour, int minute, int millisecond, DateTimeKind kind)
{
// if we have a leap second, then we adjust it to 59 so that DateTime will consider it the last in the specified minute.
return ValidateLeapSecond(new DateTime(year, month, day, hour, minute, 59, millisecond, calendar, kind));
}
// Constructs a DateTime from a given year, month, day, hour,
// minute, and second.
//
public DateTime(int year, int month, int day, int hour, int minute, int second)
{
ulong ticks = DateToTicks(year, month, day);
if (second != 60 || !SystemSupportsLeapSeconds)
{
_dateData = ticks + TimeToTicks(hour, minute, second);
}
else
{
_dateData = WithLeapSecond(ticks, hour, minute);
}
}
[MethodImpl(MethodImplOptions.NoInlining)]
private static ulong WithLeapSecond(ulong ticks, int hour, int minute)
{
// if we have a leap second, then we adjust it to 59 so that DateTime will consider it the last in the specified minute.
// codeql[cs/leap-year/unsafe-date-construction-from-two-elements] - DateTime is constructed using the user specified values, not a combination of different sources. It would be intentional to throw if an invalid combination occurred.
return ValidateLeapSecond(new DateTime(ticks + TimeToTicks(hour, minute, 59)));
}
public DateTime(int year, int month, int day, int hour, int minute, int second, DateTimeKind kind)
{
if ((uint)kind > (uint)DateTimeKind.Local) ThrowInvalidKind();
ulong ticks = DateToTicks(year, month, day) | ((ulong)(uint)kind << KindShift);
if (second != 60 || !SystemSupportsLeapSeconds)
{
_dateData = ticks + TimeToTicks(hour, minute, second);
}
else
{
_dateData = WithLeapSecond(ticks, hour, minute);
}
}
// Constructs a DateTime from a given year, month, day, hour,
// minute, and second for the specified calendar.
//
public DateTime(int year, int month, int day, int hour, int minute, int second, Calendar calendar)
{
ArgumentNullException.ThrowIfNull(calendar);
if (second != 60 || !SystemSupportsLeapSeconds)
{
_dateData = calendar.ToDateTime(year, month, day, hour, minute, second, 0).UTicks;
}
else
{
_dateData = WithLeapSecond(calendar, year, month, day, hour, minute);
}
}
[MethodImpl(MethodImplOptions.NoInlining)]
private static ulong WithLeapSecond(Calendar calendar, int year, int month, int day, int hour, int minute)
{
// if we have a leap second, then we adjust it to 59 so that DateTime will consider it the last in the specified minute.
return ValidateLeapSecond(new DateTime(year, month, day, hour, minute, 59, calendar));
}
/// <summary>
/// Initializes a new instance of the <see cref="DateTime"/> structure to the specified year, month, day, hour, minute, second,
/// millisecond, and Coordinated Universal Time (UTC) or local time for the specified calendar.
/// </summary>
/// <param name="year">The year (1 through 9999).</param>
/// <param name="month">The month (1 through 12).</param>
/// <param name="day">The day (1 through the number of days in <paramref name="month"/>).</param>
/// <param name="hour">The hours (0 through 23).</param>
/// <param name="minute">The minutes (0 through 59).</param>
/// <param name="second">The seconds (0 through 59).</param>
/// <param name="millisecond">The milliseconds (0 through 999).</param>
/// <exception cref="ArgumentOutOfRangeException">
/// <paramref name="year"/> is less than 1 or greater than 9999.
///
/// -or-
///
/// <paramref name="month"/> is less than 1 or greater than 12.
///
/// -or-
///
/// <paramref name="day"/> is less than 1 or greater than the number of days in <paramref name="month"/>.
///
/// -or-
///
/// <paramref name="hour"/> is less than 0 or greater than 23.
///
/// -or-
///
/// <paramref name="minute"/> is less than 0 or greater than 59.
///
/// -or-
///
/// <paramref name="second"/> is less than 0 or greater than 59.
///
/// -or-
///
/// <paramref name="millisecond"/> is less than 0 or greater than 999.
/// </exception>
/// <remarks>
/// This constructor interprets <paramref name="year"/>, <paramref name="month"/> and <paramref name="day"/> as a year, month and day
/// in the Gregorian calendar. To instantiate a <see cref="DateTime"/> value by using the year, month and day in another calendar, call
/// the <see cref="DateTime(int, int, int, int, int, int, int, int, Calendar)"/> constructor.
///
/// The <see cref="Kind"/> property is initialized to <see cref="DateTimeKind.Unspecified"/>.
///
/// For applications in which portability of date and time data or a limited degree of time zone awareness is important,
/// you can use the corresponding <see cref="DateTimeOffset"/> constructor.
/// </remarks>
public DateTime(int year, int month, int day, int hour, int minute, int second, int millisecond)
: this(year, month, day, hour, minute, second)
{
if ((uint)millisecond >= TimeSpan.MillisecondsPerSecond) ThrowMillisecondOutOfRange();
_dateData += (uint)millisecond * (uint)TimeSpan.TicksPerMillisecond;
}
/// <summary>
/// Initializes a new instance of the <see cref="DateTime"/> structure to the specified year, month, day, hour, minute, second,
/// millisecond, and Coordinated Universal Time (UTC) or local time for the specified calendar.
/// </summary>
/// <param name="year">The year (1 through 9999).</param>
/// <param name="month">The month (1 through 12).</param>
/// <param name="day">The day (1 through the number of days in <paramref name="month"/>).</param>
/// <param name="hour">The hours (0 through 23).</param>
/// <param name="minute">The minutes (0 through 59).</param>
/// <param name="second">The seconds (0 through 59).</param>
/// <param name="millisecond">The milliseconds (0 through 999).</param>
/// <param name="kind">
/// One of the enumeration values that indicates whether <paramref name="year"/>, <paramref name="month"/>, <paramref name="day"/>,
/// <paramref name="hour"/>, <paramref name="minute"/>, <paramref name="second"/>, and <paramref name="millisecond"/>
/// specify a local time, Coordinated Universal Time (UTC), or neither.</param>
/// <exception cref="ArgumentOutOfRangeException">
/// <paramref name="year"/> is less than 1 or greater than 9999.
///
/// -or-
///
/// <paramref name="month"/> is less than 1 or greater than 12.
///
/// -or-
///
/// <paramref name="day"/> is less than 1 or greater than the number of days in <paramref name="month"/>.
///
/// -or-
///
/// <paramref name="hour"/> is less than 0 or greater than 23.
///
/// -or-
///
/// <paramref name="minute"/> is less than 0 or greater than 59.
///
/// -or-
///
/// <paramref name="second"/> is less than 0 or greater than 59.
///
/// -or-
///
/// <paramref name="millisecond"/> is less than 0 or greater than 999.
/// </exception>
/// <exception cref="ArgumentException">
/// <paramref name="kind"/> is not one of the <see cref="DateTimeKind"/> values.
/// </exception>
/// <remarks>
/// This constructor interprets <paramref name="year"/>, <paramref name="month"/> and <paramref name="day"/> as a year, month and day
/// in the Gregorian calendar. To instantiate a <see cref="DateTime"/> value by using the year, month and day in another calendar, call
/// the <see cref="DateTime(int, int, int, int, int, int, int, int, Calendar, DateTimeKind)"/> constructor.
///
/// For applications in which portability of date and time data or a limited degree of time zone awareness is important,
/// you can use the corresponding <see cref="DateTimeOffset"/> constructor.
/// </remarks>
public DateTime(int year, int month, int day, int hour, int minute, int second, int millisecond, DateTimeKind kind)
: this(year, month, day, hour, minute, second, kind)
{
if ((uint)millisecond >= TimeSpan.MillisecondsPerSecond) ThrowMillisecondOutOfRange();
_dateData += (uint)millisecond * (uint)TimeSpan.TicksPerMillisecond;
}
/// <summary>
/// Initializes a new instance of the <see cref="DateTime"/> structure to the specified year, month, day, hour, minute, second,
/// millisecond, and Coordinated Universal Time (UTC) or local time for the specified calendar.
/// </summary>
/// <param name="year">The year (1 through the number of years in <paramref name="calendar"/>).</param>
/// <param name="month">The month (1 through the number of months in <paramref name="calendar"/>).</param>
/// <param name="day">The day (1 through the number of days in <paramref name="month"/>).</param>
/// <param name="hour">The hours (0 through 23).</param>
/// <param name="minute">The minutes (0 through 59).</param>
/// <param name="second">The seconds (0 through 59).</param>
/// <param name="millisecond">The milliseconds (0 through 999).</param>
/// <param name="calendar">The calendar that is used to interpret <paramref name="year"/>, <paramref name="month"/>, and <paramref name="day"/>.</param>
/// <exception cref="ArgumentNullException">
/// <paramref name="calendar"/> is <see langword="null"/>
/// </exception>
/// <exception cref="ArgumentOutOfRangeException">
/// <paramref name="year"/> is not in the range supported by <paramref name="calendar"/>.
///
/// -or-
///
/// <paramref name="month"/> is less than 1 or greater than the number of months in <paramref name="calendar"/>.
///
/// -or-
///
/// <paramref name="day"/> is less than 1 or greater than the number of days in <paramref name="month"/>.
///
/// -or-
///
/// <paramref name="hour"/> is less than 0 or greater than 23.
///
/// -or-
///
/// <paramref name="minute"/> is less than 0 or greater than 59.
///
/// -or-
///
/// <paramref name="second"/> is less than 0 or greater than 59.
///
/// -or-
///
/// <paramref name="millisecond"/> is less than 0 or greater than 999.
/// </exception>
/// <remarks>
/// The allowable values for <paramref name="year"/>, <paramref name="month"/>, and <paramref name="day"/> parameters
/// depend on the <paramref name="calendar"/> parameter. An exception is thrown if the specified date and time cannot
/// be expressed using <paramref name="calendar"/>.
///
/// For applications in which portability of date and time data or a limited degree of time zone awareness is important,
/// you can use the corresponding <see cref="DateTimeOffset"/> constructor.
/// </remarks>
public DateTime(int year, int month, int day, int hour, int minute, int second, int millisecond, Calendar calendar)
{
ArgumentNullException.ThrowIfNull(calendar);
if (second != 60 || !SystemSupportsLeapSeconds)
{
_dateData = calendar.ToDateTime(year, month, day, hour, minute, second, millisecond).UTicks;
}
else
{
_dateData = WithLeapSecond(calendar, year, month, day, hour, minute, millisecond);
}
}
[MethodImpl(MethodImplOptions.NoInlining)]
private static ulong WithLeapSecond(Calendar calendar, int year, int month, int day, int hour, int minute, int millisecond)
{
// if we have a leap second, then we adjust it to 59 so that DateTime will consider it the last in the specified minute.
return ValidateLeapSecond(new DateTime(year, month, day, hour, minute, 59, millisecond, calendar));
}
/// <summary>
/// Initializes a new instance of the <see cref="DateTime"/> structure to the specified year, month, day, hour, minute, second,
/// millisecond, and Coordinated Universal Time (UTC) or local time for the specified calendar.
/// </summary>
/// <param name="year">The year (1 through 9999).</param>
/// <param name="month">The month (1 through 12).</param>
/// <param name="day">The day (1 through the number of days in <paramref name="month"/>).</param>
/// <param name="hour">The hours (0 through 23).</param>
/// <param name="minute">The minutes (0 through 59).</param>
/// <param name="second">The seconds (0 through 59).</param>
/// <param name="millisecond">The milliseconds (0 through 999).</param>
/// <param name="microsecond">The microseconds (0 through 999).</param>
/// <exception cref="ArgumentOutOfRangeException">
/// <paramref name="year"/> is less than 1 or greater than 9999.
///
/// -or-
///
/// <paramref name="month"/> is less than 1 or greater than 12.
///
/// -or-
///
/// <paramref name="day"/> is less than 1 or greater than the number of days in <paramref name="month"/>.
///
/// -or-
///
/// <paramref name="hour"/> is less than 0 or greater than 23.
///
/// -or-
///
/// <paramref name="minute"/> is less than 0 or greater than 59.
///
/// -or-
///
/// <paramref name="second"/> is less than 0 or greater than 59.
///
/// -or-
///
/// <paramref name="millisecond"/> is less than 0 or greater than 999.
///
/// -or-
///
/// <paramref name="microsecond"/> is less than 0 or greater than 999.
/// </exception>
/// <remarks>
/// This constructor interprets <paramref name="year"/>, <paramref name="month"/> and <paramref name="day"/> as a year, month and day
/// in the Gregorian calendar. To instantiate a <see cref="DateTime"/> value by using the year, month and day in another calendar, call
/// the <see cref="DateTime(int, int, int, int, int, int, int, int, Calendar)"/> constructor.
///
/// The <see cref="Kind"/> property is initialized to <see cref="DateTimeKind.Unspecified"/>.
///
/// For applications in which portability of date and time data or a limited degree of time zone awareness is important,
/// you can use the corresponding <see cref="DateTimeOffset"/> constructor.
/// </remarks>
public DateTime(int year, int month, int day, int hour, int minute, int second, int millisecond, int microsecond)
: this(year, month, day, hour, minute, second, millisecond, microsecond, DateTimeKind.Unspecified)
{
}
/// <summary>
/// Initializes a new instance of the <see cref="DateTime"/> structure to the specified year, month, day, hour, minute, second,
/// millisecond, and Coordinated Universal Time (UTC) or local time for the specified calendar.
/// </summary>
/// <param name="year">The year (1 through 9999).</param>
/// <param name="month">The month (1 through 12).</param>
/// <param name="day">The day (1 through the number of days in <paramref name="month"/>).</param>
/// <param name="hour">The hours (0 through 23).</param>
/// <param name="minute">The minutes (0 through 59).</param>
/// <param name="second">The seconds (0 through 59).</param>
/// <param name="millisecond">The milliseconds (0 through 999).</param>
/// <param name="microsecond">The microseconds (0 through 999).</param>
/// <param name="kind">
/// One of the enumeration values that indicates whether <paramref name="year"/>, <paramref name="month"/>, <paramref name="day"/>,
/// <paramref name="hour"/>, <paramref name="minute"/>, <paramref name="second"/>, and <paramref name="millisecond"/>
/// specify a local time, Coordinated Universal Time (UTC), or neither.</param>
/// <exception cref="ArgumentOutOfRangeException">
/// <paramref name="year"/> is less than 1 or greater than 9999.
///
/// -or-
///
/// <paramref name="month"/> is less than 1 or greater than 12.
///
/// -or-
///
/// <paramref name="day"/> is less than 1 or greater than the number of days in <paramref name="month"/>.
///
/// -or-
///
/// <paramref name="hour"/> is less than 0 or greater than 23.
///
/// -or-
///
/// <paramref name="minute"/> is less than 0 or greater than 59.
///
/// -or-
///
/// <paramref name="second"/> is less than 0 or greater than 59.
///
/// -or-
///
/// <paramref name="millisecond"/> is less than 0 or greater than 999.
///
/// -or-
///
/// <paramref name="microsecond"/> is less than 0 or greater than 999.
/// </exception>
/// <exception cref="ArgumentException">
/// <paramref name="kind"/> is not one of the <see cref="DateTimeKind"/> values.
/// </exception>
/// <remarks>
/// This constructor interprets <paramref name="year"/>, <paramref name="month"/> and <paramref name="day"/> as a year, month and day
/// in the Gregorian calendar. To instantiate a <see cref="DateTime"/> value by using the year, month and day in another calendar, call
/// the <see cref="DateTime(int, int, int, int, int, int, int, int, Calendar, DateTimeKind)"/> constructor.
///
/// For applications in which portability of date and time data or a limited degree of time zone awareness is important,
/// you can use the corresponding <see cref="DateTimeOffset"/> constructor.
/// </remarks>
public DateTime(int year, int month, int day, int hour, int minute, int second, int millisecond, int microsecond, DateTimeKind kind)
: this(year, month, day, hour, minute, second, millisecond, kind)
{
if ((uint)microsecond >= TimeSpan.MicrosecondsPerMillisecond) ThrowMicrosecondOutOfRange();
_dateData += (uint)microsecond * (uint)TimeSpan.TicksPerMicrosecond;
}
/// <summary>
/// Initializes a new instance of the <see cref="DateTime"/> structure to the specified year, month, day, hour, minute, second,
/// millisecond, and Coordinated Universal Time (UTC) or local time for the specified calendar.
/// </summary>
/// <param name="year">The year (1 through the number of years in <paramref name="calendar"/>).</param>
/// <param name="month">The month (1 through the number of months in <paramref name="calendar"/>).</param>
/// <param name="day">The day (1 through the number of days in <paramref name="month"/>).</param>
/// <param name="hour">The hours (0 through 23).</param>
/// <param name="minute">The minutes (0 through 59).</param>
/// <param name="second">The seconds (0 through 59).</param>
/// <param name="millisecond">The milliseconds (0 through 999).</param>
/// <param name="microsecond">The microseconds (0 through 999).</param>
/// <param name="calendar">The calendar that is used to interpret <paramref name="year"/>, <paramref name="month"/>, and <paramref name="day"/>.</param>
/// <exception cref="ArgumentNullException">
/// <paramref name="calendar"/> is <see langword="null"/>
/// </exception>
/// <exception cref="ArgumentOutOfRangeException">
/// <paramref name="year"/> is not in the range supported by <paramref name="calendar"/>.
///
/// -or-
///
/// <paramref name="month"/> is less than 1 or greater than the number of months in <paramref name="calendar"/>.
///
/// -or-
///
/// <paramref name="day"/> is less than 1 or greater than the number of days in <paramref name="month"/>.
///
/// -or-
///
/// <paramref name="hour"/> is less than 0 or greater than 23.
///
/// -or-
///
/// <paramref name="minute"/> is less than 0 or greater than 59.
///
/// -or-
///
/// <paramref name="second"/> is less than 0 or greater than 59.
///
/// -or-
///
/// <paramref name="millisecond"/> is less than 0 or greater than 999.
///
/// -or-
///
/// <paramref name="microsecond"/> is less than 0 or greater than 999.
/// </exception>
/// <remarks>
/// The allowable values for <paramref name="year"/>, <paramref name="month"/>, and <paramref name="day"/> parameters
/// depend on the <paramref name="calendar"/> parameter. An exception is thrown if the specified date and time cannot
/// be expressed using <paramref name="calendar"/>.
///
/// For applications in which portability of date and time data or a limited degree of time zone awareness is important,
/// you can use the corresponding <see cref="DateTimeOffset"/> constructor.
/// </remarks>
public DateTime(int year, int month, int day, int hour, int minute, int second, int millisecond, int microsecond, Calendar calendar)
: this(year, month, day, hour, minute, second, millisecond, microsecond, calendar, DateTimeKind.Unspecified)
{
}
/// <summary>
/// Initializes a new instance of the <see cref="DateTime"/> structure to the specified year, month, day, hour, minute, second,
/// millisecond, and Coordinated Universal Time (UTC) or local time for the specified calendar.
/// </summary>
/// <param name="year">The year (1 through the number of years in <paramref name="calendar"/>).</param>
/// <param name="month">The month (1 through the number of months in <paramref name="calendar"/>).</param>
/// <param name="day">The day (1 through the number of days in <paramref name="month"/>).</param>
/// <param name="hour">The hours (0 through 23).</param>
/// <param name="minute">The minutes (0 through 59).</param>
/// <param name="second">The seconds (0 through 59).</param>
/// <param name="millisecond">The milliseconds (0 through 999).</param>
/// <param name="microsecond">The microseconds (0 through 999).</param>
/// <param name="calendar">The calendar that is used to interpret <paramref name="year"/>, <paramref name="month"/>, and <paramref name="day"/>.</param>
/// <param name="kind">
/// One of the enumeration values that indicates whether <paramref name="year"/>, <paramref name="month"/>, <paramref name="day"/>,
/// <paramref name="hour"/>, <paramref name="minute"/>, <paramref name="second"/>, and <paramref name="millisecond"/>
/// specify a local time, Coordinated Universal Time (UTC), or neither.</param>
/// <exception cref="ArgumentNullException">
/// <paramref name="calendar"/> is <see langword="null"/>
/// </exception>
/// <exception cref="ArgumentOutOfRangeException">
/// <paramref name="year"/> is not in the range supported by <paramref name="calendar"/>.
///
/// -or-
///
/// <paramref name="month"/> is less than 1 or greater than the number of months in <paramref name="calendar"/>.
///
/// -or-
///
/// <paramref name="day"/> is less than 1 or greater than the number of days in <paramref name="month"/>.
///
/// -or-
///
/// <paramref name="hour"/> is less than 0 or greater than 23.
///
/// -or-
///
/// <paramref name="minute"/> is less than 0 or greater than 59.
///
/// -or-
///
/// <paramref name="second"/> is less than 0 or greater than 59.
///
/// -or-
///
/// <paramref name="millisecond"/> is less than 0 or greater than 999.
///
/// -or-
///
/// <paramref name="microsecond"/> is less than 0 or greater than 999.
/// </exception>
/// <exception cref="ArgumentException">
/// <paramref name="kind"/> is not one of the <see cref="DateTimeKind"/> values.
/// </exception>
/// <remarks>
/// The allowable values for <paramref name="year"/>, <paramref name="month"/>, and <paramref name="day"/> parameters
/// depend on the <paramref name="calendar"/> parameter. An exception is thrown if the specified date and time cannot
/// be expressed using <paramref name="calendar"/>.
///
/// For applications in which portability of date and time data or a limited degree of time zone awareness is important,
/// you can use the corresponding <see cref="DateTimeOffset"/> constructor.
/// </remarks>
public DateTime(int year, int month, int day, int hour, int minute, int second, int millisecond, int microsecond, Calendar calendar, DateTimeKind kind)
: this(year, month, day, hour, minute, second, millisecond, calendar, kind)
{
if ((uint)microsecond >= TimeSpan.MicrosecondsPerMillisecond) ThrowMicrosecondOutOfRange();
_dateData += (uint)microsecond * (uint)TimeSpan.TicksPerMicrosecond;
}
internal static ulong ValidateLeapSecond(DateTime value)
{
if (!IsValidTimeWithLeapSeconds(value))
{
ThrowHelper.ThrowArgumentOutOfRange_BadHourMinuteSecond();
}
return value._dateData;
}
private DateTime(SerializationInfo info, StreamingContext context)
{
if (info == null) ThrowHelper.ThrowArgumentNullException(ExceptionArgument.info);
bool foundTicks = false;
// Get the data
SerializationInfoEnumerator enumerator = info.GetEnumerator();
while (enumerator.MoveNext())
{
switch (enumerator.Name)
{
case TicksField:
_dateData = (ulong)Convert.ToInt64(enumerator.Value, CultureInfo.InvariantCulture);
foundTicks = true;
continue;
case DateDataField:
_dateData = Convert.ToUInt64(enumerator.Value, CultureInfo.InvariantCulture);
goto foundData;
}
}
if (!foundTicks)
{
throw new SerializationException(SR.Serialization_MissingDateTimeData);
}
foundData:
if (UTicks > MaxTicks)
{
throw new SerializationException(SR.Serialization_DateTimeTicksOutOfRange);
}
}
private ulong UTicks => _dateData & TicksMask;
private ulong InternalKind => _dateData & FlagsMask;
// Returns the DateTime resulting from adding the given
// TimeSpan to this DateTime.
//
public DateTime Add(TimeSpan value)
{
return AddTicks(value._ticks);
}
[MethodImpl(MethodImplOptions.AggressiveInlining)]
private DateTime AddUnits(double value, long maxUnitCount, long ticksPerUnit)
{
if (Math.Abs(value) > maxUnitCount)
{
ThrowAddOutOfRange();
}
double integralPart = Math.Truncate(value);
double fractionalPart = value - integralPart;
long ticks = (long)(integralPart) * ticksPerUnit;
ticks += (long)(fractionalPart * ticksPerUnit);
return AddTicks(ticks);
}
/// <summary>
/// Returns a new <see cref="DateTime"/> that adds the specified number of days to the value of this instance.
/// </summary>
/// <param name="value">A number of whole and fractional days. The value parameter can be negative or positive.</param>
/// <returns>
/// An object whose value is the sum of the date and time represented by this instance and the number of days represented by value.
/// </returns>
public DateTime AddDays(double value) => AddUnits(value, MaxDays, TimeSpan.TicksPerDay);
/// <summary>
/// Returns a new <see cref="DateTime"/> that adds the specified number of hours to the value of this instance.
/// </summary>
/// <param name="value">A number of whole and fractional hours. The value parameter can be negative or positive.</param>
/// <returns>
/// An object whose value is the sum of the date and time represented by this instance and the number of hours represented by value.
/// </returns>
public DateTime AddHours(double value) => AddUnits(value, MaxHours, TimeSpan.TicksPerHour);
/// <summary>
/// Returns a new <see cref="DateTime"/> that adds the specified number of milliseconds to the value of this instance.
/// </summary>
/// <param name="value">A number of whole and fractional milliseconds. The value parameter can be negative or positive.</param>
/// <returns>
/// An object whose value is the sum of the date and time represented by this instance and the number of milliseconds represented by value.
/// </returns>
public DateTime AddMilliseconds(double value) => AddUnits(value, MaxMillis, TimeSpan.TicksPerMillisecond);
/// <summary>
/// Returns a new <see cref="DateTime"/> that adds the specified number of microseconds to the value of this instance.
/// </summary>
/// <param name="value">
/// A number of whole and fractional microseconds.
/// The <paramref name="value"/> parameter can be negative or positive.
/// Note that this value is rounded to the nearest integer.
/// </param>
/// <returns>
/// An object whose value is the sum of the date and time represented
/// by this instance and the number of microseconds represented by <paramref name="value"/>.
/// </returns>
/// <remarks>
/// This method does not change the value of this <see cref="DateTime"/>. Instead, it returns a new <see cref="DateTime"/>
/// whose value is the result of this operation.
///
/// The fractional part of value is the fractional part of a microsecond.
/// For example, 4.5 is equivalent to 4 microseconds and 50 ticks, where one microsecond = 10 ticks.
///
/// The value parameter is rounded to the nearest integer.
/// </remarks>
/// <exception cref="ArgumentOutOfRangeException">
/// The resulting <see cref="DateTime"/> is less than <see cref="MinValue"/> or greater than <see cref="MaxValue"/>.
/// </exception>
public DateTime AddMicroseconds(double value) => AddUnits(value, MaxMicroseconds, TimeSpan.TicksPerMicrosecond);
/// <summary>
/// Returns a new <see cref="DateTime"/> that adds the specified number of minutes to the value of this instance.
/// </summary>
/// <param name="value">A number of whole and fractional minutes. The value parameter can be negative or positive.</param>
/// <returns>
/// An object whose value is the sum of the date and time represented by this instance and the number of minutes represented by value.
/// </returns>
public DateTime AddMinutes(double value) => AddUnits(value, MaxMinutes, TimeSpan.TicksPerMinute);
// Returns the DateTime resulting from adding the given number of
// months to this DateTime. The result is computed by incrementing
// (or decrementing) the year and month parts of this DateTime by
// months months, and, if required, adjusting the day part of the
// resulting date downwards to the last day of the resulting month in the
// resulting year. The time-of-day part of the result is the same as the
// time-of-day part of this DateTime.
//
// In more precise terms, considering this DateTime to be of the
// form y / m / d + t, where y is the
// year, m is the month, d is the day, and t is the
// time-of-day, the result is y1 / m1 / d1 + t,
// where y1 and m1 are computed by adding months months
// to y and m, and d1 is the largest value less than
// or equal to d that denotes a valid day in month m1 of year
// y1.
//
public DateTime AddMonths(int months) => AddMonths(this, months);
private static DateTime AddMonths(DateTime date, int months)
{
if (months < -120000 || months > 120000) throw new ArgumentOutOfRangeException(nameof(months), SR.ArgumentOutOfRange_DateTimeBadMonths);
date.GetDate(out int year, out int month, out int day);
int y = year, d = day;
int m = month + months;
int q = m > 0 ? (int)((uint)(m - 1) / 12) : m / 12 - 1;
y += q;
m -= q * 12;
if (y < 1 || y > 9999) ThrowDateArithmetic(2);
ReadOnlySpan<uint> daysTo = IsLeapYear(y) ? DaysToMonth366 : DaysToMonth365;
uint daysToMonth = daysTo[m - 1];
int days = (int)(daysTo[m] - daysToMonth);
if (d > days) d = days;
uint n = DaysToYear((uint)y) + daysToMonth + (uint)d - 1;
return new DateTime(n * (ulong)TimeSpan.TicksPerDay + date.UTicks % TimeSpan.TicksPerDay | date.InternalKind);
}
/// <summary>
/// Returns a new <see cref="DateTime"/> that adds the specified number of seconds to the value of this instance.
/// </summary>
/// <param name="value">A number of whole and fractional seconds. The value parameter can be negative or positive.</param>
/// <returns>
/// An object whose value is the sum of the date and time represented by this instance and the number of seconds represented by value.
/// </returns>
public DateTime AddSeconds(double value) => AddUnits(value, MaxSeconds, TimeSpan.TicksPerSecond);
// Returns the DateTime resulting from adding the given number of
// 100-nanosecond ticks to this DateTime. The value argument
// is permitted to be negative.
//
public DateTime AddTicks(long value)
{
ulong ticks = (ulong)(Ticks + value);
if (ticks > MaxTicks) ThrowDateArithmetic(0);
return new DateTime(ticks | InternalKind);
}
// TryAddTicks is exact as AddTicks except it doesn't throw
internal bool TryAddTicks(long value, out DateTime result)
{
ulong ticks = (ulong)(Ticks + value);
if (ticks > MaxTicks)
{
result = default;
return false;
}
result = new DateTime(ticks | InternalKind);
return true;
}
// Returns the DateTime resulting from adding the given number of
// years to this DateTime. The result is computed by incrementing
// (or decrementing) the year part of this DateTime by value
// years. If the month and day of this DateTime is 2/29, and if the
// resulting year is not a leap year, the month and day of the resulting
// DateTime becomes 2/28. Otherwise, the month, day, and time-of-day
// parts of the result are the same as those of this DateTime.
//
public DateTime AddYears(int value) => AddYears(this, value);
private static DateTime AddYears(DateTime date, int value)
{
if (value < -10000 || value > 10000)
{
throw new ArgumentOutOfRangeException(nameof(value), SR.ArgumentOutOfRange_DateTimeBadYears);
}
date.GetDate(out int year, out int month, out int day);
int y = year + value;
if (y < 1 || y > 9999) ThrowDateArithmetic(0);
uint n = DaysToYear((uint)y);
int m = month - 1, d = day - 1;
if (IsLeapYear(y))
{
n += DaysToMonth366[m];
}
else
{
if (d == 28 && m == 1) d--;
n += DaysToMonth365[m];
}
n += (uint)d;
return new DateTime(n * (ulong)TimeSpan.TicksPerDay + date.UTicks % TimeSpan.TicksPerDay | date.InternalKind);
}
// Compares two DateTime values, returning an integer that indicates
// their relationship.
//
public static int Compare(DateTime t1, DateTime t2)
{
long ticks1 = t1.Ticks;
long ticks2 = t2.Ticks;
if (ticks1 > ticks2) return 1;
if (ticks1 < ticks2) return -1;
return 0;
}
// Compares this DateTime to a given object. This method provides an
// implementation of the IComparable interface. The object
// argument must be another DateTime, or otherwise an exception
// occurs. Null is considered less than any instance.
//
// Returns a value less than zero if this object
public int CompareTo(object? value)
{
if (value == null) return 1;
if (!(value is DateTime))
{
throw new ArgumentException(SR.Arg_MustBeDateTime);
}
return Compare(this, (DateTime)value);
}
public int CompareTo(DateTime value)
{
return Compare(this, value);
}
// Returns the tick count corresponding to the given year, month, and day.
// Will check the if the parameters are valid.
[MethodImpl(MethodImplOptions.AggressiveInlining)]
private static ulong DateToTicks(int year, int month, int day)
{
if (year < 1 || year > 9999 || month < 1 || month > 12 || day < 1)
{
ThrowHelper.ThrowArgumentOutOfRange_BadYearMonthDay();
}
ReadOnlySpan<uint> days = RuntimeHelpers.IsKnownConstant(month) && month == 1 || IsLeapYear(year) ? DaysToMonth366 : DaysToMonth365;
if ((uint)day > days[month] - days[month - 1])
{
ThrowHelper.ThrowArgumentOutOfRange_BadYearMonthDay();
}
uint n = DaysToYear((uint)year) + days[month - 1] + (uint)day - 1;
return n * (ulong)TimeSpan.TicksPerDay;
}
[MethodImpl(MethodImplOptions.AggressiveInlining)]
private static uint DaysToYear(uint year)
{
uint y = year - 1;
uint cent = y / 100;
return y * (365 * 4 + 1) / 4 - cent + cent / 4;
}
// Return the tick count corresponding to the given hour, minute, second.
// Will check the if the parameters are valid.
[MethodImpl(MethodImplOptions.AggressiveInlining)]
private static ulong TimeToTicks(int hour, int minute, int second)
{
if ((uint)hour >= 24 || (uint)minute >= 60 || (uint)second >= 60)
{
ThrowHelper.ThrowArgumentOutOfRange_BadHourMinuteSecond();
}
int totalSeconds = hour * 3600 + minute * 60 + second;
return (uint)totalSeconds * (ulong)TimeSpan.TicksPerSecond;
}
internal static ulong TimeToTicks(int hour, int minute, int second, int millisecond)
{
ulong ticks = TimeToTicks(hour, minute, second);
if ((uint)millisecond >= TimeSpan.MillisecondsPerSecond) ThrowMillisecondOutOfRange();
ticks += (uint)millisecond * (uint)TimeSpan.TicksPerMillisecond;
Debug.Assert(ticks <= MaxTicks, "Input parameters validated already");
return ticks;
}
internal static ulong TimeToTicks(int hour, int minute, int second, int millisecond, int microsecond)
{
ulong ticks = TimeToTicks(hour, minute, second, millisecond);
if ((uint)microsecond >= TimeSpan.MicrosecondsPerMillisecond) ThrowMicrosecondOutOfRange();
ticks += (uint)microsecond * (uint)TimeSpan.TicksPerMicrosecond;
Debug.Assert(ticks <= MaxTicks, "Input parameters validated already");
return ticks;
}
// Returns the number of days in the month given by the year and
// month arguments.
//
public static int DaysInMonth(int year, int month)
{
if (month < 1 || month > 12) ThrowHelper.ThrowArgumentOutOfRange_Month(month);
// IsLeapYear checks the year argument
return (IsLeapYear(year) ? DaysInMonth366 : DaysInMonth365)[month - 1];
}
// Converts an OLE Date to a tick count.
// This function is duplicated in COMDateTime.cpp
internal static long DoubleDateToTicks(double value)
{
// The check done this way will take care of NaN
if (!(value < OADateMaxAsDouble) || !(value > OADateMinAsDouble))
throw new ArgumentException(SR.Arg_OleAutDateInvalid);
// Conversion to long will not cause an overflow here, as at this point the "value" is in between OADateMinAsDouble and OADateMaxAsDouble
long millis = (long)(value * TimeSpan.MillisecondsPerDay + (value >= 0 ? 0.5 : -0.5));
// The interesting thing here is when you have a value like 12.5 it all positive 12 days and 12 hours from 01/01/1899
// However if you a value of -12.25 it is minus 12 days but still positive 6 hours, almost as though you meant -11.75 all negative
// This line below fixes up the milliseconds in the negative case
if (millis < 0)
{
millis -= (millis % TimeSpan.MillisecondsPerDay) * 2;
}
millis += DoubleDateOffset / TimeSpan.TicksPerMillisecond;
if (millis < 0 || millis > MaxMillis) throw new ArgumentException(SR.Arg_OleAutDateScale);
return millis * TimeSpan.TicksPerMillisecond;
}
// Checks if this DateTime is equal to a given object. Returns
// true if the given object is a boxed DateTime and its value
// is equal to the value of this DateTime. Returns false
// otherwise.
//
public override bool Equals([NotNullWhen(true)] object? value)
{
return value is DateTime dt && this == dt;
}
public bool Equals(DateTime value)
{
return this == value;
}
// Compares two DateTime values for equality. Returns true if
// the two DateTime values are equal, or false if they are
// not equal.
//
public static bool Equals(DateTime t1, DateTime t2)
{
return t1 == t2;
}
public static DateTime FromBinary(long dateData)
{
if (((ulong)dateData & KindLocal) != 0)
{
// Local times need to be adjusted as you move from one time zone to another,
// just as they are when serializing in text. As such the format for local times
// changes to store the ticks of the UTC time, but with flags that look like a
// local date.
long ticks = dateData & (unchecked((long)TicksMask));
// Negative ticks are stored in the top part of the range and should be converted back into a negative number
if (ticks > TicksCeiling - TimeSpan.TicksPerDay)
{
ticks -= TicksCeiling;
}
// Convert the ticks back to local. If the UTC ticks are out of range, we need to default to
// the UTC offset from MinValue and MaxValue to be consistent with Parse.
bool isAmbiguousLocalDst = false;
long offsetTicks;
if ((ulong)ticks > MaxTicks)
{
offsetTicks = TimeZoneInfo.GetLocalUtcOffset(ticks < MinTicks ? MinValue : MaxValue, TimeZoneInfoOptions.NoThrowOnInvalidTime).Ticks;
}
else
{
// Because the ticks conversion between UTC and local is lossy, we need to capture whether the
// time is in a repeated hour so that it can be passed to the DateTime constructor.
DateTime utcDt = new DateTime(ticks, DateTimeKind.Utc);
offsetTicks = TimeZoneInfo.GetUtcOffsetFromUtc(utcDt, TimeZoneInfo.Local, out _, out isAmbiguousLocalDst).Ticks;
}
ticks += offsetTicks;
// Another behaviour of parsing is to cause small times to wrap around, so that they can be used
// to compare times of day
if (ticks < 0)
{
ticks += TimeSpan.TicksPerDay;
}
if ((ulong)ticks > MaxTicks)
{
throw new ArgumentException(SR.Argument_DateTimeBadBinaryData, nameof(dateData));
}
return new DateTime(ticks, DateTimeKind.Local, isAmbiguousLocalDst);
}
else
{
if (((ulong)dateData & TicksMask) > MaxTicks)
throw new ArgumentException(SR.Argument_DateTimeBadBinaryData, nameof(dateData));
return new DateTime((ulong)dateData);
}
}
// Creates a DateTime from a Windows filetime. A Windows filetime is
// a long representing the date and time as the number of
// 100-nanosecond intervals that have elapsed since 1/1/1601 12:00am.
//
public static DateTime FromFileTime(long fileTime)
{
return FromFileTimeUtc(fileTime).ToLocalTime();
}
public static DateTime FromFileTimeUtc(long fileTime)
{
if ((ulong)fileTime > MaxTicks - FileTimeOffset)
{
throw new ArgumentOutOfRangeException(nameof(fileTime), SR.ArgumentOutOfRange_FileTimeInvalid);
}
if (SystemSupportsLeapSeconds)
{
return FromFileTimeLeapSecondsAware((ulong)fileTime);
}
// This is the ticks in Universal time for this fileTime.
ulong universalTicks = (ulong)fileTime + FileTimeOffset;
return new DateTime(universalTicks | KindUtc);
}
// Creates a DateTime from an OLE Automation Date.
//
public static DateTime FromOADate(double d)
{
return new DateTime(DoubleDateToTicks(d), DateTimeKind.Unspecified);
}
void ISerializable.GetObjectData(SerializationInfo info, StreamingContext context)
{
if (info == null) ThrowHelper.ThrowArgumentNullException(ExceptionArgument.info);
// Serialize both the old and the new format
info.AddValue(TicksField, Ticks);
info.AddValue(DateDataField, _dateData);
}
public bool IsDaylightSavingTime()
{
if (_dateData >> KindShift == (int)DateTimeKind.Utc)
{
return false;
}
return TimeZoneInfo.Local.IsDaylightSavingTime(this, TimeZoneInfoOptions.NoThrowOnInvalidTime);
}
public static DateTime SpecifyKind(DateTime value, DateTimeKind kind)
{
if ((uint)kind > (uint)DateTimeKind.Local) ThrowInvalidKind();
return new DateTime(value.UTicks | ((ulong)(uint)kind << KindShift));
}
public long ToBinary()
{
if ((_dateData & KindLocal) != 0)
{
// Local times need to be adjusted as you move from one time zone to another,
// just as they are when serializing in text. As such the format for local times
// changes to store the ticks of the UTC time, but with flags that look like a
// local date.
// To match serialization in text we need to be able to handle cases where
// the UTC value would be out of range. Unused parts of the ticks range are
// used for this, so that values just past max value are stored just past the
// end of the maximum range, and values just below minimum value are stored
// at the end of the ticks area, just below 2^62.
TimeSpan offset = TimeZoneInfo.GetLocalUtcOffset(this, TimeZoneInfoOptions.NoThrowOnInvalidTime);
long ticks = Ticks;
long storedTicks = ticks - offset.Ticks;
if (storedTicks < 0)
{
storedTicks = TicksCeiling + storedTicks;
}
return storedTicks | (unchecked((long)KindLocal));
}
else
{
return (long)_dateData;
}
}
// Returns the date part of this DateTime. The resulting value
// corresponds to this DateTime with the time-of-day part set to
// zero (midnight).
//
public DateTime Date => new((UTicks / TimeSpan.TicksPerDay * TimeSpan.TicksPerDay) | InternalKind);
// Exactly the same as Year, Month, Day properties, except computing all of
// year/month/day rather than just one of them. Used when all three
// are needed rather than redoing the computations for each.
//
// Implementation based on article https://arxiv.org/pdf/2102.06959.pdf
// Cassio Neri, Lorenz Schneider - Euclidean Affine Functions and Applications to Calendar Algorithms - 2021
internal void GetDate(out int year, out int month, out int day) => GetDate(_dateData, out year, out month, out day);
private static void GetDate(ulong dateData, out int year, out int month, out int day)
{
// y100 = number of whole 100-year periods since 3/1/0000
// r1 = (day number within 100-year period) * 4
(uint y100, uint r1) = Math.DivRem(((uint)((dateData & TicksMask) / TicksPer6Hours) | 3U) + 1224, DaysPer400Years);
ulong u2 = Math.BigMul(EafMultiplier, r1 | 3U);
uint daySinceMarch1 = (uint)u2 / EafDivider;
uint n3 = 2141 * daySinceMarch1 + 197913;
year = (int)(100 * y100 + (uint)(u2 >> 32));
// compute month and day
month = (int)(n3 >> 16);
day = (ushort)n3 / 2141 + 1;
// rollover December 31
if (daySinceMarch1 >= March1BasedDayOfNewYear)
{
++year;
month -= 12;
}
}
[MethodImpl(MethodImplOptions.AggressiveInlining)]
internal void GetTime(out int hour, out int minute, out int second)
{
ulong seconds = UTicks / TimeSpan.TicksPerSecond;
ulong minutes = seconds / 60;
second = (int)(seconds - (minutes * 60));
ulong hours = minutes / 60;
minute = (int)(minutes - (hours * 60));
hour = (int)((uint)hours % 24);
}
[MethodImpl(MethodImplOptions.AggressiveInlining)]
internal void GetTime(out int hour, out int minute, out int second, out int millisecond)
{
ulong milliseconds = UTicks / TimeSpan.TicksPerMillisecond;
ulong seconds = milliseconds / 1000;
millisecond = (int)(milliseconds - (seconds * 1000));
ulong minutes = seconds / 60;
second = (int)(seconds - (minutes * 60));
ulong hours = minutes / 60;
minute = (int)(minutes - (hours * 60));
hour = (int)((uint)hours % 24);
}
[MethodImpl(MethodImplOptions.AggressiveInlining)]
internal void GetTimePrecise(out int hour, out int minute, out int second, out int tick)
{
ulong ticks = UTicks;
ulong seconds = ticks / TimeSpan.TicksPerSecond;
tick = (int)(ticks - (seconds * TimeSpan.TicksPerSecond));
ulong minutes = seconds / 60;
second = (int)(seconds - (minutes * 60));
ulong hours = minutes / 60;
minute = (int)(minutes - (hours * 60));
hour = (int)((uint)hours % 24);
}
// Returns the day-of-month part of this DateTime. The returned
// value is an integer between 1 and 31.
//
public int Day
{
get
{
// r1 = (day number within 100-year period) * 4
uint r1 = (((uint)(UTicks / TicksPer6Hours) | 3U) + 1224) % DaysPer400Years;
ulong u2 = Math.BigMul(EafMultiplier, r1 | 3U);
ushort daySinceMarch1 = (ushort)((uint)u2 / EafDivider);
int n3 = 2141 * daySinceMarch1 + 197913;
// Return 1-based day-of-month
return (ushort)n3 / 2141 + 1;
}
}
// Returns the day-of-week part of this DateTime. The returned value
// is an integer between 0 and 6, where 0 indicates Sunday, 1 indicates
// Monday, 2 indicates Tuesday, 3 indicates Wednesday, 4 indicates
// Thursday, 5 indicates Friday, and 6 indicates Saturday.
//
public DayOfWeek DayOfWeek => (DayOfWeek)(((uint)(UTicks / TimeSpan.TicksPerDay) + 1) % 7);
// Returns the day-of-year part of this DateTime. The returned value
// is an integer between 1 and 366.
//
public int DayOfYear =>
1 + (int)(((((uint)(UTicks / TicksPer6Hours) | 3U) % (uint)DaysPer400Years) | 3U) * EafMultiplier / EafDivider);
// Returns the hash code for this DateTime.
//
public override int GetHashCode()
{
long ticks = Ticks;
return unchecked((int)ticks) ^ (int)(ticks >> 32);
}
// Returns the hour part of this DateTime. The returned value is an
// integer between 0 and 23.
//
public int Hour => (int)((uint)(UTicks / TimeSpan.TicksPerHour) % 24);
internal bool IsAmbiguousDaylightSavingTime() => _dateData >= KindLocalAmbiguousDst;
public DateTimeKind Kind
{
[MethodImpl(MethodImplOptions.AggressiveInlining)]
get
{
uint kind = (uint)(_dateData >> KindShift);
// values 0-2 map directly to DateTimeKind, 3 (LocalAmbiguousDst) needs to be mapped to 2 (Local) using bit0 NAND bit1
return (DateTimeKind)(kind & ~(kind >> 1));
}
}
// Returns the millisecond part of this DateTime. The returned value
// is an integer between 0 and 999.
//
public int Millisecond => (int)((UTicks / TimeSpan.TicksPerMillisecond) % 1000);
/// <summary>
/// The microseconds component, expressed as a value between 0 and 999.
/// </summary>
public int Microsecond => (int)((UTicks / TimeSpan.TicksPerMicrosecond) % 1000);
/// <summary>
/// The nanoseconds component, expressed as a value between 0 and 900 (in increments of 100 nanoseconds).
/// </summary>
public int Nanosecond => (int)(UTicks % TimeSpan.TicksPerMicrosecond) * 100;
// Returns the minute part of this DateTime. The returned value is
// an integer between 0 and 59.
//
public int Minute => (int)((UTicks / TimeSpan.TicksPerMinute) % 60);
// Returns the month part of this DateTime. The returned value is an
// integer between 1 and 12.
//
public int Month
{
get
{
// r1 = (day number within 100-year period) * 4
uint r1 = (((uint)(UTicks / TicksPer6Hours) | 3U) + 1224) % DaysPer400Years;
ulong u2 = Math.BigMul(EafMultiplier, r1 | 3U);
ushort daySinceMarch1 = (ushort)((uint)u2 / EafDivider);
int n3 = 2141 * daySinceMarch1 + 197913;
return (ushort)(n3 >> 16) - (daySinceMarch1 >= March1BasedDayOfNewYear ? 12 : 0);
}
}
// Returns a DateTime representing the current date and time. The
// resolution of the returned value depends on the system timer.
public static DateTime Now
{
get
{
DateTime utc = UtcNow;
long offset = TimeZoneInfo.GetDateTimeNowUtcOffsetFromUtc(utc, out bool isAmbiguousLocalDst).Ticks;
long tick = utc.Ticks + offset;
if ((ulong)tick <= MaxTicks)
{
if (!isAmbiguousLocalDst)
{
return new DateTime((ulong)tick | KindLocal);
}
return new DateTime((ulong)tick | KindLocalAmbiguousDst);
}
return new DateTime(tick < 0 ? KindLocal : MaxTicks | KindLocal);
}
}
// Returns the second part of this DateTime. The returned value is
// an integer between 0 and 59.
//
public int Second => (int)((UTicks / TimeSpan.TicksPerSecond) % 60);
// Returns the tick count for this DateTime. The returned value is
// the number of 100-nanosecond intervals that have elapsed since 1/1/0001
// 12:00am.
//
public long Ticks => (long)(_dateData & TicksMask);
// Returns the time-of-day part of this DateTime. The returned value
// is a TimeSpan that indicates the time elapsed since midnight.
//
public TimeSpan TimeOfDay => new TimeSpan((long)(UTicks % TimeSpan.TicksPerDay));
// Returns a DateTime representing the current date. The date part
// of the returned value is the current date, and the time-of-day part of
// the returned value is zero (midnight).
//
public static DateTime Today => Now.Date;
// Returns the year part of this DateTime. The returned value is an
// integer between 1 and 9999.
//
public int Year => GetYear(_dateData);
private static int GetYear(ulong dateData)
{
// y100 = number of whole 100-year periods since 1/1/0001
// r1 = (day number within 100-year period) * 4
(uint y100, uint r1) = Math.DivRem(((uint)((dateData & TicksMask) / TicksPer6Hours) | 3U), DaysPer400Years);
return 1 + (int)(100 * y100 + (r1 | 3) / DaysPer4Years);
}
// Checks whether a given year is a leap year. This method returns true if
// year is a leap year, or false if not.
//
[MethodImpl(MethodImplOptions.AggressiveInlining)]
public static bool IsLeapYear(int year)
{
if (year < 1 || year > 9999)
{
ThrowHelper.ThrowArgumentOutOfRange_Year();
}
if ((year & 3) != 0) return false;
if ((year & 15) == 0) return true;
return (uint)year % 25 != 0;
}
// Constructs a DateTime from a string. The string must specify a
// date and optionally a time in a culture-specific or universal format.
// Leading and trailing whitespace characters are allowed.
//
public static DateTime Parse(string s)
{
if (s == null) ThrowHelper.ThrowArgumentNullException(ExceptionArgument.s);
return DateTimeParse.Parse(s, DateTimeFormatInfo.CurrentInfo, DateTimeStyles.None);
}
// Constructs a DateTime from a string. The string must specify a
// date and optionally a time in a culture-specific or universal format.
// Leading and trailing whitespace characters are allowed.
//
public static DateTime Parse(string s, IFormatProvider? provider)
{
if (s == null) ThrowHelper.ThrowArgumentNullException(ExceptionArgument.s);
return DateTimeParse.Parse(s, DateTimeFormatInfo.GetInstance(provider), DateTimeStyles.None);
}
public static DateTime Parse(string s, IFormatProvider? provider, DateTimeStyles styles)
{
DateTimeFormatInfo.ValidateStyles(styles, styles: true);
if (s == null) ThrowHelper.ThrowArgumentNullException(ExceptionArgument.s);
return DateTimeParse.Parse(s, DateTimeFormatInfo.GetInstance(provider), styles);
}
public static DateTime Parse(ReadOnlySpan<char> s, IFormatProvider? provider = null, DateTimeStyles styles = DateTimeStyles.None)
{
DateTimeFormatInfo.ValidateStyles(styles, styles: true);
return DateTimeParse.Parse(s, DateTimeFormatInfo.GetInstance(provider), styles);
}
// Constructs a DateTime from a string. The string must specify a
// date and optionally a time in a culture-specific or universal format.
// Leading and trailing whitespace characters are allowed.
//
public static DateTime ParseExact(string s, [StringSyntax(StringSyntaxAttribute.DateTimeFormat)] string format, IFormatProvider? provider)
{
if (s == null) ThrowHelper.ThrowArgumentNullException(ExceptionArgument.s);
if (format == null) ThrowHelper.ThrowArgumentNullException(ExceptionArgument.format);
return DateTimeParse.ParseExact(s, format, DateTimeFormatInfo.GetInstance(provider), DateTimeStyles.None);
}
// Constructs a DateTime from a string. The string must specify a
// date and optionally a time in a culture-specific or universal format.
// Leading and trailing whitespace characters are allowed.
//
public static DateTime ParseExact(string s, [StringSyntax(StringSyntaxAttribute.DateTimeFormat)] string format, IFormatProvider? provider, DateTimeStyles style)
{
DateTimeFormatInfo.ValidateStyles(style);
if (s == null) ThrowHelper.ThrowArgumentNullException(ExceptionArgument.s);
if (format == null) ThrowHelper.ThrowArgumentNullException(ExceptionArgument.format);
return DateTimeParse.ParseExact(s, format, DateTimeFormatInfo.GetInstance(provider), style);
}
public static DateTime ParseExact(ReadOnlySpan<char> s, [StringSyntax(StringSyntaxAttribute.DateTimeFormat)] ReadOnlySpan<char> format, IFormatProvider? provider, DateTimeStyles style = DateTimeStyles.None)
{
DateTimeFormatInfo.ValidateStyles(style);
return DateTimeParse.ParseExact(s, format, DateTimeFormatInfo.GetInstance(provider), style);
}
public static DateTime ParseExact(string s, [StringSyntax(StringSyntaxAttribute.DateTimeFormat)] string[] formats, IFormatProvider? provider, DateTimeStyles style)
{
DateTimeFormatInfo.ValidateStyles(style);
if (s == null) ThrowHelper.ThrowArgumentNullException(ExceptionArgument.s);
return DateTimeParse.ParseExactMultiple(s, formats, DateTimeFormatInfo.GetInstance(provider), style);
}
public static DateTime ParseExact(ReadOnlySpan<char> s, [StringSyntax(StringSyntaxAttribute.DateTimeFormat)] string[] formats, IFormatProvider? provider, DateTimeStyles style = DateTimeStyles.None)
{
DateTimeFormatInfo.ValidateStyles(style);
return DateTimeParse.ParseExactMultiple(s, formats, DateTimeFormatInfo.GetInstance(provider), style);
}
public TimeSpan Subtract(DateTime value)
{
return new TimeSpan(Ticks - value.Ticks);
}
public DateTime Subtract(TimeSpan value)
{
ulong ticks = (ulong)(Ticks - value._ticks);
if (ticks > MaxTicks) ThrowDateArithmetic(0);
return new DateTime(ticks | InternalKind);
}
// This function is duplicated in COMDateTime.cpp
private static double TicksToOADate(long value)
{
if (value == 0)
return 0.0; // Returns OleAut's zero'ed date value.
if (value < TimeSpan.TicksPerDay) // This is a fix for VB. They want the default day to be 1/1/0001 rather than 12/30/1899.
value += DoubleDateOffset; // We could have moved this fix down but we would like to keep the bounds check.
if (value < OADateMinAsTicks)
throw new OverflowException(SR.Arg_OleAutDateInvalid);
// Currently, our max date == OA's max date (12/31/9999), so we don't
// need an overflow check in that direction.
long millis = (value - DoubleDateOffset) / TimeSpan.TicksPerMillisecond;
if (millis < 0)
{
long frac = millis % TimeSpan.MillisecondsPerDay;
if (frac != 0) millis -= (TimeSpan.MillisecondsPerDay + frac) * 2;
}
return (double)millis / TimeSpan.MillisecondsPerDay;
}
// Converts the DateTime instance into an OLE Automation compatible
// double date.
public double ToOADate()
{
return TicksToOADate(Ticks);
}
public long ToFileTime()
{
// Treats the input as local if it is not specified
return ToUniversalTime().ToFileTimeUtc();
}
public long ToFileTimeUtc()
{
// Treats the input as universal if it is not specified
long ticks = ((_dateData & KindLocal) != 0) ? ToUniversalTime().Ticks : Ticks;
if (SystemSupportsLeapSeconds)
{
return (long)ToFileTimeLeapSecondsAware(ticks);
}
ticks -= FileTimeOffset;
if (ticks < 0)
{
throw new ArgumentOutOfRangeException(null, SR.ArgumentOutOfRange_FileTimeInvalid);
}
return ticks;
}
public DateTime ToLocalTime()
{
if ((_dateData & KindLocal) != 0)
{
return this;
}
long offset = TimeZoneInfo.GetUtcOffsetFromUtc(this, TimeZoneInfo.Local, out _, out bool isAmbiguousLocalDst).Ticks;
long tick = Ticks + offset;
if ((ulong)tick <= MaxTicks)
{
if (!isAmbiguousLocalDst)
{
return new DateTime((ulong)tick | KindLocal);
}
return new DateTime((ulong)tick | KindLocalAmbiguousDst);
}
return new DateTime(tick < 0 ? KindLocal : MaxTicks | KindLocal);
}
public string ToLongDateString()
{
return DateTimeFormat.Format(this, "D", null);
}
public string ToLongTimeString()
{
return DateTimeFormat.Format(this, "T", null);
}
public string ToShortDateString()
{
return DateTimeFormat.Format(this, "d", null);
}
public string ToShortTimeString()
{
return DateTimeFormat.Format(this, "t", null);
}
public override string ToString()
{
return DateTimeFormat.Format(this, null, null);
}
public string ToString([StringSyntax(StringSyntaxAttribute.DateTimeFormat)] string? format)
{
return DateTimeFormat.Format(this, format, null);
}
public string ToString(IFormatProvider? provider)
{
return DateTimeFormat.Format(this, null, provider);
}
public string ToString([StringSyntax(StringSyntaxAttribute.DateTimeFormat)] string? format, IFormatProvider? provider)
{
return DateTimeFormat.Format(this, format, provider);
}
public bool TryFormat(Span<char> destination, out int charsWritten, [StringSyntax(StringSyntaxAttribute.DateTimeFormat)] ReadOnlySpan<char> format = default, IFormatProvider? provider = null) =>
DateTimeFormat.TryFormat(this, destination, out charsWritten, format, provider);
/// <inheritdoc cref="IUtf8SpanFormattable.TryFormat" />
public bool TryFormat(Span<byte> utf8Destination, out int bytesWritten, [StringSyntax(StringSyntaxAttribute.DateTimeFormat)] ReadOnlySpan<char> format = default, IFormatProvider? provider = null) =>
DateTimeFormat.TryFormat(this, utf8Destination, out bytesWritten, format, provider);
public DateTime ToUniversalTime()
=> _dateData >> KindShift == (int)DateTimeKind.Utc ? this : TimeZoneInfo.ConvertTimeToUtc(this, TimeZoneInfoOptions.NoThrowOnInvalidTime);
public static bool TryParse([NotNullWhen(true)] string? s, out DateTime result)
{
if (s == null)
{
result = default;
return false;
}
return DateTimeParse.TryParse(s, DateTimeFormatInfo.CurrentInfo, DateTimeStyles.None, out result);
}
public static bool TryParse(ReadOnlySpan<char> s, out DateTime result)
{
return DateTimeParse.TryParse(s, DateTimeFormatInfo.CurrentInfo, DateTimeStyles.None, out result);
}
public static bool TryParse([NotNullWhen(true)] string? s, IFormatProvider? provider, DateTimeStyles styles, out DateTime result)
{
DateTimeFormatInfo.ValidateStyles(styles, styles: true);
if (s == null)
{
result = default;
return false;
}
return DateTimeParse.TryParse(s, DateTimeFormatInfo.GetInstance(provider), styles, out result);
}
public static bool TryParse(ReadOnlySpan<char> s, IFormatProvider? provider, DateTimeStyles styles, out DateTime result)
{
DateTimeFormatInfo.ValidateStyles(styles, styles: true);
return DateTimeParse.TryParse(s, DateTimeFormatInfo.GetInstance(provider), styles, out result);
}
public static bool TryParseExact([NotNullWhen(true)] string? s, [NotNullWhen(true), StringSyntax(StringSyntaxAttribute.DateTimeFormat)] string? format, IFormatProvider? provider, DateTimeStyles style, out DateTime result)
{
DateTimeFormatInfo.ValidateStyles(style);
if (s == null || format == null)
{
result = default;
return false;
}
return DateTimeParse.TryParseExact(s, format, DateTimeFormatInfo.GetInstance(provider), style, out result);
}
public static bool TryParseExact(ReadOnlySpan<char> s, [StringSyntax(StringSyntaxAttribute.DateTimeFormat)] ReadOnlySpan<char> format, IFormatProvider? provider, DateTimeStyles style, out DateTime result)
{
DateTimeFormatInfo.ValidateStyles(style);
return DateTimeParse.TryParseExact(s, format, DateTimeFormatInfo.GetInstance(provider), style, out result);
}
public static bool TryParseExact([NotNullWhen(true)] string? s, [NotNullWhen(true), StringSyntax(StringSyntaxAttribute.DateTimeFormat)] string?[]? formats, IFormatProvider? provider, DateTimeStyles style, out DateTime result)
{
DateTimeFormatInfo.ValidateStyles(style);
if (s == null)
{
result = default;
return false;
}
return DateTimeParse.TryParseExactMultiple(s, formats, DateTimeFormatInfo.GetInstance(provider), style, out result);
}
public static bool TryParseExact(ReadOnlySpan<char> s, [NotNullWhen(true), StringSyntax(StringSyntaxAttribute.DateTimeFormat)] string?[]? formats, IFormatProvider? provider, DateTimeStyles style, out DateTime result)
{
DateTimeFormatInfo.ValidateStyles(style);
return DateTimeParse.TryParseExactMultiple(s, formats, DateTimeFormatInfo.GetInstance(provider), style, out result);
}
public static DateTime operator +(DateTime d, TimeSpan t)
{
ulong ticks = (ulong)(d.Ticks + t._ticks);
if (ticks > MaxTicks) ThrowDateArithmetic(1);
return new DateTime(ticks | d.InternalKind);
}
public static DateTime operator -(DateTime d, TimeSpan t)
{
ulong ticks = (ulong)(d.Ticks - t._ticks);
if (ticks > MaxTicks) ThrowDateArithmetic(1);
return new DateTime(ticks | d.InternalKind);
}
public static TimeSpan operator -(DateTime d1, DateTime d2) => new TimeSpan(d1.Ticks - d2.Ticks);
public static bool operator ==(DateTime d1, DateTime d2) => ((d1._dateData ^ d2._dateData) << 2) == 0;
public static bool operator !=(DateTime d1, DateTime d2) => !(d1 == d2);
/// <inheritdoc cref="IComparisonOperators{TSelf, TOther, TResult}.op_LessThan(TSelf, TOther)" />
public static bool operator <(DateTime t1, DateTime t2) => t1.Ticks < t2.Ticks;
/// <inheritdoc cref="IComparisonOperators{TSelf, TOther, TResult}.op_LessThanOrEqual(TSelf, TOther)" />
public static bool operator <=(DateTime t1, DateTime t2) => t1.Ticks <= t2.Ticks;
/// <inheritdoc cref="IComparisonOperators{TSelf, TOther, TResult}.op_GreaterThan(TSelf, TOther)" />
public static bool operator >(DateTime t1, DateTime t2) => t1.Ticks > t2.Ticks;
/// <inheritdoc cref="IComparisonOperators{TSelf, TOther, TResult}.op_GreaterThanOrEqual(TSelf, TOther)" />
public static bool operator >=(DateTime t1, DateTime t2) => t1.Ticks >= t2.Ticks;
/// <summary>
/// Deconstructs <see cref="DateTime"/> into <see cref="DateOnly"/> and <see cref="TimeOnly"/>.
/// </summary>
/// <param name="date">
/// Deconstructed <see cref="DateOnly"/>.
/// </param>
/// <param name="time">
/// Deconstructed <see cref="TimeOnly"/>.
/// </param>
[EditorBrowsable(EditorBrowsableState.Never)]
public void Deconstruct(out DateOnly date, out TimeOnly time)
{
date = DateOnly.FromDateTime(this);
time = TimeOnly.FromDateTime(this);
}
/// <summary>
/// Deconstructs <see cref="DateOnly"/> by <see cref="Year"/>, <see cref="Month"/> and <see cref="Day"/>.
/// </summary>
/// <param name="year">
/// Deconstructed parameter for <see cref="Year"/>.
/// </param>
/// <param name="month">
/// Deconstructed parameter for <see cref="Month"/>.
/// </param>
/// <param name="day">
/// Deconstructed parameter for <see cref="Day"/>.
/// </param>
[EditorBrowsable(EditorBrowsableState.Never)]
public void Deconstruct(out int year, out int month, out int day)
{
GetDate(out year, out month, out day);
}
// Returns a string array containing all of the known date and time options for the
// current culture. The strings returned are properly formatted date and
// time strings for the current instance of DateTime.
public string[] GetDateTimeFormats()
{
return GetDateTimeFormats(CultureInfo.CurrentCulture);
}
// Returns a string array containing all of the known date and time options for the
// using the information provided by IFormatProvider. The strings returned are properly formatted date and
// time strings for the current instance of DateTime.
public string[] GetDateTimeFormats(IFormatProvider? provider)
{
return DateTimeFormat.GetAllDateTimes(this, DateTimeFormatInfo.GetInstance(provider));
}
// Returns a string array containing all of the date and time options for the
// given format format and current culture. The strings returned are properly formatted date and
// time strings for the current instance of DateTime.
public string[] GetDateTimeFormats(char format)
{
return GetDateTimeFormats(format, CultureInfo.CurrentCulture);
}
// Returns a string array containing all of the date and time options for the
// given format format and given culture. The strings returned are properly formatted date and
// time strings for the current instance of DateTime.
public string[] GetDateTimeFormats(char format, IFormatProvider? provider)
{
return DateTimeFormat.GetAllDateTimes(this, format, DateTimeFormatInfo.GetInstance(provider));
}
//
// IConvertible implementation
//
public TypeCode GetTypeCode() => TypeCode.DateTime;
bool IConvertible.ToBoolean(IFormatProvider? provider) => throw InvalidCast(nameof(Boolean));
char IConvertible.ToChar(IFormatProvider? provider) => throw InvalidCast(nameof(Char));
sbyte IConvertible.ToSByte(IFormatProvider? provider) => throw InvalidCast(nameof(SByte));
byte IConvertible.ToByte(IFormatProvider? provider) => throw InvalidCast(nameof(Byte));
short IConvertible.ToInt16(IFormatProvider? provider) => throw InvalidCast(nameof(Int16));
ushort IConvertible.ToUInt16(IFormatProvider? provider) => throw InvalidCast(nameof(UInt16));
int IConvertible.ToInt32(IFormatProvider? provider) => throw InvalidCast(nameof(Int32));
uint IConvertible.ToUInt32(IFormatProvider? provider) => throw InvalidCast(nameof(UInt32));
long IConvertible.ToInt64(IFormatProvider? provider) => throw InvalidCast(nameof(Int64));
ulong IConvertible.ToUInt64(IFormatProvider? provider) => throw InvalidCast(nameof(UInt64));
float IConvertible.ToSingle(IFormatProvider? provider) => throw InvalidCast(nameof(Single));
double IConvertible.ToDouble(IFormatProvider? provider) => throw InvalidCast(nameof(Double));
decimal IConvertible.ToDecimal(IFormatProvider? provider) => throw InvalidCast(nameof(Decimal));
private static InvalidCastException InvalidCast(string to) => new InvalidCastException(SR.Format(SR.InvalidCast_FromTo, nameof(DateTime), to));
DateTime IConvertible.ToDateTime(IFormatProvider? provider) => this;
object IConvertible.ToType(Type type, IFormatProvider? provider) => Convert.DefaultToType(this, type, provider);
// Tries to construct a DateTime from a given year, month, day, hour,
// minute, second and millisecond.
//
internal static bool TryCreate(int year, int month, int day, int hour, int minute, int second, int millisecond, out DateTime result)
{
result = default;
if (year < 1 || year > 9999 || month < 1 || month > 12 || day < 1)
{
return false;
}
if ((uint)hour >= 24 || (uint)minute >= 60 || (uint)millisecond >= TimeSpan.MillisecondsPerSecond)
{
return false;
}
ReadOnlySpan<uint> days = IsLeapYear(year) ? DaysToMonth366 : DaysToMonth365;
if ((uint)day > days[month] - days[month - 1])
{
return false;
}
ulong ticks = (DaysToYear((uint)year) + days[month - 1] + (uint)day - 1) * (ulong)TimeSpan.TicksPerDay;
if ((uint)second < 60)
{
ticks += TimeToTicks(hour, minute, second) + (uint)millisecond * (uint)TimeSpan.TicksPerMillisecond;
}
else if (second == 60 && SystemSupportsLeapSeconds)
{
// if we have leap second (second = 60) then we'll need to check if it is valid time.
// if it is valid, then we adjust the second to 59 so DateTime will consider this second is last second
// of this minute.
// if it is not valid time, we'll eventually throw.
// although this is unspecified datetime kind, we'll assume the passed time is UTC to check the leap seconds.
ticks += TimeToTicks(hour, minute, 59) + 999 * TimeSpan.TicksPerMillisecond;
if (!IsValidTimeWithLeapSeconds(new DateTime(ticks)))
return false;
}
else
{
return false;
}
Debug.Assert(ticks <= MaxTicks, "Input parameters validated already");
result = new DateTime(ticks);
return true;
}
//
// IParsable
//
/// <inheritdoc cref="IParsable{TSelf}.TryParse(string?, IFormatProvider?, out TSelf)" />
public static bool TryParse([NotNullWhen(true)] string? s, IFormatProvider? provider, out DateTime result) => TryParse(s, provider, DateTimeStyles.None, out result);
//
// ISpanParsable
//
/// <inheritdoc cref="ISpanParsable{TSelf}.Parse(ReadOnlySpan{char}, IFormatProvider?)" />
public static DateTime Parse(ReadOnlySpan<char> s, IFormatProvider? provider) => Parse(s, provider, DateTimeStyles.None);
/// <inheritdoc cref="ISpanParsable{TSelf}.TryParse(ReadOnlySpan{char}, IFormatProvider?, out TSelf)" />
public static bool TryParse(ReadOnlySpan<char> s, IFormatProvider? provider, out DateTime result) => TryParse(s, provider, DateTimeStyles.None, out result);
}
}
|