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268 lines
7.6 KiB
268 lines
7.6 KiB
#include "stdafx.h"
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#include <windows.h>
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#include "helper.h"
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///////////////////////////////////////////////////////////////////////////////
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//
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// Portion copy from private\ntos\rtl\time.c
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//
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///////////////////////////////////////////////////////////////////////////////
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//
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// ULONG
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// NumberOfLeapYears (
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// IN ULONG ElapsedYears
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// );
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//
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// The number of leap years is simply the number of years divided by 4
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// minus years divided by 100 plus years divided by 400. This says
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// that every four years is a leap year except centuries, and the
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// exception to the exception is the quadricenturies
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//
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#define NumberOfLeapYears(YEARS) ( \
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((YEARS) / 4) - ((YEARS) / 100) + ((YEARS) / 400) \
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)
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//
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// ULONG
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// ElapsedYearsToDays (
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// IN ULONG ElapsedYears
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// );
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//
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// The number of days contained in elapsed years is simply the number
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// of years times 365 (because every year has at least 365 days) plus
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// the number of leap years there are (i.e., the number of 366 days years)
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//
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#define ElapsedYearsToDays(YEARS) ( \
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((YEARS) * 365) + NumberOfLeapYears(YEARS) \
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)
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//
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// BOOLEAN
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// IsLeapYear (
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// IN ULONG ElapsedYears
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// );
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//
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// If it is an even 400 or a non century leapyear then the
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// answer is true otherwise it's false
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//
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#define IsLeapYear(YEARS) ( \
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(((YEARS) % 400 == 0) || \
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((YEARS) % 100 != 0) && ((YEARS) % 4 == 0)) ? \
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TRUE \
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: \
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FALSE \
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)
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//
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// ULONG
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// MaxDaysInMonth (
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// IN ULONG Year,
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// IN ULONG Month
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// );
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//
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// The maximum number of days in a month depend on the year and month.
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// It is the difference between the days to the month and the days
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// to the following month
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//
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#define MaxDaysInMonth(YEAR,MONTH) ( \
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IsLeapYear(YEAR) ? \
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LeapYearDaysPrecedingMonth[(MONTH) + 1] - \
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LeapYearDaysPrecedingMonth[(MONTH)] \
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: \
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NormalYearDaysPrecedingMonth[(MONTH) + 1] - \
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NormalYearDaysPrecedingMonth[(MONTH)] \
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)
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#define ConvertDaysToMilliseconds(DAYS) ( \
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Int32x32To64( (DAYS), 86400000 ) \
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)
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//
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// The following two tables map a month index to the number of days preceding
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// the month in the year. Both tables are zero based. For example, 1 (Feb)
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// has 31 days preceding it. To help calculate the maximum number of days
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// in a month each table has 13 entries, so the number of days in a month
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// of index i is the table entry of i+1 minus the table entry of i.
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//
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CONST USHORT LeapYearDaysPrecedingMonth[13] = {
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0, // January
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31, // February
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31+29, // March
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31+29+31, // April
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31+29+31+30, // May
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31+29+31+30+31, // June
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31+29+31+30+31+30, // July
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31+29+31+30+31+30+31, // August
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31+29+31+30+31+30+31+31, // September
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31+29+31+30+31+30+31+31+30, // October
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31+29+31+30+31+30+31+31+30+31, // November
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31+29+31+30+31+30+31+31+30+31+30, // December
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31+29+31+30+31+30+31+31+30+31+30+31};
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CONST USHORT NormalYearDaysPrecedingMonth[13] = {
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0, // January
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31, // February
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31+28, // March
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31+28+31, // April
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31+28+31+30, // May
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31+28+31+30+31, // June
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31+28+31+30+31+30, // July
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31+28+31+30+31+30+31, // August
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31+28+31+30+31+30+31+31, // September
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31+28+31+30+31+30+31+31+30, // October
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31+28+31+30+31+30+31+31+30+31, // November
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31+28+31+30+31+30+31+31+30+31+30, // December
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31+28+31+30+31+30+31+31+30+31+30+31};
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//
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// These are known constants used to convert 1970 and 1980 times to 1601
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// times. They are the number of seconds from the 1601 base to the start
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// of 1970 and the start of 1980. The number of seconds from 1601 to
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// 1970 is 369 years worth, or (369 * 365) + 89 leap days = 134774 days, or
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// 134774 * 864000 seconds, which is equal to the large integer defined
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// below. The number of seconds from 1601 to 1980 is 379 years worth, or etc.
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//
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const LARGE_INTEGER SecondsToStartOf1970 = {0xb6109100, 0x00000002};
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const LARGE_INTEGER SecondsToStartOf1980 = {0xc8df3700, 0x00000002};
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///////////////////////////////////////////////////////////////////////////////
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//
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// Above portion copy from private\ntos\rtl\time.c
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//
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//
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///////////////////////////////////////////////////////////////////////////////
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//---------------------------------------------------------------------------
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void
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ConvertInt64ToFileTime(
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const __int64* pint64,
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FILETIME* pft
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)
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/*++
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--*/
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{
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pft->dwLowDateTime = (DWORD)(*pint64 & 0xFFFFFFFF);
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pft->dwHighDateTime = (LONG) (*pint64 >> 32);
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return;
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}
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//---------------------------------------------------------------------------
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void
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ConvertFileTimeToInt64(
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const FILETIME* pft,
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__int64* pint64
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)
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/*++
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--*/
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{
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ULARGE_INTEGER ul;
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ul.LowPart = pft->dwLowDateTime;
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ul.HighPart = pft->dwHighDateTime;
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*pint64 = (__int64)ul.QuadPart;
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return;
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}
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//---------------------------------------------------------------------------
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void
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ConvertInt64ToUlargeInt(
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const __int64* pint64,
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ULARGE_INTEGER* pularge
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)
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/*++
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--*/
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{
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pularge->QuadPart = *pint64;
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return;
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}
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//---------------------------------------------------------------------------
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BOOL
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MyMkTime(
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SYSTEMTIME* psysTime,
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FILETIME* pft
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)
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/*++
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Similar to standard C runtime mktime() except it operate on
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SYSTEMTIME, note, BUG in mktime() that it lost one day, e.g,
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add 9 year, 25 months to 1970/1/1, mktime returns 1981/1/31
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instead of 1981/2/1
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--*/
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{
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DWORD dwMilliseconds;
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ULARGE_INTEGER ul100NsSince1970;
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LONGLONG ul100NsSince1601;
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LONGLONG ul100Ns;
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FILETIME ft;
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BOOL bSuccess;
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DWORD dwDaysSince1970;
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//
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// day/hour/mins/second to 100ns
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dwMilliseconds = ((psysTime->wHour * 60 + psysTime->wMinute) * 60 + psysTime->wSecond) * 1000 + psysTime->wMilliseconds;
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ul100Ns = UInt32x32To64( dwMilliseconds, 10000 );
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//
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// Convert year/month/day to days since 1980
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while( psysTime->wMonth > 12 )
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{
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// our month is inclusive
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psysTime->wYear ++;
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psysTime->wMonth -= 12;
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}
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dwDaysSince1970 = ElapsedYearsToDays(psysTime->wYear) - ElapsedYearsToDays(1970);
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// dwDaysSince1970 already included 1/1/1970
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dwDaysSince1970 += psysTime->wDay - 1;
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if(IsLeapYear(psysTime->wYear) == TRUE)
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{
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dwDaysSince1970 += LeapYearDaysPrecedingMonth[psysTime->wMonth - 1];
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dwDaysSince1970--;
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}
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else
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{
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dwDaysSince1970 += NormalYearDaysPrecedingMonth[psysTime->wMonth - 1];
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}
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//
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// Convert days since 1980 to 100 ns since 1980
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ul100NsSince1601 = ConvertDaysToMilliseconds(dwDaysSince1970) * 10000 + ul100Ns;
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ul100NsSince1601 += (SecondsToStartOf1970.QuadPart * 10000000);
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ConvertInt64ToFileTime(&ul100NsSince1601, &ft);
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bSuccess = FileTimeToSystemTime( &ft, psysTime );
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if(bSuccess == TRUE && pft != NULL)
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{
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*pft = ft;
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}
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return bSuccess;
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}
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