/* * mktime - convert local time into calendar time */ /* $Header$ */ #include #include #include "loc_time.h" /* The code assumes that unsigned long can be converted to time_t. * A time_t should not be wider than unsigned long, since this would mean * that the check for overflow at the end could fail. */ time_t mktime(register struct tm *timep) { register long day, year; register int tm_year; int yday, month; register unsigned long seconds; int overflow; unsigned dst; timep->tm_min += timep->tm_sec / 60; timep->tm_sec %= 60; if (timep->tm_sec < 0) { timep->tm_sec += 60; timep->tm_min--; } timep->tm_hour += timep->tm_min / 60; timep->tm_min = timep->tm_min % 60; if (timep->tm_min < 0) { timep->tm_min += 60; timep->tm_hour--; } day = timep->tm_hour / 24; timep->tm_hour= timep->tm_hour % 24; if (timep->tm_hour < 0) { timep->tm_hour += 24; day--; } timep->tm_year += timep->tm_mon / 12; timep->tm_mon %= 12; if (timep->tm_mon < 0) { timep->tm_mon += 12; timep->tm_year--; } day += (timep->tm_mday - 1); while (day < 0) { day += YEARSIZE(YEAR0 + timep->tm_year - 1); timep->tm_year--; } while (day >= YEARSIZE(YEAR0 + timep->tm_year)) { day -= YEARSIZE(YEAR0 + timep->tm_year); timep->tm_year++; } while (day >= _ytab[LEAPYEAR(YEAR0 + timep->tm_year)][timep->tm_mon]) { day -= _ytab[LEAPYEAR(YEAR0 + timep->tm_year)][timep->tm_mon]; if (++(timep->tm_mon) == 12) { timep->tm_mon = 0; timep->tm_year++; } } timep->tm_mday = day + 1; _tzset(); /* set timezone and dst info */ year = EPOCH_YR; if (timep->tm_year < year - YEAR0) return (time_t)-1; seconds = 0; day = 0; /* means days since day 0 now */ overflow = 0; /* Assume that when day becomes negative, there will certainly * be overflow on seconds. * The check for overflow needs not to be done for leapyears * divisible by 400. * The code only works when year (1970) is not a leapyear. */ #if EPOCH_YR != 1970 #error EPOCH_YR != 1970 #endif tm_year = timep->tm_year + YEAR0; if (LONG_MAX / 365 < tm_year - year) overflow++; day = (tm_year - year) * 365; if (LONG_MAX - day < (tm_year - year) / 4 + 1) overflow++; day += (tm_year - year) / 4 + ((tm_year % 4) && tm_year % 4 < year % 4); day -= (tm_year - year) / 100 + ((tm_year % 100) && tm_year % 100 < year % 100); day += (tm_year - year) / 400 + ((tm_year % 400) && tm_year % 400 < year % 400); yday = month = 0; while (month < timep->tm_mon) { yday += _ytab[LEAPYEAR(tm_year)][month]; month++; } yday += (timep->tm_mday - 1); if (day + yday < 0) overflow++; day += yday; timep->tm_yday = yday; timep->tm_wday = (day + 4) % 7; /* day 0 was thursday (4) */ seconds = ((timep->tm_hour * 60L) + timep->tm_min) * 60L + timep->tm_sec; if ((TIME_MAX - seconds) / SECS_DAY < day) overflow++; seconds += day * SECS_DAY; /* Now adjust according to timezone and daylight saving time */ if (((_timezone > 0) && (TIME_MAX - _timezone < seconds)) || ((_timezone < 0) && (seconds < -_timezone))) overflow++; seconds += _timezone; if (timep->tm_isdst < 0) dst = _dstget(timep); else if (timep->tm_isdst) dst = _dst_off; else dst = 0; if (dst > seconds) overflow++; /* dst is always non-negative */ seconds -= dst; if (overflow) return (time_t)-1; if ((time_t)seconds != seconds) return (time_t)-1; return (time_t)seconds; }