/*********************************************************************** * * * This software is part of the ast package * * Copyright (c) 1985-2009 AT&T Intellectual Property * * and is licensed under the * * Common Public License, Version 1.0 * * by AT&T Intellectual Property * * * * A copy of the License is available at * * http://www.opensource.org/licenses/cpl1.0.txt * * (with md5 checksum 059e8cd6165cb4c31e351f2b69388fd9) * * * * Information and Software Systems Research * * AT&T Research * * Florham Park NJ * * * * Glenn Fowler * * David Korn * * Phong Vo * * * ***********************************************************************/ #pragma prototyped /* * Glenn Fowler * AT&T Research * * time conversion support */ #include #include #define DAYS(p) (tm_data.days[(p)->tm_mon]+((p)->tm_mon==1&&LEAP(p))) #define LEAP(p) (tmisleapyear((p)->tm_year)) /* * correct out of bounds fields in tm * * tm_isdst is not changed -- call tmxtm() to get that * * tm is the return value */ Tm_t* tmfix(register Tm_t* tm) { register int n; register int w; Tm_t* p; time_t t; /* * check for special case that adjusts tm_wday at the end * this happens during * nl_langinfo() => strftime() => tmfmt() */ if (w = !tm->tm_sec && !tm->tm_min && !tm->tm_mday && !tm->tm_year && !tm->tm_yday && !tm->tm_isdst) { tm->tm_year = 99; tm->tm_mday = 2; } /* * adjust from shortest to longest units */ if ((n = tm->tm_nsec) < 0) { tm->tm_sec -= (TMX_RESOLUTION - n) / TMX_RESOLUTION; tm->tm_nsec = TMX_RESOLUTION - (-n) % TMX_RESOLUTION; } else if (n >= TMX_RESOLUTION) { tm->tm_sec += n / TMX_RESOLUTION; tm->tm_nsec %= TMX_RESOLUTION; } if ((n = tm->tm_sec) < 0) { tm->tm_min -= (60 - n) / 60; tm->tm_sec = 60 - (-n) % 60; } else if (n > (59 + TM_MAXLEAP)) { tm->tm_min += n / 60; tm->tm_sec %= 60; } if ((n = tm->tm_min) < 0) { tm->tm_hour -= (60 - n) / 60; n = tm->tm_min = 60 - (-n) % 60; } if (n > 59) { tm->tm_hour += n / 60; tm->tm_min %= 60; } if ((n = tm->tm_hour) < 0) { tm->tm_mday -= (23 - n) / 24; tm->tm_hour = 24 - (-n) % 24; } else if (n >= 24) { tm->tm_mday += n / 24; tm->tm_hour %= 24; } if (tm->tm_mon >= 12) { tm->tm_year += tm->tm_mon / 12; tm->tm_mon %= 12; } else if (tm->tm_mon < 0) { tm->tm_year--; if ((tm->tm_mon += 12) < 0) { tm->tm_year += tm->tm_mon / 12; tm->tm_mon = (-tm->tm_mon) % 12; } } while (tm->tm_mday < -365) { tm->tm_year--; tm->tm_mday += 365 + LEAP(tm); } while (tm->tm_mday > 365) { tm->tm_mday -= 365 + LEAP(tm); tm->tm_year++; } while (tm->tm_mday < 1) { if (--tm->tm_mon < 0) { tm->tm_mon = 11; tm->tm_year--; } tm->tm_mday += DAYS(tm); } while (tm->tm_mday > (n = DAYS(tm))) { tm->tm_mday -= n; if (++tm->tm_mon > 11) { tm->tm_mon = 0; tm->tm_year++; } } if (w) { w = tm->tm_wday; t = tmtime(tm, TM_LOCALZONE); p = tmmake(&t); if (w = (w - p->tm_wday)) { if (w < 0) w += 7; tm->tm_wday += w; if ((tm->tm_mday += w) > DAYS(tm)) tm->tm_mday -= 7; } } tm->tm_yday = tm_data.sum[tm->tm_mon] + (tm->tm_mon > 1 && LEAP(tm)) + tm->tm_mday - 1; n = tm->tm_year + 1900 - 1; tm->tm_wday = (n + n / 4 - n / 100 + n / 400 + tm->tm_yday + 1) % 7; /* * tm_isdst is adjusted by tmtime() */ return tm; }