/*------------------------------------------------------------------------- * * timestamp.c * Functions for the built-in SQL92 type "timestamp" and "interval". * * Portions Copyright (c) 1996-2000, PostgreSQL, Inc * Portions Copyright (c) 1994, Regents of the University of California * * * IDENTIFICATION * $Header: /cvsroot/pgsql/src/backend/utils/adt/timestamp.c,v 1.23 2000/03/14 23:06:37 thomas Exp $ * *------------------------------------------------------------------------- */ #include #include #include #include #include "postgres.h" #ifdef HAVE_FLOAT_H #include #endif #ifdef HAVE_LIMITS_H #include #endif #ifndef USE_POSIX_TIME #include #endif #include "miscadmin.h" #include "utils/builtins.h" #if 0 static int DecodeDate(char *str, int fmask, int *tmask, struct tm * tm); static int DecodeNumber(int flen, char *field, int fmask, int *tmask, struct tm * tm, double *fsec, int *is2digits); static int DecodeNumberField(int len, char *str, int fmask, int *tmask, struct tm * tm, double *fsec, int *is2digits); static int DecodeSpecial(int field, char *lowtoken, int *val); static int DecodeTime(char *str, int fmask, int *tmask, struct tm * tm, double *fsec); static int DecodeTimezone(char *str, int *tzp); static int DecodeUnits(int field, char *lowtoken, int *val); static int EncodeSpecialTimestamp(Timestamp dt, char *str); static datetkn *datebsearch(char *key, datetkn *base, unsigned int nel); static Timestamp dt2local(Timestamp dt, int timezone); static int j2day(int jd); static double time2t(const int hour, const int min, const double sec); static int interval2tm(Interval span, struct tm * tm, float8 *fsec); static int tm2interval(struct tm * tm, double fsec, Interval *span); #define USE_DATE_CACHE 1 #define ROUND_ALL 0 int day_tab[2][13] = { {31, 28, 31, 30, 31, 30, 31, 31, 30, 31, 30, 31, 0}, {31, 29, 31, 30, 31, 30, 31, 31, 30, 31, 30, 31, 0}}; char *months[] = {"Jan", "Feb", "Mar", "Apr", "May", "Jun", "Jul", "Aug", "Sep", "Oct", "Nov", "Dec", NULL}; char *days[] = {"Sunday", "Monday", "Tuesday", "Wednesday", "Thursday", "Friday", "Saturday", NULL}; /* TMODULO() * Macro to replace modf(), which is broken on some platforms. */ #define TMODULO(t,q,u) \ do { \ q = ((t < 0)? ceil(t / u): floor(t / u)); \ if (q != 0) \ t -= rint(q * u); \ } while(0) static void GetEpochTime(struct tm * tm); #define UTIME_MINYEAR (1901) #define UTIME_MINMONTH (12) #define UTIME_MINDAY (14) #define UTIME_MAXYEAR (2038) #define UTIME_MAXMONTH (01) #define UTIME_MAXDAY (18) #define IS_VALID_UTIME(y,m,d) (((y > UTIME_MINYEAR) \ || ((y == UTIME_MINYEAR) && ((m > UTIME_MINMONTH) \ || ((m == UTIME_MINMONTH) && (d >= UTIME_MINDAY))))) \ && ((y < UTIME_MAXYEAR) \ || ((y == UTIME_MAXYEAR) && ((m < UTIME_MAXMONTH) \ || ((m == UTIME_MAXMONTH) && (d <= UTIME_MAXDAY)))))) #endif static double time2t(const int hour, const int min, const double sec); /***************************************************************************** * USER I/O ROUTINES * *****************************************************************************/ /* timestamp_in() * Convert a string to internal form. */ Timestamp * timestamp_in(char *str) { Timestamp *result; double fsec; struct tm tt, *tm = &tt; int tz; int dtype; int nf; char *field[MAXDATEFIELDS]; int ftype[MAXDATEFIELDS]; char lowstr[MAXDATELEN + 1]; if (!PointerIsValid(str)) elog(ERROR, "Bad (null) timestamp external representation"); if ((ParseDateTime(str, lowstr, field, ftype, MAXDATEFIELDS, &nf) != 0) || (DecodeDateTime(field, ftype, nf, &dtype, tm, &fsec, &tz) != 0)) elog(ERROR, "Bad timestamp external representation '%s'", str); result = palloc(sizeof(Timestamp)); switch (dtype) { case DTK_DATE: if (tm2timestamp(tm, fsec, &tz, result) != 0) elog(ERROR, "Timestamp out of range '%s'", str); break; case DTK_EPOCH: TIMESTAMP_EPOCH(*result); break; case DTK_CURRENT: TIMESTAMP_CURRENT(*result); break; case DTK_LATE: TIMESTAMP_NOEND(*result); break; case DTK_EARLY: TIMESTAMP_NOBEGIN(*result); break; case DTK_INVALID: TIMESTAMP_INVALID(*result); break; default: elog(ERROR, "Internal coding error, can't input timestamp '%s'", str); } return result; } /* timestamp_in() */ /* timestamp_out() * Convert a timestamp to external form. */ char * timestamp_out(Timestamp *dt) { char *result; int tz; struct tm tt, *tm = &tt; double fsec; char *tzn; char buf[MAXDATELEN + 1]; if (!PointerIsValid(dt)) return NULL; if (TIMESTAMP_IS_RESERVED(*dt)) { EncodeSpecialTimestamp(*dt, buf); } else if (timestamp2tm(*dt, &tz, tm, &fsec, &tzn) == 0) { EncodeDateTime(tm, fsec, &tz, &tzn, DateStyle, buf); } else EncodeSpecialTimestamp(DT_INVALID, buf); result = palloc(strlen(buf) + 1); strcpy(result, buf); return result; } /* timestamp_out() */ /* interval_in() * Convert a string to internal form. * * External format(s): * Uses the generic date/time parsing and decoding routines. */ Interval * interval_in(char *str) { Interval *span; double fsec; struct tm tt, *tm = &tt; int dtype; int nf; char *field[MAXDATEFIELDS]; int ftype[MAXDATEFIELDS]; char lowstr[MAXDATELEN + 1]; tm->tm_year = 0; tm->tm_mon = 0; tm->tm_mday = 0; tm->tm_hour = 0; tm->tm_min = 0; tm->tm_sec = 0; fsec = 0; if (!PointerIsValid(str)) elog(ERROR, "Bad (null) interval external representation"); if ((ParseDateTime(str, lowstr, field, ftype, MAXDATEFIELDS, &nf) != 0) || (DecodeDateDelta(field, ftype, nf, &dtype, tm, &fsec) != 0)) elog(ERROR, "Bad interval external representation '%s'", str); span = palloc(sizeof(Interval)); switch (dtype) { case DTK_DELTA: if (tm2interval(tm, fsec, span) != 0) { #if NOT_USED INTERVAL_INVALID(span); #endif elog(ERROR, "Bad interval external representation '%s'", str); } break; default: elog(ERROR, "Internal coding error, can't input interval '%s'", str); } return span; } /* interval_in() */ /* interval_out() * Convert a time span to external form. */ char * interval_out(Interval *span) { char *result; struct tm tt, *tm = &tt; double fsec; char buf[MAXDATELEN + 1]; if (!PointerIsValid(span)) return NULL; if (interval2tm(*span, tm, &fsec) != 0) return NULL; if (EncodeTimeSpan(tm, fsec, DateStyle, buf) != 0) elog(ERROR, "Unable to format interval"); result = palloc(strlen(buf) + 1); strcpy(result, buf); return result; } /* interval_out() */ /* EncodeSpecialTimestamp() * Convert reserved timestamp data type to string. */ int EncodeSpecialTimestamp(Timestamp dt, char *str) { if (TIMESTAMP_IS_RESERVED(dt)) { if (TIMESTAMP_IS_INVALID(dt)) strcpy(str, INVALID); else if (TIMESTAMP_IS_NOBEGIN(dt)) strcpy(str, EARLY); else if (TIMESTAMP_IS_NOEND(dt)) strcpy(str, LATE); else if (TIMESTAMP_IS_CURRENT(dt)) strcpy(str, DCURRENT); else if (TIMESTAMP_IS_EPOCH(dt)) strcpy(str, EPOCH); else strcpy(str, INVALID); return TRUE; } return FALSE; } /* EncodeSpecialTimestamp() */ Timestamp * now(void) { Timestamp *result; AbsoluteTime sec; result = palloc(sizeof(Timestamp)); sec = GetCurrentTransactionStartTime(); *result = (sec - ((date2j(2000, 1, 1) - date2j(1970, 1, 1)) * 86400)); return result; } void dt2time(Timestamp jd, int *hour, int *min, double *sec) { double time; time = jd; *hour = (time / 3600); time -= ((*hour) * 3600); *min = (time / 60); time -= ((*min) * 60); *sec = JROUND(time); return; } /* dt2time() */ /* timestamp2tm() * Convert timestamp data type to POSIX time structure. * Note that year is _not_ 1900-based, but is an explicit full value. * Also, month is one-based, _not_ zero-based. * Returns: * 0 on success * -1 on out of range * * For dates within the system-supported time_t range, convert to the * local time zone. If out of this range, leave as GMT. - tgl 97/05/27 */ int timestamp2tm(Timestamp dt, int *tzp, struct tm * tm, double *fsec, char **tzn) { double date, date0, time, sec; time_t utime; #ifdef USE_POSIX_TIME struct tm *tx; #endif date0 = date2j(2000, 1, 1); time = dt; TMODULO(time, date, 86400e0); if (time < 0) { time += 86400; date -= 1; } /* Julian day routine does not work for negative Julian days */ if (date < -date0) return -1; /* add offset to go from J2000 back to standard Julian date */ date += date0; j2date((int) date, &tm->tm_year, &tm->tm_mon, &tm->tm_mday); dt2time(time, &tm->tm_hour, &tm->tm_min, &sec); *fsec = JROUND(sec); TMODULO(*fsec, tm->tm_sec, 1e0); if (tzp != NULL) { if (IS_VALID_UTIME(tm->tm_year, tm->tm_mon, tm->tm_mday)) { utime = (dt + (date0 - date2j(1970, 1, 1)) * 86400); #ifdef USE_POSIX_TIME tx = localtime(&utime); tm->tm_year = tx->tm_year + 1900; tm->tm_mon = tx->tm_mon + 1; tm->tm_mday = tx->tm_mday; tm->tm_hour = tx->tm_hour; tm->tm_min = tx->tm_min; #if NOT_USED /* XXX HACK * Argh! My Linux box puts in a 1 second offset for dates less than 1970 * but only if the seconds field was non-zero. So, don't copy the seconds * field and instead carry forward from the original - tgl 97/06/18 * Note that GNU/Linux uses the standard freeware zic package as do * many other platforms so this may not be GNU/Linux/ix86-specific. */ tm->tm_sec = tx->tm_sec; #endif tm->tm_isdst = tx->tm_isdst; #if defined(HAVE_TM_ZONE) tm->tm_gmtoff = tx->tm_gmtoff; tm->tm_zone = tx->tm_zone; *tzp = -(tm->tm_gmtoff); /* tm_gmtoff is Sun/DEC-ism */ if (tzn != NULL) *tzn = (char *) tm->tm_zone; #elif defined(HAVE_INT_TIMEZONE) #ifdef __CYGWIN__ *tzp = (tm->tm_isdst ? (_timezone - 3600) : _timezone); #else *tzp = (tm->tm_isdst ? (timezone - 3600) : timezone); #endif if (tzn != NULL) *tzn = tzname[(tm->tm_isdst > 0)]; #else #error USE_POSIX_TIME is defined but neither HAVE_TM_ZONE or HAVE_INT_TIMEZONE are defined #endif #else /* !USE_POSIX_TIME */ *tzp = CTimeZone; /* V7 conventions; don't know timezone? */ if (tzn != NULL) *tzn = CTZName; #endif } else { *tzp = 0; tm->tm_isdst = 0; if (tzn != NULL) *tzn = NULL; } dt = dt2local(dt, *tzp); } else { tm->tm_isdst = 0; if (tzn != NULL) *tzn = NULL; } return 0; } /* timestamp2tm() */ /* tm2timestamp() * Convert a tm structure to a timestamp data type. * Note that year is _not_ 1900-based, but is an explicit full value. * Also, month is one-based, _not_ zero-based. */ int tm2timestamp(struct tm * tm, double fsec, int *tzp, Timestamp *result) { double date, time; /* Julian day routines are not correct for negative Julian days */ if (!IS_VALID_JULIAN(tm->tm_year, tm->tm_mon, tm->tm_mday)) return -1; date = date2j(tm->tm_year, tm->tm_mon, tm->tm_mday) - date2j(2000, 1, 1); time = time2t(tm->tm_hour, tm->tm_min, (tm->tm_sec + fsec)); *result = (date * 86400 + time); if (tzp != NULL) *result = dt2local(*result, -(*tzp)); return 0; } /* tm2timestamp() */ /* interval2tm() * Convert a interval data type to a tm structure. */ int interval2tm(Interval span, struct tm * tm, float8 *fsec) { double time; if (span.month != 0) { tm->tm_year = span.month / 12; tm->tm_mon = span.month % 12; } else { tm->tm_year = 0; tm->tm_mon = 0; } #ifdef ROUND_ALL time = JROUND(span.time); #else time = span.time; #endif TMODULO(time, tm->tm_mday, 86400e0); TMODULO(time, tm->tm_hour, 3600e0); TMODULO(time, tm->tm_min, 60e0); TMODULO(time, tm->tm_sec, 1e0); *fsec = time; return 0; } /* interval2tm() */ int tm2interval(struct tm * tm, double fsec, Interval *span) { span->month = ((tm->tm_year * 12) + tm->tm_mon); span->time = ((((((tm->tm_mday * 24.0) + tm->tm_hour) * 60.0) + tm->tm_min) * 60.0) + tm->tm_sec); span->time = JROUND(span->time + fsec); return 0; } /* tm2interval() */ static double time2t(const int hour, const int min, const double sec) { return (((hour * 60) + min) * 60) + sec; } /* time2t() */ Timestamp dt2local(Timestamp dt, int tz) { dt -= tz; dt = JROUND(dt); return dt; } /* dt2local() */ /***************************************************************************** * PUBLIC ROUTINES * *****************************************************************************/ bool timestamp_finite(Timestamp *timestamp) { if (!PointerIsValid(timestamp)) return FALSE; return !TIMESTAMP_NOT_FINITE(*timestamp); } /* timestamp_finite() */ bool interval_finite(Interval *interval) { if (!PointerIsValid(interval)) return FALSE; return !INTERVAL_NOT_FINITE(*interval); } /* interval_finite() */ /*---------------------------------------------------------- * Relational operators for timestamp. *---------------------------------------------------------*/ static void GetEpochTime(struct tm * tm) { struct tm *t0; time_t epoch = 0; t0 = gmtime(&epoch); tm->tm_year = t0->tm_year; tm->tm_mon = t0->tm_mon; tm->tm_mday = t0->tm_mday; tm->tm_hour = t0->tm_hour; tm->tm_min = t0->tm_min; tm->tm_sec = t0->tm_sec; if (tm->tm_year < 1900) tm->tm_year += 1900; tm->tm_mon++; return; } /* GetEpochTime() */ Timestamp SetTimestamp(Timestamp dt) { struct tm tt; if (TIMESTAMP_IS_CURRENT(dt)) { GetCurrentTime(&tt); tm2timestamp(&tt, 0, NULL, &dt); dt = dt2local(dt, -CTimeZone); } else { /* if (TIMESTAMP_IS_EPOCH(dt1)) */ GetEpochTime(&tt); tm2timestamp(&tt, 0, NULL, &dt); } return dt; } /* SetTimestamp() */ /* timestamp_relop - is timestamp1 relop timestamp2 */ bool timestamp_eq(Timestamp *timestamp1, Timestamp *timestamp2) { Timestamp dt1, dt2; if (!PointerIsValid(timestamp1) || !PointerIsValid(timestamp2)) return FALSE; dt1 = *timestamp1; dt2 = *timestamp2; if (TIMESTAMP_IS_INVALID(dt1) || TIMESTAMP_IS_INVALID(dt2)) return FALSE; if (TIMESTAMP_IS_RELATIVE(dt1)) dt1 = SetTimestamp(dt1); if (TIMESTAMP_IS_RELATIVE(dt2)) dt2 = SetTimestamp(dt2); return dt1 == dt2; } /* timestamp_eq() */ bool timestamp_ne(Timestamp *timestamp1, Timestamp *timestamp2) { Timestamp dt1, dt2; if (!PointerIsValid(timestamp1) || !PointerIsValid(timestamp2)) return FALSE; dt1 = *timestamp1; dt2 = *timestamp2; if (TIMESTAMP_IS_INVALID(dt1) || TIMESTAMP_IS_INVALID(dt2)) return FALSE; if (TIMESTAMP_IS_RELATIVE(dt1)) dt1 = SetTimestamp(dt1); if (TIMESTAMP_IS_RELATIVE(dt2)) dt2 = SetTimestamp(dt2); return dt1 != dt2; } /* timestamp_ne() */ bool timestamp_lt(Timestamp *timestamp1, Timestamp *timestamp2) { Timestamp dt1, dt2; if (!PointerIsValid(timestamp1) || !PointerIsValid(timestamp2)) return FALSE; dt1 = *timestamp1; dt2 = *timestamp2; if (TIMESTAMP_IS_INVALID(dt1) || TIMESTAMP_IS_INVALID(dt2)) return FALSE; if (TIMESTAMP_IS_RELATIVE(dt1)) dt1 = SetTimestamp(dt1); if (TIMESTAMP_IS_RELATIVE(dt2)) dt2 = SetTimestamp(dt2); return dt1 < dt2; } /* timestamp_lt() */ bool timestamp_gt(Timestamp *timestamp1, Timestamp *timestamp2) { Timestamp dt1, dt2; if (!PointerIsValid(timestamp1) || !PointerIsValid(timestamp2)) return FALSE; dt1 = *timestamp1; dt2 = *timestamp2; if (TIMESTAMP_IS_INVALID(dt1) || TIMESTAMP_IS_INVALID(dt2)) return FALSE; if (TIMESTAMP_IS_RELATIVE(dt1)) dt1 = SetTimestamp(dt1); if (TIMESTAMP_IS_RELATIVE(dt2)) dt2 = SetTimestamp(dt2); return dt1 > dt2; } /* timestamp_gt() */ bool timestamp_le(Timestamp *timestamp1, Timestamp *timestamp2) { Timestamp dt1, dt2; if (!PointerIsValid(timestamp1) || !PointerIsValid(timestamp2)) return FALSE; dt1 = *timestamp1; dt2 = *timestamp2; if (TIMESTAMP_IS_INVALID(dt1) || TIMESTAMP_IS_INVALID(dt2)) return FALSE; if (TIMESTAMP_IS_RELATIVE(dt1)) dt1 = SetTimestamp(dt1); if (TIMESTAMP_IS_RELATIVE(dt2)) dt2 = SetTimestamp(dt2); return dt1 <= dt2; } /* timestamp_le() */ bool timestamp_ge(Timestamp *timestamp1, Timestamp *timestamp2) { Timestamp dt1, dt2; if (!PointerIsValid(timestamp1) || !PointerIsValid(timestamp2)) return FALSE; dt1 = *timestamp1; dt2 = *timestamp2; if (TIMESTAMP_IS_INVALID(dt1) || TIMESTAMP_IS_INVALID(dt2)) return FALSE; if (TIMESTAMP_IS_RELATIVE(dt1)) dt1 = SetTimestamp(dt1); if (TIMESTAMP_IS_RELATIVE(dt2)) dt2 = SetTimestamp(dt2); return dt1 >= dt2; } /* timestamp_ge() */ /* timestamp_cmp - 3-state comparison for timestamp * collate invalid timestamp at the end */ int timestamp_cmp(Timestamp *timestamp1, Timestamp *timestamp2) { Timestamp dt1, dt2; if (!PointerIsValid(timestamp1) || !PointerIsValid(timestamp2)) return 0; dt1 = *timestamp1; dt2 = *timestamp2; if (TIMESTAMP_IS_INVALID(dt1)) { return (TIMESTAMP_IS_INVALID(dt2) ? 0 : 1); } else if (TIMESTAMP_IS_INVALID(dt2)) { return -1; } else { if (TIMESTAMP_IS_RELATIVE(dt1)) dt1 = SetTimestamp(dt1); if (TIMESTAMP_IS_RELATIVE(dt2)) dt2 = SetTimestamp(dt2); } return ((dt1 < dt2) ? -1 : ((dt1 > dt2) ? 1 : 0)); } /* timestamp_cmp() */ /* interval_relop - is interval1 relop interval2 */ bool interval_eq(Interval *interval1, Interval *interval2) { if (!PointerIsValid(interval1) || !PointerIsValid(interval2)) return FALSE; if (INTERVAL_IS_INVALID(*interval1) || INTERVAL_IS_INVALID(*interval2)) return FALSE; return ((interval1->time == interval2->time) && (interval1->month == interval2->month)); } /* interval_eq() */ bool interval_ne(Interval *interval1, Interval *interval2) { if (!PointerIsValid(interval1) || !PointerIsValid(interval2)) return FALSE; if (INTERVAL_IS_INVALID(*interval1) || INTERVAL_IS_INVALID(*interval2)) return FALSE; return ((interval1->time != interval2->time) || (interval1->month != interval2->month)); } /* interval_ne() */ bool interval_lt(Interval *interval1, Interval *interval2) { double span1, span2; if (!PointerIsValid(interval1) || !PointerIsValid(interval2)) return FALSE; if (INTERVAL_IS_INVALID(*interval1) || INTERVAL_IS_INVALID(*interval2)) return FALSE; span1 = interval1->time; if (interval1->month != 0) span1 += (interval1->month * (30.0 * 86400)); span2 = interval2->time; if (interval2->month != 0) span2 += (interval2->month * (30.0 * 86400)); return span1 < span2; } /* interval_lt() */ bool interval_gt(Interval *interval1, Interval *interval2) { double span1, span2; if (!PointerIsValid(interval1) || !PointerIsValid(interval2)) return FALSE; if (INTERVAL_IS_INVALID(*interval1) || INTERVAL_IS_INVALID(*interval2)) return FALSE; span1 = interval1->time; if (interval1->month != 0) span1 += (interval1->month * (30.0 * 86400)); span2 = interval2->time; if (interval2->month != 0) span2 += (interval2->month * (30.0 * 86400)); return span1 > span2; } /* interval_gt() */ bool interval_le(Interval *interval1, Interval *interval2) { double span1, span2; if (!PointerIsValid(interval1) || !PointerIsValid(interval2)) return FALSE; if (INTERVAL_IS_INVALID(*interval1) || INTERVAL_IS_INVALID(*interval2)) return FALSE; span1 = interval1->time; if (interval1->month != 0) span1 += (interval1->month * (30.0 * 86400)); span2 = interval2->time; if (interval2->month != 0) span2 += (interval2->month * (30.0 * 86400)); return span1 <= span2; } /* interval_le() */ bool interval_ge(Interval *interval1, Interval *interval2) { double span1, span2; if (!PointerIsValid(interval1) || !PointerIsValid(interval2)) return FALSE; if (INTERVAL_IS_INVALID(*interval1) || INTERVAL_IS_INVALID(*interval2)) return FALSE; span1 = interval1->time; if (interval1->month != 0) span1 += (interval1->month * (30.0 * 86400)); span2 = interval2->time; if (interval2->month != 0) span2 += (interval2->month * (30.0 * 86400)); return span1 >= span2; } /* interval_ge() */ /* interval_cmp - 3-state comparison for interval */ int interval_cmp(Interval *interval1, Interval *interval2) { double span1, span2; if (!PointerIsValid(interval1) || !PointerIsValid(interval2)) return 0; if (INTERVAL_IS_INVALID(*interval1)) { return INTERVAL_IS_INVALID(*interval2) ? 0 : 1; } else if (INTERVAL_IS_INVALID(*interval2)) return -1; span1 = interval1->time; if (interval1->month != 0) span1 += (interval1->month * (30.0 * 86400)); span2 = interval2->time; if (interval2->month != 0) span2 += (interval2->month * (30.0 * 86400)); return (span1 < span2) ? -1 : (span1 > span2) ? 1 : 0; } /* interval_cmp() */ /* overlaps_timestamp() * Implements the SQL92 OVERLAPS operator. * Algorithm from Date and Darwen, 1997 */ bool overlaps_timestamp(Timestamp *ts1, Timestamp *te1, Timestamp *ts2, Timestamp *te2) { /* Make sure we have ordered pairs... */ if (timestamp_gt(ts1, te1)) { Timestamp *tt = ts1; ts1 = te1; te1 = tt; } if (timestamp_gt(ts2, te2)) { Timestamp *tt = ts2; ts2 = te2; te2 = tt; } return ((timestamp_gt(ts1, ts2) && (timestamp_lt(ts1, te2) || timestamp_lt(te1, te2))) || (timestamp_gt(ts2, ts1) && (timestamp_lt(ts2, te1) || timestamp_lt(te2, te1))) || timestamp_eq(ts1, ts2)); } /* overlaps_timestamp() */ /*---------------------------------------------------------- * "Arithmetic" operators on date/times. * timestamp_foo returns foo as an object (pointer) that * can be passed between languages. * timestamp_xx is an internal routine which returns the * actual value. *---------------------------------------------------------*/ Timestamp * timestamp_smaller(Timestamp *timestamp1, Timestamp *timestamp2) { Timestamp *result; Timestamp dt1, dt2; if (!PointerIsValid(timestamp1) || !PointerIsValid(timestamp2)) return NULL; dt1 = *timestamp1; dt2 = *timestamp2; result = palloc(sizeof(Timestamp)); if (TIMESTAMP_IS_RELATIVE(dt1)) dt1 = SetTimestamp(dt1); if (TIMESTAMP_IS_RELATIVE(dt2)) dt2 = SetTimestamp(dt2); if (TIMESTAMP_IS_INVALID(dt1)) *result = dt2; else if (TIMESTAMP_IS_INVALID(dt2)) *result = dt1; else *result = ((dt2 < dt1) ? dt2 : dt1); return result; } /* timestamp_smaller() */ Timestamp * timestamp_larger(Timestamp *timestamp1, Timestamp *timestamp2) { Timestamp *result; Timestamp dt1, dt2; if (!PointerIsValid(timestamp1) || !PointerIsValid(timestamp2)) return NULL; dt1 = *timestamp1; dt2 = *timestamp2; result = palloc(sizeof(Timestamp)); if (TIMESTAMP_IS_RELATIVE(dt1)) dt1 = SetTimestamp(dt1); if (TIMESTAMP_IS_RELATIVE(dt2)) dt2 = SetTimestamp(dt2); if (TIMESTAMP_IS_INVALID(dt1)) *result = dt2; else if (TIMESTAMP_IS_INVALID(dt2)) *result = dt1; else *result = ((dt2 > dt1) ? dt2 : dt1); return result; } /* timestamp_larger() */ Interval * timestamp_mi(Timestamp *timestamp1, Timestamp *timestamp2) { Interval *result; Timestamp dt1, dt2; if (!PointerIsValid(timestamp1) || !PointerIsValid(timestamp2)) return NULL; dt1 = *timestamp1; dt2 = *timestamp2; result = palloc(sizeof(Interval)); if (TIMESTAMP_IS_RELATIVE(dt1)) dt1 = SetTimestamp(dt1); if (TIMESTAMP_IS_RELATIVE(dt2)) dt2 = SetTimestamp(dt2); if (TIMESTAMP_IS_INVALID(dt1) || TIMESTAMP_IS_INVALID(dt2)) { TIMESTAMP_INVALID(result->time); } else result->time = JROUND(dt1 - dt2); result->month = 0; return result; } /* timestamp_mi() */ /* timestamp_pl_span() * Add a interval to a timestamp data type. * Note that interval has provisions for qualitative year/month * units, so try to do the right thing with them. * To add a month, increment the month, and use the same day of month. * Then, if the next month has fewer days, set the day of month * to the last day of month. * Lastly, add in the "quantitative time". */ Timestamp * timestamp_pl_span(Timestamp *timestamp, Interval *span) { Timestamp *result; Timestamp dt; int tz; char *tzn; if ((!PointerIsValid(timestamp)) || (!PointerIsValid(span))) return NULL; result = palloc(sizeof(Timestamp)); if (TIMESTAMP_NOT_FINITE(*timestamp)) { *result = *timestamp; } else if (INTERVAL_IS_INVALID(*span)) { TIMESTAMP_INVALID(*result); } else { dt = (TIMESTAMP_IS_RELATIVE(*timestamp) ? SetTimestamp(*timestamp) : *timestamp); if (span->month != 0) { struct tm tt, *tm = &tt; double fsec; if (timestamp2tm(dt, &tz, tm, &fsec, &tzn) == 0) { tm->tm_mon += span->month; if (tm->tm_mon > 12) { tm->tm_year += ((tm->tm_mon - 1) / 12); tm->tm_mon = (((tm->tm_mon - 1) % 12) + 1); } else if (tm->tm_mon < 1) { tm->tm_year += ((tm->tm_mon / 12) - 1); tm->tm_mon = ((tm->tm_mon % 12) + 12); } /* adjust for end of month boundary problems... */ if (tm->tm_mday > day_tab[isleap(tm->tm_year)][tm->tm_mon - 1]) tm->tm_mday = (day_tab[isleap(tm->tm_year)][tm->tm_mon - 1]); if (tm2timestamp(tm, fsec, &tz, &dt) != 0) elog(ERROR, "Unable to add timestamp and interval"); } else TIMESTAMP_INVALID(dt); } #ifdef ROUND_ALL dt = JROUND(dt + span->time); #else dt += span->time; #endif *result = dt; } return result; } /* timestamp_pl_span() */ Timestamp * timestamp_mi_span(Timestamp *timestamp, Interval *span) { Timestamp *result; Interval tspan; if (!PointerIsValid(timestamp) || !PointerIsValid(span)) return NULL; tspan.month = -span->month; tspan.time = -span->time; result = timestamp_pl_span(timestamp, &tspan); return result; } /* timestamp_mi_span() */ Interval * interval_um(Interval *interval) { Interval *result; if (!PointerIsValid(interval)) return NULL; result = palloc(sizeof(Interval)); result->time = -(interval->time); result->month = -(interval->month); return result; } /* interval_um() */ Interval * interval_smaller(Interval *interval1, Interval *interval2) { Interval *result; double span1, span2; if (!PointerIsValid(interval1) || !PointerIsValid(interval2)) return NULL; result = palloc(sizeof(Interval)); if (INTERVAL_IS_INVALID(*interval1)) { result->time = interval2->time; result->month = interval2->month; } else if (INTERVAL_IS_INVALID(*interval2)) { result->time = interval1->time; result->month = interval1->month; } else { span1 = interval1->time; if (interval1->month != 0) span1 += (interval1->month * (30.0 * 86400)); span2 = interval2->time; if (interval2->month != 0) span2 += (interval2->month * (30.0 * 86400)); if (span2 < span1) { result->time = interval2->time; result->month = interval2->month; } else { result->time = interval1->time; result->month = interval1->month; } } return result; } /* interval_smaller() */ Interval * interval_larger(Interval *interval1, Interval *interval2) { Interval *result; double span1, span2; if (!PointerIsValid(interval1) || !PointerIsValid(interval2)) return NULL; result = palloc(sizeof(Interval)); if (INTERVAL_IS_INVALID(*interval1)) { result->time = interval2->time; result->month = interval2->month; } else if (INTERVAL_IS_INVALID(*interval2)) { result->time = interval1->time; result->month = interval1->month; } else { span1 = interval1->time; if (interval1->month != 0) span1 += (interval1->month * (30.0 * 86400)); span2 = interval2->time; if (interval2->month != 0) span2 += (interval2->month * (30.0 * 86400)); if (span2 > span1) { result->time = interval2->time; result->month = interval2->month; } else { result->time = interval1->time; result->month = interval1->month; } } return result; } /* interval_larger() */ Interval * interval_pl(Interval *span1, Interval *span2) { Interval *result; if ((!PointerIsValid(span1)) || (!PointerIsValid(span2))) return NULL; result = palloc(sizeof(Interval)); result->month = (span1->month + span2->month); result->time = JROUND(span1->time + span2->time); return result; } /* interval_pl() */ Interval * interval_mi(Interval *span1, Interval *span2) { Interval *result; if ((!PointerIsValid(span1)) || (!PointerIsValid(span2))) return NULL; result = palloc(sizeof(Interval)); result->month = (span1->month - span2->month); result->time = JROUND(span1->time - span2->time); return result; } /* interval_mi() */ Interval * interval_div(Interval *span1, float8 *arg2) { Interval *result; if ((!PointerIsValid(span1)) || (!PointerIsValid(arg2))) return NULL; if (!PointerIsValid(result = palloc(sizeof(Interval)))) elog(ERROR, "Memory allocation failed, can't divide intervals"); if (*arg2 == 0.0) elog(ERROR, "interval_div: divide by 0.0 error"); result->month = rint(span1->month / *arg2); result->time = JROUND(span1->time / *arg2); return result; } /* interval_div() */ /* timestamp_age() * Calculate time difference while retaining year/month fields. * Note that this does not result in an accurate absolute time span * since year and month are out of context once the arithmetic * is done. */ Interval * timestamp_age(Timestamp *timestamp1, Timestamp *timestamp2) { Interval *result; Timestamp dt1, dt2; double fsec, fsec1, fsec2; struct tm tt, *tm = &tt; struct tm tt1, *tm1 = &tt1; struct tm tt2, *tm2 = &tt2; if (!PointerIsValid(timestamp1) || !PointerIsValid(timestamp2)) return NULL; result = palloc(sizeof(Interval)); dt1 = *timestamp1; dt2 = *timestamp2; if (TIMESTAMP_IS_RELATIVE(dt1)) dt1 = SetTimestamp(dt1); if (TIMESTAMP_IS_RELATIVE(dt2)) dt2 = SetTimestamp(dt2); if (TIMESTAMP_IS_INVALID(dt1) || TIMESTAMP_IS_INVALID(dt2)) { TIMESTAMP_INVALID(result->time); } else if ((timestamp2tm(dt1, NULL, tm1, &fsec1, NULL) == 0) && (timestamp2tm(dt2, NULL, tm2, &fsec2, NULL) == 0)) { fsec = (fsec1 - fsec2); tm->tm_sec = (tm1->tm_sec - tm2->tm_sec); tm->tm_min = (tm1->tm_min - tm2->tm_min); tm->tm_hour = (tm1->tm_hour - tm2->tm_hour); tm->tm_mday = (tm1->tm_mday - tm2->tm_mday); tm->tm_mon = (tm1->tm_mon - tm2->tm_mon); tm->tm_year = (tm1->tm_year - tm2->tm_year); /* flip sign if necessary... */ if (dt1 < dt2) { fsec = -fsec; tm->tm_sec = -tm->tm_sec; tm->tm_min = -tm->tm_min; tm->tm_hour = -tm->tm_hour; tm->tm_mday = -tm->tm_mday; tm->tm_mon = -tm->tm_mon; tm->tm_year = -tm->tm_year; } if (tm->tm_sec < 0) { tm->tm_sec += 60; tm->tm_min--; } if (tm->tm_min < 0) { tm->tm_min += 60; tm->tm_hour--; } if (tm->tm_hour < 0) { tm->tm_hour += 24; tm->tm_mday--; } if (tm->tm_mday < 0) { if (dt1 < dt2) { tm->tm_mday += day_tab[isleap(tm1->tm_year)][tm1->tm_mon - 1]; tm->tm_mon--; } else { tm->tm_mday += day_tab[isleap(tm2->tm_year)][tm2->tm_mon - 1]; tm->tm_mon--; } } if (tm->tm_mon < 0) { tm->tm_mon += 12; tm->tm_year--; } /* recover sign if necessary... */ if (dt1 < dt2) { fsec = -fsec; tm->tm_sec = -tm->tm_sec; tm->tm_min = -tm->tm_min; tm->tm_hour = -tm->tm_hour; tm->tm_mday = -tm->tm_mday; tm->tm_mon = -tm->tm_mon; tm->tm_year = -tm->tm_year; } if (tm2interval(tm, fsec, result) != 0) elog(ERROR, "Unable to decode timestamp"); } else elog(ERROR, "Unable to decode timestamp"); return result; } /* timestamp_age() */ /*---------------------------------------------------------- * Conversion operators. *---------------------------------------------------------*/ /* timestamp_text() * Convert timestamp to text data type. */ text * timestamp_text(Timestamp *timestamp) { text *result; char *str; int len; if (!PointerIsValid(timestamp)) return NULL; str = timestamp_out(timestamp); if (!PointerIsValid(str)) return NULL; len = (strlen(str) + VARHDRSZ); result = palloc(len); VARSIZE(result) = len; memmove(VARDATA(result), str, (len - VARHDRSZ)); pfree(str); return result; } /* timestamp_text() */ /* text_timestamp() * Convert text string to timestamp. * Text type is not null terminated, so use temporary string * then call the standard input routine. */ Timestamp * text_timestamp(text *str) { Timestamp *result; int i; char *sp, *dp, dstr[MAXDATELEN + 1]; if (!PointerIsValid(str)) return NULL; sp = VARDATA(str); dp = dstr; for (i = 0; i < (VARSIZE(str) - VARHDRSZ); i++) *dp++ = *sp++; *dp = '\0'; result = timestamp_in(dstr); return result; } /* text_timestamp() */ /* interval_text() * Convert interval to text data type. */ text * interval_text(Interval *interval) { text *result; char *str; int len; if (!PointerIsValid(interval)) return NULL; str = interval_out(interval); if (!PointerIsValid(str)) return NULL; len = (strlen(str) + VARHDRSZ); result = palloc(len); VARSIZE(result) = len; memmove(VARDATA(result), str, (len - VARHDRSZ)); pfree(str); return result; } /* interval_text() */ /* text_interval() * Convert text string to interval. * Text type may not be null terminated, so copy to temporary string * then call the standard input routine. */ Interval * text_interval(text *str) { Interval *result; int i; char *sp, *dp, dstr[MAXDATELEN + 1]; if (!PointerIsValid(str)) return NULL; sp = VARDATA(str); dp = dstr; for (i = 0; i < (VARSIZE(str) - VARHDRSZ); i++) *dp++ = *sp++; *dp = '\0'; result = interval_in(dstr); return result; } /* text_interval() */ /* timestamp_trunc() * Extract specified field from timestamp. */ Timestamp * timestamp_trunc(text *units, Timestamp *timestamp) { Timestamp *result; Timestamp dt; int tz; int type, val; int i; char *up, *lp, lowunits[MAXDATELEN + 1]; double fsec; char *tzn; struct tm tt, *tm = &tt; if ((!PointerIsValid(units)) || (!PointerIsValid(timestamp))) return NULL; result = palloc(sizeof(Timestamp)); up = VARDATA(units); lp = lowunits; for (i = 0; i < (VARSIZE(units) - VARHDRSZ); i++) *lp++ = tolower(*up++); *lp = '\0'; type = DecodeUnits(0, lowunits, &val); if (TIMESTAMP_NOT_FINITE(*timestamp)) { #if NOT_USED /* should return null but Postgres doesn't like that currently. - tgl 97/06/12 */ elog(ERROR, "Timestamp is not finite", NULL); #endif *result = 0; } else { dt = (TIMESTAMP_IS_RELATIVE(*timestamp) ? SetTimestamp(*timestamp) : *timestamp); if ((type == UNITS) && (timestamp2tm(dt, &tz, tm, &fsec, &tzn) == 0)) { switch (val) { case DTK_MILLENIUM: tm->tm_year = (tm->tm_year / 1000) * 1000; case DTK_CENTURY: tm->tm_year = (tm->tm_year / 100) * 100; case DTK_DECADE: tm->tm_year = (tm->tm_year / 10) * 10; case DTK_YEAR: tm->tm_mon = 1; case DTK_QUARTER: tm->tm_mon = (3 * (tm->tm_mon / 4)) + 1; case DTK_MONTH: tm->tm_mday = 1; case DTK_DAY: tm->tm_hour = 0; case DTK_HOUR: tm->tm_min = 0; case DTK_MINUTE: tm->tm_sec = 0; case DTK_SECOND: fsec = 0; break; case DTK_MILLISEC: fsec = rint(fsec * 1000) / 1000; break; case DTK_MICROSEC: fsec = rint(fsec * 1000000) / 1000000; break; default: elog(ERROR, "Timestamp units '%s' not supported", lowunits); result = NULL; } if (IS_VALID_UTIME(tm->tm_year, tm->tm_mon, tm->tm_mday)) { #ifdef USE_POSIX_TIME tm->tm_isdst = -1; tm->tm_year -= 1900; tm->tm_mon -= 1; tm->tm_isdst = -1; mktime(tm); tm->tm_year += 1900; tm->tm_mon += 1; #if defined(HAVE_TM_ZONE) tz = -(tm->tm_gmtoff); /* tm_gmtoff is Sun/DEC-ism */ #elif defined(HAVE_INT_TIMEZONE) #ifdef __CYGWIN__ tz = (tm->tm_isdst ? (_timezone - 3600) : _timezone); #else tz = (tm->tm_isdst ? (timezone - 3600) : timezone); #endif #else #error USE_POSIX_TIME is defined but neither HAVE_TM_ZONE or HAVE_INT_TIMEZONE are defined #endif #else /* !USE_POSIX_TIME */ tz = CTimeZone; #endif } else { tm->tm_isdst = 0; tz = 0; } if (tm2timestamp(tm, fsec, &tz, result) != 0) elog(ERROR, "Unable to truncate timestamp to '%s'", lowunits); #if NOT_USED } else if ((type == RESERV) && (val == DTK_EPOCH)) { TIMESTAMP_EPOCH(*result); *result = dt - SetTimestamp(*result); #endif } else { elog(ERROR, "Timestamp units '%s' not recognized", lowunits); result = NULL; } } return result; } /* timestamp_trunc() */ /* interval_trunc() * Extract specified field from interval. */ Interval * interval_trunc(text *units, Interval *interval) { Interval *result; int type, val; int i; char *up, *lp, lowunits[MAXDATELEN + 1]; double fsec; struct tm tt, *tm = &tt; if ((!PointerIsValid(units)) || (!PointerIsValid(interval))) return NULL; result = palloc(sizeof(Interval)); up = VARDATA(units); lp = lowunits; for (i = 0; i < (VARSIZE(units) - VARHDRSZ); i++) *lp++ = tolower(*up++); *lp = '\0'; type = DecodeUnits(0, lowunits, &val); if (INTERVAL_IS_INVALID(*interval)) { #if NOT_USED elog(ERROR, "Interval is not finite", NULL); #endif result = NULL; } else if (type == UNITS) { if (interval2tm(*interval, tm, &fsec) == 0) { switch (val) { case DTK_MILLENIUM: tm->tm_year = (tm->tm_year / 1000) * 1000; case DTK_CENTURY: tm->tm_year = (tm->tm_year / 100) * 100; case DTK_DECADE: tm->tm_year = (tm->tm_year / 10) * 10; case DTK_YEAR: tm->tm_mon = 0; case DTK_QUARTER: tm->tm_mon = (3 * (tm->tm_mon / 4)); case DTK_MONTH: tm->tm_mday = 0; case DTK_DAY: tm->tm_hour = 0; case DTK_HOUR: tm->tm_min = 0; case DTK_MINUTE: tm->tm_sec = 0; case DTK_SECOND: fsec = 0; break; case DTK_MILLISEC: fsec = rint(fsec * 1000) / 1000; break; case DTK_MICROSEC: fsec = rint(fsec * 1000000) / 1000000; break; default: elog(ERROR, "Interval units '%s' not supported", lowunits); result = NULL; } if (tm2interval(tm, fsec, result) != 0) elog(ERROR, "Unable to truncate interval to '%s'", lowunits); } else { elog(NOTICE, "Interval out of range"); result = NULL; } #if NOT_USED } else if ((type == RESERV) && (val == DTK_EPOCH)) { *result = interval->time; if (interval->month != 0) { *result += ((365.25 * 86400) * (interval->month / 12)); *result += ((30 * 86400) * (interval->month % 12)); } #endif } else { elog(ERROR, "Interval units '%s' not recognized", textout(units)); result = NULL; } return result; } /* interval_trunc() */ /* timestamp_part() * Extract specified field from timestamp. */ float64 timestamp_part(text *units, Timestamp *timestamp) { float64 result; Timestamp dt; int tz; int type, val; int i; char *up, *lp, lowunits[MAXDATELEN + 1]; double dummy; double fsec; char *tzn; struct tm tt, *tm = &tt; if ((!PointerIsValid(units)) || (!PointerIsValid(timestamp))) return NULL; result = palloc(sizeof(float64data)); up = VARDATA(units); lp = lowunits; for (i = 0; i < (VARSIZE(units) - VARHDRSZ); i++) *lp++ = tolower(*up++); *lp = '\0'; type = DecodeUnits(0, lowunits, &val); if (type == IGNORE) type = DecodeSpecial(0, lowunits, &val); if (TIMESTAMP_NOT_FINITE(*timestamp)) { #if NOT_USED /* should return null but Postgres doesn't like that currently. - tgl 97/06/12 */ elog(ERROR, "Timestamp is not finite", NULL); #endif *result = 0; } else { dt = (TIMESTAMP_IS_RELATIVE(*timestamp) ? SetTimestamp(*timestamp) : *timestamp); if ((type == UNITS) && (timestamp2tm(dt, &tz, tm, &fsec, &tzn) == 0)) { switch (val) { case DTK_TZ: *result = tz; break; case DTK_TZ_MINUTE: *result = tz / 60; TMODULO(*result, dummy, 60e0); break; case DTK_TZ_HOUR: dummy = tz; TMODULO(dummy, *result, 3600e0); break; case DTK_MICROSEC: *result = (fsec * 1000000); break; case DTK_MILLISEC: *result = (fsec * 1000); break; case DTK_SECOND: *result = (tm->tm_sec + fsec); break; case DTK_MINUTE: *result = tm->tm_min; break; case DTK_HOUR: *result = tm->tm_hour; break; case DTK_DAY: *result = tm->tm_mday; break; case DTK_MONTH: *result = tm->tm_mon; break; case DTK_QUARTER: *result = (tm->tm_mon / 4) + 1; break; case DTK_YEAR: *result = tm->tm_year; break; case DTK_DECADE: *result = (tm->tm_year / 10); break; case DTK_CENTURY: *result = (tm->tm_year / 100); break; case DTK_MILLENIUM: *result = (tm->tm_year / 1000); break; default: elog(ERROR, "Timestamp units '%s' not supported", lowunits); *result = 0; } } else if (type == RESERV) { switch (val) { case DTK_EPOCH: TIMESTAMP_EPOCH(*result); *result = dt - SetTimestamp(*result); break; case DTK_DOW: if (timestamp2tm(dt, &tz, tm, &fsec, &tzn) != 0) elog(ERROR, "Unable to encode timestamp"); *result = j2day(date2j(tm->tm_year, tm->tm_mon, tm->tm_mday)); break; case DTK_DOY: if (timestamp2tm(dt, &tz, tm, &fsec, &tzn) != 0) elog(ERROR, "Unable to encode timestamp"); *result = (date2j(tm->tm_year, tm->tm_mon, tm->tm_mday) - date2j(tm->tm_year, 1, 1) + 1); break; default: elog(ERROR, "Timestamp units '%s' not supported", lowunits); *result = 0; } } else { elog(ERROR, "Timestamp units '%s' not recognized", lowunits); *result = 0; } } return result; } /* timestamp_part() */ /* interval_part() * Extract specified field from interval. */ float64 interval_part(text *units, Interval *interval) { float64 result; int type, val; int i; char *up, *lp, lowunits[MAXDATELEN + 1]; double fsec; struct tm tt, *tm = &tt; if ((!PointerIsValid(units)) || (!PointerIsValid(interval))) return NULL; result = palloc(sizeof(float64data)); up = VARDATA(units); lp = lowunits; for (i = 0; i < (VARSIZE(units) - VARHDRSZ); i++) *lp++ = tolower(*up++); *lp = '\0'; type = DecodeUnits(0, lowunits, &val); if (type == IGNORE) type = DecodeSpecial(0, lowunits, &val); if (INTERVAL_IS_INVALID(*interval)) { #if NOT_USED elog(ERROR, "Interval is not finite"); #endif *result = 0; } else if (type == UNITS) { if (interval2tm(*interval, tm, &fsec) == 0) { switch (val) { case DTK_MICROSEC: *result = (fsec * 1000000); break; case DTK_MILLISEC: *result = (fsec * 1000); break; case DTK_SECOND: *result = (tm->tm_sec + fsec); break; case DTK_MINUTE: *result = tm->tm_min; break; case DTK_HOUR: *result = tm->tm_hour; break; case DTK_DAY: *result = tm->tm_mday; break; case DTK_MONTH: *result = tm->tm_mon; break; case DTK_QUARTER: *result = (tm->tm_mon / 4) + 1; break; case DTK_YEAR: *result = tm->tm_year; break; case DTK_DECADE: *result = (tm->tm_year / 10); break; case DTK_CENTURY: *result = (tm->tm_year / 100); break; case DTK_MILLENIUM: *result = (tm->tm_year / 1000); break; default: elog(ERROR, "Interval units '%s' not yet supported", textout(units)); result = NULL; } } else { elog(NOTICE, "Interval out of range"); *result = 0; } } else if ((type == RESERV) && (val == DTK_EPOCH)) { *result = interval->time; if (interval->month != 0) { *result += ((365.25 * 86400) * (interval->month / 12)); *result += ((30 * 86400) * (interval->month % 12)); } } else { elog(ERROR, "Interval units '%s' not recognized", textout(units)); *result = 0; } return result; } /* interval_part() */ /* timestamp_zone() * Encode timestamp type with specified time zone. */ text * timestamp_zone(text *zone, Timestamp *timestamp) { text *result; Timestamp dt; int tz; int type, val; int i; char *up, *lp, lowzone[MAXDATELEN + 1]; char *tzn, upzone[MAXDATELEN + 1]; double fsec; struct tm tt, *tm = &tt; char buf[MAXDATELEN + 1]; int len; if ((!PointerIsValid(zone)) || (!PointerIsValid(timestamp))) return NULL; up = VARDATA(zone); lp = lowzone; for (i = 0; i < (VARSIZE(zone) - VARHDRSZ); i++) *lp++ = tolower(*up++); *lp = '\0'; type = DecodeSpecial(0, lowzone, &val); if (TIMESTAMP_NOT_FINITE(*timestamp)) { /* * could return null but Postgres doesn't like that currently. - * tgl 97/06/12 */ elog(ERROR, "Timestamp is not finite"); result = NULL; } else if ((type == TZ) || (type == DTZ)) { tm->tm_isdst = ((type == DTZ) ? 1 : 0); tz = val * 60; dt = (TIMESTAMP_IS_RELATIVE(*timestamp) ? SetTimestamp(*timestamp) : *timestamp); dt = dt2local(dt, tz); if (timestamp2tm(dt, NULL, tm, &fsec, NULL) != 0) elog(ERROR, "Timestamp not legal"); up = upzone; lp = lowzone; for (i = 0; *lp != '\0'; i++) *up++ = toupper(*lp++); *up = '\0'; tzn = upzone; EncodeDateTime(tm, fsec, &tz, &tzn, DateStyle, buf); len = (strlen(buf) + VARHDRSZ); result = palloc(len); VARSIZE(result) = len; memmove(VARDATA(result), buf, (len - VARHDRSZ)); } else { elog(ERROR, "Time zone '%s' not recognized", lowzone); result = NULL; } return result; } /* timestamp_zone() */