/* * nabstime.c * Utilities for the built-in type "AbsoluteTime". * Functions for the built-in type "RelativeTime". * Functions for the built-in type "TimeInterval". * * 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/nabstime.c,v 1.73 2000/07/28 02:13:31 tgl Exp $ * * NOTES * *------------------------------------------------------------------------- */ #include "postgres.h" #include #include #include #include #include #include #ifndef USE_POSIX_TIME #include #endif #include "access/xact.h" #include "miscadmin.h" #include "utils/builtins.h" #if 0 static AbsoluteTime tm2abstime(struct tm * tm, int tz); #endif #define MIN_DAYNUM -24856 /* December 13, 1901 */ #define MAX_DAYNUM 24854 /* January 18, 2038 */ #define INVALID_RELTIME_STR "Undefined RelTime" #define INVALID_RELTIME_STR_LEN (sizeof(INVALID_RELTIME_STR)-1) #define RELTIME_LABEL '@' #define RELTIME_PAST "ago" #define DIRMAXLEN (sizeof(RELTIME_PAST)-1) /* * Unix epoch is Jan 1 00:00:00 1970. * Postgres knows about times sixty-eight years on either side of that * for these 4-byte types. * * "tinterval" is two 4-byte fields. * Definitions for parsing tinterval. */ #define IsSpace(C) ((C) == ' ') #define T_INTERVAL_INVAL 0 /* data represents no valid interval */ #define T_INTERVAL_VALID 1 /* data represents a valid interval */ /* * ['Mon May 10 23:59:12 1943 PST' 'Sun Jan 14 03:14:21 1973 PST'] * 0 1 2 3 4 5 6 * 1234567890123456789012345678901234567890123456789012345678901234 * * we allocate some extra -- timezones are usually 3 characters but * this is not in the POSIX standard... */ #define T_INTERVAL_LEN 80 #define INVALID_INTERVAL_STR "Undefined Range" #define INVALID_INTERVAL_STR_LEN (sizeof(INVALID_INTERVAL_STR)-1) #define ABSTIMEMIN(t1, t2) \ (DatumGetBool(DirectFunctionCall2(abstimele, \ AbsoluteTimeGetDatum(t1), \ AbsoluteTimeGetDatum(t2))) ? (t1) : (t2)) #define ABSTIMEMAX(t1, t2) \ (DatumGetBool(DirectFunctionCall2(abstimelt, \ AbsoluteTimeGetDatum(t1), \ AbsoluteTimeGetDatum(t2))) ? (t2) : (t1)) #ifdef NOT_USED static char *unit_tab[] = { "second", "seconds", "minute", "minutes", "hour", "hours", "day", "days", "week", "weeks", "month", "months", "year", "years"}; #define UNITMAXLEN 7 /* max length of a unit name */ #define NUNITS 14 /* number of different units */ /* table of seconds per unit (month = 30 days, year = 365 days) */ static int sec_tab[] = { 1, 1, 60, 60, 3600, 3600, 86400, 86400, 604800, 604800, 2592000, 2592000, 31536000, 31536000}; #endif /* * Function prototypes -- internal to this file only */ static void reltime2tm(RelativeTime time, struct tm * tm); #ifdef NOT_USED static int correct_unit(char *unit, int *unptr); static int correct_dir(char *direction, int *signptr); #endif static int istinterval(char *i_string, AbsoluteTime *i_start, AbsoluteTime *i_end); /* GetCurrentAbsoluteTime() * Get the current system time. Set timezone parameters if not specified elsewhere. * Define HasTZSet to allow clients to specify the default timezone. * * Returns the number of seconds since epoch (January 1 1970 GMT) */ AbsoluteTime GetCurrentAbsoluteTime(void) { time_t now; #ifdef USE_POSIX_TIME struct tm *tm; now = time(NULL); #else /* ! USE_POSIX_TIME */ struct timeb tb; /* the old V7-ism */ ftime(&tb); now = tb.time; #endif if (!HasCTZSet) { #ifdef USE_POSIX_TIME #if defined(HAVE_TM_ZONE) tm = localtime(&now); CTimeZone = -tm->tm_gmtoff; /* tm_gmtoff is Sun/DEC-ism */ CDayLight = (tm->tm_isdst > 0); #ifdef NOT_USED /* * XXX is there a better way to get local timezone string w/o * tzname? - tgl 97/03/18 */ strftime(CTZName, MAXTZLEN, "%Z", tm); #endif /* * XXX FreeBSD man pages indicate that this should work - thomas * 1998-12-12 */ strcpy(CTZName, tm->tm_zone); #elif defined(HAVE_INT_TIMEZONE) tm = localtime(&now); CDayLight = tm->tm_isdst; CTimeZone = #ifdef __CYGWIN32__ (tm->tm_isdst ? (_timezone - 3600) : _timezone); #else (tm->tm_isdst ? (timezone - 3600) : timezone); #endif strcpy(CTZName, tzname[tm->tm_isdst]); #else #error USE_POSIX_TIME defined but no time zone available #endif #else /* ! USE_POSIX_TIME */ CTimeZone = tb.timezone * 60; CDayLight = (tb.dstflag != 0); /* * XXX does this work to get the local timezone string in V7? - * tgl 97/03/18 */ strftime(CTZName, MAXTZLEN, "%Z", localtime(&now)); #endif }; return (AbsoluteTime) now; } /* GetCurrentAbsoluteTime() */ void GetCurrentTime(struct tm * tm) { int tz; abstime2tm(GetCurrentTransactionStartTime(), &tz, tm, NULL); return; } /* GetCurrentTime() */ void abstime2tm(AbsoluteTime _time, int *tzp, struct tm * tm, char *tzn) { time_t time = (time_t) _time; #ifdef USE_POSIX_TIME struct tm *tx; #else /* ! USE_POSIX_TIME */ struct timeb tb; /* the old V7-ism */ ftime(&tb); #endif #ifdef USE_POSIX_TIME if (tzp != NULL) tx = localtime((time_t *) &time); else { tx = gmtime((time_t *) &time); }; #endif #ifdef USE_POSIX_TIME 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; tm->tm_sec = tx->tm_sec; tm->tm_isdst = tx->tm_isdst; #if defined(HAVE_TM_ZONE) tm->tm_gmtoff = tx->tm_gmtoff; tm->tm_zone = tx->tm_zone; if (tzp != NULL) *tzp = -tm->tm_gmtoff; /* tm_gmtoff is Sun/DEC-ism */ /* XXX FreeBSD man pages indicate that this should work - tgl 97/04/23 */ if (tzn != NULL) { /* * Copy no more than MAXTZLEN bytes of timezone to tzn, in case it * contains an error message, which doesn't fit in the buffer */ StrNCpy(tzn, tm->tm_zone, MAXTZLEN+1); if (strlen(tm->tm_zone) > MAXTZLEN) elog(NOTICE, "Invalid timezone \'%s\'", tm->tm_zone); } #elif defined(HAVE_INT_TIMEZONE) if (tzp != NULL) #ifdef __CYGWIN__ *tzp = (tm->tm_isdst ? (_timezone - 3600) : _timezone); #else *tzp = (tm->tm_isdst ? (timezone - 3600) : timezone); #endif if (tzn != NULL) { /* * Copy no more than MAXTZLEN bytes of timezone to tzn, in case it * contains an error message, which doesn't fit in the buffer */ StrNCpy(tzn, tzname[tm->tm_isdst], MAXTZLEN+1); if (strlen(tzname[tm->tm_isdst]) > MAXTZLEN) elog(NOTICE, "Invalid timezone \'%s\'", tzname[tm->tm_isdst]); } #else #error POSIX time support is broken #endif #else /* ! USE_POSIX_TIME */ if (tzp != NULL) *tzp = tb.timezone * 60; /* * XXX does this work to get the local timezone string in V7? - tgl * 97/03/18 */ if (tzn != NULL) { strftime(tzn, MAXTZLEN, "%Z", localtime(&now)); tzn[MAXTZLEN] = '\0'; /* let's just be sure it's null-terminated */ } #endif return; } /* abstime2tm() */ /* tm2abstime() * Convert a tm structure to abstime. * Note that tm has full year (not 1900-based) and 1-based month. */ static AbsoluteTime tm2abstime(struct tm * tm, int tz) { int day, sec; /* validate, before going out of range on some members */ if (tm->tm_year < 1901 || tm->tm_year > 2038 || tm->tm_mon < 1 || tm->tm_mon > 12 || tm->tm_mday < 1 || tm->tm_mday > 31 || tm->tm_hour < 0 || tm->tm_hour >= 24 || tm->tm_min < 0 || tm->tm_min > 59 || tm->tm_sec < 0 || tm->tm_sec > 59) return INVALID_ABSTIME; day = (date2j(tm->tm_year, tm->tm_mon, tm->tm_mday) - date2j(1970, 1, 1)); /* check for time out of range */ if ((day < MIN_DAYNUM) || (day > MAX_DAYNUM)) return INVALID_ABSTIME; /* convert to seconds */ sec = tm->tm_sec + tz + (tm->tm_min + (day * 24 + tm->tm_hour) * 60) * 60; /* check for overflow */ if ((day == MAX_DAYNUM && sec < 0) || (day == MIN_DAYNUM && sec > 0)) return INVALID_ABSTIME; /* check for reserved values (e.g. "current" on edge of usual range */ if (!AbsoluteTimeIsReal(sec)) return INVALID_ABSTIME; return sec; } /* tm2abstime() */ /* nabstimein() * Decode date/time string and return abstime. */ Datum nabstimein(PG_FUNCTION_ARGS) { char *str = PG_GETARG_CSTRING(0); AbsoluteTime result; double fsec; int tz = 0; struct tm date, *tm = &date; char *field[MAXDATEFIELDS]; char lowstr[MAXDATELEN + 1]; int dtype; int nf, ftype[MAXDATEFIELDS]; if (strlen(str) > MAXDATELEN) elog(ERROR, "Bad (length) abstime external representation '%s'", str); if ((ParseDateTime(str, lowstr, field, ftype, MAXDATEFIELDS, &nf) != 0) || (DecodeDateTime(field, ftype, nf, &dtype, tm, &fsec, &tz) != 0)) elog(ERROR, "Bad abstime external representation '%s'", str); switch (dtype) { case DTK_DATE: result = tm2abstime(tm, tz); break; case DTK_EPOCH: result = EPOCH_ABSTIME; break; case DTK_CURRENT: result = CURRENT_ABSTIME; break; case DTK_LATE: result = NOEND_ABSTIME; break; case DTK_EARLY: result = NOSTART_ABSTIME; break; case DTK_INVALID: result = INVALID_ABSTIME; break; default: elog(ERROR, "Bad abstime (internal coding error) '%s'", str); result = INVALID_ABSTIME; break; }; PG_RETURN_ABSOLUTETIME(result); } /* nabstimeout() * Given an AbsoluteTime return the English text version of the date */ Datum nabstimeout(PG_FUNCTION_ARGS) { AbsoluteTime time = PG_GETARG_ABSOLUTETIME(0); char *result; int tz; double fsec = 0; struct tm tt, *tm = &tt; char buf[MAXDATELEN + 1]; char zone[MAXDATELEN + 1], *tzn = zone; switch (time) { case EPOCH_ABSTIME: strcpy(buf, EPOCH); break; case INVALID_ABSTIME: strcpy(buf, INVALID); break; case CURRENT_ABSTIME: strcpy(buf, DCURRENT); break; case NOEND_ABSTIME: strcpy(buf, LATE); break; case NOSTART_ABSTIME: strcpy(buf, EARLY); break; default: abstime2tm(time, &tz, tm, tzn); EncodeDateTime(tm, fsec, &tz, &tzn, DateStyle, buf); break; } result = pstrdup(buf); PG_RETURN_CSTRING(result); } /* * AbsoluteTimeIsBefore -- true iff time1 is before time2. * AbsoluteTimeIsBefore -- true iff time1 is after time2. */ bool AbsoluteTimeIsBefore(AbsoluteTime time1, AbsoluteTime time2) { Assert(AbsoluteTimeIsValid(time1)); Assert(AbsoluteTimeIsValid(time2)); if (time1 == CURRENT_ABSTIME) time1 = GetCurrentTransactionStartTime(); if (time2 == CURRENT_ABSTIME) time2 = GetCurrentTransactionStartTime(); return time1 < time2; } #ifdef NOT_USED bool AbsoluteTimeIsAfter(AbsoluteTime time1, AbsoluteTime time2) { Assert(AbsoluteTimeIsValid(time1)); Assert(AbsoluteTimeIsValid(time2)); if (time1 == CURRENT_ABSTIME) time1 = GetCurrentTransactionStartTime(); if (time2 == CURRENT_ABSTIME) time2 = GetCurrentTransactionStartTime(); return time1 > time2; } #endif /* abstime_finite() */ Datum abstime_finite(PG_FUNCTION_ARGS) { AbsoluteTime abstime = PG_GETARG_ABSOLUTETIME(0); PG_RETURN_BOOL((abstime != INVALID_ABSTIME) && (abstime != NOSTART_ABSTIME) && (abstime != NOEND_ABSTIME)); } /* * abstimeeq - returns true iff arguments are equal * abstimene - returns true iff arguments are not equal * abstimelt - returns true iff t1 less than t2 * abstimegt - returns true iff t1 greater than t2 * abstimele - returns true iff t1 less than or equal to t2 * abstimege - returns true iff t1 greater than or equal to t2 */ Datum abstimeeq(PG_FUNCTION_ARGS) { AbsoluteTime t1 = PG_GETARG_ABSOLUTETIME(0); AbsoluteTime t2 = PG_GETARG_ABSOLUTETIME(1); if (t1 == INVALID_ABSTIME || t2 == INVALID_ABSTIME) PG_RETURN_BOOL(false); if (t1 == CURRENT_ABSTIME) t1 = GetCurrentTransactionStartTime(); if (t2 == CURRENT_ABSTIME) t2 = GetCurrentTransactionStartTime(); PG_RETURN_BOOL(t1 == t2); } Datum abstimene(PG_FUNCTION_ARGS) { AbsoluteTime t1 = PG_GETARG_ABSOLUTETIME(0); AbsoluteTime t2 = PG_GETARG_ABSOLUTETIME(1); if (t1 == INVALID_ABSTIME || t2 == INVALID_ABSTIME) PG_RETURN_BOOL(false); if (t1 == CURRENT_ABSTIME) t1 = GetCurrentTransactionStartTime(); if (t2 == CURRENT_ABSTIME) t2 = GetCurrentTransactionStartTime(); PG_RETURN_BOOL(t1 != t2); } Datum abstimelt(PG_FUNCTION_ARGS) { AbsoluteTime t1 = PG_GETARG_ABSOLUTETIME(0); AbsoluteTime t2 = PG_GETARG_ABSOLUTETIME(1); if (t1 == INVALID_ABSTIME || t2 == INVALID_ABSTIME) PG_RETURN_BOOL(false); if (t1 == CURRENT_ABSTIME) t1 = GetCurrentTransactionStartTime(); if (t2 == CURRENT_ABSTIME) t2 = GetCurrentTransactionStartTime(); PG_RETURN_BOOL(t1 < t2); } Datum abstimegt(PG_FUNCTION_ARGS) { AbsoluteTime t1 = PG_GETARG_ABSOLUTETIME(0); AbsoluteTime t2 = PG_GETARG_ABSOLUTETIME(1); if (t1 == INVALID_ABSTIME || t2 == INVALID_ABSTIME) PG_RETURN_BOOL(false); if (t1 == CURRENT_ABSTIME) t1 = GetCurrentTransactionStartTime(); if (t2 == CURRENT_ABSTIME) t2 = GetCurrentTransactionStartTime(); PG_RETURN_BOOL(t1 > t2); } Datum abstimele(PG_FUNCTION_ARGS) { AbsoluteTime t1 = PG_GETARG_ABSOLUTETIME(0); AbsoluteTime t2 = PG_GETARG_ABSOLUTETIME(1); if (t1 == INVALID_ABSTIME || t2 == INVALID_ABSTIME) PG_RETURN_BOOL(false); if (t1 == CURRENT_ABSTIME) t1 = GetCurrentTransactionStartTime(); if (t2 == CURRENT_ABSTIME) t2 = GetCurrentTransactionStartTime(); PG_RETURN_BOOL(t1 <= t2); } Datum abstimege(PG_FUNCTION_ARGS) { AbsoluteTime t1 = PG_GETARG_ABSOLUTETIME(0); AbsoluteTime t2 = PG_GETARG_ABSOLUTETIME(1); if (t1 == INVALID_ABSTIME || t2 == INVALID_ABSTIME) PG_RETURN_BOOL(false); if (t1 == CURRENT_ABSTIME) t1 = GetCurrentTransactionStartTime(); if (t2 == CURRENT_ABSTIME) t2 = GetCurrentTransactionStartTime(); PG_RETURN_BOOL(t1 >= t2); } /* datetime_abstime() * Convert timestamp to abstime. */ Datum timestamp_abstime(PG_FUNCTION_ARGS) { Timestamp timestamp = PG_GETARG_TIMESTAMP(0); AbsoluteTime result; double fsec; struct tm tt, *tm = &tt; if (TIMESTAMP_IS_INVALID(timestamp)) { result = INVALID_ABSTIME; } else if (TIMESTAMP_IS_NOBEGIN(timestamp)) { result = NOSTART_ABSTIME; } else if (TIMESTAMP_IS_NOEND(timestamp)) { result = NOEND_ABSTIME; } else { if (TIMESTAMP_IS_RELATIVE(timestamp)) { timestamp2tm(SetTimestamp(timestamp), NULL, tm, &fsec, NULL); result = tm2abstime(tm, 0); } else if (timestamp2tm(timestamp, NULL, tm, &fsec, NULL) == 0) { result = tm2abstime(tm, 0); } else { result = INVALID_ABSTIME; } } PG_RETURN_ABSOLUTETIME(result); } /* abstime_timestamp() * Convert abstime to timestamp. */ Datum abstime_timestamp(PG_FUNCTION_ARGS) { AbsoluteTime abstime = PG_GETARG_ABSOLUTETIME(0); Timestamp result; switch (abstime) { case INVALID_ABSTIME: TIMESTAMP_INVALID(result); break; case NOSTART_ABSTIME: TIMESTAMP_NOBEGIN(result); break; case NOEND_ABSTIME: TIMESTAMP_NOEND(result); break; case EPOCH_ABSTIME: TIMESTAMP_EPOCH(result); break; case CURRENT_ABSTIME: TIMESTAMP_CURRENT(result); break; default: result = abstime + ((date2j(1970, 1, 1) - date2j(2000, 1, 1)) * 86400); break; }; PG_RETURN_TIMESTAMP(result); } /***************************************************************************** * USER I/O ROUTINES * *****************************************************************************/ /* * reltimein - converts a reltime string in an internal format */ Datum reltimein(PG_FUNCTION_ARGS) { char *str = PG_GETARG_CSTRING(0); RelativeTime result; struct tm tt, *tm = &tt; double fsec; int dtype; char *field[MAXDATEFIELDS]; int nf, ftype[MAXDATEFIELDS]; char lowstr[MAXDATELEN + 1]; if (strlen(str) > MAXDATELEN) elog(ERROR, "Bad (length) reltime external representation '%s'", str); if ((ParseDateTime(str, lowstr, field, ftype, MAXDATEFIELDS, &nf) != 0) || (DecodeDateDelta(field, ftype, nf, &dtype, tm, &fsec) != 0)) elog(ERROR, "Bad reltime external representation '%s'", str); switch (dtype) { case DTK_DELTA: result = ((((tm->tm_hour * 60) + tm->tm_min) * 60) + tm->tm_sec); result += (((tm->tm_year * 365) + (tm->tm_mon * 30) + tm->tm_mday) * (24 * 60 * 60)); PG_RETURN_RELATIVETIME(result); default: PG_RETURN_RELATIVETIME(INVALID_RELTIME); } elog(ERROR, "Bad reltime (internal coding error) '%s'", str); PG_RETURN_RELATIVETIME(INVALID_RELTIME); } /* * reltimeout - converts the internal format to a reltime string */ Datum reltimeout(PG_FUNCTION_ARGS) { RelativeTime time = PG_GETARG_RELATIVETIME(0); char *result; struct tm tt, *tm = &tt; char buf[MAXDATELEN + 1]; if (time == INVALID_RELTIME) { strcpy(buf, INVALID_RELTIME_STR); } else { reltime2tm(time, tm); EncodeTimeSpan(tm, 0, DateStyle, buf); } result = pstrdup(buf); PG_RETURN_CSTRING(result); } static void reltime2tm(RelativeTime time, struct tm * tm) { TMODULO(time, tm->tm_year, 31536000); TMODULO(time, tm->tm_mon, 2592000); TMODULO(time, tm->tm_mday, 86400); TMODULO(time, tm->tm_hour, 3600); TMODULO(time, tm->tm_min, 60); TMODULO(time, tm->tm_sec, 1); return; } /* reltime2tm() */ #ifdef NOT_USED int dummyfunc() { char *timestring; long quantity; int i; int unitnr; timestring = (char *) palloc(Max(strlen(INVALID_RELTIME_STR), UNITMAXLEN) + 1); if (timevalue == INVALID_RELTIME) { strcpy(timestring, INVALID_RELTIME_STR); return timestring; } if (timevalue == 0) i = 1; /* unit = 'seconds' */ else for (i = 12; i >= 0; i = i - 2) if ((timevalue % sec_tab[i]) == 0) break; /* appropriate unit found */ unitnr = i; quantity = (timevalue / sec_tab[unitnr]); if (quantity > 1 || quantity < -1) unitnr++; /* adjust index for PLURAL of unit */ if (quantity >= 0) sprintf(timestring, "%c %lu %s", RELTIME_LABEL, quantity, unit_tab[unitnr]); else sprintf(timestring, "%c %lu %s %s", RELTIME_LABEL, (quantity * -1), unit_tab[unitnr], RELTIME_PAST); return timestring; } #endif /* * tintervalin - converts an interval string to internal format */ Datum tintervalin(PG_FUNCTION_ARGS) { char *intervalstr = PG_GETARG_CSTRING(0); TimeInterval interval; int error; AbsoluteTime i_start, i_end, t1, t2; interval = (TimeInterval) palloc(sizeof(TimeIntervalData)); error = istinterval(intervalstr, &t1, &t2); if (error == 0) interval->status = T_INTERVAL_INVAL; if (t1 == INVALID_ABSTIME || t2 == INVALID_ABSTIME) interval->status = T_INTERVAL_INVAL; /* undefined */ else { i_start = ABSTIMEMIN(t1, t2); i_end = ABSTIMEMAX(t1, t2); interval->data[0] = i_start; interval->data[1] = i_end; interval->status = T_INTERVAL_VALID; } PG_RETURN_TIMEINTERVAL(interval); } /* * tintervalout - converts an internal interval format to a string * */ Datum tintervalout(PG_FUNCTION_ARGS) { TimeInterval interval = PG_GETARG_TIMEINTERVAL(0); char *i_str, *p; i_str = (char *) palloc(T_INTERVAL_LEN); /* ['...' '...'] */ strcpy(i_str, "[\""); if (interval->status == T_INTERVAL_INVAL) strcat(i_str, INVALID_INTERVAL_STR); else { p = DatumGetCString(DirectFunctionCall1(nabstimeout, AbsoluteTimeGetDatum(interval->data[0]))); strcat(i_str, p); pfree(p); strcat(i_str, "\" \""); p = DatumGetCString(DirectFunctionCall1(nabstimeout, AbsoluteTimeGetDatum(interval->data[1]))); strcat(i_str, p); pfree(p); } strcat(i_str, "\"]\0"); PG_RETURN_CSTRING(i_str); } /***************************************************************************** * PUBLIC ROUTINES * *****************************************************************************/ Datum interval_reltime(PG_FUNCTION_ARGS) { Interval *interval = PG_GETARG_INTERVAL_P(0); RelativeTime time; int year, month; double span; if (INTERVAL_IS_INVALID(*interval)) { time = INVALID_RELTIME; } else { if (interval->month == 0) { year = 0; month = 0; } else if (abs(interval->month) >= 12) { year = (interval->month / 12); month = (interval->month % 12); } else { year = 0; month = interval->month; } span = (((((double) 365 * year) + ((double) 30 * month)) * 86400) + interval->time); time = (((span > INT_MIN) && (span < INT_MAX)) ? span : INVALID_RELTIME); } PG_RETURN_RELATIVETIME(time); } Datum reltime_interval(PG_FUNCTION_ARGS) { RelativeTime reltime = PG_GETARG_RELATIVETIME(0); Interval *result; int year, month; result = (Interval *) palloc(sizeof(Interval)); switch (reltime) { case INVALID_RELTIME: INTERVAL_INVALID(*result); break; default: TMODULO(reltime, year, 31536000); TMODULO(reltime, month, 2592000); result->time = reltime; result->month = ((12 * year) + month); break; } PG_RETURN_INTERVAL_P(result); } /* * mktinterval - creates a time interval with endpoints t1 and t2 */ Datum mktinterval(PG_FUNCTION_ARGS) { AbsoluteTime t1 = PG_GETARG_ABSOLUTETIME(0); AbsoluteTime t2 = PG_GETARG_ABSOLUTETIME(1); AbsoluteTime tstart = ABSTIMEMIN(t1, t2), tend = ABSTIMEMAX(t1, t2); TimeInterval interval; interval = (TimeInterval) palloc(sizeof(TimeIntervalData)); if (t1 == INVALID_ABSTIME || t2 == INVALID_ABSTIME) interval->status = T_INTERVAL_INVAL; else { interval->status = T_INTERVAL_VALID; interval->data[0] = tstart; interval->data[1] = tend; } PG_RETURN_TIMEINTERVAL(interval); } /* * timepl, timemi and abstimemi use the formula * abstime + reltime = abstime * so abstime - reltime = abstime * and abstime - abstime = reltime */ /* * timepl - returns the value of (abstime t1 + relime t2) */ Datum timepl(PG_FUNCTION_ARGS) { AbsoluteTime t1 = PG_GETARG_ABSOLUTETIME(0); RelativeTime t2 = PG_GETARG_RELATIVETIME(1); if (t1 == CURRENT_ABSTIME) t1 = GetCurrentTransactionStartTime(); if (AbsoluteTimeIsReal(t1) && RelativeTimeIsValid(t2) && ((t2 > 0) ? (t1 < NOEND_ABSTIME - t2) : (t1 > NOSTART_ABSTIME - t2))) /* prevent overflow */ PG_RETURN_ABSOLUTETIME(t1 + t2); PG_RETURN_ABSOLUTETIME(INVALID_ABSTIME); } /* * timemi - returns the value of (abstime t1 - reltime t2) */ Datum timemi(PG_FUNCTION_ARGS) { AbsoluteTime t1 = PG_GETARG_ABSOLUTETIME(0); RelativeTime t2 = PG_GETARG_RELATIVETIME(1); if (t1 == CURRENT_ABSTIME) t1 = GetCurrentTransactionStartTime(); if (AbsoluteTimeIsReal(t1) && RelativeTimeIsValid(t2) && ((t2 > 0) ? (t1 > NOSTART_ABSTIME + t2) : (t1 < NOEND_ABSTIME + t2))) /* prevent overflow */ PG_RETURN_ABSOLUTETIME(t1 - t2); PG_RETURN_ABSOLUTETIME(INVALID_ABSTIME); } /* * abstimemi - returns the value of (abstime t1 - abstime t2) * * This is not exported, so it's not been made fmgr-compatible. */ static RelativeTime abstimemi(AbsoluteTime t1, AbsoluteTime t2) { if (t1 == CURRENT_ABSTIME) t1 = GetCurrentTransactionStartTime(); if (t2 == CURRENT_ABSTIME) t2 = GetCurrentTransactionStartTime(); if (AbsoluteTimeIsReal(t1) && AbsoluteTimeIsReal(t2)) return t1 - t2; return INVALID_RELTIME; } /* * intinterval - returns true iff absolute date is in the interval */ Datum intinterval(PG_FUNCTION_ARGS) { AbsoluteTime t = PG_GETARG_ABSOLUTETIME(0); TimeInterval interval = PG_GETARG_TIMEINTERVAL(1); if (interval->status == T_INTERVAL_VALID && t != INVALID_ABSTIME) { if (DatumGetBool(DirectFunctionCall2(abstimege, AbsoluteTimeGetDatum(t), AbsoluteTimeGetDatum(interval->data[0]))) && DatumGetBool(DirectFunctionCall2(abstimele, AbsoluteTimeGetDatum(t), AbsoluteTimeGetDatum(interval->data[1])))) PG_RETURN_BOOL(true); } PG_RETURN_BOOL(false); } /* * tintervalrel - returns relative time corresponding to interval */ Datum tintervalrel(PG_FUNCTION_ARGS) { TimeInterval interval = PG_GETARG_TIMEINTERVAL(0); if (interval->status != T_INTERVAL_VALID) PG_RETURN_RELATIVETIME(INVALID_RELTIME); PG_RETURN_RELATIVETIME(abstimemi(interval->data[1], interval->data[0])); } /* * timenow - returns time "now", internal format * * Now AbsoluteTime is time since Jan 1 1970 -mer 7 Feb 1992 */ Datum timenow(PG_FUNCTION_ARGS) { time_t sec; if (time(&sec) < 0) PG_RETURN_ABSOLUTETIME(INVALID_ABSTIME); PG_RETURN_ABSOLUTETIME((AbsoluteTime) sec); } /* * reltimeeq - returns true iff arguments are equal * reltimene - returns true iff arguments are not equal * reltimelt - returns true iff t1 less than t2 * reltimegt - returns true iff t1 greater than t2 * reltimele - returns true iff t1 less than or equal to t2 * reltimege - returns true iff t1 greater than or equal to t2 */ Datum reltimeeq(PG_FUNCTION_ARGS) { RelativeTime t1 = PG_GETARG_RELATIVETIME(0); RelativeTime t2 = PG_GETARG_RELATIVETIME(1); if (t1 == INVALID_RELTIME || t2 == INVALID_RELTIME) PG_RETURN_BOOL(false); PG_RETURN_BOOL(t1 == t2); } Datum reltimene(PG_FUNCTION_ARGS) { RelativeTime t1 = PG_GETARG_RELATIVETIME(0); RelativeTime t2 = PG_GETARG_RELATIVETIME(1); if (t1 == INVALID_RELTIME || t2 == INVALID_RELTIME) PG_RETURN_BOOL(false); PG_RETURN_BOOL(t1 != t2); } Datum reltimelt(PG_FUNCTION_ARGS) { RelativeTime t1 = PG_GETARG_RELATIVETIME(0); RelativeTime t2 = PG_GETARG_RELATIVETIME(1); if (t1 == INVALID_RELTIME || t2 == INVALID_RELTIME) PG_RETURN_BOOL(false); PG_RETURN_BOOL(t1 < t2); } Datum reltimegt(PG_FUNCTION_ARGS) { RelativeTime t1 = PG_GETARG_RELATIVETIME(0); RelativeTime t2 = PG_GETARG_RELATIVETIME(1); if (t1 == INVALID_RELTIME || t2 == INVALID_RELTIME) PG_RETURN_BOOL(false); PG_RETURN_BOOL(t1 > t2); } Datum reltimele(PG_FUNCTION_ARGS) { RelativeTime t1 = PG_GETARG_RELATIVETIME(0); RelativeTime t2 = PG_GETARG_RELATIVETIME(1); if (t1 == INVALID_RELTIME || t2 == INVALID_RELTIME) PG_RETURN_BOOL(false); PG_RETURN_BOOL(t1 <= t2); } Datum reltimege(PG_FUNCTION_ARGS) { RelativeTime t1 = PG_GETARG_RELATIVETIME(0); RelativeTime t2 = PG_GETARG_RELATIVETIME(1); if (t1 == INVALID_RELTIME || t2 == INVALID_RELTIME) PG_RETURN_BOOL(false); PG_RETURN_BOOL(t1 >= t2); } /* * tintervalsame - returns true iff interval i1 is same as interval i2 * Check begin and end time. */ Datum tintervalsame(PG_FUNCTION_ARGS) { TimeInterval i1 = PG_GETARG_TIMEINTERVAL(0); TimeInterval i2 = PG_GETARG_TIMEINTERVAL(1); if (i1->status == T_INTERVAL_INVAL || i2->status == T_INTERVAL_INVAL) PG_RETURN_BOOL(false); if (DatumGetBool(DirectFunctionCall2(abstimeeq, AbsoluteTimeGetDatum(i1->data[0]), AbsoluteTimeGetDatum(i2->data[0]))) && DatumGetBool(DirectFunctionCall2(abstimeeq, AbsoluteTimeGetDatum(i1->data[1]), AbsoluteTimeGetDatum(i2->data[1])))) PG_RETURN_BOOL(true); PG_RETURN_BOOL(false); } /* * tintervaleq - returns true iff interval i1 is equal to interval i2 * Check length of intervals. */ Datum tintervaleq(PG_FUNCTION_ARGS) { TimeInterval i1 = PG_GETARG_TIMEINTERVAL(0); TimeInterval i2 = PG_GETARG_TIMEINTERVAL(1); AbsoluteTime t10, t11, t20, t21; if (i1->status == T_INTERVAL_INVAL || i2->status == T_INTERVAL_INVAL) PG_RETURN_BOOL(false); t10 = i1->data[0]; t11 = i1->data[1]; t20 = i2->data[0]; t21 = i2->data[1]; if ((t10 == INVALID_ABSTIME) || (t20 == INVALID_ABSTIME) || (t20 == INVALID_ABSTIME) || (t21 == INVALID_ABSTIME)) PG_RETURN_BOOL(false); if (t10 == CURRENT_ABSTIME) t10 = GetCurrentTransactionStartTime(); if (t11 == CURRENT_ABSTIME) t11 = GetCurrentTransactionStartTime(); if (t20 == CURRENT_ABSTIME) t20 = GetCurrentTransactionStartTime(); if (t21 == CURRENT_ABSTIME) t21 = GetCurrentTransactionStartTime(); PG_RETURN_BOOL((t11 - t10) == (t21 - t20)); } Datum tintervalne(PG_FUNCTION_ARGS) { TimeInterval i1 = PG_GETARG_TIMEINTERVAL(0); TimeInterval i2 = PG_GETARG_TIMEINTERVAL(1); AbsoluteTime t10, t11, t20, t21; if (i1->status == T_INTERVAL_INVAL || i2->status == T_INTERVAL_INVAL) PG_RETURN_BOOL(false); t10 = i1->data[0]; t11 = i1->data[1]; t20 = i2->data[0]; t21 = i2->data[1]; if ((t10 == INVALID_ABSTIME) || (t20 == INVALID_ABSTIME) || (t20 == INVALID_ABSTIME) || (t21 == INVALID_ABSTIME)) PG_RETURN_BOOL(false); if (t10 == CURRENT_ABSTIME) t10 = GetCurrentTransactionStartTime(); if (t11 == CURRENT_ABSTIME) t11 = GetCurrentTransactionStartTime(); if (t20 == CURRENT_ABSTIME) t20 = GetCurrentTransactionStartTime(); if (t21 == CURRENT_ABSTIME) t21 = GetCurrentTransactionStartTime(); PG_RETURN_BOOL((t11 - t10) != (t21 - t20)); } Datum tintervallt(PG_FUNCTION_ARGS) { TimeInterval i1 = PG_GETARG_TIMEINTERVAL(0); TimeInterval i2 = PG_GETARG_TIMEINTERVAL(1); AbsoluteTime t10, t11, t20, t21; if (i1->status == T_INTERVAL_INVAL || i2->status == T_INTERVAL_INVAL) PG_RETURN_BOOL(false); t10 = i1->data[0]; t11 = i1->data[1]; t20 = i2->data[0]; t21 = i2->data[1]; if ((t10 == INVALID_ABSTIME) || (t20 == INVALID_ABSTIME) || (t20 == INVALID_ABSTIME) || (t21 == INVALID_ABSTIME)) PG_RETURN_BOOL(false); if (t10 == CURRENT_ABSTIME) t10 = GetCurrentTransactionStartTime(); if (t11 == CURRENT_ABSTIME) t11 = GetCurrentTransactionStartTime(); if (t20 == CURRENT_ABSTIME) t20 = GetCurrentTransactionStartTime(); if (t21 == CURRENT_ABSTIME) t21 = GetCurrentTransactionStartTime(); PG_RETURN_BOOL((t11 - t10) < (t21 - t20)); } Datum tintervalle(PG_FUNCTION_ARGS) { TimeInterval i1 = PG_GETARG_TIMEINTERVAL(0); TimeInterval i2 = PG_GETARG_TIMEINTERVAL(1); AbsoluteTime t10, t11, t20, t21; if (i1->status == T_INTERVAL_INVAL || i2->status == T_INTERVAL_INVAL) PG_RETURN_BOOL(false); t10 = i1->data[0]; t11 = i1->data[1]; t20 = i2->data[0]; t21 = i2->data[1]; if ((t10 == INVALID_ABSTIME) || (t20 == INVALID_ABSTIME) || (t20 == INVALID_ABSTIME) || (t21 == INVALID_ABSTIME)) PG_RETURN_BOOL(false); if (t10 == CURRENT_ABSTIME) t10 = GetCurrentTransactionStartTime(); if (t11 == CURRENT_ABSTIME) t11 = GetCurrentTransactionStartTime(); if (t20 == CURRENT_ABSTIME) t20 = GetCurrentTransactionStartTime(); if (t21 == CURRENT_ABSTIME) t21 = GetCurrentTransactionStartTime(); PG_RETURN_BOOL((t11 - t10) <= (t21 - t20)); } Datum tintervalgt(PG_FUNCTION_ARGS) { TimeInterval i1 = PG_GETARG_TIMEINTERVAL(0); TimeInterval i2 = PG_GETARG_TIMEINTERVAL(1); AbsoluteTime t10, t11, t20, t21; if (i1->status == T_INTERVAL_INVAL || i2->status == T_INTERVAL_INVAL) PG_RETURN_BOOL(false); t10 = i1->data[0]; t11 = i1->data[1]; t20 = i2->data[0]; t21 = i2->data[1]; if ((t10 == INVALID_ABSTIME) || (t20 == INVALID_ABSTIME) || (t20 == INVALID_ABSTIME) || (t21 == INVALID_ABSTIME)) PG_RETURN_BOOL(false); if (t10 == CURRENT_ABSTIME) t10 = GetCurrentTransactionStartTime(); if (t11 == CURRENT_ABSTIME) t11 = GetCurrentTransactionStartTime(); if (t20 == CURRENT_ABSTIME) t20 = GetCurrentTransactionStartTime(); if (t21 == CURRENT_ABSTIME) t21 = GetCurrentTransactionStartTime(); PG_RETURN_BOOL((t11 - t10) > (t21 - t20)); } Datum tintervalge(PG_FUNCTION_ARGS) { TimeInterval i1 = PG_GETARG_TIMEINTERVAL(0); TimeInterval i2 = PG_GETARG_TIMEINTERVAL(1); AbsoluteTime t10, t11, t20, t21; if (i1->status == T_INTERVAL_INVAL || i2->status == T_INTERVAL_INVAL) PG_RETURN_BOOL(false); t10 = i1->data[0]; t11 = i1->data[1]; t20 = i2->data[0]; t21 = i2->data[1]; if ((t10 == INVALID_ABSTIME) || (t20 == INVALID_ABSTIME) || (t20 == INVALID_ABSTIME) || (t21 == INVALID_ABSTIME)) PG_RETURN_BOOL(false); if (t10 == CURRENT_ABSTIME) t10 = GetCurrentTransactionStartTime(); if (t11 == CURRENT_ABSTIME) t11 = GetCurrentTransactionStartTime(); if (t20 == CURRENT_ABSTIME) t20 = GetCurrentTransactionStartTime(); if (t21 == CURRENT_ABSTIME) t21 = GetCurrentTransactionStartTime(); PG_RETURN_BOOL((t11 - t10) >= (t21 - t20)); } /* * tintervalleneq - returns true iff length of interval i is equal to * reltime t * tintervallenne - returns true iff length of interval i is not equal * to reltime t * tintervallenlt - returns true iff length of interval i is less than * reltime t * tintervallengt - returns true iff length of interval i is greater * than reltime t * tintervallenle - returns true iff length of interval i is less or * equal than reltime t * tintervallenge - returns true iff length of interval i is greater or * equal than reltime t */ Datum tintervalleneq(PG_FUNCTION_ARGS) { TimeInterval i = PG_GETARG_TIMEINTERVAL(0); RelativeTime t = PG_GETARG_RELATIVETIME(1); RelativeTime rt; if (i->status == T_INTERVAL_INVAL || t == INVALID_RELTIME) PG_RETURN_BOOL(false); rt = DatumGetRelativeTime(DirectFunctionCall1(tintervalrel, TimeIntervalGetDatum(i))); PG_RETURN_BOOL(rt != INVALID_RELTIME && rt == t); } Datum tintervallenne(PG_FUNCTION_ARGS) { TimeInterval i = PG_GETARG_TIMEINTERVAL(0); RelativeTime t = PG_GETARG_RELATIVETIME(1); RelativeTime rt; if (i->status == T_INTERVAL_INVAL || t == INVALID_RELTIME) PG_RETURN_BOOL(false); rt = DatumGetRelativeTime(DirectFunctionCall1(tintervalrel, TimeIntervalGetDatum(i))); PG_RETURN_BOOL(rt != INVALID_RELTIME && rt != t); } Datum tintervallenlt(PG_FUNCTION_ARGS) { TimeInterval i = PG_GETARG_TIMEINTERVAL(0); RelativeTime t = PG_GETARG_RELATIVETIME(1); RelativeTime rt; if (i->status == T_INTERVAL_INVAL || t == INVALID_RELTIME) PG_RETURN_BOOL(false); rt = DatumGetRelativeTime(DirectFunctionCall1(tintervalrel, TimeIntervalGetDatum(i))); PG_RETURN_BOOL(rt != INVALID_RELTIME && rt < t); } Datum tintervallengt(PG_FUNCTION_ARGS) { TimeInterval i = PG_GETARG_TIMEINTERVAL(0); RelativeTime t = PG_GETARG_RELATIVETIME(1); RelativeTime rt; if (i->status == T_INTERVAL_INVAL || t == INVALID_RELTIME) PG_RETURN_BOOL(false); rt = DatumGetRelativeTime(DirectFunctionCall1(tintervalrel, TimeIntervalGetDatum(i))); PG_RETURN_BOOL(rt != INVALID_RELTIME && rt > t); } Datum tintervallenle(PG_FUNCTION_ARGS) { TimeInterval i = PG_GETARG_TIMEINTERVAL(0); RelativeTime t = PG_GETARG_RELATIVETIME(1); RelativeTime rt; if (i->status == T_INTERVAL_INVAL || t == INVALID_RELTIME) PG_RETURN_BOOL(false); rt = DatumGetRelativeTime(DirectFunctionCall1(tintervalrel, TimeIntervalGetDatum(i))); PG_RETURN_BOOL(rt != INVALID_RELTIME && rt <= t); } Datum tintervallenge(PG_FUNCTION_ARGS) { TimeInterval i = PG_GETARG_TIMEINTERVAL(0); RelativeTime t = PG_GETARG_RELATIVETIME(1); RelativeTime rt; if (i->status == T_INTERVAL_INVAL || t == INVALID_RELTIME) PG_RETURN_BOOL(false); rt = DatumGetRelativeTime(DirectFunctionCall1(tintervalrel, TimeIntervalGetDatum(i))); PG_RETURN_BOOL(rt != INVALID_RELTIME && rt >= t); } /* * tintervalct - returns true iff interval i1 contains interval i2 */ Datum tintervalct(PG_FUNCTION_ARGS) { TimeInterval i1 = PG_GETARG_TIMEINTERVAL(0); TimeInterval i2 = PG_GETARG_TIMEINTERVAL(1); if (i1->status == T_INTERVAL_INVAL || i2->status == T_INTERVAL_INVAL) PG_RETURN_BOOL(false); if (DatumGetBool(DirectFunctionCall2(abstimele, AbsoluteTimeGetDatum(i1->data[0]), AbsoluteTimeGetDatum(i2->data[0]))) && DatumGetBool(DirectFunctionCall2(abstimege, AbsoluteTimeGetDatum(i1->data[1]), AbsoluteTimeGetDatum(i2->data[1])))) PG_RETURN_BOOL(true); PG_RETURN_BOOL(false); } /* * tintervalov - returns true iff interval i1 (partially) overlaps i2 */ Datum tintervalov(PG_FUNCTION_ARGS) { TimeInterval i1 = PG_GETARG_TIMEINTERVAL(0); TimeInterval i2 = PG_GETARG_TIMEINTERVAL(1); if (i1->status == T_INTERVAL_INVAL || i2->status == T_INTERVAL_INVAL) PG_RETURN_BOOL(false); if (DatumGetBool(DirectFunctionCall2(abstimelt, AbsoluteTimeGetDatum(i1->data[1]), AbsoluteTimeGetDatum(i2->data[0]))) || DatumGetBool(DirectFunctionCall2(abstimegt, AbsoluteTimeGetDatum(i1->data[0]), AbsoluteTimeGetDatum(i2->data[1])))) PG_RETURN_BOOL(false); PG_RETURN_BOOL(true); } /* * tintervalstart - returns the start of interval i */ Datum tintervalstart(PG_FUNCTION_ARGS) { TimeInterval i = PG_GETARG_TIMEINTERVAL(0); if (i->status == T_INTERVAL_INVAL) PG_RETURN_ABSOLUTETIME(INVALID_ABSTIME); PG_RETURN_ABSOLUTETIME(i->data[0]); } /* * tintervalend - returns the end of interval i */ Datum tintervalend(PG_FUNCTION_ARGS) { TimeInterval i = PG_GETARG_TIMEINTERVAL(0); if (i->status == T_INTERVAL_INVAL) PG_RETURN_ABSOLUTETIME(INVALID_ABSTIME); PG_RETURN_ABSOLUTETIME(i->data[1]); } /***************************************************************************** * PRIVATE ROUTINES * *****************************************************************************/ #ifdef NOT_USED /* * isreltime - returns 1, iff datestring is of type reltime * 2, iff datestring is 'invalid time' identifier * 0, iff datestring contains a syntax error * VALID time less or equal +/- `@ 68 years' * */ int isreltime(char *str) { struct tm tt, *tm = &tt; double fsec; int dtype; char *field[MAXDATEFIELDS]; int nf, ftype[MAXDATEFIELDS]; char lowstr[MAXDATELEN + 1]; if (!PointerIsValid(str)) return 0; if (strlen(str) > MAXDATELEN) return 0; if ((ParseDateTime(str, lowstr, field, ftype, MAXDATEFIELDS, &nf) != 0) || (DecodeDateDelta(field, ftype, nf, &dtype, tm, &fsec) != 0)) return 0; switch (dtype) { case (DTK_DELTA): return (abs(tm->tm_year) <= 68) ? 1 : 0; break; case (DTK_INVALID): return 2; break; default: return 0; break; } return 0; } /* isreltime() */ #endif #ifdef NOT_USED int dummyfunc() { char *p; char c; int i; char unit[UNITMAXLEN]; char direction[DIRMAXLEN]; int localSign; int localUnitNumber; long localQuantity; if (!PointerIsValid(sign)) sign = &localSign; if (!PointerIsValid(unitnr)) unitnr = &localUnitNumber; if (!PointerIsValid(quantity)) quantity = &localQuantity; unit[0] = '\0'; direction[0] = '\0'; p = timestring; /* skip leading blanks */ while ((c = *p) != '\0') { if (c != ' ') break; p++; } /* Test whether 'invalid time' identifier or not */ if (!strncmp(INVALID_RELTIME_STR, p, strlen(INVALID_RELTIME_STR) + 1)) return 2; /* correct 'invalid time' identifier found */ /* handle label of relative time */ if (c != RELTIME_LABEL) return 0; /* syntax error */ c = *++p; if (c != ' ') return 0; /* syntax error */ p++; /* handle the quantity */ *quantity = 0; for (;;) { c = *p; if (isdigit(c)) { *quantity = *quantity * 10 + (c - '0'); p++; } else { if (c == ' ') break; /* correct quantity found */ else return 0; /* syntax error */ } } /* handle unit */ p++; i = 0; for (;;) { c = *p; if (c >= 'a' && c <= 'z' && i <= (UNITMAXLEN - 1)) { unit[i] = c; p++; i++; } else { if ((c == ' ' || c == '\0') && correct_unit(unit, unitnr)) break; /* correct unit found */ else return 0; /* syntax error */ } } /* handle optional direction */ if (c == ' ') p++; i = 0; *sign = 1; for (;;) { c = *p; if (c >= 'a' && c <= 'z' && i <= (DIRMAXLEN - 1)) { direction[i] = c; p++; i++; } else { if ((c == ' ' || c == '\0') && i == 0) { *sign = 1; break; /* no direction specified */ } if ((c == ' ' || c == '\0') && i != 0) { direction[i] = '\0'; correct_dir(direction, sign); break; /* correct direction found */ } else return 0; /* syntax error */ } } return 1; } /* * correct_unit - returns 1, iff unit is a correct unit description * * output parameter: * unptr: points to an integer which is the appropriate unit number * (see function isreltime()) */ static int correct_unit(char *unit, int *unptr) { int j = 0; while (j < NUNITS) { if (strncmp(unit, unit_tab[j], strlen(unit_tab[j])) == 0) { *unptr = j; return 1; } j++; } return 0; /* invalid unit descriptor */ } /* * correct_dir - returns 1, iff direction is a correct identifier * * output parameter: * signptr: points to -1 if dir corresponds to past tense * else to 1 */ static int correct_dir(char *direction, int *signptr) { *signptr = 1; if (strncmp(RELTIME_PAST, direction, strlen(RELTIME_PAST) + 1) == 0) { *signptr = -1; return 1; } else return 0; /* invalid direction descriptor */ } #endif /* * istinterval - returns 1, iff i_string is a valid interval descr. * 0, iff i_string is NOT a valid interval desc. * 2, iff any time is INVALID_ABSTIME * * output parameter: * i_start, i_end: interval margins * * Time interval: * `[' {` '} `'' `'' {` '} `'' `'' {` '} `]' * * OR `Undefined Range' (see also INVALID_INTERVAL_STR) * * where satisfies the syntax of absolute time. * * e.g. [ ' Jan 18 1902' 'Jan 1 00:00:00 1970'] */ static int istinterval(char *i_string, AbsoluteTime *i_start, AbsoluteTime *i_end) { char *p, *p1; char c; p = i_string; /* skip leading blanks up to '[' */ while ((c = *p) != '\0') { if (IsSpace(c)) p++; else if (c != '[') return 0; /* syntax error */ else break; } p++; /* skip leading blanks up to "'" */ while ((c = *p) != '\0') { if (IsSpace(c)) p++; else if (c != '"') return 0; /* syntax error */ else break; } p++; if (strncmp(INVALID_INTERVAL_STR, p, strlen(INVALID_INTERVAL_STR)) == 0) return 0; /* undefined range, handled like a syntax * err. */ /* search for the end of the first date and change it to a NULL */ p1 = p; while ((c = *p1) != '\0') { if (c == '"') { *p1 = '\0'; break; } p1++; } /* get the first date */ *i_start = DatumGetAbsoluteTime(DirectFunctionCall1(nabstimein, CStringGetDatum(p))); /* rechange NULL at the end of the first date to a "'" */ *p1 = '"'; p = ++p1; /* skip blanks up to "'", beginning of second date */ while ((c = *p) != '\0') { if (IsSpace(c)) p++; else if (c != '"') return 0; /* syntax error */ else break; } p++; /* search for the end of the second date and change it to a NULL */ p1 = p; while ((c = *p1) != '\0') { if (c == '"') { *p1 = '\0'; break; } p1++; } /* get the second date */ *i_end = DatumGetAbsoluteTime(DirectFunctionCall1(nabstimein, CStringGetDatum(p))); /* rechange NULL at the end of the first date to a ''' */ *p1 = '"'; p = ++p1; /* skip blanks up to ']' */ while ((c = *p) != '\0') { if (IsSpace(c)) p++; else if (c != ']') return 0; /* syntax error */ else break; } p++; c = *p; if (c != '\0') return 0; /* syntax error */ /* it seems to be a valid interval */ return 1; } /***************************************************************************** * *****************************************************************************/ Datum int4reltime(PG_FUNCTION_ARGS) { int32 timevalue = PG_GETARG_INT32(0); /* Just coerce it directly to RelativeTime ... */ PG_RETURN_RELATIVETIME((RelativeTime) timevalue); } /* * timeofday - * returns the current time as a text. similar to timenow() but returns * seconds with more precision (up to microsecs). (I need this to compare * the Wisconsin benchmark with Illustra whose TimeNow() shows current * time with precision up to microsecs.) - ay 3/95 */ Datum timeofday(PG_FUNCTION_ARGS) { struct timeval tp; struct timezone tpz; char templ[500]; char buf[500]; text *result; int len = 0; gettimeofday(&tp, &tpz); strftime(templ, sizeof(templ), "%a %b %d %H:%M:%S.%%d %Y %Z", localtime((time_t *) &tp.tv_sec)); snprintf(buf, sizeof(buf), templ, tp.tv_usec); len = VARHDRSZ + strlen(buf); result = (text *) palloc(len); VARATT_SIZEP(result) = len; memcpy(VARDATA(result), buf, strlen(buf)); PG_RETURN_TEXT_P(result); }