/* * misc - data and miscellaneous routines */ /* $Id$ */ #include #include #include #include #if defined(__BSD4_2) extern int _gettimeofday(struct timeval* tp, struct timezone* tzp); #elif !defined(_POSIX_SOURCE) && !defined(__USG) #if !defined(_MINIX) /* MINIX has no ftime() */ struct timeb { long time; unsigned short millitm; short timezone; short dstflag; }; void _ftime(struct timeb* bp); #endif #endif #include "loc_time.h" #define RULE_LEN 120 #define TZ_LEN 10 /* Make sure that the strings do not end up in ROM. * These strings probably contain the wrong value, and we cannot obtain the * right value from the system. TZ is the only help. */ static char ntstr[TZ_LEN + 1] = "GMT"; /* string for normal time */ static char dststr[TZ_LEN + 1] = "GDT"; /* string for daylight saving */ long _timezone = 0; long _dst_off = 60 * 60; int _daylight = 0; char* _tzname[2] = { ntstr, dststr }; #if defined(__USG) || defined(_POSIX_SOURCE) char* tzname[2] = { ntstr, dststr }; #if defined(__USG) long timezone = 0; int daylight = 0; #endif #endif static struct dsttype { char ds_type; /* Unknown, Julian, Zero-based or M */ int ds_date[3]; /* months, weeks, days */ long ds_sec; /* usually 02:00:00 */ } dststart = { 'U', { 0, 0, 0 }, 2 * 60 * 60 }, dstend = { 'U', { 0, 0, 0 }, 2 * 60 * 60 }; const char* _days[] = { "Sunday", "Monday", "Tuesday", "Wednesday", "Thursday", "Friday", "Saturday" }; const char* _months[] = { "January", "February", "March", "April", "May", "June", "July", "August", "September", "October", "November", "December" }; const int _ytab[2][12] = { { 31, 28, 31, 30, 31, 30, 31, 31, 30, 31, 30, 31 }, { 31, 29, 31, 30, 31, 30, 31, 31, 30, 31, 30, 31 } }; #if !defined(_POSIX_SOURCE) && !defined(__USG) #define USE_TABLE 1 #endif #if USE_TABLE static int usetable = 1; typedef struct table { const char* tz_name; const int daylight; const long zoneoffset; } TABLE; #define HOUR(x) ((x)*60 * 60) static TABLE TimezoneTable[] = { { "GMT", 0, HOUR(0) }, /* Greenwich Mean */ { "BST", 60 * 60, HOUR(0) }, /* British Summer */ { "WAT", 0, HOUR(1) }, /* West Africa */ { "AT", 0, HOUR(2) }, /* Azores */ { "BST", 0, HOUR(3) }, /* Brazil Standard */ { "NFT", 0, HOUR(3.5) }, /* Newfoundland */ { "NDT", 60 * 60, HOUR(3.5) }, /* Newfoundland Daylight */ { "AST", 0, HOUR(4) }, /* Atlantic Standard */ { "ADT", 60 * 60, HOUR(4) }, /* Atlantic Daylight */ { "EST", 0, HOUR(5) }, /* Eastern Standard */ { "EDT", 60 * 60, HOUR(5) }, /* Eastern Daylight */ { "CST", 0, HOUR(6) }, /* Central Standard */ { "CDT", 60 * 60, HOUR(6) }, /* Central Daylight */ { "MST", 0, HOUR(7) }, /* Mountain Standard */ { "MDT", 60 * 60, HOUR(7) }, /* Mountain Daylight */ { "PST", 0, HOUR(8) }, /* Pacific Standard */ { "PDT", 60 * 60, HOUR(8) }, /* Pacific Daylight */ { "YST", 0, HOUR(9) }, /* Yukon Standard */ { "YDT", 60 * 60, HOUR(9) }, /* Yukon Daylight */ { "HST", 0, HOUR(10) }, /* Hawaii Standard */ { "HDT", 60 * 60, HOUR(10) }, /* Hawaii Daylight */ { "NT", 0, HOUR(11) }, /* Nome */ { "IDLW", 0, HOUR(12) }, /* International Date Line West */ { "MET", 0, -HOUR(1) }, /* Middle European */ { "MDT", 60 * 60, -HOUR(1) }, /* Middle European Summer */ { "EET", 0, -HOUR(2) }, /* Eastern Europe, USSR Zone 1 */ { "BT", 0, -HOUR(3) }, /* Baghdad, USSR Zone 2 */ { "IT", 0, -HOUR(3.5) }, /* Iran */ { "ZP4", 0, -HOUR(4) }, /* USSR Zone 3 */ { "ZP5", 0, -HOUR(5) }, /* USSR Zone 4 */ { "IST", 0, -HOUR(5.5) }, /* Indian Standard */ { "ZP6", 0, -HOUR(6) }, /* USSR Zone 5 */ { "NST", 0, -HOUR(6.5) }, /* North Sumatra */ { "SST", 0, -HOUR(7) }, /* South Sumatra, USSR Zone 6 */ { "WAST", 0, -HOUR(7) }, /* West Australian Standard */ { "WADT", 60 * 60, -HOUR(7) }, /* West Australian Daylight */ { "JT", 0, -HOUR(7.5) }, /* Java (3pm in Cronusland!) */ { "CCT", 0, -HOUR(8) }, /* China Coast, USSR Zone 7 */ { "JST", 0, -HOUR(9) }, /* Japan Standard, USSR Zone 8 */ { "CAST", 0, -HOUR(9.5) }, /* Central Australian Standard */ { "CADT", 60 * 60, -HOUR(9.5) }, /* Central Australian Daylight */ { "EAST", 0, -HOUR(10) }, /* Eastern Australian Standard */ { "EADT", 60 * 60, -HOUR(10) }, /* Eastern Australian Daylight */ { "NZT", 0, -HOUR(12) }, /* New Zealand */ { "NZDT", 60 * 60, -HOUR(12) }, /* New Zealand Daylight */ { NULL, 0, 0 } }; /* * The function ZoneFromTable() searches the table for the current * timezone. It saves the last one found in ntstr or dststr, depending on * wheter the name is for daylight-saving-time or not. * Both ntstr and dststr are TZ_LEN + 1 chars. */ static void ZoneFromTable(long timezone) { register TABLE* tptr = TimezoneTable; while (tptr->tz_name != NULL) { if (tptr->zoneoffset == timezone) { if (tptr->daylight == 0) { strncpy(ntstr, tptr->tz_name, TZ_LEN); ntstr[TZ_LEN] = '\0'; } else { strncpy(dststr, tptr->tz_name, TZ_LEN); dststr[TZ_LEN] = '\0'; } } tptr++; } } #endif /* USE_TABLE */ static const char* parseZoneName(register char* buf, register const char* p) { register int n = 0; if (*p == ':') return NULL; while (*p && !isdigit(*p) && *p != ',' && *p != '-' && *p != '+') { if (n < TZ_LEN) *buf++ = *p; p++; n++; } if (n < 3) return NULL; /* error */ *buf = '\0'; return p; } static const char* parseTime(register long* tm, const char* p, register struct dsttype* dst) { register int n = 0; register const char* q = p; char ds_type = (dst ? dst->ds_type : '\0'); if (dst) dst->ds_type = 'U'; *tm = 0; while (*p >= '0' && *p <= '9') { n = 10 * n + (*p++ - '0'); } if (q == p) return NULL; /* "The hour shall be required" */ if (n < 0 || n >= 24) return NULL; *tm = n * 60 * 60; if (*p == ':') { p++; n = 0; while (*p >= '0' && *p <= '9') { n = 10 * n + (*p++ - '0'); } if (q == p) return NULL; /* format error */ if (n < 0 || n >= 60) return NULL; *tm += n * 60; if (*p == ':') { p++; n = 0; while (*p >= '0' && *p <= '9') { n = 10 * n + (*p++ - '0'); } if (q == p) return NULL; /* format error */ if (n < 0 || n >= 60) return NULL; *tm += n; } } if (dst) { dst->ds_type = ds_type; dst->ds_sec = *tm; } return p; } static const char* parseDate(register char* buf, register const char* p, struct dsttype* dstinfo) { register const char* q; register int n = 0; int cnt = 0; const int bnds[3][2] = { { 1, 12 }, { 1, 5 }, { 0, 6 } }; char ds_type; if (*p != 'M') { if (*p == 'J') { *buf++ = *p++; ds_type = 'J'; } else ds_type = 'Z'; q = p; while (*p >= '0' && *p <= '9') { n = 10 * n + (*p - '0'); *buf++ = *p++; } if (q == p) return NULL; /* format error */ if (n < (ds_type == 'J') || n > 365) return NULL; dstinfo->ds_type = ds_type; dstinfo->ds_date[0] = n; return p; } ds_type = 'M'; do { *buf++ = *p++; q = p; n = 0; while (*p >= '0' && *p <= '9') { n = 10 * n + (*p - '0'); *buf++ = *p++; } if (q == p) return NULL; /* format error */ if (n < bnds[cnt][0] || n > bnds[cnt][1]) return NULL; dstinfo->ds_date[cnt] = n; cnt++; } while (cnt < 3 && *p == '.'); if (cnt != 3) return NULL; *buf = '\0'; dstinfo->ds_type = ds_type; return p; } static const char* parseRule(register char* buf, register const char* p) { long tim; register const char* q; if (!(p = parseDate(buf, p, &dststart))) return NULL; buf += strlen(buf); if (*p == '/') { q = ++p; if (!(p = parseTime(&tim, p, &dststart))) return NULL; while (p != q) *buf++ = *q++; } if (*p != ',') return NULL; p++; if (!(p = parseDate(buf, p, &dstend))) return NULL; buf += strlen(buf); if (*p == '/') { q = ++p; if (!(p = parseTime(&tim, p, &dstend))) return NULL; while (*buf++ = *q++) ; } if (*p) return NULL; return p; } /* The following routine parses timezone information in POSIX-format. For * the requirements, see IEEE Std 1003.1-1988 section 8.1.1. * The function returns as soon as it spots an error. */ static void parseTZ(const char* p) { long tz, dst = 60 * 60, sign = 1; static char lastTZ[2 * RULE_LEN]; static char buffer[RULE_LEN]; if (!p) return; #if USE_TABLE usetable = 0; #endif if (*p == ':') { /* * According to POSIX, this is implementation defined. * Since it depends on the particular operating system, we * can do nothing. */ return; } if (!strcmp(lastTZ, p)) return; /* nothing changed */ *_tzname[0] = '\0'; *_tzname[1] = '\0'; dststart.ds_type = 'U'; dststart.ds_sec = 2 * 60 * 60; dstend.ds_type = 'U'; dstend.ds_sec = 2 * 60 * 60; if (strlen(p) > 2 * RULE_LEN) return; strcpy(lastTZ, p); if (!(p = parseZoneName(buffer, p))) return; if (*p == '-') { sign = -1; p++; } else if (*p == '+') p++; if (!(p = parseTime(&tz, p, NULL))) return; tz *= sign; _timezone = tz; strncpy(_tzname[0], buffer, TZ_LEN); if (!(_daylight = (*p != '\0'))) return; buffer[0] = '\0'; if (!(p = parseZoneName(buffer, p))) return; strncpy(_tzname[1], buffer, TZ_LEN); buffer[0] = '\0'; if (*p && (*p != ',')) if (!(p = parseTime(&dst, p, NULL))) return; _dst_off = dst; /* dst was initialized to 1 hour */ if (*p) { if (*p != ',') return; p++; if (strlen(p) > RULE_LEN) return; if (!(p = parseRule(buffer, p))) return; } } void _tzset(void) { #if defined(__BSD4_2) struct timeval tv; struct timezone tz; _gettimeofday(&tv, &tz); _daylight = tz.tz_dsttime; _timezone = tz.tz_minuteswest * 60L; #elif !defined(_POSIX_SOURCE) && !defined(__USG) #if !defined(_MINIX) /* MINIX has no ftime() */ struct timeb tim; _ftime(&tim); _timezone = tim.timezone * 60L; _daylight = tim.dstflag; #endif #endif /* !_POSIX_SOURCE && !__USG */ parseTZ(getenv("TZ")); /* should go inside #if */ #if defined(__USG) || defined(_POSIX_SOURCE) tzname[0] = _tzname[0]; tzname[1] = _tzname[1]; #if defined(__USG) timezone = _timezone; daylight = _daylight; #endif #endif /* __USG || _POSIX_SOURCE */ } static int last_sunday(register int day, register struct tm* timep) { int first = FIRSTSUNDAY(timep); if (day >= 58 && LEAPYEAR(YEAR0 + timep->tm_year)) day++; if (day < first) return first; return day - (day - first) % 7; } static int date_of(register struct dsttype* dst, struct tm* timep) { int leap = LEAPYEAR(YEAR0 + timep->tm_year); int firstday, tmpday; register int day, month; if (dst->ds_type != 'M') { return dst->ds_date[0] - (dst->ds_type == 'J' && leap && dst->ds_date[0] < 58); } day = 0; month = 1; while (month < dst->ds_date[0]) { day += _ytab[leap][month - 1]; month++; } firstday = (day + FIRSTDAYOF(timep)) % 7; tmpday = day; day += (dst->ds_date[2] - firstday + 7) % 7 + 7 * (dst->ds_date[1] - 1); if (day >= tmpday + _ytab[leap][month]) day -= 7; return day; } /* * The default dst transitions are those for Western Europe (except Great * Britain). */ unsigned _dstget(register struct tm* timep) { int begindst, enddst; register struct dsttype *dsts = &dststart, *dste = &dstend; int do_dst = 0; if (_daylight == -1) _tzset(); timep->tm_isdst = _daylight; if (!_daylight) return 0; if (dsts->ds_type != 'U') begindst = date_of(dsts, timep); else begindst = last_sunday(89, timep); /* last Sun before Apr */ if (dste->ds_type != 'U') enddst = date_of(dste, timep); else enddst = last_sunday(272, timep); /* last Sun in Sep */ /* assume begindst != enddst (otherwise it would be no use) */ if (begindst < enddst) { /* northern hemisphere */ if (timep->tm_yday > begindst && timep->tm_yday < enddst) do_dst = 1; } else { /* southern hemisphere */ if (timep->tm_yday > begindst || timep->tm_yday < enddst) do_dst = 1; } if (!do_dst && (timep->tm_yday == begindst || timep->tm_yday == enddst)) { long dsttranssec; /* transition when day is this old */ long cursec; if (timep->tm_yday == begindst) dsttranssec = dsts->ds_sec; else dsttranssec = dste->ds_sec; cursec = ((timep->tm_hour * 60) + timep->tm_min) * 60L + timep->tm_sec; if ((timep->tm_yday == begindst && cursec >= dsttranssec) || (timep->tm_yday == enddst && cursec < dsttranssec)) do_dst = 1; } #if USE_TABLE if (usetable) ZoneFromTable(_timezone); #endif if (do_dst) return _dst_off; timep->tm_isdst = 0; return 0; }