/* * Authors (alphabetical order) * - Bertrand Songis * - Bryan J. Rentoul (Gruvin) * - Cameron Weeks * - Erez Raviv * - Jean-Pierre Parisy * - Karl Szmutny * - Michael Blandford * - Michal Hlavinka * - Philip Moss * - Rob Thomson * - Romolo Manfredini * - Thomas Husterer * * open9x is based on code named * gruvin9x by Bryan J. Rentoul: http://code.google.com/p/gruvin9x/, * er9x by Erez Raviv: http://code.google.com/p/er9x/, * and the original (and ongoing) project by * Thomas Husterer, th9x: http://code.google.com/p/th9x/ * * This program is free software; you can redistribute it and/or modify * it under the terms of the GNU General Public License version 2 as * published by the Free Software Foundation. * * This program is distributed in the hope that it will be useful, * but WITHOUT ANY WARRANTY; without even the implied warranty of * MERCHANTABILITY or FITNESS FOR A PARTICULAR PURPOSE. See the * GNU General Public License for more details. * */ #include "gtime.h" #define LEAP_SECONDS_POSSIBLE 0 /* Shift A right by B bits portably, by dividing A by 2**B and truncating towards minus infinity. A and B should be free of side effects, and B should be in the range 0 <= B <= INT_BITS - 2, where INT_BITS is the number of useful bits in an int. GNU code can assume that INT_BITS is at least 32. ISO C99 says that A >> B is implementation-defined if A < 0. Some implementations (e.g., UNICOS 9.0 on a Cray Y-MP EL) don't shift right in the usual way when A < 0, so SHR falls back on division if ordinary A >> B doesn't seem to be the usual signed shift. */ #define SHR(a, b) \ (-1 >> 1 == -1 \ ? (a) >> (b) \ : (a) / (1 << (b)) - ((a) % (1 << (b)) < 0)) /* The extra casts in the following macros work around compiler bugs, e.g., in Cray C 5.0.3.0. */ /* True if the arithmetic type T is an integer type. bool counts as an integer. */ #define TYPE_IS_INTEGER(t) ((t) 1.5 == 1) /* True if negative values of the signed integer type T use two's complement, ones' complement, or signed magnitude representation, respectively. Much GNU code assumes two's complement, but some people like to be portable to all possible C hosts. */ #define TYPE_TWOS_COMPLEMENT(t) ((t) ~ (t) 0 == (t) -1) #define TYPE_ONES_COMPLEMENT(t) ((t) ~ (t) 0 == 0) #define TYPE_SIGNED_MAGNITUDE(t) ((t) ~ (t) 0 < (t) -1) /* True if the arithmetic type T is signed. */ #define TYPE_SIGNED(t) (! ((t) 0 < (t) -1)) /* The maximum and minimum values for the integer type T. These macros have undefined behavior if T is signed and has padding bits. If this is a problem for you, please let us know how to fix it for your host. */ #define TYPE_MINIMUM(t) \ ((t) (! TYPE_SIGNED (t) \ ? (t) 0 \ : TYPE_SIGNED_MAGNITUDE (t) \ ? ~ (t) 0 \ : ~ (t) 0 << (sizeof (t) * CHAR_BIT - 1))) #define TYPE_MAXIMUM(t) \ ((t) (! TYPE_SIGNED (t) \ ? (t) -1 \ : ~ (~ (t) 0 << (sizeof (t) * CHAR_BIT - 1)))) #ifndef TIME_T_MIN # define TIME_T_MIN TYPE_MINIMUM (gtime_t) #endif #ifndef TIME_T_MAX # define TIME_T_MAX TYPE_MAXIMUM (gtime_t) #endif #define TIME_T_MIDPOINT (SHR (TIME_T_MIN + TIME_T_MAX, 1) + 1) /* Verify a requirement at compile-time (unlike assert, which is runtime). */ #define verify(name, assertion) struct name { char a[(assertion) ? 1 : -1]; } verify (gtime_t_is_integer, TYPE_IS_INTEGER (gtime_t)); verify (twos_complement_arithmetic, TYPE_TWOS_COMPLEMENT (int)); /* The code also assumes that signed integer overflow silently wraps around, but this assumption can't be stated without causing a diagnostic on some hosts. */ #define EPOCH_YEAR 1970 #define TM_YEAR_BASE 1900 verify (base_year_is_a_multiple_of_100, TM_YEAR_BASE % 100 == 0); #define SECS_PER_HOUR 3600ul #define SECS_PER_DAY 86400ul /* Return 1 if YEAR + TM_YEAR_BASE is a leap year. */ static inline int leapyear (long int year) { /* Don't add YEAR to TM_YEAR_BASE, as that might overflow. Also, work even if YEAR is negative. */ return ((year & 3) == 0 && (year % 100 != 0 || ((year / 100) & 3) == (- (TM_YEAR_BASE / 100) & 3))); } const unsigned short int __mon_yday[2][13] = { /* Normal years. */ { 0, 31, 59, 90, 120, 151, 181, 212, 243, 273, 304, 334, 365 }, /* Leap years. */ { 0, 31, 60, 91, 121, 152, 182, 213, 244, 274, 305, 335, 366 } }; /* Compute the `struct tm' representation of *T, offset OFFSET seconds east of UTC, and store year, yday, mon, mday, wday, hour, min, sec into *TP. Return nonzero if successful. */ int __offtime ( gtime_t *t, long int offset, struct gtm *tp) { long int days, rem, y; const unsigned short int *ip; days = *t / SECS_PER_DAY; rem = *t % SECS_PER_DAY; rem += offset; while (rem < 0) { rem += SECS_PER_DAY; --days; } while (rem >= (long int)SECS_PER_DAY) { rem -= SECS_PER_DAY; ++days; } tp->tm_hour = rem / SECS_PER_HOUR; rem %= SECS_PER_HOUR; tp->tm_min = rem / 60; tp->tm_sec = rem % 60; /* January 1, 1970 was a Thursday. */ tp->tm_wday = (4 + days) % 7; if (tp->tm_wday < 0) tp->tm_wday += 7; y = 1970; #define DIV(a, b) ((a) / (b) - ((a) % (b) < 0)) #define LEAPS_THRU_END_OF(y) (DIV (y, 4) - DIV (y, 100) + DIV (y, 400)) while (days < 0 || days >= (leapyear (y) ? 366 : 365)) { /* Guess a corrected year, assuming 365 days per year. */ long int yg = y + days / 365 - (days % 365 < 0); /* Adjust DAYS and Y to match the guessed year. */ days -= ((yg - y) * 365 + LEAPS_THRU_END_OF (yg - 1) - LEAPS_THRU_END_OF (y - 1)); y = yg; } tp->tm_year = y - 1900; if (tp->tm_year != y - 1900) { /* The year cannot be represented due to overflow. */ // __set_errno (EOVERFLOW); return 0; } tp->tm_yday = days; ip = __mon_yday[leapyear(y)]; for (y = 11; days < (long int) ip[y]; --y) continue; days -= ip[y]; tp->tm_mon = y; tp->tm_mday = days + 1; return 1; } /* time_r function implementations */ // G: No time zones in our implementation so just do the converion from gtime_t to struct tm struct gtm * __localtime_r (gtime_t * t, struct gtm * tp) { __offtime(t, 0, tp); return tp; } /* Return an integer value measuring (YEAR1-YDAY1 HOUR1:MIN1:SEC1) - (YEAR0-YDAY0 HOUR0:MIN0:SEC0) in seconds, assuming that the clocks were not adjusted between the time stamps. The YEAR values uses the same numbering as TP->tm_year. Values need not be in the usual range. However, YEAR1 must not be less than 2 * INT_MIN or greater than 2 * INT_MAX. The result may overflow. It is the caller's responsibility to detect overflow. */ static inline gtime_t ydhms_diff (long int year1, long int yday1, int hour1, int min1, int sec1, int year0, int yday0, int hour0, int min0, int sec0) { verify (C99_integer_division, -1 / 2 == 0); verify (long_int_year_and_yday_are_wide_enough, INT_MAX <= LONG_MAX / 2 || TIME_T_MAX <= UINT_MAX); /* Compute intervening leap days correctly even if year is negative. Take care to avoid integer overflow here. */ int a4 = SHR (year1, 2) + SHR (TM_YEAR_BASE, 2) - ! (year1 & 3); int b4 = SHR (year0, 2) + SHR (TM_YEAR_BASE, 2) - ! (year0 & 3); int a100 = a4 / 25 - (a4 % 25 < 0); int b100 = b4 / 25 - (b4 % 25 < 0); int a400 = SHR (a100, 2); int b400 = SHR (b100, 2); int intervening_leap_days = (a4 - b4) - (a100 - b100) + (a400 - b400); /* Compute the desired time in gtime_t precision. Overflow might occur here. */ gtime_t tyear1 = year1; gtime_t years = tyear1 - year0; gtime_t days = 365 * years + yday1 - yday0 + intervening_leap_days; gtime_t hours = 24 * days + hour1 - hour0; gtime_t minutes = 60 * hours + min1 - min0; gtime_t seconds = 60 * minutes + sec1 - sec0; return seconds; } /* Return a gtime_t value corresponding to (YEAR-YDAY HOUR:MIN:SEC), assuming that *T corresponds to *TP and that no clock adjustments occurred between *TP and the desired time. If TP is null, return a value not equal to *T; this avoids false matches. If overflow occurs, yield the minimal or maximal value, except do not yield a value equal to *T. */ static gtime_t guess_time_tm (long int year, long int yday, int hour, int min, int sec, gtime_t *t, struct gtm *tp) { if (tp) { gtime_t d = ydhms_diff (year, yday, hour, min, sec, tp->tm_year, tp->tm_yday, tp->tm_hour, tp->tm_min, tp->tm_sec); gtime_t t1 = *t + d; if ((t1 < *t) == (TYPE_SIGNED (gtime_t) ? d < 0 : TIME_T_MAX / 2 < d)) return t1; } /* Overflow occurred one way or another. Return the nearest result that is actually in range, except don't report a zero difference if the actual difference is nonzero, as that would cause a false match; and don't oscillate between two values, as that would confuse the spring-forward gap detector. */ return (*t < TIME_T_MIDPOINT ? (*t <= TIME_T_MIN + 1 ? *t + 1 : TIME_T_MIN) : (TIME_T_MAX - 1 <= *t ? *t - 1 : TIME_T_MAX)); } /* Use CONVERT to convert *T to a broken down time in *TP. If *T is out of range for conversion, adjust it so that it is the nearest in-range value and then convert that. */ static struct gtm * ranged_convert (struct gtm *(*convert) (gtime_t *, struct gtm *), gtime_t *t, struct gtm *tp) { struct gtm *r = convert (t, tp); if (!r && *t) { gtime_t bad = *t; gtime_t ok = 0; /* BAD is a known unconvertible gtime_t, and OK is a known good one. Use binary search to narrow the range between BAD and OK until they differ by 1. */ while (bad != ok + (bad < 0 ? -1 : 1)) { gtime_t mid = *t = (bad < 0 ? bad + ((ok - bad) >> 1) : ok + ((bad - ok) >> 1)); r = convert (t, tp); if (r) ok = mid; else bad = mid; } if (!r && ok) { /* The last conversion attempt failed; revert to the most recent successful attempt. */ *t = ok; r = convert (t, tp); } } return r; } /* Convert *TP to a gtime_t value, inverting the monotonic and mostly-unit-linear conversion function CONVERT. Use *OFFSET to keep track of a guess at the offset of the result, compared to what the result would be for UTC without leap seconds. If *OFFSET's guess is correct, only one CONVERT call is needed. This function is external because it is used also by timegm.c. */ gtime_t __mktime_internal (struct gtm *tp, struct gtm *(*convert) (gtime_t *, struct gtm *), gtime_t *offset) { gtime_t t, gt, t0, t1, t2; struct gtm tm; /* The maximum number of probes (calls to CONVERT) should be enough to handle any combinations of time zone rule changes, solar time, leap seconds, and oscillations around a spring-forward gap. POSIX.1 prohibits leap seconds, but some hosts have them anyway. */ int remaining_probes = 6; /* Time requested. Copy it in case CONVERT modifies *TP; this can occur if TP is localtime's returned value and CONVERT is localtime. */ int sec = tp->tm_sec; int min = tp->tm_min; int hour = tp->tm_hour; int mday = tp->tm_mday; int mon = tp->tm_mon; int year_requested = tp->tm_year; /* Ensure that mon is in range, and set year accordingly. */ int mon_remainder = mon % 12; int negative_mon_remainder = mon_remainder < 0; int mon_years = mon / 12 - negative_mon_remainder; long int lyear_requested = year_requested; long int year = lyear_requested + mon_years; /* The other values need not be in range: the remaining code handles minor overflows correctly, assuming int and gtime_t arithmetic wraps around. Major overflows are caught at the end. */ /* Calculate day of year from year, month, and day of month. The result need not be in range. */ int mon_yday = ((__mon_yday[leapyear (year)] [mon_remainder + 12 * negative_mon_remainder]) - 1); long int lmday = mday; long int yday = mon_yday + lmday; gtime_t guessed_offset = *offset; int sec_requested = sec; /* if (LEAP_SECONDS_POSSIBLE) { // Handle out-of-range seconds specially, // since ydhms_tm_diff assumes every minute has 60 seconds. if (sec < 0) sec = 0; if (59 < sec) sec = 59; } */ /* Invert CONVERT by probing. First assume the same offset as last time. */ t0 = ydhms_diff (year, yday, hour, min, sec, EPOCH_YEAR - TM_YEAR_BASE, 0, 0, 0, - guessed_offset); if (TIME_T_MAX / INT_MAX / 366 / 24 / 60 / 60 < 3) { /* gtime_t isn't large enough to rule out overflows, so check for major overflows. A gross check suffices, since if t0 has overflowed, it is off by a multiple of TIME_T_MAX - TIME_T_MIN + 1. So ignore any component of the difference that is bounded by a small value. */ /* Approximate log base 2 of the number of time units per biennium. A biennium is 2 years; use this unit instead of years to avoid integer overflow. For example, 2 average Gregorian years are 2 * 365.2425 * 24 * 60 * 60 seconds, which is 63113904 seconds, and rint (log2 (63113904)) is 26. */ int ALOG2_SECONDS_PER_BIENNIUM = 26; int ALOG2_MINUTES_PER_BIENNIUM = 20; int ALOG2_HOURS_PER_BIENNIUM = 14; int ALOG2_DAYS_PER_BIENNIUM = 10; int LOG2_YEARS_PER_BIENNIUM = 1; int approx_requested_biennia = (SHR (year_requested, LOG2_YEARS_PER_BIENNIUM) - SHR (EPOCH_YEAR - TM_YEAR_BASE, LOG2_YEARS_PER_BIENNIUM) + SHR (mday, ALOG2_DAYS_PER_BIENNIUM) + SHR (hour, ALOG2_HOURS_PER_BIENNIUM) + SHR (min, ALOG2_MINUTES_PER_BIENNIUM) + (LEAP_SECONDS_POSSIBLE ? 0 : SHR (sec, ALOG2_SECONDS_PER_BIENNIUM))); int approx_biennia = SHR (t0, ALOG2_SECONDS_PER_BIENNIUM); int diff = approx_biennia - approx_requested_biennia; int abs_diff = diff < 0 ? - diff : diff; /* IRIX 4.0.5 cc miscalculates TIME_T_MIN / 3: it erroneously gives a positive value of 715827882. Setting a variable first then doing math on it seems to work. (ghazi@caip.rutgers.edu) */ gtime_t time_t_max = TIME_T_MAX; gtime_t time_t_min = TIME_T_MIN; gtime_t overflow_threshold = (time_t_max / 3 - time_t_min / 3) >> ALOG2_SECONDS_PER_BIENNIUM; if (overflow_threshold < abs_diff) { /* Overflow occurred. Try repairing it; this might work if the time zone offset is enough to undo the overflow. */ gtime_t repaired_t0 = -1 - t0; approx_biennia = SHR (repaired_t0, ALOG2_SECONDS_PER_BIENNIUM); diff = approx_biennia - approx_requested_biennia; abs_diff = diff < 0 ? - diff : diff; if (overflow_threshold < abs_diff) return -1; guessed_offset += repaired_t0 - t0; t0 = repaired_t0; } } /* Repeatedly use the error to improve the guess. */ for (t = t1 = t2 = t0; (gt = guess_time_tm (year, yday, hour, min, sec, &t, ranged_convert (convert, &t, &tm)), t != gt); t1 = t2, t2 = t, t = gt) if (t == t1 && t != t2) goto offset_found; else if (--remaining_probes == 0) return -1; offset_found: *offset = guessed_offset + t - t0; if (LEAP_SECONDS_POSSIBLE && sec_requested != tm.tm_sec) { /* Adjust time to reflect the tm_sec requested, not the normalized value. Also, repair any damage from a false match due to a leap second. */ int sec_adjustment = (sec == 0 && tm.tm_sec == 60) - sec; t1 = t + sec_requested; t2 = t1 + sec_adjustment; if (((t1 < t) != (sec_requested < 0)) | ((t2 < t1) != (sec_adjustment < 0)) | ! convert (&t2, &tm)) return -1; t = t2; } *tp = tm; return t; } /* Convert *TP to a gtime_t value. */ gtime_t mktime (struct gtm *tp) { // no time zone stuff. Just do the math ;) static gtime_t localtime_offset; return __mktime_internal (tp, __localtime_r, &localtime_offset); } /* Fill a (struct tm) TP* from a given gtime_t time stamp */ gtime_t filltm(gtime_t *t, struct gtm *tp) { return __offtime(t, 0, tp); }