/********************************************************************** time.c - $Author$ $Date$ created at: Tue Dec 28 14:31:59 JST 1993 Copyright (C) 1993-2003 Yukihiro Matsumoto **********************************************************************/ #include "ruby.h" #include #include #ifdef HAVE_UNISTD_H #include #endif #include VALUE rb_cTime; struct time_object { struct timeval tv; struct tm tm; int gmt; int tm_got; }; #define GetTimeval(obj, tobj) \ Data_Get_Struct(obj, struct time_object, tobj) static void time_free _((void *)); static void time_free(tobj) void *tobj; { if (tobj) free(tobj); } static VALUE time_s_alloc _((VALUE)); static VALUE time_s_alloc(klass) VALUE klass; { VALUE obj; struct time_object *tobj; obj = Data_Make_Struct(klass, struct time_object, 0, time_free, tobj); tobj->tm_got=0; tobj->tv.tv_sec = 0; tobj->tv.tv_usec = 0; return obj; } static void time_modify(time) VALUE time; { rb_check_frozen(time); if (!OBJ_TAINTED(time) && rb_safe_level() >= 4) rb_raise(rb_eSecurityError, "Insecure: can't modify Time"); } /* * Document-method: now * * Synonym for Time.new. Returns a +Time+ object * initialized tot he current system time. * * call-seq: * Time.new -> time * * Returns a Time object initialized to the current system * time. Note: The object created will be created using the * resolution available on your system clock, and so may include * fractional seconds. * * a = Time.new #=> Wed Apr 09 08:56:03 CDT 2003 * b = Time.new #=> Wed Apr 09 08:56:03 CDT 2003 * a == b #=> false * "%.6f" % a.to_f #=> "1049896563.230740" * "%.6f" % b.to_f #=> "1049896563.231466" * */ static VALUE time_init(time) VALUE time; { struct time_object *tobj; time_modify(time); GetTimeval(time, tobj); tobj->tm_got=0; tobj->tv.tv_sec = 0; tobj->tv.tv_usec = 0; if (gettimeofday(&tobj->tv, 0) < 0) { rb_sys_fail("gettimeofday"); } return time; } #define NDIV(x,y) (-(-((x)+1)/(y))-1) #define NMOD(x,y) ((y)-(-((x)+1)%(y))-1) static void time_overflow_p(secp, usecp) time_t *secp, *usecp; { time_t tmp, sec = *secp, usec = *usecp; if (usec >= 1000000) { /* usec positive overflow */ tmp = sec + usec / 1000000; usec %= 1000000; if (sec > 0 && tmp < 0) { rb_raise(rb_eRangeError, "out of Time range"); } sec = tmp; } if (usec < 0) { /* usec negative overflow */ tmp = sec + NDIV(usec,1000000); /* negative div */ usec = NMOD(usec,1000000); /* negative mod */ if (sec < 0 && tmp > 0) { rb_raise(rb_eRangeError, "out of Time range"); } sec = tmp; } #ifndef NEGATIVE_TIME_T if (sec < 0 || (sec == 0 && usec < 0)) rb_raise(rb_eArgError, "time must be positive"); #endif *secp = sec; *usecp = usec; } static VALUE time_new_internal(klass, sec, usec) VALUE klass; time_t sec, usec; { VALUE time = time_s_alloc(klass); struct time_object *tobj; GetTimeval(time, tobj); time_overflow_p(&sec, &usec); tobj->tv.tv_sec = sec; tobj->tv.tv_usec = usec; return time; } VALUE rb_time_new(sec, usec) time_t sec, usec; { return time_new_internal(rb_cTime, sec, usec); } static struct timeval time_timeval(time, interval) VALUE time; int interval; { struct timeval t; char *tstr = interval ? "time interval" : "time"; #ifndef NEGATIVE_TIME_T interval = 1; #endif switch (TYPE(time)) { case T_FIXNUM: t.tv_sec = FIX2LONG(time); if (interval && t.tv_sec < 0) rb_raise(rb_eArgError, "%s must be positive", tstr); t.tv_usec = 0; break; case T_FLOAT: if (interval && RFLOAT(time)->value < 0.0) rb_raise(rb_eArgError, "%s must be positive", tstr); else { double f, d; d = modf(RFLOAT(time)->value, &f); t.tv_sec = (time_t)f; if (f != t.tv_sec) { rb_raise(rb_eRangeError, "%f out of Time range", RFLOAT(time)->value); } t.tv_usec = (time_t)(d*1e6); } break; case T_BIGNUM: t.tv_sec = NUM2LONG(time); if (interval && t.tv_sec < 0) rb_raise(rb_eArgError, "%s must be positive", tstr); t.tv_usec = 0; break; default: rb_raise(rb_eTypeError, "can't convert %s into %s", rb_obj_classname(time), tstr); break; } return t; } struct timeval rb_time_interval(time) VALUE time; { return time_timeval(time, Qtrue); } struct timeval rb_time_timeval(time) VALUE time; { struct time_object *tobj; struct timeval t; if (TYPE(time) == T_DATA && RDATA(time)->dfree == time_free) { GetTimeval(time, tobj); t = tobj->tv; return t; } return time_timeval(time, Qfalse); } /* * call-seq: * Time.at( aTime ) => time * Time.at( seconds [, microseconds] ) => time * * Creates a new time object with the value given by aTime, or * the given number of seconds (and optional * microseconds) from epoch. A non-portable feature allows the * offset to be negative on some systems. * * Time.at(0) #=> Wed Dec 31 18:00:00 CST 1969 * Time.at(946702800) #=> Fri Dec 31 23:00:00 CST 1999 * Time.at(-284061600) #=> Sat Dec 31 00:00:00 CST 1960 */ static VALUE time_s_at(argc, argv, klass) int argc; VALUE *argv; VALUE klass; { struct timeval tv; VALUE time, t; if (rb_scan_args(argc, argv, "11", &time, &t) == 2) { tv.tv_sec = NUM2LONG(time); tv.tv_usec = NUM2LONG(t); } else { tv = rb_time_timeval(time); } t = time_new_internal(klass, tv.tv_sec, tv.tv_usec); if (TYPE(time) == T_DATA && RDATA(time)->dfree == time_free) { struct time_object *tobj, *tobj2; GetTimeval(time, tobj); GetTimeval(t, tobj2); tobj2->gmt = tobj->gmt; } return t; } static char *months [12] = { "jan", "feb", "mar", "apr", "may", "jun", "jul", "aug", "sep", "oct", "nov", "dec", }; static long obj2long(obj) VALUE obj; { if (TYPE(obj) == T_STRING) { obj = rb_str_to_inum(obj, 10, Qfalse); } return NUM2LONG(obj); } static void time_arg(argc, argv, tm, usec) int argc; VALUE *argv; struct tm *tm; time_t *usec; { VALUE v[8]; int i; long year; MEMZERO(tm, struct tm, 1); *usec = 0; if (argc == 10) { v[0] = argv[5]; v[1] = argv[4]; v[2] = argv[3]; v[3] = argv[2]; v[4] = argv[1]; v[5] = argv[0]; v[6] = Qnil; tm->tm_isdst = RTEST(argv[8]) ? 1 : 0; } else { rb_scan_args(argc, argv, "17", &v[0],&v[1],&v[2],&v[3],&v[4],&v[5],&v[6],&v[7]); /* v[6] may be usec or zone (parsedate) */ /* v[7] is wday (parsedate; ignored) */ tm->tm_wday = -1; tm->tm_isdst = -1; } year = obj2long(v[0]); if (0 <= year && year < 39) { year += 100; rb_warning("2 digits year is used"); } else if (69 <= year && year < 139) { rb_warning("2 or 3 digits year is used"); } else { year -= 1900; } tm->tm_year = year; if (NIL_P(v[1])) { tm->tm_mon = 0; } else { VALUE s = rb_check_string_type(v[1]); if (!NIL_P(s)) { tm->tm_mon = -1; for (i=0; i<12; i++) { if (RSTRING(s)->len == 3 && strcasecmp(months[i], RSTRING(v[1])->ptr) == 0) { tm->tm_mon = i; break; } } if (tm->tm_mon == -1) { char c = RSTRING(s)->ptr[0]; if ('0' <= c && c <= '9') { tm->tm_mon = obj2long(s)-1; } } } else { tm->tm_mon = obj2long(v[1])-1; } } if (NIL_P(v[2])) { tm->tm_mday = 1; } else { tm->tm_mday = obj2long(v[2]); } tm->tm_hour = NIL_P(v[3])?0:obj2long(v[3]); tm->tm_min = NIL_P(v[4])?0:obj2long(v[4]); tm->tm_sec = NIL_P(v[5])?0:obj2long(v[5]); if (!NIL_P(v[6])) { if (argc == 8) { /* v[6] is timezone, but ignored */ } else if (argc == 7) { *usec = obj2long(v[6]); } } /* value validation */ if ( tm->tm_year != year || #ifndef NEGATIVE_TIME_T tm->tm_year < 69 || #endif tm->tm_mon < 0 || tm->tm_mon > 11 || tm->tm_mday < 1 || tm->tm_mday > 31 || tm->tm_hour < 0 || tm->tm_hour > 23 || tm->tm_min < 0 || tm->tm_min > 59 || tm->tm_sec < 0 || tm->tm_sec > 60) rb_raise(rb_eArgError, "argument out of range"); } static VALUE time_gmtime _((VALUE)); static VALUE time_localtime _((VALUE)); static VALUE time_get_tm _((VALUE, int)); static int leap_year_p(y) long y; { return ((y % 4 == 0) && (y % 100 != 0)) || (y % 400 == 0); } #define DIV(n,d) ((n)<0 ? NDIV((n),(d)) : (n)/(d)) static time_t timegm_noleapsecond(tm) struct tm *tm; { static int common_year_yday_offset[] = { -1, -1 + 31, -1 + 31 + 28, -1 + 31 + 28 + 31, -1 + 31 + 28 + 31 + 30, -1 + 31 + 28 + 31 + 30 + 31, -1 + 31 + 28 + 31 + 30 + 31 + 30, -1 + 31 + 28 + 31 + 30 + 31 + 30 + 31, -1 + 31 + 28 + 31 + 30 + 31 + 30 + 31 + 31, -1 + 31 + 28 + 31 + 30 + 31 + 30 + 31 + 31 + 30, -1 + 31 + 28 + 31 + 30 + 31 + 30 + 31 + 31 + 30 + 31, -1 + 31 + 28 + 31 + 30 + 31 + 30 + 31 + 31 + 30 + 31 + 30 /* 1 2 3 4 5 6 7 8 9 10 11 */ }; static int leap_year_yday_offset[] = { -1, -1 + 31, -1 + 31 + 29, -1 + 31 + 29 + 31, -1 + 31 + 29 + 31 + 30, -1 + 31 + 29 + 31 + 30 + 31, -1 + 31 + 29 + 31 + 30 + 31 + 30, -1 + 31 + 29 + 31 + 30 + 31 + 30 + 31, -1 + 31 + 29 + 31 + 30 + 31 + 30 + 31 + 31, -1 + 31 + 29 + 31 + 30 + 31 + 30 + 31 + 31 + 30, -1 + 31 + 29 + 31 + 30 + 31 + 30 + 31 + 31 + 30 + 31, -1 + 31 + 29 + 31 + 30 + 31 + 30 + 31 + 31 + 30 + 31 + 30 /* 1 2 3 4 5 6 7 8 9 10 11 */ }; long tm_year = tm->tm_year; int tm_yday = tm->tm_mday; if (leap_year_p(tm_year + 1900)) tm_yday += leap_year_yday_offset[tm->tm_mon]; else tm_yday += common_year_yday_offset[tm->tm_mon]; /* * `Seconds Since the Epoch' in SUSv3: * tm_sec + tm_min*60 + tm_hour*3600 + tm_yday*86400 + * (tm_year-70)*31536000 + ((tm_year-69)/4)*86400 - * ((tm_year-1)/100)*86400 + ((tm_year+299)/400)*86400 */ return tm->tm_sec + tm->tm_min*60 + tm->tm_hour*3600 + (time_t)(tm_yday + (tm_year-70)*365 + DIV(tm_year-69,4) - DIV(tm_year-1,100) + DIV(tm_year+299,400))*86400; } static int tmcmp(a, b) struct tm *a; struct tm *b; { if (a->tm_year != b->tm_year) return a->tm_year < b->tm_year ? -1 : 1; else if (a->tm_mon != b->tm_mon) return a->tm_mon < b->tm_mon ? -1 : 1; else if (a->tm_mday != b->tm_mday) return a->tm_mday < b->tm_mday ? -1 : 1; else if (a->tm_hour != b->tm_hour) return a->tm_hour < b->tm_hour ? -1 : 1; else if (a->tm_min != b->tm_min) return a->tm_min < b->tm_min ? -1 : 1; else if (a->tm_sec != b->tm_sec) return a->tm_sec < b->tm_sec ? -1 : 1; else return 0; } static time_t search_time_t(tptr, utc_p) struct tm *tptr; int utc_p; { time_t guess, guess_lo, guess_hi; struct tm *tm, tm_lo, tm_hi; int d, have_guess; int find_dst; find_dst = 0 < tptr->tm_isdst; #ifdef NEGATIVE_TIME_T guess_lo = 1L << (8 * sizeof(time_t) - 1); #else guess_lo = 0; #endif guess_hi = ((time_t)-1) < ((time_t)0) ? (1UL << (8 * sizeof(time_t) - 1)) - 1 : ~(time_t)0; guess = timegm_noleapsecond(tptr); tm = (utc_p ? gmtime : localtime)(&guess); if (tm) { d = tmcmp(tptr, tm); if (d == 0) return guess; if (d < 0) { guess_hi = guess; guess -= 24 * 60 * 60; } else { guess_lo = guess; guess += 24 * 60 * 60; } if (guess_lo < guess && guess < guess_hi && (tm = (utc_p ? gmtime : localtime)(&guess)) != NULL) { d = tmcmp(tptr, tm); if (d == 0) return guess; if (d < 0) guess_hi = guess; else guess_lo = guess; } } tm = (utc_p ? gmtime : localtime)(&guess_lo); if (!tm) goto error; d = tmcmp(tptr, tm); if (d < 0) goto out_of_range; if (d == 0) return guess_lo; tm_lo = *tm; tm = (utc_p ? gmtime : localtime)(&guess_hi); if (!tm) goto error; d = tmcmp(tptr, tm); if (d > 0) goto out_of_range; if (d == 0) return guess_hi; tm_hi = *tm; have_guess = 0; while (guess_lo + 1 < guess_hi) { /* there is a gap between guess_lo and guess_hi. */ unsigned long range = 0; if (!have_guess) { int a, b; /* Try precious guess by a linear interpolation at first. `a' and `b' is a coefficient of guess_lo and guess_hi as: guess = (guess_lo * a + guess_hi * b) / (a + b) However this causes overflow in most cases, following assignment is used instead: guess = guess_lo / d * a + (guess_lo % d) * a / d + guess_hi / d * b + (guess_hi % d) * b / d where d = a + b To avoid overflow in this assignment, `d' is restricted to less than sqrt(2**31). By this restriction and other reasons, the guess is not accurate and some error is expected. `range' approximates the maximum error. When these parameters are not suitable, i.e. guess is not within guess_lo and guess_hi, simple guess by binary search is used. */ range = 366 * 24 * 60 * 60; a = (tm_hi.tm_year - tptr->tm_year); b = (tptr->tm_year - tm_lo.tm_year); /* 46000 is selected as `some big number less than sqrt(2**31)'. */ if (a + b <= 46000 / 12) { range = 31 * 24 * 60 * 60; a *= 12; b *= 12; a += tm_hi.tm_mon - tptr->tm_mon; b += tptr->tm_mon - tm_lo.tm_mon; if (a + b <= 46000 / 31) { range = 24 * 60 * 60; a *= 31; b *= 31; a += tm_hi.tm_mday - tptr->tm_mday; b += tptr->tm_mday - tm_lo.tm_mday; if (a + b <= 46000 / 24) { range = 60 * 60; a *= 24; b *= 24; a += tm_hi.tm_hour - tptr->tm_hour; b += tptr->tm_hour - tm_lo.tm_hour; if (a + b <= 46000 / 60) { range = 60; a *= 60; b *= 60; a += tm_hi.tm_min - tptr->tm_min; b += tptr->tm_min - tm_lo.tm_min; if (a + b <= 46000 / 60) { range = 1; a *= 60; b *= 60; a += tm_hi.tm_sec - tptr->tm_sec; b += tptr->tm_sec - tm_lo.tm_sec; } } } } } if (a <= 0) a = 1; if (b <= 0) b = 1; d = a + b; /* Although `/' and `%' may produce unexpected result with negative argument, it doesn't cause serious problem because there is a fail safe. */ guess = guess_lo / d * a + (guess_lo % d) * a / d + guess_hi / d * b + (guess_hi % d) * b / d; have_guess = 1; } if (guess <= guess_lo || guess_hi <= guess) { /* Precious guess is invalid. try binary search. */ guess = guess_lo / 2 + guess_hi / 2; if (guess <= guess_lo) guess = guess_lo + 1; else if (guess >= guess_hi) guess = guess_hi - 1; range = 0; } tm = (utc_p ? gmtime : localtime)(&guess); if (!tm) goto error; have_guess = 0; d = tmcmp(tptr, tm); if (d < 0) { guess_hi = guess; tm_hi = *tm; if (range) { guess = guess - range; range = 0; if (guess_lo < guess && guess < guess_hi) have_guess = 1; } } else if (d > 0) { guess_lo = guess; tm_lo = *tm; if (range) { guess = guess + range; range = 0; if (guess_lo < guess && guess < guess_hi) have_guess = 1; } } else { if (!utc_p) { /* If localtime is nonmonotonic, another result may exist. */ time_t guess2; if (find_dst) { guess2 = guess - 2 * 60 * 60; tm = localtime(&guess2); if (tm) { if (tptr->tm_hour != (tm->tm_hour + 2) % 24 || tptr->tm_min != tm->tm_min || tptr->tm_sec != tm->tm_sec) { guess2 -= (tm->tm_hour - tptr->tm_hour) * 60 * 60 + (tm->tm_min - tptr->tm_min) * 60 + (tm->tm_sec - tptr->tm_sec); if (tptr->tm_mday != tm->tm_mday) guess2 += 24 * 60 * 60; if (guess != guess2) { tm = localtime(&guess2); if (tmcmp(tptr, tm) == 0) { if (guess < guess2) return guess; else return guess2; } } } } } else { guess2 = guess + 2 * 60 * 60; tm = localtime(&guess2); if (tm) { if ((tptr->tm_hour + 2) % 24 != tm->tm_hour || tptr->tm_min != tm->tm_min || tptr->tm_sec != tm->tm_sec) { guess2 -= (tm->tm_hour - tptr->tm_hour) * 60 * 60 + (tm->tm_min - tptr->tm_min) * 60 + (tm->tm_sec - tptr->tm_sec); if (tptr->tm_mday != tm->tm_mday) guess2 -= 24 * 60 * 60; if (guess != guess2) { tm = localtime(&guess2); if (tmcmp(tptr, tm) == 0) { if (guess < guess2) return guess2; else return guess; } } } } } } return guess; } } /* Given argument has no corresponding time_t. Let's outerpolation. */ if (tm_lo.tm_year == tptr->tm_year && tm_lo.tm_mon == tptr->tm_mon) { return guess_lo + (tptr->tm_mday - tm_lo.tm_mday) * 24 * 60 * 60 + (tptr->tm_hour - tm_lo.tm_hour) * 60 * 60 + (tptr->tm_min - tm_lo.tm_min) * 60 + (tptr->tm_sec - tm_lo.tm_sec); } else if (tm_hi.tm_year == tptr->tm_year && tm_hi.tm_mon == tptr->tm_mon) { return guess_hi + (tptr->tm_mday - tm_hi.tm_mday) * 24 * 60 * 60 + (tptr->tm_hour - tm_hi.tm_hour) * 60 * 60 + (tptr->tm_min - tm_hi.tm_min) * 60 + (tptr->tm_sec - tm_hi.tm_sec); } out_of_range: rb_raise(rb_eArgError, "time out of range"); error: rb_raise(rb_eArgError, "gmtime/localtime error"); return 0; /* not reached */ } static time_t make_time_t(tptr, utc_p) struct tm *tptr; int utc_p; { time_t t; struct tm *tmp, buf; buf = *tptr; if (utc_p) { #if defined(HAVE_TIMEGM) if ((t = timegm(&buf)) != -1) return t; #ifdef NEGATIVE_TIME_T if ((tmp = gmtime(&t)) && tptr->tm_year == tmp->tm_year && tptr->tm_mon == tmp->tm_mon && tptr->tm_mday == tmp->tm_mday && tptr->tm_hour == tmp->tm_hour && tptr->tm_min == tmp->tm_min && tptr->tm_sec == tmp->tm_sec) return t; #endif #endif return search_time_t(&buf, utc_p); } else { #if defined(HAVE_MKTIME) if ((t = mktime(&buf)) != -1) return t; #ifdef NEGATIVE_TIME_T if ((tmp = localtime(&t)) && tptr->tm_year == tmp->tm_year && tptr->tm_mon == tmp->tm_mon && tptr->tm_mday == tmp->tm_mday && tptr->tm_hour == tmp->tm_hour && tptr->tm_min == tmp->tm_min && tptr->tm_sec == tmp->tm_sec) return t; #endif #endif return search_time_t(&buf, utc_p); } } static VALUE time_utc_or_local(argc, argv, utc_p, klass) int argc; VALUE *argv; int utc_p; VALUE klass; { struct tm tm; VALUE time; time_t usec; time_arg(argc, argv, &tm, &usec); time = time_new_internal(klass, make_time_t(&tm, utc_p), usec); if (utc_p) return time_gmtime(time); return time_localtime(time); } /* * call-seq: * Time.utc( year [, month, day, hour, min, sec, usec] ) => time * Time.utc( sec, min, hour, day, month, year, wday, yday, isdst, tz * ) => time * Time.gm( year [, month, day, hour, min, sec, usec] ) => time * Time.gm( sec, min, hour, day, month, year, wday, yday, isdst, tz * ) => time * * Creates a time based on given values, interpreted as UTC (GMT). The * year must be specified. Other values default to the minimum value * for that field (and may be nil or omitted). Months may * be specified by numbers from 1 to 12, or by the three-letter English * month names. Hours are specified on a 24-hour clock (0..23). Raises * an ArgumentError if any values are out of range. Will * also accept ten arguments in the order output by * Time#to_a. * * Time.utc(2000,"jan",1,20,15,1) #=> Sat Jan 01 20:15:01 UTC 2000 * Time.gm(2000,"jan",1,20,15,1) #=> Sat Jan 01 20:15:01 UTC 2000 */ static VALUE time_s_mkutc(argc, argv, klass) int argc; VALUE *argv; VALUE klass; { return time_utc_or_local(argc, argv, Qtrue, klass); } /* * call-seq: * Time.local( year [, month, day, hour, min, sec, usec] ) => time * Time.local( sec, min, hour, day, month, year, wday, yday, isdst, * tz ) => time * Time.mktime( year, month, day, hour, min, sec, usec ) => time * * Same as Time::gm, but interprets the values in the * local time zone. * * Time.local(2000,"jan",1,20,15,1) #=> Sat Jan 01 20:15:01 CST 2000 */ static VALUE time_s_mktime(argc, argv, klass) int argc; VALUE *argv; VALUE klass; { return time_utc_or_local(argc, argv, Qfalse, klass); } /* * call-seq: * time.to_i => int * time.tv_sec => int * * Returns the value of time as an integer number of seconds * since epoch. * * t = Time.now * "%10.5f" % t.to_f #=> "1049896564.17839" * t.to_i #=> 1049896564 */ static VALUE time_to_i(time) VALUE time; { struct time_object *tobj; GetTimeval(time, tobj); return LONG2NUM(tobj->tv.tv_sec); } /* * call-seq: * time.to_f => float * * Returns the value of time as a floating point number of * seconds since epoch. * * t = Time.now * "%10.5f" % t.to_f #=> "1049896564.13654" * t.to_i #=> 1049896564 */ static VALUE time_to_f(time) VALUE time; { struct time_object *tobj; GetTimeval(time, tobj); return rb_float_new((double)tobj->tv.tv_sec+(double)tobj->tv.tv_usec/1e6); } /* * call-seq: * time.usec => int * time.tv_usec => int * * Returns just the number of microseconds for time. * * t = Time.now #=> Wed Apr 09 08:56:04 CDT 2003 * "%10.6f" % t.to_f #=> "1049896564.259970" * t.usec #=> 259970 */ static VALUE time_usec(time) VALUE time; { struct time_object *tobj; GetTimeval(time, tobj); return LONG2NUM(tobj->tv.tv_usec); } /* * call-seq: * time <=> other_time => -1, 0, +1 * time <=> numeric => -1, 0, +1 * * Comparison---Compares time with other_time or with * numeric, which is the number of seconds (possibly * fractional) since epoch. * * t = Time.now #=> Wed Apr 09 08:56:03 CDT 2003 * t2 = t + 2592000 #=> Fri May 09 08:56:03 CDT 2003 * t <=> t2 #=> -1 * t2 <=> t #=> 1 * t <=> t #=> 0 */ static VALUE time_cmp(time1, time2) VALUE time1, time2; { struct time_object *tobj1, *tobj2; GetTimeval(time1, tobj1); if (TYPE(time2) == T_DATA && RDATA(time2)->dfree == time_free) { GetTimeval(time2, tobj2); if (tobj1->tv.tv_sec == tobj2->tv.tv_sec) { if (tobj1->tv.tv_usec == tobj2->tv.tv_usec) return INT2FIX(0); if (tobj1->tv.tv_usec > tobj2->tv.tv_usec) return INT2FIX(1); return INT2FIX(-1); } if (tobj1->tv.tv_sec > tobj2->tv.tv_sec) return INT2FIX(1); return INT2FIX(-1); } return Qnil; } /* * call-seq: * time.eql?(other_time) * * Return true if time and other_time are * both Time objects with the same seconds and fractional * seconds. */ static VALUE time_eql(time1, time2) VALUE time1, time2; { struct time_object *tobj1, *tobj2; GetTimeval(time1, tobj1); if (TYPE(time2) == T_DATA && RDATA(time2)->dfree == time_free) { GetTimeval(time2, tobj2); if (tobj1->tv.tv_sec == tobj2->tv.tv_sec) { if (tobj1->tv.tv_usec == tobj2->tv.tv_usec) return Qtrue; } } return Qfalse; } /* * call-seq: * time.utc? => true or false * time.gmt? => true or false * * Returns true if time represents a time in UTC * (GMT). * * t = Time.now #=> Wed Apr 09 08:56:04 CDT 2003 * t.utc? #=> false * t = Time.gm(2000,"jan",1,20,15,1) #=> Sat Jan 01 20:15:01 UTC 2000 * t.utc? #=> true * * t = Time.now #=> Wed Apr 09 08:56:03 CDT 2003 * t.gmt? #=> false * t = Time.gm(2000,1,1,20,15,1) #=> Sat Jan 01 20:15:01 UTC 2000 * t.gmt? #=> true */ static VALUE time_utc_p(time) VALUE time; { struct time_object *tobj; GetTimeval(time, tobj); if (tobj->gmt) return Qtrue; return Qfalse; } /* * call-seq: * time.hash => fixnum * * Return a hash code for this time object. */ static VALUE time_hash(time) VALUE time; { struct time_object *tobj; long hash; GetTimeval(time, tobj); hash = tobj->tv.tv_sec ^ tobj->tv.tv_usec; return LONG2FIX(hash); } /* :nodoc: */ static VALUE time_init_copy(copy, time) VALUE copy, time; { struct time_object *tobj, *tcopy; if (copy == time) return copy; time_modify(copy); if (TYPE(time) != T_DATA || RDATA(time)->dfree != time_free) { rb_raise(rb_eTypeError, "wrong argument type"); } GetTimeval(time, tobj); GetTimeval(copy, tcopy); MEMCPY(tcopy, tobj, struct time_object, 1); return copy; } static VALUE time_dup(time) VALUE time; { VALUE dup = time_s_alloc(rb_cTime); time_init_copy(dup, time); return dup; } /* * call-seq: * time.localtime => time * * Converts time to local time (using the local time zone in * effect for this process) modifying the receiver. * * t = Time.gm(2000, "jan", 1, 20, 15, 1) * t.gmt? #=> true * t.localtime #=> Sat Jan 01 14:15:01 CST 2000 * t.gmt? #=> false */ static VALUE time_localtime(time) VALUE time; { struct time_object *tobj; struct tm *tm_tmp; time_t t; GetTimeval(time, tobj); if (!tobj->gmt) { if (tobj->tm_got) return time; } else { time_modify(time); } t = tobj->tv.tv_sec; tm_tmp = localtime(&t); if (!tm_tmp) rb_raise(rb_eArgError, "localtime error"); tobj->tm = *tm_tmp; tobj->tm_got = 1; tobj->gmt = 0; return time; } /* * call-seq: * time.gmtime => time * time.utc => time * * Converts time to UTC (GMT), modifying the receiver. * * t = Time.now #=> Wed Apr 09 08:56:03 CDT 2003 * t.gmt? #=> false * t.gmtime #=> Wed Apr 09 13:56:03 UTC 2003 * t.gmt? #=> true * * t = Time.now #=> Wed Apr 09 08:56:04 CDT 2003 * t.utc? #=> false * t.utc #=> Wed Apr 09 13:56:04 UTC 2003 * t.utc? #=> true */ static VALUE time_gmtime(time) VALUE time; { struct time_object *tobj; struct tm *tm_tmp; time_t t; GetTimeval(time, tobj); if (tobj->gmt) { if (tobj->tm_got) return time; } else { time_modify(time); } t = tobj->tv.tv_sec; tm_tmp = gmtime(&t); if (!tm_tmp) rb_raise(rb_eArgError, "gmtime error"); tobj->tm = *tm_tmp; tobj->tm_got = 1; tobj->gmt = 1; return time; } /* * call-seq: * time.getlocal => new_time * * Returns a new new_time object representing time in * local time (using the local time zone in effect for this process). * * t = Time.gm(2000,1,1,20,15,1) #=> Sat Jan 01 20:15:01 UTC 2000 * t.gmt? #=> true * l = t.getlocal #=> Sat Jan 01 14:15:01 CST 2000 * l.gmt? #=> false * t == l #=> true */ static VALUE time_getlocaltime(time) VALUE time; { return time_localtime(time_dup(time)); } /* * call-seq: * time.getgm => new_time * time.getutc => new_time * * Returns a new new_time object representing time in * UTC. * * t = Time.local(2000,1,1,20,15,1) #=> Sat Jan 01 20:15:01 CST 2000 * t.gmt? #=> false * y = t.getgm #=> Sun Jan 02 02:15:01 UTC 2000 * y.gmt? #=> true * t == y #=> true */ static VALUE time_getgmtime(time) VALUE time; { return time_gmtime(time_dup(time)); } static VALUE time_get_tm(time, gmt) VALUE time; int gmt; { if (gmt) return time_gmtime(time); return time_localtime(time); } /* * call-seq: * time.asctime => string * time.ctime => string * * Returns a canonical string representation of time. * * Time.now.asctime #=> "Wed Apr 9 08:56:03 2003" */ static VALUE time_asctime(time) VALUE time; { struct time_object *tobj; char *s; GetTimeval(time, tobj); if (tobj->tm_got == 0) { time_get_tm(time, tobj->gmt); } s = asctime(&tobj->tm); if (s[24] == '\n') s[24] = '\0'; return rb_str_new2(s); } /* * call-seq: * time.inspect => string * time.to_s => string * * Returns a string representing time. Equivalent to calling * Time#strftime with a format string of ``%a * %b %d %H:%M:%S * %Z %Y''. * * Time.now.to_s #=> "Wed Apr 09 08:56:04 CDT 2003" */ static VALUE time_to_s(time) VALUE time; { struct time_object *tobj; char buf[128]; int len; GetTimeval(time, tobj); if (tobj->tm_got == 0) { time_get_tm(time, tobj->gmt); } if (tobj->gmt == 1) { len = strftime(buf, 128, "%a %b %d %H:%M:%S UTC %Y", &tobj->tm); } else { len = strftime(buf, 128, "%a %b %d %H:%M:%S %Z %Y", &tobj->tm); } return rb_str_new(buf, len); } #if SIZEOF_TIME_T == SIZEOF_LONG typedef unsigned long unsigned_time_t; #elif SIZEOF_TIME_T == SIZEOF_INT typedef unsigned int unsigned_time_t; #elif SIZEOF_TIME_T == SIZEOF_LONG_LONG typedef unsigned LONG_LONG unsigned_time_t; #else # error cannot find integer type which size is same as time_t. #endif static VALUE time_add(tobj, offset, sign) struct time_object *tobj; VALUE offset; int sign; { double v = NUM2DBL(offset); double f, d; unsigned_time_t sec_off; time_t usec_off, sec, usec; VALUE result; if (v < 0) { v = -v; sign = -sign; } d = modf(v, &f); sec_off = (unsigned_time_t)f; if (f != (double)sec_off) rb_raise(rb_eRangeError, "time %s %f out of Time range", sign < 0 ? "-" : "+", v); usec_off = (time_t)(d*1e6); if (sign < 0) { sec = tobj->tv.tv_sec - sec_off; usec = tobj->tv.tv_usec - usec_off; if (sec > tobj->tv.tv_sec) rb_raise(rb_eRangeError, "time - %f out of Time range", v); } else { sec = tobj->tv.tv_sec + sec_off; usec = tobj->tv.tv_usec + usec_off; if (sec < tobj->tv.tv_sec) rb_raise(rb_eRangeError, "time + %f out of Time range", v); } result = rb_time_new(sec, usec); if (tobj->gmt) { GetTimeval(result, tobj); tobj->gmt = 1; } return result; } /* * call-seq: * time + numeric => time * * Addition---Adds some number of seconds (possibly fractional) to * time and returns that value as a new time. * * t = Time.now #=> Wed Apr 09 08:56:03 CDT 2003 * t + (60 * 60 * 24) #=> Thu Apr 10 08:56:03 CDT 2003 */ static VALUE time_plus(time1, time2) VALUE time1, time2; { struct time_object *tobj; GetTimeval(time1, tobj); if (TYPE(time2) == T_DATA && RDATA(time2)->dfree == time_free) { rb_raise(rb_eTypeError, "time + time?"); } return time_add(tobj, time2, 1); } /* * call-seq: * time - other_time => float * time - numeric => time * * Difference---Returns a new time that represents the difference * between two times, or subtracts the given number of seconds in * numeric from time. * * t = Time.now #=> Wed Apr 09 08:56:03 CDT 2003 * t2 = t + 2592000 #=> Fri May 09 08:56:03 CDT 2003 * t2 - t #=> 2592000.0 * t2 - 2592000 #=> Wed Apr 09 08:56:03 CDT 2003 */ static VALUE time_minus(time1, time2) VALUE time1, time2; { struct time_object *tobj; GetTimeval(time1, tobj); if (TYPE(time2) == T_DATA && RDATA(time2)->dfree == time_free) { struct time_object *tobj2; double f; GetTimeval(time2, tobj2); f = (double)tobj->tv.tv_sec - (double)tobj2->tv.tv_sec; f += ((double)tobj->tv.tv_usec - (double)tobj2->tv.tv_usec)*1e-6; /* XXX: should check float overflow on 64bit time_t platforms */ return rb_float_new(f); } return time_add(tobj, time2, -1); } /* * call-seq: * time.succ => new_time * * Return a new time object, one second later than time. */ static VALUE time_succ(time) VALUE time; { struct time_object *tobj; GetTimeval(time, tobj); return rb_time_new(tobj->tv.tv_sec + 1, tobj->tv.tv_usec); } /* * call-seq: * time.sec => fixnum * * Returns the second of the minute (0..60)[Yes, seconds really can * range from zero to 60. This allows the system to inject leap seconds * every now and then to correct for the fact that years are not really * a convenient number of hours long.] for time. * * t = Time.now #=> Wed Apr 09 08:56:04 CDT 2003 * t.sec #=> 4 */ static VALUE time_sec(time) VALUE time; { struct time_object *tobj; GetTimeval(time, tobj); if (tobj->tm_got == 0) { time_get_tm(time, tobj->gmt); } return INT2FIX(tobj->tm.tm_sec); } /* * call-seq: * time.min => fixnum * * Returns the minute of the hour (0..59) for time. * * t = Time.now #=> Wed Apr 09 08:56:03 CDT 2003 * t.min #=> 56 */ static VALUE time_min(time) VALUE time; { struct time_object *tobj; GetTimeval(time, tobj); if (tobj->tm_got == 0) { time_get_tm(time, tobj->gmt); } return INT2FIX(tobj->tm.tm_min); } /* * call-seq: * time.hour => fixnum * * Returns the hour of the day (0..23) for time. * * t = Time.now #=> Wed Apr 09 08:56:03 CDT 2003 * t.hour #=> 8 */ static VALUE time_hour(time) VALUE time; { struct time_object *tobj; GetTimeval(time, tobj); if (tobj->tm_got == 0) { time_get_tm(time, tobj->gmt); } return INT2FIX(tobj->tm.tm_hour); } /* * call-seq: * time.day => fixnum * time.mday => fixnum * * Returns the day of the month (1..n) for time. * * t = Time.now #=> Wed Apr 09 08:56:03 CDT 2003 * t.day #=> 9 * t.mday #=> 9 */ static VALUE time_mday(time) VALUE time; { struct time_object *tobj; GetTimeval(time, tobj); if (tobj->tm_got == 0) { time_get_tm(time, tobj->gmt); } return INT2FIX(tobj->tm.tm_mday); } /* * call-seq: * time.mon => fixnum * time.month => fixnum * * Returns the month of the year (1..12) for time. * * t = Time.now #=> Wed Apr 09 08:56:03 CDT 2003 * t.mon #=> 4 * t.month #=> 4 */ static VALUE time_mon(time) VALUE time; { struct time_object *tobj; GetTimeval(time, tobj); if (tobj->tm_got == 0) { time_get_tm(time, tobj->gmt); } return INT2FIX(tobj->tm.tm_mon+1); } /* * call-seq: * time.year => fixnum * * Returns the year for time (including the century). * * t = Time.now #=> Wed Apr 09 08:56:04 CDT 2003 * t.year #=> 2003 */ static VALUE time_year(time) VALUE time; { struct time_object *tobj; GetTimeval(time, tobj); if (tobj->tm_got == 0) { time_get_tm(time, tobj->gmt); } return LONG2NUM((long)tobj->tm.tm_year+1900); } /* * call-seq: * time.wday => fixnum * * Returns an integer representing the day of the week, 0..6, with * Sunday == 0. * * t = Time.now #=> Wed Apr 09 08:56:04 CDT 2003 * t.wday #=> 3 */ static VALUE time_wday(time) VALUE time; { struct time_object *tobj; GetTimeval(time, tobj); if (tobj->tm_got == 0) { time_get_tm(time, tobj->gmt); } return INT2FIX(tobj->tm.tm_wday); } /* * call-seq: * time.yday => fixnum * * Returns an integer representing the day of the year, 1..366. * * t = Time.now #=> Wed Apr 09 08:56:04 CDT 2003 * t.yday #=> 99 */ static VALUE time_yday(time) VALUE time; { struct time_object *tobj; GetTimeval(time, tobj); if (tobj->tm_got == 0) { time_get_tm(time, tobj->gmt); } return INT2FIX(tobj->tm.tm_yday+1); } /* * call-seq: * time.isdst => true or false * time.dst? => true or false * * Returns true if time occurs during Daylight * Saving Time in its time zone. * * Time.local(2000, 7, 1).isdst #=> true * Time.local(2000, 1, 1).isdst #=> false * Time.local(2000, 7, 1).dst? #=> true * Time.local(2000, 1, 1).dst? #=> false */ static VALUE time_isdst(time) VALUE time; { struct time_object *tobj; GetTimeval(time, tobj); if (tobj->tm_got == 0) { time_get_tm(time, tobj->gmt); } return tobj->tm.tm_isdst?Qtrue:Qfalse; } /* * call-seq: * time.zone => string * * Returns the name of the time zone used for time. As of Ruby * 1.8, returns ``UTC'' rather than ``GMT'' for UTC times. * * t = Time.gm(2000, "jan", 1, 20, 15, 1) * t.zone #=> "UTC" * t = Time.local(2000, "jan", 1, 20, 15, 1) * t.zone #=> "CST" */ static VALUE time_zone(time) VALUE time; { struct time_object *tobj; #if !defined(HAVE_TM_ZONE) && (!defined(HAVE_TZNAME) || !defined(HAVE_DAYLIGHT)) char buf[64]; int len; #endif GetTimeval(time, tobj); if (tobj->tm_got == 0) { time_get_tm(time, tobj->gmt); } if (tobj->gmt == 1) { return rb_str_new2("UTC"); } #if defined(HAVE_TM_ZONE) return rb_str_new2(tobj->tm.tm_zone); #elif defined(HAVE_TZNAME) && defined(HAVE_DAYLIGHT) return rb_str_new2(tzname[daylight && tobj->tm.tm_isdst]); #else len = strftime(buf, 64, "%Z", &tobj->tm); return rb_str_new(buf, len); #endif } /* * call-seq: * time.gmt_offset => fixnum * time.gmtoff => fixnum * time.utc_offset => fixnum * * Returns the offset in seconds between the timezone of time * and UTC. * * t = Time.gm(2000,1,1,20,15,1) #=> Sat Jan 01 20:15:01 UTC 2000 * t.gmt_offset #=> 0 * l = t.getlocal #=> Sat Jan 01 14:15:01 CST 2000 * l.gmt_offset #=> -21600 */ static VALUE time_utc_offset(time) VALUE time; { struct time_object *tobj; GetTimeval(time, tobj); if (tobj->tm_got == 0) { time_get_tm(time, tobj->gmt); } if (tobj->gmt == 1) { return INT2FIX(0); } else { #if defined(HAVE_STRUCT_TM_TM_GMTOFF) return INT2NUM(tobj->tm.tm_gmtoff); #else struct tm *u, *l; time_t t; long off; l = &tobj->tm; t = tobj->tv.tv_sec; u = gmtime(&t); if (!u) rb_raise(rb_eArgError, "gmtime error"); if (l->tm_year != u->tm_year) off = l->tm_year < u->tm_year ? -1 : 1; else if (l->tm_mon != u->tm_mon) off = l->tm_mon < u->tm_mon ? -1 : 1; else if (l->tm_mday != u->tm_mday) off = l->tm_mday < u->tm_mday ? -1 : 1; else off = 0; off = off * 24 + l->tm_hour - u->tm_hour; off = off * 60 + l->tm_min - u->tm_min; off = off * 60 + l->tm_sec - u->tm_sec; return LONG2FIX(off); #endif } } /* * call-seq: * time.to_a => array * * Returns a ten-element array of values for time: * {

[ sec, min, hour, day, month, year, wday, yday, isdst, zone
 *  ]

}. See the individual methods for an explanation of the * valid ranges of each value. The ten elements can be passed directly * to Time::utc or Time::local to create a * new Time. * * now = Time.now #=> Wed Apr 09 08:56:04 CDT 2003 * t = now.to_a #=> [4, 56, 8, 9, 4, 2003, 3, 99, true, "CDT"] */ static VALUE time_to_a(time) VALUE time; { struct time_object *tobj; GetTimeval(time, tobj); if (tobj->tm_got == 0) { time_get_tm(time, tobj->gmt); } return rb_ary_new3(10, INT2FIX(tobj->tm.tm_sec), INT2FIX(tobj->tm.tm_min), INT2FIX(tobj->tm.tm_hour), INT2FIX(tobj->tm.tm_mday), INT2FIX(tobj->tm.tm_mon+1), LONG2NUM((long)tobj->tm.tm_year+1900), INT2FIX(tobj->tm.tm_wday), INT2FIX(tobj->tm.tm_yday+1), tobj->tm.tm_isdst?Qtrue:Qfalse, time_zone(time)); } #define SMALLBUF 100 static int rb_strftime(buf, format, time) char **buf; const char *format; struct tm *time; { int size, len, flen; (*buf)[0] = '\0'; flen = strlen(format); if (flen == 0) { return 0; } len = strftime(*buf, SMALLBUF, format, time); if (len != 0 || **buf == '\0') return len; for (size=1024; ; size*=2) { *buf = xmalloc(size); (*buf)[0] = '\0'; len = strftime(*buf, size, format, time); /* * buflen can be zero EITHER because there's not enough * room in the string, or because the control command * goes to the empty string. Make a reasonable guess that * if the buffer is 1024 times bigger than the length of the * format string, it's not failing for lack of room. */ if (len > 0 || size >= 1024 * flen) return len; free(*buf); } /* not reached */ } /* * call-seq: * time.strftime( string ) => string * * Formats time according to the directives in the given format * string. Any text not listed as a directive will be passed through * to the output string. * * Format meaning: * %a - The abbreviated weekday name (``Sun'') * %A - The full weekday name (``Sunday'') * %b - The abbreviated month name (``Jan'') * %B - The full month name (``January'') * %c - The preferred local date and time representation * %d - Day of the month (01..31) * %H - Hour of the day, 24-hour clock (00..23) * %I - Hour of the day, 12-hour clock (01..12) * %j - Day of the year (001..366) * %m - Month of the year (01..12) * %M - Minute of the hour (00..59) * %p - Meridian indicator (``AM'' or ``PM'') * %S - Second of the minute (00..60) * %U - Week number of the current year, * starting with the first Sunday as the first * day of the first week (00..53) * %W - Week number of the current year, * starting with the first Monday as the first * day of the first week (00..53) * %w - Day of the week (Sunday is 0, 0..6) * %x - Preferred representation for the date alone, no time * %X - Preferred representation for the time alone, no date * %y - Year without a century (00..99) * %Y - Year with century * %Z - Time zone name * %% - Literal ``%'' character * * t = Time.now * t.strftime("Printed on %m/%d/%Y") #=> "Printed on 04/09/2003" * t.strftime("at %I:%M%p") #=> "at 08:56AM" */ static VALUE time_strftime(time, format) VALUE time, format; { struct time_object *tobj; char buffer[SMALLBUF], *buf = buffer; const char *fmt; long len; VALUE str; GetTimeval(time, tobj); if (tobj->tm_got == 0) { time_get_tm(time, tobj->gmt); } StringValue(format); format = rb_str_new4(format); fmt = RSTRING(format)->ptr; len = RSTRING(format)->len; if (len == 0) { rb_warning("strftime called with empty format string"); } else if (strlen(fmt) < len) { /* Ruby string may contain \0's. */ const char *p = fmt, *pe = fmt + len; str = rb_str_new(0, 0); while (p < pe) { len = rb_strftime(&buf, p, &tobj->tm); rb_str_cat(str, buf, len); p += strlen(p) + 1; if (buf != buffer) { free(buf); buf = buffer; } for (fmt = p; p < pe && !*p; ++p); if (p > fmt) rb_str_cat(str, fmt, p - fmt); } return str; } else { len = rb_strftime(&buf, RSTRING(format)->ptr, &tobj->tm); } str = rb_str_new(buf, len); if (buf != buffer) free(buf); return str; } /* * call-seq: * Time.times => struct_tms * * Deprecated in favor of Process::times */ static VALUE time_s_times(obj) VALUE obj; { rb_warn("obsolete method Time::times; use Process::times"); return rb_proc_times(obj); } /* * undocumented */ static VALUE time_mdump(time) VALUE time; { struct time_object *tobj; struct tm *tm; unsigned long p, s; char buf[8]; time_t t; int i; GetTimeval(time, tobj); t = tobj->tv.tv_sec; tm = gmtime(&t); if ((tm->tm_year & 0xffff) != tm->tm_year) rb_raise(rb_eArgError, "year too big to marshal"); p = 0x1 << 31 | /* 1 */ tm->tm_year << 14 | /* 16 */ tm->tm_mon << 10 | /* 4 */ tm->tm_mday << 5 | /* 5 */ tm->tm_hour; /* 5 */ s = tm->tm_min << 26 | /* 6 */ tm->tm_sec << 20 | /* 6 */ tobj->tv.tv_usec; /* 20 */ for (i=0; i<4; i++) { buf[i] = p & 0xff; p = RSHIFT(p, 8); } for (i=4; i<8; i++) { buf[i] = s & 0xff; s = RSHIFT(s, 8); } return rb_str_new(buf, 8); } /* * call-seq: * time._dump => string * * Dump _time_ for marshaling. */ static VALUE time_dump(argc, argv, time) int argc; VALUE *argv; VALUE time; { VALUE str; rb_scan_args(argc, argv, "01", 0); str = time_mdump(time); if (FL_TEST(time, FL_EXIVAR)) { rb_copy_generic_ivar(str, time); FL_SET(str, FL_EXIVAR); } return str; } /* * undocumented */ static VALUE time_mload(time, str) VALUE time, str; { struct time_object *tobj; unsigned long p, s; time_t sec, usec; unsigned char *buf; struct tm tm; int i; time_modify(time); StringValue(str); buf = (unsigned char *)RSTRING(str)->ptr; if (RSTRING(str)->len != 8) { rb_raise(rb_eTypeError, "marshaled time format differ"); } p = s = 0; for (i=0; i<4; i++) { p |= buf[i]<<(8*i); } for (i=4; i<8; i++) { s |= buf[i]<<(8*(i-4)); } if ((p & (1<<31)) == 0) { sec = p; usec = s; } else { p &= ~(1<<31); tm.tm_year = (p >> 14) & 0xffff; tm.tm_mon = (p >> 10) & 0xf; tm.tm_mday = (p >> 5) & 0x1f; tm.tm_hour = p & 0x1f; tm.tm_min = (s >> 26) & 0x3f; tm.tm_sec = (s >> 20) & 0x3f; tm.tm_isdst = 0; sec = make_time_t(&tm, Qtrue); usec = (time_t)(s & 0xfffff); } time_overflow_p(&sec, &usec); GetTimeval(time, tobj); tobj->tm_got = 0; tobj->tv.tv_sec = sec; tobj->tv.tv_usec = usec; return time; } /* * call-seq: * Time._load(string) => time * * Unmarshal a dumped +Time+ object. */ static VALUE time_load(klass, str) VALUE klass, str; { VALUE time = time_s_alloc(klass); if (FL_TEST(str, FL_EXIVAR)) { rb_copy_generic_ivar(time, str); FL_SET(time, FL_EXIVAR); } time_mload(time, str); return time; } /* * Time is an abstraction of dates and times. Time is * stored internally as the number of seconds and microseconds since * the epoch, January 1, 1970 00:00 UTC. On some operating * systems, this offset is allowed to be negative. Also see the * library modules Date and ParseDate. The * Time class treats GMT (Greenwich Mean Time) and UTC * (Coordinated Universal Time)[Yes, UTC really does stand for * Coordinated Universal Time. There was a committee involved.] * as equivalent. GMT is the older way of referring to these * baseline times but persists in the names of calls on Posix * systems. * * All times are stored with some number of microseconds. Be aware of * this fact when comparing times with each other---times that are * apparently equal when displayed may be different when compared. */ void Init_Time() { rb_cTime = rb_define_class("Time", rb_cObject); rb_include_module(rb_cTime, rb_mComparable); rb_define_alloc_func(rb_cTime, time_s_alloc); rb_define_singleton_method(rb_cTime, "now", rb_class_new_instance, -1); rb_define_singleton_method(rb_cTime, "at", time_s_at, -1); rb_define_singleton_method(rb_cTime, "utc", time_s_mkutc, -1); rb_define_singleton_method(rb_cTime, "gm", time_s_mkutc, -1); rb_define_singleton_method(rb_cTime, "local", time_s_mktime, -1); rb_define_singleton_method(rb_cTime, "mktime", time_s_mktime, -1); rb_define_singleton_method(rb_cTime, "times", time_s_times, 0); rb_define_method(rb_cTime, "to_i", time_to_i, 0); rb_define_method(rb_cTime, "to_f", time_to_f, 0); rb_define_method(rb_cTime, "<=>", time_cmp, 1); rb_define_method(rb_cTime, "eql?", time_eql, 1); rb_define_method(rb_cTime, "hash", time_hash, 0); rb_define_method(rb_cTime, "initialize", time_init, 0); rb_define_method(rb_cTime, "initialize_copy", time_init_copy, 1); rb_define_method(rb_cTime, "localtime", time_localtime, 0); rb_define_method(rb_cTime, "gmtime", time_gmtime, 0); rb_define_method(rb_cTime, "utc", time_gmtime, 0); rb_define_method(rb_cTime, "getlocal", time_getlocaltime, 0); rb_define_method(rb_cTime, "getgm", time_getgmtime, 0); rb_define_method(rb_cTime, "getutc", time_getgmtime, 0); rb_define_method(rb_cTime, "ctime", time_asctime, 0); rb_define_method(rb_cTime, "asctime", time_asctime, 0); rb_define_method(rb_cTime, "to_s", time_to_s, 0); rb_define_method(rb_cTime, "inspect", time_to_s, 0); rb_define_method(rb_cTime, "to_a", time_to_a, 0); rb_define_method(rb_cTime, "+", time_plus, 1); rb_define_method(rb_cTime, "-", time_minus, 1); rb_define_method(rb_cTime, "succ", time_succ, 0); rb_define_method(rb_cTime, "sec", time_sec, 0); rb_define_method(rb_cTime, "min", time_min, 0); rb_define_method(rb_cTime, "hour", time_hour, 0); rb_define_method(rb_cTime, "mday", time_mday, 0); rb_define_method(rb_cTime, "day", time_mday, 0); rb_define_method(rb_cTime, "mon", time_mon, 0); rb_define_method(rb_cTime, "month", time_mon, 0); rb_define_method(rb_cTime, "year", time_year, 0); rb_define_method(rb_cTime, "wday", time_wday, 0); rb_define_method(rb_cTime, "yday", time_yday, 0); rb_define_method(rb_cTime, "isdst", time_isdst, 0); rb_define_method(rb_cTime, "dst?", time_isdst, 0); rb_define_method(rb_cTime, "zone", time_zone, 0); rb_define_method(rb_cTime, "gmtoff", time_utc_offset, 0); rb_define_method(rb_cTime, "gmt_offset", time_utc_offset, 0); rb_define_method(rb_cTime, "utc_offset", time_utc_offset, 0); rb_define_method(rb_cTime, "utc?", time_utc_p, 0); rb_define_method(rb_cTime, "gmt?", time_utc_p, 0); rb_define_method(rb_cTime, "tv_sec", time_to_i, 0); rb_define_method(rb_cTime, "tv_usec", time_usec, 0); rb_define_method(rb_cTime, "usec", time_usec, 0); rb_define_method(rb_cTime, "strftime", time_strftime, 1); /* methods for marshaling */ rb_define_method(rb_cTime, "_dump", time_dump, -1); rb_define_singleton_method(rb_cTime, "_load", time_load, 1); #if 0 /* Time will support marshal_dump and marshal_load in the future (1.9 maybe) */ rb_define_method(rb_cTime, "marshal_dump", time_mdump, 0); rb_define_method(rb_cTime, "marshal_load", time_mload, 1); #endif }