Annotation of OpenXM_contrib/gnuplot/time.c, Revision 1.1.1.2
1.1 maekawa 1: #ifndef lint
1.1.1.2 ! maekawa 2: static char *RCSid = "$Id: time.c,v 1.5.2.1 1999/08/19 14:35:30 lhecking Exp $";
1.1 maekawa 3: #endif
4:
5: /* GNUPLOT - time.c */
6:
7: /*[
8: * Copyright 1986 - 1993, 1998 Thomas Williams, Colin Kelley
9: *
10: * Permission to use, copy, and distribute this software and its
11: * documentation for any purpose with or without fee is hereby granted,
12: * provided that the above copyright notice appear in all copies and
13: * that both that copyright notice and this permission notice appear
14: * in supporting documentation.
15: *
16: * Permission to modify the software is granted, but not the right to
17: * distribute the complete modified source code. Modifications are to
18: * be distributed as patches to the released version. Permission to
19: * distribute binaries produced by compiling modified sources is granted,
20: * provided you
21: * 1. distribute the corresponding source modifications from the
22: * released version in the form of a patch file along with the binaries,
23: * 2. add special version identification to distinguish your version
24: * in addition to the base release version number,
25: * 3. provide your name and address as the primary contact for the
26: * support of your modified version, and
27: * 4. retain our contact information in regard to use of the base
28: * software.
29: * Permission to distribute the released version of the source code along
30: * with corresponding source modifications in the form of a patch file is
31: * granted with same provisions 2 through 4 for binary distributions.
32: *
33: * This software is provided "as is" without express or implied warranty
34: * to the extent permitted by applicable law.
35: ]*/
36:
37:
38: /* some systems may not implement time very well ; in particular,
39: * things might break as the year 2000 approaches.
40: * This module either adds a routine gstrptime() to read a formatted time,
41: * augmenting the standard suite of time routines provided by ansi,
42: * or it completely replaces the whole lot with a new set of routines,
43: * which count time relative to the year 2000. Default is to use the
44: * new routines. define USE_SYSTEM_TIME to use the system routines, at your
45: * own risk. One problem in particular is that not all systems allow
46: * the time with integer value 0 to be represented symbolically, which
47: * prevents use of relative times.
48: */
49:
50:
51: #include "plot.h"
52:
53: /* build as a standalone test */
54:
55: #ifdef TEST_TIME
56:
57: # ifdef HAVE_SYS_TIMEB_H
58: # include <sys/timeb.h>
59: #else
60: /* declare struct timeb */
61: extern int ftime(struct timeb *);
62: #endif
63:
64: # define int_error(x,y) fprintf(stderr, "Error: " x "\n")
65: # define int_warn(x,y) fprintf(stderr, "Warn: " x "\n")
66:
67: /* need (only) these from plot.h */
68: # define ZERO_YEAR 2000
69: /* 1st jan, 2000 is a Saturday (cal 1 2000 on unix) */
70: # define JAN_FIRST_WDAY 6
71:
72: /* zero gnuplot (2000) - zero system (1970) */
73: # define SEC_OFFS_SYS 946684800.0
74:
75: /* avg, incl. leap year */
76: # define YEAR_SEC 31557600.0
77:
78: /* YEAR_SEC / 12 */
79: # define MON_SEC 2629800.0
80:
81: # define WEEK_SEC 604800.0
82: # define DAY_SEC 86400.0
83:
84: /*forward decls */
85: extern char *abbrev_month_names[];
86: extern char *full_month_names[];
87: extern char *abbrev_day_names[];
88: extern char *full_day_names[];
89:
90: #else /* TEST_TIME */
91:
92: # include "setshow.h" /* for month names etc */
93:
94: #endif /* TEST_TIME */
95:
96: static char *read_int __PROTO((char *s, int nr, int *d));
97: static int gdysize __PROTO((int yr));
98:
99:
100: static char *
101: read_int(s, nr, d)
102: char *s;
103: int nr, *d;
104: {
105: int result = 0;
106:
107: while (--nr >= 0 && *s >= '0' && *s <= '9')
108: result = result * 10 + (*s++ - '0');
109:
110: *d = result;
111: return (s);
112: }
113:
114:
115:
116: #ifndef USE_SYSTEM_TIME
117:
118: /* a new set of routines to completely replace the ansi ones
119: * Use at your own risk
120: */
121:
122:
123: static int mndday[12] =
124: {31, 28, 31, 30, 31, 30, 31, 31, 30, 31, 30, 31};
125:
126: static int xstrftime __PROTO((char *buf, int bufsz, char *fmt, struct tm * tm));
127:
128: /* days in year */
129: static int gdysize(yr)
130: int yr;
131: {
132:
133: if (!(yr % 4)) {
134: if ((!(yr % 100)) && yr % 400)
135: return (365);
136: return (366);
137: }
138: return (365);
139: }
140:
141:
142: /* new strptime() and gmtime() to allow time to be read as 24 hour,
143: * and spaces in the format string. time is converted to seconds from
144: * year 2000.... */
145:
146: char *
147: gstrptime(s, fmt, tm)
148: char *s;
149: char *fmt;
150: struct tm *tm;
151: {
152: int yday, date;
153:
154: date = yday = 0;
155: tm->tm_mday = 1;
156: tm->tm_mon = tm->tm_hour = tm->tm_min = tm->tm_sec = 0;
157: /* make relative times work (user-defined tic step) */
158: tm->tm_year = ZERO_YEAR;
159:
160: /* we do not yet calculate wday or yday, so make them illegal
161: * [but yday will be read by %j]
162: */
163:
164: tm->tm_yday = tm->tm_wday = -1;
165:
166: while (*fmt) {
167: if (*fmt != '%') {
168: if (*fmt == ' ') {
169: /* space in format means zero or more spaces in input */
170: while (*s == ' ')
171: ++s;
172: ++fmt;
173: continue;
174: } else if (*fmt == *s) {
175: ++s;
176: ++fmt;
177: continue;
178: } else
179: break; /* literal match has failed */
180: }
181: /* we are processing a percent escape */
182:
183: switch (*++fmt) {
184: case 'b': /* abbreviated month name */
185: {
186: int m;
187: for (m = 0; m < 12; ++m)
188: if (strnicmp(s, abbrev_month_names[m], strlen(abbrev_month_names[m])) == 0) {
189: s += strlen(abbrev_month_names[m]);
190: goto found_abbrev_mon;
191: }
192: /* get here => not found */
193: int_warn("Bad abbreviated month name", NO_CARET);
194: m = 0;
195: found_abbrev_mon:
196: tm->tm_mon = m;
197: break;
198: }
199:
200: case 'B': /* full month name */
201: {
202: int m;
203: for (m = 0; m < 12; ++m)
204: if (strnicmp(s, full_month_names[m], strlen(full_month_names[m])) == 0) {
205: s += strlen(full_month_names[m]);
206: goto found_full_mon;
207: }
208: /* get here => not found */
209: int_warn("Bad full month name", NO_CARET);
210: m = 0;
211: found_full_mon:
212: tm->tm_mon = m;
213: break;
214: }
215:
216: case 'd': /* read a day of month */
217: s = read_int(s, 2, &tm->tm_mday);
218: date++;
219: break;
220:
221: case 'm': /* month number */
222: s = read_int(s, 2, &tm->tm_mon);
223: date++;
224: --tm->tm_mon;
225: break;
226:
227: case 'y': /* year number */
228: s = read_int(s, 2, &tm->tm_year);
1.1.1.2 ! maekawa 229: /* In line with the current UNIX98 specification by
! 230: * The Open Group and major Unix vendors,
! 231: * two-digit years 69-99 refer to the 20th century, and
! 232: * values in the range 00-68 refer to the 21st century.
! 233: */
! 234: if (tm->tm_year <= 68)
! 235: tm->tm_year += 100;
1.1 maekawa 236: date++;
237: tm->tm_year += 1900;
238: break;
239:
240: case 'Y':
241: s = read_int(s, 4, &tm->tm_year);
242: date++;
243: /* tm->tm_year -= 1900; */
244: /* HOE tm->tm_year %= 100; */
245: break;
246:
247: case 'j':
248: s = read_int(s, 3, &tm->tm_yday);
249: tm->tm_yday--;
250: date++;
251: yday++;
252: break;
253:
254: case 'H':
255: s = read_int(s, 2, &tm->tm_hour);
256: break;
257:
258: case 'M':
259: s = read_int(s, 2, &tm->tm_min);
260: break;
261:
262: case 'S':
263: s = read_int(s, 2, &tm->tm_sec);
264: break;
265:
266: default:
267: int_warn("Bad time format in string", NO_CARET);
268: }
269: fmt++;
270: }
271:
272: FPRINTF((stderr, "read date-time : %d/%d/%d:%d:%d:%d\n", tm->tm_mday, tm->tm_mon + 1, tm->tm_year, tm->tm_hour, tm->tm_min, tm->tm_sec));
273:
274: /* now check the date/time entered, normalising if necessary
275: * read_int cannot read a -ve number, but can read %m=0 then decrement
276: * it to -1
277: */
278:
279: #define S (tm->tm_sec)
280: #define M (tm->tm_min)
281: #define H (tm->tm_hour)
282:
283: if (S >= 60) {
284: M += S / 60;
285: S %= 60;
286: }
287: if (M >= 60) {
288: H += M / 60;
289: M %= 60;
290: }
291: if (H >= 24) {
292: if (yday)
293: tm->tm_yday += H / 24;
294: tm->tm_mday += H / 24;
295: H %= 24;
296: }
297: #undef S
298: #undef M
299: #undef H
300:
301: FPRINTF((stderr, "normalised time : %d/%d/%d:%d:%d:%d\n", tm->tm_mday, tm->tm_mon + 1, tm->tm_year, tm->tm_hour, tm->tm_min, tm->tm_sec));
302:
303: if (date) {
304: if (yday) {
305:
306: if (tm->tm_yday < 0)
307: int_error("Illegal day of year", NO_CARET);
308:
309: /* we just set month to jan, day to yday, and let the
310: * normalising code do the work.
311: */
312:
313: tm->tm_mon = 0;
314: /* yday is 0->365, day is 1->31 */
315: tm->tm_mday = tm->tm_yday + 1;
316: }
317: if (tm->tm_mon < 0) {
318: int_error("illegal month", NO_CARET);
319: return (NULL);
320: }
321: if (tm->tm_mday < 1) {
322: int_error("illegal day of month", NO_CARET);
323: return (NULL);
324: }
325: if (tm->tm_mon > 11) {
326: tm->tm_year += tm->tm_mon / 12;
327: tm->tm_mon %= 12;
328: } {
329: int days_in_month;
330: while (tm->tm_mday > (days_in_month = (mndday[tm->tm_mon] + (tm->tm_mon == 1 && (gdysize(tm->tm_year) > 365))))) {
331: if (++tm->tm_mon == 12) {
332: ++tm->tm_year;
333: tm->tm_mon = 0;
334: }
335: tm->tm_mday -= days_in_month;
336: }
337: }
338: }
339: return (s);
340: }
341:
342: int gstrftime(s, bsz, fmt, l_clock)
343: char *s;
344: int bsz;
345: char *fmt;
346: double l_clock;
347: {
348: struct tm tm;
349:
350: ggmtime(&tm, l_clock);
351: #if 0
352: if ((tm.tm_zone = (char *) malloc(strlen(xtm->tm_zone) + 1)))
353: strcpy(tm.tm_zone, xtm->tm_zone);
354: /* printf("zone: %s - %s\n",tm.tm_zone,xtm->tm_zone); */
355: #endif
356:
357: return (xstrftime(s, bsz, fmt, &tm));
358: }
359:
360:
361: /* some shorthands : check that there is space in the output string
362: * Odd-looking defn is dangling-else-safe
363: */
364: #define CHECK_SPACE(n) if ( (l+(n)) <= bsz) ; else return 0
365:
366: /* copy a fixed string, checking that there's room */
367: #define COPY_STRING(z) CHECK_SPACE(strlen(z)) ; strcpy(s, z)
368:
369: /* format a string, using default spec if none given
370: * w and z are width and zero-flag
371: * dw and dz are the defaults for these
372: * In fact, CHECK_SPACE(w) is not a sufficient test, since
373: * sprintf("%2d", 365) outputs three characters
374: */
375:
376: #define FORMAT_STRING(dz, dw, x) \
377: if (w==0) { w=(dw); if (!z) z=(dz); } \
378: CHECK_SPACE(w); \
379: sprintf(s, z ? "%0*d" : "%*d", w, (x) )
380:
381: static int xstrftime(str, bsz, fmt, tm)
382: char *str; /* output buffer */
383: int bsz; /* space available */
384: char *fmt;
385: struct tm *tm;
386: {
387: int l = 0; /* chars written so far */
388:
389: char *s = str;
390:
391: memset(s, '\0', bsz);
392:
393: while (*fmt != '\0') {
394: if (*fmt != '%') {
395: if (l >= bsz)
396: return (0);
397: *s++ = *fmt++;
398: l++;
399: } else {
400:
401: /* set up format modifiers */
402: int w = 0;
403: int z = 0;
404: if (*++fmt == '0') {
405: z = 1;
406: ++fmt;
407: }
408: while (*fmt >= '0' && *fmt <= '9') {
409: w = w * 10 + (*fmt - '0');
410: ++fmt;
411: }
412:
413: switch (*fmt++) {
414: case '%':
415: CHECK_SPACE(1);
416: *s = '%';
417: break;
418:
419: case 'a':
420: COPY_STRING(abbrev_day_names[tm->tm_wday]);
421: break;
422:
423: case 'A':
424: COPY_STRING(full_day_names[tm->tm_wday]);
425: break;
426:
427: case 'b':
428: case 'h':
429: COPY_STRING(abbrev_month_names[tm->tm_mon]);
430: break;
431:
432: case 'B':
433: COPY_STRING(full_month_names[tm->tm_mon]);
434: break;
435:
436:
437: #if 0
438: /* %x not currently supported, so neither is c */
439: case 'c':
440: if (!xstrftime(s, bsz - l, "%x %X", tm))
441: return (0);
442: break;
443: #endif
444:
445: case 'd':
446: FORMAT_STRING(1, 2, tm->tm_mday); /* %02d */
447: break;
448:
449: case 'D':
450: if (!xstrftime(s, bsz - l, "%m/%d/%y", tm))
451: return (0);
452: break;
453:
454: case 'H':
455: FORMAT_STRING(1, 2, tm->tm_hour); /* %02d */
456: break;
457:
458: case 'I':
459: FORMAT_STRING(1, 2, tm->tm_hour % 12); /* %02d */
460: break;
461:
462: case 'j':
463: FORMAT_STRING(1, 3, tm->tm_yday + 1); /* %03d */
464: break;
465:
466: /* not in linux strftime man page. Not really needed now */
467: case 'k':
468: FORMAT_STRING(0, 2, tm->tm_hour); /* %2d */
469: break;
470:
471: case 'l':
472: FORMAT_STRING(0, 2, tm->tm_hour % 12); /* %2d */
473: break;
474:
475: case 'm':
476: FORMAT_STRING(1, 2, tm->tm_mon + 1); /* %02d */
477: break;
478:
479: case 'M':
480: FORMAT_STRING(1, 2, tm->tm_min); /* %02d */
481: break;
482:
483: case 'p':
484: CHECK_SPACE(2);
485: strcpy(s, (tm->tm_hour < 12) ? "am" : "pm");
486: break;
487:
488: case 'r':
489: if (!xstrftime(s, bsz - l, "%I:%M:%S %p", tm))
490: return (0);
491: break;
492:
493: case 'R':
494: if (!xstrftime(s, bsz - l, "%H:%M", tm))
495: return (0);
496: break;
497:
498: case 'S':
499: FORMAT_STRING(1, 2, tm->tm_sec); /* %02d */
500: break;
501:
502: case 'T':
503: if (!xstrftime(s, bsz - l, "%H:%M:%S", tm))
504: return (0);
505: break;
506:
507: case 'W': /* mon 1 day of week */
508: {
509: int week;
510: if (tm->tm_yday <= tm->tm_wday) {
511: week = 1;
512:
513: if ((tm->tm_mday - tm->tm_yday) > 4) {
514: week = 52;
515: }
516: if (tm->tm_yday == tm->tm_wday && tm->tm_wday == 0)
517: week = 52;
518:
519: } else {
520:
521: /* sun prev week */
522: int bw = tm->tm_yday - tm->tm_wday;
523:
524: if (tm->tm_wday > 0)
525: bw += 7; /* sun end of week */
526:
527: week = (int) bw / 7;
528:
529: if ((bw % 7) > 2) /* jan 1 is before friday */
530: week++;
531: }
532: FORMAT_STRING(1, 2, week); /* %02d */
533: break;
534: }
535:
536: case 'U': /* sun 1 day of week */
537: {
538: int week, bw;
539:
540: if (tm->tm_yday <= tm->tm_wday) {
541: week = 1;
542: if ((tm->tm_mday - tm->tm_yday) > 4) {
543: week = 52;
544: }
545: } else {
546: /* sat prev week */
547: bw = tm->tm_yday - tm->tm_wday - 1;
548: if (tm->tm_wday >= 0)
549: bw += 7; /* sat end of week */
550: week = (int) bw / 7;
551: if ((bw % 7) > 1) { /* jan 1 is before friday */
552: week++;
553: }
554: }
555: FORMAT_STRING(1, 2, week); /* %02d */
556: break;
557: }
558:
559: case 'w': /* day of week, sun=0 */
560: FORMAT_STRING(1, 2, tm->tm_wday); /* %02d */
561: break;
562:
563: case 'y':
564: FORMAT_STRING(1, 2, tm->tm_year % 100); /* %02d */
565: break;
566:
567: case 'Y':
568: FORMAT_STRING(1, 4, tm->tm_year); /* %04d */
569: break;
570:
571: #if 0
572: case 'Z':
573: COPY_STRING(tm->tm_zone);
574: break;
575: #endif
576: } /* switch */
577:
578: while (*s != '\0') {
579: s++;
580: l++;
581: }
582: }
583: }
584: return (l);
585: }
586:
587:
588:
589: /* time_t */
590: double gtimegm(tm)
591: struct tm *tm;
592: {
593: register int i;
594: /* returns sec from year ZERO_YEAR, defined in plot.h */
595: double dsec;
596:
597: dsec = 0;
598: if (tm->tm_year < ZERO_YEAR) {
599: for (i = tm->tm_year; i < ZERO_YEAR; i++) {
600: dsec -= (double) gdysize(i);
601: }
602: } else {
603: for (i = ZERO_YEAR; i < tm->tm_year; i++) {
604: dsec += (double) gdysize(i);
605: }
606: }
607: if (tm->tm_mday > 0) {
608: for (i = 0; i < tm->tm_mon; i++) {
609: dsec += (double) mndday[i] + (i == 1 && (gdysize(tm->tm_year) > 365));
610: }
611: dsec += (double) tm->tm_mday - 1;
612: } else {
613: dsec += (double) tm->tm_yday;
614: }
615: dsec *= (double) 24;
616:
617: dsec += tm->tm_hour;
618: dsec *= 60.0;
619: dsec += tm->tm_min;
620: dsec *= 60.0;
621: dsec += tm->tm_sec;
622:
623: FPRINTF((stderr, "broken-down time : %d/%d/%d:%d:%d:%d = %g seconds\n", tm->tm_mday, tm->tm_mon + 1, tm->tm_year, tm->tm_hour, tm->tm_min, tm->tm_sec, dsec));
624:
625: return (dsec);
626: }
627:
628: int ggmtime(tm, l_clock)
629: struct tm *tm;
630: /* time_t l_clock; */
631: double l_clock;
632: {
633: /* l_clock is relative to ZERO_YEAR, jan 1, 00:00:00,defined in plot.h */
634: int i, days;
635:
636: /* dodgy way of doing wday - i hope it works ! */
637:
638: int wday = JAN_FIRST_WDAY; /* eg 6 for 2000 */
639:
640: FPRINTF((stderr, "%g seconds = ", l_clock));
641:
642: tm->tm_year = ZERO_YEAR;
643: tm->tm_mday = tm->tm_yday = tm->tm_mon = tm->tm_hour = tm->tm_min = tm->tm_sec = 0;
644: if (l_clock < 0) {
645: while (l_clock < 0) {
646: int days_in_year = gdysize(--tm->tm_year);
647: l_clock += days_in_year * DAY_SEC; /* 24*3600 */
648: /* adding 371 is noop in modulo 7 arithmetic, but keeps wday +ve */
649: wday += 371 - days_in_year;
650: }
651: } else {
652: for (;;) {
653: int days_in_year = gdysize(tm->tm_year);
654: if (l_clock < days_in_year * DAY_SEC)
655: break;
656: l_clock -= days_in_year * DAY_SEC;
657: tm->tm_year++;
658: /* only interested in result modulo 7, but %7 is expensive */
659: wday += (days_in_year - 364);
660: }
661: }
662: tm->tm_yday = (int) (l_clock / DAY_SEC);
663: l_clock -= tm->tm_yday * DAY_SEC;
664: tm->tm_hour = (int) l_clock / 3600;
665: l_clock -= tm->tm_hour * 3600;
666: tm->tm_min = (int) l_clock / 60;
667: l_clock -= tm->tm_min * 60;
668: tm->tm_sec = (int) l_clock;
669:
670: days = tm->tm_yday;
671:
672: /* wday%7 should be day of week of first day of year */
673: tm->tm_wday = (wday + days) % 7;
674:
675: while (days >= (i = mndday[tm->tm_mon] + (tm->tm_mon == 1 && (gdysize(tm->tm_year) > 365)))) {
676: days -= i;
677: tm->tm_mon++;
678: }
679: tm->tm_mday = days + 1;
680:
681: FPRINTF((stderr, "broken-down time : %d/%d/%d:%d:%d:%d\n", tm->tm_mday, tm->tm_mon + 1, tm->tm_year, tm->tm_hour, tm->tm_min, tm->tm_sec));
682:
683: return (0);
684: }
685:
686:
687:
688:
689: #else /* USE_SYSTEM_TIME */
690:
691: /* define gnu time routines in terms of system time routines */
692:
693: int gstrftime(buf, bufsz, fmt, l_clock)
694: char *buf;
695: int bufsz;
696: char *fmt;
697: double l_clock;
698: {
699: time_t t = (time_t) l_clock;
700: return strftime(buf, bufsz, fmt, gmtime(&t));
701: }
702:
703: double gtimegm(tm)
704: struct tm *tm;
705: {
706: return (double) mktime(tm);
707: }
708:
709: int ggmtime(tm, l_clock)
710: struct tm *tm;
711: double l_clock;
712: {
713: time_t t = (time_t) l_clock;
714: struct tm *m = gmtime(&t);
715: *tm = *m; /* can any non-ansi compilers not do this ? */
716: }
717:
718: #define NOTHING
719: #define LETTER(L, width, field, extra) \
720: case L: s=read_int(s,width,&tm->field); extra; continue
721:
722: /* supplemental routine gstrptime() to read a formatted time */
723:
724: char *
725: gstrptime(s, fmt, tm)
726: char *s;
727: char *fmt;
728: struct tm *tm;
729: {
730: FPRINTF((stderr, "gstrptime(\"%s\", \"%s\")\n", s, fmt));
731:
732: /* linux does not appear to like years before 1902
733: * NT complains if its before 1970
734: * initialise fields to midnight, 1st Jan, 1970 (for relative times)
735: */
736: tm->tm_sec = tm->tm_min = tm->tm_hour = 0;
737: tm->tm_mday = 1;
738: tm->tm_mon = 0;
739: tm->tm_year = 70;
740: /* oops - it goes wrong without this */
741: tm->tm_isdst = 0;
742:
743: for (; *fmt && *s; ++fmt) {
744: if (*fmt != '%') {
745: if (*s != *fmt)
746: return s;
747: ++s;
748: continue;
749: }
750: assert(*fmt == '%');
751:
752: switch (*++fmt) {
753: case 0:
754: /* uh oh - % is last character in format */
755: return s;
756: case '%':
757: /* literal % */
758: if (*s++ != '%')
759: return s - 1;
760: continue;
761:
762: LETTER('d', 2, tm_mday, NOTHING);
763: LETTER('m', 2, tm_mon, NOTHING);
764: LETTER('y', 2, tm_year, NOTHING);
765: LETTER('Y', 4, tm_year, tm->tm_year -= 1900);
766: LETTER('H', 2, tm_hour, NOTHING);
767: LETTER('M', 2, tm_min, NOTHING);
768: LETTER('S', 2, tm_sec, NOTHING);
769:
770: default:
771: int_error("incorrect time format character", NO_CARET);
772: }
773: }
774:
775: FPRINTF((stderr, "Before mktime : %d/%d/%d:%d:%d:%d\n", tm->tm_mday, tm->tm_mon, tm->tm_year, tm->tm_hour, tm->tm_min, tm->tm_sec));
776: /* mktime range-checks the time */
777:
778: if (mktime(tm) == -1) {
779: FPRINTF((stderr, "mktime() was not happy\n"));
780: int_error("Invalid date/time [mktime() did not like it]", NO_CARET);
781: }
782: FPRINTF((stderr, "After mktime : %d/%d/%d:%d:%d:%d\n", tm->tm_mday, tm->tm_mon, tm->tm_year, tm->tm_hour, tm->tm_min, tm->tm_sec));
783:
784: return s;
785: }
786:
787:
788: #endif /* USE_SYSTEM_TIME */
789:
790:
791: #ifdef TEST_TIME
792:
793: char *abbrev_month_names[] =
794: {"jan", "feb", "mar", "apr", "may", "jun", "jul",
795: "aug", "sep", "oct", "nov", "dec"};
796: char *full_month_names[] =
797: {"January", "February", "March", "April", "May",
798: "June", "July", "August", "September", "October", "November", "December"};
799:
800: char *abbrev_day_names[] =
801: {"sun", "mon", "tue", "wed", "thu", "fri", "sat"};
802: char *full_day_names[] =
803: {"Sunday", "Monday", "Tuesday", "Wednesday", "Thursday", "Friday", "Saturday"};
804:
805:
806:
807: /* either print current time using supplied format, or read
808: * supplied time using supplied format
809: */
810:
811:
812: int main(argc,argv)
813: int argc;
814: char *argv[];
815: {
816: char output[80];
817:
818: if (argc < 2) {
819: fputs("usage : test 'format' ['time']\n", stderr);
820: exit(EXIT_FAILURE);
821: }
822: if (argc == 2) {
823: struct timeb now;
824: struct tm *tm;
825: ftime(&now);
826: tm = gmtime(&now.time);
827: xstrftime(output, 80, argv[1], tm);
828: puts(output);
829: } else {
830: struct tm tm;
831: gstrptime(argv[2], argv[1], &tm);
832: puts(asctime(&tm));
833: }
834: exit(EXIT_SUCCESS);
835: }
836:
837: #endif /* TEST_TIME */
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