libc/time/strftime.c

1.4       jtc /*	$NetBSD: strftime.c,v 1.4 1997/07/21 14:09:22 jtc Exp $	*/
1.2    kleink
1.1       mrg /*
1.1       mrg  * Copyright (c) 1989 The Regents of the University of California.
1.1       mrg  * All rights reserved.
1.1       mrg  *
1.1       mrg  * Redistribution and use in source and binary forms, with or without
1.1       mrg  * modification, are permitted provided that the following conditions
1.1       mrg  * are met:
1.1       mrg  * 1. Redistributions of source code must retain the above copyright
1.1       mrg  *    notice, this list of conditions and the following disclaimer.
1.1       mrg  * 2. Redistributions in binary form must reproduce the above copyright
1.1       mrg  *    notice, this list of conditions and the following disclaimer in the
1.1       mrg  *    documentation and/or other materials provided with the distribution.
1.1       mrg  * 3. All advertising materials mentioning features or use of this software
1.1       mrg  *    must display the following acknowledgement:
1.1       mrg  *	This product includes software developed by the University of
1.1       mrg  *	California, Berkeley and its contributors.
1.1       mrg  * 4. Neither the name of the University nor the names of its contributors
1.1       mrg  *    may be used to endorse or promote products derived from this software
1.1       mrg  *    without specific prior written permission.
1.1       mrg  *
1.1       mrg  * THIS SOFTWARE IS PROVIDED BY THE REGENTS AND CONTRIBUTORS ``AS IS'' AND
1.1       mrg  * ANY EXPRESS OR IMPLIED WARRANTIES, INCLUDING, BUT NOT LIMITED TO, THE
1.1       mrg  * IMPLIED WARRANTIES OF MERCHANTABILITY AND FITNESS FOR A PARTICULAR PURPOSE
1.1       mrg  * ARE DISCLAIMED.  IN NO EVENT SHALL THE REGENTS OR CONTRIBUTORS BE LIABLE
1.1       mrg  * FOR ANY DIRECT, INDIRECT, INCIDENTAL, SPECIAL, EXEMPLARY, OR CONSEQUENTIAL
1.1       mrg  * DAMAGES (INCLUDING, BUT NOT LIMITED TO, PROCUREMENT OF SUBSTITUTE GOODS
1.1       mrg  * OR SERVICES; LOSS OF USE, DATA, OR PROFITS; OR BUSINESS INTERRUPTION)
1.1       mrg  * HOWEVER CAUSED AND ON ANY THEORY OF LIABILITY, WHETHER IN CONTRACT, STRICT
1.1       mrg  * LIABILITY, OR TORT (INCLUDING NEGLIGENCE OR OTHERWISE) ARISING IN ANY WAY
1.1       mrg  * OUT OF THE USE OF THIS SOFTWARE, EVEN IF ADVISED OF THE POSSIBILITY OF
1.1       mrg  * SUCH DAMAGE.
1.1       mrg  */
1.1       mrg
1.3  christos #include <sys/cdefs.h>
1.1       mrg #if defined(LIBC_SCCS) && !defined(lint)
1.3  christos #if 0
1.3  christos static char *sccsid = "@(#)strftime.c	5.11 (Berkeley) 2/24/91";
1.3  christos #else
1.4       jtc __RCSID("$NetBSD: strftime.c,v 1.4 1997/07/21 14:09:22 jtc Exp $");
1.3  christos #endif
1.1       mrg #endif /* LIBC_SCCS and not lint */
1.1       mrg
1.4       jtc #include "namespace.h"
1.1       mrg #include <sys/localedef.h>
1.1       mrg #include <locale.h>
1.1       mrg #include <string.h>
1.1       mrg #include <tzfile.h>
1.1       mrg #include <time.h>
1.1       mrg
1.1       mrg static size_t gsize;
1.1       mrg static char *pt;
1.2    kleink
1.2    kleink static	int _add __P((const char *));
1.2    kleink static	int _conv __P((int, int, char));
1.2    kleink static	int _secs __P((const struct tm *));
1.2    kleink static	size_t _fmt __P((const char *, const struct tm *));
1.1       mrg
1.1       mrg size_t
1.1       mrg strftime(s, maxsize, format, t)
1.1       mrg 	char *s;
1.1       mrg 	size_t maxsize;
1.1       mrg 	const char *format;
1.1       mrg 	const struct tm *t;
1.1       mrg {
1.1       mrg 	tzset();
1.1       mrg
1.1       mrg 	pt = s;
1.1       mrg 	if ((gsize = maxsize) < 1)
1.2    kleink 		return (0);
1.1       mrg 	if (_fmt(format, t)) {
1.1       mrg 		*pt = '\0';
1.2    kleink 		return (maxsize - gsize);
1.1       mrg 	}
1.2    kleink 	return (0);
1.1       mrg }
1.1       mrg
1.1       mrg #define SUN_WEEK(t)	(((t)->tm_yday + 7 - \
1.1       mrg 				((t)->tm_wday)) / 7)
1.1       mrg #define MON_WEEK(t)	(((t)->tm_yday + 7 - \
1.1       mrg 				((t)->tm_wday ? (t)->tm_wday - 1 : 6)) / 7)
1.1       mrg static size_t
1.1       mrg _fmt(format, t)
1.1       mrg 	register const char *format;
1.1       mrg 	const struct tm *t;
1.1       mrg {
1.1       mrg 	for (; *format; ++format) {
1.1       mrg 		if (*format == '%') {
1.1       mrg 			++format;
1.1       mrg 			if (*format == 'E') {
1.1       mrg 				/* Alternate Era */
1.1       mrg 				++format;
1.1       mrg 			} else if (*format == 'O') {
1.1       mrg 				/* Alternate numeric symbols */
1.1       mrg 				++format;
1.1       mrg 			}
1.2    kleink 			switch (*format) {
1.1       mrg 			case '\0':
1.1       mrg 				--format;
1.1       mrg 				break;
1.1       mrg 			case 'A':
1.1       mrg 				if (t->tm_wday < 0 || t->tm_wday > 6)
1.2    kleink 					return (0);
1.1       mrg 				if (!_add(_CurrentTimeLocale->day[t->tm_wday]))
1.2    kleink 					return (0);
1.1       mrg 				continue;
1.1       mrg 			case 'a':
1.1       mrg 				if (t->tm_wday < 0 || t->tm_wday > 6)
1.2    kleink 					return (0);
1.1       mrg 				if (!_add(_CurrentTimeLocale->abday[t->tm_wday]))
1.2    kleink 					return (0);
1.1       mrg 				continue;
1.1       mrg 			case 'B':
1.1       mrg 				if (t->tm_mon < 0 || t->tm_mon > 11)
1.2    kleink 					return (0);
1.1       mrg 				if (!_add(_CurrentTimeLocale->mon[t->tm_mon]))
1.2    kleink 					return (0);
1.1       mrg 				continue;
1.1       mrg 			case 'b':
1.1       mrg 			case 'h':
1.1       mrg 				if (t->tm_mon < 0 || t->tm_mon > 11)
1.2    kleink 					return (0);
1.1       mrg 				if (!_add(_CurrentTimeLocale->abmon[t->tm_mon]))
1.2    kleink 					return (0);
1.1       mrg 				continue;
1.1       mrg 			case 'C':
1.1       mrg 				if (!_conv((t->tm_year + TM_YEAR_BASE) / 100,
1.1       mrg 				    2, '0'))
1.2    kleink 					return (0);
1.1       mrg 				continue;
1.1       mrg 			case 'c':
1.1       mrg 				if (!_fmt(_CurrentTimeLocale->d_t_fmt, t))
1.2    kleink 					return (0);
1.1       mrg 				continue;
1.1       mrg 			case 'D':
1.1       mrg 				if (!_fmt("%m/%d/%y", t))
1.2    kleink 					return (0);
1.1       mrg 				continue;
1.1       mrg 			case 'd':
1.1       mrg 				if (!_conv(t->tm_mday, 2, '0'))
1.2    kleink 					return (0);
1.1       mrg 				continue;
1.1       mrg 			case 'e':
1.1       mrg 				if (!_conv(t->tm_mday, 2, ' '))
1.2    kleink 					return (0);
1.1       mrg 				continue;
1.1       mrg 			case 'H':
1.1       mrg 				if (!_conv(t->tm_hour, 2, '0'))
1.2    kleink 					return (0);
1.1       mrg 				continue;
1.1       mrg 			case 'I':
1.1       mrg 				if (!_conv(t->tm_hour % 12 ?
1.1       mrg 				    t->tm_hour % 12 : 12, 2, '0'))
1.2    kleink 					return (0);
1.1       mrg 				continue;
1.1       mrg 			case 'j':
1.1       mrg 				if (!_conv(t->tm_yday + 1, 3, '0'))
1.2    kleink 					return (0);
1.1       mrg 				continue;
1.1       mrg 			case 'k':
1.1       mrg 				if (!_conv(t->tm_hour, 2, ' '))
1.2    kleink 					return (0);
1.1       mrg 				continue;
1.1       mrg 			case 'l':
1.1       mrg 				if (!_conv(t->tm_hour % 12 ?
1.1       mrg 				    t->tm_hour % 12: 12, 2, ' '))
1.2    kleink 					return (0);
1.1       mrg 				continue;
1.1       mrg 			case 'M':
1.1       mrg 				if (!_conv(t->tm_min, 2, '0'))
1.2    kleink 					return (0);
1.1       mrg 				continue;
1.1       mrg 			case 'm':
1.1       mrg 				if (!_conv(t->tm_mon + 1, 2, '0'))
1.2    kleink 					return (0);
1.1       mrg 				continue;
1.1       mrg 			case 'n':
1.1       mrg 				if (!_add("\n"))
1.2    kleink 					return (0);
1.1       mrg 				continue;
1.1       mrg 			case 'p':
1.1       mrg 				if (!_add(_CurrentTimeLocale->am_pm[t->tm_hour >= 12]))
1.2    kleink 					return (0);
1.1       mrg 				continue;
1.1       mrg 			case 'R':
1.1       mrg 				if (!_fmt("%H:%M", t))
1.2    kleink 					return (0);
1.1       mrg 				continue;
1.1       mrg 			case 'r':
1.1       mrg 				if (!_fmt(_CurrentTimeLocale->t_fmt_ampm, t))
1.2    kleink 					return (0);
1.1       mrg 				continue;
1.1       mrg 			case 'S':
1.1       mrg 				if (!_conv(t->tm_sec, 2, '0'))
1.2    kleink 					return (0);
1.1       mrg 				continue;
1.1       mrg 			case 's':
1.1       mrg 				if (!_secs(t))
1.2    kleink 					return (0);
1.1       mrg 				continue;
1.1       mrg 			case 'T':
1.1       mrg 				if (!_fmt("%H:%M:%S", t))
1.2    kleink 					return (0);
1.1       mrg 				continue;
1.1       mrg 			case 't':
1.1       mrg 				if (!_add("\t"))
1.2    kleink 					return (0);
1.1       mrg 				continue;
1.1       mrg 			case 'U':
1.1       mrg 				if (!_conv(SUN_WEEK(t), 2, '0'))
1.2    kleink 					return (0);
1.1       mrg 				continue;
1.1       mrg 			case 'u':
1.1       mrg 				if (!_conv(t->tm_wday ? t->tm_wday : 7, 1, '0'))
1.2    kleink 					return (0);
1.1       mrg 				continue;
1.1       mrg 			case 'V':
1.1       mrg 				{
1.1       mrg 				/* ISO 8601 Week Of Year:
1.2    kleink 				 *  If the week (Monday - Sunday) containing
1.2    kleink 				 * January 1 has four or more days in the new
1.2    kleink 				 * year, then it is week 1; otherwise it is
1.2    kleink 				 * week 53 of the previous year and the next
1.2    kleink 				 * week is week one.
1.2    kleink 				 */
1.2    kleink
1.1       mrg 				int week = MON_WEEK(t);
1.1       mrg
1.2    kleink 				int days = (((t)->tm_yday + 7 -
1.2    kleink 				    ((t)->tm_wday ? (t)->tm_wday - 1 : 6)) % 7);
1.1       mrg
1.1       mrg
1.1       mrg 				if (days >= 4) {
1.1       mrg 					week++;
1.1       mrg 				} else if (week == 0) {
1.1       mrg 					week = 53;
1.1       mrg 				}
1.1       mrg
1.1       mrg 				if (!_conv(week, 2, '0'))
1.2    kleink 					return (0);
1.1       mrg 				continue;
1.1       mrg 				}
1.1       mrg 			case 'W':
1.1       mrg 				if (!_conv(MON_WEEK(t), 2, '0'))
1.2    kleink 					return (0);
1.1       mrg 				continue;
1.1       mrg 			case 'w':
1.1       mrg 				if (!_conv(t->tm_wday, 1, '0'))
1.2    kleink 					return (0);
1.1       mrg 				continue;
1.1       mrg 			case 'x':
1.1       mrg 				if (!_fmt(_CurrentTimeLocale->d_fmt, t))
1.2    kleink 					return (0);
1.1       mrg 				continue;
1.1       mrg 			case 'X':
1.1       mrg 				if (!_fmt(_CurrentTimeLocale->t_fmt, t))
1.2    kleink 					return (0);
1.1       mrg 				continue;
1.1       mrg 			case 'y':
1.1       mrg 				if (!_conv((t->tm_year + TM_YEAR_BASE) % 100,
1.1       mrg 				    2, '0'))
1.2    kleink 					return (0);
1.1       mrg 				continue;
1.1       mrg 			case 'Y':
1.1       mrg 				if (!_conv((t->tm_year + TM_YEAR_BASE), 4, '0'))
1.2    kleink 					return (0);
1.1       mrg 				continue;
1.1       mrg 			case 'Z':
1.2    kleink 				if (tzname[t->tm_isdst ? 1 : 0] &&
1.2    kleink 				    !_add(tzname[t->tm_isdst ? 1 : 0]))
1.2    kleink 					return (0);
1.1       mrg 				continue;
1.1       mrg 			case '%':
1.1       mrg 			/*
1.1       mrg 			 * X311J/88-090 (4.12.3.5): if conversion char is
1.1       mrg 			 * undefined, behavior is undefined.  Print out the
1.1       mrg 			 * character itself as printf(3) does.
1.1       mrg 			 */
1.1       mrg 			default:
1.1       mrg 				break;
1.1       mrg 			}
1.1       mrg 		}
1.1       mrg 		if (!gsize--)
1.2    kleink 			return (0);
1.1       mrg 		*pt++ = *format;
1.1       mrg 	}
1.2    kleink 	return (gsize);
1.1       mrg }
1.1       mrg
1.1       mrg static int
1.1       mrg _secs(t)
1.1       mrg 	const struct tm *t;
1.1       mrg {
1.1       mrg 	static char buf[15];
1.1       mrg 	register time_t s;
1.1       mrg 	register char *p;
1.1       mrg 	struct tm tmp;
1.1       mrg
1.1       mrg 	/* Make a copy, mktime(3) modifies the tm struct. */
1.1       mrg 	tmp = *t;
1.1       mrg 	s = mktime(&tmp);
1.1       mrg 	for (p = buf + sizeof(buf) - 2; s > 0 && p > buf; s /= 10)
1.1       mrg 		*p-- = s % 10 + '0';
1.2    kleink 	return (_add(++p));
1.1       mrg }
1.1       mrg
1.1       mrg static int
1.1       mrg _conv(n, digits, pad)
1.1       mrg 	int n, digits;
1.1       mrg 	char pad;
1.1       mrg {
1.1       mrg 	static char buf[10];
1.1       mrg 	register char *p;
1.1       mrg
1.1       mrg 	for (p = buf + sizeof(buf) - 2; n > 0 && p > buf; n /= 10, --digits)
1.1       mrg 		*p-- = n % 10 + '0';
1.1       mrg 	while (p > buf && digits-- > 0)
1.1       mrg 		*p-- = pad;
1.2    kleink 	return (_add(++p));
1.1       mrg }
1.1       mrg
1.1       mrg static int
1.1       mrg _add(str)
1.1       mrg 	register const char *str;
1.1       mrg {
1.1       mrg 	for (;; ++pt, --gsize) {
1.1       mrg 		if (!gsize)
1.2    kleink 			return (0);
1.1       mrg 		if (!(*pt = *str++))
1.2    kleink 			return (1);
1.1       mrg 	}
1.1       mrg }