Parallelize in_ifaddrhead operation
[dragonfly.git] / lib / libcalendar / calendar.c
blob1aeeabaef1d82c6985d662a892a2bf4f1b7b5aad
1 /*-
2 * Copyright (c) 1997 Wolfgang Helbig
3 * All rights reserved.
5 * Redistribution and use in source and binary forms, with or without
6 * modification, are permitted provided that the following conditions
7 * are met:
8 * 1. Redistributions of source code must retain the above copyright
9 * notice, this list of conditions and the following disclaimer.
10 * 2. Redistributions in binary form must reproduce the above copyright
11 * notice, this list of conditions and the following disclaimer in the
12 * documentation and/or other materials provided with the distribution.
14 * THIS SOFTWARE IS PROVIDED BY THE AUTHOR AND CONTRIBUTORS ``AS IS'' AND
15 * ANY EXPRESS OR IMPLIED WARRANTIES, INCLUDING, BUT NOT LIMITED TO, THE
16 * IMPLIED WARRANTIES OF MERCHANTABILITY AND FITNESS FOR A PARTICULAR PURPOSE
17 * ARE DISCLAIMED. IN NO EVENT SHALL THE AUTHOR OR CONTRIBUTORS BE LIABLE
18 * FOR ANY DIRECT, INDIRECT, INCIDENTAL, SPECIAL, EXEMPLARY, OR CONSEQUENTIAL
19 * DAMAGES (INCLUDING, BUT NOT LIMITED TO, PROCUREMENT OF SUBSTITUTE GOODS
20 * OR SERVICES; LOSS OF USE, DATA, OR PROFITS; OR BUSINESS INTERRUPTION)
21 * HOWEVER CAUSED AND ON ANY THEORY OF LIABILITY, WHETHER IN CONTRACT, STRICT
22 * LIABILITY, OR TORT (INCLUDING NEGLIGENCE OR OTHERWISE) ARISING IN ANY WAY
23 * OUT OF THE USE OF THIS SOFTWARE, EVEN IF ADVISED OF THE POSSIBILITY OF
24 * SUCH DAMAGE.
26 * $FreeBSD: src/lib/libcalendar/calendar.c,v 1.3 1999/08/28 00:04:03 peter Exp $
27 * $DragonFly: src/lib/libcalendar/calendar.c,v 1.2 2003/06/17 04:26:48 dillon Exp $
30 #include "calendar.h"
32 #ifndef NULL
33 #define NULL 0
34 #endif
37 * For each month tabulate the number of days elapsed in a year before the
38 * month. This assumes the internal date representation, where a year
39 * starts on March 1st. So we don't need a special table for leap years.
40 * But we do need a special table for the year 1582, since 10 days are
41 * deleted in October. This is month1s for the switch from Julian to
42 * Gregorian calendar.
44 static int const month1[] =
45 {0, 31, 61, 92, 122, 153, 184, 214, 245, 275, 306, 337};
46 /* M A M J J A S O N D J */
47 static int const month1s[]=
48 {0, 31, 61, 92, 122, 153, 184, 214, 235, 265, 296, 327};
50 typedef struct date date;
52 /* The last day of Julian calendar, in internal and ndays representation */
53 static int nswitch; /* The last day of Julian calendar */
54 static date jiswitch = {1582, 7, 3};
56 static date *date2idt(date *idt, date *dt);
57 static date *idt2date(date *dt, date *idt);
58 static int ndaysji(date *idt);
59 static int ndaysgi(date *idt);
60 static int firstweek(int year);
63 * Compute the Julian date from the number of days elapsed since
64 * March 1st of year zero.
66 date *
67 jdate(int ndays, date *dt)
69 date idt; /* Internal date representation */
70 int r; /* hold the rest of days */
73 * Compute the year by starting with an approximation not smaller
74 * than the answer and using linear search for the greatest
75 * year which does not begin after ndays.
77 idt.y = ndays / 365;
78 idt.m = 0;
79 idt.d = 0;
80 while ((r = ndaysji(&idt)) > ndays)
81 idt.y--;
84 * Set r to the days left in the year and compute the month by
85 * linear search as the largest month that does not begin after r
86 * days.
88 r = ndays - r;
89 for (idt.m = 11; month1[idt.m] > r; idt.m--)
92 /* Compute the days left in the month */
93 idt.d = r - month1[idt.m];
95 /* return external representation of the date */
96 return (idt2date(dt, &idt));
100 * Return the number of days since March 1st of the year zero.
101 * The date is given according to Julian calendar.
104 ndaysj(date *dt)
106 date idt; /* Internal date representation */
108 if (date2idt(&idt, dt) == NULL)
109 return (-1);
110 else
111 return (ndaysji(&idt));
115 * Same as above, where the Julian date is given in internal notation.
116 * This formula shows the beauty of this notation.
118 static int
119 ndaysji(date * idt)
122 return (idt->d + month1[idt->m] + idt->y * 365 + idt->y / 4);
126 * Compute the date according to the Gregorian calendar from the number of
127 * days since March 1st, year zero. The date computed will be Julian if it
128 * is older than 1582-10-05. This is the reverse of the function ndaysg().
130 date *
131 gdate(int ndays, date *dt)
133 int const *montht; /* month-table */
134 date idt; /* for internal date representation */
135 int r; /* holds the rest of days */
138 * Compute the year by starting with an approximation not smaller
139 * than the answer and search linearly for the greatest year not
140 * starting after ndays.
142 idt.y = ndays / 365;
143 idt.m = 0;
144 idt.d = 0;
145 while ((r = ndaysgi(&idt)) > ndays)
146 idt.y--;
149 * Set ndays to the number of days left and compute by linear
150 * search the greatest month which does not start after ndays. We
151 * use the table month1 which provides for each month the number
152 * of days that elapsed in the year before that month. Here the
153 * year 1582 is special, as 10 days are left out in October to
154 * resynchronize the calendar with the earth's orbit. October 4th
155 * 1582 is followed by October 15th 1582. We use the "switch"
156 * table month1s for this year.
158 ndays = ndays - r;
159 if (idt.y == 1582)
160 montht = month1s;
161 else
162 montht = month1;
164 for (idt.m = 11; montht[idt.m] > ndays; idt.m--)
167 idt.d = ndays - montht[idt.m]; /* the rest is the day in month */
169 /* Advance ten days deleted from October if after switch in Oct 1582 */
170 if (idt.y == jiswitch.y && idt.m == jiswitch.m && jiswitch.d < idt.d)
171 idt.d += 10;
173 /* return external representation of found date */
174 return (idt2date(dt, &idt));
178 * Return the number of days since March 1st of the year zero. The date is
179 * assumed Gregorian if younger than 1582-10-04 and Julian otherwise. This
180 * is the reverse of gdate.
183 ndaysg(date *dt)
185 date idt; /* Internal date representation */
187 if (date2idt(&idt, dt) == NULL)
188 return (-1);
189 return (ndaysgi(&idt));
193 * Same as above, but with the Gregorian date given in internal
194 * representation.
196 static int
197 ndaysgi(date *idt)
199 int nd; /* Number of days--return value */
201 /* Cache nswitch if not already done */
202 if (nswitch == 0)
203 nswitch = ndaysji(&jiswitch);
206 * Assume Julian calendar and adapt to Gregorian if necessary, i. e.
207 * younger than nswitch. Gregori deleted
208 * the ten days from Oct 5th to Oct 14th 1582.
209 * Thereafter years which are multiples of 100 and not multiples
210 * of 400 were not leap years anymore.
211 * This makes the average length of a year
212 * 365d +.25d - .01d + .0025d = 365.2425d. But the tropical
213 * year measures 365.2422d. So in 10000/3 years we are
214 * again one day ahead of the earth. Sigh :-)
215 * (d is the average length of a day and tropical year is the
216 * time from one spring point to the next.)
218 if ((nd = ndaysji(idt)) == -1)
219 return (-1);
220 if (idt->y >= 1600)
221 nd = (nd - 10 - (idt->y - 1600) / 100 + (idt->y - 1600) / 400);
222 else if (nd > nswitch)
223 nd -= 10;
224 return (nd);
228 * Compute the week number from the number of days since March 1st year 0.
229 * The weeks are numbered per year starting with 1. If the first
230 * week of a year includes at least four days of that year it is week 1,
231 * otherwise it gets the number of the last week of the previous year.
232 * The variable y will be filled with the year that contains the greater
233 * part of the week.
236 week(int nd, int *y)
238 date dt;
239 int fw; /* 1st day of week 1 of previous, this and
240 * next year */
241 gdate(nd, &dt);
242 for (*y = dt.y + 1; nd < (fw = firstweek(*y)); (*y)--)
244 return ((nd - fw) / 7 + 1);
247 /* return the first day of week 1 of year y */
248 static int
249 firstweek(int y)
251 date idt;
252 int nd, wd;
254 idt.y = y - 1; /* internal representation of y-1-1 */
255 idt.m = 10;
256 idt.d = 0;
258 nd = ndaysgi(&idt);
260 * If more than 3 days of this week are in the preceding year, the
261 * next week is week 1 (and the next monday is the answer),
262 * otherwise this week is week 1 and the last monday is the
263 * answer.
265 if ((wd = weekday(nd)) > 3)
266 return (nd - wd + 7);
267 else
268 return (nd - wd);
271 /* return the weekday (Mo = 0 .. Su = 6) */
273 weekday(int nd)
275 date dmondaygi = {1997, 8, 16}; /* Internal repr. of 1997-11-17 */
276 static int nmonday; /* ... which is a monday */
278 /* Cache the daynumber of one monday */
279 if (nmonday == 0)
280 nmonday = ndaysgi(&dmondaygi);
282 /* return (nd - nmonday) modulo 7 which is the weekday */
283 nd = (nd - nmonday) % 7;
284 if (nd < 0)
285 return (nd + 7);
286 else
287 return (nd);
291 * Convert a date to internal date representation: The year starts on
292 * March 1st, month and day numbering start at zero. E. g. March 1st of
293 * year zero is written as y=0, m=0, d=0.
295 static date *
296 date2idt(date *idt, date *dt)
299 idt->d = dt->d - 1;
300 if (dt->m > 2) {
301 idt->m = dt->m - 3;
302 idt->y = dt->y;
303 } else {
304 idt->m = dt->m + 9;
305 idt->y = dt->y - 1;
307 if (idt->m < 0 || idt->m > 11 || idt->y < 0)
308 return (NULL);
309 else
310 return idt;
313 /* Reverse of date2idt */
314 static date *
315 idt2date(date *dt, date *idt)
318 dt->d = idt->d + 1;
319 if (idt->m < 10) {
320 dt->m = idt->m + 3;
321 dt->y = idt->y;
322 } else {
323 dt->m = idt->m - 9;
324 dt->y = idt->y + 1;
326 if (dt->m < 1)
327 return (NULL);
328 else
329 return (dt);