lib/libutil/parsedate.y

 1.1  christos %{
 1.1  christos /*
 1.1  christos **  Originally written by Steven M. Bellovin <smb (at) research.att.com> while
 1.1  christos **  at the University of North Carolina at Chapel Hill.  Later tweaked by
 1.1  christos **  a couple of people on Usenet.  Completely overhauled by Rich $alz
 1.1  christos **  <rsalz (at) bbn.com> and Jim Berets <jberets (at) bbn.com> in August, 1990;
 1.1  christos **
 1.1  christos **  This grammar has 10 shift/reduce conflicts.
 1.1  christos **
 1.1  christos **  This code is in the public domain and has no copyright.
 1.1  christos */
 1.1  christos /* SUPPRESS 287 on yaccpar_sccsid *//* Unused static variable */
 1.1  christos /* SUPPRESS 288 on yyerrlab *//* Label unused */
 1.1  christos
1.15      yamt #include <sys/cdefs.h>
1.15      yamt #ifdef __RCSID
1.34       kre __RCSID("$NetBSD: parsedate.y,v 1.34 2020/10/19 15:08:17 kre Exp $");
1.15      yamt #endif
1.15      yamt
 1.1  christos #include <stdio.h>
 1.1  christos #include <ctype.h>
1.14       apb #include <errno.h>
 1.1  christos #include <string.h>
 1.1  christos #include <time.h>
 1.1  christos #include <util.h>
 1.3  drochner #include <stdlib.h>
 1.1  christos
 1.1  christos /* NOTES on rebuilding parsedate.c (particularly for inclusion in CVS
 1.1  christos    releases):
 1.1  christos
 1.1  christos    We don't want to mess with all the portability hassles of alloca.
 1.1  christos    In particular, most (all?) versions of bison will use alloca in
 1.1  christos    their parser.  If bison works on your system (e.g. it should work
 1.1  christos    with gcc), then go ahead and use it, but the more general solution
 1.1  christos    is to use byacc instead of bison, which should generate a portable
 1.1  christos    parser.  I played with adding "#define alloca dont_use_alloca", to
 1.1  christos    give an error if the parser generator uses alloca (and thus detect
 1.1  christos    unportable parsedate.c's), but that seems to cause as many problems
 1.1  christos    as it solves.  */
 1.1  christos
 1.1  christos #define EPOCH		1970
1.21  christos #define HOUR(x)		((time_t)((x) * 60))
 1.1  christos #define SECSPERDAY	(24L * 60L * 60L)
 1.1  christos
1.28       kre #define	MAXREL	16	/* hours mins secs days weeks months years - maybe twice each ...*/
1.28       kre
1.20       apb #define USE_LOCAL_TIME	99999 /* special case for Convert() and yyTimezone */
 1.1  christos
 1.1  christos /*
 1.1  christos **  An entry in the lexical lookup table.
 1.1  christos */
 1.1  christos typedef struct _TABLE {
 1.1  christos     const char	*name;
 1.1  christos     int		type;
 1.1  christos     time_t	value;
 1.1  christos } TABLE;
 1.1  christos
 1.1  christos
 1.1  christos /*
 1.1  christos **  Daylight-savings mode:  on, off, or not yet known.
 1.1  christos */
 1.1  christos typedef enum _DSTMODE {
 1.1  christos     DSTon, DSToff, DSTmaybe
 1.1  christos } DSTMODE;
 1.1  christos
 1.1  christos /*
1.31       kre **  Meridian:  am, pm, or 24-hour style (plus "noon" and "midnight").
 1.1  christos */
 1.1  christos typedef enum _MERIDIAN {
1.31       kre     MERam, MERpm, MER24, MER_NOON, MER_MN
 1.1  christos } MERIDIAN;
 1.1  christos
 1.1  christos
 1.9  christos struct dateinfo {
1.17       apb 	DSTMODE	yyDSTmode;	/* DST on/off/maybe */
 1.9  christos 	time_t	yyDayOrdinal;
 1.9  christos 	time_t	yyDayNumber;
 1.9  christos 	int	yyHaveDate;
1.17       apb 	int	yyHaveFullYear;	/* if true, year is not abbreviated. */
1.17       apb 				/* if false, need to call AdjustYear(). */
 1.9  christos 	int	yyHaveDay;
 1.9  christos 	int	yyHaveRel;
 1.9  christos 	int	yyHaveTime;
 1.9  christos 	int	yyHaveZone;
1.17       apb 	time_t	yyTimezone;	/* Timezone as minutes ahead/east of UTC */
1.17       apb 	time_t	yyDay;		/* Day of month [1-31] */
1.17       apb 	time_t	yyHour;		/* Hour of day [0-24] or [1-12] */
1.17       apb 	time_t	yyMinutes;	/* Minute of hour [0-59] */
1.17       apb 	time_t	yyMonth;	/* Month of year [1-12] */
1.17       apb 	time_t	yySeconds;	/* Second of minute [0-60] */
1.17       apb 	time_t	yyYear;		/* Year, see also yyHaveFullYear */
1.17       apb 	MERIDIAN yyMeridian;	/* Interpret yyHour as AM/PM/24 hour clock */
1.28       kre 	struct {
1.28       kre 		time_t	yyRelVal;
1.28       kre 		int	yyRelMonth;
1.28       kre 	} yyRel[MAXREL];
 1.9  christos };
 1.1  christos %}
 1.1  christos
 1.1  christos %union {
 1.1  christos     time_t		Number;
 1.1  christos     enum _MERIDIAN	Meridian;
 1.1  christos }
 1.1  christos
 1.1  christos %token	tAGO tDAY tDAYZONE tID tMERIDIAN tMINUTE_UNIT tMONTH tMONTH_UNIT
1.23  christos %token	tSEC_UNIT tSNUMBER tUNUMBER tZONE tDST AT_SIGN tTIME
 1.1  christos
 1.1  christos %type	<Number>	tDAY tDAYZONE tMINUTE_UNIT tMONTH tMONTH_UNIT
1.23  christos %type	<Number>	tSEC_UNIT tSNUMBER tUNUMBER tZONE tTIME
1.25  dholland %type	<Meridian>	tMERIDIAN
1.25  dholland
1.25  dholland %type	<Number>	at_number
1.25  dholland %type	<Meridian>	o_merid
 1.1  christos
 1.9  christos %parse-param	{ struct dateinfo *param }
 1.9  christos %parse-param 	{ const char **yyInput }
 1.9  christos %lex-param	{ const char **yyInput }
 1.9  christos %pure-parser
 1.9  christos
 1.1  christos %%
 1.1  christos
1.25  dholland spec:
1.25  dholland 	  /* empty */
 1.1  christos 	| spec item
1.25  dholland ;
 1.1  christos
1.25  dholland item:
1.25  dholland 	  time			{ param->yyHaveTime++; }
1.25  dholland 	| time_numericzone	{ param->yyHaveTime++; param->yyHaveZone++; }
1.25  dholland 	| zone			{ param->yyHaveZone++; }
1.25  dholland 	| date			{ param->yyHaveDate++; }
1.25  dholland 	| day			{ param->yyHaveDay++; }
1.25  dholland 	| rel			{ param->yyHaveRel++; }
1.25  dholland 	| cvsstamp		{ param->yyHaveTime++; param->yyHaveDate++;
1.25  dholland 				  param->yyHaveZone++; }
1.25  dholland 	| epochdate		{ param->yyHaveTime++; param->yyHaveDate++;
1.25  dholland 				  param->yyHaveZone++; }
 1.1  christos 	| number
1.25  dholland ;
 1.1  christos
1.25  dholland cvsstamp:
1.25  dholland 	tUNUMBER '.' tUNUMBER '.' tUNUMBER '.'
1.25  dholland 				tUNUMBER '.' tUNUMBER '.' tUNUMBER {
1.25  dholland 		param->yyYear = $1;
1.25  dholland 		if (param->yyYear < 100) {
1.25  dholland 			param->yyYear += 1900;
1.25  dholland 		}
1.25  dholland 		param->yyHaveFullYear = 1;
1.25  dholland 		param->yyMonth = $3;
1.25  dholland 		param->yyDay = $5;
1.25  dholland 		param->yyHour = $7;
1.25  dholland 		param->yyMinutes = $9;
1.25  dholland 		param->yySeconds = $11;
1.25  dholland 		param->yyDSTmode = DSToff;
1.25  dholland 		param->yyTimezone = 0;
1.25  dholland 	}
1.25  dholland ;
1.25  dholland
1.25  dholland epochdate:
1.25  dholland 	AT_SIGN at_number {
1.25  dholland 		time_t	when = $2;
1.25  dholland 		struct tm tmbuf;
1.25  dholland
1.25  dholland 		if (gmtime_r(&when, &tmbuf) != NULL) {
1.25  dholland 			param->yyYear = tmbuf.tm_year + 1900;
1.25  dholland 			param->yyMonth = tmbuf.tm_mon + 1;
1.25  dholland 			param->yyDay = tmbuf.tm_mday;
1.25  dholland
1.25  dholland 			param->yyHour = tmbuf.tm_hour;
1.25  dholland 			param->yyMinutes = tmbuf.tm_min;
1.25  dholland 			param->yySeconds = tmbuf.tm_sec;
1.25  dholland 		} else {
1.25  dholland 			param->yyYear = EPOCH;
1.25  dholland 			param->yyMonth = 1;
1.25  dholland 			param->yyDay = 1;
 1.1  christos
1.25  dholland 			param->yyHour = 0;
1.25  dholland 			param->yyMinutes = 0;
1.25  dholland 			param->yySeconds = 0;
1.25  dholland 		}
1.25  dholland 		param->yyHaveFullYear = 1;
1.25  dholland 		param->yyDSTmode = DSToff;
1.25  dholland 		param->yyTimezone = 0;
1.25  dholland 	}
1.25  dholland ;
1.25  dholland
1.25  dholland at_number:
1.25  dholland 	  tUNUMBER
1.25  dholland 	| tSNUMBER
1.25  dholland ;
1.25  dholland
1.25  dholland time:
1.25  dholland 	  tUNUMBER tMERIDIAN {
 1.9  christos 		param->yyMinutes = 0;
 1.9  christos 		param->yySeconds = 0;
1.31       kre 		if ($2 == MER_NOON || $2 == MER_MN) {
1.31       kre 			if ($1 == 12) {
1.31       kre 				switch ($2) {
1.31       kre 				case MER_NOON: param->yyHour = 12; break;
1.31       kre 				case MER_MN  : param->yyHour = 0;  break;
1.31       kre 				default:	/* impossible */;  break;
1.31       kre 				}
1.31       kre 				param->yyMeridian = MER24;
1.31       kre 			} else
1.31       kre 				YYREJECT;
1.31       kre 		} else {
1.31       kre 			param->yyHour = $1;
1.31       kre 			param->yyMeridian = $2;
1.31       kre 		}
1.25  dholland 	  }
 1.1  christos 	| tUNUMBER ':' tUNUMBER o_merid {
1.25  dholland 		param->yyMinutes = $3;
1.25  dholland 		param->yySeconds = 0;
1.31       kre 		if ($4 == MER_NOON || $4 == MER_MN) {
1.31       kre 			if ($1 == 12 && $3 == 0) {
1.31       kre 				switch ($4) {
1.31       kre 				case MER_NOON: param->yyHour = 12; break;
1.31       kre 				case MER_MN  : param->yyHour = 0;  break;
1.31       kre 				default:	/* impossible */;  break;
1.31       kre 				}
1.31       kre 				param->yyMeridian = MER24;
1.31       kre 			} else
1.31       kre 				YYREJECT;
1.31       kre 		} else {
1.31       kre 			param->yyHour = $1;
1.31       kre 			param->yyMeridian = $4;
1.31       kre 		}
1.25  dholland 	  }
1.19       apb 	| tUNUMBER ':' tUNUMBER ':' tUNUMBER o_merid {
1.25  dholland 		param->yyMinutes = $3;
1.25  dholland 		param->yySeconds = $5;
1.31       kre 		if ($6 == MER_NOON || $6 == MER_MN) {
1.31       kre 			if ($1 == 12 && $3 == 0 && $5 == 0) {
1.31       kre 				switch ($6) {
1.31       kre 				case MER_NOON: param->yyHour = 12; break;
1.31       kre 				case MER_MN  : param->yyHour = 0;  break;
1.31       kre 				default:	/* impossible */;  break;
1.31       kre 				}
1.31       kre 				param->yyMeridian = MER24;
1.31       kre 			} else
1.31       kre 				YYREJECT;
1.31       kre 		} else {
1.31       kre 			param->yyHour = $1;
1.31       kre 			param->yyMeridian = $6;
1.31       kre 		}
1.25  dholland 	  }
1.19       apb 	| tUNUMBER ':' tUNUMBER ':' tUNUMBER '.' tUNUMBER {
1.25  dholland 		param->yyHour = $1;
1.25  dholland 		param->yyMinutes = $3;
1.25  dholland 		param->yySeconds = $5;
1.25  dholland 		param->yyMeridian = MER24;
1.33       kre 		/* XXX: Do nothing with fractional secs ($7) */
1.33       kre 	  }
1.33       kre 	| tUNUMBER ':' tUNUMBER ':' tUNUMBER ',' tUNUMBER {
1.33       kre 		param->yyHour = $1;
1.33       kre 		param->yyMinutes = $3;
1.33       kre 		param->yySeconds = $5;
1.33       kre 		param->yyMeridian = MER24;
1.33       kre 		/* XXX: Do nothing with fractional seconds ($7) */
1.25  dholland 	  }
1.23  christos 	| tTIME {
1.25  dholland 		param->yyHour = $1;
1.25  dholland 		param->yyMinutes = 0;
1.25  dholland 		param->yySeconds = 0;
1.25  dholland 		param->yyMeridian = MER24;
1.25  dholland 		/* Tues midnight --> Weds 00:00, midnight Tues -> Tues 00:00 */
1.25  dholland 		if ($1 == 0 && param->yyHaveDay)
1.25  dholland 			param->yyDayNumber++;
1.31       kre 	  }
1.31       kre 	| tUNUMBER tTIME {
1.31       kre 		if ($1 == 12 && ($2 == 0 || $2 == 12)) {
1.31       kre 			param->yyHour = $2;
1.31       kre 			param->yyMinutes = 0;
1.31       kre 			param->yySeconds = 0;
1.31       kre 			param->yyMeridian = MER24;
1.31       kre 		} else
1.31       kre 			YYREJECT;
1.31       kre 	  }
1.25  dholland ;
1.25  dholland
1.25  dholland time_numericzone:
1.25  dholland 	  tUNUMBER ':' tUNUMBER tSNUMBER {
1.25  dholland 		param->yyHour = $1;
1.25  dholland 		param->yyMinutes = $3;
1.25  dholland 		param->yyMeridian = MER24;
1.25  dholland 		param->yyDSTmode = DSToff;
1.25  dholland 		param->yyTimezone = - ($4 % 100 + ($4 / 100) * 60);
1.25  dholland 	  }
1.19       apb 	| tUNUMBER ':' tUNUMBER ':' tUNUMBER tSNUMBER {
1.25  dholland 		param->yyHour = $1;
1.25  dholland 		param->yyMinutes = $3;
1.25  dholland 		param->yySeconds = $5;
1.25  dholland 		param->yyMeridian = MER24;
1.25  dholland 		param->yyDSTmode = DSToff;
1.25  dholland 		param->yyTimezone = - ($6 % 100 + ($6 / 100) * 60);
1.25  dholland 	}
1.25  dholland ;
1.25  dholland
1.25  dholland zone:
1.25  dholland 	  tZONE		{ param->yyTimezone = $1; param->yyDSTmode = DSToff; }
1.25  dholland 	| tDAYZONE	{ param->yyTimezone = $1; param->yyDSTmode = DSTon; }
1.25  dholland 	| tZONE tDST	{ param->yyTimezone = $1; param->yyDSTmode = DSTon; }
1.34       kre 	| tSNUMBER	{
1.34       kre 			  if (param->yyHaveDate == 0 && param->yyHaveTime == 0)
1.34       kre 				YYREJECT;
1.34       kre 			  param->yyTimezone = - ($1 % 100 + ($1 / 100) * 60);
1.34       kre 			  param->yyDSTmode = DSTmaybe;
1.34       kre 			}
1.25  dholland ;
1.25  dholland
1.25  dholland day:
1.25  dholland 	  tDAY		{ param->yyDayOrdinal = 1; param->yyDayNumber = $1; }
1.25  dholland 	| tDAY ','	{ param->yyDayOrdinal = 1; param->yyDayNumber = $1; }
1.25  dholland 	| tUNUMBER tDAY	{ param->yyDayOrdinal = $1; param->yyDayNumber = $2; }
1.25  dholland ;
 1.1  christos
1.25  dholland date:
1.25  dholland 	  tUNUMBER '/' tUNUMBER {
 1.9  christos 		param->yyMonth = $1;
 1.9  christos 		param->yyDay = $3;
1.25  dholland 	  }
1.25  dholland 	| tUNUMBER '/' tUNUMBER '/' tUNUMBER {
1.25  dholland 		if ($1 >= 100) {
1.25  dholland 			param->yyYear = $1;
1.25  dholland 			param->yyMonth = $3;
1.25  dholland 			param->yyDay = $5;
1.25  dholland 		} else {
1.25  dholland 			param->yyMonth = $1;
1.25  dholland 			param->yyDay = $3;
1.25  dholland 			param->yyYear = $5;
1.25  dholland 		}
1.25  dholland 	  }
 1.1  christos 	| tUNUMBER tSNUMBER tSNUMBER {
1.25  dholland 		/* ISO 8601 format.  yyyy-mm-dd.  */
1.25  dholland 		param->yyYear = $1;
1.25  dholland 		param->yyHaveFullYear = 1;
1.25  dholland 		param->yyMonth = -$2;
1.25  dholland 		param->yyDay = -$3;
1.25  dholland 	  }
 1.1  christos 	| tUNUMBER tMONTH tSNUMBER {
1.25  dholland 		/* e.g. 17-JUN-1992.  */
1.25  dholland 		param->yyDay = $1;
1.25  dholland 		param->yyMonth = $2;
1.25  dholland 		param->yyYear = -$3;
1.25  dholland 	  }
 1.1  christos 	| tMONTH tUNUMBER {
1.25  dholland 		param->yyMonth = $1;
1.25  dholland 		param->yyDay = $2;
1.25  dholland 	  }
 1.1  christos 	| tMONTH tUNUMBER ',' tUNUMBER {
1.25  dholland 		param->yyMonth = $1;
1.25  dholland 		param->yyDay = $2;
1.25  dholland 		param->yyYear = $4;
1.25  dholland 	  }
 1.1  christos 	| tUNUMBER tMONTH {
1.25  dholland 		param->yyMonth = $2;
1.25  dholland 		param->yyDay = $1;
1.25  dholland 	  }
 1.1  christos 	| tUNUMBER tMONTH tUNUMBER {
1.25  dholland 		param->yyMonth = $2;
1.25  dholland 		if ($1 < 35) {
1.25  dholland 			param->yyDay = $1;
1.25  dholland 			param->yyYear = $3;
1.25  dholland 		} else {
1.25  dholland 			param->yyDay = $3;
1.25  dholland 			param->yyYear = $1;
1.25  dholland 		}
1.25  dholland 	  }
1.25  dholland ;
 1.1  christos
1.25  dholland rel:
1.25  dholland 	  relunit
1.25  dholland 	| relunit tAGO {
1.28       kre 		param->yyRel[param->yyHaveRel].yyRelVal =
1.28       kre 		    -param->yyRel[param->yyHaveRel].yyRelVal;
1.25  dholland 	  }
1.25  dholland ;
1.25  dholland
1.25  dholland relunit:
1.28       kre 	  tUNUMBER tMINUTE_UNIT	{ RelVal(param, $1 * $2 * 60L, 0); }
1.28       kre 	| tSNUMBER tMINUTE_UNIT	{ RelVal(param, $1 * $2 * 60L, 0); }
1.28       kre 	| tMINUTE_UNIT		{ RelVal(param, $1 * 60L, 0); }
1.28       kre 	| tSNUMBER tSEC_UNIT	{ RelVal(param, $1, 0); }
1.28       kre 	| tUNUMBER tSEC_UNIT	{ RelVal(param, $1, 0); }
1.28       kre 	| tSEC_UNIT		{ RelVal(param, 1L, 0);  }
1.28       kre 	| tSNUMBER tMONTH_UNIT	{ RelVal(param, $1 * $2, 1); }
1.28       kre 	| tUNUMBER tMONTH_UNIT	{ RelVal(param, $1 * $2, 1); }
1.28       kre 	| tMONTH_UNIT		{ RelVal(param, $1, 1); }
1.25  dholland ;
1.25  dholland
1.25  dholland number:
1.25  dholland 	tUNUMBER {
1.25  dholland 		if (param->yyHaveTime && param->yyHaveDate &&
1.25  dholland 		    !param->yyHaveRel) {
1.25  dholland 			param->yyYear = $1;
1.25  dholland 		} else {
1.25  dholland 			if ($1 > 10000) {
1.25  dholland 				param->yyHaveDate++;
1.25  dholland 				param->yyDay = ($1)%100;
1.25  dholland 				param->yyMonth = ($1/100)%100;
1.25  dholland 				param->yyYear = $1/10000;
1.25  dholland 			}
1.25  dholland 			else {
1.25  dholland 				param->yyHaveTime++;
1.25  dholland 				if ($1 < 100) {
1.25  dholland 					param->yyHour = $1;
1.25  dholland 					param->yyMinutes = 0;
1.25  dholland 				}
1.25  dholland 				else {
1.25  dholland 					param->yyHour = $1 / 100;
1.25  dholland 					param->yyMinutes = $1 % 100;
1.25  dholland 				}
1.25  dholland 				param->yySeconds = 0;
1.25  dholland 				param->yyMeridian = MER24;
1.25  dholland 			}
 1.1  christos 		}
 1.1  christos 	}
1.25  dholland ;
 1.1  christos
1.25  dholland o_merid:
1.25  dholland 	  /* empty */		{ $$ = MER24; }
1.25  dholland 	| tMERIDIAN		{ $$ = $1; }
1.31       kre 	| tTIME			{ $$ = $1 == 0 ? MER_MN : MER_NOON; }
1.25  dholland ;
 1.1  christos
 1.1  christos %%
 1.1  christos
1.28       kre static short DaysInMonth[12] = {
1.28       kre     31, 28, 31, 30, 31, 30,
1.28       kre     31, 31, 30, 31, 30, 31
1.28       kre };
1.28       kre
1.28       kre /*
1.28       kre  * works with tm.tm_year (ie: rel to 1900)
1.28       kre  */
1.28       kre #define	isleap(yr)  (((yr) & 3) == 0 && (((yr) % 100) != 0 || \
1.28       kre 			((1900+(yr)) % 400) == 0))
1.28       kre
 1.1  christos /* Month and day table. */
1.12     joerg static const TABLE MonthDayTable[] = {
 1.1  christos     { "january",	tMONTH,  1 },
 1.1  christos     { "february",	tMONTH,  2 },
 1.1  christos     { "march",		tMONTH,  3 },
 1.1  christos     { "april",		tMONTH,  4 },
 1.1  christos     { "may",		tMONTH,  5 },
 1.1  christos     { "june",		tMONTH,  6 },
 1.1  christos     { "july",		tMONTH,  7 },
 1.1  christos     { "august",		tMONTH,  8 },
 1.1  christos     { "september",	tMONTH,  9 },
 1.1  christos     { "sept",		tMONTH,  9 },
 1.1  christos     { "october",	tMONTH, 10 },
 1.1  christos     { "november",	tMONTH, 11 },
 1.1  christos     { "december",	tMONTH, 12 },
 1.1  christos     { "sunday",		tDAY, 0 },
1.21  christos     { "su",		tDAY, 0 },
 1.1  christos     { "monday",		tDAY, 1 },
1.21  christos     { "mo",		tDAY, 1 },
 1.1  christos     { "tuesday",	tDAY, 2 },
 1.1  christos     { "tues",		tDAY, 2 },
1.21  christos     { "tu",		tDAY, 2 },
 1.1  christos     { "wednesday",	tDAY, 3 },
 1.1  christos     { "wednes",		tDAY, 3 },
1.21  christos     { "weds",		tDAY, 3 },
1.21  christos     { "we",		tDAY, 3 },
 1.1  christos     { "thursday",	tDAY, 4 },
1.21  christos     { "thurs",		tDAY, 4 },
 1.1  christos     { "thur",		tDAY, 4 },
1.21  christos     { "th",		tDAY, 4 },
 1.1  christos     { "friday",		tDAY, 5 },
1.21  christos     { "fr",		tDAY, 5 },
 1.1  christos     { "saturday",	tDAY, 6 },
1.21  christos     { "sa",		tDAY, 6 },
 1.1  christos     { NULL,		0,    0 }
 1.1  christos };
 1.1  christos
 1.1  christos /* Time units table. */
1.12     joerg static const TABLE UnitsTable[] = {
 1.1  christos     { "year",		tMONTH_UNIT,	12 },
 1.1  christos     { "month",		tMONTH_UNIT,	1 },
 1.1  christos     { "fortnight",	tMINUTE_UNIT,	14 * 24 * 60 },
 1.1  christos     { "week",		tMINUTE_UNIT,	7 * 24 * 60 },
 1.1  christos     { "day",		tMINUTE_UNIT,	1 * 24 * 60 },
 1.1  christos     { "hour",		tMINUTE_UNIT,	60 },
 1.1  christos     { "minute",		tMINUTE_UNIT,	1 },
 1.1  christos     { "min",		tMINUTE_UNIT,	1 },
 1.1  christos     { "second",		tSEC_UNIT,	1 },
 1.1  christos     { "sec",		tSEC_UNIT,	1 },
 1.1  christos     { NULL,		0,		0 }
 1.1  christos };
 1.1  christos
 1.1  christos /* Assorted relative-time words. */
1.12     joerg static const TABLE OtherTable[] = {
 1.1  christos     { "tomorrow",	tMINUTE_UNIT,	1 * 24 * 60 },
 1.1  christos     { "yesterday",	tMINUTE_UNIT,	-1 * 24 * 60 },
 1.1  christos     { "today",		tMINUTE_UNIT,	0 },
 1.1  christos     { "now",		tMINUTE_UNIT,	0 },
 1.1  christos     { "last",		tUNUMBER,	-1 },
 1.1  christos     { "this",		tMINUTE_UNIT,	0 },
 1.1  christos     { "next",		tUNUMBER,	2 },
 1.1  christos     { "first",		tUNUMBER,	1 },
 1.7  christos     { "one",		tUNUMBER,	1 },
 1.1  christos /*  { "second",		tUNUMBER,	2 }, */
 1.7  christos     { "two",		tUNUMBER,	2 },
 1.1  christos     { "third",		tUNUMBER,	3 },
 1.7  christos     { "three",		tUNUMBER,	3 },
 1.1  christos     { "fourth",		tUNUMBER,	4 },
 1.7  christos     { "four",		tUNUMBER,	4 },
 1.1  christos     { "fifth",		tUNUMBER,	5 },
 1.7  christos     { "five",		tUNUMBER,	5 },
 1.1  christos     { "sixth",		tUNUMBER,	6 },
 1.7  christos     { "six",		tUNUMBER,	6 },
 1.1  christos     { "seventh",	tUNUMBER,	7 },
 1.7  christos     { "seven",		tUNUMBER,	7 },
 1.1  christos     { "eighth",		tUNUMBER,	8 },
 1.7  christos     { "eight",		tUNUMBER,	8 },
 1.1  christos     { "ninth",		tUNUMBER,	9 },
 1.7  christos     { "nine",		tUNUMBER,	9 },
 1.1  christos     { "tenth",		tUNUMBER,	10 },
 1.7  christos     { "ten",		tUNUMBER,	10 },
 1.1  christos     { "eleventh",	tUNUMBER,	11 },
 1.7  christos     { "eleven",		tUNUMBER,	11 },
 1.1  christos     { "twelfth",	tUNUMBER,	12 },
 1.7  christos     { "twelve",		tUNUMBER,	12 },
 1.1  christos     { "ago",		tAGO,	1 },
 1.1  christos     { NULL,		0,	0 }
 1.1  christos };
 1.1  christos
 1.1  christos /* The timezone table. */
 1.1  christos /* Some of these are commented out because a time_t can't store a float. */
1.12     joerg static const TABLE TimezoneTable[] = {
 1.1  christos     { "gmt",	tZONE,     HOUR( 0) },	/* Greenwich Mean */
 1.1  christos     { "ut",	tZONE,     HOUR( 0) },	/* Universal (Coordinated) */
 1.1  christos     { "utc",	tZONE,     HOUR( 0) },
 1.1  christos     { "wet",	tZONE,     HOUR( 0) },	/* Western European */
 1.1  christos     { "bst",	tDAYZONE,  HOUR( 0) },	/* British Summer */
 1.1  christos     { "wat",	tZONE,     HOUR( 1) },	/* West Africa */
 1.1  christos     { "at",	tZONE,     HOUR( 2) },	/* Azores */
 1.1  christos #if	0
 1.1  christos     /* For completeness.  BST is also British Summer, and GST is
 1.1  christos      * also Guam Standard. */
 1.1  christos     { "bst",	tZONE,     HOUR( 3) },	/* Brazil Standard */
 1.1  christos     { "gst",	tZONE,     HOUR( 3) },	/* Greenland Standard */
 1.1  christos #endif
 1.1  christos     { "nft",	tZONE,     HOUR(3.5) },	/* Newfoundland */
 1.1  christos     { "nst",	tZONE,     HOUR(3.5) },	/* Newfoundland Standard */
 1.1  christos     { "ndt",	tDAYZONE,  HOUR(3.5) },	/* Newfoundland Daylight */
 1.1  christos     { "ast",	tZONE,     HOUR( 4) },	/* Atlantic Standard */
 1.1  christos     { "adt",	tDAYZONE,  HOUR( 4) },	/* Atlantic Daylight */
 1.1  christos     { "est",	tZONE,     HOUR( 5) },	/* Eastern Standard */
 1.1  christos     { "edt",	tDAYZONE,  HOUR( 5) },	/* Eastern Daylight */
 1.1  christos     { "cst",	tZONE,     HOUR( 6) },	/* Central Standard */
 1.1  christos     { "cdt",	tDAYZONE,  HOUR( 6) },	/* Central Daylight */
 1.1  christos     { "mst",	tZONE,     HOUR( 7) },	/* Mountain Standard */
 1.1  christos     { "mdt",	tDAYZONE,  HOUR( 7) },	/* Mountain Daylight */
 1.1  christos     { "pst",	tZONE,     HOUR( 8) },	/* Pacific Standard */
 1.1  christos     { "pdt",	tDAYZONE,  HOUR( 8) },	/* Pacific Daylight */
 1.1  christos     { "yst",	tZONE,     HOUR( 9) },	/* Yukon Standard */
 1.1  christos     { "ydt",	tDAYZONE,  HOUR( 9) },	/* Yukon Daylight */
 1.1  christos     { "hst",	tZONE,     HOUR(10) },	/* Hawaii Standard */
 1.1  christos     { "hdt",	tDAYZONE,  HOUR(10) },	/* Hawaii Daylight */
 1.1  christos     { "cat",	tZONE,     HOUR(10) },	/* Central Alaska */
 1.1  christos     { "ahst",	tZONE,     HOUR(10) },	/* Alaska-Hawaii Standard */
 1.1  christos     { "nt",	tZONE,     HOUR(11) },	/* Nome */
 1.1  christos     { "idlw",	tZONE,     HOUR(12) },	/* International Date Line West */
 1.1  christos     { "cet",	tZONE,     -HOUR(1) },	/* Central European */
 1.1  christos     { "met",	tZONE,     -HOUR(1) },	/* Middle European */
 1.1  christos     { "mewt",	tZONE,     -HOUR(1) },	/* Middle European Winter */
 1.1  christos     { "mest",	tDAYZONE,  -HOUR(1) },	/* Middle European Summer */
 1.1  christos     { "swt",	tZONE,     -HOUR(1) },	/* Swedish Winter */
 1.1  christos     { "sst",	tDAYZONE,  -HOUR(1) },	/* Swedish Summer */
 1.1  christos     { "fwt",	tZONE,     -HOUR(1) },	/* French Winter */
 1.1  christos     { "fst",	tDAYZONE,  -HOUR(1) },	/* French Summer */
 1.1  christos     { "eet",	tZONE,     -HOUR(2) },	/* Eastern Europe, USSR Zone 1 */
 1.1  christos     { "bt",	tZONE,     -HOUR(3) },	/* Baghdad, USSR Zone 2 */
 1.1  christos     { "it",	tZONE,     -HOUR(3.5) },/* Iran */
 1.1  christos     { "zp4",	tZONE,     -HOUR(4) },	/* USSR Zone 3 */
 1.1  christos     { "zp5",	tZONE,     -HOUR(5) },	/* USSR Zone 4 */
 1.1  christos     { "ist",	tZONE,     -HOUR(5.5) },/* Indian Standard */
 1.1  christos     { "zp6",	tZONE,     -HOUR(6) },	/* USSR Zone 5 */
 1.1  christos #if	0
 1.1  christos     /* For completeness.  NST is also Newfoundland Stanard, and SST is
 1.1  christos      * also Swedish Summer. */
 1.1  christos     { "nst",	tZONE,     -HOUR(6.5) },/* North Sumatra */
 1.1  christos     { "sst",	tZONE,     -HOUR(7) },	/* South Sumatra, USSR Zone 6 */
 1.1  christos #endif	/* 0 */
1.21  christos     { "ict",	tZONE,     -HOUR(7) },	/* Indo China Time (Thai) */
1.21  christos #if 0	/* this one looks to be bogus */
 1.1  christos     { "jt",	tZONE,     -HOUR(7.5) },/* Java (3pm in Cronusland!) */
 1.1  christos #endif
1.22  christos     { "wast",	tZONE,     -HOUR(8) },	/* West Australian Standard */
1.22  christos     { "awst",	tZONE,     -HOUR(8) },	/* West Australian Standard */
1.22  christos     { "wadt",	tDAYZONE,  -HOUR(8) },	/* West Australian Daylight */
1.22  christos     { "awdt",	tDAYZONE,  -HOUR(8) },	/* West Australian Daylight */
 1.1  christos     { "cct",	tZONE,     -HOUR(8) },	/* China Coast, USSR Zone 7 */
1.21  christos     { "sgt",	tZONE,     -HOUR(8) },	/* Singapore */
1.21  christos     { "hkt",	tZONE,     -HOUR(8) },	/* Hong Kong */
 1.1  christos     { "jst",	tZONE,     -HOUR(9) },	/* Japan Standard, USSR Zone 8 */
 1.1  christos     { "cast",	tZONE,     -HOUR(9.5) },/* Central Australian Standard */
1.21  christos     { "acst",	tZONE,     -HOUR(9.5) },/* Central Australian Standard */
 1.1  christos     { "cadt",	tDAYZONE,  -HOUR(9.5) },/* Central Australian Daylight */
1.21  christos     { "acdt",	tDAYZONE,  -HOUR(9.5) },/* Central Australian Daylight */
 1.1  christos     { "east",	tZONE,     -HOUR(10) },	/* Eastern Australian Standard */
1.21  christos     { "aest",	tZONE,     -HOUR(10) },	/* Eastern Australian Standard */
 1.1  christos     { "eadt",	tDAYZONE,  -HOUR(10) },	/* Eastern Australian Daylight */
1.21  christos     { "aedt",	tDAYZONE,  -HOUR(10) },	/* Eastern Australian Daylight */
 1.1  christos     { "gst",	tZONE,     -HOUR(10) },	/* Guam Standard, USSR Zone 9 */
 1.1  christos     { "nzt",	tZONE,     -HOUR(12) },	/* New Zealand */
 1.1  christos     { "nzst",	tZONE,     -HOUR(12) },	/* New Zealand Standard */
 1.1  christos     { "nzdt",	tDAYZONE,  -HOUR(12) },	/* New Zealand Daylight */
 1.1  christos     { "idle",	tZONE,     -HOUR(12) },	/* International Date Line East */
 1.1  christos     {  NULL,	0,	    0 }
 1.1  christos };
 1.1  christos
 1.1  christos /* Military timezone table. */
1.12     joerg static const TABLE MilitaryTable[] = {
 1.1  christos     { "a",	tZONE,	HOUR(  1) },
 1.1  christos     { "b",	tZONE,	HOUR(  2) },
 1.1  christos     { "c",	tZONE,	HOUR(  3) },
 1.1  christos     { "d",	tZONE,	HOUR(  4) },
 1.1  christos     { "e",	tZONE,	HOUR(  5) },
 1.1  christos     { "f",	tZONE,	HOUR(  6) },
 1.1  christos     { "g",	tZONE,	HOUR(  7) },
 1.1  christos     { "h",	tZONE,	HOUR(  8) },
 1.1  christos     { "i",	tZONE,	HOUR(  9) },
 1.1  christos     { "k",	tZONE,	HOUR( 10) },
 1.1  christos     { "l",	tZONE,	HOUR( 11) },
 1.1  christos     { "m",	tZONE,	HOUR( 12) },
 1.1  christos     { "n",	tZONE,	HOUR(- 1) },
 1.1  christos     { "o",	tZONE,	HOUR(- 2) },
 1.1  christos     { "p",	tZONE,	HOUR(- 3) },
 1.1  christos     { "q",	tZONE,	HOUR(- 4) },
 1.1  christos     { "r",	tZONE,	HOUR(- 5) },
 1.1  christos     { "s",	tZONE,	HOUR(- 6) },
 1.1  christos     { "t",	tZONE,	HOUR(- 7) },
 1.1  christos     { "u",	tZONE,	HOUR(- 8) },
 1.1  christos     { "v",	tZONE,	HOUR(- 9) },
 1.1  christos     { "w",	tZONE,	HOUR(-10) },
 1.1  christos     { "x",	tZONE,	HOUR(-11) },
 1.1  christos     { "y",	tZONE,	HOUR(-12) },
 1.1  christos     { "z",	tZONE,	HOUR(  0) },
 1.1  christos     { NULL,	0,	0 }
 1.1  christos };
 1.1  christos
1.23  christos static const TABLE TimeNames[] = {
1.23  christos     { "midnight",	tTIME,		 0 },
1.23  christos     { "mn",		tTIME,		 0 },
1.23  christos     { "noon",		tTIME,		12 },
1.28       kre     { "midday",		tTIME,		12 },
1.23  christos     { NULL,		0,		 0 }
1.23  christos };
1.23  christos
 1.1  christos
 1.1  christos
 1.1  christos /* ARGSUSED */
 1.9  christos static int
 1.1  christos yyerror(struct dateinfo *param, const char **inp, const char *s __unused)
 1.1  christos {
 1.1  christos   return 0;
 1.1  christos }
1.28       kre
1.28       kre /*
1.28       kre  * Save a relative value, if it fits
1.28       kre  */
1.28       kre static void
1.28       kre RelVal(struct dateinfo *param, time_t v, int type)
1.28       kre {
1.28       kre 	int i;
1.28       kre
1.28       kre 	if ((i = param->yyHaveRel) >= MAXREL)
1.28       kre 		return;
1.28       kre 	param->yyRel[i].yyRelMonth = type;
1.28       kre 	param->yyRel[i].yyRelVal = v;
1.28       kre }
1.32       kre
1.32       kre /*
1.17       apb  * Adjust year from a value that might be abbreviated, to a full value.
1.17       apb  * e.g. convert 70 to 1970.
1.17       apb  * Input Year is either:
1.33       kre  *  - A negative number, which means to use its absolute value (why?)
1.33       kre  *  - A number from 0 to 68, which means a year from 2000 to 2068,
1.17       apb  *  - A number from 69 to 99, which means a year from 1969 to 1999, or
1.32       kre  *  - The actual year (>=100).
1.32       kre  * Returns the full year.
1.17       apb  */
1.17       apb static time_t
1.17       apb AdjustYear(time_t Year)
1.17       apb {
1.17       apb     /* XXX Y2K */
1.17       apb     if (Year < 0)
1.33       kre 	Year = -Year;
1.17       apb     if (Year < 69)	/* POSIX compliant, 0..68 is 2000's, 69-99 1900's */
1.17       apb 	Year += 2000;
1.17       apb     else if (Year < 100)
1.17       apb 	Year += 1900;
1.17       apb     return Year;
1.17       apb }
 1.1  christos
 1.1  christos static time_t
1.11       apb Convert(
1.11       apb     time_t	Month,		/* month of year [1-12] */
1.17       apb     time_t	Day,		/* day of month [1-31] */
1.11       apb     time_t	Year,		/* year, not abbreviated in any way */
1.11       apb     time_t	Hours,		/* Hour of day [0-24] */
1.11       apb     time_t	Minutes,	/* Minute of hour [0-59] */
1.20       apb     time_t	Seconds,	/* Second of minute [0-60] */
1.20       apb     time_t	Timezone,	/* Timezone as minutes east of UTC,
1.11       apb 				 * or USE_LOCAL_TIME special case */
1.11       apb     MERIDIAN	Meridian,	/* Hours are am/pm/24 hour clock */
 1.1  christos     DSTMODE	DSTmode		/* DST on/off/maybe */
 1.1  christos )
1.13       apb {
1.23  christos     struct tm tm = {.tm_sec = 0};
1.13       apb     struct tm otm;
 1.1  christos     time_t result;
1.11       apb
1.11       apb     tm.tm_sec = Seconds;
1.30       kre     tm.tm_min = Minutes;
1.30       kre     tm.tm_hour = ((Hours == 12 && Meridian != MER24) ? 0 : Hours) +
1.30       kre 	(Meridian == MERpm ? 12 : 0);
1.11       apb
1.11       apb     tm.tm_mday = Day;
1.11       apb     tm.tm_mon = Month - 1;
1.20       apb     tm.tm_year = Year - 1900;
1.21  christos     if (Timezone == USE_LOCAL_TIME) {
1.21  christos 	    switch (DSTmode) {
1.21  christos 	    case DSTon:  tm.tm_isdst = 1; break;
1.21  christos 	    case DSToff: tm.tm_isdst = 0; break;
1.21  christos 	    default:     tm.tm_isdst = -1; break;
1.24  christos 	    }
1.20       apb 	    otm = tm;
1.20       apb 	    result = mktime(&tm);
1.20       apb     } else {
1.21  christos 	    /* We rely on mktime_z(NULL, ...) working in UTC */
1.24  christos 	    tm.tm_isdst = 0;	/* hence cannot be summer time */
1.21  christos 	    otm = tm;
1.20       apb 	    errno = 0;
1.21  christos 	    result = mktime_z(NULL, &tm);
1.21  christos 	    if (result != -1 || errno == 0) {
1.21  christos 		    result += Timezone * 60;
1.21  christos 		    if (DSTmode == DSTon)	/* if specified sumer time */
1.21  christos 			result -= 3600;		/* UTC is 1 hour earlier XXX */
1.20       apb 	    }
1.20       apb     }
1.20       apb
1.20       apb #if PARSEDATE_DEBUG
1.20       apb     fprintf(stderr, "%s(M=%jd D=%jd Y=%jd H=%jd M=%jd S=%jd Z=%jd"
1.20       apb 		    " mer=%d DST=%d)",
1.20       apb 	__func__,
1.20       apb 	(intmax_t)Month, (intmax_t)Day, (intmax_t)Year,
1.20       apb 	(intmax_t)Hours, (intmax_t)Minutes, (intmax_t)Seconds,
1.20       apb 	(intmax_t)Timezone, (int)Meridian, (int)DSTmode);
1.20       apb     fprintf(stderr, " -> %jd", (intmax_t)result);
1.20       apb     fprintf(stderr, " %s", ctime(&result));
1.20       apb #endif
1.23  christos
1.23  christos #define	TM_NE(fld) (otm.tm_ ## fld != tm.tm_ ## fld)
1.23  christos     if (TM_NE(year) || TM_NE(mon) || TM_NE(mday) ||
1.23  christos 	TM_NE(hour) || TM_NE(min) || TM_NE(sec)) {
1.23  christos 	    /* mktime() "corrected" our tm, so it must have been invalid */
1.23  christos 	    result = -1;
1.23  christos 	    errno = EAGAIN;
1.23  christos     }
1.23  christos #undef	TM_NE
1.13       apb
 1.1  christos     return result;
 1.1  christos }
 1.1  christos
 1.1  christos
 1.1  christos static time_t
 1.1  christos DSTcorrect(
 1.1  christos     time_t	Start,
 1.1  christos     time_t	Future
 1.1  christos )
 1.1  christos {
 1.1  christos     time_t	StartDay;
1.26  dholland     time_t	FutureDay;
 1.6  christos     struct tm	tm;
1.26  dholland
 1.6  christos     if (localtime_r(&Start, &tm) == NULL)
1.26  dholland 	return -1;
 1.6  christos     StartDay = (tm.tm_hour + 1) % 24;
1.26  dholland
 1.6  christos     if (localtime_r(&Future, &tm) == NULL)
1.26  dholland 	return -1;
 1.1  christos     FutureDay = (tm.tm_hour + 1) % 24;
 1.1  christos
 1.1  christos     return (Future - Start) + (StartDay - FutureDay) * 60L * 60L;
 1.1  christos }
 1.1  christos
 1.1  christos
 1.1  christos static time_t
 1.1  christos RelativeDate(
 1.1  christos     time_t	Start,
 1.1  christos     time_t	DayOrdinal,
 1.1  christos     time_t	DayNumber
 1.1  christos )
1.26  dholland {
 1.1  christos     struct tm	tm;
 1.1  christos     time_t	now;
 1.1  christos
1.26  dholland     now = Start;
1.21  christos     if (localtime_r(&now, &tm) == NULL)
1.26  dholland 	return -1;
 1.1  christos     now += SECSPERDAY * ((DayNumber - tm.tm_wday + 7) % 7);
 1.1  christos     now += 7 * SECSPERDAY * (DayOrdinal <= 0 ? DayOrdinal : DayOrdinal - 1);
 1.1  christos     return DSTcorrect(Start, now);
 1.1  christos }
 1.1  christos
 1.1  christos
 1.1  christos static time_t
 1.1  christos RelativeMonth(
 1.9  christos     time_t	Start,
 1.9  christos     time_t	RelMonth,
 1.1  christos     time_t	Timezone
 1.1  christos )
1.26  dholland {
 1.1  christos     struct tm	tm;
1.27  dholland     time_t	Month;
1.28       kre     time_t	Then;
 1.1  christos     int		Day;
 1.1  christos
 1.1  christos     if (RelMonth == 0)
1.27  dholland 	return 0;
1.27  dholland     /*
1.27  dholland      * It doesn't matter what timezone we use to do this computation,
1.27  dholland      * as long as we use the same one to reassemble the time that we
1.27  dholland      * used to disassemble it. So always use localtime and mktime. In
1.27  dholland      * particular, don't use Convert() to reassemble, because it will
1.27  dholland      * not only reassemble with the wrong timezone but it will also
1.27  dholland      * fail if we do e.g. three months from March 31 yielding July 1.
1.27  dholland      */
1.27  dholland     (void)Timezone;
1.26  dholland
 1.6  christos     if (localtime_r(&Start, &tm) == NULL)
1.27  dholland 	return -1;
1.26  dholland
1.27  dholland     Month = 12 * (tm.tm_year + 1900) + tm.tm_mon + RelMonth;
1.27  dholland     tm.tm_year = (Month / 12) - 1900;
1.28       kre     tm.tm_mon = Month % 12;
1.28       kre     if (tm.tm_mday > (Day = DaysInMonth[tm.tm_mon] +
1.28       kre 	((tm.tm_mon==1) ? isleap(tm.tm_year) : 0)))
1.27  dholland 	    tm.tm_mday = Day;
1.27  dholland     errno = 0;
1.27  dholland     Then = mktime(&tm);
1.27  dholland     if (Then == -1 && errno != 0)
1.27  dholland 	return -1;
 1.1  christos     return DSTcorrect(Start, Then);
 1.1  christos }
 1.1  christos
 1.1  christos
 1.9  christos static int
 1.1  christos LookupWord(YYSTYPE *yylval, char *buff)
 1.1  christos {
 1.1  christos     register char	*p;
 1.1  christos     register char	*q;
 1.1  christos     register const TABLE	*tp;
 1.1  christos     int			i;
 1.1  christos     int			abbrev;
 1.1  christos
 1.1  christos     /* Make it lowercase. */
 1.1  christos     for (p = buff; *p; p++)
 1.1  christos 	if (isupper((unsigned char)*p))
 1.1  christos 	    *p = tolower((unsigned char)*p);
 1.1  christos
 1.9  christos     if (strcmp(buff, "am") == 0 || strcmp(buff, "a.m.") == 0) {
 1.1  christos 	yylval->Meridian = MERam;
 1.1  christos 	return tMERIDIAN;
 1.1  christos     }
 1.9  christos     if (strcmp(buff, "pm") == 0 || strcmp(buff, "p.m.") == 0) {
 1.1  christos 	yylval->Meridian = MERpm;
 1.1  christos 	return tMERIDIAN;
 1.1  christos     }
 1.1  christos
 1.1  christos     /* See if we have an abbreviation for a month. */
 1.1  christos     if (strlen(buff) == 3)
 1.1  christos 	abbrev = 1;
 1.1  christos     else if (strlen(buff) == 4 && buff[3] == '.') {
 1.1  christos 	abbrev = 1;
 1.1  christos 	buff[3] = '\0';
 1.1  christos     }
 1.1  christos     else
 1.1  christos 	abbrev = 0;
 1.1  christos
 1.1  christos     for (tp = MonthDayTable; tp->name; tp++) {
 1.1  christos 	if (abbrev) {
 1.9  christos 	    if (strncmp(buff, tp->name, 3) == 0) {
 1.1  christos 		yylval->Number = tp->value;
 1.1  christos 		return tp->type;
 1.1  christos 	    }
 1.1  christos 	}
 1.9  christos 	else if (strcmp(buff, tp->name) == 0) {
 1.1  christos 	    yylval->Number = tp->value;
 1.1  christos 	    return tp->type;
 1.1  christos 	}
 1.1  christos     }
 1.1  christos
 1.1  christos     for (tp = TimezoneTable; tp->name; tp++)
 1.9  christos 	if (strcmp(buff, tp->name) == 0) {
 1.1  christos 	    yylval->Number = tp->value;
 1.1  christos 	    return tp->type;
 1.1  christos 	}
 1.1  christos
 1.1  christos     if (strcmp(buff, "dst") == 0)
 1.1  christos 	return tDST;
1.23  christos
1.23  christos     for (tp = TimeNames; tp->name; tp++)
1.23  christos 	if (strcmp(buff, tp->name) == 0) {
1.23  christos 	    yylval->Number = tp->value;
1.23  christos 	    return tp->type;
1.23  christos 	}
 1.1  christos
 1.1  christos     for (tp = UnitsTable; tp->name; tp++)
 1.9  christos 	if (strcmp(buff, tp->name) == 0) {
 1.1  christos 	    yylval->Number = tp->value;
 1.1  christos 	    return tp->type;
 1.1  christos 	}
 1.1  christos
 1.1  christos     /* Strip off any plural and try the units table again. */
 1.1  christos     i = strlen(buff) - 1;
 1.1  christos     if (buff[i] == 's') {
 1.1  christos 	buff[i] = '\0';
 1.1  christos 	for (tp = UnitsTable; tp->name; tp++)
 1.9  christos 	    if (strcmp(buff, tp->name) == 0) {
 1.1  christos 		yylval->Number = tp->value;
 1.1  christos 		return tp->type;
 1.1  christos 	    }
 1.1  christos 	buff[i] = 's';		/* Put back for "this" in OtherTable. */
 1.1  christos     }
 1.1  christos
 1.1  christos     for (tp = OtherTable; tp->name; tp++)
 1.9  christos 	if (strcmp(buff, tp->name) == 0) {
 1.1  christos 	    yylval->Number = tp->value;
 1.1  christos 	    return tp->type;
 1.1  christos 	}
 1.1  christos
 1.1  christos     /* Military timezones. */
 1.1  christos     if (buff[1] == '\0' && isalpha((unsigned char)*buff)) {
 1.1  christos 	for (tp = MilitaryTable; tp->name; tp++)
 1.9  christos 	    if (strcmp(buff, tp->name) == 0) {
 1.1  christos 		yylval->Number = tp->value;
 1.1  christos 		return tp->type;
 1.1  christos 	    }
 1.1  christos     }
 1.1  christos
 1.1  christos     /* Drop out any periods and try the timezone table again. */
 1.1  christos     for (i = 0, p = q = buff; *q; q++)
 1.1  christos 	if (*q != '.')
 1.1  christos 	    *p++ = *q;
 1.1  christos 	else
 1.1  christos 	    i++;
 1.1  christos     *p = '\0';
 1.1  christos     if (i)
 1.1  christos 	for (tp = TimezoneTable; tp->name; tp++)
 1.9  christos 	    if (strcmp(buff, tp->name) == 0) {
 1.1  christos 		yylval->Number = tp->value;
 1.1  christos 		return tp->type;
 1.1  christos 	    }
 1.1  christos
 1.1  christos     return tID;
 1.1  christos }
 1.1  christos
 1.1  christos
 1.9  christos static int
 1.1  christos yylex(YYSTYPE *yylval, const char **yyInput)
 1.1  christos {
 1.1  christos     register char	c;
 1.1  christos     register char	*p;
 1.1  christos     char		buff[20];
 1.1  christos     int			Count;
 1.9  christos     int			sign;
 1.1  christos     const char		*inp = *yyInput;
 1.1  christos
 1.9  christos     for ( ; ; ) {
 1.9  christos 	while (isspace((unsigned char)*inp))
 1.1  christos 	    inp++;
 1.9  christos
 1.1  christos 	if (isdigit((unsigned char)(c = *inp)) || c == '-' || c == '+') {
 1.1  christos 	    if (c == '-' || c == '+') {
 1.9  christos 		sign = c == '-' ? -1 : 1;
 1.1  christos 		if (!isdigit((unsigned char)*++inp))
 1.1  christos 		    /* skip the '-' sign */
 1.1  christos 		    continue;
 1.1  christos 	    }
 1.1  christos 	    else
 1.9  christos 		sign = 0;
 1.9  christos 	    for (yylval->Number = 0; isdigit((unsigned char)(c = *inp++)); )
 1.1  christos 		yylval->Number = 10 * yylval->Number + c - '0';
 1.9  christos 	    if (sign < 0)
 1.9  christos 		yylval->Number = -yylval->Number;
 1.1  christos 	    *yyInput = --inp;
 1.1  christos 	    return sign ? tSNUMBER : tUNUMBER;
 1.1  christos 	}
 1.9  christos 	if (isalpha((unsigned char)c)) {
 1.1  christos 	    for (p = buff; isalpha((unsigned char)(c = *inp++)) || c == '.'; )
 1.1  christos 		if (p < &buff[sizeof buff - 1])
 1.1  christos 		    *p++ = c;
 1.9  christos 	    *p = '\0';
 1.9  christos 	    *yyInput = --inp;
 1.1  christos 	    return LookupWord(yylval, buff);
 1.5      tron 	}
 1.9  christos 	if (c == '@') {
 1.5      tron 	    *yyInput = ++inp;
 1.5      tron 	    return AT_SIGN;
 1.9  christos 	}
 1.9  christos 	if (c != '(') {
 1.9  christos 	    *yyInput = ++inp;
 1.9  christos 	    return c;
 1.1  christos 	}
 1.1  christos 	Count = 0;
 1.9  christos 	do {
 1.1  christos 	    c = *inp++;
 1.1  christos 	    if (c == '\0')
 1.1  christos 		return c;
 1.1  christos 	    if (c == '(')
 1.1  christos 		Count++;
 1.1  christos 	    else if (c == ')')
 1.1  christos 		Count--;
 1.1  christos 	} while (Count > 0);
 1.1  christos     }
 1.1  christos }
 1.1  christos
 1.1  christos #define TM_YEAR_ORIGIN 1900
 1.1  christos
 1.1  christos time_t
 1.1  christos parsedate(const char *p, const time_t *now, const int *zone)
1.20       apb {
 1.1  christos     struct tm		local, *tm;
 1.1  christos     time_t		nowt;
 1.1  christos     int			zonet;
 1.6  christos     time_t		Start;
 1.9  christos     time_t		tod, rm;
1.14       apb     struct dateinfo	param;
1.28       kre     int			saved_errno;
1.14       apb     int			i;
1.14       apb
1.14       apb     saved_errno = errno;
 1.1  christos     errno = 0;
1.20       apb
 1.1  christos     if (now == NULL) {
1.20       apb         now = &nowt;
1.20       apb 	(void)time(&nowt);
1.20       apb     }
 1.1  christos     if (zone == NULL) {
1.20       apb 	zone = &zonet;
 1.1  christos 	zonet = USE_LOCAL_TIME;
 1.1  christos 	if ((tm = localtime_r(now, &local)) == NULL)
 1.1  christos 	    return -1;
1.20       apb     } else {
1.20       apb 	/*
1.20       apb 	 * Should use the specified zone, not localtime.
1.20       apb 	 * Fake it using gmtime and arithmetic.
1.20       apb 	 * This is good enough because we use only the year/month/day,
1.20       apb 	 * not other fields of struct tm.
1.20       apb 	 */
1.20       apb 	time_t fake = *now + (*zone * 60);
 1.1  christos 	if ((tm = gmtime_r(&fake, &local)) == NULL)
 1.1  christos 	    return -1;
 1.9  christos     }
 1.9  christos     param.yyYear = tm->tm_year + 1900;
 1.9  christos     param.yyMonth = tm->tm_mon + 1;
 1.9  christos     param.yyDay = tm->tm_mday;
 1.9  christos     param.yyTimezone = *zone;
 1.9  christos     param.yyDSTmode = DSTmaybe;
 1.9  christos     param.yyHour = 0;
 1.9  christos     param.yyMinutes = 0;
 1.9  christos     param.yySeconds = 0;
 1.9  christos     param.yyMeridian = MER24;
1.17       apb     param.yyHaveDate = 0;
 1.9  christos     param.yyHaveFullYear = 0;
 1.9  christos     param.yyHaveDay = 0;
 1.9  christos     param.yyHaveRel = 0;
 1.9  christos     param.yyHaveTime = 0;
 1.9  christos     param.yyHaveZone = 0;
1.34       kre
1.34       kre     /*
1.34       kre      * This one is too hard to parse using a grammar (the lexer would
1.34       kre      * confuse the 'T' with the Mil format timezone designator)
1.34       kre      * so handle it as a special case.
1.34       kre      */
1.34       kre     do {
1.34       kre 	const unsigned char *pp = (const unsigned char *)p;
1.34       kre 	char *ep;	/* starts as "expected, becomes "end ptr" */
1.34       kre 	static char format[] = "-dd-ddTdd:dd:dd";
1.34       kre
1.34       kre 	while (isdigit(*pp))
1.34       kre 		pp++;
1.34       kre
1.34       kre 	if (pp == (const unsigned char *)p)
1.34       kre 		break;
1.34       kre
1.34       kre 	for (ep = format; *ep; ep++, pp++) {
1.34       kre 		switch (*ep) {
1.34       kre 		case 'd':
1.34       kre 			if (isdigit(*pp))
1.34       kre 				continue;
1.34       kre 			break;
1.34       kre 		case 'T':
1.34       kre 			if (*pp == 'T' || *pp == 't' || *pp == ' ')
1.34       kre 				continue;
1.34       kre 			break;
1.34       kre 		default:
1.34       kre 			if (*pp == *ep)
1.34       kre 				continue;
1.34       kre 			break;
1.34       kre 		}
1.34       kre 		break;
1.34       kre 	}
1.34       kre 	if (*ep != '\0')
1.34       kre 		break;
1.34       kre 	if (*pp == '.' || *pp == ',') {
1.34       kre 		if (!isdigit(pp[1]))
1.34       kre 			break;
1.34       kre 		while (isdigit(*++pp))
1.34       kre 			continue;
1.34       kre 	}
1.34       kre 	if (*pp == 'Z' || *pp == 'z')
1.34       kre 		pp++;
1.34       kre 	else if (isdigit(*pp))
1.34       kre 		break;
1.34       kre
1.34       kre 	if (*pp != '\0' && !isspace(*pp))
1.34       kre 		break;
1.34       kre
1.34       kre 	/*
1.34       kre 	 * This is good enough to commit to there being an ISO format
1.34       kre 	 * timestamp leading the input string.   We permit standard
1.34       kre 	 * parsedate() modifiers to follow but not precede this string.
1.34       kre 	 */
1.34       kre 	param.yyHaveTime = 1;
1.34       kre 	param.yyHaveDate = 1;
1.34       kre 	param.yyHaveFullYear = 1;
1.34       kre
1.34       kre 	if (pp[-1] == 'Z' || pp[-1] == 'z') {
1.34       kre 		param.yyTimezone = 0;
1.34       kre 		param.yyHaveZone = 1;
1.34       kre 	}
1.34       kre
1.34       kre 	errno = 0;
1.34       kre 	param.yyYear = (time_t)strtol(p, &ep, 10);
1.34       kre 	if (errno != 0)			/* out of range (can be big number) */
1.34       kre 		break;			/* the ones below are all 2 digits */
1.34       kre 	param.yyMonth = (time_t)strtol(ep + 1, &ep, 10);
1.34       kre 	param.yyDay = (time_t)strtol(ep + 1, &ep, 10);
1.34       kre 	param.yyHour = (time_t)strtol(ep + 1, &ep, 10);
1.34       kre 	param.yyMinutes = (time_t)strtol(ep + 1, &ep, 10);
1.34       kre 	param.yySeconds = (time_t)strtol(ep + 1, &ep, 10);
1.34       kre 	/* ignore any fractional seconds, no way to return them in a time_t */
1.34       kre
1.34       kre 	param.yyMeridian = MER24;
1.34       kre
1.34       kre 	p = (const char *)pp;
1.34       kre     } while (0);
 1.9  christos
1.14       apb     if (yyparse(&param, &p) || param.yyHaveTime > 1 || param.yyHaveZone > 1 ||
1.14       apb 	param.yyHaveDate > 1 || param.yyHaveDay > 1) {
 1.9  christos 	errno = EINVAL;
1.14       apb 	return -1;
 1.9  christos     }
 1.9  christos
1.17       apb     if (param.yyHaveDate || param.yyHaveTime || param.yyHaveDay) {
1.17       apb 	if (! param.yyHaveFullYear) {
1.17       apb 		param.yyYear = AdjustYear(param.yyYear);
1.17       apb 		param.yyHaveFullYear = 1;
1.21  christos 	}
 1.9  christos 	errno = 0;
 1.9  christos 	Start = Convert(param.yyMonth, param.yyDay, param.yyYear, param.yyHour,
 1.9  christos 	    param.yyMinutes, param.yySeconds, param.yyTimezone,
1.14       apb 	    param.yyMeridian, param.yyDSTmode);
 1.1  christos 	if (Start == -1 && errno != 0)
 1.1  christos 	    return -1;
 1.1  christos     }
 1.1  christos     else {
 1.9  christos 	Start = *now;
 1.1  christos 	if (!param.yyHaveRel)
 1.1  christos 	    Start -= ((tm->tm_hour * 60L + tm->tm_min) * 60L) + tm->tm_sec;
 1.1  christos     }
1.28       kre
1.28       kre     if (param.yyHaveRel > MAXREL) {
 1.6  christos 	errno = EINVAL;
1.28       kre 	return -1;
1.28       kre     }
1.28       kre     for (i = 0; i < param.yyHaveRel; i++) {
1.28       kre 	if (param.yyRel[i].yyRelMonth) {
1.28       kre 	    errno = 0;
1.28       kre 	    rm = RelativeMonth(Start, param.yyRel[i].yyRelVal, param.yyTimezone);
1.28       kre 	    if (rm == -1 && errno != 0)
1.28       kre 		return -1;
1.28       kre 	    Start += rm;
1.28       kre 	} else
1.28       kre 	    Start += param.yyRel[i].yyRelVal;
 1.1  christos     }
 1.9  christos
1.21  christos     if (param.yyHaveDay && !param.yyHaveDate) {
 1.9  christos 	errno = 0;
1.21  christos 	tod = RelativeDate(Start, param.yyDayOrdinal, param.yyDayNumber);
1.21  christos 	if (tod == -1 && errno != 0)
 1.1  christos 	    return -1;
 1.1  christos 	Start += tod;
 1.1  christos     }
1.21  christos
 1.6  christos     errno = saved_errno;
 1.1  christos     return Start;
 1.1  christos }
 1.1  christos
 1.1  christos
 1.1  christos #if	defined(TEST)
 1.1  christos
 1.1  christos /* ARGSUSED */
1.14       apb int
 1.1  christos main(int ac, char *av[])
 1.1  christos {
 1.1  christos     char	buff[128];
 1.1  christos     time_t	d;
 1.1  christos
 1.1  christos     (void)printf("Enter date, or blank line to exit.\n\t> ");
1.14       apb     (void)fflush(stdout);
1.14       apb     while (fgets(buff, sizeof(buff), stdin) && buff[0] != '\n') {
 1.1  christos 	errno = 0;
1.14       apb 	d = parsedate(buff, NULL, NULL);
1.14       apb 	if (d == -1 && errno != 0)
1.14       apb 	    (void)printf("Bad format - couldn't convert: %s\n",
 1.1  christos 	        strerror(errno));
1.14       apb 	else
 1.1  christos 	    (void)printf("%jd\t%s", (intmax_t)d, ctime(&d));
 1.1  christos 	(void)printf("\t> ");
 1.1  christos 	(void)fflush(stdout);
 1.1  christos     }
 1.1  christos     exit(0);
 1.1  christos     /* NOTREACHED */
 1.1  christos }
               #endif	/* defined(TEST) */