blob: 5dc9db01bc99ccdf0b8dd22c004f337e4805135b [file] [log] [blame]
/*
** This file is in the public domain, so clarified as of
** 2006-07-17 by Arthur David Olson.
*/
static char elsieid[] = "@(#)zic.c 8.18";
#include "private.h"
#include "locale.h"
#include "tzfile.h"
#define ZIC_VERSION '2'
typedef int_fast64_t zic_t;
#ifndef ZIC_MAX_ABBR_LEN_WO_WARN
#define ZIC_MAX_ABBR_LEN_WO_WARN 6
#endif /* !defined ZIC_MAX_ABBR_LEN_WO_WARN */
#if HAVE_SYS_STAT_H
#include "sys/stat.h"
#endif
#ifdef S_IRUSR
#define MKDIR_UMASK (S_IRUSR|S_IWUSR|S_IXUSR|S_IRGRP|S_IXGRP|S_IROTH|S_IXOTH)
#else
#define MKDIR_UMASK 0755
#endif
/* Enable extensions and modifications for ICU. */
#define ICU
/* Continue executing after link failure. Even if ICU is undefined
* (for vanilla zic behavior), ICU_LINKS should be defined, since zic
* appears to fail on the 2003 data the first time through during the
* linking phase. Running zic twice, with ICU_LINKS defined, causes
* links to be handled correctly. */
#define ICU_LINKS
#ifdef ICU
#include "tz2icu.h"
#endif
/*
** On some ancient hosts, predicates like `isspace(C)' are defined
** only if isascii(C) || C == EOF. Modern hosts obey the C Standard,
** which says they are defined only if C == ((unsigned char) C) || C == EOF.
** Neither the C Standard nor Posix require that `isascii' exist.
** For portability, we check both ancient and modern requirements.
** If isascii is not defined, the isascii check succeeds trivially.
*/
#include "ctype.h"
#ifndef isascii
#define isascii(x) 1
#endif
#define OFFSET_STRLEN_MAXIMUM (7 + INT_STRLEN_MAXIMUM(long))
#define RULE_STRLEN_MAXIMUM 8 /* "Mdd.dd.d" */
#define end(cp) (strchr((cp), '\0'))
struct rule {
const char * r_filename;
int r_linenum;
const char * r_name;
int r_loyear; /* for example, 1986 */
int r_hiyear; /* for example, 1986 */
const char * r_yrtype;
int r_lowasnum;
int r_hiwasnum;
int r_month; /* 0..11 */
int r_dycode; /* see below */
int r_dayofmonth;
int r_wday;
long r_tod; /* time from midnight */
int r_todisstd; /* above is standard time if TRUE */
/* or wall clock time if FALSE */
int r_todisgmt; /* above is GMT if TRUE */
/* or local time if FALSE */
long r_stdoff; /* offset from standard time */
const char * r_abbrvar; /* variable part of abbreviation */
int r_todo; /* a rule to do (used in outzone) */
zic_t r_temp; /* used in outzone */
};
/*
** r_dycode r_dayofmonth r_wday
*/
#define DC_DOM 0 /* 1..31 */ /* unused */
#define DC_DOWGEQ 1 /* 1..31 */ /* 0..6 (Sun..Sat) */
#define DC_DOWLEQ 2 /* 1..31 */ /* 0..6 (Sun..Sat) */
struct zone {
const char * z_filename;
int z_linenum;
const char * z_name;
long z_gmtoff;
const char * z_rule;
const char * z_format;
long z_stdoff;
struct rule * z_rules;
int z_nrules;
struct rule z_untilrule;
zic_t z_untiltime;
};
extern int getopt(int argc, char * const argv[],
const char * options);
extern int link(const char * fromname, const char * toname);
extern char * optarg;
extern int optind;
static void addtt(zic_t starttime, int type);
#ifdef ICU
static int addtype(long gmtoff, long rawoff, long dstoff,
const char * abbr, int isdst,
int ttisstd, int ttisgmt);
#else
static int addtype(long gmtoff, const char * abbr, int isdst,
int ttisstd, int ttisgmt);
#endif
static void leapadd(zic_t t, int positive, int rolling, int count);
static void adjleap(void);
static void associate(void);
static int ciequal(const char * ap, const char * bp);
static void convert(long val, char * buf);
static void convert64(zic_t val, char * buf);
static void dolink(const char * fromfield, const char * tofield);
static void doabbr(char * abbr, const char * format,
const char * letters, int isdst, int doquotes);
static void eat(const char * name, int num);
static void eats(const char * name, int num,
const char * rname, int rnum);
static long eitol(int i);
static void error(const char * message);
static char ** getfields(char * buf);
static long gethms(const char * string, const char * errstrng,
int signable);
static void infile(const char * filename);
static void inleap(char ** fields, int nfields);
static void inlink(char ** fields, int nfields);
static void inrule(char ** fields, int nfields);
static int inzcont(char ** fields, int nfields);
static int inzone(char ** fields, int nfields);
static int inzsub(char ** fields, int nfields, int iscont);
static int is32(zic_t x);
static int itsabbr(const char * abbr, const char * word);
static int itsdir(const char * name);
static int lowerit(int c);
static char * memcheck(char * tocheck);
static int mkdirs(char * filename);
static void newabbr(const char * abbr);
static long oadd(long t1, long t2);
static void outzone(const struct zone * zp, int ntzones);
static void puttzcode(long code, FILE * fp);
static void puttzcode64(zic_t code, FILE * fp);
static int rcomp(const void * leftp, const void * rightp);
static zic_t rpytime(const struct rule * rp, int wantedy);
static void rulesub(struct rule * rp,
const char * loyearp, const char * hiyearp,
const char * typep, const char * monthp,
const char * dayp, const char * timep);
static int stringoffset(char * result, long offset);
static int stringrule(char * result, const struct rule * rp,
long dstoff, long gmtoff);
static void stringzone(char * result,
const struct zone * zp, int ntzones);
static void setboundaries(void);
static zic_t tadd(zic_t t1, long t2);
static void usage(FILE *stream, int status);
static void writezone(const char * name, const char * string);
static int yearistype(int year, const char * type);
#ifdef ICU
static void emit_icu_zone(FILE* f, const char* zoneName, int zoneOffset,
const struct rule* rule,
int ruleIndex, int startYear);
static void emit_icu_link(FILE* f, const char* from, const char* to);
static void emit_icu_rule(FILE* f, const struct rule* r, int ruleIndex);
static int add_icu_final_rules(const struct rule* r1, const struct rule* r2);
#endif
static int charcnt;
static int errors;
static const char * filename;
static int leapcnt;
static int leapseen;
static int leapminyear;
static int leapmaxyear;
static int linenum;
static int max_abbrvar_len;
static int max_format_len;
static zic_t max_time;
static int max_year;
static zic_t min_time;
static int min_year;
static int noise;
static const char * rfilename;
static int rlinenum;
static const char * progname;
static int timecnt;
static int typecnt;
/*
** Line codes.
*/
#define LC_RULE 0
#define LC_ZONE 1
#define LC_LINK 2
#define LC_LEAP 3
/*
** Which fields are which on a Zone line.
*/
#define ZF_NAME 1
#define ZF_GMTOFF 2
#define ZF_RULE 3
#define ZF_FORMAT 4
#define ZF_TILYEAR 5
#define ZF_TILMONTH 6
#define ZF_TILDAY 7
#define ZF_TILTIME 8
#define ZONE_MINFIELDS 5
#define ZONE_MAXFIELDS 9
/*
** Which fields are which on a Zone continuation line.
*/
#define ZFC_GMTOFF 0
#define ZFC_RULE 1
#define ZFC_FORMAT 2
#define ZFC_TILYEAR 3
#define ZFC_TILMONTH 4
#define ZFC_TILDAY 5
#define ZFC_TILTIME 6
#define ZONEC_MINFIELDS 3
#define ZONEC_MAXFIELDS 7
/*
** Which files are which on a Rule line.
*/
#define RF_NAME 1
#define RF_LOYEAR 2
#define RF_HIYEAR 3
#define RF_COMMAND 4
#define RF_MONTH 5
#define RF_DAY 6
#define RF_TOD 7
#define RF_STDOFF 8
#define RF_ABBRVAR 9
#define RULE_FIELDS 10
/*
** Which fields are which on a Link line.
*/
#define LF_FROM 1
#define LF_TO 2
#define LINK_FIELDS 3
/*
** Which fields are which on a Leap line.
*/
#define LP_YEAR 1
#define LP_MONTH 2
#define LP_DAY 3
#define LP_TIME 4
#define LP_CORR 5
#define LP_ROLL 6
#define LEAP_FIELDS 7
/*
** Year synonyms.
*/
#define YR_MINIMUM 0
#define YR_MAXIMUM 1
#define YR_ONLY 2
static struct rule * rules;
static int nrules; /* number of rules */
static struct zone * zones;
static int nzones; /* number of zones */
struct link {
const char * l_filename;
int l_linenum;
const char * l_from;
const char * l_to;
};
static struct link * links;
static int nlinks;
struct lookup {
const char * l_word;
const int l_value;
};
#ifdef ICU
/* Indices into rules[] for final rules. They will occur in pairs,
* with finalRules[i] occurring before finalRules[i+1] in the year.
* Each zone need only store a start year, a standard offset, and an
* index into finalRules[]. FinalRules[] are aliases into rules[]. */
static const struct rule ** finalRules;
static int finalRulesCount;
#endif
static struct lookup const * byword(const char * string,
const struct lookup * lp);
static struct lookup const line_codes[] = {
{ "Rule", LC_RULE },
{ "Zone", LC_ZONE },
{ "Link", LC_LINK },
{ "Leap", LC_LEAP },
{ NULL, 0}
};
static struct lookup const mon_names[] = {
{ "January", TM_JANUARY },
{ "February", TM_FEBRUARY },
{ "March", TM_MARCH },
{ "April", TM_APRIL },
{ "May", TM_MAY },
{ "June", TM_JUNE },
{ "July", TM_JULY },
{ "August", TM_AUGUST },
{ "September", TM_SEPTEMBER },
{ "October", TM_OCTOBER },
{ "November", TM_NOVEMBER },
{ "December", TM_DECEMBER },
{ NULL, 0 }
};
static struct lookup const wday_names[] = {
{ "Sunday", TM_SUNDAY },
{ "Monday", TM_MONDAY },
{ "Tuesday", TM_TUESDAY },
{ "Wednesday", TM_WEDNESDAY },
{ "Thursday", TM_THURSDAY },
{ "Friday", TM_FRIDAY },
{ "Saturday", TM_SATURDAY },
{ NULL, 0 }
};
static struct lookup const lasts[] = {
{ "last-Sunday", TM_SUNDAY },
{ "last-Monday", TM_MONDAY },
{ "last-Tuesday", TM_TUESDAY },
{ "last-Wednesday", TM_WEDNESDAY },
{ "last-Thursday", TM_THURSDAY },
{ "last-Friday", TM_FRIDAY },
{ "last-Saturday", TM_SATURDAY },
{ NULL, 0 }
};
static struct lookup const begin_years[] = {
{ "minimum", YR_MINIMUM },
{ "maximum", YR_MAXIMUM },
{ NULL, 0 }
};
static struct lookup const end_years[] = {
{ "minimum", YR_MINIMUM },
{ "maximum", YR_MAXIMUM },
{ "only", YR_ONLY },
{ NULL, 0 }
};
static struct lookup const leap_types[] = {
{ "Rolling", TRUE },
{ "Stationary", FALSE },
{ NULL, 0 }
};
static const int len_months[2][MONSPERYEAR] = {
{ 31, 28, 31, 30, 31, 30, 31, 31, 30, 31, 30, 31 },
{ 31, 29, 31, 30, 31, 30, 31, 31, 30, 31, 30, 31 }
};
static const int len_years[2] = {
DAYSPERNYEAR, DAYSPERLYEAR
};
static struct attype {
zic_t at;
unsigned char type;
} attypes[TZ_MAX_TIMES];
static long gmtoffs[TZ_MAX_TYPES];
#ifdef ICU
/* gmtoffs[i] = rawoffs[i] + dstoffs[i] */
static long rawoffs[TZ_MAX_TYPES];
static long dstoffs[TZ_MAX_TYPES];
#endif
static char isdsts[TZ_MAX_TYPES];
static unsigned char abbrinds[TZ_MAX_TYPES];
static char ttisstds[TZ_MAX_TYPES];
static char ttisgmts[TZ_MAX_TYPES];
static char chars[TZ_MAX_CHARS];
static zic_t trans[TZ_MAX_LEAPS];
static long corr[TZ_MAX_LEAPS];
static char roll[TZ_MAX_LEAPS];
/*
** Memory allocation.
*/
static char *
memcheck(ptr)
char * const ptr;
{
if (ptr == NULL) {
const char *e = strerror(errno);
(void) fprintf(stderr, _("%s: Memory exhausted: %s\n"),
progname, e);
exit(EXIT_FAILURE);
}
return ptr;
}
#define emalloc(size) memcheck(imalloc(size))
#define erealloc(ptr, size) memcheck(irealloc((ptr), (size)))
#define ecpyalloc(ptr) memcheck(icpyalloc(ptr))
#define ecatalloc(oldp, newp) memcheck(icatalloc((oldp), (newp)))
/*
** Error handling.
*/
static void
eats(name, num, rname, rnum)
const char * const name;
const int num;
const char * const rname;
const int rnum;
{
filename = name;
linenum = num;
rfilename = rname;
rlinenum = rnum;
}
static void
eat(name, num)
const char * const name;
const int num;
{
eats(name, num, (char *) NULL, -1);
}
static void
error(string)
const char * const string;
{
/*
** Match the format of "cc" to allow sh users to
** zic ... 2>&1 | error -t "*" -v
** on BSD systems.
*/
(void) fprintf(stderr, _("\"%s\", line %d: %s"),
filename, linenum, string);
if (rfilename != NULL)
(void) fprintf(stderr, _(" (rule from \"%s\", line %d)"),
rfilename, rlinenum);
(void) fprintf(stderr, "\n");
++errors;
}
static void
warning(string)
const char * const string;
{
char * cp;
cp = ecpyalloc(_("warning: "));
cp = ecatalloc(cp, string);
error(cp);
ifree(cp);
--errors;
}
static void
usage(FILE *stream, int status)
{
(void) fprintf(stream, _("%s: usage is %s \
[ --version ] [ --help ] [ -v ] [ -l localtime ] [ -p posixrules ] \\\n\
\t[ -d directory ] [ -L leapseconds ] [ -y yearistype ] [ filename ... ]\n\
\n\
Report bugs to tz@elsie.nci.nih.gov.\n"),
progname, progname);
exit(status);
}
#ifdef ICU
/* File into which we will write supplemental ICU data. */
static FILE * icuFile;
static void
emit_icu_zone(FILE* f, const char* zoneName, int zoneOffset,
const struct rule* rule,
int ruleIndex, int startYear) {
/* machine-readable section */
fprintf(f, "zone %s %d %d %s", zoneName, zoneOffset, startYear, rule->r_name);
/* human-readable section */
fprintf(f, " # zone %s, offset %d, year >= %d, rule %s (%d)\n",
zoneName, zoneOffset, startYear,
rule->r_name, ruleIndex);
}
static void
emit_icu_link(FILE* f, const char* from, const char* to) {
/* machine-readable section */
fprintf(f, "link %s %s\n", from, to);
}
static const char* DYCODE[] = {"DOM", "DOWGEQ", "DOWLEQ"};
static void
emit_icu_rule(FILE* f, const struct rule* r, int ruleIndex) {
if (r->r_yrtype != NULL) {
warning("year types not supported by ICU");
fprintf(stderr, "rule %s, file %s, line %d\n",
r->r_name, r->r_filename, r->r_linenum);
}
/* machine-readable section */
fprintf(f, "rule %s %s %d %d %d %ld %d %d %ld",
r->r_name, DYCODE[r->r_dycode],
r->r_month, r->r_dayofmonth,
(r->r_dycode == DC_DOM ? -1 : r->r_wday),
r->r_tod, r->r_todisstd, r->r_todisgmt, r->r_stdoff
);
/* human-readable section */
fprintf(f, " # %d: %s, file %s, line %d",
ruleIndex, r->r_name, r->r_filename, r->r_linenum);
fprintf(f, ", mode %s", DYCODE[r->r_dycode]);
fprintf(f, ", %s, dom %d", mon_names[r->r_month].l_word, r->r_dayofmonth);
if (r->r_dycode != DC_DOM) {
fprintf(f, ", %s", wday_names[r->r_wday].l_word);
}
fprintf(f, ", time %ld", r->r_tod);
fprintf(f, ", isstd %d", r->r_todisstd);
fprintf(f, ", isgmt %d", r->r_todisgmt);
fprintf(f, ", offset %ld", r->r_stdoff);
fprintf(f, "\n");
}
static int
add_icu_final_rules(const struct rule* r1, const struct rule* r2) {
int i;
for (i=0; i<finalRulesCount; ++i) { /* i+=2 should work too */
if (r1==finalRules[i]) return i; /* [sic] pointer comparison */
}
finalRules = (const struct rule**) (void*) erealloc((char *) finalRules,
(finalRulesCount + 2) * sizeof(*finalRules));
finalRules[finalRulesCount++] = r1;
finalRules[finalRulesCount++] = r2;
return finalRulesCount - 2;
}
#endif
static const char * psxrules;
static const char * lcltime;
static const char * directory;
static const char * leapsec;
static const char * yitcommand;
int
main(argc, argv)
int argc;
char * argv[];
{
register int i;
register int j;
register int c;
#ifdef unix
(void) umask(umask(S_IWGRP | S_IWOTH) | (S_IWGRP | S_IWOTH));
#endif /* defined unix */
#if HAVE_GETTEXT
(void) setlocale(LC_ALL, "");
#ifdef TZ_DOMAINDIR
(void) bindtextdomain(TZ_DOMAIN, TZ_DOMAINDIR);
#endif /* defined TEXTDOMAINDIR */
(void) textdomain(TZ_DOMAIN);
#endif /* HAVE_GETTEXT */
progname = argv[0];
if (TYPE_BIT(zic_t) < 64) {
(void) fprintf(stderr, "%s: %s\n", progname,
_("wild compilation-time specification of zic_t"));
exit(EXIT_FAILURE);
}
for (i = 1; i < argc; ++i)
if (strcmp(argv[i], "--version") == 0) {
(void) printf("%s\n", elsieid);
exit(EXIT_SUCCESS);
} else if (strcmp(argv[i], "--help") == 0) {
usage(stdout, EXIT_SUCCESS);
}
while ((c = getopt(argc, argv, "d:l:p:L:vsy:")) != EOF && c != -1)
switch (c) {
default:
usage(stderr, EXIT_FAILURE);
case 'd':
if (directory == NULL)
directory = optarg;
else {
(void) fprintf(stderr,
_("%s: More than one -d option specified\n"),
progname);
exit(EXIT_FAILURE);
}
break;
case 'l':
if (lcltime == NULL)
lcltime = optarg;
else {
(void) fprintf(stderr,
_("%s: More than one -l option specified\n"),
progname);
exit(EXIT_FAILURE);
}
break;
case 'p':
if (psxrules == NULL)
psxrules = optarg;
else {
(void) fprintf(stderr,
_("%s: More than one -p option specified\n"),
progname);
exit(EXIT_FAILURE);
}
break;
case 'y':
if (yitcommand == NULL)
yitcommand = optarg;
else {
(void) fprintf(stderr,
_("%s: More than one -y option specified\n"),
progname);
exit(EXIT_FAILURE);
}
break;
case 'L':
if (leapsec == NULL)
leapsec = optarg;
else {
(void) fprintf(stderr,
_("%s: More than one -L option specified\n"),
progname);
exit(EXIT_FAILURE);
}
break;
case 'v':
noise = TRUE;
break;
case 's':
(void) printf("%s: -s ignored\n", progname);
break;
}
if (optind == argc - 1 && strcmp(argv[optind], "=") == 0)
usage(stderr, EXIT_FAILURE); /* usage message by request */
if (directory == NULL)
directory = TZDIR;
if (yitcommand == NULL)
yitcommand = "yearistype";
setboundaries();
if (optind < argc && leapsec != NULL) {
infile(leapsec);
adjleap();
}
#ifdef ICU
if ((icuFile = fopen(ICU_ZONE_FILE, "w")) == NULL) {
const char *e = strerror(errno);
(void) fprintf(stderr, _("%s: Can't open %s: %s\n"),
progname, ICU_ZONE_FILE, e);
(void) exit(EXIT_FAILURE);
}
#endif
for (i = optind; i < argc; ++i)
infile(argv[i]);
if (errors)
exit(EXIT_FAILURE);
associate();
for (i = 0; i < nzones; i = j) {
/*
** Find the next non-continuation zone entry.
*/
for (j = i + 1; j < nzones && zones[j].z_name == NULL; ++j)
continue;
outzone(&zones[i], j - i);
}
/*
** Make links.
*/
for (i = 0; i < nlinks; ++i) {
eat(links[i].l_filename, links[i].l_linenum);
dolink(links[i].l_from, links[i].l_to);
#ifdef ICU
emit_icu_link(icuFile, links[i].l_from, links[i].l_to);
#endif
if (noise)
for (j = 0; j < nlinks; ++j)
if (strcmp(links[i].l_to,
links[j].l_from) == 0)
warning(_("link to link"));
}
if (lcltime != NULL) {
eat("command line", 1);
dolink(lcltime, TZDEFAULT);
}
if (psxrules != NULL) {
eat("command line", 1);
dolink(psxrules, TZDEFRULES);
}
#ifdef ICU
for (i=0; i<finalRulesCount; ++i) {
emit_icu_rule(icuFile, finalRules[i], i);
}
#endif /*ICU*/
return (errors == 0) ? EXIT_SUCCESS : EXIT_FAILURE;
}
static void
dolink(fromfield, tofield)
const char * const fromfield;
const char * const tofield;
{
register char * fromname;
register char * toname;
if (fromfield[0] == '/')
fromname = ecpyalloc(fromfield);
else {
fromname = ecpyalloc(directory);
fromname = ecatalloc(fromname, "/");
fromname = ecatalloc(fromname, fromfield);
}
if (tofield[0] == '/')
toname = ecpyalloc(tofield);
else {
toname = ecpyalloc(directory);
toname = ecatalloc(toname, "/");
toname = ecatalloc(toname, tofield);
}
/*
** We get to be careful here since
** there's a fair chance of root running us.
*/
if (!itsdir(toname))
(void) remove(toname);
if (link(fromname, toname) != 0) {
int result;
if (mkdirs(toname) != 0)
exit(EXIT_FAILURE);
result = link(fromname, toname);
#if HAVE_SYMLINK
if (result != 0 &&
access(fromname, F_OK) == 0 &&
!itsdir(fromname)) {
const char *s = tofield;
register char * symlinkcontents = NULL;
while ((s = strchr(s+1, '/')) != NULL)
symlinkcontents =
ecatalloc(symlinkcontents,
"../");
symlinkcontents =
ecatalloc(symlinkcontents,
fromname);
result = symlink(symlinkcontents,
toname);
if (result == 0)
warning(_("hard link failed, symbolic link used"));
ifree(symlinkcontents);
}
#endif /* HAVE_SYMLINK */
if (result != 0) {
const char *e = strerror(errno);
(void) fprintf(stderr,
_("%s: Can't link from %s to %s: %s\n"),
progname, fromname, toname, e);
#ifndef ICU_LINKS
exit(EXIT_FAILURE);
#endif
}
}
ifree(fromname);
ifree(toname);
}
#define TIME_T_BITS_IN_FILE 64
static void
setboundaries(void)
{
register int i;
min_time = -1;
for (i = 0; i < TIME_T_BITS_IN_FILE - 1; ++i)
min_time *= 2;
max_time = -(min_time + 1);
}
static int
itsdir(name)
const char * const name;
{
register char * myname;
register int accres;
myname = ecpyalloc(name);
myname = ecatalloc(myname, "/.");
accres = access(myname, F_OK);
ifree(myname);
return accres == 0;
}
/*
** Associate sets of rules with zones.
*/
/*
** Sort by rule name.
*/
static int
rcomp(cp1, cp2)
const void * cp1;
const void * cp2;
{
return strcmp(((const struct rule *) cp1)->r_name,
((const struct rule *) cp2)->r_name);
}
static void
associate(void)
{
register struct zone * zp;
register struct rule * rp;
register int base, out;
register int i, j;
if (nrules != 0) {
(void) qsort((void *) rules, (size_t) nrules,
(size_t) sizeof *rules, rcomp);
for (i = 0; i < nrules - 1; ++i) {
if (strcmp(rules[i].r_name,
rules[i + 1].r_name) != 0)
continue;
if (strcmp(rules[i].r_filename,
rules[i + 1].r_filename) == 0)
continue;
eat(rules[i].r_filename, rules[i].r_linenum);
warning(_("same rule name in multiple files"));
eat(rules[i + 1].r_filename, rules[i + 1].r_linenum);
warning(_("same rule name in multiple files"));
for (j = i + 2; j < nrules; ++j) {
if (strcmp(rules[i].r_name,
rules[j].r_name) != 0)
break;
if (strcmp(rules[i].r_filename,
rules[j].r_filename) == 0)
continue;
if (strcmp(rules[i + 1].r_filename,
rules[j].r_filename) == 0)
continue;
break;
}
i = j - 1;
}
}
for (i = 0; i < nzones; ++i) {
zp = &zones[i];
zp->z_rules = NULL;
zp->z_nrules = 0;
}
for (base = 0; base < nrules; base = out) {
rp = &rules[base];
for (out = base + 1; out < nrules; ++out)
if (strcmp(rp->r_name, rules[out].r_name) != 0)
break;
for (i = 0; i < nzones; ++i) {
zp = &zones[i];
if (strcmp(zp->z_rule, rp->r_name) != 0)
continue;
zp->z_rules = rp;
zp->z_nrules = out - base;
}
}
for (i = 0; i < nzones; ++i) {
zp = &zones[i];
if (zp->z_nrules == 0) {
/*
** Maybe we have a local standard time offset.
*/
eat(zp->z_filename, zp->z_linenum);
zp->z_stdoff = gethms(zp->z_rule, _("unruly zone"),
TRUE);
/*
** Note, though, that if there's no rule,
** a '%s' in the format is a bad thing.
*/
if (strchr(zp->z_format, '%') != 0)
error(_("%s in ruleless zone"));
}
}
if (errors)
exit(EXIT_FAILURE);
}
static void
infile(name)
const char * name;
{
register FILE * fp;
register char ** fields;
register char * cp;
register const struct lookup * lp;
register int nfields;
register int wantcont;
register int num;
char buf[BUFSIZ];
if (strcmp(name, "-") == 0) {
name = _("standard input");
fp = stdin;
} else if ((fp = fopen(name, "r")) == NULL) {
const char *e = strerror(errno);
(void) fprintf(stderr, _("%s: Can't open %s: %s\n"),
progname, name, e);
exit(EXIT_FAILURE);
}
wantcont = FALSE;
for (num = 1; ; ++num) {
eat(name, num);
if (fgets(buf, (int) sizeof buf, fp) != buf)
break;
cp = strchr(buf, '\n');
if (cp == NULL) {
error(_("line too long"));
exit(EXIT_FAILURE);
}
*cp = '\0';
fields = getfields(buf);
nfields = 0;
while (fields[nfields] != NULL) {
static char nada;
if (strcmp(fields[nfields], "-") == 0)
fields[nfields] = &nada;
++nfields;
}
if (nfields == 0) {
/* nothing to do */
} else if (wantcont) {
wantcont = inzcont(fields, nfields);
} else {
lp = byword(fields[0], line_codes);
if (lp == NULL)
error(_("input line of unknown type"));
else switch ((int) (lp->l_value)) {
case LC_RULE:
inrule(fields, nfields);
wantcont = FALSE;
break;
case LC_ZONE:
wantcont = inzone(fields, nfields);
break;
case LC_LINK:
inlink(fields, nfields);
wantcont = FALSE;
break;
case LC_LEAP:
if (name != leapsec)
(void) fprintf(stderr,
_("%s: Leap line in non leap seconds file %s\n"),
progname, name);
else inleap(fields, nfields);
wantcont = FALSE;
break;
default: /* "cannot happen" */
(void) fprintf(stderr,
_("%s: panic: Invalid l_value %d\n"),
progname, lp->l_value);
exit(EXIT_FAILURE);
}
}
ifree((char *) fields);
}
if (ferror(fp)) {
(void) fprintf(stderr, _("%s: Error reading %s\n"),
progname, filename);
exit(EXIT_FAILURE);
}
if (fp != stdin && fclose(fp)) {
const char *e = strerror(errno);
(void) fprintf(stderr, _("%s: Error closing %s: %s\n"),
progname, filename, e);
exit(EXIT_FAILURE);
}
if (wantcont)
error(_("expected continuation line not found"));
}
/*
** Convert a string of one of the forms
** h -h hh:mm -hh:mm hh:mm:ss -hh:mm:ss
** into a number of seconds.
** A null string maps to zero.
** Call error with errstring and return zero on errors.
*/
static long
gethms(string, errstring, signable)
const char * string;
const char * const errstring;
const int signable;
{
long hh;
int mm, ss, sign;
if (string == NULL || *string == '\0')
return 0;
if (!signable)
sign = 1;
else if (*string == '-') {
sign = -1;
++string;
} else sign = 1;
if (sscanf(string, scheck(string, "%ld"), &hh) == 1)
mm = ss = 0;
else if (sscanf(string, scheck(string, "%ld:%d"), &hh, &mm) == 2)
ss = 0;
else if (sscanf(string, scheck(string, "%ld:%d:%d"),
&hh, &mm, &ss) != 3) {
error(errstring);
return 0;
}
if (hh < 0 ||
mm < 0 || mm >= MINSPERHOUR ||
ss < 0 || ss > SECSPERMIN) {
error(errstring);
return 0;
}
if (LONG_MAX / SECSPERHOUR < hh) {
error(_("time overflow"));
return 0;
}
if (noise && hh == HOURSPERDAY && mm == 0 && ss == 0)
warning(_("24:00 not handled by pre-1998 versions of zic"));
if (noise && (hh > HOURSPERDAY ||
(hh == HOURSPERDAY && (mm != 0 || ss != 0))))
warning(_("values over 24 hours not handled by pre-2007 versions of zic"));
return oadd(eitol(sign) * hh * eitol(SECSPERHOUR),
eitol(sign) * (eitol(mm) * eitol(SECSPERMIN) + eitol(ss)));
}
static void
inrule(fields, nfields)
register char ** const fields;
const int nfields;
{
static struct rule r;
if (nfields != RULE_FIELDS) {
error(_("wrong number of fields on Rule line"));
return;
}
if (*fields[RF_NAME] == '\0') {
error(_("nameless rule"));
return;
}
r.r_filename = filename;
r.r_linenum = linenum;
r.r_stdoff = gethms(fields[RF_STDOFF], _("invalid saved time"), TRUE);
rulesub(&r, fields[RF_LOYEAR], fields[RF_HIYEAR], fields[RF_COMMAND],
fields[RF_MONTH], fields[RF_DAY], fields[RF_TOD]);
r.r_name = ecpyalloc(fields[RF_NAME]);
r.r_abbrvar = ecpyalloc(fields[RF_ABBRVAR]);
if (max_abbrvar_len < strlen(r.r_abbrvar))
max_abbrvar_len = strlen(r.r_abbrvar);
rules = (struct rule *) (void *) erealloc((char *) rules,
(int) ((nrules + 1) * sizeof *rules));
rules[nrules++] = r;
}
static int
inzone(fields, nfields)
register char ** const fields;
const int nfields;
{
register int i;
static char * buf;
if (nfields < ZONE_MINFIELDS || nfields > ZONE_MAXFIELDS) {
error(_("wrong number of fields on Zone line"));
return FALSE;
}
if (strcmp(fields[ZF_NAME], TZDEFAULT) == 0 && lcltime != NULL) {
buf = erealloc(buf, (int) (132 + strlen(TZDEFAULT)));
(void) sprintf(buf,
_("\"Zone %s\" line and -l option are mutually exclusive"),
TZDEFAULT);
error(buf);
return FALSE;
}
if (strcmp(fields[ZF_NAME], TZDEFRULES) == 0 && psxrules != NULL) {
buf = erealloc(buf, (int) (132 + strlen(TZDEFRULES)));
(void) sprintf(buf,
_("\"Zone %s\" line and -p option are mutually exclusive"),
TZDEFRULES);
error(buf);
return FALSE;
}
for (i = 0; i < nzones; ++i)
if (zones[i].z_name != NULL &&
strcmp(zones[i].z_name, fields[ZF_NAME]) == 0) {
buf = erealloc(buf, (int) (132 +
strlen(fields[ZF_NAME]) +
strlen(zones[i].z_filename)));
(void) sprintf(buf,
_("duplicate zone name %s (file \"%s\", line %d)"),
fields[ZF_NAME],
zones[i].z_filename,
zones[i].z_linenum);
error(buf);
return FALSE;
}
return inzsub(fields, nfields, FALSE);
}
static int
inzcont(fields, nfields)
register char ** const fields;
const int nfields;
{
if (nfields < ZONEC_MINFIELDS || nfields > ZONEC_MAXFIELDS) {
error(_("wrong number of fields on Zone continuation line"));
return FALSE;
}
return inzsub(fields, nfields, TRUE);
}
static int
inzsub(fields, nfields, iscont)
register char ** const fields;
const int nfields;
const int iscont;
{
register char * cp;
static struct zone z;
register int i_gmtoff, i_rule, i_format;
register int i_untilyear, i_untilmonth;
register int i_untilday, i_untiltime;
register int hasuntil;
if (iscont) {
i_gmtoff = ZFC_GMTOFF;
i_rule = ZFC_RULE;
i_format = ZFC_FORMAT;
i_untilyear = ZFC_TILYEAR;
i_untilmonth = ZFC_TILMONTH;
i_untilday = ZFC_TILDAY;
i_untiltime = ZFC_TILTIME;
z.z_name = NULL;
} else {
i_gmtoff = ZF_GMTOFF;
i_rule = ZF_RULE;
i_format = ZF_FORMAT;
i_untilyear = ZF_TILYEAR;
i_untilmonth = ZF_TILMONTH;
i_untilday = ZF_TILDAY;
i_untiltime = ZF_TILTIME;
z.z_name = ecpyalloc(fields[ZF_NAME]);
}
z.z_filename = filename;
z.z_linenum = linenum;
z.z_gmtoff = gethms(fields[i_gmtoff], _("invalid UTC offset"), TRUE);
if ((cp = strchr(fields[i_format], '%')) != 0) {
if (*++cp != 's' || strchr(cp, '%') != 0) {
error(_("invalid abbreviation format"));
return FALSE;
}
}
z.z_rule = ecpyalloc(fields[i_rule]);
z.z_format = ecpyalloc(fields[i_format]);
if (max_format_len < strlen(z.z_format))
max_format_len = strlen(z.z_format);
hasuntil = nfields > i_untilyear;
if (hasuntil) {
z.z_untilrule.r_filename = filename;
z.z_untilrule.r_linenum = linenum;
rulesub(&z.z_untilrule,
fields[i_untilyear],
"only",
"",
(nfields > i_untilmonth) ?
fields[i_untilmonth] : "Jan",
(nfields > i_untilday) ? fields[i_untilday] : "1",
(nfields > i_untiltime) ? fields[i_untiltime] : "0");
z.z_untiltime = rpytime(&z.z_untilrule,
z.z_untilrule.r_loyear);
if (iscont && nzones > 0 &&
z.z_untiltime > min_time &&
z.z_untiltime < max_time &&
zones[nzones - 1].z_untiltime > min_time &&
zones[nzones - 1].z_untiltime < max_time &&
zones[nzones - 1].z_untiltime >= z.z_untiltime) {
error(_(
"Zone continuation line end time is not after end time of previous line"
));
return FALSE;
}
}
zones = (struct zone *) (void *) erealloc((char *) zones,
(int) ((nzones + 1) * sizeof *zones));
zones[nzones++] = z;
/*
** If there was an UNTIL field on this line,
** there's more information about the zone on the next line.
*/
return hasuntil;
}
static void
inleap(fields, nfields)
register char ** const fields;
const int nfields;
{
register const char * cp;
register const struct lookup * lp;
register int i, j;
int year, month, day;
long dayoff, tod;
zic_t t;
if (nfields != LEAP_FIELDS) {
error(_("wrong number of fields on Leap line"));
return;
}
dayoff = 0;
cp = fields[LP_YEAR];
if (sscanf(cp, scheck(cp, "%d"), &year) != 1) {
/*
** Leapin' Lizards!
*/
error(_("invalid leaping year"));
return;
}
if (!leapseen || leapmaxyear < year)
leapmaxyear = year;
if (!leapseen || leapminyear > year)
leapminyear = year;
leapseen = TRUE;
j = EPOCH_YEAR;
while (j != year) {
if (year > j) {
i = len_years[isleap(j)];
++j;
} else {
--j;
i = -len_years[isleap(j)];
}
dayoff = oadd(dayoff, eitol(i));
}
if ((lp = byword(fields[LP_MONTH], mon_names)) == NULL) {
error(_("invalid month name"));
return;
}
month = lp->l_value;
j = TM_JANUARY;
while (j != month) {
i = len_months[isleap(year)][j];
dayoff = oadd(dayoff, eitol(i));
++j;
}
cp = fields[LP_DAY];
if (sscanf(cp, scheck(cp, "%d"), &day) != 1 ||
day <= 0 || day > len_months[isleap(year)][month]) {
error(_("invalid day of month"));
return;
}
dayoff = oadd(dayoff, eitol(day - 1));
if (dayoff < 0 && !TYPE_SIGNED(zic_t)) {
error(_("time before zero"));
return;
}
if (dayoff < min_time / SECSPERDAY) {
error(_("time too small"));
return;
}
if (dayoff > max_time / SECSPERDAY) {
error(_("time too large"));
return;
}
t = (zic_t) dayoff * SECSPERDAY;
tod = gethms(fields[LP_TIME], _("invalid time of day"), FALSE);
cp = fields[LP_CORR];
{
register int positive;
int count;
if (strcmp(cp, "") == 0) { /* infile() turns "-" into "" */
positive = FALSE;
count = 1;
} else if (strcmp(cp, "--") == 0) {
positive = FALSE;
count = 2;
} else if (strcmp(cp, "+") == 0) {
positive = TRUE;
count = 1;
} else if (strcmp(cp, "++") == 0) {
positive = TRUE;
count = 2;
} else {
error(_("illegal CORRECTION field on Leap line"));
return;
}
if ((lp = byword(fields[LP_ROLL], leap_types)) == NULL) {
error(_(
"illegal Rolling/Stationary field on Leap line"
));
return;
}
leapadd(tadd(t, tod), positive, lp->l_value, count);
}
}
static void
inlink(fields, nfields)
register char ** const fields;
const int nfields;
{
struct link l;
if (nfields != LINK_FIELDS) {
error(_("wrong number of fields on Link line"));
return;
}
if (*fields[LF_FROM] == '\0') {
error(_("blank FROM field on Link line"));
return;
}
if (*fields[LF_TO] == '\0') {
error(_("blank TO field on Link line"));
return;
}
l.l_filename = filename;
l.l_linenum = linenum;
l.l_from = ecpyalloc(fields[LF_FROM]);
l.l_to = ecpyalloc(fields[LF_TO]);
links = (struct link *) (void *) erealloc((char *) links,
(int) ((nlinks + 1) * sizeof *links));
links[nlinks++] = l;
}
static void
rulesub(rp, loyearp, hiyearp, typep, monthp, dayp, timep)
register struct rule * const rp;
const char * const loyearp;
const char * const hiyearp;
const char * const typep;
const char * const monthp;
const char * const dayp;
const char * const timep;
{
register const struct lookup * lp;
register const char * cp;
register char * dp;
register char * ep;
if ((lp = byword(monthp, mon_names)) == NULL) {
error(_("invalid month name"));
return;
}
rp->r_month = lp->l_value;
rp->r_todisstd = FALSE;
rp->r_todisgmt = FALSE;
dp = ecpyalloc(timep);
if (*dp != '\0') {
ep = dp + strlen(dp) - 1;
switch (lowerit(*ep)) {
case 's': /* Standard */
rp->r_todisstd = TRUE;
rp->r_todisgmt = FALSE;
*ep = '\0';
break;
case 'w': /* Wall */
rp->r_todisstd = FALSE;
rp->r_todisgmt = FALSE;
*ep = '\0';
break;
case 'g': /* Greenwich */
case 'u': /* Universal */
case 'z': /* Zulu */
rp->r_todisstd = TRUE;
rp->r_todisgmt = TRUE;
*ep = '\0';
break;
}
}
rp->r_tod = gethms(dp, _("invalid time of day"), FALSE);
ifree(dp);
/*
** Year work.
*/
cp = loyearp;
lp = byword(cp, begin_years);
rp->r_lowasnum = lp == NULL;
if (!rp->r_lowasnum) switch ((int) lp->l_value) {
case YR_MINIMUM:
rp->r_loyear = INT_MIN;
break;
case YR_MAXIMUM:
rp->r_loyear = INT_MAX;
break;
default: /* "cannot happen" */
(void) fprintf(stderr,
_("%s: panic: Invalid l_value %d\n"),
progname, lp->l_value);
exit(EXIT_FAILURE);
} else if (sscanf(cp, scheck(cp, "%d"), &rp->r_loyear) != 1) {
error(_("invalid starting year"));
return;
}
cp = hiyearp;
lp = byword(cp, end_years);
rp->r_hiwasnum = lp == NULL;
if (!rp->r_hiwasnum) switch ((int) lp->l_value) {
case YR_MINIMUM:
rp->r_hiyear = INT_MIN;
break;
case YR_MAXIMUM:
rp->r_hiyear = INT_MAX;
break;
case YR_ONLY:
rp->r_hiyear = rp->r_loyear;
break;
default: /* "cannot happen" */
(void) fprintf(stderr,
_("%s: panic: Invalid l_value %d\n"),
progname, lp->l_value);
exit(EXIT_FAILURE);
} else if (sscanf(cp, scheck(cp, "%d"), &rp->r_hiyear) != 1) {
error(_("invalid ending year"));
return;
}
if (rp->r_loyear > rp->r_hiyear) {
error(_("starting year greater than ending year"));
return;
}
if (*typep == '\0')
rp->r_yrtype = NULL;
else {
if (rp->r_loyear == rp->r_hiyear) {
error(_("typed single year"));
return;
}
rp->r_yrtype = ecpyalloc(typep);
}
/*
** Day work.
** Accept things such as:
** 1
** last-Sunday
** Sun<=20
** Sun>=7
*/
dp = ecpyalloc(dayp);
if ((lp = byword(dp, lasts)) != NULL) {
rp->r_dycode = DC_DOWLEQ;
rp->r_wday = lp->l_value;
rp->r_dayofmonth = len_months[1][rp->r_month];
} else {
if ((ep = strchr(dp, '<')) != 0)
rp->r_dycode = DC_DOWLEQ;
else if ((ep = strchr(dp, '>')) != 0)
rp->r_dycode = DC_DOWGEQ;
else {
ep = dp;
rp->r_dycode = DC_DOM;
}
if (rp->r_dycode != DC_DOM) {
*ep++ = 0;
if (*ep++ != '=') {
error(_("invalid day of month"));
ifree(dp);
return;
}
if ((lp = byword(dp, wday_names)) == NULL) {
error(_("invalid weekday name"));
ifree(dp);
return;
}
rp->r_wday = lp->l_value;
}
if (sscanf(ep, scheck(ep, "%d"), &rp->r_dayofmonth) != 1 ||
rp->r_dayofmonth <= 0 ||
(rp->r_dayofmonth > len_months[1][rp->r_month])) {
error(_("invalid day of month"));
ifree(dp);
return;
}
}
ifree(dp);
}
static void
convert(val, buf)
const long val;
char * const buf;
{
register int i;
register int shift;
for (i = 0, shift = 24; i < 4; ++i, shift -= 8)
buf[i] = val >> shift;
}
static void
convert64(val, buf)
const zic_t val;
char * const buf;
{
register int i;
register int shift;
for (i = 0, shift = 56; i < 8; ++i, shift -= 8)
buf[i] = val >> shift;
}
static void
puttzcode(val, fp)
const long val;
FILE * const fp;
{
char buf[4];
convert(val, buf);
(void) fwrite((void *) buf, (size_t) sizeof buf, (size_t) 1, fp);
}
static void
puttzcode64(val, fp)
const zic_t val;
FILE * const fp;
{
char buf[8];
convert64(val, buf);
(void) fwrite((void *) buf, (size_t) sizeof buf, (size_t) 1, fp);
}
static int
atcomp(avp, bvp)
const void * avp;
const void * bvp;
{
const zic_t a = ((const struct attype *) avp)->at;
const zic_t b = ((const struct attype *) bvp)->at;
return (a < b) ? -1 : (a > b);
}
static int
is32(x)
const zic_t x;
{
return INT32_MIN <= x && x <= INT32_MAX;
}
static void
writezone(name, string)
const char * const name;
const char * const string;
{
register FILE * fp;
register int i, j;
register int leapcnt32, leapi32;
register int timecnt32, timei32;
register int pass;
static char * fullname;
static const struct tzhead tzh0;
static struct tzhead tzh;
zic_t ats[TZ_MAX_TIMES];
unsigned char types[TZ_MAX_TIMES];
/*
** Sort.
*/
if (timecnt > 1)
(void) qsort((void *) attypes, (size_t) timecnt,
(size_t) sizeof *attypes, atcomp);
/*
** Optimize.
*/
{
int fromi;
int toi;
toi = 0;
fromi = 0;
while (fromi < timecnt && attypes[fromi].at < min_time)
++fromi;
if (isdsts[0] == 0)
while (fromi < timecnt && attypes[fromi].type == 0)
++fromi; /* handled by default rule */
for ( ; fromi < timecnt; ++fromi) {
if (toi != 0 && ((attypes[fromi].at +
gmtoffs[attypes[toi - 1].type]) <=
(attypes[toi - 1].at + gmtoffs[toi == 1 ? 0
: attypes[toi - 2].type]))) {
attypes[toi - 1].type =
attypes[fromi].type;
continue;
}
if (toi == 0 ||
attypes[toi - 1].type != attypes[fromi].type)
attypes[toi++] = attypes[fromi];
}
timecnt = toi;
}
/*
** Transfer.
*/
for (i = 0; i < timecnt; ++i) {
ats[i] = attypes[i].at;
types[i] = attypes[i].type;
}
/*
** Correct for leap seconds.
*/
for (i = 0; i < timecnt; ++i) {
j = leapcnt;
while (--j >= 0)
if (ats[i] > trans[j] - corr[j]) {
ats[i] = tadd(ats[i], corr[j]);
break;
}
}
/*
** Figure out 32-bit-limited starts and counts.
*/
timecnt32 = timecnt;
timei32 = 0;
leapcnt32 = leapcnt;
leapi32 = 0;
while (timecnt32 > 0 && !is32(ats[timecnt32 - 1]))
--timecnt32;
while (timecnt32 > 0 && !is32(ats[timei32])) {
--timecnt32;
++timei32;
}
while (leapcnt32 > 0 && !is32(trans[leapcnt32 - 1]))
--leapcnt32;
while (leapcnt32 > 0 && !is32(trans[leapi32])) {
--leapcnt32;
++leapi32;
}
fullname = erealloc(fullname,
(int) (strlen(directory) + 1 + strlen(name) + 1));
(void) sprintf(fullname, "%s/%s", directory, name);
/*
** Remove old file, if any, to snap links.
*/
if (!itsdir(fullname) && remove(fullname) != 0 && errno != ENOENT) {
const char *e = strerror(errno);
(void) fprintf(stderr, _("%s: Can't remove %s: %s\n"),
progname, fullname, e);
exit(EXIT_FAILURE);
}
if ((fp = fopen(fullname, "wb")) == NULL) {
if (mkdirs(fullname) != 0)
exit(EXIT_FAILURE);
if ((fp = fopen(fullname, "wb")) == NULL) {
const char *e = strerror(errno);
(void) fprintf(stderr, _("%s: Can't create %s: %s\n"),
progname, fullname, e);
exit(EXIT_FAILURE);
}
}
for (pass = 1; pass <= 2; ++pass) {
register int thistimei, thistimecnt;
register int thisleapi, thisleapcnt;
register int thistimelim, thisleaplim;
int writetype[TZ_MAX_TIMES];
int typemap[TZ_MAX_TYPES];
register int thistypecnt;
char thischars[TZ_MAX_CHARS];
char thischarcnt;
int indmap[TZ_MAX_CHARS];
if (pass == 1) {
thistimei = timei32;
thistimecnt = timecnt32;
thisleapi = leapi32;
thisleapcnt = leapcnt32;
} else {
thistimei = 0;
thistimecnt = timecnt;
thisleapi = 0;
thisleapcnt = leapcnt;
}
thistimelim = thistimei + thistimecnt;
thisleaplim = thisleapi + thisleapcnt;
for (i = 0; i < typecnt; ++i)
writetype[i] = thistimecnt == timecnt;
if (thistimecnt == 0) {
/*
** No transition times fall in the current
** (32- or 64-bit) window.
*/
if (typecnt != 0)
writetype[typecnt - 1] = TRUE;
} else {
for (i = thistimei - 1; i < thistimelim; ++i)
if (i >= 0)
writetype[types[i]] = TRUE;
/*
** For America/Godthab and Antarctica/Palmer
*/
if (thistimei == 0)
writetype[0] = TRUE;
}
thistypecnt = 0;
for (i = 0; i < typecnt; ++i)
typemap[i] = writetype[i] ? thistypecnt++ : -1;
for (i = 0; i < sizeof indmap / sizeof indmap[0]; ++i)
indmap[i] = -1;
thischarcnt = 0;
for (i = 0; i < typecnt; ++i) {
register char * thisabbr;
if (!writetype[i])
continue;
if (indmap[abbrinds[i]] >= 0)
continue;
thisabbr = &chars[abbrinds[i]];
for (j = 0; j < thischarcnt; ++j)
if (strcmp(&thischars[j], thisabbr) == 0)
break;
if (j == thischarcnt) {
(void) strcpy(&thischars[(int) thischarcnt],
thisabbr);
thischarcnt += strlen(thisabbr) + 1;
}
indmap[abbrinds[i]] = j;
}
#define DO(field) (void) fwrite((void *) tzh.field, \
(size_t) sizeof tzh.field, (size_t) 1, fp)
tzh = tzh0;
#ifdef ICU
* (ICUZoneinfoVersion*) &tzh.tzh_reserved = TZ_ICU_VERSION;
(void) strncpy(tzh.tzh_magic, TZ_ICU_MAGIC, sizeof tzh.tzh_magic);
#else
(void) strncpy(tzh.tzh_magic, TZ_MAGIC, sizeof tzh.tzh_magic);
#endif
tzh.tzh_version[0] = ZIC_VERSION;
convert(eitol(thistypecnt), tzh.tzh_ttisgmtcnt);
convert(eitol(thistypecnt), tzh.tzh_ttisstdcnt);
convert(eitol(thisleapcnt), tzh.tzh_leapcnt);
convert(eitol(thistimecnt), tzh.tzh_timecnt);
convert(eitol(thistypecnt), tzh.tzh_typecnt);
convert(eitol(thischarcnt), tzh.tzh_charcnt);
DO(tzh_magic);
DO(tzh_version);
DO(tzh_reserved);
DO(tzh_ttisgmtcnt);
DO(tzh_ttisstdcnt);
DO(tzh_leapcnt);
DO(tzh_timecnt);
DO(tzh_typecnt);
DO(tzh_charcnt);
#undef DO
for (i = thistimei; i < thistimelim; ++i)
if (pass == 1)
puttzcode((long) ats[i], fp);
else puttzcode64(ats[i], fp);
for (i = thistimei; i < thistimelim; ++i) {
unsigned char uc;
uc = typemap[types[i]];
(void) fwrite((void *) &uc,
(size_t) sizeof uc,
(size_t) 1,
fp);
}
for (i = 0; i < typecnt; ++i)
if (writetype[i]) {
#ifdef ICU
puttzcode((long) rawoffs[i], fp);
puttzcode((long) dstoffs[i], fp);
#else
puttzcode(gmtoffs[i], fp);
#endif
(void) putc(isdsts[i], fp);
(void) putc((unsigned char) indmap[abbrinds[i]], fp);
}
if (thischarcnt != 0)
(void) fwrite((void *) thischars,
(size_t) sizeof thischars[0],
(size_t) thischarcnt, fp);
for (i = thisleapi; i < thisleaplim; ++i) {
register zic_t todo;
if (roll[i]) {
if (timecnt == 0 || trans[i] < ats[0]) {
j = 0;
while (isdsts[j])
if (++j >= typecnt) {
j = 0;
break;
}
} else {
j = 1;
while (j < timecnt &&
trans[i] >= ats[j])
++j;
j = types[j - 1];
}
todo = tadd(trans[i], -gmtoffs[j]);
} else todo = trans[i];
if (pass == 1)
puttzcode((long) todo, fp);
else puttzcode64(todo, fp);
puttzcode(corr[i], fp);
}
for (i = 0; i < typecnt; ++i)
if (writetype[i])
(void) putc(ttisstds[i], fp);
for (i = 0; i < typecnt; ++i)
if (writetype[i])
(void) putc(ttisgmts[i], fp);
}
(void) fprintf(fp, "\n%s\n", string);
if (ferror(fp) || fclose(fp)) {
(void) fprintf(stderr, _("%s: Error writing %s\n"),
progname, fullname);
exit(EXIT_FAILURE);
}
}
static void
doabbr(abbr, format, letters, isdst, doquotes)
char * const abbr;
const char * const format;
const char * const letters;
const int isdst;
const int doquotes;
{
register char * cp;
register char * slashp;
register int len;
slashp = strchr(format, '/');
if (slashp == NULL) {
if (letters == NULL)
(void) strcpy(abbr, format);
else (void) sprintf(abbr, format, letters);
} else if (isdst) {
(void) strcpy(abbr, slashp + 1);
} else {
if (slashp > format)
(void) strncpy(abbr, format,
(unsigned) (slashp - format));
abbr[slashp - format] = '\0';
}
if (!doquotes)
return;
for (cp = abbr; *cp != '\0'; ++cp)
if (strchr("ABCDEFGHIJKLMNOPQRSTUVWXYZ", *cp) == NULL &&
strchr("abcdefghijklmnopqrstuvwxyz", *cp) == NULL)
break;
len = strlen(abbr);
if (len > 0 && *cp == '\0')
return;
abbr[len + 2] = '\0';
abbr[len + 1] = '>';
for ( ; len > 0; --len)
abbr[len] = abbr[len - 1];
abbr[0] = '<';
}
static void
updateminmax(x)
const int x;
{
if (min_year > x)
min_year = x;
if (max_year < x)
max_year = x;
}
static int
stringoffset(result, offset)
char * result;
long offset;
{
register int hours;
register int minutes;
register int seconds;
result[0] = '\0';
if (offset < 0) {
(void) strcpy(result, "-");
offset = -offset;
}
seconds = offset % SECSPERMIN;
offset /= SECSPERMIN;
minutes = offset % MINSPERHOUR;
offset /= MINSPERHOUR;
hours = offset;
if (hours >= HOURSPERDAY) {
result[0] = '\0';
return -1;
}
(void) sprintf(end(result), "%d", hours);
if (minutes != 0 || seconds != 0) {
(void) sprintf(end(result), ":%02d", minutes);
if (seconds != 0)
(void) sprintf(end(result), ":%02d", seconds);
}
return 0;
}
static int
stringrule(result, rp, dstoff, gmtoff)
char * result;
const struct rule * const rp;
const long dstoff;
const long gmtoff;
{
register long tod;
result = end(result);
if (rp->r_dycode == DC_DOM) {
register int month, total;
if (rp->r_dayofmonth == 29 && rp->r_month == TM_FEBRUARY)
return -1;
total = 0;
for (month = 0; month < rp->r_month; ++month)
total += len_months[0][month];
(void) sprintf(result, "J%d", total + rp->r_dayofmonth);
} else {
register int week;
if (rp->r_dycode == DC_DOWGEQ) {
week = 1 + rp->r_dayofmonth / DAYSPERWEEK;
if ((week - 1) * DAYSPERWEEK + 1 != rp->r_dayofmonth)
return -1;
} else if (rp->r_dycode == DC_DOWLEQ) {
if (rp->r_dayofmonth == len_months[1][rp->r_month])
week = 5;
else {
week = 1 + rp->r_dayofmonth / DAYSPERWEEK;
if (week * DAYSPERWEEK - 1 != rp->r_dayofmonth)
return -1;
}
} else return -1; /* "cannot happen" */
(void) sprintf(result, "M%d.%d.%d",
rp->r_month + 1, week, rp->r_wday);
}
tod = rp->r_tod;
if (rp->r_todisgmt)
tod += gmtoff;
if (rp->r_todisstd && rp->r_stdoff == 0)
tod += dstoff;
if (tod < 0) {
result[0] = '\0';
return -1;
}
if (tod != 2 * SECSPERMIN * MINSPERHOUR) {
(void) strcat(result, "/");
if (stringoffset(end(result), tod) != 0)
return -1;
}
return 0;
}
static void
stringzone(result, zpfirst, zonecount)
char * result;
const struct zone * const zpfirst;
const int zonecount;
{
register const struct zone * zp;
register struct rule * rp;
register struct rule * stdrp;
register struct rule * dstrp;
register int i;
register const char * abbrvar;
result[0] = '\0';
zp = zpfirst + zonecount - 1;
stdrp = dstrp = NULL;
for (i = 0; i < zp->z_nrules; ++i) {
rp = &zp->z_rules[i];
if (rp->r_hiwasnum || rp->r_hiyear != INT_MAX)
continue;
if (rp->r_yrtype != NULL)
continue;
if (rp->r_stdoff == 0) {
if (stdrp == NULL)
stdrp = rp;
else return;
} else {
if (dstrp == NULL)
dstrp = rp;
else return;
}
}
if (stdrp == NULL && dstrp == NULL) {
/*
** There are no rules running through "max".
** Let's find the latest rule.
*/
for (i = 0; i < zp->z_nrules; ++i) {
rp = &zp->z_rules[i];
if (stdrp == NULL || rp->r_hiyear > stdrp->r_hiyear ||
(rp->r_hiyear == stdrp->r_hiyear &&
rp->r_month > stdrp->r_month))
stdrp = rp;
}
if (stdrp != NULL && stdrp->r_stdoff != 0)
return; /* We end up in DST (a POSIX no-no). */
/*
** Horrid special case: if year is 2037,
** presume this is a zone handled on a year-by-year basis;
** do not try to apply a rule to the zone.
*/
if (stdrp != NULL && stdrp->r_hiyear == 2037)
return;
}
if (stdrp == NULL && zp->z_nrules != 0)
return;
abbrvar = (stdrp == NULL) ? "" : stdrp->r_abbrvar;
doabbr(result, zp->z_format, abbrvar, FALSE, TRUE);
if (stringoffset(end(result), -zp->z_gmtoff) != 0) {
result[0] = '\0';
return;
}
if (dstrp == NULL)
return;
doabbr(end(result), zp->z_format, dstrp->r_abbrvar, TRUE, TRUE);
if (dstrp->r_stdoff != SECSPERMIN * MINSPERHOUR)
if (stringoffset(end(result),
-(zp->z_gmtoff + dstrp->r_stdoff)) != 0) {
result[0] = '\0';
return;
}
(void) strcat(result, ",");
if (stringrule(result, dstrp, dstrp->r_stdoff, zp->z_gmtoff) != 0) {
result[0] = '\0';
return;
}
(void) strcat(result, ",");
if (stringrule(result, stdrp, dstrp->r_stdoff, zp->z_gmtoff) != 0) {
result[0] = '\0';
return;
}
}
static void
outzone(zpfirst, zonecount)
const struct zone * const zpfirst;
const int zonecount;
{
register const struct zone * zp;
register struct rule * rp;
register int i, j;
register int usestart, useuntil;
register zic_t starttime, untiltime;
register long gmtoff;
register long stdoff;
register int year;
register long startoff;
register int startttisstd;
register int startttisgmt;
register int type;
register char * startbuf;
register char * ab;
register char * envvar;
register int max_abbr_len;
register int max_envvar_len;
#ifdef ICU
int finalRuleYear, finalRuleIndex;
const struct rule* finalRule1;
const struct rule* finalRule2;
#endif
max_abbr_len = 2 + max_format_len + max_abbrvar_len;
max_envvar_len = 2 * max_abbr_len + 5 * 9;
startbuf = emalloc(max_abbr_len + 1);
ab = emalloc(max_abbr_len + 1);
envvar = emalloc(max_envvar_len + 1);
INITIALIZE(untiltime);
INITIALIZE(starttime);
/*
** Now. . .finally. . .generate some useful data!
*/
timecnt = 0;
typecnt = 0;
charcnt = 0;
/*
** Thanks to Earl Chew
** for noting the need to unconditionally initialize startttisstd.
*/
startttisstd = FALSE;
startttisgmt = FALSE;
min_year = max_year = EPOCH_YEAR;
if (leapseen) {
updateminmax(leapminyear);
updateminmax(leapmaxyear);
}
for (i = 0; i < zonecount; ++i) {
zp = &zpfirst[i];
if (i < zonecount - 1)
updateminmax(zp->z_untilrule.r_loyear);
for (j = 0; j < zp->z_nrules; ++j) {
rp = &zp->z_rules[j];
if (rp->r_lowasnum)
updateminmax(rp->r_loyear);
if (rp->r_hiwasnum)
updateminmax(rp->r_hiyear);
}
}
/*
** Generate lots of data if a rule can't cover all future times.
*/
stringzone(envvar, zpfirst, zonecount);
if (noise && envvar[0] == '\0') {
register char * wp;
wp = ecpyalloc(_("no POSIX environment variable for zone"));
wp = ecatalloc(wp, " ");
wp = ecatalloc(wp, zpfirst->z_name);
warning(wp);
ifree(wp);
}
if (envvar[0] == '\0') {
if (min_year >= INT_MIN + YEARSPERREPEAT)
min_year -= YEARSPERREPEAT;
else min_year = INT_MIN;
if (max_year <= INT_MAX - YEARSPERREPEAT)
max_year += YEARSPERREPEAT;
else max_year = INT_MAX;
}
/*
** For the benefit of older systems,
** generate data from 1900 through 2037.
*/
if (min_year > 1900)
min_year = 1900;
if (max_year < 2037)
max_year = 2037;
for (i = 0; i < zonecount; ++i) {
/*
** A guess that may well be corrected later.
*/
stdoff = 0;
zp = &zpfirst[i];
usestart = i > 0 && (zp - 1)->z_untiltime > min_time;
useuntil = i < (zonecount - 1);
if (useuntil && zp->z_untiltime <= min_time)
continue;
gmtoff = zp->z_gmtoff;
eat(zp->z_filename, zp->z_linenum);
*startbuf = '\0';
startoff = zp->z_gmtoff;
#ifdef ICU
finalRuleYear = finalRuleIndex = -1;
finalRule1 = finalRule2 = NULL;
if (i == (zonecount - 1)) { /* !useuntil */
/* Look for exactly 2 rules that end at 'max' and
* note them. Determine max(r_loyear) for the 2 of
* them. */
for (j=0; j<zp->z_nrules; ++j) {
rp = &zp->z_rules[j];
if (rp->r_hiyear == INT_MAX) {
if (finalRule1 == NULL) {
finalRule1 = rp;
finalRuleYear = rp->r_loyear;
} else if (finalRule2 == NULL) {
finalRule2 = rp;
if (rp->r_loyear > finalRuleYear) {
finalRuleYear = rp->r_loyear;
}
} else {
error("more than two max rules found (ICU)");
exit(EXIT_FAILURE);
}
}
}
if (finalRule1 != NULL && finalRule2 == NULL) {
error("only one max rule found (ICU)");
exit(EXIT_FAILURE);
}
if (finalRule1 != NULL) {
if (finalRule1->r_stdoff == finalRule2->r_stdoff) {
/* America/Resolute in 2009a uses a pair of rules
* which does not change the offset. ICU ignores
* such rules without actual time transitions. */
finalRuleYear = finalRuleIndex = -1;
finalRule1 = finalRule2 = NULL;
} else {
/* Swap if necessary so finalRule1 occurs before
* finalRule2 */
if (finalRule1->r_month > finalRule2->r_month) {
const struct rule* t = finalRule1;
finalRule1 = finalRule2;
finalRule2 = t;
}
/* Add final rule to our list */
finalRuleIndex = add_icu_final_rules(finalRule1, finalRule2);
}
}
}
#endif
if (zp->z_nrules == 0) {
stdoff = zp->z_stdoff;
doabbr(startbuf, zp->z_format,
(char *) NULL, stdoff != 0, FALSE);
type = addtype(oadd(zp->z_gmtoff, stdoff),
#ifdef ICU
zp->z_gmtoff, stdoff,
#endif
startbuf, stdoff != 0, startttisstd,
startttisgmt);
if (usestart) {
addtt(starttime, type);
usestart = FALSE;
} else if (stdoff != 0)
addtt(min_time, type);
} else for (year = min_year; year <= max_year; ++year) {
if (useuntil && year > zp->z_untilrule.r_hiyear)
break;
/*
** Mark which rules to do in the current year.
** For those to do, calculate rpytime(rp, year);
*/
for (j = 0; j < zp->z_nrules; ++j) {
rp = &zp->z_rules[j];
eats(zp->z_filename, zp->z_linenum,
rp->r_filename, rp->r_linenum);
rp->r_todo = year >= rp->r_loyear &&
year <= rp->r_hiyear &&
yearistype(year, rp->r_yrtype);
if (rp->r_todo)
rp->r_temp = rpytime(rp, year);
}
for ( ; ; ) {
register int k;
register zic_t jtime, ktime;
register long offset;
INITIALIZE(ktime);
if (useuntil) {
/*
** Turn untiltime into UTC
** assuming the current gmtoff and
** stdoff values.
*/
untiltime = zp->z_untiltime;
if (!zp->z_untilrule.r_todisgmt)
untiltime = tadd(untiltime,
-gmtoff);
if (!zp->z_untilrule.r_todisstd)
untiltime = tadd(untiltime,
-stdoff);
}
/*
** Find the rule (of those to do, if any)
** that takes effect earliest in the year.
*/
k = -1;
for (j = 0; j < zp->z_nrules; ++j) {
rp = &zp->z_rules[j];
if (!rp->r_todo)
continue;
eats(zp->z_filename, zp->z_linenum,
rp->r_filename, rp->r_linenum);
offset = rp->r_todisgmt ? 0 : gmtoff;
if (!rp->r_todisstd)
offset = oadd(offset, stdoff);
jtime = rp->r_temp;
if (jtime == min_time ||
jtime == max_time)
continue;
jtime = tadd(jtime, -offset);
if (k < 0 || jtime < ktime) {
k = j;
ktime = jtime;
}
}
if (k < 0)
break; /* go on to next year */
rp = &zp->z_rules[k];
rp->r_todo = FALSE;
if (useuntil && ktime >= untiltime)
break;
stdoff = rp->r_stdoff;
if (usestart && ktime == starttime)
usestart = FALSE;
if (usestart) {
if (ktime < starttime) {
startoff = oadd(zp->z_gmtoff,
stdoff);
doabbr(startbuf, zp->z_format,
rp->r_abbrvar,
rp->r_stdoff != 0,
FALSE);
continue;
}
if (*startbuf == '\0' &&
startoff == oadd(zp->z_gmtoff,
stdoff)) {
doabbr(startbuf,
zp->z_format,
rp->r_abbrvar,
rp->r_stdoff !=
0,
FALSE);
}
}
#ifdef ICU
if (year >= finalRuleYear && rp == finalRule1) {
/* We want to shift final year 1 year after
* the actual final rule takes effect (year + 1),
* because the previous type is valid until the first
* transition defined by the final rule. Otherwise
* we may see unexpected offset shift at the
* begining of the year when the final rule takes
* effect. */
/* ICU currently can support signed int32 transition
* times. Thus, the transitions in year 2038 may be
* truncated. At this moment (tzdata2008g), only
* Rule Brazil is impacted by this limitation, because
* the final set of rules are starting in 2038. Although
* this code put the first couple of transitions populated
* by the final rules, they might be dropped off when
* collecting transition times by tz2icu. */
emit_icu_zone(icuFile,
zpfirst->z_name, zp->z_gmtoff,
rp, finalRuleIndex, year + 1);
/* only emit this for the first year */
finalRule1 = NULL;
}
#endif
eats(zp->z_filename, zp->z_linenum,
rp->r_filename, rp->r_linenum);
doabbr(ab, zp->z_format, rp->r_abbrvar,
rp->r_stdoff != 0, FALSE);
offset = oadd(zp->z_gmtoff, rp->r_stdoff);
#ifdef ICU
type = addtype(offset, zp->z_gmtoff, rp->r_stdoff,
ab, rp->r_stdoff != 0,
rp->r_todisstd, rp->r_todisgmt);
#else
type = addtype(offset, ab, rp->r_stdoff != 0,
rp->r_todisstd, rp->r_todisgmt);
#endif
addtt(ktime, type);
}
}
if (usestart) {
if (*startbuf == '\0' &&
zp->z_format != NULL &&
strchr(zp->z_format, '%') == NULL &&
strchr(zp->z_format, '/') == NULL)
(void) strcpy(startbuf, zp->z_format);
eat(zp->z_filename, zp->z_linenum);
if (*startbuf == '\0')
error(_("can't determine time zone abbreviation to use just after until time"));
else addtt(starttime,
#ifdef ICU
addtype(startoff,
zp->z_gmtoff, startoff - zp->z_gmtoff,
startbuf,
startoff != zp->z_gmtoff,
startttisstd,
startttisgmt));
#else
addtype(startoff, startbuf,
startoff != zp->z_gmtoff,
startttisstd,
startttisgmt));
#endif
}
/*
** Now we may get to set starttime for the next zone line.
*/
if (useuntil) {
startttisstd = zp->z_untilrule.r_todisstd;
startttisgmt = zp->z_untilrule.r_todisgmt;
starttime = zp->z_untiltime;
if (!startttisstd)
starttime = tadd(starttime, -stdoff);
if (!startttisgmt)
starttime = tadd(starttime, -gmtoff);
}
}
writezone(zpfirst->z_name, envvar);
ifree(startbuf);
ifree(ab);
ifree(envvar);
}
static void
addtt(starttime, type)
const zic_t starttime;
int type;
{
if (starttime <= min_time ||
(timecnt == 1 && attypes[0].at < min_time)) {
gmtoffs[0] = gmtoffs[type];
#ifdef ICU
rawoffs[0] = rawoffs[type];
dstoffs[0] = dstoffs[type];
#endif
isdsts[0] = isdsts[type];
ttisstds[0] = ttisstds[type];
ttisgmts[0] = ttisgmts[type];
if (abbrinds[type] != 0)
(void) strcpy(chars, &chars[abbrinds[type]]);
abbrinds[0] = 0;
charcnt = strlen(chars) + 1;
typecnt = 1;
timecnt = 0;
type = 0;
}
if (timecnt >= TZ_MAX_TIMES) {
error(_("too many transitions?!"));
exit(EXIT_FAILURE);
}
attypes[timecnt].at = starttime;
attypes[timecnt].type = type;
++timecnt;
}
static int
#ifdef ICU
addtype(gmtoff, rawoff, dstoff, abbr, isdst, ttisstd, ttisgmt)
const long gmtoff;
const long rawoff;
const long dstoff;
#else
addtype(gmtoff, abbr, isdst, ttisstd, ttisgmt)
const long gmtoff;
#endif
const char * const abbr;
const int isdst;
const int ttisstd;
const int ttisgmt;
{
register int i, j;
if (isdst != TRUE && isdst != FALSE) {
error(_("internal error - addtype called with bad isdst"));
exit(EXIT_FAILURE);
}
if (ttisstd != TRUE && ttisstd != FALSE) {
error(_("internal error - addtype called with bad ttisstd"));
exit(EXIT_FAILURE);
}
if (ttisgmt != TRUE && ttisgmt != FALSE) {
error(_("internal error - addtype called with bad ttisgmt"));
exit(EXIT_FAILURE);
}
#ifdef ICU
if (isdst != (dstoff != 0)) {
error(_("internal error - addtype called with bad isdst/dstoff"));
(void) exit(EXIT_FAILURE);
}
if (gmtoff != (rawoff + dstoff)) {
error(_("internal error - addtype called with bad gmt/raw/dstoff"));
(void) exit(EXIT_FAILURE);
}
#endif
/*
** See if there's already an entry for this zone type.
** If so, just return its index.
*/
for (i = 0; i < typecnt; ++i) {
if (gmtoff == gmtoffs[i] && isdst == isdsts[i] &&
#ifdef ICU
rawoff == rawoffs[i] && dstoff == dstoffs[i] &&
#endif
strcmp(abbr, &chars[abbrinds[i]]) == 0 &&
ttisstd == ttisstds[i] &&
ttisgmt == ttisgmts[i])
return i;
}
/*
** There isn't one; add a new one, unless there are already too
** many.
*/
if (typecnt >= TZ_MAX_TYPES) {
error(_("too many local time types"));
exit(EXIT_FAILURE);
}