struct lconv* lc;
lc = localeconv();
- if (lc && lc->decimal_point)
- /* We assume that decimal separator aka the radix
- * character is always a single character. If it
- * ever is a string, this needs to be rethunk. */
- PL_numeric_radix = *lc->decimal_point;
+ if (lc && lc->decimal_point) {
+ if (lc->decimal_point[0] == '.' && lc->decimal_point[1] == 0) {
+ SvREFCNT_dec(PL_numeric_radix_sv);
+ PL_numeric_radix_sv = Nullsv;
+ }
+ else {
+ if (PL_numeric_radix_sv)
+ sv_setpv(PL_numeric_radix_sv, lc->decimal_point);
+ else
+ PL_numeric_radix_sv = newSVpv(lc->decimal_point, 0);
+ }
+ }
else
- PL_numeric_radix = 0;
+ PL_numeric_radix_sv = Nullsv;
# endif /* HAS_LOCALECONV */
#endif /* USE_LOCALE_NUMERIC */
}
* -1 = fallback to C locale failed
*/
-#ifdef USE_LOCALE
+#if defined(USE_LOCALE)
#ifdef USE_LOCALE_CTYPE
char *curctype = NULL;
lc_all ? lc_all : "unset",
lc_all ? '"' : ')');
+#if defined(USE_ENVIRON_ARRAY)
{
char **e;
for (e = environ; *e; e++) {
(int)(p - *e), *e, p + 1);
}
}
+#else
+ PerlIO_printf(Perl_error_log,
+ "\t(possibly more locale environment variables)\n");
+#endif
PerlIO_printf(Perl_error_log,
"\tLANG = %c%s%c\n",
void
Perl_my_setenv(pTHX_ char *nam,char *val)
{
-
-#ifdef USE_WIN32_RTL_ENV
-
- register char *envstr;
- STRLEN namlen = strlen(nam);
- STRLEN vallen;
- char *oldstr = environ[setenv_getix(nam)];
-
- /* putenv() has totally broken semantics in both the Borland
- * and Microsoft CRTLs. They either store the passed pointer in
- * the environment without making a copy, or make a copy and don't
- * free it. And on top of that, they dont free() old entries that
- * are being replaced/deleted. This means the caller must
- * free any old entries somehow, or we end up with a memory
- * leak every time my_setenv() is called. One might think
- * one could directly manipulate environ[], like the UNIX code
- * above, but direct changes to environ are not allowed when
- * calling putenv(), since the RTLs maintain an internal
- * *copy* of environ[]. Bad, bad, *bad* stink.
- * GSAR 97-06-07
- */
-
- if (!val) {
- if (!oldstr)
- return;
- val = "";
- vallen = 0;
- }
- else
- vallen = strlen(val);
- envstr = (char*)safesysmalloc((namlen + vallen + 3) * sizeof(char));
- (void)sprintf(envstr,"%s=%s",nam,val);
- (void)PerlEnv_putenv(envstr);
- if (oldstr)
- safesysfree(oldstr);
-#ifdef _MSC_VER
- safesysfree(envstr); /* MSVCRT leaks without this */
-#endif
-
-#else /* !USE_WIN32_RTL_ENV */
-
register char *envstr;
STRLEN len = strlen(nam) + 3;
if (!val) {
(void)sprintf(envstr,"%s=%s",nam,val);
(void)PerlEnv_putenv(envstr);
Safefree(envstr);
-
-#endif
}
#endif /* WIN32 */
VTOH(vtohl,long)
#endif
+PerlIO *
+Perl_my_popen_list(pTHX_ char *mode, int n, SV **args)
+{
+#if (!defined(DOSISH) || defined(HAS_FORK) || defined(AMIGAOS)) && !defined(OS2) && !defined(VMS) && !defined(__OPEN_VM) && !defined(EPOC) && !defined(MACOS_TRADITIONAL)
+ int p[2];
+ register I32 This, that;
+ register Pid_t pid;
+ SV *sv;
+ I32 did_pipes = 0;
+ int pp[2];
+
+ PERL_FLUSHALL_FOR_CHILD;
+ This = (*mode == 'w');
+ that = !This;
+ if (PL_tainting) {
+ taint_env();
+ taint_proper("Insecure %s%s", "EXEC");
+ }
+ if (PerlProc_pipe(p) < 0)
+ return Nullfp;
+ /* Try for another pipe pair for error return */
+ if (PerlProc_pipe(pp) >= 0)
+ did_pipes = 1;
+ while ((pid = vfork()) < 0) {
+ if (errno != EAGAIN) {
+ PerlLIO_close(p[This]);
+ if (did_pipes) {
+ PerlLIO_close(pp[0]);
+ PerlLIO_close(pp[1]);
+ }
+ return Nullfp;
+ }
+ sleep(5);
+ }
+ if (pid == 0) {
+ /* Child */
+ GV* tmpgv;
+ int fd;
+#undef THIS
+#undef THAT
+#define THIS that
+#define THAT This
+ /* Close parent's end of _the_ pipe */
+ PerlLIO_close(p[THAT]);
+ /* Close parent's end of error status pipe (if any) */
+ if (did_pipes) {
+ PerlLIO_close(pp[0]);
+#if defined(HAS_FCNTL) && defined(F_SETFD)
+ /* Close error pipe automatically if exec works */
+ fcntl(pp[1], F_SETFD, FD_CLOEXEC);
+#endif
+ }
+ /* Now dup our end of _the_ pipe to right position */
+ if (p[THIS] != (*mode == 'r')) {
+ PerlLIO_dup2(p[THIS], *mode == 'r');
+ PerlLIO_close(p[THIS]);
+ }
+#if !defined(HAS_FCNTL) || !defined(F_SETFD)
+ /* No automatic close - do it by hand */
+#ifndef NOFILE
+#define NOFILE 20
+#endif
+ for (fd = PL_maxsysfd + 1; fd < NOFILE; fd++) {
+ if (fd != pp[1])
+ PerlLIO_close(fd);
+ }
+#endif
+ do_aexec5(Nullsv, args-1, args-1+n, pp[1], did_pipes);
+ PerlProc__exit(1);
+#undef THIS
+#undef THAT
+ }
+ /* Parent */
+ do_execfree(); /* free any memory malloced by child on vfork */
+ /* Close child's end of pipe */
+ PerlLIO_close(p[that]);
+ if (did_pipes)
+ PerlLIO_close(pp[1]);
+ /* Keep the lower of the two fd numbers */
+ if (p[that] < p[This]) {
+ PerlLIO_dup2(p[This], p[that]);
+ PerlLIO_close(p[This]);
+ p[This] = p[that];
+ }
+ LOCK_FDPID_MUTEX;
+ sv = *av_fetch(PL_fdpid,p[This],TRUE);
+ UNLOCK_FDPID_MUTEX;
+ (void)SvUPGRADE(sv,SVt_IV);
+ SvIVX(sv) = pid;
+ PL_forkprocess = pid;
+ /* If we managed to get status pipe check for exec fail */
+ if (did_pipes && pid > 0) {
+ int errkid;
+ int n = 0, n1;
+
+ while (n < sizeof(int)) {
+ n1 = PerlLIO_read(pp[0],
+ (void*)(((char*)&errkid)+n),
+ (sizeof(int)) - n);
+ if (n1 <= 0)
+ break;
+ n += n1;
+ }
+ PerlLIO_close(pp[0]);
+ did_pipes = 0;
+ if (n) { /* Error */
+ int pid2, status;
+ if (n != sizeof(int))
+ Perl_croak(aTHX_ "panic: kid popen errno read");
+ do {
+ pid2 = wait4pid(pid, &status, 0);
+ } while (pid2 == -1 && errno == EINTR);
+ errno = errkid; /* Propagate errno from kid */
+ return Nullfp;
+ }
+ }
+ if (did_pipes)
+ PerlLIO_close(pp[0]);
+ return PerlIO_fdopen(p[This], mode);
+#else
+ Perl_croak(aTHX_ "List form of piped open not implemented");
+ return (PerlIO *) NULL;
+#endif
+}
+
/* VMS' my_popen() is in VMS.c, same with OS/2. */
#if (!defined(DOSISH) || defined(HAS_FORK) || defined(AMIGAOS)) && !defined(VMS) && !defined(__OPEN_VM) && !defined(EPOC) && !defined(MACOS_TRADITIONAL)
PerlIO *
PerlLIO_close(pp[0]);
did_pipes = 0;
if (n) { /* Error */
+ int pid2, status;
if (n != sizeof(int))
Perl_croak(aTHX_ "panic: kid popen errno read");
+ do {
+ pid2 = wait4pid(pid, &status, 0);
+ } while (pid2 == -1 && errno == EINTR);
errno = errkid; /* Propagate errno from kid */
return Nullfp;
}
sigemptyset(&act.sa_mask);
act.sa_flags = 0;
#ifdef SA_RESTART
+#if !defined(USE_PERLIO) || defined(PERL_OLD_SIGNALS)
act.sa_flags |= SA_RESTART; /* SVR4, 4.3+BSD */
#endif
+#endif
#ifdef SA_NOCLDWAIT
if (signo == SIGCHLD && handler == (Sighandler_t)SIG_IGN)
act.sa_flags |= SA_NOCLDWAIT;
sigemptyset(&act.sa_mask);
act.sa_flags = 0;
#ifdef SA_RESTART
+#if !defined(USE_PERLIO) || defined(PERL_OLD_SIGNALS)
act.sa_flags |= SA_RESTART; /* SVR4, 4.3+BSD */
#endif
+#endif
#ifdef SA_NOCLDWAIT
if (signo == SIGCHLD && handler == (Sighandler_t)SIG_IGN)
act.sa_flags |= SA_NOCLDWAIT;
LOCK_FDPID_MUTEX;
svp = av_fetch(PL_fdpid,PerlIO_fileno(ptr),TRUE);
UNLOCK_FDPID_MUTEX;
- pid = SvIVX(*svp);
+ pid = (SvTYPE(*svp) == SVt_IV) ? SvIVX(*svp) : -1;
SvREFCNT_dec(*svp);
*svp = &PL_sv_undef;
#ifdef OS2
PL_tainted = t->Ttainted;
PL_curpm = t->Tcurpm; /* XXX No PMOP ref count */
PL_nrs = newSVsv(t->Tnrs);
- PL_rs = SvREFCNT_inc(PL_nrs);
+ PL_rs = t->Tnrs ? SvREFCNT_inc(PL_nrs) : Nullsv;
PL_last_in_gv = Nullgv;
- PL_ofs_sv = SvREFCNT_inc(PL_ofs_sv);
+ PL_ofs_sv = t->Tofs_sv ? SvREFCNT_inc(PL_ofs_sv) : Nullsv;
PL_defoutgv = (GV*)SvREFCNT_inc(t->Tdefoutgv);
PL_chopset = t->Tchopset;
PL_bodytarget = newSVsv(t->Tbodytarget);
op == OP_LEAVEWRITE ? "write" : /* "write exit" not nice */
PL_op_desc[op];
char *pars = OP_IS_FILETEST(op) ? "" : "()";
- char *type = OP_IS_SOCKET(op) || (io && IoTYPE(io) == IoTYPE_SOCKET) ?
+ char *type = OP_IS_SOCKET(op) ||
+ (gv && io && IoTYPE(io) == IoTYPE_SOCKET) ?
"socket" : "filehandle";
char *name = NULL;
- if (io && IoTYPE(io) == IoTYPE_CLOSED) {
+ if (gv && io && IoTYPE(io) == IoTYPE_CLOSED) {
vile = "closed";
warn_type = WARN_CLOSED;
}
else {
Perl_warner(aTHX_ warn_type,
"%s%s on %s %s", func, pars, vile, type);
- if (io && IoDIRP(io) && !(IoFLAGS(io) & IOf_FAKE_DIRP))
+ if (gv && io && IoDIRP(io) && !(IoFLAGS(io) & IOf_FAKE_DIRP))
Perl_warner(aTHX_ warn_type,
"\t(Are you trying to call %s%s on dirhandle?)\n",
func, pars);
}
}
+
+#ifdef EBCDIC
+/* in ASCII order, not that it matters */
+static const char controllablechars[] = "?@ABCDEFGHIJKLMNOPQRSTUVWXYZ[\\]^_";
+
+int
+Perl_ebcdic_control(pTHX_ int ch)
+{
+ if (ch > 'a') {
+ char *ctlp;
+
+ if (islower(ch))
+ ch = toupper(ch);
+
+ if ((ctlp = strchr(controllablechars, ch)) == 0) {
+ Perl_die(aTHX_ "unrecognised control character '%c'\n", ch);
+ }
+
+ if (ctlp == controllablechars)
+ return('\177'); /* DEL */
+ else
+ return((unsigned char)(ctlp - controllablechars - 1));
+ } else { /* Want uncontrol */
+ if (ch == '\177' || ch == -1)
+ return('?');
+ else if (ch == '\157')
+ return('\177');
+ else if (ch == '\174')
+ return('\000');
+ else if (ch == '^') /* '\137' in 1047, '\260' in 819 */
+ return('\036');
+ else if (ch == '\155')
+ return('\037');
+ else if (0 < ch && ch < (sizeof(controllablechars) - 1))
+ return(controllablechars[ch+1]);
+ else
+ Perl_die(aTHX_ "invalid control request: '\\%03o'\n", ch & 0xFF);
+ }
+}
+#endif
+
+/* XXX struct tm on some systems (SunOS4/BSD) contains extra (non POSIX)
+ * fields for which we don't have Configure support yet:
+ * char *tm_zone; -- abbreviation of timezone name
+ * long tm_gmtoff; -- offset from GMT in seconds
+ * To workaround core dumps from the uninitialised tm_zone we get the
+ * system to give us a reasonable struct to copy. This fix means that
+ * strftime uses the tm_zone and tm_gmtoff values returned by
+ * localtime(time()). That should give the desired result most of the
+ * time. But probably not always!
+ *
+ * This is a temporary workaround to be removed once Configure
+ * support is added and NETaa14816 is considered in full.
+ * It does not address tzname aspects of NETaa14816.
+ */
+#ifdef HAS_GNULIBC
+# ifndef STRUCT_TM_HASZONE
+# define STRUCT_TM_HASZONE
+# endif
+#endif
+
+void
+Perl_init_tm(pTHX_ struct tm *ptm) /* see mktime, strftime and asctime */
+{
+#ifdef STRUCT_TM_HASZONE
+ Time_t now;
+ (void)time(&now);
+ Copy(localtime(&now), ptm, 1, struct tm);
+#endif
+}
+
+/*
+ * mini_mktime - normalise struct tm values without the localtime()
+ * semantics (and overhead) of mktime().
+ */
+void
+Perl_mini_mktime(pTHX_ struct tm *ptm)
+{
+ int yearday;
+ int secs;
+ int month, mday, year, jday;
+ int odd_cent, odd_year;
+
+#define DAYS_PER_YEAR 365
+#define DAYS_PER_QYEAR (4*DAYS_PER_YEAR+1)
+#define DAYS_PER_CENT (25*DAYS_PER_QYEAR-1)
+#define DAYS_PER_QCENT (4*DAYS_PER_CENT+1)
+#define SECS_PER_HOUR (60*60)
+#define SECS_PER_DAY (24*SECS_PER_HOUR)
+/* parentheses deliberately absent on these two, otherwise they don't work */
+#define MONTH_TO_DAYS 153/5
+#define DAYS_TO_MONTH 5/153
+/* offset to bias by March (month 4) 1st between month/mday & year finding */
+#define YEAR_ADJUST (4*MONTH_TO_DAYS+1)
+/* as used here, the algorithm leaves Sunday as day 1 unless we adjust it */
+#define WEEKDAY_BIAS 6 /* (1+6)%7 makes Sunday 0 again */
+
+/*
+ * Year/day algorithm notes:
+ *
+ * With a suitable offset for numeric value of the month, one can find
+ * an offset into the year by considering months to have 30.6 (153/5) days,
+ * using integer arithmetic (i.e., with truncation). To avoid too much
+ * messing about with leap days, we consider January and February to be
+ * the 13th and 14th month of the previous year. After that transformation,
+ * we need the month index we use to be high by 1 from 'normal human' usage,
+ * so the month index values we use run from 4 through 15.
+ *
+ * Given that, and the rules for the Gregorian calendar (leap years are those
+ * divisible by 4 unless also divisible by 100, when they must be divisible
+ * by 400 instead), we can simply calculate the number of days since some
+ * arbitrary 'beginning of time' by futzing with the (adjusted) year number,
+ * the days we derive from our month index, and adding in the day of the
+ * month. The value used here is not adjusted for the actual origin which
+ * it normally would use (1 January A.D. 1), since we're not exposing it.
+ * We're only building the value so we can turn around and get the
+ * normalised values for the year, month, day-of-month, and day-of-year.
+ *
+ * For going backward, we need to bias the value we're using so that we find
+ * the right year value. (Basically, we don't want the contribution of
+ * March 1st to the number to apply while deriving the year). Having done
+ * that, we 'count up' the contribution to the year number by accounting for
+ * full quadracenturies (400-year periods) with their extra leap days, plus
+ * the contribution from full centuries (to avoid counting in the lost leap
+ * days), plus the contribution from full quad-years (to count in the normal
+ * leap days), plus the leftover contribution from any non-leap years.
+ * At this point, if we were working with an actual leap day, we'll have 0
+ * days left over. This is also true for March 1st, however. So, we have
+ * to special-case that result, and (earlier) keep track of the 'odd'
+ * century and year contributions. If we got 4 extra centuries in a qcent,
+ * or 4 extra years in a qyear, then it's a leap day and we call it 29 Feb.
+ * Otherwise, we add back in the earlier bias we removed (the 123 from
+ * figuring in March 1st), find the month index (integer division by 30.6),
+ * and the remainder is the day-of-month. We then have to convert back to
+ * 'real' months (including fixing January and February from being 14/15 in
+ * the previous year to being in the proper year). After that, to get
+ * tm_yday, we work with the normalised year and get a new yearday value for
+ * January 1st, which we subtract from the yearday value we had earlier,
+ * representing the date we've re-built. This is done from January 1
+ * because tm_yday is 0-origin.
+ *
+ * Since POSIX time routines are only guaranteed to work for times since the
+ * UNIX epoch (00:00:00 1 Jan 1970 UTC), the fact that this algorithm
+ * applies Gregorian calendar rules even to dates before the 16th century
+ * doesn't bother me. Besides, you'd need cultural context for a given
+ * date to know whether it was Julian or Gregorian calendar, and that's
+ * outside the scope for this routine. Since we convert back based on the
+ * same rules we used to build the yearday, you'll only get strange results
+ * for input which needed normalising, or for the 'odd' century years which
+ * were leap years in the Julian calander but not in the Gregorian one.
+ * I can live with that.
+ *
+ * This algorithm also fails to handle years before A.D. 1 gracefully, but
+ * that's still outside the scope for POSIX time manipulation, so I don't
+ * care.
+ */
+
+ year = 1900 + ptm->tm_year;
+ month = ptm->tm_mon;
+ mday = ptm->tm_mday;
+ /* allow given yday with no month & mday to dominate the result */
+ if (ptm->tm_yday >= 0 && mday <= 0 && month <= 0) {
+ month = 0;
+ mday = 0;
+ jday = 1 + ptm->tm_yday;
+ }
+ else {
+ jday = 0;
+ }
+ if (month >= 2)
+ month+=2;
+ else
+ month+=14, year--;
+ yearday = DAYS_PER_YEAR * year + year/4 - year/100 + year/400;
+ yearday += month*MONTH_TO_DAYS + mday + jday;
+ /*
+ * Note that we don't know when leap-seconds were or will be,
+ * so we have to trust the user if we get something which looks
+ * like a sensible leap-second. Wild values for seconds will
+ * be rationalised, however.
+ */
+ if ((unsigned) ptm->tm_sec <= 60) {
+ secs = 0;
+ }
+ else {
+ secs = ptm->tm_sec;
+ ptm->tm_sec = 0;
+ }
+ secs += 60 * ptm->tm_min;
+ secs += SECS_PER_HOUR * ptm->tm_hour;
+ if (secs < 0) {
+ if (secs-(secs/SECS_PER_DAY*SECS_PER_DAY) < 0) {
+ /* got negative remainder, but need positive time */
+ /* back off an extra day to compensate */
+ yearday += (secs/SECS_PER_DAY)-1;
+ secs -= SECS_PER_DAY * (secs/SECS_PER_DAY - 1);
+ }
+ else {
+ yearday += (secs/SECS_PER_DAY);
+ secs -= SECS_PER_DAY * (secs/SECS_PER_DAY);
+ }
+ }
+ else if (secs >= SECS_PER_DAY) {
+ yearday += (secs/SECS_PER_DAY);
+ secs %= SECS_PER_DAY;
+ }
+ ptm->tm_hour = secs/SECS_PER_HOUR;
+ secs %= SECS_PER_HOUR;
+ ptm->tm_min = secs/60;
+ secs %= 60;
+ ptm->tm_sec += secs;
+ /* done with time of day effects */
+ /*
+ * The algorithm for yearday has (so far) left it high by 428.
+ * To avoid mistaking a legitimate Feb 29 as Mar 1, we need to
+ * bias it by 123 while trying to figure out what year it
+ * really represents. Even with this tweak, the reverse
+ * translation fails for years before A.D. 0001.
+ * It would still fail for Feb 29, but we catch that one below.
+ */
+ jday = yearday; /* save for later fixup vis-a-vis Jan 1 */
+ yearday -= YEAR_ADJUST;
+ year = (yearday / DAYS_PER_QCENT) * 400;
+ yearday %= DAYS_PER_QCENT;
+ odd_cent = yearday / DAYS_PER_CENT;
+ year += odd_cent * 100;
+ yearday %= DAYS_PER_CENT;
+ year += (yearday / DAYS_PER_QYEAR) * 4;
+ yearday %= DAYS_PER_QYEAR;
+ odd_year = yearday / DAYS_PER_YEAR;
+ year += odd_year;
+ yearday %= DAYS_PER_YEAR;
+ if (!yearday && (odd_cent==4 || odd_year==4)) { /* catch Feb 29 */
+ month = 1;
+ yearday = 29;
+ }
+ else {
+ yearday += YEAR_ADJUST; /* recover March 1st crock */
+ month = yearday*DAYS_TO_MONTH;
+ yearday -= month*MONTH_TO_DAYS;
+ /* recover other leap-year adjustment */
+ if (month > 13) {
+ month-=14;
+ year++;
+ }
+ else {
+ month-=2;
+ }
+ }
+ ptm->tm_year = year - 1900;
+ if (yearday) {
+ ptm->tm_mday = yearday;
+ ptm->tm_mon = month;
+ }
+ else {
+ ptm->tm_mday = 31;
+ ptm->tm_mon = month - 1;
+ }
+ /* re-build yearday based on Jan 1 to get tm_yday */
+ year--;
+ yearday = year*DAYS_PER_YEAR + year/4 - year/100 + year/400;
+ yearday += 14*MONTH_TO_DAYS + 1;
+ ptm->tm_yday = jday - yearday;
+ /* fix tm_wday if not overridden by caller */
+ if ((unsigned)ptm->tm_wday > 6)
+ ptm->tm_wday = (jday + WEEKDAY_BIAS) % 7;
+}
+
+char *
+Perl_my_strftime(pTHX_ char *fmt, int sec, int min, int hour, int mday, int mon, int year, int wday, int yday, int isdst)
+{
+#ifdef HAS_STRFTIME
+ char *buf;
+ int buflen;
+ struct tm mytm;
+ int len;
+
+ init_tm(&mytm); /* XXX workaround - see init_tm() above */
+ mytm.tm_sec = sec;
+ mytm.tm_min = min;
+ mytm.tm_hour = hour;
+ mytm.tm_mday = mday;
+ mytm.tm_mon = mon;
+ mytm.tm_year = year;
+ mytm.tm_wday = wday;
+ mytm.tm_yday = yday;
+ mytm.tm_isdst = isdst;
+ mini_mktime(&mytm);
+ buflen = 64;
+ New(0, buf, buflen, char);
+ len = strftime(buf, buflen, fmt, &mytm);
+ /*
+ ** The following is needed to handle to the situation where
+ ** tmpbuf overflows. Basically we want to allocate a buffer
+ ** and try repeatedly. The reason why it is so complicated
+ ** is that getting a return value of 0 from strftime can indicate
+ ** one of the following:
+ ** 1. buffer overflowed,
+ ** 2. illegal conversion specifier, or
+ ** 3. the format string specifies nothing to be returned(not
+ ** an error). This could be because format is an empty string
+ ** or it specifies %p that yields an empty string in some locale.
+ ** If there is a better way to make it portable, go ahead by
+ ** all means.
+ */
+ if ((len > 0 && len < buflen) || (len == 0 && *fmt == '\0'))
+ return buf;
+ else {
+ /* Possibly buf overflowed - try again with a bigger buf */
+ int fmtlen = strlen(fmt);
+ int bufsize = fmtlen + buflen;
+
+ New(0, buf, bufsize, char);
+ while (buf) {
+ buflen = strftime(buf, bufsize, fmt, &mytm);
+ if (buflen > 0 && buflen < bufsize)
+ break;
+ /* heuristic to prevent out-of-memory errors */
+ if (bufsize > 100*fmtlen) {
+ Safefree(buf);
+ buf = NULL;
+ break;
+ }
+ bufsize *= 2;
+ Renew(buf, bufsize, char);
+ }
+ return buf;
+ }
+#else
+ Perl_croak(aTHX_ "panic: no strftime");
+#endif
+}
+
projects / p5sagit/p5-mst-13.2.git / blobdiff