BLAPI_PROTO
bl_clock(lua_State *L)
{
double d = 0;
#ifdef _WIN32
// XXX this is a fast hack because we don't want to do 64bit calculation.
SYSTEMTIME st;
GetSystemTime(&st);
syncnow();
// XXX the may be some latency between our GetSystemTime and syncnow.
// So build again the "second" part.
d = (int)((now / 60) * 60);
d += st.wSecond;
d += (st.wMilliseconds / 1000.0f);
#else // !_WIN32
struct timeval tp;
gettimeofday(&tp, NULL);
d = bl_tv2double(&tp);
#endif // !_WIN32
lua_pushnumber(L, d);
return 1;
}
BLAPI_PROTO
bl_time(lua_State *L)
{
syncnow();
lua_pushinteger(L, now);
return 1;
}
BLAPI_PROTO
bl_ctime(lua_State *L)
{
syncnow();
lua_pushstring(L, ctime4(&now));
return 1;
}
int pwcuPlayAngel (void)
{
syncnow();
PWCU_START();
u.timeplayangel = cuser.timeplayangel = now;
PWCU_END();
}
// XXX numposts itself is an integer, but some records (by del post!?) may
// create invalid records as -1... so we'd better make it signed for real
// comparison.
char *get_restriction_reason(
unsigned int numlogindays,
unsigned int badpost,
unsigned int limits_logins,
unsigned int limits_badpost,
size_t sz_msg, char *msg) {
syncnow();
if (numlogindays / 10 < limits_logins) {
snprintf(msg, sz_msg,
STR_LOGINDAYS "未滿 %d " STR_LOGINDAYS
"(目前%d" STR_LOGINDAYS_QTY ") ",
limits_logins * 10, numlogindays);
return msg;
}
#ifdef ASSESS
if (badpost > (255 - limits_badpost)) {
snprintf(msg, sz_msg, "退文超過 %d 篇(目前%d篇)",
255 - limits_badpost, badpost);
return msg;
}
#endif
return NULL;
}
int pwcuSetMyAngel (const char *angel_uid)
{
PWCU_START();
strlcpy( u.myangel, angel_uid, sizeof( u.myangel));
strlcpy(cuser.myangel, angel_uid, sizeof(cuser.myangel));
syncnow();
cuser.timesetangel = u.timesetangel = now;
PWCU_END();
}
void
wait_penalty(int sec)
{
static time4_t lastWait = 0;
syncnow();
if (now - lastWait < sec)
{
sec = now - lastWait;
if (sec < 0 || sec >= 5)
sec = 5;
sleep(sec);
vkey_purge();
}
lastWait = now;
}
static int
dogetch(void)
{
ssize_t len;
static time_t lastact;
if (ibufsize <= icurrchar) {
if (flushf)
(*flushf) ();
refresh();
if (i_newfd) {
struct timeval timeout;
fd_set readfds;
if (i_top)
timeout = *i_top; /* copy it because select() might
* change it */
FD_ZERO(&readfds);
FD_SET(0, &readfds);
FD_SET(i_newfd, &readfds);
/* jochang: modify first argument of select from FD_SETSIZE */
/* since we are only waiting input from fd 0 and i_newfd(>0) */
while ((len = select(i_newfd + 1, &readfds, NULL, NULL,
i_top ? &timeout : NULL)) < 0) {
if (errno != EINTR)
abort_bbs();
/* raise(SIGHUP); */
}
if (len == 0){
syncnow();
return I_TIMEOUT;
}
if (i_newfd && FD_ISSET(i_newfd, &readfds)){
syncnow();
return I_OTHERDATA;
}
}
do {
len = tty_read(inbuf, IBUFSIZE);
/* tty_read will handle abort_bbs.
* len <= 0: read more */
#ifdef CONVERT
if(len > 0)
len = input_wrapper(inbuf, len);
#endif
#ifdef DBG_OUTRPT
// if (0)
{
static char xbuf[128];
sprintf(xbuf, ESC_STR "[s" ESC_STR "[2;1H [%ld] "
ESC_STR "[u", len);
write(1, xbuf, strlen(xbuf));
fsync(1);
}
#endif // DBG_OUTRPT
} while (len <= 0);
ibufsize = len;
icurrchar = 0;
}
// CRLF Handle:
//
// (UNIX) LF
// (WIN) CRLF
// (MAC) CR
//
// to work in a compatible way, (see KEY_ENTER definition)
// let KEY_ENTER = CR
{
unsigned char c = (unsigned char) inbuf[icurrchar++];
// CR LF are treated as one.
if (c == KEY_CR)
{
// peak next character.
if (icurrchar < ibufsize && inbuf[icurrchar] == KEY_LF)
icurrchar ++;
return KEY_ENTER;
}
else if (c == KEY_LF)
{
// XXX it is reported that still some users
// experience double ENTERs. We are not sure if there
// are still any stupid clients. But if any, you
// can reject the LFs. According the the compatibility
// test, most clients send CR only so it should be fine.
#ifdef ACCEPT_LF
return KEY_ENTER;
#else
return KEY_UNKNOWN;
#endif
}
// XXX also treat ^H and 127 (KEY_BS2) the same one?
// else if (c == KEY_BS2)
// {
// return KEY_BS;
// }
return c;
}
}
