newlib-cygwin/winsup/cygwin/select.cc

1794 lines
44 KiB
C++

/* select.cc
This file is part of Cygwin.
This software is a copyrighted work licensed under the terms of the
Cygwin license. Please consult the file "CYGWIN_LICENSE" for
details. */
/* The following line means that the BSD socket definitions for
fd_set, FD_ISSET etc. are used in this file. */
#define __INSIDE_CYGWIN_NET__
#include "winsup.h"
#include <dinput.h>
#include <stdlib.h>
#include <sys/param.h>
#include "ntdll.h"
#define USE_SYS_TYPES_FD_SET
#include <winsock2.h>
#include <netdb.h>
#include "cygerrno.h"
#include "security.h"
#include "path.h"
#include "fhandler.h"
#include "select.h"
#include "dtable.h"
#include "cygheap.h"
#include "pinfo.h"
#include "sigproc.h"
#include "cygtls.h"
/*
* All these defines below should be in sys/types.h
* but because of the includes above, they may not have
* been included. We create special UNIX_xxxx versions here.
*/
#ifndef NBBY
#define NBBY 8 /* number of bits in a byte */
#endif /* NBBY */
/*
* Select uses bit masks of file descriptors in longs.
* These macros manipulate such bit fields (the filesystem macros use chars).
* FD_SETSIZE may be defined by the user, but the default here
* should be >= NOFILE (param.h).
*/
#define UNIX_NFDBITS (sizeof (fd_mask) * NBBY) /* bits per mask */
#ifndef unix_howmany
#define unix_howmany(x,y) (((x)+((y)-1))/(y))
#endif
#define unix_fd_set fd_set
#define NULL_fd_set ((fd_set *) NULL)
#define sizeof_fd_set(n) \
((size_t) (NULL_fd_set->fds_bits + unix_howmany ((n), UNIX_NFDBITS)))
#define UNIX_FD_SET(n, p) \
((p)->fds_bits[(n)/UNIX_NFDBITS] |= (1L << ((n) % UNIX_NFDBITS)))
#define UNIX_FD_CLR(n, p) \
((p)->fds_bits[(n)/UNIX_NFDBITS] &= ~(1L << ((n) % UNIX_NFDBITS)))
#define UNIX_FD_ISSET(n, p) \
((p)->fds_bits[(n)/UNIX_NFDBITS] & (1L << ((n) % UNIX_NFDBITS)))
#define UNIX_FD_ZERO(p, n) \
memset ((caddr_t) (p), 0, sizeof_fd_set ((n)))
#define allocfd_set(n) ({\
size_t __sfds = sizeof_fd_set (n) + 8; \
void *__res = alloca (__sfds); \
memset (__res, 0, __sfds); \
(fd_set *) __res; \
})
#define set_handle_or_return_if_not_open(h, s) \
h = (s)->fh->get_io_handle_cyg (); \
if (cygheap->fdtab.not_open ((s)->fd)) \
{ \
(s)->thread_errno = EBADF; \
return -1; \
}
static int select (int, fd_set *, fd_set *, fd_set *, LONGLONG);
/* The main select code. */
extern "C" int
pselect (int maxfds, fd_set *readfds, fd_set *writefds, fd_set *exceptfds,
const struct timespec *to, const sigset_t *set)
{
sigset_t oldset = _my_tls.sigmask;
__try
{
if (set)
set_signal_mask (_my_tls.sigmask, *set);
select_printf ("pselect (%d, %p, %p, %p, %p, %p)", maxfds, readfds, writefds, exceptfds, to, set);
pthread_testcancel ();
int res;
if (maxfds < 0)
{
set_errno (EINVAL);
res = -1;
}
else
{
/* Convert to microseconds or -1 if to == NULL */
LONGLONG us = to ? to->tv_sec * 1000000LL + (to->tv_nsec + 999) / 1000 : -1LL;
if (to)
select_printf ("to->tv_sec %ld, to->tv_nsec %ld, us %D", to->tv_sec, to->tv_nsec, us);
else
select_printf ("to NULL, us %D", us);
res = select (maxfds, readfds ?: allocfd_set (maxfds),
writefds ?: allocfd_set (maxfds),
exceptfds ?: allocfd_set (maxfds), us);
}
syscall_printf ("%R = select (%d, %p, %p, %p, %p)", res, maxfds, readfds,
writefds, exceptfds, to);
if (set)
set_signal_mask (_my_tls.sigmask, oldset);
return res;
}
__except (EFAULT) {}
__endtry
return -1;
}
/* select () is just a wrapper on pselect (). */
extern "C" int
cygwin_select (int maxfds, fd_set *readfds, fd_set *writefds, fd_set *exceptfds,
struct timeval *to)
{
struct timespec ts;
if (to)
{
ts.tv_sec = to->tv_sec;
ts.tv_nsec = to->tv_usec * 1000;
}
return pselect (maxfds, readfds, writefds, exceptfds,
to ? &ts : NULL, NULL);
}
/* This function is arbitrarily split out from cygwin_select to avoid odd
gcc issues with the use of allocfd_set and improper constructor handling
for the sel variable. */
static int
select (int maxfds, fd_set *readfds, fd_set *writefds, fd_set *exceptfds,
LONGLONG us)
{
select_stuff::wait_states wait_state = select_stuff::select_set_zero;
int ret = 0;
/* Record the current time for later use. */
LONGLONG start_time = gtod.usecs ();
select_stuff sel;
sel.return_on_signal = 0;
/* Allocate some fd_set structures using the number of fds as a guide. */
fd_set *r = allocfd_set (maxfds);
fd_set *w = allocfd_set (maxfds);
fd_set *e = allocfd_set (maxfds);
do
{
/* Build the select record per fd linked list and set state as
needed. */
for (int i = 0; i < maxfds; i++)
if (!sel.test_and_set (i, readfds, writefds, exceptfds))
{
select_printf ("aborting due to test_and_set error");
return -1; /* Invalid fd, maybe? */
}
select_printf ("sel.always_ready %d", sel.always_ready);
if (sel.always_ready || us == 0)
/* Catch any active fds via sel.poll () below */
wait_state = select_stuff::select_ok;
else
/* wait for an fd to become active or time out */
wait_state = sel.wait (r, w, e, us);
select_printf ("sel.wait returns %d", wait_state);
if (wait_state == select_stuff::select_ok)
{
UNIX_FD_ZERO (readfds, maxfds);
UNIX_FD_ZERO (writefds, maxfds);
UNIX_FD_ZERO (exceptfds, maxfds);
/* Set bit mask from sel records. This also sets ret to the
right value >= 0, matching the number of bits set in the
fds records. if ret is 0, continue to loop. */
ret = sel.poll (readfds, writefds, exceptfds);
if (!ret)
wait_state = select_stuff::select_set_zero;
}
/* Always clean up everything here. If we're looping then build it
all up again. */
sel.cleanup ();
sel.destroy ();
/* Check and recalculate timeout. */
if (us != -1LL && wait_state == select_stuff::select_set_zero)
{
select_printf ("recalculating us");
LONGLONG now = gtod.usecs ();
if (now >= (start_time + us))
{
select_printf ("timed out after verification");
/* Set descriptor bits to zero per POSIX. */
UNIX_FD_ZERO (readfds, maxfds);
UNIX_FD_ZERO (writefds, maxfds);
UNIX_FD_ZERO (exceptfds, maxfds);
wait_state = select_stuff::select_ok;
ret = 0;
}
else
{
us -= (now - start_time);
start_time = now;
select_printf ("us now %D", us);
}
}
}
while (wait_state == select_stuff::select_set_zero);
if (wait_state < select_stuff::select_ok)
ret = -1;
return ret;
}
/* Call cleanup functions for all inspected fds. Gets rid of any
executing threads. */
void
select_stuff::cleanup ()
{
select_record *s = &start;
select_printf ("calling cleanup routines");
while ((s = s->next))
if (s->cleanup)
{
s->cleanup (s, this);
s->cleanup = NULL;
}
}
/* Destroy all storage associated with select stuff. */
inline void
select_stuff::destroy ()
{
select_record *s;
select_record *snext = start.next;
select_printf ("deleting select records");
while ((s = snext))
{
snext = s->next;
delete s;
}
start.next = NULL;
}
select_stuff::~select_stuff ()
{
cleanup ();
destroy ();
}
#ifdef DEBUGGING
void
select_record::dump_select_record ()
{
select_printf ("fd %d, h %p, fh %p, thread_errno %d, windows_handle %p",
fd, h, fh, thread_errno, windows_handle);
select_printf ("read_ready %d, write_ready %d, except_ready %d",
read_ready, write_ready, except_ready);
select_printf ("read_selected %d, write_selected %d, except_selected %d, except_on_write %d",
read_selected, write_selected, except_selected, except_on_write);
select_printf ("startup %p, peek %p, verify %p cleanup %p, next %p",
startup, peek, verify, cleanup, next);
}
#endif /*DEBUGGING*/
/* Add a record to the select chain */
bool
select_stuff::test_and_set (int i, fd_set *readfds, fd_set *writefds,
fd_set *exceptfds)
{
if (!UNIX_FD_ISSET (i, readfds) && !UNIX_FD_ISSET (i, writefds)
&& ! UNIX_FD_ISSET (i, exceptfds))
return true;
select_record *s = new select_record;
if (!s)
return false;
s->next = start.next;
start.next = s;
if (UNIX_FD_ISSET (i, readfds) && !cygheap->fdtab.select_read (i, this))
goto err;
if (UNIX_FD_ISSET (i, writefds) && !cygheap->fdtab.select_write (i, this))
goto err;
if (UNIX_FD_ISSET (i, exceptfds) && !cygheap->fdtab.select_except (i, this))
goto err; /* error */
if (s->read_ready || s->write_ready || s->except_ready)
always_ready = true;
if (s->windows_handle)
windows_used = true;
#ifdef DEBUGGING
s->dump_select_record ();
#endif
return true;
err:
start.next = s->next;
delete s;
return false;
}
/* The heart of select. Waits for an fd to do something interesting. */
select_stuff::wait_states
select_stuff::wait (fd_set *readfds, fd_set *writefds, fd_set *exceptfds,
LONGLONG us)
{
HANDLE w4[MAXIMUM_WAIT_OBJECTS];
select_record *s = &start;
DWORD m = 0, timer_idx = 0, cancel_idx = 0;
/* Always wait for signals. */
wait_signal_arrived here (w4[m++]);
/* Set a timeout, or not, for WMFO. */
DWORD wmfo_timeout = us ? INFINITE : 0;
/* Optionally wait for pthread cancellation. */
if ((w4[m] = pthread::get_cancel_event ()) != NULL)
cancel_idx = m++;
/* Loop through the select chain, starting up anything appropriate and
counting the number of active fds. */
DWORD startfds = m;
while ((s = s->next))
{
/* Make sure to leave space for the timer, if we have a finite timeout. */
if (m >= MAXIMUM_WAIT_OBJECTS - (us > 0LL ? 1 : 0))
{
set_sig_errno (EINVAL);
return select_error;
}
if (!s->startup (s, this))
{
s->set_select_errno ();
return select_error;
}
if (s->h != NULL)
{
for (DWORD i = startfds; i < m; i++)
if (w4[i] == s->h)
goto next_while;
w4[m++] = s->h;
}
next_while:;
}
/* Optionally create and set a waitable timer if a finite timeout has
been requested. Recycle cw_timer in the cygtls area so we only have
to create the timer once per thread. Since WFMO checks the handles
in order, we append the timer as last object, otherwise it's preferred
over actual events on the descriptors. */
HANDLE &wait_timer = _my_tls.locals.cw_timer;
if (us > 0LL)
{
NTSTATUS status;
if (!wait_timer)
{
status = NtCreateTimer (&wait_timer, TIMER_ALL_ACCESS, NULL,
NotificationTimer);
if (!NT_SUCCESS (status))
{
select_printf ("%y = NtCreateTimer ()\n", status);
return select_error;
}
}
LARGE_INTEGER ms_clock_ticks = { .QuadPart = -us * 10 };
status = NtSetTimer (wait_timer, &ms_clock_ticks, NULL, NULL, FALSE,
0, NULL);
if (!NT_SUCCESS (status))
{
select_printf ("%y = NtSetTimer (%D)\n",
status, ms_clock_ticks.QuadPart);
return select_error;
}
w4[m] = wait_timer;
timer_idx = m++;
}
debug_printf ("m %d, us %U, wmfo_timeout %d", m, us, wmfo_timeout);
DWORD wait_ret;
if (!windows_used)
wait_ret = WaitForMultipleObjects (m, w4, FALSE, wmfo_timeout);
else
/* Using MWMO_INPUTAVAILABLE is the officially supported solution for
the problem that the call to PeekMessage disarms the queue state
so that a subsequent MWFMO hangs, even if there are still messages
in the queue. */
wait_ret = MsgWaitForMultipleObjectsEx (m, w4, wmfo_timeout,
QS_ALLINPUT | QS_ALLPOSTMESSAGE,
MWMO_INPUTAVAILABLE);
select_printf ("wait_ret %d, m = %d. verifying", wait_ret, m);
if (timer_idx)
{
BOOLEAN current_state;
NtCancelTimer (wait_timer, &current_state);
}
wait_states res;
switch (wait_ret)
{
case WAIT_OBJECT_0:
select_printf ("signal received");
/* Need to get rid of everything when a signal occurs since we can't
be assured that a signal handler won't jump out of select entirely. */
cleanup ();
destroy ();
/* select() is always interrupted by a signal so set EINTR,
unconditionally, ignoring any SA_RESTART detection by
call_signal_handler(). */
_my_tls.call_signal_handler ();
set_sig_errno (EINTR);
res = select_signalled; /* Cause loop exit in cygwin_select */
break;
case WAIT_FAILED:
system_printf ("WaitForMultipleObjects failed, %E");
s = &start;
s->set_select_errno ();
res = select_error;
break;
case WAIT_TIMEOUT:
was_timeout:
select_printf ("timed out");
res = select_set_zero;
break;
case WAIT_OBJECT_0 + 1:
/* Cancel event? */
if (wait_ret == cancel_idx)
{
cleanup ();
destroy ();
pthread::static_cancel_self ();
/*NOTREACHED*/
}
/*FALLTHRU*/
default:
/* Timer event? */
if (wait_ret == timer_idx)
goto was_timeout;
s = &start;
res = select_set_zero;
/* Some types of objects (e.g., consoles) wake up on "inappropriate"
events like mouse movements. The verify function will detect these
situations. If it returns false, then this wakeup was a false alarm
and we should go back to waiting. */
while ((s = s->next))
if (s->saw_error ())
{
set_errno (s->saw_error ());
res = select_error; /* Somebody detected an error */
goto out;
}
else if ((((wait_ret >= m && s->windows_handle)
|| s->h == w4[wait_ret]))
&& s->verify (s, readfds, writefds, exceptfds))
res = select_ok;
select_printf ("res after verify %d", res);
break;
}
out:
select_printf ("returning %d", res);
return res;
}
static int
set_bits (select_record *me, fd_set *readfds, fd_set *writefds,
fd_set *exceptfds)
{
int ready = 0;
fhandler_socket *sock;
select_printf ("me %p, testing fd %d (%s)", me, me->fd, me->fh->get_name ());
if (me->read_selected && me->read_ready)
{
UNIX_FD_SET (me->fd, readfds);
ready++;
}
if (me->write_selected && me->write_ready)
{
UNIX_FD_SET (me->fd, writefds);
if (me->except_on_write && (sock = me->fh->is_socket ()))
{
/* Set readfds entry in case of a failed connect. */
if (!me->read_ready && me->read_selected
&& sock->connect_state () == connect_failed)
UNIX_FD_SET (me->fd, readfds);
}
ready++;
}
if (me->except_selected && me->except_ready)
{
UNIX_FD_SET (me->fd, exceptfds);
ready++;
}
select_printf ("ready %d", ready);
return ready;
}
/* Poll every fd in the select chain. Set appropriate fd in mask. */
int
select_stuff::poll (fd_set *readfds, fd_set *writefds, fd_set *exceptfds)
{
int n = 0;
select_record *s = &start;
while ((s = s->next))
n += (!s->peek || s->peek (s, true)) ?
set_bits (s, readfds, writefds, exceptfds) : 0;
return n;
}
static int
verify_true (select_record *, fd_set *, fd_set *, fd_set *)
{
return 1;
}
static int
verify_ok (select_record *me, fd_set *readfds, fd_set *writefds,
fd_set *exceptfds)
{
return set_bits (me, readfds, writefds, exceptfds);
}
static int
no_startup (select_record *, select_stuff *)
{
return 1;
}
static int
no_verify (select_record *, fd_set *, fd_set *, fd_set *)
{
return 0;
}
static int
pipe_data_available (int fd, fhandler_base *fh, HANDLE h, bool writing)
{
IO_STATUS_BLOCK iosb = {{0}, 0};
FILE_PIPE_LOCAL_INFORMATION fpli = {0};
bool res;
if (fh->has_ongoing_io ())
res = false;
else if (NtQueryInformationFile (h, &iosb, &fpli, sizeof (fpli),
FilePipeLocalInformation))
{
/* If NtQueryInformationFile fails, optimistically assume the
pipe is writable. This could happen if we somehow
inherit a pipe that doesn't permit FILE_READ_ATTRIBUTES
access on the write end. */
select_printf ("fd %d, %s, NtQueryInformationFile failed",
fd, fh->get_name ());
res = writing ? true : -1;
}
else if (!writing)
{
paranoid_printf ("fd %d, %s, read avail %u", fd, fh->get_name (),
fpli.ReadDataAvailable);
res = !!fpli.ReadDataAvailable;
}
else if ((res = (fpli.WriteQuotaAvailable = (fpli.OutboundQuota -
fpli.ReadDataAvailable))))
/* If there is anything available in the pipe buffer then signal
that. This means that a pipe could still block since you could
be trying to write more to the pipe than is available in the
buffer but that is the hazard of select(). */
paranoid_printf ("fd %d, %s, write: size %u, avail %u", fd,
fh->get_name (), fpli.OutboundQuota,
fpli.WriteQuotaAvailable);
else if ((res = (fpli.OutboundQuota < PIPE_BUF &&
fpli.WriteQuotaAvailable == fpli.OutboundQuota)))
/* If we somehow inherit a tiny pipe (size < PIPE_BUF), then consider
the pipe writable only if it is completely empty, to minimize the
probability that a subsequent write will block. */
select_printf ("fd, %s, write tiny pipe: size %u, avail %u",
fd, fh->get_name (), fpli.OutboundQuota,
fpli.WriteQuotaAvailable);
return res ?: -!!(fpli.NamedPipeState & FILE_PIPE_CLOSING_STATE);
}
static int
peek_pipe (select_record *s, bool from_select)
{
HANDLE h;
set_handle_or_return_if_not_open (h, s);
int gotone = 0;
fhandler_base *fh = (fhandler_base *) s->fh;
DWORD dev = fh->get_device ();
if (s->read_selected && dev != FH_PIPEW)
{
if (s->read_ready)
{
select_printf ("%s, already ready for read", fh->get_name ());
gotone = 1;
goto out;
}
switch (fh->get_major ())
{
case DEV_PTYM_MAJOR:
{
fhandler_pty_master *fhm = (fhandler_pty_master *) fh;
fhm->flush_to_slave ();
}
break;
default:
if (fh->get_readahead_valid ())
{
select_printf ("readahead");
gotone = s->read_ready = true;
goto out;
}
}
if (fh->bg_check (SIGTTIN, true) <= bg_eof)
{
gotone = s->read_ready = true;
goto out;
}
int n = pipe_data_available (s->fd, fh, h, false);
/* On PTY masters, check if input from the echo pipe is available. */
if (n == 0 && fh->get_echo_handle ())
n = pipe_data_available (s->fd, fh, fh->get_echo_handle (), false);
if (n < 0)
{
select_printf ("read: %s, n %d", fh->get_name (), n);
if (s->except_selected)
gotone += s->except_ready = true;
if (s->read_selected)
gotone += s->read_ready = true;
}
else if (n > 0)
{
select_printf ("read: %s, ready for read: avail %d", fh->get_name (), n);
gotone += s->read_ready = true;
}
if (!gotone && s->fh->hit_eof ())
{
select_printf ("read: %s, saw EOF", fh->get_name ());
if (s->except_selected)
gotone += s->except_ready = true;
if (s->read_selected)
gotone += s->read_ready = true;
}
}
out:
if (s->write_selected && dev != FH_PIPER)
{
gotone += s->write_ready = pipe_data_available (s->fd, fh, h, true);
select_printf ("write: %s, gotone %d", fh->get_name (), gotone);
}
return gotone;
}
static int start_thread_pipe (select_record *me, select_stuff *stuff);
static DWORD WINAPI
thread_pipe (void *arg)
{
select_pipe_info *pi = (select_pipe_info *) arg;
DWORD sleep_time = 0;
bool looping = true;
while (looping)
{
for (select_record *s = pi->start; (s = s->next); )
if (s->startup == start_thread_pipe)
{
if (peek_pipe (s, true))
looping = false;
if (pi->stop_thread)
{
select_printf ("stopping");
looping = false;
break;
}
}
if (!looping)
break;
Sleep (sleep_time >> 3);
if (sleep_time < 80)
++sleep_time;
if (pi->stop_thread)
break;
}
return 0;
}
static int
start_thread_pipe (select_record *me, select_stuff *stuff)
{
select_pipe_info *pi = stuff->device_specific_pipe;
if (pi->start)
me->h = *((select_pipe_info *) stuff->device_specific_pipe)->thread;
else
{
pi->start = &stuff->start;
pi->stop_thread = false;
pi->thread = new cygthread (thread_pipe, pi, "pipesel");
me->h = *pi->thread;
if (!me->h)
return 0;
}
return 1;
}
static void
pipe_cleanup (select_record *, select_stuff *stuff)
{
select_pipe_info *pi = (select_pipe_info *) stuff->device_specific_pipe;
if (!pi)
return;
if (pi->thread)
{
pi->stop_thread = true;
pi->thread->detach ();
}
delete pi;
stuff->device_specific_pipe = NULL;
}
select_record *
fhandler_pipe::select_read (select_stuff *ss)
{
if (!ss->device_specific_pipe
&& (ss->device_specific_pipe = new select_pipe_info) == NULL)
return NULL;
select_record *s = ss->start.next;
s->startup = start_thread_pipe;
s->peek = peek_pipe;
s->verify = verify_ok;
s->cleanup = pipe_cleanup;
s->read_selected = true;
s->read_ready = false;
return s;
}
select_record *
fhandler_pipe::select_write (select_stuff *ss)
{
if (!ss->device_specific_pipe
&& (ss->device_specific_pipe = new select_pipe_info) == NULL)
return NULL;
select_record *s = ss->start.next;
s->startup = start_thread_pipe;
s->peek = peek_pipe;
s->verify = verify_ok;
s->cleanup = pipe_cleanup;
s->write_selected = true;
s->write_ready = false;
return s;
}
select_record *
fhandler_pipe::select_except (select_stuff *ss)
{
if (!ss->device_specific_pipe
&& (ss->device_specific_pipe = new select_pipe_info) == NULL)
return NULL;
select_record *s = ss->start.next;
s->startup = start_thread_pipe;
s->peek = peek_pipe;
s->verify = verify_ok;
s->cleanup = pipe_cleanup;
s->except_selected = true;
s->except_ready = false;
return s;
}
select_record *
fhandler_fifo::select_read (select_stuff *ss)
{
if (!ss->device_specific_pipe
&& (ss->device_specific_pipe = new select_pipe_info) == NULL)
return NULL;
select_record *s = ss->start.next;
s->startup = start_thread_pipe;
s->peek = peek_pipe;
s->verify = verify_ok;
s->cleanup = pipe_cleanup;
s->read_selected = true;
s->read_ready = false;
return s;
}
select_record *
fhandler_fifo::select_write (select_stuff *ss)
{
if (!ss->device_specific_pipe
&& (ss->device_specific_pipe = new select_pipe_info) == NULL)
return NULL;
select_record *s = ss->start.next;
s->startup = start_thread_pipe;
s->peek = peek_pipe;
s->verify = verify_ok;
s->cleanup = pipe_cleanup;
s->write_selected = true;
s->write_ready = false;
return s;
}
select_record *
fhandler_fifo::select_except (select_stuff *ss)
{
if (!ss->device_specific_pipe
&& (ss->device_specific_pipe = new select_pipe_info) == NULL)
return NULL;
select_record *s = ss->start.next;
s->startup = start_thread_pipe;
s->peek = peek_pipe;
s->verify = verify_ok;
s->cleanup = pipe_cleanup;
s->except_selected = true;
s->except_ready = false;
return s;
}
static int
peek_console (select_record *me, bool)
{
fhandler_console *fh = (fhandler_console *) me->fh;
if (!me->read_selected)
return me->write_ready;
if (fh->get_cons_readahead_valid ())
{
select_printf ("cons_readahead");
return me->read_ready = true;
}
if (fh->get_readahead_valid ())
{
select_printf ("readahead");
return me->read_ready = true;
}
if (me->read_ready)
{
select_printf ("already ready");
return 1;
}
INPUT_RECORD irec;
DWORD events_read;
HANDLE h;
char tmpbuf[17];
set_handle_or_return_if_not_open (h, me);
for (;;)
if (fh->bg_check (SIGTTIN, true) <= bg_eof)
return me->read_ready = true;
else if (!PeekConsoleInput (h, &irec, 1, &events_read) || !events_read)
break;
else
{
fh->send_winch_maybe ();
if (irec.EventType == KEY_EVENT)
{
if (irec.Event.KeyEvent.bKeyDown)
{
/* Ignore Alt+Numpad keys. These are used to enter codepoints
not available in the current keyboard layout. They are
eventually handled in the key-up case below. For details see
http://www.fileformat.info/tip/microsoft/enter_unicode.htm */
if (irec.Event.KeyEvent.uChar.UnicodeChar == 0
&& irec.Event.KeyEvent.dwControlKeyState == LEFT_ALT_PRESSED
&& irec.Event.KeyEvent.wVirtualScanCode >= DIK_NUMPAD7
&& irec.Event.KeyEvent.wVirtualScanCode <= DIK_NUMPAD0
&& irec.Event.KeyEvent.wVirtualScanCode != DIK_SUBTRACT)
;
/* Handle normal input. */
else if (irec.Event.KeyEvent.uChar.UnicodeChar
|| fhandler_console::get_nonascii_key (irec, tmpbuf))
return me->read_ready = true;
}
/* Ignore key up events, except for left alt events with
non-zero character */
else if (irec.Event.KeyEvent.uChar.UnicodeChar != 0
&& irec.Event.KeyEvent.wVirtualKeyCode == VK_MENU
&& irec.Event.KeyEvent.wVirtualScanCode == 0x38)
return me->read_ready = true;
}
else
{
if (irec.EventType == MOUSE_EVENT
&& fh->mouse_aware (irec.Event.MouseEvent))
return me->read_ready = true;
if (irec.EventType == FOCUS_EVENT && fh->focus_aware ())
return me->read_ready = true;
}
/* Read and discard the event */
ReadConsoleInput (h, &irec, 1, &events_read);
}
return me->write_ready;
}
static int
verify_console (select_record *me, fd_set *rfds, fd_set *wfds,
fd_set *efds)
{
return peek_console (me, true);
}
select_record *
fhandler_console::select_read (select_stuff *ss)
{
select_record *s = ss->start.next;
if (!s->startup)
{
s->startup = no_startup;
s->verify = verify_console;
set_cursor_maybe ();
}
s->peek = peek_console;
s->h = get_handle ();
s->read_selected = true;
s->read_ready = get_readahead_valid ();
return s;
}
select_record *
fhandler_console::select_write (select_stuff *ss)
{
select_record *s = ss->start.next;
if (!s->startup)
{
s->startup = no_startup;
s->verify = no_verify;
set_cursor_maybe ();
}
s->peek = peek_console;
s->write_selected = true;
s->write_ready = true;
return s;
}
select_record *
fhandler_console::select_except (select_stuff *ss)
{
select_record *s = ss->start.next;
if (!s->startup)
{
s->startup = no_startup;
s->verify = no_verify;
set_cursor_maybe ();
}
s->peek = peek_console;
s->except_selected = true;
s->except_ready = false;
return s;
}
select_record *
fhandler_pty_common::select_read (select_stuff *ss)
{
if (!ss->device_specific_pipe
&& (ss->device_specific_pipe = new select_pipe_info) == NULL)
return NULL;
select_record *s = ss->start.next;
s->startup = start_thread_pipe;
s->peek = peek_pipe;
s->verify = verify_ok;
s->cleanup = pipe_cleanup;
s->read_selected = true;
s->read_ready = false;
return s;
}
select_record *
fhandler_pty_common::select_write (select_stuff *ss)
{
if (!ss->device_specific_pipe
&& (ss->device_specific_pipe = new select_pipe_info) == NULL)
return NULL;
select_record *s = ss->start.next;
s->startup = start_thread_pipe;
s->peek = peek_pipe;
s->verify = verify_ok;
s->cleanup = pipe_cleanup;
s->write_selected = true;
s->write_ready = false;
return s;
}
select_record *
fhandler_pty_common::select_except (select_stuff *ss)
{
if (!ss->device_specific_pipe
&& (ss->device_specific_pipe = new select_pipe_info) == NULL)
return NULL;
select_record *s = ss->start.next;
s->startup = start_thread_pipe;
s->peek = peek_pipe;
s->verify = verify_ok;
s->cleanup = pipe_cleanup;
s->except_selected = true;
s->except_ready = false;
return s;
}
static int
verify_tty_slave (select_record *me, fd_set *readfds, fd_set *writefds,
fd_set *exceptfds)
{
if (IsEventSignalled (me->h))
me->read_ready = true;
return set_bits (me, readfds, writefds, exceptfds);
}
select_record *
fhandler_pty_slave::select_read (select_stuff *ss)
{
select_record *s = ss->start.next;
s->h = input_available_event;
s->startup = no_startup;
s->peek = peek_pipe;
s->verify = verify_tty_slave;
s->read_selected = true;
s->read_ready = false;
s->cleanup = NULL;
return s;
}
select_record *
fhandler_dev_null::select_read (select_stuff *ss)
{
select_record *s = ss->start.next;
if (!s->startup)
{
s->startup = no_startup;
s->verify = no_verify;
}
s->h = get_handle ();
s->read_selected = true;
s->read_ready = true;
return s;
}
select_record *
fhandler_dev_null::select_write (select_stuff *ss)
{
select_record *s = ss->start.next;
if (!s->startup)
{
s->startup = no_startup;
s->verify = no_verify;
}
s->h = get_handle ();
s->write_selected = true;
s->write_ready = true;
return s;
}
select_record *
fhandler_dev_null::select_except (select_stuff *ss)
{
select_record *s = ss->start.next;
if (!s->startup)
{
s->startup = no_startup;
s->verify = no_verify;
}
s->h = get_handle ();
s->except_selected = true;
s->except_ready = false;
return s;
}
static int start_thread_serial (select_record *me, select_stuff *stuff);
static int
peek_serial (select_record *s, bool)
{
COMSTAT st;
fhandler_serial *fh = (fhandler_serial *) s->fh;
if (fh->get_readahead_valid () || fh->overlapped_armed < 0)
return s->read_ready = true;
select_printf ("fh->overlapped_armed %d", fh->overlapped_armed);
HANDLE h;
set_handle_or_return_if_not_open (h, s);
int ready = 0;
if ((s->read_selected && s->read_ready) || (s->write_selected && s->write_ready))
{
select_printf ("already ready");
ready = 1;
goto out;
}
/* This is apparently necessary for the com0com driver.
See: http://cygwin.com/ml/cygwin/2009-01/msg00667.html */
SetCommMask (h, 0);
SetCommMask (h, EV_RXCHAR);
if (!fh->overlapped_armed)
{
COMSTAT st;
ResetEvent (fh->io_status.hEvent);
if (!ClearCommError (h, &fh->ev, &st))
{
debug_printf ("ClearCommError");
goto err;
}
else if (st.cbInQue)
return s->read_ready = true;
else if (WaitCommEvent (h, &fh->ev, &fh->io_status))
return s->read_ready = true;
else if (GetLastError () == ERROR_IO_PENDING)
fh->overlapped_armed = 1;
else
{
debug_printf ("WaitCommEvent");
goto err;
}
}
switch (WaitForSingleObject (fh->io_status.hEvent, 10L))
{
case WAIT_OBJECT_0:
if (!ClearCommError (h, &fh->ev, &st))
{
debug_printf ("ClearCommError");
goto err;
}
else if (!st.cbInQue)
Sleep (10L);
else
{
return s->read_ready = true;
select_printf ("got something");
}
break;
case WAIT_TIMEOUT:
break;
default:
debug_printf ("WaitForMultipleObjects");
goto err;
}
out:
return ready;
err:
if (GetLastError () == ERROR_OPERATION_ABORTED)
{
select_printf ("operation aborted");
return ready;
}
s->set_select_errno ();
select_printf ("error %E");
return -1;
}
static DWORD WINAPI
thread_serial (void *arg)
{
select_serial_info *si = (select_serial_info *) arg;
bool looping = true;
while (looping)
for (select_record *s = si->start; (s = s->next); )
if (s->startup != start_thread_serial)
continue;
else
{
if (peek_serial (s, true))
looping = false;
if (si->stop_thread)
{
select_printf ("stopping");
looping = false;
break;
}
}
select_printf ("exiting");
return 0;
}
static int
start_thread_serial (select_record *me, select_stuff *stuff)
{
if (stuff->device_specific_serial)
me->h = *((select_serial_info *) stuff->device_specific_serial)->thread;
else
{
select_serial_info *si = new select_serial_info;
si->start = &stuff->start;
si->stop_thread = false;
si->thread = new cygthread (thread_serial, si, "sersel");
me->h = *si->thread;
stuff->device_specific_serial = si;
}
return 1;
}
static void
serial_cleanup (select_record *, select_stuff *stuff)
{
select_serial_info *si = (select_serial_info *) stuff->device_specific_serial;
if (!si)
return;
if (si->thread)
{
si->stop_thread = true;
si->thread->detach ();
}
delete si;
stuff->device_specific_serial = NULL;
}
select_record *
fhandler_serial::select_read (select_stuff *ss)
{
select_record *s = ss->start.next;
if (!s->startup)
{
s->startup = start_thread_serial;
s->verify = verify_ok;
s->cleanup = serial_cleanup;
}
s->peek = peek_serial;
s->read_selected = true;
s->read_ready = false;
return s;
}
select_record *
fhandler_serial::select_write (select_stuff *ss)
{
select_record *s = ss->start.next;
if (!s->startup)
{
s->startup = no_startup;
s->verify = verify_ok;
}
s->peek = peek_serial;
s->h = get_handle ();
s->write_selected = true;
s->write_ready = true;
return s;
}
select_record *
fhandler_serial::select_except (select_stuff *ss)
{
select_record *s = ss->start.next;
if (!s->startup)
{
s->startup = no_startup;
s->verify = verify_ok;
}
s->h = NULL;
s->peek = peek_serial;
s->except_selected = false; // Can't do this
s->except_ready = false;
return s;
}
select_record *
fhandler_base::select_read (select_stuff *ss)
{
select_record *s = ss->start.next;
if (!s->startup)
{
s->startup = no_startup;
s->verify = verify_ok;
}
s->h = get_io_handle_cyg ();
s->read_selected = true;
s->read_ready = true;
return s;
}
select_record *
fhandler_base::select_write (select_stuff *ss)
{
select_record *s = ss->start.next;
if (!s->startup)
{
s->startup = no_startup;
s->verify = verify_ok;
}
s->h = get_handle ();
s->write_selected = true;
s->write_ready = true;
return s;
}
select_record *
fhandler_base::select_except (select_stuff *ss)
{
select_record *s = ss->start.next;
if (!s->startup)
{
s->startup = no_startup;
s->verify = verify_ok;
}
s->h = NULL;
s->except_selected = true;
s->except_ready = false;
return s;
}
static int
peek_socket (select_record *me, bool)
{
fhandler_socket *fh = (fhandler_socket *) me->fh;
long events;
/* Don't play with the settings again, unless having taken a deep look into
Richard W. Stevens Network Programming book. Thank you. */
long evt_mask = (me->read_selected ? (FD_READ | FD_ACCEPT | FD_CLOSE) : 0)
| (me->write_selected ? (FD_WRITE | FD_CONNECT | FD_CLOSE) : 0)
| (me->except_selected ? FD_OOB : 0);
int ret = fh->evaluate_events (evt_mask, events, false);
if (me->read_selected)
me->read_ready |= ret || !!(events & (FD_READ | FD_ACCEPT | FD_CLOSE));
if (me->write_selected)
me->write_ready |= ret || !!(events & (FD_WRITE | FD_CONNECT | FD_CLOSE));
if (me->except_selected)
me->except_ready |= !!(events & FD_OOB);
select_printf ("read_ready: %d, write_ready: %d, except_ready: %d",
me->read_ready, me->write_ready, me->except_ready);
return me->read_ready || me->write_ready || me->except_ready;
}
static int start_thread_socket (select_record *, select_stuff *);
static DWORD WINAPI
thread_socket (void *arg)
{
select_socket_info *si = (select_socket_info *) arg;
DWORD timeout = (si->num_w4 <= MAXIMUM_WAIT_OBJECTS)
? INFINITE
: (64 / (roundup2 (si->num_w4, MAXIMUM_WAIT_OBJECTS)
/ MAXIMUM_WAIT_OBJECTS));
bool event = false;
select_printf ("stuff_start %p, timeout %u", si->start, timeout);
while (!event)
{
for (select_record *s = si->start; (s = s->next); )
if (s->startup == start_thread_socket)
if (peek_socket (s, false))
event = true;
if (!event)
for (int i = 0; i < si->num_w4; i += MAXIMUM_WAIT_OBJECTS)
switch (WaitForMultipleObjects (MIN (si->num_w4 - i,
MAXIMUM_WAIT_OBJECTS),
si->w4 + i, FALSE, timeout))
{
case WAIT_FAILED:
goto out;
case WAIT_TIMEOUT:
continue;
case WAIT_OBJECT_0:
if (!i) /* Socket event set. */
goto out;
/*FALLTHRU*/
default:
break;
}
}
out:
select_printf ("leaving thread_socket");
return 0;
}
static inline bool init_tls_select_info () __attribute__ ((always_inline));
static inline bool
init_tls_select_info ()
{
if (!_my_tls.locals.select.sockevt)
{
_my_tls.locals.select.sockevt = CreateEvent (&sec_none_nih, TRUE, FALSE,
NULL);
if (!_my_tls.locals.select.sockevt)
return false;
}
if (!_my_tls.locals.select.ser_num)
{
_my_tls.locals.select.ser_num
= (LONG *) malloc (MAXIMUM_WAIT_OBJECTS * sizeof (LONG));
if (!_my_tls.locals.select.ser_num)
return false;
_my_tls.locals.select.w4
= (HANDLE *) malloc (MAXIMUM_WAIT_OBJECTS * sizeof (HANDLE));
if (!_my_tls.locals.select.w4)
{
free (_my_tls.locals.select.ser_num);
_my_tls.locals.select.ser_num = NULL;
return false;
}
_my_tls.locals.select.max_w4 = MAXIMUM_WAIT_OBJECTS;
}
return true;
}
static int
start_thread_socket (select_record *me, select_stuff *stuff)
{
select_socket_info *si;
if ((si = (select_socket_info *) stuff->device_specific_socket))
{
me->h = *si->thread;
return 1;
}
si = new select_socket_info;
if (!init_tls_select_info ())
{
delete si;
return 0;
}
si->ser_num = _my_tls.locals.select.ser_num;
si->w4 = _my_tls.locals.select.w4;
si->w4[0] = _my_tls.locals.select.sockevt;
si->num_w4 = 1;
select_record *s = &stuff->start;
while ((s = s->next))
if (s->startup == start_thread_socket)
{
/* No event/socket should show up multiple times. Every socket
is uniquely identified by its serial number in the global
wsock_events record. */
const LONG ser_num = ((fhandler_socket *) s->fh)->serial_number ();
for (int i = 1; i < si->num_w4; ++i)
if (si->ser_num[i] == ser_num)
goto continue_outer_loop;
if (si->num_w4 >= _my_tls.locals.select.max_w4)
{
LONG *nser = (LONG *) realloc (si->ser_num,
(_my_tls.locals.select.max_w4
+ MAXIMUM_WAIT_OBJECTS)
* sizeof (LONG));
if (!nser)
{
delete si;
return 0;
}
_my_tls.locals.select.ser_num = si->ser_num = nser;
HANDLE *nw4 = (HANDLE *) realloc (si->w4,
(_my_tls.locals.select.max_w4
+ MAXIMUM_WAIT_OBJECTS)
* sizeof (HANDLE));
if (!nw4)
{
delete si;
return 0;
}
_my_tls.locals.select.w4 = si->w4 = nw4;
_my_tls.locals.select.max_w4 += MAXIMUM_WAIT_OBJECTS;
}
si->ser_num[si->num_w4] = ser_num;
si->w4[si->num_w4++] = ((fhandler_socket *) s->fh)->wsock_event ();
continue_outer_loop:
;
}
stuff->device_specific_socket = si;
si->start = &stuff->start;
select_printf ("stuff_start %p", &stuff->start);
si->thread = new cygthread (thread_socket, si, "socksel");
me->h = *si->thread;
return 1;
}
void
socket_cleanup (select_record *, select_stuff *stuff)
{
select_socket_info *si = (select_socket_info *) stuff->device_specific_socket;
select_printf ("si %p si->thread %p", si, si ? si->thread : NULL);
if (!si)
return;
if (si->thread)
{
SetEvent (si->w4[0]);
/* Wait for thread to go away */
si->thread->detach ();
ResetEvent (si->w4[0]);
}
delete si;
stuff->device_specific_socket = NULL;
select_printf ("returning");
}
select_record *
fhandler_socket::select_read (select_stuff *ss)
{
select_record *s = ss->start.next;
if (!s->startup)
{
s->startup = start_thread_socket;
s->verify = verify_true;
s->cleanup = socket_cleanup;
}
s->peek = peek_socket;
s->read_ready = saw_shutdown_read ();
s->read_selected = true;
return s;
}
select_record *
fhandler_socket::select_write (select_stuff *ss)
{
select_record *s = ss->start.next;
if (!s->startup)
{
s->startup = start_thread_socket;
s->verify = verify_true;
s->cleanup = socket_cleanup;
}
s->peek = peek_socket;
s->write_ready = saw_shutdown_write () || connect_state () == unconnected;
s->write_selected = true;
if (connect_state () != unconnected)
{
s->except_ready = saw_shutdown_write () || saw_shutdown_read ();
s->except_on_write = true;
}
return s;
}
select_record *
fhandler_socket::select_except (select_stuff *ss)
{
select_record *s = ss->start.next;
if (!s->startup)
{
s->startup = start_thread_socket;
s->verify = verify_true;
s->cleanup = socket_cleanup;
}
s->peek = peek_socket;
/* FIXME: Is this right? Should these be used as criteria for except? */
s->except_ready = saw_shutdown_write () || saw_shutdown_read ();
s->except_selected = true;
return s;
}
static int
peek_windows (select_record *me, bool)
{
MSG m;
HANDLE h;
set_handle_or_return_if_not_open (h, me);
/* We need the hWnd value, not the io_handle. */
h = ((fhandler_windows *) me->fh)->get_hwnd ();
if (me->read_selected && me->read_ready)
return 1;
if (PeekMessageW (&m, (HWND) h, 0, 0, PM_NOREMOVE))
{
me->read_ready = true;
select_printf ("window %d(%p) ready", me->fd, h);
return 1;
}
select_printf ("window %d(%p) not ready", me->fd, h);
return me->write_ready;
}
static int
verify_windows (select_record *me, fd_set *rfds, fd_set *wfds,
fd_set *efds)
{
return peek_windows (me, true);
}
select_record *
fhandler_windows::select_read (select_stuff *ss)
{
select_record *s = ss->start.next;
if (!s->startup)
{
s->startup = no_startup;
}
s->verify = verify_windows;
s->peek = peek_windows;
s->read_selected = true;
s->read_ready = false;
s->windows_handle = true;
return s;
}
select_record *
fhandler_windows::select_write (select_stuff *ss)
{
select_record *s = ss->start.next;
if (!s->startup)
{
s->startup = no_startup;
s->verify = verify_ok;
}
s->peek = peek_windows;
s->write_selected = true;
s->write_ready = true;
s->windows_handle = true;
return s;
}
select_record *
fhandler_windows::select_except (select_stuff *ss)
{
select_record *s = ss->start.next;
if (!s->startup)
{
s->startup = no_startup;
s->verify = verify_ok;
}
s->peek = peek_windows;
s->except_selected = true;
s->except_ready = false;
s->windows_handle = true;
return s;
}
static int
peek_mailslot (select_record *me, bool)
{
HANDLE h;
set_handle_or_return_if_not_open (h, me);
if (me->read_selected && me->read_ready)
return 1;
DWORD msgcnt = 0;
if (!GetMailslotInfo (h, NULL, NULL, &msgcnt, NULL))
{
me->except_ready = true;
select_printf ("mailslot %d(%p) error %E", me->fd, h);
return 1;
}
if (msgcnt > 0)
{
me->read_ready = true;
select_printf ("mailslot %d(%p) ready", me->fd, h);
return 1;
}
select_printf ("mailslot %d(%p) not ready", me->fd, h);
return 0;
}
static int
verify_mailslot (select_record *me, fd_set *rfds, fd_set *wfds,
fd_set *efds)
{
return peek_mailslot (me, true);
}
static int start_thread_mailslot (select_record *me, select_stuff *stuff);
static DWORD WINAPI
thread_mailslot (void *arg)
{
select_mailslot_info *mi = (select_mailslot_info *) arg;
bool gotone = false;
DWORD sleep_time = 0;
for (;;)
{
select_record *s = mi->start;
while ((s = s->next))
if (s->startup == start_thread_mailslot)
{
if (peek_mailslot (s, true))
gotone = true;
if (mi->stop_thread)
{
select_printf ("stopping");
goto out;
}
}
/* Paranoid check */
if (mi->stop_thread)
{
select_printf ("stopping from outer loop");
break;
}
if (gotone)
break;
Sleep (sleep_time >> 3);
if (sleep_time < 80)
++sleep_time;
}
out:
return 0;
}
static int
start_thread_mailslot (select_record *me, select_stuff *stuff)
{
if (stuff->device_specific_mailslot)
{
me->h = *((select_mailslot_info *) stuff->device_specific_mailslot)->thread;
return 1;
}
select_mailslot_info *mi = new select_mailslot_info;
mi->start = &stuff->start;
mi->stop_thread = false;
mi->thread = new cygthread (thread_mailslot, mi, "mailsel");
me->h = *mi->thread;
if (!me->h)
return 0;
stuff->device_specific_mailslot = mi;
return 1;
}
static void
mailslot_cleanup (select_record *, select_stuff *stuff)
{
select_mailslot_info *mi = (select_mailslot_info *) stuff->device_specific_mailslot;
if (!mi)
return;
if (mi->thread)
{
mi->stop_thread = true;
mi->thread->detach ();
}
delete mi;
stuff->device_specific_mailslot = NULL;
}
select_record *
fhandler_mailslot::select_read (select_stuff *ss)
{
select_record *s = ss->start.next;
s->startup = start_thread_mailslot;
s->peek = peek_mailslot;
s->verify = verify_mailslot;
s->cleanup = mailslot_cleanup;
s->read_selected = true;
s->read_ready = false;
return s;
}