newlib-cygwin/winsup/cygwin/sigproc.cc

1295 lines
33 KiB
C++

/* sigproc.cc: inter/intra signal and sub process handler
Copyright 1997, 1998, 1999, 2000, 2001, 2002, 2003, 2004, 2005,
2006, 2007, 2008 Red Hat, Inc.
Written by Christopher Faylor
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. */
#include "winsup.h"
#include "miscfuncs.h"
#include <stdlib.h>
#include <sys/cygwin.h>
#include "cygerrno.h"
#include "pinfo.h"
#include "path.h"
#include "fhandler.h"
#include "dtable.h"
#include "cygheap.h"
#include "child_info_magic.h"
#include "shared_info.h"
#include "cygtls.h"
#include "sigproc.h"
#include "ntdll.h"
/*
* Convenience defines
*/
#define WSSC 60000 // Wait for signal completion
#define WPSP 40000 // Wait for proc_subproc mutex
#define no_signals_available(x) (!hwait_sig || hwait_sig == INVALID_HANDLE_VALUE || ((x) && myself->exitcode & EXITCODE_SET) || &_my_tls == _sig_tls)
#define NPROCS 256
/*
* Global variables
*/
struct sigaction *global_sigs;
const char *__sp_fn ;
int __sp_ln;
char NO_COPY myself_nowait_dummy[1] = {'0'};// Flag to sig_send that signal goes to
// current process but no wait is required
HANDLE NO_COPY signal_arrived; // Event signaled when a signal has
// resulted in a user-specified
// function call
#define Static static NO_COPY
HANDLE NO_COPY sigCONT; // Used to "STOP" a process
cygthread NO_COPY *hwait_sig;
Static HANDLE wait_sig_inited; // Control synchronization of
// message queue startup
Static bool sigheld; // True if holding signals
Static int nprocs; // Number of deceased children
Static char cprocs[(NPROCS + 1) * sizeof (pinfo)];// All my children info
#define procs ((pinfo *) cprocs) // All this just to avoid expensive
// constructor operation at DLL startup
Static waitq waitq_head; // Start of queue for wait'ing threads
Static muto sync_proc_subproc; // Control access to subproc stuff
_cygtls NO_COPY *_sig_tls;
Static HANDLE my_sendsig;
Static HANDLE my_readsig;
/* Function declarations */
static int __stdcall checkstate (waitq *) __attribute__ ((regparm (1)));
static __inline__ bool get_proc_lock (DWORD, DWORD);
static bool __stdcall remove_proc (int);
static bool __stdcall stopped_or_terminated (waitq *, _pinfo *);
static DWORD WINAPI wait_sig (VOID *arg);
/* wait_sig bookkeeping */
class pending_signals
{
sigpacket sigs[NSIG + 1];
sigpacket start;
sigpacket *end;
sigpacket *prev;
sigpacket *curr;
public:
void reset () {curr = &start; prev = &start;}
void add (sigpacket&);
void del ();
sigpacket *next ();
sigpacket *save () const {return curr;}
void restore (sigpacket *saved) {curr = saved;}
friend void __stdcall sig_dispatch_pending (bool);
friend DWORD WINAPI wait_sig (VOID *arg);
};
Static pending_signals sigq;
/* Functions */
void __stdcall
sigalloc ()
{
cygheap->sigs = global_sigs =
(struct sigaction *) ccalloc_abort (HEAP_SIGS, NSIG, sizeof (struct sigaction));
global_sigs[SIGSTOP].sa_flags = SA_RESTART | SA_NODEFER;
}
void __stdcall
signal_fixup_after_exec ()
{
global_sigs = cygheap->sigs;
/* Set up child's signal handlers */
for (int i = 0; i < NSIG; i++)
{
global_sigs[i].sa_mask = 0;
if (global_sigs[i].sa_handler != SIG_IGN)
{
global_sigs[i].sa_handler = SIG_DFL;
global_sigs[i].sa_flags &= ~ SA_SIGINFO;
}
}
}
void __stdcall
wait_for_sigthread ()
{
sigproc_printf ("wait_sig_inited %p", wait_sig_inited);
HANDLE hsig_inited = wait_sig_inited;
WaitForSingleObject (hsig_inited, INFINITE);
wait_sig_inited = NULL;
myself->sendsig = my_sendsig;
myself->process_state |= PID_ACTIVE;
myself->process_state &= ~PID_INITIALIZING;
ForceCloseHandle1 (hsig_inited, wait_sig_inited);
sigproc_printf ("process/signal handling enabled, state %p", myself->process_state);
}
/* Get the sync_proc_subproc muto to control access to
* children, proc arrays.
* Attempt to handle case where process is exiting as we try to grab
* the mutex.
*/
static bool
get_proc_lock (DWORD what, DWORD val)
{
Static int lastwhat = -1;
if (!sync_proc_subproc)
{
sigproc_printf ("sync_proc_subproc is NULL (1)");
return false;
}
if (sync_proc_subproc.acquire (WPSP))
{
lastwhat = what;
return true;
}
if (!sync_proc_subproc)
{
sigproc_printf ("sync_proc_subproc is NULL (2)");
return false;
}
system_printf ("Couldn't aquire sync_proc_subproc for(%d,%d), last %d, %E",
what, val, lastwhat);
return true;
}
static bool __stdcall
proc_can_be_signalled (_pinfo *p)
{
if (!(p->exitcode & EXITCODE_SET))
{
if (ISSTATE (p, PID_INITIALIZING) ||
(((p)->process_state & (PID_ACTIVE | PID_IN_USE)) ==
(PID_ACTIVE | PID_IN_USE)))
return true;
}
set_errno (ESRCH);
return false;
}
bool __stdcall
pid_exists (pid_t pid)
{
return pinfo (pid)->exists ();
}
/* Return true if this is one of our children, false otherwise. */
static inline bool __stdcall
mychild (int pid)
{
for (int i = 0; i < nprocs; i++)
if (procs[i]->pid == pid)
return true;
return false;
}
/* Handle all subprocess requests
*/
int __stdcall
proc_subproc (DWORD what, DWORD val)
{
int rc = 1;
int potential_match;
_pinfo *child;
int clearing;
waitq *w;
#define wval ((waitq *) val)
#define vchild (*((pinfo *) val))
sigproc_printf ("args: %x, %d", what, val);
if (!get_proc_lock (what, val)) // Serialize access to this function
{
system_printf ("couldn't get proc lock. what %d, val %d", what, val);
goto out1;
}
switch (what)
{
/* Add a new subprocess to the children arrays.
* (usually called from the main thread)
*/
case PROC_ADDCHILD:
/* Filled up process table? */
if (nprocs >= NPROCS)
{
sigproc_printf ("proc table overflow: hit %d processes, pid %d\n",
nprocs, vchild->pid);
rc = 0;
set_errno (EAGAIN);
break;
}
/* fall through intentionally */
case PROC_DETACHED_CHILD:
if (vchild != myself)
{
vchild->ppid = what == PROC_DETACHED_CHILD ? 1 : myself->pid;
vchild->uid = myself->uid;
vchild->gid = myself->gid;
vchild->pgid = myself->pgid;
vchild->sid = myself->sid;
vchild->ctty = myself->ctty;
vchild->cygstarted = true;
vchild->process_state |= PID_INITIALIZING | (myself->process_state & PID_USETTY);
}
if (what == PROC_DETACHED_CHILD)
break;
procs[nprocs] = vchild;
rc = procs[nprocs].wait ();
if (rc)
{
sigproc_printf ("added pid %d to proc table, slot %d", vchild->pid,
nprocs);
nprocs++;
}
break;
/* Handle a wait4() operation. Allocates an event for the calling
* thread which is signaled when the appropriate pid exits or stops.
* (usually called from the main thread)
*/
case PROC_WAIT:
wval->ev = NULL; // Don't know event flag yet
if (wval->pid == -1 || !wval->pid)
child = NULL; // Not looking for a specific pid
else if (!mychild (wval->pid))
goto out; // invalid pid. flag no such child
wval->status = 0; // Don't know status yet
sigproc_printf ("wval->pid %d, wval->options %d", wval->pid, wval->options);
/* If the first time for this thread, create a new event, otherwise
* reset the event.
*/
if ((wval->ev = wval->thread_ev) == NULL)
{
wval->ev = wval->thread_ev = CreateEvent (&sec_none_nih, TRUE, FALSE,
NULL);
ProtectHandle1 (wval->ev, wq_ev);
}
ResetEvent (wval->ev);
w = waitq_head.next;
waitq_head.next = wval; /* Add at the beginning. */
wval->next = w; /* Link in rest of the list. */
clearing = 0;
goto scan_wait;
/* Clear all waiting threads. Called from exceptions.cc prior to
the main thread's dispatch to a signal handler function.
(called from wait_sig thread) */
case PROC_CLEARWAIT:
/* Clear all "wait"ing threads. */
if (val)
sigproc_printf ("clear waiting threads");
else
sigproc_printf ("looking for processes to reap, nprocs %d", nprocs);
clearing = val;
scan_wait:
/* Scan the linked list of wait()ing threads. If a wait's parameters
match this pid, then activate it. */
for (w = &waitq_head; w->next != NULL; w = w->next)
{
if ((potential_match = checkstate (w)) > 0)
sigproc_printf ("released waiting thread");
else if (!clearing && !(w->next->options & WNOHANG) && potential_match < 0)
sigproc_printf ("only found non-terminated children");
else if (potential_match <= 0) // nothing matched
{
sigproc_printf ("waiting thread found no children");
HANDLE oldw = w->next->ev;
w->next->pid = 0;
if (clearing)
w->next->status = -1; /* flag that a signal was received */
else if (!potential_match || !(w->next->options & WNOHANG))
w->next->ev = NULL;
if (!SetEvent (oldw))
system_printf ("couldn't wake up wait event %p, %E", oldw);
w->next = w->next->next;
}
if (w->next == NULL)
break;
}
if (!clearing)
sigproc_printf ("finished processing terminated/stopped child");
else
{
waitq_head.next = NULL;
sigproc_printf ("finished clearing");
}
if (global_sigs[SIGCHLD].sa_handler == (void *) SIG_IGN)
for (int i = 0; i < nprocs; i += remove_proc (i))
continue;
}
out:
sync_proc_subproc.release (); // Release the lock
out1:
sigproc_printf ("returning %d", rc);
return rc;
#undef wval
#undef vchild
}
// FIXME: This is inelegant
void
_cygtls::remove_wq (DWORD wait)
{
if (exit_state < ES_FINAL && sync_proc_subproc
&& sync_proc_subproc.acquire (wait))
{
for (waitq *w = &waitq_head; w->next != NULL; w = w->next)
if (w->next == &wq)
{
ForceCloseHandle1 (wq.thread_ev, wq_ev);
w->next = wq.next;
break;
}
sync_proc_subproc.release ();
}
}
/* Terminate the wait_subproc thread.
Called on process exit.
Also called by spawn_guts to disassociate any subprocesses from this
process. Subprocesses will then know to clean up after themselves and
will not become procs. */
void __stdcall
proc_terminate ()
{
sigproc_printf ("nprocs %d", nprocs);
if (nprocs)
{
sync_proc_subproc.acquire (WPSP);
proc_subproc (PROC_CLEARWAIT, 1);
/* Clean out proc processes from the pid list. */
int i;
for (i = 0; i < nprocs; i++)
{
procs[i]->ppid = 1;
if (procs[i].wait_thread)
{
// CloseHandle (procs[i].rd_proc_pipe);
procs[i].wait_thread->terminate_thread ();
}
procs[i].release ();
}
nprocs = 0;
sync_proc_subproc.release ();
}
sigproc_printf ("leaving");
}
/* Clear pending signal */
void __stdcall
sig_clear (int target_sig)
{
if (&_my_tls != _sig_tls)
sig_send (myself, -target_sig);
else
{
sigpacket *q;
sigpacket *save = sigq.save ();
sigq.reset ();
while ((q = sigq.next ()))
if (q->si.si_signo == target_sig)
{
q->si.si_signo = __SIGDELETE;
break;
}
sigq.restore (save);
}
}
extern "C" int
sigpending (sigset_t *mask)
{
sigset_t outset = (sigset_t) sig_send (myself, __SIGPENDING);
if (outset == SIG_BAD_MASK)
return -1;
*mask = outset;
return 0;
}
/* Force the wait_sig thread to wake up and scan for pending signals */
void __stdcall
sig_dispatch_pending (bool fast)
{
if (exit_state || &_my_tls == _sig_tls)
{
#ifdef DEBUGGING
sigproc_printf ("exit_state %d, cur thread id %p, _sig_tls %p, sigq.start.next %p",
exit_state, GetCurrentThreadId (), _sig_tls, sigq.start.next);
#endif
return;
}
#ifdef DEBUGGING
sigproc_printf ("flushing");
#endif
sig_send (myself, fast ? __SIGFLUSHFAST : __SIGFLUSH);
}
void __stdcall
create_signal_arrived ()
{
if (signal_arrived)
return;
/* local event signaled when main thread has been dispatched
to a signal handler function. */
signal_arrived = CreateEvent (&sec_none_nih, TRUE, FALSE, NULL);
ProtectHandle (signal_arrived);
}
/* Signal thread initialization. Called from dll_crt0_1.
This routine starts the signal handling thread. The wait_sig_inited
event is used to signal that the thread is ready to handle signals.
We don't wait for this during initialization but instead detect it
in sig_send to gain a little concurrency. */
void __stdcall
sigproc_init ()
{
wait_sig_inited = CreateEvent (&sec_none_nih, TRUE, FALSE, NULL);
ProtectHandle (wait_sig_inited);
/* sync_proc_subproc is used by proc_subproc. It serialises
access to the children and proc arrays. */
sync_proc_subproc.init ("sync_proc_subproc");
hwait_sig = new cygthread (wait_sig, 0, cygself, "sig");
hwait_sig->zap_h ();
}
/* Called on process termination to terminate signal and process threads.
*/
void __stdcall
sigproc_terminate (exit_states es)
{
exit_states prior_exit_state = exit_state;
exit_state = es;
if (prior_exit_state >= ES_FINAL)
sigproc_printf ("already performed");
else
{
sigproc_printf ("entering");
sig_send (myself_nowait, __SIGEXIT);
proc_terminate (); // clean up process stuff
}
}
int __stdcall
sig_send (_pinfo *p, int sig)
{
if (sig == __SIGHOLD)
sigheld = true;
else if (!sigheld)
/* nothing */;
else if (sig == __SIGFLUSH || sig == __SIGFLUSHFAST)
return 0;
else if (sig == __SIGNOHOLD || sig == __SIGEXIT)
{
SetEvent (sigCONT);
sigheld = false;
}
else if (&_my_tls == _main_tls)
{
#ifdef DEBUGGING
system_printf ("signal %d sent to %p while signals are on hold", sig, p);
#endif
return -1;
}
siginfo_t si = {0};
si.si_signo = sig;
si.si_code = SI_KERNEL;
si.si_pid = si.si_uid = si.si_errno = 0;
return sig_send (p, si);
}
/* Send a signal to another process by raising its signal semaphore.
If pinfo *p == NULL, send to the current process.
If sending to this process, wait for notification that a signal has
completed before returning. */
int __stdcall
sig_send (_pinfo *p, siginfo_t& si, _cygtls *tls)
{
int rc = 1;
bool its_me;
HANDLE sendsig;
sigpacket pack;
bool communing = si.si_signo == __SIGCOMMUNE;
pack.wakeup = NULL;
bool wait_for_completion;
if (!(its_me = (!hExeced && (p == NULL || p == myself || p == myself_nowait))))
{
/* It is possible that the process is not yet ready to receive messages
* or that it has exited. Detect this.
*/
if (!proc_can_be_signalled (p)) /* Is the process accepting messages? */
{
sigproc_printf ("invalid pid %d(%x), signal %d",
p->pid, p->process_state, si.si_signo);
goto out;
}
wait_for_completion = false;
}
else
{
if (no_signals_available (si.si_signo != __SIGEXIT))
{
sigproc_printf ("my_sendsig %p, myself->sendsig %p, exit_state %d",
my_sendsig, myself->sendsig, exit_state);
set_errno (EAGAIN);
goto out; // Either exiting or not yet initializing
}
if (wait_sig_inited)
wait_for_sigthread ();
wait_for_completion = p != myself_nowait && _my_tls.isinitialized () && !exit_state;
p = myself;
}
if (its_me)
sendsig = my_sendsig;
else
{
HANDLE dupsig;
DWORD dwProcessId;
for (int i = 0; !p->sendsig && i < 10000; i++)
low_priority_sleep (0);
if (p->sendsig)
{
dupsig = p->sendsig;
dwProcessId = p->dwProcessId;
}
else
{
dupsig = p->exec_sendsig;
dwProcessId = p->exec_dwProcessId;
}
if (!dupsig)
{
set_errno (EAGAIN);
sigproc_printf ("sendsig handle never materialized");
goto out;
}
HANDLE hp = OpenProcess (PROCESS_DUP_HANDLE, false, dwProcessId);
if (!hp)
{
__seterrno ();
sigproc_printf ("OpenProcess failed, %E");
goto out;
}
VerifyHandle (hp);
if (!DuplicateHandle (hp, dupsig, hMainProc, &sendsig, false, 0,
DUPLICATE_SAME_ACCESS) || !sendsig)
{
__seterrno ();
sigproc_printf ("DuplicateHandle failed, %E");
CloseHandle (hp);
goto out;
}
VerifyHandle (sendsig);
if (!communing)
CloseHandle (hp);
else
{
si._si_commune._si_process_handle = hp;
HANDLE& tome = si._si_commune._si_write_handle;
HANDLE& fromthem = si._si_commune._si_read_handle;
if (!CreatePipe (&fromthem, &tome, &sec_all_nih, 0))
{
sigproc_printf ("CreatePipe for __SIGCOMMUNE failed, %E");
__seterrno ();
goto out;
}
if (!DuplicateHandle (hMainProc, tome, hp, &tome, false, 0,
DUPLICATE_SAME_ACCESS | DUPLICATE_CLOSE_SOURCE))
{
sigproc_printf ("DuplicateHandle for __SIGCOMMUNE failed, %E");
__seterrno ();
goto out;
}
}
}
sigproc_printf ("sendsig %p, pid %d, signal %d, its_me %d", sendsig, p->pid, si.si_signo, its_me);
sigset_t pending;
if (!its_me)
pack.mask = NULL;
else if (si.si_signo == __SIGPENDING)
pack.mask = &pending;
else if (si.si_signo == __SIGFLUSH || si.si_signo > 0)
pack.mask = tls ? &tls->sigmask : &_main_tls->sigmask;
else
pack.mask = NULL;
pack.si = si;
if (!pack.si.si_pid)
pack.si.si_pid = myself->pid;
if (!pack.si.si_uid)
pack.si.si_uid = myself->uid;
pack.pid = myself->pid;
pack.tls = tls;
if (wait_for_completion)
{
pack.wakeup = CreateEvent (&sec_none_nih, FALSE, FALSE, NULL);
sigproc_printf ("wakeup %p", pack.wakeup);
ProtectHandle (pack.wakeup);
}
char *leader;
size_t packsize;
if (!communing || !(si._si_commune._si_code & PICOM_EXTRASTR))
{
leader = (char *) &pack;
packsize = sizeof (pack);
}
else
{
size_t n = strlen (si._si_commune._si_str);
char *p = leader = (char *) alloca (sizeof (pack) + sizeof (n) + n);
memcpy (p, &pack, sizeof (pack)); p += sizeof (pack);
memcpy (p, &n, sizeof (n)); p += sizeof (n);
memcpy (p, si._si_commune._si_str, n); p += n;
packsize = p - leader;
}
DWORD nb;
if (!WriteFile (sendsig, leader, packsize, &nb, NULL) || nb != packsize)
{
/* Couldn't send to the pipe. This probably means that the
process is exiting. */
if (!its_me)
{
__seterrno ();
sigproc_printf ("WriteFile for pipe %p failed, %E", sendsig);
ForceCloseHandle (sendsig);
}
else
{
if (no_signals_available (true))
sigproc_printf ("I'm going away now");
else if (!p->exec_sendsig)
system_printf ("error sending signal %d to pid %d, pipe handle %p, %E",
si.si_signo, p->pid, sendsig);
set_errno (EACCES);
}
goto out;
}
/* No need to wait for signal completion unless this was a signal to
this process.
If it was a signal to this process, wait for a dispatched signal.
Otherwise just wait for the wait_sig to signal that it has finished
processing the signal. */
if (wait_for_completion)
{
sigproc_printf ("Waiting for pack.wakeup %p", pack.wakeup);
rc = WaitForSingleObject (pack.wakeup, WSSC);
ForceCloseHandle (pack.wakeup);
}
else
{
rc = WAIT_OBJECT_0;
sigproc_printf ("Not waiting for sigcomplete. its_me %d signal %d",
its_me, si.si_signo);
if (!its_me)
ForceCloseHandle (sendsig);
}
pack.wakeup = NULL;
if (rc == WAIT_OBJECT_0)
rc = 0; // Successful exit
else
{
if (!no_signals_available (true))
system_printf ("wait for sig_complete event failed, signal %d, rc %d, %E",
si.si_signo, rc);
set_errno (ENOSYS);
rc = -1;
}
if (wait_for_completion && si.si_signo != __SIGFLUSHFAST)
_my_tls.call_signal_handler ();
goto out;
out:
if (communing && rc)
{
if (si._si_commune._si_process_handle)
CloseHandle (si._si_commune._si_process_handle);
if (si._si_commune._si_read_handle)
CloseHandle (si._si_commune._si_read_handle);
}
if (pack.wakeup)
ForceCloseHandle (pack.wakeup);
if (si.si_signo != __SIGPENDING)
/* nothing */;
else if (!rc)
rc = (int) pending;
else
rc = SIG_BAD_MASK;
sigproc_printf ("returning %p from sending signal %d", rc, si.si_signo);
return rc;
}
int child_info::retry_count = 10;
/* Initialize some of the memory block passed to child processes
by fork/spawn/exec. */
child_info::child_info (unsigned in_cb, child_info_types chtype, bool need_subproc_ready)
{
memset (this, 0, in_cb);
cb = in_cb;
/* It appears that when running under WOW64 on Vista 64, the first DWORD
value in the datastructure lpReserved2 is pointing to (msv_count in
Cygwin), has to reflect the size of that datastructure as used in the
Microsoft C runtime (a count value, counting the number of elements in
two subsequent arrays, BYTE[count and HANDLE[count]), even though the C
runtime isn't used. Otherwise, if msv_count is 0 or too small, the
datastructure gets overwritten.
This seems to be a bug in Vista's WOW64, which apparently copies the
lpReserved2 datastructure not using the cbReserved2 size information,
but using the information given in the first DWORD within lpReserved2
instead. 32 bit Windows and former WOW64 don't care if msv_count is 0
or a sensible non-0 count value. However, it's not clear if a non-0
count doesn't result in trying to evaluate the content, so we do this
really only for Vista 64 for now.
Note: It turns out that a non-zero value *does* harm operation on
XP 64 and 2K3 64 (Crash in CreateProcess call).
The value is sizeof (child_info_*) / 5 which results in a count which
covers the full datastructure, plus not more than 4 extra bytes. This
is ok as long as the child_info structure is cosily stored within a bigger
datastructure. */
msv_count = wincap.needs_count_in_si_lpres2 () ? in_cb / 5 : 0;
intro = PROC_MAGIC_GENERIC;
magic = CHILD_INFO_MAGIC;
type = chtype;
fhandler_union_cb = sizeof (fhandler_union);
user_h = cygwin_user_h;
if (strace.attached ())
flag |= _CI_STRACED;
if (need_subproc_ready)
{
subproc_ready = CreateEvent (&sec_all, FALSE, FALSE, NULL);
flag |= _CI_ISCYGWIN;
}
sigproc_printf ("subproc_ready %p", subproc_ready);
cygheap = ::cygheap;
cygheap_max = ::cygheap_max;
retry = child_info::retry_count;
/* Create an inheritable handle to pass to the child process. This will
allow the child to duplicate handles from the parent to itself. */
parent = NULL;
if (!DuplicateHandle (hMainProc, hMainProc, hMainProc, &parent, 0, TRUE,
DUPLICATE_SAME_ACCESS))
system_printf ("couldn't create handle to myself for child, %E");
}
child_info::~child_info ()
{
if (subproc_ready)
CloseHandle (subproc_ready);
if (parent)
CloseHandle (parent);
}
child_info_fork::child_info_fork () :
child_info (sizeof *this, _PROC_FORK, true)
{
}
child_info_spawn::child_info_spawn (child_info_types chtype, bool need_subproc_ready) :
child_info (sizeof *this, chtype, need_subproc_ready)
{
}
void
child_info::ready (bool execed)
{
if (!subproc_ready)
{
sigproc_printf ("subproc_ready not set");
return;
}
if (dynamically_loaded)
sigproc_printf ("not really ready");
else if (!SetEvent (subproc_ready))
api_fatal ("SetEvent failed");
else
sigproc_printf ("signalled %p that I was ready", subproc_ready);
if (execed)
{
CloseHandle (subproc_ready);
subproc_ready = NULL;
}
}
bool
child_info::sync (pid_t pid, HANDLE& hProcess, DWORD howlong)
{
bool res;
HANDLE w4[2];
unsigned n = 0;
unsigned nsubproc_ready;
if (!subproc_ready)
nsubproc_ready = WAIT_OBJECT_0 + 3;
else
{
w4[n++] = subproc_ready;
nsubproc_ready = 0;
}
w4[n++] = hProcess;
sigproc_printf ("n %d, waiting for subproc_ready(%p) and child process(%p)", n, w4[0], w4[1]);
DWORD x = WaitForMultipleObjects (n, w4, FALSE, howlong);
x -= WAIT_OBJECT_0;
if (x >= n)
{
system_printf ("wait failed, pid %u, %E", pid);
res = false;
}
else
{
if (x != nsubproc_ready)
{
res = false;
GetExitCodeProcess (hProcess, &exit_code);
}
else
{
res = true;
exit_code = STILL_ACTIVE;
if (type == _PROC_EXEC && myself->wr_proc_pipe)
{
ForceCloseHandle1 (hProcess, childhProc);
hProcess = NULL;
}
}
sigproc_printf ("pid %u, WFMO returned %d, res %d", pid, x, res);
}
return res;
}
DWORD
child_info::proc_retry (HANDLE h)
{
if (!exit_code)
return EXITCODE_OK;
switch (exit_code)
{
case STILL_ACTIVE: /* shouldn't happen */
sigproc_printf ("STILL_ACTIVE? How'd we get here?");
break;
case STATUS_DLL_NOT_FOUND:
return exit_code;
case STATUS_CONTROL_C_EXIT:
if (saw_ctrl_c ())
return EXITCODE_OK;
/* fall through intentionally */
case STATUS_DLL_INIT_FAILED:
case STATUS_DLL_INIT_FAILED_LOGOFF:
case EXITCODE_RETRY:
if (retry-- > 0)
exit_code = 0;
break;
/* Count down non-recognized exit codes more quickly since they aren't
due to known conditions. */
default:
if (!iscygwin () && (exit_code & 0xffff0000) != 0xc0000000)
break;
if ((retry -= 2) < 0)
retry = 0;
else
exit_code = 0;
}
if (!exit_code)
ForceCloseHandle1 (h, childhProc);
return exit_code;
}
bool
child_info_fork::handle_failure (DWORD err)
{
if (retry > 0)
ExitProcess (EXITCODE_RETRY);
return 0;
}
/* Check the state of all of our children to see if any are stopped or
* terminated.
*/
static int __stdcall
checkstate (waitq *parent_w)
{
int potential_match = 0;
sigproc_printf ("nprocs %d", nprocs);
/* Check already dead processes first to see if they match the criteria
* given in w->next. */
int res;
for (int i = 0; i < nprocs; i++)
if ((res = stopped_or_terminated (parent_w, procs[i])))
{
remove_proc (i);
potential_match = 1;
goto out;
}
sigproc_printf ("no matching terminated children found");
potential_match = -!!nprocs;
out:
sigproc_printf ("returning %d", potential_match);
return potential_match;
}
/* Remove a proc from procs by swapping it with the last child in the list.
Also releases shared memory of exited processes. */
static bool __stdcall
remove_proc (int ci)
{
if (procs[ci]->exists ())
return true;
sigproc_printf ("removing procs[%d], pid %d, nprocs %d", ci, procs[ci]->pid,
nprocs);
if (procs[ci] != myself)
{
procs[ci].release ();
if (procs[ci].hProcess)
ForceCloseHandle1 (procs[ci].hProcess, childhProc);
}
if (ci < --nprocs)
{
/* Wait for proc_waiter thread to make a copy of this element before
moving it or it may become confused. The chances are very high that
the proc_waiter thread has already done this by the time we
get here. */
while (!procs[nprocs].waiter_ready)
low_priority_sleep (0);
procs[ci] = procs[nprocs];
}
return 0;
}
/* Check status of child process vs. waitq member.
parent_w is the pointer to the parent of the waitq member in question.
child is the subprocess being considered.
Returns non-zero if waiting thread released. */
static bool __stdcall
stopped_or_terminated (waitq *parent_w, _pinfo *child)
{
int might_match;
waitq *w = parent_w->next;
sigproc_printf ("considering pid %d", child->pid);
if (w->pid == -1)
might_match = 1;
else if (w->pid == 0)
might_match = child->pgid == myself->pgid;
else if (w->pid < 0)
might_match = child->pgid == -w->pid;
else
might_match = (w->pid == child->pid);
if (!might_match)
return false;
int terminated;
if (!((terminated = (child->process_state == PID_EXITED)) ||
((w->options & (WUNTRACED | WCONTINUED)) && child->stopsig)))
return false;
parent_w->next = w->next; /* successful wait. remove from wait queue */
w->pid = child->pid;
if (!terminated)
{
sigproc_printf ("stopped child");
if (child->stopsig == SIGCONT)
w->status = __W_CONTINUED;
else
w->status = (child->stopsig << 8) | 0x7f;
child->stopsig = 0;
}
else
{
w->status = (__uint16_t) child->exitcode;
add_rusage (&myself->rusage_children, &child->rusage_children);
add_rusage (&myself->rusage_children, &child->rusage_self);
if (w->rusage)
{
add_rusage ((struct rusage *) w->rusage, &child->rusage_children);
add_rusage ((struct rusage *) w->rusage, &child->rusage_self);
}
}
if (!SetEvent (w->ev)) /* wake up wait4 () immediately */
system_printf ("couldn't wake up wait event %p, %E", w->ev);
return true;
}
static void
talktome (siginfo_t *si)
{
unsigned size = sizeof (*si);
sigproc_printf ("pid %d wants some information", si->si_pid);
if (si->_si_commune._si_code & PICOM_EXTRASTR)
{
size_t n;
DWORD nb;
if (!ReadFile (my_readsig, &n, sizeof (n), &nb, NULL) || nb != sizeof (n))
return;
siginfo_t *newsi = (siginfo_t *) alloca (size += n + 1);
*newsi = *si;
newsi->_si_commune._si_str = (char *) (newsi + 1);
if (!ReadFile (my_readsig, newsi->_si_commune._si_str, n, &nb, NULL) || nb != n)
return;
newsi->_si_commune._si_str[n] = '\0';
si = newsi;
}
pinfo pi (si->si_pid);
if (pi)
new cygthread (commune_process, size, si, "commune_process");
}
void
pending_signals::add (sigpacket& pack)
{
sigpacket *se;
if (sigs[pack.si.si_signo].si.si_signo)
return;
se = sigs + pack.si.si_signo;
*se = pack;
se->mask = &pack.tls->sigmask;
se->next = NULL;
if (end)
end->next = se;
end = se;
if (!start.next)
start.next = se;
}
void
pending_signals::del ()
{
sigpacket *next = curr->next;
prev->next = next;
curr->si.si_signo = 0;
#ifdef DEBUGGING
curr->next = NULL;
#endif
if (end == curr)
end = prev;
curr = next;
}
sigpacket *
pending_signals::next ()
{
sigpacket *res;
prev = curr;
if (!curr || !(curr = curr->next))
res = NULL;
else
res = curr;
return res;
}
/* Called separately to allow stack space reutilization by wait_sig.
This function relies on the fact that it will be called after cygheap
has been set up. For the case of non-dynamic DLL initialization this
means that it relies on the implicit serialization guarantted by being
run as part of DLL_PROCESS_ATTACH. */
static void __attribute__ ((noinline))
init_sig_pipe()
{
char char_sa_buf[1024];
PSECURITY_ATTRIBUTES sa_buf = sec_user_nih ((PSECURITY_ATTRIBUTES) char_sa_buf, cygheap->user.sid());
if (!CreatePipe (&my_readsig, &my_sendsig, sa_buf, 0))
api_fatal ("couldn't create signal pipe, %E");
ProtectHandle (my_readsig);
}
/* Process signals by waiting for signal data to arrive in a pipe.
Set a completion event if one was specified. */
static DWORD WINAPI
wait_sig (VOID *)
{
init_sig_pipe ();
/* Initialization */
SetThreadPriority (GetCurrentThread (), WAIT_SIG_PRIORITY);
sigCONT = CreateEvent (&sec_none_nih, FALSE, FALSE, NULL);
SetEvent (wait_sig_inited);
_sig_tls = &_my_tls;
sigproc_printf ("entering ReadFile loop, my_readsig %p, my_sendsig %p",
my_readsig, my_sendsig);
sigpacket pack;
pack.si.si_signo = 0;
for (;;)
{
if (pack.si.si_signo == __SIGHOLD)
WaitForSingleObject (sigCONT, INFINITE);
DWORD nb;
pack.tls = NULL;
if (!ReadFile (my_readsig, &pack, sizeof (pack), &nb, NULL))
break;
if (nb != sizeof (pack))
{
system_printf ("short read from signal pipe: %d != %d", nb,
sizeof (pack));
continue;
}
if (!pack.si.si_signo)
{
#ifdef DEBUGGING
system_printf ("zero signal?");
#endif
continue;
}
sigset_t dummy_mask;
if (!pack.mask)
{
dummy_mask = _main_tls->sigmask;
pack.mask = &dummy_mask;
}
sigpacket *q;
bool clearwait = false;
switch (pack.si.si_signo)
{
case __SIGCOMMUNE:
talktome (&pack.si);
break;
case __SIGSTRACE:
strace.hello ();
break;
case __SIGPENDING:
*pack.mask = 0;
unsigned bit;
sigq.reset ();
while ((q = sigq.next ()))
if (pack.tls->sigmask & (bit = SIGTOMASK (q->si.si_signo)))
*pack.mask |= bit;
break;
case __SIGHOLD:
goto loop;
break;
case __SIGNOHOLD:
case __SIGFLUSH:
case __SIGFLUSHFAST:
sigq.reset ();
while ((q = sigq.next ()))
{
int sig = q->si.si_signo;
if (sig == __SIGDELETE || q->process () > 0)
sigq.del ();
if (sig == __SIGNOHOLD && q->si.si_signo == SIGCHLD)
clearwait = true;
}
break;
case __SIGEXIT:
hwait_sig = (cygthread *) INVALID_HANDLE_VALUE;
sigproc_printf ("saw __SIGEXIT");
break; /* handle below */
default:
if (pack.si.si_signo < 0)
sig_clear (-pack.si.si_signo);
else
{
int sig = pack.si.si_signo;
// FIXME: REALLY not right when taking threads into consideration.
// We need a per-thread queue since each thread can have its own
// list of blocked signals. CGF 2005-08-24
if (sigq.sigs[sig].si.si_signo && sigq.sigs[sig].tls == pack.tls)
sigproc_printf ("sig %d already queued", pack.si.si_signo);
else
{
int sigres = pack.process ();
if (sigres <= 0)
{
#ifdef DEBUGGING2
if (!sigres)
system_printf ("Failed to arm signal %d from pid %d", pack.sig, pack.pid);
#endif
sigq.add (pack); // FIXME: Shouldn't add this in !sh condition
}
}
if (sig == SIGCHLD)
clearwait = true;
}
break;
}
if (clearwait)
proc_subproc (PROC_CLEARWAIT, 0);
loop:
if (pack.wakeup)
{
sigproc_printf ("signalling pack.wakeup %p", pack.wakeup);
SetEvent (pack.wakeup);
}
if (pack.si.si_signo == __SIGEXIT)
break;
}
ForceCloseHandle (my_readsig);
sigproc_printf ("signal thread exiting");
ExitThread (0);
}