newlib/winsup/cygwin/thread.cc
Christopher Faylor f97e7d754c * cygwin.din: Export rand48 functions.
* thread.cc (MTinterface::Init): Remove the initialization of `reent_data'.
* dcrt0.cc: Add the initalizer to the declaration of `reent_data'.
* include/cygwin/version.h: Bump CYGWIN_VERSION_API_MINOR to 35.
2001-02-20 02:53:55 +00:00

986 lines
20 KiB
C++

/* thread.cc: Locking and threading module functions
Copyright 1998, 1999, 2000, 2001 Red Hat, Inc.
Written by Marco Fuykschot <marco@ddi.nl>
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. */
#ifdef HAVE_CONFIG_H
# include "config.h"
#endif
#ifdef _MT_SAFE
#include "winsup.h"
#include <limits.h>
#include <errno.h>
#include <assert.h>
#include <stdlib.h>
#include <syslog.h>
#include "sync.h"
#include "sigproc.h"
#include "pinfo.h"
#include "perprocess.h"
#include "security.h"
extern int threadsafe;
#define MT_INTERFACE user_data->threadinterface
#define NOT_IMP(n) system_printf ("not implemented %s\n", n); return 0;
#define CHECKHANDLE(rval, release) \
if (!item->HandleOke ()) \
{ \
if (release) \
item->used=false; \
return rval; \
}
#define GETTHREAD(n) \
if (!thread) system_printf ("thread is NULL");\
SetResourceLock (LOCK_THREAD_LIST, READ_LOCK, n);\
ThreadItem *item=user_data->threadinterface->GetThread (thread); \
ReleaseResourceLock (LOCK_THREAD_LIST, READ_LOCK, n); \
if (!item) return EINVAL; \
CHECKHANDLE (EINVAL, 0);
#define GETMUTEX(n) \
SetResourceLock (LOCK_MUTEX_LIST, READ_LOCK, n); \
MutexItem* item=user_data->threadinterface->GetMutex (mutex); \
ReleaseResourceLock (LOCK_MUTEX_LIST, READ_LOCK, n); \
if (!item) return EINVAL; \
CHECKHANDLE (EINVAL, 0);
#define GETSEMA(n) \
SetResourceLock (LOCK_SEM_LIST, READ_LOCK, n); \
SemaphoreItem* item=user_data->threadinterface->GetSemaphore (sem); \
ReleaseResourceLock (LOCK_SEM_LIST, READ_LOCK, n); \
if (!item) return EINVAL; \
CHECKHANDLE (EINVAL, 0);
#define CHECKITEM(rn, rm, fn) \
if (!item) { \
ReleaseResourceLock (rn, rm, fn); \
return EINVAL; }; \
struct _reent *
_reent_clib ()
{
int tmp = GetLastError ();
struct __reent_t *_r = (struct __reent_t *) TlsGetValue (MT_INTERFACE->reent_index);
#ifdef _CYG_THREAD_FAILSAFE
if (_r == 0)
system_printf ("local thread storage not inited");
#endif
SetLastError (tmp);
return _r->_clib;
}
struct _winsup_t *
_reent_winsup ()
{
int tmp = GetLastError ();
struct __reent_t *_r;
_r = (struct __reent_t *) TlsGetValue (MT_INTERFACE->reent_index);
#ifdef _CYG_THREAD_FAILSAFE
if (_r == 0)
system_printf ("local thread storage not inited");
#endif
SetLastError (tmp);
return _r->_winsup;
}
inline LPCRITICAL_SECTION
ResourceLocks::Lock (int _resid)
{
#ifdef _CYG_THREAD_FAILSAFE
if (!inited)
system_printf ("lock called before initialization");
thread_printf ("Get Resource lock %d ==> %p for %p , real : %d , threadid %d ",
_resid, &lock, user_data, myself->pid, GetCurrentThreadId ());
#endif
return &lock;
}
void
SetResourceLock (int _res_id, int _mode, const char *_function)
{
#ifdef _CYG_THREAD_FAILSAFE
thread_printf ("Set resource lock %d mode %d for %s start",
_res_id, _mode, _function);
#endif
EnterCriticalSection (user_data->resourcelocks->Lock (_res_id));
#ifdef _CYG_THREAD_FAILSAFE
user_data->resourcelocks->owner = GetCurrentThreadId ();
user_data->resourcelocks->count++;
#endif
}
void
ReleaseResourceLock (int _res_id, int _mode, const char *_function)
{
#ifdef _CYG_THREAD_FAILSAFE
thread_printf ("Release resource lock %d mode %d for %s done", _res_id, _mode, _function);
AssertResourceOwner (_res_id, _mode);
user_data->resourcelocks->count--;
if (user_data->resourcelocks->count == 0)
user_data->resourcelocks->owner = 0;
#endif
LeaveCriticalSection (user_data->resourcelocks->Lock (_res_id));
}
#ifdef _CYG_THREAD_FAILSAFE
void
AssertResourceOwner (int _res_id, int _mode)
{
thread_printf ("Assert Resource lock %d ==> for %p , real : %d , threadid %d count %d owner %d",
_res_id, user_data, myself->pid, GetCurrentThreadId (),
user_data->resourcelocks->count, user_data->resourcelocks->owner);
if (user_data && (user_data->resourcelocks->owner != GetCurrentThreadId ()))
system_printf ("assertion failed, not the resource owner");
}
#endif
void
ResourceLocks::Init ()
{
InitializeCriticalSection (&lock);
inited = true;
#ifdef _CYG_THREAD_FAILSAFE
owner = 0;
count = 0;
#endif
thread_printf ("lock %p inited by %p , %d", &lock, user_data, myself->pid);
}
void
ResourceLocks::Delete ()
{
if (inited)
{
thread_printf ("Close Resource Locks %p ", &lock);
DeleteCriticalSection (&lock);
inited = false;
}
}
// Thread interface
void
MTinterface::ReleaseItem (MTitem * _item)
{
_item->used = false;
}
MTitem *
MTinterface::Find (void *_value, int (*comp) (void *, void *), register int &_index, MTList * _list)
{
register MTitem *current = NULL;
for (; _index < _list->index; _index++)
{
current = _list->items[_index];
if (current->used && comp (current, _value))
break;
current = NULL;
}
return current;
}
int
MTinterface::Find (MTitem & _item, MTList * _list)
{
register MTitem *current;
register int _index = 0;
for (; _index < _list->index; _index++)
{
current = _list->items[_index];
if (current->used && current == &_item)
break;
}
return (_index == _list->index ? -1 : _index);
}
int
MTinterface::FindNextUnused (MTList * _list)
{
register int i = 0;
for (; i < _list->index && _list->items[i] != NULL && _list->items[i]->used && _list->items[i]->joinable != 'Y'; i++)
continue;
return i;
}
MTitem *
MTinterface::GetItem (int _index, MTList * _list)
{
return (_index < _list->index ? _list->items[_index] : NULL);
}
MTitem *
MTinterface::SetItem (int _index, MTitem * _item, MTList * _list)
{
if (_index == _list->index && _list->index < MT_MAX_ITEMS)
_list->index++;
return (_index < _list->index ? _list->items[_index] = _item : NULL);
}
int
CmpPthreadObj (void *_i, void *_value)
{
return ((MTitem *) _i)->Id () == *(int *) _value;
}
int
CmpThreadId (void *_i, void *_id)
{
return ((ThreadItem *) _i)->thread_id == * (DWORD *) _id;
}
void
MTinterface::Init (int forked)
{
#if 0
for (int i = 0; i < MT_MAX_ITEMS; i++)
{
threadlist.items[i] = NULL;
mutexlist.items[i] = NULL;
semalist.items[i] = NULL;
}
threadlist.index = 0;
mutexlist.index = 0;
semalist.index = 0;
#endif
reent_index = TlsAlloc ();
reents._clib = _impure_ptr;
reents._winsup = &winsup_reent;
winsup_reent._process_logmask = LOG_UPTO (LOG_DEBUG);
#if 0
winsup_reent._grp_pos = 0;
winsup_reent._process_ident = 0;
winsup_reent._process_logopt = 0;
winsup_reent._process_facility = 0;
#endif
TlsSetValue (reent_index, &reents);
// the static reent_data will be used in the main thread
if (forked)
return;
// create entry for main thread
ThreadItem *item = (ThreadItem *) GetItem (0, &threadlist);
item = (ThreadItem *) SetItem (0, &mainthread, &threadlist);
item->used = true;
item->win32_obj_id = myself->hProcess;
item->thread_id = GetCurrentThreadId ();
#if 0
item->function = NULL;
item->sigs = NULL;
item->sigmask = NULL;
item->sigtodo = NULL;
#endif
}
ThreadItem *
MTinterface::CreateThread (pthread_t * t, TFD (func), void *arg, pthread_attr_t a)
{
AssertResourceOwner (LOCK_THREAD_LIST, WRITE_LOCK | READ_LOCK);
int i = FindNextUnused (&threadlist);
ThreadItem *item = (ThreadItem *) GetItem (i, &threadlist);
if (!item)
item = (ThreadItem *) SetItem (i, new ThreadItem (), &threadlist);
if (!item)
system_printf ("thread creation failed");
item->used = true;
item->function = func;
item->arg = arg;
item->attr = a;
item->win32_obj_id = ::CreateThread (&sec_none_nih, item->attr.stacksize,
(LPTHREAD_START_ROUTINE) thread_init_wrapper, item, 0, &item->thread_id);
CHECKHANDLE (NULL, 1);
*t = (pthread_t) item->win32_obj_id;
return item;
}
MutexItem *
MTinterface::CreateMutex (pthread_mutex_t * mutex)
{
AssertResourceOwner (LOCK_MUTEX_LIST, WRITE_LOCK | READ_LOCK);
int i = FindNextUnused (&mutexlist);
MutexItem *item = (MutexItem *) GetItem (i, &mutexlist);
if (!item)
item = (MutexItem *) SetItem (i, new MutexItem (), &mutexlist);
if (!item)
system_printf ("mutex creation failed");
item->used = true;
item->win32_obj_id = ::CreateMutex (&sec_none_nih, false, NULL);
CHECKHANDLE (NULL, 1);
*mutex = (pthread_mutex_t) item->win32_obj_id;
return item;
}
ThreadItem *
MTinterface::GetCallingThread ()
{
AssertResourceOwner (LOCK_THREAD_LIST, READ_LOCK);
DWORD id = GetCurrentThreadId ();
int index = 0;
return (ThreadItem *) Find (&id, &CmpThreadId, index, &threadlist);
}
ThreadItem *
MTinterface::GetThread (pthread_t * _t)
{
AssertResourceOwner (LOCK_THREAD_LIST, READ_LOCK);
int index = 0;
return (ThreadItem *) Find (_t, &CmpPthreadObj, index, &threadlist);
}
MutexItem *
MTinterface::GetMutex (pthread_mutex_t * mp)
{
AssertResourceOwner (LOCK_MUTEX_LIST, READ_LOCK);
int index = 0;
return (MutexItem *) Find (mp, &CmpPthreadObj, index, &mutexlist);
}
SemaphoreItem *
MTinterface::GetSemaphore (sem_t * sp)
{
AssertResourceOwner (LOCK_SEM_LIST, READ_LOCK);
int index = 0;
return (SemaphoreItem *) Find (sp, &CmpPthreadObj, index, &semalist);
}
void
MTitem::Destroy ()
{
CloseHandle (win32_obj_id);
}
int
MutexItem::Lock ()
{
return WaitForSingleObject (win32_obj_id, INFINITE);
}
int
MutexItem::TryLock ()
{
return WaitForSingleObject (win32_obj_id, 0);
}
int
MutexItem::UnLock ()
{
return ReleaseMutex (win32_obj_id);
}
SemaphoreItem *
MTinterface::CreateSemaphore (sem_t * _s, int pshared, int _v)
{
AssertResourceOwner (LOCK_SEM_LIST, WRITE_LOCK | READ_LOCK);
int i = FindNextUnused (&semalist);
SemaphoreItem *item = (SemaphoreItem *) GetItem (i, &semalist);
if (!item)
item = (SemaphoreItem *) SetItem (i, new SemaphoreItem (), &semalist);
if (!item)
system_printf ("semaphore creation failed");
item->used = true;
item->shared = pshared;
item->win32_obj_id = ::CreateSemaphore (&sec_none_nih, _v, LONG_MAX, NULL);
CHECKHANDLE (NULL, 1);
*_s = (sem_t) item->win32_obj_id;
return item;
}
int
SemaphoreItem::Wait ()
{
return WaitForSingleObject (win32_obj_id, INFINITE);
}
int
SemaphoreItem::Post ()
{
long pc;
return ReleaseSemaphore (win32_obj_id, 1, &pc);
}
int
SemaphoreItem::TryWait ()
{
return WaitForSingleObject (win32_obj_id, 0);
}
////////////////////////// Pthreads
void *
thread_init_wrapper (void *_arg)
{
// Setup the local/global storage of this thread
ThreadItem *thread = (ThreadItem *) _arg;
struct __reent_t local_reent;
struct _winsup_t local_winsup;
struct _reent local_clib;
struct sigaction _sigs[NSIG];
sigset_t _sig_mask; /* one set for everything to ignore. */
LONG _sigtodo[NSIG + __SIGOFFSET];
// setup signal structures
thread->sigs = _sigs;
thread->sigmask = &_sig_mask;
thread->sigtodo = _sigtodo;
memset (&local_clib, 0, sizeof (struct _reent));
memset (&local_winsup, 0, sizeof (struct _winsup_t));
local_clib._errno = 0;
local_clib._stdin = &local_clib.__sf[0];
local_clib._stdout = &local_clib.__sf[1];
local_clib._stderr = &local_clib.__sf[2];
local_reent._clib = &local_clib;
local_reent._winsup = &local_winsup;
local_winsup._process_logmask = LOG_UPTO (LOG_DEBUG);
if (!TlsSetValue (MT_INTERFACE->reent_index, &local_reent))
system_printf ("local storage for thread couldn't be set");
#ifdef _CYG_THREAD_FAILSAFE
if (_REENT == _impure_ptr)
system_printf ("local storage for thread isn't setup correctly");
#endif
thread_printf ("started thread %p %p %p %p %p %p", _arg, &local_clib, _impure_ptr, thread, thread->function, thread->arg);
// call the user's thread
void *ret = thread->function (thread->arg);
// FIX ME : cleanup code
// thread->used = false; // release thread entry
thread->return_ptr = ret;
ExitThread (0);
}
int
__pthread_create (pthread_t * thread, const pthread_attr_t * attr, TFD (start_routine), void *arg)
{
SetResourceLock (LOCK_THREAD_LIST, WRITE_LOCK | READ_LOCK, "__pthread_create");
pthread_attr_t a;
ThreadItem *item;
if (attr)
item = MT_INTERFACE->CreateThread (thread, start_routine, arg, *attr);
else
{
__pthread_attr_init (&a);
item = MT_INTERFACE->CreateThread (thread, start_routine, arg, a);
}
CHECKITEM (LOCK_THREAD_LIST, WRITE_LOCK | READ_LOCK, "__pthread_create")
ReleaseResourceLock (LOCK_THREAD_LIST, WRITE_LOCK | READ_LOCK, "__pthread_create");
return 0;
}
int
__pthread_attr_init (pthread_attr_t * attr)
{
attr->stacksize = 0;
return 0;
}
int
__pthread_attr_setstacksize (pthread_attr_t * attr, size_t size)
{
attr->stacksize = size;
return 0;
}
int
__pthread_attr_getstacksize (pthread_attr_t * attr, size_t * size)
{
*size = attr->stacksize;
return 0;
}
int
__pthread_attr_destroy (pthread_attr_t * /*attr*/)
{
return 0;
}
int
__pthread_exit (void *value_ptr)
{
ThreadItem *item = MT_INTERFACE->GetCallingThread ();
item->return_ptr = value_ptr;
ExitThread (0);
return 0;
}
int
__pthread_join (pthread_t * thread, void **return_val)
{
ThreadItem *item=user_data->threadinterface->GetThread (thread);
if (!item)
return ESRCH;
if (item->joinable == 'N')
{
if (return_val)
*return_val = NULL;
return EINVAL;
}
else
{
item->joinable = 'N';
WaitForSingleObject ((HANDLE)*thread, INFINITE);
if (return_val)
*return_val = item->return_ptr;
}/* End if*/
return 0;
}
int
__pthread_detach (pthread_t * thread)
{
ThreadItem *item=user_data->threadinterface->GetThread (thread);
if (!item)
return ESRCH;
if (item->joinable == 'N')
{
item->return_ptr = NULL;
return EINVAL;
}
item->joinable = 'N';
return 0;
}
int
__pthread_suspend (pthread_t * thread)
{
ThreadItem *item=user_data->threadinterface->GetThread (thread);
if (!item)
return ESRCH;
if (item->suspended == false)
{
item->suspended = true;
SuspendThread ((HANDLE)*thread);
}
return 0;
}
int
__pthread_continue (pthread_t * thread)
{
ThreadItem *item=user_data->threadinterface->GetThread (thread);
if (!item)
return ESRCH;
if (item->suspended == true)
ResumeThread ((HANDLE)*thread);
item->suspended = false;
return 0;
}
unsigned long
__pthread_getsequence_np (pthread_t * thread)
{
GETTHREAD ("__pthread_getsequence_np");
return item->GetThreadId ();
}
/* Thread SpecificData */
int
__pthread_key_create (pthread_key_t */*key*/)
{
NOT_IMP ("_p_key_create\n");
}
int
__pthread_key_delete (pthread_key_t */*key*/)
{
NOT_IMP ("_p_key_delete\n");
}
int
__pthread_setspecific (pthread_key_t */*key*/, const void */*value*/)
{
NOT_IMP ("_p_key_setsp\n");
}
void *
__pthread_getspecific (pthread_key_t */*key*/)
{
NOT_IMP ("_p_key_getsp\n");
}
/* Thread signal */
int
__pthread_kill (pthread_t * thread, int sig)
{
// lock myself, for the use of thread2signal
// two differ kills might clash: FIX ME
GETTHREAD ("__pthread_kill");
if (item->sigs)
myself->setthread2signal (item);
int rval = _kill (myself->pid, sig);
// unlock myself
return rval;
}
int
__pthread_sigmask (int operation, const sigset_t * set, sigset_t * old_set)
{
SetResourceLock (LOCK_THREAD_LIST, READ_LOCK, "__pthread_sigmask");
ThreadItem *item = MT_INTERFACE->GetCallingThread ();
ReleaseResourceLock (LOCK_THREAD_LIST, READ_LOCK, "__pthread_sigmask");
// lock this myself, for the use of thread2signal
// two differt kills might clash: FIX ME
if (item->sigs)
myself->setthread2signal (item);
int rval = sigprocmask (operation, set, old_set);
// unlock this myself
return rval;
}
/* ID */
pthread_t
__pthread_self ()
{
SetResourceLock (LOCK_THREAD_LIST, READ_LOCK, "__pthread_self");
ThreadItem *item = MT_INTERFACE->GetCallingThread ();
ReleaseResourceLock (LOCK_THREAD_LIST, READ_LOCK, "__pthread_self");
return (pthread_t) item->Id ();
}
int
__pthread_equal (pthread_t * t1, pthread_t * t2)
{
return (*t1 - *t2);
}
/* Mutexes */
int
__pthread_mutex_init (pthread_mutex_t * mutex, const pthread_mutexattr_t */*_attr*/)
{
SetResourceLock (LOCK_MUTEX_LIST, WRITE_LOCK | READ_LOCK, "__pthread_mutex_init");
MutexItem *item = MT_INTERFACE->CreateMutex (mutex);
CHECKITEM (LOCK_MUTEX_LIST, WRITE_LOCK | READ_LOCK, "__pthread_mutex_init");
ReleaseResourceLock (LOCK_MUTEX_LIST, WRITE_LOCK | READ_LOCK, "__pthread_mutex_init");
return 0;
}
int
__pthread_mutex_lock (pthread_mutex_t * mutex)
{
GETMUTEX ("_ptherad_mutex_lock");
item->Lock ();
return 0;
}
int
__pthread_mutex_trylock (pthread_mutex_t * mutex)
{
GETMUTEX ("_ptherad_mutex_lock");
if (item->TryLock () == WAIT_TIMEOUT)
return EBUSY;
return 0;
}
int
__pthread_mutex_unlock (pthread_mutex_t * mutex)
{
GETMUTEX ("_ptherad_mutex_lock");
item->UnLock ();
return 0;
}
int
__pthread_mutex_destroy (pthread_mutex_t * mutex)
{
SetResourceLock (LOCK_MUTEX_LIST, READ_LOCK | WRITE_LOCK, "__pthread_mutex_destroy");
MutexItem *item = MT_INTERFACE->GetMutex (mutex);
CHECKITEM (LOCK_MUTEX_LIST, WRITE_LOCK | READ_LOCK, "__pthread_mutex_init");
item->Destroy ();
MT_INTERFACE->ReleaseItem (item);
ReleaseResourceLock (LOCK_MUTEX_LIST, READ_LOCK | WRITE_LOCK, "__pthread_mutex_destroy");
return 0;
}
/* Semaphores */
int
__sem_init (sem_t * sem, int pshared, unsigned int value)
{
SetResourceLock (LOCK_SEM_LIST, READ_LOCK | WRITE_LOCK, "__sem_init");
SemaphoreItem *item = MT_INTERFACE->CreateSemaphore (sem, pshared, value);
CHECKITEM (LOCK_SEM_LIST, READ_LOCK | WRITE_LOCK, "__sem_init");
ReleaseResourceLock (LOCK_SEM_LIST, READ_LOCK | WRITE_LOCK, "__sem_init");
return 0;
}
int
__sem_destroy (sem_t * sem)
{
SetResourceLock (LOCK_SEM_LIST, READ_LOCK | WRITE_LOCK, "__sem_destroy");
SemaphoreItem *item = MT_INTERFACE->GetSemaphore (sem);
CHECKITEM (LOCK_SEM_LIST, READ_LOCK | WRITE_LOCK, "__sem_init");
item->Destroy ();
MT_INTERFACE->ReleaseItem (item);
ReleaseResourceLock (LOCK_SEM_LIST, READ_LOCK | WRITE_LOCK, "__sem_destroy");
return 0;
}
int
__sem_wait (sem_t * sem)
{
GETSEMA ("__sem_wait");
item->Wait ();
return 0;
}
int
__sem_trywait (sem_t * sem)
{
GETSEMA ("__sem_trywait");
if (item->TryWait () == WAIT_TIMEOUT)
return EAGAIN;
return 0;
}
int
__sem_post (sem_t * sem)
{
GETSEMA ("__sem_post");
item->Post ();
return 0;
}
#else
// empty functions needed when makeing the dll without mt_safe support
extern "C"
{
int __pthread_create (pthread_t *, const pthread_attr_t *, TFD (start_routine), void *arg)
{
return -1;
}
int __pthread_attr_init (pthread_attr_t * attr)
{
return -1;
}
int __pthread_attr_destroy (pthread_attr_t * attr)
{
return -1;
}
int __pthread_attr_setstacksize (pthread_attr_t * attr, size_t size)
{
return -1;
}
int __pthread_attr_getstacksize (pthread_attr_t * attr, size_t * size)
{
return -1;
}
/*
__pthread_attr_setstackaddr (...){ return -1; };
__pthread_attr_getstackaddr (...){ return -1; };
*/
int __pthread_exit (void *value_ptr)
{
return -1;
}
int __pthread_join (pthread_t thread_id, void **return_val)
{
return -1;
}
unsigned long __pthread_getsequence_np (pthread_t * thread)
{
return 0;
}
int __pthread_key_create (pthread_key_t * key)
{
return -1;
}
int __pthread_key_delete (pthread_key_t * key)
{
return -1;
}
int __pthread_setspecific (pthread_key_t * key, const void *value)
{
return -1;
}
void *__pthread_getspecific (pthread_key_t * key)
{
return NULL;
}
int __pthread_kill (pthread_t * thread, int sig)
{
return -1;
}
int __pthread_sigmask (int operation, const sigset_t * set, sigset_t * old_set)
{
return -1;
}
pthread_t __pthread_self ()
{
return -1;
}
int __pthread_equal (pthread_t * t1, pthread_t * t2)
{
return -1;
}
int __pthread_mutex_init (pthread_mutex_t *, const pthread_mutexattr_t *)
{
return -1;
}
int __pthread_mutex_lock (pthread_mutex_t *)
{
return -1;
}
int __pthread_mutex_trylock (pthread_mutex_t *)
{
return -1;
}
int __pthread_mutex_unlock (pthread_mutex_t *)
{
return -1;
}
int __pthread_mutex_destroy (pthread_mutex_t *)
{
return -1;
}
int __sem_init (sem_t * sem, int pshared, unsigned int value)
{
return -1;
}
int __sem_destroy (sem_t * sem)
{
return -1;
}
int __sem_wait (sem_t * sem)
{
return -1;
}
int __sem_trywait (sem_t * sem)
{
return -1;
}
int __sem_post (sem_t * sem)
{
return -1;
}
struct _reent *_reent_clib ()
{
return NULL;
}
}
#endif // MT_SAFE