/* GLIB - Library of useful routines for C programming * Copyright (C) 1995-1997 Peter Mattis, Spencer Kimball and Josh MacDonald * * gthread.c: solaris thread system implementation * Copyright 1998-2001 Sebastian Wilhelmi; University of Karlsruhe * Copyright 2001 Hans Breuer * * This library is free software; you can redistribute it and/or * modify it under the terms of the GNU Lesser General Public * License as published by the Free Software Foundation; either * version 2 of the License, or (at your option) any later version. * * This library is distributed in the hope that it will be useful, * but WITHOUT ANY WARRANTY; without even the implied warranty of * MERCHANTABILITY or FITNESS FOR A PARTICULAR PURPOSE. See the GNU * Lesser General Public License for more details. * * You should have received a copy of the GNU Lesser General Public * License along with this library; if not, write to the * Free Software Foundation, Inc., 59 Temple Place - Suite 330, * Boston, MA 02111-1307, USA. */ /* * Modified by the GLib Team and others 1997-2000. See the AUTHORS * file for a list of people on the GLib Team. See the ChangeLog * files for a list of changes. These files are distributed with * GLib at ftp://ftp.gtk.org/pub/gtk/. */ /* * MT safe */ #ifdef HAVE_CONFIG_H #include #endif #include #define STRICT #include #undef STRICT #include #include #define win32_check_for_error(what) G_STMT_START{ \ if (!(what)) \ g_error ("file %s: line %d (%s): error %s during %s", \ __FILE__, __LINE__, G_GNUC_PRETTY_FUNCTION, \ g_win32_error_message (GetLastError ()), #what); \ }G_STMT_END #define G_MUTEX_SIZE (sizeof (gpointer)) #define PRIORITY_LOW_VALUE THREAD_PRIORITY_BELOW_NORMAL #define PRIORITY_NORMAL_VALUE THREAD_PRIORITY_NORMAL #define PRIORITY_HIGH_VALUE THREAD_PRIORITY_ABOVE_NORMAL #define PRIORITY_URGENT_VALUE THREAD_PRIORITY_HIGHEST static DWORD g_thread_self_tls; static DWORD g_private_tls; static DWORD g_cond_event_tls; static CRITICAL_SECTION g_thread_global_spinlock; typedef BOOL (__stdcall *GTryEnterCriticalSectionFunc) (CRITICAL_SECTION *); static GTryEnterCriticalSectionFunc try_enter_critical_section = NULL; /* As noted in the docs, GPrivate is a limited resource, here we take * a rather low maximum to save memory, use GStaticPrivate instead. */ #define G_PRIVATE_MAX 16 static GDestroyNotify g_private_destructors[G_PRIVATE_MAX]; static guint g_private_next = 0; typedef struct _GThreadData GThreadData; struct _GThreadData { GThreadFunc func; gpointer data; HANDLE thread; gboolean joinable; }; struct _GCond { GPtrArray *array; CRITICAL_SECTION lock; }; static GMutex * g_mutex_new_win32_cs_impl (void) { CRITICAL_SECTION *cs = g_new (CRITICAL_SECTION, 1); gpointer *retval = g_new (gpointer, 1); InitializeCriticalSection (cs); *retval = cs; return (GMutex *) retval; } static void g_mutex_free_win32_cs_impl (GMutex *mutex) { gpointer *ptr = (gpointer *) mutex; CRITICAL_SECTION *cs = (CRITICAL_SECTION *) *ptr; DeleteCriticalSection (cs); g_free (cs); g_free (mutex); } /* NOTE: the functions g_mutex_lock and g_mutex_unlock may not use functions from gmem.c and gmessages.c; */ static void g_mutex_lock_win32_cs_impl (GMutex *mutex) { EnterCriticalSection (*(CRITICAL_SECTION **)mutex); } static gboolean g_mutex_trylock_win32_cs_impl (GMutex * mutex) { return try_enter_critical_section (*(CRITICAL_SECTION **)mutex); } static void g_mutex_unlock_win32_cs_impl (GMutex *mutex) { LeaveCriticalSection (*(CRITICAL_SECTION **)mutex); } static GMutex * g_mutex_new_win32_impl (void) { HANDLE handle; HANDLE *retval; win32_check_for_error (handle = CreateMutex (NULL, FALSE, NULL)); retval = g_new (HANDLE, 1); *retval = handle; return (GMutex *) retval; } static void g_mutex_free_win32_impl (GMutex *mutex) { win32_check_for_error (CloseHandle (*(HANDLE *) mutex)); g_free (mutex); } /* NOTE: the functions g_mutex_lock and g_mutex_unlock may not use functions from gmem.c and gmessages.c; */ static void g_mutex_lock_win32_impl (GMutex *mutex) { WaitForSingleObject (*(HANDLE *) mutex, INFINITE); } static gboolean g_mutex_trylock_win32_impl (GMutex * mutex) { DWORD result; win32_check_for_error (WAIT_FAILED != (result = WaitForSingleObject (*(HANDLE *)mutex, 0))); return result != WAIT_TIMEOUT; } static void g_mutex_unlock_win32_impl (GMutex *mutex) { ReleaseMutex (*(HANDLE *) mutex); } static GCond * g_cond_new_win32_impl (void) { GCond *retval = g_new (GCond, 1); retval->array = g_ptr_array_new (); InitializeCriticalSection (&retval->lock); return retval; } static void g_cond_signal_win32_impl (GCond * cond) { EnterCriticalSection (&cond->lock); if (cond->array->len > 0) { SetEvent (g_ptr_array_index (cond->array, 0)); g_ptr_array_remove_index (cond->array, 0); } LeaveCriticalSection (&cond->lock); } static void g_cond_broadcast_win32_impl (GCond * cond) { guint i; EnterCriticalSection (&cond->lock); for (i = 0; i < cond->array->len; i++) SetEvent (g_ptr_array_index (cond->array, i)); g_ptr_array_set_size (cond->array, 0); LeaveCriticalSection (&cond->lock); } static gboolean g_cond_wait_internal (GCond *cond, GMutex *entered_mutex, gulong milliseconds) { gulong retval; HANDLE event = TlsGetValue (g_cond_event_tls); if (!event) { win32_check_for_error (event = CreateEvent (0, FALSE, FALSE, NULL)); TlsSetValue (g_cond_event_tls, event); } EnterCriticalSection (&cond->lock); /* The event must not be signaled. Check this */ g_assert (WaitForSingleObject (event, 0) == WAIT_TIMEOUT); g_ptr_array_add (cond->array, event); LeaveCriticalSection (&cond->lock); g_mutex_unlock (entered_mutex); win32_check_for_error (WAIT_FAILED != (retval = WaitForSingleObject (event, milliseconds))); g_mutex_lock (entered_mutex); if (retval == WAIT_TIMEOUT) { EnterCriticalSection (&cond->lock); g_ptr_array_remove (cond->array, event); /* In the meantime we could have been signaled, so we must again * wait for the signal, this time with no timeout, to reset * it. retval is set again to honour the late arrival of the * signal */ win32_check_for_error (WAIT_FAILED != (retval = WaitForSingleObject (event, 0))); LeaveCriticalSection (&cond->lock); } #ifndef G_DISABLE_ASSERT EnterCriticalSection (&cond->lock); /* Now event must not be inside the array, check this */ g_assert (g_ptr_array_remove (cond->array, event) == FALSE); LeaveCriticalSection (&cond->lock); #endif /* !G_DISABLE_ASSERT */ return retval != WAIT_TIMEOUT; } static void g_cond_wait_win32_impl (GCond *cond, GMutex *entered_mutex) { g_return_if_fail (cond != NULL); g_return_if_fail (entered_mutex != NULL); g_cond_wait_internal (cond, entered_mutex, INFINITE); } static gboolean g_cond_timed_wait_win32_impl (GCond *cond, GMutex *entered_mutex, GTimeVal *abs_time) { GTimeVal current_time; gulong to_wait; g_return_val_if_fail (cond != NULL, FALSE); g_return_val_if_fail (entered_mutex != NULL, FALSE); g_get_current_time (¤t_time); to_wait = (abs_time->tv_sec - current_time.tv_sec) * 1000 + (abs_time->tv_usec - current_time.tv_usec) / 1000; return g_cond_wait_internal (cond, entered_mutex, to_wait); } static void g_cond_free_win32_impl (GCond * cond) { DeleteCriticalSection (&cond->lock); g_ptr_array_free (cond->array, TRUE); g_free (cond); } static GPrivate * g_private_new_win32_impl (GDestroyNotify destructor) { GPrivate *result; EnterCriticalSection (&g_thread_global_spinlock); if (g_private_next >= G_PRIVATE_MAX) g_error ("Too many GPrivate allocated. Their number is limited to %d.\n" "Use GStaticPrivate instead.\n", G_PRIVATE_MAX); g_private_destructors[g_private_next] = destructor; result = GUINT_TO_POINTER (g_private_next); g_private_next++; LeaveCriticalSection (&g_thread_global_spinlock); return result; } /* NOTE: the functions g_private_get and g_private_set may not use functions from gmem.c and gmessages.c */ static void g_private_set_win32_impl (GPrivate * private_key, gpointer value) { gpointer* array = TlsGetValue (g_private_tls); guint index = GPOINTER_TO_UINT (private_key); if (index >= G_PRIVATE_MAX) return; if (!array) { array = (gpointer*) calloc (G_PRIVATE_MAX, sizeof (gpointer)); TlsSetValue (g_private_tls, array); } array[index] = value; } static gpointer g_private_get_win32_impl (GPrivate * private_key) { gpointer* array = TlsGetValue (g_private_tls); guint index = GPOINTER_TO_UINT (private_key); if (index >= G_PRIVATE_MAX || !array) return NULL; return array[index]; } static void g_thread_set_priority_win32_impl (gpointer thread, GThreadPriority priority) { GThreadData *target = *(GThreadData **)thread; g_return_if_fail (priority >= G_THREAD_PRIORITY_LOW); g_return_if_fail (priority <= G_THREAD_PRIORITY_URGENT); win32_check_for_error (SetThreadPriority (target->thread, g_thread_priority_map [priority])); } static void g_thread_self_win32_impl (gpointer thread) { GThreadData *self = TlsGetValue (g_thread_self_tls); if (!self) { /* This should only happen for the main thread! */ HANDLE handle = GetCurrentThread (); HANDLE process = GetCurrentProcess (); self = g_new (GThreadData, 1); win32_check_for_error (DuplicateHandle (process, handle, process, &self->thread, 0, FALSE, DUPLICATE_SAME_ACCESS)); win32_check_for_error (TlsSetValue (g_thread_self_tls, self)); self->func = NULL; self->data = NULL; self->joinable = FALSE; } *(GThreadData **)thread = self; } static void g_thread_exit_win32_impl (void) { GThreadData *self = TlsGetValue (g_thread_self_tls); guint i, private_max; gpointer *array = TlsGetValue (g_private_tls); HANDLE event = TlsGetValue (g_cond_event_tls); EnterCriticalSection (&g_thread_global_spinlock); private_max = g_private_next; LeaveCriticalSection (&g_thread_global_spinlock); if (array) { for (i = 0; i < private_max; i++) { GDestroyNotify destructor = g_private_destructors[i]; GDestroyNotify data = array[i]; if (destructor && data) destructor (data); } g_free (array); win32_check_for_error (TlsSetValue (g_private_tls, NULL)); } if (self) { if (!self->joinable) { win32_check_for_error (CloseHandle (self->thread)); g_free (self); } win32_check_for_error (TlsSetValue (g_thread_self_tls, NULL)); } if (event) { CloseHandle (event); win32_check_for_error (TlsSetValue (g_cond_event_tls, NULL)); } _endthreadex (0); } static guint __stdcall g_thread_proxy (gpointer data) { GThreadData *self = (GThreadData*) data; win32_check_for_error (TlsSetValue (g_thread_self_tls, self)); self->func (self->data); g_thread_exit_win32_impl (); g_assert_not_reached (); return 0; } static void g_thread_create_win32_impl (GThreadFunc func, gpointer data, gulong stack_size, gboolean joinable, gboolean bound, GThreadPriority priority, gpointer thread, GError **error) { guint ignore; GThreadData *retval; g_return_if_fail (func); g_return_if_fail (priority >= G_THREAD_PRIORITY_LOW); g_return_if_fail (priority <= G_THREAD_PRIORITY_URGENT); retval = g_new(GThreadData, 1); retval->func = func; retval->data = data; retval->joinable = joinable; retval->thread = (HANDLE) _beginthreadex (NULL, stack_size, g_thread_proxy, retval, 0, &ignore); if (retval->thread == NULL) { gchar *win_error = g_win32_error_message (GetLastError ()); g_set_error (error, G_THREAD_ERROR, G_THREAD_ERROR_AGAIN, "Error creating thread: %s", win_error); g_free (retval); g_free (win_error); return; } *(GThreadData **)thread = retval; g_thread_set_priority_win32_impl (thread, priority); } static void g_thread_yield_win32_impl (void) { Sleep(0); } static void g_thread_join_win32_impl (gpointer thread) { GThreadData *target = *(GThreadData **)thread; g_return_if_fail (target->joinable); win32_check_for_error (WAIT_FAILED != WaitForSingleObject (target->thread, INFINITE)); win32_check_for_error (CloseHandle (target->thread)); g_free (target); } static GThreadFunctions g_thread_functions_for_glib_use_default = { g_mutex_new_win32_impl, /* mutex */ g_mutex_lock_win32_impl, g_mutex_trylock_win32_impl, g_mutex_unlock_win32_impl, g_mutex_free_win32_impl, g_cond_new_win32_impl, /* condition */ g_cond_signal_win32_impl, g_cond_broadcast_win32_impl, g_cond_wait_win32_impl, g_cond_timed_wait_win32_impl, g_cond_free_win32_impl, g_private_new_win32_impl, /* private thread data */ g_private_get_win32_impl, g_private_set_win32_impl, g_thread_create_win32_impl, /* thread */ g_thread_yield_win32_impl, g_thread_join_win32_impl, g_thread_exit_win32_impl, g_thread_set_priority_win32_impl, g_thread_self_win32_impl, NULL /* no equal function necessary */ }; #define HAVE_G_THREAD_IMPL_INIT static void g_thread_impl_init () { static gboolean beenhere = FALSE; HMODULE kernel32; if (beenhere) return; beenhere = TRUE; win32_check_for_error (TLS_OUT_OF_INDEXES != (g_thread_self_tls = TlsAlloc ())); win32_check_for_error (TLS_OUT_OF_INDEXES != (g_private_tls = TlsAlloc ())); win32_check_for_error (TLS_OUT_OF_INDEXES != (g_cond_event_tls = TlsAlloc ())); InitializeCriticalSection (&g_thread_global_spinlock); /* Here we are looking for TryEnterCriticalSection in KERNEL32.DLL, * if it is found, we can use the faster critical sections instead * of mutexes. Note however that * http://www2.awl.com/cseng/titles/0-201-63465-1/csmutx.htm indicates, * that critical sections might not be ideal after all on SMP machines */ kernel32 = GetModuleHandle ("KERNEL32.DLL"); if (kernel32) { try_enter_critical_section = (GTryEnterCriticalSectionFunc) GetProcAddress(kernel32, "TryEnterCriticalSection"); /* Even if TryEnterCriticalSection is found, it is not * necessarily working..., we have to check it */ if (try_enter_critical_section && try_enter_critical_section (&g_thread_global_spinlock)) { LeaveCriticalSection (&g_thread_global_spinlock); g_thread_functions_for_glib_use_default.mutex_new = g_mutex_new_win32_cs_impl; g_thread_functions_for_glib_use_default.mutex_lock = g_mutex_lock_win32_cs_impl; g_thread_functions_for_glib_use_default.mutex_trylock = g_mutex_trylock_win32_cs_impl; g_thread_functions_for_glib_use_default.mutex_unlock = g_mutex_unlock_win32_cs_impl; g_thread_functions_for_glib_use_default.mutex_free = g_mutex_free_win32_cs_impl; } } }