/* * metadata/gc.c: GC icalls. * * Author: Paolo Molaro * * Copyright 2002-2003 Ximian, Inc (http://www.ximian.com) * Copyright 2004-2009 Novell, Inc (http://www.novell.com) * Copyright 2012 Xamarin Inc (http://www.xamarin.com) */ #include #include #include #include #include #include #include #include #include #include #include #include #include #include #include #include #include #include #include #include #include /* for mono_delegate_free_ftnptr () */ #include #include #include #include #include #include #include #include #ifndef HOST_WIN32 #include #endif typedef struct DomainFinalizationReq { MonoDomain *domain; HANDLE done_event; } DomainFinalizationReq; #ifdef PLATFORM_WINCE /* FIXME: add accessors to gc.dll API */ extern void (*__imp_GC_finalizer_notifier)(void); #define GC_finalizer_notifier __imp_GC_finalizer_notifier extern int __imp_GC_finalize_on_demand; #define GC_finalize_on_demand __imp_GC_finalize_on_demand #endif static gboolean gc_disabled = FALSE; static gboolean finalizing_root_domain = FALSE; #define mono_finalizer_lock() mono_mutex_lock (&finalizer_mutex) #define mono_finalizer_unlock() mono_mutex_unlock (&finalizer_mutex) static mono_mutex_t finalizer_mutex; static mono_mutex_t reference_queue_mutex; static GSList *domains_to_finalize= NULL; static MonoMList *threads_to_finalize = NULL; static MonoInternalThread *gc_thread; static void object_register_finalizer (MonoObject *obj, void (*callback)(void *, void*)); static void mono_gchandle_set_target (guint32 gchandle, MonoObject *obj); static void reference_queue_proccess_all (void); static void mono_reference_queue_cleanup (void); static void reference_queue_clear_for_domain (MonoDomain *domain); #ifndef HAVE_NULL_GC static HANDLE pending_done_event; static HANDLE shutdown_event; #endif GCStats gc_stats; static void add_thread_to_finalize (MonoInternalThread *thread) { mono_finalizer_lock (); if (!threads_to_finalize) MONO_GC_REGISTER_ROOT_SINGLE (threads_to_finalize); threads_to_finalize = mono_mlist_append (threads_to_finalize, (MonoObject*)thread); mono_finalizer_unlock (); } static gboolean suspend_finalizers = FALSE; /* * actually, we might want to queue the finalize requests in a separate thread, * but we need to be careful about the execution domain of the thread... */ void mono_gc_run_finalize (void *obj, void *data) { MonoObject *exc = NULL; MonoObject *o; #ifndef HAVE_SGEN_GC MonoObject *o2; #endif MonoMethod* finalizer = NULL; MonoDomain *caller_domain = mono_domain_get (); MonoDomain *domain; RuntimeInvokeFunction runtime_invoke; o = (MonoObject*)((char*)obj + GPOINTER_TO_UINT (data)); if (suspend_finalizers) return; domain = o->vtable->domain; #ifndef HAVE_SGEN_GC mono_domain_finalizers_lock (domain); o2 = g_hash_table_lookup (domain->finalizable_objects_hash, o); mono_domain_finalizers_unlock (domain); if (!o2) /* Already finalized somehow */ return; #endif /* make sure the finalizer is not called again if the object is resurrected */ object_register_finalizer (obj, NULL); if (o->vtable->klass == mono_defaults.internal_thread_class) { MonoInternalThread *t = (MonoInternalThread*)o; if (mono_gc_is_finalizer_internal_thread (t)) /* Avoid finalizing ourselves */ return; if (t->threadpool_thread && finalizing_root_domain) { /* Don't finalize threadpool threads when shutting down - they're finalized when the threadpool shuts down. */ add_thread_to_finalize (t); return; } } if (o->vtable->klass->image == mono_defaults.corlib && !strcmp (o->vtable->klass->name, "DynamicMethod") && finalizing_root_domain) { /* * These can't be finalized during unloading/shutdown, since that would * free the native code which can still be referenced by other * finalizers. * FIXME: This is not perfect, objects dying at the same time as * dynamic methods can still reference them even when !shutdown. */ return; } if (mono_runtime_get_no_exec ()) return; /* speedup later... and use a timeout */ /* g_print ("Finalize run on %p %s.%s\n", o, mono_object_class (o)->name_space, mono_object_class (o)->name); */ /* Use _internal here, since this thread can enter a doomed appdomain */ mono_domain_set_internal (mono_object_domain (o)); /* delegates that have a native function pointer allocated are * registered for finalization, but they don't have a Finalize * method, because in most cases it's not needed and it's just a waste. */ if (o->vtable->klass->delegate) { MonoDelegate* del = (MonoDelegate*)o; if (del->delegate_trampoline) mono_delegate_free_ftnptr ((MonoDelegate*)o); mono_domain_set_internal (caller_domain); return; } finalizer = mono_class_get_finalizer (o->vtable->klass); #ifndef DISABLE_COM /* If object has a CCW but has no finalizer, it was only * registered for finalization in order to free the CCW. * Else it needs the regular finalizer run. * FIXME: what to do about ressurection and suppression * of finalizer on object with CCW. */ if (mono_marshal_free_ccw (o) && !finalizer) { mono_domain_set_internal (caller_domain); return; } #endif /* * To avoid the locking plus the other overhead of mono_runtime_invoke (), * create and precompile a wrapper which calls the finalize method using * a CALLVIRT. */ if (!domain->finalize_runtime_invoke) { MonoMethod *invoke = mono_marshal_get_runtime_invoke (mono_class_get_method_from_name_flags (mono_defaults.object_class, "Finalize", 0, 0), TRUE); domain->finalize_runtime_invoke = mono_compile_method (invoke); } runtime_invoke = domain->finalize_runtime_invoke; mono_runtime_class_init (o->vtable); if (G_UNLIKELY (MONO_GC_FINALIZE_INVOKE_ENABLED ())) { MONO_GC_FINALIZE_INVOKE ((unsigned long)o, mono_object_get_size (o), o->vtable->klass->name_space, o->vtable->klass->name); } runtime_invoke (o, NULL, &exc, NULL); if (exc) mono_internal_thread_unhandled_exception (exc); mono_domain_set_internal (caller_domain); } void mono_gc_finalize_threadpool_threads (void) { while (threads_to_finalize) { MonoInternalThread *thread = (MonoInternalThread*) mono_mlist_get_data (threads_to_finalize); /* Force finalization of the thread. */ thread->threadpool_thread = FALSE; mono_object_register_finalizer ((MonoObject*)thread); mono_gc_run_finalize (thread, NULL); threads_to_finalize = mono_mlist_next (threads_to_finalize); } } gpointer mono_gc_out_of_memory (size_t size) { /* * we could allocate at program startup some memory that we could release * back to the system at this point if we're really low on memory (ie, size is * lower than the memory we set apart) */ mono_raise_exception (mono_domain_get ()->out_of_memory_ex); return NULL; } /* * Some of our objects may point to a different address than the address returned by GC_malloc() * (because of the GetHashCode hack), but we need to pass the real address to register_finalizer. * This also means that in the callback we need to adjust the pointer to get back the real * MonoObject*. * We also need to be consistent in the use of the GC_debug* variants of malloc and register_finalizer, * since that, too, can cause the underlying pointer to be offset. */ static void object_register_finalizer (MonoObject *obj, void (*callback)(void *, void*)) { MonoDomain *domain; if (obj == NULL) mono_raise_exception (mono_get_exception_argument_null ("obj")); domain = obj->vtable->domain; #if HAVE_BOEHM_GC if (mono_domain_is_unloading (domain) && (callback != NULL)) /* * Can't register finalizers in a dying appdomain, since they * could be invoked after the appdomain has been unloaded. */ return; mono_domain_finalizers_lock (domain); if (callback) g_hash_table_insert (domain->finalizable_objects_hash, obj, obj); else g_hash_table_remove (domain->finalizable_objects_hash, obj); mono_domain_finalizers_unlock (domain); mono_gc_register_for_finalization (obj, callback); #elif defined(HAVE_SGEN_GC) /* * If we register finalizers for domains that are unloading we might * end up running them while or after the domain is being cleared, so * the objects will not be valid anymore. */ if (!mono_domain_is_unloading (domain)) mono_gc_register_for_finalization (obj, callback); #endif } /** * mono_object_register_finalizer: * @obj: object to register * * Records that object @obj has a finalizer, this will call the * Finalize method when the garbage collector disposes the object. * */ void mono_object_register_finalizer (MonoObject *obj) { /* g_print ("Registered finalizer on %p %s.%s\n", obj, mono_object_class (obj)->name_space, mono_object_class (obj)->name); */ object_register_finalizer (obj, mono_gc_run_finalize); } /** * mono_domain_finalize: * @domain: the domain to finalize * @timeout: msects to wait for the finalization to complete, -1 to wait indefinitely * * Request finalization of all finalizable objects inside @domain. Wait * @timeout msecs for the finalization to complete. * * Returns: TRUE if succeeded, FALSE if there was a timeout */ gboolean mono_domain_finalize (MonoDomain *domain, guint32 timeout) { DomainFinalizationReq *req; guint32 res; HANDLE done_event; MonoInternalThread *thread = mono_thread_internal_current (); #if defined(__native_client__) return FALSE; #endif if (mono_thread_internal_current () == gc_thread) /* We are called from inside a finalizer, not much we can do here */ return FALSE; /* * No need to create another thread 'cause the finalizer thread * is still working and will take care of running the finalizers */ #ifndef HAVE_NULL_GC if (gc_disabled) return TRUE; mono_gc_collect (mono_gc_max_generation ()); done_event = CreateEvent (NULL, TRUE, FALSE, NULL); if (done_event == NULL) { return FALSE; } req = g_new0 (DomainFinalizationReq, 1); req->domain = domain; req->done_event = done_event; if (domain == mono_get_root_domain ()) finalizing_root_domain = TRUE; mono_finalizer_lock (); domains_to_finalize = g_slist_append (domains_to_finalize, req); mono_finalizer_unlock (); /* Tell the finalizer thread to finalize this appdomain */ mono_gc_finalize_notify (); if (timeout == -1) timeout = INFINITE; while (TRUE) { res = WaitForSingleObjectEx (done_event, timeout, TRUE); /* printf ("WAIT RES: %d.\n", res); */ if (res == WAIT_IO_COMPLETION) { if ((thread->state & (ThreadState_StopRequested | ThreadState_SuspendRequested)) != 0) return FALSE; } else if (res == WAIT_TIMEOUT) { /* We leak the handle here */ return FALSE; } else { break; } } CloseHandle (done_event); if (domain == mono_get_root_domain ()) { mono_thread_pool_cleanup (); mono_gc_finalize_threadpool_threads (); } return TRUE; #else /* We don't support domain finalization without a GC */ return FALSE; #endif } void ves_icall_System_GC_InternalCollect (int generation) { mono_gc_collect (generation); } gint64 ves_icall_System_GC_GetTotalMemory (MonoBoolean forceCollection) { MONO_ARCH_SAVE_REGS; if (forceCollection) mono_gc_collect (mono_gc_max_generation ()); return mono_gc_get_used_size (); } void ves_icall_System_GC_KeepAlive (MonoObject *obj) { MONO_ARCH_SAVE_REGS; /* * Does nothing. */ } void ves_icall_System_GC_ReRegisterForFinalize (MonoObject *obj) { if (!obj) mono_raise_exception (mono_get_exception_argument_null ("obj")); object_register_finalizer (obj, mono_gc_run_finalize); } void ves_icall_System_GC_SuppressFinalize (MonoObject *obj) { if (!obj) mono_raise_exception (mono_get_exception_argument_null ("obj")); /* delegates have no finalizers, but we register them to deal with the * unmanaged->managed trampoline. We don't let the user suppress it * otherwise we'd leak it. */ if (obj->vtable->klass->delegate) return; /* FIXME: Need to handle case where obj has COM Callable Wrapper * generated for it that needs cleaned up, but user wants to suppress * their derived object finalizer. */ object_register_finalizer (obj, NULL); } void ves_icall_System_GC_WaitForPendingFinalizers (void) { #ifndef HAVE_NULL_GC if (!mono_gc_pending_finalizers ()) return; if (mono_thread_internal_current () == gc_thread) /* Avoid deadlocks */ return; /* If the finalizer thread is not live, lets pretend no finalizers are pending since the current thread might be the one responsible for starting it up. */ if (gc_thread == NULL) return; ResetEvent (pending_done_event); mono_gc_finalize_notify (); /* g_print ("Waiting for pending finalizers....\n"); */ WaitForSingleObjectEx (pending_done_event, INFINITE, TRUE); /* g_print ("Done pending....\n"); */ #endif } void ves_icall_System_GC_register_ephemeron_array (MonoObject *array) { #ifdef HAVE_SGEN_GC if (!mono_gc_ephemeron_array_add (array)) mono_raise_exception (mono_object_domain (array)->out_of_memory_ex); #endif } MonoObject* ves_icall_System_GC_get_ephemeron_tombstone (void) { return mono_domain_get ()->ephemeron_tombstone; } #define mono_allocator_lock() mono_mutex_lock (&allocator_section) #define mono_allocator_unlock() mono_mutex_unlock (&allocator_section) static mono_mutex_t allocator_section; static mono_mutex_t handle_section; typedef enum { HANDLE_WEAK, HANDLE_WEAK_TRACK, HANDLE_NORMAL, HANDLE_PINNED } HandleType; static HandleType mono_gchandle_get_type (guint32 gchandle); MonoObject * ves_icall_System_GCHandle_GetTarget (guint32 handle) { return mono_gchandle_get_target (handle); } /* * if type == -1, change the target of the handle, otherwise allocate a new handle. */ guint32 ves_icall_System_GCHandle_GetTargetHandle (MonoObject *obj, guint32 handle, gint32 type) { if (type == -1) { mono_gchandle_set_target (handle, obj); /* the handle doesn't change */ return handle; } switch (type) { case HANDLE_WEAK: return mono_gchandle_new_weakref (obj, FALSE); case HANDLE_WEAK_TRACK: return mono_gchandle_new_weakref (obj, TRUE); case HANDLE_NORMAL: return mono_gchandle_new (obj, FALSE); case HANDLE_PINNED: return mono_gchandle_new (obj, TRUE); default: g_assert_not_reached (); } return 0; } void ves_icall_System_GCHandle_FreeHandle (guint32 handle) { mono_gchandle_free (handle); } gpointer ves_icall_System_GCHandle_GetAddrOfPinnedObject (guint32 handle) { MonoObject *obj; if (mono_gchandle_get_type (handle) != HANDLE_PINNED) return (gpointer)-2; obj = mono_gchandle_get_target (handle); if (obj) { MonoClass *klass = mono_object_class (obj); if (klass == mono_defaults.string_class) { return mono_string_chars ((MonoString*)obj); } else if (klass->rank) { return mono_array_addr ((MonoArray*)obj, char, 0); } else { /* the C# code will check and throw the exception */ /* FIXME: missing !klass->blittable test, see bug #61134 */ if ((klass->flags & TYPE_ATTRIBUTE_LAYOUT_MASK) == TYPE_ATTRIBUTE_AUTO_LAYOUT) return (gpointer)-1; return (char*)obj + sizeof (MonoObject); } } return NULL; } MonoBoolean ves_icall_Mono_Runtime_SetGCAllowSynchronousMajor (MonoBoolean flag) { return mono_gc_set_allow_synchronous_major (flag); } typedef struct { guint32 *bitmap; gpointer *entries; guint32 size; guint8 type; guint slot_hint : 24; /* starting slot for search */ /* 2^16 appdomains should be enough for everyone (though I know I'll regret this in 20 years) */ /* we alloc this only for weak refs, since we can get the domain directly in the other cases */ guint16 *domain_ids; } HandleData; /* weak and weak-track arrays will be allocated in malloc memory */ static HandleData gc_handles [] = { {NULL, NULL, 0, HANDLE_WEAK, 0}, {NULL, NULL, 0, HANDLE_WEAK_TRACK, 0}, {NULL, NULL, 0, HANDLE_NORMAL, 0}, {NULL, NULL, 0, HANDLE_PINNED, 0} }; #define lock_handles(handles) mono_mutex_lock (&handle_section) #define unlock_handles(handles) mono_mutex_unlock (&handle_section) static int find_first_unset (guint32 bitmap) { int i; for (i = 0; i < 32; ++i) { if (!(bitmap & (1 << i))) return i; } return -1; } static void* make_root_descr_all_refs (int numbits, gboolean pinned) { #ifdef HAVE_SGEN_GC if (pinned) return NULL; #endif return mono_gc_make_root_descr_all_refs (numbits); } static guint32 alloc_handle (HandleData *handles, MonoObject *obj, gboolean track) { gint slot, i; guint32 res; lock_handles (handles); if (!handles->size) { handles->size = 32; if (handles->type > HANDLE_WEAK_TRACK) { handles->entries = mono_gc_alloc_fixed (sizeof (gpointer) * handles->size, make_root_descr_all_refs (handles->size, handles->type == HANDLE_PINNED)); } else { handles->entries = g_malloc0 (sizeof (gpointer) * handles->size); handles->domain_ids = g_malloc0 (sizeof (guint16) * handles->size); } handles->bitmap = g_malloc0 (handles->size / 8); } i = -1; for (slot = handles->slot_hint; slot < handles->size / 32; ++slot) { if (handles->bitmap [slot] != 0xffffffff) { i = find_first_unset (handles->bitmap [slot]); handles->slot_hint = slot; break; } } if (i == -1 && handles->slot_hint != 0) { for (slot = 0; slot < handles->slot_hint; ++slot) { if (handles->bitmap [slot] != 0xffffffff) { i = find_first_unset (handles->bitmap [slot]); handles->slot_hint = slot; break; } } } if (i == -1) { guint32 *new_bitmap; guint32 new_size = handles->size * 2; /* always double: we memset to 0 based on this below */ /* resize and copy the bitmap */ new_bitmap = g_malloc0 (new_size / 8); memcpy (new_bitmap, handles->bitmap, handles->size / 8); g_free (handles->bitmap); handles->bitmap = new_bitmap; /* resize and copy the entries */ if (handles->type > HANDLE_WEAK_TRACK) { gpointer *entries; entries = mono_gc_alloc_fixed (sizeof (gpointer) * new_size, make_root_descr_all_refs (new_size, handles->type == HANDLE_PINNED)); mono_gc_memmove_aligned (entries, handles->entries, sizeof (gpointer) * handles->size); mono_gc_free_fixed (handles->entries); handles->entries = entries; } else { gpointer *entries; guint16 *domain_ids; domain_ids = g_malloc0 (sizeof (guint16) * new_size); entries = g_malloc0 (sizeof (gpointer) * new_size); memcpy (domain_ids, handles->domain_ids, sizeof (guint16) * handles->size); for (i = 0; i < handles->size; ++i) { MonoObject *obj = mono_gc_weak_link_get (&(handles->entries [i])); if (obj) { mono_gc_weak_link_add (&(entries [i]), obj, track); mono_gc_weak_link_remove (&(handles->entries [i]), track); } else { g_assert (!handles->entries [i]); } } g_free (handles->entries); g_free (handles->domain_ids); handles->entries = entries; handles->domain_ids = domain_ids; } /* set i and slot to the next free position */ i = 0; slot = (handles->size + 1) / 32; handles->slot_hint = handles->size + 1; handles->size = new_size; } handles->bitmap [slot] |= 1 << i; slot = slot * 32 + i; handles->entries [slot] = NULL; if (handles->type <= HANDLE_WEAK_TRACK) { /*FIXME, what to use when obj == null?*/ handles->domain_ids [slot] = (obj ? mono_object_get_domain (obj) : mono_domain_get ())->domain_id; if (obj) mono_gc_weak_link_add (&(handles->entries [slot]), obj, track); } else { handles->entries [slot] = obj; } #ifndef DISABLE_PERFCOUNTERS mono_perfcounters->gc_num_handles++; #endif unlock_handles (handles); /*g_print ("allocated entry %d of type %d to object %p (in slot: %p)\n", slot, handles->type, obj, handles->entries [slot]);*/ res = (slot << 3) | (handles->type + 1); mono_profiler_gc_handle (MONO_PROFILER_GC_HANDLE_CREATED, handles->type, res, obj); return res; } /** * mono_gchandle_new: * @obj: managed object to get a handle for * @pinned: whether the object should be pinned * * This returns a handle that wraps the object, this is used to keep a * reference to a managed object from the unmanaged world and preventing the * object from being disposed. * * If @pinned is false the address of the object can not be obtained, if it is * true the address of the object can be obtained. This will also pin the * object so it will not be possible by a moving garbage collector to move the * object. * * Returns: a handle that can be used to access the object from * unmanaged code. */ guint32 mono_gchandle_new (MonoObject *obj, gboolean pinned) { return alloc_handle (&gc_handles [pinned? HANDLE_PINNED: HANDLE_NORMAL], obj, FALSE); } /** * mono_gchandle_new_weakref: * @obj: managed object to get a handle for * @pinned: whether the object should be pinned * * This returns a weak handle that wraps the object, this is used to * keep a reference to a managed object from the unmanaged world. * Unlike the mono_gchandle_new the object can be reclaimed by the * garbage collector. In this case the value of the GCHandle will be * set to zero. * * If @pinned is false the address of the object can not be obtained, if it is * true the address of the object can be obtained. This will also pin the * object so it will not be possible by a moving garbage collector to move the * object. * * Returns: a handle that can be used to access the object from * unmanaged code. */ guint32 mono_gchandle_new_weakref (MonoObject *obj, gboolean track_resurrection) { guint32 handle = alloc_handle (&gc_handles [track_resurrection? HANDLE_WEAK_TRACK: HANDLE_WEAK], obj, track_resurrection); return handle; } static HandleType mono_gchandle_get_type (guint32 gchandle) { guint type = (gchandle & 7) - 1; return type; } /** * mono_gchandle_get_target: * @gchandle: a GCHandle's handle. * * The handle was previously created by calling mono_gchandle_new or * mono_gchandle_new_weakref. * * Returns a pointer to the MonoObject represented by the handle or * NULL for a collected object if using a weakref handle. */ MonoObject* mono_gchandle_get_target (guint32 gchandle) { guint slot = gchandle >> 3; guint type = (gchandle & 7) - 1; HandleData *handles = &gc_handles [type]; MonoObject *obj = NULL; if (type > 3) return NULL; lock_handles (handles); if (slot < handles->size && (handles->bitmap [slot / 32] & (1 << (slot % 32)))) { if (handles->type <= HANDLE_WEAK_TRACK) { obj = mono_gc_weak_link_get (&handles->entries [slot]); } else { obj = handles->entries [slot]; } } else { /* print a warning? */ } unlock_handles (handles); /*g_print ("get target of entry %d of type %d: %p\n", slot, handles->type, obj);*/ return obj; } static void mono_gchandle_set_target (guint32 gchandle, MonoObject *obj) { guint slot = gchandle >> 3; guint type = (gchandle & 7) - 1; HandleData *handles = &gc_handles [type]; MonoObject *old_obj = NULL; if (type > 3) return; lock_handles (handles); if (slot < handles->size && (handles->bitmap [slot / 32] & (1 << (slot % 32)))) { if (handles->type <= HANDLE_WEAK_TRACK) { old_obj = handles->entries [slot]; if (handles->entries [slot]) mono_gc_weak_link_remove (&handles->entries [slot], handles->type == HANDLE_WEAK_TRACK); if (obj) mono_gc_weak_link_add (&handles->entries [slot], obj, handles->type == HANDLE_WEAK_TRACK); /*FIXME, what to use when obj == null?*/ handles->domain_ids [slot] = (obj ? mono_object_get_domain (obj) : mono_domain_get ())->domain_id; } else { handles->entries [slot] = obj; } } else { /* print a warning? */ } /*g_print ("changed entry %d of type %d to object %p (in slot: %p)\n", slot, handles->type, obj, handles->entries [slot]);*/ unlock_handles (handles); } /** * mono_gchandle_is_in_domain: * @gchandle: a GCHandle's handle. * @domain: An application domain. * * Returns: true if the object wrapped by the @gchandle belongs to the specific @domain. */ gboolean mono_gchandle_is_in_domain (guint32 gchandle, MonoDomain *domain) { guint slot = gchandle >> 3; guint type = (gchandle & 7) - 1; HandleData *handles = &gc_handles [type]; gboolean result = FALSE; if (type > 3) return FALSE; lock_handles (handles); if (slot < handles->size && (handles->bitmap [slot / 32] & (1 << (slot % 32)))) { if (handles->type <= HANDLE_WEAK_TRACK) { result = domain->domain_id == handles->domain_ids [slot]; } else { MonoObject *obj; obj = handles->entries [slot]; if (obj == NULL) result = TRUE; else result = domain == mono_object_domain (obj); } } else { /* print a warning? */ } unlock_handles (handles); return result; } /** * mono_gchandle_free: * @gchandle: a GCHandle's handle. * * Frees the @gchandle handle. If there are no outstanding * references, the garbage collector can reclaim the memory of the * object wrapped. */ void mono_gchandle_free (guint32 gchandle) { guint slot = gchandle >> 3; guint type = (gchandle & 7) - 1; HandleData *handles = &gc_handles [type]; if (type > 3) return; lock_handles (handles); if (slot < handles->size && (handles->bitmap [slot / 32] & (1 << (slot % 32)))) { if (handles->type <= HANDLE_WEAK_TRACK) { if (handles->entries [slot]) mono_gc_weak_link_remove (&handles->entries [slot], handles->type == HANDLE_WEAK_TRACK); } else { handles->entries [slot] = NULL; } handles->bitmap [slot / 32] &= ~(1 << (slot % 32)); } else { /* print a warning? */ } #ifndef DISABLE_PERFCOUNTERS mono_perfcounters->gc_num_handles--; #endif /*g_print ("freed entry %d of type %d\n", slot, handles->type);*/ unlock_handles (handles); mono_profiler_gc_handle (MONO_PROFILER_GC_HANDLE_DESTROYED, handles->type, gchandle, NULL); } /** * mono_gchandle_free_domain: * @domain: domain that is unloading * * Function used internally to cleanup any GC handle for objects belonging * to the specified domain during appdomain unload. */ void mono_gchandle_free_domain (MonoDomain *domain) { guint type; for (type = 0; type < 3; ++type) { guint slot; HandleData *handles = &gc_handles [type]; lock_handles (handles); for (slot = 0; slot < handles->size; ++slot) { if (!(handles->bitmap [slot / 32] & (1 << (slot % 32)))) continue; if (type <= HANDLE_WEAK_TRACK) { if (domain->domain_id == handles->domain_ids [slot]) { handles->bitmap [slot / 32] &= ~(1 << (slot % 32)); if (handles->entries [slot]) mono_gc_weak_link_remove (&handles->entries [slot], handles->type == HANDLE_WEAK_TRACK); } } else { if (handles->entries [slot] && mono_object_domain (handles->entries [slot]) == domain) { handles->bitmap [slot / 32] &= ~(1 << (slot % 32)); handles->entries [slot] = NULL; } } } unlock_handles (handles); } } MonoBoolean GCHandle_CheckCurrentDomain (guint32 gchandle) { return mono_gchandle_is_in_domain (gchandle, mono_domain_get ()); } #ifndef HAVE_NULL_GC #ifdef MONO_HAS_SEMAPHORES static MonoSemType finalizer_sem; #endif static HANDLE finalizer_event; static volatile gboolean finished=FALSE; void mono_gc_finalize_notify (void) { #ifdef DEBUG g_message ( "%s: prodding finalizer", __func__); #endif #ifdef MONO_HAS_SEMAPHORES MONO_SEM_POST (&finalizer_sem); #else SetEvent (finalizer_event); #endif } #ifdef HAVE_BOEHM_GC static void collect_objects (gpointer key, gpointer value, gpointer user_data) { GPtrArray *arr = (GPtrArray*)user_data; g_ptr_array_add (arr, key); } #endif /* * finalize_domain_objects: * * Run the finalizers of all finalizable objects in req->domain. */ static void finalize_domain_objects (DomainFinalizationReq *req) { MonoDomain *domain = req->domain; #if HAVE_SGEN_GC #define NUM_FOBJECTS 64 MonoObject *to_finalize [NUM_FOBJECTS]; int count; #endif /* Process finalizers which are already in the queue */ mono_gc_invoke_finalizers (); #ifdef HAVE_BOEHM_GC while (g_hash_table_size (domain->finalizable_objects_hash) > 0) { int i; GPtrArray *objs; /* * Since the domain is unloading, nobody is allowed to put * new entries into the hash table. But finalize_object might * remove entries from the hash table, so we make a copy. */ objs = g_ptr_array_new (); g_hash_table_foreach (domain->finalizable_objects_hash, collect_objects, objs); /* printf ("FINALIZING %d OBJECTS.\n", objs->len); */ for (i = 0; i < objs->len; ++i) { MonoObject *o = (MonoObject*)g_ptr_array_index (objs, i); /* FIXME: Avoid finalizing threads, etc */ mono_gc_run_finalize (o, 0); } g_ptr_array_free (objs, TRUE); } #elif defined(HAVE_SGEN_GC) while ((count = mono_gc_finalizers_for_domain (domain, to_finalize, NUM_FOBJECTS))) { int i; for (i = 0; i < count; ++i) { mono_gc_run_finalize (to_finalize [i], 0); } } #endif /* cleanup the reference queue */ reference_queue_clear_for_domain (domain); /* printf ("DONE.\n"); */ SetEvent (req->done_event); /* The event is closed in mono_domain_finalize if we get here */ g_free (req); } static guint32 finalizer_thread (gpointer unused) { gboolean wait = TRUE; while (!finished) { /* Wait to be notified that there's at least one * finaliser to run */ g_assert (mono_domain_get () == mono_get_root_domain ()); if (wait) { /* An alertable wait is required so this thread can be suspended on windows */ #ifdef MONO_HAS_SEMAPHORES MONO_SEM_WAIT_ALERTABLE (&finalizer_sem, TRUE); #else WaitForSingleObjectEx (finalizer_event, INFINITE, TRUE); #endif } wait = TRUE; mono_threads_perform_thread_dump (); mono_console_handle_async_ops (); #ifndef DISABLE_ATTACH mono_attach_maybe_start (); #endif if (domains_to_finalize) { mono_finalizer_lock (); if (domains_to_finalize) { DomainFinalizationReq *req = domains_to_finalize->data; domains_to_finalize = g_slist_remove (domains_to_finalize, req); mono_finalizer_unlock (); finalize_domain_objects (req); } else { mono_finalizer_unlock (); } } /* If finished == TRUE, mono_gc_cleanup has been called (from mono_runtime_cleanup), * before the domain is unloaded. */ mono_gc_invoke_finalizers (); mono_threads_join_threads (); reference_queue_proccess_all (); #ifdef MONO_HAS_SEMAPHORES /* Avoid posting the pending done event until there are pending finalizers */ if (MONO_SEM_TIMEDWAIT (&finalizer_sem, 0) == 0) /* Don't wait again at the start of the loop */ wait = FALSE; else SetEvent (pending_done_event); #else SetEvent (pending_done_event); #endif } SetEvent (shutdown_event); return 0; } #ifndef LAZY_GC_THREAD_CREATION static #endif void mono_gc_init_finalizer_thread (void) { gc_thread = mono_thread_create_internal (mono_domain_get (), finalizer_thread, NULL, FALSE, 0); ves_icall_System_Threading_Thread_SetName_internal (gc_thread, mono_string_new (mono_domain_get (), "Finalizer")); } void mono_gc_init (void) { mono_mutex_init_recursive (&handle_section); mono_mutex_init_recursive (&allocator_section); mono_mutex_init_recursive (&finalizer_mutex); mono_mutex_init_recursive (&reference_queue_mutex); MONO_GC_REGISTER_ROOT_FIXED (gc_handles [HANDLE_NORMAL].entries); MONO_GC_REGISTER_ROOT_FIXED (gc_handles [HANDLE_PINNED].entries); mono_counters_register ("Minor GC collections", MONO_COUNTER_GC | MONO_COUNTER_UINT, &gc_stats.minor_gc_count); mono_counters_register ("Major GC collections", MONO_COUNTER_GC | MONO_COUNTER_UINT, &gc_stats.major_gc_count); mono_counters_register ("Minor GC time", MONO_COUNTER_GC | MONO_COUNTER_ULONG | MONO_COUNTER_TIME, &gc_stats.minor_gc_time); mono_counters_register ("Major GC time", MONO_COUNTER_GC | MONO_COUNTER_ULONG | MONO_COUNTER_TIME, &gc_stats.major_gc_time); mono_counters_register ("Major GC time concurrent", MONO_COUNTER_GC | MONO_COUNTER_ULONG | MONO_COUNTER_TIME, &gc_stats.major_gc_time_concurrent); mono_gc_base_init (); if (mono_gc_is_disabled ()) { gc_disabled = TRUE; return; } finalizer_event = CreateEvent (NULL, FALSE, FALSE, NULL); pending_done_event = CreateEvent (NULL, TRUE, FALSE, NULL); shutdown_event = CreateEvent (NULL, TRUE, FALSE, NULL); if (finalizer_event == NULL || pending_done_event == NULL || shutdown_event == NULL) { g_assert_not_reached (); } #ifdef MONO_HAS_SEMAPHORES MONO_SEM_INIT (&finalizer_sem, 0); #endif #ifndef LAZY_GC_THREAD_CREATION mono_gc_init_finalizer_thread (); #endif } void mono_gc_cleanup (void) { #ifdef DEBUG g_message ("%s: cleaning up finalizer", __func__); #endif if (!gc_disabled) { ResetEvent (shutdown_event); finished = TRUE; if (mono_thread_internal_current () != gc_thread) { gboolean timed_out = FALSE; mono_gc_finalize_notify (); /* Finishing the finalizer thread, so wait a little bit... */ /* MS seems to wait for about 2 seconds */ if (WaitForSingleObjectEx (shutdown_event, 2000, FALSE) == WAIT_TIMEOUT) { int ret; /* Set a flag which the finalizer thread can check */ suspend_finalizers = TRUE; /* Try to abort the thread, in the hope that it is running managed code */ mono_thread_internal_stop (gc_thread); /* Wait for it to stop */ ret = WaitForSingleObjectEx (gc_thread->handle, 100, TRUE); if (ret == WAIT_TIMEOUT) { /* * The finalizer thread refused to die. There is not much we * can do here, since the runtime is shutting down so the * state the finalizer thread depends on will vanish. */ g_warning ("Shutting down finalizer thread timed out."); timed_out = TRUE; } } if (!timed_out) { int ret; /* Wait for the thread to actually exit */ ret = WaitForSingleObjectEx (gc_thread->handle, INFINITE, TRUE); g_assert (ret == WAIT_OBJECT_0); mono_thread_join (MONO_UINT_TO_NATIVE_THREAD_ID (gc_thread->tid)); } } gc_thread = NULL; #ifdef HAVE_BOEHM_GC GC_finalizer_notifier = NULL; #endif } mono_reference_queue_cleanup (); mono_mutex_destroy (&handle_section); mono_mutex_destroy (&allocator_section); mono_mutex_destroy (&finalizer_mutex); mono_mutex_destroy (&reference_queue_mutex); } #else /* Null GC dummy functions */ void mono_gc_finalize_notify (void) { } void mono_gc_init (void) { mono_mutex_init_recursive (&handle_section); } void mono_gc_cleanup (void) { } #endif gboolean mono_gc_is_finalizer_internal_thread (MonoInternalThread *thread) { return thread == gc_thread; } /** * mono_gc_is_finalizer_thread: * @thread: the thread to test. * * In Mono objects are finalized asynchronously on a separate thread. * This routine tests whether the @thread argument represents the * finalization thread. * * Returns true if @thread is the finalization thread. */ gboolean mono_gc_is_finalizer_thread (MonoThread *thread) { return mono_gc_is_finalizer_internal_thread (thread->internal_thread); } #if defined(__MACH__) static pthread_t mach_exception_thread; void mono_gc_register_mach_exception_thread (pthread_t thread) { mach_exception_thread = thread; } pthread_t mono_gc_get_mach_exception_thread (void) { return mach_exception_thread; } #endif /** * mono_gc_parse_environment_string_extract_number: * * @str: points to the first digit of the number * @out: pointer to the variable that will receive the value * * Tries to extract a number from the passed string, taking in to account m, k * and g suffixes * * Returns true if passing was successful */ gboolean mono_gc_parse_environment_string_extract_number (const char *str, size_t *out) { char *endptr; int len = strlen (str), shift = 0; size_t val; gboolean is_suffix = FALSE; char suffix; if (!len) return FALSE; suffix = str [len - 1]; switch (suffix) { case 'g': case 'G': shift += 10; case 'm': case 'M': shift += 10; case 'k': case 'K': shift += 10; is_suffix = TRUE; break; default: if (!isdigit (suffix)) return FALSE; break; } errno = 0; val = strtol (str, &endptr, 10); if ((errno == ERANGE && (val == LONG_MAX || val == LONG_MIN)) || (errno != 0 && val == 0) || (endptr == str)) return FALSE; if (is_suffix) { size_t unshifted; if (val < 0) /* negative numbers cannot be suffixed */ return FALSE; if (*(endptr + 1)) /* Invalid string. */ return FALSE; unshifted = (size_t)val; val <<= shift; if (val < 0) /* overflow */ return FALSE; if (((size_t)val >> shift) != unshifted) /* value too large */ return FALSE; } *out = val; return TRUE; } #ifndef HAVE_SGEN_GC void* mono_gc_alloc_mature (MonoVTable *vtable) { return mono_object_new_specific (vtable); } #endif static MonoReferenceQueue *ref_queues; static void ref_list_remove_element (RefQueueEntry **prev, RefQueueEntry *element) { do { /* Guard if head is changed concurrently. */ while (*prev != element) prev = &(*prev)->next; } while (prev && InterlockedCompareExchangePointer ((void*)prev, element->next, element) != element); } static void ref_list_push (RefQueueEntry **head, RefQueueEntry *value) { RefQueueEntry *current; do { current = *head; value->next = current; STORE_STORE_FENCE; /*Must make sure the previous store is visible before the CAS. */ } while (InterlockedCompareExchangePointer ((void*)head, value, current) != current); } static void reference_queue_proccess (MonoReferenceQueue *queue) { RefQueueEntry **iter = &queue->queue; RefQueueEntry *entry; while ((entry = *iter)) { #ifdef HAVE_SGEN_GC if (queue->should_be_deleted || !mono_gc_weak_link_get (&entry->dis_link)) { mono_gc_weak_link_remove (&entry->dis_link, TRUE); #else if (queue->should_be_deleted || !mono_gchandle_get_target (entry->gchandle)) { mono_gchandle_free ((guint32)entry->gchandle); #endif ref_list_remove_element (iter, entry); queue->callback (entry->user_data); g_free (entry); } else { iter = &entry->next; } } } static void reference_queue_proccess_all (void) { MonoReferenceQueue **iter; MonoReferenceQueue *queue = ref_queues; for (; queue; queue = queue->next) reference_queue_proccess (queue); restart: mono_mutex_lock (&reference_queue_mutex); for (iter = &ref_queues; *iter;) { queue = *iter; if (!queue->should_be_deleted) { iter = &queue->next; continue; } if (queue->queue) { mono_mutex_unlock (&reference_queue_mutex); reference_queue_proccess (queue); goto restart; } *iter = queue->next; g_free (queue); } mono_mutex_unlock (&reference_queue_mutex); } static void mono_reference_queue_cleanup (void) { MonoReferenceQueue *queue = ref_queues; for (; queue; queue = queue->next) queue->should_be_deleted = TRUE; reference_queue_proccess_all (); } static void reference_queue_clear_for_domain (MonoDomain *domain) { MonoReferenceQueue *queue = ref_queues; for (; queue; queue = queue->next) { RefQueueEntry **iter = &queue->queue; RefQueueEntry *entry; while ((entry = *iter)) { if (entry->domain == domain) { #ifdef HAVE_SGEN_GC mono_gc_weak_link_remove (&entry->dis_link, TRUE); #else mono_gchandle_free ((guint32)entry->gchandle); #endif ref_list_remove_element (iter, entry); queue->callback (entry->user_data); g_free (entry); } else { iter = &entry->next; } } } } /** * mono_gc_reference_queue_new: * @callback callback used when processing collected entries. * * Create a new reference queue used to process collected objects. * A reference queue let you add a pair of (managed object, user data) * using the mono_gc_reference_queue_add method. * * Once the managed object is collected @callback will be called * in the finalizer thread with 'user data' as argument. * * The callback is called from the finalizer thread without any locks held. * When a AppDomain is unloaded, all callbacks for objects belonging to it * will be invoked. * * @returns the new queue. */ MonoReferenceQueue* mono_gc_reference_queue_new (mono_reference_queue_callback callback) { MonoReferenceQueue *res = g_new0 (MonoReferenceQueue, 1); res->callback = callback; mono_mutex_lock (&reference_queue_mutex); res->next = ref_queues; ref_queues = res; mono_mutex_unlock (&reference_queue_mutex); return res; } /** * mono_gc_reference_queue_add: * @queue the queue to add the reference to. * @obj the object to be watched for collection * @user_data parameter to be passed to the queue callback * * Queue an object to be watched for collection, when the @obj is * collected, the callback that was registered for the @queue will * be invoked with @user_data as argument. * * @returns false if the queue is scheduled to be freed. */ gboolean mono_gc_reference_queue_add (MonoReferenceQueue *queue, MonoObject *obj, void *user_data) { RefQueueEntry *entry; if (queue->should_be_deleted) return FALSE; entry = g_new0 (RefQueueEntry, 1); entry->user_data = user_data; entry->domain = mono_object_domain (obj); #ifdef HAVE_SGEN_GC mono_gc_weak_link_add (&entry->dis_link, obj, TRUE); #else entry->gchandle = mono_gchandle_new_weakref (obj, TRUE); mono_object_register_finalizer (obj); #endif ref_list_push (&queue->queue, entry); return TRUE; } /** * mono_gc_reference_queue_free: * @queue the queue that should be freed. * * This operation signals that @queue should be freed. This operation is deferred * as it happens on the finalizer thread. * * After this call, no further objects can be queued. It's the responsibility of the * caller to make sure that no further attempt to access queue will be made. */ void mono_gc_reference_queue_free (MonoReferenceQueue *queue) { queue->should_be_deleted = TRUE; }