Beispiel #1
0
static void
mono_backtrace (int size)
{
	void *array[BACKTRACE_DEPTH];
	char **names;
	int i, symbols;
	static gboolean inited;

	if (!inited) {
		mono_os_mutex_init_recursive (&mempool_tracing_lock);
		inited = TRUE;
	}

	mono_os_mutex_lock (&mempool_tracing_lock);
	g_print ("Allocating %d bytes\n", size);
	MONO_ENTER_GC_SAFE;
	symbols = backtrace (array, BACKTRACE_DEPTH);
	names = backtrace_symbols (array, symbols);
	MONO_EXIT_GC_SAFE;
	for (i = 1; i < symbols; ++i) {
		g_print ("\t%s\n", names [i]);
	}
	g_free (names);
	mono_os_mutex_unlock (&mempool_tracing_lock);
}
Beispiel #2
0
static void mono_portability_remember_string (MonoProfiler *prof, MonoDomain *domain, MonoString *str)
{
	SavedString *head, *entry;

	if (!str || !domain || !runtime_initialized)
		return;

	entry = (SavedString*)g_malloc0 (sizeof (SavedString));
	entry->string = str;
	entry->domain = domain;
	entry->stack_entries = mono_stack_backtrace (prof, domain, entry->stack, BACKTRACE_SIZE);
	if (entry->stack_entries == 0) {
		g_free (entry);
		return;
	}

	mono_os_mutex_lock (&mismatched_files_section);
	head = (SavedString*)g_hash_table_lookup (prof->saved_strings_hash, (gpointer)str);
	if (head) {
		while (head->next)
			head = head->next;
		head->next = entry;
	} else
		g_hash_table_insert (prof->saved_strings_hash, (gpointer)str, (gpointer)entry);
	mono_os_mutex_unlock (&mismatched_files_section);
}
Beispiel #3
0
static void mono_portability_iomap_event (MonoProfiler *prof, const char *report, const char *pathname, const char *new_pathname)
{
	guint32 hash, pathnameHash;
	MismatchedFilesStats *stats;

	if (!runtime_initialized)
		return;

	mono_os_mutex_lock (&mismatched_files_section);
	hash = calc_strings_hash (pathname, new_pathname, &pathnameHash);
	stats = (MismatchedFilesStats*)g_hash_table_lookup (prof->mismatched_files_hash, &hash);
	if (stats == NULL) {
		guint32 *hashptr;

		stats = (MismatchedFilesStats*) g_malloc (sizeof (MismatchedFilesStats));
		stats->count = 1;
		stats->requestedName = g_strdup (pathname);
		stats->actualName = g_strdup (new_pathname);
		hashptr = (guint32*)g_malloc (sizeof (guint32));
		if (hashptr) {
			*hashptr = hash;
			g_hash_table_insert (prof->mismatched_files_hash, (gpointer)hashptr, stats);
		} else
			g_error ("Out of memory allocating integer pointer for mismatched files hash table.");

		store_string_location (prof, (const gchar*)stats->requestedName, pathnameHash, strlen (stats->requestedName));
		mono_os_mutex_unlock (&mismatched_files_section);

		print_report ("%s -     Found file path: '%s'\n", report, new_pathname);
	} else {
		mono_os_mutex_unlock (&mismatched_files_section);
		stats->count++;
	}
}
Beispiel #4
0
static void*
codechunk_valloc (void *preferred, guint32 size)
{
	void *ptr;
	GSList *freelist;

	if (!valloc_freelists) {
		mono_os_mutex_init_recursive (&valloc_mutex);
		valloc_freelists = g_hash_table_new (NULL, NULL);
	}

	/*
	 * Keep a small freelist of memory blocks to decrease pressure on the kernel memory subsystem to avoid #3321.
	 */
	mono_os_mutex_lock (&valloc_mutex);
	freelist = (GSList *) g_hash_table_lookup (valloc_freelists, GUINT_TO_POINTER (size));
	if (freelist) {
		ptr = freelist->data;
		memset (ptr, 0, size);
		freelist = g_slist_delete_link (freelist, freelist);
		g_hash_table_insert (valloc_freelists, GUINT_TO_POINTER (size), freelist);
	} else {
		ptr = mono_valloc (preferred, size, MONO_PROT_RWX | ARCH_MAP_FLAGS, MONO_MEM_ACCOUNT_CODE);
		if (!ptr && preferred)
			ptr = mono_valloc (NULL, size, MONO_PROT_RWX | ARCH_MAP_FLAGS, MONO_MEM_ACCOUNT_CODE);
	}
	mono_os_mutex_unlock (&valloc_mutex);
	return ptr;
}
Beispiel #5
0
/**
 * mono_counters_dump:
 * @section_mask: The sections to dump counters for
 * @outfile: a FILE to dump the results to
 *
 * Displays the counts of all the enabled counters registered. 
 * To filter by variance, you can OR one or more variance with the specific section you want.
 * Use MONO_COUNTER_SECTION_MASK to dump all categories of a specific variance.
 */
void
mono_counters_dump (int section_mask, FILE *outfile)
{
	int i, j;
	int variance;
	section_mask &= valid_mask;

	if (!initialized)
		return;

	mono_os_mutex_lock (&counters_mutex);

	if (!counters) {
		mono_os_mutex_unlock (&counters_mutex);
		return;
	}

	variance = section_mask & MONO_COUNTER_VARIANCE_MASK;

	/* If no variance mask is supplied, we default to all kinds. */
	if (!variance)
		variance = MONO_COUNTER_VARIANCE_MASK;
	section_mask &= ~MONO_COUNTER_VARIANCE_MASK;

	for (j = 0, i = MONO_COUNTER_JIT; i < MONO_COUNTER_LAST_SECTION; j++, i <<= 1) {
		if ((section_mask & i) && (set_mask & i)) {
			fprintf (outfile, "\n%s statistics\n", section_names [j]);
			mono_counters_dump_section (i, variance, outfile);
		}
	}

	fflush (outfile);
	mono_os_mutex_unlock (&counters_mutex);
}
Beispiel #6
0
void
sgen_init_pinning (void)
{
	mono_os_mutex_lock (&pin_queue_mutex);
	memset (pin_hash_filter, 0, sizeof (pin_hash_filter));
	pin_queue.mem_type = INTERNAL_MEM_PIN_QUEUE;
	sgen_pointer_queue_clear (&pin_queue_objs);
}
Beispiel #7
0
static void
lock_section_queue (SgenSectionGrayQueue *queue)
{
	if (!queue->locked)
		return;

	mono_os_mutex_lock (&queue->lock);
}
Beispiel #8
0
GrayQueueEntry
sgen_gray_object_dequeue (SgenGrayQueue *queue, gboolean is_parallel)
{
	GrayQueueEntry entry;

	HEAVY_STAT (stat_gray_queue_dequeue_slow_path ++);

	if (sgen_gray_object_queue_is_empty (queue)) {
		entry.obj = NULL;
		return entry;
	}

	STATE_ASSERT (queue->first, GRAY_QUEUE_SECTION_STATE_ENQUEUED);
	SGEN_ASSERT (9, queue->cursor >= GRAY_FIRST_CURSOR_POSITION (queue->first), "gray queue %p underflow", queue);

	entry = *queue->cursor--;

#ifdef SGEN_HEAVY_BINARY_PROTOCOL
	binary_protocol_gray_dequeue (queue, queue->cursor + 1, entry.obj);
#endif

	if (G_UNLIKELY (queue->cursor < GRAY_FIRST_CURSOR_POSITION (queue->first))) {
		GrayQueueSection *section;
		gint32 old_num_sections = 0;

		if (is_parallel)
			old_num_sections = mono_atomic_dec_i32 (&queue->num_sections);
		else
			queue->num_sections--;

		if (is_parallel && old_num_sections <= 0) {
			mono_os_mutex_lock (&queue->steal_mutex);
		}

		section = queue->first;
		queue->first = section->next;
		if (queue->first) {
			queue->first->prev = NULL;
		} else {
			queue->last = NULL;
			SGEN_ASSERT (0, !old_num_sections, "Why do we have an inconsistent number of sections ?");
		}
		section->next = queue->free_list;

		STATE_TRANSITION (section, GRAY_QUEUE_SECTION_STATE_ENQUEUED, GRAY_QUEUE_SECTION_STATE_FREE_LIST);

		queue->free_list = section;
		queue->cursor = queue->first ? queue->first->entries + queue->first->size - 1 : NULL;

		if (is_parallel && old_num_sections <= 0) {
			mono_os_mutex_unlock (&queue->steal_mutex);
		}
	}

	return entry;
}
Beispiel #9
0
static int
noshm_sem_lock (int sem)
{
	int ret;
	
	DEBUGLOG ("%s: locking nosem %d", __func__, sem);
	
	ret = mono_os_mutex_lock (&noshm_sems[sem]);
	
	return ret;
}
Beispiel #10
0
static int
mono_w32handle_lock_signal_mutex (void)
{
#ifdef DEBUG
	g_message ("%s: lock global signal mutex", __func__);
#endif

	mono_os_mutex_lock (&global_signal_mutex);

	return 0;
}
Beispiel #11
0
static int
single_writer_single_reader (void)
{
	mono_mutex_t mutex;
	MonoConcurrentHashTable *h;
	int res = 0;

	mono_os_mutex_init (&mutex);
	h = mono_conc_hashtable_new (NULL, NULL);

	mono_os_mutex_lock (&mutex);
	mono_conc_hashtable_insert (h, GUINT_TO_POINTER (10), GUINT_TO_POINTER (20));
	mono_os_mutex_unlock (&mutex);

	mono_os_mutex_lock (&mutex);
	mono_conc_hashtable_insert (h, GUINT_TO_POINTER (30), GUINT_TO_POINTER (40));
	mono_os_mutex_unlock (&mutex);

	mono_os_mutex_lock (&mutex);
	mono_conc_hashtable_insert (h, GUINT_TO_POINTER (50), GUINT_TO_POINTER (60));
	mono_os_mutex_unlock (&mutex);

	mono_os_mutex_lock (&mutex);
	mono_conc_hashtable_insert (h, GUINT_TO_POINTER (2), GUINT_TO_POINTER (3));
	mono_os_mutex_unlock (&mutex);

	if (mono_conc_hashtable_lookup (h, GUINT_TO_POINTER (30)) != GUINT_TO_POINTER (40))
		res = 1;
	if (mono_conc_hashtable_lookup (h, GUINT_TO_POINTER (10)) != GUINT_TO_POINTER (20))
		res = 2;
	if (mono_conc_hashtable_lookup (h, GUINT_TO_POINTER (2)) != GUINT_TO_POINTER (3))
		res = 3;
	if (mono_conc_hashtable_lookup (h, GUINT_TO_POINTER (50)) != GUINT_TO_POINTER (60))
		res = 4;

	mono_conc_hashtable_destroy (h);
	mono_os_mutex_destroy (&mutex);
	if (res)
		printf ("SERIAL TEST FAILED %d\n", res);
	return res;
}
Beispiel #12
0
/**
 * mono_counters_on_register
 * @callback : function to callback when a counter is registered
 *
 * Add a callback that is going to be called when a counter is registered
 */
void
mono_counters_on_register (MonoCounterRegisterCallback callback)
{
	if (!initialized) {
		g_debug ("counters not enabled");
		return;
	}

	mono_os_mutex_lock (&counters_mutex);
	register_callbacks = g_slist_append (register_callbacks, (gpointer) callback);
	mono_os_mutex_unlock (&counters_mutex);
}
Beispiel #13
0
void
mono_thread_small_id_free (int id)
{
	/* MonoBitSet operations are not atomic. */
	mono_os_mutex_lock (&small_id_mutex);

	g_assert (id >= 0 && id < small_id_table->size);
	g_assert (mono_bitset_test_fast (small_id_table, id));
	mono_bitset_clear_fast (small_id_table, id);

	mono_os_mutex_unlock (&small_id_mutex);
}
Beispiel #14
0
static int
single_writer_parallel_reader (void)
{
	pthread_t a,b,c;
	gpointer ra, rb, rc;
	int i, res = 0;
	ra = rb = rc = GINT_TO_POINTER (1);

	mono_os_mutex_init (&global_mutex);
	hash = mono_conc_hashtable_new (NULL, NULL);

	pthread_create (&a, NULL, pr_sw_thread, GINT_TO_POINTER (0));
	pthread_create (&b, NULL, pr_sw_thread, GINT_TO_POINTER (1));
	pthread_create (&c, NULL, pr_sw_thread, GINT_TO_POINTER (2));

	for (i = 0; i < 100; ++i) {
		mono_os_mutex_lock (&global_mutex);
		mono_conc_hashtable_insert (hash, GINT_TO_POINTER (i +   0 + 1), GINT_TO_POINTER ((i +   0) * 2 + 1));
		mono_os_mutex_unlock (&global_mutex);

		mono_os_mutex_lock (&global_mutex);
		mono_conc_hashtable_insert (hash, GINT_TO_POINTER (i + 100 + 1), GINT_TO_POINTER ((i + 100) * 2 + 1));
		mono_os_mutex_unlock (&global_mutex);

		mono_os_mutex_lock (&global_mutex);
		mono_conc_hashtable_insert (hash, GINT_TO_POINTER (i + 200 + 1), GINT_TO_POINTER ((i + 200) * 2 + 1));
		mono_os_mutex_unlock (&global_mutex);
	}

	pthread_join (a, &ra);
	pthread_join (b, &rb);
	pthread_join (c, &rc);
	res = GPOINTER_TO_INT (ra) + GPOINTER_TO_INT (rb) + GPOINTER_TO_INT (rc);

	mono_conc_hashtable_destroy (hash);
	mono_os_mutex_destroy (&global_mutex);
	if (res)
		printf ("SINGLE_WRITER_PAR_READER TEST FAILED %d\n", res);
	return res;
}
Beispiel #15
0
void
mono_os_event_reset (MonoOSEvent *event)
{
	g_assert (mono_lazy_is_initialized (&status));

	g_assert (event);

	mono_os_mutex_lock (&signal_mutex);

	event->signalled = FALSE;

	mono_os_mutex_unlock (&signal_mutex);
}
Beispiel #16
0
static void*
pw_sr_thread (void *arg)
{
	int i, idx = 1000 * GPOINTER_TO_INT (arg);
	mono_thread_info_attach ();

	for (i = 0; i < 1000; ++i) {
		mono_os_mutex_lock (&global_mutex);
		mono_conc_hashtable_insert (hash, GINT_TO_POINTER (i + idx), GINT_TO_POINTER (i + 1));
		mono_os_mutex_unlock (&global_mutex);
	}
	return NULL;
}
Beispiel #17
0
void
sgen_scan_pin_queue_objects (ScanCopyContext ctx)
{
	int i;
	ScanObjectFunc scan_func = ctx.ops->scan_object;

	mono_os_mutex_lock (&pin_queue_mutex);
	for (i = 0; i < pin_queue_objs.next_slot; ++i) {
		GCObject *obj = (GCObject *)pin_queue_objs.data [i];
		scan_func (obj, sgen_obj_get_descriptor_safe (obj), ctx.queue);
	}
	mono_os_mutex_unlock (&pin_queue_mutex);
}
Beispiel #18
0
static void*
pw_pr_w_del_thread (void *arg)
{
	int i, idx = 1000 * GPOINTER_TO_INT (arg);

	mono_thread_info_attach ();

	for (i = idx; i < idx + 1000; i++) {
		mono_os_mutex_lock (&global_mutex);
		mono_conc_hashtable_remove (hash, GINT_TO_POINTER (i + 1));
		mono_os_mutex_unlock (&global_mutex);
	}
	return NULL;
}
Beispiel #19
0
static void
codechunk_vfree (void *ptr, guint32 size)
{
	GSList *freelist;

	mono_os_mutex_lock (&valloc_mutex);
	freelist = (GSList *) g_hash_table_lookup (valloc_freelists, GUINT_TO_POINTER (size));
	if (!freelist || g_slist_length (freelist) < VALLOC_FREELIST_SIZE) {
		freelist = g_slist_prepend (freelist, ptr);
		g_hash_table_insert (valloc_freelists, GUINT_TO_POINTER (size), freelist);
	} else {
		mono_vfree (ptr, size, MONO_MEM_ACCOUNT_CODE);
	}
	mono_os_mutex_unlock (&valloc_mutex);
}		
Beispiel #20
0
static void
register_internal (const char *name, int type, void *addr, int size)
{
	MonoCounter *counter;
	GSList *register_callback;

	g_assert (size >= 0);
	if ((type & MONO_COUNTER_VARIANCE_MASK) == 0)
		type |= MONO_COUNTER_MONOTONIC;

	mono_os_mutex_lock (&counters_mutex);

	for (counter = counters; counter; counter = counter->next) {
		if (counter->addr == addr) {
			g_warning ("you are registering twice the same counter address");
			mono_os_mutex_unlock (&counters_mutex);
			return;
		}
	}

	counter = (MonoCounter *) malloc (sizeof (MonoCounter));
	if (!counter) {
		mono_os_mutex_unlock (&counters_mutex);
		return;
	}
	counter->name = g_strdup (name);
	counter->type = type;
	counter->addr = addr;
	counter->next = NULL;
	counter->size = size;

	set_mask |= type;

	/* Append */
	if (counters) {
		MonoCounter *item = counters;
		while (item->next)
			item = item->next;
		item->next = counter;
	} else {
		counters = counter;
	}

	for (register_callback = register_callbacks; register_callback; register_callback = register_callback->next)
		((MonoCounterRegisterCallback)register_callback->data) (counter);

	mono_os_mutex_unlock (&counters_mutex);
}
Beispiel #21
0
gpointer mono_w32handle_new_fd (MonoW32HandleType type, int fd,
			      gpointer handle_specific)
{
	MonoW32HandleBase *handle_data;
	int fd_index, fd_offset;

	g_assert (!shutting_down);

	g_assert(type_is_fd(type));

	if (fd >= mono_w32handle_fd_reserve) {
		mono_trace (G_LOG_LEVEL_DEBUG, MONO_TRACE_W32HANDLE, "%s: failed to create %s handle, fd is too big", __func__, mono_w32handle_ops_typename (type));

		return(GUINT_TO_POINTER (INVALID_HANDLE_VALUE));
	}

	fd_index = SLOT_INDEX (fd);
	fd_offset = SLOT_OFFSET (fd);

	/* Initialize the array entries on demand */
	if (!private_handles [fd_index]) {
		mono_os_mutex_lock (&scan_mutex);

		if (!private_handles [fd_index])
			private_handles [fd_index] = g_new0 (MonoW32HandleBase, HANDLE_PER_SLOT);

		mono_os_mutex_unlock (&scan_mutex);
	}

	handle_data = &private_handles [fd_index][fd_offset];

	if (handle_data->type != MONO_W32HANDLE_UNUSED) {
		mono_trace (G_LOG_LEVEL_DEBUG, MONO_TRACE_W32HANDLE, "%s: failed to create %s handle, fd is already in use", __func__, mono_w32handle_ops_typename (type));
		/* FIXME: clean up this handle?  We can't do anything
		 * with the fd, cos thats the new one
		 */
		return(GUINT_TO_POINTER (INVALID_HANDLE_VALUE));
	}

	mono_trace (G_LOG_LEVEL_DEBUG, MONO_TRACE_W32HANDLE, "%s: create %s handle %p", __func__, mono_w32handle_ops_typename (type), GUINT_TO_POINTER(fd));

	mono_w32handle_init_handle (handle_data, type, handle_specific);

	return(GUINT_TO_POINTER(fd));
}
Beispiel #22
0
void
mono_os_event_set (MonoOSEvent *event)
{
	gsize i;

	g_assert (mono_lazy_is_initialized (&status));

	g_assert (event);

	mono_os_mutex_lock (&signal_mutex);

	event->signalled = TRUE;

	for (i = 0; i < event->conds->len; ++i)
		mono_os_cond_signal ((mono_cond_t*) event->conds->pdata [i]);

	mono_os_mutex_unlock (&signal_mutex);
}
Beispiel #23
0
gpointer
mono_w32handle_new (MonoW32HandleType type, gpointer handle_specific)
{
	guint32 handle_idx = 0;
	gpointer handle;

	g_assert (!shutting_down);

	g_assert(!type_is_fd(type));

	mono_os_mutex_lock (&scan_mutex);

	while ((handle_idx = mono_w32handle_new_internal (type, handle_specific)) == 0) {
		/* Try and expand the array, and have another go */
		int idx = SLOT_INDEX (private_handles_count);
		if (idx >= SLOT_MAX) {
			break;
		}

		private_handles [idx] = g_new0 (MonoW32HandleBase, HANDLE_PER_SLOT);

		private_handles_count += HANDLE_PER_SLOT;
		private_handles_slots_count ++;
	}

	mono_os_mutex_unlock (&scan_mutex);

	if (handle_idx == 0) {
		/* We ran out of slots */
		handle = INVALID_HANDLE_VALUE;
		mono_trace (G_LOG_LEVEL_DEBUG, MONO_TRACE_W32HANDLE, "%s: failed to create %s handle", __func__, mono_w32handle_ops_typename (type));
		goto done;
	}

	/* Make sure we left the space for fd mappings */
	g_assert (handle_idx >= mono_w32handle_fd_reserve);

	handle = GUINT_TO_POINTER (handle_idx);

	mono_trace (G_LOG_LEVEL_DEBUG, MONO_TRACE_W32HANDLE, "%s: create %s handle %p", __func__, mono_w32handle_ops_typename (type), handle);

done:
	return(handle);
}
Beispiel #24
0
void
mono_w32handle_foreach (gboolean (*on_each)(gpointer handle, gpointer data, gpointer user_data), gpointer user_data)
{
	guint32 i, k;

	mono_os_mutex_lock (&scan_mutex);

	for (i = SLOT_INDEX (0); i < private_handles_slots_count; i++) {
		if (!private_handles [i])
			continue;
		for (k = SLOT_OFFSET (0); k < HANDLE_PER_SLOT; k++) {
			MonoW32HandleBase *handle_data = NULL;
			gpointer handle;
			gboolean destroy, finished;

			handle_data = &private_handles [i][k];
			if (handle_data->type == MONO_W32HANDLE_UNUSED)
				continue;

			handle = GUINT_TO_POINTER (i * HANDLE_PER_SLOT + k);

			if (!mono_w32handle_ref_core (handle, handle_data)) {
				/* we are racing with mono_w32handle_unref:
				 *  the handle ref has been decremented, but it
				 *  hasn't yet been destroyed. */
				continue;
			}

			finished = on_each (handle, handle_data->specific, user_data);

			/* we do not want to have to destroy the handle here,
			 * as it would means the ref/unref are unbalanced */
			destroy = mono_w32handle_unref_core (handle, handle_data, 2);
			g_assert (!destroy);

			if (finished)
				goto done;
		}
	}

done:
	mono_os_mutex_unlock (&scan_mutex);
}
Beispiel #25
0
int
mono_w32handle_lock_handle (gpointer handle)
{
	MonoW32HandleBase *handle_data;

#ifdef DEBUG
	g_message ("%s: locking handle %p", __func__, handle);
#endif

	if (!mono_w32handle_lookup_data (handle, &handle_data)) {
		return(0);
	}

	mono_w32handle_ref (handle);

	mono_os_mutex_lock (&handle_data->signal_mutex);

	return 0;
}
Beispiel #26
0
void
mono_w32handle_set_signal_state (gpointer handle, gboolean state, gboolean broadcast)
{
	MonoW32HandleBase *handle_data;

	if (!mono_w32handle_lookup_data (handle, &handle_data)) {
		return;
	}

#ifdef DEBUG
	g_message ("%s: setting state of %p to %s (broadcast %s)", __func__,
		   handle, state?"TRUE":"FALSE", broadcast?"TRUE":"FALSE");
#endif

	if (state == TRUE) {
		/* Tell everyone blocking on a single handle */

		/* The condition the global signal cond is waiting on is the signalling of
		 * _any_ handle. So lock it before setting the signalled state.
		 */
		mono_os_mutex_lock (&global_signal_mutex);

		/* This function _must_ be called with
		 * handle->signal_mutex locked
		 */
		handle_data->signalled=state;

		if (broadcast == TRUE) {
			mono_os_cond_broadcast (&handle_data->signal_cond);
		} else {
			mono_os_cond_signal (&handle_data->signal_cond);
		}

		/* Tell everyone blocking on multiple handles that something
		 * was signalled
		 */
		mono_os_cond_broadcast (&global_signal_cond);

		mono_os_mutex_unlock (&global_signal_mutex);
	} else {
		handle_data->signalled=state;
	}
}
Beispiel #27
0
/**
 * mono_counters_foreach:
 * @cb: The callback that will be called for each counter.
 * @user_data: Value passed as second argument of the callback.
 *
 * Iterate over all counters and call @cb for each one of them. Stop iterating if
 * the callback returns FALSE.
 *
 */
void
mono_counters_foreach (CountersEnumCallback cb, gpointer user_data)
{
	MonoCounter *counter;

	if (!initialized) {
		g_debug ("counters not enabled");
		return;
	}

	mono_os_mutex_lock (&counters_mutex);

	for (counter = counters; counter; counter = counter->next) {
		if (!cb (counter, user_data)) {
			mono_os_mutex_unlock (&counters_mutex);
			return;
		}
	}

	mono_os_mutex_unlock (&counters_mutex);
}
Beispiel #28
0
/**
 * mono_counters_cleanup:
 *
 * Perform any needed cleanup at process exit.
 */
void
mono_counters_cleanup (void)
{
	MonoCounter *counter;

	if (!initialized)
		return;

	mono_os_mutex_lock (&counters_mutex);

	counter = counters;
	counters = NULL;
	while (counter) {
		MonoCounter *tmp = counter;
		counter = counter->next;
		free ((void*)tmp->name);
		free (tmp);
	}

	mono_os_mutex_unlock (&counters_mutex);
}
Beispiel #29
0
/*
 * Allocate a small thread id.
 *
 * FIXME: The biggest part of this function is very similar to
 * domain_id_alloc() in domain.c and should be merged.
 */
int
mono_thread_small_id_alloc (void)
{
	int i, id = -1;

	mono_os_mutex_lock (&small_id_mutex);

	if (!small_id_table)
		small_id_table = mono_bitset_new (1, 0);

	id = mono_bitset_find_first_unset (small_id_table, small_id_next - 1);
	if (id == -1)
		id = mono_bitset_find_first_unset (small_id_table, -1);

	if (id == -1) {
		MonoBitSet *new_table;
		if (small_id_table->size * 2 >= (1 << 16))
			g_assert_not_reached ();
		new_table = mono_bitset_clone (small_id_table, small_id_table->size * 2);
		id = mono_bitset_find_first_unset (new_table, small_id_table->size - 1);

		mono_bitset_free (small_id_table);
		small_id_table = new_table;
	}

	g_assert (!mono_bitset_test_fast (small_id_table, id));
	mono_bitset_set_fast (small_id_table, id);

	small_id_next++;
	if (small_id_next >= small_id_table->size)
		small_id_next = 0;

	g_assert (id < HAZARD_TABLE_MAX_SIZE);
	if (id >= hazard_table_size) {
#if MONO_SMALL_CONFIG
		hazard_table = g_malloc0 (sizeof (MonoThreadHazardPointers) * HAZARD_TABLE_MAX_SIZE);
		hazard_table_size = HAZARD_TABLE_MAX_SIZE;
#else
		gpointer page_addr;
#if defined(__PASE__)
		/*
		 * HACK: allocating the table with none prot will cause i 7.1
		 * to segfault when accessing or protecting it
		 */
		int table_prot = MONO_MMAP_READ | MONO_MMAP_WRITE;
#else
		int table_prot = MONO_MMAP_NONE;
#endif
		int pagesize = mono_pagesize ();
		int num_pages = (hazard_table_size * sizeof (MonoThreadHazardPointers) + pagesize - 1) / pagesize;

		if (hazard_table == NULL) {
			hazard_table = (MonoThreadHazardPointers *volatile) mono_valloc (NULL,
				sizeof (MonoThreadHazardPointers) * HAZARD_TABLE_MAX_SIZE,
				table_prot, MONO_MEM_ACCOUNT_HAZARD_POINTERS);
		}

		g_assert (hazard_table != NULL);
		page_addr = (guint8*)hazard_table + num_pages * pagesize;

		mono_mprotect (page_addr, pagesize, MONO_MMAP_READ | MONO_MMAP_WRITE);

		++num_pages;
		hazard_table_size = num_pages * pagesize / sizeof (MonoThreadHazardPointers);

#endif
		g_assert (id < hazard_table_size);
		for (i = 0; i < HAZARD_POINTER_COUNT; ++i)
			hazard_table [id].hazard_pointers [i] = NULL;
	}

	if (id > highest_small_id) {
		highest_small_id = id;
		mono_memory_write_barrier ();
	}

	mono_os_mutex_unlock (&small_id_mutex);

	return id;
}
Beispiel #30
0
static inline void
dynamic_images_lock (void)
{
	mono_os_mutex_lock (&dynamic_images_mutex);
}