[threads] Store MonoInternalThread in MonoThreadInfo for use when detaching (#5058)

[mono.git] / mono / metadata / null-gc.c

/**
 * \file
 * GC implementation using malloc: will leak everything, just for testing.
 *
 * Copyright 2001-2003 Ximian, Inc (http://www.ximian.com)
 * Copyright 2004-2011 Novell, Inc (http://www.novell.com)
 * Copyright 2011 Xamarin, Inc (http://www.xamarin.com)
 * Licensed under the MIT license. See LICENSE file in the project root for full license information.
 */

#include "config.h"
#include <glib.h>
#include <mono/metadata/mono-gc.h>
#include <mono/metadata/gc-internals.h>
#include <mono/metadata/runtime.h>
#include <mono/utils/atomic.h>
#include <mono/utils/mono-threads.h>
#include <mono/utils/mono-counters.h>

#ifdef HAVE_NULL_GC

void
mono_gc_base_init (void)
{
        mono_counters_init ();

#ifndef HOST_WIN32
        mono_w32handle_init ();
#endif

        mono_thread_callbacks_init ();
        mono_thread_info_init (sizeof (MonoThreadInfo));

        mono_thread_info_attach ();
}

void
mono_gc_base_cleanup (void)
{
}

void
mono_gc_collect (int generation)
{
}

int
mono_gc_max_generation (void)
{
        return 0;
}

int
mono_gc_get_generation  (MonoObject *object)
{
        return 0;
}

int
mono_gc_collection_count (int generation)
{
        return 0;
}

void
mono_gc_add_memory_pressure (gint64 value)
{
}

/* maybe track the size, not important, though */
int64_t
mono_gc_get_used_size (void)
{
        return 1024*1024;
}

int64_t
mono_gc_get_heap_size (void)
{
        return 2*1024*1024;
}

gboolean
mono_gc_is_gc_thread (void)
{
        return TRUE;
}

int
mono_gc_walk_heap (int flags, MonoGCReferences callback, void *data)
{
        return 1;
}

gboolean
mono_object_is_alive (MonoObject* o)
{
        return TRUE;
}

int
mono_gc_register_root (char *start, size_t size, void *descr, MonoGCRootSource source, const char *msg)
{
        return TRUE;
}

void
mono_gc_deregister_root (char* addr)
{
}

void
mono_gc_weak_link_add (void **link_addr, MonoObject *obj, gboolean track)
{
        *link_addr = obj;
}

void
mono_gc_weak_link_remove (void **link_addr, gboolean track)
{
        *link_addr = NULL;
}

MonoObject*
mono_gc_weak_link_get (void **link_addr)
{
        return *link_addr;
}

void*
mono_gc_make_descr_for_string (gsize *bitmap, int numbits)
{
        return NULL;
}

void*
mono_gc_make_descr_for_object (gsize *bitmap, int numbits, size_t obj_size)
{
        return NULL;
}

void*
mono_gc_make_descr_for_array (int vector, gsize *elem_bitmap, int numbits, size_t elem_size)
{
        return NULL;
}

void*
mono_gc_make_descr_from_bitmap (gsize *bitmap, int numbits)
{
        return NULL;
}

void*
mono_gc_make_vector_descr (void)
{
        return NULL;
}

void*
mono_gc_make_root_descr_all_refs (int numbits)
{
        return NULL;
}

void*
mono_gc_alloc_fixed (size_t size, void *descr, MonoGCRootSource source, const char *msg)
{
        return g_malloc0 (size);
}

void
mono_gc_free_fixed (void* addr)
{
        g_free (addr);
}

void *
mono_gc_alloc_obj (MonoVTable *vtable, size_t size)
{
        MonoObject *obj = g_calloc (1, size);

        obj->vtable = vtable;

        return obj;
}

void *
mono_gc_alloc_vector (MonoVTable *vtable, size_t size, uintptr_t max_length)
{
        MonoArray *obj = g_calloc (1, size);

        obj->obj.vtable = vtable;
        obj->max_length = max_length;

        return obj;
}

void *
mono_gc_alloc_array (MonoVTable *vtable, size_t size, uintptr_t max_length, uintptr_t bounds_size)
{
        MonoArray *obj = g_calloc (1, size);

        obj->obj.vtable = vtable;
        obj->max_length = max_length;

        if (bounds_size)
                obj->bounds = (MonoArrayBounds *) ((char *) obj + size - bounds_size);

        return obj;
}

void *
mono_gc_alloc_string (MonoVTable *vtable, size_t size, gint32 len)
{
        MonoString *obj = g_calloc (1, size);

        obj->object.vtable = vtable;
        obj->length = len;
        obj->chars [len] = 0;

        return obj;
}

void*
mono_gc_alloc_mature (MonoVTable *vtable, size_t size)
{
        return mono_gc_alloc_obj (vtable, size);
}

void*
mono_gc_alloc_pinned_obj (MonoVTable *vtable, size_t size)
{
        return mono_gc_alloc_obj (vtable, size);
}

void
mono_gc_wbarrier_set_field (MonoObject *obj, gpointer field_ptr, MonoObject* value)
{
        *(void**)field_ptr = value;
}

void
mono_gc_wbarrier_set_arrayref (MonoArray *arr, gpointer slot_ptr, MonoObject* value)
{
        *(void**)slot_ptr = value;
}

void
mono_gc_wbarrier_arrayref_copy (gpointer dest_ptr, gpointer src_ptr, int count)
{
        mono_gc_memmove_aligned (dest_ptr, src_ptr, count * sizeof (gpointer));
}

void
mono_gc_wbarrier_generic_store (gpointer ptr, MonoObject* value)
{
        *(void**)ptr = value;
}

void
mono_gc_wbarrier_generic_store_atomic (gpointer ptr, MonoObject *value)
{
        InterlockedWritePointer (ptr, value);
}

void
mono_gc_wbarrier_generic_nostore (gpointer ptr)
{
}

void
mono_gc_wbarrier_value_copy (gpointer dest, gpointer src, int count, MonoClass *klass)
{
        mono_gc_memmove_atomic (dest, src, count * mono_class_value_size (klass, NULL));
}

void
mono_gc_wbarrier_object_copy (MonoObject* obj, MonoObject *src)
{
        /* do not copy the sync state */
        mono_gc_memmove_aligned ((char*)obj + sizeof (MonoObject), (char*)src + sizeof (MonoObject),
                        mono_object_class (obj)->instance_size - sizeof (MonoObject));
}

gboolean
mono_gc_is_critical_method (MonoMethod *method)
{
        return FALSE;
}

gpointer
mono_gc_thread_attach (MonoThreadInfo* info)
{
        return info;
}

void
mono_gc_thread_detach_with_lock (MonoThreadInfo *p)
{
}

gboolean
mono_gc_thread_in_critical_region (MonoThreadInfo *info)
{
        return FALSE;
}

int
mono_gc_get_aligned_size_for_allocator (int size)
{
        return size;
}

MonoMethod*
mono_gc_get_managed_allocator (MonoClass *klass, gboolean for_box, gboolean known_instance_size)
{
        return NULL;
}

MonoMethod*
mono_gc_get_managed_array_allocator (MonoClass *klass)
{
        return NULL;
}

MonoMethod*
mono_gc_get_managed_allocator_by_type (int atype, ManagedAllocatorVariant variant)
{
        return NULL;
}

guint32
mono_gc_get_managed_allocator_types (void)
{
        return 0;
}

const char *
mono_gc_get_gc_name (void)
{
        return "null";
}

void
mono_gc_add_weak_track_handle (MonoObject *obj, guint32 gchandle)
{
}

void
mono_gc_change_weak_track_handle (MonoObject *old_obj, MonoObject *obj, guint32 gchandle)
{
}

void
mono_gc_remove_weak_track_handle (guint32 gchandle)
{
}

GSList*
mono_gc_remove_weak_track_object (MonoDomain *domain, MonoObject *obj)
{
        return NULL;
}

void
mono_gc_clear_domain (MonoDomain *domain)
{
}

void
mono_gc_suspend_finalizers (void)
{
}

int
mono_gc_get_suspend_signal (void)
{
        return -1;
}

int
mono_gc_get_restart_signal (void)
{
        return -1;
}

MonoMethod*
mono_gc_get_specific_write_barrier (gboolean is_concurrent)
{
        g_assert_not_reached ();
        return NULL;
}

MonoMethod*
mono_gc_get_write_barrier (void)
{
        g_assert_not_reached ();
        return NULL;
}

void*
mono_gc_invoke_with_gc_lock (MonoGCLockedCallbackFunc func, void *data)
{
        return func (data);
}

char*
mono_gc_get_description (void)
{
        return g_strdup (DEFAULT_GC_NAME);
}

void
mono_gc_set_desktop_mode (void)
{
}

gboolean
mono_gc_is_moving (void)
{
        return FALSE;
}

gboolean
mono_gc_is_disabled (void)
{
        return FALSE;
}

void
mono_gc_wbarrier_range_copy (gpointer _dest, gpointer _src, int size)
{
        g_assert_not_reached ();
}

void*
mono_gc_get_range_copy_func (void)
{
        return &mono_gc_wbarrier_range_copy;
}

guint8*
mono_gc_get_card_table (int *shift_bits, gpointer *card_mask)
{
        g_assert_not_reached ();
        return NULL;
}

gboolean
mono_gc_card_table_nursery_check (void)
{
        g_assert_not_reached ();
        return TRUE;
}

void*
mono_gc_get_nursery (int *shift_bits, size_t *size)
{
        return NULL;
}

gboolean
mono_gc_precise_stack_mark_enabled (void)
{
        return FALSE;
}

FILE *
mono_gc_get_logfile (void)
{
        return NULL;
}

void
mono_gc_params_set (const char* options)
{
}

void
mono_gc_debug_set (const char* options)
{
}

void
mono_gc_conservatively_scan_area (void *start, void *end)
{
        g_assert_not_reached ();
}

void *
mono_gc_scan_object (void *obj, void *gc_data)
{
        g_assert_not_reached ();
        return NULL;
}

gsize*
mono_gc_get_bitmap_for_descr (void *descr, int *numbits)
{
        g_assert_not_reached ();
        return NULL;
}

void
mono_gc_set_gc_callbacks (MonoGCCallbacks *callbacks)
{
}

void
mono_gc_set_stack_end (void *stack_end)
{
}

int
mono_gc_get_los_limit (void)
{
        return G_MAXINT;
}

gboolean
mono_gc_user_markers_supported (void)
{
        return FALSE;
}

void *
mono_gc_make_root_descr_user (MonoGCRootMarkFunc marker)
{
        g_assert_not_reached ();
        return NULL;
}

#ifndef HOST_WIN32
int
mono_gc_pthread_create (pthread_t *new_thread, const pthread_attr_t *attr, void *(*start_routine)(void *), void *arg)
{
        return pthread_create (new_thread, attr, start_routine, arg);
}
#endif

void mono_gc_set_skip_thread (gboolean value)
{
}

#ifdef HOST_WIN32
BOOL APIENTRY mono_gc_dllmain (HMODULE module_handle, DWORD reason, LPVOID reserved)
{
        return TRUE;
}
#endif

guint
mono_gc_get_vtable_bits (MonoClass *klass)
{
        return 0;
}

void
mono_gc_register_altstack (gpointer stack, gint32 stack_size, gpointer altstack, gint32 altstack_size)
{
}

gboolean
mono_gc_is_null (void)
{
        return TRUE;
}
#else

MONO_EMPTY_SOURCE_FILE (null_gc);
#endif /* HAVE_NULL_GC */