darling-libobjc2/dtable.c

735 lines
19 KiB
C

#define __BSD_VISIBLE 1
#include <stdio.h>
#include <stdlib.h>
#include <assert.h>
#include "objc/runtime.h"
#include "sarray2.h"
#include "selector.h"
#include "class.h"
#include "lock.h"
#include "method_list.h"
#include "slot_pool.h"
#include "dtable.h"
#include "visibility.h"
PRIVATE dtable_t uninstalled_dtable;
/** Head of the list of temporary dtables. Protected by initialize_lock. */
PRIVATE InitializingDtable *temporary_dtables;
/** Lock used to protect the temporary dtables list. */
PRIVATE mutex_t initialize_lock;
/** The size of the largest dtable, rounded up to the nearest power of two. */
static uint32_t dtable_depth = 8;
struct objc_slot* objc_get_slot(Class cls, SEL selector);
/**
* Returns YES if the class implements a method for the specified selector, NO
* otherwise.
*/
static BOOL ownsMethod(Class cls, SEL sel)
{
struct objc_slot *slot = objc_get_slot(cls, sel);
if ((NULL != slot) && (slot->owner == cls))
{
return YES;
}
return NO;
}
/**
* Checks whether the class implements memory management methods, and whether
* they are safe to use with ARC.
*/
static void checkARCAccessors(Class cls)
{
static SEL retain, release, autorelease, isARC;
if (NULL == retain)
{
retain = sel_registerName("retain");
release = sel_registerName("release");
autorelease = sel_registerName("autorelease");
isARC = sel_registerName("_ARCCompliantRetainRelease");
}
if (ownsMethod(cls, isARC))
{
objc_set_class_flag(cls, objc_class_flag_fast_arc);
return;
}
struct objc_slot *slot = objc_get_slot(cls, retain);
if (!ownsMethod(slot->owner, isARC))
{
objc_clear_class_flag(cls, objc_class_flag_fast_arc);
}
slot = objc_get_slot(cls, release);
if (!ownsMethod(slot->owner, isARC))
{
objc_clear_class_flag(cls, objc_class_flag_fast_arc);
}
slot = objc_get_slot(cls, autorelease);
if (!ownsMethod(slot->owner, isARC))
{
objc_clear_class_flag(cls, objc_class_flag_fast_arc);
}
}
static void collectMethodsForMethodListToSparseArray(
struct objc_method_list *list,
SparseArray *sarray,
BOOL recurse)
{
if (recurse && (NULL != list->next))
{
collectMethodsForMethodListToSparseArray(list->next, sarray, YES);
}
for (unsigned i=0 ; i<list->count ; i++)
{
SparseArrayInsert(sarray, list->methods[i].selector->index,
(void*)&list->methods[i]);
}
}
#ifdef __OBJC_LOW_MEMORY__
struct objc_dtable
{
struct cache_line
{
uint32_t idx;
uint32_t version;
struct objc_slot *slot;
} cache[8];
mutex_t lock;
struct objc_slot **slots;
int slot_count;
int slot_size;
Class cls;
};
static void update_dtable(dtable_t dtable);
PRIVATE void init_dispatch_tables ()
{
INIT_LOCK(initialize_lock);
}
Class class_getSuperclass(Class);
static dtable_t create_dtable_for_class(Class class, dtable_t root_dtable)
{
// Don't create a dtable for a class that already has one
if (classHasDtable(class)) { return dtable_for_class(class); }
LOCK_RUNTIME_FOR_SCOPE();
// Make sure that another thread didn't create the dtable while we were
// waiting on the lock.
if (classHasDtable(class)) { return dtable_for_class(class); }
// Allocate the dtable
dtable_t dtable = calloc(1, sizeof(struct objc_dtable));
dtable->cls = class;
INIT_LOCK(dtable->lock);
// Initialise it
update_dtable(dtable);
return dtable;
}
PRIVATE void objc_resize_dtables(uint32_t newSize)
{
if (1<<dtable_depth > newSize) { return; }
dtable_depth <<= 1;
}
#define HASH_UID(uid) ((uid >> 2) & 7)
static struct objc_slot* check_cache(dtable_t dtable, uint32_t uid)
{
int i = HASH_UID(uid);
volatile struct cache_line *cache = &dtable->cache[i];
int32_t initial_idx = cache->idx;
if (initial_idx != uid)
{
return NULL;
}
struct objc_slot *slot;
int32_t idx;
int32_t version;
do
{
initial_idx = cache->idx;
version = cache->version;
slot = cache->slot;
__sync_synchronize();
idx = cache->idx;
} while (idx != initial_idx);
return (idx == uid) && (slot->version == version) ? slot : NULL;
}
static struct objc_slot *find_slot(uint32_t uid,
struct objc_slot **slots, int slot_count)
{
if (slot_count == 0) { return NULL; }
int idx = slot_count >> 1;
struct objc_slot *slot = slots[idx];
if (slot_count == 1)
{
if (slot->selector->index == uid)
{
return slot;
}
return NULL;
}
if (slot->selector->index > uid)
{
return find_slot(uid, slots, idx);
}
if (slot->selector->index < uid)
{
return find_slot(uid, slots+idx, slot_count - idx);
}
if (slot->selector->index == uid)
{
return slot;
}
return NULL;
}
static int slot_cmp(const void *l, const void *r)
{
return (*(struct objc_slot**)l)->selector->index
- (*(struct objc_slot**)r)->selector->index;
}
static void insert_slot(dtable_t dtable, struct objc_slot *slot, uint32_t idx)
{
if (dtable->slot_size == dtable->slot_count)
{
dtable->slot_size += 16;
dtable->slots = realloc(dtable->slots, dtable->slot_size *
sizeof(struct objc_slot));
assert(NULL != dtable->slots && "Out of memory!");
}
dtable->slots[dtable->slot_count++] = slot;
}
static void add_slot_to_dtable(SEL sel, dtable_t dtable, uint32_t
old_slot_count, struct objc_method *m, Class cls)
{
uint32_t idx = sel->index;
struct objc_slot *s = find_slot(idx, dtable->slots, old_slot_count);
if (NULL != s)
{
s->method = m->imp;
s->version++;
}
else
{
struct objc_slot *slot = new_slot_for_method_in_class(m, cls);
slot->selector = sel;
insert_slot(dtable, slot, idx);
if (Nil != cls->super_class)
{
slot = objc_dtable_lookup(dtable_for_class(cls->super_class), idx);
if (NULL != slot)
{
slot->version++;
}
}
}
}
static void update_dtable(dtable_t dtable)
{
Class cls = dtable->cls;
if (NULL == cls->methods) { return; }
SparseArray *methods = SparseArrayNewWithDepth(dtable_depth);
collectMethodsForMethodListToSparseArray((void*)cls->methods, methods, YES);
if (NULL == dtable->slots)
{
dtable->slots = calloc(sizeof(struct objc_slot), 16);
dtable->slot_size = 16;
}
uint32_t old_slot_count = dtable->slot_count;
struct objc_method *m;
uint32_t idx = 0;
while ((m = SparseArrayNext(methods, &idx)))
{
add_slot_to_dtable(m->selector, dtable, old_slot_count, m, cls);
#ifdef TYPE_DEPENDENT_DISPATCH
add_slot_to_dtable(sel_getUntyped(m->selector), dtable, old_slot_count, m, cls);
#endif
}
mergesort(dtable->slots, dtable->slot_count, sizeof(struct objc_slot*),
slot_cmp);
SparseArrayDestroy(methods);
}
PRIVATE void objc_update_dtable_for_class(Class cls)
{
dtable_t dtable = dtable_for_class(cls);
// Be lazy about constructing the slot list - don't do it unless we actually
// need to access it
if ((NULL == dtable) || (NULL == dtable->slots)) { return; }
LOCK_FOR_SCOPE(&dtable->lock);
update_dtable(dtable);
}
PRIVATE void add_method_list_to_class(Class cls,
struct objc_method_list *list)
{
objc_update_dtable_for_class(cls);
}
PRIVATE struct objc_slot* objc_dtable_lookup(dtable_t dtable, uint32_t uid)
{
if (NULL == dtable) { return NULL; }
struct objc_slot *slot = check_cache(dtable, uid);
if (NULL != slot)
{
return slot;
}
LOCK_FOR_SCOPE(&dtable->lock);
if (NULL == dtable->slots)
{
update_dtable(dtable);
}
slot = find_slot(uid, dtable->slots, dtable->slot_count);
if (NULL != slot)
{
int i = HASH_UID(uid);
volatile struct cache_line *cache = &dtable->cache[i];
// Simplified multiword atomic exchange. First we write a value that
// is an invalid but recognisable UID and then a memory barrier. Then
// we complete the update and set the index pointer if and only if
// there have been no other modifications in the meantime
cache->idx = -uid;
__sync_synchronize();
cache->version = slot->version;
cache->slot = slot;
__sync_bool_compare_and_swap(&cache->idx, -uid, uid);
return slot;
}
if (NULL != dtable->cls->super_class)
{
return objc_dtable_lookup(dtable_for_class(dtable->cls->super_class), uid);
}
return NULL;
}
PRIVATE dtable_t objc_copy_dtable_for_class(dtable_t old, Class cls)
{
dtable_t dtable = calloc(1, sizeof(struct objc_dtable));
dtable->cls = cls;
INIT_LOCK(dtable->lock);
return dtable;
}
PRIVATE void free_dtable(dtable_t dtable)
{
if (NULL != dtable->slots)
{
free(dtable->slots);
}
DESTROY_LOCK(&dtable->lock);
free(dtable);
}
#else
PRIVATE void init_dispatch_tables ()
{
INIT_LOCK(initialize_lock);
uninstalled_dtable = SparseArrayNewWithDepth(dtable_depth);
}
static BOOL installMethodInDtable(Class class,
Class owner,
SparseArray *dtable,
struct objc_method *method,
BOOL replaceExisting)
{
ASSERT(uninstalled_dtable != dtable);
uint32_t sel_id = method->selector->index;
struct objc_slot *slot = SparseArrayLookup(dtable, sel_id);
if (NULL != slot)
{
// If this method is the one already installed, pretend to install it again.
if (slot->method == method->imp) { return NO; }
// If the existing slot is for this class, we can just replace the
// implementation. We don't need to bump the version; this operation
// updates cached slots, it doesn't invalidate them.
if (slot->owner == owner)
{
// Don't replace methods if we're not meant to (if they're from
// later in a method list, for example)
if (!replaceExisting) { return NO; }
slot->method = method->imp;
return YES;
}
// Check whether the owner of this method is a subclass of the one that
// owns this method. If it is, then we don't want to install this
// method irrespective of other cases, because it has been overridden.
for (Class installedFor = slot->owner ;
Nil != installedFor ;
installedFor = installedFor->super_class)
{
if (installedFor == owner)
{
return NO;
}
}
}
struct objc_slot *oldSlot = slot;
slot = new_slot_for_method_in_class((void*)method, owner);
SparseArrayInsert(dtable, sel_id, slot);
// In TDD mode, we also register the first typed method that we
// encounter as the untyped version.
#ifdef TYPE_DEPENDENT_DISPATCH
SparseArrayInsert(dtable, get_untyped_idx(method->selector), slot);
#endif
// Invalidate the old slot, if there is one.
if (NULL != oldSlot)
{
oldSlot->version++;
}
return YES;
}
static void installMethodsInClass(Class cls,
Class owner,
SparseArray *methods,
BOOL replaceExisting)
{
SparseArray *dtable = dtable_for_class(cls);
assert(uninstalled_dtable != dtable);
uint32_t idx = 0;
struct objc_method *m;
while ((m = SparseArrayNext(methods, &idx)))
{
if (!installMethodInDtable(cls, owner, dtable, m, replaceExisting))
{
// Remove this method from the list, if it wasn't actually installed
SparseArrayInsert(methods, idx, 0);
}
}
}
static void mergeMethodsFromSuperclass(Class super, Class cls, SparseArray *methods)
{
for (struct objc_class *subclass=cls->subclass_list ;
Nil != subclass ; subclass = subclass->sibling_class)
{
// Don't bother updating dtables for subclasses that haven't been
// initialized yet
if (!classHasDtable(subclass)) { continue; }
// Create a new (copy-on-write) array to pass down to children
SparseArray *newMethods = SparseArrayCopy(methods);
// Install all of these methods except ones that are overridden in the
// subclass. All of the methods that we are updating were added in a
// superclass, so we don't replace versions registered to the subclass.
installMethodsInClass(subclass, super, newMethods, YES);
// Recursively add the methods to the subclass's subclasses.
mergeMethodsFromSuperclass(super, subclass, newMethods);
SparseArrayDestroy(newMethods);
}
}
Class class_getSuperclass(Class);
PRIVATE void objc_update_dtable_for_class(Class cls)
{
// Only update real dtables
if (!classHasDtable(cls)) { return; }
LOCK_RUNTIME_FOR_SCOPE();
SparseArray *methods = SparseArrayNewWithDepth(dtable_depth);
collectMethodsForMethodListToSparseArray((void*)cls->methods, methods, YES);
installMethodsInClass(cls, cls, methods, YES);
// Methods now contains only the new methods for this class.
mergeMethodsFromSuperclass(cls, cls, methods);
SparseArrayDestroy(methods);
checkARCAccessors(cls);
}
PRIVATE void add_method_list_to_class(Class cls,
struct objc_method_list *list)
{
// Only update real dtables
if (!classHasDtable(cls)) { return; }
LOCK_RUNTIME_FOR_SCOPE();
SparseArray *methods = SparseArrayNewWithDepth(dtable_depth);
collectMethodsForMethodListToSparseArray(list, methods, NO);
installMethodsInClass(cls, cls, methods, YES);
// Methods now contains only the new methods for this class.
mergeMethodsFromSuperclass(cls, cls, methods);
SparseArrayDestroy(methods);
checkARCAccessors(cls);
}
static dtable_t create_dtable_for_class(Class class, dtable_t root_dtable)
{
// Don't create a dtable for a class that already has one
if (classHasDtable(class)) { return dtable_for_class(class); }
LOCK_RUNTIME_FOR_SCOPE();
// Make sure that another thread didn't create the dtable while we were
// waiting on the lock.
if (classHasDtable(class)) { return dtable_for_class(class); }
Class super = class_getSuperclass(class);
dtable_t dtable;
if (Nil == super)
{
dtable = SparseArrayNewWithDepth(dtable_depth);
}
else
{
dtable_t super_dtable = dtable_for_class(super);
if (super_dtable == uninstalled_dtable)
{
if (super->isa == class)
{
super_dtable = root_dtable;
}
else
{
abort();
}
}
dtable = SparseArrayCopy(super_dtable);
}
// When constructing the initial dtable for a class, we iterate along the
// method list in forward-traversal order. The first method that we
// encounter is always the one that we want to keep, so we instruct
// installMethodInDtable() not to replace methods that are already
// associated with this class.
struct objc_method_list *list = (void*)class->methods;
while (NULL != list)
{
for (unsigned i=0 ; i<list->count ; i++)
{
installMethodInDtable(class, class, dtable, &list->methods[i], NO);
}
list = list->next;
}
return dtable;
}
Class class_table_next(void **e);
PRIVATE void objc_resize_dtables(uint32_t newSize)
{
// If dtables already have enough space to store all registered selectors, do nothing
if (1<<dtable_depth > newSize) { return; }
LOCK_RUNTIME_FOR_SCOPE();
dtable_depth <<= 1;
uint32_t oldMask = uninstalled_dtable->mask;
SparseArrayExpandingArray(uninstalled_dtable);
// Resize all existing dtables
void *e = NULL;
struct objc_class *next;
while ((next = class_table_next(&e)))
{
if (next->dtable != (void*)uninstalled_dtable &&
NULL != next->dtable &&
((SparseArray*)next->dtable)->mask == oldMask)
{
SparseArrayExpandingArray((void*)next->dtable);
}
}
}
PRIVATE dtable_t objc_copy_dtable_for_class(dtable_t old, Class cls)
{
return SparseArrayCopy(old);
}
PRIVATE void free_dtable(dtable_t dtable)
{
SparseArrayDestroy(dtable);
}
#endif // __OBJC_LOW_MEMORY__
LEGACY void update_dispatch_table_for_class(Class cls)
{
static BOOL warned = NO;
if (!warned)
{
fprintf(stderr,
"Warning: Calling deprecated private ObjC runtime function %s\n", __func__);
warned = YES;
}
objc_update_dtable_for_class(cls);
}
void objc_resolve_class(Class);
__attribute__((unused)) static void objc_release_object_lock(id *x)
{
objc_sync_exit(*x);
}
/**
* Macro that is equivalent to @synchronize, for use in C code.
*/
#define LOCK_OBJECT_FOR_SCOPE(obj) \
__attribute__((cleanup(objc_release_object_lock)))\
__attribute__((unused)) id lock_object_pointer = obj;\
objc_sync_enter(obj);
/**
* Remove a buffer from an entry in the initializing dtables list. This is
* called as a cleanup to ensure that it runs even if +initialize throws an
* exception.
*/
static void remove_dtable(InitializingDtable* meta_buffer)
{
LOCK(&initialize_lock);
InitializingDtable *buffer = meta_buffer->next;
// Remove the look-aside buffer entry.
if (temporary_dtables == meta_buffer)
{
temporary_dtables = buffer->next;
}
else
{
InitializingDtable *prev = temporary_dtables;
while (prev->next->class != meta_buffer->class)
{
prev = prev->next;
}
prev->next = buffer->next;
}
UNLOCK(&initialize_lock);
}
/**
* Send a +initialize message to the receiver, if required.
*/
PRIVATE void objc_send_initialize(id object)
{
Class class = object->isa;
// If the first message is sent to an instance (weird, but possible and
// likely for things like NSConstantString, make sure +initialize goes to
// the class not the metaclass.
if (objc_test_class_flag(class, objc_class_flag_meta))
{
class = (Class)object;
}
Class meta = class->isa;
// If this class is already initialized (e.g. in another thread), give up.
if (objc_test_class_flag(class, objc_class_flag_initialized)) { return; }
// Make sure that the class is resolved.
objc_resolve_class(class);
// Make sure that the superclass is initialized first.
if (Nil != class->super_class)
{
objc_send_initialize((id)class->super_class);
}
LOCK(&initialize_lock);
// Superclass +initialize might possibly send a message to this class, in
// which case this method would be called again. See NSObject and
// NSAutoreleasePool +initialize interaction in GNUstep.
if (objc_test_class_flag(class, objc_class_flag_initialized))
{
UNLOCK(&initialize_lock);
return;
}
// Set the initialized flag on both this class and its metaclass, to make
// sure that +initialize is only ever sent once.
objc_set_class_flag(class, objc_class_flag_initialized);
objc_set_class_flag(meta, objc_class_flag_initialized);
dtable_t class_dtable = create_dtable_for_class(class, uninstalled_dtable);
dtable_t dtable = create_dtable_for_class(meta, class_dtable);
static SEL initializeSel = 0;
if (0 == initializeSel)
{
initializeSel = sel_registerName("initialize");
}
struct objc_slot *initializeSlot =
objc_dtable_lookup(dtable, initializeSel->index);
// If there's no initialize method, then don't bother installing and
// removing the initialize dtable, just install both dtables correctly now
if (0 == initializeSlot || initializeSlot->owner != meta)
{
meta->dtable = dtable;
class->dtable = class_dtable;
checkARCAccessors(class);
UNLOCK(&initialize_lock);
return;
}
LOCK_OBJECT_FOR_SCOPE((id)meta);
// Create an entry in the dtable look-aside buffer for this. When sending
// a message to this class in future, the lookup function will check this
// buffer if the receiver's dtable is not installed, and block if
// attempting to send a message to this class.
InitializingDtable buffer = { class, class_dtable, temporary_dtables };
__attribute__((cleanup(remove_dtable)))
InitializingDtable meta_buffer = { meta, dtable, &buffer };
temporary_dtables = &meta_buffer;
UNLOCK(&initialize_lock);
checkARCAccessors(class);
// Store the buffer in the temporary dtables list. Note that it is safe to
// insert it into a global list, even though it's a temporary variable,
// because we will clean it up after this function.
initializeSlot->method((id)class, initializeSel);
// Install the real dtable for both the class and the metaclass. We can do
// this without the lock, because now both ways of accessing the dtable are
// safe. We only need the lock when we remove the cached version.
meta->dtable = dtable;
class->dtable = class_dtable;
}