/* GNU Objective C Runtime message lookup
Copyright (C) 1993, 1995, 1996, 1997, 1998,
2001, 2002, 2004, 2009, 2010 Free Software Foundation, Inc.
Contributed by Kresten Krab Thorup
This file is part of GCC.
GCC is free software; you can redistribute it and/or modify it under the
terms of the GNU General Public License as published by the Free Software
Foundation; either version 3, or (at your option) any later version.
GCC 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 General Public License for more
details.
Under Section 7 of GPL version 3, you are granted additional
permissions described in the GCC Runtime Library Exception, version
3.1, as published by the Free Software Foundation.
You should have received a copy of the GNU General Public License and
a copy of the GCC Runtime Library Exception along with this program;
see the files COPYING3 and COPYING.RUNTIME respectively. If not, see
. */
/* Uncommented the following line to enable debug logging. Use this
only while debugging the runtime. */
/* #define DEBUG 1 */
/* FIXME: This file has no business including tm.h. */
/* FIXME: This should be using libffi instead of __builtin_apply
and friends. */
#include "objc-private/common.h"
#include "objc-private/error.h"
#include "tconfig.h"
#include "coretypes.h"
#include "tm.h"
#include "objc/runtime.h"
#include "objc/message.h" /* For objc_msg_lookup(), objc_msg_lookup_super(). */
#include "objc/thr.h"
#include "objc-private/module-abi-8.h"
#include "objc-private/runtime.h"
#include "objc-private/hash.h"
#include "objc-private/sarray.h"
#include "objc-private/selector.h" /* For sel_is_mapped() */
#include "runtime-info.h"
#include /* For assert */
#include /* For strlen */
/* This is how we hack STRUCT_VALUE to be 1 or 0. */
#define gen_rtx(args...) 1
#define gen_rtx_MEM(args...) 1
#define gen_rtx_REG(args...) 1
/* Already defined in gcc/coretypes.h. So prevent double definition warning. */
#undef rtx
#define rtx int
#if ! defined (STRUCT_VALUE) || STRUCT_VALUE == 0
#define INVISIBLE_STRUCT_RETURN 1
#else
#define INVISIBLE_STRUCT_RETURN 0
#endif
/* The uninstalled dispatch table. */
struct sarray *__objc_uninstalled_dtable = 0; /* !T:MUTEX */
/* Two hooks for method forwarding. If either is set, it is invoked to
* return a function that performs the real forwarding. If both are
* set, the result of __objc_msg_forward2 will be preferred over that
* of __objc_msg_forward. If both return NULL or are unset, the
* libgcc based functions (__builtin_apply and friends) are used. */
IMP (*__objc_msg_forward) (SEL) = NULL;
IMP (*__objc_msg_forward2) (id, SEL) = NULL;
/* Send +initialize to class. */
static void __objc_send_initialize (Class);
/* Forward declare some functions */
static void __objc_install_dtable_for_class (Class cls);
static void __objc_prepare_dtable_for_class (Class cls);
static void __objc_install_prepared_dtable_for_class (Class cls);
static struct sarray *__objc_prepared_dtable_for_class (Class cls);
static IMP __objc_get_prepared_imp (Class cls,SEL sel);
/* Various forwarding functions that are used based upon the
return type for the selector.
__objc_block_forward for structures.
__objc_double_forward for floats/doubles.
__objc_word_forward for pointers or types that fit in registers. */
static double __objc_double_forward (id, SEL, ...);
static id __objc_word_forward (id, SEL, ...);
typedef struct { id many[8]; } __big;
#if INVISIBLE_STRUCT_RETURN
static __big
#else
static id
#endif
__objc_block_forward (id, SEL, ...);
static struct objc_method * search_for_method_in_hierarchy (Class class, SEL sel);
struct objc_method * search_for_method_in_list (struct objc_method_list * list, SEL op);
id nil_method (id, SEL);
/* Given a selector, return the proper forwarding implementation. */
inline
IMP
__objc_get_forward_imp (id rcv, SEL sel)
{
/* If a custom forwarding hook was registered, try getting a
forwarding function from it. There are two forward routine hooks,
one that takes the receiver as an argument and one that does
not. */
if (__objc_msg_forward2)
{
IMP result;
if ((result = __objc_msg_forward2 (rcv, sel)) != NULL)
return result;
}
if (__objc_msg_forward)
{
IMP result;
if ((result = __objc_msg_forward (sel)) != NULL)
return result;
}
/* In all other cases, use the default forwarding functions built
using __builtin_apply and friends. */
{
const char *t = sel->sel_types;
if (t && (*t == '[' || *t == '(' || *t == '{')
#ifdef OBJC_MAX_STRUCT_BY_VALUE
&& objc_sizeof_type (t) > OBJC_MAX_STRUCT_BY_VALUE
#endif
)
return (IMP)__objc_block_forward;
else if (t && (*t == 'f' || *t == 'd'))
return (IMP)__objc_double_forward;
else
return (IMP)__objc_word_forward;
}
}
/* Selectors for +resolveClassMethod: and +resolveInstanceMethod:.
These are set up at startup. */
static SEL selector_resolveClassMethod = NULL;
static SEL selector_resolveInstanceMethod = NULL;
/* Internal routines use to resolve a class method using
+resolveClassMethod:. 'class' is always a non-Nil class (*not* a
meta-class), and 'sel' is the selector that we are trying to
resolve. This must be called when class is not Nil, and the
dispatch table for class methods has already been installed.
This routine tries to call +resolveClassMethod: to give an
opportunity to resolve the method. If +resolveClassMethod: returns
YES, it tries looking up the method again, and if found, it returns
it. Else, it returns NULL. */
static inline
IMP
__objc_resolve_class_method (Class class, SEL sel)
{
/* We need to lookup +resolveClassMethod:. */
BOOL (*resolveMethodIMP) (id, SEL, SEL);
/* The dispatch table for class methods is already installed and we
don't want any forwarding to happen when looking up this method,
so we just look it up directly. Note that if 'sel' is precisely
+resolveClassMethod:, this would look it up yet again and find
nothing. That's no problem and there's no recursion. */
resolveMethodIMP = (BOOL (*) (id, SEL, SEL))sarray_get_safe
(class->class_pointer->dtable, (size_t) selector_resolveClassMethod->sel_id);
if (resolveMethodIMP && resolveMethodIMP ((id)class, selector_resolveClassMethod, sel))
{
/* +resolveClassMethod: returned YES. Look the method up again.
We already know the dtable is installed. */
/* TODO: There is the case where +resolveClassMethod: is buggy
and returned YES without actually adding the method. We
could maybe print an error message. */
return sarray_get_safe (class->class_pointer->dtable, (size_t) sel->sel_id);
}
return NULL;
}
/* Internal routines use to resolve a instance method using
+resolveInstanceMethod:. 'class' is always a non-Nil class, and
'sel' is the selector that we are trying to resolve. This must be
called when class is not Nil, and the dispatch table for instance
methods has already been installed.
This routine tries to call +resolveInstanceMethod: to give an
opportunity to resolve the method. If +resolveInstanceMethod:
returns YES, it tries looking up the method again, and if found, it
returns it. Else, it returns NULL. */
static inline
IMP
__objc_resolve_instance_method (Class class, SEL sel)
{
/* We need to lookup +resolveInstanceMethod:. */
BOOL (*resolveMethodIMP) (id, SEL, SEL);
/* The dispatch table for class methods may not be already installed
so we have to install it if needed. */
resolveMethodIMP = sarray_get_safe (class->class_pointer->dtable,
(size_t) selector_resolveInstanceMethod->sel_id);
if (resolveMethodIMP == 0)
{
/* Try again after installing the dtable. */
if (class->class_pointer->dtable == __objc_uninstalled_dtable)
{
objc_mutex_lock (__objc_runtime_mutex);
if (class->class_pointer->dtable == __objc_uninstalled_dtable)
__objc_install_dtable_for_class (class->class_pointer);
objc_mutex_unlock (__objc_runtime_mutex);
}
resolveMethodIMP = sarray_get_safe (class->class_pointer->dtable,
(size_t) selector_resolveInstanceMethod->sel_id);
}
if (resolveMethodIMP && resolveMethodIMP ((id)class, selector_resolveInstanceMethod, sel))
{
/* +resolveInstanceMethod: returned YES. Look the method up
again. We already know the dtable is installed. */
/* TODO: There is the case where +resolveInstanceMethod: is
buggy and returned YES without actually adding the method.
We could maybe print an error message. */
return sarray_get_safe (class->dtable, (size_t) sel->sel_id);
}
return NULL;
}
/* Given a CLASS and selector, return the implementation corresponding
to the method of the selector.
If CLASS is a class, the instance method is returned.
If CLASS is a meta class, the class method is returned.
Since this requires the dispatch table to be installed, this function
will implicitly invoke +initialize for CLASS if it hasn't been
invoked yet. This also insures that +initialize has been invoked
when the returned implementation is called directly.
The forwarding hooks require the receiver as an argument (if they are to
perform dynamic lookup in proxy objects etc), so this function has a
receiver argument to be used with those hooks. */
static inline
IMP
get_implementation (id receiver, Class class, SEL sel)
{
void *res;
if (class->dtable == __objc_uninstalled_dtable)
{
/* The dispatch table needs to be installed. */
objc_mutex_lock (__objc_runtime_mutex);
/* Double-checked locking pattern: Check
__objc_uninstalled_dtable again in case another thread
installed the dtable while we were waiting for the lock to be
released. */
if (class->dtable == __objc_uninstalled_dtable)
__objc_install_dtable_for_class (class);
/* If the dispatch table is not yet installed, we are still in
the process of executing +initialize. But the implementation
pointer should be available in the prepared ispatch table if
it exists at all. */
if (class->dtable == __objc_uninstalled_dtable)
{
assert (__objc_prepared_dtable_for_class (class) != 0);
res = __objc_get_prepared_imp (class, sel);
}
else
res = 0;
objc_mutex_unlock (__objc_runtime_mutex);
/* Call ourselves with the installed dispatch table and get the
real method. */
if (!res)
res = get_implementation (receiver, class, sel);
}
else
{
/* The dispatch table has been installed. */
res = sarray_get_safe (class->dtable, (size_t) sel->sel_id);
if (res == 0)
{
/* The dispatch table has been installed, and the method is
not in the dispatch table. So the method just doesn't
exist for the class. */
/* Try going through the +resolveClassMethod: or
+resolveInstanceMethod: process. */
if (CLS_ISMETA (class))
{
/* We have the meta class, but we need to invoke the
+resolveClassMethod: method on the class. So, we
need to obtain the class from the meta class, which
we do using the fact that both the class and the
meta-class have the same name. */
Class realClass = objc_lookUpClass (class->name);
if (realClass)
res = __objc_resolve_class_method (realClass, sel);
}
else
res = __objc_resolve_instance_method (class, sel);
if (res == 0)
res = __objc_get_forward_imp (receiver, sel);
}
}
return res;
}
inline
IMP
get_imp (Class class, SEL sel)
{
/* In a vanilla implementation we would first check if the dispatch
table is installed. Here instead, to get more speed in the
standard case (that the dispatch table is installed) we first try
to get the imp using brute force. Only if that fails, we do what
we should have been doing from the very beginning, that is, check
if the dispatch table needs to be installed, install it if it's
not installed, and retrieve the imp from the table if it's
installed. */
void *res = sarray_get_safe (class->dtable, (size_t) sel->sel_id);
if (res == 0)
{
res = get_implementation(nil, class, sel);
}
return res;
}
/* The new name of get_imp(). */
IMP
class_getMethodImplementation (Class class_, SEL selector)
{
if (class_ == Nil || selector == NULL)
return NULL;
/* get_imp is inlined, so we're good. */
return get_imp (class_, selector);
}
/* Given a method, return its implementation. This has been replaced
by method_getImplementation() in the modern API. */
IMP
method_get_imp (struct objc_method * method)
{
return (method != (struct objc_method *)0) ? method->method_imp : (IMP)0;
}
/* Query if an object can respond to a selector, returns YES if the
object implements the selector otherwise NO. Does not check if the
method can be forwarded. Since this requires the dispatch table to
installed, this function will implicitly invoke +initialize for the
class of OBJECT if it hasn't been invoked yet. */
inline
BOOL
__objc_responds_to (id object, SEL sel)
{
void *res;
struct sarray *dtable;
/* Install dispatch table if need be */
dtable = object->class_pointer->dtable;
if (dtable == __objc_uninstalled_dtable)
{
objc_mutex_lock (__objc_runtime_mutex);
if (object->class_pointer->dtable == __objc_uninstalled_dtable)
__objc_install_dtable_for_class (object->class_pointer);
/* If the dispatch table is not yet installed, we are still in
the process of executing +initialize. Yet the dispatch table
should be available. */
if (object->class_pointer->dtable == __objc_uninstalled_dtable)
{
dtable = __objc_prepared_dtable_for_class (object->class_pointer);
assert (dtable);
}
else
dtable = object->class_pointer->dtable;
objc_mutex_unlock (__objc_runtime_mutex);
}
/* Get the method from the dispatch table. */
res = sarray_get_safe (dtable, (size_t) sel->sel_id);
return (res != 0) ? YES : NO;
}
BOOL
class_respondsToSelector (Class class_, SEL selector)
{
struct sarray *dtable;
void *res;
if (class_ == Nil || selector == NULL)
return NO;
/* Install dispatch table if need be. */
dtable = class_->dtable;
if (dtable == __objc_uninstalled_dtable)
{
objc_mutex_lock (__objc_runtime_mutex);
if (class_->dtable == __objc_uninstalled_dtable)
__objc_install_dtable_for_class (class_);
/* If the dispatch table is not yet installed,
we are still in the process of executing +initialize.
Yet the dispatch table should be available. */
if (class_->dtable == __objc_uninstalled_dtable)
{
dtable = __objc_prepared_dtable_for_class (class_);
assert (dtable);
}
else
dtable = class_->dtable;
objc_mutex_unlock (__objc_runtime_mutex);
}
/* Get the method from the dispatch table. */
res = sarray_get_safe (dtable, (size_t) selector->sel_id);
return (res != 0) ? YES : NO;
}
/* This is the lookup function. All entries in the table are either a
valid method *or* zero. If zero then either the dispatch table
needs to be installed or it doesn't exist and forwarding is
attempted. */
IMP
objc_msg_lookup (id receiver, SEL op)
{
IMP result;
if (receiver)
{
/* First try a quick lookup assuming the dispatch table exists. */
result = sarray_get_safe (receiver->class_pointer->dtable,
(sidx)op->sel_id);
if (result == 0)
{
/* Not found ... call get_implementation () to install the
dispatch table and call +initialize as required,
providing the method implementation or a forwarding
function. */
result = get_implementation (receiver, receiver->class_pointer, op);
}
return result;
}
else
return (IMP)nil_method;
}
IMP
objc_msg_lookup_super (struct objc_super *super, SEL sel)
{
if (super->self)
return get_imp (super->super_class, sel);
else
return (IMP)nil_method;
}
/* Temporarily defined here until objc_msg_sendv() goes away. */
char *method_get_first_argument (struct objc_method *,
arglist_t argframe,
const char **type);
char *method_get_next_argument (arglist_t argframe,
const char **type);
int method_get_sizeof_arguments (struct objc_method *);
struct objc_method *
class_get_instance_method (Class class, SEL op);
retval_t
objc_msg_sendv (id object, SEL op, arglist_t arg_frame)
{
struct objc_method *m = class_get_instance_method (object->class_pointer, op);
const char *type;
*((id *) method_get_first_argument (m, arg_frame, &type)) = object;
*((SEL *) method_get_next_argument (arg_frame, &type)) = op;
return __builtin_apply ((apply_t) m->method_imp,
arg_frame,
method_get_sizeof_arguments (m));
}
void
__objc_init_dispatch_tables ()
{
__objc_uninstalled_dtable = sarray_new (200, 0);
/* TODO: It would be cool to register typed selectors here. */
selector_resolveClassMethod = sel_registerName ("resolveClassMethod:");
selector_resolveInstanceMethod = sel_registerName ("resolveInstanceMethod:");
}
/* Install dummy table for class which causes the first message to
that class (or instances hereof) to be initialized properly. */
void
__objc_install_premature_dtable (Class class)
{
assert (__objc_uninstalled_dtable);
class->dtable = __objc_uninstalled_dtable;
}
/* Send +initialize to class if not already done. */
static void
__objc_send_initialize (Class class)
{
/* This *must* be a class object. */
assert (CLS_ISCLASS (class));
assert (! CLS_ISMETA (class));
/* class_add_method_list/__objc_update_dispatch_table_for_class may
have reset the dispatch table. The canonical way to insure that
we send +initialize just once, is this flag. */
if (! CLS_ISINITIALIZED (class))
{
DEBUG_PRINTF ("+initialize: need to initialize class '%s'\n", class->name);
CLS_SETINITIALIZED (class);
CLS_SETINITIALIZED (class->class_pointer);
/* Create the garbage collector type memory description. */
__objc_generate_gc_type_description (class);
if (class->super_class)
__objc_send_initialize (class->super_class);
{
SEL op = sel_registerName ("initialize");
IMP imp = 0;
struct objc_method_list * method_list = class->class_pointer->methods;
while (method_list)
{
int i;
struct objc_method * method;
for (i = 0; i < method_list->method_count; i++)
{
method = &(method_list->method_list[i]);
if (method->method_name
&& method->method_name->sel_id == op->sel_id)
{
imp = method->method_imp;
break;
}
}
if (imp)
break;
method_list = method_list->method_next;
}
if (imp)
{
DEBUG_PRINTF (" begin of [%s +initialize]\n", class->name);
(*imp) ((id) class, op);
DEBUG_PRINTF (" end of [%s +initialize]\n", class->name);
}
#ifdef DEBUG
else
{
DEBUG_PRINTF (" class '%s' has no +initialize method\n", class->name);
}
#endif
}
}
}
/* Walk on the methods list of class and install the methods in the
reverse order of the lists. Since methods added by categories are
before the methods of class in the methods list, this allows
categories to substitute methods declared in class. However if
more than one category replaces the same method nothing is
guaranteed about what method will be used. Assumes that
__objc_runtime_mutex is locked down. */
static void
__objc_install_methods_in_dtable (struct sarray *dtable, struct objc_method_list * method_list)
{
int i;
if (! method_list)
return;
if (method_list->method_next)
__objc_install_methods_in_dtable (dtable, method_list->method_next);
for (i = 0; i < method_list->method_count; i++)
{
struct objc_method * method = &(method_list->method_list[i]);
sarray_at_put_safe (dtable,
(sidx) method->method_name->sel_id,
method->method_imp);
}
}
void
__objc_update_dispatch_table_for_class (Class class)
{
Class next;
struct sarray *arr;
DEBUG_PRINTF (" _objc_update_dtable_for_class (%s)\n", class->name);
objc_mutex_lock (__objc_runtime_mutex);
/* Not yet installed -- skip it unless in +initialize. */
if (class->dtable == __objc_uninstalled_dtable)
{
if (__objc_prepared_dtable_for_class (class))
{
/* There is a prepared table so we must be initialising this
class ... we must re-do the table preparation. */
__objc_prepare_dtable_for_class (class);
}
objc_mutex_unlock (__objc_runtime_mutex);
return;
}
arr = class->dtable;
__objc_install_premature_dtable (class); /* someone might require it... */
sarray_free (arr); /* release memory */
/* Could have been lazy... */
__objc_install_dtable_for_class (class);
if (class->subclass_list) /* Traverse subclasses. */
for (next = class->subclass_list; next; next = next->sibling_class)
__objc_update_dispatch_table_for_class (next);
objc_mutex_unlock (__objc_runtime_mutex);
}
/* This function adds a method list to a class. This function is
typically called by another function specific to the run-time. As
such this function does not worry about thread safe issues.
This one is only called for categories. Class objects have their
methods installed right away, and their selectors are made into
SEL's by the function __objc_register_selectors_from_class. */
void
class_add_method_list (Class class, struct objc_method_list * list)
{
/* Passing of a linked list is not allowed. Do multiple calls. */
assert (! list->method_next);
__objc_register_selectors_from_list(list);
/* Add the methods to the class's method list. */
list->method_next = class->methods;
class->methods = list;
/* Update the dispatch table of class. */
__objc_update_dispatch_table_for_class (class);
}
struct objc_method *
class_get_instance_method (Class class, SEL op)
{
return search_for_method_in_hierarchy (class, op);
}
struct objc_method *
class_get_class_method (MetaClass class, SEL op)
{
return search_for_method_in_hierarchy (class, op);
}
struct objc_method *
class_getInstanceMethod (Class class_, SEL selector)
{
struct objc_method *m;
if (class_ == Nil || selector == NULL)
return NULL;
m = search_for_method_in_hierarchy (class_, selector);
if (m)
return m;
/* Try going through +resolveInstanceMethod:, and do the search
again if successful. */
if (__objc_resolve_instance_method (class_, selector))
return search_for_method_in_hierarchy (class_, selector);
return NULL;
}
struct objc_method *
class_getClassMethod (Class class_, SEL selector)
{
struct objc_method *m;
if (class_ == Nil || selector == NULL)
return NULL;
m = search_for_method_in_hierarchy (class_->class_pointer,
selector);
if (m)
return m;
/* Try going through +resolveClassMethod:, and do the search again
if successful. */
if (__objc_resolve_class_method (class_, selector))
return search_for_method_in_hierarchy (class_->class_pointer,
selector);
return NULL;
}
BOOL
class_addMethod (Class class_, SEL selector, IMP implementation,
const char *method_types)
{
struct objc_method_list *method_list;
struct objc_method *method;
const char *method_name;
if (class_ == Nil || selector == NULL || implementation == NULL
|| method_types == NULL || (strcmp (method_types, "") == 0))
return NO;
method_name = sel_getName (selector);
if (method_name == NULL)
return NO;
/* If the method already exists in the class, return NO. It is fine
if the method already exists in the superclass; in that case, we
are overriding it. */
if (CLS_IS_IN_CONSTRUCTION (class_))
{
/* The class only contains a list of methods; they have not been
registered yet, ie, the method_name of each of them is still
a string, not a selector. Iterate manually over them to
check if we have already added the method. */
struct objc_method_list * method_list = class_->methods;
while (method_list)
{
int i;
/* Search the method list. */
for (i = 0; i < method_list->method_count; ++i)
{
struct objc_method * method = &method_list->method_list[i];
if (method->method_name
&& strcmp ((char *)method->method_name, method_name) == 0)
return NO;
}
/* The method wasn't found. Follow the link to the next list of
methods. */
method_list = method_list->method_next;
}
/* The method wasn't found. It's a new one. Go ahead and add
it. */
}
else
{
/* Do the standard lookup. This assumes the selectors are
mapped. */
if (search_for_method_in_list (class_->methods, selector))
return NO;
}
method_list = (struct objc_method_list *)objc_calloc (1, sizeof (struct objc_method_list));
method_list->method_count = 1;
method = &(method_list->method_list[0]);
method->method_name = objc_malloc (strlen (method_name) + 1);
strcpy ((char *)method->method_name, method_name);
method->method_types = objc_malloc (strlen (method_types) + 1);
strcpy ((char *)method->method_types, method_types);
method->method_imp = implementation;
if (CLS_IS_IN_CONSTRUCTION (class_))
{
/* We only need to add the method to the list. It will be
registered with the runtime when the class pair is registered
(if ever). */
method_list->method_next = class_->methods;
class_->methods = method_list;
}
else
{
/* Add the method to a live class. */
objc_mutex_lock (__objc_runtime_mutex);
class_add_method_list (class_, method_list);
objc_mutex_unlock (__objc_runtime_mutex);
}
return YES;
}
IMP
class_replaceMethod (Class class_, SEL selector, IMP implementation,
const char *method_types)
{
struct objc_method * method;
if (class_ == Nil || selector == NULL || implementation == NULL
|| method_types == NULL)
return NULL;
method = search_for_method_in_hierarchy (class_, selector);
if (method)
{
return method_setImplementation (method, implementation);
}
else
{
class_addMethod (class_, selector, implementation, method_types);
return NULL;
}
}
/* Search for a method starting from the current class up its
hierarchy. Return a pointer to the method's method structure if
found. NULL otherwise. */
static struct objc_method *
search_for_method_in_hierarchy (Class cls, SEL sel)
{
struct objc_method * method = NULL;
Class class;
if (! sel_is_mapped (sel))
return NULL;
/* Scan the method list of the class. If the method isn't found in
the list then step to its super class. */
for (class = cls; ((! method) && class); class = class->super_class)
method = search_for_method_in_list (class->methods, sel);
return method;
}
/* Given a linked list of method and a method's name. Search for the
named method's method structure. Return a pointer to the method's
method structure if found. NULL otherwise. */
struct objc_method *
search_for_method_in_list (struct objc_method_list * list, SEL op)
{
struct objc_method_list * method_list = list;
if (! sel_is_mapped (op))
return NULL;
/* If not found then we'll search the list. */
while (method_list)
{
int i;
/* Search the method list. */
for (i = 0; i < method_list->method_count; ++i)
{
struct objc_method * method = &method_list->method_list[i];
if (method->method_name)
if (method->method_name->sel_id == op->sel_id)
return method;
}
/* The method wasn't found. Follow the link to the next list of
methods. */
method_list = method_list->method_next;
}
return NULL;
}
static retval_t __objc_forward (id object, SEL sel, arglist_t args);
/* Forwarding pointers/integers through the normal registers. */
static id
__objc_word_forward (id rcv, SEL op, ...)
{
void *args, *res;
args = __builtin_apply_args ();
res = __objc_forward (rcv, op, args);
if (res)
__builtin_return (res);
else
return res;
}
/* Specific routine for forwarding floats/double because of
architectural differences on some processors. i386s for example
which uses a floating point stack versus general registers for
floating point numbers. This forward routine makes sure that GCC
restores the proper return values. */
static double
__objc_double_forward (id rcv, SEL op, ...)
{
void *args, *res;
args = __builtin_apply_args ();
res = __objc_forward (rcv, op, args);
__builtin_return (res);
}
#if INVISIBLE_STRUCT_RETURN
static __big
#else
static id
#endif
__objc_block_forward (id rcv, SEL op, ...)
{
void *args, *res;
args = __builtin_apply_args ();
res = __objc_forward (rcv, op, args);
if (res)
__builtin_return (res);
else
#if INVISIBLE_STRUCT_RETURN
return (__big) {{0, 0, 0, 0, 0, 0, 0, 0}};
#else
return nil;
#endif
}
/* This function is called for methods which are not implemented,
unless a custom forwarding routine has been installed. Please note
that most serious users of libobjc (eg, GNUstep base) do install
their own forwarding routines, and hence this is never actually
used. But, if no custom forwarding routine is installed, this is
called when a selector is not recognized. */
static retval_t
__objc_forward (id object, SEL sel, arglist_t args)
{
IMP imp;
static SEL frwd_sel = 0; /* !T:SAFE2 */
SEL err_sel;
/* First try if the object understands forward::. */
if (! frwd_sel)
frwd_sel = sel_get_any_uid ("forward::");
if (__objc_responds_to (object, frwd_sel))
{
imp = get_implementation (object, object->class_pointer, frwd_sel);
return (*imp) (object, frwd_sel, sel, args);
}
/* If the object recognizes the doesNotRecognize: method then we're
going to send it. */
err_sel = sel_get_any_uid ("doesNotRecognize:");
if (__objc_responds_to (object, err_sel))
{
imp = get_implementation (object, object->class_pointer, err_sel);
return (*imp) (object, err_sel, sel);
}
/* The object doesn't recognize the method. Check for responding to
error:. If it does then sent it. */
{
char msg[256 + strlen ((const char *) sel_getName (sel))
+ strlen ((const char *) object->class_pointer->name)];
sprintf (msg, "(%s) %s does not recognize %s",
(CLS_ISMETA (object->class_pointer)
? "class"
: "instance" ),
object->class_pointer->name, sel_getName (sel));
/* The object doesn't respond to doesNotRecognize:. Therefore, a
default action is taken. */
_objc_abort ("%s\n", msg);
return 0;
}
}
void
__objc_print_dtable_stats (void)
{
int total = 0;
objc_mutex_lock (__objc_runtime_mutex);
#ifdef OBJC_SPARSE2
printf ("memory usage: (%s)\n", "2-level sparse arrays");
#else
printf ("memory usage: (%s)\n", "3-level sparse arrays");
#endif
printf ("arrays: %d = %ld bytes\n", narrays,
(long) ((size_t) narrays * sizeof (struct sarray)));
total += narrays * sizeof (struct sarray);
printf ("buckets: %d = %ld bytes\n", nbuckets,
(long) ((size_t) nbuckets * sizeof (struct sbucket)));
total += nbuckets * sizeof (struct sbucket);
printf ("idxtables: %d = %ld bytes\n",
idxsize, (long) ((size_t) idxsize * sizeof (void *)));
total += idxsize * sizeof (void *);
printf ("-----------------------------------\n");
printf ("total: %d bytes\n", total);
printf ("===================================\n");
objc_mutex_unlock (__objc_runtime_mutex);
}
/* Returns the uninstalled dispatch table indicator. If a class'
dispatch table points to __objc_uninstalled_dtable then that means
it needs its dispatch table to be installed. */
struct sarray *
objc_get_uninstalled_dtable (void)
{
return __objc_uninstalled_dtable;
}
static cache_ptr prepared_dtable_table = 0;
/* This function is called by: objc_msg_lookup, get_imp and
__objc_responds_to (and the dispatch table installation functions
themselves) to install a dispatch table for a class.
If CLS is a class, it installs instance methods.
If CLS is a meta class, it installs class methods.
In either case +initialize is invoked for the corresponding class.
The implementation must insure that the dispatch table is not
installed until +initialize completes. Otherwise it opens a
potential race since the installation of the dispatch table is used
as gate in regular method dispatch and we need to guarantee that
+initialize is the first method invoked an that no other thread my
dispatch messages to the class before +initialize completes. */
static void
__objc_install_dtable_for_class (Class cls)
{
/* If the class has not yet had its class links resolved, we must
re-compute all class links. */
if (! CLS_ISRESOLV (cls))
__objc_resolve_class_links ();
/* Make sure the super class has its dispatch table installed or is
at least preparing. We do not need to send initialize for the
super class since __objc_send_initialize will insure that. */
if (cls->super_class
&& cls->super_class->dtable == __objc_uninstalled_dtable
&& !__objc_prepared_dtable_for_class (cls->super_class))
{
__objc_install_dtable_for_class (cls->super_class);
/* The superclass initialisation may have also initialised the
current class, in which case there is no more to do. */
if (cls->dtable != __objc_uninstalled_dtable)
return;
}
/* We have already been prepared but +initialize hasn't completed.
The +initialize implementation is probably sending 'self'
messages. We rely on _objc_get_prepared_imp to retrieve the
implementation pointers. */
if (__objc_prepared_dtable_for_class (cls))
return;
/* We have this function cache the implementation pointers for
_objc_get_prepared_imp but the dispatch table won't be initilized
until __objc_send_initialize completes. */
__objc_prepare_dtable_for_class (cls);
/* We may have already invoked +initialize but
__objc_update_dispatch_table_for_class invoked by
class_add_method_list may have reset dispatch table. */
/* Call +initialize. If we are a real class, we are installing
instance methods. If we are a meta class, we are installing
class methods. The __objc_send_initialize itself will insure
that the message is called only once per class. */
if (CLS_ISCLASS (cls))
__objc_send_initialize (cls);
else
{
/* Retrieve the class from the meta class. */
Class c = objc_getClass (cls->name);
assert (CLS_ISMETA (cls));
assert (c);
__objc_send_initialize (c);
}
/* We install the dispatch table correctly when +initialize completed. */
__objc_install_prepared_dtable_for_class (cls);
}
/* Builds the dispatch table for the class CLS and stores it in a
place where it can be retrieved by __objc_get_prepared_imp until
__objc_install_prepared_dtable_for_class installs it into the
class. The dispatch table should not be installed into the class
until +initialize has completed. */
static void
__objc_prepare_dtable_for_class (Class cls)
{
struct sarray *dtable;
struct sarray *super_dtable;
/* This table could be initialized in init.c. We can not use the
class name since the class maintains the instance methods and the
meta class maintains the the class methods yet both share the
same name. Classes should be unique in any program. */
if (! prepared_dtable_table)
prepared_dtable_table
= objc_hash_new (32,
(hash_func_type) objc_hash_ptr,
(compare_func_type) objc_compare_ptrs);
/* If the class has not yet had its class links resolved, we must
re-compute all class links. */
if (! CLS_ISRESOLV (cls))
__objc_resolve_class_links ();
assert (cls);
assert (cls->dtable == __objc_uninstalled_dtable);
/* If there is already a prepared dtable for this class, we must
replace it with a new version (since there must have been methods
added to or otherwise modified in the class while executing
+initialize, and the table needs to be recomputed. */
dtable = __objc_prepared_dtable_for_class (cls);
if (dtable != 0)
{
objc_hash_remove (prepared_dtable_table, cls);
sarray_free (dtable);
}
/* Now prepare the dtable for population. */
assert (cls != cls->super_class);
if (cls->super_class)
{
/* Inherit the method list from the super class. Yet the super
class may still be initializing in the case when a class
cluster sub class initializes its super classes. */
if (cls->super_class->dtable == __objc_uninstalled_dtable)
__objc_install_dtable_for_class (cls->super_class);
super_dtable = cls->super_class->dtable;
/* If the dispatch table is not yet installed, we are still in
the process of executing +initialize. Yet the dispatch table
should be available. */
if (super_dtable == __objc_uninstalled_dtable)
super_dtable = __objc_prepared_dtable_for_class (cls->super_class);
assert (super_dtable);
dtable = sarray_lazy_copy (super_dtable);
}
else
dtable = sarray_new (__objc_selector_max_index, 0);
__objc_install_methods_in_dtable (dtable, cls->methods);
objc_hash_add (&prepared_dtable_table,
cls,
dtable);
}
/* This wrapper only exists to allow an easy replacement of the lookup
implementation and it is expected that the compiler will optimize
it away. */
static struct sarray *
__objc_prepared_dtable_for_class (Class cls)
{
struct sarray *dtable = 0;
assert (cls);
if (prepared_dtable_table)
dtable = objc_hash_value_for_key (prepared_dtable_table, cls);
/* dtable my be nil, since we call this to check whether we are
currently preparing before we start preparing. */
return dtable;
}
/* Helper function for messages sent to CLS or implementation pointers
retrieved from CLS during +initialize before the dtable is
installed. When a class implicitly initializes another class which
in turn implicitly invokes methods in this class, before the
implementation of +initialize of CLS completes, this returns the
expected implementation. Forwarding remains the responsibility of
objc_msg_lookup. This function should only be called under the
global lock. */
static IMP
__objc_get_prepared_imp (Class cls,SEL sel)
{
struct sarray *dtable;
IMP imp;
assert (cls);
assert (sel);
assert (cls->dtable == __objc_uninstalled_dtable);
dtable = __objc_prepared_dtable_for_class (cls);
assert (dtable);
assert (dtable != __objc_uninstalled_dtable);
imp = sarray_get_safe (dtable, (size_t) sel->sel_id);
/* imp may be Nil if the method does not exist and we may fallback
to the forwarding implementation later. */
return imp;
}
/* When this function is called +initialize should be completed. So
now we are safe to install the dispatch table for the class so that
they become available for other threads that may be waiting in the
lock. */
static void
__objc_install_prepared_dtable_for_class (Class cls)
{
assert (cls);
assert (cls->dtable == __objc_uninstalled_dtable);
cls->dtable = __objc_prepared_dtable_for_class (cls);
assert (cls->dtable);
assert (cls->dtable != __objc_uninstalled_dtable);
objc_hash_remove (prepared_dtable_table, cls);
}