libobjc/THREADS - gcc - Git at Google

 This file describes in little detail the modifications to the
 Objective-C runtime needed to make it thread safe.

 First off, kudos to Galen Hunt who is the author of this great work.

 If you have an comments or just want to know where to
 send me money to express your undying gratitude for threading the
 Objective-C runtime you can reach Galen at:

 	gchunt@cs.rochester.edu

 Any questions, comments, bug reports, etc. should send email either to the
 GCC bug account or to:

 	Scott Christley <scottc@net-community.com>

 * Sarray Threading:

 The most critical component of the Objective-C runtime is the sparse array
 structure (sarray).  Sarrays store object selectors and implementations.
 Following in the tradition of the Objective-C runtime, my threading
 support assumes that fast message dispatching is far more important
 than *ANY* and *ALL* other operations.  The message dispatching thus
 uses *NO* locks on any kind.  In fact, if you look in sarray.h, you
 will notice that the message dispatching has not been modified.
 Instead, I have modified the sarray management functions so that all
 updates to the sarray data structure can be made in parallel will
 message dispatching.

 To support concurrent message dispatching, no dynamically allocated
 sarray data structures are freed while more than one thread is
 operational.  Sarray data structures that are no longer in use are
 kept in a linked list of garbage and are released whenever the program
 is operating with a single thread.  The programmer can also flush the
 garbage list by calling sarray_remove_garbage when the programmer can
 ensure that no message dispatching is taking place concurrently.  The
 amount of un-reclaimed sarray garbage should normally be extremely
 small in a real program as sarray structures are freed only when using
 the "poseAs" functionality and early in program initialization, which
 normally occurs while the program is single threaded.

 ******************************************************************************
 * Static Variables:

 The following variables are either statically or globally defined. This list
 does not include variables which are internal to implementation dependent
 versions of thread-*.c.

 The following threading designations are used:
 	SAFE   : Implicitly thread safe.
 	SINGLE : Must only be used in single thread mode.
 	MUTEX  : Protected by single global mutex objc_runtime_mutex.
 	UNUSED : Not used in the runtime.

 Variable Name:			Usage:  Defined:	Also used in:
 ===========================	======	============	=====================
 __objc_class_hash		MUTEX	class.c
 __objc_class_links_resolved	UNUSED	class.c		runtime.h
 __objc_class_number		MUTEX	class.c
 __objc_dangling_categories	UNUSED	init.c
 __objc_module_list		MUTEX	init.c
 __objc_selector_array		MUTEX	selector.c
 __objc_selector_hash		MUTEX	selector.c
 __objc_selector_max_index	MUTEX	selector.c	sendmsg.c runtime.h
 __objc_selector_names		MUTEX	selector.c
 __objc_thread_exit_status	SAFE	thread.c
 __objc_uninstalled_dtable	MUTEX	sendmsg.c	selector.c
 _objc_load_callback		SAFE	init.c		objc-api.h
 _objc_lookup_class		SAFE	class.c		objc-api.h
 _objc_object_alloc		SINGLE	objects.c	objc-api.h
 _objc_object_copy		SINGLE	objects.c	objc-api.h
 _objc_object_dispose		SINGLE	objects.c	objc-api.h
 frwd_sel			SAFE2	sendmsg.c
 idxsize				MUTEX	sarray.c	sendmsg.c sarray.h
 initialize_sel			SAFE2	sendmsg.c
 narrays				MUTEX	sarray.c	sendmsg.c sarray.h
 nbuckets			MUTEX	sarray.c	sendmsg.c sarray.h
 nindices			MUTEX	sarray.c	sarray.h
 previous_constructors		SAFE1	init.c
 proto_class			SAFE1	init.c
 unclaimed_categories		MUTEX	init.c
 unclaimed_proto_list		MUTEX	init.c
 uninitialized_statics		MUTEX	init.c

 Notes:
 1) Initialized once in unithread mode.
 2) Initialized value will always be same, guaranteed by lock on selector
    hash table.


 ******************************************************************************
 * Frontend/Backend design:

 The design of the Objective-C runtime thread and mutex functions utilizes a
 frontend/backend implementation.

 The frontend, as characterized by the files thr.h and thr.c, is a set
 of platform independent structures and functions which represent the
 user interface.  For example, objc_mutex_lock().  Objective-C programs
 should use these structures and functions for their thread and mutex
 work if they wish to maintain a high degree of portability across
 platforms.

 The backend is currently GCC's gthread code (gthr.h and related).  For
 example, __gthread_objc_mutex_lock().  The thread system is
 automatically configured when GCC is configured.  On most platforms
 this thread backend is able to automatically switch to non-multi-threaded
 mode if the threading library is not linked in.

 If you want to compile libobjc standalone, then you would need to modify
 the configure.ac and makefiles for it and you need to import the
 gthread code from GCC.

 ******************************************************************************
 * Threads:

 The thread system attempts to create multiple threads using whatever
 operating system or library thread support is available.  It does
 assume that all system functions are thread safe.  Notably this means
 that the system implementation of malloc and free must be thread safe.
 If a system has multiple processors, the threads are configured for
 full parallel processing.

 * Backend initialization functions

 __objc_init_thread_system(void), int
 	Initialize the thread subsystem.  Called once by __objc_exec_class.
 	Return -1 if error otherwise return 0.

 __objc_close_thread_system(void), int
 	Closes the thread subsystem, not currently guaranteed to be called.
 	Return -1 if error otherwise return 0.

 *****
 * Frontend thread functions
 * User programs should use these functions.

 objc_thread_detach(SEL selector, id object, id argument), objc_thread_t
 	Creates and detaches a new thread.  The new thread starts by
 	sending the given selector with a single argument to the
 	given object.

 objc_thread_set_priority(int priority), int
 	Sets a thread's relative priority within the program.  Valid
 	options are:

 	OBJC_THREAD_INTERACTIVE_PRIORITY
 	OBJC_THREAD_BACKGROUND_PRIORITY
 	OBJC_THREAD_LOW_PRIORITY

 objc_thread_get_priority(void), int
 	Query a thread's priority.

 objc_thread_yield(void), void
 	Yields processor to another thread with equal or higher
 	priority.  It is up to the system scheduler to determine if
 	the processor is taken or not.

 objc_thread_exit(void), int
 	Terminates a thread.  If this is the last thread executing
 	then the program will terminate.

 objc_thread_id(void), int
 	Returns the current thread's id.

 objc_thread_set_data(void *value), int
 	Set a pointer to the thread's local storage.  Local storage is
 	thread specific.

 objc_thread_get_data(void), void *
 	Returns the pointer to the thread's local storage.

 *****
 * Backend thread functions
 * User programs should *NOT* directly call these functions.

 __gthr_objc_thread_detach(void (*func)(void *arg), void *arg), objc_thread_t
 	Spawns a new thread executing func, called by objc_thread_detach.
 	Return NULL if error otherwise return thread id.

 __gthr_objc_thread_set_priority(int priority), int
 	Set the thread's priority, called by objc_thread_set_priority.
 	Return -1 if error otherwise return 0.

 __gthr_objc_thread_get_priority(void), int
 	Query a thread's priority, called by objc_thread_get_priority.
 	Return -1 if error otherwise return the priority.

 __gthr_objc_thread_yield(void), void
 	Yields the processor, called by objc_thread_yield.

 __gthr_objc_thread_exit(void), int
 	Terminates the thread, called by objc_thread_exit.
 	Return -1 if error otherwise function does not return.

 __gthr_objc_thread_id(void), objc_thread_t
 	Returns the current thread's id, called by objc_thread_id.
 	Return -1 if error otherwise return thread id.

 __gthr_objc_thread_set_data(void *value), int
 	Set pointer for thread local storage, called by objc_thread_set_data.
 	Returns -1 if error otherwise return 0.

 __gthr_objc_thread_get_data(void), void *
 	Returns the pointer to the thread's local storage.
 	Returns NULL if error, called by objc_thread_get_data.


 ******************************************************************************
 * Mutexes:

 Mutexes can be locked recursively.  Each locked mutex remembers
 its owner (by thread id) and how many times it has been locked.  The
 last unlock on a mutex removes the system lock and allows other
 threads to access the mutex.

 *****
 * Frontend mutex functions
 * User programs should use these functions.

 objc_mutex_allocate(void), objc_mutex_t
 	Allocates a new mutex.  Mutex is initially unlocked.
 	Return NULL if error otherwise return mutex pointer.

 objc_mutex_deallocate(objc_mutex_t mutex), int
 	Free a mutex.  Before freeing the mutex, makes sure that no
 	one else is using it.
 	Return -1 if error otherwise return 0.

 objc_mutex_lock(objc_mutex_t mutex), int
 	Locks a mutex.  As mentioned earlier, the same thread may call
 	this routine repeatedly.
 	Return -1 if error otherwise return 0.

 objc_mutex_trylock(objc_mutex_t mutex), int
 	Attempts to lock a mutex.  If lock on mutex can be acquired
 	then function operates exactly as objc_mutex_lock.
 	Return -1 if failed to acquire lock otherwise return 0.

 objc_mutex_unlock(objc_mutex_t mutex), int
 	Unlocks the mutex by one level.  Other threads may not acquire
 	the mutex until this thread has released all locks on it.
 	Return -1 if error otherwise return 0.

 *****
 * Backend mutex functions
 * User programs should *NOT* directly call these functions.

 __gthr_objc_mutex_allocate(objc_mutex_t mutex), int
 	Allocates a new mutex, called by objc_mutex_allocate.
 	Return -1 if error otherwise return 0.

 __gthr_objc_mutex_deallocate(objc_mutex_t mutex), int
 	Free a mutex, called by objc_mutex_deallocate.
 	Return -1 if error otherwise return 0.

 __gthr_objc_mutex_lock(objc_mutex_t mutex), int
 	Locks a mutex, called by objc_mutex_lock.
 	Return -1 if error otherwise return 0.

 __gthr_objc_mutex_trylock(objc_mutex_t mutex), int
 	Attempts to lock a mutex, called by objc_mutex_trylock.
 	Return -1 if failed to acquire lock or error otherwise return 0.

 __gthr_objc_mutex_unlock(objc_mutex_t mutex), int
 	Unlocks the mutex, called by objc_mutex_unlock.
 	Return -1 if error otherwise return 0.

 ******************************************************************************
 * Condition Mutexes:

 Mutexes can be locked recursively.  Each locked mutex remembers
 its owner (by thread id) and how many times it has been locked.  The
 last unlock on a mutex removes the system lock and allows other
 threads to access the mutex.

 *
 * Frontend condition mutex functions
 * User programs should use these functions.
 *

 objc_condition_allocate(void), objc_condition_t
 	Allocate a condition mutex.
 	Return NULL if error otherwise return condition pointer.

 objc_condition_deallocate(objc_condition_t condition), int
 	Deallocate a condition. Note that this includes an implicit
 	condition_broadcast to insure that waiting threads have the
 	opportunity to wake.  It is legal to dealloc a condition only
 	if no other thread is/will be using it. Does NOT check for
 	other threads waiting but just wakes them up.
 	Return -1 if error otherwise return 0.

 objc_condition_wait(objc_condition_t condition, objc_mutex_t mutex), int
 	Wait on the condition unlocking the mutex until objc_condition_signal()
 	or objc_condition_broadcast() are called for the same condition. The
 	given mutex *must* have the depth 1 so that it can be unlocked
 	here, for someone else can lock it and signal/broadcast the condition.
 	The mutex is used to lock access to the shared data that make up the
 	"condition" predicate.
 	Return -1 if error otherwise return 0.

 objc_condition_broadcast(objc_condition_t condition), int
 	Wake up all threads waiting on this condition. It is recommended that
 	the called would lock the same mutex as the threads in
 	objc_condition_wait before changing the "condition predicate"
 	and make this call and unlock it right away after this call.
 	Return -1 if error otherwise return 0.

 objc_condition_signal(objc_condition_t condition), int
 	Wake up one thread waiting on this condition.
 	Return -1 if error otherwise return 0.

 *
 * Backend condition mutex functions
 * User programs should *NOT* directly call these functions.
 *

 __gthr_objc_condition_allocate(objc_condition_t condition), int
 	Allocate a condition mutex, called by objc_condition_allocate.
 	Return -1 if error otherwise return 0.

 __gthr_objc_condition_deallocate(objc_condition_t condition), int
 	Deallocate a condition, called by objc_condition_deallocate.
 	Return -1 if error otherwise return 0.

 __gthr_objc_condition_wait(objc_condition_t condition, objc_mutex_t mutex), int
 	Wait on the condition, called by objc_condition_wait.
 	Return -1 if error otherwise return 0 when condition is met.

 __gthr_objc_condition_broadcast(objc_condition_t condition), int
 	Wake up all threads waiting on this condition.
 	Called by objc_condition_broadcast.
 	Return -1 if error otherwise return 0.

 __gthr_objc_condition_signal(objc_condition_t condition), int
 	Wake up one thread waiting on this condition.
 	Called by objc_condition_signal.
 	Return -1 if error otherwise return 0.
	This file describes in little detail the modifications to the
	Objective-C runtime needed to make it thread safe.

	First off, kudos to Galen Hunt who is the author of this great work.

	If you have an comments or just want to know where to
	send me money to express your undying gratitude for threading the
	Objective-C runtime you can reach Galen at:

	gchunt@cs.rochester.edu

	Any questions, comments, bug reports, etc. should send email either to the
	GCC bug account or to:

	Scott Christley <scottc@net-community.com>

	* Sarray Threading:

	The most critical component of the Objective-C runtime is the sparse array
	structure (sarray). Sarrays store object selectors and implementations.
	Following in the tradition of the Objective-C runtime, my threading
	support assumes that fast message dispatching is far more important
	than ANY and ALL other operations. The message dispatching thus
	uses NO locks on any kind. In fact, if you look in sarray.h, you
	will notice that the message dispatching has not been modified.
	Instead, I have modified the sarray management functions so that all
	updates to the sarray data structure can be made in parallel will
	message dispatching.

	To support concurrent message dispatching, no dynamically allocated
	sarray data structures are freed while more than one thread is
	operational. Sarray data structures that are no longer in use are
	kept in a linked list of garbage and are released whenever the program
	is operating with a single thread. The programmer can also flush the
	garbage list by calling sarray_remove_garbage when the programmer can
	ensure that no message dispatching is taking place concurrently. The
	amount of un-reclaimed sarray garbage should normally be extremely
	small in a real program as sarray structures are freed only when using
	the "poseAs" functionality and early in program initialization, which
	normally occurs while the program is single threaded.

	******************************************************************************
	* Static Variables:

	The following variables are either statically or globally defined. This list
	does not include variables which are internal to implementation dependent
	versions of thread-*.c.

	The following threading designations are used:
	SAFE : Implicitly thread safe.
	SINGLE : Must only be used in single thread mode.
	MUTEX : Protected by single global mutex objc_runtime_mutex.
	UNUSED : Not used in the runtime.

	Variable Name: Usage: Defined: Also used in:
	=========================== ====== ============ =====================
	__objc_class_hash MUTEX class.c
	__objc_class_links_resolved UNUSED class.c runtime.h
	__objc_class_number MUTEX class.c
	__objc_dangling_categories UNUSED init.c
	__objc_module_list MUTEX init.c
	__objc_selector_array MUTEX selector.c
	__objc_selector_hash MUTEX selector.c
	__objc_selector_max_index MUTEX selector.c sendmsg.c runtime.h
	__objc_selector_names MUTEX selector.c
	__objc_thread_exit_status SAFE thread.c
	__objc_uninstalled_dtable MUTEX sendmsg.c selector.c
	_objc_load_callback SAFE init.c objc-api.h
	_objc_lookup_class SAFE class.c objc-api.h
	_objc_object_alloc SINGLE objects.c objc-api.h
	_objc_object_copy SINGLE objects.c objc-api.h
	_objc_object_dispose SINGLE objects.c objc-api.h
	frwd_sel SAFE2 sendmsg.c
	idxsize MUTEX sarray.c sendmsg.c sarray.h
	initialize_sel SAFE2 sendmsg.c
	narrays MUTEX sarray.c sendmsg.c sarray.h
	nbuckets MUTEX sarray.c sendmsg.c sarray.h
	nindices MUTEX sarray.c sarray.h
	previous_constructors SAFE1 init.c
	proto_class SAFE1 init.c
	unclaimed_categories MUTEX init.c
	unclaimed_proto_list MUTEX init.c
	uninitialized_statics MUTEX init.c

	Notes:
	1) Initialized once in unithread mode.
	2) Initialized value will always be same, guaranteed by lock on selector
	hash table.


	******************************************************************************
	* Frontend/Backend design:

	The design of the Objective-C runtime thread and mutex functions utilizes a
	frontend/backend implementation.

	The frontend, as characterized by the files thr.h and thr.c, is a set
	of platform independent structures and functions which represent the
	user interface. For example, objc_mutex_lock(). Objective-C programs
	should use these structures and functions for their thread and mutex
	work if they wish to maintain a high degree of portability across
	platforms.

	The backend is currently GCC's gthread code (gthr.h and related). For
	example, __gthread_objc_mutex_lock(). The thread system is
	automatically configured when GCC is configured. On most platforms
	this thread backend is able to automatically switch to non-multi-threaded
	mode if the threading library is not linked in.

	If you want to compile libobjc standalone, then you would need to modify
	the configure.ac and makefiles for it and you need to import the
	gthread code from GCC.

	******************************************************************************
	* Threads:

	The thread system attempts to create multiple threads using whatever
	operating system or library thread support is available. It does
	assume that all system functions are thread safe. Notably this means
	that the system implementation of malloc and free must be thread safe.
	If a system has multiple processors, the threads are configured for
	full parallel processing.

	* Backend initialization functions

	__objc_init_thread_system(void), int
	Initialize the thread subsystem. Called once by __objc_exec_class.
	Return -1 if error otherwise return 0.

	__objc_close_thread_system(void), int
	Closes the thread subsystem, not currently guaranteed to be called.
	Return -1 if error otherwise return 0.

	*****
	* Frontend thread functions
	* User programs should use these functions.

	objc_thread_detach(SEL selector, id object, id argument), objc_thread_t
	Creates and detaches a new thread. The new thread starts by
	sending the given selector with a single argument to the
	given object.

	objc_thread_set_priority(int priority), int
	Sets a thread's relative priority within the program. Valid
	options are:

	OBJC_THREAD_INTERACTIVE_PRIORITY
	OBJC_THREAD_BACKGROUND_PRIORITY
	OBJC_THREAD_LOW_PRIORITY

	objc_thread_get_priority(void), int
	Query a thread's priority.

	objc_thread_yield(void), void
	Yields processor to another thread with equal or higher
	priority. It is up to the system scheduler to determine if
	the processor is taken or not.

	objc_thread_exit(void), int
	Terminates a thread. If this is the last thread executing
	then the program will terminate.

	objc_thread_id(void), int
	Returns the current thread's id.

	objc_thread_set_data(void *value), int
	Set a pointer to the thread's local storage. Local storage is
	thread specific.

	objc_thread_get_data(void), void *
	Returns the pointer to the thread's local storage.

	*****
	* Backend thread functions
	* User programs should NOT directly call these functions.

	__gthr_objc_thread_detach(void (func)(void arg), void *arg), objc_thread_t
	Spawns a new thread executing func, called by objc_thread_detach.
	Return NULL if error otherwise return thread id.

	__gthr_objc_thread_set_priority(int priority), int
	Set the thread's priority, called by objc_thread_set_priority.
	Return -1 if error otherwise return 0.

	__gthr_objc_thread_get_priority(void), int
	Query a thread's priority, called by objc_thread_get_priority.
	Return -1 if error otherwise return the priority.

	__gthr_objc_thread_yield(void), void
	Yields the processor, called by objc_thread_yield.

	__gthr_objc_thread_exit(void), int
	Terminates the thread, called by objc_thread_exit.
	Return -1 if error otherwise function does not return.

	__gthr_objc_thread_id(void), objc_thread_t
	Returns the current thread's id, called by objc_thread_id.
	Return -1 if error otherwise return thread id.

	__gthr_objc_thread_set_data(void *value), int
	Set pointer for thread local storage, called by objc_thread_set_data.
	Returns -1 if error otherwise return 0.

	__gthr_objc_thread_get_data(void), void *
	Returns the pointer to the thread's local storage.
	Returns NULL if error, called by objc_thread_get_data.


	******************************************************************************
	* Mutexes:

	Mutexes can be locked recursively. Each locked mutex remembers
	its owner (by thread id) and how many times it has been locked. The
	last unlock on a mutex removes the system lock and allows other
	threads to access the mutex.

	*****
	* Frontend mutex functions
	* User programs should use these functions.

	objc_mutex_allocate(void), objc_mutex_t
	Allocates a new mutex. Mutex is initially unlocked.
	Return NULL if error otherwise return mutex pointer.

	objc_mutex_deallocate(objc_mutex_t mutex), int
	Free a mutex. Before freeing the mutex, makes sure that no
	one else is using it.
	Return -1 if error otherwise return 0.

	objc_mutex_lock(objc_mutex_t mutex), int
	Locks a mutex. As mentioned earlier, the same thread may call
	this routine repeatedly.
	Return -1 if error otherwise return 0.

	objc_mutex_trylock(objc_mutex_t mutex), int
	Attempts to lock a mutex. If lock on mutex can be acquired
	then function operates exactly as objc_mutex_lock.
	Return -1 if failed to acquire lock otherwise return 0.

	objc_mutex_unlock(objc_mutex_t mutex), int
	Unlocks the mutex by one level. Other threads may not acquire
	the mutex until this thread has released all locks on it.
	Return -1 if error otherwise return 0.

	*****
	* Backend mutex functions
	* User programs should NOT directly call these functions.

	__gthr_objc_mutex_allocate(objc_mutex_t mutex), int
	Allocates a new mutex, called by objc_mutex_allocate.
	Return -1 if error otherwise return 0.

	__gthr_objc_mutex_deallocate(objc_mutex_t mutex), int
	Free a mutex, called by objc_mutex_deallocate.
	Return -1 if error otherwise return 0.

	__gthr_objc_mutex_lock(objc_mutex_t mutex), int
	Locks a mutex, called by objc_mutex_lock.
	Return -1 if error otherwise return 0.

	__gthr_objc_mutex_trylock(objc_mutex_t mutex), int
	Attempts to lock a mutex, called by objc_mutex_trylock.
	Return -1 if failed to acquire lock or error otherwise return 0.

	__gthr_objc_mutex_unlock(objc_mutex_t mutex), int
	Unlocks the mutex, called by objc_mutex_unlock.
	Return -1 if error otherwise return 0.

	******************************************************************************
	* Condition Mutexes:

	Mutexes can be locked recursively. Each locked mutex remembers
	its owner (by thread id) and how many times it has been locked. The
	last unlock on a mutex removes the system lock and allows other
	threads to access the mutex.

	*
	* Frontend condition mutex functions
	* User programs should use these functions.
	*

	objc_condition_allocate(void), objc_condition_t
	Allocate a condition mutex.
	Return NULL if error otherwise return condition pointer.

	objc_condition_deallocate(objc_condition_t condition), int
	Deallocate a condition. Note that this includes an implicit
	condition_broadcast to insure that waiting threads have the
	opportunity to wake. It is legal to dealloc a condition only
	if no other thread is/will be using it. Does NOT check for
	other threads waiting but just wakes them up.
	Return -1 if error otherwise return 0.

	objc_condition_wait(objc_condition_t condition, objc_mutex_t mutex), int
	Wait on the condition unlocking the mutex until objc_condition_signal()
	or objc_condition_broadcast() are called for the same condition. The
	given mutex must have the depth 1 so that it can be unlocked
	here, for someone else can lock it and signal/broadcast the condition.
	The mutex is used to lock access to the shared data that make up the
	"condition" predicate.
	Return -1 if error otherwise return 0.

	objc_condition_broadcast(objc_condition_t condition), int
	Wake up all threads waiting on this condition. It is recommended that
	the called would lock the same mutex as the threads in
	objc_condition_wait before changing the "condition predicate"
	and make this call and unlock it right away after this call.
	Return -1 if error otherwise return 0.

	objc_condition_signal(objc_condition_t condition), int
	Wake up one thread waiting on this condition.
	Return -1 if error otherwise return 0.

	*
	* Backend condition mutex functions
	* User programs should NOT directly call these functions.
	*

	__gthr_objc_condition_allocate(objc_condition_t condition), int
	Allocate a condition mutex, called by objc_condition_allocate.
	Return -1 if error otherwise return 0.

	__gthr_objc_condition_deallocate(objc_condition_t condition), int
	Deallocate a condition, called by objc_condition_deallocate.
	Return -1 if error otherwise return 0.

	__gthr_objc_condition_wait(objc_condition_t condition, objc_mutex_t mutex), int
	Wait on the condition, called by objc_condition_wait.
	Return -1 if error otherwise return 0 when condition is met.

	__gthr_objc_condition_broadcast(objc_condition_t condition), int
	Wake up all threads waiting on this condition.
	Called by objc_condition_broadcast.
	Return -1 if error otherwise return 0.

	__gthr_objc_condition_signal(objc_condition_t condition), int
	Wake up one thread waiting on this condition.
	Called by objc_condition_signal.
	Return -1 if error otherwise return 0.