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libobjc2 with build changes and Darling additions
objc | ||
archive.c | ||
blocks_runtime.m | ||
class_table.c | ||
class.c | ||
COPYING | ||
COPYING3 | ||
COPYING.MIT | ||
COPYING.RUNTIME | ||
encoding.c | ||
exception.c | ||
gc.c | ||
GNUmakefile | ||
hash_table.h | ||
hash.c | ||
init.c | ||
libobjc_entry.c | ||
linking.m | ||
lock.h | ||
misc.c | ||
mutation.m | ||
nil_method.c | ||
NSBlocks.m | ||
NXConstStr.m | ||
Object.m | ||
objects.c | ||
properties.m | ||
protocol.c | ||
Protocol.m | ||
README | ||
runtime.c | ||
sarray.c | ||
selector.c | ||
sendmsg2.c | ||
sendmsg.c | ||
sendmsg.d | ||
string_hash.h | ||
sync.m | ||
thr.c | ||
unwind-pe.h |
GNUstep Objective-C Runtime =========================== The GNUstep Objective-C runtime is based on the GCC runtime. It supports both a legacy and a modern ABI, allowing code compiled with old versions of GCC to be supported without requiring recompilation. The modern ABI adds the following features: - Non-fragile instance variables. - Protocol uniquing. - Object planes support. - Declared property introspection. Both ABIs support the following feature above and beyond the GNU runtime: - The modern Objective-C runtime APIs, introduced with OS X 10.5. - Blocks (closures). Non-Fragile Instance Variables ------------------------------ When a class is compiled to support non-fragile instance variables, the instance_size field in the class is set to 0 - the size of the instance variables declared on that class (excluding those inherited. For example, an NSObject subclass declaring an int ivar would have its instance_size set to 0 - sizeof(int). The offsets of each instance variable in the class's ivar_list field are then set to the offset from the start of the superclass's ivars. When the class is loaded, the runtime library uses the size of the superclass to calculate the correct size for this new class and the correct offsets. Each instance variable should have two other variables exported as global symbols. Consider the following class: @interface NewClass : SuperClass { int anIvar; } @end This would have its instance_size initialized to 0-sizeof(int), and anIvar's offset initialized to 0. It should also export the following two symbols: int __objc_ivar_offset_value_NewClass.anIvar; int *__objc_ivar_offset_NewClass.anIvar; The latter should point to the former or to the ivar_offset field in the ivar metadata. The former should be pointed to by the only element in the ivar_offsets array in the class structure. In other compilation units referring to this ivar, the latter symbol should be exported as a weak symbol pointing to an internal symbol containing the compiler's guess at the ivar offset. The ivar will then work as a fragile ivar when NewClass is compiled with the old ABI. If NewClass is compiled with the new ABI, then the linker will replace the weak symbol with the version in the class's compilation unit and references which use this offset will function correctly. If the compiler can guarantee that NewClass is compiled with the new ABI, for example if it is declared in the same compilation unit, by finding the symbol during a link-time optimization phase, or as a result of a command-line argument, then it may use the __objc_ivar_offset_value_NewClass.anIvar symbol as the ivar offset. This eliminates the need for one load for every ivar access. Protocols --------- The runtime now provides a __ObjC_Protocol_Holder_Ugly_Hack class. All protocols that are referenced but not defined should be registered as categories on this class. This ensures that every protocol is registered with the runtime. In the near future, the runtime will ensure that protocols can be looked up by name at run time and that empty protocol definitions have their fields updated to match the defined version. Protocols have been extended to provide space for introspection on properties and optional methods. These fields only exist on protocols compiled with a compiler that supports Objective-C 2. To differentiate the two, the isa pointer for new protocols will be set to the Protocol2 class. Fast Proxies and Cacheable Lookups ---------------------------------- The new runtime provides two mechanisms for faster lookup. The older Vobjc_msg_lookup() function, which returns an IMP, is still supported, however it is no longer recommended. The new lookup functions is: Slot_t objc_msg_lookup_sender(id *receiver, SEL selector, id sender) The receiver is passed by pointer, and so may be modified during the lookup process. The runtime itself will never modify the receiver. The following hook is provided to allow fast proxy support: id (*objc_proxy_lookup)(id receiver, SEL op); This function takes an object and selector as arguments and returns a new objects. The lookup will then be re-run and the final message should be sent to the new object. The returned Slot_t from the new lookup function is a pointer to a structure which contains both an IMP and a version (among other things). The version is incremented every time the method is overridden, allowing this to be cached by the caller. User code wishing to perform IMP caching may use the old mechanism if it can guarantee that the IMP will not change between calls, or the newer mechanism. Note that a modern compiler should insert caching automatically, ideally with the aid of run-time profiling results. To support this, a new hook has been added: Slot_t objc_msg_forward3(id receiver, SEL op); This is identical to objc_msg_forward2(), but returns a pointer to a slot, instead of an IMP. The slot should have its version set to 0, to prevent caching. Object Planes ------------- Object planes provide interception points for messages between groups of related objects. They can be thought of as similar to processes, with mediated inter-plane communication. A typical use-case for an object plane is to automatically queue messages sent to a thread, or to record every message sent to model objects. Planes can dramatically reduce the number of proxy objects required for this kind of activity. The GNUstep runtime adds a flag to class objects indicating that their instances are present in the global plane. All constant strings, protocols, and classes are in the global plane, and may therefore be sent and may receive messages bypassing the normal plane interception mechanism. The runtime library does not provide direct support for planes, it merely provides the core components required to implement support for planes in another framework. Two objects are regarded as being in the same plane when they words immediately before their isa pointers are the same. In this case, the runtime's usual dispatch mechanisms will be used. In all other cases, the runtime will delegate message lookup to another library via the following hook: Slot_t (*objc_plane_lookup)(id *receiver, SEL op, id sender); From the perspective of the runtime, the plane identifier is opaque. In GNUstep, it is a pointer to an NSZone structure. Threading --------- The old threading layer is gone. It was buggy, badly supported, and inadequately tested. The library now always runs in thread-safe mode. The same functions for locking the runtime mutex are still supported, but their use any mutex not exported by the runtime library is explicitly not supported. The (private) lock.h header is now used to abstract the details of different threading systems sufficiently for the runtime. This provides mechanisms for locking, unlocking, creating, and destroying mutex objects. Objective-C 2 Features ---------------------- The runtime now provides implementations of the functions required for the @synchronized directive, for property accessors, and for fast enumeration. The public runtime function interfaces now match those of OS X.