The documentation for properties in Obj-C 2.0 say that atomic properties use a lock internally, but it doesn't document the specifics of the lock. Does anybody know if this is a per-property lock, a per-object lock separate from the implicit one used by @synchronized(self), or the equivalent of @synchronized(self)?

2 Answers 2


Looking at the generated code (iOS SDK GCC 4.0/4.2 for ARM),

  • 32-bit assign properties (including struct {int32_t v;}) are accessed directly.
  • Larger-than-32-bit structs are accessed with objc_copyStruct().
  • double and int64_t are accessed with objc_copyStruct, except on GCC 4.0 where they're accessed directly with stmia/ldmia (I'm not sure if this is guaranteed to be atomic in case of interrupts).
  • retain/copy accessors call objc_getProperty and objc_setProperty.

Cocoa with Love: Memory and thread-safe custom property methods gives some details on how they're implemented in runtime version objc4-371.2; obviously the precise implementation can vary between runtimes (for example, on some platforms you can use atomic swap/CAS to spin on the ivar itself instead of using another lock).


The lock used by atomic @properties is an implementation detail--for appropriate types on appropriate platforms, atomic operations without a lock are possible and I'd be surprised if Apple was not taking advantage of them. There is no public access to the lock in any case, so you can't @synchronize on the same lock. Several Apple engineers have pointed out that atomic properties do not guarantee thread safety; atomic properties only guarantee that gets/sets of that value are atomic. For correct thread safety, you will have to make use of higher-level locking or synchronization and you almost certainly would not want to use the same lock as the synthesize getter/setter(s) might be using.

  • Ok. I was asking because I was wondering if there would be extra overhead to using both atomic properties and a @synchronized() when dealing with multiple properties at the same time. It sounds like, for operations that can't be done using an atomic primitive, there will be extra overhead as it effectively uses 2 locks. Ah well. May 27, 2009 at 20:45
  • In this case, when you are already using a @synchronized or otherwise protected block to implement higher-level locking semantics, it may make sense to use nonatomic for your properties.
    – Barry Wark
    May 27, 2009 at 22:22
  • I don't want to make all clients of the code have to use @synchronized blocks just to access the properties, nor do I want to implement my own getters/setters just to use @synchronized instead of the synthesized synchronization operations. May 27, 2009 at 23:37
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    If you're using higher-level synchronization to order access to the resources containing those properties, but you allow other clients direct access to those properties, it may be very hard to guarantee proper behavior of your multithreaded code that's reliant on those higher level synchronizations to order things. YMMV, of course, but be wary. There be dragons there.
    – Barry Wark
    May 27, 2009 at 23:43
  • I ended up not even using @synchronized but rather a few explicit NSLock objects (for locking individual private ivars), and I rely on ordering of property access instead. I believe the way I've ordered the property assignments, the client always has a usable view of the object even from another thread (e.g. the image can be set if it's not marked finished, but if it's marked finished, the image will always be set). May 28, 2009 at 0:36

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