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I have a large malloc'd region that I want to wrap in an NSData object. Some time later, I make a copy of that NSData object. I want the two NSData objects to live independent lifetimes. ARC takes care of ref-counting the NSData objects themselves, but I'm trying to clarify the lifetime of the contained malloc'd region. Here's a code sketch:

float* cubeData = (float*)malloc(cubeDataSize);
printf("cubeData=%p\n", cubeData);
// cubeData=0x01beef00

for (...) { /* fill the cubeData array */ }

NSData* data = [NSData dataWithBytesNoCopy:cubeData length:cubeDataSize
  freeWhenDone:YES];

NSData* data2 = [data copyWithZone:nil]

printf("data.bytes=%p data2.bytes=%p\n", data.bytes, data2.bytes);
// data.bytes=0x01beef00 data2.bytes=0x01beef00

It's OK with me that copyWithZone doesn't deep-copy the malloc'd region — I can use [NSData dataWithData:] if I want a deep copy. What isn't clear to me (and I'm not sure how best to test) is which NSData object owns the underlying malloc'd buffer? If they both hold a reference to the malloc'd buffer (using some form of opaque reference counting) that's great! But if the malloc'd buffer gets freed when the data object is released (as implied by freeWhenDone:YES), data2 will have trouble on its hands.

Can someone explain what NSData does in this case? Alternatively, can someone suggest a definitive test to prove to myself what's going on?

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For a good time log the pointer address of data and data2. NSLog(@"%p %p", data, data2); ;-) –  Matthias Bauch Jul 15 '13 at 18:59
    
@MatthiasBauch: you mean like the last line in the example? :-) (I used printf instead of NSLog) –  Tim Ruddick Jul 15 '13 at 19:10
    
"If YES, the returned object takes ownership of the bytes pointer and frees it on deallocation." That says to me that you'd better not count on the buffer surviving beyond the life of the first NSData. However, probably the second NSData increments the reference count of the first NSData, so the first NSData will not go poof until the second one does. (In non-ARC you could test reference counts to check this.) –  Hot Licks Jul 15 '13 at 19:11
3  
you logged the bytes. log the addresses of the NSData objects. Spoiler: They are equal. data and data2 point to the exact same object. Immutable objects usually return the same instance when you send copy. The copy will just increase the reference count of the object. Is it guaranteed to be this way? Probably not, sounds like a implementation detail. So be extra careful when testing how your code behaves. –  Matthias Bauch Jul 15 '13 at 19:13
1  
You may also run into the issue that you want to keep a pointer to the underlaying data -- but release the corresponding NSData object prematurely. This can happen when using ARC namely, immediately after the last access to the NSData object, but BEFORE the next access to the interior pointer. This causes a crash. You can however, explicitly extend the lifetime of ARC managed objects with using attribute objc_precise_lifetime e.g.: NSData* data __attribute__((objc_precise_lifetime)) = ...; This extends the lifetime up until the object goes out of block scope. –  CouchDeveloper Jul 15 '13 at 19:36

1 Answer 1

up vote 1 down vote accepted

To the underlying question:

Is the content of NSData separately reference-counted?

No. (But looking at your code, it shouldn't matter. See below after this diversion.)

--- Start Diversion ---

ARC manages retains and releases on Objective-C objects by sending the equivalent of retain and release messages at appropriate times. "Appropriate times" are determined at compile time by code inspection. That is exactly everything it does. When you start creating pointers to non-object pieces of those objects (i.e. bytes), you're on your own to manage lifetime.

@CouchDeveloper provides good information about objc_precise_lifetime. Placing this attribute on data objects can protect you from an ARC optimizations when dealing with internal pointers, but it isn't really relevant here. The point of objc_precise_lifetime is to tell ARC it's not allowed to release an object before the referencing variable goes out of scope. The problem it solves looks like this:

NSData *data = ...;
void *stuff = data.bytes; // (1)
doSomething(stuff); // (2)

ARC has an optimization that says it's allowed to destroy data between line (1) and line (2), since you never reference data again, even though data is in scope. Adding the objc_precise_lifetime attribute forbids that optimization. When you start using NSData a lot, this attribute can become important.

--- End Diversion ---

OK, but what about your situation?

float* cubeData = (float*)malloc(cubeDataSize);
NSData* data = [NSData dataWithBytesNoCopy:cubeData length:cubeDataSize freeWhenDone:YES];
NSData* data2 = [data copyWithZone:nil]

After this code has run, there are two possibilities (and you're not supposed to care most of the time which is true, since these are immutable objects):

  • data and data2 are both strong pointers to the same NSData object. That object owns the malloced memory and will free it when deallocated. (This is the one that's almost certain to happen in this particular case, but that's an implementation detail.)
  • data points to an NSData object that owns the malloced memory and will free it when deallocated. data2 points to a different NSData object with its own memory (which it will free when it is deallocated.)

(There are other options; perhaps NSData uses an underlying dispatch_data or a copy-on-write scheme. But all the options should effectively look like the above from the outside.)

In the first case, if data goes out of scope, but data2 is still around, then the owning NSData is preserved. No problem. In the second case, when data goes out of scope, it destroys its memory, but data2 has an independent copy of it, so again no problem.

I think your confusion is coming from thinking that data owns the memory. It doesn't. The NSData object that data points to owns the memory. data and data2 are just pointers.

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My confusion came from missing the fact that data and data2 are actually pointing at exactly the same object, so (of course) the contained buffer is in turn identical. I had assumed copyWithZone: would return a new object, but it doesn't do that (or doesn't in this case, anyway). @MatthiasBauch pointed in the right direction, and your answer explains the situation in much more detail. Thanks! –  Tim Ruddick Jul 16 '13 at 16:47

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