In most of the discussions I've read, it indicates that making a property atomic does not guarantee it to be thread-safe, it just guarantees that the value returned won't be garbage as a result of one object writing to it and another trying to read it at the same time.

I understand this isn't thread-safe as a third object could be writing it and while the object accessing it wouldn't get garbage back, it's not entirely certain which value it will get back as multiple objects are writing to it at the same time, and it may get any of their values.

So when we say it won't return garbage, would garbage be in the sense that if an object was non-atomic and an object tried to access it while another was writing to it, it might get the result back mid-write, and only get a partial, incomplete version of the change brought about by the write? Is this what "garbage" means in this sense, and what atomic properties help to prevent?

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    The thing about "thread safe" is that nothing, by itself, is "thread safe". "Thread safe" can only really be determined in a given context where "thread safe" means that correct operation of the entire context is assured in spite of any possible multi-threading. A particular implementation of a mutable array, say, can maybe said to be "thread safe" in a vacuum, since one will never access internally inconsistent data, but that's meaningless if it's entries are not maintained in synchronization with the external data it references. And that synchronization can only be maintained externally. – Hot Licks Jan 13 '14 at 18:40
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    @doug-smith You'll likely find my answer on this question + the comments the followed to be helpful. stackoverflow.com/questions/588866/… – bbum Jan 13 '14 at 20:28
  • Here is answer stackoverflow.com/a/32942413/1961064 – Grigori Jlavyan Feb 18 '16 at 13:45

An atomic property in Objective C guarantees that you will never see partial writes. When a @property has the attribute atomic it is impossible to only partially write the value. The setter is like that:

- (void)setProp:(NSString *)newValue {
    [_prop lock];
    _prop = newValue;
    [_prop unlock];

So if two thread want to write the value @"test" and @"otherTest" at the same time, then at any given time the property can only be the initial value of the property or @"test" or @"otherTest". nonatomic is faster but the value is a garbage value and no partial String of @"test"/@"otherTest" (thx @Gavin) or any other garbage value.

But atomic is only thread-safe with simple use. It is not garantueed. Appledoc says the following:

Consider an XYZPerson object in which both a person’s first and last names are changed using atomic accessors from one thread. If another thread accesses both names at the same time, the atomic getter methods will return complete strings (without crashing), but there’s no guarantee that those values will be the right names relative to each other. If the first name is accessed before the change, but the last name is accessed after the change, you’ll end up with an inconsistent, mismatched pair of names.

I never had a problem using atomic at all. I designed the code that way, that there is not problem with atomic properties.

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    You would never see something like "teerTest", because setting the property to a string is just setting a pointer to an Objective-C object. So what you would maybe see is a garbage pointer, but never some hybrid of the two strings that you're trying to set (unless it happened to be a string defined somewhere else, like you actually had a string "teerTest" somewhere in your app, and the garbage pointer actually managed to point to it). – Gavin Jan 13 '14 at 18:47
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    Yeah, you are right. I wrote 'to make it clear', but it is more confusing that way. I changed it, thanks for mentioning it. – Binarian Jan 13 '14 at 18:50
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    What i understand from Apple document is that: if u have two atomic properties and u need to generate result data from these two while threads accessing or modifying them in any way then u will get result(guaranteed) but may not be correct,,which i feel is good enough instead of writing thread-safe code manually. – SandyNegi.037 Apr 10 '14 at 18:45
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    For me this article about atomic and nonatomic operations at the processor level was particularly interesting to understand how a value might be written partially. – Yevhen Dubinin Mar 25 '16 at 17:46
  • I think you saying " you will see no partial writes" is misleading as if non-atomic would provide such ( You originally thought such and fixed only where the issue was bold, but didn't fix the other less important parts) :]. With respect I think your whole answer needs to be reconstructed again from scratch. Also I think your answer is a bit misleading in the sense that you have refuted partial written scenario, while that is a possibility if there is one writing attempt that has gone through half-way and a read is going on. ( this case is different from the case of 2 simultaneous attempts) – Honey Apr 18 '16 at 13:47

In answer to your third paragraph; essentially yes. An atomic number can't be read while a thread is writing the number.

For example, if a thread has written the first two bytes of an atomic four byte number, and a read of that number is requested on another thread, that read has to wait until all four bytes have been written.

Conversely, if a thread has written the first two bytes of a non-atomic four byte number, and a read of that number is requested on another thread at that moment, it will read the first two new data bytes, but will get old data from a previous write operation in the other two bytes.

  • Is it true conversely? If 4 bytes are not declared non-atomic, may one thread see 2 written bytes while another thread is writing 4? – danh Jan 13 '14 at 18:29
  • @danh: Too many double negatives for me to parse your question. I've edited my answer to clarify. – Robert Harvey Jan 13 '14 at 18:30
  • :-) I can't think of another way of phrasing not nonatomic. – danh Jan 13 '14 at 18:32
  • @danh: atomic. :) – Robert Harvey Jan 13 '14 at 18:33
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    Exactly which types are naturally atomic is platform specific. In the case of x86, at least, 4 byte integers should be. structs or doubles would not be though. – Catfish_Man Jan 13 '14 at 18:37

Robert Harvey's answer is correct, but there is a sub-case of that to consider that people often miss. Consider this code: http://pastebin.com/S7XyJm6G

As well as preventing you from reading partially written values, atomic properties also prevent you from getting objects back that you don't control the lifetime of (they do this by retaining and then autoreleasing the object). This is important in single threaded code like the example that I linked, but even more important in multithreaded code where another thread could cause the object to be released out from under you.

  • Can you please give an example for an iOS app, where thread safety is used. Let's say I am using Instagram and I attempt to download my images asynchronously, what problem could I have? It's just one device, one user, one main thread commanding everything else, which exact hypothetical property is it that could get wrote twice simultaneously and would need me to follow a thread safe design? – Honey Apr 18 '16 at 13:33
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    If you're downloading them asynchronously, the main thread isn't commanding everything. Most likely what you would run into in the situation you describe is not several simultaneous writes, but a simultaneous read (from the main thread) and write (from the download thread). Atomic properties are likely not the tool you'd use to achieve thread-safety in that example though; there are many other approaches. – Catfish_Man Apr 18 '16 at 15:05

In concurrent programing:

atomic means if a property value being accessed for writing operation in some thread(thread # 1) and other thread(thread # 2) tries to access the atomic value either for read or write operation then other thread(thread # 2) waits until thread # 1 completes its task. In other words atomic synchronize the access of property on first come first serve basis.

non atomic means if a property value being accessed for writing operation in some thread(thread # 1) and other thread(thread # 2) tries to access the non atomic value either for read or write operation then other thread(thread # 2) gets value immediately gets old value


Explicit implementation of

@property (atomic, retain) NSNumber *count

would be like this

- (NSNumber *)count {
    NSNumber *count;
    @synchronized(self) {
        count = [_count retain]; // +1
    return [count autorelease]; // delayed -1

- (void)setCount:(NSNumber *)count {
    id oldValue;
    @synchronized(self) {
        oldValue = _count;
        _count = [count retain];
    [oldValue release];

Atomic is the default behaviour for a property.An atomic property adds a level of thread safety when getting or setting values. That is, the getter and setter for the property will always be fully completed regardless of what other threads are doing. these properties will be a little slower to access than a nonatomic equivalent.

And explicitly we would implement

@property (nonatomic, retain) NSNumber *count

like this

- (NSNumber *)count {
    return _count;

- (void)setCount:(NSNumber *)count {
    if (count != _count) {
        id oldValue = _count;
        _count = [count retain];
        [_oldValue release];

Nonatomic properties are not thread safe, and will return their properties directly. This will be faster than atomic properties, but obviously carries some risk if precautions aren’t made.

setter & getter for these Nonatomic property

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