Stack Overflow is a community of 4.7 million programmers, just like you, helping each other.

Join them; it only takes a minute:

Sign up
Join the Stack Overflow community to:
  1. Ask programming questions
  2. Answer and help your peers
  3. Get recognized for your expertise

What do atomic and nonatomic mean in property declarations?

@property(nonatomic, retain) UITextField *userName;
@property(atomic, retain) UITextField *userName;
@property(retain) UITextField *userName;

What is the operational difference between these three?

share|improve this question

20 Answers 20

up vote 1356 down vote accepted

The last two are identical; "atomic" is the default behavior (note that it is not actually a keyword; it is specified only by the absence of nonatomic -- atomic was added as a keyword in recent versions of llvm/clang).

Assuming that you are @synthesizing the method implementations, atomic vs. non-atomic changes the generated code. If you are writing your own setter/getters, atomic/nonatomic/retain/assign/copy are merely advisory. (Note: @synthesize is now the default behavior in recent versions of LLVM. There is also no need to declare instance variables; they will be synthesized automatically, too, and will have an _ prepended to their name to prevent accidental direct access).

With "atomic", the synthesized setter/getter will ensure that a whole value is always returned from the getter or set by the setter, regardless of setter activity on any other thread. That is, if thread A is in the middle of the getter while thread B calls the setter, an actual viable value -- an autoreleased object, most likely -- will be returned to the caller in A.

In nonatomic, no such guarantees are made. Thus, nonatomic is considerably faster than "atomic".

What "atomic" does not do is make any guarantees about thread safety. If thread A is calling the getter simultaneously with thread B and C calling the setter with different values, thread A may get any one of the three values returned -- the one prior to any setters being called or either of the values passed into the setters in B and C. Likewise, the object may end up with the value from B or C, no way to tell.

Ensuring data integrity -- one of the primary challenges of multi-threaded programming -- is achieved by other means.

share|improve this answer
7  
Given that any thread-safe code will be doing its own locking etc, when would you want to use atomic property accessors? I'm having trouble thinking of a good example. – Daniel Dickison May 24 '11 at 20:00
3  
@bbum Makes sense. I like your comment to another answer that thread-safety is more a model-level concern. From an IBM thread safety definition: ibm.co/yTEbjY "If a class is correctly implemented, which is another way of saying that it conforms to its specification, no sequence of operations (reads or writes of public fields and calls to public methods) on objects of that class should be able to put the object into an invalid state, observe the object to be in an invalid state, or violate any of the class's invariants, preconditions, or postconditions." – Ben Flynn Jan 26 '12 at 19:22
4  
Here's an example similar to @StevenKramer 's: I have a @property NSArray* astronomicalEvents; that lists data I want to display in the UI. When the application launches the pointer points to an empty array, then the app pulls data from the web. When the web request completes (in a different thread) the app builds a new array then atomically sets the property to a new pointer value. It's thread safe and I didn't have to write any locking code, unless I'm missing something. Seems pretty useful to me. – bugloaf Feb 15 '13 at 15:52
4  
@HotLicks Another fun one; on certain architectures (Can't remember which one), 64 bit values passed as an argument might be passed half in a register and half on the stack. atomic prevents cross-thread half-value reads. (That was a fun bug to track down.) – bbum Nov 23 '13 at 23:19
5  
@congliu Thread A returns an object without retain/autorelease dance. Thread B releases object. Thread A goes boom. atomic ensures that thread A has a strong reference (a +1 retain count) for the return value. – bbum Dec 6 '13 at 7:13

This is explained in Apple's documentation, but below are some examples of what is actually happening. Note that there is no "atomic" keyword, if you do not specify "nonatomic" then the property is atomic, but specifying "atomic" explicitly will result in an error.

//@property(nonatomic, retain) UITextField *userName;
//Generates roughly

- (UITextField *) userName {
    return userName;
}

- (void) setUserName:(UITextField *)userName_ {
    [userName_ retain];
    [userName release];
    userName = userName_;
}

Now, the atomic variant is a bit more complicated:

//@property(retain) UITextField *userName;
//Generates roughly

- (UITextField *) userName {
    UITextField *retval = nil;
    @synchronized(self) {
        retval = [[userName retain] autorelease];
    }
    return retval;
}

- (void) setUserName:(UITextField *)userName_ {
    @synchronized(self) {
      [userName release];
      userName = [userName_ retain];
    }
}

Basically, the atomic version has to take a lock in order to guarantee thread safety, and also is bumping the ref count on the object (and the autorelease count to balance it) so that the object is guaranteed to exist for the caller, otherwise there is a potential race condition if another thread is setting the value, causing the ref count to drop to 0.

There are actually a large number of different variants of how these things work depending on whether the properties are scalar values or objects, and how retain, copy, readonly, nonatomic, etc interact. In general the property synthesizers just know how to do the "right thing" for all combinations.

share|improve this answer
6  
Not that the lock doesn't "guarantee thread safety". – Jonathan Sterling Dec 31 '09 at 22:36
7  
@Louis Gerbarg: I believe your version of the (nonatomic, retain) setter will not work properly if you try to assign the same object (that is: userName == userName_) – Florin Aug 12 '10 at 9:29
5  
Your code is slightly misleading; there is no guarantee on what atomic getters/setters are synchronized. Critically,@property (assign) id delegate; is not synchronized on anything (iOS SDK GCC 4.2 ARM -Os), which means there's a race between [self.delegate delegateMethod:self]; and foo.delegate = nil; self.foo = nil; [super dealloc];. See stackoverflow.com/questions/917884/… – tc. Dec 1 '10 at 18:20
    
@fyolnish I'm not sure what _val/val are, but no, not really. The getter for an atomic copy/retain property needs to ensure that it does not return an object whose refcount becomes zero due the setter being called in another thread, which essentially means it needs to read the ivar, retain it while ensuring that the setter hasn't overwritten-and-released it, and then autorelease it to balance the retain. That essentially means both the getter and setter have to use a lock (if the memory layout was fixed it should be doable with CAS2 instructions; alas -retain is a method call). – tc. Dec 10 '13 at 11:09
    
@tc It's been quite a while but what I meant to write was probably this: gist.github.com/fjolnir/5d96b3272c6255f6baae But yes it is possible for the old value to be read by a reader before setFoo: returns, and released before the reader returns it. But maybe if the setter used -autorelease instead of -release, that would fix that. – Fjölnir Dec 11 '13 at 5:47

The syntax and semantics are already well-defined by other excellent answers to this question. Because execution and performance are not detailed well, I will add my answer.

What is the functional difference between these 3?

I'd always considered atomic as a default quite curious. At the abstraction level we work at, using atomic properties for a class as a vehicle to achieve 100% thread-safety is a corner case. For truly correct multithreaded programs, intervention by the programmer is almost certainly a requirement. Meanwhile, performance characteristics and execution have not yet been detailed in depth. Having written some heavily multithreaded programs over the years, I had been declaring my properties as nonatomic the entire time because atomic was not sensible for any purpose. During discussion of the details of atomic and nonatomic properties this question, I did some profiling encountered some curious results.

Execution

Ok. The first thing I would like to clear up is that the locking implementation is implementation-defined and abstracted. Louis uses @synchronized(self) in his example -- I have seen this as a common source of confusion. The implementation does not actually use @synchronized(self); it uses object level spin locks. Louis's illustration is good for a high-level illustration using constructs we are all familiar with, but it's important to know it does not use @synchronized(self).

Another difference is that atomic properties will retain/release cycle your objects within the getter.

Performance

Here's the interesting part: Performance using atomic property accesses in uncontested (e.g. single-threaded) cases can be really very fast in some cases. In less than ideal cases, use of atomic accesses can cost more than 20 times the overhead of nonatomic. While the Contested case using 7 threads was 44 times slower for the three-byte struct (2.2 GHz Core i7 Quad Core, x86_64). The three-byte struct is an example of a very slow property.

Interesting side note: User-defined accessors of the three-byte struct were 52 times faster than the synthesized atomic accessors; or 84% the speed of synthesized nonatomic accessors.

Objects in contested cases can also exceed 50 times.

Due to the number of optimizations and variations in implementations, it's quite difficult to measure real-world impacts in these contexts. You might often hear something like "Trust it, unless you profile and find it is a problem". Due to the abstraction level, it's actually quite difficult to measure actual impact. Gleaning actual costs from profiles can be very time consuming, and due to abstractions, quite inaccurate. As well, ARC vs MRC can make a big difference.

So let's step back, not focussing on the implementation of property accesses, we'll include the usual suspects like objc_msgSend, and examine some real-world high-level results for many calls to a NSString getter in uncontested cases (values in seconds):

  • MRC | nonatomic | manually implemented getters: 2
  • MRC | nonatomic | synthesized getter: 7
  • MRC | atomic | synthesized getter: 47
  • ARC | nonatomic | synthesized getter: 38 (note: ARC's adding ref count cycling here)
  • ARC | atomic | synthesized getter: 47

As you have probably guessed, reference count activity/cycling is a significant contributor with atomics and under ARC. You would also see greater differences in contested cases.

Although I pay close attention to performance, I still say Semantics First!. Meanwhile, performance is a low priority for many projects. However, knowing execution details and costs of technologies you use certainly doesn't hurt. You should use the right technology for your needs, purposes, and abilities. Hopefully this will save you a few hours of comparisons, and help you make a better informed decision when designing your programs.

share|improve this answer
    
MRC | atomic | synthesized getter: 47 ARC | atomic | synthesized getter: 47 What makes them the same? Should't ARC have more overhead? – SDEZero Aug 27 '12 at 15:20
1  
So if atomic properties are bad y are they default. To increase the boilerplate code ? – Kunal Balani Sep 17 '13 at 20:44
    
@LearnCocos2D i just tested on 10.8.5 on the same machine, targeting 10.8, for the single threaded uncontested case with an NSString which is not immortal: -ARC atomic (BASELINE): 100% -ARC nonatomic, synthesised: 94% -ARC nonatomic, user defined: 86% -MRC nonatomic, user defined: 5% -MRC nonatomic, synthesised: 19% -MRC atomic: 102% -- the results are a little different today. I wasn't doing any @synchronized comparisons. @synchronized is semantically different, and I don't consider it a good tool if you have nontrivial concurrent programs. if you need speed, avoid @synchronized. – justin Sep 23 '13 at 13:34
    
do you have this test online somewhere? I keep adding mine here: github.com/LearnCocos2D/LearnCocos2D/tree/master/… – LearnCocos2D Sep 23 '13 at 14:09
    
@LearnCocos2D i haven't prepared them for human consumption, sorry. – justin Sep 23 '13 at 17:13

Atomic

  • is the default behavior
  • will ensure the present process is completed by the CPU, before another process accesses the variable
  • is not fast, as it ensures the process is completed entirely

Non-Atomic

  • is NOT the default behavior
  • faster (for synthesized code, that is, for variables created using @property and @synthesize)
  • not thread-safe
  • may result in unexpected behavior, when two different process access the same variable at the same time
share|improve this answer

The best way to understand the difference is using the following example.

Suppose there is an atomic string property called "name", and if you call [self setName:@"A"] from thread A, call [self setName:@"B"] from thread B, and call [self name] from thread C, then all operations on different threads will be performed serially which means if one thread is executing a setter or getter, then other threads will wait.

This makes property "name" read/write safe, but if another thread, D, calls [name release] simultaneously then this operation might produce a crash because there is no setter/getter call involved here. Which means an object is read/write safe (ATOMIC), but not thread-safe as another threads can simultaneously send any type of messages to the object. The developer should ensure thread-safety for such objects.

If the property "name" was nonatomic, then all threads in above example - A,B, C and D will execute simultaneously producing any unpredictable result. In case of atomic, either one of A, B or C will execute first, but D can still execute in parallel.

share|improve this answer

Atomic = thread safety

Non-atomic = No thread safety

Thread safety:

Instance variables are thread-safe if they behave correctly when accessed from multiple threads, regardless of the scheduling or interleaving of the execution of those threads by the runtime environment, and with no additional synchronization or other coordination on the part of the calling code.

In our context:

If a thread changes the value of the instance the changed value is available to all the threads, and only one thread can change the value at a time.

Where to use atomic:

if the instance variable is gonna be accessed in a multithreaded environment.

Implication of atomic:

Not as fast as nonatomic because nonatomic doesn't require any watchdog work on that from runtime .

Where to use nonatomic:

If the instance variable is not gonna be changed by multiple threads you can use it. It improves the performance.

share|improve this answer
2  
Everything you say here is correct, but the last sentence is essentially "wrong", Dura, for today's programming. It's really inconceivable you would bother to try to "improve performance" this way. (I mean, before you got within lightyears of that, you would be "not using ARC", "not using NSString because it is slow!" and so on.) To make an extreme example, it would be like saying "team, don't put any comments in the code, as it slows us down." There is no realistic development pipeline where you would want the (nonexistent) theoretical performance gains at the sake of unreliability. – Joe Blow Jun 1 '14 at 8:37
3  
@JoeBlow its a fact you can verify it here developer.apple.com/library/mac/documentation/Cocoa/Conceptual/… – Durai Amuthan.H Jun 1 '14 at 13:47

I found a pretty well put explanation of atomic and non-atomic properties here. Here's some relevant text from the same:

'atomic' means it cannot be broken down. In OS/programming terms an atomic function call is one that cannot be interrupted - the entire function must be executed, and not swapped out of the CPU by the OS's usual context switching until it's complete. Just in case you didn't know: since the CPU can only do one thing at a time, the OS rotates access to the CPU to all running processes in little time-slices, to give the illusion of multitasking. The CPU scheduler can (and does) interrupt a process at any point in its execution - even in mid function call. So for actions like updating shared counter variables where two processes could try to update the variable at the same time, they must be executed 'atomically', i.e., each update action has to finish in its entirety before any other process can be swapped onto the CPU.

So I'd be guessing that atomic in this case means the attribute reader methods cannot be interrupted - in effect meaning that the variable(s) being read by the method cannot change their value half way through because some other thread/call/function gets swapped onto the CPU.

Because the atomic variables can not be interrupted, the value contained by them at any point is (thread-lock) guaranteed to be uncorrupted, although, ensuring this thread lock makes access to them slower. non-atomic variables, on the other hand, make no such guarantee but do offer the luxury of quicker access. To sum it up, go with non-atomic when you know your variables won't be accessed by multiple threads simultaneously and speed things up.

share|improve this answer

Easiest answer first: There's no difference between your second two examples. By default, property accessors are atomic.

Atomic accessors in a non garbage collected environment (i.e. when using retain/release/autorelease) will use a lock to ensure that another thread doesn't interfere with the correct setting/getting of the value.

See the "Performance and Threading" section of Apple's Objective-C 2.0 documentation for some more information and for other considerations when creating multi-threaded apps.

share|improve this answer
7  
Two reasons. First off, for synthesized code it generates faster (but not threadsafe code). Second, if you are writing customer accessors that are not atomic it lets you annotate for any future user that the code is not atomic when they are reading its interface, without making them implementation. – Louis Gerbarg Feb 26 '09 at 6:34
    

After reading so many articles, Stack Overflow posts and making demo applications to check variable property attributes, I decided to put all the attributes information together:

  1. atomic // Default
  2. nonatomic
  3. strong = retain // Default
  4. weak = unsafe_unretained
  5. retain
  6. assign // Default
  7. unsafe_unretained
  8. copy
  9. readonly
  10. readwrite // Default

In the article Variable property attributes or modifiers in iOS you can find all the above-mentioned attributes, and that will definitely help you.

  1. atomic

    • atomic means only one thread access the variable (static type).
    • atomic is thread safe.
    • But it is slow in performance
    • atomic is the default behavior
    • Atomic accessors in a non garbage collected environment (i.e. when using retain/release/autorelease) will use a lock to ensure that another thread doesn't interfere with the correct setting/getting of the value.
    • It is not actually a keyword.

    Example:

        @property (retain) NSString *name;
    
        @synthesize name;
    
  2. nonatomic

    • nonatomic means multiple thread access the variable (dynamic type).
    • nonatomic is thread-unsafe.
    • But it is fast in performance
    • nonatomic is NOT default behavior. We need to add the nonatomic keyword in the property attribute.
    • It may result in unexpected behavior, when two different process (threads) access the same variable at the same time.

    Example:

        @property (nonatomic, retain) NSString *name;
    
        @synthesize name;
    
share|improve this answer

Atomic guarantees that access to the property will be performed in an atomic manner. E.g. it will be thread safe, any get/set of a property on one thread must complete before another can access it.

If you imagine the following function occurring on two threads at once you can see why the results would not be pretty.

-(void) setName:(NSString*)string
{
  if (name)
  {
    [name release]; 
    // what happens if the second thread jumps in now !?
    // name may be deleted, but our 'name' variable is still set!
    name = nil;
  }

  ...
}
share|improve this answer
5  
That comment doesn't make a lot of sense. Can you clarify? If you look at examples on the Apple site then the atomic keyword synchronizes on the object while updating its properties. – Andrew Grant Feb 26 '09 at 7:31

Atomic means only one thread accesses the variable (static type). Atomic is thread-safe, but it is slow.

Nonatomic means multiple threads access the variable (dynamic type). Nonatomic is thread-unsafe, but it is fast.

share|improve this answer

The default is atomic, this means it does cost you performance whenever you use the property, but it is thread safe. What Objective-C does, is set a lock, so only the actual thread may access the variable, as long as the setter/getter is executed.

Example with MRC of a property with an ivar _internal:

[_internal lock]; //lock
id result = [[value retain] autorelease];
[_internal unlock];
return result;

So these last two are the same:

@property(atomic, retain) UITextField *userName;

@property(retain) UITextField *userName; // defaults to atomic

On the other hand does nonatomic add nothing to your code. So it is only thread safe if you code security mechanism yourself.

@property(nonatomic, retain) UITextField *userName;

The keywords doesn't have to be written as first property attribute at all.

Don't forget, this doesn't mean that the property as a whole is thread-safe. Only the method call of the setter/getter is. But if you use a setter and after that a getter at the same time with 2 different threads, it could be broken too!

share|improve this answer

Atomic is thread safe, it is slow and it well-assures(not guaranteed) that only the locked value is provided no matter how many threads are attempting access over same zone. When used Atomic, Piece of code written inside this function becomes the part of critical section, to which only one thread can execute at a time.

It only assures the thread safety, not guarantees that. What I mean is you hire an expert driver for you car, still it doesn't guarantees car wont meet an accident. However probability remains the slightest.

Atomic - it can't be broken down so result is expected, With Nonatomic - when another thread access the memory zone it can modify it so result is unexpected.

In Atomic - Variables are localized so that each thread has its own private copy. These variables retain their values across subroutine and other code boundaries, and are thread-safe since they are local to each thread, even though the code which accesses them might be reentrant.

share|improve this answer
3  
This answer is a LOT more clearer than the one that collected 1200+ points. Well done! – amok Nov 1 '15 at 0:01
1  
I agree that this explanation is much more friendly to newer programmers. – mn1 Dec 6 '15 at 6:10

There is no such keyword "atomic"

@property(atomic, retain) UITextField *userName;

We can use the above like

@property(retain) UITextField *userName;

See Stack Overflow question I am getting issues if I use @property(atomic,retain)NSString *myString.

share|improve this answer
9  
"There is such keyword", That the keyword is not required by default and even is the default value does not mean the keyword does not exist. – Matthijn Feb 25 '13 at 14:51
3  
This is incorrect. The keyword does exist. This answer is misleading, and I would encourage taking it down. – sethfri May 20 '15 at 0:00
    
Please update your knowledge.. Atomic does exist. – Mrug Jul 2 '15 at 5:03

Atomic means only one thread access the variable (static type).

  • Atomic is thread-safe.
  • But it is slow in performance
  • Atomic is the default behavior
  • Atomic accessors in a non-garbage collected environment (i.e. when using retain/release/autorelease) will use a lock to ensure that another thread doesn't interfere with the correct setting/getting of the value.
  • it is not actually a keyword.

Example:

@property (retain) NSString *name;

@synthesize name;

Nonatomic means multiple thread access the variable (dynamic type).

  • Nonatomic is thread unsafe.
  • But it is fast in performance
  • Nonatomic is NOT default behavior, we need to add nonatomic keyword in property attribute.
  • It may result in unexpected behavior, when two different process (threads) access the same variable at the same time.

Example:

@property (nonatomic, retain) NSString *name;
@synthesize name;

Explain:

Suppose there is an atomic string property called "name", and if you call [self setName:@"A"] from thread A,

Call [self setName:@"B"] from thread B, and call [self name] from thread C, then all operations on a different thread will be performed serially which means if one thread is executing setter or getter, then other threads will wait. This makes property "name" read/write safe, but if another thread D calls [name release] simultaneously then this operation might produce a crash because there is no setter/getter call involved here. Which means an object is read/write safe (ATOMIC) but not thread safe as another threads can simultaneously send any type of messages to the object. The developer should ensure thread safety for such objects.

If the property "name" was nonatomic, then all threads in above example - A,B, C and D will execute simultaneously producing any unpredictable result. In case of atomic, Either one of A, B or C will execute first but D can still execute in parallel. - See more at:

share|improve this answer
    
good explain! just one thing: "Atomic is thread safe" but later you say: Which means an object is read/write safe (ATOMIC) but not thread safe so..why you say atomic is thread safe? – volperossa Sep 3 '15 at 12:18

Threads and data

By default, your app's code executes on the main thread of your app's process, along with most Cocoa Touch framework code. Any particular method or function runs uninterrupted from start to finish and as long as that method or function leaves all the data it touches in a good state when it returns, your program runs correctly.

When you have multiple threads in your application, things aren't so easy. One key challenge when using multiple threads is to make sure you only read data when it's in a consistent state. This is similar in concept to using a transaction in a SQL database.

Suppose you have a custom UI object that's defined like this:

@interface MyWidget {
  CGPoint center;
  // ...
}
@property CGPoint center;
// ...
@end

@implementation

@synthesize center;

// ...
@end

If you treat instances of this class as read only when you share them between threads, you're safe. The trouble appears when one or both threads start to make changes to the object. If we were to write the getter and setter for center, it would look like this:

// example assign-type getter and setter
- (CGPoint) center {
  return center;
}
- (void)setCenter:(CGPoint)theCenter {
  center = theCenter;
}

This looks simple enough, but the compiler is helping us out here. The center instance variable is a struct that's defined like this:

// struct CGPoint
struct CGPoint {
  CGFloat x;
  CGFloat y;
};

The setCenter: method is actually doing something like this:

- (void)setCenter:(CGPoint)theCenter {
  center.x = theCenter.x;
  center.y = theCenter.y;
}

Let's look at what happens when one thread calls the setter and a second thread calls the getter. In the simple case, the setter and getter calls don't overlap:

// given MyWidget instance myWidget:

// thread 1 calls setter:
[myWidget setCenter:CGPointMake(1.0f, 2.0f)];

// setCenter method executes:
- (void)setCenter:(CGPoint)theCenter {
  center.x = theCenter.x; // 1.0f
  center.y = theCenter.y; // 2.0f
}
// center is now {1.0f, 2.0f}

// ... thread 1 preempted by thread 2 ...

                    // thread 2 calls getter:
                    CGPoint point = [myWidget center];

                    // center method executes:
                    - (CGPoint) center {
                      return center; // 1.0f, 2.0f
                    }

                    // point is now {1.0f, 2.0f}

In this case, we get the answer we expect. Now suppose we do this again, only thread 1 gets preempted by thread 2 in the middle of the setCenter method:

Atomic or nonatomic Behind the scenes, the @synchronized directive uses a lock to prevent two threads from accessing a @synchronized block simultaneously. Although acquiring and releasing the lock is very quick, it's not free. Occasionally you have a property that is so frequently accessed that all this locking and unlocking adds up to a noticeable penalty. In these rare cases, you can declare the property to be

nonatomic:
@interface MyWidget {
  CGPoint center;
  // ...
}
@property (nonatomic) CGPoint center;
// ...

@endThe compiler omits the synchronization code when generating nonatomic getters and setters. Note that there isn't a corresponding atomic attribute for @property; generated getters and setters are synchronized by default.

Acquiring a lock is very fast in the common case where no other thread is holding it. According to Apple's docs, it takes about 0.0000002 seconds (that's 0.2 microseconds) on a modern Mac. Even though the iPhone is much slower, you need to be acquiring locks hundreds of thousands of times before you should consider synchronization overhead as anything significant. For the vast majority of code, you should simply not even worry about nonatomic.

Also, keep in mind that the attributes you set on your @property declarations only apply when you use @synthesize to have the compiler generate the getter and setter methods. If you write the getter or setter yourself, the attributes are ignored. Next week we'll look a little more at synchronization and show you how to write a thread safe getter when returning an Objective-C object.

share|improve this answer

Before discussing about the attributes of @property, you should know what is the use of @property. @property offers a way to define the information that a class is intended to encapsulate. If you declare an object/variable using @property, then that object/variable will be accessible to other classes importing its class. If you declare an object using @property in the header file, then you have to synthesize it using @synthesize in the implementation file.

Example:

.h class

@interface ExampleClass : NSObject
   @property (nonatomic, retain) NSString *name;
@end

.m class

@implementation ExampleClass
   @synthesize name;
@end

Now the compiler will synthesize accessor methods for name.

ExampleClass *newObject=[[ExampleClass alloc]init];
NSString *name1=[newObject name]; // get 'name'
[obj setName:@“Tiger”];

List of attributes of @property : atomic. nonatomic. retain. copy. readonly. readwrite. assign. strong.

atomic : It is the default behaviour. If an object is declared as atomic then it becomes thread-safe. Thread-safe means, at a time only one thread of a particular instance of that class can have the control over that object.

Example :

@property NSString *name; //by default atomic
@property (atomic)NSString *name; // explicitly declared atomic

nonatomic: It is not thread-safe. You can use the nonatomic property attribute to specify that synthesized accessors simply set or return a value directly, with no guarantees about what happens if that same value is accessed simultaneously from different threads. For this reason, it’s faster to access a nonatomic property than an atomic one. @property (nonatomic)NSString *name;

retain: is required when the attribute is a pointer to an object.The setter method will increase retain count of the object, so that it will occupy memory in autorelease pool. @property (retain)NSString *name;

copy: If you use copy, you can't use retain. Using copy instance of the class will contain its own copy. Even if a mutable string is set and subsequently changed, the instance captures whatever value it has at the time it is set. No setter and getter methods will be synthesized.

@property (copy) NSString *name;

NSMutableString *nameString = [NSMutableString stringWithString:@"Liza"];    
xyzObj.name = nameString;    
[nameString appendString:@"Pizza"];

readonly: If you don't want to allow the property to be changed via setter method, you can declare the property readonly. @property (readonly) NSString *name;

readwrite: is the default behaviour. You don't need to specify readwrite attribute explicitly.

@property (readwrite) NSString *name;

assign: will generate a setter which assigns the value to the instance variable directly, rather than copying or retaining it. This is best for primitive types like NSInteger and CGFloat, or objects you don't directly own, such as delegates.

@property (assign) NSInteger year;

strong: is a replacement for retain. @property (nonatomic, strong) AVPlayer *player;

unsafe_unretained: There are a few classes in Cocoa and Cocoa Touch that don’t yet support weak references, which means you can’t declare a weak property or weak local variable to keep track of them. These classes include NSTextView, NSFont and NSColorSpace,etc. If you need to use a weak reference to one of these classes, you must use an unsafe reference. An unsafe reference is similar to a weak reference in that it doesn’t keep its related object alive, but it won’t be set to nil if the destination object is deallocated.

@property (unsafe_unretained) NSObject *unsafeProperty;

share|improve this answer

If you are using your property in multi-threaded code then you would be able to see the difference between nonatomic and atomic attributes. Nonatomic is faster than atomic and atomic is thread-safe, not nonatomic.

Vijayendra Tripathi has already given an example for a multi-threaded environment.

share|improve this answer

atomic property ensures to retain fully initialised value irrespective of how many threads are doing getter & setter on it. nonatomic property specifies that synthesized accessors simply set or return a value directly, with no guarantees about what happens if that same value is accessed simultaneously from different threads.

share|improve this answer

Atomic means only one thread can access the variable at a time(static type). Atomic is thread safe but it is slow.

Nonatomic means multiple threads can access the variable at s time(dynamic type). Nonatomic is thread unsafe but it is fast.

share|improve this answer

protected by Jesse Rusak Jun 3 '13 at 1:07

Thank you for your interest in this question. Because it has attracted low-quality or spam answers that had to be removed, posting an answer now requires 10 reputation on this site.

Would you like to answer one of these unanswered questions instead?

Not the answer you're looking for? Browse other questions tagged or ask your own question.