Memory leak using (void) alloc - iphone

I have seen a similar line of code floating about in Apples code:
(void)[[URLRequest alloc] initializeRequestWithValues:postBody url:verifySession httpHeader:nil delegate:self];
URLRequest is my own custom class. I didn't write this and I think the guy that did just grabbed it from Apple's example. To me this should leak and when I test it I'm pretty sure it leaks 16 bytes. Would it? I know how to fix it if it does but wasn't sure as it was taken from Apple's code.
EDIT: The problem was with the SDK, not the above code. See answer below for further details

Thought I might update this as after further testing and the release of iOS4 it has changed.
The above code doesn't leak and the memory footprint of the App returns to normal even after 200 iterations of the code. The leak did occur in iOS3 but was very small, in iOS4 it has completely disappeared both in simulator and device.
Some might wonder why you would want to implement this code but it works and make sense when dealing with lots of different NSURLConnections throughout your code running simultaneously.

Yes. This is a leak, which can easily be fixed by adding an autorelease:
[[[URLRequest alloc] initializeRequestWithValues:postBody url:verifySession httpHeader:nil delegate:self] autorelease];
Perhaps a better fix would be to create a class function that does this:
#interface URLRequest
{
// ...
}
// ...
+ (void) requestWithValues:/* ... */
// ...
#end
Then you could simply use [URLRequest requestWithValues: /* ... */] without invoking alloc.

Not at all sure what this code is supposed to accomplish. It does appear to break every single convention about initialization methods. What's the point of returning a void pointer from an initialization method? The entire point of an initialization method is to return an object. Where in Apple's code examples did you see this?
Having said that, I don't see why it would leak. Since it doesn't return an object there is nothing to leak external to the method. There might be something internally that leaks.
Edit:
It basically does an NSURLConnection.
Because we are submitting a lot of
forms with a lot of different values
we put it in an external class. All
the delegate methods like
didFailWithError: are in NSURLRequest
and connectionDidFinishLoading just
passes the data to its delegate. So it
doesn't really need to return anything
as it is done through a delegate
method.
Yeah, you need to redesign this. At present, this method is just a disaster waiting to happening. If nothing else, everyone else looking at this code will be utterly confused about what you are doing.
If you have no need to retain the object created, then move its allocation and clean up entirely within a method. Change the method name prefix from "initialize" to something like "setup", "configure", "acquire" etc so the name doesn't imply that it creates and returns and object.
If you need a one shot instance of a particular class, use a class method like Michael Aaron Safyan suggested (again without initialize in the name.) The class method should internally initialize an instance, perform the operations needed, return the data to wherever, then dealloc the instance.
That way, you won't have to worry about leaks and everyone else who may read your code (including yourself months down the road) will immediately understand what the code does.

Related

Why does using __weak not cause local variable to nil out immediately?

I've been working on the same project for some time now, and my understanding of Objective-C and Cocoa has evolved a little through time. Looking back in some parts of my code, I see this:
__weak ASIFormDataRequest *serverQueueRequest = [ASIFormDataRequest requestWithURL:url2];
[serverQueueRequest setCompletionBlock:^{
NSLog(#"%#", serverQueueRequest.responseString);
}];
[serverQueueRequest startAsynchronous];
And that's how I've been processing all my server requests. I think I did that to suppress a warning, namely that "capturing request in block may lead to a retain cycle". So I made it weak, and that seems to have solved all my issues. I haven't noticed any real problems with this.
However, looking at the code now, it seems a little odd that it works. When I declare the request as __weak, shouldn't it immediately zero out since no one is holding on to it? Why does this code work?
Also, although this code works, I just recently discovered a case where it doesn't: when calling the method that contains this code several times in succession, say 5 times within the span of a second, 3/5 requests will have a NULL response. This is consistently the case. Removing the __weak qualifier solves this issue. What's the explanation for that?
And so finally, what is the correct way to declare a local request like this?
Update: According to this question, the correct way to do it is like so:
ASIHTTPRequest *_request = [[ASIHTTPRequest alloc] initWithURL:...
__weak ASIHTTPRequest *request = _request;
Edit: actually the fix above does not fix the issue where calling the code 5 times results in NULL responses. That problem still exists. The only way that problem goes away is by capturing the request strongly and not using any qualifiers.
Now the question is why my original code still worked..
Quoting from Apple's Programming with ARC Release Notes:
Take care when using __weak variables on the stack. Consider the
following example:
NSString __weak *string = [[NSString alloc] initWithFormat:#"First Name: %#", [self firstName]];
NSLog(#"string:%#", string);
Although string is used after the initial assignment,
there is no other strong reference to the string object at the time of
assignment; it is therefore immediately deallocated. The log statement
shows that string has a null value.
The obj C stack will always retain pointers in scope. _weak does not mean release right now it means release when the stack goes out of scope.
When you declare a var and then make calls on it in the same stack scope it will not be released until after (minimally) the stack is cleaned up.
Blocks extend method scope since they imply potentially asynchronous behavior and they utilize the stack that was present when they were invoked.
I believe it is because you are running the weak variable in a block. The block holds onto the state of the weak variable which In turn causes it to work. I'm betting much work on the variable once the block is complete may cause issues.
My guess in why it fails if you run it many times is because the asynchronous asi call stack gets to high and bombs. I've seen this before and if you are very patient you can catch the asi blow up in the debugger.

Return Statement Creates and Release an Object

I'm working someone else's code. I've never encountered something like this before:
return [[[NSObject alloc] init] autorelease];
Can someone tell me what this means and why someone would use it? Just to be clear, I'm not asking about the autorelease portion. I would have the same question about this code:
-(id)someMethod
{
lots of lines of code
...
return [[NSObject alloc]init];
}
The autorelease feature indicates that you want to release this object in the FUTURE, but not now because you still need to access it. With the release cycles and releasing of the pool of memory, autorelease is an extremely useful tool in memory management.
You can refer to: http://developer.apple.com/mac/library/DOCUMENTATION/Cocoa/Conceptual/MemoryMgmt/Articles/mmPractical.html#//apple_ref/doc/uid/TP40004447 for information on autoreleasing.
Here's a link! What is the difference between releasing and autoreleasing?
Hope this helped!
The object is being allocated, initialized and then added to an autorelease pool.
Quoting Apple documentation (the link above):
Autorelease pools provide a mechanism whereby you can send an object a
“deferred” release message. This is useful in situations where you
want to relinquish ownership of an object, but want to avoid the
possibility of it being deallocated immediately (such as when you
return an object from a method). Typically, you don’t need to create
your own autorelease pools, but there are some situations in which
either you must or it is beneficial to do so.
TL;DR if nobody will retain the object soon, it will be released on the next iteration of the run loop.
It's hard to tell without knowing any details why would anyone want to allocate an NSObject in the first place. I'd suggest searching the project for that method's usage examples and see what happens with the object next.
It is just returning an autoreleased object for convenience. This means that when you use the function you do not have to append autorelease message to it generally speaking. You may always want certain objects to be autoreleased.
As an example, many of the included convenience ("factory") methods in Objective-C return an autoreleased object. You are probably familiar with [NSString stringWithFormat:__FORMAT__] which returns an autoreleased NSString. Take a look at http://memo.tv/archive/memory_management_with_objective_c_cocoa_iphone
As an example of why a function might return an object, consider a synchronous URL request, where you may or may not care about a response, or a function like the following:
- (NSString *)modifyObject:(MyObject *)o {
o.mySettableProp = #"MODIFIED!";
return [o description];
}

Is there any case where [self retain] is valid?

Reading source code of my current project, I see:
[self retain]
in one class, in its init method.
I don't understand exactly the reason.
Reading memory management rules from Apple, I don't see anything about this, and I don't see any hypothetical [self release].
The object is asserting ownership of itself when it is initialised. The only reason I can see that this might be useful is if the object needs to guarantee its own existence until some event has happened. For example, it might run a timer and then release itself when the timer expires.
If it's not documented and there is no corresponding release, it's probably a bug.
Best guess is that the person writing the code had a retain error and this was a "quick fix" around the real problem.
This seems to be probably an error, usually it's not up to the object to retain himself.
I see only one special case: delegate and notification, where you have to be much more careful about your life cycle, but even if this case, release/retain should not be done in the object itself.
Note to Erick:
In case of UIAlert, you can release it before it has been destroyed because the view has been but in the view hiercarchy, and then referenced. So the view will be automatically destroyed when it will be removed from the view hierarchy
It's not wrong to retain self. But seeing it in an init method sounds suspicious. I can't think of a good example of where that would be a good thing to do. Also though, with ARC, you can't even do that so you'd have to think of a better way of doing things. In general, if an object is required to be alive then there would be another object that is holding onto it. Self retaining objects are prone to errors where they will never be released.
If I recall correctly some classes use the self-retain to avoid pre-mature releasing. I would say it's not exactly best practice, but if you know the rules of the game (in this case Obj-C) you can break them (sometimes).
if you have some object, it's like it have healts/ lives. when you created it , it have one live. and. function 'retain' increasing his number of lives +1, release function decreasing his number of lives -1, dealloc decreasing too, alloc increasing

iPhone leak on this line, why?

I am getting a leak on this line and I'm not sure why...
weather.condition = [weather.condition lowercaseString];
weather is a NSMutableArray with a load of NSStrings in? Is there anything obviously wrong with this line or is it a bigger issue?
Thanks
One thing you have to learn about detecting memory leaks, is that leaks doesn't detect the line the leak occurs on per say, it detects where the object that is leaking was retained/copied/created. You need to look elsewhere for the actual leak, posting more code would be helpful. I'll update this answer if you do. Please comment below to indicate you've updated the answer with more code.
I remember i had this problem when i was using stringByReplacingOccurrencesOfString and i had to declare a new string to hold it in, rather than perform it on itself if that makes any sense!:)
If weather.condition is a synthesized retain property, then you could probably get away with that statement without a leak because the synthesized setCondition method will check to see if there is a value assigned to condition, and release it. If you wrote the setCondition method, you are responsible for managing the memory associated with condition.

What are best practices that you use when writing Objective-C and Cocoa? [closed]

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I know about the HIG (which is quite handy!), but what programming practices do you use when writing Objective-C, and more specifically when using Cocoa (or CocoaTouch).
There are a few things I have started to do that I do not think are standard:
1) With the advent of properties, I no longer use "_" to prefix "private" class variables. After all, if a variable can be accessed by other classes shouldn't there be a property for it? I always disliked the "_" prefix for making code uglier, and now I can leave it out.
2) Speaking of private things, I prefer to place private method definitions within the .m file in a class extension like so:
#import "MyClass.h"
#interface MyClass ()
- (void) someMethod;
- (void) someOtherMethod;
#end
#implementation MyClass
Why clutter up the .h file with things outsiders should not care about? The empty () works for private categories in the .m file, and issues compile warnings if you do not implement the methods declared.
3) I have taken to putting dealloc at the top of the .m file, just below the #synthesize directives. Shouldn't what you dealloc be at the top of the list of things you want to think about in a class? That is especially true in an environment like the iPhone.
3.5) In table cells, make every element (including the cell itself) opaque for performance. That means setting the appropriate background color in everything.
3.6) When using an NSURLConnection, as a rule you may well want to implement the delegate method:
- (NSCachedURLResponse *)connection:(NSURLConnection *)connection
willCacheResponse:(NSCachedURLResponse *)cachedResponse
{
return nil;
}
I find most web calls are very singular and it's more the exception than the rule you'll be wanting responses cached, especially for web service calls. Implementing the method as shown disables caching of responses.
Also of interest, are some good iPhone specific tips from Joseph Mattiello (received in an iPhone mailing list). There are more, but these were the most generally useful I thought (note that a few bits have now been slightly edited from the original to include details offered in responses):
4) Only use double precision if you have to, such as when working with CoreLocation. Make sure you end your constants in 'f' to make gcc store them as floats.
float val = someFloat * 2.2f;
This is mostly important when someFloat may actually be a double, you don't need the mixed-mode math, since you're losing precision in 'val' on storage. While floating-point numbers are supported in hardware on iPhones, it may still take more time to do double-precision arithmetic as opposed to single precision. References:
Double vs float on the iPhone
iPhone/iPad double precision math
On the older phones supposedly calculations operate at the same speed but you can have more single precision components in registers than doubles, so for many calculations single precision will end up being faster.
5) Set your properties as nonatomic. They're atomic by default and upon synthesis, semaphore code will be created to prevent multi-threading problems. 99% of you probably don't need to worry about this and the code is much less bloated and more memory-efficient when set to nonatomic.
6) SQLite can be a very, very fast way to cache large data sets. A map application for instance can cache its tiles into SQLite files. The most expensive part is disk I/O. Avoid many small writes by sending BEGIN; and COMMIT; between large blocks. We use a 2 second timer for instance that resets on each new submit. When it expires, we send COMMIT; , which causes all your writes to go in one large chunk. SQLite stores transaction data to disk and doing this Begin/End wrapping avoids creation of many transaction files, grouping all of the transactions into one file.
Also, SQL will block your GUI if it's on your main thread. If you have a very long query, It's a good idea to store your queries as static objects, and run your SQL on a separate thread. Make sure to wrap anything that modifies the database for query strings in #synchronize() {} blocks. For short queries just leave things on the main thread for easier convenience.
More SQLite optimization tips are here, though the document appears out of date many of the points are probably still good;
http://web.utk.edu/~jplyon/sqlite/SQLite_optimization_FAQ.html
Don't use unknown strings as format strings
When methods or functions take a format string argument, you should make sure that you have control over the content of the format string.
For example, when logging strings, it is tempting to pass the string variable as the sole argument to NSLog:
NSString *aString = // get a string from somewhere;
NSLog(aString);
The problem with this is that the string may contain characters that are interpreted as format strings. This can lead to erroneous output, crashes, and security problems. Instead, you should substitute the string variable into a format string:
NSLog(#"%#", aString);
Use standard Cocoa naming and formatting conventions and terminology rather than whatever you're used to from another environment. There are lots of Cocoa developers out there, and when another one of them starts working with your code, it'll be much more approachable if it looks and feels similar to other Cocoa code.
Examples of what to do and what not to do:
Don't declare id m_something; in an object's interface and call it a member variable or field; use something or _something for its name and call it an instance variable.
Don't name a getter -getSomething; the proper Cocoa name is just -something.
Don't name a setter -something:; it should be -setSomething:
The method name is interspersed with the arguments and includes colons; it's -[NSObject performSelector:withObject:], not NSObject::performSelector.
Use inter-caps (CamelCase) in method names, parameters, variables, class names, etc. rather than underbars (underscores).
Class names start with an upper-case letter, variable and method names with lower-case.
Whatever else you do, don't use Win16/Win32-style Hungarian notation. Even Microsoft gave up on that with the move to the .NET platform.
IBOutlets
Historically, memory management of outlets has been poor.
Current best practice is to declare outlets as properties:
#interface MyClass :NSObject {
NSTextField *textField;
}
#property (nonatomic, retain) IBOutlet NSTextField *textField;
#end
Using properties makes the memory management semantics clear; it also provides a consistent pattern if you use instance variable synthesis.
Use the LLVM/Clang Static Analyzer
NOTE: Under Xcode 4 this is now built into the IDE.
You use the Clang Static Analyzer to -- unsurprisingly -- analyse your C and Objective-C code (no C++ yet) on Mac OS X 10.5. It's trivial to install and use:
Download the latest version from this page.
From the command-line, cd to your project directory.
Execute scan-build -k -V xcodebuild.
(There are some additional constraints etc., in particular you should analyze a project in its "Debug" configuration -- see http://clang.llvm.org/StaticAnalysisUsage.html for details -- the but that's more-or-less what it boils down to.)
The analyser then produces a set of web pages for you that shows likely memory management and other basic problems that the compiler is unable to detect.
This is subtle one but handy one. If you're passing yourself as a delegate to another object, reset that object's delegate before you dealloc.
- (void)dealloc
{
self.someObject.delegate = NULL;
self.someObject = NULL;
//
[super dealloc];
}
By doing this you're ensuring that no more delegate methods will get sent. As you're about to dealloc and disappear into the ether you want to make sure that nothing can send you any more messages by accident. Remember self.someObject could be retained by another object (it could be a singleton or on the autorelease pool or whatever) and until you tell it "stop sending me messages!", it thinks your just-about-to-be-dealloced object is fair game.
Getting into this habit will save you from lots of weird crashes that are a pain to debug.
The same principal applies to Key Value Observation, and NSNotifications too.
Edit:
Even more defensive, change:
self.someObject.delegate = NULL;
into:
if (self.someObject.delegate == self)
self.someObject.delegate = NULL;
#kendell
Instead of:
#interface MyClass (private)
- (void) someMethod
- (void) someOtherMethod
#end
Use:
#interface MyClass ()
- (void) someMethod
- (void) someOtherMethod
#end
New in Objective-C 2.0.
Class extensions are described in Apple's Objective-C 2.0 Reference.
"Class extensions allow you to declare additional required API for a class in locations other than within the primary class #interface block"
So they're part of the actual class - and NOT a (private) category in addition to the class. Subtle but important difference.
Avoid autorelease
Since you typically(1) don't have direct control over their lifetime, autoreleased objects can persist for a comparatively long time and unnecessarily increase the memory footprint of your application. Whilst on the desktop this may be of little consequence, on more constrained platforms this can be a significant issue. On all platforms, therefore, and especially on more constrained platforms, it is considered best practice to avoid using methods that would lead to autoreleased objects and instead you are encouraged to use the alloc/init pattern.
Thus, rather than:
aVariable = [AClass convenienceMethod];
where able, you should instead use:
aVariable = [[AClass alloc] init];
// do things with aVariable
[aVariable release];
When you're writing your own methods that return a newly-created object, you can take advantage of Cocoa's naming convention to flag to the receiver that it must be released by prepending the method name with "new".
Thus, instead of:
- (MyClass *)convenienceMethod {
MyClass *instance = [[[self alloc] init] autorelease];
// configure instance
return instance;
}
you could write:
- (MyClass *)newInstance {
MyClass *instance = [[self alloc] init];
// configure instance
return instance;
}
Since the method name begins with "new", consumers of your API know that they're responsible for releasing the received object (see, for example, NSObjectController's newObject method).
(1) You can take control by using your own local autorelease pools. For more on this, see Autorelease Pools.
Some of these have already been mentioned, but here's what I can think of off the top of my head:
Follow KVO naming rules. Even if you don't use KVO now, in my experience often times it's still beneficial in the future. And if you are using KVO or bindings, you need to know things are going work the way they are supposed to. This covers not just accessor methods and instance variables, but to-many relationships, validation, auto-notifying dependent keys, and so on.
Put private methods in a category. Not just the interface, but the implementation as well. It's good to have some distance conceptually between private and non-private methods. I include everything in my .m file.
Put background thread methods in a category. Same as above. I've found it's good to keep a clear conceptual barrier when you're thinking about what's on the main thread and what's not.
Use #pragma mark [section]. Usually I group by my own methods, each subclass's overrides, and any information or formal protocols. This makes it a lot easier to jump to exactly what I'm looking for. On the same topic, group similar methods (like a table view's delegate methods) together, don't just stick them anywhere.
Prefix private methods & ivars with _. I like the way it looks, and I'm less likely to use an ivar when I mean a property by accident.
Don't use mutator methods / properties in init & dealloc. I've never had anything bad happen because of it, but I can see the logic if you change the method to do something that depends on the state of your object.
Put IBOutlets in properties. I actually just read this one here, but I'm going to start doing it. Regardless of any memory benefits, it seems better stylistically (at least to me).
Avoid writing code you don't absolutely need. This really covers a lot of things, like making ivars when a #define will do, or caching an array instead of sorting it each time the data is needed. There's a lot I could say about this, but the bottom line is don't write code until you need it, or the profiler tells you to. It makes things a lot easier to maintain in the long run.
Finish what you start. Having a lot of half-finished, buggy code is the fastest way to kill a project dead. If you need a stub method that's fine, just indicate it by putting NSLog( #"stub" ) inside, or however you want to keep track of things.
Write unit tests. You can test a lot of things in Cocoa that might be harder in other frameworks. For example, with UI code, you can generally verify that things are connected as they should be and trust that they'll work when used. And you can set up state & invoke delegate methods easily to test them.
You also don't have public vs. protected vs. private method visibility getting in the way of writing tests for your internals.
Golden Rule: If you alloc then you release!
UPDATE: Unless you are using ARC
Don't write Objective-C as if it were Java/C#/C++/etc.
I once saw a team used to writing Java EE web applications try to write a Cocoa desktop application. As if it was a Java EE web application. There was a lot of AbstractFooFactory and FooFactory and IFoo and Foo flying around when all they really needed was a Foo class and possibly a Fooable protocol.
Part of ensuring you don't do this is truly understanding the differences in the language. For example, you don't need the abstract factory and factory classes above because Objective-C class methods are dispatched just as dynamically as instance methods, and can be overridden in subclasses.
Make sure you bookmark the Debugging Magic page. This should be your first stop when banging your head against a wall while trying to find the source of a Cocoa bug.
For example, it will tell you how to find the method where you first allocated memory that later is causing crashes (like during app termination).
Try to avoid what I have now decided to call Newbiecategoryaholism. When newcomers to Objective-C discover categories they often go hog wild, adding useful little categories to every class in existence ("What? i can add a method to convert a number to roman numerals to NSNumber rock on!").
Don't do this.
Your code will be more portable and easier to understand with out dozens of little category methods sprinkled on top of two dozen foundation classes.
Most of the time when you really think you need a category method to help streamline some code you'll find you never end up reusing the method.
There are other dangers too, unless you're namespacing your category methods (and who besides the utterly insane ddribin is?) there is a chance that Apple, or a plugin, or something else running in your address space will also define the same category method with the same name with a slightly different side effect....
OK. Now that you've been warned, ignore the "don't do this part". But exercise extreme restraint.
Resist subclassing the world. In Cocoa a lot is done through delegation and use of the underlying runtime that in other frameworks is done through subclassing.
For example, in Java you use instances of anonymous *Listener subclasses a lot and in .NET you use your EventArgs subclasses a lot. In Cocoa, you don't do either — the target-action is used instead.
Sort strings as the user wants
When you sort strings to present to the user, you should not use the simple compare: method. Instead, you should always use localized comparison methods such as localizedCompare: or localizedCaseInsensitiveCompare:.
For more details, see Searching, Comparing, and Sorting Strings.
Declared Properties
You should typically use the Objective-C 2.0 Declared Properties feature for all your properties. If they are not public, add them in a class extension. Using declared properties makes the memory management semantics immediately clear, and makes it easier for you to check your dealloc method -- if you group your property declarations together you can quickly scan them and compare with the implementation of your dealloc method.
You should think hard before not marking properties as 'nonatomic'. As The Objective C Programming Language Guide notes, properties are atomic by default, and incur considerable overhead. Moreover, simply making all your properties atomic does not make your application thread-safe. Also note, of course, that if you don't specify 'nonatomic' and implement your own accessor methods (rather than synthesising them), you must implement them in an atomic fashion.
Think about nil values
As this question notes, messages to nil are valid in Objective-C. Whilst this is frequently an advantage -- leading to cleaner and more natural code -- the feature can occasionally lead to peculiar and difficult-to-track-down bugs if you get a nil value when you weren't expecting it.
Use NSAssert and friends.
I use nil as valid object all the time ... especially sending messages to nil is perfectly valid in Obj-C.
However if I really want to make sure about the state of a variable, I use NSAssert and NSParameterAssert, which helps to track down problems easily.
Simple but oft-forgotten one. According to spec:
In general, methods in different
classes that have the same selector
(the same name) must also share the
same return and argument types. This
constraint is imposed by the compiler
to allow dynamic binding.
in which case all the same named selectors, even if in different classes, will be regarded as to have identical return/argument types. Here is a simple example.
#interface FooInt:NSObject{}
-(int) print;
#end
#implementation FooInt
-(int) print{
return 5;
}
#end
#interface FooFloat:NSObject{}
-(float) print;
#end
#implementation FooFloat
-(float) print{
return 3.3;
}
#end
int main (int argc, const char * argv[]) {
NSAutoreleasePool * pool = [[NSAutoreleasePool alloc] init];
id f1=[[FooFloat alloc]init];
//prints 0, runtime considers [f1 print] to return int, as f1's type is "id" and FooInt precedes FooBar
NSLog(#"%f",[f1 print]);
FooFloat* f2=[[FooFloat alloc]init];
//prints 3.3 expectedly as the static type is FooFloat
NSLog(#"%f",[f2 print]);
[f1 release];
[f2 release]
[pool drain];
return 0;
}
If you're using Leopard (Mac OS X 10.5) or later, you can use the Instruments application to find and track memory leaks. After building your program in Xcode, select Run > Start with Performance Tool > Leaks.
Even if your app doesn't show any leaks, you may be keeping objects around too long. In Instruments, you can use the ObjectAlloc instrument for this. Select the ObjectAlloc instrument in your Instruments document, and bring up the instrument's detail (if it isn't already showing) by choosing View > Detail (it should have a check mark next to it). Under "Allocation Lifespan" in the ObjectAlloc detail, make sure you choose the radio button next to "Created & Still Living".
Now whenever you stop recording your application, selecting the ObjectAlloc tool will show you how many references there are to each still-living object in your application in the "# Net" column. Make sure you not only look at your own classes, but also the classes of your NIB files' top-level objects. For example, if you have no windows on the screen, and you see references to a still-living NSWindow, you may have not released it in your code.
Clean up in dealloc.
This is one of the easiest things to forget - esp. when coding at 150mph. Always, always, always clean up your attributes/member variables in dealloc.
I like to use Objc 2 attributes - with the new dot notation - so this makes the cleanup painless. Often as simple as:
- (void)dealloc
{
self.someAttribute = NULL;
[super dealloc];
}
This will take care of the release for you and set the attribute to NULL (which I consider defensive programming - in case another method further down in dealloc accesses the member variable again - rare but could happen).
With GC turned on in 10.5, this isn't needed so much any more - but you might still need to clean up others resources you create, you can do that in the finalize method instead.
All these comments are great, but I'm really surprised nobody mentioned Google's Objective-C Style Guide that was published a while back. I think they have done a very thorough job.
Also, semi-related topic (with room for more responses!):
What are those little Xcode tips & tricks you wish you knew about 2 years ago?.
Don't forget that NSWindowController and NSViewController will release the top-level objects of the NIB files they govern.
If you manually load a NIB file, you are responsible for releasing that NIB's top-level objects when you are done with them.
One rather obvious one for a beginner to use: utilize Xcode's auto-indentation feature for your code. Even if you are copy/pasting from another source, once you have pasted the code, you can select the entire block of code, right click on it, and then choose the option to re-indent everything within that block.
Xcode will actually parse through that section and indent it based on brackets, loops, etc. It's a lot more efficient than hitting the space bar or tab key for each and every line.
I know I overlooked this when first getting into Cocoa programming.
Make sure you understand memory management responsibilities regarding NIB files. You are responsible for releasing the top-level objects in any NIB file you load. Read Apple's Documentation on the subject.
Turn on all GCC warnings, then turn off those that are regularly caused by Apple's headers to reduce noise.
Also run Clang static analysis frequently; you can enable it for all builds via the "Run Static Analyzer" build setting.
Write unit tests and run them with each build.
Variables and properties
1/ Keeping your headers clean, hiding implementation
Don't include instance variables in your header. Private variables put into class continuation as properties. Public variables declare as public properties in your header.
If it should be only read, declare it as readonly and overwrite it as readwrite in class continutation.
Basically I am not using variables at all, only properties.
2/ Give your properties a non-default variable name, example:
#synthesize property = property_;
Reason 1: You will catch errors caused by forgetting "self." when assigning the property.
Reason 2: From my experiments, Leak Analyzer in Instruments has problems to detect leaking property with default name.
3/ Never use retain or release directly on properties (or only in very exceptional situations). In your dealloc just assign them a nil. Retain properties are meant to handle retain/release by themselves. You never know if a setter is not, for example, adding or removing observers. You should use the variable directly only inside its setter and getter.
Views
1/ Put every view definition into a xib, if you can (the exception is usually dynamic content and layer settings). It saves time (it's easier than writing code), it's easy to change and it keeps your code clean.
2/ Don't try to optimize views by decreasing the number of views. Don't create UIImageView in your code instead of xib just because you want to add subviews into it. Use UIImageView as background instead. The view framework can handle hundreds of views without problems.
3/ IBOutlets don't have to be always retained (or strong). Note that most of your IBOutlets are part of your view hierarchy and thus implicitly retained.
4/ Release all IBOutlets in viewDidUnload
5/ Call viewDidUnload from your dealloc method. It is not implicitly called.
Memory
1/ Autorelease objects when you create them. Many bugs are caused by moving your release call into one if-else branch or after a return statement. Release instead of autorelease should be used only in exceptional situations - e.g. when you are waiting for a runloop and you don't want your object to be autoreleased too early.
2/ Even if you are using Authomatic Reference Counting, you have to understand perfectly how retain-release methods work. Using retain-release manually is not more complicated than ARC, in both cases you have to thing about leaks and retain-cycles.
Consider using retain-release manually on big projects or complicated object hierarchies.
Comments
1/ Make your code autodocumented.
Every variable name and method name should tell what it is doing. If code is written correctly (you need a lot of practice in this), you won't need any code comments (not the same as documentation comments). Algorithms can be complicated but the code should be always simple.
2/ Sometimes, you'll need a comment. Usually to describe a non apparent code behavior or hack. If you feel you have to write a comment, first try to rewrite the code to be simpler and without the need of comments.
Indentation
1/ Don't increase indentation too much.
Most of your method code should be indented on the method level. Nested blocks (if, for etc.) decrease readability. If you have three nested blocks, you should try to put the inner blocks into a separate method. Four or more nested blocks should be never used.
If most of your method code is inside of an if, negate the if condition, example:
if (self) {
//... long initialization code ...
}
return self;
if (!self) {
return nil;
}
//... long initialization code ...
return self;
Understand C code, mainly C structs
Note that Obj-C is only a light OOP layer over C language. You should understand how basic code structures in C work (enums, structs, arrays, pointers etc).
Example:
view.frame = CGRectMake(view.frame.origin.x, view.frame.origin.y, view.frame.size.width, view.frame.size.height + 20);
is the same as:
CGRect frame = view.frame;
frame.size.height += 20;
view.frame = frame;
And many more
Mantain your own coding standards document and update it often. Try to learn from your bugs. Understand why a bug was created and try to avoid it using coding standards.
Our coding standards have currently about 20 pages, a mix of Java Coding Standards, Google Obj-C/C++ Standards and our own addings. Document your code, use standard standard indentation, white spaces and blank lines on the right places etc.
Be more functional.
Objective-C is object-oriented language, but Cocoa framework functional-style aware, and is designed functional style in many cases.
There is separation of mutability. Use immutable classes as primary, and mutable object as secondary. For instance, use NSArray primarily, and use NSMutableArray only when you need.
There is pure functions. Not so many, buy many of framework APIs are designed like pure function. Look at functions such as CGRectMake() or CGAffineTransformMake(). Obviously pointer form looks more efficient. However indirect argument with pointers can't offer side-effect-free. Design structures purely as much as possible.
Separate even state objects. Use -copy instead of -retain when passing a value to other object. Because shared state can influence mutation to value in other object silently. So can't be side-effect-free. If you have a value from external from object, copy it. So it's also important designing shared state as minimal as possible.
However don't be afraid of using impure functions too.
There is lazy evaluation. See something like -[UIViewController view] property. The view won't be created when the object is created. It'll be created when caller reading view property at first time. UIImage will not be loaded until it actually being drawn. There are many implementation like this design. This kind of designs are very helpful for resource management, but if you don't know the concept of lazy evaluation, it's not easy to understand behavior of them.
There is closure. Use C-blocks as much as possible. This will simplify your life greatly. But read once more about block-memory-management before using it.
There is semi-auto GC. NSAutoreleasePool. Use -autorelease primary. Use manual -retain/-release secondary when you really need. (ex: memory optimization, explicit resource deletion)