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I wrote a test code to check how to use Instrument (Leaks). I have created a single view application and on a button click I have loaded a new view like this...
- (IBAction)btn_clkd:(id)sender {
new_file *new = [[new_file alloc] init];
if (new) {
[self.navigationController pushViewController:new animated:YES];
new = nil;
}
}
In new_file ViewDidLoad method, I have create a leak like below...
- (void)viewDidLoad
{
[super viewDidLoad];
// Do any additional setup after loading the view from its nib.
char *c_mem = (char*) malloc(10000000);
strcpy(c_mem, "TESTING");
// free(c_mem);
}
Even I'm using ARC, memory allocated is a plain C malloc, and I have not freed memory after used, even though I have popped and loaded again and again the new view, instrument(Leaks) is not detecting any leak in this code... What is the reason, Am I checking correctly?
Thanx
Given your view controller is deallocated (please verify), eventually Leaks will detect that c_mem pointer leaks.
Instruments may not find this immediately - due to the algorithm it uses to detect leaks.
The algorithm is basically searching for unreferenced variables looking like pointers which point into the heap. If it happens that there is an arbitrary variable, say p, whose value happens to be the value of c_mem - then Instruments thinks that pointer c_mem is still referenced from p -- even though p may contain only arbitrary data and not referencing c_mem.
Note that Instruments leak detecting algorithm is actually more sophisticated, and may change and get improved.
In order to find leaks, I always run special code - like unit tests - in a loop. If the used memory does not grow in time, you are usually good. You can also use the "Snapshot" feature of Leaks, and the "Mark Generation" feature of Allocations to check for the current state of the heap.
When you pop your ViewController, if nothing has references to it, it is deallocated automatically by ARC with all it's variables. That is why you do not get leaks.
Look at what happens to your controller, when you pop it, using Leak Instrument. Also you can see there a number of references on it. It is very convenient to detect retain cycles also.
Here is a full reference on how to use Instruments.
I have managed to get myself confused about some elements of memory management. I am new to objective-c, and memory managed languages generally.
I have read the memory management guidelines, but I remain confused about a couple of things.
1) Is there any need to clean up ivars, and method variables that are not retained by any object. For instance
-(void) someMethod{
int count = 100;
for (int i=0; i <count; i++) {
NSLog(#"Count = %d", i);
}
}
What happens to the "count" var after the method is complete?
If a method allocates lots of temporary variables, do those get removed from memory as long as they are not unreleased, alloc'd objects? Or do i need to set them to nil in some way?
2) If i have a static variable, for instance an NSString, do I have to do anything for that to be removed from memory when the class is dealloced?
3) I have noticed that NSStrings seem to have a retainCount of 2147483647 which wikipedia tells me is the max value for a 32 bit signed integer.
http://en.wikipedia.org/wiki/2147483647
myString retainCount = 2147483647
-(void) someMethod{
NSString *myString = #"testString";
NSLog(#"myString retainCount = %d", [myString retainCount]);
// logs: myString retainCount = 2147483647
}
What happens to this at the end of the method? Does this memory ever get emptied? The string is not being referenced by anything. My understanding is that the #"" convenience method for NSString returns an autoreleased object, but whats the point of autoreleasing something with a retainCount of 2147483647 anyway? In that case, whats the point of retaining or releasing ANY NSString?
I am well aware that retainCount should be ignored, but it just bugs me not to know what's going on here.
4) Does this matter at all? I know that the memory associated with an NSString isn't much to write home about, but I want to be a good memory management citizen, and I'm more interested in best practices than anything else.
Retain/release only matters for objects, not int, bool, float, double or other built-ins. So use it for id or other classes that you hold a pointer to an object. In your example, count doesn't need to be retained or released. It is allocated on the stack which is automatically cleaned up when the function returns.
You do need to deal with any local objects you alloc. Those are created with a retainCount set to 1, so you need to either hold on to them for later or release them. Most Cocoa functions (that don't start with copy or alloc) return an object that is autoreleased. This means that they will have release called on them later -- you can only hold these after the function if you call retain on them. If you want them to be cleaned up, you don't need to do anything (calling release would result in too many release calls).
If you have a static variable pointing to an object, then it is not touched when objects of that class are dealloced. If you want it to be released, you have to call release on it. If the static is an int, bool, or other built-in, you don't (can't) call release on it. That's part of the global memory of your app.
NSStrings that are set to string literals should not have release called on them. The retainCount is meaningless for them. That value is also -1 for signed int values.
If you do this -- [[NSString alloc] initCallHere:etc] -- you have to call release on it. Most of the time you get strings, you don't use alloc, so you don't need to call release. If you retain one, you need to call release.
Yes, it does matter. Over time leaks will cause the iPhone to kill your app.
You don't need to worry about count cause it's an integer, a primitive data type, not an object.
I've read that those just go away upon app termination or if you explicitly release them.
You are right in that you should not worry about the retain count in that way. Cocoa automatically gives #"" (NSConstantString objects) the absolute highest retain value so that they cannot be de-allocated.
You are over complicating the subject. The point of the three guidelines is so that you know that you only have to worry about memory management in three specific situations. Apple gives you these guidelines so that one doesn't have to worry about the specific internals for every single class (like manually tracking retainCount), not to mention that sometimes Cocoa does things differently (as with NSConstantString). As long as you remember these guidelines, you really don't have to know the very gritty details of what's going on underneath (of course, an understanding of the retain count concept helps, but compare this to manually tracking it).
I don't know which guide you read specifically, but if you haven't given this one a try, I highly recommend it. It summarizes the three guidelines in a concise and direct manner.
The Cocoa memory management rules only cover Objective C objects.
Local variables (non-static) are cleaned up when any subroutine or method exits (actually the stack memory is just reused/overwritten by subsequent subroutines or methods in the same thread). Constants which require memory (strings) and static variables are cleaned up when the app is torn down by the OS after it exits. Manually malloc'd memory is cleaned up when you manually free it.
But any object you alloc or retain: (whether assigned to an ivar, local, global, static, etc.) has to managed like any other object. Be careful assigning objects to global variables, unless you are really good at retain count management.
I ran a few stress tests on my Iphone app. The results are below. I am wondering if I should be concerned and, if so, what I might do about it.
I set up a timer to fire once a second. Whenever the timer fired, the app requested some XML data from the server. When the data arrived, the app then parsed the data and redisplayed the affected table view.On several trials, the app averaged about 500 times through the loop before crashing.
I then removed the parsing and redisplay steps from the above loop. Now it could go about 800 times.
I set up a loop to repeatedly redisplay the table view, without downloading anything. As soon as one redisplay was completed, the next one began. After 2601 loops, the app crashed.
All of the above numbers are larger than what a user is likely to do.
Also, my app never lasts long at all when I try to run it on the device under instruments. So I can't get useful data that way. (But without instruments it lasts quite a while, as detailed above.)
I would say you need to be very concerned. The first rule of programming is that the user will never do what you expect.
Things to consider:
Accessor methods. Use them. Set up
properties for all attributes and
always access them with the
appropriate getter/setter methods:
.
object.property = some_other_object; -OR-
[object setProperty:some_other_object];
and
object = some_other_object.some_property;
object = [some_other_object some_property];
Resist the temptation to do things like:
property = some_other_object;
[property retain];
Do you get output from ObjectAlloc?
There are 4 tools from memory leaks,
performance and object allocations.
Are none of them loading?
What do you get when the app crashes?
EXEC_BAD_ACCESS or some other error?
Balanced retain (either alloc or
copy) and release. It is a good idea
to keep every alloc/copy balanced
with a release/autorelease in the
same method. If you use your
accessors ALL OF THE TIME, the need
for doing manual releases is seldom.
Autorelease will often hide a real
problem. It is possible Autorelease
can mask some tricky allocation
issues. Double check your use of
autorelease.
EDITED (Added based on your fault code)
Based on your above answer of "Program received signal: 0". This indicates that you have run out of memory. I would start by looking for instances that your code does something like:
myObject = [[MyClass alloc] init];
[someMutableArray addObject:myObject];
and you do not have the "release" when you put the new object into the array. If this array then gets released, the object, myObject, will become an orphan but hang around in memory anyway. The easy way to do this is to grep for all of your "alloc"/"copy" messages. Except under exceedingly rare conditions, there should be a paired "release""/autorelease" in the same function. More often than not, the above should be:
myObject = [[[MyClass alloc] init] autorelease];
[someMutableArray addObject:myObject];
I have been looking through the questions asked on StackOverflow, but there are so many about memory management in Objective-C that I couldn't find the answer I was looking for.
The question is if it is ok (and recommnded) to call autorelease before adding a newly created object to a collection (like NSMutableArray)? Or should I release it explicitly after adding it. (I know NSMutableArray willl retain the object)
This illustrates my question:
Scenario A (autorelease):
- (void) add {
// array is an instance of NSMutableArray
MyClass *obj = [[[MyClass alloc] init] autorelease];
[array addObject:obj];
}
Scenario B (explicit release):
- (void) add {
// array is an instance of NSMutableArray
MyClass *obj = [[MyClass alloc] init];
[array addObject:obj];
[obj release];
}
I assume both are correct, but I am not sure, and I sure don't know what the preffered way is.
Can the Objective-C gurus shed some light on this?
IMHO, which way is 'right' is a matter of preference. I don't disagree with the responders who advocate not using autorelease, but my preference is to use autorelease unless there is an overwhelmingly compelling reason not to. I'll list my reasons and you can decide whether or not their appropriate to your style of programming.
As Chuck pointed out, there is a semi-urban legend that there's some kind of overhead to using autorelease pools. This could not be further from the truth, and this comes from countless hours spent using Shark.app to squeeze the last bit of performance out of code. Trying to optimize for this is deep in to "premature optimization" territory. If, and only if, Shark.app gives you hard data that this might be a problem should you even consider looking in to it.
As others pointed out, an autoreleased object is "released at some later point". This means they linger around, taking up memory, until that "later point" rolls around. For "most" cases, this is at the bottom of an event processing pass before the run loop sleeps until the next event (timer, user clicking something, etc).
Occasionally, though, you will need to get rid of those temporary objects sooner, rather than later. For example, you need to process a huge, multi-megabyte file, or tens of thousands of rows from a database. When this happens, you'll need to place a NSAutoreleasePool *pool = [[NSAutoreleasePool alloc] init]; at a well chosen point, followed by a [pool release]; at the bottom. This almost always happens in some kind of "loop batch processing", so it's usually at the start and bottom of some critical loop. Again, this should be evidence based, not hunch based. Instrument.app's ObjectAlloc is what you use to find these trouble spots.
The main reason why I prefer autorelease to release, though, is that it is much easier to write leak-free programs. In short, if you choose to go the release route, you need to guarantee that release is eventually sent to obj, under all circumstances. While this seems like it might be simple, it is actually surprisingly hard to do in practice. Take your example, for instance:
// array is an instance of NSMutableArray
MyClass *obj = [[MyClass alloc] init];
[array addObject:obj];
// Assume a few more lines of work....
[obj release];
Now imagine that for some reason, something, somewhere, subtly violates your assumption that array is mutable, maybe as the result of using some method to process the results, and the returned array containing the processed results was created as a NSArray. When you send addObject: to that immutable NSArray, an exception will be thrown, and you will never send obj its release message. Or maybe something goes wrong somewhere between when obj was allocd and the required call to release, like you check some condition and return() immediately by mistake because it slipped your mind that that call to release later on must take place.
You have just leaked an object. And probably signed yourself up to several days of trying to find out where and why it is your leaking it. From experience, you will spend many hours looking at that code above, convinced that it could not possibly be the source of the leak because you very clearly send obj a release. Then, after several days, you will experience what can only be described as a religious epiphany as you are enlightened to the cause of the problem.
Consider the autorelease case:
// array is an instance of NSMutableArray
MyClass *obj = [[[MyClass alloc] init] autorelease];
[array addObject:obj];
// Assume a few more lines of work....
Now, it no longer matters what happens because it's virtually impossible to leak obj accidentally, even under extremely unusual or exceptional corner cases.
Both are correct and will work as you're expecting them to.
I personally prefer to use the latter method, but only because I like to be explicit about when objects get released. By autoreleasing the object, all we're doing is saying "this object will get released at some arbitrary point in the future." That means you can put the autoreleased object into the array, destroy the array, and the object might (probably) still exist.
With the latter method, the object would get destroyed immediately with the array (providing that nothing else has come along and retained it in the meantime). If I'm in a memory-constrained environment (say, the iPhone) where I need to be careful about how much memory I'm using, I'll use the latter method just so I don't have so many objects lingering in an NSAutoreleasePool somewhere. If memory usage isn't a big concern for you (and it usually isn't for me, either), then either method is totally acceptable.
They are both correct but B may be preferred because it has no overhead at all. Autorelease causes the autorelease pool to take charge of the object. This has a very slight overhead which, of course, gets multiplied by the number of objects involved.
So with one object A and B are more or less the same but definitely don't use A in scenarios with lots of objects to add to the array.
In different situations autoreleasing may delay and accumulate the freeing of many objects at the end of the thread. This may be sub-optimal. Take care that anyway autoreleasing happens a lot without explicit intervention. For example many getters are implemented this way:
return [[myObject retain] autorelease];
so whenever you call the getter you add an object to the autorelease pool.
You can send the autorelease message at any point, because it isn't acted on until the application's message loop repeats (i.e. until all your methods have finished executing in response to user input).
http://macdevcenter.com/pub/a/mac/2001/07/27/cocoa.html?page=last&x-showcontent=text
You have alloc'ed the object, then it's your job to release it at some point. Both code snippets work merely the same, correct way, with the autorelease way being the potentionally slower counterpart.
Personally speaking, I prefer the autorelease way, since it's just easier to type and almost never is a bottleneck.
They're both OK. Some people will tell you to avoid autorelease because of "overhead" or some such thing, but the truth is, there is practically no overhead. Go ahead and benchmark it and try to find the "overhead." The only reason you'd avoid it is in a memory-starved situation like on the iPhone. On OS X, you have practically unlimited memory, so it isn't going to make much of a difference. Just use whichever is most convenient for you.
I prefer A (autoreleasing) for brevity and "safety", as johne calls it. It simplifies my code, and I've never run into problems with it.
That is, until today: I had a problem with autoreleasing a block before adding it to an array. See my stackoverflow question:
[myArray addObject:[[objcBlock copy] autorelease]] crashes on dealloc'ing the array (Update: Turns out the problem was elsewhere in my code, but still, there was a subtle difference in behavior with autorelease…)
I'm just beginning to have a look at Objective-C and Cocoa with a view to playing with the iPhone SDK. I'm reasonably comfortable with C's malloc and free concept, but Cocoa's references counting scheme has me rather confused. I'm told it's very elegant once you understand it, but I'm just not over the hump yet.
How do release, retain and autorelease work and what are the conventions about their use?
(Or failing that, what did you read which helped you get it?)
Let's start with retain and release; autorelease is really just a special case once you understand the basic concepts.
In Cocoa, each object keeps track of how many times it is being referenced (specifically, the NSObject base class implements this). By calling retain on an object, you are telling it that you want to up its reference count by one. By calling release, you tell the object you are letting go of it, and its reference count is decremented. If, after calling release, the reference count is now zero, then that object's memory is freed by the system.
The basic way this differs from malloc and free is that any given object doesn't need to worry about other parts of the system crashing because you've freed memory they were using. Assuming everyone is playing along and retaining/releasing according to the rules, when one piece of code retains and then releases the object, any other piece of code also referencing the object will be unaffected.
What can sometimes be confusing is knowing the circumstances under which you should call retain and release. My general rule of thumb is that if I want to hang on to an object for some length of time (if it's a member variable in a class, for instance), then I need to make sure the object's reference count knows about me. As described above, an object's reference count is incremented by calling retain. By convention, it is also incremented (set to 1, really) when the object is created with an "init" method. In either of these cases, it is my responsibility to call release on the object when I'm done with it. If I don't, there will be a memory leak.
Example of object creation:
NSString* s = [[NSString alloc] init]; // Ref count is 1
[s retain]; // Ref count is 2 - silly
// to do this after init
[s release]; // Ref count is back to 1
[s release]; // Ref count is 0, object is freed
Now for autorelease. Autorelease is used as a convenient (and sometimes necessary) way to tell the system to free this object up after a little while. From a plumbing perspective, when autorelease is called, the current thread's NSAutoreleasePool is alerted of the call. The NSAutoreleasePool now knows that once it gets an opportunity (after the current iteration of the event loop), it can call release on the object. From our perspective as programmers, it takes care of calling release for us, so we don't have to (and in fact, we shouldn't).
What's important to note is that (again, by convention) all object creation class methods return an autoreleased object. For example, in the following example, the variable "s" has a reference count of 1, but after the event loop completes, it will be destroyed.
NSString* s = [NSString stringWithString:#"Hello World"];
If you want to hang onto that string, you'd need to call retain explicitly, and then explicitly release it when you're done.
Consider the following (very contrived) bit of code, and you'll see a situation where autorelease is required:
- (NSString*)createHelloWorldString
{
NSString* s = [[NSString alloc] initWithString:#"Hello World"];
// Now what? We want to return s, but we've upped its reference count.
// The caller shouldn't be responsible for releasing it, since we're the
// ones that created it. If we call release, however, the reference
// count will hit zero and bad memory will be returned to the caller.
// The answer is to call autorelease before returning the string. By
// explicitly calling autorelease, we pass the responsibility for
// releasing the string on to the thread's NSAutoreleasePool, which will
// happen at some later time. The consequence is that the returned string
// will still be valid for the caller of this function.
return [s autorelease];
}
I realize all of this is a bit confusing - at some point, though, it will click. Here are a few references to get you going:
Apple's introduction to memory management.
Cocoa Programming for Mac OS X (4th Edition), by Aaron Hillegas - a very well written book with lots of great examples. It reads like a tutorial.
If you're truly diving in, you could head to Big Nerd Ranch. This is a training facility run by Aaron Hillegas - the author of the book mentioned above. I attended the Intro to Cocoa course there several years ago, and it was a great way to learn.
If you understand the process of retain/release then there are two golden rules that are "duh" obvious to established Cocoa programmers, but unfortunately are rarely spelled out this clearly for newcomers.
If a function which returns an object has alloc, create or copy in its name then the object is yours. You must call [object release] when you are finished with it. Or CFRelease(object), if it's a Core-Foundation object.
If it does NOT have one of these words in its name then the object belongs to someone else. You must call [object retain] if you wish to keep the object after the end of your function.
You would be well served to also follow this convention in functions you create yourself.
(Nitpickers: Yes, there are unfortunately a few API calls that are exceptions to these rules but they are rare).
If you're writing code for the desktop and you can target Mac OS X 10.5, you should at least look into using Objective-C garbage collection. It really will simplify most of your development — that's why Apple put all the effort into creating it in the first place, and making it perform well.
As for the memory management rules when not using GC:
If you create a new object using +alloc/+allocWithZone:, +new, -copy or -mutableCopy or if you -retain an object, you are taking ownership of it and must ensure it is sent -release.
If you receive an object in any other way, you are not the owner of it and should not ensure it is sent -release.
If you want to make sure an object is sent -release you can either send that yourself, or you can send the object -autorelease and the current autorelease pool will send it -release (once per received -autorelease) when the pool is drained.
Typically -autorelease is used as a way of ensuring that objects live for the length of the current event, but are cleaned up afterwards, as there is an autorelease pool that surrounds Cocoa's event processing. In Cocoa, it is far more common to return objects to a caller that are autoreleased than it is to return objets that the caller itself needs to release.
Objective-C uses Reference Counting, which means each Object has a reference count. When an object is created, it has a reference count of "1". Simply speaking, when an object is referred to (ie, stored somewhere), it gets "retained" which means its reference count is increased by one. When an object is no longer needed, it is "released" which means its reference count is decreased by one.
When an object's reference count is 0, the object is freed. This is basic reference counting.
For some languages, references are automatically increased and decreased, but objective-c is not one of those languages. Thus the programmer is responsible for retaining and releasing.
A typical way to write a method is:
id myVar = [someObject someMessage];
.... do something ....;
[myVar release];
return someValue;
The problem of needing to remember to release any acquired resources inside of code is both tedious and error-prone. Objective-C introduces another concept aimed at making this much easier: Autorelease Pools. Autorelease pools are special objects that are installed on each thread. They are a fairly simple class, if you look up NSAutoreleasePool.
When an object gets an "autorelease" message sent to it, the object will look for any autorelease pools sitting on the stack for this current thread. It will add the object to the list as an object to send a "release" message to at some point in the future, which is generally when the pool itself is released.
Taking the code above, you can rewrite it to be shorter and easier to read by saying:
id myVar = [[someObject someMessage] autorelease];
... do something ...;
return someValue;
Because the object is autoreleased, we no longer need to explicitly call "release" on it. This is because we know some autorelease pool will do it for us later.
Hopefully this helps. The Wikipedia article is pretty good about reference counting. More information about autorelease pools can be found here. Also note that if you are building for Mac OS X 10.5 and later, you can tell Xcode to build with garbage collection enabled, allowing you to completely ignore retain/release/autorelease.
Joshua (#6591) - The Garbage collection stuff in Mac OS X 10.5 seems pretty cool, but isn't available for the iPhone (or if you want your app to run on pre-10.5 versions of Mac OS X).
Also, if you're writing a library or something that might be reused, using the GC mode locks anyone using the code into also using the GC mode, so as I understand it, anyone trying to write widely reusable code tends to go for managing memory manually.
As ever, when people start trying to re-word the reference material they almost invariably get something wrong or provide an incomplete description.
Apple provides a complete description of Cocoa's memory management system in Memory Management Programming Guide for Cocoa, at the end of which there is a brief but accurate summary of the Memory Management Rules.
I'll not add to the specific of retain/release other than you might want to think about dropping $50 and getting the Hillegass book, but I would strongly suggest getting into using the Instruments tools very early in the development of your application (even your first one!). To do so, Run->Start with performance tools. I'd start with Leaks which is just one of many of the instruments available but will help to show you when you've forgot to release. It's quit daunting how much information you'll be presented with. But check out this tutorial to get up and going fast:
COCOA TUTORIAL: FIXING MEMORY LEAKS WITH INSTRUMENTS
Actually trying to force leaks might be a better way of, in turn, learning how to prevent them! Good luck ;)
Matt Dillard wrote:
return [[s autorelease] release];
Autorelease does not retain the object. Autorelease simply puts it in queue to be released later. You do not want to have a release statement there.
My usual collection of Cocoa memory management articles:
cocoa memory management
There's a free screencast available from the iDeveloperTV Network
Memory Management in Objective-C
NilObject's answer is a good start. Here's some supplemental info pertaining to manual memory management (required on the iPhone).
If you personally alloc/init an object, it comes with a reference count of 1. You are responsible for cleaning up after it when it's no longer needed, either by calling [foo release] or [foo autorelease]. release cleans it up right away, whereas autorelease adds the object to the autorelease pool, which will automatically release it at a later time.
autorelease is primarily for when you have a method that needs to return the object in question (so you can't manually release it, else you'll be returning a nil object) but you don't want to hold on to it, either.
If you acquire an object where you did not call alloc/init to get it -- for example:
foo = [NSString stringWithString:#"hello"];
but you want to hang on to this object, you need to call [foo retain]. Otherwise, it's possible it will get autoreleased and you'll be holding on to a nil reference (as it would in the above stringWithString example). When you no longer need it, call [foo release].
The answers above give clear restatements of what the documentation says; the problem most new people run into is the undocumented cases. For example:
Autorelease: docs say it will trigger a release "at some point in the future." WHEN?! Basically, you can count on the object being around until you exit your code back into the system event loop. The system MAY release the object any time after the current event cycle. (I think Matt said that, earlier.)
Static strings: NSString *foo = #"bar"; -- do you have to retain or release that? No. How about
-(void)getBar {
return #"bar";
}
...
NSString *foo = [self getBar]; // still no need to retain or release
The Creation Rule: If you created it, you own it, and are expected to release it.
In general, the way new Cocoa programmers get messed up is by not understanding which routines return an object with a retainCount > 0.
Here is a snippet from Very Simple Rules For Memory Management In Cocoa:
Retention Count rules
Within a given block, the use of -copy, -alloc and -retain should equal the use of -release and -autorelease.
Objects created using convenience constructors (e.g. NSString's stringWithString) are considered autoreleased.
Implement a -dealloc method to release the instancevariables you own
The 1st bullet says: if you called alloc (or new fooCopy), you need to call release on that object.
The 2nd bullet says: if you use a convenience constructor and you need the object to hang around (as with an image to be drawn later), you need to retain (and then later release) it.
The 3rd should be self-explanatory.
Lots of good information on cocoadev too:
MemoryManagement
RulesOfThumb
As several people mentioned already, Apple's Intro to Memory Management is by far the best place to start.
One useful link I haven't seen mentioned yet is Practical Memory Management. You'll find it in the middle of Apple's docs if you read through them, but it's worth direct linking. It's a brilliant executive summary of the memory management rules with examples and common mistakes (basically what other answers here are trying to explain, but not as well).