What you want to understand is the method declaration syntax. In Objective-C, a method has a name which looks like this
doSomethingWith:andAlso:inMode:. Each colon precedes an argument. When you declare or define a method, you also specify the types of the variables and their names; the type is given in parentheses. You also prepend things with a
- for instance methods and a
+ for static methods, as well as the (parenthesized) return type. Now, you have
- (NSString*) pickerView:(UIPickerView*)pickerView
When we decipher this, we find that:
-: It's an instance method.
(NSString*): The return type,
pickerView:: The first part of the method name.
(UIPickerView*)pickerView: The first argument; its name is
pickerView and it has type
titleForRow:: The second part of the method name.
(NSInteger)row: The second argument; its name is
row and its type is
forComponent:: The third part of the method name.
(NSInteger)component: The third argument; its name is
component and its type is
Thus, putting it all together, this defines the instance method
pickerView:titleForRow:forComponent:; it returns an
NSString*, and the three arguments it takes are of type
NSInteger, respectively. This method would be called as
[obj pickerView:myPV titleForRow:myRow forComponent:myComponent].
And just for further reference: in isolation, if you have
NSString* str, it declares a variable of type
NSString*; and if you have
(NSString*)obj, it (forcefully) converts that object to have type
NSString*. This has no connection to the method declaration syntax.
Edit 1: I also saw that you were asking about the asterisks. In (Objective-)C, this represents a pointer. If you have an
int x, say, then when you write
int y = x and then
y = 3, the original value of
x is unchanged. If, however, you have an
int* px, then you can write
px = &x. (Note that ints, declared as
int, are a completely different data type than int pointers declared as
int y = &x is garbage, as is
int* py = x, and so on.) This
& is the "address of" operator; it finds where
x is in memory and returns it. Now, if you write
int* py = px and then
py = &y, this won't change
px. But if you write
*px, you access the value currently stored in
x, and you can change it:
*px = 42 sets
42. For various reasons, when working with objects, people tend to like to work with references to them instead of their actual values; thus, in Objective-C, you only handle objects through pointers. What this means is that you will never see
NSMutableArray x, only
NSMutableArray* x; and that if you have
NSMutableArray* y = x, then
y are, roughly speaking, the same, and calling
[x addObject:obj] affects
y as well. There are more comprehensive tutorials out there—it's worth checking them out if you don't understand pointers—but this should suffice as an overview.
Edit 2: In another comment, you say you're coming from Ruby and Python. In Ruby (and I think Python, but I've used it less), every variable is a reference. This means that the basic use of pointers for object types should be familiar; as long as you never use
*, they'll function in pretty much the same way. The difference between pointers and references is that you can take references to objects and create pointers to pointers. For instance, many methods end in
...error:(NSDictionary**)error. This effectively provides an extra return value; in the method, if something goes wrong, they can write
*error = myErrorInfo. Since function arguments are copied,
error = myErrorInfo wouldn't be visible; however, the pointer's referent is still the same, and so it can be assigned to. If you then write code such as:
NSDictionary* errorDict = nil;
[obj unsafeOperation:@"http://stackoverflow.com" error:&errorDict];
You pass in a pointer to
errorDict so that the
unsafeOperation:error: method can write to
errorDict and you can see it.