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Objects, Classes, and Messaging

This chapter describes the fundamentals of objects, classes, and messaging as used and implemented by the Objective-C language. It also introduces the Objective-C runtime.

The Runtime System

The Objective-C language defers as many decisions as it can from compile time and link time to runtime. Whenever possible, it dynamically performs operations such as creating objects and determining what method to invoke. Therefore, the language requires not just a compiler, but also a runtime system to execute the compiled code. The runtime system acts as a kind of operating system for the Objective-C language; it’s what makes the language work. Typically, however, you don’t need to interact with the runtime directly. To understand more about the functionality it offers, though, see Objective-C Runtime Programming Guide.

Objects

As the name implies, object-oriented programs are built around objects. An object associates data with the particular operations that can use or affect that data. Objective-C provides a data type to identify an object variable without specifying a particular class of the object.

Object Basics
An object associates data with the particular operations that can use or affect that data. In Objective-C, these operations are known as the object’s methods; the data they affect are its instance variables (in other environments they may be referred to as ivars or member variables). In essence, an object bundles a data structure (instance variables) and a group of procedures (methods) into a self-contained programming unit.

In Objective-C, an object’s instance variables are internal to the object; generally, you get access to an object’s state only through the object’s methods (you can specify whether subclasses or other objects can access instance variables directly by using scope directives, see “The Scope of Instance Variables”). For others to find out something about an object, there has to be a method to supply the information. For example, a rectangle would have methods that reveal its size and position.

Moreover, an object sees only the methods that were designed for it; it can’t mistakenly perform methods intended for other types of objects. Just as a C function protects its local variables, hiding them from the rest of the program, an object hides both its instance variables and its method implementations.

id
In Objective-C, object identifiers are of a distinct data type: id. This type is the general type for any kind of object regardless of class and can be used for instances of a class and for class objects themselves.

id anObject;
For the object-oriented constructs of Objective-C, such as method return values, id replaces int as the default data type. (For strictly C constructs, such as function return values, int remains the default type.)

The keyword nil is defined as a null object, an id with a value of 0. id, nil, and the other basic types of Objective-C are defined in the header file objc/objc.h.

id is defined as pointer to an object data structure:

typedef struct objc_object {
    Class isa;
} *id;
Every object thus has an isa variable that tells it of what class it is an instance. Since the Class type is itself defined as a pointer:

typedef struct objc_class *Class;
the isa variable is frequently referred to as the “isa pointer.”

Dynamic Typing
The id type is completely nonrestrictive. By itself, it yields no information about an object, except that it is an object. At some point, a program typically needs to find more specific information about the objects it contains. Since the id type designator can’t supply this specific information to the compiler, each object has to be able to supply it at runtime.

The isa instance variable identifies the object’s class—what kind of object it is. Objects with the same behavior (methods) and the same kinds of data (instance variables) are members of the same class.

Objects are thus dynamically typed at runtime. Whenever it needs to, the runtime system can find the exact class that an object belongs to, just by asking the object. (To learn more about the runtime, see Objective-C Runtime Programming Guide.) Dynamic typing in Objective-C serves as the foundation for dynamic binding, discussed later.

The isa variable also enables objects to perform introspection—to find out about themselves (or other objects). The compiler records information about class definitions in data structures for the runtime system to use. The functions of the runtime system use isa to find this information at runtime. Using the runtime system, you can, for example, determine whether an object implements a particular method or discover the name of its superclass.

Object classes are discussed in more detail under “Classes.”

It’s also possible to give the compiler information about the class of an object by statically typing it in source code using the class name. Classes are particular kinds of objects, and the class name can serve as a type name. See “Class Types” and “Enabling Static Behavior.”

Memory Management
In any program, it is important to ensure that objects are deallocated when they are no longer needed—otherwise your application’s memory footprint becomes larger than necessary. It is also important to ensure that you do not deallocate objects while they’re still being used.

Objective-C offers two mechanisms for memory management that allow you to meet these goals:

Reference counting, where you are ultimately responsible for determining the lifetime of objects.
Reference counting is described in Memory Management Programming Guide.

Garbage collection, where you pass responsibility for determining the lifetime of objects to an automatic “collector.”
Garbage collection is described in Garbage Collection Programming Guide. (Not available for iOS—you cannot access this document through the iOS Dev Center.)

Object Messaging

This section explains the syntax of sending messages, including how you can nest message expressions. It also discusses the scope or “visibility” of an object’s instance variables, and the concepts of polymorphism and dynamic binding.

Message Syntax
To get an object to do something, you send it a message telling it to apply a method. In Objective-C, message expressions are enclosed in brackets:

[receiver message]
The receiver is an object, and the message tells it what to do. In source code, the message is simply the name of a method and any parameters that are passed to it. When a message is sent, the runtime system selects the appropriate method from the receiver’s repertoire and invokes it.

For example, this message tells the myRectangle object to perform its display method, which causes the rectangle to display itself:

[myRectangle display];
The message is followed by a “;” as is normal for any statement in C.

Because the method name in a message serves to “select” a method implementation, method names in messages are often referred to as selectors.

Methods can also take parameters, sometimes called arguments. A message with a single parameter affixes a colon (:) to the name and puts the parameter right after the colon:

[myRectangle setWidth:20.0];
For methods with multiple parameters, Objective-C's method names are interleaved with the parameters such that the method’s name naturally describes the parameters expected by the method. The imaginary message below tells the myRectangle object to set its origin to the coordinates (30.0, 50.0):

[myRectangle setOriginX: 30.0 y: 50.0]; // This is a good example of
                                        // multiple parameters
A selector name includes all the parts of the name, including the colons, so the selector in the preceding example is named setOriginX:y:. It has two colons, because it takes two parameters. The selector name does not, however, include anything else, such as return type or parameter types.

Important: The subparts of an Objective-C selector name are not optional, nor can their order be varied. In some languages, the terms “named parameters” and “keyword parameters” carry the implications that the parameters can vary at runtime, can have default values, can be in a different order, and can possibly have additional named parameters. None of these characteristics about parameters are true for Objective-C.
For all intents and purposes, an Objective-C method declaration is simply a C function that prepends two additional parameters (see “Messaging” in the Objective-C Runtime Programming Guide). Thus, the structure of an Objective-C method declaration differs from the structure of a method that uses named or keyword parameters in a language like Python, as the following Python example illustrates:
def func(a, b, NeatMode=SuperNeat, Thing=DefaultThing):
    pass
In this Python example, Thing and NeatMode might be omitted or might have different values when called.
In principle, a Rectangle class could instead implement a setOrigin:: method with no label for the second parameter, which would be invoked as follows:

[myRectangle setOrigin:30.0 :50.0]; // This is a bad example of multiple parameters
While syntactically legal, setOrigin:: does not interleave the method name with the parameters. Thus, the second parameter is effectively unlabeled and it is difficult for a reader of this code to determine the kind or purpose of the method’s parameters.

Methods that take a variable number of parameters are also possible, though they’re somewhat rare. Extra parameters are separated by commas after the end of the method name. (Unlike colons, the commas are not considered part of the name.) In the following example, the imaginary makeGroup: method is passed one required parameter (group) and three parameters that are optional:

[receiver makeGroup:group, memberOne, memberTwo, memberThree];
Like standard C functions, methods can return values. The following example sets the variable isFilled to YES if myRectangle is drawn as a solid rectangle, or NO if it’s drawn in outline form only.

BOOL isFilled;
isFilled = [myRectangle isFilled];
Note that a variable and a method can have the same name.

One message expression can be nested inside another. Here, the color of one rectangle is set to the color of another:

[myRectangle setPrimaryColor:[otherRect primaryColor]];
Objective-C also provides a dot (.) operator that offers a compact and convenient syntax for invoking an object’s accessor methods. The dot operator is typically used in conjunction with the declared properties feature (see “Declared Properties”) and is described in “Dot Syntax.”

Sending Messages to nil
In Objective-C, it is valid to send a message to nil—it simply has no effect at runtime. There are several patterns in Cocoa that take advantage of this fact. The value returned from a message to nil may also be valid:

If the method returns an object, then a message sent to nil returns 0 (nil). For example:
Person *motherInLaw = [[aPerson spouse] mother];
If the spouse object here is nil, then mother is sent to nil and the method returns nil.
If the method returns any pointer type, any integer scalar of size less than or equal to sizeof(void*), a float, a double, a long double, or a long long, then a message sent to nil returns 0.
If the method returns a struct, as defined by the Mac OS X ABI Function Call Guide to be returned in registers, then a message sent to nil returns 0.0 for every field in the struct. Other struct data types will not be filled with zeros.
If the method returns anything other than the aforementioned value types, the return value of a message sent to nil is undefined.
The following code fragment illustrates a valid use of sending a message to nil.

id anObjectMaybeNil = nil;
 
// this is valid
if ([anObjectMaybeNil methodThatReturnsADouble] == 0.0)
{
    // implementation continues...
}
Note: The behavior of sending messages to nil changed slightly with Mac OS X v10.5.
In Mac OS  X v10.4 and earlier, a message to nil also is valid, as long as the message returns an object, any pointer type, void, or any integer scalar of size less than or equal to sizeof(void*); if it does, a message sent to nil returns nil. If the message sent to nil returns anything other than the aforementioned value types (for example, if it returns any struct type, any floating-point type, or any vector type) the return value is undefined. Therefore, in Mac OS X v10.4 and earlier, you should not rely on the return value of messages sent to nil unless the method’s return type is an object, any pointer type, or any integer scalar of size less than or equal to sizeof(void*).
The Receiver’s Instance Variables
A method has automatic access to the receiving object’s instance variables. You don’t need to pass them to the method as parameters. For example, the primaryColor method illustrated above takes no parameters, yet it can find the primary color for otherRect and return it. Every method assumes the receiver and its instance variables, without having to declare them as parameters.

This convention simplifies Objective-C source code. It also supports the way object-oriented programmers think about objects and messages. Messages are sent to receivers much as letters are delivered to your home. Message parameters bring information from the outside to the receiver; they don’t need to bring the receiver to itself.

A method has automatic access only to the receiver’s instance variables. If it requires information about a variable stored in another object, it must send a message to the object asking it to reveal the contents of the variable. The primaryColor and isFilled methods shown earlier are used for just this purpose.

See “Defining a Class” for more information on referring to instance variables.

Polymorphism
As the earlier examples illustrate, messages in Objective-C appear in the same syntactic positions as function calls in standard C. But, because methods “belong to” an object, messages don’t behave in the same way that function calls do.

In particular, an object can be operated on by only those methods that were defined for it. It can’t confuse them with methods defined for other kinds of object, even if another object has a method with the same name. Therefore, two objects can respond differently to the same message. For example, each kind of object that receives a display message could display itself in a unique way. A Circle and a Rectangle would respond differently to identical instructions to track the cursor.

This feature, referred to as polymorphism, plays a significant role in the design of object-oriented programs. Together with dynamic binding, it permits you to write code that might apply to any number of different kinds of objects, without you having to choose at the time you write the code what kinds of objects they might be. They might even be objects that will be developed later, by other programmers working on other projects. If you write code that sends a display message to an id variable, any object that has a display method is a potential receiver.

Dynamic Binding
A crucial difference between function calls and messages is that a function and its parameters are joined together in the compiled code, but a message and a receiving object aren’t united until the program is running and the message is sent. Therefore, the exact method invoked to respond to a message can be determined only at runtime, not when the code is compiled.

When a message is sent, a runtime messaging routine looks at the receiver and at the method named in the message. It locates the receiver’s implementation of a method matching the name, “calls” the method, and passes it a pointer to the receiver’s instance variables. (For more on this routine, see “Messaging” in Objective-C Runtime Programming Guide.)

This dynamic binding of methods to messages works hand in hand with polymorphism to give object-oriented programming much of its flexibility and power. Because each object can have its own version of a method, an Objective-C statement can achieve a variety of results, not by varying the message but by varying the object that receives the message. Receivers can be decided as the program runs; the choice of receiver can be made dependent on factors such as user actions.

When executing code based upon the Application Kit (AppKit), for example, users determine which objects receive messages from menu commands such as Cut, Copy, and Paste. The message goes to whatever object controls the current selection. An object that displays text would react to a copy message differently from an object that displays scanned images. An object that represents a set of shapes would respond differently to a copy message than a Rectangle would. Because messages do not select methods until runtime (from another perspective, because binding of methods to messages does not occur until runtime), these differences in behavior are isolated to the methods themselves. The code that sends the message doesn’t have to be concerned with them; it doesn’t even have to enumerate the possibilities. An application’s objects can each respond in its own way to copy messages.

Objective-C takes dynamic binding one step further and allows even the message that’s sent (the method selector) to be a variable determined at runtime. This mechanism is discussed in the section “Messaging” in Objective-C Runtime Programming Guide.

Dynamic Method Resolution
You can provide implementations of class and instance methods at runtime using dynamic method resolution. See “Dynamic Method Resolution” in Objective-C Runtime Programming Guide for more details.

Dot Syntax
Objective-C provides a dot (.) operator that offers an alternative to square bracket notation ([]) to invoke accessor methods. Dot syntax uses the same pattern that accessing C structure elements uses:

myInstance.value = 10;
printf("myInstance value: %d", myInstance.value);
When used with objects, however, dot syntax acts as “syntactic sugar”—it is transformed by the compiler into an invocation of an accessor method. Dot syntax does not directly get or set an instance variable. The code example above is exactly equivalent to the following:

[myInstance setValue:10];
printf("myInstance value: %d", [myInstance value]);
As a corollary, if you want to access an object’s own instance variable using accessor methods, you must explicitly call out self, for example:

self.age = 10;
or the equivalent:

[self setAge:10];
If you do not use self., you access the instance variable directly. In the following example, the set accessor method for age is not invoked:

age = 10;
An advantage of dot syntax is that its representation is more compact and may be more readable than the corresponding square bracket notation, particularly when you want to access or modify a property that is a property of another object (that is a property of another object, and so on). A further advantage is that the compiler can signal an error when it detects an attempt to write to a read-only declared property. If you instead use square bracket syntax for accessing variables, the compiler—at best—generates only an undeclared method warning that you invoked a nonexistent setter method, and the code fails at runtime.

General Use

When you use dot syntax to get a value, the system calls the associated getter accessor method. By default, the getter method has the same name as the symbol following the dot. Using dot syntax to set a value calls the associated setter accessor method. By default, the setter method is named by capitalizing the symbol following the dot and prefixing it with “set.” If you don’t want to use default accessor names, you can change them by using the declared properties feature (see “Declared Properties”).

Listing 1-1 illustrates several use cases.

Listing 1-1  Accessing properties using dot syntax
Graphic *graphic = [[Graphic alloc] init];
 
NSColor *color = graphic.color;
CGFloat xLoc = graphic.xLoc;
BOOL hidden = graphic.hidden;
int textCharacterLength = graphic.text.length;
 
if (graphic.textHidden != YES) {
    graphic.text = @"Hello"; // @"Hello" is a constant NSString object.
}
graphic.bounds = NSMakeRect(10.0, 10.0, 20.0, 120.0);
The statements in Listing 1-2 compile to exactly the same code as the statements using dot syntax shown in Listing 1-1, but instead use square bracket syntax.

Listing 1-2  Accessing properties using bracket syntax
Graphic *graphic = [[Graphic alloc] init];
 
NSColor *color = [graphic color];
CGFloat xLoc = [graphic xLoc];
BOOL hidden = [graphic hidden];
int textCharacterLength = [[graphic text] length];
 
if ([graphic isTextHidden] != YES) {
    [graphic setText:@"Hello"];
}
[graphic setBounds:NSMakeRect(10.0, 10.0, 20.0, 120.0)];
For properties of the appropriate C language type, the meaning of compound assignments is well defined. For example, say you have an instance of the NSMutableData class:

NSMutableData *data = [NSMutableData dataWithLength:1024];
You could update the length property of the instance using dot syntax and compound assignments:

data.length += 1024;
data.length *= 2;
data.length /= 4;
which is equivalent to the following square bracket statements:

[data setLength:[data length] + 1024];
[data setLength:[data length] * 2];
[data setLength:[data length] / 4];
nil Values

If a nil value is encountered during property traversal, the result is the same as sending the equivalent message to nil. For example, the following pairs are all equivalent:

// Each member of the path is an object.
x = person.address.street.name;
x = [[[person address] street] name];
 
// The path contains a C struct.
// This will crash if window is nil or -contentView returns nil.
y = window.contentView.bounds.origin.y;
y = [[window contentView] bounds].origin.y;
 
// An example of using a setter.
person.address.street.name = @"Oxford Road";
[[[person address] street] setName: @"Oxford Road"];
Performance and Threading

Whether you invoke accessor methods with dot syntax or square bracket syntax, the compiler generates equivalent code. As a result, the two coding techniques result in exactly the same performance. Because using dot syntax is simply a way to invoke accessor methods, doing so introduces no additional thread dependencies.

Dot Syntax Usage

Use the Objective-C dot syntax to invoke an accessor method, as an alternative to using square bracket syntax.

The following statement invokes the aProperty getter method and assigns the return value to aVariable:
aVariable = anObject.aProperty;
The type of the aProperty property and the type of the aVariable variable must be compatible, otherwise the compiler issues a warning.
The following statement invokes the setName: setter method on the anObject object, passing @"New Name" as the method’s parameter:
anObject.name = @"New Name";
The compiler issues a warning if the setName: method does not exist, if the property name does not exist, or if the setName: method returns anything but void.
The following statement invokes the bounds method on the aView object. It then assigns to the xOrigin variable the value of the origin.x structure element of the NSRect object returned by the bounds method.
xOrigin = aView.bounds.origin.x;
The following statements result in the assignment of the value of 11 to two properties: the integerProperty property of the anObject object and the floatProperty property of the anotherObject object.
NSInteger i = 10;
anObject.integerProperty = anotherObject.floatProperty = ++i;
That is, the rightmost assignment is preevaluated and the result is passed to the setIntegerProperty: and setFloatProperty: setter methods. The data type of the preevaluated result is coerced as required at each point of assignment.
Incorrect Use of Dot Syntax

The code patterns that follow are strongly discouraged because they do not conform to the intended use of dot syntax, namely for invoking an accessor method.

The following statement generates a compiler warning (warning: value returned from property not used.).
anObject.retain;
The following code generates a compiler warning that setFooIfYouCan: does not appear to be a setter method because it does not return (void).
/* Method declaration. */
- (BOOL) setFooIfYouCan: (MyClass *)newFoo;
 
/* Code fragment. */
anObject.fooIfYouCan = myInstance;
The following statement invokes the lockFocusIfCanDraw method and assigns the return value to flag. It does not generate a compiler warning unless there is a mismatch between the type for flag and the method’s return type. Nonetheless, this pattern is strongly discouraged.
flag = aView.lockFocusIfCanDraw;
The following code generates a compiler warning because the readonlyProperty property is declared with readonly access (warning: assignment to readonly property 'readonlyProperty').
/* Property declaration. */
@property(readonly) NSInteger readonlyProperty;
 
/* Method declaration. */
- (void) setReadonlyProperty: (NSInteger)newValue;
 
/* Code fragment. */
self.readonlyProperty = 5;
Even so, because the setter method is present, this code works at runtime. This pattern is strongly discouraged because simply adding a setter for a property does not imply readwrite access. Be sure to explicitly set property access correctly in a property’s declaration statement.
Classes

An object-oriented program is typically built from a variety of objects. A program based on the Cocoa frameworks might use NSMatrix objects, NSWindow objects, NSDictionary objects, NSFont objects, NSText objects, and many others. Programs often use more than one object of the same kind or class—several NSArray objects or NSWindow objects, for example.

In Objective-C, you define objects by defining their class. The class definition is a prototype for a kind of object; it declares the instance variables that become part of every member of the class, and it defines a set of methods that all objects in the class can use.

The compiler creates just one accessible object for each class, a class object that knows how to build new objects belonging to the class. (For this reason it’s traditionally called a factory object.) The class object is the compiled version of the class; the objects it builds are instances of the class. The objects that do the main work of your program are instances created by the class object at runtime.

All instances of a class have the same set of methods, and they all have a set of instance variables cut from the same mold. Each object gets its own instance variables, but the methods are shared.

By convention, class names begin with an uppercase letter (such as Rectangle); the names of instances typically begin with a lowercase letter (such as myRectangle).

Inheritance
Class definitions are additive; each new class that you define is based on another class from which it inherits methods and instance variables. The new class simply adds to or modifies what it inherits. It doesn’t need to duplicate inherited code.

Inheritance links all classes together in a hierarchical tree with a single class at its root. When writing code that is based upon the Foundation framework, that root class is typically NSObject. Every class (except a root class) has a superclass one step nearer the root, and any class (including a root class) can be the superclass for any number of subclasses one step farther from the root. Figure 1-1 illustrates the hierarchy for a few of the classes used in a drawing program.

Figure 1-1  Some drawing program classes

Figure 1-1 shows that the Square class is a subclass of the Rectangle class, the Rectangle class is a subclass of Shape, Shape is a subclass of Graphic, and Graphic is a subclass of NSObject. Inheritance is cumulative. So a Square object has the methods and instance variables defined for Rectangle, Shape, Graphic, and NSObject, as well as those defined specifically for Square. This is simply to say that an object of type Square isn’t only a square, it’s also a rectangle, a shape, a graphic, and an object of type NSObject.

Every class but NSObject can thus be seen as a specialization or an adaptation of another class. Each successive subclass further modifies the cumulative total of what’s inherited. The Square class defines only the minimum needed to turn a rectangle into a square.

When you define a class, you link it to the hierarchy by declaring its superclass; every class you create must be the subclass of another class (unless you define a new root class). Plenty of potential superclasses are available. Cocoa includes the NSObject class and several frameworks containing definitions for more than 250 additional classes. Some are classes that you can use off the shelf and incorporate them into your program as is. Others you might want to adapt to your own needs by defining a subclass.

Some framework classes define almost everything you need, but leave some specifics to be implemented in a subclass. You can thus create very sophisticated objects by writing only a small amount of code and reusing work done by the programmers of the framework.

The NSObject Class

NSObject is a root class, and so doesn’t have a superclass. It defines the basic framework for Objective-C objects and object interactions. It imparts to the classes and instances of classes that inherit from it the ability to behave as objects and cooperate with the runtime system.

A class that doesn’t need to inherit any special behavior from another class should nevertheless be made a subclass of the NSObject class. Instances of the class must at least have the ability to behave like Objective-C objects at runtime. Inheriting this ability from the NSObject class is much simpler and much more reliable than reinventing it in a new class definition.

Note: Implementing a new root class is a delicate task and one with many hidden hazards. The class must duplicate much of what the NSObject class does, such as allocate instances, connect them to their class, and identify them to the runtime system. For this reason, you should generally use the NSObject class provided with Cocoa as the root class. For more information, see NSObject Class Reference and the NSObject Protocol Reference.
Inheriting Instance Variables

When a class object creates a new instance, the new object contains not only the instance variables that were defined for its class but also the instance variables defined for its superclass and for its superclass’s superclass, all the way back to the root class. Thus, the isa instance variable defined in the NSObject class becomes part of every object. isa connects each object to its class.

Figure 1-2 shows some of the instance variables that could be defined for a particular implementation of a Rectangle class and where they may come from. Note that the variables that make the object a rectangle are added to the ones that make it a shape, and the ones that make it a shape are added to the ones that make it a graphic, and so on.

Figure 1-2  Rectangle instance variables

A class doesn’t have to declare instance variables. It can simply define new methods and rely on the instance variables it inherits, if it needs any instance variables at all. For example, Square might not declare any new instance variables of its own.

Inheriting Methods

An object has access not only to the methods defined for its class but also to methods defined for its superclass, and for its superclass’s superclass, all the way back to the root of the hierarchy. For instance, a Square object can use methods defined in the Rectangle, Shape, Graphic, and NSObject classes as well as methods defined in its own class.

Any new class you define in your program can therefore make use of the code written for all the classes above it in the hierarchy. This type of inheritance is a major benefit of object-oriented programming. When you use one of the object-oriented frameworks provided by Cocoa, your programs can take advantage of the basic functionality coded into the framework classes. You have to add only the code that customizes the standard functionality to your application.

Class objects also inherit from the classes above them in the hierarchy. But because they don’t have instance variables (only instances do), they inherit only methods.

Overriding One Method with Another

There’s one useful exception to inheritance: When you define a new class, you can implement a new method with the same name as one defined in a class farther up the hierarchy. The new method overrides the original; instances of the new class perform it rather than the original, and subclasses of the new class inherit it rather than the original.

For example, Graphic defines a display method that Rectangle overrides by defining its own version of display. The Graphic method is available to all kinds of objects that inherit from the Graphic class—but not to Rectangle objects, which instead perform the Rectangle version of display.

Although overriding a method blocks the original version from being inherited, other methods defined in the new class can skip over the redefined method and find the original (see “Messages to self and super” to learn how).

A redefined method can also incorporate the very method it overrides. When it does, the new method serves only to refine or modify the method it overrides, rather than replace it outright. When several classes in the hierarchy define the same method, but each new version incorporates the version it overrides, the implementation of the method is effectively spread over all the classes.

Although a subclass can override inherited methods, it can’t override inherited instance variables. Because an object has memory allocated for every instance variable it inherits, you can’t override an inherited variable by declaring a new one with the same name. If you try, the compiler will complain.

Abstract Classes

Some classes are designed only or primarily so that other classes can inherit from them. These abstract classes group methods and instance variables that can be used by a number of subclasses into a common definition. The abstract class is typically incomplete by itself, but contains useful code that reduces the implementation burden of its subclasses. (Because abstract classes must have subclasses to be useful, they’re sometimes also called abstract superclasses.)

Unlike some other languages, Objective-C does not have syntax to mark classes as abstract, nor does it prevent you from creating an instance of an abstract class.

The NSObject class is the canonical example of an abstract class in Cocoa. You never use instances of the NSObject class in an application—it wouldn’t be good for anything; it would be a generic object with the ability to do nothing in particular.

The NSView class, on the other hand, provides an example of an abstract class, instances of which you might occasionally use directly.

Abstract classes often contain code that helps define the structure of an application. When you create subclasses of these classes, instances of your new classes fit effortlessly into the application structure and work automatically with other objects.

Class Types
A class definition is a specification for a kind of object. The class, in effect, defines a data type. The type is based not just on the data structure the class defines (instance variables), but also on the behavior included in the definition (methods).

A class name can appear in source code wherever a type specifier is permitted in C—for example, as an argument to the sizeof operator:

int i = sizeof(Rectangle);
Static Typing

You can use a class name in place of id to designate an object’s type:

Rectangle *myRectangle;
Because this way of declaring an object type gives the compiler information about the kind of object it is, it’s known as static typing. Just as id is actually a pointer, objects are statically typed as pointers to a class. Objects are always typed by a pointer. Static typing makes the pointer explicit; id hides it.

Static typing permits the compiler to do some type checking—for example, to warn if an object could receive a message that it appears not to be able to respond to—and to loosen some restrictions that apply to objects generically typed id. In addition, it can make your intentions clearer to others who read your source code. However, it doesn’t defeat dynamic binding or alter the dynamic determination of a receiver’s class at runtime.

An object can be statically typed to its own class or to any class that it inherits from. For example, because inheritance makes a Rectangle object a kind of Graphic object (as shown in the example hierarchy in Figure 1-1), a Rectangle instance can be statically typed to the Graphic class:

Graphic *myRectangle;
Static typing to the superclass is possible here because a Rectangle object is a Graphic object. In addition, it’s more than that because it also has the instance variables and method capabilities of Shape and Rectangle objects, but it’s a Graphic object nonetheless. For purposes of type checking, given the declaration described here, the compiler considers myRectangle to be of type Graphic. At runtime, however, if the myRectangle object is allocated and initialized as an instance of Rectangle, it is treated as one.

See “Enabling Static Behavior” for more on static typing and its benefits.

Type Introspection

Instances can reveal their types at runtime. The isMemberOfClass: method, defined in the NSObject class, checks whether the receiver is an instance of a particular class:

if ( [anObject isMemberOfClass:someClass] )
    ...
The isKindOfClass: method, also defined in the NSObject class, checks more generally whether the receiver inherits from or is a member of a particular class (whether it has the class in its inheritance path):

if ( [anObject isKindOfClass:someClass] )
    ...
The set of classes for which isKindOfClass: returns YES is the same set to which the receiver can be statically typed.

Introspection isn’t limited to type information. Later sections of this chapter discuss methods that return the class object, report whether an object can respond to a message, and reveal other information.

See NSObject Class Reference for more on isKindOfClass:, isMemberOfClass:, and related methods.

Class Objects
A class definition contains various kinds of information, much of it about instances of the class:

The name of the class and its superclass
A template describing a set of instance variables
The declarations of method names and their return and parameter types
The method implementations
This information is compiled and recorded in data structures made available to the runtime system. The compiler creates just one object, a class object, to represent the class. The class object has access to all the information about the class, which means mainly information about what instances of the class are like. It’s able to produce new instances according to the plan put forward in the class definition.

Although a class object keeps the prototype of a class instance, it’s not an instance itself. It has no instance variables of its own and it can’t perform methods intended for instances of the class. However, a class definition can include methods intended specifically for the class object—class methods as opposed to instance methods. A class object inherits class methods from the classes above it in the hierarchy, just as instances inherit instance methods.

In source code, the class object is represented by the class name. In the following example, the Rectangle class returns the class version number using a method inherited from the NSObject class:

int versionNumber = [Rectangle version];
However, the class name stands for the class object only as the receiver in a message expression. Elsewhere, you need to ask an instance or the class to return the class id. Both respond to a class message:

id aClass = [anObject class];
id rectClass = [Rectangle class];
As these examples show, class objects can, like all other objects, be typed id. But class objects can also be more specifically typed to the Class data type:

Class aClass = [anObject class];
Class rectClass = [Rectangle class];
All class objects are of type Class. Using this type name for a class is equivalent to using the class name to statically type an instance.

Class objects are thus full-fledged objects that can be dynamically typed, receive messages, and inherit methods from other classes. They’re special only in that they’re created by the compiler, lack data structures (instance variables) of their own other than those built from the class definition, and are the agents for producing instances at runtime.

Note: The compiler also builds a metaclass object for each class. It describes the class object just as the class object describes instances of the class. But while you can send messages to instances and to the class object, the metaclass object is used only internally by the runtime system.
Creating Instances

A principal function of a class object is to create new instances. This code tells the Rectangle class to create a new rectangle instance and assign it to the myRectangle variable:

id  myRectangle;
myRectangle = [Rectangle alloc];
The alloc method dynamically allocates memory for the new object’s instance variables and initializes them all to 0—all, that is, except the isa variable that connects the new instance to its class. For an object to be useful, it generally needs to be more completely initialized. That’s the function of an init method. Initialization typically follows immediately after allocation:

myRectangle = [[Rectangle alloc] init];
This line of code, or one like it, would be necessary before myRectangle could receive any of the messages that were illustrated in previous examples in this chapter. The alloc method returns a new instance and that instance performs an init method to set its initial state. Every class object has at least one method (like alloc) that enables it to produce new objects, and every instance has at least one method (like init) that prepares it for use. Initialization methods often take parameters to allow particular values to be passed and have keywords to label the parameters (initWithPosition:size:, for example, is a method that might initialize a new Rectangle instance), but every initialization method begins with “init”.

Customization with Class Objects

It’s not just a whim of the Objective-C language that classes are treated as objects. It’s a choice that has intended, and sometimes surprising, benefits for design. It’s possible, for example, to customize an object with a class, where the class belongs to an open-ended set. In AppKit, for example, an NSMatrix object can be customized with a particular kind of NSCell object.

An NSMatrix object can take responsibility for creating the individual objects that represent its cells. It can do this when the matrix is first initialized and later when new cells are needed. The visible matrix that an NSMatrix object draws on the screen can grow and shrink at runtime, perhaps in response to user actions. When it grows, the matrix needs to be able to produce new objects to fill the new slots that are added.

But what kind of objects should they be? Each matrix displays just one kind of NSCell, but there are many different kinds. The inheritance hierarchy in Figure 1-3 shows some of those provided by AppKit. All inherit from the generic NSCell class.

Figure 1-3  The inheritance hierarchy for NSCell

When a matrix creates NSCell objects, should they be NSButtonCell objects to display a bank of buttons or switches, NSTextFieldCell objects to display fields where the user can enter and edit text, or some other kind of NSCell? The NSMatrix object must allow for any kind of cell, even types that haven’t been invented yet.

One solution to this problem would be to define the NSMatrix class as abstract and require everyone who uses it to declare a subclass and implement the methods that produce new cells. Because they would be implementing the methods, users could make certain that the objects they created were of the right type.

But this solution would require users of the NSMatrix class to do work that ought to be done in the NSMatrix class itself, and it unnecessarily proliferates the number of classes. Because an application might need more than one kind of matrix, each with a different kind of cell, it could become cluttered with NSMatrix subclasses. Every time you invented a new kind of NSCell, you’d also have to define a new kind of NSMatrix. Moreover, programmers on different projects would be writing virtually identical code to do the same job, all to make up for the failure of NSMatrix to do it.

A better solution, and the solution the NSMatrix class adopts, is to allow NSMatrix instances to be initialized with a kind of NSCell—that is, with a class object. The NSMatrix class also defines a setCellClass: method that passes the class object for the kind of NSCell object an NSMatrix should use to fill empty slots:

[myMatrix setCellClass:[NSButtonCell class]];
The NSMatrix object uses the class object to produce new cells when it’s first initialized and whenever it’s resized to contain more cells. This kind of customization would be difficult if classes weren’t objects that could be passed in messages and assigned to variables.

Variables and Class Objects

When you define a new class, you can specify instance variables. Every instance of the class can maintain its own copy of the variables you declare—each object controls its own data. There is, however, no class variable counterpart to an instance variable. Only internal data structures, initialized from the class definition, are provided for the class. Moreover, a class object has no access to the instance variables of any instances; it can’t initialize, read, or alter them.

For all the instances of a class to share data, you must define an external variable of some sort. The simplest way to do this is to declare a variable in the class implementation file:

int MCLSGlobalVariable;
 
@implementation MyClass
// implementation continues
In a more sophisticated implementation, you can declare a variable to be static, and provide class methods to manage it. Declaring a variable static limits its scope to just the class—and to just the part of the class that’s implemented in the file. (Thus unlike instance variables, static variables cannot be inherited by, or directly manipulated by, subclasses.) This pattern is commonly used to define shared instances of a class (such as singletons; see “Creating a Singleton Instance” in Cocoa Fundamentals Guide).

static MyClass *MCLSSharedInstance;
 
@implementation MyClass
 
+ (MyClass *)sharedInstance
{
    // check for existence of shared instance
    // create if necessary
    return MCLSSharedInstance;
}
// implementation continues
Static variables help give the class object more functionality than just that of a factory producing instances; it can approach being a complete and versatile object in its own right. A class object can be used to coordinate the instances it creates, dispense instances from lists of objects already created, or manage other processes essential to the application. In the case when you need only one object of a particular class, you can put all the object’s state into static variables and use only class methods. This saves the step of allocating and initializing an instance.

Note: It is also possible to use external variables that are not declared static, but the limited scope of static variables better serves the purpose of encapsulating data into separate objects.
Initializing a Class Object

If you want to use a class object for anything besides allocating instances, you may need to initialize it just as you would an instance. Although programs don’t allocate class objects, Objective-C does provide a way for programs to initialize them.

If a class makes use of static or global variables, the initialize method is a good place to set their initial values. For example, if a class maintains an array of instances, the initialize method could set up the array and even allocate one or two default instances to have them ready.

The runtime system sends an initialize message to every class object before the class receives any other messages and after its superclass has received the initialize message. This sequence gives the class a chance to set up its runtime environment before it’s used. If no initialization is required, you don’t need to write an initialize method to respond to the message.

Because of inheritance, an initialize message sent to a class that doesn’t implement the initialize method is forwarded to the superclass, even though the superclass has already received the initialize message. For example, assume class A implements the initialize method, and class B inherits from class A but does not implement the initialize method. Just before class B is to receive its first message, the runtime system sends initialize to it. But, because class B doesn’t implement initialize, class A’s initialize is executed instead. Therefore, class A should ensure that its initialization logic is performed only once, and for the appropriate class.

To avoid performing initialization logic more than once, use the template in Listing 1-3 when implementing the initialize method.

Listing 1-3  Implementation of the initialize method
+ (void)initialize
{
  if (self == [ThisClass class]) {
        // Perform initialization here.
        ...
    }
}
Note: Remember that the runtime system sends initialize to each class individually. Therefore, in a class’s implementation of the initialize method, you must not send the initialize message to its superclass.
Methods of the Root Class

All objects, classes and instances alike, need an interface to the runtime system. Both class objects and instances should be able to introspect about their abilities and to report their place in the inheritance hierarchy. It’s the province of the NSObject class to provide this interface.

So that NSObject methods don’t have to be implemented twice—once to provide a runtime interface for instances and again to duplicate that interface for class objects—class objects are given special dispensation to perform instance methods defined in the root class. When a class object receives a message that it can’t respond to with a class method, the runtime system determines whether there’s a root instance method that can respond. The only instance methods that a class object can perform are those defined in the root class, and only if there’s no class method that can do the job.

For more on this peculiar ability of class objects to perform root instance methods, see NSObject Class Reference.

Class Names in Source Code
In source code, class names can be used in only two very different contexts. These contexts reflect the dual role of a class as a data type and as an object:

The class name can be used as a type name for a kind of object. For example:
Rectangle *anObject;
Here anObject is statically typed to be a pointer to a Rectangle object. The compiler expects it to have the data structure of a Rectangle instance and to have the instance methods defined and inherited by the Rectangle class. Static typing enables the compiler to do better type checking and makes source code more self-documenting. See “Enabling Static Behavior” for details.
Only instances can be statically typed; class objects can’t be, because they aren’t members of a class, but rather belong to the Class data type.

As the receiver in a message expression, the class name refers to the class object. This usage was illustrated in several of the earlier examples. The class name can stand for the class object only as a message receiver. In any other context, you must ask the class object to reveal its id (by sending it a class message). This example passes the Rectangle class as a parameter in an isKindOfClass: message:
if ( [anObject isKindOfClass:[Rectangle class]] )
    ...
It would have been illegal to simply use the name “Rectangle” as the parameter. The class name can only be a receiver.
If you don’t know the class name at compile time but have it as a string at runtime, you can use NSClassFromString to return the class object:

NSString *className;
    ...
if ( [anObject isKindOfClass:NSClassFromString(className)] )
    ...
This function returns nil if the string it’s passed is not a valid class name.
Class names exist in the same namespace as global variables and function names. A class and a global variable can’t have the same name. Class names are the only names with global visibility in Objective-C.

Testing Class Equality
You can test two class objects for equality using a direct pointer comparison. It is important, though, to get the correct class. There are several features in the Cocoa frameworks that dynamically and transparently subclass existing classes to extend their functionality (for example, key-value observing and Core Data do this—see Key-Value Observing Programming Guide and Core Data Programming Guide respectively). In a dynamically-created subclass, the class method is typically overridden such that the subclass masquerades as the class it replaces. When testing for class equality, you should therefore compare the values returned by the class method rather than those returned by lower-level functions. Put in terms of API, the following inequalities pertain for dynamic subclasses:

[object class] != object_getClass(object) != *((Class*)object)
You should therefore test two classes for equality as follows:

if ([objectA class] == [objectB class]) { //...

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