Question

I keep seeing references to the visitor pattern in blogs but I've got to admit, I just don't get it. I read the wikipedia article for the pattern and I understand its mechanics but I'm still confused as to when I'd use it.

As someone who just recently really got the decorator pattern and is now seeing uses for it absolutely everywhere I'd like to be able to really understand intuitively this seemingly handy pattern as well.

Answer 1

The reason for your confusion is probably that the Visitor is a fatal misnomer. Many (prominent¹!) programmers have stumbled over this problem. What it actually does is implement double dispatching in languages that don't support it natively (most of them don't).

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¹⁾ My favourite example is Scott Meyers, acclaimed author of “Effective C++”, who called this one of his most important C++ aha! moments ever.

Answer 2

One way to look at it is that the visitor pattern is a way of letting your clients add additional methods to all of your classes in a particular class hierarchy.

It is useful when you have a fairly stable class hierarchy, but you have changing requirements of what needs to be done with that hierarchy.

The classic example is for compilers and the like. An Abstract Syntax Tree (AST) can accurately define the structure of the programming language, but the operations you might want to do on the AST will change as your project advances: code-generators, pretty-printers, debuggers, complexity metrics analysis.

Without the Visitor Pattern, every time a developer wanted to add a new feature, they would need to add that method to every feature in the base class. This is particularly hard when the base classes appear in a separate library, or are produced by a separate team.

(I have heard it argued that the Visitor pattern is in conflict with good OO practices, because it moves the operations of the data away from the data. The Visitor pattern is useful in precisely the situation that the normal OO practices fail.)

Answer 3

At my work we recently used it for visiting every node in a tree structure.

Answer 4

I'm not very familiar with the Visitor pattern. Let's see if I got it right. Suppose you have a hierarchy of animals

class Animal {  };
class Dog: public Animal {  };
class Cat: public Animal {  };

(Suppose it is a complex hierarchy with a well-established interface.)

Now we want to add a new operation to the hierarchy, namely we want each animal to make its sound. As far as the hierarchy is this simple, you can do it with straight polymorphism:

class Animal
{ public: virtual void makeSound() = 0; };

class Dog: public Animal
{ public: void makeSound(); };

void Dog::makeSound()
{ std::cout<<"woof!\n"; }

class Cat: public Animal
{ public: void makeSound(); };

void Cat::makeSound()
{ std::cout<<"meow!\n"; }

But proceeding in this way, each time you want to add an operation you must modify the interface to every single class of the hierarchy. Now, suppose instead that you are satisfied with the original interface, and that you want to make the fewest possible modifications to it.

The Visitor pattern allows you to move each new operation in a suitable class, and you need to extend the hierarchy's interface only once. Let's do it. First, we define an abstract operation (the "Visitor" class in GoF) which has a method for every class in the hierarchy:

class Operation
{
public:
    virtual void hereIsADog(Dog *d) = 0;
    virtual void hereIsACat(Cat *c) = 0;
};

Then, we modify the hierarchy in order to accept new operations:

class Animal
{ public: virtual void letsDo(Operation *v) = 0; };

class Dog: public Animal
{ public: void letsDo(Operation *v); };

void Dog::letsDo(Operation *v)
{ v->hereIsADog(this); }

class Cat: public Animal
{ public: void letsDo(Operation *v); };

void Cat::letsDo(Operation *v)
{ v->hereIsACat(this); }

Finally, we implement the actual operation, without modifying neither Cat nor Dog:

class Sound: public Operation
{
public:
    void hereIsADog(Dog *d);
    void hereIsACat(Cat *c);
};

void Sound::hereIsADog(Dog *d)
{ std::cout<<"woof!\n"; }

void Sound::hereIsACat(Cat *c)
{ std::cout<<"meow!\n"; }

Now you have a way to add operations without modifying the hierarchy anymore. Here is how it works:

int main()
{
    Cat c;
    Sound theSound;
    c.letsDo(&theSound);
}

Answer 5

Q: When would I use the Visitor pattern?

A: You don't! You just say who you are and get someone else to use it for you!

:-)

Answer 6

The Visitor design pattern works really well for "recursive" structures like directory trees, XML structures, or document outlines.

A Visitor object visits each node in the recursive structure: each directory, each XML tag, whatever. The Visitor object doesn't loop through the structure. Instead Visitor methods are applied to each node of the structure.

Here's a typical recursive node structure. Could be a directory or an XML tag. [If your a Java person, imagine of a lot of extra methods to build and maintain the children list.]

class TreeNode( object ):
    def __init__( self, name, *children ):
        self.name= name
        self.children= children
    def visit( self, someVisitor ):
        someVisitor.arrivedAt( self )
        someVisitor.down()
        for c in self.children:
            c.visit( someVisitor )
        someVisitor.up()

The visit method applies a Visitor object to each node in the structure. In this case, it's a top-down visitor. You can change the structure of the visit method to do bottom-up or some other ordering.

Here's a superclass for visitors. It's used by the visit method. It "arrives at" each node in the structure. Since the visit method calls up and down, the visitor can keep track of the depth.

class Visitor( object ):
    def __init__( self ):
        self.depth= 0
    def down( self ):
        self.depth += 1
    def up( self ):
        self.depth -= 1
    def arrivedAt( self, aTreeNode ):
        print self.depth, aTreeNode.name

A subclass could do things like count nodes at each level and accumulate a list of nodes, generating a nice path hierarchical section numbers.

Here's an application. It builds a tree structure, someTree. It creates a Visitor, dumpNodes.

Then it applies the dumpNodes to the tree. The dumpNode object will "visit" each node in the tree.

someTree= TreeNode( "Top", TreeNode("c1"), TreeNode("c2"), TreeNode("c3") )
dumpNodes= Visitor()
someTree.visit( dumpNodes )

The TreeNode visit algorithm will assure that every TreeNode is used as an argument to the Visitor's arrivedAt method.

Answer 7

Finally got it after reading this article by Jermey Miller on my blackberry while stuck waiting in a lobby for two hours. It's long but gives a wonderful explanation of double-dispatch, visitor, and composite, and what you can do with these.

Answer 8

Everyone here is correct, but I think it fails to address the "when". First, from Design Patterns:

Visitor lets you define a new operation without changing the classes of the elements on which it operates.

Now, let's think of a simple class hierarchy. I have classes 1, 2, 3 and 4 and methods A, B, C and D. Lay them out like in a spreadsheet: the classes are lines and the methods are columns.

Now, Object Oriented design presumes you are more likely to grow new classes than new methods, so adding more lines, so to speak, is easier. You just add a new class, specify what's different in that class, and inherits the rest.

Sometimes, though, the classes are relatively static, but you need to add more methods frequently -- adding columns. The standard way in an OO design would be to add such methods to all classes, which can be costly. The Visitor pattern makes this easy.

By the way, this is the problem that Scala's pattern matches intends to solve.