Seems I'm about 14 years late to the party. But here goes.

### TLDR TLDR

Friend classes are there so that you can extend encapsulation to the group of classes which comprise your data structure.

### TLDR

Your data structure in general consists of multiple classes. Similarly to a traditional class (supported by your programming language), your data structure is a generalized class which also has data and invariants on that data which spans across objects of multiple classes. Encapsulation protects those invariants against accidental modification of the data from the outside, so that the data-structure's operations ("member functions") work correctly. Friend classes extend encapsulation from classes to your generalized class.

### The too long

A *class* is a datatype together with *invariants* which specify a subset of the values of the datatype, called the *valid states*. An object is a valid state of a class. A *member function* of a class moves a given object from a valid state to another.

It is essential that object data is not modified from outside of the class member functions, because this could break the class invariants (i.e. move the object to an invalid state). *Encapsulation* prohibits access to object data from outside of the class. This is an important safety feature of programming languages, because it makes it hard to inadvertedly break class invariants.

A class is often a natural choice for implementing a data structure, because the properties (e.g. performance) of a data structure is dependent on invariants on its data (e.g. red-black tree invariants). However, sometimes a single class is not enough to describe a data structure.

A *data structure* is any set of data, invariants, and functions which move that data from a valid state to another. This is a generalization of a class. The subtle difference is that the data may be scattered over datatypes rather than be concentrated on a single datatype.

### Data structure example

A prototypical example of a data structure is a graph which is stored using separate objects for vertices (class `Vertex`

), edges (class `Edge`

), and the graph (class `Graph`

). These classes do not make sense independently. The Graph class creates `Vertex`

s and `Edge`

s by its member functions (e.g. `graph.addVertex()`

and `graph.addEdge(aVertex, bVertex)`

) and returns pointers (or similar) to them. `Vertex`

s and `Edge`

s are similarly destroyed by their owning `Graph`

(e.g. `graph.removeVertex(vertex)`

and `graph.removeEdge(edge)`

). The collection of `Vertex`

objects, `Edge`

objects and the `Graph`

object together encode a mathematical graph. In this example the intention is that `Vertex`

/`Edge`

objects are not shared between `Graph`

objects (other design choices are also possible).

A `Graph`

object could store a list of all its vertices and edges, while each `Vertex`

could store a pointer to its owning `Graph`

. Hence, the `Graph`

object represents the whole mathematical graph, and you would pass that around whenever the mathematical graph is needed.

### Invariant example

An invariant for the graph data structure then would be that a `Vertex`

is listed in its owner `Graph`

's list. This invariant spans both the `Vertex`

object and the `Graph`

object. Multiple objects of multiple types can take part in a given invariant.

### Encapsulation example

Similarly to a class, a data structure benefits from *encapsulation* which protects against accidental modification of its data. This is because the data structure needs to preserve invariants to be able to function in promised manner, exactly like a class.

In the graph data structure example, you would state that `Vertex`

is a friend of `Graph`

, and also make the constructors and data-members of `Vertex`

private so that a `Vertex`

can only be created and modified by `Graph`

. In particular, `Vertex`

would have a private constructor which accepts a pointer to its owning graph. This constructor is called in `graph.addVertex()`

, which is possible because `Vertex`

is a friend of `Graph`

. (But note that `Graph`

is not a friend of `Vertex`

: there is no need for `Vertex`

to be able to access `Graph`

's vertex-list, say.)

### Terminology

The definition of a data structure acts itself like a class. I propose that we start using the term 'generalized class' for any set of data, invariants, and functions which move that data from a valid state to another. A C++ class is then a specific kind of a generalized class. It is then self-evident that friend classes are the precise mechanism for extending encapsulation from C++ classes to generalized classes.

(In fact, I'd like the term 'class' to be replaced with the concept of 'generalized class', and use 'native class' for the special case of a class supported by the programming language. Then when teaching classes you would learn of both native classes and these generalized classes. But perhaps that would be confusing.)