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I have been reading through the C++ FAQ and was curious about the friend declaration. I personally have never used it, however I am interested in exploring the language.

What is a good example of using friend?


Reading the FAQ a bit longer I like the idea of the << >> operator overloading and adding as a friend of those classes. However I am not sure how this doesn't break encapsulation. When can these exceptions stay within the strictness that is OOP?

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There are so many puns - I can barely resist... –  Nuby Mar 28 '12 at 14:24
@NubyMar My mind's blank right now. Explain? –  Cole Johnson Jul 26 '13 at 7:50
@Nuby not NubyMar: see comment above –  Jo So Aug 29 at 13:46
While I agree with the answer that a friend class is not necessarily A Bad Thing, I do tend to treat it as a code small. It often, although not always, indicates that the class hierarchy needs reconsidering. –  Mawg Sep 23 at 7:03

25 Answers 25

up vote 148 down vote accepted

Firstly (IMO) don't listen to people who say friend is not useful. It IS useful. In many situations you will have objects with data or functionality that are not intended to be called publicly available. This is particularly true of large codebases with many authors who may only be superficially familiar with different areas.

There ARE alternatives to the friend specifier, but often they are cumbersome (cpp-level concrete classes/masked typedefs) or not foolproof (comments or function name conventions).

Onto the answer;

The 'friend' specifier allows the designated class access to protected data or functionality within the class making the friend statement. For example in the below code anyone may ask a child for their name, but only the mother and the child may change the name.

You can take this simple example further by considering a more complex class such as a Window. Quite likely a Window will have many function/data elements that should not be publicly accessible, but ARE needed by a related class such as a WindowManager.

class Child
friend class Mother;


  string name( void );


  void setName( string newName );
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As an extra note, the C++ FAQ mentions that friend enhances encapsulation. friend grants selective access to members, just like protected does. Any fine-grained control is better than granting public access. Other languages define selective access mechanisms too, consider C#'s internal. Most negative criticism around the use of friend is related to tighter coupling, which is generally seen as a bad thing. However, in some cases, tighter coupling is precisely what you want and friend gives you that power. –  André Caron Oct 21 '10 at 18:28
Could you please say more about (cpp-level concrete classes) and (masked typedefs), Andrew? –  OmarOthman Nov 22 '11 at 7:47
This answer seems to be more focused on explaining what friend is rather than providing a motivating example. The Window/WindowManager example is better than the example shown, but too vague. This answer also does not address the encapsulation portion of the question. –  bames53 Dec 28 '12 at 23:56
For the Window/WindowManger exmaple, why not we have pointers of Window as attributes in the WindowManager? I think this is better than declaring WindowManager as a "friend" to Window. –  Peng Zhang May 3 at 21:08
So effectively 'friend' exists because C++ has no notion of a package in which all members may share implementation details? I would be really interested in a real-world example. –  weberc2 Jun 17 at 18:48

At work we use friends extensively for our testing code. It means we can provide proper encapsulation and information hiding for the main application code. But also we can have separate test code that uses friends to inspect internal state and data for testing.

Suffice to say I wouldn't use the friend keyword as an essential component of your design.

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Cor, that's a splendid idea. –  JBRWilkinson Sep 7 '09 at 9:55
That's exactly what I use it for. That or just set the member variables to protected. It's just a shame it doesn't work for C++/CLI :-( –  Jon Cage Nov 3 '11 at 16:51
Personally I would discourage this. Typically you are testing an interface, i.e. does a set of inputs give the expected set of output(s). Why do you need to inspect internal data? –  Graeme Sep 6 '12 at 22:04
@Graeme: Because a good test plan includes both white box and black box testing. –  Ben Voigt Apr 29 '13 at 0:30
@Graeme, I call testing an interface, regression testing. Testing that what implements an interface actually works is unit testing. For the purpose of unit testing, by definition, I'll need to access things behind the interface. Typically, we test both. The further away you get in abstraction from implementation, the more complicate it is to test all possible paths so it is impossible to get good coverage with regression tests. Just because the entire interface accomplishes its purpose doesn't mean that individual parts are bug free. Bugs you let live through weak testing will eventually bite! –  iheanyi Apr 14 at 20:52

The friend keyword has a number of good uses. Here are the two uses immediately visible to me:

Friend Definition

Friend definition allows to define a function in class-scope, but the function will not be defined as a member function, but as a free function of the enclosing namespace, and won't be visible normally except for argument dependent lookup. That makes it especially useful for operator overloading:

namespace utils {
    class f {
        typedef int int_type;
        int_type value;

        // let's assume it doesn't only need .value, but some
        // internal stuff.
        friend f operator+(f const& a, f const& b) {
            // name resolution finds names in class-scope. 
            // int_type is visible here.
            return f(a.value + b.value);

        int getValue() const { return value; }

int main() {
    utils::f a, b;
    std::cout << (a + b).getValue(); // valid

Private CRTP Base Class

Sometimes, you find the need that a policy needs access to the derived class:

// possible policy used for flexible-class.
template<typename Derived>
struct Policy {
    void doSomething() {
        // casting this to Derived* requires us to see that we are a 
        // base-class of Derived.
        some_type const& t = static_cast<Derived*>(this)->getSomething();

// note, derived privately
template<template<typename> class SomePolicy>
struct FlexibleClass : private SomePolicy<FlexibleClass> {
    // we derive privately, so the base-class wouldn't notice that, 
    // (even though it's the base itself!), so we need a friend declaration
    // to make the base a friend of us.
    friend class SomePolicy<FlexibleClass>;

    void doStuff() {
         // calls doSomething of the policy

    // will return useful information
    some_type getSomething();

You will find a non-contrived example for that in this answer. Another code using that is in this answer. The CRTP base casts its this pointer, to be able to access data-fields of the derived class using data-member-pointers.

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"Private CRTP Base Class" example is a good one! +1 –  Nawaz Feb 27 '12 at 6:07
Hi, I get a syntax error (in xcode 4) when I try out your CRTP. Xcode believes I'm trying to inherit a class template. The error occurs at P<C> in template<template<typename> class P> class C : P<C> {}; stating "Use of class template C requires template arguments". Have you hade the same problems or perhaps know a solution? –  bennedich Oct 22 '12 at 14:30
@bennedich at first glance, that looks like the kind of error you'd get with insufficient C++ feature support. Which is pretty common among compilers. The use of FlexibleClass within FlexibleClass should implicitly refers to its own type. –  Yakk Dec 29 '12 at 17:44
@bennedich: The rules for use of a class template's name from within the class body changed with C++11. Try enabling C++11 mode in your compiler. –  Ben Voigt Apr 29 '13 at 0:33

@roo: Encapsulation is not broken here because the class itself dictates who can access its private members. Encapsulation would only be broken if this could be caused from outside the class, e.g. if your operator << would proclaim “I'm a friend of class foo.”

friend replaces use of public, not use of private!

Actually, the C++ FAQ answers this already.

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"friend replaces use of public, not use of private!", I second that –  Waleed Eissa May 10 '09 at 5:56
The FQA also has something to say: yosefk.com/c++fqa/friend.html –  Assaf Lavie Dec 27 '09 at 19:54
@Assaf: yes, but the FQA is, for the most part a, a lot of incoherent angry gibberish without any real value. The part on friend is no exception. The only real observation here is that C++ ensures encapsulation at compile-time only. And you don’t need any more words to say it. The rest is bollocks. So, in summary: this section of the FQA is not worth mentioning. –  Konrad Rudolph Dec 27 '09 at 21:28
Most of that FQA is utter blx :) –  rama-jka toti Jan 15 '10 at 7:19
@Konrad: "The only real observation here is that C++ ensures encapsulation at compile-time only." Do any languages ensure this at runtime? As far as I know, returning references to private members (and functions, for languages who allow pointers to functions or functions as first class objects) is allowed in C#, Java, Python and many others. –  André Caron Oct 21 '10 at 18:32

The canonical example is to overload operator<<. Another common use is to allow a helper or admin class access to your internals.

Here are a couple of guidelines I heard about C++ friends. The last one is particularly memorable.

  • Your friends are not your child's friends.
  • Your child's friends are not your friends.
  • Only friends can touch your private parts.
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"The canonical example is to overload operator<<." The canonical of not using friend I guess. –  curiousguy Dec 23 '11 at 7:06

Another common version of Andrew's example, the dreaded code-couplet


Instead of worrying if both lines are always done together and in consistent order you could make the methods private and have a friend function to enforce consistency:

class Parent;

class Object {
    void setParent(Parent&);

    friend void addChild(Parent& parent, Object& child);

class Parent : public Object {
     void addChild(Object& child);

     friend void addChild(Parent& parent, Object& child);

void addChild(Parent& parent, Object& child) {
    if( &parent == &child ){ 

In other words you can keep the public interfaces smaller and enforce invariants that cut across classes and objects in friend functions.

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Why would anyone need a friend for that? Why not let addChild member function also set the parent? –  Nawaz Feb 27 '12 at 6:01
A better example would be making setParent a friend, as you don't want to allow clients to change the parent since you'll be managing it in the addChild/removeChild category of functions. –  Ylisar Feb 26 at 15:23

edit: Reading the faq a bit longer I like the idea of the << >> operator overloading and adding as a friend of those classes, however I am not sure how this doesn't break encapsulation

How would it break encapsulation?

You break encapsulation when you allow unrestricted access to a data member. Consider the following classes:

class c1 {
  int x;

class c2 {
  int foo();
  int x;

class c3 {
  friend int foo();
  int x;

c1 is obviously not encapsulated. Anyone can read and modify x in it. We have no way to enforce any kind of access control.

c2 is obviously encapsulated. There is no public access to x. All you can do is call the foo function, which performs some meaningful operation on the class.

c3? Is that less encapsulated? Does it allow unrestricted access to x? Does it allow unknown functions access?

No. It allows precisely one function to access the private members of the class. Just like c2 did. And just like c2, the one function which has access is not "some random, unknown function", but "the function listed in the class definition". Just like c2, we can see, just by looking at the class definitions, a complete list of who has access.

So how exactly is this less encapsulated? The same amount of code has access to the private members of the class. And everyone who has access is listed in the class definition.

friend does not break encapsulation. It makes some Java people programmers feel uncomfortable, because when they say "OOP", they actually mean "Java". When they say "Encapsulation", they don't mean "private members must be protected from arbitrary accesses", but "a Java class where the only functions able to access private members, are class members", even though this is complete nonsense for several reasons.

First, as already shown, it is too restricting. There's no reason why friend methods shouldn't be allowed to do the same.

Second, it is not restrictive enough. Consider a fourth class:

class c4 {
  int getx();
  void setx(int x);
  int x;

This, according to aforesaid Java mentality, is perfectly encapsulated. And yet, it allows absolutely anyone to read and modify x. How does that even make sense? (hint: It doesn't)

Bottom line: Encapsulation is about being able to control which functions can access private members. It is not about precisely where the definitions of these functions are located.

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+1 for the emphasize : "You break encapsulation when you allow unrestricted access to a data member." –  Nawaz Feb 27 '12 at 6:14

You control the access rights for members and functions using Private/Protected/Public right? so assuming the idea of each and every one of those 3 levels is clear, then it should be clear that we are missing something...

The declaration of a member/function as protected for example is pretty generic. You are saying that this function is out of reach for everyone (except for an inherited child of course). But what about exceptions? every security system lets you have some type of 'white list" right?

So friend lets you have the flexibility of having rock solid object isolation, but allows for a "loophole" to be created for things that you feel are justified.

I guess people say it is not needed because there is always a design that will do without it. I think it is similar to the discussion of global variables: You should never use them, There is always a way to do without them... but in reality, you see cases where that ends up being the (almost) most elegant way... I think this is the same case with friends.

It doesn't really do any good, other than let you access a member variable without using a setting function

well that is not exactly the way to look at it. The idea is to control WHO can access what, having or not a setting function has little to do with it.

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How is friend a loophole? It lets the methods listed in the class access its private members. It still doesn't let arbitrary code access them. As such it is no different from a public member function. –  jalf Sep 7 '09 at 9:26
friend is as close as you can get to C#/Java package-level access in C++. @jalf - what about friend classes (such as a factory class)? –  Ogre Psalm33 Oct 20 '10 at 13:46
@Ogre: What about them? You're still specifically giving that class and no one else access to the class' internals. You're not just leaving the gate open for arbitrary unknown code to screw with your class. –  jalf Oct 20 '10 at 22:55

Friend comes handy when you are building a container and you want to implement an iterator for that class. See here for an example for the iterator design pattern

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The short answer would be: use friend when it actually improves encapsulation. Improving readability and usability (operators << and >> are the canonical example) is also a good reason.

As for examples of improving encapsulation, classes specifically designed to work with the internals of other classes (test classes come to mind) are good candidates.

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"operators << and >> are the canonical example" No. Rather canonical counter examples. –  curiousguy Dec 23 '11 at 6:57
@curiousguy: operators << and >> are usually friends, instead of members, because making them members would make them awkward to use. Of course, I am talking about the case when those operators need to access private data; otherwise, friendship is useless. –  Gorpik Jan 2 '12 at 9:21
"because making them members would make them awkward to use." Obviously, making operator<< and operator>> members of the value class instead of non-members, or members of i|ostream, wouldn't provide the desired syntax, and I am not suggesting it. "I am talking about the case when those operators need to access private data" I don't quite see why the input/output operators would need to access private members. –  curiousguy Feb 18 '12 at 4:49

Another use: friend (+ virtual inheritance) can be used to avoid deriving from a class (aka: "make a class underivable") => 1, 2

From [2]:

 class Fred;

 class FredBase {
   friend class Fred;
   FredBase() { }

 class Fred : private virtual FredBase {
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One specific instance where I use friend is when creating Singleton classes. The friend keyword lets me create an accessor function, which is more concise than always having a "GetInstance()" method on the class.

// Header file
class MySingleton
    // Private c-tor for Singleton pattern
    MySingleton() {}

    friend MySingleton& GetMySingleton();

// Accessor function - less verbose than having a "GetInstance()"
//   static function on the class
MySingleton& GetMySingleton();

// Implementation file
MySingleton& GetMySingleton()
    static MySingleton theInstance;
    return theInstance;
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This may be a matter of taste, but I don't think saving a few keystrokes justifies the use of friend here. GetMySingleton() should be a static method of the class. –  Gorpik Jan 16 '09 at 8:25
The private c-tor would disallow a non-friend function to instantiate the MySingleton, so the friend keyword is needed here. –  JBRWilkinson Sep 7 '09 at 9:59
@Gorpik "This may be a matter of taste, but I don't think saving a few keystrokes justifies the use of friend here." It does. Anyway, friend does not need a particular "justification", when adding a member function doesn't. –  curiousguy Dec 23 '11 at 7:02

We had an interesting issue come up at a company I previously worked at where we used friend to decent affect. I worked in our framework department we created a basic engine level system over our custom OS. Internally we had a class structure:

        /    \
 TwoPlayer  SinglePlayer

All of these classes were part of the framework and maintained by our team. The games produced by the company were built on top of this framework deriving from one of Games children. The issue was that Game had interfaces to various things that SinglePlayer and TwoPlayer needed access to but that we did not want expose outside of the framework classes. The solution was to make those interfaces private and allow TwoPlayer and SinglePlayer access to them via friendship.

Truthfully this whole issue could have been resolved by a better implementation of our system but we were locked into what we had.

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I'm only using the friend-keyword to unittest protected functions. Some will say that you shouldn't test protected functionality. I, however, find this very useful tool when adding new functionality.

However, I don't use the keyword in directly in the class declarations, instead I use a nifty template-hack to achive this:

template<typename T>
class FriendIdentity {
  typedef T me;

 * A class to get access to protected stuff in unittests. Don't use
 * directly, use friendMe() instead.
template<class ToFriend, typename ParentClass>
class Friender: public ParentClass
  Friender() {}
  virtual ~Friender() {}
// MSVC != GCC
#ifdef _MSC_VER
  friend ToFriend;
  friend class FriendIdentity<ToFriend>::me;

 * Gives access to protected variables/functions in unittests.
 * Usage: <code>friendMe(this, someprotectedobject).someProtectedMethod();</code>
template<typename Tester, typename ParentClass>
Friender<Tester, ParentClass> & 
friendMe(Tester * me, ParentClass & instance)
    return (Friender<Tester, ParentClass> &)(instance);

This enables me to do the following:

friendMe(this, someClassInstance).someProtectedFunction();

Works on GCC and MSVC atleast.

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The creator of C++ says that isn't broking any encapsulation principle, and I will quote him:

Does "friend" violate encapsulation? No. It does not. "Friend" is an explicit mechanism for granting access, just like membership. You cannot (in a standard conforming program) grant yourself access to a class without modifying its source.

Is more than clear...

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Given friend templates, this isn't true any more... –  curiousguy Dec 23 '11 at 6:56
@curiousguy: Even in case of templates, it is true. –  Nawaz Feb 27 '12 at 6:09
@Nawaz Template friendship may be granted, but anyone can make a new partial or explicit specialization without modifying the friendship granting class. But be careful with ODR violations when you do that. And do not do that anyway. –  curiousguy Mar 5 '12 at 2:18

To do TDD many times I've used 'friend' keyword in C++.

Can a friend know everything about me?

Updated: I found this valuable answer about "friend" keyword from Bjarne Stroustrup site.

"Friend" is an explicit mechanism for granting access, just like membership.

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The tree example is a pretty good example : Having an object implemented in a few different class without having an inheritance relationship.

Maybe you could also need it to have a constructor protected and force people to use your "friend" factory.

... Ok, Well frankly you can live without it.

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Friend functions and classes provide direct access to private and protected members of class to avoid breaking encapsulation in the general case. Most usage is with ostream: we would like to be able to type:

Point p;
cout << p;

However, this may require access to the private data of Point, so we define the overloaded operator

friend ostream& operator<<(ostream& output, const Point& p);

There are obvious encapsulation implications, however. First, now the friend class or function has full access to ALL members of the class, even ones that do not pertain to its needs. Second, the implementations of the class and the friend are now enmeshed to the point where an internal change in the class can break the friend.

If you view the friend as an extension of the class, then this is not an issue, logically speaking. But, in that case, why was it necessary to spearate out the friend in the first place.

To achieve the same thing that 'friends' purport to achieve, but without breaking encapsulation, one can do this:

class A
    void need_your_data(B & myBuddy)
    string name_;

class B
    void print_buddy_name(A & myBuddy)
    void take_this_name(const string & name)
        cout << name;

Encapsulation is not broken, class B has no access to the internal implementation in A, yet the result is the same as if we had declared B a friend of A. The compiler will optimize away the function calls, so this will result in the same instructions as direct access.

I think using 'friend' is simply a shortcut with arguable benefit, but definite cost.

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You have to be very careful about when/where you use the friend keyword, and, like you, I have used it very rarely. Below are some notes on using friend and the alternatives.

Let's say you want to compare two objects to see if they're equal. You could either:

  • Use accessor methods to do the comparison (check every ivar and determine equality).
  • Or, you could access all the members directly by making them public.

The problem with the first option, is that that could be a LOT of accessors, which is (slightly) slower than direct variable access, harder to read, and cumbersome. The problem with the second approach is that you completely break encapsulation.

What would be nice, is if we could define an external function which could still get access to the private members of a class. We can do this with the friend keyword:

class Beer {
    friend bool equal(Beer a, Beer b);
    // ...

The method equal(Beer, Beer) now has direct access to a and b's private members (which may be char *brand, float percentAlcohol, etc. This is a rather contrived example, you would sooner apply friend to an overloaded == operator, but we'll get to that.

A few things to note:

  • A friend is NOT a member function of the class
  • It is an ordinary function with special access to the private members of the class
  • Don't replace all accessors and mutators with friends (you may as well make everything public!)
  • Friendship isn't reciprocal
  • Friendship isn't transitive
  • Friendship isn't inherited
  • Or, as the C++ FAQ explains: "Just because I grant you friendship access to me doesn't automatically grant your kids access to me, doesn't automatically grant your friends access to me, and doesn't automatically grant me access to you."

I only really use friends when it's much harder to do it the other way. As another example, many vector maths functions are often created as friends due to the interoperability of Mat2x2, Mat3x3, Mat4x4, Vec2, Vec3, Vec4, etc. And it's just so much easier to be friends, rather than have to use accessors everywhere. As pointed out, friend is often useful when applied to the << (really handy for debugging), >> and maybe the == operator, but can also be used for something like this:

class Birds {
    friend Birds operator +(Birds, Birds);
    int numberInFlock;

Birds operator +(Birds b1, Birds b2) {
    Birds temp;
    temp.numberInFlock = b1.numberInFlock + b2.numberInFlock;
    return temp;

As I say, I don't use friend very often at all, but every now and then it's just what you need. Hope this helps!

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When implementing tree algorithms for class, the framework code the prof gave us had the tree class as a friend of the node class.

It doesn't really do any good, other than let you access a member variable without using a setting function.

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To do TDD many times I've used 'friend' keyword in C++.
Can a friend know everything about me?

No, its only a one way friendship :`(

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With regards to operator<< and operator>> there is no good reason to make these operators friends. It is true that they should not be member functions, but they don't need to be friends, either.

The best thing to do is create public print(ostream&) and read(istream&) functions. Then, write the operator<< and operator>> in terms of those functions. This gives the added benefit of allowing you to make those functions virtual, which provides virtual serialization.

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"With regards to operator<< and operator>> there is no good reason to make these operators friends." Absolutely correct. "This gives the added benefit of allowing you to make those functions virtual," If the class in question is intended for derivation, yes. Otherwise, why bother? –  curiousguy Dec 23 '11 at 6:59
I really don't get why this answer was downvoted twice - and without even an explanation! That's rude. –  curiousguy Dec 23 '11 at 7:00

Friends are also useful for callbacks. You could implement callbacks as static methods

class MyFoo
    static void callback(void * data, void * clientData);
    void localCallback();

where callback calls localCallback internally, and the clientData has your instance in it. In my opinion,


class MyFoo
    friend void callback(void * data, void * callData);
    void localCallback();

What this allows is for the friend to be a defined purely in the cpp as a c-style function, and not clutter up the class.

Similarly, a pattern I've seen very often is to put all the really private members of a class into another class, which is declared in the header, defined in the cpp, and friended. This allows the coder to hide a lot of the complexity and internal working of the class from the user of the header.

In the header:

class MyFooPrivate;
class MyFoo
    friend class MyFooPrivate;
    // Public stuff
    MyFooPrivate _private;
    // Other private members as needed

In the cpp,

class MyFooPrivate
   MyFoo *owner;
   // Your complexity here

    this->_private->owner = this;

It becomes easier to hide things that the downstream needn't see this way.

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Wouldn't interfaces be a cleaner way to achieve this? What's to stop someone looking up MyFooPrivate.h? –  JBRWilkinson Sep 7 '09 at 10:02
Well, if you're using private and public to keep secrets, you're going to be defeated easily. By "hiding", I mean, the user of MyFoo doesn't really need to see the private members. Besides this, it's useful to maintain ABI compatibility. If you make _private a pointer, the private implementation can change as much as you want, without touching the public interface, thereby keeping ABI compatibility. –  shash Sep 16 '09 at 7:12

You may use friendship when different classes (not inheriting one from the other) are using private or protected members of the other class.

Typical use cases of friend functions are operations that are conducted between two different classes accessing private or protected members of both.

from http://www.cplusplus.com/doc/tutorial/inheritance/ .

You can see this example where non-member method accesses the private members of a class. This method has to be declared in this very class as a friend of the class.

// friend functions
#include <iostream>
using namespace std;

class Rectangle {
    int width, height;
    Rectangle() {}
    Rectangle (int x, int y) : width(x), height(y) {}
    int area() {return width * height;}
    friend Rectangle duplicate (const Rectangle&);

Rectangle duplicate (const Rectangle& param)
  Rectangle res;
  res.width = param.width*2;
  res.height = param.height*2;
  return res;

int main () {
  Rectangle foo;
  Rectangle bar (2,3);
  foo = duplicate (bar);
  cout << foo.area() << '\n';
  return 0;
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You could adhere to the strictest and purest OOP principles and ensure that no data members for any class even have accessors so that all objects must be the only ones that can know about their data with the only way to act on them is through indirect messages, i.e., methods.

But even C# has an internal visibility keyword and Java has its default package level accessibility for some things. C++ comes actually closer to the OOP ideal by minimizinbg the compromise of visibility into a class by specifying exactly which other class and only other classes could see into it.

I don't really use C++ but if C# had friends I would that instead of the assembly-global internal modifier, which I actually use a lot. It doesn't really break incapsulation, because the unit of deployment in .NET is an assembly.

But then there's the InternalsVisibleToAttribute(otherAssembly) which acts like a cross-assembly friend mechanism. Microsoft uses this for visual designer assemblies.

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