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I'm trying to understand a code snippet that I've managed to make work by trial and error. I understand everything about this snippet except why it doesn't work when I take "friend" out of the class declaration. I don't understand what friend is doing in this context.


stringstream log;

class logWrapper { friend ostream& operator<<(ostream& os, logWrapper& thislogend) { stringstream &ss = dynamic_cast(os); // This line replaced with printf for clarity // The actual code sends the C style string to a // legacy logging system that only takes C style strings // _log(LOG_ERR, "%s", ss.str().c_str()); printf("%s\n", ss.str().c_str());

ss.str(""); return os; } } logend; int main(void) { log << "This is a test" << logend; }
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It means your lazy. But lazy is good in programming. –  Loki Astari Apr 4 '11 at 22:41
4  
@Martin: "you're". –  Lightness Races in Orbit Apr 4 '11 at 22:46
    
@Martin: Not just laziness... it has it's advantages too –  David Rodríguez - dribeas Apr 4 '11 at 23:25
    
@David Rodríguez: Yes thats why I said lazy is good. It implicitly documents the tight coupling and extension of the interface. –  Loki Astari Apr 5 '11 at 0:29
    
@Martin, it does not only implicitly document, but changes the lookup rules. If the friend is defined inside the class brackets, then it will not be available in the enclosing namespace unless one of the arguments is of the enclosing class type. –  David Rodríguez - dribeas Apr 5 '11 at 8:09

4 Answers 4

You are simultaneously declaring and defining a friend function, which overloads an operator.

Functions which are declared as friend can access all the private members of any instance of the class which befriended them.

This is different from regular member functions (which can obviously also access private members), since friend functions are not members of the class -- they are stand-alone functions.

So since you've defined the stand-alone function inside the class, it appears confusing at first glance -- just remember that it's not really a member function at all.

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It means that the friend is not a member of the class, but you can access static class members and member types (including private ones) without qualification.

This makes the function "look and feel" like a member. Because operator<< here is intimately tied to the logWrapper, it is intuitive that you can implement it as if it were a member of the class.

But remember, it is not a member! It is just a free function with special access privileges, just as if it were defined outside.

Edit: Since there are no static members and no member types, this happens not to make a difference here. You could move the definition of the friend outside without changing it. This style is idiomatic, though, because you could. Often it is used with templates, which often do have member types/typedefs.

Indeed, defining a friend inside a template<…> class block is the only way to define a templated non-template function. This esoteric and sometimes-elusive beast is nonetheless sometimes very convenient to have around. Usually his creation is accidental, even serendipitous, so I won't get into that discussion…

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This is mostly wrong, sorry. Friend has nothing to do with static –  Cameron Apr 4 '11 at 22:42
    
And you can access normal members via an object (in this case the second parameters thislogend). –  Loki Astari Apr 4 '11 at 22:42
1  
@Cameron: friend has nothing to do with static, but defining inside the class { } scope means that other names defined within the class { } scope do not need to be qualified. This includes static members and member types. –  Potatoswatter Apr 4 '11 at 22:45
    
@Martin: I never said you can't access normal members. Huh? –  Potatoswatter Apr 4 '11 at 22:45
1  
@David: It's not "part of the class"; that's the point. It's not a member function, but it's been defined inside the class definition as part of a friend function definition for convenience/laziness. –  Lightness Races in Orbit Apr 4 '11 at 22:47

Besides what has been written before, the lookup rules are slightly different. If the friend function is declared and defined inside the befriending type, then it will only be considered if one of the arguments is of that particular type:

struct A {};
struct B {
   B() {}                        // allow default construction
   B( A const & ) {}             // and implicit conversion from A
   friend void foo( B const & )  // defined in the class
   {}
   friend void bar( B const & );
};
void bar( B const & ) {}         // defined outside
int main() {
   A a;
   bar( a );                     // ok, implicit conversion and calls bar(B(a))
   //foo( a );                   // error: foo not in scope!!! [*]
   B b;
   foo( b );                     // ok: the argument makes the compiler look inside B
   foo( B(a) );                  //     same here
}

[*] Since foo is defined inside B's braces, lookup will not find foo unless the argument (at least one argument) is of type B, and that will inhibit the implicit conversion from A to B --since the potential overload is not found, conversion is not performed.

This is one of the reasons why, when defining a template, it is better to provide the implementation of the friend functions (specially operators) inline, as that reduces the scope of the functions and reduces namespace pollution.

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Normally friend just tells the compiler, that the operator<< has access to the private variables of logWrapper. In your case it's used to directly implement the operator<< inside the logWrapper. Could've also been implemented like this:

class logWrapper{
}logend;

ostream& operator<<(ostream& os, logWrapper& thislogend){
  // ...
}

If you didn't use friend, you would declare that operator<< as a member function of logWrapper. It's easier to understand with a normal function:

class logWrapper{
  int func(int i, logWrapper& thislogend){
    // ...
  }
}logend;
// needs to be called as:
logend.func(5,logend);
// while
class logWrapper{
  friend int func(int i, logWrapper& thislogend){
    // ...
  }
}logend;
// would be called as
func(5,logend);
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Yes, except: (a) it is slightly different w.r.t. qualification rules inside the function's definition; and (b) you forgot the friend statement in your class definition example. –  Lightness Races in Orbit Apr 4 '11 at 22:49
    
So if I declare a function as friend inside a class then define it, it will be defined as a global function? So, the result of this is just prettier code then? –  David Hinkle Apr 4 '11 at 22:49
    
@Tomalak: I didn't, the OP doesn't even use any variables (if it has any) of the logWrapper. It's special for the use-case the OP presented in the question. –  Xeo Apr 4 '11 at 22:50
    
@David Hinkle: You're confusing the terms "free function" and "global function", but the idea that you have in your head is basically correct, yes. :) –  Lightness Races in Orbit Apr 4 '11 at 22:51
    
@David: Correct! –  Xeo Apr 4 '11 at 22:51

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