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(I know what the scope resolution operator does, and how and when to use it.)

Why does C++ have the :: operator, instead of using the . operator for this purpose? Java doesn't have a separate operator, and works fine. Is there some difference between C++ and Java that means C++ requires a separate operator in order to be parsable?

My only guess is that :: is needed for precedence reasons, but I can't think why it needs to have higher precedence than, say, .. The only situation I can think it would is so that something like

a.b::c;

would be parsed as

a.(b::c);

, but I can't think of any situation in which syntax like this would be legal anyway.

Maybe it's just a case of "they do different things, so they might as well look different". But that doesn't explain why :: has higher precedence than ..

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5 Answers

up vote 6 down vote accepted

Why C++ doesn't use . where it uses ::, is because this is how the language is defined. One plausible reason could be, to refer to the global namespace using the syntax ::a as shown below:

int a = 10;
namespace M
{
    int a = 20;
    namespace N
    {
           int a = 30;
           void f()
           {
              int x = a; //a refers to the name inside N, same as M::N::a
              int y = M::a; //M::a refers to the name inside M
              int z = ::a; //::a refers to the name in the global namespace

              std::cout<< x <<","<< y <<","<< z <<std::endl; //30,20,10
           }
    }
}

Online Demo

I don't know how Java solves this. I don't even know if in Java there is global namespace. In C#, you refer to global name using the syntax global::a, which means even C# has :: operator.


but I can't think of any situation in which syntax like this would be legal anyway.

Who said syntax like a.b::c is not legal?

Consider these classes:

struct A
{
    void f() { std::cout << "A::f()" << std::endl; }
};

struct B : A
{
    void f(int) { std::cout << "B::f(int)" << std::endl; }
};

Now see this (ideone):

B b;
b.f(10); //ok
b.f();   //error - as the function is hidden

b.f() cannot be called like that, as the function is hidden, and the GCC gives this error message:

error: no matching function for call to ‘B::f()’

In order to call b.f() (or rather A::f()), you need scope resolution operator:

b.A::f(); //ok - explicitly selecting the hidden function using scope resolution

Demo at ideone

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That doesn't explain why you can't just say b.A.f instead of b.A::f. If A is a typename instead of a variable or function, then using . could easily have meant scope resolution instead of the regular meaning. –  Nicol Bolas Feb 18 '12 at 3:42
    
@NicolBolas: Updated answer. –  Nawaz Feb 18 '12 at 3:49
    
You could still just say .a to mean the global one, and M.a to mean the one in the M namespace. –  Nicol Bolas Feb 18 '12 at 4:00
1  
The assumption I made about a.b::c not being sensible is what was causing my confusion. Accepted this answer because I think it's as good as the others but also points out my mistake. –  Karu Feb 18 '12 at 4:57
1  
There is no global namespace in Java because everything is inside one class or another. –  Karl Knechtel Feb 18 '12 at 5:08
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Unlike Java, C++ has multiple inheritance. Here is one example where scope resolution of the kind you're talking about becomes important:

#include <iostream>
using namespace std;
struct a
{
    int x;
};
struct b
{
    int x;
};
struct c : public a, public b
{
    ::a a;
    ::b b;
};
int main() {
    c v;
    v.a::x = 5;
    v.a.x = 55;
    v.b::x = 6;
    v.b.x = 66;
    cout << v.a::x << " " << v.b::x << endl;
    cout << v.a.x << " " << v.b.x << endl;
    return 0;
}
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Technically that's not about multiple inheritance. It's about being able to name your variables the same names as your derived classes. –  Nicol Bolas Feb 18 '12 at 4:07
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Because someone in the C++ standards committee thought that it was a good idea to allow this code to work:

struct foo
{
  int blah;
};

struct thingy
{
  int data;
};

struct bar : public foo
{
  thingy foo;
};

int main()
{
  bar test;
  test.foo.data = 5;
  test.foo::blah = 10;
  return 0;
}

Basically, it allows a member variable and a derived class type to have the same name. I have no idea what someone was smoking when they thought that this was important. But there it is.

When the compiler sees ., it knows that the thing to the left must be a variable. When it sees ::, it must be a typename (or nothing, indicating the global namespace). That's how it resolves this ambiguity.

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Why can't you write test.foo.blah = 10? Or test.base.blah = 10 where base is a keyword? –  Nawaz Feb 18 '12 at 4:13
    
@Nawaz: Because introducing a keyword is a lot harder than introducing an operator. And test.foo.blah is ambiguous; is it the base-class's blah or the thingy member's blah? Java (as I understand it) gets around this by stating that it's always the member; you can only get at base class member variables by casting the type. –  Nicol Bolas Feb 18 '12 at 4:15
2  
@Nawaz: Because this would not give any way of specifying which base you wanted to use. –  Mankarse Feb 18 '12 at 4:16
    
@NicolBolas: It maybe harder from compiler author perspective, but from programmers perspective base.blah is lot easier (and less awkward). –  Nawaz Feb 18 '12 at 4:21
1  
@Nawaz: Unless of course your code ever used the identifier base anywhere. Which is entirely possible. Keywording things isn't hard because of the compiler; it's hard because it makes things that used those keywords break. Even a context-specific keyword means you can't have a type named base. –  Nicol Bolas Feb 18 '12 at 4:31
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Just to answer the final bit of the question about operator precedence:

class A {
public:
  char A;
};

class B : public A {
public:
  double A;
};

int main(int c, char** v)
{
  B myB;
  myB.A = 7.89;
  myB.A::A = 'a';
  // On the line above a hypothetical myB.A.A
  // syntax would parse as (myB.A).A and since
  // (myB.A) is of type double you get (double).A in the
  // next step. Of course the '.' operator has no
  // meaning for doubles so it causes a syntax error. 
  // For this reason a different operator that binds
  // more strongly than '.' is needed.
  return 0;
}
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Are you saying that a parser couldn't simply wait and check the next token to see if it's a . before deciding on the ambiguity? –  Nicol Bolas Feb 18 '12 at 4:23
    
No, certainly such a parser could be written. The intermediate result would be ambiguous and when the next token comes in you can assume that the user didn't mean to make a syntax error. So it isn't strictly necessary in that sense, but the '::' operator is useful elsewhere and C++ parser authors have enough problems already. :) –  nolandda Feb 19 '12 at 7:02
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I always assumed C++ dot/:: usage was a style choice, to make code easier to read. As the OP writes "they do different things, so should look different."

Coming from C++, long ago, to C#, I found using only dots confusing. I was used to seeing A::doStuff(); B.doStuff();, and knowing the first is a regular function, in a namespace, and the second is a member function on instance B.

C++ is maybe my fifth language, after Basic, assembly, Pascal and Fortran, so I don't think it's first language syndrome, and I'm more a C# programmer now. But, IMHO, if you've used both, C++-style double-colon for namespaces reads better. I feel like Java/C# chose dots for both to (successfully) ease the front of the learning curve.

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