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I have an overloaded << operator from my reckful class implemented as follows:

ostream& operator << (ostream& os, const reckful& p)
{
    os << p.PrintStuff();

    return os;
}

PrintStuff() just being a member function of reckful that returns a string.

The way I understand things, if I were to write something like cout << reckobject << endl; in main(), cout << reckobject would take precedence and my overloaded << (using cout as the left operand and reckobject as the right operand) would return the ostream object os, leaving the expression os << endl; to be evaluated which would output the string and then end the line. So, the first << is the one I declared and the second is the standard << right?

However, my main question is... what is the sequence of events, which are the left and right operands, and which << operators are which when I run a statement like this:

cout << "reckful object = " << reckobject << "!" << endl;

Why does this work if there isn't an ostream object and a reckful object on either side of one << ?

Thanks.

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2 Answers 2

up vote 5 down vote accepted

If you notice standard way to implement << it returns the ostream itself. This is the critical piece

So something like

 cout << "reckful object = " << reckobject << "!" << endl;

will be called once for

cout << "reckful object = " 

This function call will return a ostream with which the second call will be made

namely

   cout  << reckobject;

so on an so forth.

You can test is out by implementing your << as

void operator << (ostream& os, const reckful& p)
{  
    os << 1;
}

in which case you can do

std::cout << p;

but not

std::cout << p << std::endl;

The operators make it harder to understand but consider this Point class

struct Point
{
    Point& setX( int x) { X = x; return *this;}
    Point& setY( int y) { Y = y; return *this;}

    int X;
    int Y;
};

The way setX and setY are defined, allows

    Point p;
    p.setX( 2 ).setY( 4 );

This is the same mechanism << is using to chain function calls.

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Because each << returns a reference to cout. Because the operator << is left-associative, the calls are done from left to right, so

a << b << c

is equivalent to

(a << b) << c

which is equivalent1 to

operator<<(operator<<(a, b), c);

So in your example, you are doing

operator<<(operator<<(operator<<(operator<<(cout, "reckful object = "), reckobject), "!"), endl);

As you can see, each << depends on the return value of the previous << (or just cout in case there is no further left <<). If you change one of the return types of the <<s to void, you effectively stop any more << calls, because void can't be used as an argument to a function.


1 It's not exactly equivalent because in that example, all operator<< are free functions, whereas in reality, some can be member functions, so you could have a mix of member and non-member calls like

operator<<(a, b).operator<<(c);

or

operator<<(a.operator<<(b), c);
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