When an operator function is implemented as a member function, the leftmost (or
only) operand must be an object (or a reference to an object) of the operator’s class. If the
left operand must be an object of a different class or a fundamental type, this operator function
must be implemented as a non-member function (e.g. when overloading
>> as the stream insertion and stream extraction operators, respectively).
A non-member operator function can be made a
friend of a class if that function
protected members of that class directly. Operator member functions of a specific class are called (implicitly by the compiler) only when the left operand of a binary operator is specifically an object of that class, or when the single operand of a unary operator is an object of that class.
Another reason why you might choose a non-member function to overload an operator is to
enable the operator to be commutative.
For example, suppose we have a fundamental type variable,
number, of type
long int, and an object
bigInteger1, of class
HugeInteger (a class in which integers may be arbitrarily large rather than being limited by the machine word size of the underlying hardware). The subtraction operator (
-) produces a temporary
HugeInteger object as the difference of a
HugeInteger and a
long int (as in the expression
bigInteger1 - number), or as the difference of a
long int and a
HugeInteger (as in the expression
number - bigInteger1). Thus, we require the subtraction operator to be commutative (exactly as it is with two fundamental-type operands). The problem is that the class object must appear on the left of the subtraction operator if that operator is to be overloaded as a member function. So, we also overload the operator as a non-member function to allow the
HugeInteger to appear on the right of the subtraction. The
operator- function that deals with the
HugeInteger on the left can still be a member function. The non-member function can simply swap its arguments and call the member function.