The other answers here will solve the problem, but the following is the pattern I use when I'm doing this:

```
class Num
{
public:
Num(int i) // Not explicit, allows implicit conversion to Num
: i_ (i)
{
}
Num (Num const & rhs)
: i_ (rhs.i_)
{
}
Num & operator+= (Num const & rhs) // Implement +=
{
i_ += rhs.i_;
return *this;
}
private:
int i_;
};
//
// Because of Num(int), any number on the LHS or RHS will implicitly
// convert to Num - so no need to have lots of overloads
Num operator+(Num const & lhs, Num const & rhs)
{
//
// Implement '+' using '+='
Num tmp (lhs);
tmp+=rhs;
return tmp;
}
```

One of the key benefits of this approach is that your functions can be implemented in terms of each other reducing the amount of overall code you need.

**UPDATE:**

To keep performance concerns at bay, I would probably define the non member operator+ as an inline function something like:

```
inline Num operator+(Num lhs, Num const & rhs)
{
lhs+=rhs;
return lhs;
}
```

The member operations are also inline (as they're declared in the class body) and so in all the code should be very close to the cost of adding two raw `int`

objects.

Finally, as pointed out by jalf, the consequences of allowing implicit conversions in general needs to be considered. The above example assumes that it's sensible to convert from an integral type to a 'Num'.