It appears those class names are a bit off. My psychic decoding is that `Addition`

is `HasAddition`

. So we have `HasOperations`

inherits from `HasBinOps`

, which inherits from both `HasAddition`

and `HasSubtraction`

.

So I get the basic plan. But I'm going to answer how to do this right. This may not line up with your assignment, but that is honestly your assignment's problem not mine!

We do not want virtual runtime dispatch and dynamic allocation going on for all basic operations. We want static polymorphism, not dynamic polymorphism.

Luckily, in C++ we have static polymorphism. A typical way to implement it is via the CRTP -- the curiously repeating template pattern.

We do not have to use CRTP here. We can instead rely on Koenig lookup!

Koenig lookup is the fact that when determing what `operator+`

to call, your parent classes `friend`

s are considered. We inject a `friend operator+`

that matches on *derived types* by making it a `template`

inside `has_addition`

.

When we have our `matrix:has_addition`

, and we invoke `+`

. this template is found. And we then substitute the type of the arguments -- the full type, not the `has_addition`

parent type.

In this full type, we have a `.add`

method.

So we can inherit from a type such that the `operator+`

in that type has a different implementation based on what the type we derive from it, but this dispatch is done statically at compile time.

At runtime, `has_addition`

basically disappears. Instead, we just get a bunch of `+`

's routed to `.add`

.

So, without further ado, here is `has_addition`

:

```
struct has_addition {
// implement + in terms of += on the lhs:
template<class L, class R>
friend std::decay_t<L> operator+( L&& lhs, R&& rhs ) {
if (!std::is_reference<L>{}) { // rvalue lhs
return std::forward<L>(lhs) += rhs;
} else if (!std::is_reference<R>{}) { // rvalue rhs
return std::forward<R>(rhs) += lhs; // assumes + commutes
} else { // rvalue neither
auto tmp = std::forward<L>(lhs);
return tmp += rhs;
}
}
// notice += on an rvalue returns a copy.
// This permits reference lifetime extension:
template<class L, class R>
friend L operator+=( L&& lhs, R&& rhs ) {
lhs.add( std::forward<R>(rhs) );
return std::forward<L>(lhs);
}
};
```

you use it via:

```
struct bob : has_addition {
int x = 0;
void add( bob const& rhs ) {
x += rhs.x;
}
};
```

Live example.

Now both `+`

and `+=`

are implemented for you based on your `add`

method. What more, there are multiple rvalue and lvalue overloads of them. If you implement move-construct, you get automatic performance boosts. If you implement add that takes an rvalue on the right hand side, you get automatic performance boosts.

If you fail to write the rvalue overloaded `add`

and move-construct, things still work. We decoupled the factors (adding something you can discard, and recycling your storage, and micro-optimization of how `+`

works) from each other. The result is easier to write code with piles of micro optimizations built-in.

Now most of the micro-optimizations in `has_addition::operator+`

are not required for a first pass.

```
struct has_addition {
// implement + in terms of += on the lhs:
template<class L, class R>
friend L operator+( L lhs, R&& rhs ) {
return std::move(lhs) += std::forward<R>(rhs);
}
template<class L, class R>
friend L operator+=( L&& lhs, R&& rhs ) {
lhs.add( std::forward<R>(rhs) );
return std::forward<L>(lhs);
}
};
```

which is much cleaner and nearly optimal.

We then extend this with

```
struct has_subtraction; // implement
struct has_binops:
has_subtraction,
has_addition
{};
struct has_operations:
has_binops
{};
```

but really, few types have every type of operation, so I personally wouldn't like this.

You could use SFINAE (substitution failure is not an error) to detect if `add`

, `subtact`

, `multiply`

, `divide`

, `order`

, `equals`

etc are implemented in your type, and write `maybe_has_addition<D>`

that does a SFINAE test on `D`

to determine if it has `D.add( D const& )`

implemented. If and only if so `has_addition`

is inherited from `maybe_has_addition<D>`

.

Then you can set it up so that a whole myriad of operator overloads are written by doing:

```
struct matrix: maybe_has_operations<matrix>
```

where as you implement new operations on `matrix`

, more and more overloaded operators kick in.

This, however, is a different problem.

Doing this with dynamic polymorphism (virtual functions) is a mess. And really, do you want to jump through multiple vtables, dynamic allocations, and lose all compile time type safety when you write `matrix1 = matrix2 + matrix3`

? This isn't Java.

The friend bit is pretty easy. Notice how `has_addition`

calls `D.add(D const&)`

. We can make `add`

private within `D`

, but only if we `friend struct has_addition;`

within the body of `D`

.

So `has_addition`

is both a parent of `D`

and a friend of `D`

.

Myself, I just leave `add`

exposed, because it is harmless.

This technique has downsides, like what happens when you add two distinct classes both of which `has_addition`

.

You can see a more fleshed-out version of this in boost.operators, which uses related techniques as well.

`BinOps`

should be the base class of`Addition`

and`Subtraction`

, not the other way around.5more comments