With `<=>`

we have to make a decision: what do we want to do if the underlying comparison we need does not yet implement `<=>`

?

One option is: don't care. Just use `<=>`

and if the relevant types don't provide it, we're not comparable. That makes for a very concise implementation (note that you need to do the same thing for `==`

for a total of six functions):

```
template <typename T>
class optional {
public:
// ...
template <typename U>
constexpr std::compare_three_way_result_t<T, U>
operator<=>(optional<U> const& rhs) const
{
if (has_value() && rhs) {
return **this <=> *rhs;
} else {
return has_value() <=> rhs.has_value();
}
}
template <typename U>
constexpr std::compare_three_way_result_t<T, U>
operator<=>(U const& rhs) const
{
if (has_value()) {
return **this <=> *rhs;
} else {
return strong_ordering::less;
}
}
constexpr strong_ordering operator<=>(nullopt_t ) const {
return has_value() ? strong_ordering::greater
: strong_ordering::equal;
}
};
```

The three-way comparison between `bool`

s yields `std::strong_ordering`

, which is implicitly convertible to the other comparison categories. Likewise, `strong_ordering::less`

being implicitly convertible to `weak_ordering::less`

, `partial_ordering::less`

, `strong_equality::unequal`

, or `weak_equality::nonequivalent`

, as appropriate.

The above is the super nice, happy answer. And hopefully as time progresses, people will adopt `<=>`

and more and more code will be able to rely on the happy answer.

Another option is: we do care, and want to fallback to synthesizing an ordering. That is, if we need to compare a `T`

and a `U`

and they don't provide a `<=>`

, we can use one of the new customization point objects in the standard library. Which one though? The most conservative option is to synthesize a `partial_ordering`

with `compare_partial_order_fallback`

. This guarantees that we will always get the right answer.

For the `optional<T>`

vs `optional<U>`

comparison, that looks like:

```
template <typename T>
class optional {
public:
// ...
template <typename U>
constexpr auto operator<=>(optional<U> const& rhs) const
-> decltype(std::compare_partial_order_fallback(**this, *rhs))
{
if (has_value() && rhs) {
return std::compare_partial_order_fallback(**this, *rhs);
} else {
return has_value() <=> rhs.has_value();
}
}
// ...
};
```

Unfortunately, as implemented above, our comparison now always returns `partial_ordering`

-- even between two `optional<int>`

s. So a better alternative might be to use whatever `<=>`

returns and use the conservative fallback otherwise. I have no idea how to name this concept yet, so I'll just go with:

```
template <typename T, std::three_way_comparable_with<T> U>
constexpr auto spaceship_or_fallback(T const& t, U const& u) {
return t <=> u;
}
template <typename T, typename U>
constexpr auto spaceship_or_fallback(T const& t, U const& u)
-> decltype(std::compare_partial_order_fallback(t, u))
{
return std::compare_partial_order_fallback(t, u);
}
```

and use that:

```
template <typename T>
class optional {
public:
// ...
template <typename U>
constexpr auto operator<=>(optional<U> const& rhs) const
-> decltype(spaceship_or_fallback(**this, *rhs))
{
if (has_value() && rhs) {
return spaceship_or_fallback(**this, *rhs);
} else {
return has_value() <=> rhs.has_value();
}
}
// ...
};
```

A third option, the most conservative option, is what the Standard Library will take. Provide *both* the relational operators *and* the three-way comparison:

```
template <typename T> class optional { /* ... */ };
template <typename T, typename U>
constexpr bool operator<(optional<T> const&, optional<U> const&);
template <typename T, typename U>
constexpr bool operator>(optional<T> const&, optional<U> const&);
template <typename T, typename U>
constexpr bool operator<=(optional<T> const&, optional<U> const&);
template <typename T, typename U>
constexpr bool operator>=(optional<T> const&, optional<U> const&);
template <typename T, std::three_way_comparable_with<T> U>
std::compare_three_way_result_t<T, U>
operator<=>(optional<T> const& x, optional<U> const& y) {
if (x && y) {
return *x <=> *y;
} else {
return x.has_value() <=> y.has_value();
}
}
```

This is the most conservative option as it effectively takes both the C++17-and-earlier comparison implementation strategy *and* the C++20 comparison implementation strategy. As in: the "Why not both?" strategy. The use of the `concept`

on `operator<=>`

is what ensures that `a < b`

invokes `<=>`

where possible, instead of `<`

.

It's by far the most tedious and verbose approach, with lots of boilerplate, but it ensures that for existing, single-object comparison types, existing comparisons continue to work and do the same thing. The standard library has to be conservative like this.

But new code doesn't.

`a>>operator<=>>c;`

that currently can be valid.