There already is such a concept in the standard library: `three_way_comparable`

. `T`

satisfies `three_way_comparable`

if *all* the binary comparison operators and `<=>`

are all valid expressions and the invocation of `<=>`

gives you at least `std::partial_ordering`

.

It's a little bit more involved than the one you're proposing - partially to avoid weird types (e.g. maybe some type defines `operator<=>`

but also deletes `operator<=`

for whatever reason? Let's just exclude those...) but also because having an ordering require equality is also pretty sensible. Just because a type is only partially ordered doesn't need it can't support `==`

as well.

One other point is your `PartialOrder<T&>`

actually ends up comparing *non-const* objects of type `T`

, rather than `const`

ones. Which isn't ideal. That's why the standard does this `const remove_reference_t<T>&`

dance.

Note that neither what you're suggesting nor the standard library concept checks that a type is *only* partially ordered, just that it's *at least* partially ordered. `int`

satisfies both `std::three_way_comparable`

and your `PartialOrder`

concepts, despite obviously having a total order.

One way of achieving proper subsumption with this particular concept is:

```
template <typename T>
concept partially_ordered = std::three_way_comparable<T>;
template <typename T>
concept totally_ordered = partially_ordered<T> &&
requires (std::remove_cvref_t<T> const& lhs, std::remove_cvref_t<T> const& rhs) {
{ lhs <=> rhs } -> std::convertible_to<std::weak_ordering>;
};
```

Or to be lazier:

```
template <typename T>
concept totally_ordered = partially_ordered<T> &&
std::three_way_comparable<T, std::weak_ordering>;
```

Possibly by replacing `weak_ordering`

with `strong_ordering`

.

Also note that there is a `std::totally_ordered`

concept - but it does not require `<=>`

.