Same way you resolve any other function which returns `auto`

in which different `return`

statements deduce differently. You either:

- Ensure that all the
`return`

s have the same type, or
- Explicitly pick a return type.

In this case, `int`

s compare as `strong_ordering`

while `double`

s compare as `partial_ordering`

, and `strong_ordering`

is implicitly convertible to `partial_ordering`

, you can do either:

```
std::partial_ordering operator <=>(const QVariant& l, const QVariant& r) {
// rest as before
}
```

or explicitly cast the integer comparison:

```
case QMetaType::Int:
return std::partial_ordering(l.toInt() <=> r.toInt());
```

That gives you a function returning `partial_ordering`

.

If you want to return `strong_ordering`

instead, you have to lift the `double`

comparison to a higher category. You can do that in two ways:

You can use `std::strong_order`

, which is a more expensive operation, but provides a total ordering over all floating point values. You would then write:

```
case QMetaType::Double:
return std::strong_order(l.toDouble(), r.toDouble());
```

Or you can do something like consider `NaN`

s ill-formed and throw them out somehow:

```
case QMetaType::Double: {
auto c = l.toDouble() <=> r.toDouble();
if (c == std::partial_ordering::unordered) {
throw something;
} else if (c == std::partial_ordering::less) {
return std::strong_ordering::less;
} else if (c == std::partial_ordering::equivalent) {
return std::strong_ordering::equal;
} else {
return std::strong_ordering::greater;
}
}
```

It's more tedious but I'm not sure if there's a more direct way to do this kind of lifting.

`<=>`

need to behave symmetrical? By switching on only`l.type()`

you violate that property.