Some time ago I defined my first three-way comparison operator. It compared a single type and replaced multiple conventional operators. Great feature. Then I tried to implement a similar operator for comparing two variants by delegation:

auto operator <=> (const QVariant& l, const QVariant& r)
   switch (l.type())
      case QMetaType::Int:
         return l.toInt() <=> r.toInt();
      case QMetaType::Double:
         return l.toDouble() <=> r.toDouble();

This doesn't compile, I get the error

inconsistent deduction for auto return type: ‘std::strong_ordering’ and then ‘std::partial_ordering’.

Obviously int and double spaceship operators return different types.

What is the correct way to solve this?

  • 1
    Doesn't <=> need to behave symmetrical? By switching on only l.type() you violate that property.
    – Bergi
    Dec 19, 2020 at 13:33
  • @Bergi You are right. This is why in my real code I am checking for equality of types. Dec 19, 2020 at 15:40

3 Answers 3


Same way you resolve any other function which returns auto in which different return statements deduce differently. You either:

  1. Ensure that all the returns have the same type, or
  2. Explicitly pick a return type.

In this case, ints compare as strong_ordering while doubles 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 NaNs 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.

  • Does std::strong_order have a performance cost over your last suggestion in the cases where the partial ordering can be simply converted to a corresponding strong ordering? That is, are those three cases the same thing that std::strong_order does for those cases? (There might still be reasons to throw on unordered results if you consider such values ill-formed and want to fail fast, so it’s a good suggestion either way, but I’m trying to understand the options a little better.)
    – KRyan
    Dec 19, 2020 at 14:30
  • @KRyan Yes. std::strong_order actually does provide a total order over floating points, including all the NaNs (this is ISO/IEC/IEEE 60559 totalOrder). That's surely more work than the branching -- but it's also very different behavior.
    – Barry
    Dec 19, 2020 at 16:57
  • I understand that, but I was asking specifically about those branches where it is the same. It seems like those branches should be the same, and performance should be the same if the values would use those branches, no?
    – KRyan
    Dec 19, 2020 at 17:20
  • @KRyan I don't understand what you're asking.
    – Barry
    Dec 19, 2020 at 17:26
  • Wondering, std::strong_order(double, double ); does not compile on g++ 11 w. std=c++20. Is there no implementation for a strong_ordering of floats in g++ ? Jan 21, 2023 at 10:42

The types of the operator<=> for int and double differ but they should have a common type. You probably want to leverage the compiler in automatically finding the proper type. You could use std::common_type to do but that would be quite ugly. It is easier to just leverage what std::common_type type does under the (when implemented in the library rather the compiler) and use the ternary operator:

auto operator <=> (const QVariant& l, const QVariant& r)
    return l.type() == QMetaType:Int? l.toInt() <=> r.toInt()
         : l.type() == QMetaType::Double? l.toDouble() <=> r.toDouble()
         : throw;
  • Sounds like a brilliant solution for two types. But well, my real life function will have dozens of types. That will be a mess, right? Dec 18, 2020 at 20:23
  • @Silicomancer: how so? You need to list your types and how to extract them anyway and I already set you how to make multiple cases be read easily. If you area so inclined you could put the logic into a variadic function where you effectively spell out the type to accessor-lmbda finction and have the logic there but it would just break down to the same stuff Dec 18, 2020 at 20:27
  • Royally inclined, yes ;-) Hm, using a variadic function came to my mind as well. I guess that could be an even better solution. Dec 18, 2020 at 20:50
  • @Silicomancer depends on how you spin it, actually. Just for this use-case it would be more typing and obfuscation. If you have a suitable binary apply() function which take the operation (in this case [](auto const& l, auto const& r)( return l <=> r; }) as argument, it could be kind of nice: return apply(op, l, r); However, writing apply() is a bit annoying albeit mechanical. Dec 18, 2020 at 20:56
  • Have a look at my answer, what do you think? Dec 19, 2020 at 23:27

I played around with some template code to implement Dietmar Kühls idea of using std::common_type. This is the result example code:

template <typename CommonT, typename... ArgsT> requires (sizeof...(ArgsT) == 0)
inline CommonT variantSpaceshipHelper([[maybe_unused]] const QVariant& pLeft, [[maybe_unused]] const QVariant& pRight) noexcept
   std::terminate(); // Variant type does not match any of the given template types

template <typename CommonT, typename T, typename... ArgsT>
inline CommonT variantSpaceshipHelper(const QVariant& pLeft, const QVariant& pRight) noexcept
   if (pLeft.type() == static_cast<QVariant::Type>(qMetaTypeId<T>()))
      return (pLeft.value<T>() <=> pRight.value<T>());

   return variantSpaceshipHelper<CommonT, ArgsT...>(pLeft, pRight);

template <typename... ArgsT>
inline auto variantSpaceship(const QVariant& pLeft, const QVariant& pRight) noexcept
   using CommonT = std::common_type_t<decltype(std::declval<ArgsT>() <=> std::declval<ArgsT>())...>;
   return variantSpaceshipHelper<CommonT, ArgsT...>(pLeft, pRight);

inline auto operator <=>(const QVariant& pLeft, const QVariant& pRight) noexcept
   assert(pLeft.type() == pRight.type());
   return variantSpaceship<int, double>(pLeft, pRight);

Additional types can easily be added to the variantSpaceship call.

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