With operator<=> being added into C++20, I wanted to try to reason about how to implement this operator for those cases where it's not a simple member-wise comparison.

How would you implement the spaceship operator for comparing an optional<T> to an optional<U>or a U, which is a case where we either have to compare the T to the U or compare underlying states, getting the correct return type? There isn't such an example in the latest paper.

  • BTW the feature is incompatible with a>>operator<=>>c; that currently can be valid. – Johannes Schaub - litb Nov 15 '17 at 19:22
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    @JohannesSchaub-litb Yes, it is. That’s also mentioned in the proposal: “Tokenization follows max munch as usual. [...] This is the only known backward source incompatibility, and it is intentional. (We could adopt a special parsing rule to keep such code working without a space, but I would discourage that as having too little benefit for the trouble.)”. Seeing as you would usually have a space and/or parentheses there anyway, I think I agree with the proposal here. – Daniel H Nov 15 '17 at 19:29
  • @Barry it isn't mentioned in the proposal, as far as I can see (it only gives a following comparison, but not a following switch, as backward incompatiblity. and it says "this is the only known backward source incompatibility") – Johannes Schaub - litb Nov 15 '17 at 19:46
  • @JohannesSchaub-litb 1. Please check who you’re replying to; Barry didn’t say the proposal mentioned that, I did, and I almost missed your comment. 2. I assume you mean “a following shift”, since I don’t see how a following switch can cause an issue. 3. I read it as saying maximum munch is the only known backward source incompatibility, although I don’t know why Herb didn’t list shift as one of the two places he’s aware of maximum munch occurring. – Daniel H Nov 15 '17 at 20:42
  • (For reference, here is an example where maximum munch changes the tokenization in a shift expression) – Daniel H Nov 15 '17 at 20:50

I believe the right way to implement this would be to use the std::compare_3way() function template to handle both (1) whether such a comparison is viable and (2) what the comparison category actually is.

That makes the implementation of all the comparison operators quite compact:

template <typename T>
class optional {
public:
    // ...

    template <typename U>
    constexpr auto operator<=>(optional<U> const& rhs) const
        -> decltype(compare_3way(**this, *rhs))
    {
        if (has_value() && rhs) {
            return compare_3way(**this, *rhs);
        } else {
            return has_value() <=> rhs.has_value();
        }
    }

    template <typename U>
    constexpr auto operator<=>(U const& rhs) const
        -> decltype(compare_3way(**this, rhs))
    {
        if (has_value()) {
            return compare_3way(**this, rhs);
        } else {
            return strong_ordering::less;
        }
    }

    constexpr strong_ordering operator<=>(nullopt_t ) const {
        return has_value() ? strong_ordering::greater
                           : strong_ordering::equal;
    }
};

The 3-way bool comparison yields std::strong_ordering, which is implicitly convertible to the other four 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.

  • Here you’re calling *lhs and *rhs when you know one of them is empty. Also, why are you implementing this as a non-member when operator<=> is intended to be implemented as a member? – Daniel H Nov 15 '17 at 19:23
  • @DanielH I fixed his typo in the 2nd comparison – Yakk - Adam Nevraumont Nov 15 '17 at 19:24
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    @DanielH Why in the world do you think it is "intended to be implemented as a member"? My complaint would rather be "why are you a template on both, and not a koenig operator". – Yakk - Adam Nevraumont Nov 15 '17 at 19:25
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    @Yakk Because of the note on page 3 of the proposal which says “Normally, operator<=> should be just a member function; you will still get conversions on each parameter because of the symmetric generation rules in §2.3.”, right above the start of section 1.4.1. – Daniel H Nov 15 '17 at 19:27
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    @DanielH You could constrain the second template to types which are not convertible to optional<T> and keep the first one as is. – Pezo Nov 18 '17 at 23:58

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