7

Let's say I have a template function:

template <typename A, typename B>
A fancy_cast(B)
{
    return {};
}

The intended usage is something like fancy_cast<int>(1.f).

But nothing stops the user from specifying the second template parameter manually: fancy_cast<int, int>(1.f), which would cause problems.

How can I prevent typename B from being specified and force it to be deduced?

I've come up with this:

// Using this wrapper prevents the code from being
// ill-formed NDR due to [temp.res]/8.3
template <auto V> inline constexpr auto constant_value = V;

template <
    typename A,
    typename ...Dummy,
    typename B,
    typename = std::enable_if_t<constant_value<sizeof...(Dummy)> == 0>
>
A fancy_cast(B)
{
    return {};
}

It appears to work, but it's extremely cumbersome. Is there a better way?

4

What about making fancy_cast a variable template?

template <typename A>
struct fancy_cast_t {
    template <typename B>
    A operator()(B x) const { return x; }
};

template <typename A>
constexpr fancy_cast_t<A> fancy_cast {};

fancy_cast<int>(1.5);  // works
fancy_cast<int, int>(1.5);  // doesn't work
fancy_cast<int>.operator()<int>(1.5);  // works, but no one would do this
3

This is not the most efficient solution, but you can create a class that has a template parameter for the type to convert to, and then have a constructor template that takes any type. Then if you add an operator T for the type you instantiate the class with you can have that return correct value. That would look like

template<typename T>
struct fancy_cast
{
    T ret;
    template<typename U>
    fancy_cast(U u) : ret(u) {} // or whatever you want to do to convert U to T
    operator T() && { return std::move(ret); }
};

int main()
{
    double a = 0;
    int b = fancy_cast<int>(a);
}

This works because there is no way to specify the template parameter for the constructor since you can't actually call it.

2

I found a good-looking solution.

We can use a non-type parameter pack, of a type that the user can't construct.1 E.g. a reference to a hidden class:

namespace impl
{
    class require_deduction_helper
    {
      protected:
        constexpr require_deduction_helper() {}
    };
}

using require_deduction = impl::require_deduction_helper &;

template <typename A, require_deduction..., typename B>
A fancy_cast(B)
{
    return {};
}

1 We do have to leave a loophole for constructing a deduction_barrier, otherwise the code would be ill-formed NDR. That's why the constructor is protected.

  • Looks good, does it work for all types? – M.Mac Nov 8 at 18:04
  • 1
    @M.Mac Do you mean for all possible A and B? I don't see why it wouldn't. – HolyBlackCat Nov 8 at 18:06
  • I don't think that you need protected, require_deduction... doesn't require to be empty (contrary to enable_if_t<sizeof...(Ts) == 0>). It is not because you cannot construct some values that template is invalid. Similarly, struct S{}; using member_ptr_t = void (S::*)(); is valid, even if S has no members. – Jarod42 Nov 8 at 18:39
  • @Jarod42 Hmm. As I read it, the clause says you have to be able to create a valid specialization with a non-empty pack, or it's ill-formed NDR. member_ptr_t can be initialized with nullptr, but if it couldn't then I'd say you couldn't make a parameter pack out of it. – HolyBlackCat Nov 8 at 19:11

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