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The (probably not C++14, probably Library TS) facility make_optional is defined (in n3672) as:

template <class T>
  constexpr optional<typename decay<T>::type> make_optional(T&& v) {
    return optional<typename decay<T>::type>(std::forward<T>(v));
  }

Why is it necessary to transform the type T (i.e. not to just return optional<T>), and is there a philosophical (as well as practical) justification for using decay specifically as the transformation?

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Because T can be an lvalue reference, and optional references aren't allowed. –  Simple Jul 3 at 14:56
1  
@Simple so why not just remove_reference? –  ecatmur Jul 3 at 15:05
1  
Presumably so you can't also make an optional<T const> or an optional<T[N]>, which would also have weird semantics. –  Simple Jul 3 at 15:14
1  
+1 I was writting a universal reference based make-like function just twenty minutes before I have seen this question on the hot questions list. When tested the first time there was no decay, and I have spent ten minutes to realize that decayis needed to remove the cualifiers and universal-reference colapsing remains... Why didn't post your question a hour before Ecatmur??? :P –  Manu343726 Jul 3 at 20:17

3 Answers 3

up vote 15 down vote accepted

A general purpose of decay is to take a type and modify it to be suitable for storage.

Take a look at these examples that decay makes work, while remove_reference would not:

auto foo( std::string const& s ) {
  if (global_condition)
    return make_optional( s );
  else
    return {};
}

or

void function() { std::cout << "hello world!\n"; }
auto bar() { return std::make_optional( function ); }

or

int buff[15];
auto baz() { return std::make_optional( buff ); }

An optional<int[15]> would be a very strange beast -- C style arrays do not behave well when treated like literals, which is what optional does to its parameter T.

If you are making a copy of data, the const or volatile nature of the source does not matter. And you can only make simple copy of arrays and functions by decaying them to pointers (without falling back on std::array or similar). (in theory, work could be done to make optional<int[15]> work, but it would be lots of extra complications)

So std::decay solves all of these issues, and does not really cause problems, so long as you allow make_optional to deduce its argument's type instead of passing T literally.

If you want to pass in a T literally, there is no reason to use make_optional after all.

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I just found open-std.org/JTC1/SC22/WG21/docs/papers/2006/n2069.html which supports your assertion that the (a) purpose of decay is "to take a type and modify it to be suitable for storage". It's unfortunate that that purpose isn't expressed more explicitly in the standard. –  ecatmur Jul 3 at 15:26

This is not new behaviour with make_optional; the utility functions make_pair and make_tuple behave in the same way. I can see at least two reasons to do this:

  1. It may be undesirable or impossible to actually instantiate the template with the undecayed types.

    • If T is a function type, well, you just can't store a function inside a class, period; but you can store a function pointer (the decayed type).

    • If T is an array type: the resulting class is going to be "defective" because it can't be copied, owing to the fact that arrays are not copy-assignable. For optional the value_or member function can't be compiled at all, because it returns T. Consequently you can't have an array type in an optional at all.

  2. Not decaying the types may lead to unexpected behaviour.

    • If the argument is a string literal, I personally would expect the type contained to be const char* rather than const char [n]. This decay occurs in most places, so why not here?

    • If v is an lvalue then T will be deduced as an lvalue reference type. Do I actually want a pair containing a reference, for instance, just because one of the arguments was an lvalue? Surely not.

    • The type inside the pair or tuple or optional or whatever shouldn't acquire the cv-qualification of v. That is, say we have x declared as const int. Should make_optional(x) create a optional<const int>? No it shouldn't; it should create optional<int>.

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Just look at what decay does:

  • Removes reference qualifiers—T&T; no optional references, else you couldn’t reseat the optional, which needs to be assignable.

  • For array types, removes extent—T[42]T*; optional fixed-extent arrays aren’t that useful because each array size has a different type, and you can’t directly pass array types by value, necessary for the value and value_or member functions to work.

  • For function types, adds pointer—T(U)T(*)(U); no optional function references, for similar reasons.

  • Otherwise, removes cv-qualifiers—const intint; no optional const values, again, else you couldn’t reseat the optional.

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Try making optional<int[35]> work -- it is tricky, as arrays do not like being copied around outside of structs. –  Yakk Jul 3 at 15:16
    
I don't understand point #2. –  Lightness Races in Orbit Jul 3 at 15:18
    
On #1, optional references do exist in this specification, as essentially pointers: reference implementation. They can be reassigned; see notes on why it was decided to do so. Though just because you can have an optional reference doesn't make it a good default for make_optional, as per @Brian's answer for why this is following conventions in make_tuple and make_pair. –  HostileFork Jul 3 at 15:24

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