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This is an rvalue reference:

void foo(int&& a);

It does not bind to lvalues:

int i = 42;
foo(i);   // error

This is a universal reference:

template<typename T>
void bar(T&& b);

It binds to rvalues and it also binds to lvalues:

bar(i);   // okay

This is an rvalue reference:

template<typename T>
struct X
    void baz(T&& c);

It does not bind to lvalues:

X<int> x;
x.baz(i);   // error

Why do universal references use the same syntax as rvalue references? Isn't that an unnecessary source of confusion? Did the committee ever consider alternative syntaxes like T&&&, T&*, T@ or T&42 (just kidding on that last one)? If so, what were the reasons for rejecting alternative syntaxes?

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Thanks, I was just getting things straight. –  chris Jan 13 '13 at 11:12
"Universal references" is not a term in the standard. They're all r-value refs and ref collapsing rules kick in sometimes. So there's no syntax because "there's no such thing as universal references" in the standard. –  Mat Jan 13 '13 at 11:14
"It does not bind to lvalues [...] It also binds to lvalues"? –  Luchian Grigore Jan 13 '13 at 11:21
Useful link T&& Doesn’t Always Mean “Rvalue Reference” from Scott Meyers –  M M. Jan 13 '13 at 11:41
X x; misses the template arguments. The code should compile when using X<int&> x;. –  Konrad Rudolph Jan 13 '13 at 14:18

1 Answer 1

up vote 13 down vote accepted

A universal reference such as T&& can deduce T to be an "object type", or a "reference type"

In your example it can deduce T as int when passed an rvalue, so the function parameter is int&&, or it can deduce T as int& when passed an lvalue, in which case the function parameter is int& (because the reference collapsing rules say std::add_rvalue_reference<int&>::type is just int&)

If T isn't deduced by the function call (as in your X::baz example) then it can't be deduced to int&, so the reference isn't a universal reference.

So IMHO there's really no need for new syntax, it fits nicely into template argument deduction and reference collapsing rules, with the small tweak that a template parameter can be deduced as a reference type (where in C++03 a function template parameter of type T or T& would always deduce T as an object type.)

These semantics and this syntax were proposed right from the beginning when rvalue references and a tweak to the argument deduction rules were proposed as the solution to the forwarding problem, see N1385. Using this syntax to provide perfect forwarding was proposed in parallel with proposing rvalue references for the purposes of move semantics: N1377 was in the same mailing as N1385. I don't think an alternative syntax was ever seriously proposed.

IMHO an alternative syntax would actually be more confusing anyway. If you had template<typename T> void bar(T&@) as the syntax for a universal reference, but the same semantics as we have today, then when calling bar(i) the template parameter T could be deduced as int& or int and the function parameter would be of type int& or int&& ... neither of which is "T&@" (whatever that type is.) So you'd have grammar in the language for a declarator T&@ which is not a type that can ever exist, because it actually always refers to some other type, either int& or int&&.

At least with the syntax we've got the type T&& is a real type, and the reference collapsing rules are not specific to function templates using universal references, they're completely consistent with the rest of the type system outside of templates:

struct A {} a;
typedef A& T;
T&& ref = a;    // T&& == A&

Or equivalently:

struct A {} a;
typedef A& T;
std::add_rvalue_reference<T>::type ref = a;    // type == A&

When T is an lvalue reference type, T&& is too. I don't think a new syntax is needed, the rules really aren't that complicated or confusing.

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+1 Nicely explained. Scott contacted me prior to his using his invented term universal reference and I expressed concern that this may actually cause more confusion than teaching what the standard actually says. Nevertheless Scott has an outstanding track record of being an excellent teacher of C++. Maybe use of his term will help people learn. Or maybe it will just cause confusion. I honestly don't know. In any event, Jonathan's explanation of why things are the way they are, and references to papers is spot on. –  Howard Hinnant Jan 13 '13 at 17:09
@HowardHinnant, same here, I had been planning to write a piece for the ACCU journal Overload explaining it in terms of the typedef and add_rvalue_reference examples above, but Scott published first. I had exactly the same reservations when reviewing his piece for Overload but decided that because he's a far better teacher than I am (with a far wider readership!) I'd trust him to do a better job of explaining it to the world. I now use the term universal references in public, but I still think in terms of deduction and ref-collapsing. –  Jonathan Wakely Jan 13 '13 at 17:17
Hmm, just noting that Daveed answered to my mild rage on cpp-next.com by saying "I (and others) voiced my preference for not trying to fit everything under the rvalue reference type, and instead introduce forwarding-specific notation" and "There were from the start people (e.g., colleagues and I) who thought the merging of “moving” and “forwarding” was a terrible idea, and we sketched out “other ways” but also "My bad for not putting in the energy to push those sketches forward as a competing proposal." –  Johannes Schaub - litb Jan 13 '13 at 21:12
Thanks, @JohannesSchaub-litb -- as I said, nothing was ever seriously proposed. If there's a proposal on the table to do it one way and noone offers an alternative proposal, then generally the one on the table wins. –  Jonathan Wakely Jan 14 '13 at 0:19
@Johannes template void ff(for T) { … } // T deduced to & or && What a beautiful repurposing of the for keyword :) –  FredOverflow Jan 14 '13 at 15:46

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