What advantages does the latter form offer over the former?
In the form
for(auto& v : vector), the type of
v is deduced as an lvalue reference to the type obtained by dereferencing the container's iterator type. This means that if the result of dereferencing the iterator is an rvalue (think
std::vector<bool> which returns a proxy type representing a reference to a single
bool value), then the code will fail to compile, because an lvalue reference cannot bind to an rvalue.
When you write
for(auto&& v : vector), this is a universal reference, meaning the type of
v will either be deduced as an rvalue reference in the case described above; or as an lvalue reference in the usual case where dereferencing the iterator returns a reference to the container's element. So it works in the
vector<bool> case as well. That's why that form should be preferred if you plan on modifying the elements you're iterating over within the loop.
Why do we usually go with
auto& instead of
auto&& if the latter is clearly advantageous?
You shouldn't. The only downside I can think of
auto&& is that it doesn't guarantee that the changes you make to the elements will necessarily propagate back to the container, but that's indicative of a broken design, and I don't think it's worth protecting against.
Is making the new ranged-for based loop equivalent to
auto && going to break existing code?
I don't see how it can break existing code because the old syntax will continue to function as it does today. But if you mean replacing existing code with the new syntax, then it might have an effect if the one you're replacing is the
auto const& form. See this example. Notice how the
auto const& version calls the
const member function, while the other two call the non-
const version? Replacing the first one with the terse version will change the member function being called.
Will it make an actual impact on new code?
Again, it's no different from old code that uses
auto&& today, so that'll see no difference. If you use it in places where you don't intend to modify the elements, then the compiler will no longer stop you from doing that accidentally, and you might call a different overload, as shown in the example above.
Wouldn't this introduce a gotcha to beginners that their code is actually equivalent to
I'm not sure I understand what you mean by this, but if you're asking whether beginners will write code without knowing, or understanding the intricacies of reference collapsing, then yes, it's possible they will. But that is one of the stated goals of the paper you've linked to. The argument is that you can stay away from teaching those difficult concepts right at the get go, but introduce beginners to a single syntax for range-based
for loops that works with everything. As far as that is concerned, I think the syntax has merit, but looking at it from a
const correctness perspective, I frown upon it because I'd rather use
auto const& if I want read-only access to the elements, and then the terse syntax seems asymmetrical.