171

const auto& would suffice if I want to perform read-only operations. However, I have bumped into

for (auto&& e : v)  // v is non-const

a couple of times recently. This makes me wonder:

Is it possible that in some obscure corner cases there is some performance benefit in using forwarding references, compared to auto& or const auto&?

(shared_ptr is a suspect for obscure corner cases)


Update Two examples that I found in my favorites:

Any disadvantage of using const reference when iterating over basic types?
Can I easily iterate over the values of a map using a range-based for loop?

Please concentrate on the question: why would I want to use auto&& in range-based for loops?

5
  • 5
    Do you really see it "often"? Oct 29, 2012 at 22:44
  • 2
    I'm not sure there's enough context in your question for me to gauge how "crazy" it is where you're seeing it. Oct 29, 2012 at 22:49
  • 8
    @LightnessRacesinOrbit Long story short: why would I want to use auto&& in range-based for loops?
    – Ali
    Oct 29, 2012 at 22:52
  • See quuxplusone.github.io/blog/2018/12/15/autorefref-always-works and the (as of this writing, two) followup posts. Jul 4, 2023 at 16:06
  • @Quuxplusone Thanks for the info. You might want to post a short summary as an answer, then link to your website. It would be better than just a comment.
    – Ali
    Jul 4, 2023 at 21:20

3 Answers 3

135

The only advantage I can see is when the sequence iterator returns a proxy reference and you need to operate on that reference in a non-const way. For example consider:

#include <vector>

int main()
{
    std::vector<bool> v(10);
    for (auto& e : v)
        e = true;
}

This doesn't compile because rvalue vector<bool>::reference returned from the iterator won't bind to a non-const lvalue reference. But this will work:

#include <vector>

int main()
{
    std::vector<bool> v(10);
    for (auto&& e : v)
        e = true;
}

All that being said, I wouldn't code this way unless you knew you needed to satisfy such a use case. I.e. I wouldn't do this gratuitously because it does cause people to wonder what you're up to. And if I did do it, it wouldn't hurt to include a comment as to why:

#include <vector>

int main()
{
    std::vector<bool> v(10);
    // using auto&& so that I can handle the rvalue reference
    //   returned for the vector<bool> case
    for (auto&& e : v)
        e = true;
}

Edit

This last case of mine should really be a template to make sense. If you know the loop is always handling a proxy reference, then auto would work as well as auto&&. But when the loop was sometimes handling non-proxy references and sometimes proxy-references, then I think auto&& would become the solution of choice.

26
  • 5
    On the other hand, there's no explicit disadvantage, is there? (Aside from potentially confusing people, which I don't think is much worth mentioning, personally.)
    – ildjarn
    Oct 29, 2012 at 22:55
  • 13
    Another term for writing code that unnecessarily confuses people is: writing confuscated code. It is best to make your code as simple as possible, but no simpler. This will help keep the bug count down. That being said, as && becomes more familiar, then maybe 5 years from now people will come to expect an auto&& idiom (assuming it actually does no harm). I don't know if that will happen or not. But simple is in the eye of the beholder, and if you're writing for more than just yourself, take your readers into account. Oct 29, 2012 at 23:02
  • 11
    I prefer const auto& when I want the compiler to help me check that I don't accidentally modify the elements in the sequence. Oct 29, 2012 at 23:04
  • 40
    I personally like to use auto&& in generic code where I need to modify the elements of the sequence. If I don't, I'll just stick to auto const&.
    – Xeo
    Oct 29, 2012 at 23:08
  • 9
    @Xeo: +1 It is because of enthusiasts like yourself, constantly experimenting and pushing for better ways of doing things, that C++ continues to evolve. Thank you. :-) Oct 29, 2012 at 23:13
33

Using auto&& or universal references with a range-based for-loop has the advantage that you captures what you get. For most kinds of iterators you'll probably get either a T& or a T const& for some type T. The interesting case is where dereferencing an iterator yields a temporary: C++ 2011 got relaxed requirements and iterators aren't necessarily required to yield an lvalue. The use of universal references matches the argument forwarding in std::for_each():

template <typename InIt, typename F>
F std::for_each(InIt it, InIt end, F f) {
    for (; it != end; ++it) {
        f(*it); // <---------------------- here
    }
    return f;
}

The function object f can treat T&, T const&, and T differently. Why should the body of a range-based for-loop be different? Of course, to actually take advantage of having deduced the type using universal references you'd need to pass them on correspondingly:

for (auto&& x: range) {
    f(std::forward<decltype(x)>(x));
}

Of course, using std::forward() means that you accept any returned values to be moved from. Whether objects like this makes much sense in non-template code I don't know (yet?). I can imagine that using universal references can offer more information to the compiler to do the Right Thing. In templated code it stays out of making any decision on what should happen with the objects.

0
11

I virtually always use auto&&. Why get bitten by an edge case when you don't have to? It's shorter to type too, and I simply find it more... transparent. When you use auto&& x, then you know that x is exactly *it, every time.

5
  • 39
    My problem is that your are giving up const-ness with auto&& if const auto& suffices. The question asks for the corner cases where I can get bitten. What are the corner cases which have not been mentioned by Dietmar or Howard yet?
    – Ali
    Oct 30, 2012 at 20:19
  • 6
    Here's a way to get bitten if you do use auto&&. If the type you are capturing should be moved in the body of the loop (for instance), and is changed to a later date so it resolves to a const& type, your code will silently continue functioning, but your moves will be come copies. This code will be very deceptive. If, however, you explicitly specify the type as an r-value reference, whoever changed the container type will get a compilation error because you really really wanted these objects moved and not copied... Apr 10, 2019 at 20:03
  • 1
    @cyberbisson I just came across this: how can I enforce an rvalue reference without explicitly specify the type? Something like for (std::decay_t<decltype(*v.begin())>&& e: v)? I guess there is a better way ...
    – Jerry Ma
    Apr 10, 2019 at 22:25
  • 2
    @JerryMa It depends on what you do know about the type. As mentioned above, auto&& will give a "universal reference", so anything other than that will get you a more specific type. If v is assumed to be a vector, you could do decltype(v)::value_type&&, which is what I assume you wanted by taking the result of operator* on an iterator type. You could also do decltype(begin(v))::value_type&& to check the iterator's types instead of the container. If we have so little insight into the type, though, we might consider it a little clearer to just go with auto&&... Apr 11, 2019 at 17:06
  • @Ali TBH classic constness (unlike constexpr) is one of the crapiest, least useful C++ features and an example of bad design. Because of lack of const constructors we ended up with const_iterator/iterator, begin()/cbegin(), lack of const propagation to the member in unique_ptr and other nonsense... It's better to use auto && , which makes things simple.
    – mip
    Dec 2, 2022 at 15:17

Your Answer

By clicking “Post Your Answer”, you agree to our terms of service and acknowledge you have read our privacy policy.

Not the answer you're looking for? Browse other questions tagged or ask your own question.