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Say I'm making a function to copy a value:

template<class ItInput, class ItOutput>
void copy(ItInput i, ItOutput o) { *o = *i; }

and I would like to avoid the assignment if i and o point to the same object, since then the assignment is pointless.

Obviously, I can't say if (i != o) { ... }, both because i and o might be of different types and because they might point into different containers (and would thus be incomparable). Less obviously, I can't use overloaded function templates either, because the iterators might belong to different containers even though they have the same type.

My initial solution to this was:

template<class ItInput, class ItOutput>
void copy(ItInput i, ItOutput o)
    if (&*o != static_cast<void const *>(&*i))
        *o = *i;

but I'm not sure if this works. What if *o or *i actually returns an object instead of a reference?

Is there a way to do this generally?

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Oh I see... 'aite. Favoriting this :) –  Luchian Grigore Jul 26 '12 at 1:59
When you say '... if input and output are the same...', do you mean the same value, or iterators that point to the same location in a container? –  Rollie Jul 26 '12 at 2:07
I agree w/chrad, your solution is fine. Your concern about *o/*i returning an object has more significant implications in that the meat of the function *o = *i; won't work in that case as well, given that both are of the same type. –  Rollie Jul 26 '12 at 2:19
What category of iterator do you require for the iterators? Can they actually be input and output iterators? An input iterator is only single-pass, so you can't indirect it twice. Strictly, only an input iterator may be a proxy iterator (an iterator whose operator* returns an object, not a reference). Forward, bidirectional, and random access iterators can't return a proxy. In practice, this is not always followed, because it's extremely useful to have a proxy iterator that provides random access (also, I don't know how you could implement vector<bool> efficiently without doing this) –  James McNellis Jul 26 '12 at 2:32
@LucDanton: The important rule is at §24.2.5[forward.iterators]/6 which mandates that for two forward iterators a and b, "if a and b are both dereferenceable, then a == b if and only if *a and *b are bound to the same object." That requirement can only be satisfied if indirection yields a reference. –  James McNellis Jul 26 '12 at 3:03

4 Answers 4

I don't think that this is really necessary: if assignment is expensive, the type should define an assignment operator that performs the (relatively cheap) self assignment check to prevent doing unnecessary work. But, it's an interesting question, with many pitfalls, so I'll take a stab at answering it.

If we are to assemble a general solution that works for input and output iterators, there are several pitfalls that we must watch out for:

  • An input iterator is a single-pass iterator: you can only perform indirection via the iterator once per element, so, we can't perform indirection via the iterator once to get the address of the pointed-to value and a second time to perform the copy.

  • An input iterator may be a proxy iterator. A proxy iterator is an iterator whose operator* returns an object, not a reference. With a proxy iterator, the expression &*it is ill-formed, because *it is an rvalue (it's possible to overload the unary-&, but doing so is usually considered evil and horrible, and most types do not do this).

  • An output iterator can only be used for output; you cannot perform indirection via it and use the result as an rvalue. You can write to the "pointed to element" but you can't read from it.

So, if we're going to make your "optimization," we'll need to make it only for the case where both iterators are forward iterators (this includes bidirectional iterators and random access iterators: they're forward iterators too).

Because we're nice, we also need to be mindful of the fact that, despite the fact that it violates the concept requirements, many proxy iterators misrepresent their category because it is very useful to have a proxy iterator that supports random access over a sequence of proxied objects. (I'm not even sure how one could implement an efficient iterator for std::vector<bool> without doing this.)

We'll use the following Standard Library headers:

#include <iterator>
#include <type_traits>
#include <utility>

We define a metafunction, is_forward_iterator, that tests whether a type is a "real" forward iterator (i.e., is not a proxy iterator):

template <typename T>
struct is_forward_iterator :
            typename std::iterator_traits<T>::iterator_category
        >::value &&
{ };

For brevity, we also define a metafunction, can_compare, that tests whether two types are both forward iterators:

template <typename T, typename U>
struct can_compare :
        is_forward_iterator<T>::value &&
{ };

Then, we'll write two overloads of the copy function and use SFINAE to select the right overload based on the iterator types: if both iterators are forward iterators, we'll include the check, otherwise we'll exclude the check and always perform the assignment:

template <typename InputIt, typename OutputIt>
auto copy(InputIt const in, OutputIt const out)
    -> typename std::enable_if<can_compare<InputIt, OutputIt>::value>::type
    if (static_cast<void const volatile*>(std::addressof(*in)) != 
        static_cast<void const volatile*>(std::addressof(*out)))
        *out = *in;

template <typename InputIt, typename OutputIt>
auto copy(InputIt const in, OutputIt const out)
    -> typename std::enable_if<!can_compare<InputIt, OutputIt>::value>::type
    *out = *in;

As easy as pie!

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Sorry for the delayed comment, but I just found this answer after doing a bunch of research (including a post to comp.std.c++, which has an interesting case of a non-proxy iterator with a similar issue). Two forward iterators, even if of the same type, are not comparable if unless they have the same underlying sequence (24.2.5/2). So unless you know that two iterators are within a common range, it's UB to compare them, and I don't believe there is any way to test whether the iterators are in the same range, because the test in 24.2.1/6 relies on ==. –  rici Dec 18 '12 at 18:01
@rici: To which part of this answer are you objecting? –  James McNellis Dec 18 '12 at 19:11
ah, sorry. I misread can_compare (confusing it with its name). So your intention is to bypass operator== on the basis that the fact that two addresses compare equal is sufficient to demonstrate that the objects pointed to are essentially the same object, even if the objects are different types. That also strikes me as questionable, but it wasn't the question I originally had, so I withdraw my objection, and sorry for the noise. –  rici Dec 19 '12 at 1:00

I think this may be a case where you may have to document some assumptions about the types you expect in the function and be content with not being completely generic.

Like operator*, operator& could be overloaded to do all sorts of things. If you're guarding against operator*, then you should consider operator& and operator!=, etc.

I would say that a good prerequisite to enforce (either through comments in the code or a concept/static_assert) is that operator* returns a reference to the object pointed to by the iterator and that it doesn't (or shouldn't) perform a copy. In that case, your code as it stands seems fine.

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Should I just ignore std::iterator_traits<It>::reference and std::iterator_traits<It>::pointer then? I mean, if I could dereferenced iterators as plain references and (and their addresses as pointers) then there was no point in having either of those typedef's defined in iterator_traits, right? value_type would've been sufficient. –  Mehrdad Jul 26 '12 at 2:14
@Mehrdad those are defined because they make using iterators with less trivial functions a lot easier. Sometimes you need to use the actual type that the iterator points to, and then you'll need to use those typedefs. –  SoapBox Jul 26 '12 at 2:19
"Sometimes you need to use the actual type that the iterator points to" If I can treat iterators as pointers, then isn't that just value_type? Why would I need pointer or reference then? –  Mehrdad Jul 26 '12 at 2:24
@Mehrdad You cannot treat iterators as pointers. The iterator concepts do not guarantee that &*it is correct (or what its type should be if it is), so you have to follow the advice here and roll out your own concept to explain that the template expects &*it != &*it to work. This gives a chance to would-be users to e.g. provide or fix an overloaded operator& to the reference type if need be. –  Luc Danton Jul 26 '12 at 2:30
"I would say that a good assumption is that operator* returns a reference to the object pointed to by the iterator" -- Except it's not, since input iterators are allowed to dereference to anything "convertible to T" (§24.2.3/2). –  Xeo Jul 26 '12 at 2:31

Your code, as is, is definitly not okay, or atleast not okay for all iterator categories.

Input iterators and output iterators are not required to be dereferenceable after the first time (they're expected to be single-pass) and input iterators are allowed to dereference to anything "convertible to T" (§24.2.3/2).

So, if you want to handle all kinds of iterators, I don't think you can enforce this "optimization", i.e. you can't generically check if two iterators point to the same object. If you're willing to forego input and output iterators, what you have should be fine. Otherwise, I'd stick with doing the copy in any case (I really don't think you have another option on this).

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I guess I guessed the code had other problems, so I'm not surprised it's not OK... what I was asking was, is there a way to achieve what I'm asking? ("No" is an acceptable answer if correct...) –  Mehrdad Jul 26 '12 at 2:38
@Mehrdad: See the edited-in conclusion. –  Xeo Jul 26 '12 at 2:41

Write a helper template function equals that automatically returns false if the iterators are different types. Either that or do a specialization or overload of your copy function itself.

If they're the same type then you can use your trick of comparing the pointers of the objects they resolve to, no casting required:

if (&*i != &*o)
    *o = *i;

If *i or *o doesn't return a reference, no problem - the copy will occur even if it didn't have to, but no harm will be done.

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That doesn't work, it's already mentioned in my question. –  Mehrdad Jul 26 '12 at 2:42
@Mehrdad, can you be more specific? Which part doesn't work, and why? –  Mark Ransom Jul 26 '12 at 2:44
"I can't use overloaded templated functions either, because the iterators might belong to different containers even though they have the same type." –  Mehrdad Jul 26 '12 at 2:46
@Mehrdad, by dereferencing the iterators it no longer matters if they belong to the same container or not. Unless you think that elements of two containers might have the same pointer address, but I think that's impossible. –  Mark Ransom Jul 26 '12 at 3:25
It matters because I don't think the standard allows you to compare iterators that belong to different containers. –  Mehrdad Jul 26 '12 at 3:31

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