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Consider the following simple make_pair class:

template <class X, class Y>
struct Pair
    X x;
    Y y;

Also, we'll make a simple class to show any moves/copies:

struct C
    C(int n_) : n(n_) {};
    C(const C& x) { n = x.n; std::cout << "Copy: " << n << std::endl; }
    C(C&& x)      { n = x.n; std::cout << "Move: " << n << std::endl; }
    int n;

We can then run:

auto z1 = Pair<C, C>{C(1),C(2)};

And there is no output, C is not moved or copied.

However, we have to specify the types in the constructor Pair. Lets say we want to infer these. We could do something like this:

template <class X, class Y>
Pair<X, Y> make_pair(X&& x, Y&& y)
    return Pair<X, Y>{std::forward<X>(x), std::forward<Y>(y)};

And then we can do:

auto z2 = make_pair(C(3),C(4));

But this prints:

Move: 3
Move: 4

Not a problem if C is a heap allocated type, but if a stack allocated type, a move is basically a copy.

But then lets define this macro:

#define MAKE_PAIR(x,y) decltype(make_pair(x,y)){x,y}

Then we can do:

auto z3 = MAKE_PAIR(C(5),C(6));

And this does type deduction AND doesn't need a move. But we need to make a macro, which I feel is a bit messy, and also stops us from using operators to do this sort of thing.

Is there a solution that does the following:

(1) Deduces types (like 2 and 3)
(2) Doesn't require a copy or move (like 1 and 3)
(3) Doesn't require a macro (like 1 and 2)

The best I can get is two out of three, but surely three out of three is possible? I can't imagine C++ would force one to use macros to get the behaviour I was after, as apparently C++ is moving away from macros.

The code is here.

share|improve this question
I can make it happen for copies, not sure about moves. (Note: Your make_pair will create a Pair<T&, U&> if you pass lvalues. ;) As such, no copies.) – Xeo Nov 2 '12 at 1:21
If your stack-based classes are so large that this is a problem, you're doing it wrong. – Puppy Nov 2 '12 at 1:26
@Xeo: Hehe, I was wondering if that was by design or if I should say anything. A little remove_reference or decay may well be in order in that maker function. – Kerrek SB Nov 2 '12 at 1:32
@KerrekSB,Xeo: It wasn't particularly by design, but it's not the main concern. The main issue I'm getting at is that the temporaries should be constructed in place. They are in examples (1) and (3), but not (2). – Clinton Nov 2 '12 at 1:36
When asking my compiler to optimize, while the outputs from the special members are still performed, all references to C, Pair and make_pair are removed anyway. So sure, the copies are not elided in the sense that their side-effects are kept. But the objects are not here anyway. Considering that the side-effects were put here presumably for instrumentation, then I don't really know what the question is about. – Luc Danton Nov 2 '12 at 2:27

I can't imagine C++ would force one to use macros to get the behaviour I was after, as apparently C++ is moving away from macros.

The behavior you're after was never guaranteed by the standard in the first place. Elision is an optimization; it is not required for any implementation. So none of them are guaranteed to do what you want, though obviously some of them at least allow it to be possible.

Forwarding effectively makes elision impossible; there's nothing that can be done about that fact. Perfect forwarding is all about references and reference collapsing; elision is about values initializing value parameters, which it can't know about at the initial call site.

In real-world situations, this should not be an issue. Most of the things that are actually worth eliding are things where copying is expensive. Copying a few ints or floats, especially for a trivial class, will likely not even show up as a blip on a profiler. In the vast majority of cases, objects that are expensive to copy are so because they hold some kind of resource, such as allocated memory. So most types that are expensive to copy can also be moveable, and thus will move cheaply.

In any case, yes, if you want to have the possibility of elision, you cannot use forwarding.

share|improve this answer

In your example, you are still having to specify the types once. If your goal is to avoid having to specify the types more than once, you can do this:

auto z = Pair<C,C>{3,4};

Note that this even works if you have more complex constuctors:

struct C {
  C(int,int) { }
  C(int) { }

auto z = Pair<C,C>{{1,2},3};

and requires no copies.

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