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I have used vector::emplace_back in order to avoid constructing temporal objects while filling a vector. Here you have a simplified version:

class Foo {
public:
    Foo(int i, double d) : i_(i), d_(d) {}
    /* ... */
};

std::vector<Foo> v;
v.reserve(10);
for (int i = 0; i < 10; i++)
    v.emplace_back(1, 1.0);

But I wanted to use std::fill_n instead:

v.reserve(10);
std::fill_n(std::back_inserter(v), 10, Foo(1, 1.0));

In this way, temporal copies will be created, though. I do not know how to use emplace in this situation. I guess I would need something like std::back_emplacer, but I could not find such a thing. Is that part of C++11, but not implemented in GCC yet? If it is not part of C++11, is there any other way to do that?

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3 Answers 3

up vote 7 down vote accepted

It's common to use tuples to ease the pass a variadic number of items (in this case, parameters to forward to emplace_back), with a little technique to unpack the tuple back. As such it is possible to write a back_emplacer utility by requiring the user to make use of the tuple factory functions (one of std::make_tuple, std::tie, std::forward_as_tuple) where it make sense:

#include <type_traits>
#include <tuple>

// Reusable utilites

template<typename T>
using RemoveReference = typename std::remove_reference<T>::type;
template<typename T>
using Bare = typename std::remove_cv<RemoveReference<T>>::type;

template<typename Out, typename In>
using WithValueCategoryOf = typename std::conditional<
    std::is_lvalue_reference<In>::value
    ,  typename std::add_lvalue_reference<Out>::type
    , typename std::conditional<
        std::is_rvalue_reference<Out>::value
        , typename std::add_rvalue_reference<Out>::type
        , Out
    >::type
>::type;

template<int N, typename Tuple>
using TupleElement = WithValueCategoryOf<
    typename std::tuple_element<N, RemoveReference<Tuple>>::type
    , Tuple
>;  

// Utilities to unpack a tuple
template<int... N>
struct indices {
    using next = indices<N..., sizeof...(N)>;
};

template<int N>
struct build_indices {
    using type = typename build_indices<N - 1>::type::next;
};
template<>
struct build_indices<0> {
    using type = indices<>;
};

template<typename Tuple>
constexpr
typename build_indices<std::tuple_size<Bare<Tuple>>::value>::type
make_indices() { return {}; }

template<typename Container>
class back_emplace_iterator {
public:
    explicit back_emplace_iterator(Container& container)
        : container(&container)
    {}  

    template<
        typename Tuple
        // It's important that a member like operator= be constrained
        // in this case the constraint is delegated to emplace,
        // where it can more easily be expressed (by expanding the tuple)   
        , typename = decltype( emplace(std::declval<Tuple>(), make_indices<Tuple>()) )
    >
    back_emplace_iterator& operator=(Tuple&& tuple)
    {
        emplace(*container, std::forward<Tuple>(tuple), make_indices<Tuple>());

        return *this;
    }

    template<
        typename Tuple
        , int... Indices  
        , typename std::enable_if<
            std::is_constructible<
                typename Container::value_type
                , TupleElement<Indices, Tuple>...
            >::value
            , int
        >::type...
    >
    void emplace(Tuple&& tuple, indices<Indices...>)
    {
        using std::get;
        container->emplace_back(get<Indices>(std::forward<Tuple>(tuple))...);
    }

    // Mimic interface of std::back_insert_iterator
    back_emplace_iterator& operator*() { return *this; }
    back_emplace_iterator& operator++() { return *this; }
    back_emplace_iterator operator++(int) { return *this; }

private:
    Container* container;  
};

template<typename Container>
back_emplace_iterator<Container> back_emplacer(Container& c)
{ return back_emplace_iterator<Container> { c }; }

A demonstration of the code is available. In your case you'd want to call std::fill_n(back_emplacer(v), 10, std::forward_as_tuple(1, 1.0)); (std::make_tuple is also acceptable). You'd also want the usual iterator stuff to make the feature complete -- I recommend Boost.Iterators for that.

I must really stress however that such a utility doesn't bring much when used with std::fill_n. In your case it would save the construction of the temporary Foo, in favour of a tuple of references (a tuple of values if you were to use std::make_tuple). I leave it to the reader to find some other algorithm where back_emplacer would be useful.

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1  
This is quite amazing :) As Matthieu and Nicol were pointing out, it would be necessary to construct just one object. So it might not be such a big issue. However, I accepted this answer since it actually provides a working solution. Thanks! –  betabandido Aug 27 '12 at 11:04

You are right that there is no back_emplacer in the standard. You could perfectly write one yourself, but what for ?

When you call emplace_back, you have to provide the arguments for the constructor (any constructor): vec.emplace_back(1, 2) for example. However, you cannot arbitrarily pass tuples of arguments in C++, so the back_emplacer would be limited to unary constructor.

In the case of fill_n, you provide an argument that will be copied, and then both back_inserter and back_emplacer would call the same copy constructor with the same argument.

Note that there is the generate and generate_n algorithms to build new elements. But likewise any temporary copy will probably be elided.

Therefore I think the need for a back_emplacer is rather light, mostly because of the language non-support of multiple return values.

EDIT

If you look at the comments below you will realize that using a combination std::forward_as_tuple and std::is_constructible it could be possible to write a back_emplacer mechanism. Thanks to Luc Danton for the breakthrough.

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@LucDanton: yes, but it is still a single argument constructor (even though that argument is a std::tuple<...>), and thus means that you cannot just pick up any class, you have to adapt it. –  Matthieu M. Aug 26 '12 at 14:23
    
@LucDanton: Ah... interesting. With the std::is_constructible trait I guess you could detect whether to unpack or not, and do the appropriate think. I am not sure the iterator assignment operator is called though, the iterator might get dereferenced first, no ? Anyway, you are right, it is indeed possible. It certainly opens up possibilities! –  Matthieu M. Aug 26 '12 at 14:52
    
@LucDanton: I think it would be great if you wrote an answer putting this altogether. This question could benefit from a comprehensive treatment (rather than a bunch of comments thrown haphazardly), and since you were the one caming up with the idea... ;) –  Matthieu M. Aug 26 '12 at 15:16

There won't be any "temporal copies" made. There will be exactly one temporary, the one you passed to fill_n. And it will be copied into each value.

And even if there was a back_emplacer, what would you call it with? The emplace familiy of functions take constructor parameters; fill_n takes an object to copy into the iterator.

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