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The standard templates std::pair and std::array are special cases of std::tuple, and it stands to reason that they should have a very similar set of capabilities.

However, uniquely among the three, std::pair allows for piecewise construction. That is, if the types T1 and T2 can be constructed from a set of arguments a1, a2, ... and b1, b2, ..., then morally speaking we can make a pair

"pair<T1, T2> p(a1, a2, ..., b1, b2, ...)"

directly. Practically, this is spelt out as something like this:

std::pair<T1, T2> p(std::piecewise_construct,
                    std::forward_as_tuple(a1, a2, ...),
                    std::forward_as_tuple(b1, b2, ...));

Question: Why doesn't the same piecewise constructibility exist for arrays and tuples? Is there a profound reason, or is this a plain omission? For example, it would be nice to have:

std::tuple<T1, T2, T3> t(std::piecewise_construct,
                         std::forward_as_tuple(a1, a2, ...),
                         std::forward_as_tuple(b1, b2, ...),
                         std::forward_as_tuple(c1, c2, ...));

Is there a reason this cannot be done? [Edit: Or am I misunderstanding the purpose of piecewise construction entirely?]

(I do really have a situation in which I would like to initialize a vector of tuples with a defaulted element value which I would prefer to construct directly from the arguments, without spelling out each tuple element type again.)

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  • 2
    It's there in N3059 and it is gone again in N3140. Now, if a human could just find out which report was actually integrated, I would know what happened to it...
    – pmr
    Aug 7, 2012 at 13:15
  • So just so I'm clear, you have a vector of tuples of types with multi-argument constructors?
    – Mark B
    Aug 7, 2012 at 13:16
  • 1
    @MarkB: Not quite. I have a single tuple type, and I want to construct such a tuple from a the arguments of the constructors of the constituent types directly, without intermediate copy-initialization. This is part of the general idiom-shift from C++03 to C++11 which prefers direct-initialization over copy-initialization whenever possible.
    – Kerrek SB
    Aug 7, 2012 at 13:24
  • 1
    in what sense is std::array a special case of std::tuple? does std::tuple have contiguous memory constraints? Aug 7, 2012 at 13:29
  • @rhalbersma std::array supports the "tuple-like access" interface but there the similarity ends. There is also no piecewise construction there, nor can there be as it's an aggregate and can't have explicit constructors. Aug 7, 2012 at 13:31

3 Answers 3

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Question: Why doesn't the same piecewise constructibility exist for arrays and tuples?

My recollection is that piecewise construction was added to std::pair for one reason only: to support uses-allocator construction of the pair elements, i.e. to allow an allocator to be provided and conditionally passed to the elements if they support construction with an allocator (see [allocator.uses] in the standard).

At one point during the C++0x process std::pair had twice as many constructors as it does now, with every constructor having a corresponding "allocator-extended" version taking a std::allocator_arg_t and an allocator argument e.g.

template<class T, class U>
  struct pair {
    pair();
    pair(allocator_arg_t, const Alloc&);
    template<class TT, class UU>
      pair(TT&&, UU&&);
    template<class Alloc, class TT, class UU>
      pair(allocator_arg_t, const Alloc&, TT&&, UU&&);
    // etc.

There was something of a running joke (haha, only serious) about the insane complexity of std::pair. The support for passing allocators to the elements was removed from std::pair and moved into std::scoped_allocator_adaptor, which is responsible for detecting whether the elements should be constructed with an allocator (see the construct overloads taking a pointer to std::pair in [allocator.adaptor.members]).

A nice consequence of the piecewise construction is that you can do "emplace" style initialization of pair elements, allowing pairs of non-movable, non-copyable types, but as far as I know that was not the goal of the design.

So the reason tuple doesn't support it is that the feature was invented to simplify pair which had ballooned from a very simple type in C++03 to a laughing stock in C++0x, but doing the same for tuple was not considered as important (it was new for C++11 anyway). Also, extending scoped_allocator_adaptor to handle tuples of arbitrary numbers of elements would have made that adaptor much more complicated.

As for std::array, that's an aggregate type (because reasons) so adding a constructor taking piecewise_construct_t is not possible without making it a non-aggregate.

1
  • I would very much need piecewise construction for tuples! Its useful. Nov 17, 2016 at 15:58
13

I'm not sure why it's not there. Previously, I thought that the implementation wouldn't be possible, given the current varadic template syntax, but I realized that it can be done if it's broken into pieces.

If they had defined an interface like this:

template<typename... T>
tuple(piecewise_construct, T&&... t);

And made it a requirement that the arguments are something that you can use std::get<N> to access the arguments (basically, tuples, pairs, arrays). There would have to be extra checks to verify there isn't a mismatch between the number of arguments given and the number of elements in the tuple.

Edit: This problem has been bothering me since I read it. And I've created the following class, it is derived from std::tuple, and has no data members, so you can assign it to the tuple and the slicing is harmless. The current version requires that the elements be moveable or copyable, as it creates a temporary and then inserts that into the tuple. If you were a tuple implementer, it should be possible to eliminate even that move.

namespace detail
{
template<int ... N>
struct index {
    typedef index<N..., sizeof...(N)> next;
};
template<int N>
struct build_index {
    typedef typename build_index<N - 1>::type::next type;
};

template<>
struct build_index<0> {
    typedef index<> type;
};

template<typename T>
struct tuple_index {
    typedef typename build_index<
            std::tuple_size<typename std::remove_reference<T>::type>::value>::type type;

};
}
template<typename ... Elements>
class piecewise_tuple: public std::tuple<Elements...>
{
    typedef std::tuple<Elements...> base_type;

    template<int Index, typename ... Args, int ... N>
    static typename std::tuple_element<Index, base_type>::type 
    construct(std::tuple<Args...>&& args, detail::index<N...>)
    {
        typedef typename std::tuple_element<Index, base_type>::type result_type;
        return result_type(std::get<N>(std::move(args))...);
    }

    template<int ...N, typename ArgTuple>
    piecewise_tuple(detail::index<N...>, ArgTuple&& element_args)
    : base_type( construct<N>( std::get<N>(std::forward<ArgTuple>(element_args)),
                 typename detail::tuple_index< typename std::tuple_element<N, typename std::remove_reference<ArgTuple>::type >::type >::type() )...)
    {

    }

public:

    piecewise_tuple() = default;

    // For non-piecewise constructors, forward them
    template<typename... Args>
    piecewise_tuple(Args&&... args) : base_type(std::forward<Args>(args)...) {}


    template<typename... T>
    piecewise_tuple(std::piecewise_construct_t, T&&... args) :
    piecewise_tuple(typename detail::tuple_index<base_type>::type(),    
                    std::forward_as_tuple(std::forward<T>(args)...))
    {

    }


};

// Usage example
int main()
{
   int i = 5;
   std::unique_ptr<int> up(new int(0));

   piecewise_tuple<std::pair<int, int>, double, std::unique_ptr<int>, int& >
   p(std::piecewise_construct,
    std::forward_as_tuple(1,2),
    std::forward_as_tuple(4.3),
    std::forward_as_tuple(std::move(up)),
    std::forward_as_tuple(i));
   return 0;
}
8
  • +1 Although I don't quite agree on the array part, the main point (why is there no piecewise constructor for tuple) is good. On the std::array case, a make_array could be provided without adding constructors to std::array, and the implementation would actually be simple. Although I don't think it would provide much value. Aug 7, 2012 at 14:19
  • 1
    I don't see this as a problem: template<class... Tuples> tuple(piecewise_construct_t, Tuples&&...). You could possibly add a trait that checks if all Tuples are really of type std::tuple.
    – Xeo
    Aug 7, 2012 at 14:24
  • @Xeo: Hrm... you're right, and you could use a static_assert to verify the length of the arguments. And you wouldn't even have to use only std::tuple (though that's the most likely use).
    – Dave S
    Aug 7, 2012 at 14:27
  • One other solution would be to allow an implementation-defined limit to the number of arguments separate from the usual pack length limit. Solve the double-variadic problem the same way the single-variadic problem was solved in C++03. Aug 7, 2012 at 15:01
  • 1
    For the record one of the selling points of std::piecewise_construct is that it allows in-place construction of non-movable types (when it takes more than one argument for such a type). The big catch however is that there's only one way to implement piecewise construction, via delegating constructors -- which makes it very intrusive. Piecewise constructors must be in std::tuple to get the real boon.
    – Luc Danton
    Aug 7, 2012 at 17:38
1

Here is my implementation of tuple piecewise (it also allow to omit values with omit "keyword"). Zero overhead (no copy/move - direct construction):

http://coliru.stacked-crooked.com/a/6b3f9a5f843362e3

#include <tuple>
#include <utility>
#include <typeinfo>


struct Omit{} omit;


template <class Field, class ...Fields>
struct TupleHolder{
    using fieldT = Field;
    using nextT = TupleHolder<Fields...>;

    Field field;
    TupleHolder<Fields...> next;

    TupleHolder(){}

    template <class ...ValuesRef>
    TupleHolder(Omit, ValuesRef&& ... values)
            : next( std::forward<ValuesRef>(values)... )
    {}

    template <std::size_t ...ids, class FieldValue, class ...ValuesRef>
    TupleHolder(std::index_sequence<ids...>, FieldValue&& field, ValuesRef&& ... values)
            :
            field( std::get<ids>(std::forward<FieldValue>(field))... ),
            next( std::forward<ValuesRef>(values)... )

    {};


    template <class FieldValue, class ...ValuesRef>
    TupleHolder(FieldValue&& field, ValuesRef&& ... values)
            : TupleHolder(
            std::make_index_sequence<
                    std::tuple_size< std::decay_t<FieldValue> >::value
            >(),
            std::forward<FieldValue>(field),
            std::forward<ValuesRef>(values)...
    )
    {}

};


template <class Field>
struct TupleHolder<Field>{
    using fieldT = Field;
    Field field;    // actually last

    TupleHolder(){}
    TupleHolder(Omit){}

    template <std::size_t ...ids, class FieldValue>
    TupleHolder(std::index_sequence<ids...>, FieldValue&& field)
            :
            field( std::get<ids>(std::forward<FieldValue>(field))... )
    {}


    template <class FieldValue>
    TupleHolder(FieldValue&& field)
            : TupleHolder(
            std::make_index_sequence<
                    std::tuple_size< std::decay_t<FieldValue> >::value
            >(),
            std::forward<FieldValue>(field)
    )
    {}
};



template <int index, int target_index, class T>
struct GetLoop{
    using type = typename T::nextT;

    constexpr static decltype(auto) get(T& data) noexcept{
        return GetLoop<index+1, target_index, typename T::nextT>::get(
                data.next
        );
    }

    constexpr static decltype(auto) get(const T& data) noexcept{
        return GetLoop<index+1, target_index, typename T::nextT>::get(
                data.next
        );
    }


    constexpr static decltype(auto) get(T&& data) noexcept{
        return GetLoop<index+1, target_index, typename T::nextT>::get(
                std::forward<type>(data.next)
        );
    }
};

template <int target_index, class T>
struct GetLoop<target_index, target_index, T>{
    using type = typename T::fieldT;

    constexpr static type& get(T& data) noexcept{
        return data.field;
    }

    constexpr static const type& get(const T& data) noexcept{
        return data.field;
    }

    constexpr static type&& get(T&& data) noexcept{
        return std::forward<type>(data.field);
    }
};


// ----------------------------------------------------------------------------------
//                          F R O N T E N D
// ----------------------------------------------------------------------------------

template<class ...FieldTypes>
struct TuplePiecewise{
    using fieldsT = TupleHolder<FieldTypes...>;
    TupleHolder<FieldTypes...> data;

    TuplePiecewise(){}

   // allow copy constructor
   TuplePiecewise(TuplePiecewise& other)
            : TuplePiecewise(static_cast<const TuplePiecewise&>(other)) {}


    template <class ...ValuesRef>
    explicit constexpr TuplePiecewise(ValuesRef&& ... values) noexcept
            : data( std::forward<ValuesRef>(values)... ){}

    TuplePiecewise( const TuplePiecewise& other ) = default;
    TuplePiecewise( TuplePiecewise&& other ) = default;


    static constexpr const std::size_t size = sizeof...(FieldTypes);
};


template<int index, class ...FieldTypes>
constexpr decltype(auto) get(TuplePiecewise<FieldTypes...> &&list) noexcept {
    return GetLoop<0, index, typename TuplePiecewise<FieldTypes...>::fieldsT >::get(  std::move(list.data) );
}

template<int index, class ...FieldTypes>
constexpr decltype(auto) get(TuplePiecewise<FieldTypes...> &list) noexcept {
    return GetLoop<0, index, typename TuplePiecewise<FieldTypes...>::fieldsT >::get(  list.data );
}

template<int index, class ...FieldTypes>
constexpr decltype(auto) get(const TuplePiecewise<FieldTypes...> &list) noexcept {
    return GetLoop<0, index, typename TuplePiecewise<FieldTypes...>::fieldsT >::get(  list.data );
}

Usage:

TuplePiecewise< CopyTest, int&, string, int >
list (forward_as_tuple(45,63), forward_as_tuple(i), forward_as_tuple("hghhh"), omit );
decltype(auto) o = get<2>(list);
cout << o;

Tuple inside tuple (zero overhead):

TuplePiecewise< string, TuplePiecewise<int,int> > list4(forward_as_tuple("RRR"), forward_as_tuple(forward_as_tuple(10), forward_as_tuple(20)));

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