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std::scoped_allocator_adaptor::construct

Defined in header <scoped_allocator>
template < class T, class... Args >
void construct( T* p, Args&&... args );
(1)
template< class T1, class T2, class... Args1, class... Args2 >
void construct( std::pair<T1, T2>* p,
                std::piecewise_construct_t,
                std::tuple<Args1...> x,
                std::tuple<Args2...> y );
(2)
template< class T1, class T2 >
void construct( std::pair<T1, T2>* p );
(3)
template< class T1, class T2, class U, class V >
void construct( std::pair<T1, T2>* p, U&& x, V&& y );
(4)
template< class T1, class T2, class U, class V >
void construct( std::pair<T1, T2>* p, const std::pair<U, V>& xy );
(5)
template< class T1, class T2, class U, class V >
void construct( std::pair<T1, T2>* p, std::pair<U, V>&& xy );
(6)

Constructs an object in allocated, but not initialized storage pointed to by p using OuterAllocator and the provided constructor arguments. If the object is of type that itself uses allocators, or if it is std::pair, passes InnerAllocator down to the constructed object.

First, determines the outermost allocator type OUTERMOST: it is the type that would be returned by calling this->outer_allocator(), and then calling the outer_allocator() member function recursively on the result of this call until reaching the type that has no such member function. That type is the outermost allocator.

Then:

1) If std::uses_allocator<T, inner_allocator_type>::value==false (the type T does not use allocators) and if std::is_constructible<T, Args...>::value==true, then calls.

std::allocator_traits<OUTERMOST>::construct( OUTERMOST(*this),
p,
std::forward<Args>(args)... );

Otherwise, if std::uses_allocator<T, inner_allocator_type>::value==true (the type T uses allocators, e.g. it is a container) and if std::is_constructible<T, std::allocator_arg_t, inner_allocator_type&, Args...>::value==true, then calls.

std::allocator_traits<OUTERMOST>::construct( OUTERMOST(*this),
p,
std::allocator_arg,
inner_allocator(),
std::forward<Args>(args)... );

Otherwise, std::uses_allocator<T, inner_allocator_type>::value==true (the type T uses allocators, e.g. it is a container) and if std::is_constructible<T, Args..., inner_allocator_type&>::value==true, then calls.

std::allocator_traits<OUTERMOST>::construct( OUTERMOST(*this),
p,
std::forward<Args>(args)...,
inner_allocator());

Otherwise, compilation error is issued because although std::uses_allocator<T> claimed that T is allocator-aware, it lacks either form of allocator-accepting constructors.

2) First, if either T1 or T2 is allocator-aware, modifies the tuples x and y to include the appropriate inner allocator, resulting in the two new tuples xprime and yprime, according to the following three rules:

2a) if T1 is not allocator-aware (std::uses_allocator<T1, inner_allocator_type>::value==false, then xprime is x, unmodified. (it is also required that std::is_constructible<T1, Args1...>::value==true).

2b) if T1 is allocator-aware (std::uses_allocator<T1, inner_allocator_type>::value==true), and its constructor takes an allocator tag (std::is_constructible<T1, std::allocator_arg_t, inner_allocator_type&, Args1...>::value==true, then xprime is std::tuple_cat( std::tuple<std::allocator_arg_t, inner_allocator_type&>( std::allocator_arg,
inner_allocator()
), std::move(x))
.

2c) if T1 is allocator-aware (std::uses_allocator<T1, inner_allocator_type>::value==true), and its constructor takes the allocator as the last argument (std::is_constructible<T1, Args1..., inner_allocator_type&>::value==true), then xprime is std::tuple_cat(std::move(x), std::tuple<inner_allocator_type&>(inner_allocator())).

Same rules apply to T2 and the replacement of y with yprime.

Once xprime and yprime are constructed (this also requires that all types in Args1... and Args2... are CopyConstructible), constructs the pair p in allocated storage by calling.

std::allocator_traits<OUTERMOST>::construct( OUTERMOST(*this),
p,
std::piecewise_construct,
std::move(xprime),
std::move(yprime));


3) Equivalent to construct(p, std::piecewise_construct, std::tuple<>(), std::tuple<>()), that is, passes the inner allocator on to the pair's member types if they accept them.

4) Equivalent to.

construct(p, std::piecewise_construct, std::forward_as_tuple(std::forward<U>(x)),
std::forward_as_tuple(std::forward<V>(y)))
.

5) Equivalent to.

construct(p, std::piecewise_construct, std::forward_as_tuple(xy.first),
std::forward_as_tuple(xy.second))
.

6) Equivalent to.

construct(p, std::piecewise_construct, std::forward_as_tuple(std::forward<U>(xy.first)),
std::forward_as_tuple(std::forward<V>(xy.second)))
.

Parameters

p - pointer to allocated, but not initialized storage
args... - the constructor arguments to pass to the constructor of T
x - the constructor arguments to pass to the constructor of T1
y - the constructor arguments to pass to the constructor of T2
xy - the pair whose two members are the constructor arguments for T1 and T2

Return value

(none).

Notes

This function is called (through std::allocator_traits) by any allocator-aware object, such as std::vector, that was given a std::scoped_allocator_adaptor as the allocator to use. Since inner_allocator is itself an instance of std::scoped_allocator_adaptor, this function will also be called when the allocator-aware objects constructed through this function start constructing their own members.

See also

[static]
constructs an object in the allocated storage
(function template)
(deprecated in C++17)
constructs an object in allocated storage
(public member function of std::allocator)

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