std::shared_ptr::shared_ptr
constexpr shared_ptr();
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(1) | |
template< class Y >
explicit shared_ptr( Y* ptr ); |
(2) | |
template< class Y, class Deleter >
shared_ptr( Y* ptr, Deleter d ); |
(3) | |
template< class Y, class Deleter, class Alloc >
shared_ptr( Y* ptr, Deleter d, Alloc alloc ); |
(4) | |
constexpr shared_ptr( std::nullptr_t );
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(5) | |
template< class Deleter >
shared_ptr( std::nullptr_t, Deleter d ); |
(6) | |
template< class Deleter, class Alloc >
shared_ptr( std::nullptr_t, Deleter d, Alloc alloc ); |
(7) | |
template< class Y >
shared_ptr( const shared_ptr<Y>& r, T *ptr ); |
(8) | |
shared_ptr( const shared_ptr& r );
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(9) | |
template< class Y >
shared_ptr( const shared_ptr<Y>& r ); |
(9) | |
shared_ptr( shared_ptr&& r );
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(10) | |
template< class Y >
shared_ptr( shared_ptr<Y>&& r ); |
(10) | |
template< class Y >
explicit shared_ptr( const std::weak_ptr<Y>& r ); |
(11) | |
template< class Y >
shared_ptr( std::auto_ptr<Y>&& r ); |
(12) | |
template< class Y, class Deleter >
shared_ptr( std::unique_ptr<Y,Deleter>&& r ); |
(13) | |
Constructs new shared_ptr
from a variety of pointer types that refer to an object to manage.
An optional deleter d
can be supplied that is later used to destroy the object when no shared_ptr
objects own it. By default, a delete-expression for type Y
is used as the deleter.
shared_ptr
with no managed object, i.e. empty shared_ptr
shared_ptr
with ptr
as the pointer to the managed object. Y
must be a complete type and ptr
must be convertible to T*
. Additionally:d
as the deleter. Deleter
must be callable for the type T
, i.e. d(ptr) must be well formed, have well-defined behavior and not throw any exceptions. Deleter
must be CopyConstructible
. The copy constructor and the destructor must not throw exceptions.alloc
for allocation of data for internal use. Alloc
must be a Allocator
. The copy constructor and destructor must not throw exceptions.shared_ptr
with no managed object, i.e. empty shared_ptr
.shared_ptr
which shares ownership information with r
, but holds an unrelated and unmanaged pointer ptr
. Even if this shared_ptr
is the last of the group to go out of scope, it will call the destructor for the object originally managed by r
. However, calling get()
on this will always return a copy of ptr
. It is the responsibility of the programmer to make sure that this ptr
remains valid as long as this shared_ptr exists, such as in the typical use cases where ptr
is a member of the object managed by r
or is an alias (e.g., downcast) of r.get()
shared_ptr
which shares ownership of the object managed by r
. If r
manages no object, *this
manages no object too. The templated overload doesn't participate in the overload resolution if Y*
is not implicitly convertible to T*
.shared_ptr
from r
. After the construction, *this contains a copy of the previous state of r
, r
is empty. The templated overload doesn't participate in the overload resolution if Y*
is not implicitly convertible to T*
.shared_ptr
which shares ownership of the object managed by r
. Y*
must be convertible to T*
. Note that r.lock() may be used for the same purpose: the difference is that this constructor throws an exception if the argument is empty, while std::weak_ptr<T>::lock() constructs an empty std::shared_ptr
in that case.shared_ptr
that stores and owns the object formerly owned by r
. Y*
must be convertible to T*
. After construction, r
is empty.shared_ptr
which manages the object currently managed by r
. The deleter associated to r
is stored for future deletion of the managed object. r
manages no object after the call. Y*
must be convertible to T*
.
Contents |
[edit] Notes
When constructing a shared_ptr
from a raw pointer to an object of a type derived from std::enable_shared_from_this, the constructors of shared_ptr
update the private weak_ptr
member of the std::enable_shared_from_this base so that future calls to shared_from_this() would share ownership with the shared_ptr
created by this raw pointer constructor.
Constructing a shared_ptr
using the raw pointer overload for an object that is already managed by a shared_ptr
leads to undefined behavior, even if the object is of a type derived from std::enable_shared_from_this (in other words, raw pointer overloads assume ownership of the pointed-to object).
[edit] Parameters
ptr | - | a pointer to an object to manage |
d | - | a deleter to use to destroy the object |
alloc | - | an allocator to use for allocations of data for internal use |
r | - | another smart pointer to share the ownership to or acquire the ownership from |
[edit] Exceptions
[edit] Example
#include <memory> #include <iostream> struct Foo { Foo() { std::cout << "Foo...\n"; } ~Foo() { std::cout << "~Foo...\n"; } }; struct D { void operator()(Foo* p) const { std::cout << "Call delete for Foo object...\n"; delete p; } }; int main() { { std::cout << "constructor with no managed object\n"; std::shared_ptr<Foo> sh1; } { std::cout << "constructor with object\n"; std::shared_ptr<Foo> sh2(new Foo); std::shared_ptr<Foo> sh3(sh2); std::cout << sh2.use_count() << '\n'; std::cout << sh3.use_count() << '\n'; } { std::cout << "constructor with object and deleter\n"; std::shared_ptr<Foo> sh4(new Foo, D()); } }
Output:
constructor with no managed object constructor with object Foo... 2 2 ~Foo... constructor with object and deleter Foo... Call delete for Foo object... ~Foo...
[edit] See also
creates a shared pointer that manages a new object (function template) |
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creates a shared pointer that manages a new object allocated using an allocator (function template) |