Defined in header <memory> | ||
---|---|---|
template< class T, class... Args > shared_ptr<T> make_shared( Args&&... args ); | (1) | (since C++11) (T is not array) |
template< class T > shared_ptr<T> make_shared( std::size_t N ); | (2) | (since C++20) (T is U[]) |
template< class T > shared_ptr<T> make_shared(); | (3) | (since C++20) (T is U[N]) |
template< class T > shared_ptr<T> make_shared( std::size_t N, const std::remove_extent_t<T>& u ); | (4) | (since C++20) (T is U[]) |
template< class T > shared_ptr<T> make_shared( const std::remove_extent_t<T>& u ); | (5) | (since C++20) (T is U[N]) |
template< class T > shared_ptr<T> make_shared_for_overwrite(); | (6) | (since C++20) (T is not U[]) |
template< class T > shared_ptr<T> make_shared_for_overwrite( std::size_t N ); | (7) | (since C++20) (T is U[]) |
T
and wraps it in a std::shared_ptr
using args
as the parameter list for the constructor of T
. The object is constructed as if by the expression ::new (pv) T(std::forward<Args>(args)...)
, where pv
is an internal void*
pointer to storage suitable to hold an object of type T
. The storage is typically larger than sizeof(T)
in order to use one allocation for both the control block of the shared pointer and the T
object. The std::shared_ptr
constructor called by this function enables shared_from_this
with a pointer to the newly constructed object of type T
. This overload participates in overload resolution only if T is not an array type. | (since C++20) |
std::remove_all_extents_t<T>
are value-initialized as if by placement-new expression ::new(pv) std::remove_all_extents_t<T>()
. The overload (2) creates an array of size N
along the first dimension. The array elements are initialized in ascending order of their addresses, and when their lifetime ends are destroyed in the reverse order of their original construction.u
. If U
is not an array type, then this is performed as if by the same placement-new expression as in (1); otherwise, this is performed as if by initializing every non-array element of the (possibly multidimensional) array with the corresponding element from u
with the same placement-new expression as in (1). The overload (4) creates an array of size N
along the first dimension. The array elements are initialized in ascending order of their addresses, and when their lifetime ends are destroyed in the reverse order of their original construction.T
is not an array type and (3) if T
is U[N]
, except that the created object is default-initialized.In each case, the object (or individual elements if T
is an array type) (since C++20) will be destroyed by p->~X()
, where p
is a pointer to the object and X
is its type.
args | - | list of arguments with which an instance of T will be constructed |
N | - | array size to use |
u | - | the initial value to initialize every element of the array |
std::shared_ptr
of an instance of type T
.
May throw std::bad_alloc
or any exception thrown by the constructor of T
. If an exception is thrown, the functions have no effect. If an exception is thrown during the construction of the array, already-initialized elements are destroyed in reverse order. (since C++20).
This function may be used as an alternative to std::shared_ptr<T>(new T(args...))
. The trade-offs are:
std::shared_ptr<T>(new T(args...))
performs at least two allocations (one for the object T
and one for the control block of the shared pointer), while std::make_shared<T>
typically performs only one allocation (the standard recommends, but does not require this; all known implementations do this). std::weak_ptr
references the control block created by std::make_shared
after the lifetime of all shared owners ended, the memory occupied by T
persists until all weak owners get destroyed as well, which may be undesirable if sizeof(T)
is large. std::shared_ptr<T>(new T(args...))
may call a non-public constructor of T
if executed in context where it is accessible, while std::make_shared
requires public access to the selected constructor. std::shared_ptr
constructors, std::make_shared
does not allow a custom deleter. std::make_shared
uses ::new
, so if any special behavior has been set up using a class-specific operator new
, it will differ from std::shared_ptr<T>(new T(args...))
.
| (until C++20) |
| (until C++17) |
A constructor enables shared_from_this
with a pointer ptr
of type U*
means that it determines if U
has an unambiguous and accessible (since C++17) base class that is a specialization of std::enable_shared_from_this
, and if so, the constructor evaluates the statement:
if (ptr != nullptr && ptr->weak_this.expired()) ptr->weak_this = std::shared_ptr<std::remove_cv_t<U>>( *this, const_cast<std::remove_cv_t<U>*>(ptr));
Where weak_this
is the hidden mutable std::weak_ptr
member of std::enable_shared_from_this
. The assignment to the weak_this
member is not atomic and conflicts with any potentially concurrent access to the same object. This ensures that future calls to shared_from_this()
would share ownership with the std::shared_ptr
created by this raw pointer constructor.
The test ptr->weak_this.expired()
in the exposition code above makes sure that weak_this
is not reassigned if it already indicates an owner. This test is required as of C++17.
Feature-test macro | Value | Std | Comment |
---|---|---|---|
__cpp_lib_shared_ptr_arrays | 201707L | (C++20) | Array support of std::make_shared ; overloads (2-5) |
__cpp_lib_smart_ptr_for_overwrite | 202002L | (C++20) | Smart pointer creation with default initialization (std::allocate_shared_for_overwrite , std::make_shared_for_overwrite , std::make_unique_for_overwrite ); overloads (6,7) |
#include <iostream> #include <memory> #include <type_traits> #include <vector> struct C { // constructors needed (until C++20) C(int i) : i(i) {} C(int i, float f) : i(i), f(f) {} int i; float f{}; }; int main() { // using `auto` for the type of `sp1` auto sp1 = std::make_shared<C>(1); // overload (1) static_assert(std::is_same_v<decltype(sp1), std::shared_ptr<C>>); std::cout << "sp1->{ i:" << sp1->i << ", f:" << sp1->f << " }\n"; // being explicit with the type of `sp2` std::shared_ptr<C> sp2 = std::make_shared<C>(2, 3.0f); // overload (1) static_assert(std::is_same_v<decltype(sp2), std::shared_ptr<C>>); static_assert(std::is_same_v<decltype(sp1), decltype(sp2)>); std::cout << "sp2->{ i:" << sp2->i << ", f:" << sp2->f << " }\n"; // shared_ptr to a value-initialized float[64]; overload (2): std::shared_ptr<float[]> sp3 = std::make_shared<float[]>(64); // shared_ptr to a value-initialized long[5][3][4]; overload (2): std::shared_ptr<long[][3][4]> sp4 = std::make_shared<long[][3][4]>(5); // shared_ptr to a value-initialized short[128]; overload (3): std::shared_ptr<short[128]> sp5 = std::make_shared<short[128]>(); // shared_ptr to a value-initialized int[7][6][5]; overload (3): std::shared_ptr<int[7][6][5]> sp6 = std::make_shared<int[7][6][5]>(); // shared_ptr to a double[256], where each element is 2.0; overload (4): std::shared_ptr<double[]> sp7 = std::make_shared<double[]>(256, 2.0); // shared_ptr to a double[7][2], where each double[2] // element is {3.0, 4.0}; overload (4): std::shared_ptr<double[][2]> sp8 = std::make_shared<double[][2]>(7, {3.0, 4.0}); // shared_ptr to a vector<int>[4], where each vector // has contents {5, 6}; overload (4): std::shared_ptr<std::vector<int>[]> sp9 = std::make_shared<std::vector<int>[]>(4, {5, 6}); // shared_ptr to a float[512], where each element is 1.0; overload (5): std::shared_ptr<float[512]> spA = std::make_shared<float[512]>(1.0); // shared_ptr to a double[6][2], where each double[2] element // is {1.0, 2.0}; overload (5): std::shared_ptr<double[6][2]> spB = std::make_shared<double[6][2]>({1.0, 2.0}); // shared_ptr to a vector<int>[4], where each vector // has contents {5, 6}; overload (5): std::shared_ptr<std::vector<int>[4]> spC = std::make_shared<std::vector<int>[4]>({5, 6}); }
Output:
sp1->{ i:1, f:0 } sp2->{ i:2, f:3 }
constructs new shared_ptr (public member function) |
|
(C++20) | creates a shared pointer that manages a new object allocated using an allocator (function template) |
(C++11) | allows an object to create a shared_ptr referring to itself (class template) |
(C++14)(C++20) | creates a unique pointer that manages a new object (function template) |
allocation functions (function) |
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