std::unique_ptr<T,Deleter>::unique_ptr
members of the primary template, unique_ptr<T> |
||
constexpr unique_ptr() noexcept; constexpr unique_ptr( std::nullptr_t ) noexcept; |
(1) | |
explicit unique_ptr( pointer p ) noexcept; |
(2) | (constexpr since C++23) |
unique_ptr( pointer p, /* see below */ d1 ) noexcept; |
(3) | (constexpr since C++23) |
unique_ptr( pointer p, /* see below */ d2 ) noexcept; |
(4) | (constexpr since C++23) |
unique_ptr( unique_ptr&& u ) noexcept; |
(5) | (constexpr since C++23) |
template< class U, class E > unique_ptr( unique_ptr<U, E>&& u ) noexcept; |
(6) | (constexpr since C++23) |
template< class U > unique_ptr( std::auto_ptr<U>&& u ) noexcept; |
(7) | (removed in C++17) |
members of the specialization for arrays, unique_ptr<T[]> |
||
constexpr unique_ptr() noexcept; constexpr unique_ptr( std::nullptr_t ) noexcept; |
(1) | |
template< class U > explicit unique_ptr( U p ) noexcept; |
(2) | (constexpr since C++23) |
template< class U > unique_ptr( U p, /* see below */ d1 ) noexcept; |
(3) | (constexpr since C++23) |
template< class U > unique_ptr( U p, /* see below */ d2 ) noexcept; |
(4) | (constexpr since C++23) |
unique_ptr( unique_ptr&& u ) noexcept; |
(5) | (constexpr since C++23) |
template< class U, class E > unique_ptr( unique_ptr<U, E>&& u ) noexcept; |
(6) | (constexpr since C++23) |
std::unique_ptr
that owns nothing. Value-initializes the stored pointer and the stored deleter. Requires that Deleter
is DefaultConstructible and that construction does not throw an exception. These overloads participate in overload resolution only if std::is_default_constructible<Deleter>::value is true and Deleter is not a pointer type.std::unique_ptr
which owns p, initializing the stored pointer with p and value-initializing the stored deleter. Requires that Deleter
is DefaultConstructible and that construction does not throw an exception. This overload participates in overload resolution only if std::is_default_constructible<Deleter>::value is true and Deleter is not a pointer type.
This constructor is not selected by class template argument deduction. |
(since C++17) |
std::unique_ptr
object which owns p, initializing the stored pointer with p and initializing a deleter D
as below (depends upon whether D
is a reference type).D
is non-reference type A, then the signatures are:
unique_ptr(pointer p, const A& d) noexcept; |
(1) | (requires that Deleter is nothrow-CopyConstructible) |
unique_ptr(pointer p, A&& d) noexcept; |
(2) | (requires that Deleter is nothrow-MoveConstructible) |
D
is an lvalue-reference type A&, then the signatures are:
unique_ptr(pointer p, A& d) noexcept; |
(1) | |
unique_ptr(pointer p, A&& d) = delete; |
(2) | |
D
is an lvalue-reference type const A&, then the signatures are:
unique_ptr(pointer p, const A& d) noexcept; |
(1) | |
unique_ptr(pointer p, const A&& d) = delete; |
(2) | |
These two constructors are not selected by class template argument deduction. |
(since C++17) |
-
U
is the same type aspointer
, or -
U
is std::nullptr_t, or -
pointer
is the same type aselement_type*
andU
is some pointer typeV*
such thatV(*)[]
is implicitly convertible toelement_type(*)[]
.
unique_ptr
by transferring ownership from u to *this and stores the null pointer in u. This constructor only participates in overload resolution if std::is_move_constructible<Deleter>::value is true. If Deleter
is not a reference type, requires that it is nothrow-MoveConstructible (if Deleter
is a reference, get_deleter()
and u.get_deleter()
after move construction reference the same value).unique_ptr
by transferring ownership from u to *this, where u is constructed with a specified deleter (E
). It depends upon whether E
is a reference type, as following:E
is a reference type, this deleter is copy constructed from u's deleter (requires that this construction does not throw),E
is a non-reference type, this deleter is move constructed from u's deleter (requires that this construction does not throw).pointer
,Deleter
is a reference type and E
is the same type as D
, or Deleter
is not a reference type and E
is implicitly convertible to D
.-
U
is an array type, -
pointer
is the same type aselement_type*
, - unique_ptr<U,E>::pointer is the same type as unique_ptr<U,E>::element_type*,
- unique_ptr<U,E>::element_type(*)[] is convertible to
element_type(*)[]
, - either
Deleter
is a reference type andE
is the same type asDeleter
, orDeleter
is not a reference type andE
is implicitly convertible toDeleter
.
unique_ptr
where the stored pointer is initialized with u.release() and the stored deleter is value-initialized. This constructor only participates in overload resolution if U*
is implicitly convertible to T*
and Deleter
is the same type as std::default_delete<T>.Parameters
p | - | a pointer to an object to manage |
d1,d2 | - | a deleter to use to destroy the object |
u | - | another smart pointer to acquire the ownership from |
Notes
Instead of using the overload (2) together with new, it is often a better idea to use std::make_unique<T>. |
(since C++14) |
std::unique_ptr<Derived> is implicitly convertible to std::unique_ptr<Base> through the overload (6) (because both the managed pointer and std::default_delete are implicitly convertible).
Because the default constructor is constexpr, static unique_ptrs are initialized as part of static non-local initialization, before any dynamic non-local initialization begins. This makes it safe to use a unique_ptr in a constructor of any static object.
There is no class template argument deduction from pointer type because it is impossible to distinguish a pointer obtained from array and non-array forms of |
(since C++17) |
Example
#include <iostream> #include <memory> struct Foo // object to manage { Foo() { std::cout << "Foo ctor\n"; } Foo(const Foo&) { std::cout << "Foo copy ctor\n"; } Foo(Foo&&) { std::cout << "Foo move ctor\n"; } ~Foo() { std::cout << "~Foo dtor\n"; } }; struct D // deleter { D() {}; D(const D&) { std::cout << "D copy ctor\n"; } D(D&) { std::cout << "D non-const copy ctor\n"; } D(D&&) { std::cout << "D move ctor \n"; } void operator()(Foo* p) const { std::cout << "D is deleting a Foo\n"; delete p; }; }; int main() { std::cout << "Example constructor(1)...\n"; std::unique_ptr<Foo> up1; // up1 is empty std::unique_ptr<Foo> up1b(nullptr); // up1b is empty std::cout << "Example constructor(2)...\n"; { std::unique_ptr<Foo> up2(new Foo); //up2 now owns a Foo } // Foo deleted std::cout << "Example constructor(3)...\n"; D d; { // deleter type is not a reference std::unique_ptr<Foo, D> up3(new Foo, d); // deleter copied } { // deleter type is a reference std::unique_ptr<Foo, D&> up3b(new Foo, d); // up3b holds a reference to d } std::cout << "Example constructor(4)...\n"; { // deleter is not a reference std::unique_ptr<Foo, D> up4(new Foo, D()); // deleter moved } std::cout << "Example constructor(5)...\n"; { std::unique_ptr<Foo> up5a(new Foo); std::unique_ptr<Foo> up5b(std::move(up5a)); // ownership transfer } std::cout << "Example constructor(6)...\n"; { std::unique_ptr<Foo, D> up6a(new Foo, d); // D is copied std::unique_ptr<Foo, D> up6b(std::move(up6a)); // D is moved std::unique_ptr<Foo, D&> up6c(new Foo, d); // D is a reference std::unique_ptr<Foo, D> up6d(std::move(up6c)); // D is copied } #if (__cplusplus < 201703L) std::cout << "Example constructor(7)...\n"; { std::auto_ptr<Foo> up7a(new Foo); std::unique_ptr<Foo> up7b(std::move(up7a)); // ownership transfer } #endif std::cout << "Example array constructor...\n"; { std::unique_ptr<Foo[]> up(new Foo[3]); } // three Foo objects deleted }
Output:
Example constructor(1)... Example constructor(2)... Foo ctor ~Foo dtor Example constructor(3)... Foo ctor D copy ctor D is deleting a Foo ~Foo dtor Foo ctor D is deleting a Foo ~Foo dtor Example constructor(4)... Foo ctor D move ctor D is deleting a Foo ~Foo dtor Example constructor(5)... Foo ctor ~Foo dtor Example constructor(6)... Foo ctor D copy ctor D move ctor Foo ctor D non-const copy ctor D is deleting a Foo ~Foo dtor D is deleting a Foo ~Foo dtor Example constructor(7)... Foo ctor ~Foo dtor Example array constructor... Foo ctor Foo ctor Foo ctor ~Foo dtor ~Foo dtor ~Foo dtor
Defect reports
The following behavior-changing defect reports were applied retroactively to previously published C++ standards.
DR | Applied to | Behavior as published | Correct behavior |
---|---|---|---|
LWG 2118 | C++11 | Constructors of unique_ptr<T[]> rejected qualification conversions.
|
Accept. |
LWG 2520 | C++11 | unique_ptr<T[]> was accidentally made non-constructible from nullptr_t .
|
Made constructible. |
LWG 2801 | C++11 | The default constructor was not constrained. | Constrained. |
LWG 2899 | C++11 | The move constructor was not constrained. | Constrained. |
LWG 2905 | C++11 | Constraint on the constructor from a pointer and a deleter was wrong. | Corrected. |
LWG 2944 | C++11 | Some preconditions were accidentally dropped by LWG 2905 | Restored. |