Defined in header
<memory> | ||
---|---|---|
template< class T > class shared_ptr; | (since C++11) |
std::shared_ptr
is a smart pointer that retains shared ownership of an object through a pointer. Several shared_ptr
objects may own the same object. The object is destroyed and its memory deallocated when either of the following happens:
shared_ptr
owning the object is destroyed; shared_ptr
owning the object is assigned another pointer via operator=
or reset()
. The object is destroyed using delete-expression
or a custom deleter that is supplied to shared_ptr
during construction.
A shared_ptr
can share ownership of an object while storing a pointer to another object. This feature can be used to point to member objects while owning the object they belong to. The stored pointer is the one accessed by get()
, the dereference and the comparison operators. The managed pointer is the one passed to the deleter when use count reaches zero.
A shared_ptr
may also own no objects, in which case it is called empty (an empty shared_ptr may have a non-null stored pointer if the aliasing constructor was used to create it).
All specializations of shared_ptr
meet the requirements of CopyConstructible
, CopyAssignable
, and LessThanComparable
and are contextually convertible to bool
.
All member functions (including copy constructor and copy assignment) can be called by multiple threads on different instances of shared_ptr
without additional synchronization even if these instances are copies and share ownership of the same object. If multiple threads of execution access the same shared_ptr
without synchronization and any of those accesses uses a non-const member function of shared_ptr
then a data race will occur; the shared_ptr overloads of atomic functions can be used to prevent the data race.
Member type | Definition | ||||
---|---|---|---|---|---|
element_type |
|
||||
weak_type (since C++17) | std::weak_ptr<T> |
constructs new shared_ptr (public member function) |
|
destructs the owned object if no more shared_ptr s link to it (public member function) |
|
assigns the shared_ptr (public member function) |
|
Modifiers |
|
replaces the managed object (public member function) |
|
swaps the managed objects (public member function) |
|
Observers |
|
returns the stored pointer (public member function) |
|
dereferences the stored pointer (public member function) |
|
(C++17)
| provides indexed access to the stored array (public member function) |
returns the number of shared_ptr objects referring to the same managed object (public member function) |
|
checks whether the managed object is managed only by the current shared_ptr instance (public member function) |
|
checks if there is associated managed object (public member function) |
|
provides owner-based ordering of shared pointers (public member function) |
creates a shared pointer that manages a new object (function template) |
|
creates a shared pointer that manages a new object allocated using an allocator (function template) |
|
applies static_cast , dynamic_cast , const_cast , or reinterpret_cast to the stored pointer (function template) |
|
returns the deleter of specified type, if owned (function template) |
|
compares with another shared_ptr or with nullptr (function template) |
|
outputs the value of the stored pointer to an output stream (function template) |
|
(C++11)
| specializes the std::swap algorithm (function template) |
specializes atomic operations for std::shared_ptr (function template) |
(C++11)
| hash support for std::shared_ptr (class template specialization) |
The ownership of an object can only be shared with another shared_ptr
by copy constructing or copy assigning its value to another shared_ptr
. Constructing a new shared_ptr
using the raw underlying pointer owned by another shared_ptr
leads to undefined behavior.
std::shared_ptr
may be used with an incomplete type T
. However, the constructor from a raw pointer (template<class Y> shared_ptr(Y*)
) and the template<class Y> void reset(Y*)
member function may only be called with a pointer to a complete type (note that std::unique_ptr
may be constructed from a raw pointer to an incomplete type).
In a typical implementation, std::shared_ptr
holds only two pointers:
get()
); The control block is a dynamically-allocated object that holds:
shared_ptr
s that own the managed object; weak_ptr
s that refer to the managed object. When shared_ptr
is created by calling std::make_shared
or std::allocate_shared
, the memory for both the control block and the managed object is created with a single allocation. The managed object is constructed in-place in a data member of the control block. When shared_ptr
is created via one of the shared_ptr
constructors, the managed object and the control block must be allocated separately. In this case, the control block stores a pointer to the managed object.
The pointer held by the shared_ptr
directly is the one returned by get()
, while the pointer/object held by the control block is the one that will be deleted when the number of shared owners reaches zero. These pointers are not necessarily equal.
The destructor of shared_ptr
decrements the number of shared owners of the control block. If that counter reaches zero, the control block calls the destructor of the managed object. The control block does not deallocate itself until the std::weak_ptr
counter reaches zero as well.
In practical implementations, the number of weak pointers may be incremented if there is a shared pointer to the same control block.
To satisfy thread safety requirements, the reference counters are typically incremented using an equivalent of std::atomic::fetch_add
with std::memory_order_relaxed
(decrementing requires stronger ordering to safely destroy the control block).
#include <iostream> #include <memory> #include <thread> #include <chrono> #include <mutex> struct Base { Base() { std::cout << " Base::Base()\n"; } // Note: non-virtual destructor is OK here ~Base() { std::cout << " Base::~Base()\n"; } }; struct Derived: public Base { Derived() { std::cout << " Derived::Derived()\n"; } ~Derived() { std::cout << " Derived::~Derived()\n"; } }; void thr(std::shared_ptr<Base> p) { std::this_thread::sleep_for(std::chrono::seconds(1)); std::shared_ptr<Base> lp = p; // thread-safe, even though the // shared use_count is incremented { static std::mutex io_mutex; std::lock_guard<std::mutex> lk(io_mutex); std::cout << "local pointer in a thread:\n" << " lp.get() = " << lp.get() << ", lp.use_count() = " << lp.use_count() << '\n'; } } int main() { std::shared_ptr<Base> p = std::make_shared<Derived>(); std::cout << "Created a shared Derived (as a pointer to Base)\n" << " p.get() = " << p.get() << ", p.use_count() = " << p.use_count() << '\n'; std::thread t1(thr, p), t2(thr, p), t3(thr, p); p.reset(); // release ownership from main std::cout << "Shared ownership between 3 threads and released\n" << "ownership from main:\n" << " p.get() = " << p.get() << ", p.use_count() = " << p.use_count() << '\n'; t1.join(); t2.join(); t3.join(); std::cout << "All threads completed, the last one deleted Derived\n"; }
Possible output:
Base::Base() Derived::Derived() Created a shared Derived (as a pointer to Base) p.get() = 0xc99028, p.use_count() = 1 Shared ownership between 3 threads and released ownership from main: p.get() = (nil), p.use_count() = 0 local pointer in a thread: lp.get() = 0xc99028, lp.use_count() = 3 local pointer in a thread: lp.get() = 0xc99028, lp.use_count() = 4 local pointer in a thread: lp.get() = 0xc99028, lp.use_count() = 2 Derived::~Derived() Base::~Base() All threads completed, the last one deleted Derived
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