std::atomic_...<std::shared_ptr>
template< class T > bool atomic_is_lock_free( const std::shared_ptr<T>* p ); | (1) | (since C++11) (deprecated in C++20) |
template< class T > std::shared_ptr<T> atomic_load( const std::shared_ptr<T>* p ); | (2) | (since C++11) (deprecated in C++20) |
template< class T >
std::shared_ptr<T> atomic_load_explicit( const std::shared_ptr<T>* p,
std::memory_order mo );
| (3) | (since C++11) (deprecated in C++20) |
template< class T >
void atomic_store( std::shared_ptr<T>* p,
std::shared_ptr<T> r );
| (4) | (since C++11) (deprecated in C++20) |
template< class T >
void atomic_store_explicit( std::shared_ptr<T>* p,
std::shared_ptr<T> r,
std::memory_order mo);
| (5) | (since C++11) (deprecated in C++20) |
template< class T >
std::shared_ptr<T> atomic_exchange( std::shared_ptr<T>* p,
std::shared_ptr<T> r);
| (6) | (since C++11) (deprecated in C++20) |
template<class T>
std::shared_ptr<T> atomic_exchange_explicit( std::shared_ptr<T>* p,
std::shared_ptr<T> r,
std::memory_order mo);
| (7) | (since C++11) (deprecated in C++20) |
template< class T >
bool atomic_compare_exchange_weak( std::shared_ptr<T>* p,
std::shared_ptr<T>* expected,
std::shared_ptr<T> desired);
| (8) | (since C++11) (deprecated in C++20) |
template<class T>
bool atomic_compare_exchange_strong( std::shared_ptr<T>* p,
std::shared_ptr<T>* expected,
std::shared_ptr<T> desired);
| (9) | (since C++11) (deprecated in C++20) |
template< class T >
bool atomic_compare_exchange_strong_explicit( std::shared_ptr<T>* p,
std::shared_ptr<T>* expected,
std::shared_ptr<T> desired,
std::memory_order success,
std::memory_order failure);
| (10) | (since C++11) (deprecated in C++20) |
template< class T >
bool atomic_compare_exchange_weak_explicit( std::shared_ptr<T>* p,
std::shared_ptr<T>* expected,
std::shared_ptr<T> desired,
std::memory_order success,
std::memory_order failure);
| (11) | (since C++11) (deprecated in C++20) |
If multiple threads of execution access the same std::shared_ptr object without synchronization and any of those accesses uses a non-const member function of shared_ptr then a data race will occur unless all such access is performed through these functions, which are overloads of the corresponding atomic access functions (std::atomic_load, std::atomic_store, etc.).
Note that the control block of a shared_ptr is thread-safe: different std::shared_ptr objects can be accessed using mutable operations, such as operator= or reset, simultaneously by multiple threads, even when these instances are copies, and share the same control block internally.
p is lock-free.atomic_load_explicit(p, std::memory_order_seq_cst)
p. As with the non-specialized std::atomic_load_explicit, mo cannot be std::memory_order_release or std::memory_order_acq_rel
atomic_store_explicit(p, r, memory_order_seq_cst)
r in the shared pointer pointed-to by p atomically, effectively executing p->swap(r). As with the non-specialized std::atomic_store_explicit, mo cannot be std::memory_order_acquire or std::memory_order_acq_rel.atomic_exchange_explicit(p, r, memory_order_seq_cst)
r in the shared pointer pointed to by p and returns the value formerly pointed-to by p, atomically. Effectively executes p->swap(r) and returns a copy of r after the swap.atomic_compare_exchange_weak_explicit(p, expected, desired, std::memory_order_seq_cst, std::memory_order_seq_cst)
atomic_compare_exchange_strong_explicit(p, expected, desired, std::memory_order_seq_cst, std::memory_order_seq_cst)
p and expected. If they are equivalent (store the same pointer value, and either share ownership of the same object or are both empty), assigns desired into *p using the memory ordering constraints specified by success and returns true. If they are not equivalent, assigns *p into *expected using the memory ordering constraints specified by failure and returns false.All these functions invoke undefined behavior if p is a null pointer.
Parameters
| p, expected | - | a pointer to a std::shared_ptr |
| r, desired | - | a std::shared_ptr |
| mo, success, failure | - | memory ordering selectors of type std::memory_order |
Exceptions
These functions do not throw exceptions.
Return value
true if atomic access is implemented using lock-free instructionstrue if the shared pointers were equivalent and the exchange was performed, false otherwise.Notes
These functions are typically implemented using mutexes, stored in a global hash table where the pointer value is used as the key.
To avoid data races, once a shared pointer is passed to any of these functions, it cannot be accessed non-atomically. In particular, you cannot dereference such a shared_ptr without first atomically loading it into another shared_ptr object, and then dereferencing through the second object.
The Concurrency TS offers atomic smart pointer classes atomic_shared_ptr and atomic_weak_ptr as a replacement for the use of these functions.
| These functions were deprecated in favor of the specializations of the | (since C++20) |
Example
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 2980 | C++11 | empty shared_ptrs are never equivalent | equivalent if they store the same pointer value |
See also
|
(C++11) | checks if the atomic type's operations are lock-free (function template) |
|
(C++11)(C++11) | atomically replaces the value of the atomic object with a non-atomic argument (function template) |
|
(C++11)(C++11) | atomically obtains the value stored in an atomic object (function template) |
|
(C++11)(C++11) | atomically replaces the value of the atomic object with non-atomic argument and returns the old value of the atomic (function template) |
|
(C++11)(C++11)(C++11)(C++11) | atomically compares the value of the atomic object with non-atomic argument and performs atomic exchange if equal or atomic load if not (function template) |
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