33 Thread support library [thread]

33.4 Mutual exclusion [thread.mutex]

33.4.4 Locks [thread.lock]

1
#

A lock is an object that holds a reference to a lockable object and may unlock the lockable object during the lock's destruction (such as when leaving block scope). An execution agent may use a lock to aid in managing ownership of a lockable object in an exception safe manner. A lock is said to own a lockable object if it is currently managing the ownership of that lockable object for an execution agent. A lock does not manage the lifetime of the lockable object it references. [Note: Locks are intended to ease the burden of unlocking the lockable object under both normal and exceptional circumstances. end note]

2
#

Some lock constructors take tag types which describe what should be done with the lockable object during the lock's construction.

namespace std {
  struct defer_lock_t  { };     // do not acquire ownership of the mutex
  struct try_to_lock_t { };     // try to acquire ownership of the mutex
                                // without blocking
  struct adopt_lock_t  { };     // assume the calling thread has already
                                // obtained mutex ownership and manage it

  inline constexpr defer_lock_t   defer_lock { };
  inline constexpr try_to_lock_t  try_to_lock { };
  inline constexpr adopt_lock_t   adopt_lock { };
}

33.4.4.1 Class template lock_­guard [thread.lock.guard]

namespace std {
  template <class Mutex>
  class lock_guard {
  public:
    using mutex_type = Mutex;

    explicit lock_guard(mutex_type& m);
    lock_guard(mutex_type& m, adopt_lock_t);
    ~lock_guard();

    lock_guard(const lock_guard&) = delete;
    lock_guard& operator=(const lock_guard&) = delete;

  private:
    mutex_type& pm; // exposition only
  };

  template<class Mutex> lock_guard(lock_guard<Mutex>) -> lock_guard<Mutex>;
}
1
#

An object of type lock_­guard controls the ownership of a lockable object within a scope. A lock_­guard object maintains ownership of a lockable object throughout the lock_­guard object's lifetime. The behavior of a program is undefined if the lockable object referenced by pm does not exist for the entire lifetime of the lock_­guard object. The supplied Mutex type shall meet the BasicLockable requirements.

explicit lock_guard(mutex_type& m);

2
#

Requires: If mutex_­type is not a recursive mutex, the calling thread does not own the mutex m.

3
#

Effects: As if by m.lock().

4
#

Postconditions: &pm == &m

lock_guard(mutex_type& m, adopt_lock_t);

5
#

Requires: The calling thread owns the mutex m.

6
#

Postconditions: &pm == &m

7
#

Throws: Nothing.

~lock_guard();

8
#

Effects: As if by pm.unlock().

33.4.4.2 Class template scoped_­lock [thread.lock.scoped]

namespace std {
  template <class... MutexTypes>
  class scoped_lock {
  public:
    using mutex_type = Mutex;  // If MutexTypes... consists of the single type Mutex

    explicit scoped_lock(MutexTypes&... m);
    explicit scoped_lock(MutexTypes&... m, adopt_lock_t);
    ~scoped_lock();

    scoped_lock(const scoped_lock&) = delete;
    scoped_lock& operator=(const scoped_lock&) = delete;

  private:
    tuple<MutexTypes&...> pm; // exposition only
  };

  template<class... MutexTypes>
    scoped_lock(scoped_lock<MutexTypes...>) -> scoped_lock<MutexTypes...>;
}
1
#

An object of type scoped_­lock controls the ownership of lockable objects within a scope. A scoped_­lock object maintains ownership of lockable objects throughout the scoped_­lock object's lifetime. The behavior of a program is undefined if the lockable objects referenced by pm do not exist for the entire lifetime of the scoped_­lock object. When sizeof...(MutexTypes) is 1, the supplied Mutex type shall meet the BasicLockable requirements. Otherwise, each of the mutex types shall meet the Lockable requirements.

explicit scoped_lock(MutexTypes&... m);

2
#

Requires: If a MutexTypes type is not a recursive mutex, the calling thread does not own the corresponding mutex element of m.

3
#

Effects: Initializes pm with tie(m...). Then if sizeof...(MutexTypes) is 0, no effects. Otherwise if sizeof...(MutexTypes) is 1, then m.lock(). Otherwise, lock(m...).

explicit scoped_lock(MutexTypes&... m, adopt_lock_t);

4
#

Requires: The calling thread owns all the mutexes in m.

5
#

Effects: Initializes pm with tie(m...).

6
#

Throws: Nothing.

~scoped_lock();

7
#

Effects: For all i in [0, sizeof...(MutexTypes)), get<i>(pm).unlock().

33.4.4.3 Class template unique_­lock [thread.lock.unique]

namespace std {
  template <class Mutex>
  class unique_lock {
  public:
    using mutex_type = Mutex;

    // [thread.lock.unique.cons], construct/copy/destroy
    unique_lock() noexcept;
    explicit unique_lock(mutex_type& m);
    unique_lock(mutex_type& m, defer_lock_t) noexcept;
    unique_lock(mutex_type& m, try_to_lock_t);
    unique_lock(mutex_type& m, adopt_lock_t);
    template <class Clock, class Duration>
      unique_lock(mutex_type& m, const chrono::time_point<Clock, Duration>& abs_time);
    template <class Rep, class Period>
      unique_lock(mutex_type& m, const chrono::duration<Rep, Period>& rel_time);
    ~unique_lock();

    unique_lock(const unique_lock&) = delete;
    unique_lock& operator=(const unique_lock&) = delete;

    unique_lock(unique_lock&& u) noexcept;
    unique_lock& operator=(unique_lock&& u);

    // [thread.lock.unique.locking], locking
    void lock();
    bool try_lock();

    template <class Rep, class Period>
      bool try_lock_for(const chrono::duration<Rep, Period>& rel_time);
    template <class Clock, class Duration>
      bool try_lock_until(const chrono::time_point<Clock, Duration>& abs_time);

    void unlock();

    // [thread.lock.unique.mod], modifiers
    void swap(unique_lock& u) noexcept;
    mutex_type* release() noexcept;

    // [thread.lock.unique.obs], observers
    bool owns_lock() const noexcept;
    explicit operator bool () const noexcept;
    mutex_type* mutex() const noexcept;

  private:
    mutex_type* pm; // exposition only
    bool owns;      // exposition only
  };

  template<class Mutex> unique_lock(unique_lock<Mutex>) -> unique_lock<Mutex>;

  template <class Mutex>
    void swap(unique_lock<Mutex>& x, unique_lock<Mutex>& y) noexcept;
}
1
#

An object of type unique_­lock controls the ownership of a lockable object within a scope. Ownership of the lockable object may be acquired at construction or after construction, and may be transferred, after acquisition, to another unique_­lock object. Objects of type unique_­lock are not copyable but are movable. The behavior of a program is undefined if the contained pointer pm is not null and the lockable object pointed to by pm does not exist for the entire remaining lifetime of the unique_­lock object. The supplied Mutex type shall meet the BasicLockable requirements.

2
#

[Note: unique_­lock<Mutex> meets the BasicLockable requirements. If Mutex meets the Lockable requirements, unique_­lock<Mutex> also meets the Lockable requirements; if Mutex meets the TimedLockable requirements, unique_­lock<Mutex> also meets the TimedLockable requirements. end note]

33.4.4.3.1 unique_­lock constructors, destructor, and assignment [thread.lock.unique.cons]

unique_lock() noexcept;

1
#

Effects: Constructs an object of type unique_­lock.

2
#

Postconditions: pm == 0 and owns == false.

explicit unique_lock(mutex_type& m);

3
#

Requires: If mutex_­type is not a recursive mutex the calling thread does not own the mutex.

4
#

Effects: Constructs an object of type unique_­lock and calls m.lock().

5
#

Postconditions: pm == addressof(m) and owns == true.

unique_lock(mutex_type& m, defer_lock_t) noexcept;

6
#

Effects: Constructs an object of type unique_­lock.

7
#

Postconditions: pm == addressof(m) and owns == false.

unique_lock(mutex_type& m, try_to_lock_t);

8
#

Requires: The supplied Mutex type shall meet the Lockable requirements. If mutex_­type is not a recursive mutex the calling thread does not own the mutex.

9
#

Effects: Constructs an object of type unique_­lock and calls m.try_­lock().

10
#

Postconditions: pm == addressof(m) and owns == res, where res is the value returned by the call to m.try_­lock().

unique_lock(mutex_type& m, adopt_lock_t);

11
#

Requires: The calling thread owns the mutex.

12
#

Effects: Constructs an object of type unique_­lock.

13
#

Postconditions: pm == addressof(m) and owns == true.

14
#

Throws: Nothing.

template <class Clock, class Duration> unique_lock(mutex_type& m, const chrono::time_point<Clock, Duration>& abs_time);

15
#

Requires: If mutex_­type is not a recursive mutex the calling thread does not own the mutex. The supplied Mutex type shall meet the TimedLockable requirements.

16
#

Effects: Constructs an object of type unique_­lock and calls m.try_­lock_­until(abs_­time).

17
#

Postconditions: pm == addressof(m) and owns == res, where res is the value returned by the call to m.try_­lock_­until(abs_­time).

template <class Rep, class Period> unique_lock(mutex_type& m, const chrono::duration<Rep, Period>& rel_time);

18
#

Requires: If mutex_­type is not a recursive mutex the calling thread does not own the mutex. The supplied Mutex type shall meet the TimedLockable requirements.

19
#

Effects: Constructs an object of type unique_­lock and calls m.try_­lock_­for(rel_­time).

20
#

Postconditions: pm == addressof(m) and owns == res, where res is the value returned by the call to m.try_­lock_­for(rel_­time).

unique_lock(unique_lock&& u) noexcept;

21
#

Postconditions: pm == u_­p.pm and owns == u_­p.owns (where u_­p is the state of u just prior to this construction), u.pm == 0 and u.owns == false.

unique_lock& operator=(unique_lock&& u);

22
#

Effects: If owns calls pm->unlock().

23
#

Postconditions: pm == u_­p.pm and owns == u_­p.owns (where u_­p is the state of u just prior to this construction), u.pm == 0 and u.owns == false.

24
#

[Note: With a recursive mutex it is possible for both *this and u to own the same mutex before the assignment. In this case, *this will own the mutex after the assignment and u will not. end note]

25
#

Throws: Nothing.

~unique_lock();

26
#

Effects: If owns calls pm->unlock().

33.4.4.3.2 unique_­lock locking [thread.lock.unique.locking]

void lock();

1
#

Effects: As if by pm->lock().

2
#

Postconditions: owns == true.

3
#

Throws: Any exception thrown by pm->lock(). system_­error when an exception is required ([thread.req.exception]).

4
#

Error conditions:

  • (4.1)

    operation_­not_­permitted — if pm is nullptr.

  • (4.2)

    resource_­deadlock_­would_­occur — if on entry owns is true.

bool try_lock();

5
#

Requires: The supplied Mutex shall meet the Lockable requirements.

6
#

Effects: As if by pm->try_­lock().

7
#

Returns: The value returned by the call to try_­lock().

8
#

Postconditions: owns == res, where res is the value returned by the call to try_­lock().

9
#

Throws: Any exception thrown by pm->try_­lock(). system_­error when an exception is required ([thread.req.exception]).

10
#

Error conditions:

  • (10.1)

    operation_­not_­permitted — if pm is nullptr.

  • (10.2)

    resource_­deadlock_­would_­occur — if on entry owns is true.

template <class Clock, class Duration> bool try_lock_until(const chrono::time_point<Clock, Duration>& abs_time);

11
#

Requires: The supplied Mutex type shall meet the TimedLockable requirements.

12
#

Effects: As if by pm->try_­lock_­until(abs_­time).

13
#

Returns: The value returned by the call to try_­lock_­until(abs_­time).

14
#

Postconditions: owns == res, where res is the value returned by the call to try_­lock_­until(abs_­time).

15
#

Throws: Any exception thrown by pm->try_­lock_­until(). system_­error when an exception is required ([thread.req.exception]).

16
#

Error conditions:

  • (16.1)

    operation_­not_­permitted — if pm is nullptr.

  • (16.2)

    resource_­deadlock_­would_­occur — if on entry owns is true.

template <class Rep, class Period> bool try_lock_for(const chrono::duration<Rep, Period>& rel_time);

17
#

Requires: The supplied Mutex type shall meet the TimedLockable requirements.

18
#

Effects: As if by pm->try_­lock_­for(rel_­time).

19
#

Returns: The value returned by the call to try_­lock_­until(rel_­time).

20
#

Postconditions: owns == res, where res is the value returned by the call to try_­lock_­for(rel_­time).

21
#

Throws: Any exception thrown by pm->try_­lock_­for(). system_­error when an exception is required ([thread.req.exception]).

22
#

Error conditions:

  • (22.1)

    operation_­not_­permitted — if pm is nullptr.

  • (22.2)

    resource_­deadlock_­would_­occur — if on entry owns is true.

void unlock();

23
#

Effects: As if by pm->unlock().

24
#

Postconditions: owns == false.

25
#

Throws: system_­error when an exception is required ([thread.req.exception]).

26
#

Error conditions:

  • (26.1)

    operation_­not_­permitted — if on entry owns is false.

33.4.4.3.3 unique_­lock modifiers [thread.lock.unique.mod]

void swap(unique_lock& u) noexcept;

1
#

Effects: Swaps the data members of *this and u.

mutex_type* release() noexcept;

2
#

Returns: The previous value of pm.

3
#

Postconditions: pm == 0 and owns == false.

template <class Mutex> void swap(unique_lock<Mutex>& x, unique_lock<Mutex>& y) noexcept;

4
#

Effects: As if by x.swap(y).

33.4.4.3.4 unique_­lock observers [thread.lock.unique.obs]

bool owns_lock() const noexcept;

1
#

Returns: owns.

explicit operator bool() const noexcept;

2
#

Returns: owns.

mutex_type *mutex() const noexcept;

3
#

Returns: pm.

33.4.4.4 Class template shared_­lock [thread.lock.shared]

namespace std {
  template <class Mutex>
  class shared_lock {
  public:
    using mutex_type = Mutex;

    // [thread.lock.shared.cons], construct/copy/destroy
    shared_lock() noexcept;
    explicit shared_lock(mutex_type& m);  // blocking
    shared_lock(mutex_type& m, defer_lock_t) noexcept;
    shared_lock(mutex_type& m, try_to_lock_t);
    shared_lock(mutex_type& m, adopt_lock_t);
    template <class Clock, class Duration>
      shared_lock(mutex_type& m,
                  const chrono::time_point<Clock, Duration>& abs_time);
    template <class Rep, class Period>
      shared_lock(mutex_type& m,
                const chrono::duration<Rep, Period>& rel_time);
    ~shared_lock();

    shared_lock(const shared_lock&) = delete;
    shared_lock& operator=(const shared_lock&) = delete;

    shared_lock(shared_lock&& u) noexcept;
    shared_lock& operator=(shared_lock&& u) noexcept;

    // [thread.lock.shared.locking], locking
    void lock();  // blocking
    bool try_lock();
    template <class Rep, class Period>
      bool try_lock_for(const chrono::duration<Rep, Period>& rel_time);
    template <class Clock, class Duration>
      bool try_lock_until(const chrono::time_point<Clock, Duration>& abs_time);
    void unlock();

    // [thread.lock.shared.mod], modifiers
    void swap(shared_lock& u) noexcept;
    mutex_type* release() noexcept;

    // [thread.lock.shared.obs], observers
    bool owns_lock() const noexcept;
    explicit operator bool () const noexcept;
    mutex_type* mutex() const noexcept;

  private:
    mutex_type* pm; // exposition only
    bool owns;      // exposition only
  };

  template<class Mutex> shared_lock(shared_lock<Mutex>) -> shared_lock<Mutex>;

  template <class Mutex>
    void swap(shared_lock<Mutex>& x, shared_lock<Mutex>& y) noexcept;
}
1
#

An object of type shared_­lock controls the shared ownership of a lockable object within a scope. Shared ownership of the lockable object may be acquired at construction or after construction, and may be transferred, after acquisition, to another shared_­lock object. Objects of type shared_­lock are not copyable but are movable. The behavior of a program is undefined if the contained pointer pm is not null and the lockable object pointed to by pm does not exist for the entire remaining lifetime of the shared_­lock object. The supplied Mutex type shall meet the shared mutex requirements.

2
#

[Note: shared_­lock<Mutex> meets the TimedLockable requirements ([thread.req.lockable.timed]). end note]

33.4.4.4.1 shared_­lock constructors, destructor, and assignment [thread.lock.shared.cons]

shared_lock() noexcept;

1
#

Effects: Constructs an object of type shared_­lock.

2
#

Postconditions: pm == nullptr and owns == false.

explicit shared_lock(mutex_type& m);

3
#

Requires: The calling thread does not own the mutex for any ownership mode.

4
#

Effects: Constructs an object of type shared_­lock and calls m.lock_­shared().

5
#

Postconditions: pm == addressof(m) and owns == true.

shared_lock(mutex_type& m, defer_lock_t) noexcept;

6
#

Effects: Constructs an object of type shared_­lock.

7
#

Postconditions: pm == addressof(m) and owns == false.

shared_lock(mutex_type& m, try_to_lock_t);

8
#

Requires: The calling thread does not own the mutex for any ownership mode.

9
#

Effects: Constructs an object of type shared_­lock and calls m.try_­lock_­shared().

10
#

Postconditions: pm == addressof(m) and owns == res where res is the value returned by the call to m.try_­lock_­shared().

shared_lock(mutex_type& m, adopt_lock_t);

11
#

Requires: The calling thread has shared ownership of the mutex.

12
#

Effects: Constructs an object of type shared_­lock.

13
#

Postconditions: pm == addressof(m) and owns == true.

template <class Clock, class Duration> shared_lock(mutex_type& m, const chrono::time_point<Clock, Duration>& abs_time);

14
#

Requires: The calling thread does not own the mutex for any ownership mode.

15
#

Effects: Constructs an object of type shared_­lock and calls m.try_­lock_­shared_­until(abs_­time).

16
#

Postconditions: pm == addressof(m) and owns == res where res is the value returned by the call to m.try_­lock_­shared_­until(abs_­time).

template <class Rep, class Period> shared_lock(mutex_type& m, const chrono::duration<Rep, Period>& rel_time);

17
#

Requires: The calling thread does not own the mutex for any ownership mode.

18
#

Effects: Constructs an object of type shared_­lock and calls m.try_­lock_­shared_­for(rel_­time).

19
#

Postconditions: pm == addressof(m) and owns == res where res is the value returned by the call to m.try_­lock_­shared_­for(rel_­time).

~shared_lock();

20
#

Effects: If owns calls pm->unlock_­shared().

shared_lock(shared_lock&& sl) noexcept;

21
#

Postconditions: pm == sl_­p.pm and owns == sl_­p.owns (where sl_­p is the state of sl just prior to this construction), sl.pm == nullptr and sl.owns == false.

shared_lock& operator=(shared_lock&& sl) noexcept;

22
#

Effects: If owns calls pm->unlock_­shared().

23
#

Postconditions: pm == sl_­p.pm and owns == sl_­p.owns (where sl_­p is the state of sl just prior to this assignment), sl.pm == nullptr and sl.owns == false.

33.4.4.4.2 shared_­lock locking [thread.lock.shared.locking]

void lock();

1
#

Effects: As if by pm->lock_­shared().

2
#

Postconditions: owns == true.

3
#

Throws: Any exception thrown by pm->lock_­shared(). system_­error when an exception is required ([thread.req.exception]).

4
#

Error conditions:

  • (4.1)

    operation_­not_­permitted — if pm is nullptr.

  • (4.2)

    resource_­deadlock_­would_­occur — if on entry owns is true.

bool try_lock();

5
#

Effects: As if by pm->try_­lock_­shared().

6
#

Returns: The value returned by the call to pm->try_­lock_­shared().

7
#

Postconditions: owns == res, where res is the value returned by the call to pm->try_­lock_­shared().

8
#

Throws: Any exception thrown by pm->try_­lock_­shared(). system_­error when an exception is required ([thread.req.exception]).

9
#

Error conditions:

  • (9.1)

    operation_­not_­permitted — if pm is nullptr.

  • (9.2)

    resource_­deadlock_­would_­occur — if on entry owns is true.

template <class Clock, class Duration> bool try_lock_until(const chrono::time_point<Clock, Duration>& abs_time);

10
#

Effects: As if by pm->try_­lock_­shared_­until(abs_­time).

11
#

Returns: The value returned by the call to pm->try_­lock_­shared_­until(abs_­time).

12
#

Postconditions: owns == res, where res is the value returned by the call to pm->try_­lock_­shared_­until(abs_­time).

13
#

Throws: Any exception thrown by pm->try_­lock_­shared_­until(abs_­time). system_­error when an exception is required ([thread.req.exception]).

14
#

Error conditions:

  • (14.1)

    operation_­not_­permitted — if pm is nullptr.

  • (14.2)

    resource_­deadlock_­would_­occur — if on entry owns is true.

template <class Rep, class Period> bool try_lock_for(const chrono::duration<Rep, Period>& rel_time);

15
#

Effects: As if by pm->try_­lock_­shared_­for(rel_­time).

16
#

Returns: The value returned by the call to pm->try_­lock_­shared_­for(rel_­time).

17
#

Postconditions: owns == res, where res is the value returned by the call to pm->try_­lock_­shared_­for(rel_­time).

18
#

Throws: Any exception thrown by pm->try_­lock_­shared_­for(rel_­time). system_­error when an exception is required ([thread.req.exception]).

19
#

Error conditions:

  • (19.1)

    operation_­not_­permitted — if pm is nullptr.

  • (19.2)

    resource_­deadlock_­would_­occur — if on entry owns is true.

void unlock();

20
#

Effects: As if by pm->unlock_­shared().

21
#

Postconditions: owns == false.

22
#

Throws: system_­error when an exception is required ([thread.req.exception]).

23
#

Error conditions:

  • (23.1)

    operation_­not_­permitted — if on entry owns is false.

33.4.4.4.3 shared_­lock modifiers [thread.lock.shared.mod]

void swap(shared_lock& sl) noexcept;

1
#

Effects: Swaps the data members of *this and sl.

mutex_type* release() noexcept;

2
#

Returns: The previous value of pm.

3
#

Postconditions: pm == nullptr and owns == false.

template <class Mutex> void swap(shared_lock<Mutex>& x, shared_lock<Mutex>& y) noexcept;

4
#

Effects: As if by x.swap(y).

33.4.4.4.4 shared_­lock observers [thread.lock.shared.obs]

bool owns_lock() const noexcept;

1
#

Returns: owns.

explicit operator bool() const noexcept;

2
#

Returns: owns.

mutex_type* mutex() const noexcept;

3
#

Returns: pm.