std::shared_mutex

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Concurrency support library
Threads
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(C++11)(deprecated in C++20)
(C++11)(deprecated in C++20)
Free functions for atomic operations
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Memory ordering
Mutual exclusion
(C++11)
shared_mutex
(C++17)
Generic lock management
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(C++11)(C++11)(C++11)
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Defined in header <shared_mutex>
class shared_mutex;
(since C++17)

The shared_mutex class is a synchronization primitive that can be used to protect shared data from being simultaneously accessed by multiple threads. In contrast to other mutex types which facilitate exclusive access, a shared_mutex has two levels of access:

  • shared - several threads can share ownership of the same mutex.
  • exclusive - only one thread can own the mutex.

If one thread has acquired the exclusive lock (through lock, try_lock), no other threads can acquire the lock (including the shared).

If one thread has acquired the shared lock (through lock_shared, try_lock_shared), no other thread can acquire the exclusive lock, but can acquire the shared lock.

Only when the exclusive lock has not been acquired by any thread, the shared lock can be acquired by multiple threads.

Within one thread, only one lock (shared or exclusive) can be acquired at the same time.

Shared mutexes are especially useful when shared data can be safely read by any number of threads simultaneously, but a thread may only write the same data when no other thread is reading or writing at the same time.

The shared_mutex class satisfies all requirements of SharedMutex and StandardLayoutType.

Member types

Member type Definition
native_handle_type(not always present) implementation-defined

Member functions

constructs the mutex
(public member function)
destroys the mutex
(public member function)
operator=
[deleted]
not copy-assignable
(public member function)
Exclusive locking
locks the mutex, blocks if the mutex is not available
(public member function)
tries to lock the mutex, returns if the mutex is not available
(public member function)
unlocks the mutex
(public member function)
Shared locking
locks the mutex for shared ownership, blocks if the mutex is not available
(public member function)
tries to lock the mutex for shared ownership, returns if the mutex is not available
(public member function)
unlocks the mutex (shared ownership)
(public member function)
Native handle
returns the underlying implementation-defined native handle object
(public member function)

Example

#include <iostream>
#include <mutex>
#include <shared_mutex>
#include <thread>
 
class ThreadSafeCounter {
 public:
  ThreadSafeCounter() = default;
 
  // Multiple threads/readers can read the counter's value at the same time.
  unsigned int get() const {
    std::shared_lock lock(mutex_);
    return value_;
  }
 
  // Only one thread/writer can increment/write the counter's value.
  unsigned int increment() {
    std::unique_lock lock(mutex_);
    return ++value_;
  }
 
  // Only one thread/writer can reset/write the counter's value.
  void reset() {
    std::unique_lock lock(mutex_);
    value_ = 0;
  }
 
 private:
  mutable std::shared_mutex mutex_;
  unsigned int value_ = 0;
};
 
int main() {
  ThreadSafeCounter counter;
 
  auto increment_and_print = [&counter]() {
    for (int i = 0; i < 3; i++) {
      std::cout << std::this_thread::get_id() << ' ' << counter.increment() << '\n';
 
      // Note: Writing to std::cout actually needs to be synchronized as well
      // by another std::mutex. This has been omitted to keep the example small.
    }
  };
 
  std::thread thread1(increment_and_print);
  std::thread thread2(increment_and_print);
 
  thread1.join();
  thread2.join();
}
 
// Explanation: The output below was generated on a single-core machine. When
// thread1 starts, it enters the loop for the first time and calls increment()
// followed by get(). However, before it can print the returned value to
// std::cout, the scheduler puts thread1 to sleep and wakes up thread2, which
// obviously has time enough to run all three loop iterations at once. Back to
// thread1, still in the first loop iteration, it finally prints its local copy
// of the counter's value, which is 1, to std::cout and then runs the remaining
// two loop iterations. On a multi-core machine, none of the threads is put to
// sleep and the output is more likely to be in ascending order.

Possible output:

123084176803584 2
123084176803584 3
123084176803584 4
123084185655040 1
123084185655040 5
123084185655040 6

See also

provides shared mutual exclusion facility and implements locking with a timeout
(class)
implements movable shared mutex ownership wrapper
(class template)
implements movable mutex ownership wrapper
(class template)