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For something simple like a counter if multiple threads will be increasing the number. I read that mutex locks can decrease efficiency since the threads have to wait. So, to me, an atomic counter would be the most efficient, but I read that internally it is basically a lock? So I guess I'm confused how either could be more efficient than the other.

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  • Should this answer be for all platforms and programming languages supporting pthreads or some subset? I do not completely understand the relationships between pthreads, operating systems and programming languages but it seems these relationships could be relevant. – snow_abstraction Sep 16 '17 at 16:37
63

Atomic operations leverage processor support (compare and swap instructions) and don't use locks at all, whereas locks are more OS-dependent and perform differently on, for example, Win and Linux.

Locks actually suspend thread execution, freeing up cpu resources for other tasks, but incurring in obvious context-switching overhead when stopping/restarting the thread. On the contrary, threads attempting atomic operations don't wait and keep trying until success (so-called busy-waiting), so they don't incur in context-switching overhead, but neither free up cpu resources.

Summing up, in general atomic operations are faster if contention between threads is sufficiently low. You should definitely do benchmarking as there's no other reliable method of knowing what's the lowest overhead between context-switching and busy-waiting.

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    I've been Googling and reading my textbook for many hours trying to find this answer. Highly, highly underrated answer – Nathan Apr 2 at 11:48
50

If you have a counter for which atomic operations are supported, it will be more efficient than a mutex.

Technically, the atomic will lock the memory bus on most platforms. However, there are two ameliorating details:

  • It is impossible to suspend a thread during the memory bus lock, but it is possible to suspend a thread during a mutex lock. This is what lets you get a lock-free guarantee (which doesn't say anything about not locking - it just guarantees that at least one thread makes progress).
  • Mutexes eventually end up being implemented with atomics. Since you need at least one atomic operation to lock a mutex, and one atomic operation to unlock a mutex, it takes at least twice long to do a mutex lock, even in the best of cases.
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    It is important to understand it depends how well the compiler or interpreter supports the platform to generate the best machine instructions (in this case lock-free instructions) for the platform. I think this is what @Cort Ammon meant by "supported". Also some mutexes might make guarantees about forward progress or fairness for some or all threads that are not made by simple atomic instructions. – snow_abstraction Sep 16 '17 at 16:28
22

A minimal (standards compliant) mutex implementation requires 2 basic ingredients:

  • A way to atomically convey a state change between threads (the 'locked' state)
  • memory barriers to enforce memory operations protected by the mutex to stay inside the protected area.

There is no way you can make it any simpler than this because of the 'synchronizes-with' relationship the C++ standard requires.

A minimal (correct) implementation might look like this:

class mutex {
    std::atomic<bool> flag{false};

public:
    void lock()
    {
        while (flag.exchange(true, std::memory_order_relaxed));
        std::atomic_thread_fence(std::memory_order_acquire);
    }

    void unlock()
    {
        std::atomic_thread_fence(std::memory_order_release);
        flag.store(false, std::memory_order_relaxed);
    }
};

Due to its simplicity (it cannot suspend the thread of execution), it is likely that, under low contention, this implementation outperforms a std::mutex. But even then, it is easy to see that each integer increment, protected by this mutex, requires the following operations:

  • an atomic store to release the mutex
  • an atomic compare-and-swap (read-modify-write) to acquire the mutex (possibly multiple times)
  • an integer increment

If you compare that with a standalone std::atomic<int> that is incremented with a single (unconditional) read-modify-write (eg. fetch_add), it is reasonable to expect that an atomic operation (using the same ordering model) will outperform the case whereby a mutex is used.

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9

atomic integer is a user mode object there for it's much more efficient than a mutex which runs in kernel mode. The scope of atomic integer is a single application while the scope of the mutex is for all running software on the machine.

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    This is almost true. Modern mutex implementations, like Linux's Futex, do tend to leverage atomic operations to avoid the switch to kernel mode on the fast path. Such mutexes only have to jump into kernel mode if the atomic operation failed to do the desired task (such as the case where the thread needs to block). – Cort Ammon Sep 20 '17 at 22:14
  • I think the scope of an atomic integer is a single process, which is significant insofar as applications can be comprised of multiple processes (e.g., Python multiprocessing for parallelism). – weberc2 Nov 10 '19 at 23:35
6

The atomic variable classes in Java are able to take advantage of Compare and swap instructions provided by the processor.

Here's a detailed description of the differences: http://www.ibm.com/developerworks/library/j-jtp11234/

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Most processors have supported an atomic read or write, and often an atomic cmp&swap. This means that the processor itself writes or reads the latest value in a single operation, and there might be a few cycles lost compared to a normal integer access, especially as the compiler can't optimise around atomic operations nearly as well as normal.

On the other hand a mutex is a number of lines of code to enter and leave, and during that execution other processors that access the same location are totally stalled, so clearly a big overhead on them. In unoptimised high-level code, the mutex enter/exit and the atomic will be function calls, but for mutex, any competing processor will be locked out while your mutex enter function returns, and while your exit function is started. For atomic, it is only the duration of the actual operation which is locked out. Optimisation should reduce that cost, but not all of it.

If you are trying to increment, then your modern processor probably supports atomic increment/decrement, which will be great.

If it does not, then it is either implemented using the processor atomic cmp&swap, or using a mutex.

Mutex:

get the lock
read
increment
write
release the lock

Atomic cmp&swap:

atomic read the value
calc the increment
do{
   atomic cmpswap value, increment
   recalc the increment
}while the cmp&swap did not see the expected value

So this second version has a loop [incase another processor increments the value between our atomic operations, so value no longer matches, and increment would be wrong] that can get long [if there are many competitors], but generally should still be quicker than the mutex version, but the mutex version may allow that processor to task switch.

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Mutex is a kernel level semantic which provides mutual exclusion even at the Process level. Note that it can be helpful in extending mutual exclusion across process boundaries and not just within a process (for threads). It is costlier.

Atomic Counter, AtomicInteger for e.g., is based on CAS, and usually try attempting to do operation until succeed. Basically, in this case, threads race or compete to increment\decrement the value atomically. Here, you may see good CPU cycles being used by a thread trying to operate on a current value.

Since you want to maintain the counter, AtomicInteger\AtomicLong will be the best for your use case.

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