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I wrote something using atomics rather than locks and perplexed at it being so much slower in my case I wrote the following mini test:

#include <pthread.h>
#include <vector>

struct test
{
    test(size_t size) : index_(0), size_(size), vec2_(size)
        {
            vec_.reserve(size_);
            pthread_mutexattr_init(&attrs_);
            pthread_mutexattr_setpshared(&attrs_, PTHREAD_PROCESS_PRIVATE);
            pthread_mutexattr_settype(&attrs_, PTHREAD_MUTEX_ADAPTIVE_NP);

            pthread_mutex_init(&lock_, &attrs_);
        }

    void lockedPush(int i);
    void atomicPush(int* i);

    size_t              index_;
    size_t              size_;
    std::vector<int>    vec_;
    std::vector<int>    vec2_;
    pthread_mutexattr_t attrs_;
    pthread_mutex_t     lock_;
};

void test::lockedPush(int i)
{
    pthread_mutex_lock(&lock_);
    vec_.push_back(i);
    pthread_mutex_unlock(&lock_);
}

void test::atomicPush(int* i)
{
    int ii       = (int) (i - &vec2_.front());
    size_t index = __sync_fetch_and_add(&index_, 1);
    vec2_[index & (size_ - 1)] = ii;
}

int main(int argc, char** argv)
{
    const size_t N = 1048576;
    test t(N);

//     for (int i = 0; i < N; ++i)
//         t.lockedPush(i);

    for (int i = 0; i < N; ++i)
        t.atomicPush(&i);
}

If I uncomment the atomicPush operation and run the test with time(1) I get output like so:

real    0m0.027s
user    0m0.022s
sys     0m0.005s

and if I run the loop calling the atomic thing (the seemingly unnecessary operation is there because i want my function to look as much as possible as what my bigger code does) I get output like so:

real    0m0.046s
user    0m0.043s
sys     0m0.003s

I'm not sure why this is happening as I would have expected the atomic to be faster than the lock in this case...

When I compile with -O3 I see lock and atomic updates as follows:

lock:
    real    0m0.024s
    user    0m0.022s
    sys     0m0.001s

atomic:    
    real    0m0.013s
    user    0m0.011s
    sys     0m0.002s

In my larger app though the performance of the lock (single threaded testing) is still doing better regardless though..

share|improve this question
    
Not sure what do you mean in the timing, in my test the lockedPush is consistently slower than atomicPush by ~70%. –  KennyTM Sep 19 '12 at 16:03
    
Which is what I'd like to see! Do you have an SMP kernel? I read somewhere the attribute PTHREAD_MUTEX_ADAPTIVE_NP will make it spin which is super fast when not contended. Some system info of mine is: 2.6.32-220.13.1.el6.x86_64 #1 SMP Thu Mar 29 11:46:40 EDT 2012 x86_64 x86_64 x86_64 GNU/Linux –  Palace Chan Sep 19 '12 at 16:08
    
3.5.4-1-ARCH #1 SMP PREEMPT Sat Sep 15 08:12:04 CEST 2012 x86_64 GNU/Linux. –  KennyTM Sep 19 '12 at 16:09
    
Ah i'm confused then how you can be getting such results. If anything I'm assuming you're using a better compiler but then according to the below ("the memory barrier prevents compiler optimizations") I would also expect you to see my timings. –  Palace Chan Sep 19 '12 at 16:15
    
How are you compiling the program? I used g++-4.7 -O3 -pthread. –  KennyTM Sep 19 '12 at 16:17

2 Answers 2

up vote 6 down vote accepted

An uncontended mutex is extremely fast to lock and unlock. With an atomic variable, you're always paying a certain memory synchronisation penalty (especially since you're not even using relaxed ordering).

Your test case is simply too naive to be useful. You have to test a heavily contended data access scenario.

Generally, atomics are slow (they get in the way of clever internal reordering, pipelining, and caching), but they allow for lock-free code which ensures that the entire program can make some progress. By contrast, if you get swapped out while holding a lock, everyone has to wait.

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But doesn't an uncontended mutex have to satisfy memory visibility guarantees, too? –  Pete Becker Sep 19 '12 at 16:07
    
Shouldn't a mutex be built on atomic primitives? –  Brian Sep 19 '12 at 16:07
    
@PeteBecker: Sure, but for starters, those will have much more restrictive ordering requirements. For example, on x86 loads acquire and stores release in any case, so the mutex probably doesn't even need a fence... –  Kerrek SB Sep 19 '12 at 16:09
1  
@Brian: A mutex is more than just the locking primitive. It also contains kernel magic to allow waiting threads to sleep, and to wake up waiting threads upon unlock. Yes, the lock state has to be accessed atomically, but there's a lot more to a mutex than that. (The simplest lock that only uses an atomic flag is a spin lock.) –  Kerrek SB Sep 19 '12 at 16:09
    
@KerrekSB - but that's also true for an atomic; on x86 it only needs a compiler barrier, not a memory barrier. Or am I thoroughly confused? –  Pete Becker Sep 19 '12 at 16:11

Just to add to the first answer, when you do a __sync_fetch_and_add you actually enforce specific code ordering. From the documentation

A full memory barrier is created when this function is invoked

A memory barrier is when

a central processing unit (CPU) or compiler to enforce an ordering constraint on memory operations issued before and after the barrier instruction

Chances are even though your work is atomic, you are losing compiler optimizations by forcing ordering of instructions.

share|improve this answer
    
See also gcc.gnu.org/onlinedocs/gcc-4.7.1/gcc/… –  Hasturkun Sep 19 '12 at 16:21

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