I implemented SpinLock class, as followed

struct Node {
    int number;
    std::atomic_bool latch;

    void add() {
    void lock() {
        bool unlatched = false;
        while(!latch.compare_exchange_weak(unlatched, true, std::memory_order_acquire));
    void unlock() {
        latch.store(false , std::memory_order_release);

I implemented above class and made two threads which call add() method of a same instance of Node class 10 million times per thread.

the result is , unfortunately, not 20 million. What am I missing here?

  • 5
    Be warned, this is about the worst spinlock you can possibly implement. Among other problems: 1) When you finally do acquire the lock, you take the mother of all mispredicted branches leaving the while loop, which is the worst possible time for such a thing. 2) The lock function can starve another thread running in the same virtual core on a hyper-threaded CPU. Commented Apr 20, 2015 at 10:50
  • 1
    @DavidSchwartz, Thank you for your comments. May I ask more on the issues you mentioned? 2). That lock function can starve another thread, (that's right!, and it is meant to do that since I am sure the lock's life time is very short). I can use some spin counters to east this problem, am I right? 1). Why I take 'the mother of all mispredicated brabches' in this code?, and how can I improve it?? do you have any comments on it? Thank you again
    – syko
    Commented Apr 26, 2015 at 5:01
  • 2
    Pause prevents speculative execution, eliminating the branch misprediction penalty. (And, by the way, if you don't know this kind of stuff inside out, you have no business writing spinlocks. You will make every mistake and not even realize you had other choices.) Commented Apr 27, 2015 at 8:50
  • 5
    @DavidSchwartz, I'm interested in writing these kinds of things but I don't know this kind of stuff inside out. Can you recommend how a person can make themselves know this inside out?
    – codeshot
    Commented Jun 1, 2016 at 0:22
  • 9
    @DavidSchwartz, It sounds like the only way to become knowledgeable enough to be allowed to try writing this kind of code is to try writing this kind of code.
    – codeshot
    Commented Jun 4, 2016 at 11:41

3 Answers 3


The problem is that compare_exchange_weak updates the unlatched variable once it fails. From the documentation of compare_exchange_weak:

Compares the contents of the atomic object's contained value with expected: - if true, it replaces the contained value with val (like store). - if false, it replaces expected with the contained value .

I.e., after the first failing compare_exchange_weak, unlatched will be updated to true, so the next loop iteration will try to compare_exchange_weak true with true. This succeeds and you just took a lock that was held by another thread.

Solution: Make sure to set unlatched back to false before each compare_exchange_weak, e.g.:

while(!latch.compare_exchange_weak(unlatched, true, std::memory_order_acquire)) {
    unlatched = false;
  • 5
    +1, and note to the OP, the default constructor of Node will not value-initialize number as-presented. I.e. Node node; will not leave a deterministic value in node.number to start your sequence. You need a constructor of such usage, Node() : number() {} is sufficient. see it live
    – WhozCraig
    Commented Oct 27, 2014 at 8:34
  • Thanks for your comments!! And I found my pool mistakes! thank you
    – syko
    Commented Oct 27, 2014 at 8:42
  • 5
    please note, that the loop also requires __mm_pause() to enable hyperthreads.
    – Anton
    Commented Oct 27, 2014 at 8:57

As mentioned by @gexicide, the problem is that the compare_exchange functions update the expected variable with the current value of the atomic variable. That is also the reason, why you have to use the local variable unlatched in the first place. To solve this you can set unlatched back to false in each loop iteration.

However, instead of using compare_exchange for something its interface is rather ill suited for, it is much simpler to use std::atomic_flag instead:

class SpinLock {
    std::atomic_flag locked = ATOMIC_FLAG_INIT ;
    void lock() {
        while (locked.test_and_set(std::memory_order_acquire)) { ; }
    void unlock() {

Source: cppreference

Manually specifying the memory order is just a minor potential performance tweak, which I copied from the source. If simplicity is more important than the last bit of performance, you can stick to the default values and just call locked.test_and_set() / locked.clear().

Btw.: std::atomic_flag is the only type that is guaranteed to be lock free, although I don't know any platform, where oparations on std::atomic_bool are not lock free.

Update: As explained in the comments by @David Schwartz, @Anton and @Technik Empire, the empty loop has some undesirable effects like branch missprediction, thread starvation on HT processors and overly high power consumption - so in short, it is a pretty inefficient way to wait. The impact and solution are architecture, platform and application specific. I'm no expert, but the usual solution seems to be to add either a cpu_relax() on linux or YieldProcessor() on windows to the loop body.

EDIT2: Just to be clear: The portable version presented here (without the special cpu_relax etc instructions) should alredy be good enough for many applications. If your SpinLock spins a lot because someone other is holding the lock for a long time (which might already indicate a general design problem), it is probably better to use a normal mutex anyway.

  • 2
    just add a std::this_thread::yield call into the while loop: en.cppreference.com/w/cpp/thread/yield Commented Jun 6, 2016 at 7:58
  • 3
    @Martin: I though about that, but std::this_thread::yield() is a pretty heavy system call, so I'm not sure, if I'd put it in the loop body of a spinlock. My (untested) assumption is that in most situations, where that would be OK, you'd want to use a std::mutex (or similar) to begin with.
    – MikeMB
    Commented Jun 6, 2016 at 8:23
  • 24
    @MartinGerhardy There is no point in using yield in a spin-lock. The goal of spin-locks is avoiding context switches which are expensive in small critical sections. Commented Jan 5, 2017 at 10:13
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    @rox that's not my point. The technical definition of spin mutex is a lock that does not release the CPU if it is already acquired by others. In single core systems you don't usually use spinlocks but a regular mutex. Commented Dec 6, 2017 at 17:32
  • 2
    @JorgeBellón As far as I know, the glibc implementation uses something similar to yield: github.com/lattera/glibc/blob/master/mach/spin-solid.c . I'm not sure where you found the definition.
    – rox
    Commented Dec 7, 2017 at 5:01

Memory optimization works only locally , therefore , these memory management methods (td::memory_order_acquire and std::memory_order_release) are useless.

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