36

I've been using volatile bool for years for thread execution control and it worked fine

// in my class declaration
volatile bool stop_;

-----------------

// In the thread function
while (!stop_)
{
     do_things();
}

Now, since C++11 added support for atomic operations, I decided to try that instead

// in my class declaration
std::atomic<bool> stop_;

-----------------

// In the thread function
while (!stop_)
{
     do_things();
}

But it's several orders of magnitude slower than the volatile bool!

Simple test case I've written takes about 1 second to complete with volatile bool approach. With std::atomic<bool> however I've been waiting for about 10 minutes and gave up!

I tried to use memory_order_relaxed flag with load and store to the same effect.

My platform:

  • Windows 7 64-bit
  • MinGW gcc 4.6.x

What I'm doing wrong?

NB: I know that volatile does not make a variable thread-safe. My question is not about volatile, it's about why atomic is ridiculously slow.

18
  • 15
    assert(your_atomic_variable.is_lock_free())? Oct 30, 2012 at 9:19
  • 33
    Your old code is incorrect, it "worked fine" by chance. Which is better: correct or fast? Oct 30, 2012 at 9:19
  • 10
    Please post your simple test case (if you want meaningful comments).
    – CB Bailey
    Oct 30, 2012 at 9:19
  • 10
    @Mysticial: Unfortunately volatile by accident happens to make store and load atomic on x86.
    – Jan Hudec
    Oct 30, 2012 at 9:20
  • 7
    @aleguna the answer seems to be "because it does different things than volatile". Oct 30, 2012 at 9:20

3 Answers 3

31

Code from "Olaf Dietsche"

 USE ATOMIC
 real   0m1.958s
 user   0m1.957s
 sys    0m0.000s

 USE VOLATILE
 real   0m1.966s
 user   0m1.953s
 sys    0m0.010s

IF YOU ARE USING GCC SMALLER 4.7

http://gcc.gnu.org/gcc-4.7/changes.html

Support for atomic operations specifying the C++11/C11 memory model has been added. These new __atomic routines replace the existing __sync built-in routines.

Atomic support is also available for memory blocks. Lock-free instructions will be used if a memory block is the same size and alignment as a supported integer type. Atomic operations which do not have lock-free support are left as function calls. A set of library functions is available on the GCC atomic wiki in the "External Atomics Library" section.

So yeah .. only solution is to upgrade to GCC 4.7

2
  • 1
    Well I found the problem (see update), you need to have GCC 4.7+ to have lock-free atomics
    – KoKuToru
    Oct 30, 2012 at 11:58
  • Is there a reasonable limit in milliseconds to how much time the boolean value in question can spend in any modern processor's cache line under one cycle? If I have a guarantee that no multiple accesses are happening under 0.1ms, or let's say 0.001ms, is it safe to assume I'll get expected behavior? Jan 19, 2016 at 12:35
13

Since I'm curious about this, I tested it myself on Ubuntu 12.04, AMD 2.3 GHz, gcc 4.6.3.

#if 1
#include <atomic>
std::atomic<bool> stop_(false);
#else
volatile bool stop_ = false;
#endif

int main(int argc, char **argv)
{
    long n = 1000000000;
    while (!stop_) {
        if (--n < 0)
            stop_ = true;
    }

    return 0;
}

Compiled with g++ -g -std=c++0x -O3 a.cpp

Although, same conclusion as @aleguna:

  • just bool:

real 0m0.004s
user 0m0.000s
sys 0m0.004s

  • volatile bool:

$ time ./a.out
real 0m1.413s
user 0m1.368s
sys 0m0.008s

  • std::atomic<bool>:

$ time ./a.out
real 0m32.550s
user 0m32.466s
sys 0m0.008s

  • std::atomic<int>:

$ time ./a.out
real 0m32.091s
user 0m31.958s
sys 0m0.012s


Update 2022-04-10, AMD Ryzen 3 3200G, g++ 9.3.0:

It looks like atomic has improved a lot in comparison to volatile. I increased the loop counter to 10,000,000,000, to have a more precise picture. Although the magnitude doesn't change by this adjustment:

  • std::atomic<bool>, std::atomic<int>: ~2.9s
  • volatile bool: ~5.4s
3
  • 7
    gcc 4.6 atomics are not lock free. Upgrade to gcc 4.7+
    – mchiasson
    Dec 22, 2014 at 20:08
  • So, 7-8 years have passed but I just tested your code on ubuntu 20 with g++ 9.4 and the atomic one is 0.773s, the volatile is 0.858s Apr 10, 2022 at 9:14
  • 1
    @CaptainCodeman Thank you for showing the improvements made by g++, I updated the answer. Apr 10, 2022 at 12:42
1

My guess is that this is an hardware question. When you write volatile you tell the compiler to not assume anything about the variable but as I understand it the hardware will still treat it as a normal variable. This means that the variable will be in the cache the whole time. When you use atomic you use special hardware instructions that probably means that the variable is fetch from the main memory each time it is used. The difference in timing is consistent with this explanation.

1
  • 1
    No. The cache is always used.
    – curiousguy
    Apr 4, 2019 at 23:09