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Take the following code:

#include <iostream>
#include <thread>
#include <mutex>
#include <condition_variable>
#include <chrono>

using namespace std;

int main() {
  mutex m;
  condition_variable c;

  bool fired = false;
  int i = 0;

  // This thread counts the times the condition_variable woke up.
  // If no spurious wakeups occur it should be close to 5.
  thread t([&]() {
    unique_lock<mutex> l(m);
    while (!fired) {
      c.wait_for(l, chrono::milliseconds(100));

  // Here we wait for 500ms, then signal the other thread to stop
    unique_lock<mutex> l(m);
    fired = true;
    cout << i << endl;

Now, when I build this using clang++ -std=c++11 -pthread foo.cpp everything is fine, it outputs 4 on my machine. When I build it with g++ -std=c++11 -pthread foo.cpp however I get something very large every time, e.g. 81513. I realize the number of spurious wakeups is undefined, but I was surprised to see it so high.

Additional information: When I replace the wait_for by a simple wait both clang and g++ output 0.

Is this a bug / feature in g++? Why is it even different from clang? Can I get it to behave more reasonably?

Also: gcc version 4.7.3 (Debian 4.7.3-4).

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A good thing to know would be which standard library you use in the clang case. It runs fine with gcc 4.8.1 on my system btw. (won't compile with 4.7.3). stracing all threads might lead to futher useful information. –  PlasmaHH Sep 6 '13 at 13:30
gcc (Ubuntu/Linaro 4.7.2-2ubuntu1) 4.7.2 gives: 4 –  Dieter Lücking Sep 6 '13 at 13:39
clang uses the same standard library as g++, i don't have libc++ on that system. it's a debian testing btw. –  lucas clemente Sep 6 '13 at 13:59
Fwiw, Apple LLVM version 4.2 (clang-425.0.28), and I likewise get 4, just as your clang does. –  WhozCraig Sep 6 '13 at 14:40
G++-4.7.3 on Coliru outputs "4" for this program, so there's some other variable here than the compiler version. –  Casey Sep 6 '13 at 16:08
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2 Answers

up vote 1 down vote accepted

I managed to get g++-4.8 running, and the problem is gone. Very weird, seems like a bug in g++-4.7.3, although I wasn't able to reproduce it on another machine.

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Edit: This is no answer, but I keep it for the comments.

Isn't this a race condition (The lock and condition_variable take the same mutex) ?

unique_lock<mutex> l(m);
fired = true;
cout << i << endl;
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No. Because the mutex is locked the cv broadcast will be sent, but not wake (yet) all waiters, but a condition variable cannot come out of wait until it can also acquire the mutex (timed wait not withstanding). IOW, this is exactly how you're supposed to do this. A cv-waiter, once active, owns the mutex until it relinquishes it via another wait or via a plain unlock. I would use a lock_guard myself, but this should work. –  WhozCraig Sep 6 '13 at 14:34
@WhozCraig This is correct code but I wouldn't say it's exactly how to do this. The CV broadcast will likely wake all the waiters, and they will immediately block on the mutex. Notifying the condition variable after unlocking the mutex results in less contention. –  Casey Sep 6 '13 at 14:43
I am especially concerned about 'cout << i << endl' –  Dieter Lücking Sep 6 '13 at 14:48
@Casey I concur. If the last thing you're going to do before releasing a mutex is a cv-notify/broadcast, it makes little sense to unlock it after, rather than before. However that isn't the case here. For whatever reason he wants to dump i after the notify, and should still be able to since he still owns the mutex. I would be interested in knowing what the results would be if he set fired, output i, then manually unlocked and then signaled. The output is the same (expectedly) on my clang rig, but his gcc rig may have something else in mind by the looks of it. –  WhozCraig Sep 6 '13 at 14:48
@Casey Wouldn't that potentially result in missed notifications? Thre ad A does it's work, releases the mutex, then then notifies the condition variable. Thread B was waiting for the mutex due to a previous notify. Upon the release of the mutex, B grabs it grabs its work context and releases the mutex. A's notification happens, but since B isn't waiting, it's lost. B finishes its work, locks the mutex, and waits on the condition variable. But since nobody was waiting for it, it got lost. (Besides, if you wanted only one thread, then notify_one, not notify_all) –  Andre Kostur Sep 6 '13 at 14:51
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