How do you force a thread to see the updated value of a shared variable? I thought mutexes were supposed to help, but in the code below, I don't see the correct behavior:

#include <thread>
#include <vector>
#include <chrono>
#include <iostream>
#include <mutex>
using namespace std;

mutex coutm;

class Timer {
        Timer() : 
            m_elapsedTime (0) {}
        ~Timer() {};
        void start() {
            while (m_elapsedTime < 50) {
                unique_lock<mutex> timerLock{m_timerMutex};
                m_elapsedTime += chrono::duration_cast<chrono::milliseconds>(chrono::high_resolution_clock::now() - m_start).count();
                unique_lock<mutex> lck{coutm};
                cout << "Timer thread. New timer value = " << m_elapsedTime << endl; 
            unique_lock<mutex> lck{coutm};
            cout << "Time = " << m_elapsedTime << ". Done!" << endl;
        double getElapsedTime() { 
            return m_elapsedTime;
        double m_elapsedTime;
        decltype(chrono::high_resolution_clock::now()) m_start;
        mutex m_timerMutex;

void dummyPrint(Timer& m) {
    unique_lock<mutex> timerLock{m.m_timerMutex};
    auto t = m.getElapsedTime();
    while (t < 50) {
        unique_lock<mutex> lck{coutm};
        cout << "Waiting... Time = " << t << endl;

int main() {
    Timer t;
    thread timerThread {&Timer::start, std::ref(t)};
    thread t1{&dummyPrint, std::ref(t)};
    return 0;

My dummyPrint() function always sees a 0 value for the time even though access to Timer::m_elapsedTimer is guarded by a mutex. I'm sure I'm using mutexes wrong, but I don't understand what exactly is wrong.

  • Did you mean to refresh the value of t inside the loop? – user2357112 supports Monica Oct 26 '20 at 12:05
  • Stupid me! Yes. That was supposed to be inside the loop! Thanks. – curiouscoder Oct 26 '20 at 12:06
  • 1
    Timer::start isn't protecting its access to m_elapsedTime in the loop condition or the final print, either, and dummyPrint doesn't release the lock until the end of the function. – user2357112 supports Monica Oct 26 '20 at 12:07
  • You could use std::atomic<double> m_elapsedTime; to prevent UB – JHBonarius Oct 26 '20 at 12:26
  • Changed it like so: cpp.sh/83x2c – curiouscoder Oct 26 '20 at 12:30
thread timerThread {&Timer::start, std::ref(t)};
thread t1{&dummyPrint, std::ref(t)};

Just because you constructed the timerThread first, and t1 after it, you have no guarantees whatsoever that Timer::start will run first, in its execution thread, and dummyPrint will run second, in its own execution thread. And not only that it has to start executing first, it also has to lock the mutex first, in order for you to see your expected results. That's not guaranteed either. Your only guarantee here is that the new execution thread will enter the thread function at some point after std::thread is fully constructed. That's it.

For whatever reason, on your particular C++ implementation, the dummyPrint execution thread manages to get its act together first, locks the mutex, and finds that it hasn't been initialized, and m_elapsedTime is still 0. This is the behavior you are seeing.

You have very few guarantees, when it comes to multiple execution threads. If you require specific behavior you will need to enforce it yourself. Here, the simplest course of action is to add a separate bool flag, and a condition variable that indicates that timerThread finished initialization. timerThread initializes everything, sets the flag, and signals the condition variable. main waits for the flag to be set, before constructing the second std::thread.

P.S. Don't skimp on condition variables. yield is not as reliable as properly using condition variables.

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