I've reached a point in my project that requires communication between threads on resources that very well may be written to, so synchronization is a must. However I don't really understand synchronization at anything other than the basic level.

Consider the last example in this link: http://www.bogotobogo.com/cplusplus/C11/7_C11_Thread_Sharing_Memory.php

#include <iostream>
#include <thread>
#include <list>
#include <algorithm>
#include <mutex>

using namespace std;

// a global variable

// a global instance of std::mutex to protect global variable
std::mutex myMutex;

void addToList(int max, int interval)
    // the access to this function is mutually exclusive
    std::lock_guard<std::mutex> guard(myMutex);
    for (int i = 0; i < max; i++) {
        if( (i % interval) == 0) myList.push_back(i);

void printList()
    // the access to this function is mutually exclusive
    std::lock_guard<std::mutex> guard(myMutex);
    for (auto itr = myList.begin(), end_itr = myList.end(); itr != end_itr; ++itr ) {
        cout << *itr << ",";

int main()
    int max = 100;

    std::thread t1(addToList, max, 1);
    std::thread t2(addToList, max, 10);
    std::thread t3(printList);


    return 0;

The example demonstrates how three threads, two writers and one reader, accesses a common resource(list).

Two global functions are used: one which is used by the two writer threads, and one being used by the reader thread. Both functions use a lock_guard to lock down the same resource, the list.

Now here is what I just can't wrap my head around: The reader uses a lock in a different scope than the two writer threads, yet still locks down the same resource. How can this work? My limited understanding of mutexes lends itself well to the writer function, there you got two threads using the exact same function. I can understand that, a check is made right as you are about to enter the protected area, and if someone else is already inside, you wait.

But when the scope is different? This would indicate that there is some sort of mechanism more powerful than the process itself, some sort of runtime environment blocking execution of the "late" thread. But I thought there were no such things in c++. So I am at a loss.

What exactly goes on under the hood here?

  • 2
    I would like to add that mutex locking is atomic. Hope this helps. – Incomputable Feb 7 '16 at 10:13

myMutex is global, which is what is used to protect myList. guard(myMutex) simply engages the lock and the exit from the block causes its destruction, dis-engaging the lock. guard is just a convenient way to engage and dis-engage the lock.

With that out of the way, mutex does not protect any data. It just provides a way to protect data. It is the design pattern that protects data. So if I write my own function to modify the list as below, the mutex cannot protect it.

void addToListUnsafe(int max, int interval)
    for (int i = 0; i < max; i++) {
        if( (i % interval) == 0) myList.push_back(i);

The lock only works if all pieces of code that need to access the data engage the lock before accessing and disengage after they are done. This design-pattern of engaging and dis-engaging the lock before and after every access is what protects the data (myList in your case)

Now you would wonder, why use mutex at all, and why not, say, a bool. And yes you can, but you will have to make sure that the bool variable will exhibit certain characteristics including but not limited to the below list.

  1. Not be cached (volatile) across multiple threads.
  2. Read and write will be atomic operation.
  3. Your lock can handle situation where there are multiple execution pipelines (logical cores, etc).

There are different synchronization mechanisms that provide "better locking" (across processes versus across threads, multiple processor versus, single processor, etc) at a cost of "slower performance", so you should always choose a locking mechanism which is just about enough for your situation.


Let’s have a look at the relevant line:

std::lock_guard<std::mutex> guard(myMutex);

Notice that the lock_guard references the global mutex myMutex. That is, the same mutex for all three threads. What lock_guard does is essentially this:

  • Upon construction, it locks myMutex and keeps a reference to it.
  • Upon destruction (i.e. when the guard's scope is left), it unlocks myMutex.

The mutex is always the same one, it has nothing to do with the scope. The point of lock_guard is just to make locking and unlocking the mutex easier for you. For example, if you manually lock/unlock, but your function throws an exception somewhere in the middle, it will never reach the unlock statement. So, doing it the manual way you have to make sure that the mutex is always unlocked. On the other hand, the lock_guard object gets destroyed automatically whenever the function is exited – regardless how it is exited.

  • 1
    You are right ofcourse, but I am afraid I've been missunderstood. What I actually mean is how it works at the low level. A piece of data is just memory set to something. If you want to protect that data, you've got to encapsulate it. It doesn't appear to be anything like that at work here, you can easily lock down a simple int in the same manner. So how is the protection mechanism that the lock represents actually implemented? Since scope is irrelevant, something else must be intersecting the late thread, shutting it down, and awakening it again once the resource is free again. Get me? – Deviatore Feb 7 '16 at 10:43
  • @Daviatore: It's called the operating system scheduler – MikeMB Feb 7 '16 at 10:58
  • This isn't really about encapsulation. The mutex is essentially a resource which you acquire when lock() is called. If the resource can't be acquired (because another thread is holding it), what happens depends on the concrete implementation; either mutual exclusion algorithms are used, or the operating system handles it, putting your thread onto a waiting queue (see for example this tutorial on POSIX Threads Programming for how UNIX/Linux systems do it). – mindriot Feb 7 '16 at 11:06

This is precisely what a lock does. When a thread takes the lock, regardless of where in the code it does so, it must wait its turn if another thread holds the lock. When a thread releases a lock, regardless of where in the code it does so, another thread may acquire that lock.

Locks protect data, not code. They do it by ensuring all code that accesses the protected data does so while it holds the lock, excluding other threads from any code that might access that same data.

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