5

Say I have a thread running a member method like runController in the example below:

class SomeClass {
public:
    SomeClass() { 
         // Start controller thread
         mControllerThread = std::thread(&SomeClass::runController, this) 
    }

    ~SomeClass() {
         // Stop controller thread
         mIsControllerThreadInterrupted = true;
         // wait for thread to die.
         std::unique_lock<std:::mutex> lk(mControllerThreadAlive); 
    }

    // Both controller and external client threads might call this
    void modifyObject() {
         std::unique_lock<std::mutex> lock(mObjectMutex);
         mObject.doSomeModification();
    }
    //...
private:
    std::mutex mObjectMutex;
    Object mObject;

    std::thread mControllerThread;
    std::atomic<bool> mIsControllerInterrupted;
    std::mutex mControllerThreadAlive;

    void runController() {        
        std::unique_lock<std::mutex> aliveLock(mControllerThreadAlive);
        while(!mIsControllerInterruped) {
            // Say I need to synchronize on mObject for all of these calls
            std::unique_lock<std::mutex> lock(mObjectMutex);
            someMethodA();
            modifyObject(); // but calling modifyObject will then lock mutex twice
            someMethodC();
        }
    }
    //...
};

And some (or all) of the subroutines in runController need to modify data that is shared between threads and guarded by a mutex. Some (or all) of them, might also be called by other threads that need to modify this shared data.

With all the glory of C++11 at my disposal, how can I ensure that no thread ever locks a mutex twice?

Right now, I'm passing unique_lock references into the methods as parameters as below. But this seems clunky, difficult to maintain, potentially disastrous, etc...

void modifyObject(std::unique_lock<std::mutex>& objectLock) {

    // We don't even know if this lock manages the right mutex... 
    // so let's waste some time checking that.
    if(objectLock.mutex() != &mObjectMutex)
         throw std::logic_error();

    // Lock mutex if not locked by this thread
    bool wasObjectLockOwned = objectLock.owns_lock();
    if(!wasObjectLockOwned)
        objectLock.lock();

    mObject.doSomeModification();

    // restore previous lock state
    if(!wasObjectLockOwned)
        objectLock.unlock();

}

Thanks!

  • I am a little confused. Do you have unchecked try_to_locks? How can a thread lock a mutex and then forget about it? – Red Alert Apr 23 '14 at 3:25
  • 1
    I don't understand the nature of the problem. You lock the mutex right before reading or modifying shared data, and unlock right after. You would normally have an instance of unique_lock on the stack, not passed in as a parameter. You must be doing something quite unorthodox if locking the same mutex twice is an actual risk in your design. Can you show exactly how this may happen for you? – Igor Tandetnik Apr 23 '14 at 3:43
  • @RedAlert Ah, perhaps std::try_to_lock is the answer I was looking for? Can I just call that from every function that needs a lock instead of creating a local unique_lock or passing locks around? – mxdubois Apr 23 '14 at 3:44
  • @IgorTandetnik I updated the question with a more explicit example, but let me know if it's still unclear. – mxdubois Apr 23 '14 at 4:04
  • @mxdubois no, then you'd lose mutual exclusion with other threads. You need to resolve this at the design level. In your example, a good fix would be to completely remove mutexes from modifyObject(), and instead have only the functions that call it handle the access to the shared resource. – Red Alert Apr 23 '14 at 4:24
8

There are several ways to avoid this kind of programming error. I recommend doing it on a class design level:

  • separate between public and private member functions,
  • only public member functions lock the mutex,
  • and public member functions are never called by other member functions.

If a function is needed both internally and externally, create two variants of the function, and delegate from one to the other:

public:
    // intended to be used from the outside
    int foobar(int x, int y)
    {
         std::unique_lock<std::mutex> lock(mControllerThreadAlive);
         return _foobar(x, y);
    }
private:
    // intended to be used from other (public or private) member functions
    int _foobar(int x, int y)
    {
        // ... code that requires locking
    }

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