9

Let's say that we want to make class A thread-safe using an std::mutex. I am having my copy constructor and assignment operator similarly to the code below:

#include <mutex>

class A {
private:
  int i;
  mutable std::mutex mtx;

public:
  A() : i(), mtx() { }

  A(const A& other) : i(), mtx()
  {
    std::lock_guard<std::mutex> _lock(other.mtx);
    i = other.i;
  }

  A& operator=(const A& other)
  {
    if (this!=&other) {
      std::lock_guard<std::mutex> _mylock(mtx), _otherlock(other.mtx);
      i = other.i;
    }
    return *this;
  }

  int get() const
  {
    std::lock_guard<std::mutex> _mylock(mtx);
    return i;
  }
};

I do not think that it has any problems, other than the possibility of other to be destroyed by another thread before being copied, which I can deal with.

My issue is that I haven't seen this pattern anywhere, so I do not know if people just haven't had a need for that or that it is plainly wrong for reasons I currently don't see.

Thanks

NOTES:

This is just an example. I can have an arbitrary number of member variables of any type, it does not have to be just an int.

After Martin York's comment for possible deadlocking, this is an updated version that uses copy-and-swap (copy elision is also possible, but it wouldn't handle efficiently the self-assignment case).

I also changed int to T, so people cannot assume that it is a POD.

template<typename T>
class A {
private:
  T t;
  mutable std::mutex mtx;

public:
  A() : t(), mtx() { }

  A(const A& other) : t(), mtx()
  {
    std::lock_guard<std::mutex> _lock(other.mtx);
    t = other.t;
  }

  A& operator=(const A& other)
  {
    if (this!=&other) {
      A tmp(other);
      std::lock_guard<std::mutex> _lock(mtx);
      std::swap(t, tmp.t);
    }
    return *this;
  }

  T get() const
  {
    std::lock_guard<std::mutex> _lock(mtx);
    return t;
  }

};
7
  • Thread-safety problems in an assignment operator might be a symptom of other things going wrong in your application. For instance, if multiple threads are assigning to the same object simultaneously, making operator= thread safe with a mutex will prevent data inconsistencies but will lead to your content being silently discarded/overwritten... Oct 27, 2010 at 21:52
  • What do you mean discarded/overwritten? My use case is that I want to copy construct or assign to my object and be in a consistent state. I do not expect all copies to be identical, but I do expect to have an internal consistent state.
    – ipapadop
    Oct 27, 2010 at 21:55
  • @André Caron: But that would be expected behavior. If I have 5 threads assigning to the object the value assigned by the last person to do the assign is what I expect in the object. What the others have done is irrelevant. Data consistency is the ONLY thing I am worried about. Oct 27, 2010 at 21:57
  • 4
    @ipapadop: Using the copy and swap idiom in your assignment should help reduce the complexity of the assignment operator. And also remove the current problem of deadlock. Thread 1: x=y; Thread 2: y=x; This situation has the possibility of deadlock. Oct 27, 2010 at 21:58
  • @Martin York: that is why I say it might be a symptom of something else going wrong. Most of the multi-threading scenarios I've come across cumulate values produced by different threads (i.e. a shared log file, producer/consumer, etc.). Of course, data consistency is always a necessity, but there are few cases where you only want the last value. Oct 27, 2010 at 22:29

5 Answers 5

6

Old question, new answer:

Imho, a better way to deal with the dead-lock problem of the original copy assignment operator is:

  A& operator=(const A& other)
  {
    if (this!=&other) {
      std::unique_lock<std::mutex> _mylock(mtx, std::defer_lock),
                                   _otherlock(other.mtx, std::defer_lock);
      std::lock(_mylock, _otherlock);
      i = other.i;
    }
    return *this;
  }

I.e. use std::lock(L1, L2) to simultaneously lock the two mutexes without fear of deadlock. This is likely to be higher performance than the copy/swap idiom, especially if the member data consists of std::vector, std::string, or types that contain vectors and/or strings.

In C++1y (we hope y is 4), there is a new <shared_mutex> header providing read/write lock capability which may provide a performance boost (performance testing would be necessary for specific use cases to confirm that). Here is how it would be used:

#include <mutex>
#include <shared_mutex>

class A {
private:
  int i;
  mutable std::shared_mutex mtx;

public:
  A() : i(), mtx() { }

  A(const A& other) : i(), mtx()
  {
    std::shared_lock<std::shared_mutex> _lock(other.mtx);
    i = other.i;
  }

  A& operator=(const A& other)
  {
    if (this!=&other) {
      std::unique_lock<std::shared_mutex> _mylock(mtx, std::defer_lock);
      std::shared_lock<std::shared_mutex> _otherlock(other.mtx, std::defer_lock);
      std::lock(_mylock, _otherlock);
      i = other.i;
    }
    return *this;
  }

  int get() const
  {
    std::shared_lock<std::shared_mutex> _mylock(mtx);
    return i;
  }
};

I.e. this is very similar to the original code (modified to use std::lock as I've done above). But the member mutex type is now std::shared_mutex instead of std::mutex. And when protecting a const A (and assuming no mutable members besides the mutex), one need only lock the mutex in "shared mode". This is easily done using shared_lock<shared_mutex>. When you need to lock the mutex in "exclusive mode", you can use unique_lock<shared_mutex>, or lock_guard<shared_mutex> as appropriate, and in the same manner as you would have used this facilities with std::mutex.

In particular note that now many threads can simultaneously copy construct from the same A, or even copy assign from the same A. But only one thread can still copy assign to the same A at a time.

3
  • If one were using the assignment by value A& operator=(A other) would the need for a sharedmutex be avoided? (Only a normal mutex would be necessary).
    – alfC
    Feb 7, 2020 at 22:17
  • 2
    In either case, only a normal mutex is necessary. The question is: can the code run faster if you allow multiple readers of the protected data to read at the same time? In the case of A& operator=(A other), this still involves copy constructing an A if you want to assign from it. If the copy constructor uses an exclusive mutex, it can only be copy constructed from one thread at a time. If it uses a shared mutex with a read lock, it can be copy constructed from many threads at a time. This doesn't mean that shared mutex is always faster though. shared mutexes can have higher overhead. Feb 8, 2020 at 4:32
  • but you show a solution with a shared_mutex. No? Amyway i need to study this more to understand the subtleties. Here it is another related challenge stackoverflow.com/q/60087792/225186 if you are interested
    – alfC
    Feb 8, 2020 at 4:48
2

Ignoring all implementation details, the reason you don't see this pattern is because it is very likely that you are locking on the wrong abstraction level.

  • If the objects are accessed from multiple threads, then you (additionally) have to manage the lifetime of the objects, which cannot be managed from within the objects.
  • For lifetime management you already need at least one object-external lock, so better use that.
  • This scheme only makes sense for single-get() objects -- if your object has more (than one member and more) than one get() function, then reading from the object can/will result in inconsistent data.

Getting correct multithreaded code isn't just a matter of makeing sure nothing "crashes" and single objects stay in a consistent state. And if you (think you) need the above scheme you may think you're save when your app is still doing-the-wrong-thing.

As for implementation details: Since you are already using C++0x for this, you also should implement appropriately defined move operations.

3
  • I do not particularly care about the lifetime - this is a different issue, completely orthogonal to have a thread-safe object. I am using the pattern above to protect access to shared resources that are not thread-safe and in addition inherently not scalable (so I do not care about performance and the shared resource outlives the threads). The wrong thing here is to have an internal inconsistent state, not getting different values. Thanks for the reminder on the move operations though.
    – ipapadop
    Oct 28, 2010 at 23:33
  • I wonder what special resources you have here that are not scalable, outlive the threads and still need to be copied? Or do you have "wrapper objects" to your resources and need to copy these?
    – Martin Ba
    Oct 29, 2010 at 6:12
  • Simple use-case (not mine, but you get the idea): a queue that threads put objects in it. Every now and then, a thread comes and copies that queue (does not clear it) and dumps it into a file. The other threads continue to use the initial queue and continue to fill it. You now have a snapshot system.
    – ipapadop
    Oct 29, 2010 at 6:26
1

I'm not an authority on this, because multi-threading is tricky, but it looks fine so far. BTW, you probably meant

std::lock_guard<std::mutex>

and in the copy-ctor:

A(const A& other) : mtx()
{
  std::lock_guard<std::mutex> _lock(other.mtx);
  i = other.i;
}

Another way to ensure thread-safety for other is only using 'safe' getters to access it, although this would not behave as expected when multiple getters are called. But, beware of references!

2
  • I'm sorry, I corrected the lock_guards. I believe that in order to be in a consistent state, I think the safest way is to lock the whole object rather than using thread-safe getters.
    – ipapadop
    Oct 27, 2010 at 21:47
  • Sure. But if e.g. one thread-safe getter would be enough for a certain class you can avoid the additional complexity (in terms of what-could-happen). Oct 27, 2010 at 21:55
0

You don't really see it because the Standard threading facilities are exceedingly new and I don't know of a single compiler that supports them - you'd get further looking for boost::thread examples. Also, your gratuitous use of synchronization will likely lead to poor performance, but that's just my opinion.

3
  • Yes, boost does it as well - I just wrote it in C++0x provided facilities that are supported by some compilers already (GCC 4.3+, MSVC 10 and some others). It will lead to less-than-optimal performance, but it is the only way if you do not have a lock-free data structure.
    – ipapadop
    Oct 27, 2010 at 21:52
  • @ipapadop: MSVC10 doesn't support Standard threading facilities. They rolled their own (the ConcRT) for that release. The performance I meant is that threading of an application must be designed in before-hand. What if somebody who wishes to use your object isn't multi-threaded, or it's otherwise unnecessary? The fact is that you, as an object provider, have no idea when, where, or even if the object user requires synchronization unless threading is an explicit part of the purpose of the object.
    – Puppy
    Oct 27, 2010 at 22:07
  • It's used in my own multithreaded code. You are right about MSVC - I forgot I changed to using Intel Compiler + TBB on Windows which they offer all that. I can always disable the mutex by passing a null_mutex that has null_mutex::lock() and null_mutex::unlock() that do nothing.
    – ipapadop
    Oct 28, 2010 at 0:01
0

this is more correct, but not entirely robust:

#include <mutex>

class A {
private:
    int i;
    std::mutex mtx;

public:
    A() : i(0), mtx() {
    }
    /* this is one option for implementation, but would be rewritten when there are more ivars in order to reduce acquisition counts */
    A(A& other) : i(other.get()), mtx() {
    }

    ~A() {
        /* unsafe if subclassed, also useful for determining whether objects are destroyed prematurely (e.g., by their containers */
        std::lock_guard<std::mutex> _mylock(this->mtx);
    }

    A& operator=(A& other) {
        std::lock_guard<std::mutex> _mylock(this->mtx);
        std::lock_guard<std::mutex> _otherlock(other.mtx);
        this->i = other.i; /* you could call other.get() and bypass the lock_guard, but i'm assuming there's really more work to be done here */
        return *this;
    }

    int get() {
        std::lock_guard<std::mutex> _mylock(this->mtx);
        return this->i;
    }
private:
    /* prohibited */
    A(const A& other);
    /* also prohibited */
    A& operator=(const A& other);
};
4
  • I do not wish to use the get() function - mainly because it is not generic enough; what happens if I have multiple values (look also at my note)? You are also making two mistakes: your version would deadlock in a self-assignment case and mutex.lock() can throw an exception in your destructor. Finally, I am declaring mutex as mutable, so the const does not create any problems.
    – ipapadop
    Oct 27, 2010 at 23:54
  • @ipapdop re init: you can still initialize correctly with one acquisition if you create an object to pass as an argument. re deadlocks: it's good to create a second template parameter for the type of lock you'll use, or base classes which are lockable. subclasses with locks are often ideal because you'd rather protect the object's vulnerable state, rather than the members within restricted scopes. attempting to ensure thread safety using a basic mutex for an arbitrary T is too often tedious and error prone.
    – justin
    Oct 28, 2010 at 16:50
  • (cont) a singular interface (as a generic pattern) is very susceptable to deadlocks (some of which will be intensely difficult to reproduce). your example is trivial in comparison to real world usage; a recursive mutex is more practical generalized object lock. it's also best to write/use a few additional objects to convey and enforce your intentions at every stage within the implementation. using mutable will only save you from rewriting existing code today. if thread safety and program correctness is your primary concern, i encourage you to omit it.
    – justin
    Oct 28, 2010 at 16:50
  • As a general rule, I avoid recursive locks as IMO they just hide a bad use of locks. Yes it is a trivial example but I don't think I should post the whole thing - however, it is very similar to what I have so 1) I cannot use atomic operations and 2) it has to conform to common practice where a get() is a const. I do not see why mutable is such a bad practice, since it has nothing to do with the internal state of the object - it is there to allow the mutex to enforce thread-safety.
    – ipapadop
    Oct 28, 2010 at 23:40

Your Answer

By clicking “Post Your Answer”, you agree to our terms of service and acknowledge you have read our privacy policy.

Not the answer you're looking for? Browse other questions tagged or ask your own question.