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Here is my attempt at implementing a C++ event.

class Event{
    typedef std::tr1::function<void( int& )> CallbackFunction;
    std::list< CallbackFunction > m_handlers;

    template<class M>
    void AddHandler(M& thisPtr, void typename (M::*callback)(int&)) 
    {           
        CallbackFunction bound = std::tr1::bind(callback, &thisPtr, _1);
        m_handlers.push_back(bound);
    }

    void operator()(int& eventArg) 
    { 
        iterate over list...
        (*iter)(eventArg);

    }}

The trouble here is thread-safety. If AddHandler and operator() are called at the same time things could break.

What is the best way to sync this? Using a mutex could kill performance. I wonder what happens behind the scenes of boost::signals or C# event in this case.

share|improve this question
1  
How often are they called per second? Why does this same object need to be available to all threads? Can't they all just send a mutex message that is received by one thread? – Keldon Alleyne Jan 12 '12 at 0:02
up vote 1 down vote accepted

A mutex is definitely what you're looking for. If each Event has its own mutex, I wouldn't worry much about performance; the reason is that unless you're adding a lot of handlers during the time you're handling events, it's unlikely the mutex will be in contention and slow you down.

However, if you have more than one thread calling the operator() method on the same object, this mutex could be a problem. But without it, how will you ensure your callbacks are invoked in a thread-safe way anyhow? (I notice you're passing in an integer reference and returning void, so I'm assuming these are not reentrant handlers.)

EDIT: very good question in your comment. To be honest, I never put much thought into whether or not mutexes had much overhead when used in a synchronous way. So I put together this little test.


#include <stdio.h>
#include <pthread.h>

#define USE_PTHREAD_MUTEX 1

int main(int argc, char * argv[]) {

pthread_mutex_t mutex;
pthread_mutex_init(&mutex, NULL);

long useless_number = 0;
long counter;

  for(counter = 0; counter < 100000000; counter++) {
    #if USE_PTHREAD_MUTEX
    pthread_mutex_lock(&mutex);
    #endif
    useless_number += rand();

    #if USE_PTHREAD_MUTEX
    pthread_mutex_unlock(&mutex);
    #endif
  }

  printf("%ld\n", useless_number);

}

I ran this on my system and got the following runtimes.

With USE_PTHREAD_MUTEX 0, the average runtime is 1.2 seconds.

With USE_PTHREAD_MUTEX 1, the average runtime is 2.8 seconds.

Thus, to answer your question, there is definitely overhead. Your mileage may vary. Besides, if multiple threads are competing for access to a resource, more time will be spent blocking, necessarily. Also, in a purely synchronous context, it's likely that more time will be spent accessing the shared resource than waiting for a mutex to lock/unlock. That is to say, the overhead of the mutex logic itself will probably be insignificant compared to these things.

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how expensive is a mutex without contention? say I syncronously call AddHandler 100000s times. What's the performance damage to expect here? – Leo Jan 12 '12 at 0:25
    
Great question. I've updated my answer with a little test, because I too am curious about that kind of performance impact. – Tom Jan 12 '12 at 1:34
2  
Make a copy of the callback list in operator(). Acquire a mutex only for the duration of the copy - bounding the duration of the lock. You also don't want a mutex around the notification loop due to the risk of deadlock. You could consider using a spin-lock if thread contention is low - ~4 times faster than a mutex but a disaster if the lock is held too long under high contention (e.g. avoid memory allocations while locked). Profiling is the only way to know for sure. – mcmcc Jan 12 '12 at 3:59

First, before you dismiss any implementation possibility as being insufficiently 'fast', you need to determine what the performance requirements actually are. Are you going to be triggering these events thousands of times every second? And if you are, are you really going to need to be adding handlers to the handlers container the whole time too.

If the answer to both those questions is, for some reason, actually 'yes' then you may need to investigate lock-free containers. This will mean building your own container rather than being able to use an stl list. Lock-free containers will use atomic intrinsics (such as InterlockedCompareExchange in windows for instance) to determine atomically if the end of the list is NULL or otherwise. They would then use a similar intrinsic to actually append to the list. Additional complications will occur if multiple threads attempt to add handlers at the same time.

However in a world of multi-core machines and instruction re-ordering and so-on, these approaches can be fraught with danger. I personally use an event system not dissimilar to what you describe, I use it with Critical Sections (which are quite efficient in windows at least), and I do not experience performance issues. But on the other hand, nothing is sent through the event system any faster than about 20Hz or so.

As with any performance-related question the answer is always going to be based on the answer to another question; Exactly where do you need your performance?

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This event is a generic helper so it's optimal if it handles efficiently any use pattern. thanks for sharing your experience, this pushes me to the critical_section solution. – Leo Jan 12 '12 at 0:34

If list really is your class then due to the nature of it, you don't need to lock every time you access it. You will lock a mutex to post to the end of the list, and you will also lock when you think you might have reached the end.

You should keep a count of the number of handlers in the class and when you are about to start iterating, you can happily iterate without locking until you reach this number.

If handlers are ever going to be removed, then you have more of a thread-contention issue.

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That is a great observation. I can use interlocked... to count that. But unfortunately I will probably add a "remove" function so a better solution is required. Any thoughts? – Leo Jan 12 '12 at 0:18
    
If you get an "unsubscribe" you mark the record with a flag rather than move it from the list. The event handler thread checks the flag and can remove unsubscribed items from the list, and you only need to lock if it is the last list item, as only the end of the list has contention. – CashCow Jan 12 '12 at 10:21

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