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For example, I've got a some work that is computed simultaneously by multiple threads.

For demonstration purposes the work is performed inside a while loop. In a single iteration each thread performs its own portion of the work, before the next iteration begins a counter should be incremented once.

My problem is that the counter is updated by each thread.

As this seems like a relatively simple thing to want to do, I presume there is a 'best practice' or common way to go about it?

Here is some sample code to illustrate the issue and help the discussion along. (Im using boost threads)

class someTask {
    int mCounter; //initialized to 0
    int mTotal; //initialized to i.e. 100000
    boost::mutex cntmutex;                
    int getCount()
            boost::mutex::scoped_lock lock( cntmutex );
            return mCount;
    void process( int thread_id, int numThreads )
        while ( getCount() < mTotal )
            // The main task is performed here and is divided 
            // into sub-tasks based on the thread_id and numThreads

                            // Wait for all thread to get to this point

            mCounter++;  // < ---- how to ensure this is only updated once?
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There is more than that: is it necessary that the threads wait for each other ? Could you not have a designated master thread ? Or perhaps a scheduler that would do nothing but wait ? –  Matthieu M. May 5 '12 at 18:45
@MatthieuM ah yes, waiting is important all threads must complete their work for the iteration before the increment is performed, i'll add it. –  AlexS May 5 '12 at 18:51
Your edit is erroneous: you need to use the same lock for all accesses to a given set of variables. Therefore you only need one lock here. –  Matthieu M. May 6 '12 at 9:40
my bad, fixed it. –  AlexS May 6 '12 at 13:23

4 Answers 4

The main problem I see here is that you reason at a too-low level. Therefore, I am going to present an alternative solution based on the new C++11 thread API.

The main idea is that you essentially have a schedule -> dispatch -> do -> collect -> loop routine. In your example you try to reason about all this within the do phase which is quite hard. Your pattern can be much more easily expressed using the opposite approach.

First we isolate the work to be done in its own routine:

void process_thread(size_t id, size_t numThreads) {
    // do something

Now, we can easily invoke this routine:

#include <future>
#include <thread>
#include <vector>

void process(size_t const total, size_t const numThreads) {
    for (size_t count = 0; count != total; ++count) {
         std::vector< std::future<void> > results;

         // Create all threads, launch the work!
         for (size_t id = 0; id != numThreads; ++id) {
             results.push_back(std::async(process_thread, id, numThreads));

         // The destruction of `std::future`
         // requires waiting for the task to complete (*)

(*) See this question.

You can read more about std::async here, and a short introduction is offered here (they appear to be somewhat contradictory on the effect of the launch policy, oh well). It is simpler here to let the implementation decides whether or not to create OS threads: it can adapt depending on the number of available cores.

Note how the code is simplified by removing shared state. Because the threads share nothing, we no longer have to worry about synchronization explicitly!

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This looks like perfectly good solution to the question I posted. (I have to say though I prefer low level solutions, simply because I know exactly what is going on.) Though i'm not sure what 'result' is being pushed into the result vector? –  AlexS May 6 '12 at 12:59
On the other hand this is not what I want because the task is creating threads, whereas I have a finite thread pool that processes tasks until all tasks in a queue are complete, when there are no tasks they wait for one. Some tasks are specified to be performed by one thread, some tasks are performed by multiple threads. hope that made sense. –  AlexS May 6 '12 at 13:08
@AlexS: The idea of the vector is just to store the future (using move construction) so that its destruction is delayed. This let us create several concurrent tasks, that may start running in parallel. Regarding async, actually it does not necessarily create a thread: you would have to using std::launch::async as the first parameter to explicitly ask for a new thread, if you do not use it, then the runtime will choose whether to create a thread or not. A good runtime is likely to maintain its own pool... –  Matthieu M. May 6 '12 at 13:17
@AlexS: [cont] If you want more precise control over the threads, it is fine too. async is only the tip of the iceberg, you are free to dive under the surface and bring up your own thread management policy in its stead. –  Matthieu M. May 6 '12 at 13:18
Thanks for your advice, I think in the long term it is probably better to try and get C++11 thread API 'under my belt'. So I'm going to go get it now and switch over from boost.threads before I get any deeper. Cheers. –  AlexS May 6 '12 at 13:28

You protected the counter with a mutex, ensuring that no two threads can access the counter at the same time. Your other option would be using Boost::atomic, c++11 atomic operations or platform-specific atomic operations.

However, your code seems to access mCounter without holding the mutex:

    while ( mCounter < mTotal )

That's a problem. You need to hold the mutex to access the shared state.

You may prefer to use this idiom:

  1. Acquire lock.

  2. Do tests and other things to decide whether we need to do work or not.

  3. Adjust accounting to reflect the work we've decided to do.

  4. Release lock. Do work. Acquire lock.

  5. Adjust accounting to reflect the work we've done.

  6. Loop back to step 2 unless we're totally done.

  7. Release lock.

share|improve this answer
good point about mCounter I had taken care of this in the 'real' code, i'll put something in and check out atomic. –  AlexS May 5 '12 at 18:52
Im sorry, I don't understand the idiom you have posted or more precisely how it differs from what I currently have, in other words I dont see how it avoids incorrectly incrementing the counter. –  AlexS May 5 '12 at 19:13
@AlexS: The idea is that you isolate the parts of the code that take time (doing actual work, waiting for work) and wrap them in an unlock/lock pair. At all other times, you hold the lock. It inverts the usual pattern of acquiring the lock, doing something quick, and then releasing it to the pattern of releasing the lock, doing something slow, and then re-acquiring it. –  David Schwartz May 5 '12 at 19:17
so for example, at point 5 only one thread would do this part due to the lock in point 4? –  AlexS May 5 '12 at 19:38
@AlexS: Correct. –  David Schwartz May 5 '12 at 20:52

You need to use a message-passing solution. This is more easily enabled by libraries like TBB or PPL. PPL is included for free in Visual Studio 2010 and above, and TBB can be downloaded for free under a FOSS licence from Intel.

concurrent_queue<unsigned int> done;
std::vector<Work> work; 
// fill work here
parallel_for(0, work.size(), [&](unsigned int i) {

It's lockless and you can have an external thread monitor the done variable to see how much, and what, has been completed.

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I would like to disagree with David on doing multiple lock acquisitions to do the work.

Mutexes are expensive and with more threads contending for a mutex , it basically falls back to a system call , which results in user space to kernel space context switch along with the with the caller Thread(/s) forced to sleep :Thus a lot of overheads.

So If you are using a multiprocessor system , I would strongly recommend using spin locks instead [1].

So what i would do is :

=> Get rid of the scoped lock acquisition to check the condition.

=> Make your counter volatile to support above

=> In the while loop do the condition check again after acquiring the lock.

class someTask {
 volatile int mCounter; //initialized to 0       : Make your counter Volatile
 int mTotal; //initialized to i.e. 100000
 boost::mutex cntmutex;                

 void process( int thread_id, int numThreads )
    while ( mCounter < mTotal ) //compare without acquiring lock
        // The main task is performed here and is divided 
        // into sub-tasks based on the thread_id and numThreads

        //Now compare again to make sure that the condition still holds
        //This would save all those acquisitions and lock release we did just to 
        //check whther the condition was true.
        if(mCounter < mTotal)



share|improve this answer
I dont think this will work, multiple threads will increment mCounter after the work is done. Unless i've missed something??? –  AlexS May 10 '12 at 18:35
It does work ! the lockless comparison avoids overheads and the locked comparison enforces sanity of your increments. Secondly lockless comparison with volatile variable makes sure that all threads look at the same copy of the variable. –  Jay D May 10 '12 at 19:20
but when one thread unlocks the mutex, another thread is free to lock it and proceed to mCounter++ , ???? –  AlexS May 10 '12 at 19:28
i.e. if there are two threads, and mTotal = 10. The while loop will exit after 5 iterations because on each iteration the mCounter is incremented twice. There should be 10 iterations and mCounter should be 10 when the process has ended. –  AlexS May 10 '12 at 19:37
it does work . pls try it out. let me know if there is any issue and i'll fix it. thanks –  Jay D May 12 '12 at 1:33

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