Take the 2-minute tour ×
Stack Overflow is a question and answer site for professional and enthusiast programmers. It's 100% free, no registration required.

In my windows message loop I am invoking a std::thread to calculate something (game-specific stuff). I wanted to disallow the loop to create a next thread until it has calculated what he had to calculate. For now I am dealing with this that way:

if( !mIsCalculating ) {
    mIsCalculating = true;
    std::thread th( Test::method, this );
    th.detach();
}

void Test::method() {
    // ...
    mIsCalculating = false;
}

but I wonder whether there is an existing solution in the std library, like std::invokeWhenLastDone? ;-)

share|improve this question
    
Without a lock, if this code will be called twice in the same time you might create 2 threads. If you call this only from one specific thread it's not an issue. –  asafrob Jun 30 '13 at 9:10
    
std::invokeWhenLastDoneWhatExactly? –  n.m. Jun 30 '13 at 9:19

3 Answers 3

up vote 2 down vote accepted

Instead of spawning a new thread for each task, why not just form a few worker threads and then use std:packaged_task and std::future to concurrently calculate things without the overhead of spawning a new thread.

For instance:

class Calculator {
public:
    Calculator() : m_bDoneFlag( false ) {
        for( auto& thread : m_arrayThreads )
        {
            thread = std::thread( [this]{
                std::unique_lock<std::mutex> lockGuard( m_mutex, std::defer_lock );

                while( !m_bDoneFlag )
                {
                    lockGuard.lock();
                    m_condTaskWaiting.wait( lockGuard, [this]{ return !m_queueTasks.empty(); } );

                    std::packaged_task<void*()> packagedTask = std::move(m_queueTasks.front());
                    m_queueTasks.pop();

                    lockGuard.unlock();

                    // Execute task:
                    packagedTask();
                }
            });
        }
    }

    ~Calculator()
    {
        m_bDoneFlag = true;

        std::unique_lock<std::mutex> lockGuard( m_mutex );
        m_queueTasks.emplace( []{ std::this_thread::sleep_for( std::chrono::milliseconds(100) ); return nullptr; } );
        m_queueTasks.emplace( []{ std::this_thread::sleep_for( std::chrono::milliseconds(100) ); return nullptr; } );
        lockGuard.unlock();
        m_condTaskWaiting.notify_all();

        for( auto& thread : m_arrayThreads )
        {
            thread.join();
        }
    }

    std::future<void*>                          AddTask( std::function<void*()> funcToAdd )
    {
        std::packaged_task<void*()> packagedTask( funcToAdd );
        std::future<void*> future = packagedTask.get_future();

        std::unique_lock<std::mutex> lockGuard( m_mutex );
        m_queueTasks.emplace( std::move(packagedTask) );
        lockGuard.unlock();
        m_condTaskWaiting.notify_one();

        return future;
    }

private:
    std::mutex                                  m_mutex;
    std::array<std::thread, 2>                  m_arrayThreads;
    std::queue<std::packaged_task<void*()>>     m_queueTasks;
    std::condition_variable                     m_condTaskWaiting;
    std::atomic<bool>                           m_bDoneFlag;
};

You can then use this like so:

int main()
{
    Calculator myCalc;

    std::future<void*> future1 = myCalc.AddTask( []{ std::string* pszTest = new std::string("Test String"); return pszTest; } );
    std::future<void*> future2 = myCalc.AddTask( []{ std::complex<float>* pcmplxTest = new std::complex<float>( 5.0f, 10.5f ); return pcmplxTest; } );

    std::string* pszTest = reinterpret_cast<std::string*>(future1.get());
    std::complex<float>* pcmplxTest = reinterpret_cast<std::complex<float>*>(future2.get());

    std::cout << *pszTest << " and " << *pcmplxTest << std::endl;

    delete pszTest;
    delete pcmplxTest;

    return 0;
}

Obviously this doesn't have the type-safety we'd want, and you can improve type-safety significantly if you can narrow down the type of return value that you will always need to prevent having to return a pointer to void.

share|improve this answer
    
AddTask and ~Calculator both access m_queueTasks without m_mutex held, resulting in a data race. –  Casey Jun 30 '13 at 10:02
    
@Casey Thank you for pointing that out!! –  Shaktal Jun 30 '13 at 10:04
    
Probably yet another case of the OP reading some moronic 'Intro to Threads' site/page, (for they are legion), that starts off 'To use threads, you have to continually create them and wait for them to terminate'. –  Martin James Jun 30 '13 at 11:05

As far as I know such a method does not exist. However, you can solve your problem by letting a single thread running forever and managing the repetitions you need inside Test::Method. When a new calculation is needed, the main loop could notify Test::Method by using a std::condition_variable.

share|improve this answer

Technically speaking, mIsCalculating should be an atomic value, so that you don't get problems with using a non-atomic variable in two different threads. Aside from that and assuming this is used in the "UI thread", it would only be called from one thread, so should be acceptable.

There are also several alternative solutions, such as have a single thread that runs forever and feed the data into a pipe, messagequeue or using an event to signal "more work available, and a similar event to for "here's the result".

share|improve this answer

Your Answer

 
discard

By posting your answer, you agree to the privacy policy and terms of service.

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