You can achieve this with some judicious use of operator-> and modern c++ which gives for much cleaner syntax than the previously accepted answer:
template<class T>
class monitor
{
public:
template<typename ...Args>
monitor(Args&&... args) : m_cl(std::forward<Args>(args)...){}
struct monitor_helper
{
monitor_helper(monitor* mon) : m_mon(mon), m_ul(mon->m_lock) {}
T* operator->() { return &m_mon->m_cl;}
monitor* m_mon;
std::unique_lock<std::mutex> m_ul;
};
monitor_helper operator->() { return monitor_helper(this); }
monitor_helper ManuallyLock() { return monitor_helper(this); }
T& GetThreadUnsafeAccess() { return m_cl; }
private:
T m_cl;
std::mutex m_lock;
};
The idea is that you use the arrow operator to access the underlying object, but that returns a helper object which locks and then unlocks the mutex around your function call. Then through the magic of the language repeatedly applying operator-> you get a reference to the underlying object.
Usage:
monitor<std::vector<int>> threadSafeVector {5};
threadSafeVector->push_back(0);
threadSafeVector->push_back(1);
threadSafeVector->push_back(2);
// Create a bunch of threads that hammer the vector
std::vector<std::thread> threads;
for(int i=0; i<16; ++i)
{
threads.push_back(std::thread([&]()
{
for(int i=0; i<1024; ++i)
{
threadSafeVector->push_back(i);
}
}));
}
// You can explicitely take a lock then call multiple functions
// without the overhead of a relock each time. The 'lock handle'
// destructor will unlock the lock correctly. This is necessary
// if you want a chain of logically connected operations
{
auto lockedHandle = threadSafeVector.ManuallyLock();
if(!lockedHandle->empty())
{
lockedHandle->pop_back();
lockedHandle->push_back(-3);
}
}
for(auto& t : threads)
{
t.join();
}
// And finally access the underlying object in a raw fashion without a lock
// Use with Caution!
std::vector<int>& rawVector = threadSafeVector.GetThreadUnsafeAccess();
rawVector.push_back(555);
// Should be 16393 (5+3+16*1024+1)
std::cout << threadSafeVector->size() << std::endl;