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Herb Sutter asked this question in a talk about C++11 and concurrency

The key idea here is to have a non locking class X where every function call should be decorated with a lock that is unlocked after a function.

however herb sutter drifts then off and presents a functor based approach. I'm wondering if it is even possible with C++11 to wrap each function call with lock and unlock of a class in a generic way not wrapping every function call manually.

class X {
  public:
    X() = default;
    void somefunc(arg1 x1, arg2 x2, ...);
    void somefunc2(arg1 x1, arg2 x2, ...);
    /* and more */
};

// herb admits one way to make all functions *available*
// in another class is by derivation

class XX : public X {
  public:
    XX() = default;
    // all functions available in NON overloaded form...
};

there is also the decorator pattern

class XXX {
  public:
    XXX(X &x) : m_x(x) {}

    // explicitly call each wrapped function ... done for each class separately.
    void somefunc(arg1 x1, arg2 x2, ...);
    void somefunc2(arg1 x1, arg2 x2, ...);
  private:
    class X& m_x;
};

but is there something like this possible:

template<>
class wrap_everything;

wrap_everything<X> x;
x.somefunc(x1,x2,...); // this is then locked.

for the sake of completeness this is herb sutter's functor based approach:

template <class T> class locker {
  private:
    mutable T m_t;
    mutable std::mutex m_m;
  public:
    locker( T t = T{} ) : m_t(t) {}
    template <typename F>
    auto operator()(F f) const -> decltype(f(m_t)) {
      std::lock_guard<mutex> _{m_m};
      return f(t);
    }
};


// usage 
locker<std::string> s;
s([](string &s) {
   s += "foobar";
   s += "barfoo";
});
share|improve this question
    
At least with some compilers (e.g., gcc) the compiler can do this with no code modification. Usually used for profiling, but you can have it insert a call to specified functions before and after each function call. Would still be non-trivial for the code to sort out where you wanted locks and where you really didn't though. –  Jerry Coffin May 31 '13 at 14:23
    
@JerryCoffin I guess this is fatal for every maintainer to have to look for the locks somewhere else than in the code. –  Alex May 31 '13 at 14:25
7  
Most probably that's completely impossible inside the language rules. But as well as I appreciate the theoretical nature of this question, I hope you are aware of the fact that the functor based approach is in most situation more useful and appropriate anyway. It's not just the possible way, it's also the better way. –  Christian Rau May 31 '13 at 14:28
1  
@Alex: Probably. Certainly wasn't meant as a practical suggestion (thus posted as comment, not answer). –  Jerry Coffin May 31 '13 at 14:29
1  
Is it me, or did you switch t and m_t in both the initialization list of the constructor of locker, and in its operator()? Also, in your operator() the lock_guard should be initialized using m_m instead of m –  Tom Knapen May 31 '13 at 14:40
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3 Answers

up vote 7 down vote accepted

The question is about the EXECUTE-AROUND pattern. I made a generic (but only barely tested) implementation of EXECUTE-AROUND POINTER at https://gitorious.org/redistd/redistd/blobs/master/include/redi/exec_around.h

This allows:

struct X { void f() { } };
auto x = mutex_around<X>();
x->f();  // locks a mutex for duration of call to X::f

A more in depth explaination on how the family of execute around patterns work can be found here (pdf)

share|improve this answer
    
I'm not sure yet whether that's what I'm looking for, but it makes me excited already! –  Alex Jun 1 '13 at 7:21
    
+1 Hah, right! The chaining behaviour of operator->! Very nice solution. –  Christian Rau Jun 5 '13 at 14:34
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I don't believe there is a portable generic way to do this in current C++. If templates were capable of taking an overload set as a template parameter (which I'd very much like to see in C++14 for many reasons), and the call site could be changed from x.y(z) to x->y(z), I think it could probably be done with a proxy and an overloaded operator->. Otherwise, the best generic way of doing something like this is using Aspect Oriented Programming frameworks for C++ (such as AspectC++).

Being able to wrap each member function call is only really half the story on this, though. According to the Interface Principle, the interface of a class is the functions that mention a class and are supplied with a class. This includes public member functions, friend functions, and free functions in the same namespace as the class. Being able to pass instances to such functions in a wrapped way is a much more subtle problem than merely wrapping member function calls, which is where Sutter's approach shows real power and flexibility.

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3  
+1 for mentioning AOP, which aims precisely at answering this kind of questions. –  Luc Touraille May 31 '13 at 14:54
5  
Classic Stroustrup paper that discusses the proxy+operator-> technique for bracketing member function calls. –  Luc Danton May 31 '13 at 19:20
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It is not possible to do exactly what you want, but something close is doable.

#include <iostream>

class Foo {
  public:
    void one (int x) {
        std::cout << "Called Foo::one(" << x << ")\n";
    }
    void two (int x, double y) {
        std::cout << "Called Foo::two(" << x << ", " << y << ")\n";
    }
};

class ScopeDecorator {
  public:
    ScopeDecorator() {
        std::cout << "Enter scope\n";
    }
    ~ScopeDecorator() {
        std::cout << "Exit scope\n";
    }
};

template <class Wrappee, class Wrapper>
class Wrap {
  public:
    Wrap (Wrappee& w) : wrappee(w) {}
    template <typename rettype, typename... argtype>
        rettype call (rettype (Wrappee::*func)(argtype...), argtype... args)
        {
            Wrapper wrapper;
            return (wrappee.*func)(args...);
        }
  private:
    Wrappee& wrappee;
};

int main ()
{
    Foo foo;
    Wrap<Foo, ScopeDecorator> wfoo(foo);
    wfoo.call(&Foo::one, 42);
    wfoo.call(&Foo::two, 32, 3.1415);
}
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