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Consider I have a function declarations like these:

void foo(int x, float y);

class X {
  void anotherFoo(double a, int c);

How can I get a tuple that corresponds to the function arguments? In the above case it would be:

boost::tuple<int, float>
boost::tuple<X*, double, int>

or even better with the result type as 0th element:

boost::tuple<void, int, float>
boost::tuple<void, X*, double, int>

I know that boost::function_types::parameter_types can do exactly this. However, I am interested in the principle of how it is implemented.

share|improve this question
I would use a struct. What is the aim / advantage of using tuples? – kol Nov 22 '11 at 9:41
@kol less boilerplate code, less noise – daramarak Nov 22 '11 at 9:45
Do you mean you want to auto-generate the tuple type at compile time or run-time, or you want to extract the parameters from the regs / stack, or both, or something else? – Rup Nov 22 '11 at 10:04
It should be all compile time - I just need the parameters as a struct/tuple so that I can use them in metaprogramming. – Karel Petranek Nov 22 '11 at 10:11
Have you tried to read boost sources? – alex vasi Nov 22 '11 at 10:18
up vote 7 down vote accepted

You can get the tuple type corresponding to your argument types, like this:

template <typename R, typename... T>
std::tuple<T...> function_args(R (*)(T...))
    return std::tuple<T...>();

// get the tuple type
typedef decltype(function_args(foo)) FooArgType;
// create a default-initialised tuple
auto args = function_args(foo);

Is that what you want? Note you may need to add one or more overloads of function_args, eg. taking a class type param for class methods.

share|improve this answer
Does the decltype still work if the function can't be instantiated because one or more of its parameter types can't be default-initialized? And if not, is there some workaround with a pointer that would do it? – Steve Jessop Nov 22 '11 at 10:38
You can still use the decltype(function_args(foo)) in a typedef or whatever, but you can never really call function_args in that case. – Useless Nov 22 '11 at 10:48
This works, thanks. Is there a way to avoid decltype (as this is C++11 only)? Boost works even on non-C++11 compilers so this should be achievable somehow. – Karel Petranek Nov 22 '11 at 10:50
I guess you can return a helper class instance with the tuple typedef'd: then you're just using the template function type deduction to save writing out the helper class type parameters. Note the variadic template syntax is also C++11 only - if you can't use it, I think you're looking at lots of overloads for different numbers of arguments. – Useless Nov 22 '11 at 11:10
@Useless: How can I achieve that tuple typedef without decltype? I am aware that I'll have to provide lots of overloads for older compilers but I guess there's no way around that. – Karel Petranek Nov 22 '11 at 11:34

Finally found a way how to do this in C++03 using partial specialization. A lot of overloads for different number of arguments and const/volatile functions are necessary but the idea is following:

/* An empty template struct, this gets chosen if the given template parameter is not a member function */
template <typename _Func>
struct MemberFunctionInfo {  };

/* Specialization for parameterless functions */
template <typename _Result, typename _Class>
struct MemberFunctionInfo<_Result (_Class::*) ()>  {
    typedef _Class class_type;
    typedef _Result result_type;
    typedef boost::tuple<> parameter_types;
    enum { arity = 0 };

/* Specialization for parameterless const functions */
template <typename _Result, typename _Class>
struct MemberFunctionInfo<_Result (_Class::*) () const> : MemberFunctionInfo<_Result (_Class::*) ()> { };

/* Specialization for functions with one parameter */
template <typename _Result, typename _Class, typename P0>
struct MemberFunctionInfo<_Result (_Class::*) (P0)>  {
    typedef _Class class_type;
    typedef _Result result_type;
    typedef boost::tuple<P0> parameter_types;
    enum { arity = 1 };

/* Specialization for const functions with one parameter */
template <typename _Result, typename _Class, typename P0>
struct MemberFunctionInfo<_Result (_Class::*) (P0) const> : MemberFunctionInfo<_Result (_Class::*) (P0)> { };


Example usage:

template <typename MemFunc>
int getArity(MemFunc fn)  {
  // Can also use MemberFunctionInfo<MemFunc>::parameter_types with boost::mpl
  return MemberFunctionInfo<MemFunc>::arity;

The above solution has some flaws. It doesn't handle function references, non-member functions or volatile/const volatile member functions but it's easy to account for these by adding more specializations.

For C++11, the approach mentioned by @Useless is way cleaner and should be preferred.

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