Given a lambda, is it possible to figure out it's parameter type and return type? If yes, how?

Basically, I want lambda_traits which can be used in following ways:

auto lambda = [](int i) { return long(i*10); };

lambda_traits<decltype(lambda)>::param_type  i; //i should be int
lambda_traits<decltype(lambda)>::return_type l; //l should be long

The motivation behind is that I want to use lambda_traits in a function template which accepts a lambda as argument, and I need to know it's parameter type and return type inside the function:

template<typename TLambda>
void f(TLambda lambda)
   typedef typename lambda_traits<TLambda>::param_type  P;
   typedef typename lambda_traits<TLambda>::return_type R;

   std::function<R(P)> fun = lambda; //I want to do this!

For the time being, we can assume that the lambda takes exactly one argument.

Initially, I tried to work with std::function as:

template<typename T>
A<T> f(std::function<bool(T)> fun)
   return A<T>(fun);

f([](int){return true;}); //error

But it obviously would give error. So I changed it to TLambda version of the function template and want to construct the std::function object inside the function (as shown above).

  • If you know the parameter type then this can be used to figure out the return type. I don't know how to figure out the parameter type though. – Mankarse Oct 30 '11 at 5:57
  • Is it assumed that function takes single argument ? – iammilind Oct 30 '11 at 6:01
  • 1
    "parameter type" But an arbitrary lambda function doesn't have a parameter type. It could take any number of parameters. So any traits class would have to be designed to query parameters by position indices. – Nicol Bolas Oct 30 '11 at 6:01
  • @iammilind: Yes. for the time being, we can assume that. – Nawaz Oct 30 '11 at 6:03
  • @NicolBolas: For the time being, we can assume that the lambda takes exactly one argument. – Nawaz Oct 30 '11 at 6:03

Funny, I've just written a function_traits implementation based on Specializing a template on a lambda in C++0x which can give the parameter types. The trick, as described in the answer in that question, is to use the decltype of the lambda's operator().

template <typename T>
struct function_traits
    : public function_traits<decltype(&T::operator())>
// For generic types, directly use the result of the signature of its 'operator()'

template <typename ClassType, typename ReturnType, typename... Args>
struct function_traits<ReturnType(ClassType::*)(Args...) const>
// we specialize for pointers to member function
    enum { arity = sizeof...(Args) };
    // arity is the number of arguments.

    typedef ReturnType result_type;

    template <size_t i>
    struct arg
        typedef typename std::tuple_element<i, std::tuple<Args...>>::type type;
        // the i-th argument is equivalent to the i-th tuple element of a tuple
        // composed of those arguments.

// test code below:
int main()
    auto lambda = [](int i) { return long(i*10); };

    typedef function_traits<decltype(lambda)> traits;

    static_assert(std::is_same<long, traits::result_type>::value, "err");
    static_assert(std::is_same<int, traits::arg<0>::type>::value, "err");

    return 0;

Note that this solution does not work for generic lambda like [](auto x) {}.

  • Heh, I was just writing this. Didn't think about tuple_element though, thanks. – GManNickG Oct 30 '11 at 7:30
  • @GMan: If your approach is not exactly same as this, please post it then. I'm going to test this solution. – Nawaz Oct 30 '11 at 7:33
  • 3
    A complete trait would also use a specialization for non-const, for those lambda declared mutable ([]() mutable -> T { ... }). – Luc Danton Oct 30 '11 at 10:14
  • 1
    @Andry that's a fundamental problem with function objects that have (potentially) multiple overloads of operator() not with this implementation. auto is not a type, so it can't ever be the answer to traits::template arg<0>::type – Caleth Jan 16 '18 at 12:19
  • 1
    @helmesjo sf.net/p/tacklelib/tacklelib/HEAD/tree/trunk/include/tacklelib/… As a solution for broken links: try to search from the root, Luke. – Andry Jan 17 at 7:59

Though I'm not sure this is strictly standard conforming, ideone compiled the following code:

template< class > struct mem_type;

template< class C, class T > struct mem_type< T C::* > {
  typedef T type;

template< class T > struct lambda_func_type {
  typedef typename mem_type< decltype( &T::operator() ) >::type type;

int main() {
  auto l = [](int i) { return long(i); };
  typedef lambda_func_type< decltype(l) >::type T;
  static_assert( std::is_same< T, long( int )const >::value, "" );

However, this provides only the function type, so the result and parameter types have to be extracted from it. If you can use boost::function_traits, result_type and arg1_type will meet the purpose. Since ideone seems not to provide boost in C++11 mode, I couldn't post the actual code, sorry.

  • 1
    I think, it is a good start. +1 for that. Now we need to work on function type to extract the required information. (I don't want to use Boost as of now, as I want to learn the stuffs). – Nawaz Oct 30 '11 at 7:22

The specialization method shown in @KennyTMs answer can be extended to cover all cases, including variadic and mutable lambdas:

template <typename T>
struct closure_traits : closure_traits<decltype(&T::operator())> {};

#define REM_CTOR(...) __VA_ARGS__
#define SPEC(cv, var, is_var)                                              \
template <typename C, typename R, typename... Args>                        \
struct closure_traits<R (C::*) (Args... REM_CTOR var) cv>                  \
{                                                                          \
    using arity = std::integral_constant<std::size_t, sizeof...(Args) >;   \
    using is_variadic = std::integral_constant<bool, is_var>;              \
    using is_const    = std::is_const<int cv>;                             \
    using result_type = R;                                                 \
    template <std::size_t i>                                               \
    using arg = typename std::tuple_element<i, std::tuple<Args...>>::type; \

SPEC(const, (,...), 1)
SPEC(const, (), 0)
SPEC(, (,...), 1)
SPEC(, (), 0)


Note that the arity is not adjusted for variadic operator()s. Instead one can also consider is_variadic.


The answer provided by @KennyTMs works great, however if a lambda has no parameters, using the index arg<0> does not compile. If anyone else was having this problem, I have a simple solution (simpler than using SFINAE related solutions, that is).

Just add void to the end of the tuple in the arg struct after the variadic argument types. i.e.

template <size_t i>
    struct arg
        typedef typename std::tuple_element<i, std::tuple<Args...,void>>::type type;

since the arity isn't dependent on the actual number of template parameters, the actual won't be incorrect, and if it's 0 then at least arg<0> will still exist and you can do with it what you will. If you already plan to not exceed the index arg<arity-1> then it shouldn't interfere with your current implementation.

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