Metaprogramming.h

#pragma once

#include <type_traits>
#include <array>
#include <functional>
#include <c10/util/TypeList.h>
#include <c10/util/Array.h>

namespace c10 { namespace guts {

/**
 * Access information about result type or arguments from a function type.
 * Example:
 * using A = function_traits<int (float, double)>::return_type // A == int
 * using A = function_traits<int (float, double)>::parameter_types::tuple_type // A == tuple<float, double>
 */
template<class Func> struct function_traits {
  static_assert(!std::is_same<Func, Func>::value, "In function_traits<Func>, Func must be a plain function type.");
};
template<class Result, class... Args>
struct function_traits<Result (Args...)> {
  using func_type = Result (Args...);
  using return_type = Result;
  using parameter_types = typelist::typelist<Args...>;
  static constexpr auto number_of_parameters = sizeof...(Args);
};

/**
 * infer_function_traits: creates a `function_traits` type for a simple
 * function (pointer) or functor (lambda/struct). Currently does not support
 * class methods.
 */

template <typename Functor>
struct infer_function_traits {
  using type = function_traits<c10::guts::detail::strip_class_t<decltype(&Functor::operator())>>;
};

template <typename Result, typename... Args>
struct infer_function_traits<Result (*)(Args...)> {
  using type = function_traits<Result(Args...)>;
};

template <typename T>
using infer_function_traits_t = typename infer_function_traits<T>::type;

/**
 * Use extract_arg_by_filtered_index to return the i-th argument whose
 * type fulfills a given type trait. The argument itself is perfectly forwarded.
 *
 * Example:
 * std::string arg1 = "Hello";
 * std::string arg2 = "World";
 * std::string&& result = extract_arg_by_filtered_index<is_string, 1>(0, arg1, 2.0, std::move(arg2));
 *
 * Warning: Taking the result by rvalue reference can cause segfaults because ownership will not be passed on
 *          from the original reference. The original reference dies after the expression and the resulting
 */
namespace detail {
template<template <class> class Condition, size_t index, class Enable, class... Args> struct extract_arg_by_filtered_index_;
template<template <class> class Condition, size_t index, class Head, class... Tail>
struct extract_arg_by_filtered_index_<Condition, index, guts::enable_if_t<!Condition<Head>::value>, Head, Tail...> {
  static auto call(Head&& /*head*/, Tail&&... tail)
  -> decltype(extract_arg_by_filtered_index_<Condition, index, void, Tail...>::call(std::forward<Tail>(tail)...)) {
    return extract_arg_by_filtered_index_<Condition, index, void, Tail...>::call(std::forward<Tail>(tail)...);
  }
};
template<template <class> class Condition, size_t index, class Head, class... Tail>
struct extract_arg_by_filtered_index_<Condition, index, guts::enable_if_t<Condition<Head>::value && index != 0>, Head, Tail...> {
  static auto call(Head&& /*head*/, Tail&&... tail)
  -> decltype(extract_arg_by_filtered_index_<Condition, index-1, void, Tail...>::call(std::forward<Tail>(tail)...)) {
    return extract_arg_by_filtered_index_<Condition, index-1, void, Tail...>::call(std::forward<Tail>(tail)...);
  }
};
template<template <class> class Condition, size_t index>
struct extract_arg_by_filtered_index_<Condition, index, void> {
  static void call() {
    static_assert(index != index, "extract_arg_by_filtered_index out of range.");
  }
};
template<template <class> class Condition, size_t index, class Head, class... Tail>
struct extract_arg_by_filtered_index_<Condition, index, guts::enable_if_t<Condition<Head>::value && index == 0>, Head, Tail...> {
  static auto call(Head&& head, Tail&&... /*tail*/)
  -> decltype(std::forward<Head>(head)) {
    return std::forward<Head>(head);
  }
};
}
template<template <class> class Condition, size_t index, class... Args>
auto extract_arg_by_filtered_index(Args&&... args)
-> decltype(detail::extract_arg_by_filtered_index_<Condition, index, void, Args...>::call(std::forward<Args>(args)...)) {
  static_assert(is_type_condition<Condition>::value, "In extract_arg_by_filtered_index, the Condition argument must be a condition type trait, i.e. have a static constexpr bool ::value member.");
  return detail::extract_arg_by_filtered_index_<Condition, index, void, Args...>::call(std::forward<Args>(args)...);
}



/**
 * Use filter_map to map a subset of the arguments to values.
 * The subset is defined by type traits, and will be evaluated at compile time.
 * At runtime, it will just loop over the pre-filtered arguments to create an std::array.
 *
 * Example:
 *  // in C++14
 *  std::array<double, 2> result = filter_map<double, std::is_integral>([] (auto a) {return (double)a;}, 3, "bla", 4);
 *  // result == {3.0, 4.0}
 *
 *  // same example in C++11
 *  struct my_map {
 *    template<class T> constexpr double operator()(T a) {
 *      return (double)a;
 *    }
 *  };
 *  std::array<double, 2> result = filter_map<double, std::is_integral>(my_map(), 3, "bla", 4);
 *  // result == {3.0, 4.0}
 */
namespace detail {

template<class ResultType, size_t num_results> struct filter_map_ {
   template<template <class> class Condition, class Mapper, class... Args, size_t... I>
   static guts::array<ResultType, num_results> call(const Mapper& mapper, guts::index_sequence<I...>, Args&&... args) {
     return guts::array<ResultType, num_results> { mapper(extract_arg_by_filtered_index<Condition, I>(std::forward<Args>(args)...))... };
   }
};
template<class ResultType> struct filter_map_<ResultType, 0> {
  template<template <class> class Condition, class Mapper, class... Args, size_t... I>
  static guts::array<ResultType, 0> call(const Mapper& /*mapper*/, guts::index_sequence<I...>, Args&&... /*args*/) {
    return guts::array<ResultType, 0> { };
  }
};
}

template<class ResultType, template <class> class Condition, class Mapper, class... Args> auto filter_map(const Mapper& mapper, Args&&... args)
-> decltype(detail::filter_map_<ResultType, typelist::count_if<Condition, typelist::typelist<Args...>>::value>::template call<Condition, Mapper, Args...>(mapper, guts::make_index_sequence<typelist::count_if<Condition, typelist::typelist<Args...>>::value>(), std::forward<Args>(args)...)) {
  static_assert(is_type_condition<Condition>::value, "In filter_map<Result, Condition>, the Condition argument must be a condition type trait, i.e. have a static constexpr bool ::value member.");

  static constexpr size_t num_results = typelist::count_if<Condition, typelist::typelist<Args...>>::value;
  return detail::filter_map_<ResultType, num_results>::template call<Condition, Mapper, Args...>(mapper, guts::make_index_sequence<num_results>(), std::forward<Args>(args)...);
}

}}