/* * Licensed under the Apache License, Version 2.0 (the "License"); * you may not use this file except in compliance with the License. * You may obtain a copy of the License at * * http://www.apache.org/licenses/LICENSE-2.0 * * Unless required by applicable law or agreed to in writing, software * distributed under the License is distributed on an "AS IS" BASIS, * WITHOUT WARRANTIES OR CONDITIONS OF ANY KIND, either express or implied. * See the License for the specific language governing permissions and * limitations under the License. * * Copyright 2015-2017 Danny Robson */ #ifndef __UTIL_INTROSPECTION_HPP #define __UTIL_INTROSPECTION_HPP #include "preprocessor.hpp" #include "variadic.hpp" #include #include #include #include #include #include #include namespace util { // XXX: clang-3.9/clang-4.0 will not instantiate static constexpr member // variables from class specialisations, so we have to use detail classes // to hold the variables and instantiate _those_ members instead. template struct type_name; #define CLANG_WORKAROUND(TYPE,TAG,NAME) \ namespace detail { \ struct type_name_##TAG { \ static constexpr const char value[] = (NAME); \ }; \ } \ \ template <> \ struct type_name : public detail::type_name_##TAG { }; CLANG_WORKAROUND(bool,bool,"bool") CLANG_WORKAROUND(char,char,"char") CLANG_WORKAROUND(void*,voidp,"void*") CLANG_WORKAROUND( uint8_t, u08, "u08") CLANG_WORKAROUND(uint16_t, u16, "u16") CLANG_WORKAROUND(uint32_t, u32, "u32") CLANG_WORKAROUND(uint64_t, u64, "u64") CLANG_WORKAROUND( int8_t, s08, "s08") CLANG_WORKAROUND(int16_t, s16, "s16") CLANG_WORKAROUND(int32_t, s32, "s32") CLANG_WORKAROUND(int64_t, s64, "s64") CLANG_WORKAROUND(float, f32, "f32") CLANG_WORKAROUND(double, f64, "f64") CLANG_WORKAROUND(const char*, const_cstring, "cstring") CLANG_WORKAROUND(char*, cstring, "cstring") CLANG_WORKAROUND(std::string, string, "string") CLANG_WORKAROUND(std::experimental::filesystem::path, path, "path"); #undef CLANG_WORKAROUND template constexpr auto type_name_v = type_name::value; template const char* to_string (void) { return type_name_v; } /////////////////////////////////////////////////////////////////////////// template struct type_char; template <> struct type_char { static constexpr char value = 'f'; }; template <> struct type_char { static constexpr char value = 'd'; }; template <> struct type_char< int8_t> { static constexpr char value = 'i'; }; template <> struct type_char< int16_t> { static constexpr char value = 'i'; }; template <> struct type_char< int32_t> { static constexpr char value = 'i'; }; template <> struct type_char< int64_t> { static constexpr char value = 'i'; }; template <> struct type_char< uint8_t> { static constexpr char value = 'u'; }; template <> struct type_char { static constexpr char value = 'u'; }; template <> struct type_char { static constexpr char value = 'u'; }; template <> struct type_char { static constexpr char value = 'u'; }; template constexpr auto type_char_v = type_char::value; /////////////////////////////////////////////////////////////////////////// /// Lists valid values of an enumeration /// /// E: enumeration type /// /// Specialisations must provide the following constexpr: /// value_type: typename /// value_count: size_t /// values: static const std::array template < typename E > struct enum_traits; /////////////////////////////////////////////////////////////////////////// /// Defines specialisations for introspection data structures for an /// enum E, in namespace NS, with variadic values __VA_ARGS__. /// /// Expects to be caleld from outside all namespaces. /// /// XXX: If we define the constexpr fields in a template specialised class /// clang has trouble instantiating them (with std=c++1z) resulting in /// undefined symbols at link time. By using a simple struct and inheriting /// from it we can avoid this problem. Revist this solution at clang-4.0. #define INTROSPECTION_ENUM_DECL(NS,E, ...) \ namespace util { \ struct PASTE(__enum_traits_,E) { \ using value_type = ::NS::E; \ \ static constexpr \ size_t value_count = VA_ARGS_COUNT(__VA_ARGS__); \ \ static const \ std::array \ values; \ \ static const \ std::array \ names; \ }; \ \ template <> \ struct enum_traits<::NS::E> : public PASTE(__enum_traits_,E) \ { }; \ \ template <> \ struct type_name<::NS::E> { \ static constexpr const char ns[] = #NS; \ static constexpr const char value[] = #E; \ }; \ } \ ///------------------------------------------------------------------------ /// Declares specialisations for introspection data structures for an /// enum E, in namespace NS, with variadic values __VA_ARGS__. /// /// Expects to be called from outside all namespaces. #define INTROSPECTION_ENUM_IMPL(NS,E, ...) \ const \ std::array< \ util::enum_traits<::NS::E>::value_type, \ util::enum_traits<::NS::E>::value_count \ > PASTE(util::__enum_traits_,E)::values = { \ MAP1(NAMESPACE_LIST, ::NS::E, __VA_ARGS__) \ }; \ \ const \ std::array< \ const char*, \ util::enum_traits<::NS::E>::value_count \ > PASTE(util::__enum_traits_,E)::names = { \ MAP(STRINGIZE_LIST, __VA_ARGS__) \ }; ///------------------------------------------------------------------------ /// Defines an istream extraction operator for an enumeration E, within /// namespace NS /// /// Expects to be called from outside all namespaces. /// /// The user is responsible for specialising the ::util::enum_traits /// parameters which are used to drive the implementation (eg, through /// INTROSPECTION_ENUM_DECL, and INTROSPECTION_ENUM_IMPL). /// /// For trivial enumerations INTROSPECTION_ENUM may be easier to use. #define INTROSPECTION_ENUM_ISTREAM(NS,E) \ std::istream& \ ::NS::operator>> (std::istream &is, ::NS::E &e) \ { \ using traits = util::enum_traits<::NS::E>; \ \ std::string name; \ is >> name; \ \ std::transform (std::begin (name), \ std::end (name), \ std::begin (name), \ ::toupper); \ \ auto name_pos = std::find ( \ std::cbegin (traits::names), \ std::cend (traits::names), \ name \ ); \ \ if (name_pos == std::cend (traits::names)) { \ is.setstate (std::istream::failbit); \ } else { \ auto d = std::distance ( \ std::begin (traits::names), \ name_pos \ ); \ \ e = traits::values[d]; \ } \ \ return is; \ } /// Defines an ostream insertion operator for an enumeration E, within /// namespace NS. /// /// Expects to be called from outside all namespaces. /// /// The user is responsible for specialising the ::util::enum_traits /// parameters which are used to drive the implementation (eg, through /// INTROSPECTION_ENUM_DECL, and INTROSPECTION_ENUM_IMPL). /// /// For trivial enumerations INTROSPECTION_ENUM may be easier to use. #define INTROSPECTION_ENUM_OSTREAM(NS,E) \ std::ostream& \ ::NS::operator<< (std::ostream &os, ::NS::E e) \ { \ using traits = ::util::enum_traits<::NS::E>; \ \ auto val_pos = std::find ( \ std::cbegin (traits::values), \ std::cend (traits::values), \ e \ ); \ \ if (val_pos == std::cend (traits::values)) { \ os.setstate (std::ostream::failbit); \ } else { \ auto d = std::distance ( \ std::cbegin (traits::values), \ val_pos \ ); \ \ os << traits::names[d]; \ } \ \ return os; \ } /// Defines an enum, its values, associated introspection structures, and /// istream and ostream operators. /// /// This must be called from outside all namespaces as /// INTROSPECTION_ENUM_DECL and INTROSPECTION_ENUM_IMPL need to declare /// and define structures outside the user's namespace. /// /// The enum will be defined inside an inline namespace to simplify the /// passing of parameters to functions which require some namespace /// prefixing. This shouldn't have a practical effect on user code. #define INTROSPECTION_ENUM(E, ...) \ inline namespace detail_intr_enum { \ enum E { __VA_ARGS__ }; \ std::ostream& operator<< (std::ostream&, E); \ std::istream& operator>> (std::istream&, E&); \ } \ INTROSPECTION_ENUM_DECL(detail_intr_enum,E,__VA_ARGS__) \ INTROSPECTION_ENUM_IMPL(detail_intr_enum,E,__VA_ARGS__) \ INTROSPECTION_ENUM_ISTREAM(detail_intr_enum,E) \ INTROSPECTION_ENUM_OSTREAM(detail_intr_enum,E) #define INTROSPECTION_ENUM_CLASS(E, ...) \ inline namespace detail_intr_enum { \ enum class E { __VA_ARGS__ }; \ std::ostream& operator<< (std::ostream&, E); \ std::istream& operator>> (std::istream&, E&); \ } \ INTROSPECTION_ENUM_DECL(detail_intr_enum,E,__VA_ARGS__) \ INTROSPECTION_ENUM_IMPL(detail_intr_enum,E,__VA_ARGS__) \ INTROSPECTION_ENUM_ISTREAM(detail_intr_enum,E) \ INTROSPECTION_ENUM_OSTREAM(detail_intr_enum,E) /////////////////////////////////////////////////////////////////////////// /// Describes a single member variable in a type availabe for introspection /// /// K: target class /// R: member type /// M: pointer-to-member template < class K, typename R, R K::*M > struct field { typedef K klass; typedef R type; static const std::string name; static const R& get (const K &k) { return k.*M; } static R& get ( K &k) { return k.*M; } static R& get ( K &&) = delete; }; /////////////////////////////////////////////////////////////////////////// /// Holds the fields of a type available for introspection /// /// Specialise the following type struct with a 'fields' tuple of the /// members that should be accessed like below: /// /// struct foo { int a; int b; }; /// /// template <> struct type /// { /// typedef std::tuple< /// field, /// field /// > fields; /// }; /// /// template <> const std::string field::name = "a"; /// template <> const std::string field::name = "b"; template struct type { }; /////////////////////////////////////////////////////////////////////////// /// traits class which converts an introspected type to a tuple /// /// K: target class template struct type_tuple; template < typename ...T > struct type_tuple< std::tuple > { typedef std::tuple type; }; template < typename K, typename I = typename std::make_index_sequence< std::tuple_size< typename type::fields >::value > > struct _type_tuple; template < typename K, size_t ...I > struct _type_tuple < K, std::index_sequence > { typedef std::tuple< typename std::tuple_element< I, typename type::fields >::type::type... > type; }; template < typename K > struct type_tuple { typedef typename _type_tuple::type type; }; /////////////////////////////////////////////////////////////////////////// namespace detail { template < typename K, typename I = typename std::make_index_sequence< std::tuple_size< typename type::fields >::value > > struct _as_tuple; template < typename K, size_t ...I > struct _as_tuple < K, std::index_sequence > { static typename type_tuple::type make (const K &k) { return std::make_tuple ( std::tuple_element::fields>::type::get (k)... ); } static auto make (K&&) = delete; }; } /// Convert an introspection capable class instance into a tuple instance /// /// K: source class template auto as_tuple (const K &k) { return detail::_as_tuple::make (k); } template auto as_tuple (K &_k) { const K &k = _k; return as_tuple (k); } template auto as_tuple (K&&) = delete; } #endif