boost/parameter/aux_/arg_list.hpp
// Copyright Daniel Wallin, David Abrahams 2005. Use, modification and // distribution is subject to the Boost Software License, Version 1.0. (See // accompanying file LICENSE_1_0.txt or copy at // http://www.boost.org/LICENSE_1_0.txt) #ifndef ARG_LIST_050329_HPP #define ARG_LIST_050329_HPP #include <boost/parameter/aux_/void.hpp> #include <boost/parameter/aux_/result_of0.hpp> #include <boost/parameter/aux_/default.hpp> #include <boost/parameter/aux_/parameter_requirements.hpp> #include <boost/parameter/aux_/yesno.hpp> #include <boost/parameter/aux_/is_maybe.hpp> #include <boost/parameter/config.hpp> #include <boost/mpl/apply.hpp> #include <boost/mpl/assert.hpp> #include <boost/mpl/begin.hpp> #include <boost/mpl/end.hpp> #include <boost/mpl/iterator_tags.hpp> #include <boost/type_traits/add_reference.hpp> #include <boost/type_traits/is_same.hpp> #include <boost/preprocessor/repetition/enum_params.hpp> #include <boost/preprocessor/repetition/enum_binary_params.hpp> #include <boost/preprocessor/facilities/intercept.hpp> namespace boost { namespace parameter { // Forward declaration for aux::arg_list, below. template<class T> struct keyword; namespace aux { // Tag type passed to MPL lambda. struct lambda_tag; // // Structures used to build the tuple of actual arguments. The // tuple is a nested cons-style list of arg_list specializations // terminated by an empty_arg_list. // // Each specialization of arg_list is derived from its successor in // the list type. This feature is used along with using // declarations to build member function overload sets that can // match against keywords. // // MPL sequence support struct arg_list_tag; // Terminates arg_list<> and represents an empty list. Since this // is just the terminating case you might want to look at arg_list // first, to get a feel for what's really happening here. struct empty_arg_list { empty_arg_list() {} // Constructor taking BOOST_PARAMETER_MAX_ARITY empty_arg_list // arguments; this makes initialization empty_arg_list( BOOST_PP_ENUM_PARAMS( BOOST_PARAMETER_MAX_ARITY, void_ BOOST_PP_INTERCEPT )) {} // A metafunction class that, given a keyword and a default // type, returns the appropriate result type for a keyword // lookup given that default struct binding { template<class KW, class Default, class Reference> struct apply { typedef Default type; }; }; // Terminator for has_key, indicating that the keyword is unique template <class KW> static no_tag has_key(KW*); #if BOOST_WORKAROUND(__BORLANDC__, BOOST_TESTED_AT(0x564)) // The overload set technique doesn't work with these older // compilers, so they need some explicit handholding. // A metafunction class that, given a keyword, returns the type // of the base sublist whose get() function can produce the // value for that key struct key_owner { template<class KW> struct apply { typedef empty_arg_list type; }; }; template <class K, class T> T& get(default_<K,T> x) const { return x.value; } template <class K, class F> typename result_of0<F>::type get(lazy_default<K,F> x) const { return x.compute_default(); } #endif // If this function is called, it means there is no argument // in the list that matches the supplied keyword. Just return // the default value. template <class K, class Default> Default& operator[](default_<K, Default> x) const { return x.value; } // If this function is called, it means there is no argument // in the list that matches the supplied keyword. Just evaluate // and return the default value. template <class K, class F> typename result_of0<F>::type operator[]( BOOST_PARAMETER_lazy_default_fallback<K,F> x) const { return x.compute_default(); } // No argument corresponding to ParameterRequirements::key_type // was found if we match this overload, so unless that parameter // has a default, we indicate that the actual arguments don't // match the function's requirements. template <class ParameterRequirements, class ArgPack> static typename ParameterRequirements::has_default satisfies(ParameterRequirements*, ArgPack*); // MPL sequence support typedef empty_arg_list type; // convenience typedef arg_list_tag tag; // For dispatching to sequence intrinsics }; // Forward declaration for arg_list::operator, template <class KW, class T> struct tagged_argument; template <class T> struct get_reference { typedef typename T::reference type; }; // A tuple of tagged arguments, terminated with empty_arg_list. // Every TaggedArg is an instance of tagged_argument<>. template <class TaggedArg, class Next = empty_arg_list> struct arg_list : Next { typedef arg_list<TaggedArg,Next> self; typedef typename TaggedArg::key_type key_type; typedef typename is_maybe<typename TaggedArg::value_type>::type holds_maybe; typedef typename mpl::eval_if< holds_maybe , get_reference<typename TaggedArg::value_type> , get_reference<TaggedArg> >::type reference; typedef typename mpl::if_< holds_maybe , reference , typename TaggedArg::value_type >::type value_type; TaggedArg arg; // Stores the argument // Store the arguments in successive nodes of this list template< // class A0, class A1, ... BOOST_PP_ENUM_PARAMS(BOOST_PARAMETER_MAX_ARITY, class A) > arg_list( // A0& a0, A1& a1, ... BOOST_PP_ENUM_BINARY_PARAMS(BOOST_PARAMETER_MAX_ARITY, A, & a) ) : Next( // a1, a2, ... BOOST_PP_ENUM_SHIFTED_PARAMS(BOOST_PARAMETER_MAX_ARITY, a) , void_reference() ) , arg(a0) {} // Create a new list by prepending arg to a copy of tail. Used // when incrementally building this structure with the comma // operator. arg_list(TaggedArg head, Next const& tail) : Next(tail) , arg(head) {} // A metafunction class that, given a keyword and a default // type, returns the appropriate result type for a keyword // lookup given that default struct binding { template <class KW, class Default, class Reference> struct apply { typedef typename mpl::eval_if< boost::is_same<KW, key_type> , mpl::if_<Reference, reference, value_type> , mpl::apply_wrap3<typename Next::binding, KW, Default, Reference> >::type type; }; }; #if !BOOST_WORKAROUND(__BORLANDC__, BOOST_TESTED_AT(0x564)) // Overload for key_type, so the assert below will fire if the // same keyword is used again static yes_tag has_key(key_type*); using Next::has_key; BOOST_MPL_ASSERT_MSG( sizeof(Next::has_key((key_type*)0)) == sizeof(no_tag) , duplicate_keyword, (key_type) ); #endif // // Begin implementation of indexing operators for looking up // specific arguments by name // // Helpers that handle the case when TaggedArg is // empty<T>. template <class D> reference get_default(D const&, mpl::false_) const { return arg.value; } template <class D> reference get_default(D const& d, mpl::true_) const { return arg.value ? arg.value.get() : arg.value.construct(d.value); } #if BOOST_WORKAROUND(__BORLANDC__, BOOST_TESTED_AT(0x564)) // These older compilers don't support the overload set creation // idiom well, so we need to do all the return type calculation // for the compiler and dispatch through an outer function template // A metafunction class that, given a keyword, returns the base // sublist whose get() function can produce the value for that // key. struct key_owner { template<class KW> struct apply { typedef typename mpl::eval_if< boost::is_same<KW, key_type> , mpl::identity<arg_list<TaggedArg,Next> > , mpl::apply_wrap1<typename Next::key_owner,KW> >::type type; }; }; // Outer indexing operators that dispatch to the right node's // get() function. template <class KW> typename mpl::apply_wrap3<binding, KW, void_, mpl::true_>::type operator[](keyword<KW> const& x) const { typename mpl::apply_wrap1<key_owner, KW>::type const& sublist = *this; return sublist.get(x); } template <class KW, class Default> typename mpl::apply_wrap3<binding, KW, Default&, mpl::true_>::type operator[](default_<KW, Default> x) const { typename mpl::apply_wrap1<key_owner, KW>::type const& sublist = *this; return sublist.get(x); } template <class KW, class F> typename mpl::apply_wrap3< binding,KW , typename result_of0<F>::type , mpl::true_ >::type operator[](lazy_default<KW,F> x) const { typename mpl::apply_wrap1<key_owner, KW>::type const& sublist = *this; return sublist.get(x); } // These just return the stored value; when empty_arg_list is // reached, indicating no matching argument was passed, the // default is returned, or if no default_ or lazy_default was // passed, compilation fails. reference get(keyword<key_type> const&) const { BOOST_MPL_ASSERT_NOT((holds_maybe)); return arg.value; } template <class Default> reference get(default_<key_type,Default> const& d) const { return get_default(d, holds_maybe()); } template <class Default> reference get(lazy_default<key_type, Default>) const { return arg.value; } #else reference operator[](keyword<key_type> const&) const { BOOST_MPL_ASSERT_NOT((holds_maybe)); return arg.value; } template <class Default> reference operator[](default_<key_type, Default> const& d) const { return get_default(d, holds_maybe()); } template <class Default> reference operator[](lazy_default<key_type, Default>) const { BOOST_MPL_ASSERT_NOT((holds_maybe)); return arg.value; } // Builds an overload set including operator[]s defined in base // classes. using Next::operator[]; // // End of indexing support // // // For parameter_requirements matching this node's key_type, // return a bool constant wrapper indicating whether the // requirements are satisfied by TaggedArg. Used only for // compile-time computation and never really called, so a // declaration is enough. // template <class HasDefault, class Predicate, class ArgPack> static typename mpl::apply_wrap2< typename mpl::lambda<Predicate, lambda_tag>::type , value_type, ArgPack >::type satisfies( parameter_requirements<key_type,Predicate,HasDefault>* , ArgPack* ); // Builds an overload set including satisfies functions defined // in base classes. using Next::satisfies; #endif // Comma operator to compose argument list without using parameters<>. // Useful for argument lists with undetermined length. template <class KW, class T2> arg_list<tagged_argument<KW, T2>, self> operator,(tagged_argument<KW,T2> x) const { return arg_list<tagged_argument<KW,T2>, self>(x, *this); } // MPL sequence support typedef self type; // Convenience for users typedef Next tail_type; // For the benefit of iterators typedef arg_list_tag tag; // For dispatching to sequence intrinsics }; // MPL sequence support template <class ArgumentPack> struct arg_list_iterator { typedef mpl::forward_iterator_tag category; // The incremented iterator typedef arg_list_iterator<typename ArgumentPack::tail_type> next; // dereferencing yields the key type typedef typename ArgumentPack::key_type type; }; template <> struct arg_list_iterator<empty_arg_list> {}; }} // namespace parameter::aux // MPL sequence support namespace mpl { template <> struct begin_impl<parameter::aux::arg_list_tag> { template <class S> struct apply { typedef parameter::aux::arg_list_iterator<S> type; }; }; template <> struct end_impl<parameter::aux::arg_list_tag> { template <class> struct apply { typedef parameter::aux::arg_list_iterator<parameter::aux::empty_arg_list> type; }; }; } } // namespace boost #endif // ARG_LIST_050329_HPP