boost/proto/detail/basic_expr.hpp
#if !defined(BOOST_PROTO_DONT_USE_PREPROCESSED_FILES)
#include <boost/proto/detail/preprocessed/basic_expr.hpp>
#elif !defined(BOOST_PP_IS_ITERATING)
/// INTERNAL ONLY
///
#define BOOST_PROTO_CHILD(Z, N, DATA) \
typedef BOOST_PP_CAT(Arg, N) BOOST_PP_CAT(proto_child, N); \
BOOST_PP_CAT(proto_child, N) BOOST_PP_CAT(child, N); \
/**< INTERNAL ONLY */
/// INTERNAL ONLY
///
#define BOOST_PROTO_VOID(Z, N, DATA) \
typedef void BOOST_PP_CAT(proto_child, N); \
/**< INTERNAL ONLY */
#if defined(__WAVE__) && defined(BOOST_PROTO_CREATE_PREPROCESSED_FILES)
#pragma wave option(preserve: 2, line: 0, output: "preprocessed/basic_expr.hpp")
#endif
///////////////////////////////////////////////////////////////////////////////
/// \file basic_expr.hpp
/// Contains definition of basic_expr\<\> class template.
//
// Copyright 2008 Eric Niebler. Distributed under 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)
#if defined(__WAVE__) && defined(BOOST_PROTO_CREATE_PREPROCESSED_FILES)
#pragma wave option(preserve: 1)
#endif
// The expr<> specializations are actually defined here.
#define BOOST_PROTO_DEFINE_TERMINAL
#define BOOST_PP_ITERATION_PARAMS_1 (3, (0, 0, <boost/proto/detail/basic_expr.hpp>))
#include BOOST_PP_ITERATE()
#undef BOOST_PROTO_DEFINE_TERMINAL
#define BOOST_PP_ITERATION_PARAMS_1 (3, (1, BOOST_PROTO_MAX_ARITY, <boost/proto/detail/basic_expr.hpp>))
#include BOOST_PP_ITERATE()
#if defined(__WAVE__) && defined(BOOST_PROTO_CREATE_PREPROCESSED_FILES)
#pragma wave option(output: null)
#endif
#undef BOOST_PROTO_CHILD
#undef BOOST_PROTO_VOID
#else
#define ARG_COUNT BOOST_PP_MAX(1, BOOST_PP_ITERATION())
/// \brief Simplified representation of a node in an expression tree.
///
/// \c proto::basic_expr\<\> is a node in an expression template tree. It
/// is a container for its child sub-trees. It also serves as
/// the terminal nodes of the tree.
///
/// \c Tag is type that represents the operation encoded by
/// this expression. It is typically one of the structs
/// in the \c boost::proto::tag namespace, but it doesn't
/// have to be.
///
/// \c Args is a type list representing the type of the children
/// of this expression. It is an instantiation of one
/// of \c proto::list1\<\>, \c proto::list2\<\>, etc. The
/// child types must all themselves be either \c expr\<\>
/// or <tt>proto::expr\<\>&</tt>. If \c Args is an
/// instantiation of \c proto::term\<\> then this
/// \c expr\<\> type represents a terminal expression;
/// the parameter to the \c proto::term\<\> template
/// represents the terminal's value type.
///
/// \c Arity is an integral constant representing the number of child
/// nodes this node contains. If \c Arity is 0, then this
/// node is a terminal.
///
/// \c proto::basic_expr\<\> is a valid Fusion random-access sequence, where
/// the elements of the sequence are the child expressions.
#ifdef BOOST_PROTO_DEFINE_TERMINAL
template<typename Tag, typename Arg0>
struct basic_expr<Tag, term<Arg0>, 0>
#else
template<typename Tag BOOST_PP_ENUM_TRAILING_PARAMS(ARG_COUNT, typename Arg)>
struct basic_expr<Tag, BOOST_PP_CAT(list, BOOST_PP_ITERATION())<BOOST_PP_ENUM_PARAMS(ARG_COUNT, Arg)>, BOOST_PP_ITERATION() >
#endif
{
typedef Tag proto_tag;
static const long proto_arity_c = BOOST_PP_ITERATION();
typedef mpl::long_<BOOST_PP_ITERATION() > proto_arity;
typedef basic_expr proto_base_expr;
#ifdef BOOST_PROTO_DEFINE_TERMINAL
typedef term<Arg0> proto_args;
#else
typedef BOOST_PP_CAT(list, BOOST_PP_ITERATION())<BOOST_PP_ENUM_PARAMS(ARG_COUNT, Arg)> proto_args;
#endif
typedef basic_expr proto_grammar;
typedef basic_default_domain proto_domain;
typedef default_generator proto_generator;
typedef proto::tag::proto_expr<Tag, proto_domain> fusion_tag;
typedef basic_expr proto_derived_expr;
typedef void proto_is_expr_; /**< INTERNAL ONLY */
BOOST_PP_REPEAT(ARG_COUNT, BOOST_PROTO_CHILD, ~)
BOOST_PP_REPEAT_FROM_TO(ARG_COUNT, BOOST_PROTO_MAX_ARITY, BOOST_PROTO_VOID, ~)
/// \return *this
///
BOOST_FORCEINLINE
basic_expr const &proto_base() const
{
return *this;
}
/// \overload
///
BOOST_FORCEINLINE
basic_expr &proto_base()
{
return *this;
}
#ifdef BOOST_PROTO_DEFINE_TERMINAL
/// \return A new \c expr\<\> object initialized with the specified
/// arguments.
///
template<typename A0>
BOOST_FORCEINLINE
static basic_expr const make(A0 &a0)
{
return detail::make_terminal(a0, static_cast<basic_expr *>(0), static_cast<proto_args *>(0));
}
/// \overload
///
template<typename A0>
BOOST_FORCEINLINE
static basic_expr const make(A0 const &a0)
{
return detail::make_terminal(a0, static_cast<basic_expr *>(0), static_cast<proto_args *>(0));
}
#else
/// \return A new \c expr\<\> object initialized with the specified
/// arguments.
///
template<BOOST_PP_ENUM_PARAMS(ARG_COUNT, typename A)>
BOOST_FORCEINLINE
static basic_expr const make(BOOST_PP_ENUM_BINARY_PARAMS(ARG_COUNT, A, const &a))
{
basic_expr that = {BOOST_PP_ENUM_PARAMS(ARG_COUNT, a)};
return that;
}
#endif
#if 1 == BOOST_PP_ITERATION()
/// If \c Tag is \c boost::proto::tag::address_of and \c proto_child0 is
/// <tt>T&</tt>, then \c address_of_hack_type_ is <tt>T*</tt>.
/// Otherwise, it is some undefined type.
typedef typename detail::address_of_hack<Tag, proto_child0>::type address_of_hack_type_;
/// \return The address of <tt>this->child0</tt> if \c Tag is
/// \c boost::proto::tag::address_of. Otherwise, this function will
/// fail to compile.
///
/// \attention Proto overloads <tt>operator&</tt>, which means that
/// proto-ified objects cannot have their addresses taken, unless we use
/// the following hack to make \c &x implicitly convertible to \c X*.
BOOST_FORCEINLINE
operator address_of_hack_type_() const
{
return boost::addressof(this->child0);
}
#else
/// INTERNAL ONLY
///
typedef detail::not_a_valid_type address_of_hack_type_;
#endif
};
#undef ARG_COUNT
#endif