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yap/expression.hpp

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#ifndef BOOST_PROTO17_EXPRESSION_HPP_INCLUDED
#define BOOST_PROTO17_EXPRESSION_HPP_INCLUDED
#include "expression_fwd.hpp"
#include "detail/expression.hpp"
#include <boost/hana/tuple.hpp>
#include <boost/hana/size.hpp>
#include <boost/hana/comparing.hpp>
namespace boost::proto17 {
namespace adl_detail {
template <typename R, typename E, typename ...T>
constexpr decltype(auto) eval_expression_as (E const & expr, hana::basic_type<R>, T &&... args);
struct eval_expression_as_fn
{
template <typename R, typename E, typename ...T>
constexpr decltype(auto) operator() (E const & expr, hana::basic_type<R> rtype, T &&... args) const
{ return eval_expression_as(expr, rtype, static_cast<T &&>(args)...); }
};
}
using adl_detail::eval_expression_as_fn;
inline namespace function_objects {
inline constexpr eval_expression_as_fn eval_expression_as{};
}
template <typename Expr, typename ...T>
decltype(auto) evaluate (Expr const & expr, T && ...t);
template <typename R, typename Expr, typename ...T>
decltype(auto) evaluate_as (Expr const & expr, T && ...t);
template <typename Expr, typename Transform>
auto transform (Expr && expr, Transform && transform);
template <expr_kind Kind, typename ...T>
struct expression
{
using this_type = expression<Kind, T...>;
using tuple_type = hana::tuple<T...>;
static const expr_kind kind = Kind;
expression (T && ... t) :
elements (static_cast<T &&>(t)...)
{}
expression (hana::tuple<T...> && rhs) :
elements (std::move(rhs))
{}
tuple_type elements;
#ifdef BOOST_PROTO17_CONVERSION_OPERATOR_TEMPLATE
template <typename R>
operator R ()
{ return eval_expression_as(*this, hana::basic_type<R>{}); }
#endif
decltype(auto) value () const &
{
using namespace hana::literals;
static_assert(
decltype(hana::size(elements))::value == 1UL,
"value() is only defined for unary expressions."
);
return elements[0_c];
}
decltype(auto) value () &
{
using namespace hana::literals;
static_assert(
decltype(hana::size(elements))::value == 1UL,
"value() is only defined for unary expressions."
);
return elements[0_c];
}
decltype(auto) value () &&
{
using namespace hana::literals;
static_assert(
decltype(hana::size(elements))::value == 1UL,
"value() is only defined for unary expressions."
);
return static_cast<tuple_type &&>(elements)[0_c];
}
decltype(auto) left () const &
{
using namespace hana::literals;
static_assert(
decltype(hana::size(elements))::value == 2UL,
"left() and right() are only defined for binary expressions."
);
return elements[0_c];
}
decltype(auto) left () &
{
using namespace hana::literals;
static_assert(
decltype(hana::size(elements))::value == 2UL,
"left() and right() are only defined for binary expressions."
);
return elements[0_c];
}
decltype(auto) left () &&
{
using namespace hana::literals;
static_assert(
decltype(hana::size(elements))::value == 2UL,
"left() and right() are only defined for binary expressions."
);
return static_cast<tuple_type &&>(elements)[0_c];
}
decltype(auto) right () const &
{
using namespace hana::literals;
static_assert(
decltype(hana::size(elements))::value == 2UL,
"left() and right() are only defined for binary expressions."
);
return elements[1_c];
}
decltype(auto) right () &
{
using namespace hana::literals;
static_assert(
decltype(hana::size(elements))::value == 2UL,
"left() and right() are only defined for binary expressions."
);
return elements[1_c];
}
decltype(auto) right () &&
{
using namespace hana::literals;
static_assert(
decltype(hana::size(elements))::value == 2UL,
"left() and right() are only defined for binary expressions."
);
return static_cast<tuple_type &&>(elements)[1_c];
}
#define BOOST_PROTO17_UNARY_MEMBER_OPERATOR(op, op_name) \
auto operator op const & \
{ \
return expression<expr_kind::op_name, this_type>{ \
hana::tuple<this_type>{*this} \
}; \
} \
auto operator op && \
{ \
return expression<expr_kind::op_name, this_type>{ \
hana::tuple<this_type>{std::move(*this)} \
}; \
}
BOOST_PROTO17_UNARY_MEMBER_OPERATOR(+(), unary_plus) // +
BOOST_PROTO17_UNARY_MEMBER_OPERATOR(-(), negate) // -
BOOST_PROTO17_UNARY_MEMBER_OPERATOR(*(), dereference) // *
BOOST_PROTO17_UNARY_MEMBER_OPERATOR(~(), complement) // ~
BOOST_PROTO17_UNARY_MEMBER_OPERATOR(&(), address_of) // &
BOOST_PROTO17_UNARY_MEMBER_OPERATOR(!(), logical_not) // !
BOOST_PROTO17_UNARY_MEMBER_OPERATOR(++(), pre_inc) // ++
BOOST_PROTO17_UNARY_MEMBER_OPERATOR(--(), pre_dec) // --
BOOST_PROTO17_UNARY_MEMBER_OPERATOR(++(int), post_inc) // ++(int)
BOOST_PROTO17_UNARY_MEMBER_OPERATOR(--(int), post_dec) // --(int)
#undef BOOST_PROTO17_UNARY_MEMBER_OPERATOR
#define BOOST_PROTO17_BINARY_MEMBER_OPERATOR(op, op_name) \
template <typename U> \
auto operator op (U && rhs) const & \
{ \
using rhs_type = detail::operand_type_t<U>; \
return expression<expr_kind::op_name, this_type, rhs_type>{ \
hana::tuple<this_type, rhs_type>{ \
*this, \
static_cast<U &&>(rhs) \
} \
}; \
} \
template <typename U> \
auto operator op (U && rhs) && \
{ \
using rhs_type = detail::operand_type_t<U>; \
return expression<expr_kind::op_name, this_type, rhs_type>{ \
hana::tuple<this_type, rhs_type>{ \
std::move(*this), \
static_cast<U &&>(rhs) \
} \
}; \
}
BOOST_PROTO17_BINARY_MEMBER_OPERATOR(<<, shift_left) // <<
BOOST_PROTO17_BINARY_MEMBER_OPERATOR(>>, shift_right) // >>
BOOST_PROTO17_BINARY_MEMBER_OPERATOR(*, multiplies) // *
BOOST_PROTO17_BINARY_MEMBER_OPERATOR(/, divides) // /
BOOST_PROTO17_BINARY_MEMBER_OPERATOR(%, modulus) // %
BOOST_PROTO17_BINARY_MEMBER_OPERATOR(+, plus) // +
BOOST_PROTO17_BINARY_MEMBER_OPERATOR(-, minus) // -
BOOST_PROTO17_BINARY_MEMBER_OPERATOR(<, less) // <
BOOST_PROTO17_BINARY_MEMBER_OPERATOR(>, greater) // >
BOOST_PROTO17_BINARY_MEMBER_OPERATOR(<=, less_equal) // <=
BOOST_PROTO17_BINARY_MEMBER_OPERATOR(>=, greater_equal) // >=
BOOST_PROTO17_BINARY_MEMBER_OPERATOR(==, equal_to) // ==
BOOST_PROTO17_BINARY_MEMBER_OPERATOR(!=, not_equal_to) // !=
BOOST_PROTO17_BINARY_MEMBER_OPERATOR(||, logical_or) // ||
BOOST_PROTO17_BINARY_MEMBER_OPERATOR(&&, logical_and) // &&
BOOST_PROTO17_BINARY_MEMBER_OPERATOR(&, bitwise_and) // &
BOOST_PROTO17_BINARY_MEMBER_OPERATOR(|, bitwise_or) // |
BOOST_PROTO17_BINARY_MEMBER_OPERATOR(^, bitwise_xor) // ^
template <typename U>
auto operator, (U && rhs) const &
{
using rhs_type = detail::operand_type_t<U>;
return expression<expr_kind::comma, this_type, rhs_type>{
hana::tuple<this_type, rhs_type>{*this, static_cast<U &&>(rhs)}
};
}
template <typename U>
auto operator, (U && rhs) &&
{
using rhs_type = detail::operand_type_t<U>;
return expression<expr_kind::comma, this_type, rhs_type>{
hana::tuple<this_type, rhs_type>{std::move(*this), static_cast<U &&>(rhs)}
};
}
BOOST_PROTO17_BINARY_MEMBER_OPERATOR(->*, mem_ptr) // ->*
BOOST_PROTO17_BINARY_MEMBER_OPERATOR(=, assign) // =
BOOST_PROTO17_BINARY_MEMBER_OPERATOR(<<=, shift_left_assign) // <<=
BOOST_PROTO17_BINARY_MEMBER_OPERATOR(>>=, shift_right_assign) // >>=
BOOST_PROTO17_BINARY_MEMBER_OPERATOR(*=, multiplies_assign) // *=
BOOST_PROTO17_BINARY_MEMBER_OPERATOR(/=, divides_assign) // /=
BOOST_PROTO17_BINARY_MEMBER_OPERATOR(%=, modulus_assign) // %=
BOOST_PROTO17_BINARY_MEMBER_OPERATOR(+=, plus_assign) // +=
BOOST_PROTO17_BINARY_MEMBER_OPERATOR(-=, minus_assign) // -=
BOOST_PROTO17_BINARY_MEMBER_OPERATOR(&=, bitwise_and_assign) // &=
BOOST_PROTO17_BINARY_MEMBER_OPERATOR(|=, bitwise_or_assign) // |=
BOOST_PROTO17_BINARY_MEMBER_OPERATOR(^=, bitwise_xor_assign) // ^=
BOOST_PROTO17_BINARY_MEMBER_OPERATOR([], subscript) // []
#undef BOOST_PROTO17_BINARY_MEMBER_OPERATOR
template <typename ...U>
auto operator() (U && ...u) const &
{
using tuple_type = hana::tuple<this_type, detail::operand_type_t<U>...>;
return detail::make_call_expression<tuple_type>(*this, static_cast<U &&>(u)...);
}
template <typename ...U>
auto operator() (U && ...u) &&
{
using tuple_type = hana::tuple<this_type, detail::operand_type_t<U>...>;
return detail::make_call_expression<tuple_type>(std::move(*this), static_cast<U &&>(u)...);
}
};
template <typename Expr>
decltype(auto) value (Expr const & expr)
{
using namespace hana::literals;
static_assert(
decltype(hana::size(expr.elements))::value == 1UL,
"value() is only defined for unary expressions."
);
return expr.elements[0_c];
}
template <typename Expr>
decltype(auto) value (Expr & expr)
{
using namespace hana::literals;
static_assert(
decltype(hana::size(expr.elements))::value == 1UL,
"value() is only defined for unary expressions."
);
return expr.elements[0_c];
}
template <typename Expr>
decltype(auto) value (std::remove_reference_t<Expr> && expr)
{
using namespace hana::literals;
static_assert(
decltype(hana::size(expr.elements))::value == 1UL,
"value() is only defined for unary expressions."
);
return static_cast<decltype(expr.elements) &&>(expr.elements)[0_c];
}
template <typename Expr>
decltype(auto) left (Expr const & expr)
{
using namespace hana::literals;
static_assert(
decltype(hana::size(expr.elements))::value == 2UL,
"left() and right() are only defined for binary expressions."
);
return expr.elements[0_c];
}
template <typename Expr>
decltype(auto) left (Expr & expr)
{
using namespace hana::literals;
static_assert(
decltype(hana::size(expr.elements))::value == 2UL,
"left() and right() are only defined for binary expressions."
);
return expr.elements[0_c];
}
template <typename Expr>
decltype(auto) left (std::remove_reference_t<Expr> && expr)
{
using namespace hana::literals;
static_assert(
decltype(hana::size(expr.elements))::value == 2UL,
"left() and right() are only defined for binary expressions."
);
return static_cast<decltype(expr.elements) &&>(expr.elements)[0_c];
}
template <typename Expr>
decltype(auto) right (Expr const & expr)
{
using namespace hana::literals;
static_assert(
decltype(hana::size(expr.elements))::value == 2UL,
"left() and right() are only defined for binary expressions."
);
return expr.elements[1_c];
}
template <typename Expr>
decltype(auto) right (Expr & expr)
{
using namespace hana::literals;
static_assert(
decltype(hana::size(expr.elements))::value == 2UL,
"left() and right() are only defined for binary expressions."
);
return expr.elements[1_c];
}
template <typename Expr>
decltype(auto) right (std::remove_reference_t<Expr> && expr)
{
using namespace hana::literals;
static_assert(
decltype(hana::size(expr.elements))::value == 2UL,
"left() and right() are only defined for binary expressions."
);
return static_cast<decltype(expr.elements) &&>(expr.elements)[1_c];
}
namespace detail {
template <expr_kind OpKind, typename T, typename U,
bool Expr = detail::is_expr<remove_cv_ref_t<T>>::value>
struct binary_op_result
{
using lhs_type = detail::operand_type_t<T>;
using rhs_type = U;
using type = expression<OpKind, lhs_type, rhs_type>;
};
template <expr_kind OpKind, typename T, typename U>
struct binary_op_result<OpKind, T, U, true>
{};
}
#define BOOST_PROTO17_BINARY_NON_MEMBER_OPERATOR(op, op_name) \
template <typename T, expr_kind Kind, typename ...U> \
auto operator op (T && lhs, expression<Kind, U...> const & rhs) \
-> typename detail::binary_op_result<expr_kind::op_name, T, expression<Kind, U...>>::type \
{ \
using lhs_type = detail::operand_type_t<T>; \
using rhs_type = expression<Kind, U...>; \
return { \
hana::tuple<lhs_type, rhs_type>{static_cast<T &&>(lhs), rhs} \
}; \
} \
template <typename T, expr_kind Kind, typename ...U> \
auto operator op (T && lhs, expression<Kind, U...> && rhs) \
-> typename detail::binary_op_result<expr_kind::op_name, T, expression<Kind, U...>>::type \
{ \
using lhs_type = detail::operand_type_t<T>; \
using rhs_type = expression<Kind, U...>; \
return { \
hana::tuple<lhs_type, rhs_type>{static_cast<T &&>(lhs), static_cast<rhs_type &&>(rhs)} \
}; \
}
BOOST_PROTO17_BINARY_NON_MEMBER_OPERATOR(<<, shift_left) // <<
BOOST_PROTO17_BINARY_NON_MEMBER_OPERATOR(>>, shift_right) // >>
BOOST_PROTO17_BINARY_NON_MEMBER_OPERATOR(*, multiplies) // *
BOOST_PROTO17_BINARY_NON_MEMBER_OPERATOR(/, divides) // /
BOOST_PROTO17_BINARY_NON_MEMBER_OPERATOR(%, modulus) // %
BOOST_PROTO17_BINARY_NON_MEMBER_OPERATOR(+, plus) // +
BOOST_PROTO17_BINARY_NON_MEMBER_OPERATOR(-, minus) // -
BOOST_PROTO17_BINARY_NON_MEMBER_OPERATOR(<, less) // <
BOOST_PROTO17_BINARY_NON_MEMBER_OPERATOR(>, greater) // >
BOOST_PROTO17_BINARY_NON_MEMBER_OPERATOR(<=, less_equal) // <=
BOOST_PROTO17_BINARY_NON_MEMBER_OPERATOR(>=, greater_equal) // >=
BOOST_PROTO17_BINARY_NON_MEMBER_OPERATOR(==, equal_to) // ==
BOOST_PROTO17_BINARY_NON_MEMBER_OPERATOR(!=, not_equal_to) // !=
BOOST_PROTO17_BINARY_NON_MEMBER_OPERATOR(||, logical_or) // ||
BOOST_PROTO17_BINARY_NON_MEMBER_OPERATOR(&&, logical_and) // &&
BOOST_PROTO17_BINARY_NON_MEMBER_OPERATOR(&, bitwise_and) // &
BOOST_PROTO17_BINARY_NON_MEMBER_OPERATOR(|, bitwise_or) // |
BOOST_PROTO17_BINARY_NON_MEMBER_OPERATOR(^, bitwise_xor) // ^
#undef BOOST_PROTO17_BINARY_NON_MEMBER_OPERATOR
template <expr_kind Kind, typename ...T>
auto make_expression (T &&... t)
{
return expression<Kind, T...>{
hana::tuple<T...>{static_cast<T &&>(t)...}
};
}
template <typename T>
auto make_terminal (T && t)
{
return expression<expr_kind::terminal, T>{
hana::tuple<T>{static_cast<T &&>(t)}
};
}
template <expr_kind Kind, typename ...T>
struct expression_function
{
template <typename ...U>
decltype(auto) operator() (U &&... u)
{ return evaluate(expr, static_cast<U &&>(u)...); }
expression<Kind, T...> expr;
};
template <expr_kind Kind, typename ...T>
auto make_expression_function (expression<Kind, T...> && expr)
{ return expression_function<Kind, T...>{std::move(expr)}; }
}
#include "detail/default_eval.hpp"
namespace boost::proto17 {
// TODO: static assert/SFINAE sizeof...(T) >= highest-indexed placeholder
template <typename Expr, typename ...T>
decltype(auto) evaluate (Expr const & expr, T && ...t)
{ return detail::default_eval_expr(expr, static_cast<T &&>(t)...); }
// TODO: static assert/SFINAE sizeof...(T) >= highest-indexed placeholder
template <typename R, typename Expr, typename ...T>
decltype(auto) evaluate_as (Expr const & expr, T && ...t)
{ return eval_expression_as(expr, hana::basic_type<R>{}, static_cast<T &&>(t)...); }
template <typename Expr, typename Transform>
auto transform (Expr && expr, Transform && transform)
{
return detail::default_transform_expression<Expr, Transform>{}(
static_cast<Expr &&>(expr),
static_cast<Transform &&>(transform)
);
}
namespace adl_detail {
template <typename R, typename E, typename ...T>
constexpr decltype(auto) eval_expression_as (E const & expr, hana::basic_type<R>, T &&... args)
{ return static_cast<R>(detail::default_eval_expr(expr, static_cast<T &&>(args)...)); }
}
}
#endif
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