boost/yap/algorithm.hpp
// Copyright (C) 2016-2018 T. Zachary Laine // // 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) #ifndef BOOST_YAP_ALGORITHM_HPP_INCLUDED #define BOOST_YAP_ALGORITHM_HPP_INCLUDED #include <boost/yap/algorithm_fwd.hpp> #include <boost/yap/user_macros.hpp> #include <boost/yap/detail/algorithm.hpp> #include <boost/hana/size.hpp> #include <boost/hana/comparing.hpp> namespace boost { namespace yap { #ifdef BOOST_NO_CONSTEXPR_IF namespace detail { template<typename Expr, bool MutableRvalueRef> struct deref_impl { constexpr decltype(auto) operator()(Expr && expr) { return std::move(*expr.elements[hana::llong_c<0>]); } }; template<typename Expr> struct deref_impl<Expr, false> { constexpr decltype(auto) operator()(Expr && expr) { return *expr.elements[hana::llong_c<0>]; } }; } #endif /** "Dereferences" a reference-expression, forwarding its referent to the caller. */ template<typename Expr> constexpr decltype(auto) deref(Expr && expr) { static_assert( is_expr<Expr>::value, "deref() is only defined for expressions."); static_assert( detail::remove_cv_ref_t<Expr>::kind == expr_kind::expr_ref, "deref() is only defined for expr_ref-kind expressions."); #ifdef BOOST_NO_CONSTEXPR_IF return detail::deref_impl < Expr, std::is_rvalue_reference<Expr>::value && !std::is_const<std::remove_reference_t<Expr>>::value > {}(static_cast<Expr &&>(expr)); #else using namespace hana::literals; if constexpr ( std::is_rvalue_reference<Expr>::value && !std::is_const<std::remove_reference_t<Expr>>::value) { return std::move(*expr.elements[0_c]); } else { return *expr.elements[0_c]; } #endif } namespace detail { template<typename Tuple, long long I> struct lvalue_ref_ith_element : std::is_lvalue_reference<decltype( std::declval<Tuple>()[hana::llong<I>{}])> { }; #ifdef BOOST_NO_CONSTEXPR_IF template<bool ValueOfTerminalsOnly, typename T> constexpr decltype(auto) value_impl(T && x); template< typename T, bool IsExprRef, bool ValueOfTerminalsOnly, bool TakeValue, bool IsLvalueRef> struct value_expr_impl; template< typename T, bool ValueOfTerminalsOnly, bool TakeValue, bool IsLvalueRef> struct value_expr_impl< T, true, ValueOfTerminalsOnly, TakeValue, IsLvalueRef> { constexpr decltype(auto) operator()(T && x) { return ::boost::yap::detail::value_impl<ValueOfTerminalsOnly>( ::boost::yap::deref(static_cast<T &&>(x))); } }; template<typename T, bool ValueOfTerminalsOnly> struct value_expr_impl<T, false, ValueOfTerminalsOnly, true, true> { constexpr decltype(auto) operator()(T && x) { return x.elements[hana::llong_c<0>]; } }; template<typename T, bool ValueOfTerminalsOnly> struct value_expr_impl<T, false, ValueOfTerminalsOnly, true, false> { constexpr decltype(auto) operator()(T && x) { return std::move(x.elements[hana::llong_c<0>]); } }; template<typename T, bool ValueOfTerminalsOnly, bool IsLvalueRef> struct value_expr_impl< T, false, ValueOfTerminalsOnly, false, IsLvalueRef> { constexpr decltype(auto) operator()(T && x) { return static_cast<T &&>(x); } }; template<typename T, bool IsExpr, bool ValueOfTerminalsOnly> struct value_impl_t { constexpr decltype(auto) operator()(T && x) { constexpr expr_kind kind = detail::remove_cv_ref_t<T>::kind; constexpr detail::expr_arity arity = detail::arity_of<kind>(); return value_expr_impl < T, kind == expr_kind::expr_ref, ValueOfTerminalsOnly, (ValueOfTerminalsOnly && kind == expr_kind::terminal) || (!ValueOfTerminalsOnly && arity == detail::expr_arity::one), std::is_lvalue_reference<T>::value || detail::lvalue_ref_ith_element< decltype(x.elements), 0>::value > {}(static_cast<T &&>(x)); } }; template<typename T, bool ValueOfTerminalsOnly> struct value_impl_t<T, false, ValueOfTerminalsOnly> { constexpr decltype(auto) operator()(T && x) { return static_cast<T &&>(x); } }; template<bool ValueOfTerminalsOnly, typename T> constexpr decltype(auto) value_impl(T && x) { return detail:: value_impl_t<T, is_expr<T>::value, ValueOfTerminalsOnly>{}( static_cast<T &&>(x)); } #else template<bool ValueOfTerminalsOnly, typename T> constexpr decltype(auto) value_impl(T && x) { if constexpr (is_expr<T>::value) { using namespace hana::literals; constexpr expr_kind kind = remove_cv_ref_t<T>::kind; constexpr expr_arity arity = arity_of<kind>(); if constexpr (kind == expr_kind::expr_ref) { return value_impl<ValueOfTerminalsOnly>( ::boost::yap::deref(static_cast<T &&>(x))); } else if constexpr ( kind == expr_kind::terminal || (!ValueOfTerminalsOnly && arity == expr_arity::one)) { if constexpr ( std::is_lvalue_reference<T>::value || detail:: lvalue_ref_ith_element<decltype(x.elements), 0>{}) { return x.elements[0_c]; } else { return std::move(x.elements[0_c]); } } else { return static_cast<T &&>(x); } } else { return static_cast<T &&>(x); } } #endif } /** Forwards the sole element of \a x to the caller, possibly calling <code>deref()</code> first if \a x is a reference expression, or forwards \a x to the caller unchanged. More formally: - If \a x is not an expression, \a x is forwarded to the caller. - Otherwise, if \a x is a reference expression, the result is <code>value(deref(x))</code>. - Otherwise, if \a x is an expression with only one value (a unary expression or a terminal expression), the result is the forwarded first element of \a x. - Otherwise, \a x is forwarded to the caller. */ template<typename T> constexpr decltype(auto) value(T && x) { return detail::value_impl<false>(static_cast<T &&>(x)); } #ifdef BOOST_NO_CONSTEXPR_IF template<typename Expr, typename I> constexpr decltype(auto) get(Expr && expr, I const & i); namespace detail { template<long long I, typename Expr, bool IsExpr, bool IsLvalueRef> struct get_impl; template<long long I, typename Expr, bool IsLvalueRef> struct get_impl<I, Expr, true, IsLvalueRef> { constexpr decltype(auto) operator()(Expr && expr, hana::llong<I> i) { return ::boost::yap::get( ::boost::yap::deref(static_cast<Expr &&>(expr)), i); } }; template<long long I, typename Expr> struct get_impl<I, Expr, false, true> { constexpr decltype(auto) operator()(Expr && expr, hana::llong<I> i) { return expr.elements[i]; } }; template<long long I, typename Expr> struct get_impl<I, Expr, false, false> { constexpr decltype(auto) operator()(Expr && expr, hana::llong<I> i) { return std::move(expr.elements[i]); } }; } #endif /** Forwards the <i>i</i>-th element of \a expr to the caller. If \a expr is a reference expression, the result is <code>get(deref(expr), i)</code>. \note <code>get()</code> is only valid if \a Expr is an expression. */ template<typename Expr, typename I> constexpr decltype(auto) get(Expr && expr, I const & i) { static_assert( is_expr<Expr>::value, "get() is only defined for expressions."); static_assert( hana::IntegralConstant<I>::value, "'i' must be an IntegralConstant"); constexpr expr_kind kind = detail::remove_cv_ref_t<Expr>::kind; static_assert( kind == expr_kind::expr_ref || (0 <= I::value && I::value < decltype(hana::size(expr.elements))::value), "In get(expr, I), I must be a valid index into expr's tuple " "elements."); #ifdef BOOST_NO_CONSTEXPR_IF return detail::get_impl< I::value, Expr, kind == expr_kind::expr_ref, std::is_lvalue_reference<Expr>::value>{}(static_cast<Expr &&>(expr), i); #else using namespace hana::literals; if constexpr (kind == expr_kind::expr_ref) { return ::boost::yap::get( ::boost::yap::deref(static_cast<Expr &&>(expr)), i); } else { if constexpr (std::is_lvalue_reference<Expr>::value) { return expr.elements[i]; } else { return std::move(expr.elements[i]); } } #endif } /** Returns <code>get(expr, boost::hana::llong_c<I>)</code>. */ template<long long I, typename Expr> constexpr decltype(auto) get_c(Expr && expr) { return ::boost::yap::get(static_cast<Expr &&>(expr), hana::llong_c<I>); } /** Returns the left operand in a binary operator expression. Equivalent to <code>get(expr, 0_c)</code>. \note <code>left()</code> is only valid if \a Expr is a binary operator expression. */ template<typename Expr> constexpr decltype(auto) left(Expr && expr) { using namespace hana::literals; return ::boost::yap::get(static_cast<Expr &&>(expr), 0_c); constexpr expr_kind kind = detail::remove_cv_ref_t<Expr>::kind; static_assert( kind == expr_kind::expr_ref || detail::arity_of<kind>() == detail::expr_arity::two, "left() is only defined for binary expressions."); } /** Returns the right operand in a binary operator expression. Equivalent to <code>get(expr, 1_c)</code>. \note <code>right()</code> is only valid if \a Expr is a binary operator expression. */ template<typename Expr> constexpr decltype(auto) right(Expr && expr) { using namespace hana::literals; return ::boost::yap::get(static_cast<Expr &&>(expr), 1_c); constexpr expr_kind kind = detail::remove_cv_ref_t<Expr>::kind; static_assert( kind == expr_kind::expr_ref || detail::arity_of<kind>() == detail::expr_arity::two, "right() is only defined for binary expressions."); } /** Returns the condition expression in an if_else expression. Equivalent to <code>get(expr, 0_c)</code>. \note <code>cond()</code> is only valid if \a Expr is an <code>expr_kind::if_else</code> expression. */ template<typename Expr> constexpr decltype(auto) cond(Expr && expr) { using namespace hana::literals; return ::boost::yap::get(static_cast<Expr &&>(expr), 0_c); constexpr expr_kind kind = detail::remove_cv_ref_t<Expr>::kind; static_assert( kind == expr_kind::expr_ref || kind == expr_kind::if_else, "cond() is only defined for if_else expressions."); } /** Returns the then-expression in an if_else expression. Equivalent to <code>get(expr, 1_c)</code>. \note <code>then()</code> is only valid if \a Expr is an <code>expr_kind::if_else</code> expression. */ template<typename Expr> constexpr decltype(auto) then(Expr && expr) { using namespace hana::literals; return ::boost::yap::get(static_cast<Expr &&>(expr), 1_c); constexpr expr_kind kind = detail::remove_cv_ref_t<Expr>::kind; static_assert( kind == expr_kind::expr_ref || kind == expr_kind::if_else, "then() is only defined for if_else expressions."); } /** Returns the else-expression in an if_else expression. Equivalent to <code>get(expr, 2_c)</code>. \note <code>else_()</code> is only valid if \a Expr is an <code>expr_kind::if_else</code> expression. */ template<typename Expr> constexpr decltype(auto) else_(Expr && expr) { using namespace hana::literals; return ::boost::yap::get(static_cast<Expr &&>(expr), 2_c); constexpr expr_kind kind = detail::remove_cv_ref_t<Expr>::kind; static_assert( kind == expr_kind::expr_ref || kind == expr_kind::if_else, "else_() is only defined for if_else expressions."); } /** Returns the callable in a call expression. Equivalent to <code>get(expr, 0)</code>. \note <code>callable()</code> is only valid if \a Expr is an <code>expr_kind::call</code> expression. */ template<typename Expr> constexpr decltype(auto) callable(Expr && expr) { return ::boost::yap::get(static_cast<Expr &&>(expr), hana::llong_c<0>); constexpr expr_kind kind = detail::remove_cv_ref_t<Expr>::kind; static_assert( kind == expr_kind::expr_ref || detail::arity_of<kind>() == detail::expr_arity::n, "callable() is only defined for call expressions."); } /** Returns the <i>i-th</i> argument expression in a call expression. Equivalent to <code>get(expr, i + 1)</code>. \note <code>argument()</code> is only valid if \a Expr is an <code>expr_kind::call</code> expression. */ template<long long I, typename Expr> constexpr decltype(auto) argument(Expr && expr, hana::llong<I> i) { return ::boost::yap::get( static_cast<Expr &&>(expr), hana::llong_c<I + 1>); constexpr expr_kind kind = detail::remove_cv_ref_t<Expr>::kind; static_assert( kind == expr_kind::expr_ref || detail::arity_of<kind>() == detail::expr_arity::n, "argument() is only defined for call expressions."); static_assert( kind == expr_kind::expr_ref || (0 <= I && I < decltype(hana::size(expr.elements))::value - 1), "I must be a valid call-expression argument index."); } /** Makes a new expression instantiated from the expression template \a ExprTemplate, of kind \a Kind, with the given values as its elements. For each parameter P: - If P is an expression, P is moved into the result if P is an rvalue and captured by reference into the result otherwise. - Otherwise, P is wrapped in a terminal expression. \note <code>make_expression()</code> is only valid if the number of parameters passed is appropriate for \a Kind. */ template< template<expr_kind, class> class ExprTemplate, expr_kind Kind, typename... T> constexpr auto make_expression(T &&... t) { constexpr detail::expr_arity arity = detail::arity_of<Kind>(); static_assert( (arity == detail::expr_arity::one && sizeof...(T) == 1) || (arity == detail::expr_arity::two && sizeof...(T) == 2) || (arity == detail::expr_arity::three && sizeof...(T) == 3) || arity == detail::expr_arity::n, "The number of parameters passed to make_expression() must " "match the arity " "implied by the expr_kind template parameter."); using tuple_type = hana::tuple<detail::operand_type_t<ExprTemplate, T>...>; return ExprTemplate<Kind, tuple_type>{tuple_type{ detail::make_operand<detail::operand_type_t<ExprTemplate, T>>{}( static_cast<T &&>(t))...}}; } /** Makes a new terminal expression instantiated from the expression template \a ExprTemplate, with the given value as its sole element. \note <code>make_terminal()</code> is only valid if \a T is \b not an expression. */ template<template<expr_kind, class> class ExprTemplate, typename T> constexpr auto make_terminal(T && t) { static_assert( !is_expr<T>::value, "make_terminal() is only defined for non expressions."); using result_type = detail::operand_type_t<ExprTemplate, T>; using tuple_type = decltype(std::declval<result_type>().elements); return result_type{tuple_type{static_cast<T &&>(t)}}; } #ifdef BOOST_NO_CONSTEXPR_IF namespace detail { template< template<expr_kind, class> class ExprTemplate, typename T, bool IsExpr> struct as_expr_impl { constexpr decltype(auto) operator()(T && t) { return static_cast<T &&>(t); } }; template<template<expr_kind, class> class ExprTemplate, typename T> struct as_expr_impl<ExprTemplate, T, false> { constexpr decltype(auto) operator()(T && t) { return make_terminal<ExprTemplate>(static_cast<T &&>(t)); } }; } #endif /** Returns an expression formed from \a t as follows: - If \a t is an expression, \a t is forwarded to the caller. - Otherwise, \a t is wrapped in a terminal expression. */ template<template<expr_kind, class> class ExprTemplate, typename T> constexpr decltype(auto) as_expr(T && t) { #ifdef BOOST_NO_CONSTEXPR_IF return detail::as_expr_impl<ExprTemplate, T, is_expr<T>::value>{}( static_cast<T &&>(t)); #else if constexpr (is_expr<T>::value) { return static_cast<T &&>(t); } else { return make_terminal<ExprTemplate>(static_cast<T &&>(t)); } #endif } /** A callable type that evaluates its contained expression when called. \see <code>make_expression_function()</code> */ template<typename Expr> struct expression_function { template<typename... U> constexpr decltype(auto) operator()(U &&... u) { return ::boost::yap::evaluate(expr, static_cast<U &&>(u)...); } Expr expr; }; namespace detail { template<expr_kind Kind, typename Tuple> struct expression_function_expr { static const expr_kind kind = Kind; Tuple elements; }; } /** Returns a callable object that \a expr has been forwarded into. This is useful for using expressions as function objects. Lvalue expressions are stored in the result by reference; rvalue expressions are moved into the result. \note <code>make_expression_function()</code> is only valid if \a Expr is an expression. */ template<typename Expr> constexpr auto make_expression_function(Expr && expr) { static_assert( is_expr<Expr>::value, "make_expression_function() is only defined for expressions."); using stored_type = detail::operand_type_t<detail::expression_function_expr, Expr &&>; return expression_function<stored_type>{ detail::make_operand<stored_type>{}(static_cast<Expr &&>(expr))}; } }} #include <boost/yap/detail/transform.hpp> namespace boost { namespace yap { /** Returns a transform object that replaces placeholders within an expression with the given values. */ template<typename... T> constexpr auto replacements(T &&... t) { return detail::placeholder_transform_t<T...>(static_cast<T &&>(t)...); } /** Returns \a expr with the placeholders replaced by YAP terminals containing the given values. \note <code>replace_placeholders(expr, t...)</code> is only valid if \a expr is an expression, and <code>max_p <= sizeof...(t)</code>, where <code>max_p</code> is the maximum placeholder index in \a expr. */ template<typename Expr, typename... T> constexpr decltype(auto) replace_placeholders(Expr && expr, T &&... t) { static_assert( is_expr<Expr>::value, "evaluate() is only defined for expressions."); return transform( static_cast<Expr &&>(expr), replacements(static_cast<T &&>(t)...)); } /** Returns a transform object that evaluates an expression using the built-in semantics. The transform replaces any placeholders with the given values. */ template<typename... T> constexpr auto evaluation(T &&... t) { return detail::evaluation_transform_t<T...>(static_cast<T &&>(t)...); } /** Evaluates \a expr using the built-in semantics, replacing any placeholders with the given values. \note <code>evaluate(expr)</code> is only valid if \a expr is an expression. */ template<typename Expr, typename... T> constexpr decltype(auto) evaluate(Expr && expr, T &&... t) { static_assert( is_expr<Expr>::value, "evaluate() is only defined for expressions."); return transform( static_cast<Expr &&>(expr), evaluation(static_cast<T &&>(t)...)); } namespace detail { template<typename... Transforms> constexpr auto make_transform_tuple(Transforms &... transforms) { return hana::tuple<Transforms *...>{&transforms...}; } template<bool Strict> struct transform_ { template<typename Expr, typename Transform, typename... Transforms> constexpr decltype(auto) operator()( Expr && expr, Transform & transform, Transforms &... transforms) const { auto transform_tuple = detail::make_transform_tuple(transform, transforms...); constexpr expr_kind kind = detail::remove_cv_ref_t<Expr>::kind; return detail:: transform_impl<Strict, 0, kind == expr_kind::expr_ref>{}( static_cast<Expr &&>(expr), transform_tuple); } }; } /** Returns the result of transforming (all or part of) \a expr using whatever overloads of <code>Transform::operator()</code> match \a expr. \note Transformations can do anything: they may have side effects; they may mutate values; they may mutate types; and they may do any combination of these. */ template<typename Expr, typename Transform, typename... Transforms> constexpr decltype(auto) transform(Expr && expr, Transform && transform, Transforms &&... transforms) { static_assert( is_expr<Expr>::value, "transform() is only defined for expressions."); return detail::transform_<false>{}( static_cast<Expr &&>(expr), transform, transforms...); } /** Returns the result of transforming \a expr using whichever overload of <code>Transform::operator()</code> best matches \a expr. If no overload of <code>Transform::operator()</code> matches, a compile-time error results. \note Transformations can do anything: they may have side effects; they may mutate values; they may mutate types; and they may do any combination of these. */ template<typename Expr, typename Transform, typename... Transforms> constexpr decltype(auto) transform_strict( Expr && expr, Transform && transform, Transforms &&... transforms) { static_assert( is_expr<Expr>::value, "transform() is only defined for expressions."); return detail::transform_<true>{}( static_cast<Expr &&>(expr), transform, transforms...); } }} #endif