584 lines
16 KiB
C++
584 lines
16 KiB
C++
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// - lambda_traits.hpp --- Boost Lambda Library ----------------------------
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//
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// Copyright (C) 1999, 2000 Jaakko Jarvi (jaakko.jarvi@cs.utu.fi)
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//
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// Distributed under the Boost Software License, Version 1.0. (See
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// accompanying file LICENSE_1_0.txt or copy at
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// http://www.boost.org/LICENSE_1_0.txt)
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//
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// For more information, see www.boost.org
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// -------------------------------------------------------------------------
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#ifndef BOOST_LAMBDA_LAMBDA_TRAITS_HPP
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#define BOOST_LAMBDA_LAMBDA_TRAITS_HPP
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#include "boost/type_traits/transform_traits.hpp"
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#include "boost/type_traits/cv_traits.hpp"
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#include "boost/type_traits/function_traits.hpp"
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#include "boost/type_traits/object_traits.hpp"
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#include "boost/tuple/tuple.hpp"
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namespace boost {
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namespace lambda {
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// -- if construct ------------------------------------------------
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// Proposed by Krzysztof Czarnecki and Ulrich Eisenecker
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namespace detail {
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template <bool If, class Then, class Else> struct IF { typedef Then RET; };
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template <class Then, class Else> struct IF<false, Then, Else> {
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typedef Else RET;
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};
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// An if construct that doesn't instantiate the non-matching template:
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// Called as:
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// IF_type<condition, A, B>::type
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// The matching template must define the typeded 'type'
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// I.e. A::type if condition is true, B::type if condition is false
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// Idea from Vesa Karvonen (from C&E as well I guess)
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template<class T>
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struct IF_type_
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{
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typedef typename T::type type;
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};
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template<bool C, class T, class E>
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struct IF_type
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{
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typedef typename
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IF_type_<typename IF<C, T, E>::RET >::type type;
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};
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// helper that can be used to give typedef T to some type
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template <class T> struct identity_mapping { typedef T type; };
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// An if construct for finding an integral constant 'value'
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// Does not instantiate the non-matching branch
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// Called as IF_value<condition, A, B>::value
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// If condition is true A::value must be defined, otherwise B::value
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template<class T>
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struct IF_value_
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{
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BOOST_STATIC_CONSTANT(int, value = T::value);
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};
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template<bool C, class T, class E>
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struct IF_value
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{
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BOOST_STATIC_CONSTANT(int, value = (IF_value_<typename IF<C, T, E>::RET>::value));
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};
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// --------------------------------------------------------------
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// removes reference from other than function types:
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template<class T> class remove_reference_if_valid
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{
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typedef typename boost::remove_reference<T>::type plainT;
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public:
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typedef typename IF<
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boost::is_function<plainT>::value,
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T,
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plainT
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>::RET type;
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};
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template<class T> struct remove_reference_and_cv {
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typedef typename boost::remove_cv<
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typename boost::remove_reference<T>::type
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>::type type;
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};
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// returns a reference to the element of tuple T
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template<int N, class T> struct tuple_element_as_reference {
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typedef typename
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boost::tuples::access_traits<
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typename boost::tuples::element<N, T>::type
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>::non_const_type type;
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};
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// returns the cv and reverence stripped type of a tuple element
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template<int N, class T> struct tuple_element_stripped {
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typedef typename
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remove_reference_and_cv<
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typename boost::tuples::element<N, T>::type
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>::type type;
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};
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// is_lambda_functor -------------------------------------------------
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template <class T> struct is_lambda_functor_ {
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BOOST_STATIC_CONSTANT(bool, value = false);
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};
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template <class Arg> struct is_lambda_functor_<lambda_functor<Arg> > {
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BOOST_STATIC_CONSTANT(bool, value = true);
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};
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} // end detail
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template <class T> struct is_lambda_functor {
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BOOST_STATIC_CONSTANT(bool,
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value =
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detail::is_lambda_functor_<
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typename detail::remove_reference_and_cv<T>::type
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>::value);
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};
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namespace detail {
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// -- parameter_traits_ ---------------------------------------------
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// An internal parameter type traits class that respects
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// the reference_wrapper class.
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// The conversions performed are:
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// references -> compile_time_error
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// T1 -> T2,
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// reference_wrapper<T> -> T&
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// const array -> ref to const array
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// array -> ref to array
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// function -> ref to function
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// ------------------------------------------------------------------------
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template<class T1, class T2>
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struct parameter_traits_ {
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typedef T2 type;
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};
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// Do not instantiate with reference types
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template<class T, class Any> struct parameter_traits_<T&, Any> {
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typedef typename
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generate_error<T&>::
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parameter_traits_class_instantiated_with_reference_type type;
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};
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// Arrays can't be stored as plain types; convert them to references
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template<class T, int n, class Any> struct parameter_traits_<T[n], Any> {
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typedef T (&type)[n];
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};
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template<class T, int n, class Any>
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struct parameter_traits_<const T[n], Any> {
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typedef const T (&type)[n];
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};
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template<class T, int n, class Any>
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struct parameter_traits_<volatile T[n], Any> {
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typedef volatile T (&type)[n];
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};
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template<class T, int n, class Any>
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struct parameter_traits_<const volatile T[n], Any> {
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typedef const volatile T (&type)[n];
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};
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template<class T, class Any>
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struct parameter_traits_<boost::reference_wrapper<T>, Any >{
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typedef T& type;
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};
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template<class T, class Any>
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struct parameter_traits_<const boost::reference_wrapper<T>, Any >{
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typedef T& type;
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};
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template<class T, class Any>
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struct parameter_traits_<volatile boost::reference_wrapper<T>, Any >{
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typedef T& type;
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};
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template<class T, class Any>
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struct parameter_traits_<const volatile boost::reference_wrapper<T>, Any >{
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typedef T& type;
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};
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template<class Any>
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struct parameter_traits_<void, Any> {
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typedef void type;
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};
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template<class Arg, class Any>
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struct parameter_traits_<lambda_functor<Arg>, Any > {
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typedef lambda_functor<Arg> type;
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};
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template<class Arg, class Any>
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struct parameter_traits_<const lambda_functor<Arg>, Any > {
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typedef lambda_functor<Arg> type;
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};
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// Are the volatile versions needed?
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template<class Arg, class Any>
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struct parameter_traits_<volatile lambda_functor<Arg>, Any > {
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typedef lambda_functor<Arg> type;
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};
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template<class Arg, class Any>
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struct parameter_traits_<const volatile lambda_functor<Arg>, Any > {
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typedef lambda_functor<Arg> type;
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};
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} // end namespace detail
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// ------------------------------------------------------------------------
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// traits classes for lambda expressions (bind functions, operators ...)
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// must be instantiated with non-reference types
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// The default is const plain type -------------------------
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// const T -> const T,
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// T -> const T,
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// references -> compile_time_error
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// reference_wrapper<T> -> T&
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// array -> const ref array
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template<class T>
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struct const_copy_argument {
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typedef typename
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detail::parameter_traits_<
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T,
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typename detail::IF<boost::is_function<T>::value, T&, const T>::RET
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>::type type;
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};
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// T may be a function type. Without the IF test, const would be added
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// to a function type, which is illegal.
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// all arrays are converted to const.
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// This traits template is used for 'const T&' parameter passing
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// and thus the knowledge of the potential
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// non-constness of an actual argument is lost.
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template<class T, int n> struct const_copy_argument <T[n]> {
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typedef const T (&type)[n];
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};
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template<class T, int n> struct const_copy_argument <volatile T[n]> {
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typedef const volatile T (&type)[n];
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};
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template<class T>
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struct const_copy_argument<T&> {};
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// do not instantiate with references
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// typedef typename detail::generate_error<T&>::references_not_allowed type;
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template<>
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struct const_copy_argument<void> {
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typedef void type;
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};
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template<>
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struct const_copy_argument<void const> {
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typedef void type;
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};
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// Does the same as const_copy_argument, but passes references through as such
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template<class T>
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struct bound_argument_conversion {
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typedef typename const_copy_argument<T>::type type;
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};
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template<class T>
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struct bound_argument_conversion<T&> {
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typedef T& type;
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};
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// The default is non-const reference -------------------------
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// const T -> const T&,
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// T -> T&,
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// references -> compile_time_error
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// reference_wrapper<T> -> T&
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template<class T>
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struct reference_argument {
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typedef typename detail::parameter_traits_<T, T&>::type type;
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};
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template<class T>
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struct reference_argument<T&> {
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typedef typename detail::generate_error<T&>::references_not_allowed type;
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};
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template<class Arg>
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struct reference_argument<lambda_functor<Arg> > {
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typedef lambda_functor<Arg> type;
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};
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template<class Arg>
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struct reference_argument<const lambda_functor<Arg> > {
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typedef lambda_functor<Arg> type;
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};
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// Are the volatile versions needed?
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template<class Arg>
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struct reference_argument<volatile lambda_functor<Arg> > {
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typedef lambda_functor<Arg> type;
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};
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template<class Arg>
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struct reference_argument<const volatile lambda_functor<Arg> > {
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typedef lambda_functor<Arg> type;
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};
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template<>
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struct reference_argument<void> {
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typedef void type;
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};
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namespace detail {
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// Array to pointer conversion
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template <class T>
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struct array_to_pointer {
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typedef T type;
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};
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template <class T, int N>
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struct array_to_pointer <const T[N]> {
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typedef const T* type;
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};
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template <class T, int N>
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struct array_to_pointer <T[N]> {
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typedef T* type;
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};
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template <class T, int N>
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struct array_to_pointer <const T (&) [N]> {
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typedef const T* type;
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};
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template <class T, int N>
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struct array_to_pointer <T (&) [N]> {
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typedef T* type;
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};
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// ---------------------------------------------------------------------------
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// The call_traits for bind
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// Respects the reference_wrapper class.
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// These templates are used outside of bind functions as well.
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// the bind_tuple_mapper provides a shorter notation for default
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// bound argument storing semantics, if all arguments are treated
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// uniformly.
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// from template<class T> foo(const T& t) : bind_traits<const T>::type
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// from template<class T> foo(T& t) : bind_traits<T>::type
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// Conversions:
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// T -> const T,
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// cv T -> cv T,
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// T& -> T&
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// reference_wrapper<T> -> T&
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// const reference_wrapper<T> -> T&
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// array -> const ref array
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// make bound arguments const, this is a deliberate design choice, the
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// purpose is to prevent side effects to bound arguments that are stored
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// as copies
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template<class T>
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struct bind_traits {
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typedef const T type;
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};
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template<class T>
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struct bind_traits<T&> {
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typedef T& type;
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};
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// null_types are an exception, we always want to store them as non const
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// so that other templates can assume that null_type is always without const
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template<>
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struct bind_traits<null_type> {
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typedef null_type type;
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};
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// the bind_tuple_mapper, bind_type_generators may
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// introduce const to null_type
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template<>
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struct bind_traits<const null_type> {
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typedef null_type type;
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};
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// Arrays can't be stored as plain types; convert them to references.
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// All arrays are converted to const. This is because bind takes its
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// parameters as const T& and thus the knowledge of the potential
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// non-constness of actual argument is lost.
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template<class T, int n> struct bind_traits <T[n]> {
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typedef const T (&type)[n];
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};
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template<class T, int n>
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struct bind_traits<const T[n]> {
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typedef const T (&type)[n];
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};
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template<class T, int n> struct bind_traits<volatile T[n]> {
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typedef const volatile T (&type)[n];
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};
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template<class T, int n>
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struct bind_traits<const volatile T[n]> {
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typedef const volatile T (&type)[n];
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};
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template<class R>
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struct bind_traits<R()> {
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typedef R(&type)();
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};
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template<class R, class Arg1>
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struct bind_traits<R(Arg1)> {
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typedef R(&type)(Arg1);
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};
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template<class R, class Arg1, class Arg2>
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struct bind_traits<R(Arg1, Arg2)> {
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typedef R(&type)(Arg1, Arg2);
|
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};
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template<class R, class Arg1, class Arg2, class Arg3>
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||
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struct bind_traits<R(Arg1, Arg2, Arg3)> {
|
||
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typedef R(&type)(Arg1, Arg2, Arg3);
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};
|
||
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||
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template<class R, class Arg1, class Arg2, class Arg3, class Arg4>
|
||
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struct bind_traits<R(Arg1, Arg2, Arg3, Arg4)> {
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||
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typedef R(&type)(Arg1, Arg2, Arg3, Arg4);
|
||
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};
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||
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||
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template<class R, class Arg1, class Arg2, class Arg3, class Arg4, class Arg5>
|
||
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struct bind_traits<R(Arg1, Arg2, Arg3, Arg4, Arg5)> {
|
||
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typedef R(&type)(Arg1, Arg2, Arg3, Arg4, Arg5);
|
||
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};
|
||
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||
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template<class R, class Arg1, class Arg2, class Arg3, class Arg4, class Arg5, class Arg6>
|
||
|
struct bind_traits<R(Arg1, Arg2, Arg3, Arg4, Arg5, Arg6)> {
|
||
|
typedef R(&type)(Arg1, Arg2, Arg3, Arg4, Arg5, Arg6);
|
||
|
};
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||
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||
|
template<class R, class Arg1, class Arg2, class Arg3, class Arg4, class Arg5, class Arg6, class Arg7>
|
||
|
struct bind_traits<R(Arg1, Arg2, Arg3, Arg4, Arg5, Arg6, Arg7)> {
|
||
|
typedef R(&type)(Arg1, Arg2, Arg3, Arg4, Arg5, Arg6, Arg7);
|
||
|
};
|
||
|
|
||
|
template<class R, class Arg1, class Arg2, class Arg3, class Arg4, class Arg5, class Arg6, class Arg7, class Arg8>
|
||
|
struct bind_traits<R(Arg1, Arg2, Arg3, Arg4, Arg5, Arg6, Arg7, Arg8)> {
|
||
|
typedef R(&type)(Arg1, Arg2, Arg3, Arg4, Arg5, Arg6, Arg7, Arg8);
|
||
|
};
|
||
|
|
||
|
template<class R, class Arg1, class Arg2, class Arg3, class Arg4, class Arg5, class Arg6, class Arg7, class Arg8, class Arg9>
|
||
|
struct bind_traits<R(Arg1, Arg2, Arg3, Arg4, Arg5, Arg6, Arg7, Arg8, Arg9)> {
|
||
|
typedef R(&type)(Arg1, Arg2, Arg3, Arg4, Arg5, Arg6, Arg7, Arg8, Arg9);
|
||
|
};
|
||
|
|
||
|
template<class T>
|
||
|
struct bind_traits<reference_wrapper<T> >{
|
||
|
typedef T& type;
|
||
|
};
|
||
|
|
||
|
template<class T>
|
||
|
struct bind_traits<const reference_wrapper<T> >{
|
||
|
typedef T& type;
|
||
|
};
|
||
|
|
||
|
template<>
|
||
|
struct bind_traits<void> {
|
||
|
typedef void type;
|
||
|
};
|
||
|
|
||
|
|
||
|
|
||
|
template <
|
||
|
class T0 = null_type, class T1 = null_type, class T2 = null_type,
|
||
|
class T3 = null_type, class T4 = null_type, class T5 = null_type,
|
||
|
class T6 = null_type, class T7 = null_type, class T8 = null_type,
|
||
|
class T9 = null_type
|
||
|
>
|
||
|
struct bind_tuple_mapper {
|
||
|
typedef
|
||
|
tuple<typename bind_traits<T0>::type,
|
||
|
typename bind_traits<T1>::type,
|
||
|
typename bind_traits<T2>::type,
|
||
|
typename bind_traits<T3>::type,
|
||
|
typename bind_traits<T4>::type,
|
||
|
typename bind_traits<T5>::type,
|
||
|
typename bind_traits<T6>::type,
|
||
|
typename bind_traits<T7>::type,
|
||
|
typename bind_traits<T8>::type,
|
||
|
typename bind_traits<T9>::type> type;
|
||
|
};
|
||
|
|
||
|
// bind_traits, except map const T& -> const T
|
||
|
// this is needed e.g. in currying. Const reference arguments can
|
||
|
// refer to temporaries, so it is not safe to store them as references.
|
||
|
template <class T> struct remove_const_reference {
|
||
|
typedef typename bind_traits<T>::type type;
|
||
|
};
|
||
|
|
||
|
template <class T> struct remove_const_reference<const T&> {
|
||
|
typedef const T type;
|
||
|
};
|
||
|
|
||
|
|
||
|
// maps the bind argument types to the resulting lambda functor type
|
||
|
template <
|
||
|
class T0 = null_type, class T1 = null_type, class T2 = null_type,
|
||
|
class T3 = null_type, class T4 = null_type, class T5 = null_type,
|
||
|
class T6 = null_type, class T7 = null_type, class T8 = null_type,
|
||
|
class T9 = null_type
|
||
|
>
|
||
|
class bind_type_generator {
|
||
|
|
||
|
typedef typename
|
||
|
detail::bind_tuple_mapper<
|
||
|
T0, T1, T2, T3, T4, T5, T6, T7, T8, T9
|
||
|
>::type args_t;
|
||
|
|
||
|
BOOST_STATIC_CONSTANT(int, nof_elems = boost::tuples::length<args_t>::value);
|
||
|
|
||
|
typedef
|
||
|
action<
|
||
|
nof_elems,
|
||
|
function_action<nof_elems>
|
||
|
> action_type;
|
||
|
|
||
|
public:
|
||
|
typedef
|
||
|
lambda_functor<
|
||
|
lambda_functor_base<
|
||
|
action_type,
|
||
|
args_t
|
||
|
>
|
||
|
> type;
|
||
|
|
||
|
};
|
||
|
|
||
|
|
||
|
|
||
|
} // detail
|
||
|
|
||
|
template <class T> inline const T& make_const(const T& t) { return t; }
|
||
|
|
||
|
|
||
|
} // end of namespace lambda
|
||
|
} // end of namespace boost
|
||
|
|
||
|
|
||
|
|
||
|
#endif // BOOST_LAMBDA_TRAITS_HPP
|