// Boost.Range library concept checks // // Copyright Daniel Walker 2006. Use, modification and distribution // are 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) // // For more information, see http://www.boost.org/libs/range/ // #ifndef BOOST_RANGE_CONCEPTS_HPP #define BOOST_RANGE_CONCEPTS_HPP #include #include #include #include /*! * \file * \brief Concept checks for the Boost Range library. * * The structures in this file may be used in conjunction with the * Boost Concept Check library to insure that the type of a function * parameter is compatible with a range concept. If not, a meaningful * compile time error is generated. Checks are provided for the range * concepts related to iterator traversal categories. For example, the * following line checks that the type T models the ForwardRange * concept. * * \code * function_requires >(); * \endcode * * An additional concept check is required for the value access * property of the range. For example to check for a * ForwardReadableRange, the following code is required. * * \code * function_requires >(); * function_requires< * ReadableIteratorConcept< * typename range_iterator::type * > * >(); * \endcode * * \see http://www.boost.org/libs/range/doc/range.html for details * about range concepts. * \see http://www.boost.org/libs/iterator/doc/iterator_concepts.html * for details about iterator concepts. * \see http://www.boost.org/libs/concept_check/concept_check.htm for * details about concept checks. */ namespace boost { //! Check if a type T models the SinglePassRange range concept. template struct SinglePassRangeConcept { typedef typename range_value::type range_value; typedef typename range_iterator::type range_iterator; typedef typename range_const_iterator::type range_const_iterator; void constraints() { function_requires< boost_concepts::SinglePassIteratorConcept< range_iterator > >(); i = boost::begin(a); i = boost::end(a); b = boost::empty(a); const_constraints(a); } void const_constraints(const T& a) { ci = boost::begin(a); ci = boost::end(a); } T a; range_iterator i; range_const_iterator ci; bool b; }; //! Check if a type T models the ForwardRange range concept. template struct ForwardRangeConcept { typedef typename range_difference::type range_difference; typedef typename range_size::type range_size; void constraints() { function_requires< SinglePassRangeConcept >(); function_requires< boost_concepts::ForwardTraversalConcept< typename range_iterator::type > >(); s = boost::size(a); } T a; range_size s; }; //! Check if a type T models the BidirectionalRange range concept. template struct BidirectionalRangeConcept { typedef typename range_reverse_iterator::type range_reverse_iterator; typedef typename range_const_reverse_iterator::type range_const_reverse_iterator; void constraints() { function_requires< ForwardRangeConcept >(); function_requires< boost_concepts::BidirectionalTraversalConcept< typename range_iterator::type > >(); i = boost::rbegin(a); i = boost::rend(a); const_constraints(a); } void const_constraints(const T& a) { ci = boost::rbegin(a); ci = boost::rend(a); } T a; range_reverse_iterator i; range_const_reverse_iterator ci; }; //! Check if a type T models the RandomAccessRange range concept. template struct RandomAccessRangeConcept { void constraints() { function_requires< BidirectionalRangeConcept >(); function_requires< boost_concepts::RandomAccessTraversalConcept< typename range_iterator::type > >(); } }; } // namespace boost #endif // BOOST_RANGE_CONCEPTS_HPP