// Copyright (c) 2001-2010 Hartmut Kaiser // Copyright (c) 2001-2010 Joel de Guzman // // 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(SPIRIT_KARMA_REPEAT_MAY_18_2009_0926AM) #define SPIRIT_KARMA_REPEAT_MAY_18_2009_0926AM #if defined(_MSC_VER) #pragma once #endif #include #include #include #include #include #include #include #include #include #include #include namespace boost { namespace spirit { /////////////////////////////////////////////////////////////////////////// // Enablers /////////////////////////////////////////////////////////////////////////// template <> struct use_directive // enables repeat[p] : mpl::true_ {}; template struct use_directive > > : mpl::true_ {}; template struct use_directive > > : mpl::true_ {}; template struct use_directive > > : mpl::true_ {}; template <> // enables *lazy* repeat(exact)[p] struct use_lazy_directive< karma::domain , tag::repeat , 1 // arity > : mpl::true_ {}; template <> // enables *lazy* repeat(min, max)[p] struct use_lazy_directive< // and repeat(min, inf)[p] karma::domain , tag::repeat , 2 // arity > : mpl::true_ {}; }} namespace boost { namespace spirit { namespace karma { using spirit::repeat; using spirit::repeat_type; using spirit::inf; using spirit::inf_type; /////////////////////////////////////////////////////////////////////////// // handles repeat(exact)[p] template struct exact_iterator { exact_iterator(T const exact) : exact(exact) {} typedef T type; T start() const { return 0; } bool got_max(T i) const { return i >= exact; } bool got_min(T i) const { return i >= exact; } T const exact; private: // silence MSVC warning C4512: assignment operator could not be generated exact_iterator& operator= (exact_iterator const&); }; // handles repeat(min, max)[p] template struct finite_iterator { finite_iterator(T const min, T const max) : min BOOST_PREVENT_MACRO_SUBSTITUTION (min) , max BOOST_PREVENT_MACRO_SUBSTITUTION (max) {} typedef T type; T start() const { return 0; } bool got_max(T i) const { return i >= max; } bool got_min(T i) const { return i >= min; } T const min; T const max; private: // silence MSVC warning C4512: assignment operator could not be generated finite_iterator& operator= (finite_iterator const&); }; // handles repeat(min, inf)[p] template struct infinite_iterator { infinite_iterator(T const min) : min BOOST_PREVENT_MACRO_SUBSTITUTION (min) {} typedef T type; T start() const { return 0; } bool got_max(T /*i*/) const { return false; } bool got_min(T i) const { return i >= min; } T const min; private: // silence MSVC warning C4512: assignment operator could not be generated infinite_iterator& operator= (infinite_iterator const&); }; /////////////////////////////////////////////////////////////////////////// template struct base_repeat_generator : unary_generator { private: // iterate over the given container until its exhausted or the embedded // (left) generator succeeds template < typename OutputIterator, typename Context, typename Delimiter , typename Iterator, typename Attribute> bool generate_subject(OutputIterator& sink, Context& ctx , Delimiter const& d, Iterator& it, Iterator& end, Attribute const&) const { // Failing subject generators are just skipped. This allows to // selectively generate items in the provided attribute. while (!traits::compare(it, end)) { if (subject.generate(sink, ctx, d, traits::deref(it))) return true; if (Strict::value) return false; traits::next(it); } return false; } template < typename OutputIterator, typename Context, typename Delimiter , typename Iterator> bool generate_subject(OutputIterator& sink, Context& ctx , Delimiter const& d, Iterator&, Iterator&, unused_type) const { // There is no way to distinguish a failed generator from a // generator to be skipped. We assume the user takes responsibility // for ending the loop if no attribute is specified. return subject.generate(sink, ctx, d, unused); } public: typedef Subject subject_type; typedef mpl::int_ properties; // Build a std::vector from the subject's attribute. Note // that build_std_vector may return unused_type if the // subject's attribute is an unused_type. template struct attribute : traits::build_std_vector< typename traits::attribute_of::type > {}; base_repeat_generator(Subject const& subject, LoopIter const& iter) : subject(subject), iter(iter) {} template bool generate(OutputIterator& sink, Context& ctx, Delimiter const& d , Attribute const& attr) const { typedef typename traits::container_iterator< typename add_const::type >::type iterator_type; iterator_type it = traits::begin(attr); iterator_type end = traits::end(attr); typename LoopIter::type i = iter.start(); // generate the minimal required amount of output for (/**/; !iter.got_min(i); ++i, traits::next(it)) { if (!generate_subject(sink, ctx, d, it, end, attr)) { // if we fail before reaching the minimum iteration // required, do not output anything and return false return false; } } // generate some more up to the maximum specified for (/**/; detail::sink_is_good(sink) && !iter.got_max(i); ++i, traits::next(it)) { if (!generate_subject(sink, ctx, d, it, end, attr)) break; } return detail::sink_is_good(sink); } template info what(Context& context) const { return info("repeat", subject.what(context)); } Subject subject; LoopIter iter; }; template struct repeat_generator : base_repeat_generator< Subject, LoopIter, mpl::false_ , repeat_generator > { typedef base_repeat_generator< Subject, LoopIter, mpl::false_, repeat_generator > base_repeat_generator_; repeat_generator(Subject const& subject, LoopIter const& iter) : base_repeat_generator_(subject, iter) {} }; template struct strict_repeat_generator : base_repeat_generator< Subject, LoopIter, mpl::true_ , strict_repeat_generator > { typedef base_repeat_generator< Subject, LoopIter, mpl::true_, strict_repeat_generator > base_repeat_generator_; strict_repeat_generator(Subject const& subject, LoopIter const& iter) : base_repeat_generator_(subject, iter) {} }; /////////////////////////////////////////////////////////////////////////// // Generator generators: make_xxx function (objects) /////////////////////////////////////////////////////////////////////////// template struct make_directive { typedef typename mpl::if_< detail::get_stricttag , strict_kleene, kleene >::type result_type; result_type operator()(unused_type, Subject const& subject , unused_type) const { return result_type(subject); } }; template struct make_directive< terminal_ex >, Subject, Modifiers> { typedef exact_iterator iterator_type; typedef typename mpl::if_< detail::get_stricttag , strict_repeat_generator , repeat_generator >::type result_type; template result_type operator()( Terminal const& term, Subject const& subject, unused_type) const { return result_type(subject, fusion::at_c<0>(term.args)); } }; template struct make_directive< terminal_ex >, Subject, Modifiers> { typedef finite_iterator iterator_type; typedef typename mpl::if_< detail::get_stricttag , strict_repeat_generator , repeat_generator >::type result_type; template result_type operator()( Terminal const& term, Subject const& subject, unused_type) const { return result_type(subject, iterator_type( fusion::at_c<0>(term.args) , fusion::at_c<1>(term.args) ) ); } }; template struct make_directive< terminal_ex >, Subject, Modifiers> { typedef infinite_iterator iterator_type; typedef typename mpl::if_< detail::get_stricttag , strict_repeat_generator , repeat_generator >::type result_type; template result_type operator()( Terminal const& term, Subject const& subject, unused_type) const { return result_type(subject, fusion::at_c<0>(term.args)); } }; }}} namespace boost { namespace spirit { namespace traits { template struct has_semantic_action > : unary_has_semantic_action {}; template struct has_semantic_action > : unary_has_semantic_action {}; }}} #endif