[ceph.git] / ceph / src / boost / libs / spirit / include / boost / spirit / home / karma / operator / sequence.hpp

//  Copyright (c) 2001-2011 Hartmut Kaiser
//  Copyright (c) 2001-2011 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_SEQUENCE_FEB_28_2007_0247PM)
#define SPIRIT_KARMA_SEQUENCE_FEB_28_2007_0247PM

#if defined(_MSC_VER)
#pragma once
#endif

#include <boost/spirit/home/karma/domain.hpp>
#include <boost/spirit/home/karma/generator.hpp>
#include <boost/spirit/home/karma/meta_compiler.hpp>
#include <boost/spirit/home/karma/detail/fail_function.hpp>
#include <boost/spirit/home/karma/detail/pass_container.hpp>
#include <boost/spirit/home/karma/detail/get_stricttag.hpp>
#include <boost/spirit/home/support/info.hpp>
#include <boost/spirit/home/support/detail/what_function.hpp>
#include <boost/spirit/home/karma/detail/attributes.hpp>
#include <boost/spirit/home/karma/detail/indirect_iterator.hpp>
#include <boost/spirit/home/support/algorithm/any_if.hpp>
#include <boost/spirit/home/support/unused.hpp>
#include <boost/spirit/home/support/sequence_base_id.hpp>
#include <boost/spirit/home/support/has_semantic_action.hpp>
#include <boost/spirit/home/support/handles_container.hpp>
#include <boost/spirit/home/support/attributes.hpp>
#include <boost/fusion/include/vector.hpp>
#include <boost/fusion/include/as_vector.hpp>
#include <boost/fusion/include/for_each.hpp>
#include <boost/type_traits/is_same.hpp>
#include <boost/mpl/bitor.hpp>
#include <boost/mpl/int.hpp>
#include <boost/mpl/and.hpp>
#include <boost/mpl/not.hpp>
#include <boost/fusion/include/transform.hpp>
#include <boost/mpl/accumulate.hpp>
#include <boost/config.hpp>

///////////////////////////////////////////////////////////////////////////////
namespace boost { namespace spirit
{
    ///////////////////////////////////////////////////////////////////////////
    // Enablers
    ///////////////////////////////////////////////////////////////////////////
    template <>
    struct use_operator<karma::domain, proto::tag::shift_left> // enables <<
      : mpl::true_ {};

    template <>
    struct flatten_tree<karma::domain, proto::tag::shift_left> // flattens <<
      : mpl::true_ {};
}}

///////////////////////////////////////////////////////////////////////////////
namespace boost { namespace spirit { namespace traits
{
    // specialization for sequences
    template <typename Elements>
    struct sequence_properties
    {
        struct element_properties
        {
            template <typename T>
            struct result;

            template <typename F, typename Element>
            struct result<F(Element)>
            {
                typedef properties_of<Element> type;
            };

            // never called, but needed for decltype-based result_of (C++0x)
#ifndef BOOST_NO_CXX11_RVALUE_REFERENCES
            template <typename Element>
            typename result<element_properties(Element)>::type
            operator()(Element&&) const;
#endif
        };

        typedef typename mpl::accumulate<
            typename fusion::result_of::transform<
                Elements, element_properties>::type
          , mpl::int_<karma::generator_properties::no_properties>
          , mpl::bitor_<mpl::_2, mpl::_1>
        >::type type;
    };
}}}

///////////////////////////////////////////////////////////////////////////////
namespace boost { namespace spirit { namespace karma
{
    template <typename Elements, typename Strict, typename Derived>
    struct base_sequence : nary_generator<Derived>
    {
        typedef typename traits::sequence_properties<Elements>::type properties;

        base_sequence(Elements const& elements)
          : elements(elements) {}

        typedef Elements elements_type;
        struct sequence_base_id;

        template <typename Context, typename Iterator = unused_type>
        struct attribute
        {
            // Put all the element attributes in a tuple
            typedef typename traits::build_attribute_sequence<
                Elements, Context, traits::sequence_attribute_transform
              , Iterator, karma::domain
            >::type all_attributes;

            // Now, build a fusion vector over the attributes. Note
            // that build_fusion_vector 1) removes all unused attributes
            // and 2) may return unused_type if all elements have
            // unused_type(s).
            typedef typename
                traits::build_fusion_vector<all_attributes>::type
            type_;

            // Finally, strip single element vectors into its
            // naked form: vector1<T> --> T
            typedef typename
                traits::strip_single_element_vector<type_>::type
            type;
        };

        // standard case. Attribute is a fusion tuple
        template <
            typename OutputIterator, typename Context, typename Delimiter
          , typename Attribute, typename Pred1, typename Pred2>
        bool generate_impl(OutputIterator& sink, Context& ctx
          , Delimiter const& d, Attribute& attr_, Pred1, Pred2) const
        {
            typedef detail::fail_function<
                OutputIterator, Context, Delimiter> fail_function;
            typedef traits::attribute_not_unused<Context> predicate;

            // wrap the attribute in a tuple if it is not a tuple or if the
            // attribute of this sequence is a single element tuple
            typedef typename attribute<Context>::type_ attr_type_;
            typename traits::wrap_if_not_tuple<Attribute
              , typename mpl::and_<
                    traits::one_element_sequence<attr_type_>
                  , mpl::not_<traits::one_element_sequence<Attribute> >
                >::type
            >::type attr(attr_);

            // return false if *any* of the generators fail
            bool r = spirit::any_if(elements, attr
                          , fail_function(sink, ctx, d), predicate());

            typedef typename traits::attribute_size<Attribute>::type size_type;

            // fail generating if sequences have not the same (logical) length
            return !r && (!Strict::value ||
                // This ignores container element count (which is not good),
                // but allows valid attributes to succeed. This will lead to
                // false positives (failing generators, even if they shouldn't)
                // if the embedded component is restricting the number of
                // container elements it consumes (i.e. repeat). This solution
                // is not optimal but much better than letting _all_ repetitive
                // components fail.
                Pred1::value ||
                size_type(traits::sequence_size<attr_type_>::value) == traits::size(attr_));
        }

        // Special case when Attribute is an stl container and the sequence's
        // attribute is not a one element sequence
        template <
            typename OutputIterator, typename Context, typename Delimiter
          , typename Attribute>
        bool generate_impl(OutputIterator& sink, Context& ctx
          , Delimiter const& d, Attribute const& attr_
          , mpl::true_, mpl::false_) const
        {
            // return false if *any* of the generators fail
            typedef detail::fail_function<
                OutputIterator, Context, Delimiter> fail_function;

            typedef typename traits::container_iterator<
                typename add_const<Attribute>::type
            >::type iterator_type;

            typedef
                typename traits::make_indirect_iterator<iterator_type>::type
            indirect_iterator_type;
            typedef detail::pass_container<
                fail_function, Attribute, indirect_iterator_type, mpl::true_>
            pass_container;

            iterator_type begin = traits::begin(attr_);
            iterator_type end = traits::end(attr_);

            pass_container pass(fail_function(sink, ctx, d),
                indirect_iterator_type(begin), indirect_iterator_type(end));
            bool r = fusion::any(elements, pass);

            // fail generating if sequences have not the same (logical) length
            return !r && (!Strict::value || begin == end);
        }

        // main generate function. Dispatches to generate_impl depending
        // on the Attribute type.
        template <
            typename OutputIterator, typename Context, typename Delimiter
          , typename Attribute>
        bool generate(OutputIterator& sink, Context& ctx, Delimiter const& d
          , Attribute const& attr) const
        {
            typedef typename traits::is_container<Attribute>::type
                is_container;

            typedef typename attribute<Context>::type_ attr_type_;
            typedef typename traits::one_element_sequence<attr_type_>::type
                is_one_element_sequence;

            return generate_impl(sink, ctx, d, attr, is_container()
              , is_one_element_sequence());
        }

        template <typename Context>
        info what(Context& context) const
        {
            info result("sequence");
            fusion::for_each(elements,
                spirit::detail::what_function<Context>(result, context));
            return result;
        }

        Elements elements;
    };

    template <typename Elements>
    struct sequence
      : base_sequence<Elements, mpl::false_, sequence<Elements> >
    {
        typedef base_sequence<Elements, mpl::false_, sequence> base_sequence_;

        sequence(Elements const& subject)
          : base_sequence_(subject) {}
    };

    template <typename Elements>
    struct strict_sequence
      : base_sequence<Elements, mpl::true_, strict_sequence<Elements> >
    {
        typedef base_sequence<Elements, mpl::true_, strict_sequence>
            base_sequence_;

        strict_sequence(Elements const& subject)
          : base_sequence_(subject) {}
    };

    ///////////////////////////////////////////////////////////////////////////
    // Generator generators: make_xxx function (objects)
    ///////////////////////////////////////////////////////////////////////////
    namespace detail
    {
        template <typename Elements, bool strict_mode = false>
        struct make_sequence
          : make_nary_composite<Elements, sequence>
        {};

        template <typename Elements>
        struct make_sequence<Elements, true>
          : make_nary_composite<Elements, strict_sequence>
        {};
    }

    template <typename Elements, typename Modifiers>
    struct make_composite<proto::tag::shift_left, Elements, Modifiers>
      : detail::make_sequence<Elements, detail::get_stricttag<Modifiers>::value>
    {};

    ///////////////////////////////////////////////////////////////////////////
    // Helper template allowing to get the required container type for a rule
    // attribute, which is part of a sequence.
    template <typename Iterator>
    struct make_sequence_iterator_range
    {
        typedef iterator_range<detail::indirect_iterator<Iterator> > type;
    };
}}}

namespace boost { namespace spirit { namespace traits
{
    ///////////////////////////////////////////////////////////////////////////
    template <typename Elements>
    struct has_semantic_action<karma::sequence<Elements> >
      : nary_has_semantic_action<Elements> {};

    template <typename Elements>
    struct has_semantic_action<karma::strict_sequence<Elements> >
      : nary_has_semantic_action<Elements> {};

    ///////////////////////////////////////////////////////////////////////////
    template <typename Elements, typename Attribute, typename Context
      , typename Iterator>
    struct handles_container<karma::sequence<Elements>, Attribute, Context
          , Iterator>
      : mpl::true_ {};

    template <typename Elements, typename Attribute, typename Context
      , typename Iterator>
    struct handles_container<karma::strict_sequence<Elements>, Attribute
          , Context, Iterator>
      : mpl::true_ {};
}}}

#endif
Commit	Line	Data
7c673cae FG	1	// Copyright (c) 2001-2011 Hartmut Kaiser
	2	// Copyright (c) 2001-2011 Joel de Guzman
	3	//
	4	// Distributed under the Boost Software License, Version 1.0. (See accompanying
	5	// file LICENSE_1_0.txt or copy at http://www.boost.org/LICENSE_1_0.txt)
	6
	7	#if !defined(SPIRIT_KARMA_SEQUENCE_FEB_28_2007_0247PM)
	8	#define SPIRIT_KARMA_SEQUENCE_FEB_28_2007_0247PM
	9
	10	#if defined(_MSC_VER)
	11	#pragma once
	12	#endif
	13
	14	#include <boost/spirit/home/karma/domain.hpp>
	15	#include <boost/spirit/home/karma/generator.hpp>
	16	#include <boost/spirit/home/karma/meta_compiler.hpp>
	17	#include <boost/spirit/home/karma/detail/fail_function.hpp>
	18	#include <boost/spirit/home/karma/detail/pass_container.hpp>
	19	#include <boost/spirit/home/karma/detail/get_stricttag.hpp>
	20	#include <boost/spirit/home/support/info.hpp>
	21	#include <boost/spirit/home/support/detail/what_function.hpp>
	22	#include <boost/spirit/home/karma/detail/attributes.hpp>
	23	#include <boost/spirit/home/karma/detail/indirect_iterator.hpp>
	24	#include <boost/spirit/home/support/algorithm/any_if.hpp>
	25	#include <boost/spirit/home/support/unused.hpp>
	26	#include <boost/spirit/home/support/sequence_base_id.hpp>
	27	#include <boost/spirit/home/support/has_semantic_action.hpp>
	28	#include <boost/spirit/home/support/handles_container.hpp>
	29	#include <boost/spirit/home/support/attributes.hpp>
	30	#include <boost/fusion/include/vector.hpp>
	31	#include <boost/fusion/include/as_vector.hpp>
	32	#include <boost/fusion/include/for_each.hpp>
	33	#include <boost/type_traits/is_same.hpp>
	34	#include <boost/mpl/bitor.hpp>
	35	#include <boost/mpl/int.hpp>
	36	#include <boost/mpl/and.hpp>
	37	#include <boost/mpl/not.hpp>
	38	#include <boost/fusion/include/transform.hpp>
	39	#include <boost/mpl/accumulate.hpp>
	40	#include <boost/config.hpp>
	41
	42	///////////////////////////////////////////////////////////////////////////////
	43	namespace boost { namespace spirit
	44	{
	45	///////////////////////////////////////////////////////////////////////////
	46	// Enablers
	47	///////////////////////////////////////////////////////////////////////////
	48	template <>
	49	struct use_operator<karma::domain, proto::tag::shift_left> // enables <<
	50	: mpl::true_ {};
	51
	52	template <>
	53	struct flatten_tree<karma::domain, proto::tag::shift_left> // flattens <<
	54	: mpl::true_ {};
	55	}}
	56
	57	///////////////////////////////////////////////////////////////////////////////
	58	namespace boost { namespace spirit { namespace traits
	59	{
	60	// specialization for sequences
	61	template <typename Elements>
	62	struct sequence_properties
	63	{
	64	struct element_properties
65	{
66	template <typename T>
67	struct result;
68
69	template <typename F, typename Element>
70	struct result<F(Element)>
71	{
72	typedef properties_of<Element> type;
73	};
74
75	// never called, but needed for decltype-based result_of (C++0x)
76	#ifndef BOOST_NO_CXX11_RVALUE_REFERENCES
77	template <typename Element>
78	typename result<element_properties(Element)>::type
79	operator()(Element&&) const;
80	#endif
81	};
82
83	typedef typename mpl::accumulate<
84	typename fusion::result_of::transform<
85	Elements, element_properties>::type
86	, mpl::int_<karma::generator_properties::no_properties>
87	, mpl::bitor_<mpl::_2, mpl::_1>
88	>::type type;
89	};
90	}}}
91
92	///////////////////////////////////////////////////////////////////////////////
93	namespace boost { namespace spirit { namespace karma
94	{
95	template <typename Elements, typename Strict, typename Derived>
96	struct base_sequence : nary_generator<Derived>
97	{
98	typedef typename traits::sequence_properties<Elements>::type properties;
99
100	base_sequence(Elements const& elements)
101	: elements(elements) {}
102
103	typedef Elements elements_type;
104	struct sequence_base_id;
105
106	template <typename Context, typename Iterator = unused_type>
107	struct attribute
108	{
109	// Put all the element attributes in a tuple
110	typedef typename traits::build_attribute_sequence<
111	Elements, Context, traits::sequence_attribute_transform
112	, Iterator, karma::domain
113	>::type all_attributes;
114
115	// Now, build a fusion vector over the attributes. Note
116	// that build_fusion_vector 1) removes all unused attributes
117	// and 2) may return unused_type if all elements have
118	// unused_type(s).
119	typedef typename
120	traits::build_fusion_vector<all_attributes>::type
121	type_;
122
123	// Finally, strip single element vectors into its
124	// naked form: vector1<T> --> T
125	typedef typename
126	traits::strip_single_element_vector<type_>::type
127	type;
128	};
129
130	// standard case. Attribute is a fusion tuple
131	template <
132	typename OutputIterator, typename Context, typename Delimiter
133	, typename Attribute, typename Pred1, typename Pred2>
134	bool generate_impl(OutputIterator& sink, Context& ctx
135	, Delimiter const& d, Attribute& attr_, Pred1, Pred2) const
136	{
137	typedef detail::fail_function<
138	OutputIterator, Context, Delimiter> fail_function;
139	typedef traits::attribute_not_unused<Context> predicate;
140
141	// wrap the attribute in a tuple if it is not a tuple or if the
142	// attribute of this sequence is a single element tuple
143	typedef typename attribute<Context>::type_ attr_type_;
144	typename traits::wrap_if_not_tuple<Attribute
145	, typename mpl::and_<
146	traits::one_element_sequence<attr_type_>
147	, mpl::not_<traits::one_element_sequence<Attribute> >
148	>::type
149	>::type attr(attr_);
150
151	// return false if any of the generators fail
152	bool r = spirit::any_if(elements, attr
153	, fail_function(sink, ctx, d), predicate());
154
155	typedef typename traits::attribute_size<Attribute>::type size_type;
156
157	// fail generating if sequences have not the same (logical) length
158	return !r && (!Strict::value \|\|
159	// This ignores container element count (which is not good),
160	// but allows valid attributes to succeed. This will lead to
161	// false positives (failing generators, even if they shouldn't)
162	// if the embedded component is restricting the number of
163	// container elements it consumes (i.e. repeat). This solution
164	// is not optimal but much better than letting _all_ repetitive
165	// components fail.
166	Pred1::value \|\|
167	size_type(traits::sequence_size<attr_type_>::value) == traits::size(attr_));
168	}
169
170	// Special case when Attribute is an stl container and the sequence's
171	// attribute is not a one element sequence
172	template <
173	typename OutputIterator, typename Context, typename Delimiter
174	, typename Attribute>
175	bool generate_impl(OutputIterator& sink, Context& ctx
176	, Delimiter const& d, Attribute const& attr_
177	, mpl::true_, mpl::false_) const
178	{
179	// return false if any of the generators fail
180	typedef detail::fail_function<
181	OutputIterator, Context, Delimiter> fail_function;
182
183	typedef typename traits::container_iterator<
184	typename add_const<Attribute>::type
185	>::type iterator_type;
186
187	typedef
188	typename traits::make_indirect_iterator<iterator_type>::type
189	indirect_iterator_type;
190	typedef detail::pass_container<
191	fail_function, Attribute, indirect_iterator_type, mpl::true_>
192	pass_container;
193
194	iterator_type begin = traits::begin(attr_);
195	iterator_type end = traits::end(attr_);
196
197	pass_container pass(fail_function(sink, ctx, d),
198	indirect_iterator_type(begin), indirect_iterator_type(end));
199	bool r = fusion::any(elements, pass);
200
201	// fail generating if sequences have not the same (logical) length
202	return !r && (!Strict::value \|\| begin == end);
203	}
204
205	// main generate function. Dispatches to generate_impl depending
206	// on the Attribute type.
207	template <
208	typename OutputIterator, typename Context, typename Delimiter
209	, typename Attribute>
210	bool generate(OutputIterator& sink, Context& ctx, Delimiter const& d
211	, Attribute const& attr) const
212	{
213	typedef typename traits::is_container<Attribute>::type
214	is_container;
215
216	typedef typename attribute<Context>::type_ attr_type_;
217	typedef typename traits::one_element_sequence<attr_type_>::type
218	is_one_element_sequence;
219
220	return generate_impl(sink, ctx, d, attr, is_container()
221	, is_one_element_sequence());
222	}
223
224	template <typename Context>
225	info what(Context& context) const
226	{
227	info result("sequence");
228	fusion::for_each(elements,
229	spirit::detail::what_function<Context>(result, context));
230	return result;
231	}
232
233	Elements elements;
234	};
235
236	template <typename Elements>
237	struct sequence
238	: base_sequence<Elements, mpl::false_, sequence<Elements> >
239	{
240	typedef base_sequence<Elements, mpl::false_, sequence> base_sequence_;
241
242	sequence(Elements const& subject)
243	: base_sequence_(subject) {}
244	};
245
246	template <typename Elements>
247	struct strict_sequence
248	: base_sequence<Elements, mpl::true_, strict_sequence<Elements> >
249	{
250	typedef base_sequence<Elements, mpl::true_, strict_sequence>
251	base_sequence_;
252
253	strict_sequence(Elements const& subject)
254	: base_sequence_(subject) {}
255	};
256
257	///////////////////////////////////////////////////////////////////////////
258	// Generator generators: make_xxx function (objects)
259	///////////////////////////////////////////////////////////////////////////
260	namespace detail
261	{
262	template <typename Elements, bool strict_mode = false>
263	struct make_sequence
264	: make_nary_composite<Elements, sequence>
265	{};
266
267	template <typename Elements>
268	struct make_sequence<Elements, true>
269	: make_nary_composite<Elements, strict_sequence>
270	{};
271	}
272
273	template <typename Elements, typename Modifiers>
274	struct make_composite<proto::tag::shift_left, Elements, Modifiers>
275	: detail::make_sequence<Elements, detail::get_stricttag<Modifiers>::value>
276	{};
277
278	///////////////////////////////////////////////////////////////////////////
279	// Helper template allowing to get the required container type for a rule
280	// attribute, which is part of a sequence.
281	template <typename Iterator>
282	struct make_sequence_iterator_range
283	{
284	typedef iterator_range<detail::indirect_iterator<Iterator> > type;
285	};
286	}}}
287
288	namespace boost { namespace spirit { namespace traits
289	{
290	///////////////////////////////////////////////////////////////////////////
291	template <typename Elements>
292	struct has_semantic_action<karma::sequence<Elements> >
293	: nary_has_semantic_action<Elements> {};
294
295	template <typename Elements>
296	struct has_semantic_action<karma::strict_sequence<Elements> >
297	: nary_has_semantic_action<Elements> {};
298
299	///////////////////////////////////////////////////////////////////////////
300	template <typename Elements, typename Attribute, typename Context
301	, typename Iterator>
302	struct handles_container<karma::sequence<Elements>, Attribute, Context
303	, Iterator>
304	: mpl::true_ {};
305
306	template <typename Elements, typename Attribute, typename Context
307	, typename Iterator>
308	struct handles_container<karma::strict_sequence<Elements>, Attribute
309	, Context, Iterator>
310	: mpl::true_ {};
311	}}}
312
313	#endif