vn-verdnaturachat/ios/Pods/boost-for-react-native/boost/graph/named_function_params.hpp

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33 KiB
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//=======================================================================
// Copyright 1997, 1998, 1999, 2000 University of Notre Dame.
// Authors: Andrew Lumsdaine, Lie-Quan Lee, Jeremy G. Siek
//
// 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_GRAPH_NAMED_FUNCTION_PARAMS_HPP
#define BOOST_GRAPH_NAMED_FUNCTION_PARAMS_HPP
#include <functional>
#include <vector>
#include <boost/limits.hpp>
#include <boost/ref.hpp>
#include <boost/utility/result_of.hpp>
#include <boost/preprocessor.hpp>
#include <boost/parameter/name.hpp>
#include <boost/parameter/binding.hpp>
#include <boost/type_traits.hpp>
#include <boost/mpl/not.hpp>
#include <boost/graph/properties.hpp>
#include <boost/graph/detail/d_ary_heap.hpp>
#include <boost/property_map/property_map.hpp>
#include <boost/property_map/shared_array_property_map.hpp>
namespace boost {
struct parity_map_t { };
struct vertex_assignment_map_t { };
struct distance_compare_t { };
struct distance_combine_t { };
struct distance_inf_t { };
struct distance_zero_t { };
struct buffer_param_t { };
struct edge_copy_t { };
struct vertex_copy_t { };
struct vertex_isomorphism_t { };
struct vertex_invariant_t { };
struct vertex_invariant1_t { };
struct vertex_invariant2_t { };
struct edge_compare_t { };
struct vertex_max_invariant_t { };
struct orig_to_copy_t { };
struct root_vertex_t { };
struct polling_t { };
struct lookahead_t { };
struct in_parallel_t { };
struct attractive_force_t { };
struct repulsive_force_t { };
struct force_pairs_t { };
struct cooling_t { };
struct vertex_displacement_t { };
struct iterations_t { };
struct diameter_range_t { };
struct learning_constant_range_t { };
struct vertices_equivalent_t { };
struct edges_equivalent_t { };
struct index_in_heap_map_t { };
struct max_priority_queue_t { };
#define BOOST_BGL_DECLARE_NAMED_PARAMS \
BOOST_BGL_ONE_PARAM_CREF(weight_map, edge_weight) \
BOOST_BGL_ONE_PARAM_CREF(weight_map2, edge_weight2) \
BOOST_BGL_ONE_PARAM_CREF(distance_map, vertex_distance) \
BOOST_BGL_ONE_PARAM_CREF(distance_map2, vertex_distance2) \
BOOST_BGL_ONE_PARAM_CREF(predecessor_map, vertex_predecessor) \
BOOST_BGL_ONE_PARAM_CREF(rank_map, vertex_rank) \
BOOST_BGL_ONE_PARAM_CREF(root_map, vertex_root) \
BOOST_BGL_ONE_PARAM_CREF(root_vertex, root_vertex) \
BOOST_BGL_ONE_PARAM_CREF(edge_centrality_map, edge_centrality) \
BOOST_BGL_ONE_PARAM_CREF(centrality_map, vertex_centrality) \
BOOST_BGL_ONE_PARAM_CREF(parity_map, parity_map) \
BOOST_BGL_ONE_PARAM_CREF(color_map, vertex_color) \
BOOST_BGL_ONE_PARAM_CREF(edge_color_map, edge_color) \
BOOST_BGL_ONE_PARAM_CREF(capacity_map, edge_capacity) \
BOOST_BGL_ONE_PARAM_CREF(residual_capacity_map, edge_residual_capacity) \
BOOST_BGL_ONE_PARAM_CREF(reverse_edge_map, edge_reverse) \
BOOST_BGL_ONE_PARAM_CREF(discover_time_map, vertex_discover_time) \
BOOST_BGL_ONE_PARAM_CREF(lowpoint_map, vertex_lowpoint) \
BOOST_BGL_ONE_PARAM_CREF(vertex_index_map, vertex_index) \
BOOST_BGL_ONE_PARAM_CREF(vertex_index1_map, vertex_index1) \
BOOST_BGL_ONE_PARAM_CREF(vertex_index2_map, vertex_index2) \
BOOST_BGL_ONE_PARAM_CREF(vertex_assignment_map, vertex_assignment_map) \
BOOST_BGL_ONE_PARAM_CREF(visitor, graph_visitor) \
BOOST_BGL_ONE_PARAM_CREF(distance_compare, distance_compare) \
BOOST_BGL_ONE_PARAM_CREF(distance_combine, distance_combine) \
BOOST_BGL_ONE_PARAM_CREF(distance_inf, distance_inf) \
BOOST_BGL_ONE_PARAM_CREF(distance_zero, distance_zero) \
BOOST_BGL_ONE_PARAM_CREF(edge_copy, edge_copy) \
BOOST_BGL_ONE_PARAM_CREF(vertex_copy, vertex_copy) \
BOOST_BGL_ONE_PARAM_REF(buffer, buffer_param) \
BOOST_BGL_ONE_PARAM_CREF(orig_to_copy, orig_to_copy) \
BOOST_BGL_ONE_PARAM_CREF(isomorphism_map, vertex_isomorphism) \
BOOST_BGL_ONE_PARAM_CREF(vertex_invariant, vertex_invariant) \
BOOST_BGL_ONE_PARAM_CREF(vertex_invariant1, vertex_invariant1) \
BOOST_BGL_ONE_PARAM_CREF(vertex_invariant2, vertex_invariant2) \
BOOST_BGL_ONE_PARAM_CREF(vertex_max_invariant, vertex_max_invariant) \
BOOST_BGL_ONE_PARAM_CREF(polling, polling) \
BOOST_BGL_ONE_PARAM_CREF(lookahead, lookahead) \
BOOST_BGL_ONE_PARAM_CREF(in_parallel, in_parallel) \
BOOST_BGL_ONE_PARAM_CREF(displacement_map, vertex_displacement) \
BOOST_BGL_ONE_PARAM_CREF(attractive_force, attractive_force) \
BOOST_BGL_ONE_PARAM_CREF(repulsive_force, repulsive_force) \
BOOST_BGL_ONE_PARAM_CREF(force_pairs, force_pairs) \
BOOST_BGL_ONE_PARAM_CREF(cooling, cooling) \
BOOST_BGL_ONE_PARAM_CREF(iterations, iterations) \
BOOST_BGL_ONE_PARAM_CREF(diameter_range, diameter_range) \
BOOST_BGL_ONE_PARAM_CREF(learning_constant_range, learning_constant_range) \
BOOST_BGL_ONE_PARAM_CREF(vertices_equivalent, vertices_equivalent) \
BOOST_BGL_ONE_PARAM_CREF(edges_equivalent, edges_equivalent) \
BOOST_BGL_ONE_PARAM_CREF(index_in_heap_map, index_in_heap_map) \
BOOST_BGL_ONE_PARAM_REF(max_priority_queue, max_priority_queue)
template <typename T, typename Tag, typename Base = no_property>
struct bgl_named_params
{
typedef bgl_named_params self;
typedef Base next_type;
typedef Tag tag_type;
typedef T value_type;
bgl_named_params(T v = T()) : m_value(v) { }
bgl_named_params(T v, const Base& b) : m_value(v), m_base(b) { }
T m_value;
Base m_base;
#define BOOST_BGL_ONE_PARAM_REF(name, key) \
template <typename PType> \
bgl_named_params<boost::reference_wrapper<PType>, BOOST_PP_CAT(key, _t), self> \
name(PType& p) const { \
typedef bgl_named_params<boost::reference_wrapper<PType>, BOOST_PP_CAT(key, _t), self> Params; \
return Params(boost::ref(p), *this); \
} \
#define BOOST_BGL_ONE_PARAM_CREF(name, key) \
template <typename PType> \
bgl_named_params<PType, BOOST_PP_CAT(key, _t), self> \
name(const PType& p) const { \
typedef bgl_named_params<PType, BOOST_PP_CAT(key, _t), self> Params; \
return Params(p, *this); \
} \
BOOST_BGL_DECLARE_NAMED_PARAMS
#undef BOOST_BGL_ONE_PARAM_REF
#undef BOOST_BGL_ONE_PARAM_CREF
// Duplicate
template <typename PType>
bgl_named_params<PType, vertex_color_t, self>
vertex_color_map(const PType& p) const {return this->color_map(p);}
};
#define BOOST_BGL_ONE_PARAM_REF(name, key) \
template <typename PType> \
bgl_named_params<boost::reference_wrapper<PType>, BOOST_PP_CAT(key, _t)> \
name(PType& p) { \
typedef bgl_named_params<boost::reference_wrapper<PType>, BOOST_PP_CAT(key, _t)> Params; \
return Params(boost::ref(p)); \
} \
#define BOOST_BGL_ONE_PARAM_CREF(name, key) \
template <typename PType> \
bgl_named_params<PType, BOOST_PP_CAT(key, _t)> \
name(const PType& p) { \
typedef bgl_named_params<PType, BOOST_PP_CAT(key, _t)> Params; \
return Params(p); \
} \
BOOST_BGL_DECLARE_NAMED_PARAMS
#undef BOOST_BGL_ONE_PARAM_REF
#undef BOOST_BGL_ONE_PARAM_CREF
// Duplicate
template <typename PType>
bgl_named_params<PType, vertex_color_t>
vertex_color_map(const PType& p) {return color_map(p);}
namespace detail {
struct unused_tag_type {};
}
typedef bgl_named_params<char, detail::unused_tag_type> no_named_parameters;
//===========================================================================
// Functions for extracting parameters from bgl_named_params
template <typename Tag, typename Args>
struct lookup_named_param {};
template <typename T, typename Tag, typename Base>
struct lookup_named_param<Tag, bgl_named_params<T, Tag, Base> > {
typedef T type;
static const T& get(const bgl_named_params<T, Tag, Base>& p) {
return p.m_value;
}
};
template <typename Tag1, typename T, typename Tag, typename Base>
struct lookup_named_param<Tag1, bgl_named_params<T, Tag, Base> > {
typedef typename lookup_named_param<Tag1, Base>::type type;
static const type& get(const bgl_named_params<T, Tag, Base>& p) {
return lookup_named_param<Tag1, Base>::get(p.m_base);
}
};
template <typename Tag, typename Args, typename Def>
struct lookup_named_param_def {
typedef Def type;
static const Def& get(const Args&, const Def& def) {return def;}
};
template <typename T, typename Tag, typename Base, typename Def>
struct lookup_named_param_def<Tag, bgl_named_params<T, Tag, Base>, Def> {
typedef T type;
static const type& get(const bgl_named_params<T, Tag, Base>& p, const Def&) {
return p.m_value;
}
};
template <typename Tag1, typename T, typename Tag, typename Base, typename Def>
struct lookup_named_param_def<Tag1, bgl_named_params<T, Tag, Base>, Def> {
typedef typename lookup_named_param_def<Tag1, Base, Def>::type type;
static const type& get(const bgl_named_params<T, Tag, Base>& p, const Def& def) {
return lookup_named_param_def<Tag1, Base, Def>::get(p.m_base, def);
}
};
struct param_not_found {};
template <typename Tag, typename Args>
struct get_param_type:
lookup_named_param_def<Tag, Args, param_not_found> {};
template <class Tag, typename Args>
inline
const typename lookup_named_param_def<Tag, Args, param_not_found>::type&
get_param(const Args& p, Tag) {
return lookup_named_param_def<Tag, Args, param_not_found>::get(p, param_not_found());
}
template <class P, class Default>
const P& choose_param(const P& param, const Default&) {
return param;
}
template <class Default>
Default choose_param(const param_not_found&, const Default& d) {
return d;
}
template <typename T>
inline bool is_default_param(const T&) { return false; }
inline bool is_default_param(const param_not_found&)
{ return true; }
namespace detail {
template <typename T>
struct const_type_as_type {typedef typename T::const_type type;};
} // namespace detail
// Use this function instead of choose_param() when you want
// to avoid requiring get(tag, g) when it is not used.
namespace detail {
template <typename GraphIsConst, typename Graph, typename Param, typename Tag>
struct choose_impl_result:
boost::mpl::eval_if<
boost::is_same<Param, param_not_found>,
boost::mpl::eval_if<
GraphIsConst,
detail::const_type_as_type<property_map<Graph, Tag> >,
property_map<Graph, Tag> >,
boost::mpl::identity<Param> > {};
// Parameters of f are (GraphIsConst, Graph, Param, Tag)
template <bool Found> struct choose_impl_helper;
template <> struct choose_impl_helper<false> {
template <typename Param, typename Graph, typename PropertyTag>
static typename property_map<typename boost::remove_const<Graph>::type, PropertyTag>::const_type
f(boost::mpl::true_, const Graph& g, const Param&, PropertyTag tag) {
return get(tag, g);
}
template <typename Param, typename Graph, typename PropertyTag>
static typename property_map<typename boost::remove_const<Graph>::type, PropertyTag>::type
f(boost::mpl::false_, Graph& g, const Param&, PropertyTag tag) {
return get(tag, g);
}
};
template <> struct choose_impl_helper<true> {
template <typename GraphIsConst, typename Param, typename Graph, typename PropertyTag>
static Param f(GraphIsConst, const Graph&, const Param& p, PropertyTag) {
return p;
}
};
}
template <typename Param, typename Graph, typename PropertyTag>
typename detail::choose_impl_result<boost::mpl::true_, Graph, Param, PropertyTag>::type
choose_const_pmap(const Param& p, const Graph& g, PropertyTag tag)
{
return detail::choose_impl_helper<!boost::is_same<Param, param_not_found>::value>
::f(boost::mpl::true_(), g, p, tag);
}
template <typename Param, typename Graph, typename PropertyTag>
typename detail::choose_impl_result<boost::mpl::false_, Graph, Param, PropertyTag>::type
choose_pmap(const Param& p, Graph& g, PropertyTag tag)
{
return detail::choose_impl_helper<!boost::is_same<Param, param_not_found>::value>
::f(boost::mpl::false_(), g, p, tag);
}
namespace detail {
// used in the max-flow algorithms
template <class Graph, class P, class T, class R>
struct edge_capacity_value
{
typedef bgl_named_params<P, T, R> Params;
typedef typename detail::choose_impl_result<boost::mpl::true_, Graph, typename get_param_type<edge_capacity_t, Params>::type, edge_capacity_t>::type CapacityEdgeMap;
typedef typename property_traits<CapacityEdgeMap>::value_type type;
};
// used in the max-flow algorithms
template <class Graph, class P, class T, class R>
struct edge_weight_value
{
typedef bgl_named_params<P, T, R> Params;
typedef typename detail::choose_impl_result<boost::mpl::true_, Graph, typename get_param_type<edge_weight_t, Params>::type, edge_weight_t>::type WeightMap;
typedef typename property_traits<WeightMap>::value_type type;
};
}
// Declare all new tags
namespace graph {
namespace keywords {
#define BOOST_BGL_ONE_PARAM_REF(name, key) BOOST_PARAMETER_NAME(name)
#define BOOST_BGL_ONE_PARAM_CREF(name, key) BOOST_PARAMETER_NAME(name)
BOOST_BGL_DECLARE_NAMED_PARAMS
#undef BOOST_BGL_ONE_PARAM_REF
#undef BOOST_BGL_ONE_PARAM_CREF
}
}
namespace detail {
template <typename Tag> struct convert_one_keyword {};
#define BOOST_BGL_ONE_PARAM_REF(name, key) \
template <> \
struct convert_one_keyword<BOOST_PP_CAT(key, _t)> { \
typedef boost::graph::keywords::tag::name type; \
};
#define BOOST_BGL_ONE_PARAM_CREF(name, key) BOOST_BGL_ONE_PARAM_REF(name, key)
BOOST_BGL_DECLARE_NAMED_PARAMS
#undef BOOST_BGL_ONE_PARAM_REF
#undef BOOST_BGL_ONE_PARAM_CREF
template <typename T>
struct convert_bgl_params_to_boost_parameter {
typedef typename convert_one_keyword<typename T::tag_type>::type new_kw;
typedef boost::parameter::aux::tagged_argument<new_kw, const typename T::value_type> tagged_arg_type;
typedef convert_bgl_params_to_boost_parameter<typename T::next_type> rest_conv;
typedef boost::parameter::aux::arg_list<tagged_arg_type, typename rest_conv::type> type;
static type conv(const T& x) {
return type(tagged_arg_type(x.m_value), rest_conv::conv(x.m_base));
}
};
template <typename P, typename R>
struct convert_bgl_params_to_boost_parameter<bgl_named_params<P, int, R> > {
typedef convert_bgl_params_to_boost_parameter<R> rest_conv;
typedef typename rest_conv::type type;
static type conv(const bgl_named_params<P, int, R>& x) {
return rest_conv::conv(x.m_base);
}
};
template <>
struct convert_bgl_params_to_boost_parameter<boost::no_property> {
typedef boost::parameter::aux::empty_arg_list type;
static type conv(const boost::no_property&) {return type();}
};
template <>
struct convert_bgl_params_to_boost_parameter<boost::no_named_parameters> {
typedef boost::parameter::aux::empty_arg_list type;
static type conv(const boost::no_named_parameters&) {return type();}
};
struct bgl_parameter_not_found_type {};
template <typename ArgPack, typename KeywordType>
struct parameter_exists : boost::mpl::not_<boost::is_same<typename boost::parameter::binding<ArgPack, KeywordType, bgl_parameter_not_found_type>::type, bgl_parameter_not_found_type> > {};
}
#define BOOST_GRAPH_DECLARE_CONVERTED_PARAMETERS(old_type, old_var) \
typedef typename boost::detail::convert_bgl_params_to_boost_parameter<old_type>::type arg_pack_type; \
arg_pack_type arg_pack = boost::detail::convert_bgl_params_to_boost_parameter<old_type>::conv(old_var);
namespace detail {
template <typename ArgType, typename Prop, typename Graph, bool Exists>
struct override_const_property_t {
typedef typename boost::remove_const<ArgType>::type result_type;
result_type operator()(const Graph&, const ArgType& a) const {return a;}
};
template <typename ArgType, typename Prop, typename Graph>
struct override_const_property_t<ArgType, Prop, Graph, false> {
typedef typename boost::property_map<Graph, Prop>::const_type result_type;
result_type operator()(const Graph& g, const ArgType&) const {return get(Prop(), g);}
};
template <typename ArgPack, typename Tag, typename Prop, typename Graph>
struct override_const_property_result {
typedef
typename override_const_property_t<
typename boost::parameter::value_type<ArgPack, Tag, int>::type,
Prop,
Graph,
boost::detail::parameter_exists<ArgPack, Tag>::value
>::result_type
type;
};
template <typename ArgPack, typename Tag, typename Prop, typename Graph>
typename override_const_property_result<ArgPack, Tag, Prop, Graph>::type
override_const_property(const ArgPack& ap, const boost::parameter::keyword<Tag>& t, const Graph& g, Prop) {
return override_const_property_t<
typename boost::parameter::value_type<ArgPack, Tag, int>::type,
Prop,
Graph,
boost::detail::parameter_exists<ArgPack, Tag>::value
>()(g, ap[t | 0]);
}
template <typename ArgType, typename Prop, typename Graph, bool Exists>
struct override_property_t {
typedef ArgType result_type;
result_type operator()(const Graph&, const typename boost::add_reference<ArgType>::type a) const {return a;}
};
template <typename ArgType, typename Prop, typename Graph>
struct override_property_t<ArgType, Prop, Graph, false> {
typedef typename boost::property_map<Graph, Prop>::type result_type;
result_type operator()(const Graph& g, const ArgType&) const {return get(Prop(), g);}
};
template <typename ArgPack, typename Tag, typename Prop, typename Graph>
struct override_property_result {
typedef
typename override_property_t<
typename boost::parameter::value_type<ArgPack, Tag, int>::type,
Prop,
Graph,
boost::detail::parameter_exists<ArgPack, Tag>::value
>::result_type
type;
};
template <typename ArgPack, typename Tag, typename Prop, typename Graph>
typename override_property_result<ArgPack, Tag, Prop, Graph>::type
override_property(const ArgPack& ap, const boost::parameter::keyword<Tag>& t, const Graph& g, Prop) {
return override_property_t<
typename boost::parameter::value_type<ArgPack, Tag, int>::type,
Prop,
Graph,
boost::detail::parameter_exists<ArgPack, Tag>::value
>()(g, ap[t | 0]);
}
template <typename F> struct make_arg_pack_type;
template <> struct make_arg_pack_type<void()> {typedef boost::parameter::aux::empty_arg_list type;};
template <typename K, typename A>
struct make_arg_pack_type<void(K, A)> {
typedef boost::parameter::aux::tagged_argument<K, A> type;
};
#define BOOST_GRAPH_OPENING_PART_OF_PAIR(z, i, n) boost::parameter::aux::arg_list<boost::parameter::aux::tagged_argument<BOOST_PP_CAT(Keyword, BOOST_PP_SUB(n, i)), BOOST_PP_CAT(Arg, BOOST_PP_SUB(n, i))>,
#define BOOST_GRAPH_MAKE_PAIR_PARAM(z, i, _) const boost::parameter::aux::tagged_argument<BOOST_PP_CAT(Keyword, i), BOOST_PP_CAT(Arg, i)>& BOOST_PP_CAT(kw, i)
#define BOOST_GRAPH_MAKE_AP_TYPE_SPECIALIZATION(z, i, _) \
template <BOOST_PP_ENUM_PARAMS(i, typename Keyword), BOOST_PP_ENUM_PARAMS(i, typename Arg)> \
struct make_arg_pack_type<void(BOOST_PP_ENUM_PARAMS(i, Keyword), BOOST_PP_ENUM_PARAMS(i, Arg))> { \
typedef \
BOOST_PP_REPEAT(i, BOOST_GRAPH_OPENING_PART_OF_PAIR, BOOST_PP_DEC(i)) boost::parameter::aux::empty_arg_list BOOST_PP_REPEAT(i, > BOOST_PP_TUPLE_EAT(3), ~) \
type; \
};
BOOST_PP_REPEAT_FROM_TO(2, 11, BOOST_GRAPH_MAKE_AP_TYPE_SPECIALIZATION, ~)
#undef BOOST_GRAPH_MAKE_AP_TYPE_SPECIALIZATION
#define BOOST_GRAPH_MAKE_FORWARDING_FUNCTION(name, nfixed, nnamed_max) \
/* Entry point for conversion from BGL-style named parameters */ \
template <BOOST_PP_ENUM_PARAMS(nfixed, typename Param) BOOST_PP_COMMA_IF(nfixed) typename ArgPack> \
typename boost::result_of< \
detail::BOOST_PP_CAT(name, _impl)<BOOST_PP_ENUM_PARAMS(nfixed, Param)>(BOOST_PP_ENUM_PARAMS(nfixed, Param) BOOST_PP_COMMA_IF(nfixed) const ArgPack&) \
>::type \
BOOST_PP_CAT(name, _with_named_params)(BOOST_PP_ENUM_BINARY_PARAMS(nfixed, const Param, & param) BOOST_PP_COMMA_IF(nfixed) const ArgPack& arg_pack) { \
return detail::BOOST_PP_CAT(name, _impl)<BOOST_PP_ENUM_PARAMS(nfixed, Param)>()(BOOST_PP_ENUM_PARAMS(nfixed, param) BOOST_PP_COMMA_IF(nfixed) arg_pack); \
} \
/* Individual functions taking Boost.Parameter-style keyword arguments */ \
BOOST_PP_REPEAT(BOOST_PP_INC(nnamed_max), BOOST_GRAPH_MAKE_FORWARDING_FUNCTION_ONE, (name)(nfixed))
#define BOOST_GRAPH_MAKE_FORWARDING_FUNCTION_ONE(z, nnamed, seq) \
BOOST_GRAPH_MAKE_FORWARDING_FUNCTION_ONEX(z, nnamed, BOOST_PP_SEQ_ELEM(0, seq), BOOST_PP_SEQ_ELEM(1, seq))
#define BOOST_GRAPH_MAKE_FORWARDING_FUNCTION_ONEX(z, nnamed, name, nfixed) \
template <BOOST_PP_ENUM_PARAMS(nfixed, typename Param) BOOST_PP_ENUM_TRAILING_PARAMS(nnamed, typename Keyword) BOOST_PP_ENUM_TRAILING_PARAMS(nnamed, typename Arg)> \
typename boost::result_of< \
detail::BOOST_PP_CAT(name, _impl)<BOOST_PP_ENUM_PARAMS(nfixed, Param)> \
(BOOST_PP_ENUM_PARAMS(nfixed, Param) BOOST_PP_COMMA_IF(nfixed) \
const typename boost::detail::make_arg_pack_type<void(BOOST_PP_ENUM_PARAMS(nnamed, Keyword) BOOST_PP_COMMA_IF(nnamed) BOOST_PP_ENUM_PARAMS(nnamed, Arg))>::type&) \
>::type \
name(BOOST_PP_ENUM_BINARY_PARAMS(nfixed, const Param, & param) \
BOOST_PP_ENUM_TRAILING(nnamed, BOOST_GRAPH_MAKE_PAIR_PARAM, ~)) { \
return detail::BOOST_PP_CAT(name, _impl)<BOOST_PP_ENUM_PARAMS(nfixed, Param)>() \
(BOOST_PP_ENUM_PARAMS(nfixed, param), \
(boost::parameter::aux::empty_arg_list() BOOST_PP_ENUM_TRAILING_PARAMS(nnamed, kw))); \
}
#define BOOST_GRAPH_MAKE_OLD_STYLE_PARAMETER_FUNCTION(name, nfixed) \
template <BOOST_PP_ENUM_PARAMS(nfixed, typename Param) BOOST_PP_COMMA_IF(nfixed) class P, class T, class R> \
typename boost::result_of< \
::boost::graph::detail::BOOST_PP_CAT(name, _impl) BOOST_PP_EXPR_IF(nfixed, <) BOOST_PP_ENUM_PARAMS(nfixed, Param) BOOST_PP_EXPR_IF(nfixed, >) \
(BOOST_PP_ENUM_PARAMS(nfixed, Param) BOOST_PP_COMMA_IF(nfixed) \
const typename boost::detail::convert_bgl_params_to_boost_parameter<boost::bgl_named_params<P, T, R> >::type &) \
>::type \
name(BOOST_PP_ENUM_BINARY_PARAMS(nfixed, const Param, & param) BOOST_PP_COMMA_IF(nfixed) const boost::bgl_named_params<P, T, R>& old_style_params) { \
typedef boost::bgl_named_params<P, T, R> old_style_params_type; \
BOOST_GRAPH_DECLARE_CONVERTED_PARAMETERS(old_style_params_type, old_style_params) \
return ::boost::graph::BOOST_PP_CAT(name, _with_named_params)(BOOST_PP_ENUM_PARAMS(nfixed, param) BOOST_PP_COMMA_IF(nfixed) arg_pack); \
} \
\
BOOST_PP_EXPR_IF(nfixed, template <) BOOST_PP_ENUM_PARAMS(nfixed, typename Param) BOOST_PP_EXPR_IF(nfixed, >) \
BOOST_PP_EXPR_IF(nfixed, typename) boost::result_of< \
::boost::graph::detail::BOOST_PP_CAT(name, _impl) BOOST_PP_EXPR_IF(nfixed, <) BOOST_PP_ENUM_PARAMS(nfixed, Param) BOOST_PP_EXPR_IF(nfixed, >) \
(BOOST_PP_ENUM_PARAMS(nfixed, Param) BOOST_PP_COMMA_IF(nfixed) const boost::parameter::aux::empty_arg_list &) \
>::type \
name(BOOST_PP_ENUM_BINARY_PARAMS(nfixed, const Param, & param)) { \
BOOST_GRAPH_DECLARE_CONVERTED_PARAMETERS(boost::no_named_parameters, boost::no_named_parameters()) \
return ::boost::graph::BOOST_PP_CAT(name, _with_named_params)(BOOST_PP_ENUM_PARAMS(nfixed, param) BOOST_PP_COMMA_IF(nfixed) arg_pack); \
}
}
namespace detail {
template <bool Exists, typename Graph, typename ArgPack, typename Value, typename PM>
struct map_maker_helper {
typedef PM map_type;
static PM make_map(const Graph&, Value, const PM& pm, const ArgPack&) {
return pm;
}
};
template <typename Graph, typename ArgPack, typename Value, typename PM>
struct map_maker_helper<false, Graph, ArgPack, Value, PM> {
typedef typename boost::remove_const<
typename override_const_property_t<
typename boost::parameter::value_type<
ArgPack, boost::graph::keywords::tag::vertex_index_map, int>::type,
boost::vertex_index_t,
Graph,
boost::detail::parameter_exists<
ArgPack, boost::graph::keywords::tag::vertex_index_map>::value
>::result_type>::type vi_map_type;
typedef
boost::shared_array_property_map<Value, vi_map_type>
map_type;
static map_type make_map(const Graph& g,
Value v,
const PM&,
const ArgPack& ap) {
return make_shared_array_property_map(
num_vertices(g),
v,
override_const_property(
ap,
boost::graph::keywords::_vertex_index_map,
g, vertex_index));
}
};
template <typename Graph, typename ArgPack, typename MapTag, typename ValueType>
struct map_maker {
BOOST_STATIC_CONSTANT(
bool,
has_map =
(parameter_exists<ArgPack, MapTag>
::value));
typedef map_maker_helper<has_map, Graph, ArgPack, ValueType,
typename boost::remove_const<
typename boost::parameter::value_type<
ArgPack,
MapTag,
int
>::type
>::type> helper;
typedef typename helper::map_type map_type;
static map_type make_map(const Graph& g, const ArgPack& ap, ValueType default_value) {
return helper::make_map(g, default_value, ap[::boost::parameter::keyword<MapTag>::instance | 0], ap);
}
};
template <typename MapTag, typename ValueType = void>
class make_property_map_from_arg_pack_gen {
ValueType default_value;
public:
make_property_map_from_arg_pack_gen(ValueType default_value)
: default_value(default_value) {}
template <typename Graph, typename ArgPack>
typename map_maker<Graph, ArgPack, MapTag, ValueType>::map_type
operator()(const Graph& g, const ArgPack& ap) const {
return map_maker<Graph, ArgPack, MapTag, ValueType>::make_map(g, ap, default_value);
}
};
template <typename MapTag>
class make_property_map_from_arg_pack_gen<MapTag, void> {
public:
template <typename ValueType, typename Graph, typename ArgPack>
typename map_maker<Graph, ArgPack, MapTag, ValueType>::map_type
operator()(const Graph& g, const ArgPack& ap, ValueType default_value) const {
return map_maker<Graph, ArgPack, MapTag, ValueType>::make_map(g, ap, default_value);
}
};
static const
make_property_map_from_arg_pack_gen<
boost::graph::keywords::tag::color_map,
default_color_type>
make_color_map_from_arg_pack(white_color);
template <bool Exists, class Graph, class ArgPack, class KeyT, class ValueT, class KeyMapTag, class IndexInHeapMapTag, class Compare, class Q>
struct priority_queue_maker_helper {
typedef Q priority_queue_type;
static priority_queue_type
make_queue(const Graph&, const ArgPack&, KeyT, const Q& q) {
return q;
}
};
template <class Graph, class ArgPack, class KeyT, class ValueT, class KeyMapTag, class IndexInHeapMapTag, class Compare, class Q>
struct priority_queue_maker_helper<false, Graph, ArgPack, KeyT, ValueT, KeyMapTag, IndexInHeapMapTag, Compare, Q> {
typedef typename std::vector<ValueT>::size_type default_index_in_heap_type;
typedef typename map_maker<Graph, ArgPack, IndexInHeapMapTag, default_index_in_heap_type>::helper::map_type index_in_heap_map;
typedef boost::d_ary_heap_indirect<ValueT, 4, index_in_heap_map, typename map_maker<Graph, ArgPack, KeyMapTag, KeyT>::helper::map_type, Compare> priority_queue_type;
static priority_queue_type
make_queue(const Graph& g, const ArgPack& ap, KeyT defaultKey, const Q&) {
return priority_queue_type(
map_maker<Graph, ArgPack, KeyMapTag, KeyT>::make_map(g, ap, defaultKey),
map_maker<Graph, ArgPack, IndexInHeapMapTag, default_index_in_heap_type>::make_map(g, ap, typename boost::property_traits<index_in_heap_map>::value_type(-1))
);
}
};
template <class Graph, class ArgPack, class KeyT, class ValueT, class PriorityQueueTag, class KeyMapTag, class IndexInHeapMapTag, class Compare>
struct priority_queue_maker {
BOOST_STATIC_CONSTANT(
bool,
g_hasQ =
(parameter_exists<ArgPack, PriorityQueueTag>
::value));
typedef boost::reference_wrapper<int> int_refw;
typedef typename boost::parameter::value_type<
ArgPack,
PriorityQueueTag,
int_refw
>::type
param_value_type_wrapper;
typedef typename param_value_type_wrapper::type
param_value_type;
typedef typename boost::remove_const<param_value_type>::type param_value_type_no_const;
typedef priority_queue_maker_helper<g_hasQ, Graph, ArgPack, KeyT, ValueT, KeyMapTag, IndexInHeapMapTag, Compare,
param_value_type_no_const> helper;
typedef typename helper::priority_queue_type priority_queue_type;
static priority_queue_type make_queue(const Graph& g, const ArgPack& ap, KeyT defaultKey) {
return helper::make_queue(g, ap, defaultKey, ap[::boost::parameter::keyword<PriorityQueueTag>::instance | 0]);
}
};
template <class PriorityQueueTag, class KeyT, class ValueT, class Compare = std::less<KeyT>, class KeyMapTag = boost::graph::keywords::tag::distance_map, class IndexInHeapMapTag = boost::graph::keywords::tag::index_in_heap_map>
struct make_priority_queue_from_arg_pack_gen {
KeyT defaultKey;
make_priority_queue_from_arg_pack_gen(KeyT defaultKey_) : defaultKey(defaultKey_) { }
template <class F>
struct result {
typedef typename remove_const<typename remove_reference<typename function_traits<F>::arg1_type>::type>::type graph_type;
typedef typename remove_const<typename remove_reference<typename function_traits<F>::arg2_type>::type>::type arg_pack_type;
typedef typename priority_queue_maker<graph_type, arg_pack_type, KeyT, ValueT, PriorityQueueTag, KeyMapTag, IndexInHeapMapTag, Compare>::priority_queue_type type;
};
template <class Graph, class ArgPack>
typename priority_queue_maker<Graph, ArgPack, KeyT, ValueT, PriorityQueueTag, KeyMapTag, IndexInHeapMapTag, Compare>::priority_queue_type
operator()(const Graph& g, const ArgPack& ap) const {
return priority_queue_maker<Graph, ArgPack, KeyT, ValueT, PriorityQueueTag, KeyMapTag, IndexInHeapMapTag, Compare>::make_queue(g, ap, defaultKey);
}
};
template <typename G>
typename boost::graph_traits<G>::vertex_descriptor
get_null_vertex(const G&) {return boost::graph_traits<G>::null_vertex();}
template <typename G>
typename boost::graph_traits<G>::vertex_descriptor
get_default_starting_vertex(const G& g) {
std::pair<typename boost::graph_traits<G>::vertex_iterator, typename boost::graph_traits<G>::vertex_iterator> iters = vertices(g);
return (iters.first == iters.second) ? boost::graph_traits<G>::null_vertex() : *iters.first;
}
template <typename G>
struct get_default_starting_vertex_t {
typedef typename boost::graph_traits<G>::vertex_descriptor result_type;
const G& g;
get_default_starting_vertex_t(const G& g): g(g) {}
result_type operator()() const {return get_default_starting_vertex(g);}
};
// Wrapper to avoid instantiating numeric_limits when users provide distance_inf value manually
template <typename T>
struct get_max {
T operator()() const {
return (std::numeric_limits<T>::max)();
}
typedef T result_type;
};
} // namespace detail
} // namespace boost
#undef BOOST_BGL_DECLARE_NAMED_PARAMS
#endif // BOOST_GRAPH_NAMED_FUNCTION_PARAMS_HPP