/*=============================================================================
Copyright (c) 2001-2011 Joel de Guzman
Copyright (c) 2001-2011 Hartmut Kaiser
Copyright (c) 2010-2011 Bryce Lelbach
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(BOOST_SPIRIT_OUTPUT_UTREE_TRAITS_APR_16_2010_0655AM)
#define BOOST_SPIRIT_OUTPUT_UTREE_TRAITS_APR_16_2010_0655AM
#include <boost/spirit/home/support/attributes.hpp>
#include <boost/spirit/home/support/container.hpp>
#include <boost/spirit/home/support/utree.hpp>
#include <boost/spirit/home/qi/domain.hpp>
#include <boost/spirit/home/karma/domain.hpp>
#include <boost/spirit/home/qi/nonterminal/nonterminal_fwd.hpp>
#include <boost/spirit/home/karma/nonterminal/nonterminal_fwd.hpp>
#include <string>
#include <boost/cstdint.hpp>
#include <boost/variant.hpp>
#include <boost/mpl/bool.hpp>
#include <boost/mpl/identity.hpp>
#include <boost/mpl/or.hpp>
#include <boost/range/iterator_range_core.hpp>
#include <boost/type_traits/is_same.hpp>
#include <boost/utility/enable_if.hpp>
///////////////////////////////////////////////////////////////////////////////
namespace boost
{
template <typename T>
inline T get(boost::spirit::utree const& x)
{
return x.get<T>();
}
}
///////////////////////////////////////////////////////////////////////////////
namespace boost { namespace spirit { namespace traits
{
namespace detail
{
inline bool is_list(utree const& ut)
{
switch (traits::which(ut))
{
case utree_type::reference_type:
return is_list(ut.deref());
case utree_type::list_type:
case utree_type::range_type:
return true;
default:
break;
}
return false;
}
inline bool is_uninitialized(utree const& ut)
{
return traits::which(ut) == utree_type::invalid_type;
}
}
// this specialization tells Spirit how to extract the type of the value
// stored in the given utree node
template <>
struct variant_which<utree>
{
static int call(utree const& u) { return u.which(); }
};
template <>
struct variant_which<utree::list_type>
{
static int call(utree::list_type const& u) { return u.which(); }
};
///////////////////////////////////////////////////////////////////////////
// Make sure all components of an alternative expose utree, even if they
// actually expose a utree::list_type
template <typename Domain>
struct alternative_attribute_transform<utree::list_type, Domain>
: mpl::identity<utree>
{};
///////////////////////////////////////////////////////////////////////////
// Make sure all components of a sequence expose utree, even if they
// actually expose a utree::list_type
template <typename Domain>
struct sequence_attribute_transform<utree::list_type, Domain>
: mpl::identity<utree>
{};
///////////////////////////////////////////////////////////////////////////
// this specialization lets Spirit know that typed basic_strings
// are strings
template <typename Base, utree_type::info I>
struct is_string<spirit::basic_string<Base, I> >
: mpl::true_
{};
///////////////////////////////////////////////////////////////////////////
// these specializations extract the character type of a utree typed string
template <typename T, utree_type::info I>
struct char_type_of<spirit::basic_string<iterator_range<T>, I> >
: char_type_of<T>
{};
template <utree_type::info I>
struct char_type_of<spirit::basic_string<std::string, I> >
: mpl::identity<char>
{};
///////////////////////////////////////////////////////////////////////////
// these specializations extract a c string from a utree typed string
template <typename String>
struct extract_c_string;
template <typename T, utree_type::info I>
struct extract_c_string<
spirit::basic_string<iterator_range<T const*>, I>
> {
typedef T char_type;
typedef spirit::basic_string<iterator_range<T const*>, I> string;
static T const* call (string& s)
{
return s.begin();
}
static T const* call (string const& s)
{
return s.begin();
}
};
template <utree_type::info I>
struct extract_c_string<spirit::basic_string<std::string, I> >
{
typedef char char_type;
typedef spirit::basic_string<std::string, I> string;
static char const* call (string& s)
{
return s.c_str();
}
static char const* call (string const& s)
{
return s.c_str();
}
};
///////////////////////////////////////////////////////////////////////////
// these specializations are needed because utree::value_type == utree
template <>
struct is_substitute<utree, utree>
: mpl::true_
{};
template <>
struct is_weak_substitute<utree, utree>
: mpl::true_
{};
template <>
struct is_substitute<utree::list_type, utree::list_type>
: mpl::true_
{};
template <>
struct is_weak_substitute<utree::list_type, utree::list_type>
: mpl::true_
{};
///////////////////////////////////////////////////////////////////////////
// this specialization tells Spirit.Qi to allow assignment to an utree from
// a variant
namespace detail
{
struct assign_to_utree_visitor : static_visitor<>
{
assign_to_utree_visitor(utree& ut) : ut_(ut) {}
template <typename T>
void operator()(T& val) const
{
ut_ = val;
}
utree& ut_;
};
}
template <BOOST_VARIANT_ENUM_PARAMS(typename T)>
struct assign_to_container_from_value<
utree, variant<BOOST_VARIANT_ENUM_PARAMS(T)> >
{
static void
call(variant<BOOST_VARIANT_ENUM_PARAMS(T)> const& val, utree& attr)
{
apply_visitor(detail::assign_to_utree_visitor(attr), val);
}
};
///////////////////////////////////////////////////////////////////////////
// this specialization tells Spirit.Qi to allow assignment to an utree from
// a STL container
template <typename Attribute>
struct assign_to_container_from_value<utree, Attribute>
{
// any non-container type will be either directly assigned or appended
static void call(Attribute const& val, utree& attr, mpl::false_)
{
if (attr.empty())
attr = val;
else
push_back(attr, val);
}
// any container type will be converted into a list_type utree
static void call(Attribute const& val, utree& attr, mpl::true_)
{
typedef typename traits::container_iterator<Attribute const>::type
iterator_type;
// make sure the attribute is a list, at least an empty one
if (attr.empty())
attr = empty_list;
iterator_type end = traits::end(val);
for (iterator_type i = traits::begin(val); i != end; traits::next(i))
push_back(attr, traits::deref(i));
}
static void call(Attribute const& val, utree& attr)
{
call(val, attr, is_container<Attribute>());
}
};
///////////////////////////////////////////////////////////////////////////
// this specialization is required to disambiguate the specializations
// related to utree
template <>
struct assign_to_container_from_value<utree, utree>
{
static void call(utree const& val, utree& attr)
{
if (attr.empty()) {
attr = val;
}
else if (detail::is_list(val)) {
typedef utree::const_iterator iterator_type;
iterator_type end = traits::end(val);
for (iterator_type i = traits::begin(val); i != end; traits::next(i))
push_back(attr, traits::deref(i));
}
else {
push_back(attr, val);
}
}
};
template <>
struct assign_to_container_from_value<utree, utree::list_type>
: assign_to_container_from_value<utree, utree>
{};
// If the destination is a utree_list, we need to force the right hand side
// value into a new sub-node, always, no questions asked.
template <>
struct assign_to_container_from_value<utree::list_type, utree>
{
static void call(utree const& val, utree& attr)
{
push_back(attr, val);
}
};
// If both, the right hand side and the left hand side are utree_lists
// we have a lhs rule which has a single rule exposing a utree_list as its
// rhs (optionally wrapped into a directive or other unary parser). In this
// case we do not create a new sub-node.
template <>
struct assign_to_container_from_value<utree::list_type, utree::list_type>
: assign_to_container_from_value<utree, utree>
{};
///////////////////////////////////////////////////////////////////////////
// this specialization makes sure strings get assigned as a whole and are
// not converted into a utree list
template <>
struct assign_to_container_from_value<utree, utf8_string_type>
{
static void call(utf8_string_type const& val, utree& attr)
{
if (attr.empty())
attr = val;
else
push_back(attr, val);
}
};
// this specialization keeps symbols from being transformed into strings
template<>
struct assign_to_container_from_value<utree, utf8_symbol_type>
{
static void call (utf8_symbol_type const& val, utree& attr)
{
if (attr.empty())
attr = val;
else
push_back(attr, val);
}
};
template <>
struct assign_to_container_from_value<utree, binary_string_type>
{
static void call(binary_string_type const& val, utree& attr)
{
if (attr.empty())
attr = val;
else
push_back(attr, val);
}
};
template<>
struct assign_to_container_from_value<utree, utf8_symbol_range_type>
{
static void call (utf8_symbol_range_type const& val, utree& attr)
{
if (attr.empty())
attr = val;
else
push_back(attr, val);
}
};
template <>
struct assign_to_container_from_value<utree, binary_range_type>
{
static void call(binary_range_type const& val, utree& attr)
{
if (attr.empty())
attr = val;
else
push_back(attr, val);
}
};
template <>
struct assign_to_container_from_value<utree, std::string>
{
static void call(std::string const& val, utree& attr)
{
if (attr.empty())
attr = val;
else
push_back(attr, val);
}
};
///////////////////////////////////////////////////////////////////////////
// this specialization tells Spirit.Qi to allow assignment to an utree from
// generic iterators
template <typename Iterator>
struct assign_to_attribute_from_iterators<utree, Iterator>
{
static void
call(Iterator const& first, Iterator const& last, utree& attr)
{
if (attr.empty())
attr.assign(first, last);
else {
for (Iterator i = first; i != last; ++i)
push_back(attr, traits::deref(i));
}
}
};
///////////////////////////////////////////////////////////////////////////
// Karma only: convert utree node to string
namespace detail
{
struct attribute_as_string_type
{
typedef utf8_string_range_type type;
static type call(utree const& attr)
{
return boost::get<utf8_string_range_type>(attr);
}
static bool is_valid(utree const& attr)
{
switch (traits::which(attr))
{
case utree_type::reference_type:
return is_valid(attr.deref());
case utree_type::string_range_type:
case utree_type::string_type:
return true;
default:
return false;
}
}
};
}
template <>
struct attribute_as<std::string, utree>
: detail::attribute_as_string_type
{};
template <>
struct attribute_as<utf8_string_type, utree>
: detail::attribute_as_string_type
{};
template <>
struct attribute_as<utf8_string_range_type, utree>
: detail::attribute_as_string_type
{};
///////////////////////////////////////////////////////////////////////////
namespace detail
{
struct attribute_as_symbol_type
{
typedef utf8_symbol_range_type type;
static type call(utree const& attr)
{
return boost::get<utf8_symbol_range_type>(attr);
}
static bool is_valid(utree const& attr)
{
switch (traits::which(attr))
{
case utree_type::reference_type:
return is_valid(attr.deref());
case utree_type::symbol_type:
return true;
default:
return false;
}
}
};
}
template <>
struct attribute_as<utf8_symbol_type, utree>
: detail::attribute_as_symbol_type
{};
template <>
struct attribute_as<utf8_symbol_range_type, utree>
: detail::attribute_as_symbol_type
{};
template <typename Attribute>
struct attribute_as<Attribute, utree::list_type>
: attribute_as<Attribute, utree>
{};
///////////////////////////////////////////////////////////////////////////
namespace detail
{
struct attribute_as_binary_string_type
{
typedef binary_range_type type;
static type call(utree const& attr)
{
return boost::get<binary_range_type>(attr);
}
static bool is_valid(utree const& attr)
{
switch (traits::which(attr))
{
case utree_type::reference_type:
return is_valid(attr.deref());
case utree_type::binary_type:
return true;
default:
return false;
}
}
};
}
template <>
struct attribute_as<binary_string_type, utree>
: detail::attribute_as_binary_string_type
{};
template <>
struct attribute_as<binary_range_type, utree>
: detail::attribute_as_binary_string_type
{};
///////////////////////////////////////////////////////////////////////////
// push_back support for utree
template <typename T>
struct push_back_container<utree, T>
{
static bool call(utree& c, T const& val)
{
switch (traits::which(c))
{
case utree_type::invalid_type:
case utree_type::nil_type:
case utree_type::list_type:
c.push_back(val);
break;
default:
{
utree ut;
ut.push_back(c);
ut.push_back(val);
c.swap(ut);
}
break;
}
return true;
}
};
template <typename T>
struct push_back_container<utree::list_type, T>
: push_back_container<utree, T>
{};
///////////////////////////////////////////////////////////////////////////
// ensure the utree attribute is an empty list
template <>
struct make_container_attribute<utree>
{
static void call(utree& ut)
{
if (!detail::is_list(ut)) {
if (detail::is_uninitialized(ut))
ut = empty_list;
else {
utree retval (empty_list);
retval.push_back(ut);
ut.swap(retval);
}
}
}
};
template <>
struct make_container_attribute<utree::list_type>
: make_container_attribute<utree>
{};
///////////////////////////////////////////////////////////////////////////
// an utree is a container on its own
template <>
struct build_std_vector<utree>
{
typedef utree type;
};
template <>
struct build_std_vector<utree::list_type>
{
typedef utree::list_type type;
};
///////////////////////////////////////////////////////////////////////////
// debug support for utree
template <typename Out>
struct print_attribute_debug<Out, utree>
{
static void call(Out& out, utree const& val)
{
out << val;
}
};
///////////////////////////////////////////////////////////////////////////
// force utree list attribute in a sequence to be dereferenced if a rule
// or a grammar exposes an utree as it's attribute
namespace detail
{
// Checks whether the exposed Attribute allows to handle utree or
// utree::list_type directly. Returning mpl::false_ from this meta
// function will force a new utree instance to be created for each
// invocation of the embedded parser.
// The purpose of using utree::list_type as an attribute is to force a
// new sub-node in the result.
template <typename Attribute, typename Enable = void>
struct handles_utree_list_container
: mpl::and_<
mpl::not_<is_same<utree::list_type, Attribute> >,
traits::is_container<Attribute> >
{};
// The following specializations make sure that the actual handling of
// an utree (or utree::list_type) attribute is deferred to the embedded
// parsers of a sequence, alternative or optional component.
template <typename Attribute>
struct handles_utree_list_container<Attribute
, typename enable_if<fusion::traits::is_sequence<Attribute> >::type>
: mpl::true_
{};
template <typename Attribute>
struct handles_utree_list_container<boost::optional<Attribute> >
: mpl::true_
{};
template <BOOST_VARIANT_ENUM_PARAMS(typename T)>
struct handles_utree_list_container<
boost::variant<BOOST_VARIANT_ENUM_PARAMS(T)> >
: mpl::true_
{};
}
template <
typename IteratorA, typename IteratorB, typename Context
, typename T1, typename T2, typename T3, typename T4>
struct handles_container<qi::rule<IteratorA, T1, T2, T3, T4>
, utree, Context, IteratorB>
: detail::handles_utree_list_container<typename attribute_of<
qi::rule<IteratorA, T1, T2, T3, T4>, Context, IteratorB
>::type>
{};
template <
typename IteratorA, typename IteratorB, typename Context
, typename T1, typename T2, typename T3, typename T4>
struct handles_container<qi::grammar<IteratorA, T1, T2, T3, T4>
, utree, Context, IteratorB>
: detail::handles_utree_list_container<typename attribute_of<
qi::grammar<IteratorA, T1, T2, T3, T4>, Context, IteratorB
>::type>
{};
template <
typename IteratorA, typename IteratorB, typename Context
, typename T1, typename T2, typename T3, typename T4>
struct handles_container<qi::rule<IteratorA, T1, T2, T3, T4>
, utree::list_type, Context, IteratorB>
: detail::handles_utree_list_container<typename attribute_of<
qi::rule<IteratorA, T1, T2, T3, T4>, Context, IteratorB
>::type>
{};
template <
typename IteratorA, typename IteratorB, typename Context
, typename T1, typename T2, typename T3, typename T4>
struct handles_container<qi::grammar<IteratorA, T1, T2, T3, T4>
, utree::list_type, Context, IteratorB>
: detail::handles_utree_list_container<typename attribute_of<
qi::grammar<IteratorA, T1, T2, T3, T4>, Context, IteratorB
>::type>
{};
///////////////////////////////////////////////////////////////////////////
template <typename Attribute, typename Sequence>
struct pass_through_container<
utree, utree, Attribute, Sequence, qi::domain>
: detail::handles_utree_list_container<Attribute>
{};
template <typename Attribute, typename Sequence>
struct pass_through_container<
utree::list_type, utree, Attribute, Sequence, qi::domain>
: detail::handles_utree_list_container<Attribute>
{};
///////////////////////////////////////////////////////////////////////////
namespace detail
{
// Checks whether the exposed Attribute allows to handle utree or
// utree::list_type directly. Returning mpl::false_ from this meta
// function will force a new utree instance to be created for each
// invocation of the embedded parser.
// The purpose of using utree::list_type as an attribute is to force a
// new sub-node in the result.
template <typename Attribute, typename Enable = void>
struct handles_utree_container
: mpl::and_<
mpl::not_<is_same<utree, Attribute> >,
traits::is_container<Attribute> >
{};
// The following specializations make sure that the actual handling of
// an utree (or utree::list_type) attribute is deferred to the embedded
// parsers of a sequence, alternative or optional component.
template <typename Attribute>
struct handles_utree_container<Attribute
, typename enable_if<fusion::traits::is_sequence<Attribute> >::type>
: mpl::true_
{};
template <typename Attribute>
struct handles_utree_container<boost::optional<Attribute> >
: mpl::true_
{};
template <BOOST_VARIANT_ENUM_PARAMS(typename T)>
struct handles_utree_container<
boost::variant<BOOST_VARIANT_ENUM_PARAMS(T)> >
: mpl::true_
{};
}
template <
typename IteratorA, typename IteratorB, typename Context
, typename T1, typename T2, typename T3, typename T4>
struct handles_container<karma::rule<IteratorA, T1, T2, T3, T4>
, utree, Context, IteratorB>
: detail::handles_utree_container<typename attribute_of<
karma::rule<IteratorA, T1, T2, T3, T4>, Context, IteratorB
>::type>
{};
template <
typename IteratorA, typename IteratorB, typename Context
, typename T1, typename T2, typename T3, typename T4>
struct handles_container<karma::grammar<IteratorA, T1, T2, T3, T4>
, utree, Context, IteratorB>
: detail::handles_utree_container<typename attribute_of<
karma::grammar<IteratorA, T1, T2, T3, T4>, Context, IteratorB
>::type>
{};
///////////////////////////////////////////////////////////////////////////
template <typename Attribute, typename Sequence>
struct pass_through_container<
utree, utree, Attribute, Sequence, karma::domain>
: detail::handles_utree_container<Attribute>
{};
///////////////////////////////////////////////////////////////////////////
// the specialization below tells Spirit how to handle utree if it is used
// with an optional component
template <>
struct optional_attribute<utree>
{
typedef utree const& type;
static type call(utree const& val)
{
return val;
}
// only 'invalid_type' utree nodes are not valid
static bool is_valid(utree const& val)
{
return !detail::is_uninitialized(val);
}
};
template <>
struct build_optional<utree>
{
typedef utree type;
};
template <>
struct build_optional<utree::list_type>
{
typedef utree::list_type type;
};
// an utree is an optional (in any domain)
template <>
struct not_is_optional<utree, qi::domain>
: mpl::false_
{};
template <>
struct not_is_optional<utree::list_type, qi::domain>
: mpl::false_
{};
template <>
struct not_is_optional<utree, karma::domain>
: mpl::false_
{};
template <>
struct not_is_optional<utree::list_type, karma::domain>
: mpl::false_
{};
///////////////////////////////////////////////////////////////////////////
// the specialization below tells Spirit to handle utree as if it
// where a 'real' variant (in the context of karma)
template <>
struct not_is_variant<utree, karma::domain>
: mpl::false_
{};
template <>
struct not_is_variant<utree::list_type, karma::domain>
: mpl::false_
{};
// The specializations below tell Spirit to verify whether an attribute
// type is compatible with a given variant type
template <>
struct compute_compatible_component_variant<
utree, iterator_range<utree::iterator> >
: mpl::true_
{
typedef iterator_range<utree::iterator> compatible_type;
static bool is_compatible(int d)
{
return d == utree_type::list_type;
}
};
template <>
struct compute_compatible_component_variant<
utree, iterator_range<utree::const_iterator> >
: mpl::true_
{
typedef iterator_range<utree::const_iterator> compatible_type;
static bool is_compatible(int d)
{
return d == utree_type::list_type;
}
};
template <>
struct compute_compatible_component_variant<utree, utree::invalid_type>
: mpl::true_
{
typedef utree::invalid_type compatible_type;
static bool is_compatible(int d)
{
return d == utree_type::invalid_type;
}
};
template <>
struct compute_compatible_component_variant<utree, utree::nil_type>
: mpl::true_
{
typedef utree::nil_type compatible_type;
static bool is_compatible(int d)
{
return d == utree_type::nil_type;
}
};
template <>
struct compute_compatible_component_variant<utree, bool>
: mpl::true_
{
typedef bool compatible_type;
static bool is_compatible(int d)
{
return d == utree_type::bool_type;
}
};
template <>
struct compute_compatible_component_variant<utree, int>
: mpl::true_
{
typedef int compatible_type;
static bool is_compatible(int d)
{
return d == utree_type::int_type;
}
};
template <>
struct compute_compatible_component_variant<utree, double>
: mpl::true_
{
typedef double compatible_type;
static bool is_compatible(int d)
{
return d == utree_type::double_type;
}
};
template <>
struct compute_compatible_component_variant<
utree, utf8_string_range_type>
: mpl::true_
{
typedef utf8_string_range_type compatible_type;
static bool is_compatible(int d)
{
return d == utree_type::string_type;
}
};
template <>
struct compute_compatible_component_variant<
utree, utf8_string_type>
: mpl::true_
{
typedef utf8_string_type compatible_type;
static bool is_compatible(int d)
{
return d == utree_type::string_type;
}
};
template <>
struct compute_compatible_component_variant<
utree, utf8_symbol_range_type>
: mpl::true_
{
typedef utf8_symbol_range_type compatible_type;
static bool is_compatible(int d)
{
return d == utree_type::symbol_type;
}
};
template <>
struct compute_compatible_component_variant<
utree, utf8_symbol_type>
: mpl::true_
{
typedef utf8_symbol_type compatible_type;
static bool is_compatible(int d)
{
return d == utree_type::symbol_type;
}
};
template <>
struct compute_compatible_component_variant<
utree, binary_range_type>
: mpl::true_
{
typedef binary_range_type compatible_type;
static bool is_compatible(int d)
{
return d == utree_type::binary_type;
}
};
template <>
struct compute_compatible_component_variant<
utree, binary_string_type>
: mpl::true_
{
typedef binary_string_type compatible_type;
static bool is_compatible(int d)
{
return d == utree_type::binary_type;
}
};
template <>
struct compute_compatible_component_variant<utree, utree>
: mpl::true_
{
typedef utree compatible_type;
static bool is_compatible(int d)
{
return d >= utree_type::invalid_type &&
d <= utree_type::reference_type;
}
};
template <>
struct compute_compatible_component_variant<
utree, std::vector<utree> >
: mpl::true_
{
typedef utree compatible_type;
static bool is_compatible(int d)
{
return d >= utree_type::invalid_type &&
d <= utree_type::reference_type;
}
};
template <typename Sequence>
struct compute_compatible_component_variant<utree, Sequence
, mpl::false_
, typename enable_if<fusion::traits::is_sequence<Sequence> >::type>
: mpl::true_
{
typedef iterator_range<utree::const_iterator> compatible_type;
static bool is_compatible(int d)
{
return d == utree_type::list_type;
}
};
template <typename Attribute>
struct compute_compatible_component_variant<utree::list_type, Attribute>
: compute_compatible_component_variant<utree, Attribute>
{};
///////////////////////////////////////////////////////////////////////////
template <>
struct symbols_lookup<utree, utf8_symbol_type>
{
typedef std::string type;
static type call(utree const& t)
{
utf8_symbol_range_type r = boost::get<utf8_symbol_range_type>(t);
return std::string(traits::begin(r), traits::end(r));
}
};
template <>
struct symbols_lookup<utf8_symbol_type, utf8_symbol_type>
{
typedef std::string type;
static type call(utf8_symbol_type const& t)
{
return t;
}
};
///////////////////////////////////////////////////////////////////////////
namespace detail
{
template <typename T>
inline T get_or_deref(utree const& t)
{
if (detail::is_list(t))
return boost::get<T>(t.front());
return boost::get<T>(t);
}
}
template <>
struct extract_from_container<utree, utree::nil_type>
{
typedef utree::nil_type type;
template <typename Context>
static type call(utree const&, Context&)
{
return nil;
}
};
template <>
struct extract_from_container<utree, char>
{
typedef char type;
template <typename Context>
static type call(utree const& t, Context&)
{
utf8_symbol_range_type r = detail::get_or_deref<utf8_symbol_range_type>(t);
return r.front();
}
};
template <>
struct extract_from_container<utree, bool>
{
typedef bool type;
template <typename Context>
static type call(utree const& t, Context&)
{
return detail::get_or_deref<bool>(t);
}
};
template <>
struct extract_from_container<utree, int>
{
typedef int type;
template <typename Context>
static type call(utree const& t, Context&)
{
return detail::get_or_deref<int>(t);
}
};
template <>
struct extract_from_container<utree, double>
{
typedef double type;
template <typename Context>
static type call(utree const& t, Context&)
{
return detail::get_or_deref<double>(t);
}
};
template <typename Traits, typename Alloc>
struct extract_from_container<utree, std::basic_string<char, Traits, Alloc> >
{
typedef std::basic_string<char, Traits, Alloc> type;
template <typename Context>
static type call(utree const& t, Context&)
{
utf8_string_range_type r = detail::get_or_deref<utf8_string_range_type>(t);
return type(traits::begin(r), traits::end(r));
}
};
template <>
struct extract_from_container<utree, utf8_symbol_type>
{
typedef utf8_symbol_type type;
template <typename Context>
static type call(utree const& t, Context&)
{
utf8_symbol_range_type r = detail::get_or_deref<utf8_symbol_range_type>(t);
return type(traits::begin(r), traits::end(r));
}
};
template <>
struct extract_from_container<utree, utf8_string_type>
{
typedef utf8_string_type type;
template <typename Context>
static type call(utree const& t, Context&)
{
utf8_string_range_type r = detail::get_or_deref<utf8_string_range_type>(t);
return type(traits::begin(r), traits::end(r));
}
};
///////////////////////////////////////////////////////////////////////////
template <>
struct transform_attribute<utree const, utree::nil_type, karma::domain>
{
typedef utree::nil_type type;
static type pre(utree const&)
{
return nil;
}
};
template <>
struct transform_attribute<utree const, char, karma::domain>
{
typedef char type;
static type pre(utree const& t)
{
utf8_string_range_type r = detail::get_or_deref<utf8_string_range_type>(t);
return r.front();
}
};
template <>
struct transform_attribute<utree const, bool, karma::domain>
{
typedef bool type;
static type pre(utree const& t)
{
return detail::get_or_deref<bool>(t);
}
};
template <>
struct transform_attribute<utree const, int, karma::domain>
{
typedef int type;
static type pre(utree const& t)
{
return detail::get_or_deref<int>(t);
}
};
template <>
struct transform_attribute<utree const, double, karma::domain>
{
typedef double type;
static type pre(utree const& t)
{
return detail::get_or_deref<double>(t);
}
};
template <typename Traits, typename Alloc>
struct transform_attribute<
utree const, std::basic_string<char, Traits, Alloc>, karma::domain>
{
typedef std::basic_string<char, Traits, Alloc> type;
static type pre(utree const& t)
{
utf8_string_range_type r = detail::get_or_deref<utf8_string_range_type>(t);
return type(traits::begin(r), traits::end(r));
}
};
// this specialization is used whenever a utree is passed to a rule as part
// of a sequence
template <typename Iterator>
struct transform_attribute<
iterator_range<Iterator> const, utree, karma::domain>
{
typedef utree type;
static type pre(iterator_range<Iterator> const& t)
{
// return utree the begin iterator points to
Iterator it = t.begin();
utree result(boost::ref(*it));
++it;
return result;
}
};
///////////////////////////////////////////////////////////////////////////
template <>
struct transform_attribute<utree const, utf8_string_type, karma::domain>
{
typedef utf8_string_type type;
static type pre(utree const& t)
{
utf8_string_range_type r = detail::get_or_deref<utf8_string_range_type>(t);
return type(traits::begin(r), traits::end(r));
}
};
template <>
struct transform_attribute<utree const, utf8_symbol_type, karma::domain>
{
typedef utf8_symbol_type type;
static type pre(utree const& t)
{
utf8_symbol_range_type r = detail::get_or_deref<utf8_symbol_range_type>(t);
return type(traits::begin(r), traits::end(r));
}
};
template <typename Attribute>
struct transform_attribute<utree::list_type const, Attribute, karma::domain>
: transform_attribute<utree const, Attribute, karma::domain>
{};
}}}
#endif