msgpack/erb/cpp03_msgpack_tuple.hpp.erb

//
// MessagePack for C++ static resolution routine
//
// Copyright (C) 2008-2013 FURUHASHI Sadayuki and KONDO Takatoshi
//
//    Licensed under the Apache License, Version 2.0 (the "License");
//    you may not use this file except in compliance with the License.
//    You may obtain a copy of the License at
//
//        http://www.apache.org/licenses/LICENSE-2.0
//
//    Unless required by applicable law or agreed to in writing, software
//    distributed under the License is distributed on an "AS IS" BASIS,
//    WITHOUT WARRANTIES OR CONDITIONS OF ANY KIND, either express or implied.
//    See the License for the specific language governing permissions and
//    limitations under the License.
//
#ifndef MSGPACK_CPP03_MSGPACK_TUPLE_HPP
#define MSGPACK_CPP03_MSGPACK_TUPLE_HPP

#include "msgpack/versioning.hpp"
#include "msgpack/object.hpp"

namespace msgpack {

MSGPACK_API_VERSION_NAMESPACE(v1) {

namespace type {

// FIXME operator==
// FIXME operator!=
<% GENERATION_LIMIT = 31 %>

template <typename A0<%1.upto(GENERATION_LIMIT+1) {|i|%>, typename A<%=i%><%}%>>
struct tuple;

template <typename Tuple, int N>
struct tuple_element;

template <typename Tuple, int N>
struct const_tuple_element;

template <typename T>
struct tuple_type {
    typedef T type;
    typedef T value_type;
    typedef T& reference;
    typedef const T& const_reference;
    typedef const T& transparent_reference;
};

template <typename T>
struct tuple_type<T&> {
    typedef T type;
    typedef T& value_type;
    typedef T& reference;
    typedef const T& const_reference;
    typedef T& transparent_reference;
};

template <typename T>
struct tuple_type<const T&> {
    typedef T type;
    typedef T& value_type;
    typedef T& reference;
    typedef const T& const_reference;
    typedef const T& transparent_reference;
};

<%0.upto(GENERATION_LIMIT) {|i|%>
<%0.upto(i) {|j|%>
template <typename A0<%1.upto(i) {|k|%>, typename A<%=k%><%}%>>
struct tuple_element<tuple<A0<%1.upto(i) {|k|%>, A<%=k%><%}%>>, <%=j%>> : tuple_type<A<%=j%>> {
    tuple_element(tuple<A0<%1.upto(i) {|k|%>, A<%=k%> <%}%>>& x) : m_x(x.a<%=j%>) {}
    typename tuple_type<A<%=j%>>::reference get() { return m_x; }
    typename tuple_type<A<%=j%>>::const_reference get() const { return m_x; }
private:
    typename tuple_type<A<%=j%>>::reference m_x;
};
<%}%>
<%}%>

<%0.upto(GENERATION_LIMIT) {|i|%>
<%0.upto(i) {|j|%>
template <typename A0<%1.upto(i) {|k|%>, typename A<%=k%><%}%>>
struct const_tuple_element<tuple<A0<%1.upto(i) {|k|%>, A<%=k%><%}%>>, <%=j%>> : tuple_type<A<%=j%>> {
    const_tuple_element(const tuple<A0<%1.upto(i) {|k|%>, A<%=k%><%}%>>& x) : m_x(x.a<%=j%>) {}
    typename tuple_type<A<%=j%>>::const_reference get() const { return m_x; }
private:
    typename tuple_type<A<%=j%>>::const_reference m_x;
};
<%}%>
<%}%>

template <>
struct tuple<> {
    tuple() {}
    tuple(object const& o) { o.convert(*this); }
    typedef tuple<> value_type;
};
<%0.upto(GENERATION_LIMIT) {|i|%>
template <typename A0<%1.upto(i) {|j|%>, typename A<%=j%><%}%>>
struct tuple<A0<%1.upto(i) {|j|%>, A<%=j%><%}%>> {
    typedef tuple<A0<%1.upto(i) {|j|%>, A<%=j%><%}%>> value_type;
    tuple() {}
    tuple(typename tuple_type<A0>::transparent_reference _a0<%1.upto(i) {|j|%>, typename tuple_type<A<%=j%>>::transparent_reference _a<%=j%><%}%>) :
        a0(_a0)<%1.upto(i) {|j|%>, a<%=j%>(_a<%=j%>)<%}%> {}
    tuple(object const& o) { o.convert(*this); }
    template <int N> typename tuple_element<value_type, N>::reference get()
        { return tuple_element<value_type, N>(*this).get(); }
    template <int N> typename const_tuple_element<value_type, N>::const_reference get() const
        { return const_tuple_element<value_type, N>(*this).get(); }
    <%0.upto(i) {|j|%>
    A<%=j%> a<%=j%>;<%}%>
};

template <int N, typename A0<%1.upto(i) {|j|%>, typename A<%=j%><%}%>>
inline typename type::tuple_element<type::tuple<A0<%1.upto(i) {|j|%>, A<%=j%><%}%>>, N>::reference get(type::tuple<A0<%1.upto(i) {|j|%>, A<%=j%><%}%>>& t)
{ return t.template get<N>(); }
template <int N, typename A0<%1.upto(i) {|j|%>, typename A<%=j%><%}%>>
inline typename type::const_tuple_element<type::tuple<A0<%1.upto(i) {|j|%>, A<%=j%><%}%>>, N>::const_reference get(type::tuple<A0<%1.upto(i) {|j|%>, A<%=j%><%}%>> const& t)
{ return t.template get<N>(); }
<%}%>

inline tuple<> make_tuple()
{
    return tuple<>();
}
<%0.upto(GENERATION_LIMIT) {|i|%>
template <typename A0<%1.upto(i) {|j|%>, typename A<%=j%><%}%>>
inline tuple<A0<%1.upto(i) {|j|%>, A<%=j%><%}%>> make_tuple(typename tuple_type<A0>::transparent_reference a0<%1.upto(i) {|j|%>, typename tuple_type<A<%=j%>>::transparent_reference a<%=j%><%}%>)
{
    return tuple<A0<%1.upto(i) {|j|%>, A<%=j%><%}%>>(a0<%1.upto(i) {|j|%>, a<%=j%><%}%>);
}
<%}%>

}  // namespace type

inline object const& operator>> (
        object const& o,
        type::tuple<>&) {
    if(o.type != type::ARRAY) { throw type_error(); }
    return o;
}
<%0.upto(GENERATION_LIMIT) {|i|%>
template <typename A0<%1.upto(i) {|j|%>, typename A<%=j%><%}%>>
inline object const& operator>> (
        object const& o,
        type::tuple<A0<%1.upto(i) {|j|%>, A<%=j%><%}%>>& v) {
    if(o.type != type::ARRAY) { throw type_error(); }
    if(o.via.array.size < <%=i+1%>) { throw type_error(); }
    <%0.upto(i) {|j|%>
    o.via.array.ptr[<%=j%>].convert<typename type::tuple_type<A<%=j%>>::type>(v.template get<<%=j%>>());<%}%>
    return o;
}
<%}%>

template <typename Stream>
inline const packer<Stream>& operator<< (
        packer<Stream>& o,
        const type::tuple<>&) {
    o.pack_array(0);
    return o;
}
<%0.upto(GENERATION_LIMIT) {|i|%>
template <typename Stream, typename A0<%1.upto(i) {|j|%>, typename A<%=j%><%}%>>
inline const packer<Stream>& operator<< (
        packer<Stream>& o,
        const type::tuple<A0<%1.upto(i) {|j|%>, A<%=j%><%}%>>& v) {
    o.pack_array(<%=i+1%>);
    <%0.upto(i) {|j|%>
    o.pack(v.template get<<%=j%>>());<%}%>
    return o;
}
<%}%>

inline void operator<< (
        object::with_zone& o,
        const type::tuple<>&) {
    o.type = type::ARRAY;
    o.via.array.ptr = nullptr;
    o.via.array.size = 0;
}
<%0.upto(GENERATION_LIMIT) {|i|%>
template <typename A0<%1.upto(i) {|j|%>, typename A<%=j%><%}%>>
inline void operator<< (
        object::with_zone& o,
        const type::tuple<A0<%1.upto(i) {|j|%>, A<%=j%><%}%>>& v) {
    o.type = type::ARRAY;
    o.via.array.ptr = static_cast<object*>(o.zone.allocate_align(sizeof(object)*<%=i+1%>));
    o.via.array.size = <%=i+1%>;
    <%0.upto(i) {|j|%>
    o.via.array.ptr[<%=j%>] = object(v.template get<<%=j%>>(), o.zone);<%}%>
}
<%}%>

}  // MSGPACK_API_VERSION_NAMESPACE(v1)

}  // namespace msgpack


//inline std::ostream& operator<< (std::ostream& o, const msgpack::type::tuple<>& v) {
//  return o << "[]";
//}
//<%0.upto(GENERATION_LIMIT) {|i|%>
//template <typename A0<%1.upto(i) {|j|%>, typename A<%=j%><%}%>>
//inline std::ostream& operator<< (std::ostream& o,
//      const msgpack::type::tuple<A0<%1.upto(i) {|j|%>, A<%=j%><%}%>>& v) {
//  return o << "["
//  <%0.upto(i) {|j|%>
//  <<<%if j != 0 then%> ", " <<<%end%> v.template get<<%=j%>>()<%}%>
//  << "]";
//}
//<%}%>

#endif // MSGPACK_CPP03_MSGPACK_TUPLE_HPP