kicad/include/boost/multi_index/composite_key.hpp

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/* Copyright 2003-2011 Joaquin M Lopez Munoz.
* 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)
*
* See http://www.boost.org/libs/multi_index for library home page.
*/
#ifndef BOOST_MULTI_INDEX_COMPOSITE_KEY_HPP
#define BOOST_MULTI_INDEX_COMPOSITE_KEY_HPP
#if defined(_MSC_VER)&&(_MSC_VER>=1200)
#pragma once
#endif
#include <boost/config.hpp> /* keep it first to prevent nasty warns in MSVC */
#include <boost/functional/hash_fwd.hpp>
#include <boost/multi_index/detail/access_specifier.hpp>
#include <boost/multi_index/detail/prevent_eti.hpp>
#include <boost/mpl/eval_if.hpp>
#include <boost/mpl/identity.hpp>
#include <boost/mpl/if.hpp>
#include <boost/mpl/or.hpp>
#include <boost/mpl/aux_/nttp_decl.hpp>
#include <boost/preprocessor/cat.hpp>
#include <boost/preprocessor/control/expr_if.hpp>
#include <boost/preprocessor/list/at.hpp>
#include <boost/preprocessor/repetition/enum.hpp>
#include <boost/preprocessor/repetition/enum_params.hpp>
#include <boost/static_assert.hpp>
#include <boost/tuple/tuple.hpp>
#include <boost/type_traits/is_same.hpp>
#include <boost/utility/enable_if.hpp>
#include <functional>
#if !defined(BOOST_NO_FUNCTION_TEMPLATE_ORDERING)
#include <boost/ref.hpp>
#endif
#if !defined(BOOST_NO_SFINAE)
#include <boost/type_traits/is_convertible.hpp>
#endif
/* A composite key stores n key extractors and "computes" the
* result on a given value as a packed reference to the value and
* the composite key itself. Actual invocations to the component
* key extractors are lazily performed when executing an operation
* on composite_key results (equality, comparison, hashing.)
* As the other key extractors in Boost.MultiIndex, composite_key<T,...>
* is overloaded to work on chained pointers to T and reference_wrappers
* of T.
*/
/* This user_definable macro limits the number of elements of a composite
* key; useful for shortening resulting symbol names (MSVC++ 6.0, for
* instance has problems coping with very long symbol names.)
* NB: This cannot exceed the maximum number of arguments of
* boost::tuple. In Boost 1.32, the limit is 10.
*/
#if !defined(BOOST_MULTI_INDEX_LIMIT_COMPOSITE_KEY_SIZE)
#if defined(BOOST_MSVC)&&(BOOST_MSVC<1300)
#define BOOST_MULTI_INDEX_LIMIT_COMPOSITE_KEY_SIZE 5
#else
#define BOOST_MULTI_INDEX_LIMIT_COMPOSITE_KEY_SIZE 10
#endif
#endif
/* maximum number of key extractors in a composite key */
#if BOOST_MULTI_INDEX_LIMIT_COMPOSITE_KEY_SIZE<10 /* max length of a tuple */
#define BOOST_MULTI_INDEX_COMPOSITE_KEY_SIZE \
BOOST_MULTI_INDEX_LIMIT_COMPOSITE_KEY_SIZE
#else
#define BOOST_MULTI_INDEX_COMPOSITE_KEY_SIZE 10
#endif
/* BOOST_PP_ENUM of BOOST_MULTI_INDEX_COMPOSITE_KEY_SIZE elements */
#define BOOST_MULTI_INDEX_CK_ENUM(macro,data) \
BOOST_PP_ENUM(BOOST_MULTI_INDEX_COMPOSITE_KEY_SIZE,macro,data)
/* BOOST_PP_ENUM_PARAMS of BOOST_MULTI_INDEX_COMPOSITE_KEY_SIZE elements */
#define BOOST_MULTI_INDEX_CK_ENUM_PARAMS(param) \
BOOST_PP_ENUM_PARAMS(BOOST_MULTI_INDEX_COMPOSITE_KEY_SIZE,param)
/* if n==0 -> text0
* otherwise -> textn=tuples::null_type
*/
#define BOOST_MULTI_INDEX_CK_TEMPLATE_PARM(z,n,text) \
typename BOOST_PP_CAT(text,n) BOOST_PP_EXPR_IF(n,=tuples::null_type)
/* const textn& kn=textn() */
#define BOOST_MULTI_INDEX_CK_CTOR_ARG(z,n,text) \
const BOOST_PP_CAT(text,n)& BOOST_PP_CAT(k,n) = BOOST_PP_CAT(text,n)()
/* typename list(0)<list(1),n>::type */
#define BOOST_MULTI_INDEX_CK_APPLY_METAFUNCTION_N(z,n,list) \
BOOST_DEDUCED_TYPENAME BOOST_PP_LIST_AT(list,0)< \
BOOST_PP_LIST_AT(list,1),n \
>::type
namespace boost{
template<class T> class reference_wrapper; /* fwd decl. */
namespace multi_index{
namespace detail{
/* n-th key extractor of a composite key */
template<typename CompositeKey,BOOST_MPL_AUX_NTTP_DECL(int, N)>
struct nth_key_from_value
{
typedef typename CompositeKey::key_extractor_tuple key_extractor_tuple;
typedef typename prevent_eti<
tuples::element<N,key_extractor_tuple>,
typename mpl::eval_if_c<
N<tuples::length<key_extractor_tuple>::value,
tuples::element<N,key_extractor_tuple>,
mpl::identity<tuples::null_type>
>::type
>::type type;
};
/* nth_composite_key_##name<CompositeKey,N>::type yields
* functor<nth_key_from_value<CompositeKey,N> >, or tuples::null_type
* if N exceeds the length of the composite key.
*/
#define BOOST_MULTI_INDEX_CK_NTH_COMPOSITE_KEY_FUNCTOR(name,functor) \
template<typename KeyFromValue> \
struct BOOST_PP_CAT(key_,name) \
{ \
typedef functor<typename KeyFromValue::result_type> type; \
}; \
\
template<> \
struct BOOST_PP_CAT(key_,name)<tuples::null_type> \
{ \
typedef tuples::null_type type; \
}; \
\
template<typename CompositeKey,BOOST_MPL_AUX_NTTP_DECL(int, N)> \
struct BOOST_PP_CAT(nth_composite_key_,name) \
{ \
typedef typename nth_key_from_value<CompositeKey,N>::type key_from_value; \
typedef typename BOOST_PP_CAT(key_,name)<key_from_value>::type type; \
};
/* nth_composite_key_equal_to
* nth_composite_key_less
* nth_composite_key_greater
* nth_composite_key_hash
*/
BOOST_MULTI_INDEX_CK_NTH_COMPOSITE_KEY_FUNCTOR(equal_to,std::equal_to)
BOOST_MULTI_INDEX_CK_NTH_COMPOSITE_KEY_FUNCTOR(less,std::less)
BOOST_MULTI_INDEX_CK_NTH_COMPOSITE_KEY_FUNCTOR(greater,std::greater)
BOOST_MULTI_INDEX_CK_NTH_COMPOSITE_KEY_FUNCTOR(hash,boost::hash)
/* used for defining equality and comparison ops of composite_key_result */
#define BOOST_MULTI_INDEX_CK_IDENTITY_ENUM_MACRO(z,n,text) text
struct generic_operator_equal
{
template<typename T,typename Q>
bool operator()(const T& x,const Q& y)const{return x==y;}
};
typedef tuple<
BOOST_MULTI_INDEX_CK_ENUM(
BOOST_MULTI_INDEX_CK_IDENTITY_ENUM_MACRO,
detail::generic_operator_equal)> generic_operator_equal_tuple;
struct generic_operator_less
{
template<typename T,typename Q>
bool operator()(const T& x,const Q& y)const{return x<y;}
};
typedef tuple<
BOOST_MULTI_INDEX_CK_ENUM(
BOOST_MULTI_INDEX_CK_IDENTITY_ENUM_MACRO,
detail::generic_operator_less)> generic_operator_less_tuple;
/* Metaprogramming machinery for implementing equality, comparison and
* hashing operations of composite_key_result.
*
* equal_* checks for equality between composite_key_results and
* between those and tuples, accepting a tuple of basic equality functors.
* compare_* does lexicographical comparison.
* hash_* computes a combination of elementwise hash values.
*/
template
<
typename KeyCons1,typename Value1,
typename KeyCons2, typename Value2,
typename EqualCons
>
struct equal_ckey_ckey; /* fwd decl. */
template
<
typename KeyCons1,typename Value1,
typename KeyCons2, typename Value2,
typename EqualCons
>
struct equal_ckey_ckey_terminal
{
static bool compare(
const KeyCons1&,const Value1&,
const KeyCons2&,const Value2&,
const EqualCons&)
{
return true;
}
};
template
<
typename KeyCons1,typename Value1,
typename KeyCons2, typename Value2,
typename EqualCons
>
struct equal_ckey_ckey_normal
{
static bool compare(
const KeyCons1& c0,const Value1& v0,
const KeyCons2& c1,const Value2& v1,
const EqualCons& eq)
{
if(!eq.get_head()(c0.get_head()(v0),c1.get_head()(v1)))return false;
return equal_ckey_ckey<
BOOST_DEDUCED_TYPENAME KeyCons1::tail_type,Value1,
BOOST_DEDUCED_TYPENAME KeyCons2::tail_type,Value2,
BOOST_DEDUCED_TYPENAME EqualCons::tail_type
>::compare(c0.get_tail(),v0,c1.get_tail(),v1,eq.get_tail());
}
};
template
<
typename KeyCons1,typename Value1,
typename KeyCons2, typename Value2,
typename EqualCons
>
struct equal_ckey_ckey:
mpl::if_<
mpl::or_<
is_same<KeyCons1,tuples::null_type>,
is_same<KeyCons2,tuples::null_type>
>,
equal_ckey_ckey_terminal<KeyCons1,Value1,KeyCons2,Value2,EqualCons>,
equal_ckey_ckey_normal<KeyCons1,Value1,KeyCons2,Value2,EqualCons>
>::type
{
};
template
<
typename KeyCons,typename Value,
typename ValCons,typename EqualCons
>
struct equal_ckey_cval; /* fwd decl. */
template
<
typename KeyCons,typename Value,
typename ValCons,typename EqualCons
>
struct equal_ckey_cval_terminal
{
static bool compare(
const KeyCons&,const Value&,const ValCons&,const EqualCons&)
{
return true;
}
static bool compare(
const ValCons&,const KeyCons&,const Value&,const EqualCons&)
{
return true;
}
};
template
<
typename KeyCons,typename Value,
typename ValCons,typename EqualCons
>
struct equal_ckey_cval_normal
{
static bool compare(
const KeyCons& c,const Value& v,const ValCons& vc,
const EqualCons& eq)
{
if(!eq.get_head()(c.get_head()(v),vc.get_head()))return false;
return equal_ckey_cval<
BOOST_DEDUCED_TYPENAME KeyCons::tail_type,Value,
BOOST_DEDUCED_TYPENAME ValCons::tail_type,
BOOST_DEDUCED_TYPENAME EqualCons::tail_type
>::compare(c.get_tail(),v,vc.get_tail(),eq.get_tail());
}
static bool compare(
const ValCons& vc,const KeyCons& c,const Value& v,
const EqualCons& eq)
{
if(!eq.get_head()(vc.get_head(),c.get_head()(v)))return false;
return equal_ckey_cval<
BOOST_DEDUCED_TYPENAME KeyCons::tail_type,Value,
BOOST_DEDUCED_TYPENAME ValCons::tail_type,
BOOST_DEDUCED_TYPENAME EqualCons::tail_type
>::compare(vc.get_tail(),c.get_tail(),v,eq.get_tail());
}
};
template
<
typename KeyCons,typename Value,
typename ValCons,typename EqualCons
>
struct equal_ckey_cval:
mpl::if_<
mpl::or_<
is_same<KeyCons,tuples::null_type>,
is_same<ValCons,tuples::null_type>
>,
equal_ckey_cval_terminal<KeyCons,Value,ValCons,EqualCons>,
equal_ckey_cval_normal<KeyCons,Value,ValCons,EqualCons>
>::type
{
};
template
<
typename KeyCons1,typename Value1,
typename KeyCons2, typename Value2,
typename CompareCons
>
struct compare_ckey_ckey; /* fwd decl. */
template
<
typename KeyCons1,typename Value1,
typename KeyCons2, typename Value2,
typename CompareCons
>
struct compare_ckey_ckey_terminal
{
static bool compare(
const KeyCons1&,const Value1&,
const KeyCons2&,const Value2&,
const CompareCons&)
{
return false;
}
};
template
<
typename KeyCons1,typename Value1,
typename KeyCons2, typename Value2,
typename CompareCons
>
struct compare_ckey_ckey_normal
{
static bool compare(
const KeyCons1& c0,const Value1& v0,
const KeyCons2& c1,const Value2& v1,
const CompareCons& comp)
{
if(comp.get_head()(c0.get_head()(v0),c1.get_head()(v1)))return true;
if(comp.get_head()(c1.get_head()(v1),c0.get_head()(v0)))return false;
return compare_ckey_ckey<
BOOST_DEDUCED_TYPENAME KeyCons1::tail_type,Value1,
BOOST_DEDUCED_TYPENAME KeyCons2::tail_type,Value2,
BOOST_DEDUCED_TYPENAME CompareCons::tail_type
>::compare(c0.get_tail(),v0,c1.get_tail(),v1,comp.get_tail());
}
};
template
<
typename KeyCons1,typename Value1,
typename KeyCons2, typename Value2,
typename CompareCons
>
struct compare_ckey_ckey:
mpl::if_<
mpl::or_<
is_same<KeyCons1,tuples::null_type>,
is_same<KeyCons2,tuples::null_type>
>,
compare_ckey_ckey_terminal<KeyCons1,Value1,KeyCons2,Value2,CompareCons>,
compare_ckey_ckey_normal<KeyCons1,Value1,KeyCons2,Value2,CompareCons>
>::type
{
};
template
<
typename KeyCons,typename Value,
typename ValCons,typename CompareCons
>
struct compare_ckey_cval; /* fwd decl. */
template
<
typename KeyCons,typename Value,
typename ValCons,typename CompareCons
>
struct compare_ckey_cval_terminal
{
static bool compare(
const KeyCons&,const Value&,const ValCons&,const CompareCons&)
{
return false;
}
static bool compare(
const ValCons&,const KeyCons&,const Value&,const CompareCons&)
{
return false;
}
};
template
<
typename KeyCons,typename Value,
typename ValCons,typename CompareCons
>
struct compare_ckey_cval_normal
{
static bool compare(
const KeyCons& c,const Value& v,const ValCons& vc,
const CompareCons& comp)
{
if(comp.get_head()(c.get_head()(v),vc.get_head()))return true;
if(comp.get_head()(vc.get_head(),c.get_head()(v)))return false;
return compare_ckey_cval<
BOOST_DEDUCED_TYPENAME KeyCons::tail_type,Value,
BOOST_DEDUCED_TYPENAME ValCons::tail_type,
BOOST_DEDUCED_TYPENAME CompareCons::tail_type
>::compare(c.get_tail(),v,vc.get_tail(),comp.get_tail());
}
static bool compare(
const ValCons& vc,const KeyCons& c,const Value& v,
const CompareCons& comp)
{
if(comp.get_head()(vc.get_head(),c.get_head()(v)))return true;
if(comp.get_head()(c.get_head()(v),vc.get_head()))return false;
return compare_ckey_cval<
BOOST_DEDUCED_TYPENAME KeyCons::tail_type,Value,
BOOST_DEDUCED_TYPENAME ValCons::tail_type,
BOOST_DEDUCED_TYPENAME CompareCons::tail_type
>::compare(vc.get_tail(),c.get_tail(),v,comp.get_tail());
}
};
template
<
typename KeyCons,typename Value,
typename ValCons,typename CompareCons
>
struct compare_ckey_cval:
mpl::if_<
mpl::or_<
is_same<KeyCons,tuples::null_type>,
is_same<ValCons,tuples::null_type>
>,
compare_ckey_cval_terminal<KeyCons,Value,ValCons,CompareCons>,
compare_ckey_cval_normal<KeyCons,Value,ValCons,CompareCons>
>::type
{
};
template<typename KeyCons,typename Value,typename HashCons>
struct hash_ckey; /* fwd decl. */
template<typename KeyCons,typename Value,typename HashCons>
struct hash_ckey_terminal
{
static std::size_t hash(
const KeyCons&,const Value&,const HashCons&,std::size_t carry)
{
return carry;
}
};
template<typename KeyCons,typename Value,typename HashCons>
struct hash_ckey_normal
{
static std::size_t hash(
const KeyCons& c,const Value& v,const HashCons& h,std::size_t carry=0)
{
/* same hashing formula as boost::hash_combine */
carry^=h.get_head()(c.get_head()(v))+0x9e3779b9+(carry<<6)+(carry>>2);
return hash_ckey<
BOOST_DEDUCED_TYPENAME KeyCons::tail_type,Value,
BOOST_DEDUCED_TYPENAME HashCons::tail_type
>::hash(c.get_tail(),v,h.get_tail(),carry);
}
};
template<typename KeyCons,typename Value,typename HashCons>
struct hash_ckey:
mpl::if_<
is_same<KeyCons,tuples::null_type>,
hash_ckey_terminal<KeyCons,Value,HashCons>,
hash_ckey_normal<KeyCons,Value,HashCons>
>::type
{
};
template<typename ValCons,typename HashCons>
struct hash_cval; /* fwd decl. */
template<typename ValCons,typename HashCons>
struct hash_cval_terminal
{
static std::size_t hash(const ValCons&,const HashCons&,std::size_t carry)
{
return carry;
}
};
template<typename ValCons,typename HashCons>
struct hash_cval_normal
{
static std::size_t hash(
const ValCons& vc,const HashCons& h,std::size_t carry=0)
{
carry^=h.get_head()(vc.get_head())+0x9e3779b9+(carry<<6)+(carry>>2);
return hash_cval<
BOOST_DEDUCED_TYPENAME ValCons::tail_type,
BOOST_DEDUCED_TYPENAME HashCons::tail_type
>::hash(vc.get_tail(),h.get_tail(),carry);
}
};
template<typename ValCons,typename HashCons>
struct hash_cval:
mpl::if_<
is_same<ValCons,tuples::null_type>,
hash_cval_terminal<ValCons,HashCons>,
hash_cval_normal<ValCons,HashCons>
>::type
{
};
} /* namespace multi_index::detail */
/* composite_key_result */
#if defined(BOOST_MSVC)
#pragma warning(push)
#pragma warning(disable:4512)
#endif
template<typename CompositeKey>
struct composite_key_result
{
typedef CompositeKey composite_key_type;
typedef typename composite_key_type::value_type value_type;
composite_key_result(
const composite_key_type& composite_key_,const value_type& value_):
composite_key(composite_key_),value(value_)
{}
const composite_key_type& composite_key;
const value_type& value;
};
#if defined(BOOST_MSVC)
#pragma warning(pop)
#endif
/* composite_key */
/* NB. Some overloads of operator() have an extra dummy parameter int=0.
* This disambiguator serves several purposes:
* - Without it, MSVC++ 6.0 incorrectly regards some overloads as
* specializations of a previous member function template.
* - MSVC++ 6.0/7.0 seem to incorrectly treat some different memfuns
* as if they have the same signature.
* - If remove_const is broken due to lack of PTS, int=0 avoids the
* declaration of memfuns with identical signature.
*/
template<
typename Value,
BOOST_MULTI_INDEX_CK_ENUM(BOOST_MULTI_INDEX_CK_TEMPLATE_PARM,KeyFromValue)
>
struct composite_key:
private tuple<BOOST_MULTI_INDEX_CK_ENUM_PARAMS(KeyFromValue)>
{
private:
typedef tuple<BOOST_MULTI_INDEX_CK_ENUM_PARAMS(KeyFromValue)> super;
public:
typedef super key_extractor_tuple;
typedef Value value_type;
typedef composite_key_result<composite_key> result_type;
composite_key(
BOOST_MULTI_INDEX_CK_ENUM(BOOST_MULTI_INDEX_CK_CTOR_ARG,KeyFromValue)):
super(BOOST_MULTI_INDEX_CK_ENUM_PARAMS(k))
{}
composite_key(const key_extractor_tuple& x):super(x){}
const key_extractor_tuple& key_extractors()const{return *this;}
key_extractor_tuple& key_extractors(){return *this;}
template<typename ChainedPtr>
#if !defined(BOOST_NO_SFINAE)
typename disable_if<
is_convertible<const ChainedPtr&,const value_type&>,result_type>::type
#else
result_type
#endif
operator()(const ChainedPtr& x)const
{
return operator()(*x);
}
result_type operator()(const value_type& x)const
{
return result_type(*this,x);
}
result_type operator()(const reference_wrapper<const value_type>& x)const
{
return result_type(*this,x.get());
}
result_type operator()(const reference_wrapper<value_type>& x,int=0)const
{
return result_type(*this,x.get());
}
};
/* comparison operators */
/* == */
template<typename CompositeKey1,typename CompositeKey2>
inline bool operator==(
const composite_key_result<CompositeKey1>& x,
const composite_key_result<CompositeKey2>& y)
{
typedef typename CompositeKey1::key_extractor_tuple key_extractor_tuple1;
typedef typename CompositeKey1::value_type value_type1;
typedef typename CompositeKey2::key_extractor_tuple key_extractor_tuple2;
typedef typename CompositeKey2::value_type value_type2;
BOOST_STATIC_ASSERT(
tuples::length<key_extractor_tuple1>::value==
tuples::length<key_extractor_tuple2>::value);
return detail::equal_ckey_ckey<
key_extractor_tuple1,value_type1,
key_extractor_tuple2,value_type2,
detail::generic_operator_equal_tuple
>::compare(
x.composite_key.key_extractors(),x.value,
y.composite_key.key_extractors(),y.value,
detail::generic_operator_equal_tuple());
}
template<
typename CompositeKey,
BOOST_MULTI_INDEX_CK_ENUM_PARAMS(typename Value)
>
inline bool operator==(
const composite_key_result<CompositeKey>& x,
const tuple<BOOST_MULTI_INDEX_CK_ENUM_PARAMS(Value)>& y)
{
typedef typename CompositeKey::key_extractor_tuple key_extractor_tuple;
typedef typename CompositeKey::value_type value_type;
typedef tuple<BOOST_MULTI_INDEX_CK_ENUM_PARAMS(Value)> key_tuple;
BOOST_STATIC_ASSERT(
tuples::length<key_extractor_tuple>::value==
tuples::length<key_tuple>::value);
return detail::equal_ckey_cval<
key_extractor_tuple,value_type,
key_tuple,detail::generic_operator_equal_tuple
>::compare(
x.composite_key.key_extractors(),x.value,
y,detail::generic_operator_equal_tuple());
}
template
<
BOOST_MULTI_INDEX_CK_ENUM_PARAMS(typename Value),
typename CompositeKey
>
inline bool operator==(
const tuple<BOOST_MULTI_INDEX_CK_ENUM_PARAMS(Value)>& x,
const composite_key_result<CompositeKey>& y)
{
typedef typename CompositeKey::key_extractor_tuple key_extractor_tuple;
typedef typename CompositeKey::value_type value_type;
typedef tuple<BOOST_MULTI_INDEX_CK_ENUM_PARAMS(Value)> key_tuple;
BOOST_STATIC_ASSERT(
tuples::length<key_extractor_tuple>::value==
tuples::length<key_tuple>::value);
return detail::equal_ckey_cval<
key_extractor_tuple,value_type,
key_tuple,detail::generic_operator_equal_tuple
>::compare(
x,y.composite_key.key_extractors(),
y.value,detail::generic_operator_equal_tuple());
}
/* < */
template<typename CompositeKey1,typename CompositeKey2>
inline bool operator<(
const composite_key_result<CompositeKey1>& x,
const composite_key_result<CompositeKey2>& y)
{
typedef typename CompositeKey1::key_extractor_tuple key_extractor_tuple1;
typedef typename CompositeKey1::value_type value_type1;
typedef typename CompositeKey2::key_extractor_tuple key_extractor_tuple2;
typedef typename CompositeKey2::value_type value_type2;
return detail::compare_ckey_ckey<
key_extractor_tuple1,value_type1,
key_extractor_tuple2,value_type2,
detail::generic_operator_less_tuple
>::compare(
x.composite_key.key_extractors(),x.value,
y.composite_key.key_extractors(),y.value,
detail::generic_operator_less_tuple());
}
template
<
typename CompositeKey,
BOOST_MULTI_INDEX_CK_ENUM_PARAMS(typename Value)
>
inline bool operator<(
const composite_key_result<CompositeKey>& x,
const tuple<BOOST_MULTI_INDEX_CK_ENUM_PARAMS(Value)>& y)
{
typedef typename CompositeKey::key_extractor_tuple key_extractor_tuple;
typedef typename CompositeKey::value_type value_type;
typedef tuple<BOOST_MULTI_INDEX_CK_ENUM_PARAMS(Value)> key_tuple;
return detail::compare_ckey_cval<
key_extractor_tuple,value_type,
key_tuple,detail::generic_operator_less_tuple
>::compare(
x.composite_key.key_extractors(),x.value,
y,detail::generic_operator_less_tuple());
}
template
<
BOOST_MULTI_INDEX_CK_ENUM_PARAMS(typename Value),
typename CompositeKey
>
inline bool operator<(
const tuple<BOOST_MULTI_INDEX_CK_ENUM_PARAMS(Value)>& x,
const composite_key_result<CompositeKey>& y)
{
typedef typename CompositeKey::key_extractor_tuple key_extractor_tuple;
typedef typename CompositeKey::value_type value_type;
typedef tuple<BOOST_MULTI_INDEX_CK_ENUM_PARAMS(Value)> key_tuple;
return detail::compare_ckey_cval<
key_extractor_tuple,value_type,
key_tuple,detail::generic_operator_less_tuple
>::compare(
x,y.composite_key.key_extractors(),
y.value,detail::generic_operator_less_tuple());
}
/* rest of comparison operators */
#define BOOST_MULTI_INDEX_CK_COMPLETE_COMP_OPS(t1,t2,a1,a2) \
template<t1,t2> inline bool operator!=(const a1& x,const a2& y) \
{ \
return !(x==y); \
} \
\
template<t1,t2> inline bool operator>(const a1& x,const a2& y) \
{ \
return y<x; \
} \
\
template<t1,t2> inline bool operator>=(const a1& x,const a2& y) \
{ \
return !(x<y); \
} \
\
template<t1,t2> inline bool operator<=(const a1& x,const a2& y) \
{ \
return !(y<x); \
}
BOOST_MULTI_INDEX_CK_COMPLETE_COMP_OPS(
typename CompositeKey1,
typename CompositeKey2,
composite_key_result<CompositeKey1>,
composite_key_result<CompositeKey2>
)
BOOST_MULTI_INDEX_CK_COMPLETE_COMP_OPS(
typename CompositeKey,
BOOST_MULTI_INDEX_CK_ENUM_PARAMS(typename Value),
composite_key_result<CompositeKey>,
tuple<BOOST_MULTI_INDEX_CK_ENUM_PARAMS(Value)>
)
BOOST_MULTI_INDEX_CK_COMPLETE_COMP_OPS(
BOOST_MULTI_INDEX_CK_ENUM_PARAMS(typename Value),
typename CompositeKey,
tuple<BOOST_MULTI_INDEX_CK_ENUM_PARAMS(Value)>,
composite_key_result<CompositeKey>
)
/* composite_key_equal_to */
template
<
BOOST_MULTI_INDEX_CK_ENUM(BOOST_MULTI_INDEX_CK_TEMPLATE_PARM,Pred)
>
struct composite_key_equal_to:
private tuple<BOOST_MULTI_INDEX_CK_ENUM_PARAMS(Pred)>
{
private:
typedef tuple<BOOST_MULTI_INDEX_CK_ENUM_PARAMS(Pred)> super;
public:
typedef super key_eq_tuple;
composite_key_equal_to(
BOOST_MULTI_INDEX_CK_ENUM(BOOST_MULTI_INDEX_CK_CTOR_ARG,Pred)):
super(BOOST_MULTI_INDEX_CK_ENUM_PARAMS(k))
{}
composite_key_equal_to(const key_eq_tuple& x):super(x){}
const key_eq_tuple& key_eqs()const{return *this;}
key_eq_tuple& key_eqs(){return *this;}
template<typename CompositeKey1,typename CompositeKey2>
bool operator()(
const composite_key_result<CompositeKey1> & x,
const composite_key_result<CompositeKey2> & y)const
{
typedef typename CompositeKey1::key_extractor_tuple key_extractor_tuple1;
typedef typename CompositeKey1::value_type value_type1;
typedef typename CompositeKey2::key_extractor_tuple key_extractor_tuple2;
typedef typename CompositeKey2::value_type value_type2;
BOOST_STATIC_ASSERT(
tuples::length<key_extractor_tuple1>::value<=
tuples::length<key_eq_tuple>::value&&
tuples::length<key_extractor_tuple1>::value==
tuples::length<key_extractor_tuple2>::value);
return detail::equal_ckey_ckey<
key_extractor_tuple1,value_type1,
key_extractor_tuple2,value_type2,
key_eq_tuple
>::compare(
x.composite_key.key_extractors(),x.value,
y.composite_key.key_extractors(),y.value,
key_eqs());
}
template
<
typename CompositeKey,
BOOST_MULTI_INDEX_CK_ENUM_PARAMS(typename Value)
>
bool operator()(
const composite_key_result<CompositeKey>& x,
const tuple<BOOST_MULTI_INDEX_CK_ENUM_PARAMS(Value)>& y)const
{
typedef typename CompositeKey::key_extractor_tuple key_extractor_tuple;
typedef typename CompositeKey::value_type value_type;
typedef tuple<BOOST_MULTI_INDEX_CK_ENUM_PARAMS(Value)> key_tuple;
BOOST_STATIC_ASSERT(
tuples::length<key_extractor_tuple>::value<=
tuples::length<key_eq_tuple>::value&&
tuples::length<key_extractor_tuple>::value==
tuples::length<key_tuple>::value);
return detail::equal_ckey_cval<
key_extractor_tuple,value_type,
key_tuple,key_eq_tuple
>::compare(x.composite_key.key_extractors(),x.value,y,key_eqs());
}
template
<
BOOST_MULTI_INDEX_CK_ENUM_PARAMS(typename Value),
typename CompositeKey
>
bool operator()(
const tuple<BOOST_MULTI_INDEX_CK_ENUM_PARAMS(Value)>& x,
const composite_key_result<CompositeKey>& y)const
{
typedef typename CompositeKey::key_extractor_tuple key_extractor_tuple;
typedef typename CompositeKey::value_type value_type;
typedef tuple<BOOST_MULTI_INDEX_CK_ENUM_PARAMS(Value)> key_tuple;
BOOST_STATIC_ASSERT(
tuples::length<key_tuple>::value<=
tuples::length<key_eq_tuple>::value&&
tuples::length<key_tuple>::value==
tuples::length<key_extractor_tuple>::value);
return detail::equal_ckey_cval<
key_extractor_tuple,value_type,
key_tuple,key_eq_tuple
>::compare(x,y.composite_key.key_extractors(),y.value,key_eqs());
}
};
/* composite_key_compare */
template
<
BOOST_MULTI_INDEX_CK_ENUM(BOOST_MULTI_INDEX_CK_TEMPLATE_PARM,Compare)
>
struct composite_key_compare:
private tuple<BOOST_MULTI_INDEX_CK_ENUM_PARAMS(Compare)>
{
private:
typedef tuple<BOOST_MULTI_INDEX_CK_ENUM_PARAMS(Compare)> super;
public:
typedef super key_comp_tuple;
composite_key_compare(
BOOST_MULTI_INDEX_CK_ENUM(BOOST_MULTI_INDEX_CK_CTOR_ARG,Compare)):
super(BOOST_MULTI_INDEX_CK_ENUM_PARAMS(k))
{}
composite_key_compare(const key_comp_tuple& x):super(x){}
const key_comp_tuple& key_comps()const{return *this;}
key_comp_tuple& key_comps(){return *this;}
template<typename CompositeKey1,typename CompositeKey2>
bool operator()(
const composite_key_result<CompositeKey1> & x,
const composite_key_result<CompositeKey2> & y)const
{
typedef typename CompositeKey1::key_extractor_tuple key_extractor_tuple1;
typedef typename CompositeKey1::value_type value_type1;
typedef typename CompositeKey2::key_extractor_tuple key_extractor_tuple2;
typedef typename CompositeKey2::value_type value_type2;
BOOST_STATIC_ASSERT(
tuples::length<key_extractor_tuple1>::value<=
tuples::length<key_comp_tuple>::value||
tuples::length<key_extractor_tuple2>::value<=
tuples::length<key_comp_tuple>::value);
return detail::compare_ckey_ckey<
key_extractor_tuple1,value_type1,
key_extractor_tuple2,value_type2,
key_comp_tuple
>::compare(
x.composite_key.key_extractors(),x.value,
y.composite_key.key_extractors(),y.value,
key_comps());
}
#if !defined(BOOST_NO_FUNCTION_TEMPLATE_ORDERING)
template<typename CompositeKey,typename Value>
bool operator()(
const composite_key_result<CompositeKey>& x,
const Value& y)const
{
return operator()(x,boost::make_tuple(boost::cref(y)));
}
#endif
template
<
typename CompositeKey,
BOOST_MULTI_INDEX_CK_ENUM_PARAMS(typename Value)
>
bool operator()(
const composite_key_result<CompositeKey>& x,
const tuple<BOOST_MULTI_INDEX_CK_ENUM_PARAMS(Value)>& y)const
{
typedef typename CompositeKey::key_extractor_tuple key_extractor_tuple;
typedef typename CompositeKey::value_type value_type;
typedef tuple<BOOST_MULTI_INDEX_CK_ENUM_PARAMS(Value)> key_tuple;
BOOST_STATIC_ASSERT(
tuples::length<key_extractor_tuple>::value<=
tuples::length<key_comp_tuple>::value||
tuples::length<key_tuple>::value<=
tuples::length<key_comp_tuple>::value);
return detail::compare_ckey_cval<
key_extractor_tuple,value_type,
key_tuple,key_comp_tuple
>::compare(x.composite_key.key_extractors(),x.value,y,key_comps());
}
#if !defined(BOOST_NO_FUNCTION_TEMPLATE_ORDERING)
template<typename Value,typename CompositeKey>
bool operator()(
const Value& x,
const composite_key_result<CompositeKey>& y)const
{
return operator()(boost::make_tuple(boost::cref(x)),y);
}
#endif
template
<
BOOST_MULTI_INDEX_CK_ENUM_PARAMS(typename Value),
typename CompositeKey
>
bool operator()(
const tuple<BOOST_MULTI_INDEX_CK_ENUM_PARAMS(Value)>& x,
const composite_key_result<CompositeKey>& y)const
{
typedef typename CompositeKey::key_extractor_tuple key_extractor_tuple;
typedef typename CompositeKey::value_type value_type;
typedef tuple<BOOST_MULTI_INDEX_CK_ENUM_PARAMS(Value)> key_tuple;
BOOST_STATIC_ASSERT(
tuples::length<key_tuple>::value<=
tuples::length<key_comp_tuple>::value||
tuples::length<key_extractor_tuple>::value<=
tuples::length<key_comp_tuple>::value);
return detail::compare_ckey_cval<
key_extractor_tuple,value_type,
key_tuple,key_comp_tuple
>::compare(x,y.composite_key.key_extractors(),y.value,key_comps());
}
};
/* composite_key_hash */
template
<
BOOST_MULTI_INDEX_CK_ENUM(BOOST_MULTI_INDEX_CK_TEMPLATE_PARM,Hash)
>
struct composite_key_hash:
private tuple<BOOST_MULTI_INDEX_CK_ENUM_PARAMS(Hash)>
{
private:
typedef tuple<BOOST_MULTI_INDEX_CK_ENUM_PARAMS(Hash)> super;
public:
typedef super key_hasher_tuple;
composite_key_hash(
BOOST_MULTI_INDEX_CK_ENUM(BOOST_MULTI_INDEX_CK_CTOR_ARG,Hash)):
super(BOOST_MULTI_INDEX_CK_ENUM_PARAMS(k))
{}
composite_key_hash(const key_hasher_tuple& x):super(x){}
const key_hasher_tuple& key_hash_functions()const{return *this;}
key_hasher_tuple& key_hash_functions(){return *this;}
template<typename CompositeKey>
std::size_t operator()(const composite_key_result<CompositeKey> & x)const
{
typedef typename CompositeKey::key_extractor_tuple key_extractor_tuple;
typedef typename CompositeKey::value_type value_type;
BOOST_STATIC_ASSERT(
tuples::length<key_extractor_tuple>::value==
tuples::length<key_hasher_tuple>::value);
return detail::hash_ckey<
key_extractor_tuple,value_type,
key_hasher_tuple
>::hash(x.composite_key.key_extractors(),x.value,key_hash_functions());
}
template<BOOST_MULTI_INDEX_CK_ENUM_PARAMS(typename Value)>
std::size_t operator()(
const tuple<BOOST_MULTI_INDEX_CK_ENUM_PARAMS(Value)>& x)const
{
typedef tuple<BOOST_MULTI_INDEX_CK_ENUM_PARAMS(Value)> key_tuple;
BOOST_STATIC_ASSERT(
tuples::length<key_tuple>::value==
tuples::length<key_hasher_tuple>::value);
return detail::hash_cval<
key_tuple,key_hasher_tuple
>::hash(x,key_hash_functions());
}
};
/* Instantiations of the former functors with "natural" basic components:
* composite_key_result_equal_to uses std::equal_to of the values.
* composite_key_result_less uses std::less.
* composite_key_result_greater uses std::greater.
* composite_key_result_hash uses boost::hash.
*/
#define BOOST_MULTI_INDEX_CK_RESULT_EQUAL_TO_SUPER \
composite_key_equal_to< \
BOOST_MULTI_INDEX_CK_ENUM( \
BOOST_MULTI_INDEX_CK_APPLY_METAFUNCTION_N, \
/* the argument is a PP list */ \
(detail::nth_composite_key_equal_to, \
(BOOST_DEDUCED_TYPENAME CompositeKeyResult::composite_key_type, \
BOOST_PP_NIL))) \
>
template<typename CompositeKeyResult>
struct composite_key_result_equal_to:
BOOST_MULTI_INDEX_PRIVATE_IF_USING_DECL_FOR_TEMPL_FUNCTIONS
BOOST_MULTI_INDEX_CK_RESULT_EQUAL_TO_SUPER
{
private:
typedef BOOST_MULTI_INDEX_CK_RESULT_EQUAL_TO_SUPER super;
public:
typedef CompositeKeyResult first_argument_type;
typedef first_argument_type second_argument_type;
typedef bool result_type;
using super::operator();
};
#define BOOST_MULTI_INDEX_CK_RESULT_LESS_SUPER \
composite_key_compare< \
BOOST_MULTI_INDEX_CK_ENUM( \
BOOST_MULTI_INDEX_CK_APPLY_METAFUNCTION_N, \
/* the argument is a PP list */ \
(detail::nth_composite_key_less, \
(BOOST_DEDUCED_TYPENAME CompositeKeyResult::composite_key_type, \
BOOST_PP_NIL))) \
>
template<typename CompositeKeyResult>
struct composite_key_result_less:
BOOST_MULTI_INDEX_PRIVATE_IF_USING_DECL_FOR_TEMPL_FUNCTIONS
BOOST_MULTI_INDEX_CK_RESULT_LESS_SUPER
{
private:
typedef BOOST_MULTI_INDEX_CK_RESULT_LESS_SUPER super;
public:
typedef CompositeKeyResult first_argument_type;
typedef first_argument_type second_argument_type;
typedef bool result_type;
using super::operator();
};
#define BOOST_MULTI_INDEX_CK_RESULT_GREATER_SUPER \
composite_key_compare< \
BOOST_MULTI_INDEX_CK_ENUM( \
BOOST_MULTI_INDEX_CK_APPLY_METAFUNCTION_N, \
/* the argument is a PP list */ \
(detail::nth_composite_key_greater, \
(BOOST_DEDUCED_TYPENAME CompositeKeyResult::composite_key_type, \
BOOST_PP_NIL))) \
>
template<typename CompositeKeyResult>
struct composite_key_result_greater:
BOOST_MULTI_INDEX_PRIVATE_IF_USING_DECL_FOR_TEMPL_FUNCTIONS
BOOST_MULTI_INDEX_CK_RESULT_GREATER_SUPER
{
private:
typedef BOOST_MULTI_INDEX_CK_RESULT_GREATER_SUPER super;
public:
typedef CompositeKeyResult first_argument_type;
typedef first_argument_type second_argument_type;
typedef bool result_type;
using super::operator();
};
#define BOOST_MULTI_INDEX_CK_RESULT_HASH_SUPER \
composite_key_hash< \
BOOST_MULTI_INDEX_CK_ENUM( \
BOOST_MULTI_INDEX_CK_APPLY_METAFUNCTION_N, \
/* the argument is a PP list */ \
(detail::nth_composite_key_hash, \
(BOOST_DEDUCED_TYPENAME CompositeKeyResult::composite_key_type, \
BOOST_PP_NIL))) \
>
template<typename CompositeKeyResult>
struct composite_key_result_hash:
BOOST_MULTI_INDEX_PRIVATE_IF_USING_DECL_FOR_TEMPL_FUNCTIONS
BOOST_MULTI_INDEX_CK_RESULT_HASH_SUPER
{
private:
typedef BOOST_MULTI_INDEX_CK_RESULT_HASH_SUPER super;
public:
typedef CompositeKeyResult argument_type;
typedef std::size_t result_type;
using super::operator();
};
} /* namespace multi_index */
} /* namespace boost */
/* Specializations of std::equal_to, std::less, std::greater and boost::hash
* for composite_key_results enabling interoperation with tuples of values.
*/
#if !defined(BOOST_NO_TEMPLATE_PARTIAL_SPECIALIZATION)
namespace std{
template<typename CompositeKey>
struct equal_to<boost::multi_index::composite_key_result<CompositeKey> >:
boost::multi_index::composite_key_result_equal_to<
boost::multi_index::composite_key_result<CompositeKey>
>
{
};
template<typename CompositeKey>
struct less<boost::multi_index::composite_key_result<CompositeKey> >:
boost::multi_index::composite_key_result_less<
boost::multi_index::composite_key_result<CompositeKey>
>
{
};
template<typename CompositeKey>
struct greater<boost::multi_index::composite_key_result<CompositeKey> >:
boost::multi_index::composite_key_result_greater<
boost::multi_index::composite_key_result<CompositeKey>
>
{
};
} /* namespace std */
namespace boost{
template<typename CompositeKey>
struct hash<boost::multi_index::composite_key_result<CompositeKey> >:
boost::multi_index::composite_key_result_hash<
boost::multi_index::composite_key_result<CompositeKey>
>
{
};
} /* namespace boost */
#else
/* Lacking template partial specialization, std::equal_to, std::less and
* std::greater will still work for composite_key_results although without
* tuple interoperability. To achieve the same graceful degrading with
* boost::hash, we define the appropriate hash_value overload.
*/
namespace boost{
#if !defined(BOOST_NO_ARGUMENT_DEPENDENT_LOOKUP)
namespace multi_index{
#endif
template<typename CompositeKey>
inline std::size_t hash_value(
const boost::multi_index::composite_key_result<CompositeKey>& x)
{
boost::multi_index::composite_key_result_hash<
boost::multi_index::composite_key_result<CompositeKey> > h;
return h(x);
}
#if !defined(BOOST_NO_ARGUMENT_DEPENDENT_LOOKUP)
} /* namespace multi_index */
#endif
} /* namespace boost */
#endif
#undef BOOST_MULTI_INDEX_CK_RESULT_HASH_SUPER
#undef BOOST_MULTI_INDEX_CK_RESULT_GREATER_SUPER
#undef BOOST_MULTI_INDEX_CK_RESULT_LESS_SUPER
#undef BOOST_MULTI_INDEX_CK_RESULT_EQUAL_TO_SUPER
#undef BOOST_MULTI_INDEX_CK_COMPLETE_COMP_OPS
#undef BOOST_MULTI_INDEX_CK_IDENTITY_ENUM_MACRO
#undef BOOST_MULTI_INDEX_CK_NTH_COMPOSITE_KEY_FUNCTOR
#undef BOOST_MULTI_INDEX_CK_APPLY_METAFUNCTION_N
#undef BOOST_MULTI_INDEX_CK_CTOR_ARG
#undef BOOST_MULTI_INDEX_CK_TEMPLATE_PARM
#undef BOOST_MULTI_INDEX_CK_ENUM_PARAMS
#undef BOOST_MULTI_INDEX_CK_ENUM
#undef BOOST_MULTI_INDEX_COMPOSITE_KEY_SIZE
#endif