boost/multi_index/detail/hash_index_node.hpp
/* Copyright 2003-2020 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_DETAIL_HASH_INDEX_NODE_HPP #define BOOST_MULTI_INDEX_DETAIL_HASH_INDEX_NODE_HPP #if defined(_MSC_VER) #pragma once #endif #include <boost/config.hpp> /* keep it first to prevent nasty warns in MSVC */ #include <boost/multi_index/detail/allocator_traits.hpp> #include <boost/multi_index/detail/raw_ptr.hpp> #include <utility> namespace boost{ namespace multi_index{ namespace detail{ /* Certain C++ requirements on unordered associative containers (see LWG issue * #579) imply a data structure where nodes are linked in a single list, which * in its turn forces implementors to add additional overhed per node to * associate each with its corresponding bucket. Others resort to storing hash * values, we use an alternative structure providing unconditional O(1) * manipulation, even in situations of unfair hash distribution, plus some * lookup speedups. For unique indices we maintain a doubly linked list of * nodes except that if N is the first node of a bucket its associated * bucket node is embedded between N and the preceding node in the following * manner: * * +---+ +---+ +---+ +---+ * <--+ |<--+ | <--+ |<--+ | * ... | B0| | B1| ... | B1| | B2| ... * | |-+ | +--> | |-+ | +--> * +-+-+ | +---+ +-+-+ | +---+ * | ^ | ^ * | | | | * | +-+ | +-+ * | | | | * v | v | * --+---+---+---+-- --+---+---+---+-- * ... | | B1| | ... | | B2| | ... * --+---+---+---+-- --+---+---+---+-- * * * The fist and last nodes of buckets can be checked with * * first node of a bucket: Npn != N * last node of a bucket: Nnp != N * * (n and p short for ->next(), ->prior(), bucket nodes have prior pointers * only). Pure insert and erase (without lookup) can be unconditionally done * in O(1). * For non-unique indices we add the following additional complexity: when * there is a group of 3 or more equivalent elements, they are linked as * follows: * * +-----------------------+ * | v * +---+ | +---+ +---+ +---+ * | | +-+ | | |<--+ | * | F | | S | ... | P | | L | * | +-->| | | +-+ | | * +---+ +---+ +---+ | +---+ * ^ | * +-----------------------+ * * F, S, P and L are the first, second, penultimate and last node in the * group, respectively (S and P can coincide if the group has size 3.) This * arrangement is used to skip equivalent elements in O(1) when doing lookup, * while preserving O(1) insert/erase. The following invariants identify * special positions (some of the operations have to be carefully implemented * as Xnn is not valid if Xn points to a bucket): * * first node of a bucket: Npnp == N * last node of a bucket: Nnpp == N * first node of a group: Nnp != N && Nnppn == N * second node of a group: Npn != N && Nppnn == N * n-1 node of a group: Nnp != N && Nnnpp == N * last node of a group: Npn != N && Npnnp == N * * The memory overhead is one pointer per bucket plus two pointers per node, * probably unbeatable. The resulting structure is bidirectonally traversable, * though currently we are just providing forward iteration. */ template<typename Allocator> struct hashed_index_node_impl; /* half-header (only prior() pointer) to use for the bucket array */ template<typename Allocator> struct hashed_index_base_node_impl { typedef typename rebind_alloc_for< Allocator,hashed_index_base_node_impl >::type base_allocator; typedef typename rebind_alloc_for< Allocator,hashed_index_node_impl<Allocator> >::type node_allocator; typedef allocator_traits<base_allocator> base_alloc_traits; typedef allocator_traits<node_allocator> node_alloc_traits; typedef typename base_alloc_traits::pointer base_pointer; typedef typename base_alloc_traits::const_pointer const_base_pointer; typedef typename node_alloc_traits::pointer pointer; typedef typename node_alloc_traits::const_pointer const_pointer; typedef typename node_alloc_traits::difference_type difference_type; pointer& prior(){return prior_;} pointer prior()const{return prior_;} private: pointer prior_; }; /* full header (prior() and next()) for the nodes */ template<typename Allocator> struct hashed_index_node_impl:hashed_index_base_node_impl<Allocator> { private: typedef hashed_index_base_node_impl<Allocator> super; public: typedef typename super::base_pointer base_pointer; typedef typename super::const_base_pointer const_base_pointer; typedef typename super::pointer pointer; typedef typename super::const_pointer const_pointer; base_pointer& next(){return next_;} base_pointer next()const{return next_;} static pointer pointer_from(base_pointer x) { return static_cast<pointer>( static_cast<hashed_index_node_impl*>( raw_ptr<super*>(x))); } static base_pointer base_pointer_from(pointer x) { return static_cast<base_pointer>( raw_ptr<hashed_index_node_impl*>(x)); } private: base_pointer next_; }; /* Boost.MultiIndex requires machinery to reverse unlink operations. A simple * way to make a pointer-manipulation function undoable is to templatize * its internal pointer assignments with a functor that, besides doing the * assignment, keeps track of the original pointer values and can later undo * the operations in reverse order. */ struct default_assigner { template<typename T> void operator()(T& x,const T& val){x=val;} }; template<typename Node> struct unlink_undo_assigner { typedef typename Node::base_pointer base_pointer; typedef typename Node::pointer pointer; unlink_undo_assigner():pointer_track_count(0),base_pointer_track_count(0){} void operator()(pointer& x,pointer val) { pointer_tracks[pointer_track_count].x=&x; pointer_tracks[pointer_track_count++].val=x; x=val; } void operator()(base_pointer& x,base_pointer val) { base_pointer_tracks[base_pointer_track_count].x=&x; base_pointer_tracks[base_pointer_track_count++].val=x; x=val; } void operator()() /* undo op */ { /* in the absence of aliasing, restitution order is immaterial */ while(pointer_track_count--){ *(pointer_tracks[pointer_track_count].x)= pointer_tracks[pointer_track_count].val; } while(base_pointer_track_count--){ *(base_pointer_tracks[base_pointer_track_count].x)= base_pointer_tracks[base_pointer_track_count].val; } } struct pointer_track {pointer* x; pointer val;}; struct base_pointer_track{base_pointer* x; base_pointer val;}; /* We know the maximum number of pointer and base pointer assignments that * the two unlink versions do, so we can statically reserve the needed * storage. */ pointer_track pointer_tracks[3]; int pointer_track_count; base_pointer_track base_pointer_tracks[2]; int base_pointer_track_count; }; /* algorithmic stuff for unique and non-unique variants */ struct hashed_unique_tag{}; struct hashed_non_unique_tag{}; template<typename Node,typename Category> struct hashed_index_node_alg; template<typename Node> struct hashed_index_node_alg<Node,hashed_unique_tag> { typedef typename Node::base_pointer base_pointer; typedef typename Node::const_base_pointer const_base_pointer; typedef typename Node::pointer pointer; typedef typename Node::const_pointer const_pointer; static bool is_first_of_bucket(pointer x) { return x->prior()->next()!=base_pointer_from(x); } static pointer after(pointer x) { return is_last_of_bucket(x)?x->next()->prior():pointer_from(x->next()); } static pointer after_local(pointer x) { return is_last_of_bucket(x)?pointer(0):pointer_from(x->next()); } static pointer next_to_inspect(pointer x) { return is_last_of_bucket(x)?pointer(0):pointer_from(x->next()); } static void link(pointer x,base_pointer buc,pointer end) { if(buc->prior()==pointer(0)){ /* empty bucket */ x->prior()=end->prior(); x->next()=end->prior()->next(); x->prior()->next()=buc; buc->prior()=x; end->prior()=x; } else{ x->prior()=buc->prior()->prior(); x->next()=base_pointer_from(buc->prior()); buc->prior()=x; x->next()->prior()=x; } } static void unlink(pointer x) { default_assigner assign; unlink(x,assign); } typedef unlink_undo_assigner<Node> unlink_undo; template<typename Assigner> static void unlink(pointer x,Assigner& assign) { if(is_first_of_bucket(x)){ if(is_last_of_bucket(x)){ assign(x->prior()->next()->prior(),pointer(0)); assign(x->prior()->next(),x->next()); assign(x->next()->prior()->prior(),x->prior()); } else{ assign(x->prior()->next()->prior(),pointer_from(x->next())); assign(x->next()->prior(),x->prior()); } } else if(is_last_of_bucket(x)){ assign(x->prior()->next(),x->next()); assign(x->next()->prior()->prior(),x->prior()); } else{ assign(x->prior()->next(),x->next()); assign(x->next()->prior(),x->prior()); } } /* used only at rehashing */ static void append(pointer x,pointer end) { x->prior()=end->prior(); x->next()=end->prior()->next(); x->prior()->next()=base_pointer_from(x); end->prior()=x; } static bool unlink_last(pointer end) { /* returns true iff bucket is emptied */ pointer x=end->prior(); if(x->prior()->next()==base_pointer_from(x)){ x->prior()->next()=x->next(); end->prior()=x->prior(); return false; } else{ x->prior()->next()->prior()=pointer(0); x->prior()->next()=x->next(); end->prior()=x->prior(); return true; } } private: static pointer pointer_from(base_pointer x) { return Node::pointer_from(x); } static base_pointer base_pointer_from(pointer x) { return Node::base_pointer_from(x); } static bool is_last_of_bucket(pointer x) { return x->next()->prior()!=x; } }; template<typename Node> struct hashed_index_node_alg<Node,hashed_non_unique_tag> { typedef typename Node::base_pointer base_pointer; typedef typename Node::const_base_pointer const_base_pointer; typedef typename Node::pointer pointer; typedef typename Node::const_pointer const_pointer; static bool is_first_of_bucket(pointer x) { return x->prior()->next()->prior()==x; } static bool is_first_of_group(pointer x) { return x->next()->prior()!=x&& x->next()->prior()->prior()->next()==base_pointer_from(x); } static pointer after(pointer x) { if(x->next()->prior()==x)return pointer_from(x->next()); if(x->next()->prior()->prior()==x)return x->next()->prior(); if(x->next()->prior()->prior()->next()==base_pointer_from(x)) return pointer_from(x->next()); return pointer_from(x->next())->next()->prior(); } static pointer after_local(pointer x) { if(x->next()->prior()==x)return pointer_from(x->next()); if(x->next()->prior()->prior()==x)return pointer(0); if(x->next()->prior()->prior()->next()==base_pointer_from(x)) return pointer_from(x->next()); return pointer_from(x->next())->next()->prior(); } static pointer next_to_inspect(pointer x) { if(x->next()->prior()==x)return pointer_from(x->next()); if(x->next()->prior()->prior()==x)return pointer(0); if(x->next()->prior()->next()->prior()!=x->next()->prior()) return pointer(0); return pointer_from(x->next()->prior()->next()); } static void link(pointer x,base_pointer buc,pointer end) { if(buc->prior()==pointer(0)){ /* empty bucket */ x->prior()=end->prior(); x->next()=end->prior()->next(); x->prior()->next()=buc; buc->prior()=x; end->prior()=x; } else{ x->prior()=buc->prior()->prior(); x->next()=base_pointer_from(buc->prior()); buc->prior()=x; x->next()->prior()=x; } } static void link(pointer x,pointer first,pointer last) { x->prior()=first->prior(); x->next()=base_pointer_from(first); if(is_first_of_bucket(first)){ x->prior()->next()->prior()=x; } else{ x->prior()->next()=base_pointer_from(x); } if(first==last){ last->prior()=x; } else if(first->next()==base_pointer_from(last)){ first->prior()=last; first->next()=base_pointer_from(x); } else{ pointer second=pointer_from(first->next()), lastbutone=last->prior(); second->prior()=first; first->prior()=last; lastbutone->next()=base_pointer_from(x); } } static void unlink(pointer x) { default_assigner assign; unlink(x,assign); } typedef unlink_undo_assigner<Node> unlink_undo; template<typename Assigner> static void unlink(pointer x,Assigner& assign) { if(x->prior()->next()==base_pointer_from(x)){ if(x->next()->prior()==x){ left_unlink(x,assign); right_unlink(x,assign); } else if(x->next()->prior()->prior()==x){ /* last of bucket */ left_unlink(x,assign); right_unlink_last_of_bucket(x,assign); } else if(x->next()->prior()->prior()->next()== base_pointer_from(x)){ /* first of group size */ left_unlink(x,assign); right_unlink_first_of_group(x,assign); } else{ /* n-1 of group */ unlink_last_but_one_of_group(x,assign); } } else if(x->prior()->next()->prior()==x){ /* first of bucket */ if(x->next()->prior()==x){ left_unlink_first_of_bucket(x,assign); right_unlink(x,assign); } else if(x->next()->prior()->prior()==x){ /* last of bucket */ assign(x->prior()->next()->prior(),pointer(0)); assign(x->prior()->next(),x->next()); assign(x->next()->prior()->prior(),x->prior()); } else{ /* first of group */ left_unlink_first_of_bucket(x,assign); right_unlink_first_of_group(x,assign); } } else if(x->next()->prior()->prior()==x){ /* last of group and bucket */ left_unlink_last_of_group(x,assign); right_unlink_last_of_bucket(x,assign); } else if(pointer_from(x->prior()->prior()->next()) ->next()==base_pointer_from(x)){ /* second of group */ unlink_second_of_group(x,assign); } else{ /* last of group, ~(last of bucket) */ left_unlink_last_of_group(x,assign); right_unlink(x,assign); } } /* used only at rehashing */ static void link_range( pointer first,pointer last,base_pointer buc,pointer cend) { if(buc->prior()==pointer(0)){ /* empty bucket */ first->prior()=cend->prior(); last->next()=cend->prior()->next(); first->prior()->next()=buc; buc->prior()=first; cend->prior()=last; } else{ first->prior()=buc->prior()->prior(); last->next()=base_pointer_from(buc->prior()); buc->prior()=first; last->next()->prior()=last; } } static void append_range(pointer first,pointer last,pointer cend) { first->prior()=cend->prior(); last->next()=cend->prior()->next(); first->prior()->next()=base_pointer_from(first); cend->prior()=last; } static std::pair<pointer,bool> unlink_last_group(pointer end) { /* returns first of group true iff bucket is emptied */ pointer x=end->prior(); if(x->prior()->next()==base_pointer_from(x)){ x->prior()->next()=x->next(); end->prior()=x->prior(); return std::make_pair(x,false); } else if(x->prior()->next()->prior()==x){ x->prior()->next()->prior()=pointer(0); x->prior()->next()=x->next(); end->prior()=x->prior(); return std::make_pair(x,true); } else{ pointer y=pointer_from(x->prior()->next()); if(y->prior()->next()==base_pointer_from(y)){ y->prior()->next()=x->next(); end->prior()=y->prior(); return std::make_pair(y,false); } else{ y->prior()->next()->prior()=pointer(0); y->prior()->next()=x->next(); end->prior()=y->prior(); return std::make_pair(y,true); } } } static void unlink_range(pointer first,pointer last) { if(is_first_of_bucket(first)){ if(is_last_of_bucket(last)){ first->prior()->next()->prior()=pointer(0); first->prior()->next()=last->next(); last->next()->prior()->prior()=first->prior(); } else{ first->prior()->next()->prior()=pointer_from(last->next()); last->next()->prior()=first->prior(); } } else if(is_last_of_bucket(last)){ first->prior()->next()=last->next(); last->next()->prior()->prior()=first->prior(); } else{ first->prior()->next()=last->next(); last->next()->prior()=first->prior(); } } private: static pointer pointer_from(base_pointer x) { return Node::pointer_from(x); } static base_pointer base_pointer_from(pointer x) { return Node::base_pointer_from(x); } static bool is_last_of_bucket(pointer x) { return x->next()->prior()->prior()==x; } template<typename Assigner> static void left_unlink(pointer x,Assigner& assign) { assign(x->prior()->next(),x->next()); } template<typename Assigner> static void right_unlink(pointer x,Assigner& assign) { assign(x->next()->prior(),x->prior()); } template<typename Assigner> static void left_unlink_first_of_bucket(pointer x,Assigner& assign) { assign(x->prior()->next()->prior(),pointer_from(x->next())); } template<typename Assigner> static void right_unlink_last_of_bucket(pointer x,Assigner& assign) { assign(x->next()->prior()->prior(),x->prior()); } template<typename Assigner> static void right_unlink_first_of_group(pointer x,Assigner& assign) { pointer second=pointer_from(x->next()), last=second->prior(), lastbutone=last->prior(); if(second==lastbutone){ assign(second->next(),base_pointer_from(last)); assign(second->prior(),x->prior()); } else{ assign(lastbutone->next(),base_pointer_from(second)); assign(second->next()->prior(),last); assign(second->prior(),x->prior()); } } template<typename Assigner> static void left_unlink_last_of_group(pointer x,Assigner& assign) { pointer lastbutone=x->prior(), first=pointer_from(lastbutone->next()), second=pointer_from(first->next()); if(lastbutone==second){ assign(lastbutone->prior(),first); assign(lastbutone->next(),x->next()); } else{ assign(second->prior(),lastbutone); assign(lastbutone->prior()->next(),base_pointer_from(first)); assign(lastbutone->next(),x->next()); } } template<typename Assigner> static void unlink_last_but_one_of_group(pointer x,Assigner& assign) { pointer first=pointer_from(x->next()), second=pointer_from(first->next()), last=second->prior(); if(second==x){ assign(last->prior(),first); assign(first->next(),base_pointer_from(last)); } else{ assign(last->prior(),x->prior()); assign(x->prior()->next(),base_pointer_from(first)); } } template<typename Assigner> static void unlink_second_of_group(pointer x,Assigner& assign) { pointer last=x->prior(), lastbutone=last->prior(), first=pointer_from(lastbutone->next()); if(lastbutone==x){ assign(first->next(),base_pointer_from(last)); assign(last->prior(),first); } else{ assign(first->next(),x->next()); assign(x->next()->prior(),last); } } }; template<typename Super> struct hashed_index_node_trampoline: hashed_index_node_impl< typename rebind_alloc_for< typename Super::allocator_type,char >::type > { typedef typename rebind_alloc_for< typename Super::allocator_type,char >::type impl_allocator_type; typedef hashed_index_node_impl<impl_allocator_type> impl_type; }; template<typename Super> struct hashed_index_node: Super,hashed_index_node_trampoline<Super> { private: typedef hashed_index_node_trampoline<Super> trampoline; public: typedef typename trampoline::impl_type impl_type; typedef typename trampoline::base_pointer impl_base_pointer; typedef typename trampoline::const_base_pointer const_impl_base_pointer; typedef typename trampoline::pointer impl_pointer; typedef typename trampoline::const_pointer const_impl_pointer; typedef typename trampoline::difference_type difference_type; template<typename Category> struct node_alg{ typedef hashed_index_node_alg<impl_type,Category> type; }; impl_pointer& prior(){return trampoline::prior();} impl_pointer prior()const{return trampoline::prior();} impl_base_pointer& next(){return trampoline::next();} impl_base_pointer next()const{return trampoline::next();} impl_pointer impl() { return static_cast<impl_pointer>( static_cast<impl_type*>(static_cast<trampoline*>(this))); } const_impl_pointer impl()const { return static_cast<const_impl_pointer>( static_cast<const impl_type*>(static_cast<const trampoline*>(this))); } static hashed_index_node* from_impl(impl_pointer x) { return static_cast<hashed_index_node*>( static_cast<trampoline*>( raw_ptr<impl_type*>(x))); } static const hashed_index_node* from_impl(const_impl_pointer x) { return static_cast<const hashed_index_node*>( static_cast<const trampoline*>( raw_ptr<const impl_type*>(x))); } /* interoperability with hashed_index_iterator */ template<typename Category> static void increment(hashed_index_node*& x) { x=from_impl(node_alg<Category>::type::after(x->impl())); } template<typename Category> static void increment_local(hashed_index_node*& x) { x=from_impl(node_alg<Category>::type::after_local(x->impl())); } }; } /* namespace multi_index::detail */ } /* namespace multi_index */ } /* namespace boost */ #endif