boost/unordered/detail/equivalent.hpp
// Copyright (C) 2003-2004 Jeremy B. Maitin-Shepard. // Copyright (C) 2005-2011 Daniel James // 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_UNORDERED_DETAIL_EQUIVALENT_HPP_INCLUDED #define BOOST_UNORDERED_DETAIL_EQUIVALENT_HPP_INCLUDED #include <boost/config.hpp> #if defined(BOOST_HAS_PRAGMA_ONCE) #pragma once #endif #include <boost/unordered/detail/extract_key.hpp> namespace boost { namespace unordered { namespace detail { template <typename A, typename T> struct grouped_node; template <typename T> struct grouped_ptr_node; template <typename Types> struct grouped_table_impl; template <typename A, typename T> struct grouped_node : boost::unordered::detail::value_base<T> { typedef typename ::boost::unordered::detail::rebind_wrap< A, grouped_node<A, T> >::type allocator; typedef typename ::boost::unordered::detail:: allocator_traits<allocator>::pointer node_pointer; typedef node_pointer link_pointer; link_pointer next_; node_pointer group_prev_; std::size_t hash_; grouped_node() : next_(), group_prev_(), hash_(0) {} void init(node_pointer self) { group_prev_ = self; } private: grouped_node& operator=(grouped_node const&); }; template <typename T> struct grouped_ptr_node : boost::unordered::detail::ptr_bucket { typedef T value_type; typedef boost::unordered::detail::ptr_bucket bucket_base; typedef grouped_ptr_node<T>* node_pointer; typedef ptr_bucket* link_pointer; node_pointer group_prev_; std::size_t hash_; boost::unordered::detail::value_base<T> value_base_; grouped_ptr_node() : bucket_base(), group_prev_(0), hash_(0) {} void init(node_pointer self) { group_prev_ = self; } void* address() { return value_base_.address(); } value_type& value() { return value_base_.value(); } value_type* value_ptr() { return value_base_.value_ptr(); } private: grouped_ptr_node& operator=(grouped_ptr_node const&); }; // If the allocator uses raw pointers use grouped_ptr_node // Otherwise use grouped_node. template <typename A, typename T, typename NodePtr, typename BucketPtr> struct pick_grouped_node2 { typedef boost::unordered::detail::grouped_node<A, T> node; typedef typename boost::unordered::detail::allocator_traits< typename boost::unordered::detail::rebind_wrap<A, node>::type >::pointer node_pointer; typedef boost::unordered::detail::bucket<node_pointer> bucket; typedef node_pointer link_pointer; }; template <typename A, typename T> struct pick_grouped_node2<A, T, boost::unordered::detail::grouped_ptr_node<T>*, boost::unordered::detail::ptr_bucket*> { typedef boost::unordered::detail::grouped_ptr_node<T> node; typedef boost::unordered::detail::ptr_bucket bucket; typedef bucket* link_pointer; }; template <typename A, typename T> struct pick_grouped_node { typedef boost::unordered::detail::allocator_traits< typename boost::unordered::detail::rebind_wrap<A, boost::unordered::detail::grouped_ptr_node<T> >::type > tentative_node_traits; typedef boost::unordered::detail::allocator_traits< typename boost::unordered::detail::rebind_wrap<A, boost::unordered::detail::ptr_bucket >::type > tentative_bucket_traits; typedef pick_grouped_node2<A, T, typename tentative_node_traits::pointer, typename tentative_bucket_traits::pointer> pick; typedef typename pick::node node; typedef typename pick::bucket bucket; typedef typename pick::link_pointer link_pointer; }; template <typename Types> struct grouped_table_impl : boost::unordered::detail::table<Types> { typedef boost::unordered::detail::table<Types> table; typedef typename table::value_type value_type; typedef typename table::bucket bucket; typedef typename table::policy policy; typedef typename table::node_pointer node_pointer; typedef typename table::node_allocator node_allocator; typedef typename table::node_allocator_traits node_allocator_traits; typedef typename table::bucket_pointer bucket_pointer; typedef typename table::link_pointer link_pointer; typedef typename table::hasher hasher; typedef typename table::key_equal key_equal; typedef typename table::key_type key_type; typedef typename table::node_constructor node_constructor; typedef typename table::node_tmp node_tmp; typedef typename table::extractor extractor; typedef typename table::iterator iterator; typedef typename table::c_iterator c_iterator; // Constructors grouped_table_impl(std::size_t n, hasher const& hf, key_equal const& eq, node_allocator const& a) : table(n, hf, eq, a) {} grouped_table_impl(grouped_table_impl const& x) : table(x, node_allocator_traits:: select_on_container_copy_construction(x.node_alloc())) { this->init(x); } grouped_table_impl(grouped_table_impl const& x, node_allocator const& a) : table(x, a) { this->init(x); } grouped_table_impl(grouped_table_impl& x, boost::unordered::detail::move_tag m) : table(x, m) {} grouped_table_impl(grouped_table_impl& x, node_allocator const& a, boost::unordered::detail::move_tag m) : table(x, a, m) { this->move_init(x); } // Accessors template <class Key, class Pred> iterator find_node_impl( std::size_t key_hash, Key const& k, Pred const& eq) const { std::size_t bucket_index = this->hash_to_bucket(key_hash); iterator n = this->begin(bucket_index); for (;;) { if (!n.node_) return n; std::size_t node_hash = n.node_->hash_; if (key_hash == node_hash) { if (eq(k, this->get_key(*n))) return n; } else { if (this->hash_to_bucket(node_hash) != bucket_index) return iterator(); } n = iterator(n.node_->group_prev_->next_); } } std::size_t count(key_type const& k) const { iterator n = this->find_node(k); if (!n.node_) return 0; std::size_t x = 0; node_pointer it = n.node_; do { it = it->group_prev_; ++x; } while(it != n.node_); return x; } std::pair<iterator, iterator> equal_range(key_type const& k) const { iterator n = this->find_node(k); return std::make_pair( n, n.node_ ? iterator(n.node_->group_prev_->next_) : n); } // Equality bool equals(grouped_table_impl const& other) const { if(this->size_ != other.size_) return false; for(iterator n1 = this->begin(); n1.node_;) { iterator n2 = other.find_matching_node(n1); if (!n2.node_) return false; iterator end1(n1.node_->group_prev_->next_); iterator end2(n2.node_->group_prev_->next_); if (!group_equals(n1, end1, n2, end2)) return false; n1 = end1; } return true; } static bool group_equals(iterator n1, iterator end1, iterator n2, iterator end2) { for(;;) { if (*n1 != *n2) break; ++n1; ++n2; if (n1 == end1) return n2 == end2; if (n2 == end2) return false; } for(iterator n1a = n1, n2a = n2;;) { ++n1a; ++n2a; if (n1a == end1) { if (n2a == end2) break; else return false; } if (n2a == end2) return false; } iterator start = n1; for(;n1 != end1; ++n1) { value_type const& v = *n1; if (find(start, n1, v)) continue; std::size_t matches = count_equal(n2, end2, v); if (!matches) return false; iterator next = n1; ++next; if (matches != 1 + count_equal(next, end1, v)) return false; } return true; } static bool find(iterator n, iterator end, value_type const& v) { for(;n != end; ++n) if (*n == v) return true; return false; } static std::size_t count_equal(iterator n, iterator end, value_type const& v) { std::size_t count = 0; for(;n != end; ++n) if (*n == v) ++count; return count; } // Emplace/Insert static inline void add_after_node( node_pointer n, node_pointer pos) { n->next_ = pos->group_prev_->next_; n->group_prev_ = pos->group_prev_; pos->group_prev_->next_ = n; pos->group_prev_ = n; } inline iterator add_node( node_pointer n, std::size_t key_hash, iterator pos) { n->hash_ = key_hash; if (pos.node_) { this->add_after_node(n, pos.node_); if (n->next_) { std::size_t next_bucket = this->hash_to_bucket( static_cast<node_pointer>(n->next_)->hash_); if (next_bucket != this->hash_to_bucket(key_hash)) { this->get_bucket(next_bucket)->next_ = n; } } } else { bucket_pointer b = this->get_bucket( this->hash_to_bucket(key_hash)); if (!b->next_) { link_pointer start_node = this->get_previous_start(); if (start_node->next_) { this->get_bucket(this->hash_to_bucket( static_cast<node_pointer>(start_node->next_)->hash_ ))->next_ = n; } b->next_ = start_node; n->next_ = start_node->next_; start_node->next_ = n; } else { n->next_ = b->next_->next_; b->next_->next_ = n; } } ++this->size_; return iterator(n); } iterator emplace_impl(node_pointer n) { node_tmp a(n, this->node_alloc()); key_type const& k = this->get_key(a.node_->value()); std::size_t key_hash = this->hash(k); iterator position = this->find_node(key_hash, k); this->reserve_for_insert(this->size_ + 1); return this->add_node(a.release(), key_hash, position); } void emplace_impl_no_rehash(node_pointer n) { node_tmp a(n, this->node_alloc()); key_type const& k = this->get_key(a.node_->value()); std::size_t key_hash = this->hash(k); iterator position = this->find_node(key_hash, k); this->add_node(a.release(), key_hash, position); } #if defined(BOOST_NO_CXX11_RVALUE_REFERENCES) # if defined(BOOST_NO_CXX11_VARIADIC_TEMPLATES) iterator emplace(boost::unordered::detail::emplace_args1< boost::unordered::detail::please_ignore_this_overload> const&) { BOOST_ASSERT(false); return iterator(); } # else iterator emplace( boost::unordered::detail::please_ignore_this_overload const&) { BOOST_ASSERT(false); return iterator(); } # endif #endif template <BOOST_UNORDERED_EMPLACE_TEMPLATE> iterator emplace(BOOST_UNORDERED_EMPLACE_ARGS) { return iterator(emplace_impl( boost::unordered::detail::func::construct_value_generic( this->node_alloc(), BOOST_UNORDERED_EMPLACE_FORWARD))); } //////////////////////////////////////////////////////////////////////// // Insert range methods // if hash function throws, or inserting > 1 element, basic exception // safety. Strong otherwise template <class I> void insert_range(I i, I j, typename boost::unordered::detail::enable_if_forward<I, void*>::type = 0) { if(i == j) return; std::size_t distance = std::distance(i, j); if(distance == 1) { emplace_impl( boost::unordered::detail::func::construct_value( this->node_alloc(), *i)); } else { // Only require basic exception safety here this->reserve_for_insert(this->size_ + distance); for (; i != j; ++i) { emplace_impl_no_rehash( boost::unordered::detail::func::construct_value( this->node_alloc(), *i)); } } } template <class I> void insert_range(I i, I j, typename boost::unordered::detail::disable_if_forward<I, void*>::type = 0) { for (; i != j; ++i) { emplace_impl( boost::unordered::detail::func::construct_value( this->node_alloc(), *i)); } } //////////////////////////////////////////////////////////////////////// // Erase // // no throw std::size_t erase_key(key_type const& k) { if(!this->size_) return 0; std::size_t key_hash = this->hash(k); std::size_t bucket_index = this->hash_to_bucket(key_hash); link_pointer prev = this->get_previous_start(bucket_index); if (!prev) return 0; for (;;) { if (!prev->next_) return 0; std::size_t node_hash = static_cast<node_pointer>(prev->next_)->hash_; if (this->hash_to_bucket(node_hash) != bucket_index) return 0; if (node_hash == key_hash && this->key_eq()(k, this->get_key( static_cast<node_pointer>(prev->next_)->value()))) break; prev = static_cast<node_pointer>(prev->next_)->group_prev_; } node_pointer first_node = static_cast<node_pointer>(prev->next_); link_pointer end = first_node->group_prev_->next_; std::size_t deleted_count = this->delete_nodes(prev, end); this->fix_bucket(bucket_index, prev); return deleted_count; } iterator erase(c_iterator r) { BOOST_ASSERT(r.node_); iterator next(r.node_); ++next; erase_nodes(r.node_, next.node_); return next; } iterator erase_range(c_iterator r1, c_iterator r2) { if (r1 == r2) return iterator(r2.node_); erase_nodes(r1.node_, r2.node_); return iterator(r2.node_); } link_pointer erase_nodes(node_pointer i, node_pointer j) { std::size_t bucket_index = this->hash_to_bucket(i->hash_); // Split the groups containing 'i' and 'j'. // And get the pointer to the node before i while // we're at it. link_pointer prev = split_groups(i, j); // If we don't have a 'prev' it means that i is at the // beginning of a block, so search through the blocks in the // same bucket. if (!prev) { prev = this->get_previous_start(bucket_index); while (prev->next_ != i) prev = static_cast<node_pointer>(prev->next_)->group_prev_; } // Delete the nodes. do { link_pointer group_end = static_cast<node_pointer>(prev->next_)->group_prev_->next_; this->delete_nodes(prev, group_end); bucket_index = this->fix_bucket(bucket_index, prev); } while(prev->next_ != j); return prev; } static link_pointer split_groups(node_pointer i, node_pointer j) { node_pointer prev = i->group_prev_; if (prev->next_ != i) prev = node_pointer(); if (j) { node_pointer first = j; while (first != i && first->group_prev_->next_ == first) { first = first->group_prev_; } boost::swap(first->group_prev_, j->group_prev_); if (first == i) return prev; } if (prev) { node_pointer first = prev; while (first->group_prev_->next_ == first) { first = first->group_prev_; } boost::swap(first->group_prev_, i->group_prev_); } return prev; } //////////////////////////////////////////////////////////////////////// // fill_buckets void copy_buckets(table const& src) { this->create_buckets(this->bucket_count_); for (iterator n = src.begin(); n.node_;) { std::size_t key_hash = n.node_->hash_; iterator group_end(n.node_->group_prev_->next_); iterator pos = this->add_node( boost::unordered::detail::func::construct_value( this->node_alloc(), *n), key_hash, iterator()); for (++n; n != group_end; ++n) { this->add_node( boost::unordered::detail::func::construct_value( this->node_alloc(), *n), key_hash, pos); } } } void move_buckets(table const& src) { this->create_buckets(this->bucket_count_); for (iterator n = src.begin(); n.node_;) { std::size_t key_hash = n.node_->hash_; iterator group_end(n.node_->group_prev_->next_); iterator pos = this->add_node( boost::unordered::detail::func::construct_value( this->node_alloc(), boost::move(*n)), key_hash, iterator()); for (++n; n != group_end; ++n) { this->add_node( boost::unordered::detail::func::construct_value( this->node_alloc(), boost::move(*n)), key_hash, pos); } } } void assign_buckets(table const& src) { node_holder<node_allocator> holder(*this); for (iterator n = src.begin(); n.node_;) { std::size_t key_hash = n.node_->hash_; iterator group_end(n.node_->group_prev_->next_); iterator pos = this->add_node(holder.copy_of(*n), key_hash, iterator()); for (++n; n != group_end; ++n) { this->add_node(holder.copy_of(*n), key_hash, pos); } } } void move_assign_buckets(table& src) { node_holder<node_allocator> holder(*this); for (iterator n = src.begin(); n.node_;) { std::size_t key_hash = n.node_->hash_; iterator group_end(n.node_->group_prev_->next_); iterator pos = this->add_node(holder.move_copy_of(*n), key_hash, iterator()); for (++n; n != group_end; ++n) { this->add_node(holder.move_copy_of(*n), key_hash, pos); } } } // strong otherwise exception safety void rehash_impl(std::size_t num_buckets) { BOOST_ASSERT(this->buckets_); this->create_buckets(num_buckets); link_pointer prev = this->get_previous_start(); while (prev->next_) prev = place_in_bucket(*this, prev, static_cast<node_pointer>(prev->next_)->group_prev_); } // Iterate through the nodes placing them in the correct buckets. // pre: prev->next_ is not null. static link_pointer place_in_bucket(table& dst, link_pointer prev, node_pointer end) { bucket_pointer b = dst.get_bucket(dst.hash_to_bucket(end->hash_)); if (!b->next_) { b->next_ = prev; return end; } else { link_pointer next = end->next_; end->next_ = b->next_->next_; b->next_->next_ = prev->next_; prev->next_ = next; return prev; } } }; }}} #endif