forked from OctaForge/libostd
655 lines
21 KiB
C++
655 lines
21 KiB
C++
/* Internal hash table implementation. Used as a base for set, map etc.
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*
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* This file is part of OctaSTD. See COPYING.md for futher information.
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*/
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#ifndef OSTD_INTERNAL_HASHTABLE_HH
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#define OSTD_INTERNAL_HASHTABLE_HH
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#include <string.h>
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#include <math.h>
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#include "ostd/types.hh"
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#include "ostd/utility.hh"
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#include "ostd/memory.hh"
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#include "ostd/range.hh"
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#include "ostd/initializer_list.hh"
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namespace ostd {
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namespace detail {
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template<typename T>
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struct HashChain {
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HashChain<T> *prev;
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HashChain<T> *next;
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T value;
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};
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template<typename R>
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static inline Size estimate_hrsize(const R &range,
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EnableIf<IsFiniteRandomAccessRange<R>::value, bool> = true
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) {
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return range.size();
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}
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template<typename R>
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static inline Size estimate_hrsize(const R &,
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EnableIf<!IsFiniteRandomAccessRange<R>::value, bool> = true
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) {
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/* we have no idea how big the range actually is */
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return 16;
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}
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}
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template<typename T>
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struct HashRange: InputRange<HashRange<T>, ForwardRangeTag, T> {
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private:
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template<typename U>
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friend struct HashRange;
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using Chain = detail::HashChain<T>;
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Chain *p_node;
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public:
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HashRange(): p_node(nullptr) {}
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HashRange(const HashRange &v): p_node(v.p_node) {}
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HashRange(Chain *node): p_node(node) {}
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template<typename U>
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HashRange(const HashRange<U> &v, EnableIf<
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IsSame<RemoveCv<T>, RemoveCv<U>>::value &&
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IsConvertible<U *, T *>::value, bool
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> = true): p_node((Chain *)v.p_node) {}
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HashRange &operator=(const HashRange &v) {
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p_node = v.p_node;
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return *this;
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}
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bool empty() const { return !p_node; }
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bool pop_front() {
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if (!p_node) return false;
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p_node = p_node->next;
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return true;
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}
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bool equals_front(const HashRange &v) const {
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return p_node == v.p_node;
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}
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T &front() const { return p_node->value; }
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};
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template<typename T>
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struct BucketRange: InputRange<BucketRange<T>, ForwardRangeTag, T> {
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private:
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template<typename U>
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friend struct BucketRange;
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using Chain = detail::HashChain<T>;
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Chain *p_node, *p_end;
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public:
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BucketRange(): p_node(nullptr) {}
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BucketRange(Chain *node, Chain *end): p_node(node), p_end(end) {}
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BucketRange(const BucketRange &v): p_node(v.p_node), p_end(v.p_end) {}
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template<typename U>
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BucketRange(const BucketRange<U> &v, EnableIf<
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IsSame<RemoveCv<T>, RemoveCv<U>>::value &&
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IsConvertible<U *, T *>::value, bool
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> = true): p_node((Chain *)v.p_node), p_end((Chain *)v.p_end) {}
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BucketRange &operator=(const BucketRange &v) {
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p_node = v.p_node;
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p_end = v.p_end;
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return *this;
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}
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bool empty() const { return p_node == p_end; }
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bool pop_front() {
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if (p_node == p_end) return false;
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p_node = p_node->next;
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return true;
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}
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bool equals_front(const BucketRange &v) const {
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return p_node == v.p_node;
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}
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T &front() const { return p_node->value; }
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};
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namespace detail {
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/* Use template metaprogramming to figure out a correct number
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* of elements to use per chunk for proper cache alignment
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* (i.e. sizeof(Chunk) % CACHE_LINE_SIZE == 0).
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*
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* If this is not possible, use the upper bound and pad the
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* structure with some extra bytes.
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*/
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static constexpr Size CACHE_LINE_SIZE = 64;
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static constexpr Size CHUNK_LOWER_BOUND = 32;
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static constexpr Size CHUNK_UPPER_BOUND = 128;
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template<typename E, Size N>
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struct HashChainAlign {
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static constexpr Size csize = sizeof(HashChain<E>[N]) + sizeof(void *);
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static constexpr Size value = ((csize % CACHE_LINE_SIZE) == 0)
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? N : HashChainAlign<E, N + 1>::value;
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};
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template<typename E>
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struct HashChainAlign<E, CHUNK_UPPER_BOUND> {
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static constexpr Size value = CHUNK_UPPER_BOUND;
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};
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template<Size N, bool B>
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struct HashChainPad;
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template<Size N>
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struct HashChainPad<N, true> {};
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template<Size N>
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struct HashChainPad<N, false> {
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byte pad[CACHE_LINE_SIZE - (N % CACHE_LINE_SIZE)];
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};
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template<Size N>
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struct HashPad: HashChainPad<N, N % CACHE_LINE_SIZE == 0> {};
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template<typename E, Size V = HashChainAlign<E, CHUNK_LOWER_BOUND>::value,
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bool P = (V == CHUNK_UPPER_BOUND)
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> struct HashChunk;
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template<typename E, Size V>
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struct HashChunk<E, V, false> {
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static constexpr Size num = V;
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HashChain<E> chains[num];
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HashChunk *next;
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};
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template<typename E, Size V>
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struct HashChunk<E, V, true>: HashPad<
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sizeof(HashChain<E>[V]) + sizeof(void *)
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> {
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static constexpr Size num = V;
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HashChain<E> chains[num];
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HashChunk *next;
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};
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template<
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typename B, /* contains methods specific to each ht type */
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typename E, /* element type */
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typename K, /* key type */
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typename T, /* value type */
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typename H, /* hash func */
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typename C, /* equality check */
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typename A, /* allocator */
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bool Multihash
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> struct Hashtable {
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private:
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using Chain = HashChain<E>;
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using Chunk = HashChunk<E>;
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Size p_size;
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Size p_len;
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Chunk *p_chunks;
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Chain *p_unused;
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using CPA = AllocatorRebind<A, Chain *>;
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using CHA = AllocatorRebind<A, Chunk>;
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using CoreAllocPair = detail::CompressedPair<CPA, CHA>;
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using AllocPair = detail::CompressedPair<A, CoreAllocPair>;
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using FuncPair = detail::CompressedPair<H, C>;
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using FAPair = detail::CompressedPair<AllocPair, FuncPair>;
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using DataPair = detail::CompressedPair<Chain **, FAPair>;
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using Range = HashRange<E>;
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using ConstRange = HashRange<const E>;
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using LocalRange = BucketRange<E>;
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using ConstLocalRange = BucketRange<const E>;
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DataPair p_data;
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float p_maxlf;
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Chain *find(const K &key, Size &h) const {
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if (!p_size) return nullptr;
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h = get_hash()(key) & (p_size - 1);
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Chain **cp = p_data.first();
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for (Chain *c = cp[h], *e = cp[h + 1]; c != e; c = c->next)
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if (get_eq()(key, B::get_key(c->value)))
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return c;
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return nullptr;
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}
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Chain *insert_node(Size h, Chain *c) {
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Chain **cp = p_data.first();
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Chain *it = cp[h + 1];
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c->next = it;
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if (it) {
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c->prev = it->prev;
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it->prev = c;
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if (c->prev) c->prev->next = c;
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} else {
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size_t nb = h;
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while (nb && !cp[nb]) --nb;
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Chain *prev = cp[nb];
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while (prev && prev->next) prev = prev->next;
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c->prev = prev;
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if (prev) prev->next = c;
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}
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for (; it == cp[h]; --h) {
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cp[h] = c;
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if (!h) break;
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}
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return c;
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}
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Chain *insert(Size h) {
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if (!p_unused) {
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Chunk *chunk = allocator_allocate(get_challoc(), 1);
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allocator_construct(get_challoc(), chunk);
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chunk->next = p_chunks;
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p_chunks = chunk;
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for (Size i = 0; i < (Chunk::num - 1); ++i)
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chunk->chains[i].next = &chunk->chains[i + 1];
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chunk->chains[Chunk::num - 1].next = p_unused;
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p_unused = chunk->chains;
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}
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++p_len;
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Chain *c = p_unused;
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p_unused = p_unused->next;
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return insert_node(h, c);
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}
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void delete_chunks(Chunk *chunks) {
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for (Chunk *nc; chunks; chunks = nc) {
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nc = chunks->next;
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allocator_destroy(get_challoc(), chunks);
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allocator_deallocate(get_challoc(), chunks, 1);
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}
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}
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T *access_base(const K &key, Size &h) const {
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if (!p_size) return NULL;
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Chain *c = find(key, h);
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if (c) return &B::get_data(c->value);
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return nullptr;
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}
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void rehash_ahead(Size n) {
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if (!bucket_count())
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reserve(n);
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else if ((float(size() + n) / bucket_count()) > max_load_factor())
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rehash(Size((size() + 1) / max_load_factor()) * 2);
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}
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protected:
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template<typename U>
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T &insert(Size h, U &&key) {
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Chain *c = insert(h);
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B::set_key(c->value, forward<U>(key), get_alloc());
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return B::get_data(c->value);
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}
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T &access_or_insert(const K &key) {
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Size h = 0;
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T *v = access_base(key, h);
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if (v) return *v;
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rehash_ahead(1);
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return insert(h, key);
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}
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T &access_or_insert(K &&key) {
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Size h = 0;
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T *v = access_base(key, h);
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if (v) return *v;
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rehash_ahead(1);
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return insert(h, move(key));
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}
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T &access(const K &key) const {
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Size h;
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return *access_base(key, h);
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}
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template<typename R>
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void assign_range(R range) {
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clear();
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reserve_at_least(detail::estimate_hrsize(range));
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for (; !range.empty(); range.pop_front())
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emplace(range.front());
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rehash_up();
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}
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void assign_init(InitializerList<E> il) {
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const E *beg = il.begin(), *end = il.end();
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clear();
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reserve_at_least(end - beg);
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while (beg != end)
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emplace(*beg++);
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}
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const H &get_hash() const { return p_data.second().second().first(); }
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const C &get_eq() const { return p_data.second().second().second(); }
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A &get_alloc() { return p_data.second().first().first(); }
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const A &get_alloc() const { return p_data.second().first().first(); }
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CPA &get_cpalloc() { return p_data.second().first().second().first(); }
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const CPA &get_cpalloc() const {
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return p_data.second().first().second().first();
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}
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CHA &get_challoc() { return p_data.second().first().second().second(); }
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const CHA &get_challoc() const {
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return p_data.second().first().second().second();
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}
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Hashtable(Size size, const H &hf, const C &eqf, const A &alloc):
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p_size(size), p_len(0), p_chunks(nullptr), p_unused(nullptr),
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p_data(nullptr, FAPair(AllocPair(alloc, CoreAllocPair(alloc, alloc)),
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FuncPair(hf, eqf))),
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p_maxlf(1.0f) {
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if (!size) return;
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p_data.first() = allocator_allocate(get_cpalloc(), size + 1);
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memset(p_data.first(), 0, (size + 1) * sizeof(Chain *));
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}
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Hashtable(const Hashtable &ht, const A &alloc): p_size(ht.p_size),
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p_len(0), p_chunks(nullptr), p_unused(nullptr),
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p_data(nullptr, FAPair(AllocPair(alloc, CoreAllocPair(alloc, alloc)),
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FuncPair(ht.get_hash(), ht.get_eq()))),
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p_maxlf(ht.p_maxlf) {
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if (!p_size) return;
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p_data.first() = allocator_allocate(get_cpalloc(), p_size + 1);
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memset(p_data.first(), 0, (p_size + 1) * sizeof(Chain *));
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Chain **och = ht.p_data.first();
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for (Chain *oc = *och; oc; oc = oc->next) {
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Size h = get_hash()(B::get_key(oc->value)) & (p_size - 1);
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Chain *nc = insert(h);
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allocator_destroy(get_alloc(), &nc->value);
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allocator_construct(get_alloc(), &nc->value, oc->value);
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}
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}
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Hashtable(Hashtable &&ht): p_size(ht.p_size), p_len(ht.p_len),
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p_chunks(ht.p_chunks), p_unused(ht.p_unused),
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p_data(move(ht.p_data)), p_maxlf(ht.p_maxlf) {
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ht.p_size = ht.p_len = 0;
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ht.p_chunks = nullptr;
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ht.p_unused = nullptr;
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ht.p_data.first() = nullptr;
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}
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Hashtable(Hashtable &&ht, const A &alloc): p_data(nullptr,
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FAPair(AllocPair(alloc, CoreAllocPair(alloc, alloc)),
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FuncPair(ht.get_hash(), ht.get_eq()))) {
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p_size = ht.p_size;
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if (alloc == ht.get_alloc()) {
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p_len = ht.p_len;
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p_chunks = ht.p_chunks;
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p_unused = ht.p_unused;
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p_data.first() = ht.p_data.first();
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p_maxlf = ht.p_maxlf;
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ht.p_size = ht.p_len = 0;
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ht.p_chunks = nullptr;
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ht.p_unused = nullptr;
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ht.p_data.first() = nullptr;
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return;
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}
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p_len = 0;
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p_chunks = nullptr;
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p_unused = nullptr;
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p_data.first() = allocator_allocate(get_cpalloc(), p_size + 1);
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memset(p_data.first(), 0, (p_size + 1) * sizeof(Chain *));
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Chain **och = ht.p_data.first();
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for (Chain *oc = *och; oc; oc = oc->next) {
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Size h = get_hash()(B::get_key(oc->value)) & (p_size - 1);
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Chain *nc = insert(h);
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B::swap_elem(oc->value, nc->value);
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}
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}
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Hashtable &operator=(const Hashtable &ht) {
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clear();
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if (AllocatorPropagateOnContainerCopyAssignment<A>::value) {
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if ((get_cpalloc() != ht.get_cpalloc()) && p_size) {
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allocator_deallocate(get_cpalloc(),
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p_data.first(), p_size + 1);
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p_data.first() = allocator_allocate(get_cpalloc(),
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p_size + 1);
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memset(p_data.first(), 0, (p_size + 1) * sizeof(Chain *));
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}
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get_alloc() = ht.get_alloc();
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get_cpalloc() = ht.get_cpalloc();
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get_challoc() = ht.get_challoc();
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}
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for (ConstRange range = ht.iter(); !range.empty(); range.pop_front())
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emplace(range.front());
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return *this;
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}
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Hashtable &operator=(Hashtable &&ht) {
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clear();
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swap_adl(p_size, ht.p_size);
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swap_adl(p_len, ht.p_len);
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swap_adl(p_chunks, ht.p_chunks);
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swap_adl(p_unused, ht.p_unused);
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swap_adl(p_data.first(), ht.p_data.first());
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swap_adl(p_data.second().second(), ht.p_data.second().second());
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if (AllocatorPropagateOnContainerMoveAssignment<A>::value)
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swap_adl(p_data.second().first(), ht.p_data.second().first());
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return *this;
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}
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void rehash_up() {
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if (load_factor() <= max_load_factor()) return;
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rehash(Size(size() / max_load_factor()) * 2);
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}
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void reserve_at_least(Size count) {
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Size nc = Size(ceil(count / max_load_factor()));
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if (p_size > nc) return;
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rehash(nc);
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}
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void swap(Hashtable &ht) {
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swap_adl(p_size, ht.p_size);
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swap_adl(p_len, ht.p_len);
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swap_adl(p_chunks, ht.p_chunks);
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swap_adl(p_unused, ht.p_unused);
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swap_adl(p_data.first(), ht.p_data.first());
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swap_adl(p_data.second().second(), ht.p_data.second().second());
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if (AllocatorPropagateOnContainerSwap<A>::value)
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swap_adl(p_data.second().first(), ht.p_data.second().first());
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}
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public:
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~Hashtable() {
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if (p_size) allocator_deallocate(get_cpalloc(),
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p_data.first(), p_size + 1);
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delete_chunks(p_chunks);
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}
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A get_allocator() const {
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return get_alloc();
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}
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void clear() {
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if (!p_len) return;
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memset(p_data.first(), 0, (p_size + 1) * sizeof(Chain *));
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p_len = 0;
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p_unused = nullptr;
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delete_chunks(p_chunks);
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}
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bool empty() const { return p_len == 0; }
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Size size() const { return p_len; }
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Size max_size() const { return Size(~0) / sizeof(E); }
|
|
|
|
Size bucket_count() const { return p_size; }
|
|
Size max_bucket_count() const { return Size(~0) / sizeof(Chain); }
|
|
|
|
Size bucket(const K &key) const {
|
|
return get_hash()(key) & (p_size - 1);
|
|
}
|
|
|
|
Size bucket_size(Size n) const {
|
|
Size ret = 0;
|
|
if (ret >= p_size) return ret;
|
|
Chain **cp = p_data.first();
|
|
for (Chain *c = cp[n], *e = cp[n + 1]; c != e; c = c->next)
|
|
++ret;
|
|
return ret;
|
|
}
|
|
|
|
template<typename ...Args>
|
|
Pair<Range, bool> emplace(Args &&...args) {
|
|
rehash_ahead(1);
|
|
E elem(forward<Args>(args)...);
|
|
Size h = get_hash()(B::get_key(elem)) & (p_size - 1);
|
|
if (Multihash) {
|
|
/* multihash: always insert */
|
|
Chain *ch = insert(h);
|
|
B::swap_elem(ch->value, elem);
|
|
return make_pair(Range(ch), true);
|
|
}
|
|
Chain *found = nullptr;
|
|
bool ins = true;
|
|
Chain **cp = p_data.first();
|
|
for (Chain *c = cp[h], *e = cp[h + 1]; c != e; c = c->next) {
|
|
if (get_eq()(B::get_key(elem), B::get_key(c->value))) {
|
|
found = c;
|
|
ins = false;
|
|
break;
|
|
}
|
|
}
|
|
if (!found) {
|
|
found = insert(h);
|
|
B::swap_elem(found->value, elem);
|
|
}
|
|
return make_pair(Range(found), ins);
|
|
}
|
|
|
|
Size erase(const K &key) {
|
|
if (!p_len) return 0;
|
|
Size olen = p_len;
|
|
Size h = get_hash()(key) & (p_size - 1);
|
|
Chain **cp = p_data.first();
|
|
for (Chain *c = cp[h], *e = cp[h + 1]; c != e; c = c->next)
|
|
if (get_eq()(key, B::get_key(c->value))) {
|
|
--p_len;
|
|
Size hh = h;
|
|
Chain *next = c->next;
|
|
for (; cp[hh] == c; --hh) {
|
|
cp[hh] = next;
|
|
if (!hh) break;
|
|
}
|
|
if (c->prev) c->prev->next = next;
|
|
if (next) next->prev = c->prev;
|
|
c->next = p_unused;
|
|
c->prev = nullptr;
|
|
p_unused = c;
|
|
allocator_destroy(get_alloc(), &c->value);
|
|
allocator_construct(get_alloc(), &c->value);
|
|
if (!Multihash) return 1;
|
|
}
|
|
return olen - p_len;
|
|
}
|
|
|
|
Size count(const K &key) {
|
|
Size h = 0;
|
|
Chain *c = find(key, h);
|
|
if (!c) return 0;
|
|
Size ret = 1;
|
|
if (!Multihash) return ret;
|
|
for (c = c->next; c; c = c->next)
|
|
if (get_eq()(key, B::get_key(c->value))) ++ret;
|
|
return ret;
|
|
}
|
|
|
|
Range find(const K &key) {
|
|
Size h = 0;
|
|
return Range(find(key, h));
|
|
}
|
|
|
|
ConstRange find(const K &key) const {
|
|
Size h = 0;
|
|
return ConstRange((detail::HashChain<const E> *)find(key, h));
|
|
}
|
|
|
|
float load_factor() const { return float(p_len) / p_size; }
|
|
float max_load_factor() const { return p_maxlf; }
|
|
void max_load_factor(float lf) { p_maxlf = lf; }
|
|
|
|
void rehash(Size count) {
|
|
Size fbcount = Size(p_len / max_load_factor());
|
|
if (fbcount > count) count = fbcount;
|
|
|
|
Chain **och = p_data.first();
|
|
Chain **nch = allocator_allocate(get_cpalloc(), count + 1);
|
|
memset(nch, 0, (count + 1) * sizeof(Chain *));
|
|
p_data.first() = nch;
|
|
|
|
Size osize = p_size;
|
|
p_size = count;
|
|
|
|
Chain *p = och ? *och : nullptr;
|
|
while (p) {
|
|
Chain *pp = p->next;
|
|
Size h = get_hash()(B::get_key(p->value)) & (p_size - 1);
|
|
p->prev = p->next = nullptr;
|
|
insert_node(h, p);
|
|
p = pp;
|
|
}
|
|
|
|
if (och && osize) allocator_deallocate(get_cpalloc(),
|
|
och, osize + 1);
|
|
}
|
|
|
|
void reserve(Size count) {
|
|
rehash(Size(ceil(count / max_load_factor())));
|
|
}
|
|
|
|
Range iter() {
|
|
if (!p_len) return Range();
|
|
return Range(*p_data.first());
|
|
}
|
|
ConstRange iter() const {
|
|
using Chain = detail::HashChain<const E>;
|
|
if (!p_len) return ConstRange();
|
|
return ConstRange((Chain *)*p_data.first());
|
|
}
|
|
ConstRange citer() const {
|
|
using Chain = detail::HashChain<const E>;
|
|
if (!p_len) return ConstRange();
|
|
return ConstRange((Chain *)*p_data.first());
|
|
}
|
|
|
|
LocalRange iter(Size n) {
|
|
if (n >= p_size) return LocalRange();
|
|
return LocalRange(p_data.first()[n], p_data.first()[n + 1]);
|
|
}
|
|
ConstLocalRange iter(Size n) const {
|
|
using Chain = detail::HashChain<const E>;
|
|
if (n >= p_size) return ConstLocalRange();
|
|
return ConstLocalRange((Chain *)p_data.first()[n],
|
|
(Chain *)p_data.first()[n + 1]);
|
|
}
|
|
ConstLocalRange citer(Size n) const {
|
|
using Chain = detail::HashChain<const E>;
|
|
if (n >= p_size) return ConstLocalRange();
|
|
return ConstLocalRange((Chain *)p_data.first()[n],
|
|
(Chain *)p_data.first()[n + 1]);
|
|
}
|
|
};
|
|
} /* namespace detail */
|
|
|
|
} /* namespace ostd */
|
|
|
|
#endif |