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hash_table7.hpp
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hash_table7.hpp
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// emhash7::HashMap for C++11/14/17
// version 2.2.5
// https://github.com/ktprime/emhash/blob/master/hash_table7.hpp
//
// Licensed under the MIT License <http://opensource.org/licenses/MIT>.
// SPDX-License-Identifier: MIT
// Copyright (c) 2019-2024 Huang Yuanbing & bailuzhou AT 163.com
//
// Permission is hereby granted, free of charge, to any person obtaining a copy
// of this software and associated documentation files (the "Software"), to deal
// in the Software without restriction, including without limitation the rights
// to use, copy, modify, merge, publish, distribute, sublicense, and/or sell
// copies of the Software, and to permit persons to whom the Software is
// furnished to do so, subject to the following conditions:
//
// The above copyright notice and this permission notice shall be included in all
// copies or substantial portions of the Software.
//
// THE SOFTWARE IS PROVIDED "AS IS", WITHOUT WARRANTY OF ANY KIND, EXPRESS OR
// IMPLIED, INCLUDING BUT NOT LIMITED TO THE WARRANTIES OF MERCHANTABILITY,
// FITNESS FOR A PARTICULAR PURPOSE AND NONINFRINGEMENT. IN NO EVENT SHALL THE
// AUTHORS OR COPYRIGHT HOLDERS BE LIABLE FOR ANY CLAIM, DAMAGES OR OTHER
// LIABILITY, WHETHER IN AN ACTION OF CONTRACT, TORT OR OTHERWISE, ARISING FROM,
// OUT OF OR IN CONNECTION WITH THE SOFTWARE OR THE USE OR OTHER DEALINGS IN THE
// SOFTWARE
// From
// NUMBER OF PROBES / LOOKUP Successful Unsuccessful
// Quadratic collision resolution 1 - ln(1-L) - L/2 1/(1-L) - L - ln(1-L)
// Linear collision resolution [1+1/(1-L)]/2 [1+1/(1-L)2]/2
// separator chain resolution 1 + L / 2 exp(-L) + L
// -- enlarge_factor -- 0.10 0.50 0.60 0.75 0.80 0.90 0.99
// QUADRATIC COLLISION RES.
// probes/successful lookup 1.05 1.44 1.62 2.01 2.21 2.85 5.11
// probes/unsuccessful lookup 1.11 2.19 2.82 4.64 5.81 11.4 103.6
// LINEAR COLLISION RES.
// probes/successful lookup 1.06 1.5 1.75 2.5 3.0 5.5 50.5
// probes/unsuccessful lookup 1.12 2.5 3.6 8.5 13.0 50.0
// SEPARATE CHAN RES.
// probes/successful lookup 1.05 1.25 1.3 1.25 1.4 1.45 1.50
// probes/unsuccessful lookup 1.00 1.11 1.15 1.22 1.25 1.31 1.37
// clacul/unsuccessful lookup 1.01 1.25 1.36, 1.56, 1.64, 1.81, 1.97
/****************
under random hashCodes, the frequency of nodes in bins follows a Poisson
distribution(http://en.wikipedia.org/wiki/Poisson_distribution) with a parameter of about 0.5
on average for the default resizing threshold of 0.75, although with a large variance because
of resizing granularity. Ignoring variance, the expected occurrences of list size k are
(exp(-0.5) * pow(0.5, k)/factorial(k)). The first values are:
0: 0.60653066
1: 0.30326533
2: 0.07581633
3: 0.01263606
4: 0.00157952
5: 0.00015795
6: 0.00001316
7: 0.00000094
8: 0.00000006
============== buckets size ration ========
1 1543981 0.36884964|0.36787944 36.885
2 768655 0.36725597|0.36787944 73.611
3 256236 0.18364065|0.18393972 91.975
4 64126 0.06127757|0.06131324 98.102
5 12907 0.01541710|0.01532831 99.644
6 2050 0.00293841|0.00306566 99.938
7 310 0.00051840|0.00051094 99.990
8 49 0.00009365|0.00007299 99.999
9 4 0.00000860|0.00000913 100.000
========== collision miss ration ===========
_num_filled aver_size k.v size_kv = 4185936, 1.58, x.x 24
collision,possion,cache_miss hit_find|hit_miss, load_factor = 36.73%,36.74%,31.31% 1.50|2.00, 1.00
============== buckets size ration ========
*******************************************************/
#pragma once
#include <cstring>
#include <string>
#include <cmath>
#include <cstdlib>
#include <type_traits>
#include <cassert>
#include <utility>
#include <cstdint>
#include <functional>
#include <iterator>
#include <algorithm>
#if EMH_WY_HASH
#include "wyhash.h"
#endif
#ifdef EMH_NEW
#undef EMH_KEY
#undef EMH_VAL
#undef EMH_PKV
#undef EMH_NEW
#undef EMH_SET
#undef EMH_BUCKET
#undef EMH_EMPTY
#undef EMH_MASK
#endif
// likely/unlikely
#if (__GNUC__ >= 4 || __clang__)
# define EMH_LIKELY(condition) __builtin_expect(condition, 1)
# define EMH_UNLIKELY(condition) __builtin_expect(condition, 0)
#else
# define EMH_LIKELY(condition) condition
# define EMH_UNLIKELY(condition) condition
#endif
#ifndef EMH_BUCKET_INDEX
#define EMH_BUCKET_INDEX 1
#endif
#if EMH_BUCKET_INDEX == 0
#define EMH_KEY(p,n) p[n].second.first
#define EMH_VAL(p,n) p[n].second.second
#define EMH_BUCKET(p,n) p[n].first
#define EMH_PKV(p,n) p[n].second
#define EMH_NEW(key, val, bucket)\
new(_pairs + bucket) PairT(bucket, value_type(key, val));\
_num_filled ++; EMH_SET(bucket)
#elif EMH_BUCKET_INDEX == 2
#define EMH_KEY(p,n) p[n].first.first
#define EMH_VAL(p,n) p[n].first.second
#define EMH_BUCKET(p,n) p[n].second
#define EMH_PKV(p,n) p[n].first
#define EMH_NEW(key, val, bucket)\
new(_pairs + bucket) PairT(value_type(key, val), bucket);\
_num_filled ++; EMH_SET(bucket)
#else
#define EMH_KEY(p,n) p[n].first
#define EMH_VAL(p,n) p[n].second
#define EMH_BUCKET(p,n) p[n].bucket
#define EMH_PKV(p,n) p[n]
#define EMH_NEW(key, val, bucket)\
new(_pairs + bucket) PairT(key, val, bucket); _num_filled ++; EMH_SET(bucket)
#endif
#define EMH_MASK(n) uint8_t(1 << (n % MASK_BIT))
#define EMH_SET(n) _bitmask[n / MASK_BIT] &= ~(EMH_MASK(n))
#define EMH_CLS(n) _bitmask[n / MASK_BIT] |= EMH_MASK(n)
#define EMH_EMPTY(n) (_bitmask[n / MASK_BIT] & (EMH_MASK(n))) != 0
#if _WIN32
#include <intrin.h>
#if _WIN64
#pragma intrinsic(_umul128)
#endif
#endif
namespace emhash7 {
#ifdef EMH_SIZE_TYPE_16BIT
typedef uint16_t size_type;
static constexpr size_type INACTIVE = 0xFFFF;
#elif EMH_SIZE_TYPE_64BIT
typedef uint64_t size_type;
static constexpr size_type INACTIVE = 0 - 0x1ull;
#else
typedef uint32_t size_type;
static constexpr size_type INACTIVE = -1;
#endif
#ifndef EMH_MALIGN
static constexpr uint32_t EMH_MALIGN = 16;
#endif
static_assert(EMH_MALIGN >= 16 && 0 == (EMH_MALIGN & (EMH_MALIGN - 1)));
#ifndef EMH_SIZE_TYPE_16BIT
static_assert((int)INACTIVE < 0, "INACTIVE must negative (to int)");
#endif
//count the leading zero bit
static inline int CTZ(size_t n)
{
#if defined(__x86_64__) || defined(_WIN32) || (__BYTE_ORDER__ && __BYTE_ORDER__ == __ORDER_LITTLE_ENDIAN__)
#elif __BIG_ENDIAN__ || (__BYTE_ORDER__ && __BYTE_ORDER__ == __ORDER_BIG_ENDIAN__)
n = __builtin_bswap64(n);
#else
static uint32_t endianness = 0x12345678;
const auto is_big = *(const char *)&endianness == 0x12;
if (is_big)
n = __builtin_bswap64(n);
#endif
#if _WIN32
unsigned long index;
#if defined(_WIN64)
_BitScanForward64(&index, n);
#else
_BitScanForward(&index, n);
#endif
#elif defined (__LP64__) || (SIZE_MAX == UINT64_MAX) || defined (__x86_64__)
auto index = __builtin_ctzll(n);
#elif 1
auto index = __builtin_ctzl(n);
#else
#if defined (__LP64__) || (SIZE_MAX == UINT64_MAX) || defined (__x86_64__)
size_type index;
__asm__("bsfq %1, %0\n" : "=r" (index) : "rm" (n) : "cc");
#else
size_type index;
__asm__("bsf %1, %0\n" : "=r" (index) : "rm" (n) : "cc");
#endif
#endif
return (int)index;
}
template <typename First, typename Second>
struct entry {
using first_type = First;
using second_type = Second;
entry(const First& key, const Second& val, size_type ibucket)
:second(val), first(key)
{
bucket = ibucket;
}
entry(First&& key, Second&& val, size_type ibucket)
:second(std::move(val)), first(std::move(key))
{
bucket = ibucket;
}
template<typename K, typename V>
entry(K&& key, V&& val, size_type ibucket)
:second(std::forward<V>(val)), first(std::forward<K>(key))
{
bucket = ibucket;
}
entry(const std::pair<First, Second>& pair)
:second(pair.second), first(pair.first)
{
bucket = INACTIVE;
}
entry(std::pair<First, Second>&& pair)
:second(std::move(pair.second)), first(std::move(pair.first))
{
bucket = INACTIVE;
}
entry(std::tuple<First, Second>&& tup)
:second(std::move(std::get<2>(tup))), first(std::move(std::get<1>(tup)))
{
bucket = INACTIVE;
}
entry(const entry& rhs)
:second(rhs.second), first(rhs.first)
{
bucket = rhs.bucket;
}
entry(entry&& rhs) noexcept
:second(std::move(rhs.second)), first(std::move(rhs.first))
{
bucket = rhs.bucket;
}
entry& operator = (entry&& rhs) noexcept
{
second = std::move(rhs.second);
bucket = rhs.bucket;
first = std::move(rhs.first);
return *this;
}
entry& operator = (const entry& rhs)
{
second = rhs.second;
bucket = rhs.bucket;
first = rhs.first;
return *this;
}
bool operator == (const entry<First, Second>& p) const
{
return first == p.first && second == p.second;
}
bool operator == (const std::pair<First, Second>& p) const
{
return first == p.first && second == p.second;
}
void swap(entry<First, Second>& o)
{
std::swap(second, o.second);
std::swap(first, o.first);
}
#if EMH_ORDER_KV || EMH_SIZE_TYPE_64BIT
First first;
size_type bucket;
Second second;
#else
Second second;
size_type bucket;
First first;
#endif
};
/// A cache-friendly hash table with open addressing, linear/qua probing and power-of-two capacity
template <typename KeyT, typename ValueT, typename HashT = std::hash<KeyT>, typename EqT = std::equal_to<KeyT>>
class HashMap
{
#ifndef EMH_DEFAULT_LOAD_FACTOR
constexpr static float EMH_DEFAULT_LOAD_FACTOR = 0.80f;
#endif
constexpr static float EMH_MIN_LOAD_FACTOR = 0.25f;
public:
typedef HashMap<KeyT, ValueT, HashT, EqT> htype;
typedef std::pair<KeyT, ValueT> value_type;
#if EMH_BUCKET_INDEX == 0
typedef value_type value_pair;
typedef std::pair<size_type, value_type> PairT;
#elif EMH_BUCKET_INDEX == 2
typedef value_type value_pair;
typedef std::pair<value_type, size_type> PairT;
#else
typedef entry<KeyT, ValueT> value_pair;
typedef entry<KeyT, ValueT> PairT;
#endif
typedef KeyT key_type;
typedef ValueT val_type;
typedef ValueT mapped_type;
typedef HashT hasher;
typedef EqT key_equal;
typedef PairT& reference;
typedef const PairT& const_reference;
class const_iterator;
class iterator
{
public:
typedef std::forward_iterator_tag iterator_category;
typedef std::ptrdiff_t difference_type;
typedef value_pair value_type;
typedef value_pair* pointer;
typedef value_pair& reference;
iterator() = default;
iterator(const const_iterator& it) : _map(it._map), _bucket(it._bucket), _from(it._from), _bmask(it._bmask) { }
//iterator(const htype* hash_map, size_type bucket, bool) : _map(hash_map), _bucket(bucket) { init(); }
#if EMH_ITER_SAFE
iterator(const htype* hash_map, size_type bucket) : _map(hash_map), _bucket(bucket) { init(); }
#else
iterator(const htype* hash_map, size_type bucket) : _map(hash_map), _bucket(bucket) { _from = size_type(-1); }
#endif
void init()
{
_from = (_bucket / SIZE_BIT) * SIZE_BIT;
if (_bucket < _map->bucket_count()) {
_bmask = *(size_t*)((size_t*)_map->_bitmask + _from / SIZE_BIT);
_bmask |= (1ull << _bucket % SIZE_BIT) - 1;
_bmask = ~_bmask;
} else {
_bmask = 0;
}
}
size_type bucket() const
{
return _bucket;
}
void clear(size_type bucket)
{
if (_bucket / SIZE_BIT == bucket / SIZE_BIT)
_bmask &= ~(1ull << (bucket % SIZE_BIT));
}
iterator& next()
{
goto_next_element();
return *this;
}
iterator& operator++()
{
#ifndef EMH_ITER_SAFE
if (_from == (size_type)-1) init();
#endif
_bmask &= _bmask - 1;
goto_next_element();
return *this;
}
iterator operator++(int)
{
#ifndef EMH_ITER_SAFE
if (_from == (size_type)-1) init();
#endif
iterator old = *this;
_bmask &= _bmask - 1;
goto_next_element();
return old;
}
reference operator*() const
{
return _map->EMH_PKV(_pairs, _bucket);
}
pointer operator->() const
{
return &(_map->EMH_PKV(_pairs, _bucket));
}
bool operator==(const iterator& rhs) const { return _bucket == rhs._bucket; }
bool operator!=(const iterator& rhs) const { return _bucket != rhs._bucket; }
bool operator==(const const_iterator& rhs) const { return _bucket == rhs._bucket; }
bool operator!=(const const_iterator& rhs) const { return _bucket != rhs._bucket; }
private:
void goto_next_element()
{
if (_bmask != 0) {
_bucket = _from + CTZ(_bmask);
return;
}
do {
_bmask = ~*(size_t*)((size_t*)_map->_bitmask + (_from += SIZE_BIT) / SIZE_BIT);
} while (_bmask == 0);
_bucket = _from + CTZ(_bmask);
}
public:
const htype* _map;
size_type _bucket;
size_type _from;
size_t _bmask;
};
class const_iterator
{
public:
typedef std::forward_iterator_tag iterator_category;
typedef std::ptrdiff_t difference_type;
typedef value_pair value_type;
typedef const value_pair* pointer;
typedef const value_pair& reference;
const_iterator(const iterator& it) : _map(it._map), _bucket(it._bucket), _from(it._from), _bmask(it._bmask) { }
//const_iterator(const htype* hash_map, size_type bucket, bool) : _map(hash_map), _bucket(bucket) { init(); }
#if EMH_ITER_SAFE
const_iterator(const htype* hash_map, size_type bucket) : _map(hash_map), _bucket(bucket) { init(); }
#else
const_iterator(const htype* hash_map, size_type bucket) : _map(hash_map), _bucket(bucket) { _from = size_type(-1); }
#endif
void init()
{
_from = (_bucket / SIZE_BIT) * SIZE_BIT;
if (_bucket < _map->bucket_count()) {
_bmask = *(size_t*)((size_t*)_map->_bitmask + _from / SIZE_BIT);
_bmask |= (1ull << _bucket % SIZE_BIT) - 1;
_bmask = ~_bmask;
} else {
_bmask = 0;
}
}
size_type bucket() const
{
return _bucket;
}
const_iterator& operator++()
{
#ifndef EMH_ITER_SAFE
if (_from == (size_type)-1) init();
#endif
goto_next_element();
return *this;
}
const_iterator operator++(int)
{
#ifndef EMH_ITER_SAFE
if (_from == (size_type)-1) init();
#endif
const_iterator old(*this);
goto_next_element();
return old;
}
reference operator*() const
{
return _map->EMH_PKV(_pairs, _bucket);
}
pointer operator->() const
{
return &(_map->EMH_PKV(_pairs, _bucket));
}
bool operator==(const const_iterator& rhs) const { return _bucket == rhs._bucket; }
bool operator!=(const const_iterator& rhs) const { return _bucket != rhs._bucket; }
private:
void goto_next_element()
{
_bmask &= _bmask - 1;
if (_bmask != 0) {
_bucket = _from + CTZ(_bmask);
return;
}
do {
_bmask = ~*(size_t*)((size_t*)_map->_bitmask + (_from += SIZE_BIT) / SIZE_BIT);
} while (_bmask == 0);
_bucket = _from + CTZ(_bmask);
}
public:
const htype* _map;
size_type _bucket;
size_type _from;
size_t _bmask;
};
void init(size_type bucket, float mlf = EMH_DEFAULT_LOAD_FACTOR)
{
_pairs = nullptr;
_bitmask = nullptr;
_num_buckets = _num_filled = 0;
_mlf = (uint32_t)((1 << 27) / EMH_DEFAULT_LOAD_FACTOR);
max_load_factor(mlf);
rehash(bucket);
}
HashMap(size_type bucket = 2, float mlf = EMH_DEFAULT_LOAD_FACTOR) noexcept
{
init(bucket, mlf);
}
static size_t AllocSize(uint64_t num_buckets)
{
return (num_buckets + EPACK_SIZE) * sizeof(PairT) + (num_buckets + 7) / 8 + BIT_PACK;
}
static PairT* alloc_bucket(size_type num_buckets)
{
#ifdef EMH_ALLOC
auto* new_pairs = (PairT*)aligned_alloc(EMH_MALIGN, AllocSize(num_buckets));
#else
auto* new_pairs = (PairT*)malloc(AllocSize(num_buckets));
#endif
return new_pairs;
}
HashMap(const HashMap& rhs) noexcept
{
if (rhs.load_factor() > EMH_MIN_LOAD_FACTOR) {
_pairs = (PairT*)alloc_bucket(rhs._num_buckets);
clone(rhs);
} else {
init(rhs._num_filled + 2, rhs.max_load_factor());
for (auto it = rhs.begin(); it != rhs.end(); ++it)
insert_unique(it->first, it->second);
}
}
HashMap(HashMap&& rhs) noexcept
{
#ifndef EMH_ZERO_MOVE
init(4);
#else
_num_buckets = _num_filled = _mask = 0;
_pairs = nullptr;
#endif
swap(rhs);
}
HashMap(std::initializer_list<value_type> ilist)
{
init((size_type)ilist.size());
for (auto it = ilist.begin(); it != ilist.end(); ++it)
do_insert(*it);
}
template<class InputIt>
HashMap(InputIt first, InputIt last, size_type bucket_count=4)
{
init(std::distance(first, last) + bucket_count);
for (; first != last; ++first)
emplace(*first);
}
HashMap& operator= (const HashMap& rhs) noexcept
{
if (this == &rhs)
return *this;
if (rhs.load_factor() < EMH_MIN_LOAD_FACTOR) {
clear(); free(_pairs); _pairs = nullptr;
rehash(rhs._num_filled + 2);
for (auto it = rhs.begin(); it != rhs.end(); ++it)
insert_unique(it->first, it->second);
return *this;
}
if (_num_filled)
clearkv();
if (_num_buckets != rhs._num_buckets) {
free(_pairs);
_pairs = alloc_bucket(rhs._num_buckets);
}
clone(rhs);
return *this;
}
HashMap& operator= (HashMap&& rhs) noexcept
{
if (this != &rhs) {
swap(rhs);
rhs.clear();
}
return *this;
}
template<typename Con>
bool operator == (const Con& rhs) const
{
if (size() != rhs.size())
return false;
for (auto it = begin(), last = end(); it != last; ++it) {
auto oi = rhs.find(it->first);
if (oi == rhs.end() || it->second != oi->second)
return false;
}
return true;
}
template<typename Con>
bool operator != (const Con& rhs) const { return !(*this == rhs); }
~HashMap() noexcept
{
if (is_triviall_destructable() && _num_filled) {
for (auto it = cbegin(); _num_filled; ++it) {
_num_filled --;
it->~value_pair();
}
}
free(_pairs);
_pairs = nullptr;
}
void clone(const HashMap& rhs) noexcept
{
_hasher = rhs._hasher;
//_eq = rhs._eq;
_num_filled = rhs._num_filled;
_mask = rhs._mask;
_mlf = rhs._mlf;
_num_buckets = rhs._num_buckets;
_bitmask = decltype(_bitmask)(_pairs + EPACK_SIZE + _num_buckets);
auto* opairs = rhs._pairs;
if (is_copy_trivially())
memcpy((char*)_pairs, opairs, AllocSize(_num_buckets));
else {
memcpy((char*)(_pairs + _num_buckets), opairs + _num_buckets, EPACK_SIZE * sizeof(PairT) + (_num_buckets + 7) / 8 + BIT_PACK);
for (auto it = rhs.cbegin(); it.bucket() < _num_buckets; ++it) {
const auto bucket = it.bucket();
new(_pairs + bucket) PairT(opairs[bucket]); EMH_BUCKET(_pairs, bucket) = EMH_BUCKET(opairs, bucket);
}
}
}
void swap(HashMap& rhs)
{
std::swap(_hasher, rhs._hasher);
//std::swap(_eq, rhs._eq);
std::swap(_pairs, rhs._pairs);
std::swap(_num_buckets, rhs._num_buckets);
std::swap(_num_filled, rhs._num_filled);
std::swap(_mask, rhs._mask);
std::swap(_mlf, rhs._mlf);
std::swap(_bitmask, rhs._bitmask);
}
// -------------------------------------------------------------
iterator begin() noexcept
{
#ifdef EMH_ZERO_MOVE
if (0 == _num_filled)
return {this, _num_buckets};
#endif
const auto bmask = ~(*(size_t*)_bitmask);
if (bmask != 0)
return {this, (size_type)CTZ(bmask)};
iterator it(this, sizeof(bmask) * 8 - 1);
it.init();
return it.next();
}
const_iterator cbegin() const noexcept
{
#ifdef EMH_ZERO_MOVE
if (0 == _num_filled)
return {this, _num_buckets};
#endif
const auto bmask = ~(*(size_t*)_bitmask);
if (bmask != 0)
return {this, (size_type)CTZ(bmask)};
iterator it(this, sizeof(bmask) * 8 - 1);
it.init();
return it.next();
}
iterator last() const
{
if (_num_filled == 0)
return end();
auto bucket = _num_buckets - 1;
while (EMH_EMPTY(bucket)) bucket--;
return {this, bucket};
}
inline const_iterator begin() const noexcept { return cbegin(); }
inline iterator end() noexcept { return {this, _num_buckets}; }
inline const_iterator cend() const { return {this, _num_buckets}; }
inline const_iterator end() const { return cend(); }
inline size_type size() const { return _num_filled; }
inline bool empty() const { return _num_filled == 0; }
inline size_type bucket_count() const { return _num_buckets; }
inline float load_factor() const { return ((float)_num_filled) / (_mask + 1); }
inline HashT& hash_function() const { return _hasher; }
inline EqT& key_eq() const { return _eq; }
inline void max_load_factor(float mlf)
{
if (mlf <= 0.999f && mlf > EMH_MIN_LOAD_FACTOR)
_mlf = (uint32_t)((1 << 28) / mlf);
}
inline constexpr float max_load_factor() const { return (1 << 27) / (float)_mlf; }
inline constexpr size_type max_size() const { return 1ull << (sizeof(size_type) * 8 - 1); }
inline constexpr size_type max_bucket_count() const { return max_size(); }
size_type bucket_main() const
{
auto main_size = 0;
for (size_type bucket = 0; bucket < _num_buckets; ++bucket) {
if (EMH_BUCKET(_pairs, bucket) == bucket)
main_size ++;
}
return main_size;
}
#if EMH_STATIS
//Returns the bucket number where the element with key k is located.
size_type bucket(const KeyT& key) const
{
const auto bucket = hash_key(key) & _mask;
const auto next_bucket = EMH_BUCKET(_pairs, bucket);
if (EMH_EMPTY(bucket))
return 0;
else if (bucket == next_bucket)
return bucket + 1;
const auto& bucket_key = EMH_KEY(_pairs, bucket);
return (hash_key(bucket_key) & _mask) + 1;
}
//Returns the number of elements in bucket n.
size_type bucket_size(const size_type bucket) const
{
if (EMH_EMPTY(bucket))
return 0;
auto next_bucket = EMH_BUCKET(_pairs, bucket);
next_bucket = hash_key(EMH_KEY(_pairs, bucket)) & _mask;
size_type bucket_size = 1;
//iterator each item in current main bucket
while (true) {
const auto nbucket = EMH_BUCKET(_pairs, next_bucket);
if (nbucket == next_bucket) {
break;
}
bucket_size++;
next_bucket = nbucket;
}
return bucket_size;
}
size_type get_main_bucket(const size_type bucket) const
{
if (EMH_EMPTY(bucket))
return INACTIVE;
const auto& bucket_key = EMH_KEY(_pairs, bucket);
const auto main_bucket = hash_key(bucket_key) & _mask;
return main_bucket;
}
size_type get_diss(size_type bucket, size_type next_bucket, const size_type slots) const
{
const int cahe_line_size = 64;
auto pbucket = reinterpret_cast<uint64_t>(&_pairs[bucket]);
auto pnext = reinterpret_cast<uint64_t>(&_pairs[next_bucket]);
if (pbucket / cahe_line_size == pnext / cahe_line_size)
return 0;
size_type diff = pbucket > pnext ? (pbucket - pnext) : (pnext - pbucket);
if (diff / cahe_line_size + 1 < slots)
return (diff / cahe_line_size + 1);
return slots - 1;
}
int get_bucket_info(const size_type bucket, size_type steps[], const size_type slots) const
{
if (EMH_EMPTY(bucket))
return -1;
auto next_bucket = EMH_BUCKET(_pairs, bucket);
if ((hash_key(EMH_KEY(_pairs, bucket)) & _mask) != bucket)
return 0;
else if (next_bucket == bucket)
return 1;
steps[get_diss(bucket, next_bucket, slots)] ++;
size_type bucket_size = 2;
while (true) {
const auto nbucket = EMH_BUCKET(_pairs, next_bucket);
if (nbucket == next_bucket)
break;
steps[get_diss(nbucket, next_bucket, slots)] ++;
bucket_size ++;
next_bucket = nbucket;
}
return bucket_size;
}
void dump_statics(bool show_cache) const
{
const int slots = 128;
size_type buckets[slots + 1] = {0};
size_type steps[slots + 1] = {0};
char buff[1024 * 8];
for (size_type bucket = 0; bucket < _num_buckets; ++bucket) {
auto bsize = get_bucket_info(bucket, steps, slots);
if (bsize >= 0)
buckets[bsize] ++;
}
size_type sumb = 0, sums = 0, sumn = 0;
size_type miss = 0, finds = 0, bucket_coll = 0;
double lf = load_factor(), fk = 1.0 / exp(lf), sum_poisson = 0;
int bsize = sprintf (buff, "============== buckets size ration ========\n");
miss += _num_buckets - _num_filled;
for (int i = 1, factorial = 1; i < int(sizeof(buckets) / sizeof(buckets[0])); i++) {
double poisson = fk / factorial; factorial *= i; fk *= lf;
if (poisson > 1e-13 && i < 20)
sum_poisson += poisson * 100.0 * (i - 1) / i;
const int64_t bucketsi = buckets[i];
if (bucketsi == 0)
continue;
sumb += bucketsi;
sumn += bucketsi * i;
bucket_coll += bucketsi * (i - 1);
finds += bucketsi * i * (i + 1) / 2;
miss += bucketsi * i * i;
auto errs = (bucketsi * 1.0 * i / _num_filled - poisson) * 100 / poisson;
bsize += sprintf(buff + bsize, " %2d %8ld %0.8lf|%0.2lf%% %2.3lf\n",
i, bucketsi, bucketsi * 1.0 * i / _num_filled, errs, sumn * 100.0 / _num_filled);
if (sumn >= _num_filled)
break;
}
bsize += sprintf(buff + bsize, "========== collision miss ration ===========\n");
for (size_type i = 0; show_cache && i < sizeof(steps) / sizeof(steps[0]); i++) {
sums += steps[i];
if (steps[i] == 0)
continue;
if (steps[i] > 10)
bsize += sprintf(buff + bsize, " %2d %8u %0.2lf %.2lf\n", (int)i, steps[i], steps[i] * 100.0 / bucket_coll, sums * 100.0 / bucket_coll);
}
if (sumb == 0) return;
bsize += sprintf(buff + bsize, " _num_filled aver_size k.v size_kv = %u, %.2lf, %s.%s %zd\n",
_num_filled, _num_filled * 1.0 / sumb, typeid(KeyT).name(), typeid(ValueT).name(), sizeof(PairT));
bsize += sprintf(buff + bsize, " collision, poisson, cache_miss hit_find|hit_miss, load_factor = %.2lf%%,%.2lf%%,%.2lf%% %.2lf|%.2lf, %.2lf\n",
(bucket_coll * 100.0 / _num_filled), sum_poisson, (bucket_coll - steps[0]) * 100.0 / _num_filled,
finds * 1.0 / _num_filled, miss * 1.0 / _num_buckets, _num_filled * 1.0 / _num_buckets);
bsize += sprintf(buff + bsize, "============== buckets size end =============\n");
buff[bsize + 1] = 0;
#ifdef EMH_LOG
EMH_LOG << __FUNCTION__ << "|" << buff << endl;
#else
puts(buff);
#endif
assert(sumn == _num_filled);
assert(sums == bucket_coll || !show_cache);
assert(bucket_coll == buckets[0]);
}
#endif
// ------------------------------------------------------------
template<typename Key = KeyT>
inline iterator find(const Key& key, size_t key_hash) noexcept
{
return {this, find_filled_hash(key, key_hash)};
}
template<typename Key = KeyT>
inline const_iterator find(const Key& key, size_t key_hash) const noexcept
{
return {this, find_filled_hash(key, key_hash)};
}
template<typename Key=KeyT>
inline iterator find(const Key& key) noexcept
{
return {this, find_filled_bucket(key)};
}
template<typename Key = KeyT>
inline const_iterator find(const Key& key) const noexcept
{
return {this, find_filled_bucket(key)};
}
template<typename Key = KeyT>
ValueT& at(const KeyT& key)
{
const auto bucket = find_filled_bucket(key);
//throw
return EMH_VAL(_pairs, bucket);
}
template<typename Key = KeyT>
const ValueT& at(const KeyT& key) const
{
const auto bucket = find_filled_bucket(key);
//throw
return EMH_VAL(_pairs, bucket);
}
template<typename Key = KeyT>
inline bool contains(const Key& key) const noexcept
{
return find_filled_bucket(key) != _num_buckets;
}
template<typename Key = KeyT>
inline size_type count(const Key& key) const noexcept
{
return find_filled_bucket(key) != _num_buckets ? 1 : 0;
}
template<typename Key = KeyT>
std::pair<iterator, iterator> equal_range(const Key& key) const noexcept
{
const auto found = {this, find_filled_bucket(key), true};
if (found.bucket() == _num_buckets)