mirror of
https://github.com/superseriousbusiness/gotosocial.git
synced 2024-11-29 23:22:45 +00:00
c06e6fb656
* update go-structr and go-mutexes with memory usage improvements * bump to go-structr v0.8.4
360 lines
8.7 KiB
Go
360 lines
8.7 KiB
Go
// Copyright 2023 Dolthub, Inc.
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//
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// Licensed under the Apache License, Version 2.0 (the "License");
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// you may not use this file except in compliance with the License.
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// You may obtain a copy of the License at
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//
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// http://www.apache.org/licenses/LICENSE-2.0
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//
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// Unless required by applicable law or agreed to in writing, software
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// distributed under the License is distributed on an "AS IS" BASIS,
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// WITHOUT WARRANTIES OR CONDITIONS OF ANY KIND, either express or implied.
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// See the License for the specific language governing permissions and
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// limitations under the License.
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package swiss
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import (
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"github.com/dolthub/maphash"
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)
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const (
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maxLoadFactor = float32(maxAvgGroupLoad) / float32(groupSize)
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)
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// Map is an open-addressing hash map
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// based on Abseil's flat_hash_map.
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type Map[K comparable, V any] struct {
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ctrl []metadata
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groups []group[K, V]
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hash maphash.Hasher[K]
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resident uint32
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dead uint32
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limit uint32
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}
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// metadata is the h2 metadata array for a group.
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// find operations first probe the controls bytes
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// to filter candidates before matching keys
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type metadata [groupSize]int8
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// group is a group of 16 key-value pairs
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type group[K comparable, V any] struct {
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keys [groupSize]K
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values [groupSize]V
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}
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const (
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h1Mask uint64 = 0xffff_ffff_ffff_ff80
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h2Mask uint64 = 0x0000_0000_0000_007f
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empty int8 = -128 // 0b1000_0000
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tombstone int8 = -2 // 0b1111_1110
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)
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// h1 is a 57 bit hash prefix
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type h1 uint64
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// h2 is a 7 bit hash suffix
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type h2 int8
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// NewMap constructs a Map.
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func NewMap[K comparable, V any](sz uint32) (m *Map[K, V]) {
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groups := numGroups(sz)
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m = &Map[K, V]{
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ctrl: make([]metadata, groups),
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groups: make([]group[K, V], groups),
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hash: maphash.NewHasher[K](),
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limit: groups * maxAvgGroupLoad,
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}
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for i := range m.ctrl {
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m.ctrl[i] = newEmptyMetadata()
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}
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return
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}
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// Has returns true if |key| is present in |m|.
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func (m *Map[K, V]) Has(key K) (ok bool) {
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hi, lo := splitHash(m.hash.Hash(key))
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g := probeStart(hi, len(m.groups))
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for { // inlined find loop
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matches := metaMatchH2(&m.ctrl[g], lo)
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for matches != 0 {
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s := nextMatch(&matches)
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if key == m.groups[g].keys[s] {
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ok = true
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return
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}
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}
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// |key| is not in group |g|,
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// stop probing if we see an empty slot
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matches = metaMatchEmpty(&m.ctrl[g])
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if matches != 0 {
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ok = false
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return
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}
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g += 1 // linear probing
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if g >= uint32(len(m.groups)) {
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g = 0
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}
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}
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}
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// Get returns the |value| mapped by |key| if one exists.
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func (m *Map[K, V]) Get(key K) (value V, ok bool) {
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hi, lo := splitHash(m.hash.Hash(key))
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g := probeStart(hi, len(m.groups))
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for { // inlined find loop
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matches := metaMatchH2(&m.ctrl[g], lo)
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for matches != 0 {
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s := nextMatch(&matches)
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if key == m.groups[g].keys[s] {
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value, ok = m.groups[g].values[s], true
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return
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}
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}
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// |key| is not in group |g|,
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// stop probing if we see an empty slot
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matches = metaMatchEmpty(&m.ctrl[g])
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if matches != 0 {
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ok = false
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return
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}
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g += 1 // linear probing
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if g >= uint32(len(m.groups)) {
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g = 0
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}
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}
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}
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// Put attempts to insert |key| and |value|
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func (m *Map[K, V]) Put(key K, value V) {
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if m.resident >= m.limit {
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m.rehash(m.nextSize())
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}
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hi, lo := splitHash(m.hash.Hash(key))
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g := probeStart(hi, len(m.groups))
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for { // inlined find loop
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matches := metaMatchH2(&m.ctrl[g], lo)
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for matches != 0 {
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s := nextMatch(&matches)
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if key == m.groups[g].keys[s] { // update
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m.groups[g].keys[s] = key
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m.groups[g].values[s] = value
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return
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}
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}
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// |key| is not in group |g|,
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// stop probing if we see an empty slot
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matches = metaMatchEmpty(&m.ctrl[g])
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if matches != 0 { // insert
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s := nextMatch(&matches)
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m.groups[g].keys[s] = key
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m.groups[g].values[s] = value
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m.ctrl[g][s] = int8(lo)
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m.resident++
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return
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}
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g += 1 // linear probing
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if g >= uint32(len(m.groups)) {
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g = 0
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}
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}
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}
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// Delete attempts to remove |key|, returns true successful.
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func (m *Map[K, V]) Delete(key K) (ok bool) {
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hi, lo := splitHash(m.hash.Hash(key))
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g := probeStart(hi, len(m.groups))
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for {
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matches := metaMatchH2(&m.ctrl[g], lo)
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for matches != 0 {
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s := nextMatch(&matches)
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if key == m.groups[g].keys[s] {
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ok = true
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// optimization: if |m.ctrl[g]| contains any empty
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// metadata bytes, we can physically delete |key|
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// rather than placing a tombstone.
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// The observation is that any probes into group |g|
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// would already be terminated by the existing empty
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// slot, and therefore reclaiming slot |s| will not
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// cause premature termination of probes into |g|.
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if metaMatchEmpty(&m.ctrl[g]) != 0 {
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m.ctrl[g][s] = empty
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m.resident--
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} else {
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m.ctrl[g][s] = tombstone
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m.dead++
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}
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var k K
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var v V
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m.groups[g].keys[s] = k
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m.groups[g].values[s] = v
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return
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}
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}
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// |key| is not in group |g|,
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// stop probing if we see an empty slot
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matches = metaMatchEmpty(&m.ctrl[g])
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if matches != 0 { // |key| absent
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ok = false
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return
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}
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g += 1 // linear probing
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if g >= uint32(len(m.groups)) {
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g = 0
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}
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}
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}
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// Iter iterates the elements of the Map, passing them to the callback.
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// It guarantees that any key in the Map will be visited only once, and
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// for un-mutated Maps, every key will be visited once. If the Map is
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// Mutated during iteration, mutations will be reflected on return from
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// Iter, but the set of keys visited by Iter is non-deterministic.
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func (m *Map[K, V]) Iter(cb func(k K, v V) (stop bool)) {
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// take a consistent view of the table in case
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// we rehash during iteration
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ctrl, groups := m.ctrl, m.groups
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// pick a random starting group
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g := randIntN(len(groups))
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for n := 0; n < len(groups); n++ {
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for s, c := range ctrl[g] {
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if c == empty || c == tombstone {
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continue
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}
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k, v := groups[g].keys[s], groups[g].values[s]
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if stop := cb(k, v); stop {
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return
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}
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}
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g++
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if g >= uint32(len(groups)) {
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g = 0
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}
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}
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}
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// Clear removes all elements from the Map.
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func (m *Map[K, V]) Clear() {
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for i, c := range m.ctrl {
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for j := range c {
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m.ctrl[i][j] = empty
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}
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}
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var k K
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var v V
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for i := range m.groups {
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g := &m.groups[i]
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for i := range g.keys {
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g.keys[i] = k
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g.values[i] = v
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}
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}
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m.resident, m.dead = 0, 0
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}
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// Count returns the number of elements in the Map.
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func (m *Map[K, V]) Count() int {
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return int(m.resident - m.dead)
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}
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// Capacity returns the number of additional elements
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// the can be added to the Map before resizing.
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func (m *Map[K, V]) Capacity() int {
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return int(m.limit - m.resident)
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}
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// find returns the location of |key| if present, or its insertion location if absent.
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// for performance, find is manually inlined into public methods.
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func (m *Map[K, V]) find(key K, hi h1, lo h2) (g, s uint32, ok bool) {
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g = probeStart(hi, len(m.groups))
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for {
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matches := metaMatchH2(&m.ctrl[g], lo)
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for matches != 0 {
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s = nextMatch(&matches)
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if key == m.groups[g].keys[s] {
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return g, s, true
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}
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}
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// |key| is not in group |g|,
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// stop probing if we see an empty slot
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matches = metaMatchEmpty(&m.ctrl[g])
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if matches != 0 {
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s = nextMatch(&matches)
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return g, s, false
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}
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g += 1 // linear probing
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if g >= uint32(len(m.groups)) {
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g = 0
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}
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}
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}
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func (m *Map[K, V]) nextSize() (n uint32) {
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n = uint32(len(m.groups)) * 2
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if m.dead >= (m.resident / 2) {
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n = uint32(len(m.groups))
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}
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return
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}
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func (m *Map[K, V]) rehash(n uint32) {
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groups, ctrl := m.groups, m.ctrl
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m.groups = make([]group[K, V], n)
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m.ctrl = make([]metadata, n)
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for i := range m.ctrl {
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m.ctrl[i] = newEmptyMetadata()
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}
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m.hash = maphash.NewSeed(m.hash)
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m.limit = n * maxAvgGroupLoad
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m.resident, m.dead = 0, 0
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for g := range ctrl {
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for s := range ctrl[g] {
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c := ctrl[g][s]
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if c == empty || c == tombstone {
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continue
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}
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m.Put(groups[g].keys[s], groups[g].values[s])
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}
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}
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}
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func (m *Map[K, V]) loadFactor() float32 {
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slots := float32(len(m.groups) * groupSize)
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return float32(m.resident-m.dead) / slots
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}
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// numGroups returns the minimum number of groups needed to store |n| elems.
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func numGroups(n uint32) (groups uint32) {
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groups = (n + maxAvgGroupLoad - 1) / maxAvgGroupLoad
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if groups == 0 {
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groups = 1
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}
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return
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}
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func newEmptyMetadata() (meta metadata) {
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for i := range meta {
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meta[i] = empty
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}
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return
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}
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func splitHash(h uint64) (h1, h2) {
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return h1((h & h1Mask) >> 7), h2(h & h2Mask)
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}
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func probeStart(hi h1, groups int) uint32 {
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return fastModN(uint32(hi), uint32(groups))
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}
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// lemire.me/blog/2016/06/27/a-fast-alternative-to-the-modulo-reduction/
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func fastModN(x, n uint32) uint32 {
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return uint32((uint64(x) * uint64(n)) >> 32)
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}
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// randIntN returns a random number in the interval [0, n).
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func randIntN(n int) uint32 {
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return fastModN(fastrand(), uint32(n))
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}
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