mirror of
https://source.quilibrium.com/quilibrium/ceremonyclient.git
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321 lines
9.0 KiB
Go
321 lines
9.0 KiB
Go
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// Copyright 2020 The LevelDB-Go and Pebble Authors. All rights reserved. Use
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// of this source code is governed by a BSD-style license that can be found in
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// the LICENSE file.
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package cache
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import (
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"fmt"
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"math/bits"
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"os"
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"runtime/debug"
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"strings"
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"time"
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"unsafe"
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"github.com/cockroachdb/pebble/internal/invariants"
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"github.com/cockroachdb/pebble/internal/manual"
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)
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var hashSeed = uint64(time.Now().UnixNano())
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// Fibonacci hash: https://probablydance.com/2018/06/16/fibonacci-hashing-the-optimization-that-the-world-forgot-or-a-better-alternative-to-integer-modulo/
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func robinHoodHash(k key, shift uint32) uint32 {
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const m = 11400714819323198485
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h := hashSeed
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h ^= k.id * m
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h ^= uint64(k.fileNum.FileNum()) * m
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h ^= k.offset * m
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return uint32(h >> shift)
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}
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type robinHoodEntry struct {
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key key
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// Note that value may point to a Go allocated object (if the "invariants"
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// build tag was specified), even though the memory for the entry itself is
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// manually managed. This is technically a volation of the Cgo pointer rules:
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//
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// https://golang.org/cmd/cgo/#hdr-Passing_pointers
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//
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// Specifically, Go pointers should not be stored in C allocated memory. The
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// reason for this rule is that the Go GC will not look at C allocated memory
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// to find pointers to Go objects. If the only reference to a Go object is
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// stored in C allocated memory, the object will be reclaimed. What makes
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// this "safe" is that the Cache guarantees that there are other pointers to
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// the entry and shard which will keep them alive. In particular, every Go
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// allocated entry in the cache is referenced by the shard.entries map. And
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// every shard is referenced by the Cache.shards map.
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value *entry
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// The distance the entry is from its desired position.
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dist uint32
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}
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type robinHoodEntries struct {
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ptr unsafe.Pointer
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len uint32
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}
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func newRobinHoodEntries(n uint32) robinHoodEntries {
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size := uintptr(n) * unsafe.Sizeof(robinHoodEntry{})
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return robinHoodEntries{
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ptr: unsafe.Pointer(&(manual.New(int(size)))[0]),
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len: n,
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}
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}
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func (e robinHoodEntries) at(i uint32) *robinHoodEntry {
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return (*robinHoodEntry)(unsafe.Pointer(uintptr(e.ptr) +
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uintptr(i)*unsafe.Sizeof(robinHoodEntry{})))
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}
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func (e robinHoodEntries) free() {
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size := uintptr(e.len) * unsafe.Sizeof(robinHoodEntry{})
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buf := (*[manual.MaxArrayLen]byte)(e.ptr)[:size:size]
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manual.Free(buf)
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}
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// robinHoodMap is an implementation of Robin Hood hashing. Robin Hood hashing
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// is an open-address hash table using linear probing. The twist is that the
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// linear probe distance is reduced by moving existing entries when inserting
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// and deleting. This is accomplished by keeping track of how far an entry is
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// from its "desired" slot (hash of key modulo number of slots). During
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// insertion, if the new entry being inserted is farther from its desired slot
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// than the target entry, we swap the target and new entry. This effectively
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// steals from the "rich" target entry and gives to the "poor" new entry (thus
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// the origin of the name).
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//
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// An extension over the base Robin Hood hashing idea comes from
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// https://probablydance.com/2017/02/26/i-wrote-the-fastest-hashtable/. A cap
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// is placed on the max distance an entry can be from its desired slot. When
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// this threshold is reached during insertion, the size of the table is doubled
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// and insertion is restarted. Additionally, the entries slice is given "max
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// dist" extra entries on the end. The very last entry in the entries slice is
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// never used and acts as a sentinel which terminates loops. The previous
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// maxDist-1 entries act as the extra entries. For example, if the size of the
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// table is 2, maxDist is computed as 4 and the actual size of the entry slice
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// is 6.
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//
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// +---+---+---+---+---+---+
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// | 0 | 1 | 2 | 3 | 4 | 5 |
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// +---+---+---+---+---+---+
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// ^
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// size
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//
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// In this scenario, the target entry for a key will always be in the range
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// [0,1]. Valid entries may reside in the range [0,4] due to the linear probing
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// of up to maxDist entries. The entry at index 5 will never contain a value,
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// and instead acts as a sentinel (its distance is always 0). The max distance
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// threshold is set to log2(num-entries). This ensures that retrieval is O(log
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// N), though note that N is the number of total entries, not the count of
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// valid entries.
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//
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// Deletion is implemented via the backward shift delete mechanism instead of
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// tombstones. This preserves the performance of the table in the presence of
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// deletions. See
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// http://codecapsule.com/2013/11/17/robin-hood-hashing-backward-shift-deletion
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// for details.
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type robinHoodMap struct {
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entries robinHoodEntries
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size uint32
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shift uint32
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count uint32
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maxDist uint32
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}
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func maxDistForSize(size uint32) uint32 {
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desired := uint32(bits.Len32(size))
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if desired < 4 {
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desired = 4
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}
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return desired
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}
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func newRobinHoodMap(initialCapacity int) *robinHoodMap {
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m := &robinHoodMap{}
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m.init(initialCapacity)
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// Note: this is a no-op if invariants are disabled or race is enabled.
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invariants.SetFinalizer(m, func(obj interface{}) {
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m := obj.(*robinHoodMap)
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if m.entries.ptr != nil {
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fmt.Fprintf(os.Stderr, "%p: robin-hood map not freed\n", m)
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os.Exit(1)
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}
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})
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return m
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}
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func (m *robinHoodMap) init(initialCapacity int) {
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if initialCapacity < 1 {
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initialCapacity = 1
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}
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targetSize := 1 << (uint(bits.Len(uint(2*initialCapacity-1))) - 1)
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m.rehash(uint32(targetSize))
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}
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func (m *robinHoodMap) free() {
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if m.entries.ptr != nil {
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m.entries.free()
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m.entries.ptr = nil
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}
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}
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func (m *robinHoodMap) rehash(size uint32) {
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oldEntries := m.entries
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m.size = size
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m.shift = uint32(64 - bits.Len32(m.size-1))
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m.maxDist = maxDistForSize(size)
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m.entries = newRobinHoodEntries(size + m.maxDist)
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m.count = 0
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for i := uint32(0); i < oldEntries.len; i++ {
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e := oldEntries.at(i)
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if e.value != nil {
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m.Put(e.key, e.value)
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}
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}
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if oldEntries.ptr != nil {
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oldEntries.free()
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}
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}
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// Find an entry containing the specified value. This is intended to be used
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// from debug and test code.
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func (m *robinHoodMap) findByValue(v *entry) *robinHoodEntry {
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for i := uint32(0); i < m.entries.len; i++ {
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e := m.entries.at(i)
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if e.value == v {
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return e
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}
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}
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return nil
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}
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func (m *robinHoodMap) Count() int {
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return int(m.count)
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}
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func (m *robinHoodMap) Put(k key, v *entry) {
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maybeExists := true
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n := robinHoodEntry{key: k, value: v, dist: 0}
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for i := robinHoodHash(k, m.shift); ; i++ {
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e := m.entries.at(i)
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if maybeExists && k == e.key {
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// Entry already exists: overwrite.
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e.value = n.value
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m.checkEntry(i)
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return
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}
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if e.value == nil {
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// Found an empty entry: insert here.
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*e = n
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m.count++
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m.checkEntry(i)
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return
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}
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if e.dist < n.dist {
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// Swap the new entry with the current entry because the current is
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// rich. We then continue to loop, looking for a new location for the
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// current entry. Note that this is also the not-found condition for
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// retrieval, which means that "k" is not present in the map. See Get().
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n, *e = *e, n
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m.checkEntry(i)
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maybeExists = false
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}
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// The new entry gradually moves away from its ideal position.
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n.dist++
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// If we've reached the max distance threshold, grow the table and restart
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// the insertion.
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if n.dist == m.maxDist {
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m.rehash(2 * m.size)
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i = robinHoodHash(n.key, m.shift) - 1
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n.dist = 0
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maybeExists = false
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}
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}
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}
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func (m *robinHoodMap) Get(k key) *entry {
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var dist uint32
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for i := robinHoodHash(k, m.shift); ; i++ {
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e := m.entries.at(i)
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if k == e.key {
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// Found.
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return e.value
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}
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if e.dist < dist {
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// Not found.
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return nil
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}
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dist++
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}
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}
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func (m *robinHoodMap) Delete(k key) {
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var dist uint32
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for i := robinHoodHash(k, m.shift); ; i++ {
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e := m.entries.at(i)
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if k == e.key {
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m.checkEntry(i)
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// We found the entry to delete. Shift the following entries backwards
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// until the next empty value or entry with a zero distance. Note that
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// empty values are guaranteed to have "dist == 0".
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m.count--
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for j := i + 1; ; j++ {
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t := m.entries.at(j)
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if t.dist == 0 {
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*e = robinHoodEntry{}
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return
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}
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e.key = t.key
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e.value = t.value
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e.dist = t.dist - 1
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e = t
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m.checkEntry(j)
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}
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}
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if dist > e.dist {
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// Not found.
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return
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}
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dist++
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}
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}
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func (m *robinHoodMap) checkEntry(i uint32) {
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if invariants.Enabled {
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e := m.entries.at(i)
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if e.value != nil {
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pos := robinHoodHash(e.key, m.shift)
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if (uint32(i) - pos) != e.dist {
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fmt.Fprintf(os.Stderr, "%d: invalid dist=%d, expected %d: %s\n%s",
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i, e.dist, uint32(i)-pos, e.key, debug.Stack())
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os.Exit(1)
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}
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if e.dist > m.maxDist {
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fmt.Fprintf(os.Stderr, "%d: invalid dist=%d > maxDist=%d: %s\n%s",
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i, e.dist, m.maxDist, e.key, debug.Stack())
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os.Exit(1)
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}
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}
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}
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}
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func (m *robinHoodMap) String() string {
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var buf strings.Builder
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fmt.Fprintf(&buf, "count: %d\n", m.count)
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for i := uint32(0); i < m.entries.len; i++ {
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e := m.entries.at(i)
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if e.value != nil {
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fmt.Fprintf(&buf, "%d: [%s,%p,%d]\n", i, e.key, e.value, e.dist)
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}
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}
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return buf.String()
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}
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