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hashmap.go
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hashmap.go
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package hashmap
import (
"bytes"
"fmt"
"reflect"
"strconv"
"sync/atomic"
"unsafe"
)
// DefaultSize is the default size for a zero allocated map
const DefaultSize = 8
// MaxFillRate is the maximum fill rate for the slice before a resize will happen.
const MaxFillRate = 50
type (
hashMapData struct {
keyshifts uintptr // Pointer size - log2 of array size, to be used as index in the data array
count uintptr // count of filled elements in the slice
data unsafe.Pointer // pointer to slice data array
index []*ListElement // storage for the slice for the garbage collector to not clean it up
}
// HashMap implements a read optimized hash map.
HashMap struct {
datamap unsafe.Pointer // pointer to a map instance that gets replaced if the map resizes
linkedlist unsafe.Pointer // key sorted linked list of elements
resizing uintptr // flag that marks a resizing operation in progress
}
// KeyValue represents a key/value that is returned by the iterator.
KeyValue struct {
Key interface{}
Value interface{}
}
)
// New returns a new HashMap instance with a specific initialization size.
func New(size uintptr) *HashMap {
m := &HashMap{}
m.allocate(size)
return m
}
// Len returns the number of elements within the map.
func (m *HashMap) Len() int {
list := m.list()
return list.Len()
}
func (m *HashMap) mapData() *hashMapData {
return (*hashMapData)(atomic.LoadPointer(&m.datamap))
}
func (m *HashMap) list() *List {
return (*List)(atomic.LoadPointer(&m.linkedlist))
}
func (m *HashMap) allocate(newSize uintptr) {
list := NewList()
// atomic swap in case of another allocation happening concurrently
if atomic.CompareAndSwapPointer(&m.linkedlist, nil, unsafe.Pointer(list)) {
if atomic.CompareAndSwapUintptr(&m.resizing, uintptr(0), uintptr(1)) {
m.grow(newSize, false)
}
}
}
// Fillrate returns the fill rate of the map as an percentage integer.
func (m *HashMap) Fillrate() uintptr {
data := m.mapData()
count := atomic.LoadUintptr(&data.count)
l := uintptr(len(data.index))
return (count * 100) / l
}
func (m *HashMap) resizeNeeded(data *hashMapData, count uintptr) bool {
l := uintptr(len(data.index))
if l == 0 {
return false
}
fillRate := (count * 100) / l
return fillRate > MaxFillRate
}
func (m *HashMap) indexElement(hashedKey uintptr) (data *hashMapData, item *ListElement) {
data = m.mapData()
if data == nil {
return nil, nil
}
index := hashedKey >> data.keyshifts
ptr := (*unsafe.Pointer)(unsafe.Pointer(uintptr(data.data) + index*intSizeBytes))
item = (*ListElement)(atomic.LoadPointer(ptr))
return data, item
}
/* The Golang 1.10.1 compiler dons not inline this function well
func (m *HashMap) searchItem(item *ListElement, key interface{}, keyHash uintptr) (value interface{}, ok bool) {
for item != nil {
if item.keyHash == keyHash && item.key == key {
return item.Value(), true
}
if item.keyHash > keyHash {
return nil, false
}
item = item.Next()
}
return nil, false
}
*/
// Del deletes the key from the map.
func (m *HashMap) Del(key interface{}) {
list := m.list()
if list == nil {
return
}
h := getKeyHash(key)
var element *ListElement
for _, element = m.indexElement(h); element != nil; element = element.Next() {
if element.keyHash == h && element.key == key {
break
}
if element.keyHash > h {
return
}
}
if element == nil {
return
}
m.deleteElement(element)
list.Delete(element)
}
// DelHashedKey deletes the hashed key from the map.
func (m *HashMap) DelHashedKey(hashedKey uintptr) {
list := m.list()
if list == nil {
return
}
_, element := m.indexElement(hashedKey)
if element == nil {
return
}
m.deleteElement(element)
list.Delete(element)
}
// deleteElement deletes an element from index
func (m *HashMap) deleteElement(element *ListElement) {
for {
data := m.mapData()
index := element.keyHash >> data.keyshifts
ptr := (*unsafe.Pointer)(unsafe.Pointer(uintptr(data.data) + index*intSizeBytes))
next := element.Next()
if next != nil && element.keyHash>>data.keyshifts != index {
next = nil // do not set index to next item if it's not the same slice index
}
atomic.CompareAndSwapPointer(ptr, unsafe.Pointer(element), unsafe.Pointer(next))
currentdata := m.mapData()
if data == currentdata { // check that no resize happened
break
}
}
}
// Insert sets the value under the specified key to the map if it does not exist yet.
// If a resizing operation is happening concurrently while calling Set, the item might show up in the map only after the resize operation is finished.
// Returns true if the item was inserted or false if it existed.
func (m *HashMap) Insert(key interface{}, value interface{}) bool {
h := getKeyHash(key)
element := &ListElement{
key: key,
keyHash: h,
value: unsafe.Pointer(&value),
}
return m.insertListElement(element, false)
}
// Set sets the value under the specified key to the map. An existing item for this key will be overwritten.
// If a resizing operation is happening concurrently while calling Set, the item might show up in the map only after the resize operation is finished.
func (m *HashMap) Set(key interface{}, value interface{}) {
h := getKeyHash(key)
element := &ListElement{
key: key,
keyHash: h,
value: unsafe.Pointer(&value),
}
m.insertListElement(element, true)
}
// SetHashedKey sets the value under the specified hash key to the map. An existing item for this key will be overwritten.
// You can use this function if your keys are already hashes and you want to avoid another hashing of the key.
// Do not use non hashes as keys for this function, the performance would decrease!
// If a resizing operation is happening concurrently while calling Set, the item might show up in the map only after the resize operation is finished.
func (m *HashMap) SetHashedKey(hashedKey uintptr, value interface{}) {
element := &ListElement{
key: hashedKey,
keyHash: hashedKey,
value: unsafe.Pointer(&value),
}
m.insertListElement(element, true)
}
func (m *HashMap) insertListElement(element *ListElement, update bool) bool {
for {
data, existing := m.indexElement(element.keyHash)
if data == nil {
m.allocate(DefaultSize)
continue // read mapdata and slice item again
}
list := m.list()
if update {
if !list.AddOrUpdate(element, existing) {
continue // a concurrent add did interfere, try again
}
} else {
existed, inserted := list.Add(element, existing)
if existed {
return false
}
if !inserted {
continue
}
}
count := data.addItemToIndex(element)
if m.resizeNeeded(data, count) {
if atomic.CompareAndSwapUintptr(&m.resizing, uintptr(0), uintptr(1)) {
go m.grow(0, true)
}
}
return true
}
}
// CasHashedKey performs a compare and swap operation sets the value under the specified hash key to the map. An existing item for this key will be overwritten.
func (m *HashMap) CasHashedKey(hashedKey uintptr, from, to interface{}) bool {
data, existing := m.indexElement(hashedKey)
if data == nil {
return false
}
list := m.list()
if list == nil {
return false
}
element := &ListElement{
key: hashedKey,
keyHash: hashedKey,
value: unsafe.Pointer(&to),
}
return list.Cas(element, from, existing)
}
// Cas performs a compare and swap operation sets the value under the specified hash key to the map. An existing item for this key will be overwritten.
func (m *HashMap) Cas(key, from, to interface{}) bool {
h := getKeyHash(key)
return m.CasHashedKey(h, from, to)
}
// adds an item to the index if needed and returns the new item counter if it changed, otherwise 0
func (mapData *hashMapData) addItemToIndex(item *ListElement) uintptr {
index := item.keyHash >> mapData.keyshifts
ptr := (*unsafe.Pointer)(unsafe.Pointer(uintptr(mapData.data) + index*intSizeBytes))
for { // loop until the smallest key hash is in the index
element := (*ListElement)(atomic.LoadPointer(ptr)) // get the current item in the index
if element == nil { // no item yet at this index
if atomic.CompareAndSwapPointer(ptr, nil, unsafe.Pointer(item)) {
return atomic.AddUintptr(&mapData.count, 1)
}
continue // a new item was inserted concurrently, retry
}
if item.keyHash < element.keyHash {
// the new item is the smallest for this index?
if !atomic.CompareAndSwapPointer(ptr, unsafe.Pointer(element), unsafe.Pointer(item)) {
continue // a new item was inserted concurrently, retry
}
}
return 0
}
}
// Grow resizes the hashmap to a new size, gets rounded up to next power of 2.
// To double the size of the hashmap use newSize 0.
// This function returns immediately, the resize operation is done in a goroutine.
// No resizing is done in case of another resize operation already being in progress.
func (m *HashMap) Grow(newSize uintptr) {
if atomic.CompareAndSwapUintptr(&m.resizing, uintptr(0), uintptr(1)) {
go m.grow(newSize, true)
}
}
func (m *HashMap) grow(newSize uintptr, loop bool) {
defer atomic.CompareAndSwapUintptr(&m.resizing, uintptr(1), uintptr(0))
for {
data := m.mapData()
if newSize == 0 {
newSize = uintptr(len(data.index)) << 1
} else {
newSize = roundUpPower2(newSize)
}
index := make([]*ListElement, newSize)
header := (*reflect.SliceHeader)(unsafe.Pointer(&index))
newdata := &hashMapData{
keyshifts: strconv.IntSize - log2(newSize),
data: unsafe.Pointer(header.Data), // use address of slice data storage
index: index,
}
m.fillIndexItems(newdata) // initialize new index slice with longer keys
atomic.StorePointer(&m.datamap, unsafe.Pointer(newdata))
m.fillIndexItems(newdata) // make sure that the new index is up to date with the current state of the linked list
if !loop {
break
}
// check if a new resize needs to be done already
count := uintptr(m.Len())
if !m.resizeNeeded(newdata, count) {
break
}
newSize = 0 // 0 means double the current size
}
}
func (m *HashMap) fillIndexItems(mapData *hashMapData) {
list := m.list()
if list == nil {
return
}
first := list.First()
item := first
lastIndex := uintptr(0)
for item != nil {
index := item.keyHash >> mapData.keyshifts
if item == first || index != lastIndex { // store item with smallest hash key for every index
mapData.addItemToIndex(item)
lastIndex = index
}
item = item.Next()
}
}
// String returns the map as a string, only hashed keys are printed.
func (m *HashMap) String() string {
list := m.list()
if list == nil {
return "[]"
}
buffer := bytes.NewBufferString("")
buffer.WriteRune('[')
first := list.First()
item := first
for item != nil {
if item != first {
buffer.WriteRune(',')
}
fmt.Fprint(buffer, item.keyHash)
item = item.Next()
}
buffer.WriteRune(']')
return buffer.String()
}
// Iter returns an iterator which could be used in a for range loop.
// The order of the items is sorted by hash keys.
func (m *HashMap) Iter() <-chan KeyValue {
ch := make(chan KeyValue) // do not use a size here since items can get added during iteration
go func() {
list := m.list()
if list == nil {
close(ch)
return
}
item := list.First()
for item != nil {
value := item.Value()
ch <- KeyValue{item.key, value}
item = item.Next()
}
close(ch)
}()
return ch
}