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package freelist
import (
"fmt"
"reflect"
"sort"
"go.etcd.io/bbolt/internal/common"
)
// pidSet holds the set of starting pgids which have the same span size
type pidSet map[common.Pgid]struct{}
type hashMap struct {
*shared
freePagesCount uint64 // count of free pages(hashmap version)
freemaps map[uint64]pidSet // key is the size of continuous pages(span), value is a set which contains the starting pgids of same size
forwardMap map[common.Pgid]uint64 // key is start pgid, value is its span size
backwardMap map[common.Pgid]uint64 // key is end pgid, value is its span size
}
func (f *hashMap) Init(pgids common.Pgids) {
// reset the counter when freelist init
f.freePagesCount = 0
f.freemaps = make(map[uint64]pidSet)
f.forwardMap = make(map[common.Pgid]uint64)
f.backwardMap = make(map[common.Pgid]uint64)
if len(pgids) == 0 {
return
}
if !sort.SliceIsSorted([]common.Pgid(pgids), func(i, j int) bool { return pgids[i] < pgids[j] }) {
panic("pgids not sorted")
}
size := uint64(1)
start := pgids[0]
for i := 1; i < len(pgids); i++ {
// continuous page
if pgids[i] == pgids[i-1]+1 {
size++
} else {
f.addSpan(start, size)
size = 1
start = pgids[i]
}
}
// init the tail
if size != 0 && start != 0 {
f.addSpan(start, size)
}
f.reindex()
}
func (f *hashMap) Allocate(txid common.Txid, n int) common.Pgid {
if n == 0 {
return 0
}
// if we have a exact size match just return short path
if bm, ok := f.freemaps[uint64(n)]; ok {
for pid := range bm {
// remove the span
f.delSpan(pid, uint64(n))
f.allocs[pid] = txid
for i := common.Pgid(0); i < common.Pgid(n); i++ {
delete(f.cache, pid+i)
}
return pid
}
}
// lookup the map to find larger span
for size, bm := range f.freemaps {
if size < uint64(n) {
continue
}
for pid := range bm {
// remove the initial
f.delSpan(pid, size)
f.allocs[pid] = txid
remain := size - uint64(n)
// add remain span
f.addSpan(pid+common.Pgid(n), remain)
for i := common.Pgid(0); i < common.Pgid(n); i++ {
delete(f.cache, pid+i)
}
return pid
}
}
return 0
}
func (f *hashMap) FreeCount() int {
common.Verify(func() {
expectedFreePageCount := f.hashmapFreeCountSlow()
common.Assert(int(f.freePagesCount) == expectedFreePageCount,
"freePagesCount (%d) is out of sync with free pages map (%d)", f.freePagesCount, expectedFreePageCount)
})
return int(f.freePagesCount)
}
func (f *hashMap) freePageIds() common.Pgids {
count := f.FreeCount()
if count == 0 {
return common.Pgids{}
}
m := make([]common.Pgid, 0, count)
startPageIds := make([]common.Pgid, 0, len(f.forwardMap))
for k := range f.forwardMap {
startPageIds = append(startPageIds, k)
}
sort.Sort(common.Pgids(startPageIds))
for _, start := range startPageIds {
if size, ok := f.forwardMap[start]; ok {
for i := 0; i < int(size); i++ {
m = append(m, start+common.Pgid(i))
}
}
}
return m
}
func (f *hashMap) hashmapFreeCountSlow() int {
count := 0
for _, size := range f.forwardMap {
count += int(size)
}
return count
}
func (f *hashMap) addSpan(start common.Pgid, size uint64) {
f.backwardMap[start-1+common.Pgid(size)] = size
f.forwardMap[start] = size
if _, ok := f.freemaps[size]; !ok {
f.freemaps[size] = make(map[common.Pgid]struct{})
}
f.freemaps[size][start] = struct{}{}
f.freePagesCount += size
}
func (f *hashMap) delSpan(start common.Pgid, size uint64) {
delete(f.forwardMap, start)
delete(f.backwardMap, start+common.Pgid(size-1))
delete(f.freemaps[size], start)
if len(f.freemaps[size]) == 0 {
delete(f.freemaps, size)
}
f.freePagesCount -= size
}
func (f *hashMap) mergeSpans(ids common.Pgids) {
common.Verify(func() {
ids1Freemap := f.idsFromFreemaps()
ids2Forward := f.idsFromForwardMap()
ids3Backward := f.idsFromBackwardMap()
if !reflect.DeepEqual(ids1Freemap, ids2Forward) {
panic(fmt.Sprintf("Detected mismatch, f.freemaps: %v, f.forwardMap: %v", f.freemaps, f.forwardMap))
}
if !reflect.DeepEqual(ids1Freemap, ids3Backward) {
panic(fmt.Sprintf("Detected mismatch, f.freemaps: %v, f.backwardMap: %v", f.freemaps, f.backwardMap))
}
sort.Sort(ids)
prev := common.Pgid(0)
for _, id := range ids {
// The ids shouldn't have duplicated free ID.
if prev == id {
panic(fmt.Sprintf("detected duplicated free ID: %d in ids: %v", id, ids))
}
prev = id
// The ids shouldn't have any overlap with the existing f.freemaps.
if _, ok := ids1Freemap[id]; ok {
panic(fmt.Sprintf("detected overlapped free page ID: %d between ids: %v and existing f.freemaps: %v", id, ids, f.freemaps))
}
}
})
for _, id := range ids {
// try to see if we can merge and update
f.mergeWithExistingSpan(id)
}
}
// mergeWithExistingSpan merges pid to the existing free spans, try to merge it backward and forward
func (f *hashMap) mergeWithExistingSpan(pid common.Pgid) {
prev := pid - 1
next := pid + 1
preSize, mergeWithPrev := f.backwardMap[prev]
nextSize, mergeWithNext := f.forwardMap[next]
newStart := pid
newSize := uint64(1)
if mergeWithPrev {
//merge with previous span
start := prev + 1 - common.Pgid(preSize)
f.delSpan(start, preSize)
newStart -= common.Pgid(preSize)
newSize += preSize
}
if mergeWithNext {
// merge with next span
f.delSpan(next, nextSize)
newSize += nextSize
}
f.addSpan(newStart, newSize)
}
// idsFromFreemaps get all free page IDs from f.freemaps.
// used by test only.
func (f *hashMap) idsFromFreemaps() map[common.Pgid]struct{} {
ids := make(map[common.Pgid]struct{})
for size, idSet := range f.freemaps {
for start := range idSet {
for i := 0; i < int(size); i++ {
id := start + common.Pgid(i)
if _, ok := ids[id]; ok {
panic(fmt.Sprintf("detected duplicated free page ID: %d in f.freemaps: %v", id, f.freemaps))
}
ids[id] = struct{}{}
}
}
}
return ids
}
// idsFromForwardMap get all free page IDs from f.forwardMap.
// used by test only.
func (f *hashMap) idsFromForwardMap() map[common.Pgid]struct{} {
ids := make(map[common.Pgid]struct{})
for start, size := range f.forwardMap {
for i := 0; i < int(size); i++ {
id := start + common.Pgid(i)
if _, ok := ids[id]; ok {
panic(fmt.Sprintf("detected duplicated free page ID: %d in f.forwardMap: %v", id, f.forwardMap))
}
ids[id] = struct{}{}
}
}
return ids
}
// idsFromBackwardMap get all free page IDs from f.backwardMap.
// used by test only.
func (f *hashMap) idsFromBackwardMap() map[common.Pgid]struct{} {
ids := make(map[common.Pgid]struct{})
for end, size := range f.backwardMap {
for i := 0; i < int(size); i++ {
id := end - common.Pgid(i)
if _, ok := ids[id]; ok {
panic(fmt.Sprintf("detected duplicated free page ID: %d in f.backwardMap: %v", id, f.backwardMap))
}
ids[id] = struct{}{}
}
}
return ids
}
func NewHashMapFreelist() Interface {
hm := &hashMap{
shared: newShared(),
freemaps: make(map[uint64]pidSet),
forwardMap: make(map[common.Pgid]uint64),
backwardMap: make(map[common.Pgid]uint64),
}
hm.Interface = hm
return hm
}
|
