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package needle_map
import ( "sort" "sync"
. "github.com/chrislusf/seaweedfs/weed/storage/types" )
const ( batch = 100000 )
type SectionalNeedleId uint32
const SectionalNeedleIdLimit = 1<<32 - 1
type SectionalNeedleValue struct { Key SectionalNeedleId OffsetLower OffsetLower `comment:"Volume offset"` //since aligned to 8 bytes, range is 4G*8=32G
Size Size `comment:"Size of the data portion"` }
type SectionalNeedleValueExtra struct { OffsetHigher OffsetHigher }
type CompactSection struct { sync.RWMutex values []SectionalNeedleValue valuesExtra []SectionalNeedleValueExtra overflow Overflow overflowExtra OverflowExtra start NeedleId end NeedleId counter int }
type Overflow []SectionalNeedleValue type OverflowExtra []SectionalNeedleValueExtra
func NewCompactSection(start NeedleId) *CompactSection { return &CompactSection{ values: make([]SectionalNeedleValue, batch), valuesExtra: make([]SectionalNeedleValueExtra, batch), overflow: Overflow(make([]SectionalNeedleValue, 0)), overflowExtra: OverflowExtra(make([]SectionalNeedleValueExtra, 0)), start: start, } }
//return old entry size
func (cs *CompactSection) Set(key NeedleId, offset Offset, size Size) (oldOffset Offset, oldSize Size) { cs.Lock() if key > cs.end { cs.end = key } skey := SectionalNeedleId(key - cs.start) if i := cs.binarySearchValues(skey); i >= 0 { oldOffset.OffsetHigher, oldOffset.OffsetLower, oldSize = cs.valuesExtra[i].OffsetHigher, cs.values[i].OffsetLower, cs.values[i].Size //println("key", key, "old size", ret)
cs.valuesExtra[i].OffsetHigher, cs.values[i].OffsetLower, cs.values[i].Size = offset.OffsetHigher, offset.OffsetLower, size } else { needOverflow := cs.counter >= batch needOverflow = needOverflow || cs.counter > 0 && cs.values[cs.counter-1].Key > skey if needOverflow { lookBackIndex := cs.counter - 128 if lookBackIndex < 0 { lookBackIndex = 0 } if cs.counter < batch && cs.values[lookBackIndex].Key < skey { // still has capacity and only partially out of order
p := &cs.values[cs.counter] p.Key, cs.valuesExtra[cs.counter].OffsetHigher, p.OffsetLower, p.Size = skey, offset.OffsetHigher, offset.OffsetLower, size //println("added index", cs.counter, "key", key, cs.values[cs.counter].Key)
for x := cs.counter - 1; x >= lookBackIndex; x-- { if cs.values[x].Key > cs.values[x+1].Key { cs.values[x], cs.values[x+1] = cs.values[x+1], cs.values[x] cs.valuesExtra[x], cs.valuesExtra[x+1] = cs.valuesExtra[x+1], cs.valuesExtra[x] } else { break } } cs.counter++ } else { //println("start", cs.start, "counter", cs.counter, "key", key)
if oldValueExtra, oldValue, found := cs.findOverflowEntry(skey); found { oldOffset.OffsetHigher, oldOffset.OffsetLower, oldSize = oldValueExtra.OffsetHigher, oldValue.OffsetLower, oldValue.Size } cs.setOverflowEntry(skey, offset, size) } } else { p := &cs.values[cs.counter] p.Key, cs.valuesExtra[cs.counter].OffsetHigher, p.OffsetLower, p.Size = skey, offset.OffsetHigher, offset.OffsetLower, size //println("added index", cs.counter, "key", key, cs.values[cs.counter].Key)
cs.counter++ } } cs.Unlock() return }
func (cs *CompactSection) setOverflowEntry(skey SectionalNeedleId, offset Offset, size Size) { needleValue := SectionalNeedleValue{Key: skey, OffsetLower: offset.OffsetLower, Size: size} needleValueExtra := SectionalNeedleValueExtra{OffsetHigher: offset.OffsetHigher} insertCandidate := sort.Search(len(cs.overflow), func(i int) bool { return cs.overflow[i].Key >= needleValue.Key }) if insertCandidate != len(cs.overflow) && cs.overflow[insertCandidate].Key == needleValue.Key { cs.overflow[insertCandidate] = needleValue } else { cs.overflow = append(cs.overflow, needleValue) cs.overflowExtra = append(cs.overflowExtra, needleValueExtra) for i := len(cs.overflow) - 1; i > insertCandidate; i-- { cs.overflow[i] = cs.overflow[i-1] cs.overflowExtra[i] = cs.overflowExtra[i-1] } cs.overflow[insertCandidate] = needleValue cs.overflowExtra[insertCandidate] = needleValueExtra } }
func (cs *CompactSection) findOverflowEntry(key SectionalNeedleId) (nve SectionalNeedleValueExtra, nv SectionalNeedleValue, found bool) { foundCandidate := sort.Search(len(cs.overflow), func(i int) bool { return cs.overflow[i].Key >= key }) if foundCandidate != len(cs.overflow) && cs.overflow[foundCandidate].Key == key { return cs.overflowExtra[foundCandidate], cs.overflow[foundCandidate], true } return nve, nv, false }
func (cs *CompactSection) deleteOverflowEntry(key SectionalNeedleId) { length := len(cs.overflow) deleteCandidate := sort.Search(length, func(i int) bool { return cs.overflow[i].Key >= key }) if deleteCandidate != length && cs.overflow[deleteCandidate].Key == key { if cs.overflow[deleteCandidate].Size.IsValid() { cs.overflow[deleteCandidate].Size = -cs.overflow[deleteCandidate].Size } } }
//return old entry size
func (cs *CompactSection) Delete(key NeedleId) Size { skey := SectionalNeedleId(key - cs.start) cs.Lock() ret := Size(0) if i := cs.binarySearchValues(skey); i >= 0 { if cs.values[i].Size > 0 && cs.values[i].Size.IsValid() { ret = cs.values[i].Size cs.values[i].Size = -cs.values[i].Size } } if _, v, found := cs.findOverflowEntry(skey); found { cs.deleteOverflowEntry(skey) ret = v.Size } cs.Unlock() return ret } func (cs *CompactSection) Get(key NeedleId) (*NeedleValue, bool) { cs.RLock() skey := SectionalNeedleId(key - cs.start) if ve, v, ok := cs.findOverflowEntry(skey); ok { cs.RUnlock() nv := toNeedleValue(ve, v, cs) return &nv, true } if i := cs.binarySearchValues(skey); i >= 0 { cs.RUnlock() nv := toNeedleValue(cs.valuesExtra[i], cs.values[i], cs) return &nv, true } cs.RUnlock() return nil, false } func (cs *CompactSection) binarySearchValues(key SectionalNeedleId) int { x := sort.Search(cs.counter, func(i int) bool { return cs.values[i].Key >= key }) if x == cs.counter { return -1 } if cs.values[x].Key > key { return -2 } return x }
//This map assumes mostly inserting increasing keys
//This map assumes mostly inserting increasing keys
type CompactMap struct { list []*CompactSection }
func NewCompactMap() *CompactMap { return &CompactMap{} }
func (cm *CompactMap) Set(key NeedleId, offset Offset, size Size) (oldOffset Offset, oldSize Size) { x := cm.binarySearchCompactSection(key) if x < 0 || (key-cm.list[x].start) > SectionalNeedleIdLimit { // println(x, "adding to existing", len(cm.list), "sections, starting", key)
cs := NewCompactSection(key) cm.list = append(cm.list, cs) x = len(cm.list) - 1 //keep compact section sorted by start
for x >= 0 { if x > 0 && cm.list[x-1].start > key { cm.list[x] = cm.list[x-1] // println("shift", x, "start", cs.start, "to", x-1)
x = x - 1 } else { cm.list[x] = cs // println("cs", x, "start", cs.start)
break } } } // println(key, "set to section[", x, "].start", cm.list[x].start)
return cm.list[x].Set(key, offset, size) } func (cm *CompactMap) Delete(key NeedleId) Size { x := cm.binarySearchCompactSection(key) if x < 0 { return Size(0) } return cm.list[x].Delete(key) } func (cm *CompactMap) Get(key NeedleId) (*NeedleValue, bool) { x := cm.binarySearchCompactSection(key) if x < 0 { return nil, false } return cm.list[x].Get(key) } func (cm *CompactMap) binarySearchCompactSection(key NeedleId) int { l, h := 0, len(cm.list)-1 if h < 0 { return -5 } if cm.list[h].start <= key { if cm.list[h].counter < batch || key <= cm.list[h].end { return h } return -4 } for l <= h { m := (l + h) / 2 if key < cm.list[m].start { h = m - 1 } else { // cm.list[m].start <= key
if cm.list[m+1].start <= key { l = m + 1 } else { return m } } } return -3 }
// Visit visits all entries or stop if any error when visiting
func (cm *CompactMap) AscendingVisit(visit func(NeedleValue) error) error { for _, cs := range cm.list { cs.RLock() var i, j int for i, j = 0, 0; i < len(cs.overflow) && j < len(cs.values) && j < cs.counter; { if cs.overflow[i].Key < cs.values[j].Key { if err := visit(toNeedleValue(cs.overflowExtra[i], cs.overflow[i], cs)); err != nil { cs.RUnlock() return err } i++ } else if cs.overflow[i].Key == cs.values[j].Key { j++ } else { if err := visit(toNeedleValue(cs.valuesExtra[j], cs.values[j], cs)); err != nil { cs.RUnlock() return err } j++ } } for ; i < len(cs.overflow); i++ { if err := visit(toNeedleValue(cs.overflowExtra[i], cs.overflow[i], cs)); err != nil { cs.RUnlock() return err } } for ; j < len(cs.values) && j < cs.counter; j++ { if err := visit(toNeedleValue(cs.valuesExtra[j], cs.values[j], cs)); err != nil { cs.RUnlock() return err } } cs.RUnlock() } return nil }
func toNeedleValue(snve SectionalNeedleValueExtra, snv SectionalNeedleValue, cs *CompactSection) NeedleValue { offset := Offset{ OffsetHigher: snve.OffsetHigher, OffsetLower: snv.OffsetLower, } return NeedleValue{Key: NeedleId(snv.Key) + cs.start, Offset: offset, Size: snv.Size} }
func (nv NeedleValue) toSectionalNeedleValue(cs *CompactSection) (SectionalNeedleValue, SectionalNeedleValueExtra) { return SectionalNeedleValue{ SectionalNeedleId(nv.Key - cs.start), nv.Offset.OffsetLower, nv.Size, }, SectionalNeedleValueExtra{ nv.Offset.OffsetHigher, } }
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