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package topology
import (
"errors"
"fmt"
"math/rand"
"sync"
"sync/atomic"
"time"
"github.com/seaweedfs/seaweedfs/weed/storage/types"
"github.com/seaweedfs/seaweedfs/weed/glog"
"github.com/seaweedfs/seaweedfs/weed/storage"
"github.com/seaweedfs/seaweedfs/weed/storage/needle"
"github.com/seaweedfs/seaweedfs/weed/storage/super_block"
)
type copyState int
const (
noCopies copyState = 0 + iota
insufficientCopies
enoughCopies
)
type volumeState string
const (
readOnlyState volumeState = "ReadOnly"
oversizedState = "Oversized"
crowdedState = "Crowded"
)
type stateIndicator func(copyState) bool
func ExistCopies() stateIndicator {
return func(state copyState) bool { return state != noCopies }
}
func NoCopies() stateIndicator {
return func(state copyState) bool { return state == noCopies }
}
type volumesBinaryState struct {
rp *super_block.ReplicaPlacement
name volumeState // the name for volume state (eg. "Readonly", "Oversized")
indicator stateIndicator // indicate whether the volumes should be marked as `name`
copyMap map[needle.VolumeId]*VolumeLocationList
}
func NewVolumesBinaryState(name volumeState, rp *super_block.ReplicaPlacement, indicator stateIndicator) *volumesBinaryState {
return &volumesBinaryState{
rp: rp,
name: name,
indicator: indicator,
copyMap: make(map[needle.VolumeId]*VolumeLocationList),
}
}
func (v *volumesBinaryState) Dump() (res []uint32) {
for vid, list := range v.copyMap {
if v.indicator(v.copyState(list)) {
res = append(res, uint32(vid))
}
}
return
}
func (v *volumesBinaryState) IsTrue(vid needle.VolumeId) bool {
list, _ := v.copyMap[vid]
return v.indicator(v.copyState(list))
}
func (v *volumesBinaryState) Add(vid needle.VolumeId, dn *DataNode) {
list, _ := v.copyMap[vid]
if list != nil {
list.Set(dn)
return
}
list = NewVolumeLocationList()
list.Set(dn)
v.copyMap[vid] = list
}
func (v *volumesBinaryState) Remove(vid needle.VolumeId, dn *DataNode) {
list, _ := v.copyMap[vid]
if list != nil {
list.Remove(dn)
if list.Length() == 0 {
delete(v.copyMap, vid)
}
}
}
func (v *volumesBinaryState) copyState(list *VolumeLocationList) copyState {
if list == nil {
return noCopies
}
if list.Length() < v.rp.GetCopyCount() {
return insufficientCopies
}
return enoughCopies
}
// mapping from volume to its locations, inverted from server to volume
type VolumeLayout struct {
growRequestCount int32
growRequestTime time.Time
rp *super_block.ReplicaPlacement
ttl *needle.TTL
diskType types.DiskType
vid2location map[needle.VolumeId]*VolumeLocationList
writables []needle.VolumeId // transient array of writable volume id
crowded map[needle.VolumeId]struct{}
readonlyVolumes *volumesBinaryState // readonly volumes
oversizedVolumes *volumesBinaryState // oversized volumes
vacuumedVolumes map[needle.VolumeId]time.Time
volumeSizeLimit uint64
replicationAsMin bool
accessLock sync.RWMutex
}
type VolumeLayoutStats struct {
TotalSize uint64
UsedSize uint64
FileCount uint64
}
func NewVolumeLayout(rp *super_block.ReplicaPlacement, ttl *needle.TTL, diskType types.DiskType, volumeSizeLimit uint64, replicationAsMin bool) *VolumeLayout {
return &VolumeLayout{
rp: rp,
ttl: ttl,
diskType: diskType,
vid2location: make(map[needle.VolumeId]*VolumeLocationList),
writables: *new([]needle.VolumeId),
crowded: make(map[needle.VolumeId]struct{}),
readonlyVolumes: NewVolumesBinaryState(readOnlyState, rp, ExistCopies()),
oversizedVolumes: NewVolumesBinaryState(oversizedState, rp, ExistCopies()),
vacuumedVolumes: make(map[needle.VolumeId]time.Time),
volumeSizeLimit: volumeSizeLimit,
replicationAsMin: replicationAsMin,
}
}
func (vl *VolumeLayout) String() string {
return fmt.Sprintf("rp:%v, ttl:%v, writables:%v, volumeSizeLimit:%v", vl.rp, vl.ttl, vl.writables, vl.volumeSizeLimit)
}
func (vl *VolumeLayout) RegisterVolume(v *storage.VolumeInfo, dn *DataNode) {
vl.accessLock.Lock()
defer vl.accessLock.Unlock()
defer vl.rememberOversizedVolume(v, dn)
if _, ok := vl.vid2location[v.Id]; !ok {
vl.vid2location[v.Id] = NewVolumeLocationList()
}
vl.vid2location[v.Id].Set(dn)
// glog.V(4).Infof("volume %d added to %s len %d copy %d", v.Id, dn.Id(), vl.vid2location[v.Id].Length(), v.ReplicaPlacement.GetCopyCount())
for _, dn := range vl.vid2location[v.Id].list {
if vInfo, err := dn.GetVolumesById(v.Id); err == nil {
if vInfo.ReadOnly {
glog.V(1).Infof("vid %d removed from writable", v.Id)
vl.removeFromWritable(v.Id)
vl.readonlyVolumes.Add(v.Id, dn)
return
} else {
vl.readonlyVolumes.Remove(v.Id, dn)
}
} else {
glog.V(1).Infof("vid %d removed from writable", v.Id)
vl.removeFromWritable(v.Id)
vl.readonlyVolumes.Remove(v.Id, dn)
return
}
}
}
func (vl *VolumeLayout) rememberOversizedVolume(v *storage.VolumeInfo, dn *DataNode) {
if vl.isOversized(v) {
vl.oversizedVolumes.Add(v.Id, dn)
} else {
vl.oversizedVolumes.Remove(v.Id, dn)
}
}
func (vl *VolumeLayout) UnRegisterVolume(v *storage.VolumeInfo, dn *DataNode) {
vl.accessLock.Lock()
defer vl.accessLock.Unlock()
// remove from vid2location map
location, ok := vl.vid2location[v.Id]
if !ok {
return
}
if location.Remove(dn) {
vl.readonlyVolumes.Remove(v.Id, dn)
vl.oversizedVolumes.Remove(v.Id, dn)
vl.ensureCorrectWritables(v.Id)
if location.Length() == 0 {
delete(vl.vid2location, v.Id)
}
}
}
func (vl *VolumeLayout) EnsureCorrectWritables(v *storage.VolumeInfo) {
vl.accessLock.Lock()
defer vl.accessLock.Unlock()
vl.ensureCorrectWritables(v.Id)
}
func (vl *VolumeLayout) ensureCorrectWritables(vid needle.VolumeId) {
if vl.enoughCopies(vid) && vl.isAllWritable(vid) {
if !vl.oversizedVolumes.IsTrue(vid) {
vl.setVolumeWritable(vid)
}
} else {
if !vl.enoughCopies(vid) {
glog.V(0).Infof("volume %d does not have enough copies", vid)
}
if !vl.isAllWritable(vid) {
glog.V(0).Infof("volume %d are not all writable", vid)
}
glog.V(0).Infof("volume %d remove from writable", vid)
vl.removeFromWritable(vid)
}
}
func (vl *VolumeLayout) isAllWritable(vid needle.VolumeId) bool {
for _, dn := range vl.vid2location[vid].list {
if v, getError := dn.GetVolumesById(vid); getError == nil {
if v.ReadOnly {
return false
}
}
}
return true
}
func (vl *VolumeLayout) isOversized(v *storage.VolumeInfo) bool {
return uint64(v.Size) >= vl.volumeSizeLimit
}
func (vl *VolumeLayout) isWritable(v *storage.VolumeInfo) bool {
return !vl.isOversized(v) &&
v.Version == needle.CurrentVersion &&
!v.ReadOnly
}
func (vl *VolumeLayout) isEmpty() bool {
vl.accessLock.RLock()
defer vl.accessLock.RUnlock()
return len(vl.vid2location) == 0
}
func (vl *VolumeLayout) Lookup(vid needle.VolumeId) []*DataNode {
vl.accessLock.RLock()
defer vl.accessLock.RUnlock()
if location := vl.vid2location[vid]; location != nil {
return location.list
}
return nil
}
func (vl *VolumeLayout) ListVolumeServers() (nodes []*DataNode) {
vl.accessLock.RLock()
defer vl.accessLock.RUnlock()
for _, location := range vl.vid2location {
nodes = append(nodes, location.list...)
}
return
}
func (vl *VolumeLayout) PickForWrite(count uint64, option *VolumeGrowOption) (*needle.VolumeId, uint64, *VolumeLocationList, error) {
vl.accessLock.RLock()
defer vl.accessLock.RUnlock()
lenWriters := len(vl.writables)
if lenWriters <= 0 {
//glog.V(0).Infoln("No more writable volumes!")
return nil, 0, nil, errors.New("No more writable volumes!")
}
if option.DataCenter == "" && option.Rack == "" && option.DataNode == "" {
vid := vl.writables[rand.Intn(lenWriters)]
locationList := vl.vid2location[vid]
if locationList != nil {
return &vid, count, locationList, nil
}
return nil, 0, nil, errors.New("Strangely vid " + vid.String() + " is on no machine!")
}
var vid needle.VolumeId
var locationList *VolumeLocationList
counter := 0
for _, v := range vl.writables {
volumeLocationList := vl.vid2location[v]
for _, dn := range volumeLocationList.list {
if option.DataCenter != "" && dn.GetDataCenter().Id() != NodeId(option.DataCenter) {
continue
}
if option.Rack != "" && dn.GetRack().Id() != NodeId(option.Rack) {
continue
}
if option.DataNode != "" && dn.Id() != NodeId(option.DataNode) {
continue
}
counter++
if rand.Intn(counter) < 1 {
vid, locationList = v, volumeLocationList.Copy()
}
}
}
return &vid, count, locationList, nil
}
func (vl *VolumeLayout) HasGrowRequest() bool {
if atomic.LoadInt32(&vl.growRequestCount) > 0 &&
vl.growRequestTime.Add(time.Minute).After(time.Now()) {
return true
}
return false
}
func (vl *VolumeLayout) AddGrowRequest() {
vl.growRequestTime = time.Now()
atomic.AddInt32(&vl.growRequestCount, 1)
}
func (vl *VolumeLayout) DoneGrowRequest() {
vl.growRequestTime = time.Unix(0, 0)
atomic.StoreInt32(&vl.growRequestCount, 0)
}
func (vl *VolumeLayout) ShouldGrowVolumes(option *VolumeGrowOption) bool {
active, crowded := vl.GetActiveVolumeCount(option)
//glog.V(0).Infof("active volume: %d, high usage volume: %d\n", active, high)
return active <= crowded
}
func (vl *VolumeLayout) GetActiveVolumeCount(option *VolumeGrowOption) (active, crowded int) {
vl.accessLock.RLock()
defer vl.accessLock.RUnlock()
if option.DataCenter == "" {
return len(vl.writables), len(vl.crowded)
}
for _, v := range vl.writables {
for _, dn := range vl.vid2location[v].list {
if dn.GetDataCenter().Id() == NodeId(option.DataCenter) {
if option.Rack != "" && dn.GetRack().Id() != NodeId(option.Rack) {
continue
}
if option.DataNode != "" && dn.Id() != NodeId(option.DataNode) {
continue
}
active++
info, _ := dn.GetVolumesById(v)
if float64(info.Size) > float64(vl.volumeSizeLimit)*option.Threshold() {
crowded++
}
}
}
}
return
}
func (vl *VolumeLayout) removeFromWritable(vid needle.VolumeId) bool {
toDeleteIndex := -1
for k, id := range vl.writables {
if id == vid {
toDeleteIndex = k
break
}
}
if toDeleteIndex >= 0 {
glog.V(0).Infoln("Volume", vid, "becomes unwritable")
vl.writables = append(vl.writables[0:toDeleteIndex], vl.writables[toDeleteIndex+1:]...)
vl.removeFromCrowded(vid)
return true
}
return false
}
func (vl *VolumeLayout) setVolumeWritable(vid needle.VolumeId) bool {
for _, v := range vl.writables {
if v == vid {
return false
}
}
glog.V(0).Infoln("Volume", vid, "becomes writable")
vl.writables = append(vl.writables, vid)
return true
}
func (vl *VolumeLayout) SetVolumeReadOnly(dn *DataNode, vid needle.VolumeId) bool {
vl.accessLock.Lock()
defer vl.accessLock.Unlock()
if _, ok := vl.vid2location[vid]; ok {
vl.readonlyVolumes.Add(vid, dn)
return vl.removeFromWritable(vid)
}
return true
}
func (vl *VolumeLayout) SetVolumeWritable(dn *DataNode, vid needle.VolumeId) bool {
vl.accessLock.Lock()
defer vl.accessLock.Unlock()
if _, ok := vl.vid2location[vid]; ok {
vl.readonlyVolumes.Remove(vid, dn)
}
if vl.enoughCopies(vid) {
return vl.setVolumeWritable(vid)
}
return false
}
func (vl *VolumeLayout) SetVolumeUnavailable(dn *DataNode, vid needle.VolumeId) bool {
vl.accessLock.Lock()
defer vl.accessLock.Unlock()
if location, ok := vl.vid2location[vid]; ok {
if location.Remove(dn) {
vl.readonlyVolumes.Remove(vid, dn)
vl.oversizedVolumes.Remove(vid, dn)
if location.Length() < vl.rp.GetCopyCount() {
glog.V(0).Infoln("Volume", vid, "has", location.Length(), "replica, less than required", vl.rp.GetCopyCount())
return vl.removeFromWritable(vid)
}
}
}
return false
}
func (vl *VolumeLayout) SetVolumeAvailable(dn *DataNode, vid needle.VolumeId, isReadOnly, isFullCapacity bool) bool {
vl.accessLock.Lock()
defer vl.accessLock.Unlock()
vInfo, err := dn.GetVolumesById(vid)
if err != nil {
return false
}
vl.vid2location[vid].Set(dn)
if vInfo.ReadOnly || isReadOnly || isFullCapacity {
return false
}
if vl.enoughCopies(vid) {
return vl.setVolumeWritable(vid)
}
return false
}
func (vl *VolumeLayout) enoughCopies(vid needle.VolumeId) bool {
locations := vl.vid2location[vid].Length()
desired := vl.rp.GetCopyCount()
return locations == desired || (vl.replicationAsMin && locations > desired)
}
func (vl *VolumeLayout) SetVolumeCapacityFull(vid needle.VolumeId) bool {
vl.accessLock.Lock()
defer vl.accessLock.Unlock()
wasWritable := vl.removeFromWritable(vid)
if wasWritable {
glog.V(0).Infof("Volume %d reaches full capacity.", vid)
}
return wasWritable
}
func (vl *VolumeLayout) removeFromCrowded(vid needle.VolumeId) {
delete(vl.crowded, vid)
}
func (vl *VolumeLayout) setVolumeCrowded(vid needle.VolumeId) {
if _, ok := vl.crowded[vid]; !ok {
vl.crowded[vid] = struct{}{}
glog.V(0).Infoln("Volume", vid, "becomes crowded")
}
}
func (vl *VolumeLayout) SetVolumeCrowded(vid needle.VolumeId) {
// since delete is guarded by accessLock.Lock(),
// and is always called in sequential order,
// RLock() should be safe enough
vl.accessLock.RLock()
defer vl.accessLock.RUnlock()
for _, v := range vl.writables {
if v == vid {
vl.setVolumeCrowded(vid)
break
}
}
}
type VolumeLayoutInfo struct {
Replication string `json:"replication"`
TTL string `json:"ttl"`
Writables []needle.VolumeId `json:"writables"`
Collection string `json:"collection"`
DiskType string `json:"diskType"`
}
func (vl *VolumeLayout) ToInfo() (info VolumeLayoutInfo) {
info.Replication = vl.rp.String()
info.TTL = vl.ttl.String()
info.Writables = vl.writables
info.DiskType = vl.diskType.ReadableString()
//m["locations"] = vl.vid2location
return
}
func (vl *VolumeLayout) Stats() *VolumeLayoutStats {
vl.accessLock.RLock()
defer vl.accessLock.RUnlock()
ret := &VolumeLayoutStats{}
freshThreshold := time.Now().Unix() - 60
for vid, vll := range vl.vid2location {
size, fileCount := vll.Stats(vid, freshThreshold)
ret.FileCount += uint64(fileCount)
ret.UsedSize += size * uint64(vll.Length())
if vl.readonlyVolumes.IsTrue(vid) {
ret.TotalSize += size * uint64(vll.Length())
} else {
ret.TotalSize += vl.volumeSizeLimit * uint64(vll.Length())
}
}
return ret
}