seaweedfs/weed/shell/command_volume_fix_replication.go
Konstantin Lebedev a143c888e5
[shell] don't require lock when there are no changes for volume.fix.replication (#6266)
* don't require lock when there are no changes

* revert takeAction
2024-11-21 08:17:25 -08:00

644 lines
21 KiB
Go

package shell
import (
"context"
"flag"
"fmt"
"io"
"path/filepath"
"strconv"
"time"
"github.com/seaweedfs/seaweedfs/weed/pb"
"github.com/seaweedfs/seaweedfs/weed/storage/needle"
"github.com/seaweedfs/seaweedfs/weed/storage/needle_map"
"github.com/seaweedfs/seaweedfs/weed/storage/types"
"golang.org/x/exp/slices"
"google.golang.org/grpc"
"github.com/seaweedfs/seaweedfs/weed/operation"
"github.com/seaweedfs/seaweedfs/weed/pb/master_pb"
"github.com/seaweedfs/seaweedfs/weed/pb/volume_server_pb"
"github.com/seaweedfs/seaweedfs/weed/storage/super_block"
)
func init() {
Commands = append(Commands, &commandVolumeFixReplication{})
}
type commandVolumeFixReplication struct {
collectionPattern *string
}
func (c *commandVolumeFixReplication) Name() string {
return "volume.fix.replication"
}
func (c *commandVolumeFixReplication) Help() string {
return `add or remove replicas to volumes that are missing replicas or over-replicated
This command finds all over-replicated volumes. If found, it will purge the oldest copies and stop.
This command also finds all under-replicated volumes, and finds volume servers with free slots.
If the free slots satisfy the replication requirement, the volume content is copied over and mounted.
volume.fix.replication -n # do not take action
volume.fix.replication # actually deleting or copying the volume files and mount the volume
volume.fix.replication -collectionPattern=important* # fix any collections with prefix "important"
Note:
* each time this will only add back one replica for each volume id that is under replicated.
If there are multiple replicas are missing, e.g. replica count is > 2, you may need to run this multiple times.
* do not run this too quickly within seconds, since the new volume replica may take a few seconds
to register itself to the master.
`
}
func (c *commandVolumeFixReplication) HasTag(tag CommandTag) bool {
return false && tag == ResourceHeavy // resource intensive only when deleting and checking with replicas.
}
func (c *commandVolumeFixReplication) Do(args []string, commandEnv *CommandEnv, writer io.Writer) (err error) {
volFixReplicationCommand := flag.NewFlagSet(c.Name(), flag.ContinueOnError)
c.collectionPattern = volFixReplicationCommand.String("collectionPattern", "", "match with wildcard characters '*' and '?'")
skipChange := volFixReplicationCommand.Bool("n", false, "skip the changes")
doDelete := volFixReplicationCommand.Bool("doDelete", true, "Also delete over-replicated volumes besides fixing under-replication")
doCheck := volFixReplicationCommand.Bool("doCheck", true, "Also check synchronization before deleting")
retryCount := volFixReplicationCommand.Int("retry", 5, "how many times to retry")
volumesPerStep := volFixReplicationCommand.Int("volumesPerStep", 0, "how many volumes to fix in one cycle")
if err = volFixReplicationCommand.Parse(args); err != nil {
return nil
}
commandEnv.noLock = *skipChange
takeAction := !*skipChange
if err = commandEnv.confirmIsLocked(args); takeAction && err != nil {
return
}
underReplicatedVolumeIdsCount := 1
for underReplicatedVolumeIdsCount > 0 {
fixedVolumeReplicas := map[string]int{}
// collect topology information
topologyInfo, _, err := collectTopologyInfo(commandEnv, 15*time.Second)
if err != nil {
return err
}
// find all volumes that needs replication
// collect all data nodes
volumeReplicas, allLocations := collectVolumeReplicaLocations(topologyInfo)
if len(allLocations) == 0 {
return fmt.Errorf("no data nodes at all")
}
// find all under replicated volumes
var underReplicatedVolumeIds, overReplicatedVolumeIds, misplacedVolumeIds []uint32
for vid, replicas := range volumeReplicas {
replica := replicas[0]
replicaPlacement, _ := super_block.NewReplicaPlacementFromByte(byte(replica.info.ReplicaPlacement))
switch {
case replicaPlacement.GetCopyCount() > len(replicas) || !satisfyReplicaCurrentLocation(replicaPlacement, replicas):
underReplicatedVolumeIds = append(underReplicatedVolumeIds, vid)
case isMisplaced(replicas, replicaPlacement):
misplacedVolumeIds = append(misplacedVolumeIds, vid)
fmt.Fprintf(writer, "volume %d replication %s is not well placed %s\n", replica.info.Id, replicaPlacement, replica.location.dataNode.Id)
case replicaPlacement.GetCopyCount() < len(replicas):
overReplicatedVolumeIds = append(overReplicatedVolumeIds, vid)
fmt.Fprintf(writer, "volume %d replication %s, but over replicated %+d\n", replica.info.Id, replicaPlacement, len(replicas))
}
}
if !commandEnv.isLocked() {
return fmt.Errorf("lock is lost")
}
if len(overReplicatedVolumeIds) > 0 && *doDelete {
if err := c.deleteOneVolume(commandEnv, writer, takeAction, *doCheck, overReplicatedVolumeIds, volumeReplicas, allLocations, pickOneReplicaToDelete); err != nil {
return err
}
}
if len(misplacedVolumeIds) > 0 && *doDelete {
if err := c.deleteOneVolume(commandEnv, writer, takeAction, *doCheck, misplacedVolumeIds, volumeReplicas, allLocations, pickOneMisplacedVolume); err != nil {
return err
}
}
underReplicatedVolumeIdsCount = len(underReplicatedVolumeIds)
if underReplicatedVolumeIdsCount > 0 {
// find the most underpopulated data nodes
fixedVolumeReplicas, err = c.fixUnderReplicatedVolumes(commandEnv, writer, takeAction, underReplicatedVolumeIds, volumeReplicas, allLocations, *retryCount, *volumesPerStep)
if err != nil {
return err
}
}
if *skipChange {
break
}
// check that the topology has been updated
if len(fixedVolumeReplicas) > 0 {
fixedVolumes := make([]string, 0, len(fixedVolumeReplicas))
for k, _ := range fixedVolumeReplicas {
fixedVolumes = append(fixedVolumes, k)
}
volumeIdLocations, err := lookupVolumeIds(commandEnv, fixedVolumes)
if err != nil {
return err
}
for _, volumeIdLocation := range volumeIdLocations {
volumeId := volumeIdLocation.VolumeOrFileId
volumeIdLocationCount := len(volumeIdLocation.Locations)
i := 0
for fixedVolumeReplicas[volumeId] >= volumeIdLocationCount {
fmt.Fprintf(writer, "the number of locations for volume %s has not increased yet, let's wait\n", volumeId)
time.Sleep(time.Duration(i+1) * time.Second * 7)
volumeLocIds, err := lookupVolumeIds(commandEnv, []string{volumeId})
if err != nil {
return err
}
volumeIdLocationCount = len(volumeLocIds[0].Locations)
if *retryCount <= i {
return fmt.Errorf("replicas volume %s mismatch in topology", volumeId)
}
i += 1
}
}
}
}
return nil
}
func collectVolumeReplicaLocations(topologyInfo *master_pb.TopologyInfo) (map[uint32][]*VolumeReplica, []location) {
volumeReplicas := make(map[uint32][]*VolumeReplica)
var allLocations []location
eachDataNode(topologyInfo, func(dc DataCenterId, rack RackId, dn *master_pb.DataNodeInfo) {
loc := newLocation(string(dc), string(rack), dn)
for _, diskInfo := range dn.DiskInfos {
for _, v := range diskInfo.VolumeInfos {
volumeReplicas[v.Id] = append(volumeReplicas[v.Id], &VolumeReplica{
location: &loc,
info: v,
})
}
}
allLocations = append(allLocations, loc)
})
return volumeReplicas, allLocations
}
type SelectOneVolumeFunc func(replicas []*VolumeReplica, replicaPlacement *super_block.ReplicaPlacement) *VolumeReplica
func checkOneVolume(a *VolumeReplica, b *VolumeReplica, writer io.Writer, grpcDialOption grpc.DialOption) (err error) {
aDB, bDB := needle_map.NewMemDb(), needle_map.NewMemDb()
defer func() {
aDB.Close()
bDB.Close()
}()
// read index db
readIndexDbCutoffFrom := uint64(time.Now().UnixNano())
if err = readIndexDatabase(aDB, a.info.Collection, a.info.Id, pb.NewServerAddressFromDataNode(a.location.dataNode), false, writer, grpcDialOption); err != nil {
return fmt.Errorf("readIndexDatabase %s volume %d: %v", a.location.dataNode, a.info.Id, err)
}
if err := readIndexDatabase(bDB, b.info.Collection, b.info.Id, pb.NewServerAddressFromDataNode(b.location.dataNode), false, writer, grpcDialOption); err != nil {
return fmt.Errorf("readIndexDatabase %s volume %d: %v", b.location.dataNode, b.info.Id, err)
}
if _, err = doVolumeCheckDisk(aDB, bDB, a, b, false, writer, true, false, float64(1), readIndexDbCutoffFrom, grpcDialOption); err != nil {
return fmt.Errorf("doVolumeCheckDisk source:%s target:%s volume %d: %v", a.location.dataNode.Id, b.location.dataNode.Id, a.info.Id, err)
}
return
}
func (c *commandVolumeFixReplication) deleteOneVolume(commandEnv *CommandEnv, writer io.Writer, takeAction bool, doCheck bool, overReplicatedVolumeIds []uint32, volumeReplicas map[uint32][]*VolumeReplica, allLocations []location, selectOneVolumeFn SelectOneVolumeFunc) error {
for _, vid := range overReplicatedVolumeIds {
replicas := volumeReplicas[vid]
replicaPlacement, _ := super_block.NewReplicaPlacementFromByte(byte(replicas[0].info.ReplicaPlacement))
replica := selectOneVolumeFn(replicas, replicaPlacement)
// check collection name pattern
if *c.collectionPattern != "" {
matched, err := filepath.Match(*c.collectionPattern, replica.info.Collection)
if err != nil {
return fmt.Errorf("match pattern %s with collection %s: %v", *c.collectionPattern, replica.info.Collection, err)
}
if !matched {
break
}
}
collectionIsMismatch := false
for _, volumeReplica := range replicas {
if volumeReplica.info.Collection != replica.info.Collection {
fmt.Fprintf(writer, "skip delete volume %d as collection %s is mismatch: %s\n", replica.info.Id, replica.info.Collection, volumeReplica.info.Collection)
collectionIsMismatch = true
}
}
if collectionIsMismatch {
continue
}
fmt.Fprintf(writer, "deleting volume %d from %s ...\n", replica.info.Id, replica.location.dataNode.Id)
if !takeAction {
break
}
if doCheck {
for _, replicaB := range replicas {
if replicaB.location.dataNode == replica.location.dataNode {
continue
}
if err := checkOneVolume(replica, replicaB, writer, commandEnv.option.GrpcDialOption); err != nil {
return fmt.Errorf("sync volume %d on %s and %s: %v\n", replica.info.Id, replica.location.dataNode.Id, replicaB.location.dataNode.Id, err)
}
}
}
if err := deleteVolume(commandEnv.option.GrpcDialOption, needle.VolumeId(replica.info.Id),
pb.NewServerAddressFromDataNode(replica.location.dataNode), false); err != nil {
return fmt.Errorf("deleting volume %d from %s : %v", replica.info.Id, replica.location.dataNode.Id, err)
}
}
return nil
}
func (c *commandVolumeFixReplication) fixUnderReplicatedVolumes(commandEnv *CommandEnv, writer io.Writer, takeAction bool, underReplicatedVolumeIds []uint32, volumeReplicas map[uint32][]*VolumeReplica, allLocations []location, retryCount int, volumesPerStep int) (fixedVolumes map[string]int, err error) {
fixedVolumes = map[string]int{}
if len(underReplicatedVolumeIds) > volumesPerStep && volumesPerStep > 0 {
underReplicatedVolumeIds = underReplicatedVolumeIds[0:volumesPerStep]
}
for _, vid := range underReplicatedVolumeIds {
for i := 0; i < retryCount+1; i++ {
if err = c.fixOneUnderReplicatedVolume(commandEnv, writer, takeAction, volumeReplicas, vid, allLocations); err == nil {
if takeAction {
fixedVolumes[strconv.FormatUint(uint64(vid), 10)] = len(volumeReplicas[vid])
}
break
} else {
fmt.Fprintf(writer, "fixing under replicated volume %d: %v\n", vid, err)
}
}
}
return fixedVolumes, nil
}
func (c *commandVolumeFixReplication) fixOneUnderReplicatedVolume(commandEnv *CommandEnv, writer io.Writer, takeAction bool, volumeReplicas map[uint32][]*VolumeReplica, vid uint32, allLocations []location) error {
replicas := volumeReplicas[vid]
replica := pickOneReplicaToCopyFrom(replicas)
replicaPlacement, _ := super_block.NewReplicaPlacementFromByte(byte(replica.info.ReplicaPlacement))
foundNewLocation := false
hasSkippedCollection := false
keepDataNodesSorted(allLocations, types.ToDiskType(replica.info.DiskType))
fn := capacityByFreeVolumeCount(types.ToDiskType(replica.info.DiskType))
for _, dst := range allLocations {
// check whether data nodes satisfy the constraints
if fn(dst.dataNode) > 0 && satisfyReplicaPlacement(replicaPlacement, replicas, dst) {
// check collection name pattern
if *c.collectionPattern != "" {
matched, err := filepath.Match(*c.collectionPattern, replica.info.Collection)
if err != nil {
return fmt.Errorf("match pattern %s with collection %s: %v", *c.collectionPattern, replica.info.Collection, err)
}
if !matched {
hasSkippedCollection = true
break
}
}
// ask the volume server to replicate the volume
foundNewLocation = true
fmt.Fprintf(writer, "replicating volume %d %s from %s to dataNode %s ...\n", replica.info.Id, replicaPlacement, replica.location.dataNode.Id, dst.dataNode.Id)
if !takeAction {
// adjust volume count
addVolumeCount(dst.dataNode.DiskInfos[replica.info.DiskType], 1)
break
}
err := operation.WithVolumeServerClient(false, pb.NewServerAddressFromDataNode(dst.dataNode), commandEnv.option.GrpcDialOption, func(volumeServerClient volume_server_pb.VolumeServerClient) error {
stream, replicateErr := volumeServerClient.VolumeCopy(context.Background(), &volume_server_pb.VolumeCopyRequest{
VolumeId: replica.info.Id,
SourceDataNode: string(pb.NewServerAddressFromDataNode(replica.location.dataNode)),
})
if replicateErr != nil {
return fmt.Errorf("copying from %s => %s : %v", replica.location.dataNode.Id, dst.dataNode.Id, replicateErr)
}
for {
resp, recvErr := stream.Recv()
if recvErr != nil {
if recvErr == io.EOF {
break
} else {
return recvErr
}
}
if resp.ProcessedBytes > 0 {
fmt.Fprintf(writer, "volume %d processed %d bytes\n", replica.info.Id, resp.ProcessedBytes)
}
}
return nil
})
if err != nil {
return err
}
// adjust volume count
addVolumeCount(dst.dataNode.DiskInfos[replica.info.DiskType], 1)
break
}
}
if !foundNewLocation && !hasSkippedCollection {
fmt.Fprintf(writer, "failed to place volume %d replica as %s, existing:%+v\n", replica.info.Id, replicaPlacement, len(replicas))
}
return nil
}
func addVolumeCount(info *master_pb.DiskInfo, count int) {
if info == nil {
return
}
info.VolumeCount += int64(count)
info.FreeVolumeCount -= int64(count)
}
func keepDataNodesSorted(dataNodes []location, diskType types.DiskType) {
fn := capacityByFreeVolumeCount(diskType)
slices.SortFunc(dataNodes, func(a, b location) int {
return int(fn(b.dataNode) - fn(a.dataNode))
})
}
func satisfyReplicaCurrentLocation(replicaPlacement *super_block.ReplicaPlacement, replicas []*VolumeReplica) bool {
existingDataCenters, existingRacks, _ := countReplicas(replicas)
if replicaPlacement.DiffDataCenterCount+1 > len(existingDataCenters) {
return false
}
if replicaPlacement.DiffRackCount+1 > len(existingRacks) {
return false
}
if replicaPlacement.SameRackCount > 0 {
foundSatisfyRack := false
for _, rackCount := range existingRacks {
if rackCount >= replicaPlacement.SameRackCount+1 {
foundSatisfyRack = true
}
}
return foundSatisfyRack
}
return true
}
/*
if on an existing data node {
return false
}
if different from existing dcs {
if lack on different dcs {
return true
}else{
return false
}
}
if not on primary dc {
return false
}
if different from existing racks {
if lack on different racks {
return true
}else{
return false
}
}
if not on primary rack {
return false
}
if lacks on same rack {
return true
} else {
return false
}
*/
func satisfyReplicaPlacement(replicaPlacement *super_block.ReplicaPlacement, replicas []*VolumeReplica, possibleLocation location) bool {
existingDataCenters, _, existingDataNodes := countReplicas(replicas)
if _, found := existingDataNodes[possibleLocation.String()]; found {
// avoid duplicated volume on the same data node
return false
}
primaryDataCenters, _ := findTopKeys(existingDataCenters)
// ensure data center count is within limit
if _, found := existingDataCenters[possibleLocation.DataCenter()]; !found {
// different from existing dcs
if len(existingDataCenters) < replicaPlacement.DiffDataCenterCount+1 {
// lack on different dcs
return true
} else {
// adding this would go over the different dcs limit
return false
}
}
// now this is same as one of the existing data center
if !isAmong(possibleLocation.DataCenter(), primaryDataCenters) {
// not on one of the primary dcs
return false
}
// now this is one of the primary dcs
primaryDcRacks := make(map[string]int)
for _, replica := range replicas {
if replica.location.DataCenter() != possibleLocation.DataCenter() {
continue
}
primaryDcRacks[replica.location.Rack()] += 1
}
primaryRacks, _ := findTopKeys(primaryDcRacks)
sameRackCount := primaryDcRacks[possibleLocation.Rack()]
// ensure rack count is within limit
if _, found := primaryDcRacks[possibleLocation.Rack()]; !found {
// different from existing racks
if len(primaryDcRacks) < replicaPlacement.DiffRackCount+1 {
// lack on different racks
return true
} else {
// adding this would go over the different racks limit
return false
}
}
// now this is same as one of the existing racks
if !isAmong(possibleLocation.Rack(), primaryRacks) {
// not on the primary rack
return false
}
// now this is on the primary rack
// different from existing data nodes
if sameRackCount < replicaPlacement.SameRackCount+1 {
// lack on same rack
return true
} else {
// adding this would go over the same data node limit
return false
}
}
func findTopKeys(m map[string]int) (topKeys []string, max int) {
for k, c := range m {
if max < c {
topKeys = topKeys[:0]
topKeys = append(topKeys, k)
max = c
} else if max == c {
topKeys = append(topKeys, k)
}
}
return
}
func isAmong(key string, keys []string) bool {
for _, k := range keys {
if k == key {
return true
}
}
return false
}
type VolumeReplica struct {
location *location
info *master_pb.VolumeInformationMessage
}
type location struct {
dc string
rack string
dataNode *master_pb.DataNodeInfo
}
func newLocation(dc, rack string, dataNode *master_pb.DataNodeInfo) location {
return location{
dc: dc,
rack: rack,
dataNode: dataNode,
}
}
func (l location) String() string {
return fmt.Sprintf("%s %s %s", l.dc, l.rack, l.dataNode.Id)
}
func (l location) Rack() string {
return fmt.Sprintf("%s %s", l.dc, l.rack)
}
func (l location) DataCenter() string {
return l.dc
}
func pickOneReplicaToCopyFrom(replicas []*VolumeReplica) *VolumeReplica {
mostRecent := replicas[0]
for _, replica := range replicas {
if replica.info.ModifiedAtSecond > mostRecent.info.ModifiedAtSecond {
mostRecent = replica
}
}
return mostRecent
}
func countReplicas(replicas []*VolumeReplica) (diffDc, diffRack, diffNode map[string]int) {
diffDc = make(map[string]int)
diffRack = make(map[string]int)
diffNode = make(map[string]int)
for _, replica := range replicas {
diffDc[replica.location.DataCenter()] += 1
diffRack[replica.location.Rack()] += 1
diffNode[replica.location.String()] += 1
}
return
}
func pickOneReplicaToDelete(replicas []*VolumeReplica, replicaPlacement *super_block.ReplicaPlacement) *VolumeReplica {
slices.SortFunc(replicas, func(a, b *VolumeReplica) int {
if a.info.Size != b.info.Size {
return int(a.info.Size - b.info.Size)
}
if a.info.ModifiedAtSecond != b.info.ModifiedAtSecond {
return int(a.info.ModifiedAtSecond - b.info.ModifiedAtSecond)
}
if a.info.CompactRevision != b.info.CompactRevision {
return int(a.info.CompactRevision - b.info.CompactRevision)
}
return 0
})
return replicas[0]
}
// check and fix misplaced volumes
func isMisplaced(replicas []*VolumeReplica, replicaPlacement *super_block.ReplicaPlacement) bool {
for i := 0; i < len(replicas); i++ {
others := otherThan(replicas, i)
if !satisfyReplicaPlacement(replicaPlacement, others, *replicas[i].location) {
return true
}
}
return false
}
func otherThan(replicas []*VolumeReplica, index int) (others []*VolumeReplica) {
for i := 0; i < len(replicas); i++ {
if index != i {
others = append(others, replicas[i])
}
}
return
}
func pickOneMisplacedVolume(replicas []*VolumeReplica, replicaPlacement *super_block.ReplicaPlacement) (toDelete *VolumeReplica) {
var deletionCandidates []*VolumeReplica
for i := 0; i < len(replicas); i++ {
others := otherThan(replicas, i)
if !isMisplaced(others, replicaPlacement) {
deletionCandidates = append(deletionCandidates, replicas[i])
}
}
if len(deletionCandidates) > 0 {
return pickOneReplicaToDelete(deletionCandidates, replicaPlacement)
}
return pickOneReplicaToDelete(replicas, replicaPlacement)
}