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minio/cmd/data-crawler.go

784 lines
23 KiB

/*
* MinIO Cloud Storage, (C) 2020 MinIO, Inc.
*
* Licensed under the Apache License, Version 2.0 (the "License");
* you may not use this file except in compliance with the License.
* You may obtain a copy of the License at
*
* http://www.apache.org/licenses/LICENSE-2.0
*
* Unless required by applicable law or agreed to in writing, software
* distributed under the License is distributed on an "AS IS" BASIS,
* WITHOUT WARRANTIES OR CONDITIONS OF ANY KIND, either express or implied.
* See the License for the specific language governing permissions and
* limitations under the License.
*/
package cmd
import (
"bytes"
"context"
"encoding/binary"
"errors"
"math/rand"
"os"
"path"
"strconv"
"strings"
"time"
"github.com/minio/minio/cmd/config"
"github.com/minio/minio/cmd/config/heal"
"github.com/minio/minio/cmd/logger"
"github.com/minio/minio/pkg/bucket/lifecycle"
"github.com/minio/minio/pkg/bucket/replication"
"github.com/minio/minio/pkg/color"
"github.com/minio/minio/pkg/env"
"github.com/minio/minio/pkg/event"
"github.com/minio/minio/pkg/hash"
"github.com/minio/minio/pkg/madmin"
"github.com/willf/bloom"
)
const (
dataCrawlSleepPerFolder = time.Millisecond // Time to wait between folders.
dataCrawlSleepDefMult = 10.0 // Default multiplier for waits between operations.
dataCrawlStartDelay = 5 * time.Minute // Time to wait on startup and between cycles.
dataUsageUpdateDirCycles = 16 // Visit all folders every n cycles.
healDeleteDangling = true
healFolderIncludeProb = 32 // Include a clean folder one in n cycles.
healObjectSelectProb = 512 // Overall probability of a file being scanned; one in n.
)
var (
globalHealConfig heal.Config
dataCrawlerLeaderLockTimeout = newDynamicTimeout(30*time.Second, 10*time.Second)
)
// initDataCrawler will start the crawler unless disabled.
func initDataCrawler(ctx context.Context, objAPI ObjectLayer) {
if env.Get(envDataUsageCrawlConf, config.EnableOn) == config.EnableOn {
go runDataCrawler(ctx, objAPI)
}
}
// runDataCrawler will start a data crawler.
// The function will block until the context is canceled.
// There should only ever be one crawler running per cluster.
func runDataCrawler(ctx context.Context, objAPI ObjectLayer) {
// Make sure only 1 crawler is running on the cluster.
locker := objAPI.NewNSLock(ctx, minioMetaBucket, "runDataCrawler.lock")
r := rand.New(rand.NewSource(time.Now().UnixNano()))
for {
err := locker.GetLock(dataCrawlerLeaderLockTimeout)
if err != nil {
time.Sleep(time.Duration(r.Float64() * float64(dataCrawlStartDelay)))
continue
}
break
// No unlock for "leader" lock.
}
// Load current bloom cycle
nextBloomCycle := intDataUpdateTracker.current() + 1
var buf bytes.Buffer
err := objAPI.GetObject(ctx, dataUsageBucket, dataUsageBloomName, 0, -1, &buf, "", ObjectOptions{})
if err != nil {
if !isErrObjectNotFound(err) && !isErrBucketNotFound(err) {
logger.LogIf(ctx, err)
}
} else {
if buf.Len() == 8 {
nextBloomCycle = binary.LittleEndian.Uint64(buf.Bytes())
}
}
for {
select {
case <-ctx.Done():
return
case <-time.NewTimer(dataCrawlStartDelay).C:
// Wait before starting next cycle and wait on startup.
results := make(chan DataUsageInfo, 1)
go storeDataUsageInBackend(ctx, objAPI, results)
bf, err := globalNotificationSys.updateBloomFilter(ctx, nextBloomCycle)
logger.LogIf(ctx, err)
err = objAPI.CrawlAndGetDataUsage(ctx, bf, results)
close(results)
logger.LogIf(ctx, err)
if err == nil {
// Store new cycle...
nextBloomCycle++
var tmp [8]byte
binary.LittleEndian.PutUint64(tmp[:], nextBloomCycle)
r, err := hash.NewReader(bytes.NewReader(tmp[:]), int64(len(tmp)), "", "", int64(len(tmp)), false)
if err != nil {
logger.LogIf(ctx, err)
continue
}
_, err = objAPI.PutObject(ctx, dataUsageBucket, dataUsageBloomName, NewPutObjReader(r, nil, nil), ObjectOptions{})
if !isErrBucketNotFound(err) {
logger.LogIf(ctx, err)
}
}
}
}
}
type cachedFolder struct {
name string
parent *dataUsageHash
objectHealProbDiv uint32
}
type folderScanner struct {
root string
getSize getSizeFn
oldCache dataUsageCache
newCache dataUsageCache
withFilter *bloomFilter
dataUsageCrawlMult float64
dataUsageCrawlDebug bool
healFolderInclude uint32 // Include a clean folder one in n cycles.
healObjectSelect uint32 // Do a heal check on an object once every n cycles. Must divide into healFolderInclude
newFolders []cachedFolder
existingFolders []cachedFolder
}
// crawlDataFolder will crawl the basepath+cache.Info.Name and return an updated cache.
// The returned cache will always be valid, but may not be updated from the existing.
// Before each operation waitForLowActiveIO is called which can be used to temporarily halt the crawler.
// If the supplied context is canceled the function will return at the first chance.
func crawlDataFolder(ctx context.Context, basePath string, cache dataUsageCache, getSize getSizeFn) (dataUsageCache, error) {
t := UTCNow()
logPrefix := color.Green("data-usage: ")
logSuffix := color.Blue(" - %v + %v", basePath, cache.Info.Name)
if intDataUpdateTracker.debug {
defer func() {
logger.Info(logPrefix+" Crawl time: %v"+logSuffix, time.Since(t))
}()
}
switch cache.Info.Name {
case "", dataUsageRoot:
return cache, errors.New("internal error: root scan attempted")
}
delayMult, err := strconv.ParseFloat(env.Get(envDataUsageCrawlDelay, "10.0"), 64)
if err != nil {
logger.LogIf(ctx, err)
delayMult = dataCrawlSleepDefMult
}
s := folderScanner{
root: basePath,
getSize: getSize,
oldCache: cache,
newCache: dataUsageCache{Info: cache.Info},
newFolders: nil,
existingFolders: nil,
dataUsageCrawlMult: delayMult,
dataUsageCrawlDebug: intDataUpdateTracker.debug,
healFolderInclude: 0,
healObjectSelect: 0,
}
// Enable healing in XL mode.
if globalIsErasure {
// Include a clean folder one in n cycles.
s.healFolderInclude = healFolderIncludeProb
// Do a heal check on an object once every n cycles. Must divide into healFolderInclude
s.healObjectSelect = healObjectSelectProb
}
if len(cache.Info.BloomFilter) > 0 {
s.withFilter = &bloomFilter{BloomFilter: &bloom.BloomFilter{}}
_, err := s.withFilter.ReadFrom(bytes.NewBuffer(cache.Info.BloomFilter))
if err != nil {
logger.LogIf(ctx, err, logPrefix+"Error reading bloom filter")
s.withFilter = nil
}
}
if s.dataUsageCrawlDebug {
logger.Info(logPrefix+"Start crawling. Bloom filter: %v"+logSuffix, s.withFilter != nil)
}
done := ctx.Done()
var flattenLevels = 2
if s.dataUsageCrawlDebug {
logger.Info(logPrefix+"Cycle: %v, Entries: %v"+logSuffix, cache.Info.NextCycle, len(cache.Cache))
}
// Always scan flattenLevels deep. Cache root is level 0.
todo := []cachedFolder{{name: cache.Info.Name, objectHealProbDiv: 1}}
for i := 0; i < flattenLevels; i++ {
if s.dataUsageCrawlDebug {
logger.Info(logPrefix+"Level %v, scanning %v directories."+logSuffix, i, len(todo))
}
select {
case <-done:
return cache, ctx.Err()
default:
}
var err error
todo, err = s.scanQueuedLevels(ctx, todo, i == flattenLevels-1)
if err != nil {
// No useful information...
return cache, err
}
}
if s.dataUsageCrawlDebug {
logger.Info(logPrefix+"New folders: %v"+logSuffix, s.newFolders)
}
// Add new folders first
for _, folder := range s.newFolders {
select {
case <-done:
return s.newCache, ctx.Err()
default:
}
du, err := s.deepScanFolder(ctx, folder)
if err != nil {
logger.LogIf(ctx, err)
continue
}
if du == nil {
logger.Info(logPrefix + "no disk usage provided" + logSuffix)
continue
}
s.newCache.replace(folder.name, "", *du)
// Add to parent manually
if folder.parent != nil {
parent := s.newCache.Cache[folder.parent.Key()]
parent.addChildString(folder.name)
}
}
if s.dataUsageCrawlDebug {
logger.Info(logPrefix+"Existing folders: %v"+logSuffix, len(s.existingFolders))
}
// Do selective scanning of existing folders.
for _, folder := range s.existingFolders {
select {
case <-done:
return s.newCache, ctx.Err()
default:
}
h := hashPath(folder.name)
if !h.mod(s.oldCache.Info.NextCycle, dataUsageUpdateDirCycles) {
if !h.mod(s.oldCache.Info.NextCycle, s.healFolderInclude/folder.objectHealProbDiv) {
s.newCache.replaceHashed(h, folder.parent, s.oldCache.Cache[h.Key()])
continue
} else {
folder.objectHealProbDiv = s.healFolderInclude
}
folder.objectHealProbDiv = dataUsageUpdateDirCycles
}
if s.withFilter != nil {
_, prefix := path2BucketObjectWithBasePath(basePath, folder.name)
if s.oldCache.Info.lifeCycle == nil || !s.oldCache.Info.lifeCycle.HasActiveRules(prefix, true) {
// If folder isn't in filter, skip it completely.
if !s.withFilter.containsDir(folder.name) {
if !h.mod(s.oldCache.Info.NextCycle, s.healFolderInclude/folder.objectHealProbDiv) {
if s.dataUsageCrawlDebug {
logger.Info(logPrefix+"Skipping non-updated folder: %v"+logSuffix, folder)
}
s.newCache.replaceHashed(h, folder.parent, s.oldCache.Cache[h.Key()])
continue
} else {
if s.dataUsageCrawlDebug {
logger.Info(logPrefix+"Adding non-updated folder to heal check: %v"+logSuffix, folder.name)
}
// Update probability of including objects
folder.objectHealProbDiv = s.healFolderInclude
}
}
}
}
// Update on this cycle...
du, err := s.deepScanFolder(ctx, folder)
if err != nil {
logger.LogIf(ctx, err)
continue
}
if du == nil {
logger.LogIf(ctx, errors.New("data-usage: no disk usage provided"))
continue
}
s.newCache.replaceHashed(h, folder.parent, *du)
}
if s.dataUsageCrawlDebug {
logger.Info(logPrefix+"Finished crawl, %v entries"+logSuffix, len(s.newCache.Cache))
}
s.newCache.Info.LastUpdate = UTCNow()
s.newCache.Info.NextCycle++
return s.newCache, nil
}
// scanQueuedLevels will scan the provided folders.
// Files found in the folders will be added to f.newCache.
// If final is provided folders will be put into f.newFolders or f.existingFolders.
// If final is not provided the folders found are returned from the function.
func (f *folderScanner) scanQueuedLevels(ctx context.Context, folders []cachedFolder, final bool) ([]cachedFolder, error) {
var nextFolders []cachedFolder
done := ctx.Done()
for _, folder := range folders {
select {
case <-done:
return nil, ctx.Err()
default:
}
thisHash := hashPath(folder.name)
existing := f.oldCache.findChildrenCopy(thisHash)
// If there are lifecycle rules for the prefix, remove the filter.
filter := f.withFilter
var activeLifeCycle *lifecycle.Lifecycle
if f.oldCache.Info.lifeCycle != nil {
_, prefix := path2BucketObjectWithBasePath(f.root, folder.name)
if f.oldCache.Info.lifeCycle.HasActiveRules(prefix, true) {
if f.dataUsageCrawlDebug {
logger.Info(color.Green("folder-scanner:")+" Prefix %q has active rules", prefix)
}
activeLifeCycle = f.oldCache.Info.lifeCycle
filter = nil
}
}
if _, ok := f.oldCache.Cache[thisHash.Key()]; filter != nil && ok {
// If folder isn't in filter and we have data, skip it completely.
if folder.name != dataUsageRoot && !filter.containsDir(folder.name) {
if !thisHash.mod(f.oldCache.Info.NextCycle, f.healFolderInclude/folder.objectHealProbDiv) {
f.newCache.copyWithChildren(&f.oldCache, thisHash, folder.parent)
if f.dataUsageCrawlDebug {
logger.Info(color.Green("folder-scanner:")+" Skipping non-updated folder: %v", folder.name)
}
continue
} else {
if f.dataUsageCrawlDebug {
logger.Info(color.Green("folder-scanner:")+" Adding non-updated folder to heal check: %v", folder.name)
}
// If probability was already crawlerHealFolderInclude, keep it.
folder.objectHealProbDiv = f.healFolderInclude
}
}
}
sleepDuration(dataCrawlSleepPerFolder, f.dataUsageCrawlMult)
cache := dataUsageEntry{}
err := readDirFn(path.Join(f.root, folder.name), func(entName string, typ os.FileMode) error {
// Parse
entName = path.Clean(path.Join(folder.name, entName))
bucket, prefix := path2BucketObjectWithBasePath(f.root, entName)
if bucket == "" {
if f.dataUsageCrawlDebug {
logger.Info(color.Green("folder-scanner:")+" no bucket (%s,%s)", f.root, entName)
}
return nil
}
if isReservedOrInvalidBucket(bucket, false) {
if f.dataUsageCrawlDebug {
logger.Info(color.Green("folder-scanner:")+" invalid bucket: %v, entry: %v", bucket, entName)
}
return nil
}
select {
case <-done:
return ctx.Err()
default:
}
if typ&os.ModeDir != 0 {
h := hashPath(entName)
_, exists := f.oldCache.Cache[h.Key()]
cache.addChildString(entName)
this := cachedFolder{name: entName, parent: &thisHash, objectHealProbDiv: folder.objectHealProbDiv}
delete(existing, h.Key())
cache.addChild(h)
if final {
if exists {
f.existingFolders = append(f.existingFolders, this)
} else {
f.newFolders = append(f.newFolders, this)
}
} else {
nextFolders = append(nextFolders, this)
}
return nil
}
// Dynamic time delay.
t := UTCNow()
// Get file size, ignore errors.
item := crawlItem{
Path: path.Join(f.root, entName),
Typ: typ,
bucket: bucket,
prefix: path.Dir(prefix),
objectName: path.Base(entName),
debug: f.dataUsageCrawlDebug,
lifeCycle: activeLifeCycle,
heal: thisHash.mod(f.oldCache.Info.NextCycle, f.healObjectSelect/folder.objectHealProbDiv),
}
size, err := f.getSize(item)
sleepDuration(time.Since(t), f.dataUsageCrawlMult)
if err == errSkipFile {
return nil
}
logger.LogIf(ctx, err)
cache.Size += size
cache.Objects++
cache.ObjSizes.add(size)
return nil
})
if err != nil {
return nil, err
}
if f.healObjectSelect == 0 {
// If we are not scanning, return now.
f.newCache.replaceHashed(thisHash, folder.parent, cache)
continue
}
objAPI := newObjectLayerFn()
if objAPI == nil {
continue
}
bgSeq, found := globalBackgroundHealState.getHealSequenceByToken(bgHealingUUID)
if !found {
continue
}
// Whatever remains in 'existing' are folders at this level
// that existed in the previous run but wasn't found now.
//
// This may be because of 2 reasons:
//
// 1) The folder/object was deleted.
// 2) We come from another disk and this disk missed the write.
//
// We therefore perform a heal check.
// If that doesn't bring it back we remove the folder and assume it was deleted.
// This means that the next run will not look for it.
for k := range existing {
// Dynamic time delay.
t := UTCNow()
bucket, prefix := path2BucketObject(k)
if f.dataUsageCrawlDebug {
logger.Info(color.Green("folder-scanner:")+" checking disappeared folder: %v/%v", bucket, prefix)
}
err = objAPI.HealObjects(ctx, bucket, prefix, madmin.HealOpts{Recursive: true, Remove: healDeleteDangling},
func(bucket, object, versionID string) error {
return bgSeq.queueHealTask(healSource{
bucket: bucket,
object: object,
versionID: versionID,
}, madmin.HealItemObject)
})
sleepDuration(time.Since(t), f.dataUsageCrawlMult)
if f.dataUsageCrawlDebug && err != nil {
logger.Info(color.Green("healObjects:")+" checking returned value %v", err)
}
// Add unless healing returned an error.
if err == nil {
this := cachedFolder{name: k, parent: &thisHash, objectHealProbDiv: folder.objectHealProbDiv}
cache.addChild(hashPath(k))
if final {
f.existingFolders = append(f.existingFolders, this)
} else {
nextFolders = append(nextFolders, this)
}
}
}
f.newCache.replaceHashed(thisHash, folder.parent, cache)
}
return nextFolders, nil
}
// deepScanFolder will deep scan a folder and return the size if no error occurs.
func (f *folderScanner) deepScanFolder(ctx context.Context, folder cachedFolder) (*dataUsageEntry, error) {
var cache dataUsageEntry
done := ctx.Done()
var addDir func(entName string, typ os.FileMode) error
var dirStack = []string{f.root, folder.name}
addDir = func(entName string, typ os.FileMode) error {
select {
case <-done:
return ctx.Err()
default:
}
if typ&os.ModeDir != 0 {
dirStack = append(dirStack, entName)
err := readDirFn(path.Join(dirStack...), addDir)
dirStack = dirStack[:len(dirStack)-1]
sleepDuration(dataCrawlSleepPerFolder, f.dataUsageCrawlMult)
return err
}
// Dynamic time delay.
t := UTCNow()
// Get file size, ignore errors.
dirStack = append(dirStack, entName)
fileName := path.Join(dirStack...)
dirStack = dirStack[:len(dirStack)-1]
bucket, prefix := path2BucketObjectWithBasePath(f.root, fileName)
var activeLifeCycle *lifecycle.Lifecycle
if f.oldCache.Info.lifeCycle != nil {
if f.oldCache.Info.lifeCycle.HasActiveRules(prefix, false) {
if f.dataUsageCrawlDebug {
logger.Info(color.Green("folder-scanner:")+" Prefix %q has active rules", prefix)
}
activeLifeCycle = f.oldCache.Info.lifeCycle
}
}
size, err := f.getSize(
crawlItem{
Path: fileName,
Typ: typ,
bucket: bucket,
prefix: path.Dir(prefix),
objectName: path.Base(entName),
debug: f.dataUsageCrawlDebug,
lifeCycle: activeLifeCycle,
heal: hashPath(path.Join(prefix, entName)).mod(f.oldCache.Info.NextCycle, f.healObjectSelect/folder.objectHealProbDiv),
})
// Don't sleep for really small amount of time
sleepDuration(time.Since(t), f.dataUsageCrawlMult)
if err == errSkipFile {
return nil
}
logger.LogIf(ctx, err)
cache.Size += size
cache.Objects++
cache.ObjSizes.add(size)
return nil
}
err := readDirFn(path.Join(dirStack...), addDir)
if err != nil {
return nil, err
}
return &cache, nil
}
// crawlItem represents each file while walking.
type crawlItem struct {
Path string
Typ os.FileMode
bucket string // Bucket.
prefix string // Only the prefix if any, does not have final object name.
objectName string // Only the object name without prefixes.
lifeCycle *lifecycle.Lifecycle
heal bool // Has the object been selected for heal check?
debug bool
}
type getSizeFn func(item crawlItem) (int64, error)
// transformMetaDir will transform a directory to prefix/file.ext
func (i *crawlItem) transformMetaDir() {
split := strings.Split(i.prefix, SlashSeparator)
if len(split) > 1 {
i.prefix = path.Join(split[:len(split)-1]...)
} else {
i.prefix = ""
}
// Object name is last element
i.objectName = split[len(split)-1]
}
// actionMeta contains information used to apply actions.
type actionMeta struct {
oi ObjectInfo
successorModTime time.Time // The modtime of the successor version
numVersions int // The number of versions of this object
}
// applyActions will apply lifecycle checks on to a scanned item.
// The resulting size on disk will always be returned.
// The metadata will be compared to consensus on the object layer before any changes are applied.
// If no metadata is supplied, -1 is returned if no action is taken.
func (i *crawlItem) applyActions(ctx context.Context, o ObjectLayer, meta actionMeta) (size int64) {
size, err := meta.oi.GetActualSize()
if i.debug {
logger.LogIf(ctx, err)
}
if i.heal {
if i.debug {
logger.Info(color.Green("applyActions:")+" heal checking: %v/%v v%s", i.bucket, i.objectPath(), meta.oi.VersionID)
}
res, err := o.HealObject(ctx, i.bucket, i.objectPath(), meta.oi.VersionID, madmin.HealOpts{Remove: healDeleteDangling})
if isErrObjectNotFound(err) || isErrVersionNotFound(err) {
return 0
}
if err != nil && !errors.Is(err, NotImplemented{}) {
logger.LogIf(ctx, err)
return 0
}
size = res.ObjectSize
}
if i.lifeCycle == nil {
return size
}
versionID := meta.oi.VersionID
action := i.lifeCycle.ComputeAction(
lifecycle.ObjectOpts{
Name: i.objectPath(),
UserTags: meta.oi.UserTags,
ModTime: meta.oi.ModTime,
VersionID: meta.oi.VersionID,
DeleteMarker: meta.oi.DeleteMarker,
IsLatest: meta.oi.IsLatest,
NumVersions: meta.numVersions,
SuccessorModTime: meta.successorModTime,
})
if i.debug {
logger.Info(color.Green("applyActions:")+" lifecycle: %q (version-id=%s), Initial scan: %v", i.objectPath(), versionID, action)
}
switch action {
case lifecycle.DeleteAction, lifecycle.DeleteVersionAction:
default:
// No action.
return size
}
obj, err := o.GetObjectInfo(ctx, i.bucket, i.objectPath(), ObjectOptions{
VersionID: versionID,
})
if err != nil {
switch err.(type) {
case MethodNotAllowed: // This happens usually for a delete marker
if !obj.DeleteMarker { // if this is not a delete marker log and return
// Do nothing - heal in the future.
logger.LogIf(ctx, err)
return size
}
case ObjectNotFound:
// object not found return 0
return 0
default:
// All other errors proceed.
logger.LogIf(ctx, err)
return size
}
}
size = obj.Size
// Recalculate action.
action = i.lifeCycle.ComputeAction(
lifecycle.ObjectOpts{
Name: i.objectPath(),
UserTags: obj.UserTags,
ModTime: obj.ModTime,
VersionID: obj.VersionID,
DeleteMarker: obj.DeleteMarker,
IsLatest: obj.IsLatest,
NumVersions: meta.numVersions,
SuccessorModTime: meta.successorModTime,
})
if i.debug {
logger.Info(color.Green("applyActions:")+" lifecycle: Secondary scan: %v", action)
}
switch action {
case lifecycle.DeleteAction, lifecycle.DeleteVersionAction:
default:
// No action.
return size
}
opts := ObjectOptions{}
switch action {
case lifecycle.DeleteVersionAction:
// Defensive code, should never happen
if obj.VersionID == "" {
return size
}
if rcfg, _ := globalBucketObjectLockSys.Get(i.bucket); rcfg.LockEnabled {
locked := enforceRetentionForDeletion(ctx, obj)
if locked {
if i.debug {
logger.Info(color.Green("applyActions:")+" lifecycle: %s is locked, not deleting", i.objectPath())
}
return size
}
}
opts.VersionID = obj.VersionID
case lifecycle.DeleteAction:
opts.Versioned = globalBucketVersioningSys.Enabled(i.bucket)
}
obj, err = o.DeleteObject(ctx, i.bucket, i.objectPath(), opts)
if err != nil {
// Assume it is still there.
logger.LogIf(ctx, err)
return size
}
// Notify object deleted event.
sendEvent(eventArgs{
EventName: event.ObjectRemovedDelete,
BucketName: i.bucket,
Object: obj,
Host: "Internal: [ILM-EXPIRY]",
})
return 0
}
// objectPath returns the prefix and object name.
func (i *crawlItem) objectPath() string {
return path.Join(i.prefix, i.objectName)
}
// sleepDuration multiplies the duration d by x and sleeps if is more than 100 micro seconds.
// sleep is limited to max 1 second.
func sleepDuration(d time.Duration, x float64) {
// Don't sleep for really small amount of time
if d := time.Duration(float64(d) * x); d > time.Microsecond*100 {
if d > time.Second {
d = time.Second
}
time.Sleep(d)
}
}
// healReplication will heal a scanned item that has failed replication.
func (i *crawlItem) healReplication(ctx context.Context, o ObjectLayer, meta actionMeta) {
if meta.oi.ReplicationStatus == replication.Pending ||
meta.oi.ReplicationStatus == replication.Failed {
globalReplicationState.queueReplicaTask(meta.oi)
}
}