minio/cmd/erasure-healing.go
Harshavardhana b7c5e45fff
heal: isObjectDangling should return false when it cannot decide (#14053)
In a multi-pool setup when disks are coming up, or in a single pool
setup let's say with 100's of erasure sets with a slow network.

It's possible when healing is attempted on `.minio.sys/config`
folder, it can lead to healing unexpectedly deleting some policy
files as dangling due to a mistake in understanding when `isObjectDangling`
is considered to be 'true'.

This issue happened in commit 30135eed86
when we assumed the validMeta with empty ErasureInfo is considered
to be fully dangling. This implementation issue gets exposed when
the server is starting up.

This is most easily seen with multiple-pool setups because of the
disconnected fashion pools that come up. The decision to purge the
object as dangling is taken incorrectly prior to the correct state
being achieved on each pool, when the corresponding drive let's say
returns 'errDiskNotFound', a 'delete' is triggered. At this point,
the 'drive' comes online because this is part of the startup sequence
as drives can come online lazily.

This kind of situation exists because we allow (totalDisks/2) number
of drives to be online when the server is being restarted.

Implementation made an incorrect assumption here leading to policies
getting deleted.

Added tests to capture the implementation requirements.
2022-01-07 19:11:54 -08:00

968 lines
30 KiB
Go

// Copyright (c) 2015-2021 MinIO, Inc.
//
// This file is part of MinIO Object Storage stack
//
// This program is free software: you can redistribute it and/or modify
// it under the terms of the GNU Affero General Public License as published by
// the Free Software Foundation, either version 3 of the License, or
// (at your option) any later version.
//
// This program is distributed in the hope that it will be useful
// but WITHOUT ANY WARRANTY; without even the implied warranty of
// MERCHANTABILITY or FITNESS FOR A PARTICULAR PURPOSE. See the
// GNU Affero General Public License for more details.
//
// You should have received a copy of the GNU Affero General Public License
// along with this program. If not, see <http://www.gnu.org/licenses/>.
package cmd
import (
"bytes"
"context"
"errors"
"fmt"
"io"
"sync"
"time"
"github.com/minio/madmin-go"
"github.com/minio/minio/internal/logger"
"github.com/minio/minio/internal/sync/errgroup"
)
const reservedMetadataPrefixLowerDataShardFix = ReservedMetadataPrefixLower + "data-shard-fix"
// AcceptableDelta returns 'true' if the fi.DiskMTime is under
// acceptable delta of "delta" duration with maxTime.
//
// This code is primarily used for heuristic detection of
// incorrect shards, as per https://github.com/minio/minio/pull/13803
//
// This check only is active if we could find maximally
// occurring disk mtimes that are somewhat same across
// the quorum. Allowing to skip those shards which we
// might think are wrong.
func (fi FileInfo) AcceptableDelta(maxTime time.Time, delta time.Duration) bool {
diff := maxTime.Sub(fi.DiskMTime)
if diff < 0 {
diff = -diff
}
return diff < delta
}
// DataShardFixed - data shard fixed?
func (fi FileInfo) DataShardFixed() bool {
return fi.Metadata[reservedMetadataPrefixLowerDataShardFix] == "true"
}
// Heals a bucket if it doesn't exist on one of the disks, additionally
// also heals the missing entries for bucket metadata files
// `policy.json, notification.xml, listeners.json`.
func (er erasureObjects) HealBucket(ctx context.Context, bucket string, opts madmin.HealOpts) (
result madmin.HealResultItem, err error) {
if !opts.DryRun {
defer NSUpdated(bucket, slashSeparator)
}
storageDisks := er.getDisks()
storageEndpoints := er.getEndpoints()
// Heal bucket.
return er.healBucket(ctx, storageDisks, storageEndpoints, bucket, opts)
}
// Heal bucket - create buckets on disks where it does not exist.
func (er erasureObjects) healBucket(ctx context.Context, storageDisks []StorageAPI, storageEndpoints []Endpoint, bucket string, opts madmin.HealOpts) (res madmin.HealResultItem, err error) {
// get write quorum for an object
writeQuorum := len(storageDisks) - er.defaultParityCount
if writeQuorum == er.defaultParityCount {
writeQuorum++
}
// Initialize sync waitgroup.
g := errgroup.WithNErrs(len(storageDisks))
// Disk states slices
beforeState := make([]string, len(storageDisks))
afterState := make([]string, len(storageDisks))
// Make a volume entry on all underlying storage disks.
for index := range storageDisks {
index := index
g.Go(func() error {
if storageDisks[index] == nil {
beforeState[index] = madmin.DriveStateOffline
afterState[index] = madmin.DriveStateOffline
return errDiskNotFound
}
beforeState[index] = madmin.DriveStateOk
afterState[index] = madmin.DriveStateOk
if bucket == minioReservedBucket {
return nil
}
if _, serr := storageDisks[index].StatVol(ctx, bucket); serr != nil {
if serr == errDiskNotFound {
beforeState[index] = madmin.DriveStateOffline
afterState[index] = madmin.DriveStateOffline
return serr
}
if serr != errVolumeNotFound {
beforeState[index] = madmin.DriveStateCorrupt
afterState[index] = madmin.DriveStateCorrupt
return serr
}
beforeState[index] = madmin.DriveStateMissing
afterState[index] = madmin.DriveStateMissing
// mutate only if not a dry-run
if opts.DryRun {
return nil
}
return serr
}
return nil
}, index)
}
errs := g.Wait()
// Initialize heal result info
res = madmin.HealResultItem{
Type: madmin.HealItemBucket,
Bucket: bucket,
DiskCount: len(storageDisks),
ParityBlocks: er.defaultParityCount,
DataBlocks: len(storageDisks) - er.defaultParityCount,
}
for i := range beforeState {
res.Before.Drives = append(res.Before.Drives, madmin.HealDriveInfo{
UUID: "",
Endpoint: storageEndpoints[i].String(),
State: beforeState[i],
})
}
reducedErr := reduceReadQuorumErrs(ctx, errs, bucketOpIgnoredErrs, res.DataBlocks)
if errors.Is(reducedErr, errVolumeNotFound) && !opts.Recreate {
for i := range beforeState {
res.After.Drives = append(res.After.Drives, madmin.HealDriveInfo{
UUID: "",
Endpoint: storageEndpoints[i].String(),
State: madmin.DriveStateOk,
})
}
return res, nil
}
// Initialize sync waitgroup.
g = errgroup.WithNErrs(len(storageDisks))
// Make a volume entry on all underlying storage disks.
for index := range storageDisks {
index := index
g.Go(func() error {
if beforeState[index] == madmin.DriveStateMissing {
makeErr := storageDisks[index].MakeVol(ctx, bucket)
if makeErr == nil {
afterState[index] = madmin.DriveStateOk
}
return makeErr
}
return errs[index]
}, index)
}
errs = g.Wait()
reducedErr = reduceWriteQuorumErrs(ctx, errs, bucketOpIgnoredErrs, writeQuorum)
if reducedErr != nil {
// If we have exactly half the drives not available,
// we should still allow HealBucket to not return error.
// this is necessary for starting the server.
readQuorum := res.DataBlocks
switch reduceReadQuorumErrs(ctx, errs, nil, readQuorum) {
case nil:
case errDiskNotFound:
default:
return res, reducedErr
}
}
for i := range afterState {
res.After.Drives = append(res.After.Drives, madmin.HealDriveInfo{
UUID: "",
Endpoint: storageEndpoints[i].String(),
State: afterState[i],
})
}
return res, nil
}
// listAllBuckets lists all buckets from all disks. It also
// returns the occurrence of each buckets in all disks
func listAllBuckets(ctx context.Context, storageDisks []StorageAPI, healBuckets map[string]VolInfo, readQuorum int) error {
g := errgroup.WithNErrs(len(storageDisks))
var mu sync.Mutex
for index := range storageDisks {
index := index
g.Go(func() error {
if storageDisks[index] == nil {
// we ignore disk not found errors
return nil
}
volsInfo, err := storageDisks[index].ListVols(ctx)
if err != nil {
return err
}
for _, volInfo := range volsInfo {
// StorageAPI can send volume names which are
// incompatible with buckets - these are
// skipped, like the meta-bucket.
if isReservedOrInvalidBucket(volInfo.Name, false) {
continue
}
mu.Lock()
if _, ok := healBuckets[volInfo.Name]; !ok {
healBuckets[volInfo.Name] = volInfo
}
mu.Unlock()
}
return nil
}, index)
}
return reduceReadQuorumErrs(ctx, g.Wait(), bucketMetadataOpIgnoredErrs, readQuorum)
}
// Only heal on disks where we are sure that healing is needed. We can expand
// this list as and when we figure out more errors can be added to this list safely.
func shouldHealObjectOnDisk(erErr, dataErr error, meta FileInfo, latestMeta FileInfo) bool {
switch {
case errors.Is(erErr, errFileNotFound) || errors.Is(erErr, errFileVersionNotFound):
return true
case errors.Is(erErr, errFileCorrupt):
return true
}
if erErr == nil {
if meta.XLV1 {
// Legacy means heal always
// always check first.
return true
}
if !meta.Deleted && !meta.IsRemote() {
// If xl.meta was read fine but there may be problem with the part.N files.
if IsErr(dataErr, []error{
errFileNotFound,
errFileVersionNotFound,
errFileCorrupt,
}...) {
return true
}
}
if !latestMeta.Equals(meta) {
return true
}
}
return false
}
// Heals an object by re-writing corrupt/missing erasure blocks.
func (er erasureObjects) healObject(ctx context.Context, bucket string, object string, versionID string, opts madmin.HealOpts) (result madmin.HealResultItem, err error) {
if !opts.DryRun {
defer NSUpdated(bucket, object)
}
dryRun := opts.DryRun
scanMode := opts.ScanMode
storageDisks := er.getDisks()
storageEndpoints := er.getEndpoints()
// Initialize heal result object
result = madmin.HealResultItem{
Type: madmin.HealItemObject,
Bucket: bucket,
Object: object,
DiskCount: len(storageDisks),
}
if !opts.NoLock {
lk := er.NewNSLock(bucket, object)
lkctx, err := lk.GetLock(ctx, globalOperationTimeout)
if err != nil {
return result, err
}
ctx = lkctx.Context()
defer lk.Unlock(lkctx.Cancel)
}
// Re-read when we have lock...
partsMetadata, errs := readAllFileInfo(ctx, storageDisks, bucket, object, versionID, true)
if isAllNotFound(errs) {
// Nothing to do, file is already gone.
return er.defaultHealResult(FileInfo{}, storageDisks, storageEndpoints,
errs, bucket, object, versionID), nil
}
readQuorum, _, err := objectQuorumFromMeta(ctx, partsMetadata, errs, er.defaultParityCount)
if err != nil {
return er.purgeObjectDangling(ctx, bucket, object, versionID, partsMetadata, errs, nil, opts)
}
result.ParityBlocks = result.DiskCount - readQuorum
result.DataBlocks = readQuorum
// List of disks having latest version of the object xl.meta
// (by modtime).
onlineDisks, modTime := listOnlineDisks(storageDisks, partsMetadata, errs)
// Latest FileInfo for reference. If a valid metadata is not
// present, it is as good as object not found.
latestMeta, err := pickValidFileInfo(ctx, partsMetadata, modTime, readQuorum)
if err != nil {
return result, toObjectErr(err, bucket, object, versionID)
}
// List of disks having all parts as per latest metadata.
// NOTE: do not pass in latestDisks to diskWithAllParts since
// the diskWithAllParts needs to reach the drive to ensure
// validity of the metadata content, we should make sure that
// we pass in disks as is for it to be verified. Once verified
// the disksWithAllParts() returns the actual disks that can be
// used here for reconstruction. This is done to ensure that
// we do not skip drives that have inconsistent metadata to be
// skipped from purging when they are stale.
availableDisks, dataErrs, diskMTime := disksWithAllParts(ctx, onlineDisks, partsMetadata,
errs, latestMeta, bucket, object, scanMode)
// Loop to find number of disks with valid data, per-drive
// data state and a list of outdated disks on which data needs
// to be healed.
outDatedDisks := make([]StorageAPI, len(storageDisks))
numAvailableDisks := 0
disksToHealCount := 0
for i, v := range availableDisks {
driveState := ""
switch {
case v != nil:
driveState = madmin.DriveStateOk
numAvailableDisks++
// If data is sane on any one disk, we can
// extract the correct object size.
result.ObjectSize = partsMetadata[i].Size
case errs[i] == errDiskNotFound, dataErrs[i] == errDiskNotFound:
driveState = madmin.DriveStateOffline
case errs[i] == errFileNotFound, errs[i] == errFileVersionNotFound, errs[i] == errVolumeNotFound:
fallthrough
case dataErrs[i] == errFileNotFound, dataErrs[i] == errFileVersionNotFound, dataErrs[i] == errVolumeNotFound:
driveState = madmin.DriveStateMissing
default:
// all remaining cases imply corrupt data/metadata
driveState = madmin.DriveStateCorrupt
}
if shouldHealObjectOnDisk(errs[i], dataErrs[i], partsMetadata[i], latestMeta) {
outDatedDisks[i] = storageDisks[i]
disksToHealCount++
result.Before.Drives = append(result.Before.Drives, madmin.HealDriveInfo{
UUID: "",
Endpoint: storageEndpoints[i].String(),
State: driveState,
})
result.After.Drives = append(result.After.Drives, madmin.HealDriveInfo{
UUID: "",
Endpoint: storageEndpoints[i].String(),
State: driveState,
})
continue
}
result.Before.Drives = append(result.Before.Drives, madmin.HealDriveInfo{
UUID: "",
Endpoint: storageEndpoints[i].String(),
State: driveState,
})
result.After.Drives = append(result.After.Drives, madmin.HealDriveInfo{
UUID: "",
Endpoint: storageEndpoints[i].String(),
State: driveState,
})
}
if isAllNotFound(errs) {
// File is fully gone, fileInfo is empty.
return er.defaultHealResult(FileInfo{}, storageDisks, storageEndpoints, errs,
bucket, object, versionID), nil
}
// If less than read quorum number of disks have all the parts
// of the data, we can't reconstruct the erasure-coded data.
if numAvailableDisks < readQuorum {
return er.purgeObjectDangling(ctx, bucket, object, versionID, partsMetadata, errs, dataErrs, opts)
}
if disksToHealCount == 0 {
// Nothing to heal!
return result, nil
}
// After this point, only have to repair data on disk - so
// return if it is a dry-run
if dryRun {
return result, nil
}
cleanFileInfo := func(fi FileInfo) FileInfo {
// Returns a copy of the 'fi' with checksums and parts nil'ed.
nfi := fi
if !fi.IsRemote() {
nfi.Erasure.Index = 0
nfi.Erasure.Checksums = nil
}
return nfi
}
// We write at temporary location and then rename to final location.
tmpID := mustGetUUID()
migrateDataDir := mustGetUUID()
copyPartsMetadata := make([]FileInfo, len(partsMetadata))
for i := range outDatedDisks {
if outDatedDisks[i] == nil {
continue
}
copyPartsMetadata[i] = partsMetadata[i]
partsMetadata[i] = cleanFileInfo(latestMeta)
}
// source data dir shall be empty in case of XLV1
// differentiate it with dstDataDir for readability
// srcDataDir is the one used with newBitrotReader()
// to read existing content.
srcDataDir := latestMeta.DataDir
dstDataDir := latestMeta.DataDir
if latestMeta.XLV1 {
dstDataDir = migrateDataDir
}
var inlineBuffers []*bytes.Buffer
if latestMeta.InlineData() {
inlineBuffers = make([]*bytes.Buffer, len(outDatedDisks))
}
// Reorder so that we have data disks first and parity disks next.
latestDisks := shuffleDisks(availableDisks, latestMeta.Erasure.Distribution)
outDatedDisks = shuffleDisks(outDatedDisks, latestMeta.Erasure.Distribution)
partsMetadata = shufflePartsMetadata(partsMetadata, latestMeta.Erasure.Distribution)
copyPartsMetadata = shufflePartsMetadata(copyPartsMetadata, latestMeta.Erasure.Distribution)
if !latestMeta.Deleted && !latestMeta.IsRemote() {
// Heal each part. erasureHealFile() will write the healed
// part to .minio/tmp/uuid/ which needs to be renamed later to
// the final location.
erasure, err := NewErasure(ctx, latestMeta.Erasure.DataBlocks,
latestMeta.Erasure.ParityBlocks, latestMeta.Erasure.BlockSize)
if err != nil {
return result, toObjectErr(err, bucket, object)
}
erasureInfo := latestMeta.Erasure
for partIndex := 0; partIndex < len(latestMeta.Parts); partIndex++ {
partSize := latestMeta.Parts[partIndex].Size
partActualSize := latestMeta.Parts[partIndex].ActualSize
partNumber := latestMeta.Parts[partIndex].Number
tillOffset := erasure.ShardFileOffset(0, partSize, partSize)
readers := make([]io.ReaderAt, len(latestDisks))
checksumAlgo := erasureInfo.GetChecksumInfo(partNumber).Algorithm
for i, disk := range latestDisks {
if disk == OfflineDisk {
continue
}
checksumInfo := copyPartsMetadata[i].Erasure.GetChecksumInfo(partNumber)
partPath := pathJoin(object, srcDataDir, fmt.Sprintf("part.%d", partNumber))
readers[i] = newBitrotReader(disk, partsMetadata[i].Data, bucket, partPath, tillOffset, checksumAlgo,
checksumInfo.Hash, erasure.ShardSize())
}
writers := make([]io.Writer, len(outDatedDisks))
for i, disk := range outDatedDisks {
if disk == OfflineDisk {
continue
}
partPath := pathJoin(tmpID, dstDataDir, fmt.Sprintf("part.%d", partNumber))
if len(inlineBuffers) > 0 {
inlineBuffers[i] = bytes.NewBuffer(make([]byte, 0, erasure.ShardFileSize(latestMeta.Size)+32))
writers[i] = newStreamingBitrotWriterBuffer(inlineBuffers[i], DefaultBitrotAlgorithm, erasure.ShardSize())
} else {
writers[i] = newBitrotWriter(disk, minioMetaTmpBucket, partPath,
tillOffset, DefaultBitrotAlgorithm, erasure.ShardSize())
}
}
err = erasure.Heal(ctx, writers, readers, partSize)
closeBitrotReaders(readers)
closeBitrotWriters(writers)
if err != nil {
return result, toObjectErr(err, bucket, object)
}
// outDatedDisks that had write errors should not be
// written to for remaining parts, so we nil it out.
for i, disk := range outDatedDisks {
if disk == OfflineDisk {
continue
}
// A non-nil stale disk which did not receive
// a healed part checksum had a write error.
if writers[i] == nil {
outDatedDisks[i] = nil
disksToHealCount--
continue
}
partsMetadata[i].DataDir = dstDataDir
partsMetadata[i].AddObjectPart(partNumber, "", partSize, partActualSize)
partsMetadata[i].Erasure.AddChecksumInfo(ChecksumInfo{
PartNumber: partNumber,
Algorithm: checksumAlgo,
Hash: bitrotWriterSum(writers[i]),
})
if len(inlineBuffers) > 0 && inlineBuffers[i] != nil {
partsMetadata[i].Data = inlineBuffers[i].Bytes()
} else {
partsMetadata[i].Data = nil
}
}
// If all disks are having errors, we give up.
if disksToHealCount == 0 {
return result, fmt.Errorf("all disks had write errors, unable to heal")
}
}
}
defer er.deleteObject(context.Background(), minioMetaTmpBucket, tmpID, len(storageDisks)/2+1)
// Rename from tmp location to the actual location.
for i, disk := range outDatedDisks {
if disk == OfflineDisk {
continue
}
// record the index of the updated disks
partsMetadata[i].Erasure.Index = i + 1
// Attempt a rename now from healed data to final location.
if err = disk.RenameData(ctx, minioMetaTmpBucket, tmpID, partsMetadata[i], bucket, object); err != nil {
logger.LogIf(ctx, err)
return result, toObjectErr(err, bucket, object)
}
// Remove any remaining parts from outdated disks from before transition.
if partsMetadata[i].IsRemote() {
rmDataDir := partsMetadata[i].DataDir
disk.DeleteVol(ctx, pathJoin(bucket, encodeDirObject(object), rmDataDir), true)
}
for i, v := range result.Before.Drives {
if v.Endpoint == disk.String() {
result.After.Drives[i].State = madmin.DriveStateOk
}
}
}
if !diskMTime.Equal(timeSentinel) && !diskMTime.IsZero() {
// Update metadata to indicate special fix.
_, err = er.PutObjectMetadata(ctx, bucket, object, ObjectOptions{
NoLock: true,
UserDefined: map[string]string{
reservedMetadataPrefixLowerDataShardFix: "true",
// another reserved metadata to capture original disk-mtime
// captured for this version of the object, to be used
// possibly in future to heal other versions if possible.
ReservedMetadataPrefixLower + "disk-mtime": diskMTime.String(),
},
})
}
// Set the size of the object in the heal result
result.ObjectSize = latestMeta.Size
return result, nil
}
// healObjectDir - heals object directory specifically, this special call
// is needed since we do not have a special backend format for directories.
func (er erasureObjects) healObjectDir(ctx context.Context, bucket, object string, dryRun bool, remove bool) (hr madmin.HealResultItem, err error) {
storageDisks := er.getDisks()
storageEndpoints := er.getEndpoints()
// Initialize heal result object
hr = madmin.HealResultItem{
Type: madmin.HealItemObject,
Bucket: bucket,
Object: object,
DiskCount: len(storageDisks),
ParityBlocks: er.defaultParityCount,
DataBlocks: len(storageDisks) - er.defaultParityCount,
ObjectSize: 0,
}
hr.Before.Drives = make([]madmin.HealDriveInfo, len(storageDisks))
hr.After.Drives = make([]madmin.HealDriveInfo, len(storageDisks))
errs := statAllDirs(ctx, storageDisks, bucket, object)
danglingObject := isObjectDirDangling(errs)
if danglingObject {
if !dryRun && remove {
var wg sync.WaitGroup
// Remove versions in bulk for each disk
for index, disk := range storageDisks {
if disk == nil {
continue
}
wg.Add(1)
go func(index int, disk StorageAPI) {
defer wg.Done()
_ = disk.Delete(ctx, bucket, object, false)
}(index, disk)
}
wg.Wait()
NSUpdated(bucket, object)
}
}
// Prepare object creation in all disks
for i, err := range errs {
drive := storageEndpoints[i].String()
switch err {
case nil:
hr.Before.Drives[i] = madmin.HealDriveInfo{Endpoint: drive, State: madmin.DriveStateOk}
hr.After.Drives[i] = madmin.HealDriveInfo{Endpoint: drive, State: madmin.DriveStateOk}
case errDiskNotFound:
hr.Before.Drives[i] = madmin.HealDriveInfo{State: madmin.DriveStateOffline}
hr.After.Drives[i] = madmin.HealDriveInfo{State: madmin.DriveStateOffline}
case errVolumeNotFound, errFileNotFound:
// Bucket or prefix/directory not found
hr.Before.Drives[i] = madmin.HealDriveInfo{Endpoint: drive, State: madmin.DriveStateMissing}
hr.After.Drives[i] = madmin.HealDriveInfo{Endpoint: drive, State: madmin.DriveStateMissing}
default:
hr.Before.Drives[i] = madmin.HealDriveInfo{Endpoint: drive, State: madmin.DriveStateCorrupt}
hr.After.Drives[i] = madmin.HealDriveInfo{Endpoint: drive, State: madmin.DriveStateCorrupt}
}
}
if dryRun || danglingObject || isAllNotFound(errs) {
// Nothing to do, file is already gone.
return hr, nil
}
for i, err := range errs {
if err == errVolumeNotFound || err == errFileNotFound {
// Bucket or prefix/directory not found
merr := storageDisks[i].MakeVol(ctx, pathJoin(bucket, object))
switch merr {
case nil, errVolumeExists:
hr.After.Drives[i].State = madmin.DriveStateOk
case errDiskNotFound:
hr.After.Drives[i].State = madmin.DriveStateOffline
default:
logger.LogIf(ctx, merr)
hr.After.Drives[i].State = madmin.DriveStateCorrupt
}
}
}
return hr, nil
}
// Populates default heal result item entries with possible values when we are returning prematurely.
// This is to ensure that in any circumstance we are not returning empty arrays with wrong values.
func (er erasureObjects) defaultHealResult(lfi FileInfo, storageDisks []StorageAPI, storageEndpoints []Endpoint, errs []error, bucket, object, versionID string) madmin.HealResultItem {
// Initialize heal result object
result := madmin.HealResultItem{
Type: madmin.HealItemObject,
Bucket: bucket,
Object: object,
ObjectSize: lfi.Size,
VersionID: versionID,
DiskCount: len(storageDisks),
}
if lfi.IsValid() {
result.ParityBlocks = lfi.Erasure.ParityBlocks
} else {
// Default to most common configuration for erasure blocks.
result.ParityBlocks = er.defaultParityCount
}
result.DataBlocks = len(storageDisks) - result.ParityBlocks
for index, disk := range storageDisks {
if disk == nil {
result.Before.Drives = append(result.Before.Drives, madmin.HealDriveInfo{
UUID: "",
Endpoint: storageEndpoints[index].String(),
State: madmin.DriveStateOffline,
})
result.After.Drives = append(result.After.Drives, madmin.HealDriveInfo{
UUID: "",
Endpoint: storageEndpoints[index].String(),
State: madmin.DriveStateOffline,
})
continue
}
driveState := madmin.DriveStateCorrupt
switch errs[index] {
case errFileNotFound, errVolumeNotFound:
driveState = madmin.DriveStateMissing
case nil:
driveState = madmin.DriveStateOk
}
result.Before.Drives = append(result.Before.Drives, madmin.HealDriveInfo{
UUID: "",
Endpoint: storageEndpoints[index].String(),
State: driveState,
})
result.After.Drives = append(result.After.Drives, madmin.HealDriveInfo{
UUID: "",
Endpoint: storageEndpoints[index].String(),
State: driveState,
})
}
return result
}
// Stat all directories.
func statAllDirs(ctx context.Context, storageDisks []StorageAPI, bucket, prefix string) []error {
g := errgroup.WithNErrs(len(storageDisks))
for index, disk := range storageDisks {
if disk == nil {
continue
}
index := index
g.Go(func() error {
entries, err := storageDisks[index].ListDir(ctx, bucket, prefix, 1)
if err != nil {
return err
}
if len(entries) > 0 {
return errVolumeNotEmpty
}
return nil
}, index)
}
return g.Wait()
}
// isAllNotFound will return if any element of the error slice is not
// errFileNotFound, errFileVersionNotFound or errVolumeNotFound.
// A 0 length slice will always return false.
func isAllNotFound(errs []error) bool {
for _, err := range errs {
if err != nil {
switch err.Error() {
case errFileNotFound.Error():
fallthrough
case errVolumeNotFound.Error():
fallthrough
case errFileVersionNotFound.Error():
continue
}
}
return false
}
return len(errs) > 0
}
// ObjectDir is considered dangling/corrupted if any only
// if total disks - a combination of corrupted and missing
// files is lesser than N/2+1 number of disks.
// If no files were found false will be returned.
func isObjectDirDangling(errs []error) (ok bool) {
var found int
var notFound int
var foundNotEmpty int
var otherFound int
for _, readErr := range errs {
if readErr == nil {
found++
} else if readErr == errFileNotFound || readErr == errVolumeNotFound {
notFound++
} else if readErr == errVolumeNotEmpty {
foundNotEmpty++
} else {
otherFound++
}
}
found = found + foundNotEmpty + otherFound
return found < notFound && found > 0
}
func (er erasureObjects) purgeObjectDangling(ctx context.Context, bucket, object, versionID string,
metaArr []FileInfo, errs []error, dataErrs []error, opts madmin.HealOpts) (madmin.HealResultItem, error,
) {
storageDisks := er.getDisks()
storageEndpoints := er.getEndpoints()
// Check if the object is dangling, if yes and user requested
// remove we simply delete it from namespace.
m, ok := isObjectDangling(metaArr, errs, dataErrs)
if ok {
parityBlocks := er.defaultParityCount
dataBlocks := len(storageDisks) - parityBlocks
if m.IsValid() {
parityBlocks = m.Erasure.ParityBlocks
dataBlocks = m.Erasure.DataBlocks
}
writeQuorum := dataBlocks
if dataBlocks == parityBlocks {
writeQuorum++
}
var err error
if opts.Remove {
err = er.deleteObjectVersion(ctx, bucket, object, writeQuorum, FileInfo{
VersionID: versionID,
}, false)
// If Delete was successful, make sure to return the appropriate error
// and heal result appropriate with delete's error messages
errs = make([]error, len(errs))
for i := range errs {
errs[i] = err
}
if err == nil {
// Dangling object successfully purged, size is '0'
m.Size = 0
}
return er.defaultHealResult(FileInfo{}, storageDisks, storageEndpoints,
errs, bucket, object, versionID), nil
}
return er.defaultHealResult(m, storageDisks, storageEndpoints,
errs, bucket, object, versionID), toObjectErr(err, bucket, object, versionID)
}
readQuorum := len(storageDisks) - er.defaultParityCount
err := toObjectErr(reduceReadQuorumErrs(ctx, errs, objectOpIgnoredErrs, readQuorum),
bucket, object, versionID)
return er.defaultHealResult(m, storageDisks, storageEndpoints, errs, bucket, object, versionID), err
}
// Object is considered dangling/corrupted if any only
// if total disks - a combination of corrupted and missing
// files is lesser than number of data blocks.
func isObjectDangling(metaArr []FileInfo, errs []error, dataErrs []error) (validMeta FileInfo, ok bool) {
// We can consider an object data not reliable
// when xl.meta is not found in read quorum disks.
// or when xl.meta is not readable in read quorum disks.
danglingErrsCount := func(cerrs []error) (int, int) {
var (
notFoundCount int
corruptedCount int
)
for _, readErr := range cerrs {
if errors.Is(readErr, errFileNotFound) || errors.Is(readErr, errFileVersionNotFound) {
notFoundCount++
} else if errors.Is(readErr, errFileCorrupt) {
corruptedCount++
}
}
return notFoundCount, corruptedCount
}
ndataErrs := make([]error, len(dataErrs))
for i := range dataErrs {
if errs[i] != dataErrs[i] {
// Only count part errors, if the error is not
// same as xl.meta error. This is to avoid
// double counting when both parts and xl.meta
// are not available.
ndataErrs[i] = dataErrs[i]
}
}
notFoundMetaErrs, corruptedMetaErrs := danglingErrsCount(errs)
notFoundPartsErrs, corruptedPartsErrs := danglingErrsCount(ndataErrs)
for _, m := range metaArr {
if m.IsValid() {
validMeta = m
break
}
}
if !validMeta.IsValid() {
// We have no idea what this file is, leave it as is.
return validMeta, false
}
if validMeta.Deleted {
// notFoundPartsErrs is ignored since
// - delete marker does not have any parts
return validMeta, corruptedMetaErrs+notFoundMetaErrs > len(errs)/2
}
totalErrs := notFoundMetaErrs + corruptedMetaErrs + notFoundPartsErrs + corruptedPartsErrs
if validMeta.IsRemote() {
// notFoundPartsErrs is ignored since
// - transition status of complete has no parts
totalErrs = notFoundMetaErrs + corruptedMetaErrs
}
// We have valid meta, now verify if we have enough files with parity blocks.
return validMeta, totalErrs > validMeta.Erasure.ParityBlocks
}
// HealObject - heal the given object, automatically deletes the object if stale/corrupted if `remove` is true.
func (er erasureObjects) HealObject(ctx context.Context, bucket, object, versionID string, opts madmin.HealOpts) (hr madmin.HealResultItem, err error) {
defer func() {
if isErrObjectNotFound(err) || isErrVersionNotFound(err) {
err = nil
}
}()
// Create context that also contains information about the object and bucket.
// The top level handler might not have this information.
reqInfo := logger.GetReqInfo(ctx)
var newReqInfo *logger.ReqInfo
if reqInfo != nil {
newReqInfo = logger.NewReqInfo(reqInfo.RemoteHost, reqInfo.UserAgent, reqInfo.DeploymentID, reqInfo.RequestID, reqInfo.API, bucket, object)
} else {
newReqInfo = logger.NewReqInfo("", "", globalDeploymentID, "", "Heal", bucket, object)
}
healCtx := logger.SetReqInfo(GlobalContext, newReqInfo)
// Healing directories handle it separately.
if HasSuffix(object, SlashSeparator) {
return er.healObjectDir(healCtx, bucket, object, opts.DryRun, opts.Remove)
}
storageDisks := er.getDisks()
storageEndpoints := er.getEndpoints()
// When versionID is empty, we read directly from the `null` versionID for healing.
if versionID == "" {
versionID = nullVersionID
}
// Perform quick read without lock.
// This allows to quickly check if all is ok or all are missing.
_, errs := readAllFileInfo(healCtx, storageDisks, bucket, object, versionID, false)
if isAllNotFound(errs) {
// Nothing to do, file is already gone.
return er.defaultHealResult(FileInfo{}, storageDisks, storageEndpoints,
errs, bucket, object, versionID), nil
}
// Heal the object.
return er.healObject(healCtx, bucket, object, versionID, opts)
}