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minio/cmd/erasure-metadata.go
Harshavardhana 1ea7826c0e
do not have to consider replicationTimestamp for healing and quorum (#17922) 
replicationTimestamp might differ if there were retries
in replication and the retried attempt overwrote in
quorum but enough shards with newer timestamp causing
the existing timestamps on xl.meta to be invalid, we
do not rely on this value for anything external.

this is purely a hint for debugging purposes, but there
is no real value in it considering the object itself
is in-tact we do not have to spend time healing this
situation.

we may consider healing this situation in future but
that needs to be decoupled to make sure that we do not
over calculate how much we have to heal.
2023-08-25 15:31:15 -07:00

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// 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 (
"context"
"encoding/hex"
"fmt"
"sort"
"strconv"
"strings"
"time"
"github.com/minio/minio/internal/amztime"
"github.com/minio/minio/internal/bucket/replication"
"github.com/minio/minio/internal/crypto"
"github.com/minio/minio/internal/hash/sha256"
xhttp "github.com/minio/minio/internal/http"
"github.com/minio/minio/internal/logger"
"github.com/minio/pkg/sync/errgroup"
"github.com/minio/sio"
)
// Object was stored with additional erasure codes due to degraded system at upload time
const minIOErasureUpgraded = "x-minio-internal-erasure-upgraded"
const erasureAlgorithm = "rs-vandermonde"
// AddChecksumInfo adds a checksum of a part.
func (e *ErasureInfo) AddChecksumInfo(ckSumInfo ChecksumInfo) {
for i, sum := range e.Checksums {
if sum.PartNumber == ckSumInfo.PartNumber {
e.Checksums[i] = ckSumInfo
return
}
}
e.Checksums = append(e.Checksums, ckSumInfo)
}
// GetChecksumInfo - get checksum of a part.
func (e ErasureInfo) GetChecksumInfo(partNumber int) (ckSum ChecksumInfo) {
for _, sum := range e.Checksums {
if sum.PartNumber == partNumber {
// Return the checksum
return sum
}
}
return ChecksumInfo{}
}
// ShardFileSize - returns final erasure size from original size.
func (e ErasureInfo) ShardFileSize(totalLength int64) int64 {
if totalLength == 0 {
return 0
}
if totalLength == -1 {
return -1
}
numShards := totalLength / e.BlockSize
lastBlockSize := totalLength % e.BlockSize
lastShardSize := ceilFrac(lastBlockSize, int64(e.DataBlocks))
return numShards*e.ShardSize() + lastShardSize
}
// ShardSize - returns actual shared size from erasure blockSize.
func (e ErasureInfo) ShardSize() int64 {
return ceilFrac(e.BlockSize, int64(e.DataBlocks))
}
// IsValid - tells if erasure info fields are valid.
func (fi FileInfo) IsValid() bool {
if fi.Deleted {
// Delete marker has no data, no need to check
// for erasure coding information
return true
}
dataBlocks := fi.Erasure.DataBlocks
parityBlocks := fi.Erasure.ParityBlocks
correctIndexes := (fi.Erasure.Index > 0 &&
fi.Erasure.Index <= dataBlocks+parityBlocks &&
len(fi.Erasure.Distribution) == (dataBlocks+parityBlocks))
return ((dataBlocks >= parityBlocks) &&
(dataBlocks > 0) && (parityBlocks >= 0) &&
correctIndexes)
}
func (fi FileInfo) checkMultipart() (int64, bool) {
if len(fi.Parts) == 0 {
return 0, false
}
if !crypto.IsMultiPart(fi.Metadata) {
return 0, false
}
var size int64
for _, part := range fi.Parts {
psize, err := sio.DecryptedSize(uint64(part.Size))
if err != nil {
return 0, false
}
size += int64(psize)
}
return size, len(extractETag(fi.Metadata)) != 32
}
// GetActualSize - returns the actual size of the stored object
func (fi FileInfo) GetActualSize() (int64, error) {
if _, ok := fi.Metadata[ReservedMetadataPrefix+"compression"]; ok {
sizeStr, ok := fi.Metadata[ReservedMetadataPrefix+"actual-size"]
if !ok {
return -1, errInvalidDecompressedSize
}
size, err := strconv.ParseInt(sizeStr, 10, 64)
if err != nil {
return -1, errInvalidDecompressedSize
}
return size, nil
}
if _, ok := crypto.IsEncrypted(fi.Metadata); ok {
size, ok := fi.checkMultipart()
if !ok {
size, err := sio.DecryptedSize(uint64(fi.Size))
if err != nil {
err = errObjectTampered // assign correct error type
}
return int64(size), err
}
return size, nil
}
return fi.Size, nil
}
// ToObjectInfo - Converts metadata to object info.
func (fi FileInfo) ToObjectInfo(bucket, object string, versioned bool) ObjectInfo {
object = decodeDirObject(object)
versionID := fi.VersionID
if versioned && versionID == "" {
versionID = nullVersionID
}
objInfo := ObjectInfo{
IsDir: HasSuffix(object, SlashSeparator),
Bucket: bucket,
Name: object,
ParityBlocks: fi.Erasure.ParityBlocks,
DataBlocks: fi.Erasure.DataBlocks,
VersionID: versionID,
IsLatest: fi.IsLatest,
DeleteMarker: fi.Deleted,
Size: fi.Size,
ModTime: fi.ModTime,
Legacy: fi.XLV1,
ContentType: fi.Metadata["content-type"],
ContentEncoding: fi.Metadata["content-encoding"],
NumVersions: fi.NumVersions,
SuccessorModTime: fi.SuccessorModTime,
}
if exp, ok := fi.Metadata["expires"]; ok {
if t, err := amztime.ParseHeader(exp); err == nil {
objInfo.Expires = t.UTC()
}
}
objInfo.backendType = BackendErasure
// Extract etag from metadata.
objInfo.ETag = extractETag(fi.Metadata)
// Add user tags to the object info
tags := fi.Metadata[xhttp.AmzObjectTagging]
if len(tags) != 0 {
objInfo.UserTags = tags
}
// Add replication status to the object info
objInfo.ReplicationStatusInternal = fi.ReplicationState.ReplicationStatusInternal
objInfo.VersionPurgeStatusInternal = fi.ReplicationState.VersionPurgeStatusInternal
objInfo.ReplicationStatus = fi.ReplicationStatus()
objInfo.VersionPurgeStatus = fi.VersionPurgeStatus()
objInfo.TransitionedObject = TransitionedObject{
Name: fi.TransitionedObjName,
VersionID: fi.TransitionVersionID,
Status: fi.TransitionStatus,
FreeVersion: fi.TierFreeVersion(),
Tier: fi.TransitionTier,
}
// etag/md5Sum has already been extracted. We need to
// remove to avoid it from appearing as part of
// response headers. e.g, X-Minio-* or X-Amz-*.
// Tags have also been extracted, we remove that as well.
objInfo.UserDefined = cleanMetadata(fi.Metadata)
// All the parts per object.
objInfo.Parts = fi.Parts
// Update storage class
if fi.TransitionTier != "" {
objInfo.StorageClass = fi.TransitionTier
} else if sc, ok := fi.Metadata[xhttp.AmzStorageClass]; ok {
objInfo.StorageClass = sc
} else {
objInfo.StorageClass = globalMinioDefaultStorageClass
}
// set restore status for transitioned object
restoreHdr, ok := fi.Metadata[xhttp.AmzRestore]
if ok {
if restoreStatus, err := parseRestoreObjStatus(restoreHdr); err == nil {
objInfo.RestoreOngoing = restoreStatus.Ongoing()
objInfo.RestoreExpires, _ = restoreStatus.Expiry()
}
}
objInfo.Checksum = fi.Checksum
objInfo.Inlined = fi.InlineData()
// Success.
return objInfo
}
// TransitionInfoEquals returns true if transition related information are equal, false otherwise.
func (fi FileInfo) TransitionInfoEquals(ofi FileInfo) bool {
switch {
case fi.TransitionStatus != ofi.TransitionStatus,
fi.TransitionTier != ofi.TransitionTier,
fi.TransitionedObjName != ofi.TransitionedObjName,
fi.TransitionVersionID != ofi.TransitionVersionID:
return false
}
return true
}
// MetadataEquals returns true if FileInfos Metadata maps are equal, false otherwise.
func (fi FileInfo) MetadataEquals(ofi FileInfo) bool {
if len(fi.Metadata) != len(ofi.Metadata) {
return false
}
for k, v := range fi.Metadata {
if ov, ok := ofi.Metadata[k]; !ok || ov != v {
return false
}
}
return true
}
// ReplicationInfoEquals returns true if server-side replication related fields are equal, false otherwise.
func (fi FileInfo) ReplicationInfoEquals(ofi FileInfo) bool {
switch {
case fi.MarkDeleted != ofi.MarkDeleted,
!fi.ReplicationState.Equal(ofi.ReplicationState):
return false
}
return true
}
// objectPartIndex - returns the index of matching object part number.
func objectPartIndex(parts []ObjectPartInfo, partNumber int) int {
for i, part := range parts {
if partNumber == part.Number {
return i
}
}
return -1
}
// AddObjectPart - add a new object part in order.
func (fi *FileInfo) AddObjectPart(partNumber int, partETag string, partSize, actualSize int64, modTime time.Time, idx []byte, checksums map[string]string) {
partInfo := ObjectPartInfo{
Number: partNumber,
ETag: partETag,
Size: partSize,
ActualSize: actualSize,
ModTime: modTime,
Index: idx,
Checksums: checksums,
}
// Update part info if it already exists.
for i, part := range fi.Parts {
if partNumber == part.Number {
fi.Parts[i] = partInfo
return
}
}
// Proceed to include new part info.
fi.Parts = append(fi.Parts, partInfo)
// Parts in FileInfo should be in sorted order by part number.
sort.Slice(fi.Parts, func(i, j int) bool { return fi.Parts[i].Number < fi.Parts[j].Number })
}
// ObjectToPartOffset - translate offset of an object to offset of its individual part.
func (fi FileInfo) ObjectToPartOffset(ctx context.Context, offset int64) (partIndex int, partOffset int64, err error) {
if offset == 0 {
// Special case - if offset is 0, then partIndex and partOffset are always 0.
return 0, 0, nil
}
partOffset = offset
// Seek until object offset maps to a particular part offset.
for i, part := range fi.Parts {
partIndex = i
// Offset is smaller than size we have reached the proper part offset.
if partOffset < part.Size {
return partIndex, partOffset, nil
}
// Continue to towards the next part.
partOffset -= part.Size
}
logger.LogIf(ctx, InvalidRange{})
// Offset beyond the size of the object return InvalidRange.
return 0, 0, InvalidRange{}
}
func findFileInfoInQuorum(ctx context.Context, metaArr []FileInfo, modTime time.Time, etag string, quorum int) (FileInfo, error) {
// with less quorum return error.
if quorum < 1 {
return FileInfo{}, errErasureReadQuorum
}
metaHashes := make([]string, len(metaArr))
h := sha256.New()
for i, meta := range metaArr {
if !meta.IsValid() {
continue
}
etagOnly := modTime.Equal(timeSentinel) && (etag != "" && etag == meta.Metadata["etag"])
mtimeValid := meta.ModTime.Equal(modTime)
if mtimeValid || etagOnly {
fmt.Fprintf(h, "%v", meta.XLV1)
if !etagOnly {
// Verify dataDir is same only when mtime is valid and etag is not considered.
fmt.Fprintf(h, "%v", meta.GetDataDir())
}
for _, part := range meta.Parts {
fmt.Fprintf(h, "part.%d", part.Number)
}
if !meta.Deleted && meta.Size != 0 {
fmt.Fprintf(h, "%v+%v", meta.Erasure.DataBlocks, meta.Erasure.ParityBlocks)
fmt.Fprintf(h, "%v", meta.Erasure.Distribution)
}
// ILM transition fields
fmt.Fprint(h, meta.TransitionStatus)
fmt.Fprint(h, meta.TransitionTier)
fmt.Fprint(h, meta.TransitionedObjName)
fmt.Fprint(h, meta.TransitionVersionID)
// Server-side replication fields
fmt.Fprintf(h, "%v", meta.MarkDeleted)
fmt.Fprint(h, meta.Metadata[string(meta.ReplicationState.ReplicaStatus)])
fmt.Fprint(h, meta.Metadata[meta.ReplicationState.ReplicationStatusInternal])
fmt.Fprint(h, meta.Metadata[meta.ReplicationState.VersionPurgeStatusInternal])
metaHashes[i] = hex.EncodeToString(h.Sum(nil))
h.Reset()
}
}
metaHashCountMap := make(map[string]int)
for _, hash := range metaHashes {
if hash == "" {
continue
}
metaHashCountMap[hash]++
}
maxHash := ""
maxCount := 0
for hash, count := range metaHashCountMap {
if count > maxCount {
maxCount = count
maxHash = hash
}
}
if maxCount < quorum {
return FileInfo{}, errErasureReadQuorum
}
for i, hash := range metaHashes {
if hash == maxHash {
if metaArr[i].IsValid() {
return metaArr[i], nil
}
}
}
return FileInfo{}, errErasureReadQuorum
}
func pickValidDiskTimeWithQuorum(metaArr []FileInfo, quorum int) time.Time {
diskMTimes := listObjectDiskMtimes(metaArr)
diskMTime, diskMaxima := commonTimeAndOccurence(diskMTimes, shardDiskTimeDelta)
if diskMaxima >= quorum {
return diskMTime
}
return timeSentinel
}
// pickValidFileInfo - picks one valid FileInfo content and returns from a
// slice of FileInfo.
func pickValidFileInfo(ctx context.Context, metaArr []FileInfo, modTime time.Time, etag string, quorum int) (FileInfo, error) {
return findFileInfoInQuorum(ctx, metaArr, modTime, etag, quorum)
}
// writeUniqueFileInfo - writes unique `xl.meta` content for each disk concurrently.
func writeUniqueFileInfo(ctx context.Context, disks []StorageAPI, bucket, prefix string, files []FileInfo, quorum int) ([]StorageAPI, error) {
g := errgroup.WithNErrs(len(disks))
// Start writing `xl.meta` to all disks in parallel.
for index := range disks {
index := index
g.Go(func() error {
if disks[index] == nil {
return errDiskNotFound
}
// Pick one FileInfo for a disk at index.
fi := files[index]
fi.Erasure.Index = index + 1
if fi.IsValid() {
return disks[index].WriteMetadata(ctx, bucket, prefix, fi)
}
return errCorruptedFormat
}, index)
}
// Wait for all the routines.
mErrs := g.Wait()
err := reduceWriteQuorumErrs(ctx, mErrs, objectOpIgnoredErrs, quorum)
return evalDisks(disks, mErrs), err
}
func commonParity(parities []int, defaultParityCount int) int {
N := len(parities)
occMap := make(map[int]int)
for _, p := range parities {
occMap[p]++
}
var maxOcc, cparity int
for parity, occ := range occMap {
if parity == -1 {
// Ignore non defined parity
continue
}
readQuorum := N - parity
if defaultParityCount > 0 && parity == 0 {
// In this case, parity == 0 implies that this object version is a
// delete marker
readQuorum = N/2 + 1
}
if occ < readQuorum {
// Ignore this parity since we don't have enough shards for read quorum
continue
}
if occ > maxOcc {
maxOcc = occ
cparity = parity
}
}
if maxOcc == 0 {
// Did not found anything useful
return -1
}
return cparity
}
func listObjectParities(partsMetadata []FileInfo, errs []error) (parities []int) {
parities = make([]int, len(partsMetadata))
for index, metadata := range partsMetadata {
if errs[index] != nil {
parities[index] = -1
continue
}
if !metadata.IsValid() {
parities[index] = -1
continue
}
// Delete marker or zero byte objects take highest parity.
if metadata.Deleted || metadata.Size == 0 {
parities[index] = len(partsMetadata) / 2
} else {
parities[index] = metadata.Erasure.ParityBlocks
}
}
return
}
// Returns per object readQuorum and writeQuorum
// readQuorum is the min required disks to read data.
// writeQuorum is the min required disks to write data.
func objectQuorumFromMeta(ctx context.Context, partsMetaData []FileInfo, errs []error, defaultParityCount int) (objectReadQuorum, objectWriteQuorum int, err error) {
// There should be atleast half correct entries, if not return failure
expectedRQuorum := len(partsMetaData) / 2
if defaultParityCount == 0 {
// if parity count is '0', we expected all entries to be present.
expectedRQuorum = len(partsMetaData)
}
reducedErr := reduceReadQuorumErrs(ctx, errs, objectOpIgnoredErrs, expectedRQuorum)
if reducedErr != nil {
return -1, -1, reducedErr
}
// special case when parity is '0'
if defaultParityCount == 0 {
return len(partsMetaData), len(partsMetaData), nil
}
parities := listObjectParities(partsMetaData, errs)
parityBlocks := commonParity(parities, defaultParityCount)
if parityBlocks < 0 {
return -1, -1, errErasureReadQuorum
}
if parityBlocks == 0 {
// For delete markers do not use 'defaultParityCount' as it is not expected to be the case.
// Use maximum allowed read quorum instead, writeQuorum+1 is returned for compatibility sake
// but there are no callers that shall be using this.
readQuorum := len(partsMetaData) / 2
return readQuorum, readQuorum + 1, nil
}
dataBlocks := len(partsMetaData) - parityBlocks
writeQuorum := dataBlocks
if dataBlocks == parityBlocks {
writeQuorum++
}
// Since all the valid erasure code meta updated at the same time are equivalent, pass dataBlocks
// from latestFileInfo to get the quorum
return dataBlocks, writeQuorum, nil
}
const (
tierFVID = "tier-free-versionID"
tierFVMarker = "tier-free-marker"
)
// SetTierFreeVersionID sets free-version's versionID. This method is used by
// object layer to pass down a versionID to set for a free-version that may be
// created.
func (fi *FileInfo) SetTierFreeVersionID(versionID string) {
if fi.Metadata == nil {
fi.Metadata = make(map[string]string)
}
fi.Metadata[ReservedMetadataPrefixLower+tierFVID] = versionID
}
// TierFreeVersionID returns the free-version's version id.
func (fi *FileInfo) TierFreeVersionID() string {
return fi.Metadata[ReservedMetadataPrefixLower+tierFVID]
}
// SetTierFreeVersion sets fi as a free-version. This method is used by
// lower layers to indicate a free-version.
func (fi *FileInfo) SetTierFreeVersion() {
if fi.Metadata == nil {
fi.Metadata = make(map[string]string)
}
fi.Metadata[ReservedMetadataPrefixLower+tierFVMarker] = ""
}
// TierFreeVersion returns true if version is a free-version.
func (fi *FileInfo) TierFreeVersion() bool {
_, ok := fi.Metadata[ReservedMetadataPrefixLower+tierFVMarker]
return ok
}
// IsRestoreObjReq returns true if fi corresponds to a RestoreObject request.
func (fi *FileInfo) IsRestoreObjReq() bool {
if restoreHdr, ok := fi.Metadata[xhttp.AmzRestore]; ok {
if restoreStatus, err := parseRestoreObjStatus(restoreHdr); err == nil {
if !restoreStatus.Ongoing() {
return true
}
}
}
return false
}
// VersionPurgeStatus returns overall version purge status for this object version across targets
func (fi *FileInfo) VersionPurgeStatus() VersionPurgeStatusType {
return fi.ReplicationState.CompositeVersionPurgeStatus()
}
// ReplicationStatus returns overall version replication status for this object version across targets
func (fi *FileInfo) ReplicationStatus() replication.StatusType {
return fi.ReplicationState.CompositeReplicationStatus()
}
// DeleteMarkerReplicationStatus returns overall replication status for this delete marker version across targets
func (fi *FileInfo) DeleteMarkerReplicationStatus() replication.StatusType {
if fi.Deleted {
return fi.ReplicationState.CompositeReplicationStatus()
}
return replication.StatusType("")
}
// GetInternalReplicationState is a wrapper method to fetch internal replication state from the map m
func GetInternalReplicationState(m map[string][]byte) ReplicationState {
m1 := make(map[string]string, len(m))
for k, v := range m {
m1[k] = string(v)
}
return getInternalReplicationState(m1)
}
// getInternalReplicationState fetches internal replication state from the map m
func getInternalReplicationState(m map[string]string) ReplicationState {
d := ReplicationState{}
for k, v := range m {
switch {
case equals(k, ReservedMetadataPrefixLower+ReplicationTimestamp):
d.ReplicaTimeStamp, _ = amztime.ParseReplicationTS(v)
case equals(k, ReservedMetadataPrefixLower+ReplicaTimestamp):
d.ReplicaTimeStamp, _ = amztime.ParseReplicationTS(v)
case equals(k, ReservedMetadataPrefixLower+ReplicaStatus):
d.ReplicaStatus = replication.StatusType(v)
case equals(k, ReservedMetadataPrefixLower+ReplicationStatus):
d.ReplicationStatusInternal = v
d.Targets = replicationStatusesMap(v)
case equals(k, VersionPurgeStatusKey):
d.VersionPurgeStatusInternal = v
d.PurgeTargets = versionPurgeStatusesMap(v)
case strings.HasPrefix(k, ReservedMetadataPrefixLower+ReplicationReset):
arn := strings.TrimPrefix(k, fmt.Sprintf("%s-", ReservedMetadataPrefixLower+ReplicationReset))
if d.ResetStatusesMap == nil {
d.ResetStatusesMap = make(map[string]string, 1)
}
d.ResetStatusesMap[arn] = v
}
}
return d
}
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