// 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 . package cmd import ( "bytes" "context" "errors" "fmt" "io" "net/http" "path" "runtime" "strconv" "strings" "sync" "time" "github.com/klauspost/readahead" "github.com/minio/madmin-go/v3" "github.com/minio/minio-go/v7/pkg/tags" "github.com/minio/minio/internal/bucket/lifecycle" "github.com/minio/minio/internal/bucket/object/lock" "github.com/minio/minio/internal/bucket/replication" "github.com/minio/minio/internal/crypto" "github.com/minio/minio/internal/event" "github.com/minio/minio/internal/hash" xhttp "github.com/minio/minio/internal/http" xioutil "github.com/minio/minio/internal/ioutil" "github.com/minio/minio/internal/logger" "github.com/minio/pkg/v2/mimedb" "github.com/minio/pkg/v2/sync/errgroup" "github.com/minio/pkg/v2/wildcard" ) // list all errors which can be ignored in object operations. var objectOpIgnoredErrs = append(baseIgnoredErrs, errDiskAccessDenied, errUnformattedDisk, errDiskOngoingReq) // Object Operations func countOnlineDisks(onlineDisks []StorageAPI) (online int) { for _, onlineDisk := range onlineDisks { if onlineDisk != nil && onlineDisk.IsOnline() { online++ } } return online } // CopyObject - copy object source object to destination object. // if source object and destination object are same we only // update metadata. func (er erasureObjects) CopyObject(ctx context.Context, srcBucket, srcObject, dstBucket, dstObject string, srcInfo ObjectInfo, srcOpts, dstOpts ObjectOptions) (oi ObjectInfo, err error) { auditObjectErasureSet(ctx, dstObject, &er) // This call shouldn't be used for anything other than metadata updates or adding self referential versions. if !srcInfo.metadataOnly { return oi, NotImplemented{} } if !dstOpts.NoLock { lk := er.NewNSLock(dstBucket, dstObject) lkctx, err := lk.GetLock(ctx, globalOperationTimeout) if err != nil { return oi, err } ctx = lkctx.Context() defer lk.Unlock(lkctx) } // Read metadata associated with the object from all disks. storageDisks := er.getDisks() var metaArr []FileInfo var errs []error // Read metadata associated with the object from all disks. if srcOpts.VersionID != "" { metaArr, errs = readAllFileInfo(ctx, storageDisks, "", srcBucket, srcObject, srcOpts.VersionID, true, false) } else { metaArr, errs = readAllXL(ctx, storageDisks, srcBucket, srcObject, true, false, true) } readQuorum, writeQuorum, err := objectQuorumFromMeta(ctx, metaArr, errs, er.defaultParityCount) if err != nil { if errors.Is(err, errErasureReadQuorum) && !strings.HasPrefix(srcBucket, minioMetaBucket) { _, derr := er.deleteIfDangling(context.Background(), srcBucket, srcObject, metaArr, errs, nil, srcOpts) if derr != nil { err = derr } } return ObjectInfo{}, toObjectErr(err, srcBucket, srcObject) } // List all online disks. onlineDisks, modTime, etag := listOnlineDisks(storageDisks, metaArr, errs, readQuorum) // Pick latest valid metadata. fi, err := pickValidFileInfo(ctx, metaArr, modTime, etag, readQuorum) if err != nil { return oi, toObjectErr(err, srcBucket, srcObject) } if fi.Deleted { if srcOpts.VersionID == "" { return oi, toObjectErr(errFileNotFound, srcBucket, srcObject) } return fi.ToObjectInfo(srcBucket, srcObject, srcOpts.Versioned || srcOpts.VersionSuspended), toObjectErr(errMethodNotAllowed, srcBucket, srcObject) } filterOnlineDisksInplace(fi, metaArr, onlineDisks) versionID := srcInfo.VersionID if srcInfo.versionOnly { versionID = dstOpts.VersionID // preserve destination versionId if specified. if versionID == "" { versionID = mustGetUUID() fi.IsLatest = true // we are creating a new version so this is latest. } } modTime = UTCNow() // We only preserve modTime if dstOpts.MTime is true. // in all other cases mtime is latest. fi.VersionID = versionID // set any new versionID we might have created fi.ModTime = modTime // set modTime for the new versionID if !dstOpts.MTime.IsZero() { modTime = dstOpts.MTime fi.ModTime = dstOpts.MTime } fi.Metadata = srcInfo.UserDefined srcInfo.UserDefined["etag"] = srcInfo.ETag inlineData := fi.InlineData() freeVersionID := fi.TierFreeVersionID() freeVersionMarker := fi.TierFreeVersion() // Update `xl.meta` content on each disks. for index := range metaArr { if metaArr[index].IsValid() { metaArr[index].ModTime = modTime metaArr[index].VersionID = versionID if !metaArr[index].InlineData() { // If the data is not inlined, we may end up incorrectly // inlining the data here, that leads to an inconsistent // situation where some objects are were not inlined // were now inlined, make sure to `nil` the Data such // that xl.meta is written as expected. metaArr[index].Data = nil } metaArr[index].Metadata = srcInfo.UserDefined // Preserve existing values if inlineData { metaArr[index].SetInlineData() } if freeVersionID != "" { metaArr[index].SetTierFreeVersionID(freeVersionID) } if freeVersionMarker { metaArr[index].SetTierFreeVersion() } } } // Write unique `xl.meta` for each disk. if _, err = writeUniqueFileInfo(ctx, onlineDisks, "", srcBucket, srcObject, metaArr, writeQuorum); err != nil { return oi, toObjectErr(err, srcBucket, srcObject) } return fi.ToObjectInfo(srcBucket, srcObject, srcOpts.Versioned || srcOpts.VersionSuspended), nil } // GetObjectNInfo - returns object info and an object // Read(Closer). When err != nil, the returned reader is always nil. func (er erasureObjects) GetObjectNInfo(ctx context.Context, bucket, object string, rs *HTTPRangeSpec, h http.Header, opts ObjectOptions) (gr *GetObjectReader, err error) { auditObjectErasureSet(ctx, object, &er) var unlockOnDefer bool nsUnlocker := func() {} defer func() { if unlockOnDefer { nsUnlocker() } }() // Acquire lock if !opts.NoLock { lock := er.NewNSLock(bucket, object) lkctx, err := lock.GetRLock(ctx, globalOperationTimeout) if err != nil { return nil, err } ctx = lkctx.Context() // Release lock when the metadata is verified, and reader // is ready to be read. // // This is possible to be lock free because // - xl.meta for inlined objects has already read the data // into memory, any mutation on xl.meta subsequently is // inconsequential to the overall read operation. // - xl.meta metadata is still verified for quorum under lock() // however writing the response doesn't need to serialize // concurrent writers unlockOnDefer = true nsUnlocker = func() { lock.RUnlock(lkctx) } } fi, metaArr, onlineDisks, err := er.getObjectFileInfo(ctx, bucket, object, opts, true) if err != nil { return nil, toObjectErr(err, bucket, object) } objInfo := fi.ToObjectInfo(bucket, object, opts.Versioned || opts.VersionSuspended) if objInfo.DeleteMarker { if opts.VersionID == "" { return &GetObjectReader{ ObjInfo: objInfo, }, toObjectErr(errFileNotFound, bucket, object) } // Make sure to return object info to provide extra information. return &GetObjectReader{ ObjInfo: objInfo, }, toObjectErr(errMethodNotAllowed, bucket, object) } if objInfo.IsRemote() { gr, err := getTransitionedObjectReader(ctx, bucket, object, rs, h, objInfo, opts) if err != nil { return nil, err } unlockOnDefer = false return gr.WithCleanupFuncs(nsUnlocker), nil } if objInfo.Size == 0 { // Zero byte objects don't even need to further initialize pipes etc. return NewGetObjectReaderFromReader(bytes.NewReader(nil), objInfo, opts) } fn, off, length, err := NewGetObjectReader(rs, objInfo, opts) if err != nil { return nil, err } if unlockOnDefer { unlockOnDefer = fi.InlineData() } pr, pw := xioutil.WaitPipe() go func() { pw.CloseWithError(er.getObjectWithFileInfo(ctx, bucket, object, off, length, pw, fi, metaArr, onlineDisks)) }() // Cleanup function to cause the go routine above to exit, in // case of incomplete read. pipeCloser := func() { pr.CloseWithError(nil) } if !unlockOnDefer { return fn(pr, h, pipeCloser, nsUnlocker) } return fn(pr, h, pipeCloser) } func (er erasureObjects) getObjectWithFileInfo(ctx context.Context, bucket, object string, startOffset int64, length int64, writer io.Writer, fi FileInfo, metaArr []FileInfo, onlineDisks []StorageAPI) error { // Reorder online disks based on erasure distribution order. // Reorder parts metadata based on erasure distribution order. onlineDisks, metaArr = shuffleDisksAndPartsMetadataByIndex(onlineDisks, metaArr, fi) // For negative length read everything. if length < 0 { length = fi.Size - startOffset } // Reply back invalid range if the input offset and length fall out of range. if startOffset > fi.Size || startOffset+length > fi.Size { return InvalidRange{startOffset, length, fi.Size} } // Get start part index and offset. partIndex, partOffset, err := fi.ObjectToPartOffset(ctx, startOffset) if err != nil { return InvalidRange{startOffset, length, fi.Size} } // Calculate endOffset according to length endOffset := startOffset if length > 0 { endOffset += length - 1 } // Get last part index to read given length. lastPartIndex, _, err := fi.ObjectToPartOffset(ctx, endOffset) if err != nil { return InvalidRange{startOffset, length, fi.Size} } var totalBytesRead int64 erasure, err := NewErasure(ctx, fi.Erasure.DataBlocks, fi.Erasure.ParityBlocks, fi.Erasure.BlockSize) if err != nil { return toObjectErr(err, bucket, object) } var healOnce sync.Once for ; partIndex <= lastPartIndex; partIndex++ { if length == totalBytesRead { break } partNumber := fi.Parts[partIndex].Number // Save the current part name and size. partSize := fi.Parts[partIndex].Size partLength := partSize - partOffset // partLength should be adjusted so that we don't write more data than what was requested. if partLength > (length - totalBytesRead) { partLength = length - totalBytesRead } tillOffset := erasure.ShardFileOffset(partOffset, partLength, partSize) // Get the checksums of the current part. readers := make([]io.ReaderAt, len(onlineDisks)) prefer := make([]bool, len(onlineDisks)) for index, disk := range onlineDisks { if disk == OfflineDisk { continue } if !metaArr[index].IsValid() { continue } if !metaArr[index].Erasure.Equal(fi.Erasure) { continue } checksumInfo := metaArr[index].Erasure.GetChecksumInfo(partNumber) partPath := pathJoin(object, metaArr[index].DataDir, fmt.Sprintf("part.%d", partNumber)) readers[index] = newBitrotReader(disk, metaArr[index].Data, bucket, partPath, tillOffset, checksumInfo.Algorithm, checksumInfo.Hash, erasure.ShardSize()) // Prefer local disks prefer[index] = disk.Hostname() == "" } written, err := erasure.Decode(ctx, writer, readers, partOffset, partLength, partSize, prefer) // Note: we should not be defer'ing the following closeBitrotReaders() call as // we are inside a for loop i.e if we use defer, we would accumulate a lot of open files by the time // we return from this function. closeBitrotReaders(readers) if err != nil { // If we have successfully written all the content that was asked // by the client, but we still see an error - this would mean // that we have some parts or data blocks missing or corrupted // - attempt a heal to successfully heal them for future calls. if written == partLength { var scan madmin.HealScanMode switch { case errors.Is(err, errFileNotFound): scan = madmin.HealNormalScan case errors.Is(err, errFileCorrupt): scan = madmin.HealDeepScan } switch scan { case madmin.HealNormalScan, madmin.HealDeepScan: healOnce.Do(func() { globalMRFState.addPartialOp(partialOperation{ bucket: bucket, object: object, versionID: fi.VersionID, queued: time.Now(), setIndex: er.setIndex, poolIndex: er.poolIndex, scanMode: scan, }) }) // Healing is triggered and we have written // successfully the content to client for // the specific part, we should `nil` this error // and proceed forward, instead of throwing errors. err = nil } } if err != nil { return toObjectErr(err, bucket, object) } } for i, r := range readers { if r == nil { onlineDisks[i] = OfflineDisk } } // Track total bytes read from disk and written to the client. totalBytesRead += partLength // partOffset will be valid only for the first part, hence reset it to 0 for // the remaining parts. partOffset = 0 } // End of read all parts loop. // Return success. return nil } // GetObjectInfo - reads object metadata and replies back ObjectInfo. func (er erasureObjects) GetObjectInfo(ctx context.Context, bucket, object string, opts ObjectOptions) (info ObjectInfo, err error) { auditObjectErasureSet(ctx, object, &er) if !opts.NoLock { // Lock the object before reading. lk := er.NewNSLock(bucket, object) lkctx, err := lk.GetRLock(ctx, globalOperationTimeout) if err != nil { return ObjectInfo{}, err } ctx = lkctx.Context() defer lk.RUnlock(lkctx) } return er.getObjectInfo(ctx, bucket, object, opts) } func auditDanglingObjectDeletion(ctx context.Context, bucket, object, versionID string, tags map[string]interface{}) { if len(logger.AuditTargets()) == 0 { return } opts := AuditLogOptions{ Event: "DeleteDanglingObject", Bucket: bucket, Object: object, VersionID: versionID, Tags: tags, } auditLogInternal(ctx, opts) } func joinErrs(errs []error) []string { s := make([]string, len(errs)) for i := range s { if errs[i] == nil { s[i] = "" } else { s[i] = errs[i].Error() } } return s } func (er erasureObjects) deleteIfDangling(ctx context.Context, bucket, object string, metaArr []FileInfo, errs []error, dataErrs []error, opts ObjectOptions) (FileInfo, error) { var err error m, ok := isObjectDangling(metaArr, errs, dataErrs) if ok { tags := make(map[string]interface{}, 4) tags["set"] = er.setIndex tags["pool"] = er.poolIndex tags["merrs"] = joinErrs(errs) tags["derrs"] = joinErrs(dataErrs) if m.IsValid() { tags["size"] = m.Size tags["mtime"] = m.ModTime.Format(http.TimeFormat) tags["data"] = m.Erasure.DataBlocks tags["parity"] = m.Erasure.ParityBlocks } else { tags["invalid-meta"] = true tags["data"] = er.setDriveCount - er.defaultParityCount tags["parity"] = er.defaultParityCount } // count the number of offline disks offline := 0 for i := 0; i < max(len(errs), len(dataErrs)); i++ { if i < len(errs) && errors.Is(errs[i], errDiskNotFound) || i < len(dataErrs) && errors.Is(dataErrs[i], errDiskNotFound) { offline++ } } if offline > 0 { tags["offline"] = offline } _, file, line, cok := runtime.Caller(1) if cok { tags["caller"] = fmt.Sprintf("%s:%d", file, line) } defer auditDanglingObjectDeletion(ctx, bucket, object, m.VersionID, tags) err = errFileNotFound if opts.VersionID != "" { err = errFileVersionNotFound } fi := FileInfo{ VersionID: m.VersionID, } if opts.VersionID != "" { fi.VersionID = opts.VersionID } fi.SetTierFreeVersionID(mustGetUUID()) disks := er.getDisks() g := errgroup.WithNErrs(len(disks)) for index := range disks { index := index g.Go(func() error { if disks[index] == nil { return errDiskNotFound } return disks[index].DeleteVersion(ctx, bucket, object, fi, false, DeleteOptions{}) }, index) } rmDisks := make(map[string]string, len(disks)) for index, err := range g.Wait() { var errStr, diskName string if err != nil { errStr = err.Error() } else { errStr = "" } if disks[index] != nil { diskName = disks[index].String() } else { diskName = fmt.Sprintf("disk-%d", index) } rmDisks[diskName] = errStr } tags["cleanupResult"] = rmDisks } return m, err } func fileInfoFromRaw(ri RawFileInfo, bucket, object string, readData, inclFreeVers, allParts bool) (FileInfo, error) { var xl xlMetaV2 if err := xl.LoadOrConvert(ri.Buf); err != nil { return FileInfo{}, err } fi, err := xl.ToFileInfo(bucket, object, "", inclFreeVers, allParts) if err != nil { return FileInfo{}, err } if !fi.IsValid() { return FileInfo{}, errCorruptedFormat } versionID := fi.VersionID if versionID == "" { versionID = nullVersionID } fileInfo, err := xl.ToFileInfo(bucket, object, versionID, inclFreeVers, allParts) if err != nil { return FileInfo{}, err } if readData { fileInfo.Data = xl.data.find(versionID) } return fileInfo, nil } func readAllRawFileInfo(ctx context.Context, disks []StorageAPI, bucket, object string, readData bool) ([]RawFileInfo, []error) { rawFileInfos := make([]RawFileInfo, len(disks)) g := errgroup.WithNErrs(len(disks)) for index := range disks { index := index g.Go(func() (err error) { if disks[index] == nil { return errDiskNotFound } rf, err := disks[index].ReadXL(ctx, bucket, object, readData) if err != nil { return err } rawFileInfos[index] = rf return nil }, index) } return rawFileInfos, g.Wait() } func pickLatestQuorumFilesInfo(ctx context.Context, rawFileInfos []RawFileInfo, errs []error, bucket, object string, readData, inclFreeVers, allParts bool) ([]FileInfo, []error) { metadataArray := make([]*xlMetaV2, len(rawFileInfos)) metaFileInfos := make([]FileInfo, len(rawFileInfos)) metadataShallowVersions := make([][]xlMetaV2ShallowVersion, len(rawFileInfos)) var v2bufs [][]byte if !readData { v2bufs = make([][]byte, len(rawFileInfos)) } // Read `xl.meta` in parallel across disks. for index := range rawFileInfos { rf := rawFileInfos[index] if rf.Buf == nil { continue } if !readData { // Save the buffer so we can reuse it. v2bufs[index] = rf.Buf } var xl xlMetaV2 if err := xl.LoadOrConvert(rf.Buf); err != nil { errs[index] = err continue } metadataArray[index] = &xl metaFileInfos[index] = FileInfo{} } for index := range metadataArray { if metadataArray[index] != nil { metadataShallowVersions[index] = metadataArray[index].versions } } readQuorum := (len(rawFileInfos) + 1) / 2 meta := &xlMetaV2{versions: mergeXLV2Versions(readQuorum, false, 1, metadataShallowVersions...)} lfi, err := meta.ToFileInfo(bucket, object, "", inclFreeVers, allParts) if err != nil { for i := range errs { if errs[i] == nil { errs[i] = err } } return metaFileInfos, errs } if !lfi.IsValid() { for i := range errs { if errs[i] == nil { errs[i] = errCorruptedFormat } } return metaFileInfos, errs } versionID := lfi.VersionID if versionID == "" { versionID = nullVersionID } for index := range metadataArray { if metadataArray[index] == nil { continue } // make sure to preserve this for diskmtime based healing bugfix. metaFileInfos[index], errs[index] = metadataArray[index].ToFileInfo(bucket, object, versionID, inclFreeVers, allParts) if errs[index] != nil { continue } if readData { metaFileInfos[index].Data = metadataArray[index].data.find(versionID) } } if !readData { for i := range v2bufs { metaDataPoolPut(v2bufs[i]) } } // Return all the metadata. return metaFileInfos, errs } // Checking if an object is dangling costs some IOPS; hence implementing this function // which decides which condition it is useful to check if an object is dangling // // errs: errors from reading xl.meta in all disks // err: reduced errs // bucket: the object name in question func shouldCheckForDangling(err error, errs []error, bucket string) bool { // Avoid data in .minio.sys for now if bucket == minioMetaBucket { return false } switch { // Check if we have a read quorum issue case errors.Is(err, errErasureReadQuorum): return true // Check if the object is inexistent in most disks but not all of them case errors.Is(err, errFileNotFound) || errors.Is(err, errFileVersionNotFound): for i := range errs { if errs[i] == nil { return true } } } return false } func readAllXL(ctx context.Context, disks []StorageAPI, bucket, object string, readData, inclFreeVers, allParts bool) ([]FileInfo, []error) { rawFileInfos, errs := readAllRawFileInfo(ctx, disks, bucket, object, readData) return pickLatestQuorumFilesInfo(ctx, rawFileInfos, errs, bucket, object, readData, inclFreeVers, allParts) } func (er erasureObjects) getObjectFileInfo(ctx context.Context, bucket, object string, opts ObjectOptions, readData bool) (FileInfo, []FileInfo, []StorageAPI, error) { rawArr := make([]RawFileInfo, er.setDriveCount) metaArr := make([]FileInfo, er.setDriveCount) errs := make([]error, er.setDriveCount) for i := range errs { errs[i] = errDiskOngoingReq } done := make(chan bool, er.setDriveCount) disks := er.getDisks() ropts := ReadOptions{ ReadData: readData, Healing: false, } mrfCheck := make(chan FileInfo) defer xioutil.SafeClose(mrfCheck) var rw sync.Mutex // Ask for all disks first; go func() { ctx, cancel := context.WithCancel(ctx) defer cancel() wg := sync.WaitGroup{} for i, disk := range disks { if disk == nil { done <- false continue } if !disk.IsOnline() { done <- false continue } wg.Add(1) go func(i int, disk StorageAPI) { defer wg.Done() var ( fi FileInfo rfi RawFileInfo err error ) if opts.VersionID != "" { // Read a specific version ID fi, err = disk.ReadVersion(ctx, "", bucket, object, opts.VersionID, ropts) } else { // Read the latest version rfi, err = disk.ReadXL(ctx, bucket, object, readData) if err == nil { fi, err = fileInfoFromRaw(rfi, bucket, object, readData, opts.InclFreeVersions, true) } } rw.Lock() rawArr[i] = rfi metaArr[i], errs[i] = fi, err rw.Unlock() done <- err == nil }(i, disk) } wg.Wait() xioutil.SafeClose(done) fi, ok := <-mrfCheck if !ok { return } if fi.Deleted { return } // if one of the disk is offline, return right here no need // to attempt a heal on the object. if countErrs(errs, errDiskNotFound) > 0 { return } var missingBlocks int for i := range errs { if IsErr(errs[i], errFileNotFound, errFileVersionNotFound, errFileCorrupt, ) { missingBlocks++ } } // if missing metadata can be reconstructed, attempt to reconstruct. // additionally do not heal delete markers inline, let them be // healed upon regular heal process. if missingBlocks > 0 && missingBlocks < fi.Erasure.DataBlocks { globalMRFState.addPartialOp(partialOperation{ bucket: fi.Volume, object: fi.Name, versionID: fi.VersionID, queued: time.Now(), setIndex: er.setIndex, poolIndex: er.poolIndex, }) } return }() validResp := 0 totalResp := 0 // minDisks value is only to reduce the number of calls // to the disks; this value is not accurate because we do // not know the storage class of the object yet minDisks := 0 if p := globalStorageClass.GetParityForSC(""); p > -1 { minDisks = er.setDriveCount - p } else { minDisks = er.setDriveCount - er.defaultParityCount } calcQuorum := func(metaArr []FileInfo, errs []error) (FileInfo, []FileInfo, []StorageAPI, time.Time, string, error) { readQuorum, _, err := objectQuorumFromMeta(ctx, metaArr, errs, er.defaultParityCount) if err != nil { return FileInfo{}, nil, nil, time.Time{}, "", err } if err := reduceReadQuorumErrs(ctx, errs, objectOpIgnoredErrs, readQuorum); err != nil { return FileInfo{}, nil, nil, time.Time{}, "", err } onlineDisks, modTime, etag := listOnlineDisks(disks, metaArr, errs, readQuorum) fi, err := pickValidFileInfo(ctx, metaArr, modTime, etag, readQuorum) if err != nil { return FileInfo{}, nil, nil, time.Time{}, "", err } onlineMeta := make([]FileInfo, len(metaArr)) for i, disk := range onlineDisks { if disk != nil { onlineMeta[i] = metaArr[i] } } return fi, onlineMeta, onlineDisks, modTime, etag, nil } var ( modTime time.Time etag string fi FileInfo onlineMeta []FileInfo onlineDisks []StorageAPI err error ) for success := range done { totalResp++ if success { validResp++ } if totalResp < er.setDriveCount { if !opts.FastGetObjInfo { continue } if validResp < minDisks { continue } } rw.Lock() if opts.VersionID == "" && totalResp == er.setDriveCount { fi, onlineMeta, onlineDisks, modTime, etag, err = calcQuorum(pickLatestQuorumFilesInfo(ctx, rawArr, errs, bucket, object, readData, opts.InclFreeVersions, true)) } else { fi, onlineMeta, onlineDisks, modTime, etag, err = calcQuorum(metaArr, errs) } rw.Unlock() if err == nil && fi.InlineData() { break } } if err != nil { // We can only look for dangling if we received all the responses, if we did // not we simply ignore it, since we can't tell for sure if its dangling object. if totalResp == er.setDriveCount && shouldCheckForDangling(err, errs, bucket) { _, derr := er.deleteIfDangling(context.Background(), bucket, object, metaArr, errs, nil, opts) if derr != nil { err = derr } } return fi, nil, nil, toObjectErr(err, bucket, object) } if !fi.Deleted && len(fi.Erasure.Distribution) != len(onlineDisks) { err := fmt.Errorf("unexpected file distribution (%v) from online disks (%v), looks like backend disks have been manually modified refusing to heal %s/%s(%s)", fi.Erasure.Distribution, onlineDisks, bucket, object, opts.VersionID) logger.LogOnceIf(ctx, err, "get-object-file-info-manually-modified") return fi, nil, nil, toObjectErr(err, bucket, object, opts.VersionID) } filterOnlineDisksInplace(fi, onlineMeta, onlineDisks) for i := range onlineMeta { // verify metadata is valid, it has similar erasure info // as well as common modtime, if modtime is not possible // verify if it has common "etag" at least. if onlineMeta[i].IsValid() && onlineMeta[i].Erasure.Equal(fi.Erasure) { ok := onlineMeta[i].ModTime.Equal(modTime) if modTime.IsZero() || modTime.Equal(timeSentinel) { ok = etag != "" && etag == fi.Metadata["etag"] } if ok { continue } } // in all other cases metadata is corrupt, do not read from it. onlineMeta[i] = FileInfo{} onlineDisks[i] = nil } select { case mrfCheck <- fi.ShallowCopy(): case <-ctx.Done(): return fi, onlineMeta, onlineDisks, toObjectErr(ctx.Err(), bucket, object) } return fi, onlineMeta, onlineDisks, nil } // getObjectInfo - wrapper for reading object metadata and constructs ObjectInfo. func (er erasureObjects) getObjectInfo(ctx context.Context, bucket, object string, opts ObjectOptions) (objInfo ObjectInfo, err error) { fi, _, _, err := er.getObjectFileInfo(ctx, bucket, object, opts, false) if err != nil { return objInfo, toObjectErr(err, bucket, object) } objInfo = fi.ToObjectInfo(bucket, object, opts.Versioned || opts.VersionSuspended) if fi.Deleted { if opts.VersionID == "" || opts.DeleteMarker { return objInfo, toObjectErr(errFileNotFound, bucket, object) } // Make sure to return object info to provide extra information. return objInfo, toObjectErr(errMethodNotAllowed, bucket, object) } return objInfo, nil } // getObjectInfoAndQuorum - wrapper for reading object metadata and constructs ObjectInfo, additionally returns write quorum for the object. func (er erasureObjects) getObjectInfoAndQuorum(ctx context.Context, bucket, object string, opts ObjectOptions) (objInfo ObjectInfo, wquorum int, err error) { fi, _, _, err := er.getObjectFileInfo(ctx, bucket, object, opts, false) if err != nil { return objInfo, er.defaultWQuorum(), toObjectErr(err, bucket, object) } wquorum = fi.WriteQuorum(er.defaultWQuorum()) objInfo = fi.ToObjectInfo(bucket, object, opts.Versioned || opts.VersionSuspended) if !fi.VersionPurgeStatus().Empty() && opts.VersionID != "" { // Make sure to return object info to provide extra information. return objInfo, wquorum, toObjectErr(errMethodNotAllowed, bucket, object) } if fi.Deleted { if opts.VersionID == "" || opts.DeleteMarker { return objInfo, wquorum, toObjectErr(errFileNotFound, bucket, object) } // Make sure to return object info to provide extra information. return objInfo, wquorum, toObjectErr(errMethodNotAllowed, bucket, object) } return objInfo, wquorum, nil } // Similar to rename but renames data from srcEntry to dstEntry at dataDir func renameData(ctx context.Context, disks []StorageAPI, srcBucket, srcEntry string, metadata []FileInfo, dstBucket, dstEntry string, writeQuorum int) ([]StorageAPI, bool, error) { g := errgroup.WithNErrs(len(disks)) fvID := mustGetUUID() for index := range disks { metadata[index].SetTierFreeVersionID(fvID) } diskVersions := make([]uint64, len(disks)) // Rename file on all underlying storage disks. 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 := metadata[index] // Assign index when index is initialized if fi.Erasure.Index == 0 { fi.Erasure.Index = index + 1 } if !fi.IsValid() { return errFileCorrupt } sign, err := disks[index].RenameData(ctx, srcBucket, srcEntry, fi, dstBucket, dstEntry, RenameOptions{}) if err != nil { return err } diskVersions[index] = sign return nil }, index) } // Wait for all renames to finish. errs := g.Wait() var versionsDisparity bool err := reduceWriteQuorumErrs(ctx, errs, objectOpIgnoredErrs, writeQuorum) if err != nil { dg := errgroup.WithNErrs(len(disks)) for index, nerr := range errs { if nerr != nil { continue } index := index // When we are going to return error, attempt to delete success // on some of the drives, if we cannot we do not have to notify // caller this dangling object will be now scheduled to be removed // via active healing. dg.Go(func() error { return disks[index].DeleteVersion(context.Background(), dstBucket, dstEntry, metadata[index], false, DeleteOptions{UndoWrite: true}) }, index) } dg.Wait() } if err == nil { versions := reduceCommonVersions(diskVersions, writeQuorum) for index, dversions := range diskVersions { if errs[index] != nil { continue } if versions != dversions { versionsDisparity = true break } } } // We can safely allow RenameData errors up to len(er.getDisks()) - writeQuorum // otherwise return failure. return evalDisks(disks, errs), versionsDisparity, err } func (er erasureObjects) putMetacacheObject(ctx context.Context, key string, r *PutObjReader, opts ObjectOptions) (objInfo ObjectInfo, err error) { data := r.Reader // No metadata is set, allocate a new one. if opts.UserDefined == nil { opts.UserDefined = make(map[string]string) } storageDisks := er.getDisks() // Get parity and data drive count based on storage class metadata parityDrives := globalStorageClass.GetParityForSC(opts.UserDefined[xhttp.AmzStorageClass]) if parityDrives < 0 { parityDrives = er.defaultParityCount } dataDrives := len(storageDisks) - parityDrives // we now know the number of blocks this object needs for data and parity. // writeQuorum is dataBlocks + 1 writeQuorum := dataDrives if dataDrives == parityDrives { writeQuorum++ } // Validate input data size and it can never be less than zero. if data.Size() < -1 { logger.LogIf(ctx, errInvalidArgument, logger.ErrorKind) return ObjectInfo{}, toObjectErr(errInvalidArgument) } // Initialize parts metadata partsMetadata := make([]FileInfo, len(storageDisks)) fi := newFileInfo(pathJoin(minioMetaBucket, key), dataDrives, parityDrives) fi.DataDir = mustGetUUID() // Initialize erasure metadata. for index := range partsMetadata { partsMetadata[index] = fi } // Order disks according to erasure distribution var onlineDisks []StorageAPI onlineDisks, partsMetadata = shuffleDisksAndPartsMetadata(storageDisks, partsMetadata, fi) erasure, err := NewErasure(ctx, fi.Erasure.DataBlocks, fi.Erasure.ParityBlocks, fi.Erasure.BlockSize) if err != nil { return ObjectInfo{}, toObjectErr(err, minioMetaBucket, key) } // Fetch buffer for I/O, returns from the pool if not allocates a new one and returns. var buffer []byte switch size := data.Size(); { case size == 0: buffer = make([]byte, 1) // Allocate at least a byte to reach EOF case size >= fi.Erasure.BlockSize: buffer = globalBytePoolCap.Get() defer globalBytePoolCap.Put(buffer) case size < fi.Erasure.BlockSize: // No need to allocate fully blockSizeV1 buffer if the incoming data is smaller. buffer = make([]byte, size, 2*size+int64(fi.Erasure.ParityBlocks+fi.Erasure.DataBlocks-1)) } if len(buffer) > int(fi.Erasure.BlockSize) { buffer = buffer[:fi.Erasure.BlockSize] } shardFileSize := erasure.ShardFileSize(data.Size()) writers := make([]io.Writer, len(onlineDisks)) inlineBuffers := make([]*bytes.Buffer, len(onlineDisks)) for i, disk := range onlineDisks { if disk == nil { continue } if disk.IsOnline() { inlineBuffers[i] = bytes.NewBuffer(make([]byte, 0, shardFileSize)) writers[i] = newStreamingBitrotWriterBuffer(inlineBuffers[i], DefaultBitrotAlgorithm, erasure.ShardSize()) } } n, erasureErr := erasure.Encode(ctx, data, writers, buffer, writeQuorum) closeBitrotWriters(writers) if erasureErr != nil { return ObjectInfo{}, toObjectErr(erasureErr, minioMetaBucket, key) } // Should return IncompleteBody{} error when reader has fewer bytes // than specified in request header. if n < data.Size() { return ObjectInfo{}, IncompleteBody{Bucket: minioMetaBucket, Object: key} } var index []byte if opts.IndexCB != nil { index = opts.IndexCB() } modTime := UTCNow() for i, w := range writers { if w == nil { // Make sure to avoid writing to disks which we couldn't complete in erasure.Encode() onlineDisks[i] = nil continue } partsMetadata[i].Data = inlineBuffers[i].Bytes() partsMetadata[i].AddObjectPart(1, "", n, data.ActualSize(), modTime, index, nil) } // Fill all the necessary metadata. // Update `xl.meta` content on each disks. for index := range partsMetadata { partsMetadata[index].Size = n partsMetadata[index].Fresh = true partsMetadata[index].ModTime = modTime partsMetadata[index].Metadata = opts.UserDefined } // Set an additional header when data is inlined. for index := range partsMetadata { partsMetadata[index].SetInlineData() } for i := 0; i < len(onlineDisks); i++ { if onlineDisks[i] != nil && onlineDisks[i].IsOnline() { // Object info is the same in all disks, so we can pick // the first meta from online disk fi = partsMetadata[i] break } } if _, err = writeUniqueFileInfo(ctx, onlineDisks, "", minioMetaBucket, key, partsMetadata, writeQuorum); err != nil { return ObjectInfo{}, toObjectErr(err, minioMetaBucket, key) } return fi.ToObjectInfo(minioMetaBucket, key, opts.Versioned || opts.VersionSuspended), nil } // PutObject - creates an object upon reading from the input stream // until EOF, erasure codes the data across all disk and additionally // writes `xl.meta` which carries the necessary metadata for future // object operations. func (er erasureObjects) PutObject(ctx context.Context, bucket string, object string, data *PutObjReader, opts ObjectOptions) (objInfo ObjectInfo, err error) { return er.putObject(ctx, bucket, object, data, opts) } // Heal up to two versions of one object when there is disparity between disks func healObjectVersionsDisparity(bucket string, entry metaCacheEntry, scanMode madmin.HealScanMode) error { if entry.isDir() { return nil } // We might land at .metacache, .trash, .multipart // no need to heal them skip, only when bucket // is '.minio.sys' if bucket == minioMetaBucket { if wildcard.Match("buckets/*/.metacache/*", entry.name) { return nil } if wildcard.Match("tmp/*", entry.name) { return nil } if wildcard.Match("multipart/*", entry.name) { return nil } if wildcard.Match("tmp-old/*", entry.name) { return nil } } fivs, err := entry.fileInfoVersions(bucket) if err != nil { healObject(bucket, entry.name, "", madmin.HealDeepScan) return err } if len(fivs.Versions) <= 2 { for _, version := range fivs.Versions { healObject(bucket, entry.name, version.VersionID, scanMode) } } return nil } // putObject wrapper for erasureObjects PutObject func (er erasureObjects) putObject(ctx context.Context, bucket string, object string, r *PutObjReader, opts ObjectOptions) (objInfo ObjectInfo, err error) { auditObjectErasureSet(ctx, object, &er) data := r.Reader if opts.CheckPrecondFn != nil { if !opts.NoLock { ns := er.NewNSLock(bucket, object) lkctx, err := ns.GetLock(ctx, globalOperationTimeout) if err != nil { return ObjectInfo{}, err } ctx = lkctx.Context() defer ns.Unlock(lkctx) opts.NoLock = true } obj, err := er.getObjectInfo(ctx, bucket, object, opts) if err == nil && opts.CheckPrecondFn(obj) { return objInfo, PreConditionFailed{} } if err != nil && !isErrVersionNotFound(err) && !isErrObjectNotFound(err) && !isErrReadQuorum(err) { return objInfo, err } } // Validate input data size and it can never be less than -1. if data.Size() < -1 { logger.LogIf(ctx, errInvalidArgument, logger.ErrorKind) return ObjectInfo{}, toObjectErr(errInvalidArgument) } userDefined := cloneMSS(opts.UserDefined) storageDisks := er.getDisks() parityDrives := len(storageDisks) / 2 if !opts.MaxParity { // Get parity and data drive count based on storage class metadata parityDrives = globalStorageClass.GetParityForSC(userDefined[xhttp.AmzStorageClass]) if parityDrives < 0 { parityDrives = er.defaultParityCount } // If we have offline disks upgrade the number of erasure codes for this object. parityOrig := parityDrives var offlineDrives int for _, disk := range storageDisks { if disk == nil { parityDrives++ offlineDrives++ continue } if !disk.IsOnline() { parityDrives++ offlineDrives++ continue } } if offlineDrives >= (len(storageDisks)+1)/2 { // if offline drives are more than 50% of the drives // we have no quorum, we shouldn't proceed just // fail at that point. return ObjectInfo{}, toObjectErr(errErasureWriteQuorum, bucket, object) } if parityDrives >= len(storageDisks)/2 { parityDrives = len(storageDisks) / 2 } if parityOrig != parityDrives { userDefined[minIOErasureUpgraded] = strconv.Itoa(parityOrig) + "->" + strconv.Itoa(parityDrives) } } dataDrives := len(storageDisks) - parityDrives // we now know the number of blocks this object needs for data and parity. // writeQuorum is dataBlocks + 1 writeQuorum := dataDrives if dataDrives == parityDrives { writeQuorum++ } // Initialize parts metadata partsMetadata := make([]FileInfo, len(storageDisks)) fi := newFileInfo(pathJoin(bucket, object), dataDrives, parityDrives) fi.VersionID = opts.VersionID if opts.Versioned && fi.VersionID == "" { fi.VersionID = mustGetUUID() } fi.DataDir = mustGetUUID() fi.Checksum = opts.WantChecksum.AppendTo(nil, nil) if opts.EncryptFn != nil { fi.Checksum = opts.EncryptFn("object-checksum", fi.Checksum) } uniqueID := mustGetUUID() tempObj := uniqueID // Initialize erasure metadata. for index := range partsMetadata { partsMetadata[index] = fi } // Order disks according to erasure distribution var onlineDisks []StorageAPI onlineDisks, partsMetadata = shuffleDisksAndPartsMetadata(storageDisks, partsMetadata, fi) erasure, err := NewErasure(ctx, fi.Erasure.DataBlocks, fi.Erasure.ParityBlocks, fi.Erasure.BlockSize) if err != nil { return ObjectInfo{}, toObjectErr(err, bucket, object) } // Fetch buffer for I/O, returns from the pool if not allocates a new one and returns. var buffer []byte switch size := data.Size(); { case size == 0: buffer = make([]byte, 1) // Allocate at least a byte to reach EOF case size >= fi.Erasure.BlockSize || size == -1: buffer = globalBytePoolCap.Get() defer globalBytePoolCap.Put(buffer) case size < fi.Erasure.BlockSize: // No need to allocate fully blockSizeV1 buffer if the incoming data is smaller. buffer = make([]byte, size, 2*size+int64(fi.Erasure.ParityBlocks+fi.Erasure.DataBlocks-1)) } if len(buffer) > int(fi.Erasure.BlockSize) { buffer = buffer[:fi.Erasure.BlockSize] } partName := "part.1" tempErasureObj := pathJoin(uniqueID, fi.DataDir, partName) defer er.deleteAll(context.Background(), minioMetaTmpBucket, tempObj) shardFileSize := erasure.ShardFileSize(data.Size()) writers := make([]io.Writer, len(onlineDisks)) var inlineBuffers []*bytes.Buffer if shardFileSize >= 0 { if !opts.Versioned && shardFileSize < smallFileThreshold { inlineBuffers = make([]*bytes.Buffer, len(onlineDisks)) } else if shardFileSize < smallFileThreshold/8 { inlineBuffers = make([]*bytes.Buffer, len(onlineDisks)) } } else { // If compressed, use actual size to determine. if sz := erasure.ShardFileSize(data.ActualSize()); sz > 0 { if !opts.Versioned && sz < smallFileThreshold { inlineBuffers = make([]*bytes.Buffer, len(onlineDisks)) } else if sz < smallFileThreshold/8 { inlineBuffers = make([]*bytes.Buffer, len(onlineDisks)) } } } for i, disk := range onlineDisks { if disk == nil { continue } if !disk.IsOnline() { continue } if len(inlineBuffers) > 0 { sz := shardFileSize if sz < 0 { sz = data.ActualSize() } inlineBuffers[i] = bytes.NewBuffer(make([]byte, 0, sz)) writers[i] = newStreamingBitrotWriterBuffer(inlineBuffers[i], DefaultBitrotAlgorithm, erasure.ShardSize()) continue } writers[i] = newBitrotWriter(disk, bucket, minioMetaTmpBucket, tempErasureObj, shardFileSize, DefaultBitrotAlgorithm, erasure.ShardSize()) } toEncode := io.Reader(data) if data.Size() > bigFileThreshold { // We use 2 buffers, so we always have a full buffer of input. bufA := globalBytePoolCap.Get() bufB := globalBytePoolCap.Get() defer globalBytePoolCap.Put(bufA) defer globalBytePoolCap.Put(bufB) ra, err := readahead.NewReaderBuffer(data, [][]byte{bufA[:fi.Erasure.BlockSize], bufB[:fi.Erasure.BlockSize]}) if err == nil { toEncode = ra defer ra.Close() } logger.LogIf(ctx, err) } n, erasureErr := erasure.Encode(ctx, toEncode, writers, buffer, writeQuorum) closeBitrotWriters(writers) if erasureErr != nil { return ObjectInfo{}, toObjectErr(erasureErr, bucket, object) } // Should return IncompleteBody{} error when reader has fewer bytes // than specified in request header. if n < data.Size() { return ObjectInfo{}, IncompleteBody{Bucket: bucket, Object: object} } var compIndex []byte if opts.IndexCB != nil { compIndex = opts.IndexCB() } if !opts.NoLock { lk := er.NewNSLock(bucket, object) lkctx, err := lk.GetLock(ctx, globalOperationTimeout) if err != nil { return ObjectInfo{}, err } ctx = lkctx.Context() defer lk.Unlock(lkctx) } modTime := opts.MTime if opts.MTime.IsZero() { modTime = UTCNow() } for i, w := range writers { if w == nil { onlineDisks[i] = nil continue } if len(inlineBuffers) > 0 && inlineBuffers[i] != nil { partsMetadata[i].Data = inlineBuffers[i].Bytes() } else { partsMetadata[i].Data = nil } // No need to add checksum to part. We already have it on the object. partsMetadata[i].AddObjectPart(1, "", n, data.ActualSize(), modTime, compIndex, nil) partsMetadata[i].Versioned = opts.Versioned || opts.VersionSuspended } userDefined["etag"] = r.MD5CurrentHexString() kind, _ := crypto.IsEncrypted(userDefined) if opts.PreserveETag != "" { if !opts.ReplicationRequest { userDefined["etag"] = opts.PreserveETag } else if kind != crypto.S3 { // if we have a replication request // and SSE-S3 is specified do not preserve // the incoming etag. userDefined["etag"] = opts.PreserveETag } } // Guess content-type from the extension if possible. if userDefined["content-type"] == "" { userDefined["content-type"] = mimedb.TypeByExtension(path.Ext(object)) } // Fill all the necessary metadata. // Update `xl.meta` content on each disks. for index := range partsMetadata { partsMetadata[index].Metadata = userDefined partsMetadata[index].Size = n partsMetadata[index].ModTime = modTime if len(inlineBuffers) > 0 { partsMetadata[index].SetInlineData() } if opts.DataMovement { partsMetadata[index].SetDataMov() } } // Rename the successfully written temporary object to final location. onlineDisks, versionsDisparity, err := renameData(ctx, onlineDisks, minioMetaTmpBucket, tempObj, partsMetadata, bucket, object, writeQuorum) if err != nil { if errors.Is(err, errFileNotFound) { return ObjectInfo{}, toObjectErr(errErasureWriteQuorum, bucket, object) } return ObjectInfo{}, toObjectErr(err, bucket, object) } for i := 0; i < len(onlineDisks); i++ { if onlineDisks[i] != nil && onlineDisks[i].IsOnline() { // Object info is the same in all disks, so we can pick // the first meta from online disk fi = partsMetadata[i] break } } // For speedtest objects do not attempt to heal them. if !opts.Speedtest { // When there is versions disparity we are healing // the content implicitly for all versions, we can // avoid triggering another MRF heal for offline drives. if !versionsDisparity { // Whether a disk was initially or becomes offline // during this upload, send it to the MRF list. for i := 0; i < len(onlineDisks); i++ { if onlineDisks[i] != nil && onlineDisks[i].IsOnline() { continue } er.addPartial(bucket, object, fi.VersionID) break } } else { globalMRFState.addPartialOp(partialOperation{ bucket: bucket, object: object, queued: time.Now(), allVersions: true, setIndex: er.setIndex, poolIndex: er.poolIndex, }) } } fi.ReplicationState = opts.PutReplicationState() // we are adding a new version to this object under the namespace lock, so this is the latest version. fi.IsLatest = true return fi.ToObjectInfo(bucket, object, opts.Versioned || opts.VersionSuspended), nil } func (er erasureObjects) deleteObjectVersion(ctx context.Context, bucket, object string, fi FileInfo, forceDelMarker bool) error { disks := er.getDisks() // Assume (N/2 + 1) quorum for Delete() // this is a theoretical assumption such that // for delete's we do not need to honor storage // class for objects that have reduced quorum // due to storage class - this only needs to be honored // for Read() requests alone that we already do. writeQuorum := len(disks)/2 + 1 g := errgroup.WithNErrs(len(disks)) for index := range disks { index := index g.Go(func() error { if disks[index] == nil { return errDiskNotFound } return disks[index].DeleteVersion(ctx, bucket, object, fi, forceDelMarker, DeleteOptions{}) }, index) } // return errors if any during deletion return reduceWriteQuorumErrs(ctx, g.Wait(), objectOpIgnoredErrs, writeQuorum) } // DeleteObjects deletes objects/versions in bulk, this function will still automatically split objects list // into smaller bulks if some object names are found to be duplicated in the delete list, splitting // into smaller bulks will avoid holding twice the write lock of the duplicated object names. func (er erasureObjects) DeleteObjects(ctx context.Context, bucket string, objects []ObjectToDelete, opts ObjectOptions) ([]DeletedObject, []error) { for _, obj := range objects { auditObjectErasureSet(ctx, obj.ObjectV.ObjectName, &er) } errs := make([]error, len(objects)) dobjects := make([]DeletedObject, len(objects)) writeQuorums := make([]int, len(objects)) storageDisks := er.getDisks() for i := range objects { // Assume (N/2 + 1) quorums for all objects // this is a theoretical assumption such that // for delete's we do not need to honor storage // class for objects which have reduced quorum // storage class only needs to be honored for // Read() requests alone which we already do. writeQuorums[i] = len(storageDisks)/2 + 1 } versionsMap := make(map[string]FileInfoVersions, len(objects)) for i := range objects { // Construct the FileInfo data that needs to be preserved on the disk. vr := FileInfo{ Name: objects[i].ObjectName, VersionID: objects[i].VersionID, ReplicationState: objects[i].ReplicationState(), // save the index to set correct error at this index. Idx: i, } vr.SetTierFreeVersionID(mustGetUUID()) // VersionID is not set means delete is not specific about // any version, look for if the bucket is versioned or not. if objects[i].VersionID == "" { // MinIO extension to bucket version configuration suspended := opts.VersionSuspended versioned := opts.Versioned if opts.PrefixEnabledFn != nil { versioned = opts.PrefixEnabledFn(objects[i].ObjectName) } if versioned || suspended { // Bucket is versioned and no version was explicitly // mentioned for deletes, create a delete marker instead. vr.ModTime = UTCNow() vr.Deleted = true // Versioning suspended means that we add a `null` version // delete marker, if not add a new version for this delete // marker. if versioned { vr.VersionID = mustGetUUID() } } } // De-dup same object name to collect multiple versions for same object. v, ok := versionsMap[objects[i].ObjectName] if ok { v.Versions = append(v.Versions, vr) } else { v = FileInfoVersions{ Name: vr.Name, Versions: []FileInfo{vr}, } } if vr.Deleted { dobjects[i] = DeletedObject{ DeleteMarker: vr.Deleted, DeleteMarkerVersionID: vr.VersionID, DeleteMarkerMTime: DeleteMarkerMTime{vr.ModTime}, ObjectName: vr.Name, ReplicationState: vr.ReplicationState, } } else { dobjects[i] = DeletedObject{ ObjectName: vr.Name, VersionID: vr.VersionID, ReplicationState: vr.ReplicationState, } } versionsMap[objects[i].ObjectName] = v } dedupVersions := make([]FileInfoVersions, 0, len(versionsMap)) for _, version := range versionsMap { dedupVersions = append(dedupVersions, version) } // Initialize list of errors. delObjErrs := make([][]error, len(storageDisks)) var wg sync.WaitGroup // Remove versions in bulk for each disk for index, disk := range storageDisks { wg.Add(1) go func(index int, disk StorageAPI) { defer wg.Done() delObjErrs[index] = make([]error, len(objects)) if disk == nil { for i := range objects { delObjErrs[index][i] = errDiskNotFound } return } errs := disk.DeleteVersions(ctx, bucket, dedupVersions, DeleteOptions{}) for i, err := range errs { if err == nil { continue } for _, v := range dedupVersions[i].Versions { if err == errFileNotFound || err == errFileVersionNotFound { if !dobjects[v.Idx].DeleteMarker { // Not delete marker, if not found, ok. continue } } delObjErrs[index][v.Idx] = err } } }(index, disk) } wg.Wait() // Reduce errors for each object for objIndex := range objects { diskErrs := make([]error, len(storageDisks)) // Iterate over disks to fetch the error // of deleting of the current object for i := range delObjErrs { // delObjErrs[i] is not nil when disks[i] is also not nil if delObjErrs[i] != nil { diskErrs[i] = delObjErrs[i][objIndex] } } err := reduceWriteQuorumErrs(ctx, diskErrs, objectOpIgnoredErrs, writeQuorums[objIndex]) if objects[objIndex].VersionID != "" { errs[objIndex] = toObjectErr(err, bucket, objects[objIndex].ObjectName, objects[objIndex].VersionID) } else { errs[objIndex] = toObjectErr(err, bucket, objects[objIndex].ObjectName) } } // Check failed deletes across multiple objects for i, dobj := range dobjects { // This object errored, we should attempt a heal just in case. if errs[i] != nil && !isErrVersionNotFound(errs[i]) && !isErrObjectNotFound(errs[i]) { // all other direct versionId references we should // ensure no dangling file is left over. er.addPartial(bucket, dobj.ObjectName, dobj.VersionID) continue } // Check if there is any offline disk and add it to the MRF list for _, disk := range storageDisks { if disk != nil && disk.IsOnline() { // Skip attempted heal on online disks. continue } // all other direct versionId references we should // ensure no dangling file is left over. er.addPartial(bucket, dobj.ObjectName, dobj.VersionID) break } } return dobjects, errs } func (er erasureObjects) deletePrefix(ctx context.Context, bucket, prefix string) error { disks := er.getDisks() g := errgroup.WithNErrs(len(disks)) dirPrefix := encodeDirObject(prefix) for index := range disks { index := index g.Go(func() error { if disks[index] == nil { return nil } // Deletes // - The prefix and its children // - The prefix__XLDIR__ defer disks[index].Delete(ctx, bucket, dirPrefix, DeleteOptions{ Recursive: true, Immediate: true, }) return disks[index].Delete(ctx, bucket, prefix, DeleteOptions{ Recursive: true, Immediate: true, }) }, index) } for _, err := range g.Wait() { if err != nil { return err } } return nil } // DeleteObject - deletes an object, this call doesn't necessary reply // any error as it is not necessary for the handler to reply back a // response to the client request. func (er erasureObjects) DeleteObject(ctx context.Context, bucket, object string, opts ObjectOptions) (objInfo ObjectInfo, err error) { auditObjectErasureSet(ctx, object, &er) if opts.DeletePrefix { if globalCacheConfig.Enabled() { return ObjectInfo{}, toObjectErr(errMethodNotAllowed, bucket, object) } return ObjectInfo{}, toObjectErr(er.deletePrefix(ctx, bucket, object), bucket, object) } var lc *lifecycle.Lifecycle var rcfg lock.Retention var replcfg *replication.Config if opts.Expiration.Expire { // Check if the current bucket has a configured lifecycle policy lc, _ = globalLifecycleSys.Get(bucket) rcfg, _ = globalBucketObjectLockSys.Get(bucket) replcfg, _ = getReplicationConfig(ctx, bucket) } // expiration attempted on a bucket with no lifecycle // rules shall be rejected. if lc == nil && opts.Expiration.Expire { if opts.VersionID != "" { return objInfo, VersionNotFound{ Bucket: bucket, Object: object, VersionID: opts.VersionID, } } return objInfo, ObjectNotFound{ Bucket: bucket, Object: object, } } storageDisks := er.getDisks() versionFound := true objInfo = ObjectInfo{VersionID: opts.VersionID} // version id needed in Delete API response. goi, _, gerr := er.getObjectInfoAndQuorum(ctx, bucket, object, opts) if gerr != nil && goi.Name == "" { if _, ok := gerr.(InsufficientReadQuorum); ok { return objInfo, InsufficientWriteQuorum{} } // For delete marker replication, versionID being replicated will not exist on disk if opts.DeleteMarker { versionFound = false } else { return objInfo, gerr } } if opts.EvalMetadataFn != nil { dsc, err := opts.EvalMetadataFn(&goi, err) if err != nil { return ObjectInfo{}, err } if dsc.ReplicateAny() { opts.SetDeleteReplicationState(dsc, opts.VersionID) goi.replicationDecision = opts.DeleteReplication.ReplicateDecisionStr } } if opts.EvalRetentionBypassFn != nil { if err := opts.EvalRetentionBypassFn(goi, gerr); err != nil { return ObjectInfo{}, err } } if opts.Expiration.Expire { if gerr == nil { evt := evalActionFromLifecycle(ctx, *lc, rcfg, replcfg, goi) var isErr bool switch evt.Action { case lifecycle.NoneAction: isErr = true case lifecycle.TransitionAction, lifecycle.TransitionVersionAction: isErr = true } if isErr { if goi.VersionID != "" { return goi, VersionNotFound{ Bucket: bucket, Object: object, VersionID: goi.VersionID, } } return goi, ObjectNotFound{ Bucket: bucket, Object: object, } } } } // Determine whether to mark object deleted for replication markDelete := goi.VersionID != "" // Default deleteMarker to true if object is under versioning deleteMarker := opts.Versioned if opts.VersionID != "" { // case where replica version needs to be deleted on target cluster if versionFound && opts.DeleteMarkerReplicationStatus() == replication.Replica { markDelete = false } if opts.VersionPurgeStatus().Empty() && opts.DeleteMarkerReplicationStatus().Empty() { markDelete = false } if opts.VersionPurgeStatus() == Complete { markDelete = false } // now, since VersionPurgeStatus() is already set, we can let the // lower layers decide this. This fixes a regression that was introduced // in PR #14555 where !VersionPurgeStatus.Empty() is automatically // considered as Delete marker true to avoid listing such objects by // regular ListObjects() calls. However for delete replication this // ends up being a problem because "upon" a successful delete this // ends up creating a new delete marker that is spurious and unnecessary. // // Regression introduced by #14555 was reintroduced in #15564 if versionFound { if !goi.VersionPurgeStatus.Empty() { deleteMarker = false } else if !goi.DeleteMarker { // implies a versioned delete of object deleteMarker = false } } } modTime := opts.MTime if opts.MTime.IsZero() { modTime = UTCNow() } fvID := mustGetUUID() defer func() { // attempt a heal before returning if there are offline disks // for both del marker and permanent delete situations. for _, disk := range storageDisks { if disk != nil && disk.IsOnline() { continue } er.addPartial(bucket, object, opts.VersionID) break } }() if markDelete && (opts.Versioned || opts.VersionSuspended) { if !deleteMarker { // versioning suspended means we add `null` version as // delete marker, if its not decided already. deleteMarker = opts.VersionSuspended && opts.VersionID == "" } fi := FileInfo{ Name: object, Deleted: deleteMarker, MarkDeleted: markDelete, ModTime: modTime, ReplicationState: opts.DeleteReplication, TransitionStatus: opts.Transition.Status, ExpireRestored: opts.Transition.ExpireRestored, } fi.SetTierFreeVersionID(fvID) if opts.VersionID != "" { fi.VersionID = opts.VersionID } else if opts.Versioned { fi.VersionID = mustGetUUID() } // versioning suspended means we add `null` version as // delete marker. Add delete marker, since we don't have // any version specified explicitly. Or if a particular // version id needs to be replicated. if err = er.deleteObjectVersion(ctx, bucket, object, fi, opts.DeleteMarker); err != nil { return objInfo, toObjectErr(err, bucket, object) } oi := fi.ToObjectInfo(bucket, object, opts.Versioned || opts.VersionSuspended) oi.replicationDecision = goi.replicationDecision return oi, nil } // Delete the object version on all disks. dfi := FileInfo{ Name: object, VersionID: opts.VersionID, MarkDeleted: markDelete, Deleted: deleteMarker, ModTime: modTime, ReplicationState: opts.DeleteReplication, TransitionStatus: opts.Transition.Status, ExpireRestored: opts.Transition.ExpireRestored, } dfi.SetTierFreeVersionID(fvID) if err = er.deleteObjectVersion(ctx, bucket, object, dfi, opts.DeleteMarker); err != nil { return objInfo, toObjectErr(err, bucket, object) } return dfi.ToObjectInfo(bucket, object, opts.Versioned || opts.VersionSuspended), nil } // Send the successful but partial upload/delete, however ignore // if the channel is blocked by other items. func (er erasureObjects) addPartial(bucket, object, versionID string) { globalMRFState.addPartialOp(partialOperation{ bucket: bucket, object: object, versionID: versionID, queued: time.Now(), }) } func (er erasureObjects) PutObjectMetadata(ctx context.Context, bucket, object string, opts ObjectOptions) (ObjectInfo, error) { if !opts.NoLock { // Lock the object before updating metadata. lk := er.NewNSLock(bucket, object) lkctx, err := lk.GetLock(ctx, globalOperationTimeout) if err != nil { return ObjectInfo{}, err } ctx = lkctx.Context() defer lk.Unlock(lkctx) } disks := er.getDisks() var metaArr []FileInfo var errs []error // Read metadata associated with the object from all disks. if opts.VersionID != "" { metaArr, errs = readAllFileInfo(ctx, disks, "", bucket, object, opts.VersionID, false, false) } else { metaArr, errs = readAllXL(ctx, disks, bucket, object, false, false, true) } readQuorum, _, err := objectQuorumFromMeta(ctx, metaArr, errs, er.defaultParityCount) if err != nil { if errors.Is(err, errErasureReadQuorum) && !strings.HasPrefix(bucket, minioMetaBucket) { _, derr := er.deleteIfDangling(context.Background(), bucket, object, metaArr, errs, nil, opts) if derr != nil { err = derr } } return ObjectInfo{}, toObjectErr(err, bucket, object) } // List all online disks. onlineDisks, modTime, etag := listOnlineDisks(disks, metaArr, errs, readQuorum) // Pick latest valid metadata. fi, err := pickValidFileInfo(ctx, metaArr, modTime, etag, readQuorum) if err != nil { return ObjectInfo{}, toObjectErr(err, bucket, object) } if fi.Deleted { return ObjectInfo{}, toObjectErr(errMethodNotAllowed, bucket, object) } filterOnlineDisksInplace(fi, metaArr, onlineDisks) // if version-id is not specified retention is supposed to be set on the latest object. if opts.VersionID == "" { opts.VersionID = fi.VersionID } objInfo := fi.ToObjectInfo(bucket, object, opts.Versioned || opts.VersionSuspended) if opts.EvalMetadataFn != nil { if _, err := opts.EvalMetadataFn(&objInfo, err); err != nil { return ObjectInfo{}, err } } for k, v := range objInfo.UserDefined { fi.Metadata[k] = v } fi.ModTime = opts.MTime fi.VersionID = opts.VersionID if err = er.updateObjectMeta(ctx, bucket, object, fi, onlineDisks); err != nil { return ObjectInfo{}, toObjectErr(err, bucket, object) } return fi.ToObjectInfo(bucket, object, opts.Versioned || opts.VersionSuspended), nil } // PutObjectTags - replace or add tags to an existing object func (er erasureObjects) PutObjectTags(ctx context.Context, bucket, object string, tags string, opts ObjectOptions) (ObjectInfo, error) { // Lock the object before updating tags. lk := er.NewNSLock(bucket, object) lkctx, err := lk.GetLock(ctx, globalOperationTimeout) if err != nil { return ObjectInfo{}, err } ctx = lkctx.Context() defer lk.Unlock(lkctx) disks := er.getDisks() var metaArr []FileInfo var errs []error // Read metadata associated with the object from all disks. if opts.VersionID != "" { metaArr, errs = readAllFileInfo(ctx, disks, "", bucket, object, opts.VersionID, false, false) } else { metaArr, errs = readAllXL(ctx, disks, bucket, object, false, false, true) } readQuorum, _, err := objectQuorumFromMeta(ctx, metaArr, errs, er.defaultParityCount) if err != nil { if errors.Is(err, errErasureReadQuorum) && !strings.HasPrefix(bucket, minioMetaBucket) { _, derr := er.deleteIfDangling(context.Background(), bucket, object, metaArr, errs, nil, opts) if derr != nil { err = derr } } return ObjectInfo{}, toObjectErr(err, bucket, object) } // List all online disks. onlineDisks, modTime, etag := listOnlineDisks(disks, metaArr, errs, readQuorum) // Pick latest valid metadata. fi, err := pickValidFileInfo(ctx, metaArr, modTime, etag, readQuorum) if err != nil { return ObjectInfo{}, toObjectErr(err, bucket, object) } if fi.Deleted { if opts.VersionID == "" { return ObjectInfo{}, toObjectErr(errFileNotFound, bucket, object) } return ObjectInfo{}, toObjectErr(errMethodNotAllowed, bucket, object) } filterOnlineDisksInplace(fi, metaArr, onlineDisks) fi.Metadata[xhttp.AmzObjectTagging] = tags fi.ReplicationState = opts.PutReplicationState() for k, v := range opts.UserDefined { fi.Metadata[k] = v } if err = er.updateObjectMeta(ctx, bucket, object, fi, onlineDisks); err != nil { return ObjectInfo{}, toObjectErr(err, bucket, object) } return fi.ToObjectInfo(bucket, object, opts.Versioned || opts.VersionSuspended), nil } func (er erasureObjects) updateObjectMetaWithOpts(ctx context.Context, bucket, object string, fi FileInfo, onlineDisks []StorageAPI, opts UpdateMetadataOpts) error { if len(fi.Metadata) == 0 { return nil } g := errgroup.WithNErrs(len(onlineDisks)) // Start writing `xl.meta` to all disks in parallel. for index := range onlineDisks { index := index g.Go(func() error { if onlineDisks[index] == nil { return errDiskNotFound } return onlineDisks[index].UpdateMetadata(ctx, bucket, object, fi, opts) }, index) } // Wait for all the routines. mErrs := g.Wait() return reduceWriteQuorumErrs(ctx, mErrs, objectOpIgnoredErrs, fi.WriteQuorum(er.defaultWQuorum())) } // updateObjectMeta will update the metadata of a file. func (er erasureObjects) updateObjectMeta(ctx context.Context, bucket, object string, fi FileInfo, onlineDisks []StorageAPI) error { return er.updateObjectMetaWithOpts(ctx, bucket, object, fi, onlineDisks, UpdateMetadataOpts{}) } // DeleteObjectTags - delete object tags from an existing object func (er erasureObjects) DeleteObjectTags(ctx context.Context, bucket, object string, opts ObjectOptions) (ObjectInfo, error) { return er.PutObjectTags(ctx, bucket, object, "", opts) } // GetObjectTags - get object tags from an existing object func (er erasureObjects) GetObjectTags(ctx context.Context, bucket, object string, opts ObjectOptions) (*tags.Tags, error) { // GetObjectInfo will return tag value as well oi, err := er.GetObjectInfo(ctx, bucket, object, opts) if err != nil { return nil, err } return tags.ParseObjectTags(oi.UserTags) } // TransitionObject - transition object content to target tier. func (er erasureObjects) TransitionObject(ctx context.Context, bucket, object string, opts ObjectOptions) error { tgtClient, err := globalTierConfigMgr.getDriver(opts.Transition.Tier) if err != nil { return err } // Acquire write lock before starting to transition the object. lk := er.NewNSLock(bucket, object) lkctx, err := lk.GetLock(ctx, globalDeleteOperationTimeout) if err != nil { return err } ctx = lkctx.Context() defer lk.Unlock(lkctx) fi, metaArr, onlineDisks, err := er.getObjectFileInfo(ctx, bucket, object, opts, true) if err != nil { return toObjectErr(err, bucket, object) } if fi.Deleted { if opts.VersionID == "" { return toObjectErr(errFileNotFound, bucket, object) } // Make sure to return object info to provide extra information. return toObjectErr(errMethodNotAllowed, bucket, object) } // verify that the object queued for transition is identical to that on disk. if !opts.MTime.Equal(fi.ModTime) || !strings.EqualFold(opts.Transition.ETag, extractETag(fi.Metadata)) { return toObjectErr(errFileNotFound, bucket, object) } // if object already transitioned, return if fi.TransitionStatus == lifecycle.TransitionComplete { return nil } if fi.XLV1 { if _, err = er.HealObject(ctx, bucket, object, "", madmin.HealOpts{NoLock: true}); err != nil { return err } // Fetch FileInfo again. HealObject migrates object the latest // format. Among other things this changes fi.DataDir and // possibly fi.Data (if data is inlined). fi, metaArr, onlineDisks, err = er.getObjectFileInfo(ctx, bucket, object, opts, true) if err != nil { return toObjectErr(err, bucket, object) } } traceFn := globalLifecycleSys.trace(fi.ToObjectInfo(bucket, object, opts.Versioned || opts.VersionSuspended)) destObj, err := genTransitionObjName(bucket) if err != nil { return err } pr, pw := xioutil.WaitPipe() go func() { err := er.getObjectWithFileInfo(ctx, bucket, object, 0, fi.Size, pw, fi, metaArr, onlineDisks) pw.CloseWithError(err) }() var rv remoteVersionID rv, err = tgtClient.Put(ctx, destObj, pr, fi.Size) pr.CloseWithError(err) if err != nil { return err } fi.TransitionStatus = lifecycle.TransitionComplete fi.TransitionedObjName = destObj fi.TransitionTier = opts.Transition.Tier fi.TransitionVersionID = string(rv) eventName := event.ObjectTransitionComplete storageDisks := er.getDisks() if err = er.deleteObjectVersion(ctx, bucket, object, fi, false); err != nil { eventName = event.ObjectTransitionFailed } for _, disk := range storageDisks { if disk != nil && disk.IsOnline() { continue } er.addPartial(bucket, object, opts.VersionID) break } objInfo := fi.ToObjectInfo(bucket, object, opts.Versioned || opts.VersionSuspended) sendEvent(eventArgs{ EventName: eventName, BucketName: bucket, Object: objInfo, UserAgent: "Internal: [ILM-Transition]", Host: globalLocalNodeName, }) tags := opts.LifecycleAuditEvent.Tags() auditLogLifecycle(ctx, objInfo, ILMTransition, tags, traceFn) return err } // RestoreTransitionedObject - restore transitioned object content locally on this cluster. // This is similar to PostObjectRestore from AWS GLACIER // storage class. When PostObjectRestore API is called, a temporary copy of the object // is restored locally to the bucket on source cluster until the restore expiry date. // The copy that was transitioned continues to reside in the transitioned tier. func (er erasureObjects) RestoreTransitionedObject(ctx context.Context, bucket, object string, opts ObjectOptions) error { return er.restoreTransitionedObject(ctx, bucket, object, opts) } // update restore status header in the metadata func (er erasureObjects) updateRestoreMetadata(ctx context.Context, bucket, object string, objInfo ObjectInfo, opts ObjectOptions) error { oi := objInfo.Clone() oi.metadataOnly = true // Perform only metadata updates. // allow retry in the case of failure to restore delete(oi.UserDefined, xhttp.AmzRestore) if _, err := er.CopyObject(ctx, bucket, object, bucket, object, oi, ObjectOptions{ VersionID: oi.VersionID, }, ObjectOptions{ VersionID: oi.VersionID, }); err != nil { logger.LogIf(ctx, fmt.Errorf("Unable to update transition restore metadata for %s/%s(%s): %s", bucket, object, oi.VersionID, err)) return err } return nil } // restoreTransitionedObject for multipart object chunks the file stream from remote tier into the same number of parts // as in the xl.meta for this version and rehydrates the part.n into the fi.DataDir for this version as in the xl.meta func (er erasureObjects) restoreTransitionedObject(ctx context.Context, bucket string, object string, opts ObjectOptions) error { setRestoreHeaderFn := func(oi ObjectInfo, rerr error) error { if rerr == nil { return nil // nothing to do; restore object was successful } er.updateRestoreMetadata(ctx, bucket, object, oi, opts) return rerr } var oi ObjectInfo // get the file info on disk for transitioned object actualfi, _, _, err := er.getObjectFileInfo(ctx, bucket, object, opts, false) if err != nil { return setRestoreHeaderFn(oi, toObjectErr(err, bucket, object)) } oi = actualfi.ToObjectInfo(bucket, object, opts.Versioned || opts.VersionSuspended) ropts := putRestoreOpts(bucket, object, opts.Transition.RestoreRequest, oi) if len(oi.Parts) == 1 { var rs *HTTPRangeSpec gr, err := getTransitionedObjectReader(ctx, bucket, object, rs, http.Header{}, oi, opts) if err != nil { return setRestoreHeaderFn(oi, toObjectErr(err, bucket, object)) } defer gr.Close() hashReader, err := hash.NewReader(ctx, gr, gr.ObjInfo.Size, "", "", gr.ObjInfo.Size) if err != nil { return setRestoreHeaderFn(oi, toObjectErr(err, bucket, object)) } pReader := NewPutObjReader(hashReader) _, err = er.PutObject(ctx, bucket, object, pReader, ropts) return setRestoreHeaderFn(oi, toObjectErr(err, bucket, object)) } res, err := er.NewMultipartUpload(ctx, bucket, object, ropts) if err != nil { return setRestoreHeaderFn(oi, err) } var uploadedParts []CompletePart var rs *HTTPRangeSpec // get reader from the warm backend - note that even in the case of encrypted objects, this stream is still encrypted. gr, err := getTransitionedObjectReader(ctx, bucket, object, rs, http.Header{}, oi, opts) if err != nil { return setRestoreHeaderFn(oi, err) } defer gr.Close() // rehydrate the parts back on disk as per the original xl.meta prior to transition for _, partInfo := range oi.Parts { hr, err := hash.NewReader(ctx, io.LimitReader(gr, partInfo.Size), partInfo.Size, "", "", partInfo.Size) if err != nil { return setRestoreHeaderFn(oi, err) } pInfo, err := er.PutObjectPart(ctx, bucket, object, res.UploadID, partInfo.Number, NewPutObjReader(hr), ObjectOptions{}) if err != nil { return setRestoreHeaderFn(oi, err) } if pInfo.Size != partInfo.Size { return setRestoreHeaderFn(oi, InvalidObjectState{Bucket: bucket, Object: object}) } uploadedParts = append(uploadedParts, CompletePart{ PartNumber: pInfo.PartNumber, ETag: pInfo.ETag, }) } _, err = er.CompleteMultipartUpload(ctx, bucket, object, res.UploadID, uploadedParts, ObjectOptions{ MTime: oi.ModTime, }) return setRestoreHeaderFn(oi, err) } // DecomTieredObject - moves tiered object to another pool during decommissioning. func (er erasureObjects) DecomTieredObject(ctx context.Context, bucket, object string, fi FileInfo, opts ObjectOptions) error { if opts.UserDefined == nil { opts.UserDefined = make(map[string]string) } // overlay Erasure info for this set of disks storageDisks := er.getDisks() // Get parity and data drive count based on storage class metadata parityDrives := globalStorageClass.GetParityForSC(opts.UserDefined[xhttp.AmzStorageClass]) if parityDrives < 0 { parityDrives = er.defaultParityCount } dataDrives := len(storageDisks) - parityDrives // we now know the number of blocks this object needs for data and parity. // writeQuorum is dataBlocks + 1 writeQuorum := dataDrives if dataDrives == parityDrives { writeQuorum++ } // Initialize parts metadata partsMetadata := make([]FileInfo, len(storageDisks)) fi2 := newFileInfo(pathJoin(bucket, object), dataDrives, parityDrives) fi.Erasure = fi2.Erasure // Initialize erasure metadata. for index := range partsMetadata { partsMetadata[index] = fi partsMetadata[index].Erasure.Index = index + 1 } // Order disks according to erasure distribution var onlineDisks []StorageAPI onlineDisks, partsMetadata = shuffleDisksAndPartsMetadata(storageDisks, partsMetadata, fi) if _, err := writeUniqueFileInfo(ctx, onlineDisks, "", bucket, object, partsMetadata, writeQuorum); err != nil { return toObjectErr(err, bucket, object) } return nil }