/* * MinIO Cloud Storage, (C) 2019,2020 MinIO, Inc. * * Licensed under the Apache License, Version 2.0 (the "License"); * you may not use this file except in compliance with the License. * You may obtain a copy of the License at * * http://www.apache.org/licenses/LICENSE-2.0 * * Unless required by applicable law or agreed to in writing, software * distributed under the License is distributed on an "AS IS" BASIS, * WITHOUT WARRANTIES OR CONDITIONS OF ANY KIND, either express or implied. * See the License for the specific language governing permissions and * limitations under the License. */ package cmd import ( "context" "errors" "fmt" "io" "math/rand" "net/http" "strconv" "strings" "sync" "time" "github.com/minio/minio-go/v7/pkg/set" "github.com/minio/minio-go/v7/pkg/tags" "github.com/minio/minio/cmd/config/storageclass" xhttp "github.com/minio/minio/cmd/http" "github.com/minio/minio/cmd/logger" "github.com/minio/minio/pkg/dsync" "github.com/minio/minio/pkg/madmin" "github.com/minio/minio/pkg/sync/errgroup" ) type erasureZones struct { GatewayUnsupported zones []*erasureSets // Shut down async operations shutdown context.CancelFunc } func (z *erasureZones) SingleZone() bool { return len(z.zones) == 1 } // Initialize new zone of erasure sets. func newErasureZones(ctx context.Context, endpointZones EndpointZones) (ObjectLayer, error) { var ( deploymentID string err error formats = make([]*formatErasureV3, len(endpointZones)) storageDisks = make([][]StorageAPI, len(endpointZones)) z = &erasureZones{zones: make([]*erasureSets, len(endpointZones))} ) var localDrives []string local := endpointZones.FirstLocal() for i, ep := range endpointZones { for _, endpoint := range ep.Endpoints { if endpoint.IsLocal { localDrives = append(localDrives, endpoint.Path) } } storageDisks[i], formats[i], err = waitForFormatErasure(local, ep.Endpoints, i+1, ep.SetCount, ep.DrivesPerSet, deploymentID) if err != nil { return nil, err } if deploymentID == "" { deploymentID = formats[i].ID } z.zones[i], err = newErasureSets(ctx, ep.Endpoints, storageDisks[i], formats[i]) if err != nil { return nil, err } } ctx, z.shutdown = context.WithCancel(ctx) go intDataUpdateTracker.start(ctx, localDrives...) return z, nil } func (z *erasureZones) NewNSLock(ctx context.Context, bucket string, objects ...string) RWLocker { return z.zones[0].NewNSLock(ctx, bucket, objects...) } func (z *erasureZones) GetAllLockers() []dsync.NetLocker { return z.zones[0].GetAllLockers() } func (z *erasureZones) SetDriveCount() int { return z.zones[0].SetDriveCount() } type zonesAvailableSpace []zoneAvailableSpace type zoneAvailableSpace struct { Index int Available uint64 } // TotalAvailable - total available space func (p zonesAvailableSpace) TotalAvailable() uint64 { total := uint64(0) for _, z := range p { total += z.Available } return total } // getAvailableZoneIdx will return an index that can hold size bytes. // -1 is returned if no zones have available space for the size given. func (z *erasureZones) getAvailableZoneIdx(ctx context.Context, size int64) int { zones := z.getZonesAvailableSpace(ctx, size) total := zones.TotalAvailable() if total == 0 { return -1 } // choose when we reach this many choose := rand.Uint64() % total atTotal := uint64(0) for _, zone := range zones { atTotal += zone.Available if atTotal > choose && zone.Available > 0 { return zone.Index } } // Should not happen, but print values just in case. logger.LogIf(ctx, fmt.Errorf("reached end of zones (total: %v, atTotal: %v, choose: %v)", total, atTotal, choose)) return -1 } // getZonesAvailableSpace will return the available space of each zone after storing the content. // If there is not enough space the zone will return 0 bytes available. // Negative sizes are seen as 0 bytes. func (z *erasureZones) getZonesAvailableSpace(ctx context.Context, size int64) zonesAvailableSpace { if size < 0 { size = 0 } var zones = make(zonesAvailableSpace, len(z.zones)) storageInfos := make([]StorageInfo, len(z.zones)) g := errgroup.WithNErrs(len(z.zones)) for index := range z.zones { index := index g.Go(func() error { storageInfos[index] = z.zones[index].StorageUsageInfo(ctx) return nil }, index) } // Wait for the go routines. g.Wait() for i, zinfo := range storageInfos { var available uint64 var total uint64 for _, disk := range zinfo.Disks { total += disk.TotalSpace available += disk.TotalSpace - disk.UsedSpace } // Make sure we can fit "size" on to the disk without getting above the diskFillFraction if available < uint64(size) { available = 0 } if available > 0 { // How much will be left after adding the file. available -= -uint64(size) // wantLeft is how much space there at least must be left. wantLeft := uint64(float64(total) * (1.0 - diskFillFraction)) if available <= wantLeft { available = 0 } } zones[i] = zoneAvailableSpace{ Index: i, Available: available, } } return zones } // getZoneIdx returns the found previous object and its corresponding zone idx, // if none are found falls back to most available space zone. func (z *erasureZones) getZoneIdx(ctx context.Context, bucket, object string, opts ObjectOptions, size int64) (idx int, err error) { if z.SingleZone() { return 0, nil } for i, zone := range z.zones { objInfo, err := zone.GetObjectInfo(ctx, bucket, object, opts) switch err.(type) { case ObjectNotFound: // VersionId was not specified but found delete marker or no versions exist. case MethodNotAllowed: // VersionId was specified but found delete marker default: if err != nil { // any other un-handled errors return right here. return -1, err } } // delete marker not specified means no versions // exist continue to next zone. if !objInfo.DeleteMarker && err != nil { continue } // Success case and when DeleteMarker is true return. return i, nil } // We multiply the size by 2 to account for erasure coding. idx = z.getAvailableZoneIdx(ctx, size*2) if idx < 0 { return -1, toObjectErr(errDiskFull) } return idx, nil } func (z *erasureZones) Shutdown(ctx context.Context) error { defer z.shutdown() if z.SingleZone() { return z.zones[0].Shutdown(ctx) } g := errgroup.WithNErrs(len(z.zones)) for index := range z.zones { index := index g.Go(func() error { return z.zones[index].Shutdown(ctx) }, index) } for _, err := range g.Wait() { if err != nil { logger.LogIf(ctx, err) } // let's the rest shutdown } return nil } func (z *erasureZones) StorageInfo(ctx context.Context, local bool) (StorageInfo, []error) { if z.SingleZone() { return z.zones[0].StorageInfo(ctx, local) } var storageInfo StorageInfo storageInfos := make([]StorageInfo, len(z.zones)) storageInfosErrs := make([][]error, len(z.zones)) g := errgroup.WithNErrs(len(z.zones)) for index := range z.zones { index := index g.Go(func() error { storageInfos[index], storageInfosErrs[index] = z.zones[index].StorageInfo(ctx, local) return nil }, index) } // Wait for the go routines. g.Wait() for _, lstorageInfo := range storageInfos { storageInfo.Disks = append(storageInfo.Disks, lstorageInfo.Disks...) storageInfo.Backend.OnlineDisks = storageInfo.Backend.OnlineDisks.Merge(lstorageInfo.Backend.OnlineDisks) storageInfo.Backend.OfflineDisks = storageInfo.Backend.OfflineDisks.Merge(lstorageInfo.Backend.OfflineDisks) } storageInfo.Backend.Type = storageInfos[0].Backend.Type storageInfo.Backend.StandardSCData = storageInfos[0].Backend.StandardSCData storageInfo.Backend.StandardSCParity = storageInfos[0].Backend.StandardSCParity storageInfo.Backend.RRSCData = storageInfos[0].Backend.RRSCData storageInfo.Backend.RRSCParity = storageInfos[0].Backend.RRSCParity var errs []error for i := range z.zones { errs = append(errs, storageInfosErrs[i]...) } return storageInfo, errs } func (z *erasureZones) CrawlAndGetDataUsage(ctx context.Context, bf *bloomFilter, updates chan<- DataUsageInfo) error { ctx, cancel := context.WithCancel(ctx) defer cancel() var wg sync.WaitGroup var mu sync.Mutex var results []dataUsageCache var firstErr error var knownBuckets = make(map[string]struct{}) // used to deduplicate buckets. var allBuckets []BucketInfo // Collect for each set in zones. for _, z := range z.zones { buckets, err := z.ListBuckets(ctx) if err != nil { return err } // Add new buckets. for _, b := range buckets { if _, ok := knownBuckets[b.Name]; ok { continue } allBuckets = append(allBuckets, b) knownBuckets[b.Name] = struct{}{} } for _, erObj := range z.sets { wg.Add(1) results = append(results, dataUsageCache{}) go func(i int, erObj *erasureObjects) { updates := make(chan dataUsageCache, 1) defer close(updates) // Start update collector. go func() { defer wg.Done() for info := range updates { mu.Lock() results[i] = info mu.Unlock() } }() // Start crawler. Blocks until done. err := erObj.crawlAndGetDataUsage(ctx, buckets, bf, updates) if err != nil { logger.LogIf(ctx, err) mu.Lock() if firstErr == nil { firstErr = err } // Cancel remaining... cancel() mu.Unlock() return } }(len(results)-1, erObj) } } updateCloser := make(chan chan struct{}) go func() { updateTicker := time.NewTicker(30 * time.Second) defer updateTicker.Stop() var lastUpdate time.Time // We need to merge since we will get the same buckets from each zone. // Therefore to get the exact bucket sizes we must merge before we can convert. var allMerged dataUsageCache update := func() { mu.Lock() defer mu.Unlock() allMerged = dataUsageCache{Info: dataUsageCacheInfo{Name: dataUsageRoot}} for _, info := range results { if info.Info.LastUpdate.IsZero() { // Not filled yet. return } allMerged.merge(info) } if allMerged.root() != nil && allMerged.Info.LastUpdate.After(lastUpdate) { updates <- allMerged.dui(allMerged.Info.Name, allBuckets) lastUpdate = allMerged.Info.LastUpdate } } for { select { case <-ctx.Done(): return case v := <-updateCloser: update() // Enforce quotas when all is done. if firstErr == nil { for _, b := range allBuckets { enforceFIFOQuotaBucket(ctx, z, b.Name, allMerged.bucketUsageInfo(b.Name)) } } close(v) return case <-updateTicker.C: update() } } }() wg.Wait() ch := make(chan struct{}) select { case updateCloser <- ch: <-ch case <-ctx.Done(): if firstErr == nil { firstErr = ctx.Err() } } return firstErr } // MakeBucketWithLocation - creates a new bucket across all zones simultaneously // even if one of the sets fail to create buckets, we proceed all the successful // operations. func (z *erasureZones) MakeBucketWithLocation(ctx context.Context, bucket string, opts BucketOptions) error { if z.SingleZone() { if err := z.zones[0].MakeBucketWithLocation(ctx, bucket, opts); err != nil { return err } // If it doesn't exist we get a new, so ignore errors meta := newBucketMetadata(bucket) if opts.LockEnabled { meta.VersioningConfigXML = enabledBucketVersioningConfig meta.ObjectLockConfigXML = enabledBucketObjectLockConfig } if err := meta.Save(ctx, z); err != nil { return toObjectErr(err, bucket) } globalBucketMetadataSys.Set(bucket, meta) return nil } g := errgroup.WithNErrs(len(z.zones)) // Create buckets in parallel across all sets. for index := range z.zones { index := index g.Go(func() error { return z.zones[index].MakeBucketWithLocation(ctx, bucket, opts) }, index) } errs := g.Wait() // Return the first encountered error for _, err := range errs { if err != nil { return err } } // If it doesn't exist we get a new, so ignore errors meta := newBucketMetadata(bucket) if opts.LockEnabled { meta.VersioningConfigXML = enabledBucketVersioningConfig meta.ObjectLockConfigXML = enabledBucketObjectLockConfig } if err := meta.Save(ctx, z); err != nil { return toObjectErr(err, bucket) } globalBucketMetadataSys.Set(bucket, meta) // Success. return nil } func (z *erasureZones) GetObjectNInfo(ctx context.Context, bucket, object string, rs *HTTPRangeSpec, h http.Header, lockType LockType, opts ObjectOptions) (gr *GetObjectReader, err error) { if err = checkGetObjArgs(ctx, bucket, object); err != nil { return nil, err } object = encodeDirObject(object) for _, zone := range z.zones { gr, err = zone.GetObjectNInfo(ctx, bucket, object, rs, h, lockType, opts) if err != nil { if isErrObjectNotFound(err) || isErrVersionNotFound(err) { continue } return gr, err } return gr, nil } if opts.VersionID != "" { return gr, VersionNotFound{Bucket: bucket, Object: object, VersionID: opts.VersionID} } return gr, ObjectNotFound{Bucket: bucket, Object: object} } func (z *erasureZones) GetObject(ctx context.Context, bucket, object string, startOffset int64, length int64, writer io.Writer, etag string, opts ObjectOptions) error { if err := checkGetObjArgs(ctx, bucket, object); err != nil { return err } object = encodeDirObject(object) for _, zone := range z.zones { if err := zone.GetObject(ctx, bucket, object, startOffset, length, writer, etag, opts); err != nil { if isErrObjectNotFound(err) || isErrVersionNotFound(err) { continue } return err } return nil } if opts.VersionID != "" { return VersionNotFound{Bucket: bucket, Object: object, VersionID: opts.VersionID} } return ObjectNotFound{Bucket: bucket, Object: object} } func (z *erasureZones) GetObjectInfo(ctx context.Context, bucket, object string, opts ObjectOptions) (objInfo ObjectInfo, err error) { if err = checkGetObjArgs(ctx, bucket, object); err != nil { return objInfo, err } object = encodeDirObject(object) for _, zone := range z.zones { objInfo, err = zone.GetObjectInfo(ctx, bucket, object, opts) if err != nil { if isErrObjectNotFound(err) || isErrVersionNotFound(err) { continue } return objInfo, err } return objInfo, nil } object = decodeDirObject(object) if opts.VersionID != "" { return objInfo, VersionNotFound{Bucket: bucket, Object: object, VersionID: opts.VersionID} } return objInfo, ObjectNotFound{Bucket: bucket, Object: object} } // PutObject - writes an object to least used erasure zone. func (z *erasureZones) PutObject(ctx context.Context, bucket string, object string, data *PutObjReader, opts ObjectOptions) (ObjectInfo, error) { // Validate put object input args. if err := checkPutObjectArgs(ctx, bucket, object, z); err != nil { return ObjectInfo{}, err } object = encodeDirObject(object) if z.SingleZone() { return z.zones[0].PutObject(ctx, bucket, object, data, opts) } idx, err := z.getZoneIdx(ctx, bucket, object, opts, data.Size()) if err != nil { return ObjectInfo{}, err } // Overwrite the object at the right zone return z.zones[idx].PutObject(ctx, bucket, object, data, opts) } func (z *erasureZones) DeleteObject(ctx context.Context, bucket string, object string, opts ObjectOptions) (objInfo ObjectInfo, err error) { if err = checkDelObjArgs(ctx, bucket, object); err != nil { return objInfo, err } object = encodeDirObject(object) if z.SingleZone() { return z.zones[0].DeleteObject(ctx, bucket, object, opts) } for _, zone := range z.zones { objInfo, err = zone.DeleteObject(ctx, bucket, object, opts) if err == nil { return objInfo, nil } if err != nil && !isErrObjectNotFound(err) && !isErrVersionNotFound(err) { break } } return objInfo, err } func (z *erasureZones) DeleteObjects(ctx context.Context, bucket string, objects []ObjectToDelete, opts ObjectOptions) ([]DeletedObject, []error) { derrs := make([]error, len(objects)) dobjects := make([]DeletedObject, len(objects)) objSets := set.NewStringSet() for i := range derrs { objects[i].ObjectName = encodeDirObject(objects[i].ObjectName) derrs[i] = checkDelObjArgs(ctx, bucket, objects[i].ObjectName) objSets.Add(objects[i].ObjectName) } // Acquire a bulk write lock across 'objects' multiDeleteLock := z.NewNSLock(ctx, bucket, objSets.ToSlice()...) if err := multiDeleteLock.GetLock(globalOperationTimeout); err != nil { for i := range derrs { derrs[i] = err } return nil, derrs } defer multiDeleteLock.Unlock() for _, zone := range z.zones { deletedObjects, errs := zone.DeleteObjects(ctx, bucket, objects, opts) for i, derr := range errs { if derrs[i] == nil { if derr != nil && !isErrObjectNotFound(derr) && !isErrVersionNotFound(derr) { derrs[i] = derr } } if derrs[i] == nil { dobjects[i] = deletedObjects[i] } } } return dobjects, derrs } func (z *erasureZones) CopyObject(ctx context.Context, srcBucket, srcObject, dstBucket, dstObject string, srcInfo ObjectInfo, srcOpts, dstOpts ObjectOptions) (objInfo ObjectInfo, err error) { srcObject = encodeDirObject(srcObject) dstObject = encodeDirObject(dstObject) cpSrcDstSame := isStringEqual(pathJoin(srcBucket, srcObject), pathJoin(dstBucket, dstObject)) zoneIdx, err := z.getZoneIdx(ctx, dstBucket, dstObject, dstOpts, srcInfo.Size) if err != nil { return objInfo, err } if cpSrcDstSame && srcInfo.metadataOnly { // Version ID is set for the destination and source == destination version ID. if dstOpts.VersionID != "" && srcOpts.VersionID == dstOpts.VersionID { return z.zones[zoneIdx].CopyObject(ctx, srcBucket, srcObject, dstBucket, dstObject, srcInfo, srcOpts, dstOpts) } // Destination is not versioned and source version ID is empty // perform an in-place update. if !dstOpts.Versioned && srcOpts.VersionID == "" { return z.zones[zoneIdx].CopyObject(ctx, srcBucket, srcObject, dstBucket, dstObject, srcInfo, srcOpts, dstOpts) } // Destination is versioned, source is not destination version, // as a special case look for if the source object is not legacy // from older format, for older format we will rewrite them as // newer using PutObject() - this is an optimization to save space if dstOpts.Versioned && srcOpts.VersionID != dstOpts.VersionID && !srcInfo.Legacy { // CopyObject optimization where we don't create an entire copy // of the content, instead we add a reference. srcInfo.versionOnly = true return z.zones[zoneIdx].CopyObject(ctx, srcBucket, srcObject, dstBucket, dstObject, srcInfo, srcOpts, dstOpts) } } putOpts := ObjectOptions{ ServerSideEncryption: dstOpts.ServerSideEncryption, UserDefined: srcInfo.UserDefined, Versioned: dstOpts.Versioned, VersionID: dstOpts.VersionID, } return z.zones[zoneIdx].PutObject(ctx, dstBucket, dstObject, srcInfo.PutObjReader, putOpts) } func (z *erasureZones) ListObjectsV2(ctx context.Context, bucket, prefix, continuationToken, delimiter string, maxKeys int, fetchOwner bool, startAfter string) (ListObjectsV2Info, error) { marker := continuationToken if marker == "" { marker = startAfter } loi, err := z.ListObjects(ctx, bucket, prefix, marker, delimiter, maxKeys) if err != nil { return ListObjectsV2Info{}, err } listObjectsV2Info := ListObjectsV2Info{ IsTruncated: loi.IsTruncated, ContinuationToken: continuationToken, NextContinuationToken: loi.NextMarker, Objects: loi.Objects, Prefixes: loi.Prefixes, } return listObjectsV2Info, err } func (z *erasureZones) listObjectsNonSlash(ctx context.Context, bucket, prefix, marker, delimiter string, maxKeys int) (loi ListObjectsInfo, err error) { zonesEntryChs := make([][]FileInfoCh, 0, len(z.zones)) zonesListTolerancePerSet := make([]int, 0, len(z.zones)) endWalkCh := make(chan struct{}) defer close(endWalkCh) for _, zone := range z.zones { zonesEntryChs = append(zonesEntryChs, zone.startMergeWalksN(ctx, bucket, prefix, "", true, endWalkCh, zone.listTolerancePerSet, false)) if zone.listTolerancePerSet == -1 { zonesListTolerancePerSet = append(zonesListTolerancePerSet, zone.setDriveCount/2) } else { zonesListTolerancePerSet = append(zonesListTolerancePerSet, zone.listTolerancePerSet-2) } } var objInfos []ObjectInfo var eof bool var prevPrefix string zonesEntriesInfos := make([][]FileInfo, 0, len(zonesEntryChs)) zonesEntriesValid := make([][]bool, 0, len(zonesEntryChs)) for _, entryChs := range zonesEntryChs { zonesEntriesInfos = append(zonesEntriesInfos, make([]FileInfo, len(entryChs))) zonesEntriesValid = append(zonesEntriesValid, make([]bool, len(entryChs))) } for { if len(objInfos) == maxKeys { break } result, quorumCount, zoneIndex, ok := lexicallySortedEntryZone(zonesEntryChs, zonesEntriesInfos, zonesEntriesValid) if !ok { eof = true break } if quorumCount < zonesListTolerancePerSet[zoneIndex] { // Skip entries which are not found on upto expected tolerance continue } var objInfo ObjectInfo index := strings.Index(strings.TrimPrefix(result.Name, prefix), delimiter) if index == -1 { objInfo = ObjectInfo{ IsDir: false, Bucket: bucket, Name: result.Name, ModTime: result.ModTime, Size: result.Size, ContentType: result.Metadata["content-type"], ContentEncoding: result.Metadata["content-encoding"], } // Extract etag from metadata. objInfo.ETag = extractETag(result.Metadata) // All the parts per object. objInfo.Parts = result.Parts // 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-*. objInfo.UserDefined = cleanMetadata(result.Metadata) // Update storage class if sc, ok := result.Metadata[xhttp.AmzStorageClass]; ok { objInfo.StorageClass = sc } else { objInfo.StorageClass = globalMinioDefaultStorageClass } } else { index = len(prefix) + index + len(delimiter) currPrefix := result.Name[:index] if currPrefix == prevPrefix { continue } prevPrefix = currPrefix objInfo = ObjectInfo{ Bucket: bucket, Name: currPrefix, IsDir: true, } } if objInfo.Name <= marker { continue } objInfos = append(objInfos, objInfo) } result := ListObjectsInfo{} for _, objInfo := range objInfos { if objInfo.IsDir { result.Prefixes = append(result.Prefixes, objInfo.Name) continue } result.Objects = append(result.Objects, objInfo) } if !eof { result.IsTruncated = true if len(objInfos) > 0 { result.NextMarker = objInfos[len(objInfos)-1].Name } } return result, nil } func (z *erasureZones) listObjectsSplunk(ctx context.Context, bucket, prefix, marker string, maxKeys int) (loi ListObjectsInfo, err error) { if strings.Contains(prefix, guidSplunk) { logger.LogIf(ctx, NotImplemented{}) return loi, NotImplemented{} } recursive := true zonesEntryChs := make([][]FileInfoCh, 0, len(z.zones)) zonesEndWalkCh := make([]chan struct{}, 0, len(z.zones)) zonesListTolerancePerSet := make([]int, 0, len(z.zones)) for _, zone := range z.zones { entryChs, endWalkCh := zone.poolSplunk.Release(listParams{bucket, recursive, marker, prefix}) if entryChs == nil { endWalkCh = make(chan struct{}) entryChs = zone.startMergeWalksN(ctx, bucket, prefix, marker, recursive, endWalkCh, zone.listTolerancePerSet, true) } zonesEntryChs = append(zonesEntryChs, entryChs) zonesEndWalkCh = append(zonesEndWalkCh, endWalkCh) if zone.listTolerancePerSet == -1 { zonesListTolerancePerSet = append(zonesListTolerancePerSet, zone.setDriveCount/2) } else { zonesListTolerancePerSet = append(zonesListTolerancePerSet, zone.listTolerancePerSet-2) } } entries := mergeZonesEntriesCh(zonesEntryChs, maxKeys, zonesListTolerancePerSet) if len(entries.Files) == 0 { return loi, nil } loi.IsTruncated = entries.IsTruncated if loi.IsTruncated { loi.NextMarker = entries.Files[len(entries.Files)-1].Name } for _, entry := range entries.Files { objInfo := entry.ToObjectInfo(bucket, entry.Name) splits := strings.Split(objInfo.Name, guidSplunk) if len(splits) == 0 { loi.Objects = append(loi.Objects, objInfo) continue } loi.Prefixes = append(loi.Prefixes, splits[0]+guidSplunk) } if loi.IsTruncated { for i, zone := range z.zones { zone.poolSplunk.Set(listParams{bucket, recursive, loi.NextMarker, prefix}, zonesEntryChs[i], zonesEndWalkCh[i]) } } return loi, nil } func (z *erasureZones) listObjects(ctx context.Context, bucket, prefix, marker, delimiter string, maxKeys int) (ListObjectsInfo, error) { loi := ListObjectsInfo{} if err := checkListObjsArgs(ctx, bucket, prefix, marker, z); err != nil { return loi, err } // Marker is set validate pre-condition. if marker != "" { // Marker not common with prefix is not implemented. Send an empty response if !HasPrefix(marker, prefix) { return loi, nil } } // With max keys of zero we have reached eof, return right here. if maxKeys == 0 { return loi, nil } // For delimiter and prefix as '/' we do not list anything at all // since according to s3 spec we stop at the 'delimiter' // along // with the prefix. On a flat namespace with 'prefix' // as '/' we don't have any entries, since all the keys are // of form 'keyName/...' if delimiter == SlashSeparator && prefix == SlashSeparator { return loi, nil } // Over flowing count - reset to maxObjectList. if maxKeys < 0 || maxKeys > maxObjectList { maxKeys = maxObjectList } if delimiter != SlashSeparator && delimiter != "" { if delimiter == guidSplunk { return z.listObjectsSplunk(ctx, bucket, prefix, marker, maxKeys) } return z.listObjectsNonSlash(ctx, bucket, prefix, marker, delimiter, maxKeys) } // Default is recursive, if delimiter is set then list non recursive. recursive := true if delimiter == SlashSeparator { recursive = false } zonesEntryChs := make([][]FileInfoCh, 0, len(z.zones)) zonesEndWalkCh := make([]chan struct{}, 0, len(z.zones)) zonesListTolerancePerSet := make([]int, 0, len(z.zones)) for _, zone := range z.zones { entryChs, endWalkCh := zone.pool.Release(listParams{bucket, recursive, marker, prefix}) if entryChs == nil { endWalkCh = make(chan struct{}) entryChs = zone.startMergeWalksN(ctx, bucket, prefix, marker, recursive, endWalkCh, zone.listTolerancePerSet, false) } zonesEntryChs = append(zonesEntryChs, entryChs) zonesEndWalkCh = append(zonesEndWalkCh, endWalkCh) if zone.listTolerancePerSet == -1 { zonesListTolerancePerSet = append(zonesListTolerancePerSet, zone.setDriveCount/2) } else { zonesListTolerancePerSet = append(zonesListTolerancePerSet, zone.listTolerancePerSet-2) } } entries := mergeZonesEntriesCh(zonesEntryChs, maxKeys, zonesListTolerancePerSet) if len(entries.Files) == 0 { return loi, nil } loi.IsTruncated = entries.IsTruncated if loi.IsTruncated { loi.NextMarker = entries.Files[len(entries.Files)-1].Name } for _, entry := range entries.Files { objInfo := entry.ToObjectInfo(entry.Volume, entry.Name) if HasSuffix(objInfo.Name, SlashSeparator) && !recursive { loi.Prefixes = append(loi.Prefixes, objInfo.Name) continue } loi.Objects = append(loi.Objects, objInfo) } if loi.IsTruncated { for i, zone := range z.zones { zone.pool.Set(listParams{bucket, recursive, loi.NextMarker, prefix}, zonesEntryChs[i], zonesEndWalkCh[i]) } } return loi, nil } // Calculate least entry across zones and across multiple FileInfo // channels, returns the least common entry and the total number of times // we found this entry. Additionally also returns a boolean // to indicate if the caller needs to call this function // again to list the next entry. It is callers responsibility // if the caller wishes to list N entries to call lexicallySortedEntry // N times until this boolean is 'false'. func lexicallySortedEntryZone(zoneEntryChs [][]FileInfoCh, zoneEntries [][]FileInfo, zoneEntriesValid [][]bool) (FileInfo, int, int, bool) { for i, entryChs := range zoneEntryChs { for j := range entryChs { zoneEntries[i][j], zoneEntriesValid[i][j] = entryChs[j].Pop() } } var isTruncated = false for _, entriesValid := range zoneEntriesValid { for _, valid := range entriesValid { if !valid { continue } isTruncated = true break } if isTruncated { break } } var lentry FileInfo var found bool var zoneIndex = -1 // TODO: following loop can be merged with above // loop, explore this possibility. for i, entriesValid := range zoneEntriesValid { for j, valid := range entriesValid { if !valid { continue } if !found { lentry = zoneEntries[i][j] found = true zoneIndex = i continue } str1 := zoneEntries[i][j].Name str2 := lentry.Name if HasSuffix(str1, globalDirSuffix) { str1 = strings.TrimSuffix(str1, globalDirSuffix) + slashSeparator } if HasSuffix(str2, globalDirSuffix) { str2 = strings.TrimSuffix(str2, globalDirSuffix) + slashSeparator } if str1 < str2 { lentry = zoneEntries[i][j] zoneIndex = i } } } // We haven't been able to find any least entry, // this would mean that we don't have valid entry. if !found { return lentry, 0, zoneIndex, isTruncated } lexicallySortedEntryCount := 0 for i, entriesValid := range zoneEntriesValid { for j, valid := range entriesValid { if !valid { continue } // Entries are duplicated across disks, // we should simply skip such entries. if lentry.Name == zoneEntries[i][j].Name && lentry.ModTime.Equal(zoneEntries[i][j].ModTime) { lexicallySortedEntryCount++ continue } // Push all entries which are lexically higher // and will be returned later in Pop() zoneEntryChs[i][j].Push(zoneEntries[i][j]) } } if HasSuffix(lentry.Name, globalDirSuffix) { lentry.Name = strings.TrimSuffix(lentry.Name, globalDirSuffix) + slashSeparator } return lentry, lexicallySortedEntryCount, zoneIndex, isTruncated } // Calculate least entry across zones and across multiple FileInfoVersions // channels, returns the least common entry and the total number of times // we found this entry. Additionally also returns a boolean // to indicate if the caller needs to call this function // again to list the next entry. It is callers responsibility // if the caller wishes to list N entries to call lexicallySortedEntry // N times until this boolean is 'false'. func lexicallySortedEntryZoneVersions(zoneEntryChs [][]FileInfoVersionsCh, zoneEntries [][]FileInfoVersions, zoneEntriesValid [][]bool) (FileInfoVersions, int, int, bool) { for i, entryChs := range zoneEntryChs { for j := range entryChs { zoneEntries[i][j], zoneEntriesValid[i][j] = entryChs[j].Pop() } } var isTruncated = false for _, entriesValid := range zoneEntriesValid { for _, valid := range entriesValid { if !valid { continue } isTruncated = true break } if isTruncated { break } } var lentry FileInfoVersions var found bool var zoneIndex = -1 for i, entriesValid := range zoneEntriesValid { for j, valid := range entriesValid { if !valid { continue } if !found { lentry = zoneEntries[i][j] found = true zoneIndex = i continue } str1 := zoneEntries[i][j].Name str2 := lentry.Name if HasSuffix(str1, globalDirSuffix) { str1 = strings.TrimSuffix(str1, globalDirSuffix) + slashSeparator } if HasSuffix(str2, globalDirSuffix) { str2 = strings.TrimSuffix(str2, globalDirSuffix) + slashSeparator } if str1 < str2 { lentry = zoneEntries[i][j] zoneIndex = i } } } // We haven't been able to find any least entry, // this would mean that we don't have valid entry. if !found { return lentry, 0, zoneIndex, isTruncated } lexicallySortedEntryCount := 0 for i, entriesValid := range zoneEntriesValid { for j, valid := range entriesValid { if !valid { continue } // Entries are duplicated across disks, // we should simply skip such entries. if lentry.Name == zoneEntries[i][j].Name && lentry.LatestModTime.Equal(zoneEntries[i][j].LatestModTime) { lexicallySortedEntryCount++ continue } // Push all entries which are lexically higher // and will be returned later in Pop() zoneEntryChs[i][j].Push(zoneEntries[i][j]) } } if HasSuffix(lentry.Name, globalDirSuffix) { lentry.Name = strings.TrimSuffix(lentry.Name, globalDirSuffix) + slashSeparator } return lentry, lexicallySortedEntryCount, zoneIndex, isTruncated } // mergeZonesEntriesVersionsCh - merges FileInfoVersions channel to entries upto maxKeys. func mergeZonesEntriesVersionsCh(zonesEntryChs [][]FileInfoVersionsCh, maxKeys int, zonesListTolerancePerSet []int) (entries FilesInfoVersions) { var i = 0 zonesEntriesInfos := make([][]FileInfoVersions, 0, len(zonesEntryChs)) zonesEntriesValid := make([][]bool, 0, len(zonesEntryChs)) for _, entryChs := range zonesEntryChs { zonesEntriesInfos = append(zonesEntriesInfos, make([]FileInfoVersions, len(entryChs))) zonesEntriesValid = append(zonesEntriesValid, make([]bool, len(entryChs))) } for { fi, quorumCount, zoneIndex, ok := lexicallySortedEntryZoneVersions(zonesEntryChs, zonesEntriesInfos, zonesEntriesValid) if !ok { // We have reached EOF across all entryChs, break the loop. break } if quorumCount < zonesListTolerancePerSet[zoneIndex] { // Skip entries which are not found upto the expected tolerance continue } entries.FilesVersions = append(entries.FilesVersions, fi) i++ if i == maxKeys { entries.IsTruncated = isTruncatedZonesVersions(zonesEntryChs, zonesEntriesInfos, zonesEntriesValid) break } } return entries } // mergeZonesEntriesCh - merges FileInfo channel to entries upto maxKeys. func mergeZonesEntriesCh(zonesEntryChs [][]FileInfoCh, maxKeys int, zonesListTolerancePerSet []int) (entries FilesInfo) { var i = 0 zonesEntriesInfos := make([][]FileInfo, 0, len(zonesEntryChs)) zonesEntriesValid := make([][]bool, 0, len(zonesEntryChs)) for _, entryChs := range zonesEntryChs { zonesEntriesInfos = append(zonesEntriesInfos, make([]FileInfo, len(entryChs))) zonesEntriesValid = append(zonesEntriesValid, make([]bool, len(entryChs))) } var prevEntry string for { fi, quorumCount, zoneIndex, ok := lexicallySortedEntryZone(zonesEntryChs, zonesEntriesInfos, zonesEntriesValid) if !ok { // We have reached EOF across all entryChs, break the loop. break } if quorumCount < zonesListTolerancePerSet[zoneIndex] { // Skip entries which are not found upto configured tolerance. continue } if HasSuffix(fi.Name, slashSeparator) && fi.Name == prevEntry { continue } entries.Files = append(entries.Files, fi) i++ if i == maxKeys { entries.IsTruncated = isTruncatedZones(zonesEntryChs, zonesEntriesInfos, zonesEntriesValid) break } prevEntry = fi.Name } return entries } func isTruncatedZones(zoneEntryChs [][]FileInfoCh, zoneEntries [][]FileInfo, zoneEntriesValid [][]bool) bool { for i, entryChs := range zoneEntryChs { for j := range entryChs { zoneEntries[i][j], zoneEntriesValid[i][j] = entryChs[j].Pop() } } var isTruncated = false for _, entriesValid := range zoneEntriesValid { for _, valid := range entriesValid { if valid { isTruncated = true break } } if isTruncated { break } } for i, entryChs := range zoneEntryChs { for j := range entryChs { if zoneEntriesValid[i][j] { zoneEntryChs[i][j].Push(zoneEntries[i][j]) } } } return isTruncated } func isTruncatedZonesVersions(zoneEntryChs [][]FileInfoVersionsCh, zoneEntries [][]FileInfoVersions, zoneEntriesValid [][]bool) bool { for i, entryChs := range zoneEntryChs { for j := range entryChs { zoneEntries[i][j], zoneEntriesValid[i][j] = entryChs[j].Pop() } } var isTruncated = false for _, entriesValid := range zoneEntriesValid { for _, valid := range entriesValid { if !valid { continue } isTruncated = true break } if isTruncated { break } } for i, entryChs := range zoneEntryChs { for j := range entryChs { if zoneEntriesValid[i][j] { zoneEntryChs[i][j].Push(zoneEntries[i][j]) } } } return isTruncated } func (z *erasureZones) listObjectVersions(ctx context.Context, bucket, prefix, marker, versionMarker, delimiter string, maxKeys int) (ListObjectVersionsInfo, error) { loi := ListObjectVersionsInfo{} if err := checkListObjsArgs(ctx, bucket, prefix, marker, z); err != nil { return loi, err } // Marker is set validate pre-condition. if marker != "" { // Marker not common with prefix is not implemented. Send an empty response if !HasPrefix(marker, prefix) { return loi, nil } } if marker == "" && versionMarker != "" { return loi, NotImplemented{} } // With max keys of zero we have reached eof, return right here. if maxKeys == 0 { return loi, nil } // For delimiter and prefix as '/' we do not list anything at all // since according to s3 spec we stop at the 'delimiter' // along // with the prefix. On a flat namespace with 'prefix' // as '/' we don't have any entries, since all the keys are // of form 'keyName/...' if delimiter == SlashSeparator && prefix == SlashSeparator { return loi, nil } // Over flowing count - reset to maxObjectList. if maxKeys < 0 || maxKeys > maxObjectList { maxKeys = maxObjectList } if delimiter != SlashSeparator && delimiter != "" { return loi, NotImplemented{} } // Default is recursive, if delimiter is set then list non recursive. recursive := true if delimiter == SlashSeparator { recursive = false } zonesEntryChs := make([][]FileInfoVersionsCh, 0, len(z.zones)) zonesEndWalkCh := make([]chan struct{}, 0, len(z.zones)) zonesListTolerancePerSet := make([]int, 0, len(z.zones)) for _, zone := range z.zones { entryChs, endWalkCh := zone.poolVersions.Release(listParams{bucket, recursive, marker, prefix}) if entryChs == nil { endWalkCh = make(chan struct{}) entryChs = zone.startMergeWalksVersionsN(ctx, bucket, prefix, marker, recursive, endWalkCh, zone.listTolerancePerSet) } zonesEntryChs = append(zonesEntryChs, entryChs) zonesEndWalkCh = append(zonesEndWalkCh, endWalkCh) if zone.listTolerancePerSet == -1 { zonesListTolerancePerSet = append(zonesListTolerancePerSet, zone.setDriveCount/2) } else { zonesListTolerancePerSet = append(zonesListTolerancePerSet, zone.listTolerancePerSet-2) } } entries := mergeZonesEntriesVersionsCh(zonesEntryChs, maxKeys, zonesListTolerancePerSet) if len(entries.FilesVersions) == 0 { return loi, nil } loi.IsTruncated = entries.IsTruncated if loi.IsTruncated { loi.NextMarker = entries.FilesVersions[len(entries.FilesVersions)-1].Name } for _, entry := range entries.FilesVersions { for _, version := range entry.Versions { objInfo := version.ToObjectInfo(bucket, entry.Name) if HasSuffix(objInfo.Name, SlashSeparator) && !recursive { loi.Prefixes = append(loi.Prefixes, objInfo.Name) continue } loi.Objects = append(loi.Objects, objInfo) } } if loi.IsTruncated { for i, zone := range z.zones { zone.poolVersions.Set(listParams{bucket, recursive, loi.NextMarker, prefix}, zonesEntryChs[i], zonesEndWalkCh[i]) } } return loi, nil } func (z *erasureZones) ListObjectVersions(ctx context.Context, bucket, prefix, marker, versionMarker, delimiter string, maxKeys int) (ListObjectVersionsInfo, error) { return z.listObjectVersions(ctx, bucket, prefix, marker, versionMarker, delimiter, maxKeys) } func (z *erasureZones) ListObjects(ctx context.Context, bucket, prefix, marker, delimiter string, maxKeys int) (ListObjectsInfo, error) { return z.listObjects(ctx, bucket, prefix, marker, delimiter, maxKeys) } func (z *erasureZones) ListMultipartUploads(ctx context.Context, bucket, prefix, keyMarker, uploadIDMarker, delimiter string, maxUploads int) (ListMultipartsInfo, error) { if err := checkListMultipartArgs(ctx, bucket, prefix, keyMarker, uploadIDMarker, delimiter, z); err != nil { return ListMultipartsInfo{}, err } if z.SingleZone() { return z.zones[0].ListMultipartUploads(ctx, bucket, prefix, keyMarker, uploadIDMarker, delimiter, maxUploads) } var zoneResult = ListMultipartsInfo{} zoneResult.MaxUploads = maxUploads zoneResult.KeyMarker = keyMarker zoneResult.Prefix = prefix zoneResult.Delimiter = delimiter for _, zone := range z.zones { result, err := zone.ListMultipartUploads(ctx, bucket, prefix, keyMarker, uploadIDMarker, delimiter, maxUploads) if err != nil { return result, err } zoneResult.Uploads = append(zoneResult.Uploads, result.Uploads...) } return zoneResult, nil } // Initiate a new multipart upload on a hashedSet based on object name. func (z *erasureZones) NewMultipartUpload(ctx context.Context, bucket, object string, opts ObjectOptions) (string, error) { if err := checkNewMultipartArgs(ctx, bucket, object, z); err != nil { return "", err } if z.SingleZone() { return z.zones[0].NewMultipartUpload(ctx, bucket, object, opts) } // We don't know the exact size, so we ask for at least 1GiB file. idx, err := z.getZoneIdx(ctx, bucket, object, opts, 1<<30) if err != nil { return "", err } return z.zones[idx].NewMultipartUpload(ctx, bucket, object, opts) } // Copies a part of an object from source hashedSet to destination hashedSet. func (z *erasureZones) CopyObjectPart(ctx context.Context, srcBucket, srcObject, destBucket, destObject string, uploadID string, partID int, startOffset int64, length int64, srcInfo ObjectInfo, srcOpts, dstOpts ObjectOptions) (PartInfo, error) { if err := checkNewMultipartArgs(ctx, srcBucket, srcObject, z); err != nil { return PartInfo{}, err } return z.PutObjectPart(ctx, destBucket, destObject, uploadID, partID, NewPutObjReader(srcInfo.Reader, nil, nil), dstOpts) } // PutObjectPart - writes part of an object to hashedSet based on the object name. func (z *erasureZones) PutObjectPart(ctx context.Context, bucket, object, uploadID string, partID int, data *PutObjReader, opts ObjectOptions) (PartInfo, error) { if err := checkPutObjectPartArgs(ctx, bucket, object, z); err != nil { return PartInfo{}, err } if z.SingleZone() { return z.zones[0].PutObjectPart(ctx, bucket, object, uploadID, partID, data, opts) } for _, zone := range z.zones { _, err := zone.GetMultipartInfo(ctx, bucket, object, uploadID, opts) if err == nil { return zone.PutObjectPart(ctx, bucket, object, uploadID, partID, data, opts) } switch err.(type) { case InvalidUploadID: // Look for information on the next zone continue } // Any other unhandled errors such as quorum return. return PartInfo{}, err } return PartInfo{}, InvalidUploadID{ Bucket: bucket, Object: object, UploadID: uploadID, } } func (z *erasureZones) GetMultipartInfo(ctx context.Context, bucket, object, uploadID string, opts ObjectOptions) (MultipartInfo, error) { if err := checkListPartsArgs(ctx, bucket, object, z); err != nil { return MultipartInfo{}, err } if z.SingleZone() { return z.zones[0].GetMultipartInfo(ctx, bucket, object, uploadID, opts) } for _, zone := range z.zones { mi, err := zone.GetMultipartInfo(ctx, bucket, object, uploadID, opts) if err == nil { return mi, nil } switch err.(type) { case InvalidUploadID: // upload id not found, continue to the next zone. continue } // any other unhandled error return right here. return MultipartInfo{}, err } return MultipartInfo{}, InvalidUploadID{ Bucket: bucket, Object: object, UploadID: uploadID, } } // ListObjectParts - lists all uploaded parts to an object in hashedSet. func (z *erasureZones) ListObjectParts(ctx context.Context, bucket, object, uploadID string, partNumberMarker int, maxParts int, opts ObjectOptions) (ListPartsInfo, error) { if err := checkListPartsArgs(ctx, bucket, object, z); err != nil { return ListPartsInfo{}, err } if z.SingleZone() { return z.zones[0].ListObjectParts(ctx, bucket, object, uploadID, partNumberMarker, maxParts, opts) } for _, zone := range z.zones { _, err := zone.GetMultipartInfo(ctx, bucket, object, uploadID, opts) if err == nil { return zone.ListObjectParts(ctx, bucket, object, uploadID, partNumberMarker, maxParts, opts) } switch err.(type) { case InvalidUploadID: continue } return ListPartsInfo{}, err } return ListPartsInfo{}, InvalidUploadID{ Bucket: bucket, Object: object, UploadID: uploadID, } } // Aborts an in-progress multipart operation on hashedSet based on the object name. func (z *erasureZones) AbortMultipartUpload(ctx context.Context, bucket, object, uploadID string, opts ObjectOptions) error { if err := checkAbortMultipartArgs(ctx, bucket, object, z); err != nil { return err } if z.SingleZone() { return z.zones[0].AbortMultipartUpload(ctx, bucket, object, uploadID, opts) } for _, zone := range z.zones { _, err := zone.GetMultipartInfo(ctx, bucket, object, uploadID, opts) if err == nil { return zone.AbortMultipartUpload(ctx, bucket, object, uploadID, opts) } switch err.(type) { case InvalidUploadID: // upload id not found move to next zone continue } return err } return InvalidUploadID{ Bucket: bucket, Object: object, UploadID: uploadID, } } // CompleteMultipartUpload - completes a pending multipart transaction, on hashedSet based on object name. func (z *erasureZones) CompleteMultipartUpload(ctx context.Context, bucket, object, uploadID string, uploadedParts []CompletePart, opts ObjectOptions) (objInfo ObjectInfo, err error) { if err = checkCompleteMultipartArgs(ctx, bucket, object, z); err != nil { return objInfo, err } if z.SingleZone() { return z.zones[0].CompleteMultipartUpload(ctx, bucket, object, uploadID, uploadedParts, opts) } // Purge any existing object. for _, zone := range z.zones { zone.DeleteObject(ctx, bucket, object, opts) } for _, zone := range z.zones { result, err := zone.ListMultipartUploads(ctx, bucket, object, "", "", "", maxUploadsList) if err != nil { return objInfo, err } if result.Lookup(uploadID) { return zone.CompleteMultipartUpload(ctx, bucket, object, uploadID, uploadedParts, opts) } } return objInfo, InvalidUploadID{ Bucket: bucket, Object: object, UploadID: uploadID, } } // GetBucketInfo - returns bucket info from one of the erasure coded zones. func (z *erasureZones) GetBucketInfo(ctx context.Context, bucket string) (bucketInfo BucketInfo, err error) { if z.SingleZone() { bucketInfo, err = z.zones[0].GetBucketInfo(ctx, bucket) if err != nil { return bucketInfo, err } meta, err := globalBucketMetadataSys.Get(bucket) if err == nil { bucketInfo.Created = meta.Created } return bucketInfo, nil } for _, zone := range z.zones { bucketInfo, err = zone.GetBucketInfo(ctx, bucket) if err != nil { if isErrBucketNotFound(err) { continue } return bucketInfo, err } meta, err := globalBucketMetadataSys.Get(bucket) if err == nil { bucketInfo.Created = meta.Created } return bucketInfo, nil } return bucketInfo, BucketNotFound{ Bucket: bucket, } } // IsNotificationSupported returns whether bucket notification is applicable for this layer. func (z *erasureZones) IsNotificationSupported() bool { return true } // IsListenSupported returns whether listen bucket notification is applicable for this layer. func (z *erasureZones) IsListenSupported() bool { return true } // IsEncryptionSupported returns whether server side encryption is implemented for this layer. func (z *erasureZones) IsEncryptionSupported() bool { return true } // IsCompressionSupported returns whether compression is applicable for this layer. func (z *erasureZones) IsCompressionSupported() bool { return true } func (z *erasureZones) IsTaggingSupported() bool { return true } // DeleteBucket - deletes a bucket on all zones simultaneously, // even if one of the zones fail to delete buckets, we proceed to // undo a successful operation. func (z *erasureZones) DeleteBucket(ctx context.Context, bucket string, forceDelete bool) error { if z.SingleZone() { return z.zones[0].DeleteBucket(ctx, bucket, forceDelete) } g := errgroup.WithNErrs(len(z.zones)) // Delete buckets in parallel across all zones. for index := range z.zones { index := index g.Go(func() error { return z.zones[index].DeleteBucket(ctx, bucket, forceDelete) }, index) } errs := g.Wait() // For any write quorum failure, we undo all the delete // buckets operation by creating all the buckets again. for _, err := range errs { if err != nil { if _, ok := err.(InsufficientWriteQuorum); ok { undoDeleteBucketZones(ctx, bucket, z.zones, errs) } return err } } // Success. return nil } // This function is used to undo a successful DeleteBucket operation. func undoDeleteBucketZones(ctx context.Context, bucket string, zones []*erasureSets, errs []error) { g := errgroup.WithNErrs(len(zones)) // Undo previous delete bucket on all underlying zones. for index := range zones { index := index g.Go(func() error { if errs[index] == nil { return zones[index].MakeBucketWithLocation(ctx, bucket, BucketOptions{}) } return nil }, index) } g.Wait() } // List all buckets from one of the zones, we are not doing merge // sort here just for simplification. As per design it is assumed // that all buckets are present on all zones. func (z *erasureZones) ListBuckets(ctx context.Context) (buckets []BucketInfo, err error) { if z.SingleZone() { buckets, err = z.zones[0].ListBuckets(ctx) } else { for _, zone := range z.zones { buckets, err = zone.ListBuckets(ctx) if err != nil { logger.LogIf(ctx, err) continue } break } } if err != nil { return nil, err } for i := range buckets { meta, err := globalBucketMetadataSys.Get(buckets[i].Name) if err == nil { buckets[i].Created = meta.Created } } return buckets, nil } func (z *erasureZones) ReloadFormat(ctx context.Context, dryRun bool) error { // No locks needed since reload happens in HealFormat under // write lock across all nodes. for _, zone := range z.zones { if err := zone.ReloadFormat(ctx, dryRun); err != nil { return err } } return nil } func (z *erasureZones) HealFormat(ctx context.Context, dryRun bool) (madmin.HealResultItem, error) { // Acquire lock on format.json formatLock := z.NewNSLock(ctx, minioMetaBucket, formatConfigFile) if err := formatLock.GetLock(globalOperationTimeout); err != nil { return madmin.HealResultItem{}, err } defer formatLock.Unlock() var r = madmin.HealResultItem{ Type: madmin.HealItemMetadata, Detail: "disk-format", } var countNoHeal int for _, zone := range z.zones { result, err := zone.HealFormat(ctx, dryRun) if err != nil && !errors.Is(err, errNoHealRequired) { logger.LogIf(ctx, err) continue } // Count errNoHealRequired across all zones, // to return appropriate error to the caller if errors.Is(err, errNoHealRequired) { countNoHeal++ } r.DiskCount += result.DiskCount r.SetCount += result.SetCount r.Before.Drives = append(r.Before.Drives, result.Before.Drives...) r.After.Drives = append(r.After.Drives, result.After.Drives...) } // Healing succeeded notify the peers to reload format and re-initialize disks. // We will not notify peers if healing is not required. for _, nerr := range globalNotificationSys.ReloadFormat(dryRun) { if nerr.Err != nil { logger.GetReqInfo(ctx).SetTags("peerAddress", nerr.Host.String()) logger.LogIf(ctx, nerr.Err) } } // No heal returned by all zones, return errNoHealRequired if countNoHeal == len(z.zones) { return r, errNoHealRequired } return r, nil } func (z *erasureZones) HealBucket(ctx context.Context, bucket string, dryRun, remove bool) (madmin.HealResultItem, error) { var r = madmin.HealResultItem{ Type: madmin.HealItemBucket, Bucket: bucket, } for _, zone := range z.zones { result, err := zone.HealBucket(ctx, bucket, dryRun, remove) if err != nil { switch err.(type) { case BucketNotFound: continue } return result, err } r.DiskCount += result.DiskCount r.SetCount += result.SetCount r.Before.Drives = append(r.Before.Drives, result.Before.Drives...) r.After.Drives = append(r.After.Drives, result.After.Drives...) } return r, nil } // Walk a bucket, optionally prefix recursively, until we have returned // all the content to objectInfo channel, it is callers responsibility // to allocate a receive channel for ObjectInfo, upon any unhandled // error walker returns error. Optionally if context.Done() is received // then Walk() stops the walker. func (z *erasureZones) Walk(ctx context.Context, bucket, prefix string, results chan<- ObjectInfo, opts ObjectOptions) error { if err := checkListObjsArgs(ctx, bucket, prefix, "", z); err != nil { // Upon error close the channel. close(results) return err } zonesListTolerancePerSet := make([]int, 0, len(z.zones)) for _, zone := range z.zones { if zone.listTolerancePerSet == -1 { zonesListTolerancePerSet = append(zonesListTolerancePerSet, zone.setDriveCount/2) } else { zonesListTolerancePerSet = append(zonesListTolerancePerSet, zone.listTolerancePerSet-2) } } if opts.WalkVersions { var zonesEntryChs [][]FileInfoVersionsCh for _, zone := range z.zones { zonesEntryChs = append(zonesEntryChs, zone.startMergeWalksVersions(ctx, bucket, prefix, "", true, ctx.Done())) } var zonesEntriesInfos [][]FileInfoVersions var zonesEntriesValid [][]bool for _, entryChs := range zonesEntryChs { zonesEntriesInfos = append(zonesEntriesInfos, make([]FileInfoVersions, len(entryChs))) zonesEntriesValid = append(zonesEntriesValid, make([]bool, len(entryChs))) } go func() { defer close(results) for { entry, quorumCount, zoneIdx, ok := lexicallySortedEntryZoneVersions(zonesEntryChs, zonesEntriesInfos, zonesEntriesValid) if !ok { // We have reached EOF across all entryChs, break the loop. return } if quorumCount >= zonesListTolerancePerSet[zoneIdx] { for _, version := range entry.Versions { results <- version.ToObjectInfo(bucket, version.Name) } } } }() return nil } zonesEntryChs := make([][]FileInfoCh, 0, len(z.zones)) for _, zone := range z.zones { zonesEntryChs = append(zonesEntryChs, zone.startMergeWalks(ctx, bucket, prefix, "", true, ctx.Done())) } zonesEntriesInfos := make([][]FileInfo, 0, len(zonesEntryChs)) zonesEntriesValid := make([][]bool, 0, len(zonesEntryChs)) for _, entryChs := range zonesEntryChs { zonesEntriesInfos = append(zonesEntriesInfos, make([]FileInfo, len(entryChs))) zonesEntriesValid = append(zonesEntriesValid, make([]bool, len(entryChs))) } go func() { defer close(results) for { entry, quorumCount, zoneIdx, ok := lexicallySortedEntryZone(zonesEntryChs, zonesEntriesInfos, zonesEntriesValid) if !ok { // We have reached EOF across all entryChs, break the loop. return } if quorumCount >= zonesListTolerancePerSet[zoneIdx] { results <- entry.ToObjectInfo(bucket, entry.Name) } } }() return nil } // HealObjectFn closure function heals the object. type HealObjectFn func(bucket, object, versionID string) error func (z *erasureZones) HealObjects(ctx context.Context, bucket, prefix string, opts madmin.HealOpts, healObject HealObjectFn) error { endWalkCh := make(chan struct{}) defer close(endWalkCh) zonesEntryChs := make([][]FileInfoVersionsCh, 0, len(z.zones)) zoneDrivesPerSet := make([]int, 0, len(z.zones)) for _, zone := range z.zones { zonesEntryChs = append(zonesEntryChs, zone.startMergeWalksVersions(ctx, bucket, prefix, "", true, endWalkCh)) zoneDrivesPerSet = append(zoneDrivesPerSet, zone.setDriveCount) } zonesEntriesInfos := make([][]FileInfoVersions, 0, len(zonesEntryChs)) zonesEntriesValid := make([][]bool, 0, len(zonesEntryChs)) for _, entryChs := range zonesEntryChs { zonesEntriesInfos = append(zonesEntriesInfos, make([]FileInfoVersions, len(entryChs))) zonesEntriesValid = append(zonesEntriesValid, make([]bool, len(entryChs))) } // If listing did not return any entries upon first attempt, we // return `ObjectNotFound`, to indicate the caller for any // actions they may want to take as if `prefix` is missing. err := toObjectErr(errFileNotFound, bucket, prefix) for { entry, quorumCount, zoneIndex, ok := lexicallySortedEntryZoneVersions(zonesEntryChs, zonesEntriesInfos, zonesEntriesValid) if !ok { break } // Indicate that first attempt was a success and subsequent loop // knows that its not our first attempt at 'prefix' err = nil if zoneIndex >= len(zoneDrivesPerSet) || zoneIndex < 0 { return fmt.Errorf("invalid zone index returned: %d", zoneIndex) } if quorumCount == zoneDrivesPerSet[zoneIndex] && opts.ScanMode == madmin.HealNormalScan { // Skip good entries. continue } for _, version := range entry.Versions { // Wait and proceed if there are active requests waitForLowHTTPReq(int32(zoneDrivesPerSet[zoneIndex]), time.Second) if err := healObject(bucket, version.Name, version.VersionID); err != nil { return toObjectErr(err, bucket, version.Name) } } } return err } func (z *erasureZones) HealObject(ctx context.Context, bucket, object, versionID string, opts madmin.HealOpts) (madmin.HealResultItem, error) { object = encodeDirObject(object) lk := z.NewNSLock(ctx, bucket, object) if bucket == minioMetaBucket { // For .minio.sys bucket heals we should hold write locks. if err := lk.GetLock(globalOperationTimeout); err != nil { return madmin.HealResultItem{}, err } defer lk.Unlock() } else { // Lock the object before healing. Use read lock since healing // will only regenerate parts & xl.meta of outdated disks. if err := lk.GetRLock(globalOperationTimeout); err != nil { return madmin.HealResultItem{}, err } defer lk.RUnlock() } if z.SingleZone() { return z.zones[0].HealObject(ctx, bucket, object, versionID, opts) } for _, zone := range z.zones { result, err := zone.HealObject(ctx, bucket, object, versionID, opts) if err != nil { if isErrObjectNotFound(err) || isErrVersionNotFound(err) { continue } return result, err } return result, nil } return madmin.HealResultItem{}, ObjectNotFound{ Bucket: bucket, Object: object, } } func (z *erasureZones) ListBucketsHeal(ctx context.Context) ([]BucketInfo, error) { var healBuckets []BucketInfo for _, zone := range z.zones { bucketsInfo, err := zone.ListBucketsHeal(ctx) if err != nil { continue } healBuckets = append(healBuckets, bucketsInfo...) } for i := range healBuckets { meta, err := globalBucketMetadataSys.Get(healBuckets[i].Name) if err == nil { healBuckets[i].Created = meta.Created } } return healBuckets, nil } // GetMetrics - no op func (z *erasureZones) GetMetrics(ctx context.Context) (*Metrics, error) { logger.LogIf(ctx, NotImplemented{}) return &Metrics{}, NotImplemented{} } func (z *erasureZones) getZoneAndSet(id string) (int, int, error) { for zoneIdx := range z.zones { format := z.zones[zoneIdx].format for setIdx, set := range format.Erasure.Sets { for _, diskID := range set { if diskID == id { return zoneIdx, setIdx, nil } } } } return 0, 0, fmt.Errorf("DiskID(%s) %w", id, errDiskNotFound) } // HealthOptions takes input options to return sepcific information type HealthOptions struct { Maintenance bool } // HealthResult returns the current state of the system, also // additionally with any specific heuristic information which // was queried type HealthResult struct { Healthy bool HealingDrives int ZoneID, SetID int WriteQuorum int } // Health - returns current status of the object layer health, // provides if write access exists across sets, additionally // can be used to query scenarios if health may be lost // if this node is taken down by an external orchestrator. func (z *erasureZones) Health(ctx context.Context, opts HealthOptions) HealthResult { erasureSetUpCount := make([][]int, len(z.zones)) for i := range z.zones { erasureSetUpCount[i] = make([]int, len(z.zones[i].sets)) } diskIDs := globalNotificationSys.GetLocalDiskIDs(ctx) if !opts.Maintenance { diskIDs = append(diskIDs, getLocalDiskIDs(z)) } for _, localDiskIDs := range diskIDs { for _, id := range localDiskIDs { zoneIdx, setIdx, err := z.getZoneAndSet(id) if err != nil { logger.LogIf(ctx, err) continue } erasureSetUpCount[zoneIdx][setIdx]++ } } reqInfo := (&logger.ReqInfo{}).AppendTags("maintenance", strconv.FormatBool(opts.Maintenance)) parityDrives := globalStorageClass.GetParityForSC(storageclass.STANDARD) diskCount := z.SetDriveCount() if parityDrives == 0 { parityDrives = getDefaultParityBlocks(diskCount) } dataDrives := diskCount - parityDrives writeQuorum := dataDrives if dataDrives == parityDrives { writeQuorum++ } var aggHealStateResult madmin.BgHealState if opts.Maintenance { // check if local disks are being healed, if they are being healed // we need to tell healthy status as 'false' so that this server // is not taken down for maintenance var err error aggHealStateResult, err = getAggregatedBackgroundHealState(ctx) if err != nil { logger.LogIf(logger.SetReqInfo(ctx, reqInfo), fmt.Errorf("Unable to verify global heal status: %w", err)) return HealthResult{ Healthy: false, } } if len(aggHealStateResult.HealDisks) > 0 { logger.LogIf(logger.SetReqInfo(ctx, reqInfo), fmt.Errorf("Total drives to be healed %d", len(aggHealStateResult.HealDisks))) } } for zoneIdx := range erasureSetUpCount { for setIdx := range erasureSetUpCount[zoneIdx] { if erasureSetUpCount[zoneIdx][setIdx] < writeQuorum { logger.LogIf(logger.SetReqInfo(ctx, reqInfo), fmt.Errorf("Write quorum may be lost on zone: %d, set: %d, expected write quorum: %d", zoneIdx, setIdx, writeQuorum)) return HealthResult{ Healthy: false, HealingDrives: len(aggHealStateResult.HealDisks), ZoneID: zoneIdx, SetID: setIdx, WriteQuorum: writeQuorum, } } } } // when maintenance is not specified we don't have // to look at the healing side of the code. if !opts.Maintenance { return HealthResult{ Healthy: true, WriteQuorum: writeQuorum, } } return HealthResult{ Healthy: len(aggHealStateResult.HealDisks) == 0, HealingDrives: len(aggHealStateResult.HealDisks), WriteQuorum: writeQuorum, } } // PutObjectTags - replace or add tags to an existing object func (z *erasureZones) PutObjectTags(ctx context.Context, bucket, object string, tags string, opts ObjectOptions) error { object = encodeDirObject(object) if z.SingleZone() { return z.zones[0].PutObjectTags(ctx, bucket, object, tags, opts) } for _, zone := range z.zones { err := zone.PutObjectTags(ctx, bucket, object, tags, opts) if err != nil { if isErrObjectNotFound(err) || isErrVersionNotFound(err) { continue } return err } return nil } if opts.VersionID != "" { return VersionNotFound{ Bucket: bucket, Object: object, VersionID: opts.VersionID, } } return ObjectNotFound{ Bucket: bucket, Object: object, } } // DeleteObjectTags - delete object tags from an existing object func (z *erasureZones) DeleteObjectTags(ctx context.Context, bucket, object string, opts ObjectOptions) error { object = encodeDirObject(object) if z.SingleZone() { return z.zones[0].DeleteObjectTags(ctx, bucket, object, opts) } for _, zone := range z.zones { err := zone.DeleteObjectTags(ctx, bucket, object, opts) if err != nil { if isErrObjectNotFound(err) || isErrVersionNotFound(err) { continue } return err } return nil } if opts.VersionID != "" { return VersionNotFound{ Bucket: bucket, Object: object, VersionID: opts.VersionID, } } return ObjectNotFound{ Bucket: bucket, Object: object, } } // GetObjectTags - get object tags from an existing object func (z *erasureZones) GetObjectTags(ctx context.Context, bucket, object string, opts ObjectOptions) (*tags.Tags, error) { object = encodeDirObject(object) if z.SingleZone() { return z.zones[0].GetObjectTags(ctx, bucket, object, opts) } for _, zone := range z.zones { tags, err := zone.GetObjectTags(ctx, bucket, object, opts) if err != nil { if isErrObjectNotFound(err) || isErrVersionNotFound(err) { continue } return tags, err } return tags, nil } if opts.VersionID != "" { return nil, VersionNotFound{ Bucket: bucket, Object: object, VersionID: opts.VersionID, } } return nil, ObjectNotFound{ Bucket: bucket, Object: object, } }