/* * Minio Cloud Storage, (C) 2016, 2017, 2017 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 ( "encoding/json" "errors" "path" "runtime" "sort" "sync" "time" ) const ( // Erasure related constants. erasureAlgorithmKlauspost = "klauspost/reedsolomon/vandermonde" ) // objectPartInfo Info of each part kept in the multipart metadata // file after CompleteMultipartUpload() is called. type objectPartInfo struct { Number int `json:"number"` Name string `json:"name"` ETag string `json:"etag"` Size int64 `json:"size"` } // byObjectPartNumber is a collection satisfying sort.Interface. type byObjectPartNumber []objectPartInfo func (t byObjectPartNumber) Len() int { return len(t) } func (t byObjectPartNumber) Swap(i, j int) { t[i], t[j] = t[j], t[i] } func (t byObjectPartNumber) Less(i, j int) bool { return t[i].Number < t[j].Number } // checkSumInfo - carries checksums of individual scattered parts per disk. type checkSumInfo struct { Name string `json:"name"` Algorithm HashAlgo `json:"algorithm"` Hash string `json:"hash"` } // HashAlgo - represents a supported hashing algorithm for bitrot // verification. type HashAlgo string const ( // HashBlake2b represents the Blake 2b hashing algorithm HashBlake2b HashAlgo = "blake2b" // HashSha256 represents the SHA256 hashing algorithm HashSha256 HashAlgo = "sha256" ) // isValidHashAlgo - function that checks if the hash algorithm is // valid (known and used). func isValidHashAlgo(algo HashAlgo) bool { switch algo { case HashSha256, HashBlake2b: return true default: return false } } // Constant indicates current bit-rot algo used when creating objects. // Depending on the architecture we are choosing a different checksum. var bitRotAlgo = getDefaultBitRotAlgo() // Get the default bit-rot algo depending on the architecture. // Currently this function defaults to "blake2b" as the preferred // checksum algorithm on all architectures except ARM64. On ARM64 // we use sha256 (optimized using sha2 instructions of ARM NEON chip). func getDefaultBitRotAlgo() HashAlgo { switch runtime.GOARCH { case "arm64": // As a special case for ARM64 we use an optimized // version of hash i.e sha256. This is done so that // blake2b is sub-optimal and slower on ARM64. // This would also allows erasure coded writes // on ARM64 servers to be on-par with their // counter-part X86_64 servers. return HashSha256 default: // Default for all other architectures we use blake2b. return HashBlake2b } } // erasureInfo - carries erasure coding related information, block // distribution and checksums. type erasureInfo struct { Algorithm HashAlgo `json:"algorithm"` DataBlocks int `json:"data"` ParityBlocks int `json:"parity"` BlockSize int64 `json:"blockSize"` Index int `json:"index"` Distribution []int `json:"distribution"` Checksum []checkSumInfo `json:"checksum,omitempty"` } // AddCheckSum - add checksum of a part. func (e *erasureInfo) AddCheckSumInfo(ckSumInfo checkSumInfo) { for i, sum := range e.Checksum { if sum.Name == ckSumInfo.Name { e.Checksum[i] = ckSumInfo return } } e.Checksum = append(e.Checksum, ckSumInfo) } // GetCheckSumInfo - get checksum of a part. func (e erasureInfo) GetCheckSumInfo(partName string) (ckSum checkSumInfo) { // Return the checksum. for _, sum := range e.Checksum { if sum.Name == partName { return sum } } return checkSumInfo{Algorithm: bitRotAlgo} } // statInfo - carries stat information of the object. type statInfo struct { Size int64 `json:"size"` // Size of the object `xl.json`. ModTime time.Time `json:"modTime"` // ModTime of the object `xl.json`. } // A xlMetaV1 represents `xl.json` metadata header. type xlMetaV1 struct { Version string `json:"version"` // Version of the current `xl.json`. Format string `json:"format"` // Format of the current `xl.json`. Stat statInfo `json:"stat"` // Stat of the current object `xl.json`. // Erasure coded info for the current object `xl.json`. Erasure erasureInfo `json:"erasure"` // Minio release tag for current object `xl.json`. Minio struct { Release string `json:"release"` } `json:"minio"` // Metadata map for current object `xl.json`. Meta map[string]string `json:"meta,omitempty"` // Captures all the individual object `xl.json`. Parts []objectPartInfo `json:"parts,omitempty"` } // XL metadata constants. const ( // XL meta version. xlMetaVersion = "1.0.1" // XL meta version. xlMetaVersion100 = "1.0.0" // XL meta format string. xlMetaFormat = "xl" // Add new constants here. ) // newXLMetaV1 - initializes new xlMetaV1, adds version, allocates a fresh erasure info. func newXLMetaV1(object string, dataBlocks, parityBlocks int) (xlMeta xlMetaV1) { xlMeta = xlMetaV1{} xlMeta.Version = xlMetaVersion xlMeta.Format = xlMetaFormat xlMeta.Minio.Release = ReleaseTag xlMeta.Erasure = erasureInfo{ Algorithm: erasureAlgorithmKlauspost, DataBlocks: dataBlocks, ParityBlocks: parityBlocks, BlockSize: blockSizeV1, Distribution: hashOrder(object, dataBlocks+parityBlocks), } return xlMeta } // IsValid - tells if the format is sane by validating the version // string and format style. func (m xlMetaV1) IsValid() bool { return isXLMetaValid(m.Version, m.Format) } // Verifies if the backend format metadata is sane by validating // the version string and format style. func isXLMetaValid(version, format string) bool { return ((version == xlMetaVersion || version == xlMetaVersion100) && format == xlMetaFormat) } // Converts metadata to object info. func (m xlMetaV1) ToObjectInfo(bucket, object string) ObjectInfo { objInfo := ObjectInfo{ IsDir: false, Bucket: bucket, Name: object, Size: m.Stat.Size, ModTime: m.Stat.ModTime, ContentType: m.Meta["content-type"], ContentEncoding: m.Meta["content-encoding"], } // Extract etag from metadata. objInfo.ETag = extractETag(m.Meta) // 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 = cleanMetaETag(m.Meta) // Success. return objInfo } // objectPartIndex - returns the index of matching object part number. func objectPartIndex(parts []objectPartInfo, partNumber int) int { for i, part := range parts { if partNumber == part.Number { return i } } return -1 } // AddObjectPart - add a new object part in order. func (m *xlMetaV1) AddObjectPart(partNumber int, partName string, partETag string, partSize int64) { partInfo := objectPartInfo{ Number: partNumber, Name: partName, ETag: partETag, Size: partSize, } // Update part info if it already exists. for i, part := range m.Parts { if partNumber == part.Number { m.Parts[i] = partInfo return } } // Proceed to include new part info. m.Parts = append(m.Parts, partInfo) // Parts in xlMeta should be in sorted order by part number. sort.Sort(byObjectPartNumber(m.Parts)) } // ObjectToPartOffset - translate offset of an object to offset of its individual part. func (m xlMetaV1) ObjectToPartOffset(offset int64) (partIndex int, partOffset int64, err error) { if offset == 0 { // Special case - if offset is 0, then partIndex and partOffset are always 0. return 0, 0, nil } partOffset = offset // Seek until object offset maps to a particular part offset. for i, part := range m.Parts { partIndex = i // Offset is smaller than size we have reached the proper part offset. if partOffset < part.Size { return partIndex, partOffset, nil } // Continue to towards the next part. partOffset -= part.Size } // Offset beyond the size of the object return InvalidRange. return 0, 0, traceError(InvalidRange{}) } // pickValidXLMeta - picks one valid xlMeta content and returns from a // slice of xlmeta content. If no value is found this function panics // and dies. func pickValidXLMeta(metaArr []xlMetaV1, modTime time.Time) (xlMetaV1, error) { // Pick latest valid metadata. for _, meta := range metaArr { if meta.IsValid() && meta.Stat.ModTime.Equal(modTime) { return meta, nil } } return xlMetaV1{}, traceError(errors.New("No valid xl.json present")) } // list of all errors that can be ignored in a metadata operation. var objMetadataOpIgnoredErrs = append(baseIgnoredErrs, errDiskAccessDenied, errVolumeNotFound, errFileNotFound, errFileAccessDenied, errCorruptedFormat) // readXLMetaParts - returns the XL Metadata Parts from xl.json of one of the disks picked at random. func (xl xlObjects) readXLMetaParts(bucket, object string) (xlMetaParts []objectPartInfo, err error) { var ignoredErrs []error for _, disk := range xl.getLoadBalancedDisks() { if disk == nil { ignoredErrs = append(ignoredErrs, errDiskNotFound) continue } xlMetaParts, err = readXLMetaParts(disk, bucket, object) if err == nil { return xlMetaParts, nil } // For any reason disk or bucket is not available continue // and read from other disks. if isErrIgnored(err, objMetadataOpIgnoredErrs...) { ignoredErrs = append(ignoredErrs, err) continue } // Error is not ignored, return right here. return nil, err } // If all errors were ignored, reduce to maximal occurrence // based on the read quorum. return nil, reduceReadQuorumErrs(ignoredErrs, nil, xl.readQuorum) } // readXLMetaStat - return xlMetaV1.Stat and xlMetaV1.Meta from one of the disks picked at random. func (xl xlObjects) readXLMetaStat(bucket, object string) (xlStat statInfo, xlMeta map[string]string, err error) { var ignoredErrs []error for _, disk := range xl.getLoadBalancedDisks() { if disk == nil { ignoredErrs = append(ignoredErrs, errDiskNotFound) continue } // parses only xlMetaV1.Meta and xlMeta.Stat xlStat, xlMeta, err = readXLMetaStat(disk, bucket, object) if err == nil { return xlStat, xlMeta, nil } // For any reason disk or bucket is not available continue // and read from other disks. if isErrIgnored(err, objMetadataOpIgnoredErrs...) { ignoredErrs = append(ignoredErrs, err) continue } // Error is not ignored, return right here. return statInfo{}, nil, err } // If all errors were ignored, reduce to maximal occurrence // based on the read quorum. return statInfo{}, nil, reduceReadQuorumErrs(ignoredErrs, nil, xl.readQuorum) } // deleteXLMetadata - deletes `xl.json` on a single disk. func deleteXLMetdata(disk StorageAPI, bucket, prefix string) error { jsonFile := path.Join(prefix, xlMetaJSONFile) return traceError(disk.DeleteFile(bucket, jsonFile)) } // writeXLMetadata - writes `xl.json` to a single disk. func writeXLMetadata(disk StorageAPI, bucket, prefix string, xlMeta xlMetaV1) error { jsonFile := path.Join(prefix, xlMetaJSONFile) // Marshal json. metadataBytes, err := json.Marshal(&xlMeta) if err != nil { return traceError(err) } // Persist marshalled data. return traceError(disk.AppendFile(bucket, jsonFile, metadataBytes)) } // deleteAllXLMetadata - deletes all partially written `xl.json` depending on errs. func deleteAllXLMetadata(disks []StorageAPI, bucket, prefix string, errs []error) { var wg = &sync.WaitGroup{} // Delete all the `xl.json` left over. for index, disk := range disks { if disk == nil { continue } // Undo rename object in parallel. wg.Add(1) go func(index int, disk StorageAPI) { defer wg.Done() if errs[index] != nil { return } _ = deleteXLMetdata(disk, bucket, prefix) }(index, disk) } wg.Wait() } // Rename `xl.json` content to destination location for each disk in order. func renameXLMetadata(disks []StorageAPI, srcBucket, srcEntry, dstBucket, dstEntry string, quorum int) ([]StorageAPI, error) { isDir := false srcXLJSON := path.Join(srcEntry, xlMetaJSONFile) dstXLJSON := path.Join(dstEntry, xlMetaJSONFile) return rename(disks, srcBucket, srcXLJSON, dstBucket, dstXLJSON, isDir, quorum) } // writeUniqueXLMetadata - writes unique `xl.json` content for each disk in order. func writeUniqueXLMetadata(disks []StorageAPI, bucket, prefix string, xlMetas []xlMetaV1, quorum int) ([]StorageAPI, error) { var wg = &sync.WaitGroup{} var mErrs = make([]error, len(disks)) // Start writing `xl.json` to all disks in parallel. for index, disk := range disks { if disk == nil { mErrs[index] = traceError(errDiskNotFound) continue } wg.Add(1) // Write `xl.json` in a routine. go func(index int, disk StorageAPI) { defer wg.Done() // Pick one xlMeta for a disk at index. xlMetas[index].Erasure.Index = index + 1 // Write unique `xl.json` for a disk at index. err := writeXLMetadata(disk, bucket, prefix, xlMetas[index]) if err != nil { mErrs[index] = err } }(index, disk) } // Wait for all the routines. wg.Wait() err := reduceWriteQuorumErrs(mErrs, objectOpIgnoredErrs, quorum) if errorCause(err) == errXLWriteQuorum { // Delete all `xl.json` successfully renamed. deleteAllXLMetadata(disks, bucket, prefix, mErrs) } return evalDisks(disks, mErrs), err } // writeSameXLMetadata - write `xl.json` on all disks in order. func writeSameXLMetadata(disks []StorageAPI, bucket, prefix string, xlMeta xlMetaV1, writeQuorum, readQuorum int) ([]StorageAPI, error) { var wg = &sync.WaitGroup{} var mErrs = make([]error, len(disks)) // Start writing `xl.json` to all disks in parallel. for index, disk := range disks { if disk == nil { mErrs[index] = traceError(errDiskNotFound) continue } wg.Add(1) // Write `xl.json` in a routine. go func(index int, disk StorageAPI, metadata xlMetaV1) { defer wg.Done() // Save the disk order index. metadata.Erasure.Index = index + 1 // Write xl metadata. err := writeXLMetadata(disk, bucket, prefix, metadata) if err != nil { mErrs[index] = err } }(index, disk, xlMeta) } // Wait for all the routines. wg.Wait() err := reduceWriteQuorumErrs(mErrs, objectOpIgnoredErrs, writeQuorum) if errorCause(err) == errXLWriteQuorum { // Delete all `xl.json` successfully renamed. deleteAllXLMetadata(disks, bucket, prefix, mErrs) } return evalDisks(disks, mErrs), err }