// Copyright (C) 2014 The Syncthing Authors. // // This Source Code Form is subject to the terms of the Mozilla Public // License, v. 2.0. If a copy of the MPL was not distributed with this file, // You can obtain one at https://mozilla.org/MPL/2.0/. package db import ( "bytes" "encoding/binary" "os" "sort" "strings" "sync/atomic" "github.com/syncthing/syncthing/lib/protocol" "github.com/syncthing/syncthing/lib/sync" "github.com/syndtr/goleveldb/leveldb" "github.com/syndtr/goleveldb/leveldb/errors" "github.com/syndtr/goleveldb/leveldb/iterator" "github.com/syndtr/goleveldb/leveldb/opt" "github.com/syndtr/goleveldb/leveldb/storage" "github.com/syndtr/goleveldb/leveldb/util" ) type deletionHandler func(t readWriteTransaction, folder, device, name []byte, dbi iterator.Iterator) type Instance struct { committed int64 // this must be the first attribute in the struct to ensure 64 bit alignment on 32 bit plaforms *leveldb.DB location string folderIdx *smallIndex deviceIdx *smallIndex } const ( keyPrefixLen = 1 keyFolderLen = 4 // indexed keyDeviceLen = 4 // indexed keyHashLen = 32 ) func Open(file string) (*Instance, error) { opts := &opt.Options{ OpenFilesCacheCapacity: 100, WriteBuffer: 4 << 20, } db, err := leveldb.OpenFile(file, opts) if leveldbIsCorrupted(err) { db, err = leveldb.RecoverFile(file, opts) } if leveldbIsCorrupted(err) { // The database is corrupted, and we've tried to recover it but it // didn't work. At this point there isn't much to do beyond dropping // the database and reindexing... l.Infoln("Database corruption detected, unable to recover. Reinitializing...") if err := os.RemoveAll(file); err != nil { return nil, err } db, err = leveldb.OpenFile(file, opts) } if err != nil { return nil, err } return newDBInstance(db, file), nil } func OpenMemory() *Instance { db, _ := leveldb.Open(storage.NewMemStorage(), nil) return newDBInstance(db, "") } func newDBInstance(db *leveldb.DB, location string) *Instance { i := &Instance{ DB: db, location: location, } i.folderIdx = newSmallIndex(i, []byte{KeyTypeFolderIdx}) i.deviceIdx = newSmallIndex(i, []byte{KeyTypeDeviceIdx}) return i } // Committed returns the number of items committed to the database since startup func (db *Instance) Committed() int64 { return atomic.LoadInt64(&db.committed) } // Location returns the filesystem path where the database is stored func (db *Instance) Location() string { return db.location } func (db *Instance) updateFiles(folder, device []byte, fs []protocol.FileInfo, meta *metadataTracker) { t := db.newReadWriteTransaction() defer t.close() var fk []byte for _, f := range fs { name := []byte(f.Name) fk = db.deviceKeyInto(fk[:cap(fk)], folder, device, name) // Get and unmarshal the file entry. If it doesn't exist or can't be // unmarshalled we'll add it as a new entry. bs, err := t.Get(fk, nil) var ef FileInfoTruncated if err == nil { err = ef.Unmarshal(bs) } // The Invalid flag might change without the version being bumped. if err == nil && ef.Version.Equal(f.Version) && ef.Invalid == f.Invalid { continue } devID := protocol.DeviceIDFromBytes(device) if err == nil { meta.removeFile(devID, ef) } meta.addFile(devID, f) t.insertFile(folder, device, f) t.updateGlobal(folder, device, f, meta) // Write out and reuse the batch every few records, to avoid the batch // growing too large and thus allocating unnecessarily much memory. t.checkFlush() } } func (db *Instance) withHave(folder, device, prefix []byte, truncate bool, fn Iterator) { t := db.newReadOnlyTransaction() defer t.close() dbi := t.NewIterator(util.BytesPrefix(db.deviceKey(folder, device, prefix)[:keyPrefixLen+keyFolderLen+keyDeviceLen+len(prefix)]), nil) defer dbi.Release() slashedPrefix := prefix if !bytes.HasSuffix(prefix, []byte{'/'}) { slashedPrefix = append(slashedPrefix, '/') } for dbi.Next() { name := db.deviceKeyName(dbi.Key()) if len(prefix) > 0 && !bytes.Equal(name, prefix) && !bytes.HasPrefix(name, slashedPrefix) { return } // The iterator function may keep a reference to the unmarshalled // struct, which in turn references the buffer it was unmarshalled // from. dbi.Value() just returns an internal slice that it reuses, so // we need to copy it. f, err := unmarshalTrunc(append([]byte{}, dbi.Value()...), truncate) if err != nil { l.Debugln("unmarshal error:", err) continue } if cont := fn(f); !cont { return } } } func (db *Instance) withAllFolderTruncated(folder []byte, fn func(device []byte, f FileInfoTruncated) bool) { t := db.newReadWriteTransaction() defer t.close() dbi := t.NewIterator(util.BytesPrefix(db.deviceKey(folder, nil, nil)[:keyPrefixLen+keyFolderLen]), nil) defer dbi.Release() for dbi.Next() { device := db.deviceKeyDevice(dbi.Key()) var f FileInfoTruncated // The iterator function may keep a reference to the unmarshalled // struct, which in turn references the buffer it was unmarshalled // from. dbi.Value() just returns an internal slice that it reuses, so // we need to copy it. err := f.Unmarshal(append([]byte{}, dbi.Value()...)) if err != nil { l.Debugln("unmarshal error:", err) continue } switch f.Name { case "", ".", "..", "/": // A few obviously invalid filenames l.Infof("Dropping invalid filename %q from database", f.Name) t.removeFromGlobal(folder, device, nil, nil) t.Delete(dbi.Key()) t.checkFlush() continue } if cont := fn(device, f); !cont { return } } } func (db *Instance) getFile(folder, device, file []byte) (protocol.FileInfo, bool) { return getFile(db, db.deviceKey(folder, device, file)) } func (db *Instance) getGlobal(folder, file []byte, truncate bool) (FileIntf, bool) { k := db.globalKey(folder, file) t := db.newReadOnlyTransaction() defer t.close() bs, err := t.Get(k, nil) if err != nil { return nil, false } var vl VersionList err = vl.Unmarshal(bs) if err == leveldb.ErrNotFound { return nil, false } if err != nil { l.Debugln("unmarshal error:", k, err) return nil, false } if len(vl.Versions) == 0 { l.Debugln("no versions:", k) return nil, false } k = db.deviceKey(folder, vl.Versions[0].Device, file) bs, err = t.Get(k, nil) if err != nil { l.Debugln("surprise error:", k, err) return nil, false } fi, err := unmarshalTrunc(bs, truncate) if err != nil { l.Debugln("unmarshal error:", k, err) return nil, false } return fi, true } func (db *Instance) withGlobal(folder, prefix []byte, truncate bool, fn Iterator) { t := db.newReadOnlyTransaction() defer t.close() dbi := t.NewIterator(util.BytesPrefix(db.globalKey(folder, prefix)), nil) defer dbi.Release() slashedPrefix := prefix if !bytes.HasSuffix(prefix, []byte{'/'}) { slashedPrefix = append(slashedPrefix, '/') } var fk []byte for dbi.Next() { var vl VersionList err := vl.Unmarshal(dbi.Value()) if err != nil { l.Debugln("unmarshal error:", err) continue } if len(vl.Versions) == 0 { l.Debugln("no versions:", dbi.Key()) continue } name := db.globalKeyName(dbi.Key()) if len(prefix) > 0 && !bytes.Equal(name, prefix) && !bytes.HasPrefix(name, slashedPrefix) { return } fk = db.deviceKeyInto(fk[:cap(fk)], folder, vl.Versions[0].Device, name) bs, err := t.Get(fk, nil) if err != nil { l.Debugln("surprise error:", err) continue } f, err := unmarshalTrunc(bs, truncate) if err != nil { l.Debugln("unmarshal error:", err) continue } if cont := fn(f); !cont { return } } } func (db *Instance) availability(folder, file []byte) []protocol.DeviceID { k := db.globalKey(folder, file) bs, err := db.Get(k, nil) if err == leveldb.ErrNotFound { return nil } if err != nil { l.Debugln("surprise error:", err) return nil } var vl VersionList err = vl.Unmarshal(bs) if err != nil { l.Debugln("unmarshal error:", err) return nil } var devices []protocol.DeviceID for _, v := range vl.Versions { if !v.Version.Equal(vl.Versions[0].Version) { break } if v.Invalid { continue } n := protocol.DeviceIDFromBytes(v.Device) devices = append(devices, n) } return devices } func (db *Instance) withNeed(folder, device []byte, truncate bool, fn Iterator) { t := db.newReadOnlyTransaction() defer t.close() dbi := t.NewIterator(util.BytesPrefix(db.globalKey(folder, nil)[:keyPrefixLen+keyFolderLen]), nil) defer dbi.Release() var fk []byte for dbi.Next() { var vl VersionList err := vl.Unmarshal(dbi.Value()) if err != nil { l.Debugln("unmarshal error:", err) continue } if len(vl.Versions) == 0 { l.Debugln("no versions:", dbi.Key()) continue } have := false // If we have the file, any version need := false // If we have a lower version of the file var haveFileVersion FileVersion for _, v := range vl.Versions { if bytes.Equal(v.Device, device) { have = true haveFileVersion = v // XXX: This marks Concurrent (i.e. conflicting) changes as // needs. Maybe we should do that, but it needs special // handling in the puller. need = !v.Version.GreaterEqual(vl.Versions[0].Version) break } } if have && !need { continue } name := db.globalKeyName(dbi.Key()) needVersion := vl.Versions[0].Version needDevice := protocol.DeviceIDFromBytes(vl.Versions[0].Device) for i := range vl.Versions { if !vl.Versions[i].Version.Equal(needVersion) { // We haven't found a valid copy of the file with the needed version. break } if vl.Versions[i].Invalid { // The file is marked invalid, don't use it. continue } fk = db.deviceKeyInto(fk[:cap(fk)], folder, vl.Versions[i].Device, name) bs, err := t.Get(fk, nil) if err != nil { l.Debugln("surprise error:", err) continue } gf, err := unmarshalTrunc(bs, truncate) if err != nil { l.Debugln("unmarshal error:", err) continue } if gf.IsDeleted() && !have { // We don't need deleted files that we don't have break } l.Debugf("need folder=%q device=%v name=%q need=%v have=%v invalid=%v haveV=%v globalV=%v globalDev=%v", folder, protocol.DeviceIDFromBytes(device), name, need, have, haveFileVersion.Invalid, haveFileVersion.Version, needVersion, needDevice) if cont := fn(gf); !cont { return } // This file is handled, no need to look further in the version list break } } } func (db *Instance) ListFolders() []string { t := db.newReadOnlyTransaction() defer t.close() dbi := t.NewIterator(util.BytesPrefix([]byte{KeyTypeGlobal}), nil) defer dbi.Release() folderExists := make(map[string]bool) for dbi.Next() { folder, ok := db.globalKeyFolder(dbi.Key()) if ok && !folderExists[string(folder)] { folderExists[string(folder)] = true } } folders := make([]string, 0, len(folderExists)) for k := range folderExists { folders = append(folders, k) } sort.Strings(folders) return folders } func (db *Instance) dropFolder(folder []byte) { t := db.newReadOnlyTransaction() defer t.close() // Remove all items related to the given folder from the device->file bucket dbi := t.NewIterator(util.BytesPrefix([]byte{KeyTypeDevice}), nil) for dbi.Next() { itemFolder := db.deviceKeyFolder(dbi.Key()) if bytes.Equal(folder, itemFolder) { db.Delete(dbi.Key(), nil) } } dbi.Release() // Remove all items related to the given folder from the global bucket dbi = t.NewIterator(util.BytesPrefix([]byte{KeyTypeGlobal}), nil) for dbi.Next() { itemFolder, ok := db.globalKeyFolder(dbi.Key()) if ok && bytes.Equal(folder, itemFolder) { db.Delete(dbi.Key(), nil) } } dbi.Release() } func (db *Instance) dropDeviceFolder(device, folder []byte, meta *metadataTracker) { t := db.newReadWriteTransaction() defer t.close() dbi := t.NewIterator(util.BytesPrefix(db.deviceKey(folder, device, nil)), nil) defer dbi.Release() for dbi.Next() { key := dbi.Key() name := db.deviceKeyName(key) t.removeFromGlobal(folder, device, name, meta) t.Delete(key) t.checkFlush() } } func (db *Instance) checkGlobals(folder []byte, meta *metadataTracker) { t := db.newReadWriteTransaction() defer t.close() dbi := t.NewIterator(util.BytesPrefix(db.globalKey(folder, nil)[:keyPrefixLen+keyFolderLen]), nil) defer dbi.Release() var fk []byte for dbi.Next() { gk := dbi.Key() var vl VersionList err := vl.Unmarshal(dbi.Value()) if err != nil { l.Debugln("unmarshal error:", err) continue } // Check the global version list for consistency. An issue in previous // versions of goleveldb could result in reordered writes so that // there are global entries pointing to no longer existing files. Here // we find those and clear them out. name := db.globalKeyName(gk) var newVL VersionList for i, version := range vl.Versions { fk = db.deviceKeyInto(fk[:cap(fk)], folder, version.Device, name) _, err := t.Get(fk, nil) if err == leveldb.ErrNotFound { continue } if err != nil { l.Debugln("surprise error:", err) return } newVL.Versions = append(newVL.Versions, version) if i == 0 { if fi, ok := t.getFile(folder, version.Device, name); ok { meta.addFile(globalDeviceID, fi) } } } if len(newVL.Versions) != len(vl.Versions) { t.Put(dbi.Key(), mustMarshal(&newVL)) t.checkFlush() } } l.Debugf("db check completed for %q", folder) } // ConvertSymlinkTypes should be run once only on an old database. It // changes SYMLINK_FILE and SYMLINK_DIRECTORY types to the current SYMLINK // type (previously SYMLINK_UNKNOWN). It does this for all devices, both // local and remote, and does not reset delta indexes. It shouldn't really // matter what the symlink type is, but this cleans it up for a possible // future when SYMLINK_FILE and SYMLINK_DIRECTORY are no longer understood. func (db *Instance) ConvertSymlinkTypes() { t := db.newReadWriteTransaction() defer t.close() dbi := t.NewIterator(util.BytesPrefix([]byte{KeyTypeDevice}), nil) defer dbi.Release() conv := 0 for dbi.Next() { var f protocol.FileInfo if err := f.Unmarshal(dbi.Value()); err != nil { // probably can't happen continue } if f.Type == protocol.FileInfoTypeDeprecatedSymlinkDirectory || f.Type == protocol.FileInfoTypeDeprecatedSymlinkFile { f.Type = protocol.FileInfoTypeSymlink bs, err := f.Marshal() if err != nil { panic("can't happen: " + err.Error()) } t.Put(dbi.Key(), bs) t.checkFlush() conv++ } } l.Infof("Updated symlink type for %d index entries", conv) } // AddInvalidToGlobal searches for invalid files and adds them to the global list. // Invalid files exist in the db if they once were not ignored and subsequently // ignored. In the new system this is still valid, but invalid files must also be // in the global list such that they cannot be mistaken for missing files. func (db *Instance) AddInvalidToGlobal(folder, device []byte) int { t := db.newReadWriteTransaction() defer t.close() dbi := t.NewIterator(util.BytesPrefix(db.deviceKey(folder, device, nil)[:keyPrefixLen+keyFolderLen+keyDeviceLen]), nil) defer dbi.Release() changed := 0 for dbi.Next() { var file protocol.FileInfo if err := file.Unmarshal(dbi.Value()); err != nil { // probably can't happen continue } if file.Invalid { changed++ l.Debugf("add invalid to global; folder=%q device=%v file=%q version=%v", folder, protocol.DeviceIDFromBytes(device), file.Name, file.Version) // this is an adapted version of readWriteTransaction.updateGlobal name := []byte(file.Name) gk := t.db.globalKey(folder, name) var fl VersionList if svl, err := t.Get(gk, nil); err == nil { fl.Unmarshal(svl) // skip error, range handles success case } nv := FileVersion{ Device: device, Version: file.Version, Invalid: file.Invalid, } inserted := false // Find a position in the list to insert this file. The file at the front // of the list is the newer, the "global". insert: for i := range fl.Versions { switch fl.Versions[i].Version.Compare(file.Version) { case protocol.Equal: // Invalid files should go after a valid file of equal version if nv.Invalid { continue insert } fallthrough case protocol.Lesser: // The version at this point in the list is equal to or lesser // ("older") than us. We insert ourselves in front of it. fl.Versions = insertVersion(fl.Versions, i, nv) inserted = true break insert case protocol.ConcurrentLesser, protocol.ConcurrentGreater: // The version at this point is in conflict with us. We must pull // the actual file metadata to determine who wins. If we win, we // insert ourselves in front of the loser here. (The "Lesser" and // "Greater" in the condition above is just based on the device // IDs in the version vector, which is not the only thing we use // to determine the winner.) // // A surprise missing file entry here is counted as a win for us. of, ok := t.getFile(folder, fl.Versions[i].Device, name) if !ok || file.WinsConflict(of) { fl.Versions = insertVersion(fl.Versions, i, nv) inserted = true break insert } } } if !inserted { // We didn't find a position for an insert above, so append to the end. fl.Versions = append(fl.Versions, nv) } t.Put(gk, mustMarshal(&fl)) } } return changed } // deviceKey returns a byte slice encoding the following information: // keyTypeDevice (1 byte) // folder (4 bytes) // device (4 bytes) // name (variable size) func (db *Instance) deviceKey(folder, device, file []byte) []byte { return db.deviceKeyInto(nil, folder, device, file) } func (db *Instance) deviceKeyInto(k []byte, folder, device, file []byte) []byte { reqLen := keyPrefixLen + keyFolderLen + keyDeviceLen + len(file) if len(k) < reqLen { k = make([]byte, reqLen) } k[0] = KeyTypeDevice binary.BigEndian.PutUint32(k[keyPrefixLen:], db.folderIdx.ID(folder)) binary.BigEndian.PutUint32(k[keyPrefixLen+keyFolderLen:], db.deviceIdx.ID(device)) copy(k[keyPrefixLen+keyFolderLen+keyDeviceLen:], file) return k[:reqLen] } // deviceKeyName returns the device ID from the key func (db *Instance) deviceKeyName(key []byte) []byte { return key[keyPrefixLen+keyFolderLen+keyDeviceLen:] } // deviceKeyFolder returns the folder name from the key func (db *Instance) deviceKeyFolder(key []byte) []byte { folder, ok := db.folderIdx.Val(binary.BigEndian.Uint32(key[keyPrefixLen:])) if !ok { panic("bug: lookup of nonexistent folder ID") } return folder } // deviceKeyDevice returns the device ID from the key func (db *Instance) deviceKeyDevice(key []byte) []byte { device, ok := db.deviceIdx.Val(binary.BigEndian.Uint32(key[keyPrefixLen+keyFolderLen:])) if !ok { panic("bug: lookup of nonexistent device ID") } return device } // globalKey returns a byte slice encoding the following information: // keyTypeGlobal (1 byte) // folder (4 bytes) // name (variable size) func (db *Instance) globalKey(folder, file []byte) []byte { k := make([]byte, keyPrefixLen+keyFolderLen+len(file)) k[0] = KeyTypeGlobal binary.BigEndian.PutUint32(k[keyPrefixLen:], db.folderIdx.ID(folder)) copy(k[keyPrefixLen+keyFolderLen:], file) return k } // globalKeyName returns the filename from the key func (db *Instance) globalKeyName(key []byte) []byte { return key[keyPrefixLen+keyFolderLen:] } // globalKeyFolder returns the folder name from the key func (db *Instance) globalKeyFolder(key []byte) ([]byte, bool) { return db.folderIdx.Val(binary.BigEndian.Uint32(key[keyPrefixLen:])) } func (db *Instance) getIndexID(device, folder []byte) protocol.IndexID { key := db.indexIDKey(device, folder) cur, err := db.Get(key, nil) if err != nil { return 0 } var id protocol.IndexID if err := id.Unmarshal(cur); err != nil { return 0 } return id } func (db *Instance) setIndexID(device, folder []byte, id protocol.IndexID) { key := db.indexIDKey(device, folder) bs, _ := id.Marshal() // marshalling can't fail if err := db.Put(key, bs, nil); err != nil { panic("storing index ID: " + err.Error()) } } func (db *Instance) indexIDKey(device, folder []byte) []byte { k := make([]byte, keyPrefixLen+keyDeviceLen+keyFolderLen) k[0] = KeyTypeIndexID binary.BigEndian.PutUint32(k[keyPrefixLen:], db.deviceIdx.ID(device)) binary.BigEndian.PutUint32(k[keyPrefixLen+keyDeviceLen:], db.folderIdx.ID(folder)) return k } func (db *Instance) indexIDDevice(key []byte) []byte { device, ok := db.deviceIdx.Val(binary.BigEndian.Uint32(key[keyPrefixLen:])) if !ok { // uuh ... return nil } return device } func (db *Instance) mtimesKey(folder []byte) []byte { prefix := make([]byte, 5) // key type + 4 bytes folder idx number prefix[0] = KeyTypeVirtualMtime binary.BigEndian.PutUint32(prefix[1:], db.folderIdx.ID(folder)) return prefix } func (db *Instance) folderMetaKey(folder []byte) []byte { prefix := make([]byte, 5) // key type + 4 bytes folder idx number prefix[0] = KeyTypeFolderMeta binary.BigEndian.PutUint32(prefix[1:], db.folderIdx.ID(folder)) return prefix } // DropLocalDeltaIndexIDs removes all index IDs for the local device ID from // the database. This will cause a full index transmission on the next // connection. func (db *Instance) DropLocalDeltaIndexIDs() { db.dropDeltaIndexIDs(true) } // DropRemoteDeltaIndexIDs removes all index IDs for the other devices than // the local one from the database. This will cause them to send us a full // index on the next connection. func (db *Instance) DropRemoteDeltaIndexIDs() { db.dropDeltaIndexIDs(false) } func (db *Instance) dropDeltaIndexIDs(local bool) { t := db.newReadWriteTransaction() defer t.close() dbi := t.NewIterator(util.BytesPrefix([]byte{KeyTypeIndexID}), nil) defer dbi.Release() for dbi.Next() { device := db.indexIDDevice(dbi.Key()) if bytes.Equal(device, protocol.LocalDeviceID[:]) == local { t.Delete(dbi.Key()) } } } func (db *Instance) dropMtimes(folder []byte) { db.dropPrefix(db.mtimesKey(folder)) } func (db *Instance) dropFolderMeta(folder []byte) { db.dropPrefix(db.folderMetaKey(folder)) } func (db *Instance) dropPrefix(prefix []byte) { t := db.newReadWriteTransaction() defer t.close() dbi := t.NewIterator(util.BytesPrefix(prefix), nil) defer dbi.Release() for dbi.Next() { t.Delete(dbi.Key()) } } func unmarshalTrunc(bs []byte, truncate bool) (FileIntf, error) { if truncate { var tf FileInfoTruncated err := tf.Unmarshal(bs) return tf, err } var tf protocol.FileInfo err := tf.Unmarshal(bs) return tf, err } // A "better" version of leveldb's errors.IsCorrupted. func leveldbIsCorrupted(err error) bool { switch { case err == nil: return false case errors.IsCorrupted(err): return true case strings.Contains(err.Error(), "corrupted"): return true } return false } // A smallIndex is an in memory bidirectional []byte to uint32 map. It gives // fast lookups in both directions and persists to the database. Don't use for // storing more items than fit comfortably in RAM. type smallIndex struct { db *Instance prefix []byte id2val map[uint32]string val2id map[string]uint32 nextID uint32 mut sync.Mutex } func newSmallIndex(db *Instance, prefix []byte) *smallIndex { idx := &smallIndex{ db: db, prefix: prefix, id2val: make(map[uint32]string), val2id: make(map[string]uint32), mut: sync.NewMutex(), } idx.load() return idx } // load iterates over the prefix space in the database and populates the in // memory maps. func (i *smallIndex) load() { tr := i.db.newReadOnlyTransaction() it := tr.NewIterator(util.BytesPrefix(i.prefix), nil) for it.Next() { val := string(it.Value()) id := binary.BigEndian.Uint32(it.Key()[len(i.prefix):]) i.id2val[id] = val i.val2id[val] = id if id >= i.nextID { i.nextID = id + 1 } } it.Release() tr.close() } // ID returns the index number for the given byte slice, allocating a new one // and persisting this to the database if necessary. func (i *smallIndex) ID(val []byte) uint32 { i.mut.Lock() // intentionally avoiding defer here as we want this call to be as fast as // possible in the general case (folder ID already exists). The map lookup // with the conversion of []byte to string is compiler optimized to not // copy the []byte, which is why we don't assign it to a temp variable // here. if id, ok := i.val2id[string(val)]; ok { i.mut.Unlock() return id } id := i.nextID i.nextID++ valStr := string(val) i.val2id[valStr] = id i.id2val[id] = valStr key := make([]byte, len(i.prefix)+8) // prefix plus uint32 id copy(key, i.prefix) binary.BigEndian.PutUint32(key[len(i.prefix):], id) i.db.Put(key, val, nil) i.mut.Unlock() return id } // Val returns the value for the given index number, or (nil, false) if there // is no such index number. func (i *smallIndex) Val(id uint32) ([]byte, bool) { i.mut.Lock() val, ok := i.id2val[id] i.mut.Unlock() if !ok { return nil, false } return []byte(val), true }