package consul import ( "bytes" "fmt" "github.com/armon/gomdb" "reflect" "strings" "sync/atomic" "time" ) var ( noIndex = fmt.Errorf("undefined index") tooManyFields = fmt.Errorf("number of fields exceeds index arity") ) const ( // lastIndexRowID is a special RowID used to represent the // last Raft index that affected the table. The index value // is not used by MDBTable, but is stored so that the client can map // back to the Raft index number lastIndexRowID = 0 ) /* An MDB table is a logical representation of a table, which is a generic row store. It provides a simple mechanism to store rows using a row id, while maintaining any number of secondary indexes. */ type MDBTable struct { Env *mdb.Env Name string // This is the name of the table, must be unique Indexes map[string]*MDBIndex Encoder func(interface{}) []byte Decoder func([]byte) interface{} // Last used rowID lastRowID uint64 } // MDBTables is used for when we have a collection of tables type MDBTables []*MDBTable // An Index is named, and uses a series of column values to // map to the row-id containing the table type MDBIndex struct { AllowBlank bool // Can fields be blank Unique bool // Controls if values are unique Fields []string // Fields are used to build the index IdxFunc IndexFunc // Can be used to provide custom indexing Virtual bool // Virtual index does not exist, but can be used for queries RealIndex string // Virtual indexes use a RealIndex for iteration table *MDBTable name string dbiName string realIndex *MDBIndex } // MDBTxn is used to wrap an underlying transaction type MDBTxn struct { readonly bool tx *mdb.Txn dbis map[string]mdb.DBI } // Abort is used to close the transaction func (t *MDBTxn) Abort() { if t != nil && t.tx != nil { t.tx.Abort() } } // Commit is used to commit a transaction func (t *MDBTxn) Commit() error { return t.tx.Commit() } type IndexFunc func(*MDBIndex, []string) string // DefaultIndexFunc is used if no IdxFunc is provided. It joins // the columns using '||' which is reasonably unlikely to occur. // We also prefix with a byte to ensure we never have a zero length // key func DefaultIndexFunc(idx *MDBIndex, parts []string) string { if len(parts) == 0 { return "_" } prefix := "_" + strings.Join(parts, "||") + "||" return prefix } // DefaultIndexPrefixFunc can be used with DefaultIndexFunc to scan // for index prefix values. This should only be used as part of a // virtual index. func DefaultIndexPrefixFunc(idx *MDBIndex, parts []string) string { if len(parts) == 0 { return "_" } prefix := "_" + strings.Join(parts, "||") return prefix } // Init is used to initialize the MDBTable and ensure it's ready func (t *MDBTable) Init() error { if t.Env == nil { return fmt.Errorf("Missing mdb env") } if t.Name == "" { return fmt.Errorf("Missing table name") } if t.Indexes == nil { return fmt.Errorf("Missing table indexes") } // Ensure we have a unique id index id, ok := t.Indexes["id"] if !ok { return fmt.Errorf("Missing id index") } if !id.Unique { return fmt.Errorf("id index must be unique") } if id.AllowBlank { return fmt.Errorf("id index must not allow blanks") } if id.Virtual { return fmt.Errorf("id index cannot be virtual") } // Create the table if err := t.createTable(); err != nil { return fmt.Errorf("table create failed: %v", err) } // Initialize the indexes for name, index := range t.Indexes { if err := index.init(t, name); err != nil { return fmt.Errorf("index %s error: %s", name, err) } } // Get the maximum row id if err := t.restoreLastRowID(); err != nil { return fmt.Errorf("error scanning table: %s", err) } return nil } // createTable is used to ensure the table exists func (t *MDBTable) createTable() error { tx, err := t.Env.BeginTxn(nil, 0) if err != nil { return err } if _, err := tx.DBIOpen(t.Name, mdb.CREATE); err != nil { tx.Abort() return err } return tx.Commit() } // restoreLastRowID is used to set the last rowID that we've used func (t *MDBTable) restoreLastRowID() error { tx, err := t.StartTxn(true, nil) if err != nil { return err } defer tx.Abort() cursor, err := tx.tx.CursorOpen(tx.dbis[t.Name]) if err != nil { return err } defer cursor.Close() key, _, err := cursor.Get(nil, mdb.LAST) if err == mdb.NotFound { t.lastRowID = 0 return nil } else if err != nil { return err } // Set the last row id t.lastRowID = bytesToUint64(key) return nil } // nextRowID returns the next usable row id func (t *MDBTable) nextRowID() uint64 { return atomic.AddUint64(&t.lastRowID, 1) } // startTxn is used to start a transaction func (t *MDBTable) StartTxn(readonly bool, mdbTxn *MDBTxn) (*MDBTxn, error) { var txFlags uint = 0 var tx *mdb.Txn var err error // Panic if we deadlock acquiring a transaction timeout := time.AfterFunc(5*time.Second, func() { panic("Timeout starting MDB transaction, potential deadlock") }) defer timeout.Stop() // Ensure the modes agree if mdbTxn != nil { if mdbTxn.readonly != readonly { return nil, fmt.Errorf("Cannot mix read/write transactions") } tx = mdbTxn.tx goto EXTEND } if readonly { txFlags |= mdb.RDONLY } tx, err = t.Env.BeginTxn(nil, txFlags) if err != nil { return nil, err } mdbTxn = &MDBTxn{ readonly: readonly, tx: tx, dbis: make(map[string]mdb.DBI), } EXTEND: dbi, err := tx.DBIOpen(t.Name, 0) if err != nil { tx.Abort() return nil, err } mdbTxn.dbis[t.Name] = dbi for _, index := range t.Indexes { if index.Virtual { continue } dbi, err := index.openDBI(tx) if err != nil { tx.Abort() return nil, err } mdbTxn.dbis[index.dbiName] = dbi } return mdbTxn, nil } // objIndexKeys builds the indexes for a given object func (t *MDBTable) objIndexKeys(obj interface{}) (map[string][]byte, error) { // Construct the indexes keys indexes := make(map[string][]byte) for name, index := range t.Indexes { if index.Virtual { continue } key, err := index.keyFromObject(obj) if err != nil { return nil, err } indexes[name] = key } return indexes, nil } // Insert is used to insert or update an object func (t *MDBTable) Insert(obj interface{}) error { // Start a new txn tx, err := t.StartTxn(false, nil) if err != nil { return err } defer tx.Abort() if err := t.InsertTxn(tx, obj); err != nil { return err } return tx.Commit() } // Insert is used to insert or update an object within // a given transaction func (t *MDBTable) InsertTxn(tx *MDBTxn, obj interface{}) error { var n int // Construct the indexes keys indexes, err := t.objIndexKeys(obj) if err != nil { return err } // Encode the obj raw := t.Encoder(obj) // Scan and check if this primary key already exists primaryDbi := tx.dbis[t.Indexes["id"].dbiName] _, err = tx.tx.Get(primaryDbi, indexes["id"]) if err == mdb.NotFound { goto AFTER_DELETE } // Delete the existing row n, err = t.deleteWithIndex(tx, t.Indexes["id"], indexes["id"]) if err != nil { return err } if n != 1 { return fmt.Errorf("unexpected number of updates: %d", n) } AFTER_DELETE: // Insert with a new row ID rowId := t.nextRowID() encRowId := uint64ToBytes(rowId) table := tx.dbis[t.Name] if err := tx.tx.Put(table, encRowId, raw, 0); err != nil { return err } // Insert the new indexes for name, index := range t.Indexes { if index.Virtual { continue } dbi := tx.dbis[index.dbiName] if err := tx.tx.Put(dbi, indexes[name], encRowId, 0); err != nil { return err } } return nil } // Get is used to lookup one or more rows. An index an appropriate // fields are specified. The fields can be a prefix of the index. func (t *MDBTable) Get(index string, parts ...string) (uint64, []interface{}, error) { // Start a readonly txn tx, err := t.StartTxn(true, nil) if err != nil { return 0, nil, err } defer tx.Abort() // Get the last associated index idx, err := t.LastIndexTxn(tx) if err != nil { return 0, nil, err } // Get the actual results res, err := t.GetTxn(tx, index, parts...) return idx, res, err } // GetTxn is like Get but it operates within a specific transaction. // This can be used for read that span multiple tables func (t *MDBTable) GetTxn(tx *MDBTxn, index string, parts ...string) ([]interface{}, error) { // Get the associated index idx, key, err := t.getIndex(index, parts) if err != nil { return nil, err } // Accumulate the results var results []interface{} err = idx.iterate(tx, key, func(encRowId, res []byte) bool { obj := t.Decoder(res) results = append(results, obj) return false }) return results, err } // getIndex is used to get the proper index, and also check the arity func (t *MDBTable) getIndex(index string, parts []string) (*MDBIndex, []byte, error) { // Get the index idx, ok := t.Indexes[index] if !ok { return nil, nil, noIndex } // Check the arity arity := idx.arity() if len(parts) > arity { return nil, nil, tooManyFields } // Construct the key key := idx.keyFromParts(parts...) return idx, key, nil } // Delete is used to delete one or more rows. An index an appropriate // fields are specified. The fields can be a prefix of the index. // Returns the rows deleted or an error. func (t *MDBTable) Delete(index string, parts ...string) (num int, err error) { // Start a write txn tx, err := t.StartTxn(false, nil) if err != nil { return 0, err } defer tx.Abort() num, err = t.DeleteTxn(tx, index, parts...) if err != nil { return 0, err } return num, tx.Commit() } // DeleteTxn is like Delete, but occurs in a specific transaction // that can span multiple tables. func (t *MDBTable) DeleteTxn(tx *MDBTxn, index string, parts ...string) (int, error) { // Get the associated index idx, key, err := t.getIndex(index, parts) if err != nil { return 0, err } // Delete with the index return t.deleteWithIndex(tx, idx, key) } // deleteWithIndex deletes all associated rows while scanning // a given index for a key prefix. func (t *MDBTable) deleteWithIndex(tx *MDBTxn, idx *MDBIndex, key []byte) (num int, err error) { // Handle an error while deleting defer func() { if r := recover(); r != nil { num = 0 err = fmt.Errorf("Panic while deleting: %v", r) } }() // Delete everything as we iterate err = idx.iterate(tx, key, func(encRowId, res []byte) bool { // Get the object obj := t.Decoder(res) // Build index values indexes, err := t.objIndexKeys(obj) if err != nil { panic(err) } // Delete the indexes we are not iterating for name, otherIdx := range t.Indexes { if name == idx.name { continue } if idx.Virtual && name == idx.RealIndex { continue } if otherIdx.Virtual { continue } dbi := tx.dbis[otherIdx.dbiName] if err := tx.tx.Del(dbi, indexes[name], encRowId); err != nil { panic(err) } } // Delete the data row if err := tx.tx.Del(tx.dbis[t.Name], encRowId, nil); err != nil { panic(err) } // Delete the object num++ return true }) if err != nil { return 0, err } // Return the deleted count return num, nil } // Initializes an index and returns a potential error func (i *MDBIndex) init(table *MDBTable, name string) error { i.table = table i.name = name i.dbiName = fmt.Sprintf("%s_%s_idx", i.table.Name, i.name) if i.IdxFunc == nil { i.IdxFunc = DefaultIndexFunc } if len(i.Fields) == 0 { return fmt.Errorf("index missing fields") } if err := i.createIndex(); err != nil { return err } // Verify real index exists if i.Virtual { if realIndex, ok := table.Indexes[i.RealIndex]; !ok { return fmt.Errorf("real index '%s' missing", i.RealIndex) } else { i.realIndex = realIndex } } return nil } // createIndex is used to ensure the index exists func (i *MDBIndex) createIndex() error { // Do not create if this is a virtual index if i.Virtual { return nil } tx, err := i.table.Env.BeginTxn(nil, 0) if err != nil { return err } var dbFlags uint = mdb.CREATE if !i.Unique { dbFlags |= mdb.DUPSORT } if _, err := tx.DBIOpen(i.dbiName, dbFlags); err != nil { tx.Abort() return err } return tx.Commit() } // openDBI is used to open a handle to the index for a transaction func (i *MDBIndex) openDBI(tx *mdb.Txn) (mdb.DBI, error) { var dbFlags uint if !i.Unique { dbFlags |= mdb.DUPSORT } return tx.DBIOpen(i.dbiName, dbFlags) } // Returns the arity of the index func (i *MDBIndex) arity() int { return len(i.Fields) } // keyFromObject constructs the index key from the object func (i *MDBIndex) keyFromObject(obj interface{}) ([]byte, error) { v := reflect.ValueOf(obj) v = reflect.Indirect(v) // Derefence the pointer if any parts := make([]string, 0, i.arity()) for _, field := range i.Fields { fv := v.FieldByName(field) if !fv.IsValid() { return nil, fmt.Errorf("Field '%s' for %#v is invalid", field, obj) } val := fv.String() if !i.AllowBlank && val == "" { return nil, fmt.Errorf("Field '%s' must be set: %#v", field, obj) } parts = append(parts, val) } key := i.keyFromParts(parts...) return key, nil } // keyFromParts returns the key from component parts func (i *MDBIndex) keyFromParts(parts ...string) []byte { return []byte(i.IdxFunc(i, parts)) } // iterate is used to iterate over keys matching the prefix, // and invoking the cb with each row. We dereference the rowid, // and only return the object row func (i *MDBIndex) iterate(tx *MDBTxn, prefix []byte, cb func(encRowId, res []byte) bool) error { table := tx.dbis[i.table.Name] // If virtual, use the correct DBI var dbi mdb.DBI if i.Virtual { dbi = tx.dbis[i.realIndex.dbiName] } else { dbi = tx.dbis[i.dbiName] } cursor, err := tx.tx.CursorOpen(dbi) if err != nil { return err } // Read-only cursors are NOT closed by MDB when a transaction // either commits or aborts, so must be closed explicitly if tx.readonly { defer cursor.Close() } var key, encRowId, objBytes []byte first := true shouldDelete := false for { if first && len(prefix) > 0 { first = false key, encRowId, err = cursor.Get(prefix, mdb.SET_RANGE) } else if shouldDelete { key, encRowId, err = cursor.Get(nil, mdb.GET_CURRENT) shouldDelete = false // LMDB will return EINVAL(22) for the GET_CURRENT op if // there is no further keys. We treat this as no more // keys being found. if num, ok := err.(mdb.Errno); ok && num == 22 { err = mdb.NotFound } } else if i.Unique { key, encRowId, err = cursor.Get(nil, mdb.NEXT) } else { key, encRowId, err = cursor.Get(nil, mdb.NEXT_DUP) if err == mdb.NotFound { key, encRowId, err = cursor.Get(nil, mdb.NEXT) } } if err == mdb.NotFound { break } else if err != nil { return fmt.Errorf("iterate failed: %v", err) } // Bail if this does not match our filter if len(prefix) > 0 && !bytes.HasPrefix(key, prefix) { break } // Lookup the actual object objBytes, err = tx.tx.Get(table, encRowId) if err != nil { return fmt.Errorf("rowid lookup failed: %v (%v)", err, encRowId) } // Invoke the cb if shouldDelete = cb(encRowId, objBytes); shouldDelete { if err := cursor.Del(0); err != nil { return fmt.Errorf("delete failed: %v", err) } } } return nil } // LastIndex is get the last index that updated the table func (t *MDBTable) LastIndex() (uint64, error) { // Start a readonly txn tx, err := t.StartTxn(true, nil) if err != nil { return 0, err } defer tx.Abort() return t.LastIndexTxn(tx) } // LastIndexTxn is like LastIndex but it operates within a specific transaction. func (t *MDBTable) LastIndexTxn(tx *MDBTxn) (uint64, error) { encRowId := uint64ToBytes(lastIndexRowID) val, err := tx.tx.Get(tx.dbis[t.Name], encRowId) if err == mdb.NotFound { return 0, nil } else if err != nil { return 0, err } // Return the last index return bytesToUint64(val), nil } // SetLastIndex is used to set the last index that updated the table func (t *MDBTable) SetLastIndex(index uint64) error { tx, err := t.StartTxn(false, nil) if err != nil { return err } defer tx.Abort() if err := t.SetLastIndexTxn(tx, index); err != nil { return err } return tx.Commit() } // SetLastIndexTxn is used to set the last index within a transaction func (t *MDBTable) SetLastIndexTxn(tx *MDBTxn, index uint64) error { encRowId := uint64ToBytes(lastIndexRowID) encIndex := uint64ToBytes(index) return tx.tx.Put(tx.dbis[t.Name], encRowId, encIndex, 0) } // StartTxn is used to create a transaction that spans a list of tables func (t MDBTables) StartTxn(readonly bool) (*MDBTxn, error) { var tx *MDBTxn for _, table := range t { newTx, err := table.StartTxn(readonly, tx) if err != nil { tx.Abort() return nil, err } tx = newTx } return tx, nil } // LastIndexTxn is used to get the last transaction from all of the tables func (t MDBTables) LastIndexTxn(tx *MDBTxn) (uint64, error) { var index uint64 for _, table := range t { idx, err := table.LastIndexTxn(tx) if err != nil { return index, err } if idx > index { index = idx } } return index, nil }