package waddrmgr import ( "fmt" "time" "github.com/btcsuite/btcd/chaincfg" "github.com/btcsuite/btcwallet/walletdb" "github.com/btcsuite/btcwallet/walletdb/migration" ) // versions is a list of the different database versions. The last entry should // reflect the latest database state. If the database happens to be at a version // number lower than the latest, migrations will be performed in order to catch // it up. var versions = []migration.Version{ { Number: 2, Migration: upgradeToVersion2, }, { Number: 5, Migration: upgradeToVersion5, }, { Number: 6, Migration: populateBirthdayBlock, }, } // getLatestVersion returns the version number of the latest database version. func getLatestVersion() uint32 { return versions[len(versions)-1].Number } // MigrationManager is an implementation of the migration.Manager interface that // will be used to handle migrations for the address manager. It exposes the // necessary parameters required to successfully perform migrations. type MigrationManager struct { ns walletdb.ReadWriteBucket } // A compile-time assertion to ensure that MigrationManager implements the // migration.Manager interface. var _ migration.Manager = (*MigrationManager)(nil) // NewMigrationManager creates a new migration manager for the address manager. // The given bucket should reflect the top-level bucket in which all of the // address manager's data is contained within. func NewMigrationManager(ns walletdb.ReadWriteBucket) *MigrationManager { return &MigrationManager{ns: ns} } // Name returns the name of the service we'll be attempting to upgrade. // // NOTE: This method is part of the migration.Manager interface. func (m *MigrationManager) Name() string { return "wallet address manager" } // Namespace returns the top-level bucket of the service. // // NOTE: This method is part of the migration.Manager interface. func (m *MigrationManager) Namespace() walletdb.ReadWriteBucket { return m.ns } // CurrentVersion returns the current version of the service's database. // // NOTE: This method is part of the migration.Manager interface. func (m *MigrationManager) CurrentVersion(ns walletdb.ReadBucket) (uint32, error) { if ns == nil { ns = m.ns } return fetchManagerVersion(ns) } // SetVersion sets the version of the service's database. // // NOTE: This method is part of the migration.Manager interface. func (m *MigrationManager) SetVersion(ns walletdb.ReadWriteBucket, version uint32) error { if ns == nil { ns = m.ns } return putManagerVersion(m.ns, version) } // Versions returns all of the available database versions of the service. // // NOTE: This method is part of the migration.Manager interface. func (m *MigrationManager) Versions() []migration.Version { return versions } // upgradeToVersion2 upgrades the database from version 1 to version 2 // 'usedAddrBucketName' a bucket for storing addrs flagged as marked is // initialized and it will be updated on the next rescan. func upgradeToVersion2(ns walletdb.ReadWriteBucket) error { currentMgrVersion := uint32(2) _, err := ns.CreateBucketIfNotExists(usedAddrBucketName) if err != nil { str := "failed to create used addresses bucket" return managerError(ErrDatabase, str, err) } return putManagerVersion(ns, currentMgrVersion) } // upgradeToVersion5 upgrades the database from version 4 to version 5. After // this update, the new ScopedKeyManager features cannot be used. This is due // to the fact that in version 5, we now store the encrypted master private // keys on disk. However, using the BIP0044 key scope, users will still be able // to create old p2pkh addresses. func upgradeToVersion5(ns walletdb.ReadWriteBucket) error { // First, we'll check if there are any existing segwit addresses, which // can't be upgraded to the new version. If so, we abort and warn the // user. err := ns.NestedReadBucket(addrBucketName).ForEach( func(k []byte, v []byte) error { row, err := deserializeAddressRow(v) if err != nil { return err } if row.addrType > adtScript { return fmt.Errorf("segwit address exists in " + "wallet, can't upgrade from v4 to " + "v5: well, we tried ¯\\_(ツ)_/¯") } return nil }) if err != nil { return err } // Next, we'll write out the new database version. if err := putManagerVersion(ns, 5); err != nil { return err } // First, we'll need to create the new buckets that are used in the new // database version. scopeBucket, err := ns.CreateBucket(scopeBucketName) if err != nil { str := "failed to create scope bucket" return managerError(ErrDatabase, str, err) } scopeSchemas, err := ns.CreateBucket(scopeSchemaBucketName) if err != nil { str := "failed to create scope schema bucket" return managerError(ErrDatabase, str, err) } // With the buckets created, we can now create the default BIP0044 // scope which will be the only scope usable in the database after this // update. scopeKey := scopeToBytes(&KeyScopeBIP0044) scopeSchema := ScopeAddrMap[KeyScopeBIP0044] schemaBytes := scopeSchemaToBytes(&scopeSchema) if err := scopeSchemas.Put(scopeKey[:], schemaBytes); err != nil { return err } if err := createScopedManagerNS(scopeBucket, &KeyScopeBIP0044); err != nil { return err } bip44Bucket := scopeBucket.NestedReadWriteBucket(scopeKey[:]) // With the buckets created, we now need to port over *each* item in // the prior main bucket, into the new default scope. mainBucket := ns.NestedReadWriteBucket(mainBucketName) // First, we'll move over the encrypted coin type private and public // keys to the new sub-bucket. encCoinPrivKeys := mainBucket.Get(coinTypePrivKeyName) encCoinPubKeys := mainBucket.Get(coinTypePubKeyName) err = bip44Bucket.Put(coinTypePrivKeyName, encCoinPrivKeys) if err != nil { return err } err = bip44Bucket.Put(coinTypePubKeyName, encCoinPubKeys) if err != nil { return err } if err := mainBucket.Delete(coinTypePrivKeyName); err != nil { return err } if err := mainBucket.Delete(coinTypePubKeyName); err != nil { return err } // Next, we'll move over everything that was in the meta bucket to the // meta bucket within the new scope. metaBucket := ns.NestedReadWriteBucket(metaBucketName) lastAccount := metaBucket.Get(lastAccountName) if err := metaBucket.Delete(lastAccountName); err != nil { return err } scopedMetaBucket := bip44Bucket.NestedReadWriteBucket(metaBucketName) err = scopedMetaBucket.Put(lastAccountName, lastAccount) if err != nil { return err } // Finally, we'll recursively move over a set of keys which were // formerly under the main bucket, into the new scoped buckets. We'll // do so by obtaining a slice of all the keys that we need to modify // and then recursing through each of them, moving both nested buckets // and key/value pairs. keysToMigrate := [][]byte{ acctBucketName, addrBucketName, usedAddrBucketName, addrAcctIdxBucketName, acctNameIdxBucketName, acctIDIdxBucketName, } // Migrate each bucket recursively. for _, bucketKey := range keysToMigrate { err := migrateRecursively(ns, bip44Bucket, bucketKey) if err != nil { return err } } return nil } // migrateRecursively moves a nested bucket from one bucket to another, // recursing into nested buckets as required. func migrateRecursively(src, dst walletdb.ReadWriteBucket, bucketKey []byte) error { // Within this bucket key, we'll migrate over, then delete each key. bucketToMigrate := src.NestedReadWriteBucket(bucketKey) newBucket, err := dst.CreateBucketIfNotExists(bucketKey) if err != nil { return err } err = bucketToMigrate.ForEach(func(k, v []byte) error { if nestedBucket := bucketToMigrate. NestedReadBucket(k); nestedBucket != nil { // We have a nested bucket, so recurse into it. return migrateRecursively(bucketToMigrate, newBucket, k) } if err := newBucket.Put(k, v); err != nil { return err } return bucketToMigrate.Delete(k) }) if err != nil { return err } // Finally, we'll delete the bucket itself. if err := src.DeleteNestedBucket(bucketKey); err != nil { return err } return nil } // populateBirthdayBlock is a migration that attempts to populate the birthday // block of the wallet. This is needed so that in the event that we need to // perform a rescan of the wallet, we can do so starting from this block, rather // than from the genesis block. // // NOTE: This migration cannot guarantee the correctness of the birthday block // being set as we do not store block timestamps, so a sanity check must be done // upon starting the wallet to ensure we do not potentially miss any relevant // events when rescanning. func populateBirthdayBlock(ns walletdb.ReadWriteBucket) error { // We'll need to jump through some hoops in order to determine the // corresponding block height for our birthday timestamp. Since we do // not store block timestamps, we'll need to estimate our height by // looking at the genesis timestamp and assuming a block occurs every 10 // minutes. This can be unsafe, and cause us to actually miss on-chain // events, so a sanity check is done before the wallet attempts to sync // itself. // // We'll start by fetching our birthday timestamp. birthdayTimestamp, err := fetchBirthday(ns) if err != nil { return fmt.Errorf("unable to fetch birthday timestamp: %v", err) } log.Infof("Setting the wallet's birthday block from timestamp=%v", birthdayTimestamp) // Now, we'll need to determine the timestamp of the genesis block for // the corresponding chain. genesisHash, err := fetchBlockHash(ns, 0) if err != nil { return fmt.Errorf("unable to fetch genesis block hash: %v", err) } var genesisTimestamp time.Time switch *genesisHash { case *chaincfg.MainNetParams.GenesisHash: genesisTimestamp = chaincfg.MainNetParams.GenesisBlock.Header.Timestamp case *chaincfg.TestNet3Params.GenesisHash: genesisTimestamp = chaincfg.TestNet3Params.GenesisBlock.Header.Timestamp case *chaincfg.RegressionNetParams.GenesisHash: genesisTimestamp = chaincfg.RegressionNetParams.GenesisBlock.Header.Timestamp case *chaincfg.SimNetParams.GenesisHash: genesisTimestamp = chaincfg.SimNetParams.GenesisBlock.Header.Timestamp default: return fmt.Errorf("unknown genesis hash %v", genesisHash) } // With the timestamps retrieved, we can estimate a block height by // taking the difference between them and dividing by the average block // time (10 minutes). birthdayHeight := int32((birthdayTimestamp.Sub(genesisTimestamp).Seconds() / 600)) // Now that we have the height estimate, we can fetch the corresponding // block and set it as our birthday block. birthdayHash, err := fetchBlockHash(ns, birthdayHeight) // To ensure we record a height that is known to us from the chain, // we'll make sure this height estimate can be found. Otherwise, we'll // continue subtracting a day worth of blocks until we can find one. for IsError(err, ErrBlockNotFound) { birthdayHeight -= 144 if birthdayHeight < 0 { birthdayHeight = 0 } birthdayHash, err = fetchBlockHash(ns, birthdayHeight) } if err != nil { return err } log.Infof("Estimated birthday block from timestamp=%v: height=%d, "+ "hash=%v", birthdayTimestamp, birthdayHeight, birthdayHash) // NOTE: The timestamp of the birthday block isn't set since we do not // store each block's timestamp. return putBirthdayBlock(ns, BlockStamp{ Height: birthdayHeight, Hash: *birthdayHash, }) }