/* * Copyright (c) 2013, 2014 Conformal Systems LLC * * Permission to use, copy, modify, and distribute this software for any * purpose with or without fee is hereby granted, provided that the above * copyright notice and this permission notice appear in all copies. * * THE SOFTWARE IS PROVIDED "AS IS" AND THE AUTHOR DISCLAIMS ALL WARRANTIES * WITH REGARD TO THIS SOFTWARE INCLUDING ALL IMPLIED WARRANTIES OF * MERCHANTABILITY AND FITNESS. IN NO EVENT SHALL THE AUTHOR BE LIABLE FOR * ANY SPECIAL, DIRECT, INDIRECT, OR CONSEQUENTIAL DAMAGES OR ANY DAMAGES * WHATSOEVER RESULTING FROM LOSS OF USE, DATA OR PROFITS, WHETHER IN AN * ACTION OF CONTRACT, NEGLIGENCE OR OTHER TORTIOUS ACTION, ARISING OUT OF * OR IN CONNECTION WITH THE USE OR PERFORMANCE OF THIS SOFTWARE. */ package main import ( "bytes" "encoding/base64" "encoding/hex" "errors" "fmt" "path/filepath" "sync" "time" "github.com/conformal/btcchain" "github.com/conformal/btcjson" "github.com/conformal/btcnet" "github.com/conformal/btcutil" "github.com/conformal/btcwallet/chain" "github.com/conformal/btcwallet/keystore" "github.com/conformal/btcwallet/txstore" "github.com/conformal/btcwire" ) var ( ErrNoWalletFiles = errors.New("no wallet files") ErrWalletExists = errors.New("wallet already exists") ErrNotSynced = errors.New("wallet is not synchronized with the chain server") ) // networkDir returns the directory name of a network directory to hold wallet // files. func networkDir(net *btcnet.Params) string { netname := net.Name // For now, we must always name the testnet data directory as "testnet" // and not "testnet3" or any other version, as the btcnet testnet3 // paramaters will likely be switched to being named "testnet3" in the // future. This is done to future proof that change, and an upgrade // plan to move the testnet3 data directory can be worked out later. if net.Net == btcwire.TestNet3 { netname = "testnet" } return filepath.Join(cfg.DataDir, netname) } // Wallet is a structure containing all the components for a // complete wallet. It contains the Armory-style key store // addresses and keys), type Wallet struct { // Data stores KeyStore *keystore.Store TxStore *txstore.Store chainSvr *chain.Client chainSvrLock sync.Locker chainSynced chan struct{} // closed when synced lockedOutpoints map[btcwire.OutPoint]struct{} FeeIncrement btcutil.Amount // Channels for rescan processing. Requests are added and merged with // any waiting requests, before being sent to another goroutine to // call the rescan RPC. rescanAddJob chan *RescanJob rescanBatch chan *rescanBatch rescanNotifications chan interface{} // From chain server rescanProgress chan *RescanProgressMsg rescanFinished chan *RescanFinishedMsg // Channel for transaction creation requests. createTxRequests chan createTxRequest // Channels for the keystore locker. unlockRequests chan unlockRequest lockRequests chan struct{} holdUnlockRequests chan chan HeldUnlock lockState chan bool changePassphrase chan changePassphraseRequest // Notification channels so other components can listen in on wallet // activity. These are initialized as nil, and must be created by // calling one of the Listen* methods. connectedBlocks chan keystore.BlockStamp disconnectedBlocks chan keystore.BlockStamp lockStateChanges chan bool // true when locked confirmedBalance chan btcutil.Amount unconfirmedBalance chan btcutil.Amount notificationLock sync.Locker wg sync.WaitGroup quit chan struct{} } // newWallet creates a new Wallet structure with the provided key and // transaction stores. func newWallet(keys *keystore.Store, txs *txstore.Store) *Wallet { return &Wallet{ KeyStore: keys, TxStore: txs, chainSvrLock: new(sync.Mutex), chainSynced: make(chan struct{}), lockedOutpoints: map[btcwire.OutPoint]struct{}{}, FeeIncrement: defaultFeeIncrement, rescanAddJob: make(chan *RescanJob), rescanBatch: make(chan *rescanBatch), rescanNotifications: make(chan interface{}), rescanProgress: make(chan *RescanProgressMsg), rescanFinished: make(chan *RescanFinishedMsg), createTxRequests: make(chan createTxRequest), unlockRequests: make(chan unlockRequest), lockRequests: make(chan struct{}), holdUnlockRequests: make(chan chan HeldUnlock), lockState: make(chan bool), changePassphrase: make(chan changePassphraseRequest), notificationLock: new(sync.Mutex), quit: make(chan struct{}), } } // ErrDuplicateListen is returned for any attempts to listen for the same // notification more than once. If callers must pass along a notifiation to // multiple places, they must broadcast it themself. var ErrDuplicateListen = errors.New("duplicate listen") func (w *Wallet) updateNotificationLock() { switch { case w.connectedBlocks == nil: fallthrough case w.disconnectedBlocks == nil: fallthrough case w.lockStateChanges == nil: fallthrough case w.confirmedBalance == nil: fallthrough case w.unconfirmedBalance == nil: return } w.notificationLock = noopLocker{} } // ListenConnectedBlocks returns a channel that passes all blocks that a wallet // has been marked in sync with. The channel must be read, or other wallet // methods will block. // // If this is called twice, ErrDuplicateListen is returned. func (w *Wallet) ListenConnectedBlocks() (<-chan keystore.BlockStamp, error) { w.notificationLock.Lock() defer w.notificationLock.Unlock() if w.connectedBlocks != nil { return nil, ErrDuplicateListen } w.connectedBlocks = make(chan keystore.BlockStamp) w.updateNotificationLock() return w.connectedBlocks, nil } // ListenDisconnectedBlocks returns a channel that passes all blocks that a // wallet has detached. The channel must be read, or other wallet methods will // block. // // If this is called twice, ErrDuplicateListen is returned. func (w *Wallet) ListenDisconnectedBlocks() (<-chan keystore.BlockStamp, error) { w.notificationLock.Lock() defer w.notificationLock.Unlock() if w.disconnectedBlocks != nil { return nil, ErrDuplicateListen } w.disconnectedBlocks = make(chan keystore.BlockStamp) w.updateNotificationLock() return w.disconnectedBlocks, nil } // ListenDisconnectedBlocks returns a channel that passes the current lock state // of the wallet keystore anytime the keystore is locked or unlocked. The value // is true for locked, and false for unlocked. The channel must be read, or // other wallet methods will block. // // If this is called twice, ErrDuplicateListen is returned. func (w *Wallet) ListenKeystoreLockStatus() (<-chan bool, error) { w.notificationLock.Lock() defer w.notificationLock.Unlock() if w.lockStateChanges != nil { return nil, ErrDuplicateListen } w.lockStateChanges = make(chan bool) w.updateNotificationLock() return w.lockStateChanges, nil } // ListenConfirmedBalance returns a channel that passes the confirmed balance // when any changes to the balance are made. This channel must be read, or // other wallet methods will block. // // If this is called twice, ErrDuplicateListen is returned. func (w *Wallet) ListenConfirmedBalance() (<-chan btcutil.Amount, error) { w.notificationLock.Lock() defer w.notificationLock.Unlock() if w.confirmedBalance != nil { return nil, ErrDuplicateListen } w.confirmedBalance = make(chan btcutil.Amount) w.updateNotificationLock() return w.confirmedBalance, nil } // ListenUnconfirmedBalance returns a channel that passes the unconfirmed // balance when any changes to the balance are made. This channel must be // read, or other wallet methods will block. // // If this is called twice, ErrDuplicateListen is returned. func (w *Wallet) ListenUnconfirmedBalance() (<-chan btcutil.Amount, error) { w.notificationLock.Lock() defer w.notificationLock.Unlock() if w.unconfirmedBalance != nil { return nil, ErrDuplicateListen } w.unconfirmedBalance = make(chan btcutil.Amount) w.updateNotificationLock() return w.unconfirmedBalance, nil } func (w *Wallet) notifyConnectedBlock(block keystore.BlockStamp) { w.notificationLock.Lock() if w.connectedBlocks != nil { w.connectedBlocks <- block } w.notificationLock.Unlock() } func (w *Wallet) notifyDisconnectedBlock(block keystore.BlockStamp) { w.notificationLock.Lock() if w.disconnectedBlocks != nil { w.disconnectedBlocks <- block } w.notificationLock.Unlock() } func (w *Wallet) notifyLockStateChange(locked bool) { w.notificationLock.Lock() if w.lockStateChanges != nil { w.lockStateChanges <- locked } w.notificationLock.Unlock() } func (w *Wallet) notifyConfirmedBalance(bal btcutil.Amount) { w.notificationLock.Lock() if w.confirmedBalance != nil { w.confirmedBalance <- bal } w.notificationLock.Unlock() } func (w *Wallet) notifyUnconfirmedBalance(bal btcutil.Amount) { w.notificationLock.Lock() if w.unconfirmedBalance != nil { w.unconfirmedBalance <- bal } w.notificationLock.Unlock() } // openWallet opens a new wallet from disk. func openWallet() (*Wallet, error) { netdir := networkDir(activeNet.Params) // Ensure that the network directory exists. // TODO: move this? if err := checkCreateDir(netdir); err != nil { return nil, err } // Read key and transaction stores. keys, err := keystore.OpenDir(netdir) var txs *txstore.Store if err == nil { txs, err = txstore.OpenDir(netdir) } if err != nil { // Special case: if the keystore was successfully read // (keys != nil) but the transaction store was not, create a // new txstore and write it out to disk. Write an unsynced // wallet back to disk so on future opens, the empty txstore // is not considered fully synced. if keys == nil { return nil, err } txs = txstore.New(netdir) txs.MarkDirty() err = txs.WriteIfDirty() if err != nil { return nil, err } keys.SetSyncedWith(nil) keys.MarkDirty() err = keys.WriteIfDirty() if err != nil { return nil, err } } log.Infof("Opened wallet files") // TODO: log balance? last sync height? return newWallet(keys, txs), nil } // newEncryptedWallet creates a new wallet encrypted with the provided // passphrase. func newEncryptedWallet(passphrase []byte, chainSvr *chain.Client) (*Wallet, error) { // Get current block's height and hash. bs, err := chainSvr.BlockStamp() if err != nil { return nil, err } // Create new wallet in memory. keys, err := keystore.New(networkDir(activeNet.Params), "Default acccount", passphrase, activeNet.Params, bs) if err != nil { return nil, err } w := newWallet(keys, txstore.New(networkDir(activeNet.Params))) return w, nil } // Start starts the goroutines necessary to manage a wallet. func (w *Wallet) Start(chainServer *chain.Client) { select { case <-w.quit: return default: } w.chainSvrLock.Lock() defer w.chainSvrLock.Unlock() w.chainSvr = chainServer w.chainSvrLock = noopLocker{} w.wg.Add(7) go w.diskWriter() go w.handleChainNotifications() go w.txCreator() go w.keystoreLocker() go w.rescanBatchHandler() go w.rescanProgressHandler() go w.rescanRPCHandler() go func() { err := w.syncWithChain() if err != nil && !w.ShuttingDown() { log.Warnf("Unable to synchronize wallet to chain: %v", err) } }() } // Stop signals all wallet goroutines to shutdown. func (w *Wallet) Stop() { select { case <-w.quit: default: close(w.quit) w.chainSvrLock.Lock() if w.chainSvr != nil { w.chainSvr.Stop() } w.chainSvrLock.Unlock() } } // ShuttingDown returns whether the wallet is currently in the process of // shutting down or not. func (w *Wallet) ShuttingDown() bool { select { case <-w.quit: return true default: return false } } // WaitForShutdown blocks until all wallet goroutines have finished executing. func (w *Wallet) WaitForShutdown() { w.chainSvrLock.Lock() if w.chainSvr != nil { w.chainSvr.WaitForShutdown() } w.chainSvrLock.Unlock() w.wg.Wait() } // ChainSynced returns whether the wallet has been attached to a chain server // and synced up to the best block on the main chain. func (w *Wallet) ChainSynced() bool { select { case <-w.chainSynced: return true default: return false } } // WaitForChainSync blocks until a wallet has been synced with the main chain // of an attached chain server. func (w *Wallet) WaitForChainSync() { <-w.chainSynced } // SynchedChainTip returns the hash and height of the block of the most // recently seen block in the main chain. It returns errors if the // wallet has not yet been marked as synched with the chain. func (w *Wallet) SyncedChainTip() (*keystore.BlockStamp, error) { select { case <-w.chainSynced: return w.chainSvr.BlockStamp() default: return nil, ErrNotSynced } } func (w *Wallet) syncWithChain() (err error) { defer func() { if err == nil { // Request notifications for connected and disconnected // blocks. err = w.chainSvr.NotifyBlocks() } }() // TODO(jrick): How should this handle a synced height earlier than // the chain server best block? // Check that there was not any reorgs done since last connection. // If so, rollback and rescan to catch up. iter := w.KeyStore.NewIterateRecentBlocks() for cont := iter != nil; cont; cont = iter.Prev() { bs := iter.BlockStamp() log.Debugf("Checking for previous saved block with height %v hash %v", bs.Height, bs.Hash) if _, err := w.chainSvr.GetBlock(bs.Hash); err != nil { continue } log.Debug("Found matching block.") // If we had to go back to any previous blocks (iter.Next // returns true), then rollback the next and all child blocks. if iter.Next() { bs := iter.BlockStamp() w.KeyStore.SetSyncedWith(&bs) err = w.TxStore.Rollback(bs.Height) if err != nil { return } w.TxStore.MarkDirty() } break } return w.RescanActiveAddresses() } type ( createTxRequest struct { pairs map[string]btcutil.Amount minconf int resp chan createTxResponse } createTxResponse struct { tx *CreatedTx err error } ) // txCreator is responsible for the input selection and creation of // transactions. These functions are the responsibility of this method // (designed to be run as its own goroutine) since input selection must be // serialized, or else it is possible to create double spends by choosing the // same inputs for multiple transactions. Along with input selection, this // method is also responsible for the signing of transactions, since we don't // want to end up in a situation where we run out of inputs as multiple // transactions are being created. In this situation, it would then be possible // for both requests, rather than just one, to fail due to not enough available // inputs. func (w *Wallet) txCreator() { out: for { select { case txr := <-w.createTxRequests: tx, err := w.txToPairs(txr.pairs, txr.minconf) txr.resp <- createTxResponse{tx, err} case <-w.quit: break out } } w.wg.Done() } func (w *Wallet) CreateSimpleTx(pairs map[string]btcutil.Amount, minconf int) (*CreatedTx, error) { req := createTxRequest{ pairs: pairs, minconf: minconf, resp: make(chan createTxResponse), } w.createTxRequests <- req resp := <-req.resp return resp.tx, resp.err } type ( unlockRequest struct { passphrase []byte timeout time.Duration // Zero value prevents the timeout. err chan error } changePassphraseRequest struct { old, new []byte err chan error } HeldUnlock chan struct{} ) // keystoreLocker manages the locked/unlocked state of a wallet. func (w *Wallet) keystoreLocker() { var timeout <-chan time.Time holdChan := make(HeldUnlock) out: for { select { case req := <-w.unlockRequests: err := w.KeyStore.Unlock(req.passphrase) if err != nil { req.err <- err continue } w.notifyLockStateChange(false) if req.timeout == 0 { timeout = nil } else { timeout = time.After(req.timeout) } req.err <- nil continue case req := <-w.changePassphrase: // Changing the passphrase requires an unlocked // keystore, and for the old passphrase to be correct. // Lock the keystore and unlock with the old passphase // check its validity. _ = w.KeyStore.Lock() w.notifyLockStateChange(true) timeout = nil err := w.KeyStore.Unlock(req.old) if err == nil { w.notifyLockStateChange(false) err = w.KeyStore.ChangePassphrase(req.new) } req.err <- err continue case req := <-w.holdUnlockRequests: if w.KeyStore.IsLocked() { close(req) continue } req <- holdChan <-holdChan // Block until the lock is released. // If, after holding onto the unlocked wallet for some // time, the timeout has expired, lock it now instead // of hoping it gets unlocked next time the top level // select runs. select { case <-timeout: // Let the top level select fallthrough so the // wallet is locked. default: continue } case w.lockState <- w.KeyStore.IsLocked(): continue case <-w.quit: break out case <-w.lockRequests: case <-timeout: } // Select statement fell through by an explicit lock or the // timer expiring. Lock the keystores here. timeout = nil if err := w.KeyStore.Lock(); err != nil { log.Errorf("Could not lock wallet: %v", err) } w.notifyLockStateChange(true) } w.wg.Done() } // Unlock unlocks the wallet's keystore and locks the wallet again after // timeout has expired. If the wallet is already unlocked and the new // passphrase is correct, the current timeout is replaced with the new one. func (w *Wallet) Unlock(passphrase []byte, timeout time.Duration) error { err := make(chan error, 1) w.unlockRequests <- unlockRequest{ passphrase: passphrase, timeout: timeout, err: err, } return <-err } // Lock locks the wallet's keystore. func (w *Wallet) Lock() { w.lockRequests <- struct{}{} } // Locked returns whether the keystore for a wallet is locked. func (w *Wallet) Locked() bool { return <-w.lockState } // HoldUnlock prevents the wallet from being locked, func (w *Wallet) HoldUnlock() (HeldUnlock, error) { req := make(chan HeldUnlock) w.holdUnlockRequests <- req hl, ok := <-req if !ok { return nil, keystore.ErrLocked } return hl, nil } // Release releases the hold on the unlocked-state of the wallet and allows the // wallet to be locked again. If a lock timeout has already expired, the // wallet is locked again as soon as Release is called. func (c HeldUnlock) Release() { c <- struct{}{} } // ChangePassphrase attempts to change the passphrase for a wallet from old // to new. Changing the passphrase is synchronized with all other keystore // locking and unlocking, and will result in a locked wallet on success. func (w *Wallet) ChangePassphrase(old, new []byte) error { err := make(chan error, 1) w.changePassphrase <- changePassphraseRequest{ old: old, new: new, err: err, } return <-err } // diskWriter periodically (every 10 seconds) writes out the key and transaction // stores to disk if they are marked dirty. On shutdown, func (w *Wallet) diskWriter() { ticker := time.NewTicker(10 * time.Second) var wg sync.WaitGroup var done bool for { select { case <-ticker.C: case <-w.quit: done = true } log.Trace("Writing wallet files") wg.Add(2) go func() { err := w.KeyStore.WriteIfDirty() if err != nil { log.Errorf("Cannot write keystore: %v", err) } wg.Done() }() go func() { err := w.TxStore.WriteIfDirty() if err != nil { log.Errorf("Cannot write txstore: %v", err) } wg.Done() }() wg.Wait() if done { break } } w.wg.Done() } // AddressUsed returns whether there are any recorded transactions spending to // a given address. Assumming correct TxStore usage, this will return true iff // there are any transactions with outputs to this address in the blockchain or // the btcd mempool. func (w *Wallet) AddressUsed(addr btcutil.Address) bool { // This not only can be optimized by recording this data as it is // read when opening a wallet, and keeping it up to date each time a // new received tx arrives, but it probably should in case an address is // used in a tx (made public) but the tx is eventually removed from the // store (consider a chain reorg). for _, r := range w.TxStore.Records() { for _, c := range r.Credits() { // Errors don't matter here. If addrs is nil, the // range below does nothing. _, addrs, _, _ := c.Addresses(activeNet.Params) for _, a := range addrs { if addr.String() == a.String() { return true } } } } return false } // CalculateBalance sums the amounts of all unspent transaction // outputs to addresses of a wallet and returns the balance. // // If confirmations is 0, all UTXOs, even those not present in a // block (height -1), will be used to get the balance. Otherwise, // a UTXO must be in a block. If confirmations is 1 or greater, // the balance will be calculated based on how many how many blocks // include a UTXO. func (w *Wallet) CalculateBalance(confirms int) (btcutil.Amount, error) { bs, err := w.SyncedChainTip() if err != nil { return 0, err } return w.TxStore.Balance(confirms, bs.Height) } // CurrentAddress gets the most recently requested Bitcoin payment address // from a wallet. If the address has already been used (there is at least // one transaction spending to it in the blockchain or btcd mempool), the next // chained address is returned. func (w *Wallet) CurrentAddress() (btcutil.Address, error) { addr := w.KeyStore.LastChainedAddress() // Get next chained address if the last one has already been used. if w.AddressUsed(addr) { return w.NewAddress() } return addr, nil } // ListSinceBlock returns a slice of objects with details about transactions // since the given block. If the block is -1 then all transactions are included. // This is intended to be used for listsinceblock RPC replies. func (w *Wallet) ListSinceBlock(since, curBlockHeight int32, minconf int) ([]btcjson.ListTransactionsResult, error) { txList := []btcjson.ListTransactionsResult{} for _, txRecord := range w.TxStore.Records() { // Transaction records must only be considered if they occur // after the block height since. if since != -1 && txRecord.BlockHeight <= since { continue } // Transactions that have not met minconf confirmations are to // be ignored. if !txRecord.Confirmed(minconf, curBlockHeight) { continue } jsonResults, err := txRecord.ToJSON("", curBlockHeight, w.KeyStore.Net()) if err != nil { return nil, err } txList = append(txList, jsonResults...) } return txList, nil } // ListTransactions returns a slice of objects with details about a recorded // transaction. This is intended to be used for listtransactions RPC // replies. func (w *Wallet) ListTransactions(from, count int) ([]btcjson.ListTransactionsResult, error) { txList := []btcjson.ListTransactionsResult{} // Get current block. The block height used for calculating // the number of tx confirmations. bs, err := w.SyncedChainTip() if err != nil { return txList, err } records := w.TxStore.Records() lastLookupIdx := len(records) - count // Search in reverse order: lookup most recently-added first. for i := len(records) - 1; i >= from && i >= lastLookupIdx; i-- { jsonResults, err := records[i].ToJSON("", bs.Height, w.KeyStore.Net()) if err != nil { return nil, err } txList = append(txList, jsonResults...) } return txList, nil } // ListAddressTransactions returns a slice of objects with details about // recorded transactions to or from any address belonging to a set. This is // intended to be used for listaddresstransactions RPC replies. func (w *Wallet) ListAddressTransactions(pkHashes map[string]struct{}) ( []btcjson.ListTransactionsResult, error) { txList := []btcjson.ListTransactionsResult{} // Get current block. The block height used for calculating // the number of tx confirmations. bs, err := w.SyncedChainTip() if err != nil { return txList, err } for _, r := range w.TxStore.Records() { for _, c := range r.Credits() { // We only care about the case where len(addrs) == 1, // and err will never be non-nil in that case. _, addrs, _, _ := c.Addresses(activeNet.Params) if len(addrs) != 1 { continue } apkh, ok := addrs[0].(*btcutil.AddressPubKeyHash) if !ok { continue } if _, ok := pkHashes[string(apkh.ScriptAddress())]; !ok { continue } jsonResult, err := c.ToJSON("", bs.Height, w.KeyStore.Net()) if err != nil { return nil, err } txList = append(txList, jsonResult) } } return txList, nil } // ListAllTransactions returns a slice of objects with details about a recorded // transaction. This is intended to be used for listalltransactions RPC // replies. func (w *Wallet) ListAllTransactions() ([]btcjson.ListTransactionsResult, error) { txList := []btcjson.ListTransactionsResult{} // Get current block. The block height used for calculating // the number of tx confirmations. bs, err := w.SyncedChainTip() if err != nil { return txList, err } // Search in reverse order: lookup most recently-added first. records := w.TxStore.Records() for i := len(records) - 1; i >= 0; i-- { jsonResults, err := records[i].ToJSON("", bs.Height, w.KeyStore.Net()) if err != nil { return nil, err } txList = append(txList, jsonResults...) } return txList, nil } // ListUnspent returns a slice of objects representing the unspent wallet // transactions fitting the given criteria. The confirmations will be more than // minconf, less than maxconf and if addresses is populated only the addresses // contained within it will be considered. If we know nothing about a // transaction an empty array will be returned. func (w *Wallet) ListUnspent(minconf, maxconf int, addresses map[string]bool) ([]*btcjson.ListUnspentResult, error) { results := []*btcjson.ListUnspentResult{} bs, err := w.SyncedChainTip() if err != nil { return results, err } filter := len(addresses) != 0 unspent, err := w.TxStore.SortedUnspentOutputs() if err != nil { return nil, err } for _, credit := range unspent { confs := credit.Confirmations(bs.Height) if int(confs) < minconf || int(confs) > maxconf { continue } if credit.IsCoinbase() { if !credit.Confirmed(btcchain.CoinbaseMaturity, bs.Height) { continue } } if w.LockedOutpoint(*credit.OutPoint()) { continue } _, addrs, _, _ := credit.Addresses(activeNet.Params) if filter { for _, addr := range addrs { _, ok := addresses[addr.EncodeAddress()] if ok { goto include } } continue } include: result := &btcjson.ListUnspentResult{ TxId: credit.Tx().Sha().String(), Vout: credit.OutputIndex, Account: "", ScriptPubKey: hex.EncodeToString(credit.TxOut().PkScript), Amount: credit.Amount().ToUnit(btcutil.AmountBTC), Confirmations: int64(confs), } // BUG: this should be a JSON array so that all // addresses can be included, or removed (and the // caller extracts addresses from the pkScript). if len(addrs) > 0 { result.Address = addrs[0].EncodeAddress() } results = append(results, result) } return results, nil } // DumpPrivKeys returns the WIF-encoded private keys for all addresses with // private keys in a wallet. func (w *Wallet) DumpPrivKeys() ([]string, error) { // Iterate over each active address, appending the private // key to privkeys. privkeys := []string{} for _, info := range w.KeyStore.ActiveAddresses() { // Only those addresses with keys needed. pka, ok := info.(keystore.PubKeyAddress) if !ok { continue } wif, err := pka.ExportPrivKey() if err != nil { // It would be nice to zero out the array here. However, // since strings in go are immutable, and we have no // control over the caller I don't think we can. :( return nil, err } privkeys = append(privkeys, wif.String()) } return privkeys, nil } // DumpWIFPrivateKey returns the WIF encoded private key for a // single wallet address. func (w *Wallet) DumpWIFPrivateKey(addr btcutil.Address) (string, error) { // Get private key from wallet if it exists. address, err := w.KeyStore.Address(addr) if err != nil { return "", err } pka, ok := address.(keystore.PubKeyAddress) if !ok { return "", fmt.Errorf("address %s is not a key type", addr) } wif, err := pka.ExportPrivKey() if err != nil { return "", err } return wif.String(), nil } // ImportPrivateKey imports a private key to the wallet and writes the new // wallet to disk. func (w *Wallet) ImportPrivateKey(wif *btcutil.WIF, bs *keystore.BlockStamp, rescan bool) (string, error) { // Attempt to import private key into wallet. addr, err := w.KeyStore.ImportPrivateKey(wif, bs) if err != nil { return "", err } // Immediately write wallet to disk. w.KeyStore.MarkDirty() if err := w.KeyStore.WriteIfDirty(); err != nil { return "", fmt.Errorf("cannot write key: %v", err) } // Rescan blockchain for transactions with txout scripts paying to the // imported address. if rescan { job := &RescanJob{ Addrs: []btcutil.Address{addr}, OutPoints: nil, BlockStamp: keystore.BlockStamp{ Hash: activeNet.Params.GenesisHash, Height: 0, }, } // Submit rescan job and log when the import has completed. // Do not block on finishing the rescan. The rescan success // or failure is logged elsewhere, and the channel is not // required to be read, so discard the return value. _ = w.SubmitRescan(job) } addrStr := addr.EncodeAddress() log.Infof("Imported payment address %s", addrStr) // Return the payment address string of the imported private key. return addrStr, nil } // ExportWatchingWallet returns the watching-only copy of a wallet. Both wallets // share the same tx store, so locking one will lock the other as well. The // returned wallet should be serialized and exported quickly, and then dropped // from scope. func (w *Wallet) ExportWatchingWallet() (*Wallet, error) { ww, err := w.KeyStore.ExportWatchingWallet() if err != nil { return nil, err } wa := *w wa.KeyStore = ww return &wa, nil } // exportBase64 exports a wallet's serialized key, and tx stores as // base64-encoded values in a map. func (w *Wallet) exportBase64() (map[string]string, error) { buf := bytes.Buffer{} m := make(map[string]string) _, err := w.KeyStore.WriteTo(&buf) if err != nil { return nil, err } m["wallet"] = base64.StdEncoding.EncodeToString(buf.Bytes()) buf.Reset() if _, err = w.TxStore.WriteTo(&buf); err != nil { return nil, err } m["tx"] = base64.StdEncoding.EncodeToString(buf.Bytes()) buf.Reset() return m, nil } // LockedOutpoint returns whether an outpoint has been marked as locked and // should not be used as an input for created transactions. func (w *Wallet) LockedOutpoint(op btcwire.OutPoint) bool { _, locked := w.lockedOutpoints[op] return locked } // LockOutpoint marks an outpoint as locked, that is, it should not be used as // an input for newly created transactions. func (w *Wallet) LockOutpoint(op btcwire.OutPoint) { w.lockedOutpoints[op] = struct{}{} } // UnlockOutpoint marks an outpoint as unlocked, that is, it may be used as an // input for newly created transactions. func (w *Wallet) UnlockOutpoint(op btcwire.OutPoint) { delete(w.lockedOutpoints, op) } // ResetLockedOutpoints resets the set of locked outpoints so all may be used // as inputs for new transactions. func (w *Wallet) ResetLockedOutpoints() { w.lockedOutpoints = map[btcwire.OutPoint]struct{}{} } // LockedOutpoints returns a slice of currently locked outpoints. This is // intended to be used by marshaling the result as a JSON array for // listlockunspent RPC results. func (w *Wallet) LockedOutpoints() []btcjson.TransactionInput { locked := make([]btcjson.TransactionInput, len(w.lockedOutpoints)) i := 0 for op := range w.lockedOutpoints { locked[i] = btcjson.TransactionInput{ Txid: op.Hash.String(), Vout: op.Index, } i++ } return locked } // Track requests btcd to send notifications of new transactions for // each address stored in a wallet. func (w *Wallet) Track() { // Request notifications for transactions sending to all wallet // addresses. // // TODO: return as slice? (doesn't have to be ordered, or // SortedActiveAddresses would be fine.) addrMap := w.KeyStore.ActiveAddresses() addrs := make([]btcutil.Address, len(addrMap)) i := 0 for addr := range addrMap { addrs[i] = addr i++ } if err := w.chainSvr.NotifyReceived(addrs); err != nil { log.Error("Unable to request transaction updates for address.") } unspent, err := w.TxStore.UnspentOutputs() if err != nil { log.Errorf("Unable to access unspent outputs: %v", err) return } w.ReqSpentUtxoNtfns(unspent) } // ResendUnminedTxs iterates through all transactions that spend from wallet // credits that are not known to have been mined into a block, and attempts // to send each to the chain server for relay. func (w *Wallet) ResendUnminedTxs() { txs := w.TxStore.UnminedDebitTxs() for _, tx := range txs { _, err := w.chainSvr.SendRawTransaction(tx.MsgTx(), false) if err != nil { // TODO(jrick): Check error for if this tx is a double spend, // remove it if so. log.Debugf("Could not resend transaction %v: %v", tx.Sha(), err) continue } log.Debugf("Resent unmined transaction %v", tx.Sha()) } } // SortedActivePaymentAddresses returns a slice of all active payment // addresses in a wallet. func (w *Wallet) SortedActivePaymentAddresses() []string { infos := w.KeyStore.SortedActiveAddresses() addrs := make([]string, len(infos)) for i, info := range infos { addrs[i] = info.Address().EncodeAddress() } return addrs } // NewAddress returns the next chained address for a wallet. func (w *Wallet) NewAddress() (btcutil.Address, error) { // Get current block's height and hash. bs, err := w.SyncedChainTip() if err != nil { return nil, err } // Get next address from wallet. addr, err := w.KeyStore.NextChainedAddress(bs) if err != nil { return nil, err } // Immediately write updated wallet to disk. w.KeyStore.MarkDirty() if err := w.KeyStore.WriteIfDirty(); err != nil { return nil, fmt.Errorf("key write failed: %v", err) } // Request updates from btcd for new transactions sent to this address. if err := w.chainSvr.NotifyReceived([]btcutil.Address{addr}); err != nil { return nil, err } return addr, nil } // NewChangeAddress returns a new change address for a wallet. func (w *Wallet) NewChangeAddress() (btcutil.Address, error) { // Get current block's height and hash. bs, err := w.SyncedChainTip() if err != nil { return nil, err } // Get next chained change address from wallet. addr, err := w.KeyStore.ChangeAddress(bs) if err != nil { return nil, err } // Immediately write updated wallet to disk. w.KeyStore.MarkDirty() if err := w.KeyStore.WriteIfDirty(); err != nil { return nil, fmt.Errorf("key write failed: %v", err) } // Request updates from btcd for new transactions sent to this address. if err := w.chainSvr.NotifyReceived([]btcutil.Address{addr}); err != nil { return nil, err } return addr, nil } // RecoverAddresses recovers the next n chained addresses of a wallet. func (w *Wallet) RecoverAddresses(n int) error { // Get info on the last chained address. The rescan starts at the // earliest block height the last chained address might appear at. last := w.KeyStore.LastChainedAddress() lastInfo, err := w.KeyStore.Address(last) if err != nil { return err } addrs, err := w.KeyStore.ExtendActiveAddresses(n) if err != nil { return err } // Determine the block necesary to start the rescan. height := lastInfo.FirstBlock() // TODO: fix our "synced to block" handling (either in // keystore or txstore, or elsewhere) so this *always* // returns the block hash. Looking it up by height is // asking for problems. hash, err := w.chainSvr.GetBlockHash(int64(height)) if err != nil { return err } // Run a goroutine to rescan blockchain for recovered addresses. job := &RescanJob{ Addrs: addrs, OutPoints: nil, BlockStamp: keystore.BlockStamp{ Hash: hash, Height: height, }, } // Begin rescan and do not wait for it to finish. Because the success // or failure of the rescan is logged elsewhere and the returned channel // does not need to be read, ignore the return value. _ = w.SubmitRescan(job) return nil } // ReqSpentUtxoNtfns sends a message to btcd to request updates for when // a stored UTXO has been spent. func (w *Wallet) ReqSpentUtxoNtfns(credits []txstore.Credit) { ops := make([]*btcwire.OutPoint, len(credits)) for i, c := range credits { op := c.OutPoint() log.Debugf("Requesting spent UTXO notifications for Outpoint "+ "hash %s index %d", op.Hash, op.Index) ops[i] = op } if err := w.chainSvr.NotifySpent(ops); err != nil { log.Errorf("Cannot request notifications for spent outputs: %v", err) } } // TotalReceived iterates through a wallet's transaction history, returning the // total amount of bitcoins received for any wallet address. Amounts received // through multisig transactions are ignored. func (w *Wallet) TotalReceived(confirms int) (btcutil.Amount, error) { bs, err := w.SyncedChainTip() if err != nil { return 0, err } var amount btcutil.Amount for _, r := range w.TxStore.Records() { for _, c := range r.Credits() { // Ignore change. if c.Change() { continue } // Tally if the appropiate number of block confirmations have passed. if c.Confirmed(confirms, bs.Height) { amount += c.Amount() } } } return amount, nil } // TxRecord iterates through all transaction records saved in the store, // returning the first with an equivalent transaction hash. func (w *Wallet) TxRecord(txSha *btcwire.ShaHash) (r *txstore.TxRecord, ok bool) { for _, r = range w.TxStore.Records() { if *r.Tx().Sha() == *txSha { return r, true } } return nil, false }