/* * 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" "crypto/ecdsa" "encoding/base64" "encoding/hex" "encoding/json" "errors" "fmt" "github.com/conformal/btcec" "github.com/conformal/btcjson" "github.com/conformal/btcscript" "github.com/conformal/btcutil" "github.com/conformal/btcwallet/txstore" "github.com/conformal/btcwallet/wallet" "github.com/conformal/btcwire" "github.com/conformal/btcws" "sync" "time" ) // Error types to simplify the reporting of specific categories of // errors, and their btcjson.Error creation. type ( // DeserializationError describes a failed deserializaion due to bad // user input. It cooresponds to btcjson.ErrDeserialization. DeserializationError struct { error } // InvalidParameterError describes an invalid parameter passed by // the user. It cooresponds to btcjson.ErrInvalidParameter. InvalidParameterError struct { error } // ParseError describes a failed parse due to bad user input. It // cooresponds to btcjson.ErrParse. ParseError struct { error } // InvalidAddressOrKeyError describes a parse, network mismatch, or // missing address error when decoding or validating an address or // key. It cooresponds to btcjson.ErrInvalidAddressOrKey. InvalidAddressOrKeyError struct { error } ) // Errors variables that are defined once here to avoid duplication below. var ( ErrNeedPositiveAmount = InvalidParameterError{ errors.New("amount must be positive"), } ErrNeedPositiveMinconf = InvalidParameterError{ errors.New("minconf must be positive"), } ErrAddressNotInWallet = InvalidAddressOrKeyError{ errors.New("address not found in wallet"), } ) // cmdHandler is a handler function to handle an unmarshaled and parsed // request into a marshalable response. If the error is a btcjson.Error // or any of the above special error classes, the server will respond with // the JSON-RPC appropiate error code. All other errors use the wallet // catch-all error code, btcjson.ErrWallet.Code. type cmdHandler func(btcjson.Cmd) (interface{}, error) var rpcHandlers = map[string]cmdHandler{ // Standard bitcoind methods (implemented) "addmultisigaddress": AddMultiSigAddress, "createmultisig": CreateMultiSig, "dumpprivkey": DumpPrivKey, "getaccount": GetAccount, "getaccountaddress": GetAccountAddress, "getaddressesbyaccount": GetAddressesByAccount, "getbalance": GetBalance, "getinfo": GetInfo, "getnewaddress": GetNewAddress, "getrawchangeaddress": GetRawChangeAddress, "getreceivedbyaccount": GetReceivedByAccount, "gettransaction": GetTransaction, "importprivkey": ImportPrivKey, "keypoolrefill": KeypoolRefill, "listaccounts": ListAccounts, "listsinceblock": ListSinceBlock, "listtransactions": ListTransactions, "listunspent": ListUnspent, "sendfrom": SendFrom, "sendmany": SendMany, "sendtoaddress": SendToAddress, "settxfee": SetTxFee, "signmessage": SignMessage, "signrawtransaction": SignRawTransaction, "validateaddress": ValidateAddress, "verifymessage": VerifyMessage, "walletlock": WalletLock, "walletpassphrase": WalletPassphrase, "walletpassphrasechange": WalletPassphraseChange, // Standard bitcoind methods (currently unimplemented) "backupwallet": Unimplemented, "dumpwallet": Unimplemented, "getblocktemplate": Unimplemented, "getreceivedbyaddress": Unimplemented, "gettxout": Unimplemented, "gettxoutsetinfo": Unimplemented, "getwork": Unimplemented, "importwallet": Unimplemented, "listaddressgroupings": Unimplemented, "listlockunspent": Unimplemented, "listreceivedbyaccount": Unimplemented, "listreceivedbyaddress": Unimplemented, "lockunspent": Unimplemented, "move": Unimplemented, "setaccount": Unimplemented, "stop": Unimplemented, // Standard bitcoind methods which won't be implemented by btcwallet. "encryptwallet": Unsupported, // Extensions not exclusive to websocket connections. "createencryptedwallet": CreateEncryptedWallet, } // Extensions exclusive to websocket connections. var wsHandlers = map[string]cmdHandler{ "exportwatchingwallet": ExportWatchingWallet, "getaddressbalance": GetAddressBalance, "getunconfirmedbalance": GetUnconfirmedBalance, "listaddresstransactions": ListAddressTransactions, "listalltransactions": ListAllTransactions, "recoveraddresses": RecoverAddresses, "walletislocked": WalletIsLocked, } // Channels to control RPCGateway var ( // Incoming requests from frontends clientRequests = make(chan *ClientRequest) // Incoming notifications from a bitcoin server (btcd) svrNtfns = make(chan btcjson.Cmd) ) // ErrServerBusy is a custom JSON-RPC error for when a client's request // could not be added to the server request queue for handling. var ErrServerBusy = btcjson.Error{ Code: -32000, Message: "Server busy", } // ErrServerBusyRaw is the raw JSON encoding of ErrServerBusy. var ErrServerBusyRaw = json.RawMessage(`{"code":-32000,"message":"Server busy"}`) // RPCGateway is the common entry point for all client RPC requests and // server notifications. If a request needs to be handled by btcwallet, // it is sent to WalletRequestProcessor's request queue, or dropped if the // queue is full. If a request is unhandled, it is recreated with a new // JSON-RPC id and sent to btcd for handling. Notifications are also queued // if they cannot be immediately handled, but are never dropped (queue may // grow infinitely large). func RPCGateway() { var ntfnQueue []btcjson.Cmd unreadChan := make(chan btcjson.Cmd) for { var ntfnOut chan btcjson.Cmd var oldestNtfn btcjson.Cmd if len(ntfnQueue) > 0 { ntfnOut = handleNtfn oldestNtfn = ntfnQueue[0] } else { ntfnOut = unreadChan } select { case r := <-clientRequests: // Check whether to handle request or send to btcd. _, std := rpcHandlers[r.request.Method()] _, ext := wsHandlers[r.request.Method()] if std || ext { select { case requestQueue <- r: default: // Server busy with too many requests. resp := RawRPCResponse{ Error: &ErrServerBusyRaw, } r.response <- resp } } else { r.request.SetId(<-NewJSONID) request := &ServerRequest{ request: r.request, response: r.response, } CurrentServerConn().SendRequest(request) } case n := <-svrNtfns: ntfnQueue = append(ntfnQueue, n) case ntfnOut <- oldestNtfn: ntfnQueue = ntfnQueue[1:] } } } // Channels to control WalletRequestProcessor var ( requestQueue = make(chan *ClientRequest, 100) handleNtfn = make(chan btcjson.Cmd) ) // WalletRequestProcessor processes client requests and btcd notifications. func WalletRequestProcessor() { for { select { case r := <-requestQueue: method := r.request.Method() f, ok := rpcHandlers[method] if !ok && r.ws { f, ok = wsHandlers[method] } if !ok { f = Unimplemented } AcctMgr.Grab() result, err := f(r.request) AcctMgr.Release() if err != nil { jsonErr := btcjson.Error{Message: err.Error()} switch e := err.(type) { case btcjson.Error: jsonErr = e case DeserializationError: jsonErr.Code = btcjson.ErrDeserialization.Code case InvalidParameterError: jsonErr.Code = btcjson.ErrInvalidParameter.Code case ParseError: jsonErr.Code = btcjson.ErrParse.Code case InvalidAddressOrKeyError: jsonErr.Code = btcjson.ErrInvalidAddressOrKey.Code default: // All other errors get the wallet error code. jsonErr.Code = btcjson.ErrWallet.Code } b, err := json.Marshal(jsonErr) // Marshal should only fail if jsonErr contains // vars of an non-mashalable type, which would // indicate a source code issue with btcjson. if err != nil { panic(err) } r.response <- RawRPCResponse{ Error: (*json.RawMessage)(&b), } continue } b, err := json.Marshal(result) // Marshal should only fail if result contains vars of // an unmashalable type. This may indicate an bug with // the calle RPC handler, and should be logged. if err != nil { log.Errorf("Cannot marshal result: %v", err) } r.response <- RawRPCResponse{ Result: (*json.RawMessage)(&b), } case n := <-handleNtfn: f, ok := notificationHandlers[n.Method()] if !ok { // Ignore unhandled notifications. continue } AcctMgr.Grab() err := f(n) AcctMgr.Release() switch err { case txstore.ErrInconsistentStore: // Assume this is a broken btcd reordered // notifications. Restart the connection // to reload accounts files from their last // known good state. log.Warn("Reconnecting to recover from " + "out-of-order btcd notification") s := CurrentServerConn() if btcd, ok := s.(*BtcdRPCConn); ok { AcctMgr.Grab() btcd.Close() AcctMgr.OpenAccounts() AcctMgr.Release() } case nil: // ignore default: log.Warn(err) } } } } // Unimplemented handles an unimplemented RPC request with the // appropiate error. func Unimplemented(icmd btcjson.Cmd) (interface{}, error) { return nil, btcjson.ErrUnimplemented } // Unsupported handles a standard bitcoind RPC request which is // unsupported by btcwallet due to design differences. func Unsupported(icmd btcjson.Cmd) (interface{}, error) { return nil, btcjson.Error{ Code: -1, Message: "Request unsupported by btcwallet", } } // makeMultiSigScript is a heper function to combine common logic for // AddMultiSig and CreateMultiSig. // all error codes are rpc parse error here to match bitcoind which just throws // a runtime exception. *sigh*. func makeMultiSigScript(keys []string, nRequired int) ([]byte, error) { keysesPrecious := make([]*btcutil.AddressPubKey, len(keys)) // The address list will made up either of addreseses (pubkey hash), for // which we need to look up the keys in wallet, straight pubkeys, or a // mixture of the two. for i, a := range keys { // try to parse as pubkey address a, err := btcutil.DecodeAddress(a, activeNet.Params) if err != nil { return nil, err } switch addr := a.(type) { case *btcutil.AddressPubKey: keysesPrecious[i] = addr case *btcutil.AddressPubKeyHash: ainfo, err := AcctMgr.Address(addr) if err != nil { return nil, err } apkinfo := ainfo.(wallet.PubKeyAddress) // This will be an addresspubkey a, err := btcutil.DecodeAddress(apkinfo.ExportPubKey(), activeNet.Params) if err != nil { return nil, err } apk := a.(*btcutil.AddressPubKey) keysesPrecious[i] = apk default: return nil, err } } return btcscript.MultiSigScript(keysesPrecious, nRequired) } // AddMultiSigAddress handles an addmultisigaddress request by adding a // multisig address to the given wallet. func AddMultiSigAddress(icmd btcjson.Cmd) (interface{}, error) { cmd, ok := icmd.(*btcjson.AddMultisigAddressCmd) if !ok { return nil, btcjson.ErrInternal } acct, err := AcctMgr.Account(cmd.Account) if err != nil { if err == ErrNotFound { return nil, btcjson.ErrWalletInvalidAccountName } return nil, err } script, err := makeMultiSigScript(cmd.Keys, cmd.NRequired) if err != nil { return nil, ParseError{err} } // TODO(oga) blockstamp current block? address, err := acct.ImportScript(script, &wallet.BlockStamp{}) if err != nil { return nil, err } return address.EncodeAddress(), nil } // CreateMultiSig handles an createmultisig request by returning a // multisig address for the given inputs. func CreateMultiSig(icmd btcjson.Cmd) (interface{}, error) { cmd, ok := icmd.(*btcjson.CreateMultisigCmd) if !ok { return nil, btcjson.ErrInternal } script, err := makeMultiSigScript(cmd.Keys, cmd.NRequired) if err != nil { return nil, ParseError{err} } address, err := btcutil.NewAddressScriptHash(script, activeNet.Params) if err != nil { // above is a valid script, shouldn't happen. return nil, err } return btcjson.CreateMultiSigResult{ Address: address.EncodeAddress(), RedeemScript: hex.EncodeToString(script), }, nil } // DumpPrivKey handles a dumpprivkey request with the private key // for a single address, or an appropiate error if the wallet // is locked. func DumpPrivKey(icmd btcjson.Cmd) (interface{}, error) { // Type assert icmd to access parameters. cmd, ok := icmd.(*btcjson.DumpPrivKeyCmd) if !ok { return nil, btcjson.ErrInternal } addr, err := btcutil.DecodeAddress(cmd.Address, activeNet.Params) if err != nil { return nil, btcjson.ErrInvalidAddressOrKey } key, err := AcctMgr.DumpWIFPrivateKey(addr) if err == wallet.ErrWalletLocked { // Address was found, but the private key isn't // accessible. return nil, btcjson.ErrWalletUnlockNeeded } return key, err } // DumpWallet handles a dumpwallet request by returning all private // keys in a wallet, or an appropiate error if the wallet is locked. // TODO: finish this to match bitcoind by writing the dump to a file. func DumpWallet(icmd btcjson.Cmd) (interface{}, error) { // Type assert icmd to access parameters. _, ok := icmd.(*btcjson.DumpWalletCmd) if !ok { return nil, btcjson.ErrInternal } keys, err := AcctMgr.DumpKeys() if err == wallet.ErrWalletLocked { // Address was found, but the private key isn't // accessible. return nil, btcjson.ErrWalletUnlockNeeded } return keys, err } // ExportWatchingWallet handles an exportwatchingwallet request by exporting // the current account wallet as a watching wallet (with no private keys), and // either writing the exported wallet to disk, or base64-encoding serialized // account files and sending them back in the response. func ExportWatchingWallet(icmd btcjson.Cmd) (interface{}, error) { // Type assert icmd to access parameters. cmd, ok := icmd.(*btcws.ExportWatchingWalletCmd) if !ok { return nil, btcjson.ErrInternal } a, err := AcctMgr.Account(cmd.Account) if err != nil { if err == ErrNotFound { return nil, btcjson.ErrWalletInvalidAccountName } return nil, err } wa, err := a.ExportWatchingWallet() if err != nil { return nil, err } if cmd.Download { return wa.exportBase64() } // Create export directory, write files there. err = wa.ExportToDirectory("watchingwallet") return nil, err } // GetAddressesByAccount handles a getaddressesbyaccount request by returning // all addresses for an account, or an error if the requested account does // not exist. func GetAddressesByAccount(icmd btcjson.Cmd) (interface{}, error) { // Type assert icmd to access parameters. cmd, ok := icmd.(*btcjson.GetAddressesByAccountCmd) if !ok { return nil, btcjson.ErrInternal } a, err := AcctMgr.Account(cmd.Account) if err != nil { if err == ErrNotFound { return nil, btcjson.ErrWalletInvalidAccountName } return nil, err } return a.SortedActivePaymentAddresses(), nil } // GetBalance handles a getbalance request by returning the balance for an // account (wallet), or an error if the requested account does not // exist. func GetBalance(icmd btcjson.Cmd) (interface{}, error) { // Type assert icmd to access parameters. cmd, ok := icmd.(*btcjson.GetBalanceCmd) if !ok { return nil, btcjson.ErrInternal } balance, err := AcctMgr.CalculateBalance(cmd.Account, cmd.MinConf) if err == ErrNotFound { return nil, btcjson.ErrWalletInvalidAccountName } return balance, err } // GetInfo handles a getinfo request by returning the a structure containing // information about the current state of btcwallet. // exist. func GetInfo(icmd btcjson.Cmd) (interface{}, error) { // Call down to btcd for all of the information in this command known // by them. This call is expected to always succeed. gicmd, err := btcjson.NewGetInfoCmd(<-NewJSONID) if err != nil { panic(err) } response := <-CurrentServerConn().SendRequest(NewServerRequest(gicmd)) var info btcjson.InfoResult _, jsonErr := response.FinishUnmarshal(&info) if jsonErr != nil { return nil, jsonErr } balance := float64(0.0) accounts := AcctMgr.ListAccounts(1) for _, v := range accounts { balance += v } info.WalletVersion = int(wallet.VersCurrent.Uint32()) info.Balance = balance // Keypool times are not tracked. set to current time. info.KeypoolOldest = time.Now().Unix() info.KeypoolSize = int(cfg.KeypoolSize) TxFeeIncrement.Lock() info.PaytxFee = float64(TxFeeIncrement.i) / float64(btcutil.SatoshiPerBitcoin) TxFeeIncrement.Unlock() /* * We don't set the following since they don't make much sense in the * wallet architecture: * - unlocked_until * - errors */ return info, nil } // GetAccount handles a getaccount request by returning the account name // associated with a single address. func GetAccount(icmd btcjson.Cmd) (interface{}, error) { // Type assert icmd to access parameters. cmd, ok := icmd.(*btcjson.GetAccountCmd) if !ok { return nil, btcjson.ErrInternal } // Is address valid? addr, err := btcutil.DecodeAddress(cmd.Address, activeNet.Params) if err != nil || !addr.IsForNet(activeNet.Params) { return nil, btcjson.ErrInvalidAddressOrKey } // Look up account which holds this address. acct, err := AcctMgr.AccountByAddress(addr) if err != nil { if err == ErrNotFound { return nil, ErrAddressNotInWallet } return nil, err } return acct.Name(), nil } // GetAccountAddress handles a getaccountaddress by returning the most // recently-created chained address that has not yet been used (does not yet // appear in the blockchain, or any tx that has arrived in the btcd mempool). // If the most recently-requested address has been used, a new address (the // next chained address in the keypool) is used. This can fail if the keypool // runs out (and will return btcjson.ErrWalletKeypoolRanOut if that happens). func GetAccountAddress(icmd btcjson.Cmd) (interface{}, error) { // Type assert icmd to access parameters. cmd, ok := icmd.(*btcjson.GetAccountAddressCmd) if !ok { return nil, btcjson.ErrInternal } // Lookup account for this request. a, err := AcctMgr.Account(cmd.Account) if err != nil { if err == ErrNotFound { return nil, btcjson.ErrWalletInvalidAccountName } return nil, err } addr, err := a.CurrentAddress() if err != nil { if err == wallet.ErrWalletLocked { return nil, btcjson.ErrWalletKeypoolRanOut } return nil, err } return addr.EncodeAddress(), err } // GetAddressBalance handles a getaddressbalance extension request by // returning the current balance (sum of unspent transaction output amounts) // for a single address. func GetAddressBalance(icmd btcjson.Cmd) (interface{}, error) { // Type assert icmd to access parameters. cmd, ok := icmd.(*btcws.GetAddressBalanceCmd) if !ok { return nil, btcjson.ErrInternal } // Is address valid? addr, err := btcutil.DecodeAddress(cmd.Address, activeNet.Params) if err != nil { return nil, btcjson.ErrInvalidAddressOrKey } // Get the account which holds the address in the request. a, err := AcctMgr.AccountByAddress(addr) if err != nil { return nil, ErrAddressNotInWallet } return a.CalculateAddressBalance(addr, int(cmd.Minconf)), nil } // GetUnconfirmedBalance handles a getunconfirmedbalance extension request // by returning the current unconfirmed balance of an account. func GetUnconfirmedBalance(icmd btcjson.Cmd) (interface{}, error) { // Type assert icmd to access parameters. cmd, ok := icmd.(*btcws.GetUnconfirmedBalanceCmd) if !ok { return nil, btcjson.ErrInternal } // Get the account included in the request. a, err := AcctMgr.Account(cmd.Account) if err != nil { if err == ErrNotFound { return nil, btcjson.ErrWalletInvalidAccountName } return nil, err } return a.CalculateBalance(0) - a.CalculateBalance(1), nil } // ImportPrivKey handles an importprivkey request by parsing // a WIF-encoded private key and adding it to an account. func ImportPrivKey(icmd btcjson.Cmd) (interface{}, error) { // Type assert icmd to access parameters. cmd, ok := icmd.(*btcjson.ImportPrivKeyCmd) if !ok { return nil, btcjson.ErrInternal } // Get the acount included in the request. Yes, Label is the // account name... a, err := AcctMgr.Account(cmd.Label) if err != nil { if err == ErrNotFound { return nil, btcjson.ErrWalletInvalidAccountName } return nil, err } wif, err := btcutil.DecodeWIF(cmd.PrivKey) if err != nil || !wif.IsForNet(activeNet.Params) { return nil, btcjson.ErrInvalidAddressOrKey } // Import the private key, handling any errors. bs := wallet.BlockStamp{} if _, err := a.ImportPrivateKey(wif, &bs, cmd.Rescan); err != nil { switch err { case wallet.ErrDuplicate: // Do not return duplicate key errors to the client. return nil, nil case wallet.ErrWalletLocked: return nil, btcjson.ErrWalletUnlockNeeded default: return nil, err } } // If the import was successful, reply with nil. return nil, nil } // KeypoolRefill handles the keypoolrefill command. Since we handle the keypool // automatically this does nothing since refilling is never manually required. func KeypoolRefill(icmd btcjson.Cmd) (interface{}, error) { return nil, nil } // NotifyBalances notifies an attached frontend of the current confirmed // and unconfirmed account balances. // // TODO(jrick): Switch this to return a single JSON object // (map[string]interface{}) of all accounts and their balances, instead of // separate notifications for each account. func NotifyBalances(frontend chan []byte) { AcctMgr.NotifyBalances(frontend) } // GetNewAddress handlesa getnewaddress request by returning a new // address for an account. If the account does not exist or the keypool // ran out with a locked wallet, an appropiate error is returned. func GetNewAddress(icmd btcjson.Cmd) (interface{}, error) { // Type assert icmd to access parameters. cmd, ok := icmd.(*btcjson.GetNewAddressCmd) if !ok { return nil, btcjson.ErrInternal } a, err := AcctMgr.Account(cmd.Account) if err != nil { if err == ErrNotFound { return nil, btcjson.ErrWalletInvalidAccountName } return nil, err } addr, err := a.NewAddress() if err != nil { return nil, err } // Return the new payment address string. return addr.EncodeAddress(), nil } // GetRawChangeAddress handles a getrawchangeaddress request by creating // and returning a new change address for an account. // // Note: bitcoind allows specifying the account as an optional parameter, // but ignores the parameter. func GetRawChangeAddress(icmd btcjson.Cmd) (interface{}, error) { cmd, ok := icmd.(*btcjson.GetRawChangeAddressCmd) if !ok { return nil, btcjson.ErrInternal } a, err := AcctMgr.Account(cmd.Account) if err != nil { if err == ErrNotFound { return nil, btcjson.ErrWalletInvalidAccountName } return nil, err } addr, err := a.NewChangeAddress() if err != nil { return nil, err } // Return the new payment address string. return addr.EncodeAddress(), nil } // GetReceivedByAccount handles a getreceivedbyaccount request by returning // the total amount received by addresses of an account. func GetReceivedByAccount(icmd btcjson.Cmd) (interface{}, error) { cmd, ok := icmd.(*btcjson.GetReceivedByAccountCmd) if !ok { return nil, btcjson.ErrInternal } a, err := AcctMgr.Account(cmd.Account) if err != nil { if err == ErrNotFound { return nil, btcjson.ErrWalletInvalidAccountName } return nil, err } return a.TotalReceived(cmd.MinConf) } // GetTransaction handles a gettransaction request by returning details about // a single transaction saved by wallet. func GetTransaction(icmd btcjson.Cmd) (interface{}, error) { // Type assert icmd to access parameters. cmd, ok := icmd.(*btcjson.GetTransactionCmd) if !ok { return nil, btcjson.ErrInternal } txSha, err := btcwire.NewShaHashFromStr(cmd.Txid) if err != nil { return nil, btcjson.ErrDecodeHexString } accumulatedTxen := AcctMgr.GetTransaction(txSha) if len(accumulatedTxen) == 0 { return nil, btcjson.ErrNoTxInfo } bs, err := GetCurBlock() if err != nil { return nil, err } received := btcutil.Amount(0) var debitTx *txstore.TxRecord var debitAccount string var targetAddr string ret := btcjson.GetTransactionResult{ Details: []btcjson.GetTransactionDetailsResult{}, WalletConflicts: []string{}, } details := []btcjson.GetTransactionDetailsResult{} for _, e := range accumulatedTxen { for _, cred := range e.Tx.Credits() { // Change is ignored. if cred.Change() { continue } received += cred.Amount() var addr string // Errors don't matter here, as we only consider the // case where len(addrs) == 1. _, addrs, _, _ := cred.Addresses(activeNet.Params) if len(addrs) == 1 { addr = addrs[0].EncodeAddress() // The first non-change output address is considered the // target for sent transactions. if targetAddr == "" { targetAddr = addr } } details = append(details, btcjson.GetTransactionDetailsResult{ Account: e.Account, Category: cred.Category(bs.Height).String(), Amount: cred.Amount().ToUnit(btcutil.AmountBTC), Address: addr, }) } if e.Tx.Debits() != nil { // There should only be a single debits record for any // of the account's transaction records. debitTx = e.Tx debitAccount = e.Account } } totalAmount := received if debitTx != nil { debits := debitTx.Debits() totalAmount -= debits.InputAmount() info := btcjson.GetTransactionDetailsResult{ Account: debitAccount, Address: targetAddr, Category: "send", // negative since it is a send Amount: (-debits.OutputAmount(true)).ToUnit(btcutil.AmountBTC), Fee: debits.Fee().ToUnit(btcutil.AmountBTC), } ret.Fee += info.Fee // Add sent information to front. ret.Details = append(ret.Details, info) } ret.Details = append(ret.Details, details...) ret.Amount = totalAmount.ToUnit(btcutil.AmountBTC) // Generic information should be the same, so just use the first one. first := accumulatedTxen[0] ret.TxID = first.Tx.Tx().Sha().String() buf := bytes.NewBuffer(nil) buf.Grow(first.Tx.Tx().MsgTx().SerializeSize()) err = first.Tx.Tx().MsgTx().Serialize(buf) if err != nil { return nil, err } ret.Hex = hex.EncodeToString(buf.Bytes()) // TODO(oga) technically we have different time and // timereceived depending on if a transaction was send or // receive. We ideally should provide the correct numbers for // both. Right now they will always be the same ret.Time = first.Tx.Received().Unix() ret.TimeReceived = first.Tx.Received().Unix() if txr := first.Tx; txr.BlockHeight != -1 { txBlock, err := txr.Block() if err != nil { return nil, err } ret.BlockIndex = int64(first.Tx.Tx().Index()) ret.BlockHash = txBlock.Hash.String() ret.BlockTime = txBlock.Time.Unix() ret.Confirmations = int64(txr.Confirmations(bs.Height)) } // TODO(oga) if the tx is a coinbase we should set "generated" to true. // Since we do not mine this currently is never the case. return ret, nil } // ListAccounts handles a listaccounts request by returning a map of account // names to their balances. func ListAccounts(icmd btcjson.Cmd) (interface{}, error) { // Type assert icmd to access parameters. cmd, ok := icmd.(*btcjson.ListAccountsCmd) if !ok { return nil, btcjson.ErrInternal } // Return the map. This will be marshaled into a JSON object. return AcctMgr.ListAccounts(cmd.MinConf), nil } // ListSinceBlock handles a listsinceblock request by returning an array of maps // with details of sent and received wallet transactions since the given block. func ListSinceBlock(icmd btcjson.Cmd) (interface{}, error) { cmd, ok := icmd.(*btcjson.ListSinceBlockCmd) if !ok { return nil, btcjson.ErrInternal } height := int32(-1) if cmd.BlockHash != "" { br, err := GetBlock(CurrentServerConn(), cmd.BlockHash) if err != nil { return nil, err } height = int32(br.Height) } bs, err := GetCurBlock() if err != nil { return nil, err } // For the result we need the block hash for the last block counted // in the blockchain due to confirmations. We send this off now so that // it can arrive asynchronously while we figure out the rest. gbh, err := btcjson.NewGetBlockHashCmd(<-NewJSONID, int64(bs.Height)+1-int64(cmd.TargetConfirmations)) if err != nil { return nil, err } bhChan := CurrentServerConn().SendRequest(NewServerRequest(gbh)) txInfoList, err := AcctMgr.ListSinceBlock(height, bs.Height, cmd.TargetConfirmations) if err != nil { return nil, err } // Done with work, get the response. response := <-bhChan var hash string _, err = response.FinishUnmarshal(&hash) if err != nil { return nil, err } res := btcjson.ListSinceBlockResult{ Transactions: txInfoList, LastBlock: hash, } return res, nil } // ListTransactions handles a listtransactions request by returning an // array of maps with details of sent and recevied wallet transactions. func ListTransactions(icmd btcjson.Cmd) (interface{}, error) { // Type assert icmd to access parameters. cmd, ok := icmd.(*btcjson.ListTransactionsCmd) if !ok { return nil, btcjson.ErrInternal } a, err := AcctMgr.Account(cmd.Account) if err != nil { if err == ErrNotFound { return nil, btcjson.ErrWalletInvalidAccountName } return nil, err } return a.ListTransactions(cmd.From, cmd.Count) } // ListAddressTransactions handles a listaddresstransactions request by // returning an array of maps with details of spent and received wallet // transactions. The form of the reply is identical to listtransactions, // but the array elements are limited to transaction details which are // about the addresess included in the request. func ListAddressTransactions(icmd btcjson.Cmd) (interface{}, error) { // Type assert icmd to access parameters. cmd, ok := icmd.(*btcws.ListAddressTransactionsCmd) if !ok { return nil, btcjson.ErrInternal } a, err := AcctMgr.Account(cmd.Account) if err != nil { if err == ErrNotFound { return nil, btcjson.ErrWalletInvalidAccountName } return nil, err } // Decode addresses. pkHashMap := make(map[string]struct{}) for _, addrStr := range cmd.Addresses { addr, err := btcutil.DecodeAddress(addrStr, activeNet.Params) if err != nil { return nil, btcjson.ErrInvalidAddressOrKey } apkh, ok := addr.(*btcutil.AddressPubKeyHash) if !ok || !apkh.IsForNet(activeNet.Params) { return nil, btcjson.ErrInvalidAddressOrKey } pkHashMap[string(addr.ScriptAddress())] = struct{}{} } return a.ListAddressTransactions(pkHashMap) } // ListAllTransactions handles a listalltransactions request by returning // a map with details of sent and recevied wallet transactions. This is // similar to ListTransactions, except it takes only a single optional // argument for the account name and replies with all transactions. func ListAllTransactions(icmd btcjson.Cmd) (interface{}, error) { // Type assert icmd to access parameters. cmd, ok := icmd.(*btcws.ListAllTransactionsCmd) if !ok { return nil, btcjson.ErrInternal } a, err := AcctMgr.Account(cmd.Account) if err != nil { if err == ErrNotFound { return nil, btcjson.ErrWalletInvalidAccountName } return nil, err } return a.ListAllTransactions() } // ListUnspent handles the listunspent command. func ListUnspent(icmd btcjson.Cmd) (interface{}, error) { cmd, ok := icmd.(*btcjson.ListUnspentCmd) if !ok { return nil, btcjson.ErrInternal } addresses := make(map[string]bool) if len(cmd.Addresses) != 0 { // confirm that all of them are good: for _, as := range cmd.Addresses { a, err := btcutil.DecodeAddress(as, activeNet.Params) if err != nil { return nil, btcjson.ErrInvalidAddressOrKey } if _, ok := addresses[a.EncodeAddress()]; ok { // duplicate return nil, btcjson.ErrInvalidParameter } addresses[a.EncodeAddress()] = true } } return AcctMgr.ListUnspent(cmd.MinConf, cmd.MaxConf, addresses) } // sendPairs is a helper routine to reduce duplicated code when creating and // sending payment transactions. func sendPairs(icmd btcjson.Cmd, account string, amounts map[string]btcutil.Amount, minconf int) (interface{}, error) { // Check that the account specified in the request exists. a, err := AcctMgr.Account(account) if err != nil { return nil, btcjson.ErrWalletInvalidAccountName } // Create transaction, replying with an error if the creation // was not successful. createdTx, err := a.txToPairs(amounts, minconf) if err != nil { switch err { case ErrNonPositiveAmount: return nil, ErrNeedPositiveAmount case wallet.ErrWalletLocked: return nil, btcjson.ErrWalletUnlockNeeded default: return nil, err } } // Mark txid as having send history so handlers adding receive history // wait until all send history has been written. SendTxHistSyncChans.add <- *createdTx.tx.Sha() // If a change address was added, sync wallet to disk and request // transaction notifications to the change address. if createdTx.changeAddr != nil { AcctMgr.ds.ScheduleWalletWrite(a) if err := AcctMgr.ds.FlushAccount(a); err != nil { return nil, fmt.Errorf("Cannot write account: %v", err) } a.ReqNewTxsForAddress(createdTx.changeAddr) } serializedTx := bytes.NewBuffer(nil) serializedTx.Grow(createdTx.tx.MsgTx().SerializeSize()) if err := createdTx.tx.MsgTx().Serialize(serializedTx); err != nil { // Hitting OOM writing to a bytes.Buffer already panics, and // all other errors are unexpected. panic(err) } hextx := hex.EncodeToString(serializedTx.Bytes()) txSha, err := SendRawTransaction(CurrentServerConn(), hextx) if err != nil { SendTxHistSyncChans.remove <- *createdTx.tx.Sha() return nil, err } return handleSendRawTxReply(icmd, txSha, a, createdTx) } // SendFrom handles a sendfrom RPC request by creating a new transaction // spending unspent transaction outputs for a wallet to another payment // address. Leftover inputs not sent to the payment address or a fee for // the miner are sent back to a new address in the wallet. Upon success, // the TxID for the created transaction is returned. func SendFrom(icmd btcjson.Cmd) (interface{}, error) { // Type assert icmd to access parameters. cmd, ok := icmd.(*btcjson.SendFromCmd) if !ok { return nil, btcjson.ErrInternal } // Check that signed integer parameters are positive. if cmd.Amount < 0 { return nil, ErrNeedPositiveAmount } if cmd.MinConf < 0 { return nil, ErrNeedPositiveMinconf } // Create map of address and amount pairs. pairs := map[string]btcutil.Amount{ cmd.ToAddress: btcutil.Amount(cmd.Amount), } return sendPairs(cmd, cmd.FromAccount, pairs, cmd.MinConf) } // SendMany handles a sendmany RPC request by creating a new transaction // spending unspent transaction outputs for a wallet to any number of // payment addresses. Leftover inputs not sent to the payment address // or a fee for the miner are sent back to a new address in the wallet. // Upon success, the TxID for the created transaction is returned. func SendMany(icmd btcjson.Cmd) (interface{}, error) { // Type assert icmd to access parameters. cmd, ok := icmd.(*btcjson.SendManyCmd) if !ok { return nil, btcjson.ErrInternal } // Check that minconf is positive. if cmd.MinConf < 0 { return nil, ErrNeedPositiveMinconf } // Recreate address/amount pairs, using btcutil.Amount. pairs := make(map[string]btcutil.Amount, len(cmd.Amounts)) for k, v := range cmd.Amounts { pairs[k] = btcutil.Amount(v) } return sendPairs(cmd, cmd.FromAccount, pairs, cmd.MinConf) } // SendToAddress handles a sendtoaddress RPC request by creating a new // transaction spending unspent transaction outputs for a wallet to another // payment address. Leftover inputs not sent to the payment address or a fee // for the miner are sent back to a new address in the wallet. Upon success, // the TxID for the created transaction is returned. func SendToAddress(icmd btcjson.Cmd) (interface{}, error) { // Type assert icmd to access parameters. cmd, ok := icmd.(*btcjson.SendToAddressCmd) if !ok { return nil, btcjson.ErrInternal } // Check that signed integer parameters are positive. if cmd.Amount < 0 { return nil, ErrNeedPositiveAmount } // Mock up map of address and amount pairs. pairs := map[string]btcutil.Amount{ cmd.Address: btcutil.Amount(cmd.Amount), } return sendPairs(cmd, "", pairs, 1) } // Channels to manage SendBeforeReceiveHistorySync. var SendTxHistSyncChans = struct { add, done, remove chan btcwire.ShaHash access chan SendTxHistSyncRequest }{ add: make(chan btcwire.ShaHash), remove: make(chan btcwire.ShaHash), done: make(chan btcwire.ShaHash), access: make(chan SendTxHistSyncRequest), } // SendTxHistSyncRequest requests a SendTxHistSyncResponse from // SendBeforeReceiveHistorySync. type SendTxHistSyncRequest struct { txsha btcwire.ShaHash response chan SendTxHistSyncResponse } // SendTxHistSyncResponse is the response type SendTxHistSyncResponse struct { c chan struct{} ok bool } // SendBeforeReceiveHistorySync manages a set of transaction hashes // created by this wallet. For each newly added txsha, a channel is // created. Once the send history has been recorded, the txsha should // be messaged across done, causing the internal channel to be closed. // Before receive history is recorded, access should be used to check // if there are or were any goroutines writing send history, and if // so, wait until the channel is closed after a done message. func SendBeforeReceiveHistorySync(add, done, remove chan btcwire.ShaHash, access chan SendTxHistSyncRequest) { m := make(map[btcwire.ShaHash]chan struct{}) for { select { case txsha := <-add: m[txsha] = make(chan struct{}) case txsha := <-remove: delete(m, txsha) case txsha := <-done: if c, ok := m[txsha]; ok { close(c) } case req := <-access: c, ok := m[req.txsha] req.response <- SendTxHistSyncResponse{c: c, ok: ok} } } } func handleSendRawTxReply(icmd btcjson.Cmd, txIDStr string, a *Account, txInfo *CreatedTx) (interface{}, error) { // Add to transaction store. txr, err := a.TxStore.InsertTx(txInfo.tx, nil) if err != nil { log.Errorf("Error adding sent tx history: %v", err) return nil, btcjson.ErrInternal } debits, err := txr.AddDebits(txInfo.inputs) if err != nil { log.Errorf("Error adding sent tx history: %v", err) return nil, btcjson.ErrInternal } AcctMgr.ds.ScheduleTxStoreWrite(a) // Notify frontends of new SendTx. bs, err := GetCurBlock() if err == nil { ltr, err := debits.ToJSON(a.Name(), bs.Height, a.Net()) if err != nil { log.Errorf("Error adding sent tx history: %v", err) return nil, btcjson.ErrInternal } for _, details := range ltr { NotifyNewTxDetails(allClients, a.Name(), details) } } // Signal that received notifiations are ok to add now. SendTxHistSyncChans.done <- *txInfo.tx.Sha() // Disk sync tx and utxo stores. if err := AcctMgr.ds.FlushAccount(a); err != nil { log.Errorf("Cannot write account: %v", err) return nil, err } // Notify all frontends of account's new unconfirmed and // confirmed balance. confirmed := a.CalculateBalance(1) unconfirmed := a.CalculateBalance(0) - confirmed NotifyWalletBalance(allClients, a.name, confirmed) NotifyWalletBalanceUnconfirmed(allClients, a.name, unconfirmed) // The comments to be saved differ based on the underlying type // of the cmd, so switch on the type to check whether it is a // SendFromCmd or SendManyCmd. // // TODO(jrick): If message succeeded in being sent, save the // transaction details with comments. switch cmd := icmd.(type) { case *btcjson.SendFromCmd: _ = cmd.Comment _ = cmd.CommentTo case *btcjson.SendManyCmd: _ = cmd.Comment case *btcjson.SendToAddressCmd: _ = cmd.Comment _ = cmd.CommentTo } log.Infof("Successfully sent transaction %v", txIDStr) return txIDStr, nil } // SetTxFee sets the transaction fee per kilobyte added to transactions. func SetTxFee(icmd btcjson.Cmd) (interface{}, error) { // Type assert icmd to access parameters. cmd, ok := icmd.(*btcjson.SetTxFeeCmd) if !ok { return nil, btcjson.ErrInternal } // Check that amount is not negative. if cmd.Amount < 0 { return nil, ErrNeedPositiveAmount } // Set global tx fee. TxFeeIncrement.Lock() TxFeeIncrement.i = btcutil.Amount(cmd.Amount) TxFeeIncrement.Unlock() // A boolean true result is returned upon success. return true, nil } // SignMessage signs the given message with the private key for the given // address func SignMessage(icmd btcjson.Cmd) (interface{}, error) { // Type assert icmd to access parameters. cmd, ok := icmd.(*btcjson.SignMessageCmd) if !ok { return nil, btcjson.ErrInternal } addr, err := btcutil.DecodeAddress(cmd.Address, activeNet.Params) if err != nil { return nil, ParseError{err} } ainfo, err := AcctMgr.Address(addr) if err != nil { return nil, btcjson.ErrInvalidAddressOrKey } pka := ainfo.(wallet.PubKeyAddress) privkey, err := pka.PrivKey() if err != nil { return nil, err } fullmsg := "Bitcoin Signed Message:\n" + cmd.Message sigbytes, err := btcec.SignCompact(btcec.S256(), privkey, btcwire.DoubleSha256([]byte(fullmsg)), ainfo.Compressed()) if err != nil { return nil, err } return base64.StdEncoding.EncodeToString(sigbytes), nil } // CreateEncryptedWallet creates a new account with an encrypted // wallet. If an account with the same name as the requested account // name already exists, an invalid account name error is returned to // the client. // // Wallets will be created on TestNet3, or MainNet if btcwallet is run with // the --mainnet option. func CreateEncryptedWallet(icmd btcjson.Cmd) (interface{}, error) { // Type assert icmd to access parameters. cmd, ok := icmd.(*btcws.CreateEncryptedWalletCmd) if !ok { return nil, btcjson.ErrInternal } err := AcctMgr.CreateEncryptedWallet([]byte(cmd.Passphrase)) if err != nil { if err == ErrWalletExists { return nil, btcjson.ErrWalletInvalidAccountName } return nil, err } // A nil reply is sent upon successful wallet creation. return nil, nil } // RecoverAddresses recovers the next n addresses from an account's wallet. func RecoverAddresses(icmd btcjson.Cmd) (interface{}, error) { cmd, ok := icmd.(*btcws.RecoverAddressesCmd) if !ok { return nil, btcjson.ErrInternal } a, err := AcctMgr.Account(cmd.Account) if err != nil { if err == ErrNotFound { return nil, btcjson.ErrWalletInvalidAccountName } return nil, err } err = a.RecoverAddresses(cmd.N) return nil, err } // pendingTx is used for async fetching of transaction dependancies in // SignRawTransaction. type pendingTx struct { resp chan RawRPCResponse inputs []uint32 // list of inputs that care about this tx. } // SignRawTransaction handles the signrawtransaction command. func SignRawTransaction(icmd btcjson.Cmd) (interface{}, error) { cmd, ok := icmd.(*btcjson.SignRawTransactionCmd) if !ok { return nil, btcjson.ErrInternal } serializedTx, err := hex.DecodeString(cmd.RawTx) if err != nil { return nil, btcjson.ErrDecodeHexString } msgTx := btcwire.NewMsgTx() err = msgTx.Deserialize(bytes.NewBuffer(serializedTx)) if err != nil { e := errors.New("TX decode failed") return nil, DeserializationError{e} } // First we add the stuff we have been given. // TODO(oga) really we probably should look these up with btcd anyway // to make sure that they match the blockchain if present. inputs := make(map[btcwire.OutPoint][]byte) scripts := make(map[string][]byte) for _, rti := range cmd.Inputs { inputSha, err := btcwire.NewShaHashFromStr(rti.Txid) if err != nil { return nil, DeserializationError{err} } script, err := hex.DecodeString(rti.ScriptPubKey) if err != nil { return nil, DeserializationError{err} } // redeemScript is only actually used iff the user provided // private keys. In which case, it is used to get the scripts // for signing. If the user did not provide keys then we always // get scripts from the wallet. // Empty strings are ok for this one and hex.DecodeString will // DTRT. if len(cmd.PrivKeys) != 0 { redeemScript, err := hex.DecodeString(rti.RedeemScript) if err != nil { return nil, DeserializationError{err} } addr, err := btcutil.NewAddressScriptHash(redeemScript, activeNet.Params) if err != nil { return nil, DeserializationError{err} } scripts[addr.String()] = redeemScript } inputs[btcwire.OutPoint{ Hash: *inputSha, Index: uint32(rti.Vout), }] = script } // Now we go and look for any inputs that we were not provided by // querying btcd with getrawtransaction. We queue up a bunch of async // requests and will wait for replies after we have checked the rest of // the arguments. requested := make(map[btcwire.ShaHash]*pendingTx) for _, txIn := range msgTx.TxIn { // Did we get this txin from the arguments? if _, ok := inputs[txIn.PreviousOutpoint]; ok { continue } // Are we already fetching this tx? If so mark us as interested // in this outpoint. (N.B. that any *sane* tx will only // reference each outpoint once, since anything else is a double // spend. We don't check this ourselves to save having to scan // the array, it will fail later if so). if ptx, ok := requested[txIn.PreviousOutpoint.Hash]; ok { ptx.inputs = append(ptx.inputs, txIn.PreviousOutpoint.Index) continue } // Never heard of this one before, request it. requested[txIn.PreviousOutpoint.Hash] = &pendingTx{ resp: GetRawTransactionAsync(CurrentServerConn(), &txIn.PreviousOutpoint.Hash), inputs: []uint32{txIn.PreviousOutpoint.Index}, } } // Parse list of private keys, if present. If there are any keys here // they are the keys that we may use for signing. If empty we will // use any keys known to us already. var keys map[string]*btcutil.WIF if len(cmd.PrivKeys) != 0 { keys = make(map[string]*btcutil.WIF) for _, key := range cmd.PrivKeys { wif, err := btcutil.DecodeWIF(key) if err != nil { return nil, DeserializationError{err} } if !wif.IsForNet(activeNet.Params) { s := "key network doesn't match wallet's" return nil, DeserializationError{errors.New(s)} } addr, err := btcutil.NewAddressPubKey(wif.SerializePubKey(), activeNet.Params) if err != nil { return nil, DeserializationError{err} } keys[addr.EncodeAddress()] = wif } } hashType := btcscript.SigHashAll if cmd.Flags != "" { switch cmd.Flags { case "ALL": hashType = btcscript.SigHashAll case "NONE": hashType = btcscript.SigHashNone case "SINGLE": hashType = btcscript.SigHashSingle case "ALL|ANYONECANPAY": hashType = btcscript.SigHashAll | btcscript.SigHashAnyOneCanPay case "NONE|ANYONECANPAY": hashType = btcscript.SigHashNone | btcscript.SigHashAnyOneCanPay case "SINGLE|ANYONECANPAY": hashType = btcscript.SigHashSingle | btcscript.SigHashAnyOneCanPay default: e := errors.New("Invalid sighash parameter") return nil, InvalidParameterError{e} } } // We have checked the rest of the args. now we can collect the async // txs. TODO(oga) If we don't mind the possibility of wasting work we // could move waiting to the following loop and be slightly more // asynchronous. for txid, ptx := range requested { tx, err := GetRawTransactionAsyncResult(ptx.resp) if err != nil { return nil, err } for _, input := range ptx.inputs { if input >= uint32(len(tx.MsgTx().TxOut)) { e := fmt.Errorf("input %s:%d is not in tx", txid.String(), input) return nil, InvalidParameterError{e} } inputs[btcwire.OutPoint{ Hash: txid, Index: input, }] = tx.MsgTx().TxOut[input].PkScript } } // All args collected. Now we can sign all the inputs that we can. // `complete' denotes that we successfully signed all outputs and that // all scripts will run to completion. This is returned as part of the // reply. complete := true for i, txIn := range msgTx.TxIn { input, ok := inputs[txIn.PreviousOutpoint] if !ok { // failure to find previous is actually an error since // we failed above if we don't have all the inputs. return nil, fmt.Errorf("%s:%d not found", txIn.PreviousOutpoint.Hash, txIn.PreviousOutpoint.Index) } // Set up our callbacks that we pass to btcscript so it can // look up the appropriate keys and scripts by address. getKey := btcscript.KeyClosure(func(addr btcutil.Address) ( *ecdsa.PrivateKey, bool, error) { if len(keys) != 0 { wif, ok := keys[addr.EncodeAddress()] if !ok { return nil, false, errors.New("no key for address") } return wif.PrivKey.ToECDSA(), wif.CompressPubKey, nil } address, err := AcctMgr.Address(addr) if err != nil { return nil, false, err } pka, ok := address.(wallet.PubKeyAddress) if !ok { return nil, false, errors.New("address is not " + "a pubkey address") } key, err := pka.PrivKey() if err != nil { return nil, false, err } return key, pka.Compressed(), nil }) getScript := btcscript.ScriptClosure(func( addr btcutil.Address) ([]byte, error) { // If keys were provided then we can only use the // scripts provided with our inputs, too. if len(keys) != 0 { script, ok := scripts[addr.EncodeAddress()] if !ok { return nil, errors.New("no script for " + "address") } return script, nil } address, err := AcctMgr.Address(addr) if err != nil { return nil, err } sa, ok := address.(wallet.ScriptAddress) if !ok { return nil, errors.New("address is not a script" + " address") } // TODO(oga) we could possible speed things up further // by returning the addresses, class and nrequired here // thus avoiding recomputing them. return sa.Script(), nil }) // SigHashSingle inputs can only be signed if there's a // corresponding output. However this could be already signed, // so we always verify the output. if (hashType&btcscript.SigHashSingle) != btcscript.SigHashSingle || i < len(msgTx.TxOut) { script, err := btcscript.SignTxOutput(activeNet.Params, msgTx, i, input, byte(hashType), getKey, getScript, txIn.SignatureScript) // Failure to sign isn't an error, it just means that // the tx isn't complete. if err != nil { complete = false continue } txIn.SignatureScript = script } // Either it was already signed or we just signed it. // Find out if it is completely satisfied or still needs more. engine, err := btcscript.NewScript(txIn.SignatureScript, input, i, msgTx, btcscript.ScriptBip16| btcscript.ScriptCanonicalSignatures) if err != nil || engine.Execute() != nil { complete = false } } buf := bytes.NewBuffer(nil) buf.Grow(msgTx.SerializeSize()) // All returned errors (not OOM, which panics) encounted during // bytes.Buffer writes are unexpected. if err = msgTx.Serialize(buf); err != nil { panic(err) } return btcjson.SignRawTransactionResult{ Hex: hex.EncodeToString(buf.Bytes()), Complete: complete, }, nil } // ValidateAddress handles the validateaddress command. func ValidateAddress(icmd btcjson.Cmd) (interface{}, error) { cmd, ok := icmd.(*btcjson.ValidateAddressCmd) if !ok { return nil, btcjson.ErrInternal } result := btcjson.ValidateAddressResult{} addr, err := btcutil.DecodeAddress(cmd.Address, activeNet.Params) if err != nil { // Use zero value (false) for IsValid. return result, nil } // We could put whether or not the address is a script here, // by checking the type of "addr", however, the reference // implementation only puts that information if the script is // "ismine", and we follow that behaviour. result.Address = addr.EncodeAddress() result.IsValid = true // We can't use AcctMgr.Address() here since we also need the account // name. if account, err := AcctMgr.AccountByAddress(addr); err == nil { // The address must be handled by this account, so we expect // this call to succeed without error. ainfo, err := account.Address(addr) if err != nil { panic(err) } result.IsMine = true result.Account = account.name if pka, ok := ainfo.(wallet.PubKeyAddress); ok { result.IsCompressed = pka.Compressed() result.PubKey = pka.ExportPubKey() } else if sa, ok := ainfo.(wallet.ScriptAddress); ok { result.IsScript = true addresses := sa.Addresses() addrStrings := make([]string, len(addresses)) for i, a := range addresses { addrStrings[i] = a.EncodeAddress() } result.Addresses = addrStrings result.Hex = hex.EncodeToString(sa.Script()) class := sa.ScriptClass() // script type result.Script = class.String() if class == btcscript.MultiSigTy { result.SigsRequired = sa.RequiredSigs() } } } return result, nil } // VerifyMessage handles the verifymessage command by verifying the provided // compact signature for the given address and message. func VerifyMessage(icmd btcjson.Cmd) (interface{}, error) { cmd, ok := icmd.(*btcjson.VerifyMessageCmd) if !ok { return nil, btcjson.ErrInternal } addr, err := btcutil.DecodeAddress(cmd.Address, activeNet.Params) if err != nil { return nil, ParseError{err} } // First check we know about the address and get the keys. ainfo, err := AcctMgr.Address(addr) if err != nil { return nil, btcjson.ErrInvalidAddressOrKey } pka := ainfo.(wallet.PubKeyAddress) privkey, err := pka.PrivKey() if err != nil { return nil, err } // decode base64 signature sig, err := base64.StdEncoding.DecodeString(cmd.Signature) if err != nil { return nil, err } // Validate the signature - this just shows that it was valid at all. // we will compare it with the key next. pk, wasCompressed, err := btcec.RecoverCompact(btcec.S256(), sig, btcwire.DoubleSha256([]byte("Bitcoin Signed Message:\n"+ cmd.Message))) if err != nil { return nil, err } // Return boolean if keys match. return (pk.X.Cmp(privkey.X) == 0 && pk.Y.Cmp(privkey.Y) == 0 && ainfo.Compressed() == wasCompressed), nil } // WalletIsLocked handles the walletislocked extension request by // returning the current lock state (false for unlocked, true for locked) // of an account. An error is returned if the requested account does not // exist. func WalletIsLocked(icmd btcjson.Cmd) (interface{}, error) { // Type assert icmd to access parameters. cmd, ok := icmd.(*btcws.WalletIsLockedCmd) if !ok { return nil, btcjson.ErrInternal } a, err := AcctMgr.Account(cmd.Account) if err != nil { if err == ErrNotFound { return nil, btcjson.ErrWalletInvalidAccountName } return nil, err } return a.Wallet.IsLocked(), nil } // WalletLock handles a walletlock request by locking the all account // wallets, returning an error if any wallet is not encrypted (for example, // a watching-only wallet). func WalletLock(icmd btcjson.Cmd) (interface{}, error) { err := AcctMgr.LockWallets() return nil, err } // WalletPassphrase responds to the walletpassphrase request by unlocking // the wallet. The decryption key is saved in the wallet until timeout // seconds expires, after which the wallet is locked. func WalletPassphrase(icmd btcjson.Cmd) (interface{}, error) { // Type assert icmd to access parameters. cmd, ok := icmd.(*btcjson.WalletPassphraseCmd) if !ok { return nil, btcjson.ErrInternal } if err := AcctMgr.UnlockWallets(cmd.Passphrase); err != nil { return nil, err } go func(timeout int64) { time.Sleep(time.Second * time.Duration(timeout)) AcctMgr.Grab() defer AcctMgr.Release() err := AcctMgr.LockWallets() if err != nil { log.Warnf("Cannot lock account wallets: %v", err) } }(cmd.Timeout) return nil, nil } // WalletPassphraseChange responds to the walletpassphrasechange request // by unlocking all accounts with the provided old passphrase, and // re-encrypting each private key with an AES key derived from the new // passphrase. // // If the old passphrase is correct and the passphrase is changed, all // wallets will be immediately locked. func WalletPassphraseChange(icmd btcjson.Cmd) (interface{}, error) { cmd, ok := icmd.(*btcjson.WalletPassphraseChangeCmd) if !ok { return nil, btcjson.ErrInternal } err := AcctMgr.ChangePassphrase([]byte(cmd.OldPassphrase), []byte(cmd.NewPassphrase)) if err == wallet.ErrWrongPassphrase { return nil, btcjson.ErrWalletPassphraseIncorrect } return nil, err } // AccountNtfn is a struct for marshalling any generic notification // about a account for a wallet frontend. // // TODO(jrick): move to btcjson so it can be shared with frontends? type AccountNtfn struct { Account string `json:"account"` Notification interface{} `json:"notification"` } // NotifyWalletLockStateChange sends a notification to all frontends // that the wallet has just been locked or unlocked. func NotifyWalletLockStateChange(account string, locked bool) { ntfn := btcws.NewWalletLockStateNtfn(account, locked) mntfn, err := ntfn.MarshalJSON() // If the marshal failed, it indicates that the btcws notification // struct contains a field with a type that is not marshalable. if err != nil { panic(err) } allClients <- mntfn } // NotifyWalletBalance sends a confirmed account balance notification // to a frontend. func NotifyWalletBalance(frontend chan []byte, account string, balance float64) { ntfn := btcws.NewAccountBalanceNtfn(account, balance, true) mntfn, err := ntfn.MarshalJSON() // If the marshal failed, it indicates that the btcws notification // struct contains a field with a type that is not marshalable. if err != nil { panic(err) } frontend <- mntfn } // NotifyWalletBalanceUnconfirmed sends a confirmed account balance // notification to a frontend. func NotifyWalletBalanceUnconfirmed(frontend chan []byte, account string, balance float64) { ntfn := btcws.NewAccountBalanceNtfn(account, balance, false) mntfn, err := ntfn.MarshalJSON() // If the marshal failed, it indicates that the btcws notification // struct contains a field with a type that is not marshalable. if err != nil { panic(err) } frontend <- mntfn } // NotifyNewTxDetails sends details of a new transaction to a frontend. func NotifyNewTxDetails(frontend chan []byte, account string, details btcjson.ListTransactionsResult) { ntfn := btcws.NewTxNtfn(account, &details) mntfn, err := ntfn.MarshalJSON() // If the marshal failed, it indicates that the btcws notification // struct contains a field with a type that is not marshalable. if err != nil { panic(err) } frontend <- mntfn } // NotifiedRecvTxRequest is used to check whether the outpoint of // a received transaction has already been notified due to // arriving first in the btcd mempool. type NotifiedRecvTxRequest struct { op btcwire.OutPoint response chan NotifiedRecvTxResponse } // NotifiedRecvTxResponse is the response of a NotifiedRecvTxRequest // request. type NotifiedRecvTxResponse bool // NotifiedRecvTxChans holds the channels to manage // StoreNotifiedMempoolTxs. var NotifiedRecvTxChans = struct { add, remove chan btcwire.OutPoint access chan NotifiedRecvTxRequest }{ add: make(chan btcwire.OutPoint), remove: make(chan btcwire.OutPoint), access: make(chan NotifiedRecvTxRequest), } // StoreNotifiedMempoolRecvTxs maintains a set of previously-sent // received transaction notifications originating from the btcd // mempool. This is used to prevent duplicate frontend transaction // notifications once a mempool tx is mined into a block. func StoreNotifiedMempoolRecvTxs(add, remove chan btcwire.OutPoint, access chan NotifiedRecvTxRequest) { m := make(map[btcwire.OutPoint]struct{}) for { select { case op := <-add: m[op] = struct{}{} case op := <-remove: if _, ok := m[op]; ok { delete(m, op) } case req := <-access: _, ok := m[req.op] req.response <- NotifiedRecvTxResponse(ok) } } } // NotifyBalanceSyncerChans holds channels for accessing // the NotifyBalanceSyncer goroutine. var NotifyBalanceSyncerChans = struct { add chan NotifyBalanceWorker remove chan btcwire.ShaHash access chan NotifyBalanceRequest }{ add: make(chan NotifyBalanceWorker), remove: make(chan btcwire.ShaHash), access: make(chan NotifyBalanceRequest), } // NotifyBalanceWorker holds a block hash to add a worker to // NotifyBalanceSyncer and uses a chan to returns the WaitGroup // which should be decremented with Done after the worker is finished. type NotifyBalanceWorker struct { block btcwire.ShaHash wg chan *sync.WaitGroup } // NotifyBalanceRequest is used by the blockconnected notification handler // to access and wait on the the WaitGroup for workers currently processing // transactions for a block. If no handlers have been added, a nil // WaitGroup is returned. type NotifyBalanceRequest struct { block btcwire.ShaHash wg chan *sync.WaitGroup } // NotifyBalanceSyncer maintains a map of block hashes to WaitGroups // for worker goroutines that must finish before it is safe to notify // frontends of a new balance in the blockconnected notification handler. func NotifyBalanceSyncer(add chan NotifyBalanceWorker, remove chan btcwire.ShaHash, access chan NotifyBalanceRequest) { m := make(map[btcwire.ShaHash]*sync.WaitGroup) for { select { case worker := <-add: wg, ok := m[worker.block] if !ok { wg = &sync.WaitGroup{} m[worker.block] = wg } wg.Add(1) m[worker.block] = wg worker.wg <- wg case block := <-remove: if _, ok := m[block]; ok { delete(m, block) } case req := <-access: req.wg <- m[req.block] } } }