// Copyright (c) 2016 The btcsuite developers // Use of this source code is governed by an ISC // license that can be found in the LICENSE file. package rpctest import ( "bytes" "encoding/binary" "fmt" "sync" "time" "github.com/btcsuite/btcd/blockchain" "github.com/btcsuite/btcd/btcec" "github.com/btcsuite/btcd/chaincfg" "github.com/btcsuite/btcd/chaincfg/chainhash" "github.com/btcsuite/btcd/txscript" "github.com/btcsuite/btcd/wire" "github.com/btcsuite/btcrpcclient" "github.com/btcsuite/btcutil" "github.com/btcsuite/btcutil/hdkeychain" ) var ( // hdSeed is the BIP 32 seed used by the memWallet to initialize it's // HD root key. This value is hard coded in order to ensure // deterministic behavior across test runs. hdSeed = [chainhash.HashSize]byte{ 0x79, 0xa6, 0x1a, 0xdb, 0xc6, 0xe5, 0xa2, 0xe1, 0x39, 0xd2, 0x71, 0x3a, 0x54, 0x6e, 0xc7, 0xc8, 0x75, 0x63, 0x2e, 0x75, 0xf1, 0xdf, 0x9c, 0x3f, 0xa6, 0x01, 0x00, 0x00, 0x00, 0x00, 0x00, 0x00, } ) // utxo represents an unspent output spendable by the memWallet. The maturity // height of the transaction is recorded in order to properly observe the // maturity period of direct coinbase outputs. type utxo struct { pkScript []byte value btcutil.Amount keyIndex uint32 maturityHeight int32 isLocked bool } // isMature returns true if the target utxo is considered "mature" at the // passed block height. Otherwise, false is returned. func (u *utxo) isMature(height int32) bool { return height >= u.maturityHeight } // chainUpdate encapsulates an update to the current main chain. This struct is // used to sync up the memWallet each time a new block is connected to the main // chain. type chainUpdate struct { blockHash *chainhash.Hash blockHeight int32 } // undoEntry is functionally the opposite of a chainUpdate. An undoEntry is // created for each new block received, then stored in a log in order to // properly handle block re-orgs. type undoEntry struct { utxosDestroyed map[wire.OutPoint]*utxo utxosCreated []wire.OutPoint } // memWallet is a simple in-memory wallet whose purpose is to provide basic // wallet functionality to the harness. The wallet uses a hard-coded HD key // hierarchy which promotes reproducibility between harness test runs. type memWallet struct { coinbaseKey *btcec.PrivateKey coinbaseAddr btcutil.Address // hdRoot is the root master private key for the wallet. hdRoot *hdkeychain.ExtendedKey // hdIndex is the next available key index offset from the hdRoot. hdIndex uint32 // currentHeight is the latest height the wallet is known to be synced // to. currentHeight int32 // addrs tracks all addresses belonging to the wallet. The addresses // are indexed by their keypath from the hdRoot. addrs map[uint32]btcutil.Address // utxos is the set of utxos spendable by the wallet. utxos map[wire.OutPoint]*utxo // reorgJournal is a map storing an undo entry for each new block // received. Once a block is disconnected, the undo entry for the // particular height is evaluated, thereby rewinding the effect of the // disconnected block on the wallet's set of spendable utxos. reorgJournal map[int32]*undoEntry chainUpdates []*chainUpdate chainUpdateSignal chan struct{} chainMtx sync.Mutex net *chaincfg.Params rpc *btcrpcclient.Client sync.RWMutex } // newMemWallet creates and returns a fully initialized instance of the // memWallet given a particular blockchain's parameters. func newMemWallet(net *chaincfg.Params, harnessID uint32) (*memWallet, error) { // The wallet's final HD seed is: hdSeed || harnessID. This method // ensures that each harness instance uses a deterministic root seed // based on its harness ID. var harnessHDSeed [chainhash.HashSize + 4]byte copy(harnessHDSeed[:], hdSeed[:]) binary.BigEndian.PutUint32(harnessHDSeed[:chainhash.HashSize], harnessID) hdRoot, err := hdkeychain.NewMaster(harnessHDSeed[:], net) if err != nil { return nil, nil } // The first child key from the hd root is reserved as the coinbase // generation address. coinbaseChild, err := hdRoot.Child(0) if err != nil { return nil, err } coinbaseKey, err := coinbaseChild.ECPrivKey() if err != nil { return nil, err } coinbaseAddr, err := keyToAddr(coinbaseKey, net) if err != nil { return nil, err } // Track the coinbase generation address to ensure we properly track // newly generated bitcoin we can spend. addrs := make(map[uint32]btcutil.Address) addrs[0] = coinbaseAddr return &memWallet{ net: net, coinbaseKey: coinbaseKey, coinbaseAddr: coinbaseAddr, hdIndex: 1, hdRoot: hdRoot, addrs: addrs, utxos: make(map[wire.OutPoint]*utxo), chainUpdateSignal: make(chan struct{}), reorgJournal: make(map[int32]*undoEntry), }, nil } // Start launches all goroutines required for the wallet to function properly. func (m *memWallet) Start() { go m.chainSyncer() } // SyncedHeight returns the height the wallet is known to be synced to. // // This function is safe for concurrent access. func (m *memWallet) SyncedHeight() int32 { m.RLock() defer m.RUnlock() return m.currentHeight } // SetRPCClient saves the passed rpc connection to btcd as the wallet's // personal rpc connection. func (m *memWallet) SetRPCClient(rpcClient *btcrpcclient.Client) { m.rpc = rpcClient } // IngestBlock is a call-back which is to be triggered each time a new block is // connected to the main chain. Ingesting a block updates the wallet's internal // utxo state based on the outputs created and destroyed within each block. func (m *memWallet) IngestBlock(blockHash *chainhash.Hash, height int32, t time.Time) { // Append this new chain update to the end of the queue of new chain // updates. m.chainMtx.Lock() m.chainUpdates = append(m.chainUpdates, &chainUpdate{blockHash, height}) m.chainMtx.Unlock() // Launch a goroutine to signal the chainSyncer that a new update is // available. We do this in a new goroutine in order to avoid blocking // the main loop of the rpc client. go func() { m.chainUpdateSignal <- struct{}{} }() } // chainSyncer is a goroutine dedicated to processing new blocks in order to // keep the wallet's utxo state up to date. // // NOTE: This MUST be run as a goroutine. func (m *memWallet) chainSyncer() { var update *chainUpdate for range m.chainUpdateSignal { // A new update is available, so pop the new chain update from // the front of the update queue. m.chainMtx.Lock() update = m.chainUpdates[0] m.chainUpdates[0] = nil // Set to nil to prevent GC leak. m.chainUpdates = m.chainUpdates[1:] m.chainMtx.Unlock() // Fetch the new block so we can process it shortly below. block, err := m.rpc.GetBlock(update.blockHash) if err != nil { return } // Update the latest synced height, then process each // transaction in the block creating and destroying utxos // within the wallet as a result. m.Lock() m.currentHeight = update.blockHeight undo := &undoEntry{ utxosDestroyed: make(map[wire.OutPoint]*utxo), } for _, tx := range block.Transactions() { mtx := tx.MsgTx() isCoinbase := blockchain.IsCoinBaseTx(mtx) m.evalOutputs(mtx.TxOut, tx.Hash(), isCoinbase, undo) m.evalInputs(mtx.TxIn, undo) } // Finally, record the undo entry for this block so we can // properly update our internal state in response to the block // being re-org'd from the main chain. m.reorgJournal[update.blockHeight] = undo m.Unlock() } } // evalOutputs evaluates each of the passed outputs, creating a new matching // utxo within the wallet if we're able to spend the output. func (m *memWallet) evalOutputs(outputs []*wire.TxOut, txHash *chainhash.Hash, isCoinbase bool, undo *undoEntry) { for i, output := range outputs { pkScript := output.PkScript // Scan all the addresses we currently control to see if the // output is paying to us. for keyIndex, addr := range m.addrs { pkHash := addr.ScriptAddress() if !bytes.Contains(pkScript, pkHash) { continue } // If this is a coinbase output, then we mark the // maturity height at the proper block height in the // future. var maturityHeight int32 if isCoinbase { maturityHeight = m.currentHeight + int32(m.net.CoinbaseMaturity) } op := wire.OutPoint{Hash: *txHash, Index: uint32(i)} m.utxos[op] = &utxo{ value: btcutil.Amount(output.Value), keyIndex: keyIndex, maturityHeight: maturityHeight, pkScript: pkScript, } undo.utxosCreated = append(undo.utxosCreated, op) } } } // evalInputs scans all the passed inputs, destroying any utxos within the // wallet which are spent by an input. func (m *memWallet) evalInputs(inputs []*wire.TxIn, undo *undoEntry) { for _, txIn := range inputs { op := txIn.PreviousOutPoint oldUtxo, ok := m.utxos[op] if !ok { continue } undo.utxosDestroyed[op] = oldUtxo delete(m.utxos, op) } } // UnwindBlock is a call-back which is to be executed each time a block is // disconnected from the main chain. Unwinding a block undoes the effect that a // particular block had on the wallet's internal utxo state. func (m *memWallet) UnwindBlock(hash *chainhash.Hash, height int32, t time.Time) { m.Lock() defer m.Unlock() undo := m.reorgJournal[height] for _, utxo := range undo.utxosCreated { delete(m.utxos, utxo) } for outPoint, utxo := range undo.utxosDestroyed { m.utxos[outPoint] = utxo } delete(m.reorgJournal, height) } // newAddress returns a new address from the wallet's hd key chain. func (m *memWallet) newAddress() (btcutil.Address, error) { index := m.hdIndex childKey, err := m.hdRoot.Child(index) if err != nil { return nil, err } privKey, err := childKey.ECPrivKey() if err != nil { return nil, err } addr, err := keyToAddr(privKey, m.net) if err != nil { return nil, err } m.addrs[index] = addr m.hdIndex++ return addr, nil } // NewAddress returns a fresh address spendable by the wallet. // // This function is safe for concurrent access. func (m *memWallet) NewAddress() (btcutil.Address, error) { m.Lock() defer m.Unlock() return m.newAddress() } // fundTx attempts to fund a transaction sending amt bitcoin. The coins are // selected such that the final amount spent pays enough fees as dictated by // the passed fee rate. The passed fee rate should be expressed in // satoshis-per-byte. // // NOTE: The memWallet's mutex must be held when this function is called. func (m *memWallet) fundTx(tx *wire.MsgTx, amt btcutil.Amount, feeRate btcutil.Amount) error { const ( // spendSize is the largest number of bytes of a sigScript // which spends a p2pkh output: OP_DATA_73 OP_DATA_33 spendSize = 1 + 73 + 1 + 33 ) var ( amtSelected btcutil.Amount txSize int ) for outPoint, utxo := range m.utxos { // Skip any outputs that are still currently immature or are // currently locked. if !utxo.isMature(m.currentHeight) || utxo.isLocked { continue } amtSelected += utxo.value // Add the selected output to the transaction, updating the // current tx size while accounting for the size of the future // sigScript. tx.AddTxIn(wire.NewTxIn(&outPoint, nil)) txSize = tx.SerializeSize() + spendSize*len(tx.TxIn) // Calculate the fee required for the txn at this point // observing the specified fee rate. If we don't have enough // coins from he current amount selected to pay the fee, then // continue to grab more coins. reqFee := btcutil.Amount(txSize * int(feeRate)) if amtSelected-reqFee < amt { continue } // If we have any change left over, then add an additional // output to the transaction reserved for change. changeVal := amtSelected - amt - reqFee if changeVal > 0 { addr, err := m.newAddress() if err != nil { return err } pkScript, err := txscript.PayToAddrScript(addr) if err != nil { return err } changeOutput := &wire.TxOut{ Value: int64(changeVal), PkScript: pkScript, } tx.AddTxOut(changeOutput) } return nil } // If we've reached this point, then coin selection failed due to an // insufficient amount of coins. return fmt.Errorf("not enough funds for coin selection") } // SendOutputs creates, then sends a transaction paying to the specified output // while observing the passed fee rate. The passed fee rate should be expressed // in satoshis-per-byte. func (m *memWallet) SendOutputs(outputs []*wire.TxOut, feeRate btcutil.Amount) (*chainhash.Hash, error) { tx, err := m.CreateTransaction(outputs, feeRate) if err != nil { return nil, err } return m.rpc.SendRawTransaction(tx, true) } // CreateTransaction returns a fully signed transaction paying to the specified // outputs while observing the desired fee rate. The passed fee rate should be // expressed in satoshis-per-byte. // // This function is safe for concurrent access. func (m *memWallet) CreateTransaction(outputs []*wire.TxOut, feeRate btcutil.Amount) (*wire.MsgTx, error) { m.Lock() defer m.Unlock() tx := wire.NewMsgTx() // Tally up the total amount to be sent in order to perform coin // selection shortly below. var outputAmt btcutil.Amount for _, output := range outputs { outputAmt += btcutil.Amount(output.Value) tx.AddTxOut(output) } // Attempt to fund the transaction with spendable utxos. if err := m.fundTx(tx, outputAmt, btcutil.Amount(feeRate)); err != nil { return nil, err } // Populate all the selected inputs with valid sigScript for spending. // Along the way record all outputs being spent in order to avoid a // potential double spend. spentOutputs := make([]*utxo, 0, len(tx.TxIn)) for i, txIn := range tx.TxIn { outPoint := txIn.PreviousOutPoint utxo := m.utxos[outPoint] extendedKey, err := m.hdRoot.Child(utxo.keyIndex) if err != nil { return nil, err } privKey, err := extendedKey.ECPrivKey() if err != nil { return nil, err } sigScript, err := txscript.SignatureScript(tx, i, utxo.pkScript, txscript.SigHashAll, privKey, true) if err != nil { return nil, err } txIn.SignatureScript = sigScript spentOutputs = append(spentOutputs, utxo) } // As these outputs are now being spent by this newly created // transaction, mark the outputs are "locked". This action ensures // these outputs won't be double spent by any subsequent transactions. // These locked outputs can be freed via a call to UnlockOutputs. for _, utxo := range spentOutputs { utxo.isLocked = true } return tx, nil } // UnlockOutputs unlocks any outputs which were previously locked due to // being selected to fund a transaction via the CreateTransaction method. // // This function is safe for concurrent access. func (m *memWallet) UnlockOutputs(inputs []*wire.TxIn) { m.Lock() defer m.Unlock() for _, input := range inputs { utxo, ok := m.utxos[input.PreviousOutPoint] if !ok { continue } utxo.isLocked = false } } // ConfirmedBalance returns the confirmed balance of the wallet. // // This function is safe for concurrent access. func (m *memWallet) ConfirmedBalance() btcutil.Amount { m.RLock() defer m.RUnlock() var balance btcutil.Amount for _, utxo := range m.utxos { // Prevent any immature or locked outputs from contributing to // the wallet's total confirmed balance. if !utxo.isMature(m.currentHeight) || utxo.isLocked { continue } balance += utxo.value } return balance } // keyToAddr maps the passed private to corresponding p2pkh address. func keyToAddr(key *btcec.PrivateKey, net *chaincfg.Params) (btcutil.Address, error) { serializedKey := key.PubKey().SerializeCompressed() pubKeyAddr, err := btcutil.NewAddressPubKey(serializedKey, net) if err != nil { return nil, err } return pubKeyAddr.AddressPubKeyHash(), nil }