lbcd/integration/rpctest/memwallet.go

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// Copyright (c) 2016-2017 The btcsuite developers
rpctest: create new rpctest package This commit adds a new package (rpctest) which provides functionality for writing automated black box tests to exercise the RPC interface. An instance of a rpctest consists of an active btcd process running in (typically) --simnet mode, a btcrpcclient instance connected to said node, and finally an embedded in-memory wallet instance (the memWallet) which manages any created coinbase outputs created by the mining btcd node. As part of the SetUp process for an RPC test, a test author can optionally opt to have a test blockchain created. The second argument to SetUp dictates the number of mature coinbase outputs desired. The btcd process will then be directed to generate a test chain of length: 100 + numMatureOutputs. The embedded memWallet instance acts as a minimal, simple wallet for each Harness instance. The memWallet itself is a BIP 32 HD wallet capable of creating new addresses, creating fully signed transactions, creating+broadcasting a transaction paying to an arbitrary set of outputs, and querying the currently confirmed balance. In order to test various scenarios of blocks containing arbitrary transactions, one can use the Generate rpc call via the exposed btcrpcclient connected to the active btcd node. Additionally, the Harness also exposes a secondary block generation API allowing callers to create blocks with a set of hand-selected transactions, and an arbitrary BlockVersion or Timestamp. After execution of test logic TearDown should be called, allowing the test instance to clean up created temporary directories, and shut down the running processes. Running multiple concurrent rpctest.Harness instances is supported in order to allow for test authors to exercise complex scenarios. As a result, the primary interface to create, and initialize an rpctest.Harness instance is concurrent safe, with shared package level private global variables protected by a sync.Mutex. Fixes #116.
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// 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"
"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 {
blockHeight int32
filteredTxns []*btcutil.Tx
rpctest: create new rpctest package This commit adds a new package (rpctest) which provides functionality for writing automated black box tests to exercise the RPC interface. An instance of a rpctest consists of an active btcd process running in (typically) --simnet mode, a btcrpcclient instance connected to said node, and finally an embedded in-memory wallet instance (the memWallet) which manages any created coinbase outputs created by the mining btcd node. As part of the SetUp process for an RPC test, a test author can optionally opt to have a test blockchain created. The second argument to SetUp dictates the number of mature coinbase outputs desired. The btcd process will then be directed to generate a test chain of length: 100 + numMatureOutputs. The embedded memWallet instance acts as a minimal, simple wallet for each Harness instance. The memWallet itself is a BIP 32 HD wallet capable of creating new addresses, creating fully signed transactions, creating+broadcasting a transaction paying to an arbitrary set of outputs, and querying the currently confirmed balance. In order to test various scenarios of blocks containing arbitrary transactions, one can use the Generate rpc call via the exposed btcrpcclient connected to the active btcd node. Additionally, the Harness also exposes a secondary block generation API allowing callers to create blocks with a set of hand-selected transactions, and an arbitrary BlockVersion or Timestamp. After execution of test logic TearDown should be called, allowing the test instance to clean up created temporary directories, and shut down the running processes. Running multiple concurrent rpctest.Harness instances is supported in order to allow for test authors to exercise complex scenarios. As a result, the primary interface to create, and initialize an rpctest.Harness instance is concurrent safe, with shared package level private global variables protected by a sync.Mutex. Fixes #116.
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}
// 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(height int32, header *wire.BlockHeader, filteredTxns []*btcutil.Tx) {
rpctest: create new rpctest package This commit adds a new package (rpctest) which provides functionality for writing automated black box tests to exercise the RPC interface. An instance of a rpctest consists of an active btcd process running in (typically) --simnet mode, a btcrpcclient instance connected to said node, and finally an embedded in-memory wallet instance (the memWallet) which manages any created coinbase outputs created by the mining btcd node. As part of the SetUp process for an RPC test, a test author can optionally opt to have a test blockchain created. The second argument to SetUp dictates the number of mature coinbase outputs desired. The btcd process will then be directed to generate a test chain of length: 100 + numMatureOutputs. The embedded memWallet instance acts as a minimal, simple wallet for each Harness instance. The memWallet itself is a BIP 32 HD wallet capable of creating new addresses, creating fully signed transactions, creating+broadcasting a transaction paying to an arbitrary set of outputs, and querying the currently confirmed balance. In order to test various scenarios of blocks containing arbitrary transactions, one can use the Generate rpc call via the exposed btcrpcclient connected to the active btcd node. Additionally, the Harness also exposes a secondary block generation API allowing callers to create blocks with a set of hand-selected transactions, and an arbitrary BlockVersion or Timestamp. After execution of test logic TearDown should be called, allowing the test instance to clean up created temporary directories, and shut down the running processes. Running multiple concurrent rpctest.Harness instances is supported in order to allow for test authors to exercise complex scenarios. As a result, the primary interface to create, and initialize an rpctest.Harness instance is concurrent safe, with shared package level private global variables protected by a sync.Mutex. Fixes #116.
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// Append this new chain update to the end of the queue of new chain
// updates.
m.chainMtx.Lock()
m.chainUpdates = append(m.chainUpdates, &chainUpdate{height, filteredTxns})
rpctest: create new rpctest package This commit adds a new package (rpctest) which provides functionality for writing automated black box tests to exercise the RPC interface. An instance of a rpctest consists of an active btcd process running in (typically) --simnet mode, a btcrpcclient instance connected to said node, and finally an embedded in-memory wallet instance (the memWallet) which manages any created coinbase outputs created by the mining btcd node. As part of the SetUp process for an RPC test, a test author can optionally opt to have a test blockchain created. The second argument to SetUp dictates the number of mature coinbase outputs desired. The btcd process will then be directed to generate a test chain of length: 100 + numMatureOutputs. The embedded memWallet instance acts as a minimal, simple wallet for each Harness instance. The memWallet itself is a BIP 32 HD wallet capable of creating new addresses, creating fully signed transactions, creating+broadcasting a transaction paying to an arbitrary set of outputs, and querying the currently confirmed balance. In order to test various scenarios of blocks containing arbitrary transactions, one can use the Generate rpc call via the exposed btcrpcclient connected to the active btcd node. Additionally, the Harness also exposes a secondary block generation API allowing callers to create blocks with a set of hand-selected transactions, and an arbitrary BlockVersion or Timestamp. After execution of test logic TearDown should be called, allowing the test instance to clean up created temporary directories, and shut down the running processes. Running multiple concurrent rpctest.Harness instances is supported in order to allow for test authors to exercise complex scenarios. As a result, the primary interface to create, and initialize an rpctest.Harness instance is concurrent safe, with shared package level private global variables protected by a sync.Mutex. Fixes #116.
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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()
// Update the latest synced height, then process each filtered
// transaction in the block creating and destroying utxos within
// the wallet as a result.
rpctest: create new rpctest package This commit adds a new package (rpctest) which provides functionality for writing automated black box tests to exercise the RPC interface. An instance of a rpctest consists of an active btcd process running in (typically) --simnet mode, a btcrpcclient instance connected to said node, and finally an embedded in-memory wallet instance (the memWallet) which manages any created coinbase outputs created by the mining btcd node. As part of the SetUp process for an RPC test, a test author can optionally opt to have a test blockchain created. The second argument to SetUp dictates the number of mature coinbase outputs desired. The btcd process will then be directed to generate a test chain of length: 100 + numMatureOutputs. The embedded memWallet instance acts as a minimal, simple wallet for each Harness instance. The memWallet itself is a BIP 32 HD wallet capable of creating new addresses, creating fully signed transactions, creating+broadcasting a transaction paying to an arbitrary set of outputs, and querying the currently confirmed balance. In order to test various scenarios of blocks containing arbitrary transactions, one can use the Generate rpc call via the exposed btcrpcclient connected to the active btcd node. Additionally, the Harness also exposes a secondary block generation API allowing callers to create blocks with a set of hand-selected transactions, and an arbitrary BlockVersion or Timestamp. After execution of test logic TearDown should be called, allowing the test instance to clean up created temporary directories, and shut down the running processes. Running multiple concurrent rpctest.Harness instances is supported in order to allow for test authors to exercise complex scenarios. As a result, the primary interface to create, and initialize an rpctest.Harness instance is concurrent safe, with shared package level private global variables protected by a sync.Mutex. Fixes #116.
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m.Lock()
m.currentHeight = update.blockHeight
undo := &undoEntry{
utxosDestroyed: make(map[wire.OutPoint]*utxo),
}
for _, tx := range update.filteredTxns {
mtx := tx.MsgTx()
rpctest: create new rpctest package This commit adds a new package (rpctest) which provides functionality for writing automated black box tests to exercise the RPC interface. An instance of a rpctest consists of an active btcd process running in (typically) --simnet mode, a btcrpcclient instance connected to said node, and finally an embedded in-memory wallet instance (the memWallet) which manages any created coinbase outputs created by the mining btcd node. As part of the SetUp process for an RPC test, a test author can optionally opt to have a test blockchain created. The second argument to SetUp dictates the number of mature coinbase outputs desired. The btcd process will then be directed to generate a test chain of length: 100 + numMatureOutputs. The embedded memWallet instance acts as a minimal, simple wallet for each Harness instance. The memWallet itself is a BIP 32 HD wallet capable of creating new addresses, creating fully signed transactions, creating+broadcasting a transaction paying to an arbitrary set of outputs, and querying the currently confirmed balance. In order to test various scenarios of blocks containing arbitrary transactions, one can use the Generate rpc call via the exposed btcrpcclient connected to the active btcd node. Additionally, the Harness also exposes a secondary block generation API allowing callers to create blocks with a set of hand-selected transactions, and an arbitrary BlockVersion or Timestamp. After execution of test logic TearDown should be called, allowing the test instance to clean up created temporary directories, and shut down the running processes. Running multiple concurrent rpctest.Harness instances is supported in order to allow for test authors to exercise complex scenarios. As a result, the primary interface to create, and initialize an rpctest.Harness instance is concurrent safe, with shared package level private global variables protected by a sync.Mutex. Fixes #116.
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isCoinbase := blockchain.IsCoinBaseTx(mtx)
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txHash := mtx.TxHash()
m.evalOutputs(mtx.TxOut, &txHash, isCoinbase, undo)
rpctest: create new rpctest package This commit adds a new package (rpctest) which provides functionality for writing automated black box tests to exercise the RPC interface. An instance of a rpctest consists of an active btcd process running in (typically) --simnet mode, a btcrpcclient instance connected to said node, and finally an embedded in-memory wallet instance (the memWallet) which manages any created coinbase outputs created by the mining btcd node. As part of the SetUp process for an RPC test, a test author can optionally opt to have a test blockchain created. The second argument to SetUp dictates the number of mature coinbase outputs desired. The btcd process will then be directed to generate a test chain of length: 100 + numMatureOutputs. The embedded memWallet instance acts as a minimal, simple wallet for each Harness instance. The memWallet itself is a BIP 32 HD wallet capable of creating new addresses, creating fully signed transactions, creating+broadcasting a transaction paying to an arbitrary set of outputs, and querying the currently confirmed balance. In order to test various scenarios of blocks containing arbitrary transactions, one can use the Generate rpc call via the exposed btcrpcclient connected to the active btcd node. Additionally, the Harness also exposes a secondary block generation API allowing callers to create blocks with a set of hand-selected transactions, and an arbitrary BlockVersion or Timestamp. After execution of test logic TearDown should be called, allowing the test instance to clean up created temporary directories, and shut down the running processes. Running multiple concurrent rpctest.Harness instances is supported in order to allow for test authors to exercise complex scenarios. As a result, the primary interface to create, and initialize an rpctest.Harness instance is concurrent safe, with shared package level private global variables protected by a sync.Mutex. Fixes #116.
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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(height int32, header *wire.BlockHeader) {
rpctest: create new rpctest package This commit adds a new package (rpctest) which provides functionality for writing automated black box tests to exercise the RPC interface. An instance of a rpctest consists of an active btcd process running in (typically) --simnet mode, a btcrpcclient instance connected to said node, and finally an embedded in-memory wallet instance (the memWallet) which manages any created coinbase outputs created by the mining btcd node. As part of the SetUp process for an RPC test, a test author can optionally opt to have a test blockchain created. The second argument to SetUp dictates the number of mature coinbase outputs desired. The btcd process will then be directed to generate a test chain of length: 100 + numMatureOutputs. The embedded memWallet instance acts as a minimal, simple wallet for each Harness instance. The memWallet itself is a BIP 32 HD wallet capable of creating new addresses, creating fully signed transactions, creating+broadcasting a transaction paying to an arbitrary set of outputs, and querying the currently confirmed balance. In order to test various scenarios of blocks containing arbitrary transactions, one can use the Generate rpc call via the exposed btcrpcclient connected to the active btcd node. Additionally, the Harness also exposes a secondary block generation API allowing callers to create blocks with a set of hand-selected transactions, and an arbitrary BlockVersion or Timestamp. After execution of test logic TearDown should be called, allowing the test instance to clean up created temporary directories, and shut down the running processes. Running multiple concurrent rpctest.Harness instances is supported in order to allow for test authors to exercise complex scenarios. As a result, the primary interface to create, and initialize an rpctest.Harness instance is concurrent safe, with shared package level private global variables protected by a sync.Mutex. Fixes #116.
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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. It also
// loads the address into the RPC client's transaction filter to ensure any
// transactions that involve it are delivered via the notifications.
rpctest: create new rpctest package This commit adds a new package (rpctest) which provides functionality for writing automated black box tests to exercise the RPC interface. An instance of a rpctest consists of an active btcd process running in (typically) --simnet mode, a btcrpcclient instance connected to said node, and finally an embedded in-memory wallet instance (the memWallet) which manages any created coinbase outputs created by the mining btcd node. As part of the SetUp process for an RPC test, a test author can optionally opt to have a test blockchain created. The second argument to SetUp dictates the number of mature coinbase outputs desired. The btcd process will then be directed to generate a test chain of length: 100 + numMatureOutputs. The embedded memWallet instance acts as a minimal, simple wallet for each Harness instance. The memWallet itself is a BIP 32 HD wallet capable of creating new addresses, creating fully signed transactions, creating+broadcasting a transaction paying to an arbitrary set of outputs, and querying the currently confirmed balance. In order to test various scenarios of blocks containing arbitrary transactions, one can use the Generate rpc call via the exposed btcrpcclient connected to the active btcd node. Additionally, the Harness also exposes a secondary block generation API allowing callers to create blocks with a set of hand-selected transactions, and an arbitrary BlockVersion or Timestamp. After execution of test logic TearDown should be called, allowing the test instance to clean up created temporary directories, and shut down the running processes. Running multiple concurrent rpctest.Harness instances is supported in order to allow for test authors to exercise complex scenarios. As a result, the primary interface to create, and initialize an rpctest.Harness instance is concurrent safe, with shared package level private global variables protected by a sync.Mutex. Fixes #116.
2016-08-20 00:36:56 +02:00
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
}
err = m.rpc.LoadTxFilter(false, []btcutil.Address{addr}, nil)
if err != nil {
return nil, err
}
rpctest: create new rpctest package This commit adds a new package (rpctest) which provides functionality for writing automated black box tests to exercise the RPC interface. An instance of a rpctest consists of an active btcd process running in (typically) --simnet mode, a btcrpcclient instance connected to said node, and finally an embedded in-memory wallet instance (the memWallet) which manages any created coinbase outputs created by the mining btcd node. As part of the SetUp process for an RPC test, a test author can optionally opt to have a test blockchain created. The second argument to SetUp dictates the number of mature coinbase outputs desired. The btcd process will then be directed to generate a test chain of length: 100 + numMatureOutputs. The embedded memWallet instance acts as a minimal, simple wallet for each Harness instance. The memWallet itself is a BIP 32 HD wallet capable of creating new addresses, creating fully signed transactions, creating+broadcasting a transaction paying to an arbitrary set of outputs, and querying the currently confirmed balance. In order to test various scenarios of blocks containing arbitrary transactions, one can use the Generate rpc call via the exposed btcrpcclient connected to the active btcd node. Additionally, the Harness also exposes a secondary block generation API allowing callers to create blocks with a set of hand-selected transactions, and an arbitrary BlockVersion or Timestamp. After execution of test logic TearDown should be called, allowing the test instance to clean up created temporary directories, and shut down the running processes. Running multiple concurrent rpctest.Harness instances is supported in order to allow for test authors to exercise complex scenarios. As a result, the primary interface to create, and initialize an rpctest.Harness instance is concurrent safe, with shared package level private global variables protected by a sync.Mutex. Fixes #116.
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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 <sig> OP_DATA_33 <pubkey>
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(wire.TxVersion)
rpctest: create new rpctest package This commit adds a new package (rpctest) which provides functionality for writing automated black box tests to exercise the RPC interface. An instance of a rpctest consists of an active btcd process running in (typically) --simnet mode, a btcrpcclient instance connected to said node, and finally an embedded in-memory wallet instance (the memWallet) which manages any created coinbase outputs created by the mining btcd node. As part of the SetUp process for an RPC test, a test author can optionally opt to have a test blockchain created. The second argument to SetUp dictates the number of mature coinbase outputs desired. The btcd process will then be directed to generate a test chain of length: 100 + numMatureOutputs. The embedded memWallet instance acts as a minimal, simple wallet for each Harness instance. The memWallet itself is a BIP 32 HD wallet capable of creating new addresses, creating fully signed transactions, creating+broadcasting a transaction paying to an arbitrary set of outputs, and querying the currently confirmed balance. In order to test various scenarios of blocks containing arbitrary transactions, one can use the Generate rpc call via the exposed btcrpcclient connected to the active btcd node. Additionally, the Harness also exposes a secondary block generation API allowing callers to create blocks with a set of hand-selected transactions, and an arbitrary BlockVersion or Timestamp. After execution of test logic TearDown should be called, allowing the test instance to clean up created temporary directories, and shut down the running processes. Running multiple concurrent rpctest.Harness instances is supported in order to allow for test authors to exercise complex scenarios. As a result, the primary interface to create, and initialize an rpctest.Harness instance is concurrent safe, with shared package level private global variables protected by a sync.Mutex. Fixes #116.
2016-08-20 00:36:56 +02:00
// 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, feeRate); err != nil {
rpctest: create new rpctest package This commit adds a new package (rpctest) which provides functionality for writing automated black box tests to exercise the RPC interface. An instance of a rpctest consists of an active btcd process running in (typically) --simnet mode, a btcrpcclient instance connected to said node, and finally an embedded in-memory wallet instance (the memWallet) which manages any created coinbase outputs created by the mining btcd node. As part of the SetUp process for an RPC test, a test author can optionally opt to have a test blockchain created. The second argument to SetUp dictates the number of mature coinbase outputs desired. The btcd process will then be directed to generate a test chain of length: 100 + numMatureOutputs. The embedded memWallet instance acts as a minimal, simple wallet for each Harness instance. The memWallet itself is a BIP 32 HD wallet capable of creating new addresses, creating fully signed transactions, creating+broadcasting a transaction paying to an arbitrary set of outputs, and querying the currently confirmed balance. In order to test various scenarios of blocks containing arbitrary transactions, one can use the Generate rpc call via the exposed btcrpcclient connected to the active btcd node. Additionally, the Harness also exposes a secondary block generation API allowing callers to create blocks with a set of hand-selected transactions, and an arbitrary BlockVersion or Timestamp. After execution of test logic TearDown should be called, allowing the test instance to clean up created temporary directories, and shut down the running processes. Running multiple concurrent rpctest.Harness instances is supported in order to allow for test authors to exercise complex scenarios. As a result, the primary interface to create, and initialize an rpctest.Harness instance is concurrent safe, with shared package level private global variables protected by a sync.Mutex. Fixes #116.
2016-08-20 00:36:56 +02:00
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
}