lbcwallet/votingpool/pool.go
2018-05-23 19:38:56 -07:00

874 lines
28 KiB
Go

// Copyright (c) 2014 The btcsuite developers
// Use of this source code is governed by an ISC
// license that can be found in the LICENSE file.
package votingpool
import (
"fmt"
"sort"
"github.com/roasbeef/btcd/txscript"
"github.com/roasbeef/btcutil"
"github.com/roasbeef/btcutil/hdkeychain"
"github.com/roasbeef/btcwallet/internal/zero"
"github.com/roasbeef/btcwallet/waddrmgr"
"github.com/roasbeef/btcwallet/walletdb"
)
const (
minSeriesPubKeys = 3
// CurrentVersion is the version used for newly created Series.
CurrentVersion = 1
)
// Branch is the type used to represent a branch number in a series.
type Branch uint32
// Index is the type used to represent an index number in a series.
type Index uint32
// SeriesData represents a Series for a given Pool.
type SeriesData struct {
version uint32
// Whether or not a series is active. This is serialized/deserialized but
// for now there's no way to deactivate a series.
active bool
// A.k.a. "m" in "m of n signatures needed".
reqSigs uint32
publicKeys []*hdkeychain.ExtendedKey
privateKeys []*hdkeychain.ExtendedKey
}
// Pool represents an arrangement of notary servers to securely
// store and account for customer cryptocurrency deposits and to redeem
// valid withdrawals. For details about how the arrangement works, see
// http://opentransactions.org/wiki/index.php?title=Category:Voting_Pools
type Pool struct {
ID []byte
seriesLookup map[uint32]*SeriesData
manager *waddrmgr.Manager
namespace walletdb.Namespace
}
// PoolAddress represents a voting pool P2SH address, generated by
// deriving public HD keys from the series' master keys using the given
// branch/index and constructing a M-of-N multi-sig script.
type PoolAddress interface {
SeriesID() uint32
Branch() Branch
Index() Index
}
type poolAddress struct {
pool *Pool
addr btcutil.Address
script []byte
seriesID uint32
branch Branch
index Index
}
// ChangeAddress is a votingpool address meant to be used on transaction change
// outputs. All change addresses have branch==0.
type ChangeAddress struct {
*poolAddress
}
// WithdrawalAddress is a votingpool address that may contain unspent outputs
// available for use in a withdrawal.
type WithdrawalAddress struct {
*poolAddress
}
// Create creates a new entry in the database with the given ID
// and returns the Pool representing it.
func Create(namespace walletdb.Namespace, m *waddrmgr.Manager, poolID []byte) (*Pool, error) {
err := namespace.Update(
func(tx walletdb.Tx) error {
return putPool(tx, poolID)
})
if err != nil {
str := fmt.Sprintf("unable to add voting pool %v to db", poolID)
return nil, newError(ErrPoolAlreadyExists, str, err)
}
return newPool(namespace, m, poolID), nil
}
// Load fetches the entry in the database with the given ID and returns the Pool
// representing it.
func Load(namespace walletdb.Namespace, m *waddrmgr.Manager, poolID []byte) (*Pool, error) {
err := namespace.View(
func(tx walletdb.Tx) error {
if exists := existsPool(tx, poolID); !exists {
str := fmt.Sprintf("unable to find voting pool %v in db", poolID)
return newError(ErrPoolNotExists, str, nil)
}
return nil
})
if err != nil {
return nil, err
}
p := newPool(namespace, m, poolID)
if err = p.LoadAllSeries(); err != nil {
return nil, err
}
return p, nil
}
// newPool creates a new Pool instance.
func newPool(namespace walletdb.Namespace, m *waddrmgr.Manager, poolID []byte) *Pool {
return &Pool{
ID: poolID,
seriesLookup: make(map[uint32]*SeriesData),
manager: m,
namespace: namespace,
}
}
// LoadAndGetDepositScript generates and returns a deposit script for the given seriesID,
// branch and index of the Pool identified by poolID.
func LoadAndGetDepositScript(namespace walletdb.Namespace, m *waddrmgr.Manager, poolID string, seriesID uint32, branch Branch, index Index) ([]byte, error) {
pid := []byte(poolID)
p, err := Load(namespace, m, pid)
if err != nil {
return nil, err
}
script, err := p.DepositScript(seriesID, branch, index)
if err != nil {
return nil, err
}
return script, nil
}
// LoadAndCreateSeries loads the Pool with the given ID, creating a new one if it doesn't
// yet exist, and then creates and returns a Series with the given seriesID, rawPubKeys
// and reqSigs. See CreateSeries for the constraints enforced on rawPubKeys and reqSigs.
func LoadAndCreateSeries(namespace walletdb.Namespace, m *waddrmgr.Manager, version uint32,
poolID string, seriesID, reqSigs uint32, rawPubKeys []string) error {
pid := []byte(poolID)
p, err := Load(namespace, m, pid)
if err != nil {
vpErr := err.(Error)
if vpErr.ErrorCode == ErrPoolNotExists {
p, err = Create(namespace, m, pid)
if err != nil {
return err
}
} else {
return err
}
}
return p.CreateSeries(version, seriesID, reqSigs, rawPubKeys)
}
// LoadAndReplaceSeries loads the voting pool with the given ID and calls ReplaceSeries,
// passing the given series ID, public keys and reqSigs to it.
func LoadAndReplaceSeries(namespace walletdb.Namespace, m *waddrmgr.Manager, version uint32,
poolID string, seriesID, reqSigs uint32, rawPubKeys []string) error {
pid := []byte(poolID)
p, err := Load(namespace, m, pid)
if err != nil {
return err
}
return p.ReplaceSeries(version, seriesID, reqSigs, rawPubKeys)
}
// LoadAndEmpowerSeries loads the voting pool with the given ID and calls EmpowerSeries,
// passing the given series ID and private key to it.
func LoadAndEmpowerSeries(namespace walletdb.Namespace, m *waddrmgr.Manager,
poolID string, seriesID uint32, rawPrivKey string) error {
pid := []byte(poolID)
pool, err := Load(namespace, m, pid)
if err != nil {
return err
}
return pool.EmpowerSeries(seriesID, rawPrivKey)
}
// Series returns the series with the given ID, or nil if it doesn't
// exist.
func (p *Pool) Series(seriesID uint32) *SeriesData {
series, exists := p.seriesLookup[seriesID]
if !exists {
return nil
}
return series
}
// Manager returns the waddrmgr.Manager used by this Pool.
func (p *Pool) Manager() *waddrmgr.Manager {
return p.manager
}
// saveSeriesToDisk stores the given series ID and data in the database,
// first encrypting the public/private extended keys.
//
// This method must be called with the Pool's manager unlocked.
func (p *Pool) saveSeriesToDisk(seriesID uint32, data *SeriesData) error {
var err error
encryptedPubKeys := make([][]byte, len(data.publicKeys))
for i, pubKey := range data.publicKeys {
encryptedPubKeys[i], err = p.manager.Encrypt(
waddrmgr.CKTPublic, []byte(pubKey.String()))
if err != nil {
str := fmt.Sprintf("key %v failed encryption", pubKey)
return newError(ErrCrypto, str, err)
}
}
encryptedPrivKeys := make([][]byte, len(data.privateKeys))
for i, privKey := range data.privateKeys {
if privKey == nil {
encryptedPrivKeys[i] = nil
} else {
encryptedPrivKeys[i], err = p.manager.Encrypt(
waddrmgr.CKTPrivate, []byte(privKey.String()))
}
if err != nil {
str := fmt.Sprintf("key %v failed encryption", privKey)
return newError(ErrCrypto, str, err)
}
}
err = p.namespace.Update(func(tx walletdb.Tx) error {
return putSeries(tx, p.ID, data.version, seriesID, data.active,
data.reqSigs, encryptedPubKeys, encryptedPrivKeys)
})
if err != nil {
str := fmt.Sprintf("cannot put series #%d into db", seriesID)
return newError(ErrSeriesSerialization, str, err)
}
return nil
}
// CanonicalKeyOrder will return a copy of the input canonically
// ordered which is defined to be lexicographical.
func CanonicalKeyOrder(keys []string) []string {
orderedKeys := make([]string, len(keys))
copy(orderedKeys, keys)
sort.Sort(sort.StringSlice(orderedKeys))
return orderedKeys
}
// Convert the given slice of strings into a slice of ExtendedKeys,
// checking that all of them are valid public (and not private) keys,
// and that there are no duplicates.
func convertAndValidatePubKeys(rawPubKeys []string) ([]*hdkeychain.ExtendedKey, error) {
seenKeys := make(map[string]bool)
keys := make([]*hdkeychain.ExtendedKey, len(rawPubKeys))
for i, rawPubKey := range rawPubKeys {
if _, seen := seenKeys[rawPubKey]; seen {
str := fmt.Sprintf("duplicated public key: %v", rawPubKey)
return nil, newError(ErrKeyDuplicate, str, nil)
}
seenKeys[rawPubKey] = true
key, err := hdkeychain.NewKeyFromString(rawPubKey)
if err != nil {
str := fmt.Sprintf("invalid extended public key %v", rawPubKey)
return nil, newError(ErrKeyChain, str, err)
}
if key.IsPrivate() {
str := fmt.Sprintf("private keys not accepted: %v", rawPubKey)
return nil, newError(ErrKeyIsPrivate, str, nil)
}
keys[i] = key
}
return keys, nil
}
// putSeries creates a new seriesData with the given arguments, ordering the
// given public keys (using CanonicalKeyOrder), validating and converting them
// to hdkeychain.ExtendedKeys, saves that to disk and adds it to this voting
// pool's seriesLookup map. It also ensures inRawPubKeys has at least
// minSeriesPubKeys items and reqSigs is not greater than the number of items in
// inRawPubKeys.
//
// This method must be called with the Pool's manager unlocked.
func (p *Pool) putSeries(version, seriesID, reqSigs uint32, inRawPubKeys []string) error {
if len(inRawPubKeys) < minSeriesPubKeys {
str := fmt.Sprintf("need at least %d public keys to create a series", minSeriesPubKeys)
return newError(ErrTooFewPublicKeys, str, nil)
}
if reqSigs > uint32(len(inRawPubKeys)) {
str := fmt.Sprintf(
"the number of required signatures cannot be more than the number of keys")
return newError(ErrTooManyReqSignatures, str, nil)
}
rawPubKeys := CanonicalKeyOrder(inRawPubKeys)
keys, err := convertAndValidatePubKeys(rawPubKeys)
if err != nil {
return err
}
data := &SeriesData{
version: version,
active: false,
reqSigs: reqSigs,
publicKeys: keys,
privateKeys: make([]*hdkeychain.ExtendedKey, len(keys)),
}
err = p.saveSeriesToDisk(seriesID, data)
if err != nil {
return err
}
p.seriesLookup[seriesID] = data
return nil
}
// CreateSeries will create and return a new non-existing series.
//
// - seriesID must be greater than or equal 1;
// - rawPubKeys has to contain three or more public keys;
// - reqSigs has to be less or equal than the number of public keys in rawPubKeys.
func (p *Pool) CreateSeries(version, seriesID, reqSigs uint32, rawPubKeys []string) error {
if seriesID == 0 {
return newError(ErrSeriesIDInvalid, "series ID cannot be 0", nil)
}
if series := p.Series(seriesID); series != nil {
str := fmt.Sprintf("series #%d already exists", seriesID)
return newError(ErrSeriesAlreadyExists, str, nil)
}
if seriesID != 1 {
if _, ok := p.seriesLookup[seriesID-1]; !ok {
str := fmt.Sprintf("series #%d cannot be created because series #%d does not exist",
seriesID, seriesID-1)
return newError(ErrSeriesIDNotSequential, str, nil)
}
}
return p.putSeries(version, seriesID, reqSigs, rawPubKeys)
}
// ActivateSeries marks the series with the given ID as active.
func (p *Pool) ActivateSeries(seriesID uint32) error {
series := p.Series(seriesID)
if series == nil {
str := fmt.Sprintf("series #%d does not exist, cannot activate it", seriesID)
return newError(ErrSeriesNotExists, str, nil)
}
series.active = true
err := p.saveSeriesToDisk(seriesID, series)
if err != nil {
return err
}
p.seriesLookup[seriesID] = series
return nil
}
// ReplaceSeries will replace an already existing series.
//
// - rawPubKeys has to contain three or more public keys
// - reqSigs has to be less or equal than the number of public keys in rawPubKeys.
func (p *Pool) ReplaceSeries(version, seriesID, reqSigs uint32, rawPubKeys []string) error {
series := p.Series(seriesID)
if series == nil {
str := fmt.Sprintf("series #%d does not exist, cannot replace it", seriesID)
return newError(ErrSeriesNotExists, str, nil)
}
if series.IsEmpowered() {
str := fmt.Sprintf("series #%d has private keys and cannot be replaced", seriesID)
return newError(ErrSeriesAlreadyEmpowered, str, nil)
}
return p.putSeries(version, seriesID, reqSigs, rawPubKeys)
}
// decryptExtendedKey uses Manager.Decrypt() to decrypt the encrypted byte slice and return
// an extended (public or private) key representing it.
//
// This method must be called with the Pool's manager unlocked.
func (p *Pool) decryptExtendedKey(keyType waddrmgr.CryptoKeyType, encrypted []byte) (*hdkeychain.ExtendedKey, error) {
decrypted, err := p.manager.Decrypt(keyType, encrypted)
if err != nil {
str := fmt.Sprintf("cannot decrypt key %v", encrypted)
return nil, newError(ErrCrypto, str, err)
}
result, err := hdkeychain.NewKeyFromString(string(decrypted))
zero.Bytes(decrypted)
if err != nil {
str := fmt.Sprintf("cannot get key from string %v", decrypted)
return nil, newError(ErrKeyChain, str, err)
}
return result, nil
}
// validateAndDecryptSeriesKeys checks that the length of the public and private key
// slices is the same, decrypts them, ensures the non-nil private keys have a matching
// public key and returns them.
//
// This function must be called with the Pool's manager unlocked.
func validateAndDecryptKeys(rawPubKeys, rawPrivKeys [][]byte, p *Pool) (pubKeys, privKeys []*hdkeychain.ExtendedKey, err error) {
pubKeys = make([]*hdkeychain.ExtendedKey, len(rawPubKeys))
privKeys = make([]*hdkeychain.ExtendedKey, len(rawPrivKeys))
if len(pubKeys) != len(privKeys) {
return nil, nil, newError(ErrKeysPrivatePublicMismatch,
"the pub key and priv key arrays should have the same number of elements",
nil)
}
for i, encryptedPub := range rawPubKeys {
pubKey, err := p.decryptExtendedKey(waddrmgr.CKTPublic, encryptedPub)
if err != nil {
return nil, nil, err
}
pubKeys[i] = pubKey
encryptedPriv := rawPrivKeys[i]
var privKey *hdkeychain.ExtendedKey
if encryptedPriv == nil {
privKey = nil
} else {
privKey, err = p.decryptExtendedKey(waddrmgr.CKTPrivate, encryptedPriv)
if err != nil {
return nil, nil, err
}
}
privKeys[i] = privKey
if privKey != nil {
checkPubKey, err := privKey.Neuter()
if err != nil {
str := fmt.Sprintf("cannot neuter key %v", privKey)
return nil, nil, newError(ErrKeyNeuter, str, err)
}
if pubKey.String() != checkPubKey.String() {
str := fmt.Sprintf("public key %v different than expected %v",
pubKey, checkPubKey)
return nil, nil, newError(ErrKeyMismatch, str, nil)
}
}
}
return pubKeys, privKeys, nil
}
// LoadAllSeries fetches all series (decrypting their public and private
// extended keys) for this Pool from the database and populates the
// seriesLookup map with them. If there are any private extended keys for
// a series, it will also ensure they have a matching extended public key
// in that series.
//
// This method must be called with the Pool's manager unlocked.
// FIXME: We should be able to get rid of this (and loadAllSeries/seriesLookup)
// by making Series() load the series data directly from the DB.
func (p *Pool) LoadAllSeries() error {
var series map[uint32]*dbSeriesRow
err := p.namespace.View(func(tx walletdb.Tx) error {
var err error
series, err = loadAllSeries(tx, p.ID)
return err
})
if err != nil {
return err
}
for id, series := range series {
pubKeys, privKeys, err := validateAndDecryptKeys(
series.pubKeysEncrypted, series.privKeysEncrypted, p)
if err != nil {
return err
}
p.seriesLookup[id] = &SeriesData{
publicKeys: pubKeys,
privateKeys: privKeys,
reqSigs: series.reqSigs,
}
}
return nil
}
// Change the order of the pubkeys based on branch number.
// Given the three pubkeys ABC, this would mean:
// - branch 0: CBA (reversed)
// - branch 1: ABC (first key priority)
// - branch 2: BAC (second key priority)
// - branch 3: CAB (third key priority)
func branchOrder(pks []*hdkeychain.ExtendedKey, branch Branch) ([]*hdkeychain.ExtendedKey, error) {
if pks == nil {
// This really shouldn't happen, but we want to be good citizens, so we
// return an error instead of crashing.
return nil, newError(ErrInvalidValue, "pks cannot be nil", nil)
}
if branch > Branch(len(pks)) {
return nil, newError(
ErrInvalidBranch, "branch number is bigger than number of public keys", nil)
}
if branch == 0 {
numKeys := len(pks)
res := make([]*hdkeychain.ExtendedKey, numKeys)
copy(res, pks)
// reverse pk
for i, j := 0, numKeys-1; i < j; i, j = i+1, j-1 {
res[i], res[j] = res[j], res[i]
}
return res, nil
}
tmp := make([]*hdkeychain.ExtendedKey, len(pks))
tmp[0] = pks[branch-1]
j := 1
for i := 0; i < len(pks); i++ {
if i != int(branch-1) {
tmp[j] = pks[i]
j++
}
}
return tmp, nil
}
// DepositScriptAddress calls DepositScript to get a multi-signature
// redemption script and returns the pay-to-script-hash-address for that script.
func (p *Pool) DepositScriptAddress(seriesID uint32, branch Branch, index Index) (btcutil.Address, error) {
script, err := p.DepositScript(seriesID, branch, index)
if err != nil {
return nil, err
}
return p.addressFor(script)
}
func (p *Pool) addressFor(script []byte) (btcutil.Address, error) {
scriptHash := btcutil.Hash160(script)
return btcutil.NewAddressScriptHashFromHash(scriptHash, p.manager.ChainParams())
}
// DepositScript constructs and returns a multi-signature redemption script where
// a certain number (Series.reqSigs) of the public keys belonging to the series
// with the given ID are required to sign the transaction for it to be successful.
func (p *Pool) DepositScript(seriesID uint32, branch Branch, index Index) ([]byte, error) {
series := p.Series(seriesID)
if series == nil {
str := fmt.Sprintf("series #%d does not exist", seriesID)
return nil, newError(ErrSeriesNotExists, str, nil)
}
pubKeys, err := branchOrder(series.publicKeys, branch)
if err != nil {
return nil, err
}
pks := make([]*btcutil.AddressPubKey, len(pubKeys))
for i, key := range pubKeys {
child, err := key.Child(uint32(index))
// TODO: implement getting the next index until we find a valid one,
// in case there is a hdkeychain.ErrInvalidChild.
if err != nil {
str := fmt.Sprintf("child #%d for this pubkey %d does not exist", index, i)
return nil, newError(ErrKeyChain, str, err)
}
pubkey, err := child.ECPubKey()
if err != nil {
str := fmt.Sprintf("child #%d for this pubkey %d does not exist", index, i)
return nil, newError(ErrKeyChain, str, err)
}
pks[i], err = btcutil.NewAddressPubKey(pubkey.SerializeCompressed(),
p.manager.ChainParams())
if err != nil {
str := fmt.Sprintf(
"child #%d for this pubkey %d could not be converted to an address",
index, i)
return nil, newError(ErrKeyChain, str, err)
}
}
script, err := txscript.MultiSigScript(pks, int(series.reqSigs))
if err != nil {
str := fmt.Sprintf("error while making multisig script hash, %d", len(pks))
return nil, newError(ErrScriptCreation, str, err)
}
return script, nil
}
// ChangeAddress returns a new votingpool address for the given seriesID and
// index, on the 0th branch (which is reserved for change addresses). The series
// with the given ID must be active.
func (p *Pool) ChangeAddress(seriesID uint32, index Index) (*ChangeAddress, error) {
series := p.Series(seriesID)
if series == nil {
return nil, newError(ErrSeriesNotExists,
fmt.Sprintf("series %d does not exist", seriesID), nil)
}
if !series.active {
str := fmt.Sprintf("ChangeAddress must be on active series; series #%d is not", seriesID)
return nil, newError(ErrSeriesNotActive, str, nil)
}
script, err := p.DepositScript(seriesID, Branch(0), index)
if err != nil {
return nil, err
}
pAddr, err := p.poolAddress(seriesID, Branch(0), index, script)
if err != nil {
return nil, err
}
return &ChangeAddress{poolAddress: pAddr}, nil
}
// WithdrawalAddress queries the address manager for the P2SH address
// of the redeem script generated with the given series/branch/index and uses
// that to populate the returned WithdrawalAddress. This is done because we
// should only withdraw from previously used addresses but also because when
// processing withdrawals we may iterate over a huge number of addresses and
// it'd be too expensive to re-generate the redeem script for all of them.
// This method must be called with the manager unlocked.
func (p *Pool) WithdrawalAddress(seriesID uint32, branch Branch, index Index) (
*WithdrawalAddress, error) {
// TODO: Ensure the given series is hot.
addr, err := p.getUsedAddr(seriesID, branch, index)
if err != nil {
return nil, err
}
if addr == nil {
str := fmt.Sprintf("cannot withdraw from unused addr (series: %d, branch: %d, index: %d)",
seriesID, branch, index)
return nil, newError(ErrWithdrawFromUnusedAddr, str, nil)
}
script, err := addr.Script()
if err != nil {
return nil, err
}
pAddr, err := p.poolAddress(seriesID, branch, index, script)
if err != nil {
return nil, err
}
return &WithdrawalAddress{poolAddress: pAddr}, nil
}
func (p *Pool) poolAddress(seriesID uint32, branch Branch, index Index, script []byte) (
*poolAddress, error) {
addr, err := p.addressFor(script)
if err != nil {
return nil, err
}
return &poolAddress{
pool: p, seriesID: seriesID, branch: branch, index: index, addr: addr,
script: script},
nil
}
// EmpowerSeries adds the given extended private key (in raw format) to the
// series with the given ID, thus allowing it to sign deposit/withdrawal
// scripts. The series with the given ID must exist, the key must be a valid
// private extended key and must match one of the series' extended public keys.
//
// This method must be called with the Pool's manager unlocked.
func (p *Pool) EmpowerSeries(seriesID uint32, rawPrivKey string) error {
// make sure this series exists
series := p.Series(seriesID)
if series == nil {
str := fmt.Sprintf("series %d does not exist for this voting pool",
seriesID)
return newError(ErrSeriesNotExists, str, nil)
}
// Check that the private key is valid.
privKey, err := hdkeychain.NewKeyFromString(rawPrivKey)
if err != nil {
str := fmt.Sprintf("invalid extended private key %v", rawPrivKey)
return newError(ErrKeyChain, str, err)
}
if !privKey.IsPrivate() {
str := fmt.Sprintf(
"to empower a series you need the extended private key, not an extended public key %v",
privKey)
return newError(ErrKeyIsPublic, str, err)
}
pubKey, err := privKey.Neuter()
if err != nil {
str := fmt.Sprintf("invalid extended private key %v, can't convert to public key",
rawPrivKey)
return newError(ErrKeyNeuter, str, err)
}
lookingFor := pubKey.String()
found := false
// Make sure the private key has the corresponding public key in the series,
// to be able to empower it.
for i, publicKey := range series.publicKeys {
if publicKey.String() == lookingFor {
found = true
series.privateKeys[i] = privKey
}
}
if !found {
str := fmt.Sprintf(
"private Key does not have a corresponding public key in this series")
return newError(ErrKeysPrivatePublicMismatch, str, nil)
}
if err = p.saveSeriesToDisk(seriesID, series); err != nil {
return err
}
return nil
}
// EnsureUsedAddr ensures we have entries in our used addresses DB for the given
// seriesID, branch and all indices up to the given one. It must be called with
// the manager unlocked.
func (p *Pool) EnsureUsedAddr(seriesID uint32, branch Branch, index Index) error {
lastIdx, err := p.highestUsedIndexFor(seriesID, branch)
if err != nil {
return err
}
if lastIdx == 0 {
// highestUsedIndexFor() returns 0 when there are no used addresses for a
// given seriesID/branch, so we do this to ensure there is an entry with
// index==0.
if err := p.addUsedAddr(seriesID, branch, lastIdx); err != nil {
return err
}
}
lastIdx++
for lastIdx <= index {
if err := p.addUsedAddr(seriesID, branch, lastIdx); err != nil {
return err
}
lastIdx++
}
return nil
}
// addUsedAddr creates a deposit script for the given seriesID/branch/index,
// ensures it is imported into the address manager and finaly adds the script
// hash to our used addresses DB. It must be called with the manager unlocked.
func (p *Pool) addUsedAddr(seriesID uint32, branch Branch, index Index) error {
script, err := p.DepositScript(seriesID, branch, index)
if err != nil {
return err
}
// First ensure the address manager has our script. That way there's no way
// to have it in the used addresses DB but not in the address manager.
// TODO: Decide how far back we want the addr manager to rescan and set the
// BlockStamp height according to that.
_, err = p.manager.ImportScript(script, &waddrmgr.BlockStamp{})
if err != nil && err.(waddrmgr.ManagerError).ErrorCode != waddrmgr.ErrDuplicateAddress {
return err
}
encryptedHash, err := p.manager.Encrypt(waddrmgr.CKTPublic, btcutil.Hash160(script))
if err != nil {
return newError(ErrCrypto, "failed to encrypt script hash", err)
}
err = p.namespace.Update(
func(tx walletdb.Tx) error {
return putUsedAddrHash(tx, p.ID, seriesID, branch, index, encryptedHash)
})
if err != nil {
return newError(ErrDatabase, "failed to store used addr script hash", err)
}
return nil
}
// getUsedAddr gets the script hash for the given series, branch and index from
// the used addresses DB and uses that to look up the ManagedScriptAddress
// from the address manager. It must be called with the manager unlocked.
func (p *Pool) getUsedAddr(seriesID uint32, branch Branch, index Index) (
waddrmgr.ManagedScriptAddress, error) {
mgr := p.manager
var encryptedHash []byte
err := p.namespace.View(
func(tx walletdb.Tx) error {
encryptedHash = getUsedAddrHash(tx, p.ID, seriesID, branch, index)
return nil
})
if err != nil {
return nil, newError(ErrDatabase, "failed to lookup script hash for used addr", err)
}
if encryptedHash == nil {
return nil, nil
}
hash, err := p.manager.Decrypt(waddrmgr.CKTPublic, encryptedHash)
if err != nil {
return nil, newError(ErrCrypto, "failed to decrypt stored script hash", err)
}
addr, err := btcutil.NewAddressScriptHashFromHash(hash, mgr.ChainParams())
if err != nil {
return nil, newError(ErrInvalidScriptHash, "failed to parse script hash", err)
}
mAddr, err := mgr.Address(addr)
if err != nil {
return nil, err
}
return mAddr.(waddrmgr.ManagedScriptAddress), nil
}
// highestUsedIndexFor returns the highest index from this Pool's used addresses
// with the given seriesID and branch. It returns 0 if there are no used
// addresses with the given seriesID and branch.
func (p *Pool) highestUsedIndexFor(seriesID uint32, branch Branch) (Index, error) {
maxIdx := Index(0)
err := p.namespace.View(
func(tx walletdb.Tx) error {
var err error
maxIdx, err = getMaxUsedIdx(tx, p.ID, seriesID, branch)
return err
})
return maxIdx, err
}
// String returns a string encoding of the underlying bitcoin payment address.
func (a *poolAddress) String() string {
return a.addr.EncodeAddress()
}
func (a *poolAddress) addrIdentifier() string {
return fmt.Sprintf("PoolAddress seriesID:%d, branch:%d, index:%d", a.seriesID, a.branch,
a.index)
}
func (a *poolAddress) redeemScript() []byte {
return a.script
}
func (a *poolAddress) series() *SeriesData {
return a.pool.Series(a.seriesID)
}
func (a *poolAddress) SeriesID() uint32 {
return a.seriesID
}
func (a *poolAddress) Branch() Branch {
return a.branch
}
func (a *poolAddress) Index() Index {
return a.index
}
// IsEmpowered returns true if this series is empowered (i.e. if it has
// at least one private key loaded).
func (s *SeriesData) IsEmpowered() bool {
for _, key := range s.privateKeys {
if key != nil {
return true
}
}
return false
}
func (s *SeriesData) getPrivKeyFor(pubKey *hdkeychain.ExtendedKey) (*hdkeychain.ExtendedKey, error) {
for i, key := range s.publicKeys {
if key.String() == pubKey.String() {
return s.privateKeys[i], nil
}
}
return nil, newError(ErrUnknownPubKey, fmt.Sprintf("unknown public key '%s'",
pubKey.String()), nil)
}