lbcwallet/waddrmgr/address.go
Roy Lee 202374ebd8 [lbry] fork from btcsuite to lbryio
1. btcd -> lbcd
2. btcwallet -> lbcallet
3. btcutil -> lbcutil
2022-05-24 10:31:06 -07:00

787 lines
24 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 waddrmgr
import (
"encoding/hex"
"fmt"
"sync"
"github.com/lbryio/lbcd/btcec"
"github.com/lbryio/lbcd/txscript"
btcutil "github.com/lbryio/lbcutil"
"github.com/lbryio/lbcutil/hdkeychain"
"github.com/lbryio/lbcwallet/internal/zero"
"github.com/lbryio/lbcwallet/walletdb"
)
// AddressType represents the various address types waddrmgr is currently able
// to generate, and maintain.
//
// NOTE: These MUST be stable as they're used for scope address schema
// recognition within the database.
type AddressType uint8
const (
// PubKeyHash is a regular p2pkh address.
PubKeyHash AddressType = iota
// Script reprints a raw script address.
Script
// RawPubKey is just raw public key to be used within scripts, This
// type indicates that a scoped manager with this address type
// shouldn't be consulted during historical rescans.
RawPubKey
// NestedWitnessPubKey represents a p2wkh output nested within a p2sh
// output. Using this address type, the wallet can receive funds from
// other wallet's which don't yet recognize the new segwit standard
// output types. Receiving funds to this address maintains the
// scalability, and malleability fixes due to segwit in a backwards
// compatible manner.
NestedWitnessPubKey
// WitnessPubKey represents a p2wkh (pay-to-witness-key-hash) address
// type.
WitnessPubKey
// WitnessScript represents a p2wsh (pay-to-witness-script-hash) address
// type.
WitnessScript
)
// ManagedAddress is an interface that provides acces to information regarding
// an address managed by an address manager. Concrete implementations of this
// type may provide further fields to provide information specific to that type
// of address.
type ManagedAddress interface {
// InternalAccount returns the internal account the address is
// associated with.
InternalAccount() uint32
// Address returns a btcutil.Address for the backing address.
Address() btcutil.Address
// AddrHash returns the key or script hash related to the address
AddrHash() []byte
// Imported returns true if the backing address was imported instead
// of being part of an address chain.
Imported() bool
// Internal returns true if the backing address was created for internal
// use such as a change output of a transaction.
Internal() bool
// Compressed returns true if the backing address is compressed.
Compressed() bool
// Used returns true if the backing address has been used in a transaction.
Used(ns walletdb.ReadBucket) bool
// AddrType returns the address type of the managed address. This can
// be used to quickly discern the address type without further
// processing
AddrType() AddressType
}
// ManagedPubKeyAddress extends ManagedAddress and additionally provides the
// public and private keys for pubkey-based addresses.
type ManagedPubKeyAddress interface {
ManagedAddress
// PubKey returns the public key associated with the address.
PubKey() *btcec.PublicKey
// ExportPubKey returns the public key associated with the address
// serialized as a hex encoded string.
ExportPubKey() string
// PrivKey returns the private key for the address. It can fail if the
// address manager is watching-only or locked, or the address does not
// have any keys.
PrivKey() (*btcec.PrivateKey, error)
// ExportPrivKey returns the private key associated with the address
// serialized as Wallet Import Format (WIF).
ExportPrivKey() (*btcutil.WIF, error)
// DerivationInfo contains the information required to derive the key
// that backs the address via traditional methods from the HD root. For
// imported keys, the first value will be set to false to indicate that
// we don't know exactly how the key was derived.
DerivationInfo() (KeyScope, DerivationPath, bool)
}
// ManagedScriptAddress extends ManagedAddress and represents a pay-to-script-hash
// style of bitcoin addresses. It additionally provides information about the
// script.
type ManagedScriptAddress interface {
ManagedAddress
// Script returns the script associated with the address.
Script() ([]byte, error)
}
// managedAddress represents a public key address. It also may or may not have
// the private key associated with the public key.
type managedAddress struct {
manager *ScopedKeyManager
derivationPath DerivationPath
address btcutil.Address
imported bool
internal bool
compressed bool
addrType AddressType
pubKey *btcec.PublicKey
privKeyEncrypted []byte // nil if part of watch-only account
privKeyCT []byte // non-nil if unlocked
privKeyMutex sync.Mutex
}
// Enforce managedAddress satisfies the ManagedPubKeyAddress interface.
var _ ManagedPubKeyAddress = (*managedAddress)(nil)
// unlock decrypts and stores a pointer to the associated private key. It will
// fail if the key is invalid or the encrypted private key is not available.
// The returned clear text private key will always be a copy that may be safely
// used by the caller without worrying about it being zeroed during an address
// lock.
func (a *managedAddress) unlock(key EncryptorDecryptor) ([]byte, error) {
// Protect concurrent access to clear text private key.
a.privKeyMutex.Lock()
defer a.privKeyMutex.Unlock()
// If the address belongs to a watch-only account, the encrypted private
// key won't be present, so we'll return an error.
if len(a.privKeyEncrypted) == 0 {
return nil, managerError(ErrWatchingOnly, errWatchingOnly, nil)
}
if len(a.privKeyCT) == 0 {
privKey, err := key.Decrypt(a.privKeyEncrypted)
if err != nil {
str := fmt.Sprintf("failed to decrypt private key for "+
"%s", a.address)
return nil, managerError(ErrCrypto, str, err)
}
a.privKeyCT = privKey
}
privKeyCopy := make([]byte, len(a.privKeyCT))
copy(privKeyCopy, a.privKeyCT)
return privKeyCopy, nil
}
// lock zeroes the associated clear text private key.
func (a *managedAddress) lock() {
// Zero and nil the clear text private key associated with this
// address.
a.privKeyMutex.Lock()
zero.Bytes(a.privKeyCT)
a.privKeyCT = nil
a.privKeyMutex.Unlock()
}
// InternalAccount returns the internal account number the address is associated
// with.
//
// This is part of the ManagedAddress interface implementation.
func (a *managedAddress) InternalAccount() uint32 {
return a.derivationPath.InternalAccount
}
// AddrType returns the address type of the managed address. This can be used
// to quickly discern the address type without further processing
//
// This is part of the ManagedAddress interface implementation.
func (a *managedAddress) AddrType() AddressType {
return a.addrType
}
// Address returns the btcutil.Address which represents the managed address.
// This will be a pay-to-pubkey-hash address.
//
// This is part of the ManagedAddress interface implementation.
func (a *managedAddress) Address() btcutil.Address {
return a.address
}
// AddrHash returns the public key hash for the address.
//
// This is part of the ManagedAddress interface implementation.
func (a *managedAddress) AddrHash() []byte {
var hash []byte
switch n := a.address.(type) {
case *btcutil.AddressPubKeyHash:
hash = n.Hash160()[:]
case *btcutil.AddressScriptHash:
hash = n.Hash160()[:]
case *btcutil.AddressWitnessPubKeyHash:
hash = n.Hash160()[:]
}
return hash
}
// Imported returns true if the address was imported instead of being part of an
// address chain.
//
// This is part of the ManagedAddress interface implementation.
func (a *managedAddress) Imported() bool {
return a.imported
}
// Internal returns true if the address was created for internal use such as a
// change output of a transaction.
//
// This is part of the ManagedAddress interface implementation.
func (a *managedAddress) Internal() bool {
return a.internal
}
// Compressed returns true if the address is compressed.
//
// This is part of the ManagedAddress interface implementation.
func (a *managedAddress) Compressed() bool {
return a.compressed
}
// Used returns true if the address has been used in a transaction.
//
// This is part of the ManagedAddress interface implementation.
func (a *managedAddress) Used(ns walletdb.ReadBucket) bool {
return a.manager.fetchUsed(ns, a.AddrHash())
}
// PubKey returns the public key associated with the address.
//
// This is part of the ManagedPubKeyAddress interface implementation.
func (a *managedAddress) PubKey() *btcec.PublicKey {
return a.pubKey
}
// pubKeyBytes returns the serialized public key bytes for the managed address
// based on whether or not the managed address is marked as compressed.
func (a *managedAddress) pubKeyBytes() []byte {
if a.compressed {
return a.pubKey.SerializeCompressed()
}
return a.pubKey.SerializeUncompressed()
}
// ExportPubKey returns the public key associated with the address
// serialized as a hex encoded string.
//
// This is part of the ManagedPubKeyAddress interface implementation.
func (a *managedAddress) ExportPubKey() string {
return hex.EncodeToString(a.pubKeyBytes())
}
// PrivKey returns the private key for the address. It can fail if the address
// manager is watching-only or locked, or the address does not have any keys.
//
// This is part of the ManagedPubKeyAddress interface implementation.
func (a *managedAddress) PrivKey() (*btcec.PrivateKey, error) {
// No private keys are available for a watching-only address manager.
if a.manager.rootManager.WatchOnly() {
return nil, managerError(ErrWatchingOnly, errWatchingOnly, nil)
}
a.manager.mtx.Lock()
defer a.manager.mtx.Unlock()
// Account manager must be unlocked to decrypt the private key.
if a.manager.rootManager.IsLocked() {
return nil, managerError(ErrLocked, errLocked, nil)
}
// Decrypt the key as needed. Also, make sure it's a copy since the
// private key stored in memory can be cleared at any time. Otherwise
// the returned private key could be invalidated from under the caller.
privKeyCopy, err := a.unlock(a.manager.rootManager.cryptoKeyPriv)
if err != nil {
return nil, err
}
privKey, _ := btcec.PrivKeyFromBytes(btcec.S256(), privKeyCopy)
zero.Bytes(privKeyCopy)
return privKey, nil
}
// ExportPrivKey returns the private key associated with the address in Wallet
// Import Format (WIF).
//
// This is part of the ManagedPubKeyAddress interface implementation.
func (a *managedAddress) ExportPrivKey() (*btcutil.WIF, error) {
pk, err := a.PrivKey()
if err != nil {
return nil, err
}
return btcutil.NewWIF(pk, a.manager.rootManager.chainParams, a.compressed)
}
// DerivationInfo contains the information required to derive the key that
// backs the address via traditional methods from the HD root. For imported
// keys, the first value will be set to false to indicate that we don't know
// exactly how the key was derived.
//
// This is part of the ManagedPubKeyAddress interface implementation.
func (a *managedAddress) DerivationInfo() (KeyScope, DerivationPath, bool) {
var (
scope KeyScope
path DerivationPath
)
// If this key is imported, then we can't return any information as we
// don't know precisely how the key was derived.
if a.imported {
return scope, path, false
}
return a.manager.Scope(), a.derivationPath, true
}
// newManagedAddressWithoutPrivKey returns a new managed address based on the
// passed account, public key, and whether or not the public key should be
// compressed.
func newManagedAddressWithoutPrivKey(m *ScopedKeyManager,
derivationPath DerivationPath, pubKey *btcec.PublicKey, compressed bool,
addrType AddressType) (*managedAddress, error) {
// Create a pay-to-pubkey-hash address from the public key.
var pubKeyHash []byte
if compressed {
pubKeyHash = btcutil.Hash160(pubKey.SerializeCompressed())
} else {
pubKeyHash = btcutil.Hash160(pubKey.SerializeUncompressed())
}
var address btcutil.Address
var err error
switch addrType {
case NestedWitnessPubKey:
// For this address type we'l generate an address which is
// backwards compatible to Bitcoin nodes running 0.6.0 onwards, but
// allows us to take advantage of segwit's scripting improvements,
// and malleability fixes.
// First, we'll generate a normal p2wkh address from the pubkey hash.
witAddr, err := btcutil.NewAddressWitnessPubKeyHash(
pubKeyHash, m.rootManager.chainParams,
)
if err != nil {
return nil, err
}
// Next we'll generate the witness program which can be used as a
// pkScript to pay to this generated address.
witnessProgram, err := txscript.PayToAddrScript(witAddr)
if err != nil {
return nil, err
}
// Finally, we'll use the witness program itself as the pre-image
// to a p2sh address. In order to spend, we first use the
// witnessProgram as the sigScript, then present the proper
// <sig, pubkey> pair as the witness.
address, err = btcutil.NewAddressScriptHash(
witnessProgram, m.rootManager.chainParams,
)
if err != nil {
return nil, err
}
case PubKeyHash:
address, err = btcutil.NewAddressPubKeyHash(
pubKeyHash, m.rootManager.chainParams,
)
if err != nil {
return nil, err
}
case WitnessPubKey:
address, err = btcutil.NewAddressWitnessPubKeyHash(
pubKeyHash, m.rootManager.chainParams,
)
if err != nil {
return nil, err
}
}
return &managedAddress{
manager: m,
address: address,
derivationPath: derivationPath,
imported: false,
internal: false,
addrType: addrType,
compressed: compressed,
pubKey: pubKey,
privKeyEncrypted: nil,
privKeyCT: nil,
}, nil
}
// newManagedAddress returns a new managed address based on the passed account,
// private key, and whether or not the public key is compressed. The managed
// address will have access to the private and public keys.
func newManagedAddress(s *ScopedKeyManager, derivationPath DerivationPath,
privKey *btcec.PrivateKey, compressed bool,
addrType AddressType) (*managedAddress, error) {
// Encrypt the private key.
//
// NOTE: The privKeyBytes here are set into the managed address which
// are cleared when locked, so they aren't cleared here.
privKeyBytes := privKey.Serialize()
privKeyEncrypted, err := s.rootManager.cryptoKeyPriv.Encrypt(privKeyBytes)
if err != nil {
str := "failed to encrypt private key"
return nil, managerError(ErrCrypto, str, err)
}
// Leverage the code to create a managed address without a private key
// and then add the private key to it.
ecPubKey := (*btcec.PublicKey)(&privKey.PublicKey)
managedAddr, err := newManagedAddressWithoutPrivKey(
s, derivationPath, ecPubKey, compressed, addrType,
)
if err != nil {
return nil, err
}
managedAddr.privKeyEncrypted = privKeyEncrypted
managedAddr.privKeyCT = privKeyBytes
return managedAddr, nil
}
// newManagedAddressFromExtKey returns a new managed address based on the passed
// account and extended key. The managed address will have access to the
// private and public keys if the provided extended key is private, otherwise it
// will only have access to the public key.
func newManagedAddressFromExtKey(s *ScopedKeyManager,
derivationPath DerivationPath, key *hdkeychain.ExtendedKey,
addrType AddressType) (*managedAddress, error) {
// Create a new managed address based on the public or private key
// depending on whether the generated key is private.
var managedAddr *managedAddress
if key.IsPrivate() {
privKey, err := key.ECPrivKey()
if err != nil {
return nil, err
}
// Ensure the temp private key big integer is cleared after
// use.
managedAddr, err = newManagedAddress(
s, derivationPath, privKey, true, addrType,
)
if err != nil {
return nil, err
}
} else {
pubKey, err := key.ECPubKey()
if err != nil {
return nil, err
}
managedAddr, err = newManagedAddressWithoutPrivKey(
s, derivationPath, pubKey, true,
addrType,
)
if err != nil {
return nil, err
}
}
return managedAddr, nil
}
// baseScriptAddress represents the common fields of a pay-to-script-hash and
// a pay-to-witness-script-hash address.
type baseScriptAddress struct {
manager *ScopedKeyManager
account uint32
address *btcutil.AddressScriptHash
scriptEncrypted []byte
scriptClearText []byte
scriptMutex sync.Mutex
}
// unlock decrypts and stores the associated script. It will fail if the key is
// invalid or the encrypted script is not available. The returned clear text
// script will always be a copy that may be safely used by the caller without
// worrying about it being zeroed during an address lock.
func (a *baseScriptAddress) unlock(key EncryptorDecryptor) ([]byte, error) {
// Protect concurrent access to clear text script.
a.scriptMutex.Lock()
defer a.scriptMutex.Unlock()
if len(a.scriptClearText) == 0 {
script, err := key.Decrypt(a.scriptEncrypted)
if err != nil {
str := fmt.Sprintf("failed to decrypt script for %s",
a.address)
return nil, managerError(ErrCrypto, str, err)
}
a.scriptClearText = script
}
scriptCopy := make([]byte, len(a.scriptClearText))
copy(scriptCopy, a.scriptClearText)
return scriptCopy, nil
}
// lock zeroes the associated clear text script.
func (a *baseScriptAddress) lock() {
// Zero and nil the clear text script associated with this address.
a.scriptMutex.Lock()
zero.Bytes(a.scriptClearText)
a.scriptClearText = nil
a.scriptMutex.Unlock()
}
// InternalAccount returns the account the address is associated with. This will
// always be the ImportedAddrAccount constant for script addresses.
//
// This is part of the ManagedAddress interface implementation.
func (a *baseScriptAddress) InternalAccount() uint32 {
return a.account
}
// Imported always returns true since script addresses are always imported
// addresses and not part of any chain.
//
// This is part of the ManagedAddress interface implementation.
func (a *baseScriptAddress) Imported() bool {
return true
}
// Internal always returns false since script addresses are always imported
// addresses and not part of any chain in order to be for internal use.
//
// This is part of the ManagedAddress interface implementation.
func (a *baseScriptAddress) Internal() bool {
return false
}
// scriptAddress represents a pay-to-script-hash address.
type scriptAddress struct {
baseScriptAddress
address *btcutil.AddressScriptHash
}
// AddrType returns the address type of the managed address. This can be used
// to quickly discern the address type without further processing
//
// This is part of the ManagedAddress interface implementation.
func (a *scriptAddress) AddrType() AddressType {
return Script
}
// Address returns the btcutil.Address which represents the managed address.
// This will be a pay-to-script-hash address.
//
// This is part of the ManagedAddress interface implementation.
func (a *scriptAddress) Address() btcutil.Address {
return a.address
}
// AddrHash returns the script hash for the address.
//
// This is part of the ManagedAddress interface implementation.
func (a *scriptAddress) AddrHash() []byte {
return a.address.Hash160()[:]
}
// Compressed returns false since script addresses are never compressed.
//
// This is part of the ManagedAddress interface implementation.
func (a *scriptAddress) Compressed() bool {
return false
}
// Used returns true if the address has been used in a transaction.
//
// This is part of the ManagedAddress interface implementation.
func (a *scriptAddress) Used(ns walletdb.ReadBucket) bool {
return a.manager.fetchUsed(ns, a.AddrHash())
}
// Script returns the script associated with the address.
//
// This is part of the ManagedAddress interface implementation.
func (a *scriptAddress) Script() ([]byte, error) {
// No script is available for a watching-only address manager.
if a.manager.rootManager.WatchOnly() {
return nil, managerError(ErrWatchingOnly, errWatchingOnly, nil)
}
a.manager.mtx.Lock()
defer a.manager.mtx.Unlock()
// Account manager must be unlocked to decrypt the script.
if a.manager.rootManager.IsLocked() {
return nil, managerError(ErrLocked, errLocked, nil)
}
// Decrypt the script as needed. Also, make sure it's a copy since the
// script stored in memory can be cleared at any time. Otherwise,
// the returned script could be invalidated from under the caller.
return a.unlock(a.manager.rootManager.cryptoKeyScript)
}
// Enforce scriptAddress satisfies the ManagedScriptAddress interface.
var _ ManagedScriptAddress = (*scriptAddress)(nil)
// newScriptAddress initializes and returns a new pay-to-script-hash address.
func newScriptAddress(m *ScopedKeyManager, account uint32, scriptHash,
scriptEncrypted []byte) (*scriptAddress, error) {
address, err := btcutil.NewAddressScriptHashFromHash(
scriptHash, m.rootManager.chainParams,
)
if err != nil {
return nil, err
}
return &scriptAddress{
baseScriptAddress: baseScriptAddress{
manager: m,
account: account,
scriptEncrypted: scriptEncrypted,
},
address: address,
}, nil
}
// witnessScriptAddress represents a pay-to-witness-script-hash address.
type witnessScriptAddress struct {
baseScriptAddress
address btcutil.Address
// witnessVersion is the version of the witness script.
witnessVersion byte
// isSecretScript denotes whether the script is considered to be "secret"
// and encrypted with the script encryption key or "public" and
// therefore only encrypted with the public encryption key.
isSecretScript bool
}
// AddrType returns the address type of the managed address. This can be used
// to quickly discern the address type without further processing
//
// This is part of the ManagedAddress interface implementation.
func (a *witnessScriptAddress) AddrType() AddressType {
return WitnessScript
}
// Address returns the btcutil.Address which represents the managed address.
// This will be a pay-to-witness-script-hash address.
//
// This is part of the ManagedAddress interface implementation.
func (a *witnessScriptAddress) Address() btcutil.Address {
return a.address
}
// AddrHash returns the script hash for the address.
//
// This is part of the ManagedAddress interface implementation.
func (a *witnessScriptAddress) AddrHash() []byte {
return a.address.ScriptAddress()
}
// Compressed returns true since witness script addresses are always compressed.
//
// This is part of the ManagedAddress interface implementation.
func (a *witnessScriptAddress) Compressed() bool {
return true
}
// Used returns true if the address has been used in a transaction.
//
// This is part of the ManagedAddress interface implementation.
func (a *witnessScriptAddress) Used(ns walletdb.ReadBucket) bool {
return a.manager.fetchUsed(ns, a.AddrHash())
}
// Script returns the script associated with the address.
//
// This is part of the ManagedAddress interface implementation.
func (a *witnessScriptAddress) Script() ([]byte, error) {
// No script is available for a watching-only address manager.
if a.isSecretScript && a.manager.rootManager.WatchOnly() {
return nil, managerError(ErrWatchingOnly, errWatchingOnly, nil)
}
a.manager.mtx.Lock()
defer a.manager.mtx.Unlock()
// Account manager must be unlocked to decrypt the script.
if a.isSecretScript && a.manager.rootManager.IsLocked() {
return nil, managerError(ErrLocked, errLocked, nil)
}
cryptoKey := a.manager.rootManager.cryptoKeyScript
if !a.isSecretScript {
cryptoKey = a.manager.rootManager.cryptoKeyPub
}
// Decrypt the script as needed. Also, make sure it's a copy since the
// script stored in memory can be cleared at any time. Otherwise,
// the returned script could be invalidated from under the caller.
return a.unlock(cryptoKey)
}
// Enforce witnessScriptAddress satisfies the ManagedScriptAddress interface.
var _ ManagedScriptAddress = (*witnessScriptAddress)(nil)
// newWitnessScriptAddress initializes and returns a new
// pay-to-witness-script-hash address.
func newWitnessScriptAddress(m *ScopedKeyManager, account uint32, scriptHash,
scriptEncrypted []byte, witnessVersion byte,
isSecretScript bool) (*witnessScriptAddress, error) {
var (
address btcutil.Address
err error
)
switch witnessVersion {
case 0x00:
address, err = btcutil.NewAddressWitnessScriptHash(
scriptHash, m.rootManager.chainParams,
)
case 0x01:
address, err = btcutil.NewAddressTaproot(
scriptHash, m.rootManager.chainParams,
)
}
if err != nil {
return nil, err
}
return &witnessScriptAddress{
baseScriptAddress: baseScriptAddress{
manager: m,
account: account,
scriptEncrypted: scriptEncrypted,
},
address: address,
witnessVersion: witnessVersion,
isSecretScript: isSecretScript,
}, nil
}