go-ethereum/accounts/usbwallet/wallet.go
Corey Lin 2fa9e99fc1 usbwallet: check error returned by driver close (#18057)
Although current two implementations(ledgerDriver, trezorDriver) of interface driver.Close do not actually return any error. Instead, they only return nil.
But since the declaration of Close function returns error, it is better to check the returned error in case in future some new implementation of Close function returns error and we may forget to modify the function which invokes Close function at that time.
2019-03-07 12:13:06 +02:00

578 lines
20 KiB
Go

// Copyright 2017 The go-ethereum Authors
// This file is part of the go-ethereum library.
//
// The go-ethereum library is free software: you can redistribute it and/or modify
// it under the terms of the GNU Lesser General Public License as published by
// the Free Software Foundation, either version 3 of the License, or
// (at your option) any later version.
//
// The go-ethereum library is distributed in the hope that it will be useful,
// but WITHOUT ANY WARRANTY; without even the implied warranty of
// MERCHANTABILITY or FITNESS FOR A PARTICULAR PURPOSE. See the
// GNU Lesser General Public License for more details.
//
// You should have received a copy of the GNU Lesser General Public License
// along with the go-ethereum library. If not, see <http://www.gnu.org/licenses/>.
// Package usbwallet implements support for USB hardware wallets.
package usbwallet
import (
"context"
"fmt"
"io"
"math/big"
"sync"
"time"
ethereum "github.com/ethereum/go-ethereum"
"github.com/ethereum/go-ethereum/accounts"
"github.com/ethereum/go-ethereum/common"
"github.com/ethereum/go-ethereum/core/types"
"github.com/ethereum/go-ethereum/crypto"
"github.com/ethereum/go-ethereum/log"
"github.com/karalabe/hid"
)
// Maximum time between wallet health checks to detect USB unplugs.
const heartbeatCycle = time.Second
// Minimum time to wait between self derivation attempts, even it the user is
// requesting accounts like crazy.
const selfDeriveThrottling = time.Second
// driver defines the vendor specific functionality hardware wallets instances
// must implement to allow using them with the wallet lifecycle management.
type driver interface {
// Status returns a textual status to aid the user in the current state of the
// wallet. It also returns an error indicating any failure the wallet might have
// encountered.
Status() (string, error)
// Open initializes access to a wallet instance. The passphrase parameter may
// or may not be used by the implementation of a particular wallet instance.
Open(device io.ReadWriter, passphrase string) error
// Close releases any resources held by an open wallet instance.
Close() error
// Heartbeat performs a sanity check against the hardware wallet to see if it
// is still online and healthy.
Heartbeat() error
// Derive sends a derivation request to the USB device and returns the Ethereum
// address located on that path.
Derive(path accounts.DerivationPath) (common.Address, error)
// SignTx sends the transaction to the USB device and waits for the user to confirm
// or deny the transaction.
SignTx(path accounts.DerivationPath, tx *types.Transaction, chainID *big.Int) (common.Address, *types.Transaction, error)
}
// wallet represents the common functionality shared by all USB hardware
// wallets to prevent reimplementing the same complex maintenance mechanisms
// for different vendors.
type wallet struct {
hub *Hub // USB hub scanning
driver driver // Hardware implementation of the low level device operations
url *accounts.URL // Textual URL uniquely identifying this wallet
info hid.DeviceInfo // Known USB device infos about the wallet
device *hid.Device // USB device advertising itself as a hardware wallet
accounts []accounts.Account // List of derive accounts pinned on the hardware wallet
paths map[common.Address]accounts.DerivationPath // Known derivation paths for signing operations
deriveNextPath accounts.DerivationPath // Next derivation path for account auto-discovery
deriveNextAddr common.Address // Next derived account address for auto-discovery
deriveChain ethereum.ChainStateReader // Blockchain state reader to discover used account with
deriveReq chan chan struct{} // Channel to request a self-derivation on
deriveQuit chan chan error // Channel to terminate the self-deriver with
healthQuit chan chan error
// Locking a hardware wallet is a bit special. Since hardware devices are lower
// performing, any communication with them might take a non negligible amount of
// time. Worse still, waiting for user confirmation can take arbitrarily long,
// but exclusive communication must be upheld during. Locking the entire wallet
// in the mean time however would stall any parts of the system that don't want
// to communicate, just read some state (e.g. list the accounts).
//
// As such, a hardware wallet needs two locks to function correctly. A state
// lock can be used to protect the wallet's software-side internal state, which
// must not be held exclusively during hardware communication. A communication
// lock can be used to achieve exclusive access to the device itself, this one
// however should allow "skipping" waiting for operations that might want to
// use the device, but can live without too (e.g. account self-derivation).
//
// Since we have two locks, it's important to know how to properly use them:
// - Communication requires the `device` to not change, so obtaining the
// commsLock should be done after having a stateLock.
// - Communication must not disable read access to the wallet state, so it
// must only ever hold a *read* lock to stateLock.
commsLock chan struct{} // Mutex (buf=1) for the USB comms without keeping the state locked
stateLock sync.RWMutex // Protects read and write access to the wallet struct fields
log log.Logger // Contextual logger to tag the base with its id
}
// URL implements accounts.Wallet, returning the URL of the USB hardware device.
func (w *wallet) URL() accounts.URL {
return *w.url // Immutable, no need for a lock
}
// Status implements accounts.Wallet, returning a custom status message from the
// underlying vendor-specific hardware wallet implementation.
func (w *wallet) Status() (string, error) {
w.stateLock.RLock() // No device communication, state lock is enough
defer w.stateLock.RUnlock()
status, failure := w.driver.Status()
if w.device == nil {
return "Closed", failure
}
return status, failure
}
// Open implements accounts.Wallet, attempting to open a USB connection to the
// hardware wallet.
func (w *wallet) Open(passphrase string) error {
w.stateLock.Lock() // State lock is enough since there's no connection yet at this point
defer w.stateLock.Unlock()
// If the device was already opened once, refuse to try again
if w.paths != nil {
return accounts.ErrWalletAlreadyOpen
}
// Make sure the actual device connection is done only once
if w.device == nil {
device, err := w.info.Open()
if err != nil {
return err
}
w.device = device
w.commsLock = make(chan struct{}, 1)
w.commsLock <- struct{}{} // Enable lock
}
// Delegate device initialization to the underlying driver
if err := w.driver.Open(w.device, passphrase); err != nil {
return err
}
// Connection successful, start life-cycle management
w.paths = make(map[common.Address]accounts.DerivationPath)
w.deriveReq = make(chan chan struct{})
w.deriveQuit = make(chan chan error)
w.healthQuit = make(chan chan error)
go w.heartbeat()
go w.selfDerive()
// Notify anyone listening for wallet events that a new device is accessible
go w.hub.updateFeed.Send(accounts.WalletEvent{Wallet: w, Kind: accounts.WalletOpened})
return nil
}
// heartbeat is a health check loop for the USB wallets to periodically verify
// whether they are still present or if they malfunctioned.
func (w *wallet) heartbeat() {
w.log.Debug("USB wallet health-check started")
defer w.log.Debug("USB wallet health-check stopped")
// Execute heartbeat checks until termination or error
var (
errc chan error
err error
)
for errc == nil && err == nil {
// Wait until termination is requested or the heartbeat cycle arrives
select {
case errc = <-w.healthQuit:
// Termination requested
continue
case <-time.After(heartbeatCycle):
// Heartbeat time
}
// Execute a tiny data exchange to see responsiveness
w.stateLock.RLock()
if w.device == nil {
// Terminated while waiting for the lock
w.stateLock.RUnlock()
continue
}
<-w.commsLock // Don't lock state while resolving version
err = w.driver.Heartbeat()
w.commsLock <- struct{}{}
w.stateLock.RUnlock()
if err != nil {
w.stateLock.Lock() // Lock state to tear the wallet down
w.close()
w.stateLock.Unlock()
}
// Ignore non hardware related errors
err = nil
}
// In case of error, wait for termination
if err != nil {
w.log.Debug("USB wallet health-check failed", "err", err)
errc = <-w.healthQuit
}
errc <- err
}
// Close implements accounts.Wallet, closing the USB connection to the device.
func (w *wallet) Close() error {
// Ensure the wallet was opened
w.stateLock.RLock()
hQuit, dQuit := w.healthQuit, w.deriveQuit
w.stateLock.RUnlock()
// Terminate the health checks
var herr error
if hQuit != nil {
errc := make(chan error)
hQuit <- errc
herr = <-errc // Save for later, we *must* close the USB
}
// Terminate the self-derivations
var derr error
if dQuit != nil {
errc := make(chan error)
dQuit <- errc
derr = <-errc // Save for later, we *must* close the USB
}
// Terminate the device connection
w.stateLock.Lock()
defer w.stateLock.Unlock()
w.healthQuit = nil
w.deriveQuit = nil
w.deriveReq = nil
if err := w.close(); err != nil {
return err
}
if herr != nil {
return herr
}
return derr
}
// close is the internal wallet closer that terminates the USB connection and
// resets all the fields to their defaults.
//
// Note, close assumes the state lock is held!
func (w *wallet) close() error {
// Allow duplicate closes, especially for health-check failures
if w.device == nil {
return nil
}
// Close the device, clear everything, then return
w.device.Close()
w.device = nil
w.accounts, w.paths = nil, nil
return w.driver.Close()
}
// Accounts implements accounts.Wallet, returning the list of accounts pinned to
// the USB hardware wallet. If self-derivation was enabled, the account list is
// periodically expanded based on current chain state.
func (w *wallet) Accounts() []accounts.Account {
// Attempt self-derivation if it's running
reqc := make(chan struct{}, 1)
select {
case w.deriveReq <- reqc:
// Self-derivation request accepted, wait for it
<-reqc
default:
// Self-derivation offline, throttled or busy, skip
}
// Return whatever account list we ended up with
w.stateLock.RLock()
defer w.stateLock.RUnlock()
cpy := make([]accounts.Account, len(w.accounts))
copy(cpy, w.accounts)
return cpy
}
// selfDerive is an account derivation loop that upon request attempts to find
// new non-zero accounts.
func (w *wallet) selfDerive() {
w.log.Debug("USB wallet self-derivation started")
defer w.log.Debug("USB wallet self-derivation stopped")
// Execute self-derivations until termination or error
var (
reqc chan struct{}
errc chan error
err error
)
for errc == nil && err == nil {
// Wait until either derivation or termination is requested
select {
case errc = <-w.deriveQuit:
// Termination requested
continue
case reqc = <-w.deriveReq:
// Account discovery requested
}
// Derivation needs a chain and device access, skip if either unavailable
w.stateLock.RLock()
if w.device == nil || w.deriveChain == nil {
w.stateLock.RUnlock()
reqc <- struct{}{}
continue
}
select {
case <-w.commsLock:
default:
w.stateLock.RUnlock()
reqc <- struct{}{}
continue
}
// Device lock obtained, derive the next batch of accounts
var (
accs []accounts.Account
paths []accounts.DerivationPath
nextAddr = w.deriveNextAddr
nextPath = w.deriveNextPath
context = context.Background()
)
for empty := false; !empty; {
// Retrieve the next derived Ethereum account
if nextAddr == (common.Address{}) {
if nextAddr, err = w.driver.Derive(nextPath); err != nil {
w.log.Warn("USB wallet account derivation failed", "err", err)
break
}
}
// Check the account's status against the current chain state
var (
balance *big.Int
nonce uint64
)
balance, err = w.deriveChain.BalanceAt(context, nextAddr, nil)
if err != nil {
w.log.Warn("USB wallet balance retrieval failed", "err", err)
break
}
nonce, err = w.deriveChain.NonceAt(context, nextAddr, nil)
if err != nil {
w.log.Warn("USB wallet nonce retrieval failed", "err", err)
break
}
// If the next account is empty, stop self-derivation, but add it nonetheless
if balance.Sign() == 0 && nonce == 0 {
empty = true
}
// We've just self-derived a new account, start tracking it locally
path := make(accounts.DerivationPath, len(nextPath))
copy(path[:], nextPath[:])
paths = append(paths, path)
account := accounts.Account{
Address: nextAddr,
URL: accounts.URL{Scheme: w.url.Scheme, Path: fmt.Sprintf("%s/%s", w.url.Path, path)},
}
accs = append(accs, account)
// Display a log message to the user for new (or previously empty accounts)
if _, known := w.paths[nextAddr]; !known || (!empty && nextAddr == w.deriveNextAddr) {
w.log.Info("USB wallet discovered new account", "address", nextAddr, "path", path, "balance", balance, "nonce", nonce)
}
// Fetch the next potential account
if !empty {
nextAddr = common.Address{}
nextPath[len(nextPath)-1]++
}
}
// Self derivation complete, release device lock
w.commsLock <- struct{}{}
w.stateLock.RUnlock()
// Insert any accounts successfully derived
w.stateLock.Lock()
for i := 0; i < len(accs); i++ {
if _, ok := w.paths[accs[i].Address]; !ok {
w.accounts = append(w.accounts, accs[i])
w.paths[accs[i].Address] = paths[i]
}
}
// Shift the self-derivation forward
// TODO(karalabe): don't overwrite changes from wallet.SelfDerive
w.deriveNextAddr = nextAddr
w.deriveNextPath = nextPath
w.stateLock.Unlock()
// Notify the user of termination and loop after a bit of time (to avoid trashing)
reqc <- struct{}{}
if err == nil {
select {
case errc = <-w.deriveQuit:
// Termination requested, abort
case <-time.After(selfDeriveThrottling):
// Waited enough, willing to self-derive again
}
}
}
// In case of error, wait for termination
if err != nil {
w.log.Debug("USB wallet self-derivation failed", "err", err)
errc = <-w.deriveQuit
}
errc <- err
}
// Contains implements accounts.Wallet, returning whether a particular account is
// or is not pinned into this wallet instance. Although we could attempt to resolve
// unpinned accounts, that would be an non-negligible hardware operation.
func (w *wallet) Contains(account accounts.Account) bool {
w.stateLock.RLock()
defer w.stateLock.RUnlock()
_, exists := w.paths[account.Address]
return exists
}
// Derive implements accounts.Wallet, deriving a new account at the specific
// derivation path. If pin is set to true, the account will be added to the list
// of tracked accounts.
func (w *wallet) Derive(path accounts.DerivationPath, pin bool) (accounts.Account, error) {
// Try to derive the actual account and update its URL if successful
w.stateLock.RLock() // Avoid device disappearing during derivation
if w.device == nil {
w.stateLock.RUnlock()
return accounts.Account{}, accounts.ErrWalletClosed
}
<-w.commsLock // Avoid concurrent hardware access
address, err := w.driver.Derive(path)
w.commsLock <- struct{}{}
w.stateLock.RUnlock()
// If an error occurred or no pinning was requested, return
if err != nil {
return accounts.Account{}, err
}
account := accounts.Account{
Address: address,
URL: accounts.URL{Scheme: w.url.Scheme, Path: fmt.Sprintf("%s/%s", w.url.Path, path)},
}
if !pin {
return account, nil
}
// Pinning needs to modify the state
w.stateLock.Lock()
defer w.stateLock.Unlock()
if _, ok := w.paths[address]; !ok {
w.accounts = append(w.accounts, account)
w.paths[address] = path
}
return account, nil
}
// SelfDerive implements accounts.Wallet, trying to discover accounts that the
// user used previously (based on the chain state), but ones that he/she did not
// explicitly pin to the wallet manually. To avoid chain head monitoring, self
// derivation only runs during account listing (and even then throttled).
func (w *wallet) SelfDerive(base accounts.DerivationPath, chain ethereum.ChainStateReader) {
w.stateLock.Lock()
defer w.stateLock.Unlock()
w.deriveNextPath = make(accounts.DerivationPath, len(base))
copy(w.deriveNextPath[:], base[:])
w.deriveNextAddr = common.Address{}
w.deriveChain = chain
}
// signHash implements accounts.Wallet, however signing arbitrary data is not
// supported for hardware wallets, so this method will always return an error.
func (w *wallet) signHash(account accounts.Account, hash []byte) ([]byte, error) {
return nil, accounts.ErrNotSupported
}
// SignData signs keccak256(data). The mimetype parameter describes the type of data being signed
func (w *wallet) SignData(account accounts.Account, mimeType string, data []byte) ([]byte, error) {
return w.signHash(account, crypto.Keccak256(data))
}
// SignDataWithPassphrase implements accounts.Wallet, attempting to sign the given
// data with the given account using passphrase as extra authentication.
// Since USB wallets don't rely on passphrases, these are silently ignored.
func (w *wallet) SignDataWithPassphrase(account accounts.Account, passphrase, mimeType string, data []byte) ([]byte, error) {
return w.SignData(account, mimeType, data)
}
func (w *wallet) SignText(account accounts.Account, text []byte) ([]byte, error) {
return w.signHash(account, accounts.TextHash(text))
}
// SignTx implements accounts.Wallet. It sends the transaction over to the Ledger
// wallet to request a confirmation from the user. It returns either the signed
// transaction or a failure if the user denied the transaction.
//
// Note, if the version of the Ethereum application running on the Ledger wallet is
// too old to sign EIP-155 transactions, but such is requested nonetheless, an error
// will be returned opposed to silently signing in Homestead mode.
func (w *wallet) SignTx(account accounts.Account, tx *types.Transaction, chainID *big.Int) (*types.Transaction, error) {
w.stateLock.RLock() // Comms have own mutex, this is for the state fields
defer w.stateLock.RUnlock()
// If the wallet is closed, abort
if w.device == nil {
return nil, accounts.ErrWalletClosed
}
// Make sure the requested account is contained within
path, ok := w.paths[account.Address]
if !ok {
return nil, accounts.ErrUnknownAccount
}
// All infos gathered and metadata checks out, request signing
<-w.commsLock
defer func() { w.commsLock <- struct{}{} }()
// Ensure the device isn't screwed with while user confirmation is pending
// TODO(karalabe): remove if hotplug lands on Windows
w.hub.commsLock.Lock()
w.hub.commsPend++
w.hub.commsLock.Unlock()
defer func() {
w.hub.commsLock.Lock()
w.hub.commsPend--
w.hub.commsLock.Unlock()
}()
// Sign the transaction and verify the sender to avoid hardware fault surprises
sender, signed, err := w.driver.SignTx(path, tx, chainID)
if err != nil {
return nil, err
}
if sender != account.Address {
return nil, fmt.Errorf("signer mismatch: expected %s, got %s", account.Address.Hex(), sender.Hex())
}
return signed, nil
}
// SignHashWithPassphrase implements accounts.Wallet, however signing arbitrary
// data is not supported for Ledger wallets, so this method will always return
// an error.
func (w *wallet) SignTextWithPassphrase(account accounts.Account, passphrase string, text []byte) ([]byte, error) {
return w.SignText(account, accounts.TextHash(text))
}
// SignTxWithPassphrase implements accounts.Wallet, attempting to sign the given
// transaction with the given account using passphrase as extra authentication.
// Since USB wallets don't rely on passphrases, these are silently ignored.
func (w *wallet) SignTxWithPassphrase(account accounts.Account, passphrase string, tx *types.Transaction, chainID *big.Int) (*types.Transaction, error) {
return w.SignTx(account, tx, chainID)
}