status-go/geth/txqueue/txqueue_manager.go

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package txqueue
import (
"context"
"math/big"
"time"
"github.com/ethereum/go-ethereum/accounts/keystore"
gethcommon "github.com/ethereum/go-ethereum/common"
"github.com/ethereum/go-ethereum/common/hexutil"
"github.com/ethereum/go-ethereum/core/types"
"github.com/ethereum/go-ethereum/les/status"
"github.com/ethereum/go-ethereum/rlp"
"github.com/pborman/uuid"
"github.com/status-im/status-go/geth/common"
"github.com/status-im/status-go/geth/log"
"github.com/status-im/status-go/geth/signal"
)
const (
// EventTransactionQueued is triggered when send transaction request is queued
EventTransactionQueued = "transaction.queued"
// EventTransactionFailed is triggered when send transaction request fails
EventTransactionFailed = "transaction.failed"
// SendTxDefaultErrorCode is sent by default, when error is not nil, but type is unknown/unexpected.
SendTxDefaultErrorCode = SendTransactionDefaultErrorCode
)
// Send transaction response codes
const (
SendTransactionNoErrorCode = "0"
SendTransactionDefaultErrorCode = "1"
SendTransactionPasswordErrorCode = "2"
SendTransactionTimeoutErrorCode = "3"
SendTransactionDiscardedErrorCode = "4"
)
var txReturnCodes = map[error]string{ // deliberately strings, in case more meaningful codes are to be returned
nil: SendTransactionNoErrorCode,
keystore.ErrDecrypt: SendTransactionPasswordErrorCode,
ErrQueuedTxTimedOut: SendTransactionTimeoutErrorCode,
ErrQueuedTxDiscarded: SendTransactionDiscardedErrorCode,
}
// Manager provides means to manage internal Status Backend (injected into LES)
type Manager struct {
nodeManager common.NodeManager
accountManager common.AccountManager
txQueue *TxQueue
}
// NewManager returns a new Manager.
func NewManager(nodeManager common.NodeManager, accountManager common.AccountManager) *Manager {
return &Manager{
nodeManager: nodeManager,
accountManager: accountManager,
txQueue: NewTransactionQueue(),
}
}
// Start starts accepting new transactions into the queue.
func (m *Manager) Start() {
log.Info("start Manager")
m.txQueue.Start()
}
// Stop stops accepting new transactions into the queue.
func (m *Manager) Stop() {
log.Info("stop Manager")
m.txQueue.Stop()
}
// TransactionQueue returns a reference to the queue.
func (m *Manager) TransactionQueue() common.TxQueue {
return m.txQueue
}
// CreateTransaction returns a transaction object.
func (m *Manager) CreateTransaction(ctx context.Context, args common.SendTxArgs) *common.QueuedTx {
return &common.QueuedTx{
ID: common.QueuedTxID(uuid.New()),
Hash: gethcommon.Hash{},
Context: ctx,
Args: args,
Done: make(chan struct{}, 1),
Discard: make(chan struct{}, 1),
}
}
// QueueTransaction puts a transaction into the queue.
func (m *Manager) QueueTransaction(tx *common.QueuedTx) error {
to := "<nil>"
if tx.Args.To != nil {
to = tx.Args.To.Hex()
}
log.Info("queue a new transaction", "id", tx.ID, "from", tx.Args.From.Hex(), "to", to)
return m.txQueue.Enqueue(tx)
}
// WaitForTransaction adds a transaction to the queue and blocks
// until it's completed, discarded or times out.
func (m *Manager) WaitForTransaction(tx *common.QueuedTx) error {
log.Info("wait for transaction", "id", tx.ID)
// now wait up until transaction is:
// - completed (via CompleteQueuedTransaction),
// - discarded (via DiscardQueuedTransaction)
// - or times out
select {
case <-tx.Done:
m.NotifyOnQueuedTxReturn(tx, tx.Err)
return tx.Err
case <-tx.Discard:
m.NotifyOnQueuedTxReturn(tx, ErrQueuedTxDiscarded)
return ErrQueuedTxDiscarded
case <-time.After(DefaultTxSendCompletionTimeout * time.Second):
m.NotifyOnQueuedTxReturn(tx, ErrQueuedTxTimedOut)
return ErrQueuedTxTimedOut
}
}
// NotifyOnQueuedTxReturn calls a handler when a transaction resolves.
func (m *Manager) NotifyOnQueuedTxReturn(queuedTx *common.QueuedTx, err error) {
m.txQueue.NotifyOnQueuedTxReturn(queuedTx, err)
}
// CompleteTransaction instructs backend to complete sending of a given transaction.
// TODO(adam): investigate a possible bug that calling this method multiple times with the same Transaction ID
// results in sending multiple transactions.
func (m *Manager) CompleteTransaction(id common.QueuedTxID, password string) (gethcommon.Hash, error) {
log.Info("complete transaction", "id", id)
queuedTx, err := m.txQueue.Get(id)
if err != nil {
log.Warn("could not get a queued transaction", "err", err)
return gethcommon.Hash{}, err
}
if err := m.txQueue.StartProcessing(queuedTx); err != nil {
return gethcommon.Hash{}, err
}
defer m.txQueue.StopProcessing(queuedTx)
selectedAccount, err := m.accountManager.SelectedAccount()
if err != nil {
log.Warn("failed to get a selected account", "err", err)
return gethcommon.Hash{}, err
}
// make sure that only account which created the tx can complete it
if queuedTx.Args.From.Hex() != selectedAccount.Address.Hex() {
log.Warn("queued transaction does not belong to the selected account", "err", ErrInvalidCompleteTxSender)
m.NotifyOnQueuedTxReturn(queuedTx, ErrInvalidCompleteTxSender)
return gethcommon.Hash{}, ErrInvalidCompleteTxSender
}
config, err := m.nodeManager.NodeConfig()
if err != nil {
log.Warn("could not get a node config", "err", err)
return gethcommon.Hash{}, err
}
// Send the transaction finally.
var hash gethcommon.Hash
var txErr error
if config.UpstreamConfig.Enabled {
hash, txErr = m.completeRemoteTransaction(queuedTx, password)
} else {
hash, txErr = m.completeLocalTransaction(queuedTx, password)
}
// when incorrect sender tries to complete the account,
// notify and keep tx in queue (so that correct sender can complete)
if txErr == keystore.ErrDecrypt {
log.Warn("failed to complete transaction", "err", txErr)
m.NotifyOnQueuedTxReturn(queuedTx, txErr)
return hash, txErr
}
log.Info("finally completed transaction", "id", queuedTx.ID, "hash", hash, "err", txErr)
queuedTx.Hash = hash
queuedTx.Err = txErr
queuedTx.Done <- struct{}{}
return hash, txErr
}
func (m *Manager) completeLocalTransaction(queuedTx *common.QueuedTx, password string) (gethcommon.Hash, error) {
log.Info("complete transaction using local node", "id", queuedTx.ID)
les, err := m.nodeManager.LightEthereumService()
if err != nil {
return gethcommon.Hash{}, err
}
return les.StatusBackend.SendTransaction(context.Background(), status.SendTxArgs(queuedTx.Args), password)
}
func (m *Manager) completeRemoteTransaction(queuedTx *common.QueuedTx, password string) (gethcommon.Hash, error) {
log.Info("complete transaction using upstream node", "id", queuedTx.ID)
var emptyHash gethcommon.Hash
config, err := m.nodeManager.NodeConfig()
if err != nil {
return emptyHash, err
}
selectedAcct, err := m.accountManager.SelectedAccount()
if err != nil {
return emptyHash, err
}
if _, err := m.accountManager.VerifyAccountPassword(
config.KeyStoreDir,
selectedAcct.Address.String(),
password,
); err != nil {
2017-10-10 09:38:49 +00:00
log.Warn("failed to verify account", "account", selectedAcct.Address.String(), "error", err.Error())
return emptyHash, err
}
// We need to request a new transaction nounce from upstream node.
ctx, cancel := context.WithTimeout(context.Background(), time.Minute)
defer cancel()
var txCount hexutil.Uint
client := m.nodeManager.RPCClient()
if err := client.CallContext(ctx, &txCount, "eth_getTransactionCount", queuedTx.Args.From, "pending"); err != nil {
return emptyHash, err
}
args := queuedTx.Args
if args.GasPrice == nil {
value, err := m.gasPrice()
if err != nil {
return emptyHash, err
}
args.GasPrice = value
}
chainID := big.NewInt(int64(config.NetworkID))
nonce := uint64(txCount)
gasPrice := (*big.Int)(args.GasPrice)
data := []byte(args.Data)
value := (*big.Int)(args.Value)
toAddr := gethcommon.Address{}
if args.To != nil {
toAddr = *args.To
}
gas, err := m.estimateGas(args)
if err != nil {
return emptyHash, err
}
log.Info(
"preparing raw transaction",
"from", args.From.Hex(),
"to", toAddr.Hex(),
"gas", gas,
"gasPrice", gasPrice,
"value", value,
)
tx := types.NewTransaction(nonce, toAddr, value, (*big.Int)(gas), gasPrice, data)
signedTx, err := types.SignTx(tx, types.NewEIP155Signer(chainID), selectedAcct.AccountKey.PrivateKey)
if err != nil {
return emptyHash, err
}
txBytes, err := rlp.EncodeToBytes(signedTx)
if err != nil {
return emptyHash, err
}
ctx2, cancel2 := context.WithTimeout(context.Background(), time.Minute)
defer cancel2()
if err := client.CallContext(ctx2, nil, "eth_sendRawTransaction", gethcommon.ToHex(txBytes)); err != nil {
return emptyHash, err
}
return signedTx.Hash(), nil
}
func (m *Manager) estimateGas(args common.SendTxArgs) (*hexutil.Big, error) {
if args.Gas != nil {
return args.Gas, nil
}
client := m.nodeManager.RPCClient()
ctx, cancel := context.WithTimeout(context.Background(), time.Minute)
defer cancel()
var gasPrice hexutil.Big
if args.GasPrice != nil {
gasPrice = (hexutil.Big)(*args.GasPrice)
}
var value hexutil.Big
if args.Value != nil {
value = (hexutil.Big)(*args.Value)
}
params := struct {
From gethcommon.Address `json:"from"`
To *gethcommon.Address `json:"to"`
Gas hexutil.Big `json:"gas"`
GasPrice hexutil.Big `json:"gasPrice"`
Value hexutil.Big `json:"value"`
Data hexutil.Bytes `json:"data"`
}{
From: args.From,
To: args.To,
GasPrice: gasPrice,
Value: value,
Data: []byte(args.Data),
}
var estimatedGas hexutil.Big
if err := client.CallContext(
ctx,
&estimatedGas,
"eth_estimateGas",
params,
); err != nil {
log.Warn("failed to estimate gas", "err", err)
return nil, err
}
return &estimatedGas, nil
}
func (m *Manager) gasPrice() (*hexutil.Big, error) {
client := m.nodeManager.RPCClient()
ctx, cancel := context.WithTimeout(context.Background(), time.Minute)
defer cancel()
var gasPrice hexutil.Big
if err := client.CallContext(ctx, &gasPrice, "eth_gasPrice"); err != nil {
log.Warn("failed to get gas price", "err", err)
return nil, err
}
return &gasPrice, nil
}
// CompleteTransactions instructs backend to complete sending of multiple transactions
func (m *Manager) CompleteTransactions(ids []common.QueuedTxID, password string) map[common.QueuedTxID]common.RawCompleteTransactionResult {
results := make(map[common.QueuedTxID]common.RawCompleteTransactionResult)
for _, txID := range ids {
txHash, txErr := m.CompleteTransaction(txID, password)
results[txID] = common.RawCompleteTransactionResult{
Hash: txHash,
Error: txErr,
}
}
return results
}
// DiscardTransaction discards a given transaction from transaction queue
func (m *Manager) DiscardTransaction(id common.QueuedTxID) error {
queuedTx, err := m.txQueue.Get(id)
if err != nil {
return err
}
// remove from queue, before notifying SendTransaction
m.txQueue.Remove(queuedTx.ID)
// allow SendTransaction to return
queuedTx.Err = ErrQueuedTxDiscarded
queuedTx.Discard <- struct{}{} // sendTransaction() waits on this, notify so that it can return
return nil
}
// DiscardTransactions discards given multiple transactions from transaction queue
func (m *Manager) DiscardTransactions(ids []common.QueuedTxID) map[common.QueuedTxID]common.RawDiscardTransactionResult {
results := make(map[common.QueuedTxID]common.RawDiscardTransactionResult)
for _, txID := range ids {
err := m.DiscardTransaction(txID)
if err != nil {
results[txID] = common.RawDiscardTransactionResult{
Error: err,
}
}
}
return results
}
// SendTransactionEvent is a signal sent on a send transaction request
type SendTransactionEvent struct {
ID string `json:"id"`
Args common.SendTxArgs `json:"args"`
MessageID string `json:"message_id"`
}
// TransactionQueueHandler returns handler that processes incoming tx queue requests
func (m *Manager) TransactionQueueHandler() func(queuedTx *common.QueuedTx) {
return func(queuedTx *common.QueuedTx) {
log.Info("calling TransactionQueueHandler")
signal.Send(signal.Envelope{
Type: EventTransactionQueued,
Event: SendTransactionEvent{
ID: string(queuedTx.ID),
Args: queuedTx.Args,
MessageID: common.MessageIDFromContext(queuedTx.Context),
},
})
}
}
// SetTransactionQueueHandler sets a handler that will be called
// when a new transaction is enqueued.
func (m *Manager) SetTransactionQueueHandler(fn common.EnqueuedTxHandler) {
m.txQueue.SetEnqueueHandler(fn)
}
// ReturnSendTransactionEvent is a JSON returned whenever transaction send is returned
type ReturnSendTransactionEvent struct {
ID string `json:"id"`
Args common.SendTxArgs `json:"args"`
MessageID string `json:"message_id"`
ErrorMessage string `json:"error_message"`
ErrorCode string `json:"error_code"`
}
// TransactionReturnHandler returns handler that processes responses from internal tx manager
func (m *Manager) TransactionReturnHandler() func(queuedTx *common.QueuedTx, err error) {
return func(queuedTx *common.QueuedTx, err error) {
if err == nil {
return
}
// discard notifications with empty tx
if queuedTx == nil {
return
}
// error occurred, signal up to application
signal.Send(signal.Envelope{
Type: EventTransactionFailed,
Event: ReturnSendTransactionEvent{
ID: string(queuedTx.ID),
Args: queuedTx.Args,
MessageID: common.MessageIDFromContext(queuedTx.Context),
ErrorMessage: err.Error(),
ErrorCode: m.sendTransactionErrorCode(err),
},
})
}
}
func (m *Manager) sendTransactionErrorCode(err error) string {
if code, ok := txReturnCodes[err]; ok {
return code
}
return SendTxDefaultErrorCode
}
// SetTransactionReturnHandler sets a handler that will be called
// when a transaction is about to return or when a recoverable error occured.
// Recoverable error is, for instance, wrong password.
func (m *Manager) SetTransactionReturnHandler(fn common.EnqueuedTxReturnHandler) {
m.txQueue.SetTxReturnHandler(fn)
}
// SendTransactionRPCHandler is a handler for eth_sendTransaction method.
// It accepts one param which is a slice with a map of transaction params.
func (m *Manager) SendTransactionRPCHandler(ctx context.Context, args ...interface{}) (interface{}, error) {
log.Info("SendTransactionRPCHandler called")
// TODO(adam): it's a hack to parse arguments as common.RPCCall can do that.
// We should refactor parsing these params to a separate struct.
rpcCall := common.RPCCall{Params: args}
tx := m.CreateTransaction(ctx, rpcCall.ToSendTxArgs())
if err := m.QueueTransaction(tx); err != nil {
return nil, err
}
if err := m.WaitForTransaction(tx); err != nil {
return nil, err
}
return tx.Hash.Hex(), nil
}