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transaction_injector.go
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transaction_injector.go
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package simulation
import (
"context"
"encoding/json"
"fmt"
"math/big"
"math/rand"
"sync/atomic"
"time"
"github.com/FantasyJony/openzeppelin-merkle-tree-go/standard_merkle_tree"
"github.com/ethereum/go-ethereum/accounts/abi/bind"
"github.com/ethereum/go-ethereum/core/types"
"github.com/ethereum/go-ethereum/crypto"
"github.com/ethereum/go-ethereum/crypto/ecies"
"github.com/ten-protocol/go-ten/contracts/generated/ManagementContract"
"github.com/ten-protocol/go-ten/contracts/generated/MessageBus"
"github.com/ten-protocol/go-ten/go/common"
"github.com/ten-protocol/go-ten/go/common/log"
"github.com/ten-protocol/go-ten/go/enclave/crosschain"
"github.com/ten-protocol/go-ten/go/ethadapter/erc20contractlib"
"github.com/ten-protocol/go-ten/go/ethadapter/mgmtcontractlib"
"github.com/ten-protocol/go-ten/go/wallet"
"github.com/ten-protocol/go-ten/integration"
"github.com/ten-protocol/go-ten/integration/common/testlog"
"github.com/ten-protocol/go-ten/integration/datagenerator"
"github.com/ten-protocol/go-ten/integration/simulation/network"
"github.com/ten-protocol/go-ten/integration/simulation/params"
"golang.org/x/sync/errgroup"
gethcommon "github.com/ethereum/go-ethereum/common"
gethlog "github.com/ethereum/go-ethereum/log"
testcommon "github.com/ten-protocol/go-ten/integration/common"
simstats "github.com/ten-protocol/go-ten/integration/simulation/stats"
)
const (
nonceTimeoutMillis = 30000 // The timeout in millis to wait for an updated nonce for a wallet.
// EnclavePublicKeyHex is the public key of the enclave.
// todo (@stefan) - retrieve this key from the management contract instead
EnclavePublicKeyHex = "034d3b7e63a8bcd532ee3d1d6ecad9d67fca7821981a044551f0f0cbec74d0bc5e"
)
// TransactionInjector is a structure that generates, issues and tracks transactions
type TransactionInjector struct {
// counters
TxTracker *txInjectorTracker
stats *simstats.Stats
// settings
avgBlockDuration time.Duration
// wallets
wallets *params.SimWallets
// connections
rpcHandles *network.RPCHandles
// addrs and libs
mgmtContractAddr *gethcommon.Address
mgmtContractLib mgmtcontractlib.MgmtContractLib
erc20ContractLib erc20contractlib.ERC20ContractLib
// controls
interruptRun *int32
fullyStoppedChan chan bool
enclavePublicKey *ecies.PublicKey
// The number of transactions of each type to issue, or 0 for unlimited transactions
txsToIssue int
// context for the transaction injector so in-flight requests can be cancelled gracefully
ctx context.Context
params *params.SimParams
logger gethlog.Logger
}
// NewTransactionInjector returns a transaction manager with a given number of obsWallets
func NewTransactionInjector(
avgBlockDuration time.Duration,
stats *simstats.Stats,
rpcHandles *network.RPCHandles,
wallets *params.SimWallets,
mgmtContractAddr *gethcommon.Address,
mgmtContractLib mgmtcontractlib.MgmtContractLib,
erc20ContractLib erc20contractlib.ERC20ContractLib,
txsToIssue int,
params *params.SimParams,
) *TransactionInjector {
interrupt := int32(0)
// We retrieve the enclave public key to encrypt transactions.
enclavePublicKey, err := crypto.DecompressPubkey(gethcommon.Hex2Bytes(EnclavePublicKeyHex))
if err != nil {
panic(fmt.Errorf("could not decompress enclave public key from hex. Cause: %w", err))
}
enclavePublicKeyEcies := ecies.ImportECDSAPublic(enclavePublicKey)
return &TransactionInjector{
avgBlockDuration: avgBlockDuration,
stats: stats,
rpcHandles: rpcHandles,
interruptRun: &interrupt,
fullyStoppedChan: make(chan bool, 1),
mgmtContractAddr: mgmtContractAddr,
mgmtContractLib: mgmtContractLib,
erc20ContractLib: erc20ContractLib,
wallets: wallets,
TxTracker: newCounter(),
enclavePublicKey: enclavePublicKeyEcies,
txsToIssue: txsToIssue,
params: params,
ctx: context.Background(), // for now we create a new context here, should allow it to be passed in
logger: testlog.Logger().New(log.CmpKey, log.TxInjectCmp),
}
}
// Start begins the execution on the TransactionInjector
// Deposits an initial balance in to each wallet
// Generates and issues L1 and L2 transactions to the network
func (ti *TransactionInjector) Start() {
var wg errgroup.Group
wg.Go(func() error {
ti.issueRandomDeposits()
return nil
})
wg.Go(func() error {
ti.issueRandomWithdrawals()
return nil
})
// in mem sim does not support the contract libraries required
// to do complex bridge transactions
if !ti.params.IsInMem {
wg.Go(func() error {
ti.bridgeRandomGasTransfers()
return nil
})
}
wg.Go(func() error {
ti.issueRandomTransfers()
return nil
})
wg.Go(func() error {
ti.issueRandomValueTransfers()
return nil
})
wg.Go(func() error {
ti.issueInvalidL2Txs()
return nil
})
_ = wg.Wait() // future proofing to return errors
ti.fullyStoppedChan <- true
}
func (ti *TransactionInjector) Stop() {
atomic.StoreInt32(ti.interruptRun, 1)
for range ti.fullyStoppedChan {
ti.logger.Info("TransactionInjector stopped successfully")
return
}
}
// issueRandomValueTransfers creates and issues a number of L2 value transfer transactions proportional to the simulation time, such that they can be processed
func (ti *TransactionInjector) issueRandomValueTransfers() {
for txCounter := 0; ti.shouldKeepIssuing(txCounter); txCounter++ {
fromWallet := ti.rndObsWallet()
toWallet := ti.rndObsWallet()
obscuroClient := ti.rpcHandles.ObscuroWalletRndClient(fromWallet)
// We avoid transfers to self, unless there is only a single L2 wallet.
for len(ti.wallets.SimObsWallets) > 1 && fromWallet.Address().Hex() == toWallet.Address().Hex() {
toWallet = ti.rndObsWallet()
}
toWalletAddr := toWallet.Address()
txData := &types.LegacyTx{
Nonce: fromWallet.GetNonceAndIncrement(),
Value: big.NewInt(int64(testcommon.RndBtw(1, 100))),
Gas: uint64(50_000),
GasPrice: gethcommon.Big1,
To: &toWalletAddr,
}
tx := obscuroClient.EstimateGasAndGasPrice(txData)
signedTx, err := fromWallet.SignTransaction(tx)
if err != nil {
panic(err)
}
ti.logger.Info("Native value transfer transaction injected into L2.", log.TxKey, signedTx.Hash(), "fromAddress", fromWallet.Address(), "toAddress", toWallet.Address())
ti.stats.NativeTransfer()
err = obscuroClient.SendTransaction(ti.ctx, signedTx)
if err != nil {
ti.logger.Info("Failed to issue transfer via RPC.", log.ErrKey, err)
continue
}
// todo (@pedro) - retrieve receipt
go ti.TxTracker.trackNativeValueTransferL2Tx(signedTx)
sleepRndBtw(ti.avgBlockDuration/10, ti.avgBlockDuration/4)
}
}
// issueRandomTransfers creates and issues a number of L2 transfer transactions proportional to the simulation time, such that they can be processed
func (ti *TransactionInjector) issueRandomTransfers() {
for txCounter := 0; ti.shouldKeepIssuing(txCounter); txCounter++ {
fromWallet := ti.rndObsWallet()
toWallet := ti.rndObsWallet()
obscuroClient := ti.rpcHandles.ObscuroWalletRndClient(fromWallet)
// We avoid transfers to self, unless there is only a single L2 wallet.
for len(ti.wallets.SimObsWallets) > 1 && fromWallet.Address().Hex() == toWallet.Address().Hex() {
toWallet = ti.rndObsWallet()
}
tx := ti.newObscuroTransferTx(fromWallet, toWallet.Address(), testcommon.RndBtw(1, 500), testcommon.HOC)
tx = obscuroClient.EstimateGasAndGasPrice(tx)
signedTx, err := fromWallet.SignTransaction(tx)
if err != nil {
panic(err)
}
ti.logger.Info("Transfer transaction injected into L2.", log.TxKey, signedTx.Hash(), "fromAddress", fromWallet.Address(), "toAddress", toWallet.Address())
ti.stats.Transfer()
err = obscuroClient.SendTransaction(ti.ctx, signedTx)
if err != nil {
ti.logger.Info("Failed to issue transfer via RPC.", log.ErrKey, err)
}
// todo (@pedro) - retrieve receipt
go ti.TxTracker.trackTransferL2Tx(signedTx)
sleepRndBtw(ti.avgBlockDuration/100, ti.avgBlockDuration/20)
}
}
func (ti *TransactionInjector) bridgeRandomGasTransfers() {
gasWallet := ti.wallets.GasBridgeWallet
ethClient := ti.rpcHandles.RndEthClient()
mgmtCtr, err := ManagementContract.NewManagementContract(*ti.mgmtContractAddr, ethClient.EthClient())
if err != nil {
panic(err)
}
busAddr, err := mgmtCtr.MessageBus(&bind.CallOpts{})
if err != nil {
panic(err)
}
for txCounter := 0; ti.shouldKeepIssuing(txCounter); txCounter++ {
ethClient = ti.rpcHandles.RndEthClient()
busCtr, err := MessageBus.NewMessageBus(busAddr, ethClient.EthClient())
if err != nil {
panic(err)
}
opts, err := bind.NewKeyedTransactorWithChainID(gasWallet.PrivateKey(), gasWallet.ChainID())
if err != nil {
panic(err)
}
receiverWallet := datagenerator.RandomWallet(ti.rndObsWallet().ChainID().Int64())
amount := big.NewInt(0).SetUint64(testcommon.RndBtw(500, 100_000))
opts.Value = big.NewInt(0).Set(amount)
tx, err := busCtr.SendValueToL2(opts, receiverWallet.Address(), amount)
if err != nil {
panic(err)
}
go ti.TxTracker.trackGasBridgingTx(tx, receiverWallet)
sleepRndBtw(ti.avgBlockDuration/3, ti.avgBlockDuration)
}
}
// issueRandomDeposits creates and issues a number of transactions proportional to the simulation time, such that they can be processed
func (ti *TransactionInjector) issueRandomDeposits() {
// todo (@stefan) - this implementation transfers from the hoc and poc owner contracts
// a better implementation should use the bridge
for txCounter := 0; ti.shouldKeepIssuing(txCounter); txCounter++ {
fromWalletToken := testcommon.HOC
if txCounter%2 == 0 {
fromWalletToken = testcommon.POC
}
fromWallet := ti.wallets.Tokens[fromWalletToken].L2Owner
toWallet := ti.rndObsWallet()
obscuroClient := ti.rpcHandles.ObscuroWalletRndClient(fromWallet)
v := testcommon.RndBtw(500, 2000)
txData := ti.newObscuroTransferTx(fromWallet, toWallet.Address(), v, fromWalletToken)
tx := obscuroClient.EstimateGasAndGasPrice(txData)
signedTx, err := fromWallet.SignTransaction(tx)
if err != nil {
panic(err)
}
ti.logger.Info("Deposit transaction injected into L2.", log.TxKey, signedTx.Hash(), "fromAddress", fromWallet.Address(), "toAddress", toWallet.Address())
ti.stats.Deposit(big.NewInt(int64(v)))
err = obscuroClient.SendTransaction(ti.ctx, signedTx)
if err != nil {
ti.logger.Info("Failed to issue deposit via RPC.", log.ErrKey, err)
} else {
go ti.TxTracker.trackTransferL2Tx(signedTx)
}
// todo (@pedro) - retrieve receipt
sleepRndBtw(ti.avgBlockDuration/3, ti.avgBlockDuration)
}
// todo (@stefan) - rework this when old contract deployer is phased out?
}
func (ti *TransactionInjector) awaitAndFinalizeWithdrawal(tx *types.Transaction, fromWallet wallet.Wallet) {
if ti.mgmtContractLib.IsMock() {
return
}
err := testcommon.AwaitReceipt(ti.ctx, ti.rpcHandles.ObscuroWalletRndClient(fromWallet), tx.Hash(), 30*time.Second)
if err != nil {
ti.logger.Error("Failed to await receipt for withdrawal transaction", log.ErrKey, err)
return
}
receipt, err := ti.rpcHandles.ObscuroWalletRndClient(fromWallet).TransactionReceipt(ti.ctx, tx.Hash())
if err != nil {
ti.logger.Error("Failed to retrieve receipt for withdrawal transaction", log.ErrKey, err)
return
}
header, err := ti.rpcHandles.ObscuroWalletRndClient(fromWallet).GetBatchHeaderByHash(receipt.BlockHash)
if err != nil {
ti.logger.Error("Failed to retrieve batch header for withdrawal transaction", log.ErrKey, err)
return
}
xchainTree := make([][]interface{}, 0) // ["v", "0xblablablabla"]
err = json.Unmarshal(header.CrossChainTree, &xchainTree)
if err != nil {
ti.logger.Error("Failed to unmarshal cross chain tree for withdrawal transaction", log.ErrKey, err)
return
}
for k, value := range xchainTree {
xchainTree[k][1] = gethcommon.HexToHash(value[1].(string))
}
tree, err := standard_merkle_tree.Of(xchainTree, crosschain.CrossChainEncodings)
if err != nil {
ti.logger.Error("Failed to load cross chain tree for withdrawal transaction", log.ErrKey, err)
return
}
if gethcommon.BytesToHash(tree.GetRoot()) != header.CrossChainRoot {
ti.logger.Error("Root of cross chain tree does not match header", "expected", header.CrossChainRoot, "actual", gethcommon.BytesToHash(tree.GetRoot()))
return
}
if len(receipt.Logs) != 1 {
panic("unexpected number of logs in receipt")
}
logs := make([]types.Log, len(receipt.Logs))
for i, log := range receipt.Logs {
logs[i] = *log
}
transfers, err := crosschain.ConvertLogsToValueTransfers(logs, crosschain.ValueTransferEventName, crosschain.MessageBusABI)
if err != nil {
panic(err)
}
vTransfers := crosschain.ValueTransfers(transfers)
proof, err := tree.GetProof(vTransfers.ForMerkleTree()[0])
if err != nil {
panic("unable to get proof for value transfer")
}
if len(proof) == 0 {
return
}
mCtr, err := ManagementContract.NewManagementContract(*ti.mgmtContractAddr, ti.rpcHandles.RndEthClient().EthClient())
if err != nil {
panic(err)
}
opts, err := bind.NewKeyedTransactorWithChainID(ti.wallets.GasWithdrawalWallet.PrivateKey(), ti.wallets.GasWithdrawalWallet.ChainID())
if err != nil {
panic(err)
}
proof32 := make([][32]byte, 0)
for i := 0; i < len(proof); i++ {
proof32 = append(proof32, [32]byte(proof[i][0:32]))
}
time.Sleep(20 * time.Second)
oldBalance, err := ti.rpcHandles.RndEthClient().BalanceAt(vTransfers[0].Receiver, nil)
if err != nil {
ti.logger.Error("Failed to retrieve balance of receiver", log.ErrKey, err)
return
}
withdrawalTx, err := mCtr.ExtractNativeValue(opts, ManagementContract.StructsValueTransferMessage(vTransfers[0]), proof32, header.CrossChainRoot)
if err != nil {
ti.logger.Error("Failed to extract value transfer from L2", log.ErrKey, err)
return
}
receipt, err = testcommon.AwaitReceiptEth(ti.ctx, ti.rpcHandles.RndEthClient().EthClient(), withdrawalTx.Hash(), 30*time.Second)
if err != nil {
ti.logger.Error("Failed to await receipt for withdrawal transaction", log.ErrKey, err)
return
}
if receipt.Status != 1 {
ti.logger.Error("Withdrawal transaction failed", log.TxKey, withdrawalTx.Hash())
return
}
newBalance, err := ti.rpcHandles.RndEthClient().BalanceAt(vTransfers[0].Receiver, nil)
if err != nil {
ti.logger.Error("Failed to retrieve balance of receiver", log.ErrKey, err)
return
}
if newBalance.Sub(newBalance, oldBalance).Cmp(vTransfers[0].Amount) != 0 {
ti.logger.Error("Balance of receiver did not increase by the expected amount", "expected", vTransfers[0].Amount, "actual", newBalance.Sub(newBalance, oldBalance))
return
}
ti.logger.Info("Successful bridge withdrawal", log.TxKey, withdrawalTx.Hash())
}
// issueRandomWithdrawals creates and issues a number of transactions proportional to the simulation time, such that they can be processed
func (ti *TransactionInjector) issueRandomWithdrawals() {
// todo (@stefan) - rework this when old contract deployer is phased out?
msgBusAddr := gethcommon.HexToAddress("0x526c84529B2b8c11F57D93d3f5537aCA3AeCEf9B")
for txCounter := 0; ti.shouldKeepIssuing(txCounter); txCounter++ {
fromWallet := ti.rndObsWallet()
client := ti.rpcHandles.ObscuroWalletRndClient(fromWallet)
price, err := client.GasPrice(ti.ctx)
if err != nil {
ti.logger.Error("unable to estimate gas price", log.ErrKey, err)
continue
}
tx := &types.LegacyTx{
Nonce: fromWallet.GetNonceAndIncrement(),
Value: gethcommon.Big1,
Gas: uint64(1_000_000_000),
GasPrice: price,
Data: nil,
To: &msgBusAddr,
}
signedTx, err := fromWallet.SignTransaction(tx)
if err != nil {
ti.logger.Error("[CrossChain] unable to sign withdrawal transaction", log.ErrKey, err)
continue
}
err = client.SendTransaction(ti.ctx, signedTx)
if err != nil {
ti.logger.Error("[CrossChain] unable to send withdrawal transaction", log.ErrKey, err)
}
go ti.TxTracker.trackWithdrawalFromL2(signedTx)
ti.logger.Info("[CrossChain] successful withdrawal tx", log.TxKey, signedTx.Hash())
go ti.awaitAndFinalizeWithdrawal(signedTx, fromWallet)
time.Sleep(testcommon.RndBtwTime(ti.avgBlockDuration/4, ti.avgBlockDuration))
}
}
// issueInvalidL2Txs creates and issues invalidly-signed L2 transactions proportional to the simulation time.
// These transactions should be rejected by the nodes, and thus we expect them to not affect the simulation
func (ti *TransactionInjector) issueInvalidL2Txs() {
// todo (@tudor) - also issue transactions with insufficient gas
for txCounter := 0; ti.shouldKeepIssuing(txCounter); txCounter++ {
fromWallet := ti.rndObsWallet()
toWallet := ti.rndObsWallet()
// We avoid transfers to self, unless there is only a single L2 wallet.
for len(ti.wallets.SimObsWallets) > 1 && fromWallet.Address().Hex() == toWallet.Address().Hex() {
toWallet = ti.rndObsWallet()
}
txData := ti.newCustomObscuroWithdrawalTx(testcommon.RndBtw(1, 100))
tx := ti.rpcHandles.ObscuroWalletRndClient(fromWallet).EstimateGasAndGasPrice(txData)
signedTx := ti.createInvalidSignage(tx, fromWallet)
err := ti.rpcHandles.ObscuroWalletRndClient(fromWallet).SendTransaction(ti.ctx, signedTx)
if err != nil {
ti.logger.Info("Failed to issue withdrawal via RPC. ", log.ErrKey, err)
}
time.Sleep(testcommon.RndBtwTime(ti.avgBlockDuration/4, ti.avgBlockDuration))
}
}
// Uses one of the approaches to create an invalidly-signed transaction.
func (ti *TransactionInjector) createInvalidSignage(tx types.TxData, w wallet.Wallet) *types.Transaction {
switch rand.Intn(2) { //nolint:gosec
case 0: // We sign the transaction with a bad signer.
incorrectChainID := int64(integration.EthereumChainID + 1)
signer := types.NewLondonSigner(big.NewInt(incorrectChainID))
signedTx, _ := types.SignNewTx(w.PrivateKey(), signer, tx)
return signedTx
case 1: // We do not sign the transaction.
return types.NewTx(tx)
}
return nil
}
func (ti *TransactionInjector) rndObsWallet() wallet.Wallet {
return ti.wallets.SimObsWallets[rand.Intn(len(ti.wallets.SimObsWallets))] //nolint:gosec
}
func (ti *TransactionInjector) newObscuroTransferTx(from wallet.Wallet, dest gethcommon.Address, amount uint64, ercType testcommon.ERC20) types.TxData {
data := erc20contractlib.CreateTransferTxData(dest, common.ValueInWei(big.NewInt(int64(amount))))
return ti.newTx(data, from.GetNonceAndIncrement(), ercType)
}
func (ti *TransactionInjector) newCustomObscuroWithdrawalTx(amount uint64) types.TxData {
transferERC20data := erc20contractlib.CreateTransferTxData(testcommon.BridgeAddress, common.ValueInWei(big.NewInt(int64(amount))))
return ti.newTx(transferERC20data, 1, testcommon.HOC)
}
func (ti *TransactionInjector) newTx(data []byte, nonce uint64, ercType testcommon.ERC20) types.TxData {
return &types.LegacyTx{
Nonce: nonce,
Value: gethcommon.Big0,
Gas: uint64(1_000_000_000),
GasPrice: gethcommon.Big1,
Data: data,
To: ti.wallets.Tokens[ercType].L2ContractAddress,
}
}
// Indicates whether to keep issuing transactions, or halt.
func (ti *TransactionInjector) shouldKeepIssuing(txCounter int) bool {
isInterrupted := atomic.LoadInt32(ti.interruptRun) != 0
// 0 is a special value indicating we should only stop issuing transactions when interrupted.
if ti.txsToIssue == 0 {
return !isInterrupted
}
return !isInterrupted && txCounter < ti.txsToIssue
}