package main import ( "encoding/binary" "encoding/hex" "flag" "fmt" "math/rand" "os" "path" "sync" "time" "github.com/simple-rules/harmony-benchmark/blockchain" "github.com/simple-rules/harmony-benchmark/client" client_config "github.com/simple-rules/harmony-benchmark/client/config" "github.com/simple-rules/harmony-benchmark/consensus" "github.com/simple-rules/harmony-benchmark/crypto/pki" "github.com/simple-rules/harmony-benchmark/log" "github.com/simple-rules/harmony-benchmark/node" "github.com/simple-rules/harmony-benchmark/p2p" proto_node "github.com/simple-rules/harmony-benchmark/proto/node" ) var ( version string builtBy string builtAt string commit string ) type txGenSettings struct { numOfAddress int crossShard bool maxNumTxsPerBatch int crossShardRatio int } var ( utxoPoolMutex sync.Mutex setting txGenSettings ) type TxInfo struct { // Global Input shardID int dataNodes []*node.Node // Temp Input id [32]byte index uint32 value int address [20]byte // Output txs []*blockchain.Transaction crossTxs []*blockchain.Transaction txCount int } // Generates at most "maxNumTxs" number of simulated transactions based on the current UtxoPools of all shards. // The transactions are generated by going through the existing utxos and // randomly select a subset of them as the input for each new transaction. The output // address of the new transaction are randomly selected from [0 - N), where N is the total number of fake addresses. // // When crossShard=true, besides the selected utxo input, select another valid utxo as input from the same address in a second shard. // Similarly, generate another utxo output in that second shard. // // NOTE: the genesis block should contain N coinbase transactions which add // token (1000) to each address in [0 - N). See node.AddTestingAddresses() // // Params: // subsetId - the which subset of the utxo to work on (used to select addresses) // shardID - the shardID for current shard // dataNodes - nodes containing utxopools of all shards // Returns: // all single-shard txs // all cross-shard txs func generateSimulatedTransactions(subsetId, numSubset int, shardId int, dataNodes []*node.Node) ([]*blockchain.Transaction, []*blockchain.Transaction) { /* UTXO map structure: address - [ txId1 - [ outputIndex1 - value1 outputIndex2 - value2 ] txId2 - [ outputIndex1 - value1 outputIndex2 - value2 ] ] */ txInfo := TxInfo{} txInfo.shardID = shardId txInfo.dataNodes = dataNodes txInfo.txCount = 0 UTXOLOOP: // Loop over all addresses for address, txMap := range dataNodes[shardId].UtxoPool.UtxoMap { if int(binary.BigEndian.Uint32(address[:]))%numSubset == subsetId%numSubset { // Work on one subset of utxo at a time txInfo.address = address // Loop over all txIds for the address for txIdStr, utxoMap := range txMap { // Parse TxId id, err := hex.DecodeString(txIdStr) if err != nil { continue } copy(txInfo.id[:], id[:]) // Loop over all utxos for the txId for index, value := range utxoMap { txInfo.index = index txInfo.value = value randNum := rand.Intn(100) if setting.crossShard && randNum < setting.crossShardRatio { // 30% cross shard transactions: add another txinput from another shard generateCrossShardTx(&txInfo) } else { generateSingleShardTx(&txInfo) } if txInfo.txCount >= setting.maxNumTxsPerBatch { break UTXOLOOP } } } } } log.Info("UTXO CLIENT", "numUtxo", dataNodes[shardId].UtxoPool.CountNumOfUtxos(), "shardId", shardId) log.Debug("[Generator] generated transations", "single-shard", len(txInfo.txs), "cross-shard", len(txInfo.crossTxs)) return txInfo.txs, txInfo.crossTxs } func generateCrossShardTx(txInfo *TxInfo) { nodeShardID := txInfo.dataNodes[txInfo.shardID].Consensus.ShardID crossShardId := nodeShardID // a random shard to spend money to for true { crossShardId = uint32(rand.Intn(len(txInfo.dataNodes))) if crossShardId != nodeShardID { break } } crossShardNode := txInfo.dataNodes[crossShardId] crossShardUtxosMap := crossShardNode.UtxoPool.UtxoMap[txInfo.address] // Get the cross shard utxo from another shard var crossTxin *blockchain.TXInput crossUtxoValue := 0 // Loop over utxos for the same address from the other shard and use the first utxo as the second cross tx input for crossTxIdStr, crossShardUtxos := range crossShardUtxosMap { // Parse TxId id, err := hex.DecodeString(crossTxIdStr) if err != nil { continue } crossTxId := [32]byte{} copy(crossTxId[:], id[:]) for crossShardIndex, crossShardValue := range crossShardUtxos { crossUtxoValue = crossShardValue crossTxin = blockchain.NewTXInput(blockchain.NewOutPoint(&crossTxId, crossShardIndex), txInfo.address, crossShardId) break } if crossTxin != nil { break } } // Add the utxo from current shard txIn := blockchain.NewTXInput(blockchain.NewOutPoint(&txInfo.id, txInfo.index), txInfo.address, nodeShardID) txInputs := []blockchain.TXInput{*txIn} // Add the utxo from the other shard, if any if crossTxin != nil { // This means the ratio of cross shard tx could be lower than 1/3 txInputs = append(txInputs, *crossTxin) } // Spend the utxo from the current shard to a random address in [0 - N) txout := blockchain.TXOutput{Amount: txInfo.value, Address: pki.GetAddressFromInt(rand.Intn(setting.numOfAddress) + 1), ShardID: nodeShardID} txOutputs := []blockchain.TXOutput{txout} // Spend the utxo from the other shard, if any, to a random address in [0 - N) if crossTxin != nil { crossTxout := blockchain.TXOutput{Amount: crossUtxoValue, Address: pki.GetAddressFromInt(rand.Intn(setting.numOfAddress) + 1), ShardID: crossShardId} txOutputs = append(txOutputs, crossTxout) } // Construct the new transaction tx := blockchain.Transaction{ID: [32]byte{}, TxInput: txInputs, TxOutput: txOutputs, Proofs: nil} priKeyInt, ok := client.LookUpIntPriKey(txInfo.address) if ok { tx.PublicKey = pki.GetBytesFromPublicKey(pki.GetPublicKeyFromScalar(pki.GetPrivateKeyScalarFromInt(priKeyInt))) tx.SetID() // TODO(RJ): figure out the correct way to set Tx ID. tx.Sign(pki.GetPrivateKeyScalarFromInt(priKeyInt)) } else { log.Error("Failed to look up the corresponding private key from address", "Address", txInfo.address) return } txInfo.crossTxs = append(txInfo.crossTxs, &tx) txInfo.txCount++ } func generateSingleShardTx(txInfo *TxInfo) { nodeShardID := txInfo.dataNodes[txInfo.shardID].Consensus.ShardID // Add the utxo as new tx input txin := blockchain.NewTXInput(blockchain.NewOutPoint(&txInfo.id, txInfo.index), txInfo.address, nodeShardID) // Spend the utxo to a random address in [0 - N) txout := blockchain.TXOutput{Amount: txInfo.value, Address: pki.GetAddressFromInt(rand.Intn(setting.numOfAddress) + 1), ShardID: nodeShardID} tx := blockchain.Transaction{ID: [32]byte{}, TxInput: []blockchain.TXInput{*txin}, TxOutput: []blockchain.TXOutput{txout}, Proofs: nil} priKeyInt, ok := client.LookUpIntPriKey(txInfo.address) if ok { tx.PublicKey = pki.GetBytesFromPublicKey(pki.GetPublicKeyFromScalar(pki.GetPrivateKeyScalarFromInt(priKeyInt))) tx.SetID() // TODO(RJ): figure out the correct way to set Tx ID. tx.Sign(pki.GetPrivateKeyScalarFromInt(priKeyInt)) } else { log.Error("Failed to look up the corresponding private key from address", "Address", txInfo.address) return } txInfo.txs = append(txInfo.txs, &tx) txInfo.txCount++ } func printVersion(me string) { fmt.Fprintf(os.Stderr, "Harmony (C) 2018. %v, version %v-%v (%v %v)\n", path.Base(me), version, commit, builtBy, builtAt) os.Exit(0) } func main() { configFile := flag.String("config_file", "local_config.txt", "file containing all ip addresses and config") maxNumTxsPerBatch := flag.Int("max_num_txs_per_batch", 10000, "number of transactions to send per message") logFolder := flag.String("log_folder", "latest", "the folder collecting the logs of this execution") numSubset := flag.Int("numSubset", 3, "the number of subsets of utxos to process separately") duration := flag.Int("duration", 60, "duration of the tx generation in second. If it's negative, the experiment runs forever.") versionFlag := flag.Bool("version", false, "Output version info") crossShardRatio := flag.Int("cross_shard_ratio", 30, "The percentage of cross shard transactions.") flag.Parse() if *versionFlag { printVersion(os.Args[0]) } // Read the configs config := client_config.NewConfig() config.ReadConfigFile(*configFile) shardIdLeaderMap := config.GetShardIdToLeaderMap() setting.numOfAddress = 10000 // Do cross shard tx if there are more than one shard setting.crossShard = len(shardIdLeaderMap) > 1 setting.maxNumTxsPerBatch = *maxNumTxsPerBatch setting.crossShardRatio = *crossShardRatio // TODO(Richard): refactor this chuck to a single method // Setup a logger to stdout and log file. logFileName := fmt.Sprintf("./%v/txgen.log", *logFolder) h := log.MultiHandler( log.StdoutHandler, log.Must.FileHandler(logFileName, log.LogfmtFormat()), // Log to file ) log.Root().SetHandler(h) // Nodes containing utxopools to mirror the shards' data in the network nodes := []*node.Node{} for shardId, _ := range shardIdLeaderMap { node := node.New(&consensus.Consensus{ShardID: shardId}, nil) // Assign many fake addresses so we have enough address to play with at first node.AddTestingAddresses(setting.numOfAddress) nodes = append(nodes, node) } // Client/txgenerator server node setup clientPort := config.GetClientPort() consensusObj := consensus.NewConsensus("0", clientPort, "0", nil, p2p.Peer{}) clientNode := node.New(consensusObj, nil) if clientPort != "" { clientNode.Client = client.NewClient(&shardIdLeaderMap) // This func is used to update the client's utxopool when new blocks are received from the leaders updateBlocksFunc := func(blocks []*blockchain.Block) { log.Debug("Received new block from leader", "len", len(blocks)) for _, block := range blocks { for _, node := range nodes { if node.Consensus.ShardID == block.ShardId { log.Debug("Adding block from leader", "shardId", block.ShardId) // Add it to blockchain node.AddNewBlock(block) utxoPoolMutex.Lock() node.UpdateUtxoAndState(block) utxoPoolMutex.Unlock() } else { continue } } } } clientNode.Client.UpdateBlocks = updateBlocksFunc // Start the client server to listen to leader's message go func() { clientNode.StartServer(clientPort) }() } // Transaction generation process time.Sleep(10 * time.Second) // wait for nodes to be ready start := time.Now() totalTime := float64(*duration) client.InitLookUpIntPriKeyMap() subsetCounter := 0 for true { t := time.Now() if totalTime > 0 && t.Sub(start).Seconds() >= totalTime { log.Debug("Generator timer ended.", "duration", (int(t.Sub(start))), "startTime", start, "totalTime", totalTime) break } shardIdTxsMap := make(map[uint32][]*blockchain.Transaction) lock := sync.Mutex{} var wg sync.WaitGroup wg.Add(len(shardIdLeaderMap)) utxoPoolMutex.Lock() log.Warn("STARTING TX GEN") for shardId, _ := range shardIdLeaderMap { // Generate simulated transactions go func() { txs, crossTxs := generateSimulatedTransactions(subsetCounter, *numSubset, int(shardId), nodes) // Put cross shard tx into a pending list waiting for proofs from leaders if clientPort != "" { clientNode.Client.PendingCrossTxsMutex.Lock() for _, tx := range crossTxs { clientNode.Client.PendingCrossTxs[tx.ID] = tx } clientNode.Client.PendingCrossTxsMutex.Unlock() } lock.Lock() // Put txs into corresponding shards shardIdTxsMap[shardId] = append(shardIdTxsMap[shardId], txs...) for _, crossTx := range crossTxs { for curShardId, _ := range client.GetInputShardIdsOfCrossShardTx(crossTx) { shardIdTxsMap[curShardId] = append(shardIdTxsMap[curShardId], crossTx) } } lock.Unlock() wg.Done() }() } utxoPoolMutex.Unlock() wg.Wait() lock.Lock() for shardId, txs := range shardIdTxsMap { // Send the txs to corresponding shards go func() { SendTxsToLeader(shardIdLeaderMap[shardId], txs) }() } lock.Unlock() subsetCounter++ time.Sleep(5000 * time.Millisecond) } // Send a stop message to stop the nodes at the end msg := proto_node.ConstructStopMessage() peers := append(config.GetValidators(), clientNode.Client.GetLeaders()...) p2p.BroadcastMessage(peers, msg) } func SendTxsToLeader(leader p2p.Peer, txs []*blockchain.Transaction) { log.Debug("[Generator] Sending txs to...", "leader", leader, "numTxs", len(txs)) msg := proto_node.ConstructTransactionListMessage(txs) p2p.SendMessage(leader, msg) }