package main import ( "flag" "fmt" "math/big" "math/rand" "os" "path" "sync" "time" "github.com/harmony-one/harmony/consensus" "github.com/harmony-one/harmony/core" "github.com/harmony-one/harmony/internal/ctxerror" "github.com/harmony-one/harmony/internal/shardchain" "github.com/ethereum/go-ethereum/crypto" "github.com/ethereum/go-ethereum/log" bls2 "github.com/harmony-one/bls/ffi/go/bls" "github.com/harmony-one/harmony/internal/params" "github.com/harmony-one/harmony/api/client" proto_node "github.com/harmony-one/harmony/api/proto/node" "github.com/harmony-one/harmony/common/denominations" "github.com/harmony-one/harmony/core/types" "github.com/harmony-one/harmony/crypto/bls" nodeconfig "github.com/harmony-one/harmony/internal/configs/node" "github.com/harmony-one/harmony/internal/genesis" "github.com/harmony-one/harmony/internal/utils" "github.com/harmony-one/harmony/node" "github.com/harmony-one/harmony/p2p" p2p_host "github.com/harmony-one/harmony/p2p/host" "github.com/harmony-one/harmony/p2p/p2pimpl" ) var ( version string builtBy string builtAt string commit string stateMutex sync.Mutex ) const ( checkFrequency = 2 //checkfrequency checks whether the transaction generator is ready to send the next batch of transactions. ) // Settings is the settings for TX generation. No Cross-Shard Support! type Settings struct { NumOfAddress int MaxNumTxsPerBatch int } func printVersion(me string) { fmt.Fprintf(os.Stderr, "Harmony (C) 2019. %v, version %v-%v (%v %v)\n", path.Base(me), version, commit, builtBy, builtAt) os.Exit(0) } // The main entrance for the transaction generator program which simulate transactions and send to the network for // processing. var ( ip = flag.String("ip", "127.0.0.1", "IP of the node") port = flag.String("port", "9999", "port of the node.") numTxns = flag.Int("numTxns", 100, "number of transactions to send per message") logFolder = flag.String("log_folder", "latest", "the folder collecting the logs of this execution") duration = flag.Int("duration", 30, "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.") //Keeping this for backward compatibility shardIDFlag = flag.Int("shardID", 0, "The shardID the node belongs to.") // Key file to store the private key keyFile = flag.String("key", "./.txgenkey", "the private key file of the txgen") // logging verbosity verbosity = flag.Int("verbosity", 5, "Logging verbosity: 0=silent, 1=error, 2=warn, 3=info, 4=debug, 5=detail (default: 5)") ) func setUpTXGen() *node.Node { nodePriKey, _, err := utils.LoadKeyFromFile(*keyFile) if err != nil { panic(err) } peerPubKey := bls.RandPrivateKey().GetPublicKey() if peerPubKey == nil { panic(fmt.Errorf("generate key error")) } shardID := *shardIDFlag selfPeer := p2p.Peer{IP: *ip, Port: *port, ConsensusPubKey: peerPubKey} gsif, err := consensus.NewGenesisStakeInfoFinder() // Nodes containing blockchain data to mirror the shards' data in the network myhost, err := p2pimpl.NewHost(&selfPeer, nodePriKey) if err != nil { panic("unable to new host in txgen") } if err != nil { fmt.Fprintf(os.Stderr, "Error :%v \n", err) os.Exit(1) } consensusObj, err := consensus.New(myhost, uint32(shardID), p2p.Peer{}, nil) chainDBFactory := &shardchain.MemDBFactory{} txGen := node.New(myhost, consensusObj, chainDBFactory, false) //Changed it : no longer archival node. txGen.Client = client.NewClient(txGen.GetHost(), uint32(shardID)) consensusObj.SetStakeInfoFinder(gsif) consensusObj.ChainReader = txGen.Blockchain() consensusObj.PublicKeys = nil genesisShardingConfig := core.ShardingSchedule.InstanceForEpoch(big.NewInt(core.GenesisEpoch)) startIdx := 0 endIdx := startIdx + genesisShardingConfig.NumNodesPerShard() for _, acct := range genesis.HarmonyAccounts[startIdx:endIdx] { pub := &bls2.PublicKey{} if err := pub.DeserializeHexStr(acct.BlsPublicKey); err != nil { fmt.Printf("Can not deserialize public key. err: %v", err) os.Exit(1) } consensusObj.PublicKeys = append(consensusObj.PublicKeys, pub) } txGen.NodeConfig.SetRole(nodeconfig.ClientNode) if shardID == 0 { txGen.NodeConfig.SetShardGroupID(p2p.GroupIDBeacon) } else { txGen.NodeConfig.SetShardGroupID(p2p.NewGroupIDByShardID(p2p.ShardID(shardID))) } txGen.NodeConfig.SetIsClient(true) return txGen } func main() { flag.Var(&utils.BootNodes, "bootnodes", "a list of bootnode multiaddress") flag.Parse() if *versionFlag { printVersion(os.Args[0]) } // Logging setup utils.SetLogContext(*port, *ip) utils.SetLogVerbosity(log.Lvl(*verbosity)) if len(utils.BootNodes) == 0 { bootNodeAddrs, err := utils.StringsToAddrs(utils.DefaultBootNodeAddrStrings) if err != nil { panic(err) } utils.BootNodes = bootNodeAddrs } // Init with LibP2P enabled, FIXME: (leochen) right now we support only one shard setting := Settings{ NumOfAddress: 10000, MaxNumTxsPerBatch: *numTxns, } shardID := *shardIDFlag utils.Logger().Debug(). Int("cx ratio", *crossShardRatio). Msg("Cross Shard Ratio Is Set But not used") // 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.StreamHandler(os.Stdout, log.TerminalFormat(false)), log.Must.FileHandler(logFileName, log.LogfmtFormat()), // Log to file ) log.Root().SetHandler(h) txGen := setUpTXGen() txGen.ServiceManagerSetup() txGen.RunServices() start := time.Now() totalTime := float64(*duration) utils.Logger().Debug(). Float64("totalTime", totalTime). Bool("RunForever", isDurationForever(totalTime)). Msg("Total Duration") ticker := time.NewTicker(checkFrequency * time.Second) txGen.DoSyncWithoutConsensus() syncLoop: for { t := time.Now() if totalTime > 0 && t.Sub(start).Seconds() >= totalTime { utils.Logger().Debug(). Int("duration", (int(t.Sub(start)))). Time("startTime", start). Float64("totalTime", totalTime). Msg("Generator timer ended in syncLoop.") break syncLoop } select { case <-ticker.C: if txGen.State.String() == "NodeReadyForConsensus" { utils.Logger().Debug(). Str("txgen node", txGen.SelfPeer.String()). Str("Node State", txGen.State.String()). Msg("Generator is now in Sync.") ticker.Stop() break syncLoop } } } readySignal := make(chan uint32) // This func is used to update the client's blockchain when new blocks are received from the leaders updateBlocksFunc := func(blocks []*types.Block) { utils.Logger().Info(). Uint64("block num", blocks[0].NumberU64()). Msg("[Txgen] Received new block") for _, block := range blocks { shardID := block.ShardID() if txGen.Consensus.ShardID == shardID { utils.Logger().Info(). Int("txNum", len(block.Transactions())). Uint32("shardID", shardID). Str("preHash", block.ParentHash().Hex()). Uint64("currentBlock", txGen.Blockchain().CurrentBlock().NumberU64()). Uint64("incoming block", block.NumberU64()). Msg("Got block from leader") if block.NumberU64()-txGen.Blockchain().CurrentBlock().NumberU64() == 1 { if err := txGen.AddNewBlock(block); err != nil { utils.Logger().Error(). Err(err). Msg("Error when adding new block") } stateMutex.Lock() if err := txGen.Worker.UpdateCurrent(block.Coinbase()); err != nil { ctxerror.Warn(utils.GetLogger(), err, "(*Worker).UpdateCurrent failed") } stateMutex.Unlock() readySignal <- shardID } } else { continue } } } txGen.Client.UpdateBlocks = updateBlocksFunc // Start the client server to listen to leader's message go func() { // wait for 3 seconds for client to send ping message to leader // FIXME (leo) the readySignal should be set once we really sent ping message to leader time.Sleep(1 * time.Second) // wait for nodes to be ready readySignal <- uint32(shardID) }() pushLoop: for { t := time.Now() utils.Logger().Debug(). Float64("running time", t.Sub(start).Seconds()). Float64("totalTime", totalTime). Msg("Current running time") if !isDurationForever(totalTime) && t.Sub(start).Seconds() >= totalTime { utils.Logger().Debug(). Int("duration", (int(t.Sub(start)))). Time("startTime", start). Float64("totalTime", totalTime). Msg("Generator timer ended.") break pushLoop } if shardID != 0 { if otherHeight, flag := txGen.IsSameHeight(); flag { if otherHeight >= 1 { go func() { readySignal <- uint32(shardID) utils.Logger().Debug().Msg("Same blockchain height so readySignal generated") time.Sleep(3 * time.Second) // wait for nodes to be ready }() } } } select { case shardID := <-readySignal: lock := sync.Mutex{} txs, err := GenerateSimulatedTransactionsAccount(uint32(shardID), txGen, setting) if err != nil { utils.Logger().Debug(). Err(err). Msg("Error in Generating Txns") } lock.Lock() SendTxsToShard(txGen, txs, uint32(shardID)) lock.Unlock() case <-time.After(10 * time.Second): utils.Logger().Warn().Msg("No new block is received so far") } } } // SendTxsToShard sends txs to shard, currently just to beacon shard func SendTxsToShard(clientNode *node.Node, txs types.Transactions, shardID uint32) { msg := proto_node.ConstructTransactionListMessageAccount(txs) var err error if shardID == 0 { err = clientNode.GetHost().SendMessageToGroups([]p2p.GroupID{p2p.GroupIDBeaconClient}, p2p_host.ConstructP2pMessage(byte(0), msg)) } else { clientGroup := p2p.NewClientGroupIDByShardID(p2p.ShardID(shardID)) err = clientNode.GetHost().SendMessageToGroups([]p2p.GroupID{clientGroup}, p2p_host.ConstructP2pMessage(byte(0), msg)) } if err != nil { utils.Logger().Debug(). Err(err). Msg("Error in Sending Txns") } } // GenerateSimulatedTransactionsAccount generates simulated transaction for account model. func GenerateSimulatedTransactionsAccount(shardID uint32, node *node.Node, setting Settings) (types.Transactions, error) { TxnsToGenerate := setting.MaxNumTxsPerBatch // TODO: make use of settings txs := make([]*types.Transaction, TxnsToGenerate) rounds := (TxnsToGenerate / 100) remainder := TxnsToGenerate % 100 for i := 0; i < 100; i++ { baseNonce := node.Worker.GetCurrentState().GetNonce(crypto.PubkeyToAddress(node.TestBankKeys[i].PublicKey)) for j := 0; j < rounds; j++ { randomUserAddress := crypto.PubkeyToAddress(node.TestBankKeys[rand.Intn(100)].PublicKey) randAmount := rand.Float32() tx, _ := types.SignTx(types.NewTransaction(baseNonce+uint64(j), randomUserAddress, shardID, big.NewInt(int64(denominations.One*randAmount)), params.TxGas, nil, nil), types.HomesteadSigner{}, node.TestBankKeys[i]) txs[100*j+i] = tx } if i < remainder { randomUserAddress := crypto.PubkeyToAddress(node.TestBankKeys[rand.Intn(100)].PublicKey) randAmount := rand.Float32() tx, _ := types.SignTx(types.NewTransaction(baseNonce+uint64(rounds), randomUserAddress, shardID, big.NewInt(int64(denominations.One*randAmount)), params.TxGas, nil, nil), types.HomesteadSigner{}, node.TestBankKeys[i]) txs[100*rounds+i] = tx } } return txs, nil } func isDurationForever(duration float64) bool { return duration <= 0 }