The core protocol of WoopChain
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woop/cmd/harmony/main.go

815 lines
25 KiB

package main
import (
"fmt"
"io/ioutil"
"math/big"
"math/rand"
"net/http"
_ "net/http/pprof"
"os"
"os/signal"
"path/filepath"
"runtime"
"strconv"
"strings"
"syscall"
"time"
harmonyconfig "github.com/harmony-one/harmony/internal/configs/harmony"
rpc_common "github.com/harmony-one/harmony/rpc/common"
ethCommon "github.com/ethereum/go-ethereum/common"
"github.com/ethereum/go-ethereum/log"
"github.com/harmony-one/bls/ffi/go/bls"
"github.com/pkg/errors"
"github.com/spf13/cobra"
"github.com/harmony-one/harmony/api/service"
"github.com/harmony-one/harmony/api/service/prometheus"
"github.com/harmony-one/harmony/api/service/synchronize"
"github.com/harmony-one/harmony/common/fdlimit"
"github.com/harmony-one/harmony/common/ntp"
"github.com/harmony-one/harmony/consensus"
"github.com/harmony-one/harmony/consensus/quorum"
"github.com/harmony-one/harmony/core"
"github.com/harmony-one/harmony/hmy/downloader"
"github.com/harmony-one/harmony/internal/cli"
"github.com/harmony-one/harmony/internal/common"
nodeconfig "github.com/harmony-one/harmony/internal/configs/node"
shardingconfig "github.com/harmony-one/harmony/internal/configs/sharding"
"github.com/harmony-one/harmony/internal/genesis"
"github.com/harmony-one/harmony/internal/params"
"github.com/harmony-one/harmony/internal/shardchain"
"github.com/harmony-one/harmony/internal/utils"
"github.com/harmony-one/harmony/multibls"
"github.com/harmony-one/harmony/node"
"github.com/harmony-one/harmony/numeric"
"github.com/harmony-one/harmony/p2p"
"github.com/harmony-one/harmony/shard"
"github.com/harmony-one/harmony/webhooks"
)
// Host
var (
myHost p2p.Host
initialAccounts = []*genesis.DeployAccount{}
)
var rootCmd = &cobra.Command{
Use: "harmony",
Short: "harmony is the Harmony node binary file",
Long: `harmony is the Harmony node binary file
Examples usage:
# start a validator node with default bls folder (default bls key files in ./.hmy/blskeys)
./harmony
# start a validator node with customized bls key folder
./harmony --bls.dir [bls_folder]
# start a validator node with open RPC endpoints and customized ports
./harmony --http.ip=0.0.0.0 --http.port=[http_port] --ws.ip=0.0.0.0 --ws.port=[ws_port]
# start an explorer node
./harmony --run=explorer --run.shard=[shard_id]
# start a harmony internal node on testnet
./harmony --run.legacy --network testnet
`,
Run: runHarmonyNode,
}
var configFlag = cli.StringFlag{
Name: "config",
Usage: "load node config from the config toml file.",
Shorthand: "c",
DefValue: "",
}
func init() {
rand.Seed(time.Now().UnixNano())
cli.SetParseErrorHandle(func(err error) {
os.Exit(128) // 128 - invalid command line arguments
})
configCmd.AddCommand(dumpConfigCmd)
configCmd.AddCommand(updateConfigCmd)
rootCmd.AddCommand(configCmd)
rootCmd.AddCommand(versionCmd)
rootCmd.AddCommand(dumpConfigLegacyCmd)
if err := registerRootCmdFlags(); err != nil {
os.Exit(2)
}
if err := registerDumpConfigFlags(); err != nil {
os.Exit(2)
}
}
func main() {
rootCmd.Execute()
}
func registerRootCmdFlags() error {
flags := getRootFlags()
return cli.RegisterFlags(rootCmd, flags)
}
func runHarmonyNode(cmd *cobra.Command, args []string) {
if cli.GetBoolFlagValue(cmd, versionFlag) {
printVersion()
os.Exit(0)
}
if err := prepareRootCmd(cmd); err != nil {
fmt.Fprint(os.Stderr, err)
os.Exit(128)
}
cfg, err := getHarmonyConfig(cmd)
if err != nil {
fmt.Fprint(os.Stderr, err)
os.Exit(128)
}
setupNodeLog(cfg)
setupPprof(cfg)
setupNodeAndRun(cfg)
}
func prepareRootCmd(cmd *cobra.Command) error {
// HACK Force usage of go implementation rather than the C based one. Do the right way, see the
// notes one line 66,67 of https://golang.org/src/net/net.go that say can make the decision at
// build time.
os.Setenv("GODEBUG", "netdns=go")
// Don't set higher than num of CPU. It will make go scheduler slower.
runtime.GOMAXPROCS(runtime.NumCPU())
// Raise fd limits
return raiseFdLimits()
}
func raiseFdLimits() error {
limit, err := fdlimit.Maximum()
if err != nil {
return errors.Wrap(err, "Failed to retrieve file descriptor allowance")
}
_, err = fdlimit.Raise(uint64(limit))
if err != nil {
return errors.Wrap(err, "Failed to raise file descriptor allowance")
}
return nil
}
func getHarmonyConfig(cmd *cobra.Command) (harmonyconfig.HarmonyConfig, error) {
var (
config harmonyconfig.HarmonyConfig
err error
migratedFrom string
configFile string
isUsingDefault bool
)
if cli.IsFlagChanged(cmd, configFlag) {
configFile = cli.GetStringFlagValue(cmd, configFlag)
config, migratedFrom, err = loadHarmonyConfig(configFile)
} else {
nt := getNetworkType(cmd)
config = getDefaultHmyConfigCopy(nt)
isUsingDefault = true
}
if err != nil {
return harmonyconfig.HarmonyConfig{}, err
}
if migratedFrom != defaultConfig.Version && !isUsingDefault {
fmt.Printf("Old config version detected %s\n",
migratedFrom)
stat, _ := os.Stdin.Stat()
// Ask to update if only using terminal
if stat.Mode()&os.ModeCharDevice != 0 {
if promptConfigUpdate() {
err := updateConfigFile(configFile)
if err != nil {
fmt.Printf("Could not update config - %s", err.Error())
fmt.Println("Update config manually with `./harmony config update [config_file]`")
}
}
} else {
fmt.Println("Update saved config with `./harmony config update [config_file]`")
}
}
applyRootFlags(cmd, &config)
if err := validateHarmonyConfig(config); err != nil {
return harmonyconfig.HarmonyConfig{}, err
}
sanityFixHarmonyConfig(&config)
return config, nil
}
func applyRootFlags(cmd *cobra.Command, config *harmonyconfig.HarmonyConfig) {
// Misc flags shall be applied first since legacy ip / port is overwritten
// by new ip / port flags
applyLegacyMiscFlags(cmd, config)
applyGeneralFlags(cmd, config)
applyNetworkFlags(cmd, config)
applyDNSSyncFlags(cmd, config)
applyP2PFlags(cmd, config)
applyHTTPFlags(cmd, config)
applyWSFlags(cmd, config)
applyRPCOptFlags(cmd, config)
applyBLSFlags(cmd, config)
applyConsensusFlags(cmd, config)
applyTxPoolFlags(cmd, config)
applyPprofFlags(cmd, config)
applyLogFlags(cmd, config)
applySysFlags(cmd, config)
applyDevnetFlags(cmd, config)
applyRevertFlags(cmd, config)
applyPrometheusFlags(cmd, config)
applySyncFlags(cmd, config)
}
func setupNodeLog(config harmonyconfig.HarmonyConfig) {
logPath := filepath.Join(config.Log.Folder, config.Log.FileName)
rotateSize := config.Log.RotateSize
verbosity := config.Log.Verbosity
utils.AddLogFile(logPath, rotateSize)
utils.SetLogVerbosity(log.Lvl(verbosity))
if config.Log.Context != nil {
ip := config.Log.Context.IP
port := config.Log.Context.Port
utils.SetLogContext(ip, strconv.Itoa(port))
}
}
func setupPprof(config harmonyconfig.HarmonyConfig) {
enabled := config.Pprof.Enabled
addr := config.Pprof.ListenAddr
if enabled {
go func() {
http.ListenAndServe(addr, nil)
}()
}
}
func setupNodeAndRun(hc harmonyconfig.HarmonyConfig) {
var err error
nodeconfigSetShardSchedule(hc)
nodeconfig.SetShardingSchedule(shard.Schedule)
nodeconfig.SetVersion(getHarmonyVersion())
if hc.General.NodeType == "validator" {
var err error
if hc.General.NoStaking {
err = setupLegacyNodeAccount(hc)
} else {
err = setupStakingNodeAccount(hc)
}
if err != nil {
fmt.Fprintf(os.Stderr, "cannot set up node account: %s\n", err)
os.Exit(1)
}
}
if hc.General.NodeType == "validator" {
fmt.Printf("%s mode; node key %s -> shard %d\n",
map[bool]string{false: "Legacy", true: "Staking"}[!hc.General.NoStaking],
nodeconfig.GetDefaultConfig().ConsensusPriKey.GetPublicKeys().SerializeToHexStr(),
initialAccounts[0].ShardID)
}
if hc.General.NodeType != "validator" && hc.General.ShardID >= 0 {
for _, initialAccount := range initialAccounts {
utils.Logger().Info().
Uint32("original", initialAccount.ShardID).
Int("override", hc.General.ShardID).
Msg("ShardID Override")
initialAccount.ShardID = uint32(hc.General.ShardID)
}
}
nodeConfig, err := createGlobalConfig(hc)
if err != nil {
fmt.Fprintf(os.Stderr, "ERROR cannot configure node: %s\n", err)
os.Exit(1)
}
// Update ethereum compatible chain ids
params.UpdateEthChainIDByShard(nodeConfig.ShardID)
currentNode := setupConsensusAndNode(hc, nodeConfig)
nodeconfig.GetDefaultConfig().ShardID = nodeConfig.ShardID
nodeconfig.GetDefaultConfig().IsOffline = nodeConfig.IsOffline
nodeconfig.GetDefaultConfig().Downloader = nodeConfig.Downloader
// Check NTP configuration
accurate, err := ntp.CheckLocalTimeAccurate(nodeConfig.NtpServer)
if !accurate {
if os.IsTimeout(err) {
fmt.Fprintf(os.Stderr, "Error: %v\n", err)
fmt.Fprintf(os.Stderr, "NTP query timed out. Continuing.\n")
} else {
fmt.Fprintf(os.Stderr, "Error: %v\n", err)
fmt.Fprintf(os.Stderr, "Error: local timeclock is not accurate. Please config NTP properly.\n")
}
}
if err != nil {
utils.Logger().Warn().Err(err).Msg("Check Local Time Accuracy Error")
}
// Parse RPC config
nodeConfig.RPCServer = nodeconfig.RPCServerConfig{
HTTPEnabled: hc.HTTP.Enabled,
HTTPIp: hc.HTTP.IP,
HTTPPort: hc.HTTP.Port,
WSEnabled: hc.WS.Enabled,
WSIp: hc.WS.IP,
WSPort: hc.WS.Port,
DebugEnabled: hc.RPCOpt.DebugEnabled,
RateLimiterEnabled: hc.RPCOpt.RateLimterEnabled,
RequestsPerSecond: hc.RPCOpt.RequestsPerSecond,
}
// Parse rosetta config
nodeConfig.RosettaServer = nodeconfig.RosettaServerConfig{
HTTPEnabled: hc.HTTP.RosettaEnabled,
HTTPIp: hc.HTTP.IP,
HTTPPort: hc.HTTP.RosettaPort,
}
if hc.Revert != nil && hc.Revert.RevertBefore != 0 && hc.Revert.RevertTo != 0 {
chain := currentNode.Blockchain()
if hc.Revert.RevertBeacon {
chain = currentNode.Beaconchain()
}
curNum := chain.CurrentBlock().NumberU64()
if curNum < uint64(hc.Revert.RevertBefore) && curNum >= uint64(hc.Revert.RevertTo) {
// Remove invalid blocks
for chain.CurrentBlock().NumberU64() >= uint64(hc.Revert.RevertTo) {
curBlock := chain.CurrentBlock()
rollbacks := []ethCommon.Hash{curBlock.Hash()}
if err := chain.Rollback(rollbacks); err != nil {
fmt.Printf("Revert failed: %v\n", err)
os.Exit(1)
}
lastSig := curBlock.Header().LastCommitSignature()
sigAndBitMap := append(lastSig[:], curBlock.Header().LastCommitBitmap()...)
chain.WriteCommitSig(curBlock.NumberU64()-1, sigAndBitMap)
}
}
}
startMsg := "==== New Harmony Node ===="
if hc.General.NodeType == nodeTypeExplorer {
startMsg = "==== New Explorer Node ===="
}
utils.Logger().Info().
Str("BLSPubKey", nodeConfig.ConsensusPriKey.GetPublicKeys().SerializeToHexStr()).
Uint32("ShardID", nodeConfig.ShardID).
Str("ShardGroupID", nodeConfig.GetShardGroupID().String()).
Str("BeaconGroupID", nodeConfig.GetBeaconGroupID().String()).
Str("ClientGroupID", nodeConfig.GetClientGroupID().String()).
Str("Role", currentNode.NodeConfig.Role().String()).
Str("Version", getHarmonyVersion()).
Str("multiaddress",
fmt.Sprintf("/ip4/%s/tcp/%d/p2p/%s", hc.P2P.IP, hc.P2P.Port, myHost.GetID().Pretty()),
).
Msg(startMsg)
nodeconfig.SetPeerID(myHost.GetID())
if hc.Log.VerbosePrints["config"] {
utils.Logger().Info().Interface("config", rpc_common.Config{
HarmonyConfig: hc,
NodeConfig: *nodeConfig,
ChainConfig: *currentNode.Blockchain().Config(),
}).Msg("verbose prints config")
}
// Setup services
if hc.Sync.Enabled {
setupSyncService(currentNode, myHost, hc)
}
if currentNode.NodeConfig.Role() == nodeconfig.Validator {
currentNode.RegisterValidatorServices()
} else if currentNode.NodeConfig.Role() == nodeconfig.ExplorerNode {
currentNode.RegisterExplorerServices()
}
if hc.Prometheus.Enabled {
setupPrometheusService(currentNode, hc, nodeConfig.ShardID)
}
if hc.DNSSync.Server && !hc.General.IsOffline {
utils.Logger().Info().Msg("support gRPC sync server")
currentNode.SupportGRPCSyncServer(hc.DNSSync.ServerPort)
}
if hc.DNSSync.Client && !hc.General.IsOffline {
utils.Logger().Info().Msg("go with gRPC sync client")
currentNode.StartGRPCSyncClient()
}
if err := currentNode.StartServices(); err != nil {
fmt.Fprint(os.Stderr, err.Error())
os.Exit(-1)
}
if err := currentNode.StartRPC(); err != nil {
utils.Logger().Warn().
Err(err).
Msg("StartRPC failed")
}
if err := currentNode.StartRosetta(); err != nil {
utils.Logger().Warn().
Err(err).
Msg("Start Rosetta failed")
}
go listenOSSigAndShutDown(currentNode)
if !hc.General.IsOffline {
if err := myHost.Start(); err != nil {
utils.Logger().Fatal().
Err(err).
Msg("Start p2p host failed")
}
if err := currentNode.BootstrapConsensus(); err != nil {
fmt.Fprint(os.Stderr, "could not bootstrap consensus", err.Error())
if !currentNode.NodeConfig.IsOffline {
os.Exit(-1)
}
}
if err := currentNode.StartPubSub(); err != nil {
fmt.Fprint(os.Stderr, "could not begin network message handling for node", err.Error())
os.Exit(-1)
}
}
select {}
}
func nodeconfigSetShardSchedule(config harmonyconfig.HarmonyConfig) {
switch config.Network.NetworkType {
case nodeconfig.Mainnet:
shard.Schedule = shardingconfig.MainnetSchedule
case nodeconfig.Testnet:
shard.Schedule = shardingconfig.TestnetSchedule
case nodeconfig.Pangaea:
shard.Schedule = shardingconfig.PangaeaSchedule
case nodeconfig.Localnet:
shard.Schedule = shardingconfig.LocalnetSchedule
case nodeconfig.Partner:
shard.Schedule = shardingconfig.PartnerSchedule
case nodeconfig.Stressnet:
shard.Schedule = shardingconfig.StressNetSchedule
case nodeconfig.Devnet:
var dnConfig harmonyconfig.DevnetConfig
if config.Devnet != nil {
dnConfig = *config.Devnet
} else {
dnConfig = getDefaultDevnetConfigCopy()
}
devnetConfig, err := shardingconfig.NewInstance(
uint32(dnConfig.NumShards), dnConfig.ShardSize, dnConfig.HmyNodeSize, numeric.OneDec(), genesis.HarmonyAccounts, genesis.FoundationalNodeAccounts, nil, shardingconfig.VLBPE)
if err != nil {
_, _ = fmt.Fprintf(os.Stderr, "ERROR invalid devnet sharding config: %s",
err)
os.Exit(1)
}
shard.Schedule = shardingconfig.NewFixedSchedule(devnetConfig)
}
}
func findAccountsByPubKeys(config shardingconfig.Instance, pubKeys multibls.PublicKeys) {
for _, key := range pubKeys {
keyStr := key.Bytes.Hex()
_, account := config.FindAccount(keyStr)
if account != nil {
initialAccounts = append(initialAccounts, account)
}
}
}
func setupLegacyNodeAccount(hc harmonyconfig.HarmonyConfig) error {
genesisShardingConfig := shard.Schedule.InstanceForEpoch(big.NewInt(core.GenesisEpoch))
multiBLSPubKey := setupConsensusKeys(hc, nodeconfig.GetDefaultConfig())
reshardingEpoch := genesisShardingConfig.ReshardingEpoch()
if len(reshardingEpoch) > 0 {
for _, epoch := range reshardingEpoch {
config := shard.Schedule.InstanceForEpoch(epoch)
findAccountsByPubKeys(config, multiBLSPubKey)
if len(initialAccounts) != 0 {
break
}
}
} else {
findAccountsByPubKeys(genesisShardingConfig, multiBLSPubKey)
}
if len(initialAccounts) == 0 {
fmt.Fprintf(
os.Stderr,
"ERROR cannot find your BLS key in the genesis/FN tables: %s\n",
multiBLSPubKey.SerializeToHexStr(),
)
os.Exit(100)
}
for _, account := range initialAccounts {
fmt.Printf("My Genesis Account: %v\n", *account)
}
return nil
}
func setupStakingNodeAccount(hc harmonyconfig.HarmonyConfig) error {
pubKeys := setupConsensusKeys(hc, nodeconfig.GetDefaultConfig())
shardID, err := nodeconfig.GetDefaultConfig().ShardIDFromConsensusKey()
if err != nil {
return errors.Wrap(err, "cannot determine shard to join")
}
if err := nodeconfig.GetDefaultConfig().ValidateConsensusKeysForSameShard(
pubKeys, shardID,
); err != nil {
return err
}
for _, blsKey := range pubKeys {
initialAccount := &genesis.DeployAccount{}
initialAccount.ShardID = shardID
initialAccount.BLSPublicKey = blsKey.Bytes.Hex()
initialAccount.Address = ""
initialAccounts = append(initialAccounts, initialAccount)
}
return nil
}
func createGlobalConfig(hc harmonyconfig.HarmonyConfig) (*nodeconfig.ConfigType, error) {
var err error
if len(initialAccounts) == 0 {
initialAccounts = append(initialAccounts, &genesis.DeployAccount{ShardID: uint32(hc.General.ShardID)})
}
nodeConfig := nodeconfig.GetShardConfig(initialAccounts[0].ShardID)
if hc.General.NodeType == nodeTypeValidator {
// Set up consensus keys.
setupConsensusKeys(hc, nodeConfig)
} else {
// set dummy bls key for consensus object
nodeConfig.ConsensusPriKey = multibls.GetPrivateKeys(&bls.SecretKey{})
}
// Set network type
netType := nodeconfig.NetworkType(hc.Network.NetworkType)
nodeconfig.SetNetworkType(netType) // sets for both global and shard configs
nodeConfig.SetShardID(initialAccounts[0].ShardID) // sets shard ID
nodeConfig.SetArchival(hc.General.IsBeaconArchival, hc.General.IsArchival)
nodeConfig.IsOffline = hc.General.IsOffline
nodeConfig.Downloader = hc.Sync.Downloader
// P2P private key is used for secure message transfer between p2p nodes.
nodeConfig.P2PPriKey, _, err = utils.LoadKeyFromFile(hc.P2P.KeyFile)
if err != nil {
return nil, errors.Wrapf(err, "cannot load or create P2P key at %#v",
hc.P2P.KeyFile)
}
selfPeer := p2p.Peer{
IP: hc.P2P.IP,
Port: strconv.Itoa(hc.P2P.Port),
ConsensusPubKey: nodeConfig.ConsensusPriKey[0].Pub.Object,
}
myHost, err = p2p.NewHost(p2p.HostConfig{
Self: &selfPeer,
BLSKey: nodeConfig.P2PPriKey,
BootNodes: hc.Network.BootNodes,
DataStoreFile: hc.P2P.DHTDataStore,
})
if err != nil {
return nil, errors.Wrap(err, "cannot create P2P network host")
}
nodeConfig.DBDir = hc.General.DataDir
if hc.Legacy != nil && hc.Legacy.WebHookConfig != nil && len(*hc.Legacy.WebHookConfig) != 0 {
p := *hc.Legacy.WebHookConfig
config, err := webhooks.NewWebHooksFromPath(p)
if err != nil {
fmt.Fprintf(
os.Stderr, "yaml path is bad: %s", p,
)
os.Exit(1)
}
nodeConfig.WebHooks.Hooks = config
}
nodeConfig.NtpServer = hc.Sys.NtpServer
return nodeConfig, nil
}
func setupConsensusAndNode(hc harmonyconfig.HarmonyConfig, nodeConfig *nodeconfig.ConfigType) *node.Node {
// Consensus object.
// TODO: consensus object shouldn't start here
decider := quorum.NewDecider(quorum.SuperMajorityVote, uint32(hc.General.ShardID))
currentConsensus, err := consensus.New(
myHost, nodeConfig.ShardID, p2p.Peer{}, nodeConfig.ConsensusPriKey, decider,
)
currentConsensus.Decider.SetMyPublicKeyProvider(func() (multibls.PublicKeys, error) {
return currentConsensus.GetPublicKeys(), nil
})
if err != nil {
_, _ = fmt.Fprintf(os.Stderr, "Error :%v \n", err)
os.Exit(1)
}
// Parse minPeers from harmonyconfig.HarmonyConfig
var minPeers int
var aggregateSig bool
if hc.Consensus != nil {
minPeers = hc.Consensus.MinPeers
aggregateSig = hc.Consensus.AggregateSig
} else {
minPeers = defaultConsensusConfig.MinPeers
aggregateSig = defaultConsensusConfig.AggregateSig
}
currentConsensus.MinPeers = minPeers
currentConsensus.AggregateSig = aggregateSig
blacklist, err := setupBlacklist(hc)
if err != nil {
utils.Logger().Warn().Msgf("Blacklist setup error: %s", err.Error())
}
// Current node.
chainDBFactory := &shardchain.LDBFactory{RootDir: nodeConfig.DBDir}
currentNode := node.New(myHost, currentConsensus, chainDBFactory, blacklist, nodeConfig.ArchiveModes(), &hc)
if hc.Legacy != nil && hc.Legacy.TPBroadcastInvalidTxn != nil {
currentNode.BroadcastInvalidTx = *hc.Legacy.TPBroadcastInvalidTxn
} else {
currentNode.BroadcastInvalidTx = defaultBroadcastInvalidTx
}
// Syncing provider is provided by following rules:
// 1. If starting with a localnet or offline, use local sync peers.
// 2. If specified with --dns=false, use legacy syncing which is syncing through self-
// discover peers.
// 3. Else, use the dns for syncing.
if hc.Network.NetworkType == nodeconfig.Localnet || hc.General.IsOffline {
epochConfig := shard.Schedule.InstanceForEpoch(ethCommon.Big0)
selfPort := hc.P2P.Port
currentNode.SyncingPeerProvider = node.NewLocalSyncingPeerProvider(
6000, uint16(selfPort), epochConfig.NumShards(), uint32(epochConfig.NumNodesPerShard()))
} else if hc.DNSSync.LegacySyncing {
currentNode.SyncingPeerProvider = node.NewLegacySyncingPeerProvider(currentNode)
} else {
currentNode.SyncingPeerProvider = node.NewDNSSyncingPeerProvider(hc.DNSSync.Zone, strconv.Itoa(hc.DNSSync.Port))
}
// TODO: refactor the creation of blockchain out of node.New()
currentConsensus.Blockchain = currentNode.Blockchain()
currentNode.NodeConfig.DNSZone = hc.DNSSync.Zone
currentNode.NodeConfig.SetBeaconGroupID(
nodeconfig.NewGroupIDByShardID(shard.BeaconChainShardID),
)
nodeconfig.GetDefaultConfig().DBDir = nodeConfig.DBDir
switch hc.General.NodeType {
case nodeTypeExplorer:
nodeconfig.SetDefaultRole(nodeconfig.ExplorerNode)
currentNode.NodeConfig.SetRole(nodeconfig.ExplorerNode)
case nodeTypeValidator:
nodeconfig.SetDefaultRole(nodeconfig.Validator)
currentNode.NodeConfig.SetRole(nodeconfig.Validator)
}
currentNode.NodeConfig.SetShardGroupID(nodeconfig.NewGroupIDByShardID(nodeconfig.ShardID(nodeConfig.ShardID)))
currentNode.NodeConfig.SetClientGroupID(nodeconfig.NewClientGroupIDByShardID(shard.BeaconChainShardID))
currentNode.NodeConfig.ConsensusPriKey = nodeConfig.ConsensusPriKey
// This needs to be executed after consensus setup
if err := currentNode.InitConsensusWithValidators(); err != nil {
utils.Logger().Warn().
Int("shardID", hc.General.ShardID).
Err(err).
Msg("InitConsensusWithMembers failed")
}
// Set the consensus ID to be the current block number
viewID := currentNode.Blockchain().CurrentBlock().Header().ViewID().Uint64()
currentConsensus.SetViewIDs(viewID + 1)
utils.Logger().Info().
Uint64("viewID", viewID).
Msg("Init Blockchain")
// Assign closure functions to the consensus object
currentConsensus.SetBlockVerifier(currentNode.VerifyNewBlock)
currentConsensus.PostConsensusJob = currentNode.PostConsensusProcessing
// update consensus information based on the blockchain
currentConsensus.SetMode(currentConsensus.UpdateConsensusInformation())
currentConsensus.NextBlockDue = time.Now()
return currentNode
}
func setupPrometheusService(node *node.Node, hc harmonyconfig.HarmonyConfig, sid uint32) {
prometheusConfig := prometheus.Config{
Enabled: hc.Prometheus.Enabled,
IP: hc.Prometheus.IP,
Port: hc.Prometheus.Port,
EnablePush: hc.Prometheus.EnablePush,
Gateway: hc.Prometheus.Gateway,
Network: hc.Network.NetworkType,
Legacy: hc.General.NoStaking,
NodeType: hc.General.NodeType,
Shard: sid,
Instance: myHost.GetID().Pretty(),
}
p := prometheus.NewService(prometheusConfig)
node.RegisterService(service.Prometheus, p)
}
func setupSyncService(node *node.Node, host p2p.Host, hc harmonyconfig.HarmonyConfig) {
blockchains := []*core.BlockChain{node.Blockchain()}
if !node.IsRunningBeaconChain() {
blockchains = append(blockchains, node.Beaconchain())
}
dConfig := downloader.Config{
ServerOnly: !hc.Sync.Downloader,
Network: nodeconfig.NetworkType(hc.Network.NetworkType),
Concurrency: hc.Sync.Concurrency,
MinStreams: hc.Sync.MinPeers,
InitStreams: hc.Sync.InitStreams,
SmSoftLowCap: hc.Sync.DiscSoftLowCap,
SmHardLowCap: hc.Sync.DiscHardLowCap,
SmHiCap: hc.Sync.DiscHighCap,
SmDiscBatch: hc.Sync.DiscBatch,
}
// If we are running side chain, we will need to do some extra works for beacon
// sync
if !node.IsRunningBeaconChain() {
dConfig.BHConfig = &downloader.BeaconHelperConfig{
BlockC: node.BeaconBlockChannel,
InsertHook: node.BeaconSyncHook,
}
}
s := synchronize.NewService(host, blockchains, dConfig)
node.RegisterService(service.Synchronize, s)
d := s.Downloaders.GetShardDownloader(node.Blockchain().ShardID())
node.Consensus.SetDownloader(d)
}
func setupBlacklist(hc harmonyconfig.HarmonyConfig) (map[ethCommon.Address]struct{}, error) {
utils.Logger().Debug().Msgf("Using blacklist file at `%s`", hc.TxPool.BlacklistFile)
dat, err := ioutil.ReadFile(hc.TxPool.BlacklistFile)
if err != nil {
return nil, err
}
addrMap := make(map[ethCommon.Address]struct{})
for _, line := range strings.Split(string(dat), "\n") {
if len(line) != 0 { // blacklist file may have trailing empty string line
b32 := strings.TrimSpace(strings.Split(string(line), "#")[0])
addr, err := common.Bech32ToAddress(b32)
if err != nil {
return nil, err
}
addrMap[addr] = struct{}{}
}
}
return addrMap, nil
}
func listenOSSigAndShutDown(node *node.Node) {
// Prepare for graceful shutdown from os signals
osSignal := make(chan os.Signal)
signal.Notify(osSignal, syscall.SIGINT, syscall.SIGTERM)
sig := <-osSignal
utils.Logger().Warn().Str("signal", sig.String()).Msg("Gracefully shutting down...")
const msg = "Got %s signal. Gracefully shutting down...\n"
fmt.Fprintf(os.Stderr, msg, sig)
go node.ShutDown()
for i := 10; i > 0; i-- {
<-osSignal
if i > 1 {
fmt.Printf("Already shutting down, interrupt more to force quit: (times=%v)\n", i-1)
}
}
fmt.Println("Forced QUIT.")
os.Exit(-1)
}