package node
import (
"bytes"
"crypto/ecdsa"
"encoding/binary"
"encoding/gob"
"encoding/hex"
"fmt"
"math/big"
"os"
"strconv"
"strings"
"sync"
"time"
"github.com/ethereum/go-ethereum/common"
"github.com/ethereum/go-ethereum/crypto"
"github.com/ethereum/go-ethereum/ethdb"
"github.com/ethereum/go-ethereum/log"
"github.com/ethereum/go-ethereum/params"
"github.com/ethereum/go-ethereum/rlp"
"github.com/harmony-one/harmony/api/client"
clientService "github.com/harmony-one/harmony/api/client/service"
proto_discovery "github.com/harmony-one/harmony/api/proto/discovery"
proto_node "github.com/harmony-one/harmony/api/proto/node"
service_manager "github.com/harmony-one/harmony/api/service"
blockproposal "github.com/harmony-one/harmony/api/service/blockproposal"
consensus_service "github.com/harmony-one/harmony/api/service/consensus"
"github.com/harmony-one/harmony/api/service/explorer"
"github.com/harmony-one/harmony/api/service/syncing"
"github.com/harmony-one/harmony/api/service/syncing/downloader"
downloader_pb "github.com/harmony-one/harmony/api/service/syncing/downloader/proto"
bft "github.com/harmony-one/harmony/consensus"
"github.com/harmony-one/harmony/core"
"github.com/harmony-one/harmony/core/types"
"github.com/harmony-one/harmony/core/vm"
"github.com/harmony-one/harmony/crypto/pki"
"github.com/harmony-one/harmony/internal/utils"
"github.com/harmony-one/harmony/node/worker"
"github.com/harmony-one/harmony/p2p"
)
// State is a state of a node.
type State byte
// All constants except the NodeLeader below are for validators only.
const (
NodeInit State = iota // Node just started, before contacting BeaconChain
NodeWaitToJoin // Node contacted BeaconChain, wait to join Shard
NodeNotInSync // Node out of sync, might be just joined Shard or offline for a period of time
NodeOffline // Node is offline
NodeReadyForConsensus // Node is ready for doing consensus
NodeDoingConsensus // Node is already doing consensus
NodeLeader // Node is the leader of some shard.
)
// Role defines a role of a node.
type Role byte
// All constants for different node roles.
const (
Unknown Role = iota
ShardLeader
ShardValidator
BeaconLeader
BeaconValidator
NewNode
)
func ( state State ) String ( ) string {
switch state {
case NodeInit :
return "NodeInit"
case NodeWaitToJoin :
return "NodeWaitToJoin"
case NodeNotInSync :
return "NodeNotInSync"
case NodeOffline :
return "NodeOffline"
case NodeReadyForConsensus :
return "NodeReadyForConsensus"
case NodeDoingConsensus :
return "NodeDoingConsensus"
case NodeLeader :
return "NodeLeader"
}
return "Unknown"
}
// Constants related to doing syncing.
const (
lastMileThreshold = 4
inSyncThreshold = 2
)
const (
waitBeforeJoinShard = time . Second * 3
timeOutToJoinShard = time . Minute * 10
// ClientServicePortDiff is the positive port diff for client service
ClientServicePortDiff = 5555
maxBroadcastNodes = 10 // broadcast at most maxBroadcastNodes peers that need in sync
broadcastTimeout int64 = 3 * 60 * 1000000000 // 3 mins
)
// use to push new block to outofsync node
type syncConfig struct {
timestamp int64
client * downloader . Client
}
// NetworkNode ...
type NetworkNode struct {
SelfPeer p2p . Peer
IDCPeer p2p . Peer
}
// Node represents a protocol-participating node in the network
type Node struct {
Consensus * bft . Consensus // Consensus object containing all Consensus related data (e.g. committee members, signatures, commits)
BlockChannel chan * types . Block // The channel to receive new blocks from Node
pendingTransactions types . Transactions // All the transactions received but not yet processed for Consensus
transactionInConsensus [ ] * types . Transaction // The transactions selected into the new block and under Consensus process
pendingTxMutex sync . Mutex
blockchain * core . BlockChain // The blockchain for the shard where this node belongs
db * ethdb . LDBDatabase // LevelDB to store blockchain.
ClientPeer * p2p . Peer // The peer for the harmony tx generator client, used for leaders to return proof-of-accept
Client * client . Client // The presence of a client object means this node will also act as a client
SelfPeer p2p . Peer // TODO(minhdoan): it could be duplicated with Self below whose is Alok work.
IDCPeer p2p . Peer
Neighbors sync . Map // All the neighbor nodes, key is the sha256 of Peer IP/Port, value is the p2p.Peer
State State // State of the Node
stateMutex sync . Mutex // mutex for change node state
TxPool * core . TxPool
Worker * worker . Worker
// Client server (for wallet requests)
clientServer * clientService . Server
// Syncing component.
downloaderServer * downloader . Server
stateSync * syncing . StateSync
peerRegistrationRecord map [ uint32 ] * syncConfig // record registration time (unixtime) of peers begin in syncing
// The p2p host used to send/receive p2p messages
host p2p . Host
// Channel to stop sending ping message
StopPing chan struct { }
// Signal channel for lost validators
OfflinePeers chan p2p . Peer
// Node Role.
Role Role
// Service manager.
serviceManager * service_manager . Manager
// For test only
TestBankKeys [ ] * ecdsa . PrivateKey
ContractKeys [ ] * ecdsa . PrivateKey
ContractAddresses [ ] common . Address
}
// Blockchain returns the blockchain from node
func ( node * Node ) Blockchain ( ) * core . BlockChain {
return node . blockchain
}
// Add new transactions to the pending transaction list
func ( node * Node ) addPendingTransactions ( newTxs types . Transactions ) {
node . pendingTxMutex . Lock ( )
node . pendingTransactions = append ( node . pendingTransactions , newTxs ... )
node . pendingTxMutex . Unlock ( )
utils . GetLogInstance ( ) . Debug ( "Got more transactions" , "num" , len ( newTxs ) , "totalPending" , len ( node . pendingTransactions ) )
}
// Take out a subset of valid transactions from the pending transaction list
// Note the pending transaction list will then contain the rest of the txs
func ( node * Node ) getTransactionsForNewBlock ( maxNumTxs int ) types . Transactions {
node . pendingTxMutex . Lock ( )
selected , unselected , invalid := node . Worker . SelectTransactionsForNewBlock ( node . pendingTransactions , maxNumTxs )
_ = invalid // invalid txs are discard
utils . GetLogInstance ( ) . Debug ( "Invalid transactions discarded" , "number" , len ( invalid ) )
node . pendingTransactions = unselected
utils . GetLogInstance ( ) . Debug ( "Remaining pending transactions" , "number" , len ( node . pendingTransactions ) )
node . pendingTxMutex . Unlock ( )
return selected
}
// StartServer starts a server and process the requests by a handler.
func ( node * Node ) StartServer ( ) {
node . host . BindHandlerAndServe ( node . StreamHandler )
}
// Count the total number of transactions in the blockchain
// Currently used for stats reporting purpose
func ( node * Node ) countNumTransactionsInBlockchain ( ) int {
count := 0
for block := node . blockchain . CurrentBlock ( ) ; block != nil ; block = node . blockchain . GetBlockByHash ( block . Header ( ) . ParentHash ) {
count += len ( block . Transactions ( ) )
}
return count
}
// SerializeNode serializes the node
// https://stackoverflow.com/questions/12854125/how-do-i-dump-the-struct-into-the-byte-array-without-reflection/12854659#12854659
func ( node * Node ) SerializeNode ( nnode * NetworkNode ) [ ] byte {
//Needs to escape the serialization of unexported fields
var result bytes . Buffer
encoder := gob . NewEncoder ( & result )
err := encoder . Encode ( nnode )
if err != nil {
fmt . Println ( "Could not serialize node" )
fmt . Println ( "ERROR" , err )
//utils.GetLogInstance().Error("Could not serialize node")
}
return result . Bytes ( )
}
// DeserializeNode deserializes the node
func DeserializeNode ( d [ ] byte ) * NetworkNode {
var wn NetworkNode
r := bytes . NewBuffer ( d )
decoder := gob . NewDecoder ( r )
err := decoder . Decode ( & wn )
if err != nil {
log . Error ( "Could not de-serialize node 1" )
}
return & wn
}
// New creates a new node.
func New ( host p2p . Host , consensus * bft . Consensus , db ethdb . Database ) * Node {
node := Node { }
if host != nil {
node . host = host
node . SelfPeer = host . GetSelfPeer ( )
}
if host != nil && consensus != nil {
// Consensus and associated channel to communicate blocks
node . Consensus = consensus
// Initialize genesis block and blockchain
genesisAlloc := node . CreateGenesisAllocWithTestingAddresses ( 100 )
contractKey , _ := ecdsa . GenerateKey ( crypto . S256 ( ) , strings . NewReader ( "Test contract key string stream that is fixed so that generated test key are deterministic every time" ) )
contractAddress := crypto . PubkeyToAddress ( contractKey . PublicKey )
contractFunds := big . NewInt ( 9000000 )
contractFunds = contractFunds . Mul ( contractFunds , big . NewInt ( params . Ether ) )
genesisAlloc [ contractAddress ] = core . GenesisAccount { Balance : contractFunds }
node . ContractKeys = append ( node . ContractKeys , contractKey )
database := db
if database == nil {
database = ethdb . NewMemDatabase ( )
}
chainConfig := params . TestChainConfig
chainConfig . ChainID = big . NewInt ( int64 ( node . Consensus . ShardID ) ) // Use ChainID as piggybacked ShardID
gspec := core . Genesis {
Config : chainConfig ,
Alloc : genesisAlloc ,
ShardID : uint32 ( node . Consensus . ShardID ) ,
}
_ = gspec . MustCommit ( database )
chain , _ := core . NewBlockChain ( database , nil , gspec . Config , node . Consensus , vm . Config { } , nil )
node . blockchain = chain
node . BlockChannel = make ( chan * types . Block )
node . TxPool = core . NewTxPool ( core . DefaultTxPoolConfig , params . TestChainConfig , chain )
node . Worker = worker . New ( params . TestChainConfig , chain , node . Consensus , pki . GetAddressFromPublicKey ( node . SelfPeer . PubKey ) , node . Consensus . ShardID )
node . AddSmartContractsToPendingTransactions ( )
node . Consensus . ConsensusBlock = make ( chan * types . Block )
node . Consensus . VerifiedNewBlock = make ( chan * types . Block )
}
if consensus != nil && consensus . IsLeader {
node . State = NodeLeader
} else {
node . State = NodeInit
}
// Setup initial state of syncing.
node . StopPing = make ( chan struct { } )
node . peerRegistrationRecord = make ( map [ uint32 ] * syncConfig )
node . OfflinePeers = make ( chan p2p . Peer )
go node . RemovePeersHandler ( )
return & node
}
// IsOutOfSync checks whether the node is out of sync by comparing latest block with consensus block
func ( node * Node ) IsOutOfSync ( consensusBlock * types . Block ) bool {
myHeight := node . blockchain . CurrentBlock ( ) . NumberU64 ( )
newHeight := consensusBlock . NumberU64 ( )
utils . GetLogInstance ( ) . Debug ( "[SYNC]" , "myHeight" , myHeight , "newHeight" , newHeight )
if newHeight - myHeight <= inSyncThreshold {
return false
}
// cache latest blocks for last mile catch up
if newHeight - myHeight <= lastMileThreshold && node . stateSync != nil {
node . stateSync . AddLastMileBlock ( consensusBlock )
}
return true
}
// DoSyncing wait for check status and starts syncing if out of sync
func ( node * Node ) DoSyncing ( ) {
for {
select {
// in current implementation logic, timeout means in sync
case <- time . After ( 5 * time . Second ) :
node . stateMutex . Lock ( )
node . State = NodeReadyForConsensus
node . stateMutex . Unlock ( )
continue
case consensusBlock := <- node . Consensus . ConsensusBlock :
// never reached from chao
if ! node . IsOutOfSync ( consensusBlock ) {
if node . State == NodeNotInSync {
utils . GetLogInstance ( ) . Info ( "[SYNC] Node is now IN SYNC!" )
node . stateSync . CloseConnections ( )
node . stateSync = nil
}
node . stateMutex . Lock ( )
node . State = NodeReadyForConsensus
node . stateMutex . Unlock ( )
continue
} else {
utils . GetLogInstance ( ) . Debug ( "[SYNC] node is out of sync" )
node . stateMutex . Lock ( )
node . State = NodeNotInSync
node . stateMutex . Unlock ( )
}
if node . stateSync == nil {
node . stateSync = syncing . CreateStateSync ( node . SelfPeer . IP , node . SelfPeer . Port )
node . stateSync . CreateSyncConfig ( node . GetSyncingPeers ( ) )
node . stateSync . MakeConnectionToPeers ( )
}
startHash := node . blockchain . CurrentBlock ( ) . Hash ( )
node . stateSync . StartStateSync ( startHash [ : ] , node . blockchain , node . Worker )
}
}
}
// AddPeers adds neighbors nodes
func ( node * Node ) AddPeers ( peers [ ] * p2p . Peer ) int {
count := 0
for _ , p := range peers {
key := fmt . Sprintf ( "%v" , p . PubKey )
_ , ok := node . Neighbors . Load ( key )
if ! ok {
node . Neighbors . Store ( key , * p )
count ++
node . host . AddPeer ( p )
continue
}
if node . SelfPeer . ValidatorID == - 1 && p . IP == node . SelfPeer . IP && p . Port == node . SelfPeer . Port {
node . SelfPeer . ValidatorID = p . ValidatorID
}
}
if count > 0 {
node . Consensus . AddPeers ( peers )
}
return count
}
// GetSyncingPort returns the syncing port.
func GetSyncingPort ( nodePort string ) string {
if port , err := strconv . Atoi ( nodePort ) ; err == nil {
return fmt . Sprintf ( "%d" , port - syncing . SyncingPortDifference )
}
os . Exit ( 1 )
return ""
}
// GetSyncingPeers returns list of peers.
func ( node * Node ) GetSyncingPeers ( ) [ ] p2p . Peer {
res := [ ] p2p . Peer { }
node . Neighbors . Range ( func ( k , v interface { } ) bool {
res = append ( res , v . ( p2p . Peer ) )
return true
} )
removeID := - 1
for i := range res {
if res [ i ] . Port == node . SelfPeer . Port {
removeID = i
}
res [ i ] . Port = GetSyncingPort ( res [ i ] . Port )
}
if removeID != - 1 {
res = append ( res [ : removeID ] , res [ removeID + 1 : ] ... )
}
utils . GetLogInstance ( ) . Debug ( "GetSyncingPeers: " , "res" , res , "self" , node . SelfPeer )
return res
}
//AddSmartContractsToPendingTransactions adds the faucet contract the genesis block.
func ( node * Node ) AddSmartContractsToPendingTransactions ( ) {
// Add a contract deployment transactionv
priKey := node . ContractKeys [ 0 ]
contractData := "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"
dataEnc := common . FromHex ( contractData )
// Unsigned transaction to avoid the case of transaction address.
contractFunds := big . NewInt ( 8000000 )
contractFunds = contractFunds . Mul ( contractFunds , big . NewInt ( params . Ether ) )
mycontracttx , _ := types . SignTx ( types . NewContractCreation ( uint64 ( 0 ) , node . Consensus . ShardID , contractFunds , params . TxGasContractCreation * 10 , nil , dataEnc ) , types . HomesteadSigner { } , priKey )
node . ContractAddresses = append ( node . ContractAddresses , crypto . CreateAddress ( crypto . PubkeyToAddress ( priKey . PublicKey ) , uint64 ( 0 ) ) )
node . addPendingTransactions ( types . Transactions { mycontracttx } )
}
//CallFaucetContract invokes the faucet contract to give the walletAddress initial money
func ( node * Node ) CallFaucetContract ( walletAddress common . Address ) common . Hash {
state , err := node . blockchain . State ( )
if err != nil {
log . Error ( "Failed to get chain state" , "Error" , err )
}
nonce := state . GetNonce ( crypto . PubkeyToAddress ( node . ContractKeys [ 0 ] . PublicKey ) )
callingFunction := "0x27c78c42000000000000000000000000"
contractData := callingFunction + hex . EncodeToString ( walletAddress . Bytes ( ) )
dataEnc := common . FromHex ( contractData )
tx , _ := types . SignTx ( types . NewTransaction ( nonce , node . ContractAddresses [ 0 ] , node . Consensus . ShardID , big . NewInt ( 0 ) , params . TxGasContractCreation * 10 , nil , dataEnc ) , types . HomesteadSigner { } , node . ContractKeys [ 0 ] )
node . addPendingTransactions ( types . Transactions { tx } )
return tx . Hash ( )
}
// JoinShard helps a new node to join a shard.
func ( node * Node ) JoinShard ( leader p2p . Peer ) {
// try to join the shard, send ping message every 1 second, with a 10 minutes time-out
tick := time . NewTicker ( 1 * time . Second )
timeout := time . NewTicker ( 10 * time . Minute )
defer tick . Stop ( )
defer timeout . Stop ( )
for {
select {
case <- tick . C :
ping := proto_discovery . NewPingMessage ( node . SelfPeer )
if node . Client != nil { // assume this is the client node
ping . Node . Role = proto_node . ClientRole
}
buffer := ping . ConstructPingMessage ( )
// Talk to leader.
node . SendMessage ( leader , buffer )
case <- timeout . C :
utils . GetLogInstance ( ) . Info ( "JoinShard timeout" )
return
case <- node . StopPing :
utils . GetLogInstance ( ) . Info ( "Stopping JoinShard" )
return
}
}
}
// SupportClient initializes and starts the client service
func ( node * Node ) SupportClient ( ) {
node . InitClientServer ( )
node . StartClientServer ( )
}
// InitClientServer initializes client server.
func ( node * Node ) InitClientServer ( ) {
node . clientServer = clientService . NewServer ( node . blockchain . State , node . CallFaucetContract )
}
// StartClientServer starts client server.
func ( node * Node ) StartClientServer ( ) {
port , _ := strconv . Atoi ( node . SelfPeer . Port )
utils . GetLogInstance ( ) . Info ( "support_client: StartClientServer on port:" , "port" , port + ClientServicePortDiff )
node . clientServer . Start ( node . SelfPeer . IP , strconv . Itoa ( port + ClientServicePortDiff ) )
}
// SupportSyncing keeps sleeping until it's doing consensus or it's a leader.
func ( node * Node ) SupportSyncing ( ) {
node . InitSyncingServer ( )
node . StartSyncingServer ( )
go node . DoSyncing ( )
go node . SendNewBlockToUnsync ( )
}
// InitSyncingServer starts downloader server.
func ( node * Node ) InitSyncingServer ( ) {
node . downloaderServer = downloader . NewServer ( node )
}
// StartSyncingServer starts syncing server.
func ( node * Node ) StartSyncingServer ( ) {
utils . GetLogInstance ( ) . Info ( "support_sycning: StartSyncingServer" )
node . downloaderServer . Start ( node . SelfPeer . IP , GetSyncingPort ( node . SelfPeer . Port ) )
}
// CalculateResponse implements DownloadInterface on Node object.
func ( node * Node ) CalculateResponse ( request * downloader_pb . DownloaderRequest ) ( * downloader_pb . DownloaderResponse , error ) {
response := & downloader_pb . DownloaderResponse { }
switch request . Type {
case downloader_pb . DownloaderRequest_HEADER :
utils . GetLogInstance ( ) . Debug ( "[SYNC] CalculateResponse DownloaderRequest_HEADER" , "request.BlockHash" , request . BlockHash )
var startHeaderHash [ ] byte
if request . BlockHash == nil {
tmp := node . blockchain . Genesis ( ) . Hash ( )
startHeaderHash = tmp [ : ]
} else {
startHeaderHash = request . BlockHash
}
for block := node . blockchain . CurrentBlock ( ) ; block != nil ; block = node . blockchain . GetBlockByHash ( block . Header ( ) . ParentHash ) {
blockHash := block . Hash ( )
if bytes . Compare ( blockHash [ : ] , startHeaderHash ) == 0 {
break
}
response . Payload = append ( response . Payload , blockHash [ : ] )
}
case downloader_pb . DownloaderRequest_BLOCK :
for _ , bytes := range request . Hashes {
var hash common . Hash
hash . SetBytes ( bytes )
block := node . blockchain . GetBlockByHash ( hash )
encodedBlock , err := rlp . EncodeToBytes ( block )
if err == nil {
response . Payload = append ( response . Payload , encodedBlock )
}
}
case downloader_pb . DownloaderRequest_NEWBLOCK :
if node . State != NodeNotInSync {
utils . GetLogInstance ( ) . Debug ( "[SYNC] new block received, but state is" , "state" , node . State . String ( ) )
response . Type = downloader_pb . DownloaderResponse_INSYNC
return response , nil
}
var blockObj types . Block
err := rlp . DecodeBytes ( request . BlockHash , & blockObj )
if err != nil {
utils . GetLogInstance ( ) . Warn ( "[SYNC] unable to decode received new block" )
return response , err
}
node . stateSync . AddNewBlock ( request . PeerHash , & blockObj )
case downloader_pb . DownloaderRequest_REGISTER :
peerID := binary . BigEndian . Uint32 ( request . PeerHash )
if _ , ok := node . peerRegistrationRecord [ peerID ] ; ok {
response . Type = downloader_pb . DownloaderResponse_FAIL
return response , nil
} else if len ( node . peerRegistrationRecord ) >= maxBroadcastNodes {
response . Type = downloader_pb . DownloaderResponse_FAIL
return response , nil
} else {
peer , ok := node . Consensus . GetPeerFromID ( peerID )
if ! ok {
utils . GetLogInstance ( ) . Warn ( "[SYNC] unable to get peer from peerID" , "peerID" , peerID )
}
client := downloader . ClientSetup ( peer . IP , GetSyncingPort ( peer . Port ) )
if client == nil {
utils . GetLogInstance ( ) . Warn ( "[SYNC] unable to setup client" )
return response , nil
}
utils . GetLogInstance ( ) . Debug ( "[SYNC] client setup correctly" , "client" , client )
config := & syncConfig { timestamp : time . Now ( ) . UnixNano ( ) , client : client }
node . stateMutex . Lock ( )
node . peerRegistrationRecord [ peerID ] = config
node . stateMutex . Unlock ( )
utils . GetLogInstance ( ) . Debug ( "[SYNC] register peerID success" , "peerID" , peerID )
response . Type = downloader_pb . DownloaderResponse_SUCCESS
}
case downloader_pb . DownloaderRequest_REGISTERTIMEOUT :
if node . State == NodeNotInSync {
count := node . stateSync . RegisterNodeInfo ( )
utils . GetLogInstance ( ) . Debug ( "[SYNC] extra node registered" , "number" , count )
}
}
return response , nil
}
// SendNewBlockToUnsync send latest verified block to unsync, registered nodes
func ( node * Node ) SendNewBlockToUnsync ( ) {
for {
block := <- node . Consensus . VerifiedNewBlock
blockHash , err := rlp . EncodeToBytes ( block )
if err != nil {
utils . GetLogInstance ( ) . Warn ( "[SYNC] unable to encode block to hashes" )
continue
}
// really need to have a unique id independent of ip/port
selfPeerID := utils . GetUniqueIDFromIPPort ( node . SelfPeer . IP , node . SelfPeer . Port )
utils . GetLogInstance ( ) . Debug ( "[SYNC] peerRegistration Record" , "peerID" , selfPeerID , "number" , len ( node . peerRegistrationRecord ) )
for peerID , config := range node . peerRegistrationRecord {
elapseTime := time . Now ( ) . UnixNano ( ) - config . timestamp
if elapseTime > broadcastTimeout {
utils . GetLogInstance ( ) . Warn ( "[SYNC] SendNewBlockToUnsync to peer timeout" , "peerID" , peerID )
// send last time and delete
config . client . PushNewBlock ( selfPeerID , blockHash , true )
node . stateMutex . Lock ( )
node . peerRegistrationRecord [ peerID ] . client . Close ( )
delete ( node . peerRegistrationRecord , peerID )
node . stateMutex . Unlock ( )
continue
}
response := config . client . PushNewBlock ( selfPeerID , blockHash , false )
if response != nil && response . Type == downloader_pb . DownloaderResponse_INSYNC {
node . stateMutex . Lock ( )
node . peerRegistrationRecord [ peerID ] . client . Close ( )
delete ( node . peerRegistrationRecord , peerID )
node . stateMutex . Unlock ( )
}
}
}
}
// RemovePeersHandler is a goroutine to wait on the OfflinePeers channel
// and remove the peers from validator list
func ( node * Node ) RemovePeersHandler ( ) {
for {
select {
case p := <- node . OfflinePeers :
node . Consensus . OfflinePeerList = append ( node . Consensus . OfflinePeerList , p )
}
}
}
func ( node * Node ) setupForShardLeader ( ) {
// Register explorer service.
node . serviceManager . RegisterService ( service_manager . SupportExplorer , explorer . New ( & node . SelfPeer ) )
// Register consensus service.
node . serviceManager . RegisterService ( service_manager . Consensus , consensus_service . NewService ( node . BlockChannel , node . Consensus ) )
// Register new block service.
node . serviceManager . RegisterService ( service_manager . BlockProposal , blockproposal . NewService ( node . Consensus . ReadySignal , node . WaitForConsensusReady ) )
}
func ( node * Node ) setupForShardValidator ( ) {
}
func ( node * Node ) setupForBeaconLeader ( ) {
}
func ( node * Node ) setupForBeaconValidator ( ) {
}
func ( node * Node ) setupForNewNode ( ) {
}
// ServiceManagerSetup setups service store.
func ( node * Node ) ServiceManagerSetup ( ) {
node . serviceManager = & service_manager . Manager { }
switch node . Role {
case ShardLeader :
node . setupForShardLeader ( )
case ShardValidator :
node . setupForShardValidator ( )
case BeaconLeader :
node . setupForBeaconLeader ( )
case BeaconValidator :
node . setupForBeaconValidator ( )
case NewNode :
node . setupForNewNode ( )
}
}
// RunServices runs registered services.
func ( node * Node ) RunServices ( ) {
if node . serviceManager == nil {
utils . GetLogInstance ( ) . Info ( "Service manager is not set up yet." )
return
}
for serviceType := range node . serviceManager . GetServices ( ) {
action := & service_manager . Action {
Action : service_manager . Start ,
ServiceType : serviceType ,
}
node . serviceManager . TakeAction ( action )
}
}