The core protocol of WoopChain
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woop/node/node.go

404 lines
14 KiB

package node
import (
"crypto/ecdsa"
"fmt"
"math/big"
"os"
"sync"
"time"
"github.com/ethereum/go-ethereum/common"
"github.com/ethereum/go-ethereum/ethdb"
"github.com/ethereum/go-ethereum/params"
"github.com/harmony-one/harmony/api/client"
clientService "github.com/harmony-one/harmony/api/client/service"
msg_pb "github.com/harmony-one/harmony/api/proto/message"
"github.com/harmony-one/harmony/api/service"
"github.com/harmony-one/harmony/api/service/syncing"
"github.com/harmony-one/harmony/api/service/syncing/downloader"
"github.com/harmony-one/harmony/consensus"
"github.com/harmony-one/harmony/contracts"
"github.com/harmony-one/harmony/contracts/structs"
"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/drand"
nodeconfig "github.com/harmony-one/harmony/internal/configs/node"
"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.
)
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"
}
const (
// 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
//SyncIDLength is the length of bytes for syncID
SyncIDLength = 20
)
// use to push new block to outofsync node
type syncConfig struct {
timestamp int64
client *downloader.Client
}
// Node represents a protocol-participating node in the network
type Node struct {
Consensus *consensus.Consensus // Consensus object containing all Consensus related data (e.g. committee members, signatures, commits)
BlockChannel chan *types.Block // The channel to send newly proposed blocks
ConfirmedBlockChannel chan *types.Block // The channel to send confirmed blocks
BeaconBlockChannel chan *types.Block // The channel to send beacon blocks for non-beaconchain nodes
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
DRand *drand.DRand // The instance for distributed randomness protocol
blockchain *core.BlockChain // The blockchain for the shard where this node belongs
beaconChain *core.BlockChain // The blockchain for beacon chain.
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.
BCPeers []p2p.Peer // list of Beacon Chain Peers. This is needed by all nodes.
// TODO: Neighbors should store only neighbor nodes in the same shard
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
// BeaconNeighbors store only neighbor nodes in the beacon chain shard
BeaconNeighbors sync.Map // All the neighbor nodes, key is the sha256 of Peer IP/Port, value is the p2p.Peer
TxPool *core.TxPool
Worker *worker.Worker
BeaconWorker *worker.Worker // worker for beacon chain
// Client server (for wallet requests)
clientServer *clientService.Server
// Syncing component.
syncID [SyncIDLength]byte // a unique ID for the node during the state syncing process with peers
downloaderServer *downloader.Server
stateSync *syncing.StateSync
beaconSync *syncing.StateSync
peerRegistrationRecord map[string]*syncConfig // record registration time (unixtime) of peers begin in syncing
// The p2p host used to send/receive p2p messages
host p2p.Host
// Signal channel for lost validators
OfflinePeers chan p2p.Peer
// Service manager.
serviceManager *service.Manager
//Staked Accounts and Contract
CurrentStakes map[common.Address]*structs.StakeInfo //This will save the latest information about staked nodes.
StakingContractAddress common.Address
DemoContractAddress common.Address
WithdrawStakeFunc []byte
//Node Account
AccountKey *ecdsa.PrivateKey
Address common.Address
// For test only
TestBankKeys []*ecdsa.PrivateKey
ContractDeployerKey *ecdsa.PrivateKey
ContractAddresses []common.Address
// Group Message Receiver
groupReceiver p2p.GroupReceiver
// Client Message Receiver to handle light client messages
// Beacon leader needs to use this receiver to talk to new node
clientReceiver p2p.GroupReceiver
// Duplicated Ping Message Received
duplicatedPing sync.Map
// Channel to notify consensus service to really start consensus
startConsensus chan struct{}
// channel to notify the peers are ready
peerReadyChan chan struct{}
// node configuration, including group ID, shard ID, etc
NodeConfig *nodeconfig.ConfigType
// map of service type to its message channel.
serviceMessageChan map[service.Type]chan *msg_pb.Message
// Used to call smart contract locally
ContractCaller *contracts.ContractCaller
}
// 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)
node.pendingTransactions = unselected
utils.GetLogInstance().Debug("Selecting Transactions", "remainPending", len(node.pendingTransactions), "selected", len(selected), "invalidDiscarded", len(invalid))
node.pendingTxMutex.Unlock()
return selected
}
// StartServer starts a server and process the requests by a handler.
func (node *Node) StartServer() {
select {}
}
// 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
}
// GetSyncID returns the syncID of this node
func (node *Node) GetSyncID() [SyncIDLength]byte {
return node.syncID
}
// New creates a new node.
func New(host p2p.Host, consensusObj *consensus.Consensus, db ethdb.Database) *Node {
var chain *core.BlockChain
var err error
var isFirstTime bool // if cannot get blockchain from database, then isFirstTime = true
node := Node{}
copy(node.syncID[:], GenerateRandomString(SyncIDLength))
if host != nil {
node.host = host
node.SelfPeer = host.GetSelfPeer()
}
if host != nil && consensusObj != nil {
// Consensus and associated channel to communicate blocks
node.Consensus = consensusObj
// Init db
database := db
if database == nil {
database = ethdb.NewMemDatabase()
chain, err = node.GenesisBlockSetup(database)
isFirstTime = true
} else {
chain, err = node.InitBlockChainFromDB(db, node.Consensus)
isFirstTime = false
if err != nil || chain == nil || chain.CurrentBlock().NumberU64() <= 0 {
chain, err = node.GenesisBlockSetup(database)
isFirstTime = true
}
}
if err != nil {
utils.GetLogInstance().Error("Error when setup blockchain", "err", err)
os.Exit(1)
}
node.blockchain = chain
// Store the genesis shard state into db.
node.blockchain.StoreNewShardState(node.blockchain.CurrentBlock(), nil)
node.BlockChannel = make(chan *types.Block)
node.ConfirmedBlockChannel = make(chan *types.Block)
node.BeaconBlockChannel = 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.ConsensusPubKey), node.Consensus.ShardID)
node.Consensus.ConsensusBlock = make(chan *consensus.BFTBlockInfo)
node.Consensus.VerifiedNewBlock = make(chan *types.Block)
if isFirstTime {
// Setup one time smart contracts
node.AddFaucetContractToPendingTransactions()
node.CurrentStakes = make(map[common.Address]*structs.StakeInfo)
node.AddStakingContractToPendingTransactions() //This will save the latest information about staked nodes in current staked
// TODO(minhdoan): Think of a better approach to deploy smart contract.
// This is temporary for demo purpose.
node.AddLotteryContract()
}
}
node.ContractCaller = contracts.NewContractCaller(&db, node.blockchain, params.TestChainConfig)
if consensusObj != nil && consensusObj.IsLeader {
node.State = NodeLeader
go node.ReceiveClientGroupMessage()
} else {
node.State = NodeInit
}
// Setup initial state of syncing.
node.peerRegistrationRecord = make(map[string]*syncConfig)
node.OfflinePeers = make(chan p2p.Peer)
go node.RemovePeersHandler()
// start the goroutine to receive group message
go node.ReceiveGroupMessage()
node.startConsensus = make(chan struct{})
node.peerReadyChan = make(chan struct{})
// init the global and the only node config
node.NodeConfig = nodeconfig.GetConfigs(nodeconfig.Global)
return &node
}
// AddPeers adds neighbors nodes
func (node *Node) AddPeers(peers []*p2p.Peer) int {
count := 0
for _, p := range peers {
key := fmt.Sprintf("%s:%s:%s", p.IP, p.Port, p.PeerID)
_, ok := node.Neighbors.LoadOrStore(key, *p)
if !ok {
// !ok means new peer is stored
count++
node.host.AddPeer(p)
continue
}
}
if count > 0 {
node.Consensus.AddPeers(peers)
// TODO: make peers into a context object shared by consensus and drand
node.DRand.AddPeers(peers)
}
return count
}
// AddBeaconPeer adds beacon chain neighbors nodes
// Return false means new neighbor peer was added
// Return true means redundant neighbor peer wasn't added
func (node *Node) AddBeaconPeer(p *p2p.Peer) bool {
key := fmt.Sprintf("%s:%s:%s", p.IP, p.Port, p.PeerID)
_, ok := node.BeaconNeighbors.LoadOrStore(key, *p)
return ok
}
// 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)
}
}
}
// isBeacon = true if the node is beacon node
// isClient = true if the node light client(txgen,wallet)
func (node *Node) initNodeConfiguration(isBeacon bool, isClient bool) (service.NodeConfig, chan p2p.Peer) {
chanPeer := make(chan p2p.Peer)
nodeConfig := service.NodeConfig{
IsBeacon: isBeacon,
IsClient: isClient,
Beacon: p2p.GroupIDBeacon,
Group: p2p.GroupIDUnknown,
Actions: make(map[p2p.GroupID]p2p.ActionType),
}
nodeConfig.Actions[p2p.GroupIDBeaconClient] = p2p.ActionStart
var err error
if isBeacon {
node.groupReceiver, err = node.host.GroupReceiver(p2p.GroupIDBeacon)
node.clientReceiver, err = node.host.GroupReceiver(p2p.GroupIDBeaconClient)
node.NodeConfig.SetClientGroupID(p2p.GroupIDBeaconClient)
} else {
node.groupReceiver, err = node.host.GroupReceiver(p2p.GroupIDBeaconClient)
}
if err != nil {
utils.GetLogInstance().Error("create group receiver error", "msg", err)
}
return nodeConfig, chanPeer
}
// AddBeaconChainDatabase adds database support for beaconchain blocks on normal sharding nodes (not BeaconChain node)
func (node *Node) AddBeaconChainDatabase(db ethdb.Database) {
database := db
if database == nil {
database = ethdb.NewMemDatabase()
}
// TODO (chao) currently we use the same genesis block as normal shard
chain, err := node.GenesisBlockSetup(database)
if err != nil {
utils.GetLogInstance().Error("Error when doing genesis setup")
os.Exit(1)
}
node.beaconChain = chain
node.BeaconWorker = worker.New(params.TestChainConfig, chain, node.Consensus, pki.GetAddressFromPublicKey(node.SelfPeer.ConsensusPubKey), node.Consensus.ShardID)
}
// InitBlockChainFromDB retrieves the latest blockchain and state available from the local database
func (node *Node) InitBlockChainFromDB(db ethdb.Database, consensus *consensus.Consensus) (*core.BlockChain, error) {
chainConfig := params.TestChainConfig
if consensus != nil {
chainConfig.ChainID = big.NewInt(int64(consensus.ShardID)) // Use ChainID as piggybacked ShardID
}
cacheConfig := core.CacheConfig{Disabled: false, TrieNodeLimit: 256 * 1024 * 1024, TrieTimeLimit: 5 * time.Minute}
chain, err := core.NewBlockChain(db, &cacheConfig, chainConfig, consensus, vm.Config{}, nil)
return chain, err
}