package node
import (
"bytes"
"crypto/ecdsa"
"encoding/gob"
"fmt"
"math/big"
"net"
"strings"
"sync"
"time"
"github.com/ethereum/go-ethereum/crypto"
"github.com/ethereum/go-ethereum/params"
"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/node/worker"
"github.com/harmony-one/harmony/blockchain"
"github.com/harmony-one/harmony/client"
bft "github.com/harmony-one/harmony/consensus"
"github.com/harmony-one/harmony/crypto/pki"
hdb "github.com/harmony-one/harmony/db"
"github.com/harmony-one/harmony/log"
"github.com/harmony-one/harmony/p2p"
proto_identity "github.com/harmony-one/harmony/proto/identity"
proto_node "github.com/harmony-one/harmony/proto/node"
)
type NodeState byte
const (
NodeInit NodeState = iota // Node just started, before contacting BeaconChain
NodeWaitToJoin // Node contacted BeaconChain, wait to join Shard
NodeJoinedShard // Node joined Shard, ready for consensus
NodeOffline // Node is offline
)
type NetworkNode struct {
SelfPeer p2p . Peer
IDCPeer p2p . Peer
}
// Node represents a program (machine) participating in the network
// TODO(minhdoan, rj): consider using BlockChannel *chan blockchain.Block for efficiency.
type Node struct {
Consensus * bft . Consensus // Consensus object containing all Consensus related data (e.g. committee members, signatures, commits)
BlockChannel chan blockchain . Block // The channel to receive new blocks from Node
pendingTransactions [ ] * blockchain . Transaction // All the transactions received but not yet processed for Consensus
transactionInConsensus [ ] * blockchain . Transaction // The transactions selected into the new block and under Consensus process
blockchain * blockchain . Blockchain // The blockchain for the shard where this node belongs
db * hdb . LDBDatabase // LevelDB to store blockchain.
UtxoPool * blockchain . UTXOPool // The corresponding UTXO pool of the current blockchain
CrossTxsInConsensus [ ] * blockchain . CrossShardTxAndProof // The cross shard txs that is under consensus, the proof is not filled yet.
CrossTxsToReturn [ ] * blockchain . CrossShardTxAndProof // The cross shard txs and proof that needs to be sent back to the user client.
log log . Logger // Log utility
pendingTxMutex sync . Mutex
crossTxToReturnMutex sync . Mutex
ClientPeer * p2p . Peer // The peer for the benchmark 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
IsWaiting bool
SelfPeer p2p . Peer // TODO(minhdoan): it could be duplicated with Self below whose is Alok work.
IDCPeer p2p . Peer
SyncNode bool // TODO(minhdoan): Remove it later.
chain * core . BlockChain // Account Model
Neighbors sync . Map // All the neighbor nodes, key is the sha256 of Peer IP/Port, value is the p2p.Peer
State NodeState // State of the Node
// Account Model
Chain * core . BlockChain
TxPool * core . TxPool
BlockChannelAccount chan * types . Block // The channel to receive new blocks from Node
worker * worker . Worker
// Test only
testBankKey * ecdsa . PrivateKey
}
// Add new crossTx and proofs to the list of crossTx that needs to be sent back to client
func ( node * Node ) addCrossTxsToReturn ( crossTxs [ ] * blockchain . CrossShardTxAndProof ) {
node . crossTxToReturnMutex . Lock ( )
node . CrossTxsToReturn = append ( node . CrossTxsToReturn , crossTxs ... )
node . crossTxToReturnMutex . Unlock ( )
node . log . Debug ( "Got more cross transactions to return" , "num" , len ( crossTxs ) , len ( node . pendingTransactions ) , "node" , node )
}
// Add new transactions to the pending transaction list
func ( node * Node ) addPendingTransactions ( newTxs [ ] * blockchain . Transaction ) {
node . pendingTxMutex . Lock ( )
node . pendingTransactions = append ( node . pendingTransactions , newTxs ... )
node . pendingTxMutex . Unlock ( )
node . log . Debug ( "Got more transactions" , "num" , len ( newTxs ) , "totalPending" , len ( node . pendingTransactions ) , "node" , node )
}
// 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 ) ( [ ] * blockchain . Transaction , [ ] * blockchain . CrossShardTxAndProof ) {
node . pendingTxMutex . Lock ( )
selected , unselected , invalid , crossShardTxs := node . UtxoPool . SelectTransactionsForNewBlock ( node . pendingTransactions , maxNumTxs )
_ = invalid // invalid txs are discard
node . log . Debug ( "Invalid transactions discarded" , "number" , len ( invalid ) )
node . pendingTransactions = unselected
node . pendingTxMutex . Unlock ( )
return selected , crossShardTxs
}
// StartServer starts a server and process the request by a handler.
func ( node * Node ) StartServer ( port string ) {
if node . SyncNode {
// Disable this temporarily.
// node.blockchain = syncing.StartBlockSyncing(node.Consensus.GetValidatorPeers())
}
fmt . Println ( "going to start server on port:" , port )
//node.log.Debug("Starting server", "node", node, "port", port)
node . listenOnPort ( port )
}
func ( node * Node ) SetLog ( ) * Node {
node . log = log . New ( )
return node
}
func ( node * Node ) listenOnPort ( port string ) {
addr := net . JoinHostPort ( "" , port )
listen , err := net . Listen ( "tcp4" , addr )
if err != nil {
node . log . Error ( "Socket listen port failed" , "addr" , addr , "err" , err )
return
}
if listen == nil {
node . log . Error ( "Listen returned nil" , "addr" , addr )
return
}
defer listen . Close ( )
backoff := p2p . NewExpBackoff ( 250 * time . Millisecond , 15 * time . Second , 2.0 )
for {
conn , err := listen . Accept ( )
if err != nil {
node . log . Error ( "Error listening on port." , "port" , port ,
"err" , err )
backoff . Sleep ( )
continue
}
go node . NodeHandler ( conn )
}
}
func ( node * Node ) String ( ) string {
return node . Consensus . String ( )
}
// Count the total number of transactions in the blockchain
// Currently used for stats reporting purpose
func ( node * Node ) countNumTransactionsInBlockchain ( ) int {
count := 0
for _ , block := range node . blockchain . Blocks {
count += len ( block . Transactions )
}
return count
}
//ConnectIdentityChain connects to identity chain
func ( node * Node ) ConnectBeaconChain ( ) {
Nnode := & NetworkNode { SelfPeer : node . SelfPeer , IDCPeer : node . IDCPeer }
msg := node . SerializeNode ( Nnode )
msgToSend := proto_identity . ConstructIdentityMessage ( proto_identity . Register , msg )
p2p . SendMessage ( node . IDCPeer , msgToSend )
}
// 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 )
//node.log.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 ( consensus * bft . Consensus , db * hdb . LDBDatabase ) * Node {
node := Node { }
if consensus != nil {
// Consensus and associated channel to communicate blocks
node . Consensus = consensus
node . BlockChannel = make ( chan blockchain . Block )
// Genesis Block
// TODO(minh): Use or implement new function in blockchain package for this.
genesisBlock := & blockchain . Blockchain { }
genesisBlock . Blocks = make ( [ ] * blockchain . Block , 0 )
// TODO(RJ): use miner's address as coinbase address
coinbaseTx := blockchain . NewCoinbaseTX ( pki . GetAddressFromInt ( 1 ) , "0" , node . Consensus . ShardID )
genesisBlock . Blocks = append ( genesisBlock . Blocks , blockchain . NewGenesisBlock ( coinbaseTx , node . Consensus . ShardID ) )
node . blockchain = genesisBlock
// UTXO pool from Genesis block
node . UtxoPool = blockchain . CreateUTXOPoolFromGenesisBlock ( node . blockchain . Blocks [ 0 ] )
// Initialize level db.
node . db = db
// (account model)
node . testBankKey , _ = ecdsa . GenerateKey ( crypto . S256 ( ) , strings . NewReader ( "Fixed source of randomnessasdffffffffffffffffffffffffffffffffffffffffsdffffffffffffffffffffffffffffffffffffffffffffffffffffff" ) )
testBankAddress := crypto . PubkeyToAddress ( node . testBankKey . PublicKey )
testBankFunds := big . NewInt ( 1000000000000000000 )
database := hdb . NewMemDatabase ( )
gspec := core . Genesis {
Config : params . TestChainConfig ,
Alloc : core . GenesisAlloc { testBankAddress : { Balance : testBankFunds } } ,
}
_ = gspec . MustCommit ( database )
chain , _ := core . NewBlockChain ( database , nil , gspec . Config , bft . NewFaker ( ) , vm . Config { } , nil )
node . Chain = chain
node . TxPool = core . NewTxPool ( core . DefaultTxPoolConfig , params . TestChainConfig , chain )
node . BlockChannelAccount = make ( chan * types . Block )
node . worker = worker . New ( params . TestChainConfig , chain , bft . NewFaker ( ) )
fmt . Println ( "BALANCE" )
fmt . Println ( node . worker . GetCurrentState ( ) . GetBalance ( testBankAddress ) )
}
// Logger
node . log = log . New ( )
node . State = NodeInit
return & node
}
// Add 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 ++
}
}
if count > 0 {
c := node . Consensus . AddPeers ( peers )
node . log . Info ( "Node.AddPeers" , "#" , c )
}
return count
}
func ( node * Node ) JoinShard ( leader p2p . Peer ) {
// try to join the shard, with 10 minutes time-out
backoff := p2p . NewExpBackoff ( 1 * time . Second , 10 * time . Minute , 2 )
for node . State == NodeWaitToJoin {
backoff . Sleep ( )
ping := proto_node . NewPingMessage ( node . SelfPeer )
buffer := ping . ConstructPingMessage ( )
p2p . SendMessage ( leader , buffer )
node . log . Debug ( "Sent ping message" )
}
}