package node
import (
"bufio"
"bytes"
"encoding/gob"
"fmt"
"net"
"os"
"strconv"
"time"
"github.com/simple-rules/harmony-benchmark/blockchain"
"github.com/simple-rules/harmony-benchmark/p2p"
"github.com/simple-rules/harmony-benchmark/proto"
"github.com/simple-rules/harmony-benchmark/proto/client"
"github.com/simple-rules/harmony-benchmark/proto/consensus"
proto_identity "github.com/simple-rules/harmony-benchmark/proto/identity"
proto_node "github.com/simple-rules/harmony-benchmark/proto/node"
)
const (
// MinNumberOfTransactionsPerBlock is the min number of transaction per a block.
MinNumberOfTransactionsPerBlock = 6000
// MaxNumberOfTransactionsPerBlock is the max number of transaction per a block.
MaxNumberOfTransactionsPerBlock = 20000
// NumBlocksBeforeStateBlock is the number of blocks allowed before generating state block
NumBlocksBeforeStateBlock = 1000
)
// MaybeBroadcastAsValidator returns if the node is a validator node.
func ( node * Node ) MaybeBroadcastAsValidator ( content [ ] byte ) {
if node . SelfPeer . ValidatorID > 0 && node . SelfPeer . ValidatorID <= p2p . MAX_BROADCAST {
go p2p . BroadcastMessageFromValidator ( node . SelfPeer , node . Consensus . GetValidatorPeers ( ) , content )
}
}
// NodeHandler handles a new incoming connection.
func ( node * Node ) NodeHandler ( conn net . Conn ) {
defer conn . Close ( )
// Read p2p message payload
content , err := p2p . ReadMessageContent ( conn )
if err != nil {
node . log . Error ( "Read p2p data failed" , "err" , err , "node" , node )
return
}
node . MaybeBroadcastAsValidator ( content )
consensusObj := node . Consensus
msgCategory , err := proto . GetMessageCategory ( content )
if err != nil {
node . log . Error ( "Read node type failed" , "err" , err , "node" , node )
return
}
msgType , err := proto . GetMessageType ( content )
if err != nil {
node . log . Error ( "Read action type failed" , "err" , err , "node" , node )
return
}
msgPayload , err := proto . GetMessagePayload ( content )
if err != nil {
node . log . Error ( "Read message payload failed" , "err" , err , "node" , node )
return
}
switch msgCategory {
case proto . IDENTITY :
actionType := proto_identity . IdentityMessageType ( msgType )
switch actionType {
case proto_identity . IDENTITY :
messageType := proto_identity . MessageType ( msgPayload [ 0 ] )
switch messageType {
case proto_identity . REGISTER :
fmt . Println ( "received a identity message" )
node . processPOWMessage ( msgPayload )
case proto_identity . ANNOUNCE :
node . log . Error ( "Announce message should be sent to IdentityChain" )
}
}
case proto . CONSENSUS :
actionType := consensus . ConsensusMessageType ( msgType )
switch actionType {
case consensus . CONSENSUS :
if consensusObj . IsLeader {
consensusObj . ProcessMessageLeader ( msgPayload )
} else {
consensusObj . ProcessMessageValidator ( msgPayload )
}
}
case proto . NODE :
actionType := proto_node . NodeMessageType ( msgType )
switch actionType {
case proto_node . Transaction :
node . transactionMessageHandler ( msgPayload )
case proto_node . BLOCK :
blockMsgType := proto_node . BlockMessageType ( msgPayload [ 0 ] )
switch blockMsgType {
case proto_node . SYNC :
decoder := gob . NewDecoder ( bytes . NewReader ( msgPayload [ 1 : ] ) ) // skip the SYNC messge type
blocks := new ( [ ] * blockchain . Block )
decoder . Decode ( blocks )
if node . Client != nil && node . Client . UpdateBlocks != nil && blocks != nil {
node . Client . UpdateBlocks ( * blocks )
}
}
case proto_node . BlockchainSync :
node . handleBlockchainSync ( msgPayload , conn )
case proto_node . CLIENT :
clientMsgType := proto_node . ClientMessageType ( msgPayload [ 0 ] )
switch clientMsgType {
case proto_node . LookupUtxo :
decoder := gob . NewDecoder ( bytes . NewReader ( msgPayload [ 1 : ] ) ) // skip the LookupUtxo messge type
fetchUtxoMessage := new ( proto_node . FetchUtxoMessage )
decoder . Decode ( fetchUtxoMessage )
utxoMap := node . UtxoPool . GetUtxoMapByAddresses ( fetchUtxoMessage . Addresses )
p2p . SendMessage ( fetchUtxoMessage . Sender , client . ConstructFetchUtxoResponseMessage ( & utxoMap , node . UtxoPool . ShardID ) )
}
case proto_node . CONTROL :
controlType := msgPayload [ 0 ]
if proto_node . ControlMessageType ( controlType ) == proto_node . STOP {
node . log . Debug ( "Stopping Node" , "node" , node , "numBlocks" , len ( node . blockchain . Blocks ) , "numTxsProcessed" , node . countNumTransactionsInBlockchain ( ) )
sizeInBytes := node . UtxoPool . GetSizeInByteOfUtxoMap ( )
node . log . Debug ( "UtxoPool Report" , "numEntries" , len ( node . UtxoPool . UtxoMap ) , "sizeInBytes" , sizeInBytes )
avgBlockSizeInBytes := 0
txCount := 0
blockCount := 0
totalTxCount := 0
totalBlockCount := 0
avgTxSize := 0
for _ , block := range node . blockchain . Blocks {
if block . IsStateBlock ( ) {
totalTxCount += int ( block . State . NumTransactions )
totalBlockCount += int ( block . State . NumBlocks )
} else {
byteBuffer := bytes . NewBuffer ( [ ] byte { } )
encoder := gob . NewEncoder ( byteBuffer )
encoder . Encode ( block )
avgBlockSizeInBytes += len ( byteBuffer . Bytes ( ) )
txCount += len ( block . Transactions )
blockCount ++
totalTxCount += len ( block . TransactionIds )
totalBlockCount ++
byteBuffer = bytes . NewBuffer ( [ ] byte { } )
encoder = gob . NewEncoder ( byteBuffer )
encoder . Encode ( block . Transactions )
avgTxSize += len ( byteBuffer . Bytes ( ) )
}
}
if blockCount != 0 {
avgBlockSizeInBytes = avgBlockSizeInBytes / blockCount
avgTxSize = avgTxSize / txCount
}
node . log . Debug ( "Blockchain Report" , "totalNumBlocks" , totalBlockCount , "avgBlockSizeInCurrentEpoch" , avgBlockSizeInBytes , "totalNumTxs" , totalTxCount , "avgTxSzieInCurrentEpoch" , avgTxSize )
os . Exit ( 0 )
}
}
case proto . CLIENT :
actionType := client . ClientMessageType ( msgType )
switch actionType {
case client . Transaction :
if node . Client != nil {
node . Client . TransactionMessageHandler ( msgPayload )
}
}
}
}
// Refactor by moving this code into a sync package.
func ( node * Node ) handleBlockchainSync ( payload [ ] byte , conn net . Conn ) {
// TODO(minhdoan): Looking to removing this.
w := bufio . NewWriter ( conn )
FOR_LOOP :
for {
syncMsgType := proto_node . BlockchainSyncMessageType ( payload [ 0 ] )
switch syncMsgType {
case proto_node . GetBlock :
block := node . blockchain . FindBlock ( payload [ 1 : 33 ] )
w . Write ( block . Serialize ( ) )
w . Flush ( )
case proto_node . GetLastBlockHashes :
blockchainSyncMessage := proto_node . BlockchainSyncMessage {
BlockHeight : len ( node . blockchain . Blocks ) ,
BlockHashes : node . blockchain . GetBlockHashes ( ) ,
}
w . Write ( proto_node . SerializeBlockchainSyncMessage ( & blockchainSyncMessage ) )
w . Flush ( )
case proto_node . DONE :
break FOR_LOOP
}
content , err := p2p . ReadMessageContent ( conn )
if err != nil {
node . log . Error ( "Failed in reading message content from syncing node" , err )
return
}
msgCategory , _ := proto . GetMessageCategory ( content )
if err != nil || msgCategory != proto . NODE {
node . log . Error ( "Failed in reading message category from syncing node" , err )
return
}
msgType , err := proto . GetMessageType ( content )
actionType := proto_node . NodeMessageType ( msgType )
if err != nil || actionType != proto_node . BlockchainSync {
node . log . Error ( "Failed in reading message type from syncing node" , err )
return
}
payload , err = proto . GetMessagePayload ( content )
if err != nil {
node . log . Error ( "Failed in reading payload from syncing node" , err )
return
}
}
node . log . Info ( "HOORAY: Done sending info to syncing node." )
}
func ( node * Node ) transactionMessageHandler ( msgPayload [ ] byte ) {
txMessageType := proto_node . TransactionMessageType ( msgPayload [ 0 ] )
switch txMessageType {
case proto_node . SEND :
txDecoder := gob . NewDecoder ( bytes . NewReader ( msgPayload [ 1 : ] ) ) // skip the SEND messge type
txList := new ( [ ] * blockchain . Transaction )
err := txDecoder . Decode ( txList )
if err != nil {
node . log . Error ( "Failed to deserialize transaction list" , "error" , err )
}
node . addPendingTransactions ( * txList )
case proto_node . REQUEST :
reader := bytes . NewBuffer ( msgPayload [ 1 : ] )
var txIDs map [ [ 32 ] byte ] bool
buf := make ( [ ] byte , 32 ) // 32 byte hash Id
for {
_ , err := reader . Read ( buf )
if err != nil {
break
}
var txID [ 32 ] byte
copy ( txID [ : ] , buf )
txIDs [ txID ] = true
}
var txToReturn [ ] * blockchain . Transaction
for _ , tx := range node . pendingTransactions {
if txIDs [ tx . ID ] {
txToReturn = append ( txToReturn , tx )
}
}
// TODO: return the transaction list to requester
case proto_node . UNLOCK :
txAndProofDecoder := gob . NewDecoder ( bytes . NewReader ( msgPayload [ 1 : ] ) ) // skip the UNLOCK messge type
txAndProofs := new ( [ ] * blockchain . Transaction )
err := txAndProofDecoder . Decode ( & txAndProofs )
if err != nil {
node . log . Error ( "Failed deserializing transaction and proofs list" , "node" , node )
}
node . log . Debug ( "RECEIVED UNLOCK MESSAGE" , "num" , len ( * txAndProofs ) )
node . addPendingTransactions ( * txAndProofs )
}
}
// WaitForConsensusReady ...
func ( node * Node ) WaitForConsensusReady ( readySignal chan struct { } ) {
node . log . Debug ( "Waiting for Consensus ready" , "node" , node )
var newBlock * blockchain . Block
timeoutCount := 0
for { // keep waiting for Consensus ready
retry := false
// TODO(minhdoan, rj): Refactor by sending signal in channel instead of waiting for 10 seconds.
select {
case <- readySignal :
time . Sleep ( 100 * time . Millisecond ) // Delay a bit so validator is catched up.
case <- time . After ( 100 * time . Second ) :
retry = true
node . Consensus . ResetState ( )
timeoutCount ++
node . log . Debug ( "Consensus timeout, retry!" , "count" , timeoutCount , "node" , node )
}
//node.log.Debug("Adding new block", "currentChainSize", len(node.blockchain.Blocks), "numTxs", len(node.blockchain.GetLatestBlock().Transactions), "PrevHash", node.blockchain.GetLatestBlock().PrevBlockHash, "Hash", node.blockchain.GetLatestBlock().Hash)
if ! retry {
if len ( node . blockchain . Blocks ) > NumBlocksBeforeStateBlock {
// Generate state block and run consensus on it
newBlock = node . blockchain . CreateStateBlock ( node . UtxoPool )
} else {
// Normal tx block consensus
for {
// Once we have pending transactions we will try creating a new block
if len ( node . pendingTransactions ) >= MaxNumberOfTransactionsPerBlock {
node . log . Debug ( "Start selecting transactions" )
selectedTxs , crossShardTxAndProofs := node . getTransactionsForNewBlock ( MaxNumberOfTransactionsPerBlock )
if len ( selectedTxs ) < MinNumberOfTransactionsPerBlock {
node . log . Debug ( "No valid transactions exist" , "pendingTx" , len ( node . pendingTransactions ) )
} else {
node . log . Debug ( "Creating new block" , "numAllTxs" , len ( selectedTxs ) , "numCrossTxs" , len ( crossShardTxAndProofs ) , "pendingTxs" , len ( node . pendingTransactions ) , "currentChainSize" , len ( node . blockchain . Blocks ) )
node . transactionInConsensus = selectedTxs
node . CrossTxsInConsensus = crossShardTxAndProofs
newBlock = blockchain . NewBlock ( selectedTxs , node . blockchain . GetLatestBlock ( ) . Hash , node . Consensus . ShardID )
break
}
}
// If not enough transactions to run Consensus,
// periodically check whether we have enough transactions to package into block.
time . Sleep ( 1 * time . Second )
}
}
}
// Send the new block to Consensus so it can be confirmed.
if newBlock != nil {
node . BlockChannel <- * newBlock
}
}
}
// SendBackProofOfAcceptOrReject is called by consensus participants to verify the block they are running consensus on
func ( node * Node ) SendBackProofOfAcceptOrReject ( ) {
if node . ClientPeer != nil && len ( node . CrossTxsToReturn ) != 0 {
node . crossTxToReturnMutex . Lock ( )
proofs := [ ] blockchain . CrossShardTxProof { }
for _ , txAndProof := range node . CrossTxsToReturn {
proofs = append ( proofs , * txAndProof . Proof )
}
node . CrossTxsToReturn = nil
node . crossTxToReturnMutex . Unlock ( )
node . log . Debug ( "SENDING PROOF TO CLIENT" , "proofs" , len ( proofs ) )
p2p . SendMessage ( * node . ClientPeer , client . ConstructProofOfAcceptOrRejectMessage ( proofs ) )
}
}
// BroadcastNewBlock is called by consensus leader to sync new blocks with other clients/nodes.
// NOTE: For now, just send to the client (basically not broadcasting)
func ( node * Node ) BroadcastNewBlock ( newBlock * blockchain . Block ) {
if node . ClientPeer != nil {
node . log . Debug ( "SENDING NEW BLOCK TO CLIENT" )
p2p . SendMessage ( * node . ClientPeer , proto_node . ConstructBlocksSyncMessage ( [ ] blockchain . Block { * newBlock } ) )
}
}
// VerifyNewBlock is called by consensus participants to verify the block they are running consensus on
func ( node * Node ) VerifyNewBlock ( newBlock * blockchain . Block ) bool {
if newBlock . IsStateBlock ( ) {
return node . UtxoPool . VerifyStateBlock ( newBlock )
}
return node . UtxoPool . VerifyTransactions ( newBlock . Transactions )
}
// PostConsensusProcessing is called by consensus participants, after consensus is done, to:
// 1. add the new block to blockchain
// 2. [leader] move cross shard tx and proof to the list where they wait to be sent to the client
func ( node * Node ) PostConsensusProcessing ( newBlock * blockchain . Block ) {
if newBlock . IsStateBlock ( ) {
// Clear out old tx blocks and put state block as genesis
if node . db != nil {
node . log . Info ( "Deleting old blocks." )
for i := 1 ; i <= len ( node . blockchain . Blocks ) ; i ++ {
blockchain . Delete ( node . db , strconv . Itoa ( i ) )
}
}
node . blockchain . Blocks = [ ] * blockchain . Block { }
}
if node . Consensus . IsLeader {
// Move crossTx-in-consensus into the list to be returned to client
for _ , crossTxAndProof := range node . CrossTxsInConsensus {
crossTxAndProof . Proof . BlockHash = newBlock . Hash
// TODO: fill in the signature proofs
}
if len ( node . CrossTxsInConsensus ) != 0 {
node . addCrossTxsToReturn ( node . CrossTxsInConsensus )
node . CrossTxsInConsensus = [ ] * blockchain . CrossShardTxAndProof { }
}
node . SendBackProofOfAcceptOrReject ( )
node . BroadcastNewBlock ( newBlock )
}
node . AddNewBlock ( newBlock )
node . UpdateUtxoAndState ( newBlock )
}
// AddNewBlock is usedd to add new block into the blockchain.
func ( node * Node ) AddNewBlock ( newBlock * blockchain . Block ) {
// Add it to blockchain
node . blockchain . Blocks = append ( node . blockchain . Blocks , newBlock )
// Store it into leveldb.
if node . db != nil {
node . log . Info ( "Writing new block into disk." )
newBlock . Write ( node . db , strconv . Itoa ( len ( node . blockchain . Blocks ) ) )
}
}
// UpdateUtxoAndState updates Utxo and state.
func ( node * Node ) UpdateUtxoAndState ( newBlock * blockchain . Block ) {
// Update UTXO pool
if newBlock . IsStateBlock ( ) {
newUtxoPool := blockchain . CreateUTXOPoolFromGenesisBlock ( newBlock )
node . UtxoPool . UtxoMap = newUtxoPool . UtxoMap
} else {
node . UtxoPool . Update ( newBlock . Transactions )
}
// Clear transaction-in-Consensus list
node . transactionInConsensus = [ ] * blockchain . Transaction { }
if node . Consensus . IsLeader {
node . log . Info ( "TX in New BLOCK" , "num" , len ( newBlock . Transactions ) , "ShardID" , node . UtxoPool . ShardID , "IsStateBlock" , newBlock . IsStateBlock ( ) )
node . log . Info ( "LEADER CURRENT UTXO" , "num" , node . UtxoPool . CountNumOfUtxos ( ) , "ShardID" , node . UtxoPool . ShardID )
node . log . Info ( "LEADER LOCKED UTXO" , "num" , node . UtxoPool . CountNumOfLockedUtxos ( ) , "ShardID" , node . UtxoPool . ShardID )
}
}