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588 lines
20 KiB
588 lines
20 KiB
package node
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import (
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"bytes"
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"encoding/gob"
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"fmt"
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"net"
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"os"
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"strconv"
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"time"
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"github.com/dedis/kyber"
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"github.com/ethereum/go-ethereum/rlp"
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"github.com/harmony-one/harmony/blockchain"
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"github.com/harmony-one/harmony/core/types"
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hmy_crypto "github.com/harmony-one/harmony/crypto"
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"github.com/harmony-one/harmony/crypto/pki"
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"github.com/harmony-one/harmony/p2p"
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"github.com/harmony-one/harmony/proto"
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"github.com/harmony-one/harmony/proto/client"
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"github.com/harmony-one/harmony/proto/consensus"
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proto_identity "github.com/harmony-one/harmony/proto/identity"
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proto_node "github.com/harmony-one/harmony/proto/node"
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)
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const (
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// MinNumberOfTransactionsPerBlock is the min number of transaction per a block.
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MinNumberOfTransactionsPerBlock = 6000
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// MaxNumberOfTransactionsPerBlock is the max number of transaction per a block.
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MaxNumberOfTransactionsPerBlock = 8000
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// NumBlocksBeforeStateBlock is the number of blocks allowed before generating state block
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NumBlocksBeforeStateBlock = 1000
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)
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// MaybeBroadcastAsValidator returns if the node is a validator node.
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func (node *Node) MaybeBroadcastAsValidator(content []byte) {
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if node.SelfPeer.ValidatorID > 0 && node.SelfPeer.ValidatorID <= p2p.MaxBroadCast {
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go p2p.BroadcastMessageFromValidator(node.SelfPeer, node.Consensus.GetValidatorPeers(), content)
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}
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}
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// NodeHandler handles a new incoming connection.
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func (node *Node) NodeHandler(conn net.Conn) {
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defer conn.Close()
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// Read p2p message payload
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content, err := p2p.ReadMessageContent(conn)
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if err != nil {
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node.log.Error("Read p2p data failed", "err", err, "node", node)
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return
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}
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// TODO: this is tree broadcasting. this needs to be removed later. Actually the whole logic needs to be replaced by p2p.
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node.MaybeBroadcastAsValidator(content)
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consensusObj := node.Consensus
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msgCategory, err := proto.GetMessageCategory(content)
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if err != nil {
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node.log.Error("Read node type failed", "err", err, "node", node)
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return
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}
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msgType, err := proto.GetMessageType(content)
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if err != nil {
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node.log.Error("Read action type failed", "err", err, "node", node)
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return
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}
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msgPayload, err := proto.GetMessagePayload(content)
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if err != nil {
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node.log.Error("Read message payload failed", "err", err, "node", node)
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return
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}
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switch msgCategory {
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case proto.Identity:
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actionType := proto_identity.IDMessageType(msgType)
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switch actionType {
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case proto_identity.Identity:
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messageType := proto_identity.MessageType(msgPayload[0])
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switch messageType {
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case proto_identity.Register:
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fmt.Println("received a identity message")
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// TODO(ak): fix it.
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// node.processPOWMessage(msgPayload)
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node.log.Info("NET: received message: IDENTITY/REGISTER")
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default:
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node.log.Error("Announce message should be sent to IdentityChain")
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}
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}
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case proto.Consensus:
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actionType := consensus.ConMessageType(msgType)
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switch actionType {
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case consensus.Consensus:
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if consensusObj.IsLeader {
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node.log.Info("NET: received message: Consensus/Leader")
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consensusObj.ProcessMessageLeader(msgPayload)
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} else {
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node.log.Info("NET: received message: Consensus/Validator")
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consensusObj.ProcessMessageValidator(msgPayload)
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}
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}
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case proto.Node:
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actionType := proto_node.MessageType(msgType)
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switch actionType {
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case proto_node.Transaction:
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node.log.Info("NET: received message: Node/Transaction")
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node.transactionMessageHandler(msgPayload)
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case proto_node.Block:
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node.log.Info("NET: received message: Node/Block")
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blockMsgType := proto_node.BlockMessageType(msgPayload[0])
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switch blockMsgType {
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case proto_node.Sync:
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decoder := gob.NewDecoder(bytes.NewReader(msgPayload[1:])) // skip the Sync messge type
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blocks := new([]*blockchain.Block)
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decoder.Decode(blocks)
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if node.Client != nil && node.Client.UpdateBlocks != nil && blocks != nil {
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node.Client.UpdateBlocks(*blocks)
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}
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}
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case proto_node.Client:
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node.log.Info("NET: received message: Node/Client")
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clientMsgType := proto_node.ClientMessageType(msgPayload[0])
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switch clientMsgType {
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case proto_node.LookupUtxo:
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decoder := gob.NewDecoder(bytes.NewReader(msgPayload[1:])) // skip the LookupUtxo messge type
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fetchUtxoMessage := new(proto_node.FetchUtxoMessage)
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decoder.Decode(fetchUtxoMessage)
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utxoMap := node.UtxoPool.GetUtxoMapByAddresses(fetchUtxoMessage.Addresses)
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p2p.SendMessage(fetchUtxoMessage.Sender, client.ConstructFetchUtxoResponseMessage(&utxoMap, node.UtxoPool.ShardID))
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}
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case proto_node.Control:
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node.log.Info("NET: received message: Node/Control")
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controlType := msgPayload[0]
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if proto_node.ControlMessageType(controlType) == proto_node.STOP {
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if node.Chain == nil {
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node.log.Debug("Stopping Node", "node", node, "numBlocks", len(node.blockchain.Blocks), "numTxsProcessed", node.countNumTransactionsInBlockchain())
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sizeInBytes := node.UtxoPool.GetSizeInByteOfUtxoMap()
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node.log.Debug("UtxoPool Report", "numEntries", len(node.UtxoPool.UtxoMap), "sizeInBytes", sizeInBytes)
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avgBlockSizeInBytes := 0
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txCount := 0
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blockCount := 0
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totalTxCount := 0
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totalBlockCount := 0
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avgTxSize := 0
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for _, block := range node.blockchain.Blocks {
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if block.IsStateBlock() {
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totalTxCount += int(block.State.NumTransactions)
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totalBlockCount += int(block.State.NumBlocks)
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} else {
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byteBuffer := bytes.NewBuffer([]byte{})
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encoder := gob.NewEncoder(byteBuffer)
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encoder.Encode(block)
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avgBlockSizeInBytes += len(byteBuffer.Bytes())
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txCount += len(block.Transactions)
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blockCount++
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totalTxCount += len(block.TransactionIds)
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totalBlockCount++
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byteBuffer = bytes.NewBuffer([]byte{})
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encoder = gob.NewEncoder(byteBuffer)
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encoder.Encode(block.Transactions)
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avgTxSize += len(byteBuffer.Bytes())
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}
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}
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if blockCount != 0 {
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avgBlockSizeInBytes = avgBlockSizeInBytes / blockCount
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avgTxSize = avgTxSize / txCount
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}
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node.log.Debug("Blockchain Report", "totalNumBlocks", totalBlockCount, "avgBlockSizeInCurrentEpoch", avgBlockSizeInBytes, "totalNumTxs", totalTxCount, "avgTxSzieInCurrentEpoch", avgTxSize)
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} else {
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node.log.Debug("Stopping Node (Account Model)", "node", node, "CurBlockNum", node.Chain.CurrentHeader().Number, "numTxsProcessed", node.countNumTransactionsInBlockchainAccount())
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}
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os.Exit(0)
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}
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case proto_node.PING:
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node.pingMessageHandler(msgPayload)
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case proto_node.PONG:
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node.pongMessageHandler(msgPayload)
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}
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case proto.Client:
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actionType := client.MessageType(msgType)
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node.log.Info("NET: received message: Client/Transaction")
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switch actionType {
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case client.Transaction:
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if node.Client != nil {
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node.Client.TransactionMessageHandler(msgPayload)
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}
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}
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default:
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node.log.Error("Unknown", "MsgCateory:", msgCategory)
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}
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}
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func (node *Node) transactionMessageHandler(msgPayload []byte) {
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txMessageType := proto_node.TransactionMessageType(msgPayload[0])
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switch txMessageType {
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case proto_node.Send:
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if node.Chain != nil {
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txs := types.Transactions{}
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err := rlp.Decode(bytes.NewReader(msgPayload[1:]), &txs) // skip the Send messge type
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if err != nil {
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node.log.Error("Failed to deserialize transaction list", "error", err)
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}
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node.addPendingTransactionsAccount(txs)
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} else {
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txDecoder := gob.NewDecoder(bytes.NewReader(msgPayload[1:])) // skip the Send messge type
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txList := new([]*blockchain.Transaction)
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err := txDecoder.Decode(&txList)
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if err != nil {
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node.log.Error("Failed to deserialize transaction list", "error", err)
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}
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node.addPendingTransactions(*txList)
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}
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case proto_node.Request:
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reader := bytes.NewBuffer(msgPayload[1:])
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txIDs := make(map[[32]byte]bool)
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buf := make([]byte, 32) // 32 byte hash Id
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for {
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_, err := reader.Read(buf)
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if err != nil {
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break
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}
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var txID [32]byte
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copy(txID[:], buf)
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txIDs[txID] = true
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}
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var txToReturn []*blockchain.Transaction
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for _, tx := range node.pendingTransactions {
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if txIDs[tx.ID] {
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txToReturn = append(txToReturn, tx)
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}
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}
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// TODO: return the transaction list to requester
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case proto_node.Unlock:
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txAndProofDecoder := gob.NewDecoder(bytes.NewReader(msgPayload[1:])) // skip the Unlock messge type
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txAndProofs := new([]*blockchain.Transaction)
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err := txAndProofDecoder.Decode(&txAndProofs)
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if err != nil {
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node.log.Error("Failed deserializing transaction and proofs list", "node", node)
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}
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node.log.Debug("RECEIVED Unlock MESSAGE", "num", len(*txAndProofs))
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node.addPendingTransactions(*txAndProofs)
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}
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}
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// WaitForConsensusReady ...
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func (node *Node) WaitForConsensusReady(readySignal chan struct{}) {
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node.log.Debug("Waiting for Consensus ready", "node", node)
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var newBlock *blockchain.Block
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timeoutCount := 0
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for { // keep waiting for Consensus ready
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retry := false
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// TODO(minhdoan, rj): Refactor by sending signal in channel instead of waiting for 10 seconds.
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select {
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case <-readySignal:
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time.Sleep(100 * time.Millisecond) // Delay a bit so validator is catched up.
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case <-time.After(200 * time.Second):
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retry = true
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node.Consensus.ResetState()
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timeoutCount++
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node.log.Debug("Consensus timeout, retry!", "count", timeoutCount, "node", node)
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}
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//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)
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if !retry {
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if len(node.blockchain.Blocks) > NumBlocksBeforeStateBlock {
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// Generate state block and run consensus on it
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newBlock = node.blockchain.CreateStateBlock(node.UtxoPool)
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} else {
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// Normal tx block consensus
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for {
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// Once we have pending transactions we will try creating a new block
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if len(node.pendingTransactions) >= MaxNumberOfTransactionsPerBlock {
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node.log.Debug("Start selecting transactions")
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selectedTxs, crossShardTxAndProofs := node.getTransactionsForNewBlock(MaxNumberOfTransactionsPerBlock)
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if len(selectedTxs) < MinNumberOfTransactionsPerBlock {
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node.log.Debug("No valid transactions exist", "pendingTx", len(node.pendingTransactions))
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} else {
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node.log.Debug("Creating new block", "numAllTxs", len(selectedTxs), "numCrossTxs", len(crossShardTxAndProofs), "pendingTxs", len(node.pendingTransactions), "currentChainSize", len(node.blockchain.Blocks))
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node.transactionInConsensus = selectedTxs
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node.CrossTxsInConsensus = crossShardTxAndProofs
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newBlock = blockchain.NewBlock(selectedTxs, node.blockchain.GetLatestBlock().Hash, node.Consensus.ShardID)
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break
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}
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}
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// If not enough transactions to run Consensus,
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// periodically check whether we have enough transactions to package into block.
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time.Sleep(1 * time.Second)
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}
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}
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}
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// Send the new block to Consensus so it can be confirmed.
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if newBlock != nil {
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node.BlockChannel <- *newBlock
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}
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}
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}
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// WaitForConsensusReadyAccount ...
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func (node *Node) WaitForConsensusReadyAccount(readySignal chan struct{}) {
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node.log.Debug("Waiting for Consensus ready", "node", node)
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var newBlock *types.Block
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timeoutCount := 0
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for { // keep waiting for Consensus ready
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retry := false
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select {
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case <-readySignal:
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time.Sleep(100 * time.Millisecond) // Delay a bit so validator is catched up.
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case <-time.After(200 * time.Second):
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retry = true
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node.Consensus.ResetState()
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timeoutCount++
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node.log.Debug("Consensus timeout, retry!", "count", timeoutCount, "node", node)
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}
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if !retry {
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for {
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if len(node.pendingTransactionsAccount) >= 1000 {
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// Normal tx block consensus
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selectedTxs, _ := node.getTransactionsForNewBlockAccount(MaxNumberOfTransactionsPerBlock)
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node.Worker.CommitTransactions(selectedTxs)
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block, err := node.Worker.Commit()
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if err != nil {
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node.log.Debug("Failed commiting new block", "Error", err)
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} else {
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newBlock = block
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break
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}
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}
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// If not enough transactions to run Consensus,
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// periodically check whether we have enough transactions to package into block.
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time.Sleep(1 * time.Second)
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}
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}
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// Send the new block to Consensus so it can be confirmed.
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if newBlock != nil {
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node.BlockChannelAccount <- newBlock
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}
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}
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}
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// SendBackProofOfAcceptOrReject is called by consensus participants to verify the block they are running consensus on
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func (node *Node) SendBackProofOfAcceptOrReject() {
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if node.ClientPeer != nil && len(node.CrossTxsToReturn) != 0 {
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node.crossTxToReturnMutex.Lock()
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proofs := []blockchain.CrossShardTxProof{}
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for _, txAndProof := range node.CrossTxsToReturn {
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proofs = append(proofs, *txAndProof.Proof)
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}
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node.CrossTxsToReturn = nil
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node.crossTxToReturnMutex.Unlock()
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node.log.Debug("SENDING PROOF TO CLIENT", "proofs", len(proofs))
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p2p.SendMessage(*node.ClientPeer, client.ConstructProofOfAcceptOrRejectMessage(proofs))
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}
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}
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// BroadcastNewBlock is called by consensus leader to sync new blocks with other clients/nodes.
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// NOTE: For now, just send to the client (basically not broadcasting)
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func (node *Node) BroadcastNewBlock(newBlock *blockchain.Block) {
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if node.ClientPeer != nil {
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node.log.Debug("NET: SENDING NEW BLOCK TO CLIENT")
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p2p.SendMessage(*node.ClientPeer, proto_node.ConstructBlocksSyncMessage([]blockchain.Block{*newBlock}))
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}
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}
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// VerifyNewBlock is called by consensus participants to verify the block they are running consensus on
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func (node *Node) VerifyNewBlock(newBlock *blockchain.Block) bool {
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if newBlock.AccountBlock != nil {
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accountBlock := new(types.Block)
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err := rlp.DecodeBytes(newBlock.AccountBlock, accountBlock)
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if err != nil {
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node.log.Error("Failed decoding the block with RLP")
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}
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return node.VerifyNewBlockAccount(accountBlock)
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}
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if newBlock.IsStateBlock() {
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return node.UtxoPool.VerifyStateBlock(newBlock)
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}
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return node.UtxoPool.VerifyTransactions(newBlock.Transactions)
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}
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// VerifyNewBlockAccount is called by consensus participants to verify the block (account model) they are running consensus on
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func (node *Node) VerifyNewBlockAccount(newBlock *types.Block) bool {
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err := node.Chain.ValidateNewBlock(newBlock, pki.GetAddressFromPublicKey(node.SelfPeer.PubKey))
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if err != nil {
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node.log.Debug("Failed verifying new block", "Error", err, "tx", newBlock.Transactions()[0])
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return false
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}
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return true
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}
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// PostConsensusProcessing is called by consensus participants, after consensus is done, to:
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// 1. add the new block to blockchain
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// 2. [leader] move cross shard tx and proof to the list where they wait to be sent to the client
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func (node *Node) PostConsensusProcessing(newBlock *blockchain.Block) {
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if newBlock.IsStateBlock() {
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// Clear out old tx blocks and put state block as genesis
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if node.db != nil {
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node.log.Info("Deleting old blocks.")
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for i := 1; i <= len(node.blockchain.Blocks); i++ {
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blockchain.Delete(node.db, strconv.Itoa(i))
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}
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}
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node.blockchain.Blocks = []*blockchain.Block{}
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}
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if node.Consensus.IsLeader {
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// Move crossTx-in-consensus into the list to be returned to client
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for _, crossTxAndProof := range node.CrossTxsInConsensus {
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crossTxAndProof.Proof.BlockHash = newBlock.Hash
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// TODO: fill in the signature proofs
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}
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if len(node.CrossTxsInConsensus) != 0 {
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node.addCrossTxsToReturn(node.CrossTxsInConsensus)
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node.CrossTxsInConsensus = []*blockchain.CrossShardTxAndProof{}
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}
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node.SendBackProofOfAcceptOrReject()
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node.BroadcastNewBlock(newBlock)
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}
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accountBlock := new(types.Block)
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err := rlp.DecodeBytes(newBlock.AccountBlock, accountBlock)
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if err != nil {
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node.log.Error("Failed decoding the block with RLP")
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}
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node.AddNewBlock(newBlock)
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node.UpdateUtxoAndState(newBlock)
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}
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// AddNewBlockAccount is usedd to add new block into the blockchain.
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func (node *Node) AddNewBlockAccount(newBlock *types.Block) {
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num, err := node.Chain.InsertChain([]*types.Block{newBlock})
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if err != nil {
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node.log.Debug("Error adding to chain", "numBlocks", num, "Error", err)
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if node.Consensus != nil {
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fmt.Println("SHARD ID", node.Consensus.ShardID)
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}
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}
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}
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// AddNewBlock is usedd to add new block into the utxo-based blockchain.
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func (node *Node) AddNewBlock(newBlock *blockchain.Block) {
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// Add it to blockchain
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node.blockchain.Blocks = append(node.blockchain.Blocks, newBlock)
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// Store it into leveldb.
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if node.db != nil {
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node.log.Info("Writing new block into disk.")
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newBlock.Write(node.db, strconv.Itoa(len(node.blockchain.Blocks)))
|
|
}
|
|
|
|
// Account model
|
|
accountBlock := new(types.Block)
|
|
err := rlp.DecodeBytes(newBlock.AccountBlock, accountBlock)
|
|
if err != nil {
|
|
node.log.Error("Failed decoding the block with RLP")
|
|
}
|
|
node.AddNewBlockAccount(accountBlock)
|
|
}
|
|
|
|
// 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)
|
|
}
|
|
}
|
|
|
|
func (node *Node) pingMessageHandler(msgPayload []byte) int {
|
|
ping, err := proto_node.GetPingMessage(msgPayload)
|
|
if err != nil {
|
|
node.log.Error("Can't get Ping Message")
|
|
return -1
|
|
}
|
|
// node.log.Info("Ping", "Msg", ping)
|
|
|
|
peer := new(p2p.Peer)
|
|
peer.IP = ping.Node.IP
|
|
peer.Port = ping.Node.Port
|
|
peer.ValidatorID = ping.Node.ValidatorID
|
|
|
|
peer.PubKey = hmy_crypto.Ed25519Curve.Point()
|
|
err = peer.PubKey.UnmarshalBinary(ping.Node.PubKey[:])
|
|
if err != nil {
|
|
node.log.Error("UnmarshalBinary Failed", "error", err)
|
|
return -1
|
|
}
|
|
|
|
// Add to Node's peer list
|
|
node.AddPeers([]p2p.Peer{*peer})
|
|
|
|
// Send a Pong message back
|
|
peers := node.Consensus.GetValidatorPeers()
|
|
pong := proto_node.NewPongMessage(peers, node.Consensus.PublicKeys)
|
|
buffer := pong.ConstructPongMessage()
|
|
|
|
for _, p := range peers {
|
|
p2p.SendMessage(p, buffer)
|
|
}
|
|
|
|
return len(peers)
|
|
}
|
|
|
|
func (node *Node) pongMessageHandler(msgPayload []byte) int {
|
|
pong, err := proto_node.GetPongMessage(msgPayload)
|
|
if err != nil {
|
|
node.log.Error("Can't get Pong Message")
|
|
return -1
|
|
}
|
|
// node.log.Info("Pong", "Msg", pong)
|
|
// TODO (lc) state syncing, and wait for all public keys
|
|
node.State = NodeJoinedShard
|
|
|
|
peers := make([]p2p.Peer, 0)
|
|
|
|
for _, p := range pong.Peers {
|
|
peer := new(p2p.Peer)
|
|
peer.IP = p.IP
|
|
peer.Port = p.Port
|
|
peer.ValidatorID = p.ValidatorID
|
|
|
|
peer.PubKey = hmy_crypto.Ed25519Curve.Point()
|
|
err = peer.PubKey.UnmarshalBinary(p.PubKey[:])
|
|
if err != nil {
|
|
node.log.Error("UnmarshalBinary Failed", "error", err)
|
|
continue
|
|
}
|
|
peers = append(peers, *peer)
|
|
}
|
|
|
|
if len(peers) > 0 {
|
|
node.AddPeers(peers)
|
|
}
|
|
|
|
// Reset Validator PublicKeys every time we receive PONG message from Leader
|
|
// The PublicKeys has to be idential across the shard on every node
|
|
// TODO (lc): we need to handle RemovePeer situation
|
|
publicKeys := make([]kyber.Point, 0)
|
|
|
|
// Create the the PubKey from the []byte sent from leader
|
|
for _, k := range pong.PubKeys {
|
|
key := hmy_crypto.Ed25519Curve.Point()
|
|
err = key.UnmarshalBinary(k[:])
|
|
if err != nil {
|
|
node.log.Error("UnmarshalBinary Failed PubKeys", "error", err)
|
|
continue
|
|
}
|
|
publicKeys = append(publicKeys, key)
|
|
}
|
|
|
|
return node.Consensus.UpdatePublicKeys(publicKeys)
|
|
}
|
|
|