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

298 lines
10 KiB

package core
import (
"encoding/binary"
"encoding/hex"
"errors"
"math/big"
"math/rand"
"sort"
"github.com/ethereum/go-ethereum/common"
"github.com/harmony-one/bls/ffi/go/bls"
"github.com/harmony-one/harmony/contracts/structs"
"github.com/harmony-one/harmony/core/types"
common2 "github.com/harmony-one/harmony/internal/common"
shardingconfig "github.com/harmony-one/harmony/internal/configs/sharding"
"github.com/harmony-one/harmony/internal/ctxerror"
"github.com/harmony-one/harmony/internal/utils"
)
const (
// GenesisEpoch is the number of the genesis epoch.
GenesisEpoch = 0
// CuckooRate is the percentage of nodes getting reshuffled in the second step of cuckoo resharding.
CuckooRate = 0.1
)
// ShardingState is data structure hold the sharding state
type ShardingState struct {
epoch uint64 // current epoch
rnd uint64 // random seed for resharding
numShards int // TODO ek – equal to len(shardState); remove this
shardState types.ShardState
}
// sortedCommitteeBySize will sort shards by size
// Suppose there are N shards, the first N/2 larger shards are called active committees
// the rest N/2 smaller committees are called inactive committees
// actually they are all just normal shards
// TODO: sort the committee weighted by total staking instead of shard size
func (ss *ShardingState) sortCommitteeBySize() {
sort.Slice(ss.shardState, func(i, j int) bool {
return len(ss.shardState[i].NodeList) > len(ss.shardState[j].NodeList)
})
}
// assignNewNodes add new nodes into the N/2 active committees evenly
func (ss *ShardingState) assignNewNodes(newNodeList []types.NodeID) {
ss.sortCommitteeBySize()
numActiveShards := ss.numShards / 2
Shuffle(newNodeList)
for i, nid := range newNodeList {
id := 0
if numActiveShards > 0 {
id = i % numActiveShards
}
if id < len(ss.shardState) {
ss.shardState[id].NodeList = append(ss.shardState[id].NodeList, nid)
} else {
utils.Logger().Error().Int("id", id).Int("shardState Count", len(ss.shardState)).Msg("assignNewNodes index out of range")
}
}
}
// cuckooResharding uses cuckoo rule to reshard X% of active committee(shards) into inactive committee(shards)
func (ss *ShardingState) cuckooResharding(percent float64) {
numActiveShards := ss.numShards / 2
kickedNodes := []types.NodeID{}
for i := range ss.shardState {
if i >= numActiveShards {
break
}
numKicked := int(percent * float64(len(ss.shardState[i].NodeList)))
if numKicked == 0 {
numKicked++ // At least kick one node out
}
length := len(ss.shardState[i].NodeList)
if length-numKicked <= 0 {
continue // Never empty a shard
}
tmp := ss.shardState[i].NodeList[length-numKicked:]
kickedNodes = append(kickedNodes, tmp...)
ss.shardState[i].NodeList = ss.shardState[i].NodeList[:length-numKicked]
}
Shuffle(kickedNodes)
numInactiveShards := ss.numShards - numActiveShards
for i, nid := range kickedNodes {
id := numActiveShards
if numInactiveShards > 0 {
id += i % numInactiveShards
}
ss.shardState[id].NodeList = append(ss.shardState[id].NodeList, nid)
}
}
// Reshard will first add new nodes into shards, then use cuckoo rule to reshard to get new shard state
func (ss *ShardingState) Reshard(newNodeList []types.NodeID, percent float64) {
rand.Seed(int64(ss.rnd))
ss.sortCommitteeBySize()
// Take out and preserve leaders
leaders := []types.NodeID{}
for i := 0; i < ss.numShards; i++ {
if len(ss.shardState[i].NodeList) > 0 {
leaders = append(leaders, ss.shardState[i].NodeList[0])
ss.shardState[i].NodeList = ss.shardState[i].NodeList[1:]
// Also shuffle the rest of the nodes
Shuffle(ss.shardState[i].NodeList)
}
}
ss.assignNewNodes(newNodeList)
ss.cuckooResharding(percent)
// Put leader back
if len(leaders) < ss.numShards {
utils.Logger().Error().Msg("Not enough leaders to assign to shards")
}
for i := 0; i < ss.numShards; i++ {
ss.shardState[i].NodeList = append([]types.NodeID{leaders[i]}, ss.shardState[i].NodeList...)
}
}
// Shuffle will shuffle the list with result uniquely determined by seed, assuming there is no repeat items in the list
func Shuffle(list []types.NodeID) {
// Sort to make sure everyone will generate the same with the same rand seed.
sort.Slice(list, func(i, j int) bool {
return types.CompareNodeIDByBLSKey(list[i], list[j]) == -1
})
rand.Shuffle(len(list), func(i, j int) {
list[i], list[j] = list[j], list[i]
})
}
// GetBlockNumberFromEpoch calculates the block number where epoch sharding information is stored
func GetBlockNumberFromEpoch(epoch uint64) uint64 {
number := epoch * ShardingSchedule.BlocksPerEpoch() // currently we use the first block in each epoch
return number
}
// GetLastBlockNumberFromEpoch calculates the last block number for the given
// epoch. TODO ek – this is a temp hack.
func GetLastBlockNumberFromEpoch(epoch uint64) uint64 {
return (epoch+1)*ShardingSchedule.BlocksPerEpoch() - 1
}
// GetEpochFromBlockNumber calculates the epoch number the block belongs to
func GetEpochFromBlockNumber(blockNumber uint64) uint64 {
return blockNumber / ShardingSchedule.BlocksPerEpoch()
}
// GetShardingStateFromBlockChain will retrieve random seed and shard map from beacon chain for given a epoch
func GetShardingStateFromBlockChain(bc *BlockChain, epoch *big.Int) (*ShardingState, error) {
if bc == nil {
return nil, errors.New("no blockchain is supplied to get shard state")
}
shardState, err := bc.ReadShardState(epoch)
if err != nil {
return nil, err
}
shardState = shardState.DeepCopy()
blockNumber := GetBlockNumberFromEpoch(epoch.Uint64())
rndSeedBytes := bc.GetVdfByNumber(blockNumber)
rndSeed := binary.BigEndian.Uint64(rndSeedBytes[:])
return &ShardingState{epoch: epoch.Uint64(), rnd: rndSeed, shardState: shardState, numShards: len(shardState)}, nil
}
// CalculateNewShardState get sharding state from previous epoch and calculate sharding state for new epoch
func CalculateNewShardState(
bc *BlockChain, epoch *big.Int,
stakeInfo *map[common.Address]*structs.StakeInfo,
) (types.ShardState, error) {
if epoch.Cmp(big.NewInt(GenesisEpoch)) == 0 {
return GetInitShardState(), nil
}
prevEpoch := new(big.Int).Sub(epoch, common.Big1)
ss, err := GetShardingStateFromBlockChain(bc, prevEpoch)
if err != nil {
return nil, ctxerror.New("cannot retrieve previous sharding state").
WithCause(err)
}
newNodeList := ss.UpdateShardingState(stakeInfo)
utils.Logger().Info().Float64("percentage", CuckooRate).Msg("Cuckoo Rate")
ss.Reshard(newNodeList, CuckooRate)
return ss.shardState, nil
}
// UpdateShardingState remove the unstaked nodes and returns the newly staked node Ids.
func (ss *ShardingState) UpdateShardingState(stakeInfo *map[common.Address]*structs.StakeInfo) []types.NodeID {
oldBlsPublicKeys := make(map[types.BlsPublicKey]bool) // map of bls public keys
for _, shard := range ss.shardState {
newNodeList := shard.NodeList
for _, nodeID := range shard.NodeList {
oldBlsPublicKeys[nodeID.BlsPublicKey] = true
_, ok := (*stakeInfo)[nodeID.EcdsaAddress]
if ok {
// newNodeList = append(newNodeList, nodeID)
} else {
// TODO: Remove the node if it's no longer staked
}
}
shard.NodeList = newNodeList
}
newAddresses := []types.NodeID{}
for addr, info := range *stakeInfo {
_, ok := oldBlsPublicKeys[info.BlsPublicKey]
if !ok {
newAddresses = append(newAddresses, types.NodeID{addr, info.BlsPublicKey})
}
}
return newAddresses
}
// TODO ek – shardingSchedule should really be part of a general-purpose network
// configuration. We are OK for the time being,
// until the day we should let one node process join multiple networks.
// ShardingSchedule is the sharding configuration schedule.
// Depends on the type of the network. Defaults to the mainnet schedule.
var ShardingSchedule shardingconfig.Schedule = shardingconfig.MainnetSchedule
// GetInitShardState returns the initial shard state at genesis.
func GetInitShardState() types.ShardState {
return GetShardState(big.NewInt(GenesisEpoch))
}
// GetShardState returns the shard state based on epoch number
func GetShardState(epoch *big.Int) types.ShardState {
utils.Logger().Info().Int64("epoch", epoch.Int64()).Msg("Get Shard State of Epoch.")
shardingConfig := ShardingSchedule.InstanceForEpoch(epoch)
shardNum := int(shardingConfig.NumShards())
shardHarmonyNodes := shardingConfig.NumHarmonyOperatedNodesPerShard()
shardSize := shardingConfig.NumNodesPerShard()
hmyAccounts := shardingConfig.HmyAccounts()
fnAccounts := shardingConfig.FnAccounts()
shardState := types.ShardState{}
for i := 0; i < shardNum; i++ {
com := types.Committee{ShardID: uint32(i)}
for j := 0; j < shardHarmonyNodes; j++ {
index := i + j*shardNum // The initial account to use for genesis nodes
6 years ago
pub := &bls.PublicKey{}
pub.DeserializeHexStr(hmyAccounts[index].BlsPublicKey)
pubKey := types.BlsPublicKey{}
6 years ago
pubKey.FromLibBLSPublicKey(pub)
// TODO: directly read address for bls too
curNodeID := types.NodeID{common2.ParseAddr(hmyAccounts[index].Address), pubKey}
com.NodeList = append(com.NodeList, curNodeID)
}
// add FN runner's key
for j := shardHarmonyNodes; j < shardSize; j++ {
index := i + (j-shardHarmonyNodes)*shardNum
pub := &bls.PublicKey{}
pub.DeserializeHexStr(fnAccounts[index].BlsPublicKey)
pubKey := types.BlsPublicKey{}
pubKey.FromLibBLSPublicKey(pub)
// TODO: directly read address for bls too
curNodeID := types.NodeID{common2.ParseAddr(fnAccounts[index].Address), pubKey}
com.NodeList = append(com.NodeList, curNodeID)
}
shardState = append(shardState, com)
}
return shardState
}
// GetPublicKeys returns the publickeys given epoch and shardID
func GetPublicKeys(epoch *big.Int, shardID uint32) []*bls.PublicKey {
shardState := GetShardState(epoch)
// Update validator public keys
committee := shardState.FindCommitteeByID(shardID)
if committee == nil {
utils.Logger().Warn().Uint32("shardID", shardID).Uint64("epoch", epoch.Uint64()).Msg("Cannot find committee")
return nil
}
pubKeys := []*bls.PublicKey{}
for _, node := range committee.NodeList {
pubKey := &bls.PublicKey{}
pubKeyBytes := node.BlsPublicKey[:]
err := pubKey.Deserialize(pubKeyBytes)
if err != nil {
utils.Logger().Warn().Str("pubKeyBytes", hex.EncodeToString(pubKeyBytes)).Msg("Cannot Deserialize pubKey")
return nil
}
pubKeys = append(pubKeys, pubKey)
}
return pubKeys
}