package core import ( "math" "math/rand" "sort" "strconv" "github.com/harmony-one/harmony/core/types" ) const ( // InitialSeed is the initial random seed, a magic number to answer everything, remove later InitialSeed uint32 = 42 ) // ShardingState is data structure hold the sharding state type ShardingState struct { epoch uint64 // current epoch rnd uint32 // random seed for resharding numShards int 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 := i % numActiveShards ss.shardState[id].NodeList = append(ss.shardState[id].NodeList, nid) } } // cuckooResharding uses cuckoo rule to reshard X% of active committee(shards) into inactive committee(shards) func (ss *ShardingState) cuckooResharding(percent float64) { ss.sortCommitteeBySize() numActiveShards := ss.numShards / 2 kickedNodes := []types.NodeID{} for i := range ss.shardState { if i >= numActiveShards { break } Shuffle(ss.shardState[i].NodeList) numKicked := int(percent * float64(len(ss.shardState[i].NodeList))) tmp := ss.shardState[i].NodeList[:numKicked] kickedNodes = append(kickedNodes, tmp...) ss.shardState[i].NodeList = ss.shardState[i].NodeList[numKicked:] } Shuffle(kickedNodes) for i, nid := range kickedNodes { id := numActiveShards + i%(ss.numShards-numActiveShards) ss.shardState[id].NodeList = append(ss.shardState[id].NodeList, nid) } } // UpdateShardState will first add new nodes into shards, then use cuckoo rule to reshard to get new shard state func (ss *ShardingState) UpdateShardState(newNodeList []types.NodeID, percent float64) { rand.Seed(int64(ss.rnd)) ss.assignNewNodes(newNodeList) ss.cuckooResharding(percent) } // 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.Slice(list, func(i, j int) bool { return types.CompareNodeID(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 * uint64(BlocksPerEpoch) // currently we use the first block in each epoch return number } // GetEpochFromBlockNumber calculates the epoch number the block belongs to func GetEpochFromBlockNumber(blockNumber uint64) uint64 { return blockNumber / uint64(BlocksPerEpoch) } // GetPreviousEpochBlockNumber gets the epoch block number of previous epoch func GetPreviousEpochBlockNumber(blockNumber uint64) uint64 { epoch := GetEpochFromBlockNumber(blockNumber) if epoch == 1 { // no previous epoch return epoch } return GetBlockNumberFromEpoch(epoch - 1) } // GetShardingStateFromBlockChain will retrieve random seed and shard map from beacon chain for given a epoch func GetShardingStateFromBlockChain(bc *BlockChain, epoch uint64) *ShardingState { number := GetBlockNumberFromEpoch(epoch) shardState := bc.GetShardStateByNumber(number) rnd := bc.GetRandSeedByNumber(number) return &ShardingState{epoch: epoch, rnd: rnd, shardState: shardState, numShards: len(shardState)} } // CalculateNewShardState get sharding state from previous epoch and calcualte sharding state for new epoch // TODO: currently, we just mock everything func CalculateNewShardState(bc *BlockChain, epoch uint64) types.ShardState { if epoch == 1 { return fakeGetInitShardState() } ss := GetShardingStateFromBlockChain(bc, epoch-1) newNodeList := fakeNewNodeList(int64(ss.rnd)) percent := ss.calculateKickoutRate(newNodeList) ss.UpdateShardState(newNodeList, percent) return ss.shardState } // calculateKickoutRate calculates the cuckoo rule kick out rate in order to make committee balanced func (ss *ShardingState) calculateKickoutRate(newNodeList []types.NodeID) float64 { numActiveCommittees := ss.numShards / 2 newNodesPerShard := math.Ceil(float64(len(newNodeList)) / float64(numActiveCommittees)) ss.sortCommitteeBySize() L := len(ss.shardState[0].NodeList) if L == 0 { return 0.0 } rate := newNodesPerShard / float64(L) return math.Min(rate, 1.0) } // FakeGenRandSeed generate random seed based on previous rnd seed; remove later after VRF implemented func FakeGenRandSeed(seed uint32) uint32 { rand.Seed(int64(seed)) return rand.Uint32() } // remove later after bootstrap codes ready func fakeGetInitShardState() types.ShardState { rand.Seed(int64(InitialSeed)) shardState := types.ShardState{} for i := 0; i < 6; i++ { sid := uint32(i) com := types.Committee{ShardID: sid} for j := 0; j < 10; j++ { nid := strconv.Itoa(int(rand.Int63())) com.NodeList = append(com.NodeList, types.NodeID(nid)) } shardState = append(shardState, com) } return shardState } // remove later after new nodes list generation ready func fakeNewNodeList(seed int64) []types.NodeID { rand.Seed(seed) numNewNodes := rand.Intn(10) nodeList := []types.NodeID{} for i := 0; i < numNewNodes; i++ { nid := strconv.Itoa(int(rand.Int63())) nodeList = append(nodeList, types.NodeID(nid)) } return nodeList }