The core protocol of WoopChain
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woop/shard/committee/assignment.go

400 lines
12 KiB

package committee
import (
"encoding/json"
"math/big"
"github.com/ethereum/go-ethereum/common"
"github.com/harmony-one/bls/ffi/go/bls"
"github.com/harmony-one/harmony/block"
"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/params"
"github.com/harmony-one/harmony/internal/utils"
"github.com/harmony-one/harmony/numeric"
"github.com/harmony-one/harmony/shard"
"github.com/harmony-one/harmony/staking/availability"
"github.com/harmony-one/harmony/staking/effective"
staking "github.com/harmony-one/harmony/staking/types"
"github.com/pkg/errors"
)
// ValidatorListProvider ..
type ValidatorListProvider interface {
Compute(
epoch *big.Int, reader DataProvider,
) (*shard.State, error)
ReadFromDB(epoch *big.Int, reader DataProvider) (*shard.State, error)
}
// Reader is committee.Reader and it is the API that committee membership assignment needs
type Reader interface {
ValidatorListProvider
}
// StakingCandidatesReader ..
type StakingCandidatesReader interface {
CurrentBlock() *types.Block
ReadValidatorInformation(addr common.Address) (*staking.ValidatorWrapper, error)
ReadValidatorSnapshot(addr common.Address) (*staking.ValidatorSnapshot, error)
ValidatorCandidates() []common.Address
}
// CandidatesForEPoS ..
type CandidatesForEPoS struct {
Orders map[common.Address]effective.SlotOrder
OpenSlotCountForExternalValidators int
}
// CompletedEPoSRound ..
type CompletedEPoSRound struct {
MedianStake numeric.Dec `json:"epos-median-stake"`
MaximumExternalSlot int `json:"max-external-slots"`
AuctionWinners []effective.SlotPurchase `json:"epos-slot-winners"`
AuctionCandidates []*CandidateOrder `json:"epos-slot-candidates"`
}
// CandidateOrder ..
type CandidateOrder struct {
*effective.SlotOrder
StakePerKey *big.Int
Validator common.Address
}
// MarshalJSON ..
func (p CandidateOrder) MarshalJSON() ([]byte, error) {
return json.Marshal(struct {
*effective.SlotOrder
StakePerKey *big.Int `json:"stake-per-key"`
Validator string `json:"validator"`
}{
p.SlotOrder,
p.StakePerKey,
common2.MustAddressToBech32(p.Validator),
})
}
// NewEPoSRound runs a fresh computation of EPoS using
// latest data always
func NewEPoSRound(epoch *big.Int, stakedReader StakingCandidatesReader) (
*CompletedEPoSRound, error,
) {
eligibleCandidate, err := prepareOrders(stakedReader)
if err != nil {
return nil, err
}
maxExternalSlots := shard.ExternalSlotsAvailableForEpoch(
epoch,
)
median, winners := effective.Apply(
eligibleCandidate, maxExternalSlots,
)
auctionCandidates := make([]*CandidateOrder, len(eligibleCandidate))
i := 0
for key := range eligibleCandidate {
// NOTE in principle, a div-by-zero should not
// happen by this point but the risk of not being explicit about
// checking is a panic, so the check is worth it
perKey := big.NewInt(0)
if l := len(eligibleCandidate[key].SpreadAmong); l > 0 {
perKey.Set(
new(big.Int).Div(
eligibleCandidate[key].Stake, big.NewInt(int64(l)),
),
)
}
auctionCandidates[i] = &CandidateOrder{
SlotOrder: eligibleCandidate[key],
StakePerKey: perKey,
Validator: key,
}
i++
}
return &CompletedEPoSRound{
MedianStake: median,
MaximumExternalSlot: maxExternalSlots,
AuctionWinners: winners,
AuctionCandidates: auctionCandidates,
}, nil
}
func prepareOrders(
stakedReader StakingCandidatesReader,
) (map[common.Address]*effective.SlotOrder, error) {
candidates := stakedReader.ValidatorCandidates()
blsKeys := map[shard.BLSPublicKey]struct{}{}
essentials := map[common.Address]*effective.SlotOrder{}
totalStaked, tempZero := big.NewInt(0), numeric.ZeroDec()
// Avoid duplicate BLS keys as harmony nodes
instance := shard.Schedule.InstanceForEpoch(stakedReader.CurrentBlock().Epoch())
for _, account := range instance.HmyAccounts() {
pub := &bls.PublicKey{}
if err := pub.DeserializeHexStr(account.BLSPublicKey); err != nil {
continue
}
pubKey := shard.BLSPublicKey{}
if err := pubKey.FromLibBLSPublicKey(pub); err != nil {
continue
}
blsKeys[pubKey] = struct{}{}
}
for i := range candidates {
validator, err := stakedReader.ReadValidatorInformation(
candidates[i],
)
if err != nil {
return nil, err
}
snapshot, err := stakedReader.ReadValidatorSnapshot(
candidates[i],
)
if err != nil {
return nil, err
}
if !IsEligibleForEPoSAuction(snapshot, validator) {
continue
}
found := false
for _, key := range validator.SlotPubKeys {
if _, ok := blsKeys[key]; ok {
found = true
} else {
blsKeys[key] = struct{}{}
}
}
if found {
continue
}
validatorStake := big.NewInt(0)
for i := range validator.Delegations {
validatorStake.Add(
validatorStake, validator.Delegations[i].Amount,
)
}
totalStaked.Add(totalStaked, validatorStake)
essentials[validator.Address] = &effective.SlotOrder{
validatorStake,
validator.SlotPubKeys,
tempZero,
}
}
totalStakedDec := numeric.NewDecFromBigInt(totalStaked)
for _, value := range essentials {
value.Percentage = numeric.NewDecFromBigInt(value.Stake).Quo(totalStakedDec)
}
return essentials, nil
}
// IsEligibleForEPoSAuction ..
func IsEligibleForEPoSAuction(snapshot *staking.ValidatorSnapshot, validator *staking.ValidatorWrapper) bool {
// This original condition to check whether a validator is in last committee is not stable
// because cross-links may arrive after the epoch ends and it still got counted into the
// NumBlocksToSign, making this condition to be true when the validator is actually not in committee
//if snapshot.Counters.NumBlocksToSign.Cmp(validator.Counters.NumBlocksToSign) != 0 {
// Check whether the validator is in current committee
if validator.LastEpochInCommittee.Cmp(snapshot.Epoch) == 0 {
// validator was in last epoch's committee
// validator with below-threshold signing activity won't be considered for next epoch
// and their status will be turned to inactive in FinalizeNewBlock
computed := availability.ComputeCurrentSigning(snapshot.Validator, validator)
if computed.IsBelowThreshold {
return false
}
}
// For validators who were not in last epoch's committee
// or for those who were and signed enough blocks,
// the decision is based on the status
switch validator.Status {
case effective.Active:
return true
default:
return false
}
}
// ChainReader is a subset of Engine.ChainReader, just enough to do assignment
type ChainReader interface {
// ReadShardState retrieves sharding state given the epoch number.
// This api reads the shard state cached or saved on the chaindb.
// Thus, only should be used to read the shard state of the current chain.
ReadShardState(epoch *big.Int) (*shard.State, error)
// GetHeader retrieves a block header from the database by hash and number.
GetHeaderByHash(common.Hash) *block.Header
// Config retrieves the blockchain's chain configuration.
Config() *params.ChainConfig
// CurrentHeader retrieves the current header from the local chain.
CurrentHeader() *block.Header
}
// DataProvider ..
type DataProvider interface {
StakingCandidatesReader
ChainReader
}
type partialStakingEnabled struct{}
var (
// WithStakingEnabled ..
WithStakingEnabled Reader = partialStakingEnabled{}
// ErrComputeForEpochInPast ..
ErrComputeForEpochInPast = errors.New("cannot compute for epoch in past")
)
// This is the shard state computation logic before staking epoch.
func preStakingEnabledCommittee(s shardingconfig.Instance) *shard.State {
shardNum := int(s.NumShards())
shardHarmonyNodes := s.NumHarmonyOperatedNodesPerShard()
shardSize := s.NumNodesPerShard()
hmyAccounts := s.HmyAccounts()
fnAccounts := s.FnAccounts()
shardState := &shard.State{}
// Shard state needs to be sorted by shard ID
for i := 0; i < shardNum; i++ {
com := shard.Committee{ShardID: uint32(i)}
for j := 0; j < shardHarmonyNodes; j++ {
index := i + j*shardNum // The initial account to use for genesis nodes
pub := &bls.PublicKey{}
pub.DeserializeHexStr(hmyAccounts[index].BLSPublicKey)
pubKey := shard.BLSPublicKey{}
pubKey.FromLibBLSPublicKey(pub)
// TODO: directly read address for bls too
curNodeID := shard.Slot{
common2.ParseAddr(hmyAccounts[index].Address),
pubKey,
nil,
}
com.Slots = append(com.Slots, 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 := shard.BLSPublicKey{}
pubKey.FromLibBLSPublicKey(pub)
// TODO: directly read address for bls too
curNodeID := shard.Slot{
common2.ParseAddr(fnAccounts[index].Address),
pubKey,
nil,
}
com.Slots = append(com.Slots, curNodeID)
}
shardState.Shards = append(shardState.Shards, com)
}
return shardState
}
func eposStakedCommittee(
epoch *big.Int, s shardingconfig.Instance, stakerReader DataProvider,
) (*shard.State, error) {
shardCount := int(s.NumShards())
shardState := &shard.State{}
shardState.Shards = make([]shard.Committee, shardCount)
hAccounts := s.HmyAccounts()
shardHarmonyNodes := s.NumHarmonyOperatedNodesPerShard()
for i := 0; i < shardCount; i++ {
shardState.Shards[i] = shard.Committee{uint32(i), shard.SlotList{}}
for j := 0; j < shardHarmonyNodes; j++ {
index := i + j*shardCount
pub := &bls.PublicKey{}
if err := pub.DeserializeHexStr(hAccounts[index].BLSPublicKey); err != nil {
return nil, err
}
pubKey := shard.BLSPublicKey{}
if err := pubKey.FromLibBLSPublicKey(pub); err != nil {
return nil, err
}
shardState.Shards[i].Slots = append(shardState.Shards[i].Slots, shard.Slot{
common2.ParseAddr(hAccounts[index].Address),
pubKey,
nil,
})
}
}
// TODO(audit): make sure external validator BLS key are also not duplicate to Harmony's keys
completedEPoSRound, err := NewEPoSRound(epoch, stakerReader)
if err != nil {
return nil, err
}
shardBig := big.NewInt(int64(shardCount))
for i := range completedEPoSRound.AuctionWinners {
purchasedSlot := completedEPoSRound.AuctionWinners[i]
shardID := int(new(big.Int).Mod(purchasedSlot.Key.Big(), shardBig).Int64())
shardState.Shards[shardID].Slots = append(
shardState.Shards[shardID].Slots, shard.Slot{
purchasedSlot.Addr,
purchasedSlot.Key,
&purchasedSlot.EPoSStake,
},
)
}
return shardState, nil
}
// ReadFromDB is a wrapper on ReadShardState
func (def partialStakingEnabled) ReadFromDB(
epoch *big.Int, reader DataProvider,
) (newSuperComm *shard.State, err error) {
return reader.ReadShardState(epoch)
}
// Compute is single entry point for
// computing a new super committee, aka new shard state
func (def partialStakingEnabled) Compute(
epoch *big.Int, stakerReader DataProvider,
) (newSuperComm *shard.State, err error) {
preStaking := true
if stakerReader != nil {
config := stakerReader.Config()
if config.IsStaking(epoch) {
preStaking = false
}
}
instance := shard.Schedule.InstanceForEpoch(epoch)
if preStaking {
// Pre-staking shard state doesn't need to set epoch (backward compatible)
return preStakingEnabledCommittee(instance), nil
}
// Sanity check, can't compute against epochs in past
if e := stakerReader.CurrentHeader().Epoch(); epoch.Cmp(e) == -1 {
utils.Logger().Error().Uint64("header-epoch", e.Uint64()).
Uint64("compute-epoch", epoch.Uint64()).
Msg("Tried to compute committee for epoch in past")
return nil, ErrComputeForEpochInPast
}
utils.AnalysisStart("computeEPoSStakedCommittee")
shardState, err := eposStakedCommittee(epoch, instance, stakerReader)
utils.AnalysisEnd("computeEPoSStakedCommittee")
if err != nil {
return nil, err
}
// Set the epoch of shard state
shardState.Epoch = big.NewInt(0).Set(epoch)
utils.Logger().Info().
Uint64("computed-for-epoch", epoch.Uint64()).
Msg("computed new super committee")
return shardState, nil
}