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

394 lines
12 KiB

package consensus
import (
"fmt"
"sync"
"sync/atomic"
"time"
"github.com/woop-chain/abool"
bls_core "github.com/woop-chain/bls/ffi/go/bls"
"github.com/woop-chain/woop/consensus/engine"
"github.com/woop-chain/woop/consensus/quorum"
"github.com/woop-chain/woop/core"
"github.com/woop-chain/woop/core/types"
"github.com/woop-chain/woop/crypto/bls"
bls_cosi "github.com/woop-chain/woop/crypto/bls"
"github.com/woop-chain/woop/internal/registry"
"github.com/woop-chain/woop/internal/utils"
"github.com/woop-chain/woop/multibls"
"github.com/woop-chain/woop/p2p"
"github.com/woop-chain/woop/shard"
"github.com/woop-chain/woop/shard/committee"
"github.com/woop-chain/woop/staking/slash"
"github.com/pkg/errors"
)
const (
vdFAndProofSize = 516 // size of VDF and Proof
vdfAndSeedSize = 548 // size of VDF/Proof and Seed
)
var errLeaderPriKeyNotFound = errors.New("leader private key not found locally")
// ProposalType is to indicate the type of signal for new block proposal
type ProposalType byte
// Constant of the type of new block proposal
const (
SyncProposal ProposalType = iota
AsyncProposal
)
type DownloadAsync interface {
DownloadAsync()
}
// Consensus is the main struct with all states and data related to consensus process.
type Consensus struct {
decider quorum.Decider
// FBFTLog stores the pbft messages and blocks during FBFT process
fBFTLog *FBFTLog
// phase: different phase of FBFT protocol: pre-prepare, prepare, commit, finish etc
phase FBFTPhase
// current indicates what state a node is in
current State
// isBackup declarative the node is in backup mode
isBackup bool
// 2 types of timeouts: normal and viewchange
consensusTimeout map[TimeoutType]*utils.Timeout
// Commits collected from validators.
aggregatedPrepareSig *bls_core.Sign
aggregatedCommitSig *bls_core.Sign
prepareBitmap *bls_cosi.Mask
commitBitmap *bls_cosi.Mask
multiSigBitmap *bls_cosi.Mask // Bitmap for parsing multisig bitmap from validators
// Registry for services.
registry *registry.Registry
// Minimal number of peers in the shard
// If the number of validators is less than minPeers, the consensus won't start
MinPeers int
// private/public keys of current node
priKey multibls.PrivateKeys
// the publickey of leader
LeaderPubKey *bls.PublicKeyWrapper
// blockNum: the next blockNumber that FBFT is going to agree on,
// should be equal to the blockNumber of next block
blockNum uint64
// Blockhash - 32 byte
blockHash [32]byte
// Block to run consensus on
block []byte
// Shard Id which this node belongs to
ShardID uint32
// IgnoreViewIDCheck determines whether to ignore viewID check
IgnoreViewIDCheck *abool.AtomicBool
// consensus mutex
mutex *sync.RWMutex
// ViewChange struct
vc *viewChange
// Signal channel for proposing a new block and start new consensus
readySignal chan ProposalType
// Channel to send full commit signatures to finish new block proposal
commitSigChannel chan []byte
// The post-consensus job func passed from Node object
// Called when consensus on a new block is done
PostConsensusJob func(*types.Block) error
// verified block to state sync broadcast
VerifiedNewBlock chan *types.Block
// Channel for DRG protocol to send pRnd (preimage of randomness resulting from combined vrf
// randomnesses) to consensus. The first 32 bytes are randomness, the rest is for bitmap.
PRndChannel chan []byte
// Channel for DRG protocol to send VDF. The first 516 bytes are the VDF/Proof and the last 32
// bytes are the seed for deriving VDF
RndChannel chan [vdfAndSeedSize]byte
pendingRnds [][vdfAndSeedSize]byte // A list of pending randomness
// The p2p host used to send/receive p2p messages
host p2p.Host
// MessageSender takes are of sending consensus message and the corresponding retry logic.
msgSender *MessageSender
// If true, this consensus will not propose view change.
disableViewChange bool
// Have a dedicated reader thread pull from this chan, like in node
SlashChan chan slash.Record
// How long in second the leader needs to wait to propose a new block.
BlockPeriod time.Duration
// The time due for next block proposal
NextBlockDue time.Time
// Temporary flag to control whether aggregate signature signing is enabled
AggregateSig bool
// TODO (leo): an new metrics system to keep track of the consensus/viewchange
// finality of previous consensus in the unit of milliseconds
finality int64
// finalityCounter keep tracks of the finality time
finalityCounter atomic.Value //int64
dHelper DownloadAsync
// Both flags only for initialization state.
start bool
isInitialLeader bool
}
// Blockchain returns the blockchain.
func (consensus *Consensus) Blockchain() core.BlockChain {
return consensus.registry.GetBlockchain()
}
func (consensus *Consensus) FBFTLog() FBFT {
return threadsafeFBFTLog{
log: consensus.fBFTLog,
mu: consensus.mutex,
}
}
// ChainReader returns the chain reader.
// This is mostly the same as Blockchain, but it returns only read methods, so we assume it's safe for concurrent use.
func (consensus *Consensus) ChainReader() engine.ChainReader {
return consensus.Blockchain()
}
func (consensus *Consensus) ReadySignal(p ProposalType) {
consensus.readySignal <- p
}
func (consensus *Consensus) GetReadySignal() chan ProposalType {
return consensus.readySignal
}
func (consensus *Consensus) GetCommitSigChannel() chan []byte {
return consensus.commitSigChannel
}
// Beaconchain returns the beaconchain.
func (consensus *Consensus) Beaconchain() core.BlockChain {
return consensus.registry.GetBeaconchain()
}
// verifyBlock is a function used to verify the block and keep trace of verified blocks.
func (consensus *Consensus) verifyBlock(block *types.Block) error {
if !consensus.fBFTLog.IsBlockVerified(block.Hash()) {
if err := consensus.BlockVerifier(block); err != nil {
return errors.Errorf("Block verification failed: %s", err)
}
consensus.fBFTLog.MarkBlockVerified(block)
}
return nil
}
// BlocksSynchronized lets the main loop know that block synchronization finished
// thus the blockchain is likely to be up to date.
func (consensus *Consensus) BlocksSynchronized() {
err := consensus.AddConsensusLastMile()
if err != nil {
consensus.GetLogger().Error().Err(err).Msg("add last mile failed")
}
consensus.mutex.Lock()
defer consensus.mutex.Unlock()
consensus.syncReadyChan()
}
// BlocksNotSynchronized lets the main loop know that block is not synchronized
func (consensus *Consensus) BlocksNotSynchronized(reason string) {
consensus.mutex.Lock()
defer consensus.mutex.Unlock()
consensus.syncNotReadyChan(reason)
}
// VdfSeedSize returns the number of VRFs for VDF computation
func (consensus *Consensus) VdfSeedSize() int {
consensus.mutex.RLock()
defer consensus.mutex.RUnlock()
return int(consensus.decider.ParticipantsCount()) * 2 / 3
}
// GetPublicKeys returns the public keys
func (consensus *Consensus) GetPublicKeys() multibls.PublicKeys {
return consensus.getPublicKeys()
}
func (consensus *Consensus) getPublicKeys() multibls.PublicKeys {
return consensus.priKey.GetPublicKeys()
}
func (consensus *Consensus) GetLeaderPubKey() *bls_cosi.PublicKeyWrapper {
consensus.mutex.RLock()
defer consensus.mutex.RUnlock()
return consensus.getLeaderPubKey()
}
func (consensus *Consensus) getLeaderPubKey() *bls_cosi.PublicKeyWrapper {
return consensus.LeaderPubKey
}
func (consensus *Consensus) SetLeaderPubKey(pub *bls_cosi.PublicKeyWrapper) {
consensus.mutex.Lock()
defer consensus.mutex.Unlock()
consensus.setLeaderPubKey(pub)
}
func (consensus *Consensus) setLeaderPubKey(pub *bls_cosi.PublicKeyWrapper) {
consensus.LeaderPubKey = pub
}
func (consensus *Consensus) GetPrivateKeys() multibls.PrivateKeys {
return consensus.priKey
}
// GetLeaderPrivateKey returns leader private key if node is the leader
func (consensus *Consensus) getLeaderPrivateKey(leaderKey *bls_core.PublicKey) (*bls.PrivateKeyWrapper, error) {
for i, key := range consensus.priKey {
if key.Pub.Object.IsEqual(leaderKey) {
return &consensus.priKey[i], nil
}
}
return nil, errors.Wrapf(errLeaderPriKeyNotFound, leaderKey.SerializeToHexStr())
}
// getConsensusLeaderPrivateKey returns consensus leader private key if node is the leader
func (consensus *Consensus) getConsensusLeaderPrivateKey() (*bls.PrivateKeyWrapper, error) {
return consensus.getLeaderPrivateKey(consensus.LeaderPubKey.Object)
}
func (consensus *Consensus) IsBackup() bool {
return consensus.isBackup
}
func (consensus *Consensus) BlockNum() uint64 {
return atomic.LoadUint64(&consensus.blockNum)
}
func (consensus *Consensus) getBlockNum() uint64 {
return atomic.LoadUint64(&consensus.blockNum)
}
// New create a new Consensus record
func New(
host p2p.Host, shard uint32, multiBLSPriKey multibls.PrivateKeys,
registry *registry.Registry,
Decider quorum.Decider, minPeers int, aggregateSig bool,
) (*Consensus, error) {
consensus := Consensus{
mutex: &sync.RWMutex{},
ShardID: shard,
fBFTLog: NewFBFTLog(),
phase: FBFTAnnounce,
current: State{mode: Normal},
decider: Decider,
registry: registry,
MinPeers: minPeers,
AggregateSig: aggregateSig,
host: host,
msgSender: NewMessageSender(host),
// FBFT timeout
consensusTimeout: createTimeout(),
dHelper: downloadAsync{},
}
if multiBLSPriKey != nil {
consensus.priKey = multiBLSPriKey
utils.Logger().Info().
Str("publicKey", consensus.GetPublicKeys().SerializeToHexStr()).Msg("My Public Key")
} else {
utils.Logger().Error().Msg("the bls key is nil")
return nil, fmt.Errorf("nil bls key, aborting")
}
// viewID has to be initialized as the height of
// the blockchain during initialization as it was
// displayed on explorer as Height right now
consensus.setCurBlockViewID(0)
consensus.SlashChan = make(chan slash.Record)
consensus.readySignal = make(chan ProposalType)
consensus.commitSigChannel = make(chan []byte)
// channel for receiving newly generated VDF
consensus.RndChannel = make(chan [vdfAndSeedSize]byte)
consensus.IgnoreViewIDCheck = abool.NewBool(false)
// Make Sure Verifier is not null
consensus.vc = newViewChange()
// init prometheus metrics
initMetrics()
consensus.AddPubkeyMetrics()
return &consensus, nil
}
func (consensus *Consensus) GetHost() p2p.Host {
return consensus.host
}
func (consensus *Consensus) Registry() *registry.Registry {
return consensus.registry
}
func (consensus *Consensus) Decider() quorum.Decider {
return quorum.NewThreadSafeDecider(consensus.decider, consensus.mutex)
}
// InitConsensusWithValidators initialize shard state
// from latest epoch and update committee pub
// keys for consensus
func (consensus *Consensus) InitConsensusWithValidators() (err error) {
shardID := consensus.ShardID
currentBlock := consensus.Blockchain().CurrentBlock()
blockNum := currentBlock.NumberU64()
consensus.SetMode(Listening)
epoch := currentBlock.Epoch()
utils.Logger().Info().
Uint64("blockNum", blockNum).
Uint32("shardID", shardID).
Uint64("epoch", epoch.Uint64()).
Msg("[InitConsensusWithValidators] Try To Get PublicKeys")
shardState, err := committee.WithStakingEnabled.Compute(
epoch, consensus.Blockchain(),
)
if err != nil {
utils.Logger().Err(err).
Uint64("blockNum", blockNum).
Uint32("shardID", shardID).
Uint64("epoch", epoch.Uint64()).
Msg("[InitConsensusWithValidators] Failed getting shard state")
return err
}
subComm, err := shardState.FindCommitteeByID(shardID)
if err != nil {
utils.Logger().Err(err).
Interface("shardState", shardState).
Msg("[InitConsensusWithValidators] Find CommitteeByID")
return err
}
pubKeys, err := subComm.BLSPublicKeys()
if err != nil {
utils.Logger().Error().
Uint32("shardID", shardID).
Uint64("blockNum", blockNum).
Msg("[InitConsensusWithValidators] PublicKeys is Empty, Cannot update public keys")
return errors.Wrapf(
err,
"[InitConsensusWithValidators] PublicKeys is Empty, Cannot update public keys",
)
}
for _, key := range pubKeys {
if consensus.GetPublicKeys().Contains(key.Object) {
utils.Logger().Info().
Uint64("blockNum", blockNum).
Int("numPubKeys", len(pubKeys)).
Str("mode", consensus.Mode().String()).
Msg("[InitConsensusWithValidators] Successfully updated public keys")
consensus.UpdatePublicKeys(pubKeys, shard.Schedule.InstanceForEpoch(epoch).ExternalAllowlist())
consensus.SetMode(Normal)
return nil
}
}
return nil
}
type downloadAsync struct {
}
func (a downloadAsync) DownloadAsync() {
}