woop/internal/chain/engine.go

package chain

import (
	"encoding/binary"

	"github.com/ethereum/go-ethereum/common"
	"github.com/ethereum/go-ethereum/rlp"
	"github.com/harmony-one/bls/ffi/go/bls"
	"github.com/harmony-one/harmony/block"
	"github.com/harmony-one/harmony/consensus/engine"
	"github.com/harmony-one/harmony/consensus/reward"
	"github.com/harmony-one/harmony/core/state"
	"github.com/harmony-one/harmony/core/types"
	common2 "github.com/harmony-one/harmony/internal/common"
	"github.com/harmony-one/harmony/internal/ctxerror"
	"github.com/harmony-one/harmony/internal/utils"
	"github.com/harmony-one/harmony/shard"
	"github.com/harmony-one/harmony/shard/committee"
	"github.com/harmony-one/harmony/staking/slash"
	staking "github.com/harmony-one/harmony/staking/types"
	"github.com/pkg/errors"
	"golang.org/x/crypto/sha3"
)

type engineImpl struct {
	d      reward.Distributor
	s      slash.Slasher
	beacon engine.ChainReader
}

// Engine is an algorithm-agnostic consensus engine.
var Engine = &engineImpl{nil, nil, nil}

// Rewarder handles the distribution of block rewards
func (e *engineImpl) Rewarder() reward.Distributor {
	return e.d
}

// SetRewarder ..
func (e *engineImpl) SetRewarder(d reward.Distributor) {
	e.d = d
}

// Slasher handles slashing accounts due to inavailibility or double-signing
func (e *engineImpl) Slasher() slash.Slasher {
	return e.s
}

// SetSlasher assigns the slasher used
func (e *engineImpl) SetSlasher(s slash.Slasher) {
	e.s = s
}

func (e *engineImpl) Beaconchain() engine.ChainReader {
	return e.beacon
}

// SetSlasher assigns the slasher used
func (e *engineImpl) SetBeaconchain(beaconchain engine.ChainReader) {
	e.beacon = beaconchain
}

// SealHash returns the hash of a block prior to it being sealed.
func (e *engineImpl) SealHash(header *block.Header) (hash common.Hash) {
	hasher := sha3.NewLegacyKeccak256()
	// TODO: update with new fields
	if err := rlp.Encode(hasher, []interface{}{
		header.ParentHash(),
		header.Coinbase(),
		header.Root(),
		header.TxHash(),
		header.ReceiptHash(),
		header.Bloom(),
		header.Number(),
		header.GasLimit(),
		header.GasUsed(),
		header.Time(),
		header.Extra(),
	}); err != nil {
		utils.Logger().Warn().Err(err).Msg("rlp.Encode failed")
	}
	hasher.Sum(hash[:0])
	return hash
}

// Seal is to seal final block.
func (e *engineImpl) Seal(chain engine.ChainReader, block *types.Block, results chan<- *types.Block, stop <-chan struct{}) error {
	// TODO: implement final block sealing
	return nil
}

// Author returns the author of the block header.
func (e *engineImpl) Author(header *block.Header) (common.Address, error) {
	// TODO: implement this
	return common.Address{}, nil
}

// Prepare is to prepare ...
// TODO(RJ): fix it.
func (e *engineImpl) Prepare(chain engine.ChainReader, header *block.Header) error {
	// TODO: implement prepare method
	return nil
}

// VerifyHeader checks whether a header conforms to the consensus rules of the bft engine.
// Note that each block header contains the bls signature of the parent block
func (e *engineImpl) VerifyHeader(chain engine.ChainReader, header *block.Header, seal bool) error {
	parentHeader := chain.GetHeader(header.ParentHash(), header.Number().Uint64()-1)
	if parentHeader == nil {
		return engine.ErrUnknownAncestor
	}
	if seal {
		if err := e.VerifySeal(chain, header); err != nil {
			return err
		}
	}
	return nil
}

// VerifyHeaders is similar to VerifyHeader, but verifies a batch of headers
// concurrently. The method returns a quit channel to abort the operations and
// a results channel to retrieve the async verifications.
func (e *engineImpl) VerifyHeaders(chain engine.ChainReader, headers []*block.Header, seals []bool) (chan<- struct{}, <-chan error) {
	abort, results := make(chan struct{}), make(chan error, len(headers))

	go func() {
		for i, header := range headers {
			err := e.VerifyHeader(chain, header, seals[i])

			select {
			case <-abort:
				return
			case results <- err:
			}
		}
	}()

	return abort, results
}

// ReadPublicKeysFromLastBlock finds the public keys of last block's committee
func ReadPublicKeysFromLastBlock(bc engine.ChainReader, header *block.Header) ([]*bls.PublicKey, error) {
	parentHeader := bc.GetHeaderByHash(header.ParentHash())
	return GetPublicKeys(bc, parentHeader, false)
}

// VerifySeal implements Engine, checking whether the given block's parent block satisfies
// the PoS difficulty requirements, i.e. >= 2f+1 valid signatures from the committee
// Note that each block header contains the bls signature of the parent block
func (e *engineImpl) VerifySeal(chain engine.ChainReader, header *block.Header) error {
	if chain.CurrentHeader().Number().Uint64() <= uint64(1) {
		return nil
	}
	publicKeys, err := ReadPublicKeysFromLastBlock(chain, header)

	if err != nil {
		return ctxerror.New("[VerifySeal] Cannot retrieve publickeys from last block").WithCause(err)
	}
	sig := header.LastCommitSignature()
	payload := append(sig[:], header.LastCommitBitmap()...)
	aggSig, mask, err := ReadSignatureBitmapByPublicKeys(payload, publicKeys)
	if err != nil {
		return ctxerror.New("[VerifySeal] Unable to deserialize the LastCommitSignature and LastCommitBitmap in Block Header").WithCause(err)
	}
	parentHash := header.ParentHash()
	parentHeader := chain.GetHeader(parentHash, header.Number().Uint64()-1)
	parentQuorum, err := QuorumForBlock(chain, parentHeader, false)
	if err != nil {
		return errors.Wrapf(err,
			"cannot calculate quorum for block %s", header.Number())
	}
	if count := utils.CountOneBits(mask.Bitmap); count < int64(parentQuorum) {
		return ctxerror.New("[VerifySeal] Not enough signature in LastCommitSignature from Block Header",
			"need", parentQuorum, "got", count)
	}

	blockNumHash := make([]byte, 8)
	binary.LittleEndian.PutUint64(blockNumHash, header.Number().Uint64()-1)
	lastCommitPayload := append(blockNumHash, parentHash[:]...)

	if !aggSig.VerifyHash(mask.AggregatePublic, lastCommitPayload) {
		return ctxerror.New("[VerifySeal] Unable to verify aggregated signature from last block", "lastBlockNum", header.Number().Uint64()-1, "lastBlockHash", parentHash)
	}
	return nil
}

// Finalize implements Engine, accumulating the block rewards,
// setting the final state and assembling the block.
func (e *engineImpl) Finalize(
	chain engine.ChainReader, header *block.Header,
	state *state.DB, txs []*types.Transaction,
	receipts []*types.Receipt, outcxs []*types.CXReceipt,
	incxs []*types.CXReceiptsProof, stks []*staking.StakingTransaction,
) (*types.Block, error) {

	// Accumulate any block and uncle rewards and commit the final state root
	// Header seems complete, assemble into a block and return
	if err := AccumulateRewards(
		chain, state, header, e.Rewarder(), e.Slasher(), e.Beaconchain(),
	); err != nil {
		return nil, ctxerror.New("cannot pay block reward").WithCause(err)
	}

	// TODO Shouldnt this logic only apply to beaconchain, right?
	// Withdraw unlocked tokens to the delegators' accounts
	// Only do such at the last block of an epoch
	if header.ShardID() == shard.BeaconChainShardID && len(header.ShardState()) > 0 {
		// TODO: make sure we are using the correct validator list
		validators, err := chain.ReadActiveValidatorList()
		if err != nil {
			return nil, ctxerror.New("failed to read active validators").WithCause(err)
		}
		for _, validator := range validators {
			wrapper := state.GetStakingInfo(validator)
			if wrapper != nil {
				for i := range wrapper.Delegations {
					delegation := wrapper.Delegations[i]
					totalWithdraw := delegation.RemoveUnlockedUndelegations(header.Epoch())
					state.AddBalance(delegation.DelegatorAddress, totalWithdraw)
				}
				if err := state.UpdateStakingInfo(validator, wrapper); err != nil {
					return nil, ctxerror.New("failed update validator info").WithCause(err)
				}
			} else {
				err = errors.New("validator came back empty " + common2.MustAddressToBech32(validator))
				return nil, ctxerror.New("failed getting validator info").WithCause(err)
			}
		}
	}
	header.SetRoot(state.IntermediateRoot(chain.Config().IsS3(header.Epoch())))
	return types.NewBlock(header, txs, receipts, outcxs, incxs, stks), nil
}

// QuorumForBlock returns the quorum for the given block header.
func QuorumForBlock(
	chain engine.ChainReader, h *block.Header, reCalculate bool,
) (quorum int, err error) {
	var ss shard.State
	if reCalculate {
		ss, _ = committee.WithStakingEnabled.Compute(h.Epoch(), chain)
	} else {
		ss, err = chain.ReadShardState(h.Epoch())
		if err != nil {
			return 0, ctxerror.New("failed to read shard state of epoch",
				"epoch", h.Epoch().Uint64()).WithCause(err)
		}
	}

	c := ss.FindCommitteeByID(h.ShardID())
	if c == nil {
		return 0, errors.Errorf(
			"cannot find shard %d in shard state", h.ShardID())
	}
	return (len(c.Slots))*2/3 + 1, nil
}

// Similiar to VerifyHeader, which is only for verifying the block headers of one's own chain, this verification
// is used for verifying "incoming" block header against commit signature and bitmap sent from the other chain cross-shard via libp2p.
// i.e. this header verification api is more flexible since the caller specifies which commit signature and bitmap to use
// for verifying the block header, which is necessary for cross-shard block header verification. Example of such is cross-shard transaction.
func (e *engineImpl) VerifyHeaderWithSignature(chain engine.ChainReader, header *block.Header, commitSig []byte, commitBitmap []byte, reCalculate bool) error {
	if chain.Config().IsStaking(header.Epoch()) {
		// Never recalculate after staking is enabled
		reCalculate = false
	}
	publicKeys, err := GetPublicKeys(chain, header, reCalculate)
	if err != nil {
		return ctxerror.New("[VerifyHeaderWithSignature] Cannot get publickeys for block header").WithCause(err)
	}

	payload := append(commitSig[:], commitBitmap[:]...)
	aggSig, mask, err := ReadSignatureBitmapByPublicKeys(payload, publicKeys)
	if err != nil {
		return ctxerror.New("[VerifyHeaderWithSignature] Unable to deserialize the commitSignature and commitBitmap in Block Header").WithCause(err)
	}

	hash := header.Hash()
	quorum, err := QuorumForBlock(chain, header, reCalculate)
	if err != nil {
		return errors.Wrapf(err,
			"cannot calculate quorum for block %s", header.Number())
	}
	if count := utils.CountOneBits(mask.Bitmap); count < int64(quorum) {
		return ctxerror.New("[VerifyHeaderWithSignature] Not enough signature in commitSignature from Block Header",
			"need", quorum, "got", count)
	}

	blockNumHash := make([]byte, 8)
	binary.LittleEndian.PutUint64(blockNumHash, header.Number().Uint64())
	commitPayload := append(blockNumHash, hash[:]...)

	if !aggSig.VerifyHash(mask.AggregatePublic, commitPayload) {
		return ctxerror.New("[VerifySeal] Unable to verify aggregated signature for block", "blockNum", header.Number().Uint64()-1, "blockHash", hash)
	}
	return nil
}

// GetPublicKeys finds the public keys of the committee that signed the block header
func GetPublicKeys(chain engine.ChainReader, header *block.Header, reCalculate bool) ([]*bls.PublicKey, error) {
	var shardState shard.State
	var err error
	if reCalculate {
		shardState, _ = committee.WithStakingEnabled.Compute(header.Epoch(), chain)
	} else {
		shardState, err = chain.ReadShardState(header.Epoch())
		if err != nil {
			return nil, ctxerror.New("failed to read shard state of epoch",
				"epoch", header.Epoch().Uint64()).WithCause(err)
		}
	}

	committee := shardState.FindCommitteeByID(header.ShardID())
	if committee == nil {
		return nil, ctxerror.New("cannot find shard in the shard state",
			"blockNumber", header.Number(),
			"shardID", header.ShardID(),
		)
	}
	var committerKeys []*bls.PublicKey

	utils.Logger().Print(committee.Slots)
	for _, member := range committee.Slots {
		committerKey := new(bls.PublicKey)
		err := member.BlsPublicKey.ToLibBLSPublicKey(committerKey)
		if err != nil {
			return nil, ctxerror.New("cannot convert BLS public key",
				"blsPublicKey", member.BlsPublicKey).WithCause(err)
		}
		committerKeys = append(committerKeys, committerKey)
	}
	return committerKeys, nil
}