prysm-pulse/beacon-chain/core/helpers/validators.go
terence tsao 703907bd99
Move ComputeProposerIndexWithValidators to test (#7460)
Co-authored-by: prylabs-bulldozer[bot] <58059840+prylabs-bulldozer[bot]@users.noreply.github.com>
2020-10-08 09:24:17 +00:00

353 lines
14 KiB
Go

package helpers
import (
"github.com/pkg/errors"
ethpb "github.com/prysmaticlabs/ethereumapis/eth/v1alpha1"
stateTrie "github.com/prysmaticlabs/prysm/beacon-chain/state"
pb "github.com/prysmaticlabs/prysm/proto/beacon/p2p/v1"
"github.com/prysmaticlabs/prysm/shared/bls"
"github.com/prysmaticlabs/prysm/shared/bytesutil"
"github.com/prysmaticlabs/prysm/shared/hashutil"
"github.com/prysmaticlabs/prysm/shared/params"
)
// IsActiveValidator returns the boolean value on whether the validator
// is active or not.
//
// Spec pseudocode definition:
// def is_active_validator(validator: Validator, epoch: Epoch) -> bool:
// """
// Check if ``validator`` is active.
// """
// return validator.activation_epoch <= epoch < validator.exit_epoch
func IsActiveValidator(validator *ethpb.Validator, epoch uint64) bool {
return checkValidatorActiveStatus(validator.ActivationEpoch, validator.ExitEpoch, epoch)
}
// IsActiveValidatorUsingTrie checks if a read only validator is active.
func IsActiveValidatorUsingTrie(validator *stateTrie.ReadOnlyValidator, epoch uint64) bool {
return checkValidatorActiveStatus(validator.ActivationEpoch(), validator.ExitEpoch(), epoch)
}
func checkValidatorActiveStatus(activationEpoch uint64, exitEpoch uint64, epoch uint64) bool {
return activationEpoch <= epoch && epoch < exitEpoch
}
// IsSlashableValidator returns the boolean value on whether the validator
// is slashable or not.
//
// Spec pseudocode definition:
// def is_slashable_validator(validator: Validator, epoch: Epoch) -> bool:
// """
// Check if ``validator`` is slashable.
// """
// return (not validator.slashed) and (validator.activation_epoch <= epoch < validator.withdrawable_epoch)
func IsSlashableValidator(activationEpoch uint64, withdrawableEpoch uint64, slashed bool, epoch uint64) bool {
return checkValidatorSlashable(activationEpoch, withdrawableEpoch, slashed, epoch)
}
// IsSlashableValidatorUsingTrie checks if a read only validator is slashable.
func IsSlashableValidatorUsingTrie(val *stateTrie.ReadOnlyValidator, epoch uint64) bool {
return checkValidatorSlashable(val.ActivationEpoch(), val.WithdrawableEpoch(), val.Slashed(), epoch)
}
func checkValidatorSlashable(activationEpoch uint64, withdrawableEpoch uint64, slashed bool, epoch uint64) bool {
active := activationEpoch <= epoch
beforeWithdrawable := epoch < withdrawableEpoch
return beforeWithdrawable && active && !slashed
}
// ActiveValidatorIndices filters out active validators based on validator status
// and returns their indices in a list.
//
// WARNING: This method allocates a new copy of the validator index set and is
// considered to be very memory expensive. Avoid using this unless you really
// need the active validator indices for some specific reason.
//
// Spec pseudocode definition:
// def get_active_validator_indices(state: BeaconState, epoch: Epoch) -> Sequence[ValidatorIndex]:
// """
// Return the sequence of active validator indices at ``epoch``.
// """
// return [ValidatorIndex(i) for i, v in enumerate(state.validators) if is_active_validator(v, epoch)]
func ActiveValidatorIndices(state *stateTrie.BeaconState, epoch uint64) ([]uint64, error) {
seed, err := Seed(state, epoch, params.BeaconConfig().DomainBeaconAttester)
if err != nil {
return nil, errors.Wrap(err, "could not get seed")
}
activeIndices, err := committeeCache.ActiveIndices(seed)
if err != nil {
return nil, errors.Wrap(err, "could not interface with committee cache")
}
if activeIndices != nil {
return activeIndices, nil
}
var indices []uint64
if err := state.ReadFromEveryValidator(func(idx int, val *stateTrie.ReadOnlyValidator) error {
if IsActiveValidatorUsingTrie(val, epoch) {
indices = append(indices, uint64(idx))
}
return nil
}); err != nil {
return nil, err
}
if err := UpdateCommitteeCache(state, epoch); err != nil {
return nil, errors.Wrap(err, "could not update committee cache")
}
return indices, nil
}
// ActiveValidatorCount returns the number of active validators in the state
// at the given epoch.
func ActiveValidatorCount(state *stateTrie.BeaconState, epoch uint64) (uint64, error) {
seed, err := Seed(state, epoch, params.BeaconConfig().DomainBeaconAttester)
if err != nil {
return 0, errors.Wrap(err, "could not get seed")
}
activeCount, err := committeeCache.ActiveIndicesCount(seed)
if err != nil {
return 0, errors.Wrap(err, "could not interface with committee cache")
}
if activeCount != 0 && state.Slot() != 0 {
return uint64(activeCount), nil
}
count := uint64(0)
if err := state.ReadFromEveryValidator(func(idx int, val *stateTrie.ReadOnlyValidator) error {
if IsActiveValidatorUsingTrie(val, epoch) {
count++
}
return nil
}); err != nil {
return 0, err
}
if err := UpdateCommitteeCache(state, epoch); err != nil {
return 0, errors.Wrap(err, "could not update committee cache")
}
return count, nil
}
// ActivationExitEpoch takes in epoch number and returns when
// the validator is eligible for activation and exit.
//
// Spec pseudocode definition:
// def compute_activation_exit_epoch(epoch: Epoch) -> Epoch:
// """
// Return the epoch during which validator activations and exits initiated in ``epoch`` take effect.
// """
// return Epoch(epoch + 1 + MAX_SEED_LOOKAHEAD)
func ActivationExitEpoch(epoch uint64) uint64 {
return epoch + 1 + params.BeaconConfig().MaxSeedLookahead
}
// ValidatorChurnLimit returns the number of validators that are allowed to
// enter and exit validator pool for an epoch.
//
// Spec pseudocode definition:
// def get_validator_churn_limit(state: BeaconState) -> uint64:
// """
// Return the validator churn limit for the current epoch.
// """
// active_validator_indices = get_active_validator_indices(state, get_current_epoch(state))
// return max(MIN_PER_EPOCH_CHURN_LIMIT, len(active_validator_indices) // CHURN_LIMIT_QUOTIENT)
func ValidatorChurnLimit(activeValidatorCount uint64) (uint64, error) {
churnLimit := activeValidatorCount / params.BeaconConfig().ChurnLimitQuotient
if churnLimit < params.BeaconConfig().MinPerEpochChurnLimit {
churnLimit = params.BeaconConfig().MinPerEpochChurnLimit
}
return churnLimit, nil
}
// BeaconProposerIndex returns proposer index of a current slot.
//
// Spec pseudocode definition:
// def get_beacon_proposer_index(state: BeaconState) -> ValidatorIndex:
// """
// Return the beacon proposer index at the current slot.
// """
// epoch = get_current_epoch(state)
// seed = hash(get_seed(state, epoch, DOMAIN_BEACON_PROPOSER) + int_to_bytes(state.slot, length=8))
// indices = get_active_validator_indices(state, epoch)
// return compute_proposer_index(state, indices, seed)
func BeaconProposerIndex(state *stateTrie.BeaconState) (uint64, error) {
e := CurrentEpoch(state)
// The cache uses the block root of the previous epoch's last slot as key. (e.g. Starting epoch 1, slot 32, the key would be block root at slot 31)
// For simplicity, the node will skip caching of genesis epoch.
if e > params.BeaconConfig().GenesisEpoch {
s, err := EndSlot(PrevEpoch(state))
if err != nil {
return 0, err
}
r, err := BlockRootAtSlot(state, s)
if err != nil {
return 0, err
}
proposerIndices, err := proposerIndicesCache.ProposerIndices(bytesutil.ToBytes32(r))
if err != nil {
return 0, errors.Wrap(err, "could not interface with committee cache")
}
if proposerIndices != nil {
return proposerIndices[state.Slot()%params.BeaconConfig().SlotsPerEpoch], nil
}
if err := UpdateProposerIndicesInCache(state, e); err != nil {
return 0, errors.Wrap(err, "could not update committee cache")
}
}
seed, err := Seed(state, e, params.BeaconConfig().DomainBeaconProposer)
if err != nil {
return 0, errors.Wrap(err, "could not generate seed")
}
seedWithSlot := append(seed[:], bytesutil.Bytes8(state.Slot())...)
seedWithSlotHash := hashutil.Hash(seedWithSlot)
indices, err := ActiveValidatorIndices(state, e)
if err != nil {
return 0, errors.Wrap(err, "could not get active indices")
}
return ComputeProposerIndex(state, indices, seedWithSlotHash)
}
// ComputeProposerIndex returns the index sampled by effective balance, which is used to calculate proposer.
//
// Spec pseudocode definition:
// def compute_proposer_index(state: BeaconState, indices: Sequence[ValidatorIndex], seed: Hash) -> ValidatorIndex:
// """
// Return from ``indices`` a random index sampled by effective balance.
// """
// assert len(indices) > 0
// MAX_RANDOM_BYTE = 2**8 - 1
// i = 0
// while True:
// candidate_index = indices[compute_shuffled_index(ValidatorIndex(i % len(indices)), len(indices), seed)]
// random_byte = hash(seed + int_to_bytes(i // 32, length=8))[i % 32]
// effective_balance = state.validators[candidate_index].effective_balance
// if effective_balance * MAX_RANDOM_BYTE >= MAX_EFFECTIVE_BALANCE * random_byte:
// return ValidatorIndex(candidate_index)
// i += 1
func ComputeProposerIndex(bState *stateTrie.BeaconState, activeIndices []uint64, seed [32]byte) (uint64, error) {
length := uint64(len(activeIndices))
if length == 0 {
return 0, errors.New("empty active indices list")
}
maxRandomByte := uint64(1<<8 - 1)
hashFunc := hashutil.CustomSHA256Hasher()
for i := uint64(0); ; i++ {
candidateIndex, err := ComputeShuffledIndex(i%length, length, seed, true /* shuffle */)
if err != nil {
return 0, err
}
candidateIndex = activeIndices[candidateIndex]
if candidateIndex >= uint64(bState.NumValidators()) {
return 0, errors.New("active index out of range")
}
b := append(seed[:], bytesutil.Bytes8(i/32)...)
randomByte := hashFunc(b)[i%32]
v, err := bState.ValidatorAtIndexReadOnly(candidateIndex)
if err != nil {
return 0, err
}
effectiveBal := v.EffectiveBalance()
if effectiveBal*maxRandomByte >= params.BeaconConfig().MaxEffectiveBalance*uint64(randomByte) {
return candidateIndex, nil
}
}
}
// Domain returns the domain version for BLS private key to sign and verify.
//
// Spec pseudocode definition:
// def get_domain(state: BeaconState, domain_type: DomainType, epoch: Epoch=None) -> Domain:
// """
// Return the signature domain (fork version concatenated with domain type) of a message.
// """
// epoch = get_current_epoch(state) if epoch is None else epoch
// fork_version = state.fork.previous_version if epoch < state.fork.epoch else state.fork.current_version
// return compute_domain(domain_type, fork_version, state.genesis_validators_root)
func Domain(fork *pb.Fork, epoch uint64, domainType [bls.DomainByteLength]byte, genesisRoot []byte) ([]byte, error) {
if fork == nil {
return []byte{}, errors.New("nil fork or domain type")
}
var forkVersion []byte
if epoch < fork.Epoch {
forkVersion = fork.PreviousVersion
} else {
forkVersion = fork.CurrentVersion
}
if len(forkVersion) != 4 {
return []byte{}, errors.New("fork version length is not 4 byte")
}
var forkVersionArray [4]byte
copy(forkVersionArray[:], forkVersion[:4])
return ComputeDomain(domainType, forkVersionArray[:], genesisRoot)
}
// IsEligibleForActivationQueue checks if the validator is eligible to
// be placed into the activation queue.
//
// Spec pseudocode definition:
// def is_eligible_for_activation_queue(validator: Validator) -> bool:
// """
// Check if ``validator`` is eligible to be placed into the activation queue.
// """
// return (
// validator.activation_eligibility_epoch == FAR_FUTURE_EPOCH
// and validator.effective_balance == MAX_EFFECTIVE_BALANCE
// )
func IsEligibleForActivationQueue(validator *ethpb.Validator) bool {
return isEligibileForActivationQueue(validator.ActivationEligibilityEpoch, validator.EffectiveBalance)
}
// IsEligibleForActivationQueueUsingTrie checks if the read-only validator is eligible to
// be placed into the activation queue.
func IsEligibleForActivationQueueUsingTrie(validator *stateTrie.ReadOnlyValidator) bool {
return isEligibileForActivationQueue(validator.ActivationEligibilityEpoch(), validator.EffectiveBalance())
}
// isEligibleForActivationQueue carries out the logic for IsEligibleForActivationQueue*
func isEligibileForActivationQueue(activationEligibilityEpoch uint64, effectiveBalance uint64) bool {
return activationEligibilityEpoch == params.BeaconConfig().FarFutureEpoch &&
effectiveBalance == params.BeaconConfig().MaxEffectiveBalance
}
// IsEligibleForActivation checks if the validator is eligible for activation.
//
// Spec pseudocode definition:
// def is_eligible_for_activation(state: BeaconState, validator: Validator) -> bool:
// """
// Check if ``validator`` is eligible for activation.
// """
// return (
// # Placement in queue is finalized
// validator.activation_eligibility_epoch <= state.finalized_checkpoint.epoch
// # Has not yet been activated
// and validator.activation_epoch == FAR_FUTURE_EPOCH
// )
func IsEligibleForActivation(state *stateTrie.BeaconState, validator *ethpb.Validator) bool {
finalizedEpoch := state.FinalizedCheckpointEpoch()
return isEligibleForActivation(validator.ActivationEligibilityEpoch, validator.ActivationEpoch, finalizedEpoch)
}
// IsEligibleForActivationUsingTrie checks if the validator is eligible for activation.
func IsEligibleForActivationUsingTrie(state *stateTrie.BeaconState, validator *stateTrie.ReadOnlyValidator) bool {
cpt := state.FinalizedCheckpoint()
if cpt == nil {
return false
}
return isEligibleForActivation(validator.ActivationEligibilityEpoch(), validator.ActivationEpoch(), cpt.Epoch)
}
// isEligibleForActivation carries out the logic for IsEligibleForActivation*
func isEligibleForActivation(activationEligibilityEpoch uint64, activationEpoch uint64, finalizedEpoch uint64) bool {
return activationEligibilityEpoch <= finalizedEpoch &&
activationEpoch == params.BeaconConfig().FarFutureEpoch
}