70 KiB
Ethereum 2.0 Phase 0 -- The Beacon Chain
Notice: This document is a work-in-progress for researchers and implementers.
Table of contents
- Ethereum 2.0 Phase 0 -- The Beacon Chain
- Table of contents
- Introduction
- Notation
- Terminology
- Custom types
- Constants
- Configuration
- Containers
- Helper functions
xor
hash
hash_tree_root
signing_root
bls_domain
slot_to_epoch
get_previous_epoch
get_current_epoch
get_epoch_start_slot
is_active_validator
is_slashable_validator
get_active_validator_indices
increase_balance
decrease_balance
get_epoch_committee_count
get_shard_delta
get_epoch_start_shard
get_attestation_data_slot
get_block_root_at_slot
get_block_root
get_randao_mix
get_compact_committees_root
generate_seed
get_beacon_proposer_index
verify_merkle_branch
get_shuffled_index
compute_committee
get_crosslink_committee
get_attesting_indices
int_to_bytes
bytes_to_int
get_total_balance
get_domain
convert_to_indexed
validate_indexed_attestation
is_slashable_attestation_data
integer_squareroot
get_delayed_activation_exit_epoch
get_churn_limit
bls_verify
bls_verify_multiple
bls_aggregate_pubkeys
- Routines for updating validator status
- Genesis
- Beacon chain state transition function
Introduction
This document represents the specification for Phase 0 of Ethereum 2.0 -- The Beacon Chain.
At the core of Ethereum 2.0 is a system chain called the "beacon chain". The beacon chain stores and manages the registry of validators. In the initial deployment phases of Ethereum 2.0, the only mechanism to become a validator is to make a one-way ETH transaction to a deposit contract on Ethereum 1.0. Activation as a validator happens when Ethereum 1.0 deposit receipts are processed by the beacon chain, the activation balance is reached, and a queuing process is completed. Exit is either voluntary or done forcibly as a penalty for misbehavior. The primary source of load on the beacon chain is "attestations". Attestations are simultaneously availability votes for a shard block and proof-of-stake votes for a beacon block. A sufficient number of attestations for the same shard block create a "crosslink", confirming the shard segment up to that shard block into the beacon chain. Crosslinks also serve as infrastructure for asynchronous cross-shard communication.
Notation
Code snippets appearing in this style
are to be interpreted as Python code.
Terminology
- Validator—a registered participant in the beacon chain. You can become one by sending ether into the Ethereum 1.0 deposit contract.
- Active validator—an active participant in the Ethereum 2.0 consensus invited to, among other things, propose and attest to blocks and vote for crosslinks.
- Committee—a (pseudo-) randomly sampled subset of active validators. When a committee is referred to collectively, as in "this committee attests to X", this is assumed to mean "some subset of that committee that contains enough validators that the protocol recognizes it as representing the committee".
- Proposer—the validator that creates a beacon chain block.
- Attester—a validator that is part of a committee that needs to sign off on a beacon chain block while simultaneously creating a link (crosslink) to a recent shard block on a particular shard chain.
- Beacon chain—the central proof-of-stake chain that is the base of the sharding system.
- Shard chain—one of the chains on which user transactions take place and account data is stored.
- Block root—a 32-byte Merkle root of a beacon chain block or shard chain block. Previously called "block hash".
- Crosslink—a set of signatures from a committee attesting to a block in a shard chain that can be included into the beacon chain. Crosslinks are the main means by which the beacon chain "learns about" the updated state of shard chains.
- Slot—a period during which one proposer has the ability to create a beacon chain block and some attesters have the ability to make attestations.
- Epoch—an aligned span of slots during which all validators get exactly one chance to make an attestation.
- Finalized, justified—see the Casper FFG paper.
- Withdrawal period—the number of slots between a validator exit and the validator balance being withdrawable.
- Genesis time—the Unix time of the genesis beacon chain block at slot 0.
Custom types
We define the following Python custom types for type hinting and readability:
Name | SSZ equivalent | Description |
---|---|---|
Slot |
uint64 |
a slot number |
Epoch |
uint64 |
an epoch number |
Shard |
uint64 |
a shard number |
ValidatorIndex |
uint64 |
a validator registry index |
Gwei |
uint64 |
an amount in Gwei |
Version |
Bytes4 |
a fork version number |
Hash |
Bytes32 |
a hashed result |
BLSPubkey |
Bytes48 |
a BLS12-381 public key |
BLSSignature |
Bytes96 |
a BLS12-381 signature |
Constants
The following values are (non-configurable) constants used throughout the specification.
Name | Value |
---|---|
FAR_FUTURE_EPOCH |
Epoch(2**64 - 1) |
ZERO_HASH |
Hash(b'\x00' * 32) |
BASE_REWARDS_PER_EPOCH |
5 |
DEPOSIT_CONTRACT_TREE_DEPTH |
2**5 (= 32) |
SECONDS_PER_DAY |
86400 |
Configuration
Note: The default mainnet configuration values are included here for spec-design purposes. The different configurations for mainnet, testnets, and YAML-based testing can be found in the configs/constant_presets
directory. These configurations are updated for releases and may be out of sync during dev
changes.
Misc
Name | Value |
---|---|
SHARD_COUNT |
2**10 (= 1,024) |
TARGET_COMMITTEE_SIZE |
2**7 (= 128) |
MAX_VALIDATORS_PER_COMMITTEE |
2**12 (= 4,096) |
MIN_PER_EPOCH_CHURN_LIMIT |
2**2 (= 4) |
CHURN_LIMIT_QUOTIENT |
2**16 (= 65,536) |
SHUFFLE_ROUND_COUNT |
90 |
MIN_GENESIS_ACTIVE_VALIDATOR_COUNT |
2**16 (= 65,536) |
MIN_GENESIS_TIME |
1578009600 (Jan 3, 2020) |
JUSTIFICATION_BITS_LENGTH |
4 |
- For the safety of crosslinks,
TARGET_COMMITTEE_SIZE
exceeds the recommended minimum committee size of 111; with sufficient active validators (at leastSLOTS_PER_EPOCH * TARGET_COMMITTEE_SIZE
), the shuffling algorithm ensures committee sizes of at leastTARGET_COMMITTEE_SIZE
. (Unbiasable randomness with a Verifiable Delay Function (VDF) will improve committee robustness and lower the safe minimum committee size.)
Gwei values
Name | Value |
---|---|
MIN_DEPOSIT_AMOUNT |
Gwei(2**0 * 10**9) (= 1,000,000,000) |
MAX_EFFECTIVE_BALANCE |
Gwei(2**5 * 10**9) (= 32,000,000,000) |
EJECTION_BALANCE |
Gwei(2**4 * 10**9) (= 16,000,000,000) |
EFFECTIVE_BALANCE_INCREMENT |
Gwei(2**0 * 10**9) (= 1,000,000,000) |
Initial values
Name | Value |
---|---|
GENESIS_SLOT |
Slot(0) |
GENESIS_EPOCH |
Epoch(0) |
BLS_WITHDRAWAL_PREFIX |
0 |
Time parameters
Name | Value | Unit | Duration |
---|---|---|---|
MIN_ATTESTATION_INCLUSION_DELAY |
2**0 (= 1) |
slots | 6 seconds |
SLOTS_PER_EPOCH |
2**6 (= 64) |
slots | 6.4 minutes |
MIN_SEED_LOOKAHEAD |
2**0 (= 1) |
epochs | 6.4 minutes |
ACTIVATION_EXIT_DELAY |
2**2 (= 4) |
epochs | 25.6 minutes |
SLOTS_PER_ETH1_VOTING_PERIOD |
2**10 (= 1,024) |
slots | ~1.7 hours |
SLOTS_PER_HISTORICAL_ROOT |
2**13 (= 8,192) |
slots | ~13 hours |
MIN_VALIDATOR_WITHDRAWABILITY_DELAY |
2**8 (= 256) |
epochs | ~27 hours |
PERSISTENT_COMMITTEE_PERIOD |
2**11 (= 2,048) |
epochs | 9 days |
MAX_EPOCHS_PER_CROSSLINK |
2**6 (= 64) |
epochs | ~7 hours |
MIN_EPOCHS_TO_INACTIVITY_PENALTY |
2**2 (= 4) |
epochs | 25.6 minutes |
MAX_EPOCHS_PER_CROSSLINK
should be a small constant timesSHARD_COUNT // SLOTS_PER_EPOCH
.
State list lengths
Name | Value | Unit | Duration |
---|---|---|---|
EPOCHS_PER_HISTORICAL_VECTOR |
2**16 (= 65,536) |
epochs | ~0.8 years |
EPOCHS_PER_SLASHINGS_VECTOR |
2**13 (= 8,192) |
epochs | ~36 days |
HISTORICAL_ROOTS_LIMIT |
2**24 (= 16,777,216) |
historical roots | ~26,131 years |
VALIDATOR_REGISTRY_LIMIT |
2**40 (= 1,099,511,627,776) |
validator spots |
Rewards and penalties
Name | Value |
---|---|
BASE_REWARD_FACTOR |
2**6 (= 64) |
WHISTLEBLOWER_REWARD_QUOTIENT |
2**9 (= 512) |
PROPOSER_REWARD_QUOTIENT |
2**3 (= 8) |
INACTIVITY_PENALTY_QUOTIENT |
2**25 (= 33,554,432) |
MIN_SLASHING_PENALTY_QUOTIENT |
2**5 (= 32) |
- The
INACTIVITY_PENALTY_QUOTIENT
equalsINVERSE_SQRT_E_DROP_TIME**2
whereINVERSE_SQRT_E_DROP_TIME := 2**12 epochs
(about 18 days) is the time it takes the inactivity penalty to reduce the balance of non-participating validators to about1/sqrt(e) ~= 60.6%
. Indeed, the balance retained by offline validators aftern
epochs is about(1 - 1/INACTIVITY_PENALTY_QUOTIENT)**(n**2/2)
; so afterINVERSE_SQRT_E_DROP_TIME
epochs, it is roughly(1 - 1/INACTIVITY_PENALTY_QUOTIENT)**(INACTIVITY_PENALTY_QUOTIENT/2) ~= 1/sqrt(e)
.
Max operations per block
Name | Value |
---|---|
MAX_PROPOSER_SLASHINGS |
2**4 (= 16) |
MAX_ATTESTER_SLASHINGS |
2**0 (= 1) |
MAX_ATTESTATIONS |
2**7 (= 128) |
MAX_DEPOSITS |
2**4 (= 16) |
MAX_VOLUNTARY_EXITS |
2**4 (= 16) |
MAX_TRANSFERS |
0 |
Signature domains
Name | Value |
---|---|
DOMAIN_BEACON_PROPOSER |
0 |
DOMAIN_RANDAO |
1 |
DOMAIN_ATTESTATION |
2 |
DOMAIN_DEPOSIT |
3 |
DOMAIN_VOLUNTARY_EXIT |
4 |
DOMAIN_TRANSFER |
5 |
Containers
The following types are SimpleSerialize (SSZ) containers.
Note: The definitions are ordered topologically to facilitate execution of the spec.
Note: Fields missing in container instantiations default to their zero value.
Misc dependencies
Fork
class Fork(Container):
previous_version: Version
current_version: Version
epoch: Epoch # Epoch of latest fork
Checkpoint
class Checkpoint(Container):
epoch: Epoch
root: Hash
Validator
class Validator(Container):
pubkey: BLSPubkey
withdrawal_credentials: Hash # Commitment to pubkey for withdrawals and transfers
effective_balance: Gwei # Balance at stake
slashed: boolean
# Status epochs
activation_eligibility_epoch: Epoch # When criteria for activation were met
activation_epoch: Epoch
exit_epoch: Epoch
withdrawable_epoch: Epoch # When validator can withdraw or transfer funds
Crosslink
class Crosslink(Container):
shard: Shard
parent_root: Hash
# Crosslinking data
start_epoch: Epoch
end_epoch: Epoch
data_root: Hash
AttestationData
class AttestationData(Container):
# LMD GHOST vote
beacon_block_root: Hash
# FFG vote
source: Checkpoint
target: Checkpoint
# Crosslink vote
crosslink: Crosslink
AttestationDataAndCustodyBit
class AttestationDataAndCustodyBit(Container):
data: AttestationData
custody_bit: bit # Challengeable bit (SSZ-bool, 1 byte) for the custody of crosslink data
IndexedAttestation
class IndexedAttestation(Container):
custody_bit_0_indices: List[ValidatorIndex, MAX_VALIDATORS_PER_COMMITTEE] # Indices with custody bit equal to 0
custody_bit_1_indices: List[ValidatorIndex, MAX_VALIDATORS_PER_COMMITTEE] # Indices with custody bit equal to 1
data: AttestationData
signature: BLSSignature
PendingAttestation
class PendingAttestation(Container):
aggregation_bits: Bitlist[MAX_VALIDATORS_PER_COMMITTEE]
data: AttestationData
inclusion_delay: Slot
proposer_index: ValidatorIndex
Eth1Data
class Eth1Data(Container):
deposit_root: Hash
deposit_count: uint64
block_hash: Hash
HistoricalBatch
class HistoricalBatch(Container):
block_roots: Vector[Hash, SLOTS_PER_HISTORICAL_ROOT]
state_roots: Vector[Hash, SLOTS_PER_HISTORICAL_ROOT]
DepositData
class DepositData(Container):
pubkey: BLSPubkey
withdrawal_credentials: Hash
amount: Gwei
signature: BLSSignature
CompactCommittee
class CompactCommittee(Container):
pubkeys: List[Bytes48, MAX_VALIDATORS_PER_COMMITTEE]
compact_validators: List[uint64, MAX_VALIDATORS_PER_COMMITTEE]
BeaconBlockHeader
class BeaconBlockHeader(Container):
slot: Slot
parent_root: Hash
state_root: Hash
body_root: Hash
signature: BLSSignature
Beacon operations
ProposerSlashing
class ProposerSlashing(Container):
proposer_index: ValidatorIndex
header_1: BeaconBlockHeader
header_2: BeaconBlockHeader
AttesterSlashing
class AttesterSlashing(Container):
attestation_1: IndexedAttestation
attestation_2: IndexedAttestation
Attestation
class Attestation(Container):
aggregation_bits: Bitlist[MAX_VALIDATORS_PER_COMMITTEE]
data: AttestationData
custody_bits: Bitlist[MAX_VALIDATORS_PER_COMMITTEE]
signature: BLSSignature
Deposit
class Deposit(Container):
proof: Vector[Hash, DEPOSIT_CONTRACT_TREE_DEPTH + 1] # Merkle path to deposit data list root
data: DepositData
VoluntaryExit
class VoluntaryExit(Container):
epoch: Epoch # Earliest epoch when voluntary exit can be processed
validator_index: ValidatorIndex
signature: BLSSignature
Transfer
class Transfer(Container):
sender: ValidatorIndex
recipient: ValidatorIndex
amount: Gwei
fee: Gwei
slot: Slot # Slot at which transfer must be processed
pubkey: BLSPubkey # Withdrawal pubkey
signature: BLSSignature # Signature checked against withdrawal pubkey
Beacon blocks
BeaconBlockBody
class BeaconBlockBody(Container):
randao_reveal: BLSSignature
eth1_data: Eth1Data # Eth1 data vote
graffiti: Bytes32 # Arbitrary data
# Operations
proposer_slashings: List[ProposerSlashing, MAX_PROPOSER_SLASHINGS]
attester_slashings: List[AttesterSlashing, MAX_ATTESTER_SLASHINGS]
attestations: List[Attestation, MAX_ATTESTATIONS]
deposits: List[Deposit, MAX_DEPOSITS]
voluntary_exits: List[VoluntaryExit, MAX_VOLUNTARY_EXITS]
transfers: List[Transfer, MAX_TRANSFERS]
BeaconBlock
class BeaconBlock(Container):
slot: Slot
parent_root: Hash
state_root: Hash
body: BeaconBlockBody
signature: BLSSignature
Beacon state
BeaconState
class BeaconState(Container):
# Versioning
genesis_time: uint64
slot: Slot
fork: Fork
# History
latest_block_header: BeaconBlockHeader
block_roots: Vector[Hash, SLOTS_PER_HISTORICAL_ROOT]
state_roots: Vector[Hash, SLOTS_PER_HISTORICAL_ROOT]
historical_roots: List[Hash, HISTORICAL_ROOTS_LIMIT]
# Eth1
eth1_data: Eth1Data
eth1_data_votes: List[Eth1Data, SLOTS_PER_ETH1_VOTING_PERIOD]
eth1_deposit_index: uint64
# Registry
validators: List[Validator, VALIDATOR_REGISTRY_LIMIT]
balances: List[Gwei, VALIDATOR_REGISTRY_LIMIT]
# Shuffling
start_shard: Shard
randao_mixes: Vector[Hash, EPOCHS_PER_HISTORICAL_VECTOR]
compact_committees_roots: Vector[Hash, EPOCHS_PER_HISTORICAL_VECTOR] # Committee digests for light clients
# Slashings
slashings: Vector[Gwei, EPOCHS_PER_SLASHINGS_VECTOR] # Per-epoch sums of slashed effective balances
# Attestations
previous_epoch_attestations: List[PendingAttestation, MAX_ATTESTATIONS * SLOTS_PER_EPOCH]
current_epoch_attestations: List[PendingAttestation, MAX_ATTESTATIONS * SLOTS_PER_EPOCH]
# Crosslinks
previous_crosslinks: Vector[Crosslink, SHARD_COUNT] # Previous epoch snapshot
current_crosslinks: Vector[Crosslink, SHARD_COUNT]
# Finality
justification_bits: Bitvector[JUSTIFICATION_BITS_LENGTH] # Bit set for every recent justified epoch
previous_justified_checkpoint: Checkpoint # Previous epoch snapshot
current_justified_checkpoint: Checkpoint
finalized_checkpoint: Checkpoint
Helper functions
Note: The definitions below are for specification purposes and are not necessarily optimal implementations.
xor
def xor(bytes1: Bytes32, bytes2: Bytes32) -> Bytes32:
return Bytes32(a ^ b for a, b in zip(bytes1, bytes2))
hash
The hash
function is SHA256.
Note: We aim to migrate to a S[T/N]ARK-friendly hash function in a future Ethereum 2.0 deployment phase.
hash_tree_root
def hash_tree_root(object: SSZSerializable) -> Hash
is a function for hashing objects into a single root by utilizing a hash tree structure, as defined in the SimpleSerialize spec.
signing_root
def signing_root(object: Container) -> Hash
is a function for computing signing messages, as defined in the SimpleSerialize spec.
bls_domain
def bls_domain(domain_type: int, fork_version: bytes=b'\x00\x00\x00\x00') -> int:
"""
Return the bls domain given by the ``domain_type`` and optional 4 byte ``fork_version`` (defaults to zero).
"""
return bytes_to_int(int_to_bytes(domain_type, length=4) + fork_version)
slot_to_epoch
def slot_to_epoch(slot: Slot) -> Epoch:
"""
Return the epoch number of the given ``slot``.
"""
return Epoch(slot // SLOTS_PER_EPOCH)
get_previous_epoch
def get_previous_epoch(state: BeaconState) -> Epoch:
"""`
Return the previous epoch of the given ``state``.
Return the current epoch if it's genesis epoch.
"""
current_epoch = get_current_epoch(state)
return GENESIS_EPOCH if current_epoch == GENESIS_EPOCH else Epoch(current_epoch - 1)
get_current_epoch
def get_current_epoch(state: BeaconState) -> Epoch:
"""
Return the current epoch of the given ``state``.
"""
return slot_to_epoch(state.slot)
get_epoch_start_slot
def get_epoch_start_slot(epoch: Epoch) -> Slot:
"""
Return the starting slot of the given ``epoch``.
"""
return Slot(epoch * SLOTS_PER_EPOCH)
is_active_validator
def is_active_validator(validator: Validator, epoch: Epoch) -> bool:
"""
Check if ``validator`` is active.
"""
return validator.activation_epoch <= epoch < validator.exit_epoch
is_slashable_validator
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)
get_active_validator_indices
def get_active_validator_indices(state: BeaconState, epoch: Epoch) -> Sequence[ValidatorIndex]:
"""
Get active validator indices at ``epoch``.
"""
return [ValidatorIndex(i) for i, v in enumerate(state.validators) if is_active_validator(v, epoch)]
increase_balance
def increase_balance(state: BeaconState, index: ValidatorIndex, delta: Gwei) -> None:
"""
Increase validator balance by ``delta``.
"""
state.balances[index] += delta
decrease_balance
def decrease_balance(state: BeaconState, index: ValidatorIndex, delta: Gwei) -> None:
"""
Decrease validator balance by ``delta`` with underflow protection.
"""
state.balances[index] = 0 if delta > state.balances[index] else state.balances[index] - delta
get_epoch_committee_count
def get_epoch_committee_count(state: BeaconState, epoch: Epoch) -> int:
"""
Return the number of committees at ``epoch``.
"""
active_validator_indices = get_active_validator_indices(state, epoch)
return max(
1,
min(
SHARD_COUNT // SLOTS_PER_EPOCH,
len(active_validator_indices) // SLOTS_PER_EPOCH // TARGET_COMMITTEE_SIZE,
)
) * SLOTS_PER_EPOCH
get_shard_delta
def get_shard_delta(state: BeaconState, epoch: Epoch) -> int:
"""
Return the number of shards to increment ``state.start_shard`` during ``epoch``.
"""
return min(get_epoch_committee_count(state, epoch), SHARD_COUNT - SHARD_COUNT // SLOTS_PER_EPOCH)
get_epoch_start_shard
def get_epoch_start_shard(state: BeaconState, epoch: Epoch) -> Shard:
"""
Return the start shard of the 0th committee in an epoch.
"""
assert epoch <= get_current_epoch(state) + 1
check_epoch = Epoch(get_current_epoch(state) + 1)
shard = Shard((state.start_shard + get_shard_delta(state, get_current_epoch(state))) % SHARD_COUNT)
while check_epoch > epoch:
check_epoch -= Epoch(1)
shard = Shard((shard + SHARD_COUNT - get_shard_delta(state, check_epoch)) % SHARD_COUNT)
return shard
get_attestation_data_slot
def get_attestation_data_slot(state: BeaconState, data: AttestationData) -> Slot:
committee_count = get_epoch_committee_count(state, data.target.epoch)
offset = (data.crosslink.shard + SHARD_COUNT - get_epoch_start_shard(state, data.target.epoch)) % SHARD_COUNT
return Slot(get_epoch_start_slot(data.target.epoch) + offset // (committee_count // SLOTS_PER_EPOCH))
get_block_root_at_slot
def get_block_root_at_slot(state: BeaconState,
slot: Slot) -> Hash:
"""
Return the block root at a recent ``slot``.
"""
assert slot < state.slot <= slot + SLOTS_PER_HISTORICAL_ROOT
return state.block_roots[slot % SLOTS_PER_HISTORICAL_ROOT]
get_block_root
def get_block_root(state: BeaconState,
epoch: Epoch) -> Hash:
"""
Return the block root at a recent ``epoch``.
"""
return get_block_root_at_slot(state, get_epoch_start_slot(epoch))
get_randao_mix
def get_randao_mix(state: BeaconState,
epoch: Epoch) -> Hash:
"""
Return the randao mix at a recent ``epoch``.
``epoch`` expected to be between (current_epoch - EPOCHS_PER_HISTORICAL_VECTOR, current_epoch].
"""
return state.randao_mixes[epoch % EPOCHS_PER_HISTORICAL_VECTOR]
get_compact_committees_root
def get_compact_committees_root(state: BeaconState, epoch: Epoch) -> Hash:
"""
Return the compact committee root for the current epoch.
"""
committees = [CompactCommittee() for _ in range(SHARD_COUNT)]
start_shard = get_epoch_start_shard(state, epoch)
for committee_number in range(get_epoch_committee_count(state, epoch)):
shard = Shard((start_shard + committee_number) % SHARD_COUNT)
for index in get_crosslink_committee(state, epoch, shard):
validator = state.validators[index]
committees[shard].pubkeys.append(validator.pubkey)
compact_balance = validator.effective_balance // EFFECTIVE_BALANCE_INCREMENT
# `index` (top 6 bytes) + `slashed` (16th bit) + `compact_balance` (bottom 15 bits)
compact_validator = uint64((index << 16) + (validator.slashed << 15) + compact_balance)
committees[shard].compact_validators.append(compact_validator)
return hash_tree_root(Vector[CompactCommittee, SHARD_COUNT](committees))
generate_seed
def generate_seed(state: BeaconState,
epoch: Epoch) -> Hash:
"""
Generate a seed for the given ``epoch``.
"""
return hash(
get_randao_mix(state, Epoch(epoch + EPOCHS_PER_HISTORICAL_VECTOR - MIN_SEED_LOOKAHEAD)) + # Avoid underflow
hash_tree_root(List[ValidatorIndex, VALIDATOR_REGISTRY_LIMIT](get_active_validator_indices(state, epoch))) +
int_to_bytes(epoch, length=32)
)
get_beacon_proposer_index
def get_beacon_proposer_index(state: BeaconState) -> ValidatorIndex:
"""
Return the current beacon proposer index.
"""
epoch = get_current_epoch(state)
committees_per_slot = get_epoch_committee_count(state, epoch) // SLOTS_PER_EPOCH
offset = committees_per_slot * (state.slot % SLOTS_PER_EPOCH)
shard = Shard((get_epoch_start_shard(state, epoch) + offset) % SHARD_COUNT)
first_committee = get_crosslink_committee(state, epoch, shard)
MAX_RANDOM_BYTE = 2**8 - 1
seed = generate_seed(state, epoch)
i = 0
while True:
candidate_index = first_committee[(epoch + i) % len(first_committee)]
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
verify_merkle_branch
def verify_merkle_branch(leaf: Hash, proof: Sequence[Hash], depth: int, index: int, root: Hash) -> bool:
"""
Verify that the given ``leaf`` is on the merkle branch ``proof``
starting with the given ``root``.
"""
value = leaf
for i in range(depth):
if index // (2**i) % 2:
value = hash(proof[i] + value)
else:
value = hash(value + proof[i])
return value == root
get_shuffled_index
def get_shuffled_index(index: ValidatorIndex, index_count: int, seed: Hash) -> ValidatorIndex:
"""
Return the shuffled validator index corresponding to ``seed`` (and ``index_count``).
"""
assert index < index_count
assert index_count <= 2**40
# Swap or not (https://link.springer.com/content/pdf/10.1007%2F978-3-642-32009-5_1.pdf)
# See the 'generalized domain' algorithm on page 3
for current_round in range(SHUFFLE_ROUND_COUNT):
pivot = bytes_to_int(hash(seed + int_to_bytes(current_round, length=1))[0:8]) % index_count
flip = ValidatorIndex((pivot + index_count - index) % index_count)
position = max(index, flip)
source = hash(
seed + int_to_bytes(current_round, length=1) +
int_to_bytes(position // 256, length=4)
)
byte = source[(position % 256) // 8]
bit = (byte >> (position % 8)) % 2
index = flip if bit else index
return ValidatorIndex(index)
compute_committee
def compute_committee(indices: Sequence[ValidatorIndex],
seed: Hash, index: int, count: int) -> Sequence[ValidatorIndex]:
start = (len(indices) * index) // count
end = (len(indices) * (index + 1)) // count
return [indices[get_shuffled_index(ValidatorIndex(i), len(indices), seed)] for i in range(start, end)]
get_crosslink_committee
def get_crosslink_committee(state: BeaconState, epoch: Epoch, shard: Shard) -> Sequence[ValidatorIndex]:
return compute_committee(
indices=get_active_validator_indices(state, epoch),
seed=generate_seed(state, epoch),
index=(shard + SHARD_COUNT - get_epoch_start_shard(state, epoch)) % SHARD_COUNT,
count=get_epoch_committee_count(state, epoch),
)
get_attesting_indices
def get_attesting_indices(state: BeaconState,
data: AttestationData,
bits: Bitlist[MAX_VALIDATORS_PER_COMMITTEE]) -> Set[ValidatorIndex]:
"""
Return the set of attesting indices corresponding to ``data`` and ``bitfield``.
"""
committee = get_crosslink_committee(state, data.target.epoch, data.crosslink.shard)
return set(index for i, index in enumerate(committee) if bits[i])
int_to_bytes
def int_to_bytes(integer: int, length: int) -> bytes:
return integer.to_bytes(length, 'little')
bytes_to_int
def bytes_to_int(data: bytes) -> int:
return int.from_bytes(data, 'little')
get_total_balance
def get_total_balance(state: BeaconState, indices: Set[ValidatorIndex]) -> Gwei:
"""
Return the combined effective balance of the ``indices``. (1 Gwei minimum to avoid divisions by zero.)
"""
return Gwei(max(sum([state.validators[index].effective_balance for index in indices]), 1))
get_domain
def get_domain(state: BeaconState,
domain_type: int,
message_epoch: Epoch=None) -> int:
"""
Return the signature domain (fork version concatenated with domain type) of a message.
"""
epoch = get_current_epoch(state) if message_epoch is None else message_epoch
fork_version = state.fork.previous_version if epoch < state.fork.epoch else state.fork.current_version
return bls_domain(domain_type, fork_version)
convert_to_indexed
def convert_to_indexed(state: BeaconState, attestation: Attestation) -> IndexedAttestation:
"""
Convert ``attestation`` to (almost) indexed-verifiable form.
"""
attesting_indices = get_attesting_indices(state, attestation.data, attestation.aggregation_bits)
custody_bit_1_indices = get_attesting_indices(state, attestation.data, attestation.custody_bits)
assert custody_bit_1_indices.issubset(attesting_indices)
custody_bit_0_indices = attesting_indices.difference(custody_bit_1_indices)
return IndexedAttestation(
custody_bit_0_indices=sorted(custody_bit_0_indices),
custody_bit_1_indices=sorted(custody_bit_1_indices),
data=attestation.data,
signature=attestation.signature,
)
validate_indexed_attestation
def validate_indexed_attestation(state: BeaconState, indexed_attestation: IndexedAttestation) -> None:
"""
Verify validity of ``indexed_attestation``.
"""
bit_0_indices = indexed_attestation.custody_bit_0_indices
bit_1_indices = indexed_attestation.custody_bit_1_indices
# Verify no index has custody bit equal to 1 [to be removed in phase 1]
assert len(bit_1_indices) == 0
# Verify max number of indices
assert len(bit_0_indices) + len(bit_1_indices) <= MAX_VALIDATORS_PER_COMMITTEE
# Verify index sets are disjoint
assert len(set(bit_0_indices).intersection(bit_1_indices)) == 0
# Verify indices are sorted
assert bit_0_indices == sorted(bit_0_indices) and bit_1_indices == sorted(bit_1_indices)
# Verify aggregate signature
assert bls_verify_multiple(
pubkeys=[
bls_aggregate_pubkeys([state.validators[i].pubkey for i in bit_0_indices]),
bls_aggregate_pubkeys([state.validators[i].pubkey for i in bit_1_indices]),
],
message_hashes=[
hash_tree_root(AttestationDataAndCustodyBit(data=indexed_attestation.data, custody_bit=0b0)),
hash_tree_root(AttestationDataAndCustodyBit(data=indexed_attestation.data, custody_bit=0b1)),
],
signature=indexed_attestation.signature,
domain=get_domain(state, DOMAIN_ATTESTATION, indexed_attestation.data.target.epoch),
)
is_slashable_attestation_data
def is_slashable_attestation_data(data_1: AttestationData, data_2: AttestationData) -> bool:
"""
Check if ``data_1`` and ``data_2`` are slashable according to Casper FFG rules.
"""
return (
# Double vote
(data_1 != data_2 and data_1.target.epoch == data_2.target.epoch) or
# Surround vote
(data_1.source.epoch < data_2.source.epoch and data_2.target.epoch < data_1.target.epoch)
)
integer_squareroot
def integer_squareroot(n: int) -> int:
"""
The largest integer ``x`` such that ``x**2`` is less than or equal to ``n``.
"""
assert n >= 0
x = n
y = (x + 1) // 2
while y < x:
x = y
y = (x + n // x) // 2
return x
get_delayed_activation_exit_epoch
def get_delayed_activation_exit_epoch(epoch: Epoch) -> Epoch:
"""
Return the epoch at which an activation or exit triggered in ``epoch`` takes effect.
"""
return Epoch(epoch + 1 + ACTIVATION_EXIT_DELAY)
get_churn_limit
def get_churn_limit(state: BeaconState) -> int:
"""
Return the churn limit based on the active validator count.
"""
return max(
MIN_PER_EPOCH_CHURN_LIMIT,
len(get_active_validator_indices(state, get_current_epoch(state))) // CHURN_LIMIT_QUOTIENT
)
bls_verify
bls_verify
is a function for verifying a BLS signature, as defined in the BLS Signature spec.
bls_verify_multiple
bls_verify_multiple
is a function for verifying a BLS signature constructed from multiple messages, as defined in the BLS Signature spec.
bls_aggregate_pubkeys
bls_aggregate_pubkeys
is a function for aggregating multiple BLS public keys into a single aggregate key, as defined in the BLS Signature spec.
Routines for updating validator status
Note: All functions in this section mutate state
.
initiate_validator_exit
def initiate_validator_exit(state: BeaconState, index: ValidatorIndex) -> None:
"""
Initiate the exit of the validator of the given ``index``.
"""
# Return if validator already initiated exit
validator = state.validators[index]
if validator.exit_epoch != FAR_FUTURE_EPOCH:
return
# Compute exit queue epoch
exit_epochs = [v.exit_epoch for v in state.validators if v.exit_epoch != FAR_FUTURE_EPOCH]
exit_queue_epoch = max(exit_epochs + [get_delayed_activation_exit_epoch(get_current_epoch(state))])
exit_queue_churn = len([v for v in state.validators if v.exit_epoch == exit_queue_epoch])
if exit_queue_churn >= get_churn_limit(state):
exit_queue_epoch += Epoch(1)
# Set validator exit epoch and withdrawable epoch
validator.exit_epoch = exit_queue_epoch
validator.withdrawable_epoch = Epoch(validator.exit_epoch + MIN_VALIDATOR_WITHDRAWABILITY_DELAY)
slash_validator
def slash_validator(state: BeaconState,
slashed_index: ValidatorIndex,
whistleblower_index: ValidatorIndex=None) -> None:
"""
Slash the validator with index ``slashed_index``.
"""
epoch = get_current_epoch(state)
initiate_validator_exit(state, slashed_index)
validator = state.validators[slashed_index]
validator.slashed = True
validator.withdrawable_epoch = max(validator.withdrawable_epoch, Epoch(epoch + EPOCHS_PER_SLASHINGS_VECTOR))
state.slashings[epoch % EPOCHS_PER_SLASHINGS_VECTOR] += validator.effective_balance
decrease_balance(state, slashed_index, validator.effective_balance // MIN_SLASHING_PENALTY_QUOTIENT)
# Apply proposer and whistleblower rewards
proposer_index = get_beacon_proposer_index(state)
if whistleblower_index is None:
whistleblower_index = proposer_index
whistleblower_reward = Gwei(validator.effective_balance // WHISTLEBLOWER_REWARD_QUOTIENT)
proposer_reward = Gwei(whistleblower_reward // PROPOSER_REWARD_QUOTIENT)
increase_balance(state, proposer_index, proposer_reward)
increase_balance(state, whistleblower_index, whistleblower_reward - proposer_reward)
Genesis
Genesis state
Before the Ethereum 2.0 genesis has been triggered, and for every Ethereum 1.0 block, call initialize_beacon_state_from_eth1(eth1_block_hash, eth1_timestamp, deposits)
where:
eth1_block_hash
is the hash of the Ethereum 1.0 blocketh1_timestamp
is the Unix timestamp corresponding toeth1_block_hash
deposits
is the sequence of all deposits, ordered chronologically, up to the block with hasheth1_block_hash
The genesis state genesis_state
is the return value of calling initialize_beacon_state_from_eth1(eth1_block_hash, eth1_timestamp, deposits)
only if is_valid_genesis_state(genesis_state) is True
.
Implementations can choose to support different (more optimized) variations of the below initialization approach:
- Build the
genesis_state
from a stream of deposits by incrementally updating thestate.eth1_data.deposit_root
. - Compute deposit proofs for the final
state.eth1_data.deposit_root
, and process as a pre-determined collection.
Note: The two constants MIN_GENESIS_TIME
and MIN_GENESIS_ACTIVE_VALIDATOR_COUNT
have yet to be agreed upon by the community, and can be updated as necessary.
def initialize_beacon_state_from_eth1(eth1_block_hash: Hash,
eth1_timestamp: uint64,
deposits: Sequence[Deposit]) -> BeaconState:
state = BeaconState(
genesis_time=eth1_timestamp - eth1_timestamp % SECONDS_PER_DAY + 2 * SECONDS_PER_DAY,
eth1_data=Eth1Data(block_hash=eth1_block_hash, deposit_count=len(deposits)),
latest_block_header=BeaconBlockHeader(body_root=hash_tree_root(BeaconBlockBody())),
)
# Process deposits
leaves = list(map(lambda deposit: deposit.data, deposits))
for index, deposit in enumerate(deposits):
state.eth1_data.deposit_root = hash_tree_root(
List[DepositData, 2**DEPOSIT_CONTRACT_TREE_DEPTH](*leaves[:index + 1])
)
process_deposit(state, deposit)
# Process activations
for index, validator in enumerate(state.validators):
if state.balances[index] >= MAX_EFFECTIVE_BALANCE:
validator.activation_eligibility_epoch = GENESIS_EPOCH
validator.activation_epoch = GENESIS_EPOCH
# Populate compact_committees_roots
genesis_committee_root = get_compact_committees_root(state, GENESIS_EPOCH)
for index in range(EPOCHS_PER_HISTORICAL_VECTOR):
state.compact_committees_roots[index] = genesis_committee_root
return state
def is_valid_genesis_state(state: BeaconState) -> bool:
if state.genesis_time < MIN_GENESIS_TIME:
return False
elif len(get_active_validator_indices(state, GENESIS_EPOCH)) < MIN_GENESIS_ACTIVE_VALIDATOR_COUNT:
return False
else:
return True
Genesis block
Let genesis_block = BeaconBlock(state_root=hash_tree_root(genesis_state))
.
Beacon chain state transition function
The post-state corresponding to a pre-state state
and a block block
is defined as state_transition(state, block)
. State transitions that trigger an unhandled excpetion (e.g. a failed assert
or an out-of-range list access) are considered invalid.
def state_transition(state: BeaconState, block: BeaconBlock, validate_state_root: bool=False) -> BeaconState:
# Process slots (including those with no blocks) since block
process_slots(state, block.slot)
# Process block
process_block(state, block)
# Validate state root (`validate_state_root == True` in production)
if validate_state_root:
assert block.state_root == hash_tree_root(state)
# Return post-state
return state
def process_slots(state: BeaconState, slot: Slot) -> None:
assert state.slot <= slot
while state.slot < slot:
process_slot(state)
# Process epoch on the first slot of the next epoch
if (state.slot + 1) % SLOTS_PER_EPOCH == 0:
process_epoch(state)
state.slot += Slot(1)
def process_slot(state: BeaconState) -> None:
# Cache state root
previous_state_root = hash_tree_root(state)
state.state_roots[state.slot % SLOTS_PER_HISTORICAL_ROOT] = previous_state_root
# Cache latest block header state root
if state.latest_block_header.state_root == ZERO_HASH:
state.latest_block_header.state_root = previous_state_root
# Cache block root
previous_block_root = signing_root(state.latest_block_header)
state.block_roots[state.slot % SLOTS_PER_HISTORICAL_ROOT] = previous_block_root
Epoch processing
Note: The # @LabelHere
lines below are placeholders to show that code will be inserted here in a future phase.
def process_epoch(state: BeaconState) -> None:
process_justification_and_finalization(state)
process_crosslinks(state)
process_rewards_and_penalties(state)
process_registry_updates(state)
# @process_reveal_deadlines
# @process_challenge_deadlines
process_slashings(state)
process_final_updates(state)
# @after_process_final_updates
Helper functions
def get_total_active_balance(state: BeaconState) -> Gwei:
return get_total_balance(state, set(get_active_validator_indices(state, get_current_epoch(state))))
def get_matching_source_attestations(state: BeaconState, epoch: Epoch) -> Sequence[PendingAttestation]:
assert epoch in (get_previous_epoch(state), get_current_epoch(state))
return state.current_epoch_attestations if epoch == get_current_epoch(state) else state.previous_epoch_attestations
def get_matching_target_attestations(state: BeaconState, epoch: Epoch) -> Sequence[PendingAttestation]:
return [
a for a in get_matching_source_attestations(state, epoch)
if a.data.target.root == get_block_root(state, epoch)
]
def get_matching_head_attestations(state: BeaconState, epoch: Epoch) -> Sequence[PendingAttestation]:
return [
a for a in get_matching_source_attestations(state, epoch)
if a.data.beacon_block_root == get_block_root_at_slot(state, get_attestation_data_slot(state, a.data))
]
def get_unslashed_attesting_indices(state: BeaconState,
attestations: Sequence[PendingAttestation]) -> Set[ValidatorIndex]:
output = set() # type: Set[ValidatorIndex]
for a in attestations:
output = output.union(get_attesting_indices(state, a.data, a.aggregation_bits))
return set(filter(lambda index: not state.validators[index].slashed, list(output)))
def get_attesting_balance(state: BeaconState, attestations: Sequence[PendingAttestation]) -> Gwei:
return get_total_balance(state, get_unslashed_attesting_indices(state, attestations))
def get_winning_crosslink_and_attesting_indices(state: BeaconState,
epoch: Epoch,
shard: Shard) -> Tuple[Crosslink, Set[ValidatorIndex]]:
attestations = [a for a in get_matching_source_attestations(state, epoch) if a.data.crosslink.shard == shard]
crosslinks = list(filter(
lambda c: hash_tree_root(state.current_crosslinks[shard]) in (c.parent_root, hash_tree_root(c)),
[a.data.crosslink for a in attestations]
))
# Winning crosslink has the crosslink data root with the most balance voting for it (ties broken lexicographically)
winning_crosslink = max(crosslinks, key=lambda c: (
get_attesting_balance(state, [a for a in attestations if a.data.crosslink == c]), c.data_root
), default=Crosslink())
winning_attestations = [a for a in attestations if a.data.crosslink == winning_crosslink]
return winning_crosslink, get_unslashed_attesting_indices(state, winning_attestations)
Justification and finalization
def process_justification_and_finalization(state: BeaconState) -> None:
if get_current_epoch(state) <= GENESIS_EPOCH + 1:
return
previous_epoch = get_previous_epoch(state)
current_epoch = get_current_epoch(state)
old_previous_justified_checkpoint = state.previous_justified_checkpoint
old_current_justified_checkpoint = state.current_justified_checkpoint
# Process justifications
state.previous_justified_checkpoint = state.current_justified_checkpoint
state.justification_bits[1:] = state.justification_bits[:-1]
state.justification_bits[0] = 0b0
matching_target_attestations = get_matching_target_attestations(state, previous_epoch) # Previous epoch
if get_attesting_balance(state, matching_target_attestations) * 3 >= get_total_active_balance(state) * 2:
state.current_justified_checkpoint = Checkpoint(epoch=previous_epoch,
root=get_block_root(state, previous_epoch))
state.justification_bits[1] = 0b1
matching_target_attestations = get_matching_target_attestations(state, current_epoch) # Current epoch
if get_attesting_balance(state, matching_target_attestations) * 3 >= get_total_active_balance(state) * 2:
state.current_justified_checkpoint = Checkpoint(epoch=current_epoch,
root=get_block_root(state, current_epoch))
state.justification_bits[0] = 0b1
# Process finalizations
bits = state.justification_bits
# The 2nd/3rd/4th most recent epochs are justified, the 2nd using the 4th as source
if all(bits[1:4]) and old_previous_justified_checkpoint.epoch + 3 == current_epoch:
state.finalized_checkpoint = old_previous_justified_checkpoint
# The 2nd/3rd most recent epochs are justified, the 2nd using the 3rd as source
if all(bits[1:3]) and old_previous_justified_checkpoint.epoch + 2 == current_epoch:
state.finalized_checkpoint = old_previous_justified_checkpoint
# The 1st/2nd/3rd most recent epochs are justified, the 1st using the 3rd as source
if all(bits[0:3]) and old_current_justified_checkpoint.epoch + 2 == current_epoch:
state.finalized_checkpoint = old_current_justified_checkpoint
# The 1st/2nd most recent epochs are justified, the 1st using the 2nd as source
if all(bits[0:2]) and old_current_justified_checkpoint.epoch + 1 == current_epoch:
state.finalized_checkpoint = old_current_justified_checkpoint
Crosslinks
def process_crosslinks(state: BeaconState) -> None:
state.previous_crosslinks = [c for c in state.current_crosslinks]
for epoch in (get_previous_epoch(state), get_current_epoch(state)):
for offset in range(get_epoch_committee_count(state, epoch)):
shard = Shard((get_epoch_start_shard(state, epoch) + offset) % SHARD_COUNT)
crosslink_committee = set(get_crosslink_committee(state, epoch, shard))
winning_crosslink, attesting_indices = get_winning_crosslink_and_attesting_indices(state, epoch, shard)
if 3 * get_total_balance(state, attesting_indices) >= 2 * get_total_balance(state, crosslink_committee):
state.current_crosslinks[shard] = winning_crosslink
Rewards and penalties
def get_base_reward(state: BeaconState, index: ValidatorIndex) -> Gwei:
total_balance = get_total_active_balance(state)
effective_balance = state.validators[index].effective_balance
return Gwei(effective_balance * BASE_REWARD_FACTOR // integer_squareroot(total_balance) // BASE_REWARDS_PER_EPOCH)
def get_attestation_deltas(state: BeaconState) -> Tuple[Sequence[Gwei], Sequence[Gwei]]:
previous_epoch = get_previous_epoch(state)
total_balance = get_total_active_balance(state)
rewards = [Gwei(0) for _ in range(len(state.validators))]
penalties = [Gwei(0) for _ in range(len(state.validators))]
eligible_validator_indices = [
ValidatorIndex(index) for index, v in enumerate(state.validators)
if is_active_validator(v, previous_epoch) or (v.slashed and previous_epoch + 1 < v.withdrawable_epoch)
]
# Micro-incentives for matching FFG source, FFG target, and head
matching_source_attestations = get_matching_source_attestations(state, previous_epoch)
matching_target_attestations = get_matching_target_attestations(state, previous_epoch)
matching_head_attestations = get_matching_head_attestations(state, previous_epoch)
for attestations in (matching_source_attestations, matching_target_attestations, matching_head_attestations):
unslashed_attesting_indices = get_unslashed_attesting_indices(state, attestations)
attesting_balance = get_total_balance(state, unslashed_attesting_indices)
for index in eligible_validator_indices:
if index in unslashed_attesting_indices:
rewards[index] += get_base_reward(state, index) * attesting_balance // total_balance
else:
penalties[index] += get_base_reward(state, index)
# Proposer and inclusion delay micro-rewards
for index in get_unslashed_attesting_indices(state, matching_source_attestations):
index = ValidatorIndex(index)
attestation = min([
a for a in matching_source_attestations
if index in get_attesting_indices(state, a.data, a.aggregation_bits)
], key=lambda a: a.inclusion_delay)
proposer_reward = Gwei(get_base_reward(state, index) // PROPOSER_REWARD_QUOTIENT)
rewards[attestation.proposer_index] += proposer_reward
max_attester_reward = get_base_reward(state, index) - proposer_reward
rewards[index] += Gwei(max_attester_reward * MIN_ATTESTATION_INCLUSION_DELAY // attestation.inclusion_delay)
# Inactivity penalty
finality_delay = previous_epoch - state.finalized_checkpoint.epoch
if finality_delay > MIN_EPOCHS_TO_INACTIVITY_PENALTY:
matching_target_attesting_indices = get_unslashed_attesting_indices(state, matching_target_attestations)
for index in eligible_validator_indices:
index = ValidatorIndex(index)
penalties[index] += Gwei(BASE_REWARDS_PER_EPOCH * get_base_reward(state, index))
if index not in matching_target_attesting_indices:
penalties[index] += Gwei(
state.validators[index].effective_balance * finality_delay // INACTIVITY_PENALTY_QUOTIENT
)
return rewards, penalties
def get_crosslink_deltas(state: BeaconState) -> Tuple[Sequence[Gwei], Sequence[Gwei]]:
rewards = [Gwei(0) for _ in range(len(state.validators))]
penalties = [Gwei(0) for _ in range(len(state.validators))]
epoch = get_previous_epoch(state)
for offset in range(get_epoch_committee_count(state, epoch)):
shard = Shard((get_epoch_start_shard(state, epoch) + offset) % SHARD_COUNT)
crosslink_committee = set(get_crosslink_committee(state, epoch, shard))
winning_crosslink, attesting_indices = get_winning_crosslink_and_attesting_indices(state, epoch, shard)
attesting_balance = get_total_balance(state, attesting_indices)
committee_balance = get_total_balance(state, crosslink_committee)
for index in crosslink_committee:
base_reward = get_base_reward(state, index)
if index in attesting_indices:
rewards[index] += base_reward * attesting_balance // committee_balance
else:
penalties[index] += base_reward
return rewards, penalties
def process_rewards_and_penalties(state: BeaconState) -> None:
if get_current_epoch(state) == GENESIS_EPOCH:
return
rewards1, penalties1 = get_attestation_deltas(state)
rewards2, penalties2 = get_crosslink_deltas(state)
for index in range(len(state.validators)):
increase_balance(state, ValidatorIndex(index), rewards1[index] + rewards2[index])
decrease_balance(state, ValidatorIndex(index), penalties1[index] + penalties2[index])
Registry updates
def process_registry_updates(state: BeaconState) -> None:
# Process activation eligibility and ejections
for index, validator in enumerate(state.validators):
if (
validator.activation_eligibility_epoch == FAR_FUTURE_EPOCH and
validator.effective_balance == MAX_EFFECTIVE_BALANCE
):
validator.activation_eligibility_epoch = get_current_epoch(state)
if is_active_validator(validator, get_current_epoch(state)) and validator.effective_balance <= EJECTION_BALANCE:
initiate_validator_exit(state, ValidatorIndex(index))
# Queue validators eligible for activation and not dequeued for activation prior to finalized epoch
activation_queue = sorted([
index for index, validator in enumerate(state.validators) if
validator.activation_eligibility_epoch != FAR_FUTURE_EPOCH and
validator.activation_epoch >= get_delayed_activation_exit_epoch(state.finalized_checkpoint.epoch)
], key=lambda index: state.validators[index].activation_eligibility_epoch)
# Dequeued validators for activation up to churn limit (without resetting activation epoch)
for index in activation_queue[:get_churn_limit(state)]:
validator = state.validators[index]
if validator.activation_epoch == FAR_FUTURE_EPOCH:
validator.activation_epoch = get_delayed_activation_exit_epoch(get_current_epoch(state))
Slashings
def process_slashings(state: BeaconState) -> None:
epoch = get_current_epoch(state)
total_balance = get_total_active_balance(state)
for index, validator in enumerate(state.validators):
if validator.slashed and epoch + EPOCHS_PER_SLASHINGS_VECTOR // 2 == validator.withdrawable_epoch:
penalty = validator.effective_balance * min(sum(state.slashings) * 3, total_balance) // total_balance
decrease_balance(state, ValidatorIndex(index), penalty)
Final updates
def process_final_updates(state: BeaconState) -> None:
current_epoch = get_current_epoch(state)
next_epoch = Epoch(current_epoch + 1)
# Reset eth1 data votes
if (state.slot + 1) % SLOTS_PER_ETH1_VOTING_PERIOD == 0:
state.eth1_data_votes = []
# Update effective balances with hysteresis
for index, validator in enumerate(state.validators):
balance = state.balances[index]
HALF_INCREMENT = EFFECTIVE_BALANCE_INCREMENT // 2
if balance < validator.effective_balance or validator.effective_balance + 3 * HALF_INCREMENT < balance:
validator.effective_balance = min(balance - balance % EFFECTIVE_BALANCE_INCREMENT, MAX_EFFECTIVE_BALANCE)
# Update start shard
state.start_shard = Shard((state.start_shard + get_shard_delta(state, current_epoch)) % SHARD_COUNT)
# Set active index root
committee_root_position = (next_epoch + ACTIVATION_EXIT_DELAY) % EPOCHS_PER_HISTORICAL_VECTOR
state.compact_committees_roots[committee_root_position] = get_compact_committees_root(state, next_epoch)
# Reset slashings
state.slashings[next_epoch % EPOCHS_PER_SLASHINGS_VECTOR] = Gwei(0)
# Set randao mix
state.randao_mixes[next_epoch % EPOCHS_PER_HISTORICAL_VECTOR] = get_randao_mix(state, current_epoch)
# Set historical root accumulator
if next_epoch % (SLOTS_PER_HISTORICAL_ROOT // SLOTS_PER_EPOCH) == 0:
historical_batch = HistoricalBatch(
block_roots=state.block_roots,
state_roots=state.state_roots,
)
state.historical_roots.append(hash_tree_root(historical_batch))
# Rotate current/previous epoch attestations
state.previous_epoch_attestations = state.current_epoch_attestations
state.current_epoch_attestations = []
Block processing
def process_block(state: BeaconState, block: BeaconBlock) -> None:
process_block_header(state, block)
process_randao(state, block.body)
process_eth1_data(state, block.body)
process_operations(state, block.body)
Block header
def process_block_header(state: BeaconState, block: BeaconBlock) -> None:
# Verify that the slots match
assert block.slot == state.slot
# Verify that the parent matches
assert block.parent_root == signing_root(state.latest_block_header)
# Save current block as the new latest block
state.latest_block_header = BeaconBlockHeader(
slot=block.slot,
parent_root=block.parent_root,
state_root=ZERO_HASH, # Overwritten in next `process_slot` call
body_root=hash_tree_root(block.body),
)
# Verify proposer is not slashed
proposer = state.validators[get_beacon_proposer_index(state)]
assert not proposer.slashed
# Verify proposer signature
assert bls_verify(proposer.pubkey, signing_root(block), block.signature, get_domain(state, DOMAIN_BEACON_PROPOSER))
RANDAO
def process_randao(state: BeaconState, body: BeaconBlockBody) -> None:
epoch = get_current_epoch(state)
# Verify RANDAO reveal
proposer = state.validators[get_beacon_proposer_index(state)]
assert bls_verify(proposer.pubkey, hash_tree_root(epoch), body.randao_reveal, get_domain(state, DOMAIN_RANDAO))
# Mix in RANDAO reveal
mix = xor(get_randao_mix(state, epoch), hash(body.randao_reveal))
state.randao_mixes[epoch % EPOCHS_PER_HISTORICAL_VECTOR] = mix
Eth1 data
def process_eth1_data(state: BeaconState, body: BeaconBlockBody) -> None:
state.eth1_data_votes.append(body.eth1_data)
if state.eth1_data_votes.count(body.eth1_data) * 2 > SLOTS_PER_ETH1_VOTING_PERIOD:
state.eth1_data = body.eth1_data
Operations
def process_operations(state: BeaconState, body: BeaconBlockBody) -> None:
# Verify that outstanding deposits are processed up to the maximum number of deposits
assert len(body.deposits) == min(MAX_DEPOSITS, state.eth1_data.deposit_count - state.eth1_deposit_index)
# Verify that there are no duplicate transfers
assert len(body.transfers) == len(set(body.transfers))
all_operations = (
(body.proposer_slashings, process_proposer_slashing),
(body.attester_slashings, process_attester_slashing),
(body.attestations, process_attestation),
(body.deposits, process_deposit),
(body.voluntary_exits, process_voluntary_exit),
(body.transfers, process_transfer),
) # type: Sequence[Tuple[List, Callable]]
for operations, function in all_operations:
for operation in operations:
function(state, operation)
Proposer slashings
def process_proposer_slashing(state: BeaconState, proposer_slashing: ProposerSlashing) -> None:
"""
Process ``ProposerSlashing`` operation.
"""
proposer = state.validators[proposer_slashing.proposer_index]
# Verify that the epoch is the same
assert slot_to_epoch(proposer_slashing.header_1.slot) == slot_to_epoch(proposer_slashing.header_2.slot)
# But the headers are different
assert proposer_slashing.header_1 != proposer_slashing.header_2
# Check proposer is slashable
assert is_slashable_validator(proposer, get_current_epoch(state))
# Signatures are valid
for header in (proposer_slashing.header_1, proposer_slashing.header_2):
domain = get_domain(state, DOMAIN_BEACON_PROPOSER, slot_to_epoch(header.slot))
assert bls_verify(proposer.pubkey, signing_root(header), header.signature, domain)
slash_validator(state, proposer_slashing.proposer_index)
Attester slashings
def process_attester_slashing(state: BeaconState, attester_slashing: AttesterSlashing) -> None:
"""
Process ``AttesterSlashing`` operation.
"""
attestation_1 = attester_slashing.attestation_1
attestation_2 = attester_slashing.attestation_2
assert is_slashable_attestation_data(attestation_1.data, attestation_2.data)
validate_indexed_attestation(state, attestation_1)
validate_indexed_attestation(state, attestation_2)
slashed_any = False
attesting_indices_1 = attestation_1.custody_bit_0_indices + attestation_1.custody_bit_1_indices
attesting_indices_2 = attestation_2.custody_bit_0_indices + attestation_2.custody_bit_1_indices
for index in sorted(set(attesting_indices_1).intersection(attesting_indices_2)):
if is_slashable_validator(state.validators[index], get_current_epoch(state)):
slash_validator(state, index)
slashed_any = True
assert slashed_any
Attestations
def process_attestation(state: BeaconState, attestation: Attestation) -> None:
"""
Process ``Attestation`` operation.
"""
data = attestation.data
assert data.crosslink.shard < SHARD_COUNT
assert data.target.epoch in (get_previous_epoch(state), get_current_epoch(state))
attestation_slot = get_attestation_data_slot(state, data)
assert attestation_slot + MIN_ATTESTATION_INCLUSION_DELAY <= state.slot <= attestation_slot + SLOTS_PER_EPOCH
pending_attestation = PendingAttestation(
data=data,
aggregation_bits=attestation.aggregation_bits,
inclusion_delay=state.slot - attestation_slot,
proposer_index=get_beacon_proposer_index(state),
)
if data.target.epoch == get_current_epoch(state):
assert data.source == state.current_justified_checkpoint
parent_crosslink = state.current_crosslinks[data.crosslink.shard]
state.current_epoch_attestations.append(pending_attestation)
else:
assert data.source == state.previous_justified_checkpoint
parent_crosslink = state.previous_crosslinks[data.crosslink.shard]
state.previous_epoch_attestations.append(pending_attestation)
# Check crosslink against expected parent crosslink
assert data.crosslink.parent_root == hash_tree_root(parent_crosslink)
assert data.crosslink.start_epoch == parent_crosslink.end_epoch
assert data.crosslink.end_epoch == min(data.target.epoch, parent_crosslink.end_epoch + MAX_EPOCHS_PER_CROSSLINK)
assert data.crosslink.data_root == ZERO_HASH # [to be removed in phase 1]
# Check signature
validate_indexed_attestation(state, convert_to_indexed(state, attestation))
Deposits
def process_deposit(state: BeaconState, deposit: Deposit) -> None:
"""
Process an Eth1 deposit, registering a validator or increasing its balance.
"""
# Verify the Merkle branch
assert verify_merkle_branch(
leaf=hash_tree_root(deposit.data),
proof=deposit.proof,
depth=DEPOSIT_CONTRACT_TREE_DEPTH + 1, # add 1 for the SSZ length mix-in
index=state.eth1_deposit_index,
root=state.eth1_data.deposit_root,
)
# Deposits must be processed in order
state.eth1_deposit_index += 1
pubkey = deposit.data.pubkey
amount = deposit.data.amount
validator_pubkeys = [v.pubkey for v in state.validators]
if pubkey not in validator_pubkeys:
# Verify the deposit signature (proof of possession).
# Invalid signatures are allowed by the deposit contract,
# and hence included on-chain, but must not be processed.
# Note: Deposits are valid across forks, hence the deposit domain is retrieved directly from `bls_domain`
if not bls_verify(
pubkey, signing_root(deposit.data), deposit.data.signature, bls_domain(DOMAIN_DEPOSIT)
):
return
# Add validator and balance entries
state.validators.append(Validator(
pubkey=pubkey,
withdrawal_credentials=deposit.data.withdrawal_credentials,
activation_eligibility_epoch=FAR_FUTURE_EPOCH,
activation_epoch=FAR_FUTURE_EPOCH,
exit_epoch=FAR_FUTURE_EPOCH,
withdrawable_epoch=FAR_FUTURE_EPOCH,
effective_balance=min(amount - amount % EFFECTIVE_BALANCE_INCREMENT, MAX_EFFECTIVE_BALANCE)
))
state.balances.append(amount)
else:
# Increase balance by deposit amount
index = ValidatorIndex(validator_pubkeys.index(pubkey))
increase_balance(state, index, amount)
Voluntary exits
def process_voluntary_exit(state: BeaconState, exit: VoluntaryExit) -> None:
"""
Process ``VoluntaryExit`` operation.
"""
validator = state.validators[exit.validator_index]
# Verify the validator is active
assert is_active_validator(validator, get_current_epoch(state))
# Verify the validator has not yet exited
assert validator.exit_epoch == FAR_FUTURE_EPOCH
# Exits must specify an epoch when they become valid; they are not valid before then
assert get_current_epoch(state) >= exit.epoch
# Verify the validator has been active long enough
assert get_current_epoch(state) >= validator.activation_epoch + PERSISTENT_COMMITTEE_PERIOD
# Verify signature
domain = get_domain(state, DOMAIN_VOLUNTARY_EXIT, exit.epoch)
assert bls_verify(validator.pubkey, signing_root(exit), exit.signature, domain)
# Initiate exit
initiate_validator_exit(state, exit.validator_index)
Transfers
def process_transfer(state: BeaconState, transfer: Transfer) -> None:
"""
Process ``Transfer`` operation.
"""
# Verify the balance the covers amount and fee (with overflow protection)
assert state.balances[transfer.sender] >= max(transfer.amount + transfer.fee, transfer.amount, transfer.fee)
# A transfer is valid in only one slot
assert state.slot == transfer.slot
# Sender must satisfy at least one of the following conditions in the parenthesis:
assert (
# * Has not been activated
state.validators[transfer.sender].activation_eligibility_epoch == FAR_FUTURE_EPOCH or
# * Is withdrawable
get_current_epoch(state) >= state.validators[transfer.sender].withdrawable_epoch or
# * Balance after transfer is more than the effective balance threshold
transfer.amount + transfer.fee + MAX_EFFECTIVE_BALANCE <= state.balances[transfer.sender]
)
# Verify that the pubkey is valid
assert (
state.validators[transfer.sender].withdrawal_credentials ==
int_to_bytes(BLS_WITHDRAWAL_PREFIX, length=1) + hash(transfer.pubkey)[1:]
)
# Verify that the signature is valid
assert bls_verify(transfer.pubkey, signing_root(transfer), transfer.signature, get_domain(state, DOMAIN_TRANSFER))
# Process the transfer
decrease_balance(state, transfer.sender, transfer.amount + transfer.fee)
increase_balance(state, transfer.recipient, transfer.amount)
increase_balance(state, get_beacon_proposer_index(state), transfer.fee)
# Verify balances are not dust
assert not (0 < state.balances[transfer.sender] < MIN_DEPOSIT_AMOUNT)
assert not (0 < state.balances[transfer.recipient] < MIN_DEPOSIT_AMOUNT)