29 KiB
Ethereum 2.0 Phase 1 -- Custody Game
Notice: This document is a work-in-progress for researchers and implementers.
Table of contents
- Introduction
- Terminology
- Constants
- Data structures
- Helpers
- Per-block processing
- Per-epoch processing
Introduction
This document details the beacon chain additions and changes in Phase 1 of Ethereum 2.0 to support the shard data custody game, building upon the Phase 0 specification.
Terminology
- Custody game—
- Custody period—
- Custody chunk—
- Custody chunk bit—
- Custody chunk challenge—
- Custody bit—
- Custody bit challenge—
- Custody key—
- Custody key reveal—
- Custody key mask—
- Custody response—
- Custody response deadline—
Constants
Misc
Name | Value |
---|---|
BLS12_381_Q |
4002409555221667393417789825735904156556882819939007885332058136124031650490837864442687629129015664037894272559787 |
MINOR_REWARD_QUOTIENT |
2**8 (= 256) |
MAX_EPOCHS_PER_CROSSLINK |
2**6 (= 64) |
Custody game parameters
Name | Value |
---|---|
BYTES_PER_SHARD_BLOCK |
2**14 (= 16,384) |
BYTES_PER_CUSTODY_CHUNK |
2**9 (= 512) |
BYTES_PER_CUSTODY_SUBCHUNK |
48 |
CHUNKS_PER_EPOCH |
2 * BYTES_PER_SHARD_BLOCK * SLOTS_PER_EPOCH // BYTES_PER_CUSTODY_CHUNK |
MAX_CUSTODY_CHUNKS |
MAX_EPOCHS_PER_CROSSLINK * CHUNKS_PER_EPOCH |
CUSTODY_DATA_DEPTH |
ceillog2(MAX_CUSTODY_CHUNKS) + 1 |
CUSTODY_CHUNK_BIT_DEPTH |
ceillog2(MAX_EPOCHS_PER_CROSSLINK * CHUNKS_PER_EPOCH // 256) + 2 |
Time parameters
Name | Value | Unit | Duration |
---|---|---|---|
MAX_CHUNK_CHALLENGE_DELAY |
2**11 (= 2,048) |
epochs | ~9 days |
CUSTODY_RESPONSE_DEADLINE |
2**14 (= 16,384) |
epochs | ~73 days |
RANDAO_PENALTY_EPOCHS |
2**1 (= 2) |
epochs | 12.8 minutes |
EARLY_DERIVED_SECRET_PENALTY_MAX_FUTURE_EPOCHS |
2**14 |
epochs | ~73 days |
EPOCHS_PER_CUSTODY_PERIOD |
2**11 (= 2,048) |
epochs | ~9 days |
CUSTODY_PERIOD_TO_RANDAO_PADDING |
2**11 (= 2,048) |
epochs | ~9 days |
MAX_REVEAL_LATENESS_DECREMENT |
2**7 (= 128) |
epochs | ~14 hours |
Max operations per block
Name | Value |
---|---|
MAX_CUSTODY_KEY_REVEALS |
2**4 (= 16) |
MAX_EARLY_DERIVED_SECRET_REVEALS |
1 |
MAX_CUSTODY_CHUNK_CHALLENGES |
2**2 (= 4) |
MAX_CUSTODY_BIT_CHALLENGES |
2**2 (= 4) |
MAX_CUSTODY_RESPONSES |
2**5 (= 32) |
Reward and penalty quotients
Name | Value |
---|---|
EARLY_DERIVED_SECRET_REVEAL_SLOT_REWARD_MULTIPLE |
2**1 (= 2) |
Signature domain types
The following types are defined, mapping into DomainType
(little endian):
Name | Value |
---|---|
DOMAIN_CUSTODY_BIT_CHALLENGE |
DomainType('0x06000000') |
TODO PLACEHOLDER
Name | Value |
---|---|
PLACEHOLDER |
2**32 |
Data structures
Custody objects
CustodyChunkChallenge
class CustodyChunkChallenge(Container):
responder_index: ValidatorIndex
attestation: Attestation
chunk_index: uint64
CustodyBitChallenge
class CustodyBitChallenge(Container):
responder_index: ValidatorIndex
attestation: Attestation
challenger_index: ValidatorIndex
responder_key: BLSSignature
chunk_bits: Bitlist[MAX_CUSTODY_CHUNKS]
signature: BLSSignature
CustodyChunkChallengeRecord
class CustodyChunkChallengeRecord(Container):
challenge_index: uint64
challenger_index: ValidatorIndex
responder_index: ValidatorIndex
inclusion_epoch: Epoch
data_root: Root
depth: uint64
chunk_index: uint64
CustodyBitChallengeRecord
class CustodyBitChallengeRecord(Container):
challenge_index: uint64
challenger_index: ValidatorIndex
responder_index: ValidatorIndex
inclusion_epoch: Epoch
data_root: Root
chunk_count: uint64
chunk_bits_merkle_root: Root
responder_key: BLSSignature
CustodyResponse
class CustodyResponse(Container):
challenge_index: uint64
chunk_index: uint64
chunk: ByteVector[BYTES_PER_CUSTODY_CHUNK]
data_branch: List[Bytes32, CUSTODY_DATA_DEPTH]
chunk_bits_branch: List[Bytes32, CUSTODY_CHUNK_BIT_DEPTH]
chunk_bits_leaf: Bitvector[256]
New beacon operations
CustodyKeyReveal
class CustodyKeyReveal(Container):
# Index of the validator whose key is being revealed
revealer_index: ValidatorIndex
# Reveal (masked signature)
reveal: BLSSignature
EarlyDerivedSecretReveal
Represents an early (punishable) reveal of one of the derived secrets, where derived secrets are RANDAO reveals and custody reveals (both are part of the same domain).
class EarlyDerivedSecretReveal(Container):
# Index of the validator whose key is being revealed
revealed_index: ValidatorIndex
# RANDAO epoch of the key that is being revealed
epoch: Epoch
# Reveal (masked signature)
reveal: BLSSignature
# Index of the validator who revealed (whistleblower)
masker_index: ValidatorIndex
# Mask used to hide the actual reveal signature (prevent reveal from being stolen)
mask: Bytes32
Phase 0 container updates
Add the following fields to the end of the specified container objects. Fields with underlying type uint64
are initialized to 0
and list fields are initialized to []
.
Validator
class Validator(Container):
# next_custody_secret_to_reveal is initialised to the custody period
# (of the particular validator) in which the validator is activated
# = get_custody_period_for_validator(...)
next_custody_secret_to_reveal: uint64
max_reveal_lateness: Epoch
BeaconState
class BeaconState(Container):
custody_chunk_challenge_records: List[CustodyChunkChallengeRecord, PLACEHOLDER]
custody_bit_challenge_records: List[CustodyBitChallengeRecord, PLACEHOLDER]
custody_challenge_index: uint64
# Future derived secrets already exposed; contains the indices of the exposed validator
# at RANDAO reveal period % EARLY_DERIVED_SECRET_PENALTY_MAX_FUTURE_EPOCHS
exposed_derived_secrets: Vector[List[ValidatorIndex, PLACEHOLDER],
EARLY_DERIVED_SECRET_PENALTY_MAX_FUTURE_EPOCHS]
BeaconBlockBody
class BeaconBlockBody(Container):
custody_chunk_challenges: List[CustodyChunkChallenge, PLACEHOLDER]
custody_bit_challenges: List[CustodyBitChallenge, PLACEHOLDER]
custody_responses: List[CustodyResponse, PLACEHOLDER]
custody_key_reveals: List[CustodyKeyReveal, PLACEHOLDER]
early_derived_secret_reveals: List[EarlyDerivedSecretReveal, PLACEHOLDER]
Helpers
ceillog2
def ceillog2(x: uint64) -> int:
return (x - 1).bit_length()
is_valid_merkle_branch_with_mixin
def is_valid_merkle_branch_with_mixin(leaf: Bytes32,
branch: Sequence[Bytes32],
depth: uint64,
index: uint64,
root: Root,
mixin: uint64) -> bool:
value = leaf
for i in range(depth):
if index // (2**i) % 2:
value = hash(branch[i] + value)
else:
value = hash(value + branch[i])
value = hash(value + mixin.to_bytes(32, "little"))
return value == root
get_crosslink_chunk_count
def get_custody_chunk_count(crosslink: Crosslink) -> int:
crosslink_length = min(MAX_EPOCHS_PER_CROSSLINK, crosslink.end_epoch - crosslink.start_epoch)
return crosslink_length * CHUNKS_PER_EPOCH
legendre_bit
Returns the Legendre symbol (a/q)
normalizes as a bit (i.e. ((a/q) + 1) // 2
). In a production implementation, a well-optimized library (e.g. GMP) should be used for this.
def legendre_bit(a: int, q: int) -> int:
if a >= q:
return legendre_bit(a % q, q)
if a == 0:
return 0
assert(q > a > 0 and q % 2 == 1)
t = 1
n = q
while a != 0:
while a % 2 == 0:
a //= 2
r = n % 8
if r == 3 or r == 5:
t = -t
a, n = n, a
if a % 4 == n % 4 == 3:
t = -t
a %= n
if n == 1:
return (t + 1) // 2
else:
return 0
custody_subchunkify
Given one proof of custody chunk, returns the proof of custody subchunks of the correct sizes.
def custody_subchunkify(bytez: bytes) -> Sequence[bytes]:
bytez += b'\x00' * (-len(bytez) % BYTES_PER_CUSTODY_SUBCHUNK)
return [bytez[i:i + BYTES_PER_CUSTODY_SUBCHUNK]
for i in range(0, len(bytez), BYTES_PER_CUSTODY_SUBCHUNK)]
get_custody_chunk_bit
def get_custody_chunk_bit(key: BLSSignature, chunk: bytes) -> bool:
full_G2_element = bls.signature_to_G2(key)
s = full_G2_element[0].coeffs
bits = [legendre_bit((i + 1) * s[i % 2] + int.from_bytes(subchunk, "little"), BLS12_381_Q)
for i, subchunk in enumerate(custody_subchunkify(chunk))]
return bool(sum(bits) % 2)
get_chunk_bits_root
def get_chunk_bits_root(chunk_bits: Bitlist[MAX_CUSTODY_CHUNKS]) -> bit:
aggregated_bits = 0
for i, b in enumerate(chunk_bits):
aggregated_bits += 2**i * b
return legendre_bit(aggregated_bits, BLS12_381_Q)
get_randao_epoch_for_custody_period
def get_randao_epoch_for_custody_period(period: uint64, validator_index: ValidatorIndex) -> Epoch:
next_period_start = (period + 1) * EPOCHS_PER_CUSTODY_PERIOD - validator_index % EPOCHS_PER_CUSTODY_PERIOD
return Epoch(next_period_start + CUSTODY_PERIOD_TO_RANDAO_PADDING)
get_custody_period_for_validator
def get_custody_period_for_validator(state: BeaconState, validator_index: ValidatorIndex, epoch: Epoch=None) -> int:
'''
Return the reveal period for a given validator.
'''
epoch = get_current_epoch(state) if epoch is None else epoch
return (epoch + validator_index % EPOCHS_PER_CUSTODY_PERIOD) // EPOCHS_PER_CUSTODY_PERIOD
replace_empty_or_append
def replace_empty_or_append(list: MutableSequence[Any], new_element: Any) -> int:
for i in range(len(list)):
if is_zero(list[i]):
list[i] = new_element
return i
list.append(new_element)
return len(list) - 1
Per-block processing
Operations
Add the following operations to the per-block processing, in the order given below and after all other operations in Phase 0.
Custody key reveals
Verify that len(block.body.custody_key_reveals) <= MAX_CUSTODY_KEY_REVEALS
.
For each reveal
in block.body.custody_key_reveals
, run the following function:
def process_custody_key_reveal(state: BeaconState, reveal: CustodyKeyReveal) -> None:
"""
Process ``CustodyKeyReveal`` operation.
Note that this function mutates ``state``.
"""
revealer = state.validators[reveal.revealer_index]
epoch_to_sign = get_randao_epoch_for_custody_period(revealer.next_custody_secret_to_reveal, reveal.revealer_index)
assert revealer.next_custody_secret_to_reveal < get_custody_period_for_validator(state, reveal.revealer_index)
# Revealed validator is active or exited, but not withdrawn
assert is_slashable_validator(revealer, get_current_epoch(state))
# Verify signature
domain = get_domain(state, DOMAIN_RANDAO, epoch_to_sign)
signing_root = compute_signing_root(epoch_to_sign, domain)
assert bls.Verify(revealer.pubkey, signing_root, reveal.reveal)
# Decrement max reveal lateness if response is timely
if epoch_to_sign + EPOCHS_PER_CUSTODY_PERIOD >= get_current_epoch(state):
if revealer.max_reveal_lateness >= MAX_REVEAL_LATENESS_DECREMENT:
revealer.max_reveal_lateness -= MAX_REVEAL_LATENESS_DECREMENT
else:
revealer.max_reveal_lateness = 0
else:
revealer.max_reveal_lateness = max(
revealer.max_reveal_lateness,
get_current_epoch(state) - epoch_to_sign - EPOCHS_PER_CUSTODY_PERIOD
)
# Process reveal
revealer.next_custody_secret_to_reveal += 1
# Reward Block Preposer
proposer_index = get_beacon_proposer_index(state)
increase_balance(
state,
proposer_index,
Gwei(get_base_reward(state, reveal.revealer_index) // MINOR_REWARD_QUOTIENT)
)
Early derived secret reveals
Verify that len(block.body.early_derived_secret_reveals) <= MAX_EARLY_DERIVED_SECRET_REVEALS
.
For each reveal
in block.body.early_derived_secret_reveals
, run the following function:
def process_early_derived_secret_reveal(state: BeaconState, reveal: EarlyDerivedSecretReveal) -> None:
"""
Process ``EarlyDerivedSecretReveal`` operation.
Note that this function mutates ``state``.
"""
revealed_validator = state.validators[reveal.revealed_index]
derived_secret_location = reveal.epoch % EARLY_DERIVED_SECRET_PENALTY_MAX_FUTURE_EPOCHS
assert reveal.epoch >= get_current_epoch(state) + RANDAO_PENALTY_EPOCHS
assert reveal.epoch < get_current_epoch(state) + EARLY_DERIVED_SECRET_PENALTY_MAX_FUTURE_EPOCHS
assert not revealed_validator.slashed
assert reveal.revealed_index not in state.exposed_derived_secrets[derived_secret_location]
# Verify signature correctness
masker = state.validators[reveal.masker_index]
pubkeys = [revealed_validator.pubkey, masker.pubkey]
domain = get_domain(state, DOMAIN_RANDAO, reveal.epoch)
signing_roots = [compute_signing_root(root, domain) for root in [hash_tree_root(reveal.epoch), reveal.mask]]
assert bls.AggregateVerify(zip(pubkeys, signing_roots), reveal.reveal)
if reveal.epoch >= get_current_epoch(state) + CUSTODY_PERIOD_TO_RANDAO_PADDING:
# Full slashing when the secret was revealed so early it may be a valid custody
# round key
slash_validator(state, reveal.revealed_index, reveal.masker_index)
else:
# Only a small penalty proportional to proposer slot reward for RANDAO reveal
# that does not interfere with the custody period
# The penalty is proportional to the max proposer reward
# Calculate penalty
max_proposer_slot_reward = (
get_base_reward(state, reveal.revealed_index)
* SLOTS_PER_EPOCH
// len(get_active_validator_indices(state, get_current_epoch(state)))
// PROPOSER_REWARD_QUOTIENT
)
penalty = Gwei(
max_proposer_slot_reward
* EARLY_DERIVED_SECRET_REVEAL_SLOT_REWARD_MULTIPLE
* (len(state.exposed_derived_secrets[derived_secret_location]) + 1)
)
# Apply penalty
proposer_index = get_beacon_proposer_index(state)
whistleblower_index = reveal.masker_index
whistleblowing_reward = Gwei(penalty // WHISTLEBLOWER_REWARD_QUOTIENT)
proposer_reward = Gwei(whistleblowing_reward // PROPOSER_REWARD_QUOTIENT)
increase_balance(state, proposer_index, proposer_reward)
increase_balance(state, whistleblower_index, whistleblowing_reward - proposer_reward)
decrease_balance(state, reveal.revealed_index, penalty)
# Mark this derived secret as exposed so validator cannot be punished repeatedly
state.exposed_derived_secrets[derived_secret_location].append(reveal.revealed_index)
Chunk challenges
Verify that len(block.body.custody_chunk_challenges) <= MAX_CUSTODY_CHUNK_CHALLENGES
.
For each challenge
in block.body.custody_chunk_challenges
, run the following function:
def process_chunk_challenge(state: BeaconState, challenge: CustodyChunkChallenge) -> None:
# Verify the attestation
assert is_valid_indexed_attestation(state, get_indexed_attestation(state, challenge.attestation))
# Verify it is not too late to challenge
assert (compute_epoch_at_slot(challenge.attestation.data.slot)
>= get_current_epoch(state) - MAX_CHUNK_CHALLENGE_DELAY)
responder = state.validators[challenge.responder_index]
assert responder.exit_epoch >= get_current_epoch(state) - MAX_CHUNK_CHALLENGE_DELAY
# Verify the responder participated in the attestation
attesters = get_attesting_indices(state, challenge.attestation.data, challenge.attestation.aggregation_bits)
assert challenge.responder_index in attesters
# Verify the challenge is not a duplicate
for record in state.custody_chunk_challenge_records:
assert (
record.data_root != challenge.attestation.data.crosslink.data_root or
record.chunk_index != challenge.chunk_index
)
# Verify depth
depth = ceillog2(get_custody_chunk_count(challenge.attestation.data.crosslink))
assert challenge.chunk_index < 2**depth
# Add new chunk challenge record
new_record = CustodyChunkChallengeRecord(
challenge_index=state.custody_challenge_index,
challenger_index=get_beacon_proposer_index(state),
responder_index=challenge.responder_index,
inclusion_epoch=get_current_epoch(state),
data_root=challenge.attestation.data.crosslink.data_root,
depth=depth,
chunk_index=challenge.chunk_index,
)
replace_empty_or_append(state.custody_chunk_challenge_records, new_record)
state.custody_challenge_index += 1
# Postpone responder withdrawability
responder.withdrawable_epoch = FAR_FUTURE_EPOCH
Bit challenges
Verify that len(block.body.custody_bit_challenges) <= MAX_CUSTODY_BIT_CHALLENGES
.
For each challenge
in block.body.custody_bit_challenges
, run the following function:
def process_bit_challenge(state: BeaconState, challenge: CustodyBitChallenge) -> None:
attestation = challenge.attestation
epoch = attestation.data.target.epoch
shard = attestation.data.crosslink.shard
# Verify challenge signature
challenger = state.validators[challenge.challenger_index]
domain = get_domain(state, DOMAIN_CUSTODY_BIT_CHALLENGE, get_current_epoch(state))
# TODO incorrect hash-tree-root, but this changes with phase 1 PR #1483
assert bls.Verify(challenger.pubkey, compute_signing_root(challenge, domain), challenge.signature)
# Verify challenger is slashable
assert is_slashable_validator(challenger, get_current_epoch(state))
# Verify attestation
assert is_valid_indexed_attestation(state, get_indexed_attestation(state, attestation))
# Verify attestation is eligible for challenging
responder = state.validators[challenge.responder_index]
assert get_current_epoch(state) <= get_randao_epoch_for_custody_period(
get_custody_period_for_validator(state, challenge.responder_index, epoch),
challenge.responder_index
) + 2 * EPOCHS_PER_CUSTODY_PERIOD + responder.max_reveal_lateness
# Verify the responder participated in the attestation
attesters = get_attesting_indices(state, attestation.data, attestation.aggregation_bits)
assert challenge.responder_index in attesters
# Verifier challenger is not already challenging
for record in state.custody_bit_challenge_records:
assert record.challenger_index != challenge.challenger_index
# Verify the responder custody key
epoch_to_sign = get_randao_epoch_for_custody_period(
get_custody_period_for_validator(state, challenge.responder_index, epoch),
challenge.responder_index,
)
domain = get_domain(state, DOMAIN_RANDAO, epoch_to_sign)
assert bls.Verify(responder.pubkey, compute_signing_root(epoch_to_sign, domain), challenge.responder_key)
# Verify the chunk count
chunk_count = get_custody_chunk_count(attestation.data.crosslink)
assert chunk_count == len(challenge.chunk_bits)
# Verify custody bit is incorrect
committee = get_beacon_committee(state, epoch, shard)
custody_bit = attestation.custody_bits[committee.index(challenge.responder_index)]
assert custody_bit != get_chunk_bits_root(challenge.chunk_bits)
# Add new bit challenge record
new_record = CustodyBitChallengeRecord(
challenge_index=state.custody_challenge_index,
challenger_index=challenge.challenger_index,
responder_index=challenge.responder_index,
inclusion_epoch=get_current_epoch(state),
data_root=attestation.data.crosslink.data_root,
chunk_count=chunk_count,
chunk_bits_merkle_root=hash_tree_root(challenge.chunk_bits),
responder_key=challenge.responder_key,
)
replace_empty_or_append(state.custody_bit_challenge_records, new_record)
state.custody_challenge_index += 1
# Postpone responder withdrawability
responder.withdrawable_epoch = FAR_FUTURE_EPOCH
Custody responses
Verify that len(block.body.custody_responses) <= MAX_CUSTODY_RESPONSES
.
For each response
in block.body.custody_responses
, run the following function:
def process_custody_response(state: BeaconState, response: CustodyResponse) -> None:
chunk_challenge = next((record for record in state.custody_chunk_challenge_records
if record.challenge_index == response.challenge_index), None)
if chunk_challenge is not None:
return process_chunk_challenge_response(state, response, chunk_challenge)
bit_challenge = next((record for record in state.custody_bit_challenge_records
if record.challenge_index == response.challenge_index), None)
if bit_challenge is not None:
return process_bit_challenge_response(state, response, bit_challenge)
assert False
def process_chunk_challenge_response(state: BeaconState,
response: CustodyResponse,
challenge: CustodyChunkChallengeRecord) -> None:
# Verify chunk index
assert response.chunk_index == challenge.chunk_index
# Verify bit challenge data is null
assert response.chunk_bits_branch == [] and response.chunk_bits_leaf == Bytes32()
# Verify minimum delay
assert get_current_epoch(state) >= challenge.inclusion_epoch + MAX_SEED_LOOKAHEAD
# Verify the chunk matches the crosslink data root
assert is_valid_merkle_branch(
leaf=hash_tree_root(response.chunk),
branch=response.data_branch,
depth=challenge.depth,
index=response.chunk_index,
root=challenge.data_root,
)
# Clear the challenge
records = state.custody_chunk_challenge_records
records[records.index(challenge)] = CustodyChunkChallengeRecord()
# Reward the proposer
proposer_index = get_beacon_proposer_index(state)
increase_balance(state, proposer_index, Gwei(get_base_reward(state, proposer_index) // MINOR_REWARD_QUOTIENT))
def process_bit_challenge_response(state: BeaconState,
response: CustodyResponse,
challenge: CustodyBitChallengeRecord) -> None:
# Verify chunk index
assert response.chunk_index < challenge.chunk_count
# Verify responder has not been slashed
responder = state.validators[challenge.responder_index]
assert not responder.slashed
# Verify the chunk matches the crosslink data root
assert is_valid_merkle_branch(
leaf=hash_tree_root(response.chunk),
branch=response.data_branch,
depth=ceillog2(challenge.chunk_count),
index=response.chunk_index,
root=challenge.data_root,
)
# Verify the chunk bit leaf matches the challenge data
assert is_valid_merkle_branch_with_mixin(
leaf=hash_tree_root(response.chunk_bits_leaf),
branch=response.chunk_bits_branch,
depth=ceillog2(MAX_CUSTODY_CHUNKS // 256),
index=response.chunk_index // 256,
root=challenge.chunk_bits_merkle_root,
mixin=challenge.chunk_count,
)
# Verify the chunk bit does not match the challenge chunk bit
assert (get_custody_chunk_bit(challenge.responder_key, response.chunk)
!= response.chunk_bits_leaf[response.chunk_index % 256])
# Clear the challenge
records = state.custody_bit_challenge_records
records[records.index(challenge)] = CustodyBitChallengeRecord()
# Slash challenger
slash_validator(state, challenge.challenger_index, challenge.responder_index)
Per-epoch processing
Handling of custody-related deadlines
Run process_reveal_deadlines(state)
immediately after process_registry_updates(state)
:
# begin insert @process_reveal_deadlines
process_reveal_deadlines(state)
# end insert @process_reveal_deadlines
def process_reveal_deadlines(state: BeaconState) -> None:
for index, validator in enumerate(state.validators):
deadline = validator.next_custody_secret_to_reveal + (CUSTODY_RESPONSE_DEADLINE // EPOCHS_PER_CUSTODY_PERIOD)
if get_custody_period_for_validator(state, ValidatorIndex(index)) > deadline:
slash_validator(state, ValidatorIndex(index))
Run process_challenge_deadlines(state)
immediately after process_reveal_deadlines(state)
:
# begin insert @process_challenge_deadlines
process_challenge_deadlines(state)
# end insert @process_challenge_deadlines
def process_challenge_deadlines(state: BeaconState) -> None:
for custody_chunk_challenge in state.custody_chunk_challenge_records:
if get_current_epoch(state) > custody_chunk_challenge.inclusion_epoch + CUSTODY_RESPONSE_DEADLINE:
slash_validator(state, custody_chunk_challenge.responder_index, custody_chunk_challenge.challenger_index)
records = state.custody_chunk_challenge
records[records.index(custody_chunk_challenge)] = CustodyChunkChallengeRecord()
for custody_bit_challenge in state.custody_bit_challenge_records:
if get_current_epoch(state) > custody_bit_challenge.inclusion_epoch + CUSTODY_RESPONSE_DEADLINE:
slash_validator(state, custody_bit_challenge.responder_index, custody_bit_challenge.challenger_index)
records = state.custody_bit_challenge_records
records[records.index(custody_bit_challenge)] = CustodyBitChallengeRecord()
Append this to process_final_updates(state)
:
# begin insert @after_process_final_updates
after_process_final_updates(state)
# end insert @after_process_final_updates
def after_process_final_updates(state: BeaconState) -> None:
current_epoch = get_current_epoch(state)
# Clean up exposed RANDAO key reveals
state.exposed_derived_secrets[current_epoch % EARLY_DERIVED_SECRET_PENALTY_MAX_FUTURE_EPOCHS] = []
# Reset withdrawable epochs if challenge records are empty
records = state.custody_chunk_challenge_records + state.custody_bit_challenge_records
validator_indices_in_records = set(
[record.challenger_index for record in records] + [record.responder_index for record in records]
)
for index, validator in enumerate(state.validators):
if index not in validator_indices_in_records:
if validator.exit_epoch != FAR_FUTURE_EPOCH and validator.withdrawable_epoch == FAR_FUTURE_EPOCH:
validator.withdrawable_epoch = Epoch(validator.exit_epoch + MIN_VALIDATOR_WITHDRAWABILITY_DELAY)