research/casper4/simple_casper.v.py

560 lines
26 KiB
Python

# Information about validators
validators: public({
# Amount of wei the validator holds
deposit: wei_value,
# The dynasty the validator is joining
dynasty_start: num,
# The dynasty the validator joined for the first time
original_dynasty_start: num,
# The dynasty the validator is leaving
dynasty_end: num,
# The timestamp at which the validator can withdraw
withdrawal_epoch: num,
# The address which the validator's signatures must verify to (to be later replaced with validation code)
addr: address,
# Addess to withdraw to
withdrawal_addr: address,
# Previous epoch in which this validator committed
prev_commit_epoch: num
}[num])
# The current dynasty (validator set changes between dynasties)
dynasty: public(num)
# Amount of wei added to the total deposits in the next dynasty
next_dynasty_wei_delta: wei_value
# Amount of wei added to the total deposits in the dynasty after that
second_next_dynasty_wei_delta: wei_value
# Total deposits during this dynasty
total_deposits: public(wei_value[num])
# Mapping of dynasty to start epoch of that dynasty
dynasty_start_epoch: public(num[num])
# Mapping of epoch to what dynasty it is
dynasty_in_epoch: public(num[num])
# Information for use in processing cryptoeconomic commitments
consensus_messages: public({
# How many prepares are there for this hash (hash of message hash + view source) from the current dynasty
prepares: wei_value[bytes32],
# Bitmap of which validator IDs have already prepared
prepare_bitmap: num256[num][bytes32],
# From the previous dynasty
prev_dyn_prepares: wei_value[bytes32],
# Is a prepare referencing the given ancestry hash justified?
ancestry_hash_justified: bool[bytes32],
# Is a commit on the given hash justified?
hash_justified: bool[bytes32],
# How many commits are there for this hash
commits: wei_value[bytes32],
# And from the previous dynasty
prev_dyn_commits: wei_value[bytes32],
# Was the block committed?
committed: bool,
# Value used to calculate the per-epoch fee that validators should be charged
deposit_scale_factor: decimal
}[num]) # index: epoch
# A bitmap, where the ith bit of dynasty_mark[arg1][arg2] shows
# whether or not validator arg1 is active during dynasty arg2*256+i
dynasty_mask: num256[num][num]
# ancestry[x][y] = k > 0: x is a kth generation ancestor of y
ancestry: public(num[bytes32][bytes32])
# Number of validators
nextValidatorIndex: public(num)
# Time between blocks
block_time: timedelta
# Length of an epoch in blocks
epoch_length: num
# Withdrawal delay
withdrawal_delay: timedelta
# Delay after which a message can be slashed due to absence of justification
insufficiency_slash_delay: timedelta
# Current epoch
current_epoch: public(num)
# Can withdraw destroyed deposits
owner: address
# Total deposits destroyed
total_destroyed: wei_value
# Sighash calculator library address
sighasher: address
# Purity checker library address
purity_checker: address
# Reward for preparing or committing, as fraction of deposit size
reward_factor: public(decimal)
# Desired total ether given out assuming 1M ETH deposited
reward_at_1m_eth: decimal
# Have I already been initialized?
initialized: bool
# Log topic for prepare
prepare_log_topic: bytes32
# Log topic for commit
commit_log_topic: bytes32
def initiate():
assert not self.initialized
self.initialized = True
# Set Casper parameters
self.block_time = 14
self.epoch_length = 100
# Only ~11.5 days, for testing purposes
self.withdrawal_delay = 1000000
# Only ~1 day, for testing purposes
self.insufficiency_slash_delay = 86400
# Temporary backdoor for testing purposes (to allow recovering destroyed deposits)
self.owner = 0x1Db3439a222C519ab44bb1144fC28167b4Fa6EE6
# Add an initial validator
self.validators[0] = {
deposit: as_wei_value(3, ether),
dynasty_start: 0,
dynasty_end: 1000000000000000000000000000000,
original_dynasty_start: 0,
withdrawal_epoch: 1000000000000000000000000000000,
addr: 0x1Db3439a222C519ab44bb1144fC28167b4Fa6EE6,
withdrawal_addr: 0x1Db3439a222C519ab44bb1144fC28167b4Fa6EE6,
prev_commit_epoch: 0,
}
self.nextValidatorIndex = 1
# Initialize the epoch counter
self.current_epoch = block.number / self.epoch_length
# Set the sighash calculator address
self.sighasher = 0x476c2cA9a7f3B16FeCa86512276271FAf63B6a24
# Set the purity checker address
self.purity_checker = 0xD7a3BD6C9eA32efF147d067f907AE6b22d436F91
# Set an initial root of the epoch hash chain
self.consensus_messages[0].ancestry_hash_justified[0x0000000000000000000000000000000000000000000000000000000000000000] = True
# self.consensus_messages[0].committed = True
# Set initial total deposit counter
self.total_deposits[0] = as_wei_value(3, ether)
# Set deposit scale factor
self.consensus_messages[0].deposit_scale_factor = 1000000000000000000.0
# Total ETH given out assuming 1m ETH deposits
self.reward_at_1m_eth = 12.5
# Log topics for prepare and commit
self.prepare_log_topic = sha3("prepare()")
self.commit_log_topic = sha3("commit()")
# Called at the start of any epoch
def initialize_epoch(epoch: num):
# Check that the epoch actually has started
computed_current_epoch = block.number / self.epoch_length
assert epoch <= computed_current_epoch and epoch == self.current_epoch + 1
# Set the epoch number
self.current_epoch = epoch
# Increment the dynasty
if self.consensus_messages[epoch - 1].committed:
self.dynasty += 1
self.total_deposits[self.dynasty] = self.total_deposits[self.dynasty - 1] + self.next_dynasty_wei_delta
self.next_dynasty_wei_delta = self.second_next_dynasty_wei_delta
self.second_next_dynasty_wei_delta = 0
self.dynasty_start_epoch[self.dynasty] = epoch
self.dynasty_in_epoch[epoch] = self.dynasty
# Compute square root factor
ether_deposited_as_number = self.total_deposits[self.dynasty] / as_wei_value(1, ether)
sqrt = ether_deposited_as_number / 2.0
for i in range(20):
sqrt = (sqrt + (ether_deposited_as_number / sqrt)) / 2
# Reward factor is the reward given for preparing or committing as a
# fraction of that validator's deposit size
base_coeff = 1.0 / sqrt * (self.reward_at_1m_eth / 1000)
# Rules:
# * You are penalized 2x per epoch
# * If you prepare, you get 1.5x, and if you commit you get another 1.5x
# Hence, assuming 100% performance, your reward per epoch is x
self.reward_factor = 1.5 * base_coeff
self.consensus_messages[epoch].deposit_scale_factor = self.consensus_messages[epoch - 1].deposit_scale_factor * (1 - 2 * base_coeff)
# Send a deposit to join the validator set
def deposit(validation_addr: address, withdrawal_addr: address):
assert self.current_epoch == block.number / self.epoch_length
assert extract32(raw_call(self.purity_checker, concat('\xa1\x90>\xab', as_bytes32(validation_addr)), gas=500000, outsize=32), 0) != as_bytes32(0)
self.validators[self.nextValidatorIndex] = {
deposit: msg.value,
dynasty_start: self.dynasty + 2,
original_dynasty_start: self.dynasty + 2,
dynasty_end: 1000000000000000000000000000000,
withdrawal_epoch: 1000000000000000000000000000000,
addr: validation_addr,
withdrawal_addr: withdrawal_addr,
prev_commit_epoch: 0,
}
self.nextValidatorIndex += 1
self.second_next_dynasty_wei_delta += msg.value
# Log in or log out from the validator set. A logged out validator can log
# back in later, if they do not log in for an entire withdrawal period,
# they can get their money out
def flick_status(logout_msg: bytes <= 1024):
assert self.current_epoch == block.number / self.epoch_length
# Get hash for signature, and implicitly assert that it is an RLP list
# consisting solely of RLP elements
sighash = extract32(raw_call(self.sighasher, logout_msg, gas=200000, outsize=32), 0)
# Extract parameters
values = RLPList(logout_msg, [num, num, bool, bytes])
validator_index = values[0]
epoch = values[1]
login_flag = values[2]
sig = values[3]
assert self.current_epoch == epoch
# Signature check
assert extract32(raw_call(self.validators[validator_index].addr, concat(sighash, sig), gas=500000, outsize=32), 0) == as_bytes32(1)
# Logging in
if login_flag:
# Check that we are logged out
assert self.validators[validator_index].dynasty_end < self.dynasty
# Check that we logged out for less than 3840 dynasties (min: ~2 months)
assert self.validators[validator_index].dynasty_end >= self.dynasty - 3840
# Apply the per-epoch deposit penalty
prev_login_epoch = self.dynasty_start_epoch[self.validators[validator_index].dynasty_start]
prev_logout_epoch = self.dynasty_start_epoch[self.validators[validator_index].dynasty_end + 1]
self.validators[validator_index].deposit = \
floor(self.validators[validator_index].deposit *
(self.consensus_messages[prev_logout_epoch].deposit_scale_factor /
self.consensus_messages[prev_login_epoch].deposit_scale_factor))
# Log back in
# Go through the dynasty mask to clear out the ineligible dynasties
old_ds = self.validators[validator_index].dynasty_end
new_ds = self.dynasty + 2
for i in range(old_ds / 256, old_ds / 256 + 16):
if old_ds > i * 256:
s = old_ds % 256
else:
s = 0
if new_ds < i * 256 + 256:
e = new_ds % 256
else:
e = 256
self.dynasty_mask[validator_index][i] = num256_sub(shift(as_num256(1), e), shift(as_num256(1), s))
if e < 256:
break
self.validators[validator_index].dynasty_start = new_ds
self.validators[validator_index].dynasty_end = 1000000000000000000000000000000
self.second_next_dynasty_wei_delta += self.validators[validator_index].deposit
# Logging out
else:
# Check that we haven't already withdrawn
assert self.validators[validator_index].dynasty_end >= self.dynasty + 2
# Set the end dynasty
self.validators[validator_index].dynasty_end = self.dynasty + 2
self.second_next_dynasty_wei_delta -= self.validators[validator_index].deposit
# Set the withdrawal date
self.validators[validator_index].withdrawal_epoch = self.current_epoch + self.withdrawal_delay / self.block_time / self.epoch_length
# Removes a validator from the validator pool
def delete_validator(validator_index: num):
self.validators[validator_index] = {
deposit: 0,
dynasty_start: 0,
dynasty_end: 0,
original_dynasty_start: 0,
withdrawal_epoch: 0,
addr: None,
withdrawal_addr: None,
prev_commit_epoch: 0,
}
# Withdraw deposited ether
def withdraw(validator_index: num):
# Check that we can withdraw
assert self.current_epoch >= self.validators[validator_index].withdrawal_epoch
# Apply the per-epoch deposit penalty
prev_login_epoch = self.dynasty_start_epoch[self.validators[validator_index].dynasty_start]
prev_logout_epoch = self.dynasty_start_epoch[self.validators[validator_index].dynasty_end + 1]
self.validators[validator_index].deposit = \
floor(self.validators[validator_index].deposit *
(self.consensus_messages[prev_logout_epoch].deposit_scale_factor /
self.consensus_messages[prev_login_epoch].deposit_scale_factor))
# Withdraw
send(self.validators[validator_index].withdrawal_addr, self.validators[validator_index].deposit)
self.delete_validator(validator_index)
# Checks if a given validator could have prepared in a given epoch
def check_eligible_in_epoch(validator_index: num, epoch: num) -> num(const):
# Time limit for submitting a prepare
assert epoch > self.current_epoch - 3840
# Original starting dynasty of the validator; fail if before
do = self.validators[validator_index].original_dynasty_start
# Ending dynasty of the current login period
de = self.validators[validator_index].dynasty_end
# Dynasty of the prepare
dc = self.dynasty_in_epoch[epoch]
# Dynasty before the prepare (for prev dynasty checking)
dp = dc - 1
# Check against mask to see if the dynasty was eligible before
cur_in_mask = bitwise_and(self.dynasty_mask[validator_index][dc / 256], shift(as_num256(1), dc % 256))
prev_in_mask = bitwise_and(self.dynasty_mask[validator_index][dp / 256], shift(as_num256(1), dp % 256))
o = 0
# Return result as bitmask, bit 1 = in_current_dynasty, bit 0 = in_prev_dynasty
if ((do <= dc and cur_in_mask == as_num256(0)) and dc < de):
o += 2
if ((do <= dp and prev_in_mask == as_num256(0)) and dp < de):
o += 1
return o
# Process a prepare message
def prepare(prepare_msg: bytes <= 1024):
# Get hash for signature, and implicitly assert that it is an RLP list
# consisting solely of RLP elements
sighash = extract32(raw_call(self.sighasher, prepare_msg, gas=200000, outsize=32), 0)
# Extract parameters
values = RLPList(prepare_msg, [num, num, bytes32, bytes32, num, bytes32, bytes])
validator_index = values[0]
epoch = values[1]
hash = values[2]
ancestry_hash = values[3]
source_epoch = values[4]
source_ancestry_hash = values[5]
sig = values[6]
new_ancestry_hash = sha3(concat(hash, ancestry_hash))
# Hash for purposes of identifying this (epoch, hash, ancestry_hash, source_epoch, source_ancestry_hash) combination
sourcing_hash = sha3(concat(as_bytes32(epoch), hash, ancestry_hash, as_bytes32(source_epoch), source_ancestry_hash))
# Check the signature
assert extract32(raw_call(self.validators[validator_index].addr, concat(sighash, sig), gas=500000, outsize=32), 0) == as_bytes32(1)
# Check that we are in an epoch after we started validating
assert self.current_epoch >= self.dynasty_start_epoch[self.validators[validator_index].dynasty_start]
# Check that this prepare has not yet been made
assert not bitwise_and(self.consensus_messages[epoch].prepare_bitmap[sourcing_hash][validator_index / 256],
shift(as_num256(1), validator_index % 256))
# Check that we are at least (epoch length / 4) blocks into the epoch
# assert block.number % self.epoch_length >= self.epoch_length / 4
# Check that this validator was active in either the previous dynasty or the current one
epochcheck = self.check_eligible_in_epoch(validator_index, epoch)
in_current_dynasty = epochcheck >= 2
in_prev_dynasty = (epochcheck % 2) == 1
assert in_current_dynasty or in_prev_dynasty
# Check that the prepare is on top of a justified prepare
assert self.consensus_messages[source_epoch].ancestry_hash_justified[source_ancestry_hash]
# Check that we have not yet prepared for this epoch
# Pay the reward if the prepare was submitted in time and the blockhash is correct
this_validators_deposit = self.validators[validator_index].deposit
if self.current_epoch == epoch: #if blockhash(epoch * self.epoch_length) == hash:
reward = floor(this_validators_deposit * self.reward_factor)
self.validators[validator_index].deposit += reward
self.total_deposits[self.dynasty] += reward
# Can't prepare for this epoch again
self.consensus_messages[epoch].prepare_bitmap[sourcing_hash][validator_index / 256] = \
bitwise_or(self.consensus_messages[epoch].prepare_bitmap[sourcing_hash][validator_index / 256],
shift(as_num256(1), validator_index % 256))
# self.validators[validator_index].max_prepared = epoch
# Record that this prepare took place
curdyn_prepares = self.consensus_messages[epoch].prepares[sourcing_hash]
if in_current_dynasty:
curdyn_prepares += this_validators_deposit
self.consensus_messages[epoch].prepares[sourcing_hash] = curdyn_prepares
prevdyn_prepares = self.consensus_messages[epoch].prev_dyn_prepares[sourcing_hash]
if in_prev_dynasty:
prevdyn_prepares += this_validators_deposit
self.consensus_messages[epoch].prev_dyn_prepares[sourcing_hash] = prevdyn_prepares
# If enough prepares with the same epoch_source and hash are made,
# then the hash value is justified for commitment
if (curdyn_prepares >= self.total_deposits[self.dynasty] * 2 / 3 and \
prevdyn_prepares >= self.total_deposits[self.dynasty - 1] * 2 / 3) and \
not self.consensus_messages[epoch].ancestry_hash_justified[new_ancestry_hash]:
self.consensus_messages[epoch].ancestry_hash_justified[new_ancestry_hash] = True
self.consensus_messages[epoch].hash_justified[hash] = True
# Add a parent-child relation between ancestry hashes to the ancestry table
if not self.ancestry[ancestry_hash][new_ancestry_hash]:
self.ancestry[ancestry_hash][new_ancestry_hash] = 1
raw_log([self.prepare_log_topic], prepare_msg)
# Process a commit message
def commit(commit_msg: bytes <= 1024):
sighash = extract32(raw_call(self.sighasher, commit_msg, gas=200000, outsize=32), 0)
# Extract parameters
values = RLPList(commit_msg, [num, num, bytes32, num, bytes])
validator_index = values[0]
epoch = values[1]
hash = values[2]
prev_commit_epoch = values[3]
sig = values[4]
# Check the signature
assert extract32(raw_call(self.validators[validator_index].addr, concat(sighash, sig), gas=500000, outsize=32), 0) == as_bytes32(1)
# Check that we are in the right epoch
assert self.current_epoch == block.number / self.epoch_length
assert self.current_epoch == epoch
# Check that we are at least (epoch length / 2) blocks into the epoch
# assert block.number % self.epoch_length >= self.epoch_length / 2
# Check that the commit is justified
assert self.consensus_messages[epoch].hash_justified[hash]
# Check that this validator was active in either the previous dynasty or the current one
epochcheck = self.check_eligible_in_epoch(validator_index, epoch)
in_current_dynasty = epochcheck >= 2
in_prev_dynasty = (epochcheck % 2) == 1
assert in_current_dynasty or in_prev_dynasty
# Check that we have not yet committed for this epoch
assert self.validators[validator_index].prev_commit_epoch == prev_commit_epoch
assert prev_commit_epoch < epoch
self.validators[validator_index].prev_commit_epoch = epoch
this_validators_deposit = self.validators[validator_index].deposit
# Pay the reward if the blockhash is correct
if True: #if blockhash(epoch * self.epoch_length) == hash:
reward = floor(this_validators_deposit * self.reward_factor)
self.validators[validator_index].deposit += reward
self.total_deposits[self.dynasty] += reward
# Can't commit for this epoch again
# self.validators[validator_index].max_committed = epoch
# Record that this commit took place
if in_current_dynasty:
self.consensus_messages[epoch].commits[hash] += this_validators_deposit
if in_prev_dynasty:
self.consensus_messages[epoch].prev_dyn_commits[hash] += this_validators_deposit
# Record if sufficient commits have been made for the block to be finalized
if (self.consensus_messages[epoch].commits[hash] >= self.total_deposits[self.dynasty] * 2 / 3 and \
self.consensus_messages[epoch].prev_dyn_commits[hash] >= self.total_deposits[self.dynasty - 1] * 2 / 3) and \
not self.consensus_messages[epoch].committed:
self.consensus_messages[epoch].committed = True
raw_log([self.commit_log_topic], commit_msg)
# Cannot make two prepares in the same epoch
def double_prepare_slash(prepare1: bytes <= 1000, prepare2: bytes <= 1000):
# Get hash for signature, and implicitly assert that it is an RLP list
# consisting solely of RLP elements
sighash1 = extract32(raw_call(self.sighasher, prepare1, gas=200000, outsize=32), 0)
sighash2 = extract32(raw_call(self.sighasher, prepare2, gas=200000, outsize=32), 0)
# Extract parameters
values1 = RLPList(prepare1, [num, num, bytes32, bytes32, num, bytes32, bytes])
values2 = RLPList(prepare2, [num, num, bytes32, bytes32, num, bytes32, bytes])
validator_index = values1[0]
epoch1 = values1[1]
sig1 = values1[6]
assert validator_index == values2[0]
epoch2 = values2[1]
sig2 = values2[6]
# Check the signatures
assert extract32(raw_call(self.validators[validator_index].addr, concat(sighash1, sig1), gas=500000, outsize=32), 0) == as_bytes32(1)
assert extract32(raw_call(self.validators[validator_index].addr, concat(sighash2, sig2), gas=500000, outsize=32), 0) == as_bytes32(1)
# Check that they're from the same epoch
assert epoch1 == epoch2
# Check that they're not the same message
assert sighash1 != sighash2
# Delete the offending validator, and give a 4% "finder's fee"
validator_deposit = self.validators[validator_index].deposit
send(msg.sender, validator_deposit / 25)
self.total_destroyed += validator_deposit * 24 / 25
self.total_deposits[self.dynasty] -= (validator_deposit - validator_deposit / 25)
self.delete_validator(validator_index)
def prepare_commit_inconsistency_slash(prepare_msg: bytes <= 1024, commit_msg: bytes <= 1024):
# Get hash for signature, and implicitly assert that it is an RLP list
# consisting solely of RLP elements
sighash1 = extract32(raw_call(self.sighasher, prepare_msg, gas=200000, outsize=32), 0)
sighash2 = extract32(raw_call(self.sighasher, commit_msg, gas=200000, outsize=32), 0)
# Extract parameters
values1 = RLPList(prepare_msg, [num, num, bytes32, bytes32, num, bytes32, bytes])
values2 = RLPList(commit_msg, [num, num, bytes32, num, bytes])
validator_index = values1[0]
prepare_epoch = values1[1]
prepare_source_epoch = values1[4]
sig1 = values1[6]
assert validator_index == values2[0]
commit_epoch = values2[1]
sig2 = values2[4]
# Check the signatures
assert extract32(raw_call(self.validators[validator_index].addr, concat(sighash1, sig1), gas=500000, outsize=32), 0) == as_bytes32(1)
assert extract32(raw_call(self.validators[validator_index].addr, concat(sighash2, sig2), gas=500000, outsize=32), 0) == as_bytes32(1)
# Check that the prepare refers to something older than the commit
assert prepare_source_epoch < commit_epoch
# Check that the prepare is newer than the commit
assert commit_epoch < prepare_epoch
# Delete the offending validator, and give a 4% "finder's fee"
validator_deposit = self.validators[validator_index].deposit
send(msg.sender, validator_deposit / 25)
self.total_destroyed += validator_deposit * 24 / 25
self.total_deposits[self.dynasty] -= validator_deposit
self.delete_validator(validator_index)
def commit_non_justification_slash(commit_msg: bytes <= 1024):
sighash = extract32(raw_call(self.sighasher, commit_msg, gas=200000, outsize=32), 0)
# Extract parameters
values = RLPList(commit_msg, [num, num, bytes32, num, bytes])
validator_index = values[0]
epoch = values[1]
hash = values[2]
sig = values[4]
# Check the signature
assert len(sig) == 96
assert extract32(raw_call(self.validators[validator_index].addr, concat(sighash, sig), gas=500000, outsize=32), 0) == as_bytes32(1)
# Check that the commit is old enough
assert self.current_epoch == block.number / self.epoch_length
assert (self.current_epoch - epoch) * self.epoch_length * self.block_time > self.insufficiency_slash_delay
assert not self.consensus_messages[epoch].hash_justified[hash]
# Delete the offending validator, and give a 4% "finder's fee"
validator_deposit = self.validators[validator_index].deposit
send(msg.sender, validator_deposit / 25)
self.total_destroyed += validator_deposit * 24 / 25
self.total_deposits[self.dynasty] -= validator_deposit
self.delete_validator(validator_index)
# Fill in the table for which hash is what-degree ancestor of which other hash
def derive_parenthood(older: bytes32, hash: bytes32, newer: bytes32):
assert sha3(concat(hash, older)) == newer
self.ancestry[older][newer] = 1
# Fill in the table for which hash is what-degree ancestor of which other hash
def derive_ancestry(oldest: bytes32, middle: bytes32, recent: bytes32):
assert self.ancestry[middle][recent]
assert self.ancestry[oldest][middle]
self.ancestry[oldest][recent] = self.ancestry[oldest][middle] + self.ancestry[middle][recent]
def prepare_non_justification_slash(prepare_msg: bytes <= 1024) -> num:
# Get hash for signature, and implicitly assert that it is an RLP list
# consisting solely of RLP elements
sighash = extract32(raw_call(self.sighasher, prepare_msg, gas=200000, outsize=32), 0)
# Extract parameters
values = RLPList(prepare_msg, [num, num, bytes32, bytes32, num, bytes32, bytes])
validator_index = values[0]
epoch = values[1]
hash = values[2]
ancestry_hash = values[3]
source_epoch = values[4]
source_ancestry_hash = values[5]
sig = values[6]
# Check the signature
assert extract32(raw_call(self.validators[validator_index].addr, concat(sighash, sig), gas=500000, outsize=32), 0) == as_bytes32(1)
# Check that the view change is old enough
assert self.current_epoch == block.number / self.epoch_length
assert (self.current_epoch - epoch) * self.block_time * self.epoch_length > self.insufficiency_slash_delay
# Check that the source ancestry hash not had enough prepares, OR that there is not the
# correct ancestry link between the current ancestry hash and source ancestry hash
c1 = self.consensus_messages[source_epoch].ancestry_hash_justified[source_ancestry_hash]
if epoch - 1 > source_epoch:
c2 = self.ancestry[source_ancestry_hash][ancestry_hash] == epoch - 1 - source_epoch
else:
c2 = source_ancestry_hash == ancestry_hash
assert not (c1 and c2)
# Delete the offending validator, and give a 4% "finder's fee"
validator_deposit = self.validators[validator_index].deposit
send(msg.sender, validator_deposit / 25)
self.total_destroyed += validator_deposit * 24 / 25
self.total_deposits[self.dynasty] -= validator_deposit
self.delete_validator(validator_index)
# Temporary backdoor for testing purposes (to allow recovering destroyed deposits)
def owner_withdraw():
send(self.owner, self.total_destroyed)
self.total_destroyed = 0
# Change backdoor address (set to zero to remove entirely)
def change_owner(new_owner: address):
if self.owner == msg.sender:
self.owner = new_owner