from copy import deepcopy from py_ecc import bls from eth2spec.phase0.state_transition import ( state_transition, ) import eth2spec.phase0.spec as spec from eth2spec.utils.minimal_ssz import signing_root from eth2spec.phase0.spec import ( # constants ZERO_HASH, # SSZ Attestation, AttestationData, AttestationDataAndCustodyBit, AttesterSlashing, BeaconBlock, BeaconBlockHeader, Deposit, DepositData, Eth1Data, ProposerSlashing, Transfer, VoluntaryExit, # functions convert_to_indexed, get_active_validator_indices, get_attesting_indices, get_block_root, get_block_root_at_slot, get_crosslink_committee, get_current_epoch, get_domain, get_epoch_start_slot, get_genesis_beacon_state, get_previous_epoch, get_shard_delta, hash_tree_root, slot_to_epoch, verify_merkle_branch, hash, ) from eth2spec.utils.merkle_minimal import ( calc_merkle_tree_from_leaves, get_merkle_proof, get_merkle_root, ) privkeys = [i + 1 for i in range(1024)] pubkeys = [bls.privtopub(privkey) for privkey in privkeys] pubkey_to_privkey = {pubkey: privkey for privkey, pubkey in zip(privkeys, pubkeys)} def get_balance(state, index): return state.balances[index] def set_bitfield_bit(bitfield, i): """ Set the bit in ``bitfield`` at position ``i`` to ``1``. """ byte_index = i // 8 bit_index = i % 8 return ( bitfield[:byte_index] + bytes([bitfield[byte_index] | (1 << bit_index)]) + bitfield[byte_index+1:] ) def create_mock_genesis_validator_deposits(num_validators, deposit_data_leaves=None): if not deposit_data_leaves: deposit_data_leaves = [] signature = b'\x33' * 96 deposit_data_list = [] for i in range(num_validators): pubkey = pubkeys[i] deposit_data = DepositData( pubkey=pubkey, # insecurely use pubkey as withdrawal key as well withdrawal_credentials=spec.BLS_WITHDRAWAL_PREFIX_BYTE + hash(pubkey)[1:], amount=spec.MAX_EFFECTIVE_BALANCE, signature=signature, ) item = deposit_data.hash_tree_root() deposit_data_leaves.append(item) tree = calc_merkle_tree_from_leaves(tuple(deposit_data_leaves)) root = get_merkle_root((tuple(deposit_data_leaves))) proof = list(get_merkle_proof(tree, item_index=i)) assert verify_merkle_branch(item, proof, spec.DEPOSIT_CONTRACT_TREE_DEPTH, i, root) deposit_data_list.append(deposit_data) genesis_validator_deposits = [] for i in range(num_validators): genesis_validator_deposits.append(Deposit( proof=list(get_merkle_proof(tree, item_index=i)), index=i, data=deposit_data_list[i] )) return genesis_validator_deposits, root def create_genesis_state(num_validators, deposit_data_leaves=None): initial_deposits, deposit_root = create_mock_genesis_validator_deposits( num_validators, deposit_data_leaves, ) return get_genesis_beacon_state( initial_deposits, genesis_time=0, genesis_eth1_data=Eth1Data( deposit_root=deposit_root, deposit_count=len(initial_deposits), block_hash=spec.ZERO_HASH, ), ) def build_empty_block_for_next_slot(state): empty_block = BeaconBlock() empty_block.slot = state.slot + 1 empty_block.body.eth1_data.deposit_count = state.deposit_index previous_block_header = deepcopy(state.latest_block_header) if previous_block_header.state_root == spec.ZERO_HASH: previous_block_header.state_root = state.hash_tree_root() empty_block.previous_block_root = signing_root(previous_block_header) return empty_block def build_deposit_data(state, pubkey, privkey, amount): deposit_data = DepositData( pubkey=pubkey, # insecurely use pubkey as withdrawal key as well withdrawal_credentials=spec.BLS_WITHDRAWAL_PREFIX_BYTE + hash(pubkey)[1:], amount=amount, ) signature = bls.sign( message_hash=signing_root(deposit_data), privkey=privkey, domain=get_domain( state, spec.DOMAIN_DEPOSIT, ) ) deposit_data.signature = signature return deposit_data def build_attestation_data(state, slot, shard): assert state.slot >= slot if slot == state.slot: block_root = build_empty_block_for_next_slot(state).previous_block_root else: block_root = get_block_root_at_slot(state, slot) current_epoch_start_slot = get_epoch_start_slot(get_current_epoch(state)) if slot < current_epoch_start_slot: epoch_boundary_root = get_block_root(state, get_previous_epoch(state)) elif slot == current_epoch_start_slot: epoch_boundary_root = block_root else: epoch_boundary_root = get_block_root(state, get_current_epoch(state)) if slot < current_epoch_start_slot: justified_epoch = state.previous_justified_epoch justified_block_root = state.previous_justified_root else: justified_epoch = state.current_justified_epoch justified_block_root = state.current_justified_root crosslinks = state.current_crosslinks if slot_to_epoch(slot) == get_current_epoch(state) else state.previous_crosslinks return AttestationData( shard=shard, beacon_block_root=block_root, source_epoch=justified_epoch, source_root=justified_block_root, target_epoch=slot_to_epoch(slot), target_root=epoch_boundary_root, crosslink_data_root=spec.ZERO_HASH, previous_crosslink_root=hash_tree_root(crosslinks[shard]), ) def build_voluntary_exit(state, epoch, validator_index, privkey): voluntary_exit = VoluntaryExit( epoch=epoch, validator_index=validator_index, ) voluntary_exit.signature = bls.sign( message_hash=signing_root(voluntary_exit), privkey=privkey, domain=get_domain( state=state, domain_type=spec.DOMAIN_VOLUNTARY_EXIT, message_epoch=epoch, ) ) return voluntary_exit def build_deposit(state, deposit_data_leaves, pubkey, privkey, amount): deposit_data = build_deposit_data(state, pubkey, privkey, amount) item = deposit_data.hash_tree_root() index = len(deposit_data_leaves) deposit_data_leaves.append(item) tree = calc_merkle_tree_from_leaves(tuple(deposit_data_leaves)) root = get_merkle_root((tuple(deposit_data_leaves))) proof = list(get_merkle_proof(tree, item_index=index)) assert verify_merkle_branch(item, proof, spec.DEPOSIT_CONTRACT_TREE_DEPTH, index, root) deposit = Deposit( proof=list(proof), index=index, data=deposit_data, ) return deposit, root, deposit_data_leaves def get_valid_proposer_slashing(state): current_epoch = get_current_epoch(state) validator_index = get_active_validator_indices(state, current_epoch)[-1] privkey = pubkey_to_privkey[state.validator_registry[validator_index].pubkey] slot = state.slot header_1 = BeaconBlockHeader( slot=slot, previous_block_root=ZERO_HASH, state_root=ZERO_HASH, block_body_root=ZERO_HASH, ) header_2 = deepcopy(header_1) header_2.previous_block_root = b'\x02' * 32 header_2.slot = slot + 1 domain = get_domain( state=state, domain_type=spec.DOMAIN_BEACON_PROPOSER, ) header_1.signature = bls.sign( message_hash=signing_root(header_1), privkey=privkey, domain=domain, ) header_2.signature = bls.sign( message_hash=signing_root(header_2), privkey=privkey, domain=domain, ) return ProposerSlashing( proposer_index=validator_index, header_1=header_1, header_2=header_2, ) def get_valid_attester_slashing(state): attestation_1 = get_valid_attestation(state) attestation_2 = deepcopy(attestation_1) attestation_2.data.target_root = b'\x01' * 32 return AttesterSlashing( attestation_1=convert_to_indexed(state, attestation_1), attestation_2=convert_to_indexed(state, attestation_2), ) def get_valid_attestation(state, slot=None): if slot is None: slot = state.slot if slot_to_epoch(slot) == get_current_epoch(state): shard = (state.latest_start_shard + slot) % spec.SLOTS_PER_EPOCH else: previous_shard_delta = get_shard_delta(state, get_previous_epoch(state)) shard = (state.latest_start_shard - previous_shard_delta + slot) % spec.SHARD_COUNT attestation_data = build_attestation_data(state, slot, shard) crosslink_committee = get_crosslink_committee(state, attestation_data.target_epoch, attestation_data.shard) committee_size = len(crosslink_committee) bitfield_length = (committee_size + 7) // 8 aggregation_bitfield = b'\xC0' + b'\x00' * (bitfield_length - 1) custody_bitfield = b'\x00' * bitfield_length attestation = Attestation( aggregation_bitfield=aggregation_bitfield, data=attestation_data, custody_bitfield=custody_bitfield, ) participants = get_attesting_indices( state, attestation.data, attestation.aggregation_bitfield, ) assert len(participants) == 2 signatures = [] for validator_index in participants: privkey = privkeys[validator_index] signatures.append( get_attestation_signature( state, attestation.data, privkey ) ) attestation.aggregation_signature = bls.aggregate_signatures(signatures) return attestation def get_valid_transfer(state, slot=None, sender_index=None, amount=None, fee=None): if slot is None: slot = state.slot current_epoch = get_current_epoch(state) if sender_index is None: sender_index = get_active_validator_indices(state, current_epoch)[-1] recipient_index = get_active_validator_indices(state, current_epoch)[0] transfer_pubkey = pubkeys[-1] transfer_privkey = privkeys[-1] if fee is None: fee = get_balance(state, sender_index) // 32 if amount is None: amount = get_balance(state, sender_index) - fee transfer = Transfer( sender=sender_index, recipient=recipient_index, amount=amount, fee=fee, slot=slot, pubkey=transfer_pubkey, signature=ZERO_HASH, ) transfer.signature = bls.sign( message_hash=signing_root(transfer), privkey=transfer_privkey, domain=get_domain( state=state, domain_type=spec.DOMAIN_TRANSFER, message_epoch=get_current_epoch(state), ) ) # ensure withdrawal_credentials reproducable state.validator_registry[transfer.sender].withdrawal_credentials = ( spec.BLS_WITHDRAWAL_PREFIX_BYTE + spec.hash(transfer.pubkey)[1:] ) return transfer def get_attestation_signature(state, attestation_data, privkey, custody_bit=0b0): message_hash = AttestationDataAndCustodyBit( data=attestation_data, custody_bit=custody_bit, ).hash_tree_root() return bls.sign( message_hash=message_hash, privkey=privkey, domain=get_domain( state=state, domain_type=spec.DOMAIN_ATTESTATION, message_epoch=attestation_data.target_epoch, ) ) def fill_aggregate_attestation(state, attestation): crosslink_committee = get_crosslink_committee(state, attestation.data.target_epoch, attestation.data.shard) for i in range(len(crosslink_committee)): attestation.aggregation_bitfield = set_bitfield_bit(attestation.aggregation_bitfield, i) def add_attestation_to_state(state, attestation, slot): block = build_empty_block_for_next_slot(state) block.slot = slot block.body.attestations.append(attestation) state_transition(state, block) def next_slot(state): """ Transition to the next slot via an empty block. Return the empty block that triggered the transition. """ block = build_empty_block_for_next_slot(state) state_transition(state, block) return block def next_epoch(state): """ Transition to the start slot of the next epoch via an empty block. Return the empty block that triggered the transition. """ block = build_empty_block_for_next_slot(state) block.slot += spec.SLOTS_PER_EPOCH - (state.slot % spec.SLOTS_PER_EPOCH) state_transition(state, block) return block def get_state_root(state, slot) -> bytes: """ Return the state root at a recent ``slot``. """ assert slot < state.slot <= slot + spec.SLOTS_PER_HISTORICAL_ROOT return state.latest_state_roots[slot % spec.SLOTS_PER_HISTORICAL_ROOT]