# Ethereum 2.0 Phase 1 -- Shard Transition and Fraud Proofs **Notice**: This document is a work-in-progress for researchers and implementers. ## Table of contents **Table of Contents** *generated with [DocToc](https://github.com/thlorenz/doctoc)* - [Introduction](#introduction) - [Helper functions](#helper-functions) - [Shard block verification functions](#shard-block-verification-functions) - [Shard state transition](#shard-state-transition) - [Fraud proofs](#fraud-proofs) - [Verifying the proof](#verifying-the-proof) ## Introduction This document describes the shard transition function and fraud proofs as part of Phase 1 of Ethereum 2.0. ## Helper functions ### Shard block verification functions ```python def verify_shard_block_message(beacon_parent_state: BeaconState, shard_parent_state: ShardState, block: ShardBlock) -> bool: # Check `shard_parent_root` field assert block.shard_parent_root == shard_parent_state.latest_block_root # Check `beacon_parent_root` field beacon_parent_block_header = beacon_parent_state.latest_block_header.copy() if beacon_parent_block_header.state_root == Root(): beacon_parent_block_header.state_root = hash_tree_root(beacon_parent_state) beacon_parent_root = hash_tree_root(beacon_parent_block_header) assert block.beacon_parent_root == beacon_parent_root # Check `slot` field shard = block.shard next_slot = Slot(block.slot + 1) offset_slots = compute_offset_slots(get_latest_slot_for_shard(beacon_parent_state, shard), next_slot) assert block.slot in offset_slots # Check `proposer_index` field assert block.proposer_index == get_shard_proposer_index(beacon_parent_state, block.slot, shard) # Check `body` field assert 0 < len(block.body) <= MAX_SHARD_BLOCK_SIZE return True ``` ```python def verify_shard_block_signature(beacon_state: BeaconState, signed_block: SignedShardBlock) -> bool: proposer = beacon_state.validators[signed_block.message.proposer_index] domain = get_domain(beacon_state, DOMAIN_SHARD_PROPOSAL, compute_epoch_at_slot(signed_block.message.slot)) signing_root = compute_signing_root(signed_block.message, domain) return bls.Verify(proposer.pubkey, signing_root, signed_block.signature) ``` ## Shard state transition ```python def shard_state_transition(shard_state: ShardState, block: ShardBlock, validate_message: bool = True, beacon_parent_state: Optional[BeaconState] = None) -> bool: if validate_message: assert beacon_parent_state is not None assert verify_shard_block_message(beacon_parent_state, shard_state, block) process_shard_block(shard_state, block) return shard_state ``` ```python def process_shard_block(shard_state: ShardState, block: ShardBlock) -> None: """ Update ``shard_state`` with shard ``block``. """ shard_state.slot = block.slot prev_gasprice = shard_state.gasprice shard_block_length = len(block.body) shard_state.gasprice = compute_updated_gasprice(prev_gasprice, uint64(shard_block_length)) if shard_block_length == 0: latest_block_root = shard_state.latest_block_root else: latest_block_root = hash_tree_root(block) shard_state.latest_block_root = latest_block_root ``` ## Fraud proofs ### Verifying the proof TODO. The intent is to have a single universal fraud proof type, which contains the following parts: 1. An on-time attestation `attestation` on some shard `shard` signing a `transition: ShardTransition` 2. An index `offset_index` of a particular position to focus on 3. The `transition: ShardTransition` itself 4. The full body of the shard block `shard_block` 5. A Merkle proof to the `shard_states` in the parent block the attestation is referencing 6. The `subkey` to generate the custody bit Call the following function to verify the proof: ```python def is_valid_fraud_proof(beacon_state: BeaconState, attestation: Attestation, offset_index: uint64, transition: ShardTransition, block: ShardBlock, subkey: BLSPubkey, beacon_parent_block: BeaconBlock) -> bool: # 1. Check if `custody_bits[offset_index][j] != generate_custody_bit(subkey, block_contents)` for any `j`. custody_bits = attestation.custody_bits_blocks for j in range(len(custody_bits[offset_index])): if custody_bits[offset_index][j] != generate_custody_bit(subkey, block): return True # 2. Check if the shard state transition result is wrong between # `transition.shard_states[offset_index - 1]` to `transition.shard_states[offset_index]`. if offset_index == 0: shard_states = beacon_parent_block.body.shard_transitions[attestation.data.shard].shard_states shard_state = shard_states[len(shard_states) - 1] else: shard_state = transition.shard_states[offset_index - 1] # Not doing the actual state updates here. shard_state_transition(shard_state, block, validate_message=False) if shard_state != transition.shard_states[offset_index]: return True return False ``` ```python def generate_custody_bit(subkey: BLSPubkey, block: ShardBlock) -> bool: # TODO ... ```