Move to a per-slot state transition function
Initial pass for the migration from a per-block state transition function to a per-slot state transition function. More simplifications and cleanups can be made.
This commit is contained in:
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@ -69,22 +69,22 @@
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- [On startup](#on-startup)
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- [Routine for activating a validator](#routine-for-activating-a-validator)
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- [Routine for exiting a validator](#routine-for-exiting-a-validator)
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- [Per-block processing](#per-block-processing)
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- [Per-slot processing](#per-slot-processing)
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- [Verify attestations](#verify-attestations)
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- [Verify proposer signature](#verify-proposer-signature)
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- [Verify and process the RANDAO reveal](#verify-and-process-the-randao-reveal)
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- [Process RANDAO](#process-randao)
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- [Process PoW receipt root](#process-pow-receipt-root)
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- [Process special objects](#process-special-objects)
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- [`VOLUNTARY_EXIT`](#voluntary_exit)
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- [`CASPER_SLASHING`](#casper_slashing)
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- [`PROPOSER_SLASHING`](#proposer_slashing)
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- [`DEPOSIT_PROOF`](#deposit_proof)
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- [Epoch boundary processing](#epoch-boundary-processing)
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- [Per-epoch processing](#per-epoch-processing)
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- [Precomputation](#precomputation)
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- [Adjust justified slots and crosslink status](#adjust-justified-slots-and-crosslink-status)
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- [Balance recalculations related to FFG rewards](#balance-recalculations-related-to-ffg-rewards)
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- [Balance recalculations related to crosslink rewards](#balance-recalculations-related-to-crosslink-rewards)
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- [Ethereum 1.0 chain related rules](#ethereum-10-chain-related-rules)
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- [Receipt root voting](#receipt-root-voting)
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- [Validator registry change](#validator-registry-change)
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- [If a validator registry change does NOT happen](#if-a-validator-registry-change-does-not-happen)
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- [Proposer reshuffling](#proposer-reshuffling)
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@ -334,11 +334,16 @@ Unless otherwise indicated, code appearing in `this style` is to be interpreted
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```python
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{
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# Misc
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'slot': 'uint64',
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'genesis_time': 'uint64',
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'fork_data': ForkData, # For versioning hard forks
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# Validator registry
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'validator_registry': [ValidatorRecord],
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'validator_registry_latest_change_slot': 'uint64',
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'validator_registry_exit_count': 'uint64',
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'validator_registry_delta_chain_tip': 'hash32', # For light clients to easily track delta
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'validator_registry_delta_chain_tip': 'hash32', # For light clients to track deltas
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# Randomness and committees
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'randao_mix': 'hash32',
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@ -363,10 +368,6 @@ Unless otherwise indicated, code appearing in `this style` is to be interpreted
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# PoW receipt root
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'processed_pow_receipt_root': 'hash32',
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'candidate_pow_receipt_roots': [CandidatePoWReceiptRootRecord],
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# Misc
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'genesis_time': 'uint64',
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'fork_data': ForkData, # For versioning hard forks
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}
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```
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@ -629,13 +630,13 @@ The beacon chain is the system chain for Ethereum 2.0. The main responsibilities
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* Store and maintain the registry of [validators](#dfn-validator)
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* Process crosslinks (see above)
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* Process its own block-by-block consensus, as well as the finality gadget
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* Process its per-slot consensus, as well as the finality gadget
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Processing the beacon chain is fundamentally similar to processing the Ethereum 1.0 chain in many respects. Clients download and process blocks, and maintain a view of what is the current "canonical chain", terminating at the current "head". However, because of the beacon chain's relationship with Ethereum 1.0, and because it is a proof-of-stake chain, there are differences.
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Processing the beacon chain is similar to processing the Ethereum 1.0 chain. Clients download and process blocks, and maintain a view of what is the current "canonical chain", terminating at the current "head". However, because of the beacon chain's relationship with Ethereum 1.0, and because it is a proof-of-stake chain, there are differences.
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For a beacon chain block, `block`, to be processed by a node, the following conditions must be met:
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* The parent block, `block.ancestor_hashes[0]`, has been processed and accepted.
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* The parent block (possibly a skip block) with hash `block.ancestor_hashes[0]` has been processed and accepted.
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* The Ethereum 1.0 block pointed to by the `state.processed_pow_receipt_root` has been processed and accepted.
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* The node's local clock time is greater than or equal to `state.genesis_time + block.slot * SLOT_DURATION`.
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@ -678,10 +679,10 @@ def lmd_ghost(store, start):
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We now define the state transition function. At a high level the state transition is made up of two parts:
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1. The per-block processing, which happens every block, and only affects a few parts of the `state`.
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2. The inter-epoch state recalculation, which happens only if `block.slot >= state.latest_state_recalculation_slot + EPOCH_LENGTH`, and affects the entire `state`.
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1. The per-slot transitions, which happens every slot, and only affects a parts of the `state`.
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2. The per-epoch transitions, which happens at every epoch boundary (i.e. `state.slot % EPOCH_LENGTH == 0`), and affects the entire `state`.
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The inter-epoch state recalculation generally focuses on changes to the [validator](#dfn-validator) registry, including adjusting balances and activating and exiting [validators](#dfn-validator), as well as processing crosslinks and managing block justification/finalization, while the per-block processing generally focuses on verifying aggregate signatures and saving temporary records relating to the per-block activity in the `BeaconState`.
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The per-epoch transitions focus on the [validator](#dfn-validator) registry, including adjusting balances and activating and exiting [validators](#dfn-validator), as well as processing crosslinks and managing block justification/finalization. The per-slot transitions generally focuses on verifying aggregate signatures and saving temporary records relating to the per-slot activity in the `BeaconState`.
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### Helper functions
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@ -982,37 +983,44 @@ def on_startup(initial_validator_entries: List[Any],
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# Setup state
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initial_shuffling = get_new_shuffling(ZERO_HASH, initial_validator_registry, 0)
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state = BeaconState(
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validator_registry=initial_validator_registry,
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validator_registry_latest_change_slot=INITIAL_SLOT_NUMBER,
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validator_registry_exit_count=0,
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validator_registry_delta_chain_tip=ZERO_HASH,
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# Randomness and committees
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randao_mix=ZERO_HASH,
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next_seed=ZERO_HASH,
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shard_committees_at_slots=initial_shuffling + initial_shuffling,
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persistent_committees=split(shuffle(initial_validator_registry, ZERO_HASH), SHARD_COUNT),
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persistent_committee_reassignments=[],
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# Finality
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previous_justified_slot=INITIAL_SLOT_NUMBER,
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justified_slot=INITIAL_SLOT_NUMBER,
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justification_bitfield=0,
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finalized_slot=INITIAL_SLOT_NUMBER,
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# Recent state
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latest_crosslinks=[CrosslinkRecord(slot=INITIAL_SLOT_NUMBER, hash=ZERO_HASH) for _ in range(SHARD_COUNT)],
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latest_state_recalculation_slot=INITIAL_SLOT_NUMBER,
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latest_block_hashes=[ZERO_HASH for _ in range(EPOCH_LENGTH * 2)],
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latest_penalized_exit_balances=[],
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latest_attestations=[],
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# PoW receipt root
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processed_pow_receipt_root=processed_pow_receipt_root,
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candidate_pow_receipt_roots=[],
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# Misc
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slot=INITIAL_SLOT_NUMBER,
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genesis_time=genesis_time,
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fork_data=ForkData(
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pre_fork_version=INITIAL_FORK_VERSION,
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post_fork_version=INITIAL_FORK_VERSION,
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fork_slot=INITIAL_SLOT_NUMBER,
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),
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# Validator registry
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validator_registry=initial_validator_registry,
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validator_registry_latest_change_slot=INITIAL_SLOT_NUMBER,
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validator_registry_exit_count=0,
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validator_registry_delta_chain_tip=ZERO_HASH,
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# Randomness and committees
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randao_mix=ZERO_HASH,
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next_seed=ZERO_HASH,
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shard_committees_at_slots=initial_shuffling + initial_shuffling,
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persistent_committees=split(shuffle(initial_validator_registry, ZERO_HASH), SHARD_COUNT),
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persistent_committee_reassignments=[],
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# Finality
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previous_justified_slot=INITIAL_SLOT_NUMBER,
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justified_slot=INITIAL_SLOT_NUMBER,
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justification_bitfield=0,
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finalized_slot=INITIAL_SLOT_NUMBER,
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# Recent state
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latest_crosslinks=[CrosslinkRecord(slot=INITIAL_SLOT_NUMBER, hash=ZERO_HASH) for _ in range(SHARD_COUNT)],
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latest_state_recalculation_slot=INITIAL_SLOT_NUMBER,
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latest_block_hashes=[ZERO_HASH for _ in range(EPOCH_LENGTH * 2)],
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latest_penalized_exit_balances=[],
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latest_attestations=[],
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# PoW receipt root
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processed_pow_receipt_root=processed_pow_receipt_root,
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candidate_pow_receipt_roots=[],
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)
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return state
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@ -1175,12 +1183,12 @@ def exit_validator(index: int,
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)
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```
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## Per-block processing
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## Per-slot processing
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This procedure should be carried out for every beacon block (denoted `block`).
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Below are the steps that happen at every slot. Denote by `block` the associated block, possibly a "skip block".
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* Let `parent_hash` be the hash of the immediate previous beacon block (ie. equal to `block.ancestor_hashes[0]`).
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* Let `parent` be the beacon block with the hash `parent_hash`.
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* Let `parent_hash` be the hash of the immediate previous beacon slot (ie. equal to `block.ancestor_hashes[0]`).
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* Let `parent` be the beacon slot with the hash `parent_hash`.
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First, set `state.latest_block_hashes` to the output of the following:
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@ -1212,7 +1220,7 @@ def update_ancestor_hashes(parent_ancestor_hashes: List[Hash32],
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For each `attestation` in `block.attestations`:
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* Verify that `attestation.data.slot <= block.slot - MIN_ATTESTATION_INCLUSION_DELAY`.
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* Verify that `attestation.data.slot <= state.slot - MIN_ATTESTATION_INCLUSION_DELAY`.
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* Verify that `attestation.data.slot >= max(parent.slot - EPOCH_LENGTH + 1, 0)`.
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* Verify that `attestation.data.justified_slot` is equal to `state.justified_slot if attestation.data.slot >= state.latest_state_recalculation_slot else state.previous_justified_slot`.
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* Verify that `attestation.data.justified_block_hash` is equal to `get_block_hash(state, block, attestation.data.justified_slot)`.
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@ -1222,28 +1230,24 @@ For each `attestation` in `block.attestations`:
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* Let `group_public_key = BLSAddPubkeys([state.validator_registry[v].pubkey for v in participants])`.
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* Verify that `BLSVerify(pubkey=group_public_key, msg=SSZTreeHash(attestation.data) + bytes1(0), sig=aggregate_signature, domain=get_domain(state.fork_data, slot, DOMAIN_ATTESTATION))`.
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* [TO BE REMOVED IN PHASE 1] Verify that `shard_block_hash == ZERO_HASH`.
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* Append `PendingAttestationRecord(data=attestation.data, participation_bitfield=attestation.participation_bitfield, custody_bitfield=attestation.custody_bitfield, slot_included=block.slot)` to `state.latest_attestations`.
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* Append `PendingAttestationRecord(data=attestation.data, participation_bitfield=attestation.participation_bitfield, custody_bitfield=attestation.custody_bitfield, slot_included=state.slot)` to `state.latest_attestations`.
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### Verify proposer signature
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* Let `block_hash_without_sig` be the hash of `block` where `proposer_signature` is set to `[0, 0]`.
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* Let `proposal_hash = hash(ProposalSignedData(block.slot, BEACON_CHAIN_SHARD_NUMBER, block_hash_without_sig))`.
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* Verify that `BLSVerify(pubkey=state.validator_registry[get_beacon_proposer_index(state, block.slot)].pubkey, data=proposal_hash, sig=block.proposer_signature, domain=get_domain(state.fork_data, block.slot, DOMAIN_PROPOSAL))`.
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* Let `proposal_hash = hash(ProposalSignedData(state.slot, BEACON_CHAIN_SHARD_NUMBER, block_hash_without_sig))`.
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* Verify that `BLSVerify(pubkey=state.validator_registry[get_beacon_proposer_index(state, state.slot)].pubkey, data=proposal_hash, sig=block.proposer_signature, domain=get_domain(state.fork_data, state.slot, DOMAIN_PROPOSAL))`.
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### Verify and process the RANDAO reveal
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### Process RANDAO
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First run the following state transition to update `randao_skips` variables for the missing slots.
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If `block` is a skip block:
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```python
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for slot in range(parent.slot + 1, block.slot):
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proposer_index = get_beacon_proposer_index(state, slot)
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state.validator_registry[proposer_index].randao_skips += 1
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```
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* Let `state.validator_registry[get_beacon_proposer_index(state, state.slot)].randao_skips += 1`.
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Then:
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If `block` is not a skip block:
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* Let `repeat_hash(x, n) = x if n == 0 else repeat_hash(hash(x), n-1)`.
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* Let `proposer = state.validator_registry[get_beacon_proposer_index(state, block.slot)]`.
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* Let `proposer = state.validator_registry[get_beacon_proposer_index(state, state.slot)]`.
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* Verify that `repeat_hash(block.randao_reveal, proposer.randao_skips + 1) == proposer.randao_commitment`.
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* Set `state.randao_mix = xor(state.randao_mix, block.randao_reveal)`.
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* Set `proposer.randao_commitment = block.randao_reveal`.
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@ -1269,9 +1273,9 @@ For each `special` in `block.specials`:
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* Let `validator = state.validator_registry[validator_index]`.
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* Verify that `BLSVerify(pubkey=validator.pubkey, msg=ZERO_HASH, sig=signature, domain=get_domain(state.fork_data, slot, DOMAIN_EXIT))`.
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* Verify that `validator.status == ACTIVE`.
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* Verify that `block.slot >= slot`.
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* Verify that `block.slot >= validator.latest_status_change_slot + SHARD_PERSISTENT_COMMITTEE_CHANGE_PERIOD`.
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* Run `exit_validator(validator_index, state, penalize=False, current_slot=block.slot)`.
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* Verify that `state.slot >= slot`.
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* Verify that `state.slot >= validator.latest_status_change_slot + SHARD_PERSISTENT_COMMITTEE_CHANGE_PERIOD`.
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* Run `exit_validator(validator_index, state, penalize=False, current_slot=state.slot)`.
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#### `CASPER_SLASHING`
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* Verify that `len(intersection) >= 1`.
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* Verify that `vote_1.data.justified_slot + 1 < vote_2.data.justified_slot + 1 == vote_2.data.slot < vote_1.data.slot` or `vote_1.data.slot == vote_2.data.slot`.
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For each [validator](#dfn-validator) index `i` in `intersection`, if `state.validator_registry[i].status` does not equal `EXITED_WITH_PENALTY`, then run `exit_validator(i, state, penalize=True, current_slot=block.slot)`
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For each [validator](#dfn-validator) index `i` in `intersection`, if `state.validator_registry[i].status` does not equal `EXITED_WITH_PENALTY`, then run `exit_validator(i, state, penalize=True, current_slot=state.slot)`
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#### `PROPOSER_SLASHING`
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* Verify that `proposal_data_1 != proposal_data_2`.
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* Verify that `proposal_data_1.slot == proposal_data_2.slot`.
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* Verify that `state.validator_registry[proposer_index].status != EXITED_WITH_PENALTY`.
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* Run `exit_validator(proposer_index, state, penalize=True, current_slot=block.slot)`.
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* Run `exit_validator(proposer_index, state, penalize=True, current_slot=state.slot)`.
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#### `DEPOSIT_PROOF`
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@ -1320,7 +1324,7 @@ def verify_merkle_branch(leaf: Hash32, branch: [Hash32], depth: int, index: int,
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return value == root
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```
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* Verify that `block.slot - (deposit_data.timestamp - state.genesis_time) // SLOT_DURATION < ZERO_BALANCE_VALIDATOR_TTL`.
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* Verify that `state.slot - (deposit_data.timestamp - state.genesis_time) // SLOT_DURATION < ZERO_BALANCE_VALIDATOR_TTL`.
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* Run the following:
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```python
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withdrawal_credentials=deposit_data.deposit_parameters.withdrawal_credentials,
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randao_commitment=deposit_data.deposit_parameters.randao_commitment,
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status=PENDING_ACTIVATION,
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current_slot=block.slot
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current_slot=state.slot
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)
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```
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## Epoch boundary processing
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## Per-epoch processing
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Repeat the steps in this section while `block.slot - state.latest_state_recalculation_slot >= EPOCH_LENGTH`. For simplicity, we use `s` as `state.latest_state_recalculation_slot`.
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Note that `state.latest_state_recalculation_slot` will always be a multiple of `EPOCH_LENGTH`. In the "happy case", this process will trigger, and loop once, every time `block.slot` passes a new exact multiple of `EPOCH_LENGTH`, but if a chain skips more than an entire epoch then the loop may run multiple times, incrementing `state.latest_state_recalculation_slot` by `EPOCH_LENGTH` with each iteration.
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The steps below happen when `state.slot % EPOCH_LENGTH == 0`. For simplicity we denote `state.slot - EPOCH_LENGTH` by `s`.
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### Precomputation
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[Validators](#dfn-Validator) justifying the epoch boundary block at the start of the current epoch:
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* Let `this_epoch_attestations = [a for a in state.latest_attestations if s <= a.data.slot < s + EPOCH_LENGTH]`. (note: this is the set of attestations _of slots in the epoch `s...s+EPOCH_LENGTH-1`_, not attestations _that got included in the chain during the epoch `s...s+EPOCH_LENGTH-1`_)
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* Let `this_epoch_attestations = [a for a in state.latest_attestations if s <= a.data.slot < s + EPOCH_LENGTH]`. (Note: this is the set of attestations of slots in the epoch `s...s+EPOCH_LENGTH-1`, _not_ attestations that got included in the chain during the epoch `s...s+EPOCH_LENGTH-1`.)
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* Let `this_epoch_boundary_attestations = [a for a in this_epoch_attestations if a.data.epoch_boundary_hash == get_block_hash(state, block, s) and a.justified_slot == state.justified_slot]`.
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* Let `this_epoch_boundary_attesters` be the union of the [validator](#dfn-validator) index sets given by `[get_attestation_participants(state, a.data, a.participation_bitfield) for a in this_epoch_boundary_attestations]`.
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* Let `this_epoch_boundary_attesting_balance = sum([get_effective_balance(v) for v in this_epoch_boundary_attesters])`.
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@ -1393,13 +1395,13 @@ For any [validator](#dfn-validator) `v`, let `base_reward(v) = get_effective_bal
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For every `ShardCommittee` object `obj`:
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* If `3 * total_attesting_balance(obj) >= 2 * total_balance(obj)`, set `crosslinks[shard] = CrosslinkRecord(slot=state.latest_state_recalculation_slot + EPOCH_LENGTH, hash=winning_hash(obj))`.
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* If `3 * total_attesting_balance(obj) >= 2 * total_balance(obj)`, set `crosslinks[shard] = CrosslinkRecord(slot=state.slot, hash=winning_hash(obj))`.
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### Balance recalculations related to FFG rewards
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Note: When applying penalties in the following balance recalculations implementers should make sure the `uint64` does not underflow.
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* Let `time_since_finality = block.slot - state.finalized_slot`.
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* Let `time_since_finality = state.slot - state.finalized_slot`.
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Case 1: `time_since_finality <= 4 * EPOCH_LENGTH`:
|
||||
|
||||
|
@ -1420,19 +1422,19 @@ For every `ShardCommittee` object `obj` in `state.shard_committees_at_slots[:EPO
|
|||
* If `v in attesting_validators(obj)`, `v.balance += adjust_for_inclusion_distance(base_reward(v) * total_attesting_balance(obj) // total_balance(obj)), inclusion_distance(v))`.
|
||||
* If `v not in attesting_validators(obj)`, `v.balance -= base_reward(v)`.
|
||||
|
||||
### Ethereum 1.0 chain related rules
|
||||
### Receipt root voting
|
||||
|
||||
If `state.latest_state_recalculation_slot % POW_RECEIPT_ROOT_VOTING_PERIOD == 0`, then:
|
||||
If `state.slot % POW_RECEIPT_ROOT_VOTING_PERIOD == 0`, then:
|
||||
|
||||
* If for any `x` in `state.candidate_pow_receipt_root`, `x.votes * 2 >= POW_RECEIPT_ROOT_VOTING_PERIOD` set `state.processed_pow_receipt_root = x.receipt_root`.
|
||||
* Set `state.processed_pow_receipt_root = x.receipt_root` if `x.votes * 2 > POW_RECEIPT_ROOT_VOTING_PERIOD` for any `x` in `state.candidate_pow_receipt_root`.
|
||||
* Set `state.candidate_pow_receipt_roots = []`.
|
||||
|
||||
### Validator registry change
|
||||
|
||||
A [validator](#dfn-validator) registry change occurs if all of the following criteria are satisfied:
|
||||
A [validator](#dfn-validator) registry change occurs if the following criteria are satisfied:
|
||||
|
||||
* `state.finalized_slot > state.validator_registry_latest_change_slot`
|
||||
* For every shard number `shard` in `state.shard_committees_at_slots`, `crosslinks[shard].slot > state.validator_registry_latest_change_slot`
|
||||
* `crosslinks[shard].slot > state.validator_registry_latest_change_slot` for every shard number `shard` in `state.shard_committees_at_slots`
|
||||
|
||||
A helper function is defined as:
|
||||
|
||||
|
@ -1528,18 +1530,17 @@ def change_validators(state: BeaconState,
|
|||
)
|
||||
```
|
||||
|
||||
And perform the following updates to the `state`:
|
||||
And perform the following updates:
|
||||
|
||||
* Set `state.validator_registry_latest_change_slot = s + EPOCH_LENGTH`.
|
||||
* Set `state.validator_registry_latest_change_slot = state.slot`.
|
||||
* Set `state.shard_committees_at_slots[:EPOCH_LENGTH] = state.shard_committees_at_slots[EPOCH_LENGTH:]`.
|
||||
* Let `next_start_shard = (state.shard_committees_at_slots[-1][-1].shard + 1) % SHARD_COUNT`.
|
||||
* Set `state.shard_committees_at_slots[EPOCH_LENGTH:] = get_new_shuffling(state.next_seed, state.validator_registry, next_start_shard)`.
|
||||
* Set `state.shard_committees_at_slots[EPOCH_LENGTH:] = get_new_shuffling(state.next_seed, state.validator_registry, next_start_shard)` where next_start_shard = (state.shard_committees_at_slots[-1][-1].shard + 1) % SHARD_COUNT`.
|
||||
* Set `state.next_seed = state.randao_mix`.
|
||||
|
||||
### If a validator registry change does NOT happen
|
||||
|
||||
* Set `state.shard_committees_at_slots[:EPOCH_LENGTH] = state.shard_committees_at_slots[EPOCH_LENGTH:]`.
|
||||
* Let `time_since_finality = block.slot - state.validator_registry_latest_change_slot`.
|
||||
* Let `time_since_finality = state.slot - state.validator_registry_latest_change_slot`.
|
||||
* Let `start_shard = state.shard_committees_at_slots[0][0].shard`.
|
||||
* If `time_since_finality * EPOCH_LENGTH <= MIN_VALIDATOR_REGISTRY_CHANGE_INTERVAL` or `time_since_finality` is an exact power of 2, set `state.shard_committees_at_slots[EPOCH_LENGTH:] = get_new_shuffling(state.next_seed, state.validator_registry, start_shard)` and set `state.next_seed = state.randao_mix`. Note that `start_shard` is not changed from the last epoch.
|
||||
|
||||
|
@ -1573,9 +1574,8 @@ while len(state.persistent_committee_reassignments) > 0 and state.persistent_com
|
|||
### Finally...
|
||||
|
||||
* Remove all attestation records older than slot `s`.
|
||||
* For any [validator](#dfn-validator) with index `i` with balance less than `MIN_BALANCE` and status `ACTIVE`, run `exit_validator(i, state, penalize=False, current_slot=block.slot)`.
|
||||
* For any [validator](#dfn-validator) with index `i` with balance less than `MIN_BALANCE` and status `ACTIVE`, run `exit_validator(i, state, penalize=False, current_slot=state.slot)`.
|
||||
* Set `state.latest_block_hashes = state.latest_block_hashes[EPOCH_LENGTH:]`.
|
||||
* Set `state.latest_state_recalculation_slot += EPOCH_LENGTH`.
|
||||
|
||||
# Appendix
|
||||
## Appendix A - Hash function
|
||||
|
|
Loading…
Reference in New Issue