# Ethereum 2.0 Phase 0 -- The Beacon Chain **NOTICE**: This document is a work in progress for researchers and implementers. ## Table of contents - [Ethereum 2.0 Phase 0 -- The Beacon Chain](#ethereum-20-phase-0----the-beacon-chain) - [Table of contents](#table-of-contents) - [Introduction](#introduction) - [Notation](#notation) - [Terminology](#terminology) - [Constants](#constants) - [Misc](#misc) - [Deposit contract](#deposit-contract) - [Gwei values](#gwei-values) - [Initial values](#initial-values) - [Time parameters](#time-parameters) - [State list lengths](#state-list-lengths) - [Reward and penalty quotients](#reward-and-penalty-quotients) - [Max operations per block](#max-operations-per-block) - [Signature domains](#signature-domains) - [Data structures](#data-structures) - [Misc dependencies](#misc-dependencies) - [`Fork`](#fork) - [`Crosslink`](#crosslink) - [`Eth1Data`](#eth1data) - [`AttestationData`](#attestationdata) - [`AttestationDataAndCustodyBit`](#attestationdataandcustodybit) - [`IndexedAttestation`](#indexedattestation) - [`DepositData`](#depositdata) - [`BeaconBlockHeader`](#beaconblockheader) - [`Validator`](#validator) - [`PendingAttestation`](#pendingattestation) - [`HistoricalBatch`](#historicalbatch) - [Beacon operations](#beacon-operations) - [`ProposerSlashing`](#proposerslashing) - [`AttesterSlashing`](#attesterslashing) - [`Attestation`](#attestation) - [`Deposit`](#deposit) - [`VoluntaryExit`](#voluntaryexit) - [`Transfer`](#transfer) - [Beacon blocks](#beacon-blocks) - [`BeaconBlockBody`](#beaconblockbody) - [`BeaconBlock`](#beaconblock) - [Beacon state](#beacon-state) - [`BeaconState`](#beaconstate) - [Custom Types](#custom-types) - [Helper functions](#helper-functions) - [`xor`](#xor) - [`hash`](#hash) - [`hash_tree_root`](#hash_tree_root) - [`signing_root`](#signing_root) - [`slot_to_epoch`](#slot_to_epoch) - [`get_previous_epoch`](#get_previous_epoch) - [`get_current_epoch`](#get_current_epoch) - [`get_epoch_start_slot`](#get_epoch_start_slot) - [`is_active_validator`](#is_active_validator) - [`is_slashable_validator`](#is_slashable_validator) - [`get_active_validator_indices`](#get_active_validator_indices) - [`increase_balance`](#increase_balance) - [`decrease_balance`](#decrease_balance) - [`get_epoch_committee_count`](#get_epoch_committee_count) - [`get_shard_delta`](#get_shard_delta) - [`get_epoch_start_shard`](#get_epoch_start_shard) - [`get_attestation_slot`](#get_attestation_slot) - [`get_block_root_at_slot`](#get_block_root_at_slot) - [`get_block_root`](#get_block_root) - [`get_randao_mix`](#get_randao_mix) - [`get_active_index_root`](#get_active_index_root) - [`generate_seed`](#generate_seed) - [`get_beacon_proposer_index`](#get_beacon_proposer_index) - [`verify_merkle_branch`](#verify_merkle_branch) - [`get_shuffled_index`](#get_shuffled_index) - [`get_crosslink_committee`](#get_crosslink_committee) - [`get_attesting_indices`](#get_attesting_indices) - [`int_to_bytes1`, `int_to_bytes2`, ...](#int_to_bytes1-int_to_bytes2-) - [`bytes_to_int`](#bytes_to_int) - [`get_total_balance`](#get_total_balance) - [`get_domain`](#get_domain) - [`get_bitfield_bit`](#get_bitfield_bit) - [`verify_bitfield`](#verify_bitfield) - [`convert_to_indexed`](#convert_to_indexed) - [`verify_indexed_attestation`](#verify_indexed_attestation) - [`integer_squareroot`](#integer_squareroot) - [`get_delayed_activation_exit_epoch`](#get_delayed_activation_exit_epoch) - [`get_churn_limit`](#get_churn_limit) - [`bls_verify`](#bls_verify) - [`bls_verify_multiple`](#bls_verify_multiple) - [`bls_aggregate_pubkeys`](#bls_aggregate_pubkeys) - [Routines for updating validator status](#routines-for-updating-validator-status) - [`initiate_validator_exit`](#initiate_validator_exit) - [`slash_validator`](#slash_validator) - [On genesis](#on-genesis) - [Beacon chain state transition function](#beacon-chain-state-transition-function) - [State caching](#state-caching) - [Per-epoch processing](#per-epoch-processing) - [Helper functions](#helper-functions-1) - [Justification and finalization](#justification-and-finalization) - [Crosslinks](#crosslinks) - [Rewards and penalties](#rewards-and-penalties) - [Registry updates](#registry-updates) - [Slashings](#slashings) - [Final updates](#final-updates) - [Per-slot processing](#per-slot-processing) - [Per-block processing](#per-block-processing) - [Block header](#block-header) - [RANDAO](#randao) - [Eth1 data](#eth1-data) - [Operations](#operations) - [Proposer slashings](#proposer-slashings) - [Attester slashings](#attester-slashings) - [Attestations](#attestations) - [Deposits](#deposits) - [Voluntary exits](#voluntary-exits) - [Transfers](#transfers) - [State root verification](#state-root-verification) ## Introduction This document represents the specification for Phase 0 of Ethereum 2.0 -- The Beacon Chain. At the core of Ethereum 2.0 is a system chain called the "beacon chain". The beacon chain stores and manages the registry of [validators](#dfn-validator). In the initial deployment phases of Ethereum 2.0, the only mechanism to become a [validator](#dfn-validator) is to make a one-way ETH transaction to a deposit contract on Ethereum 1.0. Activation as a [validator](#dfn-validator) happens when Ethereum 1.0 deposit receipts are processed by the beacon chain, the activation balance is reached, and a queuing process is completed. Exit is either voluntary or done forcibly as a penalty for misbehavior. The primary source of load on the beacon chain is "attestations". Attestations are simultaneously availability votes for a shard block and proof-of-stake votes for a beacon block. A sufficient number of attestations for the same shard block create a "crosslink", confirming the shard segment up to that shard block into the beacon chain. Crosslinks also serve as infrastructure for asynchronous cross-shard communication. ## Notation Code snippets appearing in `this style` are to be interpreted as Python code. ## Terminology * **Validator** - a registered participant in the beacon chain. You can become one by sending ether into the Ethereum 1.0 deposit contract. * **Active validator** - an active participant in the Ethereum 2.0 consensus invited to, among other things, propose and attest to blocks and vote for crosslinks. * **Committee** - a (pseudo-) randomly sampled subset of [active validators](#dfn-active-validator). When a committee is referred to collectively, as in "this committee attests to X", this is assumed to mean "some subset of that committee that contains enough [validators](#dfn-validator) that the protocol recognizes it as representing the committee". * **Proposer** - the [validator](#dfn-validator) that creates a beacon chain block. * **Attester** - a [validator](#dfn-validator) that is part of a committee that needs to sign off on a beacon chain block while simultaneously creating a link (crosslink) to a recent shard block on a particular shard chain. * **Beacon chain** - the central PoS chain that is the base of the sharding system. * **Shard chain** - one of the chains on which user transactions take place and account data is stored. * **Block root** - a 32-byte Merkle root of a beacon chain block or shard chain block. Previously called "block hash". * **Crosslink** - a set of signatures from a committee attesting to a block in a shard chain that can be included into the beacon chain. Crosslinks are the main means by which the beacon chain "learns about" the updated state of shard chains. * **Slot** - a period during which one proposer has the ability to create a beacon chain block and some attesters have the ability to make attestations. * **Epoch** - an aligned span of slots during which all [validators](#dfn-validator) get exactly one chance to make an attestation. * **Finalized**, **justified** - see the [Casper FFG paper](https://arxiv.org/abs/1710.09437). * **Withdrawal period** - the number of slots between a [validator](#dfn-validator) exit and the [validator](#dfn-validator) balance being withdrawable. * **Genesis time** - the Unix time of the genesis beacon chain block at slot 0. ## Constants Note: the default mainnet values for the constants are included here for spec-design purposes. The different configurations for mainnet, testnets, and yaml-based testing can be found in the `configs/constant_presets/` directory. These configurations are updated for releases, but may be out of sync during `dev` changes. ### Misc | Name | Value | | - | - | | `SHARD_COUNT` | `2**10` (= 1,024) | | `TARGET_COMMITTEE_SIZE` | `2**7` (= 128) | | `MAX_INDICES_PER_ATTESTATION` | `2**12` (= 4,096) | | `MIN_PER_EPOCH_CHURN_LIMIT` | `2**2` (= 4) | | `CHURN_LIMIT_QUOTIENT` | `2**16` (= 65,536) | | `BASE_REWARDS_PER_EPOCH` | `5` | | `SHUFFLE_ROUND_COUNT` | 90 | * For the safety of crosslinks `TARGET_COMMITTEE_SIZE` exceeds [the recommended minimum committee size of 111](https://vitalik.ca/files/Ithaca201807_Sharding.pdf); with sufficient active validators (at least `SLOTS_PER_EPOCH * TARGET_COMMITTEE_SIZE`), the shuffling algorithm ensures committee sizes of at least `TARGET_COMMITTEE_SIZE`. (Unbiasable randomness with a Verifiable Delay Function (VDF) will improve committee robustness and lower the safe minimum committee size.) ### Deposit contract | Name | Value | | - | - | | `DEPOSIT_CONTRACT_TREE_DEPTH` | `2**5` (= 32) | ### Gwei values | Name | Value | Unit | | - | - | :-: | | `MIN_DEPOSIT_AMOUNT` | `2**0 * 10**9` (= 1,000,000,000) | Gwei | | `MAX_EFFECTIVE_BALANCE` | `2**5 * 10**9` (= 32,000,000,000) | Gwei | | `EJECTION_BALANCE` | `2**4 * 10**9` (= 16,000,000,000) | Gwei | | `EFFECTIVE_BALANCE_INCREMENT` | `2**0 * 10**9` (= 1,000,000,000) | Gwei | ### Initial values | Name | Value | | - | - | | `GENESIS_SLOT` | `0` | | `GENESIS_EPOCH` | `0` | | `FAR_FUTURE_EPOCH` | `2**64 - 1` | | `ZERO_HASH` | `int_to_bytes32(0)` | | `BLS_WITHDRAWAL_PREFIX_BYTE` | `int_to_bytes1(0)` | ### Time parameters | Name | Value | Unit | Duration | | - | - | :-: | :-: | | `MIN_ATTESTATION_INCLUSION_DELAY` | `2**2` (= 4) | slots | 24 seconds | | `SLOTS_PER_EPOCH` | `2**6` (= 64) | slots | 6.4 minutes | | `MIN_SEED_LOOKAHEAD` | `2**0` (= 1) | epochs | 6.4 minutes | | `ACTIVATION_EXIT_DELAY` | `2**2` (= 4) | epochs | 25.6 minutes | | `SLOTS_PER_ETH1_VOTING_PERIOD` | `2**10` (= 1,024) | slots | ~1.7 hours | | `SLOTS_PER_HISTORICAL_ROOT` | `2**13` (= 8,192) | slots | ~13 hours | | `MIN_VALIDATOR_WITHDRAWABILITY_DELAY` | `2**8` (= 256) | epochs | ~27 hours | | `PERSISTENT_COMMITTEE_PERIOD` | `2**11` (= 2,048) | epochs | 9 days | | `MAX_CROSSLINK_EPOCHS` | `2**6` (= 64) | epochs | ~7 hours | | `MIN_EPOCHS_TO_INACTIVITY_PENALTY` | `2**2` (= 4) | epochs | 25.6 minutes | * `MAX_CROSSLINK_EPOCHS` should be a small constant times `SHARD_COUNT // SLOTS_PER_EPOCH` ### State list lengths | Name | Value | Unit | Duration | | - | - | :-: | :-: | | `LATEST_RANDAO_MIXES_LENGTH` | `2**13` (= 8,192) | epochs | ~36 days | | `LATEST_ACTIVE_INDEX_ROOTS_LENGTH` | `2**13` (= 8,192) | epochs | ~36 days | | `LATEST_SLASHED_EXIT_LENGTH` | `2**13` (= 8,192) | epochs | ~36 days | ### Reward and penalty quotients | Name | Value | | - | - | | `BASE_REWARD_QUOTIENT` | `2**5` (= 32) | | `WHISTLEBLOWING_REWARD_QUOTIENT` | `2**9` (= 512) | | `PROPOSER_REWARD_QUOTIENT` | `2**3` (= 8) | | `INACTIVITY_PENALTY_QUOTIENT` | `2**25` (= 33,554,432) | | `MIN_SLASHING_PENALTY_QUOTIENT` | `2**5` (= 32) | * **The `BASE_REWARD_QUOTIENT` is NOT final. Once all other protocol details are finalized it will be adjusted, to target a theoretical maximum total issuance of `2**21` ETH per year if `2**27` ETH is validating (and therefore `2**20` per year if `2**25` ETH is validating, etc etc)** * The `INACTIVITY_PENALTY_QUOTIENT` equals `INVERSE_SQRT_E_DROP_TIME**2` where `INVERSE_SQRT_E_DROP_TIME := 2**12 epochs` (~18 days) is the time it takes the inactivity penalty to reduce the balance of non-participating [validators](#dfn-validator) to about `1/sqrt(e) ~= 60.6%`. Indeed, the balance retained by offline [validators](#dfn-validator) after `n` epochs is about `(1 - 1/INACTIVITY_PENALTY_QUOTIENT)**(n**2/2)` so after `INVERSE_SQRT_E_DROP_TIME` epochs it is roughly `(1 - 1/INACTIVITY_PENALTY_QUOTIENT)**(INACTIVITY_PENALTY_QUOTIENT/2) ~= 1/sqrt(e)`. ### Max operations per block | Name | Value | | - | - | | `MAX_PROPOSER_SLASHINGS` | `2**4` (= 16) | | `MAX_ATTESTER_SLASHINGS` | `2**0` (= 1) | | `MAX_ATTESTATIONS` | `2**7` (= 128) | | `MAX_DEPOSITS` | `2**4` (= 16) | | `MAX_VOLUNTARY_EXITS` | `2**4` (= 16) | | `MAX_TRANSFERS` | `0` | ### Signature domains | Name | Value | | - | - | | `DOMAIN_BEACON_PROPOSER` | `0` | | `DOMAIN_RANDAO` | `1` | | `DOMAIN_ATTESTATION` | `2` | | `DOMAIN_DEPOSIT` | `3` | | `DOMAIN_VOLUNTARY_EXIT` | `4` | | `DOMAIN_TRANSFER` | `5` | ## Data structures The following data structures are defined as [SimpleSerialize (SSZ)](../simple-serialize.md) objects. The types are defined topologically to aid in facilitating an executable version of the spec. ### Misc dependencies #### `Fork` ```python { # Previous fork version 'previous_version': 'bytes4', # Current fork version 'current_version': 'bytes4', # Fork epoch number 'epoch': 'uint64', } ``` #### `Crosslink` ```python { # Epoch number 'epoch': 'uint64', # Root of the previous crosslink 'previous_crosslink_root': 'bytes32', # Root of the crosslinked shard data since the previous crosslink 'crosslink_data_root': 'bytes32', } ``` #### `Eth1Data` ```python { # Root of the deposit tree 'deposit_root': 'bytes32', # Total number of deposits 'deposit_count': 'uint64', # Block hash 'block_hash': 'bytes32', } ``` #### `AttestationData` ```python { # LMD GHOST vote 'beacon_block_root': 'bytes32', # FFG vote 'source_epoch': 'uint64', 'source_root': 'bytes32', 'target_epoch': 'uint64', 'target_root': 'bytes32', # Crosslink vote 'shard': 'uint64', 'previous_crosslink_root': 'bytes32', 'crosslink_data_root': 'bytes32', } ``` #### `AttestationDataAndCustodyBit` ```python { # Attestation data 'data': AttestationData, # Custody bit 'custody_bit': 'bool', } ``` #### `IndexedAttestation` ```python { # Validator indices 'custody_bit_0_indices': ['uint64'], 'custody_bit_1_indices': ['uint64'], # Attestation data 'data': AttestationData, # Aggregate signature 'signature': 'bytes96', } ``` #### `DepositData` ```python { # BLS pubkey 'pubkey': 'bytes48', # Withdrawal credentials 'withdrawal_credentials': 'bytes32', # Amount in Gwei 'amount': 'uint64', # Container self-signature 'signature': 'bytes96', } ``` #### `BeaconBlockHeader` ```python { 'slot': 'uint64', 'previous_block_root': 'bytes32', 'state_root': 'bytes32', 'block_body_root': 'bytes32', 'signature': 'bytes96', } ``` #### `Validator` ```python { # BLS public key 'pubkey': 'bytes48', # Withdrawal credentials 'withdrawal_credentials': 'bytes32', # Epoch when became eligible for activation 'activation_eligibility_epoch': 'uint64', # Epoch when validator activated 'activation_epoch': 'uint64', # Epoch when validator exited 'exit_epoch': 'uint64', # Epoch when validator is eligible to withdraw 'withdrawable_epoch': 'uint64', # Was the validator slashed 'slashed': 'bool', # Effective balance 'effective_balance': 'uint64', } ``` #### `PendingAttestation` ```python { # Attester aggregation bitfield 'aggregation_bitfield': 'bytes', # Attestation data 'data': AttestationData, # Inclusion delay 'inclusion_delay': 'uint64', # Proposer index 'proposer_index': 'uint64', } ``` #### `HistoricalBatch` ```python { # Block roots 'block_roots': ['bytes32', SLOTS_PER_HISTORICAL_ROOT], # State roots 'state_roots': ['bytes32', SLOTS_PER_HISTORICAL_ROOT], } ``` ### Beacon operations #### `ProposerSlashing` ```python { # Proposer index 'proposer_index': 'uint64', # First block header 'header_1': BeaconBlockHeader, # Second block header 'header_2': BeaconBlockHeader, } ``` #### `AttesterSlashing` ```python { # First attestation 'attestation_1': IndexedAttestation, # Second attestation 'attestation_2': IndexedAttestation, } ``` #### `Attestation` ```python { # Attester aggregation bitfield 'aggregation_bitfield': 'bytes', # Attestation data 'data': AttestationData, # Custody bitfield 'custody_bitfield': 'bytes', # BLS aggregate signature 'signature': 'bytes96', } ``` #### `Deposit` ```python { # Branch in the deposit tree 'proof': ['bytes32', DEPOSIT_CONTRACT_TREE_DEPTH], # Index in the deposit tree 'index': 'uint64', # Data 'data': DepositData, } ``` #### `VoluntaryExit` ```python { # Minimum epoch for processing exit 'epoch': 'uint64', # Index of the exiting validator 'validator_index': 'uint64', # Validator signature 'signature': 'bytes96', } ``` #### `Transfer` ```python { # Sender index 'sender': 'uint64', # Recipient index 'recipient': 'uint64', # Amount in Gwei 'amount': 'uint64', # Fee in Gwei for block proposer 'fee': 'uint64', # Inclusion slot 'slot': 'uint64', # Sender withdrawal pubkey 'pubkey': 'bytes48', # Sender signature 'signature': 'bytes96', } ``` ### Beacon blocks #### `BeaconBlockBody` ```python { 'randao_reveal': 'bytes96', 'eth1_data': Eth1Data, 'proposer_slashings': [ProposerSlashing], 'attester_slashings': [AttesterSlashing], 'attestations': [Attestation], 'deposits': [Deposit], 'voluntary_exits': [VoluntaryExit], 'transfers': [Transfer], } ``` #### `BeaconBlock` ```python { # Header 'slot': 'uint64', 'previous_block_root': 'bytes32', 'state_root': 'bytes32', 'body': BeaconBlockBody, 'signature': 'bytes96', } ``` ### Beacon state #### `BeaconState` ```python { # Misc 'slot': 'uint64', 'genesis_time': 'uint64', 'fork': Fork, # For versioning hard forks # Validator registry 'validator_registry': [Validator], 'balances': ['uint64'], # Randomness and committees 'latest_randao_mixes': ['bytes32', LATEST_RANDAO_MIXES_LENGTH], 'latest_start_shard': 'uint64', # Finality 'previous_epoch_attestations': [PendingAttestation], 'current_epoch_attestations': [PendingAttestation], 'previous_justified_epoch': 'uint64', 'current_justified_epoch': 'uint64', 'previous_justified_root': 'bytes32', 'current_justified_root': 'bytes32', 'justification_bitfield': 'uint64', 'finalized_epoch': 'uint64', 'finalized_root': 'bytes32', # Recent state 'current_crosslinks': [Crosslink, SHARD_COUNT], 'previous_crosslinks': [Crosslink, SHARD_COUNT], 'latest_block_roots': ['bytes32', SLOTS_PER_HISTORICAL_ROOT], 'latest_state_roots': ['bytes32', SLOTS_PER_HISTORICAL_ROOT], 'latest_active_index_roots': ['bytes32', LATEST_ACTIVE_INDEX_ROOTS_LENGTH], 'latest_slashed_balances': ['uint64', LATEST_SLASHED_EXIT_LENGTH], # Balances slashed at every withdrawal period 'latest_block_header': BeaconBlockHeader, # `latest_block_header.state_root == ZERO_HASH` temporarily 'historical_roots': ['bytes32'], # Ethereum 1.0 chain data 'latest_eth1_data': Eth1Data, 'eth1_data_votes': [Eth1Data], 'deposit_index': 'uint64', } ``` ## Custom Types We define the following Python custom types for type hinting and readability: | Name | SSZ equivalent | Description | | - | - | - | | `Slot` | `uint64` | a slot number | | `Epoch` | `uint64` | an epoch number | | `Shard` | `uint64` | a shard number | | `ValidatorIndex` | `uint64` | a validator registry index | | `Gwei` | `uint64` | an amount in Gwei | | `Bytes32` | `bytes32` | 32 bytes of binary data | | `BLSPubkey` | `bytes48` | a BLS12-381 public key | | `BLSSignature` | `bytes96` | a BLS12-381 signature | ## Helper functions Note: The definitions below are for specification purposes and are not necessarily optimal implementations. ### `xor` ```python def xor(bytes1: Bytes32, bytes2: Bytes32) -> Bytes32: return bytes(a ^ b for a, b in zip(bytes1, bytes2)) ``` ### `hash` The `hash` function is SHA256. Note: We aim to migrate to a S[T/N]ARK-friendly hash function in a future Ethereum 2.0 deployment phase. ### `hash_tree_root` `def hash_tree_root(object: SSZSerializable) -> Bytes32` is a function for hashing objects into a single root utilizing a hash tree structure. `hash_tree_root` is defined in the [SimpleSerialize spec](../simple-serialize.md#merkleization). ### `signing_root` `def signing_root(object: SSZContainer) -> Bytes32` is a function defined in the [SimpleSerialize spec](../simple-serialize.md#self-signed-containers) to compute signing messages. ### `slot_to_epoch` ```python def slot_to_epoch(slot: Slot) -> Epoch: """ Return the epoch number of the given ``slot``. """ return slot // SLOTS_PER_EPOCH ``` ### `get_previous_epoch` ```python def get_previous_epoch(state: BeaconState) -> Epoch: """` Return the previous epoch of the given ``state``. Return the current epoch if it's genesis epoch. """ current_epoch = get_current_epoch(state) return (current_epoch - 1) if current_epoch > GENESIS_EPOCH else current_epoch ``` ### `get_current_epoch` ```python def get_current_epoch(state: BeaconState) -> Epoch: """ Return the current epoch of the given ``state``. """ return slot_to_epoch(state.slot) ``` ### `get_epoch_start_slot` ```python def get_epoch_start_slot(epoch: Epoch) -> Slot: """ Return the starting slot of the given ``epoch``. """ return epoch * SLOTS_PER_EPOCH ``` ### `is_active_validator` ```python def is_active_validator(validator: Validator, epoch: Epoch) -> bool: """ Check if ``validator`` is active. """ return validator.activation_epoch <= epoch < validator.exit_epoch ``` ### `is_slashable_validator` ```python def is_slashable_validator(validator: Validator, epoch: Epoch) -> bool: """ Check if ``validator`` is slashable. """ return validator.slashed is False and (validator.activation_epoch <= epoch < validator.withdrawable_epoch) ``` ### `get_active_validator_indices` ```python def get_active_validator_indices(state: BeaconState, epoch: Epoch) -> List[ValidatorIndex]: """ Get active validator indices at ``epoch``. """ return [i for i, v in enumerate(state.validator_registry) if is_active_validator(v, epoch)] ``` ### `increase_balance` ```python def increase_balance(state: BeaconState, index: ValidatorIndex, delta: Gwei) -> None: """ Increase validator balance by ``delta``. """ state.balances[index] += delta ``` ### `decrease_balance` ```python def decrease_balance(state: BeaconState, index: ValidatorIndex, delta: Gwei) -> None: """ Decrease validator balance by ``delta`` with underflow protection. """ state.balances[index] = 0 if delta > state.balances[index] else state.balances[index] - delta ``` ### `get_epoch_committee_count` ```python def get_epoch_committee_count(state: BeaconState, epoch: Epoch) -> int: """ Return the number of committees at ``epoch``. """ active_validator_indices = get_active_validator_indices(state, epoch) return max( 1, min( SHARD_COUNT // SLOTS_PER_EPOCH, len(active_validator_indices) // SLOTS_PER_EPOCH // TARGET_COMMITTEE_SIZE, ) ) * SLOTS_PER_EPOCH ``` ### `get_shard_delta` ```python def get_shard_delta(state: BeaconState, epoch: Epoch) -> int: """ Return the number of shards to increment ``state.latest_start_shard`` during ``epoch``. """ return min(get_epoch_committee_count(state, epoch), SHARD_COUNT - SHARD_COUNT // SLOTS_PER_EPOCH) ``` ### `get_epoch_start_shard` ```python def get_epoch_start_shard(state: BeaconState, epoch: Epoch) -> Shard: assert epoch <= get_current_epoch(state) + 1 check_epoch = get_current_epoch(state) + 1 shard = (state.latest_start_shard + get_shard_delta(state, get_current_epoch(state))) % SHARD_COUNT while check_epoch > epoch: check_epoch -= 1 shard = (shard + SHARD_COUNT - get_shard_delta(state, check_epoch)) % SHARD_COUNT return shard ``` ### `get_attestation_slot` ```python def get_attestation_slot(state: BeaconState, attestation: Attestation) -> Slot: epoch = attestation.data.target_epoch committee_count = get_epoch_committee_count(state, epoch) offset = (attestation.data.shard - get_epoch_start_slot(epoch)) % SHARD_COUNT return get_epoch_start_slot(epoch) + offset // (committee_count // SLOTS_PER_EPOCH) ``` ### `get_block_root_at_slot` ```python def get_block_root_at_slot(state: BeaconState, slot: Slot) -> Bytes32: """ Return the block root at a recent ``slot``. """ assert slot < state.slot <= slot + SLOTS_PER_HISTORICAL_ROOT return state.latest_block_roots[slot % SLOTS_PER_HISTORICAL_ROOT] ``` ### `get_block_root` ```python def get_block_root(state: BeaconState, epoch: Epoch) -> Bytes32: """ Return the block root at a recent ``epoch``. """ return get_block_root_at_slot(state, get_epoch_start_slot(epoch)) ``` ### `get_randao_mix` ```python def get_randao_mix(state: BeaconState, epoch: Epoch) -> Bytes32: """ Return the randao mix at a recent ``epoch``. """ assert get_current_epoch(state) - LATEST_RANDAO_MIXES_LENGTH < epoch <= get_current_epoch(state) return state.latest_randao_mixes[epoch % LATEST_RANDAO_MIXES_LENGTH] ``` ### `get_active_index_root` ```python def get_active_index_root(state: BeaconState, epoch: Epoch) -> Bytes32: """ Return the index root at a recent ``epoch``. """ assert get_current_epoch(state) - LATEST_ACTIVE_INDEX_ROOTS_LENGTH + ACTIVATION_EXIT_DELAY < epoch <= get_current_epoch(state) + ACTIVATION_EXIT_DELAY return state.latest_active_index_roots[epoch % LATEST_ACTIVE_INDEX_ROOTS_LENGTH] ``` ### `generate_seed` ```python def generate_seed(state: BeaconState, epoch: Epoch) -> Bytes32: """ Generate a seed for the given ``epoch``. """ return hash( get_randao_mix(state, epoch - MIN_SEED_LOOKAHEAD) + get_active_index_root(state, epoch) + int_to_bytes32(epoch) ) ``` ### `get_beacon_proposer_index` ```python def get_beacon_proposer_index(state: BeaconState) -> ValidatorIndex: """ Return the current beacon proposer index. """ epoch = get_current_epoch(state) committees_per_slot = get_epoch_committee_count(state, epoch) // SLOTS_PER_EPOCH offset = committees_per_slot * (state.slot % EPOCH_LENGTH) first_committee = get_crosslink_committee(state, epoch, offset) MAX_RANDOM_BYTE = 2**8 - 1 i = 0 while True: candidate_index = first_committee[(epoch + i) % len(first_committee)] random_byte = hash(generate_seed(state, epoch) + int_to_bytes8(i // 32))[i % 32] effective_balance = state.validator_registry[candidate_index].effective_balance if effective_balance * MAX_RANDOM_BYTE >= MAX_EFFECTIVE_BALANCE * random_byte: return candidate_index i += 1 ``` ### `verify_merkle_branch` ```python def verify_merkle_branch(leaf: Bytes32, proof: List[Bytes32], depth: int, index: int, root: Bytes32) -> bool: """ Verify that the given ``leaf`` is on the merkle branch ``proof`` starting with the given ``root``. """ value = leaf for i in range(depth): if index // (2**i) % 2: value = hash(proof[i] + value) else: value = hash(value + proof[i]) return value == root ``` ### `get_shuffled_index` ```python def get_shuffled_index(index: ValidatorIndex, index_count: int, seed: Bytes32) -> ValidatorIndex: """ Return the shuffled validator index corresponding to ``seed`` (and ``index_count``). """ assert index < index_count assert index_count <= 2**40 # Swap or not (https://link.springer.com/content/pdf/10.1007%2F978-3-642-32009-5_1.pdf) # See the 'generalized domain' algorithm on page 3 for round in range(SHUFFLE_ROUND_COUNT): pivot = bytes_to_int(hash(seed + int_to_bytes1(round))[0:8]) % index_count flip = (pivot - index) % index_count position = max(index, flip) source = hash(seed + int_to_bytes1(round) + int_to_bytes4(position // 256)) byte = source[(position % 256) // 8] bit = (byte >> (position % 8)) % 2 index = flip if bit else index return index ``` ### `get_crosslink_committee` ```python def get_crosslink_committee(state: BeaconState, epoch: Epoch, shard: Shard) -> List[ValidatorIndex]: """ Return the crosslink committee at ``epoch`` for ``shard``. """ active_indices = get_active_validator_indices(state, epoch) committee_count = get_epoch_committee_count(state, epoch) committee_index = (shard + SHARD_COUNT - get_epoch_start_shard(state, epoch)) % SHARD_COUNT start_validator_index = (len(active_indices) * committee_index) // committee_count end_validator_index = (len(active_indices) * (committee_index + 1)) // committee_count return [ active_indices[get_shuffled_index(i, len(active_indices), generate_seed(state, epoch))] for i in range(start_validator_index, end_validator_index) ] ``` ### `get_attesting_indices` ```python def get_attesting_indices(state: BeaconState, attestation_data: AttestationData, bitfield: bytes) -> List[ValidatorIndex]: """ Return the sorted attesting indices corresponding to ``attestation_data`` and ``bitfield``. """ committee = get_crosslink_committee(state, attestation_data.target_epoch, attestation_data.shard) assert verify_bitfield(bitfield, len(committee)) return sorted([index for i, index in enumerate(committee) if get_bitfield_bit(bitfield, i) == 0b1]) ``` ### `int_to_bytes1`, `int_to_bytes2`, ... `int_to_bytes1(x): return x.to_bytes(1, 'little')`, `int_to_bytes2(x): return x.to_bytes(2, 'little')`, and so on for all integers, particularly 1, 2, 3, 4, 8, 32, 48, 96. ### `bytes_to_int` ```python def bytes_to_int(data: bytes) -> int: return int.from_bytes(data, 'little') ``` ### `get_total_balance` ```python def get_total_balance(state: BeaconState, indices: List[ValidatorIndex]) -> Gwei: """ Return the combined effective balance of an array of ``validators``. """ return sum([state.validator_registry[index].effective_balance for index in indices]) ``` ### `get_domain` ```python def get_domain(state: BeaconState, domain_type: int, message_epoch: int=None) -> int: """ Return the signature domain (fork version concatenated with domain type) of a message. """ epoch = get_current_epoch(state) if message_epoch is None else message_epoch fork_version = state.fork.previous_version if epoch < state.fork.epoch else state.fork.current_version return bytes_to_int(fork_version + int_to_bytes4(domain_type)) ``` ### `get_bitfield_bit` ```python def get_bitfield_bit(bitfield: bytes, i: int) -> int: """ Extract the bit in ``bitfield`` at position ``i``. """ return (bitfield[i // 8] >> (i % 8)) % 2 ``` ### `verify_bitfield` ```python def verify_bitfield(bitfield: bytes, committee_size: int) -> bool: """ Verify ``bitfield`` against the ``committee_size``. """ if len(bitfield) != (committee_size + 7) // 8: return False # Check `bitfield` is padded with zero bits only for i in range(committee_size, len(bitfield) * 8): if get_bitfield_bit(bitfield, i) == 0b1: return False return True ``` ### `convert_to_indexed` ```python def convert_to_indexed(state: BeaconState, attestation: Attestation) -> IndexedAttestation: """ Convert ``attestation`` to (almost) indexed-verifiable form. """ attesting_indices = get_attesting_indices(state, attestation.data, attestation.aggregation_bitfield) custody_bit_1_indices = get_attesting_indices(state, attestation.data, attestation.custody_bitfield) custody_bit_0_indices = [index for index in attesting_indices if index not in custody_bit_1_indices] return IndexedAttestation( custody_bit_0_indices=custody_bit_0_indices, custody_bit_1_indices=custody_bit_1_indices, data=attestation.data, signature=attestation.signature, ) ``` ### `verify_indexed_attestation` ```python def verify_indexed_attestation(state: BeaconState, indexed_attestation: IndexedAttestation) -> bool: """ Verify validity of ``indexed_attestation`` fields. """ custody_bit_0_indices = indexed_attestation.custody_bit_0_indices custody_bit_1_indices = indexed_attestation.custody_bit_1_indices # Ensure no duplicate indices across custody bits assert len(set(custody_bit_0_indices).intersection(set(custody_bit_1_indices))) == 0 if len(custody_bit_1_indices) > 0: # [TO BE REMOVED IN PHASE 1] return False if not (1 <= len(custody_bit_0_indices) + len(custody_bit_1_indices) <= MAX_INDICES_PER_ATTESTATION): return False if custody_bit_0_indices != sorted(custody_bit_0_indices): return False if custody_bit_1_indices != sorted(custody_bit_1_indices): return False return bls_verify_multiple( pubkeys=[ bls_aggregate_pubkeys([state.validator_registry[i].pubkey for i in custody_bit_0_indices]), bls_aggregate_pubkeys([state.validator_registry[i].pubkey for i in custody_bit_1_indices]), ], message_hashes=[ hash_tree_root(AttestationDataAndCustodyBit(data=indexed_attestation.data, custody_bit=0b0)), hash_tree_root(AttestationDataAndCustodyBit(data=indexed_attestation.data, custody_bit=0b1)), ], signature=indexed_attestation.signature, domain=get_domain(state, DOMAIN_ATTESTATION, indexed_attestation.data.target_epoch), ) ``` ### `integer_squareroot` ```python def integer_squareroot(n: int) -> int: """ The largest integer ``x`` such that ``x**2`` is less than or equal to ``n``. """ assert n >= 0 x = n y = (x + 1) // 2 while y < x: x = y y = (x + n // x) // 2 return x ``` ### `get_delayed_activation_exit_epoch` ```python def get_delayed_activation_exit_epoch(epoch: Epoch) -> Epoch: """ Return the epoch at which an activation or exit triggered in ``epoch`` takes effect. """ return epoch + 1 + ACTIVATION_EXIT_DELAY ``` ### `get_churn_limit` ```python def get_churn_limit(state: BeaconState) -> int: return max( MIN_PER_EPOCH_CHURN_LIMIT, len(get_active_validator_indices(state, get_current_epoch(state))) // CHURN_LIMIT_QUOTIENT ) ``` ### `bls_verify` `bls_verify` is a function for verifying a BLS signature, defined in the [BLS Signature spec](../bls_signature.md#bls_verify). ### `bls_verify_multiple` `bls_verify_multiple` is a function for verifying a BLS signature constructed from multiple messages, defined in the [BLS Signature spec](../bls_signature.md#bls_verify_multiple). ### `bls_aggregate_pubkeys` `bls_aggregate_pubkeys` is a function for aggregating multiple BLS public keys into a single aggregate key, defined in the [BLS Signature spec](../bls_signature.md#bls_aggregate_pubkeys). ### Routines for updating validator status Note: All functions in this section mutate `state`. #### `initiate_validator_exit` ```python def initiate_validator_exit(state: BeaconState, index: ValidatorIndex) -> None: """ Initiate the validator of the given ``index``. """ # Return if validator already initiated exit validator = state.validator_registry[index] if validator.exit_epoch != FAR_FUTURE_EPOCH: return # Compute exit queue epoch exit_epochs = [v.exit_epoch for v in state.validator_registry if v.exit_epoch != FAR_FUTURE_EPOCH] exit_queue_epoch = max(exit_epochs + [get_delayed_activation_exit_epoch(get_current_epoch(state))]) exit_queue_churn = len([v for v in state.validator_registry if v.exit_epoch == exit_queue_epoch]) if exit_queue_churn >= get_churn_limit(state): exit_queue_epoch += 1 # Set validator exit epoch and withdrawable epoch validator.exit_epoch = exit_queue_epoch validator.withdrawable_epoch = validator.exit_epoch + MIN_VALIDATOR_WITHDRAWABILITY_DELAY ``` #### `slash_validator` ```python def slash_validator(state: BeaconState, slashed_index: ValidatorIndex, whistleblower_index: ValidatorIndex=None) -> None: """ Slash the validator with index ``slashed_index``. """ current_epoch = get_current_epoch(state) initiate_validator_exit(state, slashed_index) state.validator_registry[slashed_index].slashed = True state.validator_registry[slashed_index].withdrawable_epoch = current_epoch + LATEST_SLASHED_EXIT_LENGTH slashed_balance = state.validator_registry[slashed_index].effective_balance state.latest_slashed_balances[current_epoch % LATEST_SLASHED_EXIT_LENGTH] += slashed_balance proposer_index = get_beacon_proposer_index(state) if whistleblower_index is None: whistleblower_index = proposer_index whistleblowing_reward = slashed_balance // WHISTLEBLOWING_REWARD_QUOTIENT proposer_reward = whistleblowing_reward // PROPOSER_REWARD_QUOTIENT increase_balance(state, proposer_index, proposer_reward) increase_balance(state, whistleblower_index, whistleblowing_reward - proposer_reward) decrease_balance(state, slashed_index, whistleblowing_reward) ``` ## On genesis When enough full deposits have been made to the deposit contract, an `Eth2Genesis` log is emitted. Construct a corresponding `genesis_state` and `genesis_block` as follows: * Let `genesis_validator_deposits` be the list of deposits, ordered chronologically, up to and including the deposit that triggered the `Eth2Genesis` log. * Let `genesis_time` be the timestamp specified in the `Eth2Genesis` log. * Let `genesis_eth1_data` be the `Eth1Data` object where: * `genesis_eth1_data.deposit_root` is the `deposit_root` contained in the `Eth2Genesis` log. * `genesis_eth1_data.deposit_count` is the `deposit_count` contained in the `Eth2Genesis` log. * `genesis_eth1_data.block_hash` is the hash of the Ethereum 1.0 block that emitted the `Eth2Genesis` log. * Let `genesis_state = get_genesis_beacon_state(genesis_validator_deposits, genesis_time, genesis_eth1_data)`. * Let `genesis_block = BeaconBlock(state_root=hash_tree_root(genesis_state))`. ```python def get_genesis_beacon_state(genesis_validator_deposits: List[Deposit], genesis_time: int, genesis_eth1_data: Eth1Data) -> BeaconState: """ Get the genesis ``BeaconState``. """ state = BeaconState(genesis_time=genesis_time, latest_eth1_data=genesis_eth1_data) # Process genesis deposits for deposit in genesis_validator_deposits: process_deposit(state, deposit) # Process genesis activations for index, validator in enumerate(state.validator_registry): if validator.effective_balance >= MAX_EFFECTIVE_BALANCE: validator.activation_eligibility_epoch = GENESIS_EPOCH validator.activation_epoch = GENESIS_EPOCH genesis_active_index_root = hash_tree_root(get_active_validator_indices(state, GENESIS_EPOCH)) for index in range(LATEST_ACTIVE_INDEX_ROOTS_LENGTH): state.latest_active_index_roots[index] = genesis_active_index_root return state ``` ## Beacon chain state transition function We now define the state transition function. At a high level, the state transition is made up of four parts: 1. State caching, which happens at the start of every slot. 2. The per-epoch transitions, which happens at the start of the first slot of every epoch. 3. The per-slot transitions, which happens at every slot. 4. The per-block transitions, which happens at every block. Transition section notes: * The state caching caches the state root of the previous slot and updates block and state roots records. * 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 focus on the slot counter. * The per-block transitions generally focus on verifying aggregate signatures and saving temporary records relating to the per-block activity in the `BeaconState`. Beacon blocks that trigger unhandled Python exceptions (e.g. out-of-range list accesses) and failed `assert`s during the state transition are considered invalid. Note: If there are skipped slots between a block and its parent block, run the steps in the [state-root](#state-caching), [per-epoch](#per-epoch-processing), and [per-slot](#per-slot-processing) sections once for each skipped slot and then once for the slot containing the new block. ### State caching At every `slot > GENESIS_SLOT` run the following function: ```python def cache_state(state: BeaconState) -> None: # Cache latest known state root (for previous slot) latest_state_root = hash_tree_root(state) state.latest_state_roots[state.slot % SLOTS_PER_HISTORICAL_ROOT] = latest_state_root # Store latest known state root (for previous slot) in latest_block_header if it is empty if state.latest_block_header.state_root == ZERO_HASH: state.latest_block_header.state_root = latest_state_root # Cache latest known block root (for previous slot) latest_block_root = signing_root(state.latest_block_header) state.latest_block_roots[state.slot % SLOTS_PER_HISTORICAL_ROOT] = latest_block_root ``` ### Per-epoch processing The steps below happen when `state.slot > GENESIS_SLOT and (state.slot + 1) % SLOTS_PER_EPOCH == 0`. #### Helper functions We define epoch transition helper functions: ```python def get_total_active_balance(state: BeaconState) -> Gwei: return get_total_balance(state, get_active_validator_indices(state, get_current_epoch(state))) ``` ```python def get_matching_source_attestations(state: BeaconState, epoch: Epoch) -> List[PendingAttestation]: assert epoch in (get_current_epoch(state), get_previous_epoch(state)) return state.current_epoch_attestations if epoch == get_current_epoch(state) else state.previous_epoch_attestations ``` ```python def get_matching_target_attestations(state: BeaconState, epoch: Epoch) -> List[PendingAttestation]: return [ a for a in get_matching_source_attestations(state, epoch) if a.data.target_root == get_block_root(state, epoch) ] ``` ```python def get_matching_head_attestations(state: BeaconState, epoch: Epoch) -> List[PendingAttestation]: return [ a for a in get_matching_source_attestations(state, epoch) if a.data.beacon_block_root == get_block_root_at_slot(state, get_attestation_slot(state, a)) ] ``` ```python def get_unslashed_attesting_indices(state: BeaconState, attestations: List[PendingAttestation]) -> List[ValidatorIndex]: output = set() for a in attestations: output = output.union(get_attesting_indices(state, a.data, a.aggregation_bitfield)) return sorted(filter(lambda index: not state.validator_registry[index].slashed, list(output))) ``` ```python def get_attesting_balance(state: BeaconState, attestations: List[PendingAttestation]) -> Gwei: return get_total_balance(state, get_unslashed_attesting_indices(state, attestations)) ``` ```python def get_crosslink_from_attestation_data(state: BeaconState, data: AttestationData) -> Crosslink: return Crosslink( epoch=min(data.target_epoch, state.current_crosslinks[data.shard].epoch + MAX_CROSSLINK_EPOCHS), previous_crosslink_root=data.previous_crosslink_root, crosslink_data_root=data.crosslink_data_root, ) ``` ```python def get_winning_crosslink_and_attesting_indices(state: BeaconState, shard: Shard, epoch: Epoch) -> Tuple[Crosslink, List[ValidatorIndex]]: shard_attestations = [a for a in get_matching_source_attestations(state, epoch) if a.data.shard == shard] shard_crosslinks = [get_crosslink_from_attestation_data(state, a.data) for a in shard_attestations] candidate_crosslinks = [ c for c in shard_crosslinks if hash_tree_root(state.current_crosslinks[shard]) in (c.previous_crosslink_root, hash_tree_root(c)) ] if len(candidate_crosslinks) == 0: return Crosslink(epoch=GENESIS_EPOCH, previous_crosslink_root=ZERO_HASH, crosslink_data_root=ZERO_HASH), [] def get_attestations_for(crosslink: Crosslink) -> List[PendingAttestation]: return [a for a in shard_attestations if get_crosslink_from_attestation_data(state, a.data) == crosslink] # Winning crosslink has the crosslink data root with the most balance voting for it (ties broken lexicographically) winning_crosslink = max(candidate_crosslinks, key=lambda crosslink: ( get_attesting_balance(state, get_attestations_for(crosslink)), crosslink.crosslink_data_root )) return winning_crosslink, get_unslashed_attesting_indices(state, get_attestations_for(winning_crosslink)) ``` #### Justification and finalization Run the following function: ```python def process_justification_and_finalization(state: BeaconState) -> None: if get_current_epoch(state) <= GENESIS_EPOCH + 1: return previous_epoch = get_previous_epoch(state) current_epoch = get_current_epoch(state) old_previous_justified_epoch = state.previous_justified_epoch old_current_justified_epoch = state.current_justified_epoch # Process justifications state.previous_justified_epoch = state.current_justified_epoch state.previous_justified_root = state.current_justified_root state.justification_bitfield = (state.justification_bitfield << 1) % 2**64 previous_epoch_matching_target_balance = get_attesting_balance(state, get_matching_target_attestations(state, previous_epoch)) if previous_epoch_matching_target_balance * 3 >= get_total_active_balance(state) * 2: state.current_justified_epoch = previous_epoch state.current_justified_root = get_block_root(state, state.current_justified_epoch) state.justification_bitfield |= (1 << 1) current_epoch_matching_target_balance = get_attesting_balance(state, get_matching_target_attestations(state, current_epoch)) if current_epoch_matching_target_balance * 3 >= get_total_active_balance(state) * 2: state.current_justified_epoch = current_epoch state.current_justified_root = get_block_root(state, state.current_justified_epoch) state.justification_bitfield |= (1 << 0) # Process finalizations bitfield = state.justification_bitfield # The 2nd/3rd/4th most recent epochs are justified, the 2nd using the 4th as source if (bitfield >> 1) % 8 == 0b111 and old_previous_justified_epoch == current_epoch - 3: state.finalized_epoch = old_previous_justified_epoch state.finalized_root = get_block_root(state, state.finalized_epoch) # The 2nd/3rd most recent epochs are justified, the 2nd using the 3rd as source if (bitfield >> 1) % 4 == 0b11 and old_previous_justified_epoch == current_epoch - 2: state.finalized_epoch = old_previous_justified_epoch state.finalized_root = get_block_root(state, state.finalized_epoch) # The 1st/2nd/3rd most recent epochs are justified, the 1st using the 3rd as source if (bitfield >> 0) % 8 == 0b111 and old_current_justified_epoch == current_epoch - 2: state.finalized_epoch = old_current_justified_epoch state.finalized_root = get_block_root(state, state.finalized_epoch) # The 1st/2nd most recent epochs are justified, the 1st using the 2nd as source if (bitfield >> 0) % 4 == 0b11 and old_current_justified_epoch == current_epoch - 1: state.finalized_epoch = old_current_justified_epoch state.finalized_root = get_block_root(state, state.finalized_epoch) ``` #### Crosslinks Run the following function: ```python def process_crosslinks(state: BeaconState) -> None: state.previous_crosslinks = [c for c in state.current_crosslinks] for epoch in (get_previous_epoch(state), get_current_epoch(state)): for offset in range(get_epoch_committee_count(state, epoch)): shard = (get_epoch_start_shard(epoch) + offset) % SHARD_COUNT crosslink_committee = get_crosslink_committee(state, epoch, shard) winning_crosslink, attesting_indices = get_winning_crosslink_and_attesting_indices(state, shard, epoch) if 3 * get_total_balance(state, attesting_indices) >= 2 * get_total_balance(state, crosslink_committee): state.current_crosslinks[shard] = winning_crosslink ``` #### Rewards and penalties First, we define additional helpers: ```python def get_base_reward(state: BeaconState, index: ValidatorIndex) -> Gwei: adjusted_quotient = integer_squareroot(get_total_active_balance(state)) // BASE_REWARD_QUOTIENT if adjusted_quotient == 0: return 0 return state.validator_registry[index].effective_balance // adjusted_quotient // BASE_REWARDS_PER_EPOCH ``` ```python def get_attestation_deltas(state: BeaconState) -> Tuple[List[Gwei], List[Gwei]]: previous_epoch = get_previous_epoch(state) total_balance = get_total_active_balance(state) rewards = [0 for index in range(len(state.validator_registry))] penalties = [0 for index in range(len(state.validator_registry))] eligible_validator_indices = [ index for index, v in enumerate(state.validator_registry) if is_active_validator(v, previous_epoch) or (v.slashed and previous_epoch + 1 < v.withdrawable_epoch) ] # Micro-incentives for matching FFG source, FFG target, and head matching_source_attestations = get_matching_source_attestations(state, previous_epoch) matching_target_attestations = get_matching_target_attestations(state, previous_epoch) matching_head_attestations = get_matching_head_attestations(state, previous_epoch) for attestations in (matching_source_attestations, matching_target_attestations, matching_head_attestations): unslashed_attesting_indices = get_unslashed_attesting_indices(state, attestations) attesting_balance = get_attesting_balance(state, attestations) for index in eligible_validator_indices: if index in unslashed_attesting_indices: rewards[index] += get_base_reward(state, index) * attesting_balance // total_balance else: penalties[index] += get_base_reward(state, index) # Proposer and inclusion delay micro-rewards for index in get_unslashed_attesting_indices(state, matching_source_attestations): attestation = min([ a for a in attestations if index in get_attesting_indices(state, a.data, a.aggregation_bitfield) ], key=lambda a: a.inclusion_delay) rewards[attestation.proposer_index] += get_base_reward(state, index) // PROPOSER_REWARD_QUOTIENT rewards[index] += get_base_reward(state, index) * MIN_ATTESTATION_INCLUSION_DELAY // attestation.inclusion_delay # Inactivity penalty finality_delay = previous_epoch - state.finalized_epoch if finality_delay > MIN_EPOCHS_TO_INACTIVITY_PENALTY: matching_target_attesting_indices = get_unslashed_attesting_indices(state, matching_target_attestations) for index in eligible_validator_indices: penalties[index] += BASE_REWARDS_PER_EPOCH * get_base_reward(state, index) if index not in matching_target_attesting_indices: penalties[index] += state.validator_registry[index].effective_balance * finality_delay // INACTIVITY_PENALTY_QUOTIENT return [rewards, penalties] ``` ```python def get_crosslink_deltas(state: BeaconState) -> Tuple[List[Gwei], List[Gwei]]: rewards = [0 for index in range(len(state.validator_registry))] penalties = [0 for index in range(len(state.validator_registry))] epoch = get_previous_epoch(state) for offset in range(get_epoch_committee_count(state, epoch)): shard = (get_epoch_start_shard(epoch) + offset) % SHARD_COUNT crosslink_committee = get_crosslink_committee(state, epoch, offset) winning_crosslink, attesting_indices = get_winning_crosslink_and_attesting_indices(state, shard, epoch) attesting_balance = get_total_balance(state, attesting_indices) committee_balance = get_total_balance(state, crosslink_committee) for index in crosslink_committee: base_reward = get_base_reward(state, index) if index in attesting_indices: rewards[index] += base_reward * attesting_balance // committee_balance else: penalties[index] += base_reward return [rewards, penalties] ``` Run the following function: ```python def process_rewards_and_penalties(state: BeaconState) -> None: if get_current_epoch(state) == GENESIS_EPOCH: return rewards1, penalties1 = get_attestation_deltas(state) rewards2, penalties2 = get_crosslink_deltas(state) for i in range(len(state.validator_registry)): increase_balance(state, i, rewards1[i] + rewards2[i]) decrease_balance(state, i, penalties1[i] + penalties2[i]) ``` #### Registry updates Run the following function: ```python def process_registry_updates(state: BeaconState) -> None: # Process activation eligibility and ejections for index, validator in enumerate(state.validator_registry): if validator.activation_eligibility_epoch == FAR_FUTURE_EPOCH and validator.effective_balance >= MAX_EFFECTIVE_BALANCE: validator.activation_eligibility_epoch = get_current_epoch(state) if is_active_validator(validator, get_current_epoch(state)) and validator.effective_balance <= EJECTION_BALANCE: initiate_validator_exit(state, index) # Queue validators eligible for activation and not dequeued for activation prior to finalized epoch activation_queue = sorted([ index for index, validator in enumerate(state.validator_registry) if validator.activation_eligibility_epoch != FAR_FUTURE_EPOCH and validator.activation_epoch >= get_delayed_activation_exit_epoch(state.finalized_epoch) ], key=lambda index: state.validator_registry[index].activation_eligibility_epoch) # Dequeued validators for activation up to churn limit (without resetting activation epoch) for index in activation_queue[:get_churn_limit(state)]: if validator.activation_epoch == FAR_FUTURE_EPOCH: validator.activation_epoch = get_delayed_activation_exit_epoch(get_current_epoch(state)) ``` #### Slashings Run the following function: ```python def process_slashings(state: BeaconState) -> None: current_epoch = get_current_epoch(state) active_validator_indices = get_active_validator_indices(state, current_epoch) total_balance = get_total_balance(state, active_validator_indices) # Compute `total_penalties` total_at_start = state.latest_slashed_balances[(current_epoch + 1) % LATEST_SLASHED_EXIT_LENGTH] total_at_end = state.latest_slashed_balances[current_epoch % LATEST_SLASHED_EXIT_LENGTH] total_penalties = total_at_end - total_at_start for index, validator in enumerate(state.validator_registry): if validator.slashed and current_epoch == validator.withdrawable_epoch - LATEST_SLASHED_EXIT_LENGTH // 2: penalty = max( validator.effective_balance * min(total_penalties * 3, total_balance) // total_balance, validator.effective_balance // MIN_SLASHING_PENALTY_QUOTIENT ) decrease_balance(state, index, penalty) ``` #### Final updates Run the following function: ```python def process_final_updates(state: BeaconState) -> None: current_epoch = get_current_epoch(state) next_epoch = current_epoch + 1 # Reset eth1 data votes if (state.slot + 1) % SLOTS_PER_ETH1_VOTING_PERIOD == 0: state.eth1_data_votes = [] # Update effective balances with hysteresis for index, validator in enumerate(state.validator_registry): balance = min(state.balances[index], MAX_EFFECTIVE_BALANCE) HALF_INCREMENT = EFFECTIVE_BALANCE_INCREMENT // 2 if balance < validator.effective_balance or validator.effective_balance + 3 * HALF_INCREMENT < balance: validator.effective_balance = balance - balance % EFFECTIVE_BALANCE_INCREMENT # Update start shard state.latest_start_shard = (state.latest_start_shard + get_shard_delta(state, current_epoch)) % SHARD_COUNT # Set active index root index_root_position = (next_epoch + ACTIVATION_EXIT_DELAY) % LATEST_ACTIVE_INDEX_ROOTS_LENGTH state.latest_active_index_roots[index_root_position] = hash_tree_root( get_active_validator_indices(state, next_epoch + ACTIVATION_EXIT_DELAY) ) # Set total slashed balances state.latest_slashed_balances[next_epoch % LATEST_SLASHED_EXIT_LENGTH] = ( state.latest_slashed_balances[current_epoch % LATEST_SLASHED_EXIT_LENGTH] ) # Set randao mix state.latest_randao_mixes[next_epoch % LATEST_RANDAO_MIXES_LENGTH] = get_randao_mix(state, current_epoch) # Set historical root accumulator if next_epoch % (SLOTS_PER_HISTORICAL_ROOT // SLOTS_PER_EPOCH) == 0: historical_batch = HistoricalBatch( block_roots=state.latest_block_roots, state_roots=state.latest_state_roots, ) state.historical_roots.append(hash_tree_root(historical_batch)) # Rotate current/previous epoch attestations state.previous_epoch_attestations = state.current_epoch_attestations state.current_epoch_attestations = [] ``` ### Per-slot processing At every `slot > GENESIS_SLOT` run the following function: ```python def advance_slot(state: BeaconState) -> None: state.slot += 1 ``` ### Per-block processing For every `block` except the genesis block, run `process_block_header(state, block)`, `process_randao(state, block)` and `process_eth1_data(state, block)`. #### Block header ```python def process_block_header(state: BeaconState, block: BeaconBlock) -> None: # Verify that the slots match assert block.slot == state.slot # Verify that the parent matches assert block.previous_block_root == signing_root(state.latest_block_header) # Save current block as the new latest block state.latest_block_header = BeaconBlockHeader( slot=block.slot, previous_block_root=block.previous_block_root, block_body_root=hash_tree_root(block.body), ) # Verify proposer is not slashed proposer = state.validator_registry[get_beacon_proposer_index(state)] assert not proposer.slashed # Verify proposer signature assert bls_verify(proposer.pubkey, signing_root(block), block.signature, get_domain(state, DOMAIN_BEACON_PROPOSER)) ``` #### RANDAO ```python def process_randao(state: BeaconState, block: BeaconBlock) -> None: proposer = state.validator_registry[get_beacon_proposer_index(state)] # Verify that the provided randao value is valid assert bls_verify(proposer.pubkey, hash_tree_root(get_current_epoch(state)), block.body.randao_reveal, get_domain(state, DOMAIN_RANDAO)) # Mix it in state.latest_randao_mixes[get_current_epoch(state) % LATEST_RANDAO_MIXES_LENGTH] = ( xor(get_randao_mix(state, get_current_epoch(state)), hash(block.body.randao_reveal)) ) ``` #### Eth1 data ```python def process_eth1_data(state: BeaconState, block: BeaconBlock) -> None: state.eth1_data_votes.append(block.body.eth1_data) if state.eth1_data_votes.count(block.body.eth1_data) * 2 > SLOTS_PER_ETH1_VOTING_PERIOD: state.latest_eth1_data = block.body.eth1_data ``` #### Operations Note: All functions in this section mutate `state`. ##### Proposer slashings Verify that `len(block.body.proposer_slashings) <= MAX_PROPOSER_SLASHINGS`. For each `proposer_slashing` in `block.body.proposer_slashings`, run the following function: ```python def process_proposer_slashing(state: BeaconState, proposer_slashing: ProposerSlashing) -> None: """ Process ``ProposerSlashing`` operation. """ proposer = state.validator_registry[proposer_slashing.proposer_index] # Verify that the epoch is the same assert slot_to_epoch(proposer_slashing.header_1.slot) == slot_to_epoch(proposer_slashing.header_2.slot) # But the headers are different assert proposer_slashing.header_1 != proposer_slashing.header_2 # Check proposer is slashable assert is_slashable_validator(proposer, get_current_epoch(state)) # Signatures are valid for header in (proposer_slashing.header_1, proposer_slashing.header_2): domain = get_domain(state, DOMAIN_BEACON_PROPOSER, slot_to_epoch(header.slot)) assert bls_verify(proposer.pubkey, signing_root(header), header.signature, domain) slash_validator(state, proposer_slashing.proposer_index) ``` ##### Attester slashings Verify that `len(block.body.attester_slashings) <= MAX_ATTESTER_SLASHINGS`. For each `attester_slashing` in `block.body.attester_slashings`, run the following function: ```python def process_attester_slashing(state: BeaconState, attester_slashing: AttesterSlashing) -> None: """ Process ``AttesterSlashing`` operation. """ attestation_1 = attester_slashing.attestation_1 attestation_2 = attester_slashing.attestation_2 # Check that the attestations are conflicting assert attestation_1.data != attestation_2.data source_1 = attestation_1.data.source_epoch target_1 = attestation_1.data.target_epoch source_2 = attestation_2.data.source_epoch target_2 = attestation_2.data.target_epoch assert ( # Double vote (target_1 == target_2) or # Surround vote (attestation 1 surrounds attestation 2) (source_1 < source_2 and target_2 < target_1) ) assert verify_indexed_attestation(state, attestation_1) assert verify_indexed_attestation(state, attestation_2) attesting_indices_1 = attestation_1.custody_bit_0_indices + attestation_1.custody_bit_1_indices attesting_indices_2 = attestation_2.custody_bit_0_indices + attestation_2.custody_bit_1_indices slashable_indices = [ index for index in attesting_indices_1 if ( index in attesting_indices_2 and is_slashable_validator(state.validator_registry[index], get_current_epoch(state)) ) ] assert len(slashable_indices) >= 1 for index in slashable_indices: slash_validator(state, index) ``` ##### Attestations Verify that `len(block.body.attestations) <= MAX_ATTESTATIONS`. For each `attestation` in `block.body.attestations`, run the following function: ```python def process_attestation(state: BeaconState, attestation: Attestation) -> None: """ Process ``Attestation`` operation. """ attestation_slot = get_attestation_slot(state, attestation) assert attestation_slot + MIN_ATTESTATION_INCLUSION_DELAY <= state.slot <= attestation_slot + SLOTS_PER_EPOCH # Check target epoch, source epoch, source root, and source crosslink data = attestation.data assert (data.target_epoch, data.source_epoch, data.source_root, data.previous_crosslink_root) in { (get_current_epoch(state), state.current_justified_epoch, state.current_justified_root, hash_tree_root(state.current_crosslinks[data.shard])), (get_previous_epoch(state), state.previous_justified_epoch, state.previous_justified_root, hash_tree_root(state.previous_crosslinks[data.shard])), } # Check crosslink data root assert data.crosslink_data_root == ZERO_HASH # [to be removed in phase 1] # Check signature and bitfields assert verify_indexed_attestation(state, convert_to_indexed(state, attestation)) # Cache pending attestation pending_attestation = PendingAttestation( data=data, aggregation_bitfield=attestation.aggregation_bitfield, inclusion_delay=state.slot - attestation_slot, proposer_index=get_beacon_proposer_index(state), ) if target_epoch == get_current_epoch(state): state.current_epoch_attestations.append(pending_attestation) else: state.previous_epoch_attestations.append(pending_attestation) ``` ##### Deposits Verify that `len(block.body.deposits) == min(MAX_DEPOSITS, state.latest_eth1_data.deposit_count - state.deposit_index)`. For each `deposit` in `block.body.deposits`, run the following function: ```python def process_deposit(state: BeaconState, deposit: Deposit) -> None: """ Process an Eth1 deposit, registering a validator or increasing its balance. """ # Verify the Merkle branch assert verify_merkle_branch( leaf=hash_tree_root(deposit.data), proof=deposit.proof, depth=DEPOSIT_CONTRACT_TREE_DEPTH, index=deposit.index, root=state.latest_eth1_data.deposit_root, ) # Deposits must be processed in order assert deposit.index == state.deposit_index state.deposit_index += 1 pubkey = deposit.data.pubkey amount = deposit.data.amount validator_pubkeys = [v.pubkey for v in state.validator_registry] if pubkey not in validator_pubkeys: # Verify the deposit signature (proof of possession) if not bls_verify(pubkey, signing_root(deposit.data), deposit.data.signature, get_domain(state, DOMAIN_DEPOSIT)): return # Add validator and balance entries state.validator_registry.append(Validator( pubkey=pubkey, withdrawal_credentials=deposit.data.withdrawal_credentials, activation_eligibility_epoch=FAR_FUTURE_EPOCH, activation_epoch=FAR_FUTURE_EPOCH, exit_epoch=FAR_FUTURE_EPOCH, withdrawable_epoch=FAR_FUTURE_EPOCH, effective_balance=amount - amount % EFFECTIVE_BALANCE_INCREMENT )) state.balances.append(amount) else: # Increase balance by deposit amount index = validator_pubkeys.index(pubkey) increase_balance(state, index, amount) ``` ##### Voluntary exits Verify that `len(block.body.voluntary_exits) <= MAX_VOLUNTARY_EXITS`. For each `exit` in `block.body.voluntary_exits`, run the following function: ```python def process_voluntary_exit(state: BeaconState, exit: VoluntaryExit) -> None: """ Process ``VoluntaryExit`` operation. """ validator = state.validator_registry[exit.validator_index] # Verify the validator is active assert is_active_validator(validator, get_current_epoch(state)) # Verify the validator has not yet exited assert validator.exit_epoch == FAR_FUTURE_EPOCH # Exits must specify an epoch when they become valid; they are not valid before then assert get_current_epoch(state) >= exit.epoch # Verify the validator has been active long enough assert get_current_epoch(state) - validator.activation_epoch >= PERSISTENT_COMMITTEE_PERIOD # Verify signature domain = get_domain(state, DOMAIN_VOLUNTARY_EXIT, exit.epoch) assert bls_verify(validator.pubkey, signing_root(exit), exit.signature, domain) # Initiate exit initiate_validator_exit(state, exit.validator_index) ``` ##### Transfers Verify that `len(block.body.transfers) <= MAX_TRANSFERS` and that all transfers are distinct. For each `transfer` in `block.body.transfers`, run the following function: ```python def process_transfer(state: BeaconState, transfer: Transfer) -> None: """ Process ``Transfer`` operation. """ # Verify the amount and fee are not individually too big (for anti-overflow purposes) assert state.balances[transfer.sender] >= max(transfer.amount, transfer.fee) # A transfer is valid in only one slot assert state.slot == transfer.slot # Sender must be not yet eligible for activation, withdrawn, or transfer balance over MAX_EFFECTIVE_BALANCE assert ( state.validator_registry[transfer.sender].activation_eligibility_epoch == FAR_FUTURE_EPOCH or get_current_epoch(state) >= state.validator_registry[transfer.sender].withdrawable_epoch or transfer.amount + transfer.fee + MAX_EFFECTIVE_BALANCE <= state.balances[transfer.sender] ) # Verify that the pubkey is valid assert ( state.validator_registry[transfer.sender].withdrawal_credentials == BLS_WITHDRAWAL_PREFIX_BYTE + hash(transfer.pubkey)[1:] ) # Verify that the signature is valid assert bls_verify(transfer.pubkey, signing_root(transfer), transfer.signature, get_domain(state, DOMAIN_TRANSFER)) # Process the transfer decrease_balance(state, transfer.sender, transfer.amount + transfer.fee) increase_balance(state, transfer.recipient, transfer.amount) increase_balance(state, get_beacon_proposer_index(state), transfer.fee) # Verify balances are not dust assert not (0 < state.balances[transfer.sender] < MIN_DEPOSIT_AMOUNT) assert not (0 < state.balances[transfer.recipient] < MIN_DEPOSIT_AMOUNT) ``` #### State root verification Verify the block's `state_root` by running the following function: ```python def verify_block_state_root(state: BeaconState, block: BeaconBlock) -> None: assert block.state_root == hash_tree_root(state) ```