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# Ethereum 2.0 Phase 1 -- Shard Data Chains
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**Notice**: This document is a work-in-progress for researchers and implementers.
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## Table of contents
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<!-- TOC -->
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- [Ethereum 2.0 Phase 1 -- Shard Data Chains ](#ethereum-20-phase-1----shard-data-chains )
- [Table of contents ](#table-of-contents )
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- [Introduction ](#introduction )
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- [Configuration ](#configuration )
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- [Misc ](#misc )
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- [Initial values ](#initial-values )
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- [Time parameters ](#time-parameters )
- [Signature domains ](#signature-domains )
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- [Data structures ](#data-structures )
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- [`ShardBlockBody` ](#shardblockbody )
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- [`ShardAttestation` ](#shardattestation )
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- [`ShardBlock` ](#shardblock )
- [`ShardBlockHeader` ](#shardblockheader )
- [Helper functions ](#helper-functions )
- [`get_period_committee` ](#get_period_committee )
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- [`get_switchover_epoch` ](#get_switchover_epoch )
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- [`get_persistent_committee` ](#get_persistent_committee )
- [`get_shard_proposer_index` ](#get_shard_proposer_index )
- [`get_shard_header` ](#get_shard_header )
- [`verify_shard_attestation_signature` ](#verify_shard_attestation_signature )
- [`compute_crosslink_data_root` ](#compute_crosslink_data_root )
- [Object validity ](#object-validity )
- [Shard blocks ](#shard-blocks )
- [Shard attestations ](#shard-attestations )
- [Beacon attestations ](#beacon-attestations )
- [Shard fork choice rule ](#shard-fork-choice-rule )
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<!-- /TOC -->
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## Introduction
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This document describes the shard data layer and the shard fork choice rule in Phase 1 of Ethereum 2.0.
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## Configuration
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### Misc
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| Name | Value |
| - | - |
| `BYTES_PER_SHARD_BLOCK_BODY` | `2**14` (= 16,384) |
| `MAX_SHARD_ATTESTIONS` | `2**4` (= 16) |
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### Initial values
| Name | Value |
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| `PHASE_1_FORK_EPOCH` | **TBD** |
| `PHASE_1_FORK_SLOT` | **TBD** |
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| `GENESIS_SHARD_SLOT` | 0 |
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### Time parameters
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| Name | Value | Unit | Duration |
| - | - | :-: | :-: |
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| `CROSSLINK_LOOKBACK` | `2**0` (= 1) | epochs | 6.2 minutes |
| `PERSISTENT_COMMITTEE_PERIOD` | `2**11` (= 2,048) | epochs | ~9 days |
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### Signature domains
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| Name | Value |
| - | - |
| `DOMAIN_SHARD_PROPOSER` | `128` |
| `DOMAIN_SHARD_ATTESTER` | `129` |
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### TODO PLACEHOLDER
| Name | Value |
| - | - |
| `PLACEHOLDER` | `2**32` |
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## Data structures
### `ShardBlockBody`
```python
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class ShardBlockBody(Container):
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data: Vector[Bytes[PLACEHOLDER], BYTES_PER_SHARD_BLOCK_BODY]
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```
### `ShardAttestation`
```python
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class ShardAttestation(Container):
class data(Container):
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slot: Slot
shard: Shard
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shard_block_root: Bytes32
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aggregation_bitfield: Bytes[PLACEHOLDER]
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aggregate_signature: BLSSignature
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```
### `ShardBlock`
```python
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class ShardBlock(Container):
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slot: Slot
shard: Shard
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beacon_chain_root: Bytes32
parent_root: Bytes32
data: ShardBlockBody
state_root: Bytes32
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attestations: List[ShardAttestation, PLACEHOLDER]
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signature: BLSSignature
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```
### `ShardBlockHeader`
```python
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class ShardBlockHeader(Container):
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slot: Slot
shard: Shard
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beacon_chain_root: Bytes32
parent_root: Bytes32
body_root: Bytes32
state_root: Bytes32
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attestations: List[ShardAttestation, PLACEHOLDER]
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signature: BLSSignature
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```
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## Helper functions
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### `get_period_committee`
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```python
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def get_period_committee(state: BeaconState,
epoch: Epoch,
shard: Shard,
index: int,
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count: int) -> Sequence[ValidatorIndex]:
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"""
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Return committee for a period. Used to construct persistent committees.
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"""
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return compute_committee(
indices=get_active_validator_indices(state, epoch),
seed=generate_seed(state, epoch),
index=shard * count + index,
count=SHARD_COUNT * count,
)
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```
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### `get_switchover_epoch`
```python
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def get_switchover_epoch(state: BeaconState, epoch: Epoch, index: ValidatorIndex) -> int:
earlier_start_epoch = Epoch(epoch - (epoch % PERSISTENT_COMMITTEE_PERIOD) - PERSISTENT_COMMITTEE_PERIOD * 2)
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return (bytes_to_int(hash(generate_seed(state, earlier_start_epoch) + int_to_bytes(index, length=3)[0:8]))
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% PERSISTENT_COMMITTEE_PERIOD)
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```
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### `get_persistent_committee`
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```python
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def get_persistent_committee(state: BeaconState,
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shard: Shard,
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slot: Slot) -> Sequence[ValidatorIndex]:
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"""
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Return the persistent committee for the given ``shard`` at the given ``slot``.
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"""
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epoch = slot_to_epoch(slot)
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earlier_start_epoch = Epoch(epoch - (epoch % PERSISTENT_COMMITTEE_PERIOD) - PERSISTENT_COMMITTEE_PERIOD * 2)
later_start_epoch = Epoch(epoch - (epoch % PERSISTENT_COMMITTEE_PERIOD) - PERSISTENT_COMMITTEE_PERIOD)
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committee_count = max(
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len(get_active_validator_indices(state, earlier_start_epoch)) //
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(SHARD_COUNT * TARGET_COMMITTEE_SIZE),
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len(get_active_validator_indices(state, later_start_epoch)) //
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(SHARD_COUNT * TARGET_COMMITTEE_SIZE),
) + 1
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index = slot % committee_count
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earlier_committee = get_period_committee(state, earlier_start_epoch, shard, index, committee_count)
later_committee = get_period_committee(state, later_start_epoch, shard, index, committee_count)
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# Take not-yet-cycled-out validators from earlier committee and already-cycled-in validators from
# later committee; return a sorted list of the union of the two, deduplicated
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return sorted(list(set(
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[i for i in earlier_committee if epoch % PERSISTENT_COMMITTEE_PERIOD < get_switchover_epoch ( state , epoch , i ) ] +
[i for i in later_committee if epoch % PERSISTENT_COMMITTEE_PERIOD >= get_switchover_epoch(state, epoch, i)]
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)))
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```
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### `get_shard_proposer_index`
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```python
def get_shard_proposer_index(state: BeaconState,
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shard: Shard,
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slot: Slot) -> Optional[ValidatorIndex]:
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# Randomly shift persistent committee
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persistent_committee = list(get_persistent_committee(state, shard, slot))
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seed = hash(state.current_shuffling_seed + int_to_bytes(shard, length=8) + int_to_bytes(slot, length=8))
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random_index = bytes_to_int(seed[0:8]) % len(persistent_committee)
persistent_committee = persistent_committee[random_index:] + persistent_committee[:random_index]
# Search for an active proposer
for index in persistent_committee:
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if is_active_validator(state.validators[index], get_current_epoch(state)):
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return index
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# No block can be proposed if no validator is active
return None
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```
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### `get_shard_header`
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```python
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def get_shard_header(block: ShardBlock) -> ShardBlockHeader:
return ShardBlockHeader(
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slot=block.slot,
shard=block.shard,
beacon_chain_root=block.beacon_chain_root,
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parent_root=block.parent_root,
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body_root=hash_tree_root(block.body),
state_root=block.state_root,
attestations=block.attestations,
signature=block.signature,
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)
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```
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### `verify_shard_attestation_signature`
```python
def verify_shard_attestation_signature(state: BeaconState,
attestation: ShardAttestation) -> None:
data = attestation.data
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persistent_committee = get_persistent_committee(state, data.shard, data.slot)
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assert verify_bitfield(attestation.aggregation_bitfield, len(persistent_committee))
pubkeys = []
for i, index in enumerate(persistent_committee):
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if get_bitfield_bit(attestation.aggregation_bitfield, i) == 0b1:
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validator = state.validators[index]
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assert is_active_validator(validator, get_current_epoch(state))
pubkeys.append(validator.pubkey)
assert bls_verify(
pubkey=bls_aggregate_pubkeys(pubkeys),
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message_hash=data.shard_block_root,
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signature=attestation.aggregate_signature,
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domain=get_domain(state, DOMAIN_SHARD_ATTESTER, slot_to_epoch(data.slot))
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)
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```
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### `compute_crosslink_data_root`
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```python
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def compute_crosslink_data_root(blocks: Sequence[ShardBlock]) -> Bytes32:
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def is_power_of_two(value: int) -> bool:
return (value > 0) and (value & (value - 1) == 0)
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def pad_to_power_of_2(values: MutableSequence[bytes]) -> Sequence[bytes]:
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while not is_power_of_two(len(values)):
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values.append(b'\x00' * BYTES_PER_SHARD_BLOCK_BODY)
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return values
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def hash_tree_root_of_bytes(data: bytes) -> bytes:
return hash_tree_root([data[i:i + 32] for i in range(0, len(data), 32)])
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def zpad(data: bytes, length: int) -> bytes:
return data + b'\x00' * (length - len(data))
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return hash(
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# TODO untested code.
# Need to either pass a typed list to hash-tree-root, or merkleize_chunks(values, pad_to=2**x)
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hash_tree_root(pad_to_power_of_2([
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hash_tree_root_of_bytes(
zpad(serialize(get_shard_header(block)), BYTES_PER_SHARD_BLOCK_BODY)
) for block in blocks
]))
+ hash_tree_root(pad_to_power_of_2([
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hash_tree_root_of_bytes(block.body) for block in blocks
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]))
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)
```
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## Object validity
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### Shard blocks
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Let:
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* `beacon_blocks` be the `BeaconBlock` list such that `beacon_blocks[slot]` is the canonical `BeaconBlock` at slot `slot`
* `beacon_state` be the canonical `BeaconState` after processing `beacon_blocks[-1]`
* `valid_shard_blocks` be the list of valid `ShardBlock` , recursively defined
* `candidate` be a candidate `ShardBlock` for which validity is to be determined by running `is_valid_shard_block`
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```python
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def is_valid_shard_block(beacon_blocks: Sequence[BeaconBlock],
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beacon_state: BeaconState,
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valid_shard_blocks: Sequence[ShardBlock],
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candidate: ShardBlock) -> bool:
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# Check if block is already determined valid
for _, block in enumerate(valid_shard_blocks):
if candidate == block:
return True
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# Check slot number
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assert candidate.slot >= PHASE_1_FORK_SLOT
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# Check shard number
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assert candidate.shard < = SHARD_COUNT
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# Check beacon block
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beacon_block = beacon_blocks[candidate.slot]
assert candidate.beacon_block_root == signing_root(beacon_block)
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assert beacon_block.slot < = candidate.slot
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# Check state root
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assert candidate.state_root == ZERO_HASH # [to be removed in phase 2]
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# Check parent block
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if candidate.slot == PHASE_1_FORK_SLOT:
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assert candidate.parent_root == ZERO_HASH
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else:
parent_block = next(
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(block for block in valid_shard_blocks if signing_root(block) == candidate.parent_root),
None
)
assert parent_block is not None
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assert parent_block.shard == candidate.shard
assert parent_block.slot < candidate.slot
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assert signing_root(beacon_blocks[parent_block.slot]) == parent_block.beacon_chain_root
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# Check attestations
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assert len(candidate.attestations) < = MAX_SHARD_ATTESTIONS
for _, attestation in enumerate(candidate.attestations):
assert max(GENESIS_SHARD_SLOT, candidate.slot - SLOTS_PER_EPOCH) < = attestation.data.slot
assert attestation.data.slot < = candidate.slot - MIN_ATTESTATION_INCLUSION_DELAY
assert attestation.data.crosslink.shard == candidate.shard
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verify_shard_attestation_signature(beacon_state, attestation)
# Check signature
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proposer_index = get_shard_proposer_index(beacon_state, candidate.shard, candidate.slot)
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assert proposer_index is not None
assert bls_verify(
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pubkey=beacon_state.validators[proposer_index].pubkey,
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message_hash=signing_root(candidate),
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signature=candidate.signature,
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domain=get_domain(beacon_state, DOMAIN_SHARD_PROPOSER, slot_to_epoch(candidate.slot)),
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)
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return True
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```
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### Shard attestations
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Let:
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* `valid_shard_blocks` be the list of valid `ShardBlock`
* `beacon_state` be the canonical `BeaconState`
* `candidate` be a candidate `ShardAttestation` for which validity is to be determined by running `is_valid_shard_attestation`
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```python
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def is_valid_shard_attestation(valid_shard_blocks: Sequence[ShardBlock],
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beacon_state: BeaconState,
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candidate: ShardAttestation) -> bool:
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# Check shard block
shard_block = next(
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(block for block in valid_shard_blocks if signing_root(block) == candidate.data.shard_block_root),
None,
)
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assert shard_block is not None
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assert shard_block.slot == candidate.data.slot
assert shard_block.shard == candidate.data.shard
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# Check signature
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verify_shard_attestation_signature(beacon_state, candidate)
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return True
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```
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### Beacon attestations
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Let:
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* `shard` be a valid `Shard`
* `shard_blocks` be the `ShardBlock` list such that `shard_blocks[slot]` is the canonical `ShardBlock` for shard `shard` at slot `slot`
* `beacon_state` be the canonical `BeaconState`
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* `valid_attestations` be the set of valid `Attestation` objects, recursively defined
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* `candidate` be a candidate `Attestation` which is valid under Phase 0 rules, and for which validity is to be determined under Phase 1 rules by running `is_valid_beacon_attestation`
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```python
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def is_valid_beacon_attestation(shard: Shard,
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shard_blocks: Sequence[ShardBlock],
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beacon_state: BeaconState,
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valid_attestations: Set[Attestation],
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candidate: Attestation) -> bool:
# Check if attestation is already determined valid
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for attestation in valid_attestations:
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if candidate == attestation:
return True
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# Check previous attestation
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if candidate.data.previous_crosslink.epoch < = PHASE_1_FORK_EPOCH:
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assert candidate.data.previous_crosslink.data_root == ZERO_HASH
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else:
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previous_attestation = next(
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(attestation for attestation in valid_attestations if
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attestation.data.crosslink.data_root == candidate.data.previous_crosslink.data_root),
None,
)
assert previous_attestation is not None
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assert candidate.data.previous_attestation.epoch < slot_to_epoch ( candidate . data . slot )
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# Check crosslink data root
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start_epoch = beacon_state.crosslinks[shard].epoch
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end_epoch = min(slot_to_epoch(candidate.data.slot) - CROSSLINK_LOOKBACK, start_epoch + MAX_EPOCHS_PER_CROSSLINK)
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blocks = []
for slot in range(start_epoch * SLOTS_PER_EPOCH, end_epoch * SLOTS_PER_EPOCH):
blocks.append(shard_blocks[slot])
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assert candidate.data.crosslink.data_root == compute_crosslink_data_root(blocks)
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return True
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```
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## Shard fork choice rule
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The fork choice rule for any shard is LMD GHOST using the shard attestations of the persistent committee and the beacon chain attestations of the crosslink committee currently assigned to that shard, but instead of being rooted in the genesis it is rooted in the block referenced in the most recent accepted crosslink (i.e. `state.crosslinks[shard].shard_block_root` ). Only blocks whose `beacon_chain_root` is the block in the main beacon chain at the specified `slot` should be considered. (If the beacon chain skips a slot, then the block at that slot is considered to be the block in the beacon chain at the highest slot lower than that slot.)