github/reth
1
1
Fork 0
mirror of https://github.com/paradigmxyz/reth.git synced 2026-01-29 17:18:08 -05:00
Code Issues Packages Projects Releases Wiki Activity
Files
661a2426ff9edf15d69add366e6f742f01075abb
reth/crates/executor/src/executor.rs

1053 lines
43 KiB
Rust
Raw Blame History

This file contains ambiguous Unicode characters
This file contains Unicode characters that might be confused with other characters. If you think that this is intentional, you can safely ignore this warning. Use the Escape button to reveal them.
use crate::post_state::PostState;
use reth_interfaces::executor::Error;
use reth_primitives::{
bloom::logs_bloom, Account, Address, Block, Bloom, Bytecode, ChainSpec, Hardfork, Header, Log,
Receipt, TransactionSigned, H256, U256,
};
use reth_provider::{BlockExecutor, StateProvider};
use reth_revm::{
config::{WEI_2ETH, WEI_3ETH, WEI_5ETH},
database::SubState,
env::{fill_cfg_and_block_env, fill_tx_env},
into_reth_log, to_reth_acc,
};
use reth_revm_inspectors::stack::{InspectorStack, InspectorStackConfig};
use revm::{
db::AccountState,
primitives::{
hash_map::{self, Entry},
Account as RevmAccount, AccountInfo, ResultAndState,
},
EVM,
};
use std::{
collections::{BTreeMap, HashMap},
sync::Arc,
};
/// Main block executor
pub struct Executor<DB>
where
DB: StateProvider,
{
/// The configured chain-spec
pub chain_spec: Arc<ChainSpec>,
evm: EVM<SubState<DB>>,
stack: InspectorStack,
}
impl<DB> From<Arc<ChainSpec>> for Executor<DB>
where
DB: StateProvider,
{
/// Instantiates a new executor from the chainspec. Must call
/// `with_db` to set the database before executing.
fn from(chain_spec: Arc<ChainSpec>) -> Self {
let evm = EVM::new();
Executor { chain_spec, evm, stack: InspectorStack::new(InspectorStackConfig::default()) }
}
}
impl<DB> Executor<DB>
where
DB: StateProvider,
{
/// Creates a new executor from the given chain spec and database.
pub fn new(chain_spec: Arc<ChainSpec>, db: SubState<DB>) -> Self {
let mut evm = EVM::new();
evm.database(db);
Executor { chain_spec, evm, stack: InspectorStack::new(InspectorStackConfig::default()) }
}
/// Configures the executor with the given inspectors.
pub fn with_stack(mut self, stack: InspectorStack) -> Self {
self.stack = stack;
self
}
/// Gives a reference to the database
pub fn db(&mut self) -> &mut SubState<DB> {
self.evm.db().expect("db to not be moved")
}
fn recover_senders(
&self,
body: &[TransactionSigned],
senders: Option<Vec<Address>>,
) -> Result<Vec<Address>, Error> {
if let Some(senders) = senders {
if body.len() == senders.len() {
Ok(senders)
} else {
Err(Error::SenderRecoveryError)
}
} else {
body.iter().map(|tx| tx.recover_signer().ok_or(Error::SenderRecoveryError)).collect()
}
}
/// Initializes the config and block env.
fn init_env(&mut self, header: &Header, total_difficulty: U256) {
fill_cfg_and_block_env(
&mut self.evm.env.cfg,
&mut self.evm.env.block,
&self.chain_spec,
header,
total_difficulty,
);
}
/// Commit change to the run-time database, and update the given [PostState] with the changes
/// made in the transaction, which can be persisted to the database.
fn commit_changes(
&mut self,
changes: hash_map::HashMap<Address, RevmAccount>,
has_state_clear_eip: bool,
post_state: &mut PostState,
) {
let db = self.db();
// iterate over all changed accounts
for (address, account) in changes {
if account.is_destroyed {
// get old account that we are destroying.
let db_account = match db.accounts.entry(address) {
Entry::Occupied(entry) => entry.into_mut(),
Entry::Vacant(_entry) => {
panic!("Left panic to critically jumpout if happens, as every account should be hot loaded.");
}
};
// Insert into `change` a old account and None for new account
// and mark storage to be mapped
post_state.destroy_account(address, to_reth_acc(&db_account.info));
// clear cached DB and mark account as not existing
db_account.storage.clear();
db_account.account_state = AccountState::NotExisting;
db_account.info = AccountInfo::default();
continue
} else {
// check if account code is new or old.
// does it exist inside cached contracts if it doesn't it is new bytecode that
// we are inserting inside `change`
if let Some(ref code) = account.info.code {
if !code.is_empty() && !db.contracts.contains_key(&account.info.code_hash) {
db.contracts.insert(account.info.code_hash, code.clone());
post_state.add_bytecode(account.info.code_hash, Bytecode(code.clone()));
}
}
// get old account that is going to be overwritten or none if it does not exist
// and get new account that was just inserted. new account mut ref is used for
// inserting storage
let cached_account = match db.accounts.entry(address) {
Entry::Vacant(entry) => {
let entry = entry.insert(Default::default());
entry.info = account.info.clone();
let account = to_reth_acc(&entry.info);
if !(has_state_clear_eip && account.is_empty()) {
post_state.create_account(address, account);
}
entry
}
Entry::Occupied(entry) => {
let entry = entry.into_mut();
if matches!(entry.account_state, AccountState::NotExisting) {
let account = to_reth_acc(&account.info);
if !(has_state_clear_eip && account.is_empty()) {
post_state.create_account(address, account);
}
} else if entry.info != account.info {
post_state.change_account(
address,
to_reth_acc(&entry.info),
to_reth_acc(&account.info),
);
} else if has_state_clear_eip && account.is_empty() {
// The account was touched, but it is empty, so it should be deleted.
post_state.destroy_account(address, to_reth_acc(&account.info));
}
entry.info = account.info.clone();
entry
}
};
cached_account.account_state = if account.storage_cleared {
cached_account.storage.clear();
AccountState::StorageCleared
} else if cached_account.account_state.is_storage_cleared() {
// the account already exists and its storage was cleared, preserve its previous
// state
AccountState::StorageCleared
} else {
AccountState::Touched
};
// Insert storage.
let mut storage_changeset = BTreeMap::new();
// insert storage into new db account.
cached_account.storage.extend(account.storage.into_iter().map(|(key, value)| {
storage_changeset.insert(key, (value.original_value(), value.present_value()));
(key, value.present_value())
}));
// Insert into change.
if !storage_changeset.is_empty() {
post_state.change_storage(address, storage_changeset);
}
}
}
}
/// Collect all balance changes at the end of the block.
///
/// Balance changes might include the block reward, uncle rewards, withdrawals, or irregular
/// state changes (DAO fork).
fn post_block_balance_increments(
&self,
block: &Block,
td: U256,
) -> Result<HashMap<Address, U256>, Error> {
let mut balance_increments = HashMap::<Address, U256>::default();
// Collect balance increments for block and uncle rewards.
if let Some(reward) = self.get_block_reward(block, td) {
// Calculate Uncle reward
// OpenEthereum code: https://github.com/openethereum/openethereum/blob/6c2d392d867b058ff867c4373e40850ca3f96969/crates/ethcore/src/ethereum/ethash.rs#L319-L333
for ommer in block.ommers.iter() {
let ommer_reward =
U256::from(((8 + ommer.number - block.number) as u128 * reward) >> 3);
// From yellowpaper Page 15:
// If there are collisions of the beneficiary addresses between ommers and the
// block (i.e. two ommers with the same beneficiary address
// or an ommer with the same beneficiary address as the
// present block), additions are applied cumulatively
*balance_increments.entry(ommer.beneficiary).or_default() += ommer_reward;
}
// Increment balance for main block reward.
let block_reward = U256::from(reward + (reward >> 5) * block.ommers.len() as u128);
*balance_increments.entry(block.beneficiary).or_default() += block_reward;
}
if self.chain_spec.fork(Hardfork::Shanghai).active_at_timestamp(block.timestamp) {
if let Some(withdrawals) = block.withdrawals.as_ref() {
for withdrawal in withdrawals {
*balance_increments.entry(withdrawal.address).or_default() +=
withdrawal.amount_wei();
}
}
}
Ok(balance_increments)
}
/// From yellowpapper Page 15:
/// 11.3. Reward Application. The application of rewards to a block involves raising the
/// balance of the accounts of the beneficiary address of the block and each ommer by
/// a certain amount. We raise the blocks beneficiary account by Rblock; for each
/// ommer, we raise the blocks beneficiary by an additional 1/32 of the block reward
/// and the beneficiary of the ommer gets rewarded depending on the blocknumber.
/// Formally we define the function Ω.
///
/// NOTE: Related to Ethereum reward change, for other network this is probably going to be
/// moved to config.
fn get_block_reward(&self, header: &Header, total_difficulty: U256) -> Option<u128> {
if self.chain_spec.fork(Hardfork::Paris).active_at_ttd(total_difficulty, header.difficulty)
{
None
} else if self.chain_spec.fork(Hardfork::Petersburg).active_at_block(header.number) {
Some(WEI_2ETH)
} else if self.chain_spec.fork(Hardfork::Byzantium).active_at_block(header.number) {
Some(WEI_3ETH)
} else {
Some(WEI_5ETH)
}
}
/// Irregular state change at Ethereum DAO hardfork
fn apply_dao_fork_changes(&mut self, post_state: &mut PostState) -> Result<(), Error> {
let db = self.db();
let mut drained_balance = U256::ZERO;
// drain all accounts ether
for address in crate::eth_dao_fork::DAO_HARDKFORK_ACCOUNTS {
let db_account = db.load_account(address).map_err(|_| Error::ProviderError)?;
let old = to_reth_acc(&db_account.info);
// drain balance
drained_balance += core::mem::take(&mut db_account.info.balance);
let new = to_reth_acc(&db_account.info);
// assume it is changeset as it is irregular state change
post_state.change_account(address, old, new);
}
// add drained ether to beneficiary.
let beneficiary = crate::eth_dao_fork::DAO_HARDFORK_BENEFICIARY;
self.increment_account_balance(beneficiary, drained_balance, post_state)?;
Ok(())
}
/// Increment the balance for the given account in the [PostState].
fn increment_account_balance(
&mut self,
address: Address,
increment: U256,
post_state: &mut PostState,
) -> Result<(), Error> {
let db = self.db();
let beneficiary = db.load_account(address).map_err(|_| Error::ProviderError)?;
let old = to_reth_acc(&beneficiary.info);
// Increment beneficiary balance by mutating db entry in place.
beneficiary.info.balance += increment;
let new = to_reth_acc(&beneficiary.info);
match beneficiary.account_state {
AccountState::NotExisting => {
// if account was not existing that means that storage is not
// present.
beneficiary.account_state = AccountState::StorageCleared;
// if account was not present append `Created` changeset
post_state.create_account(
address,
Account { nonce: 0, balance: new.balance, bytecode_hash: None },
)
}
AccountState::StorageCleared | AccountState::Touched | AccountState::None => {
// If account is None that means that EVM didn't touch it.
// we are changing the state to Touched as account can have
// storage in db.
if beneficiary.account_state == AccountState::None {
beneficiary.account_state = AccountState::Touched;
}
// if account was present, append changed changeset.
post_state.change_account(address, old, new);
}
}
Ok(())
}
/// Runs a single transaction in the configured environment and proceeds
/// to return the result and state diff (without applying it).
///
/// Assumes the rest of the block environment has been filled via `init_block_env`.
pub fn transact(
&mut self,
transaction: &TransactionSigned,
sender: Address,
) -> Result<ResultAndState, Error> {
// Fill revm structure.
fill_tx_env(&mut self.evm.env.tx, transaction, sender);
let hash = transaction.hash();
let out = if self.stack.should_inspect(&self.evm.env, hash) {
// execution with inspector.
let output = self.evm.inspect(&mut self.stack);
tracing::trace!(
target: "evm",
?hash, ?output, ?transaction, env = ?self.evm.env,
"Executed transaction"
);
output
} else {
// main execution.
self.evm.transact()
};
out.map_err(|e| Error::EVM { hash, message: format!("{e:?}") })
}
/// Runs the provided transactions and commits their state to the run-time database.
///
/// The returned [PostState] can be used to persist the changes to disk, and contains the
/// changes made by each transaction.
///
/// The changes in [PostState] have a transition ID associated with them: there is one
/// transition ID for each transaction (with the first executed tx having transition ID 0, and
/// so on).
///
/// The second returned value represents the total gas used by this block of transactions.
pub fn execute_transactions(
&mut self,
block: &Block,
total_difficulty: U256,
senders: Option<Vec<Address>>,
) -> Result<(PostState, u64), Error> {
let senders = self.recover_senders(&block.body, senders)?;
self.init_env(&block.header, total_difficulty);
let mut cumulative_gas_used = 0;
let mut post_state = PostState::with_tx_capacity(block.body.len());
for (transaction, sender) in block.body.iter().zip(senders.into_iter()) {
// The sum of the transactions gas limit, Tg, and the gas utilised in this block prior,
// must be no greater than the blocks gasLimit.
let block_available_gas = block.header.gas_limit - cumulative_gas_used;
if transaction.gas_limit() > block_available_gas {
return Err(Error::TransactionGasLimitMoreThenAvailableBlockGas {
transaction_gas_limit: transaction.gas_limit(),
block_available_gas,
})
}
// Execute transaction.
let ResultAndState { result, state } = self.transact(transaction, sender)?;
// commit changes
self.commit_changes(
state,
self.chain_spec.fork(Hardfork::SpuriousDragon).active_at_block(block.number),
&mut post_state,
);
// append gas used
cumulative_gas_used += result.gas_used();
// cast revm logs to reth logs
let logs: Vec<Log> = result.logs().into_iter().map(into_reth_log).collect();
// Push transaction changeset and calculate header bloom filter for receipt.
post_state.add_receipt(Receipt {
tx_type: transaction.tx_type(),
// Success flag was added in `EIP-658: Embedding transaction status code in
// receipts`.
success: result.is_success(),
cumulative_gas_used,
bloom: logs_bloom(logs.iter()),
logs,
});
post_state.finish_transition();
}
Ok((post_state, cumulative_gas_used))
}
}
impl<DB> BlockExecutor<DB> for Executor<DB>
where
DB: StateProvider,
{
fn execute(
&mut self,
block: &Block,
total_difficulty: U256,
senders: Option<Vec<Address>>,
) -> Result<PostState, Error> {
let (mut post_state, cumulative_gas_used) =
self.execute_transactions(block, total_difficulty, senders)?;
// Check if gas used matches the value set in header.
if block.gas_used != cumulative_gas_used {
return Err(Error::BlockGasUsed { got: cumulative_gas_used, expected: block.gas_used })
}
let balance_increments = self.post_block_balance_increments(block, total_difficulty)?;
let mut includes_block_transition = !balance_increments.is_empty();
for (address, increment) in balance_increments.into_iter() {
self.increment_account_balance(address, increment, &mut post_state)?;
}
if self.chain_spec.fork(Hardfork::Dao).transitions_at_block(block.number) {
includes_block_transition = true;
self.apply_dao_fork_changes(&mut post_state)?;
}
if includes_block_transition {
post_state.finish_transition();
}
Ok(post_state)
}
fn execute_and_verify_receipt(
&mut self,
block: &Block,
total_difficulty: U256,
senders: Option<Vec<Address>>,
) -> Result<PostState, Error> {
let post_state = self.execute(block, total_difficulty, senders)?;
if self.chain_spec.fork(Hardfork::Byzantium).active_at_block(block.header.number) {
verify_receipt(
block.header.receipts_root,
block.header.logs_bloom,
post_state.receipts().iter(),
)?;
}
// TODO Before Byzantium, receipts contained state root that would mean that expensive
// operation as hashing that is needed for state root got calculated in every
// transaction This was replaced with is_success flag.
// See more about EIP here: https://eips.ethereum.org/EIPS/eip-658
Ok(post_state)
}
}
/// Verify receipts
pub fn verify_receipt<'a>(
expected_receipts_root: H256,
expected_logs_bloom: Bloom,
receipts: impl Iterator<Item = &'a Receipt> + Clone,
) -> Result<(), Error> {
// Check receipts root.
let receipts_root = reth_primitives::proofs::calculate_receipt_root(receipts.clone());
if receipts_root != expected_receipts_root {
return Err(Error::ReceiptRootDiff { got: receipts_root, expected: expected_receipts_root })
}
// Create header log bloom.
let logs_bloom = receipts.fold(Bloom::zero(), |bloom, r| bloom | r.bloom);
if logs_bloom != expected_logs_bloom {
return Err(Error::BloomLogDiff {
expected: Box::new(expected_logs_bloom),
got: Box::new(logs_bloom),
})
}
Ok(())
}
#[cfg(test)]
mod tests {
use super::*;
use reth_primitives::{
hex_literal::hex, keccak256, Account, Address, BlockNumber, Bytecode, Bytes,
ChainSpecBuilder, ForkCondition, StorageKey, H256, MAINNET, U256,
};
use reth_provider::{
post_state::{Change, Storage},
AccountProvider, BlockHashProvider, StateProvider,
};
use reth_revm::database::State;
use reth_rlp::Decodable;
use std::{collections::HashMap, str::FromStr};
#[derive(Debug, Default, Clone, Eq, PartialEq)]
struct StateProviderTest {
accounts: HashMap<Address, (HashMap<StorageKey, U256>, Account)>,
contracts: HashMap<H256, Bytecode>,
block_hash: HashMap<u64, H256>,
}
impl StateProviderTest {
/// Insert account.
fn insert_account(
&mut self,
address: Address,
mut account: Account,
bytecode: Option<Bytes>,
storage: HashMap<StorageKey, U256>,
) {
if let Some(bytecode) = bytecode {
let hash = keccak256(&bytecode);
account.bytecode_hash = Some(hash);
self.contracts.insert(hash, Bytecode::new_raw(bytecode.into()));
}
self.accounts.insert(address, (storage, account));
}
}
impl AccountProvider for StateProviderTest {
fn basic_account(&self, address: Address) -> reth_interfaces::Result<Option<Account>> {
let ret = Ok(self.accounts.get(&address).map(|(_, acc)| *acc));
ret
}
}
impl BlockHashProvider for StateProviderTest {
fn block_hash(&self, number: u64) -> reth_interfaces::Result<Option<H256>> {
Ok(self.block_hash.get(&number).cloned())
}
fn canonical_hashes_range(
&self,
start: BlockNumber,
end: BlockNumber,
) -> reth_interfaces::Result<Vec<H256>> {
let range = start..end;
Ok(self
.block_hash
.iter()
.filter_map(|(block, hash)| range.contains(block).then_some(*hash))
.collect())
}
}
impl StateProvider for StateProviderTest {
fn storage(
&self,
account: Address,
storage_key: reth_primitives::StorageKey,
) -> reth_interfaces::Result<Option<reth_primitives::StorageValue>> {
Ok(self
.accounts
.get(&account)
.and_then(|(storage, _)| storage.get(&storage_key).cloned()))
}
fn bytecode_by_hash(&self, code_hash: H256) -> reth_interfaces::Result<Option<Bytecode>> {
Ok(self.contracts.get(&code_hash).cloned())
}
fn proof(
&self,
_address: Address,
_keys: &[H256],
) -> reth_interfaces::Result<(Vec<Bytes>, H256, Vec<Vec<Bytes>>)> {
todo!()
}
}
#[test]
fn sanity_execution() {
// Got rlp block from: src/GeneralStateTestsFiller/stChainId/chainIdGasCostFiller.json
let mut block_rlp = hex!("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").as_slice();
let mut block = Block::decode(&mut block_rlp).unwrap();
let mut ommer = Header::default();
let ommer_beneficiary =
Address::from_str("3000000000000000000000000000000000000000").unwrap();
ommer.beneficiary = ommer_beneficiary;
ommer.number = block.number;
block.ommers = vec![ommer];
let mut db = StateProviderTest::default();
let account1 = Address::from_str("1000000000000000000000000000000000000000").unwrap();
let account2 = Address::from_str("2adc25665018aa1fe0e6bc666dac8fc2697ff9ba").unwrap();
let account3 = Address::from_str("a94f5374fce5edbc8e2a8697c15331677e6ebf0b").unwrap();
// pre state
db.insert_account(
account1,
Account { balance: U256::ZERO, nonce: 0x00, bytecode_hash: None },
Some(hex!("5a465a905090036002900360015500").into()),
HashMap::new(),
);
let account3_old_info = Account {
balance: U256::from(0x3635c9adc5dea00000u128),
nonce: 0x00,
bytecode_hash: None,
};
db.insert_account(
account3,
Account {
balance: U256::from(0x3635c9adc5dea00000u128),
nonce: 0x00,
bytecode_hash: None,
},
None,
HashMap::new(),
);
// spec at berlin fork
let chain_spec = Arc::new(ChainSpecBuilder::mainnet().berlin_activated().build());
let db = SubState::new(State::new(db));
// execute chain and verify receipts
let mut executor = Executor::new(chain_spec, db);
let post_state = executor.execute_and_verify_receipt(&block, U256::ZERO, None).unwrap();
assert_eq!(
post_state.transitions_count(),
2,
"Should executed two transitions (1 tx and 1 block reward)"
);
let block_reward = U256::from(WEI_2ETH + (WEI_2ETH >> 5));
let account1_info = Account { balance: U256::ZERO, nonce: 0x00, bytecode_hash: None };
let account2_info = Account {
// Block reward decrease
balance: U256::from(0x1bc16d674ece94bau128 - 0x1bc16d674ec80000u128),
nonce: 0x00,
bytecode_hash: None,
};
let account2_info_with_block_reward = Account {
balance: account2_info.balance + block_reward,
nonce: 0x00,
bytecode_hash: None,
};
let account3_info = Account {
balance: U256::from(0x3635c9adc5de996b46u128),
nonce: 0x01,
bytecode_hash: None,
};
let ommer_beneficiary_info =
Account { nonce: 0, balance: U256::from((8 * WEI_2ETH) >> 3), bytecode_hash: None };
// Check if cache is set
// account1
let db = executor.db();
let cached_acc1 = db.accounts.get(&account1).unwrap();
assert_eq!(cached_acc1.info.balance, account1_info.balance);
assert_eq!(cached_acc1.info.nonce, account1_info.nonce);
assert_eq!(cached_acc1.account_state, AccountState::Touched);
assert_eq!(cached_acc1.storage.len(), 1);
assert_eq!(cached_acc1.storage.get(&U256::from(1)), Some(&U256::from(2)));
// account2 Block reward
let cached_acc2 = db.accounts.get(&account2).unwrap();
assert_eq!(cached_acc2.info.balance, account2_info.balance + block_reward);
assert_eq!(cached_acc2.info.nonce, account2_info.nonce);
assert_eq!(cached_acc2.account_state, AccountState::Touched);
assert_eq!(cached_acc2.storage.len(), 0);
// account3
let cached_acc3 = db.accounts.get(&account3).unwrap();
assert_eq!(cached_acc3.info.balance, account3_info.balance);
assert_eq!(cached_acc3.info.nonce, account3_info.nonce);
assert_eq!(cached_acc3.account_state, AccountState::Touched);
assert_eq!(cached_acc3.storage.len(), 0);
assert!(
post_state.accounts().get(&account1).is_none(),
"Account should not be present in post-state since it was not changed"
);
// Check changes
const TX_TRANSITION_ID: u64 = 0;
const BLOCK_TRANSITION_ID: u64 = 1;
// Clone and sort to make the test deterministic
let mut changes = post_state.changes().to_vec();
changes.sort_by_key(|change| (change.transition_id(), change.address()));
assert_eq!(
changes,
&[
// Storage changes on account 1
Change::StorageChanged {
id: TX_TRANSITION_ID,
address: account1,
changeset: [(U256::from(1), (U256::ZERO, U256::from(2)))].into()
},
// New account
Change::AccountCreated {
id: TX_TRANSITION_ID,
address: account2,
account: account2_info
},
// Changed account
Change::AccountChanged {
id: TX_TRANSITION_ID,
address: account3,
old: account3_old_info,
new: account3_info
},
// Block reward
Change::AccountChanged {
id: BLOCK_TRANSITION_ID,
address: account2,
old: account2_info,
new: account2_info_with_block_reward
},
// Ommer reward
Change::AccountCreated {
id: BLOCK_TRANSITION_ID,
address: ommer_beneficiary,
account: ommer_beneficiary_info
},
],
"Changeset did not match"
);
// Check final post-state
assert_eq!(
post_state.storage(),
&BTreeMap::from([(
account1,
Storage { wiped: false, storage: BTreeMap::from([(U256::from(1), U256::from(2))]) }
)]),
"Should have changed 1 storage slot"
);
assert_eq!(post_state.bytecodes().len(), 0, "Should have zero new bytecodes");
let accounts = post_state.accounts();
assert_eq!(
accounts.len(),
3,
"Should have 4 accounts (account 2, 3 and the ommer beneficiary)"
);
assert_eq!(
accounts.get(&account2).unwrap(),
&Some(account2_info_with_block_reward),
"Account 2 state is wrong"
);
assert_eq!(
accounts.get(&account3).unwrap(),
&Some(account3_info),
"Account 3 state is wrong"
);
assert_eq!(
accounts.get(&ommer_beneficiary).unwrap(),
&Some(ommer_beneficiary_info),
"Ommer beneficiary state is wrong"
);
}
#[test]
fn dao_hardfork_irregular_state_change() {
let header = Header { number: 1, ..Header::default() };
let mut db = StateProviderTest::default();
let mut beneficiary_balance = 0;
for (i, dao_address) in crate::eth_dao_fork::DAO_HARDKFORK_ACCOUNTS.iter().enumerate() {
db.insert_account(
*dao_address,
Account { balance: U256::from(i), nonce: 0x00, bytecode_hash: None },
None,
HashMap::new(),
);
beneficiary_balance += i;
}
let chain_spec = Arc::new(
ChainSpecBuilder::from(&*MAINNET)
.homestead_activated()
.with_fork(Hardfork::Dao, ForkCondition::Block(1))
.build(),
);
let db = SubState::new(State::new(db));
// execute chain and verify receipts
let mut executor = Executor::new(chain_spec, db);
let out = executor
.execute_and_verify_receipt(
&Block { header, body: vec![], ommers: vec![], withdrawals: None },
U256::ZERO,
None,
)
.unwrap();
assert_eq!(
out.transitions_count(),
1,
"Should only have 1 transition (the block transition)"
);
// Check if cache is set
// beneficiary
let db = executor.db();
let dao_beneficiary =
db.accounts.get(&crate::eth_dao_fork::DAO_HARDFORK_BENEFICIARY).unwrap();
assert_eq!(dao_beneficiary.info.balance, U256::from(beneficiary_balance));
for address in crate::eth_dao_fork::DAO_HARDKFORK_ACCOUNTS.iter() {
let account = db.accounts.get(address).unwrap();
assert_eq!(account.info.balance, U256::ZERO);
}
// check changesets
let beneficiary_state =
out.accounts().get(&crate::eth_dao_fork::DAO_HARDFORK_BENEFICIARY).unwrap().unwrap();
assert_eq!(
beneficiary_state,
Account { balance: U256::from(beneficiary_balance), ..Default::default() },
);
for address in crate::eth_dao_fork::DAO_HARDKFORK_ACCOUNTS.iter() {
let updated_account = out.accounts().get(address).unwrap().unwrap();
assert_eq!(updated_account, Account { balance: U256::ZERO, ..Default::default() });
}
}
#[test]
fn test_selfdestruct() {
// Modified version of eth test. Storage is added for selfdestructed account to see
// that changeset is set.
// Got rlp block from: src/GeneralStateTestsFiller/stArgsZeroOneBalance/suicideNonConst.json
let mut block_rlp = hex!("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").as_slice();
let block = Block::decode(&mut block_rlp).unwrap();
let mut db = StateProviderTest::default();
let address_caller = Address::from_str("a94f5374fce5edbc8e2a8697c15331677e6ebf0b").unwrap();
let address_selfdestruct =
Address::from_str("095e7baea6a6c7c4c2dfeb977efac326af552d87").unwrap();
// pre state
let pre_account_caller = Account {
balance: U256::from(0x0de0b6b3a7640000u64),
nonce: 0x00,
bytecode_hash: None,
};
db.insert_account(address_caller, pre_account_caller, None, HashMap::new());
// insert account that will selfd
let pre_account_selfdestroyed = Account {
balance: U256::ZERO,
nonce: 0x00,
bytecode_hash: Some(H256(hex!(
"56a7d44a4ecf086c34482ad1feb1007087fc56fae6dbefbd3f416002933f1705"
))),
};
let selfdestroyed_storage =
BTreeMap::from([(H256::zero(), U256::ZERO), (H256::from_low_u64_be(1), U256::from(1))]);
db.insert_account(
address_selfdestruct,
pre_account_selfdestroyed,
Some(hex!("73095e7baea6a6c7c4c2dfeb977efac326af552d8731ff00").into()),
selfdestroyed_storage.into_iter().collect::<HashMap<_, _>>(),
);
// spec at berlin fork
let chain_spec = Arc::new(ChainSpecBuilder::mainnet().berlin_activated().build());
let db = SubState::new(State::new(db));
// execute chain and verify receipts
let mut executor = Executor::new(chain_spec, db);
let out = executor.execute_and_verify_receipt(&block, U256::ZERO, None).unwrap();
assert_eq!(
out.transitions_count(),
2,
"Should only have two transitions (the transaction and the block)"
);
assert_eq!(out.bytecodes().len(), 0, "Should have zero new bytecodes");
let post_account_caller = Account {
balance: U256::from(0x0de0b6b3a761cf60u64),
nonce: 0x01,
bytecode_hash: None,
};
assert_eq!(
out.accounts().get(&address_caller).unwrap().unwrap(),
post_account_caller,
"Caller account has changed and fee is deduced"
);
assert_eq!(
out.accounts().get(&address_selfdestruct).unwrap(),
&None,
"Selfdestructed account should have been deleted"
);
assert!(
out.storage().get(&address_selfdestruct).unwrap().wiped,
"Selfdestructed account should have its storage wiped"
);
}
// Test vector from https://github.com/ethereum/tests/blob/3156db5389921125bb9e04142d18e0e7b0cf8d64/BlockchainTests/EIPTests/bc4895-withdrawals/twoIdenticalIndexDifferentValidator.json
#[test]
fn test_withdrawals() {
let block_rlp = hex!("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");
let block = Block::decode(&mut block_rlp.as_slice()).unwrap();
let withdrawals = block.withdrawals.as_ref().unwrap();
assert_eq!(withdrawals.len(), 4);
let withdrawal_beneficiary =
Address::from_str("c94f5374fce5edbc8e2a8697c15331677e6ebf0b").unwrap();
// spec at shanghai fork
let chain_spec = Arc::new(ChainSpecBuilder::mainnet().shanghai_activated().build());
let db = SubState::new(State::new(StateProviderTest::default()));
// execute chain and verify receipts
let mut executor = Executor::new(chain_spec, db);
let out = executor.execute_and_verify_receipt(&block, U256::ZERO, None).unwrap();
assert_eq!(out.transitions_count(), 1, "Only one transition (the block transition)");
let withdrawal_sum = withdrawals.iter().fold(U256::ZERO, |sum, w| sum + w.amount_wei());
let beneficiary_account = executor.db().accounts.get(&withdrawal_beneficiary).unwrap();
assert_eq!(beneficiary_account.info.balance, withdrawal_sum);
assert_eq!(beneficiary_account.info.nonce, 0);
assert_eq!(beneficiary_account.account_state, AccountState::StorageCleared);
assert_eq!(
out.accounts().get(&withdrawal_beneficiary).unwrap(),
&Some(Account { nonce: 0, balance: withdrawal_sum, bytecode_hash: None }),
"Withdrawal account should have gotten its balance set"
);
// Execute same block again
let out = executor.execute_and_verify_receipt(&block, U256::ZERO, None).unwrap();
assert_eq!(
out.transitions_count(),
1,
"Should only have one transition (the block transition)"
);
assert_eq!(
out.accounts().get(&withdrawal_beneficiary).unwrap(),
&Some(Account {
nonce: 0,
balance: withdrawal_sum + withdrawal_sum,
bytecode_hash: None
}),
"Withdrawal account should have gotten its balance set"
);
}
#[test]
fn test_account_state_preserved() {
let account = Address::from_str("c94f5374fce5edbc8e2a8697c15331677e6ebf0b").unwrap();
let mut db = StateProviderTest::default();
db.insert_account(account, Account::default(), None, HashMap::default());
let chain_spec = Arc::new(ChainSpecBuilder::mainnet().istanbul_activated().build());
let db = SubState::new(State::new(db));
let default_acc = RevmAccount {
info: AccountInfo::default(),
storage: hash_map::HashMap::default(),
is_destroyed: false,
is_touched: false,
storage_cleared: false,
is_not_existing: false,
};
let mut executor = Executor::new(chain_spec, db);
// touch account
executor.commit_changes(
hash_map::HashMap::from([(account, RevmAccount { ..default_acc.clone() })]),
true,
&mut PostState::default(),
);
// destroy account
executor.commit_changes(
hash_map::HashMap::from([(
account,
RevmAccount { is_destroyed: true, is_touched: true, ..default_acc.clone() },
)]),
true,
&mut PostState::default(),
);
// re-create account
executor.commit_changes(
hash_map::HashMap::from([(
account,
RevmAccount { is_touched: true, storage_cleared: true, ..default_acc.clone() },
)]),
true,
&mut PostState::default(),
);
// touch account
executor.commit_changes(
hash_map::HashMap::from([(account, RevmAccount { ..default_acc })]),
true,
&mut PostState::default(),
);
let db = executor.db();
let account = db.load_account(account).unwrap();
assert_eq!(account.account_state, AccountState::StorageCleared);
}
}
Reference in New Issue View Git Blame Copy Permalink