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solana
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solana/runtime/src/bank/tests.rs

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#![cfg(test)]
#[allow(deprecated)]
use solana_sdk::sysvar::fees::Fees;
use {
super::{
test_utils::{goto_end_of_slot, update_vote_account_timestamp},
*,
},
crate::{
accounts::{AccountAddressFilter, RewardInterval},
accounts_background_service::{PrunedBanksRequestHandler, SendDroppedBankCallback},
accounts_db::{AccountShrinkThreshold, DEFAULT_ACCOUNTS_SHRINK_RATIO},
accounts_index::{
AccountIndex, AccountSecondaryIndexes, IndexKey, ScanConfig, ScanError, ITER_BATCH_SIZE,
},
accounts_partition::{self, PartitionIndex, RentPayingAccountsByPartition},
ancestors::Ancestors,
bank_client::BankClient,
genesis_utils::{
self, activate_all_features, activate_feature, bootstrap_validator_stake_lamports,
create_genesis_config_with_leader, create_genesis_config_with_vote_accounts,
genesis_sysvar_and_builtin_program_lamports, GenesisConfigInfo, ValidatorVoteKeypairs,
},
inline_spl_token,
rent_collector::RENT_EXEMPT_RENT_EPOCH,
status_cache::MAX_CACHE_ENTRIES,
transaction_error_metrics::TransactionErrorMetrics,
},
crossbeam_channel::{bounded, unbounded},
itertools::Itertools,
rand::Rng,
rayon::ThreadPoolBuilder,
serde::{Deserialize, Serialize},
solana_logger,
solana_program_runtime::{
compute_budget::{self, ComputeBudget, MAX_COMPUTE_UNIT_LIMIT},
declare_process_instruction,
invoke_context::mock_process_instruction,
loaded_programs::{LoadedProgram, LoadedProgramType, DELAY_VISIBILITY_SLOT_OFFSET},
prioritization_fee::{PrioritizationFeeDetails, PrioritizationFeeType},
timings::ExecuteTimings,
},
solana_sdk::{
account::{
create_account_shared_data_with_fields as create_account, from_account, Account,
AccountSharedData, ReadableAccount, WritableAccount,
},
account_utils::StateMut,
bpf_loader,
bpf_loader_upgradeable::{self, UpgradeableLoaderState},
client::SyncClient,
clock::{
BankId, Epoch, Slot, UnixTimestamp, DEFAULT_HASHES_PER_TICK, DEFAULT_SLOTS_PER_EPOCH,
DEFAULT_TICKS_PER_SLOT, INITIAL_RENT_EPOCH, MAX_PROCESSING_AGE, MAX_RECENT_BLOCKHASHES,
},
compute_budget::ComputeBudgetInstruction,
entrypoint::MAX_PERMITTED_DATA_INCREASE,
epoch_schedule::{EpochSchedule, MINIMUM_SLOTS_PER_EPOCH},
feature::{self, Feature},
feature_set::{self, reject_callx_r10, FeatureSet},
fee::FeeStructure,
fee_calculator::FeeRateGovernor,
genesis_config::{create_genesis_config, ClusterType, GenesisConfig},
hash::{self, hash, Hash},
incinerator,
instruction::{AccountMeta, CompiledInstruction, Instruction, InstructionError},
loader_upgradeable_instruction::UpgradeableLoaderInstruction,
message::{Message, MessageHeader, SanitizedMessage},
native_loader,
native_token::{sol_to_lamports, LAMPORTS_PER_SOL},
nonce::{self, state::DurableNonce},
packet::PACKET_DATA_SIZE,
poh_config::PohConfig,
program::MAX_RETURN_DATA,
pubkey::Pubkey,
rent::Rent,
reward_type::RewardType,
secp256k1_program,
signature::{keypair_from_seed, Keypair, Signature, Signer},
stake::{
instruction as stake_instruction,
state::{Authorized, Delegation, Lockup, Stake},
},
system_instruction::{
self, SystemError, MAX_PERMITTED_ACCOUNTS_DATA_ALLOCATIONS_PER_TRANSACTION,
MAX_PERMITTED_DATA_LENGTH,
},
system_program, system_transaction, sysvar,
timing::{duration_as_s, years_as_slots},
transaction::{
Result, SanitizedTransaction, Transaction, TransactionError,
TransactionVerificationMode,
},
transaction_context::{TransactionAccount, TransactionContext},
},
solana_stake_program::stake_state::{self, StakeState},
solana_vote_program::{
vote_instruction,
vote_state::{
self, BlockTimestamp, Vote, VoteInit, VoteState, VoteStateVersions, MAX_LOCKOUT_HISTORY,
},
},
std::{
collections::{HashMap, HashSet},
convert::{TryFrom, TryInto},
fs::File,
io::Read,
str::FromStr,
sync::{
atomic::{
AtomicBool, AtomicU64,
Ordering::{Relaxed, Release},
},
Arc,
},
thread::Builder,
time::{Duration, Instant},
},
test_case::test_case,
};
#[test]
fn test_race_register_tick_freeze() {
solana_logger::setup();
let (mut genesis_config, _) = create_genesis_config(50);
genesis_config.ticks_per_slot = 1;
let p = solana_sdk::pubkey::new_rand();
let hash = hash(p.as_ref());
for _ in 0..1000 {
let bank0 = Arc::new(Bank::new_for_tests(&genesis_config));
let bank0_ = bank0.clone();
let freeze_thread = Builder::new()
.name("freeze".to_string())
.spawn(move || loop {
if bank0_.is_complete() {
assert_eq!(bank0_.last_blockhash(), hash);
break;
}
})
.unwrap();
let bank0_ = bank0.clone();
let register_tick_thread = Builder::new()
.name("register_tick".to_string())
.spawn(move || {
bank0_.register_tick(&hash);
})
.unwrap();
register_tick_thread.join().unwrap();
freeze_thread.join().unwrap();
}
}
fn new_sanitized_message(instructions: &[Instruction], payer: Option<&Pubkey>) -> SanitizedMessage {
Message::new(instructions, payer).try_into().unwrap()
}
fn new_execution_result(
status: Result<()>,
nonce: Option<&NonceFull>,
) -> TransactionExecutionResult {
TransactionExecutionResult::Executed {
details: TransactionExecutionDetails {
status,
log_messages: None,
inner_instructions: None,
durable_nonce_fee: nonce.map(DurableNonceFee::from),
return_data: None,
executed_units: 0,
accounts_data_len_delta: 0,
},
programs_modified_by_tx: Box::<LoadedProgramsForTxBatch>::default(),
programs_updated_only_for_global_cache: Box::<LoadedProgramsForTxBatch>::default(),
}
}
impl Bank {
fn clean_accounts_for_tests(&self) {
self.rc.accounts.accounts_db.clean_accounts_for_tests()
}
}
#[test]
fn test_nonce_info() {
let lamports_per_signature = 42;
let nonce_authority = keypair_from_seed(&[0; 32]).unwrap();
let nonce_address = nonce_authority.pubkey();
let from = keypair_from_seed(&[1; 32]).unwrap();
let from_address = from.pubkey();
let to_address = Pubkey::new_unique();
let durable_nonce = DurableNonce::from_blockhash(&Hash::new_unique());
let nonce_account = AccountSharedData::new_data(
43,
&nonce::state::Versions::new(nonce::State::Initialized(nonce::state::Data::new(
Pubkey::default(),
durable_nonce,
lamports_per_signature,
))),
&system_program::id(),
)
.unwrap();
let from_account = AccountSharedData::new(44, 0, &Pubkey::default());
let to_account = AccountSharedData::new(45, 0, &Pubkey::default());
let recent_blockhashes_sysvar_account = AccountSharedData::new(4, 0, &Pubkey::default());
const TEST_RENT_DEBIT: u64 = 1;
let rent_collected_nonce_account = {
let mut account = nonce_account.clone();
account.set_lamports(nonce_account.lamports() - TEST_RENT_DEBIT);
account
};
let rent_collected_from_account = {
let mut account = from_account.clone();
account.set_lamports(from_account.lamports() - TEST_RENT_DEBIT);
account
};
let instructions = vec![
system_instruction::advance_nonce_account(&nonce_address, &nonce_authority.pubkey()),
system_instruction::transfer(&from_address, &to_address, 42),
];
// NoncePartial create + NonceInfo impl
let partial = NoncePartial::new(nonce_address, rent_collected_nonce_account.clone());
assert_eq!(*partial.address(), nonce_address);
assert_eq!(*partial.account(), rent_collected_nonce_account);
assert_eq!(
partial.lamports_per_signature(),
Some(lamports_per_signature)
);
assert_eq!(partial.fee_payer_account(), None);
// Add rent debits to ensure the rollback captures accounts without rent fees
let mut rent_debits = RentDebits::default();
rent_debits.insert(
&from_address,
TEST_RENT_DEBIT,
rent_collected_from_account.lamports(),
);
rent_debits.insert(
&nonce_address,
TEST_RENT_DEBIT,
rent_collected_nonce_account.lamports(),
);
// NonceFull create + NonceInfo impl
{
let message = new_sanitized_message(&instructions, Some(&from_address));
let accounts = [
(
*message.account_keys().get(0).unwrap(),
rent_collected_from_account.clone(),
),
(
*message.account_keys().get(1).unwrap(),
rent_collected_nonce_account.clone(),
),
(*message.account_keys().get(2).unwrap(), to_account.clone()),
(
*message.account_keys().get(3).unwrap(),
recent_blockhashes_sysvar_account.clone(),
),
];
let full =
NonceFull::from_partial(partial.clone(), &message, &accounts, &rent_debits).unwrap();
assert_eq!(*full.address(), nonce_address);
assert_eq!(*full.account(), rent_collected_nonce_account);
assert_eq!(full.lamports_per_signature(), Some(lamports_per_signature));
assert_eq!(
full.fee_payer_account(),
Some(&from_account),
"rent debit should be refunded in captured fee account"
);
}
// Nonce account is fee-payer
{
let message = new_sanitized_message(&instructions, Some(&nonce_address));
let accounts = [
(
*message.account_keys().get(0).unwrap(),
rent_collected_nonce_account,
),
(
*message.account_keys().get(1).unwrap(),
rent_collected_from_account,
),
(*message.account_keys().get(2).unwrap(), to_account),
(
*message.account_keys().get(3).unwrap(),
recent_blockhashes_sysvar_account,
),
];
let full =
NonceFull::from_partial(partial.clone(), &message, &accounts, &rent_debits).unwrap();
assert_eq!(*full.address(), nonce_address);
assert_eq!(*full.account(), nonce_account);
assert_eq!(full.lamports_per_signature(), Some(lamports_per_signature));
assert_eq!(full.fee_payer_account(), None);
}
// NonceFull create, fee-payer not in account_keys fails
{
let message = new_sanitized_message(&instructions, Some(&nonce_address));
assert_eq!(
NonceFull::from_partial(partial, &message, &[], &RentDebits::default()).unwrap_err(),
TransactionError::AccountNotFound,
);
}
}
#[test]
fn test_bank_unix_timestamp_from_genesis() {
let (genesis_config, _mint_keypair) = create_genesis_config(1);
let mut bank = Arc::new(Bank::new_for_tests(&genesis_config));
assert_eq!(
genesis_config.creation_time,
bank.unix_timestamp_from_genesis()
);
let slots_per_sec = 1.0
/ (duration_as_s(&genesis_config.poh_config.target_tick_duration)
* genesis_config.ticks_per_slot as f32);
for _i in 0..slots_per_sec as usize + 1 {
bank = Arc::new(new_from_parent(&bank));
}
assert!(bank.unix_timestamp_from_genesis() - genesis_config.creation_time >= 1);
}
#[test]
#[allow(clippy::float_cmp)]
fn test_bank_new() {
let dummy_leader_pubkey = solana_sdk::pubkey::new_rand();
let dummy_leader_stake_lamports = bootstrap_validator_stake_lamports();
let mint_lamports = 10_000;
let GenesisConfigInfo {
mut genesis_config,
mint_keypair,
voting_keypair,
..
} = create_genesis_config_with_leader(
mint_lamports,
&dummy_leader_pubkey,
dummy_leader_stake_lamports,
);
genesis_config.rent = Rent {
lamports_per_byte_year: 5,
exemption_threshold: 1.2,
burn_percent: 5,
};
let bank = Bank::new_for_tests(&genesis_config);
assert_eq!(bank.get_balance(&mint_keypair.pubkey()), mint_lamports);
assert_eq!(
bank.get_balance(&voting_keypair.pubkey()),
dummy_leader_stake_lamports /* 1 token goes to the vote account associated with dummy_leader_lamports */
);
let rent_account = bank.get_account(&sysvar::rent::id()).unwrap();
let rent = from_account::<sysvar::rent::Rent, _>(&rent_account).unwrap();
assert_eq!(rent.burn_percent, 5);
assert_eq!(rent.exemption_threshold, 1.2);
assert_eq!(rent.lamports_per_byte_year, 5);
}
fn create_simple_test_bank(lamports: u64) -> Bank {
let (genesis_config, _mint_keypair) = create_genesis_config(lamports);
Bank::new_for_tests(&genesis_config)
}
fn create_simple_test_arc_bank(lamports: u64) -> Arc<Bank> {
Arc::new(create_simple_test_bank(lamports))
}
#[test]
fn test_bank_block_height() {
let bank0 = create_simple_test_arc_bank(1);
assert_eq!(bank0.block_height(), 0);
let bank1 = Arc::new(new_from_parent(&bank0));
assert_eq!(bank1.block_height(), 1);
}
#[test]
fn test_bank_update_epoch_stakes() {
impl Bank {
fn epoch_stake_keys(&self) -> Vec<Epoch> {
let mut keys: Vec<Epoch> = self.epoch_stakes.keys().copied().collect();
keys.sort_unstable();
keys
}
fn epoch_stake_key_info(&self) -> (Epoch, Epoch, usize) {
let mut keys: Vec<Epoch> = self.epoch_stakes.keys().copied().collect();
keys.sort_unstable();
(*keys.first().unwrap(), *keys.last().unwrap(), keys.len())
}
}
let mut bank = create_simple_test_bank(100_000);
let initial_epochs = bank.epoch_stake_keys();
assert_eq!(initial_epochs, vec![0, 1]);
for existing_epoch in &initial_epochs {
bank.update_epoch_stakes(*existing_epoch);
assert_eq!(bank.epoch_stake_keys(), initial_epochs);
}
for epoch in (initial_epochs.len() as Epoch)..MAX_LEADER_SCHEDULE_STAKES {
bank.update_epoch_stakes(epoch);
assert_eq!(bank.epoch_stakes.len() as Epoch, epoch + 1);
}
assert_eq!(
bank.epoch_stake_key_info(),
(
0,
MAX_LEADER_SCHEDULE_STAKES - 1,
MAX_LEADER_SCHEDULE_STAKES as usize
)
);
bank.update_epoch_stakes(MAX_LEADER_SCHEDULE_STAKES);
assert_eq!(
bank.epoch_stake_key_info(),
(
0,
MAX_LEADER_SCHEDULE_STAKES,
MAX_LEADER_SCHEDULE_STAKES as usize + 1
)
);
bank.update_epoch_stakes(MAX_LEADER_SCHEDULE_STAKES + 1);
assert_eq!(
bank.epoch_stake_key_info(),
(
1,
MAX_LEADER_SCHEDULE_STAKES + 1,
MAX_LEADER_SCHEDULE_STAKES as usize + 1
)
);
}
fn bank0_sysvar_delta() -> u64 {
const SLOT_HISTORY_SYSVAR_MIN_BALANCE: u64 = 913_326_000;
SLOT_HISTORY_SYSVAR_MIN_BALANCE
}
fn bank1_sysvar_delta() -> u64 {
const SLOT_HASHES_SYSVAR_MIN_BALANCE: u64 = 143_487_360;
SLOT_HASHES_SYSVAR_MIN_BALANCE
}
#[test]
fn test_bank_capitalization() {
let bank0 = Arc::new(Bank::new_for_tests(&GenesisConfig {
accounts: (0..42)
.map(|_| {
(
solana_sdk::pubkey::new_rand(),
Account::new(42, 0, &Pubkey::default()),
)
})
.collect(),
cluster_type: ClusterType::MainnetBeta,
..GenesisConfig::default()
}));
assert_eq!(
bank0.capitalization(),
42 * 42 + genesis_sysvar_and_builtin_program_lamports(),
);
bank0.freeze();
assert_eq!(
bank0.capitalization(),
42 * 42 + genesis_sysvar_and_builtin_program_lamports() + bank0_sysvar_delta(),
);
let bank1 = Bank::new_from_parent(&bank0, &Pubkey::default(), 1);
assert_eq!(
bank1.capitalization(),
42 * 42
+ genesis_sysvar_and_builtin_program_lamports()
+ bank0_sysvar_delta()
+ bank1_sysvar_delta(),
);
}
fn rent_with_exemption_threshold(exemption_threshold: f64) -> Rent {
Rent {
lamports_per_byte_year: 1,
exemption_threshold,
burn_percent: 10,
}
}
#[test]
/// one thing being tested here is that a failed tx (due to rent collection using up all lamports) followed by rent collection
/// results in the same state as if just rent collection ran (and emptied the accounts that have too few lamports)
fn test_credit_debit_rent_no_side_effect_on_hash() {
for set_exempt_rent_epoch_max in [false, true] {
solana_logger::setup();
let (mut genesis_config, _mint_keypair) = create_genesis_config(10);
genesis_config.rent = rent_with_exemption_threshold(21.0);
let slot = years_as_slots(
2.0,
&genesis_config.poh_config.target_tick_duration,
genesis_config.ticks_per_slot,
) as u64;
let root_bank = Arc::new(Bank::new_for_tests(&genesis_config));
let bank = Bank::new_from_parent(&root_bank, &Pubkey::default(), slot);
let root_bank_2 = Arc::new(Bank::new_for_tests(&genesis_config));
let bank_with_success_txs = Bank::new_from_parent(&root_bank_2, &Pubkey::default(), slot);
assert_eq!(bank.last_blockhash(), genesis_config.hash());
let plenty_of_lamports = 264;
let too_few_lamports = 10;
// Initialize credit-debit and credit only accounts
let accounts = [
AccountSharedData::new(plenty_of_lamports, 0, &Pubkey::default()),
AccountSharedData::new(plenty_of_lamports, 1, &Pubkey::default()),
AccountSharedData::new(plenty_of_lamports, 0, &Pubkey::default()),
AccountSharedData::new(plenty_of_lamports, 1, &Pubkey::default()),
// Transaction between these two accounts will fail
AccountSharedData::new(too_few_lamports, 0, &Pubkey::default()),
AccountSharedData::new(too_few_lamports, 1, &Pubkey::default()),
];
let keypairs = accounts.iter().map(|_| Keypair::new()).collect::<Vec<_>>();
{
// make sure rent and epoch change are such that we collect all lamports in accounts 4 & 5
let mut account_copy = accounts[4].clone();
let expected_rent = bank.rent_collector().collect_from_existing_account(
&keypairs[4].pubkey(),
&mut account_copy,
None,
set_exempt_rent_epoch_max,
);
assert_eq!(expected_rent.rent_amount, too_few_lamports);
assert_eq!(account_copy.lamports(), 0);
}
for i in 0..accounts.len() {
let account = &accounts[i];
bank.store_account(&keypairs[i].pubkey(), account);
bank_with_success_txs.store_account(&keypairs[i].pubkey(), account);
}
// Make builtin instruction loader rent exempt
let system_program_id = system_program::id();
let mut system_program_account = bank.get_account(&system_program_id).unwrap();
system_program_account.set_lamports(
bank.get_minimum_balance_for_rent_exemption(system_program_account.data().len()),
);
bank.store_account(&system_program_id, &system_program_account);
bank_with_success_txs.store_account(&system_program_id, &system_program_account);
let t1 = system_transaction::transfer(
&keypairs[0],
&keypairs[1].pubkey(),
1,
genesis_config.hash(),
);
let t2 = system_transaction::transfer(
&keypairs[2],
&keypairs[3].pubkey(),
1,
genesis_config.hash(),
);
// the idea is this transaction will result in both accounts being drained of all lamports due to rent collection
let t3 = system_transaction::transfer(
&keypairs[4],
&keypairs[5].pubkey(),
1,
genesis_config.hash(),
);
let txs = vec![t1.clone(), t2.clone(), t3];
let res = bank.process_transactions(txs.iter());
assert_eq!(res.len(), 3);
assert_eq!(res[0], Ok(()));
assert_eq!(res[1], Ok(()));
assert_eq!(res[2], Err(TransactionError::AccountNotFound));
bank.freeze();
let rwlockguard_bank_hash = bank.hash.read().unwrap();
let bank_hash = rwlockguard_bank_hash.as_ref();
let txs = vec![t2, t1];
let res = bank_with_success_txs.process_transactions(txs.iter());
assert_eq!(res.len(), 2);
assert_eq!(res[0], Ok(()));
assert_eq!(res[1], Ok(()));
bank_with_success_txs.freeze();
let rwlockguard_bank_with_success_txs_hash = bank_with_success_txs.hash.read().unwrap();
let bank_with_success_txs_hash = rwlockguard_bank_with_success_txs_hash.as_ref();
assert_eq!(bank_with_success_txs_hash, bank_hash);
}
}
fn store_accounts_for_rent_test(
bank: &Bank,
keypairs: &mut [Keypair],
mock_program_id: Pubkey,
generic_rent_due_for_system_account: u64,
) {
let mut account_pairs: Vec<TransactionAccount> = Vec::with_capacity(keypairs.len() - 1);
account_pairs.push((
keypairs[0].pubkey(),
AccountSharedData::new(
generic_rent_due_for_system_account + 2,
0,
&Pubkey::default(),
),
));
account_pairs.push((
keypairs[1].pubkey(),
AccountSharedData::new(
generic_rent_due_for_system_account + 2,
0,
&Pubkey::default(),
),
));
account_pairs.push((
keypairs[2].pubkey(),
AccountSharedData::new(
generic_rent_due_for_system_account + 2,
0,
&Pubkey::default(),
),
));
account_pairs.push((
keypairs[3].pubkey(),
AccountSharedData::new(
generic_rent_due_for_system_account + 2,
0,
&Pubkey::default(),
),
));
account_pairs.push((
keypairs[4].pubkey(),
AccountSharedData::new(10, 0, &Pubkey::default()),
));
account_pairs.push((
keypairs[5].pubkey(),
AccountSharedData::new(10, 0, &Pubkey::default()),
));
account_pairs.push((
keypairs[6].pubkey(),
AccountSharedData::new(
(2 * generic_rent_due_for_system_account) + 24,
0,
&Pubkey::default(),
),
));
account_pairs.push((
keypairs[8].pubkey(),
AccountSharedData::new(
generic_rent_due_for_system_account + 2 + 929,
0,
&Pubkey::default(),
),
));
account_pairs.push((
keypairs[9].pubkey(),
AccountSharedData::new(10, 0, &Pubkey::default()),
));
// Feeding to MockProgram to test read only rent behaviour
account_pairs.push((
keypairs[10].pubkey(),
AccountSharedData::new(
generic_rent_due_for_system_account + 3,
0,
&Pubkey::default(),
),
));
account_pairs.push((
keypairs[11].pubkey(),
AccountSharedData::new(generic_rent_due_for_system_account + 3, 0, &mock_program_id),
));
account_pairs.push((
keypairs[12].pubkey(),
AccountSharedData::new(generic_rent_due_for_system_account + 3, 0, &mock_program_id),
));
account_pairs.push((
keypairs[13].pubkey(),
AccountSharedData::new(14, 22, &mock_program_id),
));
for account_pair in account_pairs.iter() {
bank.store_account(&account_pair.0, &account_pair.1);
}
}
fn create_child_bank_for_rent_test(root_bank: &Arc<Bank>, genesis_config: &GenesisConfig) -> Bank {
let mut bank = Bank::new_from_parent(
root_bank,
&Pubkey::default(),
years_as_slots(
2.0,
&genesis_config.poh_config.target_tick_duration,
genesis_config.ticks_per_slot,
) as u64,
);
bank.rent_collector.slots_per_year = 421_812.0;
bank
}
/// if asserter returns true, check the capitalization
/// Checking the capitalization requires that the bank be a root and the slot be flushed.
/// All tests are getting converted to use the write cache, so over time, each caller will be visited to throttle this input.
/// Flushing the cache has a side effects on the test, so often the test has to be restarted to continue to function correctly.
fn assert_capitalization_diff(
bank: &Bank,
updater: impl Fn(),
asserter: impl Fn(u64, u64) -> bool,
) {
let old = bank.capitalization();
updater();
let new = bank.capitalization();
if asserter(old, new) {
add_root_and_flush_write_cache(bank);
assert_eq!(bank.capitalization(), bank.calculate_capitalization(true));
}
}
declare_process_instruction!(process_instruction, 1, |_invoke_context| {
// Default for all tests which don't bring their own processor
Ok(())
});
#[test]
fn test_store_account_and_update_capitalization_missing() {
let bank = create_simple_test_bank(0);
let pubkey = solana_sdk::pubkey::new_rand();
let some_lamports = 400;
let account = AccountSharedData::new(some_lamports, 0, &system_program::id());
assert_capitalization_diff(
&bank,
|| bank.store_account_and_update_capitalization(&pubkey, &account),
|old, new| {
assert_eq!(old + some_lamports, new);
true
},
);
assert_eq!(account, bank.get_account(&pubkey).unwrap());
}
#[test]
fn test_store_account_and_update_capitalization_increased() {
let old_lamports = 400;
let (genesis_config, mint_keypair) = create_genesis_config(old_lamports);
let bank = Bank::new_for_tests(&genesis_config);
let pubkey = mint_keypair.pubkey();
let new_lamports = 500;
let account = AccountSharedData::new(new_lamports, 0, &system_program::id());
assert_capitalization_diff(
&bank,
|| bank.store_account_and_update_capitalization(&pubkey, &account),
|old, new| {
assert_eq!(old + 100, new);
true
},
);
assert_eq!(account, bank.get_account(&pubkey).unwrap());
}
#[test]
fn test_store_account_and_update_capitalization_decreased() {
let old_lamports = 400;
let (genesis_config, mint_keypair) = create_genesis_config(old_lamports);
let bank = Bank::new_for_tests(&genesis_config);
let pubkey = mint_keypair.pubkey();
let new_lamports = 100;
let account = AccountSharedData::new(new_lamports, 0, &system_program::id());
assert_capitalization_diff(
&bank,
|| bank.store_account_and_update_capitalization(&pubkey, &account),
|old, new| {
assert_eq!(old - 300, new);
true
},
);
assert_eq!(account, bank.get_account(&pubkey).unwrap());
}
#[test]
fn test_store_account_and_update_capitalization_unchanged() {
let lamports = 400;
let (genesis_config, mint_keypair) = create_genesis_config(lamports);
let bank = Bank::new_for_tests(&genesis_config);
let pubkey = mint_keypair.pubkey();
let account = AccountSharedData::new(lamports, 1, &system_program::id());
assert_capitalization_diff(
&bank,
|| bank.store_account_and_update_capitalization(&pubkey, &account),
|old, new| {
assert_eq!(old, new);
true
},
);
assert_eq!(account, bank.get_account(&pubkey).unwrap());
}
#[test]
#[ignore]
fn test_rent_distribution() {
solana_logger::setup();
let bootstrap_validator_pubkey = solana_sdk::pubkey::new_rand();
let bootstrap_validator_stake_lamports = 30;
let mut genesis_config = create_genesis_config_with_leader(
10,
&bootstrap_validator_pubkey,
bootstrap_validator_stake_lamports,
)
.genesis_config;
// While we are preventing new accounts left in a rent-paying state, not quite ready to rip
// out all the rent assessment tests. Just deactivate the feature for now.
genesis_config
.accounts
.remove(&feature_set::require_rent_exempt_accounts::id())
.unwrap();
genesis_config.epoch_schedule = EpochSchedule::custom(
MINIMUM_SLOTS_PER_EPOCH,
genesis_config.epoch_schedule.leader_schedule_slot_offset,
false,
);
genesis_config.rent = rent_with_exemption_threshold(2.0);
let rent = Rent::free();
let validator_1_pubkey = solana_sdk::pubkey::new_rand();
let validator_1_stake_lamports = 20;
let validator_1_staking_keypair = Keypair::new();
let validator_1_voting_keypair = Keypair::new();
let validator_1_vote_account = vote_state::create_account(
&validator_1_voting_keypair.pubkey(),
&validator_1_pubkey,
0,
validator_1_stake_lamports,
);
let validator_1_stake_account = stake_state::create_account(
&validator_1_staking_keypair.pubkey(),
&validator_1_voting_keypair.pubkey(),
&validator_1_vote_account,
&rent,
validator_1_stake_lamports,
);
genesis_config.accounts.insert(
validator_1_pubkey,
Account::new(42, 0, &system_program::id()),
);
genesis_config.accounts.insert(
validator_1_staking_keypair.pubkey(),
Account::from(validator_1_stake_account),
);
genesis_config.accounts.insert(
validator_1_voting_keypair.pubkey(),
Account::from(validator_1_vote_account),
);
let validator_2_pubkey = solana_sdk::pubkey::new_rand();
let validator_2_stake_lamports = 20;
let validator_2_staking_keypair = Keypair::new();
let validator_2_voting_keypair = Keypair::new();
let validator_2_vote_account = vote_state::create_account(
&validator_2_voting_keypair.pubkey(),
&validator_2_pubkey,
0,
validator_2_stake_lamports,
);
let validator_2_stake_account = stake_state::create_account(
&validator_2_staking_keypair.pubkey(),
&validator_2_voting_keypair.pubkey(),
&validator_2_vote_account,
&rent,
validator_2_stake_lamports,
);
genesis_config.accounts.insert(
validator_2_pubkey,
Account::new(42, 0, &system_program::id()),
);
genesis_config.accounts.insert(
validator_2_staking_keypair.pubkey(),
Account::from(validator_2_stake_account),
);
genesis_config.accounts.insert(
validator_2_voting_keypair.pubkey(),
Account::from(validator_2_vote_account),
);
let validator_3_pubkey = solana_sdk::pubkey::new_rand();
let validator_3_stake_lamports = 30;
let validator_3_staking_keypair = Keypair::new();
let validator_3_voting_keypair = Keypair::new();
let validator_3_vote_account = vote_state::create_account(
&validator_3_voting_keypair.pubkey(),
&validator_3_pubkey,
0,
validator_3_stake_lamports,
);
let validator_3_stake_account = stake_state::create_account(
&validator_3_staking_keypair.pubkey(),
&validator_3_voting_keypair.pubkey(),
&validator_3_vote_account,
&rent,
validator_3_stake_lamports,
);
genesis_config.accounts.insert(
validator_3_pubkey,
Account::new(42, 0, &system_program::id()),
);
genesis_config.accounts.insert(
validator_3_staking_keypair.pubkey(),
Account::from(validator_3_stake_account),
);
genesis_config.accounts.insert(
validator_3_voting_keypair.pubkey(),
Account::from(validator_3_vote_account),
);
genesis_config.rent = rent_with_exemption_threshold(10.0);
let mut bank = Bank::new_for_tests(&genesis_config);
// Enable rent collection
bank.rent_collector.epoch = 5;
bank.rent_collector.slots_per_year = 192.0;
let payer = Keypair::new();
let payer_account = AccountSharedData::new(400, 0, &system_program::id());
bank.store_account_and_update_capitalization(&payer.pubkey(), &payer_account);
let payee = Keypair::new();
let payee_account = AccountSharedData::new(70, 1, &system_program::id());
bank.store_account_and_update_capitalization(&payee.pubkey(), &payee_account);
let bootstrap_validator_initial_balance = bank.get_balance(&bootstrap_validator_pubkey);
let tx = system_transaction::transfer(&payer, &payee.pubkey(), 180, genesis_config.hash());
let result = bank.process_transaction(&tx);
assert_eq!(result, Ok(()));
let mut total_rent_deducted = 0;
// 400 - 128(Rent) - 180(Transfer)
assert_eq!(bank.get_balance(&payer.pubkey()), 92);
total_rent_deducted += 128;
// 70 - 70(Rent) + 180(Transfer) - 21(Rent)
assert_eq!(bank.get_balance(&payee.pubkey()), 159);
total_rent_deducted += 70 + 21;
let previous_capitalization = bank.capitalization.load(Relaxed);
bank.freeze();
assert_eq!(bank.collected_rent.load(Relaxed), total_rent_deducted);
let burned_portion =
total_rent_deducted * u64::from(bank.rent_collector.rent.burn_percent) / 100;
let rent_to_be_distributed = total_rent_deducted - burned_portion;
let bootstrap_validator_portion =
((bootstrap_validator_stake_lamports * rent_to_be_distributed) as f64 / 100.0) as u64 + 1; // Leftover lamport
assert_eq!(
bank.get_balance(&bootstrap_validator_pubkey),
bootstrap_validator_portion + bootstrap_validator_initial_balance
);
// Since, validator 1 and validator 2 has equal smallest stake, it comes down to comparison
// between their pubkey.
let tweak_1 = u64::from(validator_1_pubkey > validator_2_pubkey);
let validator_1_portion =
((validator_1_stake_lamports * rent_to_be_distributed) as f64 / 100.0) as u64 + tweak_1;
assert_eq!(
bank.get_balance(&validator_1_pubkey),
validator_1_portion + 42 - tweak_1,
);
// Since, validator 1 and validator 2 has equal smallest stake, it comes down to comparison
// between their pubkey.
let tweak_2 = u64::from(validator_2_pubkey > validator_1_pubkey);
let validator_2_portion =
((validator_2_stake_lamports * rent_to_be_distributed) as f64 / 100.0) as u64 + tweak_2;
assert_eq!(
bank.get_balance(&validator_2_pubkey),
validator_2_portion + 42 - tweak_2,
);
let validator_3_portion =
((validator_3_stake_lamports * rent_to_be_distributed) as f64 / 100.0) as u64 + 1;
assert_eq!(
bank.get_balance(&validator_3_pubkey),
validator_3_portion + 42
);
let current_capitalization = bank.capitalization.load(Relaxed);
// only slot history is newly created
let sysvar_and_builtin_program_delta =
min_rent_exempt_balance_for_sysvars(&bank, &[sysvar::slot_history::id()]);
assert_eq!(
previous_capitalization - (current_capitalization - sysvar_and_builtin_program_delta),
burned_portion
);
assert!(bank.calculate_and_verify_capitalization(true));
assert_eq!(
rent_to_be_distributed,
bank.rewards
.read()
.unwrap()
.iter()
.map(|(address, reward)| {
if reward.lamports > 0 {
assert_eq!(reward.reward_type, RewardType::Rent);
if *address == validator_2_pubkey {
assert_eq!(reward.post_balance, validator_2_portion + 42 - tweak_2);
} else if *address == validator_3_pubkey {
assert_eq!(reward.post_balance, validator_3_portion + 42);
}
reward.lamports as u64
} else {
0
}
})
.sum::<u64>()
);
}
#[test]
fn test_distribute_rent_to_validators_overflow() {
solana_logger::setup();
// These values are taken from the real cluster (testnet)
const RENT_TO_BE_DISTRIBUTED: u64 = 120_525;
const VALIDATOR_STAKE: u64 = 374_999_998_287_840;
let validator_pubkey = solana_sdk::pubkey::new_rand();
let mut genesis_config =
create_genesis_config_with_leader(10, &validator_pubkey, VALIDATOR_STAKE).genesis_config;
let bank = Bank::new_for_tests(&genesis_config);
let old_validator_lamports = bank.get_balance(&validator_pubkey);
bank.distribute_rent_to_validators(&bank.vote_accounts(), RENT_TO_BE_DISTRIBUTED);
let new_validator_lamports = bank.get_balance(&validator_pubkey);
assert_eq!(
new_validator_lamports,
old_validator_lamports + RENT_TO_BE_DISTRIBUTED
);
genesis_config
.accounts
.remove(&feature_set::no_overflow_rent_distribution::id())
.unwrap();
let bank = std::panic::AssertUnwindSafe(Bank::new_for_tests(&genesis_config));
let old_validator_lamports = bank.get_balance(&validator_pubkey);
let new_validator_lamports = std::panic::catch_unwind(|| {
bank.distribute_rent_to_validators(&bank.vote_accounts(), RENT_TO_BE_DISTRIBUTED);
bank.get_balance(&validator_pubkey)
});
if let Ok(new_validator_lamports) = new_validator_lamports {
info!("asserting overflowing incorrect rent distribution");
assert_ne!(
new_validator_lamports,
old_validator_lamports + RENT_TO_BE_DISTRIBUTED
);
} else {
info!("NOT-asserting overflowing incorrect rent distribution");
}
}
#[test]
fn test_distribute_rent_to_validators_rent_paying() {
solana_logger::setup();
const RENT_PER_VALIDATOR: u64 = 55;
const TOTAL_RENT: u64 = RENT_PER_VALIDATOR * 4;
let empty_validator = ValidatorVoteKeypairs::new_rand();
let rent_paying_validator = ValidatorVoteKeypairs::new_rand();
let becomes_rent_exempt_validator = ValidatorVoteKeypairs::new_rand();
let rent_exempt_validator = ValidatorVoteKeypairs::new_rand();
let keypairs = vec![
&empty_validator,
&rent_paying_validator,
&becomes_rent_exempt_validator,
&rent_exempt_validator,
];
let genesis_config_info = create_genesis_config_with_vote_accounts(
sol_to_lamports(1000.),
&keypairs,
vec![sol_to_lamports(1000.); 4],
);
let mut genesis_config = genesis_config_info.genesis_config;
genesis_config.rent = Rent::default(); // Ensure rent is non-zero, as genesis_utils sets Rent::free by default
for deactivate_feature in [false, true] {
if deactivate_feature {
genesis_config
.accounts
.remove(&feature_set::prevent_rent_paying_rent_recipients::id())
.unwrap();
}
let bank = Bank::new_for_tests(&genesis_config);
let rent = bank.rent_collector().rent;
let rent_exempt_minimum = rent.minimum_balance(0);
// Make one validator have an empty identity account
let mut empty_validator_account = bank
.get_account_with_fixed_root(&empty_validator.node_keypair.pubkey())
.unwrap();
empty_validator_account.set_lamports(0);
bank.store_account(
&empty_validator.node_keypair.pubkey(),
&empty_validator_account,
);
// Make one validator almost rent-exempt, less RENT_PER_VALIDATOR
let mut becomes_rent_exempt_validator_account = bank
.get_account_with_fixed_root(&becomes_rent_exempt_validator.node_keypair.pubkey())
.unwrap();
becomes_rent_exempt_validator_account
.set_lamports(rent_exempt_minimum - RENT_PER_VALIDATOR);
bank.store_account(
&becomes_rent_exempt_validator.node_keypair.pubkey(),
&becomes_rent_exempt_validator_account,
);
// Make one validator rent-exempt
let mut rent_exempt_validator_account = bank
.get_account_with_fixed_root(&rent_exempt_validator.node_keypair.pubkey())
.unwrap();
rent_exempt_validator_account.set_lamports(rent_exempt_minimum);
bank.store_account(
&rent_exempt_validator.node_keypair.pubkey(),
&rent_exempt_validator_account,
);
let get_rent_state = |bank: &Bank, address: &Pubkey| -> RentState {
let account = bank
.get_account_with_fixed_root(address)
.unwrap_or_default();
RentState::from_account(&account, &rent)
};
// Assert starting RentStates
assert_eq!(
get_rent_state(&bank, &empty_validator.node_keypair.pubkey()),
RentState::Uninitialized
);
assert_eq!(
get_rent_state(&bank, &rent_paying_validator.node_keypair.pubkey()),
RentState::RentPaying {
lamports: 42,
data_size: 0,
}
);
assert_eq!(
get_rent_state(&bank, &becomes_rent_exempt_validator.node_keypair.pubkey()),
RentState::RentPaying {
lamports: rent_exempt_minimum - RENT_PER_VALIDATOR,
data_size: 0,
}
);
assert_eq!(
get_rent_state(&bank, &rent_exempt_validator.node_keypair.pubkey()),
RentState::RentExempt
);
let old_empty_validator_lamports = bank.get_balance(&empty_validator.node_keypair.pubkey());
let old_rent_paying_validator_lamports =
bank.get_balance(&rent_paying_validator.node_keypair.pubkey());
let old_becomes_rent_exempt_validator_lamports =
bank.get_balance(&becomes_rent_exempt_validator.node_keypair.pubkey());
let old_rent_exempt_validator_lamports =
bank.get_balance(&rent_exempt_validator.node_keypair.pubkey());
bank.distribute_rent_to_validators(&bank.vote_accounts(), TOTAL_RENT);
let new_empty_validator_lamports = bank.get_balance(&empty_validator.node_keypair.pubkey());
let new_rent_paying_validator_lamports =
bank.get_balance(&rent_paying_validator.node_keypair.pubkey());
let new_becomes_rent_exempt_validator_lamports =
bank.get_balance(&becomes_rent_exempt_validator.node_keypair.pubkey());
let new_rent_exempt_validator_lamports =
bank.get_balance(&rent_exempt_validator.node_keypair.pubkey());
// Assert ending balances; rent should be withheld if test is active and ending RentState
// is RentPaying, ie. empty_validator and rent_paying_validator
assert_eq!(
if deactivate_feature {
old_empty_validator_lamports + RENT_PER_VALIDATOR
} else {
old_empty_validator_lamports
},
new_empty_validator_lamports
);
assert_eq!(
if deactivate_feature {
old_rent_paying_validator_lamports + RENT_PER_VALIDATOR
} else {
old_rent_paying_validator_lamports
},
new_rent_paying_validator_lamports
);
assert_eq!(
old_becomes_rent_exempt_validator_lamports + RENT_PER_VALIDATOR,
new_becomes_rent_exempt_validator_lamports
);
assert_eq!(
old_rent_exempt_validator_lamports + RENT_PER_VALIDATOR,
new_rent_exempt_validator_lamports
);
// Assert ending RentStates
assert_eq!(
if deactivate_feature {
RentState::RentPaying {
lamports: RENT_PER_VALIDATOR,
data_size: 0,
}
} else {
RentState::Uninitialized
},
get_rent_state(&bank, &empty_validator.node_keypair.pubkey()),
);
assert_eq!(
if deactivate_feature {
RentState::RentPaying {
lamports: old_rent_paying_validator_lamports + RENT_PER_VALIDATOR,
data_size: 0,
}
} else {
RentState::RentPaying {
lamports: old_rent_paying_validator_lamports,
data_size: 0,
}
},
get_rent_state(&bank, &rent_paying_validator.node_keypair.pubkey()),
);
assert_eq!(
RentState::RentExempt,
get_rent_state(&bank, &becomes_rent_exempt_validator.node_keypair.pubkey()),
);
assert_eq!(
RentState::RentExempt,
get_rent_state(&bank, &rent_exempt_validator.node_keypair.pubkey()),
);
}
}
#[test]
fn test_rent_exempt_executable_account() {
let (mut genesis_config, mint_keypair) = create_genesis_config(100_000);
genesis_config.rent = rent_with_exemption_threshold(1000.0);
let root_bank = Arc::new(Bank::new_for_tests(&genesis_config));
let bank = create_child_bank_for_rent_test(&root_bank, &genesis_config);
let account_pubkey = solana_sdk::pubkey::new_rand();
let account_balance = 1;
let mut account = AccountSharedData::new(account_balance, 0, &solana_sdk::pubkey::new_rand());
account.set_executable(true);
bank.store_account(&account_pubkey, &account);
let transfer_lamports = 1;
let tx = system_transaction::transfer(
&mint_keypair,
&account_pubkey,
transfer_lamports,
genesis_config.hash(),
);
assert_eq!(
bank.process_transaction(&tx),
Err(TransactionError::InvalidWritableAccount)
);
assert_eq!(bank.get_balance(&account_pubkey), account_balance);
}
#[test]
#[ignore]
#[allow(clippy::cognitive_complexity)]
fn test_rent_complex() {
solana_logger::setup();
let mock_program_id = Pubkey::from([2u8; 32]);
#[derive(Serialize, Deserialize)]
enum MockInstruction {
Deduction,
}
declare_process_instruction!(process_instruction, 1, |invoke_context| {
let transaction_context = &invoke_context.transaction_context;
let instruction_context = transaction_context.get_current_instruction_context()?;
let instruction_data = instruction_context.get_instruction_data();
if let Ok(instruction) = bincode::deserialize(instruction_data) {
match instruction {
MockInstruction::Deduction => {
instruction_context
.try_borrow_instruction_account(transaction_context, 1)?
.checked_add_lamports(1)?;
instruction_context
.try_borrow_instruction_account(transaction_context, 2)?
.checked_sub_lamports(1)?;
Ok(())
}
}
} else {
Err(InstructionError::InvalidInstructionData)
}
});
let (mut genesis_config, _mint_keypair) = create_genesis_config(10);
let mut keypairs: Vec<Keypair> = Vec::with_capacity(14);
for _i in 0..14 {
keypairs.push(Keypair::new());
}
genesis_config.rent = rent_with_exemption_threshold(1000.0);
let root_bank = Bank::new_for_tests(&genesis_config);
// until we completely transition to the eager rent collection,
// we must ensure lazy rent collection doens't get broken!
root_bank.restore_old_behavior_for_fragile_tests();
let root_bank = Arc::new(root_bank);
let mut bank = create_child_bank_for_rent_test(&root_bank, &genesis_config);
bank.add_mockup_builtin(mock_program_id, process_instruction);
assert_eq!(bank.last_blockhash(), genesis_config.hash());
let slots_elapsed: u64 = (0..=bank.epoch)
.map(|epoch| {
bank.rent_collector
.epoch_schedule
.get_slots_in_epoch(epoch + 1)
})
.sum();
let generic_rent_due_for_system_account = bank
.rent_collector
.rent
.due(
bank.get_minimum_balance_for_rent_exemption(0) - 1,
0,
slots_elapsed as f64 / bank.rent_collector.slots_per_year,
)
.lamports();
store_accounts_for_rent_test(
&bank,
&mut keypairs,
mock_program_id,
generic_rent_due_for_system_account,
);
let magic_rent_number = 131; // yuck, derive this value programmatically one day
let t1 = system_transaction::transfer(
&keypairs[0],
&keypairs[1].pubkey(),
1,
genesis_config.hash(),
);
let t2 = system_transaction::transfer(
&keypairs[2],
&keypairs[3].pubkey(),
1,
genesis_config.hash(),
);
let t3 = system_transaction::transfer(
&keypairs[4],
&keypairs[5].pubkey(),
1,
genesis_config.hash(),
);
let t4 = system_transaction::transfer(
&keypairs[6],
&keypairs[7].pubkey(),
generic_rent_due_for_system_account + 1,
genesis_config.hash(),
);
let t5 = system_transaction::transfer(
&keypairs[8],
&keypairs[9].pubkey(),
929,
genesis_config.hash(),
);
let account_metas = vec![
AccountMeta::new(keypairs[10].pubkey(), true),
AccountMeta::new(keypairs[11].pubkey(), true),
AccountMeta::new(keypairs[12].pubkey(), true),
AccountMeta::new_readonly(keypairs[13].pubkey(), false),
];
let deduct_instruction =
Instruction::new_with_bincode(mock_program_id, &MockInstruction::Deduction, account_metas);
let t6 = Transaction::new_signed_with_payer(
&[deduct_instruction],
Some(&keypairs[10].pubkey()),
&[&keypairs[10], &keypairs[11], &keypairs[12]],
genesis_config.hash(),
);
let txs = vec![t6, t5, t1, t2, t3, t4];
let res = bank.process_transactions(txs.iter());
assert_eq!(res.len(), 6);
assert_eq!(res[0], Ok(()));
assert_eq!(res[1], Ok(()));
assert_eq!(res[2], Ok(()));
assert_eq!(res[3], Ok(()));
assert_eq!(res[4], Err(TransactionError::AccountNotFound));
assert_eq!(res[5], Ok(()));
bank.freeze();
let mut rent_collected = 0;
// 48992 - generic_rent_due_for_system_account(Rent) - 1(transfer)
assert_eq!(bank.get_balance(&keypairs[0].pubkey()), 1);
rent_collected += generic_rent_due_for_system_account;
// 48992 - generic_rent_due_for_system_account(Rent) + 1(transfer)
assert_eq!(bank.get_balance(&keypairs[1].pubkey()), 3);
rent_collected += generic_rent_due_for_system_account;
// 48992 - generic_rent_due_for_system_account(Rent) - 1(transfer)
assert_eq!(bank.get_balance(&keypairs[2].pubkey()), 1);
rent_collected += generic_rent_due_for_system_account;
// 48992 - generic_rent_due_for_system_account(Rent) + 1(transfer)
assert_eq!(bank.get_balance(&keypairs[3].pubkey()), 3);
rent_collected += generic_rent_due_for_system_account;
// No rent deducted
assert_eq!(bank.get_balance(&keypairs[4].pubkey()), 10);
assert_eq!(bank.get_balance(&keypairs[5].pubkey()), 10);
// 98004 - generic_rent_due_for_system_account(Rent) - 48991(transfer)
assert_eq!(bank.get_balance(&keypairs[6].pubkey()), 23);
rent_collected += generic_rent_due_for_system_account;
// 0 + 48990(transfer) - magic_rent_number(Rent)
assert_eq!(
bank.get_balance(&keypairs[7].pubkey()),
generic_rent_due_for_system_account + 1 - magic_rent_number
);
// Epoch should be updated
// Rent deducted on store side
let account8 = bank.get_account(&keypairs[7].pubkey()).unwrap();
// Epoch should be set correctly.
assert_eq!(account8.rent_epoch(), bank.epoch + 1);
rent_collected += magic_rent_number;
// 49921 - generic_rent_due_for_system_account(Rent) - 929(Transfer)
assert_eq!(bank.get_balance(&keypairs[8].pubkey()), 2);
rent_collected += generic_rent_due_for_system_account;
let account10 = bank.get_account(&keypairs[9].pubkey()).unwrap();
// Account was overwritten at load time, since it didn't have sufficient balance to pay rent
// Then, at store time we deducted `magic_rent_number` rent for the current epoch, once it has balance
assert_eq!(account10.rent_epoch(), bank.epoch + 1);
// account data is blank now
assert_eq!(account10.data().len(), 0);
// 10 - 10(Rent) + 929(Transfer) - magic_rent_number(Rent)
assert_eq!(account10.lamports(), 929 - magic_rent_number);
rent_collected += magic_rent_number + 10;
// 48993 - generic_rent_due_for_system_account(Rent)
assert_eq!(bank.get_balance(&keypairs[10].pubkey()), 3);
rent_collected += generic_rent_due_for_system_account;
// 48993 - generic_rent_due_for_system_account(Rent) + 1(Addition by program)
assert_eq!(bank.get_balance(&keypairs[11].pubkey()), 4);
rent_collected += generic_rent_due_for_system_account;
// 48993 - generic_rent_due_for_system_account(Rent) - 1(Deduction by program)
assert_eq!(bank.get_balance(&keypairs[12].pubkey()), 2);
rent_collected += generic_rent_due_for_system_account;
// No rent for read-only account
assert_eq!(bank.get_balance(&keypairs[13].pubkey()), 14);
// Bank's collected rent should be sum of rent collected from all accounts
assert_eq!(bank.collected_rent.load(Relaxed), rent_collected);
}
fn test_rent_collection_partitions(bank: &Bank) -> Vec<Partition> {
let partitions = bank.rent_collection_partitions();
let slot = bank.slot();
if slot.saturating_sub(1) == bank.parent_slot() {
let partition = accounts_partition::variable_cycle_partition_from_previous_slot(
bank.epoch_schedule(),
bank.slot(),
);
assert_eq!(
partitions.last().unwrap(),
&partition,
"slot: {}, slots per epoch: {}, partitions: {:?}",
bank.slot(),
bank.epoch_schedule().slots_per_epoch,
partitions
);
}
partitions
}
#[test]
fn test_rent_eager_across_epoch_without_gap() {
let mut bank = create_simple_test_arc_bank(1);
assert_eq!(bank.rent_collection_partitions(), vec![(0, 0, 32)]);
bank = Arc::new(new_from_parent(&bank));
assert_eq!(bank.rent_collection_partitions(), vec![(0, 1, 32)]);
for _ in 2..32 {
bank = Arc::new(new_from_parent(&bank));
}
assert_eq!(bank.rent_collection_partitions(), vec![(30, 31, 32)]);
bank = Arc::new(new_from_parent(&bank));
assert_eq!(bank.rent_collection_partitions(), vec![(0, 0, 64)]);
}
#[test]
fn test_rent_eager_across_epoch_without_gap_mnb() {
solana_logger::setup();
let (mut genesis_config, _mint_keypair) = create_genesis_config(1);
genesis_config.cluster_type = ClusterType::MainnetBeta;
let mut bank = Arc::new(Bank::new_for_tests(&genesis_config));
assert_eq!(test_rent_collection_partitions(&bank), vec![(0, 0, 32)]);
bank = Arc::new(new_from_parent(&bank));
assert_eq!(test_rent_collection_partitions(&bank), vec![(0, 1, 32)]);
for _ in 2..32 {
bank = Arc::new(new_from_parent(&bank));
}
assert_eq!(test_rent_collection_partitions(&bank), vec![(30, 31, 32)]);
bank = Arc::new(new_from_parent(&bank));
assert_eq!(test_rent_collection_partitions(&bank), vec![(0, 0, 64)]);
}
#[test]
fn test_rent_eager_across_epoch_with_full_gap() {
let (mut genesis_config, _mint_keypair) = create_genesis_config(1);
activate_all_features(&mut genesis_config);
let mut bank = Arc::new(Bank::new_for_tests(&genesis_config));
assert_eq!(bank.rent_collection_partitions(), vec![(0, 0, 32)]);
bank = Arc::new(new_from_parent(&bank));
assert_eq!(bank.rent_collection_partitions(), vec![(0, 1, 32)]);
for _ in 2..15 {
bank = Arc::new(new_from_parent(&bank));
}
assert_eq!(bank.rent_collection_partitions(), vec![(13, 14, 32)]);
bank = Arc::new(Bank::new_from_parent(&bank, &Pubkey::default(), 49));
assert_eq!(
bank.rent_collection_partitions(),
vec![(14, 31, 32), (0, 0, 64), (0, 17, 64)]
);
bank = Arc::new(new_from_parent(&bank));
assert_eq!(bank.rent_collection_partitions(), vec![(17, 18, 64)]);
}
#[test]
fn test_rent_eager_across_epoch_with_half_gap() {
let (mut genesis_config, _mint_keypair) = create_genesis_config(1);
activate_all_features(&mut genesis_config);
let mut bank = Arc::new(Bank::new_for_tests(&genesis_config));
assert_eq!(bank.rent_collection_partitions(), vec![(0, 0, 32)]);
bank = Arc::new(new_from_parent(&bank));
assert_eq!(bank.rent_collection_partitions(), vec![(0, 1, 32)]);
for _ in 2..15 {
bank = Arc::new(new_from_parent(&bank));
}
assert_eq!(bank.rent_collection_partitions(), vec![(13, 14, 32)]);
bank = Arc::new(Bank::new_from_parent(&bank, &Pubkey::default(), 32));
assert_eq!(
bank.rent_collection_partitions(),
vec![(14, 31, 32), (0, 0, 64)]
);
bank = Arc::new(new_from_parent(&bank));
assert_eq!(bank.rent_collection_partitions(), vec![(0, 1, 64)]);
}
#[test]
#[allow(clippy::cognitive_complexity)]
fn test_rent_eager_across_epoch_without_gap_under_multi_epoch_cycle() {
let leader_pubkey = solana_sdk::pubkey::new_rand();
let leader_lamports = 3;
let mut genesis_config =
create_genesis_config_with_leader(5, &leader_pubkey, leader_lamports).genesis_config;
genesis_config.cluster_type = ClusterType::MainnetBeta;
const SLOTS_PER_EPOCH: u64 = MINIMUM_SLOTS_PER_EPOCH;
const LEADER_SCHEDULE_SLOT_OFFSET: u64 = SLOTS_PER_EPOCH * 3 - 3;
genesis_config.epoch_schedule =
EpochSchedule::custom(SLOTS_PER_EPOCH, LEADER_SCHEDULE_SLOT_OFFSET, false);
let mut bank = Arc::new(Bank::new_for_tests(&genesis_config));
assert_eq!(DEFAULT_SLOTS_PER_EPOCH, 432_000);
assert_eq!(bank.get_slots_in_epoch(bank.epoch()), 32);
assert_eq!(bank.get_epoch_and_slot_index(bank.slot()), (0, 0));
assert_eq!(bank.rent_collection_partitions(), vec![(0, 0, 432_000)]);
bank = Arc::new(new_from_parent(&bank));
assert_eq!(bank.get_slots_in_epoch(bank.epoch()), 32);
assert_eq!(bank.get_epoch_and_slot_index(bank.slot()), (0, 1));
assert_eq!(bank.rent_collection_partitions(), vec![(0, 1, 432_000)]);
for _ in 2..32 {
bank = Arc::new(new_from_parent(&bank));
}
assert_eq!(bank.get_slots_in_epoch(bank.epoch()), 32);
assert_eq!(bank.get_epoch_and_slot_index(bank.slot()), (0, 31));
assert_eq!(bank.rent_collection_partitions(), vec![(30, 31, 432_000)]);
bank = Arc::new(new_from_parent(&bank));
assert_eq!(bank.get_slots_in_epoch(bank.epoch()), 32);
assert_eq!(bank.get_epoch_and_slot_index(bank.slot()), (1, 0));
assert_eq!(bank.rent_collection_partitions(), vec![(31, 32, 432_000)]);
bank = Arc::new(new_from_parent(&bank));
assert_eq!(bank.get_slots_in_epoch(bank.epoch()), 32);
assert_eq!(bank.get_epoch_and_slot_index(bank.slot()), (1, 1));
assert_eq!(bank.rent_collection_partitions(), vec![(32, 33, 432_000)]);
bank = Arc::new(Bank::new_from_parent(&bank, &Pubkey::default(), 1000));
bank = Arc::new(Bank::new_from_parent(&bank, &Pubkey::default(), 1001));
assert_eq!(bank.get_slots_in_epoch(bank.epoch()), 32);
assert_eq!(bank.get_epoch_and_slot_index(bank.slot()), (31, 9));
assert_eq!(
bank.rent_collection_partitions(),
vec![(1000, 1001, 432_000)]
);
bank = Arc::new(Bank::new_from_parent(&bank, &Pubkey::default(), 431_998));
bank = Arc::new(Bank::new_from_parent(&bank, &Pubkey::default(), 431_999));
assert_eq!(bank.get_slots_in_epoch(bank.epoch()), 32);
assert_eq!(bank.get_epoch_and_slot_index(bank.slot()), (13499, 31));
assert_eq!(
bank.rent_collection_partitions(),
vec![(431_998, 431_999, 432_000)]
);
bank = Arc::new(new_from_parent(&bank));
assert_eq!(bank.get_slots_in_epoch(bank.epoch()), 32);
assert_eq!(bank.get_epoch_and_slot_index(bank.slot()), (13500, 0));
assert_eq!(bank.rent_collection_partitions(), vec![(0, 0, 432_000)]);
bank = Arc::new(new_from_parent(&bank));
assert_eq!(bank.get_slots_in_epoch(bank.epoch()), 32);
assert_eq!(bank.get_epoch_and_slot_index(bank.slot()), (13500, 1));
assert_eq!(bank.rent_collection_partitions(), vec![(0, 1, 432_000)]);
}
#[test]
fn test_rent_eager_across_epoch_with_gap_under_multi_epoch_cycle() {
let leader_pubkey = solana_sdk::pubkey::new_rand();
let leader_lamports = 3;
let mut genesis_config =
create_genesis_config_with_leader(5, &leader_pubkey, leader_lamports).genesis_config;
genesis_config.cluster_type = ClusterType::MainnetBeta;
const SLOTS_PER_EPOCH: u64 = MINIMUM_SLOTS_PER_EPOCH;
const LEADER_SCHEDULE_SLOT_OFFSET: u64 = SLOTS_PER_EPOCH * 3 - 3;
genesis_config.epoch_schedule =
EpochSchedule::custom(SLOTS_PER_EPOCH, LEADER_SCHEDULE_SLOT_OFFSET, false);
let mut bank = Arc::new(Bank::new_for_tests(&genesis_config));
assert_eq!(DEFAULT_SLOTS_PER_EPOCH, 432_000);
assert_eq!(bank.get_slots_in_epoch(bank.epoch()), 32);
assert_eq!(bank.get_epoch_and_slot_index(bank.slot()), (0, 0));
assert_eq!(bank.rent_collection_partitions(), vec![(0, 0, 432_000)]);
bank = Arc::new(new_from_parent(&bank));
assert_eq!(bank.get_slots_in_epoch(bank.epoch()), 32);
assert_eq!(bank.get_epoch_and_slot_index(bank.slot()), (0, 1));
assert_eq!(bank.rent_collection_partitions(), vec![(0, 1, 432_000)]);
for _ in 2..19 {
bank = Arc::new(new_from_parent(&bank));
}
assert_eq!(bank.get_slots_in_epoch(bank.epoch()), 32);
assert_eq!(bank.get_epoch_and_slot_index(bank.slot()), (0, 18));
assert_eq!(bank.rent_collection_partitions(), vec![(17, 18, 432_000)]);
bank = Arc::new(Bank::new_from_parent(&bank, &Pubkey::default(), 44));
assert_eq!(bank.get_slots_in_epoch(bank.epoch()), 32);
assert_eq!(bank.get_epoch_and_slot_index(bank.slot()), (1, 12));
assert_eq!(
bank.rent_collection_partitions(),
vec![(18, 31, 432_000), (31, 31, 432_000), (31, 44, 432_000)]
);
bank = Arc::new(new_from_parent(&bank));
assert_eq!(bank.get_slots_in_epoch(bank.epoch()), 32);
assert_eq!(bank.get_epoch_and_slot_index(bank.slot()), (1, 13));
assert_eq!(bank.rent_collection_partitions(), vec![(44, 45, 432_000)]);
bank = Arc::new(Bank::new_from_parent(&bank, &Pubkey::default(), 431_993));
bank = Arc::new(Bank::new_from_parent(&bank, &Pubkey::default(), 432_011));
assert_eq!(bank.get_slots_in_epoch(bank.epoch()), 32);
assert_eq!(bank.get_epoch_and_slot_index(bank.slot()), (13500, 11));
assert_eq!(
bank.rent_collection_partitions(),
vec![
(431_993, 431_999, 432_000),
(0, 0, 432_000),
(0, 11, 432_000)
]
);
}
#[test]
fn test_rent_eager_with_warmup_epochs_under_multi_epoch_cycle() {
let leader_pubkey = solana_sdk::pubkey::new_rand();
let leader_lamports = 3;
let mut genesis_config =
create_genesis_config_with_leader(5, &leader_pubkey, leader_lamports).genesis_config;
genesis_config.cluster_type = ClusterType::MainnetBeta;
const SLOTS_PER_EPOCH: u64 = MINIMUM_SLOTS_PER_EPOCH * 8;
const LEADER_SCHEDULE_SLOT_OFFSET: u64 = SLOTS_PER_EPOCH * 3 - 3;
genesis_config.epoch_schedule =
EpochSchedule::custom(SLOTS_PER_EPOCH, LEADER_SCHEDULE_SLOT_OFFSET, true);
let mut bank = Arc::new(Bank::new_for_tests(&genesis_config));
assert_eq!(DEFAULT_SLOTS_PER_EPOCH, 432_000);
assert_eq!(bank.get_slots_in_epoch(bank.epoch()), 32);
assert_eq!(bank.first_normal_epoch(), 3);
assert_eq!(bank.get_epoch_and_slot_index(bank.slot()), (0, 0));
assert_eq!(bank.rent_collection_partitions(), vec![(0, 0, 32)]);
bank = Arc::new(Bank::new_from_parent(&bank, &Pubkey::default(), 222));
bank = Arc::new(new_from_parent(&bank));
assert_eq!(bank.get_slots_in_epoch(bank.epoch()), 128);
assert_eq!(bank.get_epoch_and_slot_index(bank.slot()), (2, 127));
assert_eq!(bank.rent_collection_partitions(), vec![(126, 127, 128)]);
bank = Arc::new(new_from_parent(&bank));
assert_eq!(bank.get_slots_in_epoch(bank.epoch()), 256);
assert_eq!(bank.get_epoch_and_slot_index(bank.slot()), (3, 0));
assert_eq!(bank.rent_collection_partitions(), vec![(0, 0, 431_872)]);
assert_eq!(431_872 % bank.get_slots_in_epoch(bank.epoch()), 0);
bank = Arc::new(new_from_parent(&bank));
assert_eq!(bank.get_slots_in_epoch(bank.epoch()), 256);
assert_eq!(bank.get_epoch_and_slot_index(bank.slot()), (3, 1));
assert_eq!(bank.rent_collection_partitions(), vec![(0, 1, 431_872)]);
bank = Arc::new(Bank::new_from_parent(
&bank,
&Pubkey::default(),
431_872 + 223 - 1,
));
bank = Arc::new(new_from_parent(&bank));
assert_eq!(bank.get_slots_in_epoch(bank.epoch()), 256);
assert_eq!(bank.get_epoch_and_slot_index(bank.slot()), (1689, 255));
assert_eq!(
bank.rent_collection_partitions(),
vec![(431_870, 431_871, 431_872)]
);
bank = Arc::new(new_from_parent(&bank));
assert_eq!(bank.get_slots_in_epoch(bank.epoch()), 256);
assert_eq!(bank.get_epoch_and_slot_index(bank.slot()), (1690, 0));
assert_eq!(bank.rent_collection_partitions(), vec![(0, 0, 431_872)]);
}
#[test]
fn test_rent_eager_under_fixed_cycle_for_development() {
solana_logger::setup();
let leader_pubkey = solana_sdk::pubkey::new_rand();
let leader_lamports = 3;
let mut genesis_config =
create_genesis_config_with_leader(5, &leader_pubkey, leader_lamports).genesis_config;
const SLOTS_PER_EPOCH: u64 = MINIMUM_SLOTS_PER_EPOCH * 8;
const LEADER_SCHEDULE_SLOT_OFFSET: u64 = SLOTS_PER_EPOCH * 3 - 3;
genesis_config.epoch_schedule =
EpochSchedule::custom(SLOTS_PER_EPOCH, LEADER_SCHEDULE_SLOT_OFFSET, true);
let mut bank = Arc::new(Bank::new_for_tests(&genesis_config));
assert_eq!(bank.get_slots_in_epoch(bank.epoch()), 32);
assert_eq!(bank.first_normal_epoch(), 3);
assert_eq!(bank.get_epoch_and_slot_index(bank.slot()), (0, 0));
assert_eq!(bank.rent_collection_partitions(), vec![(0, 0, 432_000)]);
bank = Arc::new(Bank::new_from_parent(&bank, &Pubkey::default(), 222));
bank = Arc::new(new_from_parent(&bank));
assert_eq!(bank.get_slots_in_epoch(bank.epoch()), 128);
assert_eq!(bank.get_epoch_and_slot_index(bank.slot()), (2, 127));
assert_eq!(bank.rent_collection_partitions(), vec![(222, 223, 432_000)]);
bank = Arc::new(new_from_parent(&bank));
assert_eq!(bank.get_slots_in_epoch(bank.epoch()), 256);
assert_eq!(bank.get_epoch_and_slot_index(bank.slot()), (3, 0));
assert_eq!(bank.rent_collection_partitions(), vec![(223, 224, 432_000)]);
bank = Arc::new(new_from_parent(&bank));
assert_eq!(bank.get_slots_in_epoch(bank.epoch()), 256);
assert_eq!(bank.get_epoch_and_slot_index(bank.slot()), (3, 1));
assert_eq!(bank.rent_collection_partitions(), vec![(224, 225, 432_000)]);
bank = Arc::new(Bank::new_from_parent(
&bank,
&Pubkey::default(),
432_000 - 2,
));
bank = Arc::new(new_from_parent(&bank));
assert_eq!(
bank.rent_collection_partitions(),
vec![(431_998, 431_999, 432_000)]
);
bank = Arc::new(new_from_parent(&bank));
assert_eq!(bank.rent_collection_partitions(), vec![(0, 0, 432_000)]);
bank = Arc::new(new_from_parent(&bank));
assert_eq!(bank.rent_collection_partitions(), vec![(0, 1, 432_000)]);
bank = Arc::new(Bank::new_from_parent(
&bank,
&Pubkey::default(),
864_000 - 20,
));
bank = Arc::new(Bank::new_from_parent(
&bank,
&Pubkey::default(),
864_000 + 39,
));
assert_eq!(
bank.rent_collection_partitions(),
vec![
(431_980, 431_999, 432_000),
(0, 0, 432_000),
(0, 39, 432_000)
]
);
}
impl Bank {
fn slots_by_pubkey(&self, pubkey: &Pubkey, ancestors: &Ancestors) -> Vec<Slot> {
let (locked_entry, _) = self
.rc
.accounts
.accounts_db
.accounts_index
.get(pubkey, Some(ancestors), None)
.unwrap();
locked_entry
.slot_list()
.iter()
.map(|(slot, _)| *slot)
.collect::<Vec<Slot>>()
}
}
#[test]
fn test_rent_eager_collect_rent_in_partition() {
solana_logger::setup();
let (mut genesis_config, _mint_keypair) = create_genesis_config(1_000_000);
for feature_id in FeatureSet::default().inactive {
if feature_id != solana_sdk::feature_set::set_exempt_rent_epoch_max::id() {
activate_feature(&mut genesis_config, feature_id);
}
}
let zero_lamport_pubkey = solana_sdk::pubkey::new_rand();
let rent_due_pubkey = solana_sdk::pubkey::new_rand();
let rent_exempt_pubkey = solana_sdk::pubkey::new_rand();
let mut bank = Arc::new(Bank::new_for_tests(&genesis_config));
let zero_lamports = 0;
let little_lamports = 1234;
let large_lamports = 123_456_789;
// genesis_config.epoch_schedule.slots_per_epoch == 432_000 and is unsuitable for this test
let some_slot = MINIMUM_SLOTS_PER_EPOCH; // chosen to cause epoch to be +1
let rent_collected = 1; // this is a function of 'some_slot'
bank.store_account(
&zero_lamport_pubkey,
&AccountSharedData::new(zero_lamports, 0, &Pubkey::default()),
);
bank.store_account(
&rent_due_pubkey,
&AccountSharedData::new(little_lamports, 0, &Pubkey::default()),
);
bank.store_account(
&rent_exempt_pubkey,
&AccountSharedData::new(large_lamports, 0, &Pubkey::default()),
);
let genesis_slot = 0;
let ancestors = vec![(some_slot, 0), (0, 1)].into_iter().collect();
let previous_epoch = bank.epoch();
bank = Arc::new(Bank::new_from_parent(&bank, &Pubkey::default(), some_slot));
let current_epoch = bank.epoch();
assert_eq!(previous_epoch + 1, current_epoch);
assert_eq!(bank.collected_rent.load(Relaxed), 0);
assert_eq!(
bank.get_account(&rent_due_pubkey).unwrap().lamports(),
little_lamports
);
assert_eq!(bank.get_account(&rent_due_pubkey).unwrap().rent_epoch(), 0);
assert_eq!(
bank.slots_by_pubkey(&rent_due_pubkey, &ancestors),
vec![genesis_slot]
);
assert_eq!(
bank.slots_by_pubkey(&rent_exempt_pubkey, &ancestors),
vec![genesis_slot]
);
assert_eq!(
bank.slots_by_pubkey(&zero_lamport_pubkey, &ancestors),
vec![genesis_slot]
);
assert_eq!(bank.collected_rent.load(Relaxed), 0);
bank.collect_rent_in_partition((0, 0, 1), &RentMetrics::default()); // all range
assert_eq!(bank.collected_rent.load(Relaxed), rent_collected);
assert_eq!(
bank.get_account(&rent_due_pubkey).unwrap().lamports(),
little_lamports - rent_collected
);
assert_eq!(
bank.get_account(&rent_due_pubkey).unwrap().rent_epoch(),
current_epoch + 1
);
assert_eq!(
bank.get_account(&rent_exempt_pubkey).unwrap().lamports(),
large_lamports
);
// Once preserve_rent_epoch_for_rent_exempt_accounts is activated,
// rent_epoch of rent-exempt accounts will no longer advance.
assert_eq!(
bank.get_account(&rent_exempt_pubkey).unwrap().rent_epoch(),
0
);
assert_eq!(
bank.slots_by_pubkey(&rent_due_pubkey, &ancestors),
vec![genesis_slot, some_slot]
);
assert_eq!(
bank.slots_by_pubkey(&rent_exempt_pubkey, &ancestors),
vec![genesis_slot, some_slot]
);
assert_eq!(
bank.slots_by_pubkey(&zero_lamport_pubkey, &ancestors),
vec![genesis_slot]
);
}
fn new_from_parent_next_epoch(parent: &Arc<Bank>, epochs: Epoch) -> Bank {
let mut slot = parent.slot();
let mut epoch = parent.epoch();
for _ in 0..epochs {
slot += parent.epoch_schedule().get_slots_in_epoch(epoch);
epoch = parent.epoch_schedule().get_epoch(slot);
}
Bank::new_from_parent(parent, &Pubkey::default(), slot)
}
#[test]
/// tests that an account which has already had rent collected IN this slot does not skip rewrites
fn test_collect_rent_from_accounts() {
solana_logger::setup();
for skip_rewrites in [false, true] {
let zero_lamport_pubkey = Pubkey::from([0; 32]);
let genesis_bank = create_simple_test_arc_bank(100000);
let mut first_bank = new_from_parent(&genesis_bank);
if skip_rewrites {
first_bank.activate_feature(&feature_set::skip_rent_rewrites::id());
}
let first_bank = Arc::new(first_bank);
let first_slot = 1;
assert_eq!(first_slot, first_bank.slot());
let epoch_delta = 4;
let later_bank = Arc::new(new_from_parent_next_epoch(&first_bank, epoch_delta)); // a bank a few epochs in the future
let later_slot = later_bank.slot();
assert!(later_bank.epoch() == genesis_bank.epoch() + epoch_delta);
let data_size = 0; // make sure we're rent exempt
let lamports = later_bank.get_minimum_balance_for_rent_exemption(data_size); // cannot be 0 or we zero out rent_epoch in rent collection and we need to be rent exempt
let mut account = AccountSharedData::new(lamports, data_size, &Pubkey::default());
account.set_rent_epoch(later_bank.epoch() - 1); // non-zero, but less than later_bank's epoch
// loaded from previous slot, so we skip rent collection on it
let _result = later_bank.collect_rent_from_accounts(
vec![(zero_lamport_pubkey, account, later_slot - 1)],
None,
PartitionIndex::default(),
);
let deltas = later_bank
.rc
.accounts
.accounts_db
.get_pubkey_hash_for_slot(later_slot)
.0;
assert_eq!(
!deltas
.iter()
.any(|(pubkey, _)| pubkey == &zero_lamport_pubkey),
skip_rewrites
);
}
}
#[test]
fn test_rent_eager_collect_rent_zero_lamport_deterministic() {
solana_logger::setup();
let (genesis_config, _mint_keypair) = create_genesis_config(1);
let zero_lamport_pubkey = solana_sdk::pubkey::new_rand();
let genesis_bank1 = Arc::new(Bank::new_for_tests(&genesis_config));
let genesis_bank2 = Arc::new(Bank::new_for_tests(&genesis_config));
let bank1_with_zero = Arc::new(new_from_parent(&genesis_bank1));
let bank1_without_zero = Arc::new(new_from_parent(&genesis_bank2));
let zero_lamports = 0;
let data_size = 12345; // use non-zero data size to also test accounts_data_size
let account = AccountSharedData::new(zero_lamports, data_size, &Pubkey::default());
bank1_with_zero.store_account(&zero_lamport_pubkey, &account);
bank1_without_zero.store_account(&zero_lamport_pubkey, &account);
bank1_without_zero
.rc
.accounts
.accounts_db
.accounts_index
.add_root(genesis_bank1.slot() + 1);
bank1_without_zero
.rc
.accounts
.accounts_db
.accounts_index
.purge_roots(&zero_lamport_pubkey);
// genesis_config.epoch_schedule.slots_per_epoch == 432_000 and is unsuitable for this test
let some_slot = MINIMUM_SLOTS_PER_EPOCH; // 1 epoch
let bank2_with_zero = Arc::new(Bank::new_from_parent(
&bank1_with_zero,
&Pubkey::default(),
some_slot,
));
assert_eq!(bank1_with_zero.epoch() + 1, bank2_with_zero.epoch());
let bank2_without_zero = Arc::new(Bank::new_from_parent(
&bank1_without_zero,
&Pubkey::default(),
some_slot,
));
let hash1_with_zero = bank1_with_zero.hash();
let hash1_without_zero = bank1_without_zero.hash();
assert_eq!(hash1_with_zero, hash1_without_zero);
assert_ne!(hash1_with_zero, Hash::default());
bank2_with_zero.collect_rent_in_partition((0, 0, 1), &RentMetrics::default()); // all
bank2_without_zero.collect_rent_in_partition((0, 0, 1), &RentMetrics::default()); // all
bank2_with_zero.freeze();
let hash2_with_zero = bank2_with_zero.hash();
bank2_without_zero.freeze();
let hash2_without_zero = bank2_without_zero.hash();
assert_eq!(hash2_with_zero, hash2_without_zero);
assert_ne!(hash2_with_zero, Hash::default());
}
#[test]
fn test_bank_update_vote_stake_rewards() {
let thread_pool = ThreadPoolBuilder::new().num_threads(1).build().unwrap();
check_bank_update_vote_stake_rewards(|bank: &Bank| {
bank._load_vote_and_stake_accounts_with_thread_pool(&thread_pool, null_tracer())
});
check_bank_update_vote_stake_rewards(|bank: &Bank| {
bank._load_vote_and_stake_accounts(&thread_pool, null_tracer())
});
}
#[cfg(test)]
fn check_bank_update_vote_stake_rewards<F>(load_vote_and_stake_accounts: F)
where
F: Fn(&Bank) -> LoadVoteAndStakeAccountsResult,
{
solana_logger::setup();
// create a bank that ticks really slowly...
let bank0 = Arc::new(Bank::new_for_tests(&GenesisConfig {
accounts: (0..42)
.map(|_| {
(
solana_sdk::pubkey::new_rand(),
Account::new(1_000_000_000, 0, &Pubkey::default()),
)
})
.collect(),
// set it up so the first epoch is a full year long
poh_config: PohConfig {
target_tick_duration: Duration::from_secs(
SECONDS_PER_YEAR as u64 / MINIMUM_SLOTS_PER_EPOCH / DEFAULT_TICKS_PER_SLOT,
),
hashes_per_tick: None,
target_tick_count: None,
},
cluster_type: ClusterType::MainnetBeta,
..GenesisConfig::default()
}));
// enable lazy rent collection because this test depends on rent-due accounts
// not being eagerly-collected for exact rewards calculation
bank0.restore_old_behavior_for_fragile_tests();
assert_eq!(
bank0.capitalization(),
42 * 1_000_000_000 + genesis_sysvar_and_builtin_program_lamports(),
);
let ((vote_id, mut vote_account), (stake_id, stake_account)) =
crate::stakes::tests::create_staked_node_accounts(10_000);
let starting_vote_and_stake_balance = 10_000 + 1;
// set up accounts
bank0.store_account_and_update_capitalization(&stake_id, &stake_account);
// generate some rewards
let mut vote_state = Some(vote_state::from(&vote_account).unwrap());
for i in 0..MAX_LOCKOUT_HISTORY + 42 {
if let Some(v) = vote_state.as_mut() {
vote_state::process_slot_vote_unchecked(v, i as u64)
}
let versioned = VoteStateVersions::Current(Box::new(vote_state.take().unwrap()));
vote_state::to(&versioned, &mut vote_account).unwrap();
bank0.store_account_and_update_capitalization(&vote_id, &vote_account);
match versioned {
VoteStateVersions::Current(v) => {
vote_state = Some(*v);
}
_ => panic!("Has to be of type Current"),
};
}
bank0.store_account_and_update_capitalization(&vote_id, &vote_account);
bank0.freeze();
assert_eq!(
bank0.capitalization(),
42 * 1_000_000_000
+ genesis_sysvar_and_builtin_program_lamports()
+ starting_vote_and_stake_balance
+ bank0_sysvar_delta(),
);
assert!(bank0.rewards.read().unwrap().is_empty());
load_vote_and_stake_accounts(&bank0);
// put a child bank in epoch 1, which calls update_rewards()...
let bank1 = Bank::new_from_parent(
&bank0,
&Pubkey::default(),
bank0.get_slots_in_epoch(bank0.epoch()) + 1,
);
// verify that there's inflation
assert_ne!(bank1.capitalization(), bank0.capitalization());
// verify the inflation is represented in validator_points
let paid_rewards = bank1.capitalization() - bank0.capitalization() - bank1_sysvar_delta();
// this assumes that no new builtins or precompiles were activated in bank1
let PrevEpochInflationRewards {
validator_rewards, ..
} = bank1.calculate_previous_epoch_inflation_rewards(bank0.capitalization(), bank0.epoch());
// verify the stake and vote accounts are the right size
assert!(
((bank1.get_balance(&stake_id) - stake_account.lamports() + bank1.get_balance(&vote_id)
- vote_account.lamports()) as f64
- validator_rewards as f64)
.abs()
< 1.0
);
// verify the rewards are the right size
assert!((validator_rewards as f64 - paid_rewards as f64).abs() < 1.0); // rounding, truncating
// verify validator rewards show up in bank1.rewards vector
assert_eq!(
*bank1.rewards.read().unwrap(),
vec![
(
vote_id,
RewardInfo {
reward_type: RewardType::Voting,
lamports: 0,
post_balance: bank1.get_balance(&vote_id),
commission: Some(0),
}
),
(
stake_id,
RewardInfo {
reward_type: RewardType::Staking,
lamports: validator_rewards as i64,
post_balance: bank1.get_balance(&stake_id),
commission: Some(0),
}
)
]
);
bank1.freeze();
add_root_and_flush_write_cache(&bank0);
add_root_and_flush_write_cache(&bank1);
assert!(bank1.calculate_and_verify_capitalization(true));
}
fn do_test_bank_update_rewards_determinism() -> u64 {
// create a bank that ticks really slowly...
let bank = Arc::new(Bank::new_for_tests(&GenesisConfig {
accounts: (0..42)
.map(|_| {
(
solana_sdk::pubkey::new_rand(),
Account::new(1_000_000_000, 0, &Pubkey::default()),
)
})
.collect(),
// set it up so the first epoch is a full year long
poh_config: PohConfig {
target_tick_duration: Duration::from_secs(
SECONDS_PER_YEAR as u64 / MINIMUM_SLOTS_PER_EPOCH / DEFAULT_TICKS_PER_SLOT,
),
hashes_per_tick: None,
target_tick_count: None,
},
cluster_type: ClusterType::MainnetBeta,
..GenesisConfig::default()
}));
// enable lazy rent collection because this test depends on rent-due accounts
// not being eagerly-collected for exact rewards calculation
bank.restore_old_behavior_for_fragile_tests();
assert_eq!(
bank.capitalization(),
42 * 1_000_000_000 + genesis_sysvar_and_builtin_program_lamports()
);
let vote_id = solana_sdk::pubkey::new_rand();
let mut vote_account =
vote_state::create_account(&vote_id, &solana_sdk::pubkey::new_rand(), 0, 100);
let stake_id1 = solana_sdk::pubkey::new_rand();
let stake_account1 = crate::stakes::tests::create_stake_account(123, &vote_id, &stake_id1);
let stake_id2 = solana_sdk::pubkey::new_rand();
let stake_account2 = crate::stakes::tests::create_stake_account(456, &vote_id, &stake_id2);
// set up accounts
bank.store_account_and_update_capitalization(&stake_id1, &stake_account1);
bank.store_account_and_update_capitalization(&stake_id2, &stake_account2);
// generate some rewards
let mut vote_state = Some(vote_state::from(&vote_account).unwrap());
for i in 0..MAX_LOCKOUT_HISTORY + 42 {
if let Some(v) = vote_state.as_mut() {
vote_state::process_slot_vote_unchecked(v, i as u64)
}
let versioned = VoteStateVersions::Current(Box::new(vote_state.take().unwrap()));
vote_state::to(&versioned, &mut vote_account).unwrap();
bank.store_account_and_update_capitalization(&vote_id, &vote_account);
match versioned {
VoteStateVersions::Current(v) => {
vote_state = Some(*v);
}
_ => panic!("Has to be of type Current"),
};
}
bank.store_account_and_update_capitalization(&vote_id, &vote_account);
// put a child bank in epoch 1, which calls update_rewards()...
let bank1 = Bank::new_from_parent(
&bank,
&Pubkey::default(),
bank.get_slots_in_epoch(bank.epoch()) + 1,
);
// verify that there's inflation
assert_ne!(bank1.capitalization(), bank.capitalization());
bank1.freeze();
add_root_and_flush_write_cache(&bank);
add_root_and_flush_write_cache(&bank1);
assert!(bank1.calculate_and_verify_capitalization(true));
// verify voting and staking rewards are recorded
let rewards = bank1.rewards.read().unwrap();
rewards
.iter()
.find(|(_address, reward)| reward.reward_type == RewardType::Voting)
.unwrap();
rewards
.iter()
.find(|(_address, reward)| reward.reward_type == RewardType::Staking)
.unwrap();
bank1.capitalization()
}
#[test]
fn test_bank_update_rewards_determinism() {
solana_logger::setup();
// The same reward should be distributed given same credits
let expected_capitalization = do_test_bank_update_rewards_determinism();
// Repeat somewhat large number of iterations to expose possible different behavior
// depending on the randomly-seeded HashMap ordering
for _ in 0..30 {
let actual_capitalization = do_test_bank_update_rewards_determinism();
assert_eq!(actual_capitalization, expected_capitalization);
}
}
impl VerifyAccountsHashConfig {
fn default_for_test() -> Self {
Self {
test_hash_calculation: true,
ignore_mismatch: false,
require_rooted_bank: false,
run_in_background: false,
store_hash_raw_data_for_debug: false,
}
}
}
// Test that purging 0 lamports accounts works.
#[test]
fn test_purge_empty_accounts() {
// When using the write cache, flushing is destructive/cannot be undone
// so we have to stop at various points and restart to actively test.
for pass in 0..3 {
solana_logger::setup();
let (genesis_config, mint_keypair) = create_genesis_config(sol_to_lamports(1.));
let amount = genesis_config.rent.minimum_balance(0);
let parent = Arc::new(Bank::new_for_tests_with_config(
&genesis_config,
BankTestConfig::default(),
));
let mut bank = parent;
for _ in 0..10 {
let blockhash = bank.last_blockhash();
let pubkey = solana_sdk::pubkey::new_rand();
let tx = system_transaction::transfer(&mint_keypair, &pubkey, 0, blockhash);
bank.process_transaction(&tx).unwrap();
bank.freeze();
bank.squash();
bank = Arc::new(new_from_parent(&bank));
}
bank.freeze();
bank.squash();
bank.force_flush_accounts_cache();
let hash = bank.update_accounts_hash_for_tests();
bank.clean_accounts_for_tests();
assert_eq!(bank.update_accounts_hash_for_tests(), hash);
let bank0 = Arc::new(new_from_parent(&bank));
let blockhash = bank.last_blockhash();
let keypair = Keypair::new();
let tx = system_transaction::transfer(&mint_keypair, &keypair.pubkey(), amount, blockhash);
bank0.process_transaction(&tx).unwrap();
let bank1 = Arc::new(new_from_parent(&bank0));
let pubkey = solana_sdk::pubkey::new_rand();
let blockhash = bank.last_blockhash();
let tx = system_transaction::transfer(&keypair, &pubkey, amount, blockhash);
bank1.process_transaction(&tx).unwrap();
assert_eq!(
bank0.get_account(&keypair.pubkey()).unwrap().lamports(),
amount
);
assert_eq!(bank1.get_account(&keypair.pubkey()), None);
info!("bank0 purge");
let hash = bank0.update_accounts_hash_for_tests();
bank0.clean_accounts_for_tests();
assert_eq!(bank0.update_accounts_hash_for_tests(), hash);
assert_eq!(
bank0.get_account(&keypair.pubkey()).unwrap().lamports(),
amount
);
assert_eq!(bank1.get_account(&keypair.pubkey()), None);
info!("bank1 purge");
bank1.clean_accounts_for_tests();
assert_eq!(
bank0.get_account(&keypair.pubkey()).unwrap().lamports(),
amount
);
assert_eq!(bank1.get_account(&keypair.pubkey()), None);
if pass == 0 {
add_root_and_flush_write_cache(&bank0);
assert!(bank0.verify_accounts_hash(None, VerifyAccountsHashConfig::default_for_test()));
continue;
}
// Squash and then verify hash_internal value
bank0.freeze();
bank0.squash();
add_root_and_flush_write_cache(&bank0);
if pass == 1 {
assert!(bank0.verify_accounts_hash(None, VerifyAccountsHashConfig::default_for_test()));
continue;
}
bank1.freeze();
bank1.squash();
add_root_and_flush_write_cache(&bank1);
bank1.update_accounts_hash_for_tests();
assert!(bank1.verify_accounts_hash(None, VerifyAccountsHashConfig::default_for_test()));
// keypair should have 0 tokens on both forks
assert_eq!(bank0.get_account(&keypair.pubkey()), None);
assert_eq!(bank1.get_account(&keypair.pubkey()), None);
bank1.clean_accounts_for_tests();
assert!(bank1.verify_accounts_hash(None, VerifyAccountsHashConfig::default_for_test()));
}
}
#[test]
fn test_two_payments_to_one_party() {
let (genesis_config, mint_keypair) = create_genesis_config(sol_to_lamports(1.));
let pubkey = solana_sdk::pubkey::new_rand();
let bank = Bank::new_for_tests(&genesis_config);
let amount = genesis_config.rent.minimum_balance(0);
assert_eq!(bank.last_blockhash(), genesis_config.hash());
bank.transfer(amount, &mint_keypair, &pubkey).unwrap();
assert_eq!(bank.get_balance(&pubkey), amount);
bank.transfer(amount * 2, &mint_keypair, &pubkey).unwrap();
assert_eq!(bank.get_balance(&pubkey), amount * 3);
assert_eq!(bank.transaction_count(), 2);
assert_eq!(bank.non_vote_transaction_count_since_restart(), 2);
}
#[test]
fn test_one_source_two_tx_one_batch() {
let (genesis_config, mint_keypair) = create_genesis_config(sol_to_lamports(1.));
let key1 = solana_sdk::pubkey::new_rand();
let key2 = solana_sdk::pubkey::new_rand();
let bank = Bank::new_for_tests(&genesis_config);
let amount = genesis_config.rent.minimum_balance(0);
assert_eq!(bank.last_blockhash(), genesis_config.hash());
let t1 = system_transaction::transfer(&mint_keypair, &key1, amount, genesis_config.hash());
let t2 = system_transaction::transfer(&mint_keypair, &key2, amount, genesis_config.hash());
let txs = vec![t1.clone(), t2.clone()];
let res = bank.process_transactions(txs.iter());
assert_eq!(res.len(), 2);
assert_eq!(res[0], Ok(()));
assert_eq!(res[1], Err(TransactionError::AccountInUse));
assert_eq!(
bank.get_balance(&mint_keypair.pubkey()),
sol_to_lamports(1.) - amount
);
assert_eq!(bank.get_balance(&key1), amount);
assert_eq!(bank.get_balance(&key2), 0);
assert_eq!(bank.get_signature_status(&t1.signatures[0]), Some(Ok(())));
// TODO: Transactions that fail to pay a fee could be dropped silently.
// Non-instruction errors don't get logged in the signature cache
assert_eq!(bank.get_signature_status(&t2.signatures[0]), None);
}
#[test]
fn test_one_tx_two_out_atomic_fail() {
let amount = sol_to_lamports(1.);
let (genesis_config, mint_keypair) = create_genesis_config(amount);
let key1 = solana_sdk::pubkey::new_rand();
let key2 = solana_sdk::pubkey::new_rand();
let bank = Bank::new_for_tests(&genesis_config);
let instructions = system_instruction::transfer_many(
&mint_keypair.pubkey(),
&[(key1, amount), (key2, amount)],
);
let message = Message::new(&instructions, Some(&mint_keypair.pubkey()));
let tx = Transaction::new(&[&mint_keypair], message, genesis_config.hash());
assert_eq!(
bank.process_transaction(&tx).unwrap_err(),
TransactionError::InstructionError(1, SystemError::ResultWithNegativeLamports.into())
);
assert_eq!(bank.get_balance(&mint_keypair.pubkey()), amount);
assert_eq!(bank.get_balance(&key1), 0);
assert_eq!(bank.get_balance(&key2), 0);
}
#[test]
fn test_one_tx_two_out_atomic_pass() {
let (genesis_config, mint_keypair) = create_genesis_config(sol_to_lamports(1.));
let key1 = solana_sdk::pubkey::new_rand();
let key2 = solana_sdk::pubkey::new_rand();
let bank = Bank::new_for_tests(&genesis_config);
let amount = genesis_config.rent.minimum_balance(0);
let instructions = system_instruction::transfer_many(
&mint_keypair.pubkey(),
&[(key1, amount), (key2, amount)],
);
let message = Message::new(&instructions, Some(&mint_keypair.pubkey()));
let tx = Transaction::new(&[&mint_keypair], message, genesis_config.hash());
bank.process_transaction(&tx).unwrap();
assert_eq!(
bank.get_balance(&mint_keypair.pubkey()),
sol_to_lamports(1.) - (2 * amount)
);
assert_eq!(bank.get_balance(&key1), amount);
assert_eq!(bank.get_balance(&key2), amount);
}
// This test demonstrates that fees are paid even when a program fails.
#[test]
fn test_detect_failed_duplicate_transactions() {
let (mut genesis_config, mint_keypair) = create_genesis_config(10_000);
genesis_config.fee_rate_governor = FeeRateGovernor::new(5_000, 0);
let bank = Bank::new_for_tests(&genesis_config);
let dest = Keypair::new();
// source with 0 program context
let tx =
system_transaction::transfer(&mint_keypair, &dest.pubkey(), 10_000, genesis_config.hash());
let signature = tx.signatures[0];
assert!(!bank.has_signature(&signature));
assert_eq!(
bank.process_transaction(&tx),
Err(TransactionError::InstructionError(
0,
SystemError::ResultWithNegativeLamports.into(),
))
);
// The lamports didn't move, but the from address paid the transaction fee.
assert_eq!(bank.get_balance(&dest.pubkey()), 0);
// This should be the original balance minus the transaction fee.
assert_eq!(bank.get_balance(&mint_keypair.pubkey()), 5000);
}
#[test]
fn test_account_not_found() {
solana_logger::setup();
let (genesis_config, mint_keypair) = create_genesis_config(0);
let bank = Bank::new_for_tests(&genesis_config);
let keypair = Keypair::new();
assert_eq!(
bank.transfer(
genesis_config.rent.minimum_balance(0),
&keypair,
&mint_keypair.pubkey()
),
Err(TransactionError::AccountNotFound)
);
assert_eq!(bank.transaction_count(), 0);
assert_eq!(bank.non_vote_transaction_count_since_restart(), 0);
}
#[test]
fn test_insufficient_funds() {
let mint_amount = sol_to_lamports(1.);
let (genesis_config, mint_keypair) = create_genesis_config(mint_amount);
let bank = Bank::new_for_tests(&genesis_config);
let pubkey = solana_sdk::pubkey::new_rand();
let amount = genesis_config.rent.minimum_balance(0);
bank.transfer(amount, &mint_keypair, &pubkey).unwrap();
assert_eq!(bank.transaction_count(), 1);
assert_eq!(bank.non_vote_transaction_count_since_restart(), 1);
assert_eq!(bank.get_balance(&pubkey), amount);
assert_eq!(
bank.transfer((mint_amount - amount) + 1, &mint_keypair, &pubkey),
Err(TransactionError::InstructionError(
0,
SystemError::ResultWithNegativeLamports.into(),
))
);
// transaction_count returns the count of all committed transactions since
// bank_transaction_count_fix was activated, regardless of success
assert_eq!(bank.transaction_count(), 2);
assert_eq!(bank.non_vote_transaction_count_since_restart(), 1);
let mint_pubkey = mint_keypair.pubkey();
assert_eq!(bank.get_balance(&mint_pubkey), mint_amount - amount);
assert_eq!(bank.get_balance(&pubkey), amount);
}
#[test]
fn test_executed_transaction_count_post_bank_transaction_count_fix() {
let mint_amount = sol_to_lamports(1.);
let (genesis_config, mint_keypair) = create_genesis_config(mint_amount);
let mut bank = Bank::new_for_tests(&genesis_config);
bank.activate_feature(&feature_set::bank_transaction_count_fix::id());
let pubkey = solana_sdk::pubkey::new_rand();
let amount = genesis_config.rent.minimum_balance(0);
bank.transfer(amount, &mint_keypair, &pubkey).unwrap();
assert_eq!(
bank.transfer((mint_amount - amount) + 1, &mint_keypair, &pubkey),
Err(TransactionError::InstructionError(
0,
SystemError::ResultWithNegativeLamports.into(),
))
);
// With bank_transaction_count_fix, transaction_count should include both the successful and
// failed transactions.
assert_eq!(bank.transaction_count(), 2);
assert_eq!(bank.executed_transaction_count(), 2);
assert_eq!(bank.transaction_error_count(), 1);
let bank = Arc::new(bank);
let bank2 = Bank::new_from_parent(
&bank,
&Pubkey::default(),
genesis_config.epoch_schedule.first_normal_slot,
);
assert_eq!(
bank2.transfer((mint_amount - amount) + 2, &mint_keypair, &pubkey),
Err(TransactionError::InstructionError(
0,
SystemError::ResultWithNegativeLamports.into(),
))
);
// The transaction_count inherited from parent bank is 3: 2 from the parent bank and 1 at this bank2
assert_eq!(bank2.transaction_count(), 3);
assert_eq!(bank2.executed_transaction_count(), 1);
assert_eq!(bank2.transaction_error_count(), 1);
}
#[test]
fn test_transfer_to_newb() {
solana_logger::setup();
let (genesis_config, mint_keypair) = create_genesis_config(sol_to_lamports(1.));
let bank = Bank::new_for_tests(&genesis_config);
let amount = genesis_config.rent.minimum_balance(0);
let pubkey = solana_sdk::pubkey::new_rand();
bank.transfer(amount, &mint_keypair, &pubkey).unwrap();
assert_eq!(bank.get_balance(&pubkey), amount);
}
#[test]
fn test_transfer_to_sysvar() {
solana_logger::setup();
let (genesis_config, mint_keypair) = create_genesis_config(sol_to_lamports(1.));
let bank = Arc::new(Bank::new_for_tests(&genesis_config));
let amount = genesis_config.rent.minimum_balance(0);
let normal_pubkey = solana_sdk::pubkey::new_rand();
let sysvar_pubkey = sysvar::clock::id();
assert_eq!(bank.get_balance(&normal_pubkey), 0);
assert_eq!(bank.get_balance(&sysvar_pubkey), 1_169_280);
bank.transfer(amount, &mint_keypair, &normal_pubkey)
.unwrap();
bank.transfer(amount, &mint_keypair, &sysvar_pubkey)
.unwrap_err();
assert_eq!(bank.get_balance(&normal_pubkey), amount);
assert_eq!(bank.get_balance(&sysvar_pubkey), 1_169_280);
let bank = Arc::new(new_from_parent(&bank));
assert_eq!(bank.get_balance(&normal_pubkey), amount);
assert_eq!(bank.get_balance(&sysvar_pubkey), 1_169_280);
}
#[test]
fn test_bank_deposit() {
let bank = create_simple_test_bank(100);
// Test new account
let key = solana_sdk::pubkey::new_rand();
let new_balance = bank.deposit(&key, 10).unwrap();
assert_eq!(new_balance, 10);
assert_eq!(bank.get_balance(&key), 10);
// Existing account
let new_balance = bank.deposit(&key, 3).unwrap();
assert_eq!(new_balance, 13);
assert_eq!(bank.get_balance(&key), 13);
}
#[test]
fn test_bank_withdraw() {
let bank = create_simple_test_bank(100);
// Test no account
let key = solana_sdk::pubkey::new_rand();
assert_eq!(
bank.withdraw(&key, 10),
Err(TransactionError::AccountNotFound)
);
bank.deposit(&key, 3).unwrap();
assert_eq!(bank.get_balance(&key), 3);
// Low balance
assert_eq!(
bank.withdraw(&key, 10),
Err(TransactionError::InsufficientFundsForFee)
);
// Enough balance
assert_eq!(bank.withdraw(&key, 2), Ok(()));
assert_eq!(bank.get_balance(&key), 1);
}
#[test]
fn test_bank_withdraw_from_nonce_account() {
let (mut genesis_config, _mint_keypair) = create_genesis_config(100_000);
genesis_config.rent.lamports_per_byte_year = 42;
let bank = Bank::new_for_tests(&genesis_config);
let min_balance = bank.get_minimum_balance_for_rent_exemption(nonce::State::size());
let nonce = Keypair::new();
let nonce_account = AccountSharedData::new_data(
min_balance + 42,
&nonce::state::Versions::new(nonce::State::Initialized(nonce::state::Data::default())),
&system_program::id(),
)
.unwrap();
bank.store_account(&nonce.pubkey(), &nonce_account);
assert_eq!(bank.get_balance(&nonce.pubkey()), min_balance + 42);
// Resulting in non-zero, but sub-min_balance balance fails
assert_eq!(
bank.withdraw(&nonce.pubkey(), min_balance / 2),
Err(TransactionError::InsufficientFundsForFee)
);
assert_eq!(bank.get_balance(&nonce.pubkey()), min_balance + 42);
// Resulting in exactly rent-exempt balance succeeds
bank.withdraw(&nonce.pubkey(), 42).unwrap();
assert_eq!(bank.get_balance(&nonce.pubkey()), min_balance);
// Account closure fails
assert_eq!(
bank.withdraw(&nonce.pubkey(), min_balance),
Err(TransactionError::InsufficientFundsForFee),
);
}
#[test]
fn test_bank_tx_fee() {
solana_logger::setup();
let arbitrary_transfer_amount = 42_000;
let mint = arbitrary_transfer_amount * 100;
let leader = solana_sdk::pubkey::new_rand();
let GenesisConfigInfo {
mut genesis_config,
mint_keypair,
..
} = create_genesis_config_with_leader(mint, &leader, 3);
genesis_config.fee_rate_governor = FeeRateGovernor::new(5000, 0); // something divisible by 2
let expected_fee_paid = genesis_config
.fee_rate_governor
.create_fee_calculator()
.lamports_per_signature;
let (expected_fee_collected, expected_fee_burned) =
genesis_config.fee_rate_governor.burn(expected_fee_paid);
let mut bank = Bank::new_for_tests(&genesis_config);
let capitalization = bank.capitalization();
let key = solana_sdk::pubkey::new_rand();
let tx = system_transaction::transfer(
&mint_keypair,
&key,
arbitrary_transfer_amount,
bank.last_blockhash(),
);
let initial_balance = bank.get_balance(&leader);
assert_eq!(bank.process_transaction(&tx), Ok(()));
assert_eq!(bank.get_balance(&key), arbitrary_transfer_amount);
assert_eq!(
bank.get_balance(&mint_keypair.pubkey()),
mint - arbitrary_transfer_amount - expected_fee_paid
);
assert_eq!(bank.get_balance(&leader), initial_balance);
goto_end_of_slot(&mut bank);
assert_eq!(bank.signature_count(), 1);
assert_eq!(
bank.get_balance(&leader),
initial_balance + expected_fee_collected
); // Leader collects fee after the bank is frozen
// verify capitalization
let sysvar_and_builtin_program_delta = 1;
assert_eq!(
capitalization - expected_fee_burned + sysvar_and_builtin_program_delta,
bank.capitalization()
);
assert_eq!(
*bank.rewards.read().unwrap(),
vec![(
leader,
RewardInfo {
reward_type: RewardType::Fee,
lamports: expected_fee_collected as i64,
post_balance: initial_balance + expected_fee_collected,
commission: None,
}
)]
);
// Verify that an InstructionError collects fees, too
let mut bank = Bank::new_from_parent(&Arc::new(bank), &leader, 1);
let mut tx = system_transaction::transfer(&mint_keypair, &key, 1, bank.last_blockhash());
// Create a bogus instruction to system_program to cause an instruction error
tx.message.instructions[0].data[0] = 40;
bank.process_transaction(&tx)
.expect_err("instruction error");
assert_eq!(bank.get_balance(&key), arbitrary_transfer_amount); // no change
assert_eq!(
bank.get_balance(&mint_keypair.pubkey()),
mint - arbitrary_transfer_amount - 2 * expected_fee_paid
); // mint_keypair still pays a fee
goto_end_of_slot(&mut bank);
assert_eq!(bank.signature_count(), 1);
// Profit! 2 transaction signatures processed at 3 lamports each
assert_eq!(
bank.get_balance(&leader),
initial_balance + 2 * expected_fee_collected
);
assert_eq!(
*bank.rewards.read().unwrap(),
vec![(
leader,
RewardInfo {
reward_type: RewardType::Fee,
lamports: expected_fee_collected as i64,
post_balance: initial_balance + 2 * expected_fee_collected,
commission: None,
}
)]
);
}
#[test]
fn test_bank_tx_compute_unit_fee() {
solana_logger::setup();
let key = solana_sdk::pubkey::new_rand();
let arbitrary_transfer_amount = 42;
let mint = arbitrary_transfer_amount * 10_000_000;
let leader = solana_sdk::pubkey::new_rand();
let GenesisConfigInfo {
mut genesis_config,
mint_keypair,
..
} = create_genesis_config_with_leader(mint, &leader, 3);
genesis_config.fee_rate_governor = FeeRateGovernor::new(4, 0); // something divisible by 2
let expected_fee_paid = Bank::calculate_fee(
&SanitizedMessage::try_from(Message::new(&[], Some(&Pubkey::new_unique()))).unwrap(),
genesis_config
.fee_rate_governor
.create_fee_calculator()
.lamports_per_signature,
&FeeStructure::default(),
true,
false,
true,
true,
true,
false,
);
let (expected_fee_collected, expected_fee_burned) =
genesis_config.fee_rate_governor.burn(expected_fee_paid);
let mut bank = Bank::new_for_tests(&genesis_config);
let capitalization = bank.capitalization();
let tx = system_transaction::transfer(
&mint_keypair,
&key,
arbitrary_transfer_amount,
bank.last_blockhash(),
);
let initial_balance = bank.get_balance(&leader);
assert_eq!(bank.process_transaction(&tx), Ok(()));
assert_eq!(bank.get_balance(&key), arbitrary_transfer_amount);
assert_eq!(
bank.get_balance(&mint_keypair.pubkey()),
mint - arbitrary_transfer_amount - expected_fee_paid
);
assert_eq!(bank.get_balance(&leader), initial_balance);
goto_end_of_slot(&mut bank);
assert_eq!(bank.signature_count(), 1);
assert_eq!(
bank.get_balance(&leader),
initial_balance + expected_fee_collected
); // Leader collects fee after the bank is frozen
// verify capitalization
let sysvar_and_builtin_program_delta = 1;
assert_eq!(
capitalization - expected_fee_burned + sysvar_and_builtin_program_delta,
bank.capitalization()
);
assert_eq!(
*bank.rewards.read().unwrap(),
vec![(
leader,
RewardInfo {
reward_type: RewardType::Fee,
lamports: expected_fee_collected as i64,
post_balance: initial_balance + expected_fee_collected,
commission: None,
}
)]
);
// Verify that an InstructionError collects fees, too
let mut bank = Bank::new_from_parent(&Arc::new(bank), &leader, 1);
let mut tx = system_transaction::transfer(&mint_keypair, &key, 1, bank.last_blockhash());
// Create a bogus instruction to system_program to cause an instruction error
tx.message.instructions[0].data[0] = 40;
bank.process_transaction(&tx)
.expect_err("instruction error");
assert_eq!(bank.get_balance(&key), arbitrary_transfer_amount); // no change
assert_eq!(
bank.get_balance(&mint_keypair.pubkey()),
mint - arbitrary_transfer_amount - 2 * expected_fee_paid
); // mint_keypair still pays a fee
goto_end_of_slot(&mut bank);
assert_eq!(bank.signature_count(), 1);
// Profit! 2 transaction signatures processed at 3 lamports each
assert_eq!(
bank.get_balance(&leader),
initial_balance + 2 * expected_fee_collected
);
assert_eq!(
*bank.rewards.read().unwrap(),
vec![(
leader,
RewardInfo {
reward_type: RewardType::Fee,
lamports: expected_fee_collected as i64,
post_balance: initial_balance + 2 * expected_fee_collected,
commission: None,
}
)]
);
}
#[test]
fn test_bank_blockhash_fee_structure() {
//solana_logger::setup();
let leader = solana_sdk::pubkey::new_rand();
let GenesisConfigInfo {
mut genesis_config,
mint_keypair,
..
} = create_genesis_config_with_leader(1_000_000, &leader, 3);
genesis_config
.fee_rate_governor
.target_lamports_per_signature = 5000;
genesis_config.fee_rate_governor.target_signatures_per_slot = 0;
let mut bank = Bank::new_for_tests(&genesis_config);
goto_end_of_slot(&mut bank);
let cheap_blockhash = bank.last_blockhash();
let cheap_lamports_per_signature = bank.get_lamports_per_signature();
assert_eq!(cheap_lamports_per_signature, 0);
let mut bank = Bank::new_from_parent(&Arc::new(bank), &leader, 1);
goto_end_of_slot(&mut bank);
let expensive_blockhash = bank.last_blockhash();
let expensive_lamports_per_signature = bank.get_lamports_per_signature();
assert!(cheap_lamports_per_signature < expensive_lamports_per_signature);
let bank = Bank::new_from_parent(&Arc::new(bank), &leader, 2);
// Send a transfer using cheap_blockhash
let key = solana_sdk::pubkey::new_rand();
let initial_mint_balance = bank.get_balance(&mint_keypair.pubkey());
let tx = system_transaction::transfer(&mint_keypair, &key, 1, cheap_blockhash);
assert_eq!(bank.process_transaction(&tx), Ok(()));
assert_eq!(bank.get_balance(&key), 1);
assert_eq!(
bank.get_balance(&mint_keypair.pubkey()),
initial_mint_balance - 1 - cheap_lamports_per_signature
);
// Send a transfer using expensive_blockhash
let key = solana_sdk::pubkey::new_rand();
let initial_mint_balance = bank.get_balance(&mint_keypair.pubkey());
let tx = system_transaction::transfer(&mint_keypair, &key, 1, expensive_blockhash);
assert_eq!(bank.process_transaction(&tx), Ok(()));
assert_eq!(bank.get_balance(&key), 1);
assert_eq!(
bank.get_balance(&mint_keypair.pubkey()),
initial_mint_balance - 1 - expensive_lamports_per_signature
);
}
#[test]
fn test_bank_blockhash_compute_unit_fee_structure() {
//solana_logger::setup();
let leader = solana_sdk::pubkey::new_rand();
let GenesisConfigInfo {
mut genesis_config,
mint_keypair,
..
} = create_genesis_config_with_leader(1_000_000_000, &leader, 3);
genesis_config
.fee_rate_governor
.target_lamports_per_signature = 1000;
genesis_config.fee_rate_governor.target_signatures_per_slot = 1;
let mut bank = Bank::new_for_tests(&genesis_config);
goto_end_of_slot(&mut bank);
let cheap_blockhash = bank.last_blockhash();
let cheap_lamports_per_signature = bank.get_lamports_per_signature();
assert_eq!(cheap_lamports_per_signature, 0);
let mut bank = Bank::new_from_parent(&Arc::new(bank), &leader, 1);
goto_end_of_slot(&mut bank);
let expensive_blockhash = bank.last_blockhash();
let expensive_lamports_per_signature = bank.get_lamports_per_signature();
assert!(cheap_lamports_per_signature < expensive_lamports_per_signature);
let bank = Bank::new_from_parent(&Arc::new(bank), &leader, 2);
// Send a transfer using cheap_blockhash
let key = solana_sdk::pubkey::new_rand();
let initial_mint_balance = bank.get_balance(&mint_keypair.pubkey());
let tx = system_transaction::transfer(&mint_keypair, &key, 1, cheap_blockhash);
assert_eq!(bank.process_transaction(&tx), Ok(()));
assert_eq!(bank.get_balance(&key), 1);
let cheap_fee = Bank::calculate_fee(
&SanitizedMessage::try_from(Message::new(&[], Some(&Pubkey::new_unique()))).unwrap(),
cheap_lamports_per_signature,
&FeeStructure::default(),
true,
false,
true,
true,
true,
false,
);
assert_eq!(
bank.get_balance(&mint_keypair.pubkey()),
initial_mint_balance - 1 - cheap_fee
);
// Send a transfer using expensive_blockhash
let key = solana_sdk::pubkey::new_rand();
let initial_mint_balance = bank.get_balance(&mint_keypair.pubkey());
let tx = system_transaction::transfer(&mint_keypair, &key, 1, expensive_blockhash);
assert_eq!(bank.process_transaction(&tx), Ok(()));
assert_eq!(bank.get_balance(&key), 1);
let expensive_fee = Bank::calculate_fee(
&SanitizedMessage::try_from(Message::new(&[], Some(&Pubkey::new_unique()))).unwrap(),
expensive_lamports_per_signature,
&FeeStructure::default(),
true,
false,
true,
true,
true,
false,
);
assert_eq!(
bank.get_balance(&mint_keypair.pubkey()),
initial_mint_balance - 1 - expensive_fee
);
}
#[test]
fn test_filter_program_errors_and_collect_fee() {
let leader = solana_sdk::pubkey::new_rand();
let GenesisConfigInfo {
mut genesis_config,
mint_keypair,
..
} = create_genesis_config_with_leader(100_000, &leader, 3);
genesis_config.fee_rate_governor = FeeRateGovernor::new(5000, 0);
let bank = Bank::new_for_tests(&genesis_config);
let key = solana_sdk::pubkey::new_rand();
let tx1 = SanitizedTransaction::from_transaction_for_tests(system_transaction::transfer(
&mint_keypair,
&key,
2,
genesis_config.hash(),
));
let tx2 = SanitizedTransaction::from_transaction_for_tests(system_transaction::transfer(
&mint_keypair,
&key,
5,
genesis_config.hash(),
));
let results = vec![
new_execution_result(Ok(()), None),
new_execution_result(
Err(TransactionError::InstructionError(
1,
SystemError::ResultWithNegativeLamports.into(),
)),
None,
),
];
let initial_balance = bank.get_balance(&leader);
let results = bank.filter_program_errors_and_collect_fee(&[tx1, tx2], &results);
bank.freeze();
assert_eq!(
bank.get_balance(&leader),
initial_balance
+ bank
.fee_rate_governor
.burn(bank.fee_rate_governor.lamports_per_signature * 2)
.0
);
assert_eq!(results[0], Ok(()));
assert_eq!(results[1], Ok(()));
}
#[test]
fn test_filter_program_errors_and_collect_compute_unit_fee() {
let leader = solana_sdk::pubkey::new_rand();
let GenesisConfigInfo {
mut genesis_config,
mint_keypair,
..
} = create_genesis_config_with_leader(1000000, &leader, 3);
genesis_config.fee_rate_governor = FeeRateGovernor::new(2, 0);
let bank = Bank::new_for_tests(&genesis_config);
let key = solana_sdk::pubkey::new_rand();
let tx1 = SanitizedTransaction::from_transaction_for_tests(system_transaction::transfer(
&mint_keypair,
&key,
2,
genesis_config.hash(),
));
let tx2 = SanitizedTransaction::from_transaction_for_tests(system_transaction::transfer(
&mint_keypair,
&key,
5,
genesis_config.hash(),
));
let results = vec![
new_execution_result(Ok(()), None),
new_execution_result(
Err(TransactionError::InstructionError(
1,
SystemError::ResultWithNegativeLamports.into(),
)),
None,
),
];
let initial_balance = bank.get_balance(&leader);
let results = bank.filter_program_errors_and_collect_fee(&[tx1, tx2], &results);
bank.freeze();
assert_eq!(
bank.get_balance(&leader),
initial_balance
+ bank
.fee_rate_governor
.burn(
Bank::calculate_fee(
&SanitizedMessage::try_from(Message::new(&[], Some(&Pubkey::new_unique())))
.unwrap(),
genesis_config
.fee_rate_governor
.create_fee_calculator()
.lamports_per_signature,
&FeeStructure::default(),
true,
false,
true,
true,
true,
false,
) * 2
)
.0
);
assert_eq!(results[0], Ok(()));
assert_eq!(results[1], Ok(()));
}
#[test]
fn test_debits_before_credits() {
let (genesis_config, mint_keypair) = create_genesis_config(sol_to_lamports(2.));
let bank = Bank::new_for_tests(&genesis_config);
let keypair = Keypair::new();
let tx0 = system_transaction::transfer(
&mint_keypair,
&keypair.pubkey(),
sol_to_lamports(2.),
genesis_config.hash(),
);
let tx1 = system_transaction::transfer(
&keypair,
&mint_keypair.pubkey(),
sol_to_lamports(1.),
genesis_config.hash(),
);
let txs = vec![tx0, tx1];
let results = bank.process_transactions(txs.iter());
assert!(results[1].is_err());
// Assert bad transactions aren't counted.
assert_eq!(bank.transaction_count(), 1);
assert_eq!(bank.non_vote_transaction_count_since_restart(), 1);
}
#[test]
fn test_readonly_accounts() {
let GenesisConfigInfo {
genesis_config,
mint_keypair,
..
} = create_genesis_config_with_leader(500, &solana_sdk::pubkey::new_rand(), 0);
let bank = Bank::new_for_tests(&genesis_config);
let vote_pubkey0 = solana_sdk::pubkey::new_rand();
let vote_pubkey1 = solana_sdk::pubkey::new_rand();
let vote_pubkey2 = solana_sdk::pubkey::new_rand();
let authorized_voter = Keypair::new();
let payer0 = Keypair::new();
let payer1 = Keypair::new();
// Create vote accounts
let vote_account0 =
vote_state::create_account(&vote_pubkey0, &authorized_voter.pubkey(), 0, 100);
let vote_account1 =
vote_state::create_account(&vote_pubkey1, &authorized_voter.pubkey(), 0, 100);
let vote_account2 =
vote_state::create_account(&vote_pubkey2, &authorized_voter.pubkey(), 0, 100);
bank.store_account(&vote_pubkey0, &vote_account0);
bank.store_account(&vote_pubkey1, &vote_account1);
bank.store_account(&vote_pubkey2, &vote_account2);
// Fund payers
bank.transfer(10, &mint_keypair, &payer0.pubkey()).unwrap();
bank.transfer(10, &mint_keypair, &payer1.pubkey()).unwrap();
bank.transfer(1, &mint_keypair, &authorized_voter.pubkey())
.unwrap();
let vote = Vote::new(vec![1], Hash::default());
let ix0 = vote_instruction::vote(&vote_pubkey0, &authorized_voter.pubkey(), vote.clone());
let tx0 = Transaction::new_signed_with_payer(
&[ix0],
Some(&payer0.pubkey()),
&[&payer0, &authorized_voter],
bank.last_blockhash(),
);
let ix1 = vote_instruction::vote(&vote_pubkey1, &authorized_voter.pubkey(), vote.clone());
let tx1 = Transaction::new_signed_with_payer(
&[ix1],
Some(&payer1.pubkey()),
&[&payer1, &authorized_voter],
bank.last_blockhash(),
);
let txs = vec![tx0, tx1];
let results = bank.process_transactions(txs.iter());
// If multiple transactions attempt to read the same account, they should succeed.
// Vote authorized_voter and sysvar accounts are given read-only handling
assert_eq!(results[0], Ok(()));
assert_eq!(results[1], Ok(()));
let ix0 = vote_instruction::vote(&vote_pubkey2, &authorized_voter.pubkey(), vote);
let tx0 = Transaction::new_signed_with_payer(
&[ix0],
Some(&payer0.pubkey()),
&[&payer0, &authorized_voter],
bank.last_blockhash(),
);
let tx1 = system_transaction::transfer(
&authorized_voter,
&solana_sdk::pubkey::new_rand(),
1,
bank.last_blockhash(),
);
let txs = vec![tx0, tx1];
let results = bank.process_transactions(txs.iter());
// However, an account may not be locked as read-only and writable at the same time.
assert_eq!(results[0], Ok(()));
assert_eq!(results[1], Err(TransactionError::AccountInUse));
}
#[test]
fn test_interleaving_locks() {
let (genesis_config, mint_keypair) = create_genesis_config(sol_to_lamports(1.));
let bank = Bank::new_for_tests(&genesis_config);
let alice = Keypair::new();
let bob = Keypair::new();
let amount = genesis_config.rent.minimum_balance(0);
let tx1 = system_transaction::transfer(
&mint_keypair,
&alice.pubkey(),
amount,
genesis_config.hash(),
);
let pay_alice = vec![tx1];
let lock_result = bank.prepare_batch_for_tests(pay_alice);
let results_alice = bank
.load_execute_and_commit_transactions(
&lock_result,
MAX_PROCESSING_AGE,
false,
false,
false,
false,
&mut ExecuteTimings::default(),
None,
)
.0
.fee_collection_results;
assert_eq!(results_alice[0], Ok(()));
// try executing an interleaved transfer twice
assert_eq!(
bank.transfer(amount, &mint_keypair, &bob.pubkey()),
Err(TransactionError::AccountInUse)
);
// the second time should fail as well
// this verifies that `unlock_accounts` doesn't unlock `AccountInUse` accounts
assert_eq!(
bank.transfer(amount, &mint_keypair, &bob.pubkey()),
Err(TransactionError::AccountInUse)
);
drop(lock_result);
assert!(bank
.transfer(2 * amount, &mint_keypair, &bob.pubkey())
.is_ok());
}
#[test]
fn test_readonly_relaxed_locks() {
let (genesis_config, _) = create_genesis_config(3);
let bank = Bank::new_for_tests(&genesis_config);
let key0 = Keypair::new();
let key1 = Keypair::new();
let key2 = Keypair::new();
let key3 = solana_sdk::pubkey::new_rand();
let message = Message {
header: MessageHeader {
num_required_signatures: 1,
num_readonly_signed_accounts: 0,
num_readonly_unsigned_accounts: 1,
},
account_keys: vec![key0.pubkey(), key3],
recent_blockhash: Hash::default(),
instructions: vec![],
};
let tx = Transaction::new(&[&key0], message, genesis_config.hash());
let txs = vec![tx];
let batch0 = bank.prepare_batch_for_tests(txs);
assert!(batch0.lock_results()[0].is_ok());
// Try locking accounts, locking a previously read-only account as writable
// should fail
let message = Message {
header: MessageHeader {
num_required_signatures: 1,
num_readonly_signed_accounts: 0,
num_readonly_unsigned_accounts: 0,
},
account_keys: vec![key1.pubkey(), key3],
recent_blockhash: Hash::default(),
instructions: vec![],
};
let tx = Transaction::new(&[&key1], message, genesis_config.hash());
let txs = vec![tx];
let batch1 = bank.prepare_batch_for_tests(txs);
assert!(batch1.lock_results()[0].is_err());
// Try locking a previously read-only account a 2nd time; should succeed
let message = Message {
header: MessageHeader {
num_required_signatures: 1,
num_readonly_signed_accounts: 0,
num_readonly_unsigned_accounts: 1,
},
account_keys: vec![key2.pubkey(), key3],
recent_blockhash: Hash::default(),
instructions: vec![],
};
let tx = Transaction::new(&[&key2], message, genesis_config.hash());
let txs = vec![tx];
let batch2 = bank.prepare_batch_for_tests(txs);
assert!(batch2.lock_results()[0].is_ok());
}
#[test]
fn test_bank_invalid_account_index() {
let (genesis_config, mint_keypair) = create_genesis_config(1);
let keypair = Keypair::new();
let bank = Bank::new_for_tests(&genesis_config);
let tx =
system_transaction::transfer(&mint_keypair, &keypair.pubkey(), 1, genesis_config.hash());
let mut tx_invalid_program_index = tx.clone();
tx_invalid_program_index.message.instructions[0].program_id_index = 42;
assert_eq!(
bank.process_transaction(&tx_invalid_program_index),
Err(TransactionError::SanitizeFailure)
);
let mut tx_invalid_account_index = tx;
tx_invalid_account_index.message.instructions[0].accounts[0] = 42;
assert_eq!(
bank.process_transaction(&tx_invalid_account_index),
Err(TransactionError::SanitizeFailure)
);
}
#[test]
fn test_bank_pay_to_self() {
let (genesis_config, mint_keypair) = create_genesis_config(sol_to_lamports(1.));
let key1 = Keypair::new();
let bank = Bank::new_for_tests(&genesis_config);
let amount = genesis_config.rent.minimum_balance(0);
bank.transfer(amount, &mint_keypair, &key1.pubkey())
.unwrap();
assert_eq!(bank.get_balance(&key1.pubkey()), amount);
let tx = system_transaction::transfer(&key1, &key1.pubkey(), amount, genesis_config.hash());
let _res = bank.process_transaction(&tx);
assert_eq!(bank.get_balance(&key1.pubkey()), amount);
bank.get_signature_status(&tx.signatures[0])
.unwrap()
.unwrap();
}
fn new_from_parent(parent: &Arc<Bank>) -> Bank {
Bank::new_from_parent(parent, &Pubkey::default(), parent.slot() + 1)
}
/// Verify that the parent's vector is computed correctly
#[test]
fn test_bank_parents() {
let (genesis_config, _) = create_genesis_config(1);
let parent = Arc::new(Bank::new_for_tests(&genesis_config));
let bank = new_from_parent(&parent);
assert!(Arc::ptr_eq(&bank.parents()[0], &parent));
}
/// Verifies that transactions are dropped if they have already been processed
#[test]
fn test_tx_already_processed() {
let (genesis_config, mint_keypair) = create_genesis_config(sol_to_lamports(1.));
let bank = Bank::new_for_tests(&genesis_config);
let key1 = Keypair::new();
let mut tx = system_transaction::transfer(
&mint_keypair,
&key1.pubkey(),
genesis_config.rent.minimum_balance(0),
genesis_config.hash(),
);
// First process `tx` so that the status cache is updated
assert_eq!(bank.process_transaction(&tx), Ok(()));
// Ensure that signature check works
assert_eq!(
bank.process_transaction(&tx),
Err(TransactionError::AlreadyProcessed)
);
// Change transaction signature to simulate processing a transaction with a different signature
// for the same message.
tx.signatures[0] = Signature::default();
// Ensure that message hash check works
assert_eq!(
bank.process_transaction(&tx),
Err(TransactionError::AlreadyProcessed)
);
}
/// Verifies that last ids and status cache are correctly referenced from parent
#[test]
fn test_bank_parent_already_processed() {
let (genesis_config, mint_keypair) = create_genesis_config(sol_to_lamports(1.));
let key1 = Keypair::new();
let parent = Arc::new(Bank::new_for_tests(&genesis_config));
let amount = genesis_config.rent.minimum_balance(0);
let tx =
system_transaction::transfer(&mint_keypair, &key1.pubkey(), amount, genesis_config.hash());
assert_eq!(parent.process_transaction(&tx), Ok(()));
let bank = new_from_parent(&parent);
assert_eq!(
bank.process_transaction(&tx),
Err(TransactionError::AlreadyProcessed)
);
}
/// Verifies that last ids and accounts are correctly referenced from parent
#[test]
fn test_bank_parent_account_spend() {
let (genesis_config, mint_keypair) = create_genesis_config(sol_to_lamports(1.0));
let key1 = Keypair::new();
let key2 = Keypair::new();
let parent = Arc::new(Bank::new_for_tests(&genesis_config));
let amount = genesis_config.rent.minimum_balance(0);
let tx =
system_transaction::transfer(&mint_keypair, &key1.pubkey(), amount, genesis_config.hash());
assert_eq!(parent.process_transaction(&tx), Ok(()));
let bank = new_from_parent(&parent);
let tx = system_transaction::transfer(&key1, &key2.pubkey(), amount, genesis_config.hash());
assert_eq!(bank.process_transaction(&tx), Ok(()));
assert_eq!(parent.get_signature_status(&tx.signatures[0]), None);
}
#[test]
fn test_bank_hash_internal_state() {
let (genesis_config, mint_keypair) = create_genesis_config(sol_to_lamports(1.));
let bank0 = Bank::new_for_tests(&genesis_config);
let bank1 = Bank::new_for_tests(&genesis_config);
let amount = genesis_config.rent.minimum_balance(0);
let initial_state = bank0.hash_internal_state();
assert_eq!(bank1.hash_internal_state(), initial_state);
let pubkey = solana_sdk::pubkey::new_rand();
bank0.transfer(amount, &mint_keypair, &pubkey).unwrap();
assert_ne!(bank0.hash_internal_state(), initial_state);
bank1.transfer(amount, &mint_keypair, &pubkey).unwrap();
assert_eq!(bank0.hash_internal_state(), bank1.hash_internal_state());
// Checkpointing should always result in a new state
let bank1 = Arc::new(bank1);
let bank2 = new_from_parent(&bank1);
assert_ne!(bank0.hash_internal_state(), bank2.hash_internal_state());
let pubkey2 = solana_sdk::pubkey::new_rand();
info!("transfer 2 {}", pubkey2);
bank2.transfer(amount, &mint_keypair, &pubkey2).unwrap();
add_root_and_flush_write_cache(&bank0);
add_root_and_flush_write_cache(&bank1);
add_root_and_flush_write_cache(&bank2);
bank2.update_accounts_hash_for_tests();
assert!(bank2.verify_accounts_hash(None, VerifyAccountsHashConfig::default_for_test()));
}
#[test]
fn test_bank_hash_internal_state_verify() {
for pass in 0..3 {
solana_logger::setup();
let (genesis_config, mint_keypair) = create_genesis_config(sol_to_lamports(1.));
let bank0 = Bank::new_for_tests(&genesis_config);
let amount = genesis_config.rent.minimum_balance(0);
let pubkey = solana_sdk::pubkey::new_rand();
info!("transfer 0 {} mint: {}", pubkey, mint_keypair.pubkey());
bank0.transfer(amount, &mint_keypair, &pubkey).unwrap();
let bank0_state = bank0.hash_internal_state();
let bank0 = Arc::new(bank0);
// Checkpointing should result in a new state while freezing the parent
let bank2 = Bank::new_from_parent(&bank0, &solana_sdk::pubkey::new_rand(), 1);
assert_ne!(bank0_state, bank2.hash_internal_state());
// Checkpointing should modify the checkpoint's state when freezed
assert_ne!(bank0_state, bank0.hash_internal_state());
// Checkpointing should never modify the checkpoint's state once frozen
add_root_and_flush_write_cache(&bank0);
let bank0_state = bank0.hash_internal_state();
if pass == 0 {
// we later modify bank 2, so this flush is destructive to the test
add_root_and_flush_write_cache(&bank2);
bank2.update_accounts_hash_for_tests();
assert!(bank2.verify_accounts_hash(None, VerifyAccountsHashConfig::default_for_test()));
}
let bank3 = Bank::new_from_parent(&bank0, &solana_sdk::pubkey::new_rand(), 2);
assert_eq!(bank0_state, bank0.hash_internal_state());
if pass == 0 {
// this relies on us having set the bank hash in the pass==0 if above
assert!(bank2.verify_accounts_hash(None, VerifyAccountsHashConfig::default_for_test()));
continue;
}
if pass == 1 {
// flushing slot 3 here causes us to mark it as a root. Marking it as a root
// prevents us from marking slot 2 as a root later since slot 2 is < slot 3.
// Doing so throws an assert. So, we can't flush 3 until 2 is flushed.
add_root_and_flush_write_cache(&bank3);
bank3.update_accounts_hash_for_tests();
assert!(bank3.verify_accounts_hash(None, VerifyAccountsHashConfig::default_for_test()));
continue;
}
let pubkey2 = solana_sdk::pubkey::new_rand();
info!("transfer 2 {}", pubkey2);
bank2.transfer(amount, &mint_keypair, &pubkey2).unwrap();
add_root_and_flush_write_cache(&bank2);
bank2.update_accounts_hash_for_tests();
assert!(bank2.verify_accounts_hash(None, VerifyAccountsHashConfig::default_for_test()));
add_root_and_flush_write_cache(&bank3);
bank3.update_accounts_hash_for_tests();
assert!(bank3.verify_accounts_hash(None, VerifyAccountsHashConfig::default_for_test()));
}
}
#[test]
#[should_panic(expected = "assertion failed: self.is_frozen()")]
fn test_verify_hash_unfrozen() {
let bank = create_simple_test_bank(2_000);
assert!(bank.verify_hash());
}
#[test]
fn test_verify_snapshot_bank() {
solana_logger::setup();
let pubkey = solana_sdk::pubkey::new_rand();
let (genesis_config, mint_keypair) = create_genesis_config(sol_to_lamports(1.));
let bank = Bank::new_for_tests(&genesis_config);
bank.transfer(
genesis_config.rent.minimum_balance(0),
&mint_keypair,
&pubkey,
)
.unwrap();
bank.freeze();
add_root_and_flush_write_cache(&bank);
bank.update_accounts_hash_for_tests();
assert!(bank.verify_snapshot_bank(true, false, bank.slot(), None));
// tamper the bank after freeze!
bank.increment_signature_count(1);
assert!(!bank.verify_snapshot_bank(true, false, bank.slot(), None));
}
// Test that two bank forks with the same accounts should not hash to the same value.
#[test]
fn test_bank_hash_internal_state_same_account_different_fork() {
solana_logger::setup();
let (genesis_config, mint_keypair) = create_genesis_config(sol_to_lamports(1.));
let amount = genesis_config.rent.minimum_balance(0);
let bank0 = Arc::new(Bank::new_for_tests(&genesis_config));
let initial_state = bank0.hash_internal_state();
let bank1 = Bank::new_from_parent(&bank0, &Pubkey::default(), 1);
assert_ne!(bank1.hash_internal_state(), initial_state);
info!("transfer bank1");
let pubkey = solana_sdk::pubkey::new_rand();
bank1.transfer(amount, &mint_keypair, &pubkey).unwrap();
assert_ne!(bank1.hash_internal_state(), initial_state);
info!("transfer bank2");
// bank2 should not hash the same as bank1
let bank2 = Bank::new_from_parent(&bank0, &Pubkey::default(), 2);
bank2.transfer(amount, &mint_keypair, &pubkey).unwrap();
assert_ne!(bank2.hash_internal_state(), initial_state);
assert_ne!(bank1.hash_internal_state(), bank2.hash_internal_state());
}
#[test]
fn test_hash_internal_state_genesis() {
let bank0 = Bank::new_for_tests(&create_genesis_config(10).0);
let bank1 = Bank::new_for_tests(&create_genesis_config(20).0);
assert_ne!(bank0.hash_internal_state(), bank1.hash_internal_state());
}
// See that the order of two transfers does not affect the result
// of hash_internal_state
#[test]
fn test_hash_internal_state_order() {
let (genesis_config, mint_keypair) = create_genesis_config(sol_to_lamports(1.));
let amount = genesis_config.rent.minimum_balance(0);
let bank0 = Bank::new_for_tests(&genesis_config);
let bank1 = Bank::new_for_tests(&genesis_config);
assert_eq!(bank0.hash_internal_state(), bank1.hash_internal_state());
let key0 = solana_sdk::pubkey::new_rand();
let key1 = solana_sdk::pubkey::new_rand();
bank0.transfer(amount, &mint_keypair, &key0).unwrap();
bank0.transfer(amount * 2, &mint_keypair, &key1).unwrap();
bank1.transfer(amount * 2, &mint_keypair, &key1).unwrap();
bank1.transfer(amount, &mint_keypair, &key0).unwrap();
assert_eq!(bank0.hash_internal_state(), bank1.hash_internal_state());
}
#[test]
fn test_hash_internal_state_error() {
solana_logger::setup();
let (genesis_config, mint_keypair) = create_genesis_config(sol_to_lamports(1.));
let amount = genesis_config.rent.minimum_balance(0);
let bank = Bank::new_for_tests(&genesis_config);
let key0 = solana_sdk::pubkey::new_rand();
bank.transfer(amount, &mint_keypair, &key0).unwrap();
let orig = bank.hash_internal_state();
// Transfer will error but still take a fee
assert!(bank
.transfer(sol_to_lamports(1.), &mint_keypair, &key0)
.is_err());
assert_ne!(orig, bank.hash_internal_state());
let orig = bank.hash_internal_state();
let empty_keypair = Keypair::new();
assert!(bank.transfer(amount, &empty_keypair, &key0).is_err());
assert_eq!(orig, bank.hash_internal_state());
}
#[test]
fn test_bank_hash_internal_state_squash() {
let collector_id = Pubkey::default();
let bank0 = Arc::new(Bank::new_for_tests(&create_genesis_config(10).0));
let hash0 = bank0.hash_internal_state();
// save hash0 because new_from_parent
// updates sysvar entries
let bank1 = Bank::new_from_parent(&bank0, &collector_id, 1);
// no delta in bank1, hashes should always update
assert_ne!(hash0, bank1.hash_internal_state());
// remove parent
bank1.squash();
assert!(bank1.parents().is_empty());
}
/// Verifies that last ids and accounts are correctly referenced from parent
#[test]
fn test_bank_squash() {
solana_logger::setup();
let (genesis_config, mint_keypair) = create_genesis_config(sol_to_lamports(2.));
let key1 = Keypair::new();
let key2 = Keypair::new();
let parent = Arc::new(Bank::new_for_tests(&genesis_config));
let amount = genesis_config.rent.minimum_balance(0);
let tx_transfer_mint_to_1 =
system_transaction::transfer(&mint_keypair, &key1.pubkey(), amount, genesis_config.hash());
trace!("parent process tx ");
assert_eq!(parent.process_transaction(&tx_transfer_mint_to_1), Ok(()));
trace!("done parent process tx ");
assert_eq!(parent.transaction_count(), 1);
assert_eq!(parent.non_vote_transaction_count_since_restart(), 1);
assert_eq!(
parent.get_signature_status(&tx_transfer_mint_to_1.signatures[0]),
Some(Ok(()))
);
trace!("new from parent");
let bank = new_from_parent(&parent);
trace!("done new from parent");
assert_eq!(
bank.get_signature_status(&tx_transfer_mint_to_1.signatures[0]),
Some(Ok(()))
);
assert_eq!(bank.transaction_count(), parent.transaction_count());
assert_eq!(
bank.non_vote_transaction_count_since_restart(),
parent.non_vote_transaction_count_since_restart()
);
let tx_transfer_1_to_2 =
system_transaction::transfer(&key1, &key2.pubkey(), amount, genesis_config.hash());
assert_eq!(bank.process_transaction(&tx_transfer_1_to_2), Ok(()));
assert_eq!(bank.transaction_count(), 2);
assert_eq!(bank.non_vote_transaction_count_since_restart(), 2);
assert_eq!(parent.transaction_count(), 1);
assert_eq!(parent.non_vote_transaction_count_since_restart(), 1);
assert_eq!(
parent.get_signature_status(&tx_transfer_1_to_2.signatures[0]),
None
);
for _ in 0..3 {
// first time these should match what happened above, assert that parents are ok
assert_eq!(bank.get_balance(&key1.pubkey()), 0);
assert_eq!(bank.get_account(&key1.pubkey()), None);
assert_eq!(bank.get_balance(&key2.pubkey()), amount);
trace!("start");
assert_eq!(
bank.get_signature_status(&tx_transfer_mint_to_1.signatures[0]),
Some(Ok(()))
);
assert_eq!(
bank.get_signature_status(&tx_transfer_1_to_2.signatures[0]),
Some(Ok(()))
);
// works iteration 0, no-ops on iteration 1 and 2
trace!("SQUASH");
bank.squash();
assert_eq!(parent.transaction_count(), 1);
assert_eq!(parent.non_vote_transaction_count_since_restart(), 1);
assert_eq!(bank.transaction_count(), 2);
assert_eq!(bank.non_vote_transaction_count_since_restart(), 2);
}
}
#[test]
fn test_bank_get_account_in_parent_after_squash() {
let (genesis_config, mint_keypair) = create_genesis_config(sol_to_lamports(1.));
let parent = Arc::new(Bank::new_for_tests(&genesis_config));
let amount = genesis_config.rent.minimum_balance(0);
let key1 = Keypair::new();
parent
.transfer(amount, &mint_keypair, &key1.pubkey())
.unwrap();
assert_eq!(parent.get_balance(&key1.pubkey()), amount);
let bank = new_from_parent(&parent);
bank.squash();
assert_eq!(parent.get_balance(&key1.pubkey()), amount);
}
#[test]
fn test_bank_get_account_in_parent_after_squash2() {
solana_logger::setup();
let (genesis_config, mint_keypair) = create_genesis_config(sol_to_lamports(1.));
let bank0 = Arc::new(Bank::new_for_tests(&genesis_config));
let amount = genesis_config.rent.minimum_balance(0);
let key1 = Keypair::new();
bank0
.transfer(amount, &mint_keypair, &key1.pubkey())
.unwrap();
assert_eq!(bank0.get_balance(&key1.pubkey()), amount);
let bank1 = Arc::new(Bank::new_from_parent(&bank0, &Pubkey::default(), 1));
bank1
.transfer(3 * amount, &mint_keypair, &key1.pubkey())
.unwrap();
let bank2 = Arc::new(Bank::new_from_parent(&bank0, &Pubkey::default(), 2));
bank2
.transfer(2 * amount, &mint_keypair, &key1.pubkey())
.unwrap();
let bank3 = Arc::new(Bank::new_from_parent(&bank1, &Pubkey::default(), 3));
bank1.squash();
// This picks up the values from 1 which is the highest root:
// TODO: if we need to access rooted banks older than this,
// need to fix the lookup.
assert_eq!(bank0.get_balance(&key1.pubkey()), 4 * amount);
assert_eq!(bank3.get_balance(&key1.pubkey()), 4 * amount);
assert_eq!(bank2.get_balance(&key1.pubkey()), 3 * amount);
bank3.squash();
assert_eq!(bank1.get_balance(&key1.pubkey()), 4 * amount);
let bank4 = Arc::new(Bank::new_from_parent(&bank3, &Pubkey::default(), 4));
bank4
.transfer(4 * amount, &mint_keypair, &key1.pubkey())
.unwrap();
assert_eq!(bank4.get_balance(&key1.pubkey()), 8 * amount);
assert_eq!(bank3.get_balance(&key1.pubkey()), 4 * amount);
bank4.squash();
let bank5 = Arc::new(Bank::new_from_parent(&bank4, &Pubkey::default(), 5));
bank5.squash();
let bank6 = Arc::new(Bank::new_from_parent(&bank5, &Pubkey::default(), 6));
bank6.squash();
// This picks up the values from 4 which is the highest root:
// TODO: if we need to access rooted banks older than this,
// need to fix the lookup.
assert_eq!(bank3.get_balance(&key1.pubkey()), 8 * amount);
assert_eq!(bank2.get_balance(&key1.pubkey()), 8 * amount);
assert_eq!(bank4.get_balance(&key1.pubkey()), 8 * amount);
}
#[test]
fn test_bank_get_account_modified_since_parent_with_fixed_root() {
let pubkey = solana_sdk::pubkey::new_rand();
let (genesis_config, mint_keypair) = create_genesis_config(sol_to_lamports(1.));
let amount = genesis_config.rent.minimum_balance(0);
let bank1 = Arc::new(Bank::new_for_tests(&genesis_config));
bank1.transfer(amount, &mint_keypair, &pubkey).unwrap();
let result = bank1.get_account_modified_since_parent_with_fixed_root(&pubkey);
assert!(result.is_some());
let (account, slot) = result.unwrap();
assert_eq!(account.lamports(), amount);
assert_eq!(slot, 0);
let bank2 = Arc::new(Bank::new_from_parent(&bank1, &Pubkey::default(), 1));
assert!(bank2
.get_account_modified_since_parent_with_fixed_root(&pubkey)
.is_none());
bank2.transfer(2 * amount, &mint_keypair, &pubkey).unwrap();
let result = bank1.get_account_modified_since_parent_with_fixed_root(&pubkey);
assert!(result.is_some());
let (account, slot) = result.unwrap();
assert_eq!(account.lamports(), amount);
assert_eq!(slot, 0);
let result = bank2.get_account_modified_since_parent_with_fixed_root(&pubkey);
assert!(result.is_some());
let (account, slot) = result.unwrap();
assert_eq!(account.lamports(), 3 * amount);
assert_eq!(slot, 1);
bank1.squash();
let bank3 = Bank::new_from_parent(&bank2, &Pubkey::default(), 3);
assert_eq!(
None,
bank3.get_account_modified_since_parent_with_fixed_root(&pubkey)
);
}
#[test]
fn test_bank_update_sysvar_account() {
solana_logger::setup();
// flushing the write cache is destructive, so test has to restart each time we flush and want to do 'illegal' operations once flushed
for pass in 0..5 {
use sysvar::clock::Clock;
let dummy_clock_id = solana_sdk::pubkey::new_rand();
let dummy_rent_epoch = 44;
let (mut genesis_config, _mint_keypair) = create_genesis_config(500);
let expected_previous_slot = 3;
let mut expected_next_slot = expected_previous_slot + 1;
// First, initialize the clock sysvar
for feature_id in FeatureSet::default().inactive {
activate_feature(&mut genesis_config, feature_id);
}
let bank1 = Arc::new(Bank::new_for_tests_with_config(
&genesis_config,
BankTestConfig::default(),
));
if pass == 0 {
add_root_and_flush_write_cache(&bank1);
assert_eq!(bank1.calculate_capitalization(true), bank1.capitalization());
continue;
}
assert_capitalization_diff(
&bank1,
|| {
bank1.update_sysvar_account(&dummy_clock_id, |optional_account| {
assert!(optional_account.is_none());
let mut account = create_account(
&Clock {
slot: expected_previous_slot,
..Clock::default()
},
bank1.inherit_specially_retained_account_fields(optional_account),
);
account.set_rent_epoch(dummy_rent_epoch);
account
});
let current_account = bank1.get_account(&dummy_clock_id).unwrap();
assert_eq!(
expected_previous_slot,
from_account::<Clock, _>(&current_account).unwrap().slot
);
assert_eq!(dummy_rent_epoch, current_account.rent_epoch());
},
|old, new| {
assert_eq!(
old + min_rent_exempt_balance_for_sysvars(&bank1, &[sysvar::clock::id()]),
new
);
pass == 1
},
);
if pass == 1 {
continue;
}
assert_capitalization_diff(
&bank1,
|| {
bank1.update_sysvar_account(&dummy_clock_id, |optional_account| {
assert!(optional_account.is_some());
create_account(
&Clock {
slot: expected_previous_slot,
..Clock::default()
},
bank1.inherit_specially_retained_account_fields(optional_account),
)
})
},
|old, new| {
// creating new sysvar twice in a slot shouldn't increment capitalization twice
assert_eq!(old, new);
pass == 2
},
);
if pass == 2 {
continue;
}
// Updating should increment the clock's slot
let bank2 = Arc::new(Bank::new_from_parent(&bank1, &Pubkey::default(), 1));
add_root_and_flush_write_cache(&bank1);
assert_capitalization_diff(
&bank2,
|| {
bank2.update_sysvar_account(&dummy_clock_id, |optional_account| {
let slot = from_account::<Clock, _>(optional_account.as_ref().unwrap())
.unwrap()
.slot
+ 1;
create_account(
&Clock {
slot,
..Clock::default()
},
bank2.inherit_specially_retained_account_fields(optional_account),
)
});
let current_account = bank2.get_account(&dummy_clock_id).unwrap();
assert_eq!(
expected_next_slot,
from_account::<Clock, _>(&current_account).unwrap().slot
);
assert_eq!(dummy_rent_epoch, current_account.rent_epoch());
},
|old, new| {
// if existing, capitalization shouldn't change
assert_eq!(old, new);
pass == 3
},
);
if pass == 3 {
continue;
}
// Updating again should give bank2's sysvar to the closure not bank1's.
// Thus, increment expected_next_slot accordingly
expected_next_slot += 1;
assert_capitalization_diff(
&bank2,
|| {
bank2.update_sysvar_account(&dummy_clock_id, |optional_account| {
let slot = from_account::<Clock, _>(optional_account.as_ref().unwrap())
.unwrap()
.slot
+ 1;
create_account(
&Clock {
slot,
..Clock::default()
},
bank2.inherit_specially_retained_account_fields(optional_account),
)
});
let current_account = bank2.get_account(&dummy_clock_id).unwrap();
assert_eq!(
expected_next_slot,
from_account::<Clock, _>(&current_account).unwrap().slot
);
},
|old, new| {
// updating twice in a slot shouldn't increment capitalization twice
assert_eq!(old, new);
true
},
);
}
}
#[test]
fn test_bank_epoch_vote_accounts() {
let leader_pubkey = solana_sdk::pubkey::new_rand();
let leader_lamports = 3;
let mut genesis_config =
create_genesis_config_with_leader(5, &leader_pubkey, leader_lamports).genesis_config;
// set this up weird, forces future generation, odd mod(), etc.
// this says: "vote_accounts for epoch X should be generated at slot index 3 in epoch X-2...
const SLOTS_PER_EPOCH: u64 = MINIMUM_SLOTS_PER_EPOCH;
const LEADER_SCHEDULE_SLOT_OFFSET: u64 = SLOTS_PER_EPOCH * 3 - 3;
// no warmup allows me to do the normal division stuff below
genesis_config.epoch_schedule =
EpochSchedule::custom(SLOTS_PER_EPOCH, LEADER_SCHEDULE_SLOT_OFFSET, false);
let parent = Arc::new(Bank::new_for_tests(&genesis_config));
let mut leader_vote_stake: Vec<_> = parent
.epoch_vote_accounts(0)
.map(|accounts| {
accounts
.iter()
.filter_map(|(pubkey, (stake, account))| {
if let Ok(vote_state) = account.vote_state().as_ref() {
if vote_state.node_pubkey == leader_pubkey {
Some((*pubkey, *stake))
} else {
None
}
} else {
None
}
})
.collect()
})
.unwrap();
assert_eq!(leader_vote_stake.len(), 1);
let (leader_vote_account, leader_stake) = leader_vote_stake.pop().unwrap();
assert!(leader_stake > 0);
let leader_stake = Stake {
delegation: Delegation {
stake: leader_lamports,
activation_epoch: std::u64::MAX, // bootstrap
..Delegation::default()
},
..Stake::default()
};
let mut epoch = 1;
loop {
if epoch > LEADER_SCHEDULE_SLOT_OFFSET / SLOTS_PER_EPOCH {
break;
}
let vote_accounts = parent.epoch_vote_accounts(epoch);
assert!(vote_accounts.is_some());
// epoch_stakes are a snapshot at the leader_schedule_slot_offset boundary
// in the prior epoch (0 in this case)
assert_eq!(
leader_stake.stake(0, None),
vote_accounts.unwrap().get(&leader_vote_account).unwrap().0
);
epoch += 1;
}
// child crosses epoch boundary and is the first slot in the epoch
let child = Bank::new_from_parent(
&parent,
&leader_pubkey,
SLOTS_PER_EPOCH - (LEADER_SCHEDULE_SLOT_OFFSET % SLOTS_PER_EPOCH),
);
assert!(child.epoch_vote_accounts(epoch).is_some());
assert_eq!(
leader_stake.stake(child.epoch(), None),
child
.epoch_vote_accounts(epoch)
.unwrap()
.get(&leader_vote_account)
.unwrap()
.0
);
// child crosses epoch boundary but isn't the first slot in the epoch, still
// makes an epoch stakes snapshot at 1
let child = Bank::new_from_parent(
&parent,
&leader_pubkey,
SLOTS_PER_EPOCH - (LEADER_SCHEDULE_SLOT_OFFSET % SLOTS_PER_EPOCH) + 1,
);
assert!(child.epoch_vote_accounts(epoch).is_some());
assert_eq!(
leader_stake.stake(child.epoch(), None),
child
.epoch_vote_accounts(epoch)
.unwrap()
.get(&leader_vote_account)
.unwrap()
.0
);
}
#[test]
fn test_zero_signatures() {
solana_logger::setup();
let (genesis_config, mint_keypair) = create_genesis_config(500);
let mut bank = Bank::new_for_tests(&genesis_config);
bank.fee_rate_governor.lamports_per_signature = 2;
let key = solana_sdk::pubkey::new_rand();
let mut transfer_instruction = system_instruction::transfer(&mint_keypair.pubkey(), &key, 0);
transfer_instruction.accounts[0].is_signer = false;
let message = Message::new(&[transfer_instruction], None);
let tx = Transaction::new(&[&Keypair::new(); 0], message, bank.last_blockhash());
assert_eq!(
bank.process_transaction(&tx),
Err(TransactionError::SanitizeFailure)
);
assert_eq!(bank.get_balance(&key), 0);
}
#[test]
fn test_bank_get_slots_in_epoch() {
let (genesis_config, _) = create_genesis_config(500);
let bank = Bank::new_for_tests(&genesis_config);
assert_eq!(bank.get_slots_in_epoch(0), MINIMUM_SLOTS_PER_EPOCH);
assert_eq!(bank.get_slots_in_epoch(2), (MINIMUM_SLOTS_PER_EPOCH * 4));
assert_eq!(
bank.get_slots_in_epoch(5000),
genesis_config.epoch_schedule.slots_per_epoch
);
}
#[test]
fn test_is_delta_true() {
let (genesis_config, mint_keypair) = create_genesis_config(sol_to_lamports(1.0));
let bank = Arc::new(Bank::new_for_tests(&genesis_config));
let key1 = Keypair::new();
let tx_transfer_mint_to_1 = system_transaction::transfer(
&mint_keypair,
&key1.pubkey(),
genesis_config.rent.minimum_balance(0),
genesis_config.hash(),
);
assert_eq!(bank.process_transaction(&tx_transfer_mint_to_1), Ok(()));
assert!(bank.is_delta.load(Relaxed));
let bank1 = new_from_parent(&bank);
let hash1 = bank1.hash_internal_state();
assert!(!bank1.is_delta.load(Relaxed));
assert_ne!(hash1, bank.hash());
// ticks don't make a bank into a delta or change its state unless a block boundary is crossed
bank1.register_tick(&Hash::default());
assert!(!bank1.is_delta.load(Relaxed));
assert_eq!(bank1.hash_internal_state(), hash1);
}
#[test]
fn test_is_empty() {
let (genesis_config, mint_keypair) = create_genesis_config(sol_to_lamports(1.0));
let bank0 = Arc::new(Bank::new_for_tests(&genesis_config));
let key1 = Keypair::new();
// The zeroth bank is empty becasue there are no transactions
assert!(bank0.is_empty());
// Set is_delta to true, bank is no longer empty
let tx_transfer_mint_to_1 = system_transaction::transfer(
&mint_keypair,
&key1.pubkey(),
genesis_config.rent.minimum_balance(0),
genesis_config.hash(),
);
assert_eq!(bank0.process_transaction(&tx_transfer_mint_to_1), Ok(()));
assert!(!bank0.is_empty());
}
#[test]
fn test_bank_inherit_tx_count() {
let (genesis_config, mint_keypair) = create_genesis_config(sol_to_lamports(1.0));
let bank0 = Arc::new(Bank::new_for_tests(&genesis_config));
// Bank 1
let bank1 = Arc::new(Bank::new_from_parent(
&bank0,
&solana_sdk::pubkey::new_rand(),
1,
));
// Bank 2
let bank2 = Bank::new_from_parent(&bank0, &solana_sdk::pubkey::new_rand(), 2);
// transfer a token
assert_eq!(
bank1.process_transaction(&system_transaction::transfer(
&mint_keypair,
&Keypair::new().pubkey(),
genesis_config.rent.minimum_balance(0),
genesis_config.hash(),
)),
Ok(())
);
assert_eq!(bank0.transaction_count(), 0);
assert_eq!(bank0.non_vote_transaction_count_since_restart(), 0);
assert_eq!(bank2.transaction_count(), 0);
assert_eq!(bank2.non_vote_transaction_count_since_restart(), 0);
assert_eq!(bank1.transaction_count(), 1);
assert_eq!(bank1.non_vote_transaction_count_since_restart(), 1);
bank1.squash();
assert_eq!(bank0.transaction_count(), 0);
assert_eq!(bank0.non_vote_transaction_count_since_restart(), 0);
assert_eq!(bank2.transaction_count(), 0);
assert_eq!(bank2.non_vote_transaction_count_since_restart(), 0);
assert_eq!(bank1.transaction_count(), 1);
assert_eq!(bank1.non_vote_transaction_count_since_restart(), 1);
let bank6 = Bank::new_from_parent(&bank1, &solana_sdk::pubkey::new_rand(), 3);
assert_eq!(bank1.transaction_count(), 1);
assert_eq!(bank1.non_vote_transaction_count_since_restart(), 1);
assert_eq!(bank6.transaction_count(), 1);
assert_eq!(bank6.non_vote_transaction_count_since_restart(), 1);
bank6.squash();
assert_eq!(bank6.transaction_count(), 1);
assert_eq!(bank6.non_vote_transaction_count_since_restart(), 1);
}
#[test]
fn test_bank_inherit_fee_rate_governor() {
let (mut genesis_config, _mint_keypair) = create_genesis_config(500);
genesis_config
.fee_rate_governor
.target_lamports_per_signature = 123;
let bank0 = Arc::new(Bank::new_for_tests(&genesis_config));
let bank1 = Arc::new(new_from_parent(&bank0));
assert_eq!(
bank0.fee_rate_governor.target_lamports_per_signature / 2,
bank1
.fee_rate_governor
.create_fee_calculator()
.lamports_per_signature
);
}
#[test]
fn test_bank_vote_accounts() {
let GenesisConfigInfo {
genesis_config,
mint_keypair,
..
} = create_genesis_config_with_leader(500, &solana_sdk::pubkey::new_rand(), 1);
let bank = Arc::new(Bank::new_for_tests(&genesis_config));
let vote_accounts = bank.vote_accounts();
assert_eq!(vote_accounts.len(), 1); // bootstrap validator has
// to have a vote account
let vote_keypair = Keypair::new();
let instructions = vote_instruction::create_account_with_config(
&mint_keypair.pubkey(),
&vote_keypair.pubkey(),
&VoteInit {
node_pubkey: mint_keypair.pubkey(),
authorized_voter: vote_keypair.pubkey(),
authorized_withdrawer: vote_keypair.pubkey(),
commission: 0,
},
10,
vote_instruction::CreateVoteAccountConfig {
space: VoteStateVersions::vote_state_size_of(true) as u64,
..vote_instruction::CreateVoteAccountConfig::default()
},
);
let message = Message::new(&instructions, Some(&mint_keypair.pubkey()));
let transaction = Transaction::new(
&[&mint_keypair, &vote_keypair],
message,
bank.last_blockhash(),
);
bank.process_transaction(&transaction).unwrap();
let vote_accounts = bank.vote_accounts();
assert_eq!(vote_accounts.len(), 2);
assert!(vote_accounts.get(&vote_keypair.pubkey()).is_some());
assert!(bank.withdraw(&vote_keypair.pubkey(), 10).is_ok());
let vote_accounts = bank.vote_accounts();
assert_eq!(vote_accounts.len(), 1);
}
#[test]
fn test_bank_cloned_stake_delegations() {
let GenesisConfigInfo {
mut genesis_config,
mint_keypair,
..
} = create_genesis_config_with_leader(
123_456_000_000_000,
&solana_sdk::pubkey::new_rand(),
123_000_000_000,
);
genesis_config.rent = Rent::default();
let bank = Arc::new(Bank::new_for_tests(&genesis_config));
let stake_delegations = bank.stakes_cache.stakes().stake_delegations().clone();
assert_eq!(stake_delegations.len(), 1); // bootstrap validator has
// to have a stake delegation
let (vote_balance, stake_balance) = {
let rent = &bank.rent_collector().rent;
let vote_rent_exempt_reserve = rent.minimum_balance(VoteState::size_of());
let stake_rent_exempt_reserve = rent.minimum_balance(StakeState::size_of());
let minimum_delegation = solana_stake_program::get_minimum_delegation(&bank.feature_set);
(
vote_rent_exempt_reserve,
stake_rent_exempt_reserve + minimum_delegation,
)
};
let vote_keypair = Keypair::new();
let mut instructions = vote_instruction::create_account_with_config(
&mint_keypair.pubkey(),
&vote_keypair.pubkey(),
&VoteInit {
node_pubkey: mint_keypair.pubkey(),
authorized_voter: vote_keypair.pubkey(),
authorized_withdrawer: vote_keypair.pubkey(),
commission: 0,
},
vote_balance,
vote_instruction::CreateVoteAccountConfig {
space: VoteStateVersions::vote_state_size_of(true) as u64,
..vote_instruction::CreateVoteAccountConfig::default()
},
);
let stake_keypair = Keypair::new();
instructions.extend(stake_instruction::create_account_and_delegate_stake(
&mint_keypair.pubkey(),
&stake_keypair.pubkey(),
&vote_keypair.pubkey(),
&Authorized::auto(&stake_keypair.pubkey()),
&Lockup::default(),
stake_balance,
));
let message = Message::new(&instructions, Some(&mint_keypair.pubkey()));
let transaction = Transaction::new(
&[&mint_keypair, &vote_keypair, &stake_keypair],
message,
bank.last_blockhash(),
);
bank.process_transaction(&transaction).unwrap();
let stake_delegations = bank.stakes_cache.stakes().stake_delegations().clone();
assert_eq!(stake_delegations.len(), 2);
assert!(stake_delegations.get(&stake_keypair.pubkey()).is_some());
}
#[allow(deprecated)]
#[test]
fn test_bank_fees_account() {
let (mut genesis_config, _) = create_genesis_config(500);
genesis_config.fee_rate_governor = FeeRateGovernor::new(12345, 0);
let bank = Arc::new(Bank::new_for_tests(&genesis_config));
let fees_account = bank.get_account(&sysvar::fees::id()).unwrap();
let fees = from_account::<Fees, _>(&fees_account).unwrap();
assert_eq!(
bank.fee_rate_governor.lamports_per_signature,
fees.fee_calculator.lamports_per_signature
);
assert_eq!(fees.fee_calculator.lamports_per_signature, 12345);
}
#[test]
fn test_is_delta_with_no_committables() {
let (genesis_config, mint_keypair) = create_genesis_config(8000);
let bank = Bank::new_for_tests(&genesis_config);
bank.is_delta.store(false, Relaxed);
let keypair1 = Keypair::new();
let keypair2 = Keypair::new();
let fail_tx =
system_transaction::transfer(&keypair1, &keypair2.pubkey(), 1, bank.last_blockhash());
// Should fail with TransactionError::AccountNotFound, which means
// the account which this tx operated on will not be committed. Thus
// the bank is_delta should still be false
assert_eq!(
bank.process_transaction(&fail_tx),
Err(TransactionError::AccountNotFound)
);
// Check the bank is_delta is still false
assert!(!bank.is_delta.load(Relaxed));
// Should fail with InstructionError, but InstructionErrors are committable,
// so is_delta should be true
assert_eq!(
bank.transfer(10_001, &mint_keypair, &solana_sdk::pubkey::new_rand()),
Err(TransactionError::InstructionError(
0,
SystemError::ResultWithNegativeLamports.into(),
))
);
assert!(bank.is_delta.load(Relaxed));
}
#[test]
fn test_bank_get_program_accounts() {
let (genesis_config, mint_keypair) = create_genesis_config(500);
let parent = Arc::new(Bank::new_for_tests(&genesis_config));
parent.restore_old_behavior_for_fragile_tests();
let genesis_accounts: Vec<_> = parent.get_all_accounts_with_modified_slots().unwrap();
assert!(
genesis_accounts
.iter()
.any(|(pubkey, _, _)| *pubkey == mint_keypair.pubkey()),
"mint pubkey not found"
);
assert!(
genesis_accounts
.iter()
.any(|(pubkey, _, _)| solana_sdk::sysvar::is_sysvar_id(pubkey)),
"no sysvars found"
);
let bank0 = Arc::new(new_from_parent(&parent));
let pubkey0 = solana_sdk::pubkey::new_rand();
let program_id = Pubkey::from([2; 32]);
let account0 = AccountSharedData::new(1, 0, &program_id);
bank0.store_account(&pubkey0, &account0);
assert_eq!(
bank0.get_program_accounts_modified_since_parent(&program_id),
vec![(pubkey0, account0.clone())]
);
let bank1 = Arc::new(new_from_parent(&bank0));
bank1.squash();
assert_eq!(
bank0
.get_program_accounts(&program_id, &ScanConfig::default(),)
.unwrap(),
vec![(pubkey0, account0.clone())]
);
assert_eq!(
bank1
.get_program_accounts(&program_id, &ScanConfig::default(),)
.unwrap(),
vec![(pubkey0, account0)]
);
assert_eq!(
bank1.get_program_accounts_modified_since_parent(&program_id),
vec![]
);
let bank2 = Arc::new(new_from_parent(&bank1));
let pubkey1 = solana_sdk::pubkey::new_rand();
let account1 = AccountSharedData::new(3, 0, &program_id);
bank2.store_account(&pubkey1, &account1);
// Accounts with 0 lamports should be filtered out by Accounts::load_by_program()
let pubkey2 = solana_sdk::pubkey::new_rand();
let account2 = AccountSharedData::new(0, 0, &program_id);
bank2.store_account(&pubkey2, &account2);
let bank3 = Arc::new(new_from_parent(&bank2));
bank3.squash();
assert_eq!(
bank1
.get_program_accounts(&program_id, &ScanConfig::default(),)
.unwrap()
.len(),
2
);
assert_eq!(
bank3
.get_program_accounts(&program_id, &ScanConfig::default(),)
.unwrap()
.len(),
2
);
}
#[test]
fn test_get_filtered_indexed_accounts_limit_exceeded() {
let (genesis_config, _mint_keypair) = create_genesis_config(500);
let mut account_indexes = AccountSecondaryIndexes::default();
account_indexes.indexes.insert(AccountIndex::ProgramId);
let bank = Arc::new(Bank::new_with_config_for_tests(
&genesis_config,
account_indexes,
AccountShrinkThreshold::default(),
));
let address = Pubkey::new_unique();
let program_id = Pubkey::new_unique();
let limit = 100;
let account = AccountSharedData::new(1, limit, &program_id);
bank.store_account(&address, &account);
assert!(bank
.get_filtered_indexed_accounts(
&IndexKey::ProgramId(program_id),
|_| true,
&ScanConfig::default(),
Some(limit), // limit here will be exceeded, resulting in aborted scan
)
.is_err());
}
#[test]
fn test_get_filtered_indexed_accounts() {
let (genesis_config, _mint_keypair) = create_genesis_config(500);
let mut account_indexes = AccountSecondaryIndexes::default();
account_indexes.indexes.insert(AccountIndex::ProgramId);
let bank = Arc::new(Bank::new_with_config_for_tests(
&genesis_config,
account_indexes,
AccountShrinkThreshold::default(),
));
let address = Pubkey::new_unique();
let program_id = Pubkey::new_unique();
let account = AccountSharedData::new(1, 0, &program_id);
bank.store_account(&address, &account);
let indexed_accounts = bank
.get_filtered_indexed_accounts(
&IndexKey::ProgramId(program_id),
|_| true,
&ScanConfig::default(),
None,
)
.unwrap();
assert_eq!(indexed_accounts.len(), 1);
assert_eq!(indexed_accounts[0], (address, account));
// Even though the account is re-stored in the bank (and the index) under a new program id,
// it is still present in the index under the original program id as well. This
// demonstrates the need for a redundant post-processing filter.
let another_program_id = Pubkey::new_unique();
let new_account = AccountSharedData::new(1, 0, &another_program_id);
let bank = Arc::new(new_from_parent(&bank));
bank.store_account(&address, &new_account);
let indexed_accounts = bank
.get_filtered_indexed_accounts(
&IndexKey::ProgramId(program_id),
|_| true,
&ScanConfig::default(),
None,
)
.unwrap();
assert_eq!(indexed_accounts.len(), 1);
assert_eq!(indexed_accounts[0], (address, new_account.clone()));
let indexed_accounts = bank
.get_filtered_indexed_accounts(
&IndexKey::ProgramId(another_program_id),
|_| true,
&ScanConfig::default(),
None,
)
.unwrap();
assert_eq!(indexed_accounts.len(), 1);
assert_eq!(indexed_accounts[0], (address, new_account.clone()));
// Post-processing filter
let indexed_accounts = bank
.get_filtered_indexed_accounts(
&IndexKey::ProgramId(program_id),
|account| account.owner() == &program_id,
&ScanConfig::default(),
None,
)
.unwrap();
assert!(indexed_accounts.is_empty());
let indexed_accounts = bank
.get_filtered_indexed_accounts(
&IndexKey::ProgramId(another_program_id),
|account| account.owner() == &another_program_id,
&ScanConfig::default(),
None,
)
.unwrap();
assert_eq!(indexed_accounts.len(), 1);
assert_eq!(indexed_accounts[0], (address, new_account));
}
#[test]
fn test_status_cache_ancestors() {
solana_logger::setup();
let parent = create_simple_test_arc_bank(500);
let bank1 = Arc::new(new_from_parent(&parent));
let mut bank = bank1;
for _ in 0..MAX_CACHE_ENTRIES * 2 {
bank = Arc::new(new_from_parent(&bank));
bank.squash();
}
let bank = new_from_parent(&bank);
assert_eq!(
bank.status_cache_ancestors(),
(bank.slot() - MAX_CACHE_ENTRIES as u64..=bank.slot()).collect::<Vec<_>>()
);
}
#[test]
fn test_add_builtin() {
let (genesis_config, mint_keypair) = create_genesis_config(500);
let mut bank = Bank::new_for_tests(&genesis_config);
fn mock_vote_program_id() -> Pubkey {
Pubkey::from([42u8; 32])
}
declare_process_instruction!(process_instruction, 1, |invoke_context| {
let transaction_context = &invoke_context.transaction_context;
let instruction_context = transaction_context.get_current_instruction_context()?;
let program_id = instruction_context.get_last_program_key(transaction_context)?;
if mock_vote_program_id() != *program_id {
return Err(InstructionError::IncorrectProgramId);
}
Err(InstructionError::Custom(42))
});
assert!(bank.get_account(&mock_vote_program_id()).is_none());
bank.add_mockup_builtin(mock_vote_program_id(), process_instruction);
assert!(bank.get_account(&mock_vote_program_id()).is_some());
let mock_account = Keypair::new();
let mock_validator_identity = Keypair::new();
let mut instructions = vote_instruction::create_account_with_config(
&mint_keypair.pubkey(),
&mock_account.pubkey(),
&VoteInit {
node_pubkey: mock_validator_identity.pubkey(),
..VoteInit::default()
},
1,
vote_instruction::CreateVoteAccountConfig {
space: VoteStateVersions::vote_state_size_of(true) as u64,
..vote_instruction::CreateVoteAccountConfig::default()
},
);
instructions[1].program_id = mock_vote_program_id();
let message = Message::new(&instructions, Some(&mint_keypair.pubkey()));
let transaction = Transaction::new(
&[&mint_keypair, &mock_account, &mock_validator_identity],
message,
bank.last_blockhash(),
);
assert_eq!(
bank.process_transaction(&transaction),
Err(TransactionError::InstructionError(
1,
InstructionError::Custom(42)
))
);
}
#[test]
fn test_add_duplicate_static_program() {
let GenesisConfigInfo {
genesis_config,
mint_keypair,
..
} = create_genesis_config_with_leader(500, &solana_sdk::pubkey::new_rand(), 0);
let mut bank = Bank::new_for_tests(&genesis_config);
declare_process_instruction!(process_instruction, 1, |_invoke_context| {
Err(InstructionError::Custom(42))
});
let mock_account = Keypair::new();
let mock_validator_identity = Keypair::new();
let instructions = vote_instruction::create_account_with_config(
&mint_keypair.pubkey(),
&mock_account.pubkey(),
&VoteInit {
node_pubkey: mock_validator_identity.pubkey(),
..VoteInit::default()
},
1,
vote_instruction::CreateVoteAccountConfig {
space: VoteStateVersions::vote_state_size_of(true) as u64,
..vote_instruction::CreateVoteAccountConfig::default()
},
);
let message = Message::new(&instructions, Some(&mint_keypair.pubkey()));
let transaction = Transaction::new(
&[&mint_keypair, &mock_account, &mock_validator_identity],
message,
bank.last_blockhash(),
);
let vote_loader_account = bank.get_account(&solana_vote_program::id()).unwrap();
bank.add_mockup_builtin(solana_vote_program::id(), process_instruction);
let new_vote_loader_account = bank.get_account(&solana_vote_program::id()).unwrap();
// Vote loader account should not be updated since it was included in the genesis config.
assert_eq!(vote_loader_account.data(), new_vote_loader_account.data());
assert_eq!(
bank.process_transaction(&transaction),
Err(TransactionError::InstructionError(
1,
InstructionError::Custom(42)
))
);
}
#[test]
fn test_add_instruction_processor_for_existing_unrelated_accounts() {
for pass in 0..5 {
let mut bank = create_simple_test_bank(500);
declare_process_instruction!(process_instruction, 1, |_invoke_context| {
Err(InstructionError::Custom(42))
});
// Non-builtin loader accounts can not be used for instruction processing
{
let stakes = bank.stakes_cache.stakes();
assert!(stakes.vote_accounts().as_ref().is_empty());
}
assert!(bank.stakes_cache.stakes().stake_delegations().is_empty());
if pass == 0 {
add_root_and_flush_write_cache(&bank);
assert_eq!(bank.calculate_capitalization(true), bank.capitalization());
continue;
}
let ((vote_id, vote_account), (stake_id, stake_account)) =
crate::stakes::tests::create_staked_node_accounts(1_0000);
bank.capitalization
.fetch_add(vote_account.lamports() + stake_account.lamports(), Relaxed);
bank.store_account(&vote_id, &vote_account);
bank.store_account(&stake_id, &stake_account);
{
let stakes = bank.stakes_cache.stakes();
assert!(!stakes.vote_accounts().as_ref().is_empty());
}
assert!(!bank.stakes_cache.stakes().stake_delegations().is_empty());
if pass == 1 {
add_root_and_flush_write_cache(&bank);
assert_eq!(bank.calculate_capitalization(true), bank.capitalization());
continue;
}
bank.add_builtin(
vote_id,
"mock_program1".to_string(),
LoadedProgram::new_builtin(0, 0, process_instruction),
);
bank.add_builtin(
stake_id,
"mock_program2".to_string(),
LoadedProgram::new_builtin(0, 0, process_instruction),
);
{
let stakes = bank.stakes_cache.stakes();
assert!(stakes.vote_accounts().as_ref().is_empty());
}
assert!(bank.stakes_cache.stakes().stake_delegations().is_empty());
if pass == 2 {
add_root_and_flush_write_cache(&bank);
assert_eq!(bank.calculate_capitalization(true), bank.capitalization());
continue;
}
assert_eq!(
"mock_program1",
String::from_utf8_lossy(bank.get_account(&vote_id).unwrap_or_default().data())
);
assert_eq!(
"mock_program2",
String::from_utf8_lossy(bank.get_account(&stake_id).unwrap_or_default().data())
);
// Re-adding builtin programs should be no-op
bank.update_accounts_hash_for_tests();
let old_hash = bank.get_accounts_hash().unwrap();
bank.add_mockup_builtin(vote_id, process_instruction);
bank.add_mockup_builtin(stake_id, process_instruction);
add_root_and_flush_write_cache(&bank);
bank.update_accounts_hash_for_tests();
let new_hash = bank.get_accounts_hash().unwrap();
assert_eq!(old_hash, new_hash);
{
let stakes = bank.stakes_cache.stakes();
assert!(stakes.vote_accounts().as_ref().is_empty());
}
assert!(bank.stakes_cache.stakes().stake_delegations().is_empty());
assert_eq!(bank.calculate_capitalization(true), bank.capitalization());
assert_eq!(
"mock_program1",
String::from_utf8_lossy(bank.get_account(&vote_id).unwrap_or_default().data())
);
assert_eq!(
"mock_program2",
String::from_utf8_lossy(bank.get_account(&stake_id).unwrap_or_default().data())
);
}
}
#[allow(deprecated)]
#[test]
fn test_recent_blockhashes_sysvar() {
let mut bank = create_simple_test_arc_bank(500);
for i in 1..5 {
let bhq_account = bank.get_account(&sysvar::recent_blockhashes::id()).unwrap();
let recent_blockhashes =
from_account::<sysvar::recent_blockhashes::RecentBlockhashes, _>(&bhq_account).unwrap();
// Check length
assert_eq!(recent_blockhashes.len(), i);
let most_recent_hash = recent_blockhashes.iter().next().unwrap().blockhash;
// Check order
assert!(bank.is_hash_valid_for_age(&most_recent_hash, 0));
goto_end_of_slot(Arc::get_mut(&mut bank).unwrap());
bank = Arc::new(new_from_parent(&bank));
}
}
#[allow(deprecated)]
#[test]
fn test_blockhash_queue_sysvar_consistency() {
let mut bank = create_simple_test_arc_bank(100_000);
goto_end_of_slot(Arc::get_mut(&mut bank).unwrap());
let bhq_account = bank.get_account(&sysvar::recent_blockhashes::id()).unwrap();
let recent_blockhashes =
from_account::<sysvar::recent_blockhashes::RecentBlockhashes, _>(&bhq_account).unwrap();
let sysvar_recent_blockhash = recent_blockhashes[0].blockhash;
let bank_last_blockhash = bank.last_blockhash();
assert_eq!(sysvar_recent_blockhash, bank_last_blockhash);
}
#[test]
fn test_hash_internal_state_unchanged() {
let (genesis_config, _) = create_genesis_config(500);
let bank0 = Arc::new(Bank::new_for_tests(&genesis_config));
bank0.freeze();
let bank0_hash = bank0.hash();
let bank1 = Bank::new_from_parent(&bank0, &Pubkey::default(), 1);
bank1.freeze();
let bank1_hash = bank1.hash();
// Checkpointing should always result in a new state
assert_ne!(bank0_hash, bank1_hash);
}
#[test]
fn test_ticks_change_state() {
let (genesis_config, _) = create_genesis_config(500);
let bank = Arc::new(Bank::new_for_tests(&genesis_config));
let bank1 = new_from_parent(&bank);
let hash1 = bank1.hash_internal_state();
// ticks don't change its state unless a block boundary is crossed
for _ in 0..genesis_config.ticks_per_slot {
assert_eq!(bank1.hash_internal_state(), hash1);
bank1.register_tick(&Hash::default());
}
assert_ne!(bank1.hash_internal_state(), hash1);
}
#[ignore]
#[test]
fn test_banks_leak() {
fn add_lotsa_stake_accounts(genesis_config: &mut GenesisConfig) {
const LOTSA: usize = 4_096;
(0..LOTSA).for_each(|_| {
let pubkey = solana_sdk::pubkey::new_rand();
genesis_config.add_account(
pubkey,
stake_state::create_lockup_stake_account(
&Authorized::auto(&pubkey),
&Lockup::default(),
&Rent::default(),
50_000_000,
),
);
});
}
solana_logger::setup();
let (mut genesis_config, _) = create_genesis_config(100_000_000_000_000);
add_lotsa_stake_accounts(&mut genesis_config);
let mut bank = std::sync::Arc::new(Bank::new_for_tests(&genesis_config));
let mut num_banks = 0;
let pid = std::process::id();
#[cfg(not(target_os = "linux"))]
error!(
"\nYou can run this to watch RAM:\n while read -p 'banks: '; do echo $(( $(ps -o vsize= -p {})/$REPLY));done", pid
);
loop {
num_banks += 1;
bank = std::sync::Arc::new(new_from_parent(&bank));
if num_banks % 100 == 0 {
#[cfg(target_os = "linux")]
{
let pages_consumed = std::fs::read_to_string(format!("/proc/{pid}/statm"))
.unwrap()
.split_whitespace()
.next()
.unwrap()
.parse::<usize>()
.unwrap();
error!(
"at {} banks: {} mem or {}kB/bank",
num_banks,
pages_consumed * 4096,
(pages_consumed * 4) / num_banks
);
}
#[cfg(not(target_os = "linux"))]
{
error!("{} banks, sleeping for 5 sec", num_banks);
std::thread::sleep(Duration::from_secs(5));
}
}
}
}
fn get_nonce_blockhash(bank: &Bank, nonce_pubkey: &Pubkey) -> Option<Hash> {
let account = bank.get_account(nonce_pubkey)?;
let nonce_versions = StateMut::<nonce::state::Versions>::state(&account);
match nonce_versions.ok()?.state() {
nonce::State::Initialized(ref data) => Some(data.blockhash()),
_ => None,
}
}
fn nonce_setup(
bank: &mut Arc<Bank>,
mint_keypair: &Keypair,
custodian_lamports: u64,
nonce_lamports: u64,
nonce_authority: Option<Pubkey>,
) -> Result<(Keypair, Keypair)> {
let custodian_keypair = Keypair::new();
let nonce_keypair = Keypair::new();
/* Setup accounts */
let mut setup_ixs = vec![system_instruction::transfer(
&mint_keypair.pubkey(),
&custodian_keypair.pubkey(),
custodian_lamports,
)];
let nonce_authority = nonce_authority.unwrap_or_else(|| nonce_keypair.pubkey());
setup_ixs.extend_from_slice(&system_instruction::create_nonce_account(
&custodian_keypair.pubkey(),
&nonce_keypair.pubkey(),
&nonce_authority,
nonce_lamports,
));
let message = Message::new(&setup_ixs, Some(&mint_keypair.pubkey()));
let setup_tx = Transaction::new(
&[mint_keypair, &custodian_keypair, &nonce_keypair],
message,
bank.last_blockhash(),
);
bank.process_transaction(&setup_tx)?;
Ok((custodian_keypair, nonce_keypair))
}
fn setup_nonce_with_bank<F>(
supply_lamports: u64,
mut genesis_cfg_fn: F,
custodian_lamports: u64,
nonce_lamports: u64,
nonce_authority: Option<Pubkey>,
feature_set: FeatureSet,
) -> Result<(Arc<Bank>, Keypair, Keypair, Keypair)>
where
F: FnMut(&mut GenesisConfig),
{
let (mut genesis_config, mint_keypair) = create_genesis_config(supply_lamports);
genesis_config.rent.lamports_per_byte_year = 0;
genesis_cfg_fn(&mut genesis_config);
let mut bank = Bank::new_for_tests(&genesis_config);
bank.feature_set = Arc::new(feature_set);
let mut bank = Arc::new(bank);
// Banks 0 and 1 have no fees, wait two blocks before
// initializing our nonce accounts
for _ in 0..2 {
goto_end_of_slot(Arc::get_mut(&mut bank).unwrap());
bank = Arc::new(new_from_parent(&bank));
}
let (custodian_keypair, nonce_keypair) = nonce_setup(
&mut bank,
&mint_keypair,
custodian_lamports,
nonce_lamports,
nonce_authority,
)?;
// The setup nonce is not valid to be used until the next bank
// so wait one more block
goto_end_of_slot(Arc::get_mut(&mut bank).unwrap());
bank = Arc::new(new_from_parent(&bank));
Ok((bank, mint_keypair, custodian_keypair, nonce_keypair))
}
impl Bank {
fn next_durable_nonce(&self) -> DurableNonce {
let hash_queue = self.blockhash_queue.read().unwrap();
let last_blockhash = hash_queue.last_hash();
DurableNonce::from_blockhash(&last_blockhash)
}
}
#[test]
fn test_check_transaction_for_nonce_ok() {
let (bank, _mint_keypair, custodian_keypair, nonce_keypair) = setup_nonce_with_bank(
10_000_000,
|_| {},
5_000_000,
250_000,
None,
FeatureSet::all_enabled(),
)
.unwrap();
let custodian_pubkey = custodian_keypair.pubkey();
let nonce_pubkey = nonce_keypair.pubkey();
let nonce_hash = get_nonce_blockhash(&bank, &nonce_pubkey).unwrap();
let tx = Transaction::new_signed_with_payer(
&[
system_instruction::advance_nonce_account(&nonce_pubkey, &nonce_pubkey),
system_instruction::transfer(&custodian_pubkey, &nonce_pubkey, 100_000),
],
Some(&custodian_pubkey),
&[&custodian_keypair, &nonce_keypair],
nonce_hash,
);
let nonce_account = bank.get_account(&nonce_pubkey).unwrap();
assert_eq!(
bank.check_transaction_for_nonce(
&SanitizedTransaction::from_transaction_for_tests(tx),
&bank.next_durable_nonce(),
),
Some((nonce_pubkey, nonce_account))
);
}
#[test]
fn test_check_transaction_for_nonce_not_nonce_fail() {
let (bank, _mint_keypair, custodian_keypair, nonce_keypair) = setup_nonce_with_bank(
10_000_000,
|_| {},
5_000_000,
250_000,
None,
FeatureSet::all_enabled(),
)
.unwrap();
let custodian_pubkey = custodian_keypair.pubkey();
let nonce_pubkey = nonce_keypair.pubkey();
let nonce_hash = get_nonce_blockhash(&bank, &nonce_pubkey).unwrap();
let tx = Transaction::new_signed_with_payer(
&[
system_instruction::transfer(&custodian_pubkey, &nonce_pubkey, 100_000),
system_instruction::advance_nonce_account(&nonce_pubkey, &nonce_pubkey),
],
Some(&custodian_pubkey),
&[&custodian_keypair, &nonce_keypair],
nonce_hash,
);
assert!(bank
.check_transaction_for_nonce(
&SanitizedTransaction::from_transaction_for_tests(tx,),
&bank.next_durable_nonce(),
)
.is_none());
}
#[test]
fn test_check_transaction_for_nonce_missing_ix_pubkey_fail() {
let (bank, _mint_keypair, custodian_keypair, nonce_keypair) = setup_nonce_with_bank(
10_000_000,
|_| {},
5_000_000,
250_000,
None,
FeatureSet::all_enabled(),
)
.unwrap();
let custodian_pubkey = custodian_keypair.pubkey();
let nonce_pubkey = nonce_keypair.pubkey();
let nonce_hash = get_nonce_blockhash(&bank, &nonce_pubkey).unwrap();
let mut tx = Transaction::new_signed_with_payer(
&[
system_instruction::advance_nonce_account(&nonce_pubkey, &nonce_pubkey),
system_instruction::transfer(&custodian_pubkey, &nonce_pubkey, 100_000),
],
Some(&custodian_pubkey),
&[&custodian_keypair, &nonce_keypair],
nonce_hash,
);
tx.message.instructions[0].accounts.clear();
assert!(bank
.check_transaction_for_nonce(
&SanitizedTransaction::from_transaction_for_tests(tx),
&bank.next_durable_nonce(),
)
.is_none());
}
#[test]
fn test_check_transaction_for_nonce_nonce_acc_does_not_exist_fail() {
let (bank, _mint_keypair, custodian_keypair, nonce_keypair) = setup_nonce_with_bank(
10_000_000,
|_| {},
5_000_000,
250_000,
None,
FeatureSet::all_enabled(),
)
.unwrap();
let custodian_pubkey = custodian_keypair.pubkey();
let nonce_pubkey = nonce_keypair.pubkey();
let missing_keypair = Keypair::new();
let missing_pubkey = missing_keypair.pubkey();
let nonce_hash = get_nonce_blockhash(&bank, &nonce_pubkey).unwrap();
let tx = Transaction::new_signed_with_payer(
&[
system_instruction::advance_nonce_account(&missing_pubkey, &nonce_pubkey),
system_instruction::transfer(&custodian_pubkey, &nonce_pubkey, 100_000),
],
Some(&custodian_pubkey),
&[&custodian_keypair, &nonce_keypair],
nonce_hash,
);
assert!(bank
.check_transaction_for_nonce(
&SanitizedTransaction::from_transaction_for_tests(tx),
&bank.next_durable_nonce(),
)
.is_none());
}
#[test]
fn test_check_transaction_for_nonce_bad_tx_hash_fail() {
let (bank, _mint_keypair, custodian_keypair, nonce_keypair) = setup_nonce_with_bank(
10_000_000,
|_| {},
5_000_000,
250_000,
None,
FeatureSet::all_enabled(),
)
.unwrap();
let custodian_pubkey = custodian_keypair.pubkey();
let nonce_pubkey = nonce_keypair.pubkey();
let tx = Transaction::new_signed_with_payer(
&[
system_instruction::advance_nonce_account(&nonce_pubkey, &nonce_pubkey),
system_instruction::transfer(&custodian_pubkey, &nonce_pubkey, 100_000),
],
Some(&custodian_pubkey),
&[&custodian_keypair, &nonce_keypair],
Hash::default(),
);
assert!(bank
.check_transaction_for_nonce(
&SanitizedTransaction::from_transaction_for_tests(tx),
&bank.next_durable_nonce(),
)
.is_none());
}
#[test]
fn test_assign_from_nonce_account_fail() {
let bank = create_simple_test_arc_bank(100_000_000);
let nonce = Keypair::new();
let nonce_account = AccountSharedData::new_data(
42_424_242,
&nonce::state::Versions::new(nonce::State::Initialized(nonce::state::Data::default())),
&system_program::id(),
)
.unwrap();
let blockhash = bank.last_blockhash();
bank.store_account(&nonce.pubkey(), &nonce_account);
let ix = system_instruction::assign(&nonce.pubkey(), &Pubkey::from([9u8; 32]));
let message = Message::new(&[ix], Some(&nonce.pubkey()));
let tx = Transaction::new(&[&nonce], message, blockhash);
let expect = Err(TransactionError::InstructionError(
0,
InstructionError::ModifiedProgramId,
));
assert_eq!(bank.process_transaction(&tx), expect);
}
#[test]
fn test_nonce_must_be_advanceable() {
let mut bank = create_simple_test_bank(100_000_000);
bank.feature_set = Arc::new(FeatureSet::all_enabled());
let bank = Arc::new(bank);
let nonce_keypair = Keypair::new();
let nonce_authority = nonce_keypair.pubkey();
let durable_nonce = DurableNonce::from_blockhash(&bank.last_blockhash());
let nonce_account = AccountSharedData::new_data(
42_424_242,
&nonce::state::Versions::new(nonce::State::Initialized(nonce::state::Data::new(
nonce_authority,
durable_nonce,
5000,
))),
&system_program::id(),
)
.unwrap();
bank.store_account(&nonce_keypair.pubkey(), &nonce_account);
let ix = system_instruction::advance_nonce_account(&nonce_keypair.pubkey(), &nonce_authority);
let message = Message::new(&[ix], Some(&nonce_keypair.pubkey()));
let tx = Transaction::new(&[&nonce_keypair], message, *durable_nonce.as_hash());
assert_eq!(
bank.process_transaction(&tx),
Err(TransactionError::BlockhashNotFound)
);
}
#[test]
fn test_nonce_transaction() {
let (mut bank, _mint_keypair, custodian_keypair, nonce_keypair) = setup_nonce_with_bank(
10_000_000,
|_| {},
5_000_000,
250_000,
None,
FeatureSet::all_enabled(),
)
.unwrap();
let alice_keypair = Keypair::new();
let alice_pubkey = alice_keypair.pubkey();
let custodian_pubkey = custodian_keypair.pubkey();
let nonce_pubkey = nonce_keypair.pubkey();
assert_eq!(bank.get_balance(&custodian_pubkey), 4_750_000);
assert_eq!(bank.get_balance(&nonce_pubkey), 250_000);
/* Grab the hash stored in the nonce account */
let nonce_hash = get_nonce_blockhash(&bank, &nonce_pubkey).unwrap();
/* Kick nonce hash off the blockhash_queue */
for _ in 0..MAX_RECENT_BLOCKHASHES + 1 {
goto_end_of_slot(Arc::get_mut(&mut bank).unwrap());
bank = Arc::new(new_from_parent(&bank));
}
/* Expect a non-Nonce transfer to fail */
assert_eq!(
bank.process_transaction(&system_transaction::transfer(
&custodian_keypair,
&alice_pubkey,
100_000,
nonce_hash
),),
Err(TransactionError::BlockhashNotFound),
);
/* Check fee not charged */
assert_eq!(bank.get_balance(&custodian_pubkey), 4_750_000);
/* Nonce transfer */
let nonce_tx = Transaction::new_signed_with_payer(
&[
system_instruction::advance_nonce_account(&nonce_pubkey, &nonce_pubkey),
system_instruction::transfer(&custodian_pubkey, &alice_pubkey, 100_000),
],
Some(&custodian_pubkey),
&[&custodian_keypair, &nonce_keypair],
nonce_hash,
);
assert_eq!(bank.process_transaction(&nonce_tx), Ok(()));
/* Check balances */
let mut recent_message = nonce_tx.message;
recent_message.recent_blockhash = bank.last_blockhash();
let mut expected_balance = 4_650_000
- bank
.get_fee_for_message(&recent_message.try_into().unwrap())
.unwrap();
assert_eq!(bank.get_balance(&custodian_pubkey), expected_balance);
assert_eq!(bank.get_balance(&nonce_pubkey), 250_000);
assert_eq!(bank.get_balance(&alice_pubkey), 100_000);
/* Confirm stored nonce has advanced */
let new_nonce = get_nonce_blockhash(&bank, &nonce_pubkey).unwrap();
assert_ne!(nonce_hash, new_nonce);
/* Nonce re-use fails */
let nonce_tx = Transaction::new_signed_with_payer(
&[
system_instruction::advance_nonce_account(&nonce_pubkey, &nonce_pubkey),
system_instruction::transfer(&custodian_pubkey, &alice_pubkey, 100_000),
],
Some(&custodian_pubkey),
&[&custodian_keypair, &nonce_keypair],
nonce_hash,
);
assert_eq!(
bank.process_transaction(&nonce_tx),
Err(TransactionError::BlockhashNotFound)
);
/* Check fee not charged and nonce not advanced */
assert_eq!(bank.get_balance(&custodian_pubkey), expected_balance);
assert_eq!(
new_nonce,
get_nonce_blockhash(&bank, &nonce_pubkey).unwrap()
);
let nonce_hash = new_nonce;
/* Kick nonce hash off the blockhash_queue */
for _ in 0..MAX_RECENT_BLOCKHASHES + 1 {
goto_end_of_slot(Arc::get_mut(&mut bank).unwrap());
bank = Arc::new(new_from_parent(&bank));
}
let nonce_tx = Transaction::new_signed_with_payer(
&[
system_instruction::advance_nonce_account(&nonce_pubkey, &nonce_pubkey),
system_instruction::transfer(&custodian_pubkey, &alice_pubkey, 100_000_000),
],
Some(&custodian_pubkey),
&[&custodian_keypair, &nonce_keypair],
nonce_hash,
);
assert_eq!(
bank.process_transaction(&nonce_tx),
Err(TransactionError::InstructionError(
1,
system_instruction::SystemError::ResultWithNegativeLamports.into(),
))
);
/* Check fee charged and nonce has advanced */
let mut recent_message = nonce_tx.message.clone();
recent_message.recent_blockhash = bank.last_blockhash();
expected_balance -= bank
.get_fee_for_message(&SanitizedMessage::try_from(recent_message).unwrap())
.unwrap();
assert_eq!(bank.get_balance(&custodian_pubkey), expected_balance);
assert_ne!(
nonce_hash,
get_nonce_blockhash(&bank, &nonce_pubkey).unwrap()
);
/* Confirm replaying a TX that failed with InstructionError::* now
* fails with TransactionError::BlockhashNotFound
*/
assert_eq!(
bank.process_transaction(&nonce_tx),
Err(TransactionError::BlockhashNotFound),
);
}
#[test]
fn test_nonce_transaction_with_tx_wide_caps() {
let feature_set = FeatureSet::all_enabled();
let (mut bank, _mint_keypair, custodian_keypair, nonce_keypair) =
setup_nonce_with_bank(10_000_000, |_| {}, 5_000_000, 250_000, None, feature_set).unwrap();
let alice_keypair = Keypair::new();
let alice_pubkey = alice_keypair.pubkey();
let custodian_pubkey = custodian_keypair.pubkey();
let nonce_pubkey = nonce_keypair.pubkey();
assert_eq!(bank.get_balance(&custodian_pubkey), 4_750_000);
assert_eq!(bank.get_balance(&nonce_pubkey), 250_000);
/* Grab the hash stored in the nonce account */
let nonce_hash = get_nonce_blockhash(&bank, &nonce_pubkey).unwrap();
/* Kick nonce hash off the blockhash_queue */
for _ in 0..MAX_RECENT_BLOCKHASHES + 1 {
goto_end_of_slot(Arc::get_mut(&mut bank).unwrap());
bank = Arc::new(new_from_parent(&bank));
}
/* Expect a non-Nonce transfer to fail */
assert_eq!(
bank.process_transaction(&system_transaction::transfer(
&custodian_keypair,
&alice_pubkey,
100_000,
nonce_hash
),),
Err(TransactionError::BlockhashNotFound),
);
/* Check fee not charged */
assert_eq!(bank.get_balance(&custodian_pubkey), 4_750_000);
/* Nonce transfer */
let nonce_tx = Transaction::new_signed_with_payer(
&[
system_instruction::advance_nonce_account(&nonce_pubkey, &nonce_pubkey),
system_instruction::transfer(&custodian_pubkey, &alice_pubkey, 100_000),
],
Some(&custodian_pubkey),
&[&custodian_keypair, &nonce_keypair],
nonce_hash,
);
assert_eq!(bank.process_transaction(&nonce_tx), Ok(()));
/* Check balances */
let mut recent_message = nonce_tx.message;
recent_message.recent_blockhash = bank.last_blockhash();
let mut expected_balance = 4_650_000
- bank
.get_fee_for_message(&recent_message.try_into().unwrap())
.unwrap();
assert_eq!(bank.get_balance(&custodian_pubkey), expected_balance);
assert_eq!(bank.get_balance(&nonce_pubkey), 250_000);
assert_eq!(bank.get_balance(&alice_pubkey), 100_000);
/* Confirm stored nonce has advanced */
let new_nonce = get_nonce_blockhash(&bank, &nonce_pubkey).unwrap();
assert_ne!(nonce_hash, new_nonce);
/* Nonce re-use fails */
let nonce_tx = Transaction::new_signed_with_payer(
&[
system_instruction::advance_nonce_account(&nonce_pubkey, &nonce_pubkey),
system_instruction::transfer(&custodian_pubkey, &alice_pubkey, 100_000),
],
Some(&custodian_pubkey),
&[&custodian_keypair, &nonce_keypair],
nonce_hash,
);
assert_eq!(
bank.process_transaction(&nonce_tx),
Err(TransactionError::BlockhashNotFound)
);
/* Check fee not charged and nonce not advanced */
assert_eq!(bank.get_balance(&custodian_pubkey), expected_balance);
assert_eq!(
new_nonce,
get_nonce_blockhash(&bank, &nonce_pubkey).unwrap()
);
let nonce_hash = new_nonce;
/* Kick nonce hash off the blockhash_queue */
for _ in 0..MAX_RECENT_BLOCKHASHES + 1 {
goto_end_of_slot(Arc::get_mut(&mut bank).unwrap());
bank = Arc::new(new_from_parent(&bank));
}
let nonce_tx = Transaction::new_signed_with_payer(
&[
system_instruction::advance_nonce_account(&nonce_pubkey, &nonce_pubkey),
system_instruction::transfer(&custodian_pubkey, &alice_pubkey, 100_000_000),
],
Some(&custodian_pubkey),
&[&custodian_keypair, &nonce_keypair],
nonce_hash,
);
assert_eq!(
bank.process_transaction(&nonce_tx),
Err(TransactionError::InstructionError(
1,
system_instruction::SystemError::ResultWithNegativeLamports.into(),
))
);
/* Check fee charged and nonce has advanced */
let mut recent_message = nonce_tx.message.clone();
recent_message.recent_blockhash = bank.last_blockhash();
expected_balance -= bank
.get_fee_for_message(&SanitizedMessage::try_from(recent_message).unwrap())
.unwrap();
assert_eq!(bank.get_balance(&custodian_pubkey), expected_balance);
assert_ne!(
nonce_hash,
get_nonce_blockhash(&bank, &nonce_pubkey).unwrap()
);
/* Confirm replaying a TX that failed with InstructionError::* now
* fails with TransactionError::BlockhashNotFound
*/
assert_eq!(
bank.process_transaction(&nonce_tx),
Err(TransactionError::BlockhashNotFound),
);
}
#[test]
fn test_nonce_authority() {
solana_logger::setup();
let (mut bank, _mint_keypair, custodian_keypair, nonce_keypair) = setup_nonce_with_bank(
10_000_000,
|_| {},
5_000_000,
250_000,
None,
FeatureSet::all_enabled(),
)
.unwrap();
let alice_keypair = Keypair::new();
let alice_pubkey = alice_keypair.pubkey();
let custodian_pubkey = custodian_keypair.pubkey();
let nonce_pubkey = nonce_keypair.pubkey();
let bad_nonce_authority_keypair = Keypair::new();
let bad_nonce_authority = bad_nonce_authority_keypair.pubkey();
let custodian_account = bank.get_account(&custodian_pubkey).unwrap();
debug!("alice: {}", alice_pubkey);
debug!("custodian: {}", custodian_pubkey);
debug!("nonce: {}", nonce_pubkey);
debug!("nonce account: {:?}", bank.get_account(&nonce_pubkey));
debug!("cust: {:?}", custodian_account);
let nonce_hash = get_nonce_blockhash(&bank, &nonce_pubkey).unwrap();
for _ in 0..MAX_RECENT_BLOCKHASHES + 1 {
goto_end_of_slot(Arc::get_mut(&mut bank).unwrap());
bank = Arc::new(new_from_parent(&bank));
}
let nonce_tx = Transaction::new_signed_with_payer(
&[
system_instruction::advance_nonce_account(&nonce_pubkey, &bad_nonce_authority),
system_instruction::transfer(&custodian_pubkey, &alice_pubkey, 42),
],
Some(&custodian_pubkey),
&[&custodian_keypair, &bad_nonce_authority_keypair],
nonce_hash,
);
debug!("{:?}", nonce_tx);
let initial_custodian_balance = custodian_account.lamports();
assert_eq!(
bank.process_transaction(&nonce_tx),
Err(TransactionError::BlockhashNotFound),
);
/* Check fee was *not* charged and nonce has *not* advanced */
let mut recent_message = nonce_tx.message;
recent_message.recent_blockhash = bank.last_blockhash();
assert_eq!(
bank.get_balance(&custodian_pubkey),
initial_custodian_balance
);
assert_eq!(
nonce_hash,
get_nonce_blockhash(&bank, &nonce_pubkey).unwrap()
);
}
#[test]
fn test_nonce_payer() {
solana_logger::setup();
let nonce_starting_balance = 250_000;
let (mut bank, _mint_keypair, custodian_keypair, nonce_keypair) = setup_nonce_with_bank(
10_000_000,
|_| {},
5_000_000,
nonce_starting_balance,
None,
FeatureSet::all_enabled(),
)
.unwrap();
let alice_keypair = Keypair::new();
let alice_pubkey = alice_keypair.pubkey();
let custodian_pubkey = custodian_keypair.pubkey();
let nonce_pubkey = nonce_keypair.pubkey();
debug!("alice: {}", alice_pubkey);
debug!("custodian: {}", custodian_pubkey);
debug!("nonce: {}", nonce_pubkey);
debug!("nonce account: {:?}", bank.get_account(&nonce_pubkey));
debug!("cust: {:?}", bank.get_account(&custodian_pubkey));
let nonce_hash = get_nonce_blockhash(&bank, &nonce_pubkey).unwrap();
for _ in 0..MAX_RECENT_BLOCKHASHES + 1 {
goto_end_of_slot(Arc::get_mut(&mut bank).unwrap());
bank = Arc::new(new_from_parent(&bank));
}
let nonce_tx = Transaction::new_signed_with_payer(
&[
system_instruction::advance_nonce_account(&nonce_pubkey, &nonce_pubkey),
system_instruction::transfer(&custodian_pubkey, &alice_pubkey, 100_000_000),
],
Some(&nonce_pubkey),
&[&custodian_keypair, &nonce_keypair],
nonce_hash,
);
debug!("{:?}", nonce_tx);
assert_eq!(
bank.process_transaction(&nonce_tx),
Err(TransactionError::InstructionError(
1,
system_instruction::SystemError::ResultWithNegativeLamports.into(),
))
);
/* Check fee charged and nonce has advanced */
let mut recent_message = nonce_tx.message;
recent_message.recent_blockhash = bank.last_blockhash();
assert_eq!(
bank.get_balance(&nonce_pubkey),
nonce_starting_balance
- bank
.get_fee_for_message(&recent_message.try_into().unwrap())
.unwrap()
);
assert_ne!(
nonce_hash,
get_nonce_blockhash(&bank, &nonce_pubkey).unwrap()
);
}
#[test]
fn test_nonce_payer_tx_wide_cap() {
solana_logger::setup();
let nonce_starting_balance =
250_000 + FeeStructure::default().compute_fee_bins.last().unwrap().fee;
let feature_set = FeatureSet::all_enabled();
let (mut bank, _mint_keypair, custodian_keypair, nonce_keypair) = setup_nonce_with_bank(
10_000_000,
|_| {},
5_000_000,
nonce_starting_balance,
None,
feature_set,
)
.unwrap();
let alice_keypair = Keypair::new();
let alice_pubkey = alice_keypair.pubkey();
let custodian_pubkey = custodian_keypair.pubkey();
let nonce_pubkey = nonce_keypair.pubkey();
debug!("alice: {}", alice_pubkey);
debug!("custodian: {}", custodian_pubkey);
debug!("nonce: {}", nonce_pubkey);
debug!("nonce account: {:?}", bank.get_account(&nonce_pubkey));
debug!("cust: {:?}", bank.get_account(&custodian_pubkey));
let nonce_hash = get_nonce_blockhash(&bank, &nonce_pubkey).unwrap();
for _ in 0..MAX_RECENT_BLOCKHASHES + 1 {
goto_end_of_slot(Arc::get_mut(&mut bank).unwrap());
bank = Arc::new(new_from_parent(&bank));
}
let nonce_tx = Transaction::new_signed_with_payer(
&[
system_instruction::advance_nonce_account(&nonce_pubkey, &nonce_pubkey),
system_instruction::transfer(&custodian_pubkey, &alice_pubkey, 100_000_000),
],
Some(&nonce_pubkey),
&[&custodian_keypair, &nonce_keypair],
nonce_hash,
);
debug!("{:?}", nonce_tx);
assert_eq!(
bank.process_transaction(&nonce_tx),
Err(TransactionError::InstructionError(
1,
system_instruction::SystemError::ResultWithNegativeLamports.into(),
))
);
/* Check fee charged and nonce has advanced */
let mut recent_message = nonce_tx.message;
recent_message.recent_blockhash = bank.last_blockhash();
assert_eq!(
bank.get_balance(&nonce_pubkey),
nonce_starting_balance
- bank
.get_fee_for_message(&recent_message.try_into().unwrap())
.unwrap()
);
assert_ne!(
nonce_hash,
get_nonce_blockhash(&bank, &nonce_pubkey).unwrap()
);
}
#[test]
fn test_nonce_fee_calculator_updates() {
let (mut genesis_config, mint_keypair) = create_genesis_config(1_000_000);
genesis_config.rent.lamports_per_byte_year = 0;
let mut bank = Bank::new_for_tests(&genesis_config);
bank.feature_set = Arc::new(FeatureSet::all_enabled());
let mut bank = Arc::new(bank);
// Deliberately use bank 0 to initialize nonce account, so that nonce account fee_calculator indicates 0 fees
let (custodian_keypair, nonce_keypair) =
nonce_setup(&mut bank, &mint_keypair, 500_000, 100_000, None).unwrap();
let custodian_pubkey = custodian_keypair.pubkey();
let nonce_pubkey = nonce_keypair.pubkey();
// Grab the hash and fee_calculator stored in the nonce account
let (stored_nonce_hash, stored_fee_calculator) = bank
.get_account(&nonce_pubkey)
.and_then(|acc| {
let nonce_versions = StateMut::<nonce::state::Versions>::state(&acc);
match nonce_versions.ok()?.state() {
nonce::State::Initialized(ref data) => {
Some((data.blockhash(), data.fee_calculator))
}
_ => None,
}
})
.unwrap();
// Kick nonce hash off the blockhash_queue
for _ in 0..MAX_RECENT_BLOCKHASHES + 1 {
goto_end_of_slot(Arc::get_mut(&mut bank).unwrap());
bank = Arc::new(new_from_parent(&bank));
}
// Nonce transfer
let nonce_tx = Transaction::new_signed_with_payer(
&[
system_instruction::advance_nonce_account(&nonce_pubkey, &nonce_pubkey),
system_instruction::transfer(
&custodian_pubkey,
&solana_sdk::pubkey::new_rand(),
100_000,
),
],
Some(&custodian_pubkey),
&[&custodian_keypair, &nonce_keypair],
stored_nonce_hash,
);
bank.process_transaction(&nonce_tx).unwrap();
// Grab the new hash and fee_calculator; both should be updated
let (nonce_hash, fee_calculator) = bank
.get_account(&nonce_pubkey)
.and_then(|acc| {
let nonce_versions = StateMut::<nonce::state::Versions>::state(&acc);
match nonce_versions.ok()?.state() {
nonce::State::Initialized(ref data) => {
Some((data.blockhash(), data.fee_calculator))
}
_ => None,
}
})
.unwrap();
assert_ne!(stored_nonce_hash, nonce_hash);
assert_ne!(stored_fee_calculator, fee_calculator);
}
#[test]
fn test_nonce_fee_calculator_updates_tx_wide_cap() {
let (mut genesis_config, mint_keypair) = create_genesis_config(1_000_000);
genesis_config.rent.lamports_per_byte_year = 0;
let mut bank = Bank::new_for_tests(&genesis_config);
bank.feature_set = Arc::new(FeatureSet::all_enabled());
let mut bank = Arc::new(bank);
// Deliberately use bank 0 to initialize nonce account, so that nonce account fee_calculator indicates 0 fees
let (custodian_keypair, nonce_keypair) =
nonce_setup(&mut bank, &mint_keypair, 500_000, 100_000, None).unwrap();
let custodian_pubkey = custodian_keypair.pubkey();
let nonce_pubkey = nonce_keypair.pubkey();
// Grab the hash and fee_calculator stored in the nonce account
let (stored_nonce_hash, stored_fee_calculator) = bank
.get_account(&nonce_pubkey)
.and_then(|acc| {
let nonce_versions = StateMut::<nonce::state::Versions>::state(&acc);
match nonce_versions.ok()?.state() {
nonce::State::Initialized(ref data) => {
Some((data.blockhash(), data.fee_calculator))
}
_ => None,
}
})
.unwrap();
// Kick nonce hash off the blockhash_queue
for _ in 0..MAX_RECENT_BLOCKHASHES + 1 {
goto_end_of_slot(Arc::get_mut(&mut bank).unwrap());
bank = Arc::new(new_from_parent(&bank));
}
// Nonce transfer
let nonce_tx = Transaction::new_signed_with_payer(
&[
system_instruction::advance_nonce_account(&nonce_pubkey, &nonce_pubkey),
system_instruction::transfer(
&custodian_pubkey,
&solana_sdk::pubkey::new_rand(),
100_000,
),
],
Some(&custodian_pubkey),
&[&custodian_keypair, &nonce_keypair],
stored_nonce_hash,
);
bank.process_transaction(&nonce_tx).unwrap();
// Grab the new hash and fee_calculator; both should be updated
let (nonce_hash, fee_calculator) = bank
.get_account(&nonce_pubkey)
.and_then(|acc| {
let nonce_versions = StateMut::<nonce::state::Versions>::state(&acc);
match nonce_versions.ok()?.state() {
nonce::State::Initialized(ref data) => {
Some((data.blockhash(), data.fee_calculator))
}
_ => None,
}
})
.unwrap();
assert_ne!(stored_nonce_hash, nonce_hash);
assert_ne!(stored_fee_calculator, fee_calculator);
}
#[test]
fn test_check_ro_durable_nonce_fails() {
let (mut bank, _mint_keypair, custodian_keypair, nonce_keypair) = setup_nonce_with_bank(
10_000_000,
|_| {},
5_000_000,
250_000,
None,
FeatureSet::all_enabled(),
)
.unwrap();
let custodian_pubkey = custodian_keypair.pubkey();
let nonce_pubkey = nonce_keypair.pubkey();
let nonce_hash = get_nonce_blockhash(&bank, &nonce_pubkey).unwrap();
let account_metas = vec![
AccountMeta::new_readonly(nonce_pubkey, false),
#[allow(deprecated)]
AccountMeta::new_readonly(sysvar::recent_blockhashes::id(), false),
AccountMeta::new_readonly(nonce_pubkey, true),
];
let nonce_instruction = Instruction::new_with_bincode(
system_program::id(),
&system_instruction::SystemInstruction::AdvanceNonceAccount,
account_metas,
);
let tx = Transaction::new_signed_with_payer(
&[nonce_instruction],
Some(&custodian_pubkey),
&[&custodian_keypair, &nonce_keypair],
nonce_hash,
);
// SanitizedMessage::get_durable_nonce returns None because nonce
// account is not writable. Durable nonce and blockhash domains are
// separate, so the recent_blockhash (== durable nonce) in the
// transaction is not found in the hash queue.
assert_eq!(
bank.process_transaction(&tx),
Err(TransactionError::BlockhashNotFound),
);
// Kick nonce hash off the blockhash_queue
for _ in 0..MAX_RECENT_BLOCKHASHES + 1 {
goto_end_of_slot(Arc::get_mut(&mut bank).unwrap());
bank = Arc::new(new_from_parent(&bank));
}
// Caught by the runtime because it is a nonce transaction
assert_eq!(
bank.process_transaction(&tx),
Err(TransactionError::BlockhashNotFound)
);
assert_eq!(
bank.check_transaction_for_nonce(
&SanitizedTransaction::from_transaction_for_tests(tx),
&bank.next_durable_nonce(),
),
None
);
}
#[test]
fn test_collect_balances() {
let parent = create_simple_test_arc_bank(500);
let bank0 = Arc::new(new_from_parent(&parent));
let keypair = Keypair::new();
let pubkey0 = solana_sdk::pubkey::new_rand();
let pubkey1 = solana_sdk::pubkey::new_rand();
let program_id = Pubkey::from([2; 32]);
let keypair_account = AccountSharedData::new(8, 0, &program_id);
let account0 = AccountSharedData::new(11, 0, &program_id);
let program_account = AccountSharedData::new(1, 10, &Pubkey::default());
bank0.store_account(&keypair.pubkey(), &keypair_account);
bank0.store_account(&pubkey0, &account0);
bank0.store_account(&program_id, &program_account);
let instructions = vec![CompiledInstruction::new(1, &(), vec![0])];
let tx0 = Transaction::new_with_compiled_instructions(
&[&keypair],
&[pubkey0],
Hash::default(),
vec![program_id],
instructions,
);
let instructions = vec![CompiledInstruction::new(1, &(), vec![0])];
let tx1 = Transaction::new_with_compiled_instructions(
&[&keypair],
&[pubkey1],
Hash::default(),
vec![program_id],
instructions,
);
let txs = vec![tx0, tx1];
let batch = bank0.prepare_batch_for_tests(txs.clone());
let balances = bank0.collect_balances(&batch);
assert_eq!(balances.len(), 2);
assert_eq!(balances[0], vec![8, 11, 1]);
assert_eq!(balances[1], vec![8, 0, 1]);
let txs: Vec<_> = txs.into_iter().rev().collect();
let batch = bank0.prepare_batch_for_tests(txs);
let balances = bank0.collect_balances(&batch);
assert_eq!(balances.len(), 2);
assert_eq!(balances[0], vec![8, 0, 1]);
assert_eq!(balances[1], vec![8, 11, 1]);
}
#[test]
fn test_pre_post_transaction_balances() {
let (mut genesis_config, _mint_keypair) = create_genesis_config(500_000);
let fee_rate_governor = FeeRateGovernor::new(5000, 0);
genesis_config.fee_rate_governor = fee_rate_governor;
let parent = Arc::new(Bank::new_for_tests(&genesis_config));
let bank0 = Arc::new(new_from_parent(&parent));
let keypair0 = Keypair::new();
let keypair1 = Keypair::new();
let pubkey0 = solana_sdk::pubkey::new_rand();
let pubkey1 = solana_sdk::pubkey::new_rand();
let pubkey2 = solana_sdk::pubkey::new_rand();
let keypair0_account = AccountSharedData::new(908_000, 0, &Pubkey::default());
let keypair1_account = AccountSharedData::new(909_000, 0, &Pubkey::default());
let account0 = AccountSharedData::new(911_000, 0, &Pubkey::default());
bank0.store_account(&keypair0.pubkey(), &keypair0_account);
bank0.store_account(&keypair1.pubkey(), &keypair1_account);
bank0.store_account(&pubkey0, &account0);
let blockhash = bank0.last_blockhash();
let tx0 = system_transaction::transfer(&keypair0, &pubkey0, 2_000, blockhash);
let tx1 = system_transaction::transfer(&Keypair::new(), &pubkey1, 2_000, blockhash);
let tx2 = system_transaction::transfer(&keypair1, &pubkey2, 912_000, blockhash);
let txs = vec![tx0, tx1, tx2];
let lock_result = bank0.prepare_batch_for_tests(txs);
let (transaction_results, transaction_balances_set) = bank0
.load_execute_and_commit_transactions(
&lock_result,
MAX_PROCESSING_AGE,
true,
false,
false,
false,
&mut ExecuteTimings::default(),
None,
);
assert_eq!(transaction_balances_set.pre_balances.len(), 3);
assert_eq!(transaction_balances_set.post_balances.len(), 3);
assert!(transaction_results.execution_results[0].was_executed_successfully());
assert_eq!(
transaction_balances_set.pre_balances[0],
vec![908_000, 911_000, 1]
);
assert_eq!(
transaction_balances_set.post_balances[0],
vec![901_000, 913_000, 1]
);
// Failed transactions still produce balance sets
// This is a TransactionError - not possible to charge fees
assert!(matches!(
transaction_results.execution_results[1],
TransactionExecutionResult::NotExecuted(TransactionError::AccountNotFound),
));
assert_eq!(transaction_balances_set.pre_balances[1], vec![0, 0, 1]);
assert_eq!(transaction_balances_set.post_balances[1], vec![0, 0, 1]);
// Failed transactions still produce balance sets
// This is an InstructionError - fees charged
assert!(matches!(
transaction_results.execution_results[2],
TransactionExecutionResult::Executed {
details: TransactionExecutionDetails {
status: Err(TransactionError::InstructionError(
0,
InstructionError::Custom(1),
)),
..
},
..
},
));
assert_eq!(
transaction_balances_set.pre_balances[2],
vec![909_000, 0, 1]
);
assert_eq!(
transaction_balances_set.post_balances[2],
vec![904_000, 0, 1]
);
}
#[test]
fn test_transaction_with_duplicate_accounts_in_instruction() {
let (genesis_config, mint_keypair) = create_genesis_config(500);
let mut bank = Bank::new_for_tests(&genesis_config);
declare_process_instruction!(process_instruction, 1, |invoke_context| {
let transaction_context = &invoke_context.transaction_context;
let instruction_context = transaction_context.get_current_instruction_context()?;
let instruction_data = instruction_context.get_instruction_data();
let lamports = u64::from_le_bytes(instruction_data.try_into().unwrap());
instruction_context
.try_borrow_instruction_account(transaction_context, 2)?
.checked_sub_lamports(lamports)?;
instruction_context
.try_borrow_instruction_account(transaction_context, 1)?
.checked_add_lamports(lamports)?;
instruction_context
.try_borrow_instruction_account(transaction_context, 0)?
.checked_sub_lamports(lamports)?;
instruction_context
.try_borrow_instruction_account(transaction_context, 1)?
.checked_add_lamports(lamports)?;
Ok(())
});
let mock_program_id = Pubkey::from([2u8; 32]);
bank.add_mockup_builtin(mock_program_id, process_instruction);
let from_pubkey = solana_sdk::pubkey::new_rand();
let to_pubkey = solana_sdk::pubkey::new_rand();
let dup_pubkey = from_pubkey;
let from_account = AccountSharedData::new(sol_to_lamports(100.), 1, &mock_program_id);
let to_account = AccountSharedData::new(0, 1, &mock_program_id);
bank.store_account(&from_pubkey, &from_account);
bank.store_account(&to_pubkey, &to_account);
let account_metas = vec![
AccountMeta::new(from_pubkey, false),
AccountMeta::new(to_pubkey, false),
AccountMeta::new(dup_pubkey, false),
];
let instruction =
Instruction::new_with_bincode(mock_program_id, &sol_to_lamports(10.), account_metas);
let tx = Transaction::new_signed_with_payer(
&[instruction],
Some(&mint_keypair.pubkey()),
&[&mint_keypair],
bank.last_blockhash(),
);
let result = bank.process_transaction(&tx);
assert_eq!(result, Ok(()));
assert_eq!(bank.get_balance(&from_pubkey), sol_to_lamports(80.));
assert_eq!(bank.get_balance(&to_pubkey), sol_to_lamports(20.));
}
#[test]
fn test_transaction_with_program_ids_passed_to_programs() {
let (genesis_config, mint_keypair) = create_genesis_config(500);
let mut bank = Bank::new_for_tests(&genesis_config);
let mock_program_id = Pubkey::from([2u8; 32]);
bank.add_mockup_builtin(mock_program_id, process_instruction);
let from_pubkey = solana_sdk::pubkey::new_rand();
let to_pubkey = solana_sdk::pubkey::new_rand();
let dup_pubkey = from_pubkey;
let from_account = AccountSharedData::new(100, 1, &mock_program_id);
let to_account = AccountSharedData::new(0, 1, &mock_program_id);
bank.store_account(&from_pubkey, &from_account);
bank.store_account(&to_pubkey, &to_account);
let account_metas = vec![
AccountMeta::new(from_pubkey, false),
AccountMeta::new(to_pubkey, false),
AccountMeta::new(dup_pubkey, false),
AccountMeta::new(mock_program_id, false),
];
let instruction = Instruction::new_with_bincode(mock_program_id, &10, account_metas);
let tx = Transaction::new_signed_with_payer(
&[instruction],
Some(&mint_keypair.pubkey()),
&[&mint_keypair],
bank.last_blockhash(),
);
let result = bank.process_transaction(&tx);
assert_eq!(result, Ok(()));
}
#[test]
fn test_account_ids_after_program_ids() {
solana_logger::setup();
let (genesis_config, mint_keypair) = create_genesis_config(500);
let mut bank = Bank::new_for_tests(&genesis_config);
let from_pubkey = solana_sdk::pubkey::new_rand();
let to_pubkey = solana_sdk::pubkey::new_rand();
let account_metas = vec![
AccountMeta::new(from_pubkey, false),
AccountMeta::new(to_pubkey, false),
];
let instruction = Instruction::new_with_bincode(solana_vote_program::id(), &10, account_metas);
let mut tx = Transaction::new_signed_with_payer(
&[instruction],
Some(&mint_keypair.pubkey()),
&[&mint_keypair],
bank.last_blockhash(),
);
tx.message.account_keys.push(solana_sdk::pubkey::new_rand());
bank.add_mockup_builtin(solana_vote_program::id(), process_instruction);
let result = bank.process_transaction(&tx);
assert_eq!(result, Ok(()));
let account = bank.get_account(&solana_vote_program::id()).unwrap();
info!("account: {:?}", account);
assert!(account.executable());
}
#[test]
fn test_incinerator() {
let (genesis_config, mint_keypair) = create_genesis_config(1_000_000_000_000);
let bank0 = Arc::new(Bank::new_for_tests(&genesis_config));
// Move to the first normal slot so normal rent behaviour applies
let bank = Bank::new_from_parent(
&bank0,
&Pubkey::default(),
genesis_config.epoch_schedule.first_normal_slot,
);
let pre_capitalization = bank.capitalization();
// Burn a non-rent exempt amount
let burn_amount = bank.get_minimum_balance_for_rent_exemption(0) - 1;
assert_eq!(bank.get_balance(&incinerator::id()), 0);
bank.transfer(burn_amount, &mint_keypair, &incinerator::id())
.unwrap();
assert_eq!(bank.get_balance(&incinerator::id()), burn_amount);
bank.freeze();
assert_eq!(bank.get_balance(&incinerator::id()), 0);
// Ensure that no rent was collected, and the entire burn amount was removed from bank
// capitalization
assert_eq!(bank.capitalization(), pre_capitalization - burn_amount);
}
#[test]
fn test_duplicate_account_key() {
solana_logger::setup();
let (genesis_config, mint_keypair) = create_genesis_config(500);
let mut bank = Bank::new_for_tests(&genesis_config);
let from_pubkey = solana_sdk::pubkey::new_rand();
let to_pubkey = solana_sdk::pubkey::new_rand();
let account_metas = vec![
AccountMeta::new(from_pubkey, false),
AccountMeta::new(to_pubkey, false),
];
bank.add_mockup_builtin(solana_vote_program::id(), process_instruction);
let instruction = Instruction::new_with_bincode(solana_vote_program::id(), &10, account_metas);
let mut tx = Transaction::new_signed_with_payer(
&[instruction],
Some(&mint_keypair.pubkey()),
&[&mint_keypair],
bank.last_blockhash(),
);
tx.message.account_keys.push(from_pubkey);
let result = bank.process_transaction(&tx);
assert_eq!(result, Err(TransactionError::AccountLoadedTwice));
}
#[test]
fn test_process_transaction_with_too_many_account_locks() {
solana_logger::setup();
let (genesis_config, mint_keypair) = create_genesis_config(500);
let mut bank = Bank::new_for_tests(&genesis_config);
let from_pubkey = solana_sdk::pubkey::new_rand();
let to_pubkey = solana_sdk::pubkey::new_rand();
let account_metas = vec![
AccountMeta::new(from_pubkey, false),
AccountMeta::new(to_pubkey, false),
];
bank.add_mockup_builtin(solana_vote_program::id(), process_instruction);
let instruction = Instruction::new_with_bincode(solana_vote_program::id(), &10, account_metas);
let mut tx = Transaction::new_signed_with_payer(
&[instruction],
Some(&mint_keypair.pubkey()),
&[&mint_keypair],
bank.last_blockhash(),
);
let transaction_account_lock_limit = bank.get_transaction_account_lock_limit();
while tx.message.account_keys.len() <= transaction_account_lock_limit {
tx.message.account_keys.push(solana_sdk::pubkey::new_rand());
}
let result = bank.process_transaction(&tx);
assert_eq!(result, Err(TransactionError::TooManyAccountLocks));
}
#[test]
fn test_program_id_as_payer() {
solana_logger::setup();
let (genesis_config, mint_keypair) = create_genesis_config(500);
let mut bank = Bank::new_for_tests(&genesis_config);
let from_pubkey = solana_sdk::pubkey::new_rand();
let to_pubkey = solana_sdk::pubkey::new_rand();
let account_metas = vec![
AccountMeta::new(from_pubkey, false),
AccountMeta::new(to_pubkey, false),
];
bank.add_mockup_builtin(solana_vote_program::id(), process_instruction);
let instruction = Instruction::new_with_bincode(solana_vote_program::id(), &10, account_metas);
let mut tx = Transaction::new_signed_with_payer(
&[instruction],
Some(&mint_keypair.pubkey()),
&[&mint_keypair],
bank.last_blockhash(),
);
info!(
"mint: {} account keys: {:?}",
mint_keypair.pubkey(),
tx.message.account_keys
);
assert_eq!(tx.message.account_keys.len(), 4);
tx.message.account_keys.clear();
tx.message.account_keys.push(solana_vote_program::id());
tx.message.account_keys.push(mint_keypair.pubkey());
tx.message.account_keys.push(from_pubkey);
tx.message.account_keys.push(to_pubkey);
tx.message.instructions[0].program_id_index = 0;
tx.message.instructions[0].accounts.clear();
tx.message.instructions[0].accounts.push(2);
tx.message.instructions[0].accounts.push(3);
let result = bank.process_transaction(&tx);
assert_eq!(result, Err(TransactionError::SanitizeFailure));
}
#[test]
fn test_ref_account_key_after_program_id() {
let (genesis_config, mint_keypair) = create_genesis_config(500);
let mut bank = Bank::new_for_tests(&genesis_config);
let from_pubkey = solana_sdk::pubkey::new_rand();
let to_pubkey = solana_sdk::pubkey::new_rand();
let account_metas = vec![
AccountMeta::new(from_pubkey, false),
AccountMeta::new(to_pubkey, false),
];
bank.add_mockup_builtin(solana_vote_program::id(), process_instruction);
let instruction = Instruction::new_with_bincode(solana_vote_program::id(), &10, account_metas);
let mut tx = Transaction::new_signed_with_payer(
&[instruction],
Some(&mint_keypair.pubkey()),
&[&mint_keypair],
bank.last_blockhash(),
);
tx.message.account_keys.push(solana_sdk::pubkey::new_rand());
assert_eq!(tx.message.account_keys.len(), 5);
tx.message.instructions[0].accounts.remove(0);
tx.message.instructions[0].accounts.push(4);
let result = bank.process_transaction(&tx);
assert_eq!(result, Ok(()));
}
#[test]
fn test_fuzz_instructions() {
solana_logger::setup();
use rand::{thread_rng, Rng};
let mut bank = create_simple_test_bank(1_000_000_000);
let max_programs = 5;
let program_keys: Vec<_> = (0..max_programs)
.enumerate()
.map(|i| {
let key = solana_sdk::pubkey::new_rand();
let name = format!("program{i:?}");
bank.add_builtin(
key,
name.clone(),
LoadedProgram::new_builtin(0, 0, process_instruction),
);
(key, name.as_bytes().to_vec())
})
.collect();
let max_keys = 100;
let keys: Vec<_> = (0..max_keys)
.enumerate()
.map(|_| {
let key = solana_sdk::pubkey::new_rand();
let balance = if thread_rng().gen_ratio(9, 10) {
let lamports = if thread_rng().gen_ratio(1, 5) {
thread_rng().gen_range(0, 10)
} else {
thread_rng().gen_range(20, 100)
};
let space = thread_rng().gen_range(0, 10);
let owner = Pubkey::default();
let account = AccountSharedData::new(lamports, space, &owner);
bank.store_account(&key, &account);
lamports
} else {
0
};
(key, balance)
})
.collect();
let mut results = HashMap::new();
for _ in 0..2_000 {
let num_keys = if thread_rng().gen_ratio(1, 5) {
thread_rng().gen_range(0, max_keys)
} else {
thread_rng().gen_range(1, 4)
};
let num_instructions = thread_rng().gen_range(0, max_keys - num_keys);
let mut account_keys: Vec<_> = if thread_rng().gen_ratio(1, 5) {
(0..num_keys)
.map(|_| {
let idx = thread_rng().gen_range(0, keys.len());
keys[idx].0
})
.collect()
} else {
let mut inserted = HashSet::new();
(0..num_keys)
.map(|_| {
let mut idx;
loop {
idx = thread_rng().gen_range(0, keys.len());
if !inserted.contains(&idx) {
break;
}
}
inserted.insert(idx);
keys[idx].0
})
.collect()
};
let instructions: Vec<_> = if num_keys > 0 {
(0..num_instructions)
.map(|_| {
let num_accounts_to_pass = thread_rng().gen_range(0, num_keys);
let account_indexes = (0..num_accounts_to_pass)
.map(|_| thread_rng().gen_range(0, num_keys))
.collect();
let program_index: u8 = thread_rng().gen_range(0, num_keys);
if thread_rng().gen_ratio(4, 5) {
let programs_index = thread_rng().gen_range(0, program_keys.len());
account_keys[program_index as usize] = program_keys[programs_index].0;
}
CompiledInstruction::new(program_index, &10, account_indexes)
})
.collect()
} else {
vec![]
};
let account_keys_len = std::cmp::max(account_keys.len(), 2);
let num_signatures = if thread_rng().gen_ratio(1, 5) {
thread_rng().gen_range(0, account_keys_len + 10)
} else {
thread_rng().gen_range(1, account_keys_len)
};
let num_required_signatures = if thread_rng().gen_ratio(1, 5) {
thread_rng().gen_range(0, account_keys_len + 10) as u8
} else {
thread_rng().gen_range(1, std::cmp::max(2, num_signatures)) as u8
};
let num_readonly_signed_accounts = if thread_rng().gen_ratio(1, 5) {
thread_rng().gen_range(0, account_keys_len) as u8
} else {
let max = if num_required_signatures > 1 {
num_required_signatures - 1
} else {
1
};
thread_rng().gen_range(0, max)
};
let num_readonly_unsigned_accounts = if thread_rng().gen_ratio(1, 5)
|| (num_required_signatures as usize) >= account_keys_len
{
thread_rng().gen_range(0, account_keys_len) as u8
} else {
thread_rng().gen_range(0, account_keys_len - num_required_signatures as usize) as u8
};
let header = MessageHeader {
num_required_signatures,
num_readonly_signed_accounts,
num_readonly_unsigned_accounts,
};
let message = Message {
header,
account_keys,
recent_blockhash: bank.last_blockhash(),
instructions,
};
let tx = Transaction {
signatures: vec![Signature::default(); num_signatures],
message,
};
let result = bank.process_transaction(&tx);
for (key, balance) in &keys {
assert_eq!(bank.get_balance(key), *balance);
}
for (key, name) in &program_keys {
let account = bank.get_account(key).unwrap();
assert!(account.executable());
assert_eq!(account.data(), name);
}
info!("result: {:?}", result);
let result_key = format!("{result:?}");
*results.entry(result_key).or_insert(0) += 1;
}
info!("results: {:?}", results);
}
#[test]
fn test_bank_hash_consistency() {
solana_logger::setup();
let mut genesis_config = GenesisConfig::new(
&[(
Pubkey::from([42; 32]),
AccountSharedData::new(1_000_000_000_000, 0, &system_program::id()),
)],
&[],
);
genesis_config.creation_time = 0;
genesis_config.cluster_type = ClusterType::MainnetBeta;
genesis_config.rent.burn_percent = 100;
let mut bank = Arc::new(Bank::new_for_tests(&genesis_config));
// Check a few slots, cross an epoch boundary
assert_eq!(bank.get_slots_in_epoch(0), 32);
loop {
goto_end_of_slot(Arc::get_mut(&mut bank).unwrap());
if bank.slot == 0 {
assert_eq!(
bank.hash().to_string(),
"3kzRo3M5q9j47Dxfdp9ZeEXfUTA5rxVud7jRKuttHxFz"
);
}
if bank.slot == 32 {
assert_eq!(
bank.hash().to_string(),
"bWPR5AQjsfhMypn1nLUjugmitbjHwV4rmnyTDFqCdv1"
);
}
if bank.slot == 64 {
assert_eq!(
bank.hash().to_string(),
"74hNYEVcvKU5JZwSNBYUcUWgf9Jw2Mag4b55967VPVjG"
);
}
if bank.slot == 128 {
assert_eq!(
bank.hash().to_string(),
"BvYViztQiksU8vDvMqZYBo9Lc4cgjJEmijPpqktBRMkS"
);
break;
}
bank = Arc::new(new_from_parent(&bank));
}
}
#[test]
fn test_same_program_id_uses_unqiue_executable_accounts() {
declare_process_instruction!(process_instruction, 1, |invoke_context| {
let transaction_context = &invoke_context.transaction_context;
let instruction_context = transaction_context.get_current_instruction_context()?;
let _ = instruction_context
.try_borrow_program_account(transaction_context, 1)?
.checked_add_lamports(1);
Ok(())
});
let (genesis_config, mint_keypair) = create_genesis_config(50000);
let mut bank = Bank::new_for_tests(&genesis_config);
// Add a new program
let program1_pubkey = solana_sdk::pubkey::new_rand();
bank.add_mockup_builtin(program1_pubkey, process_instruction);
// Add a new program owned by the first
let program2_pubkey = solana_sdk::pubkey::new_rand();
let mut program2_account = AccountSharedData::new(42, 1, &program1_pubkey);
program2_account.set_executable(true);
bank.store_account(&program2_pubkey, &program2_account);
let instruction = Instruction::new_with_bincode(program2_pubkey, &10, vec![]);
let tx = Transaction::new_signed_with_payer(
&[instruction.clone(), instruction],
Some(&mint_keypair.pubkey()),
&[&mint_keypair],
bank.last_blockhash(),
);
assert!(bank.process_transaction(&tx).is_ok());
assert_eq!(1, bank.get_balance(&program1_pubkey));
assert_eq!(42, bank.get_balance(&program2_pubkey));
}
fn get_shrink_account_size() -> usize {
let (genesis_config, _mint_keypair) = create_genesis_config(1_000_000_000);
// Set root for bank 0, with caching disabled so we can get the size
// of the storage for this slot
let mut bank0 = Arc::new(Bank::new_with_config_for_tests(
&genesis_config,
AccountSecondaryIndexes::default(),
AccountShrinkThreshold::default(),
));
bank0.restore_old_behavior_for_fragile_tests();
goto_end_of_slot(Arc::<Bank>::get_mut(&mut bank0).unwrap());
bank0.freeze();
bank0.squash();
add_root_and_flush_write_cache(&bank0);
let sizes = bank0
.rc
.accounts
.accounts_db
.sizes_of_accounts_in_storage_for_tests(0);
// Create an account such that it takes DEFAULT_ACCOUNTS_SHRINK_RATIO of the total account space for
// the slot, so when it gets pruned, the storage entry will become a shrink candidate.
let bank0_total_size: usize = sizes.into_iter().sum();
let pubkey0_size = (bank0_total_size as f64 / (1.0 - DEFAULT_ACCOUNTS_SHRINK_RATIO)).ceil();
assert!(
pubkey0_size / (pubkey0_size + bank0_total_size as f64) > DEFAULT_ACCOUNTS_SHRINK_RATIO
);
pubkey0_size as usize
}
#[test]
fn test_clean_nonrooted() {
solana_logger::setup();
let (genesis_config, _mint_keypair) = create_genesis_config(1_000_000_000);
let pubkey0 = Pubkey::from([0; 32]);
let pubkey1 = Pubkey::from([1; 32]);
info!("pubkey0: {}", pubkey0);
info!("pubkey1: {}", pubkey1);
// Set root for bank 0, with caching enabled
let mut bank0 = Arc::new(Bank::new_with_config_for_tests(
&genesis_config,
AccountSecondaryIndexes::default(),
AccountShrinkThreshold::default(),
));
let account_zero = AccountSharedData::new(0, 0, &Pubkey::new_unique());
goto_end_of_slot(Arc::<Bank>::get_mut(&mut bank0).unwrap());
bank0.freeze();
bank0.squash();
// Flush now so that accounts cache cleaning doesn't clean up bank 0 when later
// slots add updates to the cache
bank0.force_flush_accounts_cache();
// Store some lamports in bank 1
let some_lamports = 123;
let mut bank1 = Arc::new(Bank::new_from_parent(&bank0, &Pubkey::default(), 1));
bank1.deposit(&pubkey0, some_lamports).unwrap();
goto_end_of_slot(Arc::<Bank>::get_mut(&mut bank1).unwrap());
bank1.freeze();
bank1.flush_accounts_cache_slot_for_tests();
bank1.print_accounts_stats();
// Store some lamports for pubkey1 in bank 2, root bank 2
// bank2's parent is bank0
let mut bank2 = Arc::new(Bank::new_from_parent(&bank0, &Pubkey::default(), 2));
bank2.deposit(&pubkey1, some_lamports).unwrap();
bank2.store_account(&pubkey0, &account_zero);
goto_end_of_slot(Arc::<Bank>::get_mut(&mut bank2).unwrap());
bank2.freeze();
bank2.squash();
bank2.force_flush_accounts_cache();
bank2.print_accounts_stats();
drop(bank1);
// Clean accounts, which should add earlier slots to the shrink
// candidate set
bank2.clean_accounts_for_tests();
let mut bank3 = Arc::new(Bank::new_from_parent(&bank2, &Pubkey::default(), 3));
bank3.deposit(&pubkey1, some_lamports + 1).unwrap();
goto_end_of_slot(Arc::<Bank>::get_mut(&mut bank3).unwrap());
bank3.freeze();
bank3.squash();
bank3.force_flush_accounts_cache();
bank3.clean_accounts_for_tests();
assert_eq!(
bank3.rc.accounts.accounts_db.ref_count_for_pubkey(&pubkey0),
2
);
assert!(bank3
.rc
.accounts
.accounts_db
.storage
.get_slot_storage_entry(1)
.is_none());
bank3.print_accounts_stats();
}
#[test]
fn test_shrink_candidate_slots_cached() {
solana_logger::setup();
let (genesis_config, _mint_keypair) = create_genesis_config(1_000_000_000);
let pubkey0 = solana_sdk::pubkey::new_rand();
let pubkey1 = solana_sdk::pubkey::new_rand();
let pubkey2 = solana_sdk::pubkey::new_rand();
// Set root for bank 0, with caching enabled
let mut bank0 = Arc::new(Bank::new_with_config_for_tests(
&genesis_config,
AccountSecondaryIndexes::default(),
AccountShrinkThreshold::default(),
));
bank0.restore_old_behavior_for_fragile_tests();
let pubkey0_size = get_shrink_account_size();
let account0 = AccountSharedData::new(1000, pubkey0_size, &Pubkey::new_unique());
bank0.store_account(&pubkey0, &account0);
goto_end_of_slot(Arc::<Bank>::get_mut(&mut bank0).unwrap());
bank0.freeze();
bank0.squash();
// Flush now so that accounts cache cleaning doesn't clean up bank 0 when later
// slots add updates to the cache
bank0.force_flush_accounts_cache();
// Store some lamports in bank 1
let some_lamports = 123;
let mut bank1 = Arc::new(new_from_parent(&bank0));
bank1.deposit(&pubkey1, some_lamports).unwrap();
bank1.deposit(&pubkey2, some_lamports).unwrap();
goto_end_of_slot(Arc::<Bank>::get_mut(&mut bank1).unwrap());
bank1.freeze();
bank1.squash();
// Flush now so that accounts cache cleaning doesn't clean up bank 0 when later
// slots add updates to the cache
bank1.force_flush_accounts_cache();
// Store some lamports for pubkey1 in bank 2, root bank 2
let mut bank2 = Arc::new(new_from_parent(&bank1));
bank2.deposit(&pubkey1, some_lamports).unwrap();
bank2.store_account(&pubkey0, &account0);
goto_end_of_slot(Arc::<Bank>::get_mut(&mut bank2).unwrap());
bank2.freeze();
bank2.squash();
bank2.force_flush_accounts_cache();
// Clean accounts, which should add earlier slots to the shrink
// candidate set
bank2.clean_accounts_for_tests();
// Slots 0 and 1 should be candidates for shrinking, but slot 2
// shouldn't because none of its accounts are outdated by a later
// root
assert_eq!(bank2.shrink_candidate_slots(), 2);
let alive_counts: Vec<usize> = (0..3)
.map(|slot| {
bank2
.rc
.accounts
.accounts_db
.alive_account_count_in_slot(slot)
})
.collect();
// No more slots should be shrunk
assert_eq!(bank2.shrink_candidate_slots(), 0);
// alive_counts represents the count of alive accounts in the three slots 0,1,2
assert_eq!(alive_counts, vec![16, 1, 7]);
}
#[test]
fn test_add_builtin_no_overwrite() {
let slot = 123;
let program_id = solana_sdk::pubkey::new_rand();
let mut bank = Arc::new(Bank::new_from_parent(
&create_simple_test_arc_bank(100_000),
&Pubkey::default(),
slot,
));
assert_eq!(bank.get_account_modified_slot(&program_id), None);
Arc::get_mut(&mut bank)
.unwrap()
.add_mockup_builtin(program_id, process_instruction);
assert_eq!(bank.get_account_modified_slot(&program_id).unwrap().1, slot);
let mut bank = Arc::new(new_from_parent(&bank));
Arc::get_mut(&mut bank)
.unwrap()
.add_mockup_builtin(program_id, process_instruction);
assert_eq!(bank.get_account_modified_slot(&program_id).unwrap().1, slot);
}
#[test]
fn test_add_builtin_loader_no_overwrite() {
let slot = 123;
let loader_id = solana_sdk::pubkey::new_rand();
let mut bank = Arc::new(Bank::new_from_parent(
&create_simple_test_arc_bank(100_000),
&Pubkey::default(),
slot,
));
assert_eq!(bank.get_account_modified_slot(&loader_id), None);
Arc::get_mut(&mut bank)
.unwrap()
.add_mockup_builtin(loader_id, process_instruction);
assert_eq!(bank.get_account_modified_slot(&loader_id).unwrap().1, slot);
let mut bank = Arc::new(new_from_parent(&bank));
Arc::get_mut(&mut bank)
.unwrap()
.add_mockup_builtin(loader_id, process_instruction);
assert_eq!(bank.get_account_modified_slot(&loader_id).unwrap().1, slot);
}
#[test]
fn test_add_builtin_account() {
for pass in 0..5 {
let (mut genesis_config, _mint_keypair) = create_genesis_config(100_000);
activate_all_features(&mut genesis_config);
let slot = 123;
let program_id = solana_sdk::pubkey::new_rand();
let bank = Arc::new(Bank::new_from_parent(
&Arc::new(Bank::new_for_tests(&genesis_config)),
&Pubkey::default(),
slot,
));
add_root_and_flush_write_cache(&bank.parent().unwrap());
assert_eq!(bank.get_account_modified_slot(&program_id), None);
assert_capitalization_diff(
&bank,
|| bank.add_builtin_account("mock_program", &program_id, false),
|old, new| {
assert_eq!(old + 1, new);
pass == 0
},
);
if pass == 0 {
continue;
}
assert_eq!(bank.get_account_modified_slot(&program_id).unwrap().1, slot);
let bank = Arc::new(new_from_parent(&bank));
add_root_and_flush_write_cache(&bank.parent().unwrap());
assert_capitalization_diff(
&bank,
|| bank.add_builtin_account("mock_program", &program_id, false),
|old, new| {
assert_eq!(old, new);
pass == 1
},
);
if pass == 1 {
continue;
}
assert_eq!(bank.get_account_modified_slot(&program_id).unwrap().1, slot);
let bank = Arc::new(new_from_parent(&bank));
add_root_and_flush_write_cache(&bank.parent().unwrap());
// When replacing builtin_program, name must change to disambiguate from repeated
// invocations.
assert_capitalization_diff(
&bank,
|| bank.add_builtin_account("mock_program v2", &program_id, true),
|old, new| {
assert_eq!(old, new);
pass == 2
},
);
if pass == 2 {
continue;
}
assert_eq!(
bank.get_account_modified_slot(&program_id).unwrap().1,
bank.slot()
);
let bank = Arc::new(new_from_parent(&bank));
add_root_and_flush_write_cache(&bank.parent().unwrap());
assert_capitalization_diff(
&bank,
|| bank.add_builtin_account("mock_program v2", &program_id, true),
|old, new| {
assert_eq!(old, new);
pass == 3
},
);
if pass == 3 {
continue;
}
// replacing with same name shouldn't update account
assert_eq!(
bank.get_account_modified_slot(&program_id).unwrap().1,
bank.parent_slot()
);
}
}
/// useful to adapt tests written prior to introduction of the write cache
/// to use the write cache
fn add_root_and_flush_write_cache(bank: &Bank) {
bank.rc.accounts.add_root(bank.slot());
bank.flush_accounts_cache_slot_for_tests()
}
#[test]
fn test_add_builtin_account_inherited_cap_while_replacing() {
for pass in 0..4 {
let (genesis_config, mint_keypair) = create_genesis_config(100_000);
let bank = Bank::new_for_tests(&genesis_config);
let program_id = solana_sdk::pubkey::new_rand();
bank.add_builtin_account("mock_program", &program_id, false);
if pass == 0 {
add_root_and_flush_write_cache(&bank);
assert_eq!(bank.capitalization(), bank.calculate_capitalization(true));
continue;
}
// someone mess with program_id's balance
bank.withdraw(&mint_keypair.pubkey(), 10).unwrap();
if pass == 1 {
add_root_and_flush_write_cache(&bank);
assert_ne!(bank.capitalization(), bank.calculate_capitalization(true));
continue;
}
bank.deposit(&program_id, 10).unwrap();
if pass == 2 {
add_root_and_flush_write_cache(&bank);
assert_eq!(bank.capitalization(), bank.calculate_capitalization(true));
continue;
}
bank.add_builtin_account("mock_program v2", &program_id, true);
add_root_and_flush_write_cache(&bank);
assert_eq!(bank.capitalization(), bank.calculate_capitalization(true));
}
}
#[test]
fn test_add_builtin_account_squatted_while_not_replacing() {
for pass in 0..3 {
let (genesis_config, mint_keypair) = create_genesis_config(100_000);
let bank = Bank::new_for_tests(&genesis_config);
let program_id = solana_sdk::pubkey::new_rand();
// someone managed to squat at program_id!
bank.withdraw(&mint_keypair.pubkey(), 10).unwrap();
if pass == 0 {
add_root_and_flush_write_cache(&bank);
assert_ne!(bank.capitalization(), bank.calculate_capitalization(true));
continue;
}
bank.deposit(&program_id, 10).unwrap();
if pass == 1 {
add_root_and_flush_write_cache(&bank);
assert_eq!(bank.capitalization(), bank.calculate_capitalization(true));
continue;
}
bank.add_builtin_account("mock_program", &program_id, false);
add_root_and_flush_write_cache(&bank);
assert_eq!(bank.capitalization(), bank.calculate_capitalization(true));
}
}
#[test]
#[should_panic(
expected = "Can't change frozen bank by adding not-existing new builtin \
program (mock_program, CiXgo2KHKSDmDnV1F6B69eWFgNAPiSBjjYvfB4cvRNre). \
Maybe, inconsistent program activation is detected on snapshot restore?"
)]
fn test_add_builtin_account_after_frozen() {
let slot = 123;
let program_id = Pubkey::from_str("CiXgo2KHKSDmDnV1F6B69eWFgNAPiSBjjYvfB4cvRNre").unwrap();
let bank = Bank::new_from_parent(
&create_simple_test_arc_bank(100_000),
&Pubkey::default(),
slot,
);
bank.freeze();
bank.add_builtin_account("mock_program", &program_id, false);
}
#[test]
#[should_panic(
expected = "There is no account to replace with builtin program (mock_program, \
CiXgo2KHKSDmDnV1F6B69eWFgNAPiSBjjYvfB4cvRNre)."
)]
fn test_add_builtin_account_replace_none() {
let slot = 123;
let program_id = Pubkey::from_str("CiXgo2KHKSDmDnV1F6B69eWFgNAPiSBjjYvfB4cvRNre").unwrap();
let bank = Bank::new_from_parent(
&create_simple_test_arc_bank(100_000),
&Pubkey::default(),
slot,
);
bank.add_builtin_account("mock_program", &program_id, true);
}
#[test]
fn test_add_precompiled_account() {
for pass in 0..2 {
let (mut genesis_config, _mint_keypair) = create_genesis_config(100_000);
activate_all_features(&mut genesis_config);
let slot = 123;
let program_id = solana_sdk::pubkey::new_rand();
let bank = Arc::new(Bank::new_from_parent(
&Arc::new(Bank::new_for_tests_with_config(
&genesis_config,
BankTestConfig::default(),
)),
&Pubkey::default(),
slot,
));
add_root_and_flush_write_cache(&bank.parent().unwrap());
assert_eq!(bank.get_account_modified_slot(&program_id), None);
assert_capitalization_diff(
&bank,
|| bank.add_precompiled_account(&program_id),
|old, new| {
assert_eq!(old + 1, new);
pass == 0
},
);
if pass == 0 {
continue;
}
assert_eq!(bank.get_account_modified_slot(&program_id).unwrap().1, slot);
let bank = Arc::new(new_from_parent(&bank));
add_root_and_flush_write_cache(&bank.parent().unwrap());
assert_capitalization_diff(
&bank,
|| bank.add_precompiled_account(&program_id),
|old, new| {
assert_eq!(old, new);
true
},
);
assert_eq!(bank.get_account_modified_slot(&program_id).unwrap().1, slot);
}
}
#[test]
fn test_add_precompiled_account_inherited_cap_while_replacing() {
// when we flush the cache, it has side effects, so we have to restart the test each time we flush the cache
// and then want to continue modifying the bank
for pass in 0..4 {
let (genesis_config, mint_keypair) = create_genesis_config(100_000);
let bank = Bank::new_for_tests_with_config(&genesis_config, BankTestConfig::default());
let program_id = solana_sdk::pubkey::new_rand();
bank.add_precompiled_account(&program_id);
if pass == 0 {
add_root_and_flush_write_cache(&bank);
assert_eq!(bank.capitalization(), bank.calculate_capitalization(true));
continue;
}
// someone mess with program_id's balance
bank.withdraw(&mint_keypair.pubkey(), 10).unwrap();
if pass == 1 {
add_root_and_flush_write_cache(&bank);
assert_ne!(bank.capitalization(), bank.calculate_capitalization(true));
continue;
}
bank.deposit(&program_id, 10).unwrap();
if pass == 2 {
add_root_and_flush_write_cache(&bank);
assert_eq!(bank.capitalization(), bank.calculate_capitalization(true));
continue;
}
bank.add_precompiled_account(&program_id);
add_root_and_flush_write_cache(&bank);
assert_eq!(bank.capitalization(), bank.calculate_capitalization(true));
}
}
#[test]
fn test_add_precompiled_account_squatted_while_not_replacing() {
for pass in 0..3 {
let (genesis_config, mint_keypair) = create_genesis_config(100_000);
let bank = Bank::new_for_tests_with_config(&genesis_config, BankTestConfig::default());
let program_id = solana_sdk::pubkey::new_rand();
// someone managed to squat at program_id!
bank.withdraw(&mint_keypair.pubkey(), 10).unwrap();
if pass == 0 {
add_root_and_flush_write_cache(&bank);
assert_ne!(bank.capitalization(), bank.calculate_capitalization(true));
continue;
}
bank.deposit(&program_id, 10).unwrap();
if pass == 1 {
add_root_and_flush_write_cache(&bank);
assert_eq!(bank.capitalization(), bank.calculate_capitalization(true));
continue;
}
bank.add_precompiled_account(&program_id);
add_root_and_flush_write_cache(&bank);
assert_eq!(bank.capitalization(), bank.calculate_capitalization(true));
}
}
#[test]
#[should_panic(
expected = "Can't change frozen bank by adding not-existing new precompiled \
program (CiXgo2KHKSDmDnV1F6B69eWFgNAPiSBjjYvfB4cvRNre). \
Maybe, inconsistent program activation is detected on snapshot restore?"
)]
fn test_add_precompiled_account_after_frozen() {
let slot = 123;
let program_id = Pubkey::from_str("CiXgo2KHKSDmDnV1F6B69eWFgNAPiSBjjYvfB4cvRNre").unwrap();
let bank = Bank::new_from_parent(
&create_simple_test_arc_bank(100_000),
&Pubkey::default(),
slot,
);
bank.freeze();
bank.add_precompiled_account(&program_id);
}
#[test]
fn test_reconfigure_token2_native_mint() {
solana_logger::setup();
let mut genesis_config =
create_genesis_config_with_leader(5, &solana_sdk::pubkey::new_rand(), 0).genesis_config;
// ClusterType::Development - Native mint exists immediately
assert_eq!(genesis_config.cluster_type, ClusterType::Development);
let bank = Arc::new(Bank::new_for_tests(&genesis_config));
assert_eq!(
bank.get_balance(&inline_spl_token::native_mint::id()),
1000000000
);
// Testnet - Native mint blinks into existence at epoch 93
genesis_config.cluster_type = ClusterType::Testnet;
let bank = Arc::new(Bank::new_for_tests(&genesis_config));
assert_eq!(bank.get_balance(&inline_spl_token::native_mint::id()), 0);
bank.deposit(&inline_spl_token::native_mint::id(), 4200000000)
.unwrap();
let bank = Bank::new_from_parent(
&bank,
&Pubkey::default(),
genesis_config.epoch_schedule.get_first_slot_in_epoch(93),
);
let native_mint_account = bank
.get_account(&inline_spl_token::native_mint::id())
.unwrap();
assert_eq!(native_mint_account.data().len(), 82);
assert_eq!(
bank.get_balance(&inline_spl_token::native_mint::id()),
4200000000
);
assert_eq!(native_mint_account.owner(), &inline_spl_token::id());
// MainnetBeta - Native mint blinks into existence at epoch 75
genesis_config.cluster_type = ClusterType::MainnetBeta;
let bank = Arc::new(Bank::new_for_tests(&genesis_config));
assert_eq!(bank.get_balance(&inline_spl_token::native_mint::id()), 0);
bank.deposit(&inline_spl_token::native_mint::id(), 4200000000)
.unwrap();
let bank = Bank::new_from_parent(
&bank,
&Pubkey::default(),
genesis_config.epoch_schedule.get_first_slot_in_epoch(75),
);
let native_mint_account = bank
.get_account(&inline_spl_token::native_mint::id())
.unwrap();
assert_eq!(native_mint_account.data().len(), 82);
assert_eq!(
bank.get_balance(&inline_spl_token::native_mint::id()),
4200000000
);
assert_eq!(native_mint_account.owner(), &inline_spl_token::id());
}
#[test]
fn test_bank_load_program() {
solana_logger::setup();
let (genesis_config, _) = create_genesis_config(1);
let bank = Bank::new_for_tests(&genesis_config);
let key1 = solana_sdk::pubkey::new_rand();
let mut file = File::open("../programs/bpf_loader/test_elfs/out/noop_aligned.so").unwrap();
let mut elf = Vec::new();
file.read_to_end(&mut elf).unwrap();
let programdata_key = solana_sdk::pubkey::new_rand();
let mut program_account = AccountSharedData::new_data(
40,
&UpgradeableLoaderState::Program {
programdata_address: programdata_key,
},
&bpf_loader_upgradeable::id(),
)
.unwrap();
program_account.set_executable(true);
program_account.set_rent_epoch(1);
let programdata_data_offset = UpgradeableLoaderState::size_of_programdata_metadata();
let mut programdata_account = AccountSharedData::new(
40,
programdata_data_offset + elf.len(),
&bpf_loader_upgradeable::id(),
);
programdata_account
.set_state(&UpgradeableLoaderState::ProgramData {
slot: 42,
upgrade_authority_address: None,
})
.unwrap();
programdata_account.data_as_mut_slice()[programdata_data_offset..].copy_from_slice(&elf);
programdata_account.set_rent_epoch(1);
bank.store_account_and_update_capitalization(&key1, &program_account);
bank.store_account_and_update_capitalization(&programdata_key, &programdata_account);
let program = bank.load_program(&key1, false);
assert!(program.is_ok());
let program = program.unwrap();
assert!(matches!(program.program, LoadedProgramType::LegacyV1(_)));
assert_eq!(
program.account_size,
program_account.data().len() + programdata_account.data().len()
);
}
#[test]
fn test_bpf_loader_upgradeable_deploy_with_max_len() {
let (genesis_config, mint_keypair) = create_genesis_config(1_000_000_000);
let mut bank = Bank::new_for_tests(&genesis_config);
bank.feature_set = Arc::new(FeatureSet::all_enabled());
let bank = Arc::new(bank);
let bank_client = BankClient::new_shared(&bank);
// Setup keypairs and addresses
let payer_keypair = Keypair::new();
let program_keypair = Keypair::new();
let buffer_address = Pubkey::new_unique();
let (programdata_address, _) = Pubkey::find_program_address(
&[program_keypair.pubkey().as_ref()],
&bpf_loader_upgradeable::id(),
);
let upgrade_authority_keypair = Keypair::new();
// Load program file
let mut file = File::open("../programs/bpf_loader/test_elfs/out/noop_aligned.so")
.expect("file open failed");
let mut elf = Vec::new();
file.read_to_end(&mut elf).unwrap();
// Compute rent exempt balances
let program_len = elf.len();
let min_program_balance =
bank.get_minimum_balance_for_rent_exemption(UpgradeableLoaderState::size_of_program());
let min_buffer_balance = bank.get_minimum_balance_for_rent_exemption(
UpgradeableLoaderState::size_of_buffer(program_len),
);
let min_programdata_balance = bank.get_minimum_balance_for_rent_exemption(
UpgradeableLoaderState::size_of_programdata(program_len),
);
// Setup accounts
let buffer_account = {
let mut account = AccountSharedData::new(
min_buffer_balance,
UpgradeableLoaderState::size_of_buffer(elf.len()),
&bpf_loader_upgradeable::id(),
);
account
.set_state(&UpgradeableLoaderState::Buffer {
authority_address: Some(upgrade_authority_keypair.pubkey()),
})
.unwrap();
account
.data_as_mut_slice()
.get_mut(UpgradeableLoaderState::size_of_buffer_metadata()..)
.unwrap()
.copy_from_slice(&elf);
account
};
let program_account = AccountSharedData::new(
min_programdata_balance,
UpgradeableLoaderState::size_of_program(),
&bpf_loader_upgradeable::id(),
);
let programdata_account = AccountSharedData::new(
1,
UpgradeableLoaderState::size_of_programdata(elf.len()),
&bpf_loader_upgradeable::id(),
);
// Test successful deploy
let payer_base_balance = LAMPORTS_PER_SOL;
let deploy_fees = {
let fee_calculator = genesis_config.fee_rate_governor.create_fee_calculator();
3 * fee_calculator.lamports_per_signature
};
let min_payer_balance = min_program_balance
.saturating_add(min_programdata_balance)
.saturating_sub(min_buffer_balance.saturating_add(deploy_fees));
bank.store_account(
&payer_keypair.pubkey(),
&AccountSharedData::new(
payer_base_balance.saturating_add(min_payer_balance),
0,
&system_program::id(),
),
);
bank.store_account(&buffer_address, &buffer_account);
bank.store_account(&program_keypair.pubkey(), &AccountSharedData::default());
bank.store_account(&programdata_address, &AccountSharedData::default());
let message = Message::new(
&bpf_loader_upgradeable::deploy_with_max_program_len(
&payer_keypair.pubkey(),
&program_keypair.pubkey(),
&buffer_address,
&upgrade_authority_keypair.pubkey(),
min_program_balance,
elf.len(),
)
.unwrap(),
Some(&payer_keypair.pubkey()),
);
assert!(bank_client
.send_and_confirm_message(
&[&payer_keypair, &program_keypair, &upgrade_authority_keypair],
message
)
.is_ok());
assert_eq!(
bank.get_balance(&payer_keypair.pubkey()),
payer_base_balance
);
assert_eq!(bank.get_balance(&buffer_address), 0);
assert_eq!(None, bank.get_account(&buffer_address));
let post_program_account = bank.get_account(&program_keypair.pubkey()).unwrap();
assert_eq!(post_program_account.lamports(), min_program_balance);
assert_eq!(post_program_account.owner(), &bpf_loader_upgradeable::id());
assert_eq!(
post_program_account.data().len(),
UpgradeableLoaderState::size_of_program()
);
let state: UpgradeableLoaderState = post_program_account.state().unwrap();
assert_eq!(
state,
UpgradeableLoaderState::Program {
programdata_address
}
);
let post_programdata_account = bank.get_account(&programdata_address).unwrap();
assert_eq!(post_programdata_account.lamports(), min_programdata_balance);
assert_eq!(
post_programdata_account.owner(),
&bpf_loader_upgradeable::id()
);
let state: UpgradeableLoaderState = post_programdata_account.state().unwrap();
assert_eq!(
state,
UpgradeableLoaderState::ProgramData {
slot: bank_client.get_slot().unwrap(),
upgrade_authority_address: Some(upgrade_authority_keypair.pubkey())
}
);
for (i, byte) in post_programdata_account
.data()
.get(UpgradeableLoaderState::size_of_programdata_metadata()..)
.unwrap()
.iter()
.enumerate()
{
assert_eq!(*elf.get(i).unwrap(), *byte);
}
let loaded_program = bank
.load_program(&program_keypair.pubkey(), false)
.expect("Failed to load the program");
// Invoke deployed program
mock_process_instruction(
&bpf_loader_upgradeable::id(),
vec![0, 1],
&[],
vec![
(programdata_address, post_programdata_account),
(program_keypair.pubkey(), post_program_account),
],
Vec::new(),
Ok(()),
solana_bpf_loader_program::process_instruction,
|invoke_context| {
invoke_context
.programs_modified_by_tx
.set_slot_for_tests(bank.slot() + DELAY_VISIBILITY_SLOT_OFFSET);
invoke_context
.programs_modified_by_tx
.replenish(program_keypair.pubkey(), loaded_program.clone());
},
|_invoke_context| {},
);
// Test initialized program account
bank.clear_signatures();
bank.store_account(&buffer_address, &buffer_account);
let message = Message::new(
&[Instruction::new_with_bincode(
bpf_loader_upgradeable::id(),
&UpgradeableLoaderInstruction::DeployWithMaxDataLen {
max_data_len: elf.len(),
},
vec![
AccountMeta::new(mint_keypair.pubkey(), true),
AccountMeta::new(programdata_address, false),
AccountMeta::new(program_keypair.pubkey(), false),
AccountMeta::new(buffer_address, false),
AccountMeta::new_readonly(sysvar::rent::id(), false),
AccountMeta::new_readonly(sysvar::clock::id(), false),
AccountMeta::new_readonly(system_program::id(), false),
AccountMeta::new_readonly(upgrade_authority_keypair.pubkey(), true),
],
)],
Some(&mint_keypair.pubkey()),
);
assert_eq!(
TransactionError::InstructionError(0, InstructionError::AccountAlreadyInitialized),
bank_client
.send_and_confirm_message(&[&mint_keypair, &upgrade_authority_keypair], message)
.unwrap_err()
.unwrap()
);
// Test initialized ProgramData account
bank.clear_signatures();
bank.store_account(&buffer_address, &buffer_account);
bank.store_account(&program_keypair.pubkey(), &AccountSharedData::default());
let message = Message::new(
&bpf_loader_upgradeable::deploy_with_max_program_len(
&mint_keypair.pubkey(),
&program_keypair.pubkey(),
&buffer_address,
&upgrade_authority_keypair.pubkey(),
min_program_balance,
elf.len(),
)
.unwrap(),
Some(&mint_keypair.pubkey()),
);
assert_eq!(
TransactionError::InstructionError(1, InstructionError::Custom(0)),
bank_client
.send_and_confirm_message(
&[&mint_keypair, &program_keypair, &upgrade_authority_keypair],
message
)
.unwrap_err()
.unwrap()
);
// Test deploy no authority
bank.clear_signatures();
bank.store_account(&buffer_address, &buffer_account);
bank.store_account(&program_keypair.pubkey(), &program_account);
bank.store_account(&programdata_address, &programdata_account);
let message = Message::new(
&[Instruction::new_with_bincode(
bpf_loader_upgradeable::id(),
&UpgradeableLoaderInstruction::DeployWithMaxDataLen {
max_data_len: elf.len(),
},
vec![
AccountMeta::new(mint_keypair.pubkey(), true),
AccountMeta::new(programdata_address, false),
AccountMeta::new(program_keypair.pubkey(), false),
AccountMeta::new(buffer_address, false),
AccountMeta::new_readonly(sysvar::rent::id(), false),
AccountMeta::new_readonly(sysvar::clock::id(), false),
AccountMeta::new_readonly(system_program::id(), false),
],
)],
Some(&mint_keypair.pubkey()),
);
assert_eq!(
TransactionError::InstructionError(0, InstructionError::NotEnoughAccountKeys),
bank_client
.send_and_confirm_message(&[&mint_keypair], message)
.unwrap_err()
.unwrap()
);
// Test deploy authority not a signer
bank.clear_signatures();
bank.store_account(&buffer_address, &buffer_account);
bank.store_account(&program_keypair.pubkey(), &program_account);
bank.store_account(&programdata_address, &programdata_account);
let message = Message::new(
&[Instruction::new_with_bincode(
bpf_loader_upgradeable::id(),
&UpgradeableLoaderInstruction::DeployWithMaxDataLen {
max_data_len: elf.len(),
},
vec![
AccountMeta::new(mint_keypair.pubkey(), true),
AccountMeta::new(programdata_address, false),
AccountMeta::new(program_keypair.pubkey(), false),
AccountMeta::new(buffer_address, false),
AccountMeta::new_readonly(sysvar::rent::id(), false),
AccountMeta::new_readonly(sysvar::clock::id(), false),
AccountMeta::new_readonly(system_program::id(), false),
AccountMeta::new_readonly(upgrade_authority_keypair.pubkey(), false),
],
)],
Some(&mint_keypair.pubkey()),
);
assert_eq!(
TransactionError::InstructionError(0, InstructionError::MissingRequiredSignature),
bank_client
.send_and_confirm_message(&[&mint_keypair], message)
.unwrap_err()
.unwrap()
);
// Test invalid Buffer account state
bank.clear_signatures();
bank.store_account(&buffer_address, &AccountSharedData::default());
bank.store_account(&program_keypair.pubkey(), &AccountSharedData::default());
bank.store_account(&programdata_address, &AccountSharedData::default());
let message = Message::new(
&bpf_loader_upgradeable::deploy_with_max_program_len(
&mint_keypair.pubkey(),
&program_keypair.pubkey(),
&buffer_address,
&upgrade_authority_keypair.pubkey(),
min_program_balance,
elf.len(),
)
.unwrap(),
Some(&mint_keypair.pubkey()),
);
assert_eq!(
TransactionError::InstructionError(1, InstructionError::InvalidAccountData),
bank_client
.send_and_confirm_message(
&[&mint_keypair, &program_keypair, &upgrade_authority_keypair],
message
)
.unwrap_err()
.unwrap()
);
// Test program account not rent exempt
bank.clear_signatures();
bank.store_account(&buffer_address, &buffer_account);
bank.store_account(&program_keypair.pubkey(), &AccountSharedData::default());
bank.store_account(&programdata_address, &AccountSharedData::default());
let message = Message::new(
&bpf_loader_upgradeable::deploy_with_max_program_len(
&mint_keypair.pubkey(),
&program_keypair.pubkey(),
&buffer_address,
&upgrade_authority_keypair.pubkey(),
min_program_balance.saturating_sub(1),
elf.len(),
)
.unwrap(),
Some(&mint_keypair.pubkey()),
);
assert_eq!(
TransactionError::InstructionError(1, InstructionError::ExecutableAccountNotRentExempt),
bank_client
.send_and_confirm_message(
&[&mint_keypair, &program_keypair, &upgrade_authority_keypair],
message
)
.unwrap_err()
.unwrap()
);
// Test program account not rent exempt because data is larger than needed
bank.clear_signatures();
bank.store_account(&buffer_address, &buffer_account);
bank.store_account(&program_keypair.pubkey(), &AccountSharedData::default());
bank.store_account(&programdata_address, &AccountSharedData::default());
let mut instructions = bpf_loader_upgradeable::deploy_with_max_program_len(
&mint_keypair.pubkey(),
&program_keypair.pubkey(),
&buffer_address,
&upgrade_authority_keypair.pubkey(),
min_program_balance,
elf.len(),
)
.unwrap();
*instructions.get_mut(0).unwrap() = system_instruction::create_account(
&mint_keypair.pubkey(),
&program_keypair.pubkey(),
min_program_balance,
(UpgradeableLoaderState::size_of_program() as u64).saturating_add(1),
&bpf_loader_upgradeable::id(),
);
let message = Message::new(&instructions, Some(&mint_keypair.pubkey()));
assert_eq!(
TransactionError::InstructionError(1, InstructionError::ExecutableAccountNotRentExempt),
bank_client
.send_and_confirm_message(
&[&mint_keypair, &program_keypair, &upgrade_authority_keypair],
message
)
.unwrap_err()
.unwrap()
);
// Test program account too small
bank.clear_signatures();
bank.store_account(&buffer_address, &buffer_account);
bank.store_account(&program_keypair.pubkey(), &AccountSharedData::default());
bank.store_account(&programdata_address, &AccountSharedData::default());
let mut instructions = bpf_loader_upgradeable::deploy_with_max_program_len(
&mint_keypair.pubkey(),
&program_keypair.pubkey(),
&buffer_address,
&upgrade_authority_keypair.pubkey(),
min_program_balance,
elf.len(),
)
.unwrap();
*instructions.get_mut(0).unwrap() = system_instruction::create_account(
&mint_keypair.pubkey(),
&program_keypair.pubkey(),
min_program_balance,
(UpgradeableLoaderState::size_of_program() as u64).saturating_sub(1),
&bpf_loader_upgradeable::id(),
);
let message = Message::new(&instructions, Some(&mint_keypair.pubkey()));
assert_eq!(
TransactionError::InstructionError(1, InstructionError::AccountDataTooSmall),
bank_client
.send_and_confirm_message(
&[&mint_keypair, &program_keypair, &upgrade_authority_keypair],
message
)
.unwrap_err()
.unwrap()
);
// Test Insufficient payer funds (need more funds to cover the
// difference between buffer lamports and programdata lamports)
bank.clear_signatures();
bank.store_account(
&mint_keypair.pubkey(),
&AccountSharedData::new(
deploy_fees.saturating_add(min_program_balance),
0,
&system_program::id(),
),
);
bank.store_account(&buffer_address, &buffer_account);
bank.store_account(&program_keypair.pubkey(), &AccountSharedData::default());
bank.store_account(&programdata_address, &AccountSharedData::default());
let message = Message::new(
&bpf_loader_upgradeable::deploy_with_max_program_len(
&mint_keypair.pubkey(),
&program_keypair.pubkey(),
&buffer_address,
&upgrade_authority_keypair.pubkey(),
min_program_balance,
elf.len(),
)
.unwrap(),
Some(&mint_keypair.pubkey()),
);
assert_eq!(
TransactionError::InstructionError(1, InstructionError::Custom(1)),
bank_client
.send_and_confirm_message(
&[&mint_keypair, &program_keypair, &upgrade_authority_keypair],
message
)
.unwrap_err()
.unwrap()
);
bank.store_account(
&mint_keypair.pubkey(),
&AccountSharedData::new(1_000_000_000, 0, &system_program::id()),
);
// Test max_data_len
bank.clear_signatures();
bank.store_account(&buffer_address, &buffer_account);
bank.store_account(&program_keypair.pubkey(), &AccountSharedData::default());
bank.store_account(&programdata_address, &AccountSharedData::default());
let message = Message::new(
&bpf_loader_upgradeable::deploy_with_max_program_len(
&mint_keypair.pubkey(),
&program_keypair.pubkey(),
&buffer_address,
&upgrade_authority_keypair.pubkey(),
min_program_balance,
elf.len().saturating_sub(1),
)
.unwrap(),
Some(&mint_keypair.pubkey()),
);
assert_eq!(
TransactionError::InstructionError(1, InstructionError::AccountDataTooSmall),
bank_client
.send_and_confirm_message(
&[&mint_keypair, &program_keypair, &upgrade_authority_keypair],
message
)
.unwrap_err()
.unwrap()
);
// Test max_data_len too large
bank.clear_signatures();
bank.store_account(
&mint_keypair.pubkey(),
&AccountSharedData::new(u64::MAX / 2, 0, &system_program::id()),
);
let mut modified_buffer_account = buffer_account.clone();
modified_buffer_account.set_lamports(u64::MAX / 2);
bank.store_account(&buffer_address, &modified_buffer_account);
bank.store_account(&program_keypair.pubkey(), &AccountSharedData::default());
bank.store_account(&programdata_address, &AccountSharedData::default());
let message = Message::new(
&bpf_loader_upgradeable::deploy_with_max_program_len(
&mint_keypair.pubkey(),
&program_keypair.pubkey(),
&buffer_address,
&upgrade_authority_keypair.pubkey(),
min_program_balance,
usize::MAX,
)
.unwrap(),
Some(&mint_keypair.pubkey()),
);
assert_eq!(
TransactionError::InstructionError(1, InstructionError::InvalidArgument),
bank_client
.send_and_confirm_message(
&[&mint_keypair, &program_keypair, &upgrade_authority_keypair],
message
)
.unwrap_err()
.unwrap()
);
// Test not the system account
bank.clear_signatures();
bank.store_account(&buffer_address, &buffer_account);
bank.store_account(&program_keypair.pubkey(), &AccountSharedData::default());
bank.store_account(&programdata_address, &AccountSharedData::default());
let mut instructions = bpf_loader_upgradeable::deploy_with_max_program_len(
&mint_keypair.pubkey(),
&program_keypair.pubkey(),
&buffer_address,
&upgrade_authority_keypair.pubkey(),
min_program_balance,
elf.len(),
)
.unwrap();
*instructions
.get_mut(1)
.unwrap()
.accounts
.get_mut(6)
.unwrap() = AccountMeta::new_readonly(Pubkey::new_unique(), false);
let message = Message::new(&instructions, Some(&mint_keypair.pubkey()));
assert_eq!(
TransactionError::InstructionError(1, InstructionError::MissingAccount),
bank_client
.send_and_confirm_message(
&[&mint_keypair, &program_keypair, &upgrade_authority_keypair],
message
)
.unwrap_err()
.unwrap()
);
fn truncate_data(account: &mut AccountSharedData, len: usize) {
let mut data = account.data().to_vec();
data.truncate(len);
account.set_data(data);
}
// Test Bad ELF data
bank.clear_signatures();
let mut modified_buffer_account = buffer_account;
truncate_data(
&mut modified_buffer_account,
UpgradeableLoaderState::size_of_buffer(1),
);
bank.store_account(&buffer_address, &modified_buffer_account);
bank.store_account(&program_keypair.pubkey(), &AccountSharedData::default());
bank.store_account(&programdata_address, &AccountSharedData::default());
let message = Message::new(
&bpf_loader_upgradeable::deploy_with_max_program_len(
&mint_keypair.pubkey(),
&program_keypair.pubkey(),
&buffer_address,
&upgrade_authority_keypair.pubkey(),
min_program_balance,
elf.len(),
)
.unwrap(),
Some(&mint_keypair.pubkey()),
);
assert_eq!(
TransactionError::InstructionError(1, InstructionError::InvalidAccountData),
bank_client
.send_and_confirm_message(
&[&mint_keypair, &program_keypair, &upgrade_authority_keypair],
message
)
.unwrap_err()
.unwrap()
);
// Test small buffer account
bank.clear_signatures();
let mut modified_buffer_account = AccountSharedData::new(
min_programdata_balance,
UpgradeableLoaderState::size_of_buffer(elf.len()),
&bpf_loader_upgradeable::id(),
);
modified_buffer_account
.set_state(&UpgradeableLoaderState::Buffer {
authority_address: Some(upgrade_authority_keypair.pubkey()),
})
.unwrap();
modified_buffer_account
.data_as_mut_slice()
.get_mut(UpgradeableLoaderState::size_of_buffer_metadata()..)
.unwrap()
.copy_from_slice(&elf);
truncate_data(&mut modified_buffer_account, 5);
bank.store_account(&buffer_address, &modified_buffer_account);
bank.store_account(&program_keypair.pubkey(), &AccountSharedData::default());
bank.store_account(&programdata_address, &AccountSharedData::default());
let message = Message::new(
&bpf_loader_upgradeable::deploy_with_max_program_len(
&mint_keypair.pubkey(),
&program_keypair.pubkey(),
&buffer_address,
&upgrade_authority_keypair.pubkey(),
min_program_balance,
elf.len(),
)
.unwrap(),
Some(&mint_keypair.pubkey()),
);
assert_eq!(
TransactionError::InstructionError(1, InstructionError::InvalidAccountData),
bank_client
.send_and_confirm_message(
&[&mint_keypair, &program_keypair, &upgrade_authority_keypair],
message
)
.unwrap_err()
.unwrap()
);
// Mismatched buffer and program authority
bank.clear_signatures();
let mut modified_buffer_account = AccountSharedData::new(
min_programdata_balance,
UpgradeableLoaderState::size_of_buffer(elf.len()),
&bpf_loader_upgradeable::id(),
);
modified_buffer_account
.set_state(&UpgradeableLoaderState::Buffer {
authority_address: Some(buffer_address),
})
.unwrap();
modified_buffer_account
.data_as_mut_slice()
.get_mut(UpgradeableLoaderState::size_of_buffer_metadata()..)
.unwrap()
.copy_from_slice(&elf);
bank.store_account(&buffer_address, &modified_buffer_account);
bank.store_account(&program_keypair.pubkey(), &AccountSharedData::default());
bank.store_account(&programdata_address, &AccountSharedData::default());
let message = Message::new(
&bpf_loader_upgradeable::deploy_with_max_program_len(
&mint_keypair.pubkey(),
&program_keypair.pubkey(),
&buffer_address,
&upgrade_authority_keypair.pubkey(),
min_program_balance,
elf.len(),
)
.unwrap(),
Some(&mint_keypair.pubkey()),
);
assert_eq!(
TransactionError::InstructionError(1, InstructionError::IncorrectAuthority),
bank_client
.send_and_confirm_message(
&[&mint_keypair, &program_keypair, &upgrade_authority_keypair],
message
)
.unwrap_err()
.unwrap()
);
// Deploy buffer with mismatched None authority
bank.clear_signatures();
let mut modified_buffer_account = AccountSharedData::new(
min_programdata_balance,
UpgradeableLoaderState::size_of_buffer(elf.len()),
&bpf_loader_upgradeable::id(),
);
modified_buffer_account
.set_state(&UpgradeableLoaderState::Buffer {
authority_address: None,
})
.unwrap();
modified_buffer_account
.data_as_mut_slice()
.get_mut(UpgradeableLoaderState::size_of_buffer_metadata()..)
.unwrap()
.copy_from_slice(&elf);
bank.store_account(&buffer_address, &modified_buffer_account);
bank.store_account(&program_keypair.pubkey(), &AccountSharedData::default());
bank.store_account(&programdata_address, &AccountSharedData::default());
let message = Message::new(
&bpf_loader_upgradeable::deploy_with_max_program_len(
&mint_keypair.pubkey(),
&program_keypair.pubkey(),
&buffer_address,
&upgrade_authority_keypair.pubkey(),
min_program_balance,
elf.len(),
)
.unwrap(),
Some(&mint_keypair.pubkey()),
);
assert_eq!(
TransactionError::InstructionError(1, InstructionError::IncorrectAuthority),
bank_client
.send_and_confirm_message(
&[&mint_keypair, &program_keypair, &upgrade_authority_keypair],
message
)
.unwrap_err()
.unwrap()
);
}
#[test]
fn test_compute_active_feature_set() {
let bank0 = create_simple_test_arc_bank(100_000);
let mut bank = Bank::new_from_parent(&bank0, &Pubkey::default(), 1);
let test_feature = "TestFeature11111111111111111111111111111111"
.parse::<Pubkey>()
.unwrap();
let mut feature_set = FeatureSet::default();
feature_set.inactive.insert(test_feature);
bank.feature_set = Arc::new(feature_set.clone());
let new_activations = bank.compute_active_feature_set(true);
assert!(new_activations.is_empty());
assert!(!bank.feature_set.is_active(&test_feature));
// Depositing into the `test_feature` account should do nothing
bank.deposit(&test_feature, 42).unwrap();
let new_activations = bank.compute_active_feature_set(true);
assert!(new_activations.is_empty());
assert!(!bank.feature_set.is_active(&test_feature));
// Request `test_feature` activation
let feature = Feature::default();
assert_eq!(feature.activated_at, None);
bank.store_account(&test_feature, &feature::create_account(&feature, 42));
// Run `compute_active_feature_set` disallowing new activations
let new_activations = bank.compute_active_feature_set(false);
assert!(new_activations.is_empty());
assert!(!bank.feature_set.is_active(&test_feature));
let feature = feature::from_account(&bank.get_account(&test_feature).expect("get_account"))
.expect("from_account");
assert_eq!(feature.activated_at, None);
// Run `compute_active_feature_set` allowing new activations
let new_activations = bank.compute_active_feature_set(true);
assert_eq!(new_activations.len(), 1);
assert!(bank.feature_set.is_active(&test_feature));
let feature = feature::from_account(&bank.get_account(&test_feature).expect("get_account"))
.expect("from_account");
assert_eq!(feature.activated_at, Some(1));
// Reset the bank's feature set
bank.feature_set = Arc::new(feature_set);
assert!(!bank.feature_set.is_active(&test_feature));
// Running `compute_active_feature_set` will not cause new activations, but
// `test_feature` is now be active
let new_activations = bank.compute_active_feature_set(true);
assert!(new_activations.is_empty());
assert!(bank.feature_set.is_active(&test_feature));
}
#[test]
fn test_program_replacement() {
let mut bank = create_simple_test_bank(0);
// Setup original program account
let old_address = Pubkey::new_unique();
let new_address = Pubkey::new_unique();
bank.store_account_and_update_capitalization(
&old_address,
&AccountSharedData::from(Account {
lamports: 100,
..Account::default()
}),
);
assert_eq!(bank.get_balance(&old_address), 100);
// Setup new program account
let new_program_account = AccountSharedData::from(Account {
lamports: 123,
..Account::default()
});
bank.store_account_and_update_capitalization(&new_address, &new_program_account);
assert_eq!(bank.get_balance(&new_address), 123);
let original_capitalization = bank.capitalization();
bank.replace_program_account(&old_address, &new_address, "bank-apply_program_replacement");
// New program account is now empty
assert_eq!(bank.get_balance(&new_address), 0);
// Old program account holds the new program account
assert_eq!(bank.get_account(&old_address), Some(new_program_account));
// Lamports in the old token account were burnt
assert_eq!(bank.capitalization(), original_capitalization - 100);
}
fn min_rent_exempt_balance_for_sysvars(bank: &Bank, sysvar_ids: &[Pubkey]) -> u64 {
sysvar_ids
.iter()
.map(|sysvar_id| {
trace!("min_rent_excempt_balance_for_sysvars: {}", sysvar_id);
bank.get_minimum_balance_for_rent_exemption(
bank.get_account(sysvar_id).unwrap().data().len(),
)
})
.sum()
}
#[test]
fn test_adjust_sysvar_balance_for_rent() {
let bank = create_simple_test_bank(0);
let mut smaller_sample_sysvar = AccountSharedData::new(1, 0, &Pubkey::default());
assert_eq!(smaller_sample_sysvar.lamports(), 1);
bank.adjust_sysvar_balance_for_rent(&mut smaller_sample_sysvar);
assert_eq!(
smaller_sample_sysvar.lamports(),
bank.get_minimum_balance_for_rent_exemption(smaller_sample_sysvar.data().len()),
);
let mut bigger_sample_sysvar = AccountSharedData::new(
1,
smaller_sample_sysvar.data().len() + 1,
&Pubkey::default(),
);
bank.adjust_sysvar_balance_for_rent(&mut bigger_sample_sysvar);
assert!(smaller_sample_sysvar.lamports() < bigger_sample_sysvar.lamports());
// excess lamports shouldn't be reduced by adjust_sysvar_balance_for_rent()
let excess_lamports = smaller_sample_sysvar.lamports() + 999;
smaller_sample_sysvar.set_lamports(excess_lamports);
bank.adjust_sysvar_balance_for_rent(&mut smaller_sample_sysvar);
assert_eq!(smaller_sample_sysvar.lamports(), excess_lamports);
}
#[test]
fn test_update_clock_timestamp() {
let leader_pubkey = solana_sdk::pubkey::new_rand();
let GenesisConfigInfo {
genesis_config,
voting_keypair,
..
} = create_genesis_config_with_leader(5, &leader_pubkey, 3);
let mut bank = Bank::new_for_tests(&genesis_config);
// Advance past slot 0, which has special handling.
bank = new_from_parent(&Arc::new(bank));
bank = new_from_parent(&Arc::new(bank));
assert_eq!(
bank.clock().unix_timestamp,
bank.unix_timestamp_from_genesis()
);
bank.update_clock(None);
assert_eq!(
bank.clock().unix_timestamp,
bank.unix_timestamp_from_genesis()
);
update_vote_account_timestamp(
BlockTimestamp {
slot: bank.slot(),
timestamp: bank.unix_timestamp_from_genesis() - 1,
},
&bank,
&voting_keypair.pubkey(),
);
bank.update_clock(None);
assert_eq!(
bank.clock().unix_timestamp,
bank.unix_timestamp_from_genesis()
);
update_vote_account_timestamp(
BlockTimestamp {
slot: bank.slot(),
timestamp: bank.unix_timestamp_from_genesis(),
},
&bank,
&voting_keypair.pubkey(),
);
bank.update_clock(None);
assert_eq!(
bank.clock().unix_timestamp,
bank.unix_timestamp_from_genesis()
);
update_vote_account_timestamp(
BlockTimestamp {
slot: bank.slot(),
timestamp: bank.unix_timestamp_from_genesis() + 1,
},
&bank,
&voting_keypair.pubkey(),
);
bank.update_clock(None);
assert_eq!(
bank.clock().unix_timestamp,
bank.unix_timestamp_from_genesis() + 1
);
// Timestamp cannot go backward from ancestor Bank to child
bank = new_from_parent(&Arc::new(bank));
update_vote_account_timestamp(
BlockTimestamp {
slot: bank.slot(),
timestamp: bank.unix_timestamp_from_genesis() - 1,
},
&bank,
&voting_keypair.pubkey(),
);
bank.update_clock(None);
assert_eq!(
bank.clock().unix_timestamp,
bank.unix_timestamp_from_genesis()
);
}
fn poh_estimate_offset(bank: &Bank) -> Duration {
let mut epoch_start_slot = bank.epoch_schedule.get_first_slot_in_epoch(bank.epoch());
if epoch_start_slot == bank.slot() {
epoch_start_slot = bank
.epoch_schedule
.get_first_slot_in_epoch(bank.epoch() - 1);
}
bank.slot().saturating_sub(epoch_start_slot) as u32
* Duration::from_nanos(bank.ns_per_slot as u64)
}
#[test]
fn test_timestamp_slow() {
fn max_allowable_delta_since_epoch(bank: &Bank, max_allowable_drift: u32) -> i64 {
let poh_estimate_offset = poh_estimate_offset(bank);
(poh_estimate_offset.as_secs()
+ (poh_estimate_offset * max_allowable_drift / 100).as_secs()) as i64
}
let leader_pubkey = solana_sdk::pubkey::new_rand();
let GenesisConfigInfo {
mut genesis_config,
voting_keypair,
..
} = create_genesis_config_with_leader(5, &leader_pubkey, 3);
let slots_in_epoch = 32;
genesis_config.epoch_schedule = EpochSchedule::new(slots_in_epoch);
let mut bank = Bank::new_for_tests(&genesis_config);
let slot_duration = Duration::from_nanos(bank.ns_per_slot as u64);
let recent_timestamp: UnixTimestamp = bank.unix_timestamp_from_genesis();
let additional_secs =
((slot_duration * MAX_ALLOWABLE_DRIFT_PERCENTAGE_SLOW_V2 * 32) / 100).as_secs() as i64 + 1; // Greater than max_allowable_drift_slow_v2 for full epoch
update_vote_account_timestamp(
BlockTimestamp {
slot: bank.slot(),
timestamp: recent_timestamp + additional_secs,
},
&bank,
&voting_keypair.pubkey(),
);
// additional_secs greater than MAX_ALLOWABLE_DRIFT_PERCENTAGE_SLOW_V2 for an epoch
// timestamp bounded to 150% deviation
for _ in 0..31 {
bank = new_from_parent(&Arc::new(bank));
assert_eq!(
bank.clock().unix_timestamp,
bank.clock().epoch_start_timestamp
+ max_allowable_delta_since_epoch(&bank, MAX_ALLOWABLE_DRIFT_PERCENTAGE_SLOW_V2),
);
assert_eq!(bank.clock().epoch_start_timestamp, recent_timestamp);
}
}
#[test]
fn test_timestamp_fast() {
fn max_allowable_delta_since_epoch(bank: &Bank, max_allowable_drift: u32) -> i64 {
let poh_estimate_offset = poh_estimate_offset(bank);
(poh_estimate_offset.as_secs()
- (poh_estimate_offset * max_allowable_drift / 100).as_secs()) as i64
}
let leader_pubkey = solana_sdk::pubkey::new_rand();
let GenesisConfigInfo {
mut genesis_config,
voting_keypair,
..
} = create_genesis_config_with_leader(5, &leader_pubkey, 3);
let slots_in_epoch = 32;
genesis_config.epoch_schedule = EpochSchedule::new(slots_in_epoch);
let mut bank = Bank::new_for_tests(&genesis_config);
let recent_timestamp: UnixTimestamp = bank.unix_timestamp_from_genesis();
let additional_secs = 5; // Greater than MAX_ALLOWABLE_DRIFT_PERCENTAGE_FAST for full epoch
update_vote_account_timestamp(
BlockTimestamp {
slot: bank.slot(),
timestamp: recent_timestamp - additional_secs,
},
&bank,
&voting_keypair.pubkey(),
);
// additional_secs greater than MAX_ALLOWABLE_DRIFT_PERCENTAGE_FAST for an epoch
// timestamp bounded to 25% deviation
for _ in 0..31 {
bank = new_from_parent(&Arc::new(bank));
assert_eq!(
bank.clock().unix_timestamp,
bank.clock().epoch_start_timestamp
+ max_allowable_delta_since_epoch(&bank, MAX_ALLOWABLE_DRIFT_PERCENTAGE_FAST),
);
assert_eq!(bank.clock().epoch_start_timestamp, recent_timestamp);
}
}
#[test]
fn test_program_is_native_loader() {
let (genesis_config, mint_keypair) = create_genesis_config(50000);
let bank = Bank::new_for_tests(&genesis_config);
let tx = Transaction::new_signed_with_payer(
&[Instruction::new_with_bincode(
native_loader::id(),
&(),
vec![],
)],
Some(&mint_keypair.pubkey()),
&[&mint_keypair],
bank.last_blockhash(),
);
assert_eq!(
bank.process_transaction(&tx),
Err(TransactionError::InstructionError(
0,
InstructionError::UnsupportedProgramId
))
);
}
#[test]
fn test_debug_bank() {
let (genesis_config, _mint_keypair) = create_genesis_config(50000);
let mut bank = Bank::new_for_tests(&genesis_config);
bank.finish_init(&genesis_config, None, false);
let debug = format!("{bank:#?}");
assert!(!debug.is_empty());
}
#[derive(Debug)]
enum AcceptableScanResults {
DroppedSlotError,
NoFailure,
Both,
}
fn test_store_scan_consistency<F: 'static>(
update_f: F,
drop_callback: Option<Box<dyn DropCallback + Send + Sync>>,
acceptable_scan_results: AcceptableScanResults,
) where
F: Fn(
Arc<Bank>,
crossbeam_channel::Sender<Arc<Bank>>,
crossbeam_channel::Receiver<BankId>,
Arc<HashSet<Pubkey>>,
Pubkey,
u64,
) + std::marker::Send,
{
solana_logger::setup();
// Set up initial bank
let mut genesis_config =
create_genesis_config_with_leader(10, &solana_sdk::pubkey::new_rand(), 374_999_998_287_840)
.genesis_config;
genesis_config.rent = Rent::free();
let bank0 = Arc::new(Bank::new_with_config_for_tests(
&genesis_config,
AccountSecondaryIndexes::default(),
AccountShrinkThreshold::default(),
));
bank0.set_callback(drop_callback);
// Set up pubkeys to write to
let total_pubkeys = ITER_BATCH_SIZE * 10;
let total_pubkeys_to_modify = 10;
let all_pubkeys: Vec<Pubkey> = std::iter::repeat_with(solana_sdk::pubkey::new_rand)
.take(total_pubkeys)
.collect();
let program_id = system_program::id();
let starting_lamports = 1;
let starting_account = AccountSharedData::new(starting_lamports, 0, &program_id);
// Write accounts to the store
for key in &all_pubkeys {
bank0.store_account(key, &starting_account);
}
// Set aside a subset of accounts to modify
let pubkeys_to_modify: Arc<HashSet<Pubkey>> = Arc::new(
all_pubkeys
.into_iter()
.take(total_pubkeys_to_modify)
.collect(),
);
let exit = Arc::new(AtomicBool::new(false));
// Thread that runs scan and constantly checks for
// consistency
let pubkeys_to_modify_ = pubkeys_to_modify.clone();
// Channel over which the bank to scan is sent
let (bank_to_scan_sender, bank_to_scan_receiver): (
crossbeam_channel::Sender<Arc<Bank>>,
crossbeam_channel::Receiver<Arc<Bank>>,
) = bounded(1);
let (scan_finished_sender, scan_finished_receiver): (
crossbeam_channel::Sender<BankId>,
crossbeam_channel::Receiver<BankId>,
) = unbounded();
let num_banks_scanned = Arc::new(AtomicU64::new(0));
let scan_thread = {
let exit = exit.clone();
let num_banks_scanned = num_banks_scanned.clone();
Builder::new()
.name("scan".to_string())
.spawn(move || {
loop {
info!("starting scan iteration");
if exit.load(Relaxed) {
info!("scan exiting");
return;
}
if let Ok(bank_to_scan) =
bank_to_scan_receiver.recv_timeout(Duration::from_millis(10))
{
info!("scanning program accounts for slot {}", bank_to_scan.slot());
let accounts_result =
bank_to_scan.get_program_accounts(&program_id, &ScanConfig::default());
let _ = scan_finished_sender.send(bank_to_scan.bank_id());
num_banks_scanned.fetch_add(1, Relaxed);
match (&acceptable_scan_results, accounts_result.is_err()) {
(AcceptableScanResults::DroppedSlotError, _)
| (AcceptableScanResults::Both, true) => {
assert_eq!(
accounts_result,
Err(ScanError::SlotRemoved {
slot: bank_to_scan.slot(),
bank_id: bank_to_scan.bank_id()
})
);
}
(AcceptableScanResults::NoFailure, _)
| (AcceptableScanResults::Both, false) => {
assert!(accounts_result.is_ok())
}
}
// Should never see empty accounts because no slot ever deleted
// any of the original accounts, and the scan should reflect the
// account state at some frozen slot `X` (no partial updates).
if let Ok(accounts) = accounts_result {
assert!(!accounts.is_empty());
let mut expected_lamports = None;
let mut target_accounts_found = HashSet::new();
for (pubkey, account) in accounts {
let account_balance = account.lamports();
if pubkeys_to_modify_.contains(&pubkey) {
target_accounts_found.insert(pubkey);
if let Some(expected_lamports) = expected_lamports {
assert_eq!(account_balance, expected_lamports);
} else {
// All pubkeys in the specified set should have the same balance
expected_lamports = Some(account_balance);
}
}
}
// Should've found all the accounts, i.e. no partial cleans should
// be detected
assert_eq!(target_accounts_found.len(), total_pubkeys_to_modify);
}
}
}
})
.unwrap()
};
// Thread that constantly updates the accounts, sets
// roots, and cleans
let update_thread = Builder::new()
.name("update".to_string())
.spawn(move || {
update_f(
bank0,
bank_to_scan_sender,
scan_finished_receiver,
pubkeys_to_modify,
program_id,
starting_lamports,
);
})
.unwrap();
// Let threads run for a while, check the scans didn't see any mixed slots
let min_expected_number_of_scans = 5;
std::thread::sleep(Duration::new(5, 0));
// This can be reduced when you are running this test locally to deal with hangs
// But, if it is too low, the ci fails intermittently.
let mut remaining_loops = 2000;
loop {
if num_banks_scanned.load(Relaxed) > min_expected_number_of_scans {
break;
} else {
std::thread::sleep(Duration::from_millis(100));
}
remaining_loops -= 1;
if remaining_loops == 0 {
break; // just quit and try to get the thread result (panic, etc.)
}
}
exit.store(true, Relaxed);
scan_thread.join().unwrap();
update_thread.join().unwrap();
assert!(remaining_loops > 0, "test timed out");
}
#[test]
fn test_store_scan_consistency_unrooted() {
let (pruned_banks_sender, pruned_banks_receiver) = unbounded();
let pruned_banks_request_handler = PrunedBanksRequestHandler {
pruned_banks_receiver,
};
test_store_scan_consistency(
move |bank0,
bank_to_scan_sender,
_scan_finished_receiver,
pubkeys_to_modify,
program_id,
starting_lamports| {
let mut current_major_fork_bank = bank0;
loop {
let mut current_minor_fork_bank = current_major_fork_bank.clone();
let num_new_banks = 2;
let lamports = current_minor_fork_bank.slot() + starting_lamports + 1;
// Modify banks on the two banks on the minor fork
for pubkeys_to_modify in &pubkeys_to_modify
.iter()
.chunks(pubkeys_to_modify.len() / num_new_banks)
{
current_minor_fork_bank = Arc::new(Bank::new_from_parent(
&current_minor_fork_bank,
&solana_sdk::pubkey::new_rand(),
current_minor_fork_bank.slot() + 2,
));
let account = AccountSharedData::new(lamports, 0, &program_id);
// Write partial updates to each of the banks in the minor fork so if any of them
// get cleaned up, there will be keys with the wrong account value/missing.
for key in pubkeys_to_modify {
current_minor_fork_bank.store_account(key, &account);
}
current_minor_fork_bank.freeze();
}
// All the parent banks made in this iteration of the loop
// are currently discoverable, previous parents should have
// been squashed
assert_eq!(
current_minor_fork_bank.clone().parents_inclusive().len(),
num_new_banks + 1,
);
// `next_major_bank` needs to be sandwiched between the minor fork banks
// That way, after the squash(), the minor fork has the potential to see a
// *partial* clean of the banks < `next_major_bank`.
current_major_fork_bank = Arc::new(Bank::new_from_parent(
&current_major_fork_bank,
&solana_sdk::pubkey::new_rand(),
current_minor_fork_bank.slot() - 1,
));
let lamports = current_major_fork_bank.slot() + starting_lamports + 1;
let account = AccountSharedData::new(lamports, 0, &program_id);
for key in pubkeys_to_modify.iter() {
// Store rooted updates to these pubkeys such that the minor
// fork updates to the same keys will be deleted by clean
current_major_fork_bank.store_account(key, &account);
}
// Send the last new bank to the scan thread to perform the scan.
// Meanwhile this thread will continually set roots on a separate fork
// and squash/clean, purging the account entries from the minor forks
/*
bank 0
/ \
minor bank 1 \
/ current_major_fork_bank
minor bank 2
*/
// The capacity of the channel is 1 so that this thread will wait for the scan to finish before starting
// the next iteration, allowing the scan to stay in sync with these updates
// such that every scan will see this interruption.
if bank_to_scan_sender.send(current_minor_fork_bank).is_err() {
// Channel was disconnected, exit
return;
}
current_major_fork_bank.freeze();
current_major_fork_bank.squash();
// Try to get cache flush/clean to overlap with the scan
current_major_fork_bank.force_flush_accounts_cache();
current_major_fork_bank.clean_accounts_for_tests();
// Move purge here so that Bank::drop()->purge_slots() doesn't race
// with clean. Simulates the call from AccountsBackgroundService
pruned_banks_request_handler.handle_request(&current_major_fork_bank, true);
}
},
Some(Box::new(SendDroppedBankCallback::new(pruned_banks_sender))),
AcceptableScanResults::NoFailure,
)
}
#[test]
fn test_store_scan_consistency_root() {
test_store_scan_consistency(
|bank0,
bank_to_scan_sender,
_scan_finished_receiver,
pubkeys_to_modify,
program_id,
starting_lamports| {
let mut current_bank = bank0.clone();
let mut prev_bank = bank0;
loop {
let lamports_this_round = current_bank.slot() + starting_lamports + 1;
let account = AccountSharedData::new(lamports_this_round, 0, &program_id);
for key in pubkeys_to_modify.iter() {
current_bank.store_account(key, &account);
}
current_bank.freeze();
// Send the previous bank to the scan thread to perform the scan.
// Meanwhile this thread will squash and update roots immediately after
// so the roots will update while scanning.
//
// The capacity of the channel is 1 so that this thread will wait for the scan to finish before starting
// the next iteration, allowing the scan to stay in sync with these updates
// such that every scan will see this interruption.
if bank_to_scan_sender.send(prev_bank).is_err() {
// Channel was disconnected, exit
return;
}
current_bank.squash();
if current_bank.slot() % 2 == 0 {
current_bank.force_flush_accounts_cache();
current_bank.clean_accounts(None);
}
prev_bank = current_bank.clone();
current_bank = Arc::new(Bank::new_from_parent(
&current_bank,
&solana_sdk::pubkey::new_rand(),
current_bank.slot() + 1,
));
}
},
None,
AcceptableScanResults::NoFailure,
);
}
fn setup_banks_on_fork_to_remove(
bank0: Arc<Bank>,
pubkeys_to_modify: Arc<HashSet<Pubkey>>,
program_id: &Pubkey,
starting_lamports: u64,
num_banks_on_fork: usize,
step_size: usize,
) -> (Arc<Bank>, Vec<(Slot, BankId)>, Ancestors) {
// Need at least 2 keys to create inconsistency in account balances when deleting
// slots
assert!(pubkeys_to_modify.len() > 1);
// Tracks the bank at the tip of the to be created fork
let mut bank_at_fork_tip = bank0;
// All the slots on the fork except slot 0
let mut slots_on_fork = Vec::with_capacity(num_banks_on_fork);
// All accounts in each set of `step_size` slots will have the same account balances.
// The account balances of the accounts changes every `step_size` banks. Thus if you
// delete any one of the latest `step_size` slots, then you will see varying account
// balances when loading the accounts.
assert!(num_banks_on_fork >= 2);
assert!(step_size >= 2);
let pubkeys_to_modify: Vec<Pubkey> = pubkeys_to_modify.iter().cloned().collect();
let pubkeys_to_modify_per_slot = (pubkeys_to_modify.len() / step_size).max(1);
for _ in (0..num_banks_on_fork).step_by(step_size) {
let mut lamports_this_round = 0;
for i in 0..step_size {
bank_at_fork_tip = Arc::new(Bank::new_from_parent(
&bank_at_fork_tip,
&solana_sdk::pubkey::new_rand(),
bank_at_fork_tip.slot() + 1,
));
if lamports_this_round == 0 {
lamports_this_round = bank_at_fork_tip.bank_id() + starting_lamports + 1;
}
let pubkey_to_modify_starting_index = i * pubkeys_to_modify_per_slot;
let account = AccountSharedData::new(lamports_this_round, 0, program_id);
for pubkey_index_to_modify in pubkey_to_modify_starting_index
..pubkey_to_modify_starting_index + pubkeys_to_modify_per_slot
{
let key = pubkeys_to_modify[pubkey_index_to_modify % pubkeys_to_modify.len()];
bank_at_fork_tip.store_account(&key, &account);
}
bank_at_fork_tip.freeze();
slots_on_fork.push((bank_at_fork_tip.slot(), bank_at_fork_tip.bank_id()));
}
}
let ancestors: Vec<(Slot, usize)> = slots_on_fork.iter().map(|(s, _)| (*s, 0)).collect();
let ancestors = Ancestors::from(ancestors);
(bank_at_fork_tip, slots_on_fork, ancestors)
}
#[test]
fn test_remove_unrooted_before_scan() {
test_store_scan_consistency(
|bank0,
bank_to_scan_sender,
scan_finished_receiver,
pubkeys_to_modify,
program_id,
starting_lamports| {
loop {
let (bank_at_fork_tip, slots_on_fork, ancestors) = setup_banks_on_fork_to_remove(
bank0.clone(),
pubkeys_to_modify.clone(),
&program_id,
starting_lamports,
10,
2,
);
// Test removing the slot before the scan starts, should cause
// SlotRemoved error every time
for k in pubkeys_to_modify.iter() {
assert!(bank_at_fork_tip.load_slow(&ancestors, k).is_some());
}
bank_at_fork_tip.remove_unrooted_slots(&slots_on_fork);
// Accounts on this fork should not be found after removal
for k in pubkeys_to_modify.iter() {
assert!(bank_at_fork_tip.load_slow(&ancestors, k).is_none());
}
if bank_to_scan_sender.send(bank_at_fork_tip.clone()).is_err() {
return;
}
// Wait for scan to finish before starting next iteration
let finished_scan_bank_id = scan_finished_receiver.recv();
if finished_scan_bank_id.is_err() {
return;
}
assert_eq!(finished_scan_bank_id.unwrap(), bank_at_fork_tip.bank_id());
}
},
None,
// Test removing the slot before the scan starts, should error every time
AcceptableScanResults::DroppedSlotError,
);
}
#[test]
fn test_remove_unrooted_scan_then_recreate_same_slot_before_scan() {
test_store_scan_consistency(
|bank0,
bank_to_scan_sender,
scan_finished_receiver,
pubkeys_to_modify,
program_id,
starting_lamports| {
let mut prev_bank = bank0.clone();
loop {
let start = Instant::now();
let (bank_at_fork_tip, slots_on_fork, ancestors) = setup_banks_on_fork_to_remove(
bank0.clone(),
pubkeys_to_modify.clone(),
&program_id,
starting_lamports,
10,
2,
);
info!("setting up banks elapsed: {}", start.elapsed().as_millis());
// Remove the fork. Then we'll recreate the slots and only after we've
// recreated the slots, do we send this old bank for scanning.
// Skip scanning bank 0 on first iteration of loop, since those accounts
// aren't being removed
if prev_bank.slot() != 0 {
info!(
"sending bank with slot: {:?}, elapsed: {}",
prev_bank.slot(),
start.elapsed().as_millis()
);
// Although we dumped the slots last iteration via `remove_unrooted_slots()`,
// we've recreated those slots this iteration, so they should be findable
// again
for k in pubkeys_to_modify.iter() {
assert!(bank_at_fork_tip.load_slow(&ancestors, k).is_some());
}
// Now after we've recreated the slots removed in the previous loop
// iteration, send the previous bank, should fail even though the
// same slots were recreated
if bank_to_scan_sender.send(prev_bank.clone()).is_err() {
return;
}
let finished_scan_bank_id = scan_finished_receiver.recv();
if finished_scan_bank_id.is_err() {
return;
}
// Wait for scan to finish before starting next iteration
assert_eq!(finished_scan_bank_id.unwrap(), prev_bank.bank_id());
}
bank_at_fork_tip.remove_unrooted_slots(&slots_on_fork);
prev_bank = bank_at_fork_tip;
}
},
None,
// Test removing the slot before the scan starts, should error every time
AcceptableScanResults::DroppedSlotError,
);
}
#[test]
fn test_remove_unrooted_scan_interleaved_with_remove_unrooted_slots() {
test_store_scan_consistency(
|bank0,
bank_to_scan_sender,
scan_finished_receiver,
pubkeys_to_modify,
program_id,
starting_lamports| {
loop {
let step_size = 2;
let (bank_at_fork_tip, slots_on_fork, ancestors) = setup_banks_on_fork_to_remove(
bank0.clone(),
pubkeys_to_modify.clone(),
&program_id,
starting_lamports,
10,
step_size,
);
// Although we dumped the slots last iteration via `remove_unrooted_slots()`,
// we've recreated those slots this iteration, so they should be findable
// again
for k in pubkeys_to_modify.iter() {
assert!(bank_at_fork_tip.load_slow(&ancestors, k).is_some());
}
// Now after we've recreated the slots removed in the previous loop
// iteration, send the previous bank, should fail even though the
// same slots were recreated
if bank_to_scan_sender.send(bank_at_fork_tip.clone()).is_err() {
return;
}
// Remove 1 < `step_size` of the *latest* slots while the scan is happening.
// This should create inconsistency between the account balances of accounts
// stored in that slot, and the accounts stored in earlier slots
let slot_to_remove = *slots_on_fork.last().unwrap();
bank_at_fork_tip.remove_unrooted_slots(&[slot_to_remove]);
// Wait for scan to finish before starting next iteration
let finished_scan_bank_id = scan_finished_receiver.recv();
if finished_scan_bank_id.is_err() {
return;
}
assert_eq!(finished_scan_bank_id.unwrap(), bank_at_fork_tip.bank_id());
// Remove the rest of the slots before the next iteration
for (slot, bank_id) in slots_on_fork {
bank_at_fork_tip.remove_unrooted_slots(&[(slot, bank_id)]);
}
}
},
None,
// Test removing the slot before the scan starts, should error every time
AcceptableScanResults::Both,
);
}
#[test]
fn test_get_inflation_start_slot_devnet_testnet() {
let GenesisConfigInfo {
mut genesis_config, ..
} = create_genesis_config_with_leader(42, &solana_sdk::pubkey::new_rand(), 42);
genesis_config
.accounts
.remove(&feature_set::pico_inflation::id())
.unwrap();
genesis_config
.accounts
.remove(&feature_set::full_inflation::devnet_and_testnet::id())
.unwrap();
for pair in feature_set::FULL_INFLATION_FEATURE_PAIRS.iter() {
genesis_config.accounts.remove(&pair.vote_id).unwrap();
genesis_config.accounts.remove(&pair.enable_id).unwrap();
}
let bank = Bank::new_for_tests(&genesis_config);
// Advance slot
let mut bank = new_from_parent(&Arc::new(bank));
bank = new_from_parent(&Arc::new(bank));
assert_eq!(bank.get_inflation_start_slot(), 0);
assert_eq!(bank.slot(), 2);
// Request `pico_inflation` activation
bank.store_account(
&feature_set::pico_inflation::id(),
&feature::create_account(
&Feature {
activated_at: Some(1),
},
42,
),
);
bank.compute_active_feature_set(true);
assert_eq!(bank.get_inflation_start_slot(), 1);
// Advance slot
bank = new_from_parent(&Arc::new(bank));
assert_eq!(bank.slot(), 3);
// Request `full_inflation::devnet_and_testnet` activation,
// which takes priority over pico_inflation
bank.store_account(
&feature_set::full_inflation::devnet_and_testnet::id(),
&feature::create_account(
&Feature {
activated_at: Some(2),
},
42,
),
);
bank.compute_active_feature_set(true);
assert_eq!(bank.get_inflation_start_slot(), 2);
// Request `full_inflation::mainnet::certusone` activation,
// which should have no effect on `get_inflation_start_slot`
bank.store_account(
&feature_set::full_inflation::mainnet::certusone::vote::id(),
&feature::create_account(
&Feature {
activated_at: Some(3),
},
42,
),
);
bank.store_account(
&feature_set::full_inflation::mainnet::certusone::enable::id(),
&feature::create_account(
&Feature {
activated_at: Some(3),
},
42,
),
);
bank.compute_active_feature_set(true);
assert_eq!(bank.get_inflation_start_slot(), 2);
}
#[test]
fn test_get_inflation_start_slot_mainnet() {
let GenesisConfigInfo {
mut genesis_config, ..
} = create_genesis_config_with_leader(42, &solana_sdk::pubkey::new_rand(), 42);
genesis_config
.accounts
.remove(&feature_set::pico_inflation::id())
.unwrap();
genesis_config
.accounts
.remove(&feature_set::full_inflation::devnet_and_testnet::id())
.unwrap();
for pair in feature_set::FULL_INFLATION_FEATURE_PAIRS.iter() {
genesis_config.accounts.remove(&pair.vote_id).unwrap();
genesis_config.accounts.remove(&pair.enable_id).unwrap();
}
let bank = Bank::new_for_tests(&genesis_config);
// Advance slot
let mut bank = new_from_parent(&Arc::new(bank));
bank = new_from_parent(&Arc::new(bank));
assert_eq!(bank.get_inflation_start_slot(), 0);
assert_eq!(bank.slot(), 2);
// Request `pico_inflation` activation
bank.store_account(
&feature_set::pico_inflation::id(),
&feature::create_account(
&Feature {
activated_at: Some(1),
},
42,
),
);
bank.compute_active_feature_set(true);
assert_eq!(bank.get_inflation_start_slot(), 1);
// Advance slot
bank = new_from_parent(&Arc::new(bank));
assert_eq!(bank.slot(), 3);
// Request `full_inflation::mainnet::certusone` activation,
// which takes priority over pico_inflation
bank.store_account(
&feature_set::full_inflation::mainnet::certusone::vote::id(),
&feature::create_account(
&Feature {
activated_at: Some(2),
},
42,
),
);
bank.store_account(
&feature_set::full_inflation::mainnet::certusone::enable::id(),
&feature::create_account(
&Feature {
activated_at: Some(2),
},
42,
),
);
bank.compute_active_feature_set(true);
assert_eq!(bank.get_inflation_start_slot(), 2);
// Advance slot
bank = new_from_parent(&Arc::new(bank));
assert_eq!(bank.slot(), 4);
// Request `full_inflation::devnet_and_testnet` activation,
// which should have no effect on `get_inflation_start_slot`
bank.store_account(
&feature_set::full_inflation::devnet_and_testnet::id(),
&feature::create_account(
&Feature {
activated_at: Some(bank.slot()),
},
42,
),
);
bank.compute_active_feature_set(true);
assert_eq!(bank.get_inflation_start_slot(), 2);
}
#[test]
fn test_get_inflation_num_slots_with_activations() {
let GenesisConfigInfo {
mut genesis_config, ..
} = create_genesis_config_with_leader(42, &solana_sdk::pubkey::new_rand(), 42);
let slots_per_epoch = 32;
genesis_config.epoch_schedule = EpochSchedule::new(slots_per_epoch);
genesis_config
.accounts
.remove(&feature_set::pico_inflation::id())
.unwrap();
genesis_config
.accounts
.remove(&feature_set::full_inflation::devnet_and_testnet::id())
.unwrap();
for pair in feature_set::FULL_INFLATION_FEATURE_PAIRS.iter() {
genesis_config.accounts.remove(&pair.vote_id).unwrap();
genesis_config.accounts.remove(&pair.enable_id).unwrap();
}
let mut bank = Bank::new_for_tests(&genesis_config);
assert_eq!(bank.get_inflation_num_slots(), 0);
for _ in 0..2 * slots_per_epoch {
bank = new_from_parent(&Arc::new(bank));
}
assert_eq!(bank.get_inflation_num_slots(), 2 * slots_per_epoch);
// Activate pico_inflation
let pico_inflation_activation_slot = bank.slot();
bank.store_account(
&feature_set::pico_inflation::id(),
&feature::create_account(
&Feature {
activated_at: Some(pico_inflation_activation_slot),
},
42,
),
);
bank.compute_active_feature_set(true);
assert_eq!(bank.get_inflation_num_slots(), slots_per_epoch);
for _ in 0..slots_per_epoch {
bank = new_from_parent(&Arc::new(bank));
}
assert_eq!(bank.get_inflation_num_slots(), 2 * slots_per_epoch);
// Activate full_inflation::devnet_and_testnet
let full_inflation_activation_slot = bank.slot();
bank.store_account(
&feature_set::full_inflation::devnet_and_testnet::id(),
&feature::create_account(
&Feature {
activated_at: Some(full_inflation_activation_slot),
},
42,
),
);
bank.compute_active_feature_set(true);
assert_eq!(bank.get_inflation_num_slots(), slots_per_epoch);
for _ in 0..slots_per_epoch {
bank = new_from_parent(&Arc::new(bank));
}
assert_eq!(bank.get_inflation_num_slots(), 2 * slots_per_epoch);
}
#[test]
fn test_get_inflation_num_slots_already_activated() {
let GenesisConfigInfo {
mut genesis_config, ..
} = create_genesis_config_with_leader(42, &solana_sdk::pubkey::new_rand(), 42);
let slots_per_epoch = 32;
genesis_config.epoch_schedule = EpochSchedule::new(slots_per_epoch);
let mut bank = Bank::new_for_tests(&genesis_config);
assert_eq!(bank.get_inflation_num_slots(), 0);
for _ in 0..slots_per_epoch {
bank = new_from_parent(&Arc::new(bank));
}
assert_eq!(bank.get_inflation_num_slots(), slots_per_epoch);
for _ in 0..slots_per_epoch {
bank = new_from_parent(&Arc::new(bank));
}
assert_eq!(bank.get_inflation_num_slots(), 2 * slots_per_epoch);
}
#[test]
fn test_stake_vote_account_validity() {
let thread_pool = ThreadPoolBuilder::new().num_threads(1).build().unwrap();
check_stake_vote_account_validity(
true, // check owner change,
|bank: &Bank| {
bank._load_vote_and_stake_accounts_with_thread_pool(&thread_pool, null_tracer())
},
);
// TODO: stakes cache should be hardened for the case when the account
// owner is changed from vote/stake program to something else. see:
// https://github.com/solana-labs/solana/pull/24200#discussion_r849935444
check_stake_vote_account_validity(
false, // check owner change
|bank: &Bank| bank._load_vote_and_stake_accounts(&thread_pool, null_tracer()),
);
}
fn check_stake_vote_account_validity<F>(check_owner_change: bool, load_vote_and_stake_accounts: F)
where
F: Fn(&Bank) -> LoadVoteAndStakeAccountsResult,
{
let validator_vote_keypairs0 = ValidatorVoteKeypairs::new_rand();
let validator_vote_keypairs1 = ValidatorVoteKeypairs::new_rand();
let validator_keypairs = vec![&validator_vote_keypairs0, &validator_vote_keypairs1];
let GenesisConfigInfo { genesis_config, .. } = create_genesis_config_with_vote_accounts(
1_000_000_000,
&validator_keypairs,
vec![LAMPORTS_PER_SOL; 2],
);
let bank = Arc::new(Bank::new_with_paths(
&genesis_config,
Arc::<RuntimeConfig>::default(),
Vec::new(),
None,
None,
AccountSecondaryIndexes::default(),
AccountShrinkThreshold::default(),
false,
Some(AccountsDbConfig {
// at least one tests hit this assert, so disable it
assert_stakes_cache_consistency: false,
..ACCOUNTS_DB_CONFIG_FOR_TESTING
}),
None,
&Arc::default(),
));
let vote_and_stake_accounts =
load_vote_and_stake_accounts(&bank).vote_with_stake_delegations_map;
assert_eq!(vote_and_stake_accounts.len(), 2);
let mut vote_account = bank
.get_account(&validator_vote_keypairs0.vote_keypair.pubkey())
.unwrap_or_default();
let original_lamports = vote_account.lamports();
vote_account.set_lamports(0);
// Simulate vote account removal via full withdrawal
bank.store_account(
&validator_vote_keypairs0.vote_keypair.pubkey(),
&vote_account,
);
// Modify staked vote account owner; a vote account owned by another program could be
// freely modified with malicious data
let bogus_vote_program = Pubkey::new_unique();
vote_account.set_lamports(original_lamports);
vote_account.set_owner(bogus_vote_program);
bank.store_account(
&validator_vote_keypairs0.vote_keypair.pubkey(),
&vote_account,
);
assert_eq!(bank.vote_accounts().len(), 1);
// Modify stake account owner; a stake account owned by another program could be freely
// modified with malicious data
let bogus_stake_program = Pubkey::new_unique();
let mut stake_account = bank
.get_account(&validator_vote_keypairs1.stake_keypair.pubkey())
.unwrap_or_default();
stake_account.set_owner(bogus_stake_program);
bank.store_account(
&validator_vote_keypairs1.stake_keypair.pubkey(),
&stake_account,
);
// Accounts must be valid stake and vote accounts
let vote_and_stake_accounts =
load_vote_and_stake_accounts(&bank).vote_with_stake_delegations_map;
assert_eq!(
vote_and_stake_accounts.len(),
usize::from(!check_owner_change)
);
}
#[test]
fn test_vote_epoch_panic() {
let GenesisConfigInfo {
genesis_config,
mint_keypair,
..
} = create_genesis_config_with_leader(
1_000_000_000_000_000,
&Pubkey::new_unique(),
bootstrap_validator_stake_lamports(),
);
let bank = Arc::new(Bank::new_for_tests(&genesis_config));
let vote_keypair = keypair_from_seed(&[1u8; 32]).unwrap();
let stake_keypair = keypair_from_seed(&[2u8; 32]).unwrap();
let mut setup_ixs = Vec::new();
setup_ixs.extend(
vote_instruction::create_account_with_config(
&mint_keypair.pubkey(),
&vote_keypair.pubkey(),
&VoteInit {
node_pubkey: mint_keypair.pubkey(),
authorized_voter: vote_keypair.pubkey(),
authorized_withdrawer: mint_keypair.pubkey(),
commission: 0,
},
1_000_000_000,
vote_instruction::CreateVoteAccountConfig {
space: VoteStateVersions::vote_state_size_of(true) as u64,
..vote_instruction::CreateVoteAccountConfig::default()
},
)
.into_iter(),
);
setup_ixs.extend(
stake_instruction::create_account_and_delegate_stake(
&mint_keypair.pubkey(),
&stake_keypair.pubkey(),
&vote_keypair.pubkey(),
&Authorized::auto(&mint_keypair.pubkey()),
&Lockup::default(),
1_000_000_000_000,
)
.into_iter(),
);
setup_ixs.push(vote_instruction::withdraw(
&vote_keypair.pubkey(),
&mint_keypair.pubkey(),
1_000_000_000,
&mint_keypair.pubkey(),
));
setup_ixs.push(system_instruction::transfer(
&mint_keypair.pubkey(),
&vote_keypair.pubkey(),
1_000_000_000,
));
let result = bank.process_transaction(&Transaction::new(
&[&mint_keypair, &vote_keypair, &stake_keypair],
Message::new(&setup_ixs, Some(&mint_keypair.pubkey())),
bank.last_blockhash(),
));
assert!(result.is_ok());
let _bank = Bank::new_from_parent(
&bank,
&mint_keypair.pubkey(),
genesis_config.epoch_schedule.get_first_slot_in_epoch(1),
);
}
#[test]
fn test_tx_log_order() {
let GenesisConfigInfo {
genesis_config,
mint_keypair,
..
} = create_genesis_config_with_leader(
1_000_000_000_000_000,
&Pubkey::new_unique(),
bootstrap_validator_stake_lamports(),
);
let bank = Arc::new(Bank::new_for_tests(&genesis_config));
*bank.transaction_log_collector_config.write().unwrap() = TransactionLogCollectorConfig {
mentioned_addresses: HashSet::new(),
filter: TransactionLogCollectorFilter::All,
};
let blockhash = bank.last_blockhash();
let sender0 = Keypair::new();
let sender1 = Keypair::new();
bank.transfer(100, &mint_keypair, &sender0.pubkey())
.unwrap();
bank.transfer(100, &mint_keypair, &sender1.pubkey())
.unwrap();
let recipient0 = Pubkey::new_unique();
let recipient1 = Pubkey::new_unique();
let tx0 = system_transaction::transfer(&sender0, &recipient0, 10, blockhash);
let success_sig = tx0.signatures[0];
let tx1 = system_transaction::transfer(&sender1, &recipient1, 110, blockhash); // Should produce insufficient funds log
let failure_sig = tx1.signatures[0];
let tx2 = system_transaction::transfer(&sender0, &recipient0, 1, blockhash);
let txs = vec![tx0, tx1, tx2];
let batch = bank.prepare_batch_for_tests(txs);
let execution_results = bank
.load_execute_and_commit_transactions(
&batch,
MAX_PROCESSING_AGE,
false,
false,
true,
false,
&mut ExecuteTimings::default(),
None,
)
.0
.execution_results;
assert_eq!(execution_results.len(), 3);
assert!(execution_results[0].details().is_some());
assert!(execution_results[0]
.details()
.unwrap()
.log_messages
.as_ref()
.unwrap()[1]
.contains(&"success".to_string()));
assert!(execution_results[1].details().is_some());
assert!(execution_results[1]
.details()
.unwrap()
.log_messages
.as_ref()
.unwrap()[2]
.contains(&"failed".to_string()));
assert!(!execution_results[2].was_executed());
let stored_logs = &bank.transaction_log_collector.read().unwrap().logs;
let success_log_info = stored_logs
.iter()
.find(|transaction_log_info| transaction_log_info.signature == success_sig)
.unwrap();
assert!(success_log_info.result.is_ok());
let success_log = success_log_info.log_messages.clone().pop().unwrap();
assert!(success_log.contains(&"success".to_string()));
let failure_log_info = stored_logs
.iter()
.find(|transaction_log_info| transaction_log_info.signature == failure_sig)
.unwrap();
assert!(failure_log_info.result.is_err());
let failure_log = failure_log_info.log_messages.clone().pop().unwrap();
assert!(failure_log.contains(&"failed".to_string()));
}
#[test]
fn test_tx_return_data() {
solana_logger::setup();
let GenesisConfigInfo {
genesis_config,
mint_keypair,
..
} = create_genesis_config_with_leader(
1_000_000_000_000_000,
&Pubkey::new_unique(),
bootstrap_validator_stake_lamports(),
);
let mut bank = Bank::new_for_tests(&genesis_config);
declare_process_instruction!(process_instruction, 1, |invoke_context| {
let mock_program_id = Pubkey::from([2u8; 32]);
let transaction_context = &mut invoke_context.transaction_context;
let instruction_context = transaction_context.get_current_instruction_context()?;
let instruction_data = instruction_context.get_instruction_data();
let mut return_data = [0u8; MAX_RETURN_DATA];
if !instruction_data.is_empty() {
let index = usize::from_le_bytes(instruction_data.try_into().unwrap());
return_data[index] = 1;
transaction_context
.set_return_data(mock_program_id, return_data.to_vec())
.unwrap();
}
Ok(())
});
let mock_program_id = Pubkey::from([2u8; 32]);
let blockhash = bank.last_blockhash();
bank.add_mockup_builtin(mock_program_id, process_instruction);
for index in [
None,
Some(0),
Some(MAX_RETURN_DATA / 2),
Some(MAX_RETURN_DATA - 1),
] {
let data = if let Some(index) = index {
usize::to_le_bytes(index).to_vec()
} else {
Vec::new()
};
let txs = vec![Transaction::new_signed_with_payer(
&[Instruction {
program_id: mock_program_id,
data,
accounts: vec![AccountMeta::new(Pubkey::new_unique(), false)],
}],
Some(&mint_keypair.pubkey()),
&[&mint_keypair],
blockhash,
)];
let batch = bank.prepare_batch_for_tests(txs);
let return_data = bank
.load_execute_and_commit_transactions(
&batch,
MAX_PROCESSING_AGE,
false,
false,
false,
true,
&mut ExecuteTimings::default(),
None,
)
.0
.execution_results[0]
.details()
.unwrap()
.return_data
.clone();
if let Some(index) = index {
let return_data = return_data.unwrap();
assert_eq!(return_data.program_id, mock_program_id);
let mut expected_data = vec![0u8; index];
expected_data.push(1u8);
assert_eq!(return_data.data, expected_data);
} else {
assert!(return_data.is_none());
}
}
}
#[test]
fn test_get_largest_accounts() {
let GenesisConfigInfo { genesis_config, .. } =
create_genesis_config_with_leader(42, &solana_sdk::pubkey::new_rand(), 42);
let bank = Bank::new_for_tests(&genesis_config);
let pubkeys: Vec<_> = (0..5).map(|_| Pubkey::new_unique()).collect();
let pubkeys_hashset: HashSet<_> = pubkeys.iter().cloned().collect();
let pubkeys_balances: Vec<_> = pubkeys
.iter()
.cloned()
.zip(vec![
sol_to_lamports(2.0),
sol_to_lamports(3.0),
sol_to_lamports(3.0),
sol_to_lamports(4.0),
sol_to_lamports(5.0),
])
.collect();
// Initialize accounts; all have larger SOL balances than current Bank built-ins
let account0 = AccountSharedData::new(pubkeys_balances[0].1, 0, &Pubkey::default());
bank.store_account(&pubkeys_balances[0].0, &account0);
let account1 = AccountSharedData::new(pubkeys_balances[1].1, 0, &Pubkey::default());
bank.store_account(&pubkeys_balances[1].0, &account1);
let account2 = AccountSharedData::new(pubkeys_balances[2].1, 0, &Pubkey::default());
bank.store_account(&pubkeys_balances[2].0, &account2);
let account3 = AccountSharedData::new(pubkeys_balances[3].1, 0, &Pubkey::default());
bank.store_account(&pubkeys_balances[3].0, &account3);
let account4 = AccountSharedData::new(pubkeys_balances[4].1, 0, &Pubkey::default());
bank.store_account(&pubkeys_balances[4].0, &account4);
// Create HashSet to exclude an account
let exclude4: HashSet<_> = pubkeys[4..].iter().cloned().collect();
let mut sorted_accounts = pubkeys_balances.clone();
sorted_accounts.sort_by(|a, b| a.1.cmp(&b.1).reverse());
// Return only one largest account
assert_eq!(
bank.get_largest_accounts(1, &pubkeys_hashset, AccountAddressFilter::Include)
.unwrap(),
vec![(pubkeys[4], sol_to_lamports(5.0))]
);
assert_eq!(
bank.get_largest_accounts(1, &HashSet::new(), AccountAddressFilter::Exclude)
.unwrap(),
vec![(pubkeys[4], sol_to_lamports(5.0))]
);
assert_eq!(
bank.get_largest_accounts(1, &exclude4, AccountAddressFilter::Exclude)
.unwrap(),
vec![(pubkeys[3], sol_to_lamports(4.0))]
);
// Return all added accounts
let results = bank
.get_largest_accounts(10, &pubkeys_hashset, AccountAddressFilter::Include)
.unwrap();
assert_eq!(results.len(), sorted_accounts.len());
for pubkey_balance in sorted_accounts.iter() {
assert!(results.contains(pubkey_balance));
}
let mut sorted_results = results.clone();
sorted_results.sort_by(|a, b| a.1.cmp(&b.1).reverse());
assert_eq!(sorted_results, results);
let expected_accounts = sorted_accounts[1..].to_vec();
let results = bank
.get_largest_accounts(10, &exclude4, AccountAddressFilter::Exclude)
.unwrap();
// results include 5 Bank builtins
assert_eq!(results.len(), 10);
for pubkey_balance in expected_accounts.iter() {
assert!(results.contains(pubkey_balance));
}
let mut sorted_results = results.clone();
sorted_results.sort_by(|a, b| a.1.cmp(&b.1).reverse());
assert_eq!(sorted_results, results);
// Return 3 added accounts
let expected_accounts = sorted_accounts[0..4].to_vec();
let results = bank
.get_largest_accounts(4, &pubkeys_hashset, AccountAddressFilter::Include)
.unwrap();
assert_eq!(results.len(), expected_accounts.len());
for pubkey_balance in expected_accounts.iter() {
assert!(results.contains(pubkey_balance));
}
let expected_accounts = expected_accounts[1..4].to_vec();
let results = bank
.get_largest_accounts(3, &exclude4, AccountAddressFilter::Exclude)
.unwrap();
assert_eq!(results.len(), expected_accounts.len());
for pubkey_balance in expected_accounts.iter() {
assert!(results.contains(pubkey_balance));
}
// Exclude more, and non-sequential, accounts
let exclude: HashSet<_> = vec![pubkeys[0], pubkeys[2], pubkeys[4]]
.iter()
.cloned()
.collect();
assert_eq!(
bank.get_largest_accounts(2, &exclude, AccountAddressFilter::Exclude)
.unwrap(),
vec![pubkeys_balances[3], pubkeys_balances[1]]
);
}
#[test]
fn test_transfer_sysvar() {
solana_logger::setup();
let GenesisConfigInfo {
genesis_config,
mint_keypair,
..
} = create_genesis_config_with_leader(
1_000_000_000_000_000,
&Pubkey::new_unique(),
bootstrap_validator_stake_lamports(),
);
let mut bank = Bank::new_for_tests(&genesis_config);
declare_process_instruction!(process_instruction, 1, |invoke_context| {
let transaction_context = &invoke_context.transaction_context;
let instruction_context = transaction_context.get_current_instruction_context()?;
instruction_context
.try_borrow_instruction_account(transaction_context, 1)?
.set_data(vec![0; 40])?;
Ok(())
});
let program_id = solana_sdk::pubkey::new_rand();
bank.add_mockup_builtin(program_id, process_instruction);
let blockhash = bank.last_blockhash();
#[allow(deprecated)]
let blockhash_sysvar = sysvar::clock::id();
#[allow(deprecated)]
let orig_lamports = bank.get_account(&sysvar::clock::id()).unwrap().lamports();
let tx = system_transaction::transfer(&mint_keypair, &blockhash_sysvar, 10, blockhash);
assert_eq!(
bank.process_transaction(&tx),
Err(TransactionError::InstructionError(
0,
InstructionError::ReadonlyLamportChange
))
);
assert_eq!(
bank.get_account(&sysvar::clock::id()).unwrap().lamports(),
orig_lamports
);
let accounts = vec![
AccountMeta::new(mint_keypair.pubkey(), true),
AccountMeta::new(blockhash_sysvar, false),
];
let ix = Instruction::new_with_bincode(program_id, &0, accounts);
let message = Message::new(&[ix], Some(&mint_keypair.pubkey()));
let tx = Transaction::new(&[&mint_keypair], message, blockhash);
assert_eq!(
bank.process_transaction(&tx),
Err(TransactionError::InstructionError(
0,
InstructionError::ReadonlyDataModified
))
);
}
#[test]
fn test_clean_dropped_unrooted_frozen_banks() {
solana_logger::setup();
do_test_clean_dropped_unrooted_banks(FreezeBank1::Yes);
}
#[test]
fn test_clean_dropped_unrooted_unfrozen_banks() {
solana_logger::setup();
do_test_clean_dropped_unrooted_banks(FreezeBank1::No);
}
/// A simple enum to toggle freezing Bank1 or not. Used in the clean_dropped_unrooted tests.
enum FreezeBank1 {
No,
Yes,
}
fn do_test_clean_dropped_unrooted_banks(freeze_bank1: FreezeBank1) {
//! Test that dropped unrooted banks are cleaned up properly
//!
//! slot 0: bank0 (rooted)
//! / \
//! slot 1: / bank1 (unrooted and dropped)
//! /
//! slot 2: bank2 (rooted)
//!
//! In the scenario above, when `clean_accounts()` is called on bank2, the keys that exist
//! _only_ in bank1 should be cleaned up, since those keys are unreachable.
//!
//! The following scenarios are tested:
//!
//! 1. A key is written _only_ in an unrooted bank (key1)
//! - In this case, key1 should be cleaned up
//! 2. A key is written in both an unrooted _and_ rooted bank (key3)
//! - In this case, key3's ref-count should be decremented correctly
//! 3. A key with zero lamports is _only_ in an unrooted bank (key4)
//! - In this case, key4 should be cleaned up
//! 4. A key with zero lamports is in both an unrooted _and_ rooted bank (key5)
//! - In this case, key5's ref-count should be decremented correctly
let (genesis_config, mint_keypair) = create_genesis_config(sol_to_lamports(1.));
let bank0 = Arc::new(Bank::new_for_tests(&genesis_config));
let amount = genesis_config.rent.minimum_balance(0);
let collector = Pubkey::new_unique();
let owner = Pubkey::new_unique();
let key1 = Keypair::new(); // only touched in bank1
let key2 = Keypair::new(); // only touched in bank2
let key3 = Keypair::new(); // touched in both bank1 and bank2
let key4 = Keypair::new(); // in only bank1, and has zero lamports
let key5 = Keypair::new(); // in both bank1 and bank2, and has zero lamports
bank0
.transfer(amount, &mint_keypair, &key2.pubkey())
.unwrap();
bank0.freeze();
let slot = 1;
let bank1 = Bank::new_from_parent(&bank0, &collector, slot);
add_root_and_flush_write_cache(&bank0);
bank1
.transfer(amount, &mint_keypair, &key1.pubkey())
.unwrap();
bank1.store_account(&key4.pubkey(), &AccountSharedData::new(0, 0, &owner));
bank1.store_account(&key5.pubkey(), &AccountSharedData::new(0, 0, &owner));
if let FreezeBank1::Yes = freeze_bank1 {
bank1.freeze();
}
let slot = slot + 1;
let bank2 = Bank::new_from_parent(&bank0, &collector, slot);
bank2
.transfer(amount * 2, &mint_keypair, &key2.pubkey())
.unwrap();
bank2
.transfer(amount, &mint_keypair, &key3.pubkey())
.unwrap();
bank2.store_account(&key5.pubkey(), &AccountSharedData::new(0, 0, &owner));
bank2.freeze(); // the freeze here is not strictly necessary, but more for illustration
bank2.squash();
add_root_and_flush_write_cache(&bank2);
drop(bank1);
bank2.clean_accounts_for_tests();
let expected_ref_count_for_cleaned_up_keys = 0;
let expected_ref_count_for_keys_in_both_slot1_and_slot2 = 1;
assert_eq!(
bank2
.rc
.accounts
.accounts_db
.accounts_index
.ref_count_from_storage(&key1.pubkey()),
expected_ref_count_for_cleaned_up_keys
);
assert_ne!(
bank2
.rc
.accounts
.accounts_db
.accounts_index
.ref_count_from_storage(&key3.pubkey()),
expected_ref_count_for_cleaned_up_keys
);
assert_eq!(
bank2
.rc
.accounts
.accounts_db
.accounts_index
.ref_count_from_storage(&key4.pubkey()),
expected_ref_count_for_cleaned_up_keys
);
assert_eq!(
bank2
.rc
.accounts
.accounts_db
.accounts_index
.ref_count_from_storage(&key5.pubkey()),
expected_ref_count_for_keys_in_both_slot1_and_slot2,
);
assert_eq!(
bank2.rc.accounts.accounts_db.alive_account_count_in_slot(1),
0
);
}
#[test]
fn test_rent_debits() {
let mut rent_debits = RentDebits::default();
// No entry for 0 rewards
rent_debits.insert(&Pubkey::new_unique(), 0, 0);
assert_eq!(rent_debits.len(), 0);
// Some that actually work
rent_debits.insert(&Pubkey::new_unique(), 1, 0);
assert_eq!(rent_debits.len(), 1);
rent_debits.insert(&Pubkey::new_unique(), i64::MAX as u64, 0);
assert_eq!(rent_debits.len(), 2);
}
#[test]
fn test_compute_budget_program_noop() {
solana_logger::setup();
let GenesisConfigInfo {
genesis_config,
mint_keypair,
..
} = create_genesis_config_with_leader(
1_000_000_000_000_000,
&Pubkey::new_unique(),
bootstrap_validator_stake_lamports(),
);
let mut bank = Bank::new_for_tests(&genesis_config);
declare_process_instruction!(process_instruction, 1, |invoke_context| {
let compute_budget = invoke_context.get_compute_budget();
assert_eq!(
*compute_budget,
ComputeBudget {
compute_unit_limit: compute_budget::DEFAULT_INSTRUCTION_COMPUTE_UNIT_LIMIT as u64,
heap_size: Some(48 * 1024),
..ComputeBudget::default()
}
);
Ok(())
});
let program_id = solana_sdk::pubkey::new_rand();
bank.add_mockup_builtin(program_id, process_instruction);
let message = Message::new(
&[
ComputeBudgetInstruction::set_compute_unit_limit(
compute_budget::DEFAULT_INSTRUCTION_COMPUTE_UNIT_LIMIT,
),
ComputeBudgetInstruction::request_heap_frame(48 * 1024),
Instruction::new_with_bincode(program_id, &0, vec![]),
],
Some(&mint_keypair.pubkey()),
);
let tx = Transaction::new(&[&mint_keypair], message, bank.last_blockhash());
bank.process_transaction(&tx).unwrap();
}
#[test]
fn test_compute_request_instruction() {
solana_logger::setup();
let GenesisConfigInfo {
genesis_config,
mint_keypair,
..
} = create_genesis_config_with_leader(
1_000_000_000_000_000,
&Pubkey::new_unique(),
bootstrap_validator_stake_lamports(),
);
let mut bank = Bank::new_for_tests(&genesis_config);
declare_process_instruction!(process_instruction, 1, |invoke_context| {
let compute_budget = invoke_context.get_compute_budget();
assert_eq!(
*compute_budget,
ComputeBudget {
compute_unit_limit: compute_budget::DEFAULT_INSTRUCTION_COMPUTE_UNIT_LIMIT as u64,
heap_size: Some(48 * 1024),
..ComputeBudget::default()
}
);
Ok(())
});
let program_id = solana_sdk::pubkey::new_rand();
bank.add_mockup_builtin(program_id, process_instruction);
let message = Message::new(
&[
ComputeBudgetInstruction::set_compute_unit_limit(
compute_budget::DEFAULT_INSTRUCTION_COMPUTE_UNIT_LIMIT,
),
ComputeBudgetInstruction::request_heap_frame(48 * 1024),
Instruction::new_with_bincode(program_id, &0, vec![]),
],
Some(&mint_keypair.pubkey()),
);
let tx = Transaction::new(&[&mint_keypair], message, bank.last_blockhash());
bank.process_transaction(&tx).unwrap();
}
#[test]
fn test_failed_compute_request_instruction() {
solana_logger::setup();
let GenesisConfigInfo {
genesis_config,
mint_keypair,
..
} = create_genesis_config_with_leader(
1_000_000_000_000_000,
&Pubkey::new_unique(),
bootstrap_validator_stake_lamports(),
);
let mut bank = Bank::new_for_tests(&genesis_config);
let payer0_keypair = Keypair::new();
let payer1_keypair = Keypair::new();
bank.transfer(10, &mint_keypair, &payer0_keypair.pubkey())
.unwrap();
bank.transfer(10, &mint_keypair, &payer1_keypair.pubkey())
.unwrap();
declare_process_instruction!(process_instruction, 1, |invoke_context| {
let compute_budget = invoke_context.get_compute_budget();
assert_eq!(
*compute_budget,
ComputeBudget {
compute_unit_limit: compute_budget::DEFAULT_INSTRUCTION_COMPUTE_UNIT_LIMIT as u64,
heap_size: Some(48 * 1024),
..ComputeBudget::default()
}
);
Ok(())
});
let program_id = solana_sdk::pubkey::new_rand();
bank.add_mockup_builtin(program_id, process_instruction);
// This message will not be executed because the compute budget request is invalid
let message0 = Message::new(
&[
ComputeBudgetInstruction::request_heap_frame(1),
Instruction::new_with_bincode(program_id, &0, vec![]),
],
Some(&payer0_keypair.pubkey()),
);
// This message will be processed successfully
let message1 = Message::new(
&[
ComputeBudgetInstruction::set_compute_unit_limit(1),
ComputeBudgetInstruction::request_heap_frame(48 * 1024),
Instruction::new_with_bincode(program_id, &0, vec![]),
],
Some(&payer1_keypair.pubkey()),
);
let txs = vec![
Transaction::new(&[&payer0_keypair], message0, bank.last_blockhash()),
Transaction::new(&[&payer1_keypair], message1, bank.last_blockhash()),
];
let results = bank.process_transactions(txs.iter());
assert_eq!(
results[0],
Err(TransactionError::InstructionError(
0,
InstructionError::InvalidInstructionData
))
);
assert_eq!(results[1], Ok(()));
// two transfers and the mock program
assert_eq!(bank.signature_count(), 3);
}
#[test]
fn test_verify_and_hash_transaction_sig_len() {
let GenesisConfigInfo {
mut genesis_config, ..
} = create_genesis_config_with_leader(42, &solana_sdk::pubkey::new_rand(), 42);
// activate all features but verify_tx_signatures_len
activate_all_features(&mut genesis_config);
genesis_config
.accounts
.remove(&feature_set::verify_tx_signatures_len::id());
let bank = Bank::new_for_tests(&genesis_config);
let mut rng = rand::thread_rng();
let recent_blockhash = hash::new_rand(&mut rng);
let from_keypair = Keypair::new();
let to_keypair = Keypair::new();
let from_pubkey = from_keypair.pubkey();
let to_pubkey = to_keypair.pubkey();
enum TestCase {
AddSignature,
RemoveSignature,
}
let make_transaction = |case: TestCase| {
let message = Message::new(
&[system_instruction::transfer(&from_pubkey, &to_pubkey, 1)],
Some(&from_pubkey),
);
let mut tx = Transaction::new(&[&from_keypair], message, recent_blockhash);
assert_eq!(tx.message.header.num_required_signatures, 1);
match case {
TestCase::AddSignature => {
let signature = to_keypair.sign_message(&tx.message.serialize());
tx.signatures.push(signature);
}
TestCase::RemoveSignature => {
tx.signatures.remove(0);
}
}
tx
};
// Too few signatures: Sanitization failure
{
let tx = make_transaction(TestCase::RemoveSignature);
assert_eq!(
bank.verify_transaction(tx.into(), TransactionVerificationMode::FullVerification)
.err(),
Some(TransactionError::SanitizeFailure),
);
}
// Too many signatures: Sanitization failure
{
let tx = make_transaction(TestCase::AddSignature);
assert_eq!(
bank.verify_transaction(tx.into(), TransactionVerificationMode::FullVerification)
.err(),
Some(TransactionError::SanitizeFailure),
);
}
}
#[test]
fn test_verify_transactions_packet_data_size() {
let GenesisConfigInfo { genesis_config, .. } =
create_genesis_config_with_leader(42, &solana_sdk::pubkey::new_rand(), 42);
let bank = Bank::new_for_tests(&genesis_config);
let mut rng = rand::thread_rng();
let recent_blockhash = hash::new_rand(&mut rng);
let keypair = Keypair::new();
let pubkey = keypair.pubkey();
let make_transaction = |size| {
let ixs: Vec<_> = std::iter::repeat_with(|| {
system_instruction::transfer(&pubkey, &Pubkey::new_unique(), 1)
})
.take(size)
.collect();
let message = Message::new(&ixs[..], Some(&pubkey));
Transaction::new(&[&keypair], message, recent_blockhash)
};
// Small transaction.
{
let tx = make_transaction(5);
assert!(bincode::serialized_size(&tx).unwrap() <= PACKET_DATA_SIZE as u64);
assert!(bank
.verify_transaction(tx.into(), TransactionVerificationMode::FullVerification)
.is_ok(),);
}
// Big transaction.
{
let tx = make_transaction(25);
assert!(bincode::serialized_size(&tx).unwrap() > PACKET_DATA_SIZE as u64);
assert_eq!(
bank.verify_transaction(tx.into(), TransactionVerificationMode::FullVerification)
.err(),
Some(TransactionError::SanitizeFailure),
);
}
// Assert that verify fails as soon as serialized
// size exceeds packet data size.
for size in 1..30 {
let tx = make_transaction(size);
assert_eq!(
bincode::serialized_size(&tx).unwrap() <= PACKET_DATA_SIZE as u64,
bank.verify_transaction(tx.into(), TransactionVerificationMode::FullVerification)
.is_ok(),
);
}
}
#[test]
fn test_call_precomiled_program() {
let GenesisConfigInfo {
mut genesis_config,
mint_keypair,
..
} = create_genesis_config_with_leader(42, &Pubkey::new_unique(), 42);
activate_all_features(&mut genesis_config);
let bank = Bank::new_for_tests(&genesis_config);
// libsecp256k1
let secp_privkey = libsecp256k1::SecretKey::random(&mut rand::thread_rng());
let message_arr = b"hello";
let instruction =
solana_sdk::secp256k1_instruction::new_secp256k1_instruction(&secp_privkey, message_arr);
let tx = Transaction::new_signed_with_payer(
&[instruction],
Some(&mint_keypair.pubkey()),
&[&mint_keypair],
bank.last_blockhash(),
);
// calling the program should be successful when called from the bank
// even if the program itself is not called
bank.process_transaction(&tx).unwrap();
// ed25519
let privkey = ed25519_dalek::Keypair::generate(&mut rand::thread_rng());
let message_arr = b"hello";
let instruction =
solana_sdk::ed25519_instruction::new_ed25519_instruction(&privkey, message_arr);
let tx = Transaction::new_signed_with_payer(
&[instruction],
Some(&mint_keypair.pubkey()),
&[&mint_keypair],
bank.last_blockhash(),
);
// calling the program should be successful when called from the bank
// even if the program itself is not called
bank.process_transaction(&tx).unwrap();
}
#[test]
fn test_calculate_fee() {
// Default: no fee.
let message =
SanitizedMessage::try_from(Message::new(&[], Some(&Pubkey::new_unique()))).unwrap();
for support_set_accounts_data_size_limit_ix in [true, false] {
assert_eq!(
Bank::calculate_fee(
&message,
0,
&FeeStructure {
lamports_per_signature: 0,
..FeeStructure::default()
},
true,
false,
true,
true,
support_set_accounts_data_size_limit_ix,
false,
),
0
);
}
// One signature, a fee.
for support_set_accounts_data_size_limit_ix in [true, false] {
assert_eq!(
Bank::calculate_fee(
&message,
1,
&FeeStructure {
lamports_per_signature: 1,
..FeeStructure::default()
},
true,
false,
true,
true,
support_set_accounts_data_size_limit_ix,
false,
),
1
);
}
// Two signatures, double the fee.
let key0 = Pubkey::new_unique();
let key1 = Pubkey::new_unique();
let ix0 = system_instruction::transfer(&key0, &key1, 1);
let ix1 = system_instruction::transfer(&key1, &key0, 1);
let message = SanitizedMessage::try_from(Message::new(&[ix0, ix1], Some(&key0))).unwrap();
for support_set_accounts_data_size_limit_ix in [true, false] {
assert_eq!(
Bank::calculate_fee(
&message,
2,
&FeeStructure {
lamports_per_signature: 2,
..FeeStructure::default()
},
true,
false,
true,
true,
support_set_accounts_data_size_limit_ix,
false,
),
4
);
}
}
#[test]
fn test_calculate_fee_compute_units() {
let fee_structure = FeeStructure {
lamports_per_signature: 1,
..FeeStructure::default()
};
let max_fee = fee_structure.compute_fee_bins.last().unwrap().fee;
let lamports_per_signature = fee_structure.lamports_per_signature;
// One signature, no unit request
let message =
SanitizedMessage::try_from(Message::new(&[], Some(&Pubkey::new_unique()))).unwrap();
for support_set_accounts_data_size_limit_ix in [true, false] {
assert_eq!(
Bank::calculate_fee(
&message,
1,
&fee_structure,
true,
false,
true,
true,
support_set_accounts_data_size_limit_ix,
false,
),
max_fee + lamports_per_signature
);
}
// Three signatures, two instructions, no unit request
let ix0 = system_instruction::transfer(&Pubkey::new_unique(), &Pubkey::new_unique(), 1);
let ix1 = system_instruction::transfer(&Pubkey::new_unique(), &Pubkey::new_unique(), 1);
let message =
SanitizedMessage::try_from(Message::new(&[ix0, ix1], Some(&Pubkey::new_unique()))).unwrap();
for support_set_accounts_data_size_limit_ix in [true, false] {
assert_eq!(
Bank::calculate_fee(
&message,
1,
&fee_structure,
true,
false,
true,
true,
support_set_accounts_data_size_limit_ix,
false,
),
max_fee + 3 * lamports_per_signature
);
}
// Explicit fee schedule
for requested_compute_units in [
0,
5_000,
10_000,
100_000,
300_000,
500_000,
700_000,
900_000,
1_100_000,
1_300_000,
MAX_COMPUTE_UNIT_LIMIT,
] {
const PRIORITIZATION_FEE_RATE: u64 = 42;
let prioritization_fee_details = PrioritizationFeeDetails::new(
PrioritizationFeeType::ComputeUnitPrice(PRIORITIZATION_FEE_RATE),
requested_compute_units as u64,
);
let message = SanitizedMessage::try_from(Message::new(
&[
ComputeBudgetInstruction::set_compute_unit_limit(requested_compute_units),
ComputeBudgetInstruction::set_compute_unit_price(PRIORITIZATION_FEE_RATE),
Instruction::new_with_bincode(Pubkey::new_unique(), &0_u8, vec![]),
],
Some(&Pubkey::new_unique()),
))
.unwrap();
for support_set_accounts_data_size_limit_ix in [true, false] {
let fee = Bank::calculate_fee(
&message,
1,
&fee_structure,
true,
false,
true,
true,
support_set_accounts_data_size_limit_ix,
false,
);
assert_eq!(
fee,
lamports_per_signature + prioritization_fee_details.get_fee()
);
}
}
}
#[test]
fn test_calculate_prioritization_fee() {
let fee_structure = FeeStructure {
lamports_per_signature: 1,
..FeeStructure::default()
};
let request_units = 1_000_000_u32;
let request_unit_price = 2_000_000_000_u64;
let prioritization_fee_details = PrioritizationFeeDetails::new(
PrioritizationFeeType::ComputeUnitPrice(request_unit_price),
request_units as u64,
);
let prioritization_fee = prioritization_fee_details.get_fee();
let message = SanitizedMessage::try_from(Message::new(
&[
ComputeBudgetInstruction::set_compute_unit_limit(request_units),
ComputeBudgetInstruction::set_compute_unit_price(request_unit_price),
],
Some(&Pubkey::new_unique()),
))
.unwrap();
let fee = Bank::calculate_fee(
&message,
fee_structure.lamports_per_signature,
&fee_structure,
true, // use_default_units_per_instruction
false, // not support_request_units_deprecated
true, // remove_congestion_multiplier
true, // enable_request_heap_frame_ix
true, // support_set_accounts_data_size_limit_ix,
false, // include_loaded_account_data_size_in_fee
);
assert_eq!(
fee,
fee_structure.lamports_per_signature + prioritization_fee
);
}
#[test]
fn test_calculate_fee_secp256k1() {
let fee_structure = FeeStructure {
lamports_per_signature: 1,
..FeeStructure::default()
};
let key0 = Pubkey::new_unique();
let key1 = Pubkey::new_unique();
let ix0 = system_instruction::transfer(&key0, &key1, 1);
let mut secp_instruction1 = Instruction {
program_id: secp256k1_program::id(),
accounts: vec![],
data: vec![],
};
let mut secp_instruction2 = Instruction {
program_id: secp256k1_program::id(),
accounts: vec![],
data: vec![1],
};
let message = SanitizedMessage::try_from(Message::new(
&[
ix0.clone(),
secp_instruction1.clone(),
secp_instruction2.clone(),
],
Some(&key0),
))
.unwrap();
for support_set_accounts_data_size_limit_ix in [true, false] {
assert_eq!(
Bank::calculate_fee(
&message,
1,
&fee_structure,
true,
false,
true,
true,
support_set_accounts_data_size_limit_ix,
false,
),
2
);
}
secp_instruction1.data = vec![0];
secp_instruction2.data = vec![10];
let message = SanitizedMessage::try_from(Message::new(
&[ix0, secp_instruction1, secp_instruction2],
Some(&key0),
))
.unwrap();
for support_set_accounts_data_size_limit_ix in [true, false] {
assert_eq!(
Bank::calculate_fee(
&message,
1,
&fee_structure,
true,
false,
true,
true,
support_set_accounts_data_size_limit_ix,
false,
),
11
);
}
}
#[test]
fn test_an_empty_instruction_without_program() {
let (genesis_config, mint_keypair) = create_genesis_config(1);
let destination = solana_sdk::pubkey::new_rand();
let mut ix = system_instruction::transfer(&mint_keypair.pubkey(), &destination, 0);
ix.program_id = native_loader::id(); // Empty executable account chain
let message = Message::new(&[ix], Some(&mint_keypair.pubkey()));
let tx = Transaction::new(&[&mint_keypair], message, genesis_config.hash());
let bank = Bank::new_for_tests(&genesis_config);
assert_eq!(
bank.process_transaction(&tx).unwrap_err(),
TransactionError::InstructionError(0, InstructionError::UnsupportedProgramId),
);
}
#[test]
fn test_transaction_log_collector_get_logs_for_address() {
let address = Pubkey::new_unique();
let mut mentioned_address_map = HashMap::new();
mentioned_address_map.insert(address, vec![0]);
let transaction_log_collector = TransactionLogCollector {
mentioned_address_map,
..TransactionLogCollector::default()
};
assert_eq!(
transaction_log_collector.get_logs_for_address(Some(&address)),
Some(Vec::<TransactionLogInfo>::new()),
);
}
/// Test processing a good transaction correctly modifies the accounts data size
#[test]
fn test_accounts_data_size_with_good_transaction() {
const ACCOUNT_SIZE: u64 = MAX_PERMITTED_DATA_LENGTH;
let (genesis_config, mint_keypair) = create_genesis_config(sol_to_lamports(1_000.));
let mut bank = Bank::new_for_tests(&genesis_config);
bank.activate_feature(&feature_set::cap_accounts_data_len::id());
let transaction = system_transaction::create_account(
&mint_keypair,
&Keypair::new(),
bank.last_blockhash(),
genesis_config
.rent
.minimum_balance(ACCOUNT_SIZE.try_into().unwrap()),
ACCOUNT_SIZE,
&solana_sdk::system_program::id(),
);
let accounts_data_size_before = bank.load_accounts_data_size();
let accounts_data_size_delta_before = bank.load_accounts_data_size_delta();
let accounts_data_size_delta_on_chain_before = bank.load_accounts_data_size_delta_on_chain();
let result = bank.process_transaction(&transaction);
let accounts_data_size_after = bank.load_accounts_data_size();
let accounts_data_size_delta_after = bank.load_accounts_data_size_delta();
let accounts_data_size_delta_on_chain_after = bank.load_accounts_data_size_delta_on_chain();
assert!(result.is_ok());
assert_eq!(
accounts_data_size_after - accounts_data_size_before,
ACCOUNT_SIZE,
);
assert_eq!(
accounts_data_size_delta_after - accounts_data_size_delta_before,
ACCOUNT_SIZE as i64,
);
assert_eq!(
accounts_data_size_delta_on_chain_after - accounts_data_size_delta_on_chain_before,
ACCOUNT_SIZE as i64,
);
}
/// Test processing a bad transaction correctly modifies the accounts data size
#[test]
fn test_accounts_data_size_with_bad_transaction() {
const ACCOUNT_SIZE: u64 = MAX_PERMITTED_DATA_LENGTH;
let mut bank = create_simple_test_bank(1_000_000_000_000);
bank.activate_feature(&feature_set::cap_accounts_data_len::id());
let transaction = system_transaction::create_account(
&Keypair::new(),
&Keypair::new(),
bank.last_blockhash(),
LAMPORTS_PER_SOL,
ACCOUNT_SIZE,
&solana_sdk::system_program::id(),
);
let accounts_data_size_before = bank.load_accounts_data_size();
let accounts_data_size_delta_before = bank.load_accounts_data_size_delta();
let accounts_data_size_delta_on_chain_before = bank.load_accounts_data_size_delta_on_chain();
let result = bank.process_transaction(&transaction);
let accounts_data_size_after = bank.load_accounts_data_size();
let accounts_data_size_delta_after = bank.load_accounts_data_size_delta();
let accounts_data_size_delta_on_chain_after = bank.load_accounts_data_size_delta_on_chain();
assert!(result.is_err());
assert_eq!(accounts_data_size_after, accounts_data_size_before,);
assert_eq!(
accounts_data_size_delta_after,
accounts_data_size_delta_before,
);
assert_eq!(
accounts_data_size_delta_on_chain_after,
accounts_data_size_delta_on_chain_before,
);
}
#[derive(Serialize, Deserialize)]
enum MockTransferInstruction {
Transfer(u64),
}
declare_process_instruction!(mock_transfer_process_instruction, 1, |invoke_context| {
let transaction_context = &invoke_context.transaction_context;
let instruction_context = transaction_context.get_current_instruction_context()?;
let instruction_data = instruction_context.get_instruction_data();
if let Ok(instruction) = bincode::deserialize(instruction_data) {
match instruction {
MockTransferInstruction::Transfer(amount) => {
instruction_context
.try_borrow_instruction_account(transaction_context, 1)?
.checked_sub_lamports(amount)?;
instruction_context
.try_borrow_instruction_account(transaction_context, 2)?
.checked_add_lamports(amount)?;
Ok(())
}
}
} else {
Err(InstructionError::InvalidInstructionData)
}
});
fn create_mock_transfer(
payer: &Keypair,
from: &Keypair,
to: &Keypair,
amount: u64,
mock_program_id: Pubkey,
recent_blockhash: Hash,
) -> Transaction {
let account_metas = vec![
AccountMeta::new(payer.pubkey(), true),
AccountMeta::new(from.pubkey(), true),
AccountMeta::new(to.pubkey(), true),
];
let transfer_instruction = Instruction::new_with_bincode(
mock_program_id,
&MockTransferInstruction::Transfer(amount),
account_metas,
);
Transaction::new_signed_with_payer(
&[transfer_instruction],
Some(&payer.pubkey()),
&[payer, from, to],
recent_blockhash,
)
}
#[test]
fn test_invalid_rent_state_changes_existing_accounts() {
let GenesisConfigInfo {
mut genesis_config,
mint_keypair,
..
} = create_genesis_config_with_leader(sol_to_lamports(100.), &Pubkey::new_unique(), 42);
genesis_config.rent = Rent::default();
let mock_program_id = Pubkey::new_unique();
let account_data_size = 100;
let rent_exempt_minimum = genesis_config.rent.minimum_balance(account_data_size);
// Create legacy accounts of various kinds
let rent_paying_account = Keypair::new();
genesis_config.accounts.insert(
rent_paying_account.pubkey(),
Account::new_rent_epoch(
rent_exempt_minimum - 1,
account_data_size,
&mock_program_id,
INITIAL_RENT_EPOCH + 1,
),
);
let rent_exempt_account = Keypair::new();
genesis_config.accounts.insert(
rent_exempt_account.pubkey(),
Account::new_rent_epoch(
rent_exempt_minimum,
account_data_size,
&mock_program_id,
INITIAL_RENT_EPOCH + 1,
),
);
let mut bank = Bank::new_for_tests(&genesis_config);
bank.add_mockup_builtin(mock_program_id, mock_transfer_process_instruction);
let recent_blockhash = bank.last_blockhash();
let check_account_is_rent_exempt = |pubkey: &Pubkey| -> bool {
let account = bank.get_account(pubkey).unwrap();
Rent::default().is_exempt(account.lamports(), account.data().len())
};
// RentPaying account can be left as Uninitialized, in other RentPaying states, or RentExempt
let tx = create_mock_transfer(
&mint_keypair, // payer
&rent_paying_account, // from
&mint_keypair, // to
1,
mock_program_id,
recent_blockhash,
);
let result = bank.process_transaction(&tx);
assert!(result.is_ok());
assert!(!check_account_is_rent_exempt(&rent_paying_account.pubkey()));
let tx = create_mock_transfer(
&mint_keypair, // payer
&rent_paying_account, // from
&mint_keypair, // to
rent_exempt_minimum - 2,
mock_program_id,
recent_blockhash,
);
let result = bank.process_transaction(&tx);
assert!(result.is_ok());
assert!(bank.get_account(&rent_paying_account.pubkey()).is_none());
bank.store_account(
// restore program-owned account
&rent_paying_account.pubkey(),
&AccountSharedData::new(rent_exempt_minimum - 1, account_data_size, &mock_program_id),
);
let result = bank.transfer(1, &mint_keypair, &rent_paying_account.pubkey());
assert!(result.is_ok());
assert!(check_account_is_rent_exempt(&rent_paying_account.pubkey()));
// RentExempt account can only remain RentExempt or be Uninitialized
let tx = create_mock_transfer(
&mint_keypair, // payer
&rent_exempt_account, // from
&mint_keypair, // to
1,
mock_program_id,
recent_blockhash,
);
let result = bank.process_transaction(&tx);
assert!(result.is_err());
assert!(check_account_is_rent_exempt(&rent_exempt_account.pubkey()));
let result = bank.transfer(1, &mint_keypair, &rent_exempt_account.pubkey());
assert!(result.is_ok());
assert!(check_account_is_rent_exempt(&rent_exempt_account.pubkey()));
let tx = create_mock_transfer(
&mint_keypair, // payer
&rent_exempt_account, // from
&mint_keypair, // to
rent_exempt_minimum + 1,
mock_program_id,
recent_blockhash,
);
let result = bank.process_transaction(&tx);
assert!(result.is_ok());
assert!(bank.get_account(&rent_exempt_account.pubkey()).is_none());
}
#[test]
fn test_invalid_rent_state_changes_new_accounts() {
let GenesisConfigInfo {
mut genesis_config,
mint_keypair,
..
} = create_genesis_config_with_leader(sol_to_lamports(100.), &Pubkey::new_unique(), 42);
genesis_config.rent = Rent::default();
let mock_program_id = Pubkey::new_unique();
let account_data_size = 100;
let rent_exempt_minimum = genesis_config.rent.minimum_balance(account_data_size);
let mut bank = Bank::new_for_tests(&genesis_config);
bank.add_mockup_builtin(mock_program_id, mock_transfer_process_instruction);
let recent_blockhash = bank.last_blockhash();
let check_account_is_rent_exempt = |pubkey: &Pubkey| -> bool {
let account = bank.get_account(pubkey).unwrap();
Rent::default().is_exempt(account.lamports(), account.data().len())
};
// Try to create RentPaying account
let rent_paying_account = Keypair::new();
let tx = system_transaction::create_account(
&mint_keypair,
&rent_paying_account,
recent_blockhash,
rent_exempt_minimum - 1,
account_data_size as u64,
&mock_program_id,
);
let result = bank.process_transaction(&tx);
assert!(result.is_err());
assert!(bank.get_account(&rent_paying_account.pubkey()).is_none());
// Try to create RentExempt account
let rent_exempt_account = Keypair::new();
let tx = system_transaction::create_account(
&mint_keypair,
&rent_exempt_account,
recent_blockhash,
rent_exempt_minimum,
account_data_size as u64,
&mock_program_id,
);
let result = bank.process_transaction(&tx);
assert!(result.is_ok());
assert!(check_account_is_rent_exempt(&rent_exempt_account.pubkey()));
}
#[test]
fn test_drained_created_account() {
let GenesisConfigInfo {
mut genesis_config,
mint_keypair,
..
} = create_genesis_config_with_leader(sol_to_lamports(100.), &Pubkey::new_unique(), 42);
genesis_config.rent = Rent::default();
activate_all_features(&mut genesis_config);
let mock_program_id = Pubkey::new_unique();
// small enough to not pay rent, thus bypassing the data clearing rent
// mechanism
let data_size_no_rent = 100;
// large enough to pay rent, will have data cleared
let data_size_rent = 10000;
let lamports_to_transfer = 100;
// Create legacy accounts of various kinds
let created_keypair = Keypair::new();
let mut bank = Bank::new_for_tests(&genesis_config);
bank.add_mockup_builtin(mock_program_id, mock_transfer_process_instruction);
let recent_blockhash = bank.last_blockhash();
// Create and drain a small data size account
let create_instruction = system_instruction::create_account(
&mint_keypair.pubkey(),
&created_keypair.pubkey(),
lamports_to_transfer,
data_size_no_rent,
&mock_program_id,
);
let account_metas = vec![
AccountMeta::new(mint_keypair.pubkey(), true),
AccountMeta::new(created_keypair.pubkey(), true),
AccountMeta::new(mint_keypair.pubkey(), false),
];
let transfer_from_instruction = Instruction::new_with_bincode(
mock_program_id,
&MockTransferInstruction::Transfer(lamports_to_transfer),
account_metas,
);
let tx = Transaction::new_signed_with_payer(
&[create_instruction, transfer_from_instruction],
Some(&mint_keypair.pubkey()),
&[&mint_keypair, &created_keypair],
recent_blockhash,
);
let result = bank.process_transaction(&tx);
assert!(result.is_ok());
// account data is not stored because of zero balance even though its
// data wasn't cleared
assert!(bank.get_account(&created_keypair.pubkey()).is_none());
// Create and drain a large data size account
let create_instruction = system_instruction::create_account(
&mint_keypair.pubkey(),
&created_keypair.pubkey(),
lamports_to_transfer,
data_size_rent,
&mock_program_id,
);
let account_metas = vec![
AccountMeta::new(mint_keypair.pubkey(), true),
AccountMeta::new(created_keypair.pubkey(), true),
AccountMeta::new(mint_keypair.pubkey(), false),
];
let transfer_from_instruction = Instruction::new_with_bincode(
mock_program_id,
&MockTransferInstruction::Transfer(lamports_to_transfer),
account_metas,
);
let tx = Transaction::new_signed_with_payer(
&[create_instruction, transfer_from_instruction],
Some(&mint_keypair.pubkey()),
&[&mint_keypair, &created_keypair],
recent_blockhash,
);
let result = bank.process_transaction(&tx);
assert!(result.is_ok());
// account data is not stored because of zero balance
assert!(bank.get_account(&created_keypair.pubkey()).is_none());
}
#[test]
fn test_rent_state_changes_sysvars() {
let GenesisConfigInfo {
mut genesis_config,
mint_keypair,
..
} = create_genesis_config_with_leader(sol_to_lamports(100.), &Pubkey::new_unique(), 42);
genesis_config.rent = Rent::default();
let validator_pubkey = solana_sdk::pubkey::new_rand();
let validator_stake_lamports = sol_to_lamports(1.);
let validator_staking_keypair = Keypair::new();
let validator_voting_keypair = Keypair::new();
let validator_vote_account = vote_state::create_account(
&validator_voting_keypair.pubkey(),
&validator_pubkey,
0,
validator_stake_lamports,
);
let validator_stake_account = stake_state::create_account(
&validator_staking_keypair.pubkey(),
&validator_voting_keypair.pubkey(),
&validator_vote_account,
&genesis_config.rent,
validator_stake_lamports,
);
genesis_config.accounts.insert(
validator_pubkey,
Account::new(
genesis_config.rent.minimum_balance(0),
0,
&system_program::id(),
),
);
genesis_config.accounts.insert(
validator_staking_keypair.pubkey(),
Account::from(validator_stake_account),
);
genesis_config.accounts.insert(
validator_voting_keypair.pubkey(),
Account::from(validator_vote_account),
);
let bank = Bank::new_for_tests(&genesis_config);
// Ensure transactions with sysvars succeed, even though sysvars appear RentPaying by balance
let tx = Transaction::new_signed_with_payer(
&[stake_instruction::deactivate_stake(
&validator_staking_keypair.pubkey(),
&validator_staking_keypair.pubkey(),
)],
Some(&mint_keypair.pubkey()),
&[&mint_keypair, &validator_staking_keypair],
bank.last_blockhash(),
);
let result = bank.process_transaction(&tx);
assert!(result.is_ok());
}
#[test]
fn test_invalid_rent_state_changes_fee_payer() {
let GenesisConfigInfo {
mut genesis_config,
mint_keypair,
..
} = create_genesis_config_with_leader(sol_to_lamports(100.), &Pubkey::new_unique(), 42);
genesis_config.rent = Rent::default();
genesis_config.fee_rate_governor = FeeRateGovernor::new(
solana_sdk::fee_calculator::DEFAULT_TARGET_LAMPORTS_PER_SIGNATURE,
solana_sdk::fee_calculator::DEFAULT_TARGET_SIGNATURES_PER_SLOT,
);
let rent_exempt_minimum = genesis_config.rent.minimum_balance(0);
// Create legacy rent-paying System account
let rent_paying_fee_payer = Keypair::new();
genesis_config.accounts.insert(
rent_paying_fee_payer.pubkey(),
Account::new(rent_exempt_minimum - 1, 0, &system_program::id()),
);
// Create RentExempt recipient account
let recipient = Pubkey::new_unique();
genesis_config.accounts.insert(
recipient,
Account::new(rent_exempt_minimum, 0, &system_program::id()),
);
let bank = Bank::new_for_tests(&genesis_config);
let recent_blockhash = bank.last_blockhash();
let check_account_is_rent_exempt = |pubkey: &Pubkey| -> bool {
let account = bank.get_account(pubkey).unwrap();
Rent::default().is_exempt(account.lamports(), account.data().len())
};
// Create just-rent-exempt fee-payer
let rent_exempt_fee_payer = Keypair::new();
bank.transfer(
rent_exempt_minimum,
&mint_keypair,
&rent_exempt_fee_payer.pubkey(),
)
.unwrap();
// Dummy message to determine fee amount
let dummy_message = SanitizedMessage::try_from(Message::new_with_blockhash(
&[system_instruction::transfer(
&rent_exempt_fee_payer.pubkey(),
&recipient,
sol_to_lamports(1.),
)],
Some(&rent_exempt_fee_payer.pubkey()),
&recent_blockhash,
))
.unwrap();
let fee = bank.get_fee_for_message(&dummy_message).unwrap();
// RentPaying fee-payer can remain RentPaying
let tx = Transaction::new(
&[&rent_paying_fee_payer, &mint_keypair],
Message::new(
&[system_instruction::transfer(
&mint_keypair.pubkey(),
&recipient,
rent_exempt_minimum,
)],
Some(&rent_paying_fee_payer.pubkey()),
),
recent_blockhash,
);
let result = bank.process_transaction(&tx);
assert!(result.is_ok());
assert!(!check_account_is_rent_exempt(
&rent_paying_fee_payer.pubkey()
));
// RentPaying fee-payer can remain RentPaying on failed executed tx
let sender = Keypair::new();
let fee_payer_balance = bank.get_balance(&rent_paying_fee_payer.pubkey());
let tx = Transaction::new(
&[&rent_paying_fee_payer, &sender],
Message::new(
&[system_instruction::transfer(
&sender.pubkey(),
&recipient,
rent_exempt_minimum,
)],
Some(&rent_paying_fee_payer.pubkey()),
),
recent_blockhash,
);
let result = bank.process_transaction(&tx);
assert_eq!(
result.unwrap_err(),
TransactionError::InstructionError(0, InstructionError::Custom(1))
);
assert_ne!(
fee_payer_balance,
bank.get_balance(&rent_paying_fee_payer.pubkey())
);
assert!(!check_account_is_rent_exempt(
&rent_paying_fee_payer.pubkey()
));
// RentPaying fee-payer can be emptied with fee and transaction
let tx = Transaction::new(
&[&rent_paying_fee_payer],
Message::new(
&[system_instruction::transfer(
&rent_paying_fee_payer.pubkey(),
&recipient,
bank.get_balance(&rent_paying_fee_payer.pubkey()) - fee,
)],
Some(&rent_paying_fee_payer.pubkey()),
),
recent_blockhash,
);
let result = bank.process_transaction(&tx);
assert!(result.is_ok());
assert_eq!(0, bank.get_balance(&rent_paying_fee_payer.pubkey()));
// RentExempt fee-payer cannot become RentPaying from transaction fee
let tx = Transaction::new(
&[&rent_exempt_fee_payer, &mint_keypair],
Message::new(
&[system_instruction::transfer(
&mint_keypair.pubkey(),
&recipient,
rent_exempt_minimum,
)],
Some(&rent_exempt_fee_payer.pubkey()),
),
recent_blockhash,
);
let result = bank.process_transaction(&tx);
assert_eq!(
result.unwrap_err(),
TransactionError::InsufficientFundsForRent { account_index: 0 }
);
assert!(check_account_is_rent_exempt(
&rent_exempt_fee_payer.pubkey()
));
// RentExempt fee-payer cannot become RentPaying via failed executed tx
let tx = Transaction::new(
&[&rent_exempt_fee_payer, &sender],
Message::new(
&[system_instruction::transfer(
&sender.pubkey(),
&recipient,
rent_exempt_minimum,
)],
Some(&rent_exempt_fee_payer.pubkey()),
),
recent_blockhash,
);
let result = bank.process_transaction(&tx);
assert_eq!(
result.unwrap_err(),
TransactionError::InsufficientFundsForRent { account_index: 0 }
);
assert!(check_account_is_rent_exempt(
&rent_exempt_fee_payer.pubkey()
));
// For good measure, show that a RentExempt fee-payer that is also debited by a transaction
// cannot become RentPaying by that debit, but can still be charged for the fee
bank.transfer(fee, &mint_keypair, &rent_exempt_fee_payer.pubkey())
.unwrap();
let fee_payer_balance = bank.get_balance(&rent_exempt_fee_payer.pubkey());
assert_eq!(fee_payer_balance, rent_exempt_minimum + fee);
let tx = Transaction::new(
&[&rent_exempt_fee_payer],
Message::new(
&[system_instruction::transfer(
&rent_exempt_fee_payer.pubkey(),
&recipient,
fee,
)],
Some(&rent_exempt_fee_payer.pubkey()),
),
recent_blockhash,
);
let result = bank.process_transaction(&tx);
assert_eq!(
result.unwrap_err(),
TransactionError::InsufficientFundsForRent { account_index: 0 }
);
assert_eq!(
fee_payer_balance - fee,
bank.get_balance(&rent_exempt_fee_payer.pubkey())
);
assert!(check_account_is_rent_exempt(
&rent_exempt_fee_payer.pubkey()
));
// Also show that a RentExempt fee-payer can be completely emptied via fee and transaction
bank.transfer(fee + 1, &mint_keypair, &rent_exempt_fee_payer.pubkey())
.unwrap();
assert!(bank.get_balance(&rent_exempt_fee_payer.pubkey()) > rent_exempt_minimum + fee);
let tx = Transaction::new(
&[&rent_exempt_fee_payer],
Message::new(
&[system_instruction::transfer(
&rent_exempt_fee_payer.pubkey(),
&recipient,
bank.get_balance(&rent_exempt_fee_payer.pubkey()) - fee,
)],
Some(&rent_exempt_fee_payer.pubkey()),
),
recent_blockhash,
);
let result = bank.process_transaction(&tx);
assert!(result.is_ok());
assert_eq!(0, bank.get_balance(&rent_exempt_fee_payer.pubkey()));
// ... but not if the fee alone would make it RentPaying
bank.transfer(
rent_exempt_minimum + 1,
&mint_keypair,
&rent_exempt_fee_payer.pubkey(),
)
.unwrap();
assert!(bank.get_balance(&rent_exempt_fee_payer.pubkey()) < rent_exempt_minimum + fee);
let tx = Transaction::new(
&[&rent_exempt_fee_payer],
Message::new(
&[system_instruction::transfer(
&rent_exempt_fee_payer.pubkey(),
&recipient,
bank.get_balance(&rent_exempt_fee_payer.pubkey()) - fee,
)],
Some(&rent_exempt_fee_payer.pubkey()),
),
recent_blockhash,
);
let result = bank.process_transaction(&tx);
assert_eq!(
result.unwrap_err(),
TransactionError::InsufficientFundsForRent { account_index: 0 }
);
assert!(check_account_is_rent_exempt(
&rent_exempt_fee_payer.pubkey()
));
}
// Ensure System transfers of any size can be made to the incinerator
#[test]
fn test_rent_state_incinerator() {
let GenesisConfigInfo {
mut genesis_config,
mint_keypair,
..
} = create_genesis_config_with_leader(sol_to_lamports(100.), &Pubkey::new_unique(), 42);
genesis_config.rent = Rent::default();
let rent_exempt_minimum = genesis_config.rent.minimum_balance(0);
let bank = Bank::new_for_tests(&genesis_config);
for amount in [rent_exempt_minimum - 1, rent_exempt_minimum] {
bank.transfer(amount, &mint_keypair, &solana_sdk::incinerator::id())
.unwrap();
}
}
#[test]
fn test_rent_state_list_len() {
let GenesisConfigInfo {
mut genesis_config,
mint_keypair,
..
} = create_genesis_config_with_leader(sol_to_lamports(100.), &Pubkey::new_unique(), 42);
genesis_config.rent = Rent::default();
let bank = Bank::new_for_tests(&genesis_config);
let recipient = Pubkey::new_unique();
let tx = system_transaction::transfer(
&mint_keypair,
&recipient,
sol_to_lamports(1.),
bank.last_blockhash(),
);
let num_accounts = tx.message().account_keys.len();
let sanitized_tx = SanitizedTransaction::try_from_legacy_transaction(tx).unwrap();
let mut error_counters = TransactionErrorMetrics::default();
let loaded_txs = bank.rc.accounts.load_accounts(
&bank.ancestors,
&[sanitized_tx.clone()],
vec![(Ok(()), None)],
&bank.blockhash_queue.read().unwrap(),
&mut error_counters,
&bank.rent_collector,
&bank.feature_set,
&FeeStructure::default(),
None,
RewardInterval::OutsideInterval,
&HashMap::new(),
&LoadedProgramsForTxBatch::default(),
);
let compute_budget = bank.runtime_config.compute_budget.unwrap_or_else(|| {
ComputeBudget::new(compute_budget::DEFAULT_INSTRUCTION_COMPUTE_UNIT_LIMIT as u64)
});
let transaction_context = TransactionContext::new(
loaded_txs[0].0.as_ref().unwrap().accounts.clone(),
Some(Rent::default()),
compute_budget.max_invoke_stack_height,
compute_budget.max_instruction_trace_length,
);
assert_eq!(
bank.get_transaction_account_state_info(&transaction_context, sanitized_tx.message())
.len(),
num_accounts,
);
}
#[test]
fn test_update_accounts_data_size() {
// Test: Subtraction saturates at 0
{
let bank = create_simple_test_bank(100);
let initial_data_size = bank.load_accounts_data_size() as i64;
let data_size = 567;
bank.accounts_data_size_delta_on_chain
.store(data_size, Release);
bank.update_accounts_data_size_delta_on_chain(
(initial_data_size + data_size + 1).saturating_neg(),
);
assert_eq!(bank.load_accounts_data_size(), 0);
}
// Test: Addition saturates at u64::MAX
{
let mut bank = create_simple_test_bank(100);
let data_size_remaining = 567;
bank.accounts_data_size_initial = u64::MAX - data_size_remaining;
bank.accounts_data_size_delta_off_chain
.store((data_size_remaining + 1) as i64, Release);
assert_eq!(bank.load_accounts_data_size(), u64::MAX);
}
// Test: Updates work as expected
{
// Set the accounts data size to be in the middle, then perform a bunch of small
// updates, checking the results after each one.
let mut bank = create_simple_test_bank(100);
bank.accounts_data_size_initial = u32::MAX as u64;
let mut rng = rand::thread_rng();
for _ in 0..100 {
let initial = bank.load_accounts_data_size() as i64;
let delta1 = rng.gen_range(-500, 500);
bank.update_accounts_data_size_delta_on_chain(delta1);
let delta2 = rng.gen_range(-500, 500);
bank.update_accounts_data_size_delta_off_chain(delta2);
assert_eq!(
bank.load_accounts_data_size() as i64,
initial.saturating_add(delta1).saturating_add(delta2),
);
}
}
}
#[test]
fn test_skip_rewrite() {
solana_logger::setup();
let mut account = AccountSharedData::default();
let bank_slot = 10;
for account_rent_epoch in 0..3 {
account.set_rent_epoch(account_rent_epoch);
for rent_amount in [0, 1] {
for loaded_slot in (bank_slot - 1)..=bank_slot {
for old_rent_epoch in account_rent_epoch.saturating_sub(1)..=account_rent_epoch {
let skip = Bank::skip_rewrite(rent_amount, &account);
let mut should_skip = true;
if rent_amount != 0 || account_rent_epoch == 0 {
should_skip = false;
}
assert_eq!(
skip,
should_skip,
"{:?}",
(
account_rent_epoch,
old_rent_epoch,
rent_amount,
loaded_slot,
old_rent_epoch
)
);
}
}
}
}
}
#[test]
fn test_inner_instructions_list_from_instruction_trace() {
let instruction_trace = [1, 2, 1, 1, 2, 3, 2];
let mut transaction_context = TransactionContext::new(vec![], None, 3, instruction_trace.len());
for (index_in_trace, stack_height) in instruction_trace.into_iter().enumerate() {
while stack_height <= transaction_context.get_instruction_context_stack_height() {
transaction_context.pop().unwrap();
}
if stack_height > transaction_context.get_instruction_context_stack_height() {
transaction_context
.get_next_instruction_context()
.unwrap()
.configure(&[], &[], &[index_in_trace as u8]);
transaction_context.push().unwrap();
}
}
let inner_instructions = inner_instructions_list_from_instruction_trace(&transaction_context);
assert_eq!(
inner_instructions,
vec![
vec![InnerInstruction {
instruction: CompiledInstruction::new_from_raw_parts(0, vec![1], vec![]),
stack_height: 2,
}],
vec![],
vec![
InnerInstruction {
instruction: CompiledInstruction::new_from_raw_parts(0, vec![4], vec![]),
stack_height: 2,
},
InnerInstruction {
instruction: CompiledInstruction::new_from_raw_parts(0, vec![5], vec![]),
stack_height: 3,
},
InnerInstruction {
instruction: CompiledInstruction::new_from_raw_parts(0, vec![6], vec![]),
stack_height: 2,
},
]
]
);
}
#[derive(Serialize, Deserialize)]
enum MockReallocInstruction {
Realloc(usize, u64, Pubkey),
}
declare_process_instruction!(mock_realloc_process_instruction, 1, |invoke_context| {
let transaction_context = &invoke_context.transaction_context;
let instruction_context = transaction_context.get_current_instruction_context()?;
let instruction_data = instruction_context.get_instruction_data();
if let Ok(instruction) = bincode::deserialize(instruction_data) {
match instruction {
MockReallocInstruction::Realloc(new_size, new_balance, _) => {
// Set data length
instruction_context
.try_borrow_instruction_account(transaction_context, 1)?
.set_data_length(new_size)?;
// set balance
let current_balance = instruction_context
.try_borrow_instruction_account(transaction_context, 1)?
.get_lamports();
let diff_balance = (new_balance as i64).saturating_sub(current_balance as i64);
let amount = diff_balance.unsigned_abs();
if diff_balance.is_positive() {
instruction_context
.try_borrow_instruction_account(transaction_context, 0)?
.checked_sub_lamports(amount)?;
instruction_context
.try_borrow_instruction_account(transaction_context, 1)?
.set_lamports(new_balance)?;
} else {
instruction_context
.try_borrow_instruction_account(transaction_context, 0)?
.checked_add_lamports(amount)?;
instruction_context
.try_borrow_instruction_account(transaction_context, 1)?
.set_lamports(new_balance)?;
}
Ok(())
}
}
} else {
Err(InstructionError::InvalidInstructionData)
}
});
fn create_mock_realloc_tx(
payer: &Keypair,
funder: &Keypair,
reallocd: &Pubkey,
new_size: usize,
new_balance: u64,
mock_program_id: Pubkey,
recent_blockhash: Hash,
) -> Transaction {
let account_metas = vec![
AccountMeta::new(funder.pubkey(), false),
AccountMeta::new(*reallocd, false),
];
let instruction = Instruction::new_with_bincode(
mock_program_id,
&MockReallocInstruction::Realloc(new_size, new_balance, Pubkey::new_unique()),
account_metas,
);
Transaction::new_signed_with_payer(
&[instruction],
Some(&payer.pubkey()),
&[payer],
recent_blockhash,
)
}
#[test]
fn test_resize_and_rent() {
let GenesisConfigInfo {
mut genesis_config,
mint_keypair,
..
} = create_genesis_config_with_leader(1_000_000_000, &Pubkey::new_unique(), 42);
genesis_config.rent = Rent::default();
activate_all_features(&mut genesis_config);
let mut bank = Bank::new_for_tests(&genesis_config);
let mock_program_id = Pubkey::new_unique();
bank.add_mockup_builtin(mock_program_id, mock_realloc_process_instruction);
let recent_blockhash = bank.last_blockhash();
let account_data_size_small = 1024;
let rent_exempt_minimum_small = genesis_config.rent.minimum_balance(account_data_size_small);
let account_data_size_large = 2048;
let rent_exempt_minimum_large = genesis_config.rent.minimum_balance(account_data_size_large);
let funding_keypair = Keypair::new();
bank.store_account(
&funding_keypair.pubkey(),
&AccountSharedData::new(1_000_000_000, 0, &mock_program_id),
);
let rent_paying_pubkey = solana_sdk::pubkey::new_rand();
let mut rent_paying_account = AccountSharedData::new(
rent_exempt_minimum_small - 1,
account_data_size_small,
&mock_program_id,
);
rent_paying_account.set_rent_epoch(1);
// restore program-owned account
bank.store_account(&rent_paying_pubkey, &rent_paying_account);
// rent paying, realloc larger, fail because not rent exempt
let tx = create_mock_realloc_tx(
&mint_keypair,
&funding_keypair,
&rent_paying_pubkey,
account_data_size_large,
rent_exempt_minimum_small - 1,
mock_program_id,
recent_blockhash,
);
let expected_err = {
let account_index = tx
.message
.account_keys
.iter()
.position(|key| key == &rent_paying_pubkey)
.unwrap() as u8;
TransactionError::InsufficientFundsForRent { account_index }
};
assert_eq!(bank.process_transaction(&tx).unwrap_err(), expected_err);
assert_eq!(
rent_exempt_minimum_small - 1,
bank.get_account(&rent_paying_pubkey).unwrap().lamports()
);
// rent paying, realloc larger and rent exempt
let tx = create_mock_realloc_tx(
&mint_keypair,
&funding_keypair,
&rent_paying_pubkey,
account_data_size_large,
rent_exempt_minimum_large,
mock_program_id,
recent_blockhash,
);
let result = bank.process_transaction(&tx);
assert!(result.is_ok());
assert_eq!(
rent_exempt_minimum_large,
bank.get_account(&rent_paying_pubkey).unwrap().lamports()
);
// rent exempt, realloc small, fail because not rent exempt
let tx = create_mock_realloc_tx(
&mint_keypair,
&funding_keypair,
&rent_paying_pubkey,
account_data_size_small,
rent_exempt_minimum_small - 1,
mock_program_id,
recent_blockhash,
);
let expected_err = {
let account_index = tx
.message
.account_keys
.iter()
.position(|key| key == &rent_paying_pubkey)
.unwrap() as u8;
TransactionError::InsufficientFundsForRent { account_index }
};
assert_eq!(bank.process_transaction(&tx).unwrap_err(), expected_err);
assert_eq!(
rent_exempt_minimum_large,
bank.get_account(&rent_paying_pubkey).unwrap().lamports()
);
// rent exempt, realloc smaller and rent exempt
let tx = create_mock_realloc_tx(
&mint_keypair,
&funding_keypair,
&rent_paying_pubkey,
account_data_size_small,
rent_exempt_minimum_small,
mock_program_id,
recent_blockhash,
);
let result = bank.process_transaction(&tx);
assert!(result.is_ok());
assert_eq!(
rent_exempt_minimum_small,
bank.get_account(&rent_paying_pubkey).unwrap().lamports()
);
// rent exempt, realloc large, fail because not rent exempt
let tx = create_mock_realloc_tx(
&mint_keypair,
&funding_keypair,
&rent_paying_pubkey,
account_data_size_large,
rent_exempt_minimum_large - 1,
mock_program_id,
recent_blockhash,
);
let expected_err = {
let account_index = tx
.message
.account_keys
.iter()
.position(|key| key == &rent_paying_pubkey)
.unwrap() as u8;
TransactionError::InsufficientFundsForRent { account_index }
};
assert_eq!(bank.process_transaction(&tx).unwrap_err(), expected_err);
assert_eq!(
rent_exempt_minimum_small,
bank.get_account(&rent_paying_pubkey).unwrap().lamports()
);
// rent exempt, realloc large and rent exempt
let tx = create_mock_realloc_tx(
&mint_keypair,
&funding_keypair,
&rent_paying_pubkey,
account_data_size_large,
rent_exempt_minimum_large,
mock_program_id,
recent_blockhash,
);
let result = bank.process_transaction(&tx);
assert!(result.is_ok());
assert_eq!(
rent_exempt_minimum_large,
bank.get_account(&rent_paying_pubkey).unwrap().lamports()
);
let created_keypair = Keypair::new();
// create account, not rent exempt
let tx = system_transaction::create_account(
&mint_keypair,
&created_keypair,
recent_blockhash,
rent_exempt_minimum_small - 1,
account_data_size_small as u64,
&system_program::id(),
);
let expected_err = {
let account_index = tx
.message
.account_keys
.iter()
.position(|key| key == &created_keypair.pubkey())
.unwrap() as u8;
TransactionError::InsufficientFundsForRent { account_index }
};
assert_eq!(bank.process_transaction(&tx).unwrap_err(), expected_err);
// create account, rent exempt
let tx = system_transaction::create_account(
&mint_keypair,
&created_keypair,
recent_blockhash,
rent_exempt_minimum_small,
account_data_size_small as u64,
&system_program::id(),
);
let result = bank.process_transaction(&tx);
assert!(result.is_ok());
assert_eq!(
rent_exempt_minimum_small,
bank.get_account(&created_keypair.pubkey())
.unwrap()
.lamports()
);
let created_keypair = Keypair::new();
// create account, no data
let tx = system_transaction::create_account(
&mint_keypair,
&created_keypair,
recent_blockhash,
rent_exempt_minimum_small - 1,
0,
&system_program::id(),
);
let result = bank.process_transaction(&tx);
assert!(result.is_ok());
assert_eq!(
rent_exempt_minimum_small - 1,
bank.get_account(&created_keypair.pubkey())
.unwrap()
.lamports()
);
// alloc but not rent exempt
let tx = system_transaction::allocate(
&mint_keypair,
&created_keypair,
recent_blockhash,
(account_data_size_small + 1) as u64,
);
let expected_err = {
let account_index = tx
.message
.account_keys
.iter()
.position(|key| key == &created_keypair.pubkey())
.unwrap() as u8;
TransactionError::InsufficientFundsForRent { account_index }
};
assert_eq!(bank.process_transaction(&tx).unwrap_err(), expected_err);
// bring balance of account up to rent exemption
let tx = system_transaction::transfer(
&mint_keypair,
&created_keypair.pubkey(),
1,
recent_blockhash,
);
let result = bank.process_transaction(&tx);
assert!(result.is_ok());
assert_eq!(
rent_exempt_minimum_small,
bank.get_account(&created_keypair.pubkey())
.unwrap()
.lamports()
);
// allocate as rent exempt
let tx = system_transaction::allocate(
&mint_keypair,
&created_keypair,
recent_blockhash,
account_data_size_small as u64,
);
let result = bank.process_transaction(&tx);
assert!(result.is_ok());
assert_eq!(
rent_exempt_minimum_small,
bank.get_account(&created_keypair.pubkey())
.unwrap()
.lamports()
);
}
/// Ensure that accounts data size is updated correctly on resize transactions
#[test]
fn test_accounts_data_size_and_resize_transactions() {
let GenesisConfigInfo {
genesis_config,
mint_keypair,
..
} = genesis_utils::create_genesis_config(100 * LAMPORTS_PER_SOL);
let mut bank = Bank::new_for_tests(&genesis_config);
let mock_program_id = Pubkey::new_unique();
bank.add_mockup_builtin(mock_program_id, mock_realloc_process_instruction);
let recent_blockhash = bank.last_blockhash();
let funding_keypair = Keypair::new();
bank.store_account(
&funding_keypair.pubkey(),
&AccountSharedData::new(10 * LAMPORTS_PER_SOL, 0, &mock_program_id),
);
let mut rng = rand::thread_rng();
// Test case: Grow account
{
let account_pubkey = Pubkey::new_unique();
let account_balance = LAMPORTS_PER_SOL;
let account_size = rng.gen_range(
1,
MAX_PERMITTED_DATA_LENGTH as usize - MAX_PERMITTED_DATA_INCREASE,
);
let account_data = AccountSharedData::new(account_balance, account_size, &mock_program_id);
bank.store_account(&account_pubkey, &account_data);
let accounts_data_size_before = bank.load_accounts_data_size();
let account_grow_size = rng.gen_range(1, MAX_PERMITTED_DATA_INCREASE);
let transaction = create_mock_realloc_tx(
&mint_keypair,
&funding_keypair,
&account_pubkey,
account_size + account_grow_size,
account_balance,
mock_program_id,
recent_blockhash,
);
let result = bank.process_transaction(&transaction);
assert!(result.is_ok());
let accounts_data_size_after = bank.load_accounts_data_size();
assert_eq!(
accounts_data_size_after,
accounts_data_size_before.saturating_add(account_grow_size as u64),
);
}
// Test case: Shrink account
{
let account_pubkey = Pubkey::new_unique();
let account_balance = LAMPORTS_PER_SOL;
let account_size =
rng.gen_range(MAX_PERMITTED_DATA_LENGTH / 2, MAX_PERMITTED_DATA_LENGTH) as usize;
let account_data = AccountSharedData::new(account_balance, account_size, &mock_program_id);
bank.store_account(&account_pubkey, &account_data);
let accounts_data_size_before = bank.load_accounts_data_size();
let account_shrink_size = rng.gen_range(1, account_size);
let transaction = create_mock_realloc_tx(
&mint_keypair,
&funding_keypair,
&account_pubkey,
account_size - account_shrink_size,
account_balance,
mock_program_id,
recent_blockhash,
);
let result = bank.process_transaction(&transaction);
assert!(result.is_ok());
let accounts_data_size_after = bank.load_accounts_data_size();
assert_eq!(
accounts_data_size_after,
accounts_data_size_before.saturating_sub(account_shrink_size as u64),
);
}
}
#[test]
fn test_get_rent_paying_pubkeys() {
let lamports = 1;
let bank = create_simple_test_bank(lamports);
let n = 432_000;
assert!(bank.get_rent_paying_pubkeys(&(0, 1, n)).is_none());
assert!(bank.get_rent_paying_pubkeys(&(0, 2, n)).is_none());
assert!(bank.get_rent_paying_pubkeys(&(0, 0, n)).is_none());
let pk1 = Pubkey::from([2; 32]);
let pk2 = Pubkey::from([3; 32]);
let index1 = accounts_partition::partition_from_pubkey(&pk1, n);
let index2 = accounts_partition::partition_from_pubkey(&pk2, n);
assert!(index1 > 0, "{}", index1);
assert!(index2 > index1, "{index2}, {index1}");
let epoch_schedule = EpochSchedule::custom(n, 0, false);
let mut rent_paying_accounts_by_partition = RentPayingAccountsByPartition::new(&epoch_schedule);
rent_paying_accounts_by_partition.add_account(&pk1);
rent_paying_accounts_by_partition.add_account(&pk2);
bank.rc
.accounts
.accounts_db
.accounts_index
.rent_paying_accounts_by_partition
.set(rent_paying_accounts_by_partition)
.unwrap();
assert_eq!(
bank.get_rent_paying_pubkeys(&(0, 1, n)),
Some(HashSet::default())
);
assert_eq!(
bank.get_rent_paying_pubkeys(&(0, 2, n)),
Some(HashSet::default())
);
assert_eq!(
bank.get_rent_paying_pubkeys(&(index1.saturating_sub(1), index1, n)),
Some(HashSet::from([pk1]))
);
assert_eq!(
bank.get_rent_paying_pubkeys(&(index2.saturating_sub(1), index2, n)),
Some(HashSet::from([pk2]))
);
assert_eq!(
bank.get_rent_paying_pubkeys(&(index1.saturating_sub(1), index2, n)),
Some(HashSet::from([pk2, pk1]))
);
assert_eq!(
bank.get_rent_paying_pubkeys(&(0, 0, n)),
Some(HashSet::default())
);
}
/// Ensure that accounts data size is updated correctly by rent collection
#[test]
fn test_accounts_data_size_and_rent_collection() {
for set_exempt_rent_epoch_max in [false, true] {
let GenesisConfigInfo {
mut genesis_config, ..
} = genesis_utils::create_genesis_config(100 * LAMPORTS_PER_SOL);
genesis_config.rent = Rent::default();
activate_all_features(&mut genesis_config);
let bank = Arc::new(Bank::new_for_tests(&genesis_config));
let bank = Arc::new(Bank::new_from_parent(
&bank,
&Pubkey::default(),
bank.slot() + bank.slot_count_per_normal_epoch(),
));
// make another bank so that any reclaimed accounts from the previous bank do not impact
// this test
let bank = Arc::new(Bank::new_from_parent(
&bank,
&Pubkey::default(),
bank.slot() + bank.slot_count_per_normal_epoch(),
));
// Store an account into the bank that is rent-paying and has data
let data_size = 123;
let mut account = AccountSharedData::new(1, data_size, &Pubkey::default());
let keypair = Keypair::new();
bank.store_account(&keypair.pubkey(), &account);
// Ensure if we collect rent from the account that it will be reclaimed
{
let info = bank.rent_collector.collect_from_existing_account(
&keypair.pubkey(),
&mut account,
None,
set_exempt_rent_epoch_max,
);
assert_eq!(info.account_data_len_reclaimed, data_size as u64);
}
// Collect rent for real
let accounts_data_size_delta_before_collecting_rent = bank.load_accounts_data_size_delta();
bank.collect_rent_eagerly();
let accounts_data_size_delta_after_collecting_rent = bank.load_accounts_data_size_delta();
let accounts_data_size_delta_delta = accounts_data_size_delta_after_collecting_rent
- accounts_data_size_delta_before_collecting_rent;
assert!(accounts_data_size_delta_delta < 0);
let reclaimed_data_size = accounts_data_size_delta_delta.saturating_neg() as usize;
// Ensure the account is reclaimed by rent collection
assert_eq!(reclaimed_data_size, data_size,);
}
}
#[test]
fn test_accounts_data_size_with_default_bank() {
let bank = Bank::default_for_tests();
assert_eq!(
bank.load_accounts_data_size() as usize,
bank.get_total_accounts_stats().unwrap().data_len
);
}
#[test]
fn test_accounts_data_size_from_genesis() {
let GenesisConfigInfo {
mut genesis_config,
mint_keypair,
..
} = genesis_utils::create_genesis_config_with_leader(
1_000_000 * LAMPORTS_PER_SOL,
&Pubkey::new_unique(),
100 * LAMPORTS_PER_SOL,
);
genesis_config.rent = Rent::default();
genesis_config.ticks_per_slot = 3;
let mut bank = Arc::new(Bank::new_for_tests(&genesis_config));
assert_eq!(
bank.load_accounts_data_size() as usize,
bank.get_total_accounts_stats().unwrap().data_len
);
// Create accounts over a number of banks and ensure the accounts data size remains correct
for _ in 0..10 {
bank = Arc::new(Bank::new_from_parent(
&bank,
&Pubkey::default(),
bank.slot() + 1,
));
// Store an account into the bank that is rent-exempt and has data
let data_size = rand::thread_rng().gen_range(3333, 4444);
let transaction = system_transaction::create_account(
&mint_keypair,
&Keypair::new(),
bank.last_blockhash(),
genesis_config.rent.minimum_balance(data_size),
data_size as u64,
&solana_sdk::system_program::id(),
);
bank.process_transaction(&transaction).unwrap();
bank.fill_bank_with_ticks_for_tests();
assert_eq!(
bank.load_accounts_data_size() as usize,
bank.get_total_accounts_stats().unwrap().data_len,
);
}
}
/// Ensures that if a transaction exceeds the maximum allowed accounts data allocation size:
/// 1. The transaction fails
/// 2. The bank's accounts_data_size is unmodified
#[test]
fn test_cap_accounts_data_allocations_per_transaction() {
const NUM_MAX_SIZE_ALLOCATIONS_PER_TRANSACTION: usize =
MAX_PERMITTED_ACCOUNTS_DATA_ALLOCATIONS_PER_TRANSACTION as usize
/ MAX_PERMITTED_DATA_LENGTH as usize;
let (genesis_config, mint_keypair) = create_genesis_config(1_000_000 * LAMPORTS_PER_SOL);
let mut bank = Bank::new_for_tests(&genesis_config);
bank.activate_feature(&feature_set::enable_early_verification_of_account_modifications::id());
bank.activate_feature(&feature_set::cap_accounts_data_allocations_per_transaction::id());
let mut instructions = Vec::new();
let mut keypairs = vec![mint_keypair.insecure_clone()];
for _ in 0..=NUM_MAX_SIZE_ALLOCATIONS_PER_TRANSACTION {
let keypair = Keypair::new();
let instruction = system_instruction::create_account(
&mint_keypair.pubkey(),
&keypair.pubkey(),
bank.rent_collector()
.rent
.minimum_balance(MAX_PERMITTED_DATA_LENGTH as usize),
MAX_PERMITTED_DATA_LENGTH,
&solana_sdk::system_program::id(),
);
keypairs.push(keypair);
instructions.push(instruction);
}
let message = Message::new(&instructions, Some(&mint_keypair.pubkey()));
let signers: Vec<_> = keypairs.iter().collect();
let transaction = Transaction::new(&signers, message, bank.last_blockhash());
let accounts_data_size_before = bank.load_accounts_data_size();
let result = bank.process_transaction(&transaction);
let accounts_data_size_after = bank.load_accounts_data_size();
assert_eq!(accounts_data_size_before, accounts_data_size_after);
assert_eq!(
result,
Err(TransactionError::InstructionError(
NUM_MAX_SIZE_ALLOCATIONS_PER_TRANSACTION as u8,
solana_sdk::instruction::InstructionError::MaxAccountsDataAllocationsExceeded,
)),
);
}
#[test]
fn test_feature_activation_idempotent() {
let mut genesis_config = GenesisConfig::default();
const HASHES_PER_TICK_START: u64 = 3;
genesis_config.poh_config.hashes_per_tick = Some(HASHES_PER_TICK_START);
let mut bank = Bank::new_for_tests(&genesis_config);
assert_eq!(bank.hashes_per_tick, Some(HASHES_PER_TICK_START));
// Don't activate feature
bank.apply_feature_activations(ApplyFeatureActivationsCaller::NewFromParent, false);
assert_eq!(bank.hashes_per_tick, Some(HASHES_PER_TICK_START));
// Activate feature
let feature_account_balance =
std::cmp::max(genesis_config.rent.minimum_balance(Feature::size_of()), 1);
bank.store_account(
&feature_set::update_hashes_per_tick::id(),
&feature::create_account(&Feature { activated_at: None }, feature_account_balance),
);
bank.apply_feature_activations(ApplyFeatureActivationsCaller::NewFromParent, false);
assert_eq!(bank.hashes_per_tick, Some(DEFAULT_HASHES_PER_TICK));
// Activate feature "again"
bank.apply_feature_activations(ApplyFeatureActivationsCaller::NewFromParent, false);
assert_eq!(bank.hashes_per_tick, Some(DEFAULT_HASHES_PER_TICK));
}
#[test_case(true)]
#[test_case(false)]
fn test_stake_account_consistency_with_rent_epoch_max_feature(
rent_epoch_max_enabled_initially: bool,
) {
// this test can be removed once set_exempt_rent_epoch_max gets activated
solana_logger::setup();
let (mut genesis_config, _mint_keypair) = create_genesis_config(100 * LAMPORTS_PER_SOL);
genesis_config.rent = Rent::default();
let mut bank = Bank::new_for_tests(&genesis_config);
let expected_initial_rent_epoch = if rent_epoch_max_enabled_initially {
bank.activate_feature(&solana_sdk::feature_set::set_exempt_rent_epoch_max::id());
RENT_EXEMPT_RENT_EPOCH
} else {
Epoch::default()
};
assert!(bank.rc.accounts.accounts_db.assert_stakes_cache_consistency);
let mut pubkey_bytes_early = [0u8; 32];
pubkey_bytes_early[31] = 2;
let stake_id1 = Pubkey::from(pubkey_bytes_early);
let vote_id = solana_sdk::pubkey::new_rand();
let stake_account1 = crate::stakes::tests::create_stake_account(12300000, &vote_id, &stake_id1);
// set up accounts
bank.store_account_and_update_capitalization(&stake_id1, &stake_account1);
// create banks at a few slots
assert_eq!(
bank.load_slow(&bank.ancestors, &stake_id1)
.unwrap()
.0
.rent_epoch(),
0 // manually created, so default is 0
);
let slot = 1;
let slots_per_epoch = bank.epoch_schedule().get_slots_in_epoch(0);
let mut bank = Bank::new_from_parent(&Arc::new(bank), &Pubkey::default(), slot);
if !rent_epoch_max_enabled_initially {
bank.activate_feature(&solana_sdk::feature_set::set_exempt_rent_epoch_max::id());
}
let bank = Arc::new(bank);
let slot = slots_per_epoch - 1;
assert_eq!(
bank.load_slow(&bank.ancestors, &stake_id1)
.unwrap()
.0
.rent_epoch(),
// rent has been collected, so if rent epoch is max is activated, this will be max by now
expected_initial_rent_epoch
);
let mut bank = Arc::new(Bank::new_from_parent(&bank, &Pubkey::default(), slot));
let last_slot_in_epoch = bank.epoch_schedule().get_last_slot_in_epoch(1);
let slot = last_slot_in_epoch - 2;
assert_eq!(
bank.load_slow(&bank.ancestors, &stake_id1)
.unwrap()
.0
.rent_epoch(),
expected_initial_rent_epoch
);
bank = Arc::new(Bank::new_from_parent(&bank, &Pubkey::default(), slot));
assert_eq!(
bank.load_slow(&bank.ancestors, &stake_id1)
.unwrap()
.0
.rent_epoch(),
expected_initial_rent_epoch
);
let slot = last_slot_in_epoch - 1;
bank = Arc::new(Bank::new_from_parent(&bank, &Pubkey::default(), slot));
assert_eq!(
bank.load_slow(&bank.ancestors, &stake_id1)
.unwrap()
.0
.rent_epoch(),
RENT_EXEMPT_RENT_EPOCH
);
}
#[test]
fn test_calculate_fee_with_congestion_multiplier() {
let lamports_scale: u64 = 5;
let base_lamports_per_signature: u64 = 5_000;
let cheap_lamports_per_signature: u64 = base_lamports_per_signature / lamports_scale;
let expensive_lamports_per_signature: u64 = base_lamports_per_signature * lamports_scale;
let signature_count: u64 = 2;
let signature_fee: u64 = 10;
let fee_structure = FeeStructure {
lamports_per_signature: signature_fee,
..FeeStructure::default()
};
// Two signatures, double the fee.
let key0 = Pubkey::new_unique();
let key1 = Pubkey::new_unique();
let ix0 = system_instruction::transfer(&key0, &key1, 1);
let ix1 = system_instruction::transfer(&key1, &key0, 1);
let message = SanitizedMessage::try_from(Message::new(&[ix0, ix1], Some(&key0))).unwrap();
// assert when lamports_per_signature is less than BASE_LAMPORTS, turnning on/off
// congestion_multiplier has no effect on fee.
for remove_congestion_multiplier in [true, false] {
assert_eq!(
Bank::calculate_fee(
&message,
cheap_lamports_per_signature,
&fee_structure,
true,
false,
remove_congestion_multiplier,
true,
true,
false,
),
signature_fee * signature_count
);
}
// assert when lamports_per_signature is more than BASE_LAMPORTS, turnning on/off
// congestion_multiplier will change calculated fee.
for remove_congestion_multiplier in [true, false] {
let denominator: u64 = if remove_congestion_multiplier {
1
} else {
lamports_scale
};
assert_eq!(
Bank::calculate_fee(
&message,
expensive_lamports_per_signature,
&fee_structure,
true,
false,
remove_congestion_multiplier,
true,
true,
false,
),
signature_fee * signature_count / denominator
);
}
}
#[test]
fn test_calculate_fee_with_request_heap_frame_flag() {
let key0 = Pubkey::new_unique();
let key1 = Pubkey::new_unique();
let lamports_per_signature: u64 = 5_000;
let signature_fee: u64 = 10;
let request_cu: u64 = 1;
let lamports_per_cu: u64 = 5;
let fee_structure = FeeStructure {
lamports_per_signature: signature_fee,
..FeeStructure::default()
};
let message = SanitizedMessage::try_from(Message::new(
&[
system_instruction::transfer(&key0, &key1, 1),
ComputeBudgetInstruction::set_compute_unit_limit(request_cu as u32),
ComputeBudgetInstruction::request_heap_frame(40 * 1024),
ComputeBudgetInstruction::set_compute_unit_price(lamports_per_cu * 1_000_000),
],
Some(&key0),
))
.unwrap();
// assert when enable_request_heap_frame_ix is enabled, prioritization fee will be counted
// into transaction fee
let mut enable_request_heap_frame_ix = true;
assert_eq!(
Bank::calculate_fee(
&message,
lamports_per_signature,
&fee_structure,
true,
false,
true,
enable_request_heap_frame_ix,
true,
false,
),
signature_fee + request_cu * lamports_per_cu
);
// assert when enable_request_heap_frame_ix is disabled (an v1.13 behavior), prioritization fee will not be counted
// into transaction fee
enable_request_heap_frame_ix = false;
assert_eq!(
Bank::calculate_fee(
&message,
lamports_per_signature,
&fee_structure,
true,
false,
true,
enable_request_heap_frame_ix,
true,
false,
),
signature_fee
);
}
#[test]
fn test_runtime_feature_enable_with_program_cache() {
solana_logger::setup();
// Bank Setup
let (mut genesis_config, mint_keypair) = create_genesis_config(1_000_000 * LAMPORTS_PER_SOL);
genesis_config
.accounts
.remove(&feature_set::reject_callx_r10::id());
let mut root_bank = Bank::new_for_tests(&genesis_config);
// Test a basic transfer
let amount = genesis_config.rent.minimum_balance(0);
let pubkey = solana_sdk::pubkey::new_rand();
root_bank.transfer(amount, &mint_keypair, &pubkey).unwrap();
assert_eq!(root_bank.get_balance(&pubkey), amount);
// Program Setup
let program_keypair = Keypair::new();
let program_data =
include_bytes!("../../../programs/bpf_loader/test_elfs/out/callx-r10-sbfv1.so");
let program_account = AccountSharedData::from(Account {
lamports: Rent::default().minimum_balance(program_data.len()).min(1),
data: program_data.to_vec(),
owner: bpf_loader::id(),
executable: true,
rent_epoch: 0,
});
root_bank.store_account(&program_keypair.pubkey(), &program_account);
// Compose instruction using the desired program
let instruction1 = Instruction::new_with_bytes(program_keypair.pubkey(), &[], Vec::new());
let message1 = Message::new(&[instruction1], Some(&mint_keypair.pubkey()));
let binding1 = mint_keypair.insecure_clone();
let signers1 = vec![&binding1];
let transaction1 = Transaction::new(&signers1, message1, root_bank.last_blockhash());
// Advance the bank so the next transaction can be submitted.
goto_end_of_slot(&mut root_bank);
let mut bank = new_from_parent(&Arc::new(root_bank));
// Compose second instruction using the same program with a different block hash
let instruction2 = Instruction::new_with_bytes(program_keypair.pubkey(), &[], Vec::new());
let message2 = Message::new(&[instruction2], Some(&mint_keypair.pubkey()));
let binding2 = mint_keypair.insecure_clone();
let signers2 = vec![&binding2];
let transaction2 = Transaction::new(&signers2, message2, bank.last_blockhash());
// Execute before feature is enabled to get program into the cache.
let result_without_feature_enabled = bank.process_transaction(&transaction1);
// Should fail when executing here
assert_eq!(
result_without_feature_enabled,
Err(TransactionError::InstructionError(
0,
InstructionError::ProgramFailedToComplete
))
);
// Activate feature
bank.activate_feature(&reject_callx_r10::id());
// Execute after feature is enabled
let result_with_feature_enabled = bank.process_transaction(&transaction2);
// Feature should have been activated thus causing the TX to fail at
// verification. It should fail here with new Executor Cache because feature
// activations should force the program to recompile with the new feature,
// and in this case the feature should cause the TX to fail at verification.
// Note: `ProgramFailedToComplete` error appearing again means the account
// was not recompiled by the cache upon feature activation and thus fails in
// the same way.
match &result_with_feature_enabled {
Err(x) => {
if *x
== TransactionError::InstructionError(0, InstructionError::ProgramFailedToComplete)
{
println!("ERROR: Program was not recompiled after runtime feature was enabled.");
}
}
Ok(_) => println!("ERROR: Program should fail during execution."),
}
// assert_eq!(
// result_with_feature_enabled,
// Err(TransactionError::InstructionError(0, InstructionError::InvalidAccountData))
// );
}
#[test]
fn test_bank_verify_accounts_hash_with_base() {
let GenesisConfigInfo {
mut genesis_config,
mint_keypair: mint,
..
} = genesis_utils::create_genesis_config_with_leader(
1_000_000 * LAMPORTS_PER_SOL,
&Pubkey::new_unique(),
100 * LAMPORTS_PER_SOL,
);
genesis_config.rent = Rent::default();
genesis_config.ticks_per_slot = 3;
let do_transfers = |bank: &Bank| {
let key1 = Keypair::new(); // lamports from mint
let key2 = Keypair::new(); // will end with ZERO lamports
let key3 = Keypair::new(); // lamports from key2
let amount = 123_456_789;
let fee = {
let blockhash = bank.last_blockhash();
let transaction = SanitizedTransaction::from_transaction_for_tests(
system_transaction::transfer(&key2, &key3.pubkey(), amount, blockhash),
);
bank.get_fee_for_message(transaction.message()).unwrap()
};
bank.transfer(amount + fee, &mint, &key1.pubkey()).unwrap();
bank.transfer(amount + fee, &mint, &key2.pubkey()).unwrap();
bank.transfer(amount + fee, &key2, &key3.pubkey()).unwrap();
assert_eq!(bank.get_balance(&key2.pubkey()), 0);
bank.fill_bank_with_ticks_for_tests();
};
let mut bank = Arc::new(Bank::new_for_tests(&genesis_config));
// make some banks, do some transactions, ensure there's some zero-lamport accounts
for _ in 0..2 {
bank = Arc::new(Bank::new_from_parent(
&bank,
&Pubkey::new_unique(),
bank.slot() + 1,
));
do_transfers(&bank);
}
// update the base accounts hash
bank.squash();
bank.force_flush_accounts_cache();
bank.update_accounts_hash(CalcAccountsHashDataSource::Storages, false, false);
let base_slot = bank.slot();
let base_capitalization = bank.capitalization();
// make more banks, do more transactions, ensure there's more zero-lamport accounts
for _ in 0..2 {
bank = Arc::new(Bank::new_from_parent(
&bank,
&Pubkey::new_unique(),
bank.slot() + 1,
));
do_transfers(&bank);
}
// update the incremental accounts hash
bank.squash();
bank.force_flush_accounts_cache();
bank.update_incremental_accounts_hash(base_slot);
// ensure the accounts hash verifies
assert!(bank.verify_accounts_hash(
Some((base_slot, base_capitalization)),
VerifyAccountsHashConfig {
test_hash_calculation: false,
..VerifyAccountsHashConfig::default_for_test()
},
));
}
#[allow(clippy::field_reassign_with_default)]
#[test]
fn test_calculate_loaded_accounts_data_size_cost() {
let mut compute_budget = ComputeBudget::default();
// accounts data size are priced in block of 32K, ...
// ... requesting less than 32K should still be charged as one block
compute_budget.loaded_accounts_data_size_limit = 31_usize * 1024;
assert_eq!(
compute_budget.heap_cost,
Bank::calculate_loaded_accounts_data_size_cost(&compute_budget)
);
// ... requesting exact 32K should be charged as one block
compute_budget.loaded_accounts_data_size_limit = 32_usize * 1024;
assert_eq!(
compute_budget.heap_cost,
Bank::calculate_loaded_accounts_data_size_cost(&compute_budget)
);
// ... requesting slightly above 32K should be charged as 2 block
compute_budget.loaded_accounts_data_size_limit = 33_usize * 1024;
assert_eq!(
compute_budget.heap_cost * 2,
Bank::calculate_loaded_accounts_data_size_cost(&compute_budget)
);
// ... requesting exact 64K should be charged as 2 block
compute_budget.loaded_accounts_data_size_limit = 64_usize * 1024;
assert_eq!(
compute_budget.heap_cost * 2,
Bank::calculate_loaded_accounts_data_size_cost(&compute_budget)
);
}
#[test]
fn test_squash_timing_add_assign() {
let mut t0 = SquashTiming::default();
let t1 = SquashTiming {
squash_accounts_ms: 1,
squash_accounts_cache_ms: 2,
squash_accounts_index_ms: 3,
squash_accounts_store_ms: 4,
squash_cache_ms: 5,
};
let expected = SquashTiming {
squash_accounts_ms: 2,
squash_accounts_cache_ms: 2 * 2,
squash_accounts_index_ms: 3 * 2,
squash_accounts_store_ms: 4 * 2,
squash_cache_ms: 5 * 2,
};
t0 += t1;
t0 += t1;
assert!(t0 == expected);
}
#[test]
fn test_system_instruction_allocate() {
let (genesis_config, mint_keypair) = create_genesis_config(sol_to_lamports(1.0));
let bank = Bank::new_for_tests(&genesis_config);
let bank_client = BankClient::new(bank);
let data_len = 2;
let amount = genesis_config.rent.minimum_balance(data_len);
let alice_keypair = Keypair::new();
let alice_pubkey = alice_keypair.pubkey();
let seed = "seed";
let owner = Pubkey::new_unique();
let alice_with_seed = Pubkey::create_with_seed(&alice_pubkey, seed, &owner).unwrap();
bank_client
.transfer_and_confirm(amount, &mint_keypair, &alice_pubkey)
.unwrap();
let allocate_with_seed = Message::new(
&[system_instruction::allocate_with_seed(
&alice_with_seed,
&alice_pubkey,
seed,
data_len as u64,
&owner,
)],
Some(&alice_pubkey),
);
assert!(bank_client
.send_and_confirm_message(&[&alice_keypair], allocate_with_seed)
.is_ok());
let allocate = system_instruction::allocate(&alice_pubkey, data_len as u64);
assert!(bank_client
.send_and_confirm_instruction(&alice_keypair, allocate)
.is_ok());
}
fn with_create_zero_lamport<F>(callback: F)
where
F: Fn(&Bank),
{
solana_logger::setup();
let alice_keypair = Keypair::new();
let bob_keypair = Keypair::new();
let alice_pubkey = alice_keypair.pubkey();
let bob_pubkey = bob_keypair.pubkey();
let program = Pubkey::new_unique();
let collector = Pubkey::new_unique();
let mint_lamports = sol_to_lamports(1.0);
let len1 = 123;
let len2 = 456;
// create initial bank and fund the alice account
let (genesis_config, mint_keypair) = create_genesis_config(mint_lamports);
let bank = Arc::new(Bank::new_for_tests(&genesis_config));
let bank_client = BankClient::new_shared(&bank);
bank_client
.transfer_and_confirm(mint_lamports, &mint_keypair, &alice_pubkey)
.unwrap();
// create zero-lamports account to be cleaned
let account = AccountSharedData::new(0, len1, &program);
let bank = Arc::new(Bank::new_from_parent(&bank, &collector, bank.slot() + 1));
bank.store_account(&bob_pubkey, &account);
// transfer some to bogus pubkey just to make previous bank (=slot) really cleanable
let bank = Arc::new(Bank::new_from_parent(&bank, &collector, bank.slot() + 1));
let bank_client = BankClient::new_shared(&bank);
bank_client
.transfer_and_confirm(
genesis_config.rent.minimum_balance(0),
&alice_keypair,
&Pubkey::new_unique(),
)
.unwrap();
// super fun time; callback chooses to .clean_accounts(None) or not
let bank = Arc::new(Bank::new_from_parent(&bank, &collector, bank.slot() + 1));
callback(&bank);
// create a normal account at the same pubkey as the zero-lamports account
let lamports = genesis_config.rent.minimum_balance(len2);
let bank = Arc::new(Bank::new_from_parent(&bank, &collector, bank.slot() + 1));
let bank_client = BankClient::new_shared(&bank);
let ix = system_instruction::create_account(
&alice_pubkey,
&bob_pubkey,
lamports,
len2 as u64,
&program,
);
let message = Message::new(&[ix], Some(&alice_pubkey));
let r = bank_client.send_and_confirm_message(&[&alice_keypair, &bob_keypair], message);
assert!(r.is_ok());
}
#[test]
fn test_create_zero_lamport_with_clean() {
with_create_zero_lamport(|bank| {
bank.freeze();
bank.squash();
bank.force_flush_accounts_cache();
// do clean and assert that it actually did its job
assert_eq!(4, bank.get_snapshot_storages(None).len());
bank.clean_accounts(None);
assert_eq!(3, bank.get_snapshot_storages(None).len());
});
}
#[test]
fn test_create_zero_lamport_without_clean() {
with_create_zero_lamport(|_| {
// just do nothing; this should behave identically with test_create_zero_lamport_with_clean
});
}
#[test]
fn test_system_instruction_assign_with_seed() {
let (genesis_config, mint_keypair) = create_genesis_config(sol_to_lamports(1.0));
let bank = Bank::new_for_tests(&genesis_config);
let bank_client = BankClient::new(bank);
let alice_keypair = Keypair::new();
let alice_pubkey = alice_keypair.pubkey();
let seed = "seed";
let owner = Pubkey::new_unique();
let alice_with_seed = Pubkey::create_with_seed(&alice_pubkey, seed, &owner).unwrap();
bank_client
.transfer_and_confirm(
genesis_config.rent.minimum_balance(0),
&mint_keypair,
&alice_pubkey,
)
.unwrap();
let assign_with_seed = Message::new(
&[system_instruction::assign_with_seed(
&alice_with_seed,
&alice_pubkey,
seed,
&owner,
)],
Some(&alice_pubkey),
);
assert!(bank_client
.send_and_confirm_message(&[&alice_keypair], assign_with_seed)
.is_ok());
}
#[test]
fn test_system_instruction_unsigned_transaction() {
let (genesis_config, alice_keypair) = create_genesis_config(sol_to_lamports(1.0));
let alice_pubkey = alice_keypair.pubkey();
let mallory_keypair = Keypair::new();
let mallory_pubkey = mallory_keypair.pubkey();
let amount = genesis_config.rent.minimum_balance(0);
// Fund to account to bypass AccountNotFound error
let bank = Bank::new_for_tests(&genesis_config);
let bank_client = BankClient::new(bank);
bank_client
.transfer_and_confirm(amount, &alice_keypair, &mallory_pubkey)
.unwrap();
// Erroneously sign transaction with recipient account key
// No signature case is tested by bank `test_zero_signatures()`
let account_metas = vec![
AccountMeta::new(alice_pubkey, false),
AccountMeta::new(mallory_pubkey, true),
];
let malicious_instruction = Instruction::new_with_bincode(
system_program::id(),
&system_instruction::SystemInstruction::Transfer { lamports: amount },
account_metas,
);
assert_eq!(
bank_client
.send_and_confirm_instruction(&mallory_keypair, malicious_instruction)
.unwrap_err()
.unwrap(),
TransactionError::InstructionError(0, InstructionError::MissingRequiredSignature)
);
assert_eq!(
bank_client.get_balance(&alice_pubkey).unwrap(),
sol_to_lamports(1.0) - amount
);
assert_eq!(bank_client.get_balance(&mallory_pubkey).unwrap(), amount);
}
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