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openethereum/ethcore/src/client/client.rs

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// Copyright 2015-2019 Parity Technologies (UK) Ltd.
// This file is part of Parity Ethereum.
// Parity Ethereum is free software: you can redistribute it and/or modify
// it under the terms of the GNU General Public License as published by
// the Free Software Foundation, either version 3 of the License, or
// (at your option) any later version.
// Parity Ethereum is distributed in the hope that it will be useful,
// but WITHOUT ANY WARRANTY; without even the implied warranty of
// MERCHANTABILITY or FITNESS FOR A PARTICULAR PURPOSE. See the
// GNU General Public License for more details.
// You should have received a copy of the GNU General Public License
// along with Parity Ethereum. If not, see <http://www.gnu.org/licenses/>.
use std::cmp;
use std::collections::{HashSet, BTreeMap, VecDeque};
use std::str::FromStr;
use std::sync::atomic::{AtomicUsize, AtomicBool, Ordering as AtomicOrdering};
use std::sync::{Arc, Weak};
use std::time::{Instant, Duration};
use blockchain::{BlockReceipts, BlockChain, BlockChainDB, BlockProvider, TreeRoute, ImportRoute, TransactionAddress, ExtrasInsert, BlockNumberKey};
use bytes::Bytes;
use call_contract::{CallContract, RegistryInfo};
use ethcore_miner::pool::VerifiedTransaction;
use ethereum_types::{H256, H264, Address, U256};
use evm::Schedule;
use hash::keccak;
use io::IoChannel;
use itertools::Itertools;
use journaldb;
use kvdb::{DBValue, KeyValueDB, DBTransaction};
use parking_lot::{Mutex, RwLock};
use rand::OsRng;
use types::transaction::{self, LocalizedTransaction, UnverifiedTransaction, SignedTransaction, Action};
use trie::{TrieSpec, TrieFactory, Trie};
use types::ancestry_action::AncestryAction;
use types::encoded;
use types::filter::Filter;
use types::log_entry::LocalizedLogEntry;
use types::receipt::{Receipt, LocalizedReceipt};
use types::{BlockNumber, header::{Header, ExtendedHeader}};
use vm::{EnvInfo, LastHashes};
use block::{LockedBlock, Drain, ClosedBlock, OpenBlock, enact_verified, SealedBlock};
use client::ancient_import::AncientVerifier;
use client::{
Nonce, Balance, ChainInfo, BlockInfo, TransactionInfo,
ReopenBlock, PrepareOpenBlock, ScheduleInfo, ImportSealedBlock,
BroadcastProposalBlock, ImportBlock, StateOrBlock, StateInfo, StateClient, Call,
AccountData, BlockChain as BlockChainTrait, BlockProducer, SealedBlockImporter,
ClientIoMessage, BlockChainReset
};
use client::{
BlockId, TransactionId, UncleId, TraceId, ClientConfig, BlockChainClient,
TraceFilter, CallAnalytics, Mode,
ChainNotify, NewBlocks, ChainRoute, PruningInfo, ProvingBlockChainClient, EngineInfo, ChainMessageType,
IoClient, BadBlocks,
};
use client::bad_blocks;
use engines::{MAX_UNCLE_AGE, EthEngine, EpochTransition, ForkChoice, EngineError};
use engines::epoch::PendingTransition;
use error::{
ImportErrorKind, ExecutionError, CallError, BlockError,
QueueError, QueueErrorKind, Error as EthcoreError, EthcoreResult, ErrorKind as EthcoreErrorKind
};
use executive::{Executive, Executed, TransactOptions, contract_address};
use factory::{Factories, VmFactory};
use miner::{Miner, MinerService};
use snapshot::{self, io as snapshot_io, SnapshotClient};
use spec::Spec;
use state::{self, State};
use state_db::StateDB;
use trace::{self, TraceDB, ImportRequest as TraceImportRequest, LocalizedTrace, Database as TraceDatabase};
use transaction_ext::Transaction;
use verification::queue::kind::BlockLike;
use verification::queue::kind::blocks::Unverified;
use verification::{PreverifiedBlock, Verifier, BlockQueue};
use verification;
use ansi_term::Colour;
// re-export
pub use types::blockchain_info::BlockChainInfo;
pub use types::block_status::BlockStatus;
pub use blockchain::CacheSize as BlockChainCacheSize;
pub use verification::QueueInfo as BlockQueueInfo;
use db::{Writable, Readable, keys::BlockDetails};
use_contract!(registry, "res/contracts/registrar.json");
const MAX_ANCIENT_BLOCKS_QUEUE_SIZE: usize = 4096;
// Max number of blocks imported at once.
const MAX_ANCIENT_BLOCKS_TO_IMPORT: usize = 4;
const MAX_QUEUE_SIZE_TO_SLEEP_ON: usize = 2;
const MIN_HISTORY_SIZE: u64 = 8;
/// Report on the status of a client.
#[derive(Default, Clone, Debug, Eq, PartialEq)]
pub struct ClientReport {
/// How many blocks have been imported so far.
pub blocks_imported: usize,
/// How many transactions have been applied so far.
pub transactions_applied: usize,
/// How much gas has been processed so far.
pub gas_processed: U256,
/// Memory used by state DB
pub state_db_mem: usize,
}
impl ClientReport {
/// Alter internal reporting to reflect the additional `block` has been processed.
pub fn accrue_block(&mut self, header: &Header, transactions: usize) {
self.blocks_imported += 1;
self.transactions_applied += transactions;
self.gas_processed = self.gas_processed + *header.gas_used();
}
}
impl<'a> ::std::ops::Sub<&'a ClientReport> for ClientReport {
type Output = Self;
fn sub(mut self, other: &'a ClientReport) -> Self {
let higher_mem = ::std::cmp::max(self.state_db_mem, other.state_db_mem);
let lower_mem = ::std::cmp::min(self.state_db_mem, other.state_db_mem);
self.blocks_imported -= other.blocks_imported;
self.transactions_applied -= other.transactions_applied;
self.gas_processed = self.gas_processed - other.gas_processed;
self.state_db_mem = higher_mem - lower_mem;
self
}
}
struct SleepState {
last_activity: Option<Instant>,
last_autosleep: Option<Instant>,
}
impl SleepState {
fn new(awake: bool) -> Self {
SleepState {
last_activity: match awake { false => None, true => Some(Instant::now()) },
last_autosleep: match awake { false => Some(Instant::now()), true => None },
}
}
}
struct Importer {
/// Lock used during block import
pub import_lock: Mutex<()>, // FIXME Maybe wrap the whole `Importer` instead?
/// Used to verify blocks
pub verifier: Box<Verifier<Client>>,
/// Queue containing pending blocks
pub block_queue: BlockQueue,
/// Handles block sealing
pub miner: Arc<Miner>,
/// Ancient block verifier: import an ancient sequence of blocks in order from a starting epoch
pub ancient_verifier: AncientVerifier,
/// Ethereum engine to be used during import
pub engine: Arc<EthEngine>,
/// A lru cache of recently detected bad blocks
pub bad_blocks: bad_blocks::BadBlocks,
}
/// Blockchain database client backed by a persistent database. Owns and manages a blockchain and a block queue.
/// Call `import_block()` to import a block asynchronously; `flush_queue()` flushes the queue.
pub struct Client {
/// Flag used to disable the client forever. Not to be confused with `liveness`.
///
/// For example, auto-updater will disable client forever if there is a
/// hard fork registered on-chain that we don't have capability for.
/// When hard fork block rolls around, the client (if `update` is false)
/// knows it can't proceed further.
enabled: AtomicBool,
/// Operating mode for the client
mode: Mutex<Mode>,
chain: RwLock<Arc<BlockChain>>,
tracedb: RwLock<TraceDB<BlockChain>>,
engine: Arc<EthEngine>,
/// Client configuration
config: ClientConfig,
/// Database pruning strategy to use for StateDB
pruning: journaldb::Algorithm,
/// Client uses this to store blocks, traces, etc.
db: RwLock<Arc<BlockChainDB>>,
state_db: RwLock<StateDB>,
/// Report on the status of client
report: RwLock<ClientReport>,
sleep_state: Mutex<SleepState>,
/// Flag changed by `sleep` and `wake_up` methods. Not to be confused with `enabled`.
liveness: AtomicBool,
io_channel: RwLock<IoChannel<ClientIoMessage>>,
/// List of actors to be notified on certain chain events
notify: RwLock<Vec<Weak<ChainNotify>>>,
/// Queued transactions from IO
queue_transactions: IoChannelQueue,
/// Ancient blocks import queue
queue_ancient_blocks: IoChannelQueue,
/// Queued ancient blocks, make sure they are imported in order.
queued_ancient_blocks: Arc<RwLock<(
HashSet<H256>,
VecDeque<(Unverified, Bytes)>
)>>,
ancient_blocks_import_lock: Arc<Mutex<()>>,
/// Consensus messages import queue
queue_consensus_message: IoChannelQueue,
last_hashes: RwLock<VecDeque<H256>>,
factories: Factories,
/// Number of eras kept in a journal before they are pruned
history: u64,
/// An action to be done if a mode/spec_name change happens
on_user_defaults_change: Mutex<Option<Box<FnMut(Option<Mode>) + 'static + Send>>>,
registrar_address: Option<Address>,
/// A closure to call when we want to restart the client
exit_handler: Mutex<Option<Box<Fn(String) + 'static + Send>>>,
importer: Importer,
}
impl Importer {
pub fn new(
config: &ClientConfig,
engine: Arc<EthEngine>,
message_channel: IoChannel<ClientIoMessage>,
miner: Arc<Miner>,
) -> Result<Importer, ::error::Error> {
let block_queue = BlockQueue::new(config.queue.clone(), engine.clone(), message_channel.clone(), config.verifier_type.verifying_seal());
Ok(Importer {
import_lock: Mutex::new(()),
verifier: verification::new(config.verifier_type.clone()),
block_queue,
miner,
ancient_verifier: AncientVerifier::new(engine.clone()),
engine,
bad_blocks: Default::default(),
})
}
/// This is triggered by a message coming from a block queue when the block is ready for insertion
pub fn import_verified_blocks(&self, client: &Client) -> usize {
// Shortcut out if we know we're incapable of syncing the chain.
if !client.enabled.load(AtomicOrdering::Relaxed) {
return 0;
}
let max_blocks_to_import = client.config.max_round_blocks_to_import;
let (imported_blocks, import_results, invalid_blocks, imported, proposed_blocks, duration, has_more_blocks_to_import) = {
let mut imported_blocks = Vec::with_capacity(max_blocks_to_import);
let mut invalid_blocks = HashSet::new();
let mut proposed_blocks = Vec::with_capacity(max_blocks_to_import);
let mut import_results = Vec::with_capacity(max_blocks_to_import);
let _import_lock = self.import_lock.lock();
let blocks = self.block_queue.drain(max_blocks_to_import);
if blocks.is_empty() {
return 0;
}
trace_time!("import_verified_blocks");
let start = Instant::now();
for block in blocks {
let header = block.header.clone();
let bytes = block.bytes.clone();
let hash = header.hash();
let is_invalid = invalid_blocks.contains(header.parent_hash());
if is_invalid {
invalid_blocks.insert(hash);
continue;
}
match self.check_and_lock_block(&bytes, block, client) {
Ok((closed_block, pending)) => {
imported_blocks.push(hash);
let transactions_len = closed_block.transactions.len();
let route = self.commit_block(closed_block, &header, encoded::Block::new(bytes), pending, client);
import_results.push(route);
client.report.write().accrue_block(&header, transactions_len);
},
Err(err) => {
self.bad_blocks.report(bytes, format!("{:?}", err));
invalid_blocks.insert(hash);
},
}
}
let imported = imported_blocks.len();
let invalid_blocks = invalid_blocks.into_iter().collect::<Vec<H256>>();
if !invalid_blocks.is_empty() {
self.block_queue.mark_as_bad(&invalid_blocks);
}
let has_more_blocks_to_import = !self.block_queue.mark_as_good(&imported_blocks);
(imported_blocks, import_results, invalid_blocks, imported, proposed_blocks, start.elapsed(), has_more_blocks_to_import)
};
{
if !imported_blocks.is_empty() {
let route = ChainRoute::from(import_results.as_ref());
if !has_more_blocks_to_import {
self.miner.chain_new_blocks(client, &imported_blocks, &invalid_blocks, route.enacted(), route.retracted(), false);
}
client.notify(|notify| {
notify.new_blocks(
NewBlocks::new(
imported_blocks.clone(),
invalid_blocks.clone(),
route.clone(),
Vec::new(),
proposed_blocks.clone(),
duration,
has_more_blocks_to_import,
)
);
});
}
}
let db = client.db.read();
db.key_value().flush().expect("DB flush failed.");
imported
}
fn check_and_lock_block(&self, bytes: &[u8], block: PreverifiedBlock, client: &Client) -> EthcoreResult<(LockedBlock, Option<PendingTransition>)> {
let engine = &*self.engine;
let header = block.header.clone();
// Check the block isn't so old we won't be able to enact it.
let best_block_number = client.chain.read().best_block_number();
if client.pruning_info().earliest_state > header.number() {
warn!(target: "client", "Block import failed for #{} ({})\nBlock is ancient (current best block: #{}).", header.number(), header.hash(), best_block_number);
bail!("Block is ancient");
}
// Check if parent is in chain
let parent = match client.block_header_decoded(BlockId::Hash(*header.parent_hash())) {
Some(h) => h,
None => {
warn!(target: "client", "Block import failed for #{} ({}): Parent not found ({}) ", header.number(), header.hash(), header.parent_hash());
bail!("Parent not found");
}
};
let chain = client.chain.read();
// Verify Block Family
let verify_family_result = self.verifier.verify_block_family(
&header,
&parent,
engine,
Some(verification::FullFamilyParams {
block: &block,
block_provider: &**chain,
client
}),
);
if let Err(e) = verify_family_result {
warn!(target: "client", "Stage 3 block verification failed for #{} ({})\nError: {:?}", header.number(), header.hash(), e);
bail!(e);
};
let verify_external_result = self.verifier.verify_block_external(&header, engine);
if let Err(e) = verify_external_result {
warn!(target: "client", "Stage 4 block verification failed for #{} ({})\nError: {:?}", header.number(), header.hash(), e);
bail!(e);
};
// Enact Verified Block
let last_hashes = client.build_last_hashes(header.parent_hash());
let db = client.state_db.read().boxed_clone_canon(header.parent_hash());
let is_epoch_begin = chain.epoch_transition(parent.number(), *header.parent_hash()).is_some();
let enact_result = enact_verified(
block,
engine,
client.tracedb.read().tracing_enabled(),
db,
&parent,
last_hashes,
client.factories.clone(),
is_epoch_begin,
&mut chain.ancestry_with_metadata_iter(*header.parent_hash()),
);
let mut locked_block = match enact_result {
Ok(b) => b,
Err(e) => {
warn!(target: "client", "Block import failed for #{} ({})\nError: {:?}", header.number(), header.hash(), e);
bail!(e);
}
};
// Strip receipts for blocks before validate_receipts_transition,
// if the expected receipts root header does not match.
// (i.e. allow inconsistency in receipts outcome before the transition block)
if header.number() < engine.params().validate_receipts_transition
&& header.receipts_root() != locked_block.header.receipts_root()
{
locked_block.strip_receipts_outcomes();
}
// Final Verification
if let Err(e) = self.verifier.verify_block_final(&header, &locked_block.header) {
warn!(target: "client", "Stage 5 block verification failed for #{} ({})\nError: {:?}", header.number(), header.hash(), e);
bail!(e);
}
let pending = self.check_epoch_end_signal(
&header,
bytes,
&locked_block.receipts,
locked_block.state.db(),
client
)?;
Ok((locked_block, pending))
}
/// Import a block with transaction receipts.
///
/// The block is guaranteed to be the next best blocks in the
/// first block sequence. Does no sealing or transaction validation.
fn import_old_block(&self, unverified: Unverified, receipts_bytes: &[u8], db: &KeyValueDB, chain: &BlockChain) -> EthcoreResult<()> {
let receipts = ::rlp::decode_list(receipts_bytes);
let _import_lock = self.import_lock.lock();
{
trace_time!("import_old_block");
// verify the block, passing the chain for updating the epoch verifier.
let mut rng = OsRng::new()?;
self.ancient_verifier.verify(&mut rng, &unverified.header, &chain)?;
// Commit results
let mut batch = DBTransaction::new();
chain.insert_unordered_block(&mut batch, encoded::Block::new(unverified.bytes), receipts, None, false, true);
// Final commit to the DB
db.write_buffered(batch);
chain.commit();
}
db.flush().expect("DB flush failed.");
Ok(())
}
// NOTE: the header of the block passed here is not necessarily sealed, as
// it is for reconstructing the state transition.
//
// The header passed is from the original block data and is sealed.
// TODO: should return an error if ImportRoute is none, issue #9910
fn commit_block<B>(&self, block: B, header: &Header, block_data: encoded::Block, pending: Option<PendingTransition>, client: &Client) -> ImportRoute where B: Drain {
let hash = &header.hash();
let number = header.number();
let parent = header.parent_hash();
let chain = client.chain.read();
let mut is_finalized = false;
// Commit results
let block = block.drain();
debug_assert_eq!(header.hash(), block_data.header_view().hash());
let mut batch = DBTransaction::new();
let ancestry_actions = self.engine.ancestry_actions(&header, &mut chain.ancestry_with_metadata_iter(*parent));
let receipts = block.receipts;
let traces = block.traces.drain();
let best_hash = chain.best_block_hash();
let new = ExtendedHeader {
header: header.clone(),
is_finalized,
parent_total_difficulty: chain.block_details(&parent).expect("Parent block is in the database; qed").total_difficulty
};
let best = {
let hash = best_hash;
let header = chain.block_header_data(&hash)
.expect("Best block is in the database; qed")
.decode()
.expect("Stored block header is valid RLP; qed");
let details = chain.block_details(&hash)
.expect("Best block is in the database; qed");
ExtendedHeader {
parent_total_difficulty: details.total_difficulty - *header.difficulty(),
is_finalized: details.is_finalized,
header: header,
}
};
let route = chain.tree_route(best_hash, *parent).expect("forks are only kept when it has common ancestors; tree route from best to prospective's parent always exists; qed");
let fork_choice = if route.is_from_route_finalized {
ForkChoice::Old
} else {
self.engine.fork_choice(&new, &best)
};
// CHECK! I *think* this is fine, even if the state_root is equal to another
// already-imported block of the same number.
// TODO: Prove it with a test.
let mut state = block.state.drop().1;
// check epoch end signal, potentially generating a proof on the current
// state.
if let Some(pending) = pending {
chain.insert_pending_transition(&mut batch, header.hash(), pending);
}
state.journal_under(&mut batch, number, hash).expect("DB commit failed");
let finalized: Vec<_> = ancestry_actions.into_iter().map(|ancestry_action| {
let AncestryAction::MarkFinalized(a) = ancestry_action;
if a != header.hash() {
chain.mark_finalized(&mut batch, a).expect("Engine's ancestry action must be known blocks; qed");
} else {
// we're finalizing the current block
is_finalized = true;
}
a
}).collect();
let route = chain.insert_block(&mut batch, block_data, receipts.clone(), ExtrasInsert {
fork_choice: fork_choice,
is_finalized,
});
client.tracedb.read().import(&mut batch, TraceImportRequest {
traces: traces.into(),
block_hash: hash.clone(),
block_number: number,
enacted: route.enacted.clone(),
retracted: route.retracted.len()
});
let is_canon = route.enacted.last().map_or(false, |h| h == hash);
state.sync_cache(&route.enacted, &route.retracted, is_canon);
// Final commit to the DB
client.db.read().key_value().write_buffered(batch);
chain.commit();
self.check_epoch_end(&header, &finalized, &chain, client);
client.update_last_hashes(&parent, hash);
if let Err(e) = client.prune_ancient(state, &chain) {
warn!("Failed to prune ancient state data: {}", e);
}
route
}
// check for epoch end signal and write pending transition if it occurs.
// state for the given block must be available.
fn check_epoch_end_signal(
&self,
header: &Header,
block_bytes: &[u8],
receipts: &[Receipt],
state_db: &StateDB,
client: &Client,
) -> EthcoreResult<Option<PendingTransition>> {
use engines::EpochChange;
let hash = header.hash();
let auxiliary = ::machine::AuxiliaryData {
bytes: Some(block_bytes),
receipts: Some(&receipts),
};
match self.engine.signals_epoch_end(header, auxiliary) {
EpochChange::Yes(proof) => {
use engines::Proof;
let proof = match proof {
Proof::Known(proof) => proof,
Proof::WithState(with_state) => {
let env_info = EnvInfo {
number: header.number(),
author: header.author().clone(),
timestamp: header.timestamp(),
difficulty: header.difficulty().clone(),
last_hashes: client.build_last_hashes(header.parent_hash()),
gas_used: U256::default(),
gas_limit: u64::max_value().into(),
};
let call = move |addr, data| {
let mut state_db = state_db.boxed_clone();
let backend = ::state::backend::Proving::new(state_db.as_hash_db_mut());
let transaction =
client.contract_call_tx(BlockId::Hash(*header.parent_hash()), addr, data);
let mut state = State::from_existing(
backend,
header.state_root().clone(),
self.engine.account_start_nonce(header.number()),
client.factories.clone(),
).expect("state known to be available for just-imported block; qed");
let options = TransactOptions::with_no_tracing().dont_check_nonce();
let machine = self.engine.machine();
let schedule = machine.schedule(env_info.number);
let res = Executive::new(&mut state, &env_info, &machine, &schedule)
.transact(&transaction, options);
let res = match res {
Err(e) => {
trace!(target: "client", "Proved call failed: {}", e);
Err(e.to_string())
}
Ok(res) => Ok((res.output, state.drop().1.extract_proof())),
};
res.map(|(output, proof)| (output, proof.into_iter().map(|x| x.into_vec()).collect()))
};
match with_state.generate_proof(&call) {
Ok(proof) => proof,
Err(e) => {
warn!(target: "client", "Failed to generate transition proof for block {}: {}", hash, e);
warn!(target: "client", "Snapshots produced by this client may be incomplete");
return Err(EngineError::FailedSystemCall(e).into())
}
}
}
};
debug!(target: "client", "Block {} signals epoch end.", hash);
Ok(Some(PendingTransition { proof: proof }))
},
EpochChange::No => Ok(None),
EpochChange::Unsure(_) => {
warn!(target: "client", "Detected invalid engine implementation.");
warn!(target: "client", "Engine claims to require more block data, but everything provided.");
Err(EngineError::InvalidEngine.into())
}
}
}
// check for ending of epoch and write transition if it occurs.
fn check_epoch_end<'a>(&self, header: &'a Header, finalized: &'a [H256], chain: &BlockChain, client: &Client) {
let is_epoch_end = self.engine.is_epoch_end(
header,
finalized,
&(|hash| client.block_header_decoded(BlockId::Hash(hash))),
&(|hash| chain.get_pending_transition(hash)), // TODO: limit to current epoch.
);
if let Some(proof) = is_epoch_end {
debug!(target: "client", "Epoch transition at block {}", header.hash());
let mut batch = DBTransaction::new();
chain.insert_epoch_transition(&mut batch, header.number(), EpochTransition {
block_hash: header.hash(),
block_number: header.number(),
proof: proof,
});
// always write the batch directly since epoch transition proofs are
// fetched from a DB iterator and DB iterators are only available on
// flushed data.
client.db.read().key_value().write(batch).expect("DB flush failed");
}
}
}
impl Client {
/// Create a new client with given parameters.
/// The database is assumed to have been initialized with the correct columns.
pub fn new(
config: ClientConfig,
spec: &Spec,
db: Arc<BlockChainDB>,
miner: Arc<Miner>,
message_channel: IoChannel<ClientIoMessage>,
) -> Result<Arc<Client>, ::error::Error> {
let trie_spec = match config.fat_db {
true => TrieSpec::Fat,
false => TrieSpec::Secure,
};
let trie_factory = TrieFactory::new(trie_spec);
let factories = Factories {
vm: VmFactory::new(config.vm_type.clone(), config.jump_table_size),
trie: trie_factory,
accountdb: Default::default(),
};
let journal_db = journaldb::new(db.key_value().clone(), config.pruning, ::db::COL_STATE);
let mut state_db = StateDB::new(journal_db, config.state_cache_size);
if state_db.journal_db().is_empty() {
// Sets the correct state root.
state_db = spec.ensure_db_good(state_db, &factories)?;
let mut batch = DBTransaction::new();
state_db.journal_under(&mut batch, 0, &spec.genesis_header().hash())?;
db.key_value().write(batch)?;
}
let gb = spec.genesis_block();
let chain = Arc::new(BlockChain::new(config.blockchain.clone(), &gb, db.clone()));
let tracedb = RwLock::new(TraceDB::new(config.tracing.clone(), db.clone(), chain.clone()));
trace!("Cleanup journal: DB Earliest = {:?}, Latest = {:?}", state_db.journal_db().earliest_era(), state_db.journal_db().latest_era());
let history = if config.history < MIN_HISTORY_SIZE {
info!(target: "client", "Ignoring pruning history parameter of {}\
, falling back to minimum of {}",
config.history, MIN_HISTORY_SIZE);
MIN_HISTORY_SIZE
} else {
config.history
};
if !chain.block_header_data(&chain.best_block_hash()).map_or(true, |h| state_db.journal_db().contains(&h.state_root())) {
warn!("State root not found for block #{} ({:x})", chain.best_block_number(), chain.best_block_hash());
}
let engine = spec.engine.clone();
let awake = match config.mode { Mode::Dark(..) | Mode::Off => false, _ => true };
let importer = Importer::new(&config, engine.clone(), message_channel.clone(), miner)?;
let registrar_address = engine.additional_params().get("registrar").and_then(|s| Address::from_str(s).ok());
if let Some(ref addr) = registrar_address {
trace!(target: "client", "Found registrar at {}", addr);
}
let client = Arc::new(Client {
enabled: AtomicBool::new(true),
sleep_state: Mutex::new(SleepState::new(awake)),
liveness: AtomicBool::new(awake),
mode: Mutex::new(config.mode.clone()),
chain: RwLock::new(chain),
tracedb,
engine,
pruning: config.pruning.clone(),
db: RwLock::new(db.clone()),
state_db: RwLock::new(state_db),
report: RwLock::new(Default::default()),
io_channel: RwLock::new(message_channel),
notify: RwLock::new(Vec::new()),
queue_transactions: IoChannelQueue::new(config.transaction_verification_queue_size),
queue_ancient_blocks: IoChannelQueue::new(MAX_ANCIENT_BLOCKS_QUEUE_SIZE),
queued_ancient_blocks: Default::default(),
ancient_blocks_import_lock: Default::default(),
queue_consensus_message: IoChannelQueue::new(usize::max_value()),
last_hashes: RwLock::new(VecDeque::new()),
factories,
history,
on_user_defaults_change: Mutex::new(None),
registrar_address,
exit_handler: Mutex::new(None),
importer,
config,
});
// prune old states.
{
let state_db = client.state_db.read().boxed_clone();
let chain = client.chain.read();
client.prune_ancient(state_db, &chain)?;
}
// ensure genesis epoch proof in the DB.
{
let chain = client.chain.read();
let gh = spec.genesis_header();
if chain.epoch_transition(0, gh.hash()).is_none() {
trace!(target: "client", "No genesis transition found.");
let proof = client.with_proving_caller(
BlockId::Number(0),
|call| client.engine.genesis_epoch_data(&gh, call)
);
let proof = match proof {
Ok(proof) => proof,
Err(e) => {
warn!(target: "client", "Error generating genesis epoch data: {}. Snapshots generated may not be complete.", e);
Vec::new()
}
};
debug!(target: "client", "Obtained genesis transition proof: {:?}", proof);
let mut batch = DBTransaction::new();
chain.insert_epoch_transition(&mut batch, 0, EpochTransition {
block_hash: gh.hash(),
block_number: 0,
proof: proof,
});
client.db.read().key_value().write_buffered(batch);
}
}
// ensure buffered changes are flushed.
client.db.read().key_value().flush()?;
Ok(client)
}
/// Wakes up client if it's a sleep.
pub fn keep_alive(&self) {
let should_wake = match *self.mode.lock() {
Mode::Dark(..) | Mode::Passive(..) => true,
_ => false,
};
if should_wake {
self.wake_up();
(*self.sleep_state.lock()).last_activity = Some(Instant::now());
}
}
/// Adds an actor to be notified on certain events
pub fn add_notify(&self, target: Arc<ChainNotify>) {
self.notify.write().push(Arc::downgrade(&target));
}
/// Set a closure to call when the client wants to be restarted.
///
/// The parameter passed to the callback is the name of the new chain spec to use after
/// the restart.
pub fn set_exit_handler<F>(&self, f: F) where F: Fn(String) + 'static + Send {
*self.exit_handler.lock() = Some(Box::new(f));
}
/// Returns engine reference.
pub fn engine(&self) -> &EthEngine {
&*self.engine
}
fn notify<F>(&self, f: F) where F: Fn(&ChainNotify) {
for np in &*self.notify.read() {
if let Some(n) = np.upgrade() {
f(&*n);
}
}
}
/// Register an action to be done if a mode/spec_name change happens.
pub fn on_user_defaults_change<F>(&self, f: F) where F: 'static + FnMut(Option<Mode>) + Send {
*self.on_user_defaults_change.lock() = Some(Box::new(f));
}
/// Flush the block import queue.
pub fn flush_queue(&self) {
self.importer.block_queue.flush();
while !self.importer.block_queue.is_empty() {
self.import_verified_blocks();
}
}
/// The env info as of the best block.
pub fn latest_env_info(&self) -> EnvInfo {
self.env_info(BlockId::Latest).expect("Best block header always stored; qed")
}
/// The env info as of a given block.
/// returns `None` if the block unknown.
pub fn env_info(&self, id: BlockId) -> Option<EnvInfo> {
self.block_header(id).map(|header| {
EnvInfo {
number: header.number(),
author: header.author(),
timestamp: header.timestamp(),
difficulty: header.difficulty(),
last_hashes: self.build_last_hashes(&header.parent_hash()),
gas_used: U256::default(),
gas_limit: header.gas_limit(),
}
})
}
fn build_last_hashes(&self, parent_hash: &H256) -> Arc<LastHashes> {
{
let hashes = self.last_hashes.read();
if hashes.front().map_or(false, |h| h == parent_hash) {
let mut res = Vec::from(hashes.clone());
res.resize(256, H256::default());
return Arc::new(res);
}
}
let mut last_hashes = LastHashes::new();
last_hashes.resize(256, H256::default());
last_hashes[0] = parent_hash.clone();
let chain = self.chain.read();
for i in 0..255 {
match chain.block_details(&last_hashes[i]) {
Some(details) => {
last_hashes[i + 1] = details.parent.clone();
},
None => break,
}
}
let mut cached_hashes = self.last_hashes.write();
*cached_hashes = VecDeque::from(last_hashes.clone());
Arc::new(last_hashes)
}
/// This is triggered by a message coming from a block queue when the block is ready for insertion
pub fn import_verified_blocks(&self) -> usize {
self.importer.import_verified_blocks(self)
}
// use a state-proving closure for the given block.
fn with_proving_caller<F, T>(&self, id: BlockId, with_call: F) -> T
where F: FnOnce(&::machine::Call) -> T
{
let call = |a, d| {
let tx = self.contract_call_tx(id, a, d);
let (result, items) = self.prove_transaction(tx, id)
.ok_or_else(|| format!("Unable to make call. State unavailable?"))?;
let items = items.into_iter().map(|x| x.to_vec()).collect();
Ok((result, items))
};
with_call(&call)
}
// prune ancient states until below the memory limit or only the minimum amount remain.
fn prune_ancient(&self, mut state_db: StateDB, chain: &BlockChain) -> Result<(), ::error::Error> {
let number = match state_db.journal_db().latest_era() {
Some(n) => n,
None => return Ok(()),
};
// prune all ancient eras until we're below the memory target,
// but have at least the minimum number of states.
loop {
let needs_pruning = state_db.journal_db().is_pruned() &&
state_db.journal_db().journal_size() >= self.config.history_mem;
if !needs_pruning { break }
match state_db.journal_db().earliest_era() {
Some(era) if era + self.history <= number => {
trace!(target: "client", "Pruning state for ancient era {}", era);
match chain.block_hash(era) {
Some(ancient_hash) => {
let mut batch = DBTransaction::new();
state_db.mark_canonical(&mut batch, era, &ancient_hash)?;
self.db.read().key_value().write_buffered(batch);
state_db.journal_db().flush();
}
None =>
debug!(target: "client", "Missing expected hash for block {}", era),
}
}
_ => break, // means that every era is kept, no pruning necessary.
}
}
Ok(())
}
fn update_last_hashes(&self, parent: &H256, hash: &H256) {
let mut hashes = self.last_hashes.write();
if hashes.front().map_or(false, |h| h == parent) {
if hashes.len() > 255 {
hashes.pop_back();
}
hashes.push_front(hash.clone());
}
}
/// Get shared miner reference.
#[cfg(test)]
pub fn miner(&self) -> Arc<Miner> {
self.importer.miner.clone()
}
#[cfg(test)]
pub fn state_db(&self) -> ::parking_lot::RwLockReadGuard<StateDB> {
self.state_db.read()
}
#[cfg(test)]
pub fn chain(&self) -> Arc<BlockChain> {
self.chain.read().clone()
}
/// Replace io channel. Useful for testing.
pub fn set_io_channel(&self, io_channel: IoChannel<ClientIoMessage>) {
*self.io_channel.write() = io_channel;
}
/// Get a copy of the best block's state.
pub fn latest_state(&self) -> State<StateDB> {
let header = self.best_block_header();
State::from_existing(
self.state_db.read().boxed_clone_canon(&header.hash()),
*header.state_root(),
self.engine.account_start_nonce(header.number()),
self.factories.clone()
)
.expect("State root of best block header always valid.")
}
/// Attempt to get a copy of a specific block's final state.
///
/// This will not fail if given BlockId::Latest.
/// Otherwise, this can fail (but may not) if the DB prunes state or the block
/// is unknown.
pub fn state_at(&self, id: BlockId) -> Option<State<StateDB>> {
// fast path for latest state.
match id.clone() {
BlockId::Latest => return Some(self.latest_state()),
_ => {},
}
let block_number = match self.block_number(id) {
Some(num) => num,
None => return None,
};
self.block_header(id).and_then(|header| {
let db = self.state_db.read().boxed_clone();
// early exit for pruned blocks
if db.is_pruned() && self.pruning_info().earliest_state > block_number {
return None;
}
let root = header.state_root();
State::from_existing(db, root, self.engine.account_start_nonce(block_number), self.factories.clone()).ok()
})
}
/// Attempt to get a copy of a specific block's beginning state.
///
/// This will not fail if given BlockId::Latest.
/// Otherwise, this can fail (but may not) if the DB prunes state.
pub fn state_at_beginning(&self, id: BlockId) -> Option<State<StateDB>> {
match self.block_number(id) {
None => None,
Some(0) => self.state_at(id),
Some(n) => self.state_at(BlockId::Number(n - 1)),
}
}
/// Get a copy of the best block's state.
pub fn state(&self) -> Box<StateInfo> {
Box::new(self.latest_state()) as Box<_>
}
/// Get info on the cache.
pub fn blockchain_cache_info(&self) -> BlockChainCacheSize {
self.chain.read().cache_size()
}
/// Get the report.
pub fn report(&self) -> ClientReport {
let mut report = self.report.read().clone();
report.state_db_mem = self.state_db.read().mem_used();
report
}
/// Tick the client.
// TODO: manage by real events.
pub fn tick(&self, prevent_sleep: bool) {
self.check_garbage();
if !prevent_sleep {
self.check_snooze();
}
}
fn check_garbage(&self) {
self.chain.read().collect_garbage();
self.importer.block_queue.collect_garbage();
self.tracedb.read().collect_garbage();
}
fn check_snooze(&self) {
let mode = self.mode.lock().clone();
match mode {
Mode::Dark(timeout) => {
let mut ss = self.sleep_state.lock();
if let Some(t) = ss.last_activity {
if Instant::now() > t + timeout {
self.sleep(false);
ss.last_activity = None;
}
}
}
Mode::Passive(timeout, wakeup_after) => {
let mut ss = self.sleep_state.lock();
let now = Instant::now();
if let Some(t) = ss.last_activity {
if now > t + timeout {
self.sleep(false);
ss.last_activity = None;
ss.last_autosleep = Some(now);
}
}
if let Some(t) = ss.last_autosleep {
if now > t + wakeup_after {
self.wake_up();
ss.last_activity = Some(now);
ss.last_autosleep = None;
}
}
}
_ => {}
}
}
/// Take a snapshot at the given block.
/// If the ID given is "latest", this will default to 1000 blocks behind.
pub fn take_snapshot<W: snapshot_io::SnapshotWriter + Send>(
&self,
writer: W,
at: BlockId,
p: &snapshot::Progress,
) -> Result<(), EthcoreError> {
let db = self.state_db.read().journal_db().boxed_clone();
let best_block_number = self.chain_info().best_block_number;
let block_number = self.block_number(at).ok_or_else(|| snapshot::Error::InvalidStartingBlock(at))?;
if db.is_pruned() && self.pruning_info().earliest_state > block_number {
return Err(snapshot::Error::OldBlockPrunedDB.into());
}
let history = ::std::cmp::min(self.history, 1000);
let start_hash = match at {
BlockId::Latest => {
let start_num = match db.earliest_era() {
Some(era) => ::std::cmp::max(era, best_block_number.saturating_sub(history)),
None => best_block_number.saturating_sub(history),
};
match self.block_hash(BlockId::Number(start_num)) {
Some(h) => h,
None => return Err(snapshot::Error::InvalidStartingBlock(at).into()),
}
}
_ => match self.block_hash(at) {
Some(hash) => hash,
None => return Err(snapshot::Error::InvalidStartingBlock(at).into()),
},
};
let processing_threads = self.config.snapshot.processing_threads;
let chunker = self.engine.snapshot_components().ok_or(snapshot::Error::SnapshotsUnsupported)?;
snapshot::take_snapshot(
chunker,
&self.chain.read(),
start_hash,
db.as_hash_db(),
writer,
p,
processing_threads,
)?;
Ok(())
}
/// Ask the client what the history parameter is.
pub fn pruning_history(&self) -> u64 {
self.history
}
fn block_hash(chain: &BlockChain, id: BlockId) -> Option<H256> {
match id {
BlockId::Hash(hash) => Some(hash),
BlockId::Number(number) => chain.block_hash(number),
BlockId::Earliest => chain.block_hash(0),
BlockId::Latest => Some(chain.best_block_hash()),
}
}
fn transaction_address(&self, id: TransactionId) -> Option<TransactionAddress> {
match id {
TransactionId::Hash(ref hash) => self.chain.read().transaction_address(hash),
TransactionId::Location(id, index) => Self::block_hash(&self.chain.read(), id).map(|hash| TransactionAddress {
block_hash: hash,
index: index,
})
}
}
fn wake_up(&self) {
if !self.liveness.load(AtomicOrdering::Relaxed) {
self.liveness.store(true, AtomicOrdering::Relaxed);
self.notify(|n| n.start());
info!(target: "mode", "wake_up: Waking.");
}
}
fn sleep(&self, force: bool) {
if self.liveness.load(AtomicOrdering::Relaxed) {
// only sleep if the import queue is mostly empty.
if force || (self.queue_info().total_queue_size() <= MAX_QUEUE_SIZE_TO_SLEEP_ON) {
self.liveness.store(false, AtomicOrdering::Relaxed);
self.notify(|n| n.stop());
info!(target: "mode", "sleep: Sleeping.");
} else {
info!(target: "mode", "sleep: Cannot sleep - syncing ongoing.");
// TODO: Consider uncommenting.
//(*self.sleep_state.lock()).last_activity = Some(Instant::now());
}
}
}
// transaction for calling contracts from services like engine.
// from the null sender, with 50M gas.
fn contract_call_tx(&self, block_id: BlockId, address: Address, data: Bytes) -> SignedTransaction {
let from = Address::default();
transaction::Transaction {
nonce: self.nonce(&from, block_id).unwrap_or_else(|| self.engine.account_start_nonce(0)),
action: Action::Call(address),
gas: U256::from(50_000_000),
gas_price: U256::default(),
value: U256::default(),
data: data,
}.fake_sign(from)
}
fn do_virtual_call(
machine: &::machine::EthereumMachine,
env_info: &EnvInfo,
state: &mut State<StateDB>,
t: &SignedTransaction,
analytics: CallAnalytics,
) -> Result<Executed, CallError> {
fn call<V, T>(
state: &mut State<StateDB>,
env_info: &EnvInfo,
machine: &::machine::EthereumMachine,
state_diff: bool,
transaction: &SignedTransaction,
options: TransactOptions<T, V>,
) -> Result<Executed<T::Output, V::Output>, CallError> where
T: trace::Tracer,
V: trace::VMTracer,
{
let options = options
.dont_check_nonce()
.save_output_from_contract();
let original_state = if state_diff { Some(state.clone()) } else { None };
let schedule = machine.schedule(env_info.number);
let mut ret = Executive::new(state, env_info, &machine, &schedule).transact_virtual(transaction, options)?;
if let Some(original) = original_state {
ret.state_diff = Some(state.diff_from(original).map_err(ExecutionError::from)?);
}
Ok(ret)
}
let state_diff = analytics.state_diffing;
match (analytics.transaction_tracing, analytics.vm_tracing) {
(true, true) => call(state, env_info, machine, state_diff, t, TransactOptions::with_tracing_and_vm_tracing()),
(true, false) => call(state, env_info, machine, state_diff, t, TransactOptions::with_tracing()),
(false, true) => call(state, env_info, machine, state_diff, t, TransactOptions::with_vm_tracing()),
(false, false) => call(state, env_info, machine, state_diff, t, TransactOptions::with_no_tracing()),
}
}
fn block_number_ref(&self, id: &BlockId) -> Option<BlockNumber> {
match *id {
BlockId::Number(number) => Some(number),
BlockId::Hash(ref hash) => self.chain.read().block_number(hash),
BlockId::Earliest => Some(0),
BlockId::Latest => Some(self.chain.read().best_block_number()),
}
}
/// Retrieve a decoded header given `BlockId`
///
/// This method optimizes access patterns for latest block header
/// to avoid excessive RLP encoding, decoding and hashing.
fn block_header_decoded(&self, id: BlockId) -> Option<Header> {
match id {
BlockId::Latest
=> Some(self.chain.read().best_block_header()),
BlockId::Hash(ref hash) if hash == &self.chain.read().best_block_hash()
=> Some(self.chain.read().best_block_header()),
BlockId::Number(number) if number == self.chain.read().best_block_number()
=> Some(self.chain.read().best_block_header()),
_ => self.block_header(id).and_then(|h| h.decode().ok())
}
}
}
impl snapshot::DatabaseRestore for Client {
/// Restart the client with a new backend
fn restore_db(&self, new_db: &str) -> Result<(), EthcoreError> {
trace!(target: "snapshot", "Replacing client database with {:?}", new_db);
let _import_lock = self.importer.import_lock.lock();
let mut state_db = self.state_db.write();
let mut chain = self.chain.write();
let mut tracedb = self.tracedb.write();
self.importer.miner.clear();
let db = self.db.write();
db.restore(new_db)?;
let cache_size = state_db.cache_size();
*state_db = StateDB::new(journaldb::new(db.key_value().clone(), self.pruning, ::db::COL_STATE), cache_size);
*chain = Arc::new(BlockChain::new(self.config.blockchain.clone(), &[], db.clone()));
*tracedb = TraceDB::new(self.config.tracing.clone(), db.clone(), chain.clone());
Ok(())
}
}
impl BlockChainReset for Client {
fn reset(&self, num: u32) -> Result<(), String> {
if num as u64 > self.pruning_history() {
return Err("Attempting to reset to block with pruned state".into())
} else if num == 0 {
return Err("invalid number of blocks to reset".into())
}
let mut blocks_to_delete = Vec::with_capacity(num as usize);
let mut best_block_hash = self.chain.read().best_block_hash();
let mut batch = DBTransaction::with_capacity(blocks_to_delete.len());
for _ in 0..num {
let current_header = self.chain.read().block_header_data(&best_block_hash)
.expect("best_block_hash was fetched from db; block_header_data should exist in db; qed");
best_block_hash = current_header.parent_hash();
let (number, hash) = (current_header.number(), current_header.hash());
batch.delete(::db::COL_HEADERS, &hash);
batch.delete(::db::COL_BODIES, &hash);
Writable::delete::<BlockDetails, H264>
(&mut batch, ::db::COL_EXTRA, &hash);
Writable::delete::<H256, BlockNumberKey>
(&mut batch, ::db::COL_EXTRA, &number);
blocks_to_delete.push((number, hash));
}
let hashes = blocks_to_delete.iter().map(|(_, hash)| hash).collect::<Vec<_>>();
info!("Deleting block hashes {}",
Colour::Red
.bold()
.paint(format!("{:#?}", hashes))
);
let mut best_block_details = Readable::read::<BlockDetails, H264>(
&**self.db.read().key_value(),
::db::COL_EXTRA,
&best_block_hash
).expect("block was previously imported; best_block_details should exist; qed");
let (_, last_hash) = blocks_to_delete.last()
.expect("num is > 0; blocks_to_delete can't be empty; qed");
// remove the last block as a child so that it can be re-imported
// ethcore/blockchain/src/blockchain.rs/Blockchain::is_known_child()
best_block_details.children.retain(|h| *h != *last_hash);
batch.write(
::db::COL_EXTRA,
&best_block_hash,
&best_block_details
);
// update the new best block hash
batch.put(::db::COL_EXTRA, b"best", &best_block_hash);
self.db.read()
.key_value()
.write(batch)
.map_err(|err| format!("could not delete blocks; io error occurred: {}", err))?;
info!("New best block hash {}", Colour::Green.bold().paint(format!("{:?}", best_block_hash)));
Ok(())
}
}
impl Nonce for Client {
fn nonce(&self, address: &Address, id: BlockId) -> Option<U256> {
self.state_at(id).and_then(|s| s.nonce(address).ok())
}
}
impl Balance for Client {
fn balance(&self, address: &Address, state: StateOrBlock) -> Option<U256> {
match state {
StateOrBlock::State(s) => s.balance(address).ok(),
StateOrBlock::Block(id) => self.state_at(id).and_then(|s| s.balance(address).ok())
}
}
}
impl AccountData for Client {}
impl ChainInfo for Client {
fn chain_info(&self) -> BlockChainInfo {
let mut chain_info = self.chain.read().chain_info();
chain_info.pending_total_difficulty = chain_info.total_difficulty + self.importer.block_queue.total_difficulty();
chain_info
}
}
impl BlockInfo for Client {
fn block_header(&self, id: BlockId) -> Option<encoded::Header> {
let chain = self.chain.read();
Self::block_hash(&chain, id).and_then(|hash| chain.block_header_data(&hash))
}
fn best_block_header(&self) -> Header {
self.chain.read().best_block_header()
}
fn block(&self, id: BlockId) -> Option<encoded::Block> {
let chain = self.chain.read();
Self::block_hash(&chain, id).and_then(|hash| chain.block(&hash))
}
fn code_hash(&self, address: &Address, id: BlockId) -> Option<H256> {
self.state_at(id).and_then(|s| s.code_hash(address).unwrap_or(None))
}
}
impl TransactionInfo for Client {
fn transaction_block(&self, id: TransactionId) -> Option<H256> {
self.transaction_address(id).map(|addr| addr.block_hash)
}
}
impl BlockChainTrait for Client {}
impl RegistryInfo for Client {
fn registry_address(&self, name: String, block: BlockId) -> Option<Address> {
use ethabi::FunctionOutputDecoder;
let address = self.registrar_address?;
let (data, decoder) = registry::functions::get_address::call(keccak(name.as_bytes()), "A");
let value = decoder.decode(&self.call_contract(block, address, data).ok()?).ok()?;
if value.is_zero() {
None
} else {
Some(value)
}
}
}
impl CallContract for Client {
fn call_contract(&self, block_id: BlockId, address: Address, data: Bytes) -> Result<Bytes, String> {
let state_pruned = || CallError::StatePruned.to_string();
let state = &mut self.state_at(block_id).ok_or_else(&state_pruned)?;
let header = self.block_header_decoded(block_id).ok_or_else(&state_pruned)?;
let transaction = self.contract_call_tx(block_id, address, data);
self.call(&transaction, Default::default(), state, &header)
.map_err(|e| format!("{:?}", e))
.map(|executed| executed.output)
}
}
impl ImportBlock for Client {
fn import_block(&self, unverified: Unverified) -> EthcoreResult<H256> {
if self.chain.read().is_known(&unverified.hash()) {
bail!(EthcoreErrorKind::Import(ImportErrorKind::AlreadyInChain));
}
let status = self.block_status(BlockId::Hash(unverified.parent_hash()));
if status == BlockStatus::Unknown {
bail!(EthcoreErrorKind::Block(BlockError::UnknownParent(unverified.parent_hash())));
}
let raw = if self.importer.block_queue.is_empty() {
Some((
unverified.bytes.clone(),
unverified.header.hash(),
*unverified.header.difficulty(),
))
} else { None };
match self.importer.block_queue.import(unverified) {
Ok(hash) => {
if let Some((raw, hash, difficulty)) = raw {
self.notify(move |n| n.block_pre_import(&raw, &hash, &difficulty));
}
Ok(hash)
},
// we only care about block errors (not import errors)
Err((block, EthcoreError(EthcoreErrorKind::Block(err), _))) => {
self.importer.bad_blocks.report(block.bytes, format!("{:?}", err));
bail!(EthcoreErrorKind::Block(err))
},
Err((_, e)) => Err(e),
}
}
}
impl StateClient for Client {
type State = State<::state_db::StateDB>;
fn latest_state(&self) -> Self::State {
Client::latest_state(self)
}
fn state_at(&self, id: BlockId) -> Option<Self::State> {
Client::state_at(self, id)
}
}
impl Call for Client {
type State = State<::state_db::StateDB>;
fn call(&self, transaction: &SignedTransaction, analytics: CallAnalytics, state: &mut Self::State, header: &Header) -> Result<Executed, CallError> {
let env_info = EnvInfo {
number: header.number(),
author: header.author().clone(),
timestamp: header.timestamp(),
difficulty: header.difficulty().clone(),
last_hashes: self.build_last_hashes(header.parent_hash()),
gas_used: U256::default(),
gas_limit: U256::max_value(),
};
let machine = self.engine.machine();
Self::do_virtual_call(&machine, &env_info, state, transaction, analytics)
}
fn call_many(&self, transactions: &[(SignedTransaction, CallAnalytics)], state: &mut Self::State, header: &Header) -> Result<Vec<Executed>, CallError> {
let mut env_info = EnvInfo {
number: header.number(),
author: header.author().clone(),
timestamp: header.timestamp(),
difficulty: header.difficulty().clone(),
last_hashes: self.build_last_hashes(header.parent_hash()),
gas_used: U256::default(),
gas_limit: U256::max_value(),
};
let mut results = Vec::with_capacity(transactions.len());
let machine = self.engine.machine();
for &(ref t, analytics) in transactions {
let ret = Self::do_virtual_call(machine, &env_info, state, t, analytics)?;
env_info.gas_used = ret.cumulative_gas_used;
results.push(ret);
}
Ok(results)
}
fn estimate_gas(&self, t: &SignedTransaction, state: &Self::State, header: &Header) -> Result<U256, CallError> {
let (mut upper, max_upper, env_info) = {
let init = *header.gas_limit();
let max = init * U256::from(10);
let env_info = EnvInfo {
number: header.number(),
author: header.author().clone(),
timestamp: header.timestamp(),
difficulty: header.difficulty().clone(),
last_hashes: self.build_last_hashes(header.parent_hash()),
gas_used: U256::default(),
gas_limit: max,
};
(init, max, env_info)
};
let sender = t.sender();
let options = || TransactOptions::with_tracing().dont_check_nonce();
let exec = |gas| {
let mut tx = t.as_unsigned().clone();
tx.gas = gas;
let tx = tx.fake_sign(sender);
let mut clone = state.clone();
let machine = self.engine.machine();
let schedule = machine.schedule(env_info.number);
Executive::new(&mut clone, &env_info, &machine, &schedule)
.transact_virtual(&tx, options())
};
let cond = |gas| {
exec(gas)
.ok()
.map_or(false, |r| r.exception.is_none())
};
if !cond(upper) {
upper = max_upper;
match exec(upper) {
Ok(v) => {
if let Some(exception) = v.exception {
return Err(CallError::Exceptional(exception))
}
},
Err(_e) => {
trace!(target: "estimate_gas", "estimate_gas failed with {}", upper);
let err = ExecutionError::Internal(format!("Requires higher than upper limit of {}", upper));
return Err(err.into())
}
}
}
let lower = t.gas_required(&self.engine.schedule(env_info.number)).into();
if cond(lower) {
trace!(target: "estimate_gas", "estimate_gas succeeded with {}", lower);
return Ok(lower)
}
/// Find transition point between `lower` and `upper` where `cond` changes from `false` to `true`.
/// Returns the lowest value between `lower` and `upper` for which `cond` returns true.
/// We assert: `cond(lower) = false`, `cond(upper) = true`
fn binary_chop<F, E>(mut lower: U256, mut upper: U256, mut cond: F) -> Result<U256, E>
where F: FnMut(U256) -> bool
{
while upper - lower > 1.into() {
let mid = (lower + upper) / 2;
trace!(target: "estimate_gas", "{} .. {} .. {}", lower, mid, upper);
let c = cond(mid);
match c {
true => upper = mid,
false => lower = mid,
};
trace!(target: "estimate_gas", "{} => {} .. {}", c, lower, upper);
}
Ok(upper)
}
// binary chop to non-excepting call with gas somewhere between 21000 and block gas limit
trace!(target: "estimate_gas", "estimate_gas chopping {} .. {}", lower, upper);
binary_chop(lower, upper, cond)
}
}
impl EngineInfo for Client {
fn engine(&self) -> &EthEngine {
Client::engine(self)
}
}
impl BadBlocks for Client {
fn bad_blocks(&self) -> Vec<(Unverified, String)> {
self.importer.bad_blocks.bad_blocks()
}
}
impl BlockChainClient for Client {
fn replay(&self, id: TransactionId, analytics: CallAnalytics) -> Result<Executed, CallError> {
let address = self.transaction_address(id).ok_or(CallError::TransactionNotFound)?;
let block = BlockId::Hash(address.block_hash);
const PROOF: &'static str = "The transaction address contains a valid index within block; qed";
Ok(self.replay_block_transactions(block, analytics)?.nth(address.index).expect(PROOF).1)
}
fn replay_block_transactions(&self, block: BlockId, analytics: CallAnalytics) -> Result<Box<Iterator<Item = (H256, Executed)>>, CallError> {
let mut env_info = self.env_info(block).ok_or(CallError::StatePruned)?;
let body = self.block_body(block).ok_or(CallError::StatePruned)?;
let mut state = self.state_at_beginning(block).ok_or(CallError::StatePruned)?;
let txs = body.transactions();
let engine = self.engine.clone();
const PROOF: &'static str = "Transactions fetched from blockchain; blockchain transactions are valid; qed";
const EXECUTE_PROOF: &'static str = "Transaction replayed; qed";
Ok(Box::new(txs.into_iter()
.map(move |t| {
let transaction_hash = t.hash();
let t = SignedTransaction::new(t).expect(PROOF);
let machine = engine.machine();
let x = Self::do_virtual_call(machine, &env_info, &mut state, &t, analytics).expect(EXECUTE_PROOF);
env_info.gas_used = env_info.gas_used + x.gas_used;
(transaction_hash, x)
})))
}
fn mode(&self) -> Mode {
let r = self.mode.lock().clone().into();
trace!(target: "mode", "Asked for mode = {:?}. returning {:?}", &*self.mode.lock(), r);
r
}
fn disable(&self) {
self.set_mode(Mode::Off);
self.enabled.store(false, AtomicOrdering::Relaxed);
self.clear_queue();
}
fn set_mode(&self, new_mode: Mode) {
trace!(target: "mode", "Client::set_mode({:?})", new_mode);
if !self.enabled.load(AtomicOrdering::Relaxed) {
return;
}
{
let mut mode = self.mode.lock();
*mode = new_mode.clone().into();
trace!(target: "mode", "Mode now {:?}", &*mode);
if let Some(ref mut f) = *self.on_user_defaults_change.lock() {
trace!(target: "mode", "Making callback...");
f(Some((&*mode).clone()))
}
}
match new_mode {
Mode::Active => self.wake_up(),
Mode::Off => self.sleep(true),
_ => {(*self.sleep_state.lock()).last_activity = Some(Instant::now()); }
}
}
fn spec_name(&self) -> String {
self.config.spec_name.clone()
}
fn set_spec_name(&self, new_spec_name: String) -> Result<(), ()> {
trace!(target: "mode", "Client::set_spec_name({:?})", new_spec_name);
if !self.enabled.load(AtomicOrdering::Relaxed) {
return Err(());
}
if let Some(ref h) = *self.exit_handler.lock() {
(*h)(new_spec_name);
Ok(())
} else {
warn!("Not hypervised; cannot change chain.");
Err(())
}
}
fn block_number(&self, id: BlockId) -> Option<BlockNumber> {
self.block_number_ref(&id)
}
fn block_body(&self, id: BlockId) -> Option<encoded::Body> {
let chain = self.chain.read();
Self::block_hash(&chain, id).and_then(|hash| chain.block_body(&hash))
}
fn block_status(&self, id: BlockId) -> BlockStatus {
let chain = self.chain.read();
match Self::block_hash(&chain, id) {
Some(ref hash) if chain.is_known(hash) => BlockStatus::InChain,
Some(hash) => self.importer.block_queue.status(&hash).into(),
None => BlockStatus::Unknown
}
}
fn block_total_difficulty(&self, id: BlockId) -> Option<U256> {
let chain = self.chain.read();
Self::block_hash(&chain, id).and_then(|hash| chain.block_details(&hash)).map(|d| d.total_difficulty)
}
fn storage_root(&self, address: &Address, id: BlockId) -> Option<H256> {
self.state_at(id).and_then(|s| s.storage_root(address).ok()).and_then(|x| x)
}
fn block_hash(&self, id: BlockId) -> Option<H256> {
let chain = self.chain.read();
Self::block_hash(&chain, id)
}
fn code(&self, address: &Address, state: StateOrBlock) -> Option<Option<Bytes>> {
let result = match state {
StateOrBlock::State(s) => s.code(address).ok(),
StateOrBlock::Block(id) => self.state_at(id).and_then(|s| s.code(address).ok())
};
// Converting from `Option<Option<Arc<Bytes>>>` to `Option<Option<Bytes>>`
result.map(|c| c.map(|c| (&*c).clone()))
}
fn storage_at(&self, address: &Address, position: &H256, state: StateOrBlock) -> Option<H256> {
match state {
StateOrBlock::State(s) => s.storage_at(address, position).ok(),
StateOrBlock::Block(id) => self.state_at(id).and_then(|s| s.storage_at(address, position).ok())
}
}
fn list_accounts(&self, id: BlockId, after: Option<&Address>, count: u64) -> Option<Vec<Address>> {
if !self.factories.trie.is_fat() {
trace!(target: "fatdb", "list_accounts: Not a fat DB");
return None;
}
let state = match self.state_at(id) {
Some(state) => state,
_ => return None,
};
let (root, db) = state.drop();
let db = &db.as_hash_db();
let trie = match self.factories.trie.readonly(db, &root) {
Ok(trie) => trie,
_ => {
trace!(target: "fatdb", "list_accounts: Couldn't open the DB");
return None;
}
};
let mut iter = match trie.iter() {
Ok(iter) => iter,
_ => return None,
};
if let Some(after) = after {
if let Err(e) = iter.seek(after) {
trace!(target: "fatdb", "list_accounts: Couldn't seek the DB: {:?}", e);
} else {
// Position the iterator after the `after` element
iter.next();
}
}
let accounts = iter.filter_map(|item| {
item.ok().map(|(addr, _)| Address::from_slice(&addr))
}).take(count as usize).collect();
Some(accounts)
}
fn list_storage(&self, id: BlockId, account: &Address, after: Option<&H256>, count: u64) -> Option<Vec<H256>> {
if !self.factories.trie.is_fat() {
trace!(target: "fatdb", "list_storage: Not a fat DB");
return None;
}
let state = match self.state_at(id) {
Some(state) => state,
_ => return None,
};
let root = match state.storage_root(account) {
Ok(Some(root)) => root,
_ => return None,
};
let (_, db) = state.drop();
let account_db = &self.factories.accountdb.readonly(db.as_hash_db(), keccak(account));
let account_db = &account_db.as_hash_db();
let trie = match self.factories.trie.readonly(account_db, &root) {
Ok(trie) => trie,
_ => {
trace!(target: "fatdb", "list_storage: Couldn't open the DB");
return None;
}
};
let mut iter = match trie.iter() {
Ok(iter) => iter,
_ => return None,
};
if let Some(after) = after {
if let Err(e) = iter.seek(after) {
trace!(target: "fatdb", "list_storage: Couldn't seek the DB: {:?}", e);
} else {
// Position the iterator after the `after` element
iter.next();
}
}
let keys = iter.filter_map(|item| {
item.ok().map(|(key, _)| H256::from_slice(&key))
}).take(count as usize).collect();
Some(keys)
}
fn transaction(&self, id: TransactionId) -> Option<LocalizedTransaction> {
self.transaction_address(id).and_then(|address| self.chain.read().transaction(&address))
}
fn uncle(&self, id: UncleId) -> Option<encoded::Header> {
let index = id.position;
self.block_body(id.block).and_then(|body| body.view().uncle_rlp_at(index))
.map(encoded::Header::new)
}
fn transaction_receipt(&self, id: TransactionId) -> Option<LocalizedReceipt> {
// NOTE Don't use block_receipts here for performance reasons
let address = self.transaction_address(id)?;
let hash = address.block_hash;
let chain = self.chain.read();
let number = chain.block_number(&hash)?;
let body = chain.block_body(&hash)?;
let mut receipts = chain.block_receipts(&hash)?.receipts;
receipts.truncate(address.index + 1);
let transaction = body.view().localized_transaction_at(&hash, number, address.index)?;
let receipt = receipts.pop()?;
let gas_used = receipts.last().map_or_else(|| 0.into(), |r| r.gas_used);
let no_of_logs = receipts.into_iter().map(|receipt| receipt.logs.len()).sum::<usize>();
let receipt = transaction_receipt(self.engine().machine(), transaction, receipt, gas_used, no_of_logs);
Some(receipt)
}
fn localized_block_receipts(&self, id: BlockId) -> Option<Vec<LocalizedReceipt>> {
let hash = self.block_hash(id)?;
let chain = self.chain.read();
let receipts = chain.block_receipts(&hash)?;
let number = chain.block_number(&hash)?;
let body = chain.block_body(&hash)?;
let engine = self.engine.clone();
let mut gas_used = 0.into();
let mut no_of_logs = 0;
Some(body
.view()
.localized_transactions(&hash, number)
.into_iter()
.zip(receipts.receipts)
.map(move |(transaction, receipt)| {
let result = transaction_receipt(engine.machine(), transaction, receipt, gas_used, no_of_logs);
gas_used = result.cumulative_gas_used;
no_of_logs += result.logs.len();
result
})
.collect()
)
}
fn tree_route(&self, from: &H256, to: &H256) -> Option<TreeRoute> {
let chain = self.chain.read();
match chain.is_known(from) && chain.is_known(to) {
true => chain.tree_route(from.clone(), to.clone()),
false => None
}
}
fn find_uncles(&self, hash: &H256) -> Option<Vec<H256>> {
self.chain.read().find_uncle_hashes(hash, MAX_UNCLE_AGE)
}
fn state_data(&self, hash: &H256) -> Option<Bytes> {
self.state_db.read().journal_db().state(hash)
}
fn block_receipts(&self, hash: &H256) -> Option<BlockReceipts> {
self.chain.read().block_receipts(hash)
}
fn queue_info(&self) -> BlockQueueInfo {
self.importer.block_queue.queue_info()
}
fn is_queue_empty(&self) -> bool {
self.importer.block_queue.is_empty()
}
fn clear_queue(&self) {
self.importer.block_queue.clear();
}
fn additional_params(&self) -> BTreeMap<String, String> {
self.engine.additional_params().into_iter().collect()
}
fn logs(&self, filter: Filter) -> Result<Vec<LocalizedLogEntry>, BlockId> {
let chain = self.chain.read();
// First, check whether `filter.from_block` and `filter.to_block` is on the canon chain. If so, we can use the
// optimized version.
let is_canon = |id| {
match id {
// If it is referred by number, then it is always on the canon chain.
&BlockId::Earliest | &BlockId::Latest | &BlockId::Number(_) => true,
// If it is referred by hash, we see whether a hash -> number -> hash conversion gives us the same
// result.
&BlockId::Hash(ref hash) => chain.is_canon(hash),
}
};
let blocks = if is_canon(&filter.from_block) && is_canon(&filter.to_block) {
// If we are on the canon chain, use bloom filter to fetch required hashes.
//
// If we are sure the block does not exist (where val > best_block_number), then return error. Note that we
// don't need to care about pending blocks here because RPC query sets pending back to latest (or handled
// pending logs themselves).
let from = match self.block_number_ref(&filter.from_block) {
Some(val) if val <= chain.best_block_number() => val,
_ => return Err(filter.from_block.clone()),
};
let to = match self.block_number_ref(&filter.to_block) {
Some(val) if val <= chain.best_block_number() => val,
_ => return Err(filter.to_block.clone()),
};
// If from is greater than to, then the current bloom filter behavior is to just return empty
// result. There's no point to continue here.
if from > to {
return Err(filter.to_block.clone());
}
chain.blocks_with_bloom(&filter.bloom_possibilities(), from, to)
.into_iter()
.filter_map(|n| chain.block_hash(n))
.collect::<Vec<H256>>()
} else {
// Otherwise, we use a slower version that finds a link between from_block and to_block.
let from_hash = match Self::block_hash(&chain, filter.from_block) {
Some(val) => val,
None => return Err(filter.from_block.clone()),
};
let from_number = match chain.block_number(&from_hash) {
Some(val) => val,
None => return Err(BlockId::Hash(from_hash)),
};
let to_hash = match Self::block_hash(&chain, filter.to_block) {
Some(val) => val,
None => return Err(filter.to_block.clone()),
};
let blooms = filter.bloom_possibilities();
let bloom_match = |header: &encoded::Header| {
blooms.iter().any(|bloom| header.log_bloom().contains_bloom(bloom))
};
let (blocks, last_hash) = {
let mut blocks = Vec::new();
let mut current_hash = to_hash;
loop {
let header = match chain.block_header_data(&current_hash) {
Some(val) => val,
None => return Err(BlockId::Hash(current_hash)),
};
if bloom_match(&header) {
blocks.push(current_hash);
}
// Stop if `from` block is reached.
if header.number() <= from_number {
break;
}
current_hash = header.parent_hash();
}
blocks.reverse();
(blocks, current_hash)
};
// Check if we've actually reached the expected `from` block.
if last_hash != from_hash || blocks.is_empty() {
// In this case, from_hash is the cause (for not matching last_hash).
return Err(BlockId::Hash(from_hash));
}
blocks
};
Ok(self.chain.read().logs(blocks, |entry| filter.matches(entry), filter.limit))
}
fn filter_traces(&self, filter: TraceFilter) -> Option<Vec<LocalizedTrace>> {
if !self.tracedb.read().tracing_enabled() {
return None;
}
let start = self.block_number(filter.range.start)?;
let end = self.block_number(filter.range.end)?;
let db_filter = trace::Filter {
range: start as usize..end as usize,
from_address: filter.from_address.into(),
to_address: filter.to_address.into(),
};
let traces = self.tracedb.read()
.filter(&db_filter)
.into_iter()
.skip(filter.after.unwrap_or(0))
.take(filter.count.unwrap_or(usize::max_value()))
.collect();
Some(traces)
}
fn trace(&self, trace: TraceId) -> Option<LocalizedTrace> {
if !self.tracedb.read().tracing_enabled() {
return None;
}
let trace_address = trace.address;
self.transaction_address(trace.transaction)
.and_then(|tx_address| {
self.block_number(BlockId::Hash(tx_address.block_hash))
.and_then(|number| self.tracedb.read().trace(number, tx_address.index, trace_address))
})
}
fn transaction_traces(&self, transaction: TransactionId) -> Option<Vec<LocalizedTrace>> {
if !self.tracedb.read().tracing_enabled() {
return None;
}
self.transaction_address(transaction)
.and_then(|tx_address| {
self.block_number(BlockId::Hash(tx_address.block_hash))
.and_then(|number| self.tracedb.read().transaction_traces(number, tx_address.index))
})
}
fn block_traces(&self, block: BlockId) -> Option<Vec<LocalizedTrace>> {
if !self.tracedb.read().tracing_enabled() {
return None;
}
self.block_number(block)
.and_then(|number| self.tracedb.read().block_traces(number))
}
fn last_hashes(&self) -> LastHashes {
(*self.build_last_hashes(&self.chain.read().best_block_hash())).clone()
}
fn transactions_to_propagate(&self) -> Vec<Arc<VerifiedTransaction>> {
const PROPAGATE_FOR_BLOCKS: u32 = 4;
const MIN_TX_TO_PROPAGATE: usize = 256;
let block_gas_limit = *self.best_block_header().gas_limit();
let min_tx_gas: U256 = self.latest_schedule().tx_gas.into();
let max_len = if min_tx_gas.is_zero() {
usize::max_value()
} else {
cmp::max(
MIN_TX_TO_PROPAGATE,
cmp::min(
(block_gas_limit / min_tx_gas) * PROPAGATE_FOR_BLOCKS,
// never more than usize
usize::max_value().into()
).as_u64() as usize
)
};
self.importer.miner.ready_transactions(self, max_len, ::miner::PendingOrdering::Priority)
}
fn signing_chain_id(&self) -> Option<u64> {
self.engine.signing_chain_id(&self.latest_env_info())
}
fn block_extra_info(&self, id: BlockId) -> Option<BTreeMap<String, String>> {
self.block_header_decoded(id)
.map(|header| self.engine.extra_info(&header))
}
fn uncle_extra_info(&self, id: UncleId) -> Option<BTreeMap<String, String>> {
self.uncle(id)
.and_then(|h| {
h.decode().map(|dh| {
self.engine.extra_info(&dh)
}).ok()
})
}
fn pruning_info(&self) -> PruningInfo {
PruningInfo {
earliest_chain: self.chain.read().first_block_number().unwrap_or(1),
earliest_state: self.state_db.read().journal_db().earliest_era().unwrap_or(0),
}
}
fn transact_contract(&self, address: Address, data: Bytes) -> Result<(), transaction::Error> {
let authoring_params = self.importer.miner.authoring_params();
let service_transaction_checker = self.importer.miner.service_transaction_checker();
let gas_price = if let Some(checker) = service_transaction_checker {
match checker.check_address(self, authoring_params.author) {
Ok(true) => U256::zero(),
_ => self.importer.miner.sensible_gas_price(),
}
} else {
self.importer.miner.sensible_gas_price()
};
let transaction = transaction::Transaction {
nonce: self.latest_nonce(&authoring_params.author),
action: Action::Call(address),
gas: self.importer.miner.sensible_gas_limit(),
gas_price,
value: U256::zero(),
data: data,
};
let chain_id = self.engine.signing_chain_id(&self.latest_env_info());
let signature = self.engine.sign(transaction.hash(chain_id))
.map_err(|e| transaction::Error::InvalidSignature(e.to_string()))?;
let signed = SignedTransaction::new(transaction.with_signature(signature, chain_id))?;
self.importer.miner.import_own_transaction(self, signed.into())
}
fn registrar_address(&self) -> Option<Address> {
self.registrar_address.clone()
}
}
impl IoClient for Client {
fn queue_transactions(&self, transactions: Vec<Bytes>, peer_id: usize) {
trace_time!("queue_transactions");
let len = transactions.len();
self.queue_transactions.queue(&self.io_channel.read(), len, move |client| {
trace_time!("import_queued_transactions");
let txs: Vec<UnverifiedTransaction> = transactions
.iter()
.filter_map(|bytes| client.engine.decode_transaction(bytes).ok())
.collect();
client.notify(|notify| {
notify.transactions_received(&txs, peer_id);
});
client.importer.miner.import_external_transactions(client, txs);
}).unwrap_or_else(|e| {
debug!(target: "client", "Ignoring {} transactions: {}", len, e);
});
}
fn queue_ancient_block(&self, unverified: Unverified, receipts_bytes: Bytes) -> EthcoreResult<H256> {
trace_time!("queue_ancient_block");
let hash = unverified.hash();
{
// check block order
if self.chain.read().is_known(&hash) {
bail!(EthcoreErrorKind::Import(ImportErrorKind::AlreadyInChain));
}
let parent_hash = unverified.parent_hash();
// NOTE To prevent race condition with import, make sure to check queued blocks first
// (and attempt to acquire lock)
let is_parent_pending = self.queued_ancient_blocks.read().0.contains(&parent_hash);
if !is_parent_pending && !self.chain.read().is_known(&parent_hash) {
bail!(EthcoreErrorKind::Block(BlockError::UnknownParent(parent_hash)));
}
}
// we queue blocks here and trigger an IO message.
{
let mut queued = self.queued_ancient_blocks.write();
queued.0.insert(hash);
queued.1.push_back((unverified, receipts_bytes));
}
let queued = self.queued_ancient_blocks.clone();
let lock = self.ancient_blocks_import_lock.clone();
self.queue_ancient_blocks.queue(&self.io_channel.read(), 1, move |client| {
trace_time!("import_ancient_block");
// Make sure to hold the lock here to prevent importing out of order.
// We use separate lock, cause we don't want to block queueing.
let _lock = lock.lock();
for _i in 0..MAX_ANCIENT_BLOCKS_TO_IMPORT {
let first = queued.write().1.pop_front();
if let Some((unverified, receipts_bytes)) = first {
let hash = unverified.hash();
let result = client.importer.import_old_block(
unverified,
&receipts_bytes,
&**client.db.read().key_value(),
&*client.chain.read(),
);
if let Err(e) = result {
error!(target: "client", "Error importing ancient block: {}", e);
let mut queued = queued.write();
queued.0.clear();
queued.1.clear();
}
// remove from pending
queued.write().0.remove(&hash);
} else {
break;
}
}
})?;
Ok(hash)
}
fn queue_consensus_message(&self, message: Bytes) {
match self.queue_consensus_message.queue(&self.io_channel.read(), 1, move |client| {
if let Err(e) = client.engine().handle_message(&message) {
debug!(target: "poa", "Invalid message received: {}", e);
}
}) {
Ok(_) => (),
Err(e) => {
debug!(target: "poa", "Ignoring the message, error queueing: {}", e);
}
}
}
}
impl ReopenBlock for Client {
fn reopen_block(&self, block: ClosedBlock) -> OpenBlock {
let engine = &*self.engine;
let mut block = block.reopen(engine);
let max_uncles = engine.maximum_uncle_count(block.header.number());
if block.uncles.len() < max_uncles {
let chain = self.chain.read();
let h = chain.best_block_hash();
// Add new uncles
let uncles = chain
.find_uncle_hashes(&h, MAX_UNCLE_AGE)
.unwrap_or_else(Vec::new);
for h in uncles {
if !block.uncles.iter().any(|header| header.hash() == h) {
let uncle = chain.block_header_data(&h).expect("find_uncle_hashes only returns hashes for existing headers; qed");
let uncle = uncle.decode().expect("decoding failure");
block.push_uncle(uncle).expect("pushing up to maximum_uncle_count;
push_uncle is not ok only if more than maximum_uncle_count is pushed;
so all push_uncle are Ok;
qed");
if block.uncles.len() >= max_uncles { break }
}
}
}
block
}
}
impl PrepareOpenBlock for Client {
fn prepare_open_block(&self, author: Address, gas_range_target: (U256, U256), extra_data: Bytes) -> Result<OpenBlock, EthcoreError> {
let engine = &*self.engine;
let chain = self.chain.read();
let best_header = chain.best_block_header();
let h = best_header.hash();
let is_epoch_begin = chain.epoch_transition(best_header.number(), h).is_some();
let mut open_block = OpenBlock::new(
engine,
self.factories.clone(),
self.tracedb.read().tracing_enabled(),
self.state_db.read().boxed_clone_canon(&h),
&best_header,
self.build_last_hashes(&h),
author,
gas_range_target,
extra_data,
is_epoch_begin,
chain.ancestry_with_metadata_iter(best_header.hash()),
)?;
// Add uncles
chain
.find_uncle_headers(&h, MAX_UNCLE_AGE)
.unwrap_or_else(Vec::new)
.into_iter()
.take(engine.maximum_uncle_count(open_block.header.number()))
.foreach(|h| {
open_block.push_uncle(h.decode().expect("decoding failure")).expect("pushing maximum_uncle_count;
open_block was just created;
push_uncle is not ok only if more than maximum_uncle_count is pushed;
so all push_uncle are Ok;
qed");
});
Ok(open_block)
}
}
impl BlockProducer for Client {}
impl ScheduleInfo for Client {
fn latest_schedule(&self) -> Schedule {
self.engine.schedule(self.latest_env_info().number)
}
}
impl ImportSealedBlock for Client {
fn import_sealed_block(&self, block: SealedBlock) -> EthcoreResult<H256> {
let start = Instant::now();
let raw = block.rlp_bytes();
let header = block.header.clone();
let hash = header.hash();
self.notify(|n| n.block_pre_import(&raw, &hash, header.difficulty()));
let route = {
// Do a super duper basic verification to detect potential bugs
if let Err(e) = self.engine.verify_block_basic(&header) {
self.importer.bad_blocks.report(
block.rlp_bytes(),
format!("Detected an issue with locally sealed block: {}", e),
);
return Err(e.into());
}
// scope for self.import_lock
let _import_lock = self.importer.import_lock.lock();
trace_time!("import_sealed_block");
let block_data = block.rlp_bytes();
let pending = self.importer.check_epoch_end_signal(
&header,
&block_data,
&block.receipts,
block.state.db(),
self
)?;
let route = self.importer.commit_block(
block,
&header,
encoded::Block::new(block_data),
pending,
self
);
trace!(target: "client", "Imported sealed block #{} ({})", header.number(), hash);
self.state_db.write().sync_cache(&route.enacted, &route.retracted, false);
route
};
let route = ChainRoute::from([route].as_ref());
self.importer.miner.chain_new_blocks(
self,
&[hash],
&[],
route.enacted(),
route.retracted(),
self.engine.seals_internally().is_some(),
);
self.notify(|notify| {
notify.new_blocks(
NewBlocks::new(
vec![hash],
vec![],
route.clone(),
vec![hash],
vec![],
start.elapsed(),
false
)
);
});
self.db.read().key_value().flush().expect("DB flush failed.");
Ok(hash)
}
}
impl BroadcastProposalBlock for Client {
fn broadcast_proposal_block(&self, block: SealedBlock) {
const DURATION_ZERO: Duration = Duration::from_millis(0);
self.notify(|notify| {
notify.new_blocks(
NewBlocks::new(
vec![],
vec![],
ChainRoute::default(),
vec![],
vec![block.rlp_bytes()],
DURATION_ZERO,
false
)
);
});
}
}
impl SealedBlockImporter for Client {}
impl ::miner::TransactionVerifierClient for Client {}
impl ::miner::BlockChainClient for Client {}
impl super::traits::EngineClient for Client {
fn update_sealing(&self) {
self.importer.miner.update_sealing(self)
}
fn submit_seal(&self, block_hash: H256, seal: Vec<Bytes>) {
let import = self.importer.miner.submit_seal(block_hash, seal).and_then(|block| self.import_sealed_block(block));
if let Err(err) = import {
warn!(target: "poa", "Wrong internal seal submission! {:?}", err);
}
}
fn broadcast_consensus_message(&self, message: Bytes) {
self.notify(|notify| notify.broadcast(ChainMessageType::Consensus(message.clone())));
}
fn epoch_transition_for(&self, parent_hash: H256) -> Option<::engines::EpochTransition> {
self.chain.read().epoch_transition_for(parent_hash)
}
fn as_full_client(&self) -> Option<&BlockChainClient> { Some(self) }
fn block_number(&self, id: BlockId) -> Option<BlockNumber> {
BlockChainClient::block_number(self, id)
}
fn block_header(&self, id: BlockId) -> Option<encoded::Header> {
BlockChainClient::block_header(self, id)
}
}
impl ProvingBlockChainClient for Client {
fn prove_storage(&self, key1: H256, key2: H256, id: BlockId) -> Option<(Vec<Bytes>, H256)> {
self.state_at(id)
.and_then(move |state| state.prove_storage(key1, key2).ok())
}
fn prove_account(&self, key1: H256, id: BlockId) -> Option<(Vec<Bytes>, ::types::basic_account::BasicAccount)> {
self.state_at(id)
.and_then(move |state| state.prove_account(key1).ok())
}
fn prove_transaction(&self, transaction: SignedTransaction, id: BlockId) -> Option<(Bytes, Vec<DBValue>)> {
let (header, mut env_info) = match (self.block_header(id), self.env_info(id)) {
(Some(s), Some(e)) => (s, e),
_ => return None,
};
env_info.gas_limit = transaction.gas.clone();
let mut jdb = self.state_db.read().journal_db().boxed_clone();
state::prove_transaction_virtual(
jdb.as_hash_db_mut(),
header.state_root().clone(),
&transaction,
self.engine.machine(),
&env_info,
self.factories.clone(),
)
}
fn epoch_signal(&self, hash: H256) -> Option<Vec<u8>> {
// pending transitions are never deleted, and do not contain
// finality proofs by definition.
self.chain.read().get_pending_transition(hash).map(|pending| pending.proof)
}
}
impl SnapshotClient for Client {}
impl Drop for Client {
fn drop(&mut self) {
if let Some(c) = Arc::get_mut(&mut self.engine) {
c.stop()
} else {
warn!(target: "shutdown", "unable to get mut ref for engine for shutdown.");
}
}
}
/// Returns `LocalizedReceipt` given `LocalizedTransaction`
/// and a vector of receipts from given block up to transaction index.
fn transaction_receipt(
machine: &::machine::EthereumMachine,
mut tx: LocalizedTransaction,
receipt: Receipt,
prior_gas_used: U256,
prior_no_of_logs: usize,
) -> LocalizedReceipt {
let sender = tx.sender();
let transaction_hash = tx.hash();
let block_hash = tx.block_hash;
let block_number = tx.block_number;
let transaction_index = tx.transaction_index;
LocalizedReceipt {
from: sender,
to: match tx.action {
Action::Create => None,
Action::Call(ref address) => Some(address.clone().into())
},
transaction_hash: transaction_hash,
transaction_index: transaction_index,
block_hash: block_hash,
block_number: block_number,
cumulative_gas_used: receipt.gas_used,
gas_used: receipt.gas_used - prior_gas_used,
contract_address: match tx.action {
Action::Call(_) => None,
Action::Create => Some(contract_address(machine.create_address_scheme(block_number), &sender, &tx.nonce, &tx.data).0)
},
logs: receipt.logs.into_iter().enumerate().map(|(i, log)| LocalizedLogEntry {
entry: log,
block_hash: block_hash,
block_number: block_number,
transaction_hash: transaction_hash,
transaction_index: transaction_index,
transaction_log_index: i,
log_index: prior_no_of_logs + i,
}).collect(),
log_bloom: receipt.log_bloom,
outcome: receipt.outcome,
}
}
#[cfg(test)]
mod tests {
#[test]
fn should_not_cache_details_before_commit() {
use client::{BlockChainClient, ChainInfo};
use test_helpers::{generate_dummy_client, get_good_dummy_block_hash};
use std::thread;
use std::time::Duration;
use std::sync::Arc;
use std::sync::atomic::{AtomicBool, Ordering};
use kvdb::DBTransaction;
use blockchain::ExtrasInsert;
use types::encoded;
let client = generate_dummy_client(0);
let genesis = client.chain_info().best_block_hash;
let (new_hash, new_block) = get_good_dummy_block_hash();
let go = {
// Separate thread uncommitted transaction
let go = Arc::new(AtomicBool::new(false));
let go_thread = go.clone();
let another_client = client.clone();
thread::spawn(move || {
let mut batch = DBTransaction::new();
another_client.chain.read().insert_block(&mut batch, encoded::Block::new(new_block), Vec::new(), ExtrasInsert {
fork_choice: ::engines::ForkChoice::New,
is_finalized: false,
});
go_thread.store(true, Ordering::SeqCst);
});
go
};
while !go.load(Ordering::SeqCst) { thread::park_timeout(Duration::from_millis(5)); }
assert!(client.tree_route(&genesis, &new_hash).is_none());
}
#[test]
fn should_return_block_receipts() {
use client::{BlockChainClient, BlockId, TransactionId};
use test_helpers::{generate_dummy_client_with_data};
let client = generate_dummy_client_with_data(2, 2, &[1.into(), 1.into()]);
let receipts = client.localized_block_receipts(BlockId::Latest).unwrap();
assert_eq!(receipts.len(), 2);
assert_eq!(receipts[0].transaction_index, 0);
assert_eq!(receipts[0].block_number, 2);
assert_eq!(receipts[0].cumulative_gas_used, 53_000.into());
assert_eq!(receipts[0].gas_used, 53_000.into());
assert_eq!(receipts[1].transaction_index, 1);
assert_eq!(receipts[1].block_number, 2);
assert_eq!(receipts[1].cumulative_gas_used, 106_000.into());
assert_eq!(receipts[1].gas_used, 53_000.into());
let receipt = client.transaction_receipt(TransactionId::Hash(receipts[0].transaction_hash));
assert_eq!(receipt, Some(receipts[0].clone()));
let receipt = client.transaction_receipt(TransactionId::Hash(receipts[1].transaction_hash));
assert_eq!(receipt, Some(receipts[1].clone()));
}
#[test]
fn should_return_correct_log_index() {
use hash::keccak;
use super::transaction_receipt;
use ethkey::KeyPair;
use types::log_entry::{LogEntry, LocalizedLogEntry};
use types::receipt::{Receipt, LocalizedReceipt, TransactionOutcome};
use types::transaction::{Transaction, LocalizedTransaction, Action};
// given
let key = KeyPair::from_secret_slice(&keccak("test")).unwrap();
let secret = key.secret();
let machine = ::ethereum::new_frontier_test_machine();
let block_number = 1;
let block_hash = 5.into();
let state_root = 99.into();
let gas_used = 10.into();
let raw_tx = Transaction {
nonce: 0.into(),
gas_price: 0.into(),
gas: 21000.into(),
action: Action::Call(10.into()),
value: 0.into(),
data: vec![],
};
let tx1 = raw_tx.clone().sign(secret, None);
let transaction = LocalizedTransaction {
signed: tx1.clone().into(),
block_number: block_number,
block_hash: block_hash,
transaction_index: 1,
cached_sender: Some(tx1.sender()),
};
let logs = vec![LogEntry {
address: 5.into(),
topics: vec![],
data: vec![],
}, LogEntry {
address: 15.into(),
topics: vec![],
data: vec![],
}];
let receipt = Receipt {
outcome: TransactionOutcome::StateRoot(state_root),
gas_used: gas_used,
log_bloom: Default::default(),
logs: logs.clone(),
};
// when
let receipt = transaction_receipt(&machine, transaction, receipt, 5.into(), 1);
// then
assert_eq!(receipt, LocalizedReceipt {
from: tx1.sender().into(),
to: match tx1.action {
Action::Create => None,
Action::Call(ref address) => Some(address.clone().into())
},
transaction_hash: tx1.hash(),
transaction_index: 1,
block_hash: block_hash,
block_number: block_number,
cumulative_gas_used: gas_used,
gas_used: gas_used - 5,
contract_address: None,
logs: vec![LocalizedLogEntry {
entry: logs[0].clone(),
block_hash: block_hash,
block_number: block_number,
transaction_hash: tx1.hash(),
transaction_index: 1,
transaction_log_index: 0,
log_index: 1,
}, LocalizedLogEntry {
entry: logs[1].clone(),
block_hash: block_hash,
block_number: block_number,
transaction_hash: tx1.hash(),
transaction_index: 1,
transaction_log_index: 1,
log_index: 2,
}],
log_bloom: Default::default(),
outcome: TransactionOutcome::StateRoot(state_root),
});
}
}
/// Queue some items to be processed by IO client.
struct IoChannelQueue {
currently_queued: Arc<AtomicUsize>,
limit: usize,
}
impl IoChannelQueue {
pub fn new(limit: usize) -> Self {
IoChannelQueue {
currently_queued: Default::default(),
limit,
}
}
pub fn queue<F>(&self, channel: &IoChannel<ClientIoMessage>, count: usize, fun: F) -> Result<(), QueueError> where
F: Fn(&Client) + Send + Sync + 'static,
{
let queue_size = self.currently_queued.load(AtomicOrdering::Relaxed);
ensure!(queue_size < self.limit, QueueErrorKind::Full(self.limit));
let currently_queued = self.currently_queued.clone();
let result = channel.send(ClientIoMessage::execute(move |client| {
currently_queued.fetch_sub(count, AtomicOrdering::SeqCst);
fun(client);
}));
match result {
Ok(_) => {
self.currently_queued.fetch_add(count, AtomicOrdering::SeqCst);
Ok(())
},
Err(e) => bail!(QueueErrorKind::Channel(e)),
}
}
}
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