// 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 .
//! `BlockChain` synchronization strategy.
//! Syncs to peers and keeps up to date.
//! This implementation uses ethereum protocol v63
//!
//! Syncing strategy summary.
//! Split the chain into ranges of N blocks each. Download ranges sequentially. Split each range into subchains of M blocks. Download subchains in parallel.
//! State.
//! Sync state consists of the following data:
//! - s: State enum which can be one of the following values: `ChainHead`, `Blocks`, `Idle`
//! - H: A set of downloaded block headers
//! - B: A set of downloaded block bodies
//! - S: Set of block subchain start block hashes to download.
//! - l: Last imported / common block hash
//! - P: A set of connected peers. For each peer we maintain its last known total difficulty and starting block hash being requested if any.
//! General behaviour.
//! We start with all sets empty, l is set to the best block in the block chain, s is set to `ChainHead`.
//! If at any moment a bad block is reported by the block queue, we set s to `ChainHead`, reset l to the best block in the block chain and clear H, B and S.
//! If at any moment P becomes empty, we set s to `ChainHead`, and clear H, B and S.
//!
//! Workflow for `ChainHead` state.
//! In this state we try to get subchain headers with a single `GetBlockHeaders` request.
//! On `NewPeer` / On `Restart`:
//! If peer's total difficulty is higher and there are less than 5 peers downloading, request N/M headers with interval M+1 starting from l
//! On `BlockHeaders(R)`:
//! If R is empty:
//! If l is equal to genesis block hash or l is more than 1000 blocks behind our best hash:
//! Remove current peer from P. set l to the best block in the block chain. Select peer with maximum total difficulty from P and restart.
//! Else
//! Set l to l’s parent and restart.
//! Else if we already have all the headers in the block chain or the block queue:
//! Set s to `Idle`,
//! Else
//! Set S to R, set s to `Blocks`.
//!
//! All other messages are ignored.
//!
//! Workflow for `Blocks` state.
//! In this state we download block headers and bodies from multiple peers.
//! On `NewPeer` / On `Restart`:
//! For all idle peers:
//! Find a set of 256 or less block hashes in H which are not in B and not being downloaded by other peers. If the set is not empty:
//! Request block bodies for the hashes in the set.
//! Else
//! Find an element in S which is not being downloaded by other peers. If found: Request M headers starting from the element.
//!
//! On `BlockHeaders(R)`:
//! If R is empty remove current peer from P and restart.
//! Validate received headers:
//! For each header find a parent in H or R or the blockchain. Restart if there is a block with unknown parent.
//! Find at least one header from the received list in S. Restart if there is none.
//! Go to `CollectBlocks`.
//!
//! On `BlockBodies(R)`:
//! If R is empty remove current peer from P and restart.
//! Add bodies with a matching header in H to B.
//! Go to `CollectBlocks`.
//!
//! `CollectBlocks`:
//! Find a chain of blocks C in H starting from h where h’s parent equals to l. The chain ends with the first block which does not have a body in B.
//! Add all blocks from the chain to the block queue. Remove them from H and B. Set l to the hash of the last block from C.
//! Update and merge subchain heads in S. For each h in S find a chain of blocks in B starting from h. Remove h from S. if the chain does not include an element from S add the end of the chain to S.
//! If H is empty and S contains a single element set s to `ChainHead`.
//! Restart.
//!
//! All other messages are ignored.
//! Workflow for Idle state.
//! On `NewBlock`:
//! Import the block. If the block is unknown set s to `ChainHead` and restart.
//! On `NewHashes`:
//! Set s to `ChainHead` and restart.
//!
//! All other messages are ignored.
mod handler;
pub mod sync_packet;
mod propagator;
mod requester;
mod supplier;
use std::sync::{Arc, mpsc};
use std::collections::{HashSet, HashMap, BTreeMap};
use std::cmp;
use std::time::{Duration, Instant};
use hash::keccak;
use heapsize::HeapSizeOf;
use ethereum_types::{H256, U256};
use fastmap::{H256FastMap, H256FastSet};
use parking_lot::{Mutex, RwLock, RwLockWriteGuard};
use bytes::Bytes;
use rlp::{RlpStream, DecoderError};
use network::{self, PeerId, PacketId};
use network::client_version::ClientVersion;
use ethcore::client::{BlockChainClient, BlockStatus, BlockId, BlockChainInfo, BlockQueueInfo};
use ethcore::snapshot::{RestorationStatus};
use sync_io::SyncIo;
use super::{WarpSync, SyncConfig};
use block_sync::{BlockDownloader, DownloadAction};
use rand::Rng;
use snapshot::{Snapshot};
use api::{EthProtocolInfo as PeerInfoDigest, WARP_SYNC_PROTOCOL_ID, PriorityTask};
use private_tx::PrivateTxHandler;
use transactions_stats::{TransactionsStats, Stats as TransactionStats};
use types::transaction::UnverifiedTransaction;
use types::BlockNumber;
use self::handler::SyncHandler;
use self::sync_packet::{PacketInfo, SyncPacket};
use self::sync_packet::SyncPacket::{
NewBlockPacket,
StatusPacket,
};
use self::propagator::SyncPropagator;
use self::requester::SyncRequester;
pub(crate) use self::supplier::SyncSupplier;
known_heap_size!(0, PeerInfo);
pub type PacketDecodeError = DecoderError;
/// 63 version of Ethereum protocol.
pub const ETH_PROTOCOL_VERSION_63: (u8, u8) = (63, 0x11);
/// 62 version of Ethereum protocol.
pub const ETH_PROTOCOL_VERSION_62: (u8, u8) = (62, 0x11);
/// 1 version of Parity protocol and the packet count.
pub const PAR_PROTOCOL_VERSION_1: (u8, u8) = (1, 0x15);
/// 2 version of Parity protocol (consensus messages added).
pub const PAR_PROTOCOL_VERSION_2: (u8, u8) = (2, 0x16);
/// 3 version of Parity protocol (private transactions messages added).
pub const PAR_PROTOCOL_VERSION_3: (u8, u8) = (3, 0x18);
pub const MAX_BODIES_TO_SEND: usize = 256;
pub const MAX_HEADERS_TO_SEND: usize = 512;
pub const MAX_NODE_DATA_TO_SEND: usize = 1024;
pub const MAX_RECEIPTS_HEADERS_TO_SEND: usize = 256;
const MIN_PEERS_PROPAGATION: usize = 4;
const MAX_PEERS_PROPAGATION: usize = 128;
const MAX_PEER_LAG_PROPAGATION: BlockNumber = 20;
const MAX_NEW_HASHES: usize = 64;
const MAX_NEW_BLOCK_AGE: BlockNumber = 20;
// maximal packet size with transactions (cannot be greater than 16MB - protocol limitation).
// keep it under 8MB as well, cause it seems that it may result oversized after compression.
const MAX_TRANSACTION_PACKET_SIZE: usize = 5 * 1024 * 1024;
// Min number of blocks to be behind for a snapshot sync
const SNAPSHOT_RESTORE_THRESHOLD: BlockNumber = 30000;
const SNAPSHOT_MIN_PEERS: usize = 3;
const MAX_SNAPSHOT_CHUNKS_DOWNLOAD_AHEAD: usize = 3;
const WAIT_PEERS_TIMEOUT: Duration = Duration::from_secs(5);
const STATUS_TIMEOUT: Duration = Duration::from_secs(5);
const HEADERS_TIMEOUT: Duration = Duration::from_secs(15);
const BODIES_TIMEOUT: Duration = Duration::from_secs(20);
const RECEIPTS_TIMEOUT: Duration = Duration::from_secs(10);
const FORK_HEADER_TIMEOUT: Duration = Duration::from_secs(3);
const SNAPSHOT_MANIFEST_TIMEOUT: Duration = Duration::from_secs(5);
const SNAPSHOT_DATA_TIMEOUT: Duration = Duration::from_secs(120);
/// Defines how much time we have to complete priority transaction or block propagation.
/// after the deadline is reached the task is considered finished
/// (so we might sent only to some part of the peers we originally intended to send to)
const PRIORITY_TASK_DEADLINE: Duration = Duration::from_millis(100);
#[derive(Copy, Clone, Eq, PartialEq, Debug)]
/// Sync state
pub enum SyncState {
/// Collecting enough peers to start syncing.
WaitingPeers,
/// Waiting for snapshot manifest download
SnapshotManifest,
/// Downloading snapshot data
SnapshotData,
/// Waiting for snapshot restoration progress.
SnapshotWaiting,
/// Downloading new blocks
Blocks,
/// Initial chain sync complete. Waiting for new packets
Idle,
/// Block downloading paused. Waiting for block queue to process blocks and free some space
Waiting,
/// Downloading blocks learned from `NewHashes` packet
NewBlocks,
}
/// Syncing status and statistics
#[derive(Clone, Copy)]
pub struct SyncStatus {
/// State
pub state: SyncState,
/// Syncing protocol version. That's the maximum protocol version we connect to.
pub protocol_version: u8,
/// The underlying p2p network version.
pub network_id: u64,
/// `BlockChain` height for the moment the sync started.
pub start_block_number: BlockNumber,
/// Last fully downloaded and imported block number (if any).
pub last_imported_block_number: Option,
/// Highest block number in the download queue (if any).
pub highest_block_number: Option,
/// Total number of blocks for the sync process.
pub blocks_total: BlockNumber,
/// Number of blocks downloaded so far.
pub blocks_received: BlockNumber,
/// Total number of connected peers
pub num_peers: usize,
/// Total number of active peers.
pub num_active_peers: usize,
/// Heap memory used in bytes.
pub mem_used: usize,
/// Snapshot chunks
pub num_snapshot_chunks: usize,
/// Snapshot chunks downloaded
pub snapshot_chunks_done: usize,
/// Last fully downloaded and imported ancient block number (if any).
pub last_imported_old_block_number: Option,
}
impl SyncStatus {
/// Indicates if snapshot download is in progress
pub fn is_snapshot_syncing(&self) -> bool {
match self.state {
SyncState::SnapshotManifest |
SyncState::SnapshotData |
SyncState::SnapshotWaiting => true,
_ => false,
}
}
/// Returns max no of peers to display in informants
pub fn current_max_peers(&self, min_peers: u32, max_peers: u32) -> u32 {
if self.num_peers as u32 > min_peers {
max_peers
} else {
min_peers
}
}
/// Is it doing a major sync?
pub fn is_syncing(&self, queue_info: BlockQueueInfo) -> bool {
let is_syncing_state = match self.state { SyncState::Idle | SyncState::NewBlocks => false, _ => true };
let is_verifying = queue_info.unverified_queue_size + queue_info.verified_queue_size > 3;
is_verifying || is_syncing_state
}
}
#[derive(PartialEq, Eq, Debug, Clone)]
/// Peer data type requested
pub enum PeerAsking {
Nothing,
ForkHeader,
BlockHeaders,
BlockBodies,
BlockReceipts,
SnapshotManifest,
SnapshotData,
}
#[derive(PartialEq, Eq, Debug, Clone, Copy)]
/// Block downloader channel.
pub enum BlockSet {
/// New blocks better than out best blocks
NewBlocks,
/// Missing old blocks
OldBlocks,
}
#[derive(Clone, Eq, PartialEq)]
pub enum ForkConfirmation {
/// Fork block confirmation pending.
Unconfirmed,
/// Peer's chain is too short to confirm the fork.
TooShort,
/// Fork is confirmed.
Confirmed,
}
#[derive(Clone)]
/// Syncing peer information
pub struct PeerInfo {
/// eth protocol version
protocol_version: u8,
/// Peer chain genesis hash
genesis: H256,
/// Peer network id
network_id: u64,
/// Peer best block hash
latest_hash: H256,
/// Peer total difficulty if known
difficulty: Option,
/// Type of data currenty being requested from peer.
asking: PeerAsking,
/// A set of block numbers being requested
asking_blocks: Vec,
/// Holds requested header hash if currently requesting block header by hash
asking_hash: Option,
/// Holds requested snapshot chunk hash if any.
asking_snapshot_data: Option,
/// Request timestamp
ask_time: Instant,
/// Holds a set of transactions recently sent to this peer to avoid spamming.
last_sent_transactions: H256FastSet,
/// Holds a set of private transactions and their signatures recently sent to this peer to avoid spamming.
last_sent_private_transactions: H256FastSet,
/// Pending request is expired and result should be ignored
expired: bool,
/// Private transactions enabled
private_tx_enabled: bool,
/// Peer fork confirmation status
confirmation: ForkConfirmation,
/// Best snapshot hash
snapshot_hash: Option,
/// Best snapshot block number
snapshot_number: Option,
/// Block set requested
block_set: Option,
/// Version of the software the peer is running
client_version: ClientVersion,
}
impl PeerInfo {
fn can_sync(&self) -> bool {
self.confirmation == ForkConfirmation::Confirmed && !self.expired
}
fn is_allowed(&self) -> bool {
self.confirmation != ForkConfirmation::Unconfirmed && !self.expired
}
fn reset_asking(&mut self) {
self.asking_blocks.clear();
self.asking_hash = None;
// mark any pending requests as expired
if self.asking != PeerAsking::Nothing && self.is_allowed() {
self.expired = true;
}
}
fn reset_private_stats(&mut self) {
self.last_sent_private_transactions.clear();
}
}
#[cfg(not(test))]
pub mod random {
use rand;
pub fn new() -> rand::ThreadRng { rand::thread_rng() }
}
#[cfg(test)]
pub mod random {
use rand::{self, SeedableRng};
pub fn new() -> rand::XorShiftRng { rand::XorShiftRng::from_seed([0, 1, 2, 3]) }
}
pub type RlpResponseResult = Result, PacketDecodeError>;
pub type Peers = HashMap;
/// Thread-safe wrapper for `ChainSync`.
///
/// NOTE always lock in order of fields declaration
pub struct ChainSyncApi {
/// Priority tasks queue
priority_tasks: Mutex>,
/// The rest of sync data
sync: RwLock,
}
impl ChainSyncApi {
/// Creates new `ChainSyncApi`
pub fn new(
config: SyncConfig,
chain: &BlockChainClient,
private_tx_handler: Option>,
priority_tasks: mpsc::Receiver,
) -> Self {
ChainSyncApi {
sync: RwLock::new(ChainSync::new(config, chain, private_tx_handler)),
priority_tasks: Mutex::new(priority_tasks),
}
}
/// Gives `write` access to underlying `ChainSync`
pub fn write(&self) -> RwLockWriteGuard {
self.sync.write()
}
/// Returns info about given list of peers
pub fn peer_info(&self, ids: &[PeerId]) -> Vec> {
let sync = self.sync.read();
ids.iter().map(|id| sync.peer_info(id)).collect()
}
/// Returns synchonization status
pub fn status(&self) -> SyncStatus {
self.sync.read().status()
}
/// Returns transactions propagation statistics
pub fn transactions_stats(&self) -> BTreeMap {
self.sync.read().transactions_stats()
.iter()
.map(|(hash, stats)| (*hash, stats.into()))
.collect()
}
/// Dispatch incoming requests and responses
pub fn dispatch_packet(&self, io: &mut SyncIo, peer: PeerId, packet_id: u8, data: &[u8]) {
SyncSupplier::dispatch_packet(&self.sync, io, peer, packet_id, data)
}
/// Process a priority propagation queue.
/// This task is run from a timer and should be time constrained.
/// Hence we set up a deadline for the execution and cancel the task if the deadline is exceeded.
///
/// NOTE This method should only handle stuff that can be canceled and would reach other peers
/// by other means.
pub fn process_priority_queue(&self, io: &mut SyncIo) {
fn check_deadline(deadline: Instant) -> Option {
let now = Instant::now();
if now > deadline {
None
} else {
Some(deadline - now)
}
}
// deadline to get the task from the queue
let deadline = Instant::now() + ::api::PRIORITY_TIMER_INTERVAL;
let mut work = || {
let task = {
let tasks = self.priority_tasks.try_lock_until(deadline)?;
let left = check_deadline(deadline)?;
tasks.recv_timeout(left).ok()?
};
task.starting();
// wait for the sync lock until deadline,
// note we might drop the task here if we won't manage to acquire the lock.
let mut sync = self.sync.try_write_until(deadline)?;
// since we already have everything let's use a different deadline
// to do the rest of the job now, so that previous work is not wasted.
let deadline = Instant::now() + PRIORITY_TASK_DEADLINE;
let as_ms = move |prev| {
let dur: Duration = Instant::now() - prev;
dur.as_secs() * 1_000 + dur.subsec_millis() as u64
};
match task {
// NOTE We can't simply use existing methods,
// cause the block is not in the DB yet.
PriorityTask::PropagateBlock { started, block, hash, difficulty } => {
// try to send to peers that are on the same block as us
// (they will most likely accept the new block).
let chain_info = io.chain().chain_info();
let total_difficulty = chain_info.total_difficulty + difficulty;
let rlp = ChainSync::create_block_rlp(&block, total_difficulty);
for peers in sync.get_peers(&chain_info, PeerState::SameBlock).chunks(10) {
check_deadline(deadline)?;
for peer in peers {
SyncPropagator::send_packet(io, *peer, NewBlockPacket, rlp.clone());
if let Some(ref mut peer) = sync.peers.get_mut(peer) {
peer.latest_hash = hash;
}
}
}
debug!(target: "sync", "Finished block propagation, took {}ms", as_ms(started));
},
PriorityTask::PropagateTransactions(time, _) => {
SyncPropagator::propagate_new_transactions(&mut sync, io, || {
check_deadline(deadline).is_some()
});
debug!(target: "sync", "Finished transaction propagation, took {}ms", as_ms(time));
},
}
Some(())
};
// Process as many items as we can until the deadline is reached.
loop {
if work().is_none() {
return;
}
}
}
}
// Static methods
impl ChainSync {
/// creates rlp to send for the tree defined by 'from' and 'to' hashes
fn create_new_hashes_rlp(chain: &BlockChainClient, from: &H256, to: &H256) -> Option {
match chain.tree_route(from, to) {
Some(route) => {
let uncles = chain.find_uncles(from).unwrap_or_else(Vec::new);
match route.blocks.len() {
0 => None,
_ => {
let mut blocks = route.blocks;
blocks.extend(uncles);
let mut rlp_stream = RlpStream::new_list(blocks.len());
for block_hash in blocks {
let mut hash_rlp = RlpStream::new_list(2);
let number = chain.block_header(BlockId::Hash(block_hash.clone()))
.expect("chain.tree_route and chain.find_uncles only return hahses of blocks that are in the blockchain. qed.").number();
hash_rlp.append(&block_hash);
hash_rlp.append(&number);
rlp_stream.append_raw(hash_rlp.as_raw(), 1);
}
Some(rlp_stream.out())
}
}
},
None => None
}
}
/// creates rlp from block bytes and total difficulty
fn create_block_rlp(bytes: &Bytes, total_difficulty: U256) -> Bytes {
let mut rlp_stream = RlpStream::new_list(2);
rlp_stream.append_raw(bytes, 1);
rlp_stream.append(&total_difficulty);
rlp_stream.out()
}
/// creates latest block rlp for the given client
fn create_latest_block_rlp(chain: &BlockChainClient) -> Bytes {
Self::create_block_rlp(
&chain.block(BlockId::Hash(chain.chain_info().best_block_hash))
.expect("Best block always exists").into_inner(),
chain.chain_info().total_difficulty
)
}
/// creates given hash block rlp for the given client
fn create_new_block_rlp(chain: &BlockChainClient, hash: &H256) -> Bytes {
Self::create_block_rlp(
&chain.block(BlockId::Hash(hash.clone())).expect("Block has just been sealed; qed").into_inner(),
chain.block_total_difficulty(BlockId::Hash(hash.clone())).expect("Block has just been sealed; qed.")
)
}
fn select_random_peers(peers: &[PeerId]) -> Vec {
// take sqrt(x) peers
let mut peers = peers.to_vec();
let mut count = (peers.len() as f64).powf(0.5).round() as usize;
count = cmp::min(count, MAX_PEERS_PROPAGATION);
count = cmp::max(count, MIN_PEERS_PROPAGATION);
random::new().shuffle(&mut peers);
peers.truncate(count);
peers
}
fn get_init_state(warp_sync: WarpSync, chain: &BlockChainClient) -> SyncState {
let best_block = chain.chain_info().best_block_number;
match warp_sync {
WarpSync::Enabled => SyncState::WaitingPeers,
WarpSync::OnlyAndAfter(block) if block > best_block => SyncState::WaitingPeers,
_ => SyncState::Idle,
}
}
}
/// A peer query method for getting a list of peers
enum PeerState {
/// Peer is on different hash than us
Lagging,
/// Peer is on the same block as us
SameBlock
}
/// Blockchain sync handler.
/// See module documentation for more details.
pub struct ChainSync {
/// Sync state
state: SyncState,
/// Last block number for the start of sync
starting_block: BlockNumber,
/// Highest block number seen
highest_block: Option,
/// All connected peers
peers: Peers,
/// Peers active for current sync round
active_peers: HashSet,
/// Block download process for new blocks
new_blocks: BlockDownloader,
/// Block download process for ancient blocks
old_blocks: Option,
/// Last propagated block number
last_sent_block_number: BlockNumber,
/// Network ID
network_id: u64,
/// Optional fork block to check
fork_block: Option<(BlockNumber, H256)>,
/// Snapshot downloader.
snapshot: Snapshot,
/// Connected peers pending Status message.
/// Value is request timestamp.
handshaking_peers: HashMap,
/// Sync start timestamp. Measured when first peer is connected
sync_start_time: Option,
/// Transactions propagation statistics
transactions_stats: TransactionsStats,
/// Enable ancient block downloading
download_old_blocks: bool,
/// Shared private tx service.
private_tx_handler: Option>,
/// Enable warp sync.
warp_sync: WarpSync,
}
impl ChainSync {
/// Create a new instance of syncing strategy.
pub fn new(
config: SyncConfig,
chain: &BlockChainClient,
private_tx_handler: Option>,
) -> Self {
let chain_info = chain.chain_info();
let best_block = chain.chain_info().best_block_number;
let state = Self::get_init_state(config.warp_sync, chain);
let mut sync = ChainSync {
state,
starting_block: best_block,
highest_block: None,
peers: HashMap::new(),
handshaking_peers: HashMap::new(),
active_peers: HashSet::new(),
new_blocks: BlockDownloader::new(BlockSet::NewBlocks, &chain_info.best_block_hash, chain_info.best_block_number),
old_blocks: None,
last_sent_block_number: 0,
network_id: config.network_id,
fork_block: config.fork_block,
download_old_blocks: config.download_old_blocks,
snapshot: Snapshot::new(),
sync_start_time: None,
transactions_stats: TransactionsStats::default(),
private_tx_handler,
warp_sync: config.warp_sync,
};
sync.update_targets(chain);
sync
}
/// Returns synchonization status
pub fn status(&self) -> SyncStatus {
let last_imported_number = self.new_blocks.last_imported_block_number();
SyncStatus {
state: self.state.clone(),
protocol_version: ETH_PROTOCOL_VERSION_63.0,
network_id: self.network_id,
start_block_number: self.starting_block,
last_imported_block_number: Some(last_imported_number),
last_imported_old_block_number: self.old_blocks.as_ref().map(|d| d.last_imported_block_number()),
highest_block_number: self.highest_block.map(|n| cmp::max(n, last_imported_number)),
blocks_received: if last_imported_number > self.starting_block { last_imported_number - self.starting_block } else { 0 },
blocks_total: match self.highest_block { Some(x) if x > self.starting_block => x - self.starting_block, _ => 0 },
num_peers: self.peers.values().filter(|p| p.is_allowed()).count(),
num_active_peers: self.peers.values().filter(|p| p.is_allowed() && p.asking != PeerAsking::Nothing).count(),
num_snapshot_chunks: self.snapshot.total_chunks(),
snapshot_chunks_done: self.snapshot.done_chunks(),
mem_used:
self.new_blocks.heap_size()
+ self.old_blocks.as_ref().map_or(0, |d| d.heap_size())
+ self.peers.heap_size_of_children(),
}
}
/// Returns information on peers connections
pub fn peer_info(&self, peer_id: &PeerId) -> Option {
self.peers.get(peer_id).map(|peer_data| {
PeerInfoDigest {
version: peer_data.protocol_version as u32,
difficulty: peer_data.difficulty,
head: peer_data.latest_hash,
}
})
}
/// Returns transactions propagation statistics
pub fn transactions_stats(&self) -> &H256FastMap {
self.transactions_stats.stats()
}
/// Updates transactions were received by a peer
pub fn transactions_received(&mut self, txs: &[UnverifiedTransaction], peer_id: PeerId) {
if let Some(peer_info) = self.peers.get_mut(&peer_id) {
peer_info.last_sent_transactions.extend(txs.iter().map(|tx| tx.hash()));
}
}
/// Abort all sync activity
pub fn abort(&mut self, io: &mut SyncIo) {
self.reset_and_continue(io);
self.peers.clear();
}
/// Reset sync. Clear all downloaded data but keep the queue.
/// Set sync state to the given state or to the initial state if `None` is provided.
fn reset(&mut self, io: &mut SyncIo, state: Option) {
self.new_blocks.reset();
let chain_info = io.chain().chain_info();
for (_, ref mut p) in &mut self.peers {
if p.block_set != Some(BlockSet::OldBlocks) {
p.reset_asking();
if p.difficulty.is_none() {
// assume peer has up to date difficulty
p.difficulty = Some(chain_info.pending_total_difficulty);
}
}
}
self.state = state.unwrap_or_else(|| Self::get_init_state(self.warp_sync, io.chain()));
// Reactivate peers only if some progress has been made
// since the last sync round of if starting fresh.
self.active_peers = self.peers.keys().cloned().collect();
}
/// Restart sync
pub fn reset_and_continue(&mut self, io: &mut SyncIo) {
trace!(target: "sync", "Restarting");
if self.state == SyncState::SnapshotData {
debug!(target:"sync", "Aborting snapshot restore");
io.snapshot_service().abort_restore();
}
self.snapshot.clear();
self.reset(io, None);
self.continue_sync(io);
}
/// Remove peer from active peer set. Peer will be reactivated on the next sync
/// round.
fn deactivate_peer(&mut self, _io: &mut SyncIo, peer_id: PeerId) {
trace!(target: "sync", "Deactivating peer {}", peer_id);
self.active_peers.remove(&peer_id);
}
fn maybe_start_snapshot_sync(&mut self, io: &mut SyncIo) {
if !self.warp_sync.is_enabled() || io.snapshot_service().supported_versions().is_none() {
trace!(target: "sync", "Skipping warp sync. Disabled or not supported.");
return;
}
if self.state != SyncState::WaitingPeers && self.state != SyncState::Blocks && self.state != SyncState::Waiting {
trace!(target: "sync", "Skipping warp sync. State: {:?}", self.state);
return;
}
// Make sure the snapshot block is not too far away from best block and network best block and
// that it is higher than fork detection block
let our_best_block = io.chain().chain_info().best_block_number;
let fork_block = self.fork_block.map_or(0, |(n, _)| n);
let (best_hash, max_peers, snapshot_peers) = {
let expected_warp_block = match self.warp_sync {
WarpSync::OnlyAndAfter(block) => block,
_ => 0,
};
//collect snapshot infos from peers
let snapshots = self.peers.iter()
.filter(|&(_, p)| p.is_allowed() && p.snapshot_number.map_or(false, |sn|
// Snapshot must be old enough that it's usefull to sync with it
our_best_block < sn && (sn - our_best_block) > SNAPSHOT_RESTORE_THRESHOLD &&
// Snapshot must have been taken after the Fork
sn > fork_block &&
// Snapshot must be greater than the warp barrier if any
sn > expected_warp_block &&
// If we know a highest block, snapshot must be recent enough
self.highest_block.map_or(true, |highest| {
highest < sn || (highest - sn) <= SNAPSHOT_RESTORE_THRESHOLD
})
))
.filter_map(|(p, peer)| peer.snapshot_hash.map(|hash| (p, hash.clone())))
.filter(|&(_, ref hash)| !self.snapshot.is_known_bad(hash));
let mut snapshot_peers = HashMap::new();
let mut max_peers: usize = 0;
let mut best_hash = None;
for (p, hash) in snapshots {
let peers = snapshot_peers.entry(hash).or_insert_with(Vec::new);
peers.push(*p);
if peers.len() > max_peers {
max_peers = peers.len();
best_hash = Some(hash);
}
}
(best_hash, max_peers, snapshot_peers)
};
let timeout = (self.state == SyncState::WaitingPeers) && self.sync_start_time.map_or(false, |t| t.elapsed() > WAIT_PEERS_TIMEOUT);
if let (Some(hash), Some(peers)) = (best_hash, best_hash.map_or(None, |h| snapshot_peers.get(&h))) {
if max_peers >= SNAPSHOT_MIN_PEERS {
trace!(target: "sync", "Starting confirmed snapshot sync {:?} with {:?}", hash, peers);
self.start_snapshot_sync(io, peers);
} else if timeout {
trace!(target: "sync", "Starting unconfirmed snapshot sync {:?} with {:?}", hash, peers);
self.start_snapshot_sync(io, peers);
}
} else if timeout && !self.warp_sync.is_warp_only() {
trace!(target: "sync", "No snapshots found, starting full sync");
self.state = SyncState::Idle;
self.continue_sync(io);
}
}
fn start_snapshot_sync(&mut self, io: &mut SyncIo, peers: &[PeerId]) {
if !self.snapshot.have_manifest() {
for p in peers {
if self.peers.get(p).map_or(false, |p| p.asking == PeerAsking::Nothing) {
SyncRequester::request_snapshot_manifest(self, io, *p);
}
}
self.state = SyncState::SnapshotManifest;
trace!(target: "sync", "New snapshot sync with {:?}", peers);
} else {
self.state = SyncState::SnapshotData;
trace!(target: "sync", "Resumed snapshot sync with {:?}", peers);
}
}
/// Restart sync disregarding the block queue status. May end up re-downloading up to QUEUE_SIZE blocks
pub fn restart(&mut self, io: &mut SyncIo) {
self.update_targets(io.chain());
self.reset_and_continue(io);
}
/// Update sync after the blockchain has been changed externally.
pub fn update_targets(&mut self, chain: &BlockChainClient) {
// Do not assume that the block queue/chain still has our last_imported_block
let chain = chain.chain_info();
self.new_blocks = BlockDownloader::new(BlockSet::NewBlocks, &chain.best_block_hash, chain.best_block_number);
self.old_blocks = None;
if self.download_old_blocks {
if let (Some(ancient_block_hash), Some(ancient_block_number)) = (chain.ancient_block_hash, chain.ancient_block_number) {
trace!(target: "sync", "Downloading old blocks from {:?} (#{}) till {:?} (#{:?})", ancient_block_hash, ancient_block_number, chain.first_block_hash, chain.first_block_number);
let mut downloader = BlockDownloader::new(BlockSet::OldBlocks, &ancient_block_hash, ancient_block_number);
if let Some(hash) = chain.first_block_hash {
trace!(target: "sync", "Downloader target set to {:?}", hash);
downloader.set_target(&hash);
}
self.old_blocks = Some(downloader);
}
}
}
/// Resume downloading
pub fn continue_sync(&mut self, io: &mut SyncIo) {
if self.state == SyncState::Waiting {
trace!(target: "sync", "Waiting for the block queue");
} else if self.state == SyncState::SnapshotWaiting {
trace!(target: "sync", "Waiting for the snapshot restoration");
} else {
// Collect active peers that can sync
let mut peers: Vec<(PeerId, u8)> = self.peers.iter().filter_map(|(peer_id, peer)|
if peer.can_sync() && peer.asking == PeerAsking::Nothing && self.active_peers.contains(&peer_id) {
Some((*peer_id, peer.protocol_version))
} else {
None
}
).collect();
if peers.len() > 0 {
trace!(
target: "sync",
"Syncing with peers: {} active, {} available, {} total",
self.active_peers.len(), peers.len(), self.peers.len()
);
random::new().shuffle(&mut peers); // TODO (#646): sort by rating
// prefer peers with higher protocol version
peers.sort_by(|&(_, ref v1), &(_, ref v2)| v1.cmp(v2));
for (peer_id, _) in peers {
self.sync_peer(io, peer_id, false);
}
}
}
if
(self.state == SyncState::Blocks || self.state == SyncState::NewBlocks) &&
!self.peers.values().any(|p| p.asking != PeerAsking::Nothing && p.block_set != Some(BlockSet::OldBlocks) && p.can_sync())
{
self.complete_sync(io);
}
}
/// Called after all blocks have been downloaded
fn complete_sync(&mut self, io: &mut SyncIo) {
trace!(target: "sync", "Sync complete");
self.reset(io, Some(SyncState::Idle));
}
/// Enter waiting state
fn pause_sync(&mut self) {
trace!(target: "sync", "Block queue full, pausing sync");
self.state = SyncState::Waiting;
}
/// Find something to do for a peer. Called for a new peer or when a peer is done with its task.
fn sync_peer(&mut self, io: &mut SyncIo, peer_id: PeerId, force: bool) {
if !self.active_peers.contains(&peer_id) {
trace!(target: "sync", "Skipping deactivated peer {}", peer_id);
return;
}
let (peer_latest, peer_difficulty, peer_snapshot_number, peer_snapshot_hash) = {
if let Some(peer) = self.peers.get_mut(&peer_id) {
if peer.asking != PeerAsking::Nothing || !peer.can_sync() {
trace!(target: "sync", "Skipping busy peer {}", peer_id);
return;
}
(peer.latest_hash.clone(), peer.difficulty.clone(), peer.snapshot_number.as_ref().cloned().unwrap_or(0), peer.snapshot_hash.as_ref().cloned())
} else {
return;
}
};
let chain_info = io.chain().chain_info();
let syncing_difficulty = chain_info.pending_total_difficulty;
let num_active_peers = self.peers.values().filter(|p| p.asking != PeerAsking::Nothing).count();
let higher_difficulty = peer_difficulty.map_or(true, |pd| pd > syncing_difficulty);
if force || higher_difficulty || self.old_blocks.is_some() {
match self.state {
SyncState::WaitingPeers => {
trace!(
target: "sync",
"Checking snapshot sync: {} vs {} (peer: {})",
peer_snapshot_number,
chain_info.best_block_number,
peer_id
);
self.maybe_start_snapshot_sync(io);
},
SyncState::Idle | SyncState::Blocks | SyncState::NewBlocks => {
if io.chain().queue_info().is_full() {
self.pause_sync();
return;
}
let have_latest = io.chain().block_status(BlockId::Hash(peer_latest)) != BlockStatus::Unknown;
trace!(target: "sync", "Considering peer {}, force={}, td={:?}, our td={}, latest={}, have_latest={}, state={:?}", peer_id, force, peer_difficulty, syncing_difficulty, peer_latest, have_latest, self.state);
if !have_latest && (higher_difficulty || force || self.state == SyncState::NewBlocks) {
// check if got new blocks to download
trace!(target: "sync", "Syncing with peer {}, force={}, td={:?}, our td={}, state={:?}", peer_id, force, peer_difficulty, syncing_difficulty, self.state);
if let Some(request) = self.new_blocks.request_blocks(peer_id, io, num_active_peers) {
SyncRequester::request_blocks(self, io, peer_id, request, BlockSet::NewBlocks);
if self.state == SyncState::Idle {
self.state = SyncState::Blocks;
}
return;
}
}
// Only ask for old blocks if the peer has an equal or higher difficulty
let equal_or_higher_difficulty = peer_difficulty.map_or(true, |pd| pd >= syncing_difficulty);
if force || equal_or_higher_difficulty {
if let Some(request) = self.old_blocks.as_mut().and_then(|d| d.request_blocks(peer_id, io, num_active_peers)) {
SyncRequester::request_blocks(self, io, peer_id, request, BlockSet::OldBlocks);
return;
}
} else {
trace!(
target: "sync",
"peer {:?} is not suitable for requesting old blocks, syncing_difficulty={:?}, peer_difficulty={:?}",
peer_id,
syncing_difficulty,
peer_difficulty
);
self.deactivate_peer(io, peer_id);
}
},
SyncState::SnapshotData => {
match io.snapshot_service().status() {
RestorationStatus::Ongoing { state_chunks_done, block_chunks_done, .. } => {
// Initialize the snapshot if not already done
self.snapshot.initialize(io.snapshot_service());
if self.snapshot.done_chunks() - (state_chunks_done + block_chunks_done) as usize > MAX_SNAPSHOT_CHUNKS_DOWNLOAD_AHEAD {
trace!(target: "sync", "Snapshot queue full, pausing sync");
self.state = SyncState::SnapshotWaiting;
return;
}
},
RestorationStatus::Initializing { .. } => {
trace!(target: "warp", "Snapshot is stil initializing.");
return;
},
_ => {
return;
},
}
if peer_snapshot_hash.is_some() && peer_snapshot_hash == self.snapshot.snapshot_hash() {
self.clear_peer_download(peer_id);
SyncRequester::request_snapshot_data(self, io, peer_id);
}
},
SyncState::SnapshotManifest | //already downloading from other peer
SyncState::Waiting |
SyncState::SnapshotWaiting => ()
}
} else {
trace!(target: "sync", "Skipping peer {}, force={}, td={:?}, our td={}, state={:?}", peer_id, force, peer_difficulty, syncing_difficulty, self.state);
}
}
/// Clear all blocks/headers marked as being downloaded by a peer.
fn clear_peer_download(&mut self, peer_id: PeerId) {
if let Some(ref peer) = self.peers.get(&peer_id) {
match peer.asking {
PeerAsking::BlockHeaders => {
if let Some(ref hash) = peer.asking_hash {
self.new_blocks.clear_header_download(hash);
if let Some(ref mut old) = self.old_blocks {
old.clear_header_download(hash);
}
}
},
PeerAsking::BlockBodies => {
self.new_blocks.clear_body_download(&peer.asking_blocks);
if let Some(ref mut old) = self.old_blocks {
old.clear_body_download(&peer.asking_blocks);
}
},
PeerAsking::BlockReceipts => {
self.new_blocks.clear_receipt_download(&peer.asking_blocks);
if let Some(ref mut old) = self.old_blocks {
old.clear_receipt_download(&peer.asking_blocks);
}
},
PeerAsking::SnapshotData => {
if let Some(hash) = peer.asking_snapshot_data {
self.snapshot.clear_chunk_download(&hash);
}
},
_ => (),
}
}
}
/// Checks if there are blocks fully downloaded that can be imported into the blockchain and does the import.
fn collect_blocks(&mut self, io: &mut SyncIo, block_set: BlockSet) {
match block_set {
BlockSet::NewBlocks => {
if self.new_blocks.collect_blocks(io, self.state == SyncState::NewBlocks) == DownloadAction::Reset {
self.reset_downloads(block_set);
self.new_blocks.reset();
}
},
BlockSet::OldBlocks => {
let mut is_complete = false;
let mut download_action = DownloadAction::None;
if let Some(downloader) = self.old_blocks.as_mut() {
download_action = downloader.collect_blocks(io, false);
is_complete = downloader.is_complete();
}
if download_action == DownloadAction::Reset {
self.reset_downloads(block_set);
if let Some(downloader) = self.old_blocks.as_mut() {
downloader.reset();
}
}
if is_complete {
trace!(target: "sync", "Background block download is complete");
self.old_blocks = None;
}
}
};
}
/// Mark all outstanding requests as expired
fn reset_downloads(&mut self, block_set: BlockSet) {
trace!(target: "sync", "Resetting downloads for {:?}", block_set);
for (_, ref mut p) in self.peers.iter_mut().filter(|&(_, ref p)| p.block_set == Some(block_set)) {
p.reset_asking();
}
}
/// Reset peer status after request is complete.
fn reset_peer_asking(&mut self, peer_id: PeerId, asking: PeerAsking) -> bool {
if let Some(ref mut peer) = self.peers.get_mut(&peer_id) {
peer.expired = false;
peer.block_set = None;
if peer.asking != asking {
trace!(target:"sync", "Asking {:?} while expected {:?}", peer.asking, asking);
peer.asking = PeerAsking::Nothing;
return false;
} else {
peer.asking = PeerAsking::Nothing;
return true;
}
}
false
}
/// Send Status message
fn send_status(&mut self, io: &mut SyncIo, peer: PeerId) -> Result<(), network::Error> {
let warp_protocol_version = io.protocol_version(&WARP_SYNC_PROTOCOL_ID, peer);
let warp_protocol = warp_protocol_version != 0;
let private_tx_protocol = warp_protocol_version >= PAR_PROTOCOL_VERSION_3.0;
let protocol = if warp_protocol { warp_protocol_version } else { ETH_PROTOCOL_VERSION_63.0 };
trace!(target: "sync", "Sending status to {}, protocol version {}", peer, protocol);
let mut packet = RlpStream::new();
packet.begin_unbounded_list();
let chain = io.chain().chain_info();
packet.append(&(protocol as u32));
packet.append(&self.network_id);
packet.append(&chain.total_difficulty);
packet.append(&chain.best_block_hash);
packet.append(&chain.genesis_hash);
if warp_protocol {
let manifest = io.snapshot_service().manifest();
let block_number = manifest.as_ref().map_or(0, |m| m.block_number);
let manifest_hash = manifest.map_or(H256::new(), |m| keccak(m.into_rlp()));
packet.append(&manifest_hash);
packet.append(&block_number);
if private_tx_protocol {
packet.append(&self.private_tx_handler.is_some());
}
}
packet.complete_unbounded_list();
io.respond(StatusPacket.id(), packet.out())
}
pub fn maintain_peers(&mut self, io: &mut SyncIo) {
let tick = Instant::now();
let mut aborting = Vec::new();
for (peer_id, peer) in &self.peers {
let elapsed = tick - peer.ask_time;
let timeout = match peer.asking {
PeerAsking::BlockHeaders => elapsed > HEADERS_TIMEOUT,
PeerAsking::BlockBodies => elapsed > BODIES_TIMEOUT,
PeerAsking::BlockReceipts => elapsed > RECEIPTS_TIMEOUT,
PeerAsking::Nothing => false,
PeerAsking::ForkHeader => elapsed > FORK_HEADER_TIMEOUT,
PeerAsking::SnapshotManifest => elapsed > SNAPSHOT_MANIFEST_TIMEOUT,
PeerAsking::SnapshotData => elapsed > SNAPSHOT_DATA_TIMEOUT,
};
if timeout {
debug!(target:"sync", "Timeout {}", peer_id);
io.disconnect_peer(*peer_id);
aborting.push(*peer_id);
}
}
for p in aborting {
SyncHandler::on_peer_aborting(self, io, p);
}
// Check for handshake timeouts
for (peer, &ask_time) in &self.handshaking_peers {
let elapsed = (tick - ask_time) / 1_000_000_000;
if elapsed > STATUS_TIMEOUT {
trace!(target:"sync", "Status timeout {}", peer);
io.disconnect_peer(*peer);
}
}
}
fn check_resume(&mut self, io: &mut SyncIo) {
match self.state {
SyncState::Waiting if !io.chain().queue_info().is_full() => {
self.state = SyncState::Blocks;
self.continue_sync(io);
},
SyncState::SnapshotData => match io.snapshot_service().status() {
RestorationStatus::Inactive | RestorationStatus::Failed => {
self.state = SyncState::SnapshotWaiting;
},
RestorationStatus::Initializing { .. } | RestorationStatus::Ongoing { .. } => (),
},
SyncState::SnapshotWaiting => {
match io.snapshot_service().status() {
RestorationStatus::Inactive => {
trace!(target:"sync", "Snapshot restoration is complete");
self.restart(io);
},
RestorationStatus::Initializing { .. } => {
trace!(target:"sync", "Snapshot restoration is initializing");
},
RestorationStatus::Ongoing { state_chunks_done, block_chunks_done, .. } => {
if !self.snapshot.is_complete() && self.snapshot.done_chunks() - (state_chunks_done + block_chunks_done) as usize <= MAX_SNAPSHOT_CHUNKS_DOWNLOAD_AHEAD {
trace!(target:"sync", "Resuming snapshot sync");
self.state = SyncState::SnapshotData;
self.continue_sync(io);
}
},
RestorationStatus::Failed => {
trace!(target: "sync", "Snapshot restoration aborted");
self.state = SyncState::WaitingPeers;
self.snapshot.clear();
self.continue_sync(io);
},
}
},
_ => (),
}
}
/// returns peer ids that have different block than our chain
fn get_lagging_peers(&self, chain_info: &BlockChainInfo) -> Vec {
self.get_peers(chain_info, PeerState::Lagging)
}
/// returns peer ids that have different or the same blocks than our chain
fn get_peers(&self, chain_info: &BlockChainInfo, peers: PeerState) -> Vec {
let latest_hash = chain_info.best_block_hash;
self
.peers
.iter()
.filter_map(|(&id, ref mut peer_info)| {
trace!(target: "sync", "Checking peer our best {} their best {}", latest_hash, peer_info.latest_hash);
let matches = match peers {
PeerState::Lagging => peer_info.latest_hash != latest_hash,
PeerState::SameBlock => peer_info.latest_hash == latest_hash,
};
if matches {
Some(id)
} else {
None
}
})
.collect::>()
}
fn get_consensus_peers(&self) -> Vec {
self.peers.iter().filter_map(|(id, p)| if p.protocol_version >= PAR_PROTOCOL_VERSION_2.0 { Some(*id) } else { None }).collect()
}
fn get_private_transaction_peers(&self, transaction_hash: &H256) -> Vec {
self.peers.iter().filter_map(
|(id, p)| if p.protocol_version >= PAR_PROTOCOL_VERSION_3.0
&& !p.last_sent_private_transactions.contains(transaction_hash)
&& p.private_tx_enabled {
Some(*id)
} else {
None
}
).collect()
}
/// Maintain other peers. Send out any new blocks and transactions
pub fn maintain_sync(&mut self, io: &mut SyncIo) {
self.maybe_start_snapshot_sync(io);
self.check_resume(io);
}
/// called when block is imported to chain - propagates the blocks and updates transactions sent to peers
pub fn chain_new_blocks(&mut self, io: &mut SyncIo, _imported: &[H256], invalid: &[H256], enacted: &[H256], _retracted: &[H256], sealed: &[H256], proposed: &[Bytes]) {
let queue_info = io.chain().queue_info();
let is_syncing = self.status().is_syncing(queue_info);
if !is_syncing || !sealed.is_empty() || !proposed.is_empty() {
trace!(target: "sync", "Propagating blocks, state={:?}", self.state);
SyncPropagator::propagate_latest_blocks(self, io, sealed);
SyncPropagator::propagate_proposed_blocks(self, io, proposed);
}
if !invalid.is_empty() {
trace!(target: "sync", "Bad blocks in the queue, restarting");
self.restart(io);
}
if !is_syncing && !enacted.is_empty() && !self.peers.is_empty() {
// Select random peer to re-broadcast transactions to.
let peer = random::new().gen_range(0, self.peers.len());
trace!(target: "sync", "Re-broadcasting transactions to a random peer.");
self.peers.values_mut().nth(peer).map(|peer_info| {
peer_info.last_sent_transactions.clear();
peer_info.reset_private_stats()
}
);
}
}
pub fn on_packet(&mut self, io: &mut SyncIo, peer: PeerId, packet_id: u8, data: &[u8]) {
SyncHandler::on_packet(self, io, peer, packet_id, data);
}
/// Called by peer when it is disconnecting
pub fn on_peer_aborting(&mut self, io: &mut SyncIo, peer: PeerId) {
SyncHandler::on_peer_aborting(self, io, peer);
}
/// Called when a new peer is connected
pub fn on_peer_connected(&mut self, io: &mut SyncIo, peer: PeerId) {
SyncHandler::on_peer_connected(self, io, peer);
}
/// propagates new transactions to all peers
pub fn propagate_new_transactions(&mut self, io: &mut SyncIo) {
let deadline = Instant::now() + Duration::from_millis(500);
SyncPropagator::propagate_new_transactions(self, io, || {
if deadline > Instant::now() {
true
} else {
debug!(target: "sync", "Wasn't able to finish transaction propagation within a deadline.");
false
}
});
}
/// Broadcast consensus message to peers.
pub fn propagate_consensus_packet(&mut self, io: &mut SyncIo, packet: Bytes) {
SyncPropagator::propagate_consensus_packet(self, io, packet);
}
/// Broadcast private transaction message to peers.
pub fn propagate_private_transaction(&mut self, io: &mut SyncIo, transaction_hash: H256, packet_id: SyncPacket, packet: Bytes) {
SyncPropagator::propagate_private_transaction(self, io, transaction_hash, packet_id, packet);
}
}
#[cfg(test)]
pub mod tests {
use std::collections::{VecDeque};
use ethkey;
use network::PeerId;
use tests::helpers::{TestIo};
use tests::snapshot::TestSnapshotService;
use ethereum_types::{H256, U256, Address};
use parking_lot::RwLock;
use bytes::Bytes;
use rlp::{Rlp, RlpStream};
use super::*;
use ::SyncConfig;
use super::{PeerInfo, PeerAsking};
use ethcore::client::{BlockChainClient, EachBlockWith, TestBlockChainClient, ChainInfo, BlockInfo};
use ethcore::miner::{MinerService, PendingOrdering};
use types::header::Header;
pub fn get_dummy_block(order: u32, parent_hash: H256) -> Bytes {
let mut header = Header::new();
header.set_gas_limit(0.into());
header.set_difficulty((order * 100).into());
header.set_timestamp((order * 10) as u64);
header.set_number(order as u64);
header.set_parent_hash(parent_hash);
header.set_state_root(H256::zero());
let mut rlp = RlpStream::new_list(3);
rlp.append(&header);
rlp.append_raw(&::rlp::EMPTY_LIST_RLP, 1);
rlp.append_raw(&::rlp::EMPTY_LIST_RLP, 1);
rlp.out()
}
pub fn get_dummy_blocks(order: u32, parent_hash: H256) -> Bytes {
let mut rlp = RlpStream::new_list(2);
rlp.append_raw(&get_dummy_block(order, parent_hash), 1);
let difficulty: U256 = (100 * order).into();
rlp.append(&difficulty);
rlp.out()
}
pub fn get_dummy_hashes() -> Bytes {
let mut rlp = RlpStream::new_list(5);
for _ in 0..5 {
let mut hash_d_rlp = RlpStream::new_list(2);
let hash: H256 = H256::from(0u64);
let diff: U256 = U256::from(1u64);
hash_d_rlp.append(&hash);
hash_d_rlp.append(&diff);
rlp.append_raw(&hash_d_rlp.out(), 1);
}
rlp.out()
}
fn queue_info(unverified: usize, verified: usize) -> BlockQueueInfo {
BlockQueueInfo {
unverified_queue_size: unverified,
verified_queue_size: verified,
verifying_queue_size: 0,
max_queue_size: 1000,
max_mem_use: 1000,
mem_used: 500
}
}
fn sync_status(state: SyncState) -> SyncStatus {
SyncStatus {
state: state,
protocol_version: 0,
network_id: 0,
start_block_number: 0,
last_imported_block_number: None,
highest_block_number: None,
blocks_total: 0,
blocks_received: 0,
num_peers: 0,
num_active_peers: 0,
mem_used: 0,
num_snapshot_chunks: 0,
snapshot_chunks_done: 0,
last_imported_old_block_number: None,
}
}
#[test]
fn is_still_verifying() {
assert!(!sync_status(SyncState::Idle).is_syncing(queue_info(2, 1)));
assert!(sync_status(SyncState::Idle).is_syncing(queue_info(2, 2)));
}
#[test]
fn is_synced_state() {
assert!(sync_status(SyncState::Blocks).is_syncing(queue_info(0, 0)));
assert!(!sync_status(SyncState::Idle).is_syncing(queue_info(0, 0)));
}
pub fn dummy_sync_with_peer(peer_latest_hash: H256, client: &BlockChainClient) -> ChainSync {
let mut sync = ChainSync::new(SyncConfig::default(), client, None);
insert_dummy_peer(&mut sync, 0, peer_latest_hash);
sync
}
pub fn insert_dummy_peer(sync: &mut ChainSync, peer_id: PeerId, peer_latest_hash: H256) {
sync.peers.insert(peer_id,
PeerInfo {
protocol_version: 0,
genesis: H256::zero(),
network_id: 0,
latest_hash: peer_latest_hash,
difficulty: None,
asking: PeerAsking::Nothing,
asking_blocks: Vec::new(),
asking_hash: None,
ask_time: Instant::now(),
last_sent_transactions: Default::default(),
last_sent_private_transactions: Default::default(),
expired: false,
private_tx_enabled: false,
confirmation: super::ForkConfirmation::Confirmed,
snapshot_number: None,
snapshot_hash: None,
asking_snapshot_data: None,
block_set: None,
client_version: ClientVersion::from(""),
});
}
#[test]
fn finds_lagging_peers() {
let mut client = TestBlockChainClient::new();
client.add_blocks(100, EachBlockWith::Uncle);
let sync = dummy_sync_with_peer(client.block_hash_delta_minus(10), &client);
let chain_info = client.chain_info();
let lagging_peers = sync.get_lagging_peers(&chain_info);
assert_eq!(1, lagging_peers.len());
}
#[test]
fn calculates_tree_for_lagging_peer() {
let mut client = TestBlockChainClient::new();
client.add_blocks(15, EachBlockWith::Uncle);
let start = client.block_hash_delta_minus(4);
let end = client.block_hash_delta_minus(2);
// wrong way end -> start, should be None
let rlp = ChainSync::create_new_hashes_rlp(&client, &end, &start);
assert!(rlp.is_none());
let rlp = ChainSync::create_new_hashes_rlp(&client, &start, &end).unwrap();
// size of three rlp encoded hash-difficulty
assert_eq!(107, rlp.len());
}
// idea is that what we produce when propagading latest hashes should be accepted in
// on_peer_new_hashes in our code as well
#[test]
fn hashes_rlp_mutually_acceptable() {
let mut client = TestBlockChainClient::new();
client.add_blocks(100, EachBlockWith::Uncle);
let queue = RwLock::new(VecDeque::new());
let mut sync = dummy_sync_with_peer(client.block_hash_delta_minus(5), &client);
let chain_info = client.chain_info();
let ss = TestSnapshotService::new();
let mut io = TestIo::new(&mut client, &ss, &queue, None);
let peers = sync.get_lagging_peers(&chain_info);
SyncPropagator::propagate_new_hashes(&mut sync, &chain_info, &mut io, &peers);
let data = &io.packets[0].data.clone();
let result = SyncHandler::on_peer_new_hashes(&mut sync, &mut io, 0, &Rlp::new(data));
assert!(result.is_ok());
}
// idea is that what we produce when propagading latest block should be accepted in
// on_peer_new_block in our code as well
#[test]
fn block_rlp_mutually_acceptable() {
let mut client = TestBlockChainClient::new();
client.add_blocks(100, EachBlockWith::Uncle);
let queue = RwLock::new(VecDeque::new());
let mut sync = dummy_sync_with_peer(client.block_hash_delta_minus(5), &client);
let chain_info = client.chain_info();
let ss = TestSnapshotService::new();
let mut io = TestIo::new(&mut client, &ss, &queue, None);
let peers = sync.get_lagging_peers(&chain_info);
SyncPropagator::propagate_blocks(&mut sync, &chain_info, &mut io, &[], &peers);
let data = &io.packets[0].data.clone();
let result = SyncHandler::on_peer_new_block(&mut sync, &mut io, 0, &Rlp::new(data));
assert!(result.is_ok());
}
#[test]
fn should_add_transactions_to_queue() {
fn sender(tx: &UnverifiedTransaction) -> Address {
ethkey::public_to_address(&tx.recover_public().unwrap())
}
// given
let mut client = TestBlockChainClient::new();
client.add_blocks(98, EachBlockWith::Uncle);
client.add_blocks(1, EachBlockWith::UncleAndTransaction);
client.add_blocks(1, EachBlockWith::Transaction);
let mut sync = dummy_sync_with_peer(client.block_hash_delta_minus(5), &client);
let good_blocks = vec![client.block_hash_delta_minus(2)];
let retracted_blocks = vec![client.block_hash_delta_minus(1)];
// Add some balance to clients and reset nonces
for h in &[good_blocks[0], retracted_blocks[0]] {
let block = client.block(BlockId::Hash(*h)).unwrap();
let sender = sender(&block.transactions()[0]);;
client.set_balance(sender, U256::from(10_000_000_000_000_000_000u64));
client.set_nonce(sender, U256::from(0));
}
// when
{
let queue = RwLock::new(VecDeque::new());
let ss = TestSnapshotService::new();
let mut io = TestIo::new(&mut client, &ss, &queue, None);
io.chain.miner.chain_new_blocks(io.chain, &[], &[], &[], &good_blocks, false);
sync.chain_new_blocks(&mut io, &[], &[], &[], &good_blocks, &[], &[]);
assert_eq!(io.chain.miner.ready_transactions(io.chain, 10, PendingOrdering::Priority).len(), 1);
}
// We need to update nonce status (because we say that the block has been imported)
for h in &[good_blocks[0]] {
let block = client.block(BlockId::Hash(*h)).unwrap();
client.set_nonce(sender(&block.transactions()[0]), U256::from(1));
}
{
let queue = RwLock::new(VecDeque::new());
let ss = TestSnapshotService::new();
let mut io = TestIo::new(&client, &ss, &queue, None);
io.chain.miner.chain_new_blocks(io.chain, &[], &[], &good_blocks, &retracted_blocks, false);
sync.chain_new_blocks(&mut io, &[], &[], &good_blocks, &retracted_blocks, &[], &[]);
}
// then
assert_eq!(client.miner.ready_transactions(&client, 10, PendingOrdering::Priority).len(), 1);
}
#[test]
fn should_not_add_transactions_to_queue_if_not_synced() {
// given
let mut client = TestBlockChainClient::new();
client.add_blocks(98, EachBlockWith::Uncle);
client.add_blocks(1, EachBlockWith::UncleAndTransaction);
client.add_blocks(1, EachBlockWith::Transaction);
let mut sync = dummy_sync_with_peer(client.block_hash_delta_minus(5), &client);
let good_blocks = vec![client.block_hash_delta_minus(2)];
let retracted_blocks = vec![client.block_hash_delta_minus(1)];
let queue = RwLock::new(VecDeque::new());
let ss = TestSnapshotService::new();
let mut io = TestIo::new(&mut client, &ss, &queue, None);
// when
sync.chain_new_blocks(&mut io, &[], &[], &[], &good_blocks, &[], &[]);
assert_eq!(io.chain.miner.queue_status().status.transaction_count, 0);
sync.chain_new_blocks(&mut io, &[], &[], &good_blocks, &retracted_blocks, &[], &[]);
// then
let status = io.chain.miner.queue_status();
assert_eq!(status.status.transaction_count, 0);
}
}