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4c651637f2bb36d26f9227235fb6ab230688e535
pezkuwi-subxt/substrate/client/network/src/protocol/sync.rs
T
cheme 4c651637f2 Inner hashing of value in state trie (runtime versioning). (#9732) 
* starting

* Updated from other branch.

* setting flag

* flag in storage struct

* fix flagging to access and insert.

* added todo to fix

* also missing serialize meta to storage proof

* extract meta.

* Isolate old trie layout.

* failing test that requires storing in meta when old hash scheme is used.

* old hash compatibility

* Db migrate.

* runing tests with both states when interesting.

* fix chain spec test with serde default.

* export state (missing trie function).

* Pending using new branch, lacking genericity on layout resolution.

* extract and set global meta

* Update to branch 4

* fix iterator with root flag (no longer insert node).

* fix trie root hashing of root

* complete basic backend.

* Remove old_hash meta from proof that do not use inner_hashing.

* fix trie test for empty (force layout on empty deltas).

* Root update fix.

* debug on meta

* Use trie key iteration that do not include value in proofs.

* switch default test ext to use inner hash.

* small integration test, and fix tx cache mgmt in ext.
test  failing

* Proof scenario at state-machine level.

* trace for db upgrade

* try different param

* act more like iter_from.

* Bigger batches.

* Update trie dependency.

* drafting codec changes and refact

* before removing unused branch no value alt hashing.
more work todo rename all flag var to alt_hash, and remove extrinsic
replace by storage query at every storage_root call.

* alt hashing only for branch with value.

* fix trie tests

* Hash of value include the encoded size.

* removing fields(broken)

* fix trie_stream to also include value length in inner hash.

* triedbmut only using alt type if inner hashing.

* trie_stream to also only use alt hashing type when actually alt hashing.

* Refactor meta state, logic should work with change of trie treshold.

* Remove NoMeta variant.

* Remove state_hashed trigger specific functions.

* pending switching to using threshold, new storage root api does not
make much sense.

* refactoring to use state from backend (not possible payload changes).

* Applying from previous state

* Remove default from storage, genesis need a special build.

* rem empty space

* Catch problem: when using triedb with default: we should not revert
nodes: otherwhise thing as trie codec cannot decode-encode without
changing state.

* fix compilation

* Right logic to avoid switch on reencode when default layout.

* Clean up some todos

* remove trie meta from root upstream

* update upstream and fix benches.

* split some long lines.

* UPdate trie crate to work with new design.

* Finish update to refactored upstream.

* update to latest triedb changes.

* Clean up.

* fix executor test.

* rust fmt from master.

* rust format.

* rustfmt

* fix

* start host function driven versioning

* update state-machine part

* still need access to state version from runtime

* state hash in mem: wrong

* direction likely correct, but passing call to code exec for genesis
init seem awkward.

* state version serialize in runtime, wrong approach, just initialize it
with no threshold for core api < 4 seems more proper.

* stateversion from runtime version (core api >= 4).

* update trie, fix tests

* unused import

* clean some TODOs

* Require RuntimeVersionOf for executor

* use RuntimeVersionOf to resolve genesis state version.

* update runtime version test

* fix state-machine tests

* TODO

* Use runtime version from storage wasm with fast sync.

* rustfmt

* fmt

* fix test

* revert useless changes.

* clean some unused changes

* fmt

* removing useless trait function.

* remove remaining reference to state_hash

* fix some imports

* Follow chain state version management.

* trie update, fix and constant threshold for trie layouts.

* update deps

* Update to latest trie pr changes.

* fix benches

* Verify proof requires right layout.

* update trie_root

* Update trie deps to  latest

* Update to latest trie versioning

* Removing patch

* update lock

* extrinsic for sc-service-test using layout v0.

* Adding RuntimeVersionOf to CallExecutor works.

* fmt

* error when resolving version and no wasm in storage.

* use existing utils to instantiate runtime code.

* Patch to delay runtime switch.

* Revert "Patch to delay runtime switch."

This reverts commit 67e55fee468f1a0cda853f5362b22e0d775786da.

* useless closure

* remove remaining state_hash variables.

* Remove outdated comment

* useless inner hash

* fmt

* fmt and opt-in feature to apply state change.

* feature gate core version, use new test feature for node and test node

* Use a 'State' api version instead of Core one.

* fix merge of test function

* use blake macro.

* Fix state api (require declaring the api in runtime).

* Opt out feature, fix macro for io to select a given version
instead of latest.

* run test nodes on new state.

* fix

* Apply review change (docs and error).

* fmt

* use explicit runtime_interface in doc test

* fix ui test

* fix doc test

* fmt

* use default for path and specname when resolving version.

* small review related changes.

* doc value size requirement.

* rename old_state feature

* Remove macro changes

* feature rename

* state version as host function parameter

* remove flag for client api

* fix tests

* switch storage chain proof to V1

* host functions, pass by state version enum

* use WrappedRuntimeCode

* start

* state_version in runtime version

* rust fmt

* Update storage proof of max size.

* fix runtime version rpc test

* right intent of convert from compat

* fix doc test

* fix doc test

* split proof

* decode without replay, and remove some reexports.

* Decode with compatibility by default.

* switch state_version to u8. And remove RuntimeVersionBasis.

* test

* use api when reading embedded version

* fix decode with apis

* extract core version instead

* test fix

* unused import

* review changes.

Co-authored-by: kianenigma <kian@parity.io>
2021-12-24 08:54:07 +00:00

3173 lines
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// This file is part of Substrate.
// Copyright (C) 2017-2021 Parity Technologies (UK) Ltd.
// SPDX-License-Identifier: GPL-3.0-or-later WITH Classpath-exception-2.0
// This program 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.
// This program 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 this program. If not, see <https://www.gnu.org/licenses/>.
//! Contains the state of the chain synchronization process
//!
//! At any given point in time, a running node tries as much as possible to be at the head of the
//! chain. This module handles the logic of which blocks to request from remotes, and processing
//! responses. It yields blocks to check and potentially move to the database.
//!
//! # Usage
//!
//! The `ChainSync` struct maintains the state of the block requests. Whenever something happens on
//! the network, or whenever a block has been successfully verified, call the appropriate method in
//! order to update it.
use crate::{
protocol::message::{self, BlockAnnounce, BlockAttributes, BlockRequest, BlockResponse},
schema::v1::{StateRequest, StateResponse},
};
use blocks::BlockCollection;
use codec::Encode;
use either::Either;
use extra_requests::ExtraRequests;
use futures::{stream::FuturesUnordered, task::Poll, Future, FutureExt, StreamExt};
use libp2p::PeerId;
use log::{debug, error, info, trace, warn};
use sc_consensus::{BlockImportError, BlockImportStatus, IncomingBlock};
use sp_arithmetic::traits::Saturating;
use sp_blockchain::{Error as ClientError, HeaderMetadata};
use sp_consensus::{
block_validation::{BlockAnnounceValidator, Validation},
BlockOrigin, BlockStatus,
};
use sp_runtime::{
generic::BlockId,
traits::{
Block as BlockT, CheckedSub, Hash, HashFor, Header as HeaderT, NumberFor, One,
SaturatedConversion, Zero,
},
EncodedJustification, Justifications,
};
use state::StateSync;
use std::{
collections::{hash_map::Entry, HashMap, HashSet},
fmt,
ops::Range,
pin::Pin,
sync::Arc,
};
use warp::{WarpProofRequest, WarpSync, WarpSyncProvider};
mod blocks;
mod extra_requests;
mod state;
mod warp;
/// Maximum blocks to request in a single packet.
const MAX_BLOCKS_TO_REQUEST: usize = 64;
/// Maximum blocks to store in the import queue.
const MAX_IMPORTING_BLOCKS: usize = 2048;
/// Maximum blocks to download ahead of any gap.
const MAX_DOWNLOAD_AHEAD: u32 = 2048;
/// Maximum blocks to look backwards. The gap is the difference between the highest block and the
/// common block of a node.
const MAX_BLOCKS_TO_LOOK_BACKWARDS: u32 = MAX_DOWNLOAD_AHEAD / 2;
/// Maximum number of concurrent block announce validations.
///
/// If the queue reaches the maximum, we drop any new block
/// announcements.
const MAX_CONCURRENT_BLOCK_ANNOUNCE_VALIDATIONS: usize = 256;
/// Maximum number of concurrent block announce validations per peer.
///
/// See [`MAX_CONCURRENT_BLOCK_ANNOUNCE_VALIDATIONS`] for more information.
const MAX_CONCURRENT_BLOCK_ANNOUNCE_VALIDATIONS_PER_PEER: usize = 4;
/// Pick the state to sync as the latest finalized number minus this.
const STATE_SYNC_FINALITY_THRESHOLD: u32 = 8;
/// We use a heuristic that with a high likelihood, by the time
/// `MAJOR_SYNC_BLOCKS` have been imported we'll be on the same
/// chain as (or at least closer to) the peer so we want to delay
/// the ancestor search to not waste time doing that when we are
/// so far behind.
const MAJOR_SYNC_BLOCKS: u8 = 5;
/// Number of peers that need to be connected before warp sync is started.
const MIN_PEERS_TO_START_WARP_SYNC: usize = 3;
mod rep {
use sc_peerset::ReputationChange as Rep;
/// Reputation change when a peer sent us a message that led to a
/// database read error.
pub const BLOCKCHAIN_READ_ERROR: Rep = Rep::new(-(1 << 16), "DB Error");
/// Reputation change when a peer sent us a status message with a different
/// genesis than us.
pub const GENESIS_MISMATCH: Rep = Rep::new(i32::MIN, "Genesis mismatch");
/// Reputation change for peers which send us a block with an incomplete header.
pub const INCOMPLETE_HEADER: Rep = Rep::new(-(1 << 20), "Incomplete header");
/// Reputation change for peers which send us a block which we fail to verify.
pub const VERIFICATION_FAIL: Rep = Rep::new(-(1 << 29), "Block verification failed");
/// Reputation change for peers which send us a known bad block.
pub const BAD_BLOCK: Rep = Rep::new(-(1 << 29), "Bad block");
/// Peer did not provide us with advertised block data.
pub const NO_BLOCK: Rep = Rep::new(-(1 << 29), "No requested block data");
/// Reputation change for peers which send us non-requested block data.
pub const NOT_REQUESTED: Rep = Rep::new(-(1 << 29), "Not requested block data");
/// Reputation change for peers which send us a block with bad justifications.
pub const BAD_JUSTIFICATION: Rep = Rep::new(-(1 << 16), "Bad justification");
/// Reputation change when a peer sent us invlid ancestry result.
pub const UNKNOWN_ANCESTOR: Rep = Rep::new(-(1 << 16), "DB Error");
/// Peer response data does not have requested bits.
pub const BAD_RESPONSE: Rep = Rep::new(-(1 << 12), "Incomplete response");
}
enum PendingRequests {
Some(HashSet<PeerId>),
All,
}
impl PendingRequests {
fn add(&mut self, id: &PeerId) {
if let Self::Some(ref mut set) = self {
set.insert(*id);
}
}
fn take(&mut self) -> Self {
std::mem::take(self)
}
fn set_all(&mut self) {
*self = Self::All;
}
fn contains(&self, id: &PeerId) -> bool {
match self {
Self::Some(set) => set.contains(id),
Self::All => true,
}
}
fn is_empty(&self) -> bool {
match self {
Self::Some(set) => set.is_empty(),
Self::All => false,
}
}
}
impl Default for PendingRequests {
fn default() -> Self {
Self::Some(HashSet::default())
}
}
struct GapSync<B: BlockT> {
blocks: BlockCollection<B>,
best_queued_number: NumberFor<B>,
target: NumberFor<B>,
}
/// The main data structure which contains all the state for a chains
/// active syncing strategy.
pub struct ChainSync<B: BlockT> {
/// Chain client.
client: Arc<dyn crate::chain::Client<B>>,
/// The active peers that we are using to sync and their PeerSync status
peers: HashMap<PeerId, PeerSync<B>>,
/// A `BlockCollection` of blocks that are being downloaded from peers
blocks: BlockCollection<B>,
/// The best block number in our queue of blocks to import
best_queued_number: NumberFor<B>,
/// The best block hash in our queue of blocks to import
best_queued_hash: B::Hash,
/// Current mode (full/light)
mode: SyncMode,
/// Any extra justification requests.
extra_justifications: ExtraRequests<B>,
/// A set of hashes of blocks that are being downloaded or have been
/// downloaded and are queued for import.
queue_blocks: HashSet<B::Hash>,
/// Fork sync targets.
fork_targets: HashMap<B::Hash, ForkTarget<B>>,
/// A set of peers for which there might be potential block requests
pending_requests: PendingRequests,
/// A type to check incoming block announcements.
block_announce_validator: Box<dyn BlockAnnounceValidator<B> + Send>,
/// Maximum number of peers to ask the same blocks in parallel.
max_parallel_downloads: u32,
/// Total number of downloaded blocks.
downloaded_blocks: usize,
/// All block announcement that are currently being validated.
block_announce_validation:
FuturesUnordered<Pin<Box<dyn Future<Output = PreValidateBlockAnnounce<B::Header>> + Send>>>,
/// Stats per peer about the number of concurrent block announce validations.
block_announce_validation_per_peer_stats: HashMap<PeerId, usize>,
/// State sync in progress, if any.
state_sync: Option<StateSync<B>>,
/// Warp sync in progress, if any.
warp_sync: Option<WarpSync<B>>,
/// Warp sync provider.
warp_sync_provider: Option<Arc<dyn WarpSyncProvider<B>>>,
/// Enable importing existing blocks. This is used used after the state download to
/// catch up to the latest state while re-importing blocks.
import_existing: bool,
/// Gap download process.
gap_sync: Option<GapSync<B>>,
}
/// All the data we have about a Peer that we are trying to sync with
#[derive(Debug, Clone)]
pub struct PeerSync<B: BlockT> {
/// Peer id of this peer.
pub peer_id: PeerId,
/// The common number is the block number that is a common point of
/// ancestry for both our chains (as far as we know).
pub common_number: NumberFor<B>,
/// The hash of the best block that we've seen for this peer.
pub best_hash: B::Hash,
/// The number of the best block that we've seen for this peer.
pub best_number: NumberFor<B>,
/// The state of syncing this peer is in for us, generally categories
/// into `Available` or "busy" with something as defined by `PeerSyncState`.
pub state: PeerSyncState<B>,
}
impl<B: BlockT> PeerSync<B> {
/// Update the `common_number` iff `new_common > common_number`.
fn update_common_number(&mut self, new_common: NumberFor<B>) {
if self.common_number < new_common {
trace!(
target: "sync",
"Updating peer {} common number from={} => to={}.",
self.peer_id,
self.common_number,
new_common,
);
self.common_number = new_common;
}
}
}
/// The sync status of a peer we are trying to sync with
#[derive(Debug)]
pub struct PeerInfo<B: BlockT> {
/// Their best block hash.
pub best_hash: B::Hash,
/// Their best block number.
pub best_number: NumberFor<B>,
}
struct ForkTarget<B: BlockT> {
number: NumberFor<B>,
parent_hash: Option<B::Hash>,
peers: HashSet<PeerId>,
}
/// The state of syncing between a Peer and ourselves.
///
/// Generally two categories, "busy" or `Available`. If busy, the enum
/// defines what we are busy with.
#[derive(Copy, Clone, Eq, PartialEq, Debug)]
pub enum PeerSyncState<B: BlockT> {
/// Available for sync requests.
Available,
/// Searching for ancestors the Peer has in common with us.
AncestorSearch { start: NumberFor<B>, current: NumberFor<B>, state: AncestorSearchState<B> },
/// Actively downloading new blocks, starting from the given Number.
DownloadingNew(NumberFor<B>),
/// Downloading a stale block with given Hash. Stale means that it is a
/// block with a number that is lower than our best number. It might be
/// from a fork and not necessarily already imported.
DownloadingStale(B::Hash),
/// Downloading justification for given block hash.
DownloadingJustification(B::Hash),
/// Downloading state.
DownloadingState,
/// Downloading warp proof.
DownloadingWarpProof,
/// Actively downloading block history after warp sync.
DownloadingGap(NumberFor<B>),
}
impl<B: BlockT> PeerSyncState<B> {
pub fn is_available(&self) -> bool {
matches!(self, Self::Available)
}
}
/// Reported sync state.
#[derive(Clone, Eq, PartialEq, Debug)]
pub enum SyncState {
/// Initial sync is complete, keep-up sync is active.
Idle,
/// Actively catching up with the chain.
Downloading,
}
/// Reported state download progress.
#[derive(Clone, Eq, PartialEq, Debug)]
pub struct StateDownloadProgress {
/// Estimated download percentage.
pub percentage: u32,
/// Total state size in bytes downloaded so far.
pub size: u64,
}
/// Reported warp sync phase.
#[derive(Clone, Eq, PartialEq, Debug)]
pub enum WarpSyncPhase<B: BlockT> {
/// Waiting for peers to connect.
AwaitingPeers,
/// Downloading and verifying grandpa warp proofs.
DownloadingWarpProofs,
/// Downloading state data.
DownloadingState,
/// Importing state.
ImportingState,
/// Downloading block history.
DownloadingBlocks(NumberFor<B>),
}
impl<B: BlockT> fmt::Display for WarpSyncPhase<B> {
fn fmt(&self, f: &mut fmt::Formatter) -> fmt::Result {
match self {
Self::AwaitingPeers => write!(f, "Waiting for peers"),
Self::DownloadingWarpProofs => write!(f, "Downloading finality proofs"),
Self::DownloadingState => write!(f, "Downloading state"),
Self::ImportingState => write!(f, "Importing state"),
Self::DownloadingBlocks(n) => write!(f, "Downloading block history (#{})", n),
}
}
}
/// Reported warp sync progress.
#[derive(Clone, Eq, PartialEq, Debug)]
pub struct WarpSyncProgress<B: BlockT> {
/// Estimated download percentage.
pub phase: WarpSyncPhase<B>,
/// Total bytes downloaded so far.
pub total_bytes: u64,
}
/// Syncing status and statistics.
#[derive(Clone)]
pub struct Status<B: BlockT> {
/// Current global sync state.
pub state: SyncState,
/// Target sync block number.
pub best_seen_block: Option<NumberFor<B>>,
/// Number of peers participating in syncing.
pub num_peers: u32,
/// Number of blocks queued for import
pub queued_blocks: u32,
/// State sync status in progress, if any.
pub state_sync: Option<StateDownloadProgress>,
/// Warp sync in progress, if any.
pub warp_sync: Option<WarpSyncProgress<B>>,
}
/// A peer did not behave as expected and should be reported.
#[derive(Debug, Clone, PartialEq, Eq)]
pub struct BadPeer(pub PeerId, pub sc_peerset::ReputationChange);
impl fmt::Display for BadPeer {
fn fmt(&self, f: &mut fmt::Formatter) -> fmt::Result {
write!(f, "Bad peer {}; Reputation change: {:?}", self.0, self.1)
}
}
impl std::error::Error for BadPeer {}
/// Result of [`ChainSync::on_block_data`].
#[derive(Debug, Clone, PartialEq, Eq)]
pub enum OnBlockData<B: BlockT> {
/// The block should be imported.
Import(BlockOrigin, Vec<IncomingBlock<B>>),
/// A new block request needs to be made to the given peer.
Request(PeerId, BlockRequest<B>),
}
impl<B: BlockT> OnBlockData<B> {
/// Returns `self` as request.
#[cfg(test)]
fn into_request(self) -> Option<(PeerId, BlockRequest<B>)> {
if let Self::Request(peer, req) = self {
Some((peer, req))
} else {
None
}
}
}
/// Result of [`ChainSync::on_state_data`].
#[derive(Debug)]
pub enum OnStateData<B: BlockT> {
/// The block and state that should be imported.
Import(BlockOrigin, IncomingBlock<B>),
/// A new state request needs to be made to the given peer.
Continue,
}
/// Result of [`ChainSync::poll_block_announce_validation`].
#[derive(Debug, Clone, PartialEq, Eq)]
pub enum PollBlockAnnounceValidation<H> {
/// The announcement failed at validation.
///
/// The peer reputation should be decreased.
Failure {
/// Who sent the processed block announcement?
who: PeerId,
/// Should the peer be disconnected?
disconnect: bool,
},
/// The announcement does not require further handling.
Nothing {
/// Who sent the processed block announcement?
who: PeerId,
/// Was this their new best block?
is_best: bool,
/// The announcement.
announce: BlockAnnounce<H>,
},
/// The announcement header should be imported.
ImportHeader {
/// Who sent the processed block announcement?
who: PeerId,
/// Was this their new best block?
is_best: bool,
/// The announcement.
announce: BlockAnnounce<H>,
},
/// The block announcement should be skipped.
Skip,
}
/// Result of [`ChainSync::block_announce_validation`].
#[derive(Debug, Clone, PartialEq, Eq)]
enum PreValidateBlockAnnounce<H> {
/// The announcement failed at validation.
///
/// The peer reputation should be decreased.
Failure {
/// Who sent the processed block announcement?
who: PeerId,
/// Should the peer be disconnected?
disconnect: bool,
},
/// The pre-validation was sucessful and the announcement should be
/// further processed.
Process {
/// Is this the new best block of the peer?
is_new_best: bool,
/// The id of the peer that send us the announcement.
who: PeerId,
/// The announcement.
announce: BlockAnnounce<H>,
},
/// The announcement validation returned an error.
///
/// An error means that *this* node failed to validate it because some internal error happened.
/// If the block announcement was invalid, [`Self::Failure`] is the correct variant to express
/// this.
Error { who: PeerId },
/// The block announcement should be skipped.
///
/// This should *only* be returned when there wasn't a slot registered
/// for this block announcement validation.
Skip,
}
/// Result of [`ChainSync::on_block_justification`].
#[derive(Debug, Clone, PartialEq, Eq)]
pub enum OnBlockJustification<B: BlockT> {
/// The justification needs no further handling.
Nothing,
/// The justification should be imported.
Import { peer: PeerId, hash: B::Hash, number: NumberFor<B>, justifications: Justifications },
}
/// Operation mode.
#[derive(Debug, PartialEq, Eq)]
pub enum SyncMode {
// Sync headers only
Light,
// Sync headers and block bodies
Full,
// Sync headers and the last finalied state
LightState { storage_chain_mode: bool, skip_proofs: bool },
// Warp sync mode.
Warp,
}
/// Result of [`ChainSync::has_slot_for_block_announce_validation`].
enum HasSlotForBlockAnnounceValidation {
/// Yes, there is a slot for the block announce validation.
Yes,
/// We reached the total maximum number of validation slots.
TotalMaximumSlotsReached,
/// We reached the maximum number of validation slots for the given peer.
MaximumPeerSlotsReached,
}
impl<B: BlockT> ChainSync<B> {
/// Create a new instance.
pub fn new(
mode: SyncMode,
client: Arc<dyn crate::chain::Client<B>>,
block_announce_validator: Box<dyn BlockAnnounceValidator<B> + Send>,
max_parallel_downloads: u32,
warp_sync_provider: Option<Arc<dyn WarpSyncProvider<B>>>,
) -> Result<Self, ClientError> {
let mut sync = Self {
client,
peers: HashMap::new(),
blocks: BlockCollection::new(),
best_queued_hash: Default::default(),
best_queued_number: Zero::zero(),
extra_justifications: ExtraRequests::new("justification"),
mode,
queue_blocks: Default::default(),
fork_targets: Default::default(),
pending_requests: Default::default(),
block_announce_validator,
max_parallel_downloads,
downloaded_blocks: 0,
block_announce_validation: Default::default(),
block_announce_validation_per_peer_stats: Default::default(),
state_sync: None,
warp_sync: None,
warp_sync_provider,
import_existing: false,
gap_sync: None,
};
sync.reset_sync_start_point()?;
Ok(sync)
}
fn required_block_attributes(&self) -> BlockAttributes {
match self.mode {
SyncMode::Full =>
BlockAttributes::HEADER | BlockAttributes::JUSTIFICATION | BlockAttributes::BODY,
SyncMode::Light => BlockAttributes::HEADER | BlockAttributes::JUSTIFICATION,
SyncMode::LightState { storage_chain_mode: false, .. } | SyncMode::Warp =>
BlockAttributes::HEADER | BlockAttributes::JUSTIFICATION | BlockAttributes::BODY,
SyncMode::LightState { storage_chain_mode: true, .. } =>
BlockAttributes::HEADER |
BlockAttributes::JUSTIFICATION |
BlockAttributes::INDEXED_BODY,
}
}
fn skip_execution(&self) -> bool {
match self.mode {
SyncMode::Full => false,
SyncMode::Light => true,
SyncMode::LightState { .. } => true,
SyncMode::Warp => true,
}
}
/// Returns the state of the sync of the given peer.
///
/// Returns `None` if the peer is unknown.
pub fn peer_info(&self, who: &PeerId) -> Option<PeerInfo<B>> {
self.peers
.get(who)
.map(|p| PeerInfo { best_hash: p.best_hash, best_number: p.best_number })
}
/// Returns the current sync status.
pub fn status(&self) -> Status<B> {
let best_seen = self.peers.values().map(|p| p.best_number).max();
let sync_state = if let Some(n) = best_seen {
// A chain is classified as downloading if the provided best block is
// more than `MAJOR_SYNC_BLOCKS` behind the best queued block.
if n > self.best_queued_number && n - self.best_queued_number > MAJOR_SYNC_BLOCKS.into()
{
SyncState::Downloading
} else {
SyncState::Idle
}
} else {
SyncState::Idle
};
let warp_sync_progress = match (&self.warp_sync, &self.mode, &self.gap_sync) {
(_, _, Some(gap_sync)) => Some(WarpSyncProgress {
phase: WarpSyncPhase::DownloadingBlocks(gap_sync.best_queued_number),
total_bytes: 0,
}),
(None, SyncMode::Warp, _) =>
Some(WarpSyncProgress { phase: WarpSyncPhase::AwaitingPeers, total_bytes: 0 }),
(Some(sync), _, _) => Some(sync.progress()),
_ => None,
};
Status {
state: sync_state,
best_seen_block: best_seen,
num_peers: self.peers.len() as u32,
queued_blocks: self.queue_blocks.len() as u32,
state_sync: self.state_sync.as_ref().map(|s| s.progress()),
warp_sync: warp_sync_progress,
}
}
/// Number of active forks requests. This includes
/// requests that are pending or could be issued right away.
pub fn num_sync_requests(&self) -> usize {
self.fork_targets
.values()
.filter(|f| f.number <= self.best_queued_number)
.count()
}
/// Number of downloaded blocks.
pub fn num_downloaded_blocks(&self) -> usize {
self.downloaded_blocks
}
/// Handle a new connected peer.
///
/// Call this method whenever we connect to a new peer.
pub fn new_peer(
&mut self,
who: PeerId,
best_hash: B::Hash,
best_number: NumberFor<B>,
) -> Result<Option<BlockRequest<B>>, BadPeer> {
// There is nothing sync can get from the node that has no blockchain data.
match self.block_status(&best_hash) {
Err(e) => {
debug!(target:"sync", "Error reading blockchain: {:?}", e);
Err(BadPeer(who, rep::BLOCKCHAIN_READ_ERROR))
},
Ok(BlockStatus::KnownBad) => {
info!("💔 New peer with known bad best block {} ({}).", best_hash, best_number);
Err(BadPeer(who, rep::BAD_BLOCK))
},
Ok(BlockStatus::Unknown) => {
if best_number.is_zero() {
info!("💔 New peer with unknown genesis hash {} ({}).", best_hash, best_number);
return Err(BadPeer(who, rep::GENESIS_MISMATCH))
}
// If there are more than `MAJOR_SYNC_BLOCKS` in the import queue then we have
// enough to do in the import queue that it's not worth kicking off
// an ancestor search, which is what we do in the next match case below.
if self.queue_blocks.len() > MAJOR_SYNC_BLOCKS.into() {
debug!(
target:"sync",
"New peer with unknown best hash {} ({}), assuming common block.",
self.best_queued_hash,
self.best_queued_number
);
self.peers.insert(
who.clone(),
PeerSync {
peer_id: who,
common_number: self.best_queued_number,
best_hash,
best_number,
state: PeerSyncState::Available,
},
);
return Ok(None)
}
// If we are at genesis, just start downloading.
let (state, req) = if self.best_queued_number.is_zero() {
debug!(
target:"sync",
"New peer with best hash {} ({}).",
best_hash,
best_number,
);
(PeerSyncState::Available, None)
} else {
let common_best = std::cmp::min(self.best_queued_number, best_number);
debug!(
target:"sync",
"New peer with unknown best hash {} ({}), searching for common ancestor.",
best_hash,
best_number
);
(
PeerSyncState::AncestorSearch {
current: common_best,
start: self.best_queued_number,
state: AncestorSearchState::ExponentialBackoff(One::one()),
},
Some(ancestry_request::<B>(common_best)),
)
};
self.pending_requests.add(&who);
self.peers.insert(
who,
PeerSync {
peer_id: who,
common_number: Zero::zero(),
best_hash,
best_number,
state,
},
);
if let SyncMode::Warp = &self.mode {
if self.peers.len() >= MIN_PEERS_TO_START_WARP_SYNC && self.warp_sync.is_none()
{
log::debug!(target: "sync", "Starting warp state sync.");
if let Some(provider) = &self.warp_sync_provider {
self.warp_sync =
Some(WarpSync::new(self.client.clone(), provider.clone()));
}
}
}
Ok(req)
},
Ok(BlockStatus::Queued) |
Ok(BlockStatus::InChainWithState) |
Ok(BlockStatus::InChainPruned) => {
debug!(
target: "sync",
"New peer with known best hash {} ({}).",
best_hash,
best_number,
);
self.peers.insert(
who,
PeerSync {
peer_id: who,
common_number: std::cmp::min(self.best_queued_number, best_number),
best_hash,
best_number,
state: PeerSyncState::Available,
},
);
self.pending_requests.add(&who);
Ok(None)
},
}
}
/// Signal that a new best block has been imported.
/// `ChainSync` state with that information.
pub fn update_chain_info(&mut self, best_hash: &B::Hash, best_number: NumberFor<B>) {
self.on_block_queued(best_hash, best_number);
}
/// Schedule a justification request for the given block.
pub fn request_justification(&mut self, hash: &B::Hash, number: NumberFor<B>) {
let client = &self.client;
self.extra_justifications
.schedule((*hash, number), |base, block| is_descendent_of(&**client, base, block))
}
/// Clear all pending justification requests.
pub fn clear_justification_requests(&mut self) {
self.extra_justifications.reset();
}
/// Request syncing for the given block from given set of peers.
// The implementation is similar to on_block_announce with unknown parent hash.
pub fn set_sync_fork_request(
&mut self,
mut peers: Vec<PeerId>,
hash: &B::Hash,
number: NumberFor<B>,
) {
if peers.is_empty() {
peers = self
.peers
.iter()
// Only request blocks from peers who are ahead or on a par.
.filter(|(_, peer)| peer.best_number >= number)
.map(|(id, _)| id.clone())
.collect();
debug!(
target: "sync",
"Explicit sync request for block {:?} with no peers specified. \
Syncing from these peers {:?} instead.",
hash, peers,
);
} else {
debug!(target: "sync", "Explicit sync request for block {:?} with {:?}", hash, peers);
}
if self.is_known(&hash) {
debug!(target: "sync", "Refusing to sync known hash {:?}", hash);
return
}
trace!(target: "sync", "Downloading requested old fork {:?}", hash);
for peer_id in &peers {
if let Some(peer) = self.peers.get_mut(peer_id) {
if let PeerSyncState::AncestorSearch { .. } = peer.state {
continue
}
if number > peer.best_number {
peer.best_number = number;
peer.best_hash = *hash;
}
self.pending_requests.add(peer_id);
}
}
self.fork_targets
.entry(*hash)
.or_insert_with(|| ForkTarget { number, peers: Default::default(), parent_hash: None })
.peers
.extend(peers);
}
/// Get an iterator over all scheduled justification requests.
pub fn justification_requests(
&mut self,
) -> impl Iterator<Item = (PeerId, BlockRequest<B>)> + '_ {
let peers = &mut self.peers;
let mut matcher = self.extra_justifications.matcher();
std::iter::from_fn(move || {
if let Some((peer, request)) = matcher.next(&peers) {
peers
.get_mut(&peer)
.expect(
"`Matcher::next` guarantees the `PeerId` comes from the given peers; qed",
)
.state = PeerSyncState::DownloadingJustification(request.0);
let req = message::generic::BlockRequest {
id: 0,
fields: BlockAttributes::JUSTIFICATION,
from: message::FromBlock::Hash(request.0),
to: None,
direction: message::Direction::Ascending,
max: Some(1),
};
Some((peer, req))
} else {
None
}
})
}
/// Get an iterator over all block requests of all peers.
pub fn block_requests(&mut self) -> impl Iterator<Item = (&PeerId, BlockRequest<B>)> + '_ {
if self.pending_requests.is_empty() ||
self.state_sync.is_some() ||
self.mode == SyncMode::Warp
{
return Either::Left(std::iter::empty())
}
if self.queue_blocks.len() > MAX_IMPORTING_BLOCKS {
trace!(target: "sync", "Too many blocks in the queue.");
return Either::Left(std::iter::empty())
}
let major_sync = self.status().state == SyncState::Downloading;
let attrs = self.required_block_attributes();
let blocks = &mut self.blocks;
let fork_targets = &mut self.fork_targets;
let last_finalized =
std::cmp::min(self.best_queued_number, self.client.info().finalized_number);
let best_queued = self.best_queued_number;
let client = &self.client;
let queue = &self.queue_blocks;
let pending_requests = self.pending_requests.take();
let max_parallel = if major_sync { 1 } else { self.max_parallel_downloads };
let gap_sync = &mut self.gap_sync;
let iter = self.peers.iter_mut().filter_map(move |(id, peer)| {
if !peer.state.is_available() || !pending_requests.contains(id) {
return None
}
// If our best queued is more than `MAX_BLOCKS_TO_LOOK_BACKWARDS` blocks away from the
// common number, the peer best number is higher than our best queued and the common
// number is smaller than the last finalized block number, we should do an ancestor
// search to find a better common block. If the queue is full we wait till all blocks
// are imported though.
if best_queued.saturating_sub(peer.common_number) > MAX_BLOCKS_TO_LOOK_BACKWARDS.into() &&
best_queued < peer.best_number &&
peer.common_number < last_finalized &&
queue.len() <= MAJOR_SYNC_BLOCKS.into()
{
trace!(
target: "sync",
"Peer {:?} common block {} too far behind of our best {}. Starting ancestry search.",
id,
peer.common_number,
best_queued,
);
let current = std::cmp::min(peer.best_number, best_queued);
peer.state = PeerSyncState::AncestorSearch {
current,
start: best_queued,
state: AncestorSearchState::ExponentialBackoff(One::one()),
};
Some((id, ancestry_request::<B>(current)))
} else if let Some((range, req)) = peer_block_request(
id,
peer,
blocks,
attrs,
max_parallel,
last_finalized,
best_queued,
) {
peer.state = PeerSyncState::DownloadingNew(range.start);
trace!(
target: "sync",
"New block request for {}, (best:{}, common:{}) {:?}",
id,
peer.best_number,
peer.common_number,
req,
);
Some((id, req))
} else if let Some((hash, req)) =
fork_sync_request(id, fork_targets, best_queued, last_finalized, attrs, |hash| {
if queue.contains(hash) {
BlockStatus::Queued
} else {
client.block_status(&BlockId::Hash(*hash)).unwrap_or(BlockStatus::Unknown)
}
}) {
trace!(target: "sync", "Downloading fork {:?} from {}", hash, id);
peer.state = PeerSyncState::DownloadingStale(hash);
Some((id, req))
} else if let Some((range, req)) = gap_sync.as_mut().and_then(|sync| {
peer_gap_block_request(
id,
peer,
&mut sync.blocks,
attrs,
sync.target,
sync.best_queued_number,
)
}) {
peer.state = PeerSyncState::DownloadingGap(range.start);
trace!(
target: "sync",
"New gap block request for {}, (best:{}, common:{}) {:?}",
id,
peer.best_number,
peer.common_number,
req,
);
Some((id, req))
} else {
None
}
});
Either::Right(iter)
}
/// Get a state request, if any.
pub fn state_request(&mut self) -> Option<(PeerId, StateRequest)> {
if self.peers.iter().any(|(_, peer)| peer.state == PeerSyncState::DownloadingState) {
// Only one pending state request is allowed.
return None
}
if let Some(sync) = &self.state_sync {
if sync.is_complete() {
return None
}
for (id, peer) in self.peers.iter_mut() {
if peer.state.is_available() && peer.common_number >= sync.target_block_num() {
peer.state = PeerSyncState::DownloadingState;
let request = sync.next_request();
trace!(target: "sync", "New StateRequest for {}: {:?}", id, request);
return Some((*id, request))
}
}
}
if let Some(sync) = &self.warp_sync {
if sync.is_complete() {
return None
}
if let (Some(request), Some(target)) =
(sync.next_state_request(), sync.target_block_number())
{
for (id, peer) in self.peers.iter_mut() {
if peer.state.is_available() && peer.best_number >= target {
trace!(target: "sync", "New StateRequest for {}: {:?}", id, request);
peer.state = PeerSyncState::DownloadingState;
return Some((*id, request))
}
}
}
}
None
}
/// Get a warp sync request, if any.
pub fn warp_sync_request(&mut self) -> Option<(PeerId, WarpProofRequest<B>)> {
if self
.peers
.iter()
.any(|(_, peer)| peer.state == PeerSyncState::DownloadingWarpProof)
{
// Only one pending state request is allowed.
return None
}
if let Some(sync) = &self.warp_sync {
if sync.is_complete() {
return None
}
if let Some(request) = sync.next_warp_poof_request() {
let mut targets: Vec<_> = self.peers.values().map(|p| p.best_number).collect();
if !targets.is_empty() {
targets.sort();
let median = targets[targets.len() / 2];
// Find a random peer that is synced as much as peer majority.
for (id, peer) in self.peers.iter_mut() {
if peer.state.is_available() && peer.best_number >= median {
trace!(target: "sync", "New WarpProofRequest for {}", id);
peer.state = PeerSyncState::DownloadingWarpProof;
return Some((*id, request))
}
}
}
}
}
None
}
/// Handle a response from the remote to a block request that we made.
///
/// `request` must be the original request that triggered `response`.
/// or `None` if data comes from the block announcement.
///
/// If this corresponds to a valid block, this outputs the block that
/// must be imported in the import queue.
pub fn on_block_data(
&mut self,
who: &PeerId,
request: Option<BlockRequest<B>>,
response: BlockResponse<B>,
) -> Result<OnBlockData<B>, BadPeer> {
self.downloaded_blocks += response.blocks.len();
let mut gap = false;
let new_blocks: Vec<IncomingBlock<B>> = if let Some(peer) = self.peers.get_mut(who) {
let mut blocks = response.blocks;
if request
.as_ref()
.map_or(false, |r| r.direction == message::Direction::Descending)
{
trace!(target: "sync", "Reversing incoming block list");
blocks.reverse()
}
self.pending_requests.add(who);
if let Some(request) = request {
match &mut peer.state {
PeerSyncState::DownloadingNew(_) => {
self.blocks.clear_peer_download(who);
peer.state = PeerSyncState::Available;
if let Some(start_block) =
validate_blocks::<B>(&blocks, who, Some(request))?
{
self.blocks.insert(start_block, blocks, who.clone());
}
self.drain_blocks()
},
PeerSyncState::DownloadingGap(start_block) => {
let start_block = *start_block;
peer.state = PeerSyncState::Available;
if let Some(gap_sync) = &mut self.gap_sync {
gap_sync.blocks.clear_peer_download(who);
validate_blocks::<B>(&blocks, who, Some(request))?;
gap_sync.blocks.insert(start_block, blocks, who.clone());
gap = true;
gap_sync
.blocks
.drain(gap_sync.best_queued_number + One::one())
.into_iter()
.map(|block_data| {
let justifications = block_data.block.justifications.or(
legacy_justification_mapping(
block_data.block.justification,
),
);
IncomingBlock {
hash: block_data.block.hash,
header: block_data.block.header,
body: block_data.block.body,
indexed_body: block_data.block.indexed_body,
justifications,
origin: block_data.origin,
allow_missing_state: true,
import_existing: self.import_existing,
skip_execution: true,
state: None,
}
})
.collect()
} else {
debug!(target: "sync", "Unexpected gap block response from {}", who);
return Err(BadPeer(who.clone(), rep::NO_BLOCK))
}
},
PeerSyncState::DownloadingStale(_) => {
peer.state = PeerSyncState::Available;
if blocks.is_empty() {
debug!(target: "sync", "Empty block response from {}", who);
return Err(BadPeer(*who, rep::NO_BLOCK))
}
validate_blocks::<B>(&blocks, who, Some(request))?;
blocks
.into_iter()
.map(|b| {
let justifications = b
.justifications
.or(legacy_justification_mapping(b.justification));
IncomingBlock {
hash: b.hash,
header: b.header,
body: b.body,
indexed_body: None,
justifications,
origin: Some(*who),
allow_missing_state: true,
import_existing: self.import_existing,
skip_execution: self.skip_execution(),
state: None,
}
})
.collect()
},
PeerSyncState::AncestorSearch { current, start, state } => {
let matching_hash = match (blocks.get(0), self.client.hash(*current)) {
(Some(block), Ok(maybe_our_block_hash)) => {
trace!(
target: "sync",
"Got ancestry block #{} ({}) from peer {}",
current,
block.hash,
who,
);
maybe_our_block_hash.filter(|x| x == &block.hash)
},
(None, _) => {
debug!(
target: "sync",
"Invalid response when searching for ancestor from {}",
who,
);
return Err(BadPeer(*who, rep::UNKNOWN_ANCESTOR))
},
(_, Err(e)) => {
info!(
target: "sync",
"❌ Error answering legitimate blockchain query: {:?}",
e,
);
return Err(BadPeer(*who, rep::BLOCKCHAIN_READ_ERROR))
},
};
if matching_hash.is_some() {
if *start < self.best_queued_number &&
self.best_queued_number <= peer.best_number
{
// We've made progress on this chain since the search was started.
// Opportunistically set common number to updated number
// instead of the one that started the search.
peer.common_number = self.best_queued_number;
} else if peer.common_number < *current {
peer.common_number = *current;
}
}
if matching_hash.is_none() && current.is_zero() {
trace!(target:"sync", "Ancestry search: genesis mismatch for peer {}", who);
return Err(BadPeer(*who, rep::GENESIS_MISMATCH))
}
if let Some((next_state, next_num)) =
handle_ancestor_search_state(state, *current, matching_hash.is_some())
{
peer.state = PeerSyncState::AncestorSearch {
current: next_num,
start: *start,
state: next_state,
};
return Ok(OnBlockData::Request(*who, ancestry_request::<B>(next_num)))
} else {
// Ancestry search is complete. Check if peer is on a stale fork unknown
// to us and add it to sync targets if necessary.
trace!(
target: "sync",
"Ancestry search complete. Ours={} ({}), Theirs={} ({}), Common={:?} ({})",
self.best_queued_hash,
self.best_queued_number,
peer.best_hash,
peer.best_number,
matching_hash,
peer.common_number,
);
if peer.common_number < peer.best_number &&
peer.best_number < self.best_queued_number
{
trace!(
target: "sync",
"Added fork target {} for {}",
peer.best_hash,
who,
);
self.fork_targets
.entry(peer.best_hash)
.or_insert_with(|| ForkTarget {
number: peer.best_number,
parent_hash: None,
peers: Default::default(),
})
.peers
.insert(*who);
}
peer.state = PeerSyncState::Available;
Vec::new()
}
},
PeerSyncState::Available |
PeerSyncState::DownloadingJustification(..) |
PeerSyncState::DownloadingState |
PeerSyncState::DownloadingWarpProof => Vec::new(),
}
} else {
// When request.is_none() this is a block announcement. Just accept blocks.
validate_blocks::<B>(&blocks, who, None)?;
blocks
.into_iter()
.map(|b| {
let justifications =
b.justifications.or(legacy_justification_mapping(b.justification));
IncomingBlock {
hash: b.hash,
header: b.header,
body: b.body,
indexed_body: None,
justifications,
origin: Some(*who),
allow_missing_state: true,
import_existing: false,
skip_execution: true,
state: None,
}
})
.collect()
}
} else {
// We don't know of this peer, so we also did not request anything from it.
return Err(BadPeer(*who, rep::NOT_REQUESTED))
};
Ok(self.validate_and_queue_blocks(new_blocks, gap))
}
/// Handle a response from the remote to a state request that we made.
///
/// Returns next request if any.
pub fn on_state_data(
&mut self,
who: &PeerId,
response: StateResponse,
) -> Result<OnStateData<B>, BadPeer> {
if let Some(peer) = self.peers.get_mut(&who) {
if let PeerSyncState::DownloadingState = peer.state {
peer.state = PeerSyncState::Available;
}
}
let import_result = if let Some(sync) = &mut self.state_sync {
debug!(
target: "sync",
"Importing state data from {} with {} keys, {} proof nodes.",
who,
response.entries.len(),
response.proof.len(),
);
sync.import(response)
} else if let Some(sync) = &mut self.warp_sync {
debug!(
target: "sync",
"Importing state data from {} with {} keys, {} proof nodes.",
who,
response.entries.len(),
response.proof.len(),
);
sync.import_state(response)
} else {
debug!(target: "sync", "Ignored obsolete state response from {}", who);
return Err(BadPeer(*who, rep::NOT_REQUESTED))
};
match import_result {
state::ImportResult::Import(hash, header, state) => {
let origin = BlockOrigin::NetworkInitialSync;
let block = IncomingBlock {
hash,
header: Some(header),
body: None,
indexed_body: None,
justifications: None,
origin: None,
allow_missing_state: true,
import_existing: true,
skip_execution: self.skip_execution(),
state: Some(state),
};
debug!(target: "sync", "State download is complete. Import is queued");
Ok(OnStateData::Import(origin, block))
},
state::ImportResult::Continue => Ok(OnStateData::Continue),
state::ImportResult::BadResponse => {
debug!(target: "sync", "Bad state data received from {}", who);
Err(BadPeer(*who, rep::BAD_BLOCK))
},
}
}
/// Handle a response from the remote to a warp proof request that we made.
///
/// Returns next request.
pub fn on_warp_sync_data(
&mut self,
who: &PeerId,
response: warp::EncodedProof,
) -> Result<(), BadPeer> {
if let Some(peer) = self.peers.get_mut(&who) {
if let PeerSyncState::DownloadingWarpProof = peer.state {
peer.state = PeerSyncState::Available;
}
}
let import_result = if let Some(sync) = &mut self.warp_sync {
debug!(
target: "sync",
"Importing warp proof data from {}, {} bytes.",
who,
response.0.len(),
);
sync.import_warp_proof(response)
} else {
debug!(target: "sync", "Ignored obsolete warp sync response from {}", who);
return Err(BadPeer(*who, rep::NOT_REQUESTED))
};
match import_result {
warp::WarpProofImportResult::Success => Ok(()),
warp::WarpProofImportResult::BadResponse => {
debug!(target: "sync", "Bad proof data received from {}", who);
Err(BadPeer(*who, rep::BAD_BLOCK))
},
}
}
fn validate_and_queue_blocks(
&mut self,
mut new_blocks: Vec<IncomingBlock<B>>,
gap: bool,
) -> OnBlockData<B> {
let orig_len = new_blocks.len();
new_blocks.retain(|b| !self.queue_blocks.contains(&b.hash));
if new_blocks.len() != orig_len {
debug!(
target: "sync",
"Ignoring {} blocks that are already queued",
orig_len - new_blocks.len(),
);
}
let origin = if !gap && self.status().state != SyncState::Downloading {
BlockOrigin::NetworkBroadcast
} else {
BlockOrigin::NetworkInitialSync
};
if let Some((h, n)) = new_blocks
.last()
.and_then(|b| b.header.as_ref().map(|h| (&b.hash, *h.number())))
{
trace!(
target:"sync",
"Accepted {} blocks ({:?}) with origin {:?}",
new_blocks.len(),
h,
origin,
);
self.on_block_queued(h, n)
}
self.queue_blocks.extend(new_blocks.iter().map(|b| b.hash));
OnBlockData::Import(origin, new_blocks)
}
/// Handle a response from the remote to a justification request that we made.
///
/// `request` must be the original request that triggered `response`.
///
/// Returns `Some` if this produces a justification that must be imported
/// into the import queue.
pub fn on_block_justification(
&mut self,
who: PeerId,
response: BlockResponse<B>,
) -> Result<OnBlockJustification<B>, BadPeer> {
let peer = if let Some(peer) = self.peers.get_mut(&who) {
peer
} else {
error!(target: "sync", "💔 Called on_block_justification with a bad peer ID");
return Ok(OnBlockJustification::Nothing)
};
self.pending_requests.add(&who);
if let PeerSyncState::DownloadingJustification(hash) = peer.state {
peer.state = PeerSyncState::Available;
// We only request one justification at a time
let justification = if let Some(block) = response.blocks.into_iter().next() {
if hash != block.hash {
warn!(
target: "sync",
"💔 Invalid block justification provided by {}: requested: {:?} got: {:?}",
who,
hash,
block.hash,
);
return Err(BadPeer(who, rep::BAD_JUSTIFICATION))
}
block.justifications.or(legacy_justification_mapping(block.justification))
} else {
// we might have asked the peer for a justification on a block that we assumed it
// had but didn't (regardless of whether it had a justification for it or not).
trace!(
target: "sync",
"Peer {:?} provided empty response for justification request {:?}",
who,
hash,
);
None
};
if let Some((peer, hash, number, j)) =
self.extra_justifications.on_response(who, justification)
{
return Ok(OnBlockJustification::Import { peer, hash, number, justifications: j })
}
}
Ok(OnBlockJustification::Nothing)
}
/// A batch of blocks have been processed, with or without errors.
///
/// Call this when a batch of blocks have been processed by the import
/// queue, with or without errors.
///
/// `peer_info` is passed in case of a restart.
pub fn on_blocks_processed<'a>(
&'a mut self,
imported: usize,
count: usize,
results: Vec<(Result<BlockImportStatus<NumberFor<B>>, BlockImportError>, B::Hash)>,
) -> impl Iterator<Item = Result<(PeerId, BlockRequest<B>), BadPeer>> + 'a {
trace!(target: "sync", "Imported {} of {}", imported, count);
let mut output = Vec::new();
let mut has_error = false;
for (_, hash) in &results {
self.queue_blocks.remove(&hash);
}
for (result, hash) in results {
if has_error {
continue
}
if result.is_err() {
has_error = true;
}
match result {
Ok(BlockImportStatus::ImportedKnown(number, who)) => {
if let Some(peer) = who.and_then(|p| self.peers.get_mut(&p)) {
peer.update_common_number(number);
}
},
Ok(BlockImportStatus::ImportedUnknown(number, aux, who)) => {
if aux.clear_justification_requests {
trace!(
target: "sync",
"Block imported clears all pending justification requests {}: {:?}",
number,
hash,
);
self.clear_justification_requests();
}
if aux.needs_justification {
trace!(
target: "sync",
"Block imported but requires justification {}: {:?}",
number,
hash,
);
self.request_justification(&hash, number);
}
if aux.bad_justification {
if let Some(ref peer) = who {
warn!("💔 Sent block with bad justification to import");
output.push(Err(BadPeer(*peer, rep::BAD_JUSTIFICATION)));
}
}
if let Some(peer) = who.and_then(|p| self.peers.get_mut(&p)) {
peer.update_common_number(number);
}
let state_sync_complete =
self.state_sync.as_ref().map_or(false, |s| s.target() == hash);
if state_sync_complete {
info!(
target: "sync",
"State sync is complete ({} MiB), restarting block sync.",
self.state_sync.as_ref().map_or(0, |s| s.progress().size / (1024 * 1024)),
);
self.state_sync = None;
self.mode = SyncMode::Full;
output.extend(self.restart());
}
let warp_sync_complete = self
.warp_sync
.as_ref()
.map_or(false, |s| s.target_block_hash() == Some(hash));
if warp_sync_complete {
info!(
target: "sync",
"Warp sync is complete ({} MiB), restarting block sync.",
self.warp_sync.as_ref().map_or(0, |s| s.progress().total_bytes / (1024 * 1024)),
);
self.warp_sync = None;
self.mode = SyncMode::Full;
output.extend(self.restart());
}
let gap_sync_complete =
self.gap_sync.as_ref().map_or(false, |s| s.target == number);
if gap_sync_complete {
info!(
target: "sync",
"Block history download is complete."
);
self.gap_sync = None;
}
},
Err(BlockImportError::IncompleteHeader(who)) =>
if let Some(peer) = who {
warn!(
target: "sync",
"💔 Peer sent block with incomplete header to import",
);
output.push(Err(BadPeer(peer, rep::INCOMPLETE_HEADER)));
output.extend(self.restart());
},
Err(BlockImportError::VerificationFailed(who, e)) =>
if let Some(peer) = who {
warn!(
target: "sync",
"💔 Verification failed for block {:?} received from peer: {}, {:?}",
hash,
peer,
e,
);
output.push(Err(BadPeer(peer, rep::VERIFICATION_FAIL)));
output.extend(self.restart());
},
Err(BlockImportError::BadBlock(who)) =>
if let Some(peer) = who {
warn!(
target: "sync",
"💔 Block {:?} received from peer {} has been blacklisted",
hash,
peer,
);
output.push(Err(BadPeer(peer, rep::BAD_BLOCK)));
},
Err(BlockImportError::MissingState) => {
// This may happen if the chain we were requesting upon has been discarded
// in the meantime because other chain has been finalized.
// Don't mark it as bad as it still may be synced if explicitly requested.
trace!(target: "sync", "Obsolete block {:?}", hash);
},
e @ Err(BlockImportError::UnknownParent) | e @ Err(BlockImportError::Other(_)) => {
warn!(target: "sync", "💔 Error importing block {:?}: {:?}", hash, e);
self.state_sync = None;
self.warp_sync = None;
output.extend(self.restart());
},
Err(BlockImportError::Cancelled) => {},
};
}
self.pending_requests.set_all();
output.into_iter()
}
/// Call this when a justification has been processed by the import queue,
/// with or without errors.
pub fn on_justification_import(&mut self, hash: B::Hash, number: NumberFor<B>, success: bool) {
let finalization_result = if success { Ok((hash, number)) } else { Err(()) };
self.extra_justifications
.try_finalize_root((hash, number), finalization_result, true);
self.pending_requests.set_all();
}
/// Notify about finalization of the given block.
pub fn on_block_finalized(&mut self, hash: &B::Hash, number: NumberFor<B>) {
let client = &self.client;
let r = self.extra_justifications.on_block_finalized(hash, number, |base, block| {
is_descendent_of(&**client, base, block)
});
if let SyncMode::LightState { skip_proofs, .. } = &self.mode {
if self.state_sync.is_none() && !self.peers.is_empty() && self.queue_blocks.is_empty() {
// Finalized a recent block.
let mut heads: Vec<_> =
self.peers.iter().map(|(_, peer)| peer.best_number).collect();
heads.sort();
let median = heads[heads.len() / 2];
if number + STATE_SYNC_FINALITY_THRESHOLD.saturated_into() >= median {
if let Ok(Some(header)) = self.client.header(BlockId::hash(hash.clone())) {
log::debug!(
target: "sync",
"Starting state sync for #{} ({})",
number,
hash,
);
self.state_sync =
Some(StateSync::new(self.client.clone(), header, *skip_proofs));
}
}
}
}
if let Err(err) = r {
warn!(
target: "sync",
"💔 Error cleaning up pending extra justification data requests: {:?}",
err,
);
}
}
/// Called when a block has been queued for import.
///
/// Updates our internal state for best queued block and then goes
/// through all peers to update our view of their state as well.
fn on_block_queued(&mut self, hash: &B::Hash, number: NumberFor<B>) {
if self.fork_targets.remove(&hash).is_some() {
trace!(target: "sync", "Completed fork sync {:?}", hash);
}
if let Some(gap_sync) = &mut self.gap_sync {
if number > gap_sync.best_queued_number && number <= gap_sync.target {
gap_sync.best_queued_number = number;
}
}
if number > self.best_queued_number {
self.best_queued_number = number;
self.best_queued_hash = *hash;
// Update common blocks
for (n, peer) in self.peers.iter_mut() {
if let PeerSyncState::AncestorSearch { .. } = peer.state {
// Wait for ancestry search to complete first.
continue
}
let new_common_number =
if peer.best_number >= number { number } else { peer.best_number };
trace!(
target: "sync",
"Updating peer {} info, ours={}, common={}->{}, their best={}",
n,
number,
peer.common_number,
new_common_number,
peer.best_number,
);
peer.common_number = new_common_number;
}
}
self.pending_requests.set_all();
}
/// Checks if there is a slot for a block announce validation.
///
/// The total number and the number per peer of concurrent block announce validations
/// is capped.
///
/// Returns [`HasSlotForBlockAnnounceValidation`] to inform about the result.
///
/// # Note
///
/// It is *required* to call [`Self::peer_block_announce_validation_finished`] when the
/// validation is finished to clear the slot.
fn has_slot_for_block_announce_validation(
&mut self,
peer: &PeerId,
) -> HasSlotForBlockAnnounceValidation {
if self.block_announce_validation.len() >= MAX_CONCURRENT_BLOCK_ANNOUNCE_VALIDATIONS {
return HasSlotForBlockAnnounceValidation::TotalMaximumSlotsReached
}
match self.block_announce_validation_per_peer_stats.entry(peer.clone()) {
Entry::Vacant(entry) => {
entry.insert(1);
HasSlotForBlockAnnounceValidation::Yes
},
Entry::Occupied(mut entry) => {
if *entry.get() < MAX_CONCURRENT_BLOCK_ANNOUNCE_VALIDATIONS_PER_PEER {
*entry.get_mut() += 1;
HasSlotForBlockAnnounceValidation::Yes
} else {
HasSlotForBlockAnnounceValidation::MaximumPeerSlotsReached
}
},
}
}
/// Push a block announce validation.
///
/// It is required that [`ChainSync::poll_block_announce_validation`] is called
/// to check for finished block announce validations.
pub fn push_block_announce_validation(
&mut self,
who: PeerId,
hash: B::Hash,
announce: BlockAnnounce<B::Header>,
is_best: bool,
) {
let header = &announce.header;
let number = *header.number();
debug!(
target: "sync",
"Pre-validating received block announcement {:?} with number {:?} from {}",
hash,
number,
who,
);
if number.is_zero() {
self.block_announce_validation.push(
async move {
warn!(
target: "sync",
"💔 Ignored genesis block (#0) announcement from {}: {}",
who,
hash,
);
PreValidateBlockAnnounce::Skip
}
.boxed(),
);
return
}
// Check if there is a slot for this block announce validation.
match self.has_slot_for_block_announce_validation(&who) {
HasSlotForBlockAnnounceValidation::Yes => {},
HasSlotForBlockAnnounceValidation::TotalMaximumSlotsReached => {
self.block_announce_validation.push(
async move {
warn!(
target: "sync",
"💔 Ignored block (#{} -- {}) announcement from {} because all validation slots are occupied.",
number,
hash,
who,
);
PreValidateBlockAnnounce::Skip
}
.boxed(),
);
return
},
HasSlotForBlockAnnounceValidation::MaximumPeerSlotsReached => {
self.block_announce_validation.push(async move {
warn!(
target: "sync",
"💔 Ignored block (#{} -- {}) announcement from {} because all validation slots for this peer are occupied.",
number,
hash,
who,
);
PreValidateBlockAnnounce::Skip
}.boxed());
return
},
}
// Let external validator check the block announcement.
let assoc_data = announce.data.as_ref().map_or(&[][..], |v| v.as_slice());
let future = self.block_announce_validator.validate(&header, assoc_data);
let hash = hash.clone();
self.block_announce_validation.push(
async move {
match future.await {
Ok(Validation::Success { is_new_best }) => PreValidateBlockAnnounce::Process {
is_new_best: is_new_best || is_best,
announce,
who,
},
Ok(Validation::Failure { disconnect }) => {
debug!(
target: "sync",
"Block announcement validation of block {:?} from {} failed",
hash,
who,
);
PreValidateBlockAnnounce::Failure { who, disconnect }
},
Err(e) => {
debug!(
target: "sync",
"💔 Block announcement validation of block {:?} errored: {}",
hash,
e,
);
PreValidateBlockAnnounce::Error { who }
},
}
}
.boxed(),
);
}
/// Poll block announce validation.
///
/// Block announce validations can be pushed by using
/// [`ChainSync::push_block_announce_validation`].
///
/// This should be polled until it returns [`Poll::Pending`].
///
/// If [`PollBlockAnnounceValidation::ImportHeader`] is returned, then the caller MUST try to
/// import passed header (call `on_block_data`). The network request isn't sent in this case.
pub fn poll_block_announce_validation(
&mut self,
cx: &mut std::task::Context,
) -> Poll<PollBlockAnnounceValidation<B::Header>> {
match self.block_announce_validation.poll_next_unpin(cx) {
Poll::Ready(Some(res)) => {
self.peer_block_announce_validation_finished(&res);
Poll::Ready(self.finish_block_announce_validation(res))
},
_ => Poll::Pending,
}
}
/// Should be called when a block announce validation is finished, to update the slots
/// of the peer that send the block announce.
fn peer_block_announce_validation_finished(
&mut self,
res: &PreValidateBlockAnnounce<B::Header>,
) {
let peer = match res {
PreValidateBlockAnnounce::Failure { who, .. } |
PreValidateBlockAnnounce::Process { who, .. } |
PreValidateBlockAnnounce::Error { who } => who,
PreValidateBlockAnnounce::Skip => return,
};
match self.block_announce_validation_per_peer_stats.entry(peer.clone()) {
Entry::Vacant(_) => {
error!(
target: "sync",
"💔 Block announcement validation from peer {} finished for that no slot was allocated!",
peer,
);
},
Entry::Occupied(mut entry) => {
*entry.get_mut() = entry.get().saturating_sub(1);
if *entry.get() == 0 {
entry.remove();
}
},
}
}
/// This will finish processing of the block announcement.
fn finish_block_announce_validation(
&mut self,
pre_validation_result: PreValidateBlockAnnounce<B::Header>,
) -> PollBlockAnnounceValidation<B::Header> {
let (announce, is_best, who) = match pre_validation_result {
PreValidateBlockAnnounce::Failure { who, disconnect } => {
debug!(
target: "sync",
"Failed announce validation: {:?}, disconnect: {}",
who,
disconnect,
);
return PollBlockAnnounceValidation::Failure { who, disconnect }
},
PreValidateBlockAnnounce::Process { announce, is_new_best, who } =>
(announce, is_new_best, who),
PreValidateBlockAnnounce::Error { .. } | PreValidateBlockAnnounce::Skip => {
debug!(
target: "sync",
"Ignored announce validation",
);
return PollBlockAnnounceValidation::Skip
},
};
trace!(
target: "sync",
"Finished block announce validation: from {:?}: {:?}. local_best={}",
who,
announce.summary(),
is_best,
);
let number = *announce.header.number();
let hash = announce.header.hash();
let parent_status =
self.block_status(announce.header.parent_hash()).unwrap_or(BlockStatus::Unknown);
let known_parent = parent_status != BlockStatus::Unknown;
let ancient_parent = parent_status == BlockStatus::InChainPruned;
let known = self.is_known(&hash);
let peer = if let Some(peer) = self.peers.get_mut(&who) {
peer
} else {
error!(target: "sync", "💔 Called on_block_announce with a bad peer ID");
return PollBlockAnnounceValidation::Nothing { is_best, who, announce }
};
if is_best {
// update their best block
peer.best_number = number;
peer.best_hash = hash;
}
if let PeerSyncState::AncestorSearch { .. } = peer.state {
trace!(target: "sync", "Peer state is ancestor search.");
return PollBlockAnnounceValidation::Nothing { is_best, who, announce }
}
// If the announced block is the best they have and is not ahead of us, our common number
// is either one further ahead or it's the one they just announced, if we know about it.
if is_best {
if known && self.best_queued_number >= number {
peer.update_common_number(number);
} else if announce.header.parent_hash() == &self.best_queued_hash ||
known_parent && self.best_queued_number >= number
{
peer.update_common_number(number - One::one());
}
}
self.pending_requests.add(&who);
// known block case
if known || self.is_already_downloading(&hash) {
trace!(target: "sync", "Known block announce from {}: {}", who, hash);
if let Some(target) = self.fork_targets.get_mut(&hash) {
target.peers.insert(who.clone());
}
return PollBlockAnnounceValidation::Nothing { is_best, who, announce }
}
if ancient_parent {
trace!(
target: "sync",
"Ignored ancient block announced from {}: {} {:?}",
who,
hash,
announce.header,
);
return PollBlockAnnounceValidation::Nothing { is_best, who, announce }
}
let requires_additional_data = self.mode != SyncMode::Light || !known_parent;
if !requires_additional_data {
trace!(
target: "sync",
"Importing new header announced from {}: {} {:?}",
who,
hash,
announce.header,
);
return PollBlockAnnounceValidation::ImportHeader { is_best, announce, who }
}
if self.status().state == SyncState::Idle {
trace!(
target: "sync",
"Added sync target for block announced from {}: {} {:?}",
who,
hash,
announce.summary(),
);
self.fork_targets
.entry(hash)
.or_insert_with(|| ForkTarget {
number,
parent_hash: Some(*announce.header.parent_hash()),
peers: Default::default(),
})
.peers
.insert(who);
}
PollBlockAnnounceValidation::Nothing { is_best, who, announce }
}
/// Call when a peer has disconnected.
/// Canceled obsolete block request may result in some blocks being ready for
/// import, so this functions checks for such blocks and returns them.
pub fn peer_disconnected(&mut self, who: &PeerId) -> Option<OnBlockData<B>> {
self.blocks.clear_peer_download(who);
if let Some(gap_sync) = &mut self.gap_sync {
gap_sync.blocks.clear_peer_download(who)
}
self.peers.remove(who);
self.extra_justifications.peer_disconnected(who);
self.pending_requests.set_all();
self.fork_targets.retain(|_, target| {
target.peers.remove(who);
!target.peers.is_empty()
});
let blocks = self.drain_blocks();
if !blocks.is_empty() {
Some(self.validate_and_queue_blocks(blocks, false))
} else {
None
}
}
/// Restart the sync process. This will reset all pending block requests and return an iterator
/// of new block requests to make to peers. Peers that were downloading finality data (i.e.
/// their state was `DownloadingJustification`) are unaffected and will stay in the same state.
fn restart<'a>(
&'a mut self,
) -> impl Iterator<Item = Result<(PeerId, BlockRequest<B>), BadPeer>> + 'a {
self.blocks.clear();
if let Err(e) = self.reset_sync_start_point() {
warn!(target: "sync", "💔 Unable to restart sync. :{:?}", e);
}
self.pending_requests.set_all();
debug!(target:"sync", "Restarted with {} ({})", self.best_queued_number, self.best_queued_hash);
let old_peers = std::mem::take(&mut self.peers);
old_peers.into_iter().filter_map(move |(id, mut p)| {
// peers that were downloading justifications
// should be kept in that state.
match p.state {
PeerSyncState::DownloadingJustification(_) => {
// We make sure our commmon number is at least something we have.
p.common_number = self.best_queued_number;
self.peers.insert(id, p);
return None
},
_ => {},
}
// handle peers that were in other states.
match self.new_peer(id.clone(), p.best_hash, p.best_number) {
Ok(None) => None,
Ok(Some(x)) => Some(Ok((id, x))),
Err(e) => Some(Err(e)),
}
})
}
/// Find a block to start sync from. If we sync with state, that's the latest block we have
/// state for.
fn reset_sync_start_point(&mut self) -> Result<(), ClientError> {
let info = self.client.info();
if matches!(self.mode, SyncMode::LightState { .. }) && info.finalized_state.is_some() {
warn!(
target: "sync",
"Can't use fast sync mode with a partially synced database. Reverting to full sync mode."
);
self.mode = SyncMode::Full;
}
if matches!(self.mode, SyncMode::Warp) && info.finalized_state.is_some() {
warn!(
target: "sync",
"Can't use warp sync mode with a partially synced database. Reverting to full sync mode."
);
self.mode = SyncMode::Full;
}
self.import_existing = false;
self.best_queued_hash = info.best_hash;
self.best_queued_number = info.best_number;
if self.mode == SyncMode::Full {
if self.client.block_status(&BlockId::hash(info.best_hash))? !=
BlockStatus::InChainWithState
{
self.import_existing = true;
// Latest state is missing, start with the last finalized state or genesis instead.
if let Some((hash, number)) = info.finalized_state {
debug!(target: "sync", "Starting from finalized state #{}", number);
self.best_queued_hash = hash;
self.best_queued_number = number;
} else {
debug!(target: "sync", "Restarting from genesis");
self.best_queued_hash = Default::default();
self.best_queued_number = Zero::zero();
}
}
}
if let Some((start, end)) = info.block_gap {
debug!(target: "sync", "Starting gap sync #{} - #{}", start, end);
self.gap_sync = Some(GapSync {
best_queued_number: start - One::one(),
target: end,
blocks: BlockCollection::new(),
});
}
trace!(target: "sync", "Restarted sync at #{} ({:?})", self.best_queued_number, self.best_queued_hash);
Ok(())
}
/// What is the status of the block corresponding to the given hash?
fn block_status(&self, hash: &B::Hash) -> Result<BlockStatus, ClientError> {
if self.queue_blocks.contains(hash) {
return Ok(BlockStatus::Queued)
}
self.client.block_status(&BlockId::Hash(*hash))
}
/// Is the block corresponding to the given hash known?
fn is_known(&self, hash: &B::Hash) -> bool {
self.block_status(hash).ok().map_or(false, |s| s != BlockStatus::Unknown)
}
/// Is any peer downloading the given hash?
fn is_already_downloading(&self, hash: &B::Hash) -> bool {
self.peers
.iter()
.any(|(_, p)| p.state == PeerSyncState::DownloadingStale(*hash))
}
/// Return some key metrics.
pub(crate) fn metrics(&self) -> Metrics {
Metrics {
queued_blocks: self.queue_blocks.len().try_into().unwrap_or(std::u32::MAX),
fork_targets: self.fork_targets.len().try_into().unwrap_or(std::u32::MAX),
justifications: self.extra_justifications.metrics(),
_priv: (),
}
}
/// Drain the downloaded block set up to the first gap.
fn drain_blocks(&mut self) -> Vec<IncomingBlock<B>> {
self.blocks
.drain(self.best_queued_number + One::one())
.into_iter()
.map(|block_data| {
let justifications = block_data
.block
.justifications
.or(legacy_justification_mapping(block_data.block.justification));
IncomingBlock {
hash: block_data.block.hash,
header: block_data.block.header,
body: block_data.block.body,
indexed_body: block_data.block.indexed_body,
justifications,
origin: block_data.origin,
allow_missing_state: true,
import_existing: self.import_existing,
skip_execution: self.skip_execution(),
state: None,
}
})
.collect()
}
}
// This is purely during a backwards compatible transitionary period and should be removed
// once we can assume all nodes can send and receive multiple Justifications
// The ID tag is hardcoded here to avoid depending on the GRANDPA crate.
// See: https://github.com/paritytech/substrate/issues/8172
fn legacy_justification_mapping(
justification: Option<EncodedJustification>,
) -> Option<Justifications> {
justification.map(|just| (*b"FRNK", just).into())
}
#[derive(Debug)]
pub(crate) struct Metrics {
pub(crate) queued_blocks: u32,
pub(crate) fork_targets: u32,
pub(crate) justifications: extra_requests::Metrics,
_priv: (),
}
/// Request the ancestry for a block. Sends a request for header and justification for the given
/// block number. Used during ancestry search.
fn ancestry_request<B: BlockT>(block: NumberFor<B>) -> BlockRequest<B> {
message::generic::BlockRequest {
id: 0,
fields: BlockAttributes::HEADER | BlockAttributes::JUSTIFICATION,
from: message::FromBlock::Number(block),
to: None,
direction: message::Direction::Ascending,
max: Some(1),
}
}
/// The ancestor search state expresses which algorithm, and its stateful parameters, we are using
/// to try to find an ancestor block
#[derive(Copy, Clone, Eq, PartialEq, Debug)]
pub enum AncestorSearchState<B: BlockT> {
/// Use exponential backoff to find an ancestor, then switch to binary search.
/// We keep track of the exponent.
ExponentialBackoff(NumberFor<B>),
/// Using binary search to find the best ancestor.
/// We keep track of left and right bounds.
BinarySearch(NumberFor<B>, NumberFor<B>),
}
/// This function handles the ancestor search strategy used. The goal is to find a common point
/// that both our chains agree on that is as close to the tip as possible.
/// The way this works is we first have an exponential backoff strategy, where we try to step
/// forward until we find a block hash mismatch. The size of the step doubles each step we take.
///
/// When we've found a block hash mismatch we then fall back to a binary search between the two
/// last known points to find the common block closest to the tip.
fn handle_ancestor_search_state<B: BlockT>(
state: &AncestorSearchState<B>,
curr_block_num: NumberFor<B>,
block_hash_match: bool,
) -> Option<(AncestorSearchState<B>, NumberFor<B>)> {
let two = <NumberFor<B>>::one() + <NumberFor<B>>::one();
match state {
AncestorSearchState::ExponentialBackoff(next_distance_to_tip) => {
let next_distance_to_tip = *next_distance_to_tip;
if block_hash_match && next_distance_to_tip == One::one() {
// We found the ancestor in the first step so there is no need to execute binary
// search.
return None
}
if block_hash_match {
let left = curr_block_num;
let right = left + next_distance_to_tip / two;
let middle = left + (right - left) / two;
Some((AncestorSearchState::BinarySearch(left, right), middle))
} else {
let next_block_num =
curr_block_num.checked_sub(&next_distance_to_tip).unwrap_or_else(Zero::zero);
let next_distance_to_tip = next_distance_to_tip * two;
Some((
AncestorSearchState::ExponentialBackoff(next_distance_to_tip),
next_block_num,
))
}
},
AncestorSearchState::BinarySearch(mut left, mut right) => {
if left >= curr_block_num {
return None
}
if block_hash_match {
left = curr_block_num;
} else {
right = curr_block_num;
}
assert!(right >= left);
let middle = left + (right - left) / two;
Some((AncestorSearchState::BinarySearch(left, right), middle))
},
}
}
/// Get a new block request for the peer if any.
fn peer_block_request<B: BlockT>(
id: &PeerId,
peer: &PeerSync<B>,
blocks: &mut BlockCollection<B>,
attrs: message::BlockAttributes,
max_parallel_downloads: u32,
finalized: NumberFor<B>,
best_num: NumberFor<B>,
) -> Option<(Range<NumberFor<B>>, BlockRequest<B>)> {
if best_num >= peer.best_number {
// Will be downloaded as alternative fork instead.
return None
} else if peer.common_number < finalized {
trace!(
target: "sync",
"Requesting pre-finalized chain from {:?}, common={}, finalized={}, peer best={}, our best={}",
id, peer.common_number, finalized, peer.best_number, best_num,
);
}
let range = blocks.needed_blocks(
*id,
MAX_BLOCKS_TO_REQUEST,
peer.best_number,
peer.common_number,
max_parallel_downloads,
MAX_DOWNLOAD_AHEAD,
)?;
// The end is not part of the range.
let last = range.end.saturating_sub(One::one());
let from = if peer.best_number == last {
message::FromBlock::Hash(peer.best_hash)
} else {
message::FromBlock::Number(last)
};
let request = message::generic::BlockRequest {
id: 0,
fields: attrs.clone(),
from,
to: None,
direction: message::Direction::Descending,
max: Some((range.end - range.start).saturated_into::<u32>()),
};
Some((range, request))
}
/// Get a new block request for the peer if any.
fn peer_gap_block_request<B: BlockT>(
id: &PeerId,
peer: &PeerSync<B>,
blocks: &mut BlockCollection<B>,
attrs: message::BlockAttributes,
target: NumberFor<B>,
common_number: NumberFor<B>,
) -> Option<(Range<NumberFor<B>>, BlockRequest<B>)> {
let range = blocks.needed_blocks(
id.clone(),
MAX_BLOCKS_TO_REQUEST,
std::cmp::min(peer.best_number, target),
common_number,
1,
MAX_DOWNLOAD_AHEAD,
)?;
// The end is not part of the range.
let last = range.end.saturating_sub(One::one());
let from = message::FromBlock::Number(last);
let request = message::generic::BlockRequest {
id: 0,
fields: attrs.clone(),
from,
to: None,
direction: message::Direction::Descending,
max: Some((range.end - range.start).saturated_into::<u32>()),
};
Some((range, request))
}
/// Get pending fork sync targets for a peer.
fn fork_sync_request<B: BlockT>(
id: &PeerId,
targets: &mut HashMap<B::Hash, ForkTarget<B>>,
best_num: NumberFor<B>,
finalized: NumberFor<B>,
attributes: message::BlockAttributes,
check_block: impl Fn(&B::Hash) -> BlockStatus,
) -> Option<(B::Hash, BlockRequest<B>)> {
targets.retain(|hash, r| {
if r.number <= finalized {
trace!(target: "sync", "Removed expired fork sync request {:?} (#{})", hash, r.number);
return false
}
if check_block(hash) != BlockStatus::Unknown {
trace!(target: "sync", "Removed obsolete fork sync request {:?} (#{})", hash, r.number);
return false
}
true
});
for (hash, r) in targets {
if !r.peers.contains(id) {
continue
}
if r.number <= best_num {
let parent_status = r.parent_hash.as_ref().map_or(BlockStatus::Unknown, check_block);
let count = if parent_status == BlockStatus::Unknown {
(r.number - finalized).saturated_into::<u32>() // up to the last finalized block
} else {
// request only single block
1
};
trace!(target: "sync", "Downloading requested fork {:?} from {}, {} blocks", hash, id, count);
return Some((
hash.clone(),
message::generic::BlockRequest {
id: 0,
fields: attributes.clone(),
from: message::FromBlock::Hash(hash.clone()),
to: None,
direction: message::Direction::Descending,
max: Some(count),
},
))
}
}
None
}
/// Returns `true` if the given `block` is a descendent of `base`.
fn is_descendent_of<Block, T>(
client: &T,
base: &Block::Hash,
block: &Block::Hash,
) -> sp_blockchain::Result<bool>
where
Block: BlockT,
T: HeaderMetadata<Block, Error = sp_blockchain::Error> + ?Sized,
{
if base == block {
return Ok(false)
}
let ancestor = sp_blockchain::lowest_common_ancestor(client, *block, *base)?;
Ok(ancestor.hash == *base)
}
/// Validate that the given `blocks` are correct.
/// Returns the number of the first block in the sequence.
///
/// It is expected that `blocks` are in ascending order.
fn validate_blocks<Block: BlockT>(
blocks: &Vec<message::BlockData<Block>>,
who: &PeerId,
request: Option<BlockRequest<Block>>,
) -> Result<Option<NumberFor<Block>>, BadPeer> {
if let Some(request) = request {
if Some(blocks.len() as _) > request.max {
debug!(
target: "sync",
"Received more blocks than requested from {}. Expected in maximum {:?}, got {}.",
who,
request.max,
blocks.len(),
);
return Err(BadPeer(*who, rep::NOT_REQUESTED))
}
let block_header = if request.direction == message::Direction::Descending {
blocks.last()
} else {
blocks.first()
}
.and_then(|b| b.header.as_ref());
let expected_block = block_header.as_ref().map_or(false, |h| match request.from {
message::FromBlock::Hash(hash) => h.hash() == hash,
message::FromBlock::Number(n) => h.number() == &n,
});
if !expected_block {
debug!(
target: "sync",
"Received block that was not requested. Requested {:?}, got {:?}.",
request.from,
block_header,
);
return Err(BadPeer(*who, rep::NOT_REQUESTED))
}
if request.fields.contains(message::BlockAttributes::HEADER) &&
blocks.iter().any(|b| b.header.is_none())
{
trace!(
target: "sync",
"Missing requested header for a block in response from {}.",
who,
);
return Err(BadPeer(*who, rep::BAD_RESPONSE))
}
if request.fields.contains(message::BlockAttributes::BODY) &&
blocks.iter().any(|b| b.body.is_none())
{
trace!(
target: "sync",
"Missing requested body for a block in response from {}.",
who,
);
return Err(BadPeer(*who, rep::BAD_RESPONSE))
}
}
for b in blocks {
if let Some(header) = &b.header {
let hash = header.hash();
if hash != b.hash {
debug!(
target:"sync",
"Bad header received from {}. Expected hash {:?}, got {:?}",
who,
b.hash,
hash,
);
return Err(BadPeer(*who, rep::BAD_BLOCK))
}
}
if let (Some(header), Some(body)) = (&b.header, &b.body) {
let expected = *header.extrinsics_root();
let got = HashFor::<Block>::ordered_trie_root(
body.iter().map(Encode::encode).collect(),
sp_runtime::StateVersion::V0,
);
if expected != got {
debug!(
target:"sync",
"Bad extrinsic root for a block {} received from {}. Expected {:?}, got {:?}",
b.hash,
who,
expected,
got,
);
return Err(BadPeer(*who, rep::BAD_BLOCK))
}
}
}
Ok(blocks.first().and_then(|b| b.header.as_ref()).map(|h| *h.number()))
}
#[cfg(test)]
mod test {
use super::{
message::{BlockData, BlockState, FromBlock},
*,
};
use futures::{executor::block_on, future::poll_fn};
use sc_block_builder::BlockBuilderProvider;
use sp_blockchain::HeaderBackend;
use sp_consensus::block_validation::DefaultBlockAnnounceValidator;
use substrate_test_runtime_client::{
runtime::{Block, Hash, Header},
BlockBuilderExt, ClientBlockImportExt, ClientExt, DefaultTestClientBuilderExt, TestClient,
TestClientBuilder, TestClientBuilderExt,
};
#[test]
fn processes_empty_response_on_justification_request_for_unknown_block() {
// if we ask for a justification for a given block to a peer that doesn't know that block
// (different from not having a justification), the peer will reply with an empty response.
// internally we should process the response as the justification not being available.
let client = Arc::new(TestClientBuilder::new().build());
let block_announce_validator = Box::new(DefaultBlockAnnounceValidator);
let peer_id = PeerId::random();
let mut sync =
ChainSync::new(SyncMode::Full, client.clone(), block_announce_validator, 1, None)
.unwrap();
let (a1_hash, a1_number) = {
let a1 = client.new_block(Default::default()).unwrap().build().unwrap().block;
(a1.hash(), *a1.header.number())
};
// add a new peer with the same best block
sync.new_peer(peer_id, a1_hash, a1_number).unwrap();
// and request a justification for the block
sync.request_justification(&a1_hash, a1_number);
// the justification request should be scheduled to that peer
assert!(sync
.justification_requests()
.any(|(who, request)| { who == peer_id && request.from == FromBlock::Hash(a1_hash) }));
// there are no extra pending requests
assert_eq!(sync.extra_justifications.pending_requests().count(), 0);
// there's one in-flight extra request to the expected peer
assert!(sync.extra_justifications.active_requests().any(|(who, (hash, number))| {
*who == peer_id && *hash == a1_hash && *number == a1_number
}));
// if the peer replies with an empty response (i.e. it doesn't know the block),
// the active request should be cleared.
assert_eq!(
sync.on_block_justification(peer_id, BlockResponse::<Block> { id: 0, blocks: vec![] }),
Ok(OnBlockJustification::Nothing),
);
// there should be no in-flight requests
assert_eq!(sync.extra_justifications.active_requests().count(), 0);
// and the request should now be pending again, waiting for reschedule
assert!(sync
.extra_justifications
.pending_requests()
.any(|(hash, number)| { *hash == a1_hash && *number == a1_number }));
}
#[test]
fn restart_doesnt_affect_peers_downloading_finality_data() {
let mut client = Arc::new(TestClientBuilder::new().build());
let mut sync = ChainSync::new(
SyncMode::Full,
client.clone(),
Box::new(DefaultBlockAnnounceValidator),
1,
None,
)
.unwrap();
let peer_id1 = PeerId::random();
let peer_id2 = PeerId::random();
let peer_id3 = PeerId::random();
let mut new_blocks = |n| {
for _ in 0..n {
let block = client.new_block(Default::default()).unwrap().build().unwrap().block;
block_on(client.import(BlockOrigin::Own, block.clone())).unwrap();
}
let info = client.info();
(info.best_hash, info.best_number)
};
let (b1_hash, b1_number) = new_blocks(50);
// add 2 peers at blocks that we don't have locally
sync.new_peer(peer_id1.clone(), Hash::random(), 42).unwrap();
sync.new_peer(peer_id2.clone(), Hash::random(), 10).unwrap();
// we wil send block requests to these peers
// for these blocks we don't know about
assert!(sync.block_requests().all(|(p, _)| { *p == peer_id1 || *p == peer_id2 }));
// add a new peer at a known block
sync.new_peer(peer_id3.clone(), b1_hash, b1_number).unwrap();
// we request a justification for a block we have locally
sync.request_justification(&b1_hash, b1_number);
// the justification request should be scheduled to the
// new peer which is at the given block
assert!(sync.justification_requests().any(|(p, r)| {
p == peer_id3 &&
r.fields == BlockAttributes::JUSTIFICATION &&
r.from == message::FromBlock::Hash(b1_hash) &&
r.to == None
}));
assert_eq!(
sync.peers.get(&peer_id3).unwrap().state,
PeerSyncState::DownloadingJustification(b1_hash),
);
// we restart the sync state
let block_requests = sync.restart();
// which should make us send out block requests to the first two peers
assert!(block_requests
.map(|r| r.unwrap())
.all(|(p, _)| { p == peer_id1 || p == peer_id2 }));
// peer 3 should be unaffected it was downloading finality data
assert_eq!(
sync.peers.get(&peer_id3).unwrap().state,
PeerSyncState::DownloadingJustification(b1_hash),
);
// Set common block to something that we don't have (e.g. failed import)
sync.peers.get_mut(&peer_id3).unwrap().common_number = 100;
let _ = sync.restart().count();
assert_eq!(sync.peers.get(&peer_id3).unwrap().common_number, 50);
}
/// Send a block annoucnement for the given `header`.
fn send_block_announce(header: Header, peer_id: &PeerId, sync: &mut ChainSync<Block>) {
let block_annnounce = BlockAnnounce {
header: header.clone(),
state: Some(BlockState::Best),
data: Some(Vec::new()),
};
sync.push_block_announce_validation(peer_id.clone(), header.hash(), block_annnounce, true);
// Poll until we have procssed the block announcement
block_on(poll_fn(|cx| loop {
if sync.poll_block_announce_validation(cx).is_pending() {
break Poll::Ready(())
}
}))
}
/// Create a block response from the given `blocks`.
fn create_block_response(blocks: Vec<Block>) -> BlockResponse<Block> {
BlockResponse::<Block> {
id: 0,
blocks: blocks
.into_iter()
.map(|b| BlockData::<Block> {
hash: b.hash(),
header: Some(b.header().clone()),
body: Some(b.deconstruct().1),
indexed_body: None,
receipt: None,
message_queue: None,
justification: None,
justifications: None,
})
.collect(),
}
}
/// Get a block request from `sync` and check that is matches the expected request.
fn get_block_request(
sync: &mut ChainSync<Block>,
from: FromBlock<Hash, u64>,
max: u32,
peer: &PeerId,
) -> BlockRequest<Block> {
let requests = sync.block_requests().collect::<Vec<_>>();
log::trace!(target: "sync", "Requests: {:?}", requests);
assert_eq!(1, requests.len());
assert_eq!(peer, requests[0].0);
let request = requests[0].1.clone();
assert_eq!(from, request.from);
assert_eq!(Some(max), request.max);
request
}
/// Build and import a new best block.
fn build_block(client: &mut Arc<TestClient>, at: Option<Hash>, fork: bool) -> Block {
let at = at.unwrap_or_else(|| client.info().best_hash);
let mut block_builder =
client.new_block_at(&BlockId::Hash(at), Default::default(), false).unwrap();
if fork {
block_builder.push_storage_change(vec![1, 2, 3], Some(vec![4, 5, 6])).unwrap();
}
let block = block_builder.build().unwrap().block;
block_on(client.import(BlockOrigin::Own, block.clone())).unwrap();
block
}
/// This test is a regression test as observed on a real network.
///
/// The node is connected to multiple peers. Both of these peers are having a best block (1)
/// that is below our best block (3). Now peer 2 announces a fork of block 3 that we will
/// request from peer 2. After importing the fork, peer 2 and then peer 1 will announce block 4.
/// But as peer 1 in our view is still at block 1, we will request block 2 (which we already
/// have) from it. In the meanwhile peer 2 sends us block 4 and 3 and we send another request
/// for block 2 to peer 2. Peer 1 answers with block 2 and then peer 2. This will need to
/// succeed, as we have requested block 2 from both peers.
#[test]
fn do_not_report_peer_on_block_response_for_block_request() {
sp_tracing::try_init_simple();
let mut client = Arc::new(TestClientBuilder::new().build());
let mut sync = ChainSync::new(
SyncMode::Full,
client.clone(),
Box::new(DefaultBlockAnnounceValidator),
5,
None,
)
.unwrap();
let peer_id1 = PeerId::random();
let peer_id2 = PeerId::random();
let mut client2 = client.clone();
let mut build_block_at = |at, import| {
let mut block_builder =
client2.new_block_at(&BlockId::Hash(at), Default::default(), false).unwrap();
// Make sure we generate a different block as fork
block_builder.push_storage_change(vec![1, 2, 3], Some(vec![4, 5, 6])).unwrap();
let block = block_builder.build().unwrap().block;
if import {
block_on(client2.import(BlockOrigin::Own, block.clone())).unwrap();
}
block
};
let block1 = build_block(&mut client, None, false);
let block2 = build_block(&mut client, None, false);
let block3 = build_block(&mut client, None, false);
let block3_fork = build_block_at(block2.hash(), false);
// Add two peers which are on block 1.
sync.new_peer(peer_id1.clone(), block1.hash(), 1).unwrap();
sync.new_peer(peer_id2.clone(), block1.hash(), 1).unwrap();
// Tell sync that our best block is 3.
sync.update_chain_info(&block3.hash(), 3);
// There should be no requests.
assert!(sync.block_requests().collect::<Vec<_>>().is_empty());
// Let peer2 announce a fork of block 3
send_block_announce(block3_fork.header().clone(), &peer_id2, &mut sync);
// Import and tell sync that we now have the fork.
block_on(client.import(BlockOrigin::Own, block3_fork.clone())).unwrap();
sync.update_chain_info(&block3_fork.hash(), 3);
let block4 = build_block_at(block3_fork.hash(), false);
// Let peer2 announce block 4 and check that sync wants to get the block.
send_block_announce(block4.header().clone(), &peer_id2, &mut sync);
let request = get_block_request(&mut sync, FromBlock::Hash(block4.hash()), 2, &peer_id2);
// Peer1 announces the same block, but as the common block is still `1`, sync will request
// block 2 again.
send_block_announce(block4.header().clone(), &peer_id1, &mut sync);
let request2 = get_block_request(&mut sync, FromBlock::Number(2), 1, &peer_id1);
let response = create_block_response(vec![block4.clone(), block3_fork.clone()]);
let res = sync.on_block_data(&peer_id2, Some(request), response).unwrap();
// We should not yet import the blocks, because there is still an open request for fetching
// block `2` which blocks the import.
assert!(matches!(res, OnBlockData::Import(_, blocks) if blocks.is_empty()));
let request3 = get_block_request(&mut sync, FromBlock::Number(2), 1, &peer_id2);
let response = create_block_response(vec![block2.clone()]);
let res = sync.on_block_data(&peer_id1, Some(request2), response).unwrap();
assert!(matches!(
res,
OnBlockData::Import(_, blocks)
if blocks.iter().all(|b| [2, 3, 4].contains(b.header.as_ref().unwrap().number()))
));
let response = create_block_response(vec![block2.clone()]);
let res = sync.on_block_data(&peer_id2, Some(request3), response).unwrap();
// Nothing to import
assert!(matches!(res, OnBlockData::Import(_, blocks) if blocks.is_empty()));
}
fn unwrap_from_block_number(from: FromBlock<Hash, u64>) -> u64 {
if let FromBlock::Number(from) = from {
from
} else {
panic!("Expected a number!");
}
}
/// A regression test for a behavior we have seen on a live network.
///
/// The scenario is that the node is doing a full resync and is connected to some node that is
/// doing a major sync as well. This other node that is doing a major sync will finish before
/// our node and send a block announcement message, but we don't have seen any block
/// announcement from this node in its sync process. Meaning our common number didn't change. It
/// is now expected that we start an ancestor search to find the common number.
#[test]
fn do_ancestor_search_when_common_block_to_best_qeued_gap_is_to_big() {
sp_tracing::try_init_simple();
let blocks = {
let mut client = Arc::new(TestClientBuilder::new().build());
(0..MAX_DOWNLOAD_AHEAD * 2)
.map(|_| build_block(&mut client, None, false))
.collect::<Vec<_>>()
};
let mut client = Arc::new(TestClientBuilder::new().build());
let info = client.info();
let mut sync = ChainSync::new(
SyncMode::Full,
client.clone(),
Box::new(DefaultBlockAnnounceValidator),
5,
None,
)
.unwrap();
let peer_id1 = PeerId::random();
let peer_id2 = PeerId::random();
let best_block = blocks.last().unwrap().clone();
// Connect the node we will sync from
sync.new_peer(peer_id1.clone(), best_block.hash(), *best_block.header().number())
.unwrap();
sync.new_peer(peer_id2.clone(), info.best_hash, 0).unwrap();
let mut best_block_num = 0;
while best_block_num < MAX_DOWNLOAD_AHEAD {
let request = get_block_request(
&mut sync,
FromBlock::Number(MAX_BLOCKS_TO_REQUEST as u64 + best_block_num as u64),
MAX_BLOCKS_TO_REQUEST as u32,
&peer_id1,
);
let from = unwrap_from_block_number(request.from.clone());
let mut resp_blocks = blocks[best_block_num as usize..from as usize].to_vec();
resp_blocks.reverse();
let response = create_block_response(resp_blocks.clone());
let res = sync.on_block_data(&peer_id1, Some(request), response).unwrap();
assert!(matches!(
res,
OnBlockData::Import(_, blocks) if blocks.len() == MAX_BLOCKS_TO_REQUEST
),);
best_block_num += MAX_BLOCKS_TO_REQUEST as u32;
resp_blocks
.into_iter()
.rev()
.for_each(|b| block_on(client.import_as_final(BlockOrigin::Own, b)).unwrap());
}
// "Wait" for the queue to clear
sync.queue_blocks.clear();
// Let peer2 announce that it finished syncing
send_block_announce(best_block.header().clone(), &peer_id2, &mut sync);
let (peer1_req, peer2_req) = sync.block_requests().fold((None, None), |res, req| {
if req.0 == &peer_id1 {
(Some(req.1), res.1)
} else if req.0 == &peer_id2 {
(res.0, Some(req.1))
} else {
panic!("Unexpected req: {:?}", req)
}
});
// We should now do an ancestor search to find the correct common block.
let peer2_req = peer2_req.unwrap();
assert_eq!(Some(1), peer2_req.max);
assert_eq!(FromBlock::Number(best_block_num as u64), peer2_req.from);
let response = create_block_response(vec![blocks[(best_block_num - 1) as usize].clone()]);
let res = sync.on_block_data(&peer_id2, Some(peer2_req), response).unwrap();
assert!(matches!(
res,
OnBlockData::Import(_, blocks) if blocks.is_empty()
),);
let peer1_from = unwrap_from_block_number(peer1_req.unwrap().from);
// As we are on the same chain, we should directly continue with requesting blocks from
// peer 2 as well.
get_block_request(
&mut sync,
FromBlock::Number(peer1_from + MAX_BLOCKS_TO_REQUEST as u64),
MAX_BLOCKS_TO_REQUEST as u32,
&peer_id2,
);
}
/// A test that ensures that we can sync a huge fork.
///
/// The following scenario:
/// A peer connects to us and we both have the common block 512. The last finalized is 2048.
/// Our best block is 4096. The peer send us a block announcement with 4097 from a fork.
///
/// We will first do an ancestor search to find the common block. After that we start to sync
/// the fork and finish it ;)
#[test]
fn can_sync_huge_fork() {
sp_tracing::try_init_simple();
let mut client = Arc::new(TestClientBuilder::new().build());
let blocks = (0..MAX_BLOCKS_TO_LOOK_BACKWARDS * 4)
.map(|_| build_block(&mut client, None, false))
.collect::<Vec<_>>();
let fork_blocks = {
let mut client = Arc::new(TestClientBuilder::new().build());
let fork_blocks = blocks[..MAX_BLOCKS_TO_LOOK_BACKWARDS as usize * 2]
.into_iter()
.inspect(|b| block_on(client.import(BlockOrigin::Own, (*b).clone())).unwrap())
.cloned()
.collect::<Vec<_>>();
fork_blocks
.into_iter()
.chain(
(0..MAX_BLOCKS_TO_LOOK_BACKWARDS * 2 + 1)
.map(|_| build_block(&mut client, None, true)),
)
.collect::<Vec<_>>()
};
let info = client.info();
let mut sync = ChainSync::new(
SyncMode::Full,
client.clone(),
Box::new(DefaultBlockAnnounceValidator),
5,
None,
)
.unwrap();
let finalized_block = blocks[MAX_BLOCKS_TO_LOOK_BACKWARDS as usize * 2 - 1].clone();
let just = (*b"TEST", Vec::new());
client
.finalize_block(BlockId::Hash(finalized_block.hash()), Some(just))
.unwrap();
sync.update_chain_info(&info.best_hash, info.best_number);
let peer_id1 = PeerId::random();
let common_block = blocks[MAX_BLOCKS_TO_LOOK_BACKWARDS as usize / 2].clone();
// Connect the node we will sync from
sync.new_peer(peer_id1.clone(), common_block.hash(), *common_block.header().number())
.unwrap();
send_block_announce(fork_blocks.last().unwrap().header().clone(), &peer_id1, &mut sync);
let mut request =
get_block_request(&mut sync, FromBlock::Number(info.best_number), 1, &peer_id1);
// Do the ancestor search
loop {
let block = &fork_blocks[unwrap_from_block_number(request.from.clone()) as usize - 1];
let response = create_block_response(vec![block.clone()]);
let on_block_data = sync.on_block_data(&peer_id1, Some(request), response).unwrap();
request = match on_block_data.into_request() {
Some(req) => req.1,
// We found the ancenstor
None => break,
};
log::trace!(target: "sync", "Request: {:?}", request);
}
// Now request and import the fork.
let mut best_block_num = finalized_block.header().number().clone() as u32;
while best_block_num < *fork_blocks.last().unwrap().header().number() as u32 - 1 {
let request = get_block_request(
&mut sync,
FromBlock::Number(MAX_BLOCKS_TO_REQUEST as u64 + best_block_num as u64),
MAX_BLOCKS_TO_REQUEST as u32,
&peer_id1,
);
let from = unwrap_from_block_number(request.from.clone());
let mut resp_blocks = fork_blocks[best_block_num as usize..from as usize].to_vec();
resp_blocks.reverse();
let response = create_block_response(resp_blocks.clone());
let res = sync.on_block_data(&peer_id1, Some(request), response).unwrap();
assert!(matches!(
res,
OnBlockData::Import(_, blocks) if blocks.len() == MAX_BLOCKS_TO_REQUEST
),);
best_block_num += MAX_BLOCKS_TO_REQUEST as u32;
let _ = sync.on_blocks_processed(
MAX_BLOCKS_TO_REQUEST as usize,
MAX_BLOCKS_TO_REQUEST as usize,
resp_blocks
.iter()
.rev()
.map(|b| {
(
Ok(BlockImportStatus::ImportedUnknown(
b.header().number().clone(),
Default::default(),
Some(peer_id1.clone()),
)),
b.hash(),
)
})
.collect(),
);
resp_blocks
.into_iter()
.rev()
.for_each(|b| block_on(client.import(BlockOrigin::Own, b)).unwrap());
}
// Request the tip
get_block_request(
&mut sync,
FromBlock::Hash(fork_blocks.last().unwrap().hash()),
1,
&peer_id1,
);
}
#[test]
fn removes_target_fork_on_disconnect() {
sp_tracing::try_init_simple();
let mut client = Arc::new(TestClientBuilder::new().build());
let blocks = (0..3).map(|_| build_block(&mut client, None, false)).collect::<Vec<_>>();
let mut sync = ChainSync::new(
SyncMode::Full,
client.clone(),
Box::new(DefaultBlockAnnounceValidator),
1,
None,
)
.unwrap();
let peer_id1 = PeerId::random();
let common_block = blocks[1].clone();
// Connect the node we will sync from
sync.new_peer(peer_id1.clone(), common_block.hash(), *common_block.header().number())
.unwrap();
// Create a "new" header and announce it
let mut header = blocks[0].header().clone();
header.number = 4;
send_block_announce(header, &peer_id1, &mut sync);
assert!(sync.fork_targets.len() == 1);
sync.peer_disconnected(&peer_id1);
assert!(sync.fork_targets.len() == 0);
}
}
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