openethereum/sync/src/blocks.rs

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// Copyright 2015-2017 Parity Technologies (UK) Ltd.
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// This file is part of Parity.
// Parity is free software: you can redistribute it and/or modify
// it under the terms of the GNU General Public License as published by
// the Free Software Foundation, either version 3 of the License, or
// (at your option) any later version.
// Parity is distributed in the hope that it will be useful,
// but WITHOUT ANY WARRANTY; without even the implied warranty of
// MERCHANTABILITY or FITNESS FOR A PARTICULAR PURPOSE. See the
// GNU General Public License for more details.
// You should have received a copy of the GNU General Public License
// along with Parity. If not, see <http://www.gnu.org/licenses/>.
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use std::collections::{HashSet, HashMap};
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use std::collections::hash_map::Entry;
use smallvec::SmallVec;
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use hash::{keccak, KECCAK_NULL_RLP, KECCAK_EMPTY_LIST_RLP};
use heapsize::HeapSizeOf;
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use bigint::hash::H256;
use triehash::ordered_trie_root;
use bytes::Bytes;
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use rlp::*;
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use network;
use ethcore::header::Header as BlockHeader;
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known_heap_size!(0, HeaderId);
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type SmallHashVec = SmallVec<[H256; 1]>;
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/// Block data with optional body.
struct SyncBlock {
header: Bytes,
body: Option<Bytes>,
receipts: Option<Bytes>,
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receipts_root: H256,
}
/// Block with optional receipt
pub struct BlockAndReceipts {
/// Block data.
pub block: Bytes,
/// Block receipts RLP list.
pub receipts: Option<Bytes>,
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}
impl HeapSizeOf for SyncBlock {
fn heap_size_of_children(&self) -> usize {
self.header.heap_size_of_children() + self.body.heap_size_of_children()
}
}
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/// Used to identify header by transactions and uncles hashes
#[derive(Eq, PartialEq, Hash)]
struct HeaderId {
transactions_root: H256,
uncles: H256
}
/// A collection of blocks and subchain pointers being downloaded. This keeps track of
/// which headers/bodies need to be downloaded, which are being downloaded and also holds
/// the downloaded blocks.
#[derive(Default)]
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pub struct BlockCollection {
/// Does this collection need block receipts.
need_receipts: bool,
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/// Heads of subchains to download
heads: Vec<H256>,
/// Downloaded blocks.
blocks: HashMap<H256, SyncBlock>,
/// Downloaded blocks by parent.
parents: HashMap<H256, H256>,
/// Used to map body to header.
header_ids: HashMap<HeaderId, H256>,
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/// Used to map receipts root to headers.
receipt_ids: HashMap<H256, SmallHashVec>,
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/// First block in `blocks`.
head: Option<H256>,
/// Set of block header hashes being downloaded
downloading_headers: HashSet<H256>,
/// Set of block bodies being downloaded identified by block hash.
downloading_bodies: HashSet<H256>,
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/// Set of block receipts being downloaded identified by receipt root.
downloading_receipts: HashSet<H256>,
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}
impl BlockCollection {
/// Create a new instance.
pub fn new(download_receipts: bool) -> BlockCollection {
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BlockCollection {
need_receipts: download_receipts,
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blocks: HashMap::new(),
header_ids: HashMap::new(),
receipt_ids: HashMap::new(),
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heads: Vec::new(),
parents: HashMap::new(),
head: None,
downloading_headers: HashSet::new(),
downloading_bodies: HashSet::new(),
downloading_receipts: HashSet::new(),
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}
}
/// Clear everything.
pub fn clear(&mut self) {
self.blocks.clear();
self.parents.clear();
self.header_ids.clear();
self.receipt_ids.clear();
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self.heads.clear();
self.head = None;
self.downloading_headers.clear();
self.downloading_bodies.clear();
self.downloading_receipts.clear();
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}
/// Reset collection for a new sync round with given subchain block hashes.
pub fn reset_to(&mut self, hashes: Vec<H256>) {
self.clear();
self.heads = hashes;
}
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/// Insert a set of headers into collection and advance subchain head pointers.
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pub fn insert_headers(&mut self, headers: Vec<Bytes>) {
for h in headers {
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if let Err(e) = self.insert_header(h) {
trace!(target: "sync", "Ignored invalid header: {:?}", e);
}
}
self.update_heads();
}
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/// Insert a collection of block bodies for previously downloaded headers.
pub fn insert_bodies(&mut self, bodies: Vec<Bytes>) -> usize {
let mut inserted = 0;
for b in bodies {
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if let Err(e) = self.insert_body(b) {
trace!(target: "sync", "Ignored invalid body: {:?}", e);
} else {
inserted += 1;
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}
}
inserted
}
/// Insert a collection of block receipts for previously downloaded headers.
pub fn insert_receipts(&mut self, receipts: Vec<Bytes>) -> usize {
if !self.need_receipts {
return 0;
}
let mut inserted = 0;
for r in receipts {
if let Err(e) = self.insert_receipt(r) {
trace!(target: "sync", "Ignored invalid receipt: {:?}", e);
} else {
inserted += 1;
}
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}
inserted
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}
/// Returns a set of block hashes that require a body download. The returned set is marked as being downloaded.
pub fn needed_bodies(&mut self, count: usize, _ignore_downloading: bool) -> Vec<H256> {
if self.head.is_none() {
return Vec::new();
}
let mut needed_bodies: Vec<H256> = Vec::new();
let mut head = self.head;
while head.is_some() && needed_bodies.len() < count {
head = self.parents.get(&head.unwrap()).cloned();
if let Some(head) = head {
match self.blocks.get(&head) {
Some(block) if block.body.is_none() && !self.downloading_bodies.contains(&head) => {
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self.downloading_bodies.insert(head.clone());
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needed_bodies.push(head.clone());
}
_ => (),
}
}
}
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for h in self.header_ids.values() {
if needed_bodies.len() >= count {
break;
}
if !self.downloading_bodies.contains(h) {
needed_bodies.push(h.clone());
self.downloading_bodies.insert(h.clone());
}
}
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needed_bodies
}
/// Returns a set of block hashes that require a receipt download. The returned set is marked as being downloaded.
pub fn needed_receipts(&mut self, count: usize, _ignore_downloading: bool) -> Vec<H256> {
if self.head.is_none() || !self.need_receipts {
return Vec::new();
}
let mut needed_receipts: Vec<H256> = Vec::new();
let mut head = self.head;
while head.is_some() && needed_receipts.len() < count {
head = self.parents.get(&head.unwrap()).cloned();
if let Some(head) = head {
match self.blocks.get(&head) {
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Some(block) => {
if block.receipts.is_none() && !self.downloading_receipts.contains(&block.receipts_root) {
self.downloading_receipts.insert(block.receipts_root);
needed_receipts.push(head.clone());
}
}
_ => (),
}
}
}
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// If there are multiple blocks per receipt, only request one of them.
for (root, h) in self.receipt_ids.iter().map(|(root, hashes)| (root, hashes[0])) {
if needed_receipts.len() >= count {
break;
}
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if !self.downloading_receipts.contains(root) {
needed_receipts.push(h.clone());
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self.downloading_receipts.insert(*root);
}
}
needed_receipts
}
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/// Returns a set of block hashes that require a header download. The returned set is marked as being downloaded.
pub fn needed_headers(&mut self, count: usize, ignore_downloading: bool) -> Option<(H256, usize)> {
// find subchain to download
let mut download = None;
{
for h in &self.heads {
if ignore_downloading || !self.downloading_headers.contains(h) {
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self.downloading_headers.insert(h.clone());
download = Some(h.clone());
break;
}
}
}
download.map(|h| (h, count))
}
/// Unmark header as being downloaded.
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pub fn clear_header_download(&mut self, hash: &H256) {
self.downloading_headers.remove(hash);
}
/// Unmark block body as being downloaded.
pub fn clear_body_download(&mut self, hashes: &[H256]) {
for h in hashes {
self.downloading_bodies.remove(h);
}
}
/// Unmark block receipt as being downloaded.
pub fn clear_receipt_download(&mut self, hashes: &[H256]) {
for h in hashes {
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if let Some(ref block) = self.blocks.get(h) {
self.downloading_receipts.remove(&block.receipts_root);
}
}
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}
/// Get a valid chain of blocks ordered in descending order and ready for importing into blockchain.
pub fn drain(&mut self) -> Vec<BlockAndReceipts> {
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if self.blocks.is_empty() || self.head.is_none() {
return Vec::new();
}
let mut drained = Vec::new();
let mut hashes = Vec::new();
{
let mut blocks = Vec::new();
let mut head = self.head;
while let Some(h) = head {
head = self.parents.get(&h).cloned();
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if let Some(head) = head {
match self.blocks.get(&head) {
Some(block) if block.body.is_some() && (!self.need_receipts || block.receipts.is_some()) => {
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blocks.push(block);
hashes.push(head);
self.head = Some(head);
}
_ => break,
}
}
}
for block in blocks {
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let mut block_rlp = RlpStream::new_list(3);
block_rlp.append_raw(&block.header, 1);
{
let body = Rlp::new(block.body.as_ref().expect("blocks contains only full blocks; qed"));
block_rlp.append_raw(body.at(0).as_raw(), 1);
block_rlp.append_raw(body.at(1).as_raw(), 1);
}
drained.push(BlockAndReceipts {
block: block_rlp.out(),
receipts: block.receipts.clone(),
});
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}
}
for h in hashes {
self.blocks.remove(&h);
}
trace!(target: "sync", "Drained {} blocks, new head :{:?}", drained.len(), self.head);
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drained
}
/// Check if the collection is empty. We consider the syncing round complete once
/// there is no block data left and only a single or none head pointer remains.
pub fn is_empty(&self) -> bool {
self.heads.len() == 0 || (self.heads.len() == 1 && self.head.map_or(false, |h| h == self.heads[0]))
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}
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/// Check if collection contains a block header.
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pub fn contains(&self, hash: &H256) -> bool {
self.blocks.contains_key(hash)
}
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/// Check if collection contains a block header.
pub fn contains_head(&self, hash: &H256) -> bool {
self.heads.contains(hash)
}
/// Return used heap size.
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pub fn heap_size(&self) -> usize {
self.heads.heap_size_of_children()
+ self.blocks.heap_size_of_children()
+ self.parents.heap_size_of_children()
+ self.header_ids.heap_size_of_children()
+ self.downloading_headers.heap_size_of_children()
+ self.downloading_bodies.heap_size_of_children()
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}
/// Check if given block hash is marked as being downloaded.
pub fn is_downloading(&self, hash: &H256) -> bool {
self.downloading_headers.contains(hash) || self.downloading_bodies.contains(hash)
}
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fn insert_body(&mut self, b: Bytes) -> Result<(), network::Error> {
let header_id = {
let body = UntrustedRlp::new(&b);
let tx = body.at(0)?;
let tx_root = ordered_trie_root(tx.iter().map(|r| r.as_raw().to_vec())); //TODO: get rid of vectors here
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let uncles = keccak(body.at(1)?.as_raw());
HeaderId {
transactions_root: tx_root,
uncles: uncles
}
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};
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match self.header_ids.get(&header_id).cloned() {
Some(h) => {
self.header_ids.remove(&header_id);
self.downloading_bodies.remove(&h);
match self.blocks.get_mut(&h) {
Some(ref mut block) => {
trace!(target: "sync", "Got body {}", h);
block.body = Some(b);
Ok(())
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},
None => {
warn!("Got body with no header {}", h);
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Err(network::ErrorKind::BadProtocol.into())
}
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}
}
None => {
trace!(target: "sync", "Ignored unknown/stale block body. tx_root = {:?}, uncles = {:?}", header_id.transactions_root, header_id.uncles);
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Err(network::ErrorKind::BadProtocol.into())
}
}
}
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fn insert_receipt(&mut self, r: Bytes) -> Result<(), network::Error> {
let receipt_root = {
let receipts = UntrustedRlp::new(&r);
ordered_trie_root(receipts.iter().map(|r| r.as_raw().to_vec())) //TODO: get rid of vectors here
};
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self.downloading_receipts.remove(&receipt_root);
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match self.receipt_ids.entry(receipt_root) {
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Entry::Occupied(entry) => {
for h in entry.remove() {
match self.blocks.get_mut(&h) {
Some(ref mut block) => {
trace!(target: "sync", "Got receipt {}", h);
block.receipts = Some(r.clone());
},
None => {
warn!("Got receipt with no header {}", h);
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return Err(network::ErrorKind::BadProtocol.into())
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}
}
}
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Ok(())
}
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_ => {
trace!(target: "sync", "Ignored unknown/stale block receipt {:?}", receipt_root);
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Err(network::ErrorKind::BadProtocol.into())
}
}
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}
fn insert_header(&mut self, header: Bytes) -> Result<H256, DecoderError> {
let info: BlockHeader = UntrustedRlp::new(&header).as_val()?;
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let hash = info.hash();
if self.blocks.contains_key(&hash) {
return Ok(hash);
}
match self.head {
None if hash == self.heads[0] => {
trace!(target: "sync", "New head {}", hash);
self.head = Some(info.parent_hash().clone());
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},
_ => ()
}
let mut block = SyncBlock {
header: header,
body: None,
receipts: None,
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receipts_root: H256::new(),
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};
let header_id = HeaderId {
transactions_root: info.transactions_root().clone(),
uncles: info.uncles_hash().clone(),
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};
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if header_id.transactions_root == KECCAK_NULL_RLP && header_id.uncles == KECCAK_EMPTY_LIST_RLP {
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// empty body, just mark as downloaded
let mut body_stream = RlpStream::new_list(2);
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body_stream.append_raw(&::rlp::EMPTY_LIST_RLP, 1);
body_stream.append_raw(&::rlp::EMPTY_LIST_RLP, 1);
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block.body = Some(body_stream.out());
}
else {
trace!("Queueing body tx_root = {:?}, uncles = {:?}, block = {:?}, number = {}", header_id.transactions_root, header_id.uncles, hash, info.number());
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self.header_ids.insert(header_id, hash.clone());
}
if self.need_receipts {
let receipt_root = info.receipts_root().clone();
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if receipt_root == KECCAK_NULL_RLP {
let receipts_stream = RlpStream::new_list(0);
block.receipts = Some(receipts_stream.out());
} else {
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self.receipt_ids.entry(receipt_root).or_insert_with(|| SmallHashVec::new()).push(hash.clone());
}
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block.receipts_root = receipt_root;
}
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self.parents.insert(info.parent_hash().clone(), hash.clone());
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self.blocks.insert(hash.clone(), block);
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trace!(target: "sync", "New header: {}", hash.hex());
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Ok(hash)
}
// update subchain headers
fn update_heads(&mut self) {
let mut new_heads = Vec::new();
let old_subchains: HashSet<_> = { self.heads.iter().cloned().collect() };
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for s in self.heads.drain(..) {
let mut h = s.clone();
if !self.blocks.contains_key(&h) {
new_heads.push(h);
continue;
}
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loop {
match self.parents.get(&h) {
Some(next) => {
h = next.clone();
if old_subchains.contains(&h) {
trace!(target: "sync", "Completed subchain {:?}", s);
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break; // reached head of the other subchain, merge by not adding
}
},
_ => {
new_heads.push(h);
break;
}
}
}
}
self.heads = new_heads;
}
}
#[cfg(test)]
mod test {
use super::BlockCollection;
use ethcore::client::{TestBlockChainClient, EachBlockWith, BlockId, BlockChainClient};
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use ethcore::views::HeaderView;
use ethcore::header::BlockNumber;
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use rlp::*;
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fn is_empty(bc: &BlockCollection) -> bool {
bc.heads.is_empty() &&
bc.blocks.is_empty() &&
bc.parents.is_empty() &&
bc.header_ids.is_empty() &&
bc.head.is_none() &&
bc.downloading_headers.is_empty() &&
bc.downloading_bodies.is_empty()
}
#[test]
fn create_clear() {
let mut bc = BlockCollection::new(false);
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assert!(is_empty(&bc));
let client = TestBlockChainClient::new();
client.add_blocks(100, EachBlockWith::Nothing);
let hashes = (0 .. 100).map(|i| (&client as &BlockChainClient).block_hash(BlockId::Number(i)).unwrap()).collect();
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bc.reset_to(hashes);
assert!(!is_empty(&bc));
bc.clear();
assert!(is_empty(&bc));
}
#[test]
fn insert_headers() {
let mut bc = BlockCollection::new(false);
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assert!(is_empty(&bc));
let client = TestBlockChainClient::new();
let nblocks = 200;
client.add_blocks(nblocks, EachBlockWith::Nothing);
let blocks: Vec<_> = (0..nblocks)
.map(|i| (&client as &BlockChainClient).block(BlockId::Number(i as BlockNumber)).unwrap().into_inner())
.collect();
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let headers: Vec<_> = blocks.iter().map(|b| Rlp::new(b).at(0).as_raw().to_vec()).collect();
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let hashes: Vec<_> = headers.iter().map(|h| HeaderView::new(h).hash()).collect();
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let heads: Vec<_> = hashes.iter().enumerate().filter_map(|(i, h)| if i % 20 == 0 { Some(h.clone()) } else { None }).collect();
bc.reset_to(heads);
assert!(!bc.is_empty());
assert_eq!(hashes[0], bc.heads[0]);
assert!(bc.needed_bodies(1, false).is_empty());
assert!(!bc.contains(&hashes[0]));
assert!(!bc.is_downloading(&hashes[0]));
let (h, n) = bc.needed_headers(6, false).unwrap();
assert!(bc.is_downloading(&hashes[0]));
assert_eq!(hashes[0], h);
assert_eq!(n, 6);
assert_eq!(bc.downloading_headers.len(), 1);
assert!(bc.drain().is_empty());
bc.insert_headers(headers[0..6].to_vec());
assert_eq!(hashes[5], bc.heads[0]);
for h in &hashes[0..6] {
bc.clear_header_download(h)
}
assert_eq!(bc.downloading_headers.len(), 0);
assert!(!bc.is_downloading(&hashes[0]));
assert!(bc.contains(&hashes[0]));
assert_eq!(&bc.drain().into_iter().map(|b| b.block).collect::<Vec<_>>()[..], &blocks[0..6]);
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assert!(!bc.contains(&hashes[0]));
assert_eq!(hashes[5], bc.head.unwrap());
let (h, _) = bc.needed_headers(6, false).unwrap();
assert_eq!(hashes[5], h);
let (h, _) = bc.needed_headers(6, false).unwrap();
assert_eq!(hashes[20], h);
bc.insert_headers(headers[10..16].to_vec());
assert!(bc.drain().is_empty());
bc.insert_headers(headers[5..10].to_vec());
assert_eq!(&bc.drain().into_iter().map(|b| b.block).collect::<Vec<_>>()[..], &blocks[6..16]);
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assert_eq!(hashes[15], bc.heads[0]);
bc.insert_headers(headers[15..].to_vec());
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bc.drain();
assert!(bc.is_empty());
}
#[test]
fn insert_headers_with_gap() {
let mut bc = BlockCollection::new(false);
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assert!(is_empty(&bc));
let client = TestBlockChainClient::new();
let nblocks = 200;
client.add_blocks(nblocks, EachBlockWith::Nothing);
let blocks: Vec<_> = (0..nblocks)
.map(|i| (&client as &BlockChainClient).block(BlockId::Number(i as BlockNumber)).unwrap().into_inner())
.collect();
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let headers: Vec<_> = blocks.iter().map(|b| Rlp::new(b).at(0).as_raw().to_vec()).collect();
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let hashes: Vec<_> = headers.iter().map(|h| HeaderView::new(h).hash()).collect();
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let heads: Vec<_> = hashes.iter().enumerate().filter_map(|(i, h)| if i % 20 == 0 { Some(h.clone()) } else { None }).collect();
bc.reset_to(heads);
bc.insert_headers(headers[2..22].to_vec());
assert_eq!(hashes[0], bc.heads[0]);
assert_eq!(hashes[21], bc.heads[1]);
assert!(bc.head.is_none());
bc.insert_headers(headers[0..2].to_vec());
assert!(bc.head.is_some());
assert_eq!(hashes[21], bc.heads[0]);
}
#[test]
fn insert_headers_no_gap() {
let mut bc = BlockCollection::new(false);
assert!(is_empty(&bc));
let client = TestBlockChainClient::new();
let nblocks = 200;
client.add_blocks(nblocks, EachBlockWith::Nothing);
let blocks: Vec<_> = (0..nblocks)
.map(|i| (&client as &BlockChainClient).block(BlockId::Number(i as BlockNumber)).unwrap().into_inner())
.collect();
let headers: Vec<_> = blocks.iter().map(|b| Rlp::new(b).at(0).as_raw().to_vec()).collect();
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let hashes: Vec<_> = headers.iter().map(|h| HeaderView::new(h).hash()).collect();
let heads: Vec<_> = hashes.iter().enumerate().filter_map(|(i, h)| if i % 20 == 0 { Some(h.clone()) } else { None }).collect();
bc.reset_to(heads);
bc.insert_headers(headers[1..2].to_vec());
assert!(bc.drain().is_empty());
bc.insert_headers(headers[0..1].to_vec());
assert_eq!(bc.drain().len(), 2);
}
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}