// Copyright 2015-2018 Parity Technologies (UK) Ltd. // 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 . //! Light client header chain. //! //! Unlike a full node's `BlockChain` this doesn't store much in the database. //! It stores candidates for the last 2048-4096 blocks as well as CHT roots for //! historical blocks all the way to the genesis. If the engine makes use //! of epoch transitions, those are stored as well. //! //! This is separate from the `BlockChain` for two reasons: //! - It stores only headers (and a pruned subset of them) //! - To allow for flexibility in the database layout.. use std::collections::BTreeMap; use std::sync::Arc; use cht; use ethcore::block_status::BlockStatus; use ethcore::error::{Error, BlockImportError, BlockImportErrorKind, BlockError}; use ethcore::encoded; use ethcore::header::Header; use ethcore::ids::BlockId; use ethcore::spec::{Spec, SpecHardcodedSync}; use ethcore::engines::epoch::{ Transition as EpochTransition, PendingTransition as PendingEpochTransition }; use rlp::{Encodable, Decodable, DecoderError, RlpStream, Rlp}; use heapsize::HeapSizeOf; use ethereum_types::{H256, H264, U256}; use plain_hasher::H256FastMap; use kvdb::{DBTransaction, KeyValueDB}; use cache::Cache; use parking_lot::{Mutex, RwLock}; use smallvec::SmallVec; /// Store at least this many candidate headers at all times. /// Also functions as the delay for computing CHTs as they aren't /// relevant to any blocks we've got in memory. const HISTORY: u64 = 2048; /// The best block key. Maps to an RLP list: [best_era, last_era] const CURRENT_KEY: &'static [u8] = &*b"best_and_latest"; /// Key storing the last canonical epoch transition. const LAST_CANONICAL_TRANSITION: &'static [u8] = &*b"canonical_transition"; /// Information about a block. #[derive(Debug, Clone)] pub struct BlockDescriptor { /// The block's hash pub hash: H256, /// The block's number pub number: u64, /// The block's total difficulty. pub total_difficulty: U256, } // best block data #[derive(RlpEncodable, RlpDecodable)] struct BestAndLatest { best_num: u64, latest_num: u64 } impl BestAndLatest { fn new(best_num: u64, latest_num: u64) -> Self { BestAndLatest { best_num, latest_num, } } } // candidate block description. struct Candidate { hash: H256, parent_hash: H256, total_difficulty: U256, } struct Entry { candidates: SmallVec<[Candidate; 3]>, // 3 arbitrarily chosen canonical_hash: H256, } impl HeapSizeOf for Entry { fn heap_size_of_children(&self) -> usize { match self.candidates.spilled() { false => 0, true => self.candidates.capacity() * ::std::mem::size_of::(), } } } impl Encodable for Entry { fn rlp_append(&self, s: &mut RlpStream) { s.begin_list(self.candidates.len()); for candidate in &self.candidates { s.begin_list(3) .append(&candidate.hash) .append(&candidate.parent_hash) .append(&candidate.total_difficulty); } } } impl Decodable for Entry { fn decode(rlp: &Rlp) -> Result { let mut candidates = SmallVec::<[Candidate; 3]>::new(); for item in rlp.iter() { candidates.push(Candidate { hash: item.val_at(0)?, parent_hash: item.val_at(1)?, total_difficulty: item.val_at(2)?, }) } if candidates.is_empty() { return Err(DecoderError::Custom("Empty candidates vector submitted.")) } // rely on the invariant that the canonical entry is always first. let canon_hash = candidates[0].hash; Ok(Entry { candidates: candidates, canonical_hash: canon_hash, }) } } fn cht_key(number: u64) -> String { format!("{:08x}_canonical", number) } fn era_key(number: u64) -> String { format!("candidates_{}", number) } fn pending_transition_key(block_hash: H256) -> H264 { const LEADING: u8 = 1; let mut key = H264::default(); key[0] = LEADING; key.0[1..].copy_from_slice(&block_hash.0[..]); key } fn transition_key(block_hash: H256) -> H264 { const LEADING: u8 = 2; let mut key = H264::default(); key[0] = LEADING; key.0[1..].copy_from_slice(&block_hash.0[..]); key } // encode last canonical transition entry: header and proof. fn encode_canonical_transition(header: &Header, proof: &[u8]) -> Vec { let mut stream = RlpStream::new_list(2); stream.append(header).append(&proof); stream.out() } // decode last canonical transition entry. fn decode_canonical_transition(t: &[u8]) -> Result<(Header, &[u8]), DecoderError> { let rlp = Rlp::new(t); Ok((rlp.val_at(0)?, rlp.at(1)?.data()?)) } /// Pending changes from `insert` to be applied after the database write has finished. pub struct PendingChanges { best_block: Option, // new best block. } /// Whether or not the hardcoded sync feature is allowed. pub enum HardcodedSync { Allow, Deny, } /// Header chain. See module docs for more details. pub struct HeaderChain { genesis_header: encoded::Header, // special-case the genesis. candidates: RwLock>, best_block: RwLock, live_epoch_proofs: RwLock>, db: Arc, col: Option, cache: Arc>, } impl HeaderChain { /// Create a new header chain given this genesis block and database to read from. pub fn new( db: Arc, col: Option, spec: &Spec, cache: Arc>, allow_hs: HardcodedSync, ) -> Result { let mut live_epoch_proofs = ::std::collections::HashMap::default(); let genesis = ::rlp::encode(&spec.genesis_header()).into_vec(); let decoded_header = spec.genesis_header(); let chain = if let Some(current) = db.get(col, CURRENT_KEY)? { let curr : BestAndLatest = ::rlp::decode(¤t).expect("decoding db value failed"); let mut cur_number = curr.latest_num; let mut candidates = BTreeMap::new(); // load all era entries, referenced headers within them, // and live epoch proofs. while let Some(entry) = db.get(col, era_key(cur_number).as_bytes())? { let entry: Entry = ::rlp::decode(&entry).expect("decoding db value failed"); trace!(target: "chain", "loaded header chain entry for era {} with {} candidates", cur_number, entry.candidates.len()); for c in &entry.candidates { let key = transition_key(c.hash); if let Some(proof) = db.get(col, &*key)? { live_epoch_proofs.insert(c.hash, EpochTransition { block_hash: c.hash, block_number: cur_number, proof: proof.into_vec(), }); } } candidates.insert(cur_number, entry); cur_number -= 1; } // fill best block block descriptor. let best_block = { let era = match candidates.get(&curr.best_num) { Some(era) => era, None => bail!("Database corrupt: highest block referenced but no data."), }; let best = &era.candidates[0]; BlockDescriptor { hash: best.hash, number: curr.best_num, total_difficulty: best.total_difficulty, } }; HeaderChain { genesis_header: encoded::Header::new(genesis), best_block: RwLock::new(best_block), candidates: RwLock::new(candidates), live_epoch_proofs: RwLock::new(live_epoch_proofs), db: db, col: col, cache: cache, } } else { let chain = HeaderChain { genesis_header: encoded::Header::new(genesis), best_block: RwLock::new(BlockDescriptor { hash: decoded_header.hash(), number: 0, total_difficulty: *decoded_header.difficulty(), }), candidates: RwLock::new(BTreeMap::new()), live_epoch_proofs: RwLock::new(live_epoch_proofs), db: db.clone(), col: col, cache: cache, }; // insert the hardcoded sync into the database. if let (&Some(ref hardcoded_sync), HardcodedSync::Allow) = (&spec.hardcoded_sync, allow_hs) { let mut batch = db.transaction(); // insert the hardcoded CHT roots into the database. for (cht_num, cht_root) in hardcoded_sync.chts.iter().enumerate() { batch.put(col, cht_key(cht_num as u64).as_bytes(), &::rlp::encode(cht_root)); } let decoded_header = hardcoded_sync.header.decode()?; let decoded_header_num = decoded_header.number(); // write the block in the DB. info!(target: "chain", "Inserting hardcoded block #{} in chain", decoded_header_num); let pending = chain.insert_with_td(&mut batch, decoded_header, hardcoded_sync.total_difficulty, None)?; // check that we have enough hardcoded CHT roots. avoids panicking later. let cht_num = cht::block_to_cht_number(decoded_header_num - 1) .expect("specs provided a hardcoded block with height 0"); if cht_num >= hardcoded_sync.chts.len() as u64 { warn!(target: "chain", "specs didn't provide enough CHT roots for its \ hardcoded block ; falling back to non-hardcoded sync \ mode"); } else { db.write_buffered(batch); chain.apply_pending(pending); } } chain }; // instantiate genesis epoch data if it doesn't exist. if let None = chain.db.get(col, LAST_CANONICAL_TRANSITION)? { let genesis_data = spec.genesis_epoch_data()?; { let mut batch = chain.db.transaction(); let data = encode_canonical_transition(&decoded_header, &genesis_data); batch.put_vec(col, LAST_CANONICAL_TRANSITION, data); chain.db.write(batch)?; } } Ok(chain) } /// Insert a pre-verified header. /// /// This blindly trusts that the data given to it is sensible. /// Returns a set of pending changes to be applied with `apply_pending` /// before the next call to insert and after the transaction has been written. /// /// If the block is an epoch transition, provide the transition along with /// the header. pub fn insert( &self, transaction: &mut DBTransaction, header: Header, transition_proof: Option>, ) -> Result { self.insert_inner(transaction, header, None, transition_proof) } /// Insert a pre-verified header, with a known total difficulty. Similary to `insert`. /// /// This blindly trusts that the data given to it is sensible. pub fn insert_with_td( &self, transaction: &mut DBTransaction, header: Header, total_difficulty: U256, transition_proof: Option>, ) -> Result { self.insert_inner(transaction, header, Some(total_difficulty), transition_proof) } fn insert_inner( &self, transaction: &mut DBTransaction, header: Header, total_difficulty: Option, transition_proof: Option>, ) -> Result { let hash = header.hash(); let number = header.number(); let parent_hash = *header.parent_hash(); let transition = transition_proof.map(|proof| EpochTransition { block_hash: hash, block_number: number, proof: proof, }); let mut pending = PendingChanges { best_block: None, }; // hold candidates the whole time to guard import order. let mut candidates = self.candidates.write(); // find total difficulty. let total_difficulty = match total_difficulty { Some(td) => td, None => { let parent_td = if number == 1 { self.genesis_header.difficulty() } else { candidates.get(&(number - 1)) .and_then(|entry| entry.candidates.iter().find(|c| c.hash == parent_hash)) .map(|c| c.total_difficulty) .ok_or_else(|| BlockError::UnknownParent(parent_hash)) .map_err(BlockImportErrorKind::Block)? }; parent_td + *header.difficulty() }, }; // insert headers and candidates entries and write era to disk. { let cur_era = candidates.entry(number) .or_insert_with(|| Entry { candidates: SmallVec::new(), canonical_hash: hash }); cur_era.candidates.push(Candidate { hash: hash, parent_hash: parent_hash, total_difficulty: total_difficulty, }); // fix ordering of era before writing. if total_difficulty > cur_era.candidates[0].total_difficulty { let cur_pos = cur_era.candidates.len() - 1; cur_era.candidates.swap(cur_pos, 0); cur_era.canonical_hash = hash; } transaction.put(self.col, era_key(number).as_bytes(), &::rlp::encode(&*cur_era)) } if let Some(transition) = transition { transaction.put(self.col, &*transition_key(hash), &transition.proof); self.live_epoch_proofs.write().insert(hash, transition); } let raw = header.encoded().into_inner(); transaction.put_vec(self.col, &hash[..], raw); // TODO: For engines when required, use cryptoeconomic guarantees. let (best_num, is_new_best) = { let cur_best = self.best_block.read(); if cur_best.total_difficulty < total_difficulty { (number, true) } else { (cur_best.number, false) } }; // reorganize ancestors so canonical entries are first in their // respective candidates vectors. if is_new_best { let mut canon_hash = hash; for (&height, entry) in candidates.iter_mut().rev().skip_while(|&(height, _)| *height > number) { if height != number && entry.canonical_hash == canon_hash { break; } trace!(target: "chain", "Setting new canonical block {} for block height {}", canon_hash, height); let canon_pos = entry.candidates.iter().position(|x| x.hash == canon_hash) .expect("blocks are only inserted if parent is present; or this is the block we just added; qed"); // move the new canonical entry to the front and set the // era's canonical hash. entry.candidates.swap(0, canon_pos); entry.canonical_hash = canon_hash; // what about reorgs > cht::SIZE + HISTORY? // resetting to the last block of a given CHT should be possible. canon_hash = entry.candidates[0].parent_hash; // write altered era to disk if height != number { let rlp_era = ::rlp::encode(&*entry); transaction.put(self.col, era_key(height).as_bytes(), &rlp_era); } } trace!(target: "chain", "New best block: ({}, {}), TD {}", number, hash, total_difficulty); pending.best_block = Some(BlockDescriptor { hash: hash, number: number, total_difficulty: total_difficulty, }); // produce next CHT root if it's time. let earliest_era = *candidates.keys().next().expect("at least one era just created; qed"); if earliest_era + HISTORY + cht::SIZE <= number { let cht_num = cht::block_to_cht_number(earliest_era) .expect("fails only for number == 0; genesis never imported; qed"); let mut last_canonical_transition = None; let cht_root = { let mut i = earliest_era; let mut live_epoch_proofs = self.live_epoch_proofs.write(); // iterable function which removes the candidates as it goes // along. this will only be called until the CHT is complete. let iter = || { let era_entry = candidates.remove(&i) .expect("all eras are sequential with no gaps; qed"); transaction.delete(self.col, era_key(i).as_bytes()); i += 1; // prune old blocks and epoch proofs. for ancient in &era_entry.candidates { let maybe_transition = live_epoch_proofs.remove(&ancient.hash); if let Some(epoch_transition) = maybe_transition { transaction.delete(self.col, &*transition_key(ancient.hash)); if ancient.hash == era_entry.canonical_hash { last_canonical_transition = match self.db.get(self.col, &ancient.hash) { Err(e) => { warn!(target: "chain", "Error reading from DB: {}\n ", e); None } Ok(None) => panic!("stored candidates always have corresponding headers; qed"), Ok(Some(header)) => Some(( epoch_transition, ::rlp::decode(&header).expect("decoding value from db failed") )), }; } } transaction.delete(self.col, &ancient.hash); } let canon = &era_entry.candidates[0]; (canon.hash, canon.total_difficulty) }; cht::compute_root(cht_num, ::itertools::repeat_call(iter)) .expect("fails only when too few items; this is checked; qed") }; // write the CHT root to the database. debug!(target: "chain", "Produced CHT {} root: {:?}", cht_num, cht_root); transaction.put(self.col, cht_key(cht_num).as_bytes(), &::rlp::encode(&cht_root)); // update the last canonical transition proof if let Some((epoch_transition, header)) = last_canonical_transition { let x = encode_canonical_transition(&header, &epoch_transition.proof); transaction.put_vec(self.col, LAST_CANONICAL_TRANSITION, x); } } } // write the best and latest eras to the database. { let latest_num = *candidates.iter().rev().next().expect("at least one era just inserted; qed").0; let curr = BestAndLatest::new(best_num, latest_num); transaction.put(self.col, CURRENT_KEY, &::rlp::encode(&curr)) } Ok(pending) } /// Generates the specifications for hardcoded sync. This is typically only called manually /// from time to time by a Parity developer in order to update the chain specifications. /// /// Returns `None` if we are at the genesis block, or if an error happens . pub fn read_hardcoded_sync(&self) -> Result, Error> { let mut chts = Vec::new(); let mut cht_num = 0; loop { let cht = match self.cht_root(cht_num) { Some(cht) => cht, None if cht_num != 0 => { // end of the iteration let h_num = 1 + cht_num as u64 * cht::SIZE; let header = if let Some(header) = self.block_header(BlockId::Number(h_num)) { header } else { let msg = format!("header of block #{} not found in DB ; database in an \ inconsistent state", h_num); bail!(msg); }; let decoded = header.decode().expect("decoding db value failed"); let entry: Entry = { let bytes = self.db.get(self.col, era_key(h_num).as_bytes())? .ok_or_else(|| { format!("entry for era #{} not found in DB ; database \ in an inconsistent state", h_num) })?; ::rlp::decode(&bytes).expect("decoding db value failed") }; let total_difficulty = entry.candidates.iter() .find(|c| c.hash == decoded.hash()) .ok_or_else(|| { "no candidate matching block found in DB ; database in an \ inconsistent state" })? .total_difficulty; break Ok(Some(SpecHardcodedSync { header, total_difficulty, chts, })); }, None => { break Ok(None); }, }; chts.push(cht); cht_num += 1; } } /// Apply pending changes from a previous `insert` operation. /// Must be done before the next `insert` call. pub fn apply_pending(&self, pending: PendingChanges) { if let Some(best_block) = pending.best_block { *self.best_block.write() = best_block; } } /// Get a block's hash by ID. In the case of query by number, only canonical results /// will be returned. pub fn block_hash(&self, id: BlockId) -> Option { match id { BlockId::Earliest | BlockId::Number(0) => Some(self.genesis_hash()), BlockId::Hash(hash) => Some(hash), BlockId::Number(num) => { if self.best_block.read().number < num { return None } self.candidates.read().get(&num).map(|entry| entry.canonical_hash) } BlockId::Latest => { Some(self.best_block.read().hash) } } } /// Get a block header. In the case of query by number, only canonical blocks /// will be returned. pub fn block_header(&self, id: BlockId) -> Option { let load_from_db = |hash: H256| { let mut cache = self.cache.lock(); match cache.block_header(&hash) { Some(header) => Some(header), None => { match self.db.get(self.col, &hash) { Ok(db_value) => { db_value.map(|x| x.into_vec()).map(encoded::Header::new) .and_then(|header| { cache.insert_block_header(hash.clone(), header.clone()); Some(header) }) }, Err(e) => { warn!(target: "chain", "Failed to read from database: {}", e); None } } } } }; match id { BlockId::Earliest | BlockId::Number(0) => Some(self.genesis_header.clone()), BlockId::Hash(hash) if hash == self.genesis_hash() => { Some(self.genesis_header.clone()) } BlockId::Hash(hash) => load_from_db(hash), BlockId::Number(num) => { if self.best_block.read().number < num { return None } self.candidates.read().get(&num).map(|entry| entry.canonical_hash) .and_then(load_from_db) } BlockId::Latest => { // hold candidates hear to prevent deletion of the header // as we read it. let _candidates = self.candidates.read(); let hash = { let best = self.best_block.read(); if best.number == 0 { return Some(self.genesis_header.clone()) } best.hash }; load_from_db(hash) } } } /// Get a block's chain score. /// Returns nothing for non-canonical blocks. pub fn score(&self, id: BlockId) -> Option { let genesis_hash = self.genesis_hash(); match id { BlockId::Earliest | BlockId::Number(0) => Some(self.genesis_header.difficulty()), BlockId::Hash(hash) if hash == genesis_hash => Some(self.genesis_header.difficulty()), BlockId::Hash(hash) => match self.block_header(BlockId::Hash(hash)) { Some(header) => self.candidates.read().get(&header.number()) .and_then(|era| era.candidates.iter().find(|e| e.hash == hash)) .map(|c| c.total_difficulty), None => None, }, BlockId::Number(num) => { let candidates = self.candidates.read(); if self.best_block.read().number < num { return None } candidates.get(&num).map(|era| era.candidates[0].total_difficulty) } BlockId::Latest => Some(self.best_block.read().total_difficulty) } } /// Get the best block's header. pub fn best_header(&self) -> encoded::Header { self.block_header(BlockId::Latest).expect("Header for best block always stored; qed") } /// Get an iterator over a block and its ancestry. pub fn ancestry_iter(&self, start: BlockId) -> AncestryIter { AncestryIter { next: self.block_header(start), chain: self, } } /// Get the nth CHT root, if it's been computed. /// /// CHT root 0 is from block `1..2048`. /// CHT root 1 is from block `2049..4096` /// and so on. /// /// This is because it's assumed that the genesis hash is known, /// so including it within a CHT would be redundant. pub fn cht_root(&self, n: usize) -> Option { match self.db.get(self.col, cht_key(n as u64).as_bytes()) { Ok(db_fetch) => db_fetch.map(|bytes| ::rlp::decode(&bytes).expect("decoding value from db failed")), Err(e) => { warn!(target: "chain", "Error reading from database: {}", e); None } } } /// Get the genesis hash. pub fn genesis_hash(&self) -> H256 { self.genesis_header.hash() } /// Get the best block's data. pub fn best_block(&self) -> BlockDescriptor { self.best_block.read().clone() } /// If there is a gap between the genesis and the rest /// of the stored blocks, return the first post-gap block. pub fn first_block(&self) -> Option { let candidates = self.candidates.read(); match candidates.iter().next() { None | Some((&1, _)) => None, Some((&height, entry)) => Some(BlockDescriptor { number: height, hash: entry.canonical_hash, total_difficulty: entry.candidates.iter().find(|x| x.hash == entry.canonical_hash) .expect("entry always stores canonical candidate; qed").total_difficulty, }) } } /// Get block status. pub fn status(&self, hash: &H256) -> BlockStatus { match self.db.get(self.col, &*hash).ok().map_or(false, |x| x.is_some()) { true => BlockStatus::InChain, false => BlockStatus::Unknown, } } /// Insert a pending transition. pub fn insert_pending_transition(&self, batch: &mut DBTransaction, hash: H256, t: PendingEpochTransition) { let key = pending_transition_key(hash); batch.put(self.col, &*key, &*::rlp::encode(&t)); } /// Get pending transition for a specific block hash. pub fn pending_transition(&self, hash: H256) -> Option { let key = pending_transition_key(hash); match self.db.get(self.col, &*key) { Ok(db_fetch) => db_fetch.map(|bytes| ::rlp::decode(&bytes).expect("decoding value from db failed")), Err(e) => { warn!(target: "chain", "Error reading from database: {}", e); None } } } /// Get the transition to the epoch the given parent hash is part of /// or transitions to. /// This will give the epoch that any children of this parent belong to. /// /// The header corresponding the the parent hash must be stored already. pub fn epoch_transition_for(&self, parent_hash: H256) -> Option<(Header, Vec)> { // slow path: loop back block by block let live_proofs = self.live_epoch_proofs.read(); for hdr in self.ancestry_iter(BlockId::Hash(parent_hash)) { if let Some(transition) = live_proofs.get(&hdr.hash()).cloned() { return hdr.decode().map(|decoded_hdr| { (decoded_hdr, transition.proof) }).ok(); } } // any blocks left must be descendants of the last canonical transition block. match self.db.get(self.col, LAST_CANONICAL_TRANSITION) { Ok(x) => { let x = x.expect("last canonical transition always instantiated; qed"); let (hdr, proof) = decode_canonical_transition(&x) .expect("last canonical transition always encoded correctly; qed"); Some((hdr, proof.to_vec())) } Err(e) => { warn!("Error reading from DB: {}", e); None } } } } impl HeapSizeOf for HeaderChain { fn heap_size_of_children(&self) -> usize { self.candidates.read().heap_size_of_children() } } /// Iterator over a block's ancestry. pub struct AncestryIter<'a> { next: Option, chain: &'a HeaderChain, } impl<'a> Iterator for AncestryIter<'a> { type Item = encoded::Header; fn next(&mut self) -> Option { let next = self.next.take(); if let Some(p_hash) = next.as_ref().map(|hdr| hdr.parent_hash()) { self.next = self.chain.block_header(BlockId::Hash(p_hash)); } next } } #[cfg(test)] mod tests { use super::{HeaderChain, HardcodedSync}; use std::sync::Arc; use ethereum_types::U256; use ethcore::ids::BlockId; use ethcore::header::Header; use ethcore::spec::Spec; use cache::Cache; use kvdb::KeyValueDB; use kvdb_memorydb; use std::time::Duration; use parking_lot::Mutex; fn make_db() -> Arc { Arc::new(kvdb_memorydb::create(0)) } #[test] fn basic_chain() { let spec = Spec::new_test(); let genesis_header = spec.genesis_header(); let db = make_db(); let cache = Arc::new(Mutex::new(Cache::new(Default::default(), Duration::from_secs(6 * 3600)))); let chain = HeaderChain::new(db.clone(), None, &spec, cache, HardcodedSync::Allow).unwrap(); let mut parent_hash = genesis_header.hash(); let mut rolling_timestamp = genesis_header.timestamp(); for i in 1..10000 { let mut header = Header::new(); header.set_parent_hash(parent_hash); header.set_number(i); header.set_timestamp(rolling_timestamp); header.set_difficulty(*genesis_header.difficulty() * i as u32); parent_hash = header.hash(); let mut tx = db.transaction(); let pending = chain.insert(&mut tx, header, None).unwrap(); db.write(tx).unwrap(); chain.apply_pending(pending); rolling_timestamp += 10; } assert!(chain.block_header(BlockId::Number(10)).is_none()); assert!(chain.block_header(BlockId::Number(9000)).is_some()); assert!(chain.cht_root(2).is_some()); assert!(chain.cht_root(3).is_none()); } #[test] fn reorganize() { let spec = Spec::new_test(); let genesis_header = spec.genesis_header(); let db = make_db(); let cache = Arc::new(Mutex::new(Cache::new(Default::default(), Duration::from_secs(6 * 3600)))); let chain = HeaderChain::new(db.clone(), None, &spec, cache, HardcodedSync::Allow).unwrap(); let mut parent_hash = genesis_header.hash(); let mut rolling_timestamp = genesis_header.timestamp(); for i in 1..6 { let mut header = Header::new(); header.set_parent_hash(parent_hash); header.set_number(i); header.set_timestamp(rolling_timestamp); header.set_difficulty(*genesis_header.difficulty() * i as u32); parent_hash = header.hash(); let mut tx = db.transaction(); let pending = chain.insert(&mut tx, header, None).unwrap(); db.write(tx).unwrap(); chain.apply_pending(pending); rolling_timestamp += 10; } { let mut rolling_timestamp = rolling_timestamp; let mut parent_hash = parent_hash; for i in 6..16 { let mut header = Header::new(); header.set_parent_hash(parent_hash); header.set_number(i); header.set_timestamp(rolling_timestamp); header.set_difficulty(*genesis_header.difficulty() * i as u32); parent_hash = header.hash(); let mut tx = db.transaction(); let pending = chain.insert(&mut tx, header, None).unwrap(); db.write(tx).unwrap(); chain.apply_pending(pending); rolling_timestamp += 10; } } assert_eq!(chain.best_block().number, 15); { let mut rolling_timestamp = rolling_timestamp; let mut parent_hash = parent_hash; // import a shorter chain which has better TD. for i in 6..13 { let mut header = Header::new(); header.set_parent_hash(parent_hash); header.set_number(i); header.set_timestamp(rolling_timestamp); header.set_difficulty(*genesis_header.difficulty() * U256::from(i * i)); parent_hash = header.hash(); let mut tx = db.transaction(); let pending = chain.insert(&mut tx, header, None).unwrap(); db.write(tx).unwrap(); chain.apply_pending(pending); rolling_timestamp += 11; } } let (mut num, mut canon_hash) = (chain.best_block().number, chain.best_block().hash); assert_eq!(num, 12); while num > 0 { let header = chain.block_header(BlockId::Number(num)).unwrap(); assert_eq!(header.hash(), canon_hash); canon_hash = header.parent_hash(); num -= 1; } } #[test] fn earliest_is_latest() { let spec = Spec::new_test(); let db = make_db(); let cache = Arc::new(Mutex::new(Cache::new(Default::default(), Duration::from_secs(6 * 3600)))); let chain = HeaderChain::new(db.clone(), None, &spec, cache, HardcodedSync::Allow).unwrap(); assert!(chain.block_header(BlockId::Earliest).is_some()); assert!(chain.block_header(BlockId::Latest).is_some()); } #[test] fn restore_from_db() { let spec = Spec::new_test(); let genesis_header = spec.genesis_header(); let db = make_db(); let cache = Arc::new(Mutex::new(Cache::new(Default::default(), Duration::from_secs(6 * 3600)))); { let chain = HeaderChain::new(db.clone(), None, &spec, cache.clone(), HardcodedSync::Allow).unwrap(); let mut parent_hash = genesis_header.hash(); let mut rolling_timestamp = genesis_header.timestamp(); for i in 1..10000 { let mut header = Header::new(); header.set_parent_hash(parent_hash); header.set_number(i); header.set_timestamp(rolling_timestamp); header.set_difficulty(*genesis_header.difficulty() * i as u32); parent_hash = header.hash(); let mut tx = db.transaction(); let pending = chain.insert(&mut tx, header, None).unwrap(); db.write(tx).unwrap(); chain.apply_pending(pending); rolling_timestamp += 10; } } let chain = HeaderChain::new(db.clone(), None, &spec, cache.clone(), HardcodedSync::Allow).unwrap(); assert!(chain.block_header(BlockId::Number(10)).is_none()); assert!(chain.block_header(BlockId::Number(9000)).is_some()); assert!(chain.cht_root(2).is_some()); assert!(chain.cht_root(3).is_none()); assert_eq!(chain.block_header(BlockId::Latest).unwrap().number(), 9999); } #[test] fn restore_higher_non_canonical() { let spec = Spec::new_test(); let genesis_header = spec.genesis_header(); let db = make_db(); let cache = Arc::new(Mutex::new(Cache::new(Default::default(), Duration::from_secs(6 * 3600)))); { let chain = HeaderChain::new(db.clone(), None, &spec, cache.clone(), HardcodedSync::Allow).unwrap(); let mut parent_hash = genesis_header.hash(); let mut rolling_timestamp = genesis_header.timestamp(); // push 100 low-difficulty blocks. for i in 1..101 { let mut header = Header::new(); header.set_parent_hash(parent_hash); header.set_number(i); header.set_timestamp(rolling_timestamp); header.set_difficulty(*genesis_header.difficulty() * i as u32); parent_hash = header.hash(); let mut tx = db.transaction(); let pending = chain.insert(&mut tx, header, None).unwrap(); db.write(tx).unwrap(); chain.apply_pending(pending); rolling_timestamp += 10; } // push fewer high-difficulty blocks. for i in 1..11 { let mut header = Header::new(); header.set_parent_hash(parent_hash); header.set_number(i); header.set_timestamp(rolling_timestamp); header.set_difficulty(*genesis_header.difficulty() * U256::from(i as u32 * 1000u32)); parent_hash = header.hash(); let mut tx = db.transaction(); let pending = chain.insert(&mut tx, header, None).unwrap(); db.write(tx).unwrap(); chain.apply_pending(pending); rolling_timestamp += 10; } assert_eq!(chain.block_header(BlockId::Latest).unwrap().number(), 10); } // after restoration, non-canonical eras should still be loaded. let chain = HeaderChain::new(db.clone(), None, &spec, cache.clone(), HardcodedSync::Allow).unwrap(); assert_eq!(chain.block_header(BlockId::Latest).unwrap().number(), 10); assert!(chain.candidates.read().get(&100).is_some()) } #[test] fn genesis_header_available() { let spec = Spec::new_test(); let genesis_header = spec.genesis_header(); let db = make_db(); let cache = Arc::new(Mutex::new(Cache::new(Default::default(), Duration::from_secs(6 * 3600)))); let chain = HeaderChain::new(db.clone(), None, &spec, cache.clone(), HardcodedSync::Allow).unwrap(); assert!(chain.block_header(BlockId::Earliest).is_some()); assert!(chain.block_header(BlockId::Number(0)).is_some()); assert!(chain.block_header(BlockId::Hash(genesis_header.hash())).is_some()); } #[test] fn epoch_transitions_available_after_cht() { let spec = Spec::new_test(); let genesis_header = spec.genesis_header(); let db = make_db(); let cache = Arc::new(Mutex::new(Cache::new(Default::default(), Duration::from_secs(6 * 3600)))); let chain = HeaderChain::new(db.clone(), None, &spec, cache, HardcodedSync::Allow).unwrap(); let mut parent_hash = genesis_header.hash(); let mut rolling_timestamp = genesis_header.timestamp(); for i in 1..6 { let mut header = Header::new(); header.set_parent_hash(parent_hash); header.set_number(i); header.set_timestamp(rolling_timestamp); header.set_difficulty(*genesis_header.difficulty() * i as u32); parent_hash = header.hash(); let mut tx = db.transaction(); let epoch_proof = if i == 3 { Some(vec![1, 2, 3, 4]) } else { None }; let pending = chain.insert(&mut tx, header, epoch_proof).unwrap(); db.write(tx).unwrap(); chain.apply_pending(pending); rolling_timestamp += 10; } // these 3 should end up falling back to the genesis epoch proof in DB for i in 0..3 { let hash = chain.block_hash(BlockId::Number(i)).unwrap(); assert_eq!(chain.epoch_transition_for(hash).unwrap().1, Vec::::new()); } // these are live. for i in 3..6 { let hash = chain.block_hash(BlockId::Number(i)).unwrap(); assert_eq!(chain.epoch_transition_for(hash).unwrap().1, vec![1, 2, 3, 4]); } for i in 6..10000 { let mut header = Header::new(); header.set_parent_hash(parent_hash); header.set_number(i); header.set_timestamp(rolling_timestamp); header.set_difficulty(*genesis_header.difficulty() * i as u32); parent_hash = header.hash(); let mut tx = db.transaction(); let pending = chain.insert(&mut tx, header, None).unwrap(); db.write(tx).unwrap(); chain.apply_pending(pending); rolling_timestamp += 10; } // no live blocks have associated epoch proofs -- make sure we aren't leaking memory. assert!(chain.live_epoch_proofs.read().is_empty()); assert_eq!(chain.epoch_transition_for(parent_hash).unwrap().1, vec![1, 2, 3, 4]); } #[test] fn hardcoded_sync_gen() { let spec = Spec::new_test(); let genesis_header = spec.genesis_header(); let db = make_db(); let cache = Arc::new(Mutex::new(Cache::new(Default::default(), Duration::from_secs(6 * 3600)))); let chain = HeaderChain::new(db.clone(), None, &spec, cache, HardcodedSync::Allow).expect("failed to instantiate a new HeaderChain"); let mut parent_hash = genesis_header.hash(); let mut rolling_timestamp = genesis_header.timestamp(); let mut total_difficulty = *genesis_header.difficulty(); let h_num = 3 * ::cht::SIZE + 1; for i in 1..10000 { let mut header = Header::new(); header.set_parent_hash(parent_hash); header.set_number(i); header.set_timestamp(rolling_timestamp); let diff = *genesis_header.difficulty() * i as u32; header.set_difficulty(diff); if i <= h_num { total_difficulty = total_difficulty + diff; } parent_hash = header.hash(); let mut tx = db.transaction(); let pending = chain.insert(&mut tx, header, None).expect("failed inserting a transaction"); db.write(tx).unwrap(); chain.apply_pending(pending); rolling_timestamp += 10; } let hardcoded_sync = chain.read_hardcoded_sync().expect("failed reading hardcoded sync").expect("failed unwrapping hardcoded sync"); assert_eq!(hardcoded_sync.chts.len(), 3); assert_eq!(hardcoded_sync.total_difficulty, total_difficulty); let decoded: Header = hardcoded_sync.header.decode().expect("decoding failed"); assert_eq!(decoded.number(), h_num); } }