// 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 . //! Client backend that is backed by a database. //! //! # Canonicality vs. Finality //! //! Finality indicates that a block will not be reverted, according to the consensus algorithm, //! while canonicality indicates that the block may be reverted, but we will be unable to do so, //! having discarded heavy state that will allow a chain reorganization. //! //! Finality implies canonicality but not vice-versa. #![warn(missing_docs)] pub mod light; pub mod offchain; #[cfg(any(feature = "with-kvdb-rocksdb", test))] pub mod bench; mod cache; mod changes_tries_storage; mod children; #[cfg(feature = "with-parity-db")] mod parity_db; mod stats; mod storage_cache; #[cfg(any(feature = "with-kvdb-rocksdb", test))] mod upgrade; mod utils; use linked_hash_map::LinkedHashMap; use log::{debug, trace, warn}; use parking_lot::{Mutex, RwLock}; use std::{ collections::{HashMap, HashSet}, io, path::{Path, PathBuf}, sync::Arc, }; use crate::{ changes_tries_storage::{DbChangesTrieStorage, DbChangesTrieStorageTransaction}, stats::StateUsageStats, storage_cache::{new_shared_cache, CachingState, SharedCache, SyncingCachingState}, utils::{meta_keys, read_db, read_meta, DatabaseType, Meta}, }; use codec::{Decode, Encode}; use hash_db::Prefix; use sc_client_api::{ backend::{NewBlockState, ProvideChtRoots, PrunableStateChangesTrieStorage}, cht, leaves::{FinalizationDisplaced, LeafSet}, utils::is_descendent_of, IoInfo, MemoryInfo, MemorySize, UsageInfo, }; use sc_state_db::StateDb; use sp_arithmetic::traits::Saturating; use sp_blockchain::{ well_known_cache_keys, Backend as _, CachedHeaderMetadata, Error as ClientError, HeaderBackend, HeaderMetadata, HeaderMetadataCache, Result as ClientResult, }; use sp_core::{ offchain::OffchainOverlayedChange, storage::{well_known_keys, ChildInfo}, ChangesTrieConfiguration, }; use sp_database::Transaction; use sp_runtime::{ generic::{BlockId, DigestItem}, traits::{ Block as BlockT, Hash, HashFor, Header as HeaderT, NumberFor, One, SaturatedConversion, Zero, }, Justification, Justifications, Storage, }; use sp_state_machine::{ backend::Backend as StateBackend, ChangesTrieCacheAction, ChangesTrieTransaction, ChildStorageCollection, DBValue, IndexOperation, OffchainChangesCollection, StateMachineStats, StorageCollection, UsageInfo as StateUsageInfo, }; use sp_trie::{prefixed_key, MemoryDB, PrefixedMemoryDB}; // Re-export the Database trait so that one can pass an implementation of it. pub use sc_state_db::PruningMode; pub use sp_database::Database; #[cfg(any(feature = "with-kvdb-rocksdb", test))] pub use bench::BenchmarkingState; const MIN_BLOCKS_TO_KEEP_CHANGES_TRIES_FOR: u32 = 32768; const CACHE_HEADERS: usize = 8; /// Default value for storage cache child ratio. const DEFAULT_CHILD_RATIO: (usize, usize) = (1, 10); /// DB-backed patricia trie state, transaction type is an overlay of changes to commit. pub type DbState = sp_state_machine::TrieBackend>>, HashFor>; const DB_HASH_LEN: usize = 32; /// Hash type that this backend uses for the database. pub type DbHash = sp_core::H256; /// This is used as block body when storage-chain mode is enabled. #[derive(Debug, Encode, Decode)] struct ExtrinsicHeader { /// Hash of the indexed part indexed_hash: DbHash, // Zero hash if there's no indexed data /// The rest of the data. data: Vec, } /// A reference tracking state. /// /// It makes sure that the hash we are using stays pinned in storage /// until this structure is dropped. pub struct RefTrackingState { state: DbState, storage: Arc>, parent_hash: Option, } impl RefTrackingState { fn new(state: DbState, storage: Arc>, parent_hash: Option) -> Self { RefTrackingState { state, parent_hash, storage } } } impl Drop for RefTrackingState { fn drop(&mut self) { if let Some(hash) = &self.parent_hash { self.storage.state_db.unpin(hash); } } } impl std::fmt::Debug for RefTrackingState { fn fmt(&self, f: &mut std::fmt::Formatter<'_>) -> std::fmt::Result { write!(f, "Block {:?}", self.parent_hash) } } impl StateBackend> for RefTrackingState { type Error = as StateBackend>>::Error; type Transaction = as StateBackend>>::Transaction; type TrieBackendStorage = as StateBackend>>::TrieBackendStorage; fn storage(&self, key: &[u8]) -> Result>, Self::Error> { self.state.storage(key) } fn storage_hash(&self, key: &[u8]) -> Result, Self::Error> { self.state.storage_hash(key) } fn child_storage( &self, child_info: &ChildInfo, key: &[u8], ) -> Result>, Self::Error> { self.state.child_storage(child_info, key) } fn exists_storage(&self, key: &[u8]) -> Result { self.state.exists_storage(key) } fn exists_child_storage( &self, child_info: &ChildInfo, key: &[u8], ) -> Result { self.state.exists_child_storage(child_info, key) } fn next_storage_key(&self, key: &[u8]) -> Result>, Self::Error> { self.state.next_storage_key(key) } fn next_child_storage_key( &self, child_info: &ChildInfo, key: &[u8], ) -> Result>, Self::Error> { self.state.next_child_storage_key(child_info, key) } fn for_keys_with_prefix(&self, prefix: &[u8], f: F) { self.state.for_keys_with_prefix(prefix, f) } fn for_key_values_with_prefix(&self, prefix: &[u8], f: F) { self.state.for_key_values_with_prefix(prefix, f) } fn apply_to_key_values_while, Vec) -> bool>( &self, child_info: Option<&ChildInfo>, prefix: Option<&[u8]>, start_at: Option<&[u8]>, f: F, allow_missing: bool, ) -> Result { self.state .apply_to_key_values_while(child_info, prefix, start_at, f, allow_missing) } fn apply_to_keys_while bool>( &self, child_info: Option<&ChildInfo>, prefix: Option<&[u8]>, f: F, ) { self.state.apply_to_keys_while(child_info, prefix, f) } fn for_child_keys_with_prefix( &self, child_info: &ChildInfo, prefix: &[u8], f: F, ) { self.state.for_child_keys_with_prefix(child_info, prefix, f) } fn storage_root<'a>( &self, delta: impl Iterator)>, ) -> (B::Hash, Self::Transaction) where B::Hash: Ord, { self.state.storage_root(delta) } fn child_storage_root<'a>( &self, child_info: &ChildInfo, delta: impl Iterator)>, ) -> (B::Hash, bool, Self::Transaction) where B::Hash: Ord, { self.state.child_storage_root(child_info, delta) } fn pairs(&self) -> Vec<(Vec, Vec)> { self.state.pairs() } fn keys(&self, prefix: &[u8]) -> Vec> { self.state.keys(prefix) } fn child_keys(&self, child_info: &ChildInfo, prefix: &[u8]) -> Vec> { self.state.child_keys(child_info, prefix) } fn as_trie_backend( &self, ) -> Option<&sp_state_machine::TrieBackend>> { self.state.as_trie_backend() } fn register_overlay_stats(&self, stats: &StateMachineStats) { self.state.register_overlay_stats(stats); } fn usage_info(&self) -> StateUsageInfo { self.state.usage_info() } } /// Database settings. pub struct DatabaseSettings { /// State cache size. pub state_cache_size: usize, /// Ratio of cache size dedicated to child tries. pub state_cache_child_ratio: Option<(usize, usize)>, /// State pruning mode. pub state_pruning: PruningMode, /// Where to find the database. pub source: DatabaseSource, /// Block pruning mode. pub keep_blocks: KeepBlocks, /// Block body/Transaction storage scheme. pub transaction_storage: TransactionStorageMode, } /// Block pruning settings. #[derive(Debug, Clone, Copy)] pub enum KeepBlocks { /// Keep full block history. All, /// Keep N recent finalized blocks. Some(u32), } /// Block body storage scheme. #[derive(Debug, Clone, Copy)] pub enum TransactionStorageMode { /// Store block body as an encoded list of full transactions in the BODY column BlockBody, /// Store a list of hashes in the BODY column and each transaction individually /// in the TRANSACTION column. StorageChain, } /// Where to find the database.. #[derive(Debug, Clone)] pub enum DatabaseSource { /// Check given path, and see if there is an existing database there. If it's either `RocksDb` /// or `ParityDb`, use it. If there is none, create a new instance of `ParityDb`. Auto { /// Path to the paritydb database. paritydb_path: PathBuf, /// Path to the rocksdb database. rocksdb_path: PathBuf, /// Cache size in MiB. Used only by `RocksDb` variant of `DatabaseSource`. cache_size: usize, }, /// Load a RocksDB database from a given path. Recommended for most uses. RocksDb { /// Path to the database. path: PathBuf, /// Cache size in MiB. cache_size: usize, }, /// Load a ParityDb database from a given path. ParityDb { /// Path to the database. path: PathBuf, }, /// Use a custom already-open database. Custom(Arc>), } impl DatabaseSource { /// Return path for databases that are stored on disk. pub fn path(&self) -> Option<&Path> { match self { // as per https://github.com/paritytech/substrate/pull/9500#discussion_r684312550 // // IIUC this is needed for polkadot to create its own dbs, so until it can use parity db // I would think rocksdb, but later parity-db. DatabaseSource::Auto { paritydb_path, .. } => Some(&paritydb_path), DatabaseSource::RocksDb { path, .. } | DatabaseSource::ParityDb { path } => Some(&path), DatabaseSource::Custom(..) => None, } } /// Set path for databases that are stored on disk. pub fn set_path(&mut self, p: &Path) -> bool { match self { DatabaseSource::Auto { ref mut paritydb_path, .. } => { *paritydb_path = p.into(); true }, DatabaseSource::RocksDb { ref mut path, .. } | DatabaseSource::ParityDb { ref mut path } => { *path = p.into(); true }, DatabaseSource::Custom(..) => false, } } } impl std::fmt::Display for DatabaseSource { fn fmt(&self, f: &mut std::fmt::Formatter<'_>) -> std::fmt::Result { let name = match self { DatabaseSource::Auto { .. } => "Auto", DatabaseSource::RocksDb { .. } => "RocksDb", DatabaseSource::ParityDb { .. } => "ParityDb", DatabaseSource::Custom(_) => "Custom", }; write!(f, "{}", name) } } pub(crate) mod columns { pub const META: u32 = crate::utils::COLUMN_META; pub const STATE: u32 = 1; pub const STATE_META: u32 = 2; /// maps hashes to lookup keys and numbers to canon hashes. pub const KEY_LOOKUP: u32 = 3; pub const HEADER: u32 = 4; pub const BODY: u32 = 5; pub const JUSTIFICATIONS: u32 = 6; pub const CHANGES_TRIE: u32 = 7; pub const AUX: u32 = 8; /// Offchain workers local storage pub const OFFCHAIN: u32 = 9; pub const CACHE: u32 = 10; /// Transactions pub const TRANSACTION: u32 = 11; } struct PendingBlock { header: Block::Header, justifications: Option, body: Option>, indexed_body: Option>>, leaf_state: NewBlockState, } // wrapper that implements trait required for state_db struct StateMetaDb<'a>(&'a dyn Database); impl<'a> sc_state_db::MetaDb for StateMetaDb<'a> { type Error = io::Error; fn get_meta(&self, key: &[u8]) -> Result>, Self::Error> { Ok(self.0.get(columns::STATE_META, key)) } } struct MetaUpdate { pub hash: Block::Hash, pub number: NumberFor, pub is_best: bool, pub is_finalized: bool, pub with_state: bool, } fn cache_header( cache: &mut LinkedHashMap>, hash: Hash, header: Option
, ) { cache.insert(hash, header); while cache.len() > CACHE_HEADERS { cache.pop_front(); } } /// Block database pub struct BlockchainDb { db: Arc>, meta: Arc, Block::Hash>>>, leaves: RwLock>>, header_metadata_cache: Arc>, header_cache: Mutex>>, transaction_storage: TransactionStorageMode, } impl BlockchainDb { fn new( db: Arc>, transaction_storage: TransactionStorageMode, ) -> ClientResult { let meta = read_meta::(&*db, columns::HEADER)?; let leaves = LeafSet::read_from_db(&*db, columns::META, meta_keys::LEAF_PREFIX)?; Ok(BlockchainDb { db, leaves: RwLock::new(leaves), meta: Arc::new(RwLock::new(meta)), header_metadata_cache: Arc::new(HeaderMetadataCache::default()), header_cache: Default::default(), transaction_storage, }) } fn update_meta(&self, update: MetaUpdate) { let MetaUpdate { hash, number, is_best, is_finalized, with_state } = update; let mut meta = self.meta.write(); if number.is_zero() { meta.genesis_hash = hash; meta.finalized_hash = hash; } if is_best { meta.best_number = number; meta.best_hash = hash; } if is_finalized { if with_state { meta.finalized_state = Some((hash.clone(), number)); } meta.finalized_number = number; meta.finalized_hash = hash; } } // Get block changes trie root, if available. fn changes_trie_root(&self, block: BlockId) -> ClientResult> { self.header(block).map(|header| { header.and_then(|header| header.digest().log(DigestItem::as_changes_trie_root).cloned()) }) } } impl sc_client_api::blockchain::HeaderBackend for BlockchainDb { fn header(&self, id: BlockId) -> ClientResult> { match &id { BlockId::Hash(h) => { let mut cache = self.header_cache.lock(); if let Some(result) = cache.get_refresh(h) { return Ok(result.clone()) } let header = utils::read_header(&*self.db, columns::KEY_LOOKUP, columns::HEADER, id)?; cache_header(&mut cache, h.clone(), header.clone()); Ok(header) }, BlockId::Number(_) => utils::read_header(&*self.db, columns::KEY_LOOKUP, columns::HEADER, id), } } fn info(&self) -> sc_client_api::blockchain::Info { let meta = self.meta.read(); sc_client_api::blockchain::Info { best_hash: meta.best_hash, best_number: meta.best_number, genesis_hash: meta.genesis_hash, finalized_hash: meta.finalized_hash, finalized_number: meta.finalized_number, finalized_state: meta.finalized_state.clone(), number_leaves: self.leaves.read().count(), } } fn status(&self, id: BlockId) -> ClientResult { let exists = match id { BlockId::Hash(_) => self.header(id)?.is_some(), BlockId::Number(n) => n <= self.meta.read().best_number, }; match exists { true => Ok(sc_client_api::blockchain::BlockStatus::InChain), false => Ok(sc_client_api::blockchain::BlockStatus::Unknown), } } fn number(&self, hash: Block::Hash) -> ClientResult>> { Ok(self.header_metadata(hash).ok().map(|header_metadata| header_metadata.number)) } fn hash(&self, number: NumberFor) -> ClientResult> { self.header(BlockId::Number(number)) .and_then(|maybe_header| match maybe_header { Some(header) => Ok(Some(header.hash().clone())), None => Ok(None), }) } } impl sc_client_api::blockchain::Backend for BlockchainDb { fn body(&self, id: BlockId) -> ClientResult>> { let body = match read_db(&*self.db, columns::KEY_LOOKUP, columns::BODY, id)? { Some(body) => body, None => return Ok(None), }; match self.transaction_storage { TransactionStorageMode::BlockBody => match Decode::decode(&mut &body[..]) { Ok(body) => Ok(Some(body)), Err(err) => return Err(sp_blockchain::Error::Backend(format!( "Error decoding body: {}", err ))), }, TransactionStorageMode::StorageChain => { match Vec::::decode(&mut &body[..]) { Ok(index) => { let extrinsics: ClientResult> = index .into_iter() .map(|ExtrinsicHeader { indexed_hash, data }| { let decode_result = if indexed_hash != Default::default() { match self.db.get(columns::TRANSACTION, indexed_hash.as_ref()) { Some(t) => { let mut input = utils::join_input(data.as_ref(), t.as_ref()); Block::Extrinsic::decode(&mut input) }, None => return Err(sp_blockchain::Error::Backend(format!( "Missing indexed transaction {:?}", indexed_hash ))), } } else { Block::Extrinsic::decode(&mut data.as_ref()) }; decode_result.map_err(|err| { sp_blockchain::Error::Backend(format!( "Error decoding extrinsic: {}", err )) }) }) .collect(); Ok(Some(extrinsics?)) }, Err(err) => return Err(sp_blockchain::Error::Backend(format!( "Error decoding body list: {}", err ))), } }, } } fn justifications(&self, id: BlockId) -> ClientResult> { match read_db(&*self.db, columns::KEY_LOOKUP, columns::JUSTIFICATIONS, id)? { Some(justifications) => match Decode::decode(&mut &justifications[..]) { Ok(justifications) => Ok(Some(justifications)), Err(err) => return Err(sp_blockchain::Error::Backend(format!( "Error decoding justifications: {}", err ))), }, None => Ok(None), } } fn last_finalized(&self) -> ClientResult { Ok(self.meta.read().finalized_hash.clone()) } fn cache(&self) -> Option>> { None } fn leaves(&self) -> ClientResult> { Ok(self.leaves.read().hashes()) } fn children(&self, parent_hash: Block::Hash) -> ClientResult> { children::read_children(&*self.db, columns::META, meta_keys::CHILDREN_PREFIX, parent_hash) } fn indexed_transaction(&self, hash: &Block::Hash) -> ClientResult>> { Ok(self.db.get(columns::TRANSACTION, hash.as_ref())) } fn has_indexed_transaction(&self, hash: &Block::Hash) -> ClientResult { Ok(self.db.contains(columns::TRANSACTION, hash.as_ref())) } fn block_indexed_body(&self, id: BlockId) -> ClientResult>>> { match self.transaction_storage { TransactionStorageMode::BlockBody => Ok(None), TransactionStorageMode::StorageChain => { let body = match read_db(&*self.db, columns::KEY_LOOKUP, columns::BODY, id)? { Some(body) => body, None => return Ok(None), }; match Vec::::decode(&mut &body[..]) { Ok(index) => { let mut transactions = Vec::new(); for ExtrinsicHeader { indexed_hash, .. } in index.into_iter() { if indexed_hash != Default::default() { match self.db.get(columns::TRANSACTION, indexed_hash.as_ref()) { Some(t) => transactions.push(t), None => return Err(sp_blockchain::Error::Backend(format!( "Missing indexed transaction {:?}", indexed_hash ))), } } } Ok(Some(transactions)) }, Err(err) => return Err(sp_blockchain::Error::Backend(format!( "Error decoding body list: {}", err ))), } }, } } } impl sc_client_api::blockchain::ProvideCache for BlockchainDb { fn cache(&self) -> Option>> { None } } impl HeaderMetadata for BlockchainDb { type Error = sp_blockchain::Error; fn header_metadata( &self, hash: Block::Hash, ) -> Result, Self::Error> { self.header_metadata_cache.header_metadata(hash).map_or_else( || { self.header(BlockId::hash(hash))? .map(|header| { let header_metadata = CachedHeaderMetadata::from(&header); self.header_metadata_cache .insert_header_metadata(header_metadata.hash, header_metadata.clone()); header_metadata }) .ok_or_else(|| { ClientError::UnknownBlock(format!( "Header was not found in the database: {:?}", hash )) }) }, Ok, ) } fn insert_header_metadata(&self, hash: Block::Hash, metadata: CachedHeaderMetadata) { self.header_metadata_cache.insert_header_metadata(hash, metadata) } fn remove_header_metadata(&self, hash: Block::Hash) { self.header_cache.lock().remove(&hash); self.header_metadata_cache.remove_header_metadata(hash); } } impl ProvideChtRoots for BlockchainDb { fn header_cht_root( &self, cht_size: NumberFor, block: NumberFor, ) -> sp_blockchain::Result> { let cht_number = match cht::block_to_cht_number(cht_size, block) { Some(number) => number, None => return Ok(None), }; let cht_start: NumberFor = cht::start_number(cht::size(), cht_number); let mut current_num = cht_start; let cht_range = ::std::iter::from_fn(|| { let old_current_num = current_num; current_num = current_num + One::one(); Some(old_current_num) }); cht::compute_root::, _>( cht::size(), cht_number, cht_range.map(|num| self.hash(num)), ) .map(Some) } fn changes_trie_cht_root( &self, cht_size: NumberFor, block: NumberFor, ) -> sp_blockchain::Result> { let cht_number = match cht::block_to_cht_number(cht_size, block) { Some(number) => number, None => return Ok(None), }; let cht_start: NumberFor = cht::start_number(cht::size(), cht_number); let mut current_num = cht_start; let cht_range = ::std::iter::from_fn(|| { let old_current_num = current_num; current_num = current_num + One::one(); Some(old_current_num) }); cht::compute_root::, _>( cht::size(), cht_number, cht_range.map(|num| self.changes_trie_root(BlockId::Number(num))), ) .map(Some) } } /// Database transaction pub struct BlockImportOperation { old_state: SyncingCachingState, Block>, db_updates: PrefixedMemoryDB>, storage_updates: StorageCollection, child_storage_updates: ChildStorageCollection, offchain_storage_updates: OffchainChangesCollection, changes_trie_updates: MemoryDB>, changes_trie_build_cache_update: Option>>, changes_trie_config_update: Option>, pending_block: Option>, aux_ops: Vec<(Vec, Option>)>, finalized_blocks: Vec<(BlockId, Option)>, set_head: Option>, commit_state: bool, index_ops: Vec, } impl BlockImportOperation { fn apply_offchain(&mut self, transaction: &mut Transaction) { let mut count = 0; for ((prefix, key), value_operation) in self.offchain_storage_updates.drain(..) { count += 1; let key = crate::offchain::concatenate_prefix_and_key(&prefix, &key); match value_operation { OffchainOverlayedChange::SetValue(val) => transaction.set_from_vec(columns::OFFCHAIN, &key, val), OffchainOverlayedChange::Remove => transaction.remove(columns::OFFCHAIN, &key), } } if count > 0 { log::debug!(target: "sc_offchain", "Applied {} offchain indexing changes.", count); } } fn apply_aux(&mut self, transaction: &mut Transaction) { for (key, maybe_val) in self.aux_ops.drain(..) { match maybe_val { Some(val) => transaction.set_from_vec(columns::AUX, &key, val), None => transaction.remove(columns::AUX, &key), } } } fn apply_new_state(&mut self, storage: Storage) -> ClientResult { if storage.top.keys().any(|k| well_known_keys::is_child_storage_key(&k)) { return Err(sp_blockchain::Error::InvalidState.into()) } let child_delta = storage.children_default.iter().map(|(_storage_key, child_content)| { ( &child_content.child_info, child_content.data.iter().map(|(k, v)| (&k[..], Some(&v[..]))), ) }); let mut changes_trie_config = None; let (root, transaction) = self.old_state.full_storage_root( storage.top.iter().map(|(k, v)| { if &k[..] == well_known_keys::CHANGES_TRIE_CONFIG { changes_trie_config = Some(Decode::decode(&mut &v[..])); } (&k[..], Some(&v[..])) }), child_delta, ); let changes_trie_config = match changes_trie_config { Some(Ok(c)) => Some(c), Some(Err(_)) => return Err(sp_blockchain::Error::InvalidState.into()), None => None, }; self.db_updates = transaction; self.changes_trie_config_update = Some(changes_trie_config); Ok(root) } } impl sc_client_api::backend::BlockImportOperation for BlockImportOperation { type State = SyncingCachingState, Block>; fn state(&self) -> ClientResult> { Ok(Some(&self.old_state)) } fn set_block_data( &mut self, header: Block::Header, body: Option>, indexed_body: Option>>, justifications: Option, leaf_state: NewBlockState, ) -> ClientResult<()> { assert!(self.pending_block.is_none(), "Only one block per operation is allowed"); if let Some(changes_trie_config_update) = changes_tries_storage::extract_new_configuration(&header) { self.changes_trie_config_update = Some(changes_trie_config_update.clone()); } self.pending_block = Some(PendingBlock { header, body, indexed_body, justifications, leaf_state }); Ok(()) } fn update_cache(&mut self, _cache: HashMap>) { // Currently cache isn't implemented on full nodes. } fn update_db_storage(&mut self, update: PrefixedMemoryDB>) -> ClientResult<()> { self.db_updates = update; Ok(()) } fn reset_storage(&mut self, storage: Storage) -> ClientResult { let root = self.apply_new_state(storage)?; self.commit_state = true; Ok(root) } fn set_genesis_state(&mut self, storage: Storage, commit: bool) -> ClientResult { let root = self.apply_new_state(storage)?; self.commit_state = commit; Ok(root) } fn update_changes_trie( &mut self, update: ChangesTrieTransaction, NumberFor>, ) -> ClientResult<()> { self.changes_trie_updates = update.0; self.changes_trie_build_cache_update = Some(update.1); Ok(()) } fn insert_aux(&mut self, ops: I) -> ClientResult<()> where I: IntoIterator, Option>)>, { self.aux_ops.append(&mut ops.into_iter().collect()); Ok(()) } fn update_storage( &mut self, update: StorageCollection, child_update: ChildStorageCollection, ) -> ClientResult<()> { self.storage_updates = update; self.child_storage_updates = child_update; Ok(()) } fn update_offchain_storage( &mut self, offchain_update: OffchainChangesCollection, ) -> ClientResult<()> { self.offchain_storage_updates = offchain_update; Ok(()) } fn mark_finalized( &mut self, block: BlockId, justification: Option, ) -> ClientResult<()> { self.finalized_blocks.push((block, justification)); Ok(()) } fn mark_head(&mut self, block: BlockId) -> ClientResult<()> { assert!(self.set_head.is_none(), "Only one set head per operation is allowed"); self.set_head = Some(block); Ok(()) } fn update_transaction_index(&mut self, index_ops: Vec) -> ClientResult<()> { self.index_ops = index_ops; Ok(()) } } struct StorageDb { pub db: Arc>, pub state_db: StateDb>, prefix_keys: bool, } impl sp_state_machine::Storage> for StorageDb { fn get(&self, key: &Block::Hash, prefix: Prefix) -> Result, String> { if self.prefix_keys { let key = prefixed_key::>(key, prefix); self.state_db.get(&key, self) } else { self.state_db.get(key.as_ref(), self) } .map_err(|e| format!("Database backend error: {:?}", e)) } } impl sc_state_db::NodeDb for StorageDb { type Error = io::Error; type Key = [u8]; fn get(&self, key: &[u8]) -> Result>, Self::Error> { Ok(self.db.get(columns::STATE, key)) } } struct DbGenesisStorage { root: Block::Hash, storage: PrefixedMemoryDB>, } impl DbGenesisStorage { pub fn new(root: Block::Hash, storage: PrefixedMemoryDB>) -> Self { DbGenesisStorage { root, storage } } } impl sp_state_machine::Storage> for DbGenesisStorage { fn get(&self, key: &Block::Hash, prefix: Prefix) -> Result, String> { use hash_db::HashDB; Ok(self.storage.get(key, prefix)) } } struct EmptyStorage(pub Block::Hash); impl EmptyStorage { pub fn new() -> Self { let mut root = Block::Hash::default(); let mut mdb = MemoryDB::>::default(); sp_state_machine::TrieDBMut::>::new(&mut mdb, &mut root); EmptyStorage(root) } } impl sp_state_machine::Storage> for EmptyStorage { fn get(&self, _key: &Block::Hash, _prefix: Prefix) -> Result, String> { Ok(None) } } /// Frozen `value` at time `at`. /// /// Used as inner structure under lock in `FrozenForDuration`. struct Frozen { at: std::time::Instant, value: Option, } /// Some value frozen for period of time. /// /// If time `duration` not passed since the value was instantiated, /// current frozen value is returned. Otherwise, you have to provide /// a new value which will be again frozen for `duration`. pub(crate) struct FrozenForDuration { duration: std::time::Duration, value: parking_lot::Mutex>, } impl FrozenForDuration { fn new(duration: std::time::Duration) -> Self { Self { duration, value: Frozen { at: std::time::Instant::now(), value: None }.into() } } fn take_or_else(&self, f: F) -> T where F: FnOnce() -> T, { let mut lock = self.value.lock(); if lock.at.elapsed() > self.duration || lock.value.is_none() { let new_value = f(); lock.at = std::time::Instant::now(); lock.value = Some(new_value.clone()); new_value } else { lock.value.as_ref().expect("checked with lock above").clone() } } } /// Disk backend. /// /// Disk backend keeps data in a key-value store. In archive mode, trie nodes are kept from all /// blocks. Otherwise, trie nodes are kept only from some recent blocks. pub struct Backend { storage: Arc>, offchain_storage: offchain::LocalStorage, changes_tries_storage: DbChangesTrieStorage, blockchain: BlockchainDb, canonicalization_delay: u64, shared_cache: SharedCache, import_lock: Arc>, is_archive: bool, keep_blocks: KeepBlocks, transaction_storage: TransactionStorageMode, io_stats: FrozenForDuration<(kvdb::IoStats, StateUsageInfo)>, state_usage: Arc, genesis_state: RwLock>>>, } impl Backend { /// Create a new instance of database backend. /// /// The pruning window is how old a block must be before the state is pruned. pub fn new(config: DatabaseSettings, canonicalization_delay: u64) -> ClientResult { let db = crate::utils::open_database::(&config, DatabaseType::Full)?; Self::from_database(db as Arc<_>, canonicalization_delay, &config) } /// Create new memory-backed client backend for tests. #[cfg(any(test, feature = "test-helpers"))] pub fn new_test(keep_blocks: u32, canonicalization_delay: u64) -> Self { Self::new_test_with_tx_storage( keep_blocks, canonicalization_delay, TransactionStorageMode::BlockBody, ) } /// Create new memory-backed client backend for tests. #[cfg(any(test, feature = "test-helpers"))] pub fn new_test_with_tx_storage( keep_blocks: u32, canonicalization_delay: u64, transaction_storage: TransactionStorageMode, ) -> Self { let db = kvdb_memorydb::create(crate::utils::NUM_COLUMNS); let db = sp_database::as_database(db); let db_setting = DatabaseSettings { state_cache_size: 16777216, state_cache_child_ratio: Some((50, 100)), state_pruning: PruningMode::keep_blocks(keep_blocks), source: DatabaseSource::Custom(db), keep_blocks: KeepBlocks::Some(keep_blocks), transaction_storage, }; Self::new(db_setting, canonicalization_delay).expect("failed to create test-db") } fn from_database( db: Arc>, canonicalization_delay: u64, config: &DatabaseSettings, ) -> ClientResult { let is_archive_pruning = config.state_pruning.is_archive(); let blockchain = BlockchainDb::new(db.clone(), config.transaction_storage.clone())?; let meta = blockchain.meta.clone(); let map_e = |e: sc_state_db::Error| sp_blockchain::Error::from_state_db(e); let state_db: StateDb<_, _> = StateDb::new( config.state_pruning.clone(), !db.supports_ref_counting(), &StateMetaDb(&*db), ) .map_err(map_e)?; let storage_db = StorageDb { db: db.clone(), state_db, prefix_keys: !db.supports_ref_counting() }; let offchain_storage = offchain::LocalStorage::new(db.clone()); let changes_tries_storage = DbChangesTrieStorage::new( db, blockchain.header_metadata_cache.clone(), columns::META, columns::CHANGES_TRIE, columns::KEY_LOOKUP, columns::HEADER, columns::CACHE, meta, if is_archive_pruning { None } else { Some(MIN_BLOCKS_TO_KEEP_CHANGES_TRIES_FOR) }, )?; let backend = Backend { storage: Arc::new(storage_db), offchain_storage, changes_tries_storage, blockchain, canonicalization_delay, shared_cache: new_shared_cache( config.state_cache_size, config.state_cache_child_ratio.unwrap_or(DEFAULT_CHILD_RATIO), ), import_lock: Default::default(), is_archive: is_archive_pruning, io_stats: FrozenForDuration::new(std::time::Duration::from_secs(1)), state_usage: Arc::new(StateUsageStats::new()), keep_blocks: config.keep_blocks.clone(), transaction_storage: config.transaction_storage.clone(), genesis_state: RwLock::new(None), }; // Older DB versions have no last state key. Check if the state is available and set it. let info = backend.blockchain.info(); if info.finalized_state.is_none() && info.finalized_hash != Default::default() && sc_client_api::Backend::have_state_at( &backend, &info.finalized_hash, info.finalized_number, ) { backend.blockchain.update_meta(MetaUpdate { hash: info.finalized_hash, number: info.finalized_number, is_best: info.finalized_hash == info.best_hash, is_finalized: true, with_state: true, }); } Ok(backend) } /// Handle setting head within a transaction. `route_to` should be the last /// block that existed in the database. `best_to` should be the best block /// to be set. /// /// In the case where the new best block is a block to be imported, `route_to` /// should be the parent of `best_to`. In the case where we set an existing block /// to be best, `route_to` should equal to `best_to`. fn set_head_with_transaction( &self, transaction: &mut Transaction, route_to: Block::Hash, best_to: (NumberFor, Block::Hash), ) -> ClientResult<(Vec, Vec)> { let mut enacted = Vec::default(); let mut retracted = Vec::default(); let (best_number, best_hash) = best_to; let meta = self.blockchain.meta.read(); if meta.best_number > best_number && (meta.best_number - best_number).saturated_into::() > self.canonicalization_delay { return Err(sp_blockchain::Error::SetHeadTooOld.into()) } let parent_exists = self.blockchain.status(BlockId::Hash(route_to))? == sp_blockchain::BlockStatus::InChain; // Cannot find tree route with empty DB or when imported a detached block. if meta.best_hash != Default::default() && parent_exists { let tree_route = sp_blockchain::tree_route(&self.blockchain, meta.best_hash, route_to)?; // uncanonicalize: check safety violations and ensure the numbers no longer // point to these block hashes in the key mapping. for r in tree_route.retracted() { if r.hash == meta.finalized_hash { warn!( "Potential safety failure: reverting finalized block {:?}", (&r.number, &r.hash) ); return Err(::sp_blockchain::Error::NotInFinalizedChain.into()) } retracted.push(r.hash.clone()); utils::remove_number_to_key_mapping(transaction, columns::KEY_LOOKUP, r.number)?; } // canonicalize: set the number lookup to map to this block's hash. for e in tree_route.enacted() { enacted.push(e.hash.clone()); utils::insert_number_to_key_mapping( transaction, columns::KEY_LOOKUP, e.number, e.hash, )?; } } let lookup_key = utils::number_and_hash_to_lookup_key(best_number, &best_hash)?; transaction.set_from_vec(columns::META, meta_keys::BEST_BLOCK, lookup_key); utils::insert_number_to_key_mapping( transaction, columns::KEY_LOOKUP, best_number, best_hash, )?; Ok((enacted, retracted)) } fn ensure_sequential_finalization( &self, header: &Block::Header, last_finalized: Option, ) -> ClientResult<()> { let last_finalized = last_finalized.unwrap_or_else(|| self.blockchain.meta.read().finalized_hash); if last_finalized != self.blockchain.meta.read().genesis_hash && *header.parent_hash() != last_finalized { return Err(sp_blockchain::Error::NonSequentialFinalization(format!( "Last finalized {:?} not parent of {:?}", last_finalized, header.hash() )) .into()) } Ok(()) } fn finalize_block_with_transaction( &self, transaction: &mut Transaction, hash: &Block::Hash, header: &Block::Header, last_finalized: Option, justification: Option, changes_trie_cache_ops: &mut Option>, finalization_displaced: &mut Option>>, ) -> ClientResult> { // TODO: ensure best chain contains this block. let number = *header.number(); self.ensure_sequential_finalization(header, last_finalized)?; let with_state = sc_client_api::Backend::have_state_at(self, &hash, number); self.note_finalized( transaction, false, header, *hash, changes_trie_cache_ops, finalization_displaced, with_state, )?; if let Some(justification) = justification { transaction.set_from_vec( columns::JUSTIFICATIONS, &utils::number_and_hash_to_lookup_key(number, hash)?, Justifications::from(justification).encode(), ); } Ok(MetaUpdate { hash: *hash, number, is_best: false, is_finalized: true, with_state }) } // performs forced canonicalization with a delay after importing a non-finalized block. fn force_delayed_canonicalize( &self, transaction: &mut Transaction, hash: Block::Hash, number: NumberFor, ) -> ClientResult<()> { let number_u64 = number.saturated_into::(); if number_u64 > self.canonicalization_delay { let new_canonical = number_u64 - self.canonicalization_delay; if new_canonical <= self.storage.state_db.best_canonical().unwrap_or(0) { return Ok(()) } let hash = if new_canonical == number_u64 { hash } else { sc_client_api::blockchain::HeaderBackend::hash( &self.blockchain, new_canonical.saturated_into(), )? .ok_or_else(|| { sp_blockchain::Error::Backend(format!( "Can't canonicalize missing block number #{} when importing {:?} (#{})", new_canonical, hash, number, )) })? }; if !sc_client_api::Backend::have_state_at(self, &hash, new_canonical.saturated_into()) { return Ok(()) } trace!(target: "db", "Canonicalize block #{} ({:?})", new_canonical, hash); let commit = self.storage.state_db.canonicalize_block(&hash).map_err( |e: sc_state_db::Error| sp_blockchain::Error::from_state_db(e), )?; apply_state_commit(transaction, commit); } Ok(()) } fn try_commit_operation(&self, mut operation: BlockImportOperation) -> ClientResult<()> { let mut transaction = Transaction::new(); let mut finalization_displaced_leaves = None; operation.apply_aux(&mut transaction); operation.apply_offchain(&mut transaction); let mut meta_updates = Vec::with_capacity(operation.finalized_blocks.len()); let mut last_finalized_hash = self.blockchain.meta.read().finalized_hash; let mut last_finalized_num = self.blockchain.meta.read().finalized_number; let best_num = self.blockchain.meta.read().best_number; let mut changes_trie_cache_ops = None; for (block, justification) in operation.finalized_blocks { let block_hash = self.blockchain.expect_block_hash_from_id(&block)?; let block_header = self.blockchain.expect_header(BlockId::Hash(block_hash))?; meta_updates.push(self.finalize_block_with_transaction( &mut transaction, &block_hash, &block_header, Some(last_finalized_hash), justification, &mut changes_trie_cache_ops, &mut finalization_displaced_leaves, )?); last_finalized_hash = block_hash; last_finalized_num = block_header.number().clone(); } let imported = if let Some(pending_block) = operation.pending_block { let hash = pending_block.header.hash(); let parent_hash = *pending_block.header.parent_hash(); let number = pending_block.header.number().clone(); let existing_header = number <= best_num && self.blockchain.header(BlockId::hash(hash))?.is_some(); // blocks are keyed by number + hash. let lookup_key = utils::number_and_hash_to_lookup_key(number, hash)?; let (enacted, retracted) = if pending_block.leaf_state.is_best() { self.set_head_with_transaction(&mut transaction, parent_hash, (number, hash))? } else { (Default::default(), Default::default()) }; utils::insert_hash_to_key_mapping(&mut transaction, columns::KEY_LOOKUP, number, hash)?; transaction.set_from_vec(columns::HEADER, &lookup_key, pending_block.header.encode()); if let Some(body) = pending_block.body { match self.transaction_storage { TransactionStorageMode::BlockBody => { transaction.set_from_vec(columns::BODY, &lookup_key, body.encode()); }, TransactionStorageMode::StorageChain => { let body = apply_index_ops::(&mut transaction, body, operation.index_ops); transaction.set_from_vec(columns::BODY, &lookup_key, body); }, } } if let Some(body) = pending_block.indexed_body { match self.transaction_storage { TransactionStorageMode::BlockBody => { debug!(target: "db", "Commit: ignored indexed block body"); }, TransactionStorageMode::StorageChain => { apply_indexed_body::(&mut transaction, body); }, } } if let Some(justifications) = pending_block.justifications { transaction.set_from_vec( columns::JUSTIFICATIONS, &lookup_key, justifications.encode(), ); } if number.is_zero() { transaction.set_from_vec( columns::META, meta_keys::FINALIZED_BLOCK, lookup_key.clone(), ); transaction.set(columns::META, meta_keys::GENESIS_HASH, hash.as_ref()); // for tests, because config is set from within the reset_storage if operation.changes_trie_config_update.is_none() { operation.changes_trie_config_update = Some(None); } if operation.commit_state { transaction.set_from_vec(columns::META, meta_keys::FINALIZED_STATE, lookup_key); } else { // When we don't want to commit the genesis state, we still preserve it in // memory to bootstrap consensus. It is queried for an initial list of // authorities, etc. *self.genesis_state.write() = Some(Arc::new(DbGenesisStorage::new( pending_block.header.state_root().clone(), operation.db_updates.clone(), ))); } } let finalized = if operation.commit_state { let mut changeset: sc_state_db::ChangeSet> = sc_state_db::ChangeSet::default(); let mut ops: u64 = 0; let mut bytes: u64 = 0; let mut removal: u64 = 0; let mut bytes_removal: u64 = 0; for (mut key, (val, rc)) in operation.db_updates.drain() { if !self.storage.prefix_keys { // Strip prefix key.drain(0..key.len() - DB_HASH_LEN); }; if rc > 0 { ops += 1; bytes += key.len() as u64 + val.len() as u64; if rc == 1 { changeset.inserted.push((key, val.to_vec())); } else { changeset.inserted.push((key.clone(), val.to_vec())); for _ in 0..rc - 1 { changeset.inserted.push((key.clone(), Default::default())); } } } else if rc < 0 { removal += 1; bytes_removal += key.len() as u64; if rc == -1 { changeset.deleted.push(key); } else { for _ in 0..-rc { changeset.deleted.push(key.clone()); } } } } self.state_usage.tally_writes_nodes(ops, bytes); self.state_usage.tally_removed_nodes(removal, bytes_removal); let mut ops: u64 = 0; let mut bytes: u64 = 0; for (key, value) in operation .storage_updates .iter() .chain(operation.child_storage_updates.iter().flat_map(|(_, s)| s.iter())) { ops += 1; bytes += key.len() as u64; if let Some(v) = value.as_ref() { bytes += v.len() as u64; } } self.state_usage.tally_writes(ops, bytes); let number_u64 = number.saturated_into::(); let commit = self .storage .state_db .insert_block(&hash, number_u64, &pending_block.header.parent_hash(), changeset) .map_err(|e: sc_state_db::Error| { sp_blockchain::Error::from_state_db(e) })?; apply_state_commit(&mut transaction, commit); if number <= last_finalized_num { // Canonicalize in the db when re-importing existing blocks with state. let commit = self.storage.state_db.canonicalize_block(&hash).map_err( |e: sc_state_db::Error| sp_blockchain::Error::from_state_db(e), )?; apply_state_commit(&mut transaction, commit); meta_updates.push(MetaUpdate { hash, number, is_best: false, is_finalized: true, with_state: true, }); } // Check if need to finalize. Genesis is always finalized instantly. let finalized = number_u64 == 0 || pending_block.leaf_state.is_final(); finalized } else { number.is_zero() || pending_block.leaf_state.is_final() }; let header = &pending_block.header; let is_best = pending_block.leaf_state.is_best(); let changes_trie_updates = operation.changes_trie_updates; debug!(target: "db", "DB Commit {:?} ({}), best={}, state={}, existing={}", hash, number, is_best, operation.commit_state, existing_header, ); self.state_usage.merge_sm(operation.old_state.usage_info()); // release state reference so that it can be finalized let cache = operation.old_state.into_cache_changes(); if finalized { // TODO: ensure best chain contains this block. self.ensure_sequential_finalization(header, Some(last_finalized_hash))?; self.note_finalized( &mut transaction, true, header, hash, &mut changes_trie_cache_ops, &mut finalization_displaced_leaves, operation.commit_state, )?; } else { // canonicalize blocks which are old enough, regardless of finality. self.force_delayed_canonicalize(&mut transaction, hash, *header.number())? } if !existing_header { let changes_trie_config_update = operation.changes_trie_config_update; changes_trie_cache_ops = Some(self.changes_tries_storage.commit( &mut transaction, changes_trie_updates, cache::ComplexBlockId::new( *header.parent_hash(), if number.is_zero() { Zero::zero() } else { number - One::one() }, ), cache::ComplexBlockId::new(hash, number), header, finalized, changes_trie_config_update, changes_trie_cache_ops, )?); { let mut leaves = self.blockchain.leaves.write(); leaves.import(hash, number, parent_hash); leaves.prepare_transaction( &mut transaction, columns::META, meta_keys::LEAF_PREFIX, ); } let mut children = children::read_children( &*self.storage.db, columns::META, meta_keys::CHILDREN_PREFIX, parent_hash, )?; if !children.contains(&hash) { children.push(hash); children::write_children( &mut transaction, columns::META, meta_keys::CHILDREN_PREFIX, parent_hash, children, ); } } meta_updates.push(MetaUpdate { hash, number, is_best: pending_block.leaf_state.is_best(), is_finalized: finalized, with_state: operation.commit_state, }); Some((pending_block.header, number, hash, enacted, retracted, is_best, cache)) } else { None }; let cache_update = if let Some(set_head) = operation.set_head { if let Some(header) = sc_client_api::blockchain::HeaderBackend::header(&self.blockchain, set_head)? { let number = header.number(); let hash = header.hash(); let (enacted, retracted) = self.set_head_with_transaction( &mut transaction, hash.clone(), (number.clone(), hash.clone()), )?; meta_updates.push(MetaUpdate { hash, number: *number, is_best: true, is_finalized: false, with_state: false, }); Some((enacted, retracted)) } else { return Err(sp_blockchain::Error::UnknownBlock(format!( "Cannot set head {:?}", set_head ))) } } else { None }; self.storage.db.commit(transaction)?; // Apply all in-memory state changes. // Code beyond this point can't fail. if let Some((header, number, hash, enacted, retracted, is_best, mut cache)) = imported { trace!(target: "db", "DB Commit done {:?}", hash); let header_metadata = CachedHeaderMetadata::from(&header); self.blockchain.insert_header_metadata(header_metadata.hash, header_metadata); cache_header(&mut self.blockchain.header_cache.lock(), hash, Some(header)); cache.sync_cache( &enacted, &retracted, operation.storage_updates, operation.child_storage_updates, Some(hash), Some(number), is_best, ); } if let Some(changes_trie_build_cache_update) = operation.changes_trie_build_cache_update { self.changes_tries_storage.commit_build_cache(changes_trie_build_cache_update); } self.changes_tries_storage.post_commit(changes_trie_cache_ops); if let Some((enacted, retracted)) = cache_update { self.shared_cache.write().sync(&enacted, &retracted); } for m in meta_updates { self.blockchain.update_meta(m); } Ok(()) } // write stuff to a transaction after a new block is finalized. // this canonicalizes finalized blocks. Fails if called with a block which // was not a child of the last finalized block. fn note_finalized( &self, transaction: &mut Transaction, is_inserted: bool, f_header: &Block::Header, f_hash: Block::Hash, changes_trie_cache_ops: &mut Option>, displaced: &mut Option>>, with_state: bool, ) -> ClientResult<()> { let f_num = f_header.number().clone(); let lookup_key = utils::number_and_hash_to_lookup_key(f_num, f_hash.clone())?; if with_state { transaction.set_from_vec(columns::META, meta_keys::FINALIZED_STATE, lookup_key.clone()); } transaction.set_from_vec(columns::META, meta_keys::FINALIZED_BLOCK, lookup_key); if sc_client_api::Backend::have_state_at(self, &f_hash, f_num) && self.storage .state_db .best_canonical() .map(|c| f_num.saturated_into::() > c) .unwrap_or(true) { let commit = self.storage.state_db.canonicalize_block(&f_hash).map_err( |e: sc_state_db::Error| sp_blockchain::Error::from_state_db(e), )?; apply_state_commit(transaction, commit); } if !f_num.is_zero() { let new_changes_trie_cache_ops = self.changes_tries_storage.finalize( transaction, *f_header.parent_hash(), f_hash, f_num, if is_inserted { Some(&f_header) } else { None }, changes_trie_cache_ops.take(), )?; *changes_trie_cache_ops = Some(new_changes_trie_cache_ops); } let new_displaced = self.blockchain.leaves.write().finalize_height(f_num); self.prune_blocks(transaction, f_num, &new_displaced)?; match displaced { x @ &mut None => *x = Some(new_displaced), &mut Some(ref mut displaced) => displaced.merge(new_displaced), } Ok(()) } fn prune_blocks( &self, transaction: &mut Transaction, finalized: NumberFor, displaced: &FinalizationDisplaced>, ) -> ClientResult<()> { if let KeepBlocks::Some(keep_blocks) = self.keep_blocks { // Always keep the last finalized block let keep = std::cmp::max(keep_blocks, 1); if finalized >= keep.into() { let number = finalized.saturating_sub(keep.into()); self.prune_block(transaction, BlockId::::number(number))?; } // Also discard all blocks from displaced branches for h in displaced.leaves() { let mut number = finalized; let mut hash = h.clone(); // Follow displaced chains back until we reach a finalized block. // Since leaves are discarded due to finality, they can't have parents // that are canonical, but not yet finalized. So we stop deletig as soon as // we reach canonical chain. while self.blockchain.hash(number)? != Some(hash.clone()) { let id = BlockId::::hash(hash.clone()); match self.blockchain.header(id)? { Some(header) => { self.prune_block(transaction, id)?; number = header.number().saturating_sub(One::one()); hash = header.parent_hash().clone(); }, None => break, } } } } Ok(()) } fn prune_block( &self, transaction: &mut Transaction, id: BlockId, ) -> ClientResult<()> { match read_db(&*self.storage.db, columns::KEY_LOOKUP, columns::BODY, id)? { Some(body) => { debug!(target: "db", "Removing block #{}", id); utils::remove_from_db( transaction, &*self.storage.db, columns::KEY_LOOKUP, columns::BODY, id, )?; match self.transaction_storage { TransactionStorageMode::BlockBody => {}, TransactionStorageMode::StorageChain => { match Vec::::decode(&mut &body[..]) { Ok(body) => for ExtrinsicHeader { indexed_hash, .. } in body { if indexed_hash != Default::default() { transaction.release(columns::TRANSACTION, indexed_hash); } }, Err(err) => return Err(sp_blockchain::Error::Backend(format!( "Error decoding body list: {}", err ))), } }, } }, None => return Ok(()), } Ok(()) } fn empty_state(&self) -> ClientResult, Block>> { let root = EmptyStorage::::new().0; // Empty trie let db_state = DbState::::new(self.storage.clone(), root); let state = RefTrackingState::new(db_state, self.storage.clone(), None); let caching_state = CachingState::new(state, self.shared_cache.clone(), None); Ok(SyncingCachingState::new( caching_state, self.state_usage.clone(), self.blockchain.meta.clone(), self.import_lock.clone(), )) } } fn apply_state_commit( transaction: &mut Transaction, commit: sc_state_db::CommitSet>, ) { for (key, val) in commit.data.inserted.into_iter() { transaction.set_from_vec(columns::STATE, &key[..], val); } for key in commit.data.deleted.into_iter() { transaction.remove(columns::STATE, &key[..]); } for (key, val) in commit.meta.inserted.into_iter() { transaction.set_from_vec(columns::STATE_META, &key[..], val); } for key in commit.meta.deleted.into_iter() { transaction.remove(columns::STATE_META, &key[..]); } } fn apply_index_ops( transaction: &mut Transaction, body: Vec, ops: Vec, ) -> Vec { let mut extrinsic_headers: Vec = Vec::with_capacity(body.len()); let mut index_map = HashMap::new(); let mut renewed_map = HashMap::new(); for op in ops { match op { IndexOperation::Insert { extrinsic, hash, size } => { index_map.insert(extrinsic, (hash, size)); }, IndexOperation::Renew { extrinsic, hash } => { renewed_map.insert(extrinsic, DbHash::from_slice(hash.as_ref())); }, } } for (index, extrinsic) in body.into_iter().enumerate() { let extrinsic = extrinsic.encode(); let extrinsic_header = if let Some(hash) = renewed_map.get(&(index as u32)) { // Bump ref counter transaction.reference(columns::TRANSACTION, DbHash::from_slice(hash.as_ref())); ExtrinsicHeader { indexed_hash: hash.clone(), data: extrinsic } } else { match index_map.get(&(index as u32)) { Some((hash, size)) if *size as usize <= extrinsic.len() => { let offset = extrinsic.len() - *size as usize; transaction.store( columns::TRANSACTION, DbHash::from_slice(hash.as_ref()), extrinsic[offset..].to_vec(), ); ExtrinsicHeader { indexed_hash: DbHash::from_slice(hash.as_ref()), data: extrinsic[..offset].to_vec(), } }, _ => ExtrinsicHeader { indexed_hash: Default::default(), data: extrinsic }, } }; extrinsic_headers.push(extrinsic_header); } debug!( target: "db", "DB transaction index: {} inserted, {} renewed", index_map.len(), renewed_map.len() ); extrinsic_headers.encode() } fn apply_indexed_body(transaction: &mut Transaction, body: Vec>) { for extrinsic in body { let hash = sp_runtime::traits::BlakeTwo256::hash(&extrinsic); transaction.store(columns::TRANSACTION, DbHash::from_slice(hash.as_ref()), extrinsic); } } impl sc_client_api::backend::AuxStore for Backend where Block: BlockT, { fn insert_aux< 'a, 'b: 'a, 'c: 'a, I: IntoIterator, D: IntoIterator, >( &self, insert: I, delete: D, ) -> ClientResult<()> { let mut transaction = Transaction::new(); for (k, v) in insert { transaction.set(columns::AUX, k, v); } for k in delete { transaction.remove(columns::AUX, k); } self.storage.db.commit(transaction)?; Ok(()) } fn get_aux(&self, key: &[u8]) -> ClientResult>> { Ok(self.storage.db.get(columns::AUX, key)) } } impl sc_client_api::backend::Backend for Backend { type BlockImportOperation = BlockImportOperation; type Blockchain = BlockchainDb; type State = SyncingCachingState, Block>; type OffchainStorage = offchain::LocalStorage; fn begin_operation(&self) -> ClientResult { let mut old_state = self.empty_state()?; old_state.disable_syncing(); Ok(BlockImportOperation { pending_block: None, old_state, db_updates: PrefixedMemoryDB::default(), storage_updates: Default::default(), child_storage_updates: Default::default(), offchain_storage_updates: Default::default(), changes_trie_config_update: None, changes_trie_updates: MemoryDB::default(), changes_trie_build_cache_update: None, aux_ops: Vec::new(), finalized_blocks: Vec::new(), set_head: None, commit_state: false, index_ops: Default::default(), }) } fn begin_state_operation( &self, operation: &mut Self::BlockImportOperation, block: BlockId, ) -> ClientResult<()> { if block.is_pre_genesis() { operation.old_state = self.empty_state()?; } else { operation.old_state = self.state_at(block)?; } operation.old_state.disable_syncing(); operation.commit_state = true; Ok(()) } fn commit_operation(&self, operation: Self::BlockImportOperation) -> ClientResult<()> { let usage = operation.old_state.usage_info(); self.state_usage.merge_sm(usage); match self.try_commit_operation(operation) { Ok(_) => { self.storage.state_db.apply_pending(); Ok(()) }, e @ Err(_) => { self.storage.state_db.revert_pending(); e }, } } fn finalize_block( &self, block: BlockId, justification: Option, ) -> ClientResult<()> { let mut transaction = Transaction::new(); let hash = self.blockchain.expect_block_hash_from_id(&block)?; let header = self.blockchain.expect_header(block)?; let mut displaced = None; let mut changes_trie_cache_ops = None; let m = self.finalize_block_with_transaction( &mut transaction, &hash, &header, None, justification, &mut changes_trie_cache_ops, &mut displaced, )?; self.storage.db.commit(transaction)?; self.blockchain.update_meta(m); self.changes_tries_storage.post_commit(changes_trie_cache_ops); Ok(()) } fn append_justification( &self, block: BlockId, justification: Justification, ) -> ClientResult<()> { let mut transaction: Transaction = Transaction::new(); let hash = self.blockchain.expect_block_hash_from_id(&block)?; let header = self.blockchain.expect_header(block)?; let number = *header.number(); // Check if the block is finalized first. let is_descendent_of = is_descendent_of(&self.blockchain, None); let last_finalized = self.blockchain.last_finalized()?; // We can do a quick check first, before doing a proper but more expensive check if number > self.blockchain.info().finalized_number || (hash != last_finalized && !is_descendent_of(&hash, &last_finalized)?) { return Err(ClientError::NotInFinalizedChain) } let justifications = if let Some(mut stored_justifications) = self.blockchain.justifications(block)? { if !stored_justifications.append(justification) { return Err(ClientError::BadJustification("Duplicate consensus engine ID".into())) } stored_justifications } else { Justifications::from(justification) }; transaction.set_from_vec( columns::JUSTIFICATIONS, &utils::number_and_hash_to_lookup_key(number, hash)?, justifications.encode(), ); self.storage.db.commit(transaction)?; Ok(()) } fn changes_trie_storage(&self) -> Option<&dyn PrunableStateChangesTrieStorage> { Some(&self.changes_tries_storage) } fn offchain_storage(&self) -> Option { Some(self.offchain_storage.clone()) } fn usage_info(&self) -> Option { let (io_stats, state_stats) = self.io_stats.take_or_else(|| { ( // TODO: implement DB stats and cache size retrieval kvdb::IoStats::empty(), self.state_usage.take(), ) }); let database_cache = MemorySize::from_bytes(0); let state_cache = MemorySize::from_bytes((*&self.shared_cache).read().used_storage_cache_size()); let state_db = self.storage.state_db.memory_info(); Some(UsageInfo { memory: MemoryInfo { state_cache, database_cache, state_db }, io: IoInfo { transactions: io_stats.transactions, bytes_read: io_stats.bytes_read, bytes_written: io_stats.bytes_written, writes: io_stats.writes, reads: io_stats.reads, average_transaction_size: io_stats.avg_transaction_size() as u64, state_reads: state_stats.reads.ops, state_writes: state_stats.writes.ops, state_writes_cache: state_stats.overlay_writes.ops, state_reads_cache: state_stats.cache_reads.ops, state_writes_nodes: state_stats.nodes_writes.ops, }, }) } fn revert( &self, n: NumberFor, revert_finalized: bool, ) -> ClientResult<(NumberFor, HashSet)> { let mut reverted_finalized = HashSet::new(); let mut best_number = self.blockchain.info().best_number; let mut best_hash = self.blockchain.info().best_hash; let finalized = self.blockchain.info().finalized_number; let revertible = best_number - finalized; let n = if !revert_finalized && revertible < n { revertible } else { n }; let mut revert_blocks = || -> ClientResult> { for c in 0..n.saturated_into::() { if best_number.is_zero() { return Ok(c.saturated_into::>()) } let mut transaction = Transaction::new(); let removed_number = best_number; let removed = self.blockchain.header(BlockId::Number(best_number))?.ok_or_else(|| { sp_blockchain::Error::UnknownBlock(format!( "Error reverting to {}. Block hash not found.", best_number )) })?; let removed_hash = removed.hash(); let prev_number = best_number.saturating_sub(One::one()); let prev_hash = self.blockchain.hash(prev_number)?.ok_or_else(|| { sp_blockchain::Error::UnknownBlock(format!( "Error reverting to {}. Block hash not found.", best_number )) })?; if !self.have_state_at(&prev_hash, prev_number) { return Ok(c.saturated_into::>()) } match self.storage.state_db.revert_one() { Some(commit) => { apply_state_commit(&mut transaction, commit); best_number = prev_number; best_hash = prev_hash; let update_finalized = best_number < finalized; let key = utils::number_and_hash_to_lookup_key(best_number.clone(), &best_hash)?; let changes_trie_cache_ops = self.changes_tries_storage.revert( &mut transaction, &cache::ComplexBlockId::new(removed.hash(), removed_number), )?; if update_finalized { transaction.set_from_vec( columns::META, meta_keys::FINALIZED_BLOCK, key.clone(), ); reverted_finalized.insert(removed_hash); if let Some((hash, _)) = self.blockchain.info().finalized_state { if hash == best_hash { if !best_number.is_zero() && self.have_state_at(&prev_hash, best_number - One::one()) { let lookup_key = utils::number_and_hash_to_lookup_key( best_number - One::one(), prev_hash, )?; transaction.set_from_vec( columns::META, meta_keys::FINALIZED_STATE, lookup_key, ); } else { transaction .remove(columns::META, meta_keys::FINALIZED_STATE); } } } } transaction.set_from_vec(columns::META, meta_keys::BEST_BLOCK, key); transaction.remove(columns::KEY_LOOKUP, removed.hash().as_ref()); children::remove_children( &mut transaction, columns::META, meta_keys::CHILDREN_PREFIX, best_hash, ); self.storage.db.commit(transaction)?; self.changes_tries_storage.post_commit(Some(changes_trie_cache_ops)); self.blockchain.update_meta(MetaUpdate { hash: best_hash, number: best_number, is_best: true, is_finalized: update_finalized, with_state: false, }); }, None => return Ok(c.saturated_into::>()), } } Ok(n) }; let reverted = revert_blocks()?; let revert_leaves = || -> ClientResult<()> { let mut transaction = Transaction::new(); let mut leaves = self.blockchain.leaves.write(); leaves.revert(best_hash, best_number); leaves.prepare_transaction(&mut transaction, columns::META, meta_keys::LEAF_PREFIX); self.storage.db.commit(transaction)?; Ok(()) }; revert_leaves()?; Ok((reverted, reverted_finalized)) } fn remove_leaf_block(&self, hash: &Block::Hash) -> ClientResult<()> { let best_hash = self.blockchain.info().best_hash; if best_hash == *hash { return Err(sp_blockchain::Error::Backend(format!("Can't remove best block {:?}", hash))) } let hdr = self.blockchain.header_metadata(hash.clone())?; if !self.have_state_at(&hash, hdr.number) { return Err(sp_blockchain::Error::UnknownBlock(format!( "State already discarded for {:?}", hash ))) } let mut leaves = self.blockchain.leaves.write(); if !leaves.contains(hdr.number, *hash) { return Err(sp_blockchain::Error::Backend(format!( "Can't remove non-leaf block {:?}", hash ))) } let mut transaction = Transaction::new(); if let Some(commit) = self.storage.state_db.remove(hash) { apply_state_commit(&mut transaction, commit); } transaction.remove(columns::KEY_LOOKUP, hash.as_ref()); let changes_trie_cache_ops = self .changes_tries_storage .revert(&mut transaction, &cache::ComplexBlockId::new(*hash, hdr.number))?; self.changes_tries_storage.post_commit(Some(changes_trie_cache_ops)); leaves.revert(hash.clone(), hdr.number); leaves.prepare_transaction(&mut transaction, columns::META, meta_keys::LEAF_PREFIX); self.storage.db.commit(transaction)?; self.blockchain().remove_header_metadata(*hash); Ok(()) } fn blockchain(&self) -> &BlockchainDb { &self.blockchain } fn state_at(&self, block: BlockId) -> ClientResult { use sc_client_api::blockchain::HeaderBackend as BcHeaderBackend; let is_genesis = match &block { BlockId::Number(n) if n.is_zero() => true, BlockId::Hash(h) if h == &self.blockchain.meta.read().genesis_hash => true, _ => false, }; if is_genesis { if let Some(genesis_state) = &*self.genesis_state.read() { let root = genesis_state.root.clone(); let db_state = DbState::::new(genesis_state.clone(), root); let state = RefTrackingState::new(db_state, self.storage.clone(), None); let caching_state = CachingState::new(state, self.shared_cache.clone(), None); let mut state = SyncingCachingState::new( caching_state, self.state_usage.clone(), self.blockchain.meta.clone(), self.import_lock.clone(), ); state.disable_syncing(); return Ok(state) } } let hash = match block { BlockId::Hash(h) => h, BlockId::Number(n) => self.blockchain.hash(n)?.ok_or_else(|| { sp_blockchain::Error::UnknownBlock(format!("Unknown block number {}", n)) })?, }; match self.blockchain.header_metadata(hash) { Ok(ref hdr) => { if !self.have_state_at(&hash, hdr.number) { return Err(sp_blockchain::Error::UnknownBlock(format!( "State already discarded for {:?}", block ))) } if let Ok(()) = self.storage.state_db.pin(&hash) { let root = hdr.state_root; let db_state = DbState::::new(self.storage.clone(), root); let state = RefTrackingState::new(db_state, self.storage.clone(), Some(hash.clone())); let caching_state = CachingState::new(state, self.shared_cache.clone(), Some(hash)); Ok(SyncingCachingState::new( caching_state, self.state_usage.clone(), self.blockchain.meta.clone(), self.import_lock.clone(), )) } else { Err(sp_blockchain::Error::UnknownBlock(format!( "State already discarded for {:?}", block ))) } }, Err(e) => Err(e), } } fn have_state_at(&self, hash: &Block::Hash, number: NumberFor) -> bool { if self.is_archive { match self.blockchain.header_metadata(hash.clone()) { Ok(header) => sp_state_machine::Storage::get( self.storage.as_ref(), &header.state_root, (&[], None), ) .unwrap_or(None) .is_some(), _ => false, } } else { !self.storage.state_db.is_pruned(hash, number.saturated_into::()) } } fn get_import_lock(&self) -> &RwLock<()> { &*self.import_lock } } impl sc_client_api::backend::LocalBackend for Backend {} #[cfg(test)] pub(crate) mod tests { use super::*; use crate::columns; use hash_db::{HashDB, EMPTY_PREFIX}; use sc_client_api::{ backend::{Backend as BTrait, BlockImportOperation as Op}, blockchain::Backend as BLBTrait, }; use sp_blockchain::{lowest_common_ancestor, tree_route}; use sp_core::H256; use sp_runtime::{ generic::DigestItem, testing::{Block as RawBlock, ExtrinsicWrapper, Header}, traits::{BlakeTwo256, Hash}, ConsensusEngineId, }; use sp_state_machine::{TrieDBMut, TrieMut}; const CONS0_ENGINE_ID: ConsensusEngineId = *b"CON0"; const CONS1_ENGINE_ID: ConsensusEngineId = *b"CON1"; pub(crate) type Block = RawBlock>; pub fn prepare_changes(changes: Vec<(Vec, Vec)>) -> (H256, MemoryDB) { let mut changes_root = H256::default(); let mut changes_trie_update = MemoryDB::::default(); { let mut trie = TrieDBMut::::new(&mut changes_trie_update, &mut changes_root); for (key, value) in changes { trie.insert(&key, &value).unwrap(); } } (changes_root, changes_trie_update) } pub fn insert_header( backend: &Backend, number: u64, parent_hash: H256, changes: Option, Vec)>>, extrinsics_root: H256, ) -> H256 { insert_block(backend, number, parent_hash, changes, extrinsics_root, Vec::new(), None) } pub fn insert_block( backend: &Backend, number: u64, parent_hash: H256, changes: Option, Vec)>>, extrinsics_root: H256, body: Vec>, transaction_index: Option>, ) -> H256 { use sp_runtime::testing::Digest; let mut digest = Digest::default(); let mut changes_trie_update = Default::default(); if let Some(changes) = changes { let (root, update) = prepare_changes(changes); digest.push(DigestItem::ChangesTrieRoot(root)); changes_trie_update = update; } let header = Header { number, parent_hash, state_root: BlakeTwo256::trie_root(Vec::new()), digest, extrinsics_root, }; let header_hash = header.hash(); let block_id = if number == 0 { BlockId::Hash(Default::default()) } else { BlockId::Number(number - 1) }; let mut op = backend.begin_operation().unwrap(); backend.begin_state_operation(&mut op, block_id).unwrap(); op.set_block_data(header, Some(body), None, None, NewBlockState::Best).unwrap(); if let Some(index) = transaction_index { op.update_transaction_index(index).unwrap(); } op.update_changes_trie((changes_trie_update, ChangesTrieCacheAction::Clear)) .unwrap(); backend.commit_operation(op).unwrap(); header_hash } #[test] fn block_hash_inserted_correctly() { let backing = { let db = Backend::::new_test(1, 0); for i in 0..10 { assert!(db.blockchain().hash(i).unwrap().is_none()); { let id = if i == 0 { BlockId::Hash(Default::default()) } else { BlockId::Number(i - 1) }; let mut op = db.begin_operation().unwrap(); db.begin_state_operation(&mut op, id).unwrap(); let header = Header { number: i, parent_hash: if i == 0 { Default::default() } else { db.blockchain.hash(i - 1).unwrap().unwrap() }, state_root: Default::default(), digest: Default::default(), extrinsics_root: Default::default(), }; op.set_block_data(header, Some(vec![]), None, None, NewBlockState::Best) .unwrap(); db.commit_operation(op).unwrap(); } assert!(db.blockchain().hash(i).unwrap().is_some()) } db.storage.db.clone() }; let backend = Backend::::new( DatabaseSettings { state_cache_size: 16777216, state_cache_child_ratio: Some((50, 100)), state_pruning: PruningMode::keep_blocks(1), source: DatabaseSource::Custom(backing), keep_blocks: KeepBlocks::All, transaction_storage: TransactionStorageMode::BlockBody, }, 0, ) .unwrap(); assert_eq!(backend.blockchain().info().best_number, 9); for i in 0..10 { assert!(backend.blockchain().hash(i).unwrap().is_some()) } } #[test] fn set_state_data() { let db = Backend::::new_test(2, 0); let hash = { let mut op = db.begin_operation().unwrap(); let mut header = Header { number: 0, parent_hash: Default::default(), state_root: Default::default(), digest: Default::default(), extrinsics_root: Default::default(), }; let storage = vec![(vec![1, 3, 5], vec![2, 4, 6]), (vec![1, 2, 3], vec![9, 9, 9])]; header.state_root = op .old_state .storage_root(storage.iter().map(|(x, y)| (&x[..], Some(&y[..])))) .0 .into(); let hash = header.hash(); op.reset_storage(Storage { top: storage.into_iter().collect(), children_default: Default::default(), }) .unwrap(); op.set_block_data(header.clone(), Some(vec![]), None, None, NewBlockState::Best) .unwrap(); db.commit_operation(op).unwrap(); let state = db.state_at(BlockId::Number(0)).unwrap(); assert_eq!(state.storage(&[1, 3, 5]).unwrap(), Some(vec![2, 4, 6])); assert_eq!(state.storage(&[1, 2, 3]).unwrap(), Some(vec![9, 9, 9])); assert_eq!(state.storage(&[5, 5, 5]).unwrap(), None); hash }; { let mut op = db.begin_operation().unwrap(); db.begin_state_operation(&mut op, BlockId::Number(0)).unwrap(); let mut header = Header { number: 1, parent_hash: hash, state_root: Default::default(), digest: Default::default(), extrinsics_root: Default::default(), }; let storage = vec![(vec![1, 3, 5], None), (vec![5, 5, 5], Some(vec![4, 5, 6]))]; let (root, overlay) = op .old_state .storage_root(storage.iter().map(|(k, v)| (&k[..], v.as_ref().map(|v| &v[..])))); op.update_db_storage(overlay).unwrap(); header.state_root = root.into(); op.update_storage(storage, Vec::new()).unwrap(); op.set_block_data(header, Some(vec![]), None, None, NewBlockState::Best) .unwrap(); db.commit_operation(op).unwrap(); let state = db.state_at(BlockId::Number(1)).unwrap(); assert_eq!(state.storage(&[1, 3, 5]).unwrap(), None); assert_eq!(state.storage(&[1, 2, 3]).unwrap(), Some(vec![9, 9, 9])); assert_eq!(state.storage(&[5, 5, 5]).unwrap(), Some(vec![4, 5, 6])); } } #[test] fn delete_only_when_negative_rc() { sp_tracing::try_init_simple(); let key; let backend = Backend::::new_test(1, 0); let hash = { let mut op = backend.begin_operation().unwrap(); backend .begin_state_operation(&mut op, BlockId::Hash(Default::default())) .unwrap(); let mut header = Header { number: 0, parent_hash: Default::default(), state_root: Default::default(), digest: Default::default(), extrinsics_root: Default::default(), }; header.state_root = op.old_state.storage_root(std::iter::empty()).0.into(); let hash = header.hash(); op.reset_storage(Storage { top: Default::default(), children_default: Default::default(), }) .unwrap(); key = op.db_updates.insert(EMPTY_PREFIX, b"hello"); op.set_block_data(header, Some(vec![]), None, None, NewBlockState::Best) .unwrap(); backend.commit_operation(op).unwrap(); assert_eq!( backend .storage .db .get(columns::STATE, &sp_trie::prefixed_key::(&key, EMPTY_PREFIX)) .unwrap(), &b"hello"[..] ); hash }; let hash = { let mut op = backend.begin_operation().unwrap(); backend.begin_state_operation(&mut op, BlockId::Number(0)).unwrap(); let mut header = Header { number: 1, parent_hash: hash, state_root: Default::default(), digest: Default::default(), extrinsics_root: Default::default(), }; let storage: Vec<(_, _)> = vec![]; header.state_root = op .old_state .storage_root(storage.iter().cloned().map(|(x, y)| (x, Some(y)))) .0 .into(); let hash = header.hash(); op.db_updates.insert(EMPTY_PREFIX, b"hello"); op.db_updates.remove(&key, EMPTY_PREFIX); op.set_block_data(header, Some(vec![]), None, None, NewBlockState::Best) .unwrap(); backend.commit_operation(op).unwrap(); assert_eq!( backend .storage .db .get(columns::STATE, &sp_trie::prefixed_key::(&key, EMPTY_PREFIX)) .unwrap(), &b"hello"[..] ); hash }; let hash = { let mut op = backend.begin_operation().unwrap(); backend.begin_state_operation(&mut op, BlockId::Number(1)).unwrap(); let mut header = Header { number: 2, parent_hash: hash, state_root: Default::default(), digest: Default::default(), extrinsics_root: Default::default(), }; let storage: Vec<(_, _)> = vec![]; header.state_root = op .old_state .storage_root(storage.iter().cloned().map(|(x, y)| (x, Some(y)))) .0 .into(); let hash = header.hash(); op.db_updates.remove(&key, EMPTY_PREFIX); op.set_block_data(header, Some(vec![]), None, None, NewBlockState::Best) .unwrap(); backend.commit_operation(op).unwrap(); assert!(backend .storage .db .get(columns::STATE, &sp_trie::prefixed_key::(&key, EMPTY_PREFIX)) .is_some()); hash }; { let mut op = backend.begin_operation().unwrap(); backend.begin_state_operation(&mut op, BlockId::Number(2)).unwrap(); let mut header = Header { number: 3, parent_hash: hash, state_root: Default::default(), digest: Default::default(), extrinsics_root: Default::default(), }; let storage: Vec<(_, _)> = vec![]; header.state_root = op .old_state .storage_root(storage.iter().cloned().map(|(x, y)| (x, Some(y)))) .0 .into(); op.set_block_data(header, Some(vec![]), None, None, NewBlockState::Best) .unwrap(); backend.commit_operation(op).unwrap(); assert!(backend .storage .db .get(columns::STATE, &sp_trie::prefixed_key::(&key, EMPTY_PREFIX)) .is_none()); } backend.finalize_block(BlockId::Number(1), None).unwrap(); backend.finalize_block(BlockId::Number(2), None).unwrap(); backend.finalize_block(BlockId::Number(3), None).unwrap(); assert!(backend .storage .db .get(columns::STATE, &sp_trie::prefixed_key::(&key, EMPTY_PREFIX)) .is_none()); } #[test] fn tree_route_works() { let backend = Backend::::new_test(1000, 100); let blockchain = backend.blockchain(); let block0 = insert_header(&backend, 0, Default::default(), None, Default::default()); // fork from genesis: 3 prong. let a1 = insert_header(&backend, 1, block0, None, Default::default()); let a2 = insert_header(&backend, 2, a1, None, Default::default()); let a3 = insert_header(&backend, 3, a2, None, Default::default()); // fork from genesis: 2 prong. let b1 = insert_header(&backend, 1, block0, None, H256::from([1; 32])); let b2 = insert_header(&backend, 2, b1, None, Default::default()); { let tree_route = tree_route(blockchain, a3, b2).unwrap(); assert_eq!(tree_route.common_block().hash, block0); assert_eq!( tree_route.retracted().iter().map(|r| r.hash).collect::>(), vec![a3, a2, a1] ); assert_eq!( tree_route.enacted().iter().map(|r| r.hash).collect::>(), vec![b1, b2] ); } { let tree_route = tree_route(blockchain, a1, a3).unwrap(); assert_eq!(tree_route.common_block().hash, a1); assert!(tree_route.retracted().is_empty()); assert_eq!( tree_route.enacted().iter().map(|r| r.hash).collect::>(), vec![a2, a3] ); } { let tree_route = tree_route(blockchain, a3, a1).unwrap(); assert_eq!(tree_route.common_block().hash, a1); assert_eq!( tree_route.retracted().iter().map(|r| r.hash).collect::>(), vec![a3, a2] ); assert!(tree_route.enacted().is_empty()); } { let tree_route = tree_route(blockchain, a2, a2).unwrap(); assert_eq!(tree_route.common_block().hash, a2); assert!(tree_route.retracted().is_empty()); assert!(tree_route.enacted().is_empty()); } } #[test] fn tree_route_child() { let backend = Backend::::new_test(1000, 100); let blockchain = backend.blockchain(); let block0 = insert_header(&backend, 0, Default::default(), None, Default::default()); let block1 = insert_header(&backend, 1, block0, None, Default::default()); { let tree_route = tree_route(blockchain, block0, block1).unwrap(); assert_eq!(tree_route.common_block().hash, block0); assert!(tree_route.retracted().is_empty()); assert_eq!( tree_route.enacted().iter().map(|r| r.hash).collect::>(), vec![block1] ); } } #[test] fn lowest_common_ancestor_works() { let backend = Backend::::new_test(1000, 100); let blockchain = backend.blockchain(); let block0 = insert_header(&backend, 0, Default::default(), None, Default::default()); // fork from genesis: 3 prong. let a1 = insert_header(&backend, 1, block0, None, Default::default()); let a2 = insert_header(&backend, 2, a1, None, Default::default()); let a3 = insert_header(&backend, 3, a2, None, Default::default()); // fork from genesis: 2 prong. let b1 = insert_header(&backend, 1, block0, None, H256::from([1; 32])); let b2 = insert_header(&backend, 2, b1, None, Default::default()); { let lca = lowest_common_ancestor(blockchain, a3, b2).unwrap(); assert_eq!(lca.hash, block0); assert_eq!(lca.number, 0); } { let lca = lowest_common_ancestor(blockchain, a1, a3).unwrap(); assert_eq!(lca.hash, a1); assert_eq!(lca.number, 1); } { let lca = lowest_common_ancestor(blockchain, a3, a1).unwrap(); assert_eq!(lca.hash, a1); assert_eq!(lca.number, 1); } { let lca = lowest_common_ancestor(blockchain, a2, a3).unwrap(); assert_eq!(lca.hash, a2); assert_eq!(lca.number, 2); } { let lca = lowest_common_ancestor(blockchain, a2, a1).unwrap(); assert_eq!(lca.hash, a1); assert_eq!(lca.number, 1); } { let lca = lowest_common_ancestor(blockchain, a2, a2).unwrap(); assert_eq!(lca.hash, a2); assert_eq!(lca.number, 2); } } #[test] fn test_tree_route_regression() { // NOTE: this is a test for a regression introduced in #3665, the result // of tree_route would be erroneously computed, since it was taking into // account the `ancestor` in `CachedHeaderMetadata` for the comparison. // in this test we simulate the same behavior with the side-effect // triggering the issue being eviction of a previously fetched record // from the cache, therefore this test is dependent on the LRU cache // size for header metadata, which is currently set to 5000 elements. let backend = Backend::::new_test(10000, 10000); let blockchain = backend.blockchain(); let genesis = insert_header(&backend, 0, Default::default(), None, Default::default()); let block100 = (1..=100).fold(genesis, |parent, n| { insert_header(&backend, n, parent, None, Default::default()) }); let block7000 = (101..=7000).fold(block100, |parent, n| { insert_header(&backend, n, parent, None, Default::default()) }); // This will cause the ancestor of `block100` to be set to `genesis` as a side-effect. lowest_common_ancestor(blockchain, genesis, block100).unwrap(); // While traversing the tree we will have to do 6900 calls to // `header_metadata`, which will make sure we will exhaust our cache // which only takes 5000 elements. In particular, the `CachedHeaderMetadata` struct for // block #100 will be evicted and will get a new value (with ancestor set to its parent). let tree_route = tree_route(blockchain, block100, block7000).unwrap(); assert!(tree_route.retracted().is_empty()); } #[test] fn test_leaves_with_complex_block_tree() { let backend: Arc> = Arc::new(Backend::new_test(20, 20)); substrate_test_runtime_client::trait_tests::test_leaves_for_backend(backend); } #[test] fn test_children_with_complex_block_tree() { let backend: Arc> = Arc::new(Backend::new_test(20, 20)); substrate_test_runtime_client::trait_tests::test_children_for_backend(backend); } #[test] fn test_blockchain_query_by_number_gets_canonical() { let backend: Arc> = Arc::new(Backend::new_test(20, 20)); substrate_test_runtime_client::trait_tests::test_blockchain_query_by_number_gets_canonical( backend, ); } #[test] fn test_leaves_pruned_on_finality() { let backend: Backend = Backend::new_test(10, 10); let block0 = insert_header(&backend, 0, Default::default(), None, Default::default()); let block1_a = insert_header(&backend, 1, block0, None, Default::default()); let block1_b = insert_header(&backend, 1, block0, None, [1; 32].into()); let block1_c = insert_header(&backend, 1, block0, None, [2; 32].into()); assert_eq!(backend.blockchain().leaves().unwrap(), vec![block1_a, block1_b, block1_c]); let block2_a = insert_header(&backend, 2, block1_a, None, Default::default()); let block2_b = insert_header(&backend, 2, block1_b, None, Default::default()); let block2_c = insert_header(&backend, 2, block1_b, None, [1; 32].into()); assert_eq!( backend.blockchain().leaves().unwrap(), vec![block2_a, block2_b, block2_c, block1_c] ); backend.finalize_block(BlockId::hash(block1_a), None).unwrap(); backend.finalize_block(BlockId::hash(block2_a), None).unwrap(); // leaves at same height stay. Leaves at lower heights pruned. assert_eq!(backend.blockchain().leaves().unwrap(), vec![block2_a, block2_b, block2_c]); } #[test] fn test_aux() { let backend: Backend = Backend::new_test(0, 0); assert!(backend.get_aux(b"test").unwrap().is_none()); backend.insert_aux(&[(&b"test"[..], &b"hello"[..])], &[]).unwrap(); assert_eq!(b"hello", &backend.get_aux(b"test").unwrap().unwrap()[..]); backend.insert_aux(&[], &[&b"test"[..]]).unwrap(); assert!(backend.get_aux(b"test").unwrap().is_none()); } #[test] fn test_finalize_block_with_justification() { use sc_client_api::blockchain::Backend as BlockChainBackend; let backend = Backend::::new_test(10, 10); let block0 = insert_header(&backend, 0, Default::default(), None, Default::default()); let _ = insert_header(&backend, 1, block0, None, Default::default()); let justification = Some((CONS0_ENGINE_ID, vec![1, 2, 3])); backend.finalize_block(BlockId::Number(1), justification.clone()).unwrap(); assert_eq!( backend.blockchain().justifications(BlockId::Number(1)).unwrap(), justification.map(Justifications::from), ); } #[test] fn test_append_justification_to_finalized_block() { use sc_client_api::blockchain::Backend as BlockChainBackend; let backend = Backend::::new_test(10, 10); let block0 = insert_header(&backend, 0, Default::default(), None, Default::default()); let _ = insert_header(&backend, 1, block0, None, Default::default()); let just0 = (CONS0_ENGINE_ID, vec![1, 2, 3]); backend.finalize_block(BlockId::Number(1), Some(just0.clone().into())).unwrap(); let just1 = (CONS1_ENGINE_ID, vec![4, 5]); backend.append_justification(BlockId::Number(1), just1.clone()).unwrap(); let just2 = (CONS1_ENGINE_ID, vec![6, 7]); assert!(matches!( backend.append_justification(BlockId::Number(1), just2), Err(ClientError::BadJustification(_)) )); let justifications = { let mut just = Justifications::from(just0); just.append(just1); just }; assert_eq!( backend.blockchain().justifications(BlockId::Number(1)).unwrap(), Some(justifications), ); } #[test] fn test_finalize_multiple_blocks_in_single_op() { let backend = Backend::::new_test(10, 10); let block0 = insert_header(&backend, 0, Default::default(), None, Default::default()); let block1 = insert_header(&backend, 1, block0, None, Default::default()); let block2 = insert_header(&backend, 2, block1, None, Default::default()); let block3 = insert_header(&backend, 3, block2, None, Default::default()); let block4 = insert_header(&backend, 4, block3, None, Default::default()); { let mut op = backend.begin_operation().unwrap(); backend.begin_state_operation(&mut op, BlockId::Hash(block0)).unwrap(); op.mark_finalized(BlockId::Hash(block1), None).unwrap(); op.mark_finalized(BlockId::Hash(block2), None).unwrap(); backend.commit_operation(op).unwrap(); } { let mut op = backend.begin_operation().unwrap(); backend.begin_state_operation(&mut op, BlockId::Hash(block2)).unwrap(); op.mark_finalized(BlockId::Hash(block3), None).unwrap(); op.mark_finalized(BlockId::Hash(block4), None).unwrap(); backend.commit_operation(op).unwrap(); } } #[test] fn storage_hash_is_cached_correctly() { let backend = Backend::::new_test(10, 10); let hash0 = { let mut op = backend.begin_operation().unwrap(); backend .begin_state_operation(&mut op, BlockId::Hash(Default::default())) .unwrap(); let mut header = Header { number: 0, parent_hash: Default::default(), state_root: Default::default(), digest: Default::default(), extrinsics_root: Default::default(), }; let storage = vec![(b"test".to_vec(), b"test".to_vec())]; header.state_root = op .old_state .storage_root(storage.iter().map(|(x, y)| (&x[..], Some(&y[..])))) .0 .into(); let hash = header.hash(); op.reset_storage(Storage { top: storage.into_iter().collect(), children_default: Default::default(), }) .unwrap(); op.set_block_data(header.clone(), Some(vec![]), None, None, NewBlockState::Best) .unwrap(); backend.commit_operation(op).unwrap(); hash }; let block0_hash = backend .state_at(BlockId::Hash(hash0)) .unwrap() .storage_hash(&b"test"[..]) .unwrap(); let hash1 = { let mut op = backend.begin_operation().unwrap(); backend.begin_state_operation(&mut op, BlockId::Number(0)).unwrap(); let mut header = Header { number: 1, parent_hash: hash0, state_root: Default::default(), digest: Default::default(), extrinsics_root: Default::default(), }; let storage = vec![(b"test".to_vec(), Some(b"test2".to_vec()))]; let (root, overlay) = op .old_state .storage_root(storage.iter().map(|(k, v)| (&k[..], v.as_ref().map(|v| &v[..])))); op.update_db_storage(overlay).unwrap(); header.state_root = root.into(); let hash = header.hash(); op.update_storage(storage, Vec::new()).unwrap(); op.set_block_data(header, Some(vec![]), None, None, NewBlockState::Normal) .unwrap(); backend.commit_operation(op).unwrap(); hash }; { let header = backend.blockchain().header(BlockId::Hash(hash1)).unwrap().unwrap(); let mut op = backend.begin_operation().unwrap(); backend.begin_state_operation(&mut op, BlockId::Hash(hash0)).unwrap(); op.set_block_data(header, None, None, None, NewBlockState::Best).unwrap(); backend.commit_operation(op).unwrap(); } let block1_hash = backend .state_at(BlockId::Hash(hash1)) .unwrap() .storage_hash(&b"test"[..]) .unwrap(); assert_ne!(block0_hash, block1_hash); } #[test] fn test_finalize_non_sequential() { let backend = Backend::::new_test(10, 10); let block0 = insert_header(&backend, 0, Default::default(), None, Default::default()); let block1 = insert_header(&backend, 1, block0, None, Default::default()); let block2 = insert_header(&backend, 2, block1, None, Default::default()); { let mut op = backend.begin_operation().unwrap(); backend.begin_state_operation(&mut op, BlockId::Hash(block0)).unwrap(); op.mark_finalized(BlockId::Hash(block2), None).unwrap(); backend.commit_operation(op).unwrap_err(); } } #[test] fn header_cht_root_works() { use sc_client_api::ProvideChtRoots; let backend = Backend::::new_test(10, 10); // insert 1 + SIZE + SIZE + 1 blocks so that CHT#0 is created let mut prev_hash = insert_header(&backend, 0, Default::default(), None, Default::default()); let cht_size: u64 = cht::size(); for i in 1..1 + cht_size + cht_size + 1 { prev_hash = insert_header(&backend, i, prev_hash, None, Default::default()); } let blockchain = backend.blockchain(); let cht_root_1 = blockchain .header_cht_root(cht_size, cht::start_number(cht_size, 0)) .unwrap() .unwrap(); let cht_root_2 = blockchain .header_cht_root(cht_size, cht::start_number(cht_size, 0) + cht_size / 2) .unwrap() .unwrap(); let cht_root_3 = blockchain .header_cht_root(cht_size, cht::end_number(cht_size, 0)) .unwrap() .unwrap(); assert_eq!(cht_root_1, cht_root_2); assert_eq!(cht_root_2, cht_root_3); } #[test] fn prune_blocks_on_finalize() { for storage in &[TransactionStorageMode::BlockBody, TransactionStorageMode::StorageChain] { let backend = Backend::::new_test_with_tx_storage(2, 0, *storage); let mut blocks = Vec::new(); let mut prev_hash = Default::default(); for i in 0..5 { let hash = insert_block( &backend, i, prev_hash, None, Default::default(), vec![i.into()], None, ); blocks.push(hash); prev_hash = hash; } { let mut op = backend.begin_operation().unwrap(); backend.begin_state_operation(&mut op, BlockId::Hash(blocks[4])).unwrap(); for i in 1..5 { op.mark_finalized(BlockId::Hash(blocks[i]), None).unwrap(); } backend.commit_operation(op).unwrap(); } let bc = backend.blockchain(); assert_eq!(None, bc.body(BlockId::hash(blocks[0])).unwrap()); assert_eq!(None, bc.body(BlockId::hash(blocks[1])).unwrap()); assert_eq!(None, bc.body(BlockId::hash(blocks[2])).unwrap()); assert_eq!(Some(vec![3.into()]), bc.body(BlockId::hash(blocks[3])).unwrap()); assert_eq!(Some(vec![4.into()]), bc.body(BlockId::hash(blocks[4])).unwrap()); } } #[test] fn prune_blocks_on_finalize_with_fork() { let backend = Backend::::new_test_with_tx_storage(2, 10, TransactionStorageMode::StorageChain); let mut blocks = Vec::new(); let mut prev_hash = Default::default(); for i in 0..5 { let hash = insert_block( &backend, i, prev_hash, None, Default::default(), vec![i.into()], None, ); blocks.push(hash); prev_hash = hash; } // insert a fork at block 2 let fork_hash_root = insert_block( &backend, 2, blocks[1], None, sp_core::H256::random(), vec![2.into()], None, ); insert_block( &backend, 3, fork_hash_root, None, H256::random(), vec![3.into(), 11.into()], None, ); let mut op = backend.begin_operation().unwrap(); backend.begin_state_operation(&mut op, BlockId::Hash(blocks[4])).unwrap(); op.mark_head(BlockId::Hash(blocks[4])).unwrap(); backend.commit_operation(op).unwrap(); for i in 1..5 { let mut op = backend.begin_operation().unwrap(); backend.begin_state_operation(&mut op, BlockId::Hash(blocks[4])).unwrap(); op.mark_finalized(BlockId::Hash(blocks[i]), None).unwrap(); backend.commit_operation(op).unwrap(); } let bc = backend.blockchain(); assert_eq!(None, bc.body(BlockId::hash(blocks[0])).unwrap()); assert_eq!(None, bc.body(BlockId::hash(blocks[1])).unwrap()); assert_eq!(None, bc.body(BlockId::hash(blocks[2])).unwrap()); assert_eq!(Some(vec![3.into()]), bc.body(BlockId::hash(blocks[3])).unwrap()); assert_eq!(Some(vec![4.into()]), bc.body(BlockId::hash(blocks[4])).unwrap()); } #[test] fn renew_transaction_storage() { let backend = Backend::::new_test_with_tx_storage(2, 10, TransactionStorageMode::StorageChain); let mut blocks = Vec::new(); let mut prev_hash = Default::default(); let x1 = ExtrinsicWrapper::from(0u64).encode(); let x1_hash = as sp_core::Hasher>::hash(&x1[1..]); for i in 0..10 { let mut index = Vec::new(); if i == 0 { index.push(IndexOperation::Insert { extrinsic: 0, hash: x1_hash.as_ref().to_vec(), size: (x1.len() - 1) as u32, }); } else if i < 5 { // keep renewing 1st index.push(IndexOperation::Renew { extrinsic: 0, hash: x1_hash.as_ref().to_vec() }); } // else stop renewing let hash = insert_block( &backend, i, prev_hash, None, Default::default(), vec![i.into()], Some(index), ); blocks.push(hash); prev_hash = hash; } for i in 1..10 { let mut op = backend.begin_operation().unwrap(); backend.begin_state_operation(&mut op, BlockId::Hash(blocks[4])).unwrap(); op.mark_finalized(BlockId::Hash(blocks[i]), None).unwrap(); backend.commit_operation(op).unwrap(); let bc = backend.blockchain(); if i < 6 { assert!(bc.indexed_transaction(&x1_hash).unwrap().is_some()); } else { assert!(bc.indexed_transaction(&x1_hash).unwrap().is_none()); } } } #[test] fn remove_leaf_block_works() { let backend = Backend::::new_test_with_tx_storage(2, 10, TransactionStorageMode::StorageChain); let mut blocks = Vec::new(); let mut prev_hash = Default::default(); for i in 0..2 { let hash = insert_block( &backend, i, prev_hash, None, Default::default(), vec![i.into()], None, ); blocks.push(hash); prev_hash = hash; } // insert a fork at block 2, which becomes best block let best_hash = insert_block( &backend, 1, blocks[0], None, sp_core::H256::random(), vec![42.into()], None, ); assert!(backend.remove_leaf_block(&best_hash).is_err()); assert!(backend.have_state_at(&prev_hash, 1)); backend.remove_leaf_block(&prev_hash).unwrap(); assert_eq!(None, backend.blockchain().header(BlockId::hash(prev_hash.clone())).unwrap()); assert!(!backend.have_state_at(&prev_hash, 1)); } #[test] fn test_import_existing_block_as_new_head() { let backend: Backend = Backend::new_test(10, 3); let block0 = insert_header(&backend, 0, Default::default(), None, Default::default()); let block1 = insert_header(&backend, 1, block0, None, Default::default()); let block2 = insert_header(&backend, 2, block1, None, Default::default()); let block3 = insert_header(&backend, 3, block2, None, Default::default()); let block4 = insert_header(&backend, 4, block3, None, Default::default()); let block5 = insert_header(&backend, 5, block4, None, Default::default()); assert_eq!(backend.blockchain().info().best_hash, block5); // Insert 1 as best again. This should fail because canonicalization_delay == 3 and best == // 5 let header = Header { number: 1, parent_hash: block0, state_root: BlakeTwo256::trie_root(Vec::new()), digest: Default::default(), extrinsics_root: Default::default(), }; let mut op = backend.begin_operation().unwrap(); op.set_block_data(header, None, None, None, NewBlockState::Best).unwrap(); assert!(matches!(backend.commit_operation(op), Err(sp_blockchain::Error::SetHeadTooOld))); // Insert 2 as best again. let header = Header { number: 2, parent_hash: block1, state_root: BlakeTwo256::trie_root(Vec::new()), digest: Default::default(), extrinsics_root: Default::default(), }; let mut op = backend.begin_operation().unwrap(); op.set_block_data(header, None, None, None, NewBlockState::Best).unwrap(); backend.commit_operation(op).unwrap(); assert_eq!(backend.blockchain().info().best_hash, block2); } #[test] fn test_import_existing_block_as_final() { let backend: Backend = Backend::new_test(10, 10); let block0 = insert_header(&backend, 0, Default::default(), None, Default::default()); let block1 = insert_header(&backend, 1, block0, None, Default::default()); let _block2 = insert_header(&backend, 2, block1, None, Default::default()); // Genesis is auto finalized, the rest are not. assert_eq!(backend.blockchain().info().finalized_hash, block0); // Insert 1 as final again. let header = Header { number: 1, parent_hash: block0, state_root: BlakeTwo256::trie_root(Vec::new()), digest: Default::default(), extrinsics_root: Default::default(), }; let mut op = backend.begin_operation().unwrap(); op.set_block_data(header, None, None, None, NewBlockState::Final).unwrap(); backend.commit_operation(op).unwrap(); assert_eq!(backend.blockchain().info().finalized_hash, block1); } }