// This file is part of Substrate.
// Copyright (C) 2018-2021 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 .
//! Helper for managing the set of available leaves in the chain for DB implementations.
use std::collections::BTreeMap;
use std::cmp::Reverse;
use sp_database::{Database, Transaction};
use sp_runtime::traits::AtLeast32Bit;
use codec::{Encode, Decode};
use sp_blockchain::{Error, Result};
type DbHash = [u8; 32];
#[derive(Debug, Clone, PartialEq, Eq)]
struct LeafSetItem {
hash: H,
number: Reverse,
}
/// A displaced leaf after import.
#[must_use = "Displaced items from the leaf set must be handled."]
pub struct ImportDisplaced {
new_hash: H,
displaced: LeafSetItem,
}
/// Displaced leaves after finalization.
#[must_use = "Displaced items from the leaf set must be handled."]
pub struct FinalizationDisplaced {
leaves: BTreeMap, Vec>,
}
impl FinalizationDisplaced {
/// Merge with another. This should only be used for displaced items that
/// are produced within one transaction of each other.
pub fn merge(&mut self, mut other: Self) {
// this will ignore keys that are in duplicate, however
// if these are actually produced correctly via the leaf-set within
// one transaction, then there will be no overlap in the keys.
self.leaves.append(&mut other.leaves);
}
}
/// list of leaf hashes ordered by number (descending).
/// stored in memory for fast access.
/// this allows very fast checking and modification of active leaves.
#[derive(Debug, Clone, PartialEq, Eq)]
pub struct LeafSet {
storage: BTreeMap, Vec>,
pending_added: Vec<(H, N)>,
pending_removed: Vec,
}
impl LeafSet where
H: Clone + PartialEq + Decode + Encode,
N: std::fmt::Debug + Clone + AtLeast32Bit + Decode + Encode,
{
/// Construct a new, blank leaf set.
pub fn new() -> Self {
Self {
storage: BTreeMap::new(),
pending_added: Vec::new(),
pending_removed: Vec::new(),
}
}
/// Read the leaf list from the DB, using given prefix for keys.
pub fn read_from_db(db: &dyn Database, column: u32, prefix: &[u8]) -> Result {
let mut storage = BTreeMap::new();
match db.get(column, prefix) {
Some(leaves) => {
let vals: Vec<_> = match Decode::decode(&mut leaves.as_ref()) {
Ok(vals) => vals,
Err(_) => return Err(Error::Backend("Error decoding leaves".into())),
};
for (number, hashes) in vals.into_iter() {
storage.insert(Reverse(number), hashes);
}
}
None => {},
}
Ok(Self {
storage,
pending_added: Vec::new(),
pending_removed: Vec::new(),
})
}
/// update the leaf list on import. returns a displaced leaf if there was one.
pub fn import(&mut self, hash: H, number: N, parent_hash: H) -> Option> {
// avoid underflow for genesis.
let displaced = if number != N::zero() {
let new_number = Reverse(number.clone() - N::one());
let was_displaced = self.remove_leaf(&new_number, &parent_hash);
if was_displaced {
self.pending_removed.push(parent_hash.clone());
Some(ImportDisplaced {
new_hash: hash.clone(),
displaced: LeafSetItem {
hash: parent_hash,
number: new_number,
},
})
} else {
None
}
} else {
None
};
self.insert_leaf(Reverse(number.clone()), hash.clone());
self.pending_added.push((hash, number));
displaced
}
/// Note a block height finalized, displacing all leaves with number less than the finalized block's.
///
/// Although it would be more technically correct to also prune out leaves at the
/// same number as the finalized block, but with different hashes, the current behavior
/// is simpler and our assumptions about how finalization works means that those leaves
/// will be pruned soon afterwards anyway.
pub fn finalize_height(&mut self, number: N) -> FinalizationDisplaced {
let boundary = if number == N::zero() {
return FinalizationDisplaced { leaves: BTreeMap::new() };
} else {
number - N::one()
};
let below_boundary = self.storage.split_off(&Reverse(boundary));
self.pending_removed.extend(below_boundary.values().flat_map(|h| h.iter()).cloned());
FinalizationDisplaced {
leaves: below_boundary,
}
}
/// Undo all pending operations.
///
/// This returns an `Undo` struct, where any
/// `Displaced` objects that have returned by previous method calls
/// should be passed to via the appropriate methods. Otherwise,
/// the on-disk state may get out of sync with in-memory state.
pub fn undo(&mut self) -> Undo {
Undo { inner: self }
}
/// Revert to the given block height by dropping all leaves in the leaf set
/// with a block number higher than the target.
pub fn revert(&mut self, best_hash: H, best_number: N) {
let items = self.storage.iter()
.flat_map(|(number, hashes)| hashes.iter().map(move |h| (h.clone(), number.clone())))
.collect::>();
for (hash, number) in &items {
if number.0 > best_number {
assert!(
self.remove_leaf(number, hash),
"item comes from an iterator over storage; qed",
);
self.pending_removed.push(hash.clone());
}
}
let best_number = Reverse(best_number);
let leaves_contains_best = self.storage
.get(&best_number)
.map_or(false, |hashes| hashes.contains(&best_hash));
// we need to make sure that the best block exists in the leaf set as
// this is an invariant of regular block import.
if !leaves_contains_best {
self.insert_leaf(best_number.clone(), best_hash.clone());
self.pending_added.push((best_hash, best_number.0));
}
}
/// returns an iterator over all hashes in the leaf set
/// ordered by their block number descending.
pub fn hashes(&self) -> Vec {
self.storage.iter().flat_map(|(_, hashes)| hashes.iter()).cloned().collect()
}
/// Number of known leaves
pub fn count(&self) -> usize {
self.storage.len()
}
/// Write the leaf list to the database transaction.
pub fn prepare_transaction(&mut self, tx: &mut Transaction, column: u32, prefix: &[u8]) {
let leaves: Vec<_> = self.storage.iter().map(|(n, h)| (n.0.clone(), h.clone())).collect();
tx.set_from_vec(column, prefix, leaves.encode());
self.pending_added.clear();
self.pending_removed.clear();
}
#[cfg(test)]
fn contains(&self, number: N, hash: H) -> bool {
self.storage.get(&Reverse(number)).map_or(false, |hashes| hashes.contains(&hash))
}
fn insert_leaf(&mut self, number: Reverse, hash: H) {
self.storage.entry(number).or_insert_with(Vec::new).push(hash);
}
// returns true if this leaf was contained, false otherwise.
fn remove_leaf(&mut self, number: &Reverse, hash: &H) -> bool {
let mut empty = false;
let removed = self.storage.get_mut(number).map_or(false, |leaves| {
let mut found = false;
leaves.retain(|h| if h == hash {
found = true;
false
} else {
true
});
if leaves.is_empty() { empty = true }
found
});
if removed && empty {
self.storage.remove(number);
}
removed
}
}
/// Helper for undoing operations.
pub struct Undo<'a, H: 'a, N: 'a> {
inner: &'a mut LeafSet,
}
impl<'a, H: 'a, N: 'a> Undo<'a, H, N> where
H: Clone + PartialEq + Decode + Encode,
N: std::fmt::Debug + Clone + AtLeast32Bit + Decode + Encode,
{
/// Undo an imported block by providing the displaced leaf.
pub fn undo_import(&mut self, displaced: ImportDisplaced) {
let new_number = Reverse(displaced.displaced.number.0.clone() + N::one());
self.inner.remove_leaf(&new_number, &displaced.new_hash);
self.inner.insert_leaf(new_number, displaced.displaced.hash);
}
/// Undo a finalization operation by providing the displaced leaves.
pub fn undo_finalization(&mut self, mut displaced: FinalizationDisplaced) {
self.inner.storage.append(&mut displaced.leaves);
}
}
impl<'a, H: 'a, N: 'a> Drop for Undo<'a, H, N> {
fn drop(&mut self) {
self.inner.pending_added.clear();
self.inner.pending_removed.clear();
}
}
#[cfg(test)]
mod tests {
use super::*;
use std::sync::Arc;
#[test]
fn it_works() {
let mut set = LeafSet::new();
set.import(0u32, 0u32, 0u32);
set.import(1_1, 1, 0);
set.import(2_1, 2, 1_1);
set.import(3_1, 3, 2_1);
assert!(set.contains(3, 3_1));
assert!(!set.contains(2, 2_1));
assert!(!set.contains(1, 1_1));
assert!(!set.contains(0, 0));
set.import(2_2, 2, 1_1);
assert!(set.contains(3, 3_1));
assert!(set.contains(2, 2_2));
}
#[test]
fn flush_to_disk() {
const PREFIX: &[u8] = b"abcdefg";
let db = Arc::new(sp_database::MemDb::default());
let mut set = LeafSet::new();
set.import(0u32, 0u32, 0u32);
set.import(1_1, 1, 0);
set.import(2_1, 2, 1_1);
set.import(3_1, 3, 2_1);
let mut tx = Transaction::new();
set.prepare_transaction(&mut tx, 0, PREFIX);
db.commit(tx).unwrap();
let set2 = LeafSet::read_from_db(&*db, 0, PREFIX).unwrap();
assert_eq!(set, set2);
}
#[test]
fn two_leaves_same_height_can_be_included() {
let mut set = LeafSet::new();
set.import(1_1u32, 10u32,0u32);
set.import(1_2, 10, 0);
assert!(set.storage.contains_key(&Reverse(10)));
assert!(set.contains(10, 1_1));
assert!(set.contains(10, 1_2));
assert!(!set.contains(10, 1_3));
}
#[test]
fn finalization_consistent_with_disk() {
const PREFIX: &[u8] = b"prefix";
let db = Arc::new(sp_database::MemDb::default());
let mut set = LeafSet::new();
set.import(10_1u32, 10u32, 0u32);
set.import(11_1, 11, 10_2);
set.import(11_2, 11, 10_2);
set.import(12_1, 12, 11_123);
assert!(set.contains(10, 10_1));
let mut tx = Transaction::new();
set.prepare_transaction(&mut tx, 0, PREFIX);
db.commit(tx).unwrap();
let _ = set.finalize_height(11);
let mut tx = Transaction::new();
set.prepare_transaction(&mut tx, 0, PREFIX);
db.commit(tx).unwrap();
assert!(set.contains(11, 11_1));
assert!(set.contains(11, 11_2));
assert!(set.contains(12, 12_1));
assert!(!set.contains(10, 10_1));
let set2 = LeafSet::read_from_db(&*db, 0, PREFIX).unwrap();
assert_eq!(set, set2);
}
#[test]
fn undo_finalization() {
let mut set = LeafSet::new();
set.import(10_1u32, 10u32, 0u32);
set.import(11_1, 11, 10_2);
set.import(11_2, 11, 10_2);
set.import(12_1, 12, 11_123);
let displaced = set.finalize_height(11);
assert!(!set.contains(10, 10_1));
set.undo().undo_finalization(displaced);
assert!(set.contains(10, 10_1));
}
}