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use hash_db::Hasher;
use sp_trie::Recorder;
use log::warn;
use num_traits::One;
use crate::proving_backend::ProvingBackendRecorder;
use crate::trie_backend_essence::TrieBackendEssence;
use crate::changes_trie::{AnchorBlockId, Storage, BlockNumber};
use crate::changes_trie::storage::TrieBackendAdapter;
use crate::changes_trie::input::{ChildIndex, InputKey};
use codec::{Decode, Codec};
pub fn prune<H: Hasher, Number: BlockNumber, F: FnMut(H::Out)>(
storage: &dyn Storage<H, Number>,
first: Number,
last: Number,
current_block: &AnchorBlockId<H::Out, Number>,
mut remove_trie_node: F,
) where H::Out: Codec {
let mut block = first;
loop {
if block >= last.clone() + One::one() {
break;
}
let prev_block = block.clone();
block += One::one();
let block = prev_block;
let root = match storage.root(current_block, block.clone()) {
Ok(Some(root)) => root,
Ok(None) => continue,
Err(error) => {
warn!(target: "trie", "Failed to read changes trie root from DB: {}", error);
continue;
},
};
let children_roots = {
let trie_storage = TrieBackendEssence::<_, H>::new(
crate::changes_trie::TrieBackendStorageAdapter(storage),
root,
);
let child_prefix = ChildIndex::key_neutral_prefix(block.clone());
let mut children_roots = Vec::new();
trie_storage.for_key_values_with_prefix(&child_prefix, |key, value| {
if let Ok(InputKey::ChildIndex::<Number>(_trie_key)) = Decode::decode(&mut &key[..]) {
if let Ok(value) = <Vec<u8>>::decode(&mut &value[..]) {
let mut trie_root = <H as Hasher>::Out::default();
trie_root.as_mut().copy_from_slice(&value[..]);
children_roots.push(trie_root);
}
}
});
children_roots
};
for root in children_roots.into_iter() {
prune_trie(storage, root, &mut remove_trie_node);
}
prune_trie(storage, root, &mut remove_trie_node);
}
}
fn prune_trie<H: Hasher, Number: BlockNumber, F: FnMut(H::Out)>(
storage: &dyn Storage<H, Number>,
root: H::Out,
remove_trie_node: &mut F,
) where H::Out: Codec {
let mut proof_recorder: Recorder<H::Out> = Default::default();
{
let mut trie = ProvingBackendRecorder::<_, H> {
backend: &TrieBackendEssence::new(TrieBackendAdapter::new(storage), root),
proof_recorder: &mut proof_recorder,
};
trie.record_all_keys();
}
remove_trie_node(root);
for node in proof_recorder.drain().into_iter().map(|n| n.hash) {
remove_trie_node(node);
}
}
#[cfg(test)]
mod tests {
use std::collections::HashSet;
use sp_trie::MemoryDB;
use sp_core::H256;
use crate::backend::insert_into_memory_db;
use crate::changes_trie::storage::InMemoryStorage;
use codec::Encode;
use sp_runtime::traits::BlakeTwo256;
use super::*;
fn prune_by_collect(
storage: &dyn Storage<BlakeTwo256, u64>,
first: u64,
last: u64,
current_block: u64,
) -> HashSet<H256> {
let mut pruned_trie_nodes = HashSet::new();
let anchor = AnchorBlockId { hash: Default::default(), number: current_block };
prune(storage, first, last, &anchor,
|node| { pruned_trie_nodes.insert(node); });
pruned_trie_nodes
}
#[test]
fn prune_works() {
fn prepare_storage() -> InMemoryStorage<BlakeTwo256, u64> {
let child_info = sp_core::storage::ChildInfo::new_default(&b"1"[..]);
let child_key = ChildIndex { block: 67u64, storage_key: child_info.prefixed_storage_key() }.encode();
let mut mdb1 = MemoryDB::<BlakeTwo256>::default();
let root1 = insert_into_memory_db::<BlakeTwo256, _>(
&mut mdb1, vec![(vec![10], vec![20])]).unwrap();
let mut mdb2 = MemoryDB::<BlakeTwo256>::default();
let root2 = insert_into_memory_db::<BlakeTwo256, _>(
&mut mdb2,
vec![(vec![11], vec![21]), (vec![12], vec![22])],
).unwrap();
let mut mdb3 = MemoryDB::<BlakeTwo256>::default();
let ch_root3 = insert_into_memory_db::<BlakeTwo256, _>(
&mut mdb3, vec![(vec![110], vec![120])]).unwrap();
let root3 = insert_into_memory_db::<BlakeTwo256, _>(&mut mdb3, vec![
(vec![13], vec![23]),
(vec![14], vec![24]),
(child_key, ch_root3.as_ref().encode()),
]).unwrap();
let mut mdb4 = MemoryDB::<BlakeTwo256>::default();
let root4 = insert_into_memory_db::<BlakeTwo256, _>(
&mut mdb4,
vec![(vec![15], vec![25])],
).unwrap();
let storage = InMemoryStorage::new();
storage.insert(65, root1, mdb1);
storage.insert(66, root2, mdb2);
storage.insert(67, root3, mdb3);
storage.insert(68, root4, mdb4);
storage
}
let storage = prepare_storage();
assert!(prune_by_collect(&storage, 20, 30, 90).is_empty());
assert!(!storage.into_mdb().drain().is_empty());
let storage = prepare_storage();
let prune60_65 = prune_by_collect(&storage, 60, 65, 90);
assert!(!prune60_65.is_empty());
storage.remove_from_storage(&prune60_65);
assert!(!storage.into_mdb().drain().is_empty());
let storage = prepare_storage();
let prune60_70 = prune_by_collect(&storage, 60, 70, 90);
assert!(!prune60_70.is_empty());
storage.remove_from_storage(&prune60_70);
assert!(storage.into_mdb().drain().is_empty());
}
}