// Copyright 2017-2019 Parity Technologies (UK) Ltd.
// This file is part of Substrate.
// Substrate 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.
// Substrate 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 Substrate. If not, see .
//! State machine backends. These manage the code and storage of contracts.
use std::{error, fmt, cmp::Ord, collections::{HashMap, BTreeMap}, marker::PhantomData, ops};
use log::warn;
use hash_db::Hasher;
use crate::trie_backend::TrieBackend;
use crate::trie_backend_essence::TrieBackendStorage;
use sp_trie::{
TrieMut, MemoryDB, child_trie_root, default_child_trie_root, TrieConfiguration,
trie_types::{TrieDBMut, Layout},
};
use codec::{Encode, Codec};
use sp_core::storage::{ChildInfo, OwnedChildInfo, Storage};
/// A state backend is used to read state data and can have changes committed
/// to it.
///
/// The clone operation (if implemented) should be cheap.
pub trait Backend: std::fmt::Debug {
/// An error type when fetching data is not possible.
type Error: super::Error;
/// Storage changes to be applied if committing
type Transaction: Consolidate + Default;
/// Type of trie backend storage.
type TrieBackendStorage: TrieBackendStorage;
/// Get keyed storage or None if there is nothing associated.
fn storage(&self, key: &[u8]) -> Result>, Self::Error>;
/// Get keyed storage value hash or None if there is nothing associated.
fn storage_hash(&self, key: &[u8]) -> Result , Self::Error> {
self.storage(key).map(|v| v.map(|v| H::hash(&v)))
}
/// Get keyed child storage or None if there is nothing associated.
fn child_storage(
&self,
storage_key: &[u8],
child_info: ChildInfo,
key: &[u8],
) -> Result >, Self::Error>;
/// Get child keyed storage value hash or None if there is nothing associated.
fn child_storage_hash(
&self,
storage_key: &[u8],
child_info: ChildInfo,
key: &[u8],
) -> Result , Self::Error> {
self.child_storage(storage_key, child_info, key).map(|v| v.map(|v| H::hash(&v)))
}
/// true if a key exists in storage.
fn exists_storage(&self, key: &[u8]) -> Result {
Ok(self.storage(key)?.is_some())
}
/// true if a key exists in child storage.
fn exists_child_storage(
&self,
storage_key: &[u8],
child_info: ChildInfo,
key: &[u8],
) -> Result {
Ok(self.child_storage(storage_key, child_info, key)?.is_some())
}
/// Return the next key in storage in lexicographic order or `None` if there is no value.
fn next_storage_key(&self, key: &[u8]) -> Result>, Self::Error>;
/// Return the next key in child storage in lexicographic order or `None` if there is no value.
fn next_child_storage_key(
&self,
storage_key: &[u8],
child_info: ChildInfo,
key: &[u8]
) -> Result >, Self::Error>;
/// Retrieve all entries keys of child storage and call `f` for each of those keys.
fn for_keys_in_child_storage(
&self,
storage_key: &[u8],
child_info: ChildInfo,
f: F,
);
/// Retrieve all entries keys which start with the given prefix and
/// call `f` for each of those keys.
fn for_keys_with_prefix(&self, prefix: &[u8], mut f: F) {
self.for_key_values_with_prefix(prefix, |k, _v| f(k))
}
/// Retrieve all entries keys and values of which start with the given prefix and
/// call `f` for each of those keys.
fn for_key_values_with_prefix(&self, prefix: &[u8], f: F);
/// Retrieve all child entries keys which start with the given prefix and
/// call `f` for each of those keys.
fn for_child_keys_with_prefix(
&self,
storage_key: &[u8],
child_info: ChildInfo,
prefix: &[u8],
f: F,
);
/// Calculate the storage root, with given delta over what is already stored in
/// the backend, and produce a "transaction" that can be used to commit.
/// Does not include child storage updates.
fn storage_root(&self, delta: I) -> (H::Out, Self::Transaction)
where
I: IntoIterator- , Option
>)>,
H::Out: Ord;
/// Calculate the child storage root, with given delta over what is already stored in
/// the backend, and produce a "transaction" that can be used to commit. The second argument
/// is true if child storage root equals default storage root.
fn child_storage_root(
&self,
storage_key: &[u8],
child_info: ChildInfo,
delta: I,
) -> (H::Out, bool, Self::Transaction)
where
I: IntoIterator- , Option
>)>,
H::Out: Ord;
/// Get all key/value pairs into a Vec.
fn pairs(&self) -> Vec<(Vec, Vec)>;
/// Get all keys with given prefix
fn keys(&self, prefix: &[u8]) -> Vec> {
let mut all = Vec::new();
self.for_keys_with_prefix(prefix, |k| all.push(k.to_vec()));
all
}
/// Get all keys of child storage with given prefix
fn child_keys(
&self,
storage_key: &[u8],
child_info: ChildInfo,
prefix: &[u8],
) -> Vec> {
let mut all = Vec::new();
self.for_child_keys_with_prefix(storage_key, child_info, prefix, |k| all.push(k.to_vec()));
all
}
/// Try convert into trie backend.
fn as_trie_backend(&mut self) -> Option<&TrieBackend> {
None
}
/// Calculate the storage root, with given delta over what is already stored
/// in the backend, and produce a "transaction" that can be used to commit.
/// Does include child storage updates.
fn full_storage_root(
&self,
delta: I1,
child_deltas: I2)
-> (H::Out, Self::Transaction)
where
I1: IntoIterator- , Option
>)>,
I2i: IntoIterator- , Option
>)>,
I2: IntoIterator- , I2i, OwnedChildInfo)>,
H::Out: Ord + Encode,
{
let mut txs: Self::Transaction = Default::default();
let mut child_roots: Vec<_> = Default::default();
// child first
for (storage_key, child_delta, child_info) in child_deltas {
let (child_root, empty, child_txs) =
self.child_storage_root(&storage_key[..], child_info.as_ref(), child_delta);
txs.consolidate(child_txs);
if empty {
child_roots.push((storage_key, None));
} else {
child_roots.push((storage_key, Some(child_root.encode())));
}
}
let (root, parent_txs) = self.storage_root(
delta.into_iter().chain(child_roots.into_iter())
);
txs.consolidate(parent_txs);
(root, txs)
}
}
impl<'a, T: Backend
, H: Hasher> Backend for &'a T {
type Error = T::Error;
type Transaction = T::Transaction;
type TrieBackendStorage = T::TrieBackendStorage;
fn storage(&self, key: &[u8]) -> Result>, Self::Error> {
(*self).storage(key)
}
fn child_storage(
&self,
storage_key: &[u8],
child_info: ChildInfo,
key: &[u8],
) -> Result >, Self::Error> {
(*self).child_storage(storage_key, child_info, key)
}
fn for_keys_in_child_storage(
&self,
storage_key: &[u8],
child_info: ChildInfo,
f: F,
) {
(*self).for_keys_in_child_storage(storage_key, child_info, f)
}
fn next_storage_key(&self, key: &[u8]) -> Result>, Self::Error> {
(*self).next_storage_key(key)
}
fn next_child_storage_key(
&self,
storage_key: &[u8],
child_info: ChildInfo,
key: &[u8],
) -> Result >, Self::Error> {
(*self).next_child_storage_key(storage_key, child_info, key)
}
fn for_keys_with_prefix(&self, prefix: &[u8], f: F) {
(*self).for_keys_with_prefix(prefix, f)
}
fn for_child_keys_with_prefix(
&self,
storage_key: &[u8],
child_info: ChildInfo,
prefix: &[u8],
f: F,
) {
(*self).for_child_keys_with_prefix(storage_key, child_info, prefix, f)
}
fn storage_root(&self, delta: I) -> (H::Out, Self::Transaction)
where
I: IntoIterator- , Option
>)>,
H::Out: Ord,
{
(*self).storage_root(delta)
}
fn child_storage_root(
&self,
storage_key: &[u8],
child_info: ChildInfo,
delta: I,
) -> (H::Out, bool, Self::Transaction)
where
I: IntoIterator- , Option
>)>,
H::Out: Ord,
{
(*self).child_storage_root(storage_key, child_info, delta)
}
fn pairs(&self) -> Vec<(Vec, Vec)> {
(*self).pairs()
}
fn for_key_values_with_prefix(&self, prefix: &[u8], f: F) {
(*self).for_key_values_with_prefix(prefix, f);
}
}
/// Trait that allows consolidate two transactions together.
pub trait Consolidate {
/// Consolidate two transactions into one.
fn consolidate(&mut self, other: Self);
}
impl Consolidate for () {
fn consolidate(&mut self, _: Self) {
()
}
}
impl Consolidate for Vec<(
Option<(Vec, OwnedChildInfo)>,
Vec<(Vec, Option>)>,
)> {
fn consolidate(&mut self, mut other: Self) {
self.append(&mut other);
}
}
impl> Consolidate for sp_trie::GenericMemoryDB {
fn consolidate(&mut self, other: Self) {
sp_trie::GenericMemoryDB::consolidate(self, other)
}
}
/// Error impossible.
// FIXME: use `!` type when stabilized. https://github.com/rust-lang/rust/issues/35121
#[derive(Debug)]
pub enum Void {}
impl fmt::Display for Void {
fn fmt(&self, _: &mut fmt::Formatter) -> fmt::Result {
match *self {}
}
}
impl error::Error for Void {
fn description(&self) -> &str { "unreachable error" }
}
/// In-memory backend. Fully recomputes tries each time `as_trie_backend` is called but useful for
/// tests and proof checking.
pub struct InMemory {
inner: HashMap, OwnedChildInfo)>, BTreeMap, Vec>>,
// This field is only needed for returning reference in `as_trie_backend`.
trie: Option, H>>,
_hasher: PhantomData,
}
impl std::fmt::Debug for InMemory {
fn fmt(&self, f: &mut fmt::Formatter<'_>) -> fmt::Result {
write!(f, "InMemory ({} values)", self.inner.len())
}
}
impl Default for InMemory {
fn default() -> Self {
InMemory {
inner: Default::default(),
trie: None,
_hasher: PhantomData,
}
}
}
impl Clone for InMemory {
fn clone(&self) -> Self {
InMemory {
inner: self.inner.clone(),
trie: None,
_hasher: PhantomData,
}
}
}
impl PartialEq for InMemory {
fn eq(&self, other: &Self) -> bool {
self.inner.eq(&other.inner)
}
}
impl InMemory where H::Out: Codec {
/// Copy the state, with applied updates
pub fn update(&self, changes: >::Transaction) -> Self {
let mut inner = self.inner.clone();
for (child_info, key_values) in changes {
let entry = inner.entry(child_info).or_default();
for (key, val) in key_values {
match val {
Some(v) => { entry.insert(key, v); },
None => { entry.remove(&key); },
}
}
}
inner.into()
}
}
impl From, OwnedChildInfo)>, BTreeMap, Vec>>> for InMemory {
fn from(inner: HashMap, OwnedChildInfo)>, BTreeMap, Vec>>) -> Self {
InMemory {
inner: inner,
trie: None,
_hasher: PhantomData,
}
}
}
impl From for InMemory {
fn from(inners: Storage) -> Self {
let mut inner: HashMap, OwnedChildInfo)>, BTreeMap, Vec>>
= inners.children.into_iter().map(|(k, c)| (Some((k, c.child_info)), c.data)).collect();
inner.insert(None, inners.top);
InMemory {
inner: inner,
trie: None,
_hasher: PhantomData,
}
}
}
impl From, Vec>> for InMemory {
fn from(inner: BTreeMap, Vec>) -> Self {
let mut expanded = HashMap::new();
expanded.insert(None, inner);
InMemory {
inner: expanded,
trie: None,
_hasher: PhantomData,
}
}
}
impl From, OwnedChildInfo)>, Vec<(Vec, Option>)>)>>
for InMemory {
fn from(
inner: Vec<(Option<(Vec, OwnedChildInfo)>, Vec<(Vec, Option>)>)>,
) -> Self {
let mut expanded: HashMap, OwnedChildInfo)>, BTreeMap, Vec>>
= HashMap::new();
for (child_info, key_values) in inner {
let entry = expanded.entry(child_info).or_default();
for (key, value) in key_values {
if let Some(value) = value {
entry.insert(key, value);
}
}
}
expanded.into()
}
}
impl InMemory {
/// child storage key iterator
pub fn child_storage_keys(&self) -> impl Iterator- {
self.inner.iter().filter_map(|item|
item.0.as_ref().map(|v|(&v.0[..], v.1.as_ref()))
)
}
}
impl
Backend for InMemory where H::Out: Codec {
type Error = Void;
type Transaction = Vec<(
Option<(Vec, OwnedChildInfo)>,
Vec<(Vec, Option>)>,
)>;
type TrieBackendStorage = MemoryDB;
fn storage(&self, key: &[u8]) -> Result>, Self::Error> {
Ok(self.inner.get(&None).and_then(|map| map.get(key).map(Clone::clone)))
}
fn child_storage(
&self,
storage_key: &[u8],
child_info: ChildInfo,
key: &[u8],
) -> Result >, Self::Error> {
Ok(self.inner.get(&Some((storage_key.to_vec(), child_info.to_owned())))
.and_then(|map| map.get(key).map(Clone::clone)))
}
fn exists_storage(&self, key: &[u8]) -> Result {
Ok(self.inner.get(&None).map(|map| map.get(key).is_some()).unwrap_or(false))
}
fn next_storage_key(&self, key: &[u8]) -> Result>, Self::Error> {
let range = (ops::Bound::Excluded(key), ops::Bound::Unbounded);
let next_key = self.inner.get(&None)
.and_then(|map| map.range::<[u8], _>(range).next().map(|(k, _)| k).cloned());
Ok(next_key)
}
fn next_child_storage_key(
&self,
storage_key: &[u8],
child_info: ChildInfo,
key: &[u8],
) -> Result >, Self::Error> {
let range = (ops::Bound::Excluded(key), ops::Bound::Unbounded);
let next_key = self.inner.get(&Some((storage_key.to_vec(), child_info.to_owned())))
.and_then(|map| map.range::<[u8], _>(range).next().map(|(k, _)| k).cloned());
Ok(next_key)
}
fn for_keys_with_prefix(&self, prefix: &[u8], f: F) {
self.inner.get(&None).map(|map| map.keys().filter(|key| key.starts_with(prefix)).map(|k| &**k).for_each(f));
}
fn for_key_values_with_prefix(&self, prefix: &[u8], mut f: F) {
self.inner.get(&None).map(|map| map.iter().filter(|(key, _val)| key.starts_with(prefix))
.for_each(|(k, v)| f(k, v)));
}
fn for_keys_in_child_storage(
&self,
storage_key: &[u8],
child_info: ChildInfo,
mut f: F,
) {
self.inner.get(&Some((storage_key.to_vec(), child_info.to_owned())))
.map(|map| map.keys().for_each(|k| f(&k)));
}
fn for_child_keys_with_prefix(
&self,
storage_key: &[u8],
child_info: ChildInfo,
prefix: &[u8],
f: F,
) {
self.inner.get(&Some((storage_key.to_vec(), child_info.to_owned())))
.map(|map| map.keys().filter(|key| key.starts_with(prefix)).map(|k| &**k).for_each(f));
}
fn storage_root(&self, delta: I) -> (H::Out, Self::Transaction)
where
I: IntoIterator- , Option
>)>,
::Out: Ord,
{
let existing_pairs = self.inner.get(&None)
.into_iter()
.flat_map(|map| map.iter().map(|(k, v)| (k.clone(), Some(v.clone()))));
let transaction: Vec<_> = delta.into_iter().collect();
let root = Layout::::trie_root(existing_pairs.chain(transaction.iter().cloned())
.collect::>()
.into_iter()
.filter_map(|(k, maybe_val)| maybe_val.map(|val| (k, val)))
);
let full_transaction = transaction.into_iter().collect();
(root, vec![(None, full_transaction)])
}
fn child_storage_root(
&self,
storage_key: &[u8],
child_info: ChildInfo,
delta: I,
) -> (H::Out, bool, Self::Transaction)
where
I: IntoIterator- , Option
>)>,
H::Out: Ord
{
let storage_key = storage_key.to_vec();
let child_info = Some((storage_key.clone(), child_info.to_owned()));
let existing_pairs = self.inner.get(&child_info)
.into_iter()
.flat_map(|map| map.iter().map(|(k, v)| (k.clone(), Some(v.clone()))));
let transaction: Vec<_> = delta.into_iter().collect();
let root = child_trie_root::, _, _, _>(
&storage_key,
existing_pairs.chain(transaction.iter().cloned())
.collect::>()
.into_iter()
.filter_map(|(k, maybe_val)| maybe_val.map(|val| (k, val)))
);
let full_transaction = transaction.into_iter().collect();
let is_default = root == default_child_trie_root::>(&storage_key);
(root, is_default, vec![(child_info, full_transaction)])
}
fn pairs(&self) -> Vec<(Vec, Vec)> {
self.inner.get(&None)
.into_iter()
.flat_map(|map| map.iter().map(|(k, v)| (k.clone(), v.clone())))
.collect()
}
fn keys(&self, prefix: &[u8]) -> Vec> {
self.inner.get(&None)
.into_iter()
.flat_map(|map| map.keys().filter(|k| k.starts_with(prefix)).cloned())
.collect()
}
fn child_keys(
&self,
storage_key: &[u8],
child_info: ChildInfo,
prefix: &[u8],
) -> Vec> {
self.inner.get(&Some((storage_key.to_vec(), child_info.to_owned())))
.into_iter()
.flat_map(|map| map.keys().filter(|k| k.starts_with(prefix)).cloned())
.collect()
}
fn as_trie_backend(&mut self)-> Option<&TrieBackend> {
let mut mdb = MemoryDB::default();
let mut new_child_roots = Vec::new();
let mut root_map = None;
for (child_info, map) in &self.inner {
if let Some((storage_key, _child_info)) = child_info.as_ref() {
// no need to use child_info at this point because we use a MemoryDB for
// proof (with PrefixedMemoryDB it would be needed).
let ch = insert_into_memory_db::(&mut mdb, map.clone().into_iter())?;
new_child_roots.push((storage_key.clone(), ch.as_ref().into()));
} else {
root_map = Some(map);
}
}
let root = match root_map {
Some(map) => insert_into_memory_db::(
&mut mdb,
map.clone().into_iter().chain(new_child_roots.into_iter()),
)?,
None => insert_into_memory_db::(
&mut mdb,
new_child_roots.into_iter(),
)?,
};
self.trie = Some(TrieBackend::new(mdb, root));
self.trie.as_ref()
}
}
/// Insert input pairs into memory db.
pub(crate) fn insert_into_memory_db(mdb: &mut MemoryDB, input: I) -> Option
where
H: Hasher,
I: IntoIterator- , Vec
)>,
{
let mut root = ::Out::default();
{
let mut trie = TrieDBMut::::new(mdb, &mut root);
for (key, value) in input {
if let Err(e) = trie.insert(&key, &value) {
warn!(target: "trie", "Failed to write to trie: {}", e);
return None;
}
}
}
Some(root)
}
#[cfg(test)]
mod tests {
use super::*;
/// Assert in memory backend with only child trie keys works as trie backend.
#[test]
fn in_memory_with_child_trie_only() {
let storage = InMemory::::default();
let child_info = OwnedChildInfo::new_default(b"unique_id_1".to_vec());
let mut storage = storage.update(
vec![(
Some((b"1".to_vec(), child_info.clone())),
vec![(b"2".to_vec(), Some(b"3".to_vec()))]
)]
);
let trie_backend = storage.as_trie_backend().unwrap();
assert_eq!(trie_backend.child_storage(b"1", child_info.as_ref(), b"2").unwrap(),
Some(b"3".to_vec()));
assert!(trie_backend.storage(b"1").unwrap().is_some());
}
}