use crate::{
blueprint::{
BlueprintInspect,
BlueprintMutate,
SupportsBatching,
SupportsMerkle,
},
codec::{
Decode,
Encode,
Encoder,
},
kv_store::{
BatchOperations,
KeyValueInspect,
KeyValueMutate,
StorageColumn,
WriteOperation,
},
structured_storage::TableWithBlueprint,
tables::merkle::SparseMerkleMetadata,
Error as StorageError,
Mappable,
MerkleRoot,
Result as StorageResult,
StorageAsMut,
StorageInspect,
StorageMutate,
};
use fuel_core_types::fuel_merkle::{
sparse,
sparse::{
in_memory,
MerkleTree,
MerkleTreeKey,
},
};
use itertools::Itertools;
use std::borrow::Cow;
pub trait PrimaryKey {
type InputKey: ?Sized;
type OutputKey: ?Sized;
fn primary_key(key: &Self::InputKey) -> &Self::OutputKey;
}
pub struct Sparse<KeyCodec, ValueCodec, Metadata, Nodes, KeyConverter> {
_marker:
core::marker::PhantomData<(KeyCodec, ValueCodec, Metadata, Nodes, KeyConverter)>,
}
impl<KeyCodec, ValueCodec, Metadata, Nodes, KeyConverter>
Sparse<KeyCodec, ValueCodec, Metadata, Nodes, KeyConverter>
where
Metadata: Mappable<Value = SparseMerkleMetadata, OwnedValue = SparseMerkleMetadata>,
Nodes: Mappable<
Key = MerkleRoot,
Value = sparse::Primitive,
OwnedValue = sparse::Primitive,
>,
{
fn insert_into_tree<S, K>(
storage: &mut S,
key: &K,
key_bytes: &[u8],
value_bytes: &[u8],
) -> StorageResult<()>
where
K: ?Sized,
S: StorageMutate<Metadata, Error = StorageError>
+ StorageMutate<Nodes, Error = StorageError>,
KeyConverter: PrimaryKey<InputKey = K, OutputKey = Metadata::Key>,
{
let primary_key = KeyConverter::primary_key(key);
let prev_metadata: Cow<SparseMerkleMetadata> = storage
.storage::<Metadata>()
.get(primary_key)?
.unwrap_or_default();
let root = *prev_metadata.root();
let mut tree: MerkleTree<Nodes, _> = MerkleTree::load(storage, &root)
.map_err(|err| StorageError::Other(anyhow::anyhow!("{err:?}")))?;
tree.update(MerkleTreeKey::new(key_bytes), value_bytes)
.map_err(|err| StorageError::Other(anyhow::anyhow!("{err:?}")))?;
let root = tree.root();
let storage = tree.into_storage();
let metadata = SparseMerkleMetadata::new(root);
storage
.storage::<Metadata>()
.insert(primary_key, &metadata)?;
Ok(())
}
fn remove_from_tree<S, K>(
storage: &mut S,
key: &K,
key_bytes: &[u8],
) -> StorageResult<()>
where
K: ?Sized,
S: StorageMutate<Metadata, Error = StorageError>
+ StorageMutate<Nodes, Error = StorageError>,
KeyConverter: PrimaryKey<InputKey = K, OutputKey = Metadata::Key>,
{
let primary_key = KeyConverter::primary_key(key);
let prev_metadata: Option<Cow<SparseMerkleMetadata>> =
storage.storage::<Metadata>().get(primary_key)?;
if let Some(prev_metadata) = prev_metadata {
let root = *prev_metadata.root();
let mut tree: MerkleTree<Nodes, _> = MerkleTree::load(storage, &root)
.map_err(|err| StorageError::Other(anyhow::anyhow!("{err:?}")))?;
tree.delete(MerkleTreeKey::new(key_bytes))
.map_err(|err| StorageError::Other(anyhow::anyhow!("{err:?}")))?;
let root = tree.root();
let storage = tree.into_storage();
if &root == MerkleTree::<Nodes, S>::empty_root() {
storage.storage::<Metadata>().remove(primary_key)?;
} else {
let metadata = SparseMerkleMetadata::new(root);
storage
.storage::<Metadata>()
.insert(primary_key, &metadata)?;
}
}
Ok(())
}
}
impl<M, S, KeyCodec, ValueCodec, Metadata, Nodes, KeyConverter> BlueprintInspect<M, S>
for Sparse<KeyCodec, ValueCodec, Metadata, Nodes, KeyConverter>
where
M: Mappable,
S: KeyValueInspect,
KeyCodec: Encode<M::Key> + Decode<M::OwnedKey>,
ValueCodec: Encode<M::Value> + Decode<M::OwnedValue>,
{
type KeyCodec = KeyCodec;
type ValueCodec = ValueCodec;
}
impl<M, S, KeyCodec, ValueCodec, Metadata, Nodes, KeyConverter> BlueprintMutate<M, S>
for Sparse<KeyCodec, ValueCodec, Metadata, Nodes, KeyConverter>
where
M: Mappable,
S: KeyValueMutate,
KeyCodec: Encode<M::Key> + Decode<M::OwnedKey>,
ValueCodec: Encode<M::Value> + Decode<M::OwnedValue>,
Metadata: Mappable<Value = SparseMerkleMetadata, OwnedValue = SparseMerkleMetadata>,
Nodes: Mappable<
Key = MerkleRoot,
Value = sparse::Primitive,
OwnedValue = sparse::Primitive,
>,
KeyConverter: PrimaryKey<InputKey = M::Key, OutputKey = Metadata::Key>,
S: StorageMutate<Metadata, Error = StorageError>
+ StorageMutate<Nodes, Error = StorageError>,
{
fn put(
storage: &mut S,
key: &M::Key,
column: S::Column,
value: &M::Value,
) -> StorageResult<()> {
let key_encoder = KeyCodec::encode(key);
let key_bytes = key_encoder.as_bytes();
let value = ValueCodec::encode_as_value(value);
storage.put(key_bytes.as_ref(), column, value.clone())?;
Self::insert_into_tree(storage, key, key_bytes.as_ref(), value.as_ref())
}
fn replace(
storage: &mut S,
key: &M::Key,
column: S::Column,
value: &M::Value,
) -> StorageResult<Option<M::OwnedValue>> {
let key_encoder = KeyCodec::encode(key);
let key_bytes = key_encoder.as_bytes();
let value = ValueCodec::encode_as_value(value);
let prev = storage
.replace(key_bytes.as_ref(), column, value.clone())?
.map(|value| {
ValueCodec::decode_from_value(value).map_err(StorageError::Codec)
})
.transpose()?;
Self::insert_into_tree(storage, key, key_bytes.as_ref(), value.as_ref())?;
Ok(prev)
}
fn take(
storage: &mut S,
key: &M::Key,
column: S::Column,
) -> StorageResult<Option<M::OwnedValue>> {
let key_encoder = KeyCodec::encode(key);
let key_bytes = key_encoder.as_bytes();
let prev = storage
.take(key_bytes.as_ref(), column)?
.map(|value| {
ValueCodec::decode_from_value(value).map_err(StorageError::Codec)
})
.transpose()?;
Self::remove_from_tree(storage, key, key_bytes.as_ref())?;
Ok(prev)
}
fn delete(storage: &mut S, key: &M::Key, column: S::Column) -> StorageResult<()> {
let key_encoder = KeyCodec::encode(key);
let key_bytes = key_encoder.as_bytes();
storage.delete(key_bytes.as_ref(), column)?;
Self::remove_from_tree(storage, key, key_bytes.as_ref())
}
}
impl<M, S, KeyCodec, ValueCodec, Metadata, Nodes, KeyConverter>
SupportsMerkle<Metadata::Key, M, S>
for Sparse<KeyCodec, ValueCodec, Metadata, Nodes, KeyConverter>
where
M: Mappable,
S: KeyValueInspect,
Metadata: Mappable<Value = SparseMerkleMetadata, OwnedValue = SparseMerkleMetadata>,
Self: BlueprintInspect<M, S>,
S: StorageInspect<Metadata, Error = StorageError>,
{
fn root(storage: &S, key: &Metadata::Key) -> StorageResult<MerkleRoot> {
use crate::StorageAsRef;
let metadata: Option<Cow<SparseMerkleMetadata>> =
storage.storage_as_ref::<Metadata>().get(key)?;
let root = metadata
.map(|metadata| *metadata.root())
.unwrap_or_else(|| in_memory::MerkleTree::new().root());
Ok(root)
}
}
type NodeKeyCodec<S, Nodes> =
<<Nodes as TableWithBlueprint>::Blueprint as BlueprintInspect<Nodes, S>>::KeyCodec;
type NodeValueCodec<S, Nodes> =
<<Nodes as TableWithBlueprint>::Blueprint as BlueprintInspect<Nodes, S>>::ValueCodec;
impl<Column, M, S, KeyCodec, ValueCodec, Metadata, Nodes, KeyConverter>
SupportsBatching<M, S> for Sparse<KeyCodec, ValueCodec, Metadata, Nodes, KeyConverter>
where
Column: StorageColumn,
S: BatchOperations<Column = Column>,
M: TableWithBlueprint<
Blueprint = Sparse<KeyCodec, ValueCodec, Metadata, Nodes, KeyConverter>,
Column = Column,
>,
KeyCodec: Encode<M::Key> + Decode<M::OwnedKey>,
ValueCodec: Encode<M::Value> + Decode<M::OwnedValue>,
Metadata: Mappable<Value = SparseMerkleMetadata, OwnedValue = SparseMerkleMetadata>,
Nodes: Mappable<
Key = MerkleRoot,
Value = sparse::Primitive,
OwnedValue = sparse::Primitive,
> + TableWithBlueprint<Column = Column>,
KeyConverter: PrimaryKey<InputKey = M::Key, OutputKey = Metadata::Key>,
Nodes::Blueprint: BlueprintInspect<Nodes, S>,
S: StorageMutate<M, Error = StorageError>
+ StorageMutate<Metadata, Error = StorageError>
+ StorageMutate<Nodes, Error = StorageError>,
{
fn init<'a, Iter>(storage: &mut S, column: S::Column, set: Iter) -> StorageResult<()>
where
Iter: 'a + Iterator<Item = (&'a M::Key, &'a M::Value)>,
M::Key: 'a,
M::Value: 'a,
{
let mut set = set.peekable();
let primary_key;
if let Some((key, _)) = set.peek() {
primary_key = KeyConverter::primary_key(*key);
} else {
return Ok(())
}
if storage.storage::<Metadata>().contains_key(primary_key)? {
return Err(anyhow::anyhow!(
"The {} is already initialized",
M::column().name()
)
.into())
}
let encoded_set = set
.map(|(key, value)| {
let key = KeyCodec::encode(key).as_bytes().into_owned();
let value = ValueCodec::encode(value).as_bytes().into_owned();
(key, value)
})
.collect_vec();
let (root, nodes) = in_memory::MerkleTree::nodes_from_set(
encoded_set
.iter()
.map(|(key, value)| (MerkleTreeKey::new(key), value)),
);
storage.batch_write(
column,
encoded_set
.into_iter()
.map(|(key, value)| (key, WriteOperation::Insert(value.into()))),
)?;
let nodes = nodes.iter().map(|(key, value)| {
let key = NodeKeyCodec::<S, Nodes>::encode(key)
.as_bytes()
.into_owned();
let value = NodeValueCodec::<S, Nodes>::encode_as_value(value);
(key, WriteOperation::Insert(value))
});
storage.batch_write(Nodes::column(), nodes)?;
let metadata = SparseMerkleMetadata::new(root);
storage
.storage::<Metadata>()
.insert(primary_key, &metadata)?;
Ok(())
}
fn insert<'a, Iter>(
storage: &mut S,
column: S::Column,
set: Iter,
) -> StorageResult<()>
where
Iter: 'a + Iterator<Item = (&'a M::Key, &'a M::Value)>,
M::Key: 'a,
M::Value: 'a,
{
let mut set = set.peekable();
let primary_key;
if let Some((key, _)) = set.peek() {
primary_key = KeyConverter::primary_key(*key);
} else {
return Ok(())
}
let prev_metadata: Cow<SparseMerkleMetadata> = storage
.storage::<Metadata>()
.get(primary_key)?
.unwrap_or_default();
let root = *prev_metadata.root();
let mut tree: MerkleTree<Nodes, _> = MerkleTree::load(storage, &root)
.map_err(|err| StorageError::Other(anyhow::anyhow!("{err:?}")))?;
let encoded_set = set
.map(|(key, value)| {
let key = KeyCodec::encode(key).as_bytes().into_owned();
let value = ValueCodec::encode(value).as_bytes().into_owned();
(key, value)
})
.collect_vec();
for (key_bytes, value_bytes) in encoded_set.iter() {
tree.update(MerkleTreeKey::new(key_bytes), value_bytes)
.map_err(|err| StorageError::Other(anyhow::anyhow!("{err:?}")))?;
}
let root = tree.root();
let storage = tree.into_storage();
storage.batch_write(
column,
encoded_set
.into_iter()
.map(|(key, value)| (key, WriteOperation::Insert(value.into()))),
)?;
let metadata = SparseMerkleMetadata::new(root);
storage
.storage::<Metadata>()
.insert(primary_key, &metadata)?;
Ok(())
}
fn remove<'a, Iter>(
storage: &mut S,
column: S::Column,
set: Iter,
) -> StorageResult<()>
where
Iter: 'a + Iterator<Item = &'a M::Key>,
M::Key: 'a,
{
let mut set = set.peekable();
let primary_key;
if let Some(key) = set.peek() {
primary_key = KeyConverter::primary_key(*key);
} else {
return Ok(())
}
let prev_metadata: Cow<SparseMerkleMetadata> = storage
.storage::<Metadata>()
.get(primary_key)?
.unwrap_or_default();
let root = *prev_metadata.root();
let mut tree: MerkleTree<Nodes, _> = MerkleTree::load(storage, &root)
.map_err(|err| StorageError::Other(anyhow::anyhow!("{err:?}")))?;
let encoded_set = set
.map(|key| KeyCodec::encode(key).as_bytes().into_owned())
.collect_vec();
for key_bytes in encoded_set.iter() {
tree.delete(MerkleTreeKey::new(key_bytes))
.map_err(|err| StorageError::Other(anyhow::anyhow!("{err:?}")))?;
}
let root = tree.root();
let storage = tree.into_storage();
storage.batch_write(
column,
encoded_set
.into_iter()
.map(|key| (key, WriteOperation::Remove)),
)?;
if &root == MerkleTree::<Nodes, S>::empty_root() {
storage.storage::<Metadata>().remove(primary_key)?;
} else {
let metadata = SparseMerkleMetadata::new(root);
storage
.storage::<Metadata>()
.insert(primary_key, &metadata)?;
}
Ok(())
}
}
#[cfg(feature = "test-helpers")]
#[macro_export]
macro_rules! root_storage_tests {
($table:ident, $metadata_table:ident, $current_key:expr, $foreign_key:expr, $generate_key:ident, $generate_value:ident) => {
paste::item! {
#[cfg(test)]
mod [< $table:snake _root_tests >] {
use super::*;
use $crate::{
structured_storage::test::InMemoryStorage,
transactional::WriteTransaction,
StorageAsMut,
};
use $crate::rand::{
rngs::StdRng,
SeedableRng,
};
#[test]
fn root() {
let mut storage = InMemoryStorage::default();
let mut storage_transaction = storage.write_transaction();
let rng = &mut StdRng::seed_from_u64(1234);
let key = $generate_key(&$current_key, rng);
let value = $generate_value(rng);
storage_transaction.storage_as_mut::<$table>().insert(&key, &value)
.unwrap();
let root = storage_transaction.storage_as_mut::<$table>().root(&$current_key);
assert!(root.is_ok())
}
#[test]
fn root_returns_empty_root_for_empty_metadata() {
let mut storage = InMemoryStorage::default();
let mut storage_transaction = storage.write_transaction();
let empty_root = fuel_core_types::fuel_merkle::sparse::in_memory::MerkleTree::new().root();
let root = storage_transaction
.storage_as_mut::<$table>()
.root(&$current_key)
.unwrap();
assert_eq!(root, empty_root)
}
#[test]
fn put_updates_the_state_merkle_root_for_the_given_metadata() {
let mut storage = InMemoryStorage::default();
let mut storage_transaction = storage.write_transaction();
let rng = &mut StdRng::seed_from_u64(1234);
let key = $generate_key(&$current_key, rng);
let state = $generate_value(rng);
storage_transaction
.storage_as_mut::<$table>()
.insert(&key, &state)
.unwrap();
let root_1 = storage_transaction
.storage_as_mut::<$table>()
.root(&$current_key)
.unwrap();
let key = $generate_key(&$current_key, rng);
let state = $generate_value(rng);
storage_transaction
.storage_as_mut::<$table>()
.insert(&key, &state)
.unwrap();
let root_2 = storage_transaction
.storage_as_mut::<$table>()
.root(&$current_key)
.unwrap();
assert_ne!(root_1, root_2);
}
#[test]
fn remove_updates_the_state_merkle_root_for_the_given_metadata() {
let mut storage = InMemoryStorage::default();
let mut storage_transaction = storage.write_transaction();
let rng = &mut StdRng::seed_from_u64(1234);
let first_key = $generate_key(&$current_key, rng);
let first_state = $generate_value(rng);
storage_transaction
.storage_as_mut::<$table>()
.insert(&first_key, &first_state)
.unwrap();
let root_0 = storage_transaction
.storage_as_mut::<$table>()
.root(&$current_key)
.unwrap();
let second_key = $generate_key(&$current_key, rng);
let second_state = $generate_value(rng);
storage_transaction
.storage_as_mut::<$table>()
.insert(&second_key, &second_state)
.unwrap();
let root_1 = storage_transaction
.storage_as_mut::<$table>()
.root(&$current_key)
.unwrap();
storage_transaction.storage_as_mut::<$table>().remove(&second_key).unwrap();
let root_2 = storage_transaction
.storage_as_mut::<$table>()
.root(&$current_key)
.unwrap();
assert_ne!(root_1, root_2);
assert_eq!(root_0, root_2);
}
#[test]
fn updating_foreign_metadata_does_not_affect_the_given_metadata_insertion() {
let given_primary_key = $current_key;
let foreign_primary_key = $foreign_key;
let mut storage = InMemoryStorage::default();
let mut storage_transaction = storage.write_transaction();
let rng = &mut StdRng::seed_from_u64(1234);
let state_value = $generate_value(rng);
let given_key = $generate_key(&given_primary_key, rng);
let foreign_key = $generate_key(&foreign_primary_key, rng);
storage_transaction
.storage_as_mut::<$table>()
.insert(&given_key, &state_value)
.unwrap();
storage_transaction
.storage_as_mut::<$table>()
.insert(&foreign_key, &state_value)
.unwrap();
storage_transaction
.storage_as_mut::<$table>()
.remove(&foreign_key)
.unwrap();
let result = storage_transaction
.storage_as_mut::<$table>()
.insert(&given_key, &state_value)
.unwrap();
assert!(result.is_some());
}
#[test]
fn put_creates_merkle_metadata_when_empty() {
let mut storage = InMemoryStorage::default();
let mut storage_transaction = storage.write_transaction();
let rng = &mut StdRng::seed_from_u64(1234);
let key = $generate_key(&$current_key, rng);
let state = $generate_value(rng);
storage_transaction
.storage_as_mut::<$table>()
.insert(&key, &state)
.unwrap();
let metadata = storage_transaction
.storage_as_mut::<$metadata_table>()
.get(&$current_key)
.unwrap();
assert!(metadata.is_some());
}
#[test]
fn remove_deletes_merkle_metadata_when_empty() {
let mut storage = InMemoryStorage::default();
let mut storage_transaction = storage.write_transaction();
let rng = &mut StdRng::seed_from_u64(1234);
let key = $generate_key(&$current_key, rng);
let state = $generate_value(rng);
storage_transaction
.storage_as_mut::<$table>()
.insert(&key, &state)
.unwrap();
storage_transaction
.storage_as_mut::<$metadata_table>()
.get(&$current_key)
.unwrap()
.expect("Expected Merkle metadata to be present");
storage_transaction.storage_as_mut::<$table>().remove(&key).unwrap();
let metadata = storage_transaction
.storage_as_mut::<$metadata_table>()
.get(&$current_key)
.unwrap();
assert!(metadata.is_none());
}
}}
};
}