forked from Deuxfleurs/garage
372 lines
10 KiB
Rust
372 lines
10 KiB
Rust
use core::borrow::Borrow;
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use std::convert::TryInto;
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use std::sync::Arc;
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use serde_bytes::ByteBuf;
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use tokio::sync::Notify;
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use garage_db as db;
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use garage_db::counted_tree_hack::CountedTree;
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use garage_util::data::*;
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use garage_util::error::*;
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use garage_util::migrate::Migrate;
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use garage_rpc::system::System;
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use crate::crdt::Crdt;
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use crate::gc::GcTodoEntry;
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use crate::metrics::*;
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use crate::replication::*;
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use crate::schema::*;
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use crate::util::*;
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pub struct TableData<F: TableSchema, R: TableReplication> {
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system: Arc<System>,
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pub instance: F,
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pub replication: R,
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pub store: db::Tree,
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pub(crate) merkle_tree: db::Tree,
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pub(crate) merkle_todo: db::Tree,
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pub(crate) merkle_todo_notify: Notify,
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pub(crate) insert_queue: db::Tree,
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pub(crate) insert_queue_notify: Notify,
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pub(crate) gc_todo: CountedTree,
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pub(crate) metrics: TableMetrics,
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}
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impl<F: TableSchema, R: TableReplication> TableData<F, R> {
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pub fn new(system: Arc<System>, instance: F, replication: R, db: &db::Db) -> Arc<Self> {
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let store = db
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.open_tree(format!("{}:table", F::TABLE_NAME))
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.expect("Unable to open DB tree");
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let merkle_tree = db
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.open_tree(format!("{}:merkle_tree", F::TABLE_NAME))
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.expect("Unable to open DB Merkle tree tree");
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let merkle_todo = db
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.open_tree(format!("{}:merkle_todo", F::TABLE_NAME))
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.expect("Unable to open DB Merkle TODO tree");
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let insert_queue = db
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.open_tree(format!("{}:insert_queue", F::TABLE_NAME))
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.expect("Unable to open insert queue DB tree");
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let gc_todo = db
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.open_tree(format!("{}:gc_todo_v2", F::TABLE_NAME))
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.expect("Unable to open GC DB tree");
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let gc_todo = CountedTree::new(gc_todo).expect("Cannot count gc_todo_v2");
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let metrics = TableMetrics::new(
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F::TABLE_NAME,
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store.clone(),
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merkle_tree.clone(),
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merkle_todo.clone(),
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gc_todo.clone(),
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);
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Arc::new(Self {
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system,
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instance,
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replication,
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store,
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merkle_tree,
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merkle_todo,
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merkle_todo_notify: Notify::new(),
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insert_queue,
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insert_queue_notify: Notify::new(),
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gc_todo,
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metrics,
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})
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}
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// Read functions
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pub fn read_entry(&self, p: &F::P, s: &F::S) -> Result<Option<ByteBuf>, Error> {
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let tree_key = self.tree_key(p, s);
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if let Some(bytes) = self.store.get(tree_key)? {
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Ok(Some(ByteBuf::from(bytes.to_vec())))
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} else {
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Ok(None)
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}
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}
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pub fn read_range(
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&self,
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partition_key: &F::P,
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start: &Option<F::S>,
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filter: &Option<F::Filter>,
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limit: usize,
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enumeration_order: EnumerationOrder,
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) -> Result<Vec<Arc<ByteBuf>>, Error> {
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let partition_hash = partition_key.hash();
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match enumeration_order {
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EnumerationOrder::Forward => {
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let first_key = match start {
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None => partition_hash.to_vec(),
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Some(sk) => self.tree_key(partition_key, sk),
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};
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let range = self.store.range(first_key..)?;
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self.read_range_aux(partition_hash, range, filter, limit)
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}
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EnumerationOrder::Reverse => match start {
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Some(sk) => {
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let last_key = self.tree_key(partition_key, sk);
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let range = self.store.range_rev(..=last_key)?;
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self.read_range_aux(partition_hash, range, filter, limit)
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}
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None => {
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let mut last_key = partition_hash.to_vec();
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let lower = u128::from_be_bytes(last_key[16..32].try_into().unwrap());
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last_key[16..32].copy_from_slice(&u128::to_be_bytes(lower + 1));
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let range = self.store.range_rev(..last_key)?;
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self.read_range_aux(partition_hash, range, filter, limit)
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}
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},
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}
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}
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fn read_range_aux(
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&self,
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partition_hash: Hash,
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range: db::ValueIter,
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filter: &Option<F::Filter>,
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limit: usize,
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) -> Result<Vec<Arc<ByteBuf>>, Error> {
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let mut ret = vec![];
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for item in range {
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let (key, value) = item?;
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if &key[..32] != partition_hash.as_slice() {
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break;
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}
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let keep = match filter {
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None => true,
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Some(f) => {
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let entry = self.decode_entry(value.as_ref())?;
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F::matches_filter(&entry, f)
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}
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};
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if keep {
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ret.push(Arc::new(ByteBuf::from(value)));
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}
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if ret.len() >= limit {
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break;
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}
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}
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Ok(ret)
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}
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// Mutation functions
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// When changing this code, take care of propagating modifications correctly:
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// - When an entry is modified or deleted, call the updated() function
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// on the table instance
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// - When an entry is modified or deleted, add it to the merkle updater's todo list.
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// This has to be done atomically with the modification for the merkle updater
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// to maintain consistency. The merkle updater must then be notified with todo_notify.
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// - When an entry is updated to be a tombstone, add it to the gc_todo tree
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pub(crate) fn update_many<T: Borrow<ByteBuf>>(&self, entries: &[T]) -> Result<(), Error> {
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for update_bytes in entries.iter() {
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self.update_entry(update_bytes.borrow().as_slice())?;
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}
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Ok(())
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}
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pub(crate) fn update_entry(&self, update_bytes: &[u8]) -> Result<(), Error> {
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let update = self.decode_entry(update_bytes)?;
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self.update_entry_with(
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update.partition_key(),
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update.sort_key(),
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|_tx, ent| match ent {
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Some(mut ent) => {
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ent.merge(&update);
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Ok(ent)
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}
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None => Ok(update.clone()),
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},
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)?;
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Ok(())
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}
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pub fn update_entry_with(
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&self,
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partition_key: &F::P,
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sort_key: &F::S,
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update_fn: impl Fn(&mut db::Transaction, Option<F::E>) -> db::TxOpResult<F::E>,
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) -> Result<Option<F::E>, Error> {
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let tree_key = self.tree_key(partition_key, sort_key);
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let changed = self.store.db().transaction(|mut tx| {
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let (old_entry, old_bytes, new_entry) = match tx.get(&self.store, &tree_key)? {
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Some(old_bytes) => {
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let old_entry = self.decode_entry(&old_bytes).map_err(db::TxError::Abort)?;
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let new_entry = update_fn(&mut tx, Some(old_entry.clone()))?;
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(Some(old_entry), Some(old_bytes), new_entry)
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}
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None => (None, None, update_fn(&mut tx, None)?),
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};
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// Changed can be true in two scenarios
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// Scenario 1: the actual represented value changed,
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// so of course the messagepack encoding changed as well
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// Scenario 2: the value didn't change but due to a migration in the
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// data format, the messagepack encoding changed. In this case,
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// we also have to write the migrated value in the table and update
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// the associated Merkle tree entry.
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let new_bytes = new_entry
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.encode()
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.map_err(Error::RmpEncode)
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.map_err(db::TxError::Abort)?;
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let changed = Some(&new_bytes[..]) != old_bytes.as_deref();
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drop(old_bytes);
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if changed {
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let new_bytes_hash = blake2sum(&new_bytes);
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tx.insert(&self.merkle_todo, &tree_key, new_bytes_hash.as_slice())?;
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tx.insert(&self.store, &tree_key, new_bytes)?;
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self.instance
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.updated(&mut tx, old_entry.as_ref(), Some(&new_entry))?;
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Ok(Some((new_entry, new_bytes_hash)))
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} else {
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Ok(None)
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}
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})?;
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if let Some((new_entry, new_bytes_hash)) = changed {
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self.metrics.internal_update_counter.add(1);
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let is_tombstone = new_entry.is_tombstone();
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self.merkle_todo_notify.notify_one();
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if is_tombstone {
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// We are only responsible for GC'ing this item if we are the
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// "leader" of the partition, i.e. the first node in the
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// set of nodes that replicates this partition.
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// This avoids GC loops and does not change the termination properties
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// of the GC algorithm, as in all cases GC is suspended if
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// any node of the partition is unavailable.
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let pk_hash = Hash::try_from(&tree_key[..32]).unwrap();
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let nodes = self.replication.write_nodes(&pk_hash);
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if nodes.first() == Some(&self.system.id) {
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GcTodoEntry::new(tree_key, new_bytes_hash).save(&self.gc_todo)?;
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}
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}
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Ok(Some(new_entry))
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} else {
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Ok(None)
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}
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}
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pub(crate) fn delete_if_equal(self: &Arc<Self>, k: &[u8], v: &[u8]) -> Result<bool, Error> {
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let removed = self
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.store
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.db()
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.transaction(|mut tx| match tx.get(&self.store, k)? {
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Some(cur_v) if cur_v == v => {
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let old_entry = self.decode_entry(v).map_err(db::TxError::Abort)?;
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tx.remove(&self.store, k)?;
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tx.insert(&self.merkle_todo, k, vec![])?;
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self.instance.updated(&mut tx, Some(&old_entry), None)?;
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Ok(true)
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}
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_ => Ok(false),
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})?;
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if removed {
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self.metrics.internal_delete_counter.add(1);
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self.merkle_todo_notify.notify_one();
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}
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Ok(removed)
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}
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pub(crate) fn delete_if_equal_hash(
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self: &Arc<Self>,
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k: &[u8],
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vhash: Hash,
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) -> Result<bool, Error> {
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let removed = self
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.store
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.db()
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.transaction(|mut tx| match tx.get(&self.store, k)? {
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Some(cur_v) if blake2sum(&cur_v[..]) == vhash => {
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let old_entry = self.decode_entry(&cur_v[..]).map_err(db::TxError::Abort)?;
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tx.remove(&self.store, k)?;
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tx.insert(&self.merkle_todo, k, vec![])?;
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self.instance.updated(&mut tx, Some(&old_entry), None)?;
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Ok(true)
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}
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_ => Ok(false),
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})?;
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if removed {
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self.metrics.internal_delete_counter.add(1);
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self.merkle_todo_notify.notify_one();
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}
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Ok(removed)
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}
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// ---- Insert queue functions ----
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pub(crate) fn queue_insert(
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&self,
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tx: &mut db::Transaction,
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ins: &F::E,
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) -> db::TxResult<(), Error> {
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let tree_key = self.tree_key(ins.partition_key(), ins.sort_key());
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let new_entry = match tx.get(&self.insert_queue, &tree_key)? {
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Some(old_v) => {
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let mut entry = self.decode_entry(&old_v).map_err(db::TxError::Abort)?;
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entry.merge(ins);
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entry.encode()
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}
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None => ins.encode(),
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};
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let new_entry = new_entry
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.map_err(Error::RmpEncode)
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.map_err(db::TxError::Abort)?;
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tx.insert(&self.insert_queue, &tree_key, new_entry)?;
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self.insert_queue_notify.notify_one();
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Ok(())
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}
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// ---- Utility functions ----
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pub fn tree_key(&self, p: &F::P, s: &F::S) -> Vec<u8> {
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[p.hash().as_slice(), s.sort_key()].concat()
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}
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pub fn decode_entry(&self, bytes: &[u8]) -> Result<F::E, Error> {
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match F::E::decode(bytes) {
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Some(x) => Ok(x),
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None => {
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error!("Unable to decode entry of {}", F::TABLE_NAME);
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for line in hexdump::hexdump_iter(bytes) {
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debug!("{}", line);
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}
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Err(Error::Message(format!(
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"Unable to decode entry of {}",
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F::TABLE_NAME
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)))
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}
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}
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}
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pub fn gc_todo_len(&self) -> Result<usize, Error> {
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Ok(self.gc_todo.len())
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}
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}
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