garage/src/table/sync.rs

use std::collections::VecDeque;
use std::convert::TryInto;
use std::sync::{Arc, Mutex};
use std::time::{Duration, Instant};

use futures::future::join_all;
use futures::{pin_mut, select};
use futures_util::future::*;
use futures_util::stream::*;
use rand::Rng;
use serde::{Deserialize, Serialize};
use serde_bytes::ByteBuf;
use tokio::sync::{mpsc, watch};

use garage_rpc::ring::Ring;
use garage_util::data::*;
use garage_util::error::Error;

use crate::data::*;
use crate::merkle::*;
use crate::replication::*;
use crate::*;

const TABLE_SYNC_RPC_TIMEOUT: Duration = Duration::from_secs(30);

// Do anti-entropy every 10 minutes
const ANTI_ENTROPY_INTERVAL: Duration = Duration::from_secs(10 * 60);

pub struct TableSyncer<F: TableSchema, R: TableReplication> {
	data: Arc<TableData<F>>,
	aux: Arc<TableAux<F, R>>,

	todo: Mutex<SyncTodo>,
}

type RootCk = Vec<(MerklePartition, Hash)>;

#[derive(Debug, Clone, Copy, Serialize, Deserialize)]
pub struct PartitionRange {
	begin: MerklePartition,
	// if end is None, go all the way to partition 0xFFFF included
	end: Option<MerklePartition>,
}

#[derive(Serialize, Deserialize)]
pub(crate) enum SyncRPC {
	RootCkHash(PartitionRange, Hash),
	RootCkList(PartitionRange, RootCk),
	CkNoDifference,
	GetNode(MerkleNodeKey),
	Node(MerkleNodeKey, MerkleNode),
	Items(Vec<Arc<ByteBuf>>),
}

struct SyncTodo {
	todo: Vec<TodoPartition>,
}

#[derive(Debug, Clone)]
struct TodoPartition {
	range: PartitionRange,

	// Are we a node that stores this partition or not?
	retain: bool,
}

impl<F, R> TableSyncer<F, R>
where
	F: TableSchema + 'static,
	R: TableReplication + 'static,
{
	pub(crate) fn launch(data: Arc<TableData<F>>, aux: Arc<TableAux<F, R>>) -> Arc<Self> {
		let todo = SyncTodo { todo: vec![] };

		let syncer = Arc::new(Self {
			data: data.clone(),
			aux: aux.clone(),
			todo: Mutex::new(todo),
		});

		let (busy_tx, busy_rx) = mpsc::unbounded_channel();

		let s1 = syncer.clone();
		aux.system.background.spawn_worker(
			format!("table sync watcher for {}", data.name),
			move |must_exit: watch::Receiver<bool>| s1.watcher_task(must_exit, busy_rx),
		);

		let s2 = syncer.clone();
		aux.system.background.spawn_worker(
			format!("table syncer for {}", data.name),
			move |must_exit: watch::Receiver<bool>| s2.syncer_task(must_exit, busy_tx),
		);

		let s3 = syncer.clone();
		tokio::spawn(async move {
			tokio::time::delay_for(Duration::from_secs(20)).await;
			s3.add_full_sync();
		});

		syncer
	}

	async fn watcher_task(
		self: Arc<Self>,
		mut must_exit: watch::Receiver<bool>,
		mut busy_rx: mpsc::UnboundedReceiver<bool>,
	) -> Result<(), Error> {
		let mut ring_recv: watch::Receiver<Arc<Ring>> = self.aux.system.ring.clone();
		let mut nothing_to_do_since = Some(Instant::now());

		while !*must_exit.borrow() {
			let s_ring_recv = ring_recv.recv().fuse();
			let s_busy = busy_rx.recv().fuse();
			let s_must_exit = must_exit.recv().fuse();
			let s_timeout = tokio::time::delay_for(Duration::from_secs(1)).fuse();
			pin_mut!(s_ring_recv, s_busy, s_must_exit, s_timeout);

			select! {
				new_ring_r = s_ring_recv => {
					if new_ring_r.is_some() {
						debug!("({}) Adding ring difference to syncer todo list", self.data.name);
						self.add_full_sync();
					}
				}
				busy_opt = s_busy => {
					if let Some(busy) = busy_opt {
						if busy {
							nothing_to_do_since = None;
						} else {
							if nothing_to_do_since.is_none() {
								nothing_to_do_since = Some(Instant::now());
							}
						}
					}
				}
				must_exit_v = s_must_exit => {
					if must_exit_v.unwrap_or(false) {
						break;
					}
				}
				_ = s_timeout => {
					if nothing_to_do_since.map(|t| Instant::now() - t >= ANTI_ENTROPY_INTERVAL).unwrap_or(false) {
						nothing_to_do_since = None;
						debug!("({}) Adding full sync to syncer todo list", self.data.name);
						self.add_full_sync();
					}
				}
			}
		}
		Ok(())
	}

	pub fn add_full_sync(&self) {
		self.todo
			.lock()
			.unwrap()
			.add_full_sync(&self.data, &self.aux);
	}

	async fn syncer_task(
		self: Arc<Self>,
		mut must_exit: watch::Receiver<bool>,
		busy_tx: mpsc::UnboundedSender<bool>,
	) -> Result<(), Error> {
		while !*must_exit.borrow() {
			let task = self.todo.lock().unwrap().pop_task();
			if let Some(partition) = task {
				busy_tx.send(true)?;
				let res = self
					.clone()
					.sync_partition(&partition, &mut must_exit)
					.await;
				if let Err(e) = res {
					warn!(
						"({}) Error while syncing {:?}: {}",
						self.data.name, partition, e
					);
				}
			} else {
				busy_tx.send(false)?;
				tokio::time::delay_for(Duration::from_secs(1)).await;
			}
		}
		Ok(())
	}

	async fn sync_partition(
		self: Arc<Self>,
		partition: &TodoPartition,
		must_exit: &mut watch::Receiver<bool>,
	) -> Result<(), Error> {
		if partition.retain {
			let my_id = self.aux.system.id;

			let nodes = self
				.aux
				.replication
				.write_nodes(
					&hash_of_merkle_partition(partition.range.begin),
					&self.aux.system,
				)
				.into_iter()
				.filter(|node| *node != my_id)
				.collect::<Vec<_>>();

			debug!(
				"({}) Syncing {:?} with {:?}...",
				self.data.name, partition, nodes
			);
			let mut sync_futures = nodes
				.iter()
				.map(|node| {
					self.clone()
						.do_sync_with(partition.clone(), *node, must_exit.clone())
				})
				.collect::<FuturesUnordered<_>>();

			let mut n_errors = 0;
			while let Some(r) = sync_futures.next().await {
				if let Err(e) = r {
					n_errors += 1;
					warn!("({}) Sync error: {}", self.data.name, e);
				}
			}
			if n_errors > self.aux.replication.max_write_errors() {
				return Err(Error::Message(format!(
					"Sync failed with too many nodes (should have been: {:?}).",
					nodes
				)));
			}
		} else {
			self.offload_partition(
				&hash_of_merkle_partition(partition.range.begin),
				&hash_of_merkle_partition_opt(partition.range.end),
				must_exit,
			)
			.await?;
		}

		Ok(())
	}

	// Offload partition: this partition is not something we are storing,
	// so send it out to all other nodes that store it and delete items locally.
	// We don't bother checking if the remote nodes already have the items,
	// we just batch-send everything. Offloading isn't supposed to happen very often.
	// If any of the nodes that are supposed to store the items is unable to
	// save them, we interrupt the process.
	async fn offload_partition(
		self: &Arc<Self>,
		begin: &Hash,
		end: &Hash,
		must_exit: &mut watch::Receiver<bool>,
	) -> Result<(), Error> {
		let mut counter: usize = 0;

		while !*must_exit.borrow() {
			let mut items = Vec::new();

			for item in self.data.store.range(begin.to_vec()..end.to_vec()) {
				let (key, value) = item?;
				items.push((key.to_vec(), Arc::new(ByteBuf::from(value.as_ref()))));

				if items.len() >= 1024 {
					break;
				}
			}

			if items.len() > 0 {
				let nodes = self
					.aux
					.replication
					.write_nodes(&begin, &self.aux.system)
					.into_iter()
					.collect::<Vec<_>>();
				if nodes.contains(&self.aux.system.id) {
					warn!("Interrupting offload as partitions seem to have changed");
					break;
				}

				counter += 1;
				debug!(
					"Offloading {} items from {:?}..{:?} ({})",
					items.len(),
					begin,
					end,
					counter
				);
				self.offload_items(&items, &nodes[..]).await?;
			} else {
				break;
			}
		}

		Ok(())
	}

	async fn offload_items(
		self: &Arc<Self>,
		items: &Vec<(Vec<u8>, Arc<ByteBuf>)>,
		nodes: &[UUID],
	) -> Result<(), Error> {
		let values = items.iter().map(|(_k, v)| v.clone()).collect::<Vec<_>>();
		let update_msg = Arc::new(TableRPC::<F>::Update(values));

		for res in join_all(nodes.iter().map(|to| {
			self.aux
				.rpc_client
				.call_arc(*to, update_msg.clone(), TABLE_SYNC_RPC_TIMEOUT)
		}))
		.await
		{
			res?;
		}

		// All remote nodes have written those items, now we can delete them locally
		let mut not_removed = 0;
		for (k, v) in items.iter() {
			if !self.data.delete_if_equal(&k[..], &v[..])? {
				not_removed += 1;
			}
		}

		if not_removed > 0 {
			debug!("{} items not removed during offload because they changed in between (trying again...)", not_removed);
		}

		Ok(())
	}

	// ======= SYNCHRONIZATION PROCEDURE -- DRIVER SIDE ======

	fn get_root_ck(&self, range: PartitionRange) -> Result<RootCk, Error> {
		let begin = u16::from_be_bytes(range.begin);
		let range_iter = match range.end {
			Some(end) => {
				let end = u16::from_be_bytes(end);
				begin..=(end - 1)
			}
			None => begin..=0xFFFF,
		};

		let mut ret = vec![];
		for i in range_iter {
			let key = MerkleNodeKey {
				partition: u16::to_be_bytes(i),
				prefix: vec![],
			};
			match self.data.merkle_updater.read_node(&key)? {
				MerkleNode::Empty => (),
				x => {
					ret.push((key.partition, hash_of(&x)?));
				}
			}
		}
		Ok(ret)
	}

	async fn do_sync_with(
		self: Arc<Self>,
		partition: TodoPartition,
		who: UUID,
		must_exit: watch::Receiver<bool>,
	) -> Result<(), Error> {
		let root_ck = self.get_root_ck(partition.range)?;
		let root_ck_hash = hash_of(&root_ck)?;

		// If their root checksum has level > than us, use that as a reference
		let root_resp = self
			.aux
			.rpc_client
			.call(
				who,
				TableRPC::<F>::SyncRPC(SyncRPC::RootCkHash(partition.range, root_ck_hash)),
				TABLE_SYNC_RPC_TIMEOUT,
			)
			.await?;

		let mut todo = match root_resp {
			TableRPC::<F>::SyncRPC(SyncRPC::CkNoDifference) => {
				debug!(
					"({}) Sync {:?} with {:?}: no difference",
					self.data.name, partition, who
				);
				return Ok(());
			}
			TableRPC::<F>::SyncRPC(SyncRPC::RootCkList(_, their_root_ck)) => {
				let join = join_ordered(&root_ck[..], &their_root_ck[..]);
				let mut todo = VecDeque::new();
				for (p, v1, v2) in join.iter() {
					let diff = match (v1, v2) {
						(Some(_), None) | (None, Some(_)) => true,
						(Some(a), Some(b)) => a != b,
						_ => false,
					};
					if diff {
						todo.push_back(MerkleNodeKey {
							partition: **p,
							prefix: vec![],
						});
					}
				}
				debug!(
					"({}) Sync {:?} with {:?}: todo.len() = {}",
					self.data.name,
					partition,
					who,
					todo.len()
				);
				todo
			}
			x => {
				return Err(Error::Message(format!(
					"Invalid respone to RootCkHash RPC: {}",
					debug_serialize(x)
				)));
			}
		};

		let mut todo_items = vec![];

		while !todo.is_empty() && !*must_exit.borrow() {
			let key = todo.pop_front().unwrap();
			let node = self.data.merkle_updater.read_node(&key)?;

			match node {
				MerkleNode::Empty => {
					// They have items we don't have.
					// We don't request those items from them, they will send them.
					// We only bother with pushing items that differ
				}
				MerkleNode::Leaf(ik, _) => {
					// Just send that item directly
					if let Some(val) = self.data.store.get(ik)? {
						todo_items.push(val.to_vec());
					}
				}
				MerkleNode::Intermediate(l) => {
					let remote_node = match self
						.aux
						.rpc_client
						.call(
							who,
							TableRPC::<F>::SyncRPC(SyncRPC::GetNode(key.clone())),
							TABLE_SYNC_RPC_TIMEOUT,
						)
						.await?
					{
						TableRPC::<F>::SyncRPC(SyncRPC::Node(_, node)) => node,
						x => {
							return Err(Error::Message(format!(
								"Invalid respone to GetNode RPC: {}",
								debug_serialize(x)
							)));
						}
					};
					let int_l2 = match remote_node {
						MerkleNode::Intermediate(l2) => l2,
						_ => vec![],
					};

					let join = join_ordered(&l[..], &int_l2[..]);
					for (p, v1, v2) in join.into_iter() {
						let diff = match (v1, v2) {
							(Some(_), None) | (None, Some(_)) => true,
							(Some(a), Some(b)) => a != b,
							_ => false,
						};
						if diff {
							todo.push_back(key.add_byte(*p));
						}
					}
				}
			}

			if todo_items.len() >= 256 {
				self.send_items(who, std::mem::replace(&mut todo_items, vec![]))
					.await?;
			}
		}

		if !todo_items.is_empty() {
			self.send_items(who, todo_items).await?;
		}

		Ok(())
	}

	async fn send_items(&self, who: UUID, item_list: Vec<Vec<u8>>) -> Result<(), Error> {
		info!(
			"({}) Sending {} items to {:?}",
			self.data.name,
			item_list.len(),
			who
		);

		let mut values = vec![];
		for item in item_list.iter() {
			if let Some(v) = self.data.store.get(&item[..])? {
				values.push(Arc::new(ByteBuf::from(v.as_ref())));
			}
		}
		let rpc_resp = self
			.aux
			.rpc_client
			.call(who, TableRPC::<F>::Update(values), TABLE_SYNC_RPC_TIMEOUT)
			.await?;
		if let TableRPC::<F>::Ok = rpc_resp {
			Ok(())
		} else {
			Err(Error::Message(format!(
				"Unexpected response to RPC Update: {}",
				debug_serialize(&rpc_resp)
			)))
		}
	}

	// ======= SYNCHRONIZATION PROCEDURE -- RECEIVER SIDE ======

	pub(crate) async fn handle_rpc(self: &Arc<Self>, message: &SyncRPC) -> Result<SyncRPC, Error> {
		match message {
			SyncRPC::RootCkHash(range, h) => {
				let root_ck = self.get_root_ck(*range)?;
				let hash = hash_of(&root_ck)?;
				if hash == *h {
					Ok(SyncRPC::CkNoDifference)
				} else {
					Ok(SyncRPC::RootCkList(*range, root_ck))
				}
			}
			SyncRPC::GetNode(k) => {
				let node = self.data.merkle_updater.read_node(&k)?;
				Ok(SyncRPC::Node(k.clone(), node))
			}
			_ => Err(Error::Message(format!("Unexpected sync RPC"))),
		}
	}
}

impl SyncTodo {
	fn add_full_sync<F: TableSchema, R: TableReplication>(
		&mut self,
		data: &TableData<F>,
		aux: &TableAux<F, R>,
	) {
		let my_id = aux.system.id;

		self.todo.clear();

		let ring = aux.system.ring.borrow().clone();
		let split_points = aux.replication.split_points(&ring);

		for i in 0..split_points.len() {
			let begin: MerklePartition = {
				let b = split_points[i];
				assert_eq!(b.as_slice()[2..], [0u8; 30][..]);
				b.as_slice()[..2].try_into().unwrap()
			};

			let end: Option<MerklePartition> = if i + 1 < split_points.len() {
				let e = split_points[i + 1];
				assert_eq!(e.as_slice()[2..], [0u8; 30][..]);
				Some(e.as_slice()[..2].try_into().unwrap())
			} else {
				None
			};

			let begin_hash = hash_of_merkle_partition(begin);
			let end_hash = hash_of_merkle_partition_opt(end);

			let nodes = aux.replication.replication_nodes(&begin_hash, &ring);

			let retain = nodes.contains(&my_id);
			if !retain {
				// Check if we have some data to send, otherwise skip
				if data.store.range(begin_hash..end_hash).next().is_none() {
					continue;
				}
			}

			self.todo.push(TodoPartition {
				range: PartitionRange { begin, end },
				retain,
			});
		}
	}

	fn pop_task(&mut self) -> Option<TodoPartition> {
		if self.todo.is_empty() {
			return None;
		}

		let i = rand::thread_rng().gen_range::<usize, _, _>(0, self.todo.len());
		if i == self.todo.len() - 1 {
			self.todo.pop()
		} else {
			let replacement = self.todo.pop().unwrap();
			let ret = std::mem::replace(&mut self.todo[i], replacement);
			Some(ret)
		}
	}
}

fn hash_of<T: Serialize>(x: &T) -> Result<Hash, Error> {
	Ok(blake2sum(&rmp_to_vec_all_named(x)?[..]))
}

fn join_ordered<'a, K: Ord + Eq, V1, V2>(
	x: &'a [(K, V1)],
	y: &'a [(K, V2)],
) -> Vec<(&'a K, Option<&'a V1>, Option<&'a V2>)> {
	let mut ret = vec![];
	let mut i = 0;
	let mut j = 0;
	while i < x.len() || j < y.len() {
		if i < x.len() && j < y.len() && x[i].0 == y[j].0 {
			ret.push((&x[i].0, Some(&x[i].1), Some(&y[j].1)));
			i += 1;
			j += 1;
		} else if i < x.len() && (j == y.len() || x[i].0 < y[j].0) {
			ret.push((&x[i].0, Some(&x[i].1), None));
			i += 1;
		} else if j < y.len() && (i == x.len() || x[i].0 > y[j].0) {
			ret.push((&x[i].0, None, Some(&y[j].1)));
			j += 1;
		} else {
			unreachable!();
		}
	}
	ret
}
(not well tested) use merkle tree for sync 2021-03-11 17:28:03 +00:00			`use std::collections::VecDeque;`
			`use std::convert::TryInto;`
			`use std::sync::{Arc, Mutex};`
			`use std::time::{Duration, Instant};`

			`use futures::future::join_all;`
			`use futures::{pin_mut, select};`
			`use futures_util::future::*;`
			`use futures_util::stream::*;`
			`use rand::Rng;`
			`use serde::{Deserialize, Serialize};`
			`use serde_bytes::ByteBuf;`
			`use tokio::sync::{mpsc, watch};`

			`use garage_rpc::ring::Ring;`
			`use garage_util::data::*;`
			`use garage_util::error::Error;`

			`use crate::data::*;`
			`use crate::merkle::*;`
			`use crate::replication::*;`
			`use crate::*;`

			`const TABLE_SYNC_RPC_TIMEOUT: Duration = Duration::from_secs(30);`

			`// Do anti-entropy every 10 minutes`
			`const ANTI_ENTROPY_INTERVAL: Duration = Duration::from_secs(10 * 60);`

			`pub struct TableSyncer<F: TableSchema, R: TableReplication> {`
			`data: Arc<TableData<F>>,`
			`aux: Arc<TableAux<F, R>>,`

			`todo: Mutex<SyncTodo>,`
			`}`

			`type RootCk = Vec<(MerklePartition, Hash)>;`

			`#[derive(Debug, Clone, Copy, Serialize, Deserialize)]`
			`pub struct PartitionRange {`
			`begin: MerklePartition,`
			`// if end is None, go all the way to partition 0xFFFF included`
			`end: Option<MerklePartition>,`
			`}`

			`#[derive(Serialize, Deserialize)]`
			`pub(crate) enum SyncRPC {`
			`RootCkHash(PartitionRange, Hash),`
			`RootCkList(PartitionRange, RootCk),`
			`CkNoDifference,`
			`GetNode(MerkleNodeKey),`
			`Node(MerkleNodeKey, MerkleNode),`
			`Items(Vec<Arc<ByteBuf>>),`
			`}`

			`struct SyncTodo {`
			`todo: Vec<TodoPartition>,`
			`}`

			`#[derive(Debug, Clone)]`
			`struct TodoPartition {`
			`range: PartitionRange,`

			`// Are we a node that stores this partition or not?`
			`retain: bool,`
			`}`

			`impl<F, R> TableSyncer<F, R>`
			`where`
			`F: TableSchema + 'static,`
			`R: TableReplication + 'static,`
			`{`
			`pub(crate) fn launch(data: Arc<TableData<F>>, aux: Arc<TableAux<F, R>>) -> Arc<Self> {`
			`let todo = SyncTodo { todo: vec![] };`

			`let syncer = Arc::new(Self {`
			`data: data.clone(),`
			`aux: aux.clone(),`
			`todo: Mutex::new(todo),`
			`});`

			`let (busy_tx, busy_rx) = mpsc::unbounded_channel();`

			`let s1 = syncer.clone();`
			`aux.system.background.spawn_worker(`
			`format!("table sync watcher for {}", data.name),`
			`move \|must_exit: watch::Receiver<bool>\| s1.watcher_task(must_exit, busy_rx),`
			`);`

			`let s2 = syncer.clone();`
			`aux.system.background.spawn_worker(`
			`format!("table syncer for {}", data.name),`
			`move \|must_exit: watch::Receiver<bool>\| s2.syncer_task(must_exit, busy_tx),`
			`);`

			`let s3 = syncer.clone();`
			`tokio::spawn(async move {`
			`tokio::time::delay_for(Duration::from_secs(20)).await;`
			`s3.add_full_sync();`
			`});`

			`syncer`
			`}`

			`async fn watcher_task(`
			`self: Arc<Self>,`
			`mut must_exit: watch::Receiver<bool>,`
			`mut busy_rx: mpsc::UnboundedReceiver<bool>,`
			`) -> Result<(), Error> {`
			`let mut ring_recv: watch::Receiver<Arc<Ring>> = self.aux.system.ring.clone();`
			`let mut nothing_to_do_since = Some(Instant::now());`

			`while !*must_exit.borrow() {`
			`let s_ring_recv = ring_recv.recv().fuse();`
			`let s_busy = busy_rx.recv().fuse();`
			`let s_must_exit = must_exit.recv().fuse();`
			`let s_timeout = tokio::time::delay_for(Duration::from_secs(1)).fuse();`
			`pin_mut!(s_ring_recv, s_busy, s_must_exit, s_timeout);`

			`select! {`
			`new_ring_r = s_ring_recv => {`
			`if new_ring_r.is_some() {`
			`debug!("({}) Adding ring difference to syncer todo list", self.data.name);`
			`self.add_full_sync();`
			`}`
			`}`
			`busy_opt = s_busy => {`
			`if let Some(busy) = busy_opt {`
			`if busy {`
			`nothing_to_do_since = None;`
			`} else {`
			`if nothing_to_do_since.is_none() {`
			`nothing_to_do_since = Some(Instant::now());`
			`}`
			`}`
			`}`
			`}`
			`must_exit_v = s_must_exit => {`
			`if must_exit_v.unwrap_or(false) {`
			`break;`
			`}`
			`}`
			`_ = s_timeout => {`
			`if nothing_to_do_since.map(\|t\| Instant::now() - t >= ANTI_ENTROPY_INTERVAL).unwrap_or(false) {`
			`nothing_to_do_since = None;`
			`debug!("({}) Adding full sync to syncer todo list", self.data.name);`
			`self.add_full_sync();`
			`}`
			`}`
			`}`
			`}`
			`Ok(())`
			`}`

			`pub fn add_full_sync(&self) {`
			`self.todo`
			`.lock()`
			`.unwrap()`
			`.add_full_sync(&self.data, &self.aux);`
			`}`

			`async fn syncer_task(`
			`self: Arc<Self>,`
			`mut must_exit: watch::Receiver<bool>,`
			`busy_tx: mpsc::UnboundedSender<bool>,`
			`) -> Result<(), Error> {`
			`while !*must_exit.borrow() {`
			`let task = self.todo.lock().unwrap().pop_task();`
			`if let Some(partition) = task {`
			`busy_tx.send(true)?;`
			`let res = self`
			`.clone()`
			`.sync_partition(&partition, &mut must_exit)`
			`.await;`
			`if let Err(e) = res {`
			`warn!(`
			`"({}) Error while syncing {:?}: {}",`
			`self.data.name, partition, e`
			`);`
			`}`
			`} else {`
			`busy_tx.send(false)?;`
			`tokio::time::delay_for(Duration::from_secs(1)).await;`
			`}`
			`}`
			`Ok(())`
			`}`

			`async fn sync_partition(`
			`self: Arc<Self>,`
			`partition: &TodoPartition,`
			`must_exit: &mut watch::Receiver<bool>,`
			`) -> Result<(), Error> {`
			`if partition.retain {`
			`let my_id = self.aux.system.id;`

			`let nodes = self`
			`.aux`
			`.replication`
			`.write_nodes(`
			`&hash_of_merkle_partition(partition.range.begin),`
			`&self.aux.system,`
			`)`
			`.into_iter()`
			`.filter(\|node\| *node != my_id)`
			`.collect::<Vec<_>>();`

			`debug!(`
			`"({}) Syncing {:?} with {:?}...",`
			`self.data.name, partition, nodes`
			`);`
			`let mut sync_futures = nodes`
			`.iter()`
			`.map(\|node\| {`
			`self.clone()`
			`.do_sync_with(partition.clone(), *node, must_exit.clone())`
			`})`
			`.collect::<FuturesUnordered<_>>();`

			`let mut n_errors = 0;`
			`while let Some(r) = sync_futures.next().await {`
			`if let Err(e) = r {`
			`n_errors += 1;`
			`warn!("({}) Sync error: {}", self.data.name, e);`
			`}`
			`}`
			`if n_errors > self.aux.replication.max_write_errors() {`
			`return Err(Error::Message(format!(`
			`"Sync failed with too many nodes (should have been: {:?}).",`
			`nodes`
			`)));`
			`}`
			`} else {`
			`self.offload_partition(`
			`&hash_of_merkle_partition(partition.range.begin),`
			`&hash_of_merkle_partition_opt(partition.range.end),`
			`must_exit,`
			`)`
			`.await?;`
			`}`

			`Ok(())`
			`}`

			`// Offload partition: this partition is not something we are storing,`
			`// so send it out to all other nodes that store it and delete items locally.`
			`// We don't bother checking if the remote nodes already have the items,`
			`// we just batch-send everything. Offloading isn't supposed to happen very often.`
			`// If any of the nodes that are supposed to store the items is unable to`
			`// save them, we interrupt the process.`
			`async fn offload_partition(`
			`self: &Arc<Self>,`
			`begin: &Hash,`
			`end: &Hash,`
			`must_exit: &mut watch::Receiver<bool>,`
			`) -> Result<(), Error> {`
			`let mut counter: usize = 0;`

			`while !*must_exit.borrow() {`
			`let mut items = Vec::new();`

			`for item in self.data.store.range(begin.to_vec()..end.to_vec()) {`
			`let (key, value) = item?;`
			`items.push((key.to_vec(), Arc::new(ByteBuf::from(value.as_ref()))));`

			`if items.len() >= 1024 {`
			`break;`
			`}`
			`}`

			`if items.len() > 0 {`
			`let nodes = self`
			`.aux`
			`.replication`
			`.write_nodes(&begin, &self.aux.system)`
			`.into_iter()`
			`.collect::<Vec<_>>();`
			`if nodes.contains(&self.aux.system.id) {`
			`warn!("Interrupting offload as partitions seem to have changed");`
			`break;`
			`}`

			`counter += 1;`
			`debug!(`
			`"Offloading {} items from {:?}..{:?} ({})",`
			`items.len(),`
			`begin,`
			`end,`
			`counter`
			`);`
			`self.offload_items(&items, &nodes[..]).await?;`
			`} else {`
			`break;`
			`}`
			`}`

			`Ok(())`
			`}`

			`async fn offload_items(`
			`self: &Arc<Self>,`
			`items: &Vec<(Vec<u8>, Arc<ByteBuf>)>,`
			`nodes: &[UUID],`
			`) -> Result<(), Error> {`
			`let values = items.iter().map(\|(_k, v)\| v.clone()).collect::<Vec<_>>();`
			`let update_msg = Arc::new(TableRPC::<F>::Update(values));`

			`for res in join_all(nodes.iter().map(\|to\| {`
			`self.aux`
			`.rpc_client`
			`.call_arc(*to, update_msg.clone(), TABLE_SYNC_RPC_TIMEOUT)`
			`}))`
			`.await`
			`{`
			`res?;`
			`}`

			`// All remote nodes have written those items, now we can delete them locally`
			`let mut not_removed = 0;`
			`for (k, v) in items.iter() {`
			`if !self.data.delete_if_equal(&k[..], &v[..])? {`
			`not_removed += 1;`
			`}`
			`}`

			`if not_removed > 0 {`
			`debug!("{} items not removed during offload because they changed in between (trying again...)", not_removed);`
			`}`

			`Ok(())`
			`}`

			`// ======= SYNCHRONIZATION PROCEDURE -- DRIVER SIDE ======`

			`fn get_root_ck(&self, range: PartitionRange) -> Result<RootCk, Error> {`
			`let begin = u16::from_be_bytes(range.begin);`
			`let range_iter = match range.end {`
			`Some(end) => {`
			`let end = u16::from_be_bytes(end);`
			`begin..=(end - 1)`
			`}`
			`None => begin..=0xFFFF,`
			`};`

			`let mut ret = vec![];`
			`for i in range_iter {`
			`let key = MerkleNodeKey {`
			`partition: u16::to_be_bytes(i),`
			`prefix: vec![],`
			`};`
			`match self.data.merkle_updater.read_node(&key)? {`
			`MerkleNode::Empty => (),`
			`x => {`
			`ret.push((key.partition, hash_of(&x)?));`
			`}`
			`}`
			`}`
			`Ok(ret)`
			`}`

			`async fn do_sync_with(`
			`self: Arc<Self>,`
			`partition: TodoPartition,`
			`who: UUID,`
			`must_exit: watch::Receiver<bool>,`
			`) -> Result<(), Error> {`
			`let root_ck = self.get_root_ck(partition.range)?;`
			`let root_ck_hash = hash_of(&root_ck)?;`

			`// If their root checksum has level > than us, use that as a reference`
			`let root_resp = self`
			`.aux`
			`.rpc_client`
			`.call(`
			`who,`
			`TableRPC::<F>::SyncRPC(SyncRPC::RootCkHash(partition.range, root_ck_hash)),`
			`TABLE_SYNC_RPC_TIMEOUT,`
			`)`
			`.await?;`

			`let mut todo = match root_resp {`
			`TableRPC::<F>::SyncRPC(SyncRPC::CkNoDifference) => {`
			`debug!(`
			`"({}) Sync {:?} with {:?}: no difference",`
			`self.data.name, partition, who`
			`);`
			`return Ok(());`
			`}`
			`TableRPC::<F>::SyncRPC(SyncRPC::RootCkList(_, their_root_ck)) => {`
			`let join = join_ordered(&root_ck[..], &their_root_ck[..]);`
			`let mut todo = VecDeque::new();`
			`for (p, v1, v2) in join.iter() {`
			`let diff = match (v1, v2) {`
			`(Some(_), None) \| (None, Some(_)) => true,`
			`(Some(a), Some(b)) => a != b,`
			`_ => false,`
			`};`
			`if diff {`
			`todo.push_back(MerkleNodeKey {`
			`partition: **p,`
			`prefix: vec![],`
			`});`
			`}`
			`}`
			`debug!(`
			`"({}) Sync {:?} with {:?}: todo.len() = {}",`
			`self.data.name,`
			`partition,`
			`who,`
			`todo.len()`
			`);`
			`todo`
			`}`
			`x => {`
			`return Err(Error::Message(format!(`
			`"Invalid respone to RootCkHash RPC: {}",`
			`debug_serialize(x)`
			`)));`
			`}`
			`};`

			`let mut todo_items = vec![];`

			`while !todo.is_empty() && !*must_exit.borrow() {`
			`let key = todo.pop_front().unwrap();`
			`let node = self.data.merkle_updater.read_node(&key)?;`

			`match node {`
			`MerkleNode::Empty => {`
			`// They have items we don't have.`
			`// We don't request those items from them, they will send them.`
			`// We only bother with pushing items that differ`
			`}`
			`MerkleNode::Leaf(ik, _) => {`
			`// Just send that item directly`
			`if let Some(val) = self.data.store.get(ik)? {`
			`todo_items.push(val.to_vec());`
			`}`
			`}`
			`MerkleNode::Intermediate(l) => {`
			`let remote_node = match self`
			`.aux`
			`.rpc_client`
			`.call(`
			`who,`
			`TableRPC::<F>::SyncRPC(SyncRPC::GetNode(key.clone())),`
			`TABLE_SYNC_RPC_TIMEOUT,`
			`)`
			`.await?`
			`{`
			`TableRPC::<F>::SyncRPC(SyncRPC::Node(_, node)) => node,`
			`x => {`
			`return Err(Error::Message(format!(`
			`"Invalid respone to GetNode RPC: {}",`
			`debug_serialize(x)`
			`)));`
			`}`
			`};`
			`let int_l2 = match remote_node {`
			`MerkleNode::Intermediate(l2) => l2,`
			`_ => vec![],`
			`};`

			`let join = join_ordered(&l[..], &int_l2[..]);`
			`for (p, v1, v2) in join.into_iter() {`
			`let diff = match (v1, v2) {`
			`(Some(_), None) \| (None, Some(_)) => true,`
			`(Some(a), Some(b)) => a != b,`
			`_ => false,`
			`};`
			`if diff {`
			`todo.push_back(key.add_byte(*p));`
			`}`
			`}`
			`}`
			`}`

			`if todo_items.len() >= 256 {`
			`self.send_items(who, std::mem::replace(&mut todo_items, vec![]))`
			`.await?;`
			`}`
			`}`

			`if !todo_items.is_empty() {`
			`self.send_items(who, todo_items).await?;`
			`}`

			`Ok(())`
			`}`

			`async fn send_items(&self, who: UUID, item_list: Vec<Vec<u8>>) -> Result<(), Error> {`
			`info!(`
			`"({}) Sending {} items to {:?}",`
			`self.data.name,`
			`item_list.len(),`
			`who`
			`);`

			`let mut values = vec![];`
			`for item in item_list.iter() {`
			`if let Some(v) = self.data.store.get(&item[..])? {`
			`values.push(Arc::new(ByteBuf::from(v.as_ref())));`
			`}`
			`}`
			`let rpc_resp = self`
			`.aux`
			`.rpc_client`
			`.call(who, TableRPC::<F>::Update(values), TABLE_SYNC_RPC_TIMEOUT)`
			`.await?;`
			`if let TableRPC::<F>::Ok = rpc_resp {`
			`Ok(())`
			`} else {`
			`Err(Error::Message(format!(`
			`"Unexpected response to RPC Update: {}",`
			`debug_serialize(&rpc_resp)`
			`)))`
			`}`
			`}`

			`// ======= SYNCHRONIZATION PROCEDURE -- RECEIVER SIDE ======`

			`pub(crate) async fn handle_rpc(self: &Arc<Self>, message: &SyncRPC) -> Result<SyncRPC, Error> {`
			`match message {`
			`SyncRPC::RootCkHash(range, h) => {`
			`let root_ck = self.get_root_ck(*range)?;`
			`let hash = hash_of(&root_ck)?;`
			`if hash == *h {`
			`Ok(SyncRPC::CkNoDifference)`
			`} else {`
			`Ok(SyncRPC::RootCkList(*range, root_ck))`
			`}`
			`}`
			`SyncRPC::GetNode(k) => {`
			`let node = self.data.merkle_updater.read_node(&k)?;`
			`Ok(SyncRPC::Node(k.clone(), node))`
			`}`
			`_ => Err(Error::Message(format!("Unexpected sync RPC"))),`
			`}`
			`}`
			`}`

			`impl SyncTodo {`
			`fn add_full_sync<F: TableSchema, R: TableReplication>(`
			`&mut self,`
			`data: &TableData<F>,`
			`aux: &TableAux<F, R>,`
			`) {`
			`let my_id = aux.system.id;`

			`self.todo.clear();`

			`let ring = aux.system.ring.borrow().clone();`
			`let split_points = aux.replication.split_points(&ring);`

			`for i in 0..split_points.len() {`
			`let begin: MerklePartition = {`
			`let b = split_points[i];`
			`assert_eq!(b.as_slice()[2..], [0u8; 30][..]);`
			`b.as_slice()[..2].try_into().unwrap()`
			`};`

			`let end: Option<MerklePartition> = if i + 1 < split_points.len() {`
			`let e = split_points[i + 1];`
			`assert_eq!(e.as_slice()[2..], [0u8; 30][..]);`
			`Some(e.as_slice()[..2].try_into().unwrap())`
			`} else {`
			`None`
			`};`

			`let begin_hash = hash_of_merkle_partition(begin);`
			`let end_hash = hash_of_merkle_partition_opt(end);`

			`let nodes = aux.replication.replication_nodes(&begin_hash, &ring);`

			`let retain = nodes.contains(&my_id);`
			`if !retain {`
			`// Check if we have some data to send, otherwise skip`
			`if data.store.range(begin_hash..end_hash).next().is_none() {`
			`continue;`
			`}`
			`}`

			`self.todo.push(TodoPartition {`
			`range: PartitionRange { begin, end },`
			`retain,`
			`});`
			`}`
			`}`

			`fn pop_task(&mut self) -> Option<TodoPartition> {`
			`if self.todo.is_empty() {`
			`return None;`
			`}`

			`let i = rand::thread_rng().gen_range::<usize, _, _>(0, self.todo.len());`
			`if i == self.todo.len() - 1 {`
			`self.todo.pop()`
			`} else {`
			`let replacement = self.todo.pop().unwrap();`
			`let ret = std::mem::replace(&mut self.todo[i], replacement);`
			`Some(ret)`
			`}`
			`}`
			`}`

			`fn hash_of<T: Serialize>(x: &T) -> Result<Hash, Error> {`
			`Ok(blake2sum(&rmp_to_vec_all_named(x)?[..]))`
			`}`

			`fn join_ordered<'a, K: Ord + Eq, V1, V2>(`
			`x: &'a [(K, V1)],`
			`y: &'a [(K, V2)],`
			`) -> Vec<(&'a K, Option<&'a V1>, Option<&'a V2>)> {`
			`let mut ret = vec![];`
			`let mut i = 0;`
			`let mut j = 0;`
			`while i < x.len() \|\| j < y.len() {`
			`if i < x.len() && j < y.len() && x[i].0 == y[j].0 {`
			`ret.push((&x[i].0, Some(&x[i].1), Some(&y[j].1)));`
			`i += 1;`
			`j += 1;`
			`} else if i < x.len() && (j == y.len() \|\| x[i].0 < y[j].0) {`
			`ret.push((&x[i].0, Some(&x[i].1), None));`
			`i += 1;`
			`} else if j < y.len() && (i == x.len() \|\| x[i].0 > y[j].0) {`
			`ret.push((&x[i].0, None, Some(&y[j].1)));`
			`j += 1;`
			`} else {`
			`unreachable!();`
			`}`
			`}`
			`ret`
			`}`