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path: root/src/table_sync.rs
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use rand::Rng;
use std::collections::{BTreeSet, HashMap, VecDeque};
use std::sync::Arc;
use std::time::{Duration, Instant};

use futures::{pin_mut, select};
use futures::future::BoxFuture;
use futures_util::stream::*;
use futures_util::future::*;
use tokio::sync::watch;
use tokio::sync::Mutex;
use serde::{Serialize, Deserialize};

use crate::data::*;
use crate::error::Error;
use crate::membership::Ring;
use crate::table::*;

const SCAN_INTERVAL: Duration = Duration::from_secs(3600);
const CHECKSUM_CACHE_TIMEOUT: Duration = Duration::from_secs(1800);

pub struct TableSyncer<F: TableSchema> {
	pub table: Arc<Table<F>>,
	pub todo: Mutex<SyncTodo>,
	pub cache: Vec<Mutex<HashMap<SyncRange, RangeChecksum>>>,
}

pub struct SyncTodo {
	pub todo: Vec<Partition>,
}

#[derive(Debug, Clone)]
pub struct Partition {
	pub begin: Hash,
	pub end: Hash,
	pub retain: bool,
}

#[derive(Hash, PartialEq, Eq, Debug, Clone, Serialize, Deserialize)]
pub struct SyncRange {
	pub begin: Vec<u8>,
	pub end: Vec<u8>,
	pub level: usize,
}

#[derive(Debug, Clone, Serialize, Deserialize)]
pub struct RangeChecksum {
	pub bounds: SyncRange,
	pub children: Vec<(SyncRange, Hash)>,
	pub found_limit: Option<Vec<u8>>,

	#[serde(skip, default="std::time::Instant::now")]
	pub time: Instant,
}

impl<F: TableSchema + 'static> TableSyncer<F> {
	pub async fn launch(table: Arc<Table<F>>) -> Arc<Self> {
		let todo = SyncTodo { todo: Vec::new() };
		let syncer = Arc::new(TableSyncer {
			table: table.clone(),
			todo: Mutex::new(todo),
			cache: (0..32).map(|_| Mutex::new(HashMap::new())).collect::<Vec<_>>(),
		});

		let s1 = syncer.clone();
		table
			.system
			.background
			.spawn_worker(move |must_exit: watch::Receiver<bool>| s1.watcher_task(must_exit))
			.await;

		let s2 = syncer.clone();
		table
			.system
			.background
			.spawn_worker(move |must_exit: watch::Receiver<bool>| s2.syncer_task(must_exit))
			.await;

		syncer
	}

	async fn watcher_task(
		self: Arc<Self>,
		mut must_exit: watch::Receiver<bool>,
	) -> Result<(), Error> {
		self.todo.lock().await.add_full_scan(&self.table);
		let mut next_full_scan = tokio::time::delay_for(SCAN_INTERVAL).fuse();
		let mut prev_ring: Arc<Ring> = self.table.system.ring.borrow().clone();
		let mut ring_recv: watch::Receiver<Arc<Ring>> = self.table.system.ring.clone();

		loop {
			let s_ring_recv = ring_recv.recv().fuse();
			let s_must_exit = must_exit.recv().fuse();
			pin_mut!(s_ring_recv, s_must_exit);

			select! {
				_ = next_full_scan => {
					next_full_scan = tokio::time::delay_for(SCAN_INTERVAL).fuse();
					self.todo.lock().await.add_full_scan(&self.table);
				}
				new_ring_r = s_ring_recv => {
					if let Some(new_ring) = new_ring_r {
						self.todo.lock().await.add_ring_difference(&self.table, &prev_ring, &new_ring);
						prev_ring = new_ring;
					}
				}
				must_exit_v = s_must_exit => {
					if must_exit_v.unwrap_or(false) {
						return Ok(())
					}
				}
			}
		}
	}

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

	async fn sync_partition(self: Arc<Self>, partition: &Partition, must_exit: &mut watch::Receiver<bool>) -> Result<(), Error> {
		let root_cks = self.root_checksum(&partition.begin, &partition.end, must_exit).await?;
		eprintln!("Root checksum for {:?}: {:?}", partition, root_cks);

		let nodes = self.table.system.ring.borrow().clone().walk_ring(&partition.begin, self.table.param.replication_factor);
		let mut sync_futures = nodes.iter()
			.map(|node| self.clone().do_sync_with(root_cks.clone(), node.clone(), must_exit.clone()))
			.collect::<FuturesUnordered<_>>();

		while let Some(r) = sync_futures.next().await {
			if let Err(e) = r {
				eprintln!("Sync error: {}", e);
			}
		}
		if !partition.retain {
			self.table.delete_range(&partition.begin, &partition.end).await?;
		}

		Ok(())
	}

	async fn root_checksum(self: &Arc<Self>, begin: &Hash, end: &Hash, must_exit: &mut watch::Receiver<bool>) -> Result<RangeChecksum, Error> {
		for i in 1..32 {
			let rc = self.range_checksum(&SyncRange{
				begin: begin.to_vec(),
				end: end.to_vec(),
				level: i,
			}, must_exit).await?;
			if rc.found_limit.is_none() {
				return Ok(rc);
			}
		}
		Err(Error::Message(format!("Unable to compute root checksum (this should never happen")))
	}

	fn range_checksum<'a>(self: &'a Arc<Self>, range: &'a SyncRange, must_exit: &'a mut watch::Receiver<bool>) -> BoxFuture<'a, Result<RangeChecksum, Error>> {
		async move {
			let mut cache = self.cache[range.level].lock().await;
			if let Some(v) = cache.get(&range) {
				if Instant::now() - v.time < CHECKSUM_CACHE_TIMEOUT {
					return Ok(v.clone());
				}
			}
			cache.remove(&range);
			drop(cache);

			let v = self.range_checksum_inner(&range, must_exit).await?;

			let mut cache = self.cache[range.level].lock().await;
			eprintln!("Checksum for {:?}: {:?}", range, v);
			cache.insert(range.clone(), v.clone());
			Ok(v)
		}.boxed()
	}

	async fn range_checksum_inner(self: &Arc<Self>, range: &SyncRange, must_exit: &mut watch::Receiver<bool>) -> Result<RangeChecksum, Error> {
		if range.level == 1 {
			let mut children = vec![];
			for item in self.table.store.range(range.begin.clone()..range.end.clone()) {
				let (key, value) = item?;
				let key_hash = hash(&key[..]);
				if key != range.begin && key_hash.as_slice()[0..range.level].iter().all(|x| *x == 0) {
					return Ok(RangeChecksum{
						bounds: range.clone(),
						children,
						found_limit: Some(key.to_vec()),
						time: Instant::now(),
					})
				}
				let item_range = SyncRange{
					begin: key.to_vec(),
					end: vec![],
					level: 0,
				};
				children.push((item_range, hash(&value[..])));
			}
			Ok(RangeChecksum{
				bounds: range.clone(),
				children,
				found_limit: None,
				time: Instant::now(),
			})
		} else {
			let mut children = vec![];
			let mut sub_range = SyncRange{
				begin: range.begin.clone(),
				end: range.end.clone(),
				level: range.level - 1,
			};
			let mut time = Instant::now();
			while !*must_exit.borrow() {
				let sub_ck = self.range_checksum(&sub_range, must_exit).await?;

				if sub_ck.children.len() > 0 {
					let sub_ck_hash = hash(&rmp_to_vec_all_named(&sub_ck)?[..]);
					children.push((sub_range.clone(), sub_ck_hash));
					if sub_ck.time < time {
						time = sub_ck.time;
					}
				}

				if sub_ck.found_limit.is_none() || sub_ck.children.len() == 0 {
					return Ok(RangeChecksum{
						bounds: range.clone(),
						children,
						found_limit: None,
						time,
					});
				}
				let found_limit = sub_ck.found_limit.unwrap();

				let actual_limit_hash = hash(&found_limit[..]);
				if actual_limit_hash.as_slice()[0..range.level].iter().all(|x| *x == 0) {
					return Ok(RangeChecksum{
						bounds: range.clone(),
						children,
						found_limit: Some(found_limit.clone()),
						time,
					});
				}

				sub_range.begin = found_limit;
			}
			Err(Error::Message(format!("Exiting.")))
		}
	}

	async fn do_sync_with(self: Arc<Self>, root_ck: RangeChecksum, who: UUID, mut must_exit: watch::Receiver<bool>) -> Result<(), Error> {
		let mut todo = VecDeque::new();
		todo.push_back(root_ck);

		while !todo.is_empty() && !*must_exit.borrow() {
			let end = std::cmp::min(16, todo.len());
			let step = todo.drain(..end).collect::<Vec<_>>();
			unimplemented!()
		}
		Ok(())
	}

	pub async fn handle_checksum_rpc(self: &Arc<Self>, checksums: &[RangeChecksum], mut must_exit: watch::Receiver<bool>) -> Result<Vec<SyncRange>, Error> {
		let mut ret = vec![];
		for ckr in checksums.iter() {
			let our_ckr = self.range_checksum(&ckr.bounds, &mut must_exit).await?;
			for (range, hash) in ckr.children.iter() {
				match our_ckr.children.binary_search_by(|(our_range, _)| our_range.begin.cmp(&range.begin)) {
					Err(_) => {
						ret.push(range.clone());
					}
					Ok(i) => {
						if our_ckr.children[i].1 != *hash {
							ret.push(range.clone());
						}
					}
				}
			}
		}
		Ok(ret)
	}
}

impl SyncTodo {
	fn add_full_scan<F: TableSchema>(&mut self, table: &Table<F>) {
		let my_id = table.system.id.clone();

		self.todo.clear();

		let ring: Arc<Ring> = table.system.ring.borrow().clone();

		for i in 0..ring.ring.len() {
			let nodes = ring.walk_ring_from_pos(i, table.param.replication_factor);
			let begin = ring.ring[i].location.clone();

			if i == 0 {
				self.add_full_scan_aux(table, [0u8; 32].into(), begin.clone(), &nodes[..], &my_id);
			}

			if i == ring.ring.len() - 1 {
				self.add_full_scan_aux(table, begin, [0xffu8; 32].into(), &nodes[..], &my_id);
			} else {
				let end = ring.ring[i + 1].location.clone();
				self.add_full_scan_aux(table, begin, end, &nodes[..], &my_id);
			}
		}
	}

	fn add_full_scan_aux<F: TableSchema>(
		&mut self,
		table: &Table<F>,
		begin: Hash,
		end: Hash,
		nodes: &[UUID],
		my_id: &UUID,
	) {
		let retain = nodes.contains(my_id);
		if !retain {
			// Check if we have some data to send, otherwise skip
			if table
				.store
				.range(begin.clone()..end.clone())
				.next()
				.is_none()
			{
				return;
			}
		}

		self.todo.push(Partition { begin, end, retain });
	}

	fn add_ring_difference<F: TableSchema>(&mut self, table: &Table<F>, old: &Ring, new: &Ring) {
		let my_id = table.system.id.clone();

		let old_ring = ring_points(old);
		let new_ring = ring_points(new);
		let both_ring = old_ring.union(&new_ring).cloned().collect::<BTreeSet<_>>();

		let prev_todo_begin = self
			.todo
			.iter()
			.map(|x| x.begin.clone())
			.collect::<BTreeSet<_>>();
		let prev_todo_end = self
			.todo
			.iter()
			.map(|x| x.end.clone())
			.collect::<BTreeSet<_>>();
		let prev_todo = prev_todo_begin
			.union(&prev_todo_end)
			.cloned()
			.collect::<BTreeSet<_>>();

		let all_points = both_ring.union(&prev_todo).cloned().collect::<Vec<_>>();

		self.todo.sort_by(|x, y| x.begin.cmp(&y.begin));
		let mut new_todo = vec![];
		for i in 0..all_points.len() - 1 {
			let begin = all_points[i].clone();
			let end = all_points[i + 1].clone();
			let was_ours = old
				.walk_ring(&begin, table.param.replication_factor)
				.contains(&my_id);
			let is_ours = new
				.walk_ring(&begin, table.param.replication_factor)
				.contains(&my_id);
			let was_todo = match self.todo.binary_search_by(|x| x.begin.cmp(&begin)) {
				Ok(_) => true,
				Err(j) => {
					(j > 0 && self.todo[j - 1].begin < end && begin < self.todo[j - 1].end)
						|| (j < self.todo.len()
							&& self.todo[j].begin < end && begin < self.todo[j].end)
				}
			};
			if was_todo || (is_ours && !was_ours) || (was_ours && !is_ours) {
				new_todo.push(Partition {
					begin,
					end,
					retain: is_ours,
				});
			}
		}

		self.todo = new_todo;
	}

	fn pop_task(&mut self) -> Option<Partition> {
		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 ring_points(ring: &Ring) -> BTreeSet<Hash> {
	let mut ret = BTreeSet::new();
	ret.insert([0u8; 32].into());
	ret.insert([0xFFu8; 32].into());
	for i in 0..ring.ring.len() {
		ret.insert(ring.ring[i].location.clone());
	}
	ret
}