forked from Deuxfleurs/garage
303 lines
8.7 KiB
Rust
303 lines
8.7 KiB
Rust
//! Module containing types related to computing nodes which should receive a copy of data blocks
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//! and metadata
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use std::collections::{HashMap, HashSet};
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use std::convert::TryInto;
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use serde::{Deserialize, Serialize};
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use garage_util::data::*;
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/// A partition id, which is stored on 16 bits
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/// i.e. we have up to 2**16 partitions.
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/// (in practice we have exactly 2**PARTITION_BITS partitions)
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pub type Partition = u16;
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// TODO: make this constant parametrizable in the config file
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// For deployments with many nodes it might make sense to bump
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// it up to 10.
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// Maximum value : 16
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/// How many bits from the hash are used to make partitions. Higher numbers means more fairness in
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/// presence of numerous nodes, but exponentially bigger ring. Max 16
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pub const PARTITION_BITS: usize = 8;
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const PARTITION_MASK_U16: u16 = ((1 << PARTITION_BITS) - 1) << (16 - PARTITION_BITS);
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/// The user-defined configuration of the cluster's nodes
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#[derive(Clone, Debug, Serialize, Deserialize)]
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pub struct NetworkConfig {
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/// Map of each node's id to it's configuration
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pub members: HashMap<Uuid, NetworkConfigEntry>,
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/// Version of this config
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pub version: u64,
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}
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impl NetworkConfig {
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pub(crate) fn new() -> Self {
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Self {
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members: HashMap::new(),
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version: 0,
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}
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}
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}
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/// The overall configuration of one (possibly remote) node
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#[derive(Clone, Debug, Serialize, Deserialize)]
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pub struct NetworkConfigEntry {
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/// Datacenter at which this entry belong. This infromation might be used to perform a better
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/// geodistribution
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pub zone: String,
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/// The (relative) capacity of the node
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/// If this is set to None, the node does not participate in storing data for the system
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/// and is only active as an API gateway to other nodes
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pub capacity: Option<u32>,
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/// A tag to recognize the entry, not used for other things than display
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pub tag: String,
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}
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impl NetworkConfigEntry {
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pub fn capacity_string(&self) -> String {
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match self.capacity {
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Some(c) => format!("{}", c),
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None => "gateway".to_string(),
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}
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}
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}
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/// A ring distributing fairly objects to nodes
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#[derive(Clone)]
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pub struct Ring {
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/// The replication factor for this ring
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pub replication_factor: usize,
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/// The network configuration used to generate this ring
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pub config: NetworkConfig,
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// Internal order of nodes used to make a more compact representation of the ring
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nodes: Vec<Uuid>,
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// The list of entries in the ring
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ring: Vec<RingEntry>,
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}
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// Type to store compactly the id of a node in the system
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// Change this to u16 the day we want to have more than 256 nodes in a cluster
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type CompactNodeType = u8;
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// The maximum number of times an object might get replicated
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// This must be at least 3 because Garage supports 3-way replication
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// Here we use 6 so that the size of a ring entry is 8 bytes
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// (2 bytes partition id, 6 bytes node numbers as u8s)
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const MAX_REPLICATION: usize = 6;
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/// An entry in the ring
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#[derive(Clone, Debug)]
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struct RingEntry {
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// The two first bytes of the first hash that goes in this partition
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// (the next bytes are zeroes)
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hash_prefix: u16,
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// The nodes that store this partition, stored as a list of positions in the `nodes`
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// field of the Ring structure
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// Only items 0 up to ring.replication_factor - 1 are used, others are zeros
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nodes_buf: [CompactNodeType; MAX_REPLICATION],
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}
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impl Ring {
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// TODO this function MUST be refactored, it's 100 lines long, with a 50 lines loop, going up to 6
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// levels of imbrication. It is basically impossible to test, maintain, or understand for an
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// outsider.
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pub(crate) fn new(config: NetworkConfig, replication_factor: usize) -> Self {
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// Create a vector of partition indices (0 to 2**PARTITION_BITS-1)
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let partitions_idx = (0usize..(1usize << PARTITION_BITS)).collect::<Vec<_>>();
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let zones = config
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.members
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.iter()
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.filter(|(_id, info)| info.capacity.is_some())
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.map(|(_id, info)| info.zone.as_str())
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.collect::<HashSet<&str>>();
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let n_zones = zones.len();
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// Prepare ring
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let mut partitions: Vec<Vec<(&Uuid, &NetworkConfigEntry)>> = partitions_idx
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.iter()
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.map(|_i| Vec::new())
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.collect::<Vec<_>>();
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// Create MagLev priority queues for each node
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let mut queues = config
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.members
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.iter()
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.filter(|(_id, info)| info.capacity.is_some())
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.map(|(node_id, node_info)| {
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let mut parts = partitions_idx
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.iter()
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.map(|i| {
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let part_data =
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[&u16::to_be_bytes(*i as u16)[..], node_id.as_slice()].concat();
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(*i, fasthash(&part_data[..]))
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})
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.collect::<Vec<_>>();
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parts.sort_by_key(|(_i, h)| *h);
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let parts_i = parts.iter().map(|(i, _h)| *i).collect::<Vec<_>>();
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(node_id, node_info, parts_i, 0)
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})
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.collect::<Vec<_>>();
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let max_capacity = config
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.members
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.iter()
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.filter_map(|(_, node_info)| node_info.capacity)
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.fold(0, std::cmp::max);
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assert!(replication_factor <= MAX_REPLICATION);
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// Fill up ring
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for rep in 0..replication_factor {
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queues.sort_by_key(|(ni, _np, _q, _p)| {
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let queue_data = [&u16::to_be_bytes(rep as u16)[..], ni.as_slice()].concat();
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fasthash(&queue_data[..])
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});
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for (_, _, _, pos) in queues.iter_mut() {
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*pos = 0;
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}
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let mut remaining = partitions_idx.len();
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while remaining > 0 {
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let remaining0 = remaining;
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for i_round in 0..max_capacity {
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for (node_id, node_info, q, pos) in queues.iter_mut() {
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if i_round >= node_info.capacity.unwrap() {
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continue;
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}
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for (pos2, &qv) in q.iter().enumerate().skip(*pos) {
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if partitions[qv].len() != rep {
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continue;
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}
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let p_zns = partitions[qv]
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.iter()
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.map(|(_id, info)| info.zone.as_str())
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.collect::<HashSet<&str>>();
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if (p_zns.len() < n_zones
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&& !p_zns.contains(&node_info.zone.as_str()))
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|| (p_zns.len() == n_zones
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&& !partitions[qv].iter().any(|(id, _i)| id == node_id))
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{
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partitions[qv].push((node_id, node_info));
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remaining -= 1;
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*pos = pos2 + 1;
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break;
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}
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}
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}
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}
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if remaining == remaining0 {
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// No progress made, exit
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warn!("Could not build ring, not enough nodes configured.");
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return Self {
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replication_factor,
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config,
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nodes: vec![],
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ring: vec![],
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};
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}
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}
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}
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// Make a canonical order for nodes
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let nodes = config
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.members
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.iter()
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.filter(|(_id, info)| info.capacity.is_some())
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.map(|(id, _)| *id)
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.collect::<Vec<_>>();
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let nodes_rev = nodes
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.iter()
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.enumerate()
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.map(|(i, id)| (*id, i as CompactNodeType))
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.collect::<HashMap<Uuid, CompactNodeType>>();
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let ring = partitions
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.iter()
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.enumerate()
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.map(|(i, nodes)| {
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let top = (i as u16) << (16 - PARTITION_BITS);
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let nodes = nodes
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.iter()
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.map(|(id, _info)| *nodes_rev.get(id).unwrap())
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.collect::<Vec<CompactNodeType>>();
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assert!(nodes.len() == replication_factor);
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let mut nodes_buf = [0u8; MAX_REPLICATION];
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nodes_buf[..replication_factor].copy_from_slice(&nodes[..]);
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RingEntry {
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hash_prefix: top,
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nodes_buf,
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}
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})
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.collect::<Vec<_>>();
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Self {
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replication_factor,
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config,
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nodes,
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ring,
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}
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}
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/// Get the partition in which data would fall on
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pub fn partition_of(&self, position: &Hash) -> Partition {
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let top = u16::from_be_bytes(position.as_slice()[0..2].try_into().unwrap());
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top >> (16 - PARTITION_BITS)
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}
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/// Get the list of partitions and the first hash of a partition key that would fall in it
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pub fn partitions(&self) -> Vec<(Partition, Hash)> {
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let mut ret = vec![];
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for (i, entry) in self.ring.iter().enumerate() {
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let mut location = [0u8; 32];
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location[..2].copy_from_slice(&u16::to_be_bytes(entry.hash_prefix)[..]);
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ret.push((i as u16, location.into()));
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}
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if !ret.is_empty() {
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assert_eq!(ret[0].1, [0u8; 32].into());
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}
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ret
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}
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/// Walk the ring to find the n servers in which data should be replicated
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pub fn get_nodes(&self, position: &Hash, n: usize) -> Vec<Uuid> {
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if self.ring.len() != 1 << PARTITION_BITS {
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warn!("Ring not yet ready, read/writes will be lost!");
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return vec![];
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}
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let partition_idx = self.partition_of(position) as usize;
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let partition = &self.ring[partition_idx];
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let top = u16::from_be_bytes(position.as_slice()[0..2].try_into().unwrap());
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// Check that we haven't messed up our partition table, i.e. that this partition
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// table entrey indeed corresponds to the item we are storing
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assert_eq!(
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partition.hash_prefix & PARTITION_MASK_U16,
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top & PARTITION_MASK_U16
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);
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assert!(n <= self.replication_factor);
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partition.nodes_buf[..n]
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.iter()
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.map(|i| self.nodes[*i as usize])
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.collect::<Vec<_>>()
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}
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}
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#[cfg(test)]
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mod tests {
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use super::*;
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#[test]
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fn test_ring_entry_size() {
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assert_eq!(std::mem::size_of::<RingEntry>(), 8);
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}
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}
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