Style improvements

This commit is contained in:
Alex 2022-11-07 19:34:40 +01:00
parent 28d7a49f63
commit ea5afc2511
Signed by untrusted user: lx
GPG key ID: 0E496D15096376BE
5 changed files with 271 additions and 277 deletions

View file

@ -86,7 +86,7 @@ fn get_cluster_layout(garage: &Arc<Garage>) -> GetClusterLayoutResponse {
.map(|(k, _, v)| (hex::encode(k), v.0.clone())) .map(|(k, _, v)| (hex::encode(k), v.0.clone()))
.collect(), .collect(),
staged_role_changes: layout staged_role_changes: layout
.staging .staging_roles
.items() .items()
.iter() .iter()
.filter(|(k, _, v)| layout.roles.get(k) != Some(v)) .filter(|(k, _, v)| layout.roles.get(k) != Some(v))
@ -137,14 +137,14 @@ pub async fn handle_update_cluster_layout(
let mut layout = garage.system.get_cluster_layout(); let mut layout = garage.system.get_cluster_layout();
let mut roles = layout.roles.clone(); let mut roles = layout.roles.clone();
roles.merge(&layout.staging); roles.merge(&layout.staging_roles);
for (node, role) in updates { for (node, role) in updates {
let node = hex::decode(node).ok_or_bad_request("Invalid node identifier")?; let node = hex::decode(node).ok_or_bad_request("Invalid node identifier")?;
let node = Uuid::try_from(&node).ok_or_bad_request("Invalid node identifier")?; let node = Uuid::try_from(&node).ok_or_bad_request("Invalid node identifier")?;
layout layout
.staging .staging_roles
.merge(&roles.update_mutator(node, NodeRoleV(role))); .merge(&roles.update_mutator(node, NodeRoleV(role)));
} }

View file

@ -71,7 +71,7 @@ pub async fn cmd_status(rpc_cli: &Endpoint<SystemRpc, ()>, rpc_host: NodeID) ->
)); ));
} }
_ => { _ => {
let new_role = match layout.staging.get(&adv.id) { let new_role = match layout.staging_roles.get(&adv.id) {
Some(NodeRoleV(Some(_))) => "(pending)", Some(NodeRoleV(Some(_))) => "(pending)",
_ => "NO ROLE ASSIGNED", _ => "NO ROLE ASSIGNED",
}; };

View file

@ -63,14 +63,14 @@ pub async fn cmd_assign_role(
.collect::<Result<Vec<_>, _>>()?; .collect::<Result<Vec<_>, _>>()?;
let mut roles = layout.roles.clone(); let mut roles = layout.roles.clone();
roles.merge(&layout.staging); roles.merge(&layout.staging_roles);
for replaced in args.replace.iter() { for replaced in args.replace.iter() {
let replaced_node = find_matching_node(layout.node_ids().iter().cloned(), replaced)?; let replaced_node = find_matching_node(layout.node_ids().iter().cloned(), replaced)?;
match roles.get(&replaced_node) { match roles.get(&replaced_node) {
Some(NodeRoleV(Some(_))) => { Some(NodeRoleV(Some(_))) => {
layout layout
.staging .staging_roles
.merge(&roles.update_mutator(replaced_node, NodeRoleV(None))); .merge(&roles.update_mutator(replaced_node, NodeRoleV(None)));
} }
_ => { _ => {
@ -128,7 +128,7 @@ pub async fn cmd_assign_role(
}; };
layout layout
.staging .staging_roles
.merge(&roles.update_mutator(added_node, NodeRoleV(Some(new_entry)))); .merge(&roles.update_mutator(added_node, NodeRoleV(Some(new_entry))));
} }
@ -148,13 +148,13 @@ pub async fn cmd_remove_role(
let mut layout = fetch_layout(rpc_cli, rpc_host).await?; let mut layout = fetch_layout(rpc_cli, rpc_host).await?;
let mut roles = layout.roles.clone(); let mut roles = layout.roles.clone();
roles.merge(&layout.staging); roles.merge(&layout.staging_roles);
let deleted_node = let deleted_node =
find_matching_node(roles.items().iter().map(|(id, _, _)| *id), &args.node_id)?; find_matching_node(roles.items().iter().map(|(id, _, _)| *id), &args.node_id)?;
layout layout
.staging .staging_roles
.merge(&roles.update_mutator(deleted_node, NodeRoleV(None))); .merge(&roles.update_mutator(deleted_node, NodeRoleV(None)));
send_layout(rpc_cli, rpc_host, layout).await?; send_layout(rpc_cli, rpc_host, layout).await?;
@ -278,7 +278,7 @@ pub async fn cmd_config_layout(
println!("The zone redundancy must be at least 1."); println!("The zone redundancy must be at least 1.");
} else { } else {
layout layout
.staged_parameters .staging_parameters
.update(LayoutParameters { zone_redundancy: r }); .update(LayoutParameters { zone_redundancy: r });
println!("The new zone redundancy has been saved ({}).", r); println!("The new zone redundancy has been saved ({}).", r);
} }
@ -352,13 +352,13 @@ pub fn print_cluster_layout(layout: &ClusterLayout) -> bool {
} }
pub fn print_staging_parameters_changes(layout: &ClusterLayout) -> bool { pub fn print_staging_parameters_changes(layout: &ClusterLayout) -> bool {
let has_changes = layout.staged_parameters.get().clone() != layout.parameters; let has_changes = layout.staging_parameters.get().clone() != layout.parameters;
if has_changes { if has_changes {
println!(); println!();
println!("==== NEW LAYOUT PARAMETERS ===="); println!("==== NEW LAYOUT PARAMETERS ====");
println!( println!(
"Zone redundancy: {}", "Zone redundancy: {}",
layout.staged_parameters.get().zone_redundancy layout.staging_parameters.get().zone_redundancy
); );
println!(); println!();
} }
@ -367,7 +367,7 @@ pub fn print_staging_parameters_changes(layout: &ClusterLayout) -> bool {
pub fn print_staging_role_changes(layout: &ClusterLayout) -> bool { pub fn print_staging_role_changes(layout: &ClusterLayout) -> bool {
let has_changes = layout let has_changes = layout
.staging .staging_roles
.items() .items()
.iter() .iter()
.any(|(k, _, v)| layout.roles.get(k) != Some(v)); .any(|(k, _, v)| layout.roles.get(k) != Some(v));
@ -376,7 +376,7 @@ pub fn print_staging_role_changes(layout: &ClusterLayout) -> bool {
println!(); println!();
println!("==== STAGED ROLE CHANGES ===="); println!("==== STAGED ROLE CHANGES ====");
let mut table = vec!["ID\tTags\tZone\tCapacity".to_string()]; let mut table = vec!["ID\tTags\tZone\tCapacity".to_string()];
for (id, _, role) in layout.staging.items().iter() { for (id, _, role) in layout.staging_roles.items().iter() {
if layout.roles.get(id) == Some(role) { if layout.roles.get(id) == Some(role) {
continue; continue;
} }

View file

@ -6,33 +6,33 @@ use std::cmp::{max, min};
use std::collections::HashMap; use std::collections::HashMap;
use std::collections::VecDeque; use std::collections::VecDeque;
///Vertex data structures used in all the graphs used in layout.rs. /// Vertex data structures used in all the graphs used in layout.rs.
///usize parameters correspond to node/zone/partitions ids. /// usize parameters correspond to node/zone/partitions ids.
///To understand the vertex roles below, please refer to the formal description /// To understand the vertex roles below, please refer to the formal description
///of the layout computation algorithm. /// of the layout computation algorithm.
#[derive(Clone, Copy, Debug, PartialEq, Eq, Hash)] #[derive(Clone, Copy, Debug, PartialEq, Eq, Hash)]
pub enum Vertex { pub enum Vertex {
Source, Source,
Pup(usize), //The vertex p+ of partition p Pup(usize), // The vertex p+ of partition p
Pdown(usize), //The vertex p- of partition p Pdown(usize), // The vertex p- of partition p
PZ(usize, usize), //The vertex corresponding to x_(partition p, zone z) PZ(usize, usize), // The vertex corresponding to x_(partition p, zone z)
N(usize), //The vertex corresponding to node n N(usize), // The vertex corresponding to node n
Sink, Sink,
} }
///Edge data structure for the flow algorithm. /// Edge data structure for the flow algorithm.
#[derive(Clone, Copy, Debug)] #[derive(Clone, Copy, Debug)]
pub struct FlowEdge { pub struct FlowEdge {
cap: u32, //flow maximal capacity of the edge cap: u32, // flow maximal capacity of the edge
flow: i32, //flow value on the edge flow: i32, // flow value on the edge
dest: usize, //destination vertex id dest: usize, // destination vertex id
rev: usize, //index of the reversed edge (v, self) in the edge list of vertex v rev: usize, // index of the reversed edge (v, self) in the edge list of vertex v
} }
///Edge data structure for the detection of negative cycles. /// Edge data structure for the detection of negative cycles.
#[derive(Clone, Copy, Debug)] #[derive(Clone, Copy, Debug)]
pub struct WeightedEdge { pub struct WeightedEdge {
w: i32, //weight of the edge w: i32, // weight of the edge
dest: usize, dest: usize,
} }
@ -40,14 +40,14 @@ pub trait Edge: Clone + Copy {}
impl Edge for FlowEdge {} impl Edge for FlowEdge {}
impl Edge for WeightedEdge {} impl Edge for WeightedEdge {}
///Struct for the graph structure. We do encapsulation here to be able to both /// Struct for the graph structure. We do encapsulation here to be able to both
///provide user friendly Vertex enum to address vertices, and to use internally usize /// provide user friendly Vertex enum to address vertices, and to use internally usize
///indices and Vec instead of HashMap in the graph algorithm to optimize execution speed. /// indices and Vec instead of HashMap in the graph algorithm to optimize execution speed.
pub struct Graph<E: Edge> { pub struct Graph<E: Edge> {
vertextoid: HashMap<Vertex, usize>, vertex_to_id: HashMap<Vertex, usize>,
idtovertex: Vec<Vertex>, id_to_vertex: Vec<Vertex>,
//The graph is stored as an adjacency list // The graph is stored as an adjacency list
graph: Vec<Vec<E>>, graph: Vec<Vec<E>>,
} }
@ -60,22 +60,30 @@ impl<E: Edge> Graph<E> {
map.insert(*vert, i); map.insert(*vert, i);
} }
Graph::<E> { Graph::<E> {
vertextoid: map, vertex_to_id: map,
idtovertex: vertices.to_vec(), id_to_vertex: vertices.to_vec(),
graph: vec![Vec::<E>::new(); vertices.len()], graph: vec![Vec::<E>::new(); vertices.len()],
} }
} }
fn get_vertex_id(&self, v: &Vertex) -> Result<usize, String> {
self.vertex_to_id
.get(v)
.cloned()
.ok_or_else(|| format!("The graph does not contain vertex {:?}", v))
}
} }
impl Graph<FlowEdge> { impl Graph<FlowEdge> {
///This function adds a directed edge to the graph with capacity c, and the /// This function adds a directed edge to the graph with capacity c, and the
///corresponding reversed edge with capacity 0. /// corresponding reversed edge with capacity 0.
pub fn add_edge(&mut self, u: Vertex, v: Vertex, c: u32) -> Result<(), String> { pub fn add_edge(&mut self, u: Vertex, v: Vertex, c: u32) -> Result<(), String> {
if !self.vertextoid.contains_key(&u) || !self.vertextoid.contains_key(&v) { let idu = self.get_vertex_id(&u)?;
return Err("The graph does not contain the provided vertex.".to_string()); let idv = self.get_vertex_id(&v)?;
if idu == idv {
return Err("Cannot add edge from vertex to itself in flow graph".into());
} }
let idu = self.vertextoid[&u];
let idv = self.vertextoid[&v];
let rev_u = self.graph[idu].len(); let rev_u = self.graph[idu].len();
let rev_v = self.graph[idv].len(); let rev_v = self.graph[idv].len();
self.graph[idu].push(FlowEdge { self.graph[idu].push(FlowEdge {
@ -93,28 +101,22 @@ impl Graph<FlowEdge> {
Ok(()) Ok(())
} }
///This function returns the list of vertices that receive a positive flow from /// This function returns the list of vertices that receive a positive flow from
///vertex v. /// vertex v.
pub fn get_positive_flow_from(&self, v: Vertex) -> Result<Vec<Vertex>, String> { pub fn get_positive_flow_from(&self, v: Vertex) -> Result<Vec<Vertex>, String> {
if !self.vertextoid.contains_key(&v) { let idv = self.get_vertex_id(&v)?;
return Err("The graph does not contain the provided vertex.".to_string());
}
let idv = self.vertextoid[&v];
let mut result = Vec::<Vertex>::new(); let mut result = Vec::<Vertex>::new();
for edge in self.graph[idv].iter() { for edge in self.graph[idv].iter() {
if edge.flow > 0 { if edge.flow > 0 {
result.push(self.idtovertex[edge.dest]); result.push(self.id_to_vertex[edge.dest]);
} }
} }
Ok(result) Ok(result)
} }
///This function returns the value of the flow incoming to v. /// This function returns the value of the flow incoming to v.
pub fn get_inflow(&self, v: Vertex) -> Result<i32, String> { pub fn get_inflow(&self, v: Vertex) -> Result<i32, String> {
if !self.vertextoid.contains_key(&v) { let idv = self.get_vertex_id(&v)?;
return Err("The graph does not contain the provided vertex.".to_string());
}
let idv = self.vertextoid[&v];
let mut result = 0; let mut result = 0;
for edge in self.graph[idv].iter() { for edge in self.graph[idv].iter() {
result += max(0, self.graph[edge.dest][edge.rev].flow); result += max(0, self.graph[edge.dest][edge.rev].flow);
@ -122,12 +124,9 @@ impl Graph<FlowEdge> {
Ok(result) Ok(result)
} }
///This function returns the value of the flow outgoing from v. /// This function returns the value of the flow outgoing from v.
pub fn get_outflow(&self, v: Vertex) -> Result<i32, String> { pub fn get_outflow(&self, v: Vertex) -> Result<i32, String> {
if !self.vertextoid.contains_key(&v) { let idv = self.get_vertex_id(&v)?;
return Err("The graph does not contain the provided vertex.".to_string());
}
let idv = self.vertextoid[&v];
let mut result = 0; let mut result = 0;
for edge in self.graph[idv].iter() { for edge in self.graph[idv].iter() {
result += max(0, edge.flow); result += max(0, edge.flow);
@ -135,19 +134,19 @@ impl Graph<FlowEdge> {
Ok(result) Ok(result)
} }
///This function computes the flow total value by computing the outgoing flow /// This function computes the flow total value by computing the outgoing flow
///from the source. /// from the source.
pub fn get_flow_value(&mut self) -> Result<i32, String> { pub fn get_flow_value(&mut self) -> Result<i32, String> {
self.get_outflow(Vertex::Source) self.get_outflow(Vertex::Source)
} }
///This function shuffles the order of the edge lists. It keeps the ids of the /// This function shuffles the order of the edge lists. It keeps the ids of the
///reversed edges consistent. /// reversed edges consistent.
fn shuffle_edges(&mut self) { fn shuffle_edges(&mut self) {
let mut rng = rand::thread_rng(); let mut rng = rand::thread_rng();
for i in 0..self.graph.len() { for i in 0..self.graph.len() {
self.graph[i].shuffle(&mut rng); self.graph[i].shuffle(&mut rng);
//We need to update the ids of the reverse edges. // We need to update the ids of the reverse edges.
for j in 0..self.graph[i].len() { for j in 0..self.graph[i].len() {
let target_v = self.graph[i][j].dest; let target_v = self.graph[i][j].dest;
let target_rev = self.graph[i][j].rev; let target_rev = self.graph[i][j].rev;
@ -156,50 +155,42 @@ impl Graph<FlowEdge> {
} }
} }
///Computes an upper bound of the flow on the graph /// Computes an upper bound of the flow on the graph
pub fn flow_upper_bound(&self) -> u32 { pub fn flow_upper_bound(&self) -> Result<u32, String> {
let idsource = self.vertextoid[&Vertex::Source]; let idsource = self.get_vertex_id(&Vertex::Source)?;
let mut flow_upper_bound = 0; let mut flow_upper_bound = 0;
for edge in self.graph[idsource].iter() { for edge in self.graph[idsource].iter() {
flow_upper_bound += edge.cap; flow_upper_bound += edge.cap;
} }
flow_upper_bound Ok(flow_upper_bound)
} }
///This function computes the maximal flow using Dinic's algorithm. It starts with /// This function computes the maximal flow using Dinic's algorithm. It starts with
///the flow values already present in the graph. So it is possible to add some edge to /// the flow values already present in the graph. So it is possible to add some edge to
///the graph, compute a flow, add other edges, update the flow. /// the graph, compute a flow, add other edges, update the flow.
pub fn compute_maximal_flow(&mut self) -> Result<(), String> { pub fn compute_maximal_flow(&mut self) -> Result<(), String> {
if !self.vertextoid.contains_key(&Vertex::Source) { let idsource = self.get_vertex_id(&Vertex::Source)?;
return Err("The graph does not contain a source.".to_string()); let idsink = self.get_vertex_id(&Vertex::Sink)?;
}
if !self.vertextoid.contains_key(&Vertex::Sink) {
return Err("The graph does not contain a sink.".to_string());
}
let idsource = self.vertextoid[&Vertex::Source];
let idsink = self.vertextoid[&Vertex::Sink];
let nb_vertices = self.graph.len(); let nb_vertices = self.graph.len();
let flow_upper_bound = self.flow_upper_bound(); let flow_upper_bound = self.flow_upper_bound()?;
//To ensure the dispersion of the associations generated by the // To ensure the dispersion of the associations generated by the
//assignation, we shuffle the neighbours of the nodes. Hence, // assignation, we shuffle the neighbours of the nodes. Hence,
//the vertices do not consider their neighbours in the same order. // the vertices do not consider their neighbours in the same order.
self.shuffle_edges(); self.shuffle_edges();
//We run Dinic's max flow algorithm // We run Dinic's max flow algorithm
loop { loop {
//We build the level array from Dinic's algorithm. // We build the level array from Dinic's algorithm.
let mut level = vec![None; nb_vertices]; let mut level = vec![None; nb_vertices];
let mut fifo = VecDeque::new(); let mut fifo = VecDeque::new();
fifo.push_back((idsource, 0)); fifo.push_back((idsource, 0));
while !fifo.is_empty() { while let Some((id, lvl)) = fifo.pop_front() {
if let Some((id, lvl)) = fifo.pop_front() {
if level[id] == None { if level[id] == None {
//it means id has not yet been reached // it means id has not yet been reached
level[id] = Some(lvl); level[id] = Some(lvl);
for edge in self.graph[id].iter() { for edge in self.graph[id].iter() {
if edge.cap as i32 - edge.flow > 0 { if edge.cap as i32 - edge.flow > 0 {
@ -208,45 +199,42 @@ impl Graph<FlowEdge> {
} }
} }
} }
}
if level[idsink] == None { if level[idsink] == None {
//There is no residual flow // There is no residual flow
break; break;
} }
//Now we run DFS respecting the level array // Now we run DFS respecting the level array
let mut next_nbd = vec![0; nb_vertices]; let mut next_nbd = vec![0; nb_vertices];
let mut lifo = VecDeque::new(); let mut lifo = Vec::new();
lifo.push_back((idsource, flow_upper_bound)); lifo.push((idsource, flow_upper_bound));
while let Some((id_tmp, f_tmp)) = lifo.back() { while let Some((id, f)) = lifo.last().cloned() {
let id = *id_tmp;
let f = *f_tmp;
if id == idsink { if id == idsink {
//The DFS reached the sink, we can add a // The DFS reached the sink, we can add a
//residual flow. // residual flow.
lifo.pop_back(); lifo.pop();
while let Some((id, _)) = lifo.pop_back() { while let Some((id, _)) = lifo.pop() {
let nbd = next_nbd[id]; let nbd = next_nbd[id];
self.graph[id][nbd].flow += f as i32; self.graph[id][nbd].flow += f as i32;
let id_rev = self.graph[id][nbd].dest; let id_rev = self.graph[id][nbd].dest;
let nbd_rev = self.graph[id][nbd].rev; let nbd_rev = self.graph[id][nbd].rev;
self.graph[id_rev][nbd_rev].flow -= f as i32; self.graph[id_rev][nbd_rev].flow -= f as i32;
} }
lifo.push_back((idsource, flow_upper_bound)); lifo.push((idsource, flow_upper_bound));
continue; continue;
} }
//else we did not reach the sink // else we did not reach the sink
let nbd = next_nbd[id]; let nbd = next_nbd[id];
if nbd >= self.graph[id].len() { if nbd >= self.graph[id].len() {
//There is nothing to explore from id anymore // There is nothing to explore from id anymore
lifo.pop_back(); lifo.pop();
if let Some((parent, _)) = lifo.back() { if let Some((parent, _)) = lifo.last() {
next_nbd[*parent] += 1; next_nbd[*parent] += 1;
} }
continue; continue;
} }
//else we can try to send flow from id to its nbd // else we can try to send flow from id to its nbd
let new_flow = min( let new_flow = min(
f as i32, f as i32,
self.graph[id][nbd].cap as i32 - self.graph[id][nbd].flow, self.graph[id][nbd].cap as i32 - self.graph[id][nbd].flow,
@ -257,19 +245,19 @@ impl Graph<FlowEdge> {
} }
if let (Some(lvldest), Some(lvlid)) = (level[self.graph[id][nbd].dest], level[id]) { if let (Some(lvldest), Some(lvlid)) = (level[self.graph[id][nbd].dest], level[id]) {
if lvldest <= lvlid { if lvldest <= lvlid {
//We cannot send flow to nbd. // We cannot send flow to nbd.
next_nbd[id] += 1; next_nbd[id] += 1;
continue; continue;
} }
} }
//otherwise, we send flow to nbd. // otherwise, we send flow to nbd.
lifo.push_back((self.graph[id][nbd].dest, new_flow)); lifo.push((self.graph[id][nbd].dest, new_flow));
} }
} }
Ok(()) Ok(())
} }
///This function takes a flow, and a cost function on the edges, and tries to find an /// This function takes a flow, and a cost function on the edges, and tries to find an
/// equivalent flow with a better cost, by finding improving overflow cycles. It uses /// equivalent flow with a better cost, by finding improving overflow cycles. It uses
/// as subroutine the Bellman Ford algorithm run up to path_length. /// as subroutine the Bellman Ford algorithm run up to path_length.
/// We assume that the cost of edge (u,v) is the opposite of the cost of (v,u), and /// We assume that the cost of edge (u,v) is the opposite of the cost of (v,u), and
@ -279,19 +267,19 @@ impl Graph<FlowEdge> {
cost: &CostFunction, cost: &CostFunction,
path_length: usize, path_length: usize,
) -> Result<(), String> { ) -> Result<(), String> {
//We build the weighted graph g where we will look for negative cycle // We build the weighted graph g where we will look for negative cycle
let mut gf = self.build_cost_graph(cost)?; let mut gf = self.build_cost_graph(cost)?;
let mut cycles = gf.list_negative_cycles(path_length); let mut cycles = gf.list_negative_cycles(path_length);
while !cycles.is_empty() { while !cycles.is_empty() {
//we enumerate negative cycles // we enumerate negative cycles
for c in cycles.iter() { for c in cycles.iter() {
for i in 0..c.len() { for i in 0..c.len() {
//We add one flow unit to the edge (u,v) of cycle c // We add one flow unit to the edge (u,v) of cycle c
let idu = self.vertextoid[&c[i]]; let idu = self.vertex_to_id[&c[i]];
let idv = self.vertextoid[&c[(i + 1) % c.len()]]; let idv = self.vertex_to_id[&c[(i + 1) % c.len()]];
for j in 0..self.graph[idu].len() { for j in 0..self.graph[idu].len() {
//since idu appears at most once in the cycles, we enumerate every // since idu appears at most once in the cycles, we enumerate every
//edge at most once. // edge at most once.
let edge = self.graph[idu][j]; let edge = self.graph[idu][j];
if edge.dest == idv { if edge.dest == idv {
self.graph[idu][j].flow += 1; self.graph[idu][j].flow += 1;
@ -308,16 +296,16 @@ impl Graph<FlowEdge> {
Ok(()) Ok(())
} }
///Construct the weighted graph G_f from the flow and the cost function /// Construct the weighted graph G_f from the flow and the cost function
fn build_cost_graph(&self, cost: &CostFunction) -> Result<Graph<WeightedEdge>, String> { fn build_cost_graph(&self, cost: &CostFunction) -> Result<Graph<WeightedEdge>, String> {
let mut g = Graph::<WeightedEdge>::new(&self.idtovertex); let mut g = Graph::<WeightedEdge>::new(&self.id_to_vertex);
let nb_vertices = self.idtovertex.len(); let nb_vertices = self.id_to_vertex.len();
for i in 0..nb_vertices { for i in 0..nb_vertices {
for edge in self.graph[i].iter() { for edge in self.graph[i].iter() {
if edge.cap as i32 - edge.flow > 0 { if edge.cap as i32 - edge.flow > 0 {
//It is possible to send overflow through this edge // It is possible to send overflow through this edge
let u = self.idtovertex[i]; let u = self.id_to_vertex[i];
let v = self.idtovertex[edge.dest]; let v = self.id_to_vertex[edge.dest];
if cost.contains_key(&(u, v)) { if cost.contains_key(&(u, v)) {
g.add_edge(u, v, cost[&(u, v)])?; g.add_edge(u, v, cost[&(u, v)])?;
} else if cost.contains_key(&(v, u)) { } else if cost.contains_key(&(v, u)) {
@ -333,29 +321,26 @@ impl Graph<FlowEdge> {
} }
impl Graph<WeightedEdge> { impl Graph<WeightedEdge> {
///This function adds a single directed weighted edge to the graph. /// This function adds a single directed weighted edge to the graph.
pub fn add_edge(&mut self, u: Vertex, v: Vertex, w: i32) -> Result<(), String> { pub fn add_edge(&mut self, u: Vertex, v: Vertex, w: i32) -> Result<(), String> {
if !self.vertextoid.contains_key(&u) || !self.vertextoid.contains_key(&v) { let idu = self.get_vertex_id(&u)?;
return Err("The graph does not contain the provided vertex.".to_string()); let idv = self.get_vertex_id(&v)?;
}
let idu = self.vertextoid[&u];
let idv = self.vertextoid[&v];
self.graph[idu].push(WeightedEdge { w, dest: idv }); self.graph[idu].push(WeightedEdge { w, dest: idv });
Ok(()) Ok(())
} }
///This function lists the negative cycles it manages to find after path_length /// This function lists the negative cycles it manages to find after path_length
///iterations of the main loop of the Bellman-Ford algorithm. For the classical /// iterations of the main loop of the Bellman-Ford algorithm. For the classical
///algorithm, path_length needs to be equal to the number of vertices. However, /// algorithm, path_length needs to be equal to the number of vertices. However,
///for particular graph structures like in our case, the algorithm is still correct /// for particular graph structures like in our case, the algorithm is still correct
///when path_length is the length of the longest possible simple path. /// when path_length is the length of the longest possible simple path.
///See the formal description of the algorithm for more details. /// See the formal description of the algorithm for more details.
fn list_negative_cycles(&self, path_length: usize) -> Vec<Vec<Vertex>> { fn list_negative_cycles(&self, path_length: usize) -> Vec<Vec<Vertex>> {
let nb_vertices = self.graph.len(); let nb_vertices = self.graph.len();
//We start with every vertex at distance 0 of some imaginary extra -1 vertex. // We start with every vertex at distance 0 of some imaginary extra -1 vertex.
let mut distance = vec![0; nb_vertices]; let mut distance = vec![0; nb_vertices];
//The prev vector collects for every vertex from where does the shortest path come // The prev vector collects for every vertex from where does the shortest path come
let mut prev = vec![None; nb_vertices]; let mut prev = vec![None; nb_vertices];
for _ in 0..path_length + 1 { for _ in 0..path_length + 1 {
@ -369,29 +354,35 @@ impl Graph<WeightedEdge> {
} }
} }
//If self.graph contains a negative cycle, then at this point the graph described // If self.graph contains a negative cycle, then at this point the graph described
//by prev (which is a directed 1-forest/functional graph) // by prev (which is a directed 1-forest/functional graph)
//must contain a cycle. We list the cycles of prev. // must contain a cycle. We list the cycles of prev.
let cycles_prev = cycles_of_1_forest(&prev); let cycles_prev = cycles_of_1_forest(&prev);
//Remark that the cycle in prev is in the reverse order compared to the cycle // Remark that the cycle in prev is in the reverse order compared to the cycle
//in the graph. Thus the .rev(). // in the graph. Thus the .rev().
return cycles_prev return cycles_prev
.iter() .iter()
.map(|cycle| cycle.iter().rev().map(|id| self.idtovertex[*id]).collect()) .map(|cycle| {
cycle
.iter()
.rev()
.map(|id| self.id_to_vertex[*id])
.collect()
})
.collect(); .collect();
} }
} }
///This function returns the list of cycles of a directed 1 forest. It does not /// This function returns the list of cycles of a directed 1 forest. It does not
///check for the consistency of the input. /// check for the consistency of the input.
fn cycles_of_1_forest(forest: &[Option<usize>]) -> Vec<Vec<usize>> { fn cycles_of_1_forest(forest: &[Option<usize>]) -> Vec<Vec<usize>> {
let mut cycles = Vec::<Vec<usize>>::new(); let mut cycles = Vec::<Vec<usize>>::new();
let mut time_of_discovery = vec![None; forest.len()]; let mut time_of_discovery = vec![None; forest.len()];
for t in 0..forest.len() { for t in 0..forest.len() {
let mut id = t; let mut id = t;
//while we are on a valid undiscovered node // while we are on a valid undiscovered node
while time_of_discovery[id] == None { while time_of_discovery[id] == None {
time_of_discovery[id] = Some(t); time_of_discovery[id] = Some(t);
if let Some(i) = forest[id] { if let Some(i) = forest[id] {
@ -401,8 +392,8 @@ fn cycles_of_1_forest(forest: &[Option<usize>]) -> Vec<Vec<usize>> {
} }
} }
if forest[id] != None && time_of_discovery[id] == Some(t) { if forest[id] != None && time_of_discovery[id] == Some(t) {
//We discovered an id that we explored at this iteration t. // We discovered an id that we explored at this iteration t.
//It means we are on a cycle // It means we are on a cycle
let mut cy = vec![id; 1]; let mut cy = vec![id; 1];
let mut id2 = id; let mut id2 = id;
while let Some(id_next) = forest[id2] { while let Some(id_next) = forest[id2] {

View file

@ -19,7 +19,7 @@ use std::convert::TryInto;
const NB_PARTITIONS: usize = 1usize << PARTITION_BITS; const NB_PARTITIONS: usize = 1usize << PARTITION_BITS;
//The Message type will be used to collect information on the algorithm. // The Message type will be used to collect information on the algorithm.
type Message = Vec<String>; type Message = Vec<String>;
/// The layout of the cluster, i.e. the list of roles /// The layout of the cluster, i.e. the list of roles
@ -30,11 +30,11 @@ pub struct ClusterLayout {
pub replication_factor: usize, pub replication_factor: usize,
///This attribute is only used to retain the previously computed partition size, /// This attribute is only used to retain the previously computed partition size,
///to know to what extent does it change with the layout update. /// to know to what extent does it change with the layout update.
pub partition_size: u32, pub partition_size: u32,
///Parameters used to compute the assignation currently given by /// Parameters used to compute the assignation currently given by
///ring_assignation_data /// ring_assignation_data
pub parameters: LayoutParameters, pub parameters: LayoutParameters,
pub roles: LwwMap<Uuid, NodeRoleV>, pub roles: LwwMap<Uuid, NodeRoleV>,
@ -53,14 +53,14 @@ pub struct ClusterLayout {
pub ring_assignation_data: Vec<CompactNodeType>, pub ring_assignation_data: Vec<CompactNodeType>,
/// Parameters to be used in the next partition assignation computation. /// Parameters to be used in the next partition assignation computation.
pub staged_parameters: Lww<LayoutParameters>, pub staging_parameters: Lww<LayoutParameters>,
/// Role changes which are staged for the next version of the layout /// Role changes which are staged for the next version of the layout
pub staging: LwwMap<Uuid, NodeRoleV>, pub staging_roles: LwwMap<Uuid, NodeRoleV>,
pub staging_hash: Hash, pub staging_hash: Hash,
} }
///This struct is used to set the parameters to be used in the assignation computation /// This struct is used to set the parameters to be used in the assignation computation
///algorithm. It is stored as a Crdt. /// algorithm. It is stored as a Crdt.
#[derive(PartialEq, Eq, PartialOrd, Ord, Clone, Debug, Serialize, Deserialize)] #[derive(PartialEq, Eq, PartialOrd, Ord, Clone, Debug, Serialize, Deserialize)]
pub struct LayoutParameters { pub struct LayoutParameters {
pub zone_redundancy: usize, pub zone_redundancy: usize,
@ -114,20 +114,19 @@ impl NodeRole {
} }
} }
//Implementation of the ClusterLayout methods unrelated to the assignation algorithm. // Implementation of the ClusterLayout methods unrelated to the assignation algorithm.
impl ClusterLayout { impl ClusterLayout {
pub fn new(replication_factor: usize) -> Self { pub fn new(replication_factor: usize) -> Self {
//We set the default zone redundancy to be equal to the replication factor, // We set the default zone redundancy to be equal to the replication factor,
//i.e. as strict as possible. // i.e. as strict as possible.
let parameters = LayoutParameters { let parameters = LayoutParameters {
zone_redundancy: replication_factor, zone_redundancy: replication_factor,
}; };
let staged_parameters = Lww::<LayoutParameters>::new(parameters.clone()); let staging_parameters = Lww::<LayoutParameters>::new(parameters.clone());
let empty_lwwmap = LwwMap::new(); let empty_lwwmap = LwwMap::new();
let empty_lwwmap_hash = blake2sum(&rmp_to_vec_all_named(&empty_lwwmap).unwrap()[..]);
ClusterLayout { let mut ret = ClusterLayout {
version: 0, version: 0,
replication_factor, replication_factor,
partition_size: 0, partition_size: 0,
@ -135,10 +134,17 @@ impl ClusterLayout {
node_id_vec: Vec::new(), node_id_vec: Vec::new(),
ring_assignation_data: Vec::new(), ring_assignation_data: Vec::new(),
parameters, parameters,
staged_parameters, staging_parameters,
staging: empty_lwwmap, staging_roles: empty_lwwmap,
staging_hash: empty_lwwmap_hash, staging_hash: [0u8; 32].into(),
};
ret.staging_hash = ret.calculate_staging_hash();
ret
} }
fn calculate_staging_hash(&self) -> Hash {
let hashed_tuple = (&self.staging_roles, &self.staging_parameters);
blake2sum(&rmp_to_vec_all_named(&hashed_tuple).unwrap()[..])
} }
pub fn merge(&mut self, other: &ClusterLayout) -> bool { pub fn merge(&mut self, other: &ClusterLayout) -> bool {
@ -148,16 +154,15 @@ impl ClusterLayout {
true true
} }
Ordering::Equal => { Ordering::Equal => {
let param_changed = self.staged_parameters.get() != other.staged_parameters.get(); self.staging_parameters.merge(&other.staging_parameters);
self.staged_parameters.merge(&other.staged_parameters); self.staging_roles.merge(&other.staging_roles);
self.staging.merge(&other.staging);
let new_staging_hash = blake2sum(&rmp_to_vec_all_named(&self.staging).unwrap()[..]); let new_staging_hash = self.calculate_staging_hash();
let stage_changed = new_staging_hash != self.staging_hash; let changed = new_staging_hash != self.staging_hash;
self.staging_hash = new_staging_hash; self.staging_hash = new_staging_hash;
stage_changed || param_changed changed
} }
Ordering::Less => false, Ordering::Less => false,
} }
@ -179,13 +184,14 @@ To know the correct value of the new layout version, invoke `garage layout show`
} }
} }
self.roles.merge(&self.staging); self.roles.merge(&self.staging_roles);
self.roles.retain(|(_, _, v)| v.0.is_some()); self.roles.retain(|(_, _, v)| v.0.is_some());
self.parameters = self.staging_parameters.get().clone();
let msg = self.calculate_partition_assignation()?; let msg = self.calculate_partition_assignation()?;
self.staging.clear(); self.staging_roles.clear();
self.staging_hash = blake2sum(&rmp_to_vec_all_named(&self.staging).unwrap()[..]); self.staging_hash = self.calculate_staging_hash();
self.version += 1; self.version += 1;
@ -208,9 +214,9 @@ To know the correct value of the new layout version, invoke `garage layout show`
} }
} }
self.staging.clear(); self.staging_roles.clear();
self.staging_hash = blake2sum(&rmp_to_vec_all_named(&self.staging).unwrap()[..]); self.staging_hash = self.calculate_staging_hash();
self.staged_parameters.update(self.parameters.clone()); self.staging_parameters.update(self.parameters.clone());
self.version += 1; self.version += 1;
@ -235,7 +241,7 @@ To know the correct value of the new layout version, invoke `garage layout show`
} }
} }
///Returns the uuids of the non_gateway nodes in self.node_id_vec. /// Returns the uuids of the non_gateway nodes in self.node_id_vec.
pub fn nongateway_nodes(&self) -> Vec<Uuid> { pub fn nongateway_nodes(&self) -> Vec<Uuid> {
let mut result = Vec::<Uuid>::new(); let mut result = Vec::<Uuid>::new();
for uuid in self.node_id_vec.iter() { for uuid in self.node_id_vec.iter() {
@ -247,7 +253,7 @@ To know the correct value of the new layout version, invoke `garage layout show`
result result
} }
///Given a node uuids, this function returns the label of its zone /// Given a node uuids, this function returns the label of its zone
pub fn get_node_zone(&self, uuid: &Uuid) -> Result<String, Error> { pub fn get_node_zone(&self, uuid: &Uuid) -> Result<String, Error> {
match self.node_role(uuid) { match self.node_role(uuid) {
Some(role) => Ok(role.zone.clone()), Some(role) => Ok(role.zone.clone()),
@ -257,7 +263,7 @@ To know the correct value of the new layout version, invoke `garage layout show`
} }
} }
///Given a node uuids, this function returns its capacity or fails if it does not have any /// Given a node uuids, this function returns its capacity or fails if it does not have any
pub fn get_node_capacity(&self, uuid: &Uuid) -> Result<u32, Error> { pub fn get_node_capacity(&self, uuid: &Uuid) -> Result<u32, Error> {
match self.node_role(uuid) { match self.node_role(uuid) {
Some(NodeRole { Some(NodeRole {
@ -273,7 +279,7 @@ To know the correct value of the new layout version, invoke `garage layout show`
} }
} }
///Returns the number of partitions associated to this node in the ring /// Returns the number of partitions associated to this node in the ring
pub fn get_node_usage(&self, uuid: &Uuid) -> Result<usize, Error> { pub fn get_node_usage(&self, uuid: &Uuid) -> Result<usize, Error> {
for (i, id) in self.node_id_vec.iter().enumerate() { for (i, id) in self.node_id_vec.iter().enumerate() {
if id == uuid { if id == uuid {
@ -293,7 +299,7 @@ To know the correct value of the new layout version, invoke `garage layout show`
)) ))
} }
///Returns the sum of capacities of non gateway nodes in the cluster /// Returns the sum of capacities of non gateway nodes in the cluster
pub fn get_total_capacity(&self) -> Result<u32, Error> { pub fn get_total_capacity(&self) -> Result<u32, Error> {
let mut total_capacity = 0; let mut total_capacity = 0;
for uuid in self.nongateway_nodes().iter() { for uuid in self.nongateway_nodes().iter() {
@ -307,7 +313,7 @@ To know the correct value of the new layout version, invoke `garage layout show`
/// returns true if consistent, false if error /// returns true if consistent, false if error
pub fn check(&self) -> bool { pub fn check(&self) -> bool {
// Check that the hash of the staging data is correct // Check that the hash of the staging data is correct
let staging_hash = blake2sum(&rmp_to_vec_all_named(&self.staging).unwrap()[..]); let staging_hash = self.calculate_staging_hash();
if staging_hash != self.staging_hash { if staging_hash != self.staging_hash {
return false; return false;
} }
@ -346,14 +352,14 @@ To know the correct value of the new layout version, invoke `garage layout show`
} }
} }
//Check that every partition is associated to distinct nodes // Check that every partition is associated to distinct nodes
let rf = self.replication_factor; let rf = self.replication_factor;
for p in 0..(1 << PARTITION_BITS) { for p in 0..(1 << PARTITION_BITS) {
let nodes_of_p = self.ring_assignation_data[rf * p..rf * (p + 1)].to_vec(); let nodes_of_p = self.ring_assignation_data[rf * p..rf * (p + 1)].to_vec();
if nodes_of_p.iter().unique().count() != rf { if nodes_of_p.iter().unique().count() != rf {
return false; return false;
} }
//Check that every partition is spread over at least zone_redundancy zones. // Check that every partition is spread over at least zone_redundancy zones.
let zones_of_p = nodes_of_p.iter().map(|n| { let zones_of_p = nodes_of_p.iter().map(|n| {
self.get_node_zone(&self.node_id_vec[*n as usize]) self.get_node_zone(&self.node_id_vec[*n as usize])
.expect("Zone not found.") .expect("Zone not found.")
@ -364,7 +370,7 @@ To know the correct value of the new layout version, invoke `garage layout show`
} }
} }
//Check that the nodes capacities is consistent with the stored partitions // Check that the nodes capacities is consistent with the stored partitions
let mut node_usage = vec![0; MAX_NODE_NUMBER]; let mut node_usage = vec![0; MAX_NODE_NUMBER];
for n in self.ring_assignation_data.iter() { for n in self.ring_assignation_data.iter() {
node_usage[*n as usize] += 1; node_usage[*n as usize] += 1;
@ -380,8 +386,8 @@ To know the correct value of the new layout version, invoke `garage layout show`
} }
} }
//Check that the partition size stored is the one computed by the asignation // Check that the partition size stored is the one computed by the asignation
//algorithm. // algorithm.
let cl2 = self.clone(); let cl2 = self.clone();
let (_, zone_to_id) = cl2.generate_nongateway_zone_ids().expect("Critical Error"); let (_, zone_to_id) = cl2.generate_nongateway_zone_ids().expect("Critical Error");
match cl2.compute_optimal_partition_size(&zone_to_id) { match cl2.compute_optimal_partition_size(&zone_to_id) {
@ -394,7 +400,7 @@ To know the correct value of the new layout version, invoke `garage layout show`
} }
} }
//Implementation of the ClusterLayout methods related to the assignation algorithm. // Implementation of the ClusterLayout methods related to the assignation algorithm.
impl ClusterLayout { impl ClusterLayout {
/// This function calculates a new partition-to-node assignation. /// This function calculates a new partition-to-node assignation.
/// The computed assignation respects the node replication factor /// The computed assignation respects the node replication factor
@ -403,16 +409,13 @@ impl ClusterLayout {
/// Among such optimal assignation, it minimizes the distance to /// Among such optimal assignation, it minimizes the distance to
/// the former assignation (if any) to minimize the amount of /// the former assignation (if any) to minimize the amount of
/// data to be moved. /// data to be moved.
// Staged role changes must be merged with nodes roles before calling this function, /// Staged role changes must be merged with nodes roles before calling this function,
// hence it must only be called from apply_staged_changes() and hence is not public. /// hence it must only be called from apply_staged_changes() and hence is not public.
fn calculate_partition_assignation(&mut self) -> Result<Message, Error> { fn calculate_partition_assignation(&mut self) -> Result<Message, Error> {
//We update the node ids, since the node role list might have changed with the // We update the node ids, since the node role list might have changed with the
//changes in the layout. We retrieve the old_assignation reframed with new ids // changes in the layout. We retrieve the old_assignation reframed with new ids
let old_assignation_opt = self.update_node_id_vec()?; let old_assignation_opt = self.update_node_id_vec()?;
//We update the parameters
self.parameters = self.staged_parameters.get().clone();
let mut msg = Message::new(); let mut msg = Message::new();
msg.push("==== COMPUTATION OF A NEW PARTITION ASSIGNATION ====".into()); msg.push("==== COMPUTATION OF A NEW PARTITION ASSIGNATION ====".into());
msg.push("".into()); msg.push("".into());
@ -422,8 +425,8 @@ impl ClusterLayout {
self.replication_factor, self.parameters.zone_redundancy self.replication_factor, self.parameters.zone_redundancy
)); ));
//We generate for once numerical ids for the zones of non gateway nodes, // We generate for once numerical ids for the zones of non gateway nodes,
//to use them as indices in the flow graphs. // to use them as indices in the flow graphs.
let (id_to_zone, zone_to_id) = self.generate_nongateway_zone_ids()?; let (id_to_zone, zone_to_id) = self.generate_nongateway_zone_ids()?;
let nb_nongateway_nodes = self.nongateway_nodes().len(); let nb_nongateway_nodes = self.nongateway_nodes().len();
@ -443,10 +446,10 @@ impl ClusterLayout {
))); )));
} }
//We compute the optimal partition size // We compute the optimal partition size
//Capacities should be given in a unit so that partition size is at least 100. // Capacities should be given in a unit so that partition size is at least 100.
//In this case, integer rounding plays a marginal role in the percentages of // In this case, integer rounding plays a marginal role in the percentages of
//optimality. // optimality.
let partition_size = self.compute_optimal_partition_size(&zone_to_id)?; let partition_size = self.compute_optimal_partition_size(&zone_to_id)?;
if old_assignation_opt != None { if old_assignation_opt != None {
@ -461,7 +464,7 @@ impl ClusterLayout {
partition_size partition_size
)); ));
} }
//We write the partition size. // We write the partition size.
self.partition_size = partition_size; self.partition_size = partition_size;
if partition_size < 100 { if partition_size < 100 {
@ -472,15 +475,15 @@ impl ClusterLayout {
); );
} }
//We compute a first flow/assignation that is heuristically close to the previous // We compute a first flow/assignation that is heuristically close to the previous
//assignation // assignation
let mut gflow = self.compute_candidate_assignation(&zone_to_id, &old_assignation_opt)?; let mut gflow = self.compute_candidate_assignation(&zone_to_id, &old_assignation_opt)?;
if let Some(assoc) = &old_assignation_opt { if let Some(assoc) = &old_assignation_opt {
//We minimize the distance to the previous assignation. // We minimize the distance to the previous assignation.
self.minimize_rebalance_load(&mut gflow, &zone_to_id, assoc)?; self.minimize_rebalance_load(&mut gflow, &zone_to_id, assoc)?;
} }
//We display statistics of the computation // We display statistics of the computation
msg.append(&mut self.output_stat( msg.append(&mut self.output_stat(
&gflow, &gflow,
&old_assignation_opt, &old_assignation_opt,
@ -489,7 +492,7 @@ impl ClusterLayout {
)?); )?);
msg.push("".to_string()); msg.push("".to_string());
//We update the layout structure // We update the layout structure
self.update_ring_from_flow(id_to_zone.len(), &gflow)?; self.update_ring_from_flow(id_to_zone.len(), &gflow)?;
if !self.check() { if !self.check() {
@ -508,8 +511,8 @@ impl ClusterLayout {
/// do modify assignation_ring and node_id_vec. /// do modify assignation_ring and node_id_vec.
fn update_node_id_vec(&mut self) -> Result<Option<Vec<Vec<usize>>>, Error> { fn update_node_id_vec(&mut self) -> Result<Option<Vec<Vec<usize>>>, Error> {
// (1) We compute the new node list // (1) We compute the new node list
//Non gateway nodes should be coded on 8bits, hence they must be first in the list // Non gateway nodes should be coded on 8bits, hence they must be first in the list
//We build the new node ids // We build the new node ids
let mut new_non_gateway_nodes: Vec<Uuid> = self let mut new_non_gateway_nodes: Vec<Uuid> = self
.roles .roles
.items() .items()
@ -542,12 +545,12 @@ impl ClusterLayout {
self.node_id_vec = new_node_id_vec.clone(); self.node_id_vec = new_node_id_vec.clone();
// (2) We retrieve the old association // (2) We retrieve the old association
//We rewrite the old association with the new indices. We only consider partition // We rewrite the old association with the new indices. We only consider partition
//to node assignations where the node is still in use. // to node assignations where the node is still in use.
let mut old_assignation = vec![Vec::<usize>::new(); NB_PARTITIONS]; let mut old_assignation = vec![Vec::<usize>::new(); NB_PARTITIONS];
if self.ring_assignation_data.is_empty() { if self.ring_assignation_data.is_empty() {
//This is a new association // This is a new association
return Ok(None); return Ok(None);
} }
if self.ring_assignation_data.len() != NB_PARTITIONS * self.replication_factor { if self.ring_assignation_data.len() != NB_PARTITIONS * self.replication_factor {
@ -558,11 +561,11 @@ impl ClusterLayout {
)); ));
} }
//We build a translation table between the uuid and new ids // We build a translation table between the uuid and new ids
let mut uuid_to_new_id = HashMap::<Uuid, usize>::new(); let mut uuid_to_new_id = HashMap::<Uuid, usize>::new();
//We add the indices of only the new non-gateway nodes that can be used in the // We add the indices of only the new non-gateway nodes that can be used in the
//association ring // association ring
for (i, uuid) in new_node_id_vec.iter().enumerate() { for (i, uuid) in new_node_id_vec.iter().enumerate() {
uuid_to_new_id.insert(*uuid, i); uuid_to_new_id.insert(*uuid, i);
} }
@ -577,14 +580,14 @@ impl ClusterLayout {
} }
} }
//We write the ring // We write the ring
self.ring_assignation_data = Vec::<CompactNodeType>::new(); self.ring_assignation_data = Vec::<CompactNodeType>::new();
Ok(Some(old_assignation)) Ok(Some(old_assignation))
} }
///This function generates ids for the zone of the nodes appearing in /// This function generates ids for the zone of the nodes appearing in
///self.node_id_vec. /// self.node_id_vec.
fn generate_nongateway_zone_ids(&self) -> Result<(Vec<String>, HashMap<String, usize>), Error> { fn generate_nongateway_zone_ids(&self) -> Result<(Vec<String>, HashMap<String, usize>), Error> {
let mut id_to_zone = Vec::<String>::new(); let mut id_to_zone = Vec::<String>::new();
let mut zone_to_id = HashMap::<String, usize>::new(); let mut zone_to_id = HashMap::<String, usize>::new();
@ -607,8 +610,8 @@ impl ClusterLayout {
Ok((id_to_zone, zone_to_id)) Ok((id_to_zone, zone_to_id))
} }
///This function computes by dichotomy the largest realizable partition size, given /// This function computes by dichotomy the largest realizable partition size, given
///the layout roles and parameters. /// the layout roles and parameters.
fn compute_optimal_partition_size( fn compute_optimal_partition_size(
&self, &self,
zone_to_id: &HashMap<String, usize>, zone_to_id: &HashMap<String, usize>,
@ -662,13 +665,13 @@ impl ClusterLayout {
vertices vertices
} }
///Generates the graph to compute the maximal flow corresponding to the optimal /// Generates the graph to compute the maximal flow corresponding to the optimal
///partition assignation. /// partition assignation.
///exclude_assoc is the set of (partition, node) association that we are forbidden /// exclude_assoc is the set of (partition, node) association that we are forbidden
///to use (hence we do not add the corresponding edge to the graph). This parameter /// to use (hence we do not add the corresponding edge to the graph). This parameter
///is used to compute a first flow that uses only edges appearing in the previous /// is used to compute a first flow that uses only edges appearing in the previous
///assignation. This produces a solution that heuristically should be close to the /// assignation. This produces a solution that heuristically should be close to the
///previous one. /// previous one.
fn generate_flow_graph( fn generate_flow_graph(
&self, &self,
partition_size: u32, partition_size: u32,
@ -709,14 +712,14 @@ impl ClusterLayout {
Ok(g) Ok(g)
} }
///This function computes a first optimal assignation (in the form of a flow graph). /// This function computes a first optimal assignation (in the form of a flow graph).
fn compute_candidate_assignation( fn compute_candidate_assignation(
&self, &self,
zone_to_id: &HashMap<String, usize>, zone_to_id: &HashMap<String, usize>,
prev_assign_opt: &Option<Vec<Vec<usize>>>, prev_assign_opt: &Option<Vec<Vec<usize>>>,
) -> Result<Graph<FlowEdge>, Error> { ) -> Result<Graph<FlowEdge>, Error> {
//We list the (partition,node) associations that are not used in the // We list the (partition,node) associations that are not used in the
//previous assignation // previous assignation
let mut exclude_edge = HashSet::<(usize, usize)>::new(); let mut exclude_edge = HashSet::<(usize, usize)>::new();
if let Some(prev_assign) = prev_assign_opt { if let Some(prev_assign) = prev_assign_opt {
let nb_nodes = self.nongateway_nodes().len(); let nb_nodes = self.nongateway_nodes().len();
@ -730,13 +733,13 @@ impl ClusterLayout {
} }
} }
//We compute the best flow using only the edges used in the previous assignation // We compute the best flow using only the edges used in the previous assignation
let mut g = self.generate_flow_graph(self.partition_size, zone_to_id, &exclude_edge)?; let mut g = self.generate_flow_graph(self.partition_size, zone_to_id, &exclude_edge)?;
g.compute_maximal_flow()?; g.compute_maximal_flow()?;
//We add the excluded edges and compute the maximal flow with the full graph. // We add the excluded edges and compute the maximal flow with the full graph.
//The algorithm is such that it will start with the flow that we just computed // The algorithm is such that it will start with the flow that we just computed
//and find ameliorating paths from that. // and find ameliorating paths from that.
for (p, n) in exclude_edge.iter() { for (p, n) in exclude_edge.iter() {
let node_zone = zone_to_id[&self.get_node_zone(&self.node_id_vec[*n])?]; let node_zone = zone_to_id[&self.get_node_zone(&self.node_id_vec[*n])?];
g.add_edge(Vertex::PZ(*p, node_zone), Vertex::N(*n), 1)?; g.add_edge(Vertex::PZ(*p, node_zone), Vertex::N(*n), 1)?;
@ -745,16 +748,16 @@ impl ClusterLayout {
Ok(g) Ok(g)
} }
///This function updates the flow graph gflow to minimize the distance between /// This function updates the flow graph gflow to minimize the distance between
///its corresponding assignation and the previous one /// its corresponding assignation and the previous one
fn minimize_rebalance_load( fn minimize_rebalance_load(
&self, &self,
gflow: &mut Graph<FlowEdge>, gflow: &mut Graph<FlowEdge>,
zone_to_id: &HashMap<String, usize>, zone_to_id: &HashMap<String, usize>,
prev_assign: &[Vec<usize>], prev_assign: &[Vec<usize>],
) -> Result<(), Error> { ) -> Result<(), Error> {
//We define a cost function on the edges (pairs of vertices) corresponding // We define a cost function on the edges (pairs of vertices) corresponding
//to the distance between the two assignations. // to the distance between the two assignations.
let mut cost = CostFunction::new(); let mut cost = CostFunction::new();
for (p, assoc_p) in prev_assign.iter().enumerate() { for (p, assoc_p) in prev_assign.iter().enumerate() {
for n in assoc_p.iter() { for n in assoc_p.iter() {
@ -763,9 +766,9 @@ impl ClusterLayout {
} }
} }
//We compute the maximal length of a simple path in gflow. It is used in the // We compute the maximal length of a simple path in gflow. It is used in the
//Bellman-Ford algorithm in optimize_flow_with_cost to set the number // Bellman-Ford algorithm in optimize_flow_with_cost to set the number
//of iterations. // of iterations.
let nb_nodes = self.nongateway_nodes().len(); let nb_nodes = self.nongateway_nodes().len();
let path_length = 4 * nb_nodes; let path_length = 4 * nb_nodes;
gflow.optimize_flow_with_cost(&cost, path_length)?; gflow.optimize_flow_with_cost(&cost, path_length)?;
@ -773,7 +776,7 @@ impl ClusterLayout {
Ok(()) Ok(())
} }
///This function updates the assignation ring from the flow graph. /// This function updates the assignation ring from the flow graph.
fn update_ring_from_flow( fn update_ring_from_flow(
&mut self, &mut self,
nb_zones: usize, nb_zones: usize,
@ -801,8 +804,8 @@ impl ClusterLayout {
Ok(()) Ok(())
} }
///This function returns a message summing up the partition repartition of the new /// This function returns a message summing up the partition repartition of the new
///layout, and other statistics of the partition assignation computation. /// layout, and other statistics of the partition assignation computation.
fn output_stat( fn output_stat(
&self, &self,
gflow: &Graph<FlowEdge>, gflow: &Graph<FlowEdge>,
@ -837,7 +840,7 @@ impl ClusterLayout {
used_cap / self.replication_factor as u32 used_cap / self.replication_factor as u32
)); ));
//We define and fill in the following tables // We define and fill in the following tables
let storing_nodes = self.nongateway_nodes(); let storing_nodes = self.nongateway_nodes();
let mut new_partitions = vec![0; storing_nodes.len()]; let mut new_partitions = vec![0; storing_nodes.len()];
let mut stored_partitions = vec![0; storing_nodes.len()]; let mut stored_partitions = vec![0; storing_nodes.len()];
@ -879,7 +882,7 @@ impl ClusterLayout {
new_partitions_zone = stored_partitions_zone.clone(); new_partitions_zone = stored_partitions_zone.clone();
} }
//We display the statistics // We display the statistics
msg.push("".into()); msg.push("".into());
if *prev_assign_opt != None { if *prev_assign_opt != None {
@ -951,27 +954,27 @@ impl ClusterLayout {
} }
} }
//==================================================================================== // ====================================================================================
#[cfg(test)] #[cfg(test)]
mod tests { mod tests {
use super::{Error, *}; use super::{Error, *};
use std::cmp::min; use std::cmp::min;
//This function checks that the partition size S computed is at least better than the // This function checks that the partition size S computed is at least better than the
//one given by a very naive algorithm. To do so, we try to run the naive algorithm // one given by a very naive algorithm. To do so, we try to run the naive algorithm
//assuming a partion size of S+1. If we succed, it means that the optimal assignation // assuming a partion size of S+1. If we succed, it means that the optimal assignation
//was not optimal. The naive algorithm is the following : // was not optimal. The naive algorithm is the following :
//- we compute the max number of partitions associated to every node, capped at the // - we compute the max number of partitions associated to every node, capped at the
//partition number. It gives the number of tokens of every node. // partition number. It gives the number of tokens of every node.
//- every zone has a number of tokens equal to the sum of the tokens of its nodes. // - every zone has a number of tokens equal to the sum of the tokens of its nodes.
//- we cycle over the partitions and associate zone tokens while respecting the // - we cycle over the partitions and associate zone tokens while respecting the
//zone redundancy constraint. // zone redundancy constraint.
//NOTE: the naive algorithm is not optimal. Counter example: // NOTE: the naive algorithm is not optimal. Counter example:
//take nb_partition = 3 ; replication_factor = 5; redundancy = 4; // take nb_partition = 3 ; replication_factor = 5; redundancy = 4;
//number of tokens by zone : (A, 4), (B,1), (C,4), (D, 4), (E, 2) // number of tokens by zone : (A, 4), (B,1), (C,4), (D, 4), (E, 2)
//With these parameters, the naive algo fails, whereas there is a solution: // With these parameters, the naive algo fails, whereas there is a solution:
//(A,A,C,D,E) , (A,B,C,D,D) (A,C,C,D,E) // (A,A,C,D,E) , (A,B,C,D,D) (A,C,C,D,E)
fn check_against_naive(cl: &ClusterLayout) -> Result<bool, Error> { fn check_against_naive(cl: &ClusterLayout) -> Result<bool, Error> {
let over_size = cl.partition_size + 1; let over_size = cl.partition_size + 1;
let mut zone_token = HashMap::<String, usize>::new(); let mut zone_token = HashMap::<String, usize>::new();
@ -994,8 +997,8 @@ mod tests {
); );
} }
//For every partition, we count the number of zone already associated and // For every partition, we count the number of zone already associated and
//the name of the last zone associated // the name of the last zone associated
let mut id_zone_token = vec![0; zones.len()]; let mut id_zone_token = vec![0; zones.len()];
for (z, t) in zone_token.iter() { for (z, t) in zone_token.iter() {
@ -1049,7 +1052,7 @@ mod tests {
cl.node_id_vec.push(x); cl.node_id_vec.push(x);
} }
let update = cl.staging.update_mutator( let update = cl.staging_roles.update_mutator(
cl.node_id_vec[i], cl.node_id_vec[i],
NodeRoleV(Some(NodeRole { NodeRoleV(Some(NodeRole {
zone: (node_zone_vec[i].to_string()), zone: (node_zone_vec[i].to_string()),
@ -1057,10 +1060,10 @@ mod tests {
tags: (vec![]), tags: (vec![]),
})), })),
); );
cl.staging.merge(&update); cl.staging_roles.merge(&update);
} }
cl.staging_hash = blake2sum(&rmp_to_vec_all_named(&cl.staging).unwrap()[..]); cl.staging_hash = cl.calculate_staging_hash();
cl.staged_parameters cl.staging_parameters
.update(LayoutParameters { zone_redundancy }); .update(LayoutParameters { zone_redundancy });
} }