Corrected the warnings and errors issued by cargo clippy

2 files changed, 63 insertions, 80 deletions

diff --git a/src/rpc/layout.rs b/src/rpc/layout.rs
index ac31da72..d0ee3463 100644
--- a/src/rpc/layout.rs
+++ b/src/rpc/layout.rs
@@ -195,8 +195,8 @@ impl ClusterLayout {
 				.collect::<Vec<(String, usize)>>();
 			//We create an indexing of the zones
 			let mut zone_id = HashMap::<String, usize>::new();
-			for i in 0..part_per_zone_vec.len() {
-				zone_id.insert(part_per_zone_vec[i].0.clone(), i);
+			for (i, ppz) in part_per_zone_vec.iter().enumerate() {
+				zone_id.insert(ppz.0.clone(), i);
 			}
 
 			//We compute a candidate for the new partition to zone
@@ -212,7 +212,7 @@ impl ClusterLayout {
 			let mut node_assignation = vec![vec![None; self.replication_factor]; nb_partitions];
 			//We will decrement part_per_nod to keep track of the number
 			//of partitions that we still have to associate.
-			let mut part_per_nod = part_per_nod.clone();
+			let mut part_per_nod = part_per_nod;
 
 			//We minimize the distance to the former assignation(if any)
 
@@ -265,7 +265,7 @@ impl ClusterLayout {
 									&& part_per_nod[*id] > 0
 							})
 							.collect();
-						assert!(possible_nodes.len() > 0);
+						assert!(!possible_nodes.is_empty());
 						//We randomly pick a node
 						if let Some(nod) = possible_nodes.choose(&mut rng) {
 							node_assignation[i][j] = Some(*nod);
@@ -277,12 +277,12 @@ impl ClusterLayout {
 
 			//We write the assignation in the 1D table
 			self.ring_assignation_data = Vec::<CompactNodeType>::new();
-			for i in 0..nb_partitions {
-				for j in 0..self.replication_factor {
-					if let Some(id) = node_assignation[i][j] {
+			for ass in node_assignation {
+				for nod in ass {
+					if let Some(id) = nod {
 						self.ring_assignation_data.push(id as CompactNodeType);
 					} else {
-						assert!(false)
+						panic!()
 					}
 				}
 			}
@@ -318,7 +318,7 @@ impl ClusterLayout {
 
 		self.node_id_vec = new_node_id_vec;
 		self.ring_assignation_data = vec![];
-		return node_assignation;
+		node_assignation
 	}
 
 	///This function compute the number of partition to assign to
@@ -345,7 +345,7 @@ impl ClusterLayout {
 		//Compute the optimal number of partitions per zone
 		let sum_capacities: u32 = zone_capacity.values().sum();
 
-		if sum_capacities <= 0 {
+		if sum_capacities == 0 {
 			println!("No storage capacity in the network.");
 			return None;
 		}
@@ -493,14 +493,10 @@ impl ClusterLayout {
 			.map(|id_nod| match self.node_role(id_nod) {
 				Some(NodeRole {
 					zone: _,
-					capacity,
+					capacity: Some(c),
 					tags: _,
 				}) => {
-					if let Some(c) = capacity {
 						*c
-					} else {
-						0
-					}
 				}
 				_ => 0,
 			})
diff --git a/src/util/bipartite.rs b/src/util/bipartite.rs
index ade831a4..1e1e9caa 100644
--- a/src/util/bipartite.rs
+++ b/src/util/bipartite.rs
@@ -31,8 +31,8 @@ struct WeightedEdge {
  * as possible to old_match.
  * */
 pub fn optimize_matching(
-	old_match: &Vec<Vec<usize>>,
-	new_match: &Vec<Vec<usize>>,
+	old_match: &[Vec<usize>],
+	new_match: &[Vec<usize>],
 	nb_right: usize,
 ) -> Vec<Vec<usize>> {
 	let nb_left = old_match.len();
@@ -72,16 +72,11 @@ pub fn optimize_matching(
 	//Discovering and flipping a cycle with positive weight in this
 	//graph will make the matching closer to old_match.
 	//We use Bellman Ford algorithm to discover positive cycles
-	loop {
-		if let Some(cycle) = positive_cycle(&edge_vec, nb_left, nb_right) {
-			for i in cycle {
-				//We flip the edges of the cycle.
-				(edge_vec[i].u, edge_vec[i].v) = (edge_vec[i].v, edge_vec[i].u);
-				edge_vec[i].w *= -1;
-			}
-		} else {
-			//If there is no cycle, we return the optimal matching.
-			break;
+	while let Some(cycle) = positive_cycle(&edge_vec, nb_left, nb_right) {
+		for i in cycle {
+			//We flip the edges of the cycle.
+			(edge_vec[i].u, edge_vec[i].v) = (edge_vec[i].v, edge_vec[i].u);
+			edge_vec[i].w *= -1;
 		}
 	}
 
@@ -97,7 +92,7 @@ pub fn optimize_matching(
 
 //This function finds a positive cycle in a bipartite wieghted graph.
 fn positive_cycle(
-	edge_vec: &Vec<WeightedEdge>,
+	edge_vec: &[WeightedEdge],
 	nb_left: usize,
 	nb_right: usize,
 ) -> Option<Vec<usize>> {
@@ -122,8 +117,7 @@ fn positive_cycle(
 		//the number of partitions can be much larger than the
 		//number of nodes, we optimize that.
 		for _ in 0..(2 * nb_side_min) {
-			for j in 0..edge_vec.len() {
-				let e = edge_vec[j];
+			for (j, e) in edge_vec.iter().enumerate() {
 				if weight[e.v] < weight[e.u] + e.w {
 					weight[e.v] = weight[e.u] + e.w;
 					prev[e.v] = j;
@@ -148,8 +142,7 @@ fn positive_cycle(
 					curr = edge_vec[prev[curr]].u;
 				}
 				//Now curr is on the cycle. We collect the edges ids.
-				let mut cycle = Vec::<usize>::new();
-				cycle.push(prev[curr]);
+				let mut cycle = vec![prev[curr]];
 				let mut cycle_vert = edge_vec[prev[curr]].u;
 				while cycle_vert != curr {
 					cycle.push(prev[cycle_vert]);
@@ -180,16 +173,16 @@ pub fn dinic_compute_matching(left_cap_vec: Vec<u32>, right_cap_vec: Vec<u32>) -
 
 	// 0 will be the source
 	graph.push(vec![ed; left_cap_vec.len()]);
-	for i in 0..left_cap_vec.len() {
-		graph[0][i].c = left_cap_vec[i] as i32;
+	for (i, c) in left_cap_vec.iter().enumerate() {
+		graph[0][i].c = *c as i32;
 		graph[0][i].v = i + 2;
 		graph[0][i].rev = 0;
 	}
 
 	//1 will be the sink
 	graph.push(vec![ed; right_cap_vec.len()]);
-	for i in 0..right_cap_vec.len() {
-		graph[1][i].c = right_cap_vec[i] as i32;
+	for (i, c) in right_cap_vec.iter().enumerate() {
+		graph[1][i].c = *c as i32;
 		graph[1][i].v = i + 2 + left_cap_vec.len();
 		graph[1][i].rev = 0;
 	}
@@ -267,58 +260,52 @@ pub fn dinic_compute_matching(left_cap_vec: Vec<u32>, right_cap_vec: Vec<u32>) -
 		let mut next_nbd = vec![0; nb_vertices];
 		let mut lifo = VecDeque::new();
 
-		let flow_upper_bound;
-		if let Some(x) = left_cap_vec.iter().max() {
-			flow_upper_bound = *x as i32;
+		let flow_upper_bound = if let Some(x) = left_cap_vec.iter().max() {
+			*x as i32
 		} else {
-			flow_upper_bound = 0;
-			assert!(false);
-		}
+			panic!();
+		};
 
 		lifo.push_back((0, flow_upper_bound));
 
-		loop {
-			if let Some((id_tmp, f_tmp)) = lifo.back() {
-				let id = *id_tmp;
-				let f = *f_tmp;
-				if id == 1 {
-					//The DFS reached the sink, we can add a
-					//residual flow.
-					lifo.pop_back();
-					while !lifo.is_empty() {
-						if let Some((id, _)) = lifo.pop_back() {
-							let nbd = next_nbd[id];
-							graph[id][nbd].flow += f;
-							let id_v = graph[id][nbd].v;
-							let nbd_v = graph[id][nbd].rev;
-							graph[id_v][nbd_v].flow -= f;
-						}
+		while let Some((id_tmp, f_tmp)) = lifo.back() {
+			let id = *id_tmp;
+			let f = *f_tmp;
+			if id == 1 {
+				//The DFS reached the sink, we can add a
+				//residual flow.
+				lifo.pop_back();
+				while !lifo.is_empty() {
+					if let Some((id, _)) = lifo.pop_back() {
+						let nbd = next_nbd[id];
+						graph[id][nbd].flow += f;
+						let id_v = graph[id][nbd].v;
+						let nbd_v = graph[id][nbd].rev;
+						graph[id_v][nbd_v].flow -= f;
 					}
-					lifo.push_back((0, flow_upper_bound));
-					continue;
 				}
-				//else we did not reach the sink
-				let nbd = next_nbd[id];
-				if nbd >= graph[id].len() {
-					//There is nothing to explore from id anymore
-					lifo.pop_back();
-					if let Some((parent, _)) = lifo.back() {
-						next_nbd[*parent] += 1;
-					}
-					continue;
-				}
-				//else we can try to send flow from id to its nbd
-				let new_flow = min(f, graph[id][nbd].c - graph[id][nbd].flow);
-				if level[graph[id][nbd].v] <= level[id] || new_flow == 0 {
-					//We cannot send flow to nbd.
-					next_nbd[id] += 1;
-					continue;
+				lifo.push_back((0, flow_upper_bound));
+				continue;
+			}
+			//else we did not reach the sink
+			let nbd = next_nbd[id];
+			if nbd >= graph[id].len() {
+				//There is nothing to explore from id anymore
+				lifo.pop_back();
+				if let Some((parent, _)) = lifo.back() {
+					next_nbd[*parent] += 1;
 				}
-				//otherwise, we send flow to nbd.
-				lifo.push_back((graph[id][nbd].v, new_flow));
-			} else {
-				break;
+				continue;
+			}
+			//else we can try to send flow from id to its nbd
+			let new_flow = min(f, graph[id][nbd].c - graph[id][nbd].flow);
+			if level[graph[id][nbd].v] <= level[id] || new_flow == 0 {
+				//We cannot send flow to nbd.
+				next_nbd[id] += 1;
+				continue;
 			}
+			//otherwise, we send flow to nbd.
+			lifo.push_back((graph[id][nbd].v, new_flow));
 		}
 	}