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util.rs
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util.rs
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use super::{DisjointSets, Graph};
use crate::graph::AdjListIterator;
use std::cmp::Reverse;
impl Graph {
/// Finds the sequence of edges in an Euler path starting from u, assuming
/// it exists and that the graph is directed. Undefined behavior if this
/// precondition is violated. To extend this to undirected graphs, maintain
/// a visited array to skip the reverse edge.
pub fn euler_path(&self, u: usize) -> Vec<usize> {
let mut adj_iters = (0..self.num_v())
.map(|u| self.adj_list(u))
.collect::<Vec<_>>();
let mut edges = Vec::with_capacity(self.num_e());
self.euler_recurse(u, &mut adj_iters, &mut edges);
edges.reverse();
edges
}
// Helper function used by euler_path. Note that we can't use a for-loop
// that would consume the adjacency list as recursive calls may need it.
fn euler_recurse(&self, u: usize, adj: &mut [AdjListIterator], edges: &mut Vec<usize>) {
while let Some((e, v)) = adj[u].next() {
self.euler_recurse(v, adj, edges);
edges.push(e);
}
}
/// Kruskal's minimum spanning tree algorithm on an undirected graph.
pub fn min_spanning_tree(&self, weights: &[i64]) -> Vec<usize> {
assert_eq!(self.num_e(), 2 * weights.len());
let mut edges = (0..weights.len()).collect::<Vec<_>>();
edges.sort_unstable_by_key(|&e| weights[e]);
let mut components = DisjointSets::new(self.num_v());
edges
.into_iter()
.filter(|&e| components.merge(self.endp[2 * e], self.endp[2 * e + 1]))
.collect()
}
// Single-source shortest paths on a directed graph with non-negative weights
pub fn dijkstra(&self, weights: &[u64], u: usize) -> Vec<u64> {
assert_eq!(self.num_e(), weights.len());
let mut dist = vec![u64::max_value(); weights.len()];
let mut heap = std::collections::BinaryHeap::new();
dist[u] = 0;
heap.push((Reverse(0), 0));
while let Some((Reverse(dist_u), u)) = heap.pop() {
if dist[u] == dist_u {
for (e, v) in self.adj_list(u) {
let dist_v = dist_u + weights[e];
if dist[v] > dist_v {
dist[v] = dist_v;
heap.push((Reverse(dist_v), v));
}
}
}
}
dist
}
pub fn dfs(&self, root: usize) -> DfsIterator {
let mut visited = vec![false; self.num_v()];
visited[root] = true;
let adj_iters = (0..self.num_v())
.map(|u| self.adj_list(u))
.collect::<Vec<_>>();
DfsIterator {
visited,
stack: vec![root],
adj_iters,
}
}
}
pub struct DfsIterator<'a> {
visited: Vec<bool>,
stack: Vec<usize>,
adj_iters: Vec<AdjListIterator<'a>>,
}
impl<'a> Iterator for DfsIterator<'a> {
type Item = (usize, usize);
/// Returns next edge and vertex in the depth-first traversal
// Refs: https://www.geeksforgeeks.org/iterative-depth-first-traversal/
// https://en.wikipedia.org/wiki/Depth-first_search
fn next(&mut self) -> Option<Self::Item> {
loop {
let &u = self.stack.last()?;
for (e, v) in self.adj_iters[u].by_ref() {
if !self.visited[v] {
self.visited[v] = true;
self.stack.push(v);
return Some((e, v));
}
}
self.stack.pop();
}
}
}
#[cfg(test)]
mod test {
use super::*;
#[test]
fn test_euler() {
let mut graph = Graph::new(3, 4);
graph.add_edge(0, 1);
graph.add_edge(1, 0);
graph.add_edge(1, 2);
graph.add_edge(2, 1);
assert_eq!(graph.euler_path(0), vec![0, 2, 3, 1]);
}
#[test]
fn test_min_spanning_tree() {
let mut graph = Graph::new(3, 6);
graph.add_undirected_edge(0, 1);
graph.add_undirected_edge(1, 2);
graph.add_undirected_edge(2, 0);
let weights = [7, 3, 5];
let mst = graph.min_spanning_tree(&weights);
let mst_cost = mst.iter().map(|&e| weights[e]).sum::<i64>();
assert_eq!(mst, vec![1, 2]);
assert_eq!(mst_cost, 8);
}
#[test]
fn test_dijkstra() {
let mut graph = Graph::new(3, 3);
graph.add_edge(0, 1);
graph.add_edge(1, 2);
graph.add_edge(2, 0);
let weights = [7, 3, 5];
let dist = graph.dijkstra(&weights, 0);
assert_eq!(dist, vec![0, 7, 10]);
}
#[test]
fn test_dfs() {
let mut graph = Graph::new(4, 6);
graph.add_edge(0, 2);
graph.add_edge(2, 0);
graph.add_edge(1, 2);
graph.add_edge(0, 1);
graph.add_edge(3, 3);
graph.add_edge(2, 3);
let dfs_root = 2;
let dfs_traversal = std::iter::once(dfs_root)
.chain(graph.dfs(dfs_root).map(|(_, v)| v))
.collect::<Vec<_>>();
assert_eq!(dfs_traversal, vec![2, 3, 0, 1]);
}
#[test]
fn test_dfs2() {
let mut graph = Graph::new(5, 6);
graph.add_edge(0, 2);
graph.add_edge(2, 1);
graph.add_edge(1, 0);
graph.add_edge(0, 3);
graph.add_edge(3, 4);
graph.add_edge(4, 0);
let dfs_root = 0;
let dfs_traversal = std::iter::once(dfs_root)
.chain(graph.dfs(dfs_root).map(|(_, v)| v))
.collect::<Vec<_>>();
assert_eq!(dfs_traversal, vec![0, 3, 4, 2, 1]);
}
#[test]
fn test_dfs_space_complexity() {
let num_v = 20;
let mut graph = Graph::new(num_v, 0);
for i in 0..num_v {
for j in 0..num_v {
graph.add_undirected_edge(i, j);
}
}
let dfs_root = 7;
let mut dfs_search = graph.dfs(dfs_root);
let mut dfs_check = vec![dfs_root];
for _ in 1..num_v {
dfs_check.push(dfs_search.next().unwrap().1);
assert!(dfs_search.stack.len() <= num_v + 1);
}
dfs_check.sort();
dfs_check.dedup();
assert_eq!(0, dfs_check[0]);
assert_eq!(num_v, dfs_check.len());
assert_eq!(num_v - 1, dfs_check[num_v - 1]);
}
}