Add DijkstraResult return type instead of unnamed tuple

This commit is contained in:
2026-04-22 14:49:07 +02:00
parent 41f2332735
commit a250bde626
2 changed files with 32 additions and 26 deletions
+16 -10
View File
@@ -21,19 +21,25 @@ impl<V: Eq> Ord for DistanceOrderedVertex<V> {
} }
} }
// TODO: Maybe introduce a return struct type for Dijkstra's algorithm? pub struct DijkstraResult<V> {
pub distances: Vec<Option<u32>>,
pub predecessors: Vec<Option<V>>,
}
// TODO: Maybe variant of Dijkstra's algorithm without predecessors? // TODO: Maybe variant of Dijkstra's algorithm without predecessors?
// TODO: Replace Vec storage with VertexMap, this should make the bound on G::Vertex here obsolete. // TODO: Replace Vec storage with VertexMap, this should make the bound on G::Vertex here obsolete.
pub fn dijkstra<G>(graph: &G, source: G::Vertex) -> (Vec<Option<u32>>, Vec<Option<G::Vertex>>) pub fn dijkstra<G>(graph: &G, source: G::Vertex) -> DijkstraResult<G::Vertex>
where where
G: GraphTopology, G: GraphTopology,
G::Vertex: Into<usize>, G::Vertex: Into<usize>,
{ {
let mut distances = vec![None; graph.vertex_count()]; let mut result = DijkstraResult {
let mut predecessors = vec![None; graph.vertex_count()]; distances: vec![None; graph.vertex_count()],
predecessors: vec![None; graph.vertex_count()],
};
let mut heap = BinaryHeap::new(); let mut heap = BinaryHeap::new();
distances[source.into()] = Some(0); result.distances[source.into()] = Some(0);
heap.push(DistanceOrderedVertex { heap.push(DistanceOrderedVertex {
vertex: source, vertex: source,
distance: 0, distance: 0,
@@ -43,14 +49,14 @@ where
for neighbor in graph.neighbors(v.vertex) { for neighbor in graph.neighbors(v.vertex) {
// TODO: Add a way to provide custom edge weights for Dijkstra's algorithm. // TODO: Add a way to provide custom edge weights for Dijkstra's algorithm.
let edge_weight = 1; let edge_weight = 1;
let new_distance = distances[v.vertex.into()].unwrap() + edge_weight; let new_distance = result.distances[v.vertex.into()].unwrap() + edge_weight;
if match distances[neighbor.into()] { if match result.distances[neighbor.into()] {
None => true, None => true,
Some(old_distance) if old_distance > new_distance => true, Some(old_distance) if old_distance > new_distance => true,
_ => false, _ => false,
} { } {
distances[neighbor.into()] = Some(new_distance); result.distances[neighbor.into()] = Some(new_distance);
predecessors[neighbor.into()] = Some(v.vertex); result.predecessors[neighbor.into()] = Some(v.vertex);
heap.push(DistanceOrderedVertex { heap.push(DistanceOrderedVertex {
vertex: neighbor, vertex: neighbor,
distance: new_distance, distance: new_distance,
@@ -58,5 +64,5 @@ where
} }
} }
} }
(distances, predecessors) result
} }
+16 -16
View File
@@ -6,24 +6,24 @@ use grapherity::traits::GraphTopology;
fn dijkstra_single_vertex() { fn dijkstra_single_vertex() {
let mut graph = AppendGraph::new(); let mut graph = AppendGraph::new();
let v1 = graph.add_vertex(); let v1 = graph.add_vertex();
let (distances, predecessors) = algorithms::dijkstra(&graph, v1); let result = algorithms::dijkstra(&graph, v1);
assert_eq!( assert_eq!(
distances.len(), result.distances.len(),
1, 1,
"distances count must equal vertex count" "distances count must equal vertex count"
); );
assert_eq!( assert_eq!(
predecessors.len(), result.predecessors.len(),
1, 1,
"predecessors count must equal vertex count" "predecessors count must equal vertex count"
); );
assert_eq!( assert_eq!(
distances[0], result.distances[0],
Some(0), Some(0),
"unexpected distance of source vertex" "unexpected distance of source vertex"
); );
assert_eq!( assert_eq!(
predecessors[0], None, result.predecessors[0], None,
"unexpected predecessor of source vertex", "unexpected predecessor of source vertex",
); );
} }
@@ -33,23 +33,23 @@ fn dijkstra_disconnected() {
let mut graph = AppendGraph::new(); let mut graph = AppendGraph::new();
let v1 = graph.add_vertex(); let v1 = graph.add_vertex();
graph.add_vertex(); graph.add_vertex();
let (distances, predecessors) = algorithms::dijkstra(&graph, v1); let result = algorithms::dijkstra(&graph, v1);
assert_eq!( assert_eq!(
distances.len(), result.distances.len(),
2, 2,
"distances count must equal vertex count" "distances count must equal vertex count"
); );
assert_eq!( assert_eq!(
predecessors.len(), result.predecessors.len(),
2, 2,
"predecessors count must equal vertex count" "predecessors count must equal vertex count"
); );
assert_eq!( assert_eq!(
distances[1], None, result.distances[1], None,
"unexpected distance of disconnected vertex" "unexpected distance of disconnected vertex"
); );
assert_eq!( assert_eq!(
predecessors[0], None, result.predecessors[0], None,
"unexpected predecessor of disconnected vertex", "unexpected predecessor of disconnected vertex",
); );
} }
@@ -57,7 +57,7 @@ fn dijkstra_disconnected() {
#[test] #[test]
fn dijkstra() { fn dijkstra() {
let (graph, vertices) = make_test_graph(); let (graph, vertices) = make_test_graph();
let (distances, predecessors) = algorithms::dijkstra(&graph, vertices[0]); let result = algorithms::dijkstra(&graph, vertices[0]);
let expected_distances_from_v0 = [ let expected_distances_from_v0 = [
Some(0), Some(0),
Some(1), Some(1),
@@ -83,25 +83,25 @@ fn dijkstra() {
vec![Some(vertices[5]), Some(vertices[6]), Some(vertices[7])], vec![Some(vertices[5]), Some(vertices[6]), Some(vertices[7])],
]; ];
assert_eq!( assert_eq!(
distances.len(), result.distances.len(),
graph.vertex_count(), graph.vertex_count(),
"distances count must equal vertex count" "distances count must equal vertex count"
); );
assert_eq!( assert_eq!(
predecessors.len(), result.predecessors.len(),
graph.vertex_count(), graph.vertex_count(),
"predecessors count must equal vertex count" "predecessors count must equal vertex count"
); );
for i in 0..graph.vertex_count() { for i in 0..graph.vertex_count() {
assert_eq!( assert_eq!(
distances[i], expected_distances_from_v0[i], result.distances[i], expected_distances_from_v0[i],
"unexpected distance from {:?} to {:?}", "unexpected distance from {:?} to {:?}",
vertices[0], vertices[i] vertices[0], vertices[i]
); );
assert!( assert!(
expected_predecessors_from_v0[i].contains(&predecessors[i]), expected_predecessors_from_v0[i].contains(&result.predecessors[i]),
"unexpected predecessor {:?} of {:?}", "unexpected predecessor {:?} of {:?}",
predecessors[i], result.predecessors[i],
vertices[i] vertices[i]
); );
} }