extern crate petgraph; use std::collections::HashSet; use std::hash::Hash; use petgraph::prelude::*; use petgraph::EdgeType; use petgraph as pg; use petgraph::algo::{ dominators, has_path_connecting, is_bipartite_undirected, is_cyclic_undirected, is_isomorphic_matching, min_spanning_tree, }; use petgraph::graph::node_index as n; use petgraph::graph::IndexType; use petgraph::algo::{astar, dijkstra, DfsSpace}; use petgraph::visit::{ IntoEdges, IntoEdgesDirected, IntoNeighbors, IntoNodeIdentifiers, NodeFiltered, Reversed, Topo, VisitMap, Walker, }; use petgraph::dot::Dot; fn set(iter: I) -> HashSet where I: IntoIterator, I::Item: Hash + Eq, { iter.into_iter().collect() } #[test] fn undirected() { let mut og = Graph::new_undirected(); let a = og.add_node(0); let b = og.add_node(1); let c = og.add_node(2); let d = og.add_node(3); let _ = og.add_edge(a, b, 0); let _ = og.add_edge(a, c, 1); og.add_edge(c, a, 2); og.add_edge(a, a, 3); og.add_edge(b, c, 4); og.add_edge(b, a, 5); og.add_edge(a, d, 6); assert_eq!(og.node_count(), 4); assert_eq!(og.edge_count(), 7); assert!(og.find_edge(a, b).is_some()); assert!(og.find_edge(d, a).is_some()); assert!(og.find_edge(a, a).is_some()); for edge in og.raw_edges() { assert!(og.find_edge(edge.source(), edge.target()).is_some()); assert!(og.find_edge(edge.target(), edge.source()).is_some()); } assert_eq!(og.neighbors(b).collect::>(), vec![a, c, a]); og.remove_node(a); assert_eq!(og.neighbors(b).collect::>(), vec![c]); assert_eq!(og.node_count(), 3); assert_eq!(og.edge_count(), 1); assert!(og.find_edge(a, b).is_none()); assert!(og.find_edge(d, a).is_none()); assert!(og.find_edge(a, a).is_none()); assert!(og.find_edge(b, c).is_some()); assert_graph_consistent(&og); } #[test] fn dfs() { let mut gr = Graph::new(); let h = gr.add_node("H"); let i = gr.add_node("I"); let j = gr.add_node("J"); let k = gr.add_node("K"); // Z is disconnected. let _ = gr.add_node("Z"); gr.add_edge(h, i, 1.); gr.add_edge(h, j, 3.); gr.add_edge(i, j, 1.); gr.add_edge(i, k, 2.); println!("{}", Dot::new(&gr)); assert_eq!(Dfs::new(&gr, h).iter(&gr).count(), 4); assert_eq!(Dfs::new(&gr, h).iter(&gr).clone().count(), 4); assert_eq!(Dfs::new(&gr, h).iter(Reversed(&gr)).count(), 1); assert_eq!(Dfs::new(&gr, k).iter(Reversed(&gr)).count(), 3); assert_eq!(Dfs::new(&gr, i).iter(&gr).count(), 3); } #[test] fn dfs_order() { let mut gr = Graph::new(); let h = gr.add_node("H"); let i = gr.add_node("I"); let j = gr.add_node("J"); let k = gr.add_node("K"); gr.add_edge(h, i, ()); gr.add_edge(h, j, ()); gr.add_edge(h, k, ()); gr.add_edge(i, k, ()); gr.add_edge(k, i, ()); // H // / | \ // I J K // \___/ // // J cannot be visited between I and K in a depth-first search from H let mut seen_i = false; let mut seen_k = false; for node in Dfs::new(&gr, h).iter(&gr) { seen_i |= i == node; seen_k |= k == node; assert!(!(j == node && (seen_i ^ seen_k)), "Invalid DFS order"); } } #[test] fn bfs() { let mut gr = Graph::new(); let h = gr.add_node("H"); let i = gr.add_node("I"); let j = gr.add_node("J"); let k = gr.add_node("K"); // Z is disconnected. let _ = gr.add_node("Z"); gr.add_edge(h, i, 1.); gr.add_edge(h, j, 3.); gr.add_edge(i, j, 1.); gr.add_edge(i, k, 2.); assert_eq!(Bfs::new(&gr, h).iter(&gr).count(), 4); assert_eq!(Bfs::new(&gr, h).iter(&gr).clone().count(), 4); assert_eq!(Bfs::new(&gr, h).iter(Reversed(&gr)).count(), 1); assert_eq!(Bfs::new(&gr, k).iter(Reversed(&gr)).count(), 3); assert_eq!(Bfs::new(&gr, i).iter(&gr).count(), 3); let mut bfs = Bfs::new(&gr, h); let nx = bfs.next(&gr); assert_eq!(nx, Some(h)); let nx1 = bfs.next(&gr); assert!(nx1 == Some(i) || nx1 == Some(j)); let nx2 = bfs.next(&gr); assert!(nx2 == Some(i) || nx2 == Some(j)); assert!(nx1 != nx2); let nx = bfs.next(&gr); assert_eq!(nx, Some(k)); assert_eq!(bfs.next(&gr), None); } #[test] fn mst() { use petgraph::data::FromElements; let mut gr = Graph::<_, _>::new(); let a = gr.add_node("A"); let b = gr.add_node("B"); let c = gr.add_node("C"); let d = gr.add_node("D"); let e = gr.add_node("E"); let f = gr.add_node("F"); let g = gr.add_node("G"); gr.add_edge(a, b, 7.); gr.add_edge(a, d, 5.); gr.add_edge(d, b, 9.); gr.add_edge(b, c, 8.); gr.add_edge(b, e, 7.); gr.add_edge(c, e, 5.); gr.add_edge(d, e, 15.); gr.add_edge(d, f, 6.); gr.add_edge(f, e, 8.); gr.add_edge(f, g, 11.); gr.add_edge(e, g, 9.); // add a disjoint part let h = gr.add_node("H"); let i = gr.add_node("I"); let j = gr.add_node("J"); gr.add_edge(h, i, 1.); gr.add_edge(h, j, 3.); gr.add_edge(i, j, 1.); println!("{}", Dot::new(&gr)); let mst = UnGraph::from_elements(min_spanning_tree(&gr)); println!("{}", Dot::new(&mst)); println!("{:?}", Dot::new(&mst)); println!("MST is:\n{:#?}", mst); assert!(mst.node_count() == gr.node_count()); // |E| = |N| - 2 because there are two disconnected components. assert!(mst.edge_count() == gr.node_count() - 2); // check the exact edges are there assert!(mst.find_edge(a, b).is_some()); assert!(mst.find_edge(a, d).is_some()); assert!(mst.find_edge(b, e).is_some()); assert!(mst.find_edge(e, c).is_some()); assert!(mst.find_edge(e, g).is_some()); assert!(mst.find_edge(d, f).is_some()); assert!(mst.find_edge(h, i).is_some()); assert!(mst.find_edge(i, j).is_some()); assert!(mst.find_edge(d, b).is_none()); assert!(mst.find_edge(b, c).is_none()); } #[test] fn selfloop() { let mut gr = Graph::new(); let a = gr.add_node("A"); let b = gr.add_node("B"); let c = gr.add_node("C"); gr.add_edge(a, b, 7.); gr.add_edge(c, a, 6.); let sed = gr.add_edge(a, a, 2.); assert!(gr.find_edge(a, b).is_some()); assert!(gr.find_edge(b, a).is_none()); assert!(gr.find_edge_undirected(b, a).is_some()); assert!(gr.find_edge(a, a).is_some()); println!("{:?}", gr); gr.remove_edge(sed); assert!(gr.find_edge(a, a).is_none()); println!("{:?}", gr); } #[test] fn cyclic() { let mut gr = Graph::new(); let a = gr.add_node("A"); let b = gr.add_node("B"); let c = gr.add_node("C"); assert!(!is_cyclic_undirected(&gr)); gr.add_edge(a, b, 7.); gr.add_edge(c, a, 6.); assert!(!is_cyclic_undirected(&gr)); { let e = gr.add_edge(a, a, 0.); assert!(is_cyclic_undirected(&gr)); gr.remove_edge(e); assert!(!is_cyclic_undirected(&gr)); } { let e = gr.add_edge(b, c, 0.); assert!(is_cyclic_undirected(&gr)); gr.remove_edge(e); assert!(!is_cyclic_undirected(&gr)); } let d = gr.add_node("D"); let e = gr.add_node("E"); gr.add_edge(b, d, 0.); gr.add_edge(d, e, 0.); assert!(!is_cyclic_undirected(&gr)); gr.add_edge(c, e, 0.); assert!(is_cyclic_undirected(&gr)); assert_graph_consistent(&gr); } #[test] fn bipartite() { { let mut gr = Graph::new_undirected(); let a = gr.add_node("A"); let b = gr.add_node("B"); let c = gr.add_node("C"); let d = gr.add_node("D"); let e = gr.add_node("E"); let f = gr.add_node("F"); gr.add_edge(a, d, 7.); gr.add_edge(b, d, 6.); assert!(is_bipartite_undirected(&gr, a)); let e_index = gr.add_edge(a, b, 6.); assert!(!is_bipartite_undirected(&gr, a)); gr.remove_edge(e_index); assert!(is_bipartite_undirected(&gr, a)); gr.add_edge(b, e, 7.); gr.add_edge(b, f, 6.); gr.add_edge(c, e, 6.); assert!(is_bipartite_undirected(&gr, a)); } { let mut gr = Graph::new_undirected(); let a = gr.add_node("A"); let b = gr.add_node("B"); let c = gr.add_node("C"); let d = gr.add_node("D"); let e = gr.add_node("E"); let f = gr.add_node("F"); let g = gr.add_node("G"); let h = gr.add_node("H"); gr.add_edge(a, f, 7.); gr.add_edge(a, g, 7.); gr.add_edge(a, h, 7.); gr.add_edge(b, f, 6.); gr.add_edge(b, g, 6.); gr.add_edge(b, h, 6.); gr.add_edge(c, f, 6.); gr.add_edge(c, g, 6.); gr.add_edge(c, h, 6.); gr.add_edge(d, f, 6.); gr.add_edge(d, g, 6.); gr.add_edge(d, h, 6.); gr.add_edge(e, f, 6.); gr.add_edge(e, g, 6.); gr.add_edge(e, h, 6.); assert!(is_bipartite_undirected(&gr, a)); gr.add_edge(a, b, 6.); assert!(!is_bipartite_undirected(&gr, a)); } } #[test] fn multi() { let mut gr = Graph::new(); let a = gr.add_node("a"); let b = gr.add_node("b"); gr.add_edge(a, b, ()); gr.add_edge(a, b, ()); assert_eq!(gr.edge_count(), 2); } #[test] fn iter_multi_edges() { let mut gr = Graph::new(); let a = gr.add_node("a"); let b = gr.add_node("b"); let c = gr.add_node("c"); let mut connecting_edges = HashSet::new(); gr.add_edge(a, a, ()); connecting_edges.insert(gr.add_edge(a, b, ())); gr.add_edge(a, c, ()); gr.add_edge(c, b, ()); connecting_edges.insert(gr.add_edge(a, b, ())); gr.add_edge(b, a, ()); let mut iter = gr.edges_connecting(a, b); let edge_id = iter.next().unwrap().id(); assert!(connecting_edges.contains(&edge_id)); connecting_edges.remove(&edge_id); let edge_id = iter.next().unwrap().id(); assert!(connecting_edges.contains(&edge_id)); connecting_edges.remove(&edge_id); assert_eq!(None, iter.next()); assert!(connecting_edges.is_empty()); } #[test] fn iter_multi_undirected_edges() { let mut gr = Graph::new_undirected(); let a = gr.add_node("a"); let b = gr.add_node("b"); let c = gr.add_node("c"); let mut connecting_edges = HashSet::new(); gr.add_edge(a, a, ()); connecting_edges.insert(gr.add_edge(a, b, ())); gr.add_edge(a, c, ()); gr.add_edge(c, b, ()); connecting_edges.insert(gr.add_edge(a, b, ())); connecting_edges.insert(gr.add_edge(b, a, ())); let mut iter = gr.edges_connecting(a, b); let edge_id = iter.next().unwrap().id(); assert!(connecting_edges.contains(&edge_id)); connecting_edges.remove(&edge_id); let edge_id = iter.next().unwrap().id(); assert!(connecting_edges.contains(&edge_id)); connecting_edges.remove(&edge_id); let edge_id = iter.next().unwrap().id(); assert!(connecting_edges.contains(&edge_id)); connecting_edges.remove(&edge_id); assert_eq!(None, iter.next()); assert!(connecting_edges.is_empty()); } #[test] fn update_edge() { { let mut gr = Graph::new(); let a = gr.add_node("a"); let b = gr.add_node("b"); let e = gr.update_edge(a, b, 1); let f = gr.update_edge(a, b, 2); let _ = gr.update_edge(b, a, 3); assert_eq!(gr.edge_count(), 2); assert_eq!(e, f); assert_eq!(*gr.edge_weight(f).unwrap(), 2); } { let mut gr = Graph::new_undirected(); let a = gr.add_node("a"); let b = gr.add_node("b"); let e = gr.update_edge(a, b, 1); let f = gr.update_edge(b, a, 2); assert_eq!(gr.edge_count(), 1); assert_eq!(e, f); assert_eq!(*gr.edge_weight(f).unwrap(), 2); } } #[test] fn dijk() { let mut g = Graph::new_undirected(); let a = g.add_node("A"); let b = g.add_node("B"); let c = g.add_node("C"); let d = g.add_node("D"); let e = g.add_node("E"); let f = g.add_node("F"); g.add_edge(a, b, 7); g.add_edge(c, a, 9); g.add_edge(a, d, 14); g.add_edge(b, c, 10); g.add_edge(d, c, 2); g.add_edge(d, e, 9); g.add_edge(b, f, 15); g.add_edge(c, f, 11); g.add_edge(e, f, 6); println!("{:?}", g); for no in Bfs::new(&g, a).iter(&g) { println!("Visit {:?} = {:?}", no, g.node_weight(no)); } let scores = dijkstra(&g, a, None, |e| *e.weight()); let mut scores: Vec<_> = scores.into_iter().map(|(n, s)| (g[n], s)).collect(); scores.sort(); assert_eq!( scores, vec![ ("A", 0), ("B", 7), ("C", 9), ("D", 11), ("E", 20), ("F", 20) ] ); let scores = dijkstra(&g, a, Some(c), |e| *e.weight()); assert_eq!(scores[&c], 9); } #[test] fn test_astar_null_heuristic() { let mut g = Graph::new(); let a = g.add_node("A"); let b = g.add_node("B"); let c = g.add_node("C"); let d = g.add_node("D"); let e = g.add_node("E"); let f = g.add_node("F"); g.add_edge(a, b, 7); g.add_edge(c, a, 9); g.add_edge(a, d, 14); g.add_edge(b, c, 10); g.add_edge(d, c, 2); g.add_edge(d, e, 9); g.add_edge(b, f, 15); g.add_edge(c, f, 11); g.add_edge(e, f, 6); let path = astar(&g, a, |finish| finish == e, |e| *e.weight(), |_| 0); assert_eq!(path, Some((23, vec![a, d, e]))); // check against dijkstra let dijkstra_run = dijkstra(&g, a, Some(e), |e| *e.weight()); assert_eq!(dijkstra_run[&e], 23); let path = astar(&g, e, |finish| finish == b, |e| *e.weight(), |_| 0); assert_eq!(path, None); } #[test] fn test_astar_manhattan_heuristic() { let mut g = Graph::new(); let a = g.add_node((0., 0.)); let b = g.add_node((2., 0.)); let c = g.add_node((1., 1.)); let d = g.add_node((0., 2.)); let e = g.add_node((3., 3.)); let f = g.add_node((4., 2.)); let _ = g.add_node((5., 5.)); // no path to node g.add_edge(a, b, 2.); g.add_edge(a, d, 4.); g.add_edge(b, c, 1.); g.add_edge(b, f, 7.); g.add_edge(c, e, 5.); g.add_edge(e, f, 1.); g.add_edge(d, e, 1.); let heuristic_for = |f: NodeIndex| { let g = &g; move |node: NodeIndex| -> f32 { let (x1, y1): (f32, f32) = g[node]; let (x2, y2): (f32, f32) = g[f]; (x2 - x1).abs() + (y2 - y1).abs() } }; let path = astar( &g, a, |finish| finish == f, |e| *e.weight(), heuristic_for(f), ); assert_eq!(path, Some((6., vec![a, d, e, f]))); // check against dijkstra let dijkstra_run = dijkstra(&g, a, None, |e| *e.weight()); for end in g.node_indices() { let astar_path = astar( &g, a, |finish| finish == end, |e| *e.weight(), heuristic_for(end), ); assert_eq!(dijkstra_run.get(&end).cloned(), astar_path.map(|t| t.0)); } } #[test] fn test_astar_runtime_optimal() { let mut g = Graph::new(); let a = g.add_node("A"); let b = g.add_node("B"); let c = g.add_node("C"); let d = g.add_node("D"); let e = g.add_node("E"); g.add_edge(a, b, 2); g.add_edge(a, c, 3); g.add_edge(b, d, 3); g.add_edge(c, d, 1); g.add_edge(d, e, 1); let mut times_called = 0; let _ = astar(&g, a, |n| n == e, |edge| { times_called += 1; *edge.weight() }, |_| 0); // A* is runtime optimal in the sense it won't expand more nodes than needed, for the given // heuristic. Here, A* should expand, in order: A, B, C, D, E. This should should ask for the // costs of edges (A, B), (A, C), (B, D), (C, D), (D, E). Node D will be added to `visit_next` // twice, but should only be expanded once. If it is erroneously expanded twice, it will call // for (D, E) again and `times_called` will be 6. assert_eq!(times_called, 5); } #[test] fn test_astar_admissible_inconsistent() { let mut g = Graph::new(); let a = g.add_node("A"); let b = g.add_node("B"); let c = g.add_node("C"); let d = g.add_node("D"); g.add_edge(a, b, 3); g.add_edge(b, c, 3); g.add_edge(c, d, 3); g.add_edge(a, c, 8); g.add_edge(a, d, 10); let admissible_inconsistent = |n: NodeIndex| match g[n] { "A" => 9, "B" => 6, "C" => 0, &_ => 0, }; let optimal = astar(&g, a, |n| n == d, |e| *e.weight(), admissible_inconsistent); assert_eq!(optimal, Some((9, vec![a, b, c, d]))); } #[cfg(feature = "generate")] #[test] fn test_generate_undirected() { for size in 0..4 { let mut gen = pg::generate::Generator::::all(size, true); let nedges = (size * size - size) / 2 + size; let mut n = 0; while let Some(g) = gen.next_ref() { n += 1; println!("{:?}", g); } assert_eq!(n, 1 << nedges); } } #[cfg(feature = "generate")] #[test] fn test_generate_directed() { // Number of DAG out of all graphs (all permutations) per node size // 0, 1, 2, 3, 4, 5 .. let n_dag = &[1, 1, 3, 25, 543, 29281, 3781503]; for (size, &dags_exp) in (0..4).zip(n_dag) { let mut gen = pg::generate::Generator::::all(size, true); let nedges = size * size; let mut n = 0; let mut dags = 0; while let Some(g) = gen.next_ref() { n += 1; if !pg::algo::is_cyclic_directed(g) { dags += 1; } } /* // check that all generated graphs have unique adjacency matrices let mut adjmats = graphs.iter().map(Graph::adjacency_matrix).collect::>(); adjmats.sort(); adjmats.dedup(); assert_eq!(adjmats.len(), n); */ assert_eq!(dags_exp, dags); assert_eq!(n, 1 << nedges); } } #[cfg(feature = "generate")] #[test] fn test_generate_dag() { use petgraph::visit::GetAdjacencyMatrix; for size in 1..5 { let gen = pg::generate::Generator::directed_acyclic(size); let nedges = (size - 1) * size / 2; let graphs = gen.collect::>(); assert_eq!(graphs.len(), 1 << nedges); // check that all generated graphs have unique adjacency matrices let mut adjmats = graphs .iter() .map(Graph::adjacency_matrix) .collect::>(); adjmats.sort(); adjmats.dedup(); assert_eq!(adjmats.len(), graphs.len()); for gr in &graphs { assert!( !petgraph::algo::is_cyclic_directed(gr), "Assertion failed: {:?} acyclic", gr ); } } } #[test] fn without() { let mut og = Graph::new_undirected(); let a = og.add_node(0); let b = og.add_node(1); let c = og.add_node(2); let d = og.add_node(3); let _ = og.add_edge(a, b, 0); let _ = og.add_edge(a, c, 1); let v: Vec = og.externals(Outgoing).collect(); assert_eq!(v, vec![d]); let mut og = Graph::new(); let a = og.add_node(0); let b = og.add_node(1); let c = og.add_node(2); let d = og.add_node(3); let _ = og.add_edge(a, b, 0); let _ = og.add_edge(a, c, 1); let init: Vec = og.externals(Incoming).collect(); let term: Vec = og.externals(Outgoing).collect(); assert_eq!(init, vec![a, d]); assert_eq!(term, vec![b, c, d]); } fn assert_is_topo_order(gr: &Graph, order: &[NodeIndex]) { assert_eq!(gr.node_count(), order.len()); // check all the edges of the graph for edge in gr.raw_edges() { let a = edge.source(); let b = edge.target(); let ai = order.iter().position(|x| *x == a).unwrap(); let bi = order.iter().position(|x| *x == b).unwrap(); println!("Check that {:?} is before {:?}", a, b); assert!( ai < bi, "Topo order: assertion that node {:?} is before {:?} failed", a, b ); } } #[test] fn test_toposort() { let mut gr = Graph::<_, _>::new(); let a = gr.add_node("A"); let b = gr.add_node("B"); let c = gr.add_node("C"); let d = gr.add_node("D"); let e = gr.add_node("E"); let f = gr.add_node("F"); let g = gr.add_node("G"); gr.extend_with_edges(&[ (a, b, 7.), (a, d, 5.), (d, b, 9.), (b, c, 8.), (b, e, 7.), (c, e, 5.), (d, e, 15.), (d, f, 6.), (f, e, 8.), (f, g, 11.), (e, g, 9.), ]); // add a disjoint part let h = gr.add_node("H"); let i = gr.add_node("I"); let j = gr.add_node("J"); gr.add_edge(h, i, 1.); gr.add_edge(h, j, 3.); gr.add_edge(i, j, 1.); let order = petgraph::algo::toposort(&gr, None).unwrap(); println!("{:?}", order); assert_eq!(order.len(), gr.node_count()); assert_is_topo_order(&gr, &order); } #[test] fn test_toposort_eq() { let mut g = Graph::<_, _>::new(); let a = g.add_node("A"); let b = g.add_node("B"); g.add_edge(a, b, ()); assert_eq!(petgraph::algo::toposort(&g, None), Ok(vec![a, b])); } #[test] fn is_cyclic_directed() { let mut gr = Graph::<_, _>::new(); let a = gr.add_node("A"); let b = gr.add_node("B"); let c = gr.add_node("C"); let d = gr.add_node("D"); let e = gr.add_node("E"); let f = gr.add_node("F"); let g = gr.add_node("G"); gr.add_edge(a, b, 7.0); gr.add_edge(a, d, 5.); gr.add_edge(d, b, 9.); gr.add_edge(b, c, 8.); gr.add_edge(b, e, 7.); gr.add_edge(c, e, 5.); gr.add_edge(d, e, 15.); gr.add_edge(d, f, 6.); gr.add_edge(f, e, 8.); gr.add_edge(f, g, 11.); gr.add_edge(e, g, 9.); assert!(!petgraph::algo::is_cyclic_directed(&gr)); // add a disjoint part let h = gr.add_node("H"); let i = gr.add_node("I"); let j = gr.add_node("J"); gr.add_edge(h, i, 1.); gr.add_edge(h, j, 3.); gr.add_edge(i, j, 1.); assert!(!petgraph::algo::is_cyclic_directed(&gr)); gr.add_edge(g, e, 0.); assert!(petgraph::algo::is_cyclic_directed(&gr)); } /// Compare two scc sets. Inside each scc, the order does not matter, /// but the order of the sccs is significant. fn assert_sccs_eq( mut res: Vec>, mut answer: Vec>, scc_order_matters: bool, ) { // normalize the result and compare with the answer. for scc in &mut res { scc.sort(); } for scc in &mut answer { scc.sort(); } if !scc_order_matters { res.sort(); answer.sort(); } assert_eq!(res, answer); } #[test] fn scc() { let gr: Graph<(), ()> = Graph::from_edges(&[ (6, 0), (0, 3), (3, 6), (8, 6), (8, 2), (2, 5), (5, 8), (7, 5), (1, 7), (7, 4), (4, 1), ]); assert_sccs_eq( petgraph::algo::kosaraju_scc(&gr), vec![ vec![n(0), n(3), n(6)], vec![n(2), n(5), n(8)], vec![n(1), n(4), n(7)], ], true, ); // Reversed edges gives the same sccs (when sorted) assert_sccs_eq( petgraph::algo::kosaraju_scc(Reversed(&gr)), vec![ vec![n(1), n(4), n(7)], vec![n(2), n(5), n(8)], vec![n(0), n(3), n(6)], ], true, ); // Test an undirected graph just for fun. // Sccs are just connected components. let mut hr = gr.into_edge_type::(); // Delete an edge to disconnect it let ed = hr.find_edge(n(6), n(8)).unwrap(); assert!(hr.remove_edge(ed).is_some()); assert_sccs_eq( petgraph::algo::kosaraju_scc(&hr), vec![ vec![n(0), n(3), n(6)], vec![n(1), n(2), n(4), n(5), n(7), n(8)], ], false, ); // acyclic non-tree, #14 let n = NodeIndex::new; let mut gr = Graph::new(); gr.add_node(0); gr.add_node(1); gr.add_node(2); gr.add_node(3); gr.add_edge(n(3), n(2), ()); gr.add_edge(n(3), n(1), ()); gr.add_edge(n(2), n(0), ()); gr.add_edge(n(1), n(0), ()); assert_sccs_eq( petgraph::algo::kosaraju_scc(&gr), vec![vec![n(0)], vec![n(1)], vec![n(2)], vec![n(3)]], true, ); // Kosaraju bug from PR #60 let mut gr = Graph::<(), ()>::new(); gr.extend_with_edges(&[(0, 0), (1, 0), (2, 0), (2, 1), (2, 2)]); gr.add_node(()); // no order for the disconnected one assert_sccs_eq( petgraph::algo::kosaraju_scc(&gr), vec![vec![n(0)], vec![n(1)], vec![n(2)], vec![n(3)]], false, ); } #[test] fn tarjan_scc() { let gr: Graph<(), ()> = Graph::from_edges(&[ (6, 0), (0, 3), (3, 6), (8, 6), (8, 2), (2, 5), (5, 8), (7, 5), (1, 7), (7, 4), (4, 1), ]); let mut tarjan_scc = petgraph::algo::TarjanScc::new(); let mut result = Vec::new(); tarjan_scc.run(&gr, |scc| result.push(scc.iter().rev().cloned().collect())); assert_sccs_eq( result, vec![ vec![n(0), n(3), n(6)], vec![n(2), n(5), n(8)], vec![n(1), n(4), n(7)], ], true, ); // Test an undirected graph just for fun. // Sccs are just connected components. let mut hr = gr.into_edge_type::(); // Delete an edge to disconnect it let ed = hr.find_edge(n(6), n(8)).unwrap(); assert!(hr.remove_edge(ed).is_some()); let mut result = Vec::new(); tarjan_scc.run(&hr, |scc| result.push(scc.iter().rev().cloned().collect())); assert_sccs_eq( result, vec![ vec![n(1), n(2), n(4), n(5), n(7), n(8)], vec![n(0), n(3), n(6)], ], false, ); // acyclic non-tree, #14 let n = NodeIndex::new; let mut gr = Graph::new(); gr.add_node(0); gr.add_node(1); gr.add_node(2); gr.add_node(3); gr.add_edge(n(3), n(2), ()); gr.add_edge(n(3), n(1), ()); gr.add_edge(n(2), n(0), ()); gr.add_edge(n(1), n(0), ()); let mut result = Vec::new(); tarjan_scc.run(&gr, |scc| result.push(scc.iter().rev().cloned().collect())); assert_sccs_eq( result, vec![vec![n(0)], vec![n(1)], vec![n(2)], vec![n(3)]], true, ); // Kosaraju bug from PR #60 let mut gr = Graph::<(), ()>::new(); gr.extend_with_edges(&[(0, 0), (1, 0), (2, 0), (2, 1), (2, 2)]); gr.add_node(()); // no order for the disconnected one let mut result = Vec::new(); tarjan_scc.run(&gr, |scc| result.push(scc.iter().rev().cloned().collect())); assert_sccs_eq( result, vec![vec![n(0)], vec![n(1)], vec![n(2)], vec![n(3)]], false, ); } #[test] fn condensation() { let gr: Graph<(), ()> = Graph::from_edges(&[ (6, 0), (0, 3), (3, 6), (8, 6), (8, 2), (2, 3), (2, 5), (5, 8), (7, 5), (1, 7), (7, 4), (4, 1), ]); // make_acyclic = true let cond = petgraph::algo::condensation(gr.clone(), true); assert!(cond.node_count() == 3); assert!(cond.edge_count() == 2); assert!( !petgraph::algo::is_cyclic_directed(&cond), "Assertion failed: {:?} acyclic", cond ); // make_acyclic = false let cond = petgraph::algo::condensation(gr.clone(), false); assert!(cond.node_count() == 3); assert!(cond.edge_count() == gr.edge_count()); } #[test] fn connected_comp() { let n = NodeIndex::new; let mut gr = Graph::new(); gr.add_node(0); gr.add_node(1); gr.add_node(2); gr.add_node(3); gr.add_node(4); gr.add_node(5); gr.add_node(6); gr.add_node(7); gr.add_node(8); gr.add_edge(n(6), n(0), ()); gr.add_edge(n(0), n(3), ()); gr.add_edge(n(3), n(6), ()); gr.add_edge(n(8), n(6), ()); gr.add_edge(n(8), n(2), ()); gr.add_edge(n(2), n(5), ()); gr.add_edge(n(5), n(8), ()); gr.add_edge(n(7), n(5), ()); gr.add_edge(n(1), n(7), ()); gr.add_edge(n(7), n(4), ()); gr.add_edge(n(4), n(1), ()); assert_eq!(petgraph::algo::connected_components(&gr), 1); gr.add_node(9); gr.add_node(10); assert_eq!(petgraph::algo::connected_components(&gr), 3); gr.add_edge(n(9), n(10), ()); assert_eq!(petgraph::algo::connected_components(&gr), 2); let gr = gr.into_edge_type::(); assert_eq!(petgraph::algo::connected_components(&gr), 2); } #[should_panic] #[test] fn oob_index() { let mut gr = Graph::<_, ()>::new(); let a = gr.add_node(0); let b = gr.add_node(1); gr.remove_node(a); gr[b]; } #[test] fn usize_index() { let mut gr = Graph::<_, _, Directed, usize>::with_capacity(0, 0); let a = gr.add_node(0); let b = gr.add_node(1); let e = gr.add_edge(a, b, 1.2); let mut dfs = Dfs::new(&gr, a); while let Some(nx) = dfs.next(&gr) { gr[nx] += 1; } assert_eq!(gr[a], 1); assert_eq!(gr[b], 2); assert_eq!(gr[e], 1.2); } #[test] fn u8_index() { let mut gr = Graph::<_, (), Undirected, u8>::with_capacity(0, 0); for _ in 0..255 { gr.add_node(()); } } #[should_panic] #[test] fn u8_index_overflow() { let mut gr = Graph::<_, (), Undirected, u8>::with_capacity(0, 0); for _ in 0..256 { gr.add_node(()); } } #[should_panic] #[test] fn u8_index_overflow_edges() { let mut gr = Graph::<_, (), Undirected, u8>::with_capacity(0, 0); let a = gr.add_node('a'); let b = gr.add_node('b'); for _ in 0..256 { gr.add_edge(a, b, ()); } } #[test] fn test_weight_iterators() { let mut gr = Graph::<_, _>::new(); let a = gr.add_node("A"); let b = gr.add_node("B"); let c = gr.add_node("C"); let d = gr.add_node("D"); let e = gr.add_node("E"); let f = gr.add_node("F"); let g = gr.add_node("G"); gr.add_edge(a, b, 7.0); gr.add_edge(a, d, 5.); gr.add_edge(d, b, 9.); gr.add_edge(b, c, 8.); gr.add_edge(b, e, 7.); gr.add_edge(c, e, 5.); gr.add_edge(d, e, 15.); gr.add_edge(d, f, 6.); gr.add_edge(f, e, 8.); gr.add_edge(f, g, 11.); gr.add_edge(e, g, 9.); assert_eq!(gr.node_weights_mut().count(), gr.node_count()); assert_eq!(gr.edge_weights_mut().count(), gr.edge_count()); // add a disjoint part let h = gr.add_node("H"); let i = gr.add_node("I"); let j = gr.add_node("J"); gr.add_edge(h, i, 1.); gr.add_edge(h, j, 3.); gr.add_edge(i, j, 1.); assert_eq!(gr.node_weights_mut().count(), gr.node_count()); assert_eq!(gr.edge_weights_mut().count(), gr.edge_count()); for nw in gr.node_weights_mut() { *nw = "x"; } for node in gr.raw_nodes() { assert_eq!(node.weight, "x"); } let old = gr.clone(); for (index, ew) in gr.edge_weights_mut().enumerate() { assert_eq!(old[EdgeIndex::new(index)], *ew); *ew = -*ew; } for (index, edge) in gr.raw_edges().iter().enumerate() { assert_eq!(edge.weight, -1. * old[EdgeIndex::new(index)]); } } #[test] fn walk_edges() { let mut gr = Graph::<_, _>::new(); let a = gr.add_node(0.); let b = gr.add_node(1.); let c = gr.add_node(2.); let d = gr.add_node(3.); let e0 = gr.add_edge(a, b, 0.); let e1 = gr.add_edge(a, d, 0.); let e2 = gr.add_edge(b, c, 0.); let e3 = gr.add_edge(c, a, 0.); // Set edge weights to difference: target - source. let mut dfs = Dfs::new(&gr, a); while let Some(source) = dfs.next(&gr) { let mut edges = gr.neighbors_directed(source, Outgoing).detach(); while let Some((edge, target)) = edges.next(&gr) { gr[edge] = gr[target] - gr[source]; } } assert_eq!(gr[e0], 1.); assert_eq!(gr[e1], 3.); assert_eq!(gr[e2], 1.); assert_eq!(gr[e3], -2.); let mut nedges = 0; let mut dfs = Dfs::new(&gr, a); while let Some(node) = dfs.next(&gr) { let mut edges = gr.neighbors_directed(node, Incoming).detach(); while let Some((edge, source)) = edges.next(&gr) { assert_eq!(gr.find_edge(source, node), Some(edge)); nedges += 1; } let mut edges = gr.neighbors_directed(node, Outgoing).detach(); while let Some((edge, target)) = edges.next(&gr) { assert_eq!(gr.find_edge(node, target), Some(edge)); nedges += 1; } } assert_eq!(nedges, 8); } #[test] fn index_twice_mut() { let mut gr = Graph::<_, _>::new(); let a = gr.add_node(0.); let b = gr.add_node(0.); let c = gr.add_node(0.); let d = gr.add_node(0.); let e = gr.add_node(0.); let f = gr.add_node(0.); let g = gr.add_node(0.); gr.add_edge(a, b, 7.0); gr.add_edge(a, d, 5.); gr.add_edge(d, b, 9.); gr.add_edge(b, c, 8.); gr.add_edge(b, e, 7.); gr.add_edge(c, e, 5.); gr.add_edge(d, e, 15.); gr.add_edge(d, f, 6.); gr.add_edge(f, e, 8.); gr.add_edge(f, g, 11.); gr.add_edge(e, g, 9.); for dir in &[Incoming, Outgoing] { for nw in gr.node_weights_mut() { *nw = 0.; } // walk the graph and sum incoming edges let mut dfs = Dfs::new(&gr, a); while let Some(node) = dfs.next(&gr) { let mut edges = gr.neighbors_directed(node, *dir).detach(); while let Some(edge) = edges.next_edge(&gr) { let (nw, ew) = gr.index_twice_mut(node, edge); *nw += *ew; } } // check the sums for i in 0..gr.node_count() { let ni = NodeIndex::new(i); let s = gr .edges_directed(ni, *dir) .map(|e| *e.weight()) .fold(0., |a, b| a + b); assert_eq!(s, gr[ni]); } println!("Sum {:?}: {:?}", dir, gr); } } fn make_edge_iterator_graph() -> Graph { let mut gr = Graph::default(); let a = gr.add_node(0.); let b = gr.add_node(0.); let c = gr.add_node(0.); let d = gr.add_node(0.); let e = gr.add_node(0.); let f = gr.add_node(0.); let g = gr.add_node(0.); gr.add_edge(a, b, 7.0); gr.add_edge(a, d, 5.); gr.add_edge(d, b, 9.); gr.add_edge(b, c, 8.); gr.add_edge(b, e, 7.); gr.add_edge(c, c, 8.); gr.add_edge(c, e, 5.); gr.add_edge(d, e, 15.); gr.add_edge(d, f, 6.); gr.add_edge(f, e, 8.); gr.add_edge(f, g, 11.); gr.add_edge(e, g, 9.); gr } #[test] fn test_edge_iterators_directed() { let gr = make_edge_iterator_graph::(); for i in gr.node_indices() { itertools::assert_equal(gr.edges_directed(i, Outgoing), gr.edges(i)); // Reversed reverses edges, so target and source need to be reversed once more. itertools::assert_equal( gr.edges_directed(i, Outgoing) .map(|edge| (edge.source(), edge.target())), Reversed(&gr) .edges_directed(i, Incoming) .map(|edge| (edge.target(), edge.source())), ); for edge in gr.edges_directed(i, Outgoing) { assert_eq!( edge.source(), i, "outgoing edges should have a fixed source" ); } for edge in Reversed(&gr).edges_directed(i, Incoming) { assert_eq!( edge.target(), i, "reversed incoming edges should have a fixed target" ); } } let mut reversed_gr = gr.clone(); reversed_gr.reverse(); println!("{:#?}", gr); for i in gr.node_indices() { // Compare against reversed graphs two different ways: using .reverse() and Reversed. itertools::assert_equal(gr.edges_directed(i, Incoming), reversed_gr.edges(i)); // Reversed reverses edges, so target and source need to be reversed once more. itertools::assert_equal( gr.edges_directed(i, Incoming) .map(|edge| (edge.source(), edge.target())), Reversed(&gr) .edges(i) .map(|edge| (edge.target(), edge.source())), ); for edge in gr.edges_directed(i, Incoming) { assert_eq!( edge.target(), i, "incoming edges should have a fixed target" ); } for edge in Reversed(&gr).edges_directed(i, Outgoing) { assert_eq!( edge.source(), i, "reversed outgoing edges should have a fixed source" ); } } } #[test] fn test_edge_iterators_undir() { let gr = make_edge_iterator_graph::(); for i in gr.node_indices() { itertools::assert_equal(gr.edges_directed(i, Outgoing), gr.edges(i)); // Reversed reverses edges, so target and source need to be reversed once more. itertools::assert_equal( gr.edges_directed(i, Outgoing) .map(|edge| (edge.source(), edge.target())), Reversed(&gr) .edges_directed(i, Incoming) .map(|edge| (edge.target(), edge.source())), ); for edge in gr.edges_directed(i, Outgoing) { assert_eq!( edge.source(), i, "outgoing edges should have a fixed source" ); } for edge in Reversed(&gr).edges_directed(i, Incoming) { assert_eq!( edge.target(), i, "reversed incoming edges should have a fixed target" ); } } for i in gr.node_indices() { itertools::assert_equal(gr.edges_directed(i, Incoming), gr.edges(i)); // Reversed reverses edges, so target and source need to be reversed once more. itertools::assert_equal( gr.edges_directed(i, Incoming) .map(|edge| (edge.source(), edge.target())), Reversed(&gr) .edges(i) .map(|edge| (edge.target(), edge.source())), ); for edge in gr.edges_directed(i, Incoming) { assert_eq!( edge.target(), i, "incoming edges should have a fixed target" ); } for edge in Reversed(&gr).edges_directed(i, Outgoing) { assert_eq!( edge.source(), i, "reversed outgoing edges should have a fixed source" ); } } } #[test] fn toposort_generic() { // This is a DAG, visit it in order let mut gr = Graph::<_, _>::new(); let b = gr.add_node(("B", 0.)); let a = gr.add_node(("A", 0.)); let c = gr.add_node(("C", 0.)); let d = gr.add_node(("D", 0.)); let e = gr.add_node(("E", 0.)); let f = gr.add_node(("F", 0.)); let g = gr.add_node(("G", 0.)); gr.add_edge(a, b, 7.0); gr.add_edge(a, d, 5.); gr.add_edge(d, b, 9.); gr.add_edge(b, c, 8.); gr.add_edge(b, e, 7.); gr.add_edge(c, e, 5.); gr.add_edge(d, e, 15.); gr.add_edge(d, f, 6.); gr.add_edge(f, e, 8.); gr.add_edge(f, g, 11.); gr.add_edge(e, g, 9.); assert!(!pg::algo::is_cyclic_directed(&gr)); let mut index = 0.; let mut topo = Topo::new(&gr); while let Some(nx) = topo.next(&gr) { gr[nx].1 = index; index += 1.; } let mut order = Vec::new(); index = 0.; let mut topo = Topo::new(&gr); while let Some(nx) = topo.next(&gr) { order.push(nx); assert_eq!(gr[nx].1, index); index += 1.; } println!("{:?}", gr); assert_is_topo_order(&gr, &order); { order.clear(); let mut topo = Topo::new(&gr); while let Some(nx) = topo.next(&gr) { order.push(nx); } println!("{:?}", gr); assert_is_topo_order(&gr, &order); } let mut gr2 = gr.clone(); gr.add_edge(e, d, -1.); assert!(pg::algo::is_cyclic_directed(&gr)); assert!(pg::algo::toposort(&gr, None).is_err()); gr2.add_edge(d, d, 0.); assert!(pg::algo::is_cyclic_directed(&gr2)); assert!(pg::algo::toposort(&gr2, None).is_err()); } #[test] fn test_has_path() { // This is a DAG, visit it in order let mut gr = Graph::<_, _>::new(); let b = gr.add_node(("B", 0.)); let a = gr.add_node(("A", 0.)); let c = gr.add_node(("C", 0.)); let d = gr.add_node(("D", 0.)); let e = gr.add_node(("E", 0.)); let f = gr.add_node(("F", 0.)); let g = gr.add_node(("G", 0.)); gr.add_edge(a, b, 7.0); gr.add_edge(a, d, 5.); gr.add_edge(d, b, 9.); gr.add_edge(b, c, 8.); gr.add_edge(b, e, 7.); gr.add_edge(c, e, 5.); gr.add_edge(d, e, 15.); gr.add_edge(d, f, 6.); gr.add_edge(f, e, 8.); gr.add_edge(f, g, 11.); gr.add_edge(e, g, 9.); // disconnected island let h = gr.add_node(("H", 0.)); let i = gr.add_node(("I", 0.)); gr.add_edge(h, i, 2.); gr.add_edge(i, h, -2.); let mut state = DfsSpace::default(); gr.add_edge(b, a, 99.); assert!(has_path_connecting(&gr, c, c, None)); for edge in gr.edge_references() { assert!(has_path_connecting(&gr, edge.source(), edge.target(), None)); } assert!(has_path_connecting(&gr, a, g, Some(&mut state))); assert!(!has_path_connecting(&gr, a, h, Some(&mut state))); assert!(has_path_connecting(&gr, a, c, None)); assert!(has_path_connecting(&gr, a, c, Some(&mut state))); assert!(!has_path_connecting(&gr, h, a, Some(&mut state))); } #[test] fn map_filter_map() { let mut g = Graph::new_undirected(); let a = g.add_node("A"); let b = g.add_node("B"); let c = g.add_node("C"); let d = g.add_node("D"); let e = g.add_node("E"); let f = g.add_node("F"); g.add_edge(a, b, 7); g.add_edge(c, a, 9); g.add_edge(a, d, 14); g.add_edge(b, c, 10); g.add_edge(d, c, 2); g.add_edge(d, e, 9); g.add_edge(b, f, 15); g.add_edge(c, f, 11); g.add_edge(e, f, 6); println!("{:?}", g); let g2 = g.filter_map( |_, name| Some(*name), |_, &weight| if weight >= 10 { Some(weight) } else { None }, ); assert_eq!(g2.edge_count(), 4); for edge in g2.raw_edges() { assert!(edge.weight >= 10); } let g3 = g.filter_map( |i, &name| if i == a || i == e { None } else { Some(name) }, |i, &weight| { let (source, target) = g.edge_endpoints(i).unwrap(); // don't map edges from a removed node assert!(source != a); assert!(target != a); assert!(source != e); assert!(target != e); Some(weight) }, ); assert_eq!(g3.node_count(), g.node_count() - 2); assert_eq!(g3.edge_count(), g.edge_count() - 5); assert_graph_consistent(&g3); let mut g4 = g.clone(); g4.retain_edges(|gr, i| { let (s, t) = gr.edge_endpoints(i).unwrap(); !(s == a || s == e || t == a || t == e) }); assert_eq!(g4.edge_count(), g.edge_count() - 5); assert_graph_consistent(&g4); } #[test] fn from_edges() { let n = NodeIndex::new; let gr = Graph::<(), (), Undirected>::from_edges(&[(0, 1), (0, 2), (0, 3), (1, 2), (1, 3), (2, 3)]); assert_eq!(gr.node_count(), 4); assert_eq!(gr.edge_count(), 6); assert_eq!(gr.neighbors(n(0)).count(), 3); assert_eq!(gr.neighbors(n(1)).count(), 3); assert_eq!(gr.neighbors(n(2)).count(), 3); assert_eq!(gr.neighbors(n(3)).count(), 3); assert_graph_consistent(&gr); } #[test] fn retain() { let mut gr = Graph::::from_edges(&[ (0, 1, 2), (1, 1, 1), (0, 2, 0), (1, 2, 3), (2, 3, 3), ]); gr.retain_edges(|mut gr, i| { if gr[i] <= 0 { false } else { gr[i] -= 1; let (s, t) = gr.edge_endpoints(i).unwrap(); gr[s] += 1; gr[t] += 1; gr[i] > 0 } }); assert_eq!(gr.edge_count(), 3); assert_eq!(gr[n(0)], 1); assert_eq!(gr[n(1)], 4); assert_eq!(gr[n(2)], 2); assert_eq!(gr[n(3)], 1); assert!(gr.find_edge(n(1), n(1)).is_none()); assert!(gr.find_edge(n(0), n(2)).is_none()); assert_graph_consistent(&gr); } fn assert_graph_consistent(g: &Graph) where Ty: EdgeType, Ix: IndexType, { assert_eq!(g.node_count(), g.node_indices().count()); assert_eq!(g.edge_count(), g.edge_indices().count()); for edge in g.raw_edges() { assert!( g.find_edge(edge.source(), edge.target()).is_some(), "Edge not in graph! {:?} to {:?}", edge.source(), edge.target() ); } } #[test] fn neighbors_selfloops() { // Directed graph let mut gr = Graph::<_, ()>::new(); let a = gr.add_node("a"); let b = gr.add_node("b"); let c = gr.add_node("c"); gr.extend_with_edges(&[(a, a), (a, b), (c, a), (a, a)]); let out_edges = [a, a, b]; let in_edges = [a, a, c]; let undir_edges = [a, a, b, c]; let mut seen_out = gr.neighbors(a).collect::>(); seen_out.sort(); assert_eq!(&seen_out, &out_edges); let mut seen_in = gr.neighbors_directed(a, Incoming).collect::>(); seen_in.sort(); assert_eq!(&seen_in, &in_edges); let mut seen_undir = gr.neighbors_undirected(a).collect::>(); seen_undir.sort(); assert_eq!(&seen_undir, &undir_edges); let mut seen_out = gr.edges(a).map(|e| e.target()).collect::>(); seen_out.sort(); assert_eq!(&seen_out, &out_edges); let mut seen_walk = Vec::new(); let mut walk = gr.neighbors(a).detach(); while let Some(n) = walk.next_node(&gr) { seen_walk.push(n); } seen_walk.sort(); assert_eq!(&seen_walk, &out_edges); seen_walk.clear(); let mut walk = gr.neighbors_directed(a, Incoming).detach(); while let Some(n) = walk.next_node(&gr) { seen_walk.push(n); } seen_walk.sort(); assert_eq!(&seen_walk, &in_edges); seen_walk.clear(); let mut walk = gr.neighbors_undirected(a).detach(); while let Some(n) = walk.next_node(&gr) { seen_walk.push(n); } seen_walk.sort(); assert_eq!(&seen_walk, &undir_edges); // Undirected graph let mut gr: Graph<_, (), _> = Graph::new_undirected(); let a = gr.add_node("a"); let b = gr.add_node("b"); let c = gr.add_node("c"); gr.extend_with_edges(&[(a, a), (a, b), (c, a)]); let out_edges = [a, b, c]; let in_edges = [a, b, c]; let undir_edges = [a, b, c]; let mut seen_out = gr.neighbors(a).collect::>(); seen_out.sort(); assert_eq!(&seen_out, &out_edges); let mut seen_out = gr.edges(a).map(|e| e.target()).collect::>(); seen_out.sort(); assert_eq!(&seen_out, &out_edges); let mut seen_in = gr.neighbors_directed(a, Incoming).collect::>(); seen_in.sort(); assert_eq!(&seen_in, &in_edges); let mut seen_undir = gr.neighbors_undirected(a).collect::>(); seen_undir.sort(); assert_eq!(&seen_undir, &undir_edges); } fn degree<'a, G>(g: G, node: G::NodeId) -> usize where G: IntoNeighbors, G::NodeId: PartialEq, { // self loops count twice let original_node = node.clone(); let mut degree = 0; for v in g.neighbors(node) { degree += if v == original_node { 2 } else { 1 }; } degree } #[cfg(feature = "graphmap")] #[test] fn degree_sequence() { let mut gr = Graph::::from_edges(&[ (0, 1), (1, 2), (1, 3), (2, 4), (3, 4), (4, 4), (4, 5), (3, 5), ]); gr.add_node(0); // add isolated node let mut degree_sequence = gr .node_indices() .map(|i| degree(&gr, i)) .collect::>(); degree_sequence.sort_by(|x, y| Ord::cmp(y, x)); assert_eq!(°ree_sequence, &[5, 3, 3, 2, 2, 1, 0]); let mut gr = GraphMap::<_, (), Undirected>::from_edges(&[ (0, 1), (1, 2), (1, 3), (2, 4), (3, 4), (4, 4), (4, 5), (3, 5), ]); gr.add_node(6); // add isolated node let mut degree_sequence = gr.nodes().map(|i| degree(&gr, i)).collect::>(); degree_sequence.sort_by(|x, y| Ord::cmp(y, x)); assert_eq!(°ree_sequence, &[5, 3, 3, 2, 2, 1, 0]); } #[test] fn neighbor_order() { let mut gr = Graph::new(); let a = gr.add_node("a"); let b = gr.add_node("b"); let c = gr.add_node("c"); gr.add_edge(a, b, 0); gr.add_edge(a, a, 1); gr.add_edge(c, a, 2); gr.add_edge(a, c, 3); gr.add_edge(c, a, 4); gr.add_edge(b, a, 5); // neighbors (edges) are in lifo order, if it's a directed graph assert_eq!(gr.neighbors(a).collect::>(), vec![c, a, b]); assert_eq!( gr.neighbors_directed(a, Incoming).collect::>(), vec![b, c, c, a] ); } #[test] fn dot() { // test alternate formatting #[derive(Debug)] struct Record { a: i32, b: &'static str, }; let mut gr = Graph::new(); let a = gr.add_node(Record { a: 1, b: r"abc\" }); gr.add_edge(a, a, (1, 2)); let dot_output = format!("{:?}", Dot::new(&gr)); assert_eq!( dot_output, // The single \ turns into four \\\\ because of Debug which turns it to \\ and then escaping each \ to \\. r#"digraph { 0 [ label = "Record { a: 1, b: \"abc\\\\\" }" ] 0 -> 0 [ label = "(1, 2)" ] } "# ); } #[test] fn filtered() { let mut g = Graph::new(); let a = g.add_node("A"); let b = g.add_node("B"); let c = g.add_node("C"); let d = g.add_node("D"); let e = g.add_node("E"); let f = g.add_node("F"); g.add_edge(a, b, 7); g.add_edge(c, a, 9); g.add_edge(a, d, 14); g.add_edge(b, c, 10); g.add_edge(d, c, 2); g.add_edge(d, e, 9); g.add_edge(b, f, 15); g.add_edge(c, f, 11); g.add_edge(e, f, 6); println!("{:?}", g); let filt = NodeFiltered(&g, |n: NodeIndex| n != c && n != e); let mut dfs = DfsPostOrder::new(&filt, a); let mut po = Vec::new(); while let Some(nx) = dfs.next(&filt) { println!("Next: {:?}", nx); po.push(nx); } assert_eq!(set(po), set(g.node_identifiers().filter(|n| (filt.1)(*n)))); } #[test] fn filtered_edge_reverse() { use petgraph::visit::EdgeFiltered; #[derive(Eq, PartialEq)] enum E { A, B, } // Start with single node graph with loop let mut g = Graph::new(); let a = g.add_node("A"); g.add_edge(a, a, E::A); let ef_a = EdgeFiltered::from_fn(&g, |edge| *edge.weight() == E::A); let mut po = Vec::new(); let mut dfs = Dfs::new(&ef_a, a); while let Some(next_n_ix) = dfs.next(&ef_a) { po.push(next_n_ix); } assert_eq!(set(po), set(vec![a])); // Check in reverse let mut po = Vec::new(); let mut dfs = Dfs::new(&Reversed(&ef_a), a); while let Some(next_n_ix) = dfs.next(&Reversed(&ef_a)) { po.push(next_n_ix); } assert_eq!(set(po), set(vec![a])); let mut g = Graph::new(); let a = g.add_node("A"); let b = g.add_node("B"); let c = g.add_node("C"); let d = g.add_node("D"); let e = g.add_node("E"); let f = g.add_node("F"); let h = g.add_node("H"); let i = g.add_node("I"); let j = g.add_node("J"); g.add_edge(a, b, E::A); g.add_edge(b, c, E::A); g.add_edge(c, d, E::B); g.add_edge(d, e, E::A); g.add_edge(e, f, E::A); g.add_edge(e, h, E::A); g.add_edge(e, i, E::A); g.add_edge(i, j, E::A); let ef_a = EdgeFiltered::from_fn(&g, |edge| *edge.weight() == E::A); let ef_b = EdgeFiltered::from_fn(&g, |edge| *edge.weight() == E::B); // DFS down from a, filtered by E::A. let mut po = Vec::new(); let mut dfs = Dfs::new(&ef_a, a); while let Some(next_n_ix) = dfs.next(&ef_a) { po.push(next_n_ix); } assert_eq!(set(po), set(vec![a, b, c])); // Reversed DFS from f, filtered by E::A. let mut dfs = Dfs::new(&Reversed(&ef_a), f); let mut po = Vec::new(); while let Some(next_n_ix) = dfs.next(&Reversed(&ef_a)) { po.push(next_n_ix); } assert_eq!(set(po), set(vec![d, e, f])); // Reversed DFS from j, filtered by E::A. let mut dfs = Dfs::new(&Reversed(&ef_a), j); let mut po = Vec::new(); while let Some(next_n_ix) = dfs.next(&Reversed(&ef_a)) { po.push(next_n_ix); } assert_eq!(set(po), set(vec![d, e, i, j])); // Reversed DFS from c, filtered by E::A. let mut dfs = Dfs::new(&Reversed(&ef_a), c); let mut po = Vec::new(); while let Some(next_n_ix) = dfs.next(&Reversed(&ef_a)) { po.push(next_n_ix); } assert_eq!(set(po), set(vec![a, b, c])); // Reversed DFS from c, filtered by E::B. let mut dfs = Dfs::new(&Reversed(&ef_b), c); let mut po = Vec::new(); while let Some(next_n_ix) = dfs.next(&Reversed(&ef_b)) { po.push(next_n_ix); } assert_eq!(set(po), set(vec![c])); // Reversed DFS from d, filtered by E::B. let mut dfs = Dfs::new(&Reversed(&ef_b), d); let mut po = Vec::new(); while let Some(next_n_ix) = dfs.next(&Reversed(&ef_b)) { po.push(next_n_ix); } assert_eq!(set(po), set(vec![c, d])); // Now let's test the same graph but undirected let mut g = Graph::new_undirected(); let a = g.add_node("A"); let b = g.add_node("B"); let c = g.add_node("C"); let d = g.add_node("D"); let e = g.add_node("E"); let f = g.add_node("F"); let h = g.add_node("H"); let i = g.add_node("I"); let j = g.add_node("J"); g.add_edge(a, b, E::A); g.add_edge(b, c, E::A); g.add_edge(c, d, E::B); g.add_edge(d, e, E::A); g.add_edge(e, f, E::A); g.add_edge(e, h, E::A); g.add_edge(e, i, E::A); g.add_edge(i, j, E::A); let ef_a = EdgeFiltered::from_fn(&g, |edge| *edge.weight() == E::A); let ef_b = EdgeFiltered::from_fn(&g, |edge| *edge.weight() == E::B); let mut po = Vec::new(); let mut dfs = Dfs::new(&Reversed(&ef_b), d); while let Some(next_n_ix) = dfs.next(&Reversed(&ef_b)) { po.push(next_n_ix); } assert_eq!(set(po), set(vec![c, d])); let mut po = Vec::new(); let mut dfs = Dfs::new(&Reversed(&ef_a), h); while let Some(next_n_ix) = dfs.next(&Reversed(&ef_a)) { po.push(next_n_ix); } assert_eq!(set(po), set(vec![d, e, f, h, i, j])); } #[test] fn dfs_visit() { use petgraph::visit::Control; use petgraph::visit::DfsEvent::*; use petgraph::visit::{depth_first_search, Time}; use petgraph::visit::{VisitMap, Visitable}; let gr: Graph<(), ()> = Graph::from_edges(&[ (0, 5), (0, 2), (0, 3), (0, 1), (1, 3), (2, 3), (2, 4), (4, 0), (4, 5), ]); let invalid_time = Time(!0); let mut discover_time = vec![invalid_time; gr.node_count()]; let mut finish_time = vec![invalid_time; gr.node_count()]; let mut has_tree_edge = gr.visit_map(); let mut edges = HashSet::new(); depth_first_search(&gr, Some(n(0)), |evt| { println!("Event: {:?}", evt); match evt { Discover(n, t) => discover_time[n.index()] = t, Finish(n, t) => finish_time[n.index()] = t, TreeEdge(u, v) => { // v is an ancestor of u assert!(has_tree_edge.visit(v), "Two tree edges to {:?}!", v); assert!(discover_time[v.index()] == invalid_time); assert!(discover_time[u.index()] != invalid_time); assert!(finish_time[u.index()] == invalid_time); edges.insert((u, v)); } BackEdge(u, v) => { // u is an ancestor of v assert!(discover_time[v.index()] != invalid_time); assert!(finish_time[v.index()] == invalid_time); edges.insert((u, v)); } CrossForwardEdge(u, v) => { edges.insert((u, v)); } } }); assert!(discover_time.iter().all(|x| *x != invalid_time)); assert!(finish_time.iter().all(|x| *x != invalid_time)); assert_eq!(edges.len(), gr.edge_count()); assert_eq!( edges, set(gr.edge_references().map(|e| (e.source(), e.target()))) ); println!("{:?}", discover_time); println!("{:?}", finish_time); // find path from 0 to 4 let mut predecessor = vec![NodeIndex::end(); gr.node_count()]; let start = n(0); let goal = n(4); let ret = depth_first_search(&gr, Some(start), |event| { if let TreeEdge(u, v) = event { predecessor[v.index()] = u; if v == goal { return Control::Break(u); } } Control::Continue }); // assert we did terminate early assert!(ret.break_value().is_some()); assert!(predecessor.iter().any(|x| *x == NodeIndex::end())); let mut next = goal; let mut path = vec![next]; while next != start { let pred = predecessor[next.index()]; path.push(pred); next = pred; } path.reverse(); assert_eq!(&path, &[n(0), n(2), n(4)]); // check that if we prune 2, we never see 4. let start = n(0); let prune = n(2); let nongoal = n(4); let ret = depth_first_search(&gr, Some(start), |event| { if let Discover(n, _) = event { if n == prune { return Control::Prune; } } else if let TreeEdge(u, v) = event { if v == nongoal { return Control::Break(u); } } Control::Continue }); assert!(ret.break_value().is_none()); } #[test] fn filtered_post_order() { use petgraph::visit::NodeFiltered; let mut gr: Graph<(), ()> = Graph::from_edges(&[(0, 2), (1, 2), (0, 3), (1, 4), (2, 4), (4, 5), (3, 5)]); // map reachable nodes let mut dfs = Dfs::new(&gr, n(0)); while let Some(_) = dfs.next(&gr) {} let map = dfs.discovered; gr.add_edge(n(0), n(1), ()); let mut po = Vec::new(); let mut dfs = DfsPostOrder::new(&gr, n(0)); let f = NodeFiltered(&gr, map); while let Some(n) = dfs.next(&f) { po.push(n); } assert!(!po.contains(&n(1))); } #[test] fn filter_elements() { use petgraph::data::Element::{Edge, Node}; use petgraph::data::ElementIterator; use petgraph::data::FromElements; let elements = vec![ Node { weight: "A" }, Node { weight: "B" }, Node { weight: "C" }, Node { weight: "D" }, Node { weight: "E" }, Node { weight: "F" }, Edge { source: 0, target: 1, weight: 7, }, Edge { source: 2, target: 0, weight: 9, }, Edge { source: 0, target: 3, weight: 14, }, Edge { source: 1, target: 2, weight: 10, }, Edge { source: 3, target: 2, weight: 2, }, Edge { source: 3, target: 4, weight: 9, }, Edge { source: 1, target: 5, weight: 15, }, Edge { source: 2, target: 5, weight: 11, }, Edge { source: 4, target: 5, weight: 6, }, ]; let mut g = DiGraph::<_, _>::from_elements(elements.iter().cloned()); println!("{:#?}", g); assert!(g.contains_edge(n(1), n(5))); let g2 = DiGraph::<_, _>::from_elements(elements.iter().cloned().filter_elements(|elt| match elt { Node { ref weight } if **weight == "B" => false, _ => true, })); println!("{:#?}", g2); g.remove_node(n(1)); assert!(is_isomorphic_matching( &g, &g2, PartialEq::eq, PartialEq::eq )); } #[test] fn test_edge_filtered() { use petgraph::algo::connected_components; use petgraph::visit::EdgeFiltered; use petgraph::visit::IntoEdgeReferences; let gr = UnGraph::<(), _>::from_edges(&[ // cycle (0, 1, 7), (1, 2, 9), (2, 1, 14), // cycle (3, 4, 10), (4, 5, 2), (5, 3, 9), // cross edges (0, 3, -1), (1, 4, -2), (2, 5, -3), ]); assert_eq!(connected_components(&gr), 1); let positive_edges = EdgeFiltered::from_fn(&gr, |edge| *edge.weight() >= 0); assert_eq!(positive_edges.edge_references().count(), 6); assert!(positive_edges .edge_references() .all(|edge| *edge.weight() >= 0)); assert_eq!(connected_components(&positive_edges), 2); let mut dfs = DfsPostOrder::new(&positive_edges, n(0)); while let Some(_) = dfs.next(&positive_edges) {} let n = n::; for node in &[n(0), n(1), n(2)] { assert!(dfs.discovered.is_visited(node)); } for node in &[n(3), n(4), n(5)] { assert!(!dfs.discovered.is_visited(node)); } } #[test] fn test_dominators_simple_fast() { // Construct the following graph: // // .-----. // | <--------------------------------. // .--------+--------------| r |--------------. | // | | | | | | // | | '-----' | | // | .--V--. .--V--. | // | | | | | | // | | b | | c |--------. | // | | | | | | | // | '-----' '-----' | | // .--V--. | | .--V--. | // | | | | | | | // | a <-----+ | .----| g | | // | | | .----' | | | | // '-----' | | | '-----' | // | | | | | | // .--V--. | .-----. .--V--. | | | // | | | | | | | | | | // | d <-----+----> e <----. | f | | | | // | | | | | | | | | | // '-----' '-----' | '-----' | | | // | .-----. | | | | .--V--. | // | | | | | | .-' | | | // '-----> l | | | | | | j | | // | | '--. | | | | | | // '-----' | | | | '-----' | // | .--V--. | | .--V--. | | // | | | | | | | | | // '-------> h |-' '---> i <------' | // | | .---------> | | // '-----' | '-----' | // | .-----. | | // | | | | | // '----------> k <---------' | // | | | // '-----' | // | | // '----------------------------' // // This graph has the following dominator tree: // // r // |-- a // |-- b // |-- c // | |-- f // | `-- g // | `-- j // |-- d // | `-- l // |-- e // |-- i // |-- k // `-- h // // This graph and dominator tree are taken from figures 1 and 2 of "A Fast // Algorithm for Finding Dominators in a Flowgraph" by Lengauer et al: // http://www.cs.princeton.edu/courses/archive/spr03/cs423/download/dominators.pdf. let mut graph = DiGraph::<_, _>::new(); let r = graph.add_node("r"); let a = graph.add_node("a"); let b = graph.add_node("b"); let c = graph.add_node("c"); let d = graph.add_node("d"); let e = graph.add_node("e"); let f = graph.add_node("f"); let g = graph.add_node("g"); let h = graph.add_node("h"); let i = graph.add_node("i"); let j = graph.add_node("j"); let k = graph.add_node("k"); let l = graph.add_node("l"); graph.add_edge(r, a, ()); graph.add_edge(r, b, ()); graph.add_edge(r, c, ()); graph.add_edge(a, d, ()); graph.add_edge(b, a, ()); graph.add_edge(b, d, ()); graph.add_edge(b, e, ()); graph.add_edge(c, f, ()); graph.add_edge(c, g, ()); graph.add_edge(d, l, ()); graph.add_edge(e, h, ()); graph.add_edge(f, i, ()); graph.add_edge(g, i, ()); graph.add_edge(g, j, ()); graph.add_edge(h, e, ()); graph.add_edge(h, k, ()); graph.add_edge(i, k, ()); graph.add_edge(j, i, ()); graph.add_edge(k, r, ()); graph.add_edge(k, i, ()); graph.add_edge(l, h, ()); let doms = dominators::simple_fast(&graph, r); assert_eq!(doms.root(), r); assert_eq!( doms.immediate_dominator(r), None, "The root node has no idom" ); assert_eq!( doms.immediate_dominator(a), Some(r), "r is the immediate dominator of a" ); assert_eq!( doms.immediate_dominator(b), Some(r), "r is the immediate dominator of b" ); assert_eq!( doms.immediate_dominator(c), Some(r), "r is the immediate dominator of c" ); assert_eq!( doms.immediate_dominator(f), Some(c), "c is the immediate dominator of f" ); assert_eq!( doms.immediate_dominator(g), Some(c), "c is the immediate dominator of g" ); assert_eq!( doms.immediate_dominator(j), Some(g), "g is the immediate dominator of j" ); assert_eq!( doms.immediate_dominator(d), Some(r), "r is the immediate dominator of d" ); assert_eq!( doms.immediate_dominator(l), Some(d), "d is the immediate dominator of l" ); assert_eq!( doms.immediate_dominator(e), Some(r), "r is the immediate dominator of e" ); assert_eq!( doms.immediate_dominator(i), Some(r), "r is the immediate dominator of i" ); assert_eq!( doms.immediate_dominator(k), Some(r), "r is the immediate dominator of k" ); assert_eq!( doms.immediate_dominator(h), Some(r), "r is the immediate dominator of h" ); let mut graph = graph.clone(); let z = graph.add_node("z"); let doms = dominators::simple_fast(&graph, r); assert_eq!( doms.immediate_dominator(z), None, "nodes that aren't reachable from the root do not have an idom" ); }