tests/stable_graph.rs - third_party/github.com/petgraph/petgraph - Git at Google

 #![cfg(feature = "stable_graph")]

 extern crate itertools;
 extern crate petgraph;
 #[macro_use]
 extern crate defmac;

 use itertools::assert_equal;
 use petgraph::algo::{kosaraju_scc, min_spanning_tree, tarjan_scc};
 use petgraph::dot::Dot;
 use petgraph::prelude::*;
 use petgraph::stable_graph::node_index as n;
 use petgraph::visit::{IntoEdgeReferences, IntoNodeReferences, NodeIndexable};
 use petgraph::EdgeType;

 #[test]
 fn node_indices() {
     let mut g = StableGraph::<_, ()>::new();
     let a = g.add_node(0);
     let b = g.add_node(1);
     let c = g.add_node(2);
     g.remove_node(b);
     let mut iter = g.node_indices();
     assert_eq!(iter.next(), Some(a));
     assert_eq!(iter.next(), Some(c));
     assert_eq!(iter.next(), None);
 }

 #[test]
 fn node_bound() {
     let mut g = StableGraph::<_, ()>::new();
     assert_eq!(g.node_bound(), g.node_count());
     for i in 0..10 {
         g.add_node(i);
         assert_eq!(g.node_bound(), g.node_count());
     }
     let full_count = g.node_count();
     g.remove_node(n(0));
     g.remove_node(n(2));
     assert_eq!(g.node_bound(), full_count);
     g.clear();
     assert_eq!(g.node_bound(), 0);
 }

 #[test]
 fn clear_edges() {
     let mut gr = scc_graph();
     gr.remove_node(n(1));
     gr.clear_edges();
     // check that we use the free list for the vacancies
     assert_eq!(gr.add_node(()), n(1));
     assert_eq!(gr.add_node(()), n(4));
     assert!(gr.edge_references().next().is_none());
     assert!(gr.node_indices().all(|i| gr.neighbors(i).next().is_none()));
 }

 fn assert_sccs_eq(mut res: Vec<Vec<NodeIndex>>, normalized: Vec<Vec<NodeIndex>>) {
     // normalize the result and compare with the answer.
     for scc in &mut res {
         scc.sort();
     }
     // sort by minimum element
     res.sort_by(|v, w| v[0].cmp(&w[0]));
     assert_eq!(res, normalized);
 }

 fn scc_graph() -> StableGraph<(), ()> {
     let mut gr: StableGraph<(), ()> = StableGraph::from_edges(&[
         (6, 0),
         (0, 3),
         (3, 6),
         (8, 6),
         (8, 2),
         (2, 5),
         (5, 8),
         (7, 5),
         (1, 7),
         (7, 4),
         (4, 1),
     ]);
     // make an identical replacement of n(4) and leave a hole
     let x = gr.add_node(());
     gr.add_edge(n(7), x, ());
     gr.add_edge(x, n(1), ());
     gr.remove_node(n(4));
     gr
 }

 #[test]
 fn test_scc() {
     let gr = scc_graph();
     println!("{:?}", gr);

     let x = n(gr.node_bound() - 1);
     assert_sccs_eq(
         kosaraju_scc(&gr),
         vec![
             vec![n(0), n(3), n(6)],
             vec![n(1), n(7), x],
             vec![n(2), n(5), n(8)],
         ],
     );
 }

 #[test]
 fn test_tarjan_scc() {
     let gr = scc_graph();

     let x = n(gr.node_bound() - 1);
     assert_sccs_eq(
         tarjan_scc(&gr),
         vec![
             vec![n(0), n(3), n(6)],
             vec![n(1), n(7), x],
             vec![n(2), n(5), n(8)],
         ],
     );
 }

 fn make_graph<Ty>() -> StableGraph<(), i32, Ty>
 where
     Ty: EdgeType,
 {
     let mut gr = StableGraph::default();
     let mut c = 0..;
     let mut e = || -> i32 { c.next().unwrap() };
     gr.extend_with_edges(&[
         (6, 0, e()),
         (0, 3, e()),
         (3, 6, e()),
         (8, 6, e()),
         (8, 2, e()),
         (2, 5, e()),
         (5, 8, e()),
         (7, 5, e()),
         (1, 7, e()),
         (7, 4, e()),
         (8, 6, e()), // parallel edge
         (4, 1, e()),
     ]);
     // make an identical replacement of n(4) and leave a hole
     let x = gr.add_node(());
     gr.add_edge(n(7), x, e());
     gr.add_edge(x, n(1), e());
     gr.add_edge(x, x, e()); // make two self loops
     let rm_self_loop = gr.add_edge(x, x, e());
     gr.add_edge(x, x, e());
     gr.remove_node(n(4));
     gr.remove_node(n(6));
     gr.remove_edge(rm_self_loop);
     gr
 }

 defmac!(edges ref gr, x => gr.edges(x).map(|r| (r.target(), *r.weight())));

 #[test]
 fn test_edges_directed() {
     let gr = make_graph::<Directed>();
     let x = n(9);
     assert_equal(edges!(gr, x), vec![(x, 16), (x, 14), (n(1), 13)]);
     assert_equal(edges!(gr, n(0)), vec![(n(3), 1)]);
     assert_equal(edges!(gr, n(4)), vec![]);
 }

 #[test]
 fn test_edge_references() {
     let gr = make_graph::<Directed>();
     assert_eq!(gr.edge_count(), gr.edge_references().count());
 }

 #[test]
 fn test_edges_undirected() {
     let gr = make_graph::<Undirected>();
     let x = n(9);
     assert_equal(
         edges!(gr, x),
         vec![(x, 16), (x, 14), (n(1), 13), (n(7), 12)],
     );
     assert_equal(edges!(gr, n(0)), vec![(n(3), 1)]);
     assert_equal(edges!(gr, n(4)), vec![]);
 }

 #[test]
 fn test_edge_iterators_directed() {
     let gr = make_graph::<Directed>();
     for i in gr.node_indices() {
         itertools::assert_equal(gr.edges_directed(i, Outgoing), gr.edges(i));
         for edge in gr.edges_directed(i, Outgoing) {
             assert_eq!(
                 edge.source(),
                 i,
                 "outgoing edges should have a fixed source"
             );
         }
     }
     let mut incoming = vec![Vec::new(); gr.node_bound()];

     for i in gr.node_indices() {
         for j in gr.neighbors(i) {
             incoming[j.index()].push(i);
         }
     }

     println!("{:#?}", gr);
     for i in gr.node_indices() {
         itertools::assert_equal(
             gr.edges_directed(i, Incoming).map(|e| e.source()),
             incoming[i.index()].iter().rev().cloned(),
         );
         for edge in gr.edges_directed(i, Incoming) {
             assert_eq!(
                 edge.target(),
                 i,
                 "incoming edges should have a fixed target"
             );
         }
     }
 }

 #[test]
 fn test_edge_iterators_undir() {
     let gr = make_graph::<Undirected>();
     for i in gr.node_indices() {
         itertools::assert_equal(gr.edges_directed(i, Outgoing), gr.edges(i));
         for edge in gr.edges_directed(i, Outgoing) {
             assert_eq!(
                 edge.source(),
                 i,
                 "outgoing edges should have a fixed source"
             );
         }
     }
     for i in gr.node_indices() {
         itertools::assert_equal(gr.edges_directed(i, Incoming), gr.edges(i));
         for edge in gr.edges_directed(i, Incoming) {
             assert_eq!(
                 edge.target(),
                 i,
                 "incoming edges should have a fixed target"
             );
         }
     }
 }

 #[test]
 #[should_panic(expected = "is not a node")]
 fn add_edge_vacant() {
     let mut g = StableGraph::<_, _>::new();
     let a = g.add_node(0);
     let b = g.add_node(1);
     let _ = g.add_node(2);
     let _ = g.remove_node(b);
     g.add_edge(a, b, 1);
 }

 #[test]
 #[should_panic(expected = "is not a node")]
 fn add_edge_oob() {
     let mut g = StableGraph::<_, _>::new();
     let a = g.add_node(0);
     let _ = g.add_node(1);
     let _ = g.add_node(2);
     g.add_edge(a, n(4), 1);
 }

 #[test]
 fn test_node_references() {
     let gr = scc_graph();

     itertools::assert_equal(gr.node_references().map(|(i, _)| i), gr.node_indices());
 }

 #[test]
 fn iterators_undir() {
     let mut g = StableUnGraph::<_, _>::default();
     let a = g.add_node(0);
     let b = g.add_node(1);
     let c = g.add_node(2);
     let d = g.add_node(3);
     g.extend_with_edges(&[(a, b, 1), (a, c, 2), (b, c, 3), (c, c, 4), (a, d, 5)]);
     g.remove_node(b);

     itertools::assert_equal(g.neighbors(a), vec![d, c]);
     itertools::assert_equal(g.neighbors(c), vec![c, a]);
     itertools::assert_equal(g.neighbors(d), vec![a]);

     // the node that was removed
     itertools::assert_equal(g.neighbors(b), vec![]);

     // remove one more
     g.remove_node(c);
     itertools::assert_equal(g.neighbors(c), vec![]);
 }

 #[test]
 fn dot() {
     let mut gr = StableGraph::new();
     let a = gr.add_node("x");
     let b = gr.add_node("y");
     gr.add_edge(a, a, "10");
     gr.add_edge(a, b, "20");
     let dot_output = format!("{}", Dot::new(&gr));
     assert_eq!(
         dot_output,
         r#"digraph {
     0 [label="x"]
     1 [label="y"]
     0 -> 0 [label="10"]
     0 -> 1 [label="20"]
 }
 "#
     );
 }

 defmac!(iter_eq a, b => a.eq(b));
 defmac!(nodes_eq ref a, ref b => a.node_references().eq(b.node_references()));
 defmac!(edgew_eq ref a, ref b => a.edge_references().eq(b.edge_references()));
 defmac!(edges_eq ref a, ref b =>
         iter_eq!(
             a.edge_references().map(|e| (e.source(), e.target())),
             b.edge_references().map(|e| (e.source(), e.target()))));

 #[test]
 fn from() {
     let mut gr1 = StableGraph::new();
     let a = gr1.add_node(1);
     let b = gr1.add_node(2);
     let c = gr1.add_node(3);
     gr1.add_edge(a, a, 10);
     gr1.add_edge(a, b, 20);
     gr1.add_edge(b, c, 30);
     gr1.add_edge(a, c, 40);

     let gr2 = Graph::from(gr1.clone());
     let gr3 = StableGraph::from(gr2);
     assert!(nodes_eq!(gr1, gr3));
     assert!(edgew_eq!(gr1, gr3));
     assert!(edges_eq!(gr1, gr3));

     gr1.remove_node(b);

     let gr4 = Graph::from(gr1);
     let gr5 = StableGraph::from(gr4.clone());

     let mut ans = StableGraph::new();
     let a = ans.add_node(1);
     let c = ans.add_node(3);
     ans.add_edge(a, a, 10);
     ans.add_edge(a, c, 40);

     assert!(nodes_eq!(gr4, ans));
     assert!(edges_eq!(gr4, ans));

     assert!(nodes_eq!(gr5, ans));
     assert!(edgew_eq!(gr5, ans));
     assert!(edges_eq!(gr5, ans));
 }

 use petgraph::data::FromElements;
 use petgraph::stable_graph::StableGraph;

 #[test]
 fn from_min_spanning_tree() {
     let mut g = StableGraph::new();
     let mut nodes = Vec::new();
     for _ in 0..6 {
         nodes.push(g.add_node(()));
     }
     let es = [(4, 5), (3, 4), (3, 5)];
     for &(a, b) in es.iter() {
         g.add_edge(NodeIndex::new(a), NodeIndex::new(b), ());
     }
     for i in 0..3 {
         let _ = g.remove_node(nodes[i]);
     }
     let _ = StableGraph::<(), (), Undirected, usize>::from_elements(min_spanning_tree(&g));
 }
	#![cfg(feature = "stable_graph")]

	extern crate itertools;
	extern crate petgraph;
	#[macro_use]
	extern crate defmac;

	use itertools::assert_equal;
	use petgraph::algo::{kosaraju_scc, min_spanning_tree, tarjan_scc};
	use petgraph::dot::Dot;
	use petgraph::prelude::*;
	use petgraph::stable_graph::node_index as n;
	use petgraph::visit::{IntoEdgeReferences, IntoNodeReferences, NodeIndexable};
	use petgraph::EdgeType;

	#[test]
	fn node_indices() {
	let mut g = StableGraph::<_, ()>::new();
	let a = g.add_node(0);
	let b = g.add_node(1);
	let c = g.add_node(2);
	g.remove_node(b);
	let mut iter = g.node_indices();
	assert_eq!(iter.next(), Some(a));
	assert_eq!(iter.next(), Some(c));
	assert_eq!(iter.next(), None);
	}

	#[test]
	fn node_bound() {
	let mut g = StableGraph::<_, ()>::new();
	assert_eq!(g.node_bound(), g.node_count());
	for i in 0..10 {
	g.add_node(i);
	assert_eq!(g.node_bound(), g.node_count());
	}
	let full_count = g.node_count();
	g.remove_node(n(0));
	g.remove_node(n(2));
	assert_eq!(g.node_bound(), full_count);
	g.clear();
	assert_eq!(g.node_bound(), 0);
	}

	#[test]
	fn clear_edges() {
	let mut gr = scc_graph();
	gr.remove_node(n(1));
	gr.clear_edges();
	// check that we use the free list for the vacancies
	assert_eq!(gr.add_node(()), n(1));
	assert_eq!(gr.add_node(()), n(4));
	assert!(gr.edge_references().next().is_none());
	assert!(gr.node_indices().all(\|i\| gr.neighbors(i).next().is_none()));
	}

	fn assert_sccs_eq(mut res: Vec<Vec<NodeIndex>>, normalized: Vec<Vec<NodeIndex>>) {
	// normalize the result and compare with the answer.
	for scc in &mut res {
	scc.sort();
	}
	// sort by minimum element
	res.sort_by(\|v, w\| v[0].cmp(&w[0]));
	assert_eq!(res, normalized);
	}

	fn scc_graph() -> StableGraph<(), ()> {
	let mut gr: StableGraph<(), ()> = StableGraph::from_edges(&[
	(6, 0),
	(0, 3),
	(3, 6),
	(8, 6),
	(8, 2),
	(2, 5),
	(5, 8),
	(7, 5),
	(1, 7),
	(7, 4),
	(4, 1),
	]);
	// make an identical replacement of n(4) and leave a hole
	let x = gr.add_node(());
	gr.add_edge(n(7), x, ());
	gr.add_edge(x, n(1), ());
	gr.remove_node(n(4));
	gr
	}

	#[test]
	fn test_scc() {
	let gr = scc_graph();
	println!("{:?}", gr);

	let x = n(gr.node_bound() - 1);
	assert_sccs_eq(
	kosaraju_scc(&gr),
	vec![
	vec![n(0), n(3), n(6)],
	vec![n(1), n(7), x],
	vec![n(2), n(5), n(8)],
	],
	);
	}

	#[test]
	fn test_tarjan_scc() {
	let gr = scc_graph();

	let x = n(gr.node_bound() - 1);
	assert_sccs_eq(
	tarjan_scc(&gr),
	vec![
	vec![n(0), n(3), n(6)],
	vec![n(1), n(7), x],
	vec![n(2), n(5), n(8)],
	],
	);
	}

	fn make_graph<Ty>() -> StableGraph<(), i32, Ty>
	where
	Ty: EdgeType,
	{
	let mut gr = StableGraph::default();
	let mut c = 0..;
	let mut e = \|\| -> i32 { c.next().unwrap() };
	gr.extend_with_edges(&[
	(6, 0, e()),
	(0, 3, e()),
	(3, 6, e()),
	(8, 6, e()),
	(8, 2, e()),
	(2, 5, e()),
	(5, 8, e()),
	(7, 5, e()),
	(1, 7, e()),
	(7, 4, e()),
	(8, 6, e()), // parallel edge
	(4, 1, e()),
	]);
	// make an identical replacement of n(4) and leave a hole
	let x = gr.add_node(());
	gr.add_edge(n(7), x, e());
	gr.add_edge(x, n(1), e());
	gr.add_edge(x, x, e()); // make two self loops
	let rm_self_loop = gr.add_edge(x, x, e());
	gr.add_edge(x, x, e());
	gr.remove_node(n(4));
	gr.remove_node(n(6));
	gr.remove_edge(rm_self_loop);
	gr
	}

	defmac!(edges ref gr, x => gr.edges(x).map(\|r\| (r.target(), *r.weight())));

	#[test]
	fn test_edges_directed() {
	let gr = make_graph::<Directed>();
	let x = n(9);
	assert_equal(edges!(gr, x), vec![(x, 16), (x, 14), (n(1), 13)]);
	assert_equal(edges!(gr, n(0)), vec![(n(3), 1)]);
	assert_equal(edges!(gr, n(4)), vec![]);
	}

	#[test]
	fn test_edge_references() {
	let gr = make_graph::<Directed>();
	assert_eq!(gr.edge_count(), gr.edge_references().count());
	}

	#[test]
	fn test_edges_undirected() {
	let gr = make_graph::<Undirected>();
	let x = n(9);
	assert_equal(
	edges!(gr, x),
	vec![(x, 16), (x, 14), (n(1), 13), (n(7), 12)],
	);
	assert_equal(edges!(gr, n(0)), vec![(n(3), 1)]);
	assert_equal(edges!(gr, n(4)), vec![]);
	}

	#[test]
	fn test_edge_iterators_directed() {
	let gr = make_graph::<Directed>();
	for i in gr.node_indices() {
	itertools::assert_equal(gr.edges_directed(i, Outgoing), gr.edges(i));
	for edge in gr.edges_directed(i, Outgoing) {
	assert_eq!(
	edge.source(),
	i,
	"outgoing edges should have a fixed source"
	);
	}
	}
	let mut incoming = vec![Vec::new(); gr.node_bound()];

	for i in gr.node_indices() {
	for j in gr.neighbors(i) {
	incoming[j.index()].push(i);
	}
	}

	println!("{:#?}", gr);
	for i in gr.node_indices() {
	itertools::assert_equal(
	gr.edges_directed(i, Incoming).map(\|e\| e.source()),
	incoming[i.index()].iter().rev().cloned(),
	);
	for edge in gr.edges_directed(i, Incoming) {
	assert_eq!(
	edge.target(),
	i,
	"incoming edges should have a fixed target"
	);
	}
	}
	}

	#[test]
	fn test_edge_iterators_undir() {
	let gr = make_graph::<Undirected>();
	for i in gr.node_indices() {
	itertools::assert_equal(gr.edges_directed(i, Outgoing), gr.edges(i));
	for edge in gr.edges_directed(i, Outgoing) {
	assert_eq!(
	edge.source(),
	i,
	"outgoing edges should have a fixed source"
	);
	}
	}
	for i in gr.node_indices() {
	itertools::assert_equal(gr.edges_directed(i, Incoming), gr.edges(i));
	for edge in gr.edges_directed(i, Incoming) {
	assert_eq!(
	edge.target(),
	i,
	"incoming edges should have a fixed target"
	);
	}
	}
	}

	#[test]
	#[should_panic(expected = "is not a node")]
	fn add_edge_vacant() {
	let mut g = StableGraph::<_, _>::new();
	let a = g.add_node(0);
	let b = g.add_node(1);
	let _ = g.add_node(2);
	let _ = g.remove_node(b);
	g.add_edge(a, b, 1);
	}

	#[test]
	#[should_panic(expected = "is not a node")]
	fn add_edge_oob() {
	let mut g = StableGraph::<_, _>::new();
	let a = g.add_node(0);
	let _ = g.add_node(1);
	let _ = g.add_node(2);
	g.add_edge(a, n(4), 1);
	}

	#[test]
	fn test_node_references() {
	let gr = scc_graph();

	itertools::assert_equal(gr.node_references().map(\|(i, _)\| i), gr.node_indices());
	}

	#[test]
	fn iterators_undir() {
	let mut g = StableUnGraph::<_, _>::default();
	let a = g.add_node(0);
	let b = g.add_node(1);
	let c = g.add_node(2);
	let d = g.add_node(3);
	g.extend_with_edges(&[(a, b, 1), (a, c, 2), (b, c, 3), (c, c, 4), (a, d, 5)]);
	g.remove_node(b);

	itertools::assert_equal(g.neighbors(a), vec![d, c]);
	itertools::assert_equal(g.neighbors(c), vec![c, a]);
	itertools::assert_equal(g.neighbors(d), vec![a]);

	// the node that was removed
	itertools::assert_equal(g.neighbors(b), vec![]);

	// remove one more
	g.remove_node(c);
	itertools::assert_equal(g.neighbors(c), vec![]);
	}

	#[test]
	fn dot() {
	let mut gr = StableGraph::new();
	let a = gr.add_node("x");
	let b = gr.add_node("y");
	gr.add_edge(a, a, "10");
	gr.add_edge(a, b, "20");
	let dot_output = format!("{}", Dot::new(&gr));
	assert_eq!(
	dot_output,
	r#"digraph {
	0 [label="x"]
	1 [label="y"]
	0 -> 0 [label="10"]
	0 -> 1 [label="20"]
	}
	"#
	);
	}

	defmac!(iter_eq a, b => a.eq(b));
	defmac!(nodes_eq ref a, ref b => a.node_references().eq(b.node_references()));
	defmac!(edgew_eq ref a, ref b => a.edge_references().eq(b.edge_references()));
	defmac!(edges_eq ref a, ref b =>
	iter_eq!(
	a.edge_references().map(\|e\| (e.source(), e.target())),
	b.edge_references().map(\|e\| (e.source(), e.target()))));

	#[test]
	fn from() {
	let mut gr1 = StableGraph::new();
	let a = gr1.add_node(1);
	let b = gr1.add_node(2);
	let c = gr1.add_node(3);
	gr1.add_edge(a, a, 10);
	gr1.add_edge(a, b, 20);
	gr1.add_edge(b, c, 30);
	gr1.add_edge(a, c, 40);

	let gr2 = Graph::from(gr1.clone());
	let gr3 = StableGraph::from(gr2);
	assert!(nodes_eq!(gr1, gr3));
	assert!(edgew_eq!(gr1, gr3));
	assert!(edges_eq!(gr1, gr3));

	gr1.remove_node(b);

	let gr4 = Graph::from(gr1);
	let gr5 = StableGraph::from(gr4.clone());

	let mut ans = StableGraph::new();
	let a = ans.add_node(1);
	let c = ans.add_node(3);
	ans.add_edge(a, a, 10);
	ans.add_edge(a, c, 40);

	assert!(nodes_eq!(gr4, ans));
	assert!(edges_eq!(gr4, ans));

	assert!(nodes_eq!(gr5, ans));
	assert!(edgew_eq!(gr5, ans));
	assert!(edges_eq!(gr5, ans));
	}

	use petgraph::data::FromElements;
	use petgraph::stable_graph::StableGraph;

	#[test]
	fn from_min_spanning_tree() {
	let mut g = StableGraph::new();
	let mut nodes = Vec::new();
	for _ in 0..6 {
	nodes.push(g.add_node(()));
	}
	let es = [(4, 5), (3, 4), (3, 5)];
	for &(a, b) in es.iter() {
	g.add_edge(NodeIndex::new(a), NodeIndex::new(b), ());
	}
	for i in 0..3 {
	let _ = g.remove_node(nodes[i]);
	}
	let _ = StableGraph::<(), (), Undirected, usize>::from_elements(min_spanning_tree(&g));
	}