// Copyright ©2014 The Gonum Authors. All rights reserved. // Use of this source code is governed by a BSD-style // license that can be found in the LICENSE file. package simple_test import ( "math" "testing" "golang.org/x/exp/rand" "gonum.org/v1/gonum/graph" "gonum.org/v1/gonum/graph/internal/set" "gonum.org/v1/gonum/graph/simple" "gonum.org/v1/gonum/graph/testgraph" ) func weightedDirectedBuilder(nodes []graph.Node, edges []testgraph.WeightedLine, self, absent float64) (g graph.Graph, n []graph.Node, e []testgraph.Edge, s, a float64, ok bool) { seen := set.NewNodes() dg := simple.NewWeightedDirectedGraph(self, absent) for _, n := range nodes { seen.Add(n) dg.AddNode(n) } for _, edge := range edges { if edge.From().ID() == edge.To().ID() { continue } f := dg.Node(edge.From().ID()) if f == nil { f = edge.From() } t := dg.Node(edge.To().ID()) if t == nil { t = edge.To() } ce := simple.WeightedEdge{F: f, T: t, W: edge.Weight()} seen.Add(ce.F) seen.Add(ce.T) e = append(e, ce) dg.SetWeightedEdge(ce) } if len(e) == 0 && len(edges) != 0 { return nil, nil, nil, math.NaN(), math.NaN(), false } if len(seen) != 0 { n = make([]graph.Node, 0, len(seen)) } for _, sn := range seen { n = append(n, sn) } return dg, n, e, self, absent, true } func TestWeightedDirected(t *testing.T) { t.Run("EdgeExistence", func(t *testing.T) { testgraph.EdgeExistence(t, weightedDirectedBuilder, reversesEdges) }) t.Run("NodeExistence", func(t *testing.T) { testgraph.NodeExistence(t, weightedDirectedBuilder) }) t.Run("ReturnAdjacentNodes", func(t *testing.T) { testgraph.ReturnAdjacentNodes(t, weightedDirectedBuilder, usesEmpty, reversesEdges) }) t.Run("ReturnAllEdges", func(t *testing.T) { testgraph.ReturnAllEdges(t, weightedDirectedBuilder, usesEmpty) }) t.Run("ReturnAllNodes", func(t *testing.T) { testgraph.ReturnAllNodes(t, weightedDirectedBuilder, usesEmpty) }) t.Run("ReturnAllWeightedEdges", func(t *testing.T) { testgraph.ReturnAllWeightedEdges(t, weightedDirectedBuilder, usesEmpty) }) t.Run("ReturnEdgeSlice", func(t *testing.T) { testgraph.ReturnEdgeSlice(t, weightedDirectedBuilder, usesEmpty) }) t.Run("ReturnWeightedEdgeSlice", func(t *testing.T) { testgraph.ReturnWeightedEdgeSlice(t, weightedDirectedBuilder, usesEmpty) }) t.Run("ReturnNodeSlice", func(t *testing.T) { testgraph.ReturnNodeSlice(t, weightedDirectedBuilder, usesEmpty) }) t.Run("Weight", func(t *testing.T) { testgraph.Weight(t, weightedDirectedBuilder) }) t.Run("AddNodes", func(t *testing.T) { testgraph.AddNodes(t, simple.NewWeightedDirectedGraph(1, 0), 100) }) t.Run("AddArbitraryNodes", func(t *testing.T) { testgraph.AddArbitraryNodes(t, simple.NewWeightedDirectedGraph(1, 0), testgraph.NewRandomNodes(100, 1, func(id int64) graph.Node { return simple.Node(id) }), ) }) t.Run("RemoveNodes", func(t *testing.T) { g := simple.NewWeightedDirectedGraph(1, 0) it := testgraph.NewRandomNodes(100, 1, func(id int64) graph.Node { return simple.Node(id) }) for it.Next() { g.AddNode(it.Node()) } it.Reset() rnd := rand.New(rand.NewSource(1)) for it.Next() { u := it.Node() d := rnd.Intn(5) vit := g.Nodes() for d >= 0 && vit.Next() { v := vit.Node() if v.ID() == u.ID() { continue } d-- g.SetWeightedEdge(g.NewWeightedEdge(u, v, 1)) } } testgraph.RemoveNodes(t, g) }) t.Run("AddWeightedEdges", func(t *testing.T) { testgraph.AddWeightedEdges(t, 100, simple.NewWeightedDirectedGraph(1, 0), 0.5, func(id int64) graph.Node { return simple.Node(id) }, false, // Cannot set self-loops. true, // Can update nodes. ) }) t.Run("NoLoopAddWeightedEdges", func(t *testing.T) { testgraph.NoLoopAddWeightedEdges(t, 100, simple.NewWeightedDirectedGraph(1, 0), 0.5, func(id int64) graph.Node { return simple.Node(id) }, ) }) t.Run("RemoveEdges", func(t *testing.T) { g := simple.NewWeightedDirectedGraph(1, 0) it := testgraph.NewRandomNodes(100, 1, func(id int64) graph.Node { return simple.Node(id) }) for it.Next() { g.AddNode(it.Node()) } it.Reset() rnd := rand.New(rand.NewSource(1)) for it.Next() { u := it.Node() d := rnd.Intn(5) vit := g.Nodes() for d >= 0 && vit.Next() { v := vit.Node() if v.ID() == u.ID() { continue } d-- g.SetWeightedEdge(g.NewWeightedEdge(u, v, 1)) } } testgraph.RemoveEdges(t, g, g.Edges()) }) } // Tests Issue #27 func TestWeightedEdgeOvercounting(t *testing.T) { g := generateDummyWeightedGraph() if neigh := graph.NodesOf(g.From(int64(2))); len(neigh) != 2 { t.Errorf("Node 2 has incorrect number of neighbors got neighbors %v (count %d), expected 2 neighbors {0,1}", neigh, len(neigh)) } } func generateDummyWeightedGraph() *simple.WeightedDirectedGraph { nodes := [4]struct{ srcID, targetID int }{ {2, 1}, {1, 0}, {2, 0}, {0, 2}, } g := simple.NewWeightedDirectedGraph(0, math.Inf(1)) for _, n := range nodes { g.SetWeightedEdge(simple.WeightedEdge{F: simple.Node(n.srcID), T: simple.Node(n.targetID), W: 1}) } return g } // Test for issue #123 https://github.com/gonum/graph/issues/123 func TestIssue123WeightedDirectedGraph(t *testing.T) { defer func() { if r := recover(); r != nil { t.Errorf("unexpected panic: %v", r) } }() g := simple.NewWeightedDirectedGraph(0, math.Inf(1)) n0 := g.NewNode() g.AddNode(n0) n1 := g.NewNode() g.AddNode(n1) g.RemoveNode(n0.ID()) n2 := g.NewNode() g.AddNode(n2) }