graph/undirect_test.go - third_party/github.com/gonum/gonum - Git at Google

 // Copyright ©2015 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 graph_test

 import (
 	"math"
 	"testing"

 	"gonum.org/v1/gonum/graph"
 	"gonum.org/v1/gonum/graph/iterator"
 	"gonum.org/v1/gonum/graph/simple"
 	"gonum.org/v1/gonum/mat"
 )

 type weightedDirectedBuilder interface {
 	graph.WeightedBuilder
 	graph.WeightedDirected
 }

 var weightedDirectedGraphs = []struct {
 	skipUnweighted bool

 	g      func() weightedDirectedBuilder
 	edges  []simple.WeightedEdge
 	absent float64
 	merge  func(x, y float64, xe, ye graph.Edge) float64

 	want mat.Matrix
 }{
 	{
 		g: func() weightedDirectedBuilder { return simple.NewWeightedDirectedGraph(0, 0) },
 		edges: []simple.WeightedEdge{
 			{F: simple.Node(0), T: simple.Node(1), W: 2},
 			{F: simple.Node(1), T: simple.Node(0), W: 1},
 			{F: simple.Node(1), T: simple.Node(2), W: 1},
 		},
 		want: mat.NewSymDense(3, []float64{
 			0, (1. + 2.) / 2., 0,
 			(1. + 2.) / 2., 0, 1. / 2.,
 			0, 1. / 2., 0,
 		}),
 	},
 	{
 		g: func() weightedDirectedBuilder { return simple.NewWeightedDirectedGraph(0, 0) },
 		edges: []simple.WeightedEdge{
 			{F: simple.Node(0), T: simple.Node(1), W: 2},
 			{F: simple.Node(1), T: simple.Node(0), W: 1},
 			{F: simple.Node(1), T: simple.Node(2), W: 1},
 		},
 		absent: 1,
 		merge:  func(x, y float64, _, _ graph.Edge) float64 { return math.Sqrt(x * y) },
 		want: mat.NewSymDense(3, []float64{
 			0, math.Sqrt(1 * 2), 0,
 			math.Sqrt(1 * 2), 0, math.Sqrt(1 * 1),
 			0, math.Sqrt(1 * 1), 0,
 		}),
 	},
 	{
 		skipUnweighted: true, // The min merge function cannot be used in the unweighted case.

 		g: func() weightedDirectedBuilder { return simple.NewWeightedDirectedGraph(0, 0) },
 		edges: []simple.WeightedEdge{
 			{F: simple.Node(0), T: simple.Node(1), W: 2},
 			{F: simple.Node(1), T: simple.Node(0), W: 1},
 			{F: simple.Node(1), T: simple.Node(2), W: 1},
 		},
 		merge: func(x, y float64, _, _ graph.Edge) float64 { return math.Min(x, y) },
 		want: mat.NewSymDense(3, []float64{
 			0, math.Min(1, 2), 0,
 			math.Min(1, 2), 0, math.Min(1, 0),
 			0, math.Min(1, 0), 0,
 		}),
 	},
 	{
 		g: func() weightedDirectedBuilder { return simple.NewWeightedDirectedGraph(0, 0) },
 		edges: []simple.WeightedEdge{
 			{F: simple.Node(0), T: simple.Node(1), W: 2},
 			{F: simple.Node(1), T: simple.Node(0), W: 1},
 			{F: simple.Node(1), T: simple.Node(2), W: 1},
 		},
 		merge: func(x, y float64, xe, ye graph.Edge) float64 {
 			if xe == nil {
 				return y
 			}
 			if ye == nil {
 				return x
 			}
 			return math.Min(x, y)
 		},
 		want: mat.NewSymDense(3, []float64{
 			0, math.Min(1, 2), 0,
 			math.Min(1, 2), 0, 1,
 			0, 1, 0,
 		}),
 	},
 	{
 		g: func() weightedDirectedBuilder { return simple.NewWeightedDirectedGraph(0, 0) },
 		edges: []simple.WeightedEdge{
 			{F: simple.Node(0), T: simple.Node(1), W: 2},
 			{F: simple.Node(1), T: simple.Node(0), W: 1},
 			{F: simple.Node(1), T: simple.Node(2), W: 1},
 		},
 		merge: func(x, y float64, _, _ graph.Edge) float64 { return math.Max(x, y) },
 		want: mat.NewSymDense(3, []float64{
 			0, math.Max(1, 2), 0,
 			math.Max(1, 2), 0, math.Max(1, 0),
 			0, math.Max(1, 0), 0,
 		}),
 	},
 }

 func TestUndirect(t *testing.T) {
 	for i, test := range weightedDirectedGraphs {
 		if test.skipUnweighted {
 			continue
 		}
 		g := test.g()
 		for _, e := range test.edges {
 			g.SetWeightedEdge(e)
 		}

 		src := graph.Undirect{G: g}
 		nodes := graph.NodesOf(src.Nodes())
 		dst := simple.NewUndirectedMatrixFrom(nodes, 0, 0, 0)
 		for _, u := range nodes {
 			for _, v := range graph.NodesOf(src.From(u.ID())) {
 				dst.SetEdge(src.Edge(u.ID(), v.ID()))
 			}
 		}

 		want := unit{test.want}
 		if !mat.Equal(dst.Matrix(), want) {
 			t.Errorf("unexpected result for case %d:\ngot:\n%.4v\nwant:\n%.4v", i,
 				mat.Formatted(dst.Matrix()),
 				mat.Formatted(want),
 			)
 		}
 	}
 }

 func TestUndirectWeighted(t *testing.T) {
 	for i, test := range weightedDirectedGraphs {
 		g := test.g()
 		for _, e := range test.edges {
 			g.SetWeightedEdge(e)
 		}

 		src := graph.UndirectWeighted{G: g, Absent: test.absent, Merge: test.merge}
 		nodes := graph.NodesOf(src.Nodes())
 		dst := simple.NewUndirectedMatrixFrom(nodes, 0, 0, 0)
 		for _, u := range nodes {
 			for _, v := range graph.NodesOf(src.From(u.ID())) {
 				dst.SetWeightedEdge(src.WeightedEdge(u.ID(), v.ID()))
 			}
 		}

 		if !mat.Equal(dst.Matrix(), test.want) {
 			t.Errorf("unexpected result for case %d:\ngot:\n%.4v\nwant:\n%.4v", i,
 				mat.Formatted(dst.Matrix()),
 				mat.Formatted(test.want),
 			)
 		}
 	}
 }

 type unit struct {
 	mat.Matrix
 }

 func (m unit) At(i, j int) float64 {
 	v := m.Matrix.At(i, j)
 	if v == 0 {
 		return 0
 	}
 	return 1
 }

 var nodeIteratorPairTests = []struct {
 	a, b graph.Nodes
 	len  int
 }{
 	{a: graph.Empty, b: graph.Empty, len: 0},
 	{a: iterator.NewOrderedNodes(nil), b: iterator.NewOrderedNodes(nil), len: 0},
 	{a: iterator.NewOrderedNodes([]graph.Node{simple.Node(0)}), b: graph.Empty, len: 1},
 	{a: graph.Empty, b: iterator.NewOrderedNodes([]graph.Node{simple.Node(0)}), len: 1},
 	{a: iterator.NewOrderedNodes([]graph.Node{simple.Node(0)}), b: iterator.NewOrderedNodes([]graph.Node{simple.Node(0)}), len: 1},
 	{a: iterator.NewOrderedNodes([]graph.Node{simple.Node(0)}), b: iterator.NewOrderedNodes([]graph.Node{simple.Node(1)}), len: 2},
 	{a: iterator.NewOrderedNodes([]graph.Node{simple.Node(0), simple.Node(1)}), b: iterator.NewOrderedNodes([]graph.Node{simple.Node(1)}), len: 2},
 	{a: iterator.NewOrderedNodes([]graph.Node{simple.Node(1)}), b: iterator.NewOrderedNodes([]graph.Node{simple.Node(0), simple.Node(1)}), len: 2},
 }

 func TestNodeIteratorPair(t *testing.T) {
 	for _, test := range nodeIteratorPairTests {
 		it := graph.NewNodeIteratorPair(test.a, test.b)
 		for i := 0; i < 2; i++ {
 			n := it.Len()
 			if n != test.len {
 				t.Errorf("unexpected length of iterator construction/reset: got:%d want:%d", n, test.len)
 			}
 			for it.Next() {
 				n--
 			}
 			if n != 0 {
 				t.Errorf("unexpected remaining nodes after iterator completion: got:%d want:0", n)
 			}
 			it.Reset()
 		}
 	}
 }
	// Copyright ©2015 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 graph_test

	import (
	"math"
	"testing"

	"gonum.org/v1/gonum/graph"
	"gonum.org/v1/gonum/graph/iterator"
	"gonum.org/v1/gonum/graph/simple"
	"gonum.org/v1/gonum/mat"
	)

	type weightedDirectedBuilder interface {
	graph.WeightedBuilder
	graph.WeightedDirected
	}

	var weightedDirectedGraphs = []struct {
	skipUnweighted bool

	g func() weightedDirectedBuilder
	edges []simple.WeightedEdge
	absent float64
	merge func(x, y float64, xe, ye graph.Edge) float64

	want mat.Matrix
	}{
	{
	g: func() weightedDirectedBuilder { return simple.NewWeightedDirectedGraph(0, 0) },
	edges: []simple.WeightedEdge{
	{F: simple.Node(0), T: simple.Node(1), W: 2},
	{F: simple.Node(1), T: simple.Node(0), W: 1},
	{F: simple.Node(1), T: simple.Node(2), W: 1},
	},
	want: mat.NewSymDense(3, []float64{
	0, (1. + 2.) / 2., 0,
	(1. + 2.) / 2., 0, 1. / 2.,
	0, 1. / 2., 0,
	}),
	},
	{
	g: func() weightedDirectedBuilder { return simple.NewWeightedDirectedGraph(0, 0) },
	edges: []simple.WeightedEdge{
	{F: simple.Node(0), T: simple.Node(1), W: 2},
	{F: simple.Node(1), T: simple.Node(0), W: 1},
	{F: simple.Node(1), T: simple.Node(2), W: 1},
	},
	absent: 1,
	merge: func(x, y float64, _, _ graph.Edge) float64 { return math.Sqrt(x * y) },
	want: mat.NewSymDense(3, []float64{
	0, math.Sqrt(1 * 2), 0,
	math.Sqrt(1 * 2), 0, math.Sqrt(1 * 1),
	0, math.Sqrt(1 * 1), 0,
	}),
	},
	{
	skipUnweighted: true, // The min merge function cannot be used in the unweighted case.

	g: func() weightedDirectedBuilder { return simple.NewWeightedDirectedGraph(0, 0) },
	edges: []simple.WeightedEdge{
	{F: simple.Node(0), T: simple.Node(1), W: 2},
	{F: simple.Node(1), T: simple.Node(0), W: 1},
	{F: simple.Node(1), T: simple.Node(2), W: 1},
	},
	merge: func(x, y float64, _, _ graph.Edge) float64 { return math.Min(x, y) },
	want: mat.NewSymDense(3, []float64{
	0, math.Min(1, 2), 0,
	math.Min(1, 2), 0, math.Min(1, 0),
	0, math.Min(1, 0), 0,
	}),
	},
	{
	g: func() weightedDirectedBuilder { return simple.NewWeightedDirectedGraph(0, 0) },
	edges: []simple.WeightedEdge{
	{F: simple.Node(0), T: simple.Node(1), W: 2},
	{F: simple.Node(1), T: simple.Node(0), W: 1},
	{F: simple.Node(1), T: simple.Node(2), W: 1},
	},
	merge: func(x, y float64, xe, ye graph.Edge) float64 {
	if xe == nil {
	return y
	}
	if ye == nil {
	return x
	}
	return math.Min(x, y)
	},
	want: mat.NewSymDense(3, []float64{
	0, math.Min(1, 2), 0,
	math.Min(1, 2), 0, 1,
	0, 1, 0,
	}),
	},
	{
	g: func() weightedDirectedBuilder { return simple.NewWeightedDirectedGraph(0, 0) },
	edges: []simple.WeightedEdge{
	{F: simple.Node(0), T: simple.Node(1), W: 2},
	{F: simple.Node(1), T: simple.Node(0), W: 1},
	{F: simple.Node(1), T: simple.Node(2), W: 1},
	},
	merge: func(x, y float64, _, _ graph.Edge) float64 { return math.Max(x, y) },
	want: mat.NewSymDense(3, []float64{
	0, math.Max(1, 2), 0,
	math.Max(1, 2), 0, math.Max(1, 0),
	0, math.Max(1, 0), 0,
	}),
	},
	}

	func TestUndirect(t *testing.T) {
	for i, test := range weightedDirectedGraphs {
	if test.skipUnweighted {
	continue
	}
	g := test.g()
	for _, e := range test.edges {
	g.SetWeightedEdge(e)
	}

	src := graph.Undirect{G: g}
	nodes := graph.NodesOf(src.Nodes())
	dst := simple.NewUndirectedMatrixFrom(nodes, 0, 0, 0)
	for _, u := range nodes {
	for _, v := range graph.NodesOf(src.From(u.ID())) {
	dst.SetEdge(src.Edge(u.ID(), v.ID()))
	}
	}

	want := unit{test.want}
	if !mat.Equal(dst.Matrix(), want) {
	t.Errorf("unexpected result for case %d:\ngot:\n%.4v\nwant:\n%.4v", i,
	mat.Formatted(dst.Matrix()),
	mat.Formatted(want),
	)
	}
	}
	}

	func TestUndirectWeighted(t *testing.T) {
	for i, test := range weightedDirectedGraphs {
	g := test.g()
	for _, e := range test.edges {
	g.SetWeightedEdge(e)
	}

	src := graph.UndirectWeighted{G: g, Absent: test.absent, Merge: test.merge}
	nodes := graph.NodesOf(src.Nodes())
	dst := simple.NewUndirectedMatrixFrom(nodes, 0, 0, 0)
	for _, u := range nodes {
	for _, v := range graph.NodesOf(src.From(u.ID())) {
	dst.SetWeightedEdge(src.WeightedEdge(u.ID(), v.ID()))
	}
	}

	if !mat.Equal(dst.Matrix(), test.want) {
	t.Errorf("unexpected result for case %d:\ngot:\n%.4v\nwant:\n%.4v", i,
	mat.Formatted(dst.Matrix()),
	mat.Formatted(test.want),
	)
	}
	}
	}

	type unit struct {
	mat.Matrix
	}

	func (m unit) At(i, j int) float64 {
	v := m.Matrix.At(i, j)
	if v == 0 {
	return 0
	}
	return 1
	}

	var nodeIteratorPairTests = []struct {
	a, b graph.Nodes
	len int
	}{
	{a: graph.Empty, b: graph.Empty, len: 0},
	{a: iterator.NewOrderedNodes(nil), b: iterator.NewOrderedNodes(nil), len: 0},
	{a: iterator.NewOrderedNodes([]graph.Node{simple.Node(0)}), b: graph.Empty, len: 1},
	{a: graph.Empty, b: iterator.NewOrderedNodes([]graph.Node{simple.Node(0)}), len: 1},
	{a: iterator.NewOrderedNodes([]graph.Node{simple.Node(0)}), b: iterator.NewOrderedNodes([]graph.Node{simple.Node(0)}), len: 1},
	{a: iterator.NewOrderedNodes([]graph.Node{simple.Node(0)}), b: iterator.NewOrderedNodes([]graph.Node{simple.Node(1)}), len: 2},
	{a: iterator.NewOrderedNodes([]graph.Node{simple.Node(0), simple.Node(1)}), b: iterator.NewOrderedNodes([]graph.Node{simple.Node(1)}), len: 2},
	{a: iterator.NewOrderedNodes([]graph.Node{simple.Node(1)}), b: iterator.NewOrderedNodes([]graph.Node{simple.Node(0), simple.Node(1)}), len: 2},
	}

	func TestNodeIteratorPair(t *testing.T) {
	for _, test := range nodeIteratorPairTests {
	it := graph.NewNodeIteratorPair(test.a, test.b)
	for i := 0; i < 2; i++ {
	n := it.Len()
	if n != test.len {
	t.Errorf("unexpected length of iterator construction/reset: got:%d want:%d", n, test.len)
	}
	for it.Next() {
	n--
	}
	if n != 0 {
	t.Errorf("unexpected remaining nodes after iterator completion: got:%d want:0", n)
	}
	it.Reset()
	}
	}
	}