lnd/autopilot/simple_graph_test.go

package autopilot

import (
	"testing"

	"github.com/stretchr/testify/require"
)

var (
	testShortestPathLengths = map[int]uint32{
		0: 0,
		1: 1,
		2: 1,
		3: 1,
		4: 2,
		5: 2,
		6: 3,
		7: 3,
		8: 4,
	}
	testNodeEccentricities = map[int]uint32{
		0: 4,
		1: 5,
		2: 4,
		3: 3,
		4: 3,
		5: 3,
		6: 4,
		7: 4,
		8: 5,
	}
)

// NewTestSimpleGraph is a helper that generates a SimpleGraph from a test
// graph description.
// Assumes that the graph description is internally consistent, i.e. edges are
// not repeatedly defined.
func NewTestSimpleGraph(graph testGraphDesc) SimpleGraph {
	// We convert the test graph description into an adjacency list.
	adjList := make([][]int, graph.nodes)
	for node, neighbors := range graph.edges {
		for _, neighbor := range neighbors {
			adjList[node] = append(adjList[node], neighbor)
			adjList[neighbor] = append(adjList[neighbor], node)
		}
	}

	return SimpleGraph{Adj: adjList}
}

func TestShortestPathLengths(t *testing.T) {
	simpleGraph := NewTestSimpleGraph(centralityTestGraph)

	// Test the shortest path lengths from node 0 to all other nodes.
	shortestPathLengths := simpleGraph.shortestPathLengths(0)
	require.Equal(t, shortestPathLengths, testShortestPathLengths)
}

func TestEccentricities(t *testing.T) {
	simpleGraph := NewTestSimpleGraph(centralityTestGraph)

	// Test the node eccentricities for all nodes.
	nodes := make([]int, len(simpleGraph.Adj))
	for a := range nodes {
		nodes[a] = a
	}
	nodeEccentricities := simpleGraph.nodeEccentricities(nodes)
	require.Equal(t, nodeEccentricities, testNodeEccentricities)
}

func TestDiameterExact(t *testing.T) {
	simpleGraph := NewTestSimpleGraph(centralityTestGraph)

	// Test the diameter in a brute-force manner.
	diameter := simpleGraph.Diameter()
	require.Equal(t, uint32(5), diameter)
}

func TestDiameterCutoff(t *testing.T) {
	simpleGraph := NewTestSimpleGraph(centralityTestGraph)

	// Test the diameter by cutting out the inside of the graph.
	diameter := simpleGraph.DiameterRadialCutoff()
	require.Equal(t, uint32(5), diameter)
}

func BenchmarkShortestPathOpt(b *testing.B) {
	// TODO: a method that generates a huge graph is needed
	simpleGraph := NewTestSimpleGraph(centralityTestGraph)

	for n := 0; n < b.N; n++ {
		_ = simpleGraph.shortestPathLengths(0)
	}
}
lnrpc+autopilot: add graph diameter calculation * adds a brute force computation of the diameter * adds a more efficient calculation of the diameter 2021-12-22 11:03:03 +01:00			`package autopilot`

			`import (`
			`"testing"`

			`"github.com/stretchr/testify/require"`
			`)`

			`var (`
			`testShortestPathLengths = map[int]uint32{`
			`0: 0,`
			`1: 1,`
			`2: 1,`
			`3: 1,`
			`4: 2,`
			`5: 2,`
			`6: 3,`
			`7: 3,`
			`8: 4,`
			`}`
			`testNodeEccentricities = map[int]uint32{`
			`0: 4,`
			`1: 5,`
			`2: 4,`
			`3: 3,`
			`4: 3,`
			`5: 3,`
			`6: 4,`
			`7: 4,`
			`8: 5,`
			`}`
			`)`

			`// NewTestSimpleGraph is a helper that generates a SimpleGraph from a test`
			`// graph description.`
			`// Assumes that the graph description is internally consistent, i.e. edges are`
			`// not repeatedly defined.`
			`func NewTestSimpleGraph(graph testGraphDesc) SimpleGraph {`
			`// We convert the test graph description into an adjacency list.`
			`adjList := make([][]int, graph.nodes)`
			`for node, neighbors := range graph.edges {`
			`for _, neighbor := range neighbors {`
			`adjList[node] = append(adjList[node], neighbor)`
			`adjList[neighbor] = append(adjList[neighbor], node)`
			`}`
			`}`

			`return SimpleGraph{Adj: adjList}`
			`}`

			`func TestShortestPathLengths(t *testing.T) {`
			`simpleGraph := NewTestSimpleGraph(centralityTestGraph)`

			`// Test the shortest path lengths from node 0 to all other nodes.`
			`shortestPathLengths := simpleGraph.shortestPathLengths(0)`
			`require.Equal(t, shortestPathLengths, testShortestPathLengths)`
			`}`

			`func TestEccentricities(t *testing.T) {`
			`simpleGraph := NewTestSimpleGraph(centralityTestGraph)`

			`// Test the node eccentricities for all nodes.`
			`nodes := make([]int, len(simpleGraph.Adj))`
			`for a := range nodes {`
			`nodes[a] = a`
			`}`
			`nodeEccentricities := simpleGraph.nodeEccentricities(nodes)`
			`require.Equal(t, nodeEccentricities, testNodeEccentricities)`
			`}`

			`func TestDiameterExact(t *testing.T) {`
			`simpleGraph := NewTestSimpleGraph(centralityTestGraph)`

			`// Test the diameter in a brute-force manner.`
			`diameter := simpleGraph.Diameter()`
			`require.Equal(t, uint32(5), diameter)`
			`}`

			`func TestDiameterCutoff(t *testing.T) {`
			`simpleGraph := NewTestSimpleGraph(centralityTestGraph)`

			`// Test the diameter by cutting out the inside of the graph.`
			`diameter := simpleGraph.DiameterRadialCutoff()`
			`require.Equal(t, uint32(5), diameter)`
			`}`

			`func BenchmarkShortestPathOpt(b *testing.B) {`
			`// TODO: a method that generates a huge graph is needed`
			`simpleGraph := NewTestSimpleGraph(centralityTestGraph)`

			`for n := 0; n < b.N; n++ {`
			`_ = simpleGraph.shortestPathLengths(0)`
			`}`
			`}`