func graph(t *testing.T) (*goiso.Graph, *goiso.SubGraph, *SubGraph, *Indices) {
Graph := goiso.NewGraph(10, 10)
G := &Graph
n1 := G.AddVertex(1, "black")
n2 := G.AddVertex(2, "black")
n3 := G.AddVertex(3, "red")
n4 := G.AddVertex(4, "red")
n5 := G.AddVertex(5, "red")
n6 := G.AddVertex(6, "red")
G.AddEdge(n1, n3, "")
G.AddEdge(n1, n4, "")
G.AddEdge(n2, n5, "")
G.AddEdge(n2, n6, "")
G.AddEdge(n5, n3, "")
G.AddEdge(n4, n6, "")
sg, _ := G.SubGraph([]int{n1.Idx, n2.Idx, n3.Idx, n4.Idx, n5.Idx, n6.Idx}, nil)
indices := &Indices{
G: G,
ColorIndex: make(map[int][]int),
SrcIndex: make(map[IdColorColor][]int),
TargIndex: make(map[IdColorColor][]int),
EdgeIndex: make(map[Edge]*goiso.Edge),
EdgeCounts: make(map[Colors]int),
}
indices.InitEdgeIndices(G)
indices.InitColorMap(G)
return G, sg, FromEmbedding(sg), indices
}
func LoadGraph(getInput func() (io.Reader, func()), supportAttr string, nodeAttrs *bptree.BpTree, supportAttrs map[int]string) (graph *goiso.Graph, err error) {
var errors ParseErrors
reader, closer := getInput()
G := goiso.NewGraph(graphSize(reader))
closer()
graph = &G
vids := hashtable.NewLinearHash() // int64 ==> *goiso.Vertex
reader, closer = getInput()
defer closer()
ProcessLines(reader, func(line []byte) {
if len(line) == 0 || !bytes.Contains(line, []byte("\t")) {
return
}
line_type, data := parseLine(line)
switch line_type {
case "vertex":
if err := LoadVertex(graph, supportAttr, vids, nodeAttrs, supportAttrs, data); err != nil {
errors = append(errors, err)
}
case "edge":
if err := LoadEdge(graph, vids, data); err != nil {
errors = append(errors, err)
}
default:
errors = append(errors, fmt.Errorf("Unknown line type %v", line_type))
return
}
})
if len(errors) == 0 {
return graph, nil
}
return graph, errors
}
func randomGraph(t testing.TB, V, E int, vlabels, elabels []string) (*Digraph, *goiso.Graph, *goiso.SubGraph, *subgraph.SubGraph, *EmbListNode) {
Graph := goiso.NewGraph(10, 10)
G := &Graph
vidxs := make([]int, 0, V)
vertices := make([]*goiso.Vertex, 0, V)
for i := 0; i < V; i++ {
v := G.AddVertex(i, vlabels[rand.Intn(len(vlabels))])
vertices = append(vertices, v)
vidxs = append(vidxs, v.Idx)
}
for i := 0; i < E; i++ {
src := rand.Intn(len(vertices))
targ := rand.Intn(len(vertices))
elabel := rand.Intn(len(elabels))
if !G.HasEdge(vertices[src], vertices[targ], elabels[elabel]) {
G.AddEdge(vertices[src], vertices[targ], elabels[elabel])
}
}
sg, _ := G.SubGraph(vidxs, nil)
// make config
conf := &config.Config{
Support: 2,
Parallelism: -1,
}
// make the *Digraph
dt, err := NewDigraph(conf, &Config{
MinEdges: 0,
MaxEdges: len(G.E),
MinVertices: 0,
MaxVertices: len(G.V),
Mode: Automorphs | Caching | ExtensionPruning | EmbeddingPruning | ExtFromFreqEdges,
EmbSearchStartPoint: subgraph.RandomStart,
})
if err != nil {
errors.Logf("ERROR", "%v", err)
t.Fatal(err)
}
err = dt.Init(G)
if err != nil {
t.Fatal(err)
}
f, err := os.Create("/tmp/random-graph.dot")
if err == nil {
fmt.Fprintf(f, "%v", G)
f.Close()
}
return dt, G, sg, subgraph.FromEmbedding(sg), RootEmbListNode(dt)
}
func graph(t *testing.T) (*Digraph, *goiso.Graph, *goiso.SubGraph, *subgraph.SubGraph, *EmbListNode) {
Graph := goiso.NewGraph(10, 10)
G := &Graph
n1 := G.AddVertex(1, "black")
n2 := G.AddVertex(2, "black")
n3 := G.AddVertex(3, "red")
n4 := G.AddVertex(4, "red")
n5 := G.AddVertex(5, "red")
n6 := G.AddVertex(6, "red")
G.AddEdge(n1, n3, "")
G.AddEdge(n1, n4, "")
G.AddEdge(n2, n5, "")
G.AddEdge(n2, n6, "")
G.AddEdge(n5, n3, "")
G.AddEdge(n4, n6, "")
sg, _ := G.SubGraph([]int{n1.Idx, n2.Idx, n3.Idx, n4.Idx, n5.Idx, n6.Idx}, nil)
// make config
conf := &config.Config{
Support: 2,
}
// make the *Digraph
dt, err := NewDigraph(conf, &Config{
MinEdges: 0,
MaxEdges: len(G.E),
MinVertices: 0,
MaxVertices: len(G.V),
Mode: Automorphs | ExtFromEmb,
EmbSearchStartPoint: subgraph.RandomStart,
})
if err != nil {
t.Fatal(err)
}
err = dt.Init(G)
if err != nil {
t.Fatal(err)
}
return dt, G, sg, subgraph.FromEmbedding(sg), RootEmbListNode(dt)
}
