smegmesh/pkg/dot/dot.go
Tim Beatham 02dfd73e08 81-seperate-synchronisation-into-independent
- Separated synchronisation calls into independent processes
- Commented code for submission
2024-01-04 13:10:08 +00:00

249 lines
5.7 KiB
Go

// Graph allows the definition of a DOT graph in golang
package graph
import (
"fmt"
"hash/fnv"
"strings"
"github.com/tim-beatham/smegmesh/pkg/lib"
)
type GraphType string
type Shape string
const (
GRAPH GraphType = "graph"
DIGRAPH GraphType = "digraph"
)
const (
CIRCLE Shape = "circle"
STAR Shape = "star"
HEXAGON Shape = "hexagon"
PARALLELOGRAM Shape = "parallelogram"
)
type Graph interface {
Dottable
GetType() GraphType
}
// Cluster: represents a subgraph in the graphs
type Cluster struct {
Type GraphType
Name string
Label string
nodes map[string]*Node
edges map[string]Edge
}
// RootGraph: Represents the top level graph
type RootGraph struct {
Type GraphType
Label string
nodes map[string]*Node
clusters map[string]*Cluster
edges map[string]Edge
}
// Node: represents a graphviz not
type Node struct {
Name string
Label string
Shape Shape
Size int
}
// Edge: represents an edge between adjacent nodes
type Edge interface {
Dottable
}
// DirectEdge: contains a directed edge between any two nodes
type DirectedEdge struct {
Name string
Label string
From string
To string
}
// UndirectedEdge: contains an undirected edge between any two
// nodes
type UndirectedEdge struct {
Name string
Label string
From string
To string
}
// Dottable means an implementer can convert the struct to DOT representation
type Dottable interface {
GetDOT() (string, error)
}
// PutNode: puts a node in the root graph
func (g *RootGraph) PutNode(name, label string, size int, shape Shape) error {
_, exists := g.nodes[name]
if exists {
// If exists no need to add the ndoe
return nil
}
g.nodes[name] = &Node{Name: name, Label: label, Size: size, Shape: shape}
return nil
}
// PutCluster: puts a cluster in the root graph
func (g *RootGraph) PutCluster(graph *Cluster) {
g.clusters[graph.Label] = graph
}
func writeContituents[D Dottable](result *strings.Builder, elements ...D) error {
for _, node := range elements {
dot, err := node.GetDOT()
if err != nil {
return err
}
_, err = result.WriteString(dot)
if err != nil {
return err
}
}
return nil
}
// GetDOT: convert the root graph into dot format
func (g *RootGraph) GetDOT() (string, error) {
var result strings.Builder
result.WriteString(fmt.Sprintf("%s {\n", g.Type))
result.WriteString("node [colorscheme=set312];\n")
result.WriteString("layout = fdp;\n")
nodes := lib.MapValues(g.nodes)
edges := lib.MapValues(g.edges)
writeContituents(&result, nodes...)
writeContituents(&result, edges...)
for _, cluster := range g.clusters {
clusterDOT, err := cluster.GetDOT()
if err != nil {
return "", err
}
result.WriteString(clusterDOT)
}
result.WriteString("}")
return result.String(), nil
}
// GetType: get the graph type. DIRECTED|UNDIRECTED
func (r *RootGraph) GetType() GraphType {
return r.Type
}
func constructEdge(graph Graph, name, label, from, to string) Edge {
switch graph.GetType() {
case DIGRAPH:
return &DirectedEdge{Name: name, Label: label, From: from, To: to}
default:
return &UndirectedEdge{Name: name, Label: label, From: from, To: to}
}
}
// AddEdge: adds an edge between two nodes in the root graph
func (g *RootGraph) AddEdge(name string, label string, from string, to string) error {
g.edges[name] = constructEdge(g, name, label, from, to)
return nil
}
const numColours = 12
func (n *Node) hash() int {
h := fnv.New32a()
h.Write([]byte(n.Name))
return (int(h.Sum32()) % numColours) + 1
}
// GetDOT: convert the node into DOT format
func (n *Node) GetDOT() (string, error) {
return fmt.Sprintf("node[label=\"%s\",shape=%s, style=\"filled\", fillcolor=%d, width=%d, height=%d, fixedsize=true] \"%s\";\n",
n.Label, n.Shape, n.hash(), n.Size, n.Size, n.Name), nil
}
// GetDOT: Convert a directed edge into dot format
func (e *DirectedEdge) GetDOT() (string, error) {
return fmt.Sprintf("\"%s\" -> \"%s\" [label=\"%s\"];\n", e.From, e.To, e.Label), nil
}
// GetDOT: convert an undirected edge into dot format
func (e *UndirectedEdge) GetDOT() (string, error) {
return fmt.Sprintf("\"%s\" -- \"%s\" [label=\"%s\"];\n", e.From, e.To, e.Label), nil
}
// AddEdge: adds an edge between two nodes in the graph
func (g *Cluster) AddEdge(name string, label string, from string, to string) error {
g.edges[name] = constructEdge(g, name, label, from, to)
return nil
}
// PutNode: puts a node in the graph
func (g *Cluster) PutNode(name, label string, size int, shape Shape) error {
_, exists := g.nodes[name]
if exists {
// If exists no need to add the ndoe
return nil
}
g.nodes[name] = &Node{Name: name, Label: label, Shape: shape, Size: size}
return nil
}
// GetDOT: convert the cluster into dot format
func (g *Cluster) GetDOT() (string, error) {
var builder strings.Builder
builder.WriteString(fmt.Sprintf("subgraph \"cluster%s\" {\n", g.Label))
builder.WriteString(fmt.Sprintf("label = \"%s\"\n", g.Label))
nodes := lib.MapValues(g.nodes)
edges := lib.MapValues(g.edges)
writeContituents(&builder, nodes...)
writeContituents(&builder, edges...)
builder.WriteString("}\n")
return builder.String(), nil
}
// GetType: get the type of the subgraph (directed|undirected)
func (g *Cluster) GetType() GraphType {
return g.Type
}
// NewSubGraph: instantiate a new subgraph
func NewSubGraph(name string, label string, graphType GraphType) *Cluster {
return &Cluster{
Label: name,
Type: graphType,
Name: name,
nodes: make(map[string]*Node),
edges: make(map[string]Edge),
}
}
// NewGraph: create a new root graph
func NewGraph(label string, graphType GraphType) *RootGraph {
return &RootGraph{
Type: graphType,
Label: label,
clusters: map[string]*Cluster{},
nodes: make(map[string]*Node),
edges: make(map[string]Edge)
}
}