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dag.go
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dag.go
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// Copyright 2018, Goomba project Authors. All rights reserved.
//
// Licensed to the Apache Software Foundation (ASF) under one or more
// contributor license agreements. See the NOTICE file distributed with this
// work for additional information regarding copyright ownership. The ASF
// licenses this file to you under the Apache License, Version 2.0 (the
// "License"); you may not use this file except in compliance with the License.
// You may obtain a copy of the License at
//
// http://www.apache.org/licenses/LICENSE-2.0
//
// Unless required by applicable law or agreed to in writing, software
// distributed under the License is distributed on an "AS IS" BASIS, WITHOUT
// WARRANTIES OR CONDITIONS OF ANY KIND, either express or implied. See the
// License for the specific language governing permissions and limitations
// under the License.
package dag
import (
"fmt"
"sync"
"github.com/goombaio/orderedmap"
)
// DAG type implements a Directed Acyclic Graph data structure.
type DAG struct {
mu sync.Mutex
vertices orderedmap.OrderedMap
}
// NewDAG creates a new Directed Acyclic Graph or DAG.
func NewDAG() *DAG {
d := &DAG{
vertices: *orderedmap.NewOrderedMap(),
}
return d
}
// AddVertex adds a vertex to the graph.
func (d *DAG) AddVertex(v *Vertex) error {
d.mu.Lock()
defer d.mu.Unlock()
d.vertices.Put(v.ID, v)
return nil
}
// DeleteVertex deletes a vertex and all the edges referencing it from the
// graph.
func (d *DAG) DeleteVertex(vertex *Vertex) error {
existsVertex := false
d.mu.Lock()
defer d.mu.Unlock()
// Check if vertices exists.
for _, v := range d.vertices.Values() {
if v == vertex {
existsVertex = true
}
}
if !existsVertex {
return fmt.Errorf("Vertex with ID %v not found", vertex.ID)
}
d.vertices.Remove(vertex.ID)
return nil
}
// AddEdge adds a directed edge between two existing vertices to the graph.
func (d *DAG) AddEdge(tailVertex *Vertex, headVertex *Vertex) error {
tailExists := false
headExists := false
d.mu.Lock()
defer d.mu.Unlock()
// Check if vertices exists.
for _, vertex := range d.vertices.Values() {
if vertex == tailVertex {
tailExists = true
}
if vertex == headVertex {
headExists = true
}
}
if !tailExists {
return fmt.Errorf("Vertex with ID %v not found", tailVertex.ID)
}
if !headExists {
return fmt.Errorf("Vertex with ID %v not found", headVertex.ID)
}
// Check if edge already exists.
for _, childVertex := range tailVertex.Children.Values() {
if childVertex == headVertex {
return fmt.Errorf("Edge (%v,%v) already exists", tailVertex.ID, headVertex.ID)
}
}
// Add edge.
tailVertex.Children.Add(headVertex)
headVertex.Parents.Add(tailVertex)
return nil
}
// DeleteEdge deletes a directed edge between two existing vertices from the
// graph.
func (d *DAG) DeleteEdge(tailVertex *Vertex, headVertex *Vertex) error {
for _, childVertex := range tailVertex.Children.Values() {
if childVertex == headVertex {
tailVertex.Children.Remove(childVertex)
}
}
return nil
}
// GetVertex return a vertex from the graph given a vertex ID.
func (d *DAG) GetVertex(id interface{}) (*Vertex, error) {
var vertex *Vertex
v, found := d.vertices.Get(id)
if !found {
return vertex, fmt.Errorf("vertex %s not found in the graph", id)
}
vertex = v.(*Vertex)
return vertex, nil
}
// Order return the number of vertices in the graph.
func (d *DAG) Order() int {
numVertices := d.vertices.Size()
return numVertices
}
// Size return the number of edges in the graph.
func (d *DAG) Size() int {
numEdges := 0
for _, vertex := range d.vertices.Values() {
numEdges = numEdges + vertex.(*Vertex).Children.Size()
}
return numEdges
}
// SinkVertices return vertices with no children defined by the graph edges.
func (d *DAG) SinkVertices() []*Vertex {
var sinkVertices []*Vertex
for _, vertex := range d.vertices.Values() {
if vertex.(*Vertex).Children.Size() == 0 {
sinkVertices = append(sinkVertices, vertex.(*Vertex))
}
}
return sinkVertices
}
// SourceVertices return vertices with no parent defined by the graph edges.
func (d *DAG) SourceVertices() []*Vertex {
var sourceVertices []*Vertex
for _, vertex := range d.vertices.Values() {
if vertex.(*Vertex).Parents.Size() == 0 {
sourceVertices = append(sourceVertices, vertex.(*Vertex))
}
}
return sourceVertices
}
// Successors return vertices that are children of a given vertex.
func (d *DAG) Successors(vertex *Vertex) ([]*Vertex, error) {
var successors []*Vertex
_, found := d.GetVertex(vertex.ID)
if found != nil {
return successors, fmt.Errorf("vertex %s not found in the graph", vertex.ID)
}
for _, v := range vertex.Children.Values() {
successors = append(successors, v.(*Vertex))
}
return successors, nil
}
// Predecessors return vertices that are parent of a given vertex.
func (d *DAG) Predecessors(vertex *Vertex) ([]*Vertex, error) {
var predecessors []*Vertex
_, found := d.GetVertex(vertex.ID)
if found != nil {
return predecessors, fmt.Errorf("vertex %s not found in the graph", vertex.ID)
}
for _, v := range vertex.Parents.Values() {
predecessors = append(predecessors, v.(*Vertex))
}
return predecessors, nil
}
// String implements stringer interface.
//
// Prints an string representation of this instance.
func (d *DAG) String() string {
result := fmt.Sprintf("DAG Vertices: %d - Edges: %d\n", d.Order(), d.Size())
result += fmt.Sprintf("Vertices:\n")
for _, vertex := range d.vertices.Values() {
vertex = vertex.(*Vertex)
result += fmt.Sprintf("%s", vertex)
}
return result
}