Graph as Adjacency Lists in Java
Jump to navigation
Jump to search
Internal
Overview
Java representation of a graph G, with V and E represent a vertex and an edge:
/**
* A graph represented using adjacency lists. Undirected graphs include two edge representations for two vertices,
* one from v to u and one from u to v. Directed graphs use just one edge representation.
*/
public class G {
public V[] adj;
/**
* DIRECTED/UNDIRECTED
* edge0 as (u, v)
* edge1 as (s, t)
* ...
* Allows comment lines starting with "#"
* @param fileName - the file to load the graph description from
*/
public G(String fileName) throws Exception {
load(fileName);
}
/**
* @return the vertex with the given index.
*/
public V vertex(int id) {
return adj[id];
}
/**
* @return n
*/
public int size() {
return adj.length;
}
@Override
public String toString() {
StringBuilder sb = new StringBuilder();
for (V v : adj) {
sb.append(v).append("\n");
}
return sb.toString();
}
private void load(String fileName) throws Exception {
Map<Integer, V> vertices = new HashMap<>();
// depends on external representation
try(BufferedReader br = new BufferedReader(new FileReader(fileName))) {
String line = br.readLine().trim();
boolean directed = false;
if ("DIRECTED".equals(line)) {
directed = true;
}
else if (!"UNDIRECTED".equals(line)) {
throw new IllegalArgumentException("expecting DIRECTED|UNDIRECTED and got " + line);
}
int maxid = Integer.MIN_VALUE;
while(((line = br.readLine()) != null)) {
line = line.trim();
if (line.isEmpty()) {
continue;
}
if (line.charAt(0) == '#') {
continue;
}
String[] tok = line.split(" ");
int vi = Integer.parseInt(tok[0]);
if (vi > maxid) {
maxid = vi;
}
int ui = Integer.parseInt(tok[1]);
if (ui > maxid) {
maxid = ui;
}
V v = vertices.get(vi);
if (v == null) {
v = new V(vi);
vertices.put(vi, v);
}
V u = vertices.get(ui);
if (u == null) {
u = new V(ui);
vertices.put(ui, u);
}
v.edges.add(new E(this, u.id));
if (!directed) {
u.edges.add(new E(this, v.id));
}
}
this.adj = new V[maxid + 1];
for(int i = 0; i <= maxid; i ++) {
adj[i] = vertices.get(i);
if (adj[i] == null) {
// the vertex is not part of any edge
adj[i] = new V(i);
}
}
}
}
}
/**
* A vertex. An optimized representation may get away without a dedicated class, by only maintaining indices,
* but this becomes insufficient when we need to maintain auxiliary information per node, as required by
* various algorithms (BFS and DFS need to know whether a node was visited or not).
*/
class V {
/**
* Redundant index, it helps with displaying the structure.
*/
public int id;
public List<E> edges;
/**
* Augmentation useful to search algorithms.
*/
public boolean seen;
public V(int id) {
this.id = id;
this.edges = new ArrayList<>();
this.seen = false;
}
@Override
public String toString() {
StringBuilder s = new StringBuilder((id < 10 ? " " : "") + id + "[");
if (seen) {
s.append('*');
}
s.append("] → {");
for(int i = 0; i < edges.size(); i ++) {
s.append(edges.get(i).w);
if (i < edges.size() - 1) {
s.append(", ");
}
}
s.append("}");
return s.toString();
}
}
/**
* An edge. Useful to carry additional metadata, such as weight, etc. The same edge structure can be used for
* directed and undirected graphs. An undirected graph will maintain edge representations in both directions.
*/
class E {
private final G g;
public int weight = 1;
/**
* The index of the adjacent (distant) vertex.
*/
public int w;
public E(G g, int w) {
this.g = g;
this.w = w;
}
public V getVertexOppositeTo(V v) {
// we assume the vertex is correct, and we return the only vertex we know, the "opposite" one
return g.vertex(w);
}
}