Notes for Algorithms, Part II: Directed Graphs
Published at 2023-07-29
Last update over 365 days ago
Licensed under CC BY-NC-SA 4.0
algorithm
data-structure
java
digraph
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Table of Content
- Introduction
- Some digraph problems
- Digraph API
- Representations
- Adjacency-lists digraph representation: Java implementation
- Digraph search
- Depth-first search in digraphs
- Reachability application
- Breadth-first search in digraphs
- Multiple-source shortest paths
- Breadth-first search in digraphs application: web crawler (网络爬虫)
- Topological sort (拓扑排序)
- Precedence scheduling (优先级调度)
- Topological sort
- Strongly-connected components
This is a note for 4.2 Directed Graphs, Algorithms, Part II.
Introduction
Some digraph problems
- Path. Is there a directed path from
to ? - Shortest path. What is the shortest directed path from
to ? - Topological sort (拓扑排序). Can you draw a digraph so that all edges point upwards?
- Strong connectivity. Is there a directed path between all pairs of vertices?
- Transitive closure. For which vertices
and is there a path from to ? - PageRank. What is the importance of a web page?
Digraph API
Representations
representation | space | insert edge from v to w | edge from v to w? | iterate over vertices pointing from v? |
---|---|---|---|---|
list of edges | E | 1 | E | E |
adjacency matrix | V^2 | 1* | 1 | V |
adjacency lists | E+V | 1 | outdegree(v) | outdegree(v) |
* disallows parallel edges
Adjacency-lists digraph representation: Java implementation
public class Digraph {
private final int V;
private Bag<Integer>[] adj; // adjacency lists
public Digraph(int V) {
this.V = V;
adj = (Bag<Integer>[]) new Bag[V]; // create empty digraph with V vertices
for (int v = 0; v < V; v++) {
adj[v] = new Bag<Integer>();
}
}
// the only difference between Graph and Digraph, apart from their names
public void addEdge(int v, int w) {
adj[v].add(w); // add edge v->w
}
public Iterable<Integer> adj(int v) {
return adj[v];
}
public Digraph reverse() {
Digraph reverse = new Digraph(V);
for (int v = 0; v < V; v++) {
for (int w : adj(v)) {
reverse.addEdge(w, v);
}
}
return reverse;
}
}
Digraph search
Depth-first search in digraphs
Same method as for undirected graphs.
- Every undirected graph is a digraph (with edges in both directions).
- DFS is a digraph algorithm.
public class DirectedDFS {
private boolean[] marked; // true if path from s
public DirectedDFS(Digraph G, int s) {
marked = new boolean[G.V()]; // constructor marks vertices reachable from s
dfs(G, s);
}
private void dfs(Digraph G, int v) { // recursive DFS does the work
marked[v] = true;
for (int w : G.adj(v)) {
if (!marked[w]) {
dfs(G, w);
}
}
}
// client can ask whether any vertex is reachable from s
public boolean visited(int v) {
return marked[v];
}
}
Reachability application
- Program control-flow program
- Mark-sweep garbage collector (Mark-sweep algorithm. McCarthy, 1960)
Breadth-first search in digraphs
Same method as for undirected graphs.
- Every undirected graph is a digraph (with edges in both directions).
- BFS is a digraph algorithm.
Multiple-source shortest paths
Given a digraph and a set of source vertices, find shortest path from any vertex in the set to each other vertex.
Use BFS, but initialize by enqueuing all source vertices.
Breadth-first search in digraphs application: web crawler (网络爬虫)
Goal. Crawl web, starting from some root web page.
Solution. [BFS with implicit digraph]
- Choose root web page as source
. - Maintain a
Queue
of websites to explore. - Maintain a
SET
of discovered websites. - Dequeue the next website and enqueue websites to which it links (provided you haven’t done so before).
…
Topological sort (拓扑排序)
Precedence scheduling (优先级调度)
Goal. Given a set of tasks to be completed with precedence constraints, in which order should we schedule the tasks?
Digraph model. vertex = task; edge = precedence constraint.
Topological sort
DAG. Directed acyclic (非循环的) graph.
Topological sort. Redraw DAG so all edges point upwards.
- Run depth-first search.
- Return vertices in reverse postorder.
public class DepthFirstOrder {
private boolean[] marked;
private Stack<Integer> reversePost;
public DepthFirstOrder(Digraph G) {
reversePost = new Stack<Integer>();
marked = new boolean[G.V()];
for (int v = 0; v < G.V(); v++)
if (!marked[v]) dfs(G, v);
}
private void dfs(Digraph G, int v) {
marked[v] = true;
for (int w : G.adj(v))
if (!marked[w]) dfs(G, w);
reversePost.push(v);
}
public Iterable<Integer> reversePost() {
return reversePost; // returns all vertices in "reverse DFS postorder"
}
}
Strongly-connected components
Kosaraju-Sharir algorithm:
- Compute reverse postorder in
. - Run DFS in
, visiting unmarked vertices in reverse postorder of .
public class KosarajuSharirSCC {
private boolean[] marked;
private int[] id;
private int count;
public KosarajuSharirSCC(Digraph G) {
marked = new boolean[G.V()];
id = new int[G.V()];
DepthFirstOrder dfs = new DepthFirstOrder(G.reverse());
for (int v : dfs.reversePost()) {
if (!marked[v]) {
dfs(G, v);
count++;
}
}
}
private void dfs(Digraph G, int v) {
marked[v] = true;
id[v] = count;
for (int w : G.adj(v))
if (!marked[w])
dfs(G, w);
}
public boolean stronglyConnected(int v, int w) {
return id[v] == id[w];
}
}