# Finding all subtrees in a binary tree

I need to store all of the subtrees of a binary tree into an array of lists of vertices, where each list in the array of lists is stores the root vertex and all of the root's descendant vertices). A recursive traversal is probably best(?).

So if we have

``````class Vertex {
int index;
Vertex left;
Vertex right;
Vertex (int index, Vertex left, Vertex right){...init vars....}
}
``````

I need to generate an `ArrayList<ArrayList<Vertex>> subtreeList` that stores the root and all of its descendent vertices at the root vertex's index in the subtreelist. So it would be like `subtreeList.get(rootvertex.index).add(root vertex and all its descendents)`.

Sorry for the poor wording, I find this difficult to articulate. Help appreciated.

-
Hm, this sounds like a `homework` problem. Have you considered storing a pointer to each location in which the tree branches as you recursively traverse through the tree? –  MrGomez Mar 30 '12 at 23:46
I'm trying to code an algorithm for a fascinating paper titled [cs.cmu.edu/~bryant/pubdir/ieeetc86.pdf](Graph-Based Algorithms for Boolean Function Manipulation). The reduction algorithm reduces a binary decision diagram into an optimised form. –  comp sci balla Mar 31 '12 at 0:08

Let me know if this doesn't work. I personally would keep it in a Hashtable, but I went ahead and made code for an ArrayList.

``````import java.util.ArrayList;
import java.util.Hashtable;

public class Main {
private static int index;

public static void main(String[] args) {
index = 0;

/* Create the tree recursively. */
Vertex root = createVertex(4);

/* Create a hashtable version of the list you want. */
Hashtable<Integer, ArrayList<Vertex>> map = new Hashtable<Integer, ArrayList<Vertex>>();
fillList(root, map);

/* Find the max index. */
int maxIndex = -1;
for (int index : map.keySet()) {
if (maxIndex < index) {
maxIndex = index;
}
}

/* Copy the items over from the hashtable. */
ArrayList<ArrayList<Vertex>> list = new ArrayList<ArrayList<Vertex>>(
maxIndex + 1);
for (int i = 0; i <= maxIndex; i++) {
if (map.containsKey(i)) {
} else {
}
}

/* Print it out. */
for (int i = 0; i < list.size(); i++) {
ArrayList<Vertex> descedants = list.get(i);
if (descedants != null) {
System.out.printf("%d :", i);
for (Vertex vertex : descedants) {
System.out.printf(" %d", vertex.getIndex());
}
System.out.println();
}
}
}

private static void fillList(Vertex vertex,
Hashtable<Integer, ArrayList<Vertex>> map) {
/* Create the descendants for the current vertex. */
ArrayList<Vertex> descendants = new ArrayList<Vertex>();

/* Add the current vertex to the descendants. */
map.put(vertex.getIndex(), descendants);

/*
* Now recursively call this on the left vertex and then, once that's
* done, add the left's descendants to this one's descendants.
*/
Vertex left = vertex.getLeft();
if (left != null) {
fillList(left, map);
for (Vertex leftDescendant : map.get(left.getIndex())) {
}
}

/* Do the same with the right. */
Vertex right = vertex.getRight();
if (right != null) {
fillList(right, map);
for (Vertex rightDescendant : map.get(right.getIndex())) {
}
}
}

/* Creates a balanced binary tree recursively with depth i. */
private static Vertex createVertex(int i) {
if (i > 0) {
index++;
return new Vertex(index, createVertex(i - 1), createVertex(i - 1));
}

return null;
}

}

class Vertex {

private Vertex right;
private Vertex left;
private int index;

public Vertex(int index, Vertex left, Vertex right) {
this.index = index;
this.left = left;
this.right = right;
}

public int getIndex() {
return this.index;
}

public Vertex getLeft() {
return this.left;
}

public Vertex getRight() {
return this.right;
}
}
``````
-