programming-examples/java/Data_Structures/BST.java

 

/*************************************************************************
 *  Compilation:  javac BST.java
 *  Execution:    java BST
 *  Dependencies: StdIn.java StdOut.java Queue.java
 *  Data files:   http://algs4.cs.princeton.edu/32bst/tinyST.txt  
 *
 *  A symbol table implemented with a binary search tree.
 * 
 *  % more tinyST.txt
 *  S E A R C H E X A M P L E
 *  
 *  % java BST < tinyST.txt
 *  A 8
 *  C 4
 *  E 12
 *  H 5
 *  L 11
 *  M 9
 *  P 10
 *  R 3
 *  S 0
 *  X 7
 *
 *************************************************************************/

import java.util.NoSuchElementException;

import edu.princeton.cs.introcs.StdIn;
import edu.princeton.cs.introcs.StdOut;

public class BST<Key extends Comparable<Key>, Value> {
    private Node root;             // root of BST

    private class Node {
        private Key key;           // sorted by key
        private Value val;         // associated data
        private Node left, right;  // left and right subtrees
        private int N;             // number of nodes in subtree

        public Node(Key key, Value val, int N) {
            this.key = key;
            this.val = val;
            this.N = N;
        }
    }

    // is the symbol table empty?
    public boolean isEmpty() {
        return size() == 0;
    }

    // return number of key-value pairs in BST
    public int size() {
        return size(root);
    }

    // return number of key-value pairs in BST rooted at x
    private int size(Node x) {
        if (x == null) return 0;
        else return x.N;
    }

   /***********************************************************************
    *  Search BST for given key, and return associated value if found,
    *  return null if not found
    ***********************************************************************/
    // does there exist a key-value pair with given key?
    public boolean contains(Key key) {
        return get(key) != null;
    }

    // return value associated with the given key, or null if no such key exists
    public Value get(Key key) {
        return get(root, key);
    }

    private Value get(Node x, Key key) {
        if (x == null) return null;
        int cmp = key.compareTo(x.key);
        if      (cmp < 0) return get(x.left, key);
        else if (cmp > 0) return get(x.right, key);
        else              return x.val;
    }

   /***********************************************************************
    *  Insert key-value pair into BST
    *  If key already exists, update with new value
    ***********************************************************************/
    public void put(Key key, Value val) {
        if (val == null) { delete(key); return; }
        root = put(root, key, val);
        assert check();
    }

    private Node put(Node x, Key key, Value val) {
        if (x == null) return new Node(key, val, 1);
        int cmp = key.compareTo(x.key);
        if      (cmp < 0) x.left  = put(x.left,  key, val);
        else if (cmp > 0) x.right = put(x.right, key, val);
        else              x.val   = val;
        x.N = 1 + size(x.left) + size(x.right);
        return x;
    }

   /***********************************************************************
    *  Delete
    ***********************************************************************/

    public void deleteMin() {
        if (isEmpty()) throw new NoSuchElementException("Symbol table underflow");
        root = deleteMin(root);
        assert check();
    }

    private Node deleteMin(Node x) {
        if (x.left == null) return x.right;
        x.left = deleteMin(x.left);
        x.N = size(x.left) + size(x.right) + 1;
        return x;
    }

    public void deleteMax() {
        if (isEmpty()) throw new NoSuchElementException("Symbol table underflow");
        root = deleteMax(root);
        assert check();
    }

    private Node deleteMax(Node x) {
        if (x.right == null) return x.left;
        x.right = deleteMax(x.right);
        x.N = size(x.left) + size(x.right) + 1;
        return x;
    }

    public void delete(Key key) {
        root = delete(root, key);
        assert check();
    }

    private Node delete(Node x, Key key) {
        if (x == null) return null;
        int cmp = key.compareTo(x.key);
        if      (cmp < 0) x.left  = delete(x.left,  key);
        else if (cmp > 0) x.right = delete(x.right, key);
        else { 
            if (x.right == null) return x.left;
            if (x.left  == null) return x.right;
            Node t = x;
            x = min(t.right);
            x.right = deleteMin(t.right);
            x.left = t.left;
        } 
        x.N = size(x.left) + size(x.right) + 1;
        return x;
    } 


   /***********************************************************************
    *  Min, max, floor, and ceiling
    ***********************************************************************/
    public Key min() {
        if (isEmpty()) return null;
        return min(root).key;
    } 

    private Node min(Node x) { 
        if (x.left == null) return x; 
        else                return min(x.left); 
    } 

    public Key max() {
        if (isEmpty()) return null;
        return max(root).key;
    } 

    private Node max(Node x) { 
        if (x.right == null) return x; 
        else                 return max(x.right); 
    } 

    public Key floor(Key key) {
        Node x = floor(root, key);
        if (x == null) return null;
        else return x.key;
    } 

    private Node floor(Node x, Key key) {
        if (x == null) return null;
        int cmp = key.compareTo(x.key);
        if (cmp == 0) return x;
        if (cmp <  0) return floor(x.left, key);
        Node t = floor(x.right, key); 
        if (t != null) return t;
        else return x; 
    } 

    public Key ceiling(Key key) {
        Node x = ceiling(root, key);
        if (x == null) return null;
        else return x.key;
    }

    private Node ceiling(Node x, Key key) {
        if (x == null) return null;
        int cmp = key.compareTo(x.key);
        if (cmp == 0) return x;
        if (cmp < 0) { 
            Node t = ceiling(x.left, key); 
            if (t != null) return t;
            else return x; 
        } 
        return ceiling(x.right, key); 
    } 

   /***********************************************************************
    *  Rank and selection
    ***********************************************************************/
    public Key select(int k) {
        if (k < 0 || k >= size())  return null;
        Node x = select(root, k);
        return x.key;
    }

    // Return key of rank k. 
    private Node select(Node x, int k) {
        if (x == null) return null; 
        int t = size(x.left); 
        if      (t > k) return select(x.left,  k); 
        else if (t < k) return select(x.right, k-t-1); 
        else            return x; 
    } 

    public int rank(Key key) {
        return rank(key, root);
    } 

    // Number of keys in the subtree less than key.
    private int rank(Key key, Node x) {
        if (x == null) return 0; 
        int cmp = key.compareTo(x.key); 
        if      (cmp < 0) return rank(key, x.left); 
        else if (cmp > 0) return 1 + size(x.left) + rank(key, x.right); 
        else              return size(x.left); 
    } 

   /***********************************************************************
    *  Range count and range search.
    ***********************************************************************/
    public Iterable<Key> keys() {
        return keys(min(), max());
    }

    public Iterable<Key> keys(Key lo, Key hi) {
        Queue<Key> queue = new Queue<Key>();
        keys(root, queue, lo, hi);
        return queue;
    } 

    private void keys(Node x, Queue<Key> queue, Key lo, Key hi) { 
        if (x == null) return; 
        int cmplo = lo.compareTo(x.key); 
        int cmphi = hi.compareTo(x.key); 
        if (cmplo < 0) keys(x.left, queue, lo, hi); 
        if (cmplo <= 0 && cmphi >= 0) queue.enqueue(x.key); 
        if (cmphi > 0) keys(x.right, queue, lo, hi); 
    } 

    public int size(Key lo, Key hi) {
        if (lo.compareTo(hi) > 0) return 0;
        if (contains(hi)) return rank(hi) - rank(lo) + 1;
        else              return rank(hi) - rank(lo);
    }


    // height of this BST (one-node tree has height 0)
    public int height() { return height(root); }
    private int height(Node x) {
        if (x == null) return -1;
        return 1 + Math.max(height(x.left), height(x.right));
    }


    // level order traversal
    public Iterable<Key> levelOrder() {
        Queue<Key> keys = new Queue<Key>();
        Queue<Node> queue = new Queue<Node>();
        queue.enqueue(root);
        while (!queue.isEmpty()) {
            Node x = queue.dequeue();
            if (x == null) continue;
            keys.enqueue(x.key);
            queue.enqueue(x.left);
            queue.enqueue(x.right);
        }
        return keys;
    }

  /*************************************************************************
    *  Check integrity of BST data structure
    *************************************************************************/
    private boolean check() {
        if (!isBST())            StdOut.println("Not in symmetric order");
        if (!isSizeConsistent()) StdOut.println("Subtree counts not consistent");
        if (!isRankConsistent()) StdOut.println("Ranks not consistent");
        return isBST() && isSizeConsistent() && isRankConsistent();
    }

    // does this binary tree satisfy symmetric order?
    // Note: this test also ensures that data structure is a binary tree since order is strict
    private boolean isBST() {
        return isBST(root, null, null);
    }

    // is the tree rooted at x a BST with all keys strictly between min and max
    // (if min or max is null, treat as empty constraint)
    // Credit: Bob Dondero's elegant solution
    private boolean isBST(Node x, Key min, Key max) {
        if (x == null) return true;
        if (min != null && x.key.compareTo(min) <= 0) return false;
        if (max != null && x.key.compareTo(max) >= 0) return false;
        return isBST(x.left, min, x.key) && isBST(x.right, x.key, max);
    } 

    // are the size fields correct?
    private boolean isSizeConsistent() { return isSizeConsistent(root); }
    private boolean isSizeConsistent(Node x) {
        if (x == null) return true;
        if (x.N != size(x.left) + size(x.right) + 1) return false;
        return isSizeConsistent(x.left) && isSizeConsistent(x.right);
    } 

    // check that ranks are consistent
    private boolean isRankConsistent() {
        for (int i = 0; i < size(); i++)
            if (i != rank(select(i))) return false;
        for (Key key : keys())
            if (key.compareTo(select(rank(key))) != 0) return false;
        return true;
    }


   /*****************************************************************************
    *  Test client
    *****************************************************************************/
    public static void main(String[] args) { 
        BST<String, Integer> st = new BST<String, Integer>();
        for (int i = 0; !StdIn.isEmpty(); i++) {
            String key = StdIn.readString();
            st.put(key, i);
        }

        for (String s : st.levelOrder())
            StdOut.println(s + " " + st.get(s));

        StdOut.println();

        for (String s : st.keys())
            StdOut.println(s + " " + st.get(s));
    }
}
Initial commit 5 years ago

			`/*************************************************************************`
			`* Compilation: javac BST.java`
			`* Execution: java BST`
			`* Dependencies: StdIn.java StdOut.java Queue.java`
			`* Data files: http://algs4.cs.princeton.edu/32bst/tinyST.txt`
			`*`
			`* A symbol table implemented with a binary search tree.`
			`*`
			`* % more tinyST.txt`
			`* S E A R C H E X A M P L E`
			`*`
			`* % java BST < tinyST.txt`
			`* A 8`
			`* C 4`
			`* E 12`
			`* H 5`
			`* L 11`
			`* M 9`
			`* P 10`
			`* R 3`
			`* S 0`
			`* X 7`
			`*`
			`*************************************************************************/`

			`import java.util.NoSuchElementException;`

			`import edu.princeton.cs.introcs.StdIn;`
			`import edu.princeton.cs.introcs.StdOut;`

			`public class BST<Key extends Comparable<Key>, Value> {`
			`private Node root; // root of BST`

			`private class Node {`
			`private Key key; // sorted by key`
			`private Value val; // associated data`
			`private Node left, right; // left and right subtrees`
			`private int N; // number of nodes in subtree`

			`public Node(Key key, Value val, int N) {`
			`this.key = key;`
			`this.val = val;`
			`this.N = N;`
			`}`
			`}`

			`// is the symbol table empty?`
			`public boolean isEmpty() {`
			`return size() == 0;`
			`}`

			`// return number of key-value pairs in BST`
			`public int size() {`
			`return size(root);`
			`}`

			`// return number of key-value pairs in BST rooted at x`
			`private int size(Node x) {`
			`if (x == null) return 0;`
			`else return x.N;`
			`}`

			`/***********************************************************************`
			`* Search BST for given key, and return associated value if found,`
			`* return null if not found`
			`***********************************************************************/`
			`// does there exist a key-value pair with given key?`
			`public boolean contains(Key key) {`
			`return get(key) != null;`
			`}`

			`// return value associated with the given key, or null if no such key exists`
			`public Value get(Key key) {`
			`return get(root, key);`
			`}`

			`private Value get(Node x, Key key) {`
			`if (x == null) return null;`
			`int cmp = key.compareTo(x.key);`
			`if (cmp < 0) return get(x.left, key);`
			`else if (cmp > 0) return get(x.right, key);`
			`else return x.val;`
			`}`

			`/***********************************************************************`
			`* Insert key-value pair into BST`
			`* If key already exists, update with new value`
			`***********************************************************************/`
			`public void put(Key key, Value val) {`
			`if (val == null) { delete(key); return; }`
			`root = put(root, key, val);`
			`assert check();`
			`}`

			`private Node put(Node x, Key key, Value val) {`
			`if (x == null) return new Node(key, val, 1);`
			`int cmp = key.compareTo(x.key);`
			`if (cmp < 0) x.left = put(x.left, key, val);`
			`else if (cmp > 0) x.right = put(x.right, key, val);`
			`else x.val = val;`
			`x.N = 1 + size(x.left) + size(x.right);`
			`return x;`
			`}`

			`/***********************************************************************`
			`* Delete`
			`***********************************************************************/`

			`public void deleteMin() {`
			`if (isEmpty()) throw new NoSuchElementException("Symbol table underflow");`
			`root = deleteMin(root);`
			`assert check();`
			`}`

			`private Node deleteMin(Node x) {`
			`if (x.left == null) return x.right;`
			`x.left = deleteMin(x.left);`
			`x.N = size(x.left) + size(x.right) + 1;`
			`return x;`
			`}`

			`public void deleteMax() {`
			`if (isEmpty()) throw new NoSuchElementException("Symbol table underflow");`
			`root = deleteMax(root);`
			`assert check();`
			`}`

			`private Node deleteMax(Node x) {`
			`if (x.right == null) return x.left;`
			`x.right = deleteMax(x.right);`
			`x.N = size(x.left) + size(x.right) + 1;`
			`return x;`
			`}`

			`public void delete(Key key) {`
			`root = delete(root, key);`
			`assert check();`
			`}`

			`private Node delete(Node x, Key key) {`
			`if (x == null) return null;`
			`int cmp = key.compareTo(x.key);`
			`if (cmp < 0) x.left = delete(x.left, key);`
			`else if (cmp > 0) x.right = delete(x.right, key);`
			`else {`
			`if (x.right == null) return x.left;`
			`if (x.left == null) return x.right;`
			`Node t = x;`
			`x = min(t.right);`
			`x.right = deleteMin(t.right);`
			`x.left = t.left;`
			`}`
			`x.N = size(x.left) + size(x.right) + 1;`
			`return x;`
			`}`


			`/***********************************************************************`
			`* Min, max, floor, and ceiling`
			`***********************************************************************/`
			`public Key min() {`
			`if (isEmpty()) return null;`
			`return min(root).key;`
			`}`

			`private Node min(Node x) {`
			`if (x.left == null) return x;`
			`else return min(x.left);`
			`}`

			`public Key max() {`
			`if (isEmpty()) return null;`
			`return max(root).key;`
			`}`

			`private Node max(Node x) {`
			`if (x.right == null) return x;`
			`else return max(x.right);`
			`}`

			`public Key floor(Key key) {`
			`Node x = floor(root, key);`
			`if (x == null) return null;`
			`else return x.key;`
			`}`

			`private Node floor(Node x, Key key) {`
			`if (x == null) return null;`
			`int cmp = key.compareTo(x.key);`
			`if (cmp == 0) return x;`
			`if (cmp < 0) return floor(x.left, key);`
			`Node t = floor(x.right, key);`
			`if (t != null) return t;`
			`else return x;`
			`}`

			`public Key ceiling(Key key) {`
			`Node x = ceiling(root, key);`
			`if (x == null) return null;`
			`else return x.key;`
			`}`

			`private Node ceiling(Node x, Key key) {`
			`if (x == null) return null;`
			`int cmp = key.compareTo(x.key);`
			`if (cmp == 0) return x;`
			`if (cmp < 0) {`
			`Node t = ceiling(x.left, key);`
			`if (t != null) return t;`
			`else return x;`
			`}`
			`return ceiling(x.right, key);`
			`}`

			`/***********************************************************************`
			`* Rank and selection`
			`***********************************************************************/`
			`public Key select(int k) {`
			`if (k < 0 \|\| k >= size()) return null;`
			`Node x = select(root, k);`
			`return x.key;`
			`}`

			`// Return key of rank k.`
			`private Node select(Node x, int k) {`
			`if (x == null) return null;`
			`int t = size(x.left);`
			`if (t > k) return select(x.left, k);`
			`else if (t < k) return select(x.right, k-t-1);`
			`else return x;`
			`}`

			`public int rank(Key key) {`
			`return rank(key, root);`
			`}`

			`// Number of keys in the subtree less than key.`
			`private int rank(Key key, Node x) {`
			`if (x == null) return 0;`
			`int cmp = key.compareTo(x.key);`
			`if (cmp < 0) return rank(key, x.left);`
			`else if (cmp > 0) return 1 + size(x.left) + rank(key, x.right);`
			`else return size(x.left);`
			`}`

			`/***********************************************************************`
			`* Range count and range search.`
			`***********************************************************************/`
			`public Iterable<Key> keys() {`
			`return keys(min(), max());`
			`}`

			`public Iterable<Key> keys(Key lo, Key hi) {`
			`Queue<Key> queue = new Queue<Key>();`
			`keys(root, queue, lo, hi);`
			`return queue;`
			`}`

			`private void keys(Node x, Queue<Key> queue, Key lo, Key hi) {`
			`if (x == null) return;`
			`int cmplo = lo.compareTo(x.key);`
			`int cmphi = hi.compareTo(x.key);`
			`if (cmplo < 0) keys(x.left, queue, lo, hi);`
			`if (cmplo <= 0 && cmphi >= 0) queue.enqueue(x.key);`
			`if (cmphi > 0) keys(x.right, queue, lo, hi);`
			`}`

			`public int size(Key lo, Key hi) {`
			`if (lo.compareTo(hi) > 0) return 0;`
			`if (contains(hi)) return rank(hi) - rank(lo) + 1;`
			`else return rank(hi) - rank(lo);`
			`}`


			`// height of this BST (one-node tree has height 0)`
			`public int height() { return height(root); }`
			`private int height(Node x) {`
			`if (x == null) return -1;`
			`return 1 + Math.max(height(x.left), height(x.right));`
			`}`


			`// level order traversal`
			`public Iterable<Key> levelOrder() {`
			`Queue<Key> keys = new Queue<Key>();`
			`Queue<Node> queue = new Queue<Node>();`
			`queue.enqueue(root);`
			`while (!queue.isEmpty()) {`
			`Node x = queue.dequeue();`
			`if (x == null) continue;`
			`keys.enqueue(x.key);`
			`queue.enqueue(x.left);`
			`queue.enqueue(x.right);`
			`}`
			`return keys;`
			`}`

			`/*************************************************************************`
			`* Check integrity of BST data structure`
			`*************************************************************************/`
			`private boolean check() {`
			`if (!isBST()) StdOut.println("Not in symmetric order");`
			`if (!isSizeConsistent()) StdOut.println("Subtree counts not consistent");`
			`if (!isRankConsistent()) StdOut.println("Ranks not consistent");`
			`return isBST() && isSizeConsistent() && isRankConsistent();`
			`}`

			`// does this binary tree satisfy symmetric order?`
			`// Note: this test also ensures that data structure is a binary tree since order is strict`
			`private boolean isBST() {`
			`return isBST(root, null, null);`
			`}`

			`// is the tree rooted at x a BST with all keys strictly between min and max`
			`// (if min or max is null, treat as empty constraint)`
			`// Credit: Bob Dondero's elegant solution`
			`private boolean isBST(Node x, Key min, Key max) {`
			`if (x == null) return true;`
			`if (min != null && x.key.compareTo(min) <= 0) return false;`
			`if (max != null && x.key.compareTo(max) >= 0) return false;`
			`return isBST(x.left, min, x.key) && isBST(x.right, x.key, max);`
			`}`

			`// are the size fields correct?`
			`private boolean isSizeConsistent() { return isSizeConsistent(root); }`
			`private boolean isSizeConsistent(Node x) {`
			`if (x == null) return true;`
			`if (x.N != size(x.left) + size(x.right) + 1) return false;`
			`return isSizeConsistent(x.left) && isSizeConsistent(x.right);`
			`}`

			`// check that ranks are consistent`
			`private boolean isRankConsistent() {`
			`for (int i = 0; i < size(); i++)`
			`if (i != rank(select(i))) return false;`
			`for (Key key : keys())`
			`if (key.compareTo(select(rank(key))) != 0) return false;`
			`return true;`
			`}`


			`/*****************************************************************************`
			`* Test client`
			`*****************************************************************************/`
			`public static void main(String[] args) {`
			`BST<String, Integer> st = new BST<String, Integer>();`
			`for (int i = 0; !StdIn.isEmpty(); i++) {`
			`String key = StdIn.readString();`
			`st.put(key, i);`
			`}`

			`for (String s : st.levelOrder())`
			`StdOut.println(s + " " + st.get(s));`

			`StdOut.println();`

			`for (String s : st.keys())`
			`StdOut.println(s + " " + st.get(s));`
			`}`
			`}`