/************************************************************************* * Compilation: javac LinearProbingHashST.java * Execution: java LinearProbingHashST * * Symbol table implementation with linear probing hash table. * * % java LinearProbingHashST * 128.112.136.11 * 208.216.181.15 * null * * *************************************************************************/ public class LinearProbingHashST { private static final int INIT_CAPACITY = 4; private int N; // number of key-value pairs in the symbol table private int M; // size of linear probing table private Key[] keys; // the keys private Value[] vals; // the values // create an empty hash table - use 16 as default size public LinearProbingHashST() { this(INIT_CAPACITY); } // create linear proving hash table of given capacity public LinearProbingHashST(int capacity) { M = capacity; keys = (Key[]) new Object[M]; vals = (Value[]) new Object[M]; } // return the number of key-value pairs in the symbol table public int size() { return N; } // is the symbol table empty? public boolean isEmpty() { return size() == 0; } // does a key-value pair with the given key exist in the symbol table? public boolean contains(Key key) { return get(key) != null; } // hash function for keys - returns value between 0 and M-1 private int hash(Key key) { return (key.hashCode() & 0x7fffffff) % M; } // resize the hash table to the given capacity by re-hashing all of the keys private void resize(int capacity) { LinearProbingHashST temp = new LinearProbingHashST(capacity); for (int i = 0; i < M; i++) { if (keys[i] != null) { temp.put(keys[i], vals[i]); } } keys = temp.keys; vals = temp.vals; M = temp.M; } // insert the key-value pair into the symbol table public void put(Key key, Value val) { if (val == null) delete(key); // double table size if 50% full if (N >= M/2) resize(2*M); int i; for (i = hash(key); keys[i] != null; i = (i + 1) % M) { if (keys[i].equals(key)) { vals[i] = val; return; } } keys[i] = key; vals[i] = val; N++; } // return the value associated with the given key, null if no such value public Value get(Key key) { for (int i = hash(key); keys[i] != null; i = (i + 1) % M) if (keys[i].equals(key)) return vals[i]; return null; } // delete the key (and associated value) from the symbol table public void delete(Key key) { if (!contains(key)) return; // find position i of key int i = hash(key); while (!key.equals(keys[i])) { i = (i + 1) % M; } // delete key and associated value keys[i] = null; vals[i] = null; // rehash all keys in same cluster i = (i + 1) % M; while (keys[i] != null) { // delete keys[i] an vals[i] and reinsert Key keyToRehash = keys[i]; Value valToRehash = vals[i]; keys[i] = null; vals[i] = null; N--; put(keyToRehash, valToRehash); i = (i + 1) % M; } N--; // halves size of array if it's 12.5% full or less if (N > 0 && N <= M/8) resize(M/2); assert check(); } // return all of the keys as in Iterable public Iterable keys() { Queue queue = new Queue(); for (int i = 0; i < M; i++) if (keys[i] != null) queue.enqueue(keys[i]); return queue; } // integrity check - don't check after each put() because // integrity not maintained during a delete() private boolean check() { // check that hash table is at most 50% full if (M < 2*N) { System.err.println("Hash table size M = " + M + "; array size N = " + N); return false; } // check that each key in table can be found by get() for (int i = 0; i < M; i++) { if (keys[i] == null) continue; else if (get(keys[i]) != vals[i]) { System.err.println("get[" + keys[i] + "] = " + get(keys[i]) + "; vals[i] = " + vals[i]); return false; } } return true; } /*********************************************************************** * Unit test client. ***********************************************************************/ public static void main(String[] args) { LinearProbingHashST st = new LinearProbingHashST(); for (int i = 0; !StdIn.isEmpty(); i++) { String key = StdIn.readString(); st.put(key, i); } // print keys for (String s : st.keys()) StdOut.println(s + " " + st.get(s)); } }