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Tuesday, 14 February 2017

Chapter 27 Exercise 4, Introduction to Java Programming, Tenth Edition Y. Daniel LiangY.

27.4 (Modify MyHashMap with duplicate keys) Modify MyHashMap to allow duplicate keys for entries. You need to modify the implementation for the put(key,value) method. Also add a new method named getAll(key) that returns a set of values that match the key in the map.


import java.util.LinkedList;

public class Exercise04 {

 public static void main(String[] args) {
  MyHashMap<String, Integer> map = new MyHashMap<String, Integer>();
  map.put("Smith", 30);
  map.put("Anderson", 31);
  map.put("Smith", 345);
  map.put("Lewis", 29);
  map.put("Smith", 3);
  map.put("Cook", 29);
  map.put("Smith", 65);

  System.out.println("Entries in map: " + map);

  System.out.println("The age for " + "Lewis is " + map.get("Lewis"));

  System.out.println("Is Smith in the map? " + map.containsKey("Smith"));
  System.out.println("Is age 33 in the map? " + map.containsValue(33));

  map.remove("Smith");
  System.out.println("Entries in map: " + map);

  map.removeAll("Smith");
  System.out.println("Entries in map: " + map);

  map.clear();
  System.out.println("Entries in map: " + map);
 }

 static class MyHashMap<K, V> implements MyMap<K, V> {
  // Define the default hash table size. Must be a power of 2
  private static int DEFAULT_INITIAL_CAPACITY = 4;

  // Define the maximum hash table size. 1 << 30 is same as 2^30
  private static int MAXIMUM_CAPACITY = 1 << 30;

  // Current hash table capacity. Capacity is a power of 2
  private int capacity;

  // Define default load factor
  private static float DEFAULT_MAX_LOAD_FACTOR = 0.75f;

  // Specify a load factor used in the hash table
  private float loadFactorThreshold;

  // The number of entries in the map
  private int size = 0;

  // Hash table is an array with each cell that is a linked list
  LinkedList<MyMap.Entry<K, V>>[] table;

  /** Construct a map with the default capacity and load factor */
  public MyHashMap() {
   this(DEFAULT_INITIAL_CAPACITY, DEFAULT_MAX_LOAD_FACTOR);
  }

  /**
   * Construct a map with the specified initial capacity and default load
   * factor
   */
  public MyHashMap(int initialCapacity) {
   this(initialCapacity, DEFAULT_MAX_LOAD_FACTOR);
  }

  /**
   * Construct a map with the specified initial capacity and load factor
   */
  @SuppressWarnings("unchecked")
  public MyHashMap(int initialCapacity, float loadFactorThreshold) {
   if (initialCapacity > MAXIMUM_CAPACITY)
    this.capacity = MAXIMUM_CAPACITY;
   else
    this.capacity = trimToPowerOf2(initialCapacity);

   this.loadFactorThreshold = loadFactorThreshold;
   table = new LinkedList[capacity];
  }

  @Override
  /** Remove all of the entries from this map */
  public void clear() {
   size = 0;
   removeEntries();
  }

  @Override
  /** Return true if the specified key is in the map */
  public boolean containsKey(K key) {
   if (get(key) != null)
    return true;
   else
    return false;
  }

  @Override
  /** Return true if this map contains the value */
  public boolean containsValue(V value) {
   for (int i = 0; i < capacity; i++) {
    if (table[i] != null) {
     LinkedList<Entry<K, V>> bucket = table[i];
     for (Entry<K, V> entry : bucket)
      if (entry.getValue().equals(value))
       return true;
    }
   }

   return false;
  }

  @Override
  /** Return a set of entries in the map */
  public java.util.Set<MyMap.Entry<K, V>> entrySet() {
   java.util.Set<MyMap.Entry<K, V>> set = new java.util.HashSet<MyMap.Entry<K, V>>();

   for (int i = 0; i < capacity; i++) {
    if (table[i] != null) {
     LinkedList<Entry<K, V>> bucket = table[i];
     for (Entry<K, V> entry : bucket)
      set.add(entry);
    }
   }

   return set;
  }

  @Override
  /** Return the value that matches the specified key */
  public V get(K key) {
   int bucketIndex = hash(key.hashCode());
   if (table[bucketIndex] != null) {
    LinkedList<Entry<K, V>> bucket = table[bucketIndex];
    for (Entry<K, V> entry : bucket)
     if (entry.getKey().equals(key))
      return entry.getValue();
   }

   return null;
  }

  @Override
  /** Return true if this map contains no entries */
  public boolean isEmpty() {
   return size == 0;
  }

  @Override
  /** Return a set consisting of the keys in this map */
  public java.util.Set<K> keySet() {
   java.util.Set<K> set = new java.util.HashSet<K>();

   for (int i = 0; i < capacity; i++) {
    if (table[i] != null) {
     LinkedList<Entry<K, V>> bucket = table[i];
     for (Entry<K, V> entry : bucket)
      set.add(entry.getKey());
    }
   }

   return set;
  }

  @Override
  /** Add an entry (key, value) into the map */
  public V put(K key, V value) {

   // Check load factor
   if (size >= capacity * loadFactorThreshold) {
    if (capacity == MAXIMUM_CAPACITY)
     throw new RuntimeException("Exceeding maximum capacity");

    rehash();
   }

   int bucketIndex = hash(key.hashCode());

   // Create a linked list for the bucket if it is not created
   if (table[bucketIndex] == null) {
    table[bucketIndex] = new LinkedList<Entry<K, V>>();
   }

   // Add a new entry (key, value) to hashTable[index]
   table[bucketIndex].add(new MyMap.Entry<K, V>(key, value));

   size++; // Increase size

   return value;
  }

  @Override
  /** Remove the entries for the specified key */
  public void remove(K key) {
   int bucketIndex = hash(key.hashCode());

   // Remove the first entry that matches the key from a bucket
   if (table[bucketIndex] != null) {
    LinkedList<Entry<K, V>> bucket = table[bucketIndex];
    for (Entry<K, V> entry : bucket)
     if (entry.getKey().equals(key)) {
      bucket.remove(entry);
      size--; // Decrease size
      break; // Remove just one entry that matches the key
     }
   }
  }
  
  public void removeAll(K key) {
   int bucketIndex = hash(key.hashCode());

   // Remove the first entry that matches the key from a bucket
   if (table[bucketIndex] != null) {
    LinkedList<Entry<K, V>> bucket = table[bucketIndex];
    
    boolean deleted = true;
    while(deleted) {
     deleted = false;
     for (Entry<K, V> entry : bucket)
      if (entry.getKey().equals(key)) {
       bucket.remove(entry);
       size--; // Decrease size
       deleted = true;
       break;
      }
    }
   }
  }

  @Override
  /** Return the number of entries in this map */
  public int size() {
   return size;
  }

  @Override
  /** Return a set consisting of the values in this map */
  public java.util.Set<V> values() {
   java.util.Set<V> set = new java.util.HashSet<V>();

   for (int i = 0; i < capacity; i++) {
    if (table[i] != null) {
     LinkedList<Entry<K, V>> bucket = table[i];
     for (Entry<K, V> entry : bucket)
      set.add(entry.getValue());
    }
   }

   return set;
  }

  /** Hash function */
  private int hash(int hashCode) {
   return supplementalHash(hashCode) & (capacity - 1);
  }

  /** Ensure the hashing is evenly distributed */
  private static int supplementalHash(int h) {
   h ^= (h >>> 20) ^ (h >>> 12);
   return h ^ (h >>> 7) ^ (h >>> 4);
  }

  /** Return a power of 2 for initialCapacity */
  private int trimToPowerOf2(int initialCapacity) {
   int capacity = 1;
   while (capacity < initialCapacity) {
    capacity <<= 1;
   }

   return capacity;
  }

  /** Remove all entries from each bucket */
  private void removeEntries() {
   for (int i = 0; i < capacity; i++) {
    if (table[i] != null) {
     table[i].clear();
    }
   }
  }

  /** Rehash the map */
  @SuppressWarnings("unchecked")
  private void rehash() {
   java.util.Set<Entry<K, V>> set = entrySet(); // Get entries
   capacity <<= 1; // Double capacity
   table = new LinkedList[capacity]; // Create a new hash table
   size = 0; // Reset size to 0

   for (Entry<K, V> entry : set) {
    put(entry.getKey(), entry.getValue()); // Store to new table
   }
  }

  @Override
  public String toString() {
   StringBuilder builder = new StringBuilder("[");

   for (int i = 0; i < capacity; i++) {
    if (table[i] != null && table[i].size() > 0)
     for (Entry<K, V> entry : table[i])
      builder.append(entry);
   }

   builder.append("]");
   return builder.toString();
  }
 }

 interface MyMap<K, V> {
  /** Remove all of the entries from this map */
  public void clear();

  /** Return true if the specified key is in the map */
  public boolean containsKey(K key);

  /** Return true if this map contains the specified value */
  public boolean containsValue(V value);

  /** Return a set of entries in the map */
  public java.util.Set<Entry<K, V>> entrySet();

  /** Return the first value that matches the specified key */
  public V get(K key);

  /** Return true if this map contains no entries */
  public boolean isEmpty();

  /** Return a set consisting of the keys in this map */
  public java.util.Set<K> keySet();

  /** Add an entry (key, value) into the map */
  public V put(K key, V value);

  /** Remove the entries for the specified key */
  public void remove(K key);

  /** Return the number of mappings in this map */
  public int size();

  /** Return a set consisting of the values in this map */
  public java.util.Set<V> values();

  /** Define inner class for Entry */
  public static class Entry<K, V> {
   K key;
   V value;

   public Entry(K key, V value) {
    this.key = key;
    this.value = value;
   }

   public K getKey() {
    return key;
   }

   public V getValue() {
    return value;
   }

   @Override
   public String toString() {
    return "[" + key + ", " + value + "]";
   }
  }
 }

}

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