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So, here is the actual question (it's for a homework):

A hashtable is data structure that allows access and manipulation of the date at constant time (O(1)). The hashtable array must be initialized to null during the creation of the hashtable in order to identify the empty cells. In most cases, the time penalty is enormous especially considering that most cells will never be read. We ask of you that you implement a hashtable that bypasses this problem at the price of a heavier insertion, but still at constant time. For the purpose of this homework and to simplify your work, we suppose that you can't delete elements in this hashtable.

In the archive of this homework you will find the interface of an hashtable that you need to fill. You can use the function hashcode() from java as a hash function. You will have to use the Vector data structure from Java in order to bypass the initialization and you have to find by yourself how to do so. You can only insert elements at the end of the vector so that the complexity is still O(1).

Here are some facts to consider:

  • In a hashtable containing integers, the table contains numeric values (but they don't make any sense).

  • In a stack, you cannot access elements over the highest element, but you know for sure that all the values are valid. Furthermore, you know the index of the highest element.

Use those facts to bypass the initialization of the hashtable. The table must use linear probing to resolve collisions.

Also, here is the interface that I need to implement for this homework:

public interface NoInitHashTable<E>
{
    public void insert(E e);
    public boolean contains(E e);

    public void rehash();
    public int nextPrime(int n);
    public boolean isPrime(int n);
}

I have already implemented nextPrime and isPrime (I don't think they are different from a normal hashtable). The three other I need to figure out.

I thought a lot about it and discussed it with my teammate but I really can't find anything. I only need to know the basic principle of how to implement it, I can handle the coding.

tl;dr I need to implement an array hashtable that works without initializing the array to null at the start. The insertion must be done in constant time. I only need to know the basic principle of how to do that.

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An interesting challenge. I'm guessing the prof gave you a few more hints during recent lectures -- you should think back over what he said the last couple of class sessions to see if there are some additional clues. –  Hot Licks Oct 30 '11 at 2:24
    
Hint: Nowhere does he define an interface to set the hashtable size. –  Hot Licks Oct 30 '11 at 2:30
    
To get O(1) time complexity, you need a perfect hashing algorithm. i.e. no collisions. This rarely the case with real applications. ;) –  Peter Lawrey Oct 30 '11 at 7:17
1  
@PeterLawrey, O(1) doesn't mean no collisions. If the number of collisions is limited, you can still have O(1). And the usual implementations of hash tables are O(1), assuming you have reasonable distribution of hash codes. –  svick Oct 30 '11 at 15:00

2 Answers 2

up vote 1 down vote accepted

I think I have seen this in a book as exercise with answer at the back, but I can't remember which book or where. It is generally relevant to the question of why we usually concentrate on the time a program takes rather than the space - a program that runs efficiently in time shouldn't need huge amounts of space.

Here is some pseudo-code that checks if a cell in the hash table is valid. I will leave the job of altering the data structures it defines to make another cell in the hash table valid as a remaining exercise for the reader.

// each cell here is for a cell at the same offset in the
// hash table
int numValidWhenFirstSetValid[SIZE];
int numValidSoFar = 0; // initialise only this
// Only cells 0..numValidSoFar-1 here are valid.
int validOffsetsInOrderSeen[SIZE];

boolean isValid(int offsetInArray)
{
  int supposedWhenFirstValid =
   numValidWhenFirstSetValid[offsetInArray]
  if supposedWhenFirstValid >= numValidSoFar)
  {
    return false;
  }
  if supposedWhenFirstValid < 0)
  {
    return false;
  }
  if (validOffsetsInOrderSeen[supposedWhenFirstValid] !=
    offsetInArray)
  {
    return false;
 }
 return true;
}

Edit - this is exercise 24 in section 2.2.6 of Knuth Vol 1. The provided answer references exercise 2.12 of "The Design And Analysis of Computer Programs" by Aho, Hopcraft, and Ullman. You can avoid any accusation of plaigarism in your answer by referencing the source of the question you were asked :-)

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I didn't take it from that book : it was a question asked for a homework and it didn't reference anything. –  Djeezus Oct 30 '11 at 19:01
    
Thanks for the example. I don't really understand what the variable represent though. What is numValidWhenFirstSetValid and suppowedWhenFirstValid? Thanks –  Djeezus Nov 4 '11 at 3:16
1  
Suppose that you fill in hash slots 3, 5, 2 in that order, so validOffsetsInOrderSeen[] = {3, 5, 2}, numValidWhenFirstSetValid[3] = 0, numValidWhenFirstSetValid[5] = 1, numValidWhenFirstSetValid[2] = 2. numValidWhenFirstSetValid[k] is the number of valid slots seen so far when slot k is filled in. You know that validOffsetsInOrderSeen[0..numValidSoFar] lists the slots filled in, so to check that slot k has been filled in you set supposedWhenFirstValid = numValidWhenFirstSetValid[k]. If slot k is empty this could look plausible so you check validOffsetsInOrderSeen[supposedWhenFirstValid] == k. –  mcdowella Nov 4 '11 at 5:27

Mark each element in hashtable with some color (1, 2, ...)

F.e. Current color:

int curColor = 0;

When you put element to hash table, associate with it current color (curColor)

If you need to search, filter elements that haven't the same color (element.color == curColor)

If you need to clear hashTable, just increment current color (curColor++)

share|improve this answer
    
Wouldn't that make searching O(1)? –  svick Oct 30 '11 at 15:21
    
Average searching time for hashtable is o(n). But when items count become greater than size of hash table, searching time will be increased. You can clear all hashtable if items count(old and current) is too much –  Ivan Benko Oct 30 '11 at 16:04
    
Sorry, I meant O(n). I think your solution would make the O(n). But the requirement is to make it O(1). Hashtables usually manage to achieve that. –  svick Oct 30 '11 at 16:08
    
@svick, Oops, I made a mistake in my comment.. Searching time is O(1), becuase there is simple hashtable that has average searching time O(1) –  Ivan Benko Oct 30 '11 at 23:10

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