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Is there a solution for Towers of Hanoi whose running time is less than O(2n) where n is the number of disks to move? My solution takes O(2n) time.

Also, the below solution is with recursion. Can we use Dynamic Programming with the concept of memoization to solve this in a lesser time?

public void towersOfHanoi(
        int num, 
        MyStack<Integer> from,
        MyStack<Integer> to, 
        MyStack<Integer> spare
) {
    if (num == 1) {
        int i = from.pop();
        to.push(i);
        System.out.println("Move "+i+" from "+from.getName()+" to " + to.getName());
        return;
    }
    towersOfHanoi(num - 1, from, spare, to);
    towersOfHanoi(1, from, to, spare);
    towersOfHanoi(num - 1, spare, to, from);
}

MyStack is an extended version of Stack class in Java that adds a name field and accessor.

Also, are there any variations of the same problem?

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3  
"Is there a solution for Tower of Hanoi whose running time is less than O(2^n) where n is the number of disks to move?" - Yea. It is called cheating :-) –  Stephen C May 21 '12 at 3:02
    
And how do we do that ? –  dharam May 21 '12 at 3:10
4  
...You pick up the whole stack and move it all over at once. No, there isn't any way that follows the rules that's better than 2^n. –  Louis Wasserman May 21 '12 at 3:24

3 Answers 3

up vote 16 down vote accepted

Given that solving Towers of Hanoi always takes 2^n - 1 steps...no, you're not going to find a faster algorithm, because it takes O(2^n) just to print out the steps, much less compute them.

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I will not prove (as Stephen did), but i will try to explain intuitively that 2^n-1 are min: In every state, there are only three possible moves for the disks. Let represent the current state as ordered seq (1, 1, .. , 1) such that the first number says where the largers disk is, and the last number says where the smallest disk is. (1, 1, .., 1) means all the disks are on at position 1. Also from (1, 1, ..1) there are only two descending states: (1, 1, ... 2) and (1, 1, .... 3). From (1, 1, ... 2) there are three descending states:

  1. Go back to (1, 1, .. 1)
  2. goto (1, 1, ..., 3)
  3. goto (1, 1,...3, 2)

If you continue, you will get graph for which the nodes are the possible states and the edges (transitions) are "disk moves".

You will get image like shown below (if you continue, it will look like triangle and at the vertices will be (1, 1, ...1), (2, 2, ..2), (3, 3, ...3)). The number of steps is actually the path in the graph.

If you walk along the edge on the triangle, the number of steps in 2^n-1. All other paths are the same length or longer.

enter image description here

If you use the strategy: Move all the disks except the largest to place 3, then move the larges to place 2, and finally move all form 3 to 2, formula can be devised in the following way:

f(n) =
f(n -1) // move all except largest from 1 to 3
+ 1 // move largest from 1 to 2
+ f(n -1) // move all from 3 to 2
->
f(n) = 1+ 2 * f(n-1)

the solution of that recurrent equation gives you the number of steps required by that strategy (which happens to be the minimum number of steps)

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1  
+1 for hand drawn gfx :-) –  hirschhornsalz May 21 '12 at 8:28

The solution to the Towers of Hanoi is inescapably 2n. In a dynamic programming solution, however, each subproblem is computed only once, and then the problem is solved by combining the first subproblem solution, the current disk move, and the second subproblem solution.

Thus there are two components in generating each solution: allocating the memory for the present solution, and then filling that memory. Memory allocation is approximately independent of the size of the memory allocated and is the expensive component. Memory copy is linear in the size of memory copied, which, though fast, is exponential in n as a solution to the Towers.

Time = c1*n + c2*2n, where c1 >> c2. I.e., it starts linear and ends exponential.

Link to article appearing in ACM's SIGCSE Inroads magazine (September 2012)

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Excellent insight for this topic! At the first I am not quite convienced, until I implement it myself with the inspiration from this website found by google search, and then I started to realize both the sample program and the answerer are the same person. Thank you, @Tim-Rolfe! I feel lucky to be able to follow your trace on the web. :-) –  Iceberg Nov 13 at 8:00

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