# Tower of Hanoi: Recursive Algorithm

Although I have no problem whatsoever understanding recursion, I can't seem to wrap my head around the recursive solution to the Tower of Hanoi problem. Here is the code from Wikipedia:

``````procedure Hanoi(n: integer; source, dest, by: char);
Begin
if (n=1) then
writeln('Move the plate from ', source, ' to ', dest)
else begin
Hanoi(n-1, source, by, dest);
writeln('Move the plate from ', source, ' to ', dest);
Hanoi(n-1, by, dest, source);
end;
End;``````

I understand the base case and the concept of breaking the problem into smaller pieces until you are able to move a single disk. However, I can't figure out how the two recursive calls in the non-base case work together. Perhaps someone can help me out? Thanks.

-
That code could be improved by checking for n=0 and doing nothing in that case, to avoid the duplication of the move. – starblue Aug 3 '09 at 17:49
This might help: learneroo.com/modules/71/nodes/402 – Ari Apr 4 '14 at 20:18
I wrote a blog post on the recursion itself. It goes into some extreme depth and, quite honestly, it takes some time to grasp but once you visualize it, it makes so much more sense. Seriously, save yourself some time and check this out: dima.to/blog/?p=29 – Alexandru May 31 '14 at 23:04
Actually the basic idea is if we want to solve the problem for N disks then we can re-use the problem with N-1 disks. The Base case is when N = 1. I have tried to explain this in my blog using Java code. krishnalearnings.blogspot.in/2015/06/… – nits.kk Jul 18 '15 at 13:56
You may try to create a visualization like this: thewalnut.io/visualizer/visualize/1322/342 to see if it helps in understanding... – Akhorus Jul 28 '15 at 21:12

Actually, the section from where you took that code offers an explanation as well:

To move n discs from peg A to peg C:

1. move n−1 discs from A to B. This leaves disc #n alone on peg A
2. move disc #n from A to C
3. move n−1 discs from B to C so they sit on disc #n

It's pretty clear that you first have to remove n − 1 discs to get access to the nth one. And that you have to move them first to another peg than where you want the full tower to appear.

The code in your post has three arguments, besides the number of discs: A source peg, a destination peg and a temporary peg on which discs can be stored in between (where every disc with size n − 1 fits).

The recursion happens actually twice, there, once before the `writeln`, once after. The one before the `writeln` will move n − 1 discs onto the temporary peg, using the destination peg as temporary storage (the arguments in the recursive call are in different order). After that, the remaining disc will be moved to the destination peg and afterwards the second recursion compeltes the moving of the entire tower, by moving the n − 1 tower from the temp peg to the destination peg, above disc n.

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I saw that, but I don't quite understand how it works. – titaniumdecoy Aug 3 '09 at 16:41
The only way you can move disc #n from A to C is to do two things: (1) get all the smaller discs off of disc #n (which is still on peg A). (2) make sure peg C is ready to receive disc #n. The only way to do this is to put all those other discs onto peg B so they are out of the way. – Jason S Aug 3 '09 at 16:48
I tried explaining a little more. – Joey Aug 3 '09 at 16:57
@JasonS I am clear with the 1 and 2 steps, but I couldnt get the 3rd step. Could you please explain for that – user567879 Jan 21 '12 at 9:07
um... my post was 2 1/2 years ago.... if you mean "The only way to do this is to put all those other discs onto peg B so they are out of the way", you can do that recursively: discs 1 to n are on peg A so any discs on peg B are larger than n. – Jason S Jan 21 '12 at 14:44

a year ago i had i functional programming course and draw this illustration for the algorithm. hope it helps!

``````(0)  _|_         |          |
__|__        |          |
___|___       |          |
____|____  ____|____  ____|____

(1.1) |          |          |
__|__        |          |
___|___      _|_         |
____|____  ____|____  ____|____ (A -> B)

(1.2) |          |          |
|          |          |
___|___      _|_       __|__
____|____  ____|____  ____|____ (A -> C)

(1.3) |          |          |
|          |         _|_
___|___       |        __|__
____|____  ____|____  ____|____ (A -> C)

(2.1) |          |          |
|          |         _|_
|       ___|___     __|__
____|____  ____|____  ____|____ (A -> B)

(3.1) |          |          |
|          |          |
_|_      ___|___     __|__
____|____  ____|____  ____|____ (C -> A)

(3.2) |          |          |
|        __|__        |
_|_      ___|___       |
____|____  ____|____  ____|____ (C -> B)

(3.3) |         _|_         |
|        __|__        |
|       ___|___       |
____|____  ____|____  ____|____ (A -> B)
``````

The 3 rings problem has been splited to 2 2-rings problem (1.x and 3.x)

-

There's a good explanation of the recursive Hanoi implementation at http://www.cs.cmu.edu/~cburch/survey/recurse/hanoiimpl.html.

Summary is, if you want to move the bottom plate from stick A to stick B, you first have to move all the smaller plates on top of it from A to C. The second recursive call is then to move the plates you moved to C back onto B after your base case moved the single large plate from A to B.

-

I agree this one isn't immediate when you first look at it, but it's fairly simple when you get down to it.

Base case: your tower is of size 1. So you can do it in one move, from source directly to dest.

Recursive case: your tower is of size n > 1. So you move the top tower of size n-1 to an extra peg (by), move the bottom "tower" of size 1 to the destination peg, and move the top tower from by to dest.

So with a simple case, you have a tower of height 2:

`````` _|_    |     |
__|__   |     |
===== ===== =====
``````

First step: move the top tower of 2-1 (=1) to the extra peg (the middle one, lets say).

``````  |     |     |
__|__  _|_    |
===== ===== =====
``````

Next: move the bottom disc to the destination:

``````  |     |     |
|    _|_  __|__
===== ===== =====
``````

And finally, move the top tower of (2-1)=1 to the destination.

``````  |     |    _|_
|     |   __|__
===== ===== =====
``````

If you think about it, even if the tower were 3 or more, there will always be an empty extra peg, or a peg with all larger discs, for the recursion to use when swapping towers around.

-
I think the key is,in all recursion problems, we need to think about simple use case first and solve with an algorithm , apply the same to more input.Thanks! – kumar Dec 8 '14 at 13:51

Suppose we want to move a disc from A to C through B then:

1. move a smaller disc to B.
2. move another disc to C.
3. move B to C.
4. move from A to B.
5. move all from C to A.

If you repeat all the above steps, the disc will transfer.

-

I feel the pain!

Although this is an old post, I think what one really needs to understand, is not the "move this to that" approach but that the answer involves using the side-effect of the recursion.

A invaluable help to me was the "The Little Schemer" which teaches one to think and write recursive functions.

However, this teaches the reader to use the results of the returned result in the next recursive call.

In the Tower of Hanoi, the answer is not in the returned result per se, but in the observation of the returned result.

The magic occurs in the succesive rearrangment of the function parameters.

Yes the problem is really in three parts:

• moving a smaller tower to the spare peg
• moving the last disc to the destination peg
• moving the remaining tower on the spare peg to the destination peg.

In Scheme:

``````(define (th n a b c)
(if (zero? n) 'done
(begin
(th (- n 1) a c b)
(display (list a c))
(newline)
(th (- n 1) b a c))))
(th 5 'source 'spare 'destination)
``````

However it is the displaying of the function parameters which is the solution to the problem and crucially understanding the double tree like structure of the calls.

The solution also conveys the power of `proof by induction` and a warm glow to all programmers who have wrestled with conventional control structures.

Incidently, to solve the problem by hand is quite satisfying.

• count the number of discs
• if even, move the first disc to the spare peg, make next legal move (not involving the top disc). Then move the top disc to the destination peg, make the next legal move(nittd). Then move the top disc to the source peg, make the next legal move(nittd)...
• if odd, move the first disc to the destination peg, make the next legal move (not involving the top disc). Then move the top disc to the spare peg, make the next legal move(nittd). Then move the top disc to the source peg, make the next legal move(nittd)...

Best done by always holding the top disc with the same hand and always moving that hand in the same direction.

The final number of moves for `n` discs is `2^n - 1` the `move n disc to destination` is halfway through the process.

Lastly, it is funny how explaining a problem to a colleague, your wife/husband or even the dog (even it they not listening) can cement enlightenment.

-

Think of it as a stack with the disks diameter being represented by integers (4,3,2,1) The first recursion call will be called 3 times and thus filling the run-time stack as follows

1. first call : 1. Second call : 2,1. and third call: 3,2,1.

After the first recursion ends, the contents of the run-time stack is popped to the middle pole from largest diameter to smallest (first in last out). Next, disk with diameter 4 is moved to the destination.

The second recursion call is the same as the first with the exception of moving the elements from the middle pole to destination.

-

It's simple. Suppose you want to move from A to C

if there's only one disk, just move it.

If there's more than one disk, do

• move all disks (n-1 disks), except the bottom one from A to B
• move the bottom disk from A to C
• move the n-1 disks from the first step from A to C

Keep in mind that, when moving the n-1 disks, the nth won't be a problem at all (once it is bigger than all the others)

Note that moving the n-1 disks recurs on the same problem again, until n-1 = 1, in which case you'll be on the first if (where you should just move it).

-

The answer for the question, how does the program know, that even is "src" to "aux", and odd is "src" to "dst" for the opening move lies in the program. If you break down fist move with 4 discs, then this looks like this:

``````hanoi(4, "src", "aux", "dst");
if (disc > 0) {
hanoi(3, 'src', 'dst', 'aux');
if (disc > 0) {
hanoi(2, 'src', 'aux', 'dst');
if (disc > 0) {
hanoi(1, 'src', 'dst', 'aux');
if (disc > 0) {
hanoi(0, 'src', 'aux', 'dst');
END
document.writeln("Move disc" + 1 + "from" + Src + "to" + Aux);
hanoi(0, 'aux', 'src', 'dst');
END
}
``````

also the first move with 4 disc(even) goes from Src to Aux.

-

As some of our friends suggested, I removed previous two answers and I consolidate here.

This gives you the clear understanding.

What the general algorithm is....

Algorithm:

``````solve(n,s,i,d) //solve n discs from s to d, s-source i-intermediate d-destination
{
if(n==0)return;
solve(n-1,s,d,i); // solve n-1 discs from s to i Note:recursive call, not just move
move from s to d; // after moving n-1 discs from s to d, a left disc in s is moved to d
solve(n-1,i,s,d); // we have left n-1 disc in 'i', so bringing it to from i to d (recursive call)
}
``````

here is the working example Click here

-
``````public static void hanoi(int number, String source, String aux, String dest)
{
if (number == 1)
{
System.out.println(source + " - > "+dest);
}
else{
hanoi(number -1, source, dest, aux);
hanoi(1, source, aux, dest);
hanoi(number -1, aux, source, dest);
}
}
``````
-

After reading all these explanations I thought I'd weigh in with the method my professor used to explain the Towers of Hanoi recursive solution. Here is the algorithm again with n representing the number of rings, and A, B, C representing the pegs. The first parameter of the function is the number of rings, second parameter represents the source peg, the third is the destination peg, and fourth is the spare peg.

``````procedure Hanoi(n, A, B, C);
if n == 1
move ring n from peg A to peg B
else
Hanoi(n-1, A, C, B);
move ring n-1 from A to C
Hanoi(n-1, C, B, A);
end;
``````

I was taught in graduate school to never to be ashamed to think small. So, let's look at this algorithm for n = 5. The question to ask yourself first is if I want to move the 5th ring from A to B, where are the other 4 rings? If the 5th ring occupies peg A and we want to move it to peg B, then the other 4 rings can only be on peg C. In the algorithm above the function Hanoi (n-1, A, C, B) is trying to move all those 4 other rings on to peg C, so ring 5 will be able to move from A to B. Following this algorithm we look at n = 4. If ring 4 will be moved from A to C, where are rings 3 and smaller? They can only be on peg B. Next, for n = 3, if ring 3 will be moved from A to B, where are rings 2 and 1? On peg C of course. If you continue to follow this pattern you can visualize what the recursive algorithm is doing. This approach differs from the novice's approach in that it looks at the last disk first and the first disk last.

-
``````void TOH(int n, int a, int b){
/*Assuming a as source stack numbered as 1, b as spare stack numbered as 2 and  c as target stack numbered as 3. So once we know values of a and b, we can determine c as there sum is a constant number (3+2+1=)6.
*/
int c = 6-a-b;
if(n==1){
cout<<"Move from "<<a<<" to "<<b<<"\n";
}
else{
// Move n-1 disks from 1st to 2nd stack. As we are not allowed to move more than one disks at a time, we do it by recursion. Breaking the problem into a simpler problem.
TOH(n-1, a, c);
// Move the last alone disk from 1st to 3rd stack.
TOH(1, a, b);
// Put n-1 disks from 2nd to 3rd stack. As we are not allowed to move more than one disks at a time, we do it by recursion. Breaking the problem into a simpler problem.
TOH(n-1, c, b);
}
}
int main() {

TOH(2, 1, 3);
cout<<"FINISHED                        \n";
TOH(3, 1, 3);
cout<<"FINISHED                        \n";
TOH(4, 1, 3);
return 0;
}
``````
-

The first recursive call moves all the pieces except the biggest one from source to by using dest as the auxilary pile. When done all the pieces except the biggest will lie on by and the biggest one is free. Now you can move the biggest one to dest and use another recursive call to move all the pieces from by to dest.

The recursive calls won't know anything about the biggest piece (i.e. they will ignore it), but that's ok because the recursive calls will only deal with the pieces that are smaller and thus can be moved onto and off the biggest piece freely.

-

As a CS student, you might have heard about Mathematical induction. The recursive solution of Tower of Hanoi works analogously - only different part is to really get not lost with B and C as were the full tower ends up.

-

In simple sense the idea is to fill another tower among the three defined towers in the same order of discs as present without a larger disc overlapping a small disc at any time during the procedure.

Let 'A' , 'B' and 'C' be three towers. 'A' will be the tower containing 'n' discs initially. 'B' can be used as intermediate tower and 'C' is the target tower.

The algo is as follows:

1. Move n-1 discs from tower 'A' to 'B' using 'C'
2. Move a disc from 'A' to 'C'
3. Move n-1 discs from tower 'B' to 'C' using 'A'

The code is as follows in java:

public class TowerOfHanoi {

``````public void TOH(int n, int A , int B , int C){
if (n>0){
TOH(n-1,A,C,B);
System.out.println("Move a disk from tower "+A +" to tower " + C);
TOH(n-1,B,A,C);
}
}

public static void main(String[] args) {
new TowerOfHanoi().TOH(3, 1, 2, 3);
}
``````

}

-

`Tower (N,source,aux.dest):`

1.

``````if N =1 Then
Write : Source -> dest
return
end of if
``````
2. move N-1 disk from peg source to peg aux

``````call Tower (N-1, source, dest, aux)
``````
3. write source -> dest
4. move N-1 disks from peg aux to peg dest

``````call Tower (N-1, source, dest, aux)
``````
5. return
-

/** * */ package com.test.recursion;

/** * @author kamals1986 The Recursive algorithm for Tower of Hanoi Problem The * algorithm grows by power(2,n). */ public class TowerOfHanoi {

``````private static String SOURCE_PEG = "B";

private static String SPARE_PEG = "C";

private static String TARGET_PEG = "A";

public void listSteps(int n, String source, String target, String spare) {
if (n == 1) {
System.out.println("Please move from Peg " + source + "\tTo Peg\t"
+ target);
} else {
listSteps(n - 1, source, spare, target);
listSteps(1, source, target, spare);
listSteps(n - 1, spare, target, source);
}
}

public static void main(String[] args) {
long startTime = System.currentTimeMillis();
new TowerOfHanoi().listSteps(18, SOURCE_PEG, TARGET_PEG, SPARE_PEG);

long endTime = System.currentTimeMillis();

System.out.println("Done in " + (endTime - startTime) / 1000
+ "\t seconds");
}
``````

}

-
Please explain your answer instead of just posting code on its own. – SuperBiasedMan May 21 '15 at 16:40

I am trying to get recursion too.

I found a way i think,

i think of it like a chain of steps(the step isnt constant it may change depending on the previous node)

I have to figure out 2 things:

1. previous node
2. step kind
3. after the step what else before call(this is the argument for the next call

example

factorial

1,2,6,24,120 ......... or

1,2*(1),3*(2*1),4*(3*2*1,5*(4*3*2*1)

step=multiple by last node

after the step what i need to get to the next node,abstract 1

ok

``````function =

n*f(n-1)

its 2 steps process
from a-->to step--->b
``````

i hoped this help,just think about 2 thniks,not how to get from node to node,but node-->step-->node

node-->step is the body of the function step-->node is the arguments of the other function

bye:) hope i helped

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