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.