# Code Golf: Towers of Hanoi

## Rules

The Towers of Hanoi is a puzzle, and if you are not very familiar with it, here is how it works:

The play field consists of 3 rods, and x number of disks, each next one bigger than the previous one. The disks can be put on the rod, with these RULES:

• only one disk can be moved at once, and it must be moved on the top of another rod
• the disk must be taken from the top of a rod
• a disk can be moved somewhere, ONLY if the top-most disk at the target rod is bigger than the one to be moved

And finally - the play field STARTS like this:

• a rod, with x disks, sorted so the largest is on the bottom, and the smallest on the top
• an empty rod
• an empty rod

The GOAL of the game is to move the original "stack" of disks on another rod, that is - put all of the disks on another rod, so (again) the largest is on the bottom, and the smallest on the top

## Implementation

YOUR goal will be to make a program in programming language of your choice, that takes an input (described below) and outputs the steps necessary to solve the position.

As always, try to make it as short as possible.

Input

An example input:

4-3,7-6-5,2-1

Input is a string, consisting of 3 parts, separated by commas. The parts are a list of disks on each of the 3 rods. They are separated too, this time with hyphens ( - ), and each subpart is a number, the larger the number is, the larger the disk is.

So - for the above input, this would be a visual representation:

.               .               .
|          =====|=====          |
===|===      ======|======        =|=
====|====    =======|=======      ==|==

ROD 1           ROD 2           ROD 3

Output

As you can see in the above representation - the the left-most part of the input is rod number one, the middle is rod number two, and the last one is rod number 3.

The output of your program should look like this:

12,23,31,12,23,13

A list of numbers, separated by commas that defines the rod that a disk should be taken of, and the rod that the disk should be put on. There are only 3 rods, so there is just 6 possible combinations (because a disk has to be moved to another rod, not the same one):

12
13
21
23
31
32

## Notes

The input does not have to describe a field in "original" state - it can be mid-solved.

Your program can NOT produce null output. If the input IS in the original state, just put the disks to a DIFFERENT rod.

The input can have an empty rod(s), like these:

2-1,3,
,,1
4-3,,2-1

If the input is not in this formatted like that, your program can produce undefined behavior. So it can if the input is not valid (like bigger disk on a smaller one, missing disk, unsolvable). Input will always be valid.

Make sure the solution is as fast as possible (as little turns as possible) - that is, don't waste turns by "12,21,12"...

## Testing

So, I prepared this small flash for you, with which you can test if your program produced a good solution without writing it down or anything.

To use it, paste the input to the program to the INPUT field, and the output produced by your program to the PROCESS field. It will run a simulation, at speed which you can also change, with a visual representation, printing out any errors in the bottom part.

Hope it helps.

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## locked by Shog9♦Apr 3 at 16:49

This question exists because it has historical significance, but it is not considered a good, on-topic question for this site, so please do not use it as evidence that you can ask similar questions here. This question and its answers are frozen and cannot be changed. More info: help center.

Does the input have to be a valid state, or is a random state ok? Actually... now that I think about it... is there ALWAYS a solution to this puzzle, with ANY starting states or is it possible to create a starting state such that there is no solution? –  FrustratedWithFormsDesigner Dec 3 '10 at 16:40
Yes, the input is always valid - that is, there are all disks included from the smallest to the largest (no 1,2,4), they are ALWAYS following the rule - smaller atop bigger. There is ALWAYS a solution. Let me put that in there... –  Aurel300 Dec 3 '10 at 16:45
But every position has two possible "correct" answers. That is, if the input is "7-3,1,2", then the solution could be "31,21", or it could start with "23,12" and continue with the 123 additional steps required to move the rest of the disks to peg 2. Your problem definition has to include the direction in which a stack is to be moved. –  Jim Mischel Dec 3 '10 at 16:48
golf.shinh.org/p.rb?Tower+of+Hanoi –  mob Dec 3 '10 at 16:55
"Your program can NOT produce null output. If the input IS in the original state, just put the disks to a DIFFERENT rod" - This is a pain. I have a solution that solves anything not in the original state, and I'll have to special-case this :( –  The Archetypal Paul Dec 3 '10 at 22:32

## Perl, 209 (203) char

Rewritten to keep track of the location of each disk as opposed to the list of disks that are contained on each rod.

306 291 263 244 236 213 209 chars after removing unnecessary whitespace.

sub M{my(\$r,\$s)=@_;if(--\$m){M(\$r,\$r^\$s);\$_.=",\$r\$s";M(\$r^\$s,\$s)}s/(.),?\1//;
\$R[++\$m]=\$p}map@R[/\d+/g]=(++\$i)x99,split/,/,<>;do{1until
(\$n=\$R[1])-(\$p=\$R[++\$m]||\$n-1|2);M\$n,\$p}while 1<grep@R~~\$_,1..3;s/^,//;print

\$R[j]: the location of disk j

\$n: the location of disk #1

\$m: the number of disks to move

\$p: the location to move the disks to

&M(r,s): move \$m-1 disks from r to s. Appends to \$_ and sets @R

The substitution inside sub M optimizes the output, removing extraneous steps. It could be removed (12 characters) and the output would still be valid.

Another 12 characters can be removed if the perl interpreter is invoked with the command-line switch -apF,. With the extra 6 chars for the command-line switch, this gets us down to net 203 characters:

# invoke as   perl -apF, ...
sub M{my(\$r,\$s)=@_;if(--\$m){M(\$r,\$r^\$s);\$_=\$a.=",\$r\$s";M(\$r^\$s,\$s)}
s/(.),\1//;\$R[++\$m]=\$p}map@R[/\d+/g]=(++\$i)x99,@F;
do{1until(\$n=\$R[1])-(\$p=\$R[++\$m]||\$n-1|2);M\$n,\$p}while 1<grep@R~~\$_,1..3;s/^,//
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Does it move disks when the initial state is all disks on one rod? No Perl nearby and it's difficult to tell from the code :) –  The Archetypal Paul Dec 6 '10 at 23:15
Of course, didn't you see the do-while? :-) –  mob Dec 7 '10 at 0:01
Blast, I get mine down to 296 to beat your initial version, only for you to post an improvement. Still, I'm quite pleased with 292 for the Scala version, given it's not really known as a language suited to codegolf. It's past midnight here, I'm off... –  The Archetypal Paul Dec 7 '10 at 0:14

Here's a starter for 10, in Scala, revised a few times. I don't know of any issues, and I have no other ideas for further reducing the moves

Runs as a Scala script.

Bits of this are quite elegant (IMO) but other bits are an ugly hack

Shortest code (but non-optimal moves), tracking position of disks rather than list of disks on rods (idea shamelessly stolen from the Perl solution)

val r=args(0).split(",",-1);var d=Map{{for(q<-0 to 2 if""!=r(q);n<-r(q).split('-').map{_.toInt})yield(n,q+1)}:_*};val n=d.max._1;var m="";def s(f:Int,t:Int,n:Int):Unit=if(n!=0&&f!=t){s(f,6-f-t,n-1);d=d+(n->t);m=m+","+f+t;s(6-f-t,t,n-1)};for(c<- 2 to n)s(d(1),d(c),c-1);if(m=="")s(d(1),d(1)%3+1,n);println(m.tail.replaceAll("(.),?\\1",""))

Puzzle is taken from the command line.

338 bytes. Not too shabby since this is a statically typed language, and still relatively readable (if you replace ; with newlines)

Readable version follows (with more optimal moves)

val rods = args(0).split(",", -1);
var diskLocation = Map{
{
for (rod <-0 to 2 if rods(rod).nonEmpty;
n <-rods(rod).split('-').map{_.toInt})
yield(n, rod + 1)
}:_*
}

val nDisks = diskLocation.max._1

var moves = ""

def moveTower(start:Int, end:Int, n:Int):Unit =
if (n != 0) {
val other = 6 - start - end
moveTower(start, other, n - 1)
moveDisk(n, end)
moveTower(other, end, n - 1)
}

def moveDisk(n:Int, end:Int) = {
moves = moves + "," + diskLocation(n) + end
diskLocation = diskLocation.updated(n, end);
}

for (c <- 2 to nDisks) {
var firstLocation = diskLocation(1)
var nextLocation = diskLocation(c)
if (firstLocation != nextLocation) {
if (c != nDisks) {
val diskAfter = diskLocation(c + 1)
if (diskAfter != firstLocation && diskAfter != nextLocation) {
moveDisk(c, diskAfter)
nextLocation = diskAfter
}
}
moveTower(diskLocation(1), diskLocation(c), c - 1);
}
}

if (moves == "")
moveTower(diskLocation(1), diskLocation(1)%3 + 1, nDisks)

println(moves.tail.replaceAll("(.),?\\1",""))
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I wonder, how do you test a Scala script? I mean, I tried the compiler but that just makes a Java class file... Is there some tester? –  Aurel300 Dec 7 '10 at 17:05
Just scala hanoi.scala 7-5,4-3-2,1 –  The Archetypal Paul Dec 7 '10 at 18:00
Oh I see now! I might finally test your solution :D –  Aurel300 Dec 7 '10 at 18:05
Hmm. Bugs detected. Don't waste too much time testing (I think the really short version is OK, I've messed up the optimisations somewhere) –  The Archetypal Paul Dec 7 '10 at 18:06
First one has invalid output. Not lines, but a comma separated list (csv)... –  Aurel300 Dec 7 '10 at 18:09

### Perl 241 char

Certainly not the most efficient way, but it works.

Updated to suppress last comma.

map{map\$g[\$_]=\$i|0,/\d/g;\$i++}split\$,=',',<>;shift@g;@G=(0)x@g;@u=(1)x10;while(!\$G[@g]){\$G="@G";\$_="@g";\$i=0;\$j=\$G[0]+\$u[0];while(\$j>2||\$j<0){\$u[\$i++]*=-1;\$j=\$u[\$i]+\$G[\$i]}\$r=1+\$G[\$i].\$j+1;\$G[\$i]=\$j;\$p=1if/\$G/;push@o,\$r if\$p&&\$i++<@g}print@o

Same with whitespaces:

map{
map \$g[\$_]=\$i|0, /\d/g;
\$i++
}split\$,=',',<>;
shift@g;
@G=(0)x@g;
@u=(1)x10;
while(!\$G[@g]){
\$G="@G";
\$_="@g";
\$i=0;
\$j=\$G[0]+\$u[0];
while(\$j>2||\$j<0){
\$u[\$i++]*=-1;
\$j=\$u[\$i]+\$G[\$i]
}
\$r=1+\$G[\$i].\$j+1;
\$G[\$i]=\$j;
\$p=1if/\$G/;
push@o,\$r if\$p&&\$i++<@g
}
print@o

### Usage:

echo 5-2,3-1,4 | perl hanoi.pl

### Output:

21,23,12,23,12,32,21,23,12,23,12,32,21,32,12,23,21,32,21,32,12,23,12,32,21,23,12,23,21,32,21,32,12,23,21,32,21,32,12,23,12,32,21,23,12,23,12,32,21,32,12,23,21,32,21,23,12,23,12,32,21,23,12,23,21,32,21,32,12,23,21,32,21,32,12,23,12,32,21,23,12,23,21,32,21,32,12,23,21,32,21,23,12,23,12,32,21,23,12,23,12,32,21,32,12,23,21,32,21,23,12,23,12,32,21,23,12,23,12,32,21,32,12,23,21,32,21,32,12,23,12,32,21,23,12,23,21,32,21,32,12,23,21,32,21,23,12,23,12,32,21,23,12,23,12,32,21,32,12,23,21,32,21,23,12,23,12,32,21,23,12,23

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Has quite some problems. First - one VERY important - the output is NOT valid. It did (or just can? it happened anyway) output a comma in the end of the output string. Not right - it is not supposed to be there. Second - yeah, it is not quite optimal... But still - I wonder if you can't just make this a little bit better - I tried "3-2-1,," and it moved the tower first to row 2, then to row 3... ? –  Aurel300 Dec 7 '10 at 16:54
Typo - meant roD. :D –  Aurel300 Dec 7 '10 at 17:02
I've updated to suppress the last comma. –  Toto Dec 7 '10 at 17:18
Okay, it works now. –  Aurel300 Dec 7 '10 at 17:41
Produces no output when all disks start on the 3rd rod (,,2-1, for example)? –  mob Dec 8 '10 at 18:34

Attempt at Lua I've tried to implement the iterative solution from wikipedia, but it doesn't really work, but the time i'm spending on it is up, so I hope this inspires someone to adapt it. It does parse everything well, including empty columns. Extra goodie: it does pretty printing of the stacks as in the visual representation in the question.

-- Input "rod1,rod2,rod3" where rod? = a - seperated list of numbers, representing the disks.
print(p,q,r)
i=table.insert
u=unpack
function gen(t)
return function(v)i(t,tonumber(v)) end
end

function basic(t,n)
for k,v in pairs(t) do
print(k,"----")
for kk,vv in pairs(v) do print("\t",kk,vv) end
end
print'================'
end
function pretty(t,n)
local out={}
for k=1,n do out[k]={} end
for k=1,n do                -- K is each row
local line=out[k]
for l=1,3 do            -- L is each rod
local d=t[l][k]
if d~=1e9 then -- TODO Check if metahack necesarry
line[#line+1]=(" "):rep(n-d+1)
line[#line+1]=("="):rep(d)
line[#line+1]="|"
line[#line+1]=("="):rep(d)
line[#line+1]=(" "):rep(n-d+1)
line[#line+1]=" "
else
line[#line+1]=(" "):rep(2*n+4)
end
end
out[k]=table.concat(line)
end
for k=n,1,-1 do
io.write(out[k],"\n")
end
end
function T(f,...)
w=0
for k=1,3 do
l=({...})[k]
w=#l==0 and w or f(w,u(l))
end
return w
end

Stat=pretty
t={{},{},{}} --rods 1 - 3, discs ordered 1 = bottom
for k,v in pairs{p,q,r}do -- loop over strings
v:gsub('%d+',gen(t[k])) -- add decimal to rod
end
n=T(math.max,t[1],t[2],t[3]) -- Biggest disc = number of discs
--for k=1,3 do c=1*t[k][1] if n==c then A=k elseif m==c then C=k else B=k end end -- Rod where the biggest disc is (A)
for k=1,3 do setmetatable(t[k],{__index = function() return 1e9 end}) c=t[k] if c[#c]==1 then one=k end end -- locate smallest disc, and set index for nonexistant discs to 1e9
-- Locate second biggest disc (B), smallest stack = C -> move C to B
-- Algorithm:
-- uneven : move to the left, even: move to the right
-- move smallest, then move non-smallest.
-- repeat until done
--
-- For an even number of disks:
--
--     * make the legal move between pegs A and B
--     * make the legal move between pegs A and C
--     * make the legal move between pegs B and C
--     * repeat until complete
--
-- For an odd number of disks:
--
--     * make the legal move between pegs A and C
--     * make the legal move between pegs A and B
--     * make the legal move between pegs B and C
--     * repeat until complete
--
-- In each case, a total of 2n-1 moves are made.
d={{2,3,1},{3,1,2}}
s=d[math.fmod(n,2)+1] -- sense of movement -1 left (uneven # of discs), 1 right (even # of discs)
Stat(t,n)
for qqq=1,10 do
-- move smallest
d=s[one]
print(one,d)
if #t[d]==0 then print("skip rod",d,"next rod",s[d]) d=s[d] end-- if rod is empty, move to next in same direction
table.insert(t[d],table.remove(t[one])) --TODO Problem
print("Moved",one,"to",d)
one=d -- track the small disc
Stat(t,n)
if #t[d]==n then break end -- destination stack reached number of discs, break off.
-- find next valid move (compare the two non-previous-destination rod) to see which has the smallest disc, move disc to other rod.
z=0
for k=1,3 do
print("-- k="..k)
if k~=one then
if z>0 then
if t[k][#t[k]] > t[z][#t[z]] then   -- disc at rod z (source) is smaller than at k (destination)
d=k                                 -- destination = k
print("-- t["..k.."]>t["..z.."], d="..d..", z="..z)
else                                    -- disc at rod z (source) is bigger than at k (destination
d,z=z,k                             -- switch destination and source, so d will be z, and z will be the current rod
print("-- t["..k.."]<t["..z.."], d="..d..", z="..z)
end
else -- first of rods to compare
z=k
print("-- First rod to compare z="..z)
end
else
print("-- disc one at this location, skipping",k)
end
end
print("Will move from",z,"to",d)
table.insert(t[d],table.remove(t[z]))
Stat(t,n)
if #t[d]==n then break end -- destination stack reached number of discs, break off.
end
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