# Factorial Algorithms in different languages

I want to see all the different ways you can come up with, for a factorial subroutine, or program. The hope is that anyone can come here and see if they might want to learn a new language.

## Ideas:

• Procedural
• Functional
• Object Oriented
• One liners
• Obfuscated
• Oddball
• Polyglot

Basically I want to see an example, of different ways of writing an algorithm, and what they would look like in different languages.

Please limit it to one example per entry. I will allow you to have more than one example per answer, if you are trying to highlight a specific style, language, or just a well thought out idea that lends itself to being in one post.

The only real requirement is it must find the factorial of a given argument, in all languages represented.

# Be Creative!

## Recommended Guideline:

# Language Name: Optional Style type

- Optional bullet points

Code Goes Here

Other informational text goes here


I will ocasionally go along and edit any answer that does not have decent formatting.

-

## locked by WillMar 16 '12 at 20:24

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.

# Polyglot: 5 languages, all using bignums

So, I wrote a polyglot which works in the three languages I often write in, as well as one from my other answer to this question and one I just learned today. It's a standalone program, which reads a single line containing a nonnegative integer and prints a single line containing its factorial. Bignums are used in all languages, so the maximum computable factorial depends only on your computer's resources.

• Perl: uses built-in bignum package. Run with perl FILENAME.
• Haskell: uses built-in bignums. Run with runhugs FILENAME or your favorite compiler's equivalent.
• C++: requires GMP for bignum support. To compile with g++, use g++ -lgmpxx -lgmp -x c++ FILENAME to link against the right libraries. After compiling, run ./a.out. Or use your favorite compiler's equivalent.
• brainf*ck: I wrote some bignum support in this post. Using Muller's classic distribution, compile with bf < FILENAME > EXECUTABLE. Make the output executable and run it. Or use your favorite distribution.
• Whitespace: uses built-in bignum support. Run with wspace FILENAME.

Edit: added Whitespace as a fifth language. Incidentally, do not wrap the code with <code> tags; it breaks the Whitespace. Also, the code looks much nicer in fixed-width.

char //# b=0+0{- |0*/; #>>>>,----------[>>>>,--------
#define	a/*#--]>>>>++<<<<<<<<[>++++++[<------>-]<-<<<
#Perl	><><><>	 <> <> <<]>>>>[[>>+<<-]>>[<<+>+>-]<->
#C++	--><><>	<><><><	> < > <	+<[>>>>+<<<-<[-]]>[-]
#Whitespace	>>>>[-[>+<-]+>>>>]<<<<[<<<<]<<<<[<<<<
#brainf*ck > < ]>>>>>[>>>[>>>>]>>>>[>>>>]<<<<[[>>>>*/
exp; ;//;#+<<<<-]<<<<]>>>>+<<<<<<<[<<<<][.POLYGLOT^5.
#include <gmpxx.h>//]>>>>-[>>>[>>>>]>>>>[>>>>]<<<<[>>
#define	eval int	main()//>+<<<-]>>>[<<<+>>+>->
#include <iostream>//<]<-[>>+<<[-]]<<[<<<<]>>>>[>[>>>
#define	print std::cout	<< // >	<+<-]>[<<+>+>-]<<[>>>
#define	z std::cin>>//<< +<<<-]>>>[<<<+>>+>-]<->+++++
#define c/*++++[-<[-[>>>>+<<<<-]]>>>>[<<<<+>>>>-]<<*/
#define	abs int $n //>< <]<[>>+<<<<[-]>>[<<+>>-]]>>]< #define uc mpz_class fact(int$n){/*<<<[<<<<]<<<[<<
use bignum;sub#<<]>>>>-]>>>>]>>>[>[-]>>>]<<<<[>>+<<-]
z{$_[0+0]=readline(*STDIN);}sub fact{my($n)=shift;#>>
#[<<+>+>-]<->+<[>-<[-]]>[-<<-<<<<[>>+<<-]>>[<<+>+>+*/
24
$echo "5" | ./lazy facdec.lazy 120  Rather slow for numbers above, say, 5. The code is sort of bloated because we have to include library code for all of our own primitives (code written in Hazy, a lambda calculus interpreter and LC-to-Lazy K compiler written in Haskell). - This makes lisp/scheme look like normal code... – RCIX Sep 6 '09 at 16:11 ## XSLT 1.0 The input file, factorial.xml: <?xml version="1.0"?> <?xml-stylesheet href="factorial.xsl" type="text/xsl" ?> <n> 20 </n>  The XSLT file, factorial.xsl: <?xml version="1.0"?> <xsl:stylesheet version="1.0" xmlns:xsl="http://www.w3.org/1999/XSL/Transform" xmlns:msxsl="urn:schemas-microsoft-com:xslt" > <xsl:output method="text"/> <!-- 0! = 1 --> <xsl:template match="text()[. = 0]"> 1 </xsl:template> <!-- n! = (n-1)! * n--> <xsl:template match="text()[. > 0]"> <xsl:variable name="x"> <xsl:apply-templates select="msxsl:node-set( . - 1 )/text()"/> </xsl:variable> <xsl:value-of select="$x * ."/>
</xsl:template>
<!-- Calculate n! -->
<xsl:template match="/n">
<xsl:apply-templates select="text()"/>
</xsl:template>
</xsl:stylesheet>


Save both files in the same directory and open factorial.xml in IE.

-
I just died a little. – Josh Lee Nov 18 '09 at 23:13

# Python: Functional, One-liner

factorial = lambda n: reduce(lambda x,y: x*y, range(1, n+1), 1)


NOTE:

• It supports big integers. Example:

print factorial(100)
93326215443944152681699238856266700490715968264381621468592963895217599993229915\
608941463976156518286253697920827223758251185210916864000000000000000000000000


• It does not work for n < 0.
-
operator.mul would be much faster than lambda x,y: x*y. – spiv Oct 20 '08 at 10:05
@spiv: x*y is 1.10-1.6 times slower then mul. math.factorial is faster then both. And memoized factorial is faster then math.factorial, etc. The question is not about performance. – J.F. Sebastian Oct 22 '08 at 16:52

# APL (oddball/one-liner):

×/⍳X

1. ⍳X expands X into an array of the integers 1..X
2. ×/ multiplies every element in the array

Or with the built-in operator:

!X

-

# Perl6

sub factorial ($n) { [*] 1..$n }


I hardly know about Perl6. But I guess this [*] operator is same as Haskell's product.

This code runs on Pugs, and maybe Parrot (I didn't check it.)

Edit

This code also works.

sub postfix:<!> ($n) { [*] 1..$n }

# This function(?) call like below ... It looks like mathematical notation.
say 10!;

-

# x86-64 Assembly: Procedural

You can call this from C (only tested with GCC on linux amd64). Assembly was assembled with nasm.

section .text
global factorial
; factorial in x86-64 - n is passed in via RDI register
; takes a 64-bit unsigned integer
; returns a 64-bit unsigned integer in RAX register
; C declaration in GCC:
;   extern unsigned long long factorial(unsigned long long n);
factorial:
enter 0,0
; n is placed in rdi by caller
mov rax, 1 ; factorial = 1
mov rcx, 2 ; i = 2
loopstart:
cmp rcx, rdi
ja loopend
mul rcx ; factorial *= i
inc rcx
jmp loopstart
loopend:
leave
ret

-

## Recursively in Inform 7

(it reminds you of COBOL because it's for writing text adventures; proportional font is deliberate):

To decide what number is the factorial of (n - a number):
if n is zero, decide on one;
otherwise decide on the factorial of (n minus one) times n.

If you want to actually call this function ("phrase") from a game you need to define an action and grammar rule:

"The factorial game" [this must be the first line of the source]

There is a room. [there has to be at least one!]

Factorialing is an action applying to a number.

Understand "factorial [a number]" as factorialing.

Carry out factorialing:
Let n be the factorial of the number understood;
Say "It's [n]".

-

# C#: LINQ

    public static int factorial(int n)
{
return (Enumerable.Range(1, n).Aggregate(1, (previous, value) => previous * value));
}

-
public static long factorial(byte n){} – Chris Charabaruk Nov 22 '08 at 8:17

# Erlang: tail recursive

fac(0) -> 1;
fac(N) when N > 0 -> fac(N, 1).

fac(1, R) -> R;
fac(N, R) -> fac(N - 1, R * N).

-

ones = 1 : ones
integers   = head ones     : zipWith (+) integers   (tail ones)
factorials = head integers : zipWith (*) factorials (tail integers)

-

# Brainf*ck

+++++
>+<[[->>>>+<<<<]>>>>[-<<<<+>>+>>]<<<<>[->>+<<]<>>>[-<[->>+<<]>>[-<<+<+>>>]<]<[-]><<<-]


Written by Michael Reitzenstein.

-

# BASIC: old school

10 HOME
20 INPUT N
30 LET ANS = 1
40 FOR I = 1 TO N
50   ANS = ANS * I
60 NEXT I
70 PRINT ANS

-
wow, good old times. :-) – Paulo Guedes Nov 14 '08 at 12:36

Batch (NT):

@echo off

set n=%1
set result=1

for /l %%i in (%n%, -1, 1) do (
set /a result=result * %%i
)

echo %result%


Usage: C:>factorial.bat 15

-

# F#: Functional

### Straight forward:

let rec fact x =
if   x < 0 then failwith "Invalid value."
elif x = 0 then 1
else x * fact (x - 1)


### Getting fancy:

let fact x = [1 .. x] |> List.fold_left ( * ) 1

-

# Recursive Prolog

fac(0,1).
fac(N,X) :- N1 is N -1, fac(N1, T), X is N * T.


# Tail Recursive Prolog

fac(0,N,N).
fac(X,N,T) :- A is N * X, X1 is X - 1, fac(X1,A,T).
fac(N,T) :- fac(N,1,T).

-

# ruby recursive

(factorial=Hash.new{|h,k|k*h[k-1]})[1]=1


usage:

factorial[5]
=> 120

-
I would write that as (f=Hash.new{|h,k|h[k]=k*h[k-1]})[1]=1 or otherwise the calculated values are not stored – martinus Jan 29 '09 at 22:52

Scheme

Here is a simple recursive definition:

(define (factorial x)
(if (= x 0) 1
(* x (factorial (- x 1)))))


In Scheme tail-recursive functions use constant stack space. Here is a version of factorial that is tail-recursive:

(define factorial
(letrec ((fact (lambda (x accum)
(if (= x 0) accum
(fact (- x 1) (* accum x))))))
(lambda (x)
(fact x 1))))

-

Oddball examples? What about using the gamma function! Since, Gamma n = (n-1)!.

## OCaml: Using Gamma

let rec gamma z =
let pi = 4.0 *. atan 1.0 in
if z < 0.5 then
pi /. ((sin (pi*.z)) *. (gamma (1.0 -. z)))
else
let consts = [| 0.99999999999980993; 676.5203681218851; -1259.1392167224028;
771.32342877765313; -176.61502916214059; 12.507343278686905;
-0.13857109526572012; 9.9843695780195716e-6; 1.5056327351493116e-7;
|]
in
let z = z -. 1.0 in
let results = Array.fold_right
(fun x y -> x +. y)
(Array.mapi
(fun i x -> if i = 0 then x else x /. (z+.(float i)))
consts
)
0.0
in
let x = z +. (float (Array.length consts)) -. 1.5 in
let final = (sqrt (2.0*.pi)) *.
(x ** (z+.0.5)) *.
(exp (-.x)) *. result
in
final

let factorial_gamma n = int_of_float (gamma (float (n+1)))

-

fac n = if n == 0
then 1
else n * fac (n-1)


Sophomore Haskell programmer, at MIT (studied Scheme as a freshman)

fac = (\(n) ->
(if ((==) n 0)
then 1
else ((*) n (fac ((-) n 1)))))


Junior Haskell programmer (beginning Peano player)

fac  0    =  1
fac (n+1) = (n+1) * fac n


Another junior Haskell programmer (read that n+k patterns are “a disgusting part of Haskell” [1] and joined the “Ban n+k patterns”-movement [2])

fac 0 = 1
fac n = n * fac (n-1)


Senior Haskell programmer (voted for Nixon Buchanan Bush — “leans right”)

fac n = foldr (*) 1 [1..n]


Another senior Haskell programmer (voted for McGovern Biafra Nader — “leans left”)

fac n = foldl (*) 1 [1..n]


Yet another senior Haskell programmer (leaned so far right he came back left again!)

-- using foldr to simulate foldl

fac n = foldr (\x g n -> g (x*n)) id [1..n] 1


Memoizing Haskell programmer (takes Ginkgo Biloba daily)

facs = scanl (*) 1 [1..]

fac n = facs !! n


Pointless (ahem) “Points-free” Haskell programmer (studied at Oxford)

fac = foldr (*) 1 . enumFromTo 1


Iterative Haskell programmer (former Pascal programmer)

fac n = result (for init next done)
where init = (0,1)
next   (i,m) = (i+1, m * (i+1))
done   (i,_) = i==n
result (_,m) = m

for i n d = until d n i


Iterative one-liner Haskell programmer (former APL and C programmer)

fac n = snd (until ((>n) . fst) (\(i,m) -> (i+1, i*m)) (1,1))


Accumulating Haskell programmer (building up to a quick climax)

facAcc a 0 = a
facAcc a n = facAcc (n*a) (n-1)

fac = facAcc 1


Continuation-passing Haskell programmer (raised RABBITS in early years, then moved to New Jersey)

facCps k 0 = k 1
facCps k n = facCps (k . (n *)) (n-1)

fac = facCps id


Boy Scout Haskell programmer (likes tying knots; always “reverent,” he belongs to the Church of the Least Fixed-Point [8])

y f = f (y f)

fac = y (\f n -> if (n==0) then 1 else n * f (n-1))


Combinatory Haskell programmer (eschews variables, if not obfuscation; all this currying’s just a phase, though it seldom hinders)

s f g x = f x (g x)

k x y   = x

b f g x = f (g x)

c f g x = f x g

y f     = f (y f)

cond p f g x = if p x then f x else g x

fac  = y (b (cond ((==) 0) (k 1)) (b (s (*)) (c b pred)))


List-encoding Haskell programmer (prefers to count in unary)

arb = ()    -- "undefined" is also a good RHS, as is "arb" :)

listenc n = replicate n arb
listprj f = length . f . listenc

listprod xs ys = [ i (x,y) | x<-xs, y<-ys ]
where i _ = arb

facl []         = listenc  1
facl n@(_:pred) = listprod n (facl pred)

fac = listprj facl


Interpretive Haskell programmer (never “met a language” he didn't like)

-- a dynamically-typed term language

data Term = Occ Var
| Use Prim
| Lit Integer
| App Term Term
| Abs Var  Term
| Rec Var  Term

type Var  = String
type Prim = String

-- a domain of values, including functions

data Value = Num  Integer
| Bool Bool
| Fun (Value -> Value)

instance Show Value where
show (Num  n) = show n
show (Bool b) = show b
show (Fun  _) = ""

prjFun (Fun f) = f
prjFun  _      = error "bad function value"

prjNum (Num n) = n
prjNum  _      = error "bad numeric value"

prjBool (Bool b) = b
prjBool  _       = error "bad boolean value"

binOp inj f = Fun (\i -> (Fun (\j -> inj (f (prjNum i) (prjNum j)))))

-- environments mapping variables to values

type Env = [(Var, Value)]

getval x env =  case lookup x env of
Just v  -> v
Nothing -> error ("no value for " ++ x)

-- an environment-based evaluation function

eval env (Occ x) = getval x env
eval env (Use c) = getval c prims
eval env (Lit k) = Num k
eval env (App m n) = prjFun (eval env m) (eval env n)
eval env (Abs x m) = Fun  (\v -> eval ((x,v) : env) m)
eval env (Rec x m) = f where f = eval ((x,f) : env) m

-- a (fixed) "environment" of language primitives

times = binOp Num  (*)

minus = binOp Num  (-)
equal = binOp Bool (==)
cond  = Fun (\b -> Fun (\x -> Fun (\y -> if (prjBool b) then x else y)))

prims = [ ("*", times), ("-", minus), ("==", equal), ("if", cond) ]

-- a term representing factorial and a "wrapper" for evaluation

facTerm = Rec "f" (Abs "n"
(App (App (App (Use "if")
(App (App (Use "==") (Occ "n")) (Lit 0))) (Lit 1))
(App (App (Use "*")  (Occ "n"))
(App (Occ "f")
(App (App (Use "-") (Occ "n")) (Lit 1))))))

fac n = prjNum (eval [] (App facTerm (Lit n)))


Static Haskell programmer (he does it with class, he’s got that fundep Jones! After Thomas Hallgren’s “Fun with Functional Dependencies” [7])

-- static Peano constructors and numerals

data Zero
data Succ n

type One   = Succ Zero
type Two   = Succ One
type Three = Succ Two
type Four  = Succ Three

-- dynamic representatives for static Peanos

zero  = undefined :: Zero
one   = undefined :: One
two   = undefined :: Two
three = undefined :: Three
four  = undefined :: Four

class Add a b c | a b -> c where
add :: a -> b -> c

instance Add a b c => Add (Succ a) b (Succ c)

-- multiplication, a la Prolog

class Mul a b c | a b -> c where
mul :: a -> b -> c

instance                           Mul  Zero    b Zero
instance (Mul a b c, Add b c d) => Mul (Succ a) b d

-- factorial, a la Prolog

class Fac a b | a -> b where
fac :: a -> b

instance                                Fac  Zero    One
instance (Fac n k, Mul (Succ n) k m) => Fac (Succ n) m

-- try, for "instance" (sorry):
--
--     :t fac four


-- the natural numbers, a la Peano

data Nat = Zero | Succ Nat

-- iteration and some applications

iter z s  Zero    = z
iter z s (Succ n) = s (iter z s n)

plus n = iter n     Succ
mult n = iter Zero (plus n)

-- primitive recursion

primrec z s  Zero    = z
primrec z s (Succ n) = s n (primrec z s n)

-- two versions of factorial

fac  = snd . iter (one, one) (\(a,b) -> (Succ a, mult a b))
fac' = primrec one (mult . Succ)

-- for convenience and testing (try e.g. "fac five")

int = iter 0 (1+)

instance Show Nat where
show = show . int

(zero : one : two : three : four : five : _) = iterate Succ Zero


Origamist Haskell programmer (always starts out with the “basic Bird fold”)

-- (curried, list) fold and an application

fold c n []     = n
fold c n (x:xs) = c x (fold c n xs)

prod = fold (*) 1

-- (curried, boolean-based, list) unfold and an application

unfold p f g x =
if p x
then []
else f x : unfold p f g (g x)

downfrom = unfold (==0) id pred

-- hylomorphisms, as-is or "unfolded" (ouch! sorry ...)

refold  c n p f g   = fold c n . unfold p f g

refold' c n p f g x =
if p x
then n
else c (f x) (refold' c n p f g (g x))

-- several versions of factorial, all (extensionally) equivalent

fac   = prod . downfrom
fac'  = refold  (*) 1 (==0) id pred
fac'' = refold' (*) 1 (==0) id pred


Cartesianally-inclined Haskell programmer (prefers Greek food, avoids the spicy Indian stuff; inspired by Lex Augusteijn’s “Sorting Morphisms” [3])

-- (product-based, list) catamorphisms and an application

cata (n,c) []     = n
cata (n,c) (x:xs) = c (x, cata (n,c) xs)

mult = uncurry (*)
prod = cata (1, mult)

-- (co-product-based, list) anamorphisms and an application

ana f = either (const []) (cons . pair (id, ana f)) . f

cons = uncurry (:)

downfrom = ana uncount

uncount 0 = Left  ()
uncount n = Right (n, n-1)

-- two variations on list hylomorphisms

hylo  f  g    = cata g . ana f

hylo' f (n,c) = either (const n) (c . pair (id, hylo' f (c,n))) . f

pair (f,g) (x,y) = (f x, g y)

-- several versions of factorial, all (extensionally) equivalent

fac   = prod . downfrom
fac'  = hylo  uncount (1, mult)
fac'' = hylo' uncount (1, mult)


Ph.D. Haskell programmer (ate so many bananas that his eyes bugged out, now he needs new lenses!)

-- explicit type recursion based on functors

newtype Mu f = Mu (f (Mu f))  deriving Show

in      x  = Mu x
out (Mu x) = x

-- cata- and ana-morphisms, now for *arbitrary* (regular) base functors

cata phi = phi . fmap (cata phi) . out
ana  psi = in  . fmap (ana  psi) . psi

-- base functor and data type for natural numbers,
-- using a curried elimination operator

data N b = Zero | Succ b  deriving Show

instance Functor N where
fmap f = nelim Zero (Succ . f)

nelim z s  Zero    = z
nelim z s (Succ n) = s n

type Nat = Mu N

-- conversion to internal numbers, conveniences and applications

int = cata (nelim 0 (1+))

instance Show Nat where
show = show . int

zero = in   Zero
suck = in . Succ       -- pardon my "French" (Prelude conflict)

plus n = cata (nelim n     suck   )
mult n = cata (nelim zero (plus n))

-- base functor and data type for lists

data L a b = Nil | Cons a b  deriving Show

instance Functor (L a) where
fmap f = lelim Nil (\a b -> Cons a (f b))

lelim n c  Nil       = n
lelim n c (Cons a b) = c a b

type List a = Mu (L a)

-- conversion to internal lists, conveniences and applications

list = cata (lelim [] (:))

instance Show a => Show (List a) where
show = show . list

prod = cata (lelim (suck zero) mult)

upto = ana (nelim Nil (diag (Cons . suck)) . out)

diag f x = f x x

fac = prod . upto


Post-doc Haskell programmer (from Uustalu, Vene and Pardo’s “Recursion Schemes from Comonads” [4])

-- explicit type recursion with functors and catamorphisms

newtype Mu f = In (f (Mu f))

unIn (In x) = x

cata phi = phi . fmap (cata phi) . unIn

-- base functor and data type for natural numbers,
-- using locally-defined "eliminators"

data N c = Z | S c

instance Functor N where
fmap g  Z    = Z
fmap g (S x) = S (g x)

type Nat = Mu N

zero   = In  Z
suck n = In (S n)

add m = cata phi where
phi  Z    = m
phi (S f) = suck f

mult m = cata phi where
phi  Z    = zero
phi (S f) = add m f

-- explicit products and their functorial action

data Prod e c = Pair c e

outl (Pair x y) = x
outr (Pair x y) = y

fork f g x = Pair (f x) (g x)

instance Functor (Prod e) where
fmap g = fork (g . outl) outr

class Functor n => Comonad n where
extr :: n a -> a
dupl :: n a -> n (n a)

extr = outl
dupl = fork id outr

-- generalized catamorphisms, zygomorphisms and paramorphisms

gcata :: (Functor f, Comonad n) =>
(forall a. f (n a) -> n (f a))
-> (f (n c) -> c) -> Mu f -> c

gcata dist phi = extr . cata (fmap phi . dist . fmap dupl)

zygo chi = gcata (fork (fmap outl) (chi . fmap outr))

para :: Functor f => (f (Prod (Mu f) c) -> c) -> Mu f -> c
para = zygo In

-- factorial, the *hard* way!

fac = para phi where
phi  Z             = suck zero
phi (S (Pair f n)) = mult f (suck n)

-- for convenience and testing

int = cata phi where
phi  Z    = 0
phi (S f) = 1 + f

instance Show (Mu N) where
show = show . int


Tenured professor (teaching Haskell to freshmen)

fac n = product [1..n]

-
Wow! I have no idea what he's talking about, but I'm sure if I understood it it would be really funny. – John M Gant Nov 16 '09 at 16:46

# D Templates: Functional

template factorial(int n : 1)
{
const factorial = 1;
}

template factorial(int n)
{
const factorial =
n * factorial!(n-1);
}


or

template factorial(int n)
{
static if(n == 1)
const factorial = 1;
else
const factorial =
n * factorial!(n-1);
}


Used like this:

factorial!(5)

-

# Java 1.6: recursive, memoized (for subsequent calls)

private static Map<BigInteger, BigInteger> _results = new HashMap()

public static BigInteger factorial(BigInteger n){
if (0 >= n.compareTo(BigInteger.ONE))
return BigInteger.ONE.max(n);
if (_results.containsKey(n))
return _results.get(n);
BigInteger result = factorial(n.subtract(BigInteger.ONE)).multiply(n);
_results.put(n, result);
return result;
}

-

PowerShell

function factorial( [int] $n ) {$result = 1;

if ( $n -gt 1 ) {$result = $n * ( factorial ($n - 1 ) )
}

$result }  Here's a one-liner: $n..1 | % {$result = 1}{$result *= $_}{$result}

-

# Bash: Recursive

In bash and recursive, but with the added advantage that it deals with each iteration in a new process. The max it can calculate is !20 before overflowing, but you can still run it for big numbers if you don't care about the answer and want your system to fall over ;)

#!/bin/bash
echo $(($1 * ( [[ $1 -gt 1 ]] && ./$0 $(($1 - 1)) ) || echo 1));

-