# 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.

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show 1 more comment

## 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#<<]>>>>-]>>>>]>>>[>[-]>>>]<<<<[>>+<<-]
#[<<+>+>-]<->+<[>-<[-]]>[-<<-<<<<[>>+<<-]>>[<<+>+>+*/
uc;if(\$n==0){return 1;}return \$n*fact(\$n-1);	}//;#
eval{abs;z(\$n);print fact(\$n);print("\n")/*2;};#-]<->
'+<[>-<[-]]>]<<[<<<<]<<<<-[>>+<<-]>>[<<+>+>-]+<[>-+++
-}--	<[-]]>[-<<++++++++++<<<<-[>>+<<-]>>[<<+>+>-++
fact 0	= 1 -- ><><><><	> <><><	]+<[>-<[-]]>]<<[<<+ +
fact	n=n*fact(n-1){-<<]>>>>[[>>+<<-]>>[<<+>+++>+-}
{-x<-<[-]]>[-]>>]>]>>>[>>>>]<<<<[>+++++++[<+++++++>-]
<--.<<<<]+written+by+++A+Rex+++2009+.';#+++x-}--x*/;}
```
-
The largest factorial computable in one second (not counting output) on my computer by the various languages in this implementation: C++ gets 45000!, Haskell gets 35000!, Whitespace gets 11000!, Perl gets 2000!, and brainf*ck gets 350!. –  A. Rex Jan 14 '09 at 5:16
WTF +1 ~ –  Tim Matthews Jan 30 '09 at 11:56
After staring at this code for a few minutes, my eyes kept drifting unexplicably to the `offensive?` link.... –  AShelly Jan 30 '09 at 23:29
This is insane. –  GManNickG Jun 6 '09 at 20:44
This should be measured with WTFs per second. –  Arnis L. Jul 22 '09 at 19:42
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Vb6 :

``````Private Function factCalculation(ByVal Number%)
Dim intNum%
intNum = 1
For i = 2 To Number
intNum = intNum * Number
Next i
return intNum
End Function

Dim FactResult% : FactResult = factCalculation(3) 'e.g
Print FactResult
End Sub
``````
-

Python: functional, recursive one-liner using short circuit boolean evaluation.

``````    factorial = lambda n: ((n <= 1) and 1) or factorial(n-1) * n
``````
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C++ constexpr

``````constexpr uint64_t fact(uint32_t n)
{
return  (n==0) ? 1:n*fact(n-1);
}
``````
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# PHP - 59 chars

``````function f(\$n){return array_reduce(range(1,\$n),'bcmul',1);}
``````

# Improved Version - 27 chars

``````array_product(range(1,\$n));
``````
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# 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

# T-SQL: Recursive CTE

Inline table function using a recursive common table expression. SQL Server 2005 and up.

``````CREATE FUNCTION dbo.Factorial(@n int) RETURNS TABLE
AS
RETURN
WITH RecursiveCTE (N, Value) AS
(
SELECT 1, CAST(1 AS decimal(38,0))
UNION ALL
SELECT N+1, CAST(Value*(N+1) AS decimal(38,0))
FROM RecursiveCTE
)
SELECT TOP 1 Value
FROM RecursiveCTE
WHERE N = @n
``````
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# C++: Template Metaprogramming

Uses the classic enum hack.

``````template<unsigned int n>
struct factorial {
enum { result = n * factorial<n - 1>::result };
};

template<>
struct factorial<0> {
enum { result = 1 };
};
``````

Usage.

``````const unsigned int x = factorial<4>::result;
``````

Factorial is calculated completely at compile time based on the template parameter n. Therefore, factorial<4>::result is a constant once the compiler has done its work.

-
A caveat with this solution is that, the ANSI C++ standard only enforces compilers to execute this kind of compile-time functions up to a limit - I believe 20 - of recursion levels. After that, you're in uncharted territory, left to the mercy of compiler creators. –  Joe Pineda Sep 27 '08 at 0:25
I think factorial<20> is the largest factorial that can be represented by a signed 64-bit long, so that works out okay –  Kip Oct 6 '08 at 16:31
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Java Script: Creative method using "interview question" counting bits fnc.

``````function nu(x)
{
var r=0
while( x ) {
x &= x-1
r++
}
return r
}

function fac(n)
{
var r= Math.pow(2,n-nu(n))

for ( var i=3 ; i <= n ; i+= 2 )
r *= Math.pow(i,Math.floor(Math.log(n/i)/Math.LN2)+1)
return r
}
``````

Works up to 21! then Chrome switches to scientific notation. Inspiration thanks lack of sleep and Knuth, et al's "concrete mathematics".

-

# Scheme evolution

## Regular Scheme program:

``````(define factorial
(lambda (n)
(if (= n 0)
1
(* n (factorial (- n 1))))))
``````

Should work, but notice that calling this function on large numbers will extend the stack on every recursion, which is bad in languages like C and Java.

## Continuation-passing style

``````(define factorial
(lambda (n)
(factorial_cps n (lambda (k) k))))

(define factorial_cps
(lambda (n k)
(if (zero? n)
(k 1)
(factorial (- n 1) (lambda (v)
(k (* n v)))))))
``````

Ah, this way, we don't grow our stack every recursion because we can extend a continuation instead. However, C doesn't have continuations.

## Representation-independent CPS

``````(define factorial
(lambda (n)
(factorial_cps n (k_))))

(define factorial_cps
(lambda (n k)
(if (zero? n)
(apply_k 1)
(factorial (- n 1) (k_extend n k))))

(define apply_k
(lambda (ko v)
(ko v)))
(define kt_empty
(lambda ()
(lambda (v) v)))
(define kt_extend
(lambda ()
(lambda (v)
(apply_k k (* n v)))))
``````

Notice that responsibility for representation of the continuations used in the original CPS program has been shifted to the `kt_` helper procedures.

## Representation-independent CPS using ParentheC unions

Since representation of the continuations is in the helper procedures, we can switch to using ParentheC instead, with `kt_` being a type designator.

``````(define factorial
(lambda (n)
(factorial_cps n (kt_empty))))

(define factorial_cps
(lambda (n k)
(if (zero? n)
(apply_k 1)
(factorial (- n 1) (kt_extend n k))))

(define-union kt
(empty)
(extend n k))
(define apply_k
(lambda ()
(union-case kh kt
[(empty) v]
[(extend n k) (begin
(set! kh k)
(set! v (* n v))
(apply_k))])))
``````

## Trampolined, registerized ParentheC program

That's not enough. We now replace all function calls by instead setting global variables and a program counter. Procedures are now labels suitable for GOTO statements.

``````(define-registers n k kh v)
(define-program-counter pc)

(define-label main
(begin
(set! n 5) ; what is the factorial of 5??
(set! pc factorial_cps)
(mount-trampoline kt_empty k pc)
(printf "Factorial of 5: ~d\n" v)))

(define-label factorial_cps
(if (zero? n)
(begin
(set! kh k)
(set! v 1)
(set! pc apply_k))
(begin
(set! k (kt_extend n k))
(set! n (- n 1))
(set! pc factorial_cps))))

(define-union kt
(empty dismount) ; get off the trampoline!
(extend n k))

(define-label apply_k
(union-case kh kt
[(empty dismount) (dismount-trampoline dismount)]
[(extend n k) (begin
(set! kh k)
(set! v (* n v))
(set! pc apply_k))]))
``````

Oh look, we have a `main` procedure now too. Now all that's left to do is save this file as `fact5.pc` and run it through ParentheC's pc2c:

``````> (load "pc2c.ss")
> (pc2c "fact5.pc" "fact5.c" "fact5.h")
``````

Could it be? We got `fact5.c` and `fact5.h`. Let's see...

``````\$ gcc fact5.c -o fact5
\$ ./fact5
Factorial of 5: 120
``````

Success! We have converted a recursive Scheme program into a non-recursive C program! And it only took several hours and many forehead-shaped impressions in the wall to do it! For convenience, fact5.c and and fact5.h.

-

In Io:

``````factorial := method(n,
if (list(0, 1) contains(n),
1,
n * factorial(n - 1)
)
)
``````
-

## Oh fork() its another example in Perl

This will make use of your multiple core CPUs... although perhaps not in the most effective manner. The open statement clones the process with fork and opens a pipe from the child process to the parent. The work of multiplying numbers 2 at a time is split among a tree of very short lived processes. Of course, this example is a bit silly. The point is that if you actually had more difficult calculations to do then this example illustrates one way to divide up the work in parallel.

``````#!/usr/bin/perl -w

use strict;
use bigint;

print STDOUT &main::rangeProduct(1,\$ARGV[0])."\n";

sub main::rangeProduct {
my(\$l, \$h) = @_;
return \$l    if (\$l==\$h);
return \$l*\$h if (\$l==(\$h-1));
# arghhh - multiplying more than 2 numbers at a time is too much work
# find the midpoint and split the work up :-)
my \$m = int((\$h+\$l)/2);
my \$pid = open(my \$KID, "-|");
if (\$pid){ # parent
my \$X = &main::rangeProduct(\$l,\$m);
my \$Y = <\$KID>;
chomp(\$Y);
close(\$KID);
die "kid failed" unless defined \$Y;
return \$X*\$Y;
} else {
# kid
print STDOUT &main::rangeProduct(\$m+1,\$h)."\n";
exit(0);
}
}
``````
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FORTH, iterative 1 liner

``````: FACT 1 SWAP 1 + 1 DO I * LOOP ;
``````
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# Golfscript: designed for golfing, of course

``````~),1>{*}*
``````
• `~` evaluates the input string (to an integer)
• `)` increments the number
• `,` is range (4, becomes [0 1 2 3])
• `1>` selects values whose index is 1 or bigger
• `{*}*` folds multiplication over the list
• Stack contents are printed when the program terminates.

To run:

``````echo 5 | ruby gs.rb fact.gs
``````
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## CLOS

I see Common Lisp solutions abusing recursion, LOOP, and even FORMAT. I guess it's time for somebody to write a solution that abuses CLOS!

``````(defgeneric factorial (n))
(defmethod factorial ((n (eql 0))) 1)
(defmethod factorial ((n integer)) (* n (factorial (1- n))))
``````

(Can your favorite language's object system dispatcher do that?)

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# Befunge:

``````0&>:1-:v v *_\$.@
^    _\$>\:^
``````
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# Scala

The factorial can be defined functionally as:

``````def fact(n: Int): BigInt = 1 to n reduceLeft(_*_)
``````

or more traditionally as

``````def fact(n: Int): BigInt = if (n == 0) 1 else fact(n-1) * n
``````

and we can make ! a valid method on Ints:

``````object extendBuiltins extends Application {

class Factorizer(n: Int) {
def ! = 1 to n reduceLeft(_*_)
}

implicit def int2fact(n: Int) = new Factorizer(n)

println("10! = " + (10!))
}
``````
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show 1 more comment

``````factorial n = product [1..n]
``````
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# Lambda Calculus

Input and output are Church numerals (i.e. natural number `k` is `\f n. f^k n`; so `3 = \f n. f (f (f n)))`

``````(\x. x x) (\y f. f (y y f)) (\y n. n (\x y z. z) (\x y. x) (\f n. f n) (\f. n (y (\f m. n (\g h. h (g f)) (\x. m) (\x. x)) f)))
``````
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# Brainf*ck

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

Written by Michael Reitzenstein.

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show 2 more comments

## SETL

...where Haskell and Python borrowed their list comprehensions from.

``````proc factorial(n);
return 1 */ {1..n};
end factorial;
``````

And the built-in `INTEGER` type is arbitrary-precision, so this will work for any positive `n`.

-

*NIX Shell

Linux version:

``````seq -s'*' 42 | bc
``````

BSD version:

``````jot -s'*' 42 | bc
``````
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Python:

``````def factorial(n):
return reduce(lambda x, y: x * y,range(1, n + 1))
``````
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Here's my proposal. Runs in Mathematica, works fine:

``````gen[f_, n_] := Module[{id = -1, val = Table[Null, {n}], visit},
visit[k_] := Module[{t},
id++; If[k != 0, val[[k]] = id];
If[id == n, f[val]];
Do[If[val[[t]] == Null, visit[t]], {t, 1, n}];
id--; val[[k]] = Null;];
visit[0];
]

Factorial[n_] := Module[{res=0}, gen[res++&, n]; res]
``````

Update Ok, here's how it works: the visit function is from Sedgewick's Algorithm book, it "visits" all permutations of length n. Upon the visit, it calls function f with the permutation as an argument.

So, Factorial enumerates all permutations of length n, and for each permutation the counter res is increased, thus computing n! in O(n+1)! time.

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# Perl 6: Functional

``````multi factorial ( Int \$n where { \$n <= 0 } ){
return 1;
}
multi factorial ( Int \$n ){
return \$n * factorial( \$n-1 );
}
``````

This will also work:

``````multi factorial(0) { 1 }
multi factorial(Int \$n) { \$n * factorial(\$n - 1) }
``````

Check Jonathan Worthington's journal on use.perl.org, for more information about the last example.

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# REBOL

Math is definitely not one of REBOL's strong points, since it lacks arbitrary precision integers. For the sake of completeness, I thought I'd add it anyway.

Here's a standard, naïve recursive implementation:

```fac: func [ [catch] n [integer!] ] [
if n < 0 [ throw make error! "Hey dummy, your argument was less than 0!" ]
either n = 0 [ 1 ] [
n * fac (n - 1)
]
]```

And that's about it. Move along, folks, nothing to see here ... :)

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# LazyK

Your pure functional programming nightmares come true!

The only Esoteric Turing-complete Programming Language that has:

Here's the Factorial code in all its parenthetical glory:

``````K(SII(S(K(S(S(KS)(S(K(S(KS)))(S(K(S(KK)))(S(K(S(K(S(K(S(K(S(SI(K(S(K(S(S(KS)K)I))
(S(S(KS)K)(SII(S(S(KS)K)I))))))))K))))))(S(K(S(K(S(SI(K(S(K(S(SI(K(S(K(S(S(KS)K)I))
(S(S(KS)K)(SII(S(S(KS)K)I))(S(S(KS)K))(S(SII)I(S(S(KS)K)I))))))))K)))))))
(S(S(KS)K)(K(S(S(KS)K)))))))))(K(S(K(S(S(KS)K)))K))))(SII))II)
``````

Features:

• No subtraction or conditionals
• Prints all factorials (if you wait long enough)
• Uses a second layer of Church numerals to convert the Nth factorial to N! asterisks followed by a newline
• Uses the Y combinator for recursion

In case you are interested in trying to understand it, here is the Scheme source code to run through the Lazier compiler:

``````(lazy-def '(fac input)
'((Y (lambda (f n a) ((lambda (b) ((cons 10) ((b (cons 42)) (f (1+ n) b))))
(* a n)))) 1 1))
``````

(for suitable definitions of Y, cons, 1, 10, 42, 1+, and *).

EDIT:

# Lazy K Factorial in Decimal

(10KB of gibberish or else I would paste it). For example, at the Unix prompt:

```    \$ echo "4" | ./lazy facdec.lazy
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

This is one of the faster algorithms, up to 170!. It fails inexplicably beyond 170!, and it's relatively slow for small factorials, but for factorials between 80 and 170 it's blazingly fast compared to many algorithms.

``````curl http://www.google.com/search?q=170!
``````

There's also an online interface, try it out now!

Let me know if you find a bug, or faster implementation for large factorials.

### EDIT:

This algorithm is slightly slower, but gives results beyond 170:

``````curl http://www58.wolframalpha.com/input/?i=171!
``````

It also simplifies them into various other representations.

-
Use MPFR (mpfr.org). It allows floats with exponents in the 2^(2^32) range, or so... –  Jared Updike Sep 16 '08 at 22:11
I managed to get it to work all the way up to 170.6243769! –  Evan Fosmark Feb 23 '09 at 2:06
That's a thing Wolfram Alpha performs better at than Google does :) –  Moritz Beutel Jun 5 '09 at 13:18
Google uses 1024bit numbers for internal representation. 171! is too big to fit in 1024 bits. –  LiraNuna Feb 19 '10 at 20:17
... and the formatting of the page is destroyed! –  Lazer Jun 22 '10 at 7:32
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Perl, pessimal:

``````# Because there are just so many other ways to get programs wrong...
use strict;
use warnings;

sub factorial {
my (\$x)=@_;

for(my \$f=1;;\$f++) {
my \$tmp=\$f;
foreach my \$g (1..\$x) {
\$tmp/=\$g;
}
return \$f if \$tmp == 1;
}
}
``````

I trust I get extra points for not using the '*' operator...

-
show 1 more comment

Another ruby one.

``````class Integer
def fact
return 1 if self.zero?
(1..self).to_a.inject(:*)
end
end``````

This works if to_proc is supported on symbols.

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